calcphirb_save_nov06.f

c       program testingphi
c       
c       implicit real(a-h,o-z)
c 
c 
c       px_spa =   1.
c       py_spa =   10.
c       pz_spa = -20.
c       e_spa  =  15.
c       
c       px_lar =  0.1
c       py_lar =  0.2
c       pz_lar = -1.
c       e_lar  =  3.
c       
c       call       calc_phir(px_spa,py_spa,pz_spa,e_spa,
c      +                     px_lar,py_lar,pz_lar,e_lar,
c      +                     empz,phi_r,iifail)    
c 
c       print *,phi_r,iifail
c       
c       end
*****************************************************************
      real function calcphirb(x,index)
*****************************************************************
      implicit real*4(a-h,o-z)

      include 'forpaw.common'
      integer index

      sm1 = 0.
      sm2 = 0.
      sm3 = 0.
      sm4 = 0.
      sm5 = 0.
      sm6 = 0.

      if (index.ge.1) then
      call smear(sm1,0.03)
      call smear(sm2,0.03)
  
      call smear(sm3,1.e-3)
      call smear(sm4,3.e-3)

      call smear(sm5,1.e-3)
      call smear(sm6,3.e-3)
      endif

      sm1 = 0.
      sm2 = 0.
      sm3 = 0.
      sm4 = 0.
      sm5 = 0.
      sm6 = 0.

      px_spa = plolab(1)*(1.+sm1)*(1.+sm3/(plolab(1)/plolab(2)))
     + *(1.-(plolab(1)/plolab(2))*sm5)
      py_spa = plolab(2)*(1.+sm1)*(1.+sm3/(plolab(1)/plolab(2)))
     + *(1.+sm5/(plolab(1)/plolab(2)))
      pz_spa = plolab(3)*(1.+sm1)*(1.-(plolab(1)/plolab(2))*sm3)
      e_spa =  plolab(4)*(1.+sm1)

      px_lar = prglab(1)*(1.+sm2)*(1.+sm4/(plolab(1)/plolab(2)))
     + *(1.-(plolab(1)/plolab(2))*sm6)
      py_lar = prglab(2)*(1.+sm2)*(1.+sm4/(plolab(1)/plolab(2)))
     + *(1.+sm6/(plolab(1)/plolab(2)))
      pz_lar = prglab(3)*(1.+sm2)*(1.-(plolab(1)/plolab(2))*sm4)
      e_lar =  prglab(4)*(1.+sm2)

c      px_spa = plolab(1)
c      py_spa = plolab(2)
c      pz_spa = plolab(3)
c      e_spa =  plolab(4)
c      px_lar = prglab(1)
c      py_lar = prglab(2)
c      pz_lar = prglab(3)
c      e_lar =  prglab(4)

      empz = e_spa-pz_spa+e_lar-pz_lar
ccc      empz = plilab(4)-plilab(3)!empz 
      
      call calcphir(px_spa,py_spa,pz_spa,e_spa,
     +                     px_lar,py_lar,pz_lar,e_lar,
     +                     empz,phi_r,iifail)
     
      calcphirb=phi_r
      
      return
      end
      
*****************************************************************
      subroutine calcphir(px_spa,py_spa,pz_spa,e_spa,
     +                     px_lar,py_lar,pz_lar,e_lar,
     +                     empz,phi_r,iifail)
*****************************************************************

      implicit real(a-h,o-z)

      double precision mp,pi,elep,eproton,shat,boostp

      integer i,iifail

      real vec1(3),vec2(3),xvec1,xvec2,term1,term2,term3

**>> INI
      real px_spa,py_spa,pz_spa,e_spa,
     +     px_lar,py_lar,pz_lar,e_lar,
     +     empz

**>> OUT
      real phi_r,asym

      real pelep, phad, p4e(4), P(4), Q(4)
      double precision dpelep, dphad, dp4e(4), dP(4), dQ(4)

      real phisegp, phiggp, phipgp
      real phi_po,phi_lo,delta_phi,phi_poprf,phi_loprf

      real       xntp,qntp,yntp,phintp,tntp,
* -> In Lab frame :
     +         plilab(4),plolab(4),ppilab(4),ppolab(4),
     +         pvglab(4),prglab(4),
     +         pvisr(4),
* -> In p rest frame :
     +         pliprf(4),ploprf(4),ppiprf(4),ppoprf(4),
     +         pvgprf(4),prgprf(4),
* -> In Belitsky frame :
     +         plibel(4),plobel(4),ppibel(4),ppobel(4),
     +         pvgbel(4),prgbel(4)

* -> Lab frame :
      double precision pli_l(4)   ! incoming lepton in lab frame
      double precision plo_l(4)   ! outcoming lepton in lab frame
      double precision pvgam_l(4) ! virtual photon in lab frame
      double precision ppi_l(4)   ! incoming proton in lab frame
      double precision ppo_l(4)   ! outcoming proton
      double precision prgam_l(4) ! outcoming photon

* -> Proton rest frame :
      double precision pli_tmp(4)   ! incoming lepton in p-rest frame
      double precision plo_tmp(4)   ! outcoming lepton in p-rest frame
      double precision pvgam_tmp(4) ! virtual photon in p-rest frame
      double precision ppi_tmp(4)   ! incoming proton in p-rest frame
      double precision ppo_tmp(4)   ! outcoming proton
      double precision prgam_tmp(4) ! outcoming photon
      double precision toto_li(4)
      double precision toto_lo(4)
      double precision toto_vgam(4)


* -> In p-rest frame, with z = - q_1^3
*    (cf fig. 1 of Belitsky et al.)
      double precision pli_b(4)   ! incoming lepton
      double precision plo_b(4)   ! outcoming lepton
      double precision pvgam_b(4) ! virtual photon
      double precision ppi_b(4)   ! incoming proton
      double precision prgam_b(4) ! outcoming (real) photon
      double precision ppo_b(4)   ! outcoming proton


      double precision beta(3),betar(3)
      double precision ptmp(4)
      double precision rot(3)

      logical do_xaxis
      common/xaxis/do_xaxis,i_xaxis

      mp = 0.93827d0
      pi = datan(1.d0) * 4.0d0

      empz_calc = empz
cc      empz_calc = e_spa-pz_spa+e_lar-pz_lar

      elep     = dble(empz_calc/2.) ! for tests...

      eproton = 920.d0
      shat    = 4.0d0 * elep * eproton

* -> incoming lepton in lab frame
      pli_l(4) =  elep
      pli_l(3) = -elep
      pli_l(1) = 0.d0
      pli_l(2) = 0.d0
      call v_copy(pli_l,plilab)

* -> incoming proton in lab frame
      ppi_l(4) = dsqrt(eproton**2 + mp**2)
      ppi_l(3) = eproton
      ppi_l(1) = 0.0d0
      ppi_l(2) = 0.0d0
      call v_copy(ppi_l,ppilab)

c      print *,'px_sp_kin,py_sp_kin,pz_sp_kin',
c     +         px_sp_kin,py_sp_kin,pz_sp_kin

* -> outcoming lepton in lab frame

      plo_l(4) = dble(e_spa)
      plo_l(1) = dble(px_spa)
      plo_l(2) = dble(py_spa)
      plo_l(3) = dble(pz_spa)

      iifail = 0

      call v_copy(plo_l,plolab)

c      print *,'plolab(1),plolab(2),',
c     +        'plolab(3),plolab(4)',
c     +         real(plolab(1)),real(plolab(2)),
c     +         real(plolab(3)),real(plolab(4))

* -> virtual photon in lab frame
      do i=1,4
       pvgam_l(i) = pli_l(i) - plo_l(i)
      enddo
      call v_copy(pvgam_l,pvglab)
     
c      print *,'pvglab(1),pvglab(2),',
c     +        'pvglab(3),pvglab(4)',
c     +         real(pvglab(1)),real(pvglab(2)),
c     +         real(pvglab(3)),real(pvglab(4))

* -> real photon in lab frame

      prgam_l(4) = dble(e_lar)
      prgam_l(1) = dble(px_lar)
      prgam_l(2) = dble(py_lar)
      prgam_l(3) = dble(pz_lar)

      call v_copy(prgam_l,prglab)

c      print *,'prglab(1),prglab(2),',
c     +        'prglab(3),prglab(4)',
c     +         real(prglab(1)),real(prglab(2)),
c     +         real(prglab(3)),real(prglab(4))
 

* -> outgoing proton in lab frame

      ppo_l(4) = ppi_l(4)+pli_l(4)-prgam_l(4)-plo_l(4)
      ppo_l(1) = ppi_l(1)+pli_l(1)-prgam_l(1)-plo_l(1)
      ppo_l(2) = ppi_l(2)+pli_l(2)-prgam_l(2)-plo_l(2)
      ppo_l(3) = ppi_l(3)+pli_l(3)-prgam_l(3)-plo_l(3)

      call v_copy(ppo_l,ppolab)

c      print *,'ppolab(1),ppolab(2),',
c     +        'ppolab(3),ppolab(4)',
c     +         real(ppolab(1)),real(ppolab(2)),
c     +         real(ppolab(3)),real(ppolab(4))

* -> calculate phi angles in lab frame...

      phi_p_lab  = atan2(ppolab(2),ppolab(1))
      phi_l_lab  = atan2(plolab(2),plolab(1))
      phi_g_lab  = atan2(prglab(2),prglab(1))
      phi_li_lab = atan2(plilab(2),plilab(1))


* -> calculate phi between po and lo in lab frame...
      dphi_lab=atan2(ppolab(2),ppolab(1))-
     +          atan2(plolab(2),plolab(1))


* --- Boost to p-rest frame, same system axis ---

      boostp = eproton / mp
      beta(1) =  -ppi_l(1) / ppi_l(4)
      beta(2) =  -ppi_l(2) / ppi_l(4)
      beta(3) =  -ppi_l(3) / ppi_l(4)

      do i=1,3
       betar(i) = -beta(i)
      enddo

* -> Boost incoming lepton
      do i=1,4
       ptmp(i)    = pli_l(i)
      enddo
      call boost(ptmp,beta)
      do i=1,4
       pli_tmp(i) = ptmp(i)
      enddo
      call v_copy(pli_tmp,pliprf)

c      print *,'pliprf(1),pliprf(2),',
c     +        'pliprf(3),pliprf(4)',
c     +         real(pliprf(1)),real(pliprf(2)),
c     +         real(pliprf(3)),real(pliprf(4))

* -> Boost outcoming lepton
      do i=1,4
       ptmp(i)    = plo_l(i)
      enddo
      call boost(ptmp,beta)
      do i=1,4
       plo_tmp(i) = ptmp(i)
      enddo
      call v_copy(plo_tmp,ploprf)

c      print *,'ploprf(1),ploprf(2),',
c     +        'ploprf(3),ploprf(4)',
c     +         real(ploprf(1)),real(ploprf(2)),
c     +         real(ploprf(3)),real(ploprf(4))

* -> Boost incoming proton
      do i=1,4
       ptmp(i)    = ppi_l(i)
      enddo
      call boost(ptmp,beta)
      do i=1,4
       ppi_tmp(i) = ptmp(i)
      enddo
      call v_copy(ppi_tmp,ppiprf)

c      print *,'ppiprf(1),ppiprf(2),',
c     +        'ppiprf(3),ppiprf(4)',
c     +         real(ppiprf(1)),real(ppiprf(2)),
c     +         real(ppiprf(3)),real(ppiprf(4))

* -> Boost virtual photon
      do i=1,4
       ptmp(i)      = pvgam_l(i)
      enddo
      call boost(ptmp,beta)
      do i=1,4
       pvgam_tmp(i) = ptmp(i)
      enddo
      call v_copy(pvgam_tmp,pvgprf)

c      print *,'pvgprf(1),pvgprf(2),',
c     +        'pvgprf(3),pvgprf(4)',
c     +         real(pvgprf(1)),real(pvgprf(2)),
c     +         real(pvgprf(3)),real(pvgprf(4))

* -> Boost real gamma
      do i=1,4
       ptmp(i)    = prgam_l(i)
      enddo
      call boost(ptmp,beta)
      do i=1,4
       prgam_tmp(i) = ptmp(i)
      enddo
      call v_copy(prgam_tmp,prgprf)

c      print *,'prgprf(1),prgprf(2),',
c     +        'prgprf(3),prgprf(4)',
c     +         real(prgprf(1)),real(prgprf(2)),
c     +         real(prgprf(3)),real(prgprf(4))

* -> Boost outgoing proton
      do i=1,4
       ptmp(i)    = ppo_l(i)
      enddo
      call boost(ptmp,beta)
      do i=1,4
       ppo_tmp(i) = ptmp(i)
      enddo
      call v_copy(ppo_tmp,ppoprf)

c      print *,'ppoprf(1),ppoprf(2),',
c     +        'ppoprf(3),ppoprf(4)',
c     +         real(ppoprf(1)),real(ppoprf(2)),
c     +         real(ppoprf(3)),real(ppoprf(4))

* -> calculate phi angles in prf frame...

      phi_p_prf  = atan2(ppoprf(2),ppoprf(1))
      phi_l_prf  = atan2(ploprf(2),ploprf(1))
      phi_g_prf  = atan2(prgprf(2),prgprf(1))
      phi_li_prf = atan2(pliprf(2),pliprf(1))

* -> calculate phi between po and lo in prf frame...

      dphi_prf=atan2(ppoprf(2),ppoprf(1))-
     +          atan2(ploprf(2),ploprf(1))


* --- all the rest is needed to go in the belitsky frame...
* --- Rotate the system axis, z = -q_1^3 ---

      do i=1,3
       rot(i) = -pvgam_tmp(i)
      enddo

c      print *,'rot(1),rot(2),rot(3)',
c     +    real(rot(1)),real(rot(2)),real(rot(3))

      do_xaxis = .true.
      i_xaxis  = 1
      call rotate(pli_tmp,rot,1,pli_b)
      do_xaxis = .false.
      call v_copy(pli_b,plibel)

c      print *,'plibel(1),plibel(2),',
c     +        'plibel(3),plibel(4)',
c     +         real(plibel(1)),real(plibel(2)),
c     +         real(plibel(3)),real(plibel(4))

      call rotate(plo_tmp,rot,1,plo_b)
      call rotate(pvgam_tmp,rot,1,pvgam_b)
      call rotate(ppi_tmp,rot,1,ppi_b)
      call rotate(ppo_tmp,rot,1,ppo_b)
      call rotate(prgam_tmp,rot,1,prgam_b)

      call v_copy(plo_b,plobel)
      call v_copy(pvgam_b,pvgbel)
      call v_copy(ppi_b,ppibel)
      call v_copy(ppo_b,ppobel)
      call v_copy(prgam_b,prgbel)

c      print *,'plobel(1),plobel(2),',
c     +        'plobel(3),plobel(4)',
c     +         real(plobel(1)),real(plobel(2)),
c     +         real(plobel(3)),real(plobel(4))

c      print *,'pvgbel(1),pvgbel(2),',
c     +        'pvgbel(3),pvgbel(4)',
c     +         real(pvgbel(1)),real(pvgbel(2)),
c     +         real(pvgbel(3)),real(pvgbel(4))

c      print *,'ppibel(1),ppibel(2),',
c     +        'ppibel(3),ppibel(4)',
c     +         real(ppibel(1)),real(ppibel(2)),
c     +         real(ppibel(3)),real(ppibel(4))


c      print *,'ppobel(1),ppobel(2),',
c     +        'ppobel(3),ppobel(4)',
c     +         real(ppobel(1)),real(ppobel(2)),
c     +         real(ppobel(3)),real(ppobel(4))

c      print *,'prgbel(1),prgbel(2),',
c     +        'prgbel(3),prgbel(4)',
c     +         real(prgbel(1)),real(prgbel(2)),
c     +         real(prgbel(3)),real(prgbel(4))


      phi_p_bel  = atan2(ppobel(2),ppobel(1))
      phi_l_bel  = atan2(plobel(2),plobel(1))
      phi_g_bel  = atan2(prgbel(2),prgbel(1))
      phi_li_bel = atan2(plibel(2),plibel(1))

      dphi_bel=atan2(ppobel(2),ppobel(1))-
     +          atan2(plobel(2),plobel(1))

* --- final angle (which should be the correct PHI)
      phi_r = phi_p_bel
     
c       write(89,*) phi_p_lab,phi_l_lab,phi_g_lab,phi_li_lab,
c      +            phi_p_prf,phi_l_prf,phi_g_prf,phi_li_prf,
c      +            phi_p_bel,phi_l_bel,phi_g_bel,phi_li_bel


 5    continue

      return 
      end