model/src/forward_step.F

C $Header: /u/u3/gcmpack/MITgcm/model/src/forward_step.F,v 1.78 2003/12/15 02:07:29 jmc Exp $
C $Name:  $

#include "PACKAGES_CONFIG.h"
#include "CPP_OPTIONS.h"

cswdptr -- add --
#ifdef ALLOW_GCHEM
# include "GCHEM_OPTIONS.h"
#endif
cswdptr -- end add ---

CBOP
C     !ROUTINE: FORWARD_STEP
C     !INTERFACE:
      SUBROUTINE FORWARD_STEP( iloop, myTime, myIter, myThid )

C     !DESCRIPTION: \bv
C     *==================================================================
C     | SUBROUTINE forward_step
C     | o Run the ocean model and, optionally, evaluate a cost function.
C     *==================================================================
C     |
C     | THE_MAIN_LOOP is the toplevel routine for the Tangent Linear and
C     | Adjoint Model Compiler (TAMC). For this purpose the initialization
C     | of the model was split into two parts. Those parameters that do
C     | not depend on a specific model run are set in INITIALISE_FIXED,   
C     | whereas those that do depend on the specific realization are
C     | initialized in INITIALISE_VARIA.   
C     |
C     *==================================================================
C     \ev

C     !USES:
      IMPLICIT NONE
C     == Global variables ==
#include "SIZE.h"
#include "EEPARAMS.h"
#include "PARAMS.h"
#include "DYNVARS.h"
#include "FFIELDS.h"

#ifdef ALLOW_NONHYDROSTATIC
#include "CG3D.h"
#endif

#ifdef ALLOW_SHAP_FILT
#include "SHAP_FILT.h"
#endif
#ifdef ALLOW_ZONAL_FILT
#include "ZONAL_FILT.h"
#endif

#ifdef ALLOW_AUTODIFF_TAMC
# include "tamc.h"
# include "ctrl.h"
# include "ctrl_dummy.h"
# include "cost.h"
# include "EOS.h"
# ifdef ALLOW_EXF
#  include "exf_fields.h"
#  ifdef ALLOW_BULKFORMULAE
#   include "exf_constants.h"
#  endif
# endif
# ifdef ALLOW_OBCS
#  include "OBCS.h"
# endif
# ifdef ALLOW_PTRACERS
#  include "PTRACERS.h"
# endif
#endif /* ALLOW_AUTODIFF_TAMC */

C     !LOCAL VARIABLES:
C     == Routine arguments ==
C     note: under the multi-threaded model myiter and 
C           mytime are local variables passed around as routine 
C           arguments. Although this is fiddly it saves the need to 
C           impose additional synchronisation points when they are 
C           updated.
C     myiter - iteration counter for this thread
C     mytime - time counter for this thread
C     mythid - thread number for this instance of the routine.
      integer iloop
      integer mythid 
      integer myiter
      _RL     mytime
#ifdef ALLOW_BULK_FORCE
      INTEGER bi,bj
#endif

CEOP

#ifdef ALLOW_DEBUG
      IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_ENTER('FORWARD_STEP',myThid)
#endif

#ifdef ALLOW_AUTODIFF_TAMC
C--   Reset the model iteration counter and the model time.
      myiter = nIter0 + (iloop-1)
      mytime = startTime + float(iloop-1)*deltaTclock
#endif

#if (defined (ALLOW_AUTODIFF_TAMC) && defined (ALLOW_AUTODIFF_MONITOR))
C     Include call to a dummy routine. Its adjoint will be 
C     called at the proper place in the adjoint code.
C     The adjoint routine will print out adjoint values 
C     if requested. The location of the call is important, 
C     it has to be after the adjoint of the exchanges 
C     (DO_GTERM_BLOCKING_EXCHANGES).
      CALL DUMMY_IN_STEPPING( myTime, myIter, myThid )
cph   I've commented this line since it may conflict with MITgcm's adjoint
cph   However, need to check whether that's still consistent
cph   with the ecco-branch (it should).
cph      CALL DO_FIELDS_BLOCKING_EXCHANGES( myThid )
#endif

#ifdef EXACT_CONSERV
      IF (exactConserv) THEN
C--   Update etaH(n+1) :
         CALL TIMER_START('UPDATE_ETAH        [FORWARD_STEP]',mythid)
         CALL UPDATE_ETAH( myTime, myIter, myThid )
         CALL TIMER_STOP ('UPDATE_ETAH        [FORWARD_STEP]',mythid)
      ENDIF
#endif /* EXACT_CONSERV */ 

#ifdef NONLIN_FRSURF
      IF ( select_rStar.NE.0 ) THEN
C--   r* : compute the future level thickness according to etaH(n+1) 
          CALL TIMER_START('CALC_R_STAR       [FORWARD_STEP]',mythid)
          CALL CALC_R_STAR(etaH, myTime, myIter, myThid )
          CALL TIMER_STOP ('CALC_R_STAR       [FORWARD_STEP]',mythid)
      ELSEIF ( nonlinFreeSurf.GT.0) THEN
C--   compute the future surface level thickness according to etaH(n+1) 
          CALL TIMER_START('CALC_SURF_DR      [FORWARD_STEP]',mythid)
          CALL CALC_SURF_DR(etaH, myTime, myIter, myThid )
          CALL TIMER_STOP ('CALC_SURF_DR      [FORWARD_STEP]',mythid)
      ENDIF
#endif /* NONLIN_FRSURF */

#ifdef ALLOW_AUTODIFF_TAMC
c**************************************
#include "checkpoint_lev1_directives.h"
c**************************************
#endif

C--   Call external forcing package
#ifdef ALLOW_BULK_FORCE
      IF ( useBulkForce ) THEN
#ifdef ALLOW_DEBUG
       IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('BULKF_FIELDS_LOAD',myThid)
#endif
       CALL TIMER_START('BULKF_FORCING      [FORWARD_STEP]',mythid)
C-    load all forcing fields at current time
       CALL BULKF_FIELDS_LOAD( myTime, myIter, myThid )
C-    calculate qnet and empmr (and wind stress)
       CALL BULKF_FORCING( myTime, myIter, myThid )
       CALL TIMER_STOP ('BULKF_FORCING      [FORWARD_STEP]',mythid)
      ELSE
#endif /* ALLOW_BULK_FORCE */

# ifdef ALLOW_EXF
#  ifdef ALLOW_DEBUG
      IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('EXF_GETFORCING',myThid)
#  endif
      CALL TIMER_START('EXF_GETFORCING     [FORWARD_STEP]',mythid)
      CALL EXF_GETFORCING( mytime, myiter, mythid )
      CALL TIMER_STOP ('EXF_GETFORCING     [FORWARD_STEP]',mythid)
# else /* ALLOW_EXF undef */
cph The following IF-statement creates an additional dependency
cph for the forcing fields requiring additional storing.
cph Therefore, the IF-statement will be put between CPP-OPTIONS,
cph assuming that ALLOW_SEAICE has not yet been differentiated.
#  ifdef ALLOW_SEAICE
      IF ( .NOT. useSEAICE ) THEN
#  endif
#ifdef ALLOW_DEBUG
       IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('EXTERNAL_FIELDS_LOAD',myThid)
#endif
       CALL TIMER_START('EXTERNAL_FIELDS_LOAD[FORWARD_STEP]',mythid)
       CALL EXTERNAL_FIELDS_LOAD( mytime, myiter, mythid )
       CALL TIMER_STOP ('EXTERNAL_FIELDS_LOAD[FORWARD_STEP]',mythid)
#  ifdef ALLOW_SEAICE
      ENDIF
#  endif
# endif /* ALLOW_EXF */
#ifdef ALLOW_BULK_FORCE
C--   end of if/else block useBulfforce --
      ENDIF
#endif /* ALLOW_BULK_FORCE */

#ifdef ALLOW_AUTODIFF
c--   Add control vector for forcing and parameter fields
      if ( myiter .EQ. nIter0 )
     &     CALL CTRL_MAP_FORCING (mythid)
#endif

#ifdef ALLOW_THSICE
      IF (useThSIce) THEN
#ifdef ALLOW_DEBUG
        IF ( debugLevel .GE. debLevB )
     &    CALL DEBUG_CALL('THSICE_MAIN',myThid)
#endif
C--     Step forward Therm.Sea-Ice variables
C       and modify forcing terms including effects from ice
        CALL TIMER_START('THSICE_MAIN        [FORWARD_STEP]', myThid)
        CALL THSICE_MAIN( myTime, myIter, myThid )
        CALL TIMER_STOP( 'THSICE_MAIN        [FORWARD_STEP]', myThid)
      ENDIF
#endif /* ALLOW_THSICE */

# ifdef ALLOW_SEAICE
C--   Call sea ice model to compute forcing/external data fields.  In
C     addition to computing prognostic sea-ice variables and diagnosing the
C     forcing/external data fields that drive the ocean model, SEAICE_MODEL
C     also sets theta to the freezing point under sea-ice.  The implied
C     surface heat flux is then stored in variable surfaceTendencyTice,
C     which is needed by KPP package (kpp_calc.F and kpp_transport_t.F)
C     to diagnose surface buoyancy fluxes and for the non-local transport
C     term.  Because this call precedes model thermodynamics, temperature
C     under sea-ice may not be "exactly" at the freezing point by the time
C     theta is dumped or time-averaged.
      IF ( useSEAICE ) THEN
#ifdef ALLOW_DEBUG
         IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('SEAICE_MODEL',myThid)
#endif
         CALL TIMER_START('SEAICE_MODEL       [FORWARD_STEP]',myThid)
         CALL SEAICE_MODEL( myTime, myIter, myThid )
         CALL TIMER_STOP ('SEAICE_MODEL       [FORWARD_STEP]',myThid)
      ENDIF
# endif /* ALLOW_SEAICE */

C--   Freeze water at the surface
#ifdef ALLOW_AUTODIFF_TAMC
CADJ STORE theta = comlev1, key = ikey_dynamics
#endif
      IF ( allowFreezing .AND. .NOT. useSEAICE
     &                   .AND. .NOT. useThSIce ) THEN
        CALL FREEZE_SURFACE(  myTime, myIter, myThid )
      ENDIF

#ifdef ALLOW_AUTODIFF_TAMC
# ifdef ALLOW_PTRACERS
cph this replaces _bibj storing of ptracer within thermodynamics
CADJ STORE ptracer  = comlev1, key = ikey_dynamics
# endif
#endif

#ifdef ALLOW_PTRACERS
# ifdef ALLOW_GCHEM
         CALL GCHEM_FIELDS_LOAD( mytime, myiter, mythid )
# endif
#endif

#ifdef COMPONENT_MODULE
       IF ( useCoupler ) THEN
C      Post coupling data that I export.
C      Read in coupling data that I import.
         CALL TIMER_START('CPL_EXPORT-IMPORT  [FORWARD_STEP]',myThid)
         CALL CPL_EXPORT_MY_DATA(       myIter, myTime, myThid )
         CALL CPL_IMPORT_EXTERNAL_DATA( myIter, myTime, myThid )
         CALL TIMER_STOP ('CPL_EXPORT-IMPORT  [FORWARD_STEP]',myThid)
       ENDIF
#endif /* COMPONENT_MODULE */

#ifdef COMPONENT_MODULE
# ifndef ALLOW_AIM
C jmc: don't know precisely where to put this call. leave it here for now.
       IF ( useCoupler ) THEN
         CALL OCN_APPLY_IMPORT( myTime, myIter, myThid )
       ENDIF
# endif
#endif /* COMPONENT_MODULE */

C--     Step forward fields and calculate time tendency terms.
C AMM
#ifdef ALLOW_FIZHI
        CALL UPDATE_OCEAN_EXPORTS ( myTime, myIter, myThid )
        CALL UPDATE_EARTH_EXPORTS ( myTime, myIter, myThid )
        CALL UPDATE_CHEMISTRY_EXPORTS ( myTime, myIter, myThid )
        CALL TIMER_START('FIZHI_WRAPPER       [FORWARD_STEP]',mythid)
        CALL FIZHI_WRAPPER ( myTime, myIter, myThid )
        CALL TIMER_STOP ('FIZHI_WRAPPER       [FORWARD_STEP]',mythid)
                                                                                           
        CALL STEP_FIZHI_FG ( myTime, myIter, myThid )
#endif
C AMM

#ifdef ALLOW_DEBUG
      IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('THERMODYNAMICS',myThid)
#endif
        CALL TIMER_START('THERMODYNAMICS      [FORWARD_STEP]',mythid)
        CALL THERMODYNAMICS( myTime, myIter, myThid )
        CALL TIMER_STOP ('THERMODYNAMICS      [FORWARD_STEP]',mythid)

C--   do exchanges (needed for DYNAMICS) when using stagger time-step :
#ifdef ALLOW_DEBUG
      IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('DO_STAGGER_FIELDS_EXCH.',myThid)
#endif
        CALL TIMER_START('BLOCKING_EXCHANGES  [FORWARD_STEP]',myThid)
        CALL DO_STAGGER_FIELDS_EXCHANGES( myTime, myIter, myThid )
        CALL TIMER_STOP ('BLOCKING_EXCHANGES  [FORWARD_STEP]',myThid)

#ifdef ALLOW_SHAP_FILT
      IF (useSHAP_FILT .AND. 
     &     staggerTimeStep .AND. shap_filt_TrStagg ) THEN
#ifdef ALLOW_DEBUG
        IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('SHAP_FILT_APPLY_TS',myThid)
#endif
        CALL TIMER_START('SHAP_FILT           [FORWARD_STEP]',myThid)
        CALL SHAP_FILT_APPLY_TS(gT,gS,myTime+deltaT,myIter+1,myThid)
        CALL TIMER_STOP ('SHAP_FILT           [FORWARD_STEP]',myThid)
      ENDIF
#endif
#ifdef ALLOW_ZONAL_FILT
      IF (useZONAL_FILT .AND. 
     &     staggerTimeStep .AND. zonal_filt_TrStagg ) THEN
#ifdef ALLOW_DEBUG
        IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('ZONAL_FILT_APPLY_TS',myThid)
#endif
        CALL TIMER_START('ZONAL_FILT_APPLY    [FORWARD_STEP]',myThid)
        CALL ZONAL_FILT_APPLY_TS( gT, gS, myThid )
        CALL TIMER_STOP ('ZONAL_FILT_APPLY    [FORWARD_STEP]',myThid)
      ENDIF
#endif   

C--   Step forward fields and calculate time tendency terms.
#ifndef ALLOW_AUTODIFF_TAMC
      IF ( momStepping ) THEN
#endif
#ifdef ALLOW_DEBUG
        IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_CALL('DYNAMICS',myThid)
#endif
        CALL TIMER_START('DYNAMICS            [FORWARD_STEP]',mythid)
        CALL DYNAMICS( myTime, myIter, myThid )
        CALL TIMER_STOP ('DYNAMICS            [FORWARD_STEP]',mythid)
#ifndef ALLOW_AUTODIFF_TAMC
      ENDIF
#endif

#ifdef ALLOW_NONHYDROSTATIC
C--   Step forward W field in N-H algorithm
      IF ( momStepping .AND. nonHydrostatic ) THEN
#ifdef ALLOW_DEBUG
          IF ( debugLevel .GE. debLevB ) 
     &     CALL DEBUG_CALL('CALC_GW',myThid)
#endif
         CALL TIMER_START('CALC_GW          [FORWARD_STEP]',myThid)
         CALL CALC_GW(myThid)
         CALL TIMER_STOP ('CALC_GW          [FORWARD_STEP]',myThid)
      ENDIF
#endif

#ifdef NONLIN_FRSURF
C--   update hfacC,W,S and recip_hFac according to etaH(n+1) :
      IF ( nonlinFreeSurf.GT.0) THEN
       IF ( select_rStar.GT.0 ) THEN
        CALL TIMER_START('UPDATE_R_STAR      [FORWARD_STEP]',myThid)
        CALL UPDATE_R_STAR( myTime, myIter, myThid )
        CALL TIMER_STOP ('UPDATE_R_STAR      [FORWARD_STEP]',myThid)
       ELSE
        CALL TIMER_START('UPDATE_SURF_DR     [FORWARD_STEP]',myThid)
        CALL UPDATE_SURF_DR( myTime, myIter, myThid )
        CALL TIMER_STOP ('UPDATE_SURF_DR     [FORWARD_STEP]',myThid)
       ENDIF
      ENDIF
C-    update also CG2D matrix (and preconditioner)
      IF ( momStepping .AND. nonlinFreeSurf.GT.2 ) THEN
        CALL TIMER_START('UPDATE_CG2D        [FORWARD_STEP]',myThid)
        CALL UPDATE_CG2D( myTime, myIter, myThid )
        CALL TIMER_STOP ('UPDATE_CG2D        [FORWARD_STEP]',myThid)
      ENDIF
#endif

C--   Apply Filters to u*,v* before SOLVE_FOR_PRESSURE
#ifdef ALLOW_SHAP_FILT
      IF (useSHAP_FILT .AND. shap_filt_uvStar) THEN
        CALL TIMER_START('SHAP_FILT           [FORWARD_STEP]',myThid)
        IF (implicDiv2Dflow.LT.1.) THEN
C--   Explicit+Implicit part of the Barotropic Flow Divergence
C      => Filtering of uVel,vVel is necessary
          CALL SHAP_FILT_APPLY_UV( uVel,vVel,
     &                             myTime+deltaT, myIter+1, myThid )
        ENDIF
        CALL SHAP_FILT_APPLY_UV( gU,gV,myTime+deltaT,myIter+1,myThid)
        CALL TIMER_STOP ('SHAP_FILT           [FORWARD_STEP]',myThid)
      ENDIF
#endif
#ifdef ALLOW_ZONAL_FILT
      IF (useZONAL_FILT .AND. zonal_filt_uvStar) THEN
        CALL TIMER_START('ZONAL_FILT_APPLY    [FORWARD_STEP]',myThid)
        IF (implicDiv2Dflow.LT.1.) THEN
C--   Explicit+Implicit part of the Barotropic Flow Divergence
C      => Filtering of uVel,vVel is necessary
          CALL ZONAL_FILT_APPLY_UV( uVel, vVel, myThid )
        ENDIF
        CALL ZONAL_FILT_APPLY_UV( gU, gV, myThid )
        CALL TIMER_STOP ('ZONAL_FILT_APPLY    [FORWARD_STEP]',myThid)
      ENDIF
#endif  

C--   Solve elliptic equation(s).
C     Two-dimensional only for conventional hydrostatic or 
C     three-dimensional for non-hydrostatic and/or IGW scheme.
      IF ( momStepping ) THEN
      CALL TIMER_START('SOLVE_FOR_PRESSURE  [FORWARD_STEP]',myThid)
      CALL SOLVE_FOR_PRESSURE(myTime, myIter, myThid)
      CALL TIMER_STOP ('SOLVE_FOR_PRESSURE  [FORWARD_STEP]',myThid)
      ENDIF

#ifdef ALLOW_AUTODIFF_TAMC
cph This is needed because convective_adjustment calls
cph find_rho which may use pressure()
CADJ STORE totphihyd  = comlev1, key = ikey_dynamics
#endif
C--   Correct divergence in flow field and cycle time-stepping
C     arrays (for all fields) ; update time-counter
      myIter = nIter0 + iLoop
      myTime = startTime + deltaTClock * float(iLoop)
      CALL TIMER_START('THE_CORRECTION_STEP [FORWARD_STEP]',myThid)
      CALL THE_CORRECTION_STEP(myTime, myIter, myThid)
      CALL TIMER_STOP ('THE_CORRECTION_STEP [FORWARD_STEP]',myThid)

C--   Do "blocking" sends and receives for tendency "overlap" terms
c     CALL TIMER_START('BLOCKING_EXCHANGES  [FORWARD_STEP]',myThid)
c     CALL DO_GTERM_BLOCKING_EXCHANGES( myThid )
c     CALL TIMER_STOP ('BLOCKING_EXCHANGES  [FORWARD_STEP]',myThid)

C--   Do "blocking" sends and receives for field "overlap" terms
      CALL TIMER_START('BLOCKING_EXCHANGES  [FORWARD_STEP]',myThid)
      CALL DO_FIELDS_BLOCKING_EXCHANGES( myThid )
      CALL TIMER_STOP ('BLOCKING_EXCHANGES  [FORWARD_STEP]',myThid)

cswdptr -- add for seperate timestepping of chemical/biological/forcing
cswdptr    of ptracers ---
#ifdef ALLOW_GCHEM
ceh3 This is broken -- this ifdef should not be visible!
#ifdef PTRACERS_SEPARATE_FORCING
ceh3 needs an IF ( use GCHEM ) THEN
        call GCHEM_FORCING_SEP( myTime,myIter,myThid )
#endif /* PTRACERS_SEPARATE_FORCING */
#endif /* ALLOW_GCHEM */
cswdptr -- end add ---

C AMM
#ifdef ALLOW_FIZHI
        CALL STEP_FIZHI_CORR ( myTime, myIter, myThid )
#endif
C AMM

#ifdef ALLOW_FLT
C--   Calculate float trajectories
      IF (useFLT) THEN
        CALL TIMER_START('FLOATS            [FORWARD_STEP]',myThid)
        CALL FLT_MAIN(myIter,myTime, myThid)
        CALL TIMER_STOP ('FLOATS            [FORWARD_STEP]',myThid)
      ENDIF
#endif

#ifdef ALLOW_MONITOR
C--   Check status of solution (statistics, cfl, etc...)
      CALL TIMER_START('MONITOR             [FORWARD_STEP]',myThid)
      CALL MONITOR( myIter, myTime, myThid )
      CALL TIMER_STOP ('MONITOR             [FORWARD_STEP]',myThid)
#endif /* ALLOW_MONITOR */

C--   Do IO if needed.
      CALL TIMER_START('DO_THE_MODEL_IO     [FORWARD_STEP]',myThid)
      CALL DO_THE_MODEL_IO( myTime, myIter, myThid )
      CALL TIMER_STOP ('DO_THE_MODEL_IO     [FORWARD_STEP]',myThid)

C--   Save state for restarts
C     Note:    (jmc: is it still the case after ckp35 ?)
C     =====
C     Because of the ordering of the timestepping code and
C     tendency term code at end of loop model arrays hold
C     U,V,T,S  at "time-level" N but gu, gv, gs, gt, guNM1,... 
C     at "time-level" N+1/2 (guNM1 at "time-level" N+1/2 is 
C     gu at "time-level" N-1/2) and etaN at "time-level" N+1/2.
C      where N = I+timeLevBase-1
C     Thus a checkpoint contains U.0000000000, GU.0000000001 and 
C     etaN.0000000001 in the indexing scheme used for the model 
C     "state" files. This example is referred to as a checkpoint 
C     at time level 1 
      CALL TIMER_START('WRITE_CHECKPOINT    [FORWARD_STEP]',myThid)
      CALL PACKAGES_WRITE_PICKUP(
     I               .FALSE., myTime, myIter, myThid )
      CALL WRITE_CHECKPOINT(
     I               .FALSE., myTime, myIter, myThid )   
      CALL TIMER_STOP ('WRITE_CHECKPOINT    [FORWARD_STEP]',myThid)

#ifdef ALLOW_DEBUG
      IF ( debugLevel .GE. debLevB ) 
     &    CALL DEBUG_LEAVE('FORWARD_STEP',myThid)
#endif

      RETURN
      END
1	C $Header: /u/u3/gcmpack/MITgcm/model/src/forward_step.F,v 1.78 2003/12/15 02:07:29 jmc Exp $
2	C $Name: $
3
4	#include "PACKAGES_CONFIG.h"
5	#include "CPP_OPTIONS.h"
6
7	cswdptr -- add --
8	#ifdef ALLOW_GCHEM
9	# include "GCHEM_OPTIONS.h"
10	#endif
11	cswdptr -- end add ---
12
13	CBOP
14	C !ROUTINE: FORWARD_STEP
15	C !INTERFACE:
16	SUBROUTINE FORWARD_STEP( iloop, myTime, myIter, myThid )
17
18	C !DESCRIPTION: \bv
19	C *==================================================================
20	C \| SUBROUTINE forward_step
21	C \| o Run the ocean model and, optionally, evaluate a cost function.
22	C *==================================================================
23	C \|
24	C \| THE_MAIN_LOOP is the toplevel routine for the Tangent Linear and
25	C \| Adjoint Model Compiler (TAMC). For this purpose the initialization
26	C \| of the model was split into two parts. Those parameters that do
27	C \| not depend on a specific model run are set in INITIALISE_FIXED,
28	C \| whereas those that do depend on the specific realization are
29	C \| initialized in INITIALISE_VARIA.
30	C \|
31	C *==================================================================
32	C \ev
33
34	C !USES:
35	IMPLICIT NONE
36	C == Global variables ==
37	#include "SIZE.h"
38	#include "EEPARAMS.h"
39	#include "PARAMS.h"
40	#include "DYNVARS.h"
41	#include "FFIELDS.h"
42
43	#ifdef ALLOW_NONHYDROSTATIC
44	#include "CG3D.h"
45	#endif
46
47	#ifdef ALLOW_SHAP_FILT
48	#include "SHAP_FILT.h"
49	#endif
50	#ifdef ALLOW_ZONAL_FILT
51	#include "ZONAL_FILT.h"
52	#endif
53
54	#ifdef ALLOW_AUTODIFF_TAMC
55	# include "tamc.h"
56	# include "ctrl.h"
57	# include "ctrl_dummy.h"
58	# include "cost.h"
59	# include "EOS.h"
60	# ifdef ALLOW_EXF
61	# include "exf_fields.h"
62	# ifdef ALLOW_BULKFORMULAE
63	# include "exf_constants.h"
64	# endif
65	# endif
66	# ifdef ALLOW_OBCS
67	# include "OBCS.h"
68	# endif
69	# ifdef ALLOW_PTRACERS
70	# include "PTRACERS.h"
71	# endif
72	#endif /* ALLOW_AUTODIFF_TAMC */
73
74	C !LOCAL VARIABLES:
75	C == Routine arguments ==
76	C note: under the multi-threaded model myiter and
77	C mytime are local variables passed around as routine
78	C arguments. Although this is fiddly it saves the need to
79	C impose additional synchronisation points when they are
80	C updated.
81	C myiter - iteration counter for this thread
82	C mytime - time counter for this thread
83	C mythid - thread number for this instance of the routine.
84	integer iloop
85	integer mythid
86	integer myiter
87	_RL mytime
88	#ifdef ALLOW_BULK_FORCE
89	INTEGER bi,bj
90	#endif
91
92	CEOP
93
94	#ifdef ALLOW_DEBUG
95	IF ( debugLevel .GE. debLevB )
96	& CALL DEBUG_ENTER('FORWARD_STEP',myThid)
97	#endif
98
99	#ifdef ALLOW_AUTODIFF_TAMC
100	C-- Reset the model iteration counter and the model time.
101	myiter = nIter0 + (iloop-1)
102	mytime = startTime + float(iloop-1)*deltaTclock
103	#endif
104
105	#if (defined (ALLOW_AUTODIFF_TAMC) && defined (ALLOW_AUTODIFF_MONITOR))
106	C Include call to a dummy routine. Its adjoint will be
107	C called at the proper place in the adjoint code.
108	C The adjoint routine will print out adjoint values
109	C if requested. The location of the call is important,
110	C it has to be after the adjoint of the exchanges
111	C (DO_GTERM_BLOCKING_EXCHANGES).
112	CALL DUMMY_IN_STEPPING( myTime, myIter, myThid )
113	cph I've commented this line since it may conflict with MITgcm's adjoint
114	cph However, need to check whether that's still consistent
115	cph with the ecco-branch (it should).
116	cph CALL DO_FIELDS_BLOCKING_EXCHANGES( myThid )
117	#endif
118
119	#ifdef EXACT_CONSERV
120	IF (exactConserv) THEN
121	C-- Update etaH(n+1) :
122	CALL TIMER_START('UPDATE_ETAH [FORWARD_STEP]',mythid)
123	CALL UPDATE_ETAH( myTime, myIter, myThid )
124	CALL TIMER_STOP ('UPDATE_ETAH [FORWARD_STEP]',mythid)
125	ENDIF
126	#endif /* EXACT_CONSERV */
127
128	#ifdef NONLIN_FRSURF
129	IF ( select_rStar.NE.0 ) THEN
130	C-- r* : compute the future level thickness according to etaH(n+1)
131	CALL TIMER_START('CALC_R_STAR [FORWARD_STEP]',mythid)
132	CALL CALC_R_STAR(etaH, myTime, myIter, myThid )
133	CALL TIMER_STOP ('CALC_R_STAR [FORWARD_STEP]',mythid)
134	ELSEIF ( nonlinFreeSurf.GT.0) THEN
135	C-- compute the future surface level thickness according to etaH(n+1)
136	CALL TIMER_START('CALC_SURF_DR [FORWARD_STEP]',mythid)
137	CALL CALC_SURF_DR(etaH, myTime, myIter, myThid )
138	CALL TIMER_STOP ('CALC_SURF_DR [FORWARD_STEP]',mythid)
139	ENDIF
140	#endif /* NONLIN_FRSURF */
141
142	#ifdef ALLOW_AUTODIFF_TAMC
143	c**************************************
144	#include "checkpoint_lev1_directives.h"
145	c**************************************
146	#endif
147
148	C-- Call external forcing package
149	#ifdef ALLOW_BULK_FORCE
150	IF ( useBulkForce ) THEN
151	#ifdef ALLOW_DEBUG
152	IF ( debugLevel .GE. debLevB )
153	& CALL DEBUG_CALL('BULKF_FIELDS_LOAD',myThid)
154	#endif
155	CALL TIMER_START('BULKF_FORCING [FORWARD_STEP]',mythid)
156	C- load all forcing fields at current time
157	CALL BULKF_FIELDS_LOAD( myTime, myIter, myThid )
158	C- calculate qnet and empmr (and wind stress)
159	CALL BULKF_FORCING( myTime, myIter, myThid )
160	CALL TIMER_STOP ('BULKF_FORCING [FORWARD_STEP]',mythid)
161	ELSE
162	#endif /* ALLOW_BULK_FORCE */
163
164	# ifdef ALLOW_EXF
165	# ifdef ALLOW_DEBUG
166	IF ( debugLevel .GE. debLevB )
167	& CALL DEBUG_CALL('EXF_GETFORCING',myThid)
168	# endif
169	CALL TIMER_START('EXF_GETFORCING [FORWARD_STEP]',mythid)
170	CALL EXF_GETFORCING( mytime, myiter, mythid )
171	CALL TIMER_STOP ('EXF_GETFORCING [FORWARD_STEP]',mythid)
172	# else /* ALLOW_EXF undef */
173	cph The following IF-statement creates an additional dependency
174	cph for the forcing fields requiring additional storing.
175	cph Therefore, the IF-statement will be put between CPP-OPTIONS,
176	cph assuming that ALLOW_SEAICE has not yet been differentiated.
177	# ifdef ALLOW_SEAICE
178	IF ( .NOT. useSEAICE ) THEN
179	# endif
180	#ifdef ALLOW_DEBUG
181	IF ( debugLevel .GE. debLevB )
182	& CALL DEBUG_CALL('EXTERNAL_FIELDS_LOAD',myThid)
183	#endif
184	CALL TIMER_START('EXTERNAL_FIELDS_LOAD[FORWARD_STEP]',mythid)
185	CALL EXTERNAL_FIELDS_LOAD( mytime, myiter, mythid )
186	CALL TIMER_STOP ('EXTERNAL_FIELDS_LOAD[FORWARD_STEP]',mythid)
187	# ifdef ALLOW_SEAICE
188	ENDIF
189	# endif
190	# endif /* ALLOW_EXF */
191	#ifdef ALLOW_BULK_FORCE
192	C-- end of if/else block useBulfforce --
193	ENDIF
194	#endif /* ALLOW_BULK_FORCE */
195
196	#ifdef ALLOW_AUTODIFF
197	c-- Add control vector for forcing and parameter fields
198	if ( myiter .EQ. nIter0 )
199	& CALL CTRL_MAP_FORCING (mythid)
200	#endif
201
202	#ifdef ALLOW_THSICE
203	IF (useThSIce) THEN
204	#ifdef ALLOW_DEBUG
205	IF ( debugLevel .GE. debLevB )
206	& CALL DEBUG_CALL('THSICE_MAIN',myThid)
207	#endif
208	C-- Step forward Therm.Sea-Ice variables
209	C and modify forcing terms including effects from ice
210	CALL TIMER_START('THSICE_MAIN [FORWARD_STEP]', myThid)
211	CALL THSICE_MAIN( myTime, myIter, myThid )
212	CALL TIMER_STOP( 'THSICE_MAIN [FORWARD_STEP]', myThid)
213	ENDIF
214	#endif /* ALLOW_THSICE */
215
216	# ifdef ALLOW_SEAICE
217	C-- Call sea ice model to compute forcing/external data fields. In
218	C addition to computing prognostic sea-ice variables and diagnosing the
219	C forcing/external data fields that drive the ocean model, SEAICE_MODEL
220	C also sets theta to the freezing point under sea-ice. The implied
221	C surface heat flux is then stored in variable surfaceTendencyTice,
222	C which is needed by KPP package (kpp_calc.F and kpp_transport_t.F)
223	C to diagnose surface buoyancy fluxes and for the non-local transport
224	C term. Because this call precedes model thermodynamics, temperature
225	C under sea-ice may not be "exactly" at the freezing point by the time
226	C theta is dumped or time-averaged.
227	IF ( useSEAICE ) THEN
228	#ifdef ALLOW_DEBUG
229	IF ( debugLevel .GE. debLevB )
230	& CALL DEBUG_CALL('SEAICE_MODEL',myThid)
231	#endif
232	CALL TIMER_START('SEAICE_MODEL [FORWARD_STEP]',myThid)
233	CALL SEAICE_MODEL( myTime, myIter, myThid )
234	CALL TIMER_STOP ('SEAICE_MODEL [FORWARD_STEP]',myThid)
235	ENDIF
236	# endif /* ALLOW_SEAICE */
237
238	C-- Freeze water at the surface
239	#ifdef ALLOW_AUTODIFF_TAMC
240	CADJ STORE theta = comlev1, key = ikey_dynamics
241	#endif
242	IF ( allowFreezing .AND. .NOT. useSEAICE
243	& .AND. .NOT. useThSIce ) THEN
244	CALL FREEZE_SURFACE( myTime, myIter, myThid )
245	ENDIF
246
247	#ifdef ALLOW_AUTODIFF_TAMC
248	# ifdef ALLOW_PTRACERS
249	cph this replaces _bibj storing of ptracer within thermodynamics
250	CADJ STORE ptracer = comlev1, key = ikey_dynamics
251	# endif
252	#endif
253
254	#ifdef ALLOW_PTRACERS
255	# ifdef ALLOW_GCHEM
256	CALL GCHEM_FIELDS_LOAD( mytime, myiter, mythid )
257	# endif
258	#endif
259
260	#ifdef COMPONENT_MODULE
261	IF ( useCoupler ) THEN
262	C Post coupling data that I export.
263	C Read in coupling data that I import.
264	CALL TIMER_START('CPL_EXPORT-IMPORT [FORWARD_STEP]',myThid)
265	CALL CPL_EXPORT_MY_DATA( myIter, myTime, myThid )
266	CALL CPL_IMPORT_EXTERNAL_DATA( myIter, myTime, myThid )
267	CALL TIMER_STOP ('CPL_EXPORT-IMPORT [FORWARD_STEP]',myThid)
268	ENDIF
269	#endif /* COMPONENT_MODULE */
270
271	#ifdef COMPONENT_MODULE
272	# ifndef ALLOW_AIM
273	C jmc: don't know precisely where to put this call. leave it here for now.
274	IF ( useCoupler ) THEN
275	CALL OCN_APPLY_IMPORT( myTime, myIter, myThid )
276	ENDIF
277	# endif
278	#endif /* COMPONENT_MODULE */
279
280	C-- Step forward fields and calculate time tendency terms.
281	C AMM
282	#ifdef ALLOW_FIZHI
283	CALL UPDATE_OCEAN_EXPORTS ( myTime, myIter, myThid )
284	CALL UPDATE_EARTH_EXPORTS ( myTime, myIter, myThid )
285	CALL UPDATE_CHEMISTRY_EXPORTS ( myTime, myIter, myThid )
286	CALL TIMER_START('FIZHI_WRAPPER [FORWARD_STEP]',mythid)
287	CALL FIZHI_WRAPPER ( myTime, myIter, myThid )
288	CALL TIMER_STOP ('FIZHI_WRAPPER [FORWARD_STEP]',mythid)
289
290	CALL STEP_FIZHI_FG ( myTime, myIter, myThid )
291	#endif
292	C AMM
293
294	#ifdef ALLOW_DEBUG
295	IF ( debugLevel .GE. debLevB )
296	& CALL DEBUG_CALL('THERMODYNAMICS',myThid)
297	#endif
298	CALL TIMER_START('THERMODYNAMICS [FORWARD_STEP]',mythid)
299	CALL THERMODYNAMICS( myTime, myIter, myThid )
300	CALL TIMER_STOP ('THERMODYNAMICS [FORWARD_STEP]',mythid)
301
302	C-- do exchanges (needed for DYNAMICS) when using stagger time-step :
303	#ifdef ALLOW_DEBUG
304	IF ( debugLevel .GE. debLevB )
305	& CALL DEBUG_CALL('DO_STAGGER_FIELDS_EXCH.',myThid)
306	#endif
307	CALL TIMER_START('BLOCKING_EXCHANGES [FORWARD_STEP]',myThid)
308	CALL DO_STAGGER_FIELDS_EXCHANGES( myTime, myIter, myThid )
309	CALL TIMER_STOP ('BLOCKING_EXCHANGES [FORWARD_STEP]',myThid)
310
311	#ifdef ALLOW_SHAP_FILT
312	IF (useSHAP_FILT .AND.
313	& staggerTimeStep .AND. shap_filt_TrStagg ) THEN
314	#ifdef ALLOW_DEBUG
315	IF ( debugLevel .GE. debLevB )
316	& CALL DEBUG_CALL('SHAP_FILT_APPLY_TS',myThid)
317	#endif
318	CALL TIMER_START('SHAP_FILT [FORWARD_STEP]',myThid)
319	CALL SHAP_FILT_APPLY_TS(gT,gS,myTime+deltaT,myIter+1,myThid)
320	CALL TIMER_STOP ('SHAP_FILT [FORWARD_STEP]',myThid)
321	ENDIF
322	#endif
323	#ifdef ALLOW_ZONAL_FILT
324	IF (useZONAL_FILT .AND.
325	& staggerTimeStep .AND. zonal_filt_TrStagg ) THEN
326	#ifdef ALLOW_DEBUG
327	IF ( debugLevel .GE. debLevB )
328	& CALL DEBUG_CALL('ZONAL_FILT_APPLY_TS',myThid)
329	#endif
330	CALL TIMER_START('ZONAL_FILT_APPLY [FORWARD_STEP]',myThid)
331	CALL ZONAL_FILT_APPLY_TS( gT, gS, myThid )
332	CALL TIMER_STOP ('ZONAL_FILT_APPLY [FORWARD_STEP]',myThid)
333	ENDIF
334	#endif
335
336	C-- Step forward fields and calculate time tendency terms.
337	#ifndef ALLOW_AUTODIFF_TAMC
338	IF ( momStepping ) THEN
339	#endif
340	#ifdef ALLOW_DEBUG
341	IF ( debugLevel .GE. debLevB )
342	& CALL DEBUG_CALL('DYNAMICS',myThid)
343	#endif
344	CALL TIMER_START('DYNAMICS [FORWARD_STEP]',mythid)
345	CALL DYNAMICS( myTime, myIter, myThid )
346	CALL TIMER_STOP ('DYNAMICS [FORWARD_STEP]',mythid)
347	#ifndef ALLOW_AUTODIFF_TAMC
348	ENDIF
349	#endif
350
351	#ifdef ALLOW_NONHYDROSTATIC
352	C-- Step forward W field in N-H algorithm
353	IF ( momStepping .AND. nonHydrostatic ) THEN
354	#ifdef ALLOW_DEBUG
355	IF ( debugLevel .GE. debLevB )
356	& CALL DEBUG_CALL('CALC_GW',myThid)
357	#endif
358	CALL TIMER_START('CALC_GW [FORWARD_STEP]',myThid)
359	CALL CALC_GW(myThid)
360	CALL TIMER_STOP ('CALC_GW [FORWARD_STEP]',myThid)
361	ENDIF
362	#endif
363
364	#ifdef NONLIN_FRSURF
365	C-- update hfacC,W,S and recip_hFac according to etaH(n+1) :
366	IF ( nonlinFreeSurf.GT.0) THEN
367	IF ( select_rStar.GT.0 ) THEN
368	CALL TIMER_START('UPDATE_R_STAR [FORWARD_STEP]',myThid)
369	CALL UPDATE_R_STAR( myTime, myIter, myThid )
370	CALL TIMER_STOP ('UPDATE_R_STAR [FORWARD_STEP]',myThid)
371	ELSE
372	CALL TIMER_START('UPDATE_SURF_DR [FORWARD_STEP]',myThid)
373	CALL UPDATE_SURF_DR( myTime, myIter, myThid )
374	CALL TIMER_STOP ('UPDATE_SURF_DR [FORWARD_STEP]',myThid)
375	ENDIF
376	ENDIF
377	C- update also CG2D matrix (and preconditioner)
378	IF ( momStepping .AND. nonlinFreeSurf.GT.2 ) THEN
379	CALL TIMER_START('UPDATE_CG2D [FORWARD_STEP]',myThid)
380	CALL UPDATE_CG2D( myTime, myIter, myThid )
381	CALL TIMER_STOP ('UPDATE_CG2D [FORWARD_STEP]',myThid)
382	ENDIF
383	#endif
384
385	C-- Apply Filters to u,v before SOLVE_FOR_PRESSURE
386	#ifdef ALLOW_SHAP_FILT
387	IF (useSHAP_FILT .AND. shap_filt_uvStar) THEN
388	CALL TIMER_START('SHAP_FILT [FORWARD_STEP]',myThid)
389	IF (implicDiv2Dflow.LT.1.) THEN
390	C-- Explicit+Implicit part of the Barotropic Flow Divergence
391	C => Filtering of uVel,vVel is necessary
392	CALL SHAP_FILT_APPLY_UV( uVel,vVel,
393	& myTime+deltaT, myIter+1, myThid )
394	ENDIF
395	CALL SHAP_FILT_APPLY_UV( gU,gV,myTime+deltaT,myIter+1,myThid)
396	CALL TIMER_STOP ('SHAP_FILT [FORWARD_STEP]',myThid)
397	ENDIF
398	#endif
399	#ifdef ALLOW_ZONAL_FILT
400	IF (useZONAL_FILT .AND. zonal_filt_uvStar) THEN
401	CALL TIMER_START('ZONAL_FILT_APPLY [FORWARD_STEP]',myThid)
402	IF (implicDiv2Dflow.LT.1.) THEN
403	C-- Explicit+Implicit part of the Barotropic Flow Divergence
404	C => Filtering of uVel,vVel is necessary
405	CALL ZONAL_FILT_APPLY_UV( uVel, vVel, myThid )
406	ENDIF
407	CALL ZONAL_FILT_APPLY_UV( gU, gV, myThid )
408	CALL TIMER_STOP ('ZONAL_FILT_APPLY [FORWARD_STEP]',myThid)
409	ENDIF
410	#endif
411
412	C-- Solve elliptic equation(s).
413	C Two-dimensional only for conventional hydrostatic or
414	C three-dimensional for non-hydrostatic and/or IGW scheme.
415	IF ( momStepping ) THEN
416	CALL TIMER_START('SOLVE_FOR_PRESSURE [FORWARD_STEP]',myThid)
417	CALL SOLVE_FOR_PRESSURE(myTime, myIter, myThid)
418	CALL TIMER_STOP ('SOLVE_FOR_PRESSURE [FORWARD_STEP]',myThid)
419	ENDIF
420
421	#ifdef ALLOW_AUTODIFF_TAMC
422	cph This is needed because convective_adjustment calls
423	cph find_rho which may use pressure()
424	CADJ STORE totphihyd = comlev1, key = ikey_dynamics
425	#endif
426	C-- Correct divergence in flow field and cycle time-stepping
427	C arrays (for all fields) ; update time-counter
428	myIter = nIter0 + iLoop
429	myTime = startTime + deltaTClock * float(iLoop)
430	CALL TIMER_START('THE_CORRECTION_STEP [FORWARD_STEP]',myThid)
431	CALL THE_CORRECTION_STEP(myTime, myIter, myThid)
432	CALL TIMER_STOP ('THE_CORRECTION_STEP [FORWARD_STEP]',myThid)
433
434	C-- Do "blocking" sends and receives for tendency "overlap" terms
435	c CALL TIMER_START('BLOCKING_EXCHANGES [FORWARD_STEP]',myThid)
436	c CALL DO_GTERM_BLOCKING_EXCHANGES( myThid )
437	c CALL TIMER_STOP ('BLOCKING_EXCHANGES [FORWARD_STEP]',myThid)
438
439	C-- Do "blocking" sends and receives for field "overlap" terms
440	CALL TIMER_START('BLOCKING_EXCHANGES [FORWARD_STEP]',myThid)
441	CALL DO_FIELDS_BLOCKING_EXCHANGES( myThid )
442	CALL TIMER_STOP ('BLOCKING_EXCHANGES [FORWARD_STEP]',myThid)
443
444	cswdptr -- add for seperate timestepping of chemical/biological/forcing
445	cswdptr of ptracers ---
446	#ifdef ALLOW_GCHEM
447	ceh3 This is broken -- this ifdef should not be visible!
448	#ifdef PTRACERS_SEPARATE_FORCING
449	ceh3 needs an IF ( use GCHEM ) THEN
450	call GCHEM_FORCING_SEP( myTime,myIter,myThid )
451	#endif /* PTRACERS_SEPARATE_FORCING */
452	#endif /* ALLOW_GCHEM */
453	cswdptr -- end add ---
454
455	C AMM
456	#ifdef ALLOW_FIZHI
457	CALL STEP_FIZHI_CORR ( myTime, myIter, myThid )
458	#endif
459	C AMM
460
461	#ifdef ALLOW_FLT
462	C-- Calculate float trajectories
463	IF (useFLT) THEN
464	CALL TIMER_START('FLOATS [FORWARD_STEP]',myThid)
465	CALL FLT_MAIN(myIter,myTime, myThid)
466	CALL TIMER_STOP ('FLOATS [FORWARD_STEP]',myThid)
467	ENDIF
468	#endif
469
470	#ifdef ALLOW_MONITOR
471	C-- Check status of solution (statistics, cfl, etc...)
472	CALL TIMER_START('MONITOR [FORWARD_STEP]',myThid)
473	CALL MONITOR( myIter, myTime, myThid )
474	CALL TIMER_STOP ('MONITOR [FORWARD_STEP]',myThid)
475	#endif /* ALLOW_MONITOR */
476
477	C-- Do IO if needed.
478	CALL TIMER_START('DO_THE_MODEL_IO [FORWARD_STEP]',myThid)
479	CALL DO_THE_MODEL_IO( myTime, myIter, myThid )
480	CALL TIMER_STOP ('DO_THE_MODEL_IO [FORWARD_STEP]',myThid)
481
482	C-- Save state for restarts
483	C Note: (jmc: is it still the case after ckp35 ?)
484	C =====
485	C Because of the ordering of the timestepping code and
486	C tendency term code at end of loop model arrays hold
487	C U,V,T,S at "time-level" N but gu, gv, gs, gt, guNM1,...
488	C at "time-level" N+1/2 (guNM1 at "time-level" N+1/2 is
489	C gu at "time-level" N-1/2) and etaN at "time-level" N+1/2.
490	C where N = I+timeLevBase-1
491	C Thus a checkpoint contains U.0000000000, GU.0000000001 and
492	C etaN.0000000001 in the indexing scheme used for the model
493	C "state" files. This example is referred to as a checkpoint
494	C at time level 1
495	CALL TIMER_START('WRITE_CHECKPOINT [FORWARD_STEP]',myThid)
496	CALL PACKAGES_WRITE_PICKUP(
497	I .FALSE., myTime, myIter, myThid )
498	CALL WRITE_CHECKPOINT(
499	I .FALSE., myTime, myIter, myThid )
500	CALL TIMER_STOP ('WRITE_CHECKPOINT [FORWARD_STEP]',myThid)
501
502	#ifdef ALLOW_DEBUG
503	IF ( debugLevel .GE. debLevB )
504	& CALL DEBUG_LEAVE('FORWARD_STEP',myThid)
505	#endif
506
507	RETURN
508	END