PROGRAM ZCHKAA * * -- LAPACK test routine (version 3.1.1) -- * Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd.. * January 2007 * * Purpose * ======= * * ZCHKAA is the main test program for the COMPLEX*16 linear equation * routines. * * The program must be driven by a short data file. The first 14 records * specify problem dimensions and program options using list-directed * input. The remaining lines specify the LAPACK test paths and the * number of matrix types to use in testing. An annotated example of a * data file can be obtained by deleting the first 3 characters from the * following 38 lines: * Data file for testing COMPLEX*16 LAPACK linear equation routines * 7 Number of values of M * 0 1 2 3 5 10 16 Values of M (row dimension) * 7 Number of values of N * 0 1 2 3 5 10 16 Values of N (column dimension) * 1 Number of values of NRHS * 2 Values of NRHS (number of right hand sides) * 5 Number of values of NB * 1 3 3 3 20 Values of NB (the blocksize) * 1 0 5 9 1 Values of NX (crossover point) * 3 Number of values of RANK * 30 50 90 Values of rank (as a % of N) * 30.0 Threshold value of test ratio * T Put T to test the LAPACK routines * T Put T to test the driver routines * T Put T to test the error exits * ZGE 11 List types on next line if 0 < NTYPES < 11 * ZGB 8 List types on next line if 0 < NTYPES < 8 * ZGT 12 List types on next line if 0 < NTYPES < 12 * ZPO 9 List types on next line if 0 < NTYPES < 9 * ZPS 9 List types on next line if 0 < NTYPES < 9 * ZPP 9 List types on next line if 0 < NTYPES < 9 * ZPB 8 List types on next line if 0 < NTYPES < 8 * ZPT 12 List types on next line if 0 < NTYPES < 12 * ZHE 10 List types on next line if 0 < NTYPES < 10 * ZHP 10 List types on next line if 0 < NTYPES < 10 * ZSY 11 List types on next line if 0 < NTYPES < 11 * ZSP 11 List types on next line if 0 < NTYPES < 11 * ZTR 18 List types on next line if 0 < NTYPES < 18 * ZTP 18 List types on next line if 0 < NTYPES < 18 * ZTB 17 List types on next line if 0 < NTYPES < 17 * ZQR 8 List types on next line if 0 < NTYPES < 8 * ZRQ 8 List types on next line if 0 < NTYPES < 8 * ZLQ 8 List types on next line if 0 < NTYPES < 8 * ZQL 8 List types on next line if 0 < NTYPES < 8 * ZQP 6 List types on next line if 0 < NTYPES < 6 * ZTZ 3 List types on next line if 0 < NTYPES < 3 * ZLS 6 List types on next line if 0 < NTYPES < 6 * ZEQ * * Internal Parameters * =================== * * NMAX INTEGER * The maximum allowable value for N. * * MAXIN INTEGER * The number of different values that can be used for each of * M, N, or NB * * MAXRHS INTEGER * The maximum number of right hand sides * * NIN INTEGER * The unit number for input * * NOUT INTEGER * The unit number for output * * ===================================================================== * * .. Parameters .. INTEGER NMAX PARAMETER ( NMAX = 132 ) INTEGER MAXIN PARAMETER ( MAXIN = 12 ) INTEGER MAXRHS PARAMETER ( MAXRHS = 16 ) INTEGER MATMAX PARAMETER ( MATMAX = 30 ) INTEGER NIN, NOUT PARAMETER ( NIN = 5, NOUT = 6 ) INTEGER KDMAX PARAMETER ( KDMAX = NMAX+( NMAX+1 ) / 4 ) * .. * .. Local Scalars .. LOGICAL FATAL, TSTCHK, TSTDRV, TSTERR CHARACTER C1 CHARACTER*2 C2 CHARACTER*3 PATH CHARACTER*10 INTSTR CHARACTER*72 ALINE INTEGER I, IC, J, K, LA, LAFAC, LDA, NB, NM, NMATS, NN, $ NNB, NNB2, NNS, NRHS, NTYPES, NRANK, $ VERS_MAJOR, VERS_MINOR, VERS_PATCH DOUBLE PRECISION EPS, S1, S2, THREQ, THRESH * .. * .. Local Arrays .. LOGICAL DOTYPE( MATMAX ) INTEGER IWORK( 25*NMAX ), MVAL( MAXIN ), $ NBVAL( MAXIN ), NBVAL2( MAXIN ), $ NSVAL( MAXIN ), NVAL( MAXIN ), NXVAL( MAXIN ), $ RANKVAL( MAXIN ), PIV( NMAX ) DOUBLE PRECISION RWORK( 150*NMAX+2*MAXRHS ), S( 2*NMAX ) COMPLEX*16 A( ( KDMAX+1 )*NMAX, 7 ), B( NMAX*MAXRHS, 4 ), $ WORK( NMAX, NMAX+MAXRHS+10 ) * .. * .. External Functions .. LOGICAL LSAME, LSAMEN DOUBLE PRECISION DLAMCH, DSECND EXTERNAL LSAME, LSAMEN, DLAMCH, DSECND * .. * .. External Subroutines .. EXTERNAL ALAREQ, ZCHKEQ, ZCHKGB, ZCHKGE, ZCHKGT, ZCHKHE, $ ZCHKHP, ZCHKLQ, ZCHKPB, ZCHKPO, ZCHKPS, ZCHKPP, $ ZCHKPT, ZCHKQ3, ZCHKQL, ZCHKQP, ZCHKQR, ZCHKRQ, $ ZCHKSP, ZCHKSY, ZCHKTB, ZCHKTP, ZCHKTR, ZCHKTZ, $ ZDRVGB, ZDRVGE, ZDRVGT, ZDRVHE, ZDRVHP, ZDRVLS, $ ZDRVPB, ZDRVPO, ZDRVPP, ZDRVPT, ZDRVSP, ZDRVSY, $ ILAVER * .. * .. Scalars in Common .. LOGICAL LERR, OK CHARACTER*32 SRNAMT INTEGER INFOT, NUNIT * .. * .. Arrays in Common .. INTEGER IPARMS( 100 ) * .. * .. Common blocks .. COMMON / INFOC / INFOT, NUNIT, OK, LERR COMMON / SRNAMC / SRNAMT COMMON / CLAENV / IPARMS * .. * .. Data statements .. DATA THREQ / 2.0D0 / , INTSTR / '0123456789' / * .. * .. Executable Statements .. * S1 = DSECND( ) LDA = NMAX FATAL = .FALSE. * * Read a dummy line. * READ( NIN, FMT = * ) * * Report values of parameters. * CALL ILAVER( VERS_MAJOR, VERS_MINOR, VERS_PATCH ) WRITE( NOUT, FMT = 9994 ) VERS_MAJOR, VERS_MINOR, VERS_PATCH * * Read the values of M * READ( NIN, FMT = * )NM IF( NM.LT.1 ) THEN WRITE( NOUT, FMT = 9996 )' NM ', NM, 1 NM = 0 FATAL = .TRUE. ELSE IF( NM.GT.MAXIN ) THEN WRITE( NOUT, FMT = 9995 )' NM ', NM, MAXIN NM = 0 FATAL = .TRUE. END IF READ( NIN, FMT = * )( MVAL( I ), I = 1, NM ) DO 10 I = 1, NM IF( MVAL( I ).LT.0 ) THEN WRITE( NOUT, FMT = 9996 )' M ', MVAL( I ), 0 FATAL = .TRUE. ELSE IF( MVAL( I ).GT.NMAX ) THEN WRITE( NOUT, FMT = 9995 )' M ', MVAL( I ), NMAX FATAL = .TRUE. END IF 10 CONTINUE IF( NM.GT.0 ) $ WRITE( NOUT, FMT = 9993 )'M ', ( MVAL( I ), I = 1, NM ) * * Read the values of N * READ( NIN, FMT = * )NN IF( NN.LT.1 ) THEN WRITE( NOUT, FMT = 9996 )' NN ', NN, 1 NN = 0 FATAL = .TRUE. ELSE IF( NN.GT.MAXIN ) THEN WRITE( NOUT, FMT = 9995 )' NN ', NN, MAXIN NN = 0 FATAL = .TRUE. END IF READ( NIN, FMT = * )( NVAL( I ), I = 1, NN ) DO 20 I = 1, NN IF( NVAL( I ).LT.0 ) THEN WRITE( NOUT, FMT = 9996 )' N ', NVAL( I ), 0 FATAL = .TRUE. ELSE IF( NVAL( I ).GT.NMAX ) THEN WRITE( NOUT, FMT = 9995 )' N ', NVAL( I ), NMAX FATAL = .TRUE. END IF 20 CONTINUE IF( NN.GT.0 ) $ WRITE( NOUT, FMT = 9993 )'N ', ( NVAL( I ), I = 1, NN ) * * Read the values of NRHS * READ( NIN, FMT = * )NNS IF( NNS.LT.1 ) THEN WRITE( NOUT, FMT = 9996 )' NNS', NNS, 1 NNS = 0 FATAL = .TRUE. ELSE IF( NNS.GT.MAXIN ) THEN WRITE( NOUT, FMT = 9995 )' NNS', NNS, MAXIN NNS = 0 FATAL = .TRUE. END IF READ( NIN, FMT = * )( NSVAL( I ), I = 1, NNS ) DO 30 I = 1, NNS IF( NSVAL( I ).LT.0 ) THEN WRITE( NOUT, FMT = 9996 )'NRHS', NSVAL( I ), 0 FATAL = .TRUE. ELSE IF( NSVAL( I ).GT.MAXRHS ) THEN WRITE( NOUT, FMT = 9995 )'NRHS', NSVAL( I ), MAXRHS FATAL = .TRUE. END IF 30 CONTINUE IF( NNS.GT.0 ) $ WRITE( NOUT, FMT = 9993 )'NRHS', ( NSVAL( I ), I = 1, NNS ) * * Read the values of NB * READ( NIN, FMT = * )NNB IF( NNB.LT.1 ) THEN WRITE( NOUT, FMT = 9996 )'NNB ', NNB, 1 NNB = 0 FATAL = .TRUE. ELSE IF( NNB.GT.MAXIN ) THEN WRITE( NOUT, FMT = 9995 )'NNB ', NNB, MAXIN NNB = 0 FATAL = .TRUE. END IF READ( NIN, FMT = * )( NBVAL( I ), I = 1, NNB ) DO 40 I = 1, NNB IF( NBVAL( I ).LT.0 ) THEN WRITE( NOUT, FMT = 9996 )' NB ', NBVAL( I ), 0 FATAL = .TRUE. END IF 40 CONTINUE IF( NNB.GT.0 ) $ WRITE( NOUT, FMT = 9993 )'NB ', ( NBVAL( I ), I = 1, NNB ) * * Set NBVAL2 to be the set of unique values of NB * NNB2 = 0 DO 60 I = 1, NNB NB = NBVAL( I ) DO 50 J = 1, NNB2 IF( NB.EQ.NBVAL2( J ) ) $ GO TO 60 50 CONTINUE NNB2 = NNB2 + 1 NBVAL2( NNB2 ) = NB 60 CONTINUE * * Read the values of NX * READ( NIN, FMT = * )( NXVAL( I ), I = 1, NNB ) DO 70 I = 1, NNB IF( NXVAL( I ).LT.0 ) THEN WRITE( NOUT, FMT = 9996 )' NX ', NXVAL( I ), 0 FATAL = .TRUE. END IF 70 CONTINUE IF( NNB.GT.0 ) $ WRITE( NOUT, FMT = 9993 )'NX ', ( NXVAL( I ), I = 1, NNB ) * * Read the values of RANKVAL * READ( NIN, FMT = * )NRANK IF( NN.LT.1 ) THEN WRITE( NOUT, FMT = 9996 )' NRANK ', NRANK, 1 NRANK = 0 FATAL = .TRUE. ELSE IF( NN.GT.MAXIN ) THEN WRITE( NOUT, FMT = 9995 )' NRANK ', NRANK, MAXIN NRANK = 0 FATAL = .TRUE. END IF READ( NIN, FMT = * )( RANKVAL( I ), I = 1, NRANK ) DO I = 1, NRANK IF( RANKVAL( I ).LT.0 ) THEN WRITE( NOUT, FMT = 9996 )' RANK ', RANKVAL( I ), 0 FATAL = .TRUE. ELSE IF( RANKVAL( I ).GT.100 ) THEN WRITE( NOUT, FMT = 9995 )' RANK ', RANKVAL( I ), 100 FATAL = .TRUE. END IF END DO IF( NRANK.GT.0 ) $ WRITE( NOUT, FMT = 9993 )'RANK % OF N', $ ( RANKVAL( I ), I = 1, NRANK ) * * Read the threshold value for the test ratios. * READ( NIN, FMT = * )THRESH WRITE( NOUT, FMT = 9992 )THRESH * * Read the flag that indicates whether to test the LAPACK routines. * READ( NIN, FMT = * )TSTCHK * * Read the flag that indicates whether to test the driver routines. * READ( NIN, FMT = * )TSTDRV * * Read the flag that indicates whether to test the error exits. * READ( NIN, FMT = * )TSTERR * IF( FATAL ) THEN WRITE( NOUT, FMT = 9999 ) STOP END IF * * Calculate and print the machine dependent constants. * EPS = DLAMCH( 'Underflow threshold' ) WRITE( NOUT, FMT = 9991 )'underflow', EPS EPS = DLAMCH( 'Overflow threshold' ) WRITE( NOUT, FMT = 9991 )'overflow ', EPS EPS = DLAMCH( 'Epsilon' ) WRITE( NOUT, FMT = 9991 )'precision', EPS WRITE( NOUT, FMT = * ) NRHS = NSVAL( 1 ) * 80 CONTINUE * * Read a test path and the number of matrix types to use. * READ( NIN, FMT = '(A72)', END = 140 )ALINE PATH = ALINE( 1: 3 ) NMATS = MATMAX I = 3 90 CONTINUE I = I + 1 IF( I.GT.72 ) $ GO TO 130 IF( ALINE( I: I ).EQ.' ' ) $ GO TO 90 NMATS = 0 100 CONTINUE C1 = ALINE( I: I ) DO 110 K = 1, 10 IF( C1.EQ.INTSTR( K: K ) ) THEN IC = K - 1 GO TO 120 END IF 110 CONTINUE GO TO 130 120 CONTINUE NMATS = NMATS*10 + IC I = I + 1 IF( I.GT.72 ) $ GO TO 130 GO TO 100 130 CONTINUE C1 = PATH( 1: 1 ) C2 = PATH( 2: 3 ) * * Check first character for correct precision. * IF( .NOT.LSAME( C1, 'Zomplex precision' ) ) THEN WRITE( NOUT, FMT = 9990 )PATH * ELSE IF( NMATS.LE.0 ) THEN * * Check for a positive number of tests requested. * WRITE( NOUT, FMT = 9989 )PATH * ELSE IF( LSAMEN( 2, C2, 'GE' ) ) THEN * * GE: general matrices * NTYPES = 11 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKGE( DOTYPE, NM, MVAL, NN, NVAL, NNB2, NBVAL2, NNS, $ NSVAL, THRESH, TSTERR, LDA, A( 1, 1 ), $ A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), B( 1, 2 ), $ B( 1, 3 ), WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVGE( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), S, WORK, $ RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'GB' ) ) THEN * * GB: general banded matrices * LA = ( 2*KDMAX+1 )*NMAX LAFAC = ( 3*KDMAX+1 )*NMAX NTYPES = 8 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKGB( DOTYPE, NM, MVAL, NN, NVAL, NNB2, NBVAL2, NNS, $ NSVAL, THRESH, TSTERR, A( 1, 1 ), LA, $ A( 1, 3 ), LAFAC, B( 1, 1 ), B( 1, 2 ), $ B( 1, 3 ), WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVGB( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, $ A( 1, 1 ), LA, A( 1, 3 ), LAFAC, A( 1, 6 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), S, $ WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'GT' ) ) THEN * * GT: general tridiagonal matrices * NTYPES = 12 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKGT( DOTYPE, NN, NVAL, NNS, NSVAL, THRESH, TSTERR, $ A( 1, 1 ), A( 1, 2 ), B( 1, 1 ), B( 1, 2 ), $ B( 1, 3 ), WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVGT( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, $ A( 1, 1 ), A( 1, 2 ), B( 1, 1 ), B( 1, 2 ), $ B( 1, 3 ), WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'PO' ) ) THEN * * PO: positive definite matrices * NTYPES = 9 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKPO( DOTYPE, NN, NVAL, NNB2, NBVAL2, NNS, NSVAL, $ THRESH, TSTERR, LDA, A( 1, 1 ), A( 1, 2 ), $ A( 1, 3 ), B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), $ WORK, RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVPO( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), S, WORK, $ RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'PS' ) ) THEN * * PS: positive semi-definite matrices * NTYPES = 9 * CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKPS( DOTYPE, NN, NVAL, NNB2, NBVAL2, NRANK, $ RANKVAL, THRESH, TSTERR, LDA, A( 1, 1 ), $ A( 1, 2 ), A( 1, 3 ), PIV, WORK, RWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'PP' ) ) THEN * * PP: positive definite packed matrices * NTYPES = 9 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKPP( DOTYPE, NN, NVAL, NNS, NSVAL, THRESH, TSTERR, $ LDA, A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), WORK, RWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVPP( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), S, WORK, $ RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'PB' ) ) THEN * * PB: positive definite banded matrices * NTYPES = 8 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKPB( DOTYPE, NN, NVAL, NNB2, NBVAL2, NNS, NSVAL, $ THRESH, TSTERR, LDA, A( 1, 1 ), A( 1, 2 ), $ A( 1, 3 ), B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), $ WORK, RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVPB( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), S, WORK, $ RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'PT' ) ) THEN * * PT: positive definite tridiagonal matrices * NTYPES = 12 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKPT( DOTYPE, NN, NVAL, NNS, NSVAL, THRESH, TSTERR, $ A( 1, 1 ), S, A( 1, 2 ), B( 1, 1 ), B( 1, 2 ), $ B( 1, 3 ), WORK, RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVPT( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, $ A( 1, 1 ), S, A( 1, 2 ), B( 1, 1 ), B( 1, 2 ), $ B( 1, 3 ), WORK, RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'HE' ) ) THEN * * HE: Hermitian indefinite matrices * NTYPES = 10 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKHE( DOTYPE, NN, NVAL, NNB2, NBVAL2, NNS, NSVAL, $ THRESH, TSTERR, LDA, A( 1, 1 ), A( 1, 2 ), $ A( 1, 3 ), B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), $ WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVHE( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), WORK, RWORK, IWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'HP' ) ) THEN * * HP: Hermitian indefinite packed matrices * NTYPES = 10 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKHP( DOTYPE, NN, NVAL, NNS, NSVAL, THRESH, TSTERR, $ LDA, A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), WORK, RWORK, $ IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVHP( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), WORK, RWORK, IWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'SY' ) ) THEN * * SY: symmetric indefinite matrices * NTYPES = 11 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKSY( DOTYPE, NN, NVAL, NNB2, NBVAL2, NNS, NSVAL, $ THRESH, TSTERR, LDA, A( 1, 1 ), A( 1, 2 ), $ A( 1, 3 ), B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), $ WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVSY( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), WORK, RWORK, IWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'SP' ) ) THEN * * SP: symmetric indefinite packed matrices * NTYPES = 11 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKSP( DOTYPE, NN, NVAL, NNS, NSVAL, THRESH, TSTERR, $ LDA, A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), WORK, RWORK, $ IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * IF( TSTDRV ) THEN CALL ZDRVSP( DOTYPE, NN, NVAL, NRHS, THRESH, TSTERR, LDA, $ A( 1, 1 ), A( 1, 2 ), A( 1, 3 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), WORK, RWORK, IWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9988 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'TR' ) ) THEN * * TR: triangular matrices * NTYPES = 18 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKTR( DOTYPE, NN, NVAL, NNB2, NBVAL2, NNS, NSVAL, $ THRESH, TSTERR, LDA, A( 1, 1 ), A( 1, 2 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), WORK, RWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'TP' ) ) THEN * * TP: triangular packed matrices * NTYPES = 18 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKTP( DOTYPE, NN, NVAL, NNS, NSVAL, THRESH, TSTERR, $ LDA, A( 1, 1 ), A( 1, 2 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), WORK, RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'TB' ) ) THEN * * TB: triangular banded matrices * NTYPES = 17 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKTB( DOTYPE, NN, NVAL, NNS, NSVAL, THRESH, TSTERR, $ LDA, A( 1, 1 ), A( 1, 2 ), B( 1, 1 ), $ B( 1, 2 ), B( 1, 3 ), WORK, RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'QR' ) ) THEN * * QR: QR factorization * NTYPES = 8 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKQR( DOTYPE, NM, MVAL, NN, NVAL, NNB, NBVAL, NXVAL, $ NRHS, THRESH, TSTERR, NMAX, A( 1, 1 ), $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), A( 1, 5 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), $ WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'LQ' ) ) THEN * * LQ: LQ factorization * NTYPES = 8 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKLQ( DOTYPE, NM, MVAL, NN, NVAL, NNB, NBVAL, NXVAL, $ NRHS, THRESH, TSTERR, NMAX, A( 1, 1 ), $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), A( 1, 5 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), $ WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'QL' ) ) THEN * * QL: QL factorization * NTYPES = 8 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKQL( DOTYPE, NM, MVAL, NN, NVAL, NNB, NBVAL, NXVAL, $ NRHS, THRESH, TSTERR, NMAX, A( 1, 1 ), $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), A( 1, 5 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), $ WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'RQ' ) ) THEN * * RQ: RQ factorization * NTYPES = 8 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKRQ( DOTYPE, NM, MVAL, NN, NVAL, NNB, NBVAL, NXVAL, $ NRHS, THRESH, TSTERR, NMAX, A( 1, 1 ), $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), A( 1, 5 ), $ B( 1, 1 ), B( 1, 2 ), B( 1, 3 ), B( 1, 4 ), $ WORK, RWORK, IWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'EQ' ) ) THEN * * EQ: Equilibration routines for general and positive definite * matrices (THREQ should be between 2 and 10) * IF( TSTCHK ) THEN CALL ZCHKEQ( THREQ, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'TZ' ) ) THEN * * TZ: Trapezoidal matrix * NTYPES = 3 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKTZ( DOTYPE, NM, MVAL, NN, NVAL, THRESH, TSTERR, $ A( 1, 1 ), A( 1, 2 ), S( 1 ), S( NMAX+1 ), $ B( 1, 1 ), WORK, RWORK, NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'QP' ) ) THEN * * QP: QR factorization with pivoting * NTYPES = 6 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTCHK ) THEN CALL ZCHKQP( DOTYPE, NM, MVAL, NN, NVAL, THRESH, TSTERR, $ A( 1, 1 ), A( 1, 2 ), S( 1 ), S( NMAX+1 ), $ B( 1, 1 ), WORK, RWORK, IWORK, NOUT ) CALL ZCHKQ3( DOTYPE, NM, MVAL, NN, NVAL, NNB, NBVAL, NXVAL, $ THRESH, A( 1, 1 ), A( 1, 2 ), S( 1 ), $ S( NMAX+1 ), B( 1, 1 ), WORK, RWORK, IWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE IF( LSAMEN( 2, C2, 'LS' ) ) THEN * * LS: Least squares drivers * NTYPES = 6 CALL ALAREQ( PATH, NMATS, DOTYPE, NTYPES, NIN, NOUT ) * IF( TSTDRV ) THEN CALL ZDRVLS( DOTYPE, NM, MVAL, NN, NVAL, NNS, NSVAL, NNB, $ NBVAL, NXVAL, THRESH, TSTERR, A( 1, 1 ), $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), A( 1, 5 ), $ S( 1 ), S( NMAX+1 ), WORK, RWORK, IWORK, $ NOUT ) ELSE WRITE( NOUT, FMT = 9989 )PATH END IF * ELSE * WRITE( NOUT, FMT = 9990 )PATH END IF * * Go back to get another input line. * GO TO 80 * * Branch to this line when the last record is read. * 140 CONTINUE CLOSE ( NIN ) S2 = DSECND( ) WRITE( NOUT, FMT = 9998 ) WRITE( NOUT, FMT = 9997 )S2 - S1 * 9999 FORMAT( / ' Execution not attempted due to input errors' ) 9998 FORMAT( / ' End of tests' ) 9997 FORMAT( ' Total time used = ', F12.2, ' seconds', / ) 9996 FORMAT( ' Invalid input value: ', A4, '=', I6, '; must be >=', $ I6 ) 9995 FORMAT( ' Invalid input value: ', A4, '=', I6, '; must be <=', $ I6 ) 9994 FORMAT( ' Tests of the COMPLEX*16 LAPACK routines ', $ / ' LAPACK VERSION ', I1, '.', I1, '.', I1, $ / / ' The following parameter values will be used:' ) 9993 FORMAT( 4X, A4, ': ', 10I6, / 11X, 10I6 ) 9992 FORMAT( / ' Routines pass computational tests if test ratio is ', $ 'less than', F8.2, / ) 9991 FORMAT( ' Relative machine ', A, ' is taken to be', D16.6 ) 9990 FORMAT( / 1X, A3, ': Unrecognized path name' ) 9989 FORMAT( / 1X, A3, ' routines were not tested' ) 9988 FORMAT( / 1X, A3, ' driver routines were not tested' ) * * End of ZCHKAA * END