[u/mrichter/AliRoot.git] / THijing / AliGenHijing.cxx

/**************************************************************************
 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 *                                                                        *
 * Author: The ALICE Off-line Project.                                    *
 * Contributors are mentioned in the code where appropriate.              *
 *                                                                        *
 * Permission to use, copy, modify and distribute this software and its   *
 * documentation strictly for non-commercial purposes is hereby granted   *
 * without fee, provided that the above copyright notice appears in all   *
 * copies and that both the copyright notice and this permission notice   *
 * appear in the supporting documentation. The authors make no claims     *
 * about the suitability of this software for any purpose. It is          *
 * provided "as is" without express or implied warranty.                  *
 **************************************************************************/

/* $Id$ */

// Generator using HIJING as an external generator
// The main HIJING options are accessable for the user through this interface.
// Uses the THijing implementation of TGenerator.
// Author:
// Andreas Morsch    (andreas.morsch@cern.ch)
//

#include <TClonesArray.h>
#include <TGraph.h>
#include <THijing.h>
#include <TLorentzVector.h>
#include <TPDGCode.h>
#include <TParticle.h>

#include "AliGenHijing.h"
#include "AliGenHijingEventHeader.h"
#include "AliHijingRndm.h"
#include "AliLog.h"
#include "AliRun.h"

ClassImp(AliGenHijing)

AliGenHijing::AliGenHijing()
    :AliGenMC(),
     fFrame("CMS"),
     fMinImpactParam(0.),
     fMaxImpactParam(5.),
     fKeep(0),
     fQuench(1),
     fShadowing(1),
     fDecaysOff(3),
     fTrigger(0),     
     fEvaluate(0),
     fSelectAll(0),
     fFlavor(0),
     fKineBias(0.),
     fTrials(0),
     fXsection(0.),
     fHijing(0),
     fPtHardMin(2.0),
     fPtHardMax(-1),
     fSpectators(1),
     fDsigmaDb(0),
     fDnDb(0),
     fPtMinJet(-2.5),
     fEtaMinJet(-20.),
     fEtaMaxJet(+20.),
     fPhiMinJet(0.),
     fPhiMaxJet(2. * TMath::Pi()),
     fRadiation(3),
     fSimpleJet(kFALSE),
     fNoGammas(kFALSE),
     fProjectileSpecn(0),
     fProjectileSpecp(0),
     fTargetSpecn(0),
     fTargetSpecp(0),
     fLHC(kFALSE),
     fRandomPz(kFALSE),
     fNoHeavyQuarks(kFALSE),
     fHeader(AliGenHijingEventHeader("Hijing"))
{
  // Constructor
  fEnergyCMS = 5500.;
  AliHijingRndm::SetHijingRandom(GetRandom());
}

AliGenHijing::AliGenHijing(Int_t npart)
    :AliGenMC(npart),
     fFrame("CMS"),
     fMinImpactParam(0.),
     fMaxImpactParam(5.),
     fKeep(0),
     fQuench(1),
     fShadowing(1),
     fDecaysOff(3),
     fTrigger(0),     
     fEvaluate(0),
     fSelectAll(0),
     fFlavor(0),
     fKineBias(0.),
     fTrials(0),
     fXsection(0.),
     fHijing(0),
     fPtHardMin(2.0),
     fPtHardMax(-1),
     fSpectators(1),
     fDsigmaDb(0),
     fDnDb(0),
     fPtMinJet(-2.5),
     fEtaMinJet(-20.),
     fEtaMaxJet(+20.),
     fPhiMinJet(0.),
     fPhiMaxJet(2. * TMath::Pi()),
     fRadiation(3),
     fSimpleJet(kFALSE),
     fNoGammas(kFALSE),
     fProjectileSpecn(0),
     fProjectileSpecp(0),
     fTargetSpecn(0),
     fTargetSpecp(0),
     fLHC(kFALSE),
     fRandomPz(kFALSE),
     fNoHeavyQuarks(kFALSE),
     fHeader(AliGenHijingEventHeader("Hijing"))
{
// Default PbPb collisions at 5. 5 TeV
//
    fEnergyCMS = 5500.;
    fName = "Hijing";
    fTitle= "Particle Generator using HIJING";
//
//
// Set random number generator   
    AliHijingRndm::SetHijingRandom(GetRandom());
    
}

AliGenHijing::~AliGenHijing()
{
// Destructor
    if ( fDsigmaDb) delete  fDsigmaDb;  
    if ( fDnDb)     delete  fDnDb;  
}

void AliGenHijing::Init()
{
// Initialisation
    fFrame.Resize(8);
    fTarget.Resize(8);
    fProjectile.Resize(8);
    
    SetMC(new THijing(fEnergyCMS, fFrame, fProjectile, fTarget, 
		      fAProjectile, fZProjectile, fATarget, fZTarget, 
		      fMinImpactParam, fMaxImpactParam));

    fHijing=(THijing*) fMCEvGen;
    fHijing->SetIHPR2(2,  fRadiation);
    fHijing->SetIHPR2(3,  fTrigger);
    fHijing->SetIHPR2(6,  fShadowing);
    fHijing->SetIHPR2(12, fDecaysOff);    
    fHijing->SetIHPR2(21, fKeep);
    fHijing->SetHIPR1(8,  fPtHardMin); 	
    fHijing->SetHIPR1(9,  fPtHardMax); 	
    fHijing->SetHIPR1(10, fPtMinJet); 	
    fHijing->SetHIPR1(50, fSimpleJet);
//
//  Quenching
//
//
//  fQuench = 0:  no quenching
//  fQuench = 1:  hijing default
//  fQuench = 2:  new LHC  parameters for HIPR1(11) and HIPR1(14)
//  fQuench = 3:  new RHIC parameters for HIPR1(11) and HIPR1(14)
//  fQuench = 4:  new LHC  parameters with log(e) dependence
//  fQuench = 5:  new RHIC parameters with log(e) dependence
    fHijing->SetIHPR2(50, 0);
    if (fQuench > 0) 
	fHijing->SetIHPR2(4,  1);
    else
	fHijing->SetIHPR2(4,  0);
// New LHC parameters from Xin-Nian Wang
    if (fQuench == 2) {
	fHijing->SetHIPR1(14, 1.1);
	fHijing->SetHIPR1(11, 3.7);
    } else if (fQuench == 3) {
	fHijing->SetHIPR1(14, 0.20);
	fHijing->SetHIPR1(11, 2.5);
    } else if (fQuench == 4) {
	fHijing->SetIHPR2(50, 1);
	fHijing->SetHIPR1(14, 4.*0.34);
	fHijing->SetHIPR1(11, 3.7);
    } else if (fQuench == 5) {
	fHijing->SetIHPR2(50, 1);
	fHijing->SetHIPR1(14, 0.34);
	fHijing->SetHIPR1(11, 2.5);
    }
    
//
// Heavy quarks
//    
    if (fNoHeavyQuarks) {
	fHijing->SetIHPR2(49, 1);
    } else {
	fHijing->SetIHPR2(49, 0);
    }
    
    
    AliGenMC::Init();
    
//
//  Initialize Hijing  
//    
    fHijing->Initialize();
//
    if (fEvaluate) EvaluateCrossSections();
//
}

void AliGenHijing::Generate()
{
// Generate one event

  Float_t polar[3]    =   {0,0,0};
  Float_t origin[3]   =   {0,0,0};
  Float_t origin0[3]  =   {0,0,0};
  Float_t time0 = 0.;
  Float_t p[3];
  Float_t tof;

//  converts from mm/c to s
  const Float_t kconv = 0.001/2.99792458e8;
//
  Int_t nt  = 0;
  Int_t jev = 0;
  Int_t j, kf, ks, ksp, imo;
  kf = 0;
    

  fTrials = 0;
  
  for (j = 0;j < 3; j++) origin0[j] = fOrigin[j];
  time0 = fTimeOrigin;

  if(fVertexSmear == kPerEvent) {
      Vertex();
      for (j=0; j < 3; j++) origin0[j] = fVertex[j];
      time0 = fTime;
  } 


  Float_t sign = (fRandomPz && (Rndm() < 0.5))? -1. : 1.;

  while(1)
  {
//    Generate one event
// --------------------------------------------------------------------------
      fProjectileSpecn    = 0;  
      fProjectileSpecp    = 0;
      fTargetSpecn        = 0;  
      fTargetSpecp        = 0;
// --------------------------------------------------------------------------
      fHijing->GenerateEvent();
      fTrials++;
      fNprimaries = 0;
      fHijing->ImportParticles(&fParticles,"All");
      if (fTrigger != kNoTrigger) {
	  if (!CheckTrigger()) continue;
      }
      if (fLHC) Boost();
      
      
      Int_t np = fParticles.GetEntriesFast();
      Int_t nc = 0;
      if (np == 0 ) continue;
      Int_t i;
      Int_t* newPos     = new Int_t[np];
      Int_t* pSelected  = new Int_t[np];

      for (i = 0; i < np; i++) {
	  newPos[i]    = i;
	  pSelected[i] = 0;
      }
      
//      Get event vertex
//
      fVertex[0] = origin0[0];
      fVertex[1] = origin0[1];	
      fVertex[2] = origin0[2];
      fTime = time0;
//
//      First select parent particles
//
      TParticle *  iparticle = 0;
      for (i = 0; i < np; i++) {
	  iparticle = (TParticle *) fParticles.At(i);

// Is this a parent particle ?
	  if (Stable(iparticle)) continue;
//
	  Bool_t  selected             =  kTRUE;
	  Bool_t  hasSelectedDaughters =  kFALSE;
	  
	  
	  kf        = iparticle->GetPdgCode();
	  ks        = iparticle->GetStatusCode();
	  if (kf == 92) continue;
	    
	  if (!fSelectAll) selected = KinematicSelection(iparticle, 0) && 
			       SelectFlavor(kf);
	  hasSelectedDaughters = DaughtersSelection(iparticle);
//
// Put particle on the stack if it is either selected or 
// it is the mother of at least one seleted particle
//
	  if (selected || hasSelectedDaughters) {
	      nc++;
	      pSelected[i] = 1;
	  } // selected
      } // particle loop parents
//
// Now select the final state particles
//

      for (i = 0; i<np; i++) {
	  iparticle = (TParticle *) fParticles.At(i);
// Is this a final state particle ?
	  if (!Stable(iparticle)) continue;
      
	  Bool_t  selected             =  kTRUE;
	  kf        = iparticle->GetPdgCode();
	  ks        = iparticle->GetStatusCode();
	  ksp       = iparticle->GetUniqueID();
	  
// --------------------------------------------------------------------------
// Count spectator neutrons and protons
	  if(ksp == 0 || ksp == 1){
	      if(kf == kNeutron) fProjectileSpecn += 1;
	      if(kf == kProton)  fProjectileSpecp += 1;
	  }
	  else if(ksp == 10 || ksp == 11){
	      if(kf == kNeutron) fTargetSpecn += 1;
	      if(kf == kProton)  fTargetSpecp += 1;
	  }
// --------------------------------------------------------------------------
//	    
	  if (!fSelectAll) {
	      selected = KinematicSelection(iparticle,0)&&SelectFlavor(kf);
	      if (!fSpectators && selected) selected = (ksp != 0 && ksp != 1 && ksp != 10
							&& ksp != 11);
	  }
//
// Put particle on the stack if selected
//
	  if (selected) {
	      nc++;
	      pSelected[i] = 1;
	  } // selected
      } // particle loop final state

//
// Write particles to stack

      for (i = 0; i<np; i++) {
	  iparticle = (TParticle *) fParticles.At(i);
	  Bool_t  hasMother   = (iparticle->GetFirstMother()     >=0);
	  Bool_t  hasDaughter = (iparticle->GetFirstDaughter()   >=0);
	  if (pSelected[i]) {
	      kf   = iparticle->GetPdgCode();
	      ks   = iparticle->GetStatusCode();
	      p[0] = iparticle->Px();
	      p[1] = iparticle->Py();
	      p[2] = iparticle->Pz() * sign;
	      origin[0] = origin0[0]+iparticle->Vx()/10;
	      origin[1] = origin0[1]+iparticle->Vy()/10;
	      origin[2] = origin0[2]+iparticle->Vz()/10;
	      tof = time0+kconv * iparticle->T();

	      imo = -1;
	      TParticle* mother = 0;
	      if (hasMother) {
		  imo = iparticle->GetFirstMother();
		  mother = (TParticle *) fParticles.At(imo);
		  imo = (mother->GetPdgCode() != 92) ? newPos[imo] : -1;
	      } // if has mother   
	      Bool_t tFlag = (fTrackIt && !hasDaughter);
	      PushTrack(tFlag,imo,kf,p,origin,polar,tof,kPNoProcess,nt, 1., ks);
	      fNprimaries++;
	      KeepTrack(nt);
	      newPos[i] = nt;
	  } // if selected
      } // particle loop
      delete[] newPos;
      delete[] pSelected;
      
      AliInfo(Form("\n I've put %i particles on the stack \n",nc));
      if (nc > 0) {
	  jev += nc;
	  if (jev >= fNpart || fNpart == -1) {
	      fKineBias = Float_t(fNpart)/Float_t(fTrials);
	      AliInfo(Form("\n Trials: %i %i %i\n",fTrials, fNpart, jev));
	      break;
	  }
      }
  } // event loop

  MakeHeader();
  SetHighWaterMark(nt);
}

void AliGenHijing::KeepFullEvent()
{
    fKeep=1;
}

void AliGenHijing::EvaluateCrossSections()
{
//     Glauber Calculation of geometrical x-section
//
    Float_t xTot       = 0.;          // barn
    Float_t xTotHard   = 0.;          // barn 
    Float_t xPart      = 0.;          // barn
    Float_t xPartHard  = 0.;          // barn 
    Float_t sigmaHard  = 0.1;         // mbarn
    Float_t bMin       = 0.;
    Float_t bMax       = fHijing->GetHIPR1(34)+fHijing->GetHIPR1(35);
    const Float_t kdib = 0.2;
    Int_t   kMax       = Int_t((bMax-bMin)/kdib)+1;


    printf("\n Projectile Radius (fm): %f \n",fHijing->GetHIPR1(34));
    printf("\n Target     Radius (fm): %f \n",fHijing->GetHIPR1(35));    
    printf("\n Inelastic and total cross section (mb) %f %f \n",fHijing->GetHINT1(12), fHijing->GetHINT1(13));    
    Int_t i;
    Float_t oldvalue= 0.;

    Float_t* b   = new Float_t[kMax];
    Float_t* si1 = new Float_t[kMax];    
    Float_t* si2 = new Float_t[kMax];    
    for (i = 0; i < kMax; i++){
      b[i] = 0.;
      si1[i] = 0.;
      si2[i] = 0.;
    }

    for (i = 0; i < kMax; i++)
    {
	Float_t xb  = bMin+i*kdib;
	Float_t ov;
	ov=fHijing->Profile(xb);
	Float_t gb  =  2.*0.01*fHijing->GetHIPR1(40)*kdib*xb*(1.-TMath::Exp(-fHijing->GetHINT1(12)*ov));
	Float_t gbh =  2.*0.01*fHijing->GetHIPR1(40)*kdib*xb*sigmaHard*ov;
	xTot+=gb;
	xTotHard += gbh;
	printf("profile %f %f %f\n", xb, ov, fHijing->GetHINT1(12));
	
	if (xb > fMinImpactParam && xb < fMaxImpactParam)
	{
	    xPart += gb;
	    xPartHard += gbh;
	}
	
	if(oldvalue) if ((xTot-oldvalue)/oldvalue<0.0001) break;
	oldvalue = xTot;
	printf("\n Total cross section (barn): %d %f %f \n",i, xb, xTot);
	printf("\n Hard  cross section (barn): %d %f %f \n\n",i, xb, xTotHard);
	if (i>0) {
	    si1[i] = gb/kdib;
	    si2[i] = gbh/gb;
	    b[i]  = xb;
	}
    }

    printf("\n Total cross section (barn): %f \n",xTot);
    printf("\n Hard  cross section (barn): %f \n \n",xTotHard);
    printf("\n Partial       cross section (barn): %f %f \n",xPart, xPart/xTot*100.);
    printf("\n Partial  hard cross section (barn): %f %f \n",xPartHard, xPartHard/xTotHard*100.);

//  Store result as a graph
    b[0] = 0;
    si1[0] = 0;
    si2[0]=si2[1];
    
    fDsigmaDb  = new TGraph(i, b, si1);
    fDnDb      = new TGraph(i, b, si2);
}

Bool_t AliGenHijing::DaughtersSelection(const TParticle* iparticle)
{
//
// Looks recursively if one of the daughters has been selected
//
//    printf("\n Consider daughters %d:",iparticle->GetPdgCode());
    Int_t imin = -1;
    Int_t imax = -1;
    Int_t i;
    Bool_t hasDaughters = (iparticle->GetFirstDaughter() >=0);
    Bool_t selected = kFALSE;
    if (hasDaughters) {
	imin = iparticle->GetFirstDaughter();
	imax = iparticle->GetLastDaughter();       
	for (i = imin; i <= imax; i++){
	    TParticle *  jparticle = (TParticle *) fParticles.At(i);	
	    Int_t ip = jparticle->GetPdgCode();
	    if (KinematicSelection(jparticle,0)&&SelectFlavor(ip)) {
		selected=kTRUE; break;
	    }
	    if (DaughtersSelection(jparticle)) {selected=kTRUE; break; }
	}
    } else {
	return kFALSE;
    }
    return selected;
}


Bool_t AliGenHijing::SelectFlavor(Int_t pid)
{
// Select flavor of particle
// 0: all
// 4: charm and beauty
// 5: beauty
    Bool_t res = 0;
    
    if (fFlavor == 0) {
	res = kTRUE;
    } else {
	Int_t ifl = TMath::Abs(pid/100);
	if (ifl > 10) ifl/=10;
	res = (fFlavor == ifl);
    }
//
//  This part if gamma writing is inhibited
    if (fNoGammas) 
	res = res && (pid != kGamma && pid != kPi0);
//
    return res;
}

Bool_t AliGenHijing::Stable(const TParticle*  particle) const
{
// Return true for a stable particle
//
    
    if (particle->GetFirstDaughter() < 0 )
    {
	return kTRUE;
    } else {
	return kFALSE;
    }
}


void AliGenHijing::MakeHeader()
{
// Builds the event header, to be called after each event
    fHeader.SetNProduced(fNprimaries);
    fHeader.SetImpactParameter(fHijing->GetHINT1(19));
    fHeader.SetTotalEnergy(fHijing->GetEATT());
    fHeader.SetHardScatters(fHijing->GetJATT());
    fHeader.SetParticipants(fHijing->GetNP(), fHijing->GetNT());
    fHeader.SetCollisions(fHijing->GetN0(),
			  fHijing->GetN01(),
			  fHijing->GetN10(),
			  fHijing->GetN11());
    fHeader.SetSpectators(fProjectileSpecn, fProjectileSpecp,
			  fTargetSpecn,fTargetSpecp);
    fHeader.SetReactionPlaneAngle(fHijing->GetHINT1(20));
    fHeader.SetTrueNPart(fHijing->GetNPART());

// 4-momentum vectors of the triggered jets.
//
// Before final state gluon radiation.
    TLorentzVector* jet1 = new TLorentzVector(fHijing->GetHINT1(21), 
					      fHijing->GetHINT1(22),
					      fHijing->GetHINT1(23),
					      fHijing->GetHINT1(24));

    TLorentzVector* jet2 = new TLorentzVector(fHijing->GetHINT1(31), 
					      fHijing->GetHINT1(32),
					      fHijing->GetHINT1(33),
					      fHijing->GetHINT1(34));
// After final state gluon radiation.
    TLorentzVector* jet3 = new TLorentzVector(fHijing->GetHINT1(26), 
					      fHijing->GetHINT1(27),
					      fHijing->GetHINT1(28),
					      fHijing->GetHINT1(29));

    TLorentzVector* jet4 = new TLorentzVector(fHijing->GetHINT1(36), 
					      fHijing->GetHINT1(37),
					      fHijing->GetHINT1(38),
					      fHijing->GetHINT1(39));
    fHeader.SetJets(jet1, jet2, jet3, jet4);
// Bookkeeping for kinematic bias
    fHeader.SetTrials(fTrials);
// Event Vertex
    fHeader.SetPrimaryVertex(fVertex);
    fHeader.SetInteractionTime(fTime);

    Int_t nsd1 = 0,nsd2 = 0,ndd = 0;
    Int_t nT = fHijing->GetNT();
    Int_t nP = fHijing->GetNP();
    for (Int_t i = 1; i <= nP; ++i) {
      for (Int_t j = 1; j <= nT; ++j) {
      Int_t tp = fHijing->GetNFP(i, 5);
      Int_t tt = fHijing->GetNFT(j, 5);
      if (tp == 2)
        nsd1++;
      if (tt == 2)
        nsd2++;
      if (tp == 2 && tt == 2)
        ndd++;
      }
    }
    fHeader.SetNDiffractive(nsd1, nsd2, ndd);
    AddHeader(&fHeader);
    fCollisionGeometry = &fHeader;
}


Bool_t AliGenHijing::CheckTrigger()
{
// Check the kinematic trigger condition
//
    Bool_t   triggered = kFALSE;
 
    if (fTrigger == 1) {
//
//  jet-jet Trigger	
	
	TLorentzVector* jet1 = new TLorentzVector(fHijing->GetHINT1(26), 
						  fHijing->GetHINT1(27),
						  fHijing->GetHINT1(28),
						  fHijing->GetHINT1(29));
	
	TLorentzVector* jet2 = new TLorentzVector(fHijing->GetHINT1(36), 
						  fHijing->GetHINT1(37),
						  fHijing->GetHINT1(38),
						  fHijing->GetHINT1(39));
	Double_t eta1      = jet1->Eta();
	Double_t eta2      = jet2->Eta();
	Double_t phi1      = jet1->Phi();
	Double_t phi2      = jet2->Phi();
//    printf("\n Trigger: %f %f %f %f",
//	   fEtaMinJet, fEtaMaxJet, fPhiMinJet, fPhiMaxJet);
	if (
	    (eta1 < fEtaMaxJet && eta1 > fEtaMinJet &&  
	     phi1 < fPhiMaxJet && phi1 > fPhiMinJet) 
	    ||
	    (eta2 < fEtaMaxJet && eta2 > fEtaMinJet &&  
	     phi2 < fPhiMaxJet && phi2 > fPhiMinJet)
	    ) 
	    triggered = kTRUE;
    } else if (fTrigger == 2) {
//  Gamma Jet
//
	Int_t np = fParticles.GetEntriesFast();
	for (Int_t i = 0; i < np; i++) {
	    TParticle* part = (TParticle*) fParticles.At(i);
	    Int_t kf = part->GetPdgCode();
	    Int_t ksp = part->GetUniqueID();
	    if (kf == 22 && ksp == 40) {
		Float_t phi = part->Phi();
		Float_t eta = part->Eta();
		if  (eta < fEtaMaxJet && 
		     eta > fEtaMinJet &&
		     phi < fPhiMaxJet && 
		     phi > fPhiMinJet) {
		    triggered = 1;
		    break;
		} // check phi,eta within limits
	    } // direct gamma ? 
	} // particle loop
    } // fTrigger == 2
    return triggered;
}
Commit	Line	Data
36b81802	1	/**************************************************************************
	2	* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	3	* *
	4	* Author: The ALICE Off-line Project. *
	5	* Contributors are mentioned in the code where appropriate. *
	6	* *
	7	* Permission to use, copy, modify and distribute this software and its *
	8	* documentation strictly for non-commercial purposes is hereby granted *
	9	* without fee, provided that the above copyright notice appears in all *
	10	* copies and that both the copyright notice and this permission notice *
	11	* appear in the supporting documentation. The authors make no claims *
	12	* about the suitability of this software for any purpose. It is *
	13	* provided "as is" without express or implied warranty. *
	14	**************************************************************************/
	15
7cdba479	16	/* $Id$ */
36b81802	17
	18	// Generator using HIJING as an external generator
	19	// The main HIJING options are accessable for the user through this interface.
	20	// Uses the THijing implementation of TGenerator.
14cae7e9	21	// Author:
14cae7e9	22	// Andreas Morsch (andreas.morsch@cern.ch)
36b81802	23	//
36b81802	24
3010c308	25	#include <TClonesArray.h>
36b81802	26	#include <TGraph.h>
	27	#include <THijing.h>
	28	#include <TLorentzVector.h>
	29	#include <TPDGCode.h>
	30	#include <TParticle.h>
	31
	32	#include "AliGenHijing.h"
	33	#include "AliGenHijingEventHeader.h"
7cdba479	34	#include "AliHijingRndm.h"
3f4e7ad8	35	#include "AliLog.h"
3f4e7ad8	36	#include "AliRun.h"
36b81802	37
7cdba479	38	ClassImp(AliGenHijing)
36b81802	39
36b81802	40	AliGenHijing::AliGenHijing()
9d89c88d	41	:AliGenMC(),
	42	fFrame("CMS"),
	43	fMinImpactParam(0.),
	44	fMaxImpactParam(5.),
	45	fKeep(0),
	46	fQuench(1),
	47	fShadowing(1),
6965c13e	48	fDecaysOff(3),
9d89c88d	49	fTrigger(0),
	50	fEvaluate(0),
	51	fSelectAll(0),
	52	fFlavor(0),
9d89c88d	53	fKineBias(0.),
	54	fTrials(0),
	55	fXsection(0.),
	56	fHijing(0),
5bfd0cb7	57	fPtHardMin(2.0),
5bfd0cb7	58	fPtHardMax(-1),
9d89c88d	59	fSpectators(1),
	60	fDsigmaDb(0),
	61	fDnDb(0),
	62	fPtMinJet(-2.5),
	63	fEtaMinJet(-20.),
	64	fEtaMaxJet(+20.),
	65	fPhiMinJet(0.),
	66	fPhiMaxJet(2. * TMath::Pi()),
	67	fRadiation(3),
	68	fSimpleJet(kFALSE),
	69	fNoGammas(kFALSE),
	70	fProjectileSpecn(0),
	71	fProjectileSpecp(0),
	72	fTargetSpecn(0),
	73	fTargetSpecp(0),
	74	fLHC(kFALSE),
	75	fRandomPz(kFALSE),
d07f0af2	76	fNoHeavyQuarks(kFALSE),
f2f240a9	77	fHeader(AliGenHijingEventHeader("Hijing"))
36b81802	78	{
fc7e1b1c	79	// Constructor
e7c989e4	80	fEnergyCMS = 5500.;
fc7e1b1c	81	AliHijingRndm::SetHijingRandom(GetRandom());
36b81802	82	}
	83
	84	AliGenHijing::AliGenHijing(Int_t npart)
9d89c88d	85	:AliGenMC(npart),
	86	fFrame("CMS"),
	87	fMinImpactParam(0.),
	88	fMaxImpactParam(5.),
	89	fKeep(0),
	90	fQuench(1),
	91	fShadowing(1),
6965c13e	92	fDecaysOff(3),
9d89c88d	93	fTrigger(0),
	94	fEvaluate(0),
	95	fSelectAll(0),
	96	fFlavor(0),
9d89c88d	97	fKineBias(0.),
	98	fTrials(0),
	99	fXsection(0.),
	100	fHijing(0),
5bfd0cb7	101	fPtHardMin(2.0),
5bfd0cb7	102	fPtHardMax(-1),
9d89c88d	103	fSpectators(1),
	104	fDsigmaDb(0),
	105	fDnDb(0),
	106	fPtMinJet(-2.5),
	107	fEtaMinJet(-20.),
	108	fEtaMaxJet(+20.),
	109	fPhiMinJet(0.),
	110	fPhiMaxJet(2. * TMath::Pi()),
	111	fRadiation(3),
	112	fSimpleJet(kFALSE),
	113	fNoGammas(kFALSE),
	114	fProjectileSpecn(0),
	115	fProjectileSpecp(0),
	116	fTargetSpecn(0),
	117	fTargetSpecp(0),
	118	fLHC(kFALSE),
	119	fRandomPz(kFALSE),
d07f0af2	120	fNoHeavyQuarks(kFALSE),
f2f240a9	121	fHeader(AliGenHijingEventHeader("Hijing"))
36b81802	122	{
	123	// Default PbPb collisions at 5. 5 TeV
	124	//
e7c989e4	125	fEnergyCMS = 5500.;
36b81802	126	fName = "Hijing";
36b81802	127	fTitle= "Particle Generator using HIJING";
36b81802	128	//
36b81802	129	//
36b81802	130	// Set random number generator
7cdba479	131	AliHijingRndm::SetHijingRandom(GetRandom());
f2f240a9	132
36b81802	133	}
36b81802	134
36b81802	135	AliGenHijing::~AliGenHijing()
	136	{
	137	// Destructor
	138	if ( fDsigmaDb) delete fDsigmaDb;
	139	if ( fDnDb) delete fDnDb;
36b81802	140	}
	141
	142	void AliGenHijing::Init()
	143	{
	144	// Initialisation
9071ae63	145	fFrame.Resize(8);
	146	fTarget.Resize(8);
	147	fProjectile.Resize(8);
36b81802	148
	149	SetMC(new THijing(fEnergyCMS, fFrame, fProjectile, fTarget,
	150	fAProjectile, fZProjectile, fATarget, fZTarget,
	151	fMinImpactParam, fMaxImpactParam));
	152
b88f5cea	153	fHijing=(THijing*) fMCEvGen;
36b81802	154	fHijing->SetIHPR2(2, fRadiation);
	155	fHijing->SetIHPR2(3, fTrigger);
	156	fHijing->SetIHPR2(6, fShadowing);
	157	fHijing->SetIHPR2(12, fDecaysOff);
	158	fHijing->SetIHPR2(21, fKeep);
5bfd0cb7	159	fHijing->SetHIPR1(8, fPtHardMin);
5bfd0cb7	160	fHijing->SetHIPR1(9, fPtHardMax);
36b81802	161	fHijing->SetHIPR1(10, fPtMinJet);
	162	fHijing->SetHIPR1(50, fSimpleJet);
	163	//
	164	// Quenching
	165	//
	166	//
	167	// fQuench = 0: no quenching
	168	// fQuench = 1: hijing default
	169	// fQuench = 2: new LHC parameters for HIPR1(11) and HIPR1(14)
	170	// fQuench = 3: new RHIC parameters for HIPR1(11) and HIPR1(14)
	171	// fQuench = 4: new LHC parameters with log(e) dependence
	172	// fQuench = 5: new RHIC parameters with log(e) dependence
	173	fHijing->SetIHPR2(50, 0);
	174	if (fQuench > 0)
	175	fHijing->SetIHPR2(4, 1);
	176	else
	177	fHijing->SetIHPR2(4, 0);
	178	// New LHC parameters from Xin-Nian Wang
	179	if (fQuench == 2) {
	180	fHijing->SetHIPR1(14, 1.1);
	181	fHijing->SetHIPR1(11, 3.7);
	182	} else if (fQuench == 3) {
	183	fHijing->SetHIPR1(14, 0.20);
	184	fHijing->SetHIPR1(11, 2.5);
	185	} else if (fQuench == 4) {
	186	fHijing->SetIHPR2(50, 1);
	187	fHijing->SetHIPR1(14, 4.*0.34);
	188	fHijing->SetHIPR1(11, 3.7);
	189	} else if (fQuench == 5) {
	190	fHijing->SetIHPR2(50, 1);
	191	fHijing->SetHIPR1(14, 0.34);
	192	fHijing->SetHIPR1(11, 2.5);
	193	}
	194
f82795ff	195	//
	196	// Heavy quarks
	197	//
	198	if (fNoHeavyQuarks) {
	199	fHijing->SetIHPR2(49, 1);
	200	} else {
	201	fHijing->SetIHPR2(49, 0);
	202	}
	203
36b81802	204
cc463e4a	205	AliGenMC::Init();
36b81802	206
	207	//
	208	// Initialize Hijing
	209	//
	210	fHijing->Initialize();
	211	//
	212	if (fEvaluate) EvaluateCrossSections();
	213	//
	214	}
	215
	216	void AliGenHijing::Generate()
	217	{
	218	// Generate one event
	219
	220	Float_t polar[3] = {0,0,0};
	221	Float_t origin[3] = {0,0,0};
	222	Float_t origin0[3] = {0,0,0};
21391258	223	Float_t time0 = 0.;
0c0c6204	224	Float_t p[3];
36b81802	225	Float_t tof;
	226
	227	// converts from mm/c to s
14bca1e5	228	const Float_t kconv = 0.001/2.99792458e8;
36b81802	229	//
	230	Int_t nt = 0;
	231	Int_t jev = 0;
2d677e30	232	Int_t j, kf, ks, ksp, imo;
36b81802	233	kf = 0;
	234
	235
	236
	237	fTrials = 0;
e60d2969	238
36b81802	239	for (j = 0;j < 3; j++) origin0[j] = fOrigin[j];
21391258	240	time0 = fTimeOrigin;
16a37f16	241
36b81802	242	if(fVertexSmear == kPerEvent) {
0c0c6204	243	Vertex();
0c0c6204	244	for (j=0; j < 3; j++) origin0[j] = fVertex[j];
21391258	245	time0 = fTime;
0c0c6204	246	}
0c0c6204	247
b25b821e	248
b25b821e	249	Float_t sign = (fRandomPz && (Rndm() < 0.5))? -1. : 1.;
16a37f16	250
36b81802	251	while(1)
	252	{
	253	// Generate one event
	254	// --------------------------------------------------------------------------
f0c86dd6	255	fProjectileSpecn = 0;
f0c86dd6	256	fProjectileSpecp = 0;
b25b821e	257	fTargetSpecn = 0;
b25b821e	258	fTargetSpecp = 0;
36b81802	259	// --------------------------------------------------------------------------
	260	fHijing->GenerateEvent();
	261	fTrials++;
e60d2969	262	fNprimaries = 0;
8507138f	263	fHijing->ImportParticles(&fParticles,"All");
36b81802	264	if (fTrigger != kNoTrigger) {
	265	if (!CheckTrigger()) continue;
	266	}
71ea527c	267	if (fLHC) Boost();
36b81802	268
36b81802	269
8507138f	270	Int_t np = fParticles.GetEntriesFast();
36b81802	271	Int_t nc = 0;
	272	if (np == 0 ) continue;
	273	Int_t i;
	274	Int_t* newPos = new Int_t[np];
	275	Int_t* pSelected = new Int_t[np];
	276
	277	for (i = 0; i < np; i++) {
	278	newPos[i] = i;
	279	pSelected[i] = 0;
	280	}
	281
	282	// Get event vertex
	283	//
0c0c6204	284	fVertex[0] = origin0[0];
	285	fVertex[1] = origin0[1];
	286	fVertex[2] = origin0[2];
21391258	287	fTime = time0;
36b81802	288	//
	289	// First select parent particles
	290	//
8f64c44f	291	TParticle * iparticle = 0;
36b81802	292	for (i = 0; i < np; i++) {
8507138f	293	iparticle = (TParticle *) fParticles.At(i);
36b81802	294
	295	// Is this a parent particle ?
	296	if (Stable(iparticle)) continue;
	297	//
	298	Bool_t selected = kTRUE;
	299	Bool_t hasSelectedDaughters = kFALSE;
	300
	301
	302	kf = iparticle->GetPdgCode();
	303	ks = iparticle->GetStatusCode();
	304	if (kf == 92) continue;
	305
	306	if (!fSelectAll) selected = KinematicSelection(iparticle, 0) &&
	307	SelectFlavor(kf);
	308	hasSelectedDaughters = DaughtersSelection(iparticle);
	309	//
	310	// Put particle on the stack if it is either selected or
	311	// it is the mother of at least one seleted particle
	312	//
	313	if (selected \|\| hasSelectedDaughters) {
	314	nc++;
	315	pSelected[i] = 1;
	316	} // selected
	317	} // particle loop parents
	318	//
	319	// Now select the final state particles
	320	//
	321
	322	for (i = 0; i<np; i++) {
c4998efa	323	iparticle = (TParticle *) fParticles.At(i);
36b81802	324	// Is this a final state particle ?
	325	if (!Stable(iparticle)) continue;
	326
	327	Bool_t selected = kTRUE;
	328	kf = iparticle->GetPdgCode();
	329	ks = iparticle->GetStatusCode();
2d677e30	330	ksp = iparticle->GetUniqueID();
36b81802	331
	332	// --------------------------------------------------------------------------
	333	// Count spectator neutrons and protons
2d677e30	334	if(ksp == 0 \|\| ksp == 1){
f0c86dd6	335	if(kf == kNeutron) fProjectileSpecn += 1;
	336	if(kf == kProton) fProjectileSpecp += 1;
	337	}
2d677e30	338	else if(ksp == 10 \|\| ksp == 11){
f0c86dd6	339	if(kf == kNeutron) fTargetSpecn += 1;
f0c86dd6	340	if(kf == kProton) fTargetSpecp += 1;
36b81802	341	}
	342	// --------------------------------------------------------------------------
	343	//
	344	if (!fSelectAll) {
	345	selected = KinematicSelection(iparticle,0)&&SelectFlavor(kf);
2d677e30	346	if (!fSpectators && selected) selected = (ksp != 0 && ksp != 1 && ksp != 10
2d677e30	347	&& ksp != 11);
36b81802	348	}
	349	//
	350	// Put particle on the stack if selected
	351	//
	352	if (selected) {
	353	nc++;
	354	pSelected[i] = 1;
	355	} // selected
	356	} // particle loop final state
3439da17	357
36b81802	358	//
3439da17	359	// Write particles to stack
3439da17	360
36b81802	361	for (i = 0; i<np; i++) {
c4998efa	362	iparticle = (TParticle *) fParticles.At(i);
36b81802	363	Bool_t hasMother = (iparticle->GetFirstMother() >=0);
36b81802	364	Bool_t hasDaughter = (iparticle->GetFirstDaughter() >=0);
36b81802	365	if (pSelected[i]) {
	366	kf = iparticle->GetPdgCode();
	367	ks = iparticle->GetStatusCode();
	368	p[0] = iparticle->Px();
	369	p[1] = iparticle->Py();
b25b821e	370	p[2] = iparticle->Pz() * sign;
36b81802	371	origin[0] = origin0[0]+iparticle->Vx()/10;
	372	origin[1] = origin0[1]+iparticle->Vy()/10;
	373	origin[2] = origin0[2]+iparticle->Vz()/10;
21391258	374	tof = time0+kconv * iparticle->T();
21391258	375
36b81802	376	imo = -1;
	377	TParticle* mother = 0;
	378	if (hasMother) {
	379	imo = iparticle->GetFirstMother();
8507138f	380	mother = (TParticle *) fParticles.At(imo);
e57522c0	381	imo = (mother->GetPdgCode() != 92) ? newPos[imo] : -1;
36b81802	382	} // if has mother
36b81802	383	Bool_t tFlag = (fTrackIt && !hasDaughter);
3439da17	384	PushTrack(tFlag,imo,kf,p,origin,polar,tof,kPNoProcess,nt, 1., ks);
e60d2969	385	fNprimaries++;
36b81802	386	KeepTrack(nt);
	387	newPos[i] = nt;
	388	} // if selected
	389	} // particle loop
	390	delete[] newPos;
	391	delete[] pSelected;
	392
3f4e7ad8	393	AliInfo(Form("\n I've put %i particles on the stack \n",nc));
36b81802	394	if (nc > 0) {
	395	jev += nc;
	396	if (jev >= fNpart \|\| fNpart == -1) {
	397	fKineBias = Float_t(fNpart)/Float_t(fTrials);
3f4e7ad8	398	AliInfo(Form("\n Trials: %i %i %i\n",fTrials, fNpart, jev));
36b81802	399	break;
	400	}
	401	}
	402	} // event loop
cfccaf66	403
36b81802	404	MakeHeader();
	405	SetHighWaterMark(nt);
	406	}
	407
	408	void AliGenHijing::KeepFullEvent()
	409	{
	410	fKeep=1;
	411	}
	412
	413	void AliGenHijing::EvaluateCrossSections()
	414	{
	415	// Glauber Calculation of geometrical x-section
	416	//
	417	Float_t xTot = 0.; // barn
	418	Float_t xTotHard = 0.; // barn
	419	Float_t xPart = 0.; // barn
	420	Float_t xPartHard = 0.; // barn
	421	Float_t sigmaHard = 0.1; // mbarn
	422	Float_t bMin = 0.;
	423	Float_t bMax = fHijing->GetHIPR1(34)+fHijing->GetHIPR1(35);
	424	const Float_t kdib = 0.2;
	425	Int_t kMax = Int_t((bMax-bMin)/kdib)+1;
	426
	427
	428	printf("\n Projectile Radius (fm): %f \n",fHijing->GetHIPR1(34));
	429	printf("\n Target Radius (fm): %f \n",fHijing->GetHIPR1(35));
6965c13e	430	printf("\n Inelastic and total cross section (mb) %f %f \n",fHijing->GetHINT1(12), fHijing->GetHINT1(13));
36b81802	431	Int_t i;
	432	Float_t oldvalue= 0.;
	433
	434	Float_t* b = new Float_t[kMax];
	435	Float_t* si1 = new Float_t[kMax];
	436	Float_t* si2 = new Float_t[kMax];
8f64c44f	437	for (i = 0; i < kMax; i++){
	438	b[i] = 0.;
	439	si1[i] = 0.;
	440	si2[i] = 0.;
	441	}
	442
36b81802	443	for (i = 0; i < kMax; i++)
	444	{
	445	Float_t xb = bMin+i*kdib;
	446	Float_t ov;
	447	ov=fHijing->Profile(xb);
	448	Float_t gb = 2.0.01fHijing->GetHIPR1(40)kdibxb(1.-TMath::Exp(-fHijing->GetHINT1(12)ov));
	449	Float_t gbh = 2.0.01fHijing->GetHIPR1(40)kdibxbsigmaHardov;
	450	xTot+=gb;
	451	xTotHard += gbh;
	452	printf("profile %f %f %f\n", xb, ov, fHijing->GetHINT1(12));
	453
	454	if (xb > fMinImpactParam && xb < fMaxImpactParam)
	455	{
	456	xPart += gb;
	457	xPartHard += gbh;
	458	}
	459
	460	if(oldvalue) if ((xTot-oldvalue)/oldvalue<0.0001) break;
	461	oldvalue = xTot;
	462	printf("\n Total cross section (barn): %d %f %f \n",i, xb, xTot);
	463	printf("\n Hard cross section (barn): %d %f %f \n\n",i, xb, xTotHard);
	464	if (i>0) {
	465	si1[i] = gb/kdib;
	466	si2[i] = gbh/gb;
	467	b[i] = xb;
	468	}
	469	}
	470
	471	printf("\n Total cross section (barn): %f \n",xTot);
	472	printf("\n Hard cross section (barn): %f \n \n",xTotHard);
	473	printf("\n Partial cross section (barn): %f %f \n",xPart, xPart/xTot*100.);
	474	printf("\n Partial hard cross section (barn): %f %f \n",xPartHard, xPartHard/xTotHard*100.);
	475
	476	// Store result as a graph
	477	b[0] = 0;
	478	si1[0] = 0;
	479	si2[0]=si2[1];
	480
	481	fDsigmaDb = new TGraph(i, b, si1);
	482	fDnDb = new TGraph(i, b, si2);
	483	}
	484
904a753d	485	Bool_t AliGenHijing::DaughtersSelection(const TParticle* iparticle)
36b81802	486	{
	487	//
	488	// Looks recursively if one of the daughters has been selected
	489	//
	490	// printf("\n Consider daughters %d:",iparticle->GetPdgCode());
	491	Int_t imin = -1;
	492	Int_t imax = -1;
	493	Int_t i;
	494	Bool_t hasDaughters = (iparticle->GetFirstDaughter() >=0);
	495	Bool_t selected = kFALSE;
	496	if (hasDaughters) {
	497	imin = iparticle->GetFirstDaughter();
	498	imax = iparticle->GetLastDaughter();
	499	for (i = imin; i <= imax; i++){
8507138f	500	TParticle * jparticle = (TParticle *) fParticles.At(i);
36b81802	501	Int_t ip = jparticle->GetPdgCode();
	502	if (KinematicSelection(jparticle,0)&&SelectFlavor(ip)) {
	503	selected=kTRUE; break;
	504	}
	505	if (DaughtersSelection(jparticle)) {selected=kTRUE; break; }
	506	}
	507	} else {
	508	return kFALSE;
	509	}
	510	return selected;
	511	}
	512
	513
	514	Bool_t AliGenHijing::SelectFlavor(Int_t pid)
	515	{
	516	// Select flavor of particle
	517	// 0: all
	518	// 4: charm and beauty
	519	// 5: beauty
	520	Bool_t res = 0;
	521
	522	if (fFlavor == 0) {
	523	res = kTRUE;
	524	} else {
	525	Int_t ifl = TMath::Abs(pid/100);
	526	if (ifl > 10) ifl/=10;
	527	res = (fFlavor == ifl);
	528	}
	529	//
	530	// This part if gamma writing is inhibited
	531	if (fNoGammas)
	532	res = res && (pid != kGamma && pid != kPi0);
	533	//
	534	return res;
	535	}
	536
904a753d	537	Bool_t AliGenHijing::Stable(const TParticle* particle) const
36b81802	538	{
	539	// Return true for a stable particle
	540	//
	541
	542	if (particle->GetFirstDaughter() < 0 )
	543	{
	544	return kTRUE;
	545	} else {
	546	return kFALSE;
	547	}
	548	}
	549
	550
36b81802	551
	552	void AliGenHijing::MakeHeader()
	553	{
	554	// Builds the event header, to be called after each event
f2f240a9	555	fHeader.SetNProduced(fNprimaries);
	556	fHeader.SetImpactParameter(fHijing->GetHINT1(19));
	557	fHeader.SetTotalEnergy(fHijing->GetEATT());
	558	fHeader.SetHardScatters(fHijing->GetJATT());
	559	fHeader.SetParticipants(fHijing->GetNP(), fHijing->GetNT());
	560	fHeader.SetCollisions(fHijing->GetN0(),
	561	fHijing->GetN01(),
	562	fHijing->GetN10(),
	563	fHijing->GetN11());
	564	fHeader.SetSpectators(fProjectileSpecn, fProjectileSpecp,
	565	fTargetSpecn,fTargetSpecp);
	566	fHeader.SetReactionPlaneAngle(fHijing->GetHINT1(20));
369eeebb	567	fHeader.SetTrueNPart(fHijing->GetNPART());
36b81802	568
	569	// 4-momentum vectors of the triggered jets.
	570	//
	571	// Before final state gluon radiation.
	572	TLorentzVector* jet1 = new TLorentzVector(fHijing->GetHINT1(21),
	573	fHijing->GetHINT1(22),
	574	fHijing->GetHINT1(23),
	575	fHijing->GetHINT1(24));
	576
	577	TLorentzVector* jet2 = new TLorentzVector(fHijing->GetHINT1(31),
	578	fHijing->GetHINT1(32),
	579	fHijing->GetHINT1(33),
	580	fHijing->GetHINT1(34));
	581	// After final state gluon radiation.
	582	TLorentzVector* jet3 = new TLorentzVector(fHijing->GetHINT1(26),
	583	fHijing->GetHINT1(27),
	584	fHijing->GetHINT1(28),
	585	fHijing->GetHINT1(29));
	586
	587	TLorentzVector* jet4 = new TLorentzVector(fHijing->GetHINT1(36),
	588	fHijing->GetHINT1(37),
	589	fHijing->GetHINT1(38),
	590	fHijing->GetHINT1(39));
f2f240a9	591	fHeader.SetJets(jet1, jet2, jet3, jet4);
36b81802	592	// Bookkeeping for kinematic bias
f2f240a9	593	fHeader.SetTrials(fTrials);
36b81802	594	// Event Vertex
f2f240a9	595	fHeader.SetPrimaryVertex(fVertex);
21391258	596	fHeader.SetInteractionTime(fTime);
cfccaf66	597
	598	Int_t nsd1 = 0,nsd2 = 0,ndd = 0;
	599	Int_t nT = fHijing->GetNT();
	600	Int_t nP = fHijing->GetNP();
	601	for (Int_t i = 1; i <= nP; ++i) {
	602	for (Int_t j = 1; j <= nT; ++j) {
	603	Int_t tp = fHijing->GetNFP(i, 5);
	604	Int_t tt = fHijing->GetNFT(j, 5);
	605	if (tp == 2)
	606	nsd1++;
	607	if (tt == 2)
	608	nsd2++;
	609	if (tp == 2 && tt == 2)
	610	ndd++;
	611	}
	612	}
	613	fHeader.SetNDiffractive(nsd1, nsd2, ndd);
f2f240a9	614	AddHeader(&fHeader);
f2f240a9	615	fCollisionGeometry = &fHeader;
36b81802	616	}
36b81802	617
cf57b268	618
36b81802	619	Bool_t AliGenHijing::CheckTrigger()
	620	{
	621	// Check the kinematic trigger condition
	622	//
	623	Bool_t triggered = kFALSE;
	624
	625	if (fTrigger == 1) {
	626	//
	627	// jet-jet Trigger
	628
	629	TLorentzVector* jet1 = new TLorentzVector(fHijing->GetHINT1(26),
	630	fHijing->GetHINT1(27),
	631	fHijing->GetHINT1(28),
	632	fHijing->GetHINT1(29));
	633
	634	TLorentzVector* jet2 = new TLorentzVector(fHijing->GetHINT1(36),
	635	fHijing->GetHINT1(37),
	636	fHijing->GetHINT1(38),
	637	fHijing->GetHINT1(39));
	638	Double_t eta1 = jet1->Eta();
	639	Double_t eta2 = jet2->Eta();
	640	Double_t phi1 = jet1->Phi();
	641	Double_t phi2 = jet2->Phi();
	642	// printf("\n Trigger: %f %f %f %f",
	643	// fEtaMinJet, fEtaMaxJet, fPhiMinJet, fPhiMaxJet);
	644	if (
	645	(eta1 < fEtaMaxJet && eta1 > fEtaMinJet &&
	646	phi1 < fPhiMaxJet && phi1 > fPhiMinJet)
	647	\|\|
	648	(eta2 < fEtaMaxJet && eta2 > fEtaMinJet &&
	649	phi2 < fPhiMaxJet && phi2 > fPhiMinJet)
	650	)
	651	triggered = kTRUE;
	652	} else if (fTrigger == 2) {
	653	// Gamma Jet
	654	//
8507138f	655	Int_t np = fParticles.GetEntriesFast();
36b81802	656	for (Int_t i = 0; i < np; i++) {
8507138f	657	TParticle* part = (TParticle*) fParticles.At(i);
36b81802	658	Int_t kf = part->GetPdgCode();
2d677e30	659	Int_t ksp = part->GetUniqueID();
2d677e30	660	if (kf == 22 && ksp == 40) {
36b81802	661	Float_t phi = part->Phi();
	662	Float_t eta = part->Eta();
	663	if (eta < fEtaMaxJet &&
	664	eta > fEtaMinJet &&
	665	phi < fPhiMaxJet &&
	666	phi > fPhiMinJet) {
	667	triggered = 1;
	668	break;
	669	} // check phi,eta within limits
	670	} // direct gamma ?
	671	} // particle loop
	672	} // fTrigger == 2
	673	return triggered;
	674	}