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source: palm/trunk/SOURCE/poismg_mod.f90 @ 2020

Last change on this file since 2020 was 2001, checked in by knoop, 8 years ago
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1	!> @file poismg.f90
2	!------------------------------------------------------------------------------!
3	! This file is part of PALM.
4	!
5	! PALM is free software: you can redistribute it and/or modify it under the
6	! terms of the GNU General Public License as published by the Free Software
7	! Foundation, either version 3 of the License, or (at your option) any later
8	! version.
9	!
10	! PALM is distributed in the hope that it will be useful, but WITHOUT ANY
11	! WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
12	! A PARTICULAR PURPOSE. See the GNU General Public License for more details.
13	!
14	! You should have received a copy of the GNU General Public License along with
15	! PALM. If not, see <http://www.gnu.org/licenses/>.
16	!
17	! Copyright 1997-2016 Leibniz Universitaet Hannover
18	!------------------------------------------------------------------------------!
19	!
20	! Current revisions:
21	! -----------------
22	!
23	!
24	! Former revisions:
25	! -----------------
26	! $Id: poismg_mod.f90 2001 2016-08-20 18:41:22Z hellstea $
27	!
28	! 2000 2016-08-20 18:09:15Z knoop
29	! Forced header and separation lines into 80 columns
30	!
31	! 1934 2016-06-13 09:46:57Z hellstea
32	! Rename subroutines and cpu-measure log points to indicate default version
33	!
34	! 1904 2016-05-11 13:06:12Z suehring
35	! Bugfix: enable special_exchange_horiz only for finer grid levels.
36	! Some formatting adjustments and variable descriptions.
37	!
38	! 1898 2016-05-03 11:27:17Z suehring
39	! Bugfix: bottom and top boundary condition in resid_fast
40	! Bugfix: restriction at nzb+1
41	! formatting adjustments, variable descriptions added in some declaration blocks
42	!
43	! 1850 2016-04-08 13:29:27Z maronga
44	! Module renamed
45	!
46	!
47	! 1762 2016-02-25 12:31:13Z hellstea
48	! Introduction of nested domain feature
49	!
50	! 1682 2015-10-07 23:56:08Z knoop
51	! Code annotations made doxygen readable
52	!
53	! 1609 2015-07-03 15:37:58Z maronga
54	! Bugfix: allow compilation without __parallel.
55	!
56	! 1575 2015-03-27 09:56:27Z raasch
57	! Initial revision.
58	! Routine re-written and optimised based on poismg.
59	!
60	! Following optimisations have been made:
61	! - vectorisation (for Intel-CPUs) of the red-black algorithm by resorting
62	! array elements with even and odd indices
63	! - explicit boundary conditions for building walls removed (solver is
64	! running through the buildings
65	! - reduced data transfer in case of ghost point exchange, because only
66	! "red" or "black" data points need to be exchanged. This is not applied
67	! for coarser grid levels, since for then the transfer time is latency bound
68	!
69	!
70	! Description:
71	! ------------
72	!> Solves the Poisson equation for the perturbation pressure with a multigrid
73	!> V- or W-Cycle scheme.
74	!>
75	!> This multigrid method was originally developed for PALM by Joerg Uhlenbrock,
76	!> September 2000 - July 2001. It has been optimised for speed by Klaus
77	!> Ketelsen in November 2014.
78	!>
79	!> @attention Loop unrolling and cache optimization in SOR-Red/Black method
80	!> still does not give the expected speedup!
81	!>
82	!> @todo Further work required.
83	!------------------------------------------------------------------------------!
84	MODULE poismg_mod
85
86
87	USE cpulog, &
88	ONLY: cpu_log, log_point_s
89
90	USE kinds
91
92	USE pegrid
93
94	PRIVATE
95
96	INTEGER, SAVE :: ind_even_odd !< border index between even and odd k index
97	INTEGER, DIMENSION(:), SAVE, ALLOCATABLE :: even_odd_level !< stores ind_even_odd for all MG levels
98
99	REAL(wp), DIMENSION(:,:), SAVE, ALLOCATABLE :: f1_mg_b, f2_mg_b, f3_mg_b !< blocked version of f1_mg ...
100
101	INTERFACE poismg
102	MODULE PROCEDURE poismg
103	END INTERFACE poismg
104
105	INTERFACE sort_k_to_even_odd_blocks
106	MODULE PROCEDURE sort_k_to_even_odd_blocks
107	MODULE PROCEDURE sort_k_to_even_odd_blocks_int
108	MODULE PROCEDURE sort_k_to_even_odd_blocks_1d
109	END INTERFACE sort_k_to_even_odd_blocks
110
111	PUBLIC poismg
112
113	CONTAINS
114
115	!------------------------------------------------------------------------------!
116	! Description:
117	! ------------
118	!> Solves the Poisson equation for the perturbation pressure with a multigrid
119	!> V- or W-Cycle scheme.
120	!------------------------------------------------------------------------------!
121	SUBROUTINE poismg( r )
122
123	USE arrays_3d, &
124	ONLY: d, p_loc
125
126	USE control_parameters, &
127	ONLY: gathered_size, grid_level, grid_level_count, &
128	maximum_grid_level, message_string, mgcycles, mg_cycles, &
129	mg_switch_to_pe0_level, residual_limit, subdomain_size
130
131	USE cpulog, &
132	ONLY: cpu_log, log_point_s
133
134	USE indices, &
135	ONLY: nxl, nxlg, nxl_mg, nxr, nxrg, nxr_mg, nys, nysg, nys_mg, nyn,&
136	nyng, nyn_mg, nzb, nzt, nzt_mg
137
138	IMPLICIT NONE
139
140	REAL(wp) :: maxerror !<
141	REAL(wp) :: maximum_mgcycles !<
142	REAL(wp) :: residual_norm !<
143
144	REAL(wp), DIMENSION(nzb:nzt+1,nys-1:nyn+1,nxl-1:nxr+1) :: r !<
145
146	REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: p3 !<
147
148
149	CALL cpu_log( log_point_s(29), 'poismg', 'start' )
150	!
151	!-- Initialize arrays and variables used in this subroutine
152
153	!-- If the number of grid points of the gathered grid, which is collected
154	!-- on PE0, is larger than the number of grid points of an PE, than array
155	!-- p3 will be enlarged.
156	IF ( gathered_size > subdomain_size ) THEN
157	ALLOCATE( p3(nzb:nzt_mg(mg_switch_to_pe0_level)+1,nys_mg( &
158	mg_switch_to_pe0_level)-1:nyn_mg(mg_switch_to_pe0_level)+1,&
159	nxl_mg(mg_switch_to_pe0_level)-1:nxr_mg( &
160	mg_switch_to_pe0_level)+1) )
161	ELSE
162	ALLOCATE ( p3(nzb:nzt+1,nysg:nyng,nxlg:nxrg) )
163	ENDIF
164
165	p3 = 0.0_wp
166
167
168	!
169	!-- Ghost boundaries have to be added to divergence array.
170	!-- Exchange routine needs to know the grid level!
171	grid_level = maximum_grid_level
172	CALL exchange_horiz( d, 1)
173	d(nzb,:,:) = d(nzb+1,:,:)
174
175	!
176	!-- Initiation of the multigrid scheme. Does n cycles until the
177	!-- residual is smaller than the given limit. The accuracy of the solution
178	!-- of the poisson equation will increase with the number of cycles.
179	!-- If the number of cycles is preset by the user, this number will be
180	!-- carried out regardless of the accuracy.
181	grid_level_count = 0
182	mgcycles = 0
183	IF ( mg_cycles == -1 ) THEN
184	maximum_mgcycles = 0
185	residual_norm = 1.0_wp
186	ELSE
187	maximum_mgcycles = mg_cycles
188	residual_norm = 0.0_wp
189	ENDIF
190
191	!
192	!-- Initial settings for sorting k-dimension from sequential order (alternate
193	!-- even/odd) into blocks of even and odd or vice versa
194	CALL init_even_odd_blocks
195
196	!
197	!-- Sort input arrays in even/odd blocks along k-dimension
198	CALL sort_k_to_even_odd_blocks( d, grid_level )
199	CALL sort_k_to_even_odd_blocks( p_loc, grid_level )
200
201	!
202	!-- The complete multigrid cycles are running in block mode, i.e. over
203	!-- seperate data blocks of even and odd indices
204	DO WHILE ( residual_norm > residual_limit .OR. &
205	mgcycles < maximum_mgcycles )
206
207	CALL next_mg_level( d, p_loc, p3, r)
208
209	!
210	!-- Calculate the residual if the user has not preset the number of
211	!-- cycles to be performed
212	IF ( maximum_mgcycles == 0 ) THEN
213	CALL resid( d, p_loc, r )
214	maxerror = SUM( r(nzb+1:nzt,nys:nyn,nxl:nxr)**2 )
215
216	#if defined( __parallel )
217	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
218	CALL MPI_ALLREDUCE( maxerror, residual_norm, 1, MPI_REAL, &
219	MPI_SUM, comm2d, ierr)
220	#else
221	residual_norm = maxerror
222	#endif
223	residual_norm = SQRT( residual_norm )
224	ENDIF
225
226	mgcycles = mgcycles + 1
227
228	!
229	!-- If the user has not limited the number of cycles, stop the run in case
230	!-- of insufficient convergence
231	IF ( mgcycles > 1000 .AND. mg_cycles == -1 ) THEN
232	message_string = 'no sufficient convergence within 1000 cycles'
233	CALL message( 'poismg', 'PA0283', 1, 2, 0, 6, 0 )
234	ENDIF
235
236	ENDDO
237
238	DEALLOCATE( p3 )
239	!
240	!-- Result has to be sorted back from even/odd blocks to sequential order
241	CALL sort_k_to_sequential( p_loc )
242	!
243	!-- Unset the grid level. Variable is used to determine the MPI datatypes for
244	!-- ghost point exchange
245	grid_level = 0
246
247	CALL cpu_log( log_point_s(29), 'poismg', 'stop' )
248
249	END SUBROUTINE poismg
250
251
252	!------------------------------------------------------------------------------!
253	! Description:
254	! ------------
255	!> Computes the residual of the perturbation pressure.
256	!------------------------------------------------------------------------------!
257	SUBROUTINE resid( f_mg, p_mg, r )
258
259
260	USE arrays_3d, &
261	ONLY: f1_mg, f2_mg, f3_mg
262
263	USE control_parameters, &
264	ONLY: bc_lr_cyc, bc_ns_cyc, grid_level, ibc_p_b, ibc_p_t, inflow_l,&
265	inflow_n, inflow_r, inflow_s, nest_bound_l, nest_bound_n, &
266	nest_bound_r, nest_bound_s, outflow_l, outflow_n, outflow_r, &
267	outflow_s
268
269	USE grid_variables, &
270	ONLY: ddx2_mg, ddy2_mg
271
272	USE indices, &
273	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
274
275	IMPLICIT NONE
276
277	INTEGER(iwp) :: i !< index variable along x
278	INTEGER(iwp) :: j !< index variable along y
279	INTEGER(iwp) :: k !< index variable along z
280	INTEGER(iwp) :: l !< index indicating grid level
281	INTEGER(iwp) :: km1 !< index variable along z dimension (k-1)
282	INTEGER(iwp) :: kp1 !< index variable along z dimension (k+1)
283
284	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
285	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
286	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: f_mg !< velocity divergence
287	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
288	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
289	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: p_mg !< perturbation pressure
290	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
291	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
292	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: r !< residuum of perturbation pressure
293
294	!
295	!-- Calculate the residual
296	l = grid_level
297
298	CALL cpu_log( log_point_s(53), 'resid', 'start' )
299	!$OMP PARALLEL PRIVATE (i,j,k,km1,kp1)
300	!$OMP DO
301	DO i = nxl_mg(l), nxr_mg(l)
302	DO j = nys_mg(l), nyn_mg(l)
303	!DIR$ IVDEP
304	DO k = ind_even_odd+1, nzt_mg(l)
305	km1 = k-ind_even_odd-1
306	kp1 = k-ind_even_odd
307	r(k,j,i) = f_mg(k,j,i) &
308	- ddx2_mg(l) * &
309	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
310	- ddy2_mg(l) * &
311	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
312	- f2_mg_b(k,l) * p_mg(kp1,j,i) &
313	- f3_mg_b(k,l) * p_mg(km1,j,i) &
314	+ f1_mg_b(k,l) * p_mg(k,j,i)
315	ENDDO
316	!DIR$ IVDEP
317	DO k = nzb+1, ind_even_odd
318	km1 = k+ind_even_odd
319	kp1 = k+ind_even_odd+1
320	r(k,j,i) = f_mg(k,j,i) &
321	- ddx2_mg(l) * &
322	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
323	- ddy2_mg(l) * &
324	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
325	- f2_mg_b(k,l) * p_mg(kp1,j,i) &
326	- f3_mg_b(k,l) * p_mg(km1,j,i) &
327	+ f1_mg_b(k,l) * p_mg(k,j,i)
328	ENDDO
329	ENDDO
330	ENDDO
331	!$OMP END PARALLEL
332	!
333	!-- Horizontal boundary conditions
334	CALL exchange_horiz( r, 1)
335
336	IF ( .NOT. bc_lr_cyc ) THEN
337	IF ( inflow_l .OR. outflow_l .OR. nest_bound_l ) THEN
338	r(:,:,nxl_mg(l)-1) = r(:,:,nxl_mg(l))
339	ENDIF
340	IF ( inflow_r .OR. outflow_r .OR. nest_bound_r ) THEN
341	r(:,:,nxr_mg(l)+1) = r(:,:,nxr_mg(l))
342	ENDIF
343	ENDIF
344
345	IF ( .NOT. bc_ns_cyc ) THEN
346	IF ( inflow_n .OR. outflow_n .OR. nest_bound_n ) THEN
347	r(:,nyn_mg(l)+1,:) = r(:,nyn_mg(l),:)
348	ENDIF
349	IF ( inflow_s .OR. outflow_s .OR. nest_bound_s ) THEN
350	r(:,nys_mg(l)-1,:) = r(:,nys_mg(l),:)
351	ENDIF
352	ENDIF
353
354	!
355	!-- Boundary conditions at bottom and top of the domain. Points may be within
356	!-- buildings, but that doesn't matter.
357	IF ( ibc_p_b == 1 ) THEN
358	!
359	!-- equivalent to r(nzb,:,: ) = r(nzb+1,:,:)
360	r(nzb,:,: ) = r(ind_even_odd+1,:,:)
361	ELSE
362	r(nzb,:,: ) = 0.0_wp
363	ENDIF
364
365	IF ( ibc_p_t == 1 ) THEN
366	!
367	!-- equivalent to r(nzt_mg(l)+1,:,: ) = r(nzt_mg(l),:,:)
368	r(nzt_mg(l)+1,:,: ) = r(ind_even_odd,:,:)
369	ELSE
370	r(nzt_mg(l)+1,:,: ) = 0.0_wp
371	ENDIF
372
373	CALL cpu_log( log_point_s(53), 'resid', 'stop' )
374
375	END SUBROUTINE resid
376
377
378	!------------------------------------------------------------------------------!
379	! Description:
380	! ------------
381	!> Interpolates the residual on the next coarser grid with "full weighting"
382	!> scheme
383	!------------------------------------------------------------------------------!
384	SUBROUTINE restrict( f_mg, r )
385
386
387	USE control_parameters, &
388	ONLY: bc_lr_cyc, bc_ns_cyc, grid_level, ibc_p_b, ibc_p_t, inflow_l,&
389	inflow_n, inflow_r, inflow_s, nest_bound_l, nest_bound_n, &
390	nest_bound_r, nest_bound_s, outflow_l, outflow_n, outflow_r, &
391	outflow_s
392
393	USE indices, &
394	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
395
396	IMPLICIT NONE
397
398	INTEGER(iwp) :: i !< index variable along x on finer grid
399	INTEGER(iwp) :: ic !< index variable along x on coarser grid
400	INTEGER(iwp) :: j !< index variable along y on finer grid
401	INTEGER(iwp) :: jc !< index variable along y on coarser grid
402	INTEGER(iwp) :: k !< index variable along z on finer grid
403	INTEGER(iwp) :: kc !< index variable along z on coarser grid
404	INTEGER(iwp) :: l !< index indicating finer grid level
405	INTEGER(iwp) :: km1 !< index variable along z dimension (k-1 on finer level)
406	INTEGER(iwp) :: kp1 !< index variable along z dimension (k+1 on finer level)
407
408
409	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
410	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
411	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: &
412	f_mg !< Residual on coarser grid level
413
414	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level+1)+1, &
415	nys_mg(grid_level+1)-1:nyn_mg(grid_level+1)+1, &
416	nxl_mg(grid_level+1)-1:nxr_mg(grid_level+1)+1) :: &
417	r !< Residual on finer grid level
418
419	!
420	!-- Interpolate the residual
421	l = grid_level
422
423	CALL cpu_log( log_point_s(54), 'restrict', 'start' )
424	!
425	!-- No wall treatment
426	!$OMP PARALLEL PRIVATE (i,j,k,ic,jc,kc,km1,kp1)
427	DO ic = nxl_mg(l), nxr_mg(l)
428	i = 2*ic
429	!$OMP DO SCHEDULE( STATIC )
430	DO jc = nys_mg(l), nyn_mg(l)
431	!
432	!-- Calculation for the first point along k
433	j = 2*jc
434	!
435	!-- Calculation for the other points along k
436	!DIR$ IVDEP
437	DO k = ind_even_odd+1, nzt_mg(l+1) ! Fine grid at this point
438	km1 = k-ind_even_odd-1
439	kp1 = k-ind_even_odd
440	kc = k-ind_even_odd ! Coarse grid index
441
442	f_mg(kc,jc,ic) = 1.0_wp / 64.0_wp * ( &
443	8.0_wp * r(k,j,i) &
444	+ 4.0_wp * ( r(k,j,i-1) + r(k,j,i+1) + &
445	r(k,j+1,i) + r(k,j-1,i) ) &
446	+ 2.0_wp * ( r(k,j-1,i-1) + r(k,j+1,i-1) + &
447	r(k,j-1,i+1) + r(k,j+1,i+1) ) &
448	+ 4.0_wp * r(km1,j,i) &
449	+ 2.0_wp * ( r(km1,j,i-1) + r(km1,j,i+1) + &
450	r(km1,j+1,i) + r(km1,j-1,i) ) &
451	+ ( r(km1,j-1,i-1) + r(km1,j+1,i-1) + &
452	r(km1,j-1,i+1) + r(km1,j+1,i+1) ) &
453	+ 4.0_wp * r(kp1,j,i) &
454	+ 2.0_wp * ( r(kp1,j,i-1) + r(kp1,j,i+1) + &
455	r(kp1,j+1,i) + r(kp1,j-1,i) ) &
456	+ ( r(kp1,j-1,i-1) + r(kp1,j+1,i-1) + &
457	r(kp1,j-1,i+1) + r(kp1,j+1,i+1) ) &
458	)
459	ENDDO
460	ENDDO
461	!$OMP ENDDO nowait
462	ENDDO
463	!$OMP END PARALLEL
464
465	!
466	!-- Ghost point exchange
467	CALL exchange_horiz( f_mg, 1)
468	!
469	!-- Horizontal boundary conditions
470	IF ( .NOT. bc_lr_cyc ) THEN
471	IF ( inflow_l .OR. outflow_l .OR. nest_bound_l ) THEN
472	f_mg(:,:,nxl_mg(l)-1) = f_mg(:,:,nxl_mg(l))
473	ENDIF
474	IF ( inflow_r .OR. outflow_r .OR. nest_bound_r ) THEN
475	f_mg(:,:,nxr_mg(l)+1) = f_mg(:,:,nxr_mg(l))
476	ENDIF
477	ENDIF
478
479	IF ( .NOT. bc_ns_cyc ) THEN
480	IF ( inflow_n .OR. outflow_n .OR. nest_bound_n ) THEN
481	f_mg(:,nyn_mg(l)+1,:) = f_mg(:,nyn_mg(l),:)
482	ENDIF
483	IF ( inflow_s .OR. outflow_s .OR. nest_bound_s ) THEN
484	f_mg(:,nys_mg(l)-1,:) = f_mg(:,nys_mg(l),:)
485	ENDIF
486	ENDIF
487
488	!
489	!-- Boundary conditions at bottom and top of the domain.
490	!-- These points are not handled by the above loop. Points may be within
491	!-- buildings, but that doesn't matter. Remark: f_mg is ordered sequentielly
492	!-- after interpolation on coarse grid (is ordered in odd-even blocks further
493	!-- below).
494	IF ( ibc_p_b == 1 ) THEN
495	f_mg(nzb,:,: ) = f_mg(nzb+1,:,:)
496	ELSE
497	f_mg(nzb,:,: ) = 0.0_wp
498	ENDIF
499
500	IF ( ibc_p_t == 1 ) THEN
501	f_mg(nzt_mg(l)+1,:,: ) = f_mg(nzt_mg(l),:,:)
502	ELSE
503	f_mg(nzt_mg(l)+1,:,: ) = 0.0_wp
504	ENDIF
505
506	CALL cpu_log( log_point_s(54), 'restrict', 'stop' )
507	!
508	!-- Since residual is in sequential order after interpolation, an additional
509	!-- sorting in odd-even blocks along z dimension is required at this point.
510	CALL sort_k_to_even_odd_blocks( f_mg , l)
511
512	END SUBROUTINE restrict
513
514
515	!------------------------------------------------------------------------------!
516	! Description:
517	! ------------
518	!> Interpolates the correction of the perturbation pressure
519	!> to the next finer grid.
520	!------------------------------------------------------------------------------!
521	SUBROUTINE prolong( p, temp )
522
523
524	USE control_parameters, &
525	ONLY: bc_lr_cyc, bc_ns_cyc, grid_level, ibc_p_b, ibc_p_t, inflow_l,&
526	inflow_n, inflow_r, inflow_s, nest_bound_l, nest_bound_n, &
527	nest_bound_r, nest_bound_s, outflow_l, outflow_n, &
528	outflow_r, outflow_s
529
530	USE indices, &
531	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
532
533	IMPLICIT NONE
534
535	INTEGER(iwp) :: i !< index variable along x on coarser grid level
536	INTEGER(iwp) :: j !< index variable along y on coarser grid level
537	INTEGER(iwp) :: k !< index variable along z on coarser grid level
538	INTEGER(iwp) :: l !< index indicating finer grid level
539	INTEGER(iwp) :: kp1 !< index variable along z
540	INTEGER(iwp) :: ke !< index for prolog even
541	INTEGER(iwp) :: ko !< index for prolog odd
542
543	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level-1)+1, &
544	nys_mg(grid_level-1)-1:nyn_mg(grid_level-1)+1, &
545	nxl_mg(grid_level-1)-1:nxr_mg(grid_level-1)+1 ) :: &
546	p !< perturbation pressure on coarser grid level
547
548	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
549	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
550	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: &
551	temp !< perturbation pressure on finer grid level
552
553
554	CALL cpu_log( log_point_s(55), 'prolong', 'start' )
555
556	!
557	!-- First, store elements of the coarser grid on the next finer grid
558	l = grid_level
559	ind_even_odd = even_odd_level(grid_level-1)
560
561	!$OMP PARALLEL PRIVATE (i,j,k,kp1,ke,ko)
562	!$OMP DO
563	DO i = nxl_mg(l-1), nxr_mg(l-1)
564	DO j = nys_mg(l-1), nyn_mg(l-1)
565
566	!DIR$ IVDEP
567	DO k = ind_even_odd+1, nzt_mg(l-1)
568	kp1 = k - ind_even_odd
569	ke = 2 * ( k-ind_even_odd - 1 ) + 1
570	ko = 2 * k - 1
571	!
572	!-- Points of the coarse grid are directly stored on the next finer
573	!-- grid
574	temp(ko,2j,2i) = p(k,j,i)
575	!
576	!-- Points between two coarse-grid points
577	temp(ko,2j,2i+1) = 0.5_wp * ( p(k,j,i) + p(k,j,i+1) )
578	temp(ko,2j+1,2i) = 0.5_wp * ( p(k,j,i) + p(k,j+1,i) )
579	temp(ke,2j,2i) = 0.5_wp * ( p(k,j,i) + p(kp1,j,i) )
580	!
581	!-- Points in the center of the planes stretched by four points
582	!-- of the coarse grid cube
583	temp(ko,2j+1,2i+1) = 0.25_wp * ( p(k,j,i) + p(k,j,i+1) + &
584	p(k,j+1,i) + p(k,j+1,i+1) )
585	temp(ke,2j,2i+1) = 0.25_wp * ( p(k,j,i) + p(k,j,i+1) + &
586	p(kp1,j,i) + p(kp1,j,i+1) )
587	temp(ke,2j+1,2i) = 0.25_wp * ( p(k,j,i) + p(k,j+1,i) + &
588	p(kp1,j,i) + p(kp1,j+1,i) )
589	!
590	!-- Points in the middle of coarse grid cube
591	temp(ke,2j+1,2i+1) = 0.125_wp * &
592	( p(k,j,i) + p(k,j,i+1) + &
593	p(k,j+1,i) + p(k,j+1,i+1) + &
594	p(kp1,j,i) + p(kp1,j,i+1) + &
595	p(kp1,j+1,i) + p(kp1,j+1,i+1) )
596
597	ENDDO
598
599	!DIR$ IVDEP
600	DO k = nzb+1, ind_even_odd
601	kp1 = k + ind_even_odd + 1
602	ke = 2 * k
603	ko = 2 * ( k + ind_even_odd )
604	!
605	!-- Points of the coarse grid are directly stored on the next finer
606	!-- grid
607	temp(ko,2j,2i) = p(k,j,i)
608	!
609	!-- Points between two coarse-grid points
610	temp(ko,2j,2i+1) = 0.5_wp * ( p(k,j,i) + p(k,j,i+1) )
611	temp(ko,2j+1,2i) = 0.5_wp * ( p(k,j,i) + p(k,j+1,i) )
612	temp(ke,2j,2i) = 0.5_wp * ( p(k,j,i) + p(kp1,j,i) )
613	!
614	!-- Points in the center of the planes stretched by four points
615	!-- of the coarse grid cube
616	temp(ko,2j+1,2i+1) = 0.25_wp * ( p(k,j,i) + p(k,j,i+1) + &
617	p(k,j+1,i) + p(k,j+1,i+1) )
618	temp(ke,2j,2i+1) = 0.25_wp * ( p(k,j,i) + p(k,j,i+1) + &
619	p(kp1,j,i) + p(kp1,j,i+1) )
620	temp(ke,2j+1,2i) = 0.25_wp * ( p(k,j,i) + p(k,j+1,i) + &
621	p(kp1,j,i) + p(kp1,j+1,i) )
622	!
623	!-- Points in the middle of coarse grid cube
624	temp(ke,2j+1,2i+1) = 0.125_wp * &
625	( p(k,j,i) + p(k,j,i+1) + &
626	p(k,j+1,i) + p(k,j+1,i+1) + &
627	p(kp1,j,i) + p(kp1,j,i+1) + &
628	p(kp1,j+1,i) + p(kp1,j+1,i+1) )
629
630	ENDDO
631
632	ENDDO
633	ENDDO
634	!$OMP END PARALLEL
635
636	ind_even_odd = even_odd_level(grid_level)
637	!
638	!-- Horizontal boundary conditions
639	CALL exchange_horiz( temp, 1)
640
641	IF ( .NOT. bc_lr_cyc ) THEN
642	IF ( inflow_l .OR. outflow_l .OR. nest_bound_l ) THEN
643	temp(:,:,nxl_mg(l)-1) = temp(:,:,nxl_mg(l))
644	ENDIF
645	IF ( inflow_r .OR. outflow_r .OR. nest_bound_r ) THEN
646	temp(:,:,nxr_mg(l)+1) = temp(:,:,nxr_mg(l))
647	ENDIF
648	ENDIF
649
650	IF ( .NOT. bc_ns_cyc ) THEN
651	IF ( inflow_n .OR. outflow_n .OR. nest_bound_n ) THEN
652	temp(:,nyn_mg(l)+1,:) = temp(:,nyn_mg(l),:)
653	ENDIF
654	IF ( inflow_s .OR. outflow_s .OR. nest_bound_s ) THEN
655	temp(:,nys_mg(l)-1,:) = temp(:,nys_mg(l),:)
656	ENDIF
657	ENDIF
658
659	!
660	!-- Bottom and top boundary conditions
661	IF ( ibc_p_b == 1 ) THEN
662	!
663	!-- equivalent to temp(nzb,:,: ) = temp(nzb+1,:,:)
664	temp(nzb,:,: ) = temp(ind_even_odd+1,:,:)
665	ELSE
666	temp(nzb,:,: ) = 0.0_wp
667	ENDIF
668
669	IF ( ibc_p_t == 1 ) THEN
670	!
671	!-- equivalent to temp(nzt_mg(l)+1,:,: ) = temp(nzt_mg(l),:,:)
672	temp(nzt_mg(l)+1,:,: ) = temp(ind_even_odd,:,:)
673	ELSE
674	temp(nzt_mg(l)+1,:,: ) = 0.0_wp
675	ENDIF
676
677	CALL cpu_log( log_point_s(55), 'prolong', 'stop' )
678
679	END SUBROUTINE prolong
680
681
682	!------------------------------------------------------------------------------!
683	! Description:
684	! ------------
685	!> Relaxation method for the multigrid scheme. A Gauss-Seidel iteration with
686	!> 3D-Red-Black decomposition (GS-RB) is used.
687	!------------------------------------------------------------------------------!
688	SUBROUTINE redblack( f_mg, p_mg )
689
690
691	USE arrays_3d, &
692	ONLY: f1_mg, f2_mg, f3_mg
693
694	USE control_parameters, &
695	ONLY: bc_lr_cyc, bc_ns_cyc, grid_level, ibc_p_b, ibc_p_t, inflow_l,&
696	inflow_n, inflow_r, inflow_s, nest_bound_l, nest_bound_n, &
697	nest_bound_r, nest_bound_s, ngsrb, outflow_l, outflow_n, &
698	outflow_r, outflow_s
699
700	USE grid_variables, &
701	ONLY: ddx2_mg, ddy2_mg
702
703	USE indices, &
704	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
705
706	IMPLICIT NONE
707
708	INTEGER(iwp) :: color !< grid point color, either red or black
709	INTEGER(iwp) :: i !< index variable along x
710	INTEGER(iwp) :: ic !< index variable along x
711	INTEGER(iwp) :: j !< index variable along y
712	INTEGER(iwp) :: jc !< index variable along y
713	INTEGER(iwp) :: jj !< index variable along y
714	INTEGER(iwp) :: k !< index variable along z
715	INTEGER(iwp) :: l !< grid level
716	INTEGER(iwp) :: n !< loop variable GauÃ-Seidel iterations
717	INTEGER(iwp) :: km1 !< index variable (k-1)
718	INTEGER(iwp) :: kp1 !< index variable (k+1)
719
720	LOGICAL :: unroll !< flag indicating whether loop unrolling is possible
721
722	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
723	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
724	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: &
725	f_mg !< residual of perturbation pressure
726	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
727	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
728	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: &
729	p_mg !< perturbation pressure
730
731	l = grid_level
732
733	unroll = ( MOD( nyn_mg(l)-nys_mg(l)+1, 4 ) == 0 .AND. &
734	MOD( nxr_mg(l)-nxl_mg(l)+1, 2 ) == 0 )
735
736	DO n = 1, ngsrb
737
738	DO color = 1, 2
739
740	IF ( .NOT. unroll ) THEN
741
742	CALL cpu_log( log_point_s(36), 'redblack_no_unroll_f', 'start' )
743	!
744	!-- Without unrolling of loops, no cache optimization
745	!$OMP PARALLEL PRIVATE (i,j,k,km1,kp1)
746	!$OMP DO
747	DO i = nxl_mg(l), nxr_mg(l), 2
748	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
749	!DIR$ IVDEP
750	DO k = ind_even_odd+1, nzt_mg(l)
751	km1 = k-ind_even_odd-1
752	kp1 = k-ind_even_odd
753	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
754	ddx2_mg(l) * &
755	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
756	+ ddy2_mg(l) * &
757	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
758	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
759	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
760	- f_mg(k,j,i) )
761	ENDDO
762	ENDDO
763	ENDDO
764
765	!$OMP DO
766	DO i = nxl_mg(l)+1, nxr_mg(l), 2
767	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
768	!DIR$ IVDEP
769	DO k = ind_even_odd+1, nzt_mg(l)
770	km1 = k-ind_even_odd-1
771	kp1 = k-ind_even_odd
772	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
773	ddx2_mg(l) * &
774	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
775	+ ddy2_mg(l) * &
776	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
777	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
778	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
779	- f_mg(k,j,i) )
780	ENDDO
781	ENDDO
782	ENDDO
783
784	!$OMP DO
785	DO i = nxl_mg(l), nxr_mg(l), 2
786	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
787	!DIR$ IVDEP
788	DO k = nzb+1, ind_even_odd
789	km1 = k+ind_even_odd
790	kp1 = k+ind_even_odd+1
791	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
792	ddx2_mg(l) * &
793	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
794	+ ddy2_mg(l) * &
795	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
796	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
797	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
798	- f_mg(k,j,i) )
799	ENDDO
800	ENDDO
801	ENDDO
802
803	!$OMP DO
804	DO i = nxl_mg(l)+1, nxr_mg(l), 2
805	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
806	!DIR$ IVDEP
807	DO k = nzb+1, ind_even_odd
808	km1 = k+ind_even_odd
809	kp1 = k+ind_even_odd+1
810	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
811	ddx2_mg(l) * &
812	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
813	+ ddy2_mg(l) * &
814	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
815	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
816	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
817	- f_mg(k,j,i) )
818	ENDDO
819	ENDDO
820	ENDDO
821	!$OMP END PARALLEL
822
823	CALL cpu_log( log_point_s(36), 'redblack_no_unroll_f', 'stop' )
824
825	ELSE
826	!
827	!-- Loop unrolling along y, only one i loop for better cache use
828	CALL cpu_log( log_point_s(38), 'redblack_unroll_f', 'start' )
829
830	!$OMP PARALLEL PRIVATE (i,j,k,ic,jc,km1,kp1,jj)
831	!$OMP DO
832	DO ic = nxl_mg(l), nxr_mg(l), 2
833	DO jc = nys_mg(l), nyn_mg(l), 4
834	i = ic
835	jj = jc+2-color
836	!DIR$ IVDEP
837	DO k = ind_even_odd+1, nzt_mg(l)
838	km1 = k-ind_even_odd-1
839	kp1 = k-ind_even_odd
840	j = jj
841	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
842	ddx2_mg(l) * &
843	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
844	+ ddy2_mg(l) * &
845	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
846	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
847	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
848	- f_mg(k,j,i) )
849	j = jj+2
850	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
851	ddx2_mg(l) * &
852	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
853	+ ddy2_mg(l) * &
854	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
855	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
856	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
857	- f_mg(k,j,i) )
858	ENDDO
859
860	i = ic+1
861	jj = jc+color-1
862	!DIR$ IVDEP
863	DO k = ind_even_odd+1, nzt_mg(l)
864	km1 = k-ind_even_odd-1
865	kp1 = k-ind_even_odd
866	j = jj
867	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
868	ddx2_mg(l) * &
869	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
870	+ ddy2_mg(l) * &
871	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
872	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
873	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
874	- f_mg(k,j,i) )
875	j = jj+2
876	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
877	ddx2_mg(l) * &
878	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
879	+ ddy2_mg(l) * &
880	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
881	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
882	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
883	- f_mg(k,j,i) )
884	ENDDO
885
886	i = ic
887	jj = jc+color-1
888	!DIR$ IVDEP
889	DO k = nzb+1, ind_even_odd
890	km1 = k+ind_even_odd
891	kp1 = k+ind_even_odd+1
892	j = jj
893	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
894	ddx2_mg(l) * &
895	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
896	+ ddy2_mg(l) * &
897	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
898	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
899	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
900	- f_mg(k,j,i) )
901	j = jj+2
902	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
903	ddx2_mg(l) * &
904	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
905	+ ddy2_mg(l) * &
906	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
907	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
908	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
909	- f_mg(k,j,i) )
910	ENDDO
911
912	i = ic+1
913	jj = jc+2-color
914	!DIR$ IVDEP
915	DO k = nzb+1, ind_even_odd
916	km1 = k+ind_even_odd
917	kp1 = k+ind_even_odd+1
918	j = jj
919	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
920	ddx2_mg(l) * &
921	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
922	+ ddy2_mg(l) * &
923	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
924	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
925	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
926	- f_mg(k,j,i) )
927	j = jj+2
928	p_mg(k,j,i) = 1.0_wp / f1_mg_b(k,l) * ( &
929	ddx2_mg(l) * &
930	( p_mg(k,j,i+1) + p_mg(k,j,i-1) ) &
931	+ ddy2_mg(l) * &
932	( p_mg(k,j+1,i) + p_mg(k,j-1,i) ) &
933	+ f2_mg_b(k,l) * p_mg(kp1,j,i) &
934	+ f3_mg_b(k,l) * p_mg(km1,j,i) &
935	- f_mg(k,j,i) )
936	ENDDO
937
938	ENDDO
939	ENDDO
940	!$OMP END PARALLEL
941
942	CALL cpu_log( log_point_s(38), 'redblack_unroll_f', 'stop' )
943
944	ENDIF
945
946	!
947	!-- Horizontal boundary conditions
948	CALL special_exchange_horiz( p_mg, color )
949
950	IF ( .NOT. bc_lr_cyc ) THEN
951	IF ( inflow_l .OR. outflow_l .OR. nest_bound_l ) THEN
952	p_mg(:,:,nxl_mg(l)-1) = p_mg(:,:,nxl_mg(l))
953	ENDIF
954	IF ( inflow_r .OR. outflow_r .OR. nest_bound_r ) THEN
955	p_mg(:,:,nxr_mg(l)+1) = p_mg(:,:,nxr_mg(l))
956	ENDIF
957	ENDIF
958
959	IF ( .NOT. bc_ns_cyc ) THEN
960	IF ( inflow_n .OR. outflow_n .OR. nest_bound_n ) THEN
961	p_mg(:,nyn_mg(l)+1,:) = p_mg(:,nyn_mg(l),:)
962	ENDIF
963	IF ( inflow_s .OR. outflow_s .OR. nest_bound_s ) THEN
964	p_mg(:,nys_mg(l)-1,:) = p_mg(:,nys_mg(l),:)
965	ENDIF
966	ENDIF
967
968	!
969	!-- Bottom and top boundary conditions
970	IF ( ibc_p_b == 1 ) THEN
971	!
972	!-- equivalent to p_mg(nzb,:,: ) = p_mg(nzb+1,:,:)
973	p_mg(nzb,:,: ) = p_mg(ind_even_odd+1,:,:)
974	ELSE
975	p_mg(nzb,:,: ) = 0.0_wp
976	ENDIF
977
978	IF ( ibc_p_t == 1 ) THEN
979	!
980	!-- equivalent to p_mg(nzt_mg(l)+1,:,: ) = p_mg(nzt_mg(l),:,:)
981	p_mg(nzt_mg(l)+1,:,: ) = p_mg(ind_even_odd,:,:)
982	ELSE
983	p_mg(nzt_mg(l)+1,:,: ) = 0.0_wp
984	ENDIF
985
986	ENDDO
987
988	ENDDO
989
990	END SUBROUTINE redblack
991
992
993	!------------------------------------------------------------------------------!
994	! Description:
995	! ------------
996	!> Sort k-Dimension from sequential into blocks of even and odd.
997	!> This is required to vectorize the red-black subroutine.
998	!> Version for 3D-REAL arrays
999	!------------------------------------------------------------------------------!
1000	SUBROUTINE sort_k_to_even_odd_blocks( p_mg , glevel )
1001
1002
1003	USE control_parameters, &
1004	ONLY: grid_level
1005
1006	USE indices, &
1007	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
1008
1009	IMPLICIT NONE
1010
1011	INTEGER(iwp), INTENT(IN) :: glevel !< grid level
1012
1013	REAL(wp), DIMENSION(nzb:nzt_mg(glevel)+1, &
1014	nys_mg(glevel)-1:nyn_mg(glevel)+1, &
1015	nxl_mg(glevel)-1:nxr_mg(glevel)+1) :: &
1016	p_mg !< array to be sorted
1017	!
1018	!-- Local variables
1019	INTEGER(iwp) :: i !< index variable along x
1020	INTEGER(iwp) :: j !< index variable along y
1021	INTEGER(iwp) :: k !< index variable along z
1022	INTEGER(iwp) :: l !< grid level
1023	INTEGER(iwp) :: ind !< index variable along z
1024	REAL(wp), DIMENSION(nzb:nzt_mg(glevel)+1) :: tmp !< odd-even sorted temporary array
1025
1026
1027	CALL cpu_log( log_point_s(52), 'sort_k_to_even_odd', 'start' )
1028
1029	l = glevel
1030	ind_even_odd = even_odd_level(l)
1031
1032	!$OMP PARALLEL PRIVATE (i,j,k,ind,tmp)
1033	!$OMP DO
1034	DO i = nxl_mg(l)-1, nxr_mg(l)+1
1035	DO j = nys_mg(l)-1, nyn_mg(l)+1
1036
1037	!
1038	!-- Sort the data with even k index
1039	ind = nzb-1
1040	DO k = nzb, nzt_mg(l), 2
1041	ind = ind + 1
1042	tmp(ind) = p_mg(k,j,i)
1043	ENDDO
1044	!
1045	!-- Sort the data with odd k index
1046	DO k = nzb+1, nzt_mg(l)+1, 2
1047	ind = ind + 1
1048	tmp(ind) = p_mg(k,j,i)
1049	ENDDO
1050
1051	p_mg(:,j,i) = tmp
1052
1053	ENDDO
1054	ENDDO
1055	!$OMP END PARALLEL
1056
1057	CALL cpu_log( log_point_s(52), 'sort_k_to_even_odd', 'stop' )
1058
1059	END SUBROUTINE sort_k_to_even_odd_blocks
1060
1061
1062	!------------------------------------------------------------------------------!
1063	! Description:
1064	! ------------
1065	!> Sort k-Dimension from sequential into blocks of even and odd.
1066	!> This is required to vectorize the red-black subroutine.
1067	!> Version for 1D-REAL arrays
1068	!------------------------------------------------------------------------------!
1069	SUBROUTINE sort_k_to_even_odd_blocks_1d( f_mg, f_mg_b, glevel )
1070
1071
1072	USE indices, &
1073	ONLY: nzb, nzt_mg
1074
1075	IMPLICIT NONE
1076
1077	INTEGER(iwp), INTENT(IN) :: glevel !< grid level
1078
1079	REAL(wp), DIMENSION(nzb+1:nzt_mg(glevel)) :: f_mg !< 1D input array
1080	REAL(wp), DIMENSION(nzb:nzt_mg(glevel)+1) :: f_mg_b !< 1D output array
1081
1082	!
1083	!-- Local variables
1084	INTEGER(iwp) :: ind !< index variable along z
1085	INTEGER(iwp) :: k !< index variable along z
1086
1087
1088	ind = nzb - 1
1089	!
1090	!-- Sort the data with even k index
1091	DO k = nzb, nzt_mg(glevel), 2
1092	ind = ind + 1
1093	IF ( k >= nzb+1 .AND. k <= nzt_mg(glevel) ) THEN
1094	f_mg_b(ind) = f_mg(k)
1095	ENDIF
1096	ENDDO
1097	!
1098	!-- Sort the data with odd k index
1099	DO k = nzb+1, nzt_mg(glevel)+1, 2
1100	ind = ind + 1
1101	IF( k >= nzb+1 .AND. k <= nzt_mg(glevel) ) THEN
1102	f_mg_b(ind) = f_mg(k)
1103	ENDIF
1104	ENDDO
1105
1106	END SUBROUTINE sort_k_to_even_odd_blocks_1d
1107
1108
1109	!------------------------------------------------------------------------------!
1110	! Description:
1111	! ------------
1112	!> Sort k-Dimension from sequential into blocks of even and odd.
1113	!> This is required to vectorize the red-black subroutine.
1114	!> Version for 2D-INTEGER arrays
1115	!------------------------------------------------------------------------------!
1116	SUBROUTINE sort_k_to_even_odd_blocks_int( i_mg , glevel )
1117
1118
1119	USE control_parameters, &
1120	ONLY: grid_level
1121
1122	USE indices, &
1123	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
1124
1125	IMPLICIT NONE
1126
1127	INTEGER(iwp), INTENT(IN) :: glevel !< grid level
1128
1129	INTEGER(iwp), DIMENSION(nzb:nzt_mg(glevel)+1, &
1130	nys_mg(glevel)-1:nyn_mg(glevel)+1, &
1131	nxl_mg(glevel)-1:nxr_mg(glevel)+1) :: &
1132	i_mg !< array to be sorted
1133	!
1134	!-- Local variables
1135	INTEGER(iwp) :: i !< index variabel along x
1136	INTEGER(iwp) :: j !< index variable along y
1137	INTEGER(iwp) :: k !< index variable along z
1138	INTEGER(iwp) :: l !< grid level
1139	INTEGER(iwp) :: ind !< index variable along z
1140	INTEGER(iwp),DIMENSION(nzb:nzt_mg(glevel)+1) :: tmp !< temporary odd-even sorted array
1141
1142
1143	CALL cpu_log( log_point_s(52), 'sort_k_to_even_odd', 'start' )
1144
1145	l = glevel
1146	ind_even_odd = even_odd_level(l)
1147
1148	DO i = nxl_mg(l)-1, nxr_mg(l)+1
1149	DO j = nys_mg(l)-1, nyn_mg(l)+1
1150
1151	!
1152	!-- Sort the data with even k index
1153	ind = nzb-1
1154	DO k = nzb, nzt_mg(l), 2
1155	ind = ind + 1
1156	tmp(ind) = i_mg(k,j,i)
1157	ENDDO
1158	!
1159	!++ ATTENTION: Check reason for this error. Remove it or replace WRITE
1160	!++ by PALM message
1161	#if defined ( __parallel )
1162	IF ( ind /= ind_even_odd ) THEN
1163	WRITE (0,*) 'ERROR ==> illegal ind_even_odd ',ind,ind_even_odd,l
1164	CALL MPI_ABORT(MPI_COMM_WORLD,i,j)
1165	ENDIF
1166	#endif
1167	!
1168	!-- Sort the data with odd k index
1169	DO k = nzb+1, nzt_mg(l)+1, 2
1170	ind = ind + 1
1171	tmp(ind) = i_mg(k,j,i)
1172	ENDDO
1173
1174	i_mg(:,j,i) = tmp
1175
1176	ENDDO
1177	ENDDO
1178
1179	CALL cpu_log( log_point_s(52), 'sort_k_to_even_odd', 'stop' )
1180
1181	END SUBROUTINE sort_k_to_even_odd_blocks_int
1182
1183
1184	!------------------------------------------------------------------------------!
1185	! Description:
1186	! ------------
1187	!> Sort k-dimension from blocks of even and odd into sequential
1188	!------------------------------------------------------------------------------!
1189	SUBROUTINE sort_k_to_sequential( p_mg )
1190
1191
1192	USE control_parameters, &
1193	ONLY: grid_level
1194
1195	USE indices, &
1196	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
1197
1198	IMPLICIT NONE
1199
1200	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1201	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1202	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: &
1203	p_mg !< array to be sorted
1204	!
1205	!-- Local variables
1206	INTEGER(iwp) :: i !< index variable along x
1207	INTEGER(iwp) :: j !< index variable along y
1208	INTEGER(iwp) :: k !< index variable along z
1209	INTEGER(iwp) :: l !< grid level
1210	INTEGER(iwp) :: ind !< index variable along z
1211
1212	REAL(wp),DIMENSION(nzb:nzt_mg(grid_level)+1) :: tmp
1213
1214
1215	l = grid_level
1216
1217	!$OMP PARALLEL PRIVATE (i,j,k,ind,tmp)
1218	!$OMP DO
1219	DO i = nxl_mg(l)-1, nxr_mg(l)+1
1220	DO j = nys_mg(l)-1, nyn_mg(l)+1
1221
1222	ind = nzb - 1
1223	tmp = p_mg(:,j,i)
1224	DO k = nzb, nzt_mg(l), 2
1225	ind = ind + 1
1226	p_mg(k,j,i) = tmp(ind)
1227	ENDDO
1228
1229	DO k = nzb+1, nzt_mg(l)+1, 2
1230	ind = ind + 1
1231	p_mg(k,j,i) = tmp(ind)
1232	ENDDO
1233	ENDDO
1234	ENDDO
1235	!$OMP END PARALLEL
1236
1237	END SUBROUTINE sort_k_to_sequential
1238
1239
1240	!------------------------------------------------------------------------------!
1241	! Description:
1242	! ------------
1243	!> Gather subdomain data from all PEs.
1244	!------------------------------------------------------------------------------!
1245	SUBROUTINE mg_gather( f2, f2_sub )
1246
1247	USE control_parameters, &
1248	ONLY: grid_level
1249
1250	USE cpulog, &
1251	ONLY: cpu_log, log_point_s
1252
1253	USE indices, &
1254	ONLY: mg_loc_ind, nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
1255
1256	IMPLICIT NONE
1257
1258	INTEGER(iwp) :: i !<
1259	INTEGER(iwp) :: il !<
1260	INTEGER(iwp) :: ir !<
1261	INTEGER(iwp) :: j !<
1262	INTEGER(iwp) :: jn !<
1263	INTEGER(iwp) :: js !<
1264	INTEGER(iwp) :: k !<
1265	INTEGER(iwp) :: nwords !<
1266
1267	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1268	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1269	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: f2 !<
1270	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1271	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1272	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: f2_l !<
1273
1274	REAL(wp), DIMENSION(nzb:mg_loc_ind(5,myid)+1, &
1275	mg_loc_ind(3,myid)-1:mg_loc_ind(4,myid)+1, &
1276	mg_loc_ind(1,myid)-1:mg_loc_ind(2,myid)+1) :: f2_sub !<
1277
1278
1279	#if defined( __parallel )
1280	CALL cpu_log( log_point_s(34), 'mg_gather', 'start' )
1281
1282	f2_l = 0.0_wp
1283
1284	!
1285	!-- Store the local subdomain array on the total array
1286	js = mg_loc_ind(3,myid)
1287	IF ( south_border_pe ) js = js - 1
1288	jn = mg_loc_ind(4,myid)
1289	IF ( north_border_pe ) jn = jn + 1
1290	il = mg_loc_ind(1,myid)
1291	IF ( left_border_pe ) il = il - 1
1292	ir = mg_loc_ind(2,myid)
1293	IF ( right_border_pe ) ir = ir + 1
1294	DO i = il, ir
1295	DO j = js, jn
1296	DO k = nzb, nzt_mg(grid_level)+1
1297	f2_l(k,j,i) = f2_sub(k,j,i)
1298	ENDDO
1299	ENDDO
1300	ENDDO
1301
1302	!
1303	!-- Find out the number of array elements of the total array
1304	nwords = SIZE( f2 )
1305
1306	!
1307	!-- Gather subdomain data from all PEs
1308	IF ( collective_wait ) CALL MPI_BARRIER( comm2d, ierr )
1309	CALL MPI_ALLREDUCE( f2_l(nzb,nys_mg(grid_level)-1,nxl_mg(grid_level)-1), &
1310	f2(nzb,nys_mg(grid_level)-1,nxl_mg(grid_level)-1), &
1311	nwords, MPI_REAL, MPI_SUM, comm2d, ierr )
1312
1313	CALL cpu_log( log_point_s(34), 'mg_gather', 'stop' )
1314	#endif
1315
1316	END SUBROUTINE mg_gather
1317
1318
1319
1320	!------------------------------------------------------------------------------!
1321	! Description:
1322	! ------------
1323	!> @todo It might be possible to improve the speed of this routine by using
1324	!> non-blocking communication
1325	!------------------------------------------------------------------------------!
1326	SUBROUTINE mg_scatter( p2, p2_sub )
1327
1328	USE control_parameters, &
1329	ONLY: grid_level
1330
1331	USE cpulog, &
1332	ONLY: cpu_log, log_point_s
1333
1334	USE indices, &
1335	ONLY: mg_loc_ind, nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
1336
1337	IMPLICIT NONE
1338
1339	INTEGER(iwp) :: nwords !<
1340
1341	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level-1)+1, &
1342	nys_mg(grid_level-1)-1:nyn_mg(grid_level-1)+1, &
1343	nxl_mg(grid_level-1)-1:nxr_mg(grid_level-1)+1) :: p2 !<
1344
1345	REAL(wp), DIMENSION(nzb:mg_loc_ind(5,myid)+1, &
1346	mg_loc_ind(3,myid)-1:mg_loc_ind(4,myid)+1, &
1347	mg_loc_ind(1,myid)-1:mg_loc_ind(2,myid)+1) :: p2_sub !<
1348
1349	!
1350	!-- Find out the number of array elements of the subdomain array
1351	nwords = SIZE( p2_sub )
1352
1353	#if defined( __parallel )
1354	CALL cpu_log( log_point_s(35), 'mg_scatter', 'start' )
1355
1356	p2_sub = p2(:,mg_loc_ind(3,myid)-1:mg_loc_ind(4,myid)+1, &
1357	mg_loc_ind(1,myid)-1:mg_loc_ind(2,myid)+1)
1358
1359	CALL cpu_log( log_point_s(35), 'mg_scatter', 'stop' )
1360	#endif
1361
1362	END SUBROUTINE mg_scatter
1363
1364
1365	!------------------------------------------------------------------------------!
1366	! Description:
1367	! ------------
1368	!> This is where the multigrid technique takes place. V- and W- Cycle are
1369	!> implemented and steered by the parameter "gamma". Parameter "nue" determines
1370	!> the convergence of the multigrid iterative solution. There are nue times
1371	!> RB-GS iterations. It should be set to "1" or "2", considering the time effort
1372	!> one would like to invest. Last choice shows a very good converging factor,
1373	!> but leads to an increase in computing time.
1374	!------------------------------------------------------------------------------!
1375	RECURSIVE SUBROUTINE next_mg_level( f_mg, p_mg, p3, r )
1376
1377	USE control_parameters, &
1378	ONLY: bc_lr_dirrad, bc_lr_raddir, bc_ns_dirrad, bc_ns_raddir, &
1379	gamma_mg, grid_level, grid_level_count, ibc_p_b, ibc_p_t, &
1380	inflow_l, inflow_n, inflow_r, inflow_s, maximum_grid_level, &
1381	mg_switch_to_pe0_level, mg_switch_to_pe0, nest_domain, &
1382	nest_bound_l, nest_bound_n, nest_bound_r, nest_bound_s, &
1383	ngsrb, outflow_l, outflow_n, outflow_r, outflow_s
1384
1385	USE indices, &
1386	ONLY: mg_loc_ind, nxl, nxl_mg, nxr, nxr_mg, nys, nys_mg, nyn, &
1387	nyn_mg, nzb, nzt, nzt_mg
1388
1389	IMPLICIT NONE
1390
1391	INTEGER(iwp) :: i !< index variable along x
1392	INTEGER(iwp) :: j !< index variable along y
1393	INTEGER(iwp) :: k !< index variable along z
1394	INTEGER(iwp) :: nxl_mg_save !<
1395	INTEGER(iwp) :: nxr_mg_save !<
1396	INTEGER(iwp) :: nyn_mg_save !<
1397	INTEGER(iwp) :: nys_mg_save !<
1398	INTEGER(iwp) :: nzt_mg_save !<
1399
1400	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1401	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1402	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: f_mg !<
1403	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1404	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1405	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: p_mg !<
1406	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1407	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1408	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: p3 !<
1409	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1410	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1411	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: r !<
1412
1413	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level-1)+1, &
1414	nys_mg(grid_level-1)-1:nyn_mg(grid_level-1)+1, &
1415	nxl_mg(grid_level-1)-1:nxr_mg(grid_level-1)+1) :: f2 !<
1416	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level-1)+1, &
1417	nys_mg(grid_level-1)-1:nyn_mg(grid_level-1)+1, &
1418	nxl_mg(grid_level-1)-1:nxr_mg(grid_level-1)+1) :: p2 !<
1419
1420	REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: f2_sub !<
1421	REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: p2_sub !<
1422
1423	!
1424	!-- Restriction to the coarsest grid
1425	10 IF ( grid_level == 1 ) THEN
1426
1427	!
1428	!-- Solution on the coarsest grid. Double the number of Gauss-Seidel
1429	!-- iterations in order to get a more accurate solution.
1430	ngsrb = 2 * ngsrb
1431
1432	ind_even_odd = even_odd_level(grid_level)
1433
1434	CALL redblack( f_mg, p_mg )
1435
1436	ngsrb = ngsrb / 2
1437
1438
1439	ELSEIF ( grid_level /= 1 ) THEN
1440
1441	grid_level_count(grid_level) = grid_level_count(grid_level) + 1
1442
1443	!
1444	!-- Solution on the actual grid level
1445	ind_even_odd = even_odd_level(grid_level)
1446
1447	CALL redblack( f_mg, p_mg )
1448
1449	!
1450	!-- Determination of the actual residual
1451	CALL resid( f_mg, p_mg, r )
1452
1453	!-- Restriction of the residual (finer grid values!) to the next coarser
1454	!-- grid. Therefore, the grid level has to be decremented now. nxl..nzt have
1455	!-- to be set to the coarse grid values, because these variables are needed
1456	!-- for the exchange of ghost points in routine exchange_horiz
1457	grid_level = grid_level - 1
1458
1459	nxl = nxl_mg(grid_level)
1460	nys = nys_mg(grid_level)
1461	nxr = nxr_mg(grid_level)
1462	nyn = nyn_mg(grid_level)
1463	nzt = nzt_mg(grid_level)
1464
1465	IF ( grid_level == mg_switch_to_pe0_level ) THEN
1466
1467	!
1468	!-- From this level on, calculations are done on PE0 only.
1469	!-- First, carry out restriction on the subdomain.
1470	!-- Therefore, indices of the level have to be changed to subdomain
1471	!-- values in between (otherwise, the restrict routine would expect
1472	!-- the gathered array)
1473
1474	nxl_mg_save = nxl_mg(grid_level)
1475	nxr_mg_save = nxr_mg(grid_level)
1476	nys_mg_save = nys_mg(grid_level)
1477	nyn_mg_save = nyn_mg(grid_level)
1478	nzt_mg_save = nzt_mg(grid_level)
1479	nxl_mg(grid_level) = mg_loc_ind(1,myid)
1480	nxr_mg(grid_level) = mg_loc_ind(2,myid)
1481	nys_mg(grid_level) = mg_loc_ind(3,myid)
1482	nyn_mg(grid_level) = mg_loc_ind(4,myid)
1483	nzt_mg(grid_level) = mg_loc_ind(5,myid)
1484	nxl = mg_loc_ind(1,myid)
1485	nxr = mg_loc_ind(2,myid)
1486	nys = mg_loc_ind(3,myid)
1487	nyn = mg_loc_ind(4,myid)
1488	nzt = mg_loc_ind(5,myid)
1489
1490	ALLOCATE( f2_sub(nzb:nzt_mg(grid_level)+1, &
1491	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1492	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) )
1493
1494	CALL restrict( f2_sub, r )
1495
1496	!
1497	!-- Restore the correct indices of this level
1498	nxl_mg(grid_level) = nxl_mg_save
1499	nxr_mg(grid_level) = nxr_mg_save
1500	nys_mg(grid_level) = nys_mg_save
1501	nyn_mg(grid_level) = nyn_mg_save
1502	nzt_mg(grid_level) = nzt_mg_save
1503	nxl = nxl_mg(grid_level)
1504	nxr = nxr_mg(grid_level)
1505	nys = nys_mg(grid_level)
1506	nyn = nyn_mg(grid_level)
1507	nzt = nzt_mg(grid_level)
1508	!
1509	!-- Gather all arrays from the subdomains on PE0
1510	CALL mg_gather( f2, f2_sub )
1511
1512	!
1513	!-- Set switch for routine exchange_horiz, that no ghostpoint exchange
1514	!-- has to be carried out from now on
1515	mg_switch_to_pe0 = .TRUE.
1516
1517	!
1518	!-- In case of non-cyclic lateral boundary conditions, both in- and
1519	!-- outflow conditions have to be used on all PEs after the switch,
1520	!-- because then they have the total domain.
1521	IF ( bc_lr_dirrad ) THEN
1522	inflow_l = .TRUE.
1523	inflow_r = .FALSE.
1524	outflow_l = .FALSE.
1525	outflow_r = .TRUE.
1526	ELSEIF ( bc_lr_raddir ) THEN
1527	inflow_l = .FALSE.
1528	inflow_r = .TRUE.
1529	outflow_l = .TRUE.
1530	outflow_r = .FALSE.
1531	ELSEIF ( nest_domain ) THEN
1532	nest_bound_l = .TRUE.
1533	nest_bound_r = .TRUE.
1534	ENDIF
1535
1536	IF ( bc_ns_dirrad ) THEN
1537	inflow_n = .TRUE.
1538	inflow_s = .FALSE.
1539	outflow_n = .FALSE.
1540	outflow_s = .TRUE.
1541	ELSEIF ( bc_ns_raddir ) THEN
1542	inflow_n = .FALSE.
1543	inflow_s = .TRUE.
1544	outflow_n = .TRUE.
1545	outflow_s = .FALSE.
1546	ELSEIF ( nest_domain ) THEN
1547	nest_bound_s = .TRUE.
1548	nest_bound_n = .TRUE.
1549	ENDIF
1550
1551	DEALLOCATE( f2_sub )
1552
1553	ELSE
1554
1555	CALL restrict( f2, r )
1556
1557	ind_even_odd = even_odd_level(grid_level) ! must be after restrict
1558
1559	ENDIF
1560
1561	p2 = 0.0_wp
1562
1563	!
1564	!-- Repeat the same procedure till the coarsest grid is reached
1565	CALL next_mg_level( f2, p2, p3, r )
1566
1567	ENDIF
1568
1569	!
1570	!-- Now follows the prolongation
1571	IF ( grid_level >= 2 ) THEN
1572
1573	!
1574	!-- Prolongation of the new residual. The values are transferred
1575	!-- from the coarse to the next finer grid.
1576	IF ( grid_level == mg_switch_to_pe0_level+1 ) THEN
1577
1578	#if defined( __parallel )
1579	!
1580	!-- At this level, the new residual first has to be scattered from
1581	!-- PE0 to the other PEs
1582	ALLOCATE( p2_sub(nzb:mg_loc_ind(5,myid)+1, &
1583	mg_loc_ind(3,myid)-1:mg_loc_ind(4,myid)+1, &
1584	mg_loc_ind(1,myid)-1:mg_loc_ind(2,myid)+1) )
1585
1586	CALL mg_scatter( p2, p2_sub )
1587
1588	!
1589	!-- Therefore, indices of the previous level have to be changed to
1590	!-- subdomain values in between (otherwise, the prolong routine would
1591	!-- expect the gathered array)
1592	nxl_mg_save = nxl_mg(grid_level-1)
1593	nxr_mg_save = nxr_mg(grid_level-1)
1594	nys_mg_save = nys_mg(grid_level-1)
1595	nyn_mg_save = nyn_mg(grid_level-1)
1596	nzt_mg_save = nzt_mg(grid_level-1)
1597	nxl_mg(grid_level-1) = mg_loc_ind(1,myid)
1598	nxr_mg(grid_level-1) = mg_loc_ind(2,myid)
1599	nys_mg(grid_level-1) = mg_loc_ind(3,myid)
1600	nyn_mg(grid_level-1) = mg_loc_ind(4,myid)
1601	nzt_mg(grid_level-1) = mg_loc_ind(5,myid)
1602
1603	!
1604	!-- Set switch for routine exchange_horiz, that ghostpoint exchange
1605	!-- has to be carried again out from now on
1606	mg_switch_to_pe0 = .FALSE.
1607
1608	!
1609	!-- For non-cyclic lateral boundary conditions, restore the
1610	!-- in-/outflow conditions
1611	inflow_l = .FALSE.; inflow_r = .FALSE.
1612	inflow_n = .FALSE.; inflow_s = .FALSE.
1613	outflow_l = .FALSE.; outflow_r = .FALSE.
1614	outflow_n = .FALSE.; outflow_s = .FALSE.
1615
1616	IF ( pleft == MPI_PROC_NULL ) THEN
1617	IF ( bc_lr_dirrad ) THEN
1618	inflow_l = .TRUE.
1619	ELSEIF ( bc_lr_raddir ) THEN
1620	outflow_l = .TRUE.
1621	ELSEIF ( nest_domain ) THEN
1622	nest_bound_l = .TRUE.
1623	ENDIF
1624	ENDIF
1625
1626	IF ( pright == MPI_PROC_NULL ) THEN
1627	IF ( bc_lr_dirrad ) THEN
1628	outflow_r = .TRUE.
1629	ELSEIF ( bc_lr_raddir ) THEN
1630	inflow_r = .TRUE.
1631	ELSEIF ( nest_domain ) THEN
1632	nest_bound_r = .TRUE.
1633	ENDIF
1634	ENDIF
1635
1636	IF ( psouth == MPI_PROC_NULL ) THEN
1637	IF ( bc_ns_dirrad ) THEN
1638	outflow_s = .TRUE.
1639	ELSEIF ( bc_ns_raddir ) THEN
1640	inflow_s = .TRUE.
1641	ELSEIF ( nest_domain ) THEN
1642	nest_bound_s = .TRUE.
1643	ENDIF
1644	ENDIF
1645
1646	IF ( pnorth == MPI_PROC_NULL ) THEN
1647	IF ( bc_ns_dirrad ) THEN
1648	inflow_n = .TRUE.
1649	ELSEIF ( bc_ns_raddir ) THEN
1650	outflow_n = .TRUE.
1651	ELSEIF ( nest_domain ) THEN
1652	nest_bound_n = .TRUE.
1653	ENDIF
1654	ENDIF
1655
1656	CALL prolong( p2_sub, p3 )
1657
1658	!
1659	!-- Restore the correct indices of the previous level
1660	nxl_mg(grid_level-1) = nxl_mg_save
1661	nxr_mg(grid_level-1) = nxr_mg_save
1662	nys_mg(grid_level-1) = nys_mg_save
1663	nyn_mg(grid_level-1) = nyn_mg_save
1664	nzt_mg(grid_level-1) = nzt_mg_save
1665
1666	DEALLOCATE( p2_sub )
1667	#endif
1668
1669	ELSE
1670
1671	CALL prolong( p2, p3 )
1672
1673	ENDIF
1674
1675	!
1676	!-- Computation of the new pressure correction. Therefore,
1677	!-- values from prior grids are added up automatically stage by stage.
1678	DO i = nxl_mg(grid_level)-1, nxr_mg(grid_level)+1
1679	DO j = nys_mg(grid_level)-1, nyn_mg(grid_level)+1
1680	DO k = nzb, nzt_mg(grid_level)+1
1681	p_mg(k,j,i) = p_mg(k,j,i) + p3(k,j,i)
1682	ENDDO
1683	ENDDO
1684	ENDDO
1685
1686	!
1687	!-- Relaxation of the new solution
1688	CALL redblack( f_mg, p_mg )
1689
1690	ENDIF
1691
1692
1693	!
1694	!-- The following few lines serve the steering of the multigrid scheme
1695	IF ( grid_level == maximum_grid_level ) THEN
1696
1697	GOTO 20
1698
1699	ELSEIF ( grid_level /= maximum_grid_level .AND. grid_level /= 1 .AND. &
1700	grid_level_count(grid_level) /= gamma_mg ) THEN
1701
1702	GOTO 10
1703
1704	ENDIF
1705
1706	!
1707	!-- Reset counter for the next call of poismg
1708	grid_level_count(grid_level) = 0
1709
1710	!
1711	!-- Continue with the next finer level. nxl..nzt have to be
1712	!-- set to the finer grid values, because these variables are needed for the
1713	!-- exchange of ghost points in routine exchange_horiz
1714	grid_level = grid_level + 1
1715	ind_even_odd = even_odd_level(grid_level)
1716
1717	nxl = nxl_mg(grid_level)
1718	nxr = nxr_mg(grid_level)
1719	nys = nys_mg(grid_level)
1720	nyn = nyn_mg(grid_level)
1721	nzt = nzt_mg(grid_level)
1722
1723	20 CONTINUE
1724
1725	END SUBROUTINE next_mg_level
1726
1727
1728	!------------------------------------------------------------------------------!
1729	! Description:
1730	! ------------
1731	!> Initial settings for sorting k-dimension from sequential order (alternate
1732	!> even/odd) into blocks of even and odd or vice versa
1733	!------------------------------------------------------------------------------!
1734	SUBROUTINE init_even_odd_blocks
1735
1736
1737	USE arrays_3d, &
1738	ONLY: f1_mg, f2_mg, f3_mg
1739
1740	USE control_parameters, &
1741	ONLY: grid_level, maximum_grid_level
1742
1743	USE indices, &
1744	ONLY: nzb, nzt, nzt_mg
1745
1746	USE indices, &
1747	ONLY: nxl_mg, nxr_mg, nys_mg, nyn_mg, nzb, nzt_mg
1748
1749	IMPLICIT NONE
1750	!
1751	!-- Local variables
1752	INTEGER(iwp) :: i !<
1753	INTEGER(iwp) :: l !<
1754
1755	LOGICAL, SAVE :: lfirst = .TRUE.
1756
1757
1758	IF ( .NOT. lfirst ) RETURN
1759
1760	ALLOCATE( even_odd_level(maximum_grid_level) )
1761
1762	ALLOCATE( f1_mg_b(nzb:nzt+1,maximum_grid_level), &
1763	f2_mg_b(nzb:nzt+1,maximum_grid_level), &
1764	f3_mg_b(nzb:nzt+1,maximum_grid_level) )
1765
1766	!
1767	!-- Set border index between the even and odd block
1768	DO i = maximum_grid_level, 1, -1
1769	even_odd_level(i) = nzt_mg(i) / 2
1770	ENDDO
1771
1772	!
1773	!-- Sort grid coefficients used in red/black scheme and for calculating the
1774	!-- residual to block (even/odd) structure
1775	DO l = maximum_grid_level, 1 , -1
1776	CALL sort_k_to_even_odd_blocks( f1_mg(nzb+1:nzt_mg(grid_level),l), &
1777	f1_mg_b(nzb:nzt_mg(grid_level)+1,l), &
1778	l )
1779	CALL sort_k_to_even_odd_blocks( f2_mg(nzb+1:nzt_mg(grid_level),l), &
1780	f2_mg_b(nzb:nzt_mg(grid_level)+1,l), &
1781	l )
1782	CALL sort_k_to_even_odd_blocks( f3_mg(nzb+1:nzt_mg(grid_level),l), &
1783	f3_mg_b(nzb:nzt_mg(grid_level)+1,l), &
1784	l )
1785	ENDDO
1786
1787	lfirst = .FALSE.
1788
1789	END SUBROUTINE init_even_odd_blocks
1790
1791
1792	!------------------------------------------------------------------------------!
1793	! Description:
1794	! ------------
1795	!> Special exchange_horiz subroutine for use in redblack. Transfers only
1796	!> "red" or "black" data points.
1797	!------------------------------------------------------------------------------!
1798	SUBROUTINE special_exchange_horiz ( p_mg, color )
1799
1800
1801	USE control_parameters, &
1802	ONLY: bc_lr_cyc, bc_ns_cyc, grid_level, ibc_p_b, ibc_p_t, &
1803	inflow_l, inflow_n, inflow_r, inflow_s, maximum_grid_level, &
1804	mg_switch_to_pe0_level, outflow_l, outflow_n, outflow_r, &
1805	outflow_s, synchronous_exchange
1806
1807	USE indices, &
1808	ONLY: mg_loc_ind, nxl, nxl_mg, nxr, nxr_mg, nys, nys_mg, nyn, &
1809	nyn_mg, nzb, nzt, nzt_mg
1810
1811	IMPLICIT NONE
1812
1813	REAL(wp), DIMENSION(nzb:nzt_mg(grid_level)+1, &
1814	nys_mg(grid_level)-1:nyn_mg(grid_level)+1, &
1815	nxl_mg(grid_level)-1:nxr_mg(grid_level)+1) :: &
1816	p_mg !< treated array
1817
1818	INTEGER(iwp), intent(IN) :: color !< flag for grid point type (red or black)
1819	!
1820	!-- Local variables
1821	INTEGER(iwp) :: i !< index variable along x
1822	INTEGER(iwp) :: i1 !< index variable along x on coarse level
1823	INTEGER(iwp) :: i2 !< index variable along x on coarse level
1824
1825	INTEGER(iwp) :: j !< index variable along y
1826	INTEGER(iwp) :: j1 !< index variable along y on coarse level
1827	INTEGER(iwp) :: j2 !< index variable along y on coarse level
1828	INTEGER(iwp) :: k !< index variable along z
1829	INTEGER(iwp) :: l !< short for grid level
1830	INTEGER(iwp) :: jys !< index for lower local PE boundary along y
1831	INTEGER(iwp) :: jyn !< index for upper local PE boundary along y
1832	INTEGER(iwp) :: ixl !< index for lower local PE boundary along x
1833	INTEGER(iwp) :: ixr !< index for upper local PE boundary along x
1834
1835	LOGICAL :: sendrecv_in_background_save !< dummy to reset sendrecv_in_background to prescribed value
1836	LOGICAL :: synchronous_exchange_save !< dummy to reset synchronous_exchange to prescribed value
1837
1838	REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: temp !< temporary array on next coarser grid level
1839
1840	#if defined ( __parallel )
1841	sendrecv_in_background_save = sendrecv_in_background
1842	sendrecv_in_background = .FALSE.
1843	synchronous_exchange_save = synchronous_exchange
1844	synchronous_exchange = .FALSE.
1845
1846	l = grid_level
1847
1848	ind_even_odd = even_odd_level(grid_level)
1849
1850	!
1851	!-- Restricted transfer only on finer levels with enough data.
1852	!-- Restricted transfer is not possible for levels smaller or equal to
1853	!-- 'switch to PE0 levels', since array bounds does not fit. Moreover,
1854	!-- it is not possible for the coarsest grid level, since the dimensions
1855	!-- of temp are not defined. For such cases, normal exchange_horiz is called.
1856	IF ( l > 1 .AND. l > mg_switch_to_pe0_level + 1 .AND. &
1857	( ngp_xz(grid_level) >= 900 .OR. ngp_yz(grid_level) >= 900 ) ) THEN
1858
1859	jys = nys_mg(grid_level-1)
1860	jyn = nyn_mg(grid_level-1)
1861	ixl = nxl_mg(grid_level-1)
1862	ixr = nxr_mg(grid_level-1)
1863	ALLOCATE( temp(nzb:nzt_mg(l-1)+1,jys-1:jyn+1,ixl-1:ixr+1) )
1864	!
1865	!-- Handling the even k Values
1866	!-- Collecting data for the north - south exchange
1867	!-- Since only every second value has to be transfered, data are stored
1868	!-- on the next coarser grid level, because the arrays on that level
1869	!-- have just the required size
1870	i1 = nxl_mg(grid_level-1)
1871	i2 = nxl_mg(grid_level-1)
1872
1873	DO i = nxl_mg(l), nxr_mg(l), 2
1874	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
1875
1876	IF ( j == nys_mg(l) ) THEN
1877	!DIR$ IVDEP
1878	DO k = ind_even_odd+1, nzt_mg(l)
1879	temp(k-ind_even_odd,jys,i1) = p_mg(k,j,i)
1880	ENDDO
1881	i1 = i1 + 1
1882
1883	ENDIF
1884
1885	IF ( j == nyn_mg(l) ) THEN
1886	!DIR$ IVDEP
1887	DO k = ind_even_odd+1, nzt_mg(l)
1888	temp(k-ind_even_odd,jyn,i2) = p_mg(k,j,i)
1889	ENDDO
1890	i2 = i2 + 1
1891
1892	ENDIF
1893
1894	ENDDO
1895	ENDDO
1896
1897	DO i = nxl_mg(l)+1, nxr_mg(l), 2
1898	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
1899
1900	IF ( j == nys_mg(l) ) THEN
1901	!DIR$ IVDEP
1902	DO k = ind_even_odd+1, nzt_mg(l)
1903	temp(k-ind_even_odd,jys,i1) = p_mg(k,j,i)
1904	ENDDO
1905	i1 = i1 + 1
1906
1907	ENDIF
1908
1909	IF ( j == nyn_mg(l) ) THEN
1910	!DIR$ IVDEP
1911	DO k = ind_even_odd+1, nzt_mg(l)
1912	temp(k-ind_even_odd,jyn,i2) = p_mg(k,j,i)
1913	ENDDO
1914	i2 = i2 + 1
1915
1916	ENDIF
1917
1918	ENDDO
1919	ENDDO
1920
1921	grid_level = grid_level-1
1922
1923	nxl = nxl_mg(grid_level)
1924	nys = nys_mg(grid_level)
1925	nxr = nxr_mg(grid_level)
1926	nyn = nyn_mg(grid_level)
1927	nzt = nzt_mg(grid_level)
1928
1929	send_receive = 'ns'
1930	CALL exchange_horiz( temp, 1 )
1931
1932	grid_level = grid_level+1
1933
1934	i1 = nxl_mg(grid_level-1)
1935	i2 = nxl_mg(grid_level-1)
1936
1937	DO i = nxl_mg(l), nxr_mg(l), 2
1938	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
1939
1940	IF ( j == nys_mg(l) ) THEN
1941	!DIR$ IVDEP
1942	DO k = ind_even_odd+1, nzt_mg(l)
1943	p_mg(k,nyn_mg(l)+1,i) = temp(k-ind_even_odd,jyn+1,i1)
1944	ENDDO
1945	i1 = i1 + 1
1946
1947	ENDIF
1948
1949	IF ( j == nyn_mg(l) ) THEN
1950	!DIR$ IVDEP
1951	DO k = ind_even_odd+1, nzt_mg(l)
1952	p_mg(k,nys_mg(l)-1,i) = temp(k-ind_even_odd,jys-1,i2)
1953	ENDDO
1954	i2 = i2 + 1
1955
1956	ENDIF
1957
1958	ENDDO
1959	ENDDO
1960
1961	DO i = nxl_mg(l)+1, nxr_mg(l), 2
1962	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
1963
1964	IF ( j == nys_mg(l) ) THEN
1965	!DIR$ IVDEP
1966	DO k = ind_even_odd+1, nzt_mg(l)
1967	p_mg(k,nyn_mg(l)+1,i) = temp(k-ind_even_odd,jyn+1,i1)
1968	ENDDO
1969	i1 = i1 + 1
1970
1971	ENDIF
1972
1973	IF ( j == nyn_mg(l) ) THEN
1974	!DIR$ IVDEP
1975	DO k = ind_even_odd+1, nzt_mg(l)
1976	p_mg(k,nys_mg(l)-1,i) = temp(k-ind_even_odd,jys-1,i2)
1977	ENDDO
1978	i2 = i2 + 1
1979
1980	ENDIF
1981
1982	ENDDO
1983	ENDDO
1984
1985	!
1986	!-- Collecting data for the left - right exchange
1987	!-- Since only every second value has to be transfered, data are stored
1988	!-- on the next coarser grid level, because the arrays on that level
1989	!-- have just the required size
1990	j1 = nys_mg(grid_level-1)
1991	j2 = nys_mg(grid_level-1)
1992
1993	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
1994	DO i = nxl_mg(l), nxr_mg(l), 2
1995
1996	IF ( i == nxl_mg(l) ) THEN
1997	!DIR$ IVDEP
1998	DO k = ind_even_odd+1, nzt_mg(l)
1999	temp(k-ind_even_odd,j1,ixl) = p_mg(k,j,i)
2000	ENDDO
2001	j1 = j1 + 1
2002
2003	ENDIF
2004
2005	IF ( i == nxr_mg(l) ) THEN
2006	!DIR$ IVDEP
2007	DO k = ind_even_odd+1, nzt_mg(l)
2008	temp(k-ind_even_odd,j2,ixr) = p_mg(k,j,i)
2009	ENDDO
2010	j2 = j2 + 1
2011
2012	ENDIF
2013
2014	ENDDO
2015	ENDDO
2016
2017	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
2018	DO i = nxl_mg(l)+1, nxr_mg(l), 2
2019
2020	IF ( i == nxl_mg(l) ) THEN
2021	!DIR$ IVDEP
2022	DO k = ind_even_odd+1, nzt_mg(l)
2023	temp(k-ind_even_odd,j1,ixl) = p_mg(k,j,i)
2024	ENDDO
2025	j1 = j1 + 1
2026
2027	ENDIF
2028
2029	IF ( i == nxr_mg(l) ) THEN
2030	!DIR$ IVDEP
2031	DO k = ind_even_odd+1, nzt_mg(l)
2032	temp(k-ind_even_odd,j2,ixr) = p_mg(k,j,i)
2033	ENDDO
2034	j2 = j2 + 1
2035
2036	ENDIF
2037
2038	ENDDO
2039	ENDDO
2040
2041	grid_level = grid_level-1
2042	send_receive = 'lr'
2043
2044	CALL exchange_horiz( temp, 1 )
2045
2046	grid_level = grid_level+1
2047
2048	j1 = nys_mg(grid_level-1)
2049	j2 = nys_mg(grid_level-1)
2050
2051	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
2052	DO i = nxl_mg(l), nxr_mg(l), 2
2053
2054	IF ( i == nxl_mg(l) ) THEN
2055	!DIR$ IVDEP
2056	DO k = ind_even_odd+1, nzt_mg(l)
2057	p_mg(k,j,nxr_mg(l)+1) = temp(k-ind_even_odd,j1,ixr+1)
2058	ENDDO
2059	j1 = j1 + 1
2060
2061	ENDIF
2062
2063	IF ( i == nxr_mg(l) ) THEN
2064	!DIR$ IVDEP
2065	DO k = ind_even_odd+1, nzt_mg(l)
2066	p_mg(k,j,nxl_mg(l)-1) = temp(k-ind_even_odd,j2,ixl-1)
2067	ENDDO
2068	j2 = j2 + 1
2069
2070	ENDIF
2071
2072	ENDDO
2073	ENDDO
2074
2075	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
2076	DO i = nxl_mg(l)+1, nxr_mg(l), 2
2077
2078	IF ( i == nxl_mg(l) ) THEN
2079	!DIR$ IVDEP
2080	DO k = ind_even_odd+1, nzt_mg(l)
2081	p_mg(k,j,nxr_mg(l)+1) = temp(k-ind_even_odd,j1,ixr+1)
2082	ENDDO
2083	j1 = j1 + 1
2084
2085	ENDIF
2086
2087	IF ( i == nxr_mg(l) ) THEN
2088	!DIR$ IVDEP
2089	DO k = ind_even_odd+1, nzt_mg(l)
2090	p_mg(k,j,nxl_mg(l)-1) = temp(k-ind_even_odd,j2,ixl-1)
2091	ENDDO
2092	j2 = j2 + 1
2093
2094	ENDIF
2095
2096	ENDDO
2097	ENDDO
2098
2099	!
2100	!-- Now handling the even k values
2101	!-- Collecting data for the north - south exchange
2102	!-- Since only every second value has to be transfered, data are stored
2103	!-- on the next coarser grid level, because the arrays on that level
2104	!-- have just the required size
2105	i1 = nxl_mg(grid_level-1)
2106	i2 = nxl_mg(grid_level-1)
2107
2108	DO i = nxl_mg(l), nxr_mg(l), 2
2109	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
2110
2111	IF ( j == nys_mg(l) ) THEN
2112	!DIR$ IVDEP
2113	DO k = nzb+1, ind_even_odd
2114	temp(k,jys,i1) = p_mg(k,j,i)
2115	ENDDO
2116	i1 = i1 + 1
2117
2118	ENDIF
2119
2120	IF ( j == nyn_mg(l) ) THEN
2121	!DIR$ IVDEP
2122	DO k = nzb+1, ind_even_odd
2123	temp(k,jyn,i2) = p_mg(k,j,i)
2124	ENDDO
2125	i2 = i2 + 1
2126
2127	ENDIF
2128
2129	ENDDO
2130	ENDDO
2131
2132	DO i = nxl_mg(l)+1, nxr_mg(l), 2
2133	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
2134
2135	IF ( j == nys_mg(l) ) THEN
2136	!DIR$ IVDEP
2137	DO k = nzb+1, ind_even_odd
2138	temp(k,jys,i1) = p_mg(k,j,i)
2139	ENDDO
2140	i1 = i1 + 1
2141
2142	ENDIF
2143
2144	IF ( j == nyn_mg(l) ) THEN
2145	!DIR$ IVDEP
2146	DO k = nzb+1, ind_even_odd
2147	temp(k,jyn,i2) = p_mg(k,j,i)
2148	ENDDO
2149	i2 = i2 + 1
2150
2151	ENDIF
2152
2153	ENDDO
2154	ENDDO
2155
2156	grid_level = grid_level-1
2157
2158	send_receive = 'ns'
2159	CALL exchange_horiz( temp, 1 )
2160
2161	grid_level = grid_level+1
2162
2163	i1 = nxl_mg(grid_level-1)
2164	i2 = nxl_mg(grid_level-1)
2165
2166	DO i = nxl_mg(l), nxr_mg(l), 2
2167	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
2168
2169	IF ( j == nys_mg(l) ) THEN
2170	!DIR$ IVDEP
2171	DO k = nzb+1, ind_even_odd
2172	p_mg(k,nyn_mg(l)+1,i) = temp(k,jyn+1,i1)
2173	ENDDO
2174	i1 = i1 + 1
2175
2176	ENDIF
2177
2178	IF ( j == nyn_mg(l) ) THEN
2179	!DIR$ IVDEP
2180	DO k = nzb+1, ind_even_odd
2181	p_mg(k,nys_mg(l)-1,i) = temp(k,jys-1,i2)
2182	ENDDO
2183	i2 = i2 + 1
2184
2185	ENDIF
2186
2187	ENDDO
2188	ENDDO
2189
2190	DO i = nxl_mg(l)+1, nxr_mg(l), 2
2191	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
2192
2193	IF ( j == nys_mg(l) ) THEN
2194	!DIR$ IVDEP
2195	DO k = nzb+1, ind_even_odd
2196	p_mg(k,nyn_mg(l)+1,i) = temp(k,jyn+1,i1)
2197	ENDDO
2198	i1 = i1 + 1
2199
2200	ENDIF
2201
2202	IF ( j == nyn_mg(l) ) THEN
2203	!DIR$ IVDEP
2204	DO k = nzb+1, ind_even_odd
2205	p_mg(k,nys_mg(l)-1,i) = temp(k,jys-1,i2)
2206	ENDDO
2207	i2 = i2 + 1
2208
2209	ENDIF
2210
2211	ENDDO
2212	ENDDO
2213
2214	j1 = nys_mg(grid_level-1)
2215	j2 = nys_mg(grid_level-1)
2216
2217	DO i = nxl_mg(l), nxr_mg(l), 2
2218	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
2219
2220	IF ( i == nxl_mg(l) ) THEN
2221	!DIR$ IVDEP
2222	DO k = nzb+1, ind_even_odd
2223	temp(k,j1,ixl) = p_mg(k,j,i)
2224	ENDDO
2225	j1 = j1 + 1
2226
2227	ENDIF
2228
2229	IF ( i == nxr_mg(l) ) THEN
2230	!DIR$ IVDEP
2231	DO k = nzb+1, ind_even_odd
2232	temp(k,j2,ixr) = p_mg(k,j,i)
2233	ENDDO
2234	j2 = j2 + 1
2235
2236	ENDIF
2237
2238	ENDDO
2239	ENDDO
2240
2241	DO i = nxl_mg(l)+1, nxr_mg(l), 2
2242	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
2243
2244	IF ( i == nxl_mg(l) ) THEN
2245	!DIR$ IVDEP
2246	DO k = nzb+1, ind_even_odd
2247	temp(k,j1,ixl) = p_mg(k,j,i)
2248	ENDDO
2249	j1 = j1 + 1
2250
2251	ENDIF
2252
2253	IF ( i == nxr_mg(l) ) THEN
2254	!DIR$ IVDEP
2255	DO k = nzb+1, ind_even_odd
2256	temp(k,j2,ixr) = p_mg(k,j,i)
2257	ENDDO
2258	j2 = j2 + 1
2259
2260	ENDIF
2261
2262	ENDDO
2263	ENDDO
2264
2265	grid_level = grid_level-1
2266
2267	send_receive = 'lr'
2268	CALL exchange_horiz( temp, 1 )
2269
2270	grid_level = grid_level+1
2271
2272	nxl = nxl_mg(grid_level)
2273	nys = nys_mg(grid_level)
2274	nxr = nxr_mg(grid_level)
2275	nyn = nyn_mg(grid_level)
2276	nzt = nzt_mg(grid_level)
2277
2278	j1 = nys_mg(grid_level-1)
2279	j2 = nys_mg(grid_level-1)
2280
2281	DO i = nxl_mg(l), nxr_mg(l), 2
2282	DO j = nys_mg(l) + (color-1), nyn_mg(l), 2
2283
2284	IF ( i == nxl_mg(l) ) THEN
2285	!DIR$ IVDEP
2286	DO k = nzb+1, ind_even_odd
2287	p_mg(k,j,nxr_mg(l)+1) = temp(k,j1,ixr+1)
2288	ENDDO
2289	j1 = j1 + 1
2290
2291	ENDIF
2292
2293	IF ( i == nxr_mg(l) ) THEN
2294	!DIR$ IVDEP
2295	DO k = nzb+1, ind_even_odd
2296	p_mg(k,j,nxl_mg(l)-1) = temp(k,j2,ixl-1)
2297	ENDDO
2298	j2 = j2 + 1
2299
2300	ENDIF
2301
2302	ENDDO
2303	ENDDO
2304
2305	DO i = nxl_mg(l)+1, nxr_mg(l), 2
2306	DO j = nys_mg(l) + 2 - color, nyn_mg(l), 2
2307
2308	IF ( i == nxl_mg(l) ) THEN
2309	!DIR$ IVDEP
2310	DO k = nzb+1, ind_even_odd
2311	p_mg(k,j,nxr_mg(l)+1) = temp(k,j1,ixr+1)
2312	ENDDO
2313	j1 = j1 + 1
2314
2315	ENDIF
2316
2317	IF ( i == nxr_mg(l) ) THEN
2318	!DIR$ IVDEP
2319	DO k = nzb+1, ind_even_odd
2320	p_mg(k,j,nxl_mg(l)-1) = temp(k,j2,ixl-1)
2321	ENDDO
2322	j2 = j2 + 1
2323
2324	ENDIF
2325
2326	ENDDO
2327	ENDDO
2328
2329	DEALLOCATE( temp )
2330
2331	ELSE
2332
2333	!
2334	!-- Standard horizontal ghost boundary exchange for small coarse grid
2335	!-- levels, where the transfer time is latency bound
2336	CALL exchange_horiz( p_mg, 1 )
2337
2338	ENDIF
2339
2340	!
2341	!-- Reset values to default PALM setup
2342	sendrecv_in_background = sendrecv_in_background_save
2343	synchronous_exchange = synchronous_exchange_save
2344	send_receive = 'al'
2345	#else
2346
2347	!
2348	!-- Standard horizontal ghost boundary exchange for small coarse grid
2349	!-- levels, where the transfer time is latency bound
2350	CALL exchange_horiz( p_mg, 1 )
2351	#endif
2352
2353	END SUBROUTINE special_exchange_horiz
2354
2355	END MODULE poismg_mod

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