Esempio n. 1
0
ATOOLS::Vec4D_Vector II_Dipole::GeneratePoint
(const ATOOLS::Vec4D_Vector &p,Cut_Data *const cuts,const double *rns)
{
  DEBUG_FUNC("");
  // massless x- and v-bounds so far
  double *rn(p_vegas->GeneratePoint(rns));
  if (m_ijt==0) m_xmin=p[m_ijt].PPlus()/rpa->gen.PBeam(0).PPlus();
  else m_xmin=p[m_ijt].PMinus()/rpa->gen.PBeam(1).PMinus();
  msg_Debugging()<<"vegased :     ";
  msg_Debugging()<<"x = "<<rn[0]<<", v = "<<rn[1]
                 <<", phi = "<<rn[2]<<", xmin = "<<m_xmin<<"\n";
  m_rn[0]=Channel_Basics::PeakedDist(0.0,m_xexp,m_xmin,1.0-m_amin,1,rn[0]);
  m_rn[1]=Channel_Basics::PeakedDist(0.0,m_vexp,m_amin,1.0-m_rn[0],1,rn[1]);
  m_rn[2]=rn[2]*2.0*M_PI;
  msg_Debugging()<<"transformed : ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", v = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<"\n";
  Vec4D_Vector pp(p.size()+1);
  for (size_t i(0);i<p.size();++i) pp[m_brmap[i]]=p[i];
  if (m_rn[1]>1.-m_rn[0]) {
    msg_Error()<<METHOD<<"(): v > 1-x, "<<m_rn[1]
	       <<" vs. "<<1.0-m_rn[0]<<"\n";
    m_rn[1]=(1.0-1.0e-6)*(1.0-m_rn[0]);
  }
  Construct(pp[m_sub.m_i],pp[m_sub.m_j],pp[m_sub.m_k],pp,
            m_rn[0],m_rn[1],m_rn[2],p[m_ijt],p[m_kt],p);
  return pp;
}
Esempio n. 2
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ATOOLS::Vec4D_Vector IF_Dipole::GeneratePoint
(const ATOOLS::Vec4D_Vector &p,Cut_Data *const cuts,const double *rns)
{
  DEBUG_FUNC("");
  double *rn(p_vegas->GeneratePoint(rns));
  if (m_ijt==0) m_xmin=p[m_ijt].PPlus()/rpa->gen.PBeam(0).PPlus();
  else m_xmin=p[m_ijt].PMinus()/rpa->gen.PBeam(1).PMinus();
  msg_Debugging()<<"vegased :     ";
  msg_Debugging()<<"x = "<<rn[0]<<", u = "<<rn[1]
                 <<", phi = "<<rn[2]<<", xmin = "<<m_xmin<<"\n";
  m_rn[0]=Channel_Basics::PeakedDist(0.0,m_xexp,m_xmin,1.0,1,rn[0]);
  double umax((1.0-m_rn[0])/(1.0-m_rn[0]+m_rn[0]*m_mk2/(2.0*p[m_ijt]*p[m_kt])));
  m_rn[1]=Channel_Basics::PeakedDist(0.0,m_uexp,m_amin,umax,1,rn[1]);
  m_rn[2]=rn[2]*2.0*M_PI;
  msg_Debugging()<<"transformed : ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", u = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<"\n";
  Vec4D_Vector pp(p.size()+1);
  for (size_t i(0);i<p.size();++i) pp[m_brmap[i]]=p[i];
  Kin_Args ifp(m_rn[1],m_rn[0],m_rn[2],1);
  if (ConstructIFDipole(0.0,0.0,0.0,m_mk2,0.0,
			p[m_ijt],p[m_kt],Vec4D(),ifp)<0)
    msg_Error()<<METHOD<<"(): Invalid kinematics"<<std::endl;
  pp[m_sub.m_i]=ifp.m_pi;
  pp[m_sub.m_j]=ifp.m_pj;
  pp[m_sub.m_k]=ifp.m_pk;
  if (m_ijt!=m_sub.m_i) {
    for (size_t i(0);i<pp.size();++i) pp[i]=Rotate(pp[i]);
  }
  return pp;
}
Esempio n. 3
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double FI_Dipole::GenerateWeight
(const ATOOLS::Vec4D_Vector &p,Cut_Data *const cuts)
{
  Vec4D_Vector pp(p.size()-1);
  for (size_t i(0);i<p.size();++i) pp[m_rbmap[i]]=p[i];
  Kin_Args fi(ClusterFIDipole(m_mi2,m_mj2,m_mij2,0.0,
			      p[m_sub.m_i],p[m_sub.m_j],p[m_sub.m_k],1));
  if (fi.m_stat!=1) msg_Error()<<METHOD<<"(): Invalid kinematics"<<std::endl;
  m_rn[0]=1.0-fi.m_y;
  m_rn[1]=fi.m_z;
  m_rn[2]=fi.m_phi;
  pp[m_ijt]=fi.m_pi;
  pp[m_kt]=fi.m_pk;
  double Q2(2.0*pp[m_ijt]*pp[m_kt]);
  if (!ValidPoint(pp)) return m_weight=m_rbweight=0.0;
  if (m_rn[2]<0.0) m_rn[2]+=2.0*M_PI;
  if (m_kt==0) m_xmin=pp[m_kt].PPlus()/rpa->gen.PBeam(0).PPlus();
  else m_xmin=pp[m_kt].PMinus()/rpa->gen.PBeam(1).PMinus();
  msg_Debugging()<<"again :       ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", z = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<"\n";
  if (m_rn[0]<m_xmin || m_rn[0]>1.0-m_amin) {
    m_rbweight=m_weight=0.0;
    return 0.0;
  }
  if (m_bmcw) {
    p_fsmc->GenerateWeight(&pp.front(),cuts);
    m_isrspkey[3]=(pp[0]+pp[1]).Abs2();
    m_isrykey[2]=(pp[0]+pp[1]).Y();
    p_ismc->GenerateWeight(m_isrmode);
  }
  m_weight=Q2/(16.0*sqr(M_PI))/sqr(m_rn[0]);
  m_weight*=pow(m_rn[0],m_xexp)*pow(m_rn[1],m_zexp);
  if (!m_massive) {
    m_weight*=Channel_Basics::PeakedWeight
      (0.0,m_xexp,m_xmin,1.0-m_amin,m_rn[0],1,m_rn[0]);
    m_weight*=Channel_Basics::PeakedWeight
      (0.0,m_zexp,0.0,1.0,m_rn[1],1,m_rn[1]);
  }
  else {
    double eps((1-m_rn[0])*Q2+m_rn[0]*(m_mij2+m_mi2-m_mj2));
    double kap(sqrt(sqr(eps-2.0*m_rn[0]*m_mi2)-4.0*m_mi2*m_mj2));
    double zmin(0.5*(eps-kap)/((1-m_rn[0])*Q2+m_rn[0]*m_mij2));
    double zmax(0.5*(eps+kap)/((1-m_rn[0])*Q2+m_rn[0]*m_mij2));
    if (zmax>1.0 && IsEqual(zmax,1.0)) zmax=1.0;
    m_weight*=Channel_Basics::PeakedWeight
      (0.0,m_xexp,m_xmin,1.0-m_amin,m_rn[0],1,m_rn[0]);
    m_weight*=Channel_Basics::PeakedWeight
      (0.0,m_zexp,zmin,zmax,m_rn[1],1,m_rn[1]);
  }
  m_rn[2]/=2.0*M_PI;
  msg_Debugging()<<"recovered :   ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", z = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<", xmin = "<<m_xmin<<"\n";
  m_rbweight=m_weight*=p_vegas->GenerateWeight(m_rn);
  if (!m_bmcw) return m_weight;
  return m_weight*=p_fsmc->Weight()*p_ismc->Weight();
}
Esempio n. 4
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double AMEGIC::Single_Process_External::DSigma(const ATOOLS::Vec4D_Vector &_moms,bool lookup)
{
  m_lastxs = 0.;
  if (p_partner == this) {
    m_lastxs = m_Norm * operator()((ATOOLS::Vec4D*)&_moms.front());
  }
  else {
    if (lookup && p_partner->m_lookup)
      m_lastxs = p_partner->LastXS()*m_sfactor;
    else m_lastxs = m_Norm * p_partner->operator()((ATOOLS::Vec4D*)&_moms.front())*m_sfactor;
  }
  return m_lastxs;
}
Esempio n. 5
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double Decay_Channel::Differential(ATOOLS::Vec4D_Vector& momenta, bool anti,
                                   METOOLS::Spin_Density* sigma,
                                   const std::vector<ATOOLS::Particle*>& p)
{
  Poincare labboost(momenta[0]);
  labboost.Boost(momenta[0]);
  Channels()->GeneratePoint(&momenta.front(),NULL);
  Channels()->GenerateWeight(&momenta.front(),NULL);
  
  labboost.Invert();
  for (size_t i(0); i<momenta.size(); ++i) labboost.Boost(momenta[i]);
  double dsigma_lab=ME2(momenta, anti, sigma, p);
  return dsigma_lab*Channels()->Weight();
}
Esempio n. 6
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void Comix1to3::Calculate(const ATOOLS::Vec4D_Vector& momenta, bool anti) {
  DEBUG_FUNC(momenta.size());
  p_ci->GeneratePoint();
  if (anti) {
    for (size_t i(0);i<m_anticur.size();++i) {
      m_anticur[i]->ConstructJ(i==0?-momenta[i]:momenta[i],0,p_ci->I()[i],p_ci->J()[i],0);
      m_anticur[i]->Print();
    }
    m_antiscur->Evaluate();
    m_antifcur->Evaluate();
  }
  else {
    for (size_t i(0);i<m_cur.size();++i) {
      m_cur[i]->ConstructJ(i==0?-momenta[i]:momenta[i],0,p_ci->I()[i],p_ci->J()[i],0);
      m_cur[i]->Print();
    }
    m_scur->Evaluate();
    m_fcur->Evaluate();
  }


  vector<int> fill(m_n,1);
  for (size_t i(0);i<m_n;++i) (*this)[i]=Complex(0.0,0.0);
  if (anti) {
    m_antifcur->Contract<double>(*m_anticur.front(),fill,*this,0);
  }
  else {
    m_fcur->Contract<double>(*m_cur.front(),fill,*this,0);
  }

  for (size_t i=0; i<size(); ++i) {
    (*this)[i] *= sqrt(p_ci->GlobalWeight());
  }
}
Esempio n. 7
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double AMEGIC::Single_Process_MHV::DSigma(const ATOOLS::Vec4D_Vector &_moms,bool lookup)
{
  m_lastxs = 0.;
  if (m_nin==2) {
    for (size_t i=0;i<m_nin+m_nout;i++) {
      if (_moms[i][0]<m_flavs[i].Mass()) return 0.0;
    }
  }
  if (m_nin==1) {
    for (size_t i=m_nin;i<m_nin+m_nout;i++) {
      if (_moms[i][0]<m_flavs[i].Mass()) return 0.0;
    }
  }
  if (p_partner == this) {
    m_lastxs = m_Norm * operator()((ATOOLS::Vec4D*)&_moms.front());
  }
  else {
    if (lookup && p_partner->m_lookup) m_lastxs = p_partner->LastXS()*m_sfactor;
    else m_lastxs = m_Norm * p_partner->operator()((ATOOLS::Vec4D*)&_moms.front())*m_sfactor;
  }
  return m_lastxs;
}
Esempio n. 8
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ATOOLS::Vec4D_Vector FI_Dipole::GeneratePoint
(const ATOOLS::Vec4D_Vector &p,Cut_Data *const cuts,const double *rns)
{
  DEBUG_FUNC("");
  double *rn(p_vegas->GeneratePoint(rns));
  msg_Debugging()<<"vegased :     ";
  if (m_kt==0) m_xmin=p[m_kt].PPlus()/rpa->gen.PBeam(0).PPlus();
  else m_xmin=p[m_kt].PMinus()/rpa->gen.PBeam(1).PMinus();
  msg_Debugging()<<"x = "<<rn[0]<<", z = "<<rn[1]
                 <<", phi = "<<rn[2]<<", xmin = "<<m_xmin<<"\n";
  if (!m_massive) {
    m_rn[0]=Channel_Basics::PeakedDist(0.0,m_xexp,m_xmin,1.0-m_amin,1,rn[0]);
    m_rn[1]=Channel_Basics::PeakedDist(0.0,m_zexp,0.0,1.0,1,rn[1]);
  }
  else {
    double Q2(2.0*p[m_ijt]*p[m_kt]);
    m_rn[0]=Channel_Basics::PeakedDist(0.0,m_xexp,m_xmin,1-m_amin,1,rn[0]);
    double eps((1-m_rn[0])*Q2+m_rn[0]*(m_mij2+m_mi2-m_mj2));
    double kap(sqrt(sqr(eps-2.0*m_rn[0]*m_mi2)-4.0*m_mi2*m_mj2));
    double zmin(0.5*(eps-kap)/((1-m_rn[0])*Q2+m_rn[0]*m_mij2));
    double zmax(0.5*(eps+kap)/((1-m_rn[0])*Q2+m_rn[0]*m_mij2));
    if (zmax>1.0 && IsEqual(zmax,1.0)) zmax=1.0;
    m_rn[1]=Channel_Basics::PeakedDist(0.0,m_zexp,zmin,zmax,1,rn[1]);
  }
  m_rn[2]=rn[2]*2.0*M_PI;
  msg_Debugging()<<"transformed : ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", z = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<"\n";
  Vec4D_Vector pp(p.size()+1);
  for (size_t i(0);i<p.size();++i) pp[m_brmap[i]]=p[i];
  Kin_Args fi(1.0-m_rn[0],m_rn[1],m_rn[2]);
  if (ConstructFIDipole(m_mi2,m_mj2,m_mij2,0.0,p[m_ijt],p[m_kt],fi)<0)
    msg_Error()<<METHOD<<"(): Invalid kinematics"<<std::endl;
  pp[m_sub.m_i]=fi.m_pi;
  pp[m_sub.m_j]=fi.m_pj;
  pp[m_sub.m_k]=fi.m_pk;
  return pp;
}
Esempio n. 9
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void Decay_Channel::
GenerateKinematics(ATOOLS::Vec4D_Vector& momenta, bool anti,
		   METOOLS::Spin_Density* sigma,
		   const std::vector<ATOOLS::Particle*>& parts)
{
  static std::string mname(METHOD);
  Return_Value::IncCall(mname);
  if(momenta.size()==2) {
    momenta[1]=momenta[0];
    if (sigma) {
      if (p_amps) delete p_amps;
      p_amps=new Amplitude2_Tensor(parts, 0);
    }
    return;
  }
  double value(0.);
  int trials(0);
  do {
    if(trials>10000) {
      msg_Error()<<METHOD<<"("<<Name()<<"): "
                 <<"Rejected decay kinematics 10000 times. "
                 <<"This indicates a wrong maximum. "
                 <<"Will accept kinematics."
                 <<endl;
      Return_Value::IncRetryMethod(mname);
      break;
    }
    value = Differential(momenta,anti,sigma, parts);
    if(value/m_max>1.05 && m_max>1e-30) {
      if(value/m_max>1.3) {
        msg_Info()<<METHOD<<"("<<Name()<<") warning:"<<endl
                  <<"  d\\Gamma(x)="<<value<<" > max(d\\Gamma)="<<m_max
                  <<std::endl;
      }
      m_max=value;
      Return_Value::IncRetryMethod(mname);
      break;
    }
    trials++;
  } while( ran->Get() > value/m_max );
}
Esempio n. 10
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double II_Dipole::GenerateWeight
(const ATOOLS::Vec4D_Vector &p,Cut_Data *const cuts)
{
  // massless x-/v-bounds and weight so far
  Vec4D_Vector pp(p.size()-1);
  Calculate(p[m_sub.m_i],p[m_sub.m_j],p[m_sub.m_k],p,
            m_rn[0],m_rn[1],m_rn[2],pp[m_ijt],pp[m_kt],pp);
  if (!ValidPoint(pp)) return m_weight=m_rbweight=0.0;
  if (m_rn[2]<0.0) m_rn[2]+=2.0*M_PI;
  if (m_ijt==0) m_xmin=pp[m_ijt].PPlus()/rpa->gen.PBeam(0).PPlus();
  else m_xmin=pp[m_ijt].PMinus()/rpa->gen.PBeam(1).PMinus();
  msg_Debugging()<<"again :       ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", v = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<"\n";
  if (m_rn[0]<m_xmin || m_rn[0]>1.0-m_amin ||
      m_rn[1]<m_amin || m_rn[1]>1.0-m_rn[0]) {
    m_rbweight=m_weight=0.0;
    return 0.0;
  }
  if (m_bmcw) {
    p_fsmc->GenerateWeight(&pp.front(),cuts);
    m_isrspkey[3]=(pp[0]+pp[1]).Abs2();
    m_isrykey[2]=(pp[0]+pp[1]).Y();
    p_ismc->GenerateWeight(m_isrmode);
  }
  // 2(pa*pb)/16pi^2
  m_weight=(p[m_sub.m_i]+p[m_sub.m_k]).Abs2()/
    (16.0*sqr(M_PI))/m_rn[0];
  m_weight*=pow(m_rn[1],m_vexp)*pow(m_rn[0],m_xexp);
  m_weight*=Channel_Basics::PeakedWeight
    (0.0,m_vexp,m_amin,1.0-m_rn[0],m_rn[1],1,m_rn[1]);
  m_weight*=Channel_Basics::PeakedWeight
    (0.0,m_xexp,m_xmin,1.0-m_amin,m_rn[0],1,m_rn[0]);
  m_rn[2]/=2.0*M_PI;
  msg_Debugging()<<"recovered :   ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", v = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<", xmin = "<<m_xmin<<"\n";
  m_rbweight=m_weight*=p_vegas->GenerateWeight(m_rn);
  if (!m_bmcw) return m_weight;
  return m_weight*=p_fsmc->Weight()*p_ismc->Weight();
}
Esempio n. 11
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void II_Dipole::Calculate
(const ATOOLS::Vec4D &pi, const ATOOLS::Vec4D &pj, const ATOOLS::Vec4D &pk,
 const ATOOLS::Vec4D_Vector& kj,
 double &x, double &v, double &phi,
 ATOOLS::Vec4D &pijt, ATOOLS::Vec4D &pkt,
 ATOOLS::Vec4D_Vector& kjt)
{
  double pipj(pi*pj), pipk(pi*pk), pjpk(pj*pk);
  x=(pipk-pipj-pjpk)/pipk;
  v=pipj/pipk;

  pijt=x*pi;
  pkt=pk;

  double kp(sqrt(2.*pipk*v*(1.-x-v)));
  Vec4D kperp(pj-(1.-x-v)/x*pijt-v*pkt);
  if      ((kperp[1]>=0. && kperp[2]>=0.) || (kperp[1]>=0. && kperp[2]<0.))
    phi=acos(kperp[2]/kp);
  else if ((kperp[1]<0. && kperp[2]<0.) || (kperp[1]<0. && kperp[2]>=0.))
    phi=-acos(kperp[2]/kp)+2.*M_PI;
  else THROW(fatal_error,"Could not determine phi.");

  Vec4D K(pi-pj+pk), Kt(pijt+pkt);
  ATOOLS::Lorentz_Ten2D Lambda = MetricTensor()
                                 - 2./(K+Kt).Abs2()*BuildTensor(Kt+K,Kt+K)
                                 + 2./Kt.Abs2()*BuildTensor(Kt,K);

  pijt=Rotate(pijt);
  pkt=Rotate(pkt);

  for (size_t j(2), i(j);j<kjt.size();++i,++j) {
    if (i==m_sub.m_j) ++i;
    kjt[m_rbmap[i]] = Rotate(Contraction(Lambda,2,kj[i]));
    msg_Debugging()<<"("<<i<<"):"<<kj[i]
		   <<" -> ("<<m_rbmap[i]<<"):"<<kjt[m_rbmap[i]]<<std::endl;
  }
}
Esempio n. 12
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void II_Dipole::Construct
(ATOOLS::Vec4D &pi, ATOOLS::Vec4D &pj, ATOOLS::Vec4D &pk,
 ATOOLS::Vec4D_Vector& kj,
 const double &x, const double &v, const double &phi,
 const ATOOLS::Vec4D &ipijt, const ATOOLS::Vec4D &ipkt,
 const ATOOLS::Vec4D_Vector& kjt)
{
  DEBUG_FUNC("");
  Vec4D pijt=Rotate(ipijt);
  Vec4D pkt=Rotate(ipkt);
  pi=1./x*pijt;
  pk=pkt;

  double kp=sqrt(2.*pi*pk*v*(1.-x-v));
  Vec4D kperp(0.,sin(phi)*kp,cos(phi)*kp,0.);

  pj=(1.-x-v)/x*pijt + v*pkt + kperp;
  msg_Debugging()<<"("<<m_ijt<<"):"<<pijt
                 <<" -> ("<<m_sub.m_i<<"):"<<pi
                 <<" ("<<m_sub.m_j<<"):"<<pj<<std::endl;
  msg_Debugging()<<"("<<m_kt<<"):"<<pkt
                 <<" -> ("<<m_sub.m_k<<"):"<<pk<<std::endl;

  Vec4D K(pi-pj+pk), Kt(pijt+pkt);
  ATOOLS::Lorentz_Ten2D Lambda = MetricTensor()
                                 - 2./(K+Kt).Abs2()*BuildTensor(Kt+K,Kt+K)
                                 + 2./Kt.Abs2()*BuildTensor(K,Kt);

  for (size_t i(0);i<kjt.size();++i) {
    if (i!=m_ijt && i!=m_kt) {
      kj[m_brmap[i]] = Contraction(Lambda,2,Rotate(kjt[i]));
      msg_Debugging()<<"("<<i<<"):"<<kjt[i]
                     <<" -> ("<<m_brmap[i]<<"):"<<kj[m_brmap[i]]<<std::endl;
    }
  }
}
Esempio n. 13
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double IF_Dipole::GenerateWeight
(const ATOOLS::Vec4D_Vector &p,Cut_Data *const cuts)
{
  Vec4D_Vector pp(p.size()-1);
  for (size_t i(0);i<p.size();++i) pp[m_rbmap[i]]=p[i];
  if (m_ijt==m_sub.m_i) {
    Kin_Args ifp(ClusterIFDipole
		(0.0,0.0,0.0,m_mk2,0.0,
		 p[m_sub.m_i],p[m_sub.m_j],p[m_sub.m_k],Vec4D(),1|4));
    if (ifp.m_stat!=1) msg_Error()<<METHOD<<"(): Invalid kinematics"<<std::endl;
    m_rn[0]=ifp.m_z;
    m_rn[1]=ifp.m_y;
    m_rn[2]=ifp.m_phi;
    pp[m_ijt]=ifp.m_pi;
    pp[m_kt]=ifp.m_pk;
  }
  else {
    for (size_t i(0);i<pp.size();++i) pp[i]=Rotate(pp[i]);
    Kin_Args ifp(ClusterIFDipole
		(0.0,0.0,0.0,m_mk2,0.0,
		 Rotate(p[m_sub.m_i]),Rotate(p[m_sub.m_j]),
		 Rotate(p[m_sub.m_k]),Vec4D(),1|4));
    if (ifp.m_stat!=1) msg_Error()<<METHOD<<"(): Invalid kinematics"<<std::endl;
    m_rn[0]=ifp.m_z;
    m_rn[1]=ifp.m_y;
    m_rn[2]=ifp.m_phi;
    pp[m_ijt]=ifp.m_pi;
    pp[m_kt]=ifp.m_pk;
  }
  if (!ValidPoint(pp)) return m_weight=m_rbweight=0.0;
  if (m_rn[2]<0.0) m_rn[2]+=2.0*M_PI;
  if (m_ijt==0) m_xmin=pp[m_ijt].PPlus()/rpa->gen.PBeam(0).PPlus();
  else m_xmin=pp[m_ijt].PMinus()/rpa->gen.PBeam(1).PMinus();
  msg_Debugging()<<"again :       ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", u = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<"\n";
  if (m_rn[0]<m_xmin ||
      m_rn[1]<m_amin) {
    m_rbweight=m_weight=0.0;
    return 0.0;
  }
  if (m_bmcw) {
    p_fsmc->GenerateWeight(&pp.front(),cuts);
    m_isrspkey[3]=(pp[0]+pp[1]).Abs2();
    m_isrykey[2]=(pp[0]+pp[1]).Y();
    p_ismc->GenerateWeight(m_isrmode);
  }
  double Q2(2.0*pp[m_ijt]*pp[m_kt]);
  m_weight=Q2/(16.0*sqr(M_PI))/sqr(m_rn[0]);
  m_weight*=pow(m_rn[1],m_uexp)*pow(m_rn[0],m_xexp);
  double umax((1.0-m_rn[0])/(1.0-m_rn[0]+m_rn[0]*m_mk2/Q2));
  m_weight*=Channel_Basics::PeakedWeight
    (0.0,m_uexp,m_amin,umax,m_rn[1],1,m_rn[1]);
  m_weight*=Channel_Basics::PeakedWeight
    (0.0,m_xexp,m_xmin,1.0,m_rn[0],1,m_rn[0]);
  m_rn[2]/=2.0*M_PI;
  msg_Debugging()<<"recovered :   ";
  msg_Debugging()<<"x = "<<m_rn[0]<<", u = "<<m_rn[1]
                 <<", phi = "<<m_rn[2]<<", xmin = "<<m_xmin<<"\n";
  m_rbweight=m_weight*=p_vegas->GenerateWeight(m_rn);
  if (!m_bmcw) return m_weight;
  return m_weight*=p_fsmc->Weight()*p_ismc->Weight();
}