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|
#if defined(MPI)
*DECK SNDMPI
SUBROUTINE SNDMPI(NENTRY,HENTRY,IENTRY,JENTRY,KENTRY)
*
*-----------------------------------------------------------------------
*
* EXPORT THE CONTENT OF A LCM OBJECT USING MPI
*
* INPUT/OUTPUT PARAMETERS:
* NENTRY : NUMBER OF LCM OBJECTS AND FILES USED BY THE MODULE.
* HENTRY : CHARACTER*12 NAME OF EACH LCM OBJECT.
* IENTRY : =0 CLE-2000 VARIABLE; =1 LINKED LIST; =2 XSM FILE;
* =3 SEQUENTIAL BINARY FILE; =4 SEQUENTIAL ASCII FILE;
* =5 DIRECT ACCESS FILE.
* JENTRY : =0 THE LINKED LIST OR FILE IS CREATED.
* =1 THE LINKED LIST OR FILE IS OPEN FOR MODIFICATIONS;
* =2 THE LINKED LIST OR FILE IS OPEN IN READ-ONLY MODE.
* KENTRY : =FILE UNIT NUMBER; =LCM OBJECT ADDRESS OTHERWISE.
* DIMENSION HENTRY(NENTRY),IENTRY(NENTRY),JENTRY(NENTRY),
* KENTRY(NENTRY)
*
* LCM OBJECTS:
* HENTRY(1) : ANY CREATE LCM OBJECT
* HENTRY(2) : ANY READ-ONLY LCM OBJECT
*
*----------------------------------- AUTHOR: R. CHAMBON ; 01/05/2003 ---
*
USE GANLIB
include 'mpif.h'
*----
* SUBROUTINE ARGUMENTS
*----
INTEGER NENTRY,IENTRY(NENTRY),JENTRY(NENTRY)
CHARACTER HENTRY(NENTRY)*12
TYPE(C_PTR) KENTRY(NENTRY)
*----
* LOCAL VARIABLES
*----
PARAMETER (MAXLEV=50)
PARAMETER (IHEAD=0,IHNAM=1,ILLIST=4,INEXT=5,IFATH=6,IFDIR=7,
1 IMODE=8,INREF=10,LFNODE=12)
PARAMETER (JDATA=0,JJLON=1,JJTYP=2,JCMT=7)
PARAMETER (IPRT=1)
TYPE(C_PTR) IPLIS1,IPLIS2
CHARACTER NAMT*12,HSMG*131,NAMLCM*12,MYNAME*12,PATH(MAXLEV)*12,
1 FIRST(MAXLEV)*12
LOGICAL EMPTY,LCM
TYPE(C_PTR) KDATA1(MAXLEV),KDATA2(MAXLEV)
INTEGER KJLON(MAXLEV),IVEC(MAXLEV),IGO(MAXLEV)
INTEGER*4 IPRINT,RANK,SIZE,IERR,ICOMM,ITAG
INTEGER*4 ICPUFM,ICPUTO
LOGICAL LALL,LCPUFM,LCPUTO,LITEM
INTEGER ILONG,ITYLCM
CHARACTER TEXT12*12
CHARACTER HMSG*131
DOUBLE PRECISION DFLOTT,DFLOTTT,DFLOTTF
*----
* ALLOCATABLE STATEMENTS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: ISTATU,IASS
#if defined(__x86_64__)
# define M64 2
#else
# define M64 1
#endif
*----
* VALIDITY OF OBJECTS
*----
IF( NENTRY.EQ.2 )THEN
* CALL XABORT('SENDP: 2 OBJECTS EXPECTED.')
* CHECK LL# 1 = ANY OBJECT (LINKED_LIST OR XSM_FILE) IS READ ONLY
IF((JENTRY(2).NE.2).OR.((IENTRY(2).NE.1).AND.(IENTRY(2).NE.2)))
1 CALL XABORT('SNDMPI: LINKED LIST OR XSM FILE IN READ-ONLY'
2 //' MODE EXPECTED AT RHS:'//HENTRY(2))
IPLIS1= KENTRY(2)
* CHECK LL# 2 = ANY OBJECT (LINKED_LIST OR XSM_FILE) IS CREATED
IF((JENTRY(1).NE.0).OR.((IENTRY(1).NE.1).AND.(IENTRY(1).NE.2)))
1 CALL XABORT('SNDMPI: LINKED LIST OR XSM FILE IN CREATED'
2 //' MODE EXPECTED AT LHS:'//HENTRY(1))
IPLIS2= KENTRY(1)
ENDIF
*----
* VARIABLE INITIALISATION
*----
IPRINT= 0
ICPUFM= -1
ICPUTO= -1
ICOMM= MPI_COMM_WORLD
ALLOCATE(ISTATU(MPI_STATUS_SIZE))
ITAG=1
LALL=.FALSE.
LITEM=.FALSE.
CALL MPI_COMM_RANK(ICOMM,RANK,IERR)
CALL MPI_COMM_SIZE(ICOMM,SIZE,IERR)
CALL MPI_TYPE_CONTIGUOUS(12,MPI_CHARACTER,MPI_DIRNAME,IERR)
CALL MPI_TYPE_COMMIT(MPI_DIRNAME,IERR)
CALL MPI_TYPE_CONTIGUOUS(4,MPI_CHARACTER,MPI_CHAR4,IERR)
CALL MPI_TYPE_COMMIT(MPI_CHAR4,IERR)
LCPUFM=.FALSE.
LCPUTO=.FALSE.
*----
* READ USER INPUT:
*----
2 CALL REDGET(ITYP,NITMA,FLOTT,TEXT12,DFLOTT)
* EDITION LEVEL
IF(TEXT12.EQ.'EDIT') THEN
CALL REDGET(ITYP,IPRINT,FLOTT,TEXT12,DFLOTT)
IF(ITYP.NE.1) CALL XABORT('SNDMPI: *IPRINT* MUST BE INTEGER')
* CPU FROM
ELSEIF(TEXT12.EQ.'FROM')THEN
CALL REDGET(ITYP,ICPUFM,FLOTT,TEXT12,DFLOTT)
IF(ITYP.NE.1) CALL XABORT('SNDMPI: *ICPUFM* MUST BE'
1 //'INTEGER AFTER FROM')
IF((ICPUFM.LT.0).OR.(ICPUFM.GE.SIZE)) THEN
WRITE(HMSG,2000) ICPUFM,SIZE-1
CALL XABORT(HMSG)
ENDIF
LCPUFM=(ICPUFM.EQ.RANK)
* CPU TO
ELSEIF(TEXT12.EQ.'TO')THEN
CALL REDGET(ITYP,ICPUTO,FLOTT,TEXT12,DFLOTT)
IF((ITYP.NE.1).AND.(TEXT12.NE.'ALL')) CALL XABORT('SNDMPI:'
1 //'*ICPUTO* MUST BE INTEGER OR THE KEYWORD: ALL')
IF(((ICPUTO.LT.0).OR.(ICPUTO.GE.SIZE)).AND.(TEXT12.NE.'ALL'))
1 THEN
WRITE(HMSG,2010) ICPUTO,SIZE-1
CALL XABORT(HMSG)
ENDIF
IF(TEXT12.EQ.'ALL')THEN
LALL=.TRUE.
ELSE
LCPUTO=(ICPUTO.EQ.RANK)
ENDIF
* ITEM
ELSEIF(TEXT12.EQ.'ITEM')THEN
LITEM=.TRUE.
CALL REDGET(ITYPF,NITMAF,FLOTTF,TEXT12,DFLOTTF)
CALL REDGET(ITYPT,NITMAT,FLOTTT,TEXT12,DFLOTTT)
IF((ITYPF.NE.1.AND.ITYPF.NE.2.AND.ITYPF.NE.4.AND.ITYPF.NE.5)
1 .OR.(ITYPF.NE.-ITYPT))THEN
CALL XABORT('SNDMPI: INVALID TYPE FOR ITEM "FROM" OR "TO"')
ENDIF
* END OF THIS SUBROUTINE
ELSEIF( TEXT12.EQ.';' )THEN
IF((ICPUFM.LT.0).OR.(ICPUTO.LT.0)) CALL XABORT('SNDMPI: '
1 //'*FROM* OR *TO* KEYWORD IS MISSING')
IF(LITEM.AND.(LALL.OR.LCPUFM.OR.LCPUTO)) GOTO 191
ILEV=1
KDATA1(1)=IPLIS1
KDATA2(1)=IPLIS2
KJLON(1)=-1
IVEC(1)=1
IGO(1)=5
IF(LALL)THEN
GOTO 120
ELSEIF(LCPUFM.OR.LCPUTO)THEN
GOTO 20
ELSE
GOTO 200
ENDIF
ELSE
CALL XABORT('SNDMPI: '//TEXT12//' IS AN INVALID KEYWORD.')
ENDIF
GO TO 2
*----
* READING ON A CPU AND WRITING ON ANOTHER ONE
*----
* USE A GENERAL COPY ALGORITHM.
*
* ASSOCIATIVE TABLE.
20 IF(LCPUFM) THEN
CALL LCMINF(IPLIS1,NAMLCM,MYNAME,EMPTY,ILONG,LCM)
CALL MPI_SEND(EMPTY,1*M64,MPI_LOGICAL,ICPUTO,
1 ITAG,ICOMM,IERR)
CALL MPI_SEND(ILONG,1*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(EMPTY,1*M64,MPI_LOGICAL,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
CALL MPI_RECV(ILONG,1*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
ENDIF
IF(EMPTY) GO TO ( 60, 60, 90, 90,200),IGO(ILEV)
NAMT=' '
IF(LCPUFM) THEN
CALL LCMNXT(IPLIS1,NAMT)
CALL MPI_SEND(NAMT,1,MPI_DIRNAME,ICPUTO,ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(NAMT,1,MPI_DIRNAME,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
ENDIF
*
FIRST(ILEV)=NAMT
30 IF(LCPUFM) THEN
CALL LCMLEN(IPLIS1,NAMT,ILONG,ITYLCM)
CALL MPI_SEND(ILONG,1*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
CALL MPI_SEND(ITYLCM,1*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(ILONG,1*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
CALL MPI_RECV(ITYLCM,1*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
ENDIF
IF((ILONG.NE.0).AND.(ITYLCM.EQ.0)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* ASSOCIATIVE TABLE DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,1
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=ILONG
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGID(IPLIS1,NAMT)
ENDIF
IF(LCPUTO) THEN
KDATA2(ILEV)=LCMDID(IPLIS2,NAMT)
ENDIF
PATH(ILEV)=NAMT
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IF(LCPUTO) THEN
IPLIS2=KDATA2(ILEV)
ENDIF
IVEC(ILEV)=1
IGO(ILEV)=1
GO TO 20
ELSE IF((ILONG.NE.0).AND.(ITYLCM.EQ.10)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* LIST DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,2
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=ILONG
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGID(IPLIS1,NAMT)
ENDIF
IF(LCPUTO) THEN
KDATA2(ILEV)=LCMLID(IPLIS2,NAMT,ILONG)
ENDIF
PATH(ILEV)=NAMT
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IF(LCPUTO) THEN
IPLIS2=KDATA2(ILEV)
ENDIF
IVEC(ILEV)=0
IGO(ILEV)=2
GO TO 70
ELSE IF((ILONG.NE.0).AND.(ITYLCM.LE.6)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* DATA
ALLOCATE(IASS(ILONG))
IF(LCPUFM) THEN
CALL LCMGET(IPLIS1,NAMT,IASS)
CALL MPI_SEND(IASS,ILONG*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(IASS,ILONG*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
CALL LCMPUT(IPLIS2,NAMT,ILONG,ITYLCM,IASS)
DEALLOCATE(IASS)
ENDIF
IF(LCPUFM) DEALLOCATE(IASS)
ENDIF
IF(LCPUFM) THEN
CALL LCMNXT(IPLIS1,NAMT)
CALL MPI_SEND(NAMT,1,MPI_DIRNAME,ICPUTO,ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(NAMT,1,MPI_DIRNAME,ICPUFM,ITAG,ICOMM,ISTATU,IERR)
ENDIF
IF(NAMT.NE.FIRST(ILEV)) GO TO 30
GO TO ( 60, 60, 90, 90,200),IGO(ILEV)
*
60 NAMT=PATH(ILEV)
ILEV=ILEV-1
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IF(LCPUTO) THEN
IPLIS2=KDATA2(ILEV)
ENDIF
IF(LCPUFM) THEN
CALL LCMNXT(IPLIS1,NAMT)
CALL MPI_SEND(NAMT,1,MPI_DIRNAME,ICPUTO,ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(NAMT,1,MPI_DIRNAME,ICPUFM,ITAG,ICOMM,ISTATU,IERR)
ENDIF
IF(NAMT.NE.FIRST(ILEV)) GO TO 30
GO TO ( 60, 60, 90, 90,200),IGO(ILEV)
*
* LIST.
70 IVEC(ILEV)=IVEC(ILEV)+1
IF(IVEC(ILEV).GT.KJLON(ILEV)) THEN
GO TO ( 60, 60, 90, 90,200),IGO(ILEV)
ENDIF
IF(LCPUFM) THEN
CALL LCMLEL(KDATA1(ILEV),IVEC(ILEV),ILONG,ITYLCM)
CALL MPI_SEND(ILONG,1*M64,MPI_INTEGER,ICPUTO,ITAG,ICOMM,IERR)
CALL MPI_SEND(ITYLCM,1*M64,MPI_INTEGER,ICPUTO,ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(ILONG,1*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
CALL MPI_RECV(ITYLCM,1*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
ENDIF
IF((ILONG.NE.0).AND.(ITYLCM.EQ.0)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* ASSOCIATIVE TABLE DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,3
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=-1
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGIL(IPLIS1,IVEC(ILEV-1))
ENDIF
IF(LCPUTO) THEN
KDATA2(ILEV)=LCMDIL(IPLIS2,IVEC(ILEV-1))
ENDIF
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IF(LCPUTO) THEN
IPLIS2=KDATA2(ILEV)
ENDIF
IVEC(ILEV)=1
IGO(ILEV)=3
GO TO 20
ELSE IF((ILONG.NE.0).AND.(ITYLCM.EQ.10)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* LIST DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,4
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=ILONG
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGIL(IPLIS1,IVEC(ILEV-1))
ENDIF
IF(LCPUTO) THEN
KDATA2(ILEV)=LCMLIL(IPLIS2,IVEC(ILEV-1),ILONG)
ENDIF
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IF(LCPUTO) THEN
IPLIS2=KDATA2(ILEV)
ENDIF
IVEC(ILEV)=0
IGO(ILEV)=4
GO TO 70
ELSE IF((ILONG.NE.0).AND.(ITYLCM.LE.6)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* DATA
ALLOCATE(IASS(ILONG))
IF(LCPUFM) THEN
CALL LCMGDL(IPLIS1,IVEC(ILEV),IASS)
CALL MPI_SEND(IASS,ILONG*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
ENDIF
IF(LCPUTO) THEN
CALL MPI_RECV(IASS,ILONG*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
CALL LCMPDL(IPLIS2,IVEC(ILEV),ILONG,ITYLCM,IASS)
DEALLOCATE(IASS)
ENDIF
IF(LCPUFM) DEALLOCATE(IASS)
ENDIF
GO TO 70
*
90 ILEV=ILEV-1
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IF(LCPUTO) THEN
IPLIS2=KDATA2(ILEV)
ENDIF
GO TO 70
*----
* READING ON A CPU AND WRITING ON ALL OTHER
*----
* USE A GENERAL COPY ALGORITHM.
*
* ASSOCIATIVE TABLE.
120 IF(LCPUFM) THEN
CALL LCMINF(IPLIS1,NAMLCM,MYNAME,EMPTY,ILONG,LCM)
ENDIF
CALL MPI_BCAST(EMPTY,1*M64,MPI_LOGICAL,ICPUFM,ICOMM,IERR)
CALL MPI_BCAST(ILONG,1*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
IF(EMPTY) GO TO (160,160,190,190,200),IGO(ILEV)
NAMT=' '
IF(LCPUFM) THEN
CALL LCMNXT(IPLIS1,NAMT)
ENDIF
CALL MPI_BCAST(NAMT,1,MPI_DIRNAME,ICPUFM,ICOMM,IERR)
*
FIRST(ILEV)=NAMT
130 IF(LCPUFM) THEN
CALL LCMLEN(IPLIS1,NAMT,ILONG,ITYLCM)
ENDIF
CALL MPI_BCAST(ILONG,1*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
CALL MPI_BCAST(ITYLCM,1*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
IF((ILONG.NE.0).AND.(ITYLCM.EQ.0)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* ASSOCIATIVE TABLE DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,5
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=ILONG
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGID(IPLIS1,NAMT)
ENDIF
KDATA2(ILEV)=LCMDID(IPLIS2,NAMT)
PATH(ILEV)=NAMT
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IPLIS2=KDATA2(ILEV)
IVEC(ILEV)=1
IGO(ILEV)=1
GO TO 120
ELSE IF((ILONG.NE.0).AND.(ITYLCM.EQ.10)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* LIST DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,6
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=ILONG
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGID(IPLIS1,NAMT)
ENDIF
KDATA2(ILEV)=LCMLID(IPLIS2,NAMT,ILONG)
PATH(ILEV)=NAMT
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IPLIS2=KDATA2(ILEV)
IVEC(ILEV)=0
IGO(ILEV)=2
GO TO 170
ELSE IF((ILONG.NE.0).AND.(ITYLCM.LE.6)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* DATA
ALLOCATE(IASS(ILONG))
IF(LCPUFM) THEN
CALL LCMGET(IPLIS1,NAMT,IASS)
ENDIF
CALL MPI_BCAST(IASS,ILONG*M64,MPI_INTEGER,ICPUFM,
1 ICOMM,IERR)
CALL LCMPUT(IPLIS2,NAMT,ILONG,ITYLCM,IASS)
DEALLOCATE(IASS)
ENDIF
IF(LCPUFM) THEN
CALL LCMNXT(IPLIS1,NAMT)
ENDIF
CALL MPI_BCAST(NAMT,1,MPI_DIRNAME,ICPUFM,ICOMM,IERR)
IF(NAMT.NE.FIRST(ILEV)) GO TO 130
GO TO (160,160,190,190,200),IGO(ILEV)
*
160 NAMT=PATH(ILEV)
ILEV=ILEV-1
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IPLIS2=KDATA2(ILEV)
IF(LCPUFM) THEN
CALL LCMNXT(IPLIS1,NAMT)
ENDIF
CALL MPI_BCAST(NAMT,1,MPI_DIRNAME,ICPUFM,ICOMM,IERR)
IF(NAMT.NE.FIRST(ILEV)) GO TO 130
GO TO (160,160,190,190,200),IGO(ILEV)
*
* LIST.
170 IVEC(ILEV)=IVEC(ILEV)+1
IF(IVEC(ILEV).GT.KJLON(ILEV)) THEN
GO TO (160,160,190,190,200),IGO(ILEV)
ENDIF
IF(LCPUFM) THEN
CALL LCMLEL(KDATA1(ILEV),IVEC(ILEV),ILONG,ITYLCM)
ENDIF
CALL MPI_BCAST(ILONG,1*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
CALL MPI_BCAST(ITYLCM,1*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
IF((ILONG.NE.0).AND.(ITYLCM.EQ.0)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* ASSOCIATIVE TABLE DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,7
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=-1
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGIL(IPLIS1,IVEC(ILEV-1))
ENDIF
KDATA2(ILEV)=LCMDIL(IPLIS2,IVEC(ILEV-1))
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IPLIS2=KDATA2(ILEV)
IVEC(ILEV)=1
IGO(ILEV)=3
GO TO 120
ELSE IF((ILONG.NE.0).AND.(ITYLCM.EQ.10)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* LIST DATA.
ILEV=ILEV+1
IF(ILEV.GT.MAXLEV) THEN
WRITE(HSMG,2020) NAMLCM,8
CALL XABORT(HSMG)
ENDIF
KJLON(ILEV)=ILONG
IF(LCPUFM) THEN
KDATA1(ILEV)=LCMGIL(IPLIS1,IVEC(ILEV-1))
ENDIF
KDATA2(ILEV)=LCMLIL(IPLIS2,IVEC(ILEV-1),ILONG)
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IPLIS2=KDATA2(ILEV)
IVEC(ILEV)=0
IGO(ILEV)=4
GO TO 170
ELSE IF((ILONG.NE.0).AND.(ITYLCM.LE.6)) THEN
IF(IPRT.GT.0) WRITE(6,1010) ILEV,NAMT,ITYLCM,ILONG
* DATA
ALLOCATE(IASS(ILONG))
IF(LCPUFM) THEN
CALL LCMGDL(IPLIS1,IVEC(ILEV),IASS)
ENDIF
CALL MPI_BCAST(IASS,ILONG*M64,MPI_INTEGER,ICPUFM,
1 ICOMM,IERR)
CALL LCMPDL(IPLIS2,IVEC(ILEV),ILONG,ITYLCM,IASS)
DEALLOCATE(IASS)
ENDIF
GO TO 170
*
190 ILEV=ILEV-1
IF(LCPUFM) THEN
IPLIS1=KDATA1(ILEV)
ENDIF
IPLIS2=KDATA2(ILEV)
GO TO 170
*----
* SENDING ITEM
*----
191 IF(LALL)THEN
IF(ITYPF.EQ.1.OR.ITYPF.EQ.5)THEN
CALL MPI_BCAST(NITMAF,1*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
ELSEIF(ITYPF.EQ.2)THEN
CALL MPI_BCAST(FLOTTF,1*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
ELSEIF(ITYPF.EQ.4)THEN
CALL MPI_BCAST(DFLOTTF,2*M64,MPI_INTEGER,ICPUFM,ICOMM,IERR)
ENDIF
GO TO 199
ENDIF
IF(LCPUFM) THEN
IF(ITYPF.EQ.1.OR.ITYPF.EQ.5)THEN
CALL MPI_SEND(NITMAF,1*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
ELSEIF(ITYPF.EQ.2)THEN
CALL MPI_SEND(FLOTTF,1*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
ELSEIF(ITYPF.EQ.4)THEN
CALL MPI_SEND(DFLOTTF,2*M64,MPI_INTEGER,ICPUTO,
1 ITAG,ICOMM,IERR)
ENDIF
ENDIF
IF(LCPUTO) THEN
IF(ITYPF.EQ.1.OR.ITYPF.EQ.5)THEN
CALL MPI_RECV(NITMAF,1*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
ELSEIF(ITYPF.EQ.2)THEN
CALL MPI_RECV(FLOTTF,1*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
ELSEIF(ITYPF.EQ.4)THEN
CALL MPI_RECV(DFLOTTF,2*M64,MPI_INTEGER,ICPUFM,
1 ITAG,ICOMM,ISTATU,IERR)
ENDIF
ENDIF
199 CALL REDPUT(ITYPF,NITMAF,FLOTTF,TEXT12,DFLOTTF)
200 RETURN
STOP
*----
* FORMAT
*----
1010 FORMAT (1X,I5,3H ',A12,1H',2I8)
2000 FORMAT(38HSNDMPI: PROCESSOR NUMBER *FROM* SET TO,I4,
1 30HINSTEAD OF BEING BETWEEN 0 AND,I4)
2010 FORMAT(36HSNDMPI: PROCESSOR NUMBER *TO* SET TO,I4,
1 30HINSTEAD OF BEING BETWEEN 0 AND,I4)
2020 FORMAT(37HSNDMPI: TOO MANY DIRECTORY LEVELS ON ,A,2H (,I1,2H).)
END
#endif /* defined(MPI) */
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