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bdyice.F90 in NEMO/branches/2020/temporary_r4_trunk/src/OCE/BDY – NEMO

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source: NEMO/branches/2020/temporary_r4_trunk/src/OCE/BDY/bdyice.F90 @ 13466

Last change on this file since 13466 was 13466, checked in by smasson, 4 years ago
r4_trunk: merge r4 13280:13310, see #2523
Property svn:keywords set to `Id`
File size: 26.0 KB

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1	MODULE bdyice
2	!!======================================================================
3	!! * MODULE bdyice *
4	!! Unstructured Open Boundary Cond. : Open boundary conditions for sea-ice (SI3)
5	!!======================================================================
6	!! History : 3.3 ! 2010-09 (D. Storkey) Original code
7	!! 3.4 ! 2012-01 (C. Rousset) add new sea ice model
8	!! 4.0 ! 2018 (C. Rousset) SI3 compatibility
9	!!----------------------------------------------------------------------
10	#if defined key_si3
11	!!----------------------------------------------------------------------
12	!! 'key_si3' SI3 sea ice model
13	!!----------------------------------------------------------------------
14	!! bdy_ice : Application of open boundaries to ice
15	!! bdy_ice_frs : Application of Flow Relaxation Scheme
16	!!----------------------------------------------------------------------
17	USE oce ! ocean dynamics and tracers variables
18	USE ice ! sea-ice: variables
19	USE icevar ! sea-ice: operations
20	USE icecor ! sea-ice: corrections
21	USE icectl ! sea-ice: control prints
22	USE phycst ! physical constant
23	USE eosbn2 ! equation of state
24	USE par_oce ! ocean parameters
25	USE dom_oce ! ocean space and time domain variables
26	USE sbc_oce ! Surface boundary condition: ocean fields
27	USE bdy_oce ! ocean open boundary conditions
28	!
29	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
30	USE in_out_manager ! write to numout file
31	USE lib_mpp ! distributed memory computing
32	USE lib_fortran ! to use key_nosignedzero
33	USE timing ! Timing
34
35	IMPLICIT NONE
36	PRIVATE
37
38	PUBLIC bdy_ice ! routine called in sbcmod
39	PUBLIC bdy_ice_dyn ! routine called in icedyn_rhg_evp
40
41	!!----------------------------------------------------------------------
42	!! NEMO/OCE 4.0 , NEMO Consortium (2018)
43	!! $Id$
44	!! Software governed by the CeCILL license (see ./LICENSE)
45	!!----------------------------------------------------------------------
46	CONTAINS
47
48	SUBROUTINE bdy_ice( kt )
49	!!----------------------------------------------------------------------
50	!! * SUBROUTINE bdy_ice *
51	!!
52	!! ** Purpose : Apply open boundary conditions for sea ice
53	!!
54	!!----------------------------------------------------------------------
55	INTEGER, INTENT(in) :: kt ! Main time step counter
56	!
57	INTEGER :: jbdy, ir ! BDY set index, rim index
58	INTEGER :: ibeg, iend ! length of rim to be treated (rim 0 or rim 1)
59	LOGICAL :: llrim0 ! indicate if rim 0 is treated
60	LOGICAL, DIMENSION(4) :: llsend1, llrecv1 ! indicate how communications are to be carried out
61	!!----------------------------------------------------------------------
62	! controls
63	IF( ln_timing ) CALL timing_start('bdy_ice_thd') ! timing
64	IF( ln_icediachk ) CALL ice_cons_hsm(0,'bdy_ice_thd', rdiag_v, rdiag_s, rdiag_t, rdiag_fv, rdiag_fs, rdiag_ft) ! conservation
65	IF( ln_icediachk ) CALL ice_cons2D (0,'bdy_ice_thd', diag_v, diag_s, diag_t, diag_fv, diag_fs, diag_ft) ! conservation
66	!
67	CALL ice_var_glo2eqv
68	!
69	llsend1(:) = .false. ; llrecv1(:) = .false.
70	DO ir = 1, 0, -1 ! treat rim 1 before rim 0
71	IF( ir == 0 ) THEN ; llrim0 = .TRUE.
72	ELSE ; llrim0 = .FALSE.
73	END IF
74	DO jbdy = 1, nb_bdy
75	!
76	SELECT CASE( cn_ice(jbdy) )
77	CASE('none') ; CYCLE
78	CASE('frs' ) ; CALL bdy_ice_frs( idx_bdy(jbdy), dta_bdy(jbdy), kt, jbdy, llrim0 )
79	CASE DEFAULT
80	CALL ctl_stop( 'bdy_ice : unrecognised option for open boundaries for ice fields' )
81	END SELECT
82	!
83	END DO
84	!
85	! Update bdy points
86	IF( nn_hls > 1 .AND. ir == 1 ) CYCLE ! at least 2 halos will be corrected -> no need to correct rim 1 before rim 0
87	IF( nn_hls == 1 ) THEN ; llsend1(:) = .false. ; llrecv1(:) = .false. ; END IF
88	DO jbdy = 1, nb_bdy
89	IF( cn_ice(jbdy) == 'frs' ) THEN
90	llsend1(:) = llsend1(:) .OR. lsend_bdyint(jbdy,1,:,ir) ! possibly every direction, T points
91	llrecv1(:) = llrecv1(:) .OR. lrecv_bdyint(jbdy,1,:,ir) ! possibly every direction, T points
92	END IF
93	END DO ! jbdy
94	IF( ANY(llsend1) .OR. ANY(llrecv1) ) THEN ! if need to send/recv in at least one direction
95	! exchange 3d arrays
96	CALL lbc_lnk_multi( 'bdyice', a_i , 'T', 1., h_i , 'T', 1., h_s , 'T', 1., oa_i, 'T', 1. &
97	& , s_i , 'T', 1., t_su, 'T', 1., v_i , 'T', 1., v_s , 'T', 1., sv_i, 'T', 1. &
98	& , a_ip, 'T', 1., v_ip, 'T', 1., v_il, 'T', 1. &
99	& , kfillmode=jpfillnothing ,lsend=llsend1, lrecv=llrecv1 )
100	! exchange 4d arrays : third dimension = 1 and then third dimension = jpk
101	CALL lbc_lnk_multi( 'bdyice', t_s , 'T', 1., e_s , 'T', 1., kfillmode=jpfillnothing ,lsend=llsend1, lrecv=llrecv1 )
102	CALL lbc_lnk_multi( 'bdyice', t_i , 'T', 1., e_i , 'T', 1., kfillmode=jpfillnothing ,lsend=llsend1, lrecv=llrecv1 )
103	END IF
104	END DO ! ir
105	!
106	CALL ice_cor( kt , 0 ) ! -- In case categories are out of bounds, do a remapping
107	! ! i.e. inputs have not the same ice thickness distribution (set by rn_himean)
108	! ! than the regional simulation
109	CALL ice_var_agg(1)
110	!
111	! controls
112	IF( ln_icectl ) CALL ice_prt ( kt, iiceprt, jiceprt, 1, ' - ice thermo bdy - ' ) ! prints
113	IF( ln_icediachk ) CALL ice_cons_hsm(1,'bdy_ice_thd', rdiag_v, rdiag_s, rdiag_t, rdiag_fv, rdiag_fs, rdiag_ft) ! conservation
114	IF( ln_icediachk ) CALL ice_cons2D (1,'bdy_ice_thd', diag_v, diag_s, diag_t, diag_fv, diag_fs, diag_ft) ! conservation
115	IF( ln_timing ) CALL timing_stop ('bdy_ice_thd') ! timing
116	!
117	END SUBROUTINE bdy_ice
118
119
120	SUBROUTINE bdy_ice_frs( idx, dta, kt, jbdy, llrim0 )
121	!!------------------------------------------------------------------------------
122	!! * SUBROUTINE bdy_ice_frs *
123	!!
124	!! ** Purpose : Apply the Flow Relaxation Scheme for sea-ice fields
125	!!
126	!! Reference : Engedahl H., 1995: Use of the flow relaxation scheme in a three-
127	!! dimensional baroclinic ocean model with realistic topography. Tellus, 365-382.
128	!!------------------------------------------------------------------------------
129	TYPE(OBC_INDEX), INTENT(in) :: idx ! OBC indices
130	TYPE(OBC_DATA), INTENT(in) :: dta ! OBC external data
131	INTEGER, INTENT(in) :: kt ! main time-step counter
132	INTEGER, INTENT(in) :: jbdy ! BDY set index
133	LOGICAL, INTENT(in) :: llrim0 ! indicate if rim 0 is treated
134	!
135	INTEGER :: jpbound ! 0 = incoming ice
136	! ! 1 = outgoing ice
137	INTEGER :: ibeg, iend ! length of rim to be treated (rim 0 or rim 1)
138	INTEGER :: i_bdy, jgrd ! dummy loop indices
139	INTEGER :: ji, jj, jk, jl, ib, jb
140	REAL(wp) :: zwgt, zwgt1 ! local scalar
141	REAL(wp) :: ztmelts, zdh
142	REAL(wp), POINTER :: flagu, flagv ! short cuts
143	!!------------------------------------------------------------------------------
144	!
145	jgrd = 1 ! Everything is at T-points here
146	IF( llrim0 ) THEN ; ibeg = 1 ; iend = idx%nblenrim0(jgrd)
147	ELSE ; ibeg = idx%nblenrim0(jgrd)+1 ; iend = idx%nblenrim(jgrd)
148	END IF
149	!
150	DO jl = 1, jpl
151	DO i_bdy = ibeg, iend
152	ji = idx%nbi(i_bdy,jgrd)
153	jj = idx%nbj(i_bdy,jgrd)
154	zwgt = idx%nbw(i_bdy,jgrd)
155	zwgt1 = 1.e0 - idx%nbw(i_bdy,jgrd)
156	a_i (ji,jj, jl) = ( a_i (ji,jj, jl) * zwgt1 + dta%a_i(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Ice concentration
157	h_i (ji,jj, jl) = ( h_i (ji,jj, jl) * zwgt1 + dta%h_i(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Ice depth
158	h_s (ji,jj, jl) = ( h_s (ji,jj, jl) * zwgt1 + dta%h_s(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Snow depth
159	t_i (ji,jj,:,jl) = ( t_i (ji,jj,:,jl) * zwgt1 + dta%t_i(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Ice temperature
160	t_s (ji,jj,:,jl) = ( t_s (ji,jj,:,jl) * zwgt1 + dta%t_s(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Snow temperature
161	t_su(ji,jj, jl) = ( t_su(ji,jj, jl) * zwgt1 + dta%tsu(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Surf temperature
162	s_i (ji,jj, jl) = ( s_i (ji,jj, jl) * zwgt1 + dta%s_i(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Ice salinity
163	a_ip(ji,jj, jl) = ( a_ip(ji,jj, jl) * zwgt1 + dta%aip(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Ice pond concentration
164	h_ip(ji,jj, jl) = ( h_ip(ji,jj, jl) * zwgt1 + dta%hip(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Ice pond depth
165	h_il(ji,jj, jl) = ( h_il(ji,jj, jl) * zwgt1 + dta%hil(i_bdy,jl) * zwgt ) * tmask(ji,jj,1) ! Ice pond lid depth
166	!
167	sz_i(ji,jj,:,jl) = s_i(ji,jj,jl)
168	!
169	! make sure ponds = 0 if no ponds scheme
170	IF( .NOT.ln_pnd ) THEN
171	a_ip(ji,jj,jl) = 0._wp
172	h_ip(ji,jj,jl) = 0._wp
173	h_il(ji,jj,jl) = 0._wp
174	ENDIF
175
176	IF( .NOT.ln_pnd_lids ) THEN
177	h_il(ji,jj,jl) = 0._wp
178	ENDIF
179	!
180	! -----------------
181	! Pathological case
182	! -----------------
183	! In case a) snow load would be in excess or b) ice is coming into a warmer environment that would lead to
184	! very large transformation from snow to ice (see icethd_dh.F90)
185
186	! Then, a) transfer the snow excess into the ice (different from icethd_dh)
187	zdh = MAX( 0._wp, ( rhos * h_s(ji,jj,jl) + ( rhoi - rau0 ) * h_i(ji,jj,jl) ) * r1_rau0 )
188	! Or, b) transfer all the snow into ice (if incoming ice is likely to melt as it comes into a warmer environment)
189	!zdh = MAX( 0._wp, h_s(ji,jj,jl) * rhos / rhoi )
190
191	! recompute h_i, h_s
192	h_i(ji,jj,jl) = MIN( hi_max(jl), h_i(ji,jj,jl) + zdh )
193	h_s(ji,jj,jl) = MAX( 0._wp, h_s(ji,jj,jl) - zdh * rhoi / rhos )
194	!
195	ENDDO
196	ENDDO
197
198	DO jl = 1, jpl
199	DO i_bdy = ibeg, iend
200	ji = idx%nbi(i_bdy,jgrd)
201	jj = idx%nbj(i_bdy,jgrd)
202	flagu => idx%flagu(i_bdy,jgrd)
203	flagv => idx%flagv(i_bdy,jgrd)
204	! condition on ice thickness depends on the ice velocity
205	! if velocity is outward (strictly), then ice thickness, volume... must be equal to adjacent values
206	jpbound = 0 ; ib = ji ; jb = jj
207	!
208	IF( flagu == 1. ) THEN
209	IF( ji+1 > jpi ) CYCLE
210	IF( u_ice(ji ,jj ) < 0. ) jpbound = 1 ; ib = ji+1
211	END IF
212	IF( flagu == -1. ) THEN
213	IF( ji-1 < 1 ) CYCLE
214	IF( u_ice(ji-1,jj ) < 0. ) jpbound = 1 ; ib = ji-1
215	END IF
216	IF( flagv == 1. ) THEN
217	IF( jj+1 > jpj ) CYCLE
218	IF( v_ice(ji ,jj ) < 0. ) jpbound = 1 ; jb = jj+1
219	END IF
220	IF( flagv == -1. ) THEN
221	IF( jj-1 < 1 ) CYCLE
222	IF( v_ice(ji ,jj-1) < 0. ) jpbound = 1 ; jb = jj-1
223	END IF
224	!
225	IF( nn_ice_dta(jbdy) == 0 ) jpbound = 0 ; ib = ji ; jb = jj ! case ice boundaries = initial conditions
226	! ! do not make state variables dependent on velocity
227	!
228	IF( a_i(ib,jb,jl) > 0._wp ) THEN ! there is ice at the boundary
229	!
230	a_i (ji,jj, jl) = a_i (ib,jb, jl)
231	h_i (ji,jj, jl) = h_i (ib,jb, jl)
232	h_s (ji,jj, jl) = h_s (ib,jb, jl)
233	t_i (ji,jj,:,jl) = t_i (ib,jb,:,jl)
234	t_s (ji,jj,:,jl) = t_s (ib,jb,:,jl)
235	t_su(ji,jj, jl) = t_su(ib,jb, jl)
236	s_i (ji,jj, jl) = s_i (ib,jb, jl)
237	a_ip(ji,jj, jl) = a_ip(ib,jb, jl)
238	h_ip(ji,jj, jl) = h_ip(ib,jb, jl)
239	h_il(ji,jj, jl) = h_il(ib,jb, jl)
240	!
241	sz_i(ji,jj,:,jl) = sz_i(ib,jb,:,jl)
242	!
243	! ice age
244	IF ( jpbound == 0 ) THEN ! velocity is inward
245	oa_i(ji,jj,jl) = rice_age(jbdy) * a_i(ji,jj,jl)
246	ELSEIF( jpbound == 1 ) THEN ! velocity is outward
247	oa_i(ji,jj,jl) = oa_i(ib,jb,jl)
248	ENDIF
249	!
250	IF( nn_icesal == 1 ) THEN ! if constant salinity
251	s_i (ji,jj ,jl) = rn_icesal
252	sz_i(ji,jj,:,jl) = rn_icesal
253	ENDIF
254	!
255	! global fields
256	v_i (ji,jj,jl) = h_i(ji,jj,jl) * a_i(ji,jj,jl) ! volume ice
257	v_s (ji,jj,jl) = h_s(ji,jj,jl) * a_i(ji,jj,jl) ! volume snw
258	sv_i(ji,jj,jl) = MIN( s_i(ji,jj,jl) , sss_m(ji,jj) ) * v_i(ji,jj,jl) ! salt content
259	DO jk = 1, nlay_s
260	t_s(ji,jj,jk,jl) = MIN( t_s(ji,jj,jk,jl), -0.15_wp + rt0 ) ! Force t_s to be lower than -0.15deg (arbitrary) => likely conservation issue
261	! ! otherwise instant melting can occur
262	e_s(ji,jj,jk,jl) = rhos * ( rcpi * ( rt0 - t_s(ji,jj,jk,jl) ) + rLfus ) ! enthalpy in J/m3
263	e_s(ji,jj,jk,jl) = e_s(ji,jj,jk,jl) * v_s(ji,jj,jl) * r1_nlay_s ! enthalpy in J/m2
264	END DO
265	t_su(ji,jj,jl) = MIN( t_su(ji,jj,jl), -0.15_wp + rt0 ) ! Force t_su to be lower than -0.15deg (arbitrary)
266	DO jk = 1, nlay_i
267	ztmelts = - rTmlt * sz_i(ji,jj,jk,jl) ! Melting temperature in C
268	t_i(ji,jj,jk,jl) = MIN( t_i(ji,jj,jk,jl), (ztmelts-0.15_wp) + rt0 ) ! Force t_i to be lower than melting point (-0.15) => likely conservation issue
269	! ! otherwise instant melting can occur
270	e_i(ji,jj,jk,jl) = rhoi * ( rcpi * ( ztmelts - ( t_i(ji,jj,jk,jl) - rt0 ) ) & ! enthalpy in J/m3
271	& + rLfus * ( 1._wp - ztmelts / ( t_i(ji,jj,jk,jl) - rt0 ) ) &
272	& - rcp * ztmelts )
273	e_i(ji,jj,jk,jl) = e_i(ji,jj,jk,jl) * v_i(ji,jj,jl) * r1_nlay_i ! enthalpy in J/m2
274	END DO
275	!
276	! melt ponds
277	v_ip(ji,jj,jl) = h_ip(ji,jj,jl) * a_ip(ji,jj,jl)
278	v_il(ji,jj,jl) = h_il(ji,jj,jl) * a_ip(ji,jj,jl)
279	!
280	ELSE ! no ice at the boundary
281	!
282	a_i (ji,jj, jl) = 0._wp
283	h_i (ji,jj, jl) = 0._wp
284	h_s (ji,jj, jl) = 0._wp
285	oa_i(ji,jj, jl) = 0._wp
286	t_su(ji,jj, jl) = rt0
287	t_s (ji,jj,:,jl) = rt0
288	t_i (ji,jj,:,jl) = rt0
289
290	a_ip(ji,jj,jl) = 0._wp
291	h_ip(ji,jj,jl) = 0._wp
292	h_il(ji,jj,jl) = 0._wp
293
294	IF( nn_icesal == 1 ) THEN ! if constant salinity
295	s_i (ji,jj ,jl) = rn_icesal
296	sz_i(ji,jj,:,jl) = rn_icesal
297	ELSE ! if variable salinity
298	s_i (ji,jj,jl) = rn_simin
299	sz_i(ji,jj,:,jl) = rn_simin
300	ENDIF
301	!
302	! global fields
303	v_i (ji,jj, jl) = 0._wp
304	v_s (ji,jj, jl) = 0._wp
305	sv_i(ji,jj, jl) = 0._wp
306	e_s (ji,jj,:,jl) = 0._wp
307	e_i (ji,jj,:,jl) = 0._wp
308	v_ip(ji,jj, jl) = 0._wp
309	v_il(ji,jj, jl) = 0._wp
310
311	ENDIF
312
313	END DO
314	!
315	END DO ! jl
316	!
317	END SUBROUTINE bdy_ice_frs
318
319
320	SUBROUTINE bdy_ice_dyn( cd_type )
321	!!------------------------------------------------------------------------------
322	!! * SUBROUTINE bdy_ice_dyn *
323	!!
324	!! ** Purpose : Apply dynamics boundary conditions for sea-ice.
325	!!
326	!! ** Method : if this adjacent grid point is not ice free, then u_ice and v_ice take its value
327	!! if is ice free, then u_ice and v_ice are unchanged by BDY
328	!! they keep values calculated in rheology
329	!!
330	!!------------------------------------------------------------------------------
331	CHARACTER(len=1), INTENT(in) :: cd_type ! nature of velocity grid-points
332	!
333	INTEGER :: i_bdy, jgrd ! dummy loop indices
334	INTEGER :: ji, jj ! local scalar
335	INTEGER :: jbdy, ir ! BDY set index, rim index
336	INTEGER :: ibeg, iend ! length of rim to be treated (rim 0 or rim 1)
337	REAL(wp) :: zmsk1, zmsk2, zflag
338	LOGICAL, DIMENSION(4) :: llsend2, llrecv2, llsend3, llrecv3 ! indicate how communications are to be carried out
339	!!------------------------------------------------------------------------------
340	IF( ln_timing ) CALL timing_start('bdy_ice_dyn')
341	!
342	llsend2(:) = .false. ; llrecv2(:) = .false.
343	llsend3(:) = .false. ; llrecv3(:) = .false.
344	DO ir = 1, 0, -1
345	DO jbdy = 1, nb_bdy
346	!
347	SELECT CASE( cn_ice(jbdy) )
348	!
349	CASE('none')
350	CYCLE
351	!
352	CASE('frs')
353	!
354	IF( nn_ice_dta(jbdy) == 0 ) CYCLE ! case ice boundaries = initial conditions
355	! ! do not change ice velocity (it is only computed by rheology)
356	SELECT CASE ( cd_type )
357	!
358	CASE ( 'U' )
359	jgrd = 2 ! u velocity
360	IF( ir == 0 ) THEN ; ibeg = 1 ; iend = idx_bdy(jbdy)%nblenrim0(jgrd)
361	ELSE ; ibeg = idx_bdy(jbdy)%nblenrim0(jgrd)+1 ; iend = idx_bdy(jbdy)%nblenrim(jgrd)
362	END IF
363	DO i_bdy = ibeg, iend
364	ji = idx_bdy(jbdy)%nbi(i_bdy,jgrd)
365	jj = idx_bdy(jbdy)%nbj(i_bdy,jgrd)
366	zflag = idx_bdy(jbdy)%flagu(i_bdy,jgrd)
367	! i-1 i i \| ! i i i+1 \| ! i i i+1 \|
368	! > ice > \| ! o > ice \| ! o > o \|
369	! => set at u_ice(i-1) ! => set to O ! => unchanged
370	IF( zflag == -1. .AND. ji > 1 .AND. ji < jpi ) THEN
371	IF ( vt_i(ji ,jj) > 0. ) THEN ; u_ice(ji,jj) = u_ice(ji-1,jj)
372	ELSEIF( vt_i(ji+1,jj) > 0. ) THEN ; u_ice(ji,jj) = 0._wp
373	END IF
374	END IF
375	! \| i i+1 i+1 ! \| i i i+1 ! \| i i i+1
376	! \| > ice > ! \| ice > o ! \| o > o
377	! => set at u_ice(i+1) ! => set to O ! => unchanged
378	IF( zflag == 1. .AND. ji+1 < jpi+1 ) THEN
379	IF ( vt_i(ji+1,jj) > 0. ) THEN ; u_ice(ji,jj) = u_ice(ji+1,jj)
380	ELSEIF( vt_i(ji ,jj) > 0. ) THEN ; u_ice(ji,jj) = 0._wp
381	END IF
382	END IF
383	!
384	IF( zflag == 0. ) u_ice(ji,jj) = 0._wp ! u_ice = 0 if north/south bdy
385	!
386	END DO
387	!
388	CASE ( 'V' )
389	jgrd = 3 ! v velocity
390	IF( ir == 0 ) THEN ; ibeg = 1 ; iend = idx_bdy(jbdy)%nblenrim0(jgrd)
391	ELSE ; ibeg = idx_bdy(jbdy)%nblenrim0(jgrd)+1 ; iend = idx_bdy(jbdy)%nblenrim(jgrd)
392	END IF
393	DO i_bdy = ibeg, iend
394	ji = idx_bdy(jbdy)%nbi(i_bdy,jgrd)
395	jj = idx_bdy(jbdy)%nbj(i_bdy,jgrd)
396	zflag = idx_bdy(jbdy)%flagv(i_bdy,jgrd)
397	! ! ice (jj+1) ! o (jj+1)
398	! ^ (jj ) ! ^ (jj ) ! ^ (jj )
399	! ice (jj ) ! o (jj ) ! o (jj )
400	! ^ (jj-1) ! !
401	! => set to u_ice(jj-1) ! => set to 0 ! => unchanged
402	IF( zflag == -1. .AND. jj > 1 .AND. jj < jpj ) THEN
403	IF ( vt_i(ji,jj ) > 0. ) THEN ; v_ice(ji,jj) = v_ice(ji,jj-1)
404	ELSEIF( vt_i(ji,jj+1) > 0. ) THEN ; v_ice(ji,jj) = 0._wp
405	END IF
406	END IF
407	! ^ (jj+1) ! !
408	! ice (jj+1) ! o (jj+1) ! o (jj+1)
409	! ^ (jj ) ! ^ (jj ) ! ^ (jj )
410	! ________________ ! ____ice___(jj )_ ! _____o____(jj )
411	! => set to u_ice(jj+1) ! => set to 0 ! => unchanged
412	IF( zflag == 1. .AND. jj < jpj ) THEN
413	IF ( vt_i(ji,jj+1) > 0. ) THEN ; v_ice(ji,jj) = v_ice(ji,jj+1)
414	ELSEIF( vt_i(ji,jj ) > 0. ) THEN ; v_ice(ji,jj) = 0._wp
415	END IF
416	END IF
417	!
418	IF( zflag == 0. ) v_ice(ji,jj) = 0._wp ! v_ice = 0 if west/east bdy
419	!
420	END DO
421	!
422	END SELECT
423	!
424	CASE DEFAULT
425	CALL ctl_stop( 'bdy_ice_dyn : unrecognised option for open boundaries for ice fields' )
426	END SELECT
427	!
428	END DO ! jbdy
429	!
430	SELECT CASE ( cd_type )
431	CASE ( 'U' )
432	IF( nn_hls > 1 .AND. ir == 1 ) CYCLE ! at least 2 halos will be corrected -> no need to correct rim 1 before rim 0
433	IF( nn_hls == 1 ) THEN ; llsend2(:) = .false. ; llrecv2(:) = .false. ; END IF
434	DO jbdy = 1, nb_bdy
435	IF( cn_ice(jbdy) == 'frs' .AND. nn_ice_dta(jbdy) /= 0 ) THEN
436	llsend2(:) = llsend2(:) .OR. lsend_bdyint(jbdy,2,:,ir) ! possibly every direction, U points
437	llsend2(1) = llsend2(1) .OR. lsend_bdyext(jbdy,2,1,ir) ! neighbour might search point towards its west bdy
438	llrecv2(:) = llrecv2(:) .OR. lrecv_bdyint(jbdy,2,:,ir) ! possibly every direction, U points
439	llrecv2(2) = llrecv2(2) .OR. lrecv_bdyext(jbdy,2,2,ir) ! might search point towards east bdy
440	END IF
441	END DO
442	IF( ANY(llsend2) .OR. ANY(llrecv2) ) THEN ! if need to send/recv in at least one direction
443	CALL lbc_lnk( 'bdyice', u_ice, 'U', -1., kfillmode=jpfillnothing ,lsend=llsend2, lrecv=llrecv2 )
444	END IF
445	CASE ( 'V' )
446	IF( nn_hls > 1 .AND. ir == 1 ) CYCLE ! at least 2 halos will be corrected -> no need to correct rim 1 before rim 0
447	IF( nn_hls == 1 ) THEN ; llsend3(:) = .false. ; llrecv3(:) = .false. ; END IF
448	DO jbdy = 1, nb_bdy
449	IF( cn_ice(jbdy) == 'frs' .AND. nn_ice_dta(jbdy) /= 0 ) THEN
450	llsend3(:) = llsend3(:) .OR. lsend_bdyint(jbdy,3,:,ir) ! possibly every direction, V points
451	llsend3(3) = llsend3(3) .OR. lsend_bdyext(jbdy,3,3,ir) ! neighbour might search point towards its south bdy
452	llrecv3(:) = llrecv3(:) .OR. lrecv_bdyint(jbdy,3,:,ir) ! possibly every direction, V points
453	llrecv3(4) = llrecv3(4) .OR. lrecv_bdyext(jbdy,3,4,ir) ! might search point towards north bdy
454	END IF
455	END DO
456	IF( ANY(llsend3) .OR. ANY(llrecv3) ) THEN ! if need to send/recv in at least one direction
457	CALL lbc_lnk( 'bdyice', v_ice, 'V', -1., kfillmode=jpfillnothing ,lsend=llsend3, lrecv=llrecv3 )
458	END IF
459	END SELECT
460	END DO ! ir
461	!
462	IF( ln_timing ) CALL timing_stop('bdy_ice_dyn')
463	!
464	END SUBROUTINE bdy_ice_dyn
465
466	#else
467	!!---------------------------------------------------------------------------------
468	!! Default option Empty module
469	!!---------------------------------------------------------------------------------
470	CONTAINS
471	SUBROUTINE bdy_ice( kt ) ! Empty routine
472	IMPLICIT NONE
473	INTEGER, INTENT( in ) :: kt
474	WRITE(,) 'bdy_ice: You should not have seen this print! error?', kt
475	END SUBROUTINE bdy_ice
476	#endif
477
478	!!=================================================================================
479	END MODULE bdyice

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