source: svn/trunk/Delphes.cpp@ 264

/***********************************************************************
**                                                                    **
**          /----------------------------------------------\          **
**         |  Delphes, a framework for the fast simulation  |         **
**         |       of a  generic collider experiment        |         **
**          \----------------------------------------------/          **
**                                                                    **
**                                                                    **
**   This package uses:                                               **
**   ------------------                                               **
**   FastJet algorithm: Phys. Lett. B641 (2006) [hep-ph/0512210]      ** 
**   Hector: JINST 2:P09005 (2007) [physics.acc-ph:0707.1198v2]       ** 
**   FROG: [hep-ex/0901.2718v1]                                       **
**                                                                    **
** ------------------------------------------------------------------ **
**                                                                    **
**   Main authors:                                                    **
**   -------------                                                    **
**                                                                    **
**                Severine Ovyn                Xavier Rouby           ** 
**          severine.ovyn@uclouvain.be      xavier.rouby@cern         ** 
**                                                                    ** 
**         Center for Particle Physics and Phenomenology (CP3)        ** 
**                Universite catholique de Louvain (UCL)              **       
**                     Louvain-la-Neuve, Belgium                      **            
**                                                                    **
**                      Copyright (C) 2008-2009,                      **
**                        All rights reserved.                        **  
**                                                                    **
***********************************************************************/

/// \file Delphes.cpp
/// \brief Executable for Delphes

#include "TChain.h"
#include "TApplication.h"
#include "TStopwatch.h"
#include "TFile.h"

#include "ExRootTreeReader.h"
#include "ExRootTreeWriter.h"
#include "ExRootTreeBranch.h"
#include "ExRootProgressBar.h"

#include "DataConverter.h"
#include "HEPEVTConverter.h"
#include "LHEFConverter.h"
#include "STDHEPConverter.h"

#include "SmearUtil.h"
#include "CaloUtil.h"
#include "BFieldProp.h"
#include "TriggerUtil.h"
#include "VeryForward.h"
#include "JetsUtil.h"
#include "FrogUtil.h"

#include <vector>
#include <iostream>

using namespace std;

//------------------------------------------------------------------------------
void todo(string filename) {
  ifstream infile(filename.c_str());
  cout << "** TODO list ..." << endl;
  while(infile.good()) {
    string temp;
    getline(infile,temp);
    cout << "*" << temp << endl;
  }
  cout << "** done...\n"; 
}

//------------------------------------------------------------------------------

int main(int argc, char *argv[])
{
unsigned int nnnn=0, mmmm=0;

  int appargc = 2;
  char *appName= new char[20];
  char *appOpt= new char[20];
  sprintf(appName,"Delphes");
  sprintf(appOpt,"-b");
  char *appargv[] = {appName,appOpt};
  TApplication app(appName, &appargc, appargv);
  delete [] appName;
  delete [] appOpt;

  if(argc != 3 && argc != 4 && argc != 5) {
    cout << " Usage: " << argv[0] << " input_file output_file [detector_card] [trigger_card] " << endl;
    cout << " input_list - list of files in Ntpl, StdHep of LHEF format," << endl;
    cout << " output_file - output file." << endl;
    cout << " detector_card - Datacard containing resolution variables for the detector simulation (optional) "<<endl;
    cout << " trigger_card - Datacard containing the trigger algorithms (optional) "<<endl;
    exit(1);
  }


  
 
cout << endl << endl;

cout <<"*********************************************************************"<< endl;
cout <<"*********************************************************************"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**                            Welcome to                           **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**     .ddddddd-            lL             hH                      **"<< endl;
cout <<"**     -Dd` `dD:           Ll             hH`                      **"<< endl;
cout <<"**     dDd   dDd    eeee.  lL  .pp+pp    Hh+hhh`   -eeee- `sssss   **"<< endl;
cout <<"**    -Dd   `DD   ee. ee  Ll   .Pp. PP   Hh. HH.  ee. ee  sSs      **"<< endl;
cout <<"**    dD`   dDd  eEeee:   lL.  pP.  pP  hH   hH` eEeee:` -sSSSs.   **"<< endl;
cout <<"**   .Dd  :dd    eE.     LlL   PpppPP   Hh  Hh   eE         sSS    **"<< endl;
cout <<"**   dddddd:.     eee+:  lL.  pp.      hh.  hh    eee+  sssssS     **"<< endl;
cout <<"**                            Pp                                   **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**           Delphes, a framework for the fast simulation          **"<< endl;
cout <<"**                 of a  generic collider experiment               **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**                --- Version 1.4beta of Delphes ---               **"<< endl;
cout <<"**               Last date of change: 9 February 2009              **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**     This package uses:                                          **"<< endl;
cout <<"**     ------------------                                          **"<< endl;
cout <<"**     FastJet algorithm: Phys. Lett. B641 (2006) [hep-ph/0512210] **"<< endl;
cout <<"**     Hector: JINST 2:P09005 (2007) [physics.acc-ph:0707.1198v2]  **"<< endl;
cout <<"**     FROG:                               [hep-ex/0901.2718v1]    **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**-----------------------------------------------------------------**"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**   Main authors:                                                 **"<< endl;
cout <<"**   -------------                                                 **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**              Séverine Ovyn               Xavier Rouby           **"<< endl;
cout <<"**       severine.ovyn@uclouvain.be      xavier.rouby@cern         **"<< endl;
cout <<"**       Center for Particle Physics and Phenomenology (CP3)       **"<< endl;
cout <<"**       Universite Catholique de Louvain (UCL)                    **"<< endl;
cout <<"**       Louvain-la-Neuve, Belgium                                 **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**-----------------------------------------------------------------**"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**   Former Delphes versions and documentation can be found on :   **"<< endl;
cout <<"**               http://www.fynu.ucl.ac.be/delphes.html            **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"**   Disclaimer: this program is a beta version of Delphes and     **"<< endl;
cout <<"** therefore comes without guarantees. Beware of errors and please **"<< endl;
cout <<"**        give us your feedbacks about potential bugs              **"<< endl;
cout <<"**                                                                 **"<< endl;
cout <<"*********************************************************************"<< endl;
cout <<"*********************************************************************"<< endl;
 
// 1. ********** initialisation ***********

  srand (time (NULL));         /* Initialisation du générateur */
  TStopwatch globalwatch, loopwatch, triggerwatch, frogwatch;
  globalwatch.Start();

  
  //read the output TROOT file
  string inputFileList(argv[1]), outputfilename(argv[2]);
  if(outputfilename.find(".root") > outputfilename.length()) {
    cout <<"**    ERROR: 'output_file' should be a .root file. Exiting...      **"<< endl;
    exit(1);
  }
  //create output log-file name
  string forLog = outputfilename;
  string LogName = forLog.erase(forLog.find(".root"));
  LogName = LogName+"_run.log";
  
  TFile *outputFile = TFile::Open(outputfilename.c_str(), "RECREATE"); // Creates the file, but should be closed just after
  outputFile->Close();
  
  string line;
  ifstream infile(inputFileList.c_str());
  infile >> line; // the first line determines the type of input files
  
  //read the datacard input file
  string DetDatacard("");                  //for detector smearing parameters
  string TrigDatacard("data/trigger.dat"); //for trigger selection
 
  string lineCard1,lineCard2;
  bool detecCard=false,trigCard=false;
  if(argv[3]) 
    {  
      ifstream infile1(argv[3]);
      infile1 >> lineCard1; // the first line determines the type of input files
      if(strstr(lineCard1.c_str(),"DETECTOR") && detecCard==true) 
           cerr <<"**         ERROR: A DETECTOR card has already been loaded          **"<< endl;
      else if(strstr(lineCard1.c_str(),"DETECTOR") && detecCard==false){DetDatacard =argv[3]; detecCard=true;}
      else if(strstr(lineCard1.c_str(),"TRIGGER") && trigCard==true)
           cerr <<"**         ERROR: A TRIGGER card has already been loaded           **"<< endl;
      else if(strstr(lineCard1.c_str(),"TRIGGER") && trigCard==false){TrigDatacard =argv[3]; trigCard=true;}
    }
  if(argv[4])
    {  
      ifstream infile2(argv[4]);
      infile2 >> lineCard2; // the first line determines the type of input files
      if(strstr(lineCard2.c_str(),"DETECTOR") && detecCard==true)
           cerr <<"**         ERROR: A DETECTOR card has already been loaded          **"<< endl;
      else if(strstr(lineCard2.c_str(),"DETECTOR") && detecCard==false){DetDatacard =argv[4]; detecCard=true;}
      else if(strstr(lineCard2.c_str(),"TRIGGER") && trigCard==true)
           cerr <<"**         ERROR: A TRIGGER card has already been loaded           **"<< endl;
      else if(strstr(lineCard2.c_str(),"TRIGGER") && trigCard==false){TrigDatacard =argv[4]; trigCard=true;}
    }
  
  //Smearing information
  RESOLution *DET = new RESOLution();
  cout <<"**                                                                 **"<< endl;
  cout <<"**        ####### Start reading DETECTOR parameters #######        **"<< endl;
  cout << left  << setw(40) <<"**        Opening configuration card: "<<""
       << left  << setw(27) << DetDatacard                            <<""
       << right << setw(2) <<"**"<<""<<endl;
  DET->ReadDataCard(DetDatacard);
  DET->Logfile(LogName);
  cout << left  << setw(42) <<"**        Parameters summarised in file: "<<""
       << left  << setw(27) << LogName                            <<""
       << right << setw(2) <<"**"<<""<<endl;
  cout <<"**                                                                 **"<< endl;

  //Trigger information
  cout <<"**        ########### Start reading TRIGGER card ##########        **"<< endl;
  if(trigCard==false)
     {
       cout <<"**        WARNING: Datadard  not found, use default card           **" << endl;
       TrigDatacard="data/trigger.dat";
     }
  TriggerTable *TRIGT = new TriggerTable();
  TRIGT->TriggerCardReader(TrigDatacard.c_str());
  TRIGT->PrintTriggerTable(LogName);
  if(DET->FLAG_trigger == 1)
    {
      cout << left  << setw(40) <<"**        Opening configuration card: "<<""
           << left  << setw(27) << TrigDatacard                            <<""
           << right << setw(2) <<"**"<<""<<endl;
      cout <<"**                                                                 **"<< endl;
    }
  
  //Propagation of tracks in the B field
  TrackPropagation *TRACP = new TrackPropagation(DET); 
  
  //Jet information
  JetsUtil *JETRUN = new JetsUtil(DET);
  
  //VFD information
  VeryForward * VFD = new VeryForward(DET);
 
  // data converters
  DataConverter *converter=NULL;
  cout <<"**                                                                 **"<<endl;
  cout <<"**        ####### Start convertion to TRoot format ########        **"<< endl;

  if(strstr(line.c_str(),".hep"))
    {                           
      cout <<"**                 StdHEP file format detected                     **"<<endl;
      cout <<"**                This can take several minutes                    **"<< endl;
      converter = new STDHEPConverter(inputFileList,outputfilename);//case ntpl file in input list
    }
  else if(strstr(line.c_str(),".lhe"))
    {
      cout <<"**                   LHEF file format detected                     **"<<endl;
      cout <<"**                 This can take several minutes                   **"<< endl;
      converter = new LHEFConverter(inputFileList,outputfilename);//case ntpl file in input list
    }
  else if(strstr(line.c_str(),".root"))
    {
      cout <<"**                   h2root file format detected                   **"<<endl;
      cout <<"**                  This can take several minutes                  **"<< endl;
      converter = new HEPEVTConverter(inputFileList,outputfilename);//case ntpl file in input list
    }
  else {
      cerr << left  << setw(4) <<"**  "<<""
           << left  << setw(63) << line.c_str() <<""
           << right << setw(2) <<"**"<<endl;
      cerr <<"**         ERROR: File format not identified --  Exiting...        **"<< endl;
      cout <<"**                                                                 **"<< endl;
      cout <<"*********************************************************************"<< endl;
      return -1;};
  cout <<"**                       Exiting conversion...                     **"<< endl;

  TChain chain("GEN");
  chain.Add(outputfilename.c_str());
  ExRootTreeReader *treeReader = new ExRootTreeReader(&chain);
  const TClonesArray *branchGen = treeReader->UseBranch("Particle");

  TIter itGen((TCollection*)branchGen);
  
  //Output file : contents of the analysis object data
  ExRootTreeWriter *treeWriter = new ExRootTreeWriter(outputfilename, "Analysis");
  ExRootTreeBranch *branchJet = treeWriter->NewBranch("Jet", TRootJet::Class());
  ExRootTreeBranch *branchTauJet = treeWriter->NewBranch("TauJet", TRootTauJet::Class());
  ExRootTreeBranch *branchElectron = treeWriter->NewBranch("Electron", TRootElectron::Class());
  ExRootTreeBranch *branchMuon = treeWriter->NewBranch("Muon", TRootMuon::Class());
  ExRootTreeBranch *branchPhoton = treeWriter->NewBranch("Photon", TRootPhoton::Class());
  //ExRootTreeBranch *branchTracks = treeWriter->NewBranch("Tracks", TRootTracks::Class());
  ExRootTreeBranch *branchTrack = treeWriter->NewBranch("Tracks", D_Track::Class());
  ExRootTreeBranch *branchETmis = treeWriter->NewBranch("ETmis", TRootETmis::Class());
  ExRootTreeBranch *branchCalo = treeWriter->NewBranch("CaloTower", TRootCalo::Class());
  ExRootTreeBranch *branchZDC = treeWriter->NewBranch("ZDChits", TRootZdcHits::Class());
  ExRootTreeBranch *branchRP220 = treeWriter->NewBranch("RP220hits", TRootRomanPotHits::Class());
  ExRootTreeBranch *branchFP420 = treeWriter->NewBranch("FP420hits", TRootRomanPotHits::Class());
  
  TRootETmis *elementEtmis;
  TRootElectron *elementElec;
  TRootMuon *elementMu;
  TRootPhoton *elementPhoton;
  D_Track * elementTrack;
  TRootCalo *elementCalo;
  
  TLorentzVector genMomentum(0,0,0,0);        // four-momentum at the vertex
  TLorentzVector genMomentumBfield(0,0,0,0);  // four-momentum at the exit of the tracks
  TLorentzVector momentumCaloSegmentation(0,0,0,0);    // four-momentum in the calo, after applying the calo segmentation
  LorentzVector jetMomentum;
  
  vector<fastjet::PseudoJet> input_particles;//for FastJet algorithm
  vector<fastjet::PseudoJet> sorted_jets;
  vector<TLorentzVector> TrackCentral;  
  vector<PhysicsTower> towers;
  //vector<ParticleUtil> electron;
  vector<D_Particle> electron;
  //vector<ParticleUtil> muon;
  vector<D_Particle> muon;
  //vector<ParticleUtil> gamma;
  vector<D_Particle> gamma;

  TSimpleArray<TRootGenParticle> NFCentralQ;

D_CaloList list_of_calorimeters;
D_CaloElement CentralCalo("centralcalo", 
        -DET->CEN_max_calo_cen, DET->CEN_max_calo_cen,
         DET->ELG_Ccen,  DET->ELG_Ncen,  DET->ELG_Scen,
         DET->HAD_Chcal, DET->HAD_Nhcal, DET->HAD_Shcal);
D_CaloElement ForwardCalo("forwardcalo",
         DET->CEN_max_calo_cen, DET->CEN_max_calo_fwd, 
         DET->ELG_Cfwd,  DET->ELG_Nfwd,  DET->ELG_Sfwd,
         DET->HAD_Chf,   DET->HAD_Nhf,   DET->HAD_Shf  );
D_CaloElement BackwardCalo("backwardcalo",
        -DET->CEN_max_calo_fwd, -DET->CEN_max_calo_cen,
         DET->ELG_Cfwd,  DET->ELG_Nfwd,  DET->ELG_Sfwd,
         DET->HAD_Chf,   DET->HAD_Nhf,   DET->HAD_Shf  );
//D_CaloElement CastorCalo("castor",5.5,6.6,1,0,0,1,0,0);
list_of_calorimeters.addElement(CentralCalo);
list_of_calorimeters.addElement(ForwardCalo);
list_of_calorimeters.addElement(BackwardCalo);
//list_of_calorimeters.addElement(CastorCalo);
list_of_calorimeters.sortElements();


// 2. ********** Loop over all events ***********
  Long64_t entry, allEntries = treeReader->GetEntries();
  cout <<"**                                                                 **"<<endl;
  cout <<"**        ####### Start fast detector simulation ########          **"<< endl;
  cout << left  << setw(52) <<"**              Total number of events to run: "<<""
       << left  << setw(15) << allEntries <<""
       << right << setw(2) <<"**"<<endl;

  ExRootProgressBar *Progress = new ExRootProgressBar(allEntries);

  loopwatch.Start();

  // loop on all events
  for(entry = 0; entry < allEntries; ++entry)
    {
      Progress->Update(entry);
      TLorentzVector PTmis(0,0,0,0);
      treeReader->ReadEntry(entry);
      treeWriter->Clear();
      
      electron.clear();
      muon.clear();
      gamma.clear();
      NFCentralQ.Clear();
      
      TrackCentral.clear();
      towers.clear();
      input_particles.clear();


/*
if(0) { // OLD SMEARING ALGORITHM without energy flow
      // 2.1 Loop over all particles in event
      itGen.Reset();
      while( (particle = (TRootGenParticle*) itGen.Next()) ) {
          int pid = abs(particle->PID);
          float iPhi=0,iEta=0;

        
          // 2.1.1********************* preparation for the b-tagging
          //// This subarray is needed for the B-jet algorithm
          // optimization for speed : put first PID condition, then ETA condition, then either pt or status
          if( (pid <= pB || pid == pGLUON) &&// is it a light quark or a gluon, i.e. is it one of these : u,d,c,s,b,g ?
              fabs(particle->Eta) < DET->CEN_max_tracker &&
              particle->Status != 1 &&
              particle->PT > DET->PT_QUARKS_MIN ) {
            NFCentralQ.Add(particle);
          }
          
          // 2.1.2 ********************* central detector: keep only visible particles
          // keeps only final particles, visible by the central detector, including the fiducial volume
          // the ordering of conditions have been optimised for speed : put first the STATUS condition
          if( (particle->Status == 1)    &&
              (pid != pNU1) && (pid != pNU2) && (pid != pNU3) &&
              (fabs(particle->Eta) < DET->CEN_max_calo_fwd)
              ) 
            { 
              genMomentum.SetPxPyPzE(particle->Px, particle->Py, particle->Pz, particle->E);
              genMomentumBfield = genMomentum;

              // 2.1.2.1 ********************* central detector: magnetic field
              // genMomentumBfield is then changed with respect to the magnetic field
              if(DET->FLAG_bfield==1)  TRACP->Propagation(particle,genMomentumBfield);
              float eta=fabs(genMomentumBfield.Eta());
             
 
              // 2.1.2.2 ********************* central detector: smearing (calorimeters, muon chambers)
              switch(pid) {
                
              case pE: // all electrons with eta < DET->MAX_CALO_FWD
                DET->SmearElectron(genMomentumBfield);
                if(genMomentumBfield.E()!=0 && eta < DET->CEN_max_tracker && genMomentumBfield.Pt() > DET->PTCUT_elec){
                  electron.push_back(ParticleUtil(genMomentumBfield,particle->PID));
                }
                break; // case pE
              case pGAMMA: // all photons with eta < DET->MAX_CALO_FWD
                DET->SmearElectron(genMomentumBfield);
                if(genMomentumBfield.E()!=0 && eta < DET->CEN_max_tracker && genMomentumBfield.Pt() > DET->PTCUT_gamma) {
                  gamma.push_back(ParticleUtil(genMomentumBfield,particle->PID));
                }
                break; // case pGAMMA
              case pMU: // all muons with eta < DET->MAX_MU
                DET->SmearMu(genMomentumBfield);
                if(genMomentumBfield.E()!=0 && eta < DET->CEN_max_mu &&  genMomentumBfield.Pt() > DET->PTCUT_muon){
                  muon.push_back(ParticleUtil(genMomentumBfield,particle->PID));
                }
                break; // case pMU
              case pLAMBDA: // all lambdas with eta < DET->MAX_CALO_FWD
              case pK0S:    // all K0s with eta < DET->MAX_CALO_FWD
                DET->SmearHadron(genMomentumBfield, 0.7);
                break; // case hadron
              default:   // all other final particles with eta < DET->MAX_CALO_FWD
                DET->SmearHadron(genMomentumBfield, 1.0);
                break;
              } // 2.1.2.2  switch (pid)
             
 
              // 2.1.2.3 ********************* central detector: calotowers
              // all final particles but muons and neutrinos    
              // for calorimetric towers and missing PT
              int charge=Charge(pid); 
              if(genMomentumBfield.E() !=0 && pid != pMU) {
                // in case the Bfield is not simulated, checks that charged particles have enough pt to reach the calos
                if ( !DET->FLAG_bfield && charge!=0 && genMomentumBfield.Pt() <= DET->TRACK_ptmin ) {}// particules do not reach calos 
                else { // particles reach calos 
                  // applies the calo segmentation and returns iEta & iPhi
                  DET->BinEtaPhi(genMomentumBfield.Phi(), genMomentumBfield.Eta(), iPhi, iEta); 
                  if(iEta != UNDEFINED && iPhi != UNDEFINED) { 
                      momentumCaloSegmentation.SetPtEtaPhiE(genMomentumBfield.Pt(),iEta,iPhi,genMomentumBfield.E());
                      elementCalo = (TRootCalo*) branchCalo->NewEntry();
                      elementCalo->Set(momentumCaloSegmentation);
                      PhysicsTower Tower(LorentzVector(momentumCaloSegmentation.Px(),momentumCaloSegmentation.Py(),momentumCaloSegmentation.Pz(),momentumCaloSegmentation.E()));
                      towers.push_back(Tower);
                  } // if iEta != UNDEFINED
                } // else : when particles reach the calos
              } // 2.1.2.3 calotowers


              // 2.1.2.4 ********************* central detector: tracks
              // all final charged particles
              if(
                 (genMomentumBfield.E()!=0) &&
                 (fabs(genMomentumBfield.Eta()) < DET->CEN_max_tracker) && 
                 (DET->FLAG_bfield || ( !DET->FLAG_bfield && genMomentum.Pt() > DET->TRACK_ptmin )) &&     
                        // if bfield not simulated, pt should be high enough to be taken into account
                 ((rand()%100) < DET->TRACK_eff)  &&
                 (charge!=0)
                 )
                {
                  elementTracks = (TRootTracks*) branchTracks->NewEntry();
                  elementTracks->Set(genMomentum); // fills px,py,pz,pt,e,eta,phi at vertex
                  elementTracks->Etaout = genMomentumBfield.Eta();
                  elementTracks->Phiout = genMomentumBfield.Phi();
                  // TODO!!! apply a smearing on the position of the origin of the track
                  // elementTracks->SetPosition(particle->X,particle->Y,particle->Z);
                  // uses the output of the bfield computation : Xout=... Yout=... Zout...
                  // TODO!!! elementTrakcs->SetPositionOut(Xout,Yout,Zout);
                  TrackCentral.push_back(genMomentum); // tracks at vertex!
                } // 2.1.2.4 tracks
              
            } // 2.1.2 central detector
          
          // 2.1.3 ********************* forward detectors: zdc
          if(DET->FLAG_vfd==1) {
             VFD->ZDC(treeWriter,branchZDC,particle);
             VFD->RomanPots(treeWriter,branchRP220,branchFP420,particle);
          }
} // IF OLD ALGORITHM (= no energy flow )




else // IF NEW ALGORITHM with energy flow              
*/
{
      D_CaloTowerList list_of_active_towers; 
      D_CaloTowerList list_of_towers_with_photon; // to speed up the code: will only look in interesting towers for gamma candidates

      // 2.1a Loop over all particles in event, to fill the towers
      itGen.Reset();
      TRootGenParticle *particle; 
      while( (particle = (TRootGenParticle*) itGen.Next()) ) {
          int pid = abs(particle->PID);
          particle->Charge=Charge(pid);
          particle->setFractions(); // init


          // 2.1a.1********************* preparation for the b-tagging
          //// This subarray is needed for the B-jet algorithm
          // optimization for speed : put first PID condition, then ETA condition, then either pt or status
          if( (pid <= pB || pid == pGLUON) &&// is it a light quark or a gluon, i.e. is it one of these : u,d,c,s,b,g ?
              fabs(particle->Eta) < DET->CEN_max_tracker &&
              particle->Status != 1 &&
              particle->PT > DET->PT_QUARKS_MIN ) {
            NFCentralQ.Add(particle);
          }

          // 2.1a.2********************* visible particles only
          if( (particle->Status == 1) && (pid != pNU1) && (pid != pNU2) && (pid != pNU3) ){

            // 2.1a.2.1 Central solenoidal magnetic field 
            TRACP->bfield(particle); // fills in particle->EtaCalo et particle->PhiCalo
            particle->SetEtaPhi(particle->EtaCalo,particle->PhiCalo); // ???? check this line

            // 2.1a.2.2 Filling the calorimetric towers -- includes also forward detectors ?
            // first checks if the charged particles reach the calo!
            if( DET->FLAG_bfield || 
                particle->getCharge()==0 ||
                (!DET->FLAG_bfield && particle->getCharge()!=0 && particle->PT > DET->TRACK_ptmin)) 
            if(
                (particle->EtaCalo > list_of_calorimeters.getEtamin() ) &&
                (particle->EtaCalo < list_of_calorimeters.getEtamax() )
              ) {
                float iEta=UNDEFINED, iPhi=UNDEFINED;
                DET->BinEtaPhi(particle->PhiCalo,particle->EtaCalo,iPhi,iEta); // fills in iPhi and iEta
                if (iEta != UNDEFINED && iPhi != UNDEFINED) 
                {
                  D_CaloTower tower(iEta,iPhi);                                // new tower
                  tower.Set_Eem_Ehad_E_ET(particle->E*particle->getFem() , particle->E*particle->getFhad() );
                
                  list_of_active_towers.addTower(tower);
                  // this list may contain several times the same calotower, as several particles 
                  // may leave some energy in the same calotower
                  // After the loop on particles, identical cells in the list should be merged 
                } // iEta and iPhi must be defined
            }

            // 2.1a.2.3 charged particles in tracker: energy flow
            // if bfield not simulated, pt should be high enough to be taken into account
            // it is supposed here that DET->MAX_calo > DET->CEN_max_tracker > DET->CEN_max_mu > 0
            if( particle->getCharge() !=0 &&
                fabs(particle->EtaCalo)< DET->CEN_max_tracker && // stays in the tracker -> track available
               ( DET->FLAG_bfield || 
                  (!DET->FLAG_bfield && particle->PT > DET->TRACK_ptmin)
                )
              ) {       
                // 2.1a.2.3.1 Filling the particle properties + smearing
                   // Hypothesis: the final eta/phi are the ones from the generator, thanks to the track reconstruction
                   // This is the EnergyFlow hypothesis
                   particle->SetEtaPhi(particle->Eta,particle->Phi);
                   float sET=UNDEFINED; // smeared ET, computed from the smeared E -> needed for the tracks

                   // 2.1a.2.3.2 Muons
                   if (pid == pMU && fabs(particle->EtaCalo)< DET->CEN_max_mu && particle->PT > DET->PTCUT_muon ) {
                        TLorentzVector p;
                        float sPT = gRandom->Gaus(particle->PT, DET->MU_SmearPt*particle->PT );
                        if (sPT > 0 && sPT > DET->PTCUT_muon) {
                           p.SetPtEtaPhiE(sPT,particle->Eta,particle->Phi,sPT*cosh(particle->Eta));
                           muon.push_back(D_Particle(p,pMU,particle->EtaCalo,particle->PhiCalo));
                        }
                        sET = (sPT >0)? sPT : 0;
                   }  
                   // 2.1a.2.3.3 Electrons
                   else if (pid == pE) {
                     // Finds in which calorimeter the particle has gone, to know its resolution

                     D_CaloElement currentCalo = list_of_calorimeters.getElement(particle->EtaCalo);
                     if(currentCalo.getName() == dummyCalo.getName()) {
                        cout << "** Warning: the calo coverage behind the tracker is not complete! **" << endl; }

                     // final smeared EM energy   // electromagnetic fraction F_em =1 for electrons;
                     float sE  = currentCalo.getElectromagneticResolution().Smear(particle->E);
                     if (sE>0) {
                       sET = sE/cosh(particle->Eta); 
                       // NB: ET is found via the calorimetry and not via the track curvature

                       TLorentzVector p;
                       p.SetPtEtaPhiE(sET,particle->Eta,particle->Phi,sE);
                       if (sET > DET->PTCUT_elec)
                         electron.push_back(D_Particle(p,particle->PID,particle->EtaCalo,particle->PhiCalo));
                     } else { sET=0;} // if negative smeared energy -- needed for the tracks
                   }  
                   // 2.1a.2.3.4 Other charged particles : smear them for the tracks!
                   else {  //other particles
                        D_CaloElement currentCalo = list_of_calorimeters.getElement(particle->EtaCalo);
                        float sEem  = currentCalo.getElectromagneticResolution().Smear(particle->E * particle->getFem());
                        float sEhad = currentCalo.getHadronicResolution().Smear(particle->E * particle->getFhad());
                        float sE = ( (sEem>0)? sEem : 0 ) + ( (sEhad>0)? sEhad : 0 );
                        sET = sE/cosh(particle->EtaCalo);
                   }

                   // 2.1a.2.3.5 Tracks
                   if( (rand()%100) < DET->TRACK_eff && sET!=0) {
                     elementTrack = (D_Track*) branchTrack->NewEntry();
                     elementTrack->Set(particle->Eta, particle->Phi, particle->EtaCalo, particle->PhiCalo, sET);
                     TrackCentral.push_back(elementTrack->GetFourVector()); // tracks at vertex!
                     // TODO!!! associates the tracks to the calo where it points to
                     // TODO!!! apply a smearing on the position of the origin of the track
                     // TODO!!! elementTracks->SetPositionOut(Xout,Yout,Zout);
                   }
            } // 2.1a.2.3 : if tracker/energy-flow
            // 2.1a.2.4 Photons
               // stays in the tracker -> track available -> gamma ID
            else if( (pid == pGAMMA) && fabs(particle->EtaCalo)< DET->CEN_max_tracker ) {
                float iEta=UNDEFINED, iPhi=UNDEFINED;
                DET->BinEtaPhi(particle->PhiCalo,particle->EtaCalo,iPhi,iEta); // fills in iPhi and iEta
                D_CaloTower tower(iEta,iPhi); 
                // stores the list of towers where to apply the photon ID algorithm. Just a trick for a faster search
                list_of_towers_with_photon.addTower(tower); 
            }
            // 2.1a.2.5 : very forward detectors
            else if (DET->FLAG_vfd==1) {
                // for the moment, only protons are transported
                // BUT !!! could be a beam of other particles! (heavy ions?)
                // BUT ALSO !!! if very forward muons, or others!
              VFD->RomanPots(treeWriter,branchRP220,branchFP420,particle);
              VFD->ZDC(treeWriter,branchZDC,particle);
            }
            // 2.1a.2.6: Zero degree calorimeter
            //else if(DET->FLAG_zdc==1) {
              //VFD->ZDC(treeWriter,branchZDC,particle);
            //}

          } // 2.1a.2 : if visible particle
      } // loop on all particles 2.1a
        

      // 2.1b loop on all (activated) towers
      // at this stage, list_of_active_towers may contain several times the same tower
      // first step is to merge identical towers, by matching their (iEta,iPhi)  
      list_of_active_towers.mergeDuplicates();
      // Calotower smearing 
      list_of_active_towers.smearTowers(list_of_calorimeters);

      for(unsigned int i=0; i<list_of_active_towers.size(); i++) {
        float iEta = list_of_active_towers[i].getEta();
        float iPhi = list_of_active_towers[i].getPhi();
        float e = list_of_active_towers[i].getE(); 
        if(iEta != UNDEFINED && iPhi != UNDEFINED && e!=0) {
           elementCalo = (TRootCalo*) branchCalo->NewEntry();
           elementCalo->set(list_of_active_towers[i]);
           // not beautiful : should be improved!
           TLorentzVector p;
           p.SetPtEtaPhiE(list_of_active_towers[i].getET(), iEta, iPhi, e );
           PhysicsTower Tower(LorentzVector(p.Px(),p.Py(),p.Pz(),p.E()));
           towers.push_back(Tower);
        }
      } // loop on towers

      // 2.1c photon ID
      // list_of_towers_with_photon is the list of towers with photon candidates
      // already smeared !
      // sorts the vector and smears duplicates 
      list_of_towers_with_photon.mergeDuplicates(); 

      for(unsigned int i=0; i<list_of_towers_with_photon.size(); i++) {
          float eta = list_of_towers_with_photon[i].getEta(); 
          float phi = list_of_towers_with_photon[i].getPhi();
          D_CaloTower cal(list_of_active_towers.getElement(eta,phi));
          if(cal.getEta() != UNDEFINED && cal.getPhi() != UNDEFINED &&  cal.getE() > 0) {
            TLorentzVector p;
            p.SetPtEtaPhiE(cal.getET(), eta,phi,cal.getE() );
            if (cal.getET() > DET->PTCUT_gamma) { gamma.push_back(D_Particle(p,pGAMMA,p.Eta(),p.Phi())); }
          }
      } // for -- list of photons

}  // IF NEW ALGORITHM with energy flow




      // 2.2 ********** Output preparation & complex objects  ***********
      // 2.2.1 ********************* sorting collections by decreasing pt
      DET->SortedVector(electron); 
      for(unsigned int i=0; i < electron.size(); i++) {
        elementElec = (TRootElectron*) branchElectron->NewEntry();
        elementElec->Set(electron[i].Px(),electron[i].Py(),electron[i].Pz(),electron[i].E());
        elementElec->EtaCalo = electron[i].EtaCalo(); 
        elementElec->PhiCalo = electron[i].PhiCalo();
        elementElec->Charge = sign(electron[i].PID());
        elementElec->IsolFlag = DET->Isolation(electron[i].Phi(),electron[i].Eta(),TrackCentral,2.0);//isolation based on tracks
      }
      DET->SortedVector(muon);
      for(unsigned int i=0; i < muon.size(); i++) {
        elementMu = (TRootMuon*) branchMuon->NewEntry();
        elementMu->Charge = sign(muon[i].PID());
        elementMu->Set(muon[i].Px(),muon[i].Py(),muon[i].Pz(),muon[i].E());
        elementMu->EtaCalo = muon[i].EtaCalo(); 
        elementMu->PhiCalo = muon[i].PhiCalo();
        elementMu->IsolFlag = DET->Isolation(muon[i].Phi(),muon[i].Eta(),TrackCentral,2.0);
      }
      DET->SortedVector(gamma);
      for(unsigned int i=0; i < gamma.size(); i++) {
        elementPhoton = (TRootPhoton*) branchPhoton->NewEntry();
        elementPhoton->Set(gamma[i].Px(),gamma[i].Py(),gamma[i].Pz(),gamma[i].E());
        elementPhoton->EtaCalo = gamma[i].EtaCalo();
        elementPhoton->PhiCalo = gamma[i].PhiCalo();
      }
      
      // 2.2.2 ************* computes the Missing Transverse Momentum
      TLorentzVector Att(0.,0.,0.,0.);
      for(unsigned int i=0; i < towers.size(); i++)
        {
          Att.SetPxPyPzE(towers[i].fourVector.px, towers[i].fourVector.py, towers[i].fourVector.pz, towers[i].fourVector.E);
          if(fabs(Att.Eta()) < DET->CEN_max_calo_fwd)
          {
            PTmis = PTmis + Att;
            // create a fastjet::PseudoJet with these components and put it onto
            // back of the input_particles vector
            input_particles.push_back(fastjet::PseudoJet(towers[i].fourVector.px,towers[i].fourVector.py,towers[i].fourVector.pz,towers[i].fourVector.E));
          }
        }
      elementEtmis = (TRootETmis*) branchETmis->NewEntry();
      elementEtmis->ET = (PTmis).Pt();
      elementEtmis->Phi = (-PTmis).Phi();
      elementEtmis->Px = (-PTmis).Px();
      elementEtmis->Py = (-PTmis).Py();
      
      // 2.2.3 ************* jets, B-tag, tau jets
      sorted_jets=JETRUN->RunJets(input_particles);
      JETRUN->RunJetBtagging(treeWriter, branchJet,sorted_jets,NFCentralQ);
      JETRUN->RunTauJets(treeWriter,branchTauJet,sorted_jets,towers, TrackCentral);
      
      treeWriter->Fill();
    } // 2. Loop over all events ('for' loop)


  cout <<"**                                                                 **"<< endl;
  cout <<"**                 Exiting detector simulation...                  **"<< endl;

 
  treeWriter->Write();
  delete treeWriter;
  loopwatch.Stop();
 

 
  // 3. ********** Trigger  & Frog ***********
  // 3.1 ************ running the trigger in case the FLAG trigger is put to 1 in the datacard
  triggerwatch.Start();
  if(DET->FLAG_trigger == 1)
    {
       cout <<"**                                                                 **"<<endl;
       cout <<"**        ########### Start Trigger selection ###########          **"<< endl;

      // input
      TChain chainT("Analysis");
      chainT.Add(outputfilename.c_str());
      ExRootTreeReader *treeReaderT = new ExRootTreeReader(&chainT);
      
      // output
      TClonesArray *branchElecTrig = treeReaderT->UseBranch("Electron");
      TClonesArray *branchMuonTrig = treeReaderT->UseBranch("Muon");
      TClonesArray *branchJetTrig = treeReaderT->UseBranch("Jet");
      TClonesArray *branchTauJetTrig = treeReaderT->UseBranch("TauJet");
      TClonesArray *branchPhotonTrig = treeReaderT->UseBranch("Photon");
      TClonesArray *branchETmisTrig = treeReaderT->UseBranch("ETmis");
      
      ExRootTreeWriter *treeWriterT = new ExRootTreeWriter(outputfilename, "Trigger");
      ExRootTreeBranch *branchTrigger = treeWriterT->NewBranch("TrigResult", TRootTrigger::Class());
     
 
      Long64_t entryT, allEntriesT = treeReaderT->GetEntries();
      // loop on all entries
      for(entryT = 0; entryT < allEntriesT; ++entryT) {
          treeWriterT->Clear();
          treeReaderT->ReadEntry(entryT);
          TRIGT->GetGlobalResult(branchElecTrig, branchMuonTrig,branchJetTrig, branchTauJetTrig,branchPhotonTrig, branchETmisTrig,branchTrigger);
          treeWriterT->Fill();
      } // loop on all entries
      cout <<"**                 Exiting trigger simulation...                   **"<< endl;
      
      treeWriterT->Write();
      delete treeWriterT;
      delete treeReaderT;
    } // trigger
    triggerwatch.Stop();
 
 
  // 3.2 ************** FROG display
  frogwatch.Start();
  if(DET->FLAG_frog == 1) {
      cout <<"**                                                                 **"<<endl;
      cout <<"**        ################## Start FROG #################          **"<< endl;

      FrogDisplay *FROG = new FrogDisplay(DET);
      FROG->BuildEvents(outputfilename);
      FROG->BuildGeom();
      delete FROG;
  }
  frogwatch.Stop();
  



// 4. ********** End & Exit ***********

  globalwatch.Stop();
  cout <<"**                                                                 **"<< endl;
  cout <<"**        ################## Time report #################         **"<< endl;
  cout << left  << setw(32) <<"**              Time report for "<<""
              << left  << setw(15) << allEntries <<""
              << right << setw(22) <<"events         **"<<endl;
  cout <<"**                                                                 **"<< endl;
  cout << left  << setw(10) <<"**"<<""
       << left  << setw(15) <<"Time (s):"<<""
       << right << setw(15) <<"CPU"<<""
       << right << setw(15) <<"Real"<<""
       << right << setw(14)  <<"**"<<endl;
  cout << left  << setw(10) <<"**"<<""
       << left  << setw(15) <<" +  Global:"<<""
       << right << setw(15) <<globalwatch.CpuTime()<<""
       << right << setw(15) <<globalwatch.RealTime()<<""
       << right << setw(14)  <<"**"<<endl;
  cout << left  << setw(10) <<"**"<<""
       << left  << setw(15) <<" +  Events:"<<""
       << right << setw(15) <<loopwatch.CpuTime()<<""
       << right << setw(15) <<loopwatch.RealTime()<<""
       << right << setw(14)  <<"**"<<endl;
  if(DET->FLAG_trigger == 1)
    {
     cout << left  << setw(10) <<"**"<<""
          << left  << setw(15) <<" +  Trigger:"<<""
          << right << setw(15) <<triggerwatch.CpuTime()<<""
          << right << setw(15) <<triggerwatch.RealTime()<<""
          << right << setw(14)  <<"**"<<endl;
    }
  if(DET->FLAG_frog == 1)
    {
     cout << left  << setw(10) <<"**"<<""
          << left  << setw(15) <<" +  Frog:"<<""
          << right << setw(15) <<frogwatch.CpuTime()<<""
          << right << setw(15) <<frogwatch.RealTime()<<""
          << right << setw(14)  <<"**"<<endl;

    }
  
   cout <<"**                                                                 **"<< endl;
   cout <<"**                        Exiting Delphes ...                      **"<< endl;
   cout <<"**                                                                 **"<< endl;
   cout <<"*********************************************************************"<< endl;
   cout <<"*********************************************************************"<< endl;


  delete treeReader;
  delete DET;
  delete TRIGT;
  delete TRACP;
  delete JETRUN;
  delete VFD;
  delete converter;
  
//  todo("TODO");
}