Context Navigation

source: codes/icosagcm/trunk/src/timeloop_gcm.f90 @ 473

Last change on this file since 473 was 473, checked in by ymipsl, 8 years ago

Repairing openMP :
Only master thread may call XIOS

YM

File size: 13.8 KB

Line
1	MODULE timeloop_gcm_mod
2	USE icosa
3	USE disvert_mod
4	USE trace
5	USE omp_para
6	USE euler_scheme_mod
7	USE explicit_scheme_mod
8	USE hevi_scheme_mod
9	IMPLICIT NONE
10	PRIVATE
11
12	INTEGER, PARAMETER :: itau_sync=10
13	TYPE(t_message),SAVE :: req_ps0, req_mass0, req_theta_rhodz0, req_u0, req_q0, req_W0, req_geopot0
14	LOGICAL, SAVE :: positive_theta
15
16	PUBLIC :: init_timeloop, timeloop
17
18	CONTAINS
19
20	SUBROUTINE init_timeloop
21	USE dissip_gcm_mod
22	USE observable_mod
23	USE caldyn_mod
24	USE etat0_mod
25	USE guided_mod
26	USE advect_tracer_mod
27	USE check_conserve_mod
28	USE output_field_mod
29	USE theta2theta_rhodz_mod
30	USE sponge_mod
31
32	CHARACTER(len=255) :: def
33
34	CALL init_caldyn
35
36	! IF (xios_output) itau_out=1
37	IF (.NOT. enable_io) itau_out=HUGE(itau_out)
38
39	positive_theta=.FALSE.
40	CALL getin('positive_theta',positive_theta)
41	IF(positive_theta .AND. nqtot<1) THEN
42	PRINT *, 'nqtot must be >0 if positive_theta is .TRUE.'
43	STOP
44	END IF
45
46	def='ARK2.3'
47	CALL getin('time_scheme',def)
48	SELECT CASE (TRIM(def))
49	CASE('euler')
50	scheme_family=explicit
51	scheme=euler
52	nb_stage=1
53	CASE ('runge_kutta')
54	scheme_family=explicit
55	scheme=rk4
56	nb_stage=4
57	CASE ('RK2.5')
58	scheme_family=explicit
59	scheme=rk25
60	nb_stage=5
61	CASE ('leapfrog_matsuno')
62	scheme_family=explicit
63	scheme=mlf
64	matsuno_period=5
65	CALL getin('matsuno_period',matsuno_period)
66	nb_stage=matsuno_period+1
67	CASE('ARK2.3')
68	scheme_family=hevi
69	scheme=ark23
70	nb_stage=3
71	CALL set_coefs_ark23(dt)
72	CASE('ARK3.3')
73	scheme_family=hevi
74	scheme=ark33
75	nb_stage=3
76	CALL set_coefs_ark33(dt)
77	CASE ('none')
78	nb_stage=0
79	CASE default
80	PRINT*,'Bad selector for variable scheme : <', TRIM(def), &
81	' > options are <euler>, <runge_kutta>, <leapfrog_matsuno>,<RK2.5>,<ARK2.3>'
82	STOP
83	END SELECT
84
85	! Time-independant orography
86	CALL allocate_field(f_phis,field_t,type_real,name='phis')
87	! Model state at current time step
88	CALL allocate_field(f_ps,field_t,type_real, name='ps')
89	CALL allocate_field(f_mass,field_t,type_real,llm,name='mass')
90	CALL allocate_field(f_rhodz,field_t,type_real,llm,name='rhodz')
91	CALL allocate_field(f_theta_rhodz,field_t,type_real,llm,nqdyn,name='theta_rhodz')
92	CALL allocate_field(f_u,field_u,type_real,llm,name='u')
93	CALL allocate_field(f_geopot,field_t,type_real,llm+1,name='geopot')
94	CALL allocate_field(f_W,field_t,type_real,llm+1,name='W')
95	CALL allocate_field(f_q,field_t,type_real,llm,nqtot,'q')
96	! Mass fluxes
97	CALL allocate_field(f_hflux,field_u,type_real,llm) ! instantaneous mass fluxes
98	CALL allocate_field(f_hfluxt,field_u,type_real,llm) ! mass "fluxes" accumulated in time
99	CALL allocate_field(f_wflux,field_t,type_real,llm+1) ! vertical mass fluxes
100	CALL allocate_field(f_wfluxt,field_t,type_real,llm+1,name='wfluxt')
101
102	SELECT CASE(scheme_family)
103	CASE(explicit)
104	! Trends
105	CALL allocate_field(f_dps,field_t,type_real,name='dps')
106	CALL allocate_field(f_dmass,field_t,type_real,llm, name='dmass')
107	CALL allocate_field(f_dtheta_rhodz,field_t,type_real,llm,nqdyn,name='dtheta_rhodz')
108	CALL allocate_field(f_du,field_u,type_real,llm,name='du')
109	! Model state at previous time step (RK/MLF)
110	CALL allocate_field(f_psm1,field_t,type_real,name='psm1')
111	CALL allocate_field(f_massm1,field_t,type_real,llm, name='massm1')
112	CALL allocate_field(f_theta_rhodzm1,field_t,type_real,llm,nqdyn,name='theta_rhodzm1')
113	CALL allocate_field(f_um1,field_u,type_real,llm,name='um1')
114	CASE(hevi)
115	! Trends
116	CALL allocate_fields(nb_stage,f_dps_slow, field_t,type_real,name='dps_slow')
117	CALL allocate_fields(nb_stage,f_dmass_slow, field_t,type_real,llm, name='dmass_slow')
118	CALL allocate_fields(nb_stage,f_dtheta_rhodz_slow, field_t,type_real,llm,nqdyn,name='dtheta_rhodz_fast')
119	CALL allocate_fields(nb_stage,f_du_slow, field_u,type_real,llm,name='du_slow')
120	CALL allocate_fields(nb_stage,f_du_fast, field_u,type_real,llm,name='du_fast')
121	CALL allocate_fields(nb_stage,f_dW_slow, field_t,type_real,llm+1,name='dW_slow')
122	CALL allocate_fields(nb_stage,f_dW_fast, field_t,type_real,llm+1,name='dW_fast')
123	CALL allocate_fields(nb_stage,f_dPhi_slow, field_t,type_real,llm+1,name='dPhi_slow')
124	CALL allocate_fields(nb_stage,f_dPhi_fast, field_t,type_real,llm+1,name='dPhi_fast')
125	f_dps => f_dps_slow(:,1)
126	f_du => f_du_slow(:,1)
127	f_dtheta_rhodz => f_dtheta_rhodz_slow(:,1)
128	END SELECT
129
130	SELECT CASE(scheme)
131	CASE(mlf)
132	! Model state 2 time steps ago (MLF)
133	CALL allocate_field(f_psm2,field_t,type_real)
134	CALL allocate_field(f_massm2,field_t,type_real,llm)
135	CALL allocate_field(f_theta_rhodzm2,field_t,type_real,llm,nqdyn)
136	CALL allocate_field(f_um2,field_u,type_real,llm)
137	END SELECT
138
139	CALL init_theta2theta_rhodz
140	CALL init_dissip
141	CALL init_sponge
142	CALL init_observable
143	CALL init_guided
144	CALL init_advect_tracer
145	CALL init_check_conserve
146
147	CALL etat0(f_ps,f_mass,f_phis,f_theta_rhodz,f_u, f_geopot,f_W, f_q)
148
149	CALL transfert_request(f_phis,req_i0)
150	CALL transfert_request(f_phis,req_i1)
151
152	CALL init_message(f_ps,req_i0,req_ps0)
153	CALL init_message(f_mass,req_i0,req_mass0)
154	CALL init_message(f_theta_rhodz,req_i0,req_theta_rhodz0)
155	CALL init_message(f_u,req_e0_vect,req_u0)
156	CALL init_message(f_q,req_i0,req_q0)
157	CALL init_message(f_geopot,req_i0,req_geopot0)
158	CALL init_message(f_W,req_i0,req_W0)
159
160	END SUBROUTINE init_timeloop
161
162	SUBROUTINE timeloop
163	USE dissip_gcm_mod
164	USE sponge_mod
165	USE observable_mod
166	USE etat0_mod
167	USE guided_mod
168	USE caldyn_mod
169	USE advect_tracer_mod
170	USE physics_mod
171	USE mpipara
172	USE transfert_mod
173	USE check_conserve_mod
174	USE xios_mod
175	USE output_field_mod
176	USE write_etat0_mod
177	USE checksum_mod
178	USE explicit_scheme_mod
179	USE hevi_scheme_mod
180	REAL(rstd),POINTER :: rhodz(:,:), mass(:,:), ps(:)
181
182	INTEGER :: ind
183	INTEGER :: it,i,j,l,n, stage
184	LOGICAL :: fluxt_zero(ndomain) ! set to .TRUE. to start accumulating fluxes in time
185	LOGICAL, PARAMETER :: check_rhodz=.FALSE.
186	INTEGER :: start_clock, stop_clock, rate_clock
187	LOGICAL,SAVE :: first_physic=.TRUE.
188	!$OMP THREADPRIVATE(first_physic)
189
190	CALL switch_omp_distrib_level
191	CALL caldyn_BC(f_phis, f_geopot, f_wflux) ! set constant values in first/last interfaces
192
193	!$OMP BARRIER
194	DO ind=1,ndomain
195	IF (.NOT. assigned_domain(ind)) CYCLE
196	CALL swap_dimensions(ind)
197	CALL swap_geometry(ind)
198	rhodz=f_rhodz(ind); mass=f_mass(ind); ps=f_ps(ind)
199	IF(caldyn_eta==eta_mass) THEN
200	CALL compute_rhodz(.TRUE., ps, rhodz) ! save rhodz for transport scheme before dynamics update ps
201	ELSE
202	DO l=ll_begin,ll_end
203	rhodz(:,l)=mass(:,l)
204	ENDDO
205	END IF
206	END DO
207	!$OMP BARRIER
208	fluxt_zero=.TRUE.
209
210	IF(positive_theta) CALL copy_theta_to_q(f_theta_rhodz,f_rhodz,f_q)
211
212	!$OMP MASTER
213	CALL SYSTEM_CLOCK(start_clock)
214	CALL SYSTEM_CLOCK(count_rate=rate_clock)
215	!$OMP END MASTER
216
217	CALL check_conserve(f_ps,f_dps,f_u,f_theta_rhodz,f_phis,itau0)
218
219	CALL trace_on
220
221	IF (xios_output) THEN ! we must call update_calendar before any XIOS output
222	IF (is_omp_master) CALL xios_update_calendar(1)
223	END IF
224	CALL write_output_fields_basic(.TRUE., f_phis, f_ps, f_mass, f_geopot, f_theta_rhodz, f_u, f_W, f_q)
225
226	DO it=itau0+1,itau0+itaumax
227
228	IF (is_master) CALL print_iteration(it, itau0, itaumax, start_clock, rate_clock)
229
230	IF (xios_output) THEN
231
232	IF(it>itau0+1 .AND. is_omp_master) CALL xios_update_calendar(it-itau0)
233	ELSE
234	CALL update_time_counter(dt*it)
235	END IF
236
237	IF (it==itau0+1 .OR. MOD(it,itau_sync)==0) THEN
238	CALL send_message(f_ps,req_ps0)
239	CALL wait_message(req_ps0)
240	CALL send_message(f_mass,req_mass0)
241	CALL wait_message(req_mass0)
242	CALL send_message(f_theta_rhodz,req_theta_rhodz0)
243	CALL wait_message(req_theta_rhodz0)
244	CALL send_message(f_u,req_u0)
245	CALL wait_message(req_u0)
246	CALL send_message(f_q,req_q0)
247	CALL wait_message(req_q0)
248	IF(.NOT. hydrostatic) THEN
249	! CALL send_message(f_geopot,req_geopot0)
250	! CALL wait_message(req_geopot0)
251	! CALL send_message(f_W,req_W0)
252	! CALL wait_message(req_W0)
253	END IF
254	ENDIF
255
256	CALL guided(it*dt,f_ps,f_theta_rhodz,f_u,f_q)
257
258	SELECT CASE(scheme_family)
259	CASE(explicit)
260	CALL explicit_scheme(it, fluxt_zero)
261	CASE(hevi)
262	CALL HEVI_scheme(it, fluxt_zero)
263	END SELECT
264
265	IF (MOD(it,itau_dissip)==0) THEN
266
267	IF(caldyn_eta==eta_mass) THEN
268	!ym flush ps
269	!$OMP BARRIER
270	DO ind=1,ndomain
271	IF (.NOT. assigned_domain(ind)) CYCLE
272	CALL swap_dimensions(ind)
273	CALL swap_geometry(ind)
274	mass=f_mass(ind); ps=f_ps(ind);
275	CALL compute_rhodz(.TRUE., ps, mass)
276	END DO
277	ENDIF
278
279	CALL check_conserve_detailed(it, AAM_dyn, &
280	f_ps,f_dps,f_u,f_theta_rhodz,f_phis)
281
282	CALL dissip(f_u,f_du,f_mass,f_phis, f_theta_rhodz,f_dtheta_rhodz)
283
284	CALL euler_scheme(.FALSE.) ! update only u, theta
285	IF (iflag_sponge > 0) THEN
286	CALL sponge(f_u,f_du,f_theta_rhodz,f_dtheta_rhodz)
287	CALL euler_scheme(.FALSE.) ! update only u, theta
288	END IF
289
290	CALL check_conserve_detailed(it, AAM_dissip, &
291	f_ps,f_dps,f_u,f_theta_rhodz,f_phis)
292	END IF
293
294	IF(MOD(it,itau_adv)==0) THEN
295	CALL advect_tracer(f_hfluxt,f_wfluxt,f_u, f_q,f_rhodz) ! update q and rhodz after RK step
296	fluxt_zero=.TRUE.
297	! FIXME : check that rhodz is consistent with ps
298	IF (check_rhodz) THEN
299	DO ind=1,ndomain
300	IF (.NOT. assigned_domain(ind)) CYCLE
301	CALL swap_dimensions(ind)
302	CALL swap_geometry(ind)
303	rhodz=f_rhodz(ind); ps=f_ps(ind);
304	CALL compute_rhodz(.FALSE., ps, rhodz)
305	END DO
306	ENDIF
307	IF(positive_theta) CALL copy_q_to_theta(f_theta_rhodz,f_rhodz,f_q)
308	END IF
309
310	IF (MOD(it,itau_physics)==0) THEN
311	CALL check_conserve_detailed(it, AAM_dyn, &
312	f_ps,f_dps,f_u,f_theta_rhodz,f_phis)
313	CALL physics(it,f_phis, f_ps, f_theta_rhodz, f_u, f_wflux, f_q)
314	CALL check_conserve_detailed(it, AAM_phys, &
315	f_ps,f_dps,f_u,f_theta_rhodz,f_phis)
316	!$OMP MASTER
317	IF (first_physic) CALL SYSTEM_CLOCK(start_clock)
318	!$OMP END MASTER
319	first_physic=.FALSE.
320	END IF
321
322	IF (MOD(it,itau_check_conserv)==0) THEN
323	CALL check_conserve_detailed(it, AAM_dyn, &
324	f_ps,f_dps,f_u,f_theta_rhodz,f_phis)
325	CALL check_conserve(f_ps,f_dps,f_u,f_theta_rhodz,f_phis,it)
326	ENDIF
327
328	IF (mod(it,itau_out)==0 ) THEN
329	CALL transfert_request(f_u,req_e1_vect)
330	CALL write_output_fields_basic(.FALSE.,f_phis, f_ps, f_mass, f_geopot, f_theta_rhodz, f_u, f_W, f_q)
331	ENDIF
332
333	END DO
334
335	! CALL write_etat0(itau0+itaumax,f_ps, f_phis,f_theta_rhodz,f_u,f_q)
336
337	CALL check_conserve_detailed(it, AAM_dyn, &
338	f_ps,f_dps,f_u,f_theta_rhodz,f_phis)
339	CALL check_conserve(f_ps,f_dps,f_u,f_theta_rhodz,f_phis,it)
340
341	!$OMP MASTER
342	CALL SYSTEM_CLOCK(stop_clock)
343
344	IF (mpi_rank==0) THEN
345	PRINT ,"Time elapsed : ",(stop_clock-start_clock)1./rate_clock
346	ENDIF
347	!$OMP END MASTER
348
349	! CONTAINS
350	END SUBROUTINE timeloop
351
352	SUBROUTINE print_iteration(it,itau0,itaumax,start_clock,rate_clock)
353	INTEGER :: it, itau0, itaumax, start_clock, stop_clock, rate_clock, throughput
354	REAL :: per_step,total, elapsed
355	WRITE(,'(A,I7,A,F14.1)') "It No :",it," t :",dtit
356	IF(MOD(it,10)==0) THEN
357	CALL SYSTEM_CLOCK(stop_clock)
358	elapsed = (stop_clock-start_clock)*1./rate_clock
359	per_step = elapsed/(it-itau0)
360	throughput = dt/per_step
361	total = per_step*(itaumax-itau0)
362	WRITE(*,'(A,I5,A,F6.2,A,I6)') 'Time spent (s):',INT(elapsed), &
363	' -- ms/step : ', 1000*per_step, &
364	' -- Throughput :', throughput
365	WRITE(*,'(A,I5,A,I5)') 'Whole job (min) :', INT(total/60.), &
366	' -- Completion in (min) : ', INT((total-elapsed)/60.)
367	END IF
368	END SUBROUTINE print_iteration
369
370	SUBROUTINE copy_theta_to_q(f_theta_rhodz,f_rhodz,f_q)
371	TYPE(t_field),POINTER :: f_theta_rhodz(:),f_rhodz(:), f_q(:)
372	REAL(rstd), POINTER :: theta_rhodz(:,:,:), rhodz(:,:), q(:,:,:)
373	INTEGER :: ind, iq
374	DO ind=1, ndomain
375	IF (.NOT. assigned_domain(ind)) CYCLE
376	CALL swap_dimensions(ind)
377	CALL swap_geometry(ind)
378	theta_rhodz=f_theta_rhodz(ind)
379	rhodz=f_rhodz(ind)
380	q=f_q(ind)
381	DO iq=1, nqdyn
382	q(:,:,iq) = theta_rhodz(:,:,iq)/rhodz(:,:)
383	END DO
384	END DO
385	END SUBROUTINE copy_theta_to_q
386
387	SUBROUTINE copy_q_to_theta(f_theta_rhodz,f_rhodz,f_q)
388	TYPE(t_field),POINTER :: f_theta_rhodz(:),f_rhodz(:), f_q(:)
389	REAL(rstd), POINTER :: theta_rhodz(:,:,:), rhodz(:,:), q(:,:,:)
390	INTEGER :: ind, iq
391	DO ind=1, ndomain
392	IF (.NOT. assigned_domain(ind)) CYCLE
393	CALL swap_dimensions(ind)
394	CALL swap_geometry(ind)
395	theta_rhodz=f_theta_rhodz(ind)
396	rhodz=f_rhodz(ind)
397	q=f_q(ind)
398	DO iq=1,nqdyn
399	theta_rhodz(:,:,iq) = rhodz(:,:)*q(:,:,iq)
400	END DO
401	END DO
402	END SUBROUTINE copy_q_to_theta
403
404	END MODULE timeloop_gcm_mod

Note: See TracBrowser for help on using the repository browser.

Download in other formats: