[7309] | 1 | MODULE agrif_lim3_interp |
---|
| 2 | !!===================================================================================== |
---|
| 3 | !! *** MODULE agrif_lim3_interp *** |
---|
| 4 | !! Nesting module : interp surface ice boundary condition from a parent grid |
---|
| 5 | !! Sea-Ice model : LIM 3.6 Sea ice model time-stepping |
---|
| 6 | !!===================================================================================== |
---|
| 7 | !! History : 2.0 ! 04-2008 (F. Dupont) initial version |
---|
| 8 | !! 3.4 ! 09-2012 (R. Benshila, C. Herbaut) update and EVP |
---|
| 9 | !! 3.6 ! 05-2016 (C. Rousset) Add LIM3 compatibility |
---|
| 10 | !!---------------------------------------------------------------------- |
---|
| 11 | #if defined key_agrif && defined key_lim3 |
---|
| 12 | !!---------------------------------------------------------------------- |
---|
| 13 | !! 'key_lim3' : LIM 3.6 sea-ice model |
---|
| 14 | !! 'key_agrif' : AGRIF library |
---|
| 15 | !!---------------------------------------------------------------------- |
---|
| 16 | !! agrif_interp_lim3 : interpolation of ice at "after" sea-ice time step |
---|
| 17 | !! agrif_interp_u_ice : atomic routine to interpolate u_ice |
---|
| 18 | !! agrif_interp_v_ice : atomic routine to interpolate v_ice |
---|
| 19 | !! agrif_interp_tra_ice : atomic routine to interpolate ice properties |
---|
| 20 | !!---------------------------------------------------------------------- |
---|
| 21 | USE par_oce |
---|
| 22 | USE dom_oce |
---|
| 23 | USE sbc_oce |
---|
| 24 | USE ice |
---|
| 25 | USE agrif_ice |
---|
| 26 | |
---|
| 27 | IMPLICIT NONE |
---|
| 28 | PRIVATE |
---|
| 29 | |
---|
| 30 | PUBLIC agrif_interp_lim3 |
---|
| 31 | |
---|
| 32 | !!---------------------------------------------------------------------- |
---|
| 33 | !! NEMO/NST 3.6 , NEMO Consortium (2016) |
---|
| 34 | !! $Id: agrif_lim3_interp.F90 6204 2016-01-04 13:47:06Z cetlod $ |
---|
| 35 | !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) |
---|
| 36 | !!---------------------------------------------------------------------- |
---|
| 37 | |
---|
| 38 | CONTAINS |
---|
| 39 | |
---|
| 40 | SUBROUTINE agrif_interp_lim3( cd_type, kiter, kitermax ) |
---|
| 41 | !!----------------------------------------------------------------------- |
---|
| 42 | !! *** ROUTINE agrif_rhg_lim3 *** |
---|
| 43 | !! |
---|
| 44 | !! ** Method : simple call to atomic routines using stored values to |
---|
| 45 | !! fill the boundaries depending of the position of the point and |
---|
| 46 | !! computing factor for time interpolation |
---|
| 47 | !!----------------------------------------------------------------------- |
---|
| 48 | CHARACTER(len=1), INTENT( in ) :: cd_type |
---|
| 49 | INTEGER , INTENT( in ), OPTIONAL :: kiter, kitermax |
---|
| 50 | !! |
---|
| 51 | REAL(wp) :: zbeta |
---|
| 52 | !!----------------------------------------------------------------------- |
---|
| 53 | ! |
---|
| 54 | IF( Agrif_Root() ) RETURN |
---|
| 55 | ! |
---|
| 56 | IF( PRESENT( kiter ) ) THEN ! interpolation at the child sub-time step (for ice rheology) |
---|
| 57 | zbeta = ( REAL(lim_nbstep) - REAL(kitermax - kiter) / REAL(kitermax) ) / & |
---|
| 58 | & ( Agrif_Rhot() * REAL(Agrif_Parent(nn_fsbc)) / REAL(nn_fsbc) ) |
---|
| 59 | ELSE ! interpolation at the child time step |
---|
| 60 | zbeta = REAL(lim_nbstep) / ( Agrif_Rhot() * REAL(Agrif_Parent(nn_fsbc)) / REAL(nn_fsbc) ) |
---|
| 61 | ENDIF |
---|
| 62 | ! |
---|
| 63 | Agrif_SpecialValue=-9999. |
---|
| 64 | Agrif_UseSpecialValue = .TRUE. |
---|
| 65 | SELECT CASE(cd_type) |
---|
| 66 | CASE('U') |
---|
| 67 | CALL Agrif_Bc_variable( u_ice_id , procname=interp_u_ice , calledweight=zbeta ) |
---|
| 68 | CASE('V') |
---|
| 69 | CALL Agrif_Bc_variable( v_ice_id , procname=interp_v_ice , calledweight=zbeta ) |
---|
| 70 | CASE('T') |
---|
| 71 | CALL Agrif_Bc_variable( tra_ice_id, procname=interp_tra_ice, calledweight=zbeta ) |
---|
| 72 | END SELECT |
---|
| 73 | Agrif_SpecialValue=0. |
---|
| 74 | Agrif_UseSpecialValue = .FALSE. |
---|
| 75 | ! |
---|
| 76 | END SUBROUTINE agrif_interp_lim3 |
---|
| 77 | |
---|
| 78 | !!------------------ |
---|
| 79 | !! Local subroutines |
---|
| 80 | !!------------------ |
---|
| 81 | SUBROUTINE interp_u_ice( ptab, i1, i2, j1, j2, before ) |
---|
| 82 | !!----------------------------------------------------------------------- |
---|
| 83 | !! *** ROUTINE interp_u_ice *** |
---|
| 84 | !! |
---|
| 85 | !! i1 i2 j1 j2 are the index of the boundaries parent(when before) and child (when after) |
---|
| 86 | !! To solve issues when parent grid is "land" masked but not all the corresponding child grid points, |
---|
| 87 | !! put -9999 WHERE the parent grid is masked. The child solution will be found in the 9(?) points around |
---|
| 88 | !!----------------------------------------------------------------------- |
---|
| 89 | INTEGER , INTENT(in) :: i1, i2, j1, j2 |
---|
| 90 | REAL(wp), DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab |
---|
| 91 | LOGICAL , INTENT(in) :: before |
---|
| 92 | !! |
---|
| 93 | REAL(wp) :: zrhoy |
---|
| 94 | !!----------------------------------------------------------------------- |
---|
| 95 | ! |
---|
| 96 | IF( before ) THEN ! parent grid |
---|
| 97 | ptab(:,:) = e2u(i1:i2,j1:j2) * u_ice_b(i1:i2,j1:j2) |
---|
| 98 | WHERE( umask(i1:i2,j1:j2,1) == 0. ) ptab(:,:) = -9999. |
---|
| 99 | ELSE ! child grid |
---|
| 100 | zrhoy = Agrif_Rhoy() |
---|
| 101 | u_ice(i1:i2,j1:j2) = ptab(:,:) / ( e2u(i1:i2,j1:j2) * zrhoy ) * umask(i1:i2,j1:j2,1) |
---|
| 102 | ENDIF |
---|
| 103 | ! |
---|
| 104 | END SUBROUTINE interp_u_ice |
---|
| 105 | |
---|
| 106 | |
---|
| 107 | SUBROUTINE interp_v_ice( ptab, i1, i2, j1, j2, before ) |
---|
| 108 | !!----------------------------------------------------------------------- |
---|
| 109 | !! *** ROUTINE interp_v_ice *** |
---|
| 110 | !! |
---|
| 111 | !! i1 i2 j1 j2 are the index of the boundaries parent(when before) and child (when after) |
---|
| 112 | !! To solve issues when parent grid is "land" masked but not all the corresponding child grid points, |
---|
| 113 | !! put -9999 WHERE the parent grid is masked. The child solution will be found in the 9(?) points around |
---|
| 114 | !!----------------------------------------------------------------------- |
---|
| 115 | INTEGER , INTENT(in) :: i1, i2, j1, j2 |
---|
| 116 | REAL(wp), DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab |
---|
| 117 | LOGICAL , INTENT(in) :: before |
---|
| 118 | !! |
---|
| 119 | REAL(wp) :: zrhox |
---|
| 120 | !!----------------------------------------------------------------------- |
---|
| 121 | ! |
---|
| 122 | IF( before ) THEN ! parent grid |
---|
| 123 | ptab(:,:) = e1v(i1:i2,j1:j2) * v_ice_b(i1:i2,j1:j2) |
---|
| 124 | WHERE( vmask(i1:i2,j1:j2,1) == 0. ) ptab(:,:) = -9999. |
---|
| 125 | ELSE ! child grid |
---|
| 126 | zrhox = Agrif_Rhox() |
---|
| 127 | v_ice(i1:i2,j1:j2) = ptab(:,:) / ( e1v(i1:i2,j1:j2) * zrhox ) * vmask(i1:i2,j1:j2,1) |
---|
| 128 | ENDIF |
---|
| 129 | ! |
---|
| 130 | END SUBROUTINE interp_v_ice |
---|
| 131 | |
---|
| 132 | |
---|
| 133 | SUBROUTINE interp_tra_ice( ptab, i1, i2, j1, j2, k1, k2, before, nb, ndir ) |
---|
| 134 | !!----------------------------------------------------------------------- |
---|
| 135 | !! *** ROUTINE interp_tra_ice *** |
---|
| 136 | !! |
---|
| 137 | !! i1 i2 j1 j2 are the index of the boundaries parent(when before) and child (when after) |
---|
| 138 | !! To solve issues when parent grid is "land" masked but not all the corresponding child grid points, |
---|
| 139 | !! put -9999 WHERE the parent grid is masked. The child solution will be found in the 9(?) points around |
---|
| 140 | !!----------------------------------------------------------------------- |
---|
| 141 | REAL(wp), DIMENSION(i1:i2,j1:j2,k1:k2), INTENT(inout) :: ptab |
---|
| 142 | INTEGER , INTENT(in) :: i1, i2, j1, j2, k1, k2 |
---|
| 143 | LOGICAL , INTENT(in) :: before |
---|
| 144 | INTEGER , INTENT(in) :: nb, ndir |
---|
| 145 | !! |
---|
| 146 | REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: ztab |
---|
| 147 | INTEGER :: ji, jj, jk, jl, jm |
---|
| 148 | INTEGER :: imin, imax, jmin, jmax |
---|
| 149 | REAL(wp) :: zrhox, z1, z2, z3, z4, z5, z6, z7 |
---|
| 150 | LOGICAL :: western_side, eastern_side, northern_side, southern_side |
---|
| 151 | |
---|
| 152 | !!----------------------------------------------------------------------- |
---|
| 153 | ! clem: pkoi on n'utilise pas les quantités intégrées ici => before: * e1e2t ; after: * r1_e1e2t / rhox / rhoy |
---|
| 154 | ! a priori c'est ok comme ca (cf ce qui est fait dans l'ocean). Je ne sais pas pkoi ceci dit |
---|
| 155 | ALLOCATE( ztab(SIZE(a_i_b,1),SIZE(a_i_b,2),SIZE(ptab,3)) ) |
---|
| 156 | |
---|
| 157 | IF( before ) THEN ! parent grid |
---|
| 158 | jm = 1 |
---|
| 159 | DO jl = 1, jpl |
---|
| 160 | ptab(i1:i2,j1:j2,jm) = a_i_b (i1:i2,j1:j2,jl) ; jm = jm + 1 |
---|
| 161 | ptab(i1:i2,j1:j2,jm) = v_i_b (i1:i2,j1:j2,jl) ; jm = jm + 1 |
---|
| 162 | ptab(i1:i2,j1:j2,jm) = v_s_b (i1:i2,j1:j2,jl) ; jm = jm + 1 |
---|
| 163 | ptab(i1:i2,j1:j2,jm) = smv_i_b(i1:i2,j1:j2,jl) ; jm = jm + 1 |
---|
| 164 | ptab(i1:i2,j1:j2,jm) = oa_i_b (i1:i2,j1:j2,jl) ; jm = jm + 1 |
---|
| 165 | DO jk = 1, nlay_s |
---|
| 166 | ptab(i1:i2,j1:j2,jm) = e_s_b(i1:i2,j1:j2,jk,jl) ; jm = jm + 1 |
---|
| 167 | ENDDO |
---|
| 168 | DO jk = 1, nlay_i |
---|
| 169 | ptab(i1:i2,j1:j2,jm) = e_i_b(i1:i2,j1:j2,jk,jl) ; jm = jm + 1 |
---|
| 170 | ENDDO |
---|
| 171 | ENDDO |
---|
| 172 | |
---|
| 173 | DO jk = k1, k2 |
---|
| 174 | WHERE( tmask(i1:i2,j1:j2,1) == 0. ) ptab(i1:i2,j1:j2,jk) = -9999. |
---|
| 175 | ENDDO |
---|
| 176 | |
---|
| 177 | ELSE ! child grid |
---|
| 178 | !! ==> The easiest interpolation is the following commented lines |
---|
| 179 | !! jm = 1 |
---|
| 180 | !! DO jl = 1, jpl |
---|
| 181 | !! a_i (i1:i2,j1:j2,jl) = ptab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 182 | !! v_i (i1:i2,j1:j2,jl) = ptab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 183 | !! v_s (i1:i2,j1:j2,jl) = ptab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 184 | !! smv_i(i1:i2,j1:j2,jl) = ptab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 185 | !! oa_i (i1:i2,j1:j2,jl) = ptab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 186 | !! DO jk = 1, nlay_s |
---|
| 187 | !! e_s(i1:i2,j1:j2,jk,jl) = ptab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 188 | !! ENDDO |
---|
| 189 | !! DO jk = 1, nlay_i |
---|
| 190 | !! e_i(i1:i2,j1:j2,jk,jl) = ptab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 191 | !! ENDDO |
---|
| 192 | !! ENDDO |
---|
| 193 | |
---|
| 194 | !! ==> this is a more complex interpolation since we mix solutions over a couple of grid points |
---|
| 195 | !! it is advised to use it for fields modified by high order schemes (e.g. advection UM5...) |
---|
| 196 | ! record ztab |
---|
| 197 | jm = 1 |
---|
| 198 | DO jl = 1, jpl |
---|
| 199 | ztab(:,:,jm) = a_i_b (:,:,jl) ; jm = jm + 1 |
---|
| 200 | ztab(:,:,jm) = v_i_b (:,:,jl) ; jm = jm + 1 |
---|
| 201 | ztab(:,:,jm) = v_s_b (:,:,jl) ; jm = jm + 1 |
---|
| 202 | ztab(:,:,jm) = smv_i_b(:,:,jl) ; jm = jm + 1 |
---|
| 203 | ztab(:,:,jm) = oa_i_b (:,:,jl) ; jm = jm + 1 |
---|
| 204 | DO jk = 1, nlay_s |
---|
| 205 | ztab(:,:,jm) = e_s_b(:,:,jk,jl) ; jm = jm + 1 |
---|
| 206 | ENDDO |
---|
| 207 | DO jk = 1, nlay_i |
---|
| 208 | ztab(:,:,jm) = e_i_b(:,:,jk,jl) ; jm = jm + 1 |
---|
| 209 | ENDDO |
---|
| 210 | ENDDO |
---|
| 211 | ! |
---|
| 212 | ! borders of the domain |
---|
| 213 | western_side = (nb == 1).AND.(ndir == 1) ; eastern_side = (nb == 1).AND.(ndir == 2) |
---|
| 214 | southern_side = (nb == 2).AND.(ndir == 1) ; northern_side = (nb == 2).AND.(ndir == 2) |
---|
| 215 | ! |
---|
| 216 | ! spatial smoothing |
---|
| 217 | zrhox = Agrif_Rhox() |
---|
| 218 | z1 = ( zrhox - 1. ) * 0.5 |
---|
| 219 | z3 = ( zrhox - 1. ) / ( zrhox + 1. ) |
---|
| 220 | z6 = 2. * ( zrhox - 1. ) / ( zrhox + 1. ) |
---|
| 221 | z7 = - ( zrhox - 1. ) / ( zrhox + 3. ) |
---|
| 222 | z2 = 1. - z1 |
---|
| 223 | z4 = 1. - z3 |
---|
| 224 | z5 = 1. - z6 - z7 |
---|
| 225 | ! |
---|
| 226 | ! Remove corners |
---|
| 227 | imin = i1 ; imax = i2 ; jmin = j1 ; jmax = j2 |
---|
| 228 | IF( (nbondj == -1) .OR. (nbondj == 2) ) jmin = 3 |
---|
| 229 | IF( (nbondj == +1) .OR. (nbondj == 2) ) jmax = nlcj-2 |
---|
| 230 | IF( (nbondi == -1) .OR. (nbondi == 2) ) imin = 3 |
---|
| 231 | IF( (nbondi == +1) .OR. (nbondi == 2) ) imax = nlci-2 |
---|
| 232 | |
---|
| 233 | ! smoothed fields |
---|
| 234 | IF( eastern_side ) THEN |
---|
| 235 | ztab(nlci,j1:j2,:) = z1 * ptab(nlci,j1:j2,:) + z2 * ptab(nlci-1,j1:j2,:) |
---|
| 236 | DO jj = jmin, jmax |
---|
| 237 | rswitch = 0. |
---|
| 238 | IF( u_ice(nlci-2,jj) > 0._wp ) rswitch = 1. |
---|
| 239 | ztab(nlci-1,jj,:) = ( 1. - umask(nlci-2,jj,1) ) * ztab(nlci,jj,:) & |
---|
| 240 | & + umask(nlci-2,jj,1) * & |
---|
| 241 | & ( ( 1. - rswitch ) * ( z4 * ztab(nlci,jj,:) + z3 * ztab(nlci-2,jj,:) ) & |
---|
| 242 | & + rswitch * ( z6 * ztab(nlci-2,jj,:) + z5 * ztab(nlci,jj,:) + z7 * ztab(nlci-3,jj,:) ) ) |
---|
| 243 | ztab(nlci-1,jj,:) = ztab(nlci-1,jj,:) * tmask(nlci-1,jj,1) |
---|
| 244 | END DO |
---|
| 245 | ENDIF |
---|
| 246 | ! |
---|
| 247 | IF( northern_side ) THEN |
---|
| 248 | ztab(i1:i2,nlcj,:) = z1 * ptab(i1:i2,nlcj,:) + z2 * ptab(i1:i2,nlcj-1,:) |
---|
| 249 | DO ji = imin, imax |
---|
| 250 | rswitch = 0. |
---|
| 251 | IF( v_ice(ji,nlcj-2) > 0._wp ) rswitch = 1. |
---|
| 252 | ztab(ji,nlcj-1,:) = ( 1. - vmask(ji,nlcj-2,1) ) * ztab(ji,nlcj,:) & |
---|
| 253 | & + vmask(ji,nlcj-2,1) * & |
---|
| 254 | & ( ( 1. - rswitch ) * ( z4 * ztab(ji,nlcj,:) + z3 * ztab(ji,nlcj-2,:) ) & |
---|
| 255 | & + rswitch * ( z6 * ztab(ji,nlcj-2,:) + z5 * ztab(ji,nlcj,:) + z7 * ztab(ji,nlcj-3,:) ) ) |
---|
| 256 | ztab(ji,nlcj-1,:) = ztab(ji,nlcj-1,:) * tmask(ji,nlcj-1,1) |
---|
| 257 | END DO |
---|
| 258 | END IF |
---|
| 259 | ! |
---|
| 260 | IF( western_side) THEN |
---|
| 261 | ztab(1,j1:j2,:) = z1 * ptab(1,j1:j2,:) + z2 * ptab(2,j1:j2,:) |
---|
| 262 | DO jj = jmin, jmax |
---|
| 263 | rswitch = 0. |
---|
| 264 | IF( u_ice(2,jj) > 0._wp ) rswitch = 1. |
---|
| 265 | ztab(2,jj,:) = ( 1. - umask(2,jj,1) ) * ztab(1,jj,:) & |
---|
| 266 | & + umask(2,jj,1) * & |
---|
| 267 | & ( ( 1. - rswitch ) * ( z4 * ztab(1,jj,:) + z3 * ztab(3,jj,:) ) & |
---|
| 268 | & + rswitch * ( z6 * ztab(3,jj,:) + z5 * ztab(1,jj,:) + z7 * ztab(4,jj,:) ) ) |
---|
| 269 | ztab(2,jj,:) = ztab(2,jj,:) * tmask(2,jj,1) |
---|
| 270 | END DO |
---|
| 271 | ENDIF |
---|
| 272 | ! |
---|
| 273 | IF( southern_side ) THEN |
---|
| 274 | ztab(i1:i2,1,:) = z1 * ptab(i1:i2,1,:) + z2 * ptab(i1:i2,2,:) |
---|
| 275 | DO ji = imin, imax |
---|
| 276 | rswitch = 0. |
---|
| 277 | IF( v_ice(ji,2) > 0._wp ) rswitch = 1. |
---|
| 278 | ztab(ji,2,:) = ( 1. - vmask(ji,2,1) ) * ztab(ji,1,:) & |
---|
| 279 | & + vmask(ji,2,1) * & |
---|
| 280 | & ( ( 1. - rswitch ) * ( z4 * ztab(ji,1,:) + z3 * ztab(ji,3,:) ) & |
---|
| 281 | & + rswitch * ( z6 * ztab(ji,3,:) + z5 * ztab(ji,1,:) + z7 * ztab(ji,4,:) ) ) |
---|
| 282 | ztab(ji,2,:) = ztab(ji,2,:) * tmask(ji,2,1) |
---|
| 283 | END DO |
---|
| 284 | END IF |
---|
| 285 | ! |
---|
| 286 | ! Treatment of corners |
---|
| 287 | IF( (eastern_side) .AND. ((nbondj == -1).OR.(nbondj == 2)) ) ztab(nlci-1,2,:) = ptab(nlci-1,2,:) ! East south |
---|
| 288 | IF( (eastern_side) .AND. ((nbondj == 1).OR.(nbondj == 2)) ) ztab(nlci-1,nlcj-1,:) = ptab(nlci-1,nlcj-1,:) ! East north |
---|
| 289 | IF( (western_side) .AND. ((nbondj == -1).OR.(nbondj == 2)) ) ztab(2,2,:) = ptab(2,2,:) ! West south |
---|
| 290 | IF( (western_side) .AND. ((nbondj == 1).OR.(nbondj == 2)) ) ztab(2,nlcj-1,:) = ptab(2,nlcj-1,:) ! West north |
---|
| 291 | |
---|
| 292 | ! retrieve ice tracers |
---|
| 293 | jm = 1 |
---|
| 294 | DO jl = 1, jpl |
---|
| 295 | a_i (i1:i2,j1:j2,jl) = ztab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 296 | v_i (i1:i2,j1:j2,jl) = ztab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 297 | v_s (i1:i2,j1:j2,jl) = ztab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 298 | smv_i(i1:i2,j1:j2,jl) = ztab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 299 | oa_i (i1:i2,j1:j2,jl) = ztab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 300 | DO jk = 1, nlay_s |
---|
| 301 | e_s(i1:i2,j1:j2,jk,jl) = ztab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 302 | ENDDO |
---|
| 303 | DO jk = 1, nlay_i |
---|
| 304 | e_i(i1:i2,j1:j2,jk,jl) = ztab(i1:i2,j1:j2,jm) * tmask(i1:i2,j1:j2,1) ; jm = jm + 1 |
---|
| 305 | ENDDO |
---|
| 306 | ENDDO |
---|
| 307 | |
---|
| 308 | ENDIF |
---|
| 309 | |
---|
| 310 | DEALLOCATE( ztab ) |
---|
| 311 | ! |
---|
| 312 | END SUBROUTINE interp_tra_ice |
---|
| 313 | |
---|
| 314 | #else |
---|
| 315 | CONTAINS |
---|
| 316 | SUBROUTINE agrif_lim3_interp_empty |
---|
| 317 | !!--------------------------------------------- |
---|
| 318 | !! *** ROUTINE agrif_lim3_interp_empty *** |
---|
| 319 | !!--------------------------------------------- |
---|
| 320 | WRITE(*,*) 'agrif_lim3_interp : You should not have seen this print! error?' |
---|
| 321 | END SUBROUTINE agrif_lim3_interp_empty |
---|
| 322 | #endif |
---|
| 323 | END MODULE agrif_lim3_interp |
---|