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|
PROGRAM PDBLA2TIM
*
* -- PBLAS timing driver (version 2.0) --
* University of Tennessee, Knoxville, Oak Ridge National Laboratory,
* and University of California, Berkeley.
* April 1, 1998
*
* Purpose
* =======
*
* PDBLA2TIM is the main timing program for the Level 2 PBLAS routines.
*
* The program must be driven by a short data file. An annotated exam-
* ple of a data file can be obtained by deleting the first 3 characters
* from the following 55 lines:
* 'Level 2 PBLAS, Timing input file'
* 'Intel iPSC/860 hypercube, gamma model.'
* 'PDBLAS2TIM.SUMM' output file name (if any)
* 6 device out
* 10 value of the logical computational blocksize NB
* 1 number of process grids (ordered pairs of P & Q)
* 2 2 1 4 2 3 8 values of P
* 2 2 4 1 3 2 1 values of Q
* 1.0D0 value of ALPHA
* 1.0D0 value of BETA
* 2 number of tests problems
* 'U' 'L' values of UPLO
* 'N' 'T' values of TRANS
* 'N' 'U' values of DIAG
* 3 4 values of M
* 3 4 values of N
* 6 10 values of M_A
* 6 10 values of N_A
* 2 5 values of IMB_A
* 2 5 values of INB_A
* 2 5 values of MB_A
* 2 5 values of NB_A
* 0 1 values of RSRC_A
* 0 0 values of CSRC_A
* 1 1 values of IA
* 1 1 values of JA
* 6 10 values of M_X
* 6 10 values of N_X
* 2 5 values of IMB_X
* 2 5 values of INB_X
* 2 5 values of MB_X
* 2 5 values of NB_X
* 0 1 values of RSRC_X
* 0 0 values of CSRC_X
* 1 1 values of IX
* 1 1 values of JX
* 1 1 values of INCX
* 6 10 values of M_Y
* 6 10 values of N_Y
* 2 5 values of IMB_Y
* 2 5 values of INB_Y
* 2 5 values of MB_Y
* 2 5 values of NB_Y
* 0 1 values of RSRC_Y
* 0 0 values of CSRC_Y
* 1 1 values of IY
* 1 1 values of JY
* 6 1 values of INCY
* PDGEMV T put F for no test in the same column
* PDSYMV T put F for no test in the same column
* PDTRMV T put F for no test in the same column
* PDTRSV T put F for no test in the same column
* PDGER T put F for no test in the same column
* PDSYR T put F for no test in the same column
* PDSYR2 T put F for no test in the same column
*
* Internal Parameters
* ===================
*
* TOTMEM INTEGER
* TOTMEM is a machine-specific parameter indicating the maxi-
* mum amount of available memory per process in bytes. The
* user should customize TOTMEM to his platform. Remember to
* leave room in memory for the operating system, the BLACS
* buffer, etc. For example, on a system with 8 MB of memory
* per process (e.g., one processor on an Intel iPSC/860), the
* parameters we use are TOTMEM=6200000 (leaving 1.8 MB for OS,
* code, BLACS buffer, etc). However, for PVM, we usually set
* TOTMEM = 2000000. Some experimenting with the maximum value
* of TOTMEM may be required. By default, TOTMEM is 2000000.
*
* DBLESZ INTEGER
* DBLESZ indicates the length in bytes on the given platform
* for a double precision real. By default, DBLESZ is set to
* eight.
*
* MEM DOUBLE PRECISION array
* MEM is an array of dimension TOTMEM / DBLESZ.
* All arrays used by SCALAPACK routines are allocated from this
* array MEM and referenced by pointers. The integer IPA, for
* example, is a pointer to the starting element of MEM for the
* matrix A.
*
* -- Written on April 1, 1998 by
* Antoine Petitet, University of Tennessee, Knoxville 37996, USA.
*
* =====================================================================
*
* .. Parameters ..
INTEGER MAXTESTS, MAXGRIDS, DBLESZ, TOTMEM, MEMSIZ,
$ NSUBS
DOUBLE PRECISION ONE
PARAMETER ( MAXTESTS = 20, MAXGRIDS = 20, DBLESZ = 8,
$ ONE = 1.0D+0, TOTMEM = 2000000, NSUBS = 7,
$ MEMSIZ = TOTMEM / DBLESZ )
INTEGER BLOCK_CYCLIC_2D_INB, CSRC_, CTXT_, DLEN_,
$ DTYPE_, IMB_, INB_, LLD_, MB_, M_, NB_, N_,
$ RSRC_
PARAMETER ( BLOCK_CYCLIC_2D_INB = 2, DLEN_ = 11,
$ DTYPE_ = 1, CTXT_ = 2, M_ = 3, N_ = 4,
$ IMB_ = 5, INB_ = 6, MB_ = 7, NB_ = 8,
$ RSRC_ = 9, CSRC_ = 10, LLD_ = 11 )
* ..
* .. Local Scalars ..
CHARACTER*1 AFORM, DIAG, DIAGDO, TRANS, UPLO
INTEGER CSRCA, CSRCX, CSRCY, I, IA, IAM, IASEED, ICTXT,
$ IMBA, IMBX, IMBY, IMIDA, IMIDX, IMIDY, INBA,
$ INBX, INBY, INCX, INCY, IPA, IPOSTA, IPOSTX,
$ IPOSTY, IPREA, IPREX, IPREY, IPX, IPY, IX,
$ IXSEED, IY, IYSEED, J, JA, JX, JY, K, M, MA,
$ MBA, MBX, MBY, MEMREQD, MPA, MPX, MPY, MX, MY,
$ MYCOL, MYROW, N, NA, NBA, NBX, NBY, NCOLA,
$ NGRIDS, NLX, NLY, NOUT, NPCOL, NPROCS, NPROW,
$ NQA, NQX, NQY, NROWA, NTESTS, NX, NY, OFFD,
$ RSRCA, RSRCX, RSRCY
DOUBLE PRECISION ALPHA, BETA, CFLOPS, NOPS, SCALE, WFLOPS
* ..
* .. Local Arrays ..
LOGICAL LTEST( NSUBS ), YCHECK( NSUBS )
CHARACTER*1 DIAGVAL( MAXTESTS ), TRANVAL( MAXTESTS ),
$ UPLOVAL( MAXTESTS )
CHARACTER*80 OUTFILE
INTEGER CSCAVAL( MAXTESTS ), CSCXVAL( MAXTESTS ),
$ CSCYVAL( MAXTESTS ), DESCA( DLEN_ ),
$ DESCX( DLEN_ ), DESCY( DLEN_ ),
$ IAVAL( MAXTESTS ), IERR( 3 ),
$ IMBAVAL( MAXTESTS ), IMBXVAL( MAXTESTS ),
$ IMBYVAL( MAXTESTS ), INBAVAL( MAXTESTS ),
$ INBXVAL( MAXTESTS ), INBYVAL( MAXTESTS ),
$ INCXVAL( MAXTESTS ), INCYVAL( MAXTESTS ),
$ IXVAL( MAXTESTS ), IYVAL( MAXTESTS ),
$ JAVAL( MAXTESTS ), JXVAL( MAXTESTS ),
$ JYVAL( MAXTESTS ), MAVAL( MAXTESTS ),
$ MBAVAL( MAXTESTS ), MBXVAL( MAXTESTS ),
$ MBYVAL( MAXTESTS ), MVAL( MAXTESTS ),
$ MXVAL( MAXTESTS ), MYVAL( MAXTESTS ),
$ NAVAL( MAXTESTS ), NBAVAL( MAXTESTS ),
$ NBXVAL( MAXTESTS ), NBYVAL( MAXTESTS ),
$ NVAL( MAXTESTS ), NXVAL( MAXTESTS ),
$ NYVAL( MAXTESTS ), PVAL( MAXTESTS ),
$ QVAL( MAXTESTS ), RSCAVAL( MAXTESTS ),
$ RSCXVAL( MAXTESTS ), RSCYVAL( MAXTESTS )
DOUBLE PRECISION CTIME( 1 ), MEM( MEMSIZ ), WTIME( 1 )
* ..
* .. External Subroutines ..
EXTERNAL BLACS_BARRIER, BLACS_EXIT, BLACS_GET,
$ BLACS_GRIDEXIT, BLACS_GRIDINFO, BLACS_GRIDINIT,
$ BLACS_PINFO, IGSUM2D, PB_BOOT, PB_COMBINE,
$ PB_TIMER, PDBLA2TIMINFO, PDGEMV, PDGER,
$ PDLAGEN, PDLASCAL, PDSYMV, PDSYR, PDSYR2,
$ PDTRMV, PDTRSV, PMDESCCHK, PMDIMCHK, PVDESCCHK,
$ PVDIMCHK
* ..
* .. External Functions ..
LOGICAL LSAME
DOUBLE PRECISION PDOPBL2
EXTERNAL LSAME, PDOPBL2
* ..
* .. Intrinsic Functions ..
INTRINSIC DBLE, MAX
* ..
* .. Common Blocks ..
CHARACTER*7 SNAMES( NSUBS )
LOGICAL ABRTFLG
INTEGER INFO, NBLOG
COMMON /SNAMEC/SNAMES
COMMON /INFOC/INFO, NBLOG
COMMON /PBERRORC/NOUT, ABRTFLG
* ..
* .. Data Statements ..
DATA SNAMES/'PDGEMV ', 'PDSYMV ', 'PDTRMV ',
$ 'PDTRSV ', 'PDGER ', 'PDSYR ',
$ 'PDSYR2 '/
DATA YCHECK/.TRUE., .TRUE., .FALSE., .FALSE.,
$ .TRUE., .FALSE., .TRUE./
* ..
* .. Executable Statements ..
*
* Initialization
*
* Set flag so that the PBLAS error handler won't abort on errors, so
* that the tester will detect unsupported operations.
*
ABRTFLG = .TRUE.
*
* Seeds for random matrix generations.
*
IASEED = 100
IXSEED = 200
IYSEED = 300
*
* Get starting information
*
CALL BLACS_PINFO( IAM, NPROCS )
CALL PDBLA2TIMINFO( OUTFILE, NOUT, NTESTS, DIAGVAL, TRANVAL,
$ UPLOVAL, MVAL, NVAL, MAVAL, NAVAL, IMBAVAL,
$ MBAVAL, INBAVAL, NBAVAL, RSCAVAL, CSCAVAL,
$ IAVAL, JAVAL, MXVAL, NXVAL, IMBXVAL, MBXVAL,
$ INBXVAL, NBXVAL, RSCXVAL, CSCXVAL, IXVAL,
$ JXVAL, INCXVAL, MYVAL, NYVAL, IMBYVAL,
$ MBYVAL, INBYVAL, NBYVAL, RSCYVAL,
$ CSCYVAL, IYVAL, JYVAL, INCYVAL, MAXTESTS,
$ NGRIDS, PVAL, MAXGRIDS, QVAL, MAXGRIDS,
$ NBLOG, LTEST, IAM, NPROCS, ALPHA, BETA, MEM )
*
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9983 )
*
* Loop over different process grids
*
DO 60 I = 1, NGRIDS
*
NPROW = PVAL( I )
NPCOL = QVAL( I )
*
* Make sure grid information is correct
*
IERR( 1 ) = 0
IF( NPROW.LT.1 ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9999 ) 'GRID SIZE', 'NPROW', NPROW
IERR( 1 ) = 1
ELSE IF( NPCOL.LT.1 ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9999 ) 'GRID SIZE', 'NPCOL', NPCOL
IERR( 1 ) = 1
ELSE IF( NPROW*NPCOL.GT.NPROCS ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9998 ) NPROW*NPCOL, NPROCS
IERR( 1 ) = 1
END IF
*
IF( IERR( 1 ).GT.0 ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9997 ) 'GRID'
GO TO 60
END IF
*
* Define process grid
*
CALL BLACS_GET( -1, 0, ICTXT )
CALL BLACS_GRIDINIT( ICTXT, 'Row-major', NPROW, NPCOL )
CALL BLACS_GRIDINFO( ICTXT, NPROW, NPCOL, MYROW, MYCOL )
*
* Go to bottom of process grid loop if this case doesn't use my
* process
*
IF( MYROW.GE.NPROW .OR. MYCOL.GE.NPCOL )
$ GO TO 60
*
* Loop over number of tests
*
DO 50 J = 1, NTESTS
*
* Get the test parameters
*
DIAG = DIAGVAL( J )
TRANS = TRANVAL( J )
UPLO = UPLOVAL( J )
*
M = MVAL( J )
N = NVAL( J )
*
MA = MAVAL( J )
NA = NAVAL( J )
IMBA = IMBAVAL( J )
MBA = MBAVAL( J )
INBA = INBAVAL( J )
NBA = NBAVAL( J )
RSRCA = RSCAVAL( J )
CSRCA = CSCAVAL( J )
IA = IAVAL( J )
JA = JAVAL( J )
*
MX = MXVAL( J )
NX = NXVAL( J )
IMBX = IMBXVAL( J )
MBX = MBXVAL( J )
INBX = INBXVAL( J )
NBX = NBXVAL( J )
RSRCX = RSCXVAL( J )
CSRCX = CSCXVAL( J )
IX = IXVAL( J )
JX = JXVAL( J )
INCX = INCXVAL( J )
*
MY = MYVAL( J )
NY = NYVAL( J )
IMBY = IMBYVAL( J )
MBY = MBYVAL( J )
INBY = INBYVAL( J )
NBY = NBYVAL( J )
RSRCY = RSCYVAL( J )
CSRCY = CSCYVAL( J )
IY = IYVAL( J )
JY = JYVAL( J )
INCY = INCYVAL( J )
*
IF( IAM.EQ.0 ) THEN
*
WRITE( NOUT, FMT = * )
WRITE( NOUT, FMT = 9996 ) J, NPROW, NPCOL
WRITE( NOUT, FMT = * )
*
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9994 )
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9993 ) M, N, UPLO, TRANS, DIAG
*
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9992 )
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9991 ) IA, JA, MA, NA, IMBA, INBA,
$ MBA, NBA, RSRCA, CSRCA
*
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9990 )
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9989 ) IX, JX, MX, NX, IMBX, INBX,
$ MBX, NBX, RSRCX, CSRCX, INCX
*
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9988 )
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9989 ) IY, JY, MY, NY, IMBY, INBY,
$ MBY, NBY, RSRCY, CSRCY, INCY
*
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = 9980 )
*
END IF
*
* Check the validity of the input test parameters
*
IF( .NOT.LSAME( UPLO, 'U' ).AND.
$ .NOT.LSAME( UPLO, 'L' ) ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9997 ) 'UPLO'
GO TO 40
END IF
*
IF( .NOT.LSAME( TRANS, 'N' ).AND.
$ .NOT.LSAME( TRANS, 'T' ).AND.
$ .NOT.LSAME( TRANS, 'C' ) ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9997 ) 'TRANS'
GO TO 40
END IF
*
IF( .NOT.LSAME( DIAG , 'U' ).AND.
$ .NOT.LSAME( DIAG , 'N' ) )THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9997 ) TRANS
WRITE( NOUT, FMT = 9997 ) 'DIAG'
GO TO 40
END IF
*
* Check and initialize the matrix descriptors
*
CALL PMDESCCHK( ICTXT, NOUT, 'A', DESCA,
$ BLOCK_CYCLIC_2D_INB, MA, NA, IMBA, INBA,
$ MBA, NBA, RSRCA, CSRCA, MPA, NQA, IPREA,
$ IMIDA, IPOSTA, 0, 0, IERR( 1 ) )
CALL PVDESCCHK( ICTXT, NOUT, 'X', DESCX,
$ BLOCK_CYCLIC_2D_INB, MX, NX, IMBX, INBX,
$ MBX, NBX, RSRCX, CSRCX, INCX, MPX, NQX,
$ IPREX, IMIDX, IPOSTX, 0, 0, IERR( 2 ) )
CALL PVDESCCHK( ICTXT, NOUT, 'Y', DESCY,
$ BLOCK_CYCLIC_2D_INB, MY, NY, IMBY, INBY,
$ MBY, NBY, RSRCY, CSRCY, INCY, MPY, NQY,
$ IPREY, IMIDY, IPOSTY, 0, 0, IERR( 3 ) )
*
IF( IERR( 1 ).GT.0 .OR. IERR( 2 ).GT.0 .OR.
$ IERR( 3 ).GT.0 ) THEN
GO TO 40
END IF
*
* Assign pointers into MEM for matrices corresponding to
* the distributed matrices A, X and Y.
*
IPA = 1
IPX = IPA + DESCA( LLD_ ) * NQA
IPY = IPX + DESCX( LLD_ ) * NQX
*
* Check if sufficient memory.
*
MEMREQD = IPY + DESCY( LLD_ ) * NQY - 1
IERR( 1 ) = 0
IF( MEMREQD.GT.MEMSIZ ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9986 ) MEMREQD*DBLESZ
IERR( 1 ) = 1
END IF
*
* Check all processes for an error
*
CALL IGSUM2D( ICTXT, 'All', ' ', 1, 1, IERR, 1, -1, 0 )
*
IF( IERR( 1 ).GT.0 ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9987 )
GO TO 40
END IF
*
* Loop over all PBLAS 2 routines
*
DO 30 K = 1, NSUBS
*
* Continue only if this subroutine has to be tested.
*
IF( .NOT.LTEST( K ) )
$ GO TO 30
*
* Define the size of the operands
*
IF( K.EQ.1 ) THEN
NROWA = M
NCOLA = N
IF( LSAME( TRANS, 'N' ) ) THEN
NLX = N
NLY = M
ELSE
NLX = M
NLY = N
END IF
ELSE IF( K.EQ.5 ) THEN
NROWA = M
NCOLA = N
NLX = M
NLY = N
ELSE
NROWA = N
NCOLA = N
NLX = N
NLY = N
END IF
*
* Check the validity of the operand sizes
*
CALL PMDIMCHK( ICTXT, NOUT, NROWA, NCOLA, 'A', IA, JA,
$ DESCA, IERR( 1 ) )
CALL PVDIMCHK( ICTXT, NOUT, NLX, 'X', IX, JX, DESCX,
$ INCX, IERR( 2 ) )
CALL PVDIMCHK( ICTXT, NOUT, NLY, 'Y', IY, JY, DESCY,
$ INCY, IERR( 3 ) )
*
IF( IERR( 1 ).NE.0 .OR. IERR( 2 ).NE.0 .OR.
$ IERR( 3 ).NE.0 ) THEN
GO TO 30
END IF
*
* Generate distributed matrices A, X and Y
*
IF( K.EQ.2 .OR. K.EQ.6 .OR. K.EQ.7 ) THEN
AFORM = 'S'
DIAGDO = 'N'
OFFD = IA - JA
ELSE IF( ( K.EQ.4 ).AND.( LSAME( DIAG, 'N' ) ) ) THEN
AFORM = 'N'
DIAGDO = 'D'
OFFD = IA - JA
ELSE
AFORM = 'N'
DIAGDO = 'N'
OFFD = 0
END IF
*
CALL PDLAGEN( .FALSE., AFORM, DIAGDO, OFFD, MA, NA,
$ 1, 1, DESCA, IASEED, MEM( IPA ),
$ DESCA( LLD_ ) )
CALL PDLAGEN( .FALSE., 'None', 'No diag', 0, MX, NX,
$ 1, 1, DESCX, IXSEED, MEM( IPX ),
$ DESCX( LLD_ ) )
IF( YCHECK( K ) )
$ CALL PDLAGEN( .FALSE., 'None', 'No diag', 0, MY,
$ NY, 1, 1, DESCY, IYSEED, MEM( IPY ),
$ DESCY( LLD_ ) )
*
IF( ( K.EQ.4 ).AND.( .NOT.( LSAME( DIAG, 'N' ) ) ).AND.
$ ( MAX( NROWA, NCOLA ).GT.1 ) ) THEN
SCALE = ONE / DBLE( MAX( NROWA, NCOLA ) )
IF( LSAME( UPLO, 'L' ) ) THEN
CALL PDLASCAL( 'Lower', NROWA-1, NCOLA-1, SCALE,
$ MEM( IPA ), IA+1, JA, DESCA )
ELSE
CALL PDLASCAL( 'Upper', NROWA-1, NCOLA-1, SCALE,
$ MEM( IPA ), IA, JA+1, DESCA )
END IF
END IF
*
INFO = 0
CALL PB_BOOT()
CALL BLACS_BARRIER( ICTXT, 'All' )
*
* Call the Level 2 PBLAS routine
*
IF( K.EQ.1 ) THEN
*
* Test PDGEMV
*
CALL PB_TIMER( 1 )
CALL PDGEMV( TRANS, M, N, ALPHA, MEM( IPA ), IA, JA,
$ DESCA, MEM( IPX ), IX, JX, DESCX, INCX,
$ BETA, MEM( IPY ), IY, JY, DESCY, INCY )
CALL PB_TIMER( 1 )
*
ELSE IF( K.EQ.2 ) THEN
*
* Test PDSYMV
*
CALL PB_TIMER( 1 )
CALL PDSYMV( UPLO, N, ALPHA, MEM( IPA ), IA, JA,
$ DESCA, MEM( IPX ), IX, JX, DESCX, INCX,
$ BETA, MEM( IPY ), IY, JY, DESCY, INCY )
CALL PB_TIMER( 1 )
*
ELSE IF( K.EQ.3 ) THEN
*
* Test PDTRMV
*
CALL PB_TIMER( 1 )
CALL PDTRMV( UPLO, TRANS, DIAG, N, MEM( IPA ), IA, JA,
$ DESCA, MEM( IPX ), IX, JX, DESCX, INCX )
CALL PB_TIMER( 1 )
*
ELSE IF( K.EQ.4 ) THEN
*
* Test PDTRSV
*
CALL PB_TIMER( 1 )
CALL PDTRSV( UPLO, TRANS, DIAG, N, MEM( IPA ), IA, JA,
$ DESCA, MEM( IPX ), IX, JX, DESCX, INCX )
CALL PB_TIMER( 1 )
*
ELSE IF( K.EQ.5 ) THEN
*
* Test PDGER
*
CALL PB_TIMER( 1 )
CALL PDGER( M, N, ALPHA, MEM( IPX ), IX, JX, DESCX,
$ INCX, MEM( IPY ), IY, JY, DESCY, INCY,
$ MEM( IPA ), IA, JA, DESCA )
CALL PB_TIMER( 1 )
*
ELSE IF( K.EQ.6 ) THEN
*
* Test PDSYR
*
CALL PB_TIMER( 1 )
CALL PDSYR( UPLO, N, ALPHA, MEM( IPX ), IX, JX, DESCX,
$ INCX, MEM( IPA ), IA, JA, DESCA )
CALL PB_TIMER( 1 )
*
ELSE IF( K.EQ.7 ) THEN
*
* Test PDSYR2
*
CALL PB_TIMER( 1 )
CALL PDSYR2( UPLO, N, ALPHA, MEM( IPX ), IX, JX,
$ DESCX, INCX, MEM( IPY ), IY, JY, DESCY,
$ INCY, MEM( IPA ), IA, JA, DESCA )
CALL PB_TIMER( 1 )
*
END IF
*
* Check if the operation has been performed.
*
IF( INFO.NE.0 ) THEN
IF( IAM.EQ.0 )
$ WRITE( NOUT, FMT = 9982 ) INFO
GO TO 30
END IF
*
CALL PB_COMBINE( ICTXT, 'All', '>', 'W', 1, 1, WTIME )
CALL PB_COMBINE( ICTXT, 'All', '>', 'C', 1, 1, CTIME )
*
* Only node 0 prints timing test result
*
IF( IAM.EQ.0 ) THEN
*
* Calculate total flops
*
NOPS = PDOPBL2( SNAMES( K ), NROWA, NCOLA, 0, 0 )
*
* Print WALL time if machine supports it
*
IF( WTIME( 1 ).GT.0.0D+0 ) THEN
WFLOPS = NOPS / ( WTIME( 1 ) * 1.0D+6 )
ELSE
WFLOPS = 0.0D+0
END IF
*
* Print CPU time if machine supports it
*
IF( CTIME( 1 ).GT.0.0D+0 ) THEN
CFLOPS = NOPS / ( CTIME( 1 ) * 1.0D+6 )
ELSE
CFLOPS = 0.0D+0
END IF
*
WRITE( NOUT, FMT = 9981 ) SNAMES( K ), WTIME( 1 ),
$ WFLOPS, CTIME( 1 ), CFLOPS
*
END IF
*
30 CONTINUE
*
40 IF( IAM.EQ.0 ) THEN
WRITE( NOUT, FMT = 9995 )
WRITE( NOUT, FMT = * )
WRITE( NOUT, FMT = 9985 ) J
END IF
*
50 CONTINUE
*
CALL BLACS_GRIDEXIT( ICTXT )
*
60 CONTINUE
*
* Print results
*
IF( IAM.EQ.0 ) THEN
WRITE( NOUT, FMT = * )
WRITE( NOUT, FMT = 9984 )
WRITE( NOUT, FMT = * )
END IF
*
CALL BLACS_EXIT( 0 )
*
9999 FORMAT( 'ILLEGAL ', A, ': ', A, ' = ', I10,
$ ' should be at least 1' )
9998 FORMAT( 'ILLEGAL GRID: NPROW*NPCOL = ', I4,
$ '. It can be at most', I4 )
9997 FORMAT( 'Bad ', A, ' parameters: going on to next test case.' )
9996 FORMAT( 2X, 'Test number ', I2 , ' started on a ', I4, ' x ',
$ I4, ' process grid.' )
9995 FORMAT( 2X, ' ------------------------------------------------',
$ '--------------------------' )
9994 FORMAT( 2X, ' M N UPLO TRANS DIAG' )
9993 FORMAT( 5X,I6,1X,I6,9X,A1,11X,A1,10X,A1 )
9992 FORMAT( 2X, ' IA JA MA NA IMBA INBA',
$ ' MBA NBA RSRCA CSRCA' )
9991 FORMAT( 5X,I6,1X,I6,1X,I6,1X,I6,1X,I6,1X,I6,1X,I6,1X,I6,
$ 1X,I5,1X,I5 )
9990 FORMAT( 2X, ' IX JX MX NX IMBX INBX',
$ ' MBX NBX RSRCX CSRCX INCX' )
9989 FORMAT( 5X,I6,1X,I6,1X,I6,1X,I6,1X,I6,1X,I6,1X,I6,1X,I6,
$ 1X,I5,1X,I5,1X,I6 )
9988 FORMAT( 2X, ' IY JY MY NY IMBY INBY',
$ ' MBY NBY RSRCY CSRCY INCY' )
9987 FORMAT( 'Not enough memory for this test: going on to',
$ ' next test case.' )
9986 FORMAT( 'Not enough memory. Need: ', I12 )
9985 FORMAT( 2X, 'Test number ', I2, ' completed.' )
9984 FORMAT( 2X, 'End of Tests.' )
9983 FORMAT( 2X, 'Tests started.' )
9982 FORMAT( 2X, ' ***** Operation not supported, error code: ',
$ I5, ' *****' )
9981 FORMAT( 2X, '| ', A, 2X, F13.3, 2X, F13.3, 2X, F13.3, 2X, F13.3 )
9980 FORMAT( 2X, ' WALL time (s) WALL Mflops ',
$ ' CPU time (s) CPU Mflops' )
*
STOP
*
* End of PDBLA2TIM
*
END
SUBROUTINE PDBLA2TIMINFO( SUMMRY, NOUT, NMAT, DIAGVAL, TRANVAL,
$ UPLOVAL, MVAL, NVAL, MAVAL, NAVAL,
$ IMBAVAL, MBAVAL, INBAVAL, NBAVAL,
$ RSCAVAL, CSCAVAL, IAVAL, JAVAL,
$ MXVAL, NXVAL, IMBXVAL, MBXVAL,
$ INBXVAL, NBXVAL, RSCXVAL, CSCXVAL,
$ IXVAL, JXVAL, INCXVAL, MYVAL, NYVAL,
$ IMBYVAL, MBYVAL, INBYVAL, NBYVAL,
$ RSCYVAL, CSCYVAL, IYVAL, JYVAL,
$ INCYVAL, LDVAL, NGRIDS, PVAL, LDPVAL,
$ QVAL, LDQVAL, NBLOG, LTEST, IAM, NPROCS,
$ ALPHA, BETA, WORK )
*
* -- PBLAS test routine (version 2.0) --
* University of Tennessee, Knoxville, Oak Ridge National Laboratory,
* and University of California, Berkeley.
* April 1, 1998
*
* .. Scalar Arguments ..
INTEGER IAM, LDPVAL, LDQVAL, LDVAL, NBLOG, NGRIDS,
$ NMAT, NOUT, NPROCS
DOUBLE PRECISION ALPHA, BETA
* ..
* .. Array Arguments ..
CHARACTER*( * ) SUMMRY
CHARACTER*1 DIAGVAL( LDVAL ), TRANVAL( LDVAL ),
$ UPLOVAL( LDVAL )
LOGICAL LTEST( * )
INTEGER CSCAVAL( LDVAL ), CSCXVAL( LDVAL ),
$ CSCYVAL( LDVAL ), IAVAL( LDVAL ),
$ IMBAVAL( LDVAL ), IMBXVAL( LDVAL ),
$ IMBYVAL( LDVAL ), INBAVAL( LDVAL ),
$ INBXVAL( LDVAL ), INBYVAL( LDVAL ),
$ INCXVAL( LDVAL ), INCYVAL( LDVAL ),
$ IXVAL( LDVAL ), IYVAL( LDVAL ), JAVAL( LDVAL ),
$ JXVAL( LDVAL ), JYVAL( LDVAL ), MAVAL( LDVAL ),
$ MBAVAL( LDVAL ), MBXVAL( LDVAL ),
$ MBYVAL( LDVAL ), MVAL( LDVAL ), MXVAL( LDVAL ),
$ MYVAL( LDVAL ), NAVAL( LDVAL ),
$ NBAVAL( LDVAL ), NBXVAL( LDVAL ),
$ NBYVAL( LDVAL ), NVAL( LDVAL ), NXVAL( LDVAL ),
$ NYVAL( LDVAL ), PVAL( LDPVAL ), QVAL( LDQVAL ),
$ RSCAVAL( LDVAL ), RSCXVAL( LDVAL ),
$ RSCYVAL( LDVAL ), WORK( * )
* ..
*
* Purpose
* =======
*
* PDBLA2TIMINFO get the needed startup information for timing various
* Level 2 PBLAS routines, and transmits it to all processes.
*
* Notes
* =====
*
* For packing the information we assumed that the length in bytes of an
* integer is equal to the length in bytes of a real single precision.
*
* Arguments
* =========
*
* SUMMRY (global output) CHARACTER*(*)
* On exit, SUMMRY is the name of output (summary) file (if
* any). SUMMRY is only defined for process 0.
*
* NOUT (global output) INTEGER
* On exit, NOUT specifies the unit number for the output file.
* When NOUT is 6, output to screen, when NOUT is 0, output to
* stderr. NOUT is only defined for process 0.
*
* NMAT (global output) INTEGER
* On exit, NMAT specifies the number of different test cases.
*
* DIAGVAL (global output) CHARACTER array
* On entry, DIAGVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DIAG to run the code with.
*
* TRANVAL (global output) CHARACTER array
* On entry, TRANVAL is an array of dimension LDVAL. On exit,
* this array contains the values of TRANS to run the code
* with.
*
* UPLOVAL (global output) CHARACTER array
* On entry, UPLOVAL is an array of dimension LDVAL. On exit,
* this array contains the values of UPLO to run the code with.
*
* MVAL (global output) INTEGER array
* On entry, MVAL is an array of dimension LDVAL. On exit, this
* array contains the values of M to run the code with.
*
* NVAL (global output) INTEGER array
* On entry, NVAL is an array of dimension LDVAL. On exit, this
* array contains the values of N to run the code with.
*
* MAVAL (global output) INTEGER array
* On entry, MAVAL is an array of dimension LDVAL. On exit, this
* array contains the values of DESCA( M_ ) to run the code
* with.
*
* NAVAL (global output) INTEGER array
* On entry, NAVAL is an array of dimension LDVAL. On exit, this
* array contains the values of DESCA( N_ ) to run the code
* with.
*
* IMBAVAL (global output) INTEGER array
* On entry, IMBAVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCA( IMB_ ) to run the
* code with.
*
* MBAVAL (global output) INTEGER array
* On entry, MBAVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCA( MB_ ) to run the
* code with.
*
* INBAVAL (global output) INTEGER array
* On entry, INBAVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCA( INB_ ) to run the
* code with.
*
* NBAVAL (global output) INTEGER array
* On entry, NBAVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCA( NB_ ) to run the
* code with.
*
* RSCAVAL (global output) INTEGER array
* On entry, RSCAVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCA( RSRC_ ) to run the
* code with.
*
* CSCAVAL (global output) INTEGER array
* On entry, CSCAVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCA( CSRC_ ) to run the
* code with.
*
* IAVAL (global output) INTEGER array
* On entry, IAVAL is an array of dimension LDVAL. On exit, this
* array contains the values of IA to run the code with.
*
* JAVAL (global output) INTEGER array
* On entry, JAVAL is an array of dimension LDVAL. On exit, this
* array contains the values of JA to run the code with.
*
* MXVAL (global output) INTEGER array
* On entry, MXVAL is an array of dimension LDVAL. On exit, this
* array contains the values of DESCX( M_ ) to run the code
* with.
*
* NXVAL (global output) INTEGER array
* On entry, NXVAL is an array of dimension LDVAL. On exit, this
* array contains the values of DESCX( N_ ) to run the code
* with.
*
* IMBXVAL (global output) INTEGER array
* On entry, IMBXVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCX( IMB_ ) to run the
* code with.
*
* MBXVAL (global output) INTEGER array
* On entry, MBXVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCX( MB_ ) to run the
* code with.
*
* INBXVAL (global output) INTEGER array
* On entry, INBXVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCX( INB_ ) to run the
* code with.
*
* NBXVAL (global output) INTEGER array
* On entry, NBXVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCX( NB_ ) to run the
* code with.
*
* RSCXVAL (global output) INTEGER array
* On entry, RSCXVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCX( RSRC_ ) to run the
* code with.
*
* CSCXVAL (global output) INTEGER array
* On entry, CSCXVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCX( CSRC_ ) to run the
* code with.
*
* IXVAL (global output) INTEGER array
* On entry, IXVAL is an array of dimension LDVAL. On exit, this
* array contains the values of IX to run the code with.
*
* JXVAL (global output) INTEGER array
* On entry, JXVAL is an array of dimension LDVAL. On exit, this
* array contains the values of JX to run the code with.
*
* INCXVAL (global output) INTEGER array
* On entry, INCXVAL is an array of dimension LDVAL. On exit,
* this array contains the values of INCX to run the code with.
*
* MYVAL (global output) INTEGER array
* On entry, MYVAL is an array of dimension LDVAL. On exit, this
* array contains the values of DESCY( M_ ) to run the code
* with.
*
* NYVAL (global output) INTEGER array
* On entry, NYVAL is an array of dimension LDVAL. On exit, this
* array contains the values of DESCY( N_ ) to run the code
* with.
*
* IMBYVAL (global output) INTEGER array
* On entry, IMBYVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCY( IMB_ ) to run the
* code with.
*
* MBYVAL (global output) INTEGER array
* On entry, MBYVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCY( MB_ ) to run the
* code with.
*
* INBYVAL (global output) INTEGER array
* On entry, INBYVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCY( INB_ ) to run the
* code with.
*
* NBYVAL (global output) INTEGER array
* On entry, NBYVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCY( NB_ ) to run the
* code with.
*
* RSCYVAL (global output) INTEGER array
* On entry, RSCYVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCY( RSRC_ ) to run the
* code with.
*
* CSCYVAL (global output) INTEGER array
* On entry, CSCYVAL is an array of dimension LDVAL. On exit,
* this array contains the values of DESCY( CSRC_ ) to run the
* code with.
*
* IYVAL (global output) INTEGER array
* On entry, IYVAL is an array of dimension LDVAL. On exit, this
* array contains the values of IY to run the code with.
*
* JYVAL (global output) INTEGER array
* On entry, JYVAL is an array of dimension LDVAL. On exit, this
* array contains the values of JY to run the code with.
*
* INCYVAL (global output) INTEGER array
* On entry, INCYVAL is an array of dimension LDVAL. On exit,
* this array contains the values of INCY to run the code with.
*
* LDVAL (global input) INTEGER
* On entry, LDVAL specifies the maximum number of different va-
* lues that can be used for DIAG, TRANS, UPLO, M, N, DESCA(:),
* IA, JA, DESCX(:), IX, JX, INCX, DESCY(:), IY, JY and INCY.
* This is also the maximum number of test cases.
*
* NGRIDS (global output) INTEGER
* On exit, NGRIDS specifies the number of different values that
* can be used for P and Q.
*
* PVAL (global output) INTEGER array
* On entry, PVAL is an array of dimension LDPVAL. On exit, this
* array contains the values of P to run the code with.
*
* LDPVAL (global input) INTEGER
* On entry, LDPVAL specifies the maximum number of different
* values that can be used for P.
*
* QVAL (global output) INTEGER array
* On entry, QVAL is an array of dimension LDQVAL. On exit, this
* array contains the values of Q to run the code with.
*
* LDQVAL (global input) INTEGER
* On entry, LDQVAL specifies the maximum number of different
* values that can be used for Q.
*
* NBLOG (global output) INTEGER
* On exit, NBLOG specifies the logical computational block size
* to run the tests with. NBLOG must be at least one.
*
* LTEST (global output) LOGICAL array
* On entry, LTEST is an array of dimension at least seven. On
* exit, if LTEST( i ) is .TRUE., the i-th Level 2 PBLAS routine
* will be tested. See the input file for the ordering of the
* routines.
*
* IAM (local input) INTEGER
* On entry, IAM specifies the number of the process executing
* this routine.
*
* NPROCS (global input) INTEGER
* On entry, NPROCS specifies the total number of processes.
*
* ALPHA (global output) DOUBLE PRECISION
* On exit, ALPHA specifies the value of alpha to be used in all
* the test cases.
*
* BETA (global output) DOUBLE PRECISION
* On exit, BETA specifies the value of beta to be used in all
* the test cases.
*
* WORK (local workspace) INTEGER array
* On entry, WORK is an array of dimension at least
* MAX( 3, 2*NGRIDS+37*NMAT+NSUBS ) with NSUBS = 7. This array
* is used to pack all output arrays in order to send info in
* one message.
*
* -- Written on April 1, 1998 by
* Antoine Petitet, University of Tennessee, Knoxville 37996, USA.
*
* =====================================================================
*
* .. Parameters ..
INTEGER NIN, NSUBS
PARAMETER ( NIN = 11, NSUBS = 7 )
* ..
* .. Local Scalars ..
LOGICAL LTESTT
INTEGER I, ICTXT, J
* ..
* .. Local Arrays ..
CHARACTER*7 SNAMET
CHARACTER*79 USRINFO
* ..
* .. External Subroutines ..
EXTERNAL BLACS_ABORT, BLACS_GET, BLACS_GRIDEXIT,
$ BLACS_GRIDINIT, BLACS_SETUP, DGEBR2D, DGEBS2D,
$ ICOPY, IGEBR2D, IGEBS2D, SGEBR2D, SGEBS2D
* ..
* .. Intrinsic Functions ..
INTRINSIC CHAR, ICHAR, MAX, MIN
* ..
* .. Common Blocks ..
CHARACTER*7 SNAMES( NSUBS )
COMMON /SNAMEC/SNAMES
* ..
* .. Executable Statements ..
*
* Process 0 reads the input data, broadcasts to other processes and
* writes needed information to NOUT
*
IF( IAM.EQ.0 ) THEN
*
* Open file and skip data file header
*
OPEN( NIN, FILE='PDBLAS2TIM.dat', STATUS='OLD' )
READ( NIN, FMT = * ) SUMMRY
SUMMRY = ' '
*
* Read in user-supplied info about machine type, compiler, etc.
*
READ( NIN, FMT = 9999 ) USRINFO
*
* Read name and unit number for summary output file
*
READ( NIN, FMT = * ) SUMMRY
READ( NIN, FMT = * ) NOUT
IF( NOUT.NE.0 .AND. NOUT.NE.6 )
$ OPEN( NOUT, FILE = SUMMRY, STATUS = 'UNKNOWN' )
*
* Read and check the parameter values for the tests.
*
* Get logical computational block size
*
READ( NIN, FMT = * ) NBLOG
IF( NBLOG.LT.1 )
$ NBLOG = 32
*
* Get number of grids
*
READ( NIN, FMT = * ) NGRIDS
IF( NGRIDS.LT.1 .OR. NGRIDS.GT.LDPVAL ) THEN
WRITE( NOUT, FMT = 9998 ) 'Grids', LDPVAL
GO TO 120
ELSE IF( NGRIDS.GT.LDQVAL ) THEN
WRITE( NOUT, FMT = 9998 ) 'Grids', LDQVAL
GO TO 120
END IF
*
* Get values of P and Q
*
READ( NIN, FMT = * ) ( PVAL( I ), I = 1, NGRIDS )
READ( NIN, FMT = * ) ( QVAL( I ), I = 1, NGRIDS )
*
* Read ALPHA, BETA
*
READ( NIN, FMT = * ) ALPHA
READ( NIN, FMT = * ) BETA
*
* Read number of tests.
*
READ( NIN, FMT = * ) NMAT
IF( NMAT.LT.1 .OR. NMAT.GT.LDVAL ) THEN
WRITE( NOUT, FMT = 9998 ) 'Tests', LDVAL
GO TO 120
END IF
*
* Read in input data into arrays.
*
READ( NIN, FMT = * ) ( UPLOVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( TRANVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( DIAGVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( MVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( NVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( MAVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( NAVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( IMBAVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( INBAVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( MBAVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( NBAVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( RSCAVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( CSCAVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( IAVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( JAVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( MXVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( NXVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( IMBXVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( INBXVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( MBXVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( NBXVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( RSCXVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( CSCXVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( IXVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( JXVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( INCXVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( MYVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( NYVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( IMBYVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( INBYVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( MBYVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( NBYVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( RSCYVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( CSCYVAL( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( IYVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( JYVAL ( I ), I = 1, NMAT )
READ( NIN, FMT = * ) ( INCYVAL( I ), I = 1, NMAT )
*
* Read names of subroutines and flags which indicate
* whether they are to be tested.
*
DO 10 I = 1, NSUBS
LTEST( I ) = .FALSE.
10 CONTINUE
20 CONTINUE
READ( NIN, FMT = 9996, END = 50 ) SNAMET, LTESTT
DO 30 I = 1, NSUBS
IF( SNAMET.EQ.SNAMES( I ) )
$ GO TO 40
30 CONTINUE
*
WRITE( NOUT, FMT = 9995 )SNAMET
GO TO 120
*
40 CONTINUE
LTEST( I ) = LTESTT
GO TO 20
*
50 CONTINUE
*
* Close input file
*
CLOSE ( NIN )
*
* For pvm only: if virtual machine not set up, allocate it and
* spawn the correct number of processes.
*
IF( NPROCS.LT.1 ) THEN
NPROCS = 0
DO 60 I = 1, NGRIDS
NPROCS = MAX( NPROCS, PVAL( I )*QVAL( I ) )
60 CONTINUE
CALL BLACS_SETUP( IAM, NPROCS )
END IF
*
* Temporarily define blacs grid to include all processes so
* information can be broadcast to all processes
*
CALL BLACS_GET( -1, 0, ICTXT )
CALL BLACS_GRIDINIT( ICTXT, 'Row-major', 1, NPROCS )
*
* Pack information arrays and broadcast
*
CALL DGEBS2D( ICTXT, 'All', ' ', 1, 1, ALPHA, 1 )
CALL DGEBS2D( ICTXT, 'All', ' ', 1, 1, BETA, 1 )
*
WORK( 1 ) = NGRIDS
WORK( 2 ) = NMAT
WORK( 3 ) = NBLOG
CALL IGEBS2D( ICTXT, 'All', ' ', 3, 1, WORK, 3 )
*
I = 1
DO 70 J = 1, NMAT
WORK( I ) = ICHAR( DIAGVAL( J ) )
WORK( I+1 ) = ICHAR( TRANVAL( J ) )
WORK( I+2 ) = ICHAR( UPLOVAL( J ) )
I = I + 3
70 CONTINUE
CALL ICOPY( NGRIDS, PVAL, 1, WORK( I ), 1 )
I = I + NGRIDS
CALL ICOPY( NGRIDS, QVAL, 1, WORK( I ), 1 )
I = I + NGRIDS
CALL ICOPY( NMAT, MVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, NVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, MAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, NAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, IMBAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, INBAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, MBAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, NBAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, RSCAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, CSCAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, IAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, JAVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, MXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, NXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, IMBXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, INBXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, MBXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, NBXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, RSCXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, CSCXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, IXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, JXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, INCXVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, MYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, NYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, IMBYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, INBYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, MBYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, NBYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, RSCYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, CSCYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, IYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, JYVAL, 1, WORK( I ), 1 )
I = I + NMAT
CALL ICOPY( NMAT, INCYVAL, 1, WORK( I ), 1 )
I = I + NMAT
*
DO 80 J = 1, NSUBS
IF( LTEST( J ) ) THEN
WORK( I ) = 1
ELSE
WORK( I ) = 0
END IF
I = I + 1
80 CONTINUE
I = I - 1
CALL IGEBS2D( ICTXT, 'All', ' ', I, 1, WORK, I )
*
* regurgitate input
*
WRITE( NOUT, FMT = 9999 )
$ 'Level 2 PBLAS timing program.'
WRITE( NOUT, FMT = 9999 ) USRINFO
WRITE( NOUT, FMT = * )
WRITE( NOUT, FMT = 9999 )
$ 'Tests of the real double precision '//
$ 'Level 2 PBLAS'
WRITE( NOUT, FMT = * )
WRITE( NOUT, FMT = 9992 ) NMAT
WRITE( NOUT, FMT = 9986 ) NBLOG
WRITE( NOUT, FMT = 9991 ) NGRIDS
WRITE( NOUT, FMT = 9989 )
$ 'P', ( PVAL(I), I = 1, MIN(NGRIDS, 5) )
IF( NGRIDS.GT.5 )
$ WRITE( NOUT, FMT = 9990 ) ( PVAL(I), I = 6,
$ MIN( 10, NGRIDS ) )
IF( NGRIDS.GT.10 )
$ WRITE( NOUT, FMT = 9990 ) ( PVAL(I), I = 11,
$ MIN( 15, NGRIDS ) )
IF( NGRIDS.GT.15 )
$ WRITE( NOUT, FMT = 9990 ) ( PVAL(I), I = 16, NGRIDS )
WRITE( NOUT, FMT = 9989 )
$ 'Q', ( QVAL(I), I = 1, MIN(NGRIDS, 5) )
IF( NGRIDS.GT.5 )
$ WRITE( NOUT, FMT = 9990 ) ( QVAL(I), I = 6,
$ MIN( 10, NGRIDS ) )
IF( NGRIDS.GT.10 )
$ WRITE( NOUT, FMT = 9990 ) ( QVAL(I), I = 11,
$ MIN( 15, NGRIDS ) )
IF( NGRIDS.GT.15 )
$ WRITE( NOUT, FMT = 9990 ) ( QVAL(I), I = 16, NGRIDS )
WRITE( NOUT, FMT = 9994 ) ALPHA
WRITE( NOUT, FMT = 9993 ) BETA
IF( LTEST( 1 ) ) THEN
WRITE( NOUT, FMT = 9988 ) SNAMES( 1 ), ' ... Yes'
ELSE
WRITE( NOUT, FMT = 9988 ) SNAMES( 1 ), ' ... No '
END IF
DO 90 I = 1, NSUBS
IF( LTEST( I ) ) THEN
WRITE( NOUT, FMT = 9987 ) SNAMES( I ), ' ... Yes'
ELSE
WRITE( NOUT, FMT = 9987 ) SNAMES( I ), ' ... No '
END IF
90 CONTINUE
WRITE( NOUT, FMT = * )
*
ELSE
*
* If in pvm, must participate setting up virtual machine
*
IF( NPROCS.LT.1 )
$ CALL BLACS_SETUP( IAM, NPROCS )
*
* Temporarily define blacs grid to include all processes so
* information can be broadcast to all processes
*
CALL BLACS_GET( -1, 0, ICTXT )
CALL BLACS_GRIDINIT( ICTXT, 'Row-major', 1, NPROCS )
*
CALL DGEBR2D( ICTXT, 'All', ' ', 1, 1, ALPHA, 1, 0, 0 )
CALL DGEBR2D( ICTXT, 'All', ' ', 1, 1, BETA, 1, 0, 0 )
*
CALL IGEBR2D( ICTXT, 'All', ' ', 3, 1, WORK, 3, 0, 0 )
NGRIDS = WORK( 1 )
NMAT = WORK( 2 )
NBLOG = WORK( 3 )
*
I = 2*NGRIDS + 37*NMAT + NSUBS
CALL IGEBR2D( ICTXT, 'All', ' ', I, 1, WORK, I, 0, 0 )
*
I = 1
DO 100 J = 1, NMAT
DIAGVAL( J ) = CHAR( WORK( I ) )
TRANVAL( J ) = CHAR( WORK( I+1 ) )
UPLOVAL( J ) = CHAR( WORK( I+2 ) )
I = I + 3
100 CONTINUE
CALL ICOPY( NGRIDS, WORK( I ), 1, PVAL, 1 )
I = I + NGRIDS
CALL ICOPY( NGRIDS, WORK( I ), 1, QVAL, 1 )
I = I + NGRIDS
CALL ICOPY( NMAT, WORK( I ), 1, MVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, NVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, MAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, NAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, IMBAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, INBAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, MBAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, NBAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, RSCAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, CSCAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, IAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, JAVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, MXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, NXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, IMBXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, INBXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, MBXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, NBXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, RSCXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, CSCXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, IXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, JXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, INCXVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, MYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, NYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, IMBYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, INBYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, MBYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, NBYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, RSCYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, CSCYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, IYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, JYVAL, 1 )
I = I + NMAT
CALL ICOPY( NMAT, WORK( I ), 1, INCYVAL, 1 )
I = I + NMAT
*
DO 110 J = 1, NSUBS
IF( WORK( I ).EQ.1 ) THEN
LTEST( J ) = .TRUE.
ELSE
LTEST( J ) = .FALSE.
END IF
I = I + 1
110 CONTINUE
*
END IF
*
CALL BLACS_GRIDEXIT( ICTXT )
*
RETURN
*
120 WRITE( NOUT, FMT = 9997 )
CLOSE( NIN )
IF( NOUT.NE.6 .AND. NOUT.NE.0 )
$ CLOSE( NOUT )
CALL BLACS_ABORT( ICTXT, 1 )
*
STOP
*
9999 FORMAT( A )
9998 FORMAT( ' Number of values of ',5A, ' is less than 1 or greater ',
$ 'than ', I2 )
9997 FORMAT( ' Illegal input in file ',40A,'. Aborting run.' )
9996 FORMAT( A7, L2 )
9995 FORMAT( ' Subprogram name ', A7, ' not recognized',
$ /' ******* TESTS ABANDONED *******' )
9994 FORMAT( 2X, 'Alpha : ', G16.6 )
9993 FORMAT( 2X, 'Beta : ', G16.6 )
9992 FORMAT( 2X, 'Number of Tests : ', I6 )
9991 FORMAT( 2X, 'Number of process grids : ', I6 )
9990 FORMAT( 2X, ' : ', 5I6 )
9989 FORMAT( 2X, A1, ' : ', 5I6 )
9988 FORMAT( 2X, 'Routines to be tested : ', A, A8 )
9987 FORMAT( 2X, ' ', A, A8 )
9986 FORMAT( 2X, 'Logical block size : ', I6 )
*
* End of PDBLA2TIMINFO
*
END
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