pkg/exch2/exch2_rx2_cube_ad.template

C $Header: /u/gcmpack/MITgcm/pkg/exch2/exch2_rx2_cube_ad.template,v 1.6 2009/05/30 21:26:31 jmc Exp $
C $Name:  $

#include "CPP_EEOPTIONS.h"
#undef LOCAL_DBUG

CBOP
C     !ROUTINE: EXCH_RX2_CUBE_AD

C     !INTERFACE:
      SUBROUTINE EXCH2_RX2_CUBE_AD(
     U            array1, array2,
     I            signOption, fieldCode,
     I            myOLw, myOLe, myOLn, myOLs, myNz,
     I            exchWidthX, exchWidthY,
     I            simulationMode, cornerMode, myThid )

C     !DESCRIPTION:
C     Two components vector field AD-Exchange:
C     Tile-edge overlap-region of a 2 component vector field is added to
C     corresponding near-edge interior data point and then zero out.

C     !USES:
      IMPLICIT NONE

C     == Global data ==
#include "SIZE.h"
#include "EEPARAMS.h"
#include "EESUPPORT.h"
#include "W2_EXCH2_SIZE.h"
#include "W2_EXCH2_TOPOLOGY.h"
#include "W2_EXCH2_BUFFER.h"

C     !INPUT/OUTPUT PARAMETERS:
C     array1      :: 1rst component array with edges to exchange.
C     array2      :: 2nd  component array with edges to exchange.
C     signOption  :: Flag controlling whether vector is signed.
C     fieldCode   :: field code (position on staggered grid)
C     myOLw,myOLe :: West and East overlap region sizes.
C     myOLn,myOLs :: North and South overlap region sizes.
C     exchWidthX  :: Width of data region exchanged in X.
C     exchWidthY  :: Width of data region exchanged in Y.
C     cornerMode  :: halo-corner-region treatment: update/ignore corner region
C     myThid      :: Thread number of this instance of S/R EXCH...

      INTEGER myOLw, myOLe, myOLn, myOLs, myNz
      _RX array1(1-myOLw:sNx+myOLe,
     &           1-myOLs:sNy+myOLn,
     &           myNz, nSx, nSy)
      _RX array2(1-myOLw:sNx+myOLe,
     &           1-myOLs:sNy+myOLn,
     &           myNz, nSx, nSy)
      LOGICAL signOption
      CHARACTER*2 fieldCode
      INTEGER exchWidthX
      INTEGER exchWidthY
      INTEGER simulationMode
      INTEGER cornerMode
      INTEGER myThid

C     !LOCAL VARIABLES:
C     e2_msgHandles :: Synchronization and coordination data structure used to
C                   :: coordinate access to e2Bufr1_RX or to regulate message
C                   :: buffering. In PUT communication sender will increment
C                   :: handle entry once data is ready in buffer. Receiver will
C                   :: decrement handle once data is consumed from buffer.
C                   :: For MPI MSG communication MPI_Wait uses hanlde to check
C                   :: Isend has cleared. This is done in routine after receives.
C     note: a) current implementation does not use e2_msgHandles for communication
C              between threads: all-threads barriers are used (see CNH note below).
C              For a 2-threads synchro communication (future version),
C              e2_msgHandles should be shared (in common block, moved to BUFFER.h)
      INTEGER bi, bj
C     Variables for working through W2 topology
      INTEGER e2_msgHandles( 2, W2_maxNeighbours, nSx, nSy )
      INTEGER thisTile, farTile, N, nN, oN
      INTEGER tIlo1, tIhi1, tJlo1, tJhi1, oIs1, oJs1
      INTEGER tIlo2, tIhi2, tJlo2, tJhi2, oIs2, oJs2
      INTEGER tIStride, tJStride
      INTEGER tKlo, tKhi, tKStride
      INTEGER i1Lo, i1Hi, j1Lo, j1Hi, k1Lo, k1Hi
      INTEGER i2Lo, i2Hi, j2Lo, j2Hi, k2Lo, k2Hi

#ifdef ALLOW_USE_MPI
      INTEGER iBufr1, iBufr2, nri, nrj
C     MPI stuff (should be in a routine call)
      INTEGER mpiStatus(MPI_STATUS_SIZE)
      INTEGER mpiRc
      INTEGER wHandle
#endif
CEOP

C-    Tile size of arrays to exchange:
      i1Lo  = 1-myOLw
      i1Hi  = sNx+myOLe
      j1Lo  = 1-myOLs
      j1Hi  = sNy+myOLn
      k1Lo  = 1
      k1Hi  = myNz
      i2Lo  = 1-myOLw
      i2Hi  = sNx+myOLe
      j2Lo  = 1-myOLs
      j2Hi  = sNy+myOLn
      k2Lo  = 1
      k2Hi  = myNz

C     For now tile <-> tile exchanges are sequentialised through
C     thread 1. This is a temporary feature for preliminary testing until
C     general tile decomposition is in place (CNH April 11, 2001)
      CALL BAR2( myThid )

C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-|--+----|

C--   Extract from buffer (either from level 1 if local exch,
C                     or level 2 if coming from an other Proc)
C  AD: = fill buffer from my-tile-edge overlap-region, level 1 or 2 depending
C  AD:   on local (to this Proc) or remote Proc tile destination
      DO bj=myByLo(myThid), myByHi(myThid)
       DO bi=myBxLo(myThid), myBxHi(myThid)
        thisTile=W2_myTileList(bi,bj)
        nN=exch2_nNeighbours(thisTile)
        DO N=1,nN
          CALL EXCH2_GET_UV_BOUNDS(
     I               fieldCode, exchWidthX,
     I               thisTile, N,
     O               tIlo1, tIhi1, tJlo1, tJhi1,
     O               tIlo2, tIhi2, tJlo2, tJhi2,
     O               tiStride, tjStride,
     O               oIs1, oJs1, oIs2, oJs2,
     I               myThid )
          tKLo=1
          tKHi=myNz
          tKStride=1

C     From buffer, get my points
C     (tIlo:tIhi:tiStride,tJlo:tJhi,tJStride,tKlo:tKhi,tKStride) in "array1,2":
C     Note: when transferring data within a process:
C      o e2Bufr entry to read is entry associated with opposing send record
C      o e2_msgHandle entry to read is entry associated with opposing send record.
          CALL EXCH2_AD_GET_RX2(
     I               tIlo1, tIhi1, tIlo2, tIhi2, tiStride,
     I               tJlo1, tJhi1, tJlo2, tJhi2, tjStride,
     I               tKlo, tKhi, tkStride,
     I               thisTile, N, bi, bj,
     I               e2BufrRecSize, W2_maxNeighbours, nSx, nSy,
     O               iBuf1Filled(N,bi,bj), iBuf2Filled(N,bi,bj),
     O               e2Bufr1_RX, e2Bufr2_RX,
     U               array1(1-myOLw,1-myOLs,1,bi,bj),
     U               array2(1-myOLw,1-myOLs,1,bi,bj),
     I               i1Lo, i1Hi, j1Lo, j1Hi, k1Lo, k1Hi,
     I               i2Lo, i2Hi, j2Lo, j2Hi, k2Lo, k2Hi,
     U               e2_msgHandles,
     I               W2_myCommFlag(N,bi,bj), myThid )
        ENDDO
       ENDDO
      ENDDO

C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-|--+----|

#ifdef ALLOW_USE_MPI
C  AD: all MPI part is acting on buffer and is identical to forward code,
C  AD: except a) the buffer level: send from lev.2, receive into lev.1
C  AD:        b) the length of transfered buffer (<- match the ad_put/ad_get)

C     wait until all threads finish filling buffer
      CALL BAR2( myThid )
      _BEGIN_MASTER( myThid )

C--   Send my data (in buffer, level 1) to target Process
      DO bj=1,nSy
       DO bi=1,nSx
        thisTile=W2_myTileList(bi,bj)
        nN=exch2_nNeighbours(thisTile)
        DO N=1,nN
C-    Skip the call if this is an internal exchange
         IF ( W2_myCommFlag(N,bi,bj) .EQ. 'M' ) THEN
          CALL EXCH2_SEND_RX2(
     I               thisTile, N,
     I               e2BufrRecSize,
     I               iBuf1Filled(N,bi,bj),    iBuf2Filled(N,bi,bj),
     I               e2Bufr1_RX(1,N,bi,bj,2), e2Bufr2_RX(1,N,bi,bj,2),
     O               e2_msgHandles(1,N,bi,bj),
     I               W2_myCommFlag(N,bi,bj), myThid )
         ENDIF
        ENDDO
       ENDDO
      ENDDO

C--   Receive data (in buffer, level 1) from source Process
      DO bj=1,nSy
       DO bi=1,nSx
        thisTile=W2_myTileList(bi,bj)
        nN=exch2_nNeighbours(thisTile)
        DO N=1,nN
C-    Skip the call if this is an internal exchange
         IF ( W2_myCommFlag(N,bi,bj) .EQ. 'M' ) THEN
          farTile=exch2_neighbourId(N,thisTile)
          oN = exch2_opposingSend(N,thisTile)
          CALL EXCH2_GET_UV_BOUNDS(
     I               fieldCode, exchWidthX,
     I               farTile, oN,
     O               tIlo1, tIhi1, tJlo1, tJhi1,
     O               tIlo2, tIhi2, tJlo2, tJhi2,
     O               tiStride, tjStride,
     O               oIs1, oJs1, oIs2, oJs2,
     I               myThid )
          nri = 1 + (tIhi1-tIlo1)/tiStride
          nrj = 1 + (tJhi1-tJlo1)/tjStride
          iBufr1 = nri*nrj*myNz
          nri = 1 + (tIhi2-tIlo2)/tiStride
          nrj = 1 + (tJhi2-tJlo2)/tjStride
          iBufr2 = nri*nrj*myNz
C       Receive from neighbour N to fill buffer and later on the array
          CALL EXCH2_RECV_RX2(
     I               thisTile, N,
     I               e2BufrRecSize,
     I               iBufr1, iBufr2,
     I               e2Bufr1_RX(1,N,bi,bj,1), e2Bufr2_RX(1,N,bi,bj,1),
     I               W2_myCommFlag(N,bi,bj), myThid )
         ENDIF
        ENDDO
       ENDDO
      ENDDO

C--   Clear message handles/locks
      DO bj=1,nSy
       DO bi=1,nSx
        thisTile=W2_myTileList(bi,bj)
        nN=exch2_nNeighbours(thisTile)
        DO N=1,nN
C     Note: In a between process tile-tile data transport using
C           MPI the sender needs to clear an Isend wait handle here.
C           In a within process tile-tile data transport using true
C           shared address space/or direct transfer through commonly
C           addressable memory blocks the receiver needs to assert
C           that he has consumed the buffer the sender filled here.
         farTile=exch2_neighbourId(N,thisTile)
         IF     ( W2_myCommFlag(N,bi,bj) .EQ. 'M' ) THEN
          wHandle = e2_msgHandles(1,N,bi,bj)
          CALL MPI_Wait( wHandle, mpiStatus, mpiRc )
          wHandle = e2_msgHandles(2,N,bi,bj)
          CALL MPI_Wait( wHandle, mpiStatus, mpiRc )
         ELSEIF ( W2_myCommFlag(N,bi,bj) .EQ. 'P' ) THEN
         ELSE
         ENDIF
        ENDDO
       ENDDO
      ENDDO

      _END_MASTER( myThid )
#endif /* ALLOW_USE_MPI */

C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-|--+----|
C     Wait until all threads finish receiving or filling buffer
      CALL BAR2( myThid )

C--   Post sends into buffer (buffer level 1):
      DO bj=myByLo(myThid), myByHi(myThid)
       DO bi=myBxLo(myThid), myBxHi(myThid)
        thisTile=W2_myTileList(bi,bj)
        nN=exch2_nNeighbours(thisTile)
        DO N=1,nN
          farTile=exch2_neighbourId(N,thisTile)
          oN = exch2_opposingSend(N,thisTile)
          CALL EXCH2_GET_UV_BOUNDS(
     I               fieldCode, exchWidthX,
     I               farTile, oN,
     O               tIlo1, tIhi1, tJlo1, tJhi1,
     O               tIlo2, tIhi2, tJlo2, tJhi2,
     O               tiStride, tjStride,
     O               oIs1, oJs1, oIs2, oJs2,
     I               myThid )
          tKLo=1
          tKHi=myNz
          tKStride=1
C-    Put my points in buffer for neighbour N to fill points
C     (tIlo:tIhi:tiStride,tJlo:tJhi,tJStride,tKlo:tKhi,tKStride)
C     in its copy of "array1" & "array2".
          CALL EXCH2_AD_PUT_RX2(
     I               tIlo1, tIhi1, tIlo2, tIhi2, tiStride,
     I               tJlo1, tJhi1, tJlo2, tJhi2, tjStride,
     I               tKlo, tKhi, tkStride,
     I               oIs1, oJs1, oIs2, oJs2,
     I               thisTile, N,
     I               e2BufrRecSize,
     O               e2Bufr1_RX(1,N,bi,bj,1), e2Bufr2_RX(1,N,bi,bj,1),
     I               array1(1-myOLw,1-myOLs,1,bi,bj),
     I               array2(1-myOLw,1-myOLs,1,bi,bj),
     I               i1Lo, i1Hi, j1Lo, j1Hi, k1Lo, k1Hi,
     I               i2Lo, i2Hi, j2Lo, j2Hi, k2Lo, k2Hi,
     O               e2_msgHandles(1,N,bi,bj),
     I               W2_myCommFlag(N,bi,bj), signOption, myThid )
        ENDDO
       ENDDO
      ENDDO

      CALL BAR2(myThid)

      RETURN
      END

C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-|--+----|

CEH3 ;;; Local Variables: ***
CEH3 ;;; mode:fortran ***
CEH3 ;;; End: ***
1	C $Header: /u/gcmpack/MITgcm/pkg/exch2/exch2_rx2_cube_ad.template,v 1.6 2009/05/30 21:26:31 jmc Exp $
2	C $Name: $
3
4	#include "CPP_EEOPTIONS.h"
5	#undef LOCAL_DBUG
6
7	CBOP
8	C !ROUTINE: EXCH_RX2_CUBE_AD
9
10	C !INTERFACE:
11	SUBROUTINE EXCH2_RX2_CUBE_AD(
12	U array1, array2,
13	I signOption, fieldCode,
14	I myOLw, myOLe, myOLn, myOLs, myNz,
15	I exchWidthX, exchWidthY,
16	I simulationMode, cornerMode, myThid )
17
18	C !DESCRIPTION:
19	C Two components vector field AD-Exchange:
20	C Tile-edge overlap-region of a 2 component vector field is added to
21	C corresponding near-edge interior data point and then zero out.
22
23	C !USES:
24	IMPLICIT NONE
25
26	C == Global data ==
27	#include "SIZE.h"
28	#include "EEPARAMS.h"
29	#include "EESUPPORT.h"
30	#include "W2_EXCH2_SIZE.h"
31	#include "W2_EXCH2_TOPOLOGY.h"
32	#include "W2_EXCH2_BUFFER.h"
33
34	C !INPUT/OUTPUT PARAMETERS:
35	C array1 :: 1rst component array with edges to exchange.
36	C array2 :: 2nd component array with edges to exchange.
37	C signOption :: Flag controlling whether vector is signed.
38	C fieldCode :: field code (position on staggered grid)
39	C myOLw,myOLe :: West and East overlap region sizes.
40	C myOLn,myOLs :: North and South overlap region sizes.
41	C exchWidthX :: Width of data region exchanged in X.
42	C exchWidthY :: Width of data region exchanged in Y.
43	C cornerMode :: halo-corner-region treatment: update/ignore corner region
44	C myThid :: Thread number of this instance of S/R EXCH...
45
46	INTEGER myOLw, myOLe, myOLn, myOLs, myNz
47	_RX array1(1-myOLw:sNx+myOLe,
48	& 1-myOLs:sNy+myOLn,
49	& myNz, nSx, nSy)
50	_RX array2(1-myOLw:sNx+myOLe,
51	& 1-myOLs:sNy+myOLn,
52	& myNz, nSx, nSy)
53	LOGICAL signOption
54	CHARACTER*2 fieldCode
55	INTEGER exchWidthX
56	INTEGER exchWidthY
57	INTEGER simulationMode
58	INTEGER cornerMode
59	INTEGER myThid
60
61	C !LOCAL VARIABLES:
62	C e2_msgHandles :: Synchronization and coordination data structure used to
63	C :: coordinate access to e2Bufr1_RX or to regulate message
64	C :: buffering. In PUT communication sender will increment
65	C :: handle entry once data is ready in buffer. Receiver will
66	C :: decrement handle once data is consumed from buffer.
67	C :: For MPI MSG communication MPI_Wait uses hanlde to check
68	C :: Isend has cleared. This is done in routine after receives.
69	C note: a) current implementation does not use e2_msgHandles for communication
70	C between threads: all-threads barriers are used (see CNH note below).
71	C For a 2-threads synchro communication (future version),
72	C e2_msgHandles should be shared (in common block, moved to BUFFER.h)
73	INTEGER bi, bj
74	C Variables for working through W2 topology
75	INTEGER e2_msgHandles( 2, W2_maxNeighbours, nSx, nSy )
76	INTEGER thisTile, farTile, N, nN, oN
77	INTEGER tIlo1, tIhi1, tJlo1, tJhi1, oIs1, oJs1
78	INTEGER tIlo2, tIhi2, tJlo2, tJhi2, oIs2, oJs2
79	INTEGER tIStride, tJStride
80	INTEGER tKlo, tKhi, tKStride
81	INTEGER i1Lo, i1Hi, j1Lo, j1Hi, k1Lo, k1Hi
82	INTEGER i2Lo, i2Hi, j2Lo, j2Hi, k2Lo, k2Hi
83
84	#ifdef ALLOW_USE_MPI
85	INTEGER iBufr1, iBufr2, nri, nrj
86	C MPI stuff (should be in a routine call)
87	INTEGER mpiStatus(MPI_STATUS_SIZE)
88	INTEGER mpiRc
89	INTEGER wHandle
90	#endif
91	CEOP
92
93	C- Tile size of arrays to exchange:
94	i1Lo = 1-myOLw
95	i1Hi = sNx+myOLe
96	j1Lo = 1-myOLs
97	j1Hi = sNy+myOLn
98	k1Lo = 1
99	k1Hi = myNz
100	i2Lo = 1-myOLw
101	i2Hi = sNx+myOLe
102	j2Lo = 1-myOLs
103	j2Hi = sNy+myOLn
104	k2Lo = 1
105	k2Hi = myNz
106
107	C For now tile <-> tile exchanges are sequentialised through
108	C thread 1. This is a temporary feature for preliminary testing until
109	C general tile decomposition is in place (CNH April 11, 2001)
110	CALL BAR2( myThid )
111
112	C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-\|--+----\|
113
114	C-- Extract from buffer (either from level 1 if local exch,
115	C or level 2 if coming from an other Proc)
116	C AD: = fill buffer from my-tile-edge overlap-region, level 1 or 2 depending
117	C AD: on local (to this Proc) or remote Proc tile destination
118	DO bj=myByLo(myThid), myByHi(myThid)
119	DO bi=myBxLo(myThid), myBxHi(myThid)
120	thisTile=W2_myTileList(bi,bj)
121	nN=exch2_nNeighbours(thisTile)
122	DO N=1,nN
123	CALL EXCH2_GET_UV_BOUNDS(
124	I fieldCode, exchWidthX,
125	I thisTile, N,
126	O tIlo1, tIhi1, tJlo1, tJhi1,
127	O tIlo2, tIhi2, tJlo2, tJhi2,
128	O tiStride, tjStride,
129	O oIs1, oJs1, oIs2, oJs2,
130	I myThid )
131	tKLo=1
132	tKHi=myNz
133	tKStride=1
134
135	C From buffer, get my points
136	C (tIlo:tIhi:tiStride,tJlo:tJhi,tJStride,tKlo:tKhi,tKStride) in "array1,2":
137	C Note: when transferring data within a process:
138	C o e2Bufr entry to read is entry associated with opposing send record
139	C o e2_msgHandle entry to read is entry associated with opposing send record.
140	CALL EXCH2_AD_GET_RX2(
141	I tIlo1, tIhi1, tIlo2, tIhi2, tiStride,
142	I tJlo1, tJhi1, tJlo2, tJhi2, tjStride,
143	I tKlo, tKhi, tkStride,
144	I thisTile, N, bi, bj,
145	I e2BufrRecSize, W2_maxNeighbours, nSx, nSy,
146	O iBuf1Filled(N,bi,bj), iBuf2Filled(N,bi,bj),
147	O e2Bufr1_RX, e2Bufr2_RX,
148	U array1(1-myOLw,1-myOLs,1,bi,bj),
149	U array2(1-myOLw,1-myOLs,1,bi,bj),
150	I i1Lo, i1Hi, j1Lo, j1Hi, k1Lo, k1Hi,
151	I i2Lo, i2Hi, j2Lo, j2Hi, k2Lo, k2Hi,
152	U e2_msgHandles,
153	I W2_myCommFlag(N,bi,bj), myThid )
154	ENDDO
155	ENDDO
156	ENDDO
157
158	C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-\|--+----\|
159
160	#ifdef ALLOW_USE_MPI
161	C AD: all MPI part is acting on buffer and is identical to forward code,
162	C AD: except a) the buffer level: send from lev.2, receive into lev.1
163	C AD: b) the length of transfered buffer (<- match the ad_put/ad_get)
164
165	C wait until all threads finish filling buffer
166	CALL BAR2( myThid )
167	_BEGIN_MASTER( myThid )
168
169	C-- Send my data (in buffer, level 1) to target Process
170	DO bj=1,nSy
171	DO bi=1,nSx
172	thisTile=W2_myTileList(bi,bj)
173	nN=exch2_nNeighbours(thisTile)
174	DO N=1,nN
175	C- Skip the call if this is an internal exchange
176	IF ( W2_myCommFlag(N,bi,bj) .EQ. 'M' ) THEN
177	CALL EXCH2_SEND_RX2(
178	I thisTile, N,
179	I e2BufrRecSize,
180	I iBuf1Filled(N,bi,bj), iBuf2Filled(N,bi,bj),
181	I e2Bufr1_RX(1,N,bi,bj,2), e2Bufr2_RX(1,N,bi,bj,2),
182	O e2_msgHandles(1,N,bi,bj),
183	I W2_myCommFlag(N,bi,bj), myThid )
184	ENDIF
185	ENDDO
186	ENDDO
187	ENDDO
188
189	C-- Receive data (in buffer, level 1) from source Process
190	DO bj=1,nSy
191	DO bi=1,nSx
192	thisTile=W2_myTileList(bi,bj)
193	nN=exch2_nNeighbours(thisTile)
194	DO N=1,nN
195	C- Skip the call if this is an internal exchange
196	IF ( W2_myCommFlag(N,bi,bj) .EQ. 'M' ) THEN
197	farTile=exch2_neighbourId(N,thisTile)
198	oN = exch2_opposingSend(N,thisTile)
199	CALL EXCH2_GET_UV_BOUNDS(
200	I fieldCode, exchWidthX,
201	I farTile, oN,
202	O tIlo1, tIhi1, tJlo1, tJhi1,
203	O tIlo2, tIhi2, tJlo2, tJhi2,
204	O tiStride, tjStride,
205	O oIs1, oJs1, oIs2, oJs2,
206	I myThid )
207	nri = 1 + (tIhi1-tIlo1)/tiStride
208	nrj = 1 + (tJhi1-tJlo1)/tjStride
209	iBufr1 = nrinrjmyNz
210	nri = 1 + (tIhi2-tIlo2)/tiStride
211	nrj = 1 + (tJhi2-tJlo2)/tjStride
212	iBufr2 = nrinrjmyNz
213	C Receive from neighbour N to fill buffer and later on the array
214	CALL EXCH2_RECV_RX2(
215	I thisTile, N,
216	I e2BufrRecSize,
217	I iBufr1, iBufr2,
218	I e2Bufr1_RX(1,N,bi,bj,1), e2Bufr2_RX(1,N,bi,bj,1),
219	I W2_myCommFlag(N,bi,bj), myThid )
220	ENDIF
221	ENDDO
222	ENDDO
223	ENDDO
224
225	C-- Clear message handles/locks
226	DO bj=1,nSy
227	DO bi=1,nSx
228	thisTile=W2_myTileList(bi,bj)
229	nN=exch2_nNeighbours(thisTile)
230	DO N=1,nN
231	C Note: In a between process tile-tile data transport using
232	C MPI the sender needs to clear an Isend wait handle here.
233	C In a within process tile-tile data transport using true
234	C shared address space/or direct transfer through commonly
235	C addressable memory blocks the receiver needs to assert
236	C that he has consumed the buffer the sender filled here.
237	farTile=exch2_neighbourId(N,thisTile)
238	IF ( W2_myCommFlag(N,bi,bj) .EQ. 'M' ) THEN
239	wHandle = e2_msgHandles(1,N,bi,bj)
240	CALL MPI_Wait( wHandle, mpiStatus, mpiRc )
241	wHandle = e2_msgHandles(2,N,bi,bj)
242	CALL MPI_Wait( wHandle, mpiStatus, mpiRc )
243	ELSEIF ( W2_myCommFlag(N,bi,bj) .EQ. 'P' ) THEN
244	ELSE
245	ENDIF
246	ENDDO
247	ENDDO
248	ENDDO
249
250	_END_MASTER( myThid )
251	#endif /* ALLOW_USE_MPI */
252
253	C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-\|--+----\|
254	C Wait until all threads finish receiving or filling buffer
255	CALL BAR2( myThid )
256
257	C-- Post sends into buffer (buffer level 1):
258	DO bj=myByLo(myThid), myByHi(myThid)
259	DO bi=myBxLo(myThid), myBxHi(myThid)
260	thisTile=W2_myTileList(bi,bj)
261	nN=exch2_nNeighbours(thisTile)
262	DO N=1,nN
263	farTile=exch2_neighbourId(N,thisTile)
264	oN = exch2_opposingSend(N,thisTile)
265	CALL EXCH2_GET_UV_BOUNDS(
266	I fieldCode, exchWidthX,
267	I farTile, oN,
268	O tIlo1, tIhi1, tJlo1, tJhi1,
269	O tIlo2, tIhi2, tJlo2, tJhi2,
270	O tiStride, tjStride,
271	O oIs1, oJs1, oIs2, oJs2,
272	I myThid )
273	tKLo=1
274	tKHi=myNz
275	tKStride=1
276	C- Put my points in buffer for neighbour N to fill points
277	C (tIlo:tIhi:tiStride,tJlo:tJhi,tJStride,tKlo:tKhi,tKStride)
278	C in its copy of "array1" & "array2".
279	CALL EXCH2_AD_PUT_RX2(
280	I tIlo1, tIhi1, tIlo2, tIhi2, tiStride,
281	I tJlo1, tJhi1, tJlo2, tJhi2, tjStride,
282	I tKlo, tKhi, tkStride,
283	I oIs1, oJs1, oIs2, oJs2,
284	I thisTile, N,
285	I e2BufrRecSize,
286	O e2Bufr1_RX(1,N,bi,bj,1), e2Bufr2_RX(1,N,bi,bj,1),
287	I array1(1-myOLw,1-myOLs,1,bi,bj),
288	I array2(1-myOLw,1-myOLs,1,bi,bj),
289	I i1Lo, i1Hi, j1Lo, j1Hi, k1Lo, k1Hi,
290	I i2Lo, i2Hi, j2Lo, j2Hi, k2Lo, k2Hi,
291	O e2_msgHandles(1,N,bi,bj),
292	I W2_myCommFlag(N,bi,bj), signOption, myThid )
293	ENDDO
294	ENDDO
295	ENDDO
296
297	CALL BAR2(myThid)
298
299	RETURN
300	END
301
302	C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-\|--+----\|
303
304	CEH3 ;;; Local Variables: ***
305	CEH3 ;;; mode:fortran ***
306	CEH3 ;;; End: ***