Changeset 6478
- Timestamp:
- 2016-04-15T18:43:21+02:00 (8 years ago)
- Location:
- trunk/NEMOGCM/NEMO
- Files:
-
- 5 edited
Legend:
- Unmodified
- Added
- Removed
-
trunk/NEMOGCM/NEMO/LIM_SRC_3/ice.F90
r6416 r6478 234 234 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: u_oce, v_oce !: surface ocean velocity used in ice dynamics 235 235 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: ahiu , ahiv !: hor. diffusivity coeff. at U- and V-points [m2/s] 236 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: pahu , pahv !: ice hor. eddy diffusivity coef. at U- and V-points237 236 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: ust2s, hicol !: friction velocity, ice collection thickness accreted in leads 238 237 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: strp1, strp2 !: strength at previous time steps … … 303 302 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: hfx_res !: residual heat flux due to correction of ice thickness [W.m-2] 304 303 305 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: ftr_ice !: transmitted solar radiation under ice 304 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: ftr_ice !: transmitted solar radiation under ice 305 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: pahu3D , pahv3D 306 306 REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: rn_amax_2d !: maximum ice concentration 2d array 307 307 … … 429 429 ALLOCATE( u_oce (jpi,jpj) , v_oce (jpi,jpj) , & 430 430 & ahiu (jpi,jpj) , ahiv (jpi,jpj) , & 431 & pahu (jpi,jpj) , pahv (jpi,jpj) , &432 431 & ust2s (jpi,jpj) , hicol (jpi,jpj) , & 433 432 & strp1 (jpi,jpj) , strp2 (jpi,jpj) , strength (jpi,jpj) , & … … 442 441 & wfx_res(jpi,jpj) , wfx_sni(jpi,jpj) , wfx_opw(jpi,jpj) , wfx_spr(jpi,jpj) , & 443 442 & afx_tot(jpi,jpj) , afx_thd(jpi,jpj), afx_dyn(jpi,jpj) , & 444 & fhtur (jpi,jpj) , ftr_ice(jpi,jpj,jpl), qlead (jpi,jpj) ,&445 & rn_amax_2d (jpi,jpj),&446 & sfx_res(jpi,jpj) , sfx_bri(jpi,jpj) , sfx_dyn(jpi,jpj) , sfx_sub(jpi,jpj) ,&443 & fhtur (jpi,jpj) , ftr_ice(jpi,jpj,jpl), pahu3D(jpi,jpj,jpl+1), pahv3D(jpi,jpj,jpl+1), & 444 & rn_amax_2d (jpi,jpj), qlead (jpi, jpj), & 445 & sfx_res(jpi,jpj) , sfx_bri(jpi,jpj) , sfx_dyn(jpi,jpj) , & 447 446 & sfx_bog(jpi,jpj) , sfx_bom(jpi,jpj) , sfx_sum(jpi,jpj) , sfx_sni(jpi,jpj) , sfx_opw(jpi,jpj) , & 448 447 & hfx_res(jpi,jpj) , hfx_snw(jpi,jpj) , hfx_sub(jpi,jpj) , hfx_err(jpi,jpj) , & … … 514 513 !!====================================================================== 515 514 END MODULE ice 515 -
trunk/NEMOGCM/NEMO/LIM_SRC_3/limhdf.F90
r5836 r6478 7 7 !! - ! 2001-05 (G. Madec, R. Hordoir) opa norm 8 8 !! 1.0 ! 2002-08 (C. Ethe) F90, free form 9 !! 3.0 ! 2015-08 (O. Tintó and M. Castrillo) added lim_hdf (multiple) 9 10 !!---------------------------------------------------------------------- 10 11 #if defined key_lim3 … … 27 28 PRIVATE 28 29 29 PUBLIC lim_hdf 30 PUBLIC lim_hdf ! called by lim_trp 30 31 PUBLIC lim_hdf_init ! called by sbc_lim_init 31 32 … … 43 44 CONTAINS 44 45 45 SUBROUTINE lim_hdf( ptab )46 SUBROUTINE lim_hdf( ptab , ihdf_vars , jpl , nlay_i ) 46 47 !!------------------------------------------------------------------- 47 48 !! *** ROUTINE lim_hdf *** … … 54 55 !! ** Action : update ptab with the diffusive contribution 55 56 !!------------------------------------------------------------------- 56 REAL(wp), DIMENSION(jpi,jpj), INTENT( inout ) :: ptab ! Field on which the diffusion is applied 57 ! 58 INTEGER :: ji, jj ! dummy loop indices 57 INTEGER :: jpl, nlay_i, isize, ihdf_vars 58 REAL(wp), DIMENSION(:,:,:), INTENT( inout ),TARGET :: ptab ! Field on which the diffusion is applied 59 ! 60 INTEGER :: ji, jj, jk, jl , jm ! dummy loop indices 59 61 INTEGER :: iter, ierr ! local integers 60 REAL(wp) :: zrlxint, zconv ! local scalars 61 REAL(wp), POINTER, DIMENSION(:,:) :: zrlx, zflu, zflv, zdiv0, zdiv, ztab0 62 REAL(wp) :: zrlxint ! local scalars 63 REAL(wp), POINTER , DIMENSION ( : ) :: zconv ! local scalars 64 REAL(wp), POINTER , DIMENSION(:,:,:) :: zrlx,zdiv0, ztab0 65 REAL(wp), POINTER , DIMENSION(:,:) :: zflu, zflv, zdiv 62 66 CHARACTER(lc) :: charout ! local character 63 67 REAL(wp), PARAMETER :: zrelax = 0.5_wp ! relaxation constant for iterative procedure … … 65 69 INTEGER , PARAMETER :: its = 100 ! Maximum number of iteration 66 70 !!------------------------------------------------------------------- 71 TYPE(arrayptr) , ALLOCATABLE, DIMENSION(:) :: pt2d_array, zrlx_array 72 CHARACTER(len=1) , ALLOCATABLE, DIMENSION(:) :: type_array ! define the nature of ptab array grid-points 73 ! ! = T , U , V , F , W and I points 74 REAL(wp) , ALLOCATABLE, DIMENSION(:) :: psgn_array ! =-1 the sign change across the north fold boundary 75 76 !!--------------------------------------------------------------------- 77 78 ! !== Initialisation ==! 79 ! +1 open water diffusion 80 isize = jpl*(ihdf_vars+nlay_i)+1 81 ALLOCATE( zconv (isize) ) 82 ALLOCATE( pt2d_array(isize) , zrlx_array(isize) ) 83 ALLOCATE( type_array(isize) ) 84 ALLOCATE( psgn_array(isize) ) 67 85 68 CALL wrk_alloc( jpi, jpj, zrlx, zflu, zflv, zdiv0, zdiv, ztab0 ) 69 70 ! !== Initialisation ==! 86 CALL wrk_alloc( jpi, jpj, isize, zrlx, zdiv0, ztab0 ) 87 CALL wrk_alloc( jpi, jpj, zflu, zflv, zdiv ) 88 89 DO jk= 1 , isize 90 pt2d_array(jk)%pt2d=>ptab(:,:,jk) 91 zrlx_array(jk)%pt2d=>zrlx(:,:,jk) 92 type_array(jk)='T' 93 psgn_array(jk)=1. 94 END DO 95 71 96 ! 72 97 IF( linit ) THEN ! Metric coefficient (compute at the first call and saved in efact) … … 74 99 IF( lk_mpp ) CALL mpp_sum( ierr ) 75 100 IF( ierr /= 0 ) CALL ctl_stop( 'STOP', 'lim_hdf : unable to allocate arrays' ) 76 DO jj = 2, jpjm1 101 DO jj = 2, jpjm1 77 102 DO ji = fs_2 , fs_jpim1 ! vector opt. 78 103 efact(ji,jj) = ( e2u(ji,jj) + e2u(ji-1,jj) + e1v(ji,jj) + e1v(ji,jj-1) ) * r1_e1e2t(ji,jj) … … 83 108 ! ! Time integration parameters 84 109 ! 85 ztab0(:, : ) = ptab(:,:) ! Arrays initialization 86 zdiv0(:, 1 ) = 0._wp 87 zdiv0(:,jpj) = 0._wp 88 zflu (jpi,:) = 0._wp 89 zflv (jpi,:) = 0._wp 90 zdiv0(1, :) = 0._wp 91 zdiv0(jpi,:) = 0._wp 110 zflu (jpi,: ) = 0._wp 111 zflv (jpi,: ) = 0._wp 112 113 DO jk=1 , isize 114 ztab0(:, : , jk ) = ptab(:,:,jk) ! Arrays initialization 115 zdiv0(:, 1 , jk ) = 0._wp 116 zdiv0(:,jpj, jk ) = 0._wp 117 zdiv0(1, :, jk ) = 0._wp 118 zdiv0(jpi,:, jk ) = 0._wp 119 END DO 92 120 93 121 zconv = 1._wp !== horizontal diffusion using a Crant-Nicholson scheme ==! 94 122 iter = 0 95 123 ! 96 DO WHILE( zconv> ( 2._wp * 1.e-04 ) .AND. iter <= its ) ! Sub-time step loop124 DO WHILE( MAXVAL(zconv(:)) > ( 2._wp * 1.e-04 ) .AND. iter <= its ) ! Sub-time step loop 97 125 ! 98 126 iter = iter + 1 ! incrementation of the sub-time step number 99 127 ! 128 DO jk = 1 , isize 129 jl = (jk-1) /( ihdf_vars+nlay_i)+1 130 IF (zconv(jk) > ( 2._wp * 1.e-04 )) THEN 131 DO jj = 1, jpjm1 ! diffusive fluxes in U- and V- direction 132 DO ji = 1 , fs_jpim1 ! vector opt. 133 zflu(ji,jj) = pahu3D(ji,jj,jl) * e2u(ji,jj) * r1_e1u(ji,jj) * ( ptab(ji+1,jj,jk) - ptab(ji,jj,jk) ) 134 zflv(ji,jj) = pahv3D(ji,jj,jl) * e1v(ji,jj) * r1_e2v(ji,jj) * ( ptab(ji,jj+1,jk) - ptab(ji,jj,jk) ) 135 END DO 136 END DO 137 ! 138 DO jj= 2, jpjm1 ! diffusive trend : divergence of the fluxes 139 DO ji = fs_2 , fs_jpim1 ! vector opt. 140 zdiv(ji,jj) = ( zflu(ji,jj) - zflu(ji-1,jj) + zflv(ji,jj) - zflv(ji,jj-1) ) * r1_e1e2t(ji,jj) 141 END DO 142 END DO 143 ! 144 IF( iter == 1 ) zdiv0(:,:,jk) = zdiv(:,:) ! save the 1st evaluation of the diffusive trend in zdiv0 145 ! 146 DO jj = 2, jpjm1 ! iterative evaluation 147 DO ji = fs_2 , fs_jpim1 ! vector opt. 148 zrlxint = ( ztab0(ji,jj,jk) & 149 & + rdt_ice * ( zalfa * ( zdiv(ji,jj) + efact(ji,jj) * ptab(ji,jj,jk) ) & 150 & + ( 1.0 - zalfa ) * zdiv0(ji,jj,jk) ) & 151 & ) / ( 1.0 + zalfa * rdt_ice * efact(ji,jj) ) 152 zrlx(ji,jj,jk) = ptab(ji,jj,jk) + zrelax * ( zrlxint - ptab(ji,jj,jk) ) 153 END DO 154 END DO 155 END IF 156 157 END DO 158 159 CALL lbc_lnk_multi( zrlx_array, type_array , psgn_array , isize ) ! Multiple interchange of all the variables 160 ! 161 IF ( MOD( iter-1 , nn_convfrq ) == 0 ) THEN !Convergence test every nn_convfrq iterations (perf. optimization ) 162 DO jk=1,isize 163 zconv(jk) = 0._wp ! convergence test 164 DO jj = 2, jpjm1 165 DO ji = fs_2, fs_jpim1 166 zconv(jk) = MAX( zconv(jk), ABS( zrlx(ji,jj,jk) - ptab(ji,jj,jk) ) ) 167 END DO 168 END DO 169 END DO 170 IF( lk_mpp ) CALL mpp_max_multiple( zconv , isize ) ! max over the global domain for all the variables 171 ENDIF 172 ! 173 DO jk=1,isize 174 ptab(:,:,jk) = zrlx(:,:,jk) 175 END DO 176 ! 177 END DO ! end of sub-time step loop 178 179 ! ----------------------- 180 !!! final step (clem) !!! 181 DO jk = 1, isize 182 jl = (jk-1) /( ihdf_vars+nlay_i)+1 100 183 DO jj = 1, jpjm1 ! diffusive fluxes in U- and V- direction 101 184 DO ji = 1 , fs_jpim1 ! vector opt. 102 zflu(ji,jj) = pahu (ji,jj) * e2u(ji,jj) * r1_e1u(ji,jj) * ( ptab(ji+1,jj) - ptab(ji,jj) )103 zflv(ji,jj) = pahv (ji,jj) * e1v(ji,jj) * r1_e2v(ji,jj) * ( ptab(ji,jj+1) - ptab(ji,jj) )185 zflu(ji,jj) = pahu3D(ji,jj,jl) * e2u(ji,jj) * r1_e1u(ji,jj) * ( ptab(ji+1,jj,jk) - ptab(ji,jj,jk) ) 186 zflv(ji,jj) = pahv3D(ji,jj,jl) * e1v(ji,jj) * r1_e2v(ji,jj) * ( ptab(ji,jj+1,jk) - ptab(ji,jj,jk) ) 104 187 END DO 105 188 END DO … … 108 191 DO ji = fs_2 , fs_jpim1 ! vector opt. 109 192 zdiv(ji,jj) = ( zflu(ji,jj) - zflu(ji-1,jj) + zflv(ji,jj) - zflv(ji,jj-1) ) * r1_e1e2t(ji,jj) 110 END DO 111 END DO 112 ! 113 IF( iter == 1 ) zdiv0(:,:) = zdiv(:,:) ! save the 1st evaluation of the diffusive trend in zdiv0 114 ! 115 DO jj = 2, jpjm1 ! iterative evaluation 116 DO ji = fs_2 , fs_jpim1 ! vector opt. 117 zrlxint = ( ztab0(ji,jj) & 118 & + rdt_ice * ( zalfa * ( zdiv(ji,jj) + efact(ji,jj) * ptab(ji,jj) ) & 119 & + ( 1.0 - zalfa ) * zdiv0(ji,jj) ) & 120 & ) / ( 1.0 + zalfa * rdt_ice * efact(ji,jj) ) 121 zrlx(ji,jj) = ptab(ji,jj) + zrelax * ( zrlxint - ptab(ji,jj) ) 122 END DO 123 END DO 124 CALL lbc_lnk( zrlx, 'T', 1. ) ! lateral boundary condition 125 ! 126 IF ( MOD( iter, nn_convfrq ) == 0 ) THEN ! convergence test every nn_convfrq iterations (perf. optimization) 127 zconv = 0._wp 128 DO jj = 2, jpjm1 129 DO ji = fs_2, fs_jpim1 130 zconv = MAX( zconv, ABS( zrlx(ji,jj) - ptab(ji,jj) ) ) 131 END DO 132 END DO 133 IF( lk_mpp ) CALL mpp_max( zconv ) ! max over the global domain 134 ENDIF 135 ! 136 ptab(:,:) = zrlx(:,:) 137 ! 138 END DO ! end of sub-time step loop 139 140 ! ----------------------- 141 !!! final step (clem) !!! 142 DO jj = 1, jpjm1 ! diffusive fluxes in U- and V- direction 143 DO ji = 1 , fs_jpim1 ! vector opt. 144 zflu(ji,jj) = pahu(ji,jj) * e2u(ji,jj) * r1_e1u(ji,jj) * ( ptab(ji+1,jj) - ptab(ji,jj) ) 145 zflv(ji,jj) = pahv(ji,jj) * e1v(ji,jj) * r1_e2v(ji,jj) * ( ptab(ji,jj+1) - ptab(ji,jj) ) 193 ptab(ji,jj,jk) = ztab0(ji,jj,jk) + 0.5 * ( zdiv(ji,jj) + zdiv0(ji,jj,jk) ) 194 END DO 146 195 END DO 147 196 END DO 148 ! 149 DO jj= 2, jpjm1 ! diffusive trend : divergence of the fluxes 150 DO ji = fs_2 , fs_jpim1 ! vector opt. 151 zdiv(ji,jj) = ( zflu(ji,jj) - zflu(ji-1,jj) + zflv(ji,jj) - zflv(ji,jj-1) ) * r1_e1e2t(ji,jj) 152 ptab(ji,jj) = ztab0(ji,jj) + 0.5 * ( zdiv(ji,jj) + zdiv0(ji,jj) ) 153 END DO 154 END DO 155 CALL lbc_lnk( ptab, 'T', 1. ) ! lateral boundary condition 197 198 CALL lbc_lnk_multi( pt2d_array, type_array , psgn_array , isize ) ! Multiple interchange of all the variables 199 156 200 !!! final step (clem) !!! 157 201 ! ----------------------- 158 202 159 203 IF(ln_ctl) THEN 160 zrlx(:,:) = ptab(:,:) - ztab0(:,:) 161 WRITE(charout,FMT="(' lim_hdf : zconv =',D23.16, ' iter =',I4,2X)") zconv, iter 162 CALL prt_ctl( tab2d_1=zrlx, clinfo1=charout ) 163 ENDIF 164 ! 165 CALL wrk_dealloc( jpi, jpj, zrlx, zflu, zflv, zdiv0, zdiv, ztab0 ) 204 DO jk = 1 , isize 205 zrlx(:,:,jk) = ptab(:,:,jk) - ztab0(:,:,jk) 206 WRITE(charout,FMT="(' lim_hdf : zconv =',D23.16, ' iter =',I4,2X)") zconv, iter 207 CALL prt_ctl( tab2d_1=zrlx(:,:,jk), clinfo1=charout ) 208 END DO 209 ENDIF 210 ! 211 CALL wrk_dealloc( jpi, jpj, isize, zrlx, zdiv0, ztab0 ) 212 CALL wrk_dealloc( jpi, jpj, zflu, zflv, zdiv ) 213 214 DEALLOCATE( zconv ) 215 DEALLOCATE( pt2d_array , zrlx_array ) 216 DEALLOCATE( type_array ) 217 DEALLOCATE( psgn_array ) 166 218 ! 167 219 END SUBROUTINE lim_hdf 220 168 221 169 222 … … 179 232 !!------------------------------------------------------------------- 180 233 INTEGER :: ios ! Local integer output status for namelist read 181 NAMELIST/namicehdf/ nn_convfrq 234 NAMELIST/namicehdf/ nn_convfrq 182 235 !!------------------------------------------------------------------- 183 236 ! … … 212 265 !!====================================================================== 213 266 END MODULE limhdf 267 -
trunk/NEMOGCM/NEMO/LIM_SRC_3/limtrp.F90
r6403 r6478 63 63 INTEGER, INTENT(in) :: kt ! number of iteration 64 64 ! 65 INTEGER :: ji, jj, jk, j l, jt ! dummy loop indices65 INTEGER :: ji, jj, jk, jm , jl, jt ! dummy loop indices 66 66 INTEGER :: initad ! number of sub-timestep for the advection 67 67 REAL(wp) :: zcfl , zusnit ! - - … … 75 75 REAL(wp), POINTER, DIMENSION(:,:,:) :: zhimax ! old ice thickness 76 76 REAL(wp), POINTER, DIMENSION(:,:) :: zatold, zeiold, zesold ! old concentration, enthalpies 77 REAL(wp), POINTER, DIMENSION(:,:,:) :: zhdfptab 77 78 REAL(wp) :: zdv, zvi, zvs, zsmv, zes, zei 78 79 REAL(wp) :: zvi_b, zsmv_b, zei_b, zfs_b, zfw_b, zft_b 80 !!--------------------------------------------------------------------- 81 INTEGER :: ihdf_vars = 6 !!Number of variables in which we apply horizontal diffusion 82 !! inside limtrp for each ice category , not counting the 83 !! variables corresponding to ice_layers 79 84 !!--------------------------------------------------------------------- 80 85 IF( nn_timing == 1 ) CALL timing_start('limtrp') … … 85 90 CALL wrk_alloc( jpi,jpj,nlay_i,jpl, z0ei ) 86 91 CALL wrk_alloc( jpi,jpj,jpl, zhimax, zviold, zvsold, zsmvold ) 92 CALL wrk_alloc( jpi,jpj,jpl*(ihdf_vars + nlay_i)+1,zhdfptab) 87 93 88 94 IF( numit == nstart .AND. lwp ) THEN … … 170 176 z0oi (:,:,jl) = oa_i (:,:, jl) * e1e2t(:,:) ! Age content 171 177 z0es (:,:,jl) = e_s (:,:,1,jl) * e1e2t(:,:) ! Snow heat content 172 178 DO jk = 1, nlay_i 173 179 z0ei (:,:,jk,jl) = e_i (:,:,jk,jl) * e1e2t(:,:) ! Ice heat content 174 180 END DO … … 284 290 ! Diffusion of Ice fields 285 291 !------------------------------------------------------------------------------! 286 292 !------------------------------------ 293 ! Diffusion of other ice variables 294 !------------------------------------ 295 jm=1 296 DO jl = 1, jpl 297 ! ! Masked eddy diffusivity coefficient at ocean U- and V-points 298 ! DO jj = 1, jpjm1 ! NB: has not to be defined on jpj line and jpi row 299 ! DO ji = 1 , fs_jpim1 ! vector opt. 300 ! pahu(ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji ,jj,jl) ) ) ) & 301 ! & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji+1,jj,jl) ) ) ) * ahiu(ji,jj) 302 ! pahv(ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji,jj ,jl) ) ) ) & 303 ! & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp,- a_i(ji,jj+1,jl) ) ) ) * ahiv(ji,jj) 304 ! END DO 305 ! END DO 306 DO jj = 1, jpjm1 ! NB: has not to be defined on jpj line and jpi row 307 DO ji = 1 , fs_jpim1 ! vector opt. 308 pahu3D(ji,jj,jl) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji ,jj, jl ) ) ) ) & 309 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji+1,jj, jl ) ) ) ) * ahiu(ji,jj) 310 pahv3D(ji,jj,jl) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji, jj, jl ) ) ) ) & 311 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp,- a_i(ji, jj+1,jl ) ) ) ) * ahiv(ji,jj) 312 END DO 313 END DO 314 315 zhdfptab(:,:,jm)= a_i (:,:, jl); jm = jm + 1 316 zhdfptab(:,:,jm)= v_i (:,:, jl); jm = jm + 1 317 zhdfptab(:,:,jm)= v_s (:,:, jl); jm = jm + 1 318 zhdfptab(:,:,jm)= smv_i(:,:, jl); jm = jm + 1 319 zhdfptab(:,:,jm)= oa_i (:,:, jl); jm = jm + 1 320 zhdfptab(:,:,jm)= e_s (:,:,1,jl); jm = jm + 1 321 ! Sample of adding more variables to apply lim_hdf using lim_hdf optimization--- 322 ! zhdfptab(:,:,jm) = variable_1 (:,:,1,jl); jm = jm + 1 323 ! zhdfptab(:,:,jm) = variable_2 (:,:,1,jl); jm = jm + 1 324 ! 325 ! and in this example the parameter ihdf_vars musb be changed to 8 (necessary for allocation) 326 !---------------------------------------------------------------------------------------- 327 DO jk = 1, nlay_i 328 zhdfptab(:,:,jm)=e_i(:,:,jk,jl); jm= jm+1 329 END DO 330 END DO 287 331 ! 288 332 !-------------------------------- … … 290 334 !-------------------------------- 291 335 ! ! Masked eddy diffusivity coefficient at ocean U- and V-points 336 !DO jj = 1, jpjm1 ! NB: has not to be defined on jpj line and jpi row 337 ! DO ji = 1 , fs_jpim1 ! vector opt. 338 ! pahu(ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji ,jj) ) ) ) & 339 ! & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji+1,jj) ) ) ) * ahiu(ji,jj) 340 ! pahv(ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji,jj ) ) ) ) & 341 ! & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp,- at_i(ji,jj+1) ) ) ) * ahiv(ji,jj) 342 ! END DO 343 !END DO 344 292 345 DO jj = 1, jpjm1 ! NB: has not to be defined on jpj line and jpi row 293 346 DO ji = 1 , fs_jpim1 ! vector opt. 294 pahu (ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji ,jj) ) ) ) &295 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji+1,jj) ) ) ) * ahiu(ji,jj)296 pahv (ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji,jj ) ) ) ) &297 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp,- at_i(ji,jj+1) ) ) ) * ahiv(ji,jj)347 pahu3D(ji,jj,jpl+1) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji ,jj) ) ) ) & 348 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji+1,jj) ) ) ) * ahiu(ji,jj) 349 pahv3D(ji,jj,jpl+1) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -at_i(ji,jj ) ) ) ) & 350 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp,- at_i(ji,jj+1) ) ) ) * ahiv(ji,jj) 298 351 END DO 299 352 END DO 300 353 ! 301 CALL lim_hdf( ato_i (:,:) ) 302 303 !------------------------------------ 304 ! Diffusion of other ice variables 305 !------------------------------------ 306 DO jl = 1, jpl 307 ! ! Masked eddy diffusivity coefficient at ocean U- and V-points 308 DO jj = 1, jpjm1 ! NB: has not to be defined on jpj line and jpi row 309 DO ji = 1 , fs_jpim1 ! vector opt. 310 pahu(ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji ,jj,jl) ) ) ) & 311 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji+1,jj,jl) ) ) ) * ahiu(ji,jj) 312 pahv(ji,jj) = ( 1._wp - MAX( 0._wp, SIGN( 1._wp, -a_i(ji,jj ,jl) ) ) ) & 313 & * ( 1._wp - MAX( 0._wp, SIGN( 1._wp,- a_i(ji,jj+1,jl) ) ) ) * ahiv(ji,jj) 314 END DO 315 END DO 316 317 CALL lim_hdf( v_i (:,:, jl) ) 318 CALL lim_hdf( v_s (:,:, jl) ) 319 CALL lim_hdf( smv_i(:,:, jl) ) 320 CALL lim_hdf( oa_i (:,:, jl) ) 321 CALL lim_hdf( a_i (:,:, jl) ) 322 CALL lim_hdf( e_s (:,:,1,jl) ) 354 zhdfptab(:,:,jm)= ato_i (:,:); 355 CALL lim_hdf( zhdfptab, ihdf_vars, jpl, nlay_i) 356 357 jm=1 358 DO jl = 1, jpl 359 a_i (:,:, jl) = zhdfptab(:,:,jm); jm = jm + 1 360 v_i (:,:, jl) = zhdfptab(:,:,jm); jm = jm + 1 361 v_s (:,:, jl) = zhdfptab(:,:,jm); jm = jm + 1 362 smv_i(:,:, jl) = zhdfptab(:,:,jm); jm = jm + 1 363 oa_i (:,:, jl) = zhdfptab(:,:,jm); jm = jm + 1 364 e_s (:,:,1,jl) = zhdfptab(:,:,jm); jm = jm + 1 365 ! Sample of adding more variables to apply lim_hdf--------- 366 ! variable_1 (:,:,1,jl) = zhdfptab(:,:, jm ) ; jm + 1 367 ! variable_2 (:,:,1,jl) = zhdfptab(:,:, jm ) ; jm + 1 368 !----------------------------------------------------------- 323 369 DO jk = 1, nlay_i 324 CALL lim_hdf( e_i(:,:,jk,jl) ) 325 END DO 326 END DO 370 e_i(:,:,jk,jl) = zhdfptab(:,:,jm);jm= jm + 1 371 END DO 372 END DO 373 374 ato_i (:,:) = zhdfptab(:,:,jm) 327 375 328 376 !------------------------------------------------------------------------------! … … 464 512 CALL wrk_dealloc( jpi,jpj,nlay_i,jpl, z0ei ) 465 513 CALL wrk_dealloc( jpi,jpj,jpl, zviold, zvsold, zhimax, zsmvold ) 514 CALL wrk_dealloc( jpi,jpj,jpl*(ihdf_vars+nlay_i)+1,zhdfptab) 466 515 ! 467 516 IF( nn_timing == 1 ) CALL timing_stop('limtrp') … … 479 528 !!====================================================================== 480 529 END MODULE limtrp 530 -
trunk/NEMOGCM/NEMO/OPA_SRC/LBC/lbclnk.F90
r6140 r6478 9 9 !! 3.5 ! 2012 (S.Mocavero, I. Epicoco) optimization of BDY comm. via lbc_bdy_lnk and lbc_obc_lnk 10 10 !! 3.4 ! 2012-12 (R. Bourdalle-Badie, G. Reffray) add a C1D case 11 !! 3.6 ! 2015-06 (O. Tintó and M. Castrillo) add lbc_lnk_multi 11 12 !!---------------------------------------------------------------------- 12 13 #if defined key_mpp_mpi … … 22 23 23 24 INTERFACE lbc_lnk_multi 24 MODULE PROCEDURE mpp_lnk_2d_9 25 MODULE PROCEDURE mpp_lnk_2d_9, mpp_lnk_2d_multiple 25 26 END INTERFACE 26 27 ! … … 90 91 END INTERFACE 91 92 ! 93 INTERFACE lbc_lnk_multi 94 MODULE PROCEDURE lbc_lnk_2d_9, lbc_lnk_2d_multiple 95 END INTERFACE 96 92 97 INTERFACE lbc_bdy_lnk 93 98 MODULE PROCEDURE lbc_bdy_lnk_2d, lbc_bdy_lnk_3d … … 97 102 MODULE PROCEDURE lbc_lnk_2d_e 98 103 END INTERFACE 104 105 TYPE arrayptr 106 REAL , DIMENSION (:,:), POINTER :: pt2d 107 END TYPE arrayptr 108 PUBLIC arrayptr 99 109 100 110 PUBLIC lbc_lnk ! ocean/ice lateral boundary conditions 101 111 PUBLIC lbc_lnk_e ! 112 PUBLIC lbc_lnk_multi ! modified ocean lateral boundary conditions 102 113 PUBLIC lbc_bdy_lnk ! ocean lateral BDY boundary conditions 103 114 PUBLIC lbc_lnk_icb ! … … 181 192 ! 182 193 END SUBROUTINE lbc_lnk_2d 194 195 SUBROUTINE lbc_lnk_2d_multiple( pt2d_array , type_array , psgn_array , num_fields ) 196 !! 197 INTEGER :: num_fields 198 TYPE( arrayptr ), DIMENSION(:) :: pt2d_array 199 CHARACTER(len=1), DIMENSION(:), INTENT(in ) :: type_array ! define the nature of ptab array grid-points 200 ! ! = T , U , V , F , W and I points 201 REAL(wp) , DIMENSION(:), INTENT(in ) :: psgn_array ! =-1 the sign change across the north fold boundary 202 ! ! = 1. , the sign is kept 203 ! 204 INTEGER :: ii !!MULTI SEND DUMMY LOOP INDICES 205 ! 206 DO ii = 1, num_fields 207 CALL lbc_lnk_2d( pt2d_array(ii)%pt2d, type_array(ii), psgn_array(ii) ) 208 END DO 209 ! 210 END SUBROUTINE lbc_lnk_2d_multiple 211 212 SUBROUTINE lbc_lnk_2d_9( pt2dA, cd_typeA, psgnA, pt2dB, cd_typeB, psgnB, pt2dC, cd_typeC, psgnC & 213 & , pt2dD, cd_typeD, psgnD, pt2dE, cd_typeE, psgnE, pt2dF, cd_typeF, psgnF & 214 & , pt2dG, cd_typeG, psgnG, pt2dH, cd_typeH, psgnH, pt2dI, cd_typeI, psgnI, cd_mpp, pval) 215 !!--------------------------------------------------------------------- 216 ! Second 2D array on which the boundary condition is applied 217 REAL(wp), DIMENSION(jpi,jpj), TARGET , INTENT(inout) :: pt2dA 218 REAL(wp), DIMENSION(jpi,jpj), TARGET, OPTIONAL, INTENT(inout) :: pt2dB , pt2dC , pt2dD , pt2dE 219 REAL(wp), DIMENSION(jpi,jpj), TARGET, OPTIONAL, INTENT(inout) :: pt2dF , pt2dG , pt2dH , pt2dI 220 ! define the nature of ptab array grid-points 221 CHARACTER(len=1) , INTENT(in ) :: cd_typeA 222 CHARACTER(len=1) , OPTIONAL, INTENT(in ) :: cd_typeB , cd_typeC , cd_typeD , cd_typeE 223 CHARACTER(len=1) , OPTIONAL, INTENT(in ) :: cd_typeF , cd_typeG , cd_typeH , cd_typeI 224 ! =-1 the sign change across the north fold boundary 225 REAL(wp) , INTENT(in ) :: psgnA 226 REAL(wp) , OPTIONAL, INTENT(in ) :: psgnB , psgnC , psgnD , psgnE 227 REAL(wp) , OPTIONAL, INTENT(in ) :: psgnF , psgnG , psgnH , psgnI 228 CHARACTER(len=3) , OPTIONAL, INTENT(in ) :: cd_mpp ! fill the overlap area only 229 REAL(wp) , OPTIONAL, INTENT(in ) :: pval ! background value (used at closed boundaries) 230 !! 231 !!--------------------------------------------------------------------- 232 233 !!The first array 234 CALL lbc_lnk( pt2dA, cd_typeA, psgnA ) 235 236 !! Look if more arrays to process 237 IF(PRESENT (psgnB) )CALL lbc_lnk( pt2dA, cd_typeA, psgnA ) 238 IF(PRESENT (psgnC) )CALL lbc_lnk( pt2dC, cd_typeC, psgnC ) 239 IF(PRESENT (psgnD) )CALL lbc_lnk( pt2dD, cd_typeD, psgnD ) 240 IF(PRESENT (psgnE) )CALL lbc_lnk( pt2dE, cd_typeE, psgnE ) 241 IF(PRESENT (psgnF) )CALL lbc_lnk( pt2dF, cd_typeF, psgnF ) 242 IF(PRESENT (psgnG) )CALL lbc_lnk( pt2dG, cd_typeG, psgnG ) 243 IF(PRESENT (psgnH) )CALL lbc_lnk( pt2dH, cd_typeH, psgnH ) 244 IF(PRESENT (psgnI) )CALL lbc_lnk( pt2dI, cd_typeI, psgnI ) 245 246 END SUBROUTINE lbc_lnk_2d_9 247 248 249 250 183 251 184 252 #else … … 379 447 ! 380 448 END SUBROUTINE lbc_lnk_2d 449 450 SUBROUTINE lbc_lnk_2d_multiple( pt2d_array , type_array , psgn_array , num_fields ) 451 !! 452 INTEGER :: num_fields 453 TYPE( arrayptr ), DIMENSION(:) :: pt2d_array 454 CHARACTER(len=1), DIMENSION(:), INTENT(in ) :: type_array ! define the nature of ptab array grid-points 455 ! ! = T , U , V , F , W and I points 456 REAL(wp) , DIMENSION(:), INTENT(in ) :: psgn_array ! =-1 the sign change across the north fold boundary 457 ! ! = 1. , the sign is kept 458 ! 459 INTEGER :: ii !!MULTI SEND DUMMY LOOP INDICES 460 ! 461 DO ii = 1, num_fields 462 CALL lbc_lnk_2d( pt2d_array(ii)%pt2d, type_array(ii), psgn_array(ii) ) 463 END DO 464 ! 465 END SUBROUTINE lbc_lnk_2d_multiple 466 467 SUBROUTINE lbc_lnk_2d_9( pt2dA, cd_typeA, psgnA, pt2dB, cd_typeB, psgnB, pt2dC, cd_typeC, psgnC & 468 & , pt2dD, cd_typeD, psgnD, pt2dE, cd_typeE, psgnE, pt2dF, cd_typeF, psgnF & 469 & , pt2dG, cd_typeG, psgnG, pt2dH, cd_typeH, psgnH, pt2dI, cd_typeI, psgnI, cd_mpp, pval) 470 !!--------------------------------------------------------------------- 471 ! Second 2D array on which the boundary condition is applied 472 REAL(wp), DIMENSION(jpi,jpj), TARGET , INTENT(inout) :: pt2dA 473 REAL(wp), DIMENSION(jpi,jpj), TARGET, OPTIONAL, INTENT(inout) :: pt2dB , pt2dC , pt2dD , pt2dE 474 REAL(wp), DIMENSION(jpi,jpj), TARGET, OPTIONAL, INTENT(inout) :: pt2dF , pt2dG , pt2dH , pt2dI 475 ! define the nature of ptab array grid-points 476 CHARACTER(len=1) , INTENT(in ) :: cd_typeA 477 CHARACTER(len=1) , OPTIONAL, INTENT(in ) :: cd_typeB , cd_typeC , cd_typeD , cd_typeE 478 CHARACTER(len=1) , OPTIONAL, INTENT(in ) :: cd_typeF , cd_typeG , cd_typeH , cd_typeI 479 ! =-1 the sign change across the north fold boundary 480 REAL(wp) , INTENT(in ) :: psgnA 481 REAL(wp) , OPTIONAL, INTENT(in ) :: psgnB , psgnC , psgnD , psgnE 482 REAL(wp) , OPTIONAL, INTENT(in ) :: psgnF , psgnG , psgnH , psgnI 483 CHARACTER(len=3) , OPTIONAL, INTENT(in ) :: cd_mpp ! fill the overlap area only 484 REAL(wp) , OPTIONAL, INTENT(in ) :: pval ! background value (used at closed boundaries) 485 !! 486 !!--------------------------------------------------------------------- 487 488 !!The first array 489 CALL lbc_lnk( pt2dA, cd_typeA, psgnA ) 490 491 !! Look if more arrays to process 492 IF(PRESENT (psgnB) )CALL lbc_lnk( pt2dA, cd_typeA, psgnA ) 493 IF(PRESENT (psgnC) )CALL lbc_lnk( pt2dC, cd_typeC, psgnC ) 494 IF(PRESENT (psgnD) )CALL lbc_lnk( pt2dD, cd_typeD, psgnD ) 495 IF(PRESENT (psgnE) )CALL lbc_lnk( pt2dE, cd_typeE, psgnE ) 496 IF(PRESENT (psgnF) )CALL lbc_lnk( pt2dF, cd_typeF, psgnF ) 497 IF(PRESENT (psgnG) )CALL lbc_lnk( pt2dG, cd_typeG, psgnG ) 498 IF(PRESENT (psgnH) )CALL lbc_lnk( pt2dH, cd_typeH, psgnH ) 499 IF(PRESENT (psgnI) )CALL lbc_lnk( pt2dI, cd_typeI, psgnI ) 500 501 END SUBROUTINE lbc_lnk_2d_9 502 381 503 382 504 #endif … … 448 570 !!====================================================================== 449 571 END MODULE lbclnk 572 -
trunk/NEMOGCM/NEMO/OPA_SRC/LBC/lib_mpp.F90
r6140 r6478 24 24 !! 3.5 ! 2013 ( C. Ethe, G. Madec ) message passing arrays as local variables 25 25 !! 3.5 ! 2013 (S.Mocavero, I.Epicoco - CMCC) north fold optimizations 26 !! 3.6 ! 2015 (O. Tintó and M. Castrillo - BSC) Added 'mpp_lnk_2d_multiple', 'mpp_lbc_north_2d_multiple', 'mpp_max_multiple' 26 27 !!---------------------------------------------------------------------- 27 28 … … 62 63 USE lbcnfd ! north fold treatment 63 64 USE in_out_manager ! I/O manager 65 USE wrk_nemo ! work arrays 64 66 65 67 IMPLICIT NONE … … 70 72 PUBLIC mpp_ini_north, mpp_lbc_north, mpp_lbc_north_e 71 73 PUBLIC mpp_min, mpp_max, mpp_sum, mpp_minloc, mpp_maxloc 74 PUBLIC mpp_max_multiple 72 75 PUBLIC mpp_lnk_3d, mpp_lnk_3d_gather, mpp_lnk_2d, mpp_lnk_2d_e 73 PUBLIC mpp_lnk_2d_9 76 PUBLIC mpp_lnk_2d_9 , mpp_lnk_2d_multiple 74 77 PUBLIC mpp_lnk_sum_3d, mpp_lnk_sum_2d 75 78 PUBLIC mppscatter, mppgather … … 79 82 PUBLIC mpp_lnk_bdy_2d, mpp_lnk_bdy_3d 80 83 PUBLIC mpp_lbc_north_icb, mpp_lnk_2d_icb 84 PUBLIC mpprank 81 85 82 86 TYPE arrayptr 83 87 REAL , DIMENSION (:,:), POINTER :: pt2d 84 88 END TYPE arrayptr 89 PUBLIC arrayptr 85 90 86 91 !! * Interfaces … … 106 111 INTERFACE mpp_maxloc 107 112 MODULE PROCEDURE mpp_maxloc2d ,mpp_maxloc3d 113 END INTERFACE 114 115 INTERFACE mpp_max_multiple 116 MODULE PROCEDURE mppmax_real_multiple 108 117 END INTERFACE 109 118 … … 726 735 ! ----------------------- 727 736 ! 728 DO ii = 1 , num_fields729 737 !First Array 730 IF( npolj /= 0 .AND. .NOT. PRESENT(cd_mpp) ) THEN 731 ! 732 SELECT CASE ( jpni ) 733 CASE ( 1 ) ; CALL lbc_nfd ( pt2d_array(ii)%pt2d( : , : ), type_array(ii) , psgn_array(ii) ) ! only 1 northern proc, no mpp 734 CASE DEFAULT ; CALL mpp_lbc_north( pt2d_array(ii)%pt2d( : , : ), type_array(ii), psgn_array(ii) ) ! for all northern procs. 735 END SELECT 736 ! 737 ENDIF 738 ! 739 END DO 738 IF( npolj /= 0 .AND. .NOT. PRESENT(cd_mpp) ) THEN 739 ! 740 SELECT CASE ( jpni ) 741 CASE ( 1 ) ; 742 DO ii = 1 , num_fields 743 CALL lbc_nfd ( pt2d_array(ii)%pt2d( : , : ), type_array(ii) , psgn_array(ii) ) ! only 1 northern proc, no mpp 744 END DO 745 CASE DEFAULT ; CALL mpp_lbc_north_2d_multiple( pt2d_array, type_array, psgn_array, num_fields ) ! for all northern procs. 746 END SELECT 747 ! 748 ENDIF 749 ! 740 750 ! 741 751 DEALLOCATE( zt2ns, zt2sn, zt2ew, zt2we ) … … 2019 2029 END SUBROUTINE mppmax_real 2020 2030 2031 SUBROUTINE mppmax_real_multiple( ptab, NUM , kcom ) 2032 !!---------------------------------------------------------------------- 2033 !! *** routine mppmax_real *** 2034 !! 2035 !! ** Purpose : Maximum 2036 !! 2037 !!---------------------------------------------------------------------- 2038 REAL(wp), DIMENSION(:) , INTENT(inout) :: ptab ! ??? 2039 INTEGER , INTENT(in ) :: NUM 2040 INTEGER , INTENT(in ), OPTIONAL :: kcom ! ??? 2041 !! 2042 INTEGER :: ierror, localcomm 2043 REAL(wp) , POINTER , DIMENSION(:) :: zwork 2044 !!---------------------------------------------------------------------- 2045 ! 2046 CALL wrk_alloc(NUM , zwork) 2047 localcomm = mpi_comm_opa 2048 IF( PRESENT(kcom) ) localcomm = kcom 2049 ! 2050 CALL mpi_allreduce( ptab, zwork, NUM, mpi_double_precision, mpi_max, localcomm, ierror ) 2051 ptab = zwork 2052 CALL wrk_dealloc(NUM , zwork) 2053 ! 2054 END SUBROUTINE mppmax_real_multiple 2055 2021 2056 2022 2057 SUBROUTINE mppmin_a_real( ptab, kdim, kcom ) … … 2912 2947 END SUBROUTINE mpp_lbc_north_2d 2913 2948 2949 SUBROUTINE mpp_lbc_north_2d_multiple( pt2d_array, cd_type, psgn, num_fields) 2950 !!--------------------------------------------------------------------- 2951 !! *** routine mpp_lbc_north_2d *** 2952 !! 2953 !! ** Purpose : Ensure proper north fold horizontal bondary condition 2954 !! in mpp configuration in case of jpn1 > 1 2955 !! (for multiple 2d arrays ) 2956 !! 2957 !! ** Method : North fold condition and mpp with more than one proc 2958 !! in i-direction require a specific treatment. We gather 2959 !! the 4 northern lines of the global domain on 1 processor 2960 !! and apply lbc north-fold on this sub array. Then we 2961 !! scatter the north fold array back to the processors. 2962 !! 2963 !!---------------------------------------------------------------------- 2964 INTEGER , INTENT (in ) :: num_fields ! number of variables contained in pt2d 2965 TYPE( arrayptr ), DIMENSION(:) :: pt2d_array 2966 CHARACTER(len=1), DIMENSION(:), INTENT(in ) :: cd_type ! nature of pt2d grid-points 2967 ! ! = T , U , V , F or W gridpoints 2968 REAL(wp), DIMENSION(:), INTENT(in ) :: psgn ! = -1. the sign change across the north fold 2969 !! ! = 1. , the sign is kept 2970 INTEGER :: ji, jj, jr, jk 2971 INTEGER :: ierr, itaille, ildi, ilei, iilb 2972 INTEGER :: ijpj, ijpjm1, ij, iproc 2973 INTEGER, DIMENSION (jpmaxngh) :: ml_req_nf !for mpi_isend when avoiding mpi_allgather 2974 INTEGER :: ml_err ! for mpi_isend when avoiding mpi_allgather 2975 INTEGER, DIMENSION(MPI_STATUS_SIZE):: ml_stat ! for mpi_isend when avoiding mpi_allgather 2976 ! ! Workspace for message transfers avoiding mpi_allgather 2977 REAL(wp), DIMENSION(:,:,:) , ALLOCATABLE :: ztab 2978 REAL(wp), DIMENSION(:,:,:) , ALLOCATABLE :: znorthloc, zfoldwk 2979 REAL(wp), DIMENSION(:,:,:,:), ALLOCATABLE :: znorthgloio 2980 REAL(wp), DIMENSION(:,:,:) , ALLOCATABLE :: ztabl, ztabr 2981 INTEGER :: istatus(mpi_status_size) 2982 INTEGER :: iflag 2983 !!---------------------------------------------------------------------- 2984 ! 2985 ALLOCATE( ztab(jpiglo,4,num_fields), znorthloc(jpi,4,num_fields), zfoldwk(jpi,4,num_fields), znorthgloio(jpi,4,num_fields,jpni) ) ! expanded to 3 dimensions 2986 ALLOCATE( ztabl(jpi,4,num_fields), ztabr(jpi*jpmaxngh, 4,num_fields) ) 2987 ! 2988 ijpj = 4 2989 ijpjm1 = 3 2990 ! 2991 2992 DO jk = 1, num_fields 2993 DO jj = nlcj-ijpj+1, nlcj ! put in znorthloc the last 4 jlines of pt2d (for every variable) 2994 ij = jj - nlcj + ijpj 2995 znorthloc(:,ij,jk) = pt2d_array(jk)%pt2d(:,jj) 2996 END DO 2997 END DO 2998 ! ! Build in procs of ncomm_north the znorthgloio 2999 itaille = jpi * ijpj 3000 3001 IF ( l_north_nogather ) THEN 3002 ! 3003 ! Avoid the use of mpi_allgather by exchanging only with the processes already identified 3004 ! (in nemo_northcomms) as being involved in this process' northern boundary exchange 3005 ! 3006 ztabr(:,:,:) = 0 3007 ztabl(:,:,:) = 0 3008 3009 DO jk = 1, num_fields 3010 DO jj = nlcj-ijpj+1, nlcj ! First put local values into the global array 3011 ij = jj - nlcj + ijpj 3012 DO ji = nfsloop, nfeloop 3013 ztabl(ji,ij,jk) = pt2d_array(jk)%pt2d(ji,jj) 3014 END DO 3015 END DO 3016 END DO 3017 3018 DO jr = 1,nsndto 3019 IF ((nfipproc(isendto(jr),jpnj) .ne. (narea-1)) .and. (nfipproc(isendto(jr),jpnj) .ne. -1)) THEN 3020 CALL mppsend(5, znorthloc, itaille*num_fields, nfipproc(isendto(jr),jpnj), ml_req_nf(jr)) ! Buffer expanded "num_fields" times 3021 ENDIF 3022 END DO 3023 DO jr = 1,nsndto 3024 iproc = nfipproc(isendto(jr),jpnj) 3025 IF(iproc .ne. -1) THEN 3026 ilei = nleit (iproc+1) 3027 ildi = nldit (iproc+1) 3028 iilb = nfiimpp(isendto(jr),jpnj) - nfiimpp(isendto(1),jpnj) 3029 ENDIF 3030 IF((iproc .ne. (narea-1)) .and. (iproc .ne. -1)) THEN 3031 CALL mpprecv(5, zfoldwk, itaille*num_fields, iproc) ! Buffer expanded "num_fields" times 3032 DO jk = 1 , num_fields 3033 DO jj = 1, ijpj 3034 DO ji = ildi, ilei 3035 ztabr(iilb+ji,jj,jk) = zfoldwk(ji,jj,jk) ! Modified to 3D 3036 END DO 3037 END DO 3038 END DO 3039 ELSE IF (iproc .eq. (narea-1)) THEN 3040 DO jk = 1, num_fields 3041 DO jj = 1, ijpj 3042 DO ji = ildi, ilei 3043 ztabr(iilb+ji,jj,jk) = pt2d_array(jk)%pt2d(ji,nlcj-ijpj+jj) ! Modified to 3D 3044 END DO 3045 END DO 3046 END DO 3047 ENDIF 3048 END DO 3049 IF (l_isend) THEN 3050 DO jr = 1,nsndto 3051 IF ((nfipproc(isendto(jr),jpnj) .ne. (narea-1)) .and. (nfipproc(isendto(jr),jpnj) .ne. -1)) THEN 3052 CALL mpi_wait(ml_req_nf(jr), ml_stat, ml_err) 3053 ENDIF 3054 END DO 3055 ENDIF 3056 ! 3057 DO ji = 1, num_fields ! Loop to manage 3D variables 3058 CALL mpp_lbc_nfd( ztabl(:,:,ji), ztabr(:,:,ji), cd_type(ji), psgn(ji) ) ! North fold boundary condition 3059 END DO 3060 ! 3061 DO jk = 1, num_fields 3062 DO jj = nlcj-ijpj+1, nlcj ! Scatter back to pt2d 3063 ij = jj - nlcj + ijpj 3064 DO ji = 1, nlci 3065 pt2d_array(jk)%pt2d(ji,jj) = ztabl(ji,ij,jk) ! Modified to 3D 3066 END DO 3067 END DO 3068 END DO 3069 3070 ! 3071 ELSE 3072 ! 3073 CALL MPI_ALLGATHER( znorthloc , itaille*num_fields, MPI_DOUBLE_PRECISION, & 3074 & znorthgloio, itaille*num_fields, MPI_DOUBLE_PRECISION, ncomm_north, ierr ) 3075 ! 3076 ztab(:,:,:) = 0.e0 3077 DO jk = 1, num_fields 3078 DO jr = 1, ndim_rank_north ! recover the global north array 3079 iproc = nrank_north(jr) + 1 3080 ildi = nldit (iproc) 3081 ilei = nleit (iproc) 3082 iilb = nimppt(iproc) 3083 DO jj = 1, ijpj 3084 DO ji = ildi, ilei 3085 ztab(ji+iilb-1,jj,jk) = znorthgloio(ji,jj,jk,jr) 3086 END DO 3087 END DO 3088 END DO 3089 END DO 3090 3091 DO ji = 1, num_fields 3092 CALL lbc_nfd( ztab(:,:,ji), cd_type(ji), psgn(ji) ) ! North fold boundary condition 3093 END DO 3094 ! 3095 DO jk = 1, num_fields 3096 DO jj = nlcj-ijpj+1, nlcj ! Scatter back to pt2d 3097 ij = jj - nlcj + ijpj 3098 DO ji = 1, nlci 3099 pt2d_array(jk)%pt2d(ji,jj) = ztab(ji+nimpp-1,ij,jk) 3100 END DO 3101 END DO 3102 END DO 3103 ! 3104 ! 3105 ENDIF 3106 DEALLOCATE( ztab, znorthloc, zfoldwk, znorthgloio ) 3107 DEALLOCATE( ztabl, ztabr ) 3108 ! 3109 END SUBROUTINE mpp_lbc_north_2d_multiple 2914 3110 2915 3111 SUBROUTINE mpp_lbc_north_e( pt2d, cd_type, psgn)
Note: See TracChangeset
for help on using the changeset viewer.