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mathelp.f90 @ 1

Last change on this file since 1 was 1, checked in by lfita, 10 years ago

-- --- Opening of the WRF+LMDZ coupling repository --- -- -

WRF: version v3.3
LMDZ: version v1818

More details in:

File size: 83.0 KB

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1	MODULE mathelp
2	!-
3	!$Id: mathelp.f90 1927 2012-11-22 13:54:21Z dsolyga $
4	!-
5	! This software is governed by the CeCILL license
6	! See IOIPSL/IOIPSL_License_CeCILL.txt
7	!---------------------------------------------------------------------
8	USE errioipsl,ONLY : ipslerr
9	USE stringop
10	!-
11	PRIVATE
12	PUBLIC :: mathop,moycum,moycum_index,buildop
13	!-
14	INTERFACE mathop
15	MODULE PROCEDURE mathop_r11,mathop_r21,mathop_r31
16	END INTERFACE
17	!-
18	!- Variables used to detect and identify the operations
19	!-
20	CHARACTER(LEN=80),SAVE :: &
21	& seps='( ) , + - / * ^', ops = '+ - * / ^', mima = 'min max'
22	CHARACTER(LEN=250),SAVE :: &
23	& funcs = 'sin cos tan asin acos atan exp log sqrt chs abs '&
24	& //'cels kelv deg rad gather scatter fill coll undef only ident'
25	CHARACTER(LEN=120),SAVE :: &
26	& indexfu = 'gather, scatter, fill, coll, undef, only'
27	!---------------------------------------------------------------------
28	CONTAINS
29	!===
30	SUBROUTINE buildop (c_str,ex_topps,topp,fill_val,opps,scal,nbops)
31	!---------------------------------------------------------------------
32	!- This subroutine decomposes the input string in the elementary
33	!- functions which need to be applied to the vector of data.
34	!- This vector is represented by X in the string.
35	!- This subroutine is the driver of the decomposition and gets
36	!- the time operation but then call decoop for the other operations
37	!-
38	!- INPUT
39	!-
40	!- c_str : String containing the operations
41	!- ex_toops : Time operations that can be expected within the string
42	!- fill_val :
43	!-
44	!- OUTPUT
45	!-
46	!- topp : Time operation
47	!- opps :
48	!- scal :
49	!- nbops :
50	!---------------------------------------------------------------------
51	IMPLICIT NONE
52	!-
53	CHARACTER(LEN=*),INTENT(IN) :: c_str,ex_topps
54	CHARACTER(LEN=*),INTENT(OUT) :: topp
55	CHARACTER(LEN=*),DIMENSION(:),INTENT(OUT) :: opps
56	REAL,INTENT(IN) :: fill_val
57	REAL,DIMENSION(:),INTENT(OUT) :: scal
58	INTEGER,INTENT(OUT) :: nbops
59	!-
60	CHARACTER(LEN=LEN(c_str)) :: str,new_str
61	INTEGER :: leng,ind_opb,ind_clb
62	!-
63	LOGICAL :: check = .FALSE.
64	!---------------------------------------------------------------------
65	IF (check) WRITE(,) 'buildop : Some preliminary cleaning'
66	!-
67	str = c_str
68	leng = LEN_TRIM(str)
69	IF ( str(1:1) == '(' .AND. str(leng:leng) == ')' ) THEN
70	str = str(2:leng-1)
71	leng = leng-2
72	ENDIF
73	!-
74	IF (check) &
75	& WRITE(,) 'buildop : Starting to test the various options'
76	!-
77	IF (leng <= 5 .AND. INDEX(ex_topps,str(1:leng)) > 0) THEN
78	IF (check) WRITE(,) 'buildop : Time operation only'
79	nbops = 0
80	topp = str(1:leng)
81	ELSE
82	IF (check) THEN
83	WRITE(,) 'buildop : Time operation and something else'
84	ENDIF
85	!--
86	ind_opb = INDEX(str(1:leng),'(')
87	IF (ind_opb > 0) THEN
88	IF (INDEX(ex_topps,str(1:ind_opb-1)) > 0) THEN
89	IF (check) THEN
90	WRITE(*,'(2a)') &
91	& ' buildop : Extract time operation from : ',str
92	ENDIF
93	topp = str(1:ind_opb-1)
94	ind_clb = INDEX(str(1:leng),')',BACK=.TRUE.)
95	new_str = str(ind_opb+1:ind_clb-1)
96	IF (check) THEN
97	WRITE(*,'(2a,2I3)') &
98	& ' buildop : Call decoop ',new_str,ind_opb,ind_clb
99	ENDIF
100	CALL decoop (new_str,fill_val,opps,scal,nbops)
101	ELSE
102	CALL ipslerr(3,'buildop', &
103	& 'time operation does not exist',str(1:ind_opb-1),' ')
104	ENDIF
105	ELSE
106	CALL ipslerr(3,'buildop', &
107	& 'some long operation exists but wihout parenthesis', &
108	& str(1:leng),' ')
109	ENDIF
110	ENDIF
111	!-
112	IF (check) THEN
113	DO leng=1,nbops
114	WRITE(,) &
115	& 'buildop : i -- opps, scal : ',leng,opps(leng),scal(leng)
116	ENDDO
117	ENDIF
118	!---------------------
119	END SUBROUTINE buildop
120	!===
121	SUBROUTINE decoop (pstr,fill_val,opps,scal,nbops)
122	!---------------------------------------------------------------------
123	IMPLICIT NONE
124	!-
125	CHARACTER(LEN=*),INTENT(IN) :: pstr
126	REAL,INTENT(IN) :: fill_val
127	CHARACTER(LEN=*),DIMENSION(:),INTENT(OUT) :: opps
128	REAL,DIMENSION(:),INTENT(OUT) :: scal
129	INTEGER,INTENT(OUT) :: nbops
130	!-
131	CHARACTER(LEN=1),DIMENSION(2) :: f_char,s_char
132	INTEGER,DIMENSION(2) :: f_pos,s_pos
133	CHARACTER(LEN=20) :: opp_str,scal_str
134	CHARACTER(LEN=LEN(pstr)) :: str
135	INTEGER :: nbsep,nbops_max,xpos,leng,ppos,epos,int_tmp
136	CHARACTER(LEN=3) :: tl,dl
137	CHARACTER(LEN=10) :: fmt
138	!-
139	LOGICAL :: check = .FALSE.,prio
140	!---------------------------------------------------------------------
141	IF (check) WRITE(*,'(2A)') ' decoop : Incoming string : ',pstr
142	!-
143	str = pstr; nbops = 0;
144	!-
145	CALL findsep (str,nbsep,f_char,f_pos,s_char,s_pos)
146	IF (check) WRITE(,) 'decoop : Out of findsep',nbsep
147	!-
148	nbops_max = min(SIZE(opps),SIZE(scal))
149	!-
150	DO WHILE (nbsep > 0)
151	IF (nbops >= nbops_max) THEN
152	CALL ipslerr(3,'decoop','Expression too complex',TRIM(str),' ')
153	ENDIF
154	!--
155	xpos = INDEX(str,'X')
156	leng = LEN_TRIM(str)
157	nbops = nbops+1
158	!--
159	IF (check) THEN
160	WRITE(,) 'decoop : str -> ',TRIM(str)
161	WRITE(,) 'decoop : nbops -> ',nbops
162	WRITE(,) s_char(1),'-',f_char(1),'\|',f_char(2),'-',s_char(2)
163	WRITE(,) s_pos(1),'-',f_pos(1),'\|',f_pos(2),'-',s_pos(2)
164	ENDIF
165	!---
166	!-- Start the analysis of the syntax. 3 types of constructs
167	!-- are recognized. They are scanned sequentialy
168	!---
169	IF (nbsep == 1) THEN
170	IF (check) WRITE(,) 'decoop : Only one operation'
171	IF (INDEX(ops,f_char(1)) > 0) THEN
172	!------ Type : scal+X
173	IF (f_char(1) == '-' .OR. f_char(1) == '/') THEN
174	opp_str = f_char(1)//'I'
175	ELSE
176	opp_str = f_char(1)
177	ENDIF
178	scal_str = str(s_pos(1)+1:f_pos(1)-1)
179	str = 'X'
180	ELSE IF (INDEX(ops,f_char(2)) > 0) THEN
181	!------ Type : X+scal
182	opp_str = f_char(2)
183	scal_str = str(f_pos(2)+1:s_pos(2)-1)
184	str = 'X'
185	ELSE
186	CALL ipslerr(3,'decoop', &
187	& 'Unknown operations of type X+scal',f_char(1),pstr)
188	ENDIF
189	ELSE
190	IF (check) WRITE(,) 'decoop : More complex operation'
191	IF ( f_char(1) == '(' .AND. f_char(2) == ')' ) THEN
192	!------ Type : sin(X)
193	opp_str = str(s_pos(1)+1:f_pos(1)-1)
194	scal_str = '?'
195	str = str(1:s_pos(1))//'X'//str(f_pos(2)+1:leng)
196	ELSE IF ( (f_char(1) == '(' .AND. f_char(2) == ',')&
197	& .OR.(f_char(1) == ',' .AND. f_char(2) == ')')) THEN
198	!------ Type : max(X,scal) or max(scal,X)
199	IF (f_char(1) == '(' .AND. s_char(2) == ')') THEN
200	!-------- Type : max(X,scal)
201	opp_str = str(f_pos(1)-3:f_pos(1)-1)
202	scal_str = str(f_pos(2)+1:s_pos(2)-1)
203	str = str(1:f_pos(1)-4)//'X'//str(s_pos(2)+1:leng)
204	ELSE IF (f_char(1) == ',' .AND. s_char(1) == '(') THEN
205	!-------- Type : max(scal,X)
206	opp_str = str(s_pos(1)-3:s_pos(1)-1)
207	scal_str = str(s_pos(1)+1:f_pos(1)-1)
208	str = str(1:s_pos(1)-4)//'X'//str(f_pos(2)+1:leng)
209	ELSE
210	CALL ipslerr(3,'decoop','Syntax error 1',str,' ')
211	ENDIF
212	ELSE
213	prio = (f_char(2) == '*').OR.(f_char(2) == '^')
214	IF ( (INDEX(ops,f_char(1)) > 0) &
215	& .AND.(xpos-f_pos(1) == 1).AND.(.NOT.prio) ) THEN
216	!-------- Type : ... scal+X ...
217	IF (f_char(1) == '-' .OR. f_char(1) == '/') THEN
218	opp_str = f_char(1)//'I'
219	ELSE
220	opp_str = f_char(1)
221	ENDIF
222	scal_str = str(s_pos(1)+1:f_pos(1)-1)
223	str = str(1:s_pos(1))//'X'//str(f_pos(1)+2:leng)
224	ELSE IF ( (INDEX(ops,f_char(2)) > 0) &
225	& .AND.(f_pos(2)-xpos == 1) ) THEN
226	!-------- Type : ... X+scal ...
227	opp_str = f_char(2)
228	scal_str = str(f_pos(2)+1:s_pos(2)-1)
229	str = str(1:f_pos(2)-2)//'X'//str(s_pos(2):leng)
230	ELSE
231	CALL ipslerr(3,'decoop','Syntax error 2',str,' ')
232	ENDIF
233	ENDIF
234	ENDIF
235	!---
236	IF (check) WRITE(,) 'decoop : Finished syntax,str = ',TRIM(str)
237	!---
238	!-- Now that the different components of the operation are identified
239	!-- we transform them into what is going to be used in the program
240	!---
241	IF (INDEX(scal_str,'?') > 0) THEN
242	IF (INDEX(funcs,opp_str(1:LEN_TRIM(opp_str))) > 0) THEN
243	opps(nbops) = opp_str(1:LEN_TRIM(opp_str))
244	scal(nbops) = fill_val
245	ELSE
246	CALL ipslerr(3,'decoop', &
247	& 'Unknown function',opp_str(1:LEN_TRIM(opp_str)),' ')
248	ENDIF
249	ELSE
250	leng = LEN_TRIM(opp_str)
251	IF (INDEX(mima,opp_str(1:leng)) > 0) THEN
252	opps(nbops) = 'fu'//opp_str(1:leng)
253	ELSE
254	IF (INDEX(opp_str(1:leng),'+') > 0) THEN
255	opps(nbops) = 'add'
256	ELSE IF (INDEX(opp_str(1:leng),'-I') > 0) THEN
257	opps(nbops) = 'subi'
258	ELSE IF (INDEX(opp_str(1:leng),'-') > 0) THEN
259	opps(nbops) = 'sub'
260	ELSE IF (INDEX(opp_str(1:leng),'*') > 0) THEN
261	opps(nbops) = 'mult'
262	ELSE IF (INDEX(opp_str(1:leng),'/') > 0) THEN
263	opps(nbops) = 'div'
264	ELSE IF (INDEX(opp_str(1:leng),'/I') > 0) THEN
265	opps(nbops) = 'divi'
266	ELSE IF (INDEX(opp_str(1:leng),'^') > 0) THEN
267	opps(nbops) = 'power'
268	ELSE
269	CALL ipslerr(3,'decoop', &
270	& 'Unknown operation',opp_str(1:leng),' ')
271	ENDIF
272	ENDIF
273	!-----
274	leng = LEN_TRIM(scal_str)
275	ppos = INDEX(scal_str,'.')
276	epos = INDEX(scal_str,'e')
277	IF (epos == 0) epos = INDEX(scal_str,'E')
278	!-----
279	!---- Try to catch a few errors
280	!-----
281	IF (INDEX(ops,scal_str) > 0) THEN
282	CALL ipslerr(3,'decoop', &
283	& 'Strange scalar you have here ',scal_str,pstr)
284	ENDIF
285	IF (epos > 0) THEN
286	WRITE(tl,'(I3.3)') leng
287	WRITE(dl,'(I3.3)') epos-ppos-1
288	fmt='(e'//tl//'.'//dl//')'
289	READ(scal_str,fmt) scal(nbops)
290	ELSE IF (ppos > 0) THEN
291	WRITE(tl,'(I3.3)') leng
292	WRITE(dl,'(I3.3)') leng-ppos
293	fmt='(f'//tl//'.'//dl//')'
294	READ(scal_str,fmt) scal(nbops)
295	ELSE
296	WRITE(tl,'(I3.3)') leng
297	fmt = '(I'//tl//')'
298	READ(scal_str,fmt) int_tmp
299	scal(nbops) = REAL(int_tmp)
300	ENDIF
301	ENDIF
302	IF (check) WRITE(,) 'decoop : Finished interpretation'
303	CALL findsep(str,nbsep,f_char,f_pos,s_char,s_pos)
304	ENDDO
305	!--------------------
306	END SUBROUTINE decoop
307	!===
308	SUBROUTINE findsep (str,nbsep,f_char,f_pos,s_char,s_pos)
309	!---------------------------------------------------------------------
310	!- Subroutine finds all separators in a given string
311	!- It returns the following information about str :
312	!- f_char : The first separation character
313	!- (1 for before and 2 for after)
314	!- f_pos : The position of the first separator
315	!- s_char : The second separation character
316	!- (1 for before and 2 for after)
317	!- s_pos : The position of the second separator
318	!---------------------------------------------------------------------
319	IMPLICIT NONE
320	!-
321	CHARACTER(LEN=*),INTENT(INOUT) :: str
322	INTEGER :: nbsep
323	CHARACTER(LEN=1),DIMENSION(2) :: f_char,s_char
324	INTEGER,DIMENSION(2) :: f_pos,s_pos
325	!-
326	CHARACTER(LEN=10) :: str_tmp
327	LOGICAL :: f_found,s_found
328	INTEGER :: ind,xpos,leng,i
329	!-
330	LOGICAL :: check = .FALSE.
331	!---------------------------------------------------------------------
332	IF (check) WRITE(,) 'findsep : call cleanstr: ',TRIM(str)
333	!-
334	CALL cleanstr(str)
335	!-
336	IF (check) WRITE(,) 'findsep : out of cleanstr: ',TRIM(str)
337	!-
338	xpos = INDEX(str,'X')
339	leng = LEN_TRIM(str)
340	!-
341	f_pos(1:2) = (/ 0,leng+1 /)
342	f_char(1:2) = (/ '?','?' /)
343	s_pos(1:2) = (/ 0,leng+1 /)
344	s_char(1:2) = (/ '?','?' /)
345	!-
346	nbsep = 0
347	!-
348	f_found = .FALSE.
349	s_found = .FALSE.
350	IF (xpos > 1) THEN
351	DO i=xpos-1,1,-1
352	ind = INDEX(seps,str(i:i))
353	IF (ind > 0) THEN
354	IF (.NOT.f_found) THEN
355	f_char(1) = str(i:i)
356	f_pos(1) = i
357	nbsep = nbsep+1
358	f_found = .TRUE.
359	ELSE IF (.NOT.s_found) THEN
360	s_char(1) = str(i:i)
361	s_pos(1) = i
362	nbsep = nbsep+1
363	s_found = .TRUE.
364	ENDIF
365	ENDIF
366	ENDDO
367	ENDIF
368	!-
369	f_found = .FALSE.
370	s_found = .FALSE.
371	IF (xpos < leng) THEN
372	DO i=xpos+1,leng
373	ind = INDEX(seps,str(i:i))
374	IF (ind > 0) THEN
375	IF (.NOT.f_found) THEN
376	f_char(2) = str(i:i)
377	f_pos(2) = i
378	nbsep = nbsep+1
379	f_found = .TRUE.
380	ELSE IF (.NOT.s_found) THEN
381	s_char(2) = str(i:i)
382	s_pos(2) = i
383	nbsep = nbsep+1
384	s_found = .TRUE.
385	ENDIF
386	ENDIF
387	ENDDO
388	ENDIF
389	!-
390	IF (nbsep > 4) THEN
391	WRITE(str_tmp,'("number :",I3)') nbsep
392	CALL ipslerr(3,'findsep', &
393	& 'How can I find that many separators',str_tmp,TRIM(str))
394	ENDIF
395	!-
396	IF (check) WRITE(,) 'Finished findsep : ',nbsep,leng
397	!---------------------
398	END SUBROUTINE findsep
399	!===
400	SUBROUTINE cleanstr(str)
401	!---------------------------------------------------------------------
402	!- We clean up the string by taking out the extra () and puting
403	!- everything in lower case except for the X describing the variable
404	!---------------------------------------------------------------------
405	IMPLICIT NONE
406	!-
407	CHARACTER(LEN=*),INTENT(INOUT) :: str
408	!-
409	INTEGER :: ind,leng,ic,it
410	LOGICAL :: check = .FALSE.
411	!---------------------------------------------------------------------
412	leng = LEN_TRIM(str)
413	CALL strlowercase(str)
414	!-
415	ind = INDEX(str,'x')
416	IF (check) THEN
417	WRITE (,) 'cleanstr 1.0 : ind = ',ind, &
418	& ' str = ',str(1:leng),'---'
419	ENDIF
420	!-
421	! If the character before the x is not a letter then we can assume
422	! that it is the variable and promote it to a capital letter
423	!-
424	DO WHILE (ind > 0)
425	ic = 0
426	IF (ind > 1) ic = IACHAR(str(ind-1:ind-1))
427	IF (ic < 97 .OR. ic > 122) THEN
428	str(ind:ind) = 'X'
429	ENDIF
430	it = INDEX(str(ind+1:leng),'x')
431	IF (it > 0) THEN
432	ind = ind+it
433	ELSE
434	ind = it
435	ENDIF
436	ENDDO
437	!-
438	IF (check) WRITE (,) 'cleanstr 2.0 : str = ',str(1:leng),'---'
439	!-
440	IF ( str(1:1) == '(' .AND. str(leng:leng) == ')' ) THEN
441	str = str(2:leng-1)
442	ENDIF
443	!-
444	IF (check) WRITE (,) 'cleanstr 3.0 : str = ',str(1:leng),'---'
445	!-
446	leng = LEN_TRIM(str)
447	ind = INDEX(str,'((X))')
448	IF (ind > 0) THEN
449	str=str(1:ind-1)//'(X)'//str(ind+5:leng)//' '
450	ENDIF
451	!-
452	IF (check) WRITE (,) 'cleanstr 4.0 : str = ',str(1:leng),'---'
453	!-
454	leng = LEN_TRIM(str)
455	ind = INDEX(str,'(X)')
456	IF (ind > 0 .AND. ind+3 < leng) THEN
457	IF ( (INDEX(seps,str(ind-1:ind-1)) > 0) &
458	& .AND. (INDEX(seps,str(ind+3:ind+3)) > 0) ) THEN
459	str=str(1:ind-1)//'X'//str(ind+3:leng)//' '
460	ENDIF
461	ENDIF
462	!-
463	IF (check) WRITE (,) 'cleanstr 5.0 : str = ',str(1:leng),'---'
464	!-
465	leng = LEN_TRIM(str)
466	ind = INDEX(str(1:leng),' ')
467	DO WHILE (ind > 0)
468	str=str(1:ind-1)//str(ind+1:leng)//' '
469	leng = LEN_TRIM(str)
470	ind = INDEX(str(1:leng),' ')
471	ENDDO
472	!-
473	IF (check) WRITE (,) 'cleanstr 6.0 : str = ',str(1:leng),'---'
474	!----------------------
475	END SUBROUTINE cleanstr
476	!===
477	!===
478	SUBROUTINE mathop_r11 &
479	& (fun,nb,work_in,miss_val,nb_index,nindex,scal,nb_max,work_out)
480	!---------------------------------------------------------------------
481	!- This subroutines gives an interface to the various operation
482	!- which are allowed. The interface is general enough to allow its use
483	!- for other cases.
484	!-
485	!- INPUT
486	!-
487	!- fun : function to be applied to the vector of data
488	!- nb : Length of input vector
489	!- work_in : Input vector of data (REAL)
490	!- miss_val : The value of the missing data flag (it has to be a
491	!- maximum value, in f90 : huge( a real ))
492	!- nb_index : Length of index vector
493	!- nindex : Vector of indices
494	!- scal : A scalar value for vector/scalar operations
495	!- nb_max : maximum length of output vector
496	!-
497	!- OUTPUT
498	!-
499	!- nb_max : Actual length of output variable
500	!- work_out : Output vector after the operation was applied
501	!---------------------------------------------------------------------
502	IMPLICIT NONE
503	!-
504	CHARACTER(LEN=7) :: fun
505	INTEGER :: nb,nb_max,nb_index
506	INTEGER :: nindex(nb_index)
507	REAL :: work_in(nb),scal,miss_val
508	REAL :: work_out(nb_max)
509	!-
510	INTEGER :: ierr
511	!-
512	INTRINSIC SIN,COS,TAN,ASIN,ACOS,ATAN,EXP,LOG,SQRT,ABS
513	!---------------------------------------------------------------------
514	ierr = 0
515	!-
516	IF (scal >= miss_val-1.) THEN
517	IF (INDEX(indexfu,fun(1:LEN_TRIM(fun))) == 0) THEN
518	SELECT CASE (fun)
519	CASE('sin')
520	ierr = ma_sin_r11(nb,work_in,nb_max,work_out)
521	CASE('cos')
522	ierr = ma_cos_r11(nb,work_in,nb_max,work_out)
523	CASE('tan')
524	ierr = ma_tan_r11(nb,work_in,nb_max,work_out)
525	CASE('asin')
526	ierr = ma_asin_r11(nb,work_in,nb_max,work_out)
527	CASE('acos')
528	ierr = ma_acos_r11(nb,work_in,nb_max,work_out)
529	CASE('atan')
530	ierr = ma_atan_r11(nb,work_in,nb_max,work_out)
531	CASE('exp')
532	ierr = ma_exp_r11(nb,work_in,nb_max,work_out)
533	CASE('log')
534	ierr = ma_log_r11(nb,work_in,nb_max,work_out)
535	CASE('sqrt')
536	ierr = ma_sqrt_r11(nb,work_in,nb_max,work_out)
537	CASE('chs')
538	ierr = ma_chs_r11(nb,work_in,nb_max,work_out)
539	CASE('abs')
540	ierr = ma_abs_r11(nb,work_in,nb_max,work_out)
541	CASE('cels')
542	ierr = ma_cels_r11(nb,work_in,nb_max,work_out)
543	CASE('kelv')
544	ierr = ma_kelv_r11(nb,work_in,nb_max,work_out)
545	CASE('deg')
546	ierr = ma_deg_r11(nb,work_in,nb_max,work_out)
547	CASE('rad')
548	ierr = ma_rad_r11(nb,work_in,nb_max,work_out)
549	CASE('ident')
550	ierr = ma_ident_r11(nb,work_in,nb_max,work_out)
551	CASE DEFAULT
552	CALL ipslerr(3,"mathop", &
553	& 'scalar variable undefined and no indexing', &
554	& 'but still unknown function',fun)
555	END SELECT
556	IF (ierr > 0) THEN
557	CALL ipslerr(3,"mathop", &
558	& 'Error while executing a simple function',fun,' ')
559	ENDIF
560	ELSE
561	SELECT CASE (fun)
562	CASE('gather')
563	ierr = ma_fugath_r11(nb,work_in,nb_index,nindex, &
564	& miss_val,nb_max,work_out)
565	CASE('scatter')
566	IF (nb_index > nb) THEN
567	work_out(1:nb_max) = miss_val
568	ierr=1
569	ELSE
570	ierr = ma_fuscat_r11(nb,work_in,nb_index,nindex, &
571	& miss_val,nb_max,work_out)
572	ENDIF
573	CASE('coll')
574	ierr = ma_fucoll_r11(nb,work_in,nb_index,nindex, &
575	& miss_val,nb_max,work_out)
576	CASE('fill')
577	ierr = ma_fufill_r11(nb,work_in,nb_index,nindex, &
578	& miss_val,nb_max,work_out)
579	CASE('undef')
580	ierr = ma_fuundef_r11(nb,work_in,nb_index,nindex, &
581	& miss_val,nb_max,work_out)
582	CASE('only')
583	ierr = ma_fuonly_r11(nb,work_in,nb_index,nindex, &
584	& miss_val,nb_max,work_out)
585	CASE DEFAULT
586	CALL ipslerr(3,"mathop", &
587	& 'scalar variable undefined and indexing',&
588	& 'was requested but with unknown function',fun)
589	END SELECT
590	IF (ierr > 0) THEN
591	CALL ipslerr(3,"mathop_r11", &
592	& 'Error while executing an indexing function',fun,' ')
593	ENDIF
594	ENDIF
595	ELSE
596	SELECT CASE (fun)
597	CASE('fumin')
598	ierr = ma_fumin_r11(nb,work_in,scal,nb_max,work_out)
599	CASE('fumax')
600	ierr = ma_fumax_r11(nb,work_in,scal,nb_max,work_out)
601	CASE('add')
602	ierr = ma_add_r11(nb,work_in,scal,nb_max,work_out)
603	CASE('subi')
604	ierr = ma_subi_r11(nb,work_in,scal,nb_max,work_out)
605	CASE('sub')
606	ierr = ma_sub_r11(nb,work_in,scal,nb_max,work_out)
607	CASE('mult')
608	ierr = ma_mult_r11(nb,work_in,scal,nb_max,work_out)
609	CASE('div')
610	ierr = ma_div_r11(nb,work_in,scal,nb_max,work_out)
611	CASE('divi')
612	ierr = ma_divi_r11(nb,work_in,scal,nb_max,work_out)
613	CASE('power')
614	ierr = ma_power_r11(nb,work_in,scal,nb_max,work_out)
615	CASE DEFAULT
616	CALL ipslerr(3,"mathop", &
617	& 'Unknown operation with a scalar',fun,' ')
618	END SELECT
619	IF (ierr > 0) THEN
620	CALL ipslerr(3,"mathop", &
621	& 'Error while executing a scalar function',fun,' ')
622	ENDIF
623	ENDIF
624	!------------------------
625	END SUBROUTINE mathop_r11
626	!-
627	!=== FUNCTIONS (only one argument)
628	!-
629	INTEGER FUNCTION ma_sin_r11(nb,x,nbo,y)
630	!---------------------------------------------------------------------
631	IMPLICIT NONE
632	!-
633	INTEGER :: nb,nbo,i
634	REAL :: x(nb),y(nbo)
635	!---------------------------------------------------------------------
636	DO i=1,nb
637	y(i) = SIN(x(i))
638	ENDDO
639	!-
640	nbo = nb
641	ma_sin_r11 = 0
642	!----------------------
643	END FUNCTION ma_sin_r11
644	!===
645	INTEGER FUNCTION ma_cos_r11(nb,x,nbo,y)
646	!---------------------------------------------------------------------
647	IMPLICIT NONE
648	!-
649	INTEGER :: nb,nbo,i
650	REAL :: x(nb),y(nbo)
651	!---------------------------------------------------------------------
652	DO i=1,nb
653	y(i) = COS(x(i))
654	ENDDO
655	!-
656	nbo = nb
657	ma_cos_r11 = 0
658	!----------------------
659	END FUNCTION ma_cos_r11
660	!===
661	INTEGER FUNCTION ma_tan_r11(nb,x,nbo,y)
662	!---------------------------------------------------------------------
663	IMPLICIT NONE
664	!-
665	INTEGER :: nb,nbo,i
666	REAL :: x(nb),y(nbo)
667	!---------------------------------------------------------------------
668	DO i=1,nb
669	y(i) = TAN(x(i))
670	ENDDO
671	!-
672	nbo = nb
673	ma_tan_r11 = 0
674	!----------------------
675	END FUNCTION ma_tan_r11
676	!===
677	INTEGER FUNCTION ma_asin_r11(nb,x,nbo,y)
678	!---------------------------------------------------------------------
679	IMPLICIT NONE
680	!-
681	INTEGER :: nb,nbo,i
682	REAL :: x(nb),y(nbo)
683	!---------------------------------------------------------------------
684	DO i=1,nb
685	y(i) = ASIN(x(i))
686	ENDDO
687	!-
688	nbo = nb
689	ma_asin_r11 = 0
690	!-----------------------
691	END FUNCTION ma_asin_r11
692	!===
693	INTEGER FUNCTION ma_acos_r11(nb,x,nbo,y)
694	!---------------------------------------------------------------------
695	IMPLICIT NONE
696	!-
697	INTEGER :: nb,nbo,i
698	REAL :: x(nb),y(nbo)
699	!---------------------------------------------------------------------
700	DO i=1,nb
701	y(i) = ACOS(x(i))
702	ENDDO
703	!-
704	nbo = nb
705	ma_acos_r11 = 0
706	!-----------------------
707	END FUNCTION ma_acos_r11
708	!===
709	INTEGER FUNCTION ma_atan_r11(nb,x,nbo,y)
710	!---------------------------------------------------------------------
711	IMPLICIT NONE
712	!-
713	INTEGER :: nb,nbo,i
714	REAL :: x(nb),y(nbo)
715	!---------------------------------------------------------------------
716	DO i=1,nb
717	y(i) = ATAN(x(i))
718	ENDDO
719	!-
720	nbo = nb
721	ma_atan_r11 = 0
722	!-----------------------
723	END FUNCTION ma_atan_r11
724	!===
725	INTEGER FUNCTION ma_exp_r11(nb,x,nbo,y)
726	!---------------------------------------------------------------------
727	IMPLICIT NONE
728	!-
729	INTEGER :: nb,nbo,i
730	REAL :: x(nb),y(nbo)
731	!---------------------------------------------------------------------
732	DO i=1,nb
733	y(i) = EXP(x(i))
734	ENDDO
735	!-
736	nbo = nb
737	ma_exp_r11 = 0
738	!----------------------
739	END FUNCTION ma_exp_r11
740	!===
741	INTEGER FUNCTION ma_log_r11(nb,x,nbo,y)
742	!---------------------------------------------------------------------
743	IMPLICIT NONE
744	!-
745	INTEGER :: nb,nbo,i
746	REAL :: x(nb),y(nbo)
747	!---------------------------------------------------------------------
748	DO i=1,nb
749	y(i) = log(x(i))
750	ENDDO
751	!-
752	nbo = nb
753	ma_log_r11 = 0
754	!----------------------
755	END FUNCTION ma_log_r11
756	!===
757	INTEGER FUNCTION ma_sqrt_r11(nb,x,nbo,y)
758	!---------------------------------------------------------------------
759	IMPLICIT NONE
760	!-
761	INTEGER :: nb,nbo,i
762	REAL :: x(nb),y(nbo)
763	!---------------------------------------------------------------------
764	DO i=1,nb
765	y(i) = SQRT(x(i))
766	ENDDO
767	!-
768	nbo = nb
769	ma_sqrt_r11 = 0
770	!-----------------------
771	END FUNCTION ma_sqrt_r11
772	!===
773	INTEGER FUNCTION ma_abs_r11(nb,x,nbo,y)
774	!---------------------------------------------------------------------
775	IMPLICIT NONE
776	!-
777	INTEGER :: nb,nbo,i
778	REAL :: x(nb),y(nbo)
779	!---------------------------------------------------------------------
780	DO i=1,nb
781	y(i) = ABS(x(i))
782	ENDDO
783	!-
784	nbo = nb
785	ma_abs_r11 = 0
786	!----------------------
787	END FUNCTION ma_abs_r11
788	!===
789	INTEGER FUNCTION ma_chs_r11(nb,x,nbo,y)
790	!---------------------------------------------------------------------
791	IMPLICIT NONE
792	!-
793	INTEGER :: nb,nbo,i
794	REAL :: x(nb),y(nbo)
795	!---------------------------------------------------------------------
796	DO i=1,nb
797	y(i) = x(i)*(-1.)
798	ENDDO
799	!-
800	nbo = nb
801	ma_chs_r11 = 0
802	!----------------------
803	END FUNCTION ma_chs_r11
804	!===
805	INTEGER FUNCTION ma_cels_r11(nb,x,nbo,y)
806	!---------------------------------------------------------------------
807	IMPLICIT NONE
808	!-
809	INTEGER :: nb,nbo,i
810	REAL :: x(nb),y(nbo)
811	!---------------------------------------------------------------------
812	DO i=1,nb
813	y(i) = x(i)-273.15
814	ENDDO
815	!-
816	nbo = nb
817	ma_cels_r11 = 0
818	!-----------------------
819	END FUNCTION ma_cels_r11
820	!===
821	INTEGER FUNCTION ma_kelv_r11(nb,x,nbo,y)
822	!---------------------------------------------------------------------
823	IMPLICIT NONE
824	!-
825	INTEGER :: nb,nbo,i
826	REAL :: x(nb),y(nbo)
827	!---------------------------------------------------------------------
828	DO i=1,nb
829	y(i) = x(i)+273.15
830	ENDDO
831	!-
832	nbo = nb
833	ma_kelv_r11 = 0
834	!-----------------------
835	END FUNCTION ma_kelv_r11
836	!===
837	INTEGER FUNCTION ma_deg_r11(nb,x,nbo,y)
838	!---------------------------------------------------------------------
839	IMPLICIT NONE
840	!-
841	INTEGER :: nb,nbo,i
842	REAL :: x(nb),y(nbo)
843	!---------------------------------------------------------------------
844	DO i=1,nb
845	y(i) = x(i)*57.29577951
846	ENDDO
847	!-
848	nbo = nb
849	ma_deg_r11 = 0
850	!-----------------------
851	END FUNCTION ma_deg_r11
852	!===
853	INTEGER FUNCTION ma_rad_r11(nb,x,nbo,y)
854	!---------------------------------------------------------------------
855	IMPLICIT NONE
856	!-
857	INTEGER :: nb,nbo,i
858	REAL :: x(nb),y(nbo)
859	!---------------------------------------------------------------------
860	DO i=1,nb
861	y(i) = x(i)*0.01745329252
862	ENDDO
863	!-
864	nbo = nb
865	ma_rad_r11 = 0
866	!----------------------
867	END FUNCTION ma_rad_r11
868	!===
869	INTEGER FUNCTION ma_ident_r11(nb,x,nbo,y)
870	!---------------------------------------------------------------------
871	IMPLICIT NONE
872	!-
873	INTEGER :: nb,nbo,i
874	REAL :: x(nb),y(nbo)
875	!---------------------------------------------------------------------
876	DO i=1,nb
877	y(i) = x(i)
878	ENDDO
879	!-
880	nbo = nb
881	ma_ident_r11 = 0
882	!------------------------
883	END FUNCTION ma_ident_r11
884	!-
885	!=== OPERATIONS (two argument)
886	!-
887	INTEGER FUNCTION ma_add_r11(nb,x,s,nbo,y)
888	!---------------------------------------------------------------------
889	IMPLICIT NONE
890	!-
891	INTEGER :: nb,nbo
892	REAL :: x(nb),s,y(nbo)
893	!-
894	INTEGER :: i
895	!---------------------------------------------------------------------
896	DO i=1,nb
897	y(i) = x(i)+s
898	ENDDO
899	!-
900	nbo = nb
901	ma_add_r11 = 0
902	!-----------------------
903	END FUNCTION ma_add_r11
904	!===
905	INTEGER FUNCTION ma_sub_r11(nb,x,s,nbo,y)
906	!---------------------------------------------------------------------
907	IMPLICIT NONE
908	!-
909	INTEGER :: nb,nbo
910	REAL :: x(nb),s,y(nbo)
911	!-
912	INTEGER :: i
913	!---------------------------------------------------------------------
914	DO i=1,nb
915	y(i) = x(i)-s
916	ENDDO
917	!-
918	nbo = nb
919	ma_sub_r11 = 0
920	!----------------------
921	END FUNCTION ma_sub_r11
922	!===
923	INTEGER FUNCTION ma_subi_r11(nb,x,s,nbo,y)
924	!---------------------------------------------------------------------
925	IMPLICIT NONE
926	!-
927	INTEGER :: nb,nbo
928	REAL :: x(nb),s,y(nbo)
929	!-
930	INTEGER :: i
931	!---------------------------------------------------------------------
932	DO i=1,nb
933	y(i) = s-x(i)
934	ENDDO
935	!-
936	nbo = nb
937	ma_subi_r11 = 0
938	!-----------------------
939	END FUNCTION ma_subi_r11
940	!===
941	INTEGER FUNCTION ma_mult_r11(nb,x,s,nbo,y)
942	!---------------------------------------------------------------------
943	IMPLICIT NONE
944	!-
945	INTEGER :: nb,nbo
946	REAL :: x(nb),s,y(nbo)
947	!-
948	INTEGER :: i
949	!---------------------------------------------------------------------
950	DO i=1,nb
951	y(i) = x(i)*s
952	ENDDO
953	!-
954	nbo = nb
955	ma_mult_r11 = 0
956	!-----------------------
957	END FUNCTION ma_mult_r11
958	!===
959	INTEGER FUNCTION ma_div_r11(nb,x,s,nbo,y)
960	!---------------------------------------------------------------------
961	IMPLICIT NONE
962	!-
963	INTEGER :: nb,nbo
964	REAL :: x(nb),s,y(nbo)
965	!-
966	INTEGER :: i
967	!---------------------------------------------------------------------
968	DO i=1,nb
969	y(i) = x(i)/s
970	ENDDO
971	!-
972	nbo = nb
973	ma_div_r11 = 0
974	!-----------------------
975	END FUNCTION ma_div_r11
976	!===
977	INTEGER FUNCTION ma_divi_r11(nb,x,s,nbo,y)
978	!---------------------------------------------------------------------
979	IMPLICIT NONE
980	!-
981	INTEGER :: nb,nbo
982	REAL :: x(nb),s,y(nbo)
983	!-
984	INTEGER :: i
985	!---------------------------------------------------------------------
986	DO i=1,nb
987	y(i) = s/x(i)
988	ENDDO
989	!-
990	nbo = nb
991	ma_divi_r11 = 0
992	!-----------------------
993	END FUNCTION ma_divi_r11
994	!===
995	INTEGER FUNCTION ma_power_r11(nb,x,s,nbo,y)
996	!---------------------------------------------------------------------
997	IMPLICIT NONE
998	!-
999	INTEGER :: nb,nbo
1000	REAL :: x(nb),s,y(nbo)
1001	!-
1002	INTEGER :: i
1003	!---------------------------------------------------------------------
1004	DO i=1,nb
1005	y(i) = x(i)**s
1006	ENDDO
1007	!-
1008	nbo = nb
1009	ma_power_r11 = 0
1010	!-----------------------
1011	END FUNCTION ma_power_r11
1012	!===
1013	INTEGER FUNCTION ma_fumin_r11(nb,x,s,nbo,y)
1014	!---------------------------------------------------------------------
1015	IMPLICIT NONE
1016	!-
1017	INTEGER :: nb,nbo
1018	REAL :: x(nb),s,y(nbo)
1019	!-
1020	INTEGER :: i
1021	!---------------------------------------------------------------------
1022	DO i=1,nb
1023	y(i) = MIN(x(i),s)
1024	ENDDO
1025	!-
1026	nbo = nb
1027	ma_fumin_r11 = 0
1028	!------------------------
1029	END FUNCTION ma_fumin_r11
1030	!===
1031	INTEGER FUNCTION ma_fumax_r11(nb,x,s,nbo,y)
1032	!---------------------------------------------------------------------
1033	IMPLICIT NONE
1034	!-
1035	INTEGER :: nb,nbo
1036	REAL :: x(nb),s,y(nbo)
1037	!-
1038	INTEGER :: i
1039	!---------------------------------------------------------------------
1040	DO i=1,nb
1041	y(i) = MAX(x(i),s)
1042	ENDDO
1043	!-
1044	nbo = nb
1045	ma_fumax_r11 = 0
1046	!------------------------
1047	END FUNCTION ma_fumax_r11
1048	!===
1049	INTEGER FUNCTION ma_fuscat_r11(nb,x,nbi,ind,miss_val,nbo,y)
1050	!---------------------------------------------------------------------
1051	IMPLICIT NONE
1052	!-
1053	INTEGER :: nb,nbo,nbi
1054	INTEGER :: ind(nbi)
1055	REAL :: x(nb),miss_val,y(nbo)
1056	!-
1057	INTEGER :: i,ii,ipos
1058	!---------------------------------------------------------------------
1059	ma_fuscat_r11 = 0
1060	!-
1061	y(1:nbo) = miss_val
1062	!-
1063	IF (nbi <= nb) THEN
1064	ipos = 0
1065	DO i=1,nbi
1066	IF (ind(i) <= nbo .AND. ind(i) > 0) THEN
1067	ipos = ipos+1
1068	y(ind(i)) = x(ipos)
1069	ELSE
1070	IF (ind(i) > nbo) ma_fuscat_r11 = ma_fuscat_r11+1
1071	ENDIF
1072	ENDDO
1073	!-- Repeat the data if needed
1074	IF (MINVAL(ind) < 0) THEN
1075	DO i=1,nbi
1076	IF (ind(i) <= 0) THEN
1077	DO ii=1,ABS(ind(i))-1
1078	IF (ind(i+1)+ii <= nbo) THEN
1079	y(ind(i+1)+ii) = y(ind(i+1))
1080	ELSE
1081	ma_fuscat_r11 = ma_fuscat_r11+1
1082	ENDIF
1083	ENDDO
1084	ENDIF
1085	ENDDO
1086	ENDIF
1087	ELSE
1088	ma_fuscat_r11 = 1
1089	ENDIF
1090	!-------------------------
1091	END FUNCTION ma_fuscat_r11
1092	!===
1093	INTEGER FUNCTION ma_fugath_r11(nb,x,nbi,ind,miss_val,nbo,y)
1094	!---------------------------------------------------------------------
1095	IMPLICIT NONE
1096	!-
1097	INTEGER :: nb,nbo,nbi
1098	INTEGER :: ind(nbi)
1099	REAL :: x(nb),miss_val,y(nbo)
1100	!-
1101	INTEGER :: i,ipos
1102	!---------------------------------------------------------------------
1103	IF (nbi <= nbo) THEN
1104	ma_fugath_r11 = 0
1105	y(1:nbo) = miss_val
1106	ipos = 0
1107	DO i=1,nbi
1108	IF (ipos+1 <= nbo) THEN
1109	IF (ind(i) > 0) THEN
1110	ipos = ipos+1
1111	y(ipos) = x(ind(i))
1112	ENDIF
1113	ELSE
1114	IF (ipos+1 > nbo) ma_fugath_r11 = ma_fugath_r11+1
1115	ENDIF
1116	ENDDO
1117	ELSE
1118	ma_fugath_r11 = 1
1119	ENDIF
1120	!-
1121	nbo = ipos
1122	!-------------------------
1123	END FUNCTION ma_fugath_r11
1124	!===
1125	INTEGER FUNCTION ma_fufill_r11(nb,x,nbi,ind,miss_val,nbo,y)
1126	!---------------------------------------------------------------------
1127	IMPLICIT NONE
1128	!-
1129	INTEGER :: nb,nbo,nbi
1130	INTEGER :: ind(nbi)
1131	REAL :: x(nb),miss_val,y(nbo)
1132	!-
1133	INTEGER :: i,ii,ipos
1134	!---------------------------------------------------------------------
1135	ma_fufill_r11 = 0
1136	!-
1137	IF (nbi <= nb) THEN
1138	ipos = 0
1139	DO i=1,nbi
1140	IF (ind(i) <= nbo .AND. ind(i) > 0) THEN
1141	ipos = ipos+1
1142	y(ind(i)) = x(ipos)
1143	ELSE
1144	IF (ind(i) > nbo) ma_fufill_r11 = ma_fufill_r11+1
1145	ENDIF
1146	ENDDO
1147	!-- Repeat the data if needed
1148	IF (MINVAL(ind) < 0) THEN
1149	DO i=1,nbi
1150	IF (ind(i) <= 0) THEN
1151	DO ii=1,ABS(ind(i))-1
1152	IF (ind(i+1)+ii <= nbo) THEN
1153	y(ind(i+1)+ii) = y(ind(i+1))
1154	ELSE
1155	ma_fufill_r11 = ma_fufill_r11+1
1156	ENDIF
1157	ENDDO
1158	ENDIF
1159	ENDDO
1160	ENDIF
1161	ELSE
1162	ma_fufill_r11 = 1
1163	ENDIF
1164	!-------------------------
1165	END FUNCTION ma_fufill_r11
1166	!===
1167	INTEGER FUNCTION ma_fucoll_r11(nb,x,nbi,ind,miss_val,nbo,y)
1168	!---------------------------------------------------------------------
1169	IMPLICIT NONE
1170	!-
1171	INTEGER :: nb,nbo,nbi
1172	INTEGER :: ind(nbi)
1173	REAL :: x(nb),miss_val,y(nbo)
1174	!-
1175	INTEGER :: i,ipos
1176	!---------------------------------------------------------------------
1177	IF (nbi <= nbo) THEN
1178	ma_fucoll_r11 = 0
1179	ipos = 0
1180	DO i=1,nbi
1181	IF (ipos+1 <= nbo) THEN
1182	IF (ind(i) > 0) THEN
1183	ipos = ipos+1
1184	y(ipos) = x(ind(i))
1185	ENDIF
1186	ELSE
1187	IF (ipos+1 > nbo) ma_fucoll_r11 = ma_fucoll_r11+1
1188	ENDIF
1189	ENDDO
1190	ELSE
1191	ma_fucoll_r11 = 1
1192	ENDIF
1193	!-
1194	nbo = ipos
1195	!-------------------------
1196	END FUNCTION ma_fucoll_r11
1197	!===
1198	INTEGER FUNCTION ma_fuundef_r11(nb,x,nbi,ind,miss_val,nbo,y)
1199	!---------------------------------------------------------------------
1200	IMPLICIT NONE
1201	!-
1202	INTEGER :: nb,nbo,nbi
1203	INTEGER :: ind(nbi)
1204	REAL :: x(nb),miss_val,y(nbo)
1205	!-
1206	INTEGER :: i
1207	!---------------------------------------------------------------------
1208	IF (nbi <= nbo .AND. nbo == nb) THEN
1209	ma_fuundef_r11 = 0
1210	DO i=1,nbo
1211	y(i) = x(i)
1212	ENDDO
1213	DO i=1,nbi
1214	IF (ind(i) <= nbo .AND. ind(i) > 0) THEN
1215	y(ind(i)) = miss_val
1216	ELSE
1217	IF (ind(i) > nbo) ma_fuundef_r11 = ma_fuundef_r11+1
1218	ENDIF
1219	ENDDO
1220	ELSE
1221	ma_fuundef_r11 = 1
1222	ENDIF
1223	!--------------------------
1224	END FUNCTION ma_fuundef_r11
1225	!===
1226	INTEGER FUNCTION ma_fuonly_r11(nb,x,nbi,ind,miss_val,nbo,y)
1227	!---------------------------------------------------------------------
1228	IMPLICIT NONE
1229	!-
1230	INTEGER :: nb,nbo,nbi
1231	INTEGER :: ind(nbi)
1232	REAL :: x(nb),miss_val,y(nbo)
1233	!-
1234	INTEGER :: i
1235	!---------------------------------------------------------------------
1236	IF ( (nbi <= nbo).AND.(nbo == nb) &
1237	& .AND.ALL(ind(1:nbi) <= nbo) ) THEN
1238	ma_fuonly_r11 = 0
1239	y(1:nbo) = miss_val
1240	DO i=1,nbi
1241	IF (ind(i) > 0) THEN
1242	y(ind(i)) = x(ind(i))
1243	ENDIF
1244	ENDDO
1245	ELSE
1246	ma_fuonly_r11 = 1
1247	ENDIF
1248	!-------------------------
1249	END FUNCTION ma_fuonly_r11
1250	!===
1251	!===
1252	SUBROUTINE mathop_r21 &
1253	& (fun,nb,work_in,miss_val,nb_index,nindex,scal,nb_max,work_out)
1254	!---------------------------------------------------------------------
1255	!- This subroutines gives an interface to the various operations
1256	!- which are allowed. The interface is general enough to allow its use
1257	!- for other cases.
1258	!-
1259	!- INPUT
1260	!-
1261	!- fun : function to be applied to the vector of data
1262	!- nb : Length of input vector
1263	!- work_in : Input vector of data (REAL)
1264	!- miss_val : The value of the missing data flag (it has to be a
1265	!- maximum value, in f90 : huge( a real ))
1266	!- nb_index : Length of index vector
1267	!- nindex : Vector of indices
1268	!- scal : A scalar value for vector/scalar operations
1269	!- nb_max : maximum length of output vector
1270	!-
1271	!- OUTPUT
1272	!-
1273	!- nb_max : Actual length of output variable
1274	!- work_out : Output vector after the operation was applied
1275	!---------------------------------------------------------------------
1276	IMPLICIT NONE
1277	!-
1278	CHARACTER(LEN=7) :: fun
1279	INTEGER :: nb(2),nb_max,nb_index
1280	INTEGER :: nindex(nb_index)
1281	REAL :: work_in(nb(1),nb(2)),scal,miss_val
1282	REAL :: work_out(nb_max)
1283	!-
1284	INTEGER :: ierr
1285	!-
1286	INTRINSIC SIN,COS,TAN,ASIN,ACOS,ATAN,EXP,LOG,SQRT,ABS
1287	!---------------------------------------------------------------------
1288	ierr = 0
1289	!-
1290	IF (scal >= miss_val-1.) THEN
1291	IF (INDEX(indexfu,fun(1:LEN_TRIM(fun))) == 0) THEN
1292	SELECT CASE (fun)
1293	CASE('sin')
1294	ierr = ma_sin_r21(nb,work_in,nb_max,work_out)
1295	CASE('cos')
1296	ierr = ma_cos_r21(nb,work_in,nb_max,work_out)
1297	CASE('tan')
1298	ierr = ma_tan_r21(nb,work_in,nb_max,work_out)
1299	CASE('asin')
1300	ierr = ma_asin_r21(nb,work_in,nb_max,work_out)
1301	CASE('acos')
1302	ierr = ma_acos_r21(nb,work_in,nb_max,work_out)
1303	CASE('atan')
1304	ierr = ma_atan_r21(nb,work_in,nb_max,work_out)
1305	CASE('exp')
1306	ierr = ma_exp_r21(nb,work_in,nb_max,work_out)
1307	CASE('log')
1308	ierr = ma_log_r21(nb,work_in,nb_max,work_out)
1309	CASE('sqrt')
1310	ierr = ma_sqrt_r21(nb,work_in,nb_max,work_out)
1311	CASE('chs')
1312	ierr = ma_chs_r21(nb,work_in,nb_max,work_out)
1313	CASE('abs')
1314	ierr = ma_abs_r21(nb,work_in,nb_max,work_out)
1315	CASE('cels')
1316	ierr = ma_cels_r21(nb,work_in,nb_max,work_out)
1317	CASE('kelv')
1318	ierr = ma_kelv_r21(nb,work_in,nb_max,work_out)
1319	CASE('deg')
1320	ierr = ma_deg_r21(nb,work_in,nb_max,work_out)
1321	CASE('rad')
1322	ierr = ma_rad_r21(nb,work_in,nb_max,work_out)
1323	CASE('ident')
1324	ierr = ma_ident_r21(nb,work_in,nb_max,work_out)
1325	CASE DEFAULT
1326	CALL ipslerr(3,"mathop", &
1327	& 'scalar variable undefined and no indexing', &
1328	& 'but still unknown function',fun)
1329	END SELECT
1330	IF (ierr > 0) THEN
1331	CALL ipslerr(3,"mathop", &
1332	& 'Error while executing a simple function',fun,' ')
1333	ENDIF
1334	ELSE
1335	SELECT CASE (fun)
1336	CASE('gather')
1337	ierr = ma_fugath_r21(nb,work_in,nb_index,nindex, &
1338	& miss_val,nb_max,work_out)
1339	CASE('scatter')
1340	IF (nb_index > (nb(1)*nb(2)) ) THEN
1341	work_out(1:nb_max) = miss_val
1342	ierr=1
1343	ELSE
1344	ierr = ma_fuscat_r21(nb,work_in,nb_index,nindex, &
1345	& miss_val,nb_max,work_out)
1346	ENDIF
1347	CASE('coll')
1348	ierr = ma_fucoll_r21(nb,work_in,nb_index,nindex, &
1349	& miss_val,nb_max,work_out)
1350	CASE('fill')
1351	ierr = ma_fufill_r21(nb,work_in,nb_index,nindex, &
1352	& miss_val,nb_max,work_out)
1353	CASE('undef')
1354	ierr = ma_fuundef_r21(nb,work_in,nb_index,nindex, &
1355	& miss_val,nb_max,work_out)
1356	CASE('only')
1357	ierr = ma_fuonly_r21(nb,work_in,nb_index,nindex, &
1358	& miss_val,nb_max,work_out)
1359	CASE DEFAULT
1360	CALL ipslerr(3,"mathop", &
1361	& 'scalar variable undefined and indexing', &
1362	& 'was requested but with unknown function',fun)
1363	END SELECT
1364	IF (ierr > 0) THEN
1365	CALL ipslerr(3,"mathop_r21", &
1366	& 'Error while executing an indexing function',fun,' ')
1367	ENDIF
1368	ENDIF
1369	ELSE
1370	SELECT CASE (fun)
1371	CASE('fumin')
1372	ierr = ma_fumin_r21(nb,work_in,scal,nb_max,work_out)
1373	CASE('fumax')
1374	ierr = ma_fumax_r21(nb,work_in,scal,nb_max,work_out)
1375	CASE('add')
1376	ierr = ma_add_r21(nb,work_in,scal,nb_max,work_out)
1377	CASE('subi')
1378	ierr = ma_subi_r21(nb,work_in,scal,nb_max,work_out)
1379	CASE('sub')
1380	ierr = ma_sub_r21(nb,work_in,scal,nb_max,work_out)
1381	CASE('mult')
1382	ierr = ma_mult_r21(nb,work_in,scal,nb_max,work_out)
1383	CASE('div')
1384	ierr = ma_div_r21(nb,work_in,scal,nb_max,work_out)
1385	CASE('divi')
1386	ierr = ma_divi_r21(nb,work_in,scal,nb_max,work_out)
1387	CASE('power')
1388	ierr = ma_power_r21(nb,work_in,scal,nb_max,work_out)
1389	CASE DEFAULT
1390	CALL ipslerr(3,"mathop", &
1391	& 'Unknown operation with a scalar',fun,' ')
1392	END SELECT
1393	IF (ierr > 0) THEN
1394	CALL ipslerr(3,"mathop", &
1395	& 'Error while executing a scalar function',fun,' ')
1396	ENDIF
1397	ENDIF
1398	!------------------------
1399	END SUBROUTINE mathop_r21
1400	!-
1401	!=== FUNCTIONS (only one argument)
1402	!-
1403	INTEGER FUNCTION ma_sin_r21(nb,x,nbo,y)
1404	!---------------------------------------------------------------------
1405	IMPLICIT NONE
1406	!-
1407	INTEGER :: nb(2),nbo,i,j,ij
1408	REAL :: x(nb(1),nb(2)),y(nbo)
1409	!---------------------------------------------------------------------
1410	ij = 0
1411	DO j=1,nb(2)
1412	DO i=1,nb(1)
1413	ij = ij+1
1414	y(ij) = SIN(x(i,j))
1415	ENDDO
1416	ENDDO
1417	!-
1418	nbo = nb(1)*nb(2)
1419	ma_sin_r21 = 0
1420	!----------------------
1421	END FUNCTION ma_sin_r21
1422	!===
1423	INTEGER FUNCTION ma_cos_r21(nb,x,nbo,y)
1424	!---------------------------------------------------------------------
1425	IMPLICIT NONE
1426	!-
1427	INTEGER :: nb(2),nbo,i,j,ij
1428	REAL :: x(nb(1),nb(2)),y(nbo)
1429	!---------------------------------------------------------------------
1430	ij = 0
1431	DO j=1,nb(2)
1432	DO i=1,nb(1)
1433	ij = ij+1
1434	y(ij) = COS(x(i,j))
1435	ENDDO
1436	ENDDO
1437	!-
1438	nbo = nb(1)*nb(2)
1439	ma_cos_r21 = 0
1440	!----------------------
1441	END FUNCTION ma_cos_r21
1442	!===
1443	INTEGER FUNCTION ma_tan_r21(nb,x,nbo,y)
1444	!---------------------------------------------------------------------
1445	IMPLICIT NONE
1446	!-
1447	INTEGER :: nb(2),nbo,i,j,ij
1448	REAL :: x(nb(1),nb(2)),y(nbo)
1449	!---------------------------------------------------------------------
1450	ij = 0
1451	DO j=1,nb(2)
1452	DO i=1,nb(1)
1453	ij = ij+1
1454	y(ij) = TAN(x(i,j))
1455	ENDDO
1456	ENDDO
1457	!-
1458	nbo = nb(1)*nb(2)
1459	ma_tan_r21 = 0
1460	!----------------------
1461	END FUNCTION ma_tan_r21
1462	!===
1463	INTEGER FUNCTION ma_asin_r21(nb,x,nbo,y)
1464	!---------------------------------------------------------------------
1465	IMPLICIT NONE
1466	!-
1467	INTEGER :: nb(2),nbo,i,j,ij
1468	REAL :: x(nb(1),nb(2)),y(nbo)
1469	!---------------------------------------------------------------------
1470	ij = 0
1471	DO j=1,nb(2)
1472	DO i=1,nb(1)
1473	ij = ij+1
1474	y(ij) = ASIN(x(i,j))
1475	ENDDO
1476	ENDDO
1477	!-
1478	nbo = nb(1)*nb(2)
1479	ma_asin_r21 = 0
1480	!-----------------------
1481	END FUNCTION ma_asin_r21
1482	!===
1483	INTEGER FUNCTION ma_acos_r21(nb,x,nbo,y)
1484	!---------------------------------------------------------------------
1485	IMPLICIT NONE
1486	!-
1487	INTEGER :: nb(2),nbo,i,j,ij
1488	REAL :: x(nb(1),nb(2)),y(nbo)
1489	!---------------------------------------------------------------------
1490	ij = 0
1491	DO j=1,nb(2)
1492	DO i=1,nb(1)
1493	ij = ij+1
1494	y(ij) = ACOS(x(i,j))
1495	ENDDO
1496	ENDDO
1497	!-
1498	nbo = nb(1)*nb(2)
1499	ma_acos_r21 = 0
1500	!-----------------------
1501	END FUNCTION ma_acos_r21
1502	!===
1503	INTEGER FUNCTION ma_atan_r21(nb,x,nbo,y)
1504	!---------------------------------------------------------------------
1505	IMPLICIT NONE
1506	!-
1507	INTEGER :: nb(2),nbo,i,j,ij
1508	REAL :: x(nb(1),nb(2)),y(nbo)
1509	!---------------------------------------------------------------------
1510	ij = 0
1511	DO j=1,nb(2)
1512	DO i=1,nb(1)
1513	ij = ij+1
1514	y(ij) = ATAN(x(i,j))
1515	ENDDO
1516	ENDDO
1517	!-
1518	nbo = nb(1)*nb(2)
1519	ma_atan_r21 = 0
1520	!-----------------------
1521	END FUNCTION ma_atan_r21
1522	!===
1523	INTEGER FUNCTION ma_exp_r21(nb,x,nbo,y)
1524	!---------------------------------------------------------------------
1525	IMPLICIT NONE
1526	!-
1527	INTEGER :: nb(2),nbo,i,j,ij
1528	REAL :: x(nb(1),nb(2)),y(nbo)
1529	!---------------------------------------------------------------------
1530	ij = 0
1531	DO j=1,nb(2)
1532	DO i=1,nb(1)
1533	ij = ij+1
1534	y(ij) = EXP(x(i,j))
1535	ENDDO
1536	ENDDO
1537	!-
1538	nbo = nb(1)*nb(2)
1539	ma_exp_r21 = 0
1540	!----------------------
1541	END FUNCTION ma_exp_r21
1542	!===
1543	INTEGER FUNCTION ma_log_r21(nb,x,nbo,y)
1544	!---------------------------------------------------------------------
1545	IMPLICIT NONE
1546	!-
1547	INTEGER :: nb(2),nbo,i,j,ij
1548	REAL :: x(nb(1),nb(2)),y(nbo)
1549	!---------------------------------------------------------------------
1550	ij = 0
1551	DO j=1,nb(2)
1552	DO i=1,nb(1)
1553	ij = ij+1
1554	y(ij) = LOG(x(i,j))
1555	ENDDO
1556	ENDDO
1557	!-
1558	nbo = nb(1)*nb(2)
1559	ma_log_r21 = 0
1560	!----------------------
1561	END FUNCTION ma_log_r21
1562	!===
1563	INTEGER FUNCTION ma_sqrt_r21(nb,x,nbo,y)
1564	!---------------------------------------------------------------------
1565	IMPLICIT NONE
1566	!-
1567	INTEGER :: nb(2),nbo,i,j,ij
1568	REAL :: x(nb(1),nb(2)),y(nbo)
1569	!---------------------------------------------------------------------
1570	ij = 0
1571	DO j=1,nb(2)
1572	DO i=1,nb(1)
1573	ij = ij+1
1574	y(ij) = SQRT(x(i,j))
1575	ENDDO
1576	ENDDO
1577	!-
1578	nbo = nb(1)*nb(2)
1579	ma_sqrt_r21 = 0
1580	!-----------------------
1581	END FUNCTION ma_sqrt_r21
1582	!===
1583	INTEGER FUNCTION ma_abs_r21(nb,x,nbo,y)
1584	!---------------------------------------------------------------------
1585	IMPLICIT NONE
1586	!-
1587	INTEGER :: nb(2),nbo,i,j,ij
1588	REAL :: x(nb(1),nb(2)),y(nbo)
1589	!---------------------------------------------------------------------
1590	ij = 0
1591	DO j=1,nb(2)
1592	DO i=1,nb(1)
1593	ij = ij+1
1594	y(ij) = ABS(x(i,j))
1595	ENDDO
1596	ENDDO
1597	!-
1598	nbo = nb(1)*nb(2)
1599	ma_abs_r21 = 0
1600	!----------------------
1601	END FUNCTION ma_abs_r21
1602	!===
1603	INTEGER FUNCTION ma_chs_r21(nb,x,nbo,y)
1604	!---------------------------------------------------------------------
1605	IMPLICIT NONE
1606	!-
1607	INTEGER :: nb(2),nbo,i,j,ij
1608	REAL :: x(nb(1),nb(2)),y(nbo)
1609	!---------------------------------------------------------------------
1610	ij = 0
1611	DO j=1,nb(2)
1612	DO i=1,nb(1)
1613	ij = ij+1
1614	y(ij) = x(i,j)*(-1.)
1615	ENDDO
1616	ENDDO
1617	!-
1618	nbo = nb(1)*nb(2)
1619	ma_chs_r21 = 0
1620	!----------------------
1621	END FUNCTION ma_chs_r21
1622	!===
1623	INTEGER FUNCTION ma_cels_r21(nb,x,nbo,y)
1624	!---------------------------------------------------------------------
1625	IMPLICIT NONE
1626	!-
1627	INTEGER :: nb(2),nbo,i,j,ij
1628	REAL :: x(nb(1),nb(2)),y(nbo)
1629	!---------------------------------------------------------------------
1630	ij = 0
1631	DO j=1,nb(2)
1632	DO i=1,nb(1)
1633	ij = ij+1
1634	y(ij) = x(i,j)-273.15
1635	ENDDO
1636	ENDDO
1637	!-
1638	nbo = nb(1)*nb(2)
1639	ma_cels_r21 = 0
1640	!-----------------------
1641	END FUNCTION ma_cels_r21
1642	!===
1643	INTEGER FUNCTION ma_kelv_r21(nb,x,nbo,y)
1644	!---------------------------------------------------------------------
1645	IMPLICIT NONE
1646	!-
1647	INTEGER :: nb(2),nbo,i,j,ij
1648	REAL :: x(nb(1),nb(2)),y(nbo)
1649	!---------------------------------------------------------------------
1650	ij = 0
1651	DO j=1,nb(2)
1652	DO i=1,nb(1)
1653	ij = ij+1
1654	y(ij) = x(i,j)+273.15
1655	ENDDO
1656	ENDDO
1657	!-
1658	nbo = nb(1)*nb(2)
1659	ma_kelv_r21 = 0
1660	!-----------------------
1661	END FUNCTION ma_kelv_r21
1662	!===
1663	INTEGER FUNCTION ma_deg_r21(nb,x,nbo,y)
1664	!---------------------------------------------------------------------
1665	IMPLICIT NONE
1666	!-
1667	INTEGER :: nb(2),nbo,i,j,ij
1668	REAL :: x(nb(1),nb(2)),y(nbo)
1669	!---------------------------------------------------------------------
1670	ij = 0
1671	DO j=1,nb(2)
1672	DO i=1,nb(1)
1673	ij = ij+1
1674	y(ij) = x(i,j)*57.29577951
1675	ENDDO
1676	ENDDO
1677	!-
1678	nbo = nb(1)*nb(2)
1679	ma_deg_r21 = 0
1680	!----------------------
1681	END FUNCTION ma_deg_r21
1682	!===
1683	INTEGER FUNCTION ma_rad_r21(nb,x,nbo,y)
1684	!---------------------------------------------------------------------
1685	IMPLICIT NONE
1686	!-
1687	INTEGER :: nb(2),nbo,i,j,ij
1688	REAL :: x(nb(1),nb(2)),y(nbo)
1689	!---------------------------------------------------------------------
1690	ij = 0
1691	DO j=1,nb(2)
1692	DO i=1,nb(1)
1693	ij = ij+1
1694	y(ij) = x(i,j)*0.01745329252
1695	ENDDO
1696	ENDDO
1697	!-
1698	nbo = nb(1)*nb(2)
1699	ma_rad_r21 = 0
1700	!----------------------
1701	END FUNCTION ma_rad_r21
1702	!===
1703	INTEGER FUNCTION ma_ident_r21(nb,x,nbo,y)
1704	!---------------------------------------------------------------------
1705	IMPLICIT NONE
1706	!-
1707	INTEGER :: nb(2),nbo,i,j,ij
1708	REAL :: x(nb(1),nb(2)),y(nbo)
1709	!---------------------------------------------------------------------
1710	ij = 0
1711	DO j=1,nb(2)
1712	DO i=1,nb(1)
1713	ij = ij+1
1714	y(ij) = x(i,j)
1715	ENDDO
1716	ENDDO
1717	!-
1718	nbo = nb(1)*nb(2)
1719	ma_ident_r21 = 0
1720	!------------------------
1721	END FUNCTION ma_ident_r21
1722	!-
1723	!=== OPERATIONS (two argument)
1724	!-
1725	INTEGER FUNCTION ma_add_r21(nb,x,s,nbo,y)
1726	!---------------------------------------------------------------------
1727	IMPLICIT NONE
1728	!-
1729	INTEGER :: nb(2),nbo
1730	REAL :: x(nb(1),nb(2)),s,y(nbo)
1731	!-
1732	INTEGER :: i,j,ij
1733	!---------------------------------------------------------------------
1734	ij = 0
1735	DO j=1,nb(2)
1736	DO i=1,nb(1)
1737	ij = ij+1
1738	y(ij) = x(i,j)+s
1739	ENDDO
1740	ENDDO
1741	!-
1742	nbo = nb(1)*nb(2)
1743	ma_add_r21 = 0
1744	!----------------------
1745	END FUNCTION ma_add_r21
1746	!===
1747	INTEGER FUNCTION ma_sub_r21(nb,x,s,nbo,y)
1748	!---------------------------------------------------------------------
1749	IMPLICIT NONE
1750	!-
1751	INTEGER :: nb(2),nbo
1752	REAL :: x(nb(1),nb(2)),s,y(nbo)
1753	!-
1754	INTEGER :: i,j,ij
1755	!---------------------------------------------------------------------
1756	ij = 0
1757	DO j=1,nb(2)
1758	DO i=1,nb(1)
1759	ij = ij+1
1760	y(ij) = x(i,j)-s
1761	ENDDO
1762	ENDDO
1763	!-
1764	nbo = nb(1)*nb(2)
1765	ma_sub_r21 = 0
1766	!----------------------
1767	END FUNCTION ma_sub_r21
1768	!===
1769	INTEGER FUNCTION ma_subi_r21(nb,x,s,nbo,y)
1770	!---------------------------------------------------------------------
1771	IMPLICIT NONE
1772	!-
1773	INTEGER :: nb(2),nbo
1774	REAL :: x(nb(1),nb(2)),s,y(nbo)
1775	!-
1776	INTEGER :: i,j,ij
1777	!---------------------------------------------------------------------
1778	ij = 0
1779	DO j=1,nb(2)
1780	DO i=1,nb(1)
1781	ij = ij+1
1782	y(ij) = s-x(i,j)
1783	ENDDO
1784	ENDDO
1785	!-
1786	nbo = nb(1)*nb(2)
1787	ma_subi_r21 = 0
1788	!-----------------------
1789	END FUNCTION ma_subi_r21
1790	!===
1791	INTEGER FUNCTION ma_mult_r21(nb,x,s,nbo,y)
1792	!---------------------------------------------------------------------
1793	IMPLICIT NONE
1794	!-
1795	INTEGER :: nb(2),nbo
1796	REAL :: x(nb(1),nb(2)),s,y(nbo)
1797	!-
1798	INTEGER :: i,j,ij
1799	!---------------------------------------------------------------------
1800	ij = 0
1801	DO j=1,nb(2)
1802	DO i=1,nb(1)
1803	ij = ij+1
1804	y(ij) = x(i,j)*s
1805	ENDDO
1806	ENDDO
1807	!-
1808	nbo = nb(1)*nb(2)
1809	ma_mult_r21 = 0
1810	!-----------------------
1811	END FUNCTION ma_mult_r21
1812	!===
1813	INTEGER FUNCTION ma_div_r21(nb,x,s,nbo,y)
1814	!---------------------------------------------------------------------
1815	IMPLICIT NONE
1816	!-
1817	INTEGER :: nb(2),nbo
1818	REAL :: x(nb(1),nb(2)),s,y(nbo)
1819	!-
1820	INTEGER :: i,j,ij
1821	!---------------------------------------------------------------------
1822	ij = 0
1823	DO j=1,nb(2)
1824	DO i=1,nb(1)
1825	ij = ij+1
1826	y(ij) = x(i,j)/s
1827	ENDDO
1828	ENDDO
1829	!-
1830	nbo = nb(1)*nb(2)
1831	ma_div_r21 = 0
1832	!----------------------
1833	END FUNCTION ma_div_r21
1834	!===
1835	INTEGER FUNCTION ma_divi_r21(nb,x,s,nbo,y)
1836	!---------------------------------------------------------------------
1837	IMPLICIT NONE
1838	!-
1839	INTEGER :: nb(2),nbo
1840	REAL :: x(nb(1),nb(2)),s,y(nbo)
1841	!-
1842	INTEGER :: i,j,ij
1843	!---------------------------------------------------------------------
1844	ij = 0
1845	DO j=1,nb(2)
1846	DO i=1,nb(1)
1847	ij = ij+1
1848	y(ij) = s/x(i,j)
1849	ENDDO
1850	ENDDO
1851	!-
1852	nbo = nb(1)*nb(2)
1853	ma_divi_r21 = 0
1854	!-----------------------
1855	END FUNCTION ma_divi_r21
1856	!===
1857	INTEGER FUNCTION ma_power_r21(nb,x,s,nbo,y)
1858	!---------------------------------------------------------------------
1859	IMPLICIT NONE
1860	!-
1861	INTEGER :: nb(2),nbo
1862	REAL :: x(nb(1),nb(2)),s,y(nbo)
1863	!-
1864	INTEGER :: i,j,ij
1865	!---------------------------------------------------------------------
1866	ij = 0
1867	DO j=1,nb(2)
1868	DO i=1,nb(1)
1869	ij = ij+1
1870	y(ij) = x(i,j) ** s
1871	ENDDO
1872	ENDDO
1873	!-
1874	nbo = nb(1)*nb(2)
1875	ma_power_r21 = 0
1876	!------------------------
1877	END FUNCTION ma_power_r21
1878	!===
1879	INTEGER FUNCTION ma_fumin_r21(nb,x,s,nbo,y)
1880	!---------------------------------------------------------------------
1881	IMPLICIT NONE
1882	!-
1883	INTEGER :: nb(2),nbo
1884	REAL :: x(nb(1),nb(2)),s,y(nbo)
1885	!-
1886	INTEGER :: i,j,ij
1887	!---------------------------------------------------------------------
1888	ij = 0
1889	DO j=1,nb(2)
1890	DO i=1,nb(1)
1891	ij = ij+1
1892	y(ij) = MIN(x(i,j),s)
1893	ENDDO
1894	ENDDO
1895	!-
1896	nbo = nb(1)*nb(2)
1897	ma_fumin_r21 = 0
1898	!------------------------
1899	END FUNCTION ma_fumin_r21
1900	!===
1901	INTEGER FUNCTION ma_fumax_r21(nb,x,s,nbo,y)
1902	!---------------------------------------------------------------------
1903	IMPLICIT NONE
1904	!-
1905	INTEGER :: nb(2),nbo
1906	REAL :: x(nb(1),nb(2)),s,y(nbo)
1907	!-
1908	INTEGER :: i,j,ij
1909	!---------------------------------------------------------------------
1910	ij = 0
1911	DO j=1,nb(2)
1912	DO i=1,nb(1)
1913	ij = ij+1
1914	y(ij) = MAX(x(i,j),s)
1915	ENDDO
1916	ENDDO
1917	!-
1918	nbo = nb(1)*nb(2)
1919	ma_fumax_r21 = 0
1920	!------------------------
1921	END FUNCTION ma_fumax_r21
1922	!===
1923	INTEGER FUNCTION ma_fuscat_r21(nb,x,nbi,ind,miss_val,nbo,y)
1924	!---------------------------------------------------------------------
1925	IMPLICIT NONE
1926	!-
1927	INTEGER :: nb(2),nbo,nbi
1928	INTEGER :: ind(nbi)
1929	REAL :: x(nb(1),nb(2)),miss_val,y(nbo)
1930	!-
1931	INTEGER :: i,j,ij,ii,ipos
1932	!---------------------------------------------------------------------
1933	ma_fuscat_r21 = 0
1934	!-
1935	y(1:nbo) = miss_val
1936	!-
1937	IF (nbi <= nb(1)*nb(2)) THEN
1938	ipos = 0
1939	DO ij=1,nbi
1940	IF (ind(ij) <= nbo .AND. ind(ij) > 0) THEN
1941	ipos = ipos+1
1942	j = ((ipos-1)/nb(1))+1
1943	i = (ipos-(j-1)*nb(1))
1944	y(ind(ij)) = x(i,j)
1945	ELSE
1946	IF (ind(ij) > nbo) ma_fuscat_r21 = ma_fuscat_r21+1
1947	ENDIF
1948	ENDDO
1949	!-- Repeat the data if needed
1950	IF (MINVAL(ind) < 0) THEN
1951	DO i=1,nbi
1952	IF (ind(i) <= 0) THEN
1953	DO ii=1,ABS(ind(i))-1
1954	IF (ind(i+1)+ii <= nbo) THEN
1955	y(ind(i+1)+ii) = y(ind(i+1))
1956	ELSE
1957	ma_fuscat_r21 = ma_fuscat_r21+1
1958	ENDIF
1959	ENDDO
1960	ENDIF
1961	ENDDO
1962	ENDIF
1963	ELSE
1964	ma_fuscat_r21 = 1
1965	ENDIF
1966	!-------------------------
1967	END FUNCTION ma_fuscat_r21
1968	!===
1969	INTEGER FUNCTION ma_fugath_r21(nb,x,nbi,ind,miss_val,nbo,y)
1970	!---------------------------------------------------------------------
1971	IMPLICIT NONE
1972	!-
1973	INTEGER :: nb(2),nbo,nbi
1974	INTEGER :: ind(nbi)
1975	REAL :: x(nb(1),nb(2)),miss_val,y(nbo)
1976	!-
1977	INTEGER :: i,j,ij,ipos
1978	!---------------------------------------------------------------------
1979	IF (nbi <= nbo) THEN
1980	ma_fugath_r21 = 0
1981	y(1:nbo) = miss_val
1982	ipos = 0
1983	DO ij=1,nbi
1984	IF (ipos+1 <= nbo) THEN
1985	IF (ind(ij) > 0) THEN
1986	j = ((ind(ij)-1)/nb(1))+1
1987	i = (ind(ij)-(j-1)*nb(1))
1988	ipos = ipos+1
1989	y(ipos) = x(i,j)
1990	ENDIF
1991	ELSE
1992	IF (ipos+1 > nbo) ma_fugath_r21 = ma_fugath_r21+1
1993	ENDIF
1994	ENDDO
1995	ELSE
1996	ma_fugath_r21 = 1
1997	ENDIF
1998	nbo = ipos
1999	!-------------------------
2000	END FUNCTION ma_fugath_r21
2001	!===
2002	INTEGER FUNCTION ma_fufill_r21(nb,x,nbi,ind,miss_val,nbo,y)
2003	!---------------------------------------------------------------------
2004	IMPLICIT NONE
2005	!-
2006	INTEGER :: nb(2),nbo,nbi
2007	INTEGER :: ind(nbi)
2008	REAL :: x(nb(1),nb(2)),miss_val,y(nbo)
2009	!-
2010	INTEGER :: i,j,ij,ii,ipos
2011	!---------------------------------------------------------------------
2012	ma_fufill_r21 = 0
2013	!-
2014	IF (nbi <= nb(1)*nb(2)) THEN
2015	ipos = 0
2016	DO ij=1,nbi
2017	IF (ind(ij) <= nbo .AND. ind(ij) > 0) THEN
2018	ipos = ipos+1
2019	j = ((ipos-1)/nb(1))+1
2020	i = (ipos-(j-1)*nb(1))
2021	y(ind(ij)) = x(i,j)
2022	ELSE
2023	IF (ind(ij) > nbo) ma_fufill_r21 = ma_fufill_r21+1
2024	ENDIF
2025	ENDDO
2026	!-- Repeat the data if needed
2027	IF (MINVAL(ind) < 0) THEN
2028	DO i=1,nbi
2029	IF (ind(i) <= 0) THEN
2030	DO ii=1,ABS(ind(i))-1
2031	IF (ind(i+1)+ii <= nbo) THEN
2032	y(ind(i+1)+ii) = y(ind(i+1))
2033	ELSE
2034	ma_fufill_r21 = ma_fufill_r21+1
2035	ENDIF
2036	ENDDO
2037	ENDIF
2038	ENDDO
2039	ENDIF
2040	ELSE
2041	ma_fufill_r21 = 1
2042	ENDIF
2043	!-------------------------
2044	END FUNCTION ma_fufill_r21
2045	!===
2046	INTEGER FUNCTION ma_fucoll_r21(nb,x,nbi,ind,miss_val,nbo,y)
2047	!---------------------------------------------------------------------
2048	IMPLICIT NONE
2049	!-
2050	INTEGER :: nb(2),nbo,nbi
2051	INTEGER :: ind(nbi)
2052	REAL :: x(nb(1),nb(2)),miss_val,y(nbo)
2053	!-
2054	INTEGER :: i,j,ij,ipos
2055	!---------------------------------------------------------------------
2056	IF (nbi <= nbo) THEN
2057	ma_fucoll_r21 = 0
2058	ipos = 0
2059	DO ij=1,nbi
2060	IF (ipos+1 <= nbo) THEN
2061	IF (ind(ij) > 0) THEN
2062	j = ((ind(ij)-1)/nb(1))+1
2063	i = (ind(ij)-(j-1)*nb(1))
2064	ipos = ipos+1
2065	y(ipos) = x(i,j)
2066	ENDIF
2067	ELSE
2068	IF (ipos+1 > nbo) ma_fucoll_r21 = ma_fucoll_r21+1
2069	ENDIF
2070	ENDDO
2071	ELSE
2072	ma_fucoll_r21 = 1
2073	ENDIF
2074	nbo = ipos
2075	!-------------------------
2076	END FUNCTION ma_fucoll_r21
2077	!===
2078	INTEGER FUNCTION ma_fuundef_r21(nb,x,nbi,ind,miss_val,nbo,y)
2079	!---------------------------------------------------------------------
2080	IMPLICIT NONE
2081	!-
2082	INTEGER :: nb(2),nbo,nbi
2083	INTEGER :: ind(nbi)
2084	REAL :: x(nb(1),nb(2)),miss_val,y(nbo)
2085	!-
2086	INTEGER :: i,j,ij
2087	!---------------------------------------------------------------------
2088	IF (nbi <= nbo .AND. nbo == nb(1)*nb(2)) THEN
2089	ma_fuundef_r21 = 0
2090	DO ij=1,nbo
2091	j = ((ij-1)/nb(1))+1
2092	i = (ij-(j-1)*nb(1))
2093	y(ij) = x(i,j)
2094	ENDDO
2095	DO i=1,nbi
2096	IF (ind(i) <= nbo .AND. ind(i) > 0) THEN
2097	y(ind(i)) = miss_val
2098	ELSE
2099	IF (ind(i) > nbo) ma_fuundef_r21 = ma_fuundef_r21+1
2100	ENDIF
2101	ENDDO
2102	ELSE
2103	ma_fuundef_r21 = 1
2104	ENDIF
2105	!--------------------------
2106	END FUNCTION ma_fuundef_r21
2107	!===
2108	INTEGER FUNCTION ma_fuonly_r21(nb,x,nbi,ind,miss_val,nbo,y)
2109	!---------------------------------------------------------------------
2110	IMPLICIT NONE
2111	!-
2112	INTEGER :: nb(2),nbo,nbi
2113	INTEGER :: ind(nbi)
2114	REAL :: x(nb(1),nb(2)),miss_val,y(nbo)
2115	!-
2116	INTEGER :: i,j,ij
2117	!---------------------------------------------------------------------
2118	IF ( (nbi <= nbo).AND.(nbo == nb(1)*nb(2)) &
2119	& .AND.ALL(ind(1:nbi) <= nbo) ) THEN
2120	ma_fuonly_r21 = 0
2121	y(1:nbo) = miss_val
2122	DO ij=1,nbi
2123	IF (ind(ij) > 0) THEN
2124	j = ((ind(ij)-1)/nb(1))+1
2125	i = (ind(ij)-(j-1)*nb(1))
2126	y(ind(ij)) = x(i,j)
2127	ENDIF
2128	ENDDO
2129	ELSE
2130	ma_fuonly_r21 = 1
2131	ENDIF
2132	!-------------------------
2133	END FUNCTION ma_fuonly_r21
2134	!===
2135	!===
2136	SUBROUTINE mathop_r31 &
2137	& (fun,nb,work_in,miss_val,nb_index,nindex,scal,nb_max,work_out)
2138	!---------------------------------------------------------------------
2139	!- This subroutines gives an interface to the various operations
2140	!- which are allowed. The interface is general enough to allow its use
2141	!- for other cases.
2142	!-
2143	!- INPUT
2144	!-
2145	!- fun : function to be applied to the vector of data
2146	!- nb : Length of input vector
2147	!- work_in : Input vector of data (REAL)
2148	!- miss_val : The value of the missing data flag (it has to be a
2149	!- maximum value, in f90 : huge( a real ))
2150	!- nb_index : Length of index vector
2151	!- nindex : Vector of indices
2152	!- scal : A scalar value for vector/scalar operations
2153	!- nb_max : maximum length of output vector
2154	!-
2155	!- OUTPUT
2156	!-
2157	!- nb_max : Actual length of output variable
2158	!- work_out : Output vector after the operation was applied
2159	!---------------------------------------------------------------------
2160	IMPLICIT NONE
2161	!-
2162	CHARACTER(LEN=7) :: fun
2163	INTEGER :: nb(3),nb_max,nb_index
2164	INTEGER :: nindex(nb_index)
2165	REAL :: work_in(nb(1),nb(2),nb(3)),scal,miss_val
2166	REAL :: work_out(nb_max)
2167	!-
2168	INTEGER :: ierr
2169	!-
2170	INTRINSIC SIN,COS,TAN,ASIN,ACOS,ATAN,EXP,LOG,SQRT,ABS
2171	!---------------------------------------------------------------------
2172	ierr = 0
2173	!-
2174	IF (scal >= miss_val-1.) THEN
2175	IF (INDEX(indexfu,fun(1:LEN_TRIM(fun))) == 0) THEN
2176	SELECT CASE (fun)
2177	CASE('sin')
2178	ierr = ma_sin_r31(nb,work_in,nb_max,work_out)
2179	CASE('cos')
2180	ierr = ma_cos_r31(nb,work_in,nb_max,work_out)
2181	CASE('tan')
2182	ierr = ma_tan_r31(nb,work_in,nb_max,work_out)
2183	CASE('asin')
2184	ierr = ma_asin_r31(nb,work_in,nb_max,work_out)
2185	CASE('acos')
2186	ierr = ma_acos_r31(nb,work_in,nb_max,work_out)
2187	CASE('atan')
2188	ierr = ma_atan_r31(nb,work_in,nb_max,work_out)
2189	CASE('exp')
2190	ierr = ma_exp_r31(nb,work_in,nb_max,work_out)
2191	CASE('log')
2192	ierr = ma_log_r31(nb,work_in,nb_max,work_out)
2193	CASE('sqrt')
2194	ierr = ma_sqrt_r31(nb,work_in,nb_max,work_out)
2195	CASE('chs')
2196	ierr = ma_chs_r31(nb,work_in,nb_max,work_out)
2197	CASE('abs')
2198	ierr = ma_abs_r31(nb,work_in,nb_max,work_out)
2199	CASE('cels')
2200	ierr = ma_cels_r31(nb,work_in,nb_max,work_out)
2201	CASE('kelv')
2202	ierr = ma_kelv_r31(nb,work_in,nb_max,work_out)
2203	CASE('deg')
2204	ierr = ma_deg_r31(nb,work_in,nb_max,work_out)
2205	CASE('rad')
2206	ierr = ma_rad_r31(nb,work_in,nb_max,work_out)
2207	CASE('ident')
2208	ierr = ma_ident_r31(nb,work_in,nb_max,work_out)
2209	CASE DEFAULT
2210	CALL ipslerr(3,"mathop", &
2211	& 'scalar variable undefined and no indexing', &
2212	& 'but still unknown function',fun)
2213	END SELECT
2214	IF (ierr > 0) THEN
2215	CALL ipslerr(3,"mathop", &
2216	& 'Error while executing a simple function',fun,' ')
2217	ENDIF
2218	ELSE
2219	SELECT CASE (fun)
2220	CASE('gather')
2221	ierr = ma_fugath_r31(nb,work_in,nb_index,nindex, &
2222	& miss_val,nb_max,work_out)
2223	CASE('scatter')
2224	IF (nb_index > (nb(1)nb(2)nb(3))) THEN
2225	work_out(1:nb_max) = miss_val
2226	ierr=1
2227	ELSE
2228	ierr = ma_fuscat_r31(nb,work_in,nb_index,nindex, &
2229	& miss_val,nb_max,work_out)
2230	ENDIF
2231	CASE('coll')
2232	ierr = ma_fucoll_r31(nb,work_in,nb_index,nindex, &
2233	& miss_val,nb_max,work_out)
2234	CASE('fill')
2235	ierr = ma_fufill_r31(nb,work_in,nb_index,nindex, &
2236	& miss_val,nb_max,work_out)
2237	CASE('undef')
2238	ierr = ma_fuundef_r31(nb,work_in,nb_index,nindex, &
2239	& miss_val,nb_max,work_out)
2240	CASE('only')
2241	ierr = ma_fuonly_r31(nb,work_in,nb_index,nindex, &
2242	& miss_val,nb_max,work_out)
2243	CASE DEFAULT
2244	CALL ipslerr(3,"mathop", &
2245	& 'scalar variable undefined and indexing', &
2246	& 'was requested but with unknown function',fun)
2247	END SELECT
2248	IF (ierr > 0) THEN
2249	CALL ipslerr(3,"mathop_r31", &
2250	& 'Error while executing an indexing function',fun,' ')
2251	ENDIF
2252	ENDIF
2253	ELSE
2254	SELECT CASE (fun)
2255	CASE('fumin')
2256	ierr = ma_fumin_r31(nb,work_in,scal,nb_max,work_out)
2257	CASE('fumax')
2258	ierr = ma_fumax_r31(nb,work_in,scal,nb_max,work_out)
2259	CASE('add')
2260	ierr = ma_add_r31(nb,work_in,scal,nb_max,work_out)
2261	CASE('subi')
2262	ierr = ma_subi_r31(nb,work_in,scal,nb_max,work_out)
2263	CASE('sub')
2264	ierr = ma_sub_r31(nb,work_in,scal,nb_max,work_out)
2265	CASE('mult')
2266	ierr = ma_mult_r31(nb,work_in,scal,nb_max,work_out)
2267	CASE('div')
2268	ierr = ma_div_r31(nb,work_in,scal,nb_max,work_out)
2269	CASE('divi')
2270	ierr = ma_divi_r31(nb,work_in,scal,nb_max,work_out)
2271	CASE('power')
2272	ierr = ma_power_r31(nb,work_in,scal,nb_max,work_out)
2273	CASE DEFAULT
2274	CALL ipslerr(3,"mathop", &
2275	& 'Unknown operation with a scalar',fun,' ')
2276	END SELECT
2277	IF (ierr > 0) THEN
2278	CALL ipslerr(3,"mathop", &
2279	& 'Error while executing a scalar function',fun,' ')
2280	ENDIF
2281	ENDIF
2282	!------------------------
2283	END SUBROUTINE mathop_r31
2284	!-
2285	!=== FUNCTIONS (only one argument)
2286	!-
2287	INTEGER FUNCTION ma_sin_r31(nb,x,nbo,y)
2288	!---------------------------------------------------------------------
2289	IMPLICIT NONE
2290	!-
2291	INTEGER :: nb(3),nbo,i,j,k,ij
2292	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2293	!---------------------------------------------------------------------
2294	ij = 0
2295	DO k=1,nb(3)
2296	DO j=1,nb(2)
2297	DO i=1,nb(1)
2298	ij = ij+1
2299	y(ij) = SIN(x(i,j,k))
2300	ENDDO
2301	ENDDO
2302	ENDDO
2303	!-
2304	nbo = nb(1)nb(2)nb(3)
2305	ma_sin_r31 = 0
2306	!----------------------
2307	END FUNCTION ma_sin_r31
2308	!===
2309	INTEGER FUNCTION ma_cos_r31(nb,x,nbo,y)
2310	!---------------------------------------------------------------------
2311	IMPLICIT NONE
2312	!-
2313	INTEGER :: nb(3),nbo,i,j,k,ij
2314	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2315	!---------------------------------------------------------------------
2316	ij = 0
2317	DO k=1,nb(3)
2318	DO j=1,nb(2)
2319	DO i=1,nb(1)
2320	ij = ij+1
2321	y(ij) = COS(x(i,j,k))
2322	ENDDO
2323	ENDDO
2324	ENDDO
2325	!-
2326	nbo = nb(1)nb(2)nb(3)
2327	ma_cos_r31 = 0
2328	!----------------------
2329	END FUNCTION ma_cos_r31
2330	!===
2331	INTEGER FUNCTION ma_tan_r31(nb,x,nbo,y)
2332	!---------------------------------------------------------------------
2333	IMPLICIT NONE
2334	!-
2335	INTEGER :: nb(3),nbo,i,j,k,ij
2336	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2337	!---------------------------------------------------------------------
2338	ij = 0
2339	DO k=1,nb(3)
2340	DO j=1,nb(2)
2341	DO i=1,nb(1)
2342	ij = ij+1
2343	y(ij) = TAN(x(i,j,k))
2344	ENDDO
2345	ENDDO
2346	ENDDO
2347	!-
2348	nbo = nb(1)nb(2)nb(3)
2349	ma_tan_r31 = 0
2350	!----------------------
2351	END FUNCTION ma_tan_r31
2352	!===
2353	INTEGER FUNCTION ma_asin_r31(nb,x,nbo,y)
2354	!---------------------------------------------------------------------
2355	IMPLICIT NONE
2356	!-
2357	INTEGER :: nb(3),nbo,i,j,k,ij
2358	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2359	!---------------------------------------------------------------------
2360	ij = 0
2361	DO k=1,nb(3)
2362	DO j=1,nb(2)
2363	DO i=1,nb(1)
2364	ij = ij+1
2365	y(ij) = ASIN(x(i,j,k))
2366	ENDDO
2367	ENDDO
2368	ENDDO
2369	!-
2370	nbo = nb(1)nb(2)nb(3)
2371	ma_asin_r31 = 0
2372	!-----------------------
2373	END FUNCTION ma_asin_r31
2374	!===
2375	INTEGER FUNCTION ma_acos_r31(nb,x,nbo,y)
2376	!---------------------------------------------------------------------
2377	IMPLICIT NONE
2378	!-
2379	INTEGER :: nb(3),nbo,i,j,k,ij
2380	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2381	!---------------------------------------------------------------------
2382	ij = 0
2383	DO k=1,nb(3)
2384	DO j=1,nb(2)
2385	DO i=1,nb(1)
2386	ij = ij+1
2387	y(ij) = ACOS(x(i,j,k))
2388	ENDDO
2389	ENDDO
2390	ENDDO
2391	!-
2392	nbo = nb(1)nb(2)nb(3)
2393	ma_acos_r31 = 0
2394	!-----------------------
2395	END FUNCTION ma_acos_r31
2396	!===
2397	INTEGER FUNCTION ma_atan_r31(nb,x,nbo,y)
2398	!---------------------------------------------------------------------
2399	IMPLICIT NONE
2400	!-
2401	INTEGER :: nb(3),nbo,i,j,k,ij
2402	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2403	!---------------------------------------------------------------------
2404	ij = 0
2405	DO k=1,nb(3)
2406	DO j=1,nb(2)
2407	DO i=1,nb(1)
2408	ij = ij+1
2409	y(ij) = ATAN(x(i,j,k))
2410	ENDDO
2411	ENDDO
2412	ENDDO
2413	!-
2414	nbo = nb(1)nb(2)nb(3)
2415	ma_atan_r31 = 0
2416	!-----------------------
2417	END FUNCTION ma_atan_r31
2418	!===
2419	INTEGER FUNCTION ma_exp_r31(nb,x,nbo,y)
2420	!---------------------------------------------------------------------
2421	IMPLICIT NONE
2422	!-
2423	INTEGER :: nb(3),nbo,i,j,k,ij
2424	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2425	!---------------------------------------------------------------------
2426	ij = 0
2427	DO k=1,nb(3)
2428	DO j=1,nb(2)
2429	DO i=1,nb(1)
2430	ij = ij+1
2431	y(ij) = EXP(x(i,j,k))
2432	ENDDO
2433	ENDDO
2434	ENDDO
2435	!-
2436	nbo = nb(1)nb(2)nb(3)
2437	ma_exp_r31 = 0
2438	!----------------------
2439	END FUNCTION ma_exp_r31
2440	!===
2441	INTEGER FUNCTION ma_log_r31(nb,x,nbo,y)
2442	!---------------------------------------------------------------------
2443	IMPLICIT NONE
2444	!-
2445	INTEGER :: nb(3),nbo,i,j,k,ij
2446	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2447	!---------------------------------------------------------------------
2448	ij = 0
2449	DO k=1,nb(3)
2450	DO j=1,nb(2)
2451	DO i=1,nb(1)
2452	ij = ij+1
2453	y(ij) = LOG(x(i,j,k))
2454	ENDDO
2455	ENDDO
2456	ENDDO
2457	!-
2458	nbo = nb(1)nb(2)nb(3)
2459	ma_log_r31 = 0
2460	!----------------------
2461	END FUNCTION ma_log_r31
2462	!===
2463	INTEGER FUNCTION ma_sqrt_r31(nb,x,nbo,y)
2464	!---------------------------------------------------------------------
2465	IMPLICIT NONE
2466	!-
2467	INTEGER :: nb(3),nbo,i,j,k,ij
2468	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2469	!---------------------------------------------------------------------
2470	ij = 0
2471	DO k=1,nb(3)
2472	DO j=1,nb(2)
2473	DO i=1,nb(1)
2474	ij = ij+1
2475	y(ij) = SQRT(x(i,j,k))
2476	ENDDO
2477	ENDDO
2478	ENDDO
2479	!-
2480	nbo = nb(1)nb(2)nb(3)
2481	ma_sqrt_r31 = 0
2482	!-----------------------
2483	END FUNCTION ma_sqrt_r31
2484	!===
2485	INTEGER FUNCTION ma_abs_r31(nb,x,nbo,y)
2486	!---------------------------------------------------------------------
2487	IMPLICIT NONE
2488	!-
2489	INTEGER :: nb(3),nbo,i,j,k,ij
2490	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2491	!---------------------------------------------------------------------
2492	ij = 0
2493	DO k=1,nb(3)
2494	DO j=1,nb(2)
2495	DO i=1,nb(1)
2496	ij = ij+1
2497	y(ij) = ABS(x(i,j,k))
2498	ENDDO
2499	ENDDO
2500	ENDDO
2501	!-
2502	nbo = nb(1)nb(2)nb(3)
2503	ma_abs_r31 = 0
2504	!----------------------
2505	END FUNCTION ma_abs_r31
2506	!===
2507	INTEGER FUNCTION ma_chs_r31(nb,x,nbo,y)
2508	!---------------------------------------------------------------------
2509	IMPLICIT NONE
2510	!-
2511	INTEGER :: nb(3),nbo,i,j,k,ij
2512	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2513	!---------------------------------------------------------------------
2514	ij = 0
2515	DO k=1,nb(3)
2516	DO j=1,nb(2)
2517	DO i=1,nb(1)
2518	ij = ij+1
2519	y(ij) = x(i,j,k)*(-1.)
2520	ENDDO
2521	ENDDO
2522	ENDDO
2523	!-
2524	nbo = nb(1)nb(2)nb(3)
2525	ma_chs_r31 = 0
2526	!----------------------
2527	END FUNCTION ma_chs_r31
2528	!===
2529	INTEGER FUNCTION ma_cels_r31(nb,x,nbo,y)
2530	!---------------------------------------------------------------------
2531	IMPLICIT NONE
2532	!-
2533	INTEGER :: nb(3),nbo,i,j,k,ij
2534	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2535	!---------------------------------------------------------------------
2536	ij = 0
2537	DO k=1,nb(3)
2538	DO j=1,nb(2)
2539	DO i=1,nb(1)
2540	ij = ij+1
2541	y(ij) = x(i,j,k)-273.15
2542	ENDDO
2543	ENDDO
2544	ENDDO
2545	!-
2546	nbo = nb(1)nb(2)nb(3)
2547	ma_cels_r31 = 0
2548	!-----------------------
2549	END FUNCTION ma_cels_r31
2550	!===
2551	INTEGER FUNCTION ma_kelv_r31(nb,x,nbo,y)
2552	!---------------------------------------------------------------------
2553	IMPLICIT NONE
2554	!-
2555	INTEGER :: nb(3),nbo,i,j,k,ij
2556	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2557	!---------------------------------------------------------------------
2558	ij = 0
2559	DO k=1,nb(3)
2560	DO j=1,nb(2)
2561	DO i=1,nb(1)
2562	ij = ij+1
2563	y(ij) = x(i,j,k)+273.15
2564	ENDDO
2565	ENDDO
2566	ENDDO
2567	!-
2568	nbo = nb(1)nb(2)nb(3)
2569	ma_kelv_r31 = 0
2570	!-----------------------
2571	END FUNCTION ma_kelv_r31
2572	!===
2573	INTEGER FUNCTION ma_deg_r31(nb,x,nbo,y)
2574	!---------------------------------------------------------------------
2575	IMPLICIT NONE
2576	!-
2577	INTEGER :: nb(3),nbo,i,j,k,ij
2578	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2579	!---------------------------------------------------------------------
2580	ij = 0
2581	DO k=1,nb(3)
2582	DO j=1,nb(2)
2583	DO i=1,nb(1)
2584	ij = ij+1
2585	y(ij) = x(i,j,k)*57.29577951
2586	ENDDO
2587	ENDDO
2588	ENDDO
2589	!-
2590	nbo = nb(1)nb(2)nb(3)
2591	ma_deg_r31 = 0
2592	!----------------------
2593	END FUNCTION ma_deg_r31
2594	!===
2595	INTEGER FUNCTION ma_rad_r31(nb,x,nbo,y)
2596	!---------------------------------------------------------------------
2597	IMPLICIT NONE
2598	!-
2599	INTEGER :: nb(3),nbo,i,j,k,ij
2600	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2601	!---------------------------------------------------------------------
2602	ij = 0
2603	DO k=1,nb(3)
2604	DO j=1,nb(2)
2605	DO i=1,nb(1)
2606	ij = ij+1
2607	y(ij) = x(i,j,k)*0.01745329252
2608	ENDDO
2609	ENDDO
2610	ENDDO
2611	!-
2612	nbo = nb(1)nb(2)nb(3)
2613	ma_rad_r31 = 0
2614	!----------------------
2615	END FUNCTION ma_rad_r31
2616	!===
2617	INTEGER FUNCTION ma_ident_r31(nb,x,nbo,y)
2618	!---------------------------------------------------------------------
2619	IMPLICIT NONE
2620	!-
2621	INTEGER :: nb(3),nbo,i,j,k,ij
2622	REAL :: x(nb(1),nb(2),nb(3)),y(nbo)
2623	!---------------------------------------------------------------------
2624	ij = 0
2625	DO k=1,nb(3)
2626	DO j=1,nb(2)
2627	DO i=1,nb(1)
2628	ij = ij+1
2629	y(ij) = x(i,j,k)
2630	ENDDO
2631	ENDDO
2632	ENDDO
2633	!-
2634	nbo = nb(1)nb(2)nb(3)
2635	ma_ident_r31 = 0
2636	!------------------------
2637	END FUNCTION ma_ident_r31
2638	!-
2639	!=== OPERATIONS (two argument)
2640	!-
2641	INTEGER FUNCTION ma_add_r31(nb,x,s,nbo,y)
2642	!---------------------------------------------------------------------
2643	IMPLICIT NONE
2644	!-
2645	INTEGER :: nb(3),nbo
2646	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2647	!-
2648	INTEGER :: i,j,k,ij
2649	!---------------------------------------------------------------------
2650	ij = 0
2651	DO k=1,nb(3)
2652	DO j=1,nb(2)
2653	DO i=1,nb(1)
2654	ij = ij+1
2655	y(ij) = x(i,j,k)+s
2656	ENDDO
2657	ENDDO
2658	ENDDO
2659	!-
2660	nbo = nb(1)nb(2)nb(3)
2661	ma_add_r31 = 0
2662	!----------------------
2663	END FUNCTION ma_add_r31
2664	!===
2665	INTEGER FUNCTION ma_sub_r31(nb,x,s,nbo,y)
2666	!---------------------------------------------------------------------
2667	IMPLICIT NONE
2668	!-
2669	INTEGER :: nb(3),nbo
2670	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2671	!-
2672	INTEGER :: i,j,k,ij
2673	!---------------------------------------------------------------------
2674	ij = 0
2675	DO k=1,nb(3)
2676	DO j=1,nb(2)
2677	DO i=1,nb(1)
2678	ij = ij+1
2679	y(ij) = x(i,j,k)-s
2680	ENDDO
2681	ENDDO
2682	ENDDO
2683	!-
2684	nbo = nb(1)nb(2)nb(3)
2685	ma_sub_r31 = 0
2686	!----------------------
2687	END FUNCTION ma_sub_r31
2688	!===
2689	INTEGER FUNCTION ma_subi_r31(nb,x,s,nbo,y)
2690	!---------------------------------------------------------------------
2691	IMPLICIT NONE
2692	!-
2693	INTEGER :: nb(3),nbo
2694	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2695	!-
2696	INTEGER :: i,j,k,ij
2697	!---------------------------------------------------------------------
2698	ij = 0
2699	DO k=1,nb(3)
2700	DO j=1,nb(2)
2701	DO i=1,nb(1)
2702	ij = ij+1
2703	y(ij) = s-x(i,j,k)
2704	ENDDO
2705	ENDDO
2706	ENDDO
2707	!-
2708	nbo = nb(1)nb(2)nb(3)
2709	ma_subi_r31 = 0
2710	!-----------------------
2711	END FUNCTION ma_subi_r31
2712	!===
2713	INTEGER FUNCTION ma_mult_r31(nb,x,s,nbo,y)
2714	!---------------------------------------------------------------------
2715	IMPLICIT NONE
2716	!-
2717	INTEGER :: nb(3),nbo
2718	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2719	!-
2720	INTEGER :: i,j,k,ij
2721	!---------------------------------------------------------------------
2722	ij = 0
2723	DO k=1,nb(3)
2724	DO j=1,nb(2)
2725	DO i=1,nb(1)
2726	ij = ij+1
2727	y(ij) = x(i,j,k)*s
2728	ENDDO
2729	ENDDO
2730	ENDDO
2731	!-
2732	nbo = nb(1)nb(2)nb(3)
2733	ma_mult_r31 = 0
2734	!-----------------------
2735	END FUNCTION ma_mult_r31
2736	!===
2737	INTEGER FUNCTION ma_div_r31(nb,x,s,nbo,y)
2738	!---------------------------------------------------------------------
2739	IMPLICIT NONE
2740	!-
2741	INTEGER :: nb(3),nbo
2742	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2743	!-
2744	INTEGER :: i,j,k,ij
2745	!---------------------------------------------------------------------
2746	ij = 0
2747	DO k=1,nb(3)
2748	DO j=1,nb(2)
2749	DO i=1,nb(1)
2750	ij = ij+1
2751	y(ij) = x(i,j,k)/s
2752	ENDDO
2753	ENDDO
2754	ENDDO
2755	!-
2756	nbo = nb(1)nb(2)nb(3)
2757	ma_div_r31 = 0
2758	!----------------------
2759	END FUNCTION ma_div_r31
2760	!===
2761	INTEGER FUNCTION ma_divi_r31(nb,x,s,nbo,y)
2762	!---------------------------------------------------------------------
2763	IMPLICIT NONE
2764	!-
2765	INTEGER :: nb(3),nbo
2766	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2767	!-
2768	INTEGER :: i,j,k,ij
2769	!---------------------------------------------------------------------
2770	ij = 0
2771	DO k=1,nb(3)
2772	DO j=1,nb(2)
2773	DO i=1,nb(1)
2774	ij = ij+1
2775	y(ij) = s/x(i,j,k)
2776	ENDDO
2777	ENDDO
2778	ENDDO
2779	!-
2780	nbo = nb(1)nb(2)nb(3)
2781	ma_divi_r31 = 0
2782	!-----------------------
2783	END FUNCTION ma_divi_r31
2784	!===
2785	INTEGER FUNCTION ma_power_r31(nb,x,s,nbo,y)
2786	!---------------------------------------------------------------------
2787	IMPLICIT NONE
2788	!-
2789	INTEGER :: nb(3),nbo
2790	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2791	!-
2792	INTEGER :: i,j,k,ij
2793	!---------------------------------------------------------------------
2794	ij = 0
2795	DO k=1,nb(3)
2796	DO j=1,nb(2)
2797	DO i=1,nb(1)
2798	ij = ij+1
2799	y(ij) = x(i,j,k)**s
2800	ENDDO
2801	ENDDO
2802	ENDDO
2803	!-
2804	nbo = nb(1)nb(2)nb(3)
2805	ma_power_r31 = 0
2806	!------------------------
2807	END FUNCTION ma_power_r31
2808	!===
2809	INTEGER FUNCTION ma_fumin_r31(nb,x,s,nbo,y)
2810	!---------------------------------------------------------------------
2811	IMPLICIT NONE
2812	!-
2813	INTEGER :: nb(3),nbo
2814	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2815	!-
2816	INTEGER :: i,j,k,ij
2817	!---------------------------------------------------------------------
2818	ij = 0
2819	DO k=1,nb(3)
2820	DO j=1,nb(2)
2821	DO i=1,nb(1)
2822	ij = ij+1
2823	y(ij) = MIN(x(i,j,k),s)
2824	ENDDO
2825	ENDDO
2826	ENDDO
2827	!-
2828	nbo = nb(1)nb(2)nb(3)
2829	ma_fumin_r31 = 0
2830	!------------------------
2831	END FUNCTION ma_fumin_r31
2832	!===
2833	INTEGER FUNCTION ma_fumax_r31(nb,x,s,nbo,y)
2834	!---------------------------------------------------------------------
2835	IMPLICIT NONE
2836	!-
2837	INTEGER :: nb(3),nbo
2838	REAL :: x(nb(1),nb(2),nb(3)),s,y(nbo)
2839	!-
2840	INTEGER :: i,j,k,ij
2841	!---------------------------------------------------------------------
2842	ij = 0
2843	DO k=1,nb(3)
2844	DO j=1,nb(2)
2845	DO i=1,nb(1)
2846	ij = ij+1
2847	y(ij) = MAX(x(i,j,k),s)
2848	ENDDO
2849	ENDDO
2850	ENDDO
2851	!-
2852	nbo = nb(1)nb(2)nb(3)
2853	ma_fumax_r31 = 0
2854	!------------------------
2855	END FUNCTION ma_fumax_r31
2856	!===
2857	INTEGER FUNCTION ma_fuscat_r31(nb,x,nbi,ind,miss_val,nbo,y)
2858	!---------------------------------------------------------------------
2859	IMPLICIT NONE
2860	!-
2861	INTEGER :: nb(3),nbo,nbi
2862	INTEGER :: ind(nbi)
2863	REAL :: x(nb(1),nb(2),nb(3)),miss_val,y(nbo)
2864	!-
2865	INTEGER :: i,j,k,ij,ii,ipos,ipp,isb
2866	!---------------------------------------------------------------------
2867	ma_fuscat_r31 = 0
2868	!-
2869	y(1:nbo) = miss_val
2870	!-
2871	IF (nbi <= nb(1)nb(2)nb(3)) THEN
2872	ipos = 0
2873	isb = nb(1)*nb(2)
2874	DO ij=1,nbi
2875	IF (ind(ij) <= nbo .AND. ind(ij) > 0) THEN
2876	ipos = ipos+1
2877	k = ((ipos-1)/isb)+1
2878	ipp = ipos-(k-1)*isb
2879	j = ((ipp-1)/nb(1))+1
2880	i = (ipp-(j-1)*nb(1))
2881	y(ind(ij)) = x(i,j,k)
2882	ELSE
2883	IF (ind(ij) > nbo) ma_fuscat_r31 = ma_fuscat_r31+1
2884	ENDIF
2885	ENDDO
2886	!-- Repeat the data if needed
2887	IF (MINVAL(ind) < 0) THEN
2888	DO i=1,nbi
2889	IF (ind(i) <= 0) THEN
2890	DO ii=1,ABS(ind(i))-1
2891	IF (ind(i+1)+ii <= nbo) THEN
2892	y(ind(i+1)+ii) = y(ind(i+1))
2893	ELSE
2894	ma_fuscat_r31 = ma_fuscat_r31+1
2895	ENDIF
2896	ENDDO
2897	ENDIF
2898	ENDDO
2899	ENDIF
2900	ELSE
2901	ma_fuscat_r31 = 1
2902	ENDIF
2903	!-------------------------
2904	END FUNCTION ma_fuscat_r31
2905	!===
2906	INTEGER FUNCTION ma_fugath_r31(nb,x,nbi,ind,miss_val,nbo,y)
2907	!---------------------------------------------------------------------
2908	IMPLICIT NONE
2909	!-
2910	INTEGER :: nb(3),nbo,nbi
2911	INTEGER :: ind(nbi)
2912	REAL :: x(nb(1),nb(2),nb(3)),miss_val,y(nbo)
2913	!-
2914	INTEGER :: i,j,k,ij,ipos,ipp,isb
2915	!---------------------------------------------------------------------
2916	IF (nbi <= nbo) THEN
2917	ma_fugath_r31 = 0
2918	y(1:nbo) = miss_val
2919	ipos = 0
2920	isb = nb(1)*nb(2)
2921	DO ij=1,nbi
2922	IF (ipos+1 <= nbo) THEN
2923	IF (ind(ij) > 0) THEN
2924	k = ((ind(ij)-1)/isb)+1
2925	ipp = ind(ij)-(k-1)*isb
2926	j = ((ipp-1)/nb(1))+1
2927	i = (ipp-(j-1)*nb(1))
2928	ipos = ipos+1
2929	y(ipos) = x(i,j,k)
2930	ENDIF
2931	ELSE
2932	IF (ipos+1 > nbo) ma_fugath_r31 = ma_fugath_r31+1
2933	ENDIF
2934	ENDDO
2935	ELSE
2936	ma_fugath_r31 = 1
2937	ENDIF
2938	nbo = ipos
2939	!-------------------------
2940	END FUNCTION ma_fugath_r31
2941	!===
2942	INTEGER FUNCTION ma_fufill_r31(nb,x,nbi,ind,miss_val,nbo,y)
2943	!---------------------------------------------------------------------
2944	IMPLICIT NONE
2945	!-
2946	INTEGER :: nb(3),nbo,nbi
2947	INTEGER :: ind(nbi)
2948	REAL :: x(nb(1),nb(2),nb(3)),miss_val,y(nbo)
2949	!-
2950	INTEGER :: i,j,k,ij,ii,ipos,ipp,isb
2951	!---------------------------------------------------------------------
2952	ma_fufill_r31 = 0
2953	IF (nbi <= nb(1)nb(2)nb(3)) THEN
2954	ipos = 0
2955	isb = nb(1)*nb(2)
2956	DO ij=1,nbi
2957	IF (ind(ij) <= nbo .AND. ind(ij) > 0) THEN
2958	ipos = ipos+1
2959	k = ((ipos-1)/isb)+1
2960	ipp = ipos-(k-1)*isb
2961	j = ((ipp-1)/nb(1))+1
2962	i = (ipp-(j-1)*nb(1))
2963	y(ind(ij)) = x(i,j,k)
2964	ELSE
2965	IF (ind(ij) > nbo) ma_fufill_r31 = ma_fufill_r31+1
2966	ENDIF
2967	ENDDO
2968	!-- Repeat the data if needed
2969	IF (MINVAL(ind) < 0) THEN
2970	DO i=1,nbi
2971	IF (ind(i) <= 0) THEN
2972	DO ii=1,ABS(ind(i))-1
2973	IF (ind(i+1)+ii <= nbo) THEN
2974	y(ind(i+1)+ii) = y(ind(i+1))
2975	ELSE
2976	ma_fufill_r31 = ma_fufill_r31+1
2977	ENDIF
2978	ENDDO
2979	ENDIF
2980	ENDDO
2981	ENDIF
2982	ELSE
2983	ma_fufill_r31 = 1
2984	ENDIF
2985	!-------------------------
2986	END FUNCTION ma_fufill_r31
2987	!===
2988	INTEGER FUNCTION ma_fucoll_r31(nb,x,nbi,ind,miss_val,nbo,y)
2989	!---------------------------------------------------------------------
2990	IMPLICIT NONE
2991	!-
2992	INTEGER :: nb(3),nbo,nbi
2993	INTEGER :: ind(nbi)
2994	REAL :: x(nb(1),nb(2),nb(3)),miss_val,y(nbo)
2995	!-
2996	INTEGER :: i,j,k,ij,ipos,ipp,isb
2997	!---------------------------------------------------------------------
2998	IF (nbi <= nbo) THEN
2999	ma_fucoll_r31 = 0
3000	ipos = 0
3001	isb = nb(1)*nb(2)
3002	DO ij=1,nbi
3003	IF (ipos+1 <= nbo) THEN
3004	IF (ind(ij) > 0) THEN
3005	k = ((ind(ij)-1)/isb)+1
3006	ipp = ind(ij)-(k-1)*isb
3007	j = ((ipp-1)/nb(1))+1
3008	i = (ipp-(j-1)*nb(1))
3009	ipos = ipos+1
3010	y(ipos) = x(i,j,k)
3011	ENDIF
3012	ELSE
3013	IF (ipos+1 > nbo) ma_fucoll_r31 = ma_fucoll_r31+1
3014	ENDIF
3015	ENDDO
3016	ELSE
3017	ma_fucoll_r31 = 1
3018	ENDIF
3019	nbo = ipos
3020	!-------------------------
3021	END FUNCTION ma_fucoll_r31
3022	!===
3023	INTEGER FUNCTION ma_fuundef_r31(nb,x,nbi,ind,miss_val,nbo,y)
3024	!---------------------------------------------------------------------
3025	IMPLICIT NONE
3026	!-
3027	INTEGER :: nb(3),nbo,nbi
3028	INTEGER :: ind(nbi)
3029	REAL :: x(nb(1),nb(2),nb(3)),miss_val,y(nbo)
3030	!-
3031	INTEGER :: i,j,k,ij,ipp,isb
3032	!---------------------------------------------------------------------
3033	IF (nbi <= nbo .AND. nbo == nb(1)nb(2)nb(3)) THEN
3034	ma_fuundef_r31 = 0
3035	isb = nb(1)*nb(2)
3036	DO ij=1,nbo
3037	k = ((ij-1)/isb)+1
3038	ipp = ij-(k-1)*isb
3039	j = ((ipp-1)/nb(1))+1
3040	i = (ipp-(j-1)*nb(1))
3041	y(ij) = x(i,j,k)
3042	ENDDO
3043	DO i=1,nbi
3044	IF (ind(i) <= nbo .AND. ind(i) > 0) THEN
3045	y(ind(i)) = miss_val
3046	ELSE
3047	IF (ind(i) > nbo) ma_fuundef_r31 = ma_fuundef_r31+1
3048	ENDIF
3049	ENDDO
3050	ELSE
3051	ma_fuundef_r31 = 1
3052	ENDIF
3053	!--------------------------
3054	END FUNCTION ma_fuundef_r31
3055	!===
3056	INTEGER FUNCTION ma_fuonly_r31(nb,x,nbi,ind,miss_val,nbo,y)
3057	!---------------------------------------------------------------------
3058	IMPLICIT NONE
3059	!-
3060	INTEGER :: nb(3),nbo,nbi
3061	INTEGER :: ind(nbi)
3062	REAL :: x(nb(1),nb(2),nb(3)),miss_val,y(nbo)
3063	!-
3064	INTEGER :: i,j,k,ij,ipp,isb
3065	!---------------------------------------------------------------------
3066	IF ( (nbi <= nbo).AND.(nbo == nb(1)nb(2)nb(3)) &
3067	& .AND.ALL(ind(1:nbi) <= nbo) ) THEN
3068	ma_fuonly_r31 = 0
3069	y(1:nbo) = miss_val
3070	isb = nb(1)*nb(2)
3071	DO ij=1,nbi
3072	IF (ind(ij) > 0) THEN
3073	k = ((ind(ij)-1)/isb)+1
3074	ipp = ind(ij)-(k-1)*isb
3075	j = ((ipp-1)/nb(1))+1
3076	i = (ipp-(j-1)*nb(1))
3077	y(ind(ij)) = x(i,j,k)
3078	ENDIF
3079	ENDDO
3080	ELSE
3081	ma_fuonly_r31 = 1
3082	ENDIF
3083	!-------------------------
3084	END FUNCTION ma_fuonly_r31
3085	!===
3086	SUBROUTINE moycum (opp,np,px,py,pwx)
3087	!---------------------------------------------------------------------
3088	!- Does time operations
3089	!---------------------------------------------------------------------
3090	IMPLICIT NONE
3091	!-
3092	CHARACTER(LEN=7) :: opp
3093	INTEGER :: np
3094	REAL,DIMENSION(:) :: px,py
3095	INTEGER :: pwx
3096	!---------------------------------------------------------------------
3097	IF (pwx /= 0) THEN
3098	IF (opp == 'ave') THEN
3099	px(1:np)=(px(1:np)*pwx+py(1:np))/REAL(pwx+1)
3100	ELSE IF (opp == 't_sum') THEN
3101	px(1:np)=px(1:np)+py(1:np)
3102	ELSE IF ( (opp == 'l_min').OR.(opp == 't_min') ) THEN
3103	px(1:np)=MIN(px(1:np),py(1:np))
3104	ELSE IF ( (opp == 'l_max').OR.(opp == 't_max') ) THEN
3105	px(1:np)=MAX(px(1:np),py(1:np))
3106	ELSE
3107	CALL ipslerr(3,"moycum",'Unknown time operation',opp,' ')
3108	ENDIF
3109	ELSE
3110	IF (opp == 'l_min') THEN
3111	px(1:np)=MIN(px(1:np),py(1:np))
3112	ELSE IF (opp == 'l_max') THEN
3113	px(1:np)=MAX(px(1:np),py(1:np))
3114	ELSE
3115	px(1:np)=py(1:np)
3116	ENDIF
3117	ENDIF
3118	!--------------------
3119	END SUBROUTINE moycum
3120	!===
3121	SUBROUTINE moycum_index( opp, px, py, pwx, nbi, ind )
3122	!---------------------------------------------------------------------
3123	!- Does time operations on index points
3124	!---------------------------------------------------------------------
3125	IMPLICIT NONE
3126	!-
3127
3128	!! 0. Parameters and variables declaration
3129
3130	!! 0.1 Input variables
3131
3132	CHARACTER(LEN=7), INTENT(in) :: opp !! Operation performed
3133	INTEGER, INTENT(in) :: nbi !! Size of index vector
3134	INTEGER, DIMENSION(nbi), INTENT(in) :: ind !! Index vector
3135	REAL, DIMENSION(:), INTENT(in) :: py !! Vector containing the
3136	!! previous values of px
3137	!! Warning : due to memory
3138	!! optimization, we have
3139	!! generally SIZE(px) /= SIZE(py)
3140	INTEGER, INTENT(in) :: pwx !! Used to calculate average value
3141
3142	!! 0.3 Modified variables
3143
3144	REAL, DIMENSION(:), INTENT(inout) :: px !! Result
3145
3146	!! 0.4 Local variables
3147
3148	INTEGER :: ig !! Index
3149
3150	!---------------------------------------------------------------------
3151
3152	!! Perform operations only if the values of ind don't exceed the size of px
3153
3154	IF ( MAXVAL(ind) > SIZE(px) ) THEN
3155	CALL ipslerr(3,"moycum_index", &
3156	& "the index vector is out of range for px", &
3157	& "Indexation vector problem. We stop", " " )
3158	END IF
3159
3160	IF (pwx /= 0) THEN
3161	IF (opp == 'ave') THEN
3162	DO ig = 1,nbi
3163	px(ind(ig)) = (px(ind(ig))*pwx + py(ind(ig)))/REAL(pwx+1)
3164	END DO
3165	ELSE IF (opp == 't_sum') THEN
3166	DO ig = 1,nbi
3167	px(ind(ig)) = px(ind(ig)) + py(ind(ig))
3168	END DO
3169	ELSE IF ( (opp == 'l_min').OR.(opp == 't_min') ) THEN
3170	DO ig = 1,nbi
3171	px(ind(ig)) = MIN(px(ind(ig)),py(ind(ig)))
3172	END DO
3173	ELSE IF ( (opp == 'l_max').OR.(opp == 't_max') ) THEN
3174	DO ig = 1,nbi
3175	px(ind(ig)) = MAX(px(ind(ig)),py(ind(ig)))
3176	END DO
3177	ELSE
3178	CALL ipslerr(3,"moycum_index",'Unknown time operation',opp,' ')
3179	END IF
3180	ELSE
3181	IF (opp == 'l_min') THEN
3182	DO ig = 1,nbi
3183	px(ind(ig)) = MIN(px(ind(ig)),py(ind(ig)))
3184	END DO
3185	ELSE IF (opp == 'l_max') THEN
3186	DO ig = 1,nbi
3187	px(ind(ig)) = MAX(px(ind(ig)),py(ind(ig)))
3188	END DO
3189	ELSE
3190	DO ig = 1,nbi
3191	px(ind(ig)) = py(ind(ig))
3192	END DO
3193	ENDIF
3194	END IF
3195
3196	END SUBROUTINE moycum_index
3197
3198
3199	!-----------------
3200	END MODULE mathelp

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