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MODULE step
!!======================================================================
!! *** MODULE step ***
!! Time-stepping : manager of the ocean, tracer and ice time stepping
!!======================================================================
!! History : OPA ! 1991-03 (G. Madec) Original code
!! - ! 1991-11 (G. Madec)
!! - ! 1992-06 (M. Imbard) add a first output record
!! - ! 1996-04 (G. Madec) introduction of dynspg
!! - ! 1996-04 (M.A. Foujols) introduction of passive tracer
!! 8.0 ! 1997-06 (G. Madec) new architecture of call
!! 8.2 ! 1997-06 (G. Madec, M. Imbard, G. Roullet) free surface
!! - ! 1999-02 (G. Madec, N. Grima) hpg implicit
!! - ! 2000-07 (J-M Molines, M. Imbard) Open Bondary Conditions
!! NEMO 1.0 ! 2002-06 (G. Madec) free form, suppress macro-tasking
!! - ! 2004-08 (C. Talandier) New trends organization
!! - ! 2005-01 (C. Ethe) Add the KPP closure scheme
!! - ! 2005-11 (G. Madec) Reorganisation of tra and dyn calls
!! - ! 2006-01 (L. Debreu, C. Mazauric) Agrif implementation
!! - ! 2006-07 (S. Masson) restart using iom
!! 3.2 ! 2009-02 (G. Madec, R. Benshila) reintroduicing z*-coordinate
!! - ! 2009-06 (S. Masson, G. Madec) TKE restart compatible with key_cpl
!! 3.3 ! 2010-05 (K. Mogensen, A. Weaver, M. Martin, D. Lea) Assimilation interface
!! - ! 2010-10 (C. Ethe, G. Madec) reorganisation of initialisation phase + merge TRC-TRA
!! 3.4 ! 2011-04 (G. Madec, C. Ethe) Merge of dtatem and dtasal
!! 3.6 ! 2012-07 (J. Simeon, G. Madec. C. Ethe) Online coarsening of outputs
!! 3.6 ! 2014-04 (F. Roquet, G. Madec) New equations of state
!! 3.6 ! 2014-10 (E. Clementi, P. Oddo) Add Qiao vertical mixing in case of waves
!! 3.7 ! 2014-10 (G. Madec) LDF simplication
!! - ! 2014-12 (G. Madec) remove KPP scheme
!! - ! 2015-11 (J. Chanut) free surface simplification (remove filtered free surface)
!! 4.0 ! 2017-05 (G. Madec) introduction of the vertical physics manager (zdfphy)
!! 4.1 ! 2019-08 (A. Coward, D. Storkey) rewrite in preparation for new timestepping scheme
!!----------------------------------------------------------------------
#if defined key_qco || defined key_linssh
!!----------------------------------------------------------------------
!! 'key_qco' EMPTY MODULE Quasi-Eulerian vertical coordinate
!! OR
!! 'key_linssh EMPTY MODULE Fixed in time vertical coordinate
!!----------------------------------------------------------------------
#else
!!----------------------------------------------------------------------
!! stp : OCE system time-stepping
!!----------------------------------------------------------------------
USE step_oce ! time stepping definition modules
IMPLICIT NONE
PRIVATE
PUBLIC stp ! called by nemogcm.F90
! !** time level indices **!
INTEGER, PUBLIC :: Nbb, Nnn, Naa, Nrhs !: used by nemo_init
!! * Substitutions
# include "do_loop_substitute.h90"
!!----------------------------------------------------------------------
!! NEMO/OCE 4.0 , NEMO Consortium (2018)
!! $Id: step.F90 15398 2021-10-19 08:49:42Z timgraham $
!! Software governed by the CeCILL license (see ./LICENSE)
!!----------------------------------------------------------------------
CONTAINS
#if defined key_agrif
RECURSIVE SUBROUTINE stp( )
INTEGER :: kstp ! ocean time-step index
#else
SUBROUTINE stp( kstp )
INTEGER, INTENT(in) :: kstp ! ocean time-step index
#endif
!!----------------------------------------------------------------------
!! *** ROUTINE stp ***
!!
!! ** Purpose : - Time stepping of OCE (momentum and active tracer eqs.)
!! - Time stepping of SI3 (dynamic and thermodynamic eqs.)
!! - Time stepping of TRC (passive tracer eqs.)
!!
!! ** Method : -1- Update forcings and data
!! -2- Update ocean physics
!! -3- Compute the t and s trends
!! -4- Update t and s
!! -5- Compute the momentum trends
!! -6- Update the horizontal velocity
!! -7- Compute the diagnostics variables (rd,N2, hdiv,w)
!! -8- Outputs and diagnostics
!!----------------------------------------------------------------------
INTEGER :: ji, jj, jk, jtile ! dummy loop indice
!! ---------------------------------------------------------------------
#if defined key_agrif
IF( nstop > 0 ) RETURN ! avoid to go further if an error was detected during previous time step (child grid)
kstp = nit000 + Agrif_Nb_Step()
Kbb_a = Nbb; Kmm_a = Nnn; Krhs_a = Nrhs ! agrif_oce module copies of time level indices
IF( lk_agrif_debug ) THEN
IF( Agrif_Root() .and. lwp) WRITE(*,*) '---'
IF(lwp) WRITE(*,*) 'Grid Number', Agrif_Fixed(),' time step ', kstp, 'int tstep', Agrif_NbStepint()
ENDIF
IF( kstp == nit000 + 1 ) lk_agrif_fstep = .FALSE.
# if defined key_xios
IF( Agrif_Nbstepint() == 0 ) CALL iom_swap( cxios_context )
# endif
#endif
!
IF( ln_timing ) CALL timing_start('stp')
!
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! model timestep
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
!
IF( l_1st_euler ) THEN ! start or restart with Euler 1st time-step
rDt = rn_Dt
r1_Dt = 1._wp / rDt
ENDIF
!
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! update I/O and calendar
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
!
IF( kstp == nit000 ) THEN ! initialize IOM context (must be done after nemo_init for AGRIF+XIOS+OASIS)
CALL iom_init( cxios_context, ld_closedef=.FALSE. ) ! for model grid (including possible AGRIF zoom)
IF( lk_diamlr ) CALL dia_mlr_iom_init ! with additional setup for multiple-linear-regression analysis
CALL iom_init_closedef
IF( ln_crs ) CALL iom_init( TRIM(cxios_context)//"_crs" ) ! for coarse grid
ENDIF
IF( kstp == nitrst .AND. lwxios ) THEN
CALL iom_swap( cw_ocerst_cxt )
CALL iom_init_closedef( cw_ocerst_cxt )
CALL iom_setkt( kstp - nit000 + 1, cw_ocerst_cxt )
#if defined key_top
CALL iom_swap( cw_toprst_cxt )
CALL iom_init_closedef( cw_toprst_cxt )
CALL iom_setkt( kstp - nit000 + 1, cw_toprst_cxt )
#endif
ENDIF
IF( kstp + nn_fsbc - 1 == nitrst .AND. lwxios ) THEN
#if defined key_si3
CALL iom_swap( cw_icerst_cxt )
CALL iom_init_closedef( cw_icerst_cxt )
CALL iom_setkt( kstp - nit000 + 1, cw_icerst_cxt )
#endif
IF( ln_abl ) THEN
CALL iom_swap( cw_ablrst_cxt )
CALL iom_init_closedef( cw_ablrst_cxt )
CALL iom_setkt( kstp - nit000 + 1, cw_ablrst_cxt )
ENDIF
ENDIF
IF( kstp /= nit000 ) CALL day( kstp ) ! Calendar (day was already called at nit000 in day_init)
CALL iom_setkt( kstp - nit000 + 1, cxios_context ) ! tell IOM we are at time step kstp
IF( ln_crs ) CALL iom_setkt( kstp - nit000 + 1, TRIM(cxios_context)//"_crs" ) ! tell IOM we are at time step kstp
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Update external forcing (tides, open boundaries, ice shelf interaction and surface boundary condition (including sea-ice)
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
IF( ln_tide ) CALL tide_update( kstp ) ! update tide potential
IF( ln_apr_dyn ) CALL sbc_apr ( kstp ) ! atmospheric pressure (NB: call before bdy_dta which needs ssh_ib)
IF( ln_bdy ) CALL bdy_dta ( kstp, Nnn ) ! update dynamic & tracer data at open boundaries
IF( ln_isf ) CALL isf_stp ( kstp, Nnn )
CALL sbc ( kstp, Nbb, Nnn ) ! Sea Boundary Condition (including sea-ice)
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Update stochastic parameters and random T/S fluctuations
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
IF( ln_sto_eos ) CALL sto_par( kstp ) ! Stochastic parameters
IF( ln_sto_eos ) CALL sto_pts( ts(:,:,:,:,Nnn) ) ! Random T/S fluctuations
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Ocean physics update
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
! THERMODYNAMICS
CALL eos_rab( ts(:,:,:,:,Nbb), rab_b, Nnn ) ! before local thermal/haline expension ratio at T-points
CALL eos_rab( ts(:,:,:,:,Nnn), rab_n, Nnn ) ! now local thermal/haline expension ratio at T-points
CALL bn2 ( ts(:,:,:,:,Nbb), rab_b, rn2b, Nnn ) ! before Brunt-Vaisala frequency
CALL bn2 ( ts(:,:,:,:,Nnn), rab_n, rn2, Nnn ) ! now Brunt-Vaisala frequency
! VERTICAL PHYSICS
! lbc_lnk needed for zdf_sh2 when using nn_hls = 2, moved here to allow tiling in zdf_phy
IF( nn_hls == 2 .AND. l_zdfsh2 ) CALL lbc_lnk( 'stp', avm_k, 'W', 1.0_wp )
IF( ln_tile ) CALL dom_tile_start ! [tiling] ZDF tiling loop
DO jtile = 1, nijtile
IF( ln_tile ) CALL dom_tile( ntsi, ntsj, ntei, ntej, ktile = jtile )
CALL zdf_phy( kstp, Nbb, Nnn, Nrhs ) ! vertical physics update (top/bot drag, avt, avs, avm + MLD)
END DO
IF( ln_tile ) CALL dom_tile_stop
! LATERAL PHYSICS
!
IF( ln_zps .OR. l_ldfslp ) CALL eos( ts(:,:,:,:,Nbb), rhd, gdept_0(:,:,:) ) ! before in situ density
IF( ln_zps .AND. .NOT. ln_isfcav) &
& CALL zps_hde ( kstp, jpts, ts(:,:,:,:,Nbb), gtsu, gtsv, & ! Partial steps: before horizontal gradient
& rhd, gru , grv ) ! of t, s, rd at the last ocean level
IF( ln_zps .AND. ln_isfcav) &
& CALL zps_hde_isf( kstp, jpts, ts(:,:,:,:,Nbb), gtsu, gtsv, gtui, gtvi, & ! Partial steps for top cell (ISF)
& rhd, gru , grv , grui, grvi ) ! of t, s, rd at the first ocean level
IF( l_ldfslp ) THEN ! slope of lateral mixing
IF( ln_traldf_triad ) THEN
CALL ldf_slp_triad( kstp, Nbb, Nnn ) ! before slope for triad operator
ELSE
CALL ldf_slp ( kstp, rhd, rn2b, Nbb, Nnn ) ! before slope for standard operator
ENDIF
ENDIF
! ! eddy diffusivity coeff.
IF( l_ldftra_time .OR. l_ldfeiv_time ) CALL ldf_tra( kstp, Nbb, Nnn ) ! and/or eiv coeff.
IF( l_ldfdyn_time ) CALL ldf_dyn( kstp, Nbb ) ! eddy viscosity coeff.
! BBL coefficients
!
IF( ln_trabbl ) CALL bbl( kstp, nit000, Nbb, Nnn ) ! BBL diffusion coefficients and transports
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!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Ocean dynamics : hdiv, ssh, e3, u, v, w
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
CALL ssh_nxt ( kstp, Nbb, Nnn, ssh, Naa ) ! after ssh (includes call to div_hor)
IF( .NOT.ln_linssh ) &
& CALL dom_vvl_sf_nxt( kstp, Nbb, Nnn, Naa ) ! after vertical scale factors
CALL wzv ( kstp, Nbb, Nnn, Naa, ww ) ! now cross-level velocity
IF( ln_zad_Aimp ) CALL wAimp ( kstp, Nnn ) ! Adaptive-implicit vertical advection partitioning
CALL eos ( ts(:,:,:,:,Nnn), rhd, rhop, gdept(:,:,:,Nnn) ) ! now in situ density for hpg computation
uu(:,:,:,Nrhs) = 0._wp ! set dynamics trends to zero
vv(:,:,:,Nrhs) = 0._wp
IF( ln_tile ) CALL dom_tile_start ! [tiling] DYN tiling loop (1)
DO jtile = 1, nijtile
IF( ln_tile ) CALL dom_tile( ntsi, ntsj, ntei, ntej, ktile = jtile )
IF( lk_asminc .AND. ln_asmiau .AND. ln_dyninc ) &
& CALL dyn_asm_inc ( kstp, Nbb, Nnn, uu, vv, Nrhs ) ! apply dynamics assimilation increment
IF( ln_bkgwri ) CALL asm_bkg_wri( kstp, Nnn ) ! output background fields
IF( ln_bdy ) CALL bdy_dyn3d_dmp ( kstp, Nbb, uu, vv, Nrhs ) ! bdy damping trends
#if defined key_agrif
END DO
IF( ln_tile ) CALL dom_tile_stop
IF(.NOT. Agrif_Root()) &
& CALL Agrif_Sponge_dyn ! momentum sponge
IF( ln_tile ) CALL dom_tile_start ! [tiling] DYN tiling loop (1, continued)
DO jtile = 1, nijtile
IF( ln_tile ) CALL dom_tile( ntsi, ntsj, ntei, ntej, ktile = jtile )
#endif
CALL dyn_adv( kstp, Nbb, Nnn , uu, vv, Nrhs ) ! advection (VF or FF) ==> RHS
CALL dyn_vor( kstp, Nnn , uu, vv, Nrhs ) ! vorticity ==> RHS
CALL dyn_ldf( kstp, Nbb, Nnn , uu, vv, Nrhs ) ! lateral mixing
IF( ln_zdfosm ) CALL dyn_osm( kstp, Nnn , uu, vv, Nrhs ) ! OSMOSIS non-local velocity fluxes ==> RHS
CALL dyn_hpg( kstp, Nnn , uu, vv, Nrhs ) ! horizontal gradient of Hydrostatic pressure
END DO
IF( ln_tile ) CALL dom_tile_stop
CALL dyn_spg( kstp, Nbb, Nnn, Nrhs, uu, vv, ssh, uu_b, vv_b, Naa ) ! surface pressure gradient
! With split-explicit free surface, since now transports have been updated and ssh(:,:,Nrhs) as well
IF( ln_dynspg_ts ) THEN ! vertical scale factors and vertical velocity need to be updated
IF( ln_tile ) CALL dom_tile_start ! [tiling] DYN tiling loop (2- div_hor only)
DO jtile = 1, nijtile
IF( ln_tile ) CALL dom_tile( ntsi, ntsj, ntei, ntej, ktile = jtile )
CALL div_hor ( kstp, Nbb, Nnn ) ! Horizontal divergence (2nd call in time-split case)
END DO
IF( ln_tile ) CALL dom_tile_stop
IF(.NOT. ln_linssh) CALL dom_vvl_sf_nxt( kstp, Nbb, Nnn, Naa, kcall=2 ) ! after vertical scale factors (update depth average component)
ENDIF
IF( ln_tile ) CALL dom_tile_start ! [tiling] DYN tiling loop (3- dyn_zdf only)
DO jtile = 1, nijtile
IF( ln_tile ) CALL dom_tile( ntsi, ntsj, ntei, ntej, ktile = jtile )
CALL dyn_zdf ( kstp, Nbb, Nnn, Nrhs, uu, vv, Naa ) ! vertical diffusion
END DO
IF( ln_tile ) CALL dom_tile_stop
IF( ln_dynspg_ts ) THEN ! vertical scale factors and vertical velocity need to be updated
CALL wzv ( kstp, Nbb, Nnn, Naa, ww ) ! Nnn cross-level velocity
IF( ln_zad_Aimp ) CALL wAimp ( kstp, Nnn ) ! Adaptive-implicit vertical advection partitioning
ENDIF
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! cool skin
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
IF ( ln_diurnal ) CALL diurnal_layers( kstp )
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! diagnostics and outputs
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
IF( ln_floats ) CALL flo_stp ( kstp, Nbb, Nnn ) ! drifting Floats
IF( ln_diacfl ) CALL dia_cfl ( kstp, Nnn ) ! Courant number diagnostics
CALL dia_hth ( kstp, Nnn ) ! Thermocline depth (20 degres isotherm depth)
IF( ln_diadct ) CALL dia_dct ( kstp, Nnn ) ! Transports
CALL dia_ar5 ( kstp, Nnn ) ! ar5 diag
CALL dia_ptr ( kstp, Nnn ) ! Poleward adv/ldf TRansports diagnostics
CALL dia_wri ( kstp, Nnn ) ! ocean model: outputs
IF( ln_crs ) CALL crs_fld ( kstp, Nnn ) ! ocean model: online field coarsening & output
IF( lk_diadetide ) CALL dia_detide( kstp ) ! Weights computation for daily detiding of model diagnostics
IF( lk_diamlr ) CALL dia_mlr ! Update time used in multiple-linear-regression analysis
#if defined key_top
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Passive Tracer Model
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
CALL trc_stp ( kstp, Nbb, Nnn, Nrhs, Naa ) ! time-stepping
#endif
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Active tracers
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
ts(:,:,:,:,Nrhs) = 0._wp ! set tracer trends to zero
IF( ln_tile ) CALL dom_tile_start ! [tiling] TRA tiling loop (1)
DO jtile = 1, nijtile
IF( ln_tile ) CALL dom_tile( ntsi, ntsj, ntei, ntej, ktile = jtile )
IF( lk_asminc .AND. ln_asmiau .AND. &
& ln_trainc ) CALL tra_asm_inc( kstp, Nbb, Nnn, ts, Nrhs ) ! apply tracer assimilation increment
CALL tra_sbc ( kstp, Nnn, ts, Nrhs ) ! surface boundary condition
IF( ln_traqsr ) CALL tra_qsr ( kstp, Nnn, ts, Nrhs ) ! penetrative solar radiation qsr
IF( ln_isf ) CALL tra_isf ( kstp, Nnn, ts, Nrhs ) ! ice shelf heat flux
IF( ln_trabbc ) CALL tra_bbc ( kstp, Nnn, ts, Nrhs ) ! bottom heat flux
IF( ln_trabbl ) CALL tra_bbl ( kstp, Nbb, Nnn, ts, Nrhs ) ! advective (and/or diffusive) bottom boundary layer scheme
IF( ln_tradmp ) CALL tra_dmp ( kstp, Nbb, Nnn, ts, Nrhs ) ! internal damping trends
IF( ln_bdy ) CALL bdy_tra_dmp( kstp, Nbb, ts, Nrhs ) ! bdy damping trends
END DO
IF( ln_tile ) CALL dom_tile_stop
#if defined key_agrif
IF(.NOT. Agrif_Root() ) THEN
CALL Agrif_Sponge_tra ! tracers sponge
ENDIF
#endif
! TEMP: [tiling] Separate loop over tile domains (due to tra_adv workarounds for tiling)
IF( ln_tile ) CALL dom_tile_start ! [tiling] TRA tiling loop (2)
DO jtile = 1, nijtile
IF( ln_tile ) CALL dom_tile( ntsi, ntsj, ntei, ntej, ktile = jtile )
CALL tra_adv ( kstp, Nbb, Nnn, ts, Nrhs ) ! hor. + vert. advection ==> RHS
IF( ln_zdfmfc ) CALL tra_mfc ( kstp, Nbb, ts, Nrhs ) ! Mass Flux Convection
IF( ln_zdfosm ) THEN
CALL tra_osm ( kstp, Nnn, ts, Nrhs ) ! OSMOSIS non-local tracer fluxes ==> RHS
IF( lrst_oce ) CALL osm_rst ( kstp, Nnn, 'WRITE' ) ! write OSMOSIS outputs + ww (so must do here) to restarts
ENDIF
CALL tra_ldf ( kstp, Nbb, Nnn, ts, Nrhs ) ! lateral mixing
CALL tra_zdf ( kstp, Nbb, Nnn, Nrhs, ts, Naa ) ! vertical mixing and after tracer fields
IF( ln_zdfnpc ) CALL tra_npc ( kstp, Nnn, Nrhs, ts, Naa ) ! update after fields by non-penetrative convection
END DO
IF( ln_tile ) CALL dom_tile_stop
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Set boundary conditions, time filter and swap time levels
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
!!jc1: For agrif, it would be much better to finalize tracers/momentum here (e.g. bdy conditions) and move the swap
!! (and time filtering) after Agrif update. Then restart would be done after and would contain updated fields.
!! If so:
!! (i) no need to call agrif update at initialization time
!! (ii) no need to update "before" fields
!!
!! Apart from creating new tra_swp/dyn_swp routines, this however:
!! (i) makes boundary conditions at initialization time computed from updated fields which is not the case between
!! two restarts => restartability issue. One can circumvent this, maybe, by assuming "interface separation",
!! e.g. a shift of the feedback interface inside child domain.
!! (ii) requires that all restart outputs of updated variables by agrif (e.g. passive tracers/tke/barotropic arrays) are done at the same
!! place.
!!
!!jc2: dynnxt must be the latest call. e3t(:,:,:,Nbb) are indeed updated in that routine
CALL tra_atf ( kstp, Nbb, Nnn, Naa, ts ) ! time filtering of "now" tracer arrays
CALL dyn_atf ( kstp, Nbb, Nnn, Naa, uu, vv, e3t, e3u, e3v ) ! time filtering of "now" velocities and scale factors
CALL ssh_atf ( kstp, Nbb, Nnn, Naa, ssh ) ! time filtering of "now" sea surface height
!
! Swap time levels
Nrhs = Nbb
Nbb = Nnn
Nnn = Naa
Naa = Nrhs
!
IF(.NOT.ln_linssh) CALL dom_vvl_sf_update( kstp, Nbb, Nnn, Naa ) ! recompute vertical scale factors
!
IF( ln_diahsb ) CALL dia_hsb ( kstp, Nbb, Nnn ) ! - ML - global conservation diagnostics
!!gm : This does not only concern the dynamics ==>>> add a new title
!!gm2: why ouput restart before AGRIF update?
!!
!!jc: That would be better, but see comment above
!!
IF( lrst_oce ) CALL rst_write ( kstp, Nbb, Nnn ) ! write output ocean restart file
IF( ln_sto_eos ) CALL sto_rst_write( kstp ) ! write restart file for stochastic parameters
#if defined key_agrif
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! AGRIF recursive integration
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
Kbb_a = Nbb; Kmm_a = Nnn; Krhs_a = Nrhs ! agrif_oce module copies of time level indices
CALL Agrif_Integrate_ChildGrids( stp ) ! allows to finish all the Child Grids before updating
#endif
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Control
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
CALL stp_ctl ( kstp, Nnn )
#if defined key_agrif
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! AGRIF update
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
IF( Agrif_NbStepint() == 0 .AND. nstop == 0 ) &
& CALL Agrif_update_all( ) ! Update all components
#endif
IF( ln_diaobs .AND. nstop == 0 ) &
& CALL dia_obs( kstp, Nnn ) ! obs-minus-model (assimilation) diags (after dynamics update)
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! File manipulation at the end of the first time step
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
IF( kstp == nit000 ) THEN ! 1st time step only
CALL iom_close( numror ) ! close input ocean restart file
IF( lrxios ) CALL iom_context_finalize( cr_ocerst_cxt )
IF(lwm) CALL FLUSH ( numond ) ! flush output namelist oce
IF(lwm .AND. numoni /= -1 ) CALL FLUSH ( numoni ) ! flush output namelist ice (if exist)
ENDIF
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Coupled mode
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
IF( lk_oasis .AND. nstop == 0 ) CALL sbc_cpl_snd( kstp, Nbb, Nnn ) ! coupled mode : field exchanges
!
#if defined key_xios
!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
! Finalize contextes if end of simulation or error detected
!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
IF( kstp == nitend .OR. nstop > 0 ) THEN
CALL iom_context_finalize( cxios_context ) ! needed for XIOS+AGRIF
IF( ln_crs ) CALL iom_context_finalize( trim(cxios_context)//"_crs" ) !
ENDIF
#endif
!
IF( l_1st_euler ) THEN ! recover Leap-frog timestep
rDt = 2._wp * rn_Dt
r1_Dt = 1._wp / rDt
l_1st_euler = .FALSE.
ENDIF
!
IF( ln_timing ) CALL timing_stop('stp')
!
END SUBROUTINE stp
!
#endif
!!======================================================================
END MODULE step