source: LMDZ.3.3/branches/rel-LF/libf/phylmd/oasis.F @ 486

Last change on this file since 486 was 486, checked in by lmdzadmin, 21 years ago

Phasage avec la version de Ionela
IM/LF

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[105]1C $Id: oasis.F 486 2003-12-15 17:50:41Z lmdzadmin $
[2]2C****
3C
4C**** *INICMA*  - Initialize coupled mode communication for atmosphere
[105]5C                 and exchange some initial information with Oasis
[2]6C
7C     Input:
8C     -----
9C       KASTP  : total number of timesteps in atmospheric model
10C       KEXCH  : frequency of exchange (in time steps)
[105]11C       KSTEP  : length of timestep (in seconds)
[2]12C
13C     -----------------------------------------------------------
14C
[121]15      SUBROUTINE inicma(kastp,kexch,kstep,imjm)
[13]16c
[397]17c     INCLUDE "param.h"
[105]18c
[121]19      INTEGER kastp, kexch, kstep,imjm
[13]20      INTEGER iparal(3)
[105]21      INTEGER ifcpl, idt, info, imxtag, istep, jf
[13]22c
[397]23#include "param_cou.h"
24#include "inc_cpl.h"
[13]25      CHARACTER*3 cljobnam      ! experiment name
26      CHARACTER*6 clmodnam      ! model name
[105]27c     EM: not used by Oasis2.4
28CEM      CHARACTER*6 clbid(2)      ! for CLIM_Init call (not used)
29CEM                                ! must be dimensioned by the number of models
30CEM      INTEGER nbid(2)           ! for CLIM_Init call (not used)
31CEM                                ! must be dimensioned by the number of models
[13]32      CHARACTER*5 cloasis       ! coupler name (Oasis)
[105]33      INTEGER imess(4)
34      INTEGER getpid            ! system functions
[2]35      INTEGER nuout
[105]36CEM      LOGICAL llmodel
[2]37      PARAMETER (nuout = 6)
[13]38c
[397]39#include "clim.h"
40#include "mpiclim.h"
[13]41c
[486]42#include "oasis.h"     
43                        ! contains the name of communication technique. Here
[105]44                        ! cchan=CLIM only is possible.
45c                       ! ctype=MPI2
46c
[2]47C     -----------------------------------------------------------
48C
49C*    1. Initializations
50C        ---------------
51C
52      WRITE(nuout,*) ' '
53      WRITE(nuout,*) ' '
54      WRITE(nuout,*) ' ROUTINE INICMA'
55      WRITE(nuout,*) ' **************'
56      WRITE(nuout,*) ' '
57      WRITE(nuout,*) ' '
58c
[105]59c     Define the model name
[2]60c
[131]61      clmodnam = 'lmdz.x'       ! as in $NBMODEL in Cpl/Nam/namcouple.tmp
[2]62c
[105]63c     Define the coupler name
[2]64c
[105]65      cloasis = 'Oasis'        !  always 'Oasis' as in the coupler
[2]66c
67c
[105]68c     Define symbolic name for fields exchanged from atmos to coupler,
[13]69c         must be the same as (1) of the field  definition in namcouple:
[2]70c
[105]71      cl_writ(1)='COSHFICE'
72      cl_writ(2)='COSHFOCE'
73      cl_writ(3)='CONSFICE'
74      cl_writ(4)='CONSFOCE'
75      cl_writ(5)='CODFLXDT'
76c      cl_writ(6)='COICTEMP'
77      cl_writ(6)='COTFSICE'
78      cl_writ(7)='COTFSOCE'
79      cl_writ(8)='COTOLPSU'
80      cl_writ(9)='COTOSPSU'
81      cl_writ(10)='CORUNCOA'
82      cl_writ(11)='CORIVFLU'
[394]83      cl_writ(12)='COCALVIN'
84c$$$      cl_writ(13)='COZOTAUX'
85c$$$      cl_writ(14)='COZOTAUV'
86c$$$      cl_writ(15)='COMETAUY'
87c$$$      cl_writ(16)='COMETAUU'
88      cl_writ(13)='COTAUXXU'
89      cl_writ(14)='COTAUYYU'
90      cl_writ(15)='COTAUZZU'
91      cl_writ(16)='COTAUXXV'
92      cl_writ(17)='COTAUYYV'
93      cl_writ(18)='COTAUZZV'
[2]94c
[105]95c     Define files name for fields exchanged from atmos to coupler,
[13]96c         must be the same as (6) of the field  definition in namcouple:
[2]97c
[105]98      cl_f_writ(1)='flxatmos'
99      cl_f_writ(2)='flxatmos'
100      cl_f_writ(3)='flxatmos'
101      cl_f_writ(4)='flxatmos'
102      cl_f_writ(5)='flxatmos'
103      cl_f_writ(6)='flxatmos'
104      cl_f_writ(7)='flxatmos'
105      cl_f_writ(8)='flxatmos'
106      cl_f_writ(9)='flxatmos'
107      cl_f_writ(10)='flxatmos'
108      cl_f_writ(11)='flxatmos'
109      cl_f_writ(12)='flxatmos'
110      cl_f_writ(13)='flxatmos'
111      cl_f_writ(14)='flxatmos'
112      cl_f_writ(15)='flxatmos'
[177]113      cl_f_writ(16)='flxatmos'
114      cl_f_writ(17)='flxatmos'
[394]115      cl_f_writ(18)='flxatmos'
[177]116
[2]117c
118c
[105]119c     Define symbolic name for fields exchanged from coupler to atmosphere,
[13]120c         must be the same as (2) of the field  definition in namcouple:
[2]121c
[105]122      cl_read(1)='SISUTESW'
[13]123      cl_read(2)='SIICECOV'
[105]124      cl_read(3)='SIICEALW'
125      cl_read(4)='SIICTEMW'
[2]126c
[105]127c     Define files names for fields exchanged from coupler to atmosphere,
[13]128c         must be the same as (7) of the field  definition in namcouple:
[2]129c
[105]130      cl_f_read(1)='sstatmos'
131      cl_f_read(2)='sstatmos'
132      cl_f_read(3)='sstatmos'
133      cl_f_read(4)='sstatmos'
[2]134c
135c
[105]136c     Define the number of processors involved in the coupling for
137c     Oasis (=1) and each model (as last two INTEGER on $CHATYPE line
138c     in the namcouple); they will be stored in a COMMON in mpiclim.h
139c     (used for CLIM/MPI2 only)
140      mpi_nproc(0)=1
141      mpi_nproc(1)=1
142      mpi_nproc(2)=1
[2]143c
[105]144c     Define infos to be sent initially to oasis
[2]145c
[105]146      imess(1) = kastp      ! total number of timesteps in atmospheric model
147      imess(2) = kexch      ! period of exchange (in time steps)
148      imess(3) = kstep      ! length of atmospheric timestep (in seconds)
149      imess(4) = getpid()   ! PID of atmospheric model
[2]150c
[105]151c     Initialization and exchange of initial info in the CLIM technique
[2]152c
[105]153      IF (cchan.eq.'CLIM') THEN
[2]154c
[105]155c     Define the experiment name :
[2]156c
[105]157          cljobnam = 'CLI'      ! as $JOBNAM in namcouple
[2]158c
[105]159c         Start the coupling
160c         (see lib/clim/src/CLIM_Init for the definition of input parameters)
[2]161c
[105]162cEM          clbid(1)='      '
163cEM          clbid(2)='      '
164cEM          nbid(1)=0
165cEM          nbid(2)=0
166CEM          llmodel=.true.
[2]167c
[105]168c         Define the number of processors used by each model as in
169c         $CHATYPE line of namcouple (used for CLIM/MPI2 only)
170          mpi_totproc(1)=1
171          mpi_totproc(2)=1
[2]172c
[105]173c         Define names of each model as in $NBMODEL line of namcouple
174c         (used for CLIM/MPI2 only)       
[131]175          cmpi_modnam(1)='lmdz.x'
[153]176          cmpi_modnam(2)='opa.xx'
[105]177c         Start the coupling
[2]178c
[13]179          CALL CLIM_Init ( cljobnam, clmodnam, 3, 7,
[2]180     *                 kastp, kexch, kstep,
[13]181     *                 5, 3600, 3600, info )
[2]182c
[105]183          IF (info.ne.CLIM_Ok) THEN
[13]184              WRITE ( nuout, *) ' inicma : pb init clim '
185              WRITE ( nuout, *) ' error code is = ', info
[105]186              CALL halte('STOP in inicma')
[13]187            ELSE
188              WRITE(nuout,*) 'inicma : init clim ok '
189          ENDIF
[2]190c
[105]191c         For each coupling field, association of a port to its symbolic name
192c
193c         -Define the parallel decomposition associated to the port of each
194c          field; here no decomposition for all ports.
195          iparal ( clim_strategy ) = clim_serial
196          iparal ( clim_length   ) = imjm
[13]197          iparal ( clim_offset   ) = 0
[2]198c
[105]199c         -Loop on total number of coupler-to-atmosphere fields
200c         (see lib/clim/src/CLIM_Define for the definition of input parameters)
[13]201          DO jf=1, jpfldo2a
202            CALL CLIM_Define (cl_read(jf), clim_in , clim_double, iparal
203     $          , info ) 
[394]204            WRITE(nuout,*) 'inicma : clim define done for ',jf
205     $          ,cl_read(jf)
[13]206          END DO
[2]207c
[105]208c         -Loop on total number of atmosphere-to-coupler fields
209c         (see lib/clim/src/CLIM_Define for the definition of input parameters)
210          DO jf=1, jpflda2o1+jpflda2o2
[13]211            CALL CLIM_Define (cl_writ(jf), clim_out , clim_double,
212     $          iparal, info )   
[394]213            WRITE(nuout,*) 'inicma : clim define done for ',jf
214     $          ,cl_writ(jf)
[13]215          END DO
[105]216c
[13]217          WRITE(nuout,*) 'inicma : clim_define ok '
[105]218c
219c         -Join a pvm group, wait for other programs and broadcast usefull
220c          informations to Oasis and to the ocean (see lib/clim/src/CLIM_Start)
[13]221          CALL CLIM_Start ( imxtag, info )
222          IF (info.ne.clim_ok) THEN
223              WRITE ( nuout, *) 'inicma : pb start clim '
224              WRITE ( nuout, *) ' error code is = ', info
[105]225              CALL halte('stop in inicma')
[13]226            ELSE
227              WRITE ( nuout, *)  'inicma : start clim ok '
228          ENDIF
[2]229c
[105]230c         -Get initial information from Oasis
231c          (see lib/clim/src/CLIM_Stepi)
[13]232          CALL CLIM_Stepi (cloasis, istep, ifcpl, idt, info)
233          IF (info .NE. clim_ok) THEN
234              WRITE ( UNIT = nuout, FMT = *)
235     $            ' warning : problem in getting step info ',
236     $            'from oasis '
237              WRITE (UNIT = nuout, FMT = *)
238     $            ' =======   error code number = ', info
239            ELSE
240              WRITE (UNIT = nuout, FMT = *)
241     $            ' got step information from oasis '
242          ENDIF
243          WRITE ( nuout, *) ' number of tstep in oasis ', istep
244          WRITE ( nuout, *) ' exchange frequency in oasis ', ifcpl
245          WRITE ( nuout, *) ' length of tstep in oasis ', idt
246      ENDIF
247
[2]248      RETURN
249      END
[13]250
[105]251c $Id: oasis.F 486 2003-12-15 17:50:41Z lmdzadmin $
252      SUBROUTINE fromcpl(kt, imjm, sst, gla, tice, albedo)
253c ======================================================================
254c S. Valcke (02/99) adapted From L.Z.X Li: this subroutine reads the SST
255c and Sea-Ice provided by the coupler with the CLIM (PVM exchange messages)
256c technique.
257c======================================================================
[2]258      IMPLICIT none
[13]259      INTEGER imjm, kt
260      REAL sst(imjm)          ! sea-surface-temperature
[105]261      REAL gla(imjm)          ! sea-ice
262      REAL tice(imjm)          ! temp glace
263      REAL albedo(imjm)          ! albedo glace
[2]264c
[13]265      INTEGER nuout             ! listing output unit
[2]266      PARAMETER (nuout=6)
267c
268      INTEGER nuread, ios, iflag, icpliter
[13]269      INTEGER info, jf
[2]270c
[397]271#include "clim.h"
[2]272c
[397]273#include "oasis.h"
274#include "param_cou.h"
[2]275c
[397]276#include "inc_cpl.h"
[2]277c
278c
[13]279      WRITE (nuout,*) ' '
[105]280      WRITE (nuout,*) 'Fromcpl: Reading fields from CPL, kt=',kt
[13]281      WRITE (nuout,*) ' '
[2]282      CALL flush (nuout)
[13]283
284
[105]285      IF (cchan.eq.'CLIM') THEN
[2]286
287c
[105]288c     -Get interpolated oceanic fields from Oasis
[13]289c
[105]290          DO jf=1,jpfldo2a
291            IF (jf.eq.1) CALL CLIM_Import (cl_read(jf) , kt, sst, info)
292            IF (jf.eq.2) CALL CLIM_Import (cl_read(jf) , kt, gla, info)
293            IF (jf.eq.3) CALL CLIM_Import (cl_read(jf), kt,albedo, info)
294            IF (jf.eq.4) CALL CLIM_Import (cl_read(jf) , kt, tice, info)
295            IF ( info .NE. CLIM_Ok) THEN
[13]296                WRITE(nuout,*)'Pb in reading ', cl_read(jf), jf
297                WRITE(nuout,*)'Couplage kt is = ',kt
298                WRITE(nuout,*)'CLIM error code is = ', info
[105]299                CALL halte('STOP in fromcpl.F')
[13]300            ENDIF
301          END DO
302
303      ENDIF
304c
[2]305      RETURN
306      END
307
[105]308c $Id: oasis.F 486 2003-12-15 17:50:41Z lmdzadmin $
309      SUBROUTINE intocpl(kt, imjm, fsolice, fsolwat, fnsolice, fnsolwat,
[394]310     $    fnsicedt, evice, evwat, lpre, spre, dirunoff, rivrunoff,
311     $    calving, tauxx_u, tauyy_u, tauzz_u, tauxx_v, tauyy_v, tauzz_v
312     $    , last)
[105]313c ======================================================================
314c S. Valcke (02/99) adapted From L.Z.X Li: this subroutine provides the
315c atmospheric coupling fields to the coupler with the CLIM (PVM exchange
316c messages) technique.
317c IF last time step, writes output fields to binary files.
318c ======================================================================
[2]319      IMPLICIT NONE
[13]320      INTEGER kt, imjm
[2]321c
[105]322      REAL fsolice(imjm)
323      REAL fsolwat(imjm)
324      REAL fnsolwat(imjm)
[177]325      REAL fnsolice(imjm)
326      REAL fnsicedt(imjm)
[105]327      REAL evice(imjm)
328      REAL evwat(imjm)
329      REAL lpre(imjm)
330      REAL spre(imjm)
331      REAL dirunoff(imjm)
332      REAL rivrunoff(imjm)
[394]333      REAL calving(imjm)
[177]334c$$$      REAL tauxu(imjm)
335c$$$      REAL tauxv(imjm)
336c$$$      REAL tauyu(imjm)
337c$$$      REAL tauyv(imjm)
338      REAL tauxx_u(imjm)
339      REAL tauxx_v(imjm)
340      REAL tauyy_u(imjm)
341      REAL tauyy_v(imjm)
342      REAL tauzz_u(imjm)
343      REAL tauzz_v(imjm)
[13]344      LOGICAL last
[2]345c
346      INTEGER nuout
347      PARAMETER (nuout = 6)
348c
[397]349#include "clim.h"
350#include "param_cou.h"
351#include "inc_cpl.h"
[2]352c
[105]353      CHARACTER*8 file_name(jpmaxfld)
[13]354      INTEGER max_file
355      INTEGER file_unit_max, file_unit(jpmaxfld),
356     $    file_unit_field(jpmaxfld)
357
358      INTEGER icstep, info, jn, jf, ierror
359      LOGICAL trouve
[2]360c
[397]361#include "oasis.h"
[2]362c
[13]363      icstep=kt
[2]364c
[13]365      WRITE(nuout,*) ' '
[105]366      WRITE(nuout,*) 'Intocpl: sending fields to CPL, kt= ', kt
[394]367      WRITE(nuout,*) 'last  ', last
368      WRITE(nuout,*)
[13]369
[105]370      IF (last) THEN
[2]371c
[105]372c     -WRITE fields to binary files for coupler restart at last time step
[2]373c
[105]374c         -initialisation and files opening
[2]375c
[13]376          max_file=1
377          file_unit_max=99
[105]378c         -keeps first file name
[13]379          file_name(max_file)=cl_f_writ(max_file)
[105]380c         -keeps first file unit
[13]381          file_unit(max_file)=file_unit_max
[105]382c         -decrements file unit maximum
[13]383          file_unit_max=file_unit_max-1
[105]384c         -keeps file unit for field
[13]385          file_unit_field(1)=file_unit(max_file)
[2]386c
[105]387c         -different files names counter
[2]388c
[105]389          DO jf= 2, jpflda2o1 + jpflda2o2
[13]390            trouve=.false.
391            DO jn= 1, max_file
392              IF (.not.trouve) THEN
393                  IF (cl_f_writ(jf).EQ.file_name(jn)) THEN
[105]394c                 -keep file unit for field
[13]395                      file_unit_field(jf)=file_unit(jn)
396                      trouve=.true.
397                  END IF
398              END IF
399            END DO
400            IF (.not.trouve) then
[105]401c           -increment the number of different files
[13]402                max_file=max_file+1
[105]403c           -keep file name
[13]404                file_name(max_file)=cl_f_writ(jf)
[105]405c           -keep file unit for file
[13]406                file_unit(max_file)=file_unit_max
[105]407c           -keep file unit for field
[13]408                file_unit_field(jf)=file_unit(max_file)
[105]409c           -decrement unit maximum number from 99 to 98, ...
[13]410                file_unit_max=file_unit_max-1
411            END IF
412          END DO
[105]413c         
[13]414          DO jn=1, max_file
415            OPEN (file_unit(jn), FILE=file_name(jn), FORM='UNFORMATTED')
[394]416            WRITE(*,*) 'Opening FILE ', file_unit(jn), ' '
417     $          , file_name(jn)
418            REWIND(file_unit(jn))
[105]419          END DO
420c
421c         WRITE fields to files         
422          DO jf=1, jpflda2o1 + jpflda2o2
[13]423            IF (jf.eq.1)
[105]424     $          CALL locwrite(cl_writ(jf),fsolice, imjm,
[394]425     $          file_unit_field(jf), ierror)
[13]426            IF (jf.eq.2)
[105]427     $          CALL locwrite(cl_writ(jf),fsolwat, imjm,
[394]428     $          file_unit_field(jf), ierror)
[13]429            IF (jf.eq.3)
[105]430     $          CALL locwrite(cl_writ(jf),fnsolice, imjm,
[394]431     $          file_unit_field(jf), ierror)
[13]432            IF (jf.eq.4)
[105]433     $          CALL locwrite(cl_writ(jf),fnsolwat, imjm,
[394]434     $          file_unit_field(jf), ierror)
[13]435            IF (jf.eq.5)
[105]436     $          CALL locwrite(cl_writ(jf),fnsicedt, imjm,
[394]437     $          file_unit_field(jf), ierror)
[105]438c            IF (jf.eq.6)
439c     $          CALL locwrite(cl_writ(jf),ictemp, imjm,
[394]440c     $          file_unit_field(jf), ierror)
[13]441            IF (jf.eq.6)
[105]442     $          CALL locwrite(cl_writ(jf),evice, imjm,
[394]443     $          file_unit_field(jf), ierror)
[13]444            IF (jf.eq.7)
[105]445     $          CALL locwrite(cl_writ(jf),evwat, imjm,
[394]446     $          file_unit_field(jf), ierror)
[13]447            IF (jf.eq.8)
[105]448     $          CALL locwrite(cl_writ(jf),lpre, imjm,
[394]449     $          file_unit_field(jf), ierror)
[13]450            IF (jf.eq.9)
[105]451     $          CALL locwrite(cl_writ(jf),spre, imjm,
[394]452     $          file_unit_field(jf), ierror)
[13]453            IF (jf.eq.10)
[105]454     $          CALL locwrite(cl_writ(jf),dirunoff, imjm,
[394]455     $          file_unit_field(jf), ierror)
[105]456            IF (jf.eq.11)
457     $          CALL locwrite(cl_writ(jf),rivrunoff, imjm,
[394]458     $          file_unit_field(jf), ierror)
459            IF (jf.eq.12)
460     $          CALL locwrite(cl_writ(jf),calving, imjm,
461     $          file_unit_field(jf), ierror)
462c$$$            IF (jf.eq.13)
[177]463c$$$     $          CALL locwrite(cl_writ(jf),tauxu, imjm,
[394]464c$$$     $          file_unit_field(jf),ierror)
465c$$$            IF (jf.eq.1')
[177]466c$$$     $          CALL locwrite(cl_writ(jf),tauxv, imjm,
[394]467c$$$     $          file_unit_field(jf),ierror)
468c$$$            IF (jf.eq.15)
[177]469c$$$     $          CALL locwrite(cl_writ(jf),tauyv, imjm,
[394]470c$$$     $          file_unit_field(jf),ierror)
471c$$$            IF (jf.eq.16)
[177]472c$$$     $          CALL locwrite(cl_writ(jf),tauyu, imjm,
[394]473c$$$     $          file_unit_field(jf), ierror)
474            IF (jf.eq.13)
[177]475     $          CALL locwrite(cl_writ(jf),tauxx_u, imjm,
476     $          file_unit_field(jf),ierror)
[394]477            IF (jf.eq.14)
[177]478     $          CALL locwrite(cl_writ(jf),tauyy_u, imjm,
479     $          file_unit_field(jf),ierror)
[394]480            IF (jf.eq.15)
[177]481     $          CALL locwrite(cl_writ(jf),tauzz_u, imjm,
482     $          file_unit_field(jf),ierror)
[394]483            IF (jf.eq.16)
[177]484     $          CALL locwrite(cl_writ(jf),tauxx_v, imjm,
485     $          file_unit_field(jf),ierror)
[394]486            IF (jf.eq.17)
[177]487     $          CALL locwrite(cl_writ(jf),tauyy_v, imjm,
488     $          file_unit_field(jf),ierror)
[394]489            IF (jf.eq.18)
[177]490     $          CALL locwrite(cl_writ(jf),tauzz_v, imjm,
491     $          file_unit_field(jf),ierror)
[13]492          END DO
493C
[105]494C         -simulate a FLUSH
[13]495C
496          DO jn=1, max_file
497            CLOSE (file_unit(jn))
498          END DO
[105]499C
500C
[13]501          IF(cchan.eq.'CLIM') THEN
[105]502C
503C         -inform PVM daemon that message exchange is finished
504C
[13]505              CALL CLIM_Quit (CLIM_ContPvm, info)
506              IF (info .NE. CLIM_Ok) THEN
507                  WRITE (6, *)
508     $                'An error occured while leaving CLIM. Error = ',
509     $                info
510              ENDIF
511          END IF
[105]512          RETURN   
[13]513      END IF
[105]514C
515      IF(cchan.eq.'CLIM') THEN
516C
517C     -Give atmospheric fields to Oasis
518C
519          DO jn=1, jpflda2o1 + jpflda2o2
520C           
521          IF (jn.eq.1) CALL CLIM_Export(cl_writ(jn), kt, fsolice, info)
522          IF (jn.eq.2) CALL CLIM_Export(cl_writ(jn), kt, fsolwat, info)
523          IF (jn.eq.3) CALL CLIM_Export(cl_writ(jn), kt, fnsolice, info)
524          IF (jn.eq.4) CALL CLIM_Export(cl_writ(jn), kt, fnsolwat, info)
525          IF (jn.eq.5) CALL CLIM_Export(cl_writ(jn), kt, fnsicedt, info)
526c          IF (jn.eq.6) CALL CLIM_Export(cl_writ(jn), kt, ictemp, info)
527          IF (jn.eq.6) CALL CLIM_Export(cl_writ(jn), kt, evice, info)
528          IF (jn.eq.7) CALL CLIM_Export(cl_writ(jn), kt, evwat, info)
529          IF (jn.eq.8) CALL CLIM_Export(cl_writ(jn), kt, lpre, info)
530          IF (jn.eq.9) CALL CLIM_Export(cl_writ(jn), kt, spre, info)
531          IF (jn.eq.10) CALL CLIM_Export(cl_writ(jn),kt,dirunoff, info)
532          IF (jn.eq.11) CALL CLIM_Export(cl_writ(jn),kt,rivrunoff,info)
[394]533          IF (jn.eq.12) CALL CLIM_Export(cl_writ(jn),kt,calving,info)
534c$$$          IF (jn.eq.13) CALL CLIM_Export(cl_writ(jn), kt, tauxu, info)
535c$$$          IF (jn.eq.14) CALL CLIM_Export(cl_writ(jn), kt, tauxv, info)
536c$$$          IF (jn.eq.15) CALL CLIM_Export(cl_writ(jn), kt, tauyv, info)
537c$$$          IF (jn.eq.16) CALL CLIM_Export(cl_writ(jn), kt, tauyu, info)
538          IF (jn.eq.13) CALL CLIM_Export(cl_writ(jn), kt, tauxx_u, info)
539          IF (jn.eq.14) CALL CLIM_Export(cl_writ(jn), kt, tauyy_u, info)
540          IF (jn.eq.15) CALL CLIM_Export(cl_writ(jn), kt, tauzz_u, info)
541          IF (jn.eq.16) CALL CLIM_Export(cl_writ(jn), kt, tauxx_v, info)
542          IF (jn.eq.17) CALL CLIM_Export(cl_writ(jn), kt, tauyy_v, info)
543          IF (jn.eq.18) CALL CLIM_Export(cl_writ(jn), kt, tauzz_v, info)
[13]544         
545            IF (info .NE. CLIM_Ok) THEN
546                WRITE (nuout,*) 'STEP : Pb giving ',cl_writ(jn), ':',jn
547                WRITE (nuout,*) ' at timestep = ', icstep,'kt = ',kt
548                WRITE (nuout,*) 'Clim error code is = ',info
[105]549                CALL halte('STOP in intocpl ')
[13]550            ENDIF
551          END DO
552      ENDIF
[105]553C
[2]554      RETURN
555      END
556
[486]557      SUBROUTINE halte
558      print *, 'Attention dans oasis.F, halte est non defini'
559      RETURN
560      END
561
562      SUBROUTINE locread
563      print *, 'Attention dans oasis.F, locread est non defini'
564      RETURN
565      END
566
567      SUBROUTINE locwrite
568      print *, 'Attention dans oasis.F, locwrite est non defini'
569      RETURN
570      END
571
[109]572      SUBROUTINE pipe_model_define
573      print*,'Attention dans oasis.F, pipe_model_define est non defini'
574      RETURN
575      END
576
577      SUBROUTINE pipe_model_stepi
578      print*,'Attention dans oasis.F, pipe_model_stepi est non defini'
579      RETURN
580      END
581
582      SUBROUTINE pipe_model_recv
583      print *, 'Attention dans oasis.F, pipe_model_recv est non defini'
584      RETURN
585      END
586
587      SUBROUTINE pipe_model_send
588      print *, 'Attention dans oasis.F, pipe_model_send est non defini'
589      RETURN
590      END
591
[486]592      SUBROUTINE clim_stepi
593      print *, 'Attention dans oasis.F, clim_stepi est non defini'
594      RETURN
595      END
596
597      SUBROUTINE clim_start
598      print *, 'Attention dans oasis.F, clim_start est non defini'
599      RETURN
600      END
601
602      SUBROUTINE clim_import
603      print *, 'Attention dans oasis.F, clim_import est non defini'
604      RETURN
605      END
606
607      SUBROUTINE clim_export
608      print *, 'Attention dans oasis.F, clim_export est non defini'
609      RETURN
610      END
611
612      SUBROUTINE clim_init
613      print *, 'Attention dans oasis.F, clim_init est non defini'
614      RETURN
615      END
616
617      SUBROUTINE clim_define
618      print *, 'Attention dans oasis.F, clim_define est non defini'
619      RETURN
620      END
621
622      SUBROUTINE clim_quit
623      print *, 'Attention dans oasis.F, clim_quit est non defini'
624      RETURN
625      END
626
627      SUBROUTINE svipc_write
628      print *, 'Attention dans oasis.F, svipc_write est non defini'
629      RETURN
630      END
631
632      SUBROUTINE svipc_close
633      print *, 'Attention dans oasis.F, svipc_close est non defini'
634      RETURN
635      END
636
637      SUBROUTINE svipc_read
638      print *, 'Attention dans oasis.F, svipc_read est non defini'
639      RETURN
640      END
641
[109]642      SUBROUTINE quitcpl
643      print *, 'Attention dans oasis.F, quitcpl est non defini'
644      RETURN
645      END
646
647      SUBROUTINE sipc_write_model
648      print *, 'Attention dans oasis.F, sipc_write_model est non defini'
649      RETURN
650      END
651
652      SUBROUTINE sipc_attach
653      print *, 'Attention dans oasis.F, sipc_attach est non defini'
654      RETURN
655      END
656
657      SUBROUTINE sipc_init_model
658      print *, 'Attention dans oasis.F, sipc_init_model est non defini'
659      RETURN
660      END
661
662      SUBROUTINE sipc_read_model
663      print *, 'Attention dans oasis.F, sipc_read_model est non defini'
664      RETURN
665      END
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