source: LMDZ6/branches/Amaury_dev/libf/dynphy_lonlat/inigeomphy_mod.F90 @ 5119

! $Id: $

MODULE inigeomphy_mod

CONTAINS

  SUBROUTINE inigeomphy(iim, jjm, nlayer, &
          nbp, communicator, &
          rlatu, rlatv, rlonu, rlonv, aire, cu, cv)
    USE lmdz_grid_phy, ONLY: klon_glo, & ! number of atmospheric columns (on full grid)
            regular_lonlat, &  ! regular longitude-latitude grid type
            nbp_lon, nbp_lat, nbp_lev
    USE lmdz_phys_para, ONLY: klon_omp, & ! number of columns (on local omp grid)
            klon_omp_begin, & ! start index of local omp subgrid
            klon_omp_end, & ! end index of local omp subgrid
            klon_mpi_begin ! start indes of columns (on local mpi grid)
    USE lmdz_geometry, ONLY: init_geometry
    USE lmdz_physics_distribution, ONLY: init_physics_distribution
    USE lmdz_regular_lonlat, ONLY: init_regular_lonlat, &
            east, west, north, south, &
            north_east, north_west, &
            south_west, south_east
    USE mod_interface_dyn_phys, ONLY: init_interface_dyn_phys
    USE lmdz_physical_constants, ONLY: pi
    USE comvert_mod, ONLY: preff, ap, bp, aps, bps, presnivs, &
            scaleheight, pseudoalt, presinter
    USE lmdz_vertical_layers, ONLY: init_vertical_layers
    USE lmdz_iniprint, ONLY: lunout, prt_level
    IMPLICIT NONE

    ! =======================================================================
    ! Initialisation of the physical constants and some positional and
    ! geometrical arrays for the physics
    ! =======================================================================

    INTEGER, INTENT (IN) :: nlayer ! number of atmospheric layers
    INTEGER, INTENT (IN) :: iim ! number of atmospheric columns along longitudes
    INTEGER, INTENT (IN) :: jjm ! number of atompsheric columns along latitudes
    INTEGER, INTENT(IN) :: nbp ! number of physics columns for this MPI process
    INTEGER, INTENT(IN) :: communicator ! MPI communicator
    REAL, INTENT (IN) :: rlatu(jjm + 1) ! latitudes of the physics grid
    REAL, INTENT (IN) :: rlatv(jjm) ! latitude boundaries of the physics grid
    REAL, INTENT (IN) :: rlonv(iim + 1) ! longitudes of the physics grid
    REAL, INTENT (IN) :: rlonu(iim + 1) ! longitude boundaries of the physics grid
    REAL, INTENT (IN) :: aire(iim + 1, jjm + 1) ! area of the dynamics grid (m2)
    REAL, INTENT (IN) :: cu((iim + 1) * (jjm + 1)) ! cu coeff. (u_covariant = cu * u)
    REAL, INTENT (IN) :: cv((iim + 1) * jjm) ! cv coeff. (v_covariant = cv * v)

    INTEGER :: ibegin, iend, offset
    INTEGER :: i, j, k
    CHARACTER (LEN = 20) :: modname = 'inigeomphy'
    CHARACTER (LEN = 80) :: abort_message
    REAL :: total_area_phy, total_area_dyn

    ! boundaries, on global grid
    REAL, ALLOCATABLE :: boundslon_reg(:, :)
    REAL, ALLOCATABLE :: boundslat_reg(:, :)

    ! global array, on full physics grid:
    REAL, ALLOCATABLE :: latfi_glo(:)
    REAL, ALLOCATABLE :: lonfi_glo(:)
    REAL, ALLOCATABLE :: cufi_glo(:)
    REAL, ALLOCATABLE :: cvfi_glo(:)
    REAL, ALLOCATABLE :: airefi_glo(:)
    REAL, ALLOCATABLE :: boundslonfi_glo(:, :)
    REAL, ALLOCATABLE :: boundslatfi_glo(:, :)

    ! local arrays, on given MPI/OpenMP domain:
    REAL, ALLOCATABLE, SAVE :: latfi(:)
    REAL, ALLOCATABLE, SAVE :: lonfi(:)
    REAL, ALLOCATABLE, SAVE :: cufi(:)
    REAL, ALLOCATABLE, SAVE :: cvfi(:)
    REAL, ALLOCATABLE, SAVE :: airefi(:)
    REAL, ALLOCATABLE, SAVE :: boundslonfi(:, :)
    REAL, ALLOCATABLE, SAVE :: boundslatfi(:, :)
    INTEGER, ALLOCATABLE, SAVE :: ind_cell_glo_fi(:)
    !$OMP THREADPRIVATE (latfi,lonfi,cufi,cvfi,airefi,boundslonfi,boundslatfi,ind_cell_glo_fi)

    ! Initialize Physics distibution and parameters and interface with dynamics
    IF (iim * jjm>1) THEN ! general 3D case
      CALL init_physics_distribution(regular_lonlat, 4, &
              nbp, iim, jjm + 1, nlayer, communicator)
    ELSE ! For 1D model
      CALL init_physics_distribution(regular_lonlat, 4, &
              1, 1, 1, nlayer, communicator)
    ENDIF
    CALL init_interface_dyn_phys

    ! init regular global longitude-latitude grid points and boundaries
    ALLOCATE(boundslon_reg(iim, 2))
    ALLOCATE(boundslat_reg(jjm + 1, 2))

    ! specific handling of the -180 longitude scalar grid point boundaries
    boundslon_reg(1, east) = rlonu(1)
    boundslon_reg(1, west) = rlonu(iim) - 2 * PI
    DO i = 2, iim
      boundslon_reg(i, east) = rlonu(i)
      boundslon_reg(i, west) = rlonu(i - 1)
    ENDDO

    boundslat_reg(1, north) = PI / 2
    boundslat_reg(1, south) = rlatv(1)
    DO j = 2, jjm
      boundslat_reg(j, north) = rlatv(j - 1)
      boundslat_reg(j, south) = rlatv(j)
    ENDDO
    boundslat_reg(jjm + 1, north) = rlatv(jjm)
    boundslat_reg(jjm + 1, south) = -PI / 2

    ! Write values in module lmdz_regular_lonlat
    CALL init_regular_lonlat(iim, jjm + 1, rlonv(1:iim), rlatu, &
            boundslon_reg, boundslat_reg)

    ! Generate global arrays on full physics grid
    ALLOCATE(latfi_glo(klon_glo), lonfi_glo(klon_glo))
    ALLOCATE(cufi_glo(klon_glo), cvfi_glo(klon_glo))
    ALLOCATE(airefi_glo(klon_glo))
    ALLOCATE(boundslonfi_glo(klon_glo, 4))
    ALLOCATE(boundslatfi_glo(klon_glo, 4))

    IF (klon_glo>1) THEN ! general case
      ! North pole
      latfi_glo(1) = rlatu(1)
      lonfi_glo(1) = 0.
      cufi_glo(1) = cu(1)
      cvfi_glo(1) = cv(1)
      boundslonfi_glo(1, north_east) = PI
      boundslatfi_glo(1, north_east) = PI / 2
      boundslonfi_glo(1, north_west) = -PI
      boundslatfi_glo(1, north_west) = PI / 2
      boundslonfi_glo(1, south_west) = -PI
      boundslatfi_glo(1, south_west) = rlatv(1)
      boundslonfi_glo(1, south_east) = PI
      boundslatfi_glo(1, south_east) = rlatv(1)
      DO j = 2, jjm
        DO i = 1, iim
          k = (j - 2) * iim + 1 + i
          latfi_glo(k) = rlatu(j)
          lonfi_glo(k) = rlonv(i)
          cufi_glo(k) = cu((j - 1) * (iim + 1) + i)
          cvfi_glo(k) = cv((j - 1) * (iim + 1) + i)
          boundslonfi_glo(k, north_east) = rlonu(i)
          boundslatfi_glo(k, north_east) = rlatv(j - 1)
          IF (i==1) THEN
            ! special case for the first longitude's west bound
            boundslonfi_glo(k, north_west) = rlonu(iim) - 2 * PI
            boundslonfi_glo(k, south_west) = rlonu(iim) - 2 * PI
          else
            boundslonfi_glo(k, north_west) = rlonu(i - 1)
            boundslonfi_glo(k, south_west) = rlonu(i - 1)
          endif
          boundslatfi_glo(k, north_west) = rlatv(j - 1)
          boundslatfi_glo(k, south_west) = rlatv(j)
          boundslonfi_glo(k, south_east) = rlonu(i)
          boundslatfi_glo(k, south_east) = rlatv(j)
        ENDDO
      ENDDO
      ! South pole
      latfi_glo(klon_glo) = rlatu(jjm + 1)
      lonfi_glo(klon_glo) = 0.
      cufi_glo(klon_glo) = cu((iim + 1) * jjm + 1)
      cvfi_glo(klon_glo) = cv((iim + 1) * jjm - iim)
      boundslonfi_glo(klon_glo, north_east) = PI
      boundslatfi_glo(klon_glo, north_east) = rlatv(jjm)
      boundslonfi_glo(klon_glo, north_west) = -PI
      boundslatfi_glo(klon_glo, north_west) = rlatv(jjm)
      boundslonfi_glo(klon_glo, south_west) = -PI
      boundslatfi_glo(klon_glo, south_west) = -PI / 2
      boundslonfi_glo(klon_glo, south_east) = PI
      boundslatfi_glo(klon_glo, south_east) = -Pi / 2

      ! build airefi(), mesh area on physics grid
      CALL gr_dyn_fi(1, iim + 1, jjm + 1, klon_glo, aire, airefi_glo)
      ! Poles are single points on physics grid
      airefi_glo(1) = sum(aire(1:iim, 1))
      airefi_glo(klon_glo) = sum(aire(1:iim, jjm + 1))

      ! Sanity check: do total planet area match between physics and dynamics?
      total_area_dyn = sum(aire(1:iim, 1:jjm + 1))
      total_area_phy = sum(airefi_glo(1:klon_glo))
      IF (total_area_dyn/=total_area_phy) THEN
        WRITE (lunout, *) 'inigeomphy: planet total surface discrepancy !!!'
        WRITE (lunout, *) '     in the dynamics total_area_dyn=', total_area_dyn
        WRITE (lunout, *) '  but in the physics total_area_phy=', total_area_phy
        IF (abs(total_area_dyn - total_area_phy)>0.00001 * total_area_dyn) THEN
          ! stop here if the relative difference is more than 0.001%
          abort_message = 'planet total surface discrepancy'
          CALL abort_gcm(modname, abort_message, 1)
        ENDIF
      ENDIF
    ELSE ! klon_glo==1, running the 1D model
      ! just copy over input values
      latfi_glo(1) = rlatu(1)
      lonfi_glo(1) = rlonv(1)
      cufi_glo(1) = cu(1)
      cvfi_glo(1) = cv(1)
      airefi_glo(1) = aire(1, 1)
      boundslonfi_glo(1, north_east) = rlonu(1)
      boundslatfi_glo(1, north_east) = PI / 2
      boundslonfi_glo(1, north_west) = rlonu(2)
      boundslatfi_glo(1, north_west) = PI / 2
      boundslonfi_glo(1, south_west) = rlonu(2)
      boundslatfi_glo(1, south_west) = rlatv(1)
      boundslonfi_glo(1, south_east) = rlonu(1)
      boundslatfi_glo(1, south_east) = rlatv(1)
    ENDIF ! of IF (klon_glo>1)

    !$OMP PARALLEL
    ! Now generate local lon/lat/cu/cv/area/bounds arrays
    ALLOCATE(latfi(klon_omp), lonfi(klon_omp), cufi(klon_omp), cvfi(klon_omp))
    ALLOCATE(airefi(klon_omp))
    ALLOCATE(boundslonfi(klon_omp, 4))
    ALLOCATE(boundslatfi(klon_omp, 4))
    ALLOCATE(ind_cell_glo_fi(klon_omp))

    offset = klon_mpi_begin - 1
    airefi(1:klon_omp) = airefi_glo(offset + klon_omp_begin:offset + klon_omp_end)
    cufi(1:klon_omp) = cufi_glo(offset + klon_omp_begin:offset + klon_omp_end)
    cvfi(1:klon_omp) = cvfi_glo(offset + klon_omp_begin:offset + klon_omp_end)
    lonfi(1:klon_omp) = lonfi_glo(offset + klon_omp_begin:offset + klon_omp_end)
    latfi(1:klon_omp) = latfi_glo(offset + klon_omp_begin:offset + klon_omp_end)
    boundslonfi(1:klon_omp, :) = boundslonfi_glo(offset + klon_omp_begin:offset + klon_omp_end, :)
    boundslatfi(1:klon_omp, :) = boundslatfi_glo(offset + klon_omp_begin:offset + klon_omp_end, :)
    ind_cell_glo_fi(1:klon_omp) = (/ (i, i = offset + klon_omp_begin, offset + klon_omp_end) /)

    ! copy over local grid longitudes and latitudes
    CALL init_geometry(klon_omp, lonfi, latfi, boundslonfi, boundslatfi, &
            airefi, ind_cell_glo_fi, cufi, cvfi)

    ! copy over preff , ap(), bp(), etc
    CALL init_vertical_layers(nlayer, preff, scaleheight, &
            ap, bp, aps, bps, presnivs, presinter, pseudoalt)

    !$OMP END PARALLEL

  END SUBROUTINE inigeomphy

END MODULE inigeomphy_mod