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source: CONFIG/UNIFORM/v6/IPSLCM6/SOURCES/NEMO/closea.F90 @ 2674

Last change on this file since 2674 was 2485, checked in by omamce, 9 years ago

O.M. : handling old ORCA1 and extended ORCA1 grids

in closea.F90

File size: 22.7 KB

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1	MODULE closea
2	!!======================================================================
3	!! * MODULE closea *
4	!! Closed Seas : specific treatments associated with closed seas
5	!!======================================================================
6	!! History : 8.2 ! 00-05 (O. Marti) Original code
7	!! 8.5 ! 02-06 (E. Durand, G. Madec) F90
8	!! 9.0 ! 06-07 (G. Madec) add clo_rnf, clo_ups, clo_bat
9	!! NEMO 3.4 ! 03-12 (P.G. Fogli) sbc_clo bug fix & mpp reproducibility
10	!!----------------------------------------------------------------------
11
12	!!----------------------------------------------------------------------
13	!! dom_clo : modification of the ocean domain for closed seas cases
14	!! sbc_clo : Special handling of closed seas
15	!! clo_rnf : set close sea outflows as river mouths (see sbcrnf)
16	!! clo_ups : set mixed centered/upstream scheme in closed sea (see traadv_cen2)
17	!! clo_bat : set to zero a field over closed sea (see domzrg)
18	!!----------------------------------------------------------------------
19	USE oce ! dynamics and tracers
20	USE dom_oce ! ocean space and time domain
21	USE phycst ! physical constants
22	USE in_out_manager ! I/O manager
23	!USE iom ! I/O manager library
24	USE sbc_oce ! ocean surface boundary conditions
25	USE lib_fortran, ONLY: glob_sum, DDPDD
26	USE lbclnk ! lateral boundary condition - MPP exchanges
27	USE lib_mpp ! MPP library
28	USE timing
29
30	IMPLICIT NONE
31	PRIVATE
32
33	PUBLIC dom_clo ! routine called by domain module
34	PUBLIC sbc_clo ! routine called by step module
35	PUBLIC clo_rnf ! routine called by sbcrnf module
36	PUBLIC clo_ups ! routine called in traadv_cen2(_jki) module
37	PUBLIC clo_bat ! routine called in domzgr module
38
39	INTEGER, PUBLIC, PARAMETER :: jpncs = 4 !: number of closed sea
40	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncstt !: Type of closed sea
41	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncsi1, ncsj1 !: south-west closed sea limits (i,j)
42	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncsi2, ncsj2 !: north-east closed sea limits (i,j)
43	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncsnr !: number of point where run-off pours
44	INTEGER, PUBLIC, DIMENSION(jpncs,4) :: ncsir, ncsjr !: Location of runoff
45
46	REAL(wp), DIMENSION (:,:), ALLOCATABLE :: clo_mask !: Defines area where excess run-off is distributed
47
48	REAL(wp), DIMENSION (jpncs+1) :: surf !: Closed sea surface
49
50	INTEGER :: dia_closea_alloc
51
52	!! * Substitutions
53	# include "vectopt_loop_substitute.h90"
54	!!----------------------------------------------------------------------
55	!! NEMO/OPA 3.3 , NEMO Consortium (2010)
56	!! $Id: closea.F90 4162 2013-11-07 10:19:49Z cetlod $
57	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
58	!!----------------------------------------------------------------------
59	CONTAINS
60
61	SUBROUTINE dom_clo
62	!!---------------------------------------------------------------------
63	!! * ROUTINE dom_clo *
64	!!
65	!! ** Purpose : Closed sea domain initialization
66	!!
67	!! ** Method : if a closed sea is located only in a model grid point
68	!! just the thermodynamic processes are applied.
69	!!
70	!! ** Action : ncsi1(), ncsj1() : south-west closed sea limits (i,j)
71	!! ncsi2(), ncsj2() : north-east Closed sea limits (i,j)
72	!! ncsir(), ncsjr() : Location of runoff
73	!! ncsnr : number of point where run-off pours
74	!! ncstt : Type of closed sea
75	!! =0 spread over the world ocean
76	!! =2 put at location runoff
77	!!----------------------------------------------------------------------
78	INTEGER :: jc ! dummy loop indices
79	REAL(wp):: ztmp
80	INTEGER :: isrow
81	!!----------------------------------------------------------------------
82
83	IF(lwp) WRITE(numout,*)
84	IF(lwp) WRITE(numout,*)'dom_clo : closed seas '
85	IF(lwp) WRITE(numout,*)'~~~~~~~'
86
87	! Initial values
88	ncsnr(:) = 1 ; ncsi1(:) = 1 ; ncsi2(:) = 1 ; ncsir(:,:) = 1
89	ncstt(:) = 0 ; ncsj1(:) = 1 ; ncsj2(:) = 1 ; ncsjr(:,:) = 1
90
91	! set the closed seas (in data domain indices)
92	! -------------------
93
94	IF( cp_cfg == "orca" ) THEN
95	!
96	SELECT CASE ( jp_cfg )
97	! ! =======================
98	CASE ( 1 ) ! ORCA_R1 configuration
99	!
100	!! This dirty section will be suppressed by simplification process: all this will come back in input files
101	!! Currently these hard-wired indices relate to the original (pre-v3.6) configuration which had a grid-size of 362x292.
102	!! This grid has been extended southwards for use with the under ice-shelf options (isf) introduced in v3.6. The original
103	!! domain can still be used optionally if the isf code is not activated. An adjustment (isrow) is made to the hard-wired
104	!! indices if the extended domain (362x332) is being used.
105	!! =======================
106	IF ( jpjglo == 292 ) THEN ! ORCA1 R1 Â Using pre-v3.6 files or adjusted start row from isf-extended grid
107	isrow = 0
108	ELSEIF ( jpjglo == 332 ) THEN ! ORCA1 R1 - Using full isfÂextended domain.
109	isrow = 40 ! - Adjust jÂindices to account for more southerly starting latitude
110	ENDIF
111
112	ncsnr(1) = 1 ; ncstt(1) = 0 ! Caspian Sea
113	ncsi1(1) = 332 ; ncsj1(1) = 203 + isrow ! spread over the globe
114	ncsi2(1) = 344 ; ncsj2(1) = 235 + isrow
115	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
116	!
117	ncsnr(2) = 4 ; ncstt(2) = 2 ! Great North American Lakes
118	ncsi1(2) = 198 ; ncsj1(2) = 209 + isrow ! put at St Laurent mouth
119	ncsi2(2) = 213 ; ncsj2(2) = 223 + isrow
120	ncsir(1,2) = 225 ; ncsjr(1,2) = 220 + isrow
121	ncsir(1,2) = 225 ; ncsjr(1,2) = 221 + isrow
122	ncsir(1,2) = 226 ; ncsjr(1,2) = 220 + isrow
123	ncsir(1,2) = 226 ; ncsjr(1,2) = 221 + isrow
124
125	!
126	! ! =======================
127	CASE ( 2 ) ! ORCA_R2 configuration
128	! ! =======================
129	! ! Caspian Sea
130	ncsnr(1) = 1 ; ncstt(1) = 0 ! spread over the globe
131	ncsi1(1) = 11 ; ncsj1(1) = 103
132	ncsi2(1) = 17 ; ncsj2(1) = 112
133	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
134	! ! Great North American Lakes
135	ncsnr(2) = 1 ; ncstt(2) = 2 ! put at St Laurent mouth
136	ncsi1(2) = 97 ; ncsj1(2) = 107
137	ncsi2(2) = 103 ; ncsj2(2) = 111
138	ncsir(2,1) = 110 ; ncsjr(2,1) = 111
139	! ! Black Sea (crossed by the cyclic boundary condition)
140	ncsnr(3:4) = 4 ; ncstt(3:4) = 2 ! put in Med Sea (north of Aegean Sea)
141	ncsir(3:4,1) = 171; ncsjr(3:4,1) = 106 !
142	ncsir(3:4,2) = 170; ncsjr(3:4,2) = 106
143	ncsir(3:4,3) = 171; ncsjr(3:4,3) = 105
144	ncsir(3:4,4) = 170; ncsjr(3:4,4) = 105
145	ncsi1(3) = 174 ; ncsj1(3) = 107 ! 1 : west part of the Black Sea
146	ncsi2(3) = 181 ; ncsj2(3) = 112 ! (ie west of the cyclic b.c.)
147	ncsi1(4) = 2 ; ncsj1(4) = 107 ! 2 : east part of the Black Sea
148	ncsi2(4) = 6 ; ncsj2(4) = 112 ! (ie east of the cyclic b.c.)
149
150
151
152	! ! =======================
153	CASE ( 4 ) ! ORCA_R4 configuration
154	! ! =======================
155	! ! Caspian Sea
156	ncsnr(1) = 1 ; ncstt(1) = 0
157	ncsi1(1) = 4 ; ncsj1(1) = 53
158	ncsi2(1) = 4 ; ncsj2(1) = 56
159	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
160	! ! Great North American Lakes
161	ncsnr(2) = 1 ; ncstt(2) = 2
162	ncsi1(2) = 49 ; ncsj1(2) = 55
163	ncsi2(2) = 51 ; ncsj2(2) = 56
164	ncsir(2,1) = 57 ; ncsjr(2,1) = 55
165	! ! Black Sea
166	ncsnr(3) = 4 ; ncstt(3) = 2
167	ncsi1(3) = 88 ; ncsj1(3) = 55
168	ncsi2(3) = 91 ; ncsj2(3) = 56
169	ncsir(3,1) = 86 ; ncsjr(3,1) = 53
170	ncsir(3,2) = 87 ; ncsjr(3,2) = 53
171	ncsir(3,3) = 86 ; ncsjr(3,3) = 52
172	ncsir(3,4) = 87 ; ncsjr(3,4) = 52
173	! ! Baltic Sea
174	ncsnr(4) = 1 ; ncstt(4) = 2
175	ncsi1(4) = 75 ; ncsj1(4) = 59
176	ncsi2(4) = 76 ; ncsj2(4) = 61
177	ncsir(4,1) = 84 ; ncsjr(4,1) = 59
178	! ! =======================
179	CASE ( 025 ) ! ORCA_R025 configuration
180	! ! =======================
181	ncsnr(1) = 1 ; ncstt(1) = 0 ! Caspian + Aral sea
182	ncsi1(1) = 1330 ; ncsj1(1) = 645
183	ncsi2(1) = 1400 ; ncsj2(1) = 795
184	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
185	!
186	ncsnr(2) = 1 ; ncstt(2) = 0 ! Azov Sea
187	ncsi1(2) = 1284 ; ncsj1(2) = 722
188	ncsi2(2) = 1304 ; ncsj2(2) = 747
189	ncsir(2,1) = 1 ; ncsjr(2,1) = 1
190	!
191	END SELECT
192	!
193	ENDIF
194
195	! convert the position in local domain indices
196	! --------------------------------------------
197	DO jc = 1, jpncs
198	ncsi1(jc) = mi0( ncsi1(jc) )
199	ncsj1(jc) = mj0( ncsj1(jc) )
200
201	ncsi2(jc) = mi1( ncsi2(jc) )
202	ncsj2(jc) = mj1( ncsj2(jc) )
203	END DO
204
205	!
206	END SUBROUTINE dom_clo
207
208
209	SUBROUTINE sbc_clo( kt )
210	!!---------------------------------------------------------------------
211	!! * ROUTINE sbc_clo *
212	!!
213	!! ** Purpose : Special handling of closed seas
214	!!
215	!! ** Method : Water flux is forced to zero over closed sea
216	!! Excess is shared between remaining ocean, or
217	!! put as run-off in open ocean.
218	!!
219	!! ** Action : emp updated surface freshwater fluxes and associated heat content at kt
220	!!----------------------------------------------------------------------
221	INTEGER, INTENT(in) :: kt ! ocean model time step
222	!
223	INTEGER :: ji, jj, jc, jn ! dummy loop indices
224	REAL(wp), PARAMETER :: rsmall = 1.e-20_wp ! Closed sea correction epsilon
225	REAL(wp) :: zze2, ztmp, zcorr !
226	REAL(wp) :: zcoef, zcoef1 !
227	COMPLEX(wp) :: ctmp
228	REAL(wp), DIMENSION(jpncs) :: zfwf ! 1D workspace
229	!!----------------------------------------------------------------------
230	!
231	IF( nn_timing == 1 ) CALL timing_start('sbc_clo')
232	! !------------------!
233	IF( kt == nit000 ) THEN ! Initialisation !
234	! !------------------!
235	IF(lwp) WRITE(numout,*)
236	IF(lwp) WRITE(numout,*)'sbc_clo : closed seas '
237	IF(lwp) WRITE(numout,*)'~~~~~~~'
238	!
239	! Mask
240	! --------------------------------------------
241	ALLOCATE ( clo_mask (jpi, jpj), STAT=dia_closea_alloc)
242	IF(dia_closea_alloc /= 0) CALL ctl_warn('dia_closea_alloc: failed to allocate arrays.')
243
244	clo_mask (:,:) = tmask (:,:,1)
245
246	! Latitude limits
247	WHERE ( gphit (:,:) .GT. 30.0_wp ) clo_mask (:,:) = 0.0_wp
248	WHERE ( gphit (:,:) .LT. -30.0_wp ) clo_mask (:,:) = 0.0_wp
249	!
250	! Remove closed seas from mask
251	DO jc = 1, jpncs
252	DO jj = ncsj1(jc), ncsj2(jc)
253	DO ji = ncsi1(jc), ncsi2(jc)
254	clo_mask (ji, jj) = 0.0_wp
255	END DO
256	END DO
257	END DO
258
259	IF( lk_mpp ) CALL lbc_lnk ( clo_mask, 'T', 1._wp)
260
261	!
262	surf(:) = 0.e0_wp
263	!
264	surf(jpncs+1) = glob_sum( e1e2t(:,:) * clo_mask (:,:) ) ! surface of the ocean where excess run-off goes
265	!
266	! ! surface of closed seas
267	IF( lk_mpp_rep ) THEN ! MPP reproductible calculation
268	DO jc = 1, jpncs
269	ctmp = CMPLX( 0.e0, 0.e0, wp )
270	DO jj = ncsj1(jc), ncsj2(jc)
271	DO ji = ncsi1(jc), ncsi2(jc)
272	ztmp = e1e2t(ji,jj) * tmask_i(ji,jj)
273	CALL DDPDD( CMPLX( ztmp, 0.e0, wp ), ctmp )
274	END DO
275	END DO
276	IF( lk_mpp ) CALL mpp_sum( ctmp )
277	surf(jc) = REAL(ctmp,wp)
278	END DO
279	ELSE ! Standard calculation
280	DO jc = 1, jpncs
281	DO jj = ncsj1(jc), ncsj2(jc)
282	DO ji = ncsi1(jc), ncsi2(jc)
283	surf(jc) = surf(jc) + e1e2t(ji,jj) * tmask_i(ji,jj) ! surface of closed seas
284	END DO
285	END DO
286	END DO
287	IF( lk_mpp ) CALL mpp_sum ( surf, jpncs ) ! mpp: sum over all the global domain
288	ENDIF
289
290	IF(lwp) WRITE(numout,*)' Closed sea surfaces'
291	DO jc = 1, jpncs
292	IF(lwp)WRITE(numout,FMT='(1I3,4I4,5X,F16.2)') jc, ncsi1(jc), ncsi2(jc), ncsj1(jc), ncsj2(jc), surf(jc)
293	END DO
294
295	IF(lwp) WRITE(numout,*)' Surface for redistribution in closea ', surf(jpncs+1)
296
297	!
298	ENDIF
299	!
300	! !--------------------!
301	! ! update emp !
302	zfwf = 0.e0_wp !--------------------!
303	IF( lk_mpp_rep ) THEN ! MPP reproductible calculation
304	DO jc = 1, jpncs
305	ctmp = CMPLX( 0.e0, 0.e0, wp )
306	DO jj = ncsj1(jc), ncsj2(jc)
307	DO ji = ncsi1(jc), ncsi2(jc)
308	ztmp = e1e2t(ji,jj) * ( emp(ji,jj)-rnf(ji,jj) ) * tmask_i(ji,jj)
309	CALL DDPDD( CMPLX( ztmp, 0.e0, wp ), ctmp )
310	END DO
311	END DO
312	IF( lk_mpp ) CALL mpp_sum( ctmp )
313	zfwf(jc) = REAL(ctmp,wp)
314	END DO
315	ELSE ! Standard calculation
316	DO jc = 1, jpncs
317	DO jj = ncsj1(jc), ncsj2(jc)
318	DO ji = ncsi1(jc), ncsi2(jc)
319	zfwf(jc) = zfwf(jc) + e1e2t(ji,jj) * ( emp(ji,jj)-rnf(ji,jj) ) * tmask_i(ji,jj)
320	END DO
321	END DO
322	END DO
323	IF( lk_mpp ) CALL mpp_sum ( zfwf(:) , jpncs ) ! mpp: sum over all the global domain
324	ENDIF
325
326	IF( cp_cfg == "orca" .AND. jp_cfg == 2 ) THEN ! Black Sea case for ORCA_R2 configuration
327	zze2 = ( zfwf(3) + zfwf(4) ) * 0.5_wp
328	zfwf(3) = zze2
329	zfwf(4) = zze2
330	ENDIF
331
332	zcorr = 0._wp
333
334	DO jc = 1, jpncs
335	!
336	! The following if avoids the redistribution of the round off
337	IF ( ABS(zfwf(jc) / surf(jpncs+1) ) > rsmall) THEN
338	!
339	IF( ncstt(jc) == 0 ) THEN ! water/evap excess is shared by all open ocean
340	zcoef = zfwf(jc) / surf(jpncs+1)
341	zcoef1 = rcp * zcoef
342	emp(:,:) = emp(:,:) + zcoef * clo_mask (:,:)
343	qns(:,:) = qns(:,:) - zcoef1 * sst_m(:,:) * clo_mask (:,:)
344	!
345	ELSEIF( ncstt(jc) == 1 ) THEN ! Excess water in open sea, at outflow location, excess evap shared
346	IF ( zfwf(jc) <= 0.e0_wp ) THEN
347	DO jn = 1, ncsnr(jc)
348	ji = mi0(ncsir(jc,jn))
349	jj = mj0(ncsjr(jc,jn)) ! Location of outflow in open ocean
350	IF ( ji > 1 .AND. ji < jpi &
351	.AND. jj > 1 .AND. jj < jpj ) THEN
352	zcoef = zfwf(jc) / ( REAL(ncsnr(jc)) * e1e2t(ji,jj) )
353	zcoef1 = rcp * zcoef
354	emp(ji,jj) = emp(ji,jj) + zcoef
355	qns(ji,jj) = qns(ji,jj) - zcoef1 * sst_m(ji,jj)
356	ENDIF
357	END DO
358	ELSE
359	zcoef = zfwf(jc) / surf(jpncs+1)
360	zcoef1 = rcp * zcoef
361	emp(:,:) = emp(:,:) + zcoef * clo_mask (:,:)
362	qns(:,:) = qns(:,:) - zcoef1 * sst_m(:,:) * clo_mask (:,:)
363	ENDIF
364	ELSEIF( ncstt(jc) == 2 ) THEN ! Excess e-p-r (either sign) goes to open ocean, at outflow location
365	DO jn = 1, ncsnr(jc)
366	ji = mi0(ncsir(jc,jn))
367	jj = mj0(ncsjr(jc,jn)) ! Location of outflow in open ocean
368	IF( ji > 1 .AND. ji < jpi &
369	.AND. jj > 1 .AND. jj < jpj ) THEN
370	zcoef = zfwf(jc) / ( REAL(ncsnr(jc)) * e1e2t(ji,jj) )
371	zcoef1 = rcp * zcoef
372	emp(ji,jj) = emp(ji,jj) + zcoef
373	qns(ji,jj) = qns(ji,jj) - zcoef1 * sst_m(ji,jj)
374	ENDIF
375	END DO
376	ENDIF
377	!
378	DO jj = ncsj1(jc), ncsj2(jc)
379	DO ji = ncsi1(jc), ncsi2(jc)
380	zcoef = zfwf(jc) / surf(jc)
381	zcoef1 = rcp * zcoef
382	emp(ji,jj) = emp(ji,jj) - zcoef
383	qns(ji,jj) = qns(ji,jj) + zcoef1 * sst_m(ji,jj)
384	END DO
385	END DO
386	!
387	END IF
388	END DO
389
390	emp (:,:) = emp (:,:) * tmask(:,:,1)
391	qns (:,:) = qns (:,:) * tmask(:,:,1)
392	!
393	CALL lbc_lnk( emp , 'T', 1._wp )
394	CALL lbc_lnk( qns , 'T', 1._wp )
395	!
396	IF( nn_timing == 1 ) CALL timing_stop('sbc_clo')
397	!
398	END SUBROUTINE sbc_clo
399
400
401	SUBROUTINE clo_rnf( p_rnfmsk )
402	!!---------------------------------------------------------------------
403	!! * ROUTINE sbc_rnf *
404	!!
405	!! ** Purpose : allow the treatment of closed sea outflow grid-points
406	!! to be the same as river mouth grid-points
407	!!
408	!! ** Method : set to 1 the runoff mask (mskrnf, see sbcrnf module)
409	!! at the closed sea outflow grid-point.
410	!!
411	!! ** Action : update (p_)mskrnf (set 1 at closed sea outflow)
412	!!----------------------------------------------------------------------
413	REAL(wp), DIMENSION(jpi,jpj), INTENT(inout) :: p_rnfmsk ! river runoff mask (rnfmsk array)
414	!
415	INTEGER :: jc, jn, ji, jj ! dummy loop indices
416	!!----------------------------------------------------------------------
417	!
418	DO jc = 1, jpncs
419	IF( ncstt(jc) >= 1 ) THEN ! runoff mask set to 1 at closed sea outflows
420	DO jn = 1, 4
421	DO jj = mj0( ncsjr(jc,jn) ), mj1( ncsjr(jc,jn) )
422	DO ji = mi0( ncsir(jc,jn) ), mi1( ncsir(jc,jn) )
423	p_rnfmsk(ji,jj) = MAX( p_rnfmsk(ji,jj), 1.0_wp )
424	END DO
425	END DO
426	END DO
427	ENDIF
428	END DO
429	!
430	END SUBROUTINE clo_rnf
431
432
433	SUBROUTINE clo_ups( p_upsmsk )
434	!!---------------------------------------------------------------------
435	!! * ROUTINE sbc_rnf *
436	!!
437	!! ** Purpose : allow the treatment of closed sea outflow grid-points
438	!! to be the same as river mouth grid-points
439	!!
440	!! ** Method : set to 0.5 the upstream mask (upsmsk, see traadv_cen2
441	!! module) over the closed seas.
442	!!
443	!! ** Action : update (p_)upsmsk (set 0.5 over closed seas)
444	!!----------------------------------------------------------------------
445	REAL(wp), DIMENSION(jpi,jpj), INTENT(inout) :: p_upsmsk ! upstream mask (upsmsk array)
446	!
447	INTEGER :: jc, ji, jj ! dummy loop indices
448	!!----------------------------------------------------------------------
449	!
450	DO jc = 1, jpncs
451	DO jj = ncsj1(jc), ncsj2(jc)
452	DO ji = ncsi1(jc), ncsi2(jc)
453	p_upsmsk(ji,jj) = 0.5_wp ! mixed upstream/centered scheme over closed seas
454	END DO
455	END DO
456	END DO
457	!
458	END SUBROUTINE clo_ups
459
460
461	SUBROUTINE clo_bat( pbat, kbat )
462	!!---------------------------------------------------------------------
463	!! * ROUTINE clo_bat *
464	!!
465	!! ** Purpose : suppress closed sea from the domain
466	!!
467	!! ** Method : set to 0 the meter and level bathymetry (given in
468	!! arguments) over the closed seas.
469	!!
470	!! ** Action : set pbat=0 and kbat=0 over closed seas
471	!!----------------------------------------------------------------------
472	REAL(wp), DIMENSION(jpi,jpj), INTENT(inout) :: pbat ! bathymetry in meters (bathy array)
473	INTEGER , DIMENSION(jpi,jpj), INTENT(inout) :: kbat ! bathymetry in levels (mbathy array)
474	!
475	INTEGER :: jc, ji, jj ! dummy loop indices
476	!!----------------------------------------------------------------------
477	!
478	DO jc = 1, jpncs
479	DO jj = ncsj1(jc), ncsj2(jc)
480	DO ji = ncsi1(jc), ncsi2(jc)
481	pbat(ji,jj) = 0._wp
482	kbat(ji,jj) = 0
483	END DO
484	END DO
485	END DO
486	!
487	END SUBROUTINE clo_bat
488
489	!!======================================================================
490	END MODULE closea
491

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