pkg/ctrl/ctrl_getobcsw.F


#include "CTRL_CPPOPTIONS.h"
#ifdef ALLOW_OBCS
# include "OBCS_OPTIONS.h"
#endif


      subroutine ctrl_getobcsw(
     I                             mytime,
     I                             myiter,
     I                             mythid
     &                           )

c     ==================================================================
c     SUBROUTINE ctrl_getobcsw
c     ==================================================================
c
c     o Get western obc of the control vector and add it
c       to dyn. fields
c
c     started: heimbach@mit.edu, 29-Aug-2001
c
c     ==================================================================
c     SUBROUTINE ctrl_getobcsw
c     ==================================================================

      implicit none

#ifdef ALLOW_OBCSW_CONTROL

c     == global variables ==

#include "EEPARAMS.h"
#include "SIZE.h"
#include "PARAMS.h"
#include "GRID.h"
#include "OBCS.h"

#include "ctrl.h"
#include "ctrl_dummy.h"
#include "optim.h"

c     == routine arguments ==

      _RL     mytime
      integer myiter
      integer mythid

c     == local variables ==

      integer bi,bj
      integer i,j,k
      integer itlo,ithi
      integer jtlo,jthi
      integer jmin,jmax
      integer imin,imax
      integer ilobcsw
      integer iobcs
      integer ip1

      _RL     dummy
      _RL     obcswfac
      logical obcswfirst
      logical obcswchanged
      integer obcswcount0
      integer obcswcount1

cgg      _RL maskyz   (1-oly:sny+oly,nr,nsx,nsy)

      logical doglobalread
      logical ladinit

      character*(80) fnameobcsw

#ifdef BALANCE_CONTROL_VOLFLUX
cgg(  Variables for balancing volume flux.
      _RL ubaro
      _RL ubarocount
cgg)
#endif

c     == external functions ==

      integer  ilnblnk
      external ilnblnk


c     == end of interface ==

      jtlo = mybylo(mythid)
      jthi = mybyhi(mythid)
      itlo = mybxlo(mythid)
      ithi = mybxhi(mythid)
      jmin = 1-oly
      jmax = sny+oly
      imin = 1-olx
      imax = snx+olx
      ip1  = 1

#ifdef BALANCE_CONTROL_VOLFLUX
cgg(  Initialize variables for balancing volume flux.
      ubaro = 0.d0
      ubarocount = 0.d0
cgg)
#endif

c--   Now, read the control vector.
      doglobalread = .false.
      ladinit      = .false.

      if (optimcycle .ge. 0) then
        ilobcsw=ilnblnk( xx_obcsw_file )
        write(fnameobcsw(1:80),'(2a,i10.10)') 
     &       xx_obcsw_file(1:ilobcsw), '.', optimcycle
      else
        print*
        print*,' ctrl_getobcsw: optimcycle not set correctly.'
        print*,' ... stopped in ctrl_getobcsw.'
      endif

c--   Get the counters, flags, and the interpolation factor.
      call ctrl_GetRec( 'xx_obcsw',
     O                   obcswfac, obcswfirst, obcswchanged,
     O                   obcswcount0,obcswcount1,
     I                   mytime, myiter, mythid )

      do iobcs = 1,nobcs
       
cgg        if ( (obcswfirst) .or. (obcswchanged) ) then
cgg          call active_read_yz( 'maskobcsw', maskyz, 
cgg     &                         iobcs,
cgg     &                         doglobalread, ladinit, 0,
cgg     &                         mythid, dummy )
cgg        endif

        if ( obcswfirst ) then
          call active_read_yz( fnameobcsw, tmpfldyz, 
     &                         (obcswcount0-1)*nobcs+iobcs,
     &                         doglobalread, ladinit, optimcycle,
     &                         mythid, xx_obcsw_dummy )

#ifdef BALANCE_CONTROL_VOLFLUX
          if ( optimcycle .gt. 0) then           
            if (iobcs .eq. 3) then
cgg(        Make sure that the xx velocity field has a balanced net volume flux.
cgg         Find the barotropic flow normal to the boundary.
cgg         For the north, this is the v velocity, iobcs = 4.
              do bj = jtlo,jthi
                do bi = itlo, ithi
                  do j = jmin,jmax
                    i = OB_Iw(j,bi,bj)
                    ubaro = 0.d0
                    ubarocount = 0.d0
                    do k = 1,nr
cgg(   If cells are not full, this should be modified with hFac.
                      ubaro = tmpfldyz(j,k,bi,bj)*maskW(i+ip1,j,k,bi,bj)
     &                      * delZ(k) + ubaro 
                      ubarocount = maskW(i+ip1,j,k,bi,bj)
     &                           * delZ(k) +ubarocount
                    enddo
                    if (ubarocount .eq. 0.) then
                      ubaro = 0.
                    else
                      ubaro = ubaro / ubarocount
                    endif
                    do k = 1,nr
                      tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj) - ubaro
                    enddo
                  enddo
                enddo
              enddo
            endif
          endif
cgg)
#endif
#ifdef BALANCE_CONTROL_VOLFLUX_GLOBAL 
          if (optimcycle .gt. 0) then
            if ( iobcs .eq. 3) then
              do bj = jtlo,jthi
                do bi = itlo, ithi
                  do k = 1,Nr
                    do j = jmin,jmax
                      i = OB_Iw(j,bi,bj)
                      tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj) 
     &                   - shiftvel(1) *maskW(i+ip1,j,k,bi,bj)
                    enddo
                  enddo
                enddo
              enddo
            endif
          endif
#endif

          do bj = jtlo,jthi
            do bi = itlo,ithi
              do k = 1,nr
                do j = jmin,jmax
                  xx_obcsw1(j,k,bi,bj,iobcs)  = tmpfldyz (j,k,bi,bj)
                 enddo
              enddo
            enddo
          enddo
        endif

        if ( (obcswfirst) .or. (obcswchanged)) then
          
cgg(    This is a terribly long way to do it. However, the dimensions don't exactly
cgg     match up. I will blame Fortran for the ugliness.

          do bj = jtlo,jthi
            do bi = itlo,ithi
              do k = 1,nr
                do j = jmin,jmax

                  tmpfldyz(j,k,bi,bj) = xx_obcsw1(j,k,bi,bj,iobcs)
                enddo
              enddo
            enddo
          enddo

          call exf_swapffields_yz( tmpfldyz2, tmpfldyz, mythid)

          do bj = jtlo,jthi
            do bi = itlo,ithi
              do k = 1,nr
                do j = jmin,jmax
                  xx_obcsw0(j,k,bi,bj,iobcs) = tmpfldyz2(j,k,bi,bj)        
                enddo
              enddo
            enddo
          enddo

          call active_read_yz( fnameobcsw, tmpfldyz, 
     &                         (obcswcount1-1)*nobcs+iobcs,
     &                         doglobalread, ladinit, optimcycle,
     &                         mythid, xx_obcsw_dummy )

#ifdef BALANCE_CONTROL_VOLFLUX
          if (optimcycle .gt. 0) then
            if (iobcs .eq. 3) then
cgg(        Make sure that the xx velocity field has a balanced net volume flux.
cgg         Find the barotropic flow normal to the boundary.
cgg         For the north, this is the v velocity, iobcs = 4.
              do bj = jtlo,jthi
                do bi = itlo, ithi
                  do j = jmin,jmax
                    i = OB_Iw(j,bi,bj)
                    ubaro = 0.d0
                    ubarocount = 0.d0
                    do k = 1,nr
cgg(   If cells are not full, this should be modified with hFac.
                      ubaro = tmpfldyz(j,k,bi,bj)*maskw(i+ip1,j,k,bi,bj)
     &                      * delZ(k) + ubaro 
                      ubarocount = maskW(i+ip1,j,k,bi,bj)
     &                           * delZ(k) + ubarocount
                    enddo
                    if (ubarocount .eq. 0.) then
                      ubaro = 0.
                    else
                      ubaro = ubaro / ubarocount
                    endif
                    do k = 1,nr
                      tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj) - ubaro
                    enddo
                  enddo
                enddo
              enddo
            endif
          endif
cgg)
#endif
#ifdef BALANCE_CONTROL_VOLFLUX_GLOBAL 
          if (optimcycle .gt. 0) then
            if ( iobcs .eq. 3) then
              do bj = jtlo,jthi
                do bi = itlo, ithi
                  do k = 1,Nr
                    do j = jmin,jmax
                      i = OB_Iw(j,bi,bj)
                      tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj) 
     &                   - shiftvel(2) *maskW(i+ip1,j,k,bi,bj)
                    enddo
                  enddo
                enddo
              enddo
            endif
          endif
#endif

          do bj = jtlo,jthi
            do bi = itlo,ithi
              do k = 1,nr
                do j = jmin,jmax
                  xx_obcsw1 (j,k,bi,bj,iobcs) = tmpfldyz (j,k,bi,bj)
                 enddo
              enddo
            enddo
          enddo
        endif

c--     Add control to model variable.
        do bj = jtlo,jthi
           do bi = itlo,ithi
c--        Calculate mask for tracer cells (0 => land, 1 => water).
              do k = 1,nr
                 do j = 1,sny
                    i = OB_Iw(j,bi,bj)
                    if (iobcs .EQ. 1) then
                       OBWt(j,k,bi,bj) = OBWt (j,k,bi,bj)
     &                 + obcswfac            *xx_obcsw0(j,k,bi,bj,iobcs)
     &                 + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
                       OBWt(j,k,bi,bj) = OBWt(j,k,bi,bj)
     &                      *maskW(i+ip1,j,k,bi,bj)
                    else if (iobcs .EQ. 2) then
                       OBWs(j,k,bi,bj) = OBWs (j,k,bi,bj)
     &                 + obcswfac            *xx_obcsw0(j,k,bi,bj,iobcs)
     &                 + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
                       OBWs(j,k,bi,bj) = OBWs(j,k,bi,bj)
     &                      *maskW(i+ip1,j,k,bi,bj)
                    else if (iobcs .EQ. 3) then
                       OBWu(j,k,bi,bj) = OBWu (j,k,bi,bj)
     &                 + obcswfac            *xx_obcsw0(j,k,bi,bj,iobcs)
     &                 + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
                       OBWu(j,k,bi,bj) = OBWu(j,k,bi,bj)
     &                      *maskW(i+ip1,j,k,bi,bj)
                    else if (iobcs .EQ. 4) then
                       OBWv(j,k,bi,bj) = OBWv (j,k,bi,bj)
     &                 + obcswfac            *xx_obcsw0(j,k,bi,bj,iobcs)
     &                 + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
                       OBWv(j,k,bi,bj) = OBWv(j,k,bi,bj)
     &                      *maskS(i,j,k,bi,bj)
                    endif
                 enddo
              enddo
           enddo
        enddo

C--   End over iobcs loop
      enddo

#else /* ALLOW_OBCSW_CONTROL undefined */

c     == routine arguments ==

      _RL     mytime
      integer myiter
      integer mythid

c--   CPP flag ALLOW_OBCSW_CONTROL undefined.

#endif /* ALLOW_OBCSW_CONTROL */

      end

1
2	#include "CTRL_CPPOPTIONS.h"
3	#ifdef ALLOW_OBCS
4	# include "OBCS_OPTIONS.h"
5	#endif
6
7
8	subroutine ctrl_getobcsw(
9	I mytime,
10	I myiter,
11	I mythid
12	& )
13
14	c ==================================================================
15	c SUBROUTINE ctrl_getobcsw
16	c ==================================================================
17	c
18	c o Get western obc of the control vector and add it
19	c to dyn. fields
20	c
21	c started: heimbach@mit.edu, 29-Aug-2001
22	c
23	c ==================================================================
24	c SUBROUTINE ctrl_getobcsw
25	c ==================================================================
26
27	implicit none
28
29	#ifdef ALLOW_OBCSW_CONTROL
30
31	c == global variables ==
32
33	#include "EEPARAMS.h"
34	#include "SIZE.h"
35	#include "PARAMS.h"
36	#include "GRID.h"
37	#include "OBCS.h"
38
39	#include "ctrl.h"
40	#include "ctrl_dummy.h"
41	#include "optim.h"
42
43	c == routine arguments ==
44
45	_RL mytime
46	integer myiter
47	integer mythid
48
49	c == local variables ==
50
51	integer bi,bj
52	integer i,j,k
53	integer itlo,ithi
54	integer jtlo,jthi
55	integer jmin,jmax
56	integer imin,imax
57	integer ilobcsw
58	integer iobcs
59	integer ip1
60
61	_RL dummy
62	_RL obcswfac
63	logical obcswfirst
64	logical obcswchanged
65	integer obcswcount0
66	integer obcswcount1
67
68	cgg _RL maskyz (1-oly:sny+oly,nr,nsx,nsy)
69
70	logical doglobalread
71	logical ladinit
72
73	character*(80) fnameobcsw
74
75	#ifdef BALANCE_CONTROL_VOLFLUX
76	cgg( Variables for balancing volume flux.
77	_RL ubaro
78	_RL ubarocount
79	cgg)
80	#endif
81
82	c == external functions ==
83
84	integer ilnblnk
85	external ilnblnk
86
87
88	c == end of interface ==
89
90	jtlo = mybylo(mythid)
91	jthi = mybyhi(mythid)
92	itlo = mybxlo(mythid)
93	ithi = mybxhi(mythid)
94	jmin = 1-oly
95	jmax = sny+oly
96	imin = 1-olx
97	imax = snx+olx
98	ip1 = 1
99
100	#ifdef BALANCE_CONTROL_VOLFLUX
101	cgg( Initialize variables for balancing volume flux.
102	ubaro = 0.d0
103	ubarocount = 0.d0
104	cgg)
105	#endif
106
107	c-- Now, read the control vector.
108	doglobalread = .false.
109	ladinit = .false.
110
111	if (optimcycle .ge. 0) then
112	ilobcsw=ilnblnk( xx_obcsw_file )
113	write(fnameobcsw(1:80),'(2a,i10.10)')
114	& xx_obcsw_file(1:ilobcsw), '.', optimcycle
115	else
116	print*
117	print*,' ctrl_getobcsw: optimcycle not set correctly.'
118	print*,' ... stopped in ctrl_getobcsw.'
119	endif
120
121	c-- Get the counters, flags, and the interpolation factor.
122	call ctrl_GetRec( 'xx_obcsw',
123	O obcswfac, obcswfirst, obcswchanged,
124	O obcswcount0,obcswcount1,
125	I mytime, myiter, mythid )
126
127	do iobcs = 1,nobcs
128
129	cgg if ( (obcswfirst) .or. (obcswchanged) ) then
130	cgg call active_read_yz( 'maskobcsw', maskyz,
131	cgg & iobcs,
132	cgg & doglobalread, ladinit, 0,
133	cgg & mythid, dummy )
134	cgg endif
135
136	if ( obcswfirst ) then
137	call active_read_yz( fnameobcsw, tmpfldyz,
138	& (obcswcount0-1)*nobcs+iobcs,
139	& doglobalread, ladinit, optimcycle,
140	& mythid, xx_obcsw_dummy )
141
142	#ifdef BALANCE_CONTROL_VOLFLUX
143	if ( optimcycle .gt. 0) then
144	if (iobcs .eq. 3) then
145	cgg( Make sure that the xx velocity field has a balanced net volume flux.
146	cgg Find the barotropic flow normal to the boundary.
147	cgg For the north, this is the v velocity, iobcs = 4.
148	do bj = jtlo,jthi
149	do bi = itlo, ithi
150	do j = jmin,jmax
151	i = OB_Iw(j,bi,bj)
152	ubaro = 0.d0
153	ubarocount = 0.d0
154	do k = 1,nr
155	cgg( If cells are not full, this should be modified with hFac.
156	ubaro = tmpfldyz(j,k,bi,bj)*maskW(i+ip1,j,k,bi,bj)
157	& * delZ(k) + ubaro
158	ubarocount = maskW(i+ip1,j,k,bi,bj)
159	& * delZ(k) +ubarocount
160	enddo
161	if (ubarocount .eq. 0.) then
162	ubaro = 0.
163	else
164	ubaro = ubaro / ubarocount
165	endif
166	do k = 1,nr
167	tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj) - ubaro
168	enddo
169	enddo
170	enddo
171	enddo
172	endif
173	endif
174	cgg)
175	#endif
176	#ifdef BALANCE_CONTROL_VOLFLUX_GLOBAL
177	if (optimcycle .gt. 0) then
178	if ( iobcs .eq. 3) then
179	do bj = jtlo,jthi
180	do bi = itlo, ithi
181	do k = 1,Nr
182	do j = jmin,jmax
183	i = OB_Iw(j,bi,bj)
184	tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj)
185	& - shiftvel(1) *maskW(i+ip1,j,k,bi,bj)
186	enddo
187	enddo
188	enddo
189	enddo
190	endif
191	endif
192	#endif
193
194	do bj = jtlo,jthi
195	do bi = itlo,ithi
196	do k = 1,nr
197	do j = jmin,jmax
198	xx_obcsw1(j,k,bi,bj,iobcs) = tmpfldyz (j,k,bi,bj)
199	enddo
200	enddo
201	enddo
202	enddo
203	endif
204
205	if ( (obcswfirst) .or. (obcswchanged)) then
206
207	cgg( This is a terribly long way to do it. However, the dimensions don't exactly
208	cgg match up. I will blame Fortran for the ugliness.
209
210	do bj = jtlo,jthi
211	do bi = itlo,ithi
212	do k = 1,nr
213	do j = jmin,jmax
214
215	tmpfldyz(j,k,bi,bj) = xx_obcsw1(j,k,bi,bj,iobcs)
216	enddo
217	enddo
218	enddo
219	enddo
220
221	call exf_swapffields_yz( tmpfldyz2, tmpfldyz, mythid)
222
223	do bj = jtlo,jthi
224	do bi = itlo,ithi
225	do k = 1,nr
226	do j = jmin,jmax
227	xx_obcsw0(j,k,bi,bj,iobcs) = tmpfldyz2(j,k,bi,bj)
228	enddo
229	enddo
230	enddo
231	enddo
232
233	call active_read_yz( fnameobcsw, tmpfldyz,
234	& (obcswcount1-1)*nobcs+iobcs,
235	& doglobalread, ladinit, optimcycle,
236	& mythid, xx_obcsw_dummy )
237
238	#ifdef BALANCE_CONTROL_VOLFLUX
239	if (optimcycle .gt. 0) then
240	if (iobcs .eq. 3) then
241	cgg( Make sure that the xx velocity field has a balanced net volume flux.
242	cgg Find the barotropic flow normal to the boundary.
243	cgg For the north, this is the v velocity, iobcs = 4.
244	do bj = jtlo,jthi
245	do bi = itlo, ithi
246	do j = jmin,jmax
247	i = OB_Iw(j,bi,bj)
248	ubaro = 0.d0
249	ubarocount = 0.d0
250	do k = 1,nr
251	cgg( If cells are not full, this should be modified with hFac.
252	ubaro = tmpfldyz(j,k,bi,bj)*maskw(i+ip1,j,k,bi,bj)
253	& * delZ(k) + ubaro
254	ubarocount = maskW(i+ip1,j,k,bi,bj)
255	& * delZ(k) + ubarocount
256	enddo
257	if (ubarocount .eq. 0.) then
258	ubaro = 0.
259	else
260	ubaro = ubaro / ubarocount
261	endif
262	do k = 1,nr
263	tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj) - ubaro
264	enddo
265	enddo
266	enddo
267	enddo
268	endif
269	endif
270	cgg)
271	#endif
272	#ifdef BALANCE_CONTROL_VOLFLUX_GLOBAL
273	if (optimcycle .gt. 0) then
274	if ( iobcs .eq. 3) then
275	do bj = jtlo,jthi
276	do bi = itlo, ithi
277	do k = 1,Nr
278	do j = jmin,jmax
279	i = OB_Iw(j,bi,bj)
280	tmpfldyz(j,k,bi,bj) = tmpfldyz(j,k,bi,bj)
281	& - shiftvel(2) *maskW(i+ip1,j,k,bi,bj)
282	enddo
283	enddo
284	enddo
285	enddo
286	endif
287	endif
288	#endif
289
290	do bj = jtlo,jthi
291	do bi = itlo,ithi
292	do k = 1,nr
293	do j = jmin,jmax
294	xx_obcsw1 (j,k,bi,bj,iobcs) = tmpfldyz (j,k,bi,bj)
295	enddo
296	enddo
297	enddo
298	enddo
299	endif
300
301	c-- Add control to model variable.
302	do bj = jtlo,jthi
303	do bi = itlo,ithi
304	c-- Calculate mask for tracer cells (0 => land, 1 => water).
305	do k = 1,nr
306	do j = 1,sny
307	i = OB_Iw(j,bi,bj)
308	if (iobcs .EQ. 1) then
309	OBWt(j,k,bi,bj) = OBWt (j,k,bi,bj)
310	& + obcswfac *xx_obcsw0(j,k,bi,bj,iobcs)
311	& + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
312	OBWt(j,k,bi,bj) = OBWt(j,k,bi,bj)
313	& *maskW(i+ip1,j,k,bi,bj)
314	else if (iobcs .EQ. 2) then
315	OBWs(j,k,bi,bj) = OBWs (j,k,bi,bj)
316	& + obcswfac *xx_obcsw0(j,k,bi,bj,iobcs)
317	& + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
318	OBWs(j,k,bi,bj) = OBWs(j,k,bi,bj)
319	& *maskW(i+ip1,j,k,bi,bj)
320	else if (iobcs .EQ. 3) then
321	OBWu(j,k,bi,bj) = OBWu (j,k,bi,bj)
322	& + obcswfac *xx_obcsw0(j,k,bi,bj,iobcs)
323	& + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
324	OBWu(j,k,bi,bj) = OBWu(j,k,bi,bj)
325	& *maskW(i+ip1,j,k,bi,bj)
326	else if (iobcs .EQ. 4) then
327	OBWv(j,k,bi,bj) = OBWv (j,k,bi,bj)
328	& + obcswfac *xx_obcsw0(j,k,bi,bj,iobcs)
329	& + (1. _d 0 - obcswfac)*xx_obcsw1(j,k,bi,bj,iobcs)
330	OBWv(j,k,bi,bj) = OBWv(j,k,bi,bj)
331	& *maskS(i,j,k,bi,bj)
332	endif
333	enddo
334	enddo
335	enddo
336	enddo
337
338	C-- End over iobcs loop
339	enddo
340
341	#else /* ALLOW_OBCSW_CONTROL undefined */
342
343	c == routine arguments ==
344
345	_RL mytime
346	integer myiter
347	integer mythid
348
349	c-- CPP flag ALLOW_OBCSW_CONTROL undefined.
350
351	#endif /* ALLOW_OBCSW_CONTROL */
352
353	end
354