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fldread.F90 @ 8243

Last change on this file since 8243 was 8243, checked in by andmirek, 7 years ago
#1914 working XIOS read, XIOS write and single processor read
File size: 85.2 KB

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1	MODULE fldread
2	!!======================================================================
3	!! * MODULE fldread *
4	!! Ocean forcing: read input field for surface boundary condition
5	!!=====================================================================
6	!! History : 2.0 ! 06-2006 (S. Masson, G. Madec) Original code
7	!! ! 05-2008 (S. Alderson) Modified for Interpolation in memory
8	!! ! from input grid to model grid
9	!! ! 10-2013 (D. Delrosso, P. Oddo) implement suppression of
10	!! ! land point prior to interpolation
11	!!----------------------------------------------------------------------
12
13	!!----------------------------------------------------------------------
14	!! fld_read : read input fields used for the computation of the
15	!! surface boundary condition
16	!!----------------------------------------------------------------------
17	USE oce ! ocean dynamics and tracers
18	USE dom_oce ! ocean space and time domain
19	USE phycst ! ???
20	USE in_out_manager ! I/O manager
21	USE iom ! I/O manager library
22	USE geo2ocean ! for vector rotation on to model grid
23	USE lib_mpp ! MPP library
24	USE wrk_nemo ! work arrays
25	USE lbclnk ! ocean lateral boundary conditions (C1D case)
26	USE ioipsl, ONLY : ymds2ju, ju2ymds ! for calendar
27	USE sbc_oce
28
29	IMPLICIT NONE
30	PRIVATE
31
32	PUBLIC fld_map ! routine called by tides_init
33	PUBLIC fld_read, fld_fill ! called by sbc... modules
34	PUBLIC fld_clopn
35
36	TYPE, PUBLIC :: FLD_N !: Namelist field informations
37	CHARACTER(len = 256) :: clname ! generic name of the NetCDF flux file
38	REAL(wp) :: nfreqh ! frequency of each flux file
39	CHARACTER(len = 34) :: clvar ! generic name of the variable in the NetCDF flux file
40	LOGICAL :: ln_tint ! time interpolation or not (T/F)
41	LOGICAL :: ln_clim ! climatology or not (T/F)
42	CHARACTER(len = 8) :: cltype ! type of data file 'daily', 'monthly' or yearly'
43	CHARACTER(len = 256) :: wname ! generic name of a NetCDF weights file to be used, blank if not
44	CHARACTER(len = 34) :: vcomp ! symbolic component name if a vector that needs rotation
45	! ! a string starting with "U" or "V" for each component
46	! ! chars 2 onwards identify which components go together
47	CHARACTER(len = 34) :: lname ! generic name of a NetCDF land/sea mask file to be used, blank if not
48	! ! 0=sea 1=land
49	END TYPE FLD_N
50
51	TYPE, PUBLIC :: FLD !: Input field related variables
52	CHARACTER(len = 256) :: clrootname ! generic name of the NetCDF file
53	CHARACTER(len = 256) :: clname ! current name of the NetCDF file
54	REAL(wp) :: nfreqh ! frequency of each flux file
55	CHARACTER(len = 34) :: clvar ! generic name of the variable in the NetCDF flux file
56	LOGICAL :: ln_tint ! time interpolation or not (T/F)
57	LOGICAL :: ln_clim ! climatology or not (T/F)
58	CHARACTER(len = 8) :: cltype ! type of data file 'daily', 'monthly' or yearly'
59	INTEGER :: num ! iom id of the jpfld files to be read
60	INTEGER , DIMENSION(2) :: nrec_b ! before record (1: index, 2: second since Jan. 1st 00h of nit000 year)
61	INTEGER , DIMENSION(2) :: nrec_a ! after record (1: index, 2: second since Jan. 1st 00h of nit000 year)
62	REAL(wp) , ALLOCATABLE, DIMENSION(:,:,: ) :: fnow ! input fields interpolated to now time step
63	REAL(wp) , ALLOCATABLE, DIMENSION(:,:,:,:) :: fdta ! 2 consecutive record of input fields
64	CHARACTER(len = 256) :: wgtname ! current name of the NetCDF weight file acting as a key
65	! ! into the WGTLIST structure
66	CHARACTER(len = 34) :: vcomp ! symbolic name for a vector component that needs rotation
67	LOGICAL, DIMENSION(2) :: rotn ! flag to indicate whether before/after field has been rotated
68	INTEGER :: nreclast ! last record to be read in the current file
69	CHARACTER(len = 256) :: lsmname ! current name of the NetCDF mask file acting as a key
70	END TYPE FLD
71
72	TYPE, PUBLIC :: MAP_POINTER !: Map from input data file to local domain
73	INTEGER, POINTER, DIMENSION(:) :: ptr ! Array of integer pointers to 1D arrays
74	LOGICAL :: ll_unstruc ! Unstructured (T) or structured (F) boundary data file
75	END TYPE MAP_POINTER
76
77	!$AGRIF_DO_NOT_TREAT
78
79	!! keep list of all weights variables so they're only read in once
80	!! need to add AGRIF directives not to process this structure
81	!! also need to force wgtname to include AGRIF nest number
82	TYPE :: WGT !: Input weights related variables
83	CHARACTER(len = 256) :: wgtname ! current name of the NetCDF weight file
84	INTEGER , DIMENSION(2) :: ddims ! shape of input grid
85	INTEGER , DIMENSION(2) :: botleft ! top left corner of box in input grid containing
86	! ! current processor grid
87	INTEGER , DIMENSION(2) :: topright ! top right corner of box
88	INTEGER :: jpiwgt ! width of box on input grid
89	INTEGER :: jpjwgt ! height of box on input grid
90	INTEGER :: numwgt ! number of weights (4=bilinear, 16=bicubic)
91	INTEGER :: nestid ! for agrif, keep track of nest we're in
92	INTEGER :: overlap ! =0 when cyclic grid has no overlapping EW columns
93	! ! =>1 when they have one or more overlapping columns
94	! ! =-1 not cyclic
95	LOGICAL :: cyclic ! east-west cyclic or not
96	INTEGER, DIMENSION(:,:,:), POINTER :: data_jpi ! array of source integers
97	INTEGER, DIMENSION(:,:,:), POINTER :: data_jpj ! array of source integers
98	REAL(wp), DIMENSION(:,:,:), POINTER :: data_wgt ! array of weights on model grid
99	REAL(wp), DIMENSION(:,:,:), POINTER :: fly_dta ! array of values on input grid
100	REAL(wp), DIMENSION(:,:,:), POINTER :: col ! temporary array for reading in columns
101	END TYPE WGT
102
103	INTEGER, PARAMETER :: tot_wgts = 10
104	TYPE( WGT ), DIMENSION(tot_wgts) :: ref_wgts ! array of wgts
105	INTEGER :: nxt_wgt = 1 ! point to next available space in ref_wgts array
106	REAL(wp), PARAMETER :: undeff_lsm = -999.00_wp
107
108	!$AGRIF_END_DO_NOT_TREAT
109
110	!!----------------------------------------------------------------------
111	!! NEMO/OPA 3.3 , NEMO Consortium (2010)
112	!! $Id$
113	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
114	!!----------------------------------------------------------------------
115	CONTAINS
116
117	SUBROUTINE fld_read( kt, kn_fsbc, sd, map, kit, kt_offset )
118	!!---------------------------------------------------------------------
119	!! * ROUTINE fld_read *
120	!!
121	!! ** Purpose : provide at each time step the surface ocean fluxes
122	!! (momentum, heat, freshwater and runoff)
123	!!
124	!! ** Method : READ each input fields in NetCDF files using IOM
125	!! and intepolate it to the model time-step.
126	!! Several assumptions are made on the input file:
127	!! blahblahblah....
128	!!----------------------------------------------------------------------
129	INTEGER , INTENT(in ) :: kt ! ocean time step
130	INTEGER , INTENT(in ) :: kn_fsbc ! sbc computation period (in time step)
131	TYPE(FLD), INTENT(inout), DIMENSION(:) :: sd ! input field related variables
132	TYPE(MAP_POINTER),INTENT(in), OPTIONAL, DIMENSION(:) :: map ! global-to-local mapping indices
133	INTEGER , INTENT(in ), OPTIONAL :: kit ! subcycle timestep for timesplitting option
134	INTEGER , INTENT(in ), OPTIONAL :: kt_offset ! provide fields at time other than "now"
135	! kt_offset = -1 => fields at "before" time level
136	! kt_offset = +1 => fields at "after" time level
137	! etc.
138	!!
139	INTEGER :: itmp ! temporary variable
140	INTEGER :: imf ! size of the structure sd
141	INTEGER :: jf ! dummy indices
142	INTEGER :: isecend ! number of second since Jan. 1st 00h of nit000 year at nitend
143	INTEGER :: isecsbc ! number of seconds between Jan. 1st 00h of nit000 year and the middle of sbc time step
144	INTEGER :: it_offset ! local time offset variable
145	LOGICAL :: llnxtyr ! open next year file?
146	LOGICAL :: llnxtmth ! open next month file?
147	LOGICAL :: llstop ! stop is the file does not exist
148	LOGICAL :: ll_firstcall ! true if this is the first call to fld_read for this set of fields
149	REAL(wp) :: ztinta ! ratio applied to after records when doing time interpolation
150	REAL(wp) :: ztintb ! ratio applied to before records when doing time interpolation
151	CHARACTER(LEN=1000) :: clfmt ! write format
152	TYPE(MAP_POINTER) :: imap ! global-to-local mapping indices
153	!!---------------------------------------------------------------------
154	ll_firstcall = kt == nit000
155	IF( PRESENT(kit) ) ll_firstcall = ll_firstcall .and. kit == 1
156
157	IF ( nn_components == jp_iam_sas ) THEN ; it_offset = nn_fsbc
158	ELSE ; it_offset = 0
159	ENDIF
160	IF( PRESENT(kt_offset) ) it_offset = kt_offset
161
162	imap%ptr => NULL()
163
164	! Note that shifting time to be centrered in the middle of sbc time step impacts only nsec_* variables of the calendar
165	IF( present(kit) ) THEN ! ignore kn_fsbc in this case
166	isecsbc = nsec_year + nsec1jan000 + (kit+it_offset)*NINT( rdt/REAL(nn_baro,wp) )
167	ELSE ! middle of sbc time step
168	isecsbc = nsec_year + nsec1jan000 + NINT(0.5 * REAL(kn_fsbc - 1,wp) * rdttra(1)) + it_offset * NINT(rdttra(1))
169	ENDIF
170	imf = SIZE( sd )
171	!
172	IF( ll_firstcall ) THEN ! initialization
173	DO jf = 1, imf
174	IF( PRESENT(map) ) imap = map(jf)
175	CALL fld_init( kn_fsbc, sd(jf), imap ) ! read each before field (put them in after as they will be swapped)
176	END DO
177	IF( lwp ) CALL wgt_print() ! control print
178	ENDIF
179	! ! ====================================== !
180	IF( MOD( kt-1, kn_fsbc ) == 0 ) THEN ! update field at each kn_fsbc time-step !
181	! ! ====================================== !
182	!
183	DO jf = 1, imf ! --- loop over field --- !
184
185	IF( isecsbc > sd(jf)%nrec_a(2) .OR. ll_firstcall ) THEN ! read/update the after data?
186
187	IF( PRESENT(map) ) imap = map(jf) ! temporary definition of map
188
189	sd(jf)%nrec_b(:) = sd(jf)%nrec_a(:) ! swap before record informations
190	sd(jf)%rotn(1) = sd(jf)%rotn(2) ! swap before rotate informations
191	IF( sd(jf)%ln_tint ) sd(jf)%fdta(:,:,:,1) = sd(jf)%fdta(:,:,:,2) ! swap before record field
192
193	CALL fld_rec( kn_fsbc, sd(jf), kt_offset = it_offset, kit = kit ) ! update after record informations
194
195	! if kn_fsbc*rdttra is larger than nfreqh (which is kind of odd),
196	! it is possible that the before value is no more the good one... we have to re-read it
197	! if before is not the last record of the file currently opened and after is the first record to be read
198	! in a new file which means after = 1 (the file to be opened corresponds to the current time)
199	! or after = nreclast + 1 (the file to be opened corresponds to a future time step)
200	IF( .NOT. ll_firstcall .AND. sd(jf)%ln_tint .AND. sd(jf)%nrec_b(1) /= sd(jf)%nreclast &
201	& .AND. MOD( sd(jf)%nrec_a(1), sd(jf)%nreclast ) == 1 ) THEN
202	itmp = sd(jf)%nrec_a(1) ! temporary storage
203	sd(jf)%nrec_a(1) = sd(jf)%nreclast ! read the last record of the file currently opened
204	CALL fld_get( sd(jf), imap ) ! read after data
205	sd(jf)%fdta(:,:,:,1) = sd(jf)%fdta(:,:,:,2) ! re-swap before record field
206	sd(jf)%nrec_b(1) = sd(jf)%nrec_a(1) ! update before record informations
207	sd(jf)%nrec_b(2) = sd(jf)%nrec_a(2) - NINT( sd(jf)%nfreqh * 3600 ) ! assume freq to be in hours in this case
208	sd(jf)%rotn(1) = sd(jf)%rotn(2) ! update before rotate informations
209	sd(jf)%nrec_a(1) = itmp ! move back to after record
210	ENDIF
211
212	CALL fld_clopn( sd(jf) ) ! Do we need to open a new year/month/week/day file?
213
214	IF( sd(jf)%ln_tint ) THEN
215
216	! if kn_fsbc*rdttra is larger than nfreqh (which is kind of odd),
217	! it is possible that the before value is no more the good one... we have to re-read it
218	! if before record is not just just before the after record...
219	IF( .NOT. ll_firstcall .AND. MOD( sd(jf)%nrec_a(1), sd(jf)%nreclast ) /= 1 &
220	& .AND. sd(jf)%nrec_b(1) /= sd(jf)%nrec_a(1) - 1 ) THEN
221	sd(jf)%nrec_a(1) = sd(jf)%nrec_a(1) - 1 ! move back to before record
222	CALL fld_get( sd(jf), imap ) ! read after data
223	sd(jf)%fdta(:,:,:,1) = sd(jf)%fdta(:,:,:,2) ! re-swap before record field
224	sd(jf)%nrec_b(1) = sd(jf)%nrec_a(1) ! update before record informations
225	sd(jf)%nrec_b(2) = sd(jf)%nrec_a(2) - NINT( sd(jf)%nfreqh * 3600 ) ! assume freq to be in hours in this case
226	sd(jf)%rotn(1) = sd(jf)%rotn(2) ! update before rotate informations
227	sd(jf)%nrec_a(1) = sd(jf)%nrec_a(1) + 1 ! move back to after record
228	ENDIF
229
230	! do we have to change the year/month/week/day of the forcing field??
231	! if we do time interpolation we will need to open next year/month/week/day file before the end of the current
232	! one. If so, we are still before the end of the year/month/week/day when calling fld_rec so sd(jf)%nrec_a(1)
233	! will be larger than the record number that should be read for current year/month/week/day
234	! do we need next file data?
235	IF( sd(jf)%nrec_a(1) > sd(jf)%nreclast ) THEN
236
237	sd(jf)%nrec_a(1) = sd(jf)%nrec_a(1) - sd(jf)%nreclast !
238
239	IF( .NOT. ( sd(jf)%ln_clim .AND. sd(jf)%cltype == 'yearly' ) ) THEN ! close/open the current/new file
240
241	llnxtmth = sd(jf)%cltype == 'monthly' .OR. nday == nmonth_len(nmonth) ! open next month file?
242	llnxtyr = sd(jf)%cltype == 'yearly' .OR. (nmonth == 12 .AND. llnxtmth) ! open next year file?
243
244	! if the run finishes at the end of the current year/month/week/day, we will allow next
245	! year/month/week/day file to be not present. If the run continue further than the current
246	! year/month/week/day, next year/month/week/day file must exist
247	isecend = nsec_year + nsec1jan000 + (nitend - kt) * NINT(rdttra(1)) ! second at the end of the run
248	llstop = isecend > sd(jf)%nrec_a(2) ! read more than 1 record of next year
249	! we suppose that the date of next file is next day (should be ok even for weekly files...)
250	CALL fld_clopn( sd(jf), nyear + COUNT((/llnxtyr /)) , &
251	& nmonth + COUNT((/llnxtmth/)) - 12 * COUNT((/llnxtyr /)), &
252	& nday + 1 - nmonth_len(nmonth) * COUNT((/llnxtmth/)), llstop )
253
254	IF( sd(jf)%num <= 0 .AND. .NOT. llstop ) THEN ! next year file does not exist
255	CALL ctl_warn('next year/month/week/day file: '//TRIM(sd(jf)%clname)// &
256	& ' not present -> back to current year/month/day')
257	CALL fld_clopn( sd(jf) ) ! back to the current year/month/day
258	sd(jf)%nrec_a(1) = sd(jf)%nreclast ! force to read the last record in the current year file
259	ENDIF
260
261	ENDIF
262	ENDIF ! open need next file?
263
264	ENDIF ! temporal interpolation?
265
266	! read after data
267	CALL fld_get( sd(jf), imap )
268
269	ENDIF ! read new data?
270	END DO ! --- end loop over field --- !
271
272	CALL fld_rot( kt, sd ) ! rotate vector before/now/after fields if needed
273
274	DO jf = 1, imf ! --- loop over field --- !
275	!
276	IF( sd(jf)%ln_tint ) THEN ! temporal interpolation
277	IF(lwp .AND. kt - nit000 <= 100 ) THEN
278	clfmt = "('fld_read: var ', a, ' kt = ', i8, ' (', f9.4,' days), Y/M/D = ', i4.4,'/', i2.2,'/', i2.2," // &
279	& "', records b/a: ', i6.4, '/', i6.4, ' (days ', f9.4,'/', f9.4, ')')"
280	WRITE(numout, clfmt) TRIM( sd(jf)%clvar ), kt, REAL(isecsbc,wp)/rday, nyear, nmonth, nday, &
281	& sd(jf)%nrec_b(1), sd(jf)%nrec_a(1), REAL(sd(jf)%nrec_b(2),wp)/rday, REAL(sd(jf)%nrec_a(2),wp)/rday
282	WRITE(numout, *) 'it_offset is : ',it_offset
283	ENDIF
284	! temporal interpolation weights
285	ztinta = REAL( isecsbc - sd(jf)%nrec_b(2), wp ) / REAL( sd(jf)%nrec_a(2) - sd(jf)%nrec_b(2), wp )
286	ztintb = 1. - ztinta
287	!CDIR COLLAPSE
288	sd(jf)%fnow(:,:,:) = ztintb * sd(jf)%fdta(:,:,:,1) + ztinta * sd(jf)%fdta(:,:,:,2)
289	ELSE ! nothing to do...
290	IF(lwp .AND. kt - nit000 <= 100 ) THEN
291	clfmt = "('fld_read: var ', a, ' kt = ', i8,' (', f9.4,' days), Y/M/D = ', i4.4,'/', i2.2,'/', i2.2," // &
292	& "', record: ', i6.4, ' (days ', f9.4, ' <-> ', f9.4, ')')"
293	WRITE(numout, clfmt) TRIM(sd(jf)%clvar), kt, REAL(isecsbc,wp)/rday, nyear, nmonth, nday, &
294	& sd(jf)%nrec_a(1), REAL(sd(jf)%nrec_b(2),wp)/rday, REAL(sd(jf)%nrec_a(2),wp)/rday
295	ENDIF
296	ENDIF
297	!
298	IF( kt == nitend - kn_fsbc + 1 ) CALL iom_close( sd(jf)%num ) ! Close the input files
299
300	END DO ! --- end loop over field --- !
301	!
302	! ! ====================================== !
303	ENDIF ! update field at each kn_fsbc time-step !
304	! ! ====================================== !
305	!
306	END SUBROUTINE fld_read
307
308
309	SUBROUTINE fld_init( kn_fsbc, sdjf, map )
310	!!---------------------------------------------------------------------
311	!! * ROUTINE fld_init *
312	!!
313	!! ** Purpose : - first call to fld_rec to define before values
314	!! - if time interpolation, read before data
315	!!----------------------------------------------------------------------
316	INTEGER , INTENT(in ) :: kn_fsbc ! sbc computation period (in time step)
317	TYPE(FLD), INTENT(inout) :: sdjf ! input field related variables
318	TYPE(MAP_POINTER),INTENT(in) :: map ! global-to-local mapping indices
319	!!
320	LOGICAL :: llprevyr ! are we reading previous year file?
321	LOGICAL :: llprevmth ! are we reading previous month file?
322	LOGICAL :: llprevweek ! are we reading previous week file?
323	LOGICAL :: llprevday ! are we reading previous day file?
324	LOGICAL :: llprev ! llprevyr .OR. llprevmth .OR. llprevweek .OR. llprevday
325	INTEGER :: idvar ! variable id
326	INTEGER :: inrec ! number of record existing for this variable
327	INTEGER :: iyear, imonth, iday ! first day of the current file in yyyy mm dd
328	INTEGER :: isec_week ! number of seconds since start of the weekly file
329	CHARACTER(LEN=1000) :: clfmt ! write format
330	!!---------------------------------------------------------------------
331	llprevyr = .FALSE.
332	llprevmth = .FALSE.
333	llprevweek = .FALSE.
334	llprevday = .FALSE.
335	isec_week = 0
336
337	! define record informations
338	CALL fld_rec( kn_fsbc, sdjf, ldbefore = .TRUE. ) ! return before values in sdjf%nrec_a (as we will swap it later)
339
340	! Note that shifting time to be centrered in the middle of sbc time step impacts only nsec_* variables of the calendar
341
342	IF( sdjf%ln_tint ) THEN ! we need to read the previous record and we will put it in the current record structure
343
344	IF( sdjf%nrec_a(1) == 0 ) THEN ! we redefine record sdjf%nrec_a(1) with the last record of previous year file
345	IF ( sdjf%nfreqh == -12 ) THEN ! yearly mean
346	IF( sdjf%cltype == 'yearly' ) THEN ! yearly file
347	sdjf%nrec_a(1) = 1 ! force to read the unique record
348	llprevyr = .NOT. sdjf%ln_clim ! use previous year file?
349	ELSE
350	CALL ctl_stop( "fld_init: yearly mean file must be in a yearly type of file: "//TRIM(sdjf%clrootname) )
351	ENDIF
352	ELSEIF( sdjf%nfreqh == -1 ) THEN ! monthly mean
353	IF( sdjf%cltype == 'monthly' ) THEN ! monthly file
354	sdjf%nrec_a(1) = 1 ! force to read the unique record
355	llprevmth = .TRUE. ! use previous month file?
356	llprevyr = llprevmth .AND. nmonth == 1 ! use previous year file?
357	ELSE ! yearly file
358	sdjf%nrec_a(1) = 12 ! force to read december mean
359	llprevyr = .NOT. sdjf%ln_clim ! use previous year file?
360	ENDIF
361	ELSE ! higher frequency mean (in hours)
362	IF ( sdjf%cltype == 'monthly' ) THEN ! monthly file
363	sdjf%nrec_a(1) = NINT( 24 * nmonth_len(nmonth-1) / sdjf%nfreqh ) ! last record of previous month
364	llprevmth = .TRUE. ! use previous month file?
365	llprevyr = llprevmth .AND. nmonth == 1 ! use previous year file?
366	ELSEIF( sdjf%cltype(1:4) == 'week' ) THEN ! weekly file
367	llprevweek = .TRUE. ! use previous week file?
368	sdjf%nrec_a(1) = NINT( 24 * 7 / sdjf%nfreqh ) ! last record of previous week
369	isec_week = NINT(rday) * 7 ! add a shift toward previous week
370	ELSEIF( sdjf%cltype == 'daily' ) THEN ! daily file
371	sdjf%nrec_a(1) = NINT( 24 / sdjf%nfreqh ) ! last record of previous day
372	llprevday = .TRUE. ! use previous day file?
373	llprevmth = llprevday .AND. nday == 1 ! use previous month file?
374	llprevyr = llprevmth .AND. nmonth == 1 ! use previous year file?
375	ELSE ! yearly file
376	sdjf%nrec_a(1) = NINT( 24 * nyear_len(0) / sdjf%nfreqh ) ! last record of previous year
377	llprevyr = .NOT. sdjf%ln_clim ! use previous year file?
378	ENDIF
379	ENDIF
380	ENDIF
381	!
382	IF ( sdjf%cltype(1:4) == 'week' ) THEN
383	isec_week = isec_week + ksec_week( sdjf%cltype(6:8) ) ! second since the beginning of the week
384	llprevmth = isec_week > nsec_month ! longer time since the beginning of the week than the month
385	llprevyr = llprevmth .AND. nmonth == 1
386	ENDIF
387	llprev = llprevyr .OR. llprevmth .OR. llprevweek .OR. llprevday
388	!
389	iyear = nyear - COUNT((/llprevyr /))
390	imonth = nmonth - COUNT((/llprevmth/)) + 12 * COUNT((/llprevyr /))
391	iday = nday - COUNT((/llprevday/)) + nmonth_len(nmonth-1) * COUNT((/llprevmth/)) - isec_week / NINT(rday)
392	!
393	CALL fld_clopn( sdjf, iyear, imonth, iday, .NOT. llprev )
394
395	! if previous year/month/day file does not exist, we switch to the current year/month/day
396	IF( llprev .AND. sdjf%num <= 0 ) THEN
397	CALL ctl_warn( 'previous year/month/week/day file: '//TRIM(sdjf%clrootname)// &
398	& ' not present -> back to current year/month/week/day' )
399	! we force to read the first record of the current year/month/day instead of last record of previous year/month/day
400	llprev = .FALSE.
401	sdjf%nrec_a(1) = 1
402	CALL fld_clopn( sdjf )
403	ENDIF
404
405	IF( llprev ) THEN ! check if the record sdjf%nrec_a(1) exists in the file
406	idvar = iom_varid( sdjf%num, sdjf%clvar ) ! id of the variable sdjf%clvar
407	IF( idvar <= 0 ) RETURN
408	inrec = iom_file( sdjf%num )%dimsz( iom_file( sdjf%num )%ndims(idvar), idvar ) ! size of the last dim of idvar
409	sdjf%nrec_a(1) = MIN( sdjf%nrec_a(1), inrec ) ! make sure we select an existing record
410	ENDIF
411
412	! read before data in after arrays(as we will swap it later)
413	CALL fld_get( sdjf, map )
414
415	clfmt = "('fld_init : time-interpolation for ', a, ' read previous record = ', i6, ' at time = ', f7.2, ' days')"
416	IF(lwp) WRITE(numout, clfmt) TRIM(sdjf%clvar), sdjf%nrec_a(1), REAL(sdjf%nrec_a(2),wp)/rday
417
418	ENDIF
419	!
420	END SUBROUTINE fld_init
421
422
423	SUBROUTINE fld_rec( kn_fsbc, sdjf, ldbefore, kit, kt_offset )
424	!!---------------------------------------------------------------------
425	!! * ROUTINE fld_rec *
426	!!
427	!! ** Purpose : Compute
428	!! if sdjf%ln_tint = .TRUE.
429	!! nrec_a: record number and its time (nrec_b is obtained from nrec_a when swapping)
430	!! if sdjf%ln_tint = .FALSE.
431	!! nrec_a(1): record number
432	!! nrec_b(2) and nrec_a(2): time of the beginning and end of the record (for print only)
433	!!----------------------------------------------------------------------
434	INTEGER , INTENT(in ) :: kn_fsbc ! sbc computation period (in time step)
435	TYPE(FLD), INTENT(inout) :: sdjf ! input field related variables
436	LOGICAL , INTENT(in ), OPTIONAL :: ldbefore ! sent back before record values (default = .FALSE.)
437	INTEGER , INTENT(in ), OPTIONAL :: kit ! index of barotropic subcycle
438	! used only if sdjf%ln_tint = .TRUE.
439	INTEGER , INTENT(in ), OPTIONAL :: kt_offset ! Offset of required time level compared to "now"
440	! time level in units of time steps.
441	!!
442	LOGICAL :: llbefore ! local definition of ldbefore
443	INTEGER :: iendrec ! end of this record (in seconds)
444	INTEGER :: imth ! month number
445	INTEGER :: ifreq_sec ! frequency mean (in seconds)
446	INTEGER :: isec_week ! number of seconds since the start of the weekly file
447	INTEGER :: it_offset ! local time offset variable
448	REAL(wp) :: ztmp ! temporary variable
449	!!----------------------------------------------------------------------
450	!
451	! Note that shifting time to be centrered in the middle of sbc time step impacts only nsec_* variables of the calendar
452	!
453	IF( PRESENT(ldbefore) ) THEN ; llbefore = ldbefore .AND. sdjf%ln_tint ! needed only if sdjf%ln_tint = .TRUE.
454	ELSE ; llbefore = .FALSE.
455	ENDIF
456	!
457	IF ( nn_components == jp_iam_sas ) THEN ; it_offset = nn_fsbc
458	ELSE ; it_offset = 0
459	ENDIF
460	IF( PRESENT(kt_offset) ) it_offset = kt_offset
461	IF( PRESENT(kit) ) THEN ; it_offset = ( kit + it_offset ) * NINT( rdt/REAL(nn_baro,wp) )
462	ELSE ; it_offset = it_offset * NINT( rdttra(1) )
463	ENDIF
464	!
465	! ! =========== !
466	IF ( sdjf%nfreqh == -12 ) THEN ! yearly mean
467	! ! =========== !
468	!
469	IF( sdjf%ln_tint ) THEN ! time interpolation, shift by 1/2 record
470	!
471	! INT( ztmp )
472	! /\|\
473	! 1 \| *----
474	! 0 \|----(
475	! \|----+----\|--> time
476	! 0 /\|\ 1 (nday/nyear_len(1))
477	! \|
478	! \|
479	! forcing record : 1
480	!
481	ztmp = REAL( nsec_year, wp ) / ( REAL( nyear_len(1), wp ) * rday ) + 0.5 &
482	& + REAL( it_offset, wp ) / ( REAL( nyear_len(1), wp ) * rday )
483	sdjf%nrec_a(1) = 1 + INT( ztmp ) - COUNT((/llbefore/))
484	! swap at the middle of the year
485	IF( llbefore ) THEN ; sdjf%nrec_a(2) = nsec1jan000 - (1 - INT(ztmp)) * NINT(0.5 * rday) * nyear_len(0) + &
486	& INT(ztmp) * NINT( 0.5 * rday) * nyear_len(1)
487	ELSE ; sdjf%nrec_a(2) = nsec1jan000 + (1 - INT(ztmp)) * NINT(0.5 * rday) * nyear_len(1) + &
488	& INT(ztmp) * INT(rday) * nyear_len(1) + INT(ztmp) * NINT( 0.5 * rday) * nyear_len(2)
489	ENDIF
490	ELSE ! no time interpolation
491	sdjf%nrec_a(1) = 1
492	sdjf%nrec_a(2) = NINT(rday) * nyear_len(1) + nsec1jan000 ! swap at the end of the year
493	sdjf%nrec_b(2) = nsec1jan000 ! beginning of the year (only for print)
494	ENDIF
495	!
496	! ! ============ !
497	ELSEIF( sdjf%nfreqh == -1 ) THEN ! monthly mean !
498	! ! ============ !
499	!
500	IF( sdjf%ln_tint ) THEN ! time interpolation, shift by 1/2 record
501	!
502	! INT( ztmp )
503	! /\|\
504	! 1 \| *----
505	! 0 \|----(
506	! \|----+----\|--> time
507	! 0 /\|\ 1 (nday/nmonth_len(nmonth))
508	! \|
509	! \|
510	! forcing record : nmonth
511	!
512	ztmp = REAL( nsec_month, wp ) / ( REAL( nmonth_len(nmonth), wp ) * rday ) + 0.5 &
513	& + REAL( it_offset, wp ) / ( REAL( nmonth_len(nmonth), wp ) * rday )
514	imth = nmonth + INT( ztmp ) - COUNT((/llbefore/))
515	IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nrec_a(1) = 1 + INT( ztmp ) - COUNT((/llbefore/))
516	ELSE ; sdjf%nrec_a(1) = imth
517	ENDIF
518	sdjf%nrec_a(2) = nmonth_half( imth ) + nsec1jan000 ! swap at the middle of the month
519	ELSE ! no time interpolation
520	IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nrec_a(1) = 1
521	ELSE ; sdjf%nrec_a(1) = nmonth
522	ENDIF
523	sdjf%nrec_a(2) = nmonth_end(nmonth ) + nsec1jan000 ! swap at the end of the month
524	sdjf%nrec_b(2) = nmonth_end(nmonth-1) + nsec1jan000 ! beginning of the month (only for print)
525	ENDIF
526	!
527	! ! ================================ !
528	ELSE ! higher frequency mean (in hours)
529	! ! ================================ !
530	!
531	ifreq_sec = NINT( sdjf%nfreqh * 3600 ) ! frequency mean (in seconds)
532	IF( sdjf%cltype(1:4) == 'week' ) isec_week = ksec_week( sdjf%cltype(6:8) ) ! since the first day of the current week
533	! number of second since the beginning of the file
534	IF( sdjf%cltype == 'monthly' ) THEN ; ztmp = REAL(nsec_month,wp) ! since the first day of the current month
535	ELSEIF( sdjf%cltype(1:4) == 'week' ) THEN ; ztmp = REAL(isec_week ,wp) ! since the first day of the current week
536	ELSEIF( sdjf%cltype == 'daily' ) THEN ; ztmp = REAL(nsec_day ,wp) ! since 00h of the current day
537	ELSE ; ztmp = REAL(nsec_year ,wp) ! since 00h on Jan 1 of the current year
538	ENDIF
539	ztmp = ztmp + 0.5 * REAL(kn_fsbc - 1, wp) * rdttra(1) + REAL( it_offset, wp ) ! centrered in the middle of sbc time step
540	ztmp = ztmp + 0.01 * rdttra(1) ! avoid truncation error
541	IF( sdjf%ln_tint ) THEN ! time interpolation, shift by 1/2 record
542	!
543	! INT( ztmp/ifreq_sec + 0.5 )
544	! /\|\
545	! 2 \| *-----(
546	! 1 \| *-----(
547	! 0 \|--(
548	! \|--+--\|--+--\|--+--\|--> time
549	! 0 /\|\ 1 /\|\ 2 /\|\ 3 (ztmp/ifreq_sec)
550	! \| \| \|
551	! \| \| \|
552	! forcing record : 1 2 3
553	!
554	ztmp= ztmp / REAL(ifreq_sec, wp) + 0.5
555	ELSE ! no time interpolation
556	!
557	! INT( ztmp/ifreq_sec )
558	! /\|\
559	! 2 \| *-----(
560	! 1 \| *-----(
561	! 0 \|-----(
562	! \|--+--\|--+--\|--+--\|--> time
563	! 0 /\|\ 1 /\|\ 2 /\|\ 3 (ztmp/ifreq_sec)
564	! \| \| \|
565	! \| \| \|
566	! forcing record : 1 2 3
567	!
568	ztmp= ztmp / REAL(ifreq_sec, wp)
569	ENDIF
570	sdjf%nrec_a(1) = 1 + INT( ztmp ) - COUNT((/llbefore/)) ! record number to be read
571
572	iendrec = ifreq_sec * sdjf%nrec_a(1) + nsec1jan000 ! end of this record (in second)
573	! add the number of seconds between 00h Jan 1 and the end of previous month/week/day (ok if nmonth=1)
574	IF( sdjf%cltype == 'monthly' ) iendrec = iendrec + NINT(rday) * SUM(nmonth_len(1:nmonth -1))
575	IF( sdjf%cltype(1:4) == 'week' ) iendrec = iendrec + ( nsec_year - isec_week )
576	IF( sdjf%cltype == 'daily' ) iendrec = iendrec + NINT(rday) * ( nday_year - 1 )
577	IF( sdjf%ln_tint ) THEN
578	sdjf%nrec_a(2) = iendrec - ifreq_sec / 2 ! swap at the middle of the record
579	ELSE
580	sdjf%nrec_a(2) = iendrec ! swap at the end of the record
581	sdjf%nrec_b(2) = iendrec - ifreq_sec ! beginning of the record (only for print)
582	ENDIF
583	!
584	ENDIF
585	!
586	END SUBROUTINE fld_rec
587
588
589	SUBROUTINE fld_get( sdjf, map )
590	!!---------------------------------------------------------------------
591	!! * ROUTINE fld_get *
592	!!
593	!! ** Purpose : read the data
594	!!----------------------------------------------------------------------
595	TYPE(FLD), INTENT(inout) :: sdjf ! input field related variables
596	TYPE(MAP_POINTER),INTENT(in) :: map ! global-to-local mapping indices
597	!!
598	INTEGER :: ipk ! number of vertical levels of sdjf%fdta ( 2D: ipk=1 ; 3D: ipk=jpk )
599	INTEGER :: iw ! index into wgts array
600	INTEGER :: ipdom ! index of the domain
601	INTEGER :: idvar ! variable ID
602	INTEGER :: idmspc ! number of spatial dimensions
603	LOGICAL :: lmoor ! C1D case: point data
604	!!---------------------------------------------------------------------
605	!
606	ipk = SIZE( sdjf%fnow, 3 )
607	!
608	IF( ASSOCIATED(map%ptr) ) THEN
609	IF( sdjf%ln_tint ) THEN ; CALL fld_map( sdjf%num, sdjf%clvar, sdjf%fdta(:,:,:,2), sdjf%nrec_a(1), map )
610	ELSE ; CALL fld_map( sdjf%num, sdjf%clvar, sdjf%fnow(:,:,: ), sdjf%nrec_a(1), map )
611	ENDIF
612	ELSE IF( LEN(TRIM(sdjf%wgtname)) > 0 ) THEN
613	CALL wgt_list( sdjf, iw )
614	IF( sdjf%ln_tint ) THEN ; CALL fld_interp( sdjf%num, sdjf%clvar, iw , ipk , sdjf%fdta(:,:,:,2), &
615	& sdjf%nrec_a(1), sdjf%lsmname )
616	ELSE ; CALL fld_interp( sdjf%num, sdjf%clvar, iw , ipk , sdjf%fnow(:,:,: ), &
617	& sdjf%nrec_a(1), sdjf%lsmname )
618	ENDIF
619	ELSE
620	IF( SIZE(sdjf%fnow, 1) == jpi ) THEN ; ipdom = jpdom_data
621	ELSE ; ipdom = jpdom_unknown
622	ENDIF
623	! C1D case: If product of spatial dimensions == ipk, then x,y are of
624	! size 1 (point/mooring data): this must be read onto the central grid point
625	idvar = iom_varid( sdjf%num, sdjf%clvar )
626	idmspc = iom_file( sdjf%num )%ndims( idvar )
627	IF( iom_file( sdjf%num )%luld( idvar ) ) idmspc = idmspc - 1
628	lmoor = (idmspc == 0 .OR. PRODUCT( iom_file( sdjf%num )%dimsz( 1:MAX(idmspc,1) ,idvar ) ) == ipk)
629	!
630	SELECT CASE( ipk )
631	CASE(1)
632	IF( lk_c1d .AND. lmoor ) THEN
633	IF( sdjf%ln_tint ) THEN
634	CALL iom_get( sdjf%num, sdjf%clvar, sdjf%fdta(2,2,1,2), sdjf%nrec_a(1) )
635	CALL lbc_lnk( sdjf%fdta(:,:,1,2),'Z',1. )
636	ELSE
637	CALL iom_get( sdjf%num, sdjf%clvar, sdjf%fnow(2,2,1 ), sdjf%nrec_a(1) )
638	CALL lbc_lnk( sdjf%fnow(:,:,1 ),'Z',1. )
639	ENDIF
640	ELSE
641	IF( sdjf%ln_tint ) THEN ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fdta(:,:,1,2), sdjf%nrec_a(1) )
642	ELSE ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fnow(:,:,1 ), sdjf%nrec_a(1) )
643	ENDIF
644	ENDIF
645	CASE DEFAULT
646	IF (lk_c1d .AND. lmoor ) THEN
647	IF( sdjf%ln_tint ) THEN
648	CALL iom_get( sdjf%num, jpdom_unknown, sdjf%clvar, sdjf%fdta(2,2,:,2), sdjf%nrec_a(1) )
649	CALL lbc_lnk( sdjf%fdta(:,:,:,2),'Z',1. )
650	ELSE
651	CALL iom_get( sdjf%num, jpdom_unknown, sdjf%clvar, sdjf%fnow(2,2,: ), sdjf%nrec_a(1) )
652	CALL lbc_lnk( sdjf%fnow(:,:,: ),'Z',1. )
653	ENDIF
654	ELSE
655	IF( sdjf%ln_tint ) THEN ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fdta(:,:,:,2), sdjf%nrec_a(1) )
656	ELSE ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fnow(:,:,: ), sdjf%nrec_a(1) )
657	ENDIF
658	ENDIF
659	END SELECT
660	ENDIF
661	!
662	sdjf%rotn(2) = .false. ! vector not yet rotated
663
664	END SUBROUTINE fld_get
665
666	SUBROUTINE fld_map( num, clvar, dta, nrec, map )
667	!!---------------------------------------------------------------------
668	!! * ROUTINE fld_map *
669	!!
670	!! ** Purpose : read global data from file and map onto local data
671	!! using a general mapping (for open boundaries)
672	!!----------------------------------------------------------------------
673	#if defined key_bdy
674	USE bdy_oce, ONLY: dta_global, dta_global2 ! workspace to read in global data arrays
675	#endif
676	INTEGER , INTENT(in ) :: num ! stream number
677	CHARACTER(LEN=*) , INTENT(in ) :: clvar ! variable name
678	REAL(wp), DIMENSION(:,:,:), INTENT(out) :: dta ! output field on model grid (2 dimensional)
679	INTEGER , INTENT(in ) :: nrec ! record number to read (ie time slice)
680	TYPE(MAP_POINTER) , INTENT(in ) :: map ! global-to-local mapping indices
681	!!
682	INTEGER :: ipi ! length of boundary data on local process
683	INTEGER :: ipj ! length of dummy dimension ( = 1 )
684	INTEGER :: ipk ! number of vertical levels of dta ( 2D: ipk=1 ; 3D: ipk=jpk )
685	INTEGER :: ilendta ! length of data in file
686	INTEGER :: idvar ! variable ID
687	INTEGER :: ib, ik, ji, jj ! loop counters
688	INTEGER :: ierr
689	REAL(wp), POINTER, DIMENSION(:,:,:) :: dta_read ! work space for global data
690	!!---------------------------------------------------------------------
691
692	ipi = SIZE( dta, 1 )
693	ipj = 1
694	ipk = SIZE( dta, 3 )
695
696	idvar = iom_varid( num, clvar )
697	ilendta = iom_file(num)%dimsz(1,idvar)
698
699	#if defined key_bdy
700	ipj = iom_file(num)%dimsz(2,idvar)
701	IF ( map%ll_unstruc) THEN ! unstructured open boundary data file
702	dta_read => dta_global
703	ELSE ! structured open boundary data file
704	dta_read => dta_global2
705	ENDIF
706	#endif
707
708	IF(lwp) WRITE(numout,*) 'Dim size for ',TRIM(clvar),' is ', ilendta
709	IF(lwp) WRITE(numout,*) 'Number of levels for ',TRIM(clvar),' is ', ipk
710
711	SELECT CASE( ipk )
712	CASE(1) ; CALL iom_get ( num, jpdom_unknown, clvar, dta_read(1:ilendta,1:ipj,1 ), nrec )
713	CASE DEFAULT ; CALL iom_get ( num, jpdom_unknown, clvar, dta_read(1:ilendta,1:ipj,1:ipk), nrec )
714	END SELECT
715	!
716	IF ( map%ll_unstruc ) THEN ! unstructured open boundary data file
717	DO ib = 1, ipi
718	DO ik = 1, ipk
719	dta(ib,1,ik) = dta_read(map%ptr(ib),1,ik)
720	END DO
721	END DO
722	ELSE ! structured open boundary data file
723	DO ib = 1, ipi
724	jj=1+floor(REAL(map%ptr(ib)-1)/REAL(ilendta))
725	ji=map%ptr(ib)-(jj-1)*ilendta
726	DO ik = 1, ipk
727	dta(ib,1,ik) = dta_read(ji,jj,ik)
728	END DO
729	END DO
730	ENDIF
731
732	END SUBROUTINE fld_map
733
734
735	SUBROUTINE fld_rot( kt, sd )
736	!!---------------------------------------------------------------------
737	!! * ROUTINE fld_rot *
738	!!
739	!! ** Purpose : Vector fields may need to be rotated onto the local grid direction
740	!!----------------------------------------------------------------------
741	INTEGER , INTENT(in ) :: kt ! ocean time step
742	TYPE(FLD), INTENT(inout), DIMENSION(:) :: sd ! input field related variables
743	!!
744	INTEGER :: ju,jv,jk,jn ! loop indices
745	INTEGER :: imf ! size of the structure sd
746	INTEGER :: ill ! character length
747	INTEGER :: iv ! indice of V component
748	REAL(wp), POINTER, DIMENSION(:,:) :: utmp, vtmp ! temporary arrays for vector rotation
749	CHARACTER (LEN=100) :: clcomp ! dummy weight name
750	!!---------------------------------------------------------------------
751
752	CALL wrk_alloc( jpi,jpj, utmp, vtmp )
753
754	!! (sga: following code should be modified so that pairs arent searched for each time
755	!
756	imf = SIZE( sd )
757	DO ju = 1, imf
758	ill = LEN_TRIM( sd(ju)%vcomp )
759	DO jn = 2-COUNT((/sd(ju)%ln_tint/)), 2
760	IF( ill > 0 .AND. .NOT. sd(ju)%rotn(jn) ) THEN ! find vector rotations required
761	IF( sd(ju)%vcomp(1:1) == 'U' ) THEN ! east-west component has symbolic name starting with 'U'
762	! look for the north-south component which has same symbolic name but with 'U' replaced with 'V'
763	clcomp = 'V' // sd(ju)%vcomp(2:ill) ! works even if ill == 1
764	iv = -1
765	DO jv = 1, imf
766	IF( TRIM(sd(jv)%vcomp) == TRIM(clcomp) ) iv = jv
767	END DO
768	IF( iv > 0 ) THEN ! fields ju and iv are two components which need to be rotated together
769	DO jk = 1, SIZE( sd(ju)%fnow, 3 )
770	IF( sd(ju)%ln_tint )THEN
771	CALL rot_rep( sd(ju)%fdta(:,:,jk,jn), sd(iv)%fdta(:,:,jk,jn), 'T', 'en->i', utmp(:,:) )
772	CALL rot_rep( sd(ju)%fdta(:,:,jk,jn), sd(iv)%fdta(:,:,jk,jn), 'T', 'en->j', vtmp(:,:) )
773	sd(ju)%fdta(:,:,jk,jn) = utmp(:,:) ; sd(iv)%fdta(:,:,jk,jn) = vtmp(:,:)
774	ELSE
775	CALL rot_rep( sd(ju)%fnow(:,:,jk ), sd(iv)%fnow(:,:,jk ), 'T', 'en->i', utmp(:,:) )
776	CALL rot_rep( sd(ju)%fnow(:,:,jk ), sd(iv)%fnow(:,:,jk ), 'T', 'en->j', vtmp(:,:) )
777	sd(ju)%fnow(:,:,jk ) = utmp(:,:) ; sd(iv)%fnow(:,:,jk ) = vtmp(:,:)
778	ENDIF
779	END DO
780	sd(ju)%rotn(jn) = .TRUE. ! vector was rotated
781	IF( lwp .AND. kt == nit000 ) WRITE(numout,*) &
782	& 'fld_read: vector pair ('//TRIM(sd(ju)%clvar)//', '//TRIM(sd(iv)%clvar)//') rotated on to model grid'
783	ENDIF
784	ENDIF
785	ENDIF
786	END DO
787	END DO
788	!
789	CALL wrk_dealloc( jpi,jpj, utmp, vtmp )
790	!
791	END SUBROUTINE fld_rot
792
793
794	SUBROUTINE fld_clopn( sdjf, kyear, kmonth, kday, ldstop )
795	!!---------------------------------------------------------------------
796	!! * ROUTINE fld_clopn *
797	!!
798	!! ** Purpose : update the file name and open the file
799	!!----------------------------------------------------------------------
800	TYPE(FLD) , INTENT(inout) :: sdjf ! input field related variables
801	INTEGER, OPTIONAL, INTENT(in ) :: kyear ! year value
802	INTEGER, OPTIONAL, INTENT(in ) :: kmonth ! month value
803	INTEGER, OPTIONAL, INTENT(in ) :: kday ! day value
804	LOGICAL, OPTIONAL, INTENT(in ) :: ldstop ! stop if open to read a non-existing file (default = .TRUE.)
805	!!
806	LOGICAL :: llprevyr ! are we reading previous year file?
807	LOGICAL :: llprevmth ! are we reading previous month file?
808	INTEGER :: iyear, imonth, iday ! first day of the current file in yyyy mm dd
809	INTEGER :: isec_week ! number of seconds since start of the weekly file
810	INTEGER :: indexyr ! year undex (O/1/2: previous/current/next)
811	INTEGER :: iyear_len, imonth_len ! length (days) of iyear and imonth !
812	CHARACTER(len = 256):: clname ! temporary file name
813	!!----------------------------------------------------------------------
814	IF( PRESENT(kyear) ) THEN ! use given values
815	iyear = kyear
816	imonth = kmonth
817	iday = kday
818	IF ( sdjf%cltype(1:4) == 'week' ) THEN ! find the day of the beginning of the week
819	isec_week = ksec_week( sdjf%cltype(6:8) )- (86400 * 8 )
820	llprevmth = isec_week > nsec_month ! longer time since beginning of the week than the month
821	llprevyr = llprevmth .AND. nmonth == 1
822	iyear = nyear - COUNT((/llprevyr /))
823	imonth = nmonth - COUNT((/llprevmth/)) + 12 * COUNT((/llprevyr /))
824	iday = nday + nmonth_len(nmonth-1) * COUNT((/llprevmth/)) - isec_week / NINT(rday)
825	ENDIF
826	ELSE ! use current day values
827	IF ( sdjf%cltype(1:4) == 'week' ) THEN ! find the day of the beginning of the week
828	isec_week = ksec_week( sdjf%cltype(6:8) ) ! second since the beginning of the week
829	llprevmth = isec_week > nsec_month ! longer time since beginning of the week than the month
830	llprevyr = llprevmth .AND. nmonth == 1
831	ELSE
832	isec_week = 0
833	llprevmth = .FALSE.
834	llprevyr = .FALSE.
835	ENDIF
836	iyear = nyear - COUNT((/llprevyr /))
837	imonth = nmonth - COUNT((/llprevmth/)) + 12 * COUNT((/llprevyr /))
838	iday = nday + nmonth_len(nmonth-1) * COUNT((/llprevmth/)) - isec_week / NINT(rday)
839	ENDIF
840
841	! build the new filename if not climatological data
842	clname=TRIM(sdjf%clrootname)
843	!
844	! note that sdjf%ln_clim is is only acting on the presence of the year in the file name
845	IF( .NOT. sdjf%ln_clim ) THEN
846	WRITE(clname, '(a,"_y",i4.4)' ) TRIM( sdjf%clrootname ), iyear ! add year
847	IF( sdjf%cltype /= 'yearly' ) WRITE(clname, '(a,"m" ,i2.2)' ) TRIM( clname ), imonth ! add month
848	ELSE
849	! build the new filename if climatological data
850	IF( sdjf%cltype /= 'yearly' ) WRITE(clname, '(a,"_m",i2.2)' ) TRIM( sdjf%clrootname ), imonth ! add month
851	ENDIF
852	IF( sdjf%cltype == 'daily' .OR. sdjf%cltype(1:4) == 'week' ) &
853	& WRITE(clname, '(a,"d" ,i2.2)' ) TRIM( clname ), iday ! add day
854	!
855	IF( TRIM(clname) /= TRIM(sdjf%clname) .OR. sdjf%num == 0 ) THEN ! new file to be open
856
857	sdjf%clname = TRIM(clname)
858	IF( sdjf%num /= 0 ) CALL iom_close( sdjf%num ) ! close file if already open
859	CALL iom_open( sdjf%clname, sdjf%num, ldstop = ldstop, ldiof = LEN(TRIM(sdjf%wgtname)) > 0 )
860
861	! find the last record to be read -> update sdjf%nreclast
862	indexyr = iyear - nyear + 1
863	iyear_len = nyear_len( indexyr )
864	SELECT CASE ( indexyr )
865	CASE ( 0 ) ; imonth_len = 31 ! previous year -> imonth = 12
866	CASE ( 1 ) ; imonth_len = nmonth_len(imonth)
867	CASE ( 2 ) ; imonth_len = 31 ! next year -> imonth = 1
868	END SELECT
869
870	! last record to be read in the current file
871	IF ( sdjf%nfreqh == -12 ) THEN ; sdjf%nreclast = 1 ! yearly mean
872	ELSEIF( sdjf%nfreqh == -1 ) THEN ! monthly mean
873	IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nreclast = 1
874	ELSE ; sdjf%nreclast = 12
875	ENDIF
876	ELSE ! higher frequency mean (in hours)
877	IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nreclast = NINT( 24 * imonth_len / sdjf%nfreqh )
878	ELSEIF( sdjf%cltype(1:4) == 'week' ) THEN ; sdjf%nreclast = NINT( 24 * 7 / sdjf%nfreqh )
879	ELSEIF( sdjf%cltype == 'daily' ) THEN ; sdjf%nreclast = NINT( 24 / sdjf%nfreqh )
880	ELSE ; sdjf%nreclast = NINT( 24 * iyear_len / sdjf%nfreqh )
881	ENDIF
882	ENDIF
883
884	ENDIF
885	!
886	END SUBROUTINE fld_clopn
887
888
889	SUBROUTINE fld_fill( sdf, sdf_n, cdir, cdcaller, cdtitle, cdnam )
890	!!---------------------------------------------------------------------
891	!! * ROUTINE fld_fill *
892	!!
893	!! ** Purpose : fill sdf with sdf_n and control print
894	!!----------------------------------------------------------------------
895	TYPE(FLD) , DIMENSION(:), INTENT(inout) :: sdf ! structure of input fields (file informations, fields read)
896	TYPE(FLD_N), DIMENSION(:), INTENT(in ) :: sdf_n ! array of namelist information structures
897	CHARACTER(len=*) , INTENT(in ) :: cdir ! Root directory for location of flx files
898	CHARACTER(len=*) , INTENT(in ) :: cdcaller !
899	CHARACTER(len=*) , INTENT(in ) :: cdtitle !
900	CHARACTER(len=*) , INTENT(in ) :: cdnam !
901	!
902	INTEGER :: jf ! dummy indices
903	!!---------------------------------------------------------------------
904
905	DO jf = 1, SIZE(sdf)
906	sdf(jf)%clrootname = TRIM( cdir )//TRIM( sdf_n(jf)%clname )
907	sdf(jf)%clname = "not yet defined"
908	sdf(jf)%nfreqh = sdf_n(jf)%nfreqh
909	sdf(jf)%clvar = sdf_n(jf)%clvar
910	sdf(jf)%ln_tint = sdf_n(jf)%ln_tint
911	sdf(jf)%ln_clim = sdf_n(jf)%ln_clim
912	sdf(jf)%cltype = sdf_n(jf)%cltype
913	sdf(jf)%num = -1
914	sdf(jf)%wgtname = " "
915	IF( LEN( TRIM(sdf_n(jf)%wname) ) > 0 ) sdf(jf)%wgtname = TRIM( cdir )//TRIM( sdf_n(jf)%wname )
916	sdf(jf)%lsmname = " "
917	IF( LEN( TRIM(sdf_n(jf)%lname) ) > 0 ) sdf(jf)%lsmname = TRIM( cdir )//TRIM( sdf_n(jf)%lname )
918	sdf(jf)%vcomp = sdf_n(jf)%vcomp
919	sdf(jf)%rotn(:) = .TRUE. ! pretend to be rotated -> won't try to rotate data before the first call to fld_get
920	IF( sdf(jf)%cltype(1:4) == 'week' .AND. nn_leapy == 0 ) &
921	& CALL ctl_stop('fld_clopn: weekly file ('//TRIM(sdf(jf)%clrootname)//') needs nn_leapy = 1')
922	IF( sdf(jf)%cltype(1:4) == 'week' .AND. sdf(jf)%ln_clim ) &
923	& CALL ctl_stop('fld_clopn: weekly file ('//TRIM(sdf(jf)%clrootname)//') needs ln_clim = .FALSE.')
924	sdf(jf)%nreclast = -1 ! Set to non zero default value to avoid errors, is updated to meaningful value during fld_clopn
925	END DO
926
927	IF(lwp) THEN ! control print
928	WRITE(numout,*)
929	WRITE(numout,*) TRIM( cdcaller )//' : '//TRIM( cdtitle )
930	WRITE(numout,*) (/ ('~', jf = 1, LEN_TRIM( cdcaller ) ) /)
931	WRITE(numout,*) ' '//TRIM( cdnam )//' Namelist'
932	WRITE(numout,*) ' list of files and frequency (>0: in hours ; <0 in months)'
933	DO jf = 1, SIZE(sdf)
934	WRITE(numout,*) ' root filename: ' , TRIM( sdf(jf)%clrootname ), &
935	& ' variable name: ' , TRIM( sdf(jf)%clvar )
936	WRITE(numout,*) ' frequency: ' , sdf(jf)%nfreqh , &
937	& ' time interp: ' , sdf(jf)%ln_tint , &
938	& ' climatology: ' , sdf(jf)%ln_clim , &
939	& ' weights : ' , TRIM( sdf(jf)%wgtname ), &
940	& ' pairing : ' , TRIM( sdf(jf)%vcomp ), &
941	& ' data type: ' , sdf(jf)%cltype , &
942	& ' land/sea mask:' , TRIM( sdf(jf)%lsmname )
943	END DO
944	ENDIF
945
946	END SUBROUTINE fld_fill
947
948
949	SUBROUTINE wgt_list( sd, kwgt )
950	!!---------------------------------------------------------------------
951	!! * ROUTINE wgt_list *
952	!!
953	!! ** Purpose : search array of WGTs and find a weights file
954	!! entry, or return a new one adding it to the end
955	!! if it is a new entry, the weights data is read in and
956	!! restructured (fld_weight)
957	!!----------------------------------------------------------------------
958	TYPE( FLD ), INTENT(in ) :: sd ! field with name of weights file
959	INTEGER , INTENT(inout) :: kwgt ! index of weights
960	!!
961	INTEGER :: kw, nestid ! local integer
962	LOGICAL :: found ! local logical
963	!!----------------------------------------------------------------------
964	!
965	!! search down linked list
966	!! weights filename is either present or we hit the end of the list
967	found = .FALSE.
968
969	!! because agrif nest part of filenames are now added in iom_open
970	!! to distinguish between weights files on the different grids, need to track
971	!! nest number explicitly
972	nestid = 0
973	#if defined key_agrif
974	nestid = Agrif_Fixed()
975	#endif
976	DO kw = 1, nxt_wgt-1
977	IF( TRIM(ref_wgts(kw)%wgtname) == TRIM(sd%wgtname) .AND. &
978	ref_wgts(kw)%nestid == nestid) THEN
979	kwgt = kw
980	found = .TRUE.
981	EXIT
982	ENDIF
983	END DO
984	IF( .NOT.found ) THEN
985	kwgt = nxt_wgt
986	CALL fld_weight( sd )
987	ENDIF
988	!
989	END SUBROUTINE wgt_list
990
991
992	SUBROUTINE wgt_print( )
993	!!---------------------------------------------------------------------
994	!! * ROUTINE wgt_print *
995	!!
996	!! ** Purpose : print the list of known weights
997	!!----------------------------------------------------------------------
998	INTEGER :: kw !
999	!!----------------------------------------------------------------------
1000	!
1001	DO kw = 1, nxt_wgt-1
1002	WRITE(numout,*) 'weight file: ',TRIM(ref_wgts(kw)%wgtname)
1003	WRITE(numout,*) ' ddims: ',ref_wgts(kw)%ddims(1),ref_wgts(kw)%ddims(2)
1004	WRITE(numout,*) ' numwgt: ',ref_wgts(kw)%numwgt
1005	WRITE(numout,*) ' jpiwgt: ',ref_wgts(kw)%jpiwgt
1006	WRITE(numout,*) ' jpjwgt: ',ref_wgts(kw)%jpjwgt
1007	WRITE(numout,*) ' botleft: ',ref_wgts(kw)%botleft
1008	WRITE(numout,*) ' topright: ',ref_wgts(kw)%topright
1009	IF( ref_wgts(kw)%cyclic ) THEN
1010	WRITE(numout,*) ' cyclical'
1011	IF( ref_wgts(kw)%overlap > 0 ) WRITE(numout,*) ' with overlap of ', ref_wgts(kw)%overlap
1012	ELSE
1013	WRITE(numout,*) ' not cyclical'
1014	ENDIF
1015	IF( ASSOCIATED(ref_wgts(kw)%data_wgt) ) WRITE(numout,*) ' allocated'
1016	END DO
1017	!
1018	END SUBROUTINE wgt_print
1019
1020
1021	SUBROUTINE fld_weight( sd )
1022	!!---------------------------------------------------------------------
1023	!! * ROUTINE fld_weight *
1024	!!
1025	!! ** Purpose : create a new WGT structure and fill in data from
1026	!! file, restructuring as required
1027	!!----------------------------------------------------------------------
1028	TYPE( FLD ), INTENT(in) :: sd ! field with name of weights file
1029	!!
1030	INTEGER :: jn ! dummy loop indices
1031	INTEGER :: inum ! temporary logical unit
1032	INTEGER :: id ! temporary variable id
1033	INTEGER :: ipk ! temporary vertical dimension
1034	CHARACTER (len=5) :: aname
1035	INTEGER , DIMENSION(:), ALLOCATABLE :: ddims
1036	INTEGER , POINTER, DIMENSION(:,:) :: data_src
1037	REAL(wp), POINTER, DIMENSION(:,:) :: data_tmp
1038	LOGICAL :: cyclical
1039	INTEGER :: zwrap ! local integer
1040	!!----------------------------------------------------------------------
1041	!
1042	CALL wrk_alloc( jpi,jpj, data_src ) ! integer
1043	CALL wrk_alloc( jpi,jpj, data_tmp )
1044	!
1045	IF( nxt_wgt > tot_wgts ) THEN
1046	CALL ctl_stop("fld_weight: weights array size exceeded, increase tot_wgts")
1047	ENDIF
1048	!
1049	!! new weights file entry, add in extra information
1050	!! a weights file represents a 2D grid of a certain shape, so we assume that the current
1051	!! input data file is representative of all other files to be opened and processed with the
1052	!! current weights file
1053
1054	!! open input data file (non-model grid)
1055	CALL iom_open( sd%clname, inum, ldiof = LEN(TRIM(sd%wgtname)) > 0 )
1056
1057	!! get dimensions
1058	IF ( SIZE(sd%fnow, 3) > 1 ) THEN
1059	ALLOCATE( ddims(4) )
1060	ELSE
1061	ALLOCATE( ddims(3) )
1062	ENDIF
1063	id = iom_varid( inum, sd%clvar, ddims )
1064
1065	!! close it
1066	CALL iom_close( inum )
1067
1068	!! now open the weights file
1069
1070	CALL iom_open ( sd%wgtname, inum ) ! interpolation weights
1071	IF ( inum > 0 ) THEN
1072
1073	!! determine whether we have an east-west cyclic grid
1074	!! from global attribute called "ew_wrap" in the weights file
1075	!! note that if not found, iom_getatt returns -999 and cyclic with no overlap is assumed
1076	!! since this is the most common forcing configuration
1077
1078	CALL iom_getatt(inum, 'ew_wrap', zwrap)
1079	IF( zwrap >= 0 ) THEN
1080	cyclical = .TRUE.
1081	ELSE IF( zwrap == -999 ) THEN
1082	cyclical = .TRUE.
1083	zwrap = 0
1084	ELSE
1085	cyclical = .FALSE.
1086	ENDIF
1087
1088	ref_wgts(nxt_wgt)%ddims(1) = ddims(1)
1089	ref_wgts(nxt_wgt)%ddims(2) = ddims(2)
1090	ref_wgts(nxt_wgt)%wgtname = sd%wgtname
1091	ref_wgts(nxt_wgt)%overlap = zwrap
1092	ref_wgts(nxt_wgt)%cyclic = cyclical
1093	ref_wgts(nxt_wgt)%nestid = 0
1094	#if defined key_agrif
1095	ref_wgts(nxt_wgt)%nestid = Agrif_Fixed()
1096	#endif
1097	!! weights file is stored as a set of weights (wgt01->wgt04 or wgt01->wgt16)
1098	!! for each weight wgtNN there is an integer array srcNN which gives the point in
1099	!! the input data grid which is to be multiplied by the weight
1100	!! they are both arrays on the model grid so the result of the multiplication is
1101	!! added into an output array on the model grid as a running sum
1102
1103	!! two possible cases: bilinear (4 weights) or bicubic (16 weights)
1104	id = iom_varid(inum, 'src05', ldstop=.FALSE.)
1105	IF( id <= 0) THEN
1106	ref_wgts(nxt_wgt)%numwgt = 4
1107	ELSE
1108	ref_wgts(nxt_wgt)%numwgt = 16
1109	ENDIF
1110
1111	ALLOCATE( ref_wgts(nxt_wgt)%data_jpi(jpi,jpj,4) )
1112	ALLOCATE( ref_wgts(nxt_wgt)%data_jpj(jpi,jpj,4) )
1113	ALLOCATE( ref_wgts(nxt_wgt)%data_wgt(jpi,jpj,ref_wgts(nxt_wgt)%numwgt) )
1114
1115	DO jn = 1,4
1116	aname = ' '
1117	WRITE(aname,'(a3,i2.2)') 'src',jn
1118	data_tmp(:,:) = 0
1119	CALL iom_get ( inum, jpdom_data, aname, data_tmp(:,:) )
1120	data_src(:,:) = INT(data_tmp(:,:))
1121	ref_wgts(nxt_wgt)%data_jpj(:,:,jn) = 1 + (data_src(:,:)-1) / ref_wgts(nxt_wgt)%ddims(1)
1122	ref_wgts(nxt_wgt)%data_jpi(:,:,jn) = data_src(:,:) - ref_wgts(nxt_wgt)%ddims(1)*(ref_wgts(nxt_wgt)%data_jpj(:,:,jn)-1)
1123	END DO
1124
1125	DO jn = 1, ref_wgts(nxt_wgt)%numwgt
1126	aname = ' '
1127	WRITE(aname,'(a3,i2.2)') 'wgt',jn
1128	ref_wgts(nxt_wgt)%data_wgt(:,:,jn) = 0.0
1129	CALL iom_get ( inum, jpdom_data, aname, ref_wgts(nxt_wgt)%data_wgt(:,:,jn) )
1130	END DO
1131	CALL iom_close (inum)
1132
1133	! find min and max indices in grid
1134	ref_wgts(nxt_wgt)%botleft(1) = MINVAL(ref_wgts(nxt_wgt)%data_jpi(:,:,:))
1135	ref_wgts(nxt_wgt)%botleft(2) = MINVAL(ref_wgts(nxt_wgt)%data_jpj(:,:,:))
1136	ref_wgts(nxt_wgt)%topright(1) = MAXVAL(ref_wgts(nxt_wgt)%data_jpi(:,:,:))
1137	ref_wgts(nxt_wgt)%topright(2) = MAXVAL(ref_wgts(nxt_wgt)%data_jpj(:,:,:))
1138
1139	! and therefore dimensions of the input box
1140	ref_wgts(nxt_wgt)%jpiwgt = ref_wgts(nxt_wgt)%topright(1) - ref_wgts(nxt_wgt)%botleft(1) + 1
1141	ref_wgts(nxt_wgt)%jpjwgt = ref_wgts(nxt_wgt)%topright(2) - ref_wgts(nxt_wgt)%botleft(2) + 1
1142
1143	! shift indexing of source grid
1144	ref_wgts(nxt_wgt)%data_jpi(:,:,:) = ref_wgts(nxt_wgt)%data_jpi(:,:,:) - ref_wgts(nxt_wgt)%botleft(1) + 1
1145	ref_wgts(nxt_wgt)%data_jpj(:,:,:) = ref_wgts(nxt_wgt)%data_jpj(:,:,:) - ref_wgts(nxt_wgt)%botleft(2) + 1
1146
1147	! create input grid, give it a halo to allow gradient calculations
1148	! SA: +3 stencil is a patch to avoid out-of-bound computation in some configuration.
1149	! a more robust solution will be given in next release
1150	ipk = SIZE(sd%fnow, 3)
1151	ALLOCATE( ref_wgts(nxt_wgt)%fly_dta(ref_wgts(nxt_wgt)%jpiwgt+3, ref_wgts(nxt_wgt)%jpjwgt+3 ,ipk) )
1152	IF( ref_wgts(nxt_wgt)%cyclic ) ALLOCATE( ref_wgts(nxt_wgt)%col(1,ref_wgts(nxt_wgt)%jpjwgt+3,ipk) )
1153
1154	nxt_wgt = nxt_wgt + 1
1155
1156	ELSE
1157	CALL ctl_stop( ' fld_weight : unable to read the file ' )
1158	ENDIF
1159
1160	DEALLOCATE (ddims )
1161
1162	CALL wrk_dealloc( jpi,jpj, data_src ) ! integer
1163	CALL wrk_dealloc( jpi,jpj, data_tmp )
1164	!
1165	END SUBROUTINE fld_weight
1166
1167
1168	SUBROUTINE apply_seaoverland(clmaskfile,zfieldo,jpi1_lsm,jpi2_lsm,jpj1_lsm, &
1169	& jpj2_lsm,itmpi,itmpj,itmpz,rec1_lsm,recn_lsm)
1170	!!---------------------------------------------------------------------
1171	!! * ROUTINE apply_seaoverland *
1172	!!
1173	!! ** Purpose : avoid spurious fluxes in coastal or near-coastal areas
1174	!! due to the wrong usage of "land" values from the coarse
1175	!! atmospheric model when spatial interpolation is required
1176	!! D. Delrosso INGV
1177	!!----------------------------------------------------------------------
1178	INTEGER :: inum,jni,jnj,jnz,jc ! temporary indices
1179	INTEGER, INTENT(in) :: itmpi,itmpj,itmpz ! lengths
1180	INTEGER, INTENT(in) :: jpi1_lsm,jpi2_lsm,jpj1_lsm,jpj2_lsm ! temporary indices
1181	INTEGER, DIMENSION(3), INTENT(in) :: rec1_lsm,recn_lsm ! temporary arrays for start and length
1182	REAL(wp),DIMENSION (:,:,:),INTENT(inout) :: zfieldo ! input/output array for seaoverland application
1183	REAL(wp),DIMENSION (:,:,:),ALLOCATABLE :: zslmec1 ! temporary array for land point detection
1184	REAL(wp),DIMENSION (:,:), ALLOCATABLE :: zfieldn ! array of forcing field with undeff for land points
1185	REAL(wp),DIMENSION (:,:), ALLOCATABLE :: zfield ! array of forcing field
1186	CHARACTER (len=100), INTENT(in) :: clmaskfile ! land/sea mask file name
1187	!!---------------------------------------------------------------------
1188	ALLOCATE ( zslmec1(itmpi,itmpj,itmpz) )
1189	ALLOCATE ( zfieldn(itmpi,itmpj) )
1190	ALLOCATE ( zfield(itmpi,itmpj) )
1191
1192	! Retrieve the land sea mask data
1193	CALL iom_open( clmaskfile, inum )
1194	SELECT CASE( SIZE(zfieldo(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:),3) )
1195	CASE(1)
1196	CALL iom_get( inum, jpdom_unknown, 'LSM', zslmec1(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,1), 1, rec1_lsm, recn_lsm)
1197	CASE DEFAULT
1198	CALL iom_get( inum, jpdom_unknown, 'LSM', zslmec1(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:), 1, rec1_lsm, recn_lsm)
1199	END SELECT
1200	CALL iom_close( inum )
1201
1202	DO jnz=1,rec1_lsm(3) !! Loop over k dimension
1203
1204	DO jni=1,itmpi !! copy the original field into a tmp array
1205	DO jnj=1,itmpj !! substituting undeff over land points
1206	zfieldn(jni,jnj) = zfieldo(jni,jnj,jnz)
1207	IF ( zslmec1(jni,jnj,jnz) == 1. ) THEN
1208	zfieldn(jni,jnj) = undeff_lsm
1209	ENDIF
1210	END DO
1211	END DO
1212
1213	CALL seaoverland(zfieldn,itmpi,itmpj,zfield)
1214	DO jc=1,nn_lsm
1215	CALL seaoverland(zfield,itmpi,itmpj,zfield)
1216	END DO
1217
1218	! Check for Undeff and substitute original values
1219	IF(ANY(zfield==undeff_lsm)) THEN
1220	DO jni=1,itmpi
1221	DO jnj=1,itmpj
1222	IF (zfield(jni,jnj)==undeff_lsm) THEN
1223	zfield(jni,jnj) = zfieldo(jni,jnj,jnz)
1224	ENDIF
1225	ENDDO
1226	ENDDO
1227	ENDIF
1228
1229	zfieldo(:,:,jnz)=zfield(:,:)
1230
1231	END DO !! End Loop over k dimension
1232
1233	DEALLOCATE ( zslmec1 )
1234	DEALLOCATE ( zfieldn )
1235	DEALLOCATE ( zfield )
1236
1237	END SUBROUTINE apply_seaoverland
1238
1239
1240	SUBROUTINE seaoverland(zfieldn,ileni,ilenj,zfield)
1241	!!---------------------------------------------------------------------
1242	!! * ROUTINE seaoverland *
1243	!!
1244	!! ** Purpose : create shifted matrices for seaoverland application
1245	!! D. Delrosso INGV
1246	!!----------------------------------------------------------------------
1247	INTEGER,INTENT(in) :: ileni,ilenj ! lengths
1248	REAL,DIMENSION (ileni,ilenj),INTENT(in) :: zfieldn ! array of forcing field with undeff for land points
1249	REAL,DIMENSION (ileni,ilenj),INTENT(out) :: zfield ! array of forcing field
1250	REAL,DIMENSION (ileni,ilenj) :: zmat1,zmat2,zmat3,zmat4 ! temporary arrays for seaoverland application
1251	REAL,DIMENSION (ileni,ilenj) :: zmat5,zmat6,zmat7,zmat8 ! temporary arrays for seaoverland application
1252	REAL,DIMENSION (ileni,ilenj) :: zlsm2d ! temporary arrays for seaoverland application
1253	REAL,DIMENSION (ileni,ilenj,8) :: zlsm3d ! temporary arrays for seaoverland application
1254	LOGICAL,DIMENSION (ileni,ilenj,8) :: ll_msknan3d ! logical mask for undeff detection
1255	LOGICAL,DIMENSION (ileni,ilenj) :: ll_msknan2d ! logical mask for undeff detection
1256	!!----------------------------------------------------------------------
1257	zmat8 = eoshift(zfieldn , SHIFT=-1, BOUNDARY = (/zfieldn(:,1)/) ,DIM=2)
1258	zmat1 = eoshift(zmat8 , SHIFT=-1, BOUNDARY = (/zmat8(1,:)/) ,DIM=1)
1259	zmat2 = eoshift(zfieldn , SHIFT=-1, BOUNDARY = (/zfieldn(1,:)/) ,DIM=1)
1260	zmat4 = eoshift(zfieldn , SHIFT= 1, BOUNDARY = (/zfieldn(:,ilenj)/),DIM=2)
1261	zmat3 = eoshift(zmat4 , SHIFT=-1, BOUNDARY = (/zmat4(1,:)/) ,DIM=1)
1262	zmat5 = eoshift(zmat4 , SHIFT= 1, BOUNDARY = (/zmat4(ileni,:)/) ,DIM=1)
1263	zmat6 = eoshift(zfieldn , SHIFT= 1, BOUNDARY = (/zfieldn(ileni,:)/),DIM=1)
1264	zmat7 = eoshift(zmat8 , SHIFT= 1, BOUNDARY = (/zmat8(ileni,:)/) ,DIM=1)
1265
1266	zlsm3d = RESHAPE( (/ zmat1, zmat2, zmat3, zmat4, zmat5, zmat6, zmat7, zmat8 /), (/ ileni, ilenj, 8 /))
1267	ll_msknan3d = .not.(zlsm3d==undeff_lsm)
1268	ll_msknan2d = .not.(zfieldn==undeff_lsm) ! FALSE where is Undeff (land)
1269	zlsm2d = (SUM ( zlsm3d, 3 , ll_msknan3d ) )/(MAX(1,(COUNT( ll_msknan3d , 3 )) ))
1270	WHERE ((COUNT( ll_msknan3d , 3 )) == 0.0_wp) zlsm2d = undeff_lsm
1271	zfield = MERGE (zfieldn,zlsm2d,ll_msknan2d)
1272	END SUBROUTINE seaoverland
1273
1274
1275	SUBROUTINE fld_interp( num, clvar, kw, kk, dta, &
1276	& nrec, lsmfile)
1277	!!---------------------------------------------------------------------
1278	!! * ROUTINE fld_interp *
1279	!!
1280	!! ** Purpose : apply weights to input gridded data to create data
1281	!! on model grid
1282	!!----------------------------------------------------------------------
1283	INTEGER , INTENT(in ) :: num ! stream number
1284	CHARACTER(LEN=*) , INTENT(in ) :: clvar ! variable name
1285	INTEGER , INTENT(in ) :: kw ! weights number
1286	INTEGER , INTENT(in ) :: kk ! vertical dimension of kk
1287	REAL(wp), DIMENSION(:,:,:), INTENT(inout) :: dta ! output field on model grid
1288	INTEGER , INTENT(in ) :: nrec ! record number to read (ie time slice)
1289	CHARACTER(LEN=*) , INTENT(in ) :: lsmfile ! land sea mask file name
1290	!!
1291	REAL(wp),DIMENSION(:,:,:),ALLOCATABLE :: ztmp_fly_dta ! temporary array of values on input grid
1292	INTEGER, DIMENSION(3) :: rec1,recn ! temporary arrays for start and length
1293	INTEGER, DIMENSION(3) :: rec1_lsm,recn_lsm ! temporary arrays for start and length in case of seaoverland
1294	INTEGER :: ii_lsm1,ii_lsm2,ij_lsm1,ij_lsm2 ! temporary indices
1295	INTEGER :: jk, jn, jm, jir, jjr ! loop counters
1296	INTEGER :: ni, nj ! lengths
1297	INTEGER :: jpimin,jpiwid ! temporary indices
1298	INTEGER :: jpimin_lsm,jpiwid_lsm ! temporary indices
1299	INTEGER :: jpjmin,jpjwid ! temporary indices
1300	INTEGER :: jpjmin_lsm,jpjwid_lsm ! temporary indices
1301	INTEGER :: jpi1,jpi2,jpj1,jpj2 ! temporary indices
1302	INTEGER :: jpi1_lsm,jpi2_lsm,jpj1_lsm,jpj2_lsm ! temporary indices
1303	INTEGER :: itmpi,itmpj,itmpz ! lengths
1304
1305	!!----------------------------------------------------------------------
1306	!
1307	!! for weighted interpolation we have weights at four corners of a box surrounding
1308	!! a model grid point, each weight is multiplied by a grid value (bilinear case)
1309	!! or by a grid value and gradients at the corner point (bicubic case)
1310	!! so we need to have a 4 by 4 subgrid surrounding each model point to cover both cases
1311
1312	!! sub grid from non-model input grid which encloses all grid points in this nemo process
1313	jpimin = ref_wgts(kw)%botleft(1)
1314	jpjmin = ref_wgts(kw)%botleft(2)
1315	jpiwid = ref_wgts(kw)%jpiwgt
1316	jpjwid = ref_wgts(kw)%jpjwgt
1317
1318	!! when reading in, expand this sub-grid by one halo point all the way round for calculating gradients
1319	rec1(1) = MAX( jpimin-1, 1 )
1320	rec1(2) = MAX( jpjmin-1, 1 )
1321	rec1(3) = 1
1322	recn(1) = MIN( jpiwid+2, ref_wgts(kw)%ddims(1)-rec1(1)+1 )
1323	recn(2) = MIN( jpjwid+2, ref_wgts(kw)%ddims(2)-rec1(2)+1 )
1324	recn(3) = kk
1325
1326	!! where we need to put it in the non-nemo grid fly_dta
1327	!! note that jpi1 and jpj1 only differ from 1 when jpimin and jpjmin are 1
1328	!! (ie at the extreme west or south of the whole input grid) and similarly for jpi2 and jpj2
1329	jpi1 = 2 + rec1(1) - jpimin
1330	jpj1 = 2 + rec1(2) - jpjmin
1331	jpi2 = jpi1 + recn(1) - 1
1332	jpj2 = jpj1 + recn(2) - 1
1333
1334
1335	IF( LEN( TRIM(lsmfile) ) > 0 ) THEN
1336	!! indeces for ztmp_fly_dta
1337	! --------------------------
1338	rec1_lsm(1)=MAX(rec1(1)-nn_lsm,1) ! starting index for enlarged external data, x direction
1339	rec1_lsm(2)=MAX(rec1(2)-nn_lsm,1) ! starting index for enlarged external data, y direction
1340	rec1_lsm(3) = 1 ! vertical dimension
1341	recn_lsm(1)=MIN(rec1(1)-rec1_lsm(1)+recn(1)+nn_lsm,ref_wgts(kw)%ddims(1)-rec1_lsm(1)) ! n points in x direction
1342	recn_lsm(2)=MIN(rec1(2)-rec1_lsm(2)+recn(2)+nn_lsm,ref_wgts(kw)%ddims(2)-rec1_lsm(2)) ! n points in y direction
1343	recn_lsm(3) = kk ! number of vertical levels in the input file
1344
1345	! Avoid out of bound
1346	jpimin_lsm = MAX( rec1_lsm(1)+1, 1 )
1347	jpjmin_lsm = MAX( rec1_lsm(2)+1, 1 )
1348	jpiwid_lsm = MIN( recn_lsm(1)-2,ref_wgts(kw)%ddims(1)-rec1(1)+1)
1349	jpjwid_lsm = MIN( recn_lsm(2)-2,ref_wgts(kw)%ddims(2)-rec1(2)+1)
1350
1351	jpi1_lsm = 2+rec1_lsm(1)-jpimin_lsm
1352	jpj1_lsm = 2+rec1_lsm(2)-jpjmin_lsm
1353	jpi2_lsm = jpi1_lsm + recn_lsm(1) - 1
1354	jpj2_lsm = jpj1_lsm + recn_lsm(2) - 1
1355
1356
1357	itmpi=jpi2_lsm-jpi1_lsm+1
1358	itmpj=jpj2_lsm-jpj1_lsm+1
1359	itmpz=kk
1360	ALLOCATE(ztmp_fly_dta(itmpi,itmpj,itmpz))
1361	ztmp_fly_dta(:,:,:) = 0.0
1362	SELECT CASE( SIZE(ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:),3) )
1363	CASE(1)
1364	CALL iom_get( num, jpdom_unknown, clvar, ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,1), &
1365	& nrec, rec1_lsm, recn_lsm)
1366	CASE DEFAULT
1367	CALL iom_get( num, jpdom_unknown, clvar, ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:), &
1368	& nrec, rec1_lsm, recn_lsm)
1369	END SELECT
1370	CALL apply_seaoverland(lsmfile,ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:), &
1371	& jpi1_lsm,jpi2_lsm,jpj1_lsm,jpj2_lsm, &
1372	& itmpi,itmpj,itmpz,rec1_lsm,recn_lsm)
1373
1374
1375	! Relative indeces for remapping
1376	ii_lsm1 = (rec1(1)-rec1_lsm(1))+1
1377	ii_lsm2 = (ii_lsm1+recn(1))-1
1378	ij_lsm1 = (rec1(2)-rec1_lsm(2))+1
1379	ij_lsm2 = (ij_lsm1+recn(2))-1
1380
1381	ref_wgts(kw)%fly_dta(:,:,:) = 0.0
1382	ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,:) = ztmp_fly_dta(ii_lsm1:ii_lsm2,ij_lsm1:ij_lsm2,:)
1383	DEALLOCATE(ztmp_fly_dta)
1384
1385	ELSE
1386
1387	ref_wgts(kw)%fly_dta(:,:,:) = 0.0
1388	SELECT CASE( SIZE(ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,:),3) )
1389	CASE(1)
1390	CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,1), nrec, rec1, recn)
1391	CASE DEFAULT
1392	CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,:), nrec, rec1, recn)
1393	END SELECT
1394	ENDIF
1395
1396
1397	!! first four weights common to both bilinear and bicubic
1398	!! data_jpi, data_jpj have already been shifted to (1,1) corresponding to botleft
1399	!! note that we have to offset by 1 into fly_dta array because of halo
1400	dta(:,:,:) = 0.0
1401	DO jk = 1,4
1402	DO jn = 1, jpj
1403	DO jm = 1,jpi
1404	ni = ref_wgts(kw)%data_jpi(jm,jn,jk)
1405	nj = ref_wgts(kw)%data_jpj(jm,jn,jk)
1406	dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk) * ref_wgts(kw)%fly_dta(ni+1,nj+1,:)
1407	END DO
1408	END DO
1409	END DO
1410
1411	IF (ref_wgts(kw)%numwgt .EQ. 16) THEN
1412
1413	!! fix up halo points that we couldnt read from file
1414	IF( jpi1 == 2 ) THEN
1415	ref_wgts(kw)%fly_dta(jpi1-1,:,:) = ref_wgts(kw)%fly_dta(jpi1,:,:)
1416	ENDIF
1417	IF( jpi2 + jpimin - 1 == ref_wgts(kw)%ddims(1)+1 ) THEN
1418	ref_wgts(kw)%fly_dta(jpi2+1,:,:) = ref_wgts(kw)%fly_dta(jpi2,:,:)
1419	ENDIF
1420	IF( jpj1 == 2 ) THEN
1421	ref_wgts(kw)%fly_dta(:,jpj1-1,:) = ref_wgts(kw)%fly_dta(:,jpj1,:)
1422	ENDIF
1423	IF( jpj2 + jpjmin - 1 == ref_wgts(kw)%ddims(2)+1 .AND. jpj2 .lt. jpjwid+2 ) THEN
1424	ref_wgts(kw)%fly_dta(:,jpj2+1,:) = 2.0*ref_wgts(kw)%fly_dta(:,jpj2,:) - ref_wgts(kw)%fly_dta(:,jpj2-1,:)
1425	ENDIF
1426
1427	!! if data grid is cyclic we can do better on east-west edges
1428	!! but have to allow for whether first and last columns are coincident
1429	IF( ref_wgts(kw)%cyclic ) THEN
1430	rec1(2) = MAX( jpjmin-1, 1 )
1431	recn(1) = 1
1432	recn(2) = MIN( jpjwid+2, ref_wgts(kw)%ddims(2)-rec1(2)+1 )
1433	jpj1 = 2 + rec1(2) - jpjmin
1434	jpj2 = jpj1 + recn(2) - 1
1435
1436	rec1(1) = ref_wgts(kw)%ddims(1) - ref_wgts(kw)%overlap
1437	SELECT CASE( SIZE( ref_wgts(kw)%col(:,jpj1:jpj2,:),3) )
1438	CASE(1)
1439	CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,1), nrec, rec1, recn)
1440	CASE DEFAULT
1441	CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,:), nrec, rec1, recn)
1442	END SELECT
1443	IF( jpi1 == 2 ) THEN
1444	ref_wgts(kw)%fly_dta(jpi1-1,jpj1:jpj2,:) = ref_wgts(kw)%col(1,jpj1:jpj2,:)
1445	ENDIF
1446
1447	rec1(1) = 1 + ref_wgts(kw)%overlap
1448	SELECT CASE( SIZE( ref_wgts(kw)%col(:,jpj1:jpj2,:),3) )
1449	CASE(1)
1450	CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,1), nrec, rec1, recn)
1451	CASE DEFAULT
1452	CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,:), nrec, rec1, recn)
1453	END SELECT
1454	IF( jpi2 + jpimin - 1 == ref_wgts(kw)%ddims(1)+1 ) THEN
1455	ref_wgts(kw)%fly_dta(jpi2+1,jpj1:jpj2,:) = ref_wgts(kw)%col(1,jpj1:jpj2,:)
1456	ENDIF
1457	ENDIF
1458
1459	! gradient in the i direction
1460	DO jk = 1,4
1461	DO jn = 1, jpj
1462	DO jm = 1,jpi
1463	ni = ref_wgts(kw)%data_jpi(jm,jn,jk)
1464	nj = ref_wgts(kw)%data_jpj(jm,jn,jk)
1465	dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk+4) * 0.5 * &
1466	(ref_wgts(kw)%fly_dta(ni+2,nj+1,:) - ref_wgts(kw)%fly_dta(ni,nj+1,:))
1467	END DO
1468	END DO
1469	END DO
1470
1471	! gradient in the j direction
1472	DO jk = 1,4
1473	DO jn = 1, jpj
1474	DO jm = 1,jpi
1475	ni = ref_wgts(kw)%data_jpi(jm,jn,jk)
1476	nj = ref_wgts(kw)%data_jpj(jm,jn,jk)
1477	dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk+8) * 0.5 * &
1478	(ref_wgts(kw)%fly_dta(ni+1,nj+2,:) - ref_wgts(kw)%fly_dta(ni+1,nj,:))
1479	END DO
1480	END DO
1481	END DO
1482
1483	! gradient in the ij direction
1484	DO jk = 1,4
1485	DO jn = 1, jpj
1486	DO jm = 1,jpi
1487	ni = ref_wgts(kw)%data_jpi(jm,jn,jk)
1488	nj = ref_wgts(kw)%data_jpj(jm,jn,jk)
1489	dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk+12) * 0.25 * ( &
1490	(ref_wgts(kw)%fly_dta(ni+2,nj+2,:) - ref_wgts(kw)%fly_dta(ni ,nj+2,:)) - &
1491	(ref_wgts(kw)%fly_dta(ni+2,nj ,:) - ref_wgts(kw)%fly_dta(ni ,nj ,:)))
1492	END DO
1493	END DO
1494	END DO
1495	!
1496	END IF
1497	!
1498	END SUBROUTINE fld_interp
1499
1500
1501	FUNCTION ksec_week( cdday )
1502	!!---------------------------------------------------------------------
1503	!! * FUNCTION kshift_week *
1504	!!
1505	!! ** Purpose :
1506	!!---------------------------------------------------------------------
1507	CHARACTER(len=*), INTENT(in) :: cdday !3 first letters of the first day of the weekly file
1508	!!
1509	INTEGER :: ksec_week ! output variable
1510	INTEGER :: ijul !temp variable
1511	INTEGER :: ishift !temp variable
1512	CHARACTER(len=3),DIMENSION(7) :: cl_week
1513	!!----------------------------------------------------------------------
1514	cl_week = (/"sun","sat","fri","thu","wed","tue","mon"/)
1515	DO ijul = 1, 7
1516	IF( cl_week(ijul) == TRIM(cdday) ) EXIT
1517	END DO
1518	IF( ijul .GT. 7 ) CALL ctl_stop( 'ksec_week: wrong day for sdjf%cltype(6:8): '//TRIM(cdday) )
1519	!
1520	ishift = ijul * NINT(rday)
1521	!
1522	ksec_week = nsec_week + ishift
1523	ksec_week = MOD( ksec_week, 7*NINT(rday) )
1524	!
1525	END FUNCTION ksec_week
1526
1527	!!======================================================================
1528	END MODULE fldread

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source: branches/UKMO/test_moci_test_suite/NEMOGCM/NEMO/OPA_SRC/SBC/fldread.F90 @ 8243

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