[u/mrichter/AliRoot.git] / TEvtGen / EvtGenModels / EvtVubHybrid.cxx

//---------------------------------------------------------------------------
//
// Environment:
//      This software is part of the EvtGen package developed jointly
//      for the BaBar and CLEO collaborations.  If you use all or part
//      of it, please give an appropriate acknowledgement.
//
// Copyright Information:
//      Copyright (C) 1998      Caltech, UCSB
//
// Module: EvtVubHybrid.cc
//
// Description: Routine to decay a particle according to phase space. 
//
// Modification history:
//
//   Jochen Dingfelder February 1, 2005  Created Module as update of the
//                                       original module EvtVub by Sven Menke 
//---------------------------------------------------------------------------
//
#include "EvtGenBase/EvtPatches.hh"
#include <stdlib.h>
#include "EvtGenBase/EvtParticle.hh"
#include "EvtGenBase/EvtGenKine.hh"
#include "EvtGenBase/EvtPDL.hh"
#include "EvtGenBase/EvtReport.hh"
#include "EvtGenModels/EvtVubHybrid.hh"
#include "EvtGenBase/EvtVector4R.hh"
#include "EvtGenModels/EvtPFermi.hh"
#include "EvtGenModels/EvtVubdGamma.hh"
#include "EvtGenBase/EvtRandom.hh"

#include <string>
#include <iostream>
#include <fstream>
using std::ifstream;
using std::cout;
using std::endl;


// _noHybrid will be set TRUE if the DECAY.DEC file has no binning or weights
// _storeQplus should alwasy be TRUE: writes out Fermi motion parameter

EvtVubHybrid::EvtVubHybrid() 
  : _noHybrid(false), _storeQplus(true),
    _mb(4.62), _a(2.27), _alphas(0.22), _dGMax(3.),
    _nbins_mX(0), _nbins_q2(0), _nbins_El(0), _nbins(0),
    _masscut(0.28), _bins_mX(0), _bins_q2(0), _bins_El(0),
    _weights(0), _dGamma(0)
{}

EvtVubHybrid::~EvtVubHybrid() {
  delete _dGamma;
  delete [] _bins_mX;
  delete [] _bins_q2;
  delete [] _bins_El;
  delete [] _weights;

}

std::string EvtVubHybrid::getName(){

  return "VUBHYBRID";     

}

EvtDecayBase* EvtVubHybrid::clone(){

  return new EvtVubHybrid;

}

void EvtVubHybrid::init(){

  // check that there are at least 3 arguments
  if (getNArg() < EvtVubHybrid::nParameters) {
    report(ERROR,"EvtVubHybrid") << "EvtVub generator expected "
				 << "at least " << EvtVubHybrid::nParameters
				 << " arguments but found: " << getNArg()
				 << "\nWill terminate execution!"<<endl;
    ::abort(); 
  } else if (getNArg() == EvtVubHybrid::nParameters) {
    report(WARNING,"EvtVubHybrid") << "EvtVub: generate B -> Xu l nu events " 
				   << "without using the hybrid reweighting." 
				   << endl;
    _noHybrid = true;
  } else if (getNArg() < EvtVubHybrid::nParameters+EvtVubHybrid::nVariables) {
     report(ERROR,"EvtVubHybrid") << "EvtVub could not read number of bins for "
				  << "all variables used in the reweighting\n"
				  << "Will terminate execution!" << endl;
     ::abort();    
  }

  // check that there are 3 daughters
  checkNDaug(3);

  // read minimum required parameters from decay.dec
  _mb     = getArg(0);
  _a      = getArg(1);
  _alphas = getArg(2);

  // the maximum dGamma*p2 value depends on alpha_s only:
  const double dGMax0 = 3.;
  _dGMax = 0.21344+8.905*_alphas;
  if ( _dGMax < dGMax0 ) _dGMax = dGMax0;

  // for the Fermi Motion we need a B-Meson mass - but it's not critical
  // to get an exact value; in order to stay in the phase space for
  // B+- and B0 use the smaller mass
  
  static double mB0 = EvtPDL::getMaxMass(EvtPDL::getId("B0"));
  static double mBP = EvtPDL::getMaxMass(EvtPDL::getId("B+"));
  static double mB = (mB0<mBP?mB0:mBP);
  
  const double xlow = -_mb;
  const double xhigh = mB-_mb;
  const int aSize = 10000;

  EvtPFermi pFermi(_a,mB,_mb);
  // pf is the cumulative distribution normalized to 1.
  _pf.resize(aSize);
  for(int i=0;i<aSize;i++){
    double kplus = xlow + (double)(i+0.5)/((double)aSize)*(xhigh-xlow);
    if ( i== 0 )
      _pf[i] = pFermi.getFPFermi(kplus);
    else
      _pf[i] = _pf[i-1] + pFermi.getFPFermi(kplus);
  }
  for (size_t index=0; index<_pf.size(); index++) {
    _pf[index]/=_pf[_pf.size()-1];
  }

  _dGamma = new EvtVubdGamma(_alphas);
  
  if (_noHybrid) return;	// Without hybrid weighting, nothing else to do

  _nbins_mX = abs((int)getArg(3));
  _nbins_q2 = abs((int)getArg(4));
  _nbins_El = abs((int)getArg(5));

  int nextArg = EvtVubHybrid::nParameters + EvtVubHybrid::nVariables;

  _nbins = _nbins_mX*_nbins_q2*_nbins_El;	// Binning of weight table

  int expectArgs = nextArg + _nbins_mX +_nbins_q2 + _nbins_El + _nbins;

  if (getNArg() < expectArgs) {
    report(ERROR,"EvtVubHybrid")
      << " finds " << getNArg() << " arguments, expected " << expectArgs
      << ".  Something is wrong with the tables of weights or thresholds."
      << "\nWill terminate execution!" << endl;
    ::abort();        
  }

  // read bin boundaries from decay.dec
  int i;

  _bins_mX  = new double[_nbins_mX];
  for (i = 0; i < _nbins_mX; i++,nextArg++) {
    _bins_mX[i] = getArg(nextArg);
  }
  _masscut = _bins_mX[0];

  _bins_q2  = new double[_nbins_q2];
  for (i = 0; i < _nbins_q2; i++,nextArg++) {
    _bins_q2[i] = getArg(nextArg);    
  }

  _bins_El  = new double[_nbins_El];
  for (i = 0; i < _nbins_El; i++,nextArg++) {
    _bins_El[i] = getArg(nextArg);    
  }
    
  // read in weights (and rescale to range 0..1)
  readWeights(nextArg); 
}

void EvtVubHybrid::initProbMax(){
  noProbMax();
}

void EvtVubHybrid::decay( EvtParticle *p ){

  int j;
  // B+ -> u-bar specflav l+ nu
  
  EvtParticle *xuhad, *lepton, *neutrino;
  EvtVector4R p4;
  // R. Faccini 21/02/03
  // move the reweighting up , before also shooting the fermi distribution
  double x,z,p2;
  double sh=0.0;
  double mB,ml,xlow,xhigh,qplus;
  double El=0.0;
  double Eh=0.0;
  double kplus;
  double q2, mX;

  const double lp2epsilon=-10;
  bool rew(true);
  while(rew){
    
    p->initializePhaseSpace(getNDaug(),getDaugs());
    
    xuhad=p->getDaug(0);
    lepton=p->getDaug(1);
    neutrino=p->getDaug(2);
    
    mB = p->mass();
    ml = lepton->mass();
    
    xlow = -_mb;
    xhigh = mB-_mb;    
    
    // Fermi motion does not need to be computed inside the
    // tryit loop as m_b in Gamma0 does not need to be replaced by (m_b+kplus).
    // The difference however should be of the Order (lambda/m_b)^2 which is
    // beyond the considered orders in the paper anyway ...
    
    // for alpha_S = 0 and a mass cut on X_u not all values of kplus are 
    // possible. The maximum value is mB/2-_mb + sqrt(mB^2/4-_masscut^2)
    kplus = 2*xhigh;
    
    while( kplus >= xhigh || kplus <= xlow 
	   || (_alphas == 0 && kplus >= mB/2-_mb 
	       + sqrt(mB*mB/4-_masscut*_masscut))) {
      kplus = findPFermi(); //_pFermi->shoot();
      kplus = xlow + kplus*(xhigh-xlow);
    }
    qplus = mB-_mb-kplus;
    if( (mB-qplus)/2.<=ml) continue;
   
    int tryit = 1;
    while (tryit) {
      
      x = EvtRandom::Flat();
      z = EvtRandom::Flat(0,2);
      p2=EvtRandom::Flat();
      p2 = pow(10,lp2epsilon*p2);
      
      El = x*(mB-qplus)/2;
      if ( El > ml && El < mB/2) {
	
	Eh = z*(mB-qplus)/2+qplus;
	if ( Eh > 0 && Eh < mB ) {
	  
	  sh = p2*pow(mB-qplus,2)+2*qplus*(Eh-qplus)+qplus*qplus;
	  if ( sh > _masscut*_masscut
	       && mB*mB + sh - 2*mB*Eh > ml*ml) {
	    
	    double xran = EvtRandom::Flat();
	    
	    double y = _dGamma->getdGdxdzdp(x,z,p2)/_dGMax*p2;
	    
	    if ( y > 1 ) report(WARNING,"EvtVubHybrid") <<"EvtVubHybrid decay probability > 1 found: " << y << endl;
 	    if ( y >= xran ) tryit = 0;
	  }
	}
      }
    }

    // compute all kinematic variables needed for reweighting (J. Dingfelder)
    mX = sqrt(sh);
    q2 = mB*mB + sh - 2*mB*Eh;

    // Reweighting in bins of mX, q2, El (J. Dingfelder)
    if (_nbins>0) {
      double xran1 = EvtRandom::Flat();
      double w = 1.0;
      if (!_noHybrid) w = getWeight(mX, q2, El); 
      if ( w >= xran1 ) rew = false;
    } 
    else {
      rew = false;
    }
  }

  // o.k. we have the three kineamtic variables 
  // now calculate a flat cos Theta_H [-1,1] distribution of the 
  // hadron flight direction w.r.t the B flight direction 
  // because the B is a scalar and should decay isotropic.
  // Then chose a flat Phi_H [0,2Pi] w.r.t the B flight direction 
  // and and a flat Phi_L [0,2Pi] in the W restframe w.r.t the 
  // W flight direction.

  double ctH = EvtRandom::Flat(-1,1);
  double phH = EvtRandom::Flat(0,2*M_PI);
  double phL = EvtRandom::Flat(0,2*M_PI);

  // now compute the four vectors in the B Meson restframe
    
  double ptmp,sttmp;
  // calculate the hadron 4 vector in the B Meson restframe

  sttmp = sqrt(1-ctH*ctH);
  ptmp = sqrt(Eh*Eh-sh);
  double pHB[4] = {Eh,ptmp*sttmp*cos(phH),ptmp*sttmp*sin(phH),ptmp*ctH};
  p4.set(pHB[0],pHB[1],pHB[2],pHB[3]);
  xuhad->init( getDaug(0), p4);

  if (_storeQplus ) {
    // cludge to store the hidden parameter q+ with the decay; 
    // the lifetime of the Xu is abused for this purpose.
    // tau = 1 ps corresponds to ctau = 0.3 mm -> in order to
    // stay well below BaBars sensitivity we take q+/(10000 GeV) which 
    // goes up to 0.0005 in the most extreme cases as ctau in mm.
    // To extract q+ back from the StdHepTrk its necessary to get
    // delta_ctau = Xu->anyDaughter->getVertexTime()-Xu->getVertexTime()
    // where these pseudo calls refere to the StdHep time stored at
    // the production vertex in the lab for each particle. The boost 
    // has to be reversed and the result is:
    //
    // q+ = delta_ctau * 10000 GeV/mm * Mass_Xu/Energy_Xu     
    //
    xuhad->setLifetime(qplus/10000.);
  }

  // calculate the W 4 vector in the B Meson restrframe

  double apWB = ptmp;
  double pWB[4] = {mB-Eh,-pHB[1],-pHB[2],-pHB[3]};

  // first go in the W restframe and calculate the lepton and
  // the neutrino in the W frame

  double mW2   = mB*mB + sh - 2*mB*Eh;
  double beta  = ptmp/pWB[0];
  double gamma = pWB[0]/sqrt(mW2);

  double pLW[4];
    
  ptmp = (mW2-ml*ml)/2/sqrt(mW2);
  pLW[0] = sqrt(ml*ml + ptmp*ptmp);

  double ctL = (El - gamma*pLW[0])/beta/gamma/ptmp;
  if ( ctL < -1 ) ctL = -1;
  if ( ctL >  1 ) ctL =  1;
  sttmp = sqrt(1-ctL*ctL);

  // eX' = eZ x eW
  double xW[3] = {-pWB[2],pWB[1],0};
  // eZ' = eW
  double zW[3] = {pWB[1]/apWB,pWB[2]/apWB,pWB[3]/apWB};
  
  double lx = sqrt(xW[0]*xW[0]+xW[1]*xW[1]);
  for (j=0;j<2;j++) 
    xW[j] /= lx;

  // eY' = eZ' x eX'
  double yW[3] = {-pWB[1]*pWB[3],-pWB[2]*pWB[3],pWB[1]*pWB[1]+pWB[2]*pWB[2]};
  double ly = sqrt(yW[0]*yW[0]+yW[1]*yW[1]+yW[2]*yW[2]);
  for (j=0;j<3;j++) 
    yW[j] /= ly;

  // p_lep = |p_lep| * (  sin(Theta) * cos(Phi) * eX'
  //                    + sin(Theta) * sin(Phi) * eY'
  //                    + cos(Theta) *            eZ')
  for (j=0;j<3;j++)
    pLW[j+1] = sttmp*cos(phL)*ptmp*xW[j] 
      +        sttmp*sin(phL)*ptmp*yW[j]
      +          ctL         *ptmp*zW[j];

  double apLW = ptmp;
  // calculate the neutrino 4 vector in the W restframe
  //double pNW[4] = {sqrt(mW2)-pLW[0],-pLW[1],-pLW[2],-pLW[3]};
    
  // boost them back in the B Meson restframe
  
  double appLB = beta*gamma*pLW[0] + gamma*ctL*apLW;
 
  ptmp = sqrt(El*El-ml*ml);
  double ctLL = appLB/ptmp;

  if ( ctLL >  1 ) ctLL =  1;
  if ( ctLL < -1 ) ctLL = -1;
    
  double pLB[4] = {El,0,0,0};
  double pNB[4] = {pWB[0]-El,0,0,0};

  for (j=1;j<4;j++) {
    pLB[j] = pLW[j] + (ctLL*ptmp - ctL*apLW)/apWB*pWB[j];
    pNB[j] = pWB[j] - pLB[j];
  }

  p4.set(pLB[0],pLB[1],pLB[2],pLB[3]);
  lepton->init( getDaug(1), p4);

  p4.set(pNB[0],pNB[1],pNB[2],pNB[3]);
  neutrino->init( getDaug(2), p4);

  return ;
}


double EvtVubHybrid::findPFermi() {

  double ranNum=EvtRandom::Flat();
  double oOverBins= 1.0/(float(_pf.size()));
  int nBinsBelow = 0;	  // largest k such that I[k] is known to be <= rand
  int nBinsAbove = _pf.size();  // largest k such that I[k] is known to be >  rand
  int middle;
  
  while (nBinsAbove > nBinsBelow+1) {
    middle = (nBinsAbove + nBinsBelow+1)>>1;
    if (ranNum >= _pf[middle]) {
      nBinsBelow = middle;
    } else {
      nBinsAbove = middle;
    }
  } 

  double bSize = _pf[nBinsAbove] - _pf[nBinsBelow];
  // binMeasure is always aProbFunc[nBinsBelow], 
  
  if ( bSize == 0 ) { 
    // rand lies right in a bin of measure 0.  Simply return the center
    // of the range of that bin.  (Any value between k/N and (k+1)/N is 
    // equally good, in this rare case.)
    return (nBinsBelow + .5) * oOverBins;
  }
  
  double bFract = (ranNum - _pf[nBinsBelow]) / bSize;
  
  return (nBinsBelow + bFract) * oOverBins;

} 


double EvtVubHybrid::getWeight(double mX, double q2, double El) {

  int ibin_mX = -1;
  int ibin_q2 = -1;
  int ibin_El = -1;

  for (int i = 0; i < _nbins_mX; i++) {
    if (mX >= _bins_mX[i]) ibin_mX = i;
  }
  for (int i = 0; i < _nbins_q2; i++) {
    if (q2 >= _bins_q2[i]) ibin_q2 = i;
  }
  for (int i = 0; i < _nbins_El; i++) {
    if (El >= _bins_El[i]) ibin_El = i;
  }
  int ibin = ibin_mX + ibin_q2*_nbins_mX + ibin_El*_nbins_mX*_nbins_q2;

  if ( (ibin_mX < 0) || (ibin_q2 < 0) || (ibin_El < 0) ) {
    report(ERROR,"EvtVubHybrid") << "Cannot determine hybrid weight "
                                 << "for this event " 
				 << "-> assign weight = 0" << endl;
    return 0.0;
  }

  return _weights[ibin];
}


void EvtVubHybrid::readWeights(int startArg) {
  _weights  = new double[_nbins];

  double maxw = 0.0;
  for (int i = 0; i < _nbins; i++, startArg++) {
    _weights[i] = getArg(startArg);
    if (_weights[i] > maxw) maxw = _weights[i];
  }

  if (maxw == 0) {
    report(ERROR,"EvtVubHybrid") << "EvtVub generator expected at least one " 
				 << " weight > 0, but found none! " 
				 << "Will terminate execution!"<<endl;
    ::abort();
  }

  // rescale weights (to be in range 0..1)
  for (int i = 0; i < _nbins; i++) {
    _weights[i] /= maxw;
  }
}
Commit	Line	Data
da0e9ce3	1	//---------------------------------------------------------------------------
	2	//
	3	// Environment:
	4	// This software is part of the EvtGen package developed jointly
	5	// for the BaBar and CLEO collaborations. If you use all or part
	6	// of it, please give an appropriate acknowledgement.
	7	//
	8	// Copyright Information:
	9	// Copyright (C) 1998 Caltech, UCSB
	10	//
	11	// Module: EvtVubHybrid.cc
	12	//
	13	// Description: Routine to decay a particle according to phase space.
	14	//
	15	// Modification history:
	16	//
	17	// Jochen Dingfelder February 1, 2005 Created Module as update of the
	18	// original module EvtVub by Sven Menke
	19	//---------------------------------------------------------------------------
	20	//
	21	#include "EvtGenBase/EvtPatches.hh"
	22	#include <stdlib.h>
	23	#include "EvtGenBase/EvtParticle.hh"
	24	#include "EvtGenBase/EvtGenKine.hh"
	25	#include "EvtGenBase/EvtPDL.hh"
	26	#include "EvtGenBase/EvtReport.hh"
	27	#include "EvtGenModels/EvtVubHybrid.hh"
	28	#include "EvtGenBase/EvtVector4R.hh"
	29	#include "EvtGenModels/EvtPFermi.hh"
	30	#include "EvtGenModels/EvtVubdGamma.hh"
	31	#include "EvtGenBase/EvtRandom.hh"
	32
	33	#include <string>
	34	#include <iostream>
	35	#include <fstream>
	36	using std::ifstream;
	37	using std::cout;
	38	using std::endl;
	39
	40
	41	// _noHybrid will be set TRUE if the DECAY.DEC file has no binning or weights
	42	// _storeQplus should alwasy be TRUE: writes out Fermi motion parameter
	43
	44	EvtVubHybrid::EvtVubHybrid()
	45	: _noHybrid(false), _storeQplus(true),
	46	_mb(4.62), _a(2.27), _alphas(0.22), _dGMax(3.),
	47	_nbins_mX(0), _nbins_q2(0), _nbins_El(0), _nbins(0),
	48	_masscut(0.28), _bins_mX(0), _bins_q2(0), _bins_El(0),
	49	_weights(0), _dGamma(0)
	50	{}
	51
	52	EvtVubHybrid::~EvtVubHybrid() {
	53	delete _dGamma;
	54	delete [] _bins_mX;
	55	delete [] _bins_q2;
	56	delete [] _bins_El;
	57	delete [] _weights;
	58
	59	}
	60
	61	std::string EvtVubHybrid::getName(){
	62
	63	return "VUBHYBRID";
	64
65	}
66
67	EvtDecayBase* EvtVubHybrid::clone(){
68
69	return new EvtVubHybrid;
70
71	}
72
73	void EvtVubHybrid::init(){
74
75	// check that there are at least 3 arguments
76	if (getNArg() < EvtVubHybrid::nParameters) {
77	report(ERROR,"EvtVubHybrid") << "EvtVub generator expected "
78	<< "at least " << EvtVubHybrid::nParameters
79	<< " arguments but found: " << getNArg()
80	<< "\nWill terminate execution!"<<endl;
81	::abort();
82	} else if (getNArg() == EvtVubHybrid::nParameters) {
83	report(WARNING,"EvtVubHybrid") << "EvtVub: generate B -> Xu l nu events "
84	<< "without using the hybrid reweighting."
85	<< endl;
86	_noHybrid = true;
87	} else if (getNArg() < EvtVubHybrid::nParameters+EvtVubHybrid::nVariables) {
88	report(ERROR,"EvtVubHybrid") << "EvtVub could not read number of bins for "
89	<< "all variables used in the reweighting\n"
90	<< "Will terminate execution!" << endl;
91	::abort();
92	}
93
94	// check that there are 3 daughters
95	checkNDaug(3);
96
97	// read minimum required parameters from decay.dec
98	_mb = getArg(0);
99	_a = getArg(1);
100	_alphas = getArg(2);
101
102	// the maximum dGamma*p2 value depends on alpha_s only:
103	const double dGMax0 = 3.;
104	_dGMax = 0.21344+8.905*_alphas;
105	if ( _dGMax < dGMax0 ) _dGMax = dGMax0;
106
107	// for the Fermi Motion we need a B-Meson mass - but it's not critical
108	// to get an exact value; in order to stay in the phase space for
109	// B+- and B0 use the smaller mass
110
111	static double mB0 = EvtPDL::getMaxMass(EvtPDL::getId("B0"));
112	static double mBP = EvtPDL::getMaxMass(EvtPDL::getId("B+"));
113	static double mB = (mB0<mBP?mB0:mBP);
114
115	const double xlow = -_mb;
116	const double xhigh = mB-_mb;
117	const int aSize = 10000;
118
119	EvtPFermi pFermi(_a,mB,_mb);
120	// pf is the cumulative distribution normalized to 1.
121	_pf.resize(aSize);
122	for(int i=0;i<aSize;i++){
123	double kplus = xlow + (double)(i+0.5)/((double)aSize)*(xhigh-xlow);
124	if ( i== 0 )
125	_pf[i] = pFermi.getFPFermi(kplus);
126	else
127	_pf[i] = _pf[i-1] + pFermi.getFPFermi(kplus);
128	}
129	for (size_t index=0; index<_pf.size(); index++) {
130	_pf[index]/=_pf[_pf.size()-1];
131	}
132
133	_dGamma = new EvtVubdGamma(_alphas);
134
135	if (_noHybrid) return; // Without hybrid weighting, nothing else to do
136
137	_nbins_mX = abs((int)getArg(3));
138	_nbins_q2 = abs((int)getArg(4));
139	_nbins_El = abs((int)getArg(5));
140
141	int nextArg = EvtVubHybrid::nParameters + EvtVubHybrid::nVariables;
142
143	_nbins = _nbins_mX_nbins_q2_nbins_El; // Binning of weight table
144
145	int expectArgs = nextArg + _nbins_mX +_nbins_q2 + _nbins_El + _nbins;
146
147	if (getNArg() < expectArgs) {
148	report(ERROR,"EvtVubHybrid")
149	<< " finds " << getNArg() << " arguments, expected " << expectArgs
150	<< ". Something is wrong with the tables of weights or thresholds."
151	<< "\nWill terminate execution!" << endl;
152	::abort();
153	}
154
155	// read bin boundaries from decay.dec
156	int i;
157
158	_bins_mX = new double[_nbins_mX];
159	for (i = 0; i < _nbins_mX; i++,nextArg++) {
160	_bins_mX[i] = getArg(nextArg);
161	}
162	_masscut = _bins_mX[0];
163
164	_bins_q2 = new double[_nbins_q2];
165	for (i = 0; i < _nbins_q2; i++,nextArg++) {
166	_bins_q2[i] = getArg(nextArg);
167	}
168
169	_bins_El = new double[_nbins_El];
170	for (i = 0; i < _nbins_El; i++,nextArg++) {
171	_bins_El[i] = getArg(nextArg);
172	}
173
174	// read in weights (and rescale to range 0..1)
175	readWeights(nextArg);
176	}
177
178	void EvtVubHybrid::initProbMax(){
179	noProbMax();
180	}
181
182	void EvtVubHybrid::decay( EvtParticle *p ){
183
184	int j;
185	// B+ -> u-bar specflav l+ nu
186
187	EvtParticle xuhad, lepton, *neutrino;
188	EvtVector4R p4;
189	// R. Faccini 21/02/03
190	// move the reweighting up , before also shooting the fermi distribution
191	double x,z,p2;
192	double sh=0.0;
193	double mB,ml,xlow,xhigh,qplus;
194	double El=0.0;
195	double Eh=0.0;
196	double kplus;
197	double q2, mX;
198
199	const double lp2epsilon=-10;
200	bool rew(true);
201	while(rew){
202
203	p->initializePhaseSpace(getNDaug(),getDaugs());
204
205	xuhad=p->getDaug(0);
206	lepton=p->getDaug(1);
207	neutrino=p->getDaug(2);
208
209	mB = p->mass();
210	ml = lepton->mass();
211
212	xlow = -_mb;
213	xhigh = mB-_mb;
214
215	// Fermi motion does not need to be computed inside the
216	// tryit loop as m_b in Gamma0 does not need to be replaced by (m_b+kplus).
217	// The difference however should be of the Order (lambda/m_b)^2 which is
218	// beyond the considered orders in the paper anyway ...
219
220	// for alpha_S = 0 and a mass cut on X_u not all values of kplus are
221	// possible. The maximum value is mB/2-_mb + sqrt(mB^2/4-_masscut^2)
222	kplus = 2*xhigh;
223
224	while( kplus >= xhigh \|\| kplus <= xlow
225	\|\| (_alphas == 0 && kplus >= mB/2-_mb
226	+ sqrt(mBmB/4-_masscut_masscut))) {
227	kplus = findPFermi(); //_pFermi->shoot();
228	kplus = xlow + kplus*(xhigh-xlow);
229	}
230	qplus = mB-_mb-kplus;
231	if( (mB-qplus)/2.<=ml) continue;
232
233	int tryit = 1;
234	while (tryit) {
235
236	x = EvtRandom::Flat();
237	z = EvtRandom::Flat(0,2);
238	p2=EvtRandom::Flat();
239	p2 = pow(10,lp2epsilon*p2);
240
241	El = x*(mB-qplus)/2;
242	if ( El > ml && El < mB/2) {
243
244	Eh = z*(mB-qplus)/2+qplus;
245	if ( Eh > 0 && Eh < mB ) {
246
247	sh = p2pow(mB-qplus,2)+2qplus(Eh-qplus)+qplusqplus;
248	if ( sh > _masscut*_masscut
249	&& mBmB + sh - 2mBEh > mlml) {
250
251	double xran = EvtRandom::Flat();
252
253	double y = _dGamma->getdGdxdzdp(x,z,p2)/_dGMax*p2;
254
255	if ( y > 1 ) report(WARNING,"EvtVubHybrid") <<"EvtVubHybrid decay probability > 1 found: " << y << endl;
256	if ( y >= xran ) tryit = 0;
257	}
258	}
259	}
260	}
261
262	// compute all kinematic variables needed for reweighting (J. Dingfelder)
263	mX = sqrt(sh);
264	q2 = mBmB + sh - 2mB*Eh;
265
266	// Reweighting in bins of mX, q2, El (J. Dingfelder)
267	if (_nbins>0) {
268	double xran1 = EvtRandom::Flat();
269	double w = 1.0;
270	if (!_noHybrid) w = getWeight(mX, q2, El);
271	if ( w >= xran1 ) rew = false;
272	}
273	else {
274	rew = false;
275	}
276	}
277
278	// o.k. we have the three kineamtic variables
279	// now calculate a flat cos Theta_H [-1,1] distribution of the
280	// hadron flight direction w.r.t the B flight direction
281	// because the B is a scalar and should decay isotropic.
282	// Then chose a flat Phi_H [0,2Pi] w.r.t the B flight direction
283	// and and a flat Phi_L [0,2Pi] in the W restframe w.r.t the
284	// W flight direction.
285
286	double ctH = EvtRandom::Flat(-1,1);
287	double phH = EvtRandom::Flat(0,2*M_PI);
288	double phL = EvtRandom::Flat(0,2*M_PI);
289
290	// now compute the four vectors in the B Meson restframe
291
292	double ptmp,sttmp;
293	// calculate the hadron 4 vector in the B Meson restframe
294
295	sttmp = sqrt(1-ctH*ctH);
296	ptmp = sqrt(Eh*Eh-sh);
297	double pHB[4] = {Eh,ptmpsttmpcos(phH),ptmpsttmpsin(phH),ptmp*ctH};
298	p4.set(pHB[0],pHB[1],pHB[2],pHB[3]);
299	xuhad->init( getDaug(0), p4);
300
301	if (_storeQplus ) {
302	// cludge to store the hidden parameter q+ with the decay;
303	// the lifetime of the Xu is abused for this purpose.
304	// tau = 1 ps corresponds to ctau = 0.3 mm -> in order to
305	// stay well below BaBars sensitivity we take q+/(10000 GeV) which
306	// goes up to 0.0005 in the most extreme cases as ctau in mm.
307	// To extract q+ back from the StdHepTrk its necessary to get
308	// delta_ctau = Xu->anyDaughter->getVertexTime()-Xu->getVertexTime()
309	// where these pseudo calls refere to the StdHep time stored at
310	// the production vertex in the lab for each particle. The boost
311	// has to be reversed and the result is:
312	//
313	// q+ = delta_ctau * 10000 GeV/mm * Mass_Xu/Energy_Xu
314	//
315	xuhad->setLifetime(qplus/10000.);
316	}
317
318	// calculate the W 4 vector in the B Meson restrframe
319
320	double apWB = ptmp;
321	double pWB[4] = {mB-Eh,-pHB[1],-pHB[2],-pHB[3]};
322
323	// first go in the W restframe and calculate the lepton and
324	// the neutrino in the W frame
325
326	double mW2 = mBmB + sh - 2mB*Eh;
327	double beta = ptmp/pWB[0];
328	double gamma = pWB[0]/sqrt(mW2);
329
330	double pLW[4];
331
332	ptmp = (mW2-ml*ml)/2/sqrt(mW2);
333	pLW[0] = sqrt(mlml + ptmpptmp);
334
335	double ctL = (El - gamma*pLW[0])/beta/gamma/ptmp;
336	if ( ctL < -1 ) ctL = -1;
337	if ( ctL > 1 ) ctL = 1;
338	sttmp = sqrt(1-ctL*ctL);
339
340	// eX' = eZ x eW
341	double xW[3] = {-pWB[2],pWB[1],0};
342	// eZ' = eW
343	double zW[3] = {pWB[1]/apWB,pWB[2]/apWB,pWB[3]/apWB};
344
345	double lx = sqrt(xW[0]xW[0]+xW[1]xW[1]);
346	for (j=0;j<2;j++)
347	xW[j] /= lx;
348
349	// eY' = eZ' x eX'
350	double yW[3] = {-pWB[1]pWB[3],-pWB[2]pWB[3],pWB[1]pWB[1]+pWB[2]pWB[2]};
351	double ly = sqrt(yW[0]yW[0]+yW[1]yW[1]+yW[2]*yW[2]);
352	for (j=0;j<3;j++)
353	yW[j] /= ly;
354
355	// p_lep = \|p_lep\| * ( sin(Theta) * cos(Phi) * eX'
356	// + sin(Theta) * sin(Phi) * eY'
357	// + cos(Theta) * eZ')
358	for (j=0;j<3;j++)
359	pLW[j+1] = sttmpcos(phL)ptmp*xW[j]
360	+ sttmpsin(phL)ptmp*yW[j]
361	+ ctL ptmpzW[j];
362
363	double apLW = ptmp;
364	// calculate the neutrino 4 vector in the W restframe
365	//double pNW[4] = {sqrt(mW2)-pLW[0],-pLW[1],-pLW[2],-pLW[3]};
366
367	// boost them back in the B Meson restframe
368
369	double appLB = betagammapLW[0] + gammactLapLW;
370
371	ptmp = sqrt(ElEl-mlml);
372	double ctLL = appLB/ptmp;
373
374	if ( ctLL > 1 ) ctLL = 1;
375	if ( ctLL < -1 ) ctLL = -1;
376
377	double pLB[4] = {El,0,0,0};
378	double pNB[4] = {pWB[0]-El,0,0,0};
379
380	for (j=1;j<4;j++) {
381	pLB[j] = pLW[j] + (ctLLptmp - ctLapLW)/apWB*pWB[j];
382	pNB[j] = pWB[j] - pLB[j];
383	}
384
385	p4.set(pLB[0],pLB[1],pLB[2],pLB[3]);
386	lepton->init( getDaug(1), p4);
387
388	p4.set(pNB[0],pNB[1],pNB[2],pNB[3]);
389	neutrino->init( getDaug(2), p4);
390
391	return ;
392	}
393
394
395	double EvtVubHybrid::findPFermi() {
396
397	double ranNum=EvtRandom::Flat();
398	double oOverBins= 1.0/(float(_pf.size()));
399	int nBinsBelow = 0; // largest k such that I[k] is known to be <= rand
400	int nBinsAbove = _pf.size(); // largest k such that I[k] is known to be > rand
401	int middle;
402
403	while (nBinsAbove > nBinsBelow+1) {
404	middle = (nBinsAbove + nBinsBelow+1)>>1;
405	if (ranNum >= _pf[middle]) {
406	nBinsBelow = middle;
407	} else {
408	nBinsAbove = middle;
409	}
410	}
411
412	double bSize = _pf[nBinsAbove] - _pf[nBinsBelow];
413	// binMeasure is always aProbFunc[nBinsBelow],
414
415	if ( bSize == 0 ) {
416	// rand lies right in a bin of measure 0. Simply return the center
417	// of the range of that bin. (Any value between k/N and (k+1)/N is
418	// equally good, in this rare case.)
419	return (nBinsBelow + .5) * oOverBins;
420	}
421
422	double bFract = (ranNum - _pf[nBinsBelow]) / bSize;
423
424	return (nBinsBelow + bFract) * oOverBins;
425
426	}
427
428
429	double EvtVubHybrid::getWeight(double mX, double q2, double El) {
430
431	int ibin_mX = -1;
432	int ibin_q2 = -1;
433	int ibin_El = -1;
434
435	for (int i = 0; i < _nbins_mX; i++) {
436	if (mX >= _bins_mX[i]) ibin_mX = i;
437	}
438	for (int i = 0; i < _nbins_q2; i++) {
439	if (q2 >= _bins_q2[i]) ibin_q2 = i;
440	}
441	for (int i = 0; i < _nbins_El; i++) {
442	if (El >= _bins_El[i]) ibin_El = i;
443	}
444	int ibin = ibin_mX + ibin_q2_nbins_mX + ibin_El_nbins_mX*_nbins_q2;
445
446	if ( (ibin_mX < 0) \|\| (ibin_q2 < 0) \|\| (ibin_El < 0) ) {
447	report(ERROR,"EvtVubHybrid") << "Cannot determine hybrid weight "
448	<< "for this event "
449	<< "-> assign weight = 0" << endl;
450	return 0.0;
451	}
452
453	return _weights[ibin];
454	}
455
456
457	void EvtVubHybrid::readWeights(int startArg) {
458	_weights = new double[_nbins];
459
460	double maxw = 0.0;
461	for (int i = 0; i < _nbins; i++, startArg++) {
462	_weights[i] = getArg(startArg);
463	if (_weights[i] > maxw) maxw = _weights[i];
464	}
465
466	if (maxw == 0) {
467	report(ERROR,"EvtVubHybrid") << "EvtVub generator expected at least one "
468	<< " weight > 0, but found none! "
469	<< "Will terminate execution!"<<endl;
470	::abort();
471	}
472
473	// rescale weights (to be in range 0..1)
474	for (int i = 0; i < _nbins; i++) {
475	_weights[i] /= maxw;
476	}
477	}