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traldf_triad.F90 in NEMO/branches/2021/dev_r14273_HPC-02_Daley_Tiling/src/OCE/TRA – NEMO

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source: NEMO/branches/2021/dev_r14273_HPC-02_Daley_Tiling/src/OCE/TRA/traldf_triad.F90 @ 14632

Last change on this file since 14632 was 14632, checked in by hadcv, 3 years ago
#2600: Take out some unnecessary tags
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1	MODULE traldf_triad
2	!!======================================================================
3	!! * MODULE traldf_triad *
4	!! Ocean tracers: horizontal component of the lateral tracer mixing trend
5	!!======================================================================
6	!! History : 3.3 ! 2010-10 (G. Nurser, C. Harris, G. Madec) Griffies operator (original code)
7	!! 3.7 ! 2013-12 (F. Lemarie, G. Madec) triad operator (Griffies) + Method of Stabilizing Correction
8	!!----------------------------------------------------------------------
9
10	!!----------------------------------------------------------------------
11	!! tra_ldf_triad : update the tracer trend with the iso-neutral laplacian triad-operator
12	!!----------------------------------------------------------------------
13	USE oce ! ocean dynamics and active tracers
14	USE dom_oce ! ocean space and time domain
15	USE domutl, ONLY : is_tile
16	USE phycst ! physical constants
17	USE trc_oce ! share passive tracers/Ocean variables
18	USE zdf_oce ! ocean vertical physics
19	USE ldftra ! lateral physics: eddy diffusivity
20	USE ldfslp ! lateral physics: iso-neutral slopes
21	USE traldf_iso ! lateral diffusion (Madec operator) (tra_ldf_iso routine)
22	USE diaptr ! poleward transport diagnostics
23	USE diaar5 ! AR5 diagnostics
24	USE zpshde ! partial step: hor. derivative (zps_hde routine)
25	!
26	USE in_out_manager ! I/O manager
27	USE iom ! I/O library
28	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
29	USE lib_mpp ! MPP library
30
31	IMPLICIT NONE
32	PRIVATE
33
34	PUBLIC tra_ldf_triad ! routine called by traldf.F90
35
36	LOGICAL :: l_ptr ! flag to compute poleward transport
37	LOGICAL :: l_hst ! flag to compute heat transport
38
39
40	!! * Substitutions
41	# include "do_loop_substitute.h90"
42	# include "domzgr_substitute.h90"
43	!!----------------------------------------------------------------------
44	!! NEMO/OCE 4.0 , NEMO Consortium (2018)
45	!! $Id$
46	!! Software governed by the CeCILL license (see ./LICENSE)
47	!!----------------------------------------------------------------------
48	CONTAINS
49
50	SUBROUTINE tra_ldf_triad( kt, Kmm, kit000, cdtype, pahu, pahv, &
51	& pgu , pgv , pgui, pgvi, &
52	& pt, pt2, pt_rhs, kjpt, kpass )
53	!!
54	INTEGER , INTENT(in ) :: kt ! ocean time-step index
55	INTEGER , INTENT(in ) :: kit000 ! first time step index
56	CHARACTER(len=3) , INTENT(in ) :: cdtype ! =TRA or TRC (tracer indicator)
57	INTEGER , INTENT(in ) :: kjpt ! number of tracers
58	INTEGER , INTENT(in ) :: kpass ! =1/2 first or second passage
59	INTEGER , INTENT(in ) :: Kmm ! ocean time level indices
60	REAL(wp), DIMENSION(:,:,:) , INTENT(in ) :: pahu, pahv ! eddy diffusivity at u- and v-points [m2/s]
61	REAL(wp), DIMENSION(:,:,:) , INTENT(in ) :: pgu , pgv ! tracer gradient at pstep levels
62	REAL(wp), DIMENSION(:,:,:) , INTENT(in ) :: pgui, pgvi ! tracer gradient at top levels
63	REAL(wp), DIMENSION(:,:,:,:), INTENT(in ) :: pt ! tracer (kpass=1) or laplacian of tracer (kpass=2)
64	REAL(wp), DIMENSION(:,:,:,:), INTENT(in ) :: pt2 ! tracer (only used in kpass=2)
65	REAL(wp), DIMENSION(:,:,:,:), INTENT(inout) :: pt_rhs ! tracer trend
66	!!
67	CALL tra_ldf_triad_t( kt, Kmm, kit000, cdtype, pahu, pahv, is_tile(pahu), &
68	& pgu , pgv , is_tile(pgu) , pgui, pgvi, is_tile(pgui), &
69	& pt, is_tile(pt), pt2, is_tile(pt2), pt_rhs, is_tile(pt_rhs), kjpt, kpass )
70	END SUBROUTINE tra_ldf_triad
71
72
73	SUBROUTINE tra_ldf_triad_t( kt, Kmm, kit000, cdtype, pahu, pahv, ktah, &
74	& pgu , pgv , ktg , pgui, pgvi, ktgi, &
75	& pt, ktt, pt2, ktt2, pt_rhs, ktt_rhs, kjpt, kpass )
76	!!----------------------------------------------------------------------
77	!! * ROUTINE tra_ldf_triad *
78	!!
79	!! ** Purpose : Compute the before horizontal tracer (t & s) diffusive
80	!! trend for a laplacian tensor (ezxcept the dz[ dz[.] ] term) and
81	!! add it to the general trend of tracer equation.
82	!!
83	!! ** Method : The horizontal component of the lateral diffusive trends
84	!! is provided by a 2nd order operator rotated along neural or geopo-
85	!! tential surfaces to which an eddy induced advection can be added
86	!! It is computed using before fields (forward in time) and isopyc-
87	!! nal or geopotential slopes computed in routine ldfslp.
88	!!
89	!! see documentation for the desciption
90	!!
91	!! ** Action : pt_rhs updated with the before rotated diffusion
92	!! ah_wslp2 ....
93	!! akz stabilizing vertical diffusivity coefficient (used in trazdf_imp)
94	!!----------------------------------------------------------------------
95	INTEGER , INTENT(in ) :: kt ! ocean time-step index
96	INTEGER , INTENT(in ) :: kit000 ! first time step index
97	CHARACTER(len=3) , INTENT(in ) :: cdtype ! =TRA or TRC (tracer indicator)
98	INTEGER , INTENT(in ) :: kjpt ! number of tracers
99	INTEGER , INTENT(in ) :: kpass ! =1/2 first or second passage
100	INTEGER , INTENT(in) :: Kmm ! ocean time level indices
101	INTEGER , INTENT(in ) :: ktah, ktg, ktgi, ktt, ktt2, ktt_rhs
102	REAL(wp), DIMENSION(A2D_T(ktah), JPK) , INTENT(in ) :: pahu, pahv ! eddy diffusivity at u- and v-points [m2/s]
103	REAL(wp), DIMENSION(A2D_T(ktg), KJPT), INTENT(in ) :: pgu , pgv ! tracer gradient at pstep levels
104	REAL(wp), DIMENSION(A2D_T(ktgi), KJPT), INTENT(in ) :: pgui, pgvi ! tracer gradient at top levels
105	REAL(wp), DIMENSION(A2D_T(ktt), JPK,KJPT), INTENT(in ) :: pt ! tracer (kpass=1) or laplacian of tracer (kpass=2)
106	REAL(wp), DIMENSION(A2D_T(ktt2), JPK,KJPT), INTENT(in ) :: pt2 ! tracer (only used in kpass=2)
107	REAL(wp), DIMENSION(A2D_T(ktt_rhs),JPK,KJPT), INTENT(inout) :: pt_rhs ! tracer trend
108	!
109	INTEGER :: ji, jj, jk, jn ! dummy loop indices
110	INTEGER :: ip,jp,kp ! dummy loop indices
111	INTEGER :: ierr, iij ! local integer
112	REAL(wp) :: zmsku, zabe1, zcof1, zcoef3 ! local scalars
113	REAL(wp) :: zmskv, zabe2, zcof2, zcoef4 ! - -
114	REAL(wp) :: zcoef0, ze3w_2, zsign ! - -
115	!
116	REAL(wp) :: zslope_skew, zslope_iso, zslope2, zbu, zbv
117	REAL(wp) :: ze1ur, ze2vr, ze3wr, zdxt, zdyt, zdzt
118	REAL(wp) :: zah, zah_slp, zaei_slp
119	REAL(wp), DIMENSION(A2D(nn_hls),0:1) :: zdkt3d ! vertical tracer gradient at 2 levels
120	REAL(wp), DIMENSION(A2D(nn_hls) ) :: z2d ! 2D workspace
121	REAL(wp), DIMENSION(A2D(nn_hls),jpk) :: zdit, zdjt, zpsi_uw, zpsi_vw ! 3D -
122	! NOTE: [halo1-halo2]
123	REAL(wp), DIMENSION(A2D(nn_hls),jpk,2) :: zftu, zftv
124	REAL(wp), DIMENSION(A2D(nn_hls),jpk,2,2) :: ztfw
125	!!----------------------------------------------------------------------
126	!
127	IF( .NOT. l_istiled .OR. ntile == 1 ) THEN ! Do only on the first tile
128	IF( kpass == 1 .AND. kt == kit000 ) THEN
129	IF(lwp) WRITE(numout,*)
130	IF(lwp) WRITE(numout,*) 'tra_ldf_triad : rotated laplacian diffusion operator on ', cdtype
131	IF(lwp) WRITE(numout,*) '~~~~~~~~~~~~~'
132	ENDIF
133	!
134	l_hst = .FALSE.
135	l_ptr = .FALSE.
136	IF( cdtype == 'TRA' ) THEN
137	IF( iom_use( 'sophtldf' ) .OR. iom_use( 'sopstldf') ) l_ptr = .TRUE.
138	IF( iom_use("uadv_heattr") .OR. iom_use("vadv_heattr") .OR. &
139	& iom_use("uadv_salttr") .OR. iom_use("vadv_salttr") ) l_hst = .TRUE.
140	ENDIF
141	ENDIF
142	!
143	! Define pt_rhs halo points for multi-point haloes in bilaplacian case
144	IF( nldf_tra == np_blp_it .AND. kpass == 1 ) THEN ; iij = nn_hls
145	ELSE ; iij = 1
146	ENDIF
147
148	!
149	IF( kpass == 1 ) THEN ; zsign = 1._wp ! bilaplacian operator require a minus sign (eddy diffusivity >0)
150	ELSE ; zsign = -1._wp
151	ENDIF
152	!
153	!!----------------------------------------------------------------------
154	!! 0 - calculate ah_wslp2, akz, and optionally zpsi_uw, zpsi_vw
155	!!----------------------------------------------------------------------
156	!
157	IF( kpass == 1 ) THEN !== first pass only and whatever the tracer is ==!
158	!
159	! [comm_cleanup] ! DO_3D( 0, 0, 0, 0, 1, jpk )
160	DO_3D_OVR( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 1, jpk )
161	akz (ji,jj,jk) = 0._wp
162	ah_wslp2(ji,jj,jk) = 0._wp
163	END_3D
164	!
165	! NOTE: [halo1-halo2]
166	zftu(:,:,:,:) = 0._wp
167	zftv(:,:,:,:) = 0._wp
168	!
169	DO ip = 0, 1 ! i-k triads
170	DO kp = 0, 1
171	! [comm_cleanup] ! DO_3D( 0, 0, 0, 0, 1, jpkm1 )
172	DO_3D( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 1, jpkm1 )
173	ze3wr = 1._wp / e3w(ji,jj,jk+kp,Kmm)
174	zbu = e1e2u(ji-ip,jj) * e3u(ji-ip,jj,jk,Kmm)
175	zah = 0.25_wp * pahu(ji-ip,jj,jk)
176	zslope_skew = triadi_g(ji,jj,jk,1-ip,kp)
177	! Subtract s-coordinate slope at t-points to give slope rel to s-surfaces (do this by adding gradient of depth)
178	zslope2 = zslope_skew + ( gdept(ji-ip+1,jj,jk,Kmm) - gdept(ji-ip,jj,jk,Kmm) ) * r1_e1u(ji-ip,jj) * umask(ji-ip,jj,jk+kp)
179	zslope2 = zslope2 *zslope2
180	! NOTE: [halo1-halo2]
181	zftu(ji,jj,jk+kp,ip+1) = zftu(ji,jj,jk+kp,ip+1) + &
182	& zah * zbu * ze3wr * r1_e1e2t(ji,jj) * zslope2
183	zftv(ji,jj,jk+kp,ip+1) = zftv(ji,jj,jk+kp,ip+1) + &
184	& zah * r1_e1u(ji-ip,jj) * r1_e1u(ji-ip,jj) * umask(ji-ip,jj,jk+kp)
185	!
186	END_3D
187	END DO
188	END DO
189	!
190	! NOTE: [halo1-halo2] Use DO_3D instead of DO_3D_OVR
191	! ip loop contributions added here to ensure consistent floating point arithmetic for different nn_hls
192	DO_3D_OVR( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 1, jpk )
193	ah_wslp2(ji,jj,jk) = ah_wslp2(ji,jj,jk) + (zftu(ji,jj,jk,1) + zftu(ji,jj,jk,2))
194	akz (ji,jj,jk) = akz (ji,jj,jk) + (zftv(ji,jj,jk,1) + zftv(ji,jj,jk,2))
195	END_3D
196	!
197	! NOTE: [halo1-halo2]
198	zftu(:,:,:,:) = 0._wp
199	zftv(:,:,:,:) = 0._wp
200	!
201	DO jp = 0, 1 ! j-k triads
202	DO kp = 0, 1
203	! [comm_cleanup] ! DO_3D( 0, 0, 0, 0, 1, jpkm1 )
204	DO_3D( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 1, jpkm1 )
205	ze3wr = 1.0_wp / e3w(ji,jj,jk+kp,Kmm)
206	zbv = e1e2v(ji,jj-jp) * e3v(ji,jj-jp,jk,Kmm)
207	zah = 0.25_wp * pahv(ji,jj-jp,jk)
208	zslope_skew = triadj_g(ji,jj,jk,1-jp,kp)
209	! Subtract s-coordinate slope at t-points to give slope rel to s surfaces
210	! (do this by adding gradient of depth)
211	zslope2 = zslope_skew + ( gdept(ji,jj-jp+1,jk,Kmm) - gdept(ji,jj-jp,jk,Kmm) ) * r1_e2v(ji,jj-jp) * vmask(ji,jj-jp,jk+kp)
212	zslope2 = zslope2 * zslope2
213	! NOTE: [halo1-halo2]
214	zftu(ji,jj,jk+kp,jp+1) = zftu(ji,jj,jk+kp,jp+1) + &
215	& zah * zbv * ze3wr * r1_e1e2t(ji,jj) * zslope2
216	zftv(ji,jj,jk+kp,jp+1) = zftv(ji,jj,jk+kp,jp+1) + &
217	& zah * r1_e2v(ji,jj-jp) * r1_e2v(ji,jj-jp) * vmask(ji,jj-jp,jk+kp)
218	!
219	END_3D
220	END DO
221	END DO
222	!
223	! NOTE: [halo1-halo2] Use DO_3D instead of DO_3D_OVR
224	! jp loop contributions added here to ensure consistent floating point arithmetic for different nn_hls
225	DO_3D_OVR( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 1, jpk )
226	ah_wslp2(ji,jj,jk) = ah_wslp2(ji,jj,jk) + (zftu(ji,jj,jk,1) + zftu(ji,jj,jk,2))
227	akz (ji,jj,jk) = akz (ji,jj,jk) + (zftv(ji,jj,jk,1) + zftv(ji,jj,jk,2))
228	END_3D
229	!
230	IF( ln_traldf_msc ) THEN ! stabilizing vertical diffusivity coefficient
231	!
232	IF( ln_traldf_blp ) THEN ! bilaplacian operator
233	! [comm_cleanup] ! DO_3D( 0, 0, 0, 0, 2, jpkm1 )
234	DO_3D_OVR( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 2, jpkm1 )
235	akz(ji,jj,jk) = 16._wp &
236	& * ah_wslp2 (ji,jj,jk) &
237	& * ( akz (ji,jj,jk) &
238	& + ah_wslp2(ji,jj,jk) &
239	& / ( e3w (ji,jj,jk,Kmm) * e3w(ji,jj,jk,Kmm) ) )
240	END_3D
241	ELSEIF( ln_traldf_lap ) THEN ! laplacian operator
242	! [comm_cleanup] ! DO_3D( 0, 0, 0, 0, 2, jpkm1 )
243	DO_3D_OVR( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 2, jpkm1 )
244	ze3w_2 = e3w(ji,jj,jk,Kmm) * e3w(ji,jj,jk,Kmm)
245	zcoef0 = rDt * ( akz(ji,jj,jk) + ah_wslp2(ji,jj,jk) / ze3w_2 )
246	akz(ji,jj,jk) = MAX( zcoef0 - 0.5_wp , 0._wp ) * ze3w_2 * r1_Dt
247	END_3D
248	ENDIF
249	!
250	ELSE ! 33 flux set to zero with akz=ah_wslp2 ==>> computed in full implicit
251	! [comm_cleanup] ! DO_3D( 0, 0, 0, 0, 1, jpk )
252	DO_3D_OVR( nn_hls-1, nn_hls-1, nn_hls-1, nn_hls-1, 1, jpk )
253	akz(ji,jj,jk) = ah_wslp2(ji,jj,jk)
254	END_3D
255	ENDIF
256	!
257	IF( ln_ldfeiv_dia .AND. cdtype == 'TRA' ) THEN
258	zpsi_uw(:,:,:) = 0._wp
259	zpsi_vw(:,:,:) = 0._wp
260
261	DO jp = 0, 1
262	DO kp = 0, 1
263	DO_3D( 1, 0, 1, 0, 1, jpkm1 )
264	zpsi_uw(ji,jj,jk+kp) = zpsi_uw(ji,jj,jk+kp) &
265	& + 0.25_wp * aeiu(ji,jj,jk) * e2u(ji,jj) * triadi_g(ji+jp,jj,jk,1-jp,kp)
266	zpsi_vw(ji,jj,jk+kp) = zpsi_vw(ji,jj,jk+kp) &
267	& + 0.25_wp * aeiv(ji,jj,jk) * e1v(ji,jj) * triadj_g(ji,jj+jp,jk,1-jp,kp)
268	END_3D
269	END DO
270	END DO
271	CALL ldf_eiv_dia( zpsi_uw, zpsi_vw, Kmm )
272	ENDIF
273	!
274	ENDIF !== end 1st pass only ==!
275	!
276	! ! ===========
277	DO jn = 1, kjpt ! tracer loop
278	! ! ===========
279	! Zero fluxes for each tracer
280	!!gm this should probably be done outside the jn loop
281	! NOTE: [halo1-halo2]
282	ztfw(:,:,:,:,:) = 0._wp
283	zftu(:,:,:,:) = 0._wp
284	zftv(:,:,:,:) = 0._wp
285	!
286	! [comm_cleanup] ! DO_3D( 1, 0, 1, 0, 1, jpkm1 ) !== before lateral T & S gradients at T-level jk ==!
287	DO_3D( iij, iij-1, iij, iij-1, 1, jpkm1 )
288	zdit(ji,jj,jk) = ( pt(ji+1,jj ,jk,jn) - pt(ji,jj,jk,jn) ) * umask(ji,jj,jk)
289	zdjt(ji,jj,jk) = ( pt(ji ,jj+1,jk,jn) - pt(ji,jj,jk,jn) ) * vmask(ji,jj,jk)
290	END_3D
291	IF( ln_zps .AND. l_grad_zps ) THEN ! partial steps: correction at top/bottom ocean level
292	! [comm_cleanup] ! DO_2D( 1, 0, 1, 0 ) ! bottom level
293	DO_2D( iij, iij-1, iij, iij-1 )
294	zdit(ji,jj,mbku(ji,jj)) = pgu(ji,jj,jn)
295	zdjt(ji,jj,mbkv(ji,jj)) = pgv(ji,jj,jn)
296	END_2D
297	IF( ln_isfcav ) THEN ! top level (ocean cavities only)
298	! [comm_cleanup] ! DO_2D( 1, 0, 1, 0 )
299	DO_2D( iij, iij-1, iij, iij-1 )
300	IF( miku(ji,jj) > 1 ) zdit(ji,jj,miku(ji,jj) ) = pgui(ji,jj,jn)
301	IF( mikv(ji,jj) > 1 ) zdjt(ji,jj,mikv(ji,jj) ) = pgvi(ji,jj,jn)
302	END_2D
303	ENDIF
304	ENDIF
305	!
306	!!----------------------------------------------------------------------
307	!! II - horizontal trend (full)
308	!!----------------------------------------------------------------------
309	!
310	DO jk = 1, jpkm1
311	! !== Vertical tracer gradient at level jk and jk+1
312	! [comm_cleanup] ! DO_2D( 1, 1, 1, 1 )
313	DO_2D( iij, iij, iij, iij )
314	zdkt3d(ji,jj,1) = ( pt(ji,jj,jk,jn) - pt(ji,jj,jk+1,jn) ) * tmask(ji,jj,jk+1)
315	END_2D
316	!
317	! ! surface boundary condition: zdkt3d(jk=0)=zdkt3d(jk=1)
318	IF( jk == 1 ) THEN ; zdkt3d(:,:,0) = zdkt3d(:,:,1)
319	ELSE
320	! [comm_cleanup] ! DO_2D( 1, 1, 1, 1 )
321	DO_2D( iij, iij, iij, iij )
322	zdkt3d(ji,jj,0) = ( pt(ji,jj,jk-1,jn) - pt(ji,jj,jk,jn) ) * tmask(ji,jj,jk)
323	END_2D
324	ENDIF
325	!
326	zaei_slp = 0._wp
327	!
328	IF( ln_botmix_triad ) THEN
329	DO ip = 0, 1 !== Horizontal & vertical fluxes
330	DO kp = 0, 1
331	! [comm_cleanup] ! DO_2D( 1, 0, 1, 0 )
332	DO_2D( iij, iij-1, iij, iij-1 )
333	ze1ur = r1_e1u(ji,jj)
334	zdxt = zdit(ji,jj,jk) * ze1ur
335	ze3wr = 1._wp / e3w(ji+ip,jj,jk+kp,Kmm)
336	zdzt = zdkt3d(ji+ip,jj,kp) * ze3wr
337	zslope_skew = triadi_g(ji+ip,jj,jk,1-ip,kp)
338	zslope_iso = triadi (ji+ip,jj,jk,1-ip,kp)
339	!
340	zbu = 0.25_wp * e1e2u(ji,jj) * e3u(ji,jj,jk,Kmm)
341	! ln_botmix_triad is .T. don't mask zah for bottom half cells !!gm ????? ahu is masked....
342	zah = pahu(ji,jj,jk)
343	zah_slp = zah * zslope_iso
344	IF( ln_ldfeiv ) zaei_slp = aeiu(ji,jj,jk) * zslope_skew
345	! NOTE: [halo1-halo2]
346	zftu(ji ,jj,jk,ip+1 ) = zftu(ji ,jj,jk,ip+1 ) - &
347	& ( zah * zdxt + (zah_slp - zaei_slp) * zdzt ) * zbu * ze1ur
348	ztfw(ji,jj,jk+kp,ip+1,1) = ztfw(ji,jj,jk+kp,ip+1,1) - &
349	& (zah_slp + zaei_slp) * zdxt * zbu * ze3wr
350	END_2D
351	END DO
352	END DO
353	!
354	DO jp = 0, 1
355	DO kp = 0, 1
356	! [comm_cleanup] ! DO_2D( 1, 0, 1, 0 )
357	DO_2D( iij, iij-1, iij, iij-1 )
358	ze2vr = r1_e2v(ji,jj)
359	zdyt = zdjt(ji,jj,jk) * ze2vr
360	ze3wr = 1._wp / e3w(ji,jj+jp,jk+kp,Kmm)
361	zdzt = zdkt3d(ji,jj+jp,kp) * ze3wr
362	zslope_skew = triadj_g(ji,jj+jp,jk,1-jp,kp)
363	zslope_iso = triadj(ji,jj+jp,jk,1-jp,kp)
364	zbv = 0.25_wp * e1e2v(ji,jj) * e3v(ji,jj,jk,Kmm)
365	! ln_botmix_triad is .T. don't mask zah for bottom half cells !!gm ????? ahv is masked...
366	zah = pahv(ji,jj,jk)
367	zah_slp = zah * zslope_iso
368	IF( ln_ldfeiv ) zaei_slp = aeiv(ji,jj,jk) * zslope_skew
369	! NOTE: [halo1-halo2]
370	zftv(ji,jj ,jk,jp+1 ) = zftv(ji,jj ,jk,jp+1 ) - &
371	& ( zah * zdyt + (zah_slp - zaei_slp) * zdzt ) * zbv * ze2vr
372	ztfw(ji,jj,jk+kp,jp+1,2) = ztfw(ji,jj,jk+kp,jp+1,2) - &
373	& (zah_slp + zaei_slp) * zdyt * zbv * ze3wr
374	END_2D
375	END DO
376	END DO
377	!
378	ELSE
379	!
380	DO ip = 0, 1 !== Horizontal & vertical fluxes
381	DO kp = 0, 1
382	! [comm_cleanup] ! DO_2D( 1, 0, 1, 0 )
383	DO_2D( iij, iij-1, iij, iij-1 )
384	ze1ur = r1_e1u(ji,jj)
385	zdxt = zdit(ji,jj,jk) * ze1ur
386	ze3wr = 1._wp / e3w(ji+ip,jj,jk+kp,Kmm)
387	zdzt = zdkt3d(ji+ip,jj,kp) * ze3wr
388	zslope_skew = triadi_g(ji+ip,jj,jk,1-ip,kp)
389	zslope_iso = triadi(ji+ip,jj,jk,1-ip,kp)
390	!
391	zbu = 0.25_wp * e1e2u(ji,jj) * e3u(ji,jj,jk,Kmm)
392	! ln_botmix_triad is .F. mask zah for bottom half cells
393	zah = pahu(ji,jj,jk) * umask(ji,jj,jk+kp) ! pahu(ji+ip,jj,jk) ===>> ????
394	zah_slp = zah * zslope_iso
395	IF( ln_ldfeiv ) zaei_slp = aeiu(ji,jj,jk) * zslope_skew ! aeit(ji+ip,jj,jk)*zslope_skew
396	! NOTE: [halo1-halo2]
397	zftu(ji ,jj,jk,ip+1 ) = zftu(ji ,jj,jk,ip+1 ) - &
398	& ( zah * zdxt + (zah_slp - zaei_slp) * zdzt ) * zbu * ze1ur
399	ztfw(ji,jj,jk+kp,ip+1,1) = ztfw(ji,jj,jk+kp,ip+1,1) - &
400	& (zah_slp + zaei_slp) * zdxt * zbu * ze3wr
401	END_2D
402	END DO
403	END DO
404	!
405	DO jp = 0, 1
406	DO kp = 0, 1
407	! [comm_cleanup] ! DO_2D( 1, 0, 1, 0 )
408	DO_2D( iij, iij-1, iij, iij-1 )
409	ze2vr = r1_e2v(ji,jj)
410	zdyt = zdjt(ji,jj,jk) * ze2vr
411	ze3wr = 1._wp / e3w(ji,jj+jp,jk+kp,Kmm)
412	zdzt = zdkt3d(ji,jj+jp,kp) * ze3wr
413	zslope_skew = triadj_g(ji,jj+jp,jk,1-jp,kp)
414	zslope_iso = triadj(ji,jj+jp,jk,1-jp,kp)
415	zbv = 0.25_wp * e1e2v(ji,jj) * e3v(ji,jj,jk,Kmm)
416	! ln_botmix_triad is .F. mask zah for bottom half cells
417	zah = pahv(ji,jj,jk) * vmask(ji,jj,jk+kp) ! pahv(ji,jj+jp,jk) ????
418	zah_slp = zah * zslope_iso
419	IF( ln_ldfeiv ) zaei_slp = aeiv(ji,jj,jk) * zslope_skew ! aeit(ji,jj+jp,jk)*zslope_skew
420	! NOTE: [halo1-halo2]
421	zftv(ji,jj,jk, jp+1 ) = zftv(ji,jj,jk, jp+1 ) - &
422	& ( zah * zdyt + (zah_slp - zaei_slp) * zdzt ) * zbv * ze2vr
423	ztfw(ji,jj,jk+kp,jp+1,2) = ztfw(ji,jj,jk+kp,jp+1,2) - &
424	& (zah_slp + zaei_slp) * zdyt * zbv * ze3wr
425	END_2D
426	END DO
427	END DO
428	ENDIF
429	! NOTE: [halo1-halo2]
430	! ip and jp loop contributions added here to ensure consistent floating point arithmetic for different nn_hls
431	DO_2D( iij, iij-1, iij, iij-1 )
432	zftu(ji,jj,jk,1) = zftu(ji,jj,jk,1) + zftu(ji,jj,jk,2)
433	zftv(ji,jj,jk,1) = zftv(ji,jj,jk,1) + zftv(ji,jj,jk,2)
434	END_2D
435	DO_2D( iij-1, iij-1, iij-1, iij-1 )
436	ztfw(ji,jj,jk,1,1) = (ztfw(ji,jj,jk,1,1) + ztfw(ji-1,jj,jk,2,1)) + &
437	& (ztfw(ji,jj,jk,1,2) + ztfw(ji,jj-1,jk,2,2))
438	END_2D
439	! !== horizontal divergence and add to the general trend ==!
440	! [comm_cleanup] ! DO_2D( 0, 0, 0, 0 )
441	DO_2D( iij-1, iij-1, iij-1, iij-1 )
442	! NOTE: [halo1-halo2]
443	! Extra brackets required to ensure consistent floating point arithmetic for different nn_hls for bilaplacian
444	pt_rhs(ji,jj,jk,jn) = pt_rhs(ji,jj,jk,jn) &
445	& + zsign * ( (zftu(ji-1,jj,jk,1) - zftu(ji,jj,jk,1)) &
446	& + (zftv(ji,jj-1,jk,1) - zftv(ji,jj,jk,1)) ) &
447	& / ( e1e2t(ji,jj) * e3t(ji,jj,jk,Kmm) )
448	END_2D
449	!
450	END DO
451	!
452	! !== add the vertical 33 flux ==!
453	IF( ln_traldf_lap ) THEN ! laplacian case: eddy coef = ah_wslp2 - akz
454	! [comm_cleanup] ! DO_3D( 0, 0, 1, 0, 2, jpkm1 )
455	DO_3D( iij-1, iij-1, iij-1, iij-1, 2, jpkm1 )
456	ztfw(ji,jj,jk,1,1) = ztfw(ji,jj,jk,1,1) - e1e2t(ji,jj) / e3w(ji,jj,jk,Kmm) * tmask(ji,jj,jk) &
457	& * ( ah_wslp2(ji,jj,jk) - akz(ji,jj,jk) ) &
458	& * ( pt(ji,jj,jk-1,jn) - pt(ji,jj,jk,jn) )
459	END_3D
460	ELSE ! bilaplacian
461	SELECT CASE( kpass )
462	CASE( 1 ) ! 1st pass : eddy coef = ah_wslp2
463	! [comm_cleanup] ! DO_3D( 0, 0, 1, 0, 2, jpkm1 )
464	DO_3D( iij-1, iij-1, iij-1, iij-1, 2, jpkm1 )
465	ztfw(ji,jj,jk,1,1) = ztfw(ji,jj,jk,1,1) - e1e2t(ji,jj) / e3w(ji,jj,jk,Kmm) * tmask(ji,jj,jk) &
466	& * ah_wslp2(ji,jj,jk) * ( pt(ji,jj,jk-1,jn) - pt(ji,jj,jk,jn) )
467	END_3D
468	CASE( 2 ) ! 2nd pass : eddy flux = ah_wslp2 and akz applied on pt and pt2 gradients, resp.
469	DO_3D( 0, 0, 0, 0, 2, jpkm1 )
470	ztfw(ji,jj,jk,1,1) = ztfw(ji,jj,jk,1,1) - e1e2t(ji,jj) / e3w(ji,jj,jk,Kmm) * tmask(ji,jj,jk) &
471	& * ( ah_wslp2(ji,jj,jk) * ( pt (ji,jj,jk-1,jn) - pt (ji,jj,jk,jn) ) &
472	& + akz (ji,jj,jk) * ( pt2(ji,jj,jk-1,jn) - pt2(ji,jj,jk,jn) ) )
473	END_3D
474	END SELECT
475	ENDIF
476	!
477	! [comm_cleanup] ! DO_3D( 0, 0, 0, 0, 1, jpkm1 ) !== Divergence of vertical fluxes added to pta ==!
478	DO_3D( iij-1, iij-1, iij-1, iij-1, 1, jpkm1 )
479	pt_rhs(ji,jj,jk,jn) = pt_rhs(ji,jj,jk,jn) + zsign * ( ztfw(ji,jj,jk+1,1,1) - ztfw(ji,jj,jk,1,1) ) &
480	& / ( e1e2t(ji,jj) * e3t(ji,jj,jk,Kmm) )
481	END_3D
482	!
483	IF( ( kpass == 1 .AND. ln_traldf_lap ) .OR. & !== first pass only ( laplacian) ==!
484	( kpass == 2 .AND. ln_traldf_blp ) ) THEN !== 2nd pass (bilaplacian) ==!
485	!
486	! ! "Poleward" diffusive heat or salt transports (T-S case only)
487	! NOTE: [halo1-halo2]
488	IF( l_ptr ) CALL dia_ptr_hst( jn, 'ldf', zftv(:,:,:,1) )
489	! ! Diffusive heat transports
490	! NOTE: [halo1-halo2]
491	IF( l_hst ) CALL dia_ar5_hst( jn, 'ldf', zftu(:,:,:,1), zftv(:,:,:,1) )
492	!
493	ENDIF !== end pass selection ==!
494	!
495	! ! ===============
496	END DO ! end tracer loop
497	! ! ===============
498	END SUBROUTINE tra_ldf_triad_t
499
500	!!==============================================================================
501	END MODULE traldf_triad

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