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integrd_p.F @ 3979

Last change on this file since 3979 was 1446, checked in by Ehouarn Millour, 14 years ago

Implemented modifications to enable running with only one tracer for planet types different from "earth". Rem: If flag 'planet_type' is set to "earth" (default behaviour) then there must be at least 2 tracers for the dynamics to function properly.

These updates do not induce any changes in model outputs with respect to previous revisions.

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Property svn:keywords set to Author Date Id Revision

File size: 8.5 KB

Rev	Line
[630]	1	!
[1279]	2	! $Id: integrd_p.F 1446 2010-10-22 09:27:25Z emillour $
[630]	3	!
	4	SUBROUTINE integrd_p
	5	$ ( nq,vcovm1,ucovm1,tetam1,psm1,massem1,
[764]	6	$ dv,du,dteta,dq,dp,vcov,ucov,teta,q,ps0,masse,phis,finvmaold)
[630]	7	USE parallel
[1446]	8	USE control_mod, only : planet_type
[630]	9	IMPLICIT NONE
	10
	11
	12	c=======================================================================
	13	c
	14	c Auteur: P. Le Van
	15	c -------
	16	c
	17	c objet:
	18	c ------
	19	c
	20	c Incrementation des tendances dynamiques
	21	c
	22	c=======================================================================
	23	c-----------------------------------------------------------------------
	24	c Declarations:
	25	c -------------
	26
	27	#include "dimensions.h"
	28	#include "paramet.h"
	29	#include "comconst.h"
	30	#include "comgeom.h"
	31	#include "comvert.h"
	32	#include "logic.h"
	33	#include "temps.h"
	34	#include "serre.h"
	35
	36	c Arguments:
	37	c ----------
	38
	39	INTEGER nq
	40
	41	REAL vcov(ip1jm,llm),ucov(ip1jmp1,llm),teta(ip1jmp1,llm)
	42	REAL q(ip1jmp1,llm,nq)
[764]	43	REAL ps0(ip1jmp1),masse(ip1jmp1,llm),phis(ip1jmp1)
[630]	44
	45	REAL vcovm1(ip1jm,llm),ucovm1(ip1jmp1,llm)
	46	REAL tetam1(ip1jmp1,llm),psm1(ip1jmp1),massem1(ip1jmp1,llm)
	47
	48	REAL dv(ip1jm,llm),du(ip1jmp1,llm)
	49	REAL dteta(ip1jmp1,llm),dp(ip1jmp1)
	50	REAL dq(ip1jmp1,llm,nq), finvmaold(ip1jmp1,llm)
	51
	52	c Local:
	53	c ------
	54
	55	REAL vscr( ip1jm ),uscr( ip1jmp1 ),hscr( ip1jmp1 ),pscr(ip1jmp1)
	56	REAL massescr( ip1jmp1,llm ), finvmasse(ip1jmp1,llm)
[764]	57	REAL,SAVE :: p(ip1jmp1,llmp1)
[630]	58	REAL tpn,tps,tppn(iim),tpps(iim)
	59	REAL qpn,qps,qppn(iim),qpps(iim)
[985]	60	REAL,SAVE :: deltap( ip1jmp1,llm )
[630]	61
	62	INTEGER l,ij,iq
	63
	64	REAL SSUM
	65	EXTERNAL SSUM
	66	INTEGER ijb,ije,jjb,jje
[764]	67	REAL,SAVE :: ps(ip1jmp1)
[985]	68	LOGICAL :: checksum
	69	INTEGER :: stop_it
[630]	70	c-----------------------------------------------------------------------
[985]	71	c$OMP BARRIER
[630]	72	if (pole_nord) THEN
[764]	73	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
[630]	74	DO l = 1,llm
	75	DO ij = 1,iip1
	76	ucov( ij , l) = 0.
	77	uscr( ij ) = 0.
	78	ENDDO
	79	ENDDO
[764]	80	c$OMP END DO NOWAIT
[630]	81	ENDIF
	82
	83	if (pole_sud) THEN
[764]	84	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
[630]	85	DO l = 1,llm
	86	DO ij = 1,iip1
	87	ucov( ij +ip1jm, l) = 0.
	88	uscr( ij +ip1jm ) = 0.
	89	ENDDO
	90	ENDDO
[764]	91	c$OMP END DO NOWAIT
[630]	92	ENDIF
	93
	94	c ............ integration de ps ..............
	95
	96	c CALL SCOPY(ip1jmp1*llm, masse, 1, massescr, 1)
	97
	98	ijb=ij_begin
	99	ije=ij_end
[764]	100	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
	101	DO l = 1,llm
	102	massescr(ijb:ije,l)=masse(ijb:ije,l)
	103	ENDDO
	104	c$OMP END DO NOWAIT
	105
[985]	106	c$OMP DO SCHEDULE(STATIC)
[630]	107	DO 2 ij = ijb,ije
[764]	108	pscr (ij) = ps0(ij)
[630]	109	ps (ij) = psm1(ij) + dt * dp(ij)
	110	2 CONTINUE
[985]	111	c$OMP END DO
	112	c$OMP BARRIER
	113	c --> ici synchro OPENMP pour ps
	114
	115	checksum=.TRUE.
	116	stop_it=0
	117
	118	c$OMP DO SCHEDULE(STATIC)
[630]	119	DO ij = ijb,ije
[985]	120	IF( ps(ij).LT.0. ) THEN
	121	IF (checksum) stop_it=ij
	122	checksum=.FALSE.
	123	ENDIF
	124	ENDDO
	125	c$OMP END DO NOWAIT
	126
	127	IF( .NOT. checksum ) THEN
	128	PRINT*,' Au point ij = ',stop_it, ' , pression sol neg. '
	129	& , ps(stop_it)
[630]	130	STOP' dans integrd'
	131	ENDIF
[985]	132
[630]	133	c
[985]	134	C$OMP MASTER
[630]	135	if (pole_nord) THEN
	136
	137	DO ij = 1, iim
	138	tppn(ij) = aire( ij ) * ps( ij )
	139	ENDDO
	140	tpn = SSUM(iim,tppn,1)/apoln
	141	DO ij = 1, iip1
	142	ps( ij ) = tpn
	143	ENDDO
	144
	145	ENDIF
	146
	147	if (pole_sud) THEN
	148
	149	DO ij = 1, iim
	150	tpps(ij) = aire(ij+ip1jm) * ps(ij+ip1jm)
	151	ENDDO
	152	tps = SSUM(iim,tpps,1)/apols
	153	DO ij = 1, iip1
	154	ps(ij+ip1jm) = tps
	155	ENDDO
	156
	157	ENDIF
[764]	158	c$OMP END MASTER
	159	c$OMP BARRIER
[630]	160	c
	161	c ... Calcul de la nouvelle masse d'air au dernier temps integre t+1 ...
	162	c
[764]	163
[630]	164	CALL pression_p ( ip1jmp1, ap, bp, ps, p )
[764]	165	c$OMP BARRIER
[630]	166	CALL massdair_p ( p , masse )
	167
	168	c CALL SCOPY( ijp1llm , masse, 1, finvmasse, 1 )
	169	ijb=ij_begin
	170	ije=ij_end
[764]	171
	172	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
	173	DO l = 1,llm
	174	finvmasse(ijb:ije,l)=masse(ijb:ije,l)
	175	ENDDO
	176	c$OMP END DO NOWAIT
[630]	177
	178	jjb=jj_begin
	179	jje=jj_end
	180	CALL filtreg_p( finvmasse,jjb,jje, jjp1, llm, -2, 2, .TRUE., 1 )
	181	c
	182
	183	c ............ integration de ucov, vcov, h ..............
	184
[764]	185	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
[630]	186	DO 10 l = 1,llm
	187
	188	ijb=ij_begin
	189	ije=ij_end
	190	if (pole_nord) ijb=ij_begin+iip1
	191	if (pole_sud) ije=ij_end-iip1
	192
	193	DO 4 ij = ijb,ije
	194	uscr( ij ) = ucov( ij,l )
	195	ucov( ij,l ) = ucovm1( ij,l ) + dt * du( ij,l )
	196	4 CONTINUE
	197
	198	ijb=ij_begin
	199	ije=ij_end
	200	if (pole_sud) ije=ij_end-iip1
	201
	202	DO 5 ij = ijb,ije
	203	vscr( ij ) = vcov( ij,l )
	204	vcov( ij,l ) = vcovm1( ij,l ) + dt * dv( ij,l )
	205	5 CONTINUE
	206
	207	ijb=ij_begin
	208	ije=ij_end
	209
	210	DO 6 ij = ijb,ije
	211	hscr( ij ) = teta(ij,l)
	212	teta ( ij,l ) = tetam1(ij,l) * massem1(ij,l) / masse(ij,l)
	213	$ + dt * dteta(ij,l) / masse(ij,l)
	214	6 CONTINUE
	215
	216	c .... Calcul de la valeur moyenne, unique aux poles pour teta ......
	217	c
	218	c
	219	IF (pole_nord) THEN
	220
	221	DO ij = 1, iim
	222	tppn(ij) = aire( ij ) * teta( ij ,l)
	223	ENDDO
	224	tpn = SSUM(iim,tppn,1)/apoln
	225
	226	DO ij = 1, iip1
	227	teta( ij ,l) = tpn
	228	ENDDO
	229
	230	ENDIF
	231
	232	IF (pole_sud) THEN
	233
	234	DO ij = 1, iim
	235	tpps(ij) = aire(ij+ip1jm) * teta(ij+ip1jm,l)
	236	ENDDO
	237	tps = SSUM(iim,tpps,1)/apols
	238
	239	DO ij = 1, iip1
	240	teta(ij+ip1jm,l) = tps
	241	ENDDO
	242
	243	ENDIF
	244	c
	245
	246	IF(leapf) THEN
	247	c CALL SCOPY ( ip1jmp1, uscr(1), 1, ucovm1(1, l), 1 )
	248	c CALL SCOPY ( ip1jm, vscr(1), 1, vcovm1(1, l), 1 )
	249	c CALL SCOPY ( ip1jmp1, hscr(1), 1, tetam1(1, l), 1 )
	250	ijb=ij_begin
	251	ije=ij_end
	252	ucovm1(ijb:ije,l)=uscr(ijb:ije)
	253	tetam1(ijb:ije,l)=hscr(ijb:ije)
	254	if (pole_sud) ije=ij_end-iip1
	255	vcovm1(ijb:ije,l)=vscr(ijb:ije)
	256
	257	END IF
	258
	259	10 CONTINUE
[764]	260	c$OMP END DO NOWAIT
[630]	261
	262	c
	263	c ....... integration de q ......
	264	c
	265	ijb=ij_begin
	266	ije=ij_end
[1279]	267
	268	if (planet_type.eq."earth") then
	269	! Earth-specific treatment of first 2 tracers (water)
[985]	270	c$OMP BARRIER
	271	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
[1279]	272	DO l = 1, llm
	273	DO ij = ijb, ije
	274	deltap(ij,l) = p(ij,l) - p(ij,l+1)
	275	ENDDO
[630]	276	ENDDO
[985]	277	c$OMP END DO NOWAIT
	278	c$OMP BARRIER
[630]	279
[1279]	280	CALL qminimum_p( q, nq, deltap )
[630]	281	c
	282	c ..... Calcul de la valeur moyenne, unique aux poles pour q .....
	283	c
[985]	284	c$OMP BARRIER
[630]	285	IF (pole_nord) THEN
	286
	287	DO iq = 1, nq
[985]	288
	289	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
[630]	290	DO l = 1, llm
	291
	292	DO ij = 1, iim
	293	qppn(ij) = aire( ij ) * q( ij ,l,iq)
	294	ENDDO
	295	qpn = SSUM(iim,qppn,1)/apoln
	296
	297	DO ij = 1, iip1
	298	q( ij ,l,iq) = qpn
	299	ENDDO
	300
	301	ENDDO
[985]	302	c$OMP END DO NOWAIT
	303
[630]	304	ENDDO
	305
	306	ENDIF
	307
	308	IF (pole_sud) THEN
	309
	310	DO iq = 1, nq
[985]	311
	312	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
[630]	313	DO l = 1, llm
	314
	315	DO ij = 1, iim
	316	qpps(ij) = aire(ij+ip1jm) * q(ij+ip1jm,l,iq)
	317	ENDDO
	318	qps = SSUM(iim,qpps,1)/apols
	319
	320	DO ij = 1, iip1
	321	q(ij+ip1jm,l,iq) = qps
	322	ENDDO
	323
	324	ENDDO
[985]	325	c$OMP END DO NOWAIT
	326
[630]	327	ENDDO
	328
	329	ENDIF
[764]	330
[630]	331	c CALL SCOPY( ijp1llm , finvmasse, 1, finvmaold, 1 )
[764]	332
	333	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
	334	DO l = 1, llm
	335	finvmaold(ijb:ije,l)=finvmasse(ijb:ije,l)
	336	ENDDO
	337	c$OMP END DO NOWAIT
[1446]	338
	339	endif ! of if (planet_type.eq."earth")
	340
[630]	341	c
	342	c
	343	c ..... FIN de l'integration de q .......
	344
	345	15 continue
	346
[985]	347	c$OMP DO SCHEDULE(STATIC)
	348	DO ij=ijb,ije
	349	ps0(ij)=ps(ij)
	350	ENDDO
	351	c$OMP END DO NOWAIT
	352
[630]	353	c .................................................................
	354
	355
	356	IF( leapf ) THEN
	357	c CALL SCOPY ( ip1jmp1 , pscr , 1, psm1 , 1 )
	358	c CALL SCOPY ( ip1jmp1*llm, massescr, 1, massem1, 1 )
[985]	359	c$OMP DO SCHEDULE(STATIC)
	360	DO ij=ijb,ije
	361	psm1(ij)=pscr(ij)
	362	ENDDO
	363	c$OMP END DO NOWAIT
[764]	364
	365	c$OMP DO SCHEDULE(STATIC,OMP_CHUNK)
	366	DO l = 1, llm
	367	massem1(ijb:ije,l)=massescr(ijb:ije,l)
	368	ENDDO
	369	c$OMP END DO NOWAIT
[630]	370	END IF
[985]	371	c$OMP BARRIER
[630]	372	RETURN
	373	END

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