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startvar.F @ 177

Last change on this file since 177 was 177, checked in by lmdzadmin, 23 years ago

Lots of stuff, plus particulierement:

appel a ORCHIDEE en etat de marche (pb de grille subsiste)
modifs de Pascale sur soil dans le cas ou ok_veget=false -

Property svn:eol-style set to native
Property svn:keywords set to Author Date Id Revision

File size: 33.3 KB

Line
1	! $Header$
2	MODULE startvar
3	!
4	!
5	! There are three ways to access data from the database of atmospheric data which
6	! can be used to initialize the model. This depends on the type of field which needs
7	! to be extracted. In any case the call should come after a restget and should be of the type :
8	! CALL startget(...)
9	!
10	! We will details the possible arguments to startget here :
11	!
12	! - A 2D variable on the dynamical grid :
13	! CALL startget(varname, iml, jml, lon_in, lat_in, champ, val_ex)
14	!
15	!
16	! - A 1D variable on the physical grid :
17	! CALL startget(varname, iml, jml, lon_in, lat_in, nbindex, champ, val_exp)
18	!
19	!
20	! - A 3D variable on the dynamical grid :
21	! CALL startget(varname, iml, jml, lon_in, lat_in, lml, pls, workvar, champ, val_exp)
22	!
23	!
24	! There is special constraint on the atmospheric data base except that the
25	! the data needs to be in netCDF and the variables should have the the following
26	! names in the file :
27	!
28	! 'RELIEF' : High resolution orography
29	! 'ST' : Surface temperature
30	! 'CDSW' : Soil moisture
31	! 'Z' : Surface geopotential
32	! 'SP' : Surface pressure
33	! 'U' : East ward wind
34	! 'V' : Northward wind
35	! 'TEMP' : Temperature
36	! 'R' : Relative humidity
37	!
38	USE ioipsl
39	!
40	!
41	IMPLICIT NONE
42	!
43	!
44	PRIVATE
45	PUBLIC startget
46	!
47	!
48	INTERFACE startget
49	MODULE PROCEDURE startget_phys2d, startget_phys1d, startget_dyn
50	END INTERFACE
51	!
52	INTEGER, SAVE :: fid_phys, fid_dyn
53	INTEGER, SAVE :: iml_phys, iml_rel, iml_dyn
54	INTEGER, SAVE :: jml_phys, jml_rel, jml_dyn
55	INTEGER, SAVE :: llm_dyn, ttm_dyn
56	REAL, ALLOCATABLE, SAVE, DIMENSION (:,:) :: lon_phys, lon_rug,
57	. lon_alb, lon_rel, lon_dyn
58	REAL, ALLOCATABLE, SAVE, DIMENSION (:,:) :: lat_phys, lat_rug,
59	. lat_alb, lat_rel, lat_dyn
60	REAL, ALLOCATABLE, SAVE, DIMENSION (:) :: lev_dyn
61	REAL, ALLOCATABLE, SAVE, DIMENSION (:,:) :: relief, zstd, zsig,
62	. zgam, zthe, zpic, zval
63	REAL, ALLOCATABLE, SAVE, DIMENSION (:,:) :: rugo, masque, phis
64	!
65	REAL, ALLOCATABLE, SAVE, DIMENSION (:,:) :: tsol, qsol, psol_dyn
66	REAL, ALLOCATABLE, SAVE, DIMENSION (:,:,:) :: var_ana3d
67	!
68	CONTAINS
69	!
70	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
71	!
72	SUBROUTINE startget_phys2d(varname, iml, jml, lon_in, lat_in,
73	. champ, val_exp)
74	!
75	! There is a big mess with the size in logitude, should it be iml or iml+1.
76	! I have chosen to use the iml+1 as an argument to this routine and we declare
77	! internaly smaler fields when needed. This needs to be cleared once and for all in LMDZ.
78	! A convention is required.
79	!
80	!
81	CHARACTER(), INTENT(in) :: varname
82	INTEGER, INTENT(in) :: iml, jml
83	REAL, INTENT(in) :: lon_in(iml), lat_in(jml)
84	REAL, INTENT(inout) :: champ(iml,jml)
85	REAL, INTENT(in) :: val_exp
86	!
87	! This routine only works if the variable does not exist or is constant
88	!
89	IF ( MINVAL(champ(:,:)).EQ.MAXVAL(champ(:,:)) .AND.
90	.MINVAL(champ(:,:)).EQ.val_exp ) THEN
91	!
92	SELECTCASE(varname)
93	!
94	CASE ('relief')
95	!
96	! If we do not have the orography we need to get it
97	!
98	IF ( .NOT.ALLOCATED(relief)) THEN
99	!
100	CALL start_init_orog( iml, jml, lon_in, lat_in)
101	!
102	ENDIF
103	!
104	IF (SIZE(relief) .NE. SIZE(champ)) THEN
105	!
106	WRITE(,) 'STARTVAR module has been',
107	.' initialized to the wrong size'
108	STOP
109	!
110	ENDIF
111	!
112	champ(:,:) = relief(:,:)
113	!
114	CASE ('rugosite')
115	!
116	! If we do not have the orography we need to get it
117	!
118	IF ( .NOT.ALLOCATED(rugo)) THEN
119	!
120	CALL start_init_orog( iml, jml, lon_in, lat_in)
121	!
122	ENDIF
123	!
124	IF (SIZE(rugo) .NE. SIZE(champ)) THEN
125	!
126	WRITE(,)
127	. 'STARTVAR module has been initialized to the wrong size'
128	STOP
129	!
130	ENDIF
131	!
132	champ(:,:) = rugo(:,:)
133	!
134	CASE ('masque')
135	!
136	! If we do not have the orography we need to get it
137	!
138	IF ( .NOT.ALLOCATED(masque)) THEN
139	!
140	CALL start_init_orog( iml, jml, lon_in, lat_in)
141	!
142	ENDIF
143	!
144	IF (SIZE(masque) .NE. SIZE(champ)) THEN
145	!
146	WRITE(,)
147	. 'STARTVAR module has been initialized to the wrong size'
148	STOP
149	!
150	ENDIF
151	!
152	champ(:,:) = masque(:,:)
153	!
154	CASE ('surfgeo')
155	!
156	! If we do not have the orography we need to get it
157	!
158	IF ( .NOT.ALLOCATED(phis)) THEN
159	!
160	CALL start_init_orog( iml, jml, lon_in, lat_in)
161	!
162	ENDIF
163	!
164	IF (SIZE(phis) .NE. SIZE(champ)) THEN
165	!
166	WRITE(,)
167	. 'STARTVAR module has been initialized to the wrong size'
168	STOP
169	!
170	ENDIF
171	!
172	champ(:,:) = phis(:,:)
173	!
174	CASE ('psol')
175	!
176	! If we do not have the orography we need to get it
177	!
178	IF ( .NOT.ALLOCATED(psol_dyn)) THEN
179	!
180	CALL start_init_dyn( iml, jml, lon_in, lat_in)
181	!
182	ENDIF
183	!
184	IF (SIZE(psol_dyn) .NE. SIZE(champ)) THEN
185	!
186	WRITE(,)
187	. 'STARTVAR module has been initialized to the wrong size'
188	STOP
189	!
190	ENDIF
191	!
192	champ(:,:) = psol_dyn(:,:)
193	!
194	CASE DEFAULT
195	!
196	WRITE(,) 'startget_phys2d'
197	WRITE(,) 'No rule is present to extract variable',
198	. varname(:LEN_TRIM(varname)),' from any data set'
199	STOP
200	!
201	END SELECT
202	!
203	ELSE
204	!
205	! There are a few fields we might need if we need to interpolate 3D filed. Thus if they come through here we
206	! will catch them
207	!
208	SELECTCASE(varname)
209	!
210	CASE ('surfgeo')
211	!
212	IF ( .NOT.ALLOCATED(phis)) THEN
213	ALLOCATE(phis(iml,jml))
214	ENDIF
215	!
216	IF (SIZE(phis) .NE. SIZE(champ)) THEN
217	!
218	WRITE(,)
219	. 'STARTVAR module has been initialized to the wrong size'
220	STOP
221	!
222	ENDIF
223	!
224	phis(:,:) = champ(:,:)
225	!
226	END SELECT
227	!
228	ENDIF
229	!
230	END SUBROUTINE startget_phys2d
231	!
232	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
233	!
234	SUBROUTINE start_init_orog( iml, jml, lon_in, lat_in)
235	!
236	INTEGER, INTENT(in) :: iml, jml
237	REAL, INTENT(in) :: lon_in(iml), lat_in(jml)
238	!
239	! LOCAL
240	!
241	REAL :: lev(1), date, dt
242	INTEGER :: itau(1), fid
243	INTEGER :: llm_tmp, ttm_tmp
244	INTEGER :: i, j
245	INTEGER :: iret
246	REAL, ALLOCATABLE :: relief_hi(:,:)
247	REAL, ALLOCATABLE :: lon_rad(:), lat_rad(:)
248	REAL, ALLOCATABLE :: tmp_var(:,:)
249	INTEGER, ALLOCATABLE :: tmp_int(:,:)
250	!
251	CHARACTER*120 :: orogfname
252	LOGICAL :: check=.TRUE.
253	!
254	!
255	orogfname = 'Relief.nc'
256	!
257	IF ( check ) WRITE(,) 'Reading the high resolution orography'
258	!
259	CALL flininfo(orogfname,iml_rel, jml_rel, llm_tmp, ttm_tmp, fid)
260	!
261	ALLOCATE (lat_rel(iml_rel,jml_rel), stat=iret)
262	ALLOCATE (lon_rel(iml_rel,jml_rel), stat=iret)
263	ALLOCATE (relief_hi(iml_rel,jml_rel), stat=iret)
264	!
265	CALL flinopen(orogfname, .FALSE., iml_rel, jml_rel,
266	.llm_tmp, lon_rel, lat_rel, lev, ttm_tmp,
267	. itau, date, dt, fid)
268	!
269	CALL flinget(fid, 'RELIEF', iml_rel, jml_rel, llm_tmp,
270	. ttm_tmp, 1, 1, relief_hi)
271	!
272	CALL flinclo(fid)
273	!
274	! In case we have a file which is in degrees we do the transformation
275	!
276	ALLOCATE(lon_rad(iml_rel))
277	IF ( MAXVAL(lon_rel(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
278	lon_rad(:) = lon_rel(:,1) * 2.0 * ASIN(1.0) / 180.0
279	ELSE
280	lon_rad(:) = lon_rel(:,1)
281	ENDIF
282	ALLOCATE(lat_rad(jml_rel))
283	IF ( MAXVAL(lat_rel(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
284	lat_rad(:) = lat_rel(1,:) * 2.0 * ASIN(1.0) / 180.0
285	ELSE
286	lat_rad(:) = lat_rel(1,:)
287	ENDIF
288	!
289	!
290	IF ( check ) WRITE(,) 'Computes all the parameters needed',
291	.' for the gravity wave drag code'
292	!
293	! Allocate the data we need to put in the interpolated fields
294	!
295	! RELIEF: orographie moyenne
296	ALLOCATE(relief(iml,jml))
297	! zphi : orographie moyenne
298	ALLOCATE(phis(iml,jml))
299	! zstd: deviation standard de l'orographie sous-maille
300	ALLOCATE(zstd(iml,jml))
301	! zsig: pente de l'orographie sous-maille
302	ALLOCATE(zsig(iml,jml))
303	! zgam: anisotropy de l'orographie sous maille
304	ALLOCATE(zgam(iml,jml))
305	! zthe: orientation de l'axe oriente dans la direction
306	! de plus grande pente de l'orographie sous maille
307	ALLOCATE(zthe(iml,jml))
308	! zpic: hauteur pics de la SSO
309	ALLOCATE(zpic(iml,jml))
310	! zval: hauteur vallees de la SSO
311	ALLOCATE(zval(iml,jml))
312	! masque : Masque terre ocean
313	ALLOCATE(tmp_int(iml,jml))
314	ALLOCATE(masque(iml,jml))
315	!
316	CALL grid_noro(iml_rel, jml_rel, lon_rad, lat_rad, relief_hi,
317	$ iml-1, jml, lon_in, lat_in,
318	! . phis, relief, zstd, zsig, zgam, zthe, zpic, zval, tmp_int)
319	! PB masque avec % terre mai 2000
320	$ phis, relief, zstd, zsig, zgam, zthe, zpic, zval, masque)
321	phis = phis * 9.81
322	! write(,)'phis sortie grid_noro'
323	! write(,)phis
324	!
325	!PB supression ligne suivant pour masque avec % terre
326	! masque(:,:) = FLOAT(tmp_int(:,:))
327	!
328	! Compute surface roughness
329	!
330	IF ( check ) WRITE(,)
331	.'Compute surface roughness induced by the orography'
332	!
333	ALLOCATE(rugo(iml,jml))
334	ALLOCATE(tmp_var(iml-1,jml))
335	!
336	CALL rugsoro(iml_rel, jml_rel, lon_rad, lat_rad, relief_hi,
337	. iml-1, jml, lon_in, lat_in, tmp_var)
338	!
339	DO j = 1, jml
340	DO i = 1, iml-1
341	rugo(i,j) = tmp_var(i,j)
342	ENDDO
343	rugo(iml,j) = tmp_var(1,j)
344	ENDDO
345	!
346	! Build land-sea mask
347	!
348	!
349	RETURN
350	!
351	END SUBROUTINE start_init_orog
352	!
353	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
354	!
355	SUBROUTINE startget_phys1d(varname, iml, jml, lon_in,
356	.lat_in, nbindex, champ, val_exp)
357	!
358	CHARACTER(), INTENT(in) :: varname
359	INTEGER, INTENT(in) :: iml, jml, nbindex
360	REAL, INTENT(in) :: lon_in(iml), lat_in(jml)
361	REAL, INTENT(inout) :: champ(nbindex)
362	REAL, INTENT(in) :: val_exp
363	!
364	!
365	! This routine only works if the variable does not exist or is constant
366	!
367	IF ( MINVAL(champ(:)).EQ.MAXVAL(champ(:)) .AND.
368	.MINVAL(champ(:)).EQ.val_exp ) THEN
369	SELECTCASE(varname)
370	CASE ('tsol')
371	IF ( .NOT.ALLOCATED(tsol)) THEN
372	CALL start_init_phys( iml, jml, lon_in, lat_in)
373	ENDIF
374	IF ( SIZE(tsol) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
375	WRITE(,)
376	. 'STARTVAR module has been initialized to the wrong size'
377	STOP
378	ENDIF
379	CALL gr_dyn_fi(1, iml, jml, nbindex, tsol, champ)
380	CASE ('qsol')
381	IF ( .NOT.ALLOCATED(qsol)) THEN
382	CALL start_init_phys( iml, jml, lon_in, lat_in)
383	ENDIF
384	IF ( SIZE(qsol) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
385	WRITE(,)
386	. 'STARTVAR module has been initialized to the wrong size'
387	STOP
388	ENDIF
389	CALL gr_dyn_fi(1, iml, jml, nbindex, qsol, champ)
390	CASE ('psol')
391	IF ( .NOT.ALLOCATED(psol_dyn)) THEN
392	CALL start_init_dyn( iml, jml, lon_in, lat_in)
393	ENDIF
394	IF (SIZE(psol_dyn) .NE. SIZE(lon_in)*SIZE(lat_in)) THEN
395	WRITE(,)
396	. 'STARTVAR module has been initialized to the wrong size'
397	STOP
398	ENDIF
399	CALL gr_dyn_fi(1, iml, jml, nbindex, psol_dyn, champ)
400	! PB ajout pour masque terre mer fractionneiare
401	CASE ('zmasq')
402	IF (.NOT. ALLOCATED(masque) ) THEN
403	CALL start_init_orog ( iml, jml,lon_in, lat_in)
404	ENDIF
405	IF ( SIZE(masque) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
406	WRITE(,)
407	. 'STARTVAR module has been initialized to the wrong size'
408	STOP
409	ENDIF
410	CALL gr_dyn_fi(1, iml, jml, nbindex, masque, champ)
411	CASE ('zmea')
412	IF ( .NOT.ALLOCATED(relief)) THEN
413	CALL start_init_orog( iml, jml, lon_in, lat_in)
414	ENDIF
415	IF ( SIZE(relief) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
416	WRITE(,)
417	. 'STARTVAR module has been initialized to the wrong size'
418	STOP
419	ENDIF
420	CALL gr_dyn_fi(1, iml, jml, nbindex, relief, champ)
421	CASE ('zstd')
422	IF ( .NOT.ALLOCATED(zstd)) THEN
423	CALL start_init_orog( iml, jml, lon_in, lat_in)
424	ENDIF
425	IF ( SIZE(zstd) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
426	WRITE(,)
427	. 'STARTVAR module has been initialized to the wrong size'
428	STOP
429	ENDIF
430	CALL gr_dyn_fi(1, iml, jml, nbindex,zstd, champ)
431	CASE ('zsig')
432	IF ( .NOT.ALLOCATED(zsig)) THEN
433	CALL start_init_orog( iml, jml, lon_in, lat_in)
434	ENDIF
435	IF ( SIZE(zsig) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
436	WRITE(,)
437	. 'STARTVAR module has been initialized to the wrong size'
438	STOP
439	ENDIF
440	CALL gr_dyn_fi(1, iml, jml, nbindex,zsig, champ)
441	CASE ('zgam')
442	IF ( .NOT.ALLOCATED(zgam)) THEN
443	CALL start_init_orog( iml, jml, lon_in, lat_in)
444	ENDIF
445	IF ( SIZE(zgam) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
446	WRITE(,)
447	. 'STARTVAR module has been initialized to the wrong size'
448	STOP
449	ENDIF
450	CALL gr_dyn_fi(1, iml, jml, nbindex,zgam, champ)
451	CASE ('zthe')
452	IF ( .NOT.ALLOCATED(zthe)) THEN
453	CALL start_init_orog( iml, jml, lon_in, lat_in)
454	ENDIF
455	IF ( SIZE(zthe) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
456	WRITE(,)
457	. 'STARTVAR module has been initialized to the wrong size'
458	STOP
459	ENDIF
460	CALL gr_dyn_fi(1, iml, jml, nbindex,zthe, champ)
461	CASE ('zpic')
462	IF ( .NOT.ALLOCATED(zpic)) THEN
463	CALL start_init_orog( iml, jml, lon_in, lat_in)
464	ENDIF
465	IF ( SIZE(zpic) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
466	WRITE(,)
467	. 'STARTVAR module has been initialized to the wrong size'
468	STOP
469	ENDIF
470	CALL gr_dyn_fi(1, iml, jml, nbindex,zpic, champ)
471	CASE ('zval')
472	IF ( .NOT.ALLOCATED(zval)) THEN
473	CALL start_init_orog( iml, jml, lon_in, lat_in)
474	ENDIF
475	IF ( SIZE(zval) .NE. SIZE(lon_in)*SIZE(lat_in) ) THEN
476	WRITE(,)
477	. 'STARTVAR module has been initialized to the wrong size'
478	STOP
479	ENDIF
480	CALL gr_dyn_fi(1, iml, jml, nbindex,zval, champ)
481	CASE ('rads')
482	champ(:) = 0.0
483	CASE ('snow')
484	champ(:) = 0.0
485	CASE ('deltat')
486	champ(:) = 0.0
487	CASE ('rugmer')
488	champ(:) = 0.001
489	CASE ('agsno')
490	champ(:) = 50.0
491	CASE DEFAULT
492	WRITE(,) 'startget_phys1d'
493	WRITE(,) 'No rule is present to extract variable ',
494	. varname(:LEN_TRIM(varname)),' from any data set'
495	STOP
496	END SELECT
497	ELSE
498	!
499	! If we see tsol we catch it as we may need it for a 3D interpolation
500	!
501	SELECTCASE(varname)
502	CASE ('tsol')
503	IF ( .NOT.ALLOCATED(tsol)) THEN
504	ALLOCATE(tsol(SIZE(lon_in),SIZE(lat_in) ))
505	ENDIF
506	CALL gr_fi_dyn(1, iml, jml, nbindex, champ, tsol)
507	END SELECT
508	ENDIF
509	END SUBROUTINE startget_phys1d
510	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
511	!
512	SUBROUTINE start_init_phys( iml, jml, lon_in, lat_in)
513	!
514	INTEGER, INTENT(in) :: iml, jml
515	REAL, INTENT(in) :: lon_in(iml), lat_in(jml)
516	!
517	! LOCAL
518	!
519	REAL :: lev(1), date, dt
520	INTEGER :: itau(1)
521	INTEGER :: llm_tmp, ttm_tmp
522	INTEGER :: i, j
523	!
524	CHARACTER*120 :: physfname
525	LOGICAL :: check=.TRUE.
526	!
527	REAL, ALLOCATABLE :: lon_rad(:), lat_rad(:)
528	REAL, ALLOCATABLE :: var_ana(:,:), tmp_var(:,:)
529	!
530	physfname = 'ECPHY.nc'
531	!
532	IF ( check ) WRITE(,) 'Opening the surface analysis'
533	!
534	CALL flininfo(physfname, iml_phys, jml_phys, llm_tmp,
535	. ttm_tmp, fid_phys)
536	!
537	!
538	ALLOCATE (lat_phys(iml_phys,jml_phys))
539	ALLOCATE (lon_phys(iml_phys,jml_phys))
540	!
541	CALL flinopen(physfname, .FALSE., iml_phys, jml_phys,
542	. llm_tmp, lon_phys, lat_phys, lev, ttm_tmp,
543	. itau, date, dt, fid_phys)
544	!
545	! Allocate the space we will need to get the data out of this file
546	!
547	ALLOCATE(var_ana(iml_phys, jml_phys))
548	!
549	! In case we have a file which is in degrees we do the transformation
550	!
551	ALLOCATE(lon_rad(iml_phys))
552	IF ( MAXVAL(lon_phys(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
553	lon_rad(:) = lon_phys(:,1) * 2.0 * ASIN(1.0) / 180.0
554	ELSE
555	lon_rad(:) = lon_phys(:,1)
556	ENDIF
557	ALLOCATE(lat_rad(jml_phys))
558	IF ( MAXVAL(lat_phys(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
559	lat_rad(:) = lat_phys(1,:) * 2.0 * ASIN(1.0) / 180.0
560	ELSE
561	lat_rad(:) = lat_phys(1,:)
562	ENDIF
563	!
564	! We get the two standard varibales
565	! Surface temperature
566	!
567	ALLOCATE(tsol(iml,jml))
568	ALLOCATE(tmp_var(iml-1,jml))
569	!
570	!
571	CALL flinget(fid_phys, 'ST', iml_phys, jml_phys,
572	.llm_tmp, ttm_tmp, 1, 1, var_ana)
573	CALL grille_m(iml_phys, jml_phys, lon_rad, lat_rad,
574	. var_ana, iml-1, jml, lon_in, lat_in, tmp_var)
575	CALL gr_int_dyn(tmp_var, tsol, iml-1, jml)
576	!
577	! Soil moisture
578	!
579	ALLOCATE(qsol(iml,jml))
580	CALL flinget(fid_phys, 'CDSW', iml_phys, jml_phys,
581	. llm_tmp, ttm_tmp, 1, 1, var_ana)
582	CALL grille_m(iml_phys, jml_phys, lon_rad, lat_rad,
583	. var_ana, iml-1, jml, lon_in, lat_in, tmp_var)
584	CALL gr_int_dyn(tmp_var, qsol, iml-1, jml)
585	!
586	CALL flinclo(fid_phys)
587	!
588	END SUBROUTINE start_init_phys
589	!
590	!
591	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
592	!
593	!
594	SUBROUTINE startget_dyn(varname, iml, jml, lon_in, lat_in,
595	. lml, pls, workvar, champ, val_exp)
596	!
597	! ARGUMENTS
598	!
599	CHARACTER(), INTENT(in) :: varname
600	INTEGER, INTENT(in) :: iml, jml, lml
601	REAL, INTENT(in) :: lon_in(iml), lat_in(jml)
602	REAL, INTENT(in) :: pls(iml, jml, lml)
603	REAL, INTENT(in) :: workvar(iml, jml, lml)
604	REAL, INTENT(inout) :: champ(iml, jml, lml)
605	REAL, INTENT(in) :: val_exp
606	!
607	! LOCAL
608	!
609	INTEGER :: il, ij, ii
610	REAL :: xppn, xpps
611	!
612	! C'est vraiment une galere de devoir rajouter tant de commons just pour avoir les aires.
613	! Il faudrait mettre une structure plus flexible et moins dangereuse.
614	!
615	#include "dimensions.h"
616	#include "paramet.h"
617	#include "comgeom2.h"
618	#include "comconst.h"
619	!
620	! This routine only works if the variable does not exist or is constant
621	!
622	IF ( MINVAL(champ(:,:,:)).EQ.MAXVAL(champ(:,:,:)) .AND.
623	. MINVAL(champ(:,:,:)).EQ.val_exp ) THEN
624	!
625	SELECTCASE(varname)
626	CASE ('u')
627	IF ( .NOT.ALLOCATED(psol_dyn)) THEN
628	CALL start_init_dyn( iml, jml, lon_in, lat_in)
629	ENDIF
630	CALL start_inter_3d('U', iml, jml, lml, lon_in,
631	. lat_in, pls, champ)
632	DO il=1,lml
633	DO ij=1,jml
634	DO ii=1,iml-1
635	champ(ii,ij,il) = champ(ii,ij,il) * cu(ii,ij)
636	ENDDO
637	champ(iml,ij, il) = champ(1,ij, il)
638	ENDDO
639	ENDDO
640	CASE ('v')
641	IF ( .NOT.ALLOCATED(psol_dyn)) THEN
642	CALL start_init_dyn( iml, jml, lon_in, lat_in)
643	ENDIF
644	CALL start_inter_3d('V', iml, jml, lml, lon_in,
645	. lat_in, pls, champ)
646	DO il=1,lml
647	DO ij=1,jml
648	DO ii=1,iml-1
649	champ(ii,ij,il) = champ(ii,ij,il) * cv(ii,ij)
650	ENDDO
651	champ(iml,ij, il) = champ(1,ij, il)
652	ENDDO
653	ENDDO
654	CASE ('t')
655	IF ( .NOT.ALLOCATED(psol_dyn)) THEN
656	CALL start_init_dyn( iml, jml, lon_in, lat_in)
657	ENDIF
658	CALL start_inter_3d('TEMP', iml, jml, lml, lon_in,
659	. lat_in, pls, champ)
660
661	CASE ('tpot')
662	IF ( .NOT.ALLOCATED(psol_dyn)) THEN
663	CALL start_init_dyn( iml, jml, lon_in, lat_in)
664	ENDIF
665	CALL start_inter_3d('TEMP', iml, jml, lml, lon_in,
666	. lat_in, pls, champ)
667	IF ( MINVAL(workvar(:,:,:)) .NE. MAXVAL(workvar(:,:,:)) )
668	. THEN
669	DO il=1,lml
670	DO ij=1,jml
671	DO ii=1,iml-1
672	champ(ii,ij,il) = champ(ii,ij,il) * cpp
673	. / workvar(ii,ij,il)
674	ENDDO
675	champ(iml,ij,il) = champ(1,ij,il)
676	ENDDO
677	ENDDO
678	DO il=1,lml
679	xppn = SUM(aire(:,1)*champ(:,1,il))/apoln
680	xpps = SUM(aire(:,jml)*champ(:,jml,il))/apols
681	champ(:,1,il) = xppn
682	champ(:,jml,il) = xpps
683	ENDDO
684	ELSE
685	WRITE(,)'Could not compute potential temperature as the'
686	WRITE(,)'Exner function is missing or constant.'
687	STOP
688	ENDIF
689	CASE ('q')
690	IF ( .NOT.ALLOCATED(psol_dyn)) THEN
691	CALL start_init_dyn( iml, jml, lon_in, lat_in)
692	ENDIF
693	CALL start_inter_3d('R', iml, jml, lml, lon_in, lat_in,
694	. pls, champ)
695	IF ( MINVAL(workvar(:,:,:)) .NE. MAXVAL(workvar(:,:,:)) )
696	. THEN
697	DO il=1,lml
698	DO ij=1,jml
699	DO ii=1,iml-1
700	champ(ii,ij,il) = 0.01 * champ(ii,ij,il) *
701	. workvar(ii,ij,il)
702	ENDDO
703	champ(iml,ij,il) = champ(1,ij,il)
704	ENDDO
705	ENDDO
706	WHERE ( champ .LT. 0.) champ = 1.0E-10
707	DO il=1,lml
708	xppn = SUM(aire(:,1)*champ(:,1,il))/apoln
709	xpps = SUM(aire(:,jml)*champ(:,jml,il))/apols
710	champ(:,1,il) = xppn
711	champ(:,jml,il) = xpps
712	ENDDO
713	ELSE
714	WRITE(,)'Could not compute specific humidity as the'
715	WRITE(,)'saturated humidity is missing or constant.'
716	STOP
717	ENDIF
718	CASE DEFAULT
719	WRITE(,) 'startget_dyn'
720	WRITE(,) 'No rule is present to extract variable ',
721	. varname(:LEN_TRIM(varname)),' from any data set'
722	STOP
723	END SELECT
724	ENDIF
725	END SUBROUTINE startget_dyn
726	!
727	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
728	!
729	SUBROUTINE start_init_dyn( iml, jml, lon_in, lat_in)
730	!
731	INTEGER, INTENT(in) :: iml, jml
732	REAL, INTENT(in) :: lon_in(iml), lat_in(jml)
733	!
734	! LOCAL
735	!
736	REAL :: lev(1), date, dt
737	INTEGER :: itau(1)
738	INTEGER :: i, j
739	integer :: iret
740	!
741	CHARACTER*120 :: physfname
742	LOGICAL :: check=.TRUE.
743	!
744	REAL, ALLOCATABLE :: lon_rad(:), lat_rad(:)
745	REAL, ALLOCATABLE :: var_ana(:,:), tmp_var(:,:), z(:,:)
746	REAL, ALLOCATABLE :: xppn(:), xpps(:)
747	LOGICAL :: allo
748	!
749	! Ce n'est pas tres pratique d'avoir a charger 3 include pour avoir la grille du modele
750	!
751	#include "dimensions.h"
752	#include "paramet.h"
753	#include "comgeom2.h"
754	!
755	physfname = 'ECDYN.nc'
756	!
757	IF ( check ) WRITE(,) 'Opening the surface analysis'
758	!
759	CALL flininfo(physfname, iml_dyn, jml_dyn, llm_dyn,
760	. ttm_dyn, fid_dyn)
761	IF ( check ) WRITE(,) 'Values read: ', iml_dyn, jml_dyn,
762	. llm_dyn, ttm_dyn
763	!
764	ALLOCATE (lat_dyn(iml_dyn,jml_dyn), stat=iret)
765	ALLOCATE (lon_dyn(iml_dyn,jml_dyn), stat=iret)
766	ALLOCATE (lev_dyn(llm_dyn), stat=iret)
767	!
768	CALL flinopen(physfname, .FALSE., iml_dyn, jml_dyn, llm_dyn,
769	. lon_dyn, lat_dyn, lev_dyn, ttm_dyn,
770	. itau, date, dt, fid_dyn)
771	!
772
773	allo = allocated (var_ana)
774	if (allo) then
775	DEALLOCATE(var_ana, stat=iret)
776	endif
777	ALLOCATE(var_ana(iml_dyn, jml_dyn), stat=iret)
778
779	allo = allocated (lon_rad)
780	if (allo) then
781	DEALLOCATE(lon_rad, stat=iret)
782	endif
783	ALLOCATE(lon_rad(iml_dyn), stat=iret)
784
785	IF ( MAXVAL(lon_dyn(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
786	lon_rad(:) = lon_dyn(:,1) * 2.0 * ASIN(1.0) / 180.0
787	ELSE
788	lon_rad(:) = lon_dyn(:,1)
789	ENDIF
790	ALLOCATE(lat_rad(jml_dyn))
791	IF ( MAXVAL(lat_dyn(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
792	lat_rad(:) = lat_dyn(1,:) * 2.0 * ASIN(1.0) / 180.0
793	ELSE
794	lat_rad(:) = lat_dyn(1,:)
795	ENDIF
796	!
797	ALLOCATE(z(iml, jml))
798	ALLOCATE(tmp_var(iml-1,jml))
799	!
800	CALL flinget(fid_dyn, 'Z', iml_dyn, jml_dyn, 0, ttm_dyn,
801	. 1, 1, var_ana)
802	CALL grille_m(iml_dyn, jml_dyn , lon_rad, lat_rad, var_ana,
803	. iml-1, jml, lon_in, lat_in, tmp_var)
804	CALL gr_int_dyn(tmp_var, z, iml-1, jml)
805	!
806	ALLOCATE(psol_dyn(iml, jml))
807	!
808	CALL flinget(fid_dyn, 'SP', iml_dyn, jml_dyn, 0, ttm_dyn,
809	. 1, 1, var_ana)
810	CALL grille_m(iml_dyn, jml_dyn , lon_rad, lat_rad, var_ana,
811	. iml-1, jml, lon_in, lat_in, tmp_var)
812	CALL gr_int_dyn(tmp_var, psol_dyn, iml-1, jml)
813	!
814	IF ( .NOT.ALLOCATED(tsol)) THEN
815	! These variables may have been allocated by the need to
816	! create a start field for them or by the varibale
817	! coming out of the restart file. In case we dor have it we will initialize it.
818	!
819	CALL start_init_phys( iml, jml, lon_in, lat_in)
820	ELSE
821	IF ( SIZE(tsol) .NE. SIZE(psol_dyn) ) THEN
822	WRITE(,) 'start_init_dyn :'
823	WRITE(,) 'The temperature field we have does not ',
824	. 'have the right size'
825	STOP
826	ENDIF
827	ENDIF
828	IF ( .NOT.ALLOCATED(phis)) THEN
829	!
830	! These variables may have been allocated by the need to create a start field for them or by the varibale
831	! coming out of the restart file. In case we dor have it we will initialize it.
832	!
833	CALL start_init_orog( iml, jml, lon_in, lat_in)
834	!
835	ELSE
836	!
837	IF (SIZE(phis) .NE. SIZE(psol_dyn)) THEN
838	!
839	WRITE(,) 'start_init_dyn :'
840	WRITE(,) 'The orography field we have does not ',
841	. ' have the right size'
842	STOP
843	ENDIF
844	!
845	ENDIF
846	!
847	! PSOL is computed in Pascals
848	!
849	!
850	DO j = 1, jml
851	DO i = 1, iml-1
852	psol_dyn(i,j) = psol_dyn(i,j)*(1.0+(z(i,j)-phis(i,j))
853	. /287.0/tsol(i,j))
854	ENDDO
855	psol_dyn(iml,j) = psol_dyn(1,j)
856	ENDDO
857	!
858	!
859	ALLOCATE(xppn(iml-1))
860	ALLOCATE(xpps(iml-1))
861	!
862	DO i = 1, iml-1
863	xppn(i) = aire( i,1) * psol_dyn( i,1)
864	xpps(i) = aire( i,jml) * psol_dyn( i,jml)
865	ENDDO
866	!
867	DO i = 1, iml
868	psol_dyn(i,1 ) = SUM(xppn)/apoln
869	psol_dyn(i,jml) = SUM(xpps)/apols
870	ENDDO
871	!
872	RETURN
873	!
874	END SUBROUTINE start_init_dyn
875	!
876	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
877	!
878	SUBROUTINE start_inter_3d(varname, iml, jml, lml, lon_in,
879	. lat_in, pls_in, var3d)
880	!
881	! This subroutine gets a variables from a 3D file and does the interpolations needed
882	!
883	!
884	! ARGUMENTS
885	!
886	CHARACTER() :: varname
887	INTEGER :: iml, jml, lml
888	REAL :: lon_in(iml), lat_in(jml), pls_in(iml, jml, lml)
889	REAL :: var3d(iml, jml, lml)
890	!
891	! LOCAL
892	!
893	INTEGER :: ii, ij, il
894	REAL :: bx, by
895	REAL, ALLOCATABLE :: lon_rad(:), lat_rad(:)
896	REAL, ALLOCATABLE :: var_tmp2d(:,:), var_tmp3d(:,:,:)
897	REAL, ALLOCATABLE :: ax(:), ay(:), yder(:)
898	INTEGER, ALLOCATABLE :: lind(:)
899	!
900	LOGICAL :: check = .TRUE.
901	!
902	IF ( .NOT. ALLOCATED(var_ana3d)) THEN
903	ALLOCATE(var_ana3d(iml_dyn, jml_dyn, llm_dyn))
904	ENDIF
905	!
906	!
907	IF ( check) WRITE(,) 'Going into flinget to extract the 3D ',
908	. ' field.', fid_dyn
909	IF ( check) WRITE(,) fid_dyn, varname, iml_dyn, jml_dyn,
910	. llm_dyn,ttm_dyn
911	!
912	CALL flinget(fid_dyn, varname, iml_dyn, jml_dyn, llm_dyn,
913	. ttm_dyn, 1, 1, var_ana3d)
914	!
915	IF ( check) WRITE(,) 'Allocating space for the interpolation',
916	. iml, jml, llm_dyn
917	!
918	ALLOCATE(lon_rad(iml_dyn))
919	IF ( MAXVAL(lon_dyn(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
920	lon_rad(:) = lon_dyn(:,1) * 2.0 * ASIN(1.0) / 180.0
921	ELSE
922	lon_rad(:) = lon_dyn(:,1)
923	ENDIF
924	ALLOCATE(lat_rad(jml_dyn))
925	IF ( MAXVAL(lat_dyn(:,:)) .GT. 2.0 * ASIN(1.0) ) THEN
926	lat_rad(:) = lat_dyn(1,:) * 2.0 * ASIN(1.0) / 180.0
927	ELSE
928	lat_rad(:) = lat_dyn(1,:)
929	ENDIF
930	!
931	ALLOCATE(var_tmp2d(iml-1, jml))
932	ALLOCATE(var_tmp3d(iml, jml, llm_dyn))
933	ALLOCATE(ax(llm_dyn))
934	ALLOCATE(ay(llm_dyn))
935	ALLOCATE(yder(llm_dyn))
936	ALLOCATE(lind(llm_dyn))
937	!
938	DO il=1,llm_dyn
939	!
940	CALL grille_m(iml_dyn, jml_dyn, lon_rad, lat_rad,
941	.var_ana3d(:,:,il), iml-1, jml, lon_in, lat_in, var_tmp2d)
942	!
943	CALL gr_int_dyn(var_tmp2d, var_tmp3d(:,:,il), iml-1, jml)
944	!
945	ENDDO
946	!
947	! IF needed we return the vertical axis. The spline interpolation
948	! Requires the coordinate to be in increasing order.
949	!
950	IF ( lev_dyn(1) .LT. lev_dyn(llm_dyn)) THEN
951	DO il=1,llm_dyn
952	lind(il) = il
953	ENDDO
954	ELSE
955	DO il=1,llm_dyn
956	lind(il) = llm_dyn-il+1
957	ENDDO
958	ENDIF
959	!
960	DO ij=1,jml
961	DO ii=1,iml-1
962	!
963	ax(:) = lev_dyn(lind(:)) * 100
964	ay(:) = var_tmp3d(ii, ij, lind(:))
965	!
966	CALL SPLINE(ax, ay, llm_dyn, 1.e30, 1.e30, yder)
967	!
968	DO il=1,lml
969	bx = pls_in(ii, ij, il)
970	CALL SPLINT(ax, ay, yder, llm_dyn, bx, by)
971	var3d(ii, ij, il) = by
972	ENDDO
973	!
974	ENDDO
975	var3d(iml, ij, :) = var3d(1, ij, :)
976	ENDDO
977
978	DEALLOCATE(lon_rad)
979	DEALLOCATE(lat_rad)
980	DEALLOCATE(var_tmp2d)
981	DEALLOCATE(var_tmp3d)
982	DEALLOCATE(ax)
983	DEALLOCATE(ay)
984	DEALLOCATE(yder)
985	DEALLOCATE(lind)
986
987	!
988	RETURN
989	!
990	END SUBROUTINE start_inter_3d
991	!
992	END MODULE startvar

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