[u/mrichter/AliRoot.git] / TPHIC / AliGenTPHIC.cxx

/**************************************************************************
 * Copyright(c) 1998-2003, 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.                  *
 *                                                                        *
 **************************************************************************/

/* $Id$ */

// Event generator of two-photon processes
// in ultra-peripheral ion collisions.
// 5 two-photon process are implemented, see comments to SetProcess().
//%
// The example of the generator initialization for the process
// gamma gamma -> X in CaCa collisions at 7000 TeV/nucleon is the following:
//%
//    AliGenTPHIC *gener = new AliGenTPHIC();
//    gener->SetProcess(1);
//    gener->SetBeamEnergy(3500.);
//    gener->SetBeamZ(20);
//    gener->SetBeamA(40);
//    gener->SetMggRange(70.,200.);
//    gener->SetYggRange(-5.,5.);
//    gener->SetLumFunName("lum_ca_70_200.dat");
//    gener->SetLumFunFlag(-1);
//    gener->Init();
//%
// The two-photon luminosity function needed for the process cross section
// calculation is time-consuming, therefore it can be calculated once for a
// selected two-photon energy and rapidity range and selected ion species,
// saved into a file and then can be reused in further calculation.
//%
// The integral cross section of the process is calculated in each event
// by the Monte Carlo integration procedure, the differential cross section
// of each thrown event is assigned as a weight to each track of the event
// which can be then used during the event analysis by retreiving this weight
// from any of the event tracks.
// 
// The manual of the fortran generator is available in
// $ALICE_ROOT/TPHIC/TPHIC_doc.ps.gz
// For the two-photon physics in heavy ion collisions see
// G.Baur et al, Phys.Rep. 364 (2002), 359.
//%
// Author: Yuri.Kharlov@cern.ch
// 15 April 2003

#include <TParticle.h>
#include <TParticlePDG.h>
#include <TDatabasePDG.h>
#include <TClonesArray.h>

#include "AliPythia.h"
#include "AliRun.h"
#include <AliGenTPHIC.h>
#include <TPHICgen.h>
#include <TPHICcommon.h>

ClassImp(AliGenTPHIC)

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

AliGenTPHIC::AliGenTPHIC() :
  AliGenMC(),
  fTPHICgen(0x0),
  fPythia(0x0),
  fParticles(0x0),
  fEvent(-1),
  fDebug(0),
  fDebugEventFirst(-1),
  fDebugEventLast(-1)
{
  // Constructor: create generator instance,
  // create particle array
  // Set TPHIC parameters to default values:
  // eta_b production in Ca-Ca collisions at 7 A*TeV

  SetMC(new TPHICgen());
  fPythia = AliPythia::Instance();
  fParticles = new TClonesArray("TParticle",100);

  SetProcess   ();
  SetBeamEnergy();
  SetBeamZ     ();
  SetBeamA     ();
  SetYggRange  ();
  SetMggRange  ();
  SetNgridY    ();
  SetNgridM    ();
  SetLumFunName();
  SetLumFunFlag();
  SetKfOnium   ();
}

//____________________________________________________________
AliGenTPHIC::~AliGenTPHIC()
{
  // Destroys the object, deletes and disposes all TParticles currently on list.
  if (fParticles) {
    fParticles->Delete();
    delete fParticles;
    fParticles = 0;
  }
}

//____________________________________________________________
void AliGenTPHIC::Init()
{
  // Initialize the generator TPHIC

  fTPHICgen->Initialize();
  fEvent = 0;
}

//____________________________________________________________
void AliGenTPHIC::Generate()
{
  // Generate one event of two-photon process.
  // Gaussian smearing on the vertex is done if selected. 
  // All particles from the TPHIC/PYTHIA event listing
  // are stored in TreeK, and only final-state particles are tracked.
  // The event differectial cross section is assigned as a weight
  // to each track of the event.

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

  Int_t    ks,kf,iparent,nt, trackIt;
  Float_t  random[6];
  const Float_t kconv=0.001/2.999792458e8;

  fTPHICgen->GenerateEvent();
  weight = GetXSectionCurrent();
  if (gAlice->GetEvNumber()>=fDebugEventFirst &&
      gAlice->GetEvNumber()<=fDebugEventLast) fPythia->Pylist(1);
  fPythia->ImportParticles(fParticles,"All");

  if (fDebug == 1)
    Info("Generate()","one event is produced");

  Int_t j;
  for (j=0;j<3;j++) origin0[j]=fOrigin[j];
  time0 = fTimeOrigin;
  if(fVertexSmear==kPerEvent) {
    Rndm(random,6);
    for (j=0;j<3;j++) {
      origin0[j]+=fOsigma[j]*TMath::Cos(2*random[2*j]*TMath::Pi())*
	TMath::Sqrt(-2*TMath::Log(random[2*j+1]));
    }
    Rndm(random,2);
    time0 += fOsigma[2]/TMath::Ccgs()*
      TMath::Cos(2*random[0]*TMath::Pi())*
      TMath::Sqrt(-2*TMath::Log(random[1]));
  }

  Int_t ip;
  Int_t np = fParticles->GetEntriesFast();
  TParticle *iparticle;
//   Int_t* pParent   = new Int_t[np];
  for (ip=0; ip<np; ip++) {
    iparticle = (TParticle *) fParticles->At(ip);
    ks = iparticle->GetStatusCode();
//     // No initial state partons
//     if (ks==21) continue;
    p[0] = iparticle->Px();
    p[1] = iparticle->Py();
    p[2] = iparticle->Pz();
    origin[0] = origin0[0]+iparticle->Vx()/10.;
    origin[1] = origin0[1]+iparticle->Vy()/10.;
    origin[2] = origin0[2]+iparticle->Vz()/10.;
    kf = CheckPDGCode(iparticle->GetPdgCode());
    iparent = -1;
    tof     = time0 + kconv*iparticle->T();
    if (ks == 1) trackIt = 1;
    else         trackIt = 0;
    PushTrack(fTrackIt*trackIt,iparent,kf,p,origin,polar,tof,kPPrimary,nt,weight,ks);
    KeepTrack(nt); 

    if (fDebug == 2)
      printf("id=%+4d, parent=%3d, ks=%d, p = (%+11.4e,%+11.4e,%+11.4e) GeV\n",
	     kf,iparent,fTrackIt*trackIt,p[0],p[1],p[2]);
  }
  fEvent++;
  fTPHICgen->SetNEVENT(fEvent);
  if (fDebug == 1 && fEvent%100 == 0) {
    Info("Generate","Event %d\n",fEvent);
    fTPHICgen->Finish();
  }
}

//____________________________________________________________
void AliGenTPHIC::SetEventListRange(Int_t eventFirst, Int_t eventLast)
{
  // Set a range of event numbers, for which a table
  // of generated particle will be printed
  fDebugEventFirst = eventFirst;
  fDebugEventLast  = eventLast;
  if (fDebugEventLast==-1) fDebugEventLast=fDebugEventFirst;
}

//____________________________________________________________
void AliGenTPHIC::SetProcess       (Int_t   proc  )
{
  // Set process number:
  // proc=1 - gamma gamma -> X
  // proc=2 - gamma gamma -> quarkonium
  // proc=3 - gamma gamma -> fermion+ fermion-
  // proc=4 - gamma gamma -> W+ W-
  // proc=5 - not implemented
  // proc=6 - gamma gamma -> V1 V2 (vector meson pair)

  fTPHICgen->SetIPROC(proc);
}
//____________________________________________________________
  void AliGenTPHIC::SetBeamEnergy  (Float_t energy)
{
  // Set energy of the beam ion per nucleon in GeV
  fTPHICgen->SetEBMN(energy);
}
//____________________________________________________________
  void AliGenTPHIC::SetBeamZ       (Int_t   z     )
{
  // Set beam ion charge
  fTPHICgen->SetIZ(z);
}
//____________________________________________________________
  void AliGenTPHIC::SetBeamA       (Int_t   a     )
{
  // Set beam ion atomic number
  fTPHICgen->SetIA(a);
}
//____________________________________________________________
  void AliGenTPHIC::SetYggRange    (Float_t ymin, Float_t ymax)
{
  // Set rapidity range of 2-photon system for the
  // luminosity function calculation
  fTPHICgen->SetYMIN(ymin);
  fTPHICgen->SetYMAX(ymax);
}
//____________________________________________________________
  void AliGenTPHIC::SetMggRange    (Float_t mmin, Float_t mmax)
{
  // Set invariant mass range of 2-photon system for the
  // luminosity function calculation
  fTPHICgen->SetAMIN(mmin);
  fTPHICgen->SetAMAX(mmax);
}
//____________________________________________________________
  void AliGenTPHIC::SetNgridY      (Int_t   ny    )
{
  // Set number of nodes on the grid along the rapidity axis
  // to calculate the 2-photon luminosity function
  fTPHICgen->SetNY(ny);
}
//____________________________________________________________
  void AliGenTPHIC::SetNgridM      (Int_t   nm    )
{
  // Set number of nodes on the grid along the mass axis
  // to calculate the 2-photon luminosity function
  fTPHICgen->SetNMAS(nm);
}
//____________________________________________________________
  void AliGenTPHIC::SetLumFunName  (TString name  )
{
  // Set filename to store the 2-photon luminosity
  // function calculated on the grid
  fTPHICgen->SetLUMFIL(name);
}
//____________________________________________________________
  void AliGenTPHIC::SetLumFunFlag  (Int_t   flag  )
{
  // Set flag to calculate the 2-photon luminosity function:
  // flag=-1 if a new lumimosity function to be calculated
  //         and stored in a file
  // flag=+1 if a previously calculated function to be read
  //         from a file
  fTPHICgen->SetILUMF(flag);
}
//____________________________________________________________
  void AliGenTPHIC::SetKfFermion   (Int_t   kf    )
{
  // Set a PDG flavour code of a fermion for the process 3,
  // gamma gamma -> fermion+ fermion-
  fTPHICgen->SetKFERM(kf);
}
//____________________________________________________________
  void AliGenTPHIC::SetKfOnium    (Int_t   kf    )
{
  // Set a PDG flavour code of a quarkonium for the process 2,
  // gamma gamma -> quarkonium
  fTPHICgen->SetKFONIUM(kf);
}
//____________________________________________________________
  void AliGenTPHIC::SetMassOnium   (Float_t mass  )
{
  // Set a quarkonium mass [GeV] for the process 2 if it
  // differes from the Pythia's particle table.
  // For the well-known quarkonia no need to set this mass
  // because it will be taken from the Pythia table
  fTPHICgen->SetXMRES(mass);
}
//____________________________________________________________
  void AliGenTPHIC::SetGGwidthOnium(Float_t width )
{
  // Set 2-photon partial width [GeV] of the quarkonium for
  // the process 2 if it differes fromthe Pythia's particle table.
  // For the well-known quarkonia no need to set this width
  // because it will be taken from the Pythia table
  fTPHICgen->SetXGGRES(width);
}
//____________________________________________________________
  void AliGenTPHIC::SetKfVmesons   (Int_t kf1, Int_t kf2)
{
  // Set PDG flavour codes of the two vector vesons
  // for the process 2:  gamma gamma -> V1 V2
  // So far this processes is implemented for the following
  // mesons and their combinations only:
  // pho0 (113), omega (223), phi (333), J/psi (443)
  fTPHICgen->SetKV1(kf1);
  fTPHICgen->SetKV2(kf2);
}
//____________________________________________________________
  Float_t AliGenTPHIC::GetGGmass    ()
{
  // Get invariant mass of generated 2-photon system
  return fTPHICgen->GetWSQ();
}
//____________________________________________________________
  Float_t AliGenTPHIC::GetGGrapidity()
{
  // Get rapidity of generated 2-photon system
  return fTPHICgen->GetYGG();
}
//____________________________________________________________
  Float_t AliGenTPHIC::GetG1mass    ()
{
  // Get a mass of the first virtual photon of
  // the 2-photon process (-sqrt(q1^2)).
  return fTPHICgen->GetXMG1();
}
//____________________________________________________________
  Float_t AliGenTPHIC::GetG2mass    ()
{
  // Get a mass of the second virtual photon of
  // the 2-photon process (-sqrt(q2^2)).
  return fTPHICgen->GetXMG2();
}
//____________________________________________________________
  TClonesArray*  AliGenTPHIC::GetParticleList ()
{
  // Get array of particles of the event listing
  return fParticles;
}
//____________________________________________________________
  TLorentzVector AliGenTPHIC::MomentumRecNucl1()
{
  // Get 4-momentum of the first recoil nucleus after
  // the 2-photon process.
  return TLorentzVector(fTPHICgen->GetPTAG1(0),
			fTPHICgen->GetPTAG1(1),
			fTPHICgen->GetPTAG1(2),
			fTPHICgen->GetPTAG1(3));
}
//____________________________________________________________
  TLorentzVector AliGenTPHIC::MomentumRecNucl2()
{
  // Get 4-momentum of the first recoil nucleus after
  // the 2-photon process.
  return TLorentzVector(fTPHICgen->GetPTAG2(0),
			fTPHICgen->GetPTAG2(1),
			fTPHICgen->GetPTAG2(2),
			fTPHICgen->GetPTAG2(3));
}
//____________________________________________________________
  Float_t AliGenTPHIC::GetXSectionCurrent()
{
  // Get the cross section of the produced event for the
  // Monte Carlo integral cross section calculation
  return fTPHICgen->GetXSCUR();
}
//____________________________________________________________
  Float_t AliGenTPHIC::GetXSection       ()
{
  // Get the integral cross section of the process
  // calculated so far
  return fTPHICgen->GetXSTOT();
}
//____________________________________________________________
  Float_t AliGenTPHIC::GetXSectionError  ()
{
  // Get the error of the integral cross section of the process
  // calculated so far
  return fTPHICgen->GetXSTOTE();
}
Commit	Line	Data
0b5dd071	1	/**************************************************************************
	2	* Copyright(c) 1998-2003, 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	**************************************************************************/
	16
	17	/* $Id$ */
	18
0b5dd071	19	// Event generator of two-photon processes
	20	// in ultra-peripheral ion collisions.
	21	// 5 two-photon process are implemented, see comments to SetProcess().
	22	//%
	23	// The example of the generator initialization for the process
	24	// gamma gamma -> X in CaCa collisions at 7000 TeV/nucleon is the following:
	25	//%
	26	// AliGenTPHIC *gener = new AliGenTPHIC();
	27	// gener->SetProcess(1);
	28	// gener->SetBeamEnergy(3500.);
	29	// gener->SetBeamZ(20);
	30	// gener->SetBeamA(40);
	31	// gener->SetMggRange(70.,200.);
	32	// gener->SetYggRange(-5.,5.);
	33	// gener->SetLumFunName("lum_ca_70_200.dat");
	34	// gener->SetLumFunFlag(-1);
	35	// gener->Init();
	36	//%
	37	// The two-photon luminosity function needed for the process cross section
	38	// calculation is time-consuming, therefore it can be calculated once for a
	39	// selected two-photon energy and rapidity range and selected ion species,
	40	// saved into a file and then can be reused in further calculation.
	41	//%
	42	// The integral cross section of the process is calculated in each event
	43	// by the Monte Carlo integration procedure, the differential cross section
	44	// of each thrown event is assigned as a weight to each track of the event
	45	// which can be then used during the event analysis by retreiving this weight
	46	// from any of the event tracks.
	47	//
	48	// The manual of the fortran generator is available in
	49	// $ALICE_ROOT/TPHIC/TPHIC_doc.ps.gz
	50	// For the two-photon physics in heavy ion collisions see
	51	// G.Baur et al, Phys.Rep. 364 (2002), 359.
	52	//%
	53	// Author: Yuri.Kharlov@cern.ch
	54	// 15 April 2003
	55
	56	#include <TParticle.h>
	57	#include <TParticlePDG.h>
	58	#include <TDatabasePDG.h>
37b09b91	59	#include <TClonesArray.h>
37b09b91	60
0b5dd071	61	#include "AliPythia.h"
	62	#include "AliRun.h"
	63	#include <AliGenTPHIC.h>
	64	#include <TPHICgen.h>
	65	#include <TPHICcommon.h>
	66
	67	ClassImp(AliGenTPHIC)
	68
	69	//------------------------------------------------------------
	70
f893d4a5	71	AliGenTPHIC::AliGenTPHIC() :
	72	AliGenMC(),
	73	fTPHICgen(0x0),
	74	fPythia(0x0),
	75	fParticles(0x0),
	76	fEvent(-1),
	77	fDebug(0),
	78	fDebugEventFirst(-1),
	79	fDebugEventLast(-1)
0b5dd071	80	{
	81	// Constructor: create generator instance,
	82	// create particle array
	83	// Set TPHIC parameters to default values:
	84	// eta_b production in Ca-Ca collisions at 7 A*TeV
	85
	86	SetMC(new TPHICgen());
	87	fPythia = AliPythia::Instance();
	88	fParticles = new TClonesArray("TParticle",100);
	89
	90	SetProcess ();
	91	SetBeamEnergy();
	92	SetBeamZ ();
	93	SetBeamA ();
	94	SetYggRange ();
	95	SetMggRange ();
	96	SetNgridY ();
	97	SetNgridM ();
	98	SetLumFunName();
	99	SetLumFunFlag();
	100	SetKfOnium ();
	101	}
	102
0b5dd071	103	//____________________________________________________________
	104	AliGenTPHIC::~AliGenTPHIC()
	105	{
	106	// Destroys the object, deletes and disposes all TParticles currently on list.
	107	if (fParticles) {
	108	fParticles->Delete();
	109	delete fParticles;
	110	fParticles = 0;
	111	}
	112	}
	113
	114	//____________________________________________________________
	115	void AliGenTPHIC::Init()
	116	{
	117	// Initialize the generator TPHIC
	118
	119	fTPHICgen->Initialize();
	120	fEvent = 0;
	121	}
	122
	123	//____________________________________________________________
	124	void AliGenTPHIC::Generate()
	125	{
	126	// Generate one event of two-photon process.
	127	// Gaussian smearing on the vertex is done if selected.
	128	// All particles from the TPHIC/PYTHIA event listing
	129	// are stored in TreeK, and only final-state particles are tracked.
	130	// The event differectial cross section is assigned as a weight
	131	// to each track of the event.
	132
8feee6f7	133	Float_t polar[3] = {0,0,0};
8feee6f7	134	Float_t origin0[3] = {0,0,0};
21391258	135	Float_t time0 = 0.;
8feee6f7	136	Float_t origin[3] = {0,0,0};
0b5dd071	137	Float_t p[3], tof;
	138	Double_t weight;
	139
	140	Int_t ks,kf,iparent,nt, trackIt;
	141	Float_t random[6];
	142	const Float_t kconv=0.001/2.999792458e8;
	143
	144	fTPHICgen->GenerateEvent();
	145	weight = GetXSectionCurrent();
	146	if (gAlice->GetEvNumber()>=fDebugEventFirst &&
	147	gAlice->GetEvNumber()<=fDebugEventLast) fPythia->Pylist(1);
	148	fPythia->ImportParticles(fParticles,"All");
	149
	150	if (fDebug == 1)
	151	Info("Generate()","one event is produced");
	152
	153	Int_t j;
21391258	154	for (j=0;j<3;j++) origin0[j]=fOrigin[j];
21391258	155	time0 = fTimeOrigin;
0b5dd071	156	if(fVertexSmear==kPerEvent) {
	157	Rndm(random,6);
	158	for (j=0;j<3;j++) {
	159	origin0[j]+=fOsigma[j]TMath::Cos(2random[2j]TMath::Pi())*
	160	TMath::Sqrt(-2TMath::Log(random[2j+1]));
	161	}
21391258	162	Rndm(random,2);
	163	time0 += fOsigma[2]/TMath::Ccgs()*
	164	TMath::Cos(2random[0]TMath::Pi())*
	165	TMath::Sqrt(-2*TMath::Log(random[1]));
0b5dd071	166	}
	167
	168	Int_t ip;
	169	Int_t np = fParticles->GetEntriesFast();
	170	TParticle *iparticle;
	171	// Int_t* pParent = new Int_t[np];
	172	for (ip=0; ip<np; ip++) {
	173	iparticle = (TParticle *) fParticles->At(ip);
	174	ks = iparticle->GetStatusCode();
	175	// // No initial state partons
	176	// if (ks==21) continue;
	177	p[0] = iparticle->Px();
	178	p[1] = iparticle->Py();
	179	p[2] = iparticle->Pz();
	180	origin[0] = origin0[0]+iparticle->Vx()/10.;
	181	origin[1] = origin0[1]+iparticle->Vy()/10.;
	182	origin[2] = origin0[2]+iparticle->Vz()/10.;
	183	kf = CheckPDGCode(iparticle->GetPdgCode());
	184	iparent = -1;
21391258	185	tof = time0 + kconv*iparticle->T();
0b5dd071	186	if (ks == 1) trackIt = 1;
0b5dd071	187	else trackIt = 0;
642f15cf	188	PushTrack(fTrackIt*trackIt,iparent,kf,p,origin,polar,tof,kPPrimary,nt,weight,ks);
0b5dd071	189	KeepTrack(nt);
	190
	191	if (fDebug == 2)
	192	printf("id=%+4d, parent=%3d, ks=%d, p = (%+11.4e,%+11.4e,%+11.4e) GeV\n",
	193	kf,iparent,fTrackIt*trackIt,p[0],p[1],p[2]);
	194	}
	195	fEvent++;
	196	fTPHICgen->SetNEVENT(fEvent);
	197	if (fDebug == 1 && fEvent%100 == 0) {
	198	Info("Generate","Event %d\n",fEvent);
	199	fTPHICgen->Finish();
	200	}
	201	}
	202
	203	//____________________________________________________________
	204	void AliGenTPHIC::SetEventListRange(Int_t eventFirst, Int_t eventLast)
	205	{
	206	// Set a range of event numbers, for which a table
	207	// of generated particle will be printed
	208	fDebugEventFirst = eventFirst;
	209	fDebugEventLast = eventLast;
	210	if (fDebugEventLast==-1) fDebugEventLast=fDebugEventFirst;
	211	}
	212
	213	//____________________________________________________________
	214	void AliGenTPHIC::SetProcess (Int_t proc )
	215	{
	216	// Set process number:
	217	// proc=1 - gamma gamma -> X
	218	// proc=2 - gamma gamma -> quarkonium
	219	// proc=3 - gamma gamma -> fermion+ fermion-
	220	// proc=4 - gamma gamma -> W+ W-
	221	// proc=5 - not implemented
	222	// proc=6 - gamma gamma -> V1 V2 (vector meson pair)
	223
	224	fTPHICgen->SetIPROC(proc);
	225	}
	226	//____________________________________________________________
	227	void AliGenTPHIC::SetBeamEnergy (Float_t energy)
	228	{
	229	// Set energy of the beam ion per nucleon in GeV
	230	fTPHICgen->SetEBMN(energy);
	231	}
	232	//____________________________________________________________
	233	void AliGenTPHIC::SetBeamZ (Int_t z )
	234	{
	235	// Set beam ion charge
	236	fTPHICgen->SetIZ(z);
	237	}
	238	//____________________________________________________________
	239	void AliGenTPHIC::SetBeamA (Int_t a )
	240	{
	241	// Set beam ion atomic number
	242	fTPHICgen->SetIA(a);
	243	}
	244	//____________________________________________________________
	245	void AliGenTPHIC::SetYggRange (Float_t ymin, Float_t ymax)
	246	{
	247	// Set rapidity range of 2-photon system for the
	248	// luminosity function calculation
	249	fTPHICgen->SetYMIN(ymin);
	250	fTPHICgen->SetYMAX(ymax);
	251	}
	252	//____________________________________________________________
253	void AliGenTPHIC::SetMggRange (Float_t mmin, Float_t mmax)
254	{
255	// Set invariant mass range of 2-photon system for the
256	// luminosity function calculation
257	fTPHICgen->SetAMIN(mmin);
258	fTPHICgen->SetAMAX(mmax);
259	}
260	//____________________________________________________________
261	void AliGenTPHIC::SetNgridY (Int_t ny )
262	{
263	// Set number of nodes on the grid along the rapidity axis
264	// to calculate the 2-photon luminosity function
265	fTPHICgen->SetNY(ny);
266	}
267	//____________________________________________________________
268	void AliGenTPHIC::SetNgridM (Int_t nm )
269	{
270	// Set number of nodes on the grid along the mass axis
271	// to calculate the 2-photon luminosity function
272	fTPHICgen->SetNMAS(nm);
273	}
274	//____________________________________________________________
275	void AliGenTPHIC::SetLumFunName (TString name )
276	{
277	// Set filename to store the 2-photon luminosity
278	// function calculated on the grid
279	fTPHICgen->SetLUMFIL(name);
280	}
281	//____________________________________________________________
282	void AliGenTPHIC::SetLumFunFlag (Int_t flag )
283	{
284	// Set flag to calculate the 2-photon luminosity function:
285	// flag=-1 if a new lumimosity function to be calculated
286	// and stored in a file
287	// flag=+1 if a previously calculated function to be read
288	// from a file
289	fTPHICgen->SetILUMF(flag);
290	}
291	//____________________________________________________________
292	void AliGenTPHIC::SetKfFermion (Int_t kf )
293	{
294	// Set a PDG flavour code of a fermion for the process 3,
295	// gamma gamma -> fermion+ fermion-
296	fTPHICgen->SetKFERM(kf);
297	}
298	//____________________________________________________________
299	void AliGenTPHIC::SetKfOnium (Int_t kf )
300	{
301	// Set a PDG flavour code of a quarkonium for the process 2,
302	// gamma gamma -> quarkonium
303	fTPHICgen->SetKFONIUM(kf);
304	}
305	//____________________________________________________________
306	void AliGenTPHIC::SetMassOnium (Float_t mass )
307	{
308	// Set a quarkonium mass [GeV] for the process 2 if it
309	// differes from the Pythia's particle table.
310	// For the well-known quarkonia no need to set this mass
311	// because it will be taken from the Pythia table
312	fTPHICgen->SetXMRES(mass);
313	}
314	//____________________________________________________________
315	void AliGenTPHIC::SetGGwidthOnium(Float_t width )
316	{
317	// Set 2-photon partial width [GeV] of the quarkonium for
318	// the process 2 if it differes fromthe Pythia's particle table.
319	// For the well-known quarkonia no need to set this width
320	// because it will be taken from the Pythia table
321	fTPHICgen->SetXGGRES(width);
322	}
323	//____________________________________________________________
324	void AliGenTPHIC::SetKfVmesons (Int_t kf1, Int_t kf2)
325	{
326	// Set PDG flavour codes of the two vector vesons
327	// for the process 2: gamma gamma -> V1 V2
328	// So far this processes is implemented for the following
329	// mesons and their combinations only:
330	// pho0 (113), omega (223), phi (333), J/psi (443)
331	fTPHICgen->SetKV1(kf1);
332	fTPHICgen->SetKV2(kf2);
333	}
334	//____________________________________________________________
335	Float_t AliGenTPHIC::GetGGmass ()
336	{
337	// Get invariant mass of generated 2-photon system
338	return fTPHICgen->GetWSQ();
339	}
340	//____________________________________________________________
341	Float_t AliGenTPHIC::GetGGrapidity()
342	{
343	// Get rapidity of generated 2-photon system
344	return fTPHICgen->GetYGG();
345	}
346	//____________________________________________________________
347	Float_t AliGenTPHIC::GetG1mass ()
348	{
349	// Get a mass of the first virtual photon of
350	// the 2-photon process (-sqrt(q1^2)).
351	return fTPHICgen->GetXMG1();
352	}
353	//____________________________________________________________
354	Float_t AliGenTPHIC::GetG2mass ()
355	{
356	// Get a mass of the second virtual photon of
357	// the 2-photon process (-sqrt(q2^2)).
358	return fTPHICgen->GetXMG2();
359	}
360	//____________________________________________________________
361	TClonesArray* AliGenTPHIC::GetParticleList ()
362	{
363	// Get array of particles of the event listing
364	return fParticles;
365	}
366	//____________________________________________________________
367	TLorentzVector AliGenTPHIC::MomentumRecNucl1()
368	{
369	// Get 4-momentum of the first recoil nucleus after
370	// the 2-photon process.
2c23f883	371	return TLorentzVector(fTPHICgen->GetPTAG1(0),
2c23f883	372	fTPHICgen->GetPTAG1(1),
0b5dd071	373	fTPHICgen->GetPTAG1(2),
2c23f883	374	fTPHICgen->GetPTAG1(3));
0b5dd071	375	}
	376	//____________________________________________________________
	377	TLorentzVector AliGenTPHIC::MomentumRecNucl2()
	378	{
	379	// Get 4-momentum of the first recoil nucleus after
	380	// the 2-photon process.
2c23f883	381	return TLorentzVector(fTPHICgen->GetPTAG2(0),
2c23f883	382	fTPHICgen->GetPTAG2(1),
0b5dd071	383	fTPHICgen->GetPTAG2(2),
2c23f883	384	fTPHICgen->GetPTAG2(3));
0b5dd071	385	}
	386	//____________________________________________________________
	387	Float_t AliGenTPHIC::GetXSectionCurrent()
	388	{
	389	// Get the cross section of the produced event for the
	390	// Monte Carlo integral cross section calculation
	391	return fTPHICgen->GetXSCUR();
	392	}
	393	//____________________________________________________________
	394	Float_t AliGenTPHIC::GetXSection ()
	395	{
	396	// Get the integral cross section of the process
	397	// calculated so far
	398	return fTPHICgen->GetXSTOT();
	399	}
	400	//____________________________________________________________
	401	Float_t AliGenTPHIC::GetXSectionError ()
	402	{
	403	// Get the error of the integral cross section of the process
	404	// calculated so far
	405	return fTPHICgen->GetXSTOTE();
	406	}