[u/mrichter/AliRoot.git] / FASTSIM / AliQuenchingWeights.h

#ifndef ALIQUENCHINGWEIGHTS_H
#define ALIQUENCHINGWEIGHTS_H
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice                               */

/* $Id$ */

//----------------------------------------------------------------------------
//     Implementation of the class to calculate the parton energy loss
//  Based on the "BDMPS" quenching weights by C.A.Salgado and U.A.Wiedemann
//
//  References:
//   C.A.Salgado and U.A.Wiedemann, Phys.Rev.D68 (2003) 014008 [hep-ph/0302184]
//   A.Dainese, Eur.Phys.J.C, in press, [nucl-ex/0312005]             
//
//            Origin:  C. Loizides   constantin.loizides@cern.ch
//                     A. Dainese    andrea.dainese@pd.infn.it            
//----------------------------------------------------------------------------

#include <TMath.h>
#include <TObject.h>
class TH1F;

class AliQuenchingWeights : public TObject {
 public:
  enum kECMethod {kDefault=0,kReweight=1,kReweightCont=2};

  AliQuenchingWeights();
  AliQuenchingWeights(const AliQuenchingWeights& a);
  AliQuenchingWeights& operator=(const AliQuenchingWeights& a)
      {a.Copy(*this); return(*this);}
  virtual ~AliQuenchingWeights();

  void Reset();
  Int_t SampleEnergyLoss();
  Int_t SampleEnergyLoss(Int_t ipart, Double_t r);

  Double_t GetELossRandom(Int_t ipart, Double_t length, Double_t e=1.e10) const;
  Double_t CalcQuenchedEnergy(Int_t ipart, Double_t length, Double_t e)  const;
  Double_t GetELossRandom(Int_t ipart, TH1F *hell, Double_t e=1.e10) const;
  Double_t CalcQuenchedEnergy(Int_t ipart, TH1F *hell, Double_t e)  const;
  Double_t GetELossRandomK(Int_t ipart, Double_t I0, Double_t I1, Double_t e=1.e10);
  Double_t CalcQuenchedEnergyK(Int_t ipart, Double_t I0, Double_t I1, Double_t e);
  Double_t GetELossRandomKFast(Int_t ipart, Double_t I0, Double_t I1, Double_t e=1.e10);
  Double_t GetELossRandomKFastR(Int_t ipart, Double_t r, Double_t wc, Double_t e=1.e10);
  Double_t CalcQuenchedEnergyKFast(Int_t ipart, Double_t I0, Double_t I1, Double_t e);

  Double_t GetDiscreteWeight(Int_t ipart, Double_t I0, Double_t I1);
  Double_t GetDiscreteWeightR(Int_t ipart, Double_t r);
  void GetZeroLossProb(Double_t &p,Double_t &prw,Double_t &prwcont,
		       Int_t ipart,Double_t I0,Double_t I1,Double_t e=1.e10);
  void GetZeroLossProbR(Double_t &p,Double_t &prw, Double_t &prwcont,
			Int_t ipart,Double_t r,Double_t wc,Double_t e=1.e10);

  //multiple soft scattering approximation
  Int_t InitMult(const Char_t *contall="$(ALICE_ROOT)/FASTSIM/data/cont_mult.all",
                 const Char_t *discall="$(ALICE_ROOT)/FASTSIM/data/disc_mult.all"); 

  //single hard scattering approximation
  Int_t InitSingleHard(const Char_t *contall="$(ALICE_ROOT)/FASTSIM/data/cont_lin.all",
                       const Char_t *discall="$(ALICE_ROOT)/FASTSIM/data/disc_lin.all"); 

  Int_t CalcMult(Int_t ipart, Double_t rrrr,Double_t xxxx,
                 Double_t &continuous,Double_t &discrete) const;
  Int_t CalcMult(Int_t ipart, 
		 Double_t w, Double_t qtransp, Double_t length,
                 Double_t &continuous,Double_t &discrete) const;
  Int_t CalcSingleHard(Int_t ipart, Double_t rrrr,Double_t xxxx,
		       Double_t &continuous,Double_t &discrete) const;
  Int_t CalcSingleHard(Int_t ipart, 
  		       Double_t w, Double_t mu, Double_t length,
                       Double_t &continuous,Double_t &discrete) const;

  Double_t CalcWC(Double_t q, Double_t l) const 
    {return 0.5*q*l*l*fgkConvFmToInvGeV;}

  Double_t CalcWCbar(Double_t mu, Double_t l) const 
    {return 0.5*mu*mu*l*fgkConvFmToInvGeV;}

  Double_t CalcWC(Double_t l) const 
    {if(fMultSoft) return CalcWC(fQTransport,l);
     else return CalcWCbar(fMu,l);}

  Double_t CalcWCk(Double_t I1) const 
    {if(fMultSoft) return CalcWCk(fK,I1);
     else return -1;} //not implemented!

  Double_t CalcWCk(Double_t k, Double_t I1) const 
    {if(fMultSoft) return k*I1/fgkConvFmToInvGeV;
     else return -1;} //not implemented!

  Double_t CalcR(Double_t wc, Double_t l) const; 

  Double_t CalcRk(Double_t I0, Double_t I1) const
    {return CalcRk(fK,I0,I1);} 

  Double_t CalcRk(Double_t k, Double_t I0, Double_t I1) const; 

  Double_t CalcQk(Double_t I0, Double_t I1) const
    {return CalcQk(fK,I0,I1);} 

  Double_t CalcQk(Double_t k, Double_t I0, Double_t I1) const
    {return I0*I0/2./I1/fgkConvFmToInvGeV/fgkConvFmToInvGeV*k;}

  Double_t CalcLk(Double_t i0, Double_t i1) const
    {return 2.*i1/i0;}

  Int_t CalcLengthMax(Double_t q) const
    {Double_t l3max=fgkRMax/.5/q/fgkConvFmToInvGeV/fgkConvFmToInvGeV;
     return (Int_t)TMath::Power(l3max,1./3.);} 

  const TH1F* GetHisto(Int_t ipart,Double_t length) const;

  void SetMu(Double_t m=1.) {fMu=m;}
  void SetQTransport(Double_t q=1.) {fQTransport=q;}
  void SetK(Double_t k=4.e5) {fK=k;} //about 1 GeV^2/fm
  void SetECMethod(kECMethod type=kDefault);
  void SetLengthMax(Int_t l=20) {fLengthMax=l;}

  Float_t GetMu()           const {return fMu;}
  Float_t GetQTransport()   const {return fQTransport;}
  Float_t GetK()            const {return fK;}
  Bool_t  GetECMethod()     const {return fECMethod;}
  Bool_t  GetTablesLoaded() const {return fTablesLoaded;}
  Bool_t  GetMultSoft()     const {return fMultSoft;}
  Int_t   GetLengthMax()    const {return fLengthMax;}

  TH1F* ComputeQWHisto (Int_t ipart,Double_t medval,Double_t length)  const; 
  TH1F* ComputeQWHistoX(Int_t ipart,Double_t medval,Double_t length)  const; 
  TH1F* ComputeQWHistoX(Int_t ipart,Double_t r)                       const; 
  TH1F* ComputeELossHisto(Int_t ipart,Double_t medval,Double_t l,Double_t e=1.e10) const; 
  TH1F* ComputeELossHisto(Int_t ipart,Double_t medval,TH1F *hEll,Double_t e=1.e10) const; 
  TH1F* ComputeELossHisto(Int_t ipart,Double_t r)                                  const; 

  Double_t GetMeanELoss(Int_t ipart,Double_t medval,Double_t l) const;
  Double_t GetMeanELoss(Int_t ipart,Double_t medval,TH1F *hEll) const; 
  Double_t GetMeanELoss(Int_t ipart,Double_t r)                 const; 
  
  void PlotDiscreteWeights(Double_t len=4,Double_t qm=5)         const; 
  void PlotContWeights(Int_t itype,Double_t len)                 const;
  void PlotContWeightsVsL(Int_t itype,Double_t medval)           const;
  void PlotAvgELoss(Double_t len,Double_t qm=5,Double_t e=1.e10) const;
  void PlotAvgELoss(TH1F *hEll,Double_t e=1.e10)                 const;
  void PlotAvgELossVsL(Double_t e=1.e10)                         const;
  void PlotAvgELossVsPt(Double_t medval,Double_t len)            const;
  void PlotAvgELossVsPt(Double_t medval,TH1F *hEll)              const;

 protected:
  Int_t GetIndex(Double_t len) const;

  static const Double_t fgkConvFmToInvGeV; //conversion factor
  static const Int_t    fgkBins;           //number of bins for hists
  static const Double_t fgkMaxBin;         //max. value of wc
  static const Double_t fgkRMax;           //max. tabled value of R

  static Int_t fgCounter;//static instance counter
  Int_t fInstanceNumber; //instance number of class

  Bool_t fMultSoft;     //approximation type
  kECMethod fECMethod;     //energy constraint method
  Double_t fQTransport; //transport coefficient [GeV^2/fm]]
  Double_t fMu;         //Debye screening mass
  Double_t fK;          //proportional constant [fm]
  Int_t fLengthMax;     //maximum length
  Int_t fLengthMaxOld;  //maximum length used for histos

  //discrete and cont part of quenching for
  //both parton type and different lengths
  TH1F ***fHistos; //!
  TH1F *fHisto; //!

  // data strucs for tables
  Double_t fxx[400];      //sampled energy quark
  Double_t fxxg[400];     //sampled energy gluon
  Double_t fdaq[34];      //discrete weight quark
  Double_t fdag[34];      //discrete weight gluon
  Double_t fcaq[34][261]; //continuous weights quarks
  Double_t fcag[34][261]; //continuous weights gluons  
  Double_t frrr[34];      //r value quark
  Double_t frrrg[34];     //r value gluon
  Bool_t fTablesLoaded;   //tables loaded

  ClassDef(AliQuenchingWeights,1)    // Base class for Quenching Weights
};

#endif
Commit	Line	Data
	1	#ifndef ALIQUENCHINGWEIGHTS_H
	2	#define ALIQUENCHINGWEIGHTS_H
	3	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
	5
	6	/* $Id$ */
	7
	8	//----------------------------------------------------------------------------
	9	// Implementation of the class to calculate the parton energy loss
	10	// Based on the "BDMPS" quenching weights by C.A.Salgado and U.A.Wiedemann
	11	//
	12	// References:
	13	// C.A.Salgado and U.A.Wiedemann, Phys.Rev.D68 (2003) 014008 [hep-ph/0302184]
	14	// A.Dainese, Eur.Phys.J.C, in press, [nucl-ex/0312005]
	15	//
	16	// Origin: C. Loizides constantin.loizides@cern.ch
	17	// A. Dainese andrea.dainese@pd.infn.it
	18	//----------------------------------------------------------------------------
	19
	20	#include <TMath.h>
	21	#include <TObject.h>
	22	class TH1F;
	23
	24	class AliQuenchingWeights : public TObject {
	25	public:
	26	enum kECMethod {kDefault=0,kReweight=1,kReweightCont=2};
	27
	28	AliQuenchingWeights();
	29	AliQuenchingWeights(const AliQuenchingWeights& a);
	30	AliQuenchingWeights& operator=(const AliQuenchingWeights& a)
	31	{a.Copy(this); return(this);}
	32	virtual ~AliQuenchingWeights();
	33
	34	void Reset();
	35	Int_t SampleEnergyLoss();
	36	Int_t SampleEnergyLoss(Int_t ipart, Double_t r);
	37
	38	Double_t GetELossRandom(Int_t ipart, Double_t length, Double_t e=1.e10) const;
	39	Double_t CalcQuenchedEnergy(Int_t ipart, Double_t length, Double_t e) const;
	40	Double_t GetELossRandom(Int_t ipart, TH1F *hell, Double_t e=1.e10) const;
	41	Double_t CalcQuenchedEnergy(Int_t ipart, TH1F *hell, Double_t e) const;
	42	Double_t GetELossRandomK(Int_t ipart, Double_t I0, Double_t I1, Double_t e=1.e10);
	43	Double_t CalcQuenchedEnergyK(Int_t ipart, Double_t I0, Double_t I1, Double_t e);
	44	Double_t GetELossRandomKFast(Int_t ipart, Double_t I0, Double_t I1, Double_t e=1.e10);
	45	Double_t GetELossRandomKFastR(Int_t ipart, Double_t r, Double_t wc, Double_t e=1.e10);
	46	Double_t CalcQuenchedEnergyKFast(Int_t ipart, Double_t I0, Double_t I1, Double_t e);
	47
	48	Double_t GetDiscreteWeight(Int_t ipart, Double_t I0, Double_t I1);
	49	Double_t GetDiscreteWeightR(Int_t ipart, Double_t r);
	50	void GetZeroLossProb(Double_t &p,Double_t &prw,Double_t &prwcont,
	51	Int_t ipart,Double_t I0,Double_t I1,Double_t e=1.e10);
	52	void GetZeroLossProbR(Double_t &p,Double_t &prw, Double_t &prwcont,
	53	Int_t ipart,Double_t r,Double_t wc,Double_t e=1.e10);
	54
	55	//multiple soft scattering approximation
	56	Int_t InitMult(const Char_t *contall="$(ALICE_ROOT)/FASTSIM/data/cont_mult.all",
	57	const Char_t *discall="$(ALICE_ROOT)/FASTSIM/data/disc_mult.all");
	58
	59	//single hard scattering approximation
	60	Int_t InitSingleHard(const Char_t *contall="$(ALICE_ROOT)/FASTSIM/data/cont_lin.all",
	61	const Char_t *discall="$(ALICE_ROOT)/FASTSIM/data/disc_lin.all");
	62
	63	Int_t CalcMult(Int_t ipart, Double_t rrrr,Double_t xxxx,
	64	Double_t &continuous,Double_t &discrete) const;
	65	Int_t CalcMult(Int_t ipart,
	66	Double_t w, Double_t qtransp, Double_t length,
	67	Double_t &continuous,Double_t &discrete) const;
	68	Int_t CalcSingleHard(Int_t ipart, Double_t rrrr,Double_t xxxx,
	69	Double_t &continuous,Double_t &discrete) const;
	70	Int_t CalcSingleHard(Int_t ipart,
	71	Double_t w, Double_t mu, Double_t length,
	72	Double_t &continuous,Double_t &discrete) const;
	73
	74	Double_t CalcWC(Double_t q, Double_t l) const
	75	{return 0.5qllfgkConvFmToInvGeV;}
	76
	77	Double_t CalcWCbar(Double_t mu, Double_t l) const
	78	{return 0.5mumulfgkConvFmToInvGeV;}
	79
	80	Double_t CalcWC(Double_t l) const
	81	{if(fMultSoft) return CalcWC(fQTransport,l);
	82	else return CalcWCbar(fMu,l);}
	83
	84	Double_t CalcWCk(Double_t I1) const
	85	{if(fMultSoft) return CalcWCk(fK,I1);
	86	else return -1;} //not implemented!
	87
	88	Double_t CalcWCk(Double_t k, Double_t I1) const
	89	{if(fMultSoft) return k*I1/fgkConvFmToInvGeV;
	90	else return -1;} //not implemented!
	91
	92	Double_t CalcR(Double_t wc, Double_t l) const;
	93
	94	Double_t CalcRk(Double_t I0, Double_t I1) const
	95	{return CalcRk(fK,I0,I1);}
	96
	97	Double_t CalcRk(Double_t k, Double_t I0, Double_t I1) const;
	98
	99	Double_t CalcQk(Double_t I0, Double_t I1) const
	100	{return CalcQk(fK,I0,I1);}
	101
	102	Double_t CalcQk(Double_t k, Double_t I0, Double_t I1) const
	103	{return I0I0/2./I1/fgkConvFmToInvGeV/fgkConvFmToInvGeVk;}
	104
	105	Double_t CalcLk(Double_t i0, Double_t i1) const
	106	{return 2.*i1/i0;}
	107
	108	Int_t CalcLengthMax(Double_t q) const
	109	{Double_t l3max=fgkRMax/.5/q/fgkConvFmToInvGeV/fgkConvFmToInvGeV;
	110	return (Int_t)TMath::Power(l3max,1./3.);}
	111
	112	const TH1F* GetHisto(Int_t ipart,Double_t length) const;
	113
	114	void SetMu(Double_t m=1.) {fMu=m;}
	115	void SetQTransport(Double_t q=1.) {fQTransport=q;}
	116	void SetK(Double_t k=4.e5) {fK=k;} //about 1 GeV^2/fm
	117	void SetECMethod(kECMethod type=kDefault);
	118	void SetLengthMax(Int_t l=20) {fLengthMax=l;}
	119
	120	Float_t GetMu() const {return fMu;}
	121	Float_t GetQTransport() const {return fQTransport;}
	122	Float_t GetK() const {return fK;}
	123	Bool_t GetECMethod() const {return fECMethod;}
	124	Bool_t GetTablesLoaded() const {return fTablesLoaded;}
	125	Bool_t GetMultSoft() const {return fMultSoft;}
	126	Int_t GetLengthMax() const {return fLengthMax;}
	127
	128	TH1F* ComputeQWHisto (Int_t ipart,Double_t medval,Double_t length) const;
	129	TH1F* ComputeQWHistoX(Int_t ipart,Double_t medval,Double_t length) const;
	130	TH1F* ComputeQWHistoX(Int_t ipart,Double_t r) const;
	131	TH1F* ComputeELossHisto(Int_t ipart,Double_t medval,Double_t l,Double_t e=1.e10) const;
	132	TH1F* ComputeELossHisto(Int_t ipart,Double_t medval,TH1F *hEll,Double_t e=1.e10) const;
	133	TH1F* ComputeELossHisto(Int_t ipart,Double_t r) const;
	134
	135	Double_t GetMeanELoss(Int_t ipart,Double_t medval,Double_t l) const;
	136	Double_t GetMeanELoss(Int_t ipart,Double_t medval,TH1F *hEll) const;
	137	Double_t GetMeanELoss(Int_t ipart,Double_t r) const;
	138
	139	void PlotDiscreteWeights(Double_t len=4,Double_t qm=5) const;
	140	void PlotContWeights(Int_t itype,Double_t len) const;
	141	void PlotContWeightsVsL(Int_t itype,Double_t medval) const;
	142	void PlotAvgELoss(Double_t len,Double_t qm=5,Double_t e=1.e10) const;
	143	void PlotAvgELoss(TH1F *hEll,Double_t e=1.e10) const;
	144	void PlotAvgELossVsL(Double_t e=1.e10) const;
	145	void PlotAvgELossVsPt(Double_t medval,Double_t len) const;
	146	void PlotAvgELossVsPt(Double_t medval,TH1F *hEll) const;
	147
	148	protected:
	149	Int_t GetIndex(Double_t len) const;
	150
	151	static const Double_t fgkConvFmToInvGeV; //conversion factor
	152	static const Int_t fgkBins; //number of bins for hists
	153	static const Double_t fgkMaxBin; //max. value of wc
	154	static const Double_t fgkRMax; //max. tabled value of R
	155
	156	static Int_t fgCounter;//static instance counter
	157	Int_t fInstanceNumber; //instance number of class
	158
	159	Bool_t fMultSoft; //approximation type
	160	kECMethod fECMethod; //energy constraint method
	161	Double_t fQTransport; //transport coefficient [GeV^2/fm]]
	162	Double_t fMu; //Debye screening mass
	163	Double_t fK; //proportional constant [fm]
	164	Int_t fLengthMax; //maximum length
	165	Int_t fLengthMaxOld; //maximum length used for histos
	166
	167	//discrete and cont part of quenching for
	168	//both parton type and different lengths
	169	TH1F ***fHistos; //!
	170	TH1F *fHisto; //!
	171
	172	// data strucs for tables
	173	Double_t fxx[400]; //sampled energy quark
	174	Double_t fxxg[400]; //sampled energy gluon
	175	Double_t fdaq[34]; //discrete weight quark
	176	Double_t fdag[34]; //discrete weight gluon
	177	Double_t fcaq[34][261]; //continuous weights quarks
	178	Double_t fcag[34][261]; //continuous weights gluons
	179	Double_t frrr[34]; //r value quark
	180	Double_t frrrg[34]; //r value gluon
	181	Bool_t fTablesLoaded; //tables loaded
	182
	183	ClassDef(AliQuenchingWeights,1) // Base class for Quenching Weights
	184	};
	185
	186	#endif