Home

Context Navigation

source: palm/trunk/SOURCE/transpose.f90 @ 513

Last change on this file since 513 was 484, checked in by raasch, 15 years ago
typo in file headers removed
Property svn:keywords set to `Id`
File size: 17.8 KB

Line
1	SUBROUTINE transpose_xy( f_in, work, f_out )
2
3	!------------------------------------------------------------------------------!
4	! Current revisions:
5	! -----------------
6	!
7	!
8	! Former revisions:
9	! -----------------
10	! $Id: transpose.f90 484 2010-02-05 07:36:54Z heinze $
11	!
12	! 164 2008-05-15 08:46:15Z raasch
13	! f_inv changed from subroutine argument to automatic array in order to do
14	! re-ordering from f_in to f_inv in one step, one array work is needed instead
15	! of work1 and work2
16	!
17	! February 2007
18	! RCS Log replace by Id keyword, revision history cleaned up
19	!
20	! Revision 1.2 2004/04/30 13:12:17 raasch
21	! Switched from mpi_alltoallv to the simpler mpi_alltoall,
22	! all former transpose-routine files collected in this file, enlarged
23	! transposition arrays introduced
24	!
25	! Revision 1.1 2004/04/30 13:08:16 raasch
26	! Initial revision (collection of former routines transpose_xy, transpose_xz,
27	! transpose_yx, transpose_yz, transpose_zx, transpose_zy)
28	!
29	! Revision 1.1 1997/07/24 11:25:18 raasch
30	! Initial revision
31	!
32	!
33	! Description:
34	! ------------
35	! Transposition of input array (f_in) from x to y. For the input array, all
36	! elements along x reside on the same PE, while after transposition, all
37	! elements along y reside on the same PE.
38	!------------------------------------------------------------------------------!
39
40	USE cpulog
41	USE indices
42	USE interfaces
43	USE pegrid
44	USE transpose_indices
45
46	IMPLICIT NONE
47
48	INTEGER :: i, j, k, l, m, ys
49
50	REAL :: f_in(0:nxa,nys_x:nyn_xa,nzb_x:nzt_xa), &
51	f_inv(nys_x:nyn_xa,nzb_x:nzt_xa,0:nxa), &
52	f_out(0:nya,nxl_y:nxr_ya,nzb_y:nzt_ya), &
53	work(nnxnnynnz)
54
55	#if defined( __parallel )
56
57	!
58	!-- Rearrange indices of input array in order to make data to be send
59	!-- by MPI contiguous
60	DO i = 0, nxa
61	DO k = nzb_x, nzt_xa
62	DO j = nys_x, nyn_xa
63	f_inv(j,k,i) = f_in(i,j,k)
64	ENDDO
65	ENDDO
66	ENDDO
67
68	!
69	!-- Transpose array
70	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
71	CALL MPI_ALLTOALL( f_inv(nys_x,nzb_x,0), sendrecvcount_xy, MPI_REAL, &
72	work(1), sendrecvcount_xy, MPI_REAL, &
73	comm1dy, ierr )
74	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
75
76	!
77	!-- Reorder transposed array
78	m = 0
79	DO l = 0, pdims(2) - 1
80	ys = 0 + l * ( nyn_xa - nys_x + 1 )
81	DO i = nxl_y, nxr_ya
82	DO k = nzb_y, nzt_ya
83	DO j = ys, ys + nyn_xa - nys_x
84	m = m + 1
85	f_out(j,i,k) = work(m)
86	ENDDO
87	ENDDO
88	ENDDO
89	ENDDO
90
91	#endif
92
93	END SUBROUTINE transpose_xy
94
95
96	SUBROUTINE transpose_xz( f_in, work, f_out )
97
98	!------------------------------------------------------------------------------!
99	! Description:
100	! ------------
101	! Transposition of input array (f_in) from x to z. For the input array, all
102	! elements along x reside on the same PE, while after transposition, all
103	! elements along z reside on the same PE.
104	!------------------------------------------------------------------------------!
105
106	USE cpulog
107	USE indices
108	USE interfaces
109	USE pegrid
110	USE transpose_indices
111
112	IMPLICIT NONE
113
114	INTEGER :: i, j, k, l, m, xs
115
116	REAL :: f_in(0:nxa,nys_x:nyn_xa,nzb_x:nzt_xa), &
117	f_inv(nys:nyna,nxl:nxra,1:nza), &
118	f_out(1:nza,nys:nyna,nxl:nxra), &
119	work(nnxnnynnz)
120
121	#if defined( __parallel )
122
123	!
124	!-- If the PE grid is one-dimensional along y, the array has only to be
125	!-- reordered locally and therefore no transposition has to be done.
126	IF ( pdims(1) /= 1 ) THEN
127	!
128	!-- Reorder input array for transposition
129	m = 0
130	DO l = 0, pdims(1) - 1
131	xs = 0 + l * nnx
132	DO k = nzb_x, nzt_xa
133	DO i = xs, xs + nnx - 1
134	DO j = nys_x, nyn_xa
135	m = m + 1
136	work(m) = f_in(i,j,k)
137	ENDDO
138	ENDDO
139	ENDDO
140	ENDDO
141
142	!
143	!-- Transpose array
144	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
145	CALL MPI_ALLTOALL( work(1), sendrecvcount_zx, MPI_REAL, &
146	f_inv(nys,nxl,1), sendrecvcount_zx, MPI_REAL, &
147	comm1dx, ierr )
148	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
149
150	!
151	!-- Reorder transposed array in a way that the z index is in first position
152	DO k = 1, nza
153	DO i = nxl, nxra
154	DO j = nys, nyna
155	f_out(k,j,i) = f_inv(j,i,k)
156	ENDDO
157	ENDDO
158	ENDDO
159	ELSE
160	!
161	!-- Reorder the array in a way that the z index is in first position
162	DO i = nxl, nxra
163	DO j = nys, nyna
164	DO k = 1, nza
165	f_inv(j,i,k) = f_in(i,j,k)
166	ENDDO
167	ENDDO
168	ENDDO
169
170	DO k = 1, nza
171	DO i = nxl, nxra
172	DO j = nys, nyna
173	f_out(k,j,i) = f_inv(j,i,k)
174	ENDDO
175	ENDDO
176	ENDDO
177
178	ENDIF
179
180
181	#endif
182
183	END SUBROUTINE transpose_xz
184
185
186	SUBROUTINE transpose_yx( f_in, work, f_out )
187
188	!------------------------------------------------------------------------------!
189	! Description:
190	! ------------
191	! Transposition of input array (f_in) from y to x. For the input array, all
192	! elements along y reside on the same PE, while after transposition, all
193	! elements along x reside on the same PE.
194	!------------------------------------------------------------------------------!
195
196	USE cpulog
197	USE indices
198	USE interfaces
199	USE pegrid
200	USE transpose_indices
201
202	IMPLICIT NONE
203
204	INTEGER :: i, j, k, l, m, ys
205
206	REAL :: f_in(0:nya,nxl_y:nxr_ya,nzb_y:nzt_ya), &
207	f_inv(nys_x:nyn_xa,nzb_x:nzt_xa,0:nxa), &
208	f_out(0:nxa,nys_x:nyn_xa,nzb_x:nzt_xa), &
209	work(nnxnnynnz)
210
211	#if defined( __parallel )
212
213	!
214	!-- Reorder input array for transposition
215	m = 0
216	DO l = 0, pdims(2) - 1
217	ys = 0 + l * ( nyn_xa - nys_x + 1 )
218	DO i = nxl_y, nxr_ya
219	DO k = nzb_y, nzt_ya
220	DO j = ys, ys + nyn_xa - nys_x
221	m = m + 1
222	work(m) = f_in(j,i,k)
223	ENDDO
224	ENDDO
225	ENDDO
226	ENDDO
227
228	!
229	!-- Transpose array
230	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
231	CALL MPI_ALLTOALL( work(1), sendrecvcount_xy, MPI_REAL, &
232	f_inv(nys_x,nzb_x,0), sendrecvcount_xy, MPI_REAL, &
233	comm1dy, ierr )
234	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
235
236	!
237	!-- Reorder transposed array in a way that the x index is in first position
238	DO i = 0, nxa
239	DO k = nzb_x, nzt_xa
240	DO j = nys_x, nyn_xa
241	f_out(i,j,k) = f_inv(j,k,i)
242	ENDDO
243	ENDDO
244	ENDDO
245
246	#endif
247
248	END SUBROUTINE transpose_yx
249
250
251	SUBROUTINE transpose_yxd( f_in, work, f_out )
252
253	!------------------------------------------------------------------------------!
254	! Description:
255	! ------------
256	! Transposition of input array (f_in) from y to x. For the input array, all
257	! elements along y reside on the same PE, while after transposition, all
258	! elements along x reside on the same PE.
259	! This is a direct transposition for arrays with indices in regular order
260	! (k,j,i) (cf. transpose_yx).
261	!------------------------------------------------------------------------------!
262
263	USE cpulog
264	USE indices
265	USE interfaces
266	USE pegrid
267	USE transpose_indices
268
269	IMPLICIT NONE
270
271	INTEGER :: i, j, k, l, m, recvcount_yx, sendcount_yx, xs
272
273	REAL :: f_in(1:nza,nys:nyna,nxl:nxra), f_inv(nxl:nxra,1:nza,nys:nyna), &
274	f_out(0:nxa,nys_x:nyn_xa,nzb_x:nzt_xa), &
275	work(nnxnnynnz)
276
277	#if defined( __parallel )
278
279	!
280	!-- Rearrange indices of input array in order to make data to be send
281	!-- by MPI contiguous
282	DO k = 1, nza
283	DO j = nys, nyna
284	DO i = nxl, nxra
285	f_inv(i,k,j) = f_in(k,j,i)
286	ENDDO
287	ENDDO
288	ENDDO
289
290	!
291	!-- Transpose array
292	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
293	CALL MPI_ALLTOALL( f_inv(nxl,1,nys), sendrecvcount_xy, MPI_REAL, &
294	work(1), sendrecvcount_xy, MPI_REAL, &
295	comm1dx, ierr )
296	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
297
298	!
299	!-- Reorder transposed array
300	m = 0
301	DO l = 0, pdims(1) - 1
302	xs = 0 + l * nnx
303	DO j = nys_x, nyn_xa
304	DO k = 1, nza
305	DO i = xs, xs + nnx - 1
306	m = m + 1
307	f_out(i,j,k) = work(m)
308	ENDDO
309	ENDDO
310	ENDDO
311	ENDDO
312
313	#endif
314
315	END SUBROUTINE transpose_yxd
316
317
318	SUBROUTINE transpose_yz( f_in, work, f_out )
319
320	!------------------------------------------------------------------------------!
321	! Description:
322	! ------------
323	! Transposition of input array (f_in) from y to z. For the input array, all
324	! elements along y reside on the same PE, while after transposition, all
325	! elements along z reside on the same PE.
326	!------------------------------------------------------------------------------!
327
328	USE cpulog
329	USE indices
330	USE interfaces
331	USE pegrid
332	USE transpose_indices
333
334	IMPLICIT NONE
335
336	INTEGER :: i, j, k, l, m, zs
337
338	REAL :: f_in(0:nya,nxl_y:nxr_ya,nzb_y:nzt_ya), &
339	f_inv(nxl_y:nxr_ya,nzb_y:nzt_ya,0:nya), &
340	f_out(nxl_z:nxr_za,nys_z:nyn_za,1:nza), &
341	work(nnxnnynnz)
342
343	#if defined( __parallel )
344
345	!
346	!-- Rearrange indices of input array in order to make data to be send
347	!-- by MPI contiguous
348	DO j = 0, nya
349	DO k = nzb_y, nzt_ya
350	DO i = nxl_y, nxr_ya
351	f_inv(i,k,j) = f_in(j,i,k)
352	ENDDO
353	ENDDO
354	ENDDO
355
356	!
357	!-- Move data to different array, because memory location of work1 is
358	!-- needed further below (work1 = work2).
359	!-- If the PE grid is one-dimensional along y, only local reordering
360	!-- of the data is necessary and no transposition has to be done.
361	IF ( pdims(1) == 1 ) THEN
362	DO j = 0, nya
363	DO k = nzb_y, nzt_ya
364	DO i = nxl_y, nxr_ya
365	f_out(i,j,k) = f_inv(i,k,j)
366	ENDDO
367	ENDDO
368	ENDDO
369	RETURN
370	ENDIF
371
372	!
373	!-- Transpose array
374	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
375	CALL MPI_ALLTOALL( f_inv(nxl_y,nzb_y,0), sendrecvcount_yz, MPI_REAL, &
376	work(1), sendrecvcount_yz, MPI_REAL, &
377	comm1dx, ierr )
378	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
379
380	!
381	!-- Reorder transposed array
382	m = 0
383	DO l = 0, pdims(1) - 1
384	zs = 1 + l * ( nzt_ya - nzb_y + 1 )
385	DO j = nys_z, nyn_za
386	DO k = zs, zs + nzt_ya - nzb_y
387	DO i = nxl_z, nxr_za
388	m = m + 1
389	f_out(i,j,k) = work(m)
390	ENDDO
391	ENDDO
392	ENDDO
393	ENDDO
394
395	#endif
396
397	END SUBROUTINE transpose_yz
398
399
400	SUBROUTINE transpose_zx( f_in, work, f_out )
401
402	!------------------------------------------------------------------------------!
403	! Description:
404	! ------------
405	! Transposition of input array (f_in) from z to x. For the input array, all
406	! elements along z reside on the same PE, while after transposition, all
407	! elements along x reside on the same PE.
408	!------------------------------------------------------------------------------!
409
410	USE cpulog
411	USE indices
412	USE interfaces
413	USE pegrid
414	USE transpose_indices
415
416	IMPLICIT NONE
417
418	INTEGER :: i, j, k, l, m, xs
419
420	REAL :: f_in(1:nza,nys:nyna,nxl:nxra), f_inv(nys:nyna,nxl:nxra,1:nza), &
421	f_out(0:nxa,nys_x:nyn_xa,nzb_x:nzt_xa), &
422	work(nnxnnynnz)
423
424	#if defined( __parallel )
425
426	!
427	!-- Rearrange indices of input array in order to make data to be send
428	!-- by MPI contiguous
429	DO k = 1,nza
430	DO i = nxl, nxra
431	DO j = nys, nyna
432	f_inv(j,i,k) = f_in(k,j,i)
433	ENDDO
434	ENDDO
435	ENDDO
436
437	!
438	!-- Move data to different array, because memory location of work1 is
439	!-- needed further below (work1 = work2).
440	!-- If the PE grid is one-dimensional along y, only local reordering
441	!-- of the data is necessary and no transposition has to be done.
442	IF ( pdims(1) == 1 ) THEN
443	DO k = 1, nza
444	DO i = nxl, nxra
445	DO j = nys, nyna
446	f_out(i,j,k) = f_inv(j,i,k)
447	ENDDO
448	ENDDO
449	ENDDO
450	RETURN
451	ENDIF
452
453	!
454	!-- Transpose array
455	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
456	CALL MPI_ALLTOALL( f_inv(nys,nxl,1), sendrecvcount_zx, MPI_REAL, &
457	work(1), sendrecvcount_zx, MPI_REAL, &
458	comm1dx, ierr )
459	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
460
461	!
462	!-- Reorder transposed array
463	m = 0
464	DO l = 0, pdims(1) - 1
465	xs = 0 + l * nnx
466	DO k = nzb_x, nzt_xa
467	DO i = xs, xs + nnx - 1
468	DO j = nys_x, nyn_xa
469	m = m + 1
470	f_out(i,j,k) = work(m)
471	ENDDO
472	ENDDO
473	ENDDO
474	ENDDO
475
476	#endif
477
478	END SUBROUTINE transpose_zx
479
480
481	SUBROUTINE transpose_zy( f_in, work, f_out )
482
483	!------------------------------------------------------------------------------!
484	! Description:
485	! ------------
486	! Transposition of input array (f_in) from z to y. For the input array, all
487	! elements along z reside on the same PE, while after transposition, all
488	! elements along y reside on the same PE.
489	!------------------------------------------------------------------------------!
490
491	USE cpulog
492	USE indices
493	USE interfaces
494	USE pegrid
495	USE transpose_indices
496
497	IMPLICIT NONE
498
499	INTEGER :: i, j, k, l, m, zs
500
501	REAL :: f_in(nxl_z:nxr_za,nys_z:nyn_za,1:nza), &
502	f_inv(nxl_y:nxr_ya,nzb_y:nzt_ya,0:nya), &
503	f_out(0:nya,nxl_y:nxr_ya,nzb_y:nzt_ya), &
504	work(nnxnnynnz)
505
506	#if defined( __parallel )
507
508	!
509	!-- If the PE grid is one-dimensional along y, the array has only to be
510	!-- reordered locally and therefore no transposition has to be done.
511	IF ( pdims(1) /= 1 ) THEN
512	!
513	!-- Reorder input array for transposition
514	m = 0
515	DO l = 0, pdims(1) - 1
516	zs = 1 + l * ( nzt_ya - nzb_y + 1 )
517	DO j = nys_z, nyn_za
518	DO k = zs, zs + nzt_ya - nzb_y
519	DO i = nxl_z, nxr_za
520	m = m + 1
521	work(m) = f_in(i,j,k)
522	ENDDO
523	ENDDO
524	ENDDO
525	ENDDO
526
527	!
528	!-- Transpose array
529	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
530	CALL MPI_ALLTOALL( work(1), sendrecvcount_yz, MPI_REAL, &
531	f_inv(nxl_y,nzb_y,0), sendrecvcount_yz, MPI_REAL, &
532	comm1dx, ierr )
533	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
534
535	!
536	!-- Reorder transposed array in a way that the y index is in first position
537	DO j = 0, nya
538	DO k = nzb_y, nzt_ya
539	DO i = nxl_y, nxr_ya
540	f_out(j,i,k) = f_inv(i,k,j)
541	ENDDO
542	ENDDO
543	ENDDO
544	ELSE
545	!
546	!-- Reorder the array in a way that the y index is in first position
547	DO k = nzb_y, nzt_ya
548	DO j = 0, nya
549	DO i = nxl_y, nxr_ya
550	f_inv(i,k,j) = f_in(i,j,k)
551	ENDDO
552	ENDDO
553	ENDDO
554	!
555	!-- Move data to output array
556	DO k = nzb_y, nzt_ya
557	DO i = nxl_y, nxr_ya
558	DO j = 0, nya
559	f_out(j,i,k) = f_inv(i,k,j)
560	ENDDO
561	ENDDO
562	ENDDO
563
564	ENDIF
565
566	#endif
567
568	END SUBROUTINE transpose_zy
569
570
571	SUBROUTINE transpose_zyd( f_in, work, f_out )
572
573	!------------------------------------------------------------------------------!
574	! Description:
575	! ------------
576	! Transposition of input array (f_in) from z to y. For the input array, all
577	! elements along z reside on the same PE, while after transposition, all
578	! elements along y reside on the same PE.
579	! This is a direct transposition for arrays with indices in regular order
580	! (k,j,i) (cf. transpose_zy).
581	!------------------------------------------------------------------------------!
582
583	USE cpulog
584	USE indices
585	USE interfaces
586	USE pegrid
587	USE transpose_indices
588
589	IMPLICIT NONE
590
591	INTEGER :: i, j, k, l, m, ys
592
593	REAL :: f_in(1:nza,nys:nyna,nxl:nxra), f_inv(nys:nyna,nxl:nxra,1:nza), &
594	f_out(0:nya,nxl_yd:nxr_yda,nzb_yd:nzt_yda), &
595	work(nnxnnynnz)
596
597	#if defined( __parallel )
598
599	!
600	!-- Rearrange indices of input array in order to make data to be send
601	!-- by MPI contiguous
602	DO i = nxl, nxra
603	DO j = nys, nyna
604	DO k = 1, nza
605	f_inv(j,i,k) = f_in(k,j,i)
606	ENDDO
607	ENDDO
608	ENDDO
609
610	!
611	!-- Move data to different array, because memory location of work1 is
612	!-- needed further below (work1 = work2).
613	!-- If the PE grid is one-dimensional along x, only local reordering
614	!-- of the data is necessary and no transposition has to be done.
615	IF ( pdims(2) == 1 ) THEN
616	DO k = 1, nza
617	DO i = nxl, nxra
618	DO j = nys, nyna
619	f_out(j,i,k) = f_inv(j,i,k)
620	ENDDO
621	ENDDO
622	ENDDO
623	RETURN
624	ENDIF
625
626	!
627	!-- Transpose array
628	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'start' )
629	CALL MPI_ALLTOALL( f_inv(nys,nxl,1), sendrecvcount_zyd, MPI_REAL, &
630	work(1), sendrecvcount_zyd, MPI_REAL, &
631	comm1dy, ierr )
632	CALL cpu_log( log_point_s(32), 'mpi_alltoall', 'stop' )
633
634	!
635	!-- Reorder transposed array
636	m = 0
637	DO l = 0, pdims(2) - 1
638	ys = 0 + l * nny
639	DO k = nzb_yd, nzt_yda
640	DO i = nxl_yd, nxr_yda
641	DO j = ys, ys + nny - 1
642	m = m + 1
643	f_out(j,i,k) = work(m)
644	ENDDO
645	ENDDO
646	ENDDO
647	ENDDO
648
649	#endif
650
651	END SUBROUTINE transpose_zyd

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

Download in other formats:

| Impressum | ©Leibniz Universität Hannover |