source: NEMO/branches/UKMO/dev_r9888_proto_GO8_package/src/OCE/LBC/mpp_nfd_generic.h90 @ 9977

#if defined MULTI
#   define NAT_IN(k)                cd_nat(k)   
#   define SGN_IN(k)                psgn(k)
#   define F_SIZE(ptab)             kfld
#   define LBC_ARG                  (jf)
#   if defined DIM_2d
#      define ARRAY_TYPE(i,j,k,l,f)    TYPE(PTR_2D)     , INTENT(inout) ::   ptab(f)
#      define ARRAY_IN(i,j,k,l,f)      ptab(f)%pt2d(i,j)
#      define K_SIZE(ptab)             1
#      define L_SIZE(ptab)             1
#   endif
#   if defined DIM_3d
#      define ARRAY_TYPE(i,j,k,l,f)    TYPE(PTR_3D)     , INTENT(inout) ::   ptab(f)
#      define ARRAY_IN(i,j,k,l,f)      ptab(f)%pt3d(i,j,k)
#      define K_SIZE(ptab)             SIZE(ptab(1)%pt3d,3)
#      define L_SIZE(ptab)             1
#   endif
#   if defined DIM_4d
#      define ARRAY_TYPE(i,j,k,l,f)    TYPE(PTR_4D)     , INTENT(inout) ::   ptab(f)
#      define ARRAY_IN(i,j,k,l,f)      ptab(f)%pt4d(i,j,k,l)
#      define K_SIZE(ptab)             SIZE(ptab(1)%pt4d,3)
#      define L_SIZE(ptab)             SIZE(ptab(1)%pt4d,4)
#   endif
#else
!                          !==  IN: ptab is an array  ==!
#   define ARRAY_TYPE(i,j,k,l,f)    REAL(wp)         , INTENT(inout) ::   ARRAY_IN(i,j,k,l,f)
#   define NAT_IN(k)                cd_nat
#   define SGN_IN(k)                psgn
#   define F_SIZE(ptab)             1
#   define LBC_ARG
#   if defined DIM_2d
#      define ARRAY_IN(i,j,k,l,f)   ptab(i,j)
#      define K_SIZE(ptab)          1
#      define L_SIZE(ptab)          1
#   endif
#   if defined DIM_3d
#      define ARRAY_IN(i,j,k,l,f)   ptab(i,j,k)
#      define K_SIZE(ptab)          SIZE(ptab,3)
#      define L_SIZE(ptab)          1
#   endif
#   if defined DIM_4d
#      define ARRAY_IN(i,j,k,l,f)   ptab(i,j,k,l)
#      define K_SIZE(ptab)          SIZE(ptab,3)
#      define L_SIZE(ptab)          SIZE(ptab,4)
#   endif
#endif

   SUBROUTINE ROUTINE_NFD( ptab, cd_nat, psgn, kfld )
      !!----------------------------------------------------------------------
      ARRAY_TYPE(:,:,:,:,:)   ! array or pointer of arrays on which the boundary condition is applied
      CHARACTER(len=1) , INTENT(in   ) ::   NAT_IN(:)   ! nature of array grid-points
      REAL(wp)         , INTENT(in   ) ::   SGN_IN(:)   ! sign used across the north fold boundary
      INTEGER, OPTIONAL, INTENT(in   ) ::   kfld        ! number of pt3d arrays
      !
      INTEGER  ::   ji,  jj,  jk,  jl, jh, jf, jr   ! dummy loop indices
      INTEGER  ::   ipi, ipj, ipk, ipl, ipf         ! dimension of the input array
      INTEGER  ::   imigr, iihom, ijhom             ! local integers
      INTEGER  ::   ierr, itaille, ilci, ildi, ilei, iilb
      INTEGER  ::   ij, iproc
      INTEGER, DIMENSION (jpmaxngh)       ::   ml_req_nf   ! for mpi_isend when avoiding mpi_allgather
      INTEGER                             ::   ml_err      ! for mpi_isend when avoiding mpi_allgather
      INTEGER, DIMENSION(MPI_STATUS_SIZE) ::   ml_stat     ! for mpi_isend when avoiding mpi_allgather
      !                                                    ! Workspace for message transfers avoiding mpi_allgather
      REAL(wp), DIMENSION(:,:,:,:,:)  , ALLOCATABLE ::   ztab, ztabl, ztabr
      REAL(wp), DIMENSION(:,:,:,:,:)  , ALLOCATABLE ::   znorthloc, zfoldwk      
      REAL(wp), DIMENSION(:,:,:,:,:,:), ALLOCATABLE ::   znorthgloio
      !!----------------------------------------------------------------------
      !
      ipk = K_SIZE(ptab)   ! 3rd dimension
      ipl = L_SIZE(ptab)   ! 4th    -
      ipf = F_SIZE(ptab)   ! 5th    -      use in "multi" case (array of pointers)
      !
      ipj   = 4            ! 2nd dimension of message transfers (last j-lines)
      !
      ALLOCATE( znorthloc(jpimax,4,ipk,ipl,ipf) )
      !
      znorthloc(:,:,:,:,:) = 0._wp
      !
      DO jf = 1, ipf                ! put in znorthloc the last ipj j-lines of ptab
         DO jl = 1, ipl
            DO jk = 1, ipk
               DO jj = nlcj - ipj +1, nlcj
                  ij = jj - nlcj + ipj
                  znorthloc(1:jpi,ij,jk,jl,jf) = ARRAY_IN(1:jpi,jj,jk,jl,jf)
               END DO
            END DO
         END DO
      END DO
      !
      !
      itaille = jpimax * ipj * ipk * ipl * ipf
      !
      IF( l_north_nogather ) THEN      !==  ????  ==!
         ALLOCATE( zfoldwk(jpimax,4,ipk,ipl,ipf) )
         ALLOCATE( ztabl(jpimax   ,4,ipk,ipl,ipf) , ztabr(jpimax*jpmaxngh,4,ipk,ipl,ipf) ) 
         !
         DO jf = 1, ipf
            DO jl = 1, ipl
               DO jk = 1, ipk
                  DO jj = nlcj-ipj+1, nlcj          ! First put local values into the global array
                     ij = jj - nlcj + ipj
                     DO ji = nfsloop, nfeloop
                        ztabl(ji,ij,jk,jl,jf) = ARRAY_IN(ji,jj,jk,jl,jf)
                     END DO
                  END DO
               END DO
            END DO
         END DO
         !
         DO jr = 1, nsndto
            IF( nfipproc(isendto(jr),jpnj) /= narea-1 .AND. nfipproc(isendto(jr),jpnj) /= -1 ) THEN
              CALL mppsend( 5, znorthloc, itaille, nfipproc(isendto(jr),jpnj), ml_req_nf(jr) )
            ENDIF
         END DO
         DO jr = 1,nsndto
            iproc = nfipproc(isendto(jr),jpnj)
            IF(iproc /= -1) THEN
               iilb = nimppt(iproc+1)
               ilci = nlcit (iproc+1)
               ildi = nldit (iproc+1)
               ilei = nleit (iproc+1)
               IF( iilb            ==      1 )   ildi = 1      ! e-w boundary already done -> force to take 1st column
               IF( iilb + ilci - 1 == jpiglo )   ilei = ilci   ! e-w boundary already done -> force to take last column
               iilb = nfiimpp(isendto(jr),jpnj) - nfiimpp(isendto(1),jpnj)
            ENDIF
            IF( iproc /= narea-1 .AND. iproc /= -1 ) THEN
              CALL mpprecv(5, zfoldwk, itaille, iproc)
               DO jf = 1, ipf
                  DO jl = 1, ipl
                     DO jk = 1, ipk
                        DO jj = 1, ipj
                           DO ji = ildi, ilei
                              ztabr(iilb+ji,jj,jk,jl,jf) = zfoldwk(ji,jj,jk,jl,jf)
                           END DO
                        END DO
                     END DO
                  END DO
               END DO
            ELSE IF( iproc == narea-1 ) THEN
               DO jf = 1, ipf
                  DO jl = 1, ipl
                     DO jk = 1, ipk
                        DO jj = 1, ipj
                           DO ji = ildi, ilei
                              ztabr(iilb+ji,jj,jk,jl,jf) = ARRAY_IN(ji,nlcj-ipj+jj,jk,jl,jf)
                           END DO
                        END DO
                     END DO
                  END DO
               END DO
            ENDIF
         END DO
         IF( l_isend ) THEN
            DO jr = 1,nsndto
               IF( nfipproc(isendto(jr),jpnj) /= narea-1 .AND. nfipproc(isendto(jr),jpnj) /= -1 ) THEN
                  CALL mpi_wait( ml_req_nf(jr), ml_stat, ml_err )
               ENDIF    
            END DO
         ENDIF
         DO jf = 1, ipf
            CALL lbc_nfd_nogather( ztabl(:,:,:,:,jf), ztabr(:,:,:,:,jf), cd_nat LBC_ARG, psgn LBC_ARG )   ! North fold boundary condition
         END DO
         DO jf = 1, ipf
            DO jl = 1, ipl
               DO jk = 1, ipk
                  DO jj = nlcj-ipj+1, nlcj             ! Scatter back to ARRAY_IN
                     ij = jj - nlcj + ipj
                     DO ji= 1, nlci
                        ARRAY_IN(ji,jj,jk,jl,jf) = ztabl(ji,ij,jk,jl,jf)
                     END DO
                  END DO
               END DO
            END DO
         END DO
         !
         DEALLOCATE( zfoldwk )
         DEALLOCATE( ztabl, ztabr ) 
      ELSE                             !==  ????  ==!
         ALLOCATE( ztab       (jpiglo,4,ipk,ipl,ipf     ) )
         ALLOCATE( znorthgloio(jpimax,4,ipk,ipl,ipf,jpni) )
         !
         CALL MPI_ALLGATHER( znorthloc  , itaille, MPI_DOUBLE_PRECISION,                &
            &                znorthgloio, itaille, MPI_DOUBLE_PRECISION, ncomm_north, ierr )
         !
         DO jr = 1, ndim_rank_north         ! recover the global north array
            iproc = nrank_north(jr) + 1
            iilb  = nimppt(iproc)
            ilci  = nlcit (iproc)
            ildi  = nldit (iproc)
            ilei  = nleit (iproc)
            IF( iilb            ==      1 )   ildi = 1      ! e-w boundary already done -> force to take 1st column
            IF( iilb + ilci - 1 == jpiglo )   ilei = ilci   ! e-w boundary already done -> force to take last column
            DO jf = 1, ipf
               DO jl = 1, ipl
                  DO jk = 1, ipk
                     DO jj = 1, ipj
                        DO ji = ildi, ilei
                           ztab(ji+iilb-1,jj,jk,jl,jf) = znorthgloio(ji,jj,jk,jl,jf,jr)
                        END DO
                     END DO
                  END DO
               END DO
            END DO
         END DO
         DO jf = 1, ipf
            CALL lbc_nfd( ztab(:,:,:,:,jf), cd_nat LBC_ARG, psgn LBC_ARG )   ! North fold boundary condition
         END DO
         !
         DO jf = 1, ipf
            DO jl = 1, ipl
               DO jk = 1, ipk
                  DO jj = nlcj-ipj+1, nlcj             ! Scatter back to ARRAY_IN
                     ij = jj - nlcj + ipj
                     DO ji= 1, nlci
                        ARRAY_IN(ji,jj,jk,jl,jf) = ztab(ji+nimpp-1,ij,jk,jl,jf)
                     END DO
                  END DO
               END DO
            END DO
         END DO
         !
      !
         DEALLOCATE( ztab )
         DEALLOCATE( znorthgloio )
      ENDIF
      !
      DEALLOCATE( znorthloc )
      !
   END SUBROUTINE ROUTINE_NFD

#undef ARRAY_TYPE
#undef NAT_IN
#undef SGN_IN
#undef ARRAY_IN
#undef K_SIZE
#undef L_SIZE
#undef F_SIZE
#undef LBC_ARG