source: LMDZ4/trunk/libf/dyn3dpar/vlspltgen_p.F @ 791

!
! $Header$
!
       SUBROUTINE vlspltgen_p( q,iadv,pente_max,masse,w,pbaru,pbarv,pdt,
     ,                                  p,pk,teta                 )
c
c     Auteurs:   P.Le Van, F.Hourdin, F.Forget, F.Codron 
c
c    ********************************************************************
c          Shema  d'advection " pseudo amont " .
c      + test sur humidite specifique: Q advecte< Qsat aval
c                   (F. Codron, 10/99)
c    ********************************************************************
c     q,pbaru,pbarv,w sont des arguments d'entree  pour le s-pg ....
c
c     pente_max facteur de limitation des pentes: 2 en general
c                                                0 pour un schema amont
c     pbaru,pbarv,w flux de masse en u ,v ,w
c     pdt pas de temps
c
c     teta temperature potentielle, p pression aux interfaces,
c     pk exner au milieu des couches necessaire pour calculer Qsat
c   --------------------------------------------------------------------
      USE parallel
      USE mod_hallo
      USE Write_Field_p
      USE VAMPIR
      IMPLICIT NONE

c
#include "dimensions.h"
#include "paramet.h"
#include "logic.h"
#include "comvert.h"
#include "comconst.h"

c
c   Arguments:
c   ----------
      INTEGER iadv(nqmx)
      REAL masse(ip1jmp1,llm),pente_max
      REAL pbaru( ip1jmp1,llm ),pbarv( ip1jm,llm)
      REAL q(ip1jmp1,llm,nqmx)
      REAL w(ip1jmp1,llm),pdt
      REAL p(ip1jmp1,llmp1),teta(ip1jmp1,llm),pk(ip1jmp1,llm)
c
c      Local 
c   ---------
c
      INTEGER ij,l
c
      REAL,SAVE :: qsat(ip1jmp1,llm)
      REAL,SAVE :: zm(ip1jmp1,llm,nqmx)
      REAL,SAVE :: mu(ip1jmp1,llm)
      REAL,SAVE :: mv(ip1jm,llm)
      REAL,SAVE :: mw(ip1jmp1,llm+1)
      REAL,SAVE :: zq(ip1jmp1,llm,nqmx)
      REAL zzpbar, zzw

      REAL qmin,qmax
      DATA qmin,qmax/0.,1.e33/

c--pour rapport de melange saturant--

      REAL rtt,retv,r2es,r3les,r3ies,r4les,r4ies,play
      REAL ptarg,pdelarg,foeew,zdelta
      REAL tempe(ip1jmp1)
      INTEGER ijb,ije,iq
      type(request) :: MyRequest1
      type(request) :: MyRequest2

c    fonction psat(T)

       FOEEW ( PTARG,PDELARG ) = EXP (
     *          (R3LES*(1.-PDELARG)+R3IES*PDELARG) * (PTARG-RTT)
     * / (PTARG-(R4LES*(1.-PDELARG)+R4IES*PDELARG)) )

        r2es  = 380.11733 
        r3les = 17.269
        r3ies = 21.875
        r4les = 35.86
        r4ies = 7.66
        retv = 0.6077667
        rtt  = 273.16

c-- Calcul de Qsat en chaque point
c-- approximation: au milieu des couches play(l)=(p(l)+p(l+1))/2
c   pour eviter une exponentielle.
c$OMP MASTER
      call SetTag(MyRequest1,100)
      call SetTag(MyRequest2,101)
c$OMP END MASTER
        
        ijb=ij_begin-iip1
        ije=ij_end+iip1
        if (pole_nord) ijb=ij_begin
        if (pole_sud) ije=ij_end
        
c$OMP DO SCHEDULE(STATIC,OMP_CHUNK) 
        DO l = 1, llm
         DO ij = ijb, ije
          tempe(ij) = teta(ij,l) * pk(ij,l) /cpp
         ENDDO
         DO ij = ijb, ije
          zdelta = MAX( 0., SIGN(1., rtt - tempe(ij)) )
          play   = 0.5*(p(ij,l)+p(ij,l+1))
          qsat(ij,l) = MIN(0.5, r2es* FOEEW(tempe(ij),zdelta) / play )
          qsat(ij,l) = qsat(ij,l) / ( 1. - retv * qsat(ij,l) )
         ENDDO
        ENDDO
c$OMP END DO NOWAIT
c      PRINT*,'Debut vlsplt version debug sans vlyqs'

        zzpbar = 0.5 * pdt
        zzw    = pdt

      ijb=ij_begin
      ije=ij_end
      if (pole_nord) ijb=ijb+iip1
      if (pole_sud)  ije=ije-iip1

c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)       
      DO l=1,llm
        DO ij = ijb,ije
            mu(ij,l)=pbaru(ij,l) * zzpbar
         ENDDO
      ENDDO
c$OMP END DO NOWAIT
      
      ijb=ij_begin-iip1
      ije=ij_end
      if (pole_nord) ijb=ij_begin
      if (pole_sud)  ije=ij_end-iip1

c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
      DO l=1,llm
         DO ij=ijb,ije
            mv(ij,l)=pbarv(ij,l) * zzpbar
         ENDDO
      ENDDO
c$OMP END DO NOWAIT

      ijb=ij_begin
      ije=ij_end

c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)      
      DO l=1,llm
         DO ij=ijb,ije
            mw(ij,l)=w(ij,l) * zzw
         ENDDO
      ENDDO
c$OMP END DO NOWAIT

c$OMP MASTER
      DO ij=ijb,ije
         mw(ij,llm+1)=0.
      ENDDO
c$OMP END MASTER

c      CALL SCOPY(ijp1llm,q,1,zq,1)
c      CALL SCOPY(ijp1llm,masse,1,zm,1)

       ijb=ij_begin
       ije=ij_end

      DO iq=1,nqmx
c$OMP DO SCHEDULE(STATIC,OMP_CHUNK) 
        DO l=1,llm
          zq(ijb:ije,l,iq)=q(ijb:ije,l,iq)
          zm(ijb:ije,l,iq)=masse(ijb:ije,l)
        ENDDO
c$OMP END DO NOWAIT
      ENDDO


c$OMP BARRIER           
      DO iq=1,nqmx

        if(iadv(iq) == 0) then
        
          cycle 
        
        else if (iadv(iq)==10) then
        
          call vlx_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,
     &               ij_begin,ij_begin+2*iip1-1)
          call vlx_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,
     &               ij_end-2*iip1+1,ij_end)

c$OMP MASTER
          call VTb(VTHallo)
          call Register_Hallo(zq(1,1,iq),ip1jmp1,llm,2,2,2,2,MyRequest1)
          call Register_Hallo(zm(1,1,iq),ip1jmp1,llm,1,1,1,1,MyRequest1)
          call VTe(VTHallo)
c$OMP END MASTER
        else if (iadv(iq)==14) then
      
          call vlxqs_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,qsat,
     &                 ij_begin,ij_begin+2*iip1-1)
          call vlxqs_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,qsat,
     &                 ij_end-2*iip1+1,ij_end)
c$OMP MASTER
          call VTb(VTHallo)
          call Register_Hallo(zq(1,1,iq),ip1jmp1,llm,2,2,2,2,MyRequest1)
          call Register_Hallo(zm(1,1,iq),ip1jmp1,llm,1,1,1,1,MyRequest1)
          call VTe(VTHallo)
c$OMP END MASTER 
        else
        
          stop 'vlspltgen_p : schema non parallelise'
      
        endif
      
      enddo
      
      
c$OMP BARRIER      
c$OMP MASTER      
      call VTb(VTHallo)
      call SendRequest(MyRequest1)
      call VTe(VTHallo)
c$OMP END MASTER       
c$OMP BARRIER
      do iq=1,nqmx

        if(iadv(iq) == 0) then
        
          cycle 
        
        else if (iadv(iq)==10) then

          call vlx_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,
     &               ij_begin+2*iip1,ij_end-2*iip1)
        
        else if (iadv(iq)==14) then

          call vlxqs_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,qsat,
     &                 ij_begin+2*iip1,ij_end-2*iip1)
    
        else
        
          stop 'vlspltgen_p : schema non parallelise'
      
        endif
      
      enddo
c$OMP BARRIER      
c$OMP MASTER
      call VTb(VTHallo)
      call WaitRecvRequest(MyRequest1)
      call WaitSendRequest(MyRequest1)
      call VTe(VTHallo)
c$OMP END MASTER
c$OMP BARRIER
 
      do iq=1,nqmx

        if(iadv(iq) == 0) then
        
          cycle 
        
        else if (iadv(iq)==10) then
        
          call vly_p(zq(1,1,iq),pente_max,zm(1,1,iq),mv)
  
        else if (iadv(iq)==14) then
      
          call vlyqs_p(zq(1,1,iq),pente_max,zm(1,1,iq),mv,qsat)
 
        else
        
          stop 'vlspltgen_p : schema non parallelise'
      
        endif
       
       enddo

      do iq=1,nqmx

        if(iadv(iq) == 0) then 
          
          cycle 
        
        else if (iadv(iq)==10 .or. iadv(iq)==14 ) then

c$OMP BARRIER        
          call vlz_p(zq(1,1,iq),pente_max,zm(1,1,iq),mw,
     &               ij_begin,ij_begin+2*iip1-1)
          call vlz_p(zq(1,1,iq),pente_max,zm(1,1,iq),mw,
     &               ij_end-2*iip1+1,ij_end)
c$OMP BARRIER

c$OMP MASTER
          call VTb(VTHallo)
          call Register_Hallo(zq(1,1,iq),ip1jmp1,llm,2,2,2,2,MyRequest2)
          call Register_Hallo(zm(1,1,iq),ip1jmp1,llm,1,1,1,1,MyRequest2)
          call VTe(VTHallo)
c$OMP END MASTER        
c$OMP BARRIER
        else
        
          stop 'vlspltgen_p : schema non parallelise'
      
        endif
      
      enddo
c$OMP BARRIER      
c$OMP MASTER        
      call VTb(VTHallo)
      call SendRequest(MyRequest2)
      call VTe(VTHallo)
c$OMP END MASTER        
c$OMP BARRIER
      do iq=1,nqmx

        if(iadv(iq) == 0) then
          
          cycle 
        
        else if (iadv(iq)==10 .or. iadv(iq)==14 ) then
c$OMP BARRIER        
          call vlz_p(zq(1,1,iq),pente_max,zm(1,1,iq),mw,
     &               ij_begin+2*iip1,ij_end-2*iip1)
c$OMP BARRIER        
        else
        
          stop 'vlspltgen_p : schema non parallelise'
      
        endif
      
      enddo

c$OMP BARRIER
c$OMP MASTER
      call VTb(VTHallo)
      call WaitRecvRequest(MyRequest2)
      call WaitSendRequest(MyRequest2)
      call VTe(VTHallo)
c$OMP END MASTER
c$OMP BARRIER


      do iq=1,nqmx

        if(iadv(iq) == 0) then
        
          cycle 
        
        else if (iadv(iq)==10) then
        
          call vly_p(zq(1,1,iq),pente_max,zm(1,1,iq),mv)
  
        else if (iadv(iq)==14) then
      
          call vlyqs_p(zq(1,1,iq),pente_max,zm(1,1,iq),mv,qsat)
 
        else
        
          stop 'vlspltgen_p : schema non parallelise'
      
        endif
       
       enddo

      do iq=1,nqmx

        if(iadv(iq) == 0) then 
          
          cycle 
        
        else if (iadv(iq)==10) then
        
          call vlx_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,
     &               ij_begin,ij_end)
  
        else if (iadv(iq)==14) then
      
          call vlxqs_p(zq(1,1,iq),pente_max,zm(1,1,iq),mu,qsat,
     &                 ij_begin,ij_end)
 
        else
        
          stop 'vlspltgen_p : schema non parallelise'
      
        endif
       
       enddo

     
      ijb=ij_begin
      ije=ij_end
c$OMP BARRIER      

      DO iq=1,nqmx

c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)          
        DO l=1,llm
           DO ij=ijb,ije
c             print *,'zq-->',ij,l,iq,zq(ij,l,iq)
c            print *,'q-->',ij,l,iq,q(ij,l,iq)
             q(ij,l,iq)=zq(ij,l,iq)
           ENDDO
        ENDDO
c$OMP END DO NOWAIT          

c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
        DO l=1,llm
           DO ij=ijb,ije-iip1+1,iip1
              q(ij+iim,l,iq)=q(ij,l,iq)
           ENDDO
        ENDDO
c$OMP END DO NOWAIT  

      ENDDO
        
      
c$OMP BARRIER

cc$OMP MASTER      
c      call WaitSendRequest(MyRequest1) 
c      call WaitSendRequest(MyRequest2)
cc$OMP END MASTER
cc$OMP BARRIER

      RETURN
      END