/atlas/src/lapack-lite-3.1.1/TESTING/EIG/dchkee.f
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Possible License(s): BSD-3-Clause
- PROGRAM DCHKEE
- *
- * -- LAPACK test routine (version 3.1.1) --
- * Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd..
- * January 2007
- *
- * Purpose
- * =======
- *
- * DCHKEE tests the DOUBLE PRECISION LAPACK subroutines for the matrix
- * eigenvalue problem. The test paths in this version are
- *
- * NEP (Nonsymmetric Eigenvalue Problem):
- * Test DGEHRD, DORGHR, DHSEQR, DTREVC, DHSEIN, and DORMHR
- *
- * SEP (Symmetric Eigenvalue Problem):
- * Test DSYTRD, DORGTR, DSTEQR, DSTERF, DSTEIN, DSTEDC,
- * and drivers DSYEV(X), DSBEV(X), DSPEV(X), DSTEV(X),
- * DSYEVD, DSBEVD, DSPEVD, DSTEVD
- *
- * SVD (Singular Value Decomposition):
- * Test DGEBRD, DORGBR, DBDSQR, DBDSDC
- * and the drivers DGESVD, DGESDD
- *
- * DEV (Nonsymmetric Eigenvalue/eigenvector Driver):
- * Test DGEEV
- *
- * DES (Nonsymmetric Schur form Driver):
- * Test DGEES
- *
- * DVX (Nonsymmetric Eigenvalue/eigenvector Expert Driver):
- * Test DGEEVX
- *
- * DSX (Nonsymmetric Schur form Expert Driver):
- * Test DGEESX
- *
- * DGG (Generalized Nonsymmetric Eigenvalue Problem):
- * Test DGGHRD, DGGBAL, DGGBAK, DHGEQZ, and DTGEVC
- * and the driver routines DGEGS and DGEGV
- *
- * DGS (Generalized Nonsymmetric Schur form Driver):
- * Test DGGES
- *
- * DGV (Generalized Nonsymmetric Eigenvalue/eigenvector Driver):
- * Test DGGEV
- *
- * DGX (Generalized Nonsymmetric Schur form Expert Driver):
- * Test DGGESX
- *
- * DXV (Generalized Nonsymmetric Eigenvalue/eigenvector Expert Driver):
- * Test DGGEVX
- *
- * DSG (Symmetric Generalized Eigenvalue Problem):
- * Test DSYGST, DSYGV, DSYGVD, DSYGVX, DSPGST, DSPGV, DSPGVD,
- * DSPGVX, DSBGST, DSBGV, DSBGVD, and DSBGVX
- *
- * DSB (Symmetric Band Eigenvalue Problem):
- * Test DSBTRD
- *
- * DBB (Band Singular Value Decomposition):
- * Test DGBBRD
- *
- * DEC (Eigencondition estimation):
- * Test DLALN2, DLASY2, DLAEQU, DLAEXC, DTRSYL, DTREXC, DTRSNA,
- * DTRSEN, and DLAQTR
- *
- * DBL (Balancing a general matrix)
- * Test DGEBAL
- *
- * DBK (Back transformation on a balanced matrix)
- * Test DGEBAK
- *
- * DGL (Balancing a matrix pair)
- * Test DGGBAL
- *
- * DGK (Back transformation on a matrix pair)
- * Test DGGBAK
- *
- * GLM (Generalized Linear Regression Model):
- * Tests DGGGLM
- *
- * GQR (Generalized QR and RQ factorizations):
- * Tests DGGQRF and DGGRQF
- *
- * GSV (Generalized Singular Value Decomposition):
- * Tests DGGSVD, DGGSVP, DTGSJA, DLAGS2, DLAPLL, and DLAPMT
- *
- * LSE (Constrained Linear Least Squares):
- * Tests DGGLSE
- *
- * Each test path has a different set of inputs, but the data sets for
- * the driver routines xEV, xES, xVX, and xSX can be concatenated in a
- * single input file. The first line of input should contain one of the
- * 3-character path names in columns 1-3. The number of remaining lines
- * depends on what is found on the first line.
- *
- * The number of matrix types used in testing is often controllable from
- * the input file. The number of matrix types for each path, and the
- * test routine that describes them, is as follows:
- *
- * Path name(s) Types Test routine
- *
- * DHS or NEP 21 DCHKHS
- * DST or SEP 21 DCHKST (routines)
- * 18 DDRVST (drivers)
- * DBD or SVD 16 DCHKBD (routines)
- * 5 DDRVBD (drivers)
- * DEV 21 DDRVEV
- * DES 21 DDRVES
- * DVX 21 DDRVVX
- * DSX 21 DDRVSX
- * DGG 26 DCHKGG (routines)
- * 26 DDRVGG (drivers)
- * DGS 26 DDRGES
- * DGX 5 DDRGSX
- * DGV 26 DDRGEV
- * DXV 2 DDRGVX
- * DSG 21 DDRVSG
- * DSB 15 DCHKSB
- * DBB 15 DCHKBB
- * DEC - DCHKEC
- * DBL - DCHKBL
- * DBK - DCHKBK
- * DGL - DCHKGL
- * DGK - DCHKGK
- * GLM 8 DCKGLM
- * GQR 8 DCKGQR
- * GSV 8 DCKGSV
- * LSE 8 DCKLSE
- *
- *-----------------------------------------------------------------------
- *
- * NEP input file:
- *
- * line 2: NN, INTEGER
- * Number of values of N.
- *
- * line 3: NVAL, INTEGER array, dimension (NN)
- * The values for the matrix dimension N.
- *
- * line 4: NPARMS, INTEGER
- * Number of values of the parameters NB, NBMIN, NX, NS, and
- * MAXB.
- *
- * line 5: NBVAL, INTEGER array, dimension (NPARMS)
- * The values for the blocksize NB.
- *
- * line 6: NBMIN, INTEGER array, dimension (NPARMS)
- * The values for the minimum blocksize NBMIN.
- *
- * line 7: NXVAL, INTEGER array, dimension (NPARMS)
- * The values for the crossover point NX.
- *
- * line 8: INMIN, INTEGER array, dimension (NPARMS)
- * LAHQR vs TTQRE crossover point, >= 11
- *
- * line 9: INWIN, INTEGER array, dimension (NPARMS)
- * recommended deflation window size
- *
- * line 10: INIBL, INTEGER array, dimension (NPARMS)
- * nibble crossover point
- *
- * line 11: ISHFTS, INTEGER array, dimension (NPARMS)
- * number of simultaneous shifts)
- *
- * line 12: IACC22, INTEGER array, dimension (NPARMS)
- * select structured matrix multiply: 0, 1 or 2)
- *
- * line 13: THRESH
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold. To have all of the test
- * ratios printed, use THRESH = 0.0 .
- *
- * line 14: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 14 was 2:
- *
- * line 15: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 15-EOF: The remaining lines occur in sets of 1 or 2 and allow
- * the user to specify the matrix types. Each line contains
- * a 3-character path name in columns 1-3, and the number
- * of matrix types must be the first nonblank item in columns
- * 4-80. If the number of matrix types is at least 1 but is
- * less than the maximum number of possible types, a second
- * line will be read to get the numbers of the matrix types to
- * be used. For example,
- * NEP 21
- * requests all of the matrix types for the nonsymmetric
- * eigenvalue problem, while
- * NEP 4
- * 9 10 11 12
- * requests only matrices of type 9, 10, 11, and 12.
- *
- * The valid 3-character path names are 'NEP' or 'SHS' for the
- * nonsymmetric eigenvalue routines.
- *
- *-----------------------------------------------------------------------
- *
- * SEP or DSG input file:
- *
- * line 2: NN, INTEGER
- * Number of values of N.
- *
- * line 3: NVAL, INTEGER array, dimension (NN)
- * The values for the matrix dimension N.
- *
- * line 4: NPARMS, INTEGER
- * Number of values of the parameters NB, NBMIN, and NX.
- *
- * line 5: NBVAL, INTEGER array, dimension (NPARMS)
- * The values for the blocksize NB.
- *
- * line 6: NBMIN, INTEGER array, dimension (NPARMS)
- * The values for the minimum blocksize NBMIN.
- *
- * line 7: NXVAL, INTEGER array, dimension (NPARMS)
- * The values for the crossover point NX.
- *
- * line 8: THRESH
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 9: TSTCHK, LOGICAL
- * Flag indicating whether or not to test the LAPACK routines.
- *
- * line 10: TSTDRV, LOGICAL
- * Flag indicating whether or not to test the driver routines.
- *
- * line 11: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 12: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 12 was 2:
- *
- * line 13: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 13-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path names are 'SEP' or 'SST' for the
- * symmetric eigenvalue routines and driver routines, and
- * 'DSG' for the routines for the symmetric generalized
- * eigenvalue problem.
- *
- *-----------------------------------------------------------------------
- *
- * SVD input file:
- *
- * line 2: NN, INTEGER
- * Number of values of M and N.
- *
- * line 3: MVAL, INTEGER array, dimension (NN)
- * The values for the matrix row dimension M.
- *
- * line 4: NVAL, INTEGER array, dimension (NN)
- * The values for the matrix column dimension N.
- *
- * line 5: NPARMS, INTEGER
- * Number of values of the parameter NB, NBMIN, NX, and NRHS.
- *
- * line 6: NBVAL, INTEGER array, dimension (NPARMS)
- * The values for the blocksize NB.
- *
- * line 7: NBMIN, INTEGER array, dimension (NPARMS)
- * The values for the minimum blocksize NBMIN.
- *
- * line 8: NXVAL, INTEGER array, dimension (NPARMS)
- * The values for the crossover point NX.
- *
- * line 9: NSVAL, INTEGER array, dimension (NPARMS)
- * The values for the number of right hand sides NRHS.
- *
- * line 10: THRESH
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 11: TSTCHK, LOGICAL
- * Flag indicating whether or not to test the LAPACK routines.
- *
- * line 12: TSTDRV, LOGICAL
- * Flag indicating whether or not to test the driver routines.
- *
- * line 13: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 14: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 14 was 2:
- *
- * line 15: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 15-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path names are 'SVD' or 'SBD' for both the
- * SVD routines and the SVD driver routines.
- *
- *-----------------------------------------------------------------------
- *
- * DEV and DES data files:
- *
- * line 1: 'DEV' or 'DES' in columns 1 to 3.
- *
- * line 2: NSIZES, INTEGER
- * Number of sizes of matrices to use. Should be at least 0
- * and at most 20. If NSIZES = 0, no testing is done
- * (although the remaining 3 lines are still read).
- *
- * line 3: NN, INTEGER array, dimension(NSIZES)
- * Dimensions of matrices to be tested.
- *
- * line 4: NB, NBMIN, NX, NS, NBCOL, INTEGERs
- * These integer parameters determine how blocking is done
- * (see ILAENV for details)
- * NB : block size
- * NBMIN : minimum block size
- * NX : minimum dimension for blocking
- * NS : number of shifts in xHSEQR
- * NBCOL : minimum column dimension for blocking
- *
- * line 5: THRESH, REAL
- * The test threshold against which computed residuals are
- * compared. Should generally be in the range from 10. to 20.
- * If it is 0., all test case data will be printed.
- *
- * line 6: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits.
- *
- * line 7: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 7 was 2:
- *
- * line 8: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 9 and following: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'DEV' to test SGEEV, or
- * 'DES' to test SGEES.
- *
- *-----------------------------------------------------------------------
- *
- * The DVX data has two parts. The first part is identical to DEV,
- * and the second part consists of test matrices with precomputed
- * solutions.
- *
- * line 1: 'DVX' in columns 1-3.
- *
- * line 2: NSIZES, INTEGER
- * If NSIZES = 0, no testing of randomly generated examples
- * is done, but any precomputed examples are tested.
- *
- * line 3: NN, INTEGER array, dimension(NSIZES)
- *
- * line 4: NB, NBMIN, NX, NS, NBCOL, INTEGERs
- *
- * line 5: THRESH, REAL
- *
- * line 6: TSTERR, LOGICAL
- *
- * line 7: NEWSD, INTEGER
- *
- * If line 7 was 2:
- *
- * line 8: INTEGER array, dimension (4)
- *
- * lines 9 and following: The first line contains 'DVX' in columns 1-3
- * followed by the number of matrix types, possibly with
- * a second line to specify certain matrix types.
- * If the number of matrix types = 0, no testing of randomly
- * generated examples is done, but any precomputed examples
- * are tested.
- *
- * remaining lines : Each matrix is stored on 1+2*N lines, where N is
- * its dimension. The first line contains the dimension (a
- * single integer). The next N lines contain the matrix, one
- * row per line. The last N lines correspond to each
- * eigenvalue. Each of these last N lines contains 4 real
- * values: the real part of the eigenvalue, the imaginary
- * part of the eigenvalue, the reciprocal condition number of
- * the eigenvalues, and the reciprocal condition number of the
- * eigenvector. The end of data is indicated by dimension N=0.
- * Even if no data is to be tested, there must be at least one
- * line containing N=0.
- *
- *-----------------------------------------------------------------------
- *
- * The DSX data is like DVX. The first part is identical to DEV, and the
- * second part consists of test matrices with precomputed solutions.
- *
- * line 1: 'DSX' in columns 1-3.
- *
- * line 2: NSIZES, INTEGER
- * If NSIZES = 0, no testing of randomly generated examples
- * is done, but any precomputed examples are tested.
- *
- * line 3: NN, INTEGER array, dimension(NSIZES)
- *
- * line 4: NB, NBMIN, NX, NS, NBCOL, INTEGERs
- *
- * line 5: THRESH, REAL
- *
- * line 6: TSTERR, LOGICAL
- *
- * line 7: NEWSD, INTEGER
- *
- * If line 7 was 2:
- *
- * line 8: INTEGER array, dimension (4)
- *
- * lines 9 and following: The first line contains 'DSX' in columns 1-3
- * followed by the number of matrix types, possibly with
- * a second line to specify certain matrix types.
- * If the number of matrix types = 0, no testing of randomly
- * generated examples is done, but any precomputed examples
- * are tested.
- *
- * remaining lines : Each matrix is stored on 3+N lines, where N is its
- * dimension. The first line contains the dimension N and the
- * dimension M of an invariant subspace. The second line
- * contains M integers, identifying the eigenvalues in the
- * invariant subspace (by their position in a list of
- * eigenvalues ordered by increasing real part). The next N
- * lines contain the matrix. The last line contains the
- * reciprocal condition number for the average of the selected
- * eigenvalues, and the reciprocal condition number for the
- * corresponding right invariant subspace. The end of data is
- * indicated by a line containing N=0 and M=0. Even if no data
- * is to be tested, there must be at least one line containing
- * N=0 and M=0.
- *
- *-----------------------------------------------------------------------
- *
- * DGG input file:
- *
- * line 2: NN, INTEGER
- * Number of values of N.
- *
- * line 3: NVAL, INTEGER array, dimension (NN)
- * The values for the matrix dimension N.
- *
- * line 4: NPARMS, INTEGER
- * Number of values of the parameters NB, NBMIN, NS, MAXB, and
- * NBCOL.
- *
- * line 5: NBVAL, INTEGER array, dimension (NPARMS)
- * The values for the blocksize NB.
- *
- * line 6: NBMIN, INTEGER array, dimension (NPARMS)
- * The values for NBMIN, the minimum row dimension for blocks.
- *
- * line 7: NSVAL, INTEGER array, dimension (NPARMS)
- * The values for the number of shifts.
- *
- * line 8: MXBVAL, INTEGER array, dimension (NPARMS)
- * The values for MAXB, used in determining minimum blocksize.
- *
- * line 9: NBCOL, INTEGER array, dimension (NPARMS)
- * The values for NBCOL, the minimum column dimension for
- * blocks.
- *
- * line 10: THRESH
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 11: TSTCHK, LOGICAL
- * Flag indicating whether or not to test the LAPACK routines.
- *
- * line 12: TSTDRV, LOGICAL
- * Flag indicating whether or not to test the driver routines.
- *
- * line 13: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 14: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 14 was 2:
- *
- * line 15: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 15-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'DGG' for the generalized
- * eigenvalue problem routines and driver routines.
- *
- *-----------------------------------------------------------------------
- *
- * DGS and DGV input files:
- *
- * line 1: 'DGS' or 'DGV' in columns 1 to 3.
- *
- * line 2: NN, INTEGER
- * Number of values of N.
- *
- * line 3: NVAL, INTEGER array, dimension(NN)
- * Dimensions of matrices to be tested.
- *
- * line 4: NB, NBMIN, NX, NS, NBCOL, INTEGERs
- * These integer parameters determine how blocking is done
- * (see ILAENV for details)
- * NB : block size
- * NBMIN : minimum block size
- * NX : minimum dimension for blocking
- * NS : number of shifts in xHGEQR
- * NBCOL : minimum column dimension for blocking
- *
- * line 5: THRESH, REAL
- * The test threshold against which computed residuals are
- * compared. Should generally be in the range from 10. to 20.
- * If it is 0., all test case data will be printed.
- *
- * line 6: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits.
- *
- * line 7: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 17 was 2:
- *
- * line 7: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 7-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'DGS' for the generalized
- * eigenvalue problem routines and driver routines.
- *
- *-----------------------------------------------------------------------
- *
- * DXV input files:
- *
- * line 1: 'DXV' in columns 1 to 3.
- *
- * line 2: N, INTEGER
- * Value of N.
- *
- * line 3: NB, NBMIN, NX, NS, NBCOL, INTEGERs
- * These integer parameters determine how blocking is done
- * (see ILAENV for details)
- * NB : block size
- * NBMIN : minimum block size
- * NX : minimum dimension for blocking
- * NS : number of shifts in xHGEQR
- * NBCOL : minimum column dimension for blocking
- *
- * line 4: THRESH, REAL
- * The test threshold against which computed residuals are
- * compared. Should generally be in the range from 10. to 20.
- * Information will be printed about each test for which the
- * test ratio is greater than or equal to the threshold.
- *
- * line 5: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 6: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 6 was 2:
- *
- * line 7: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * If line 2 was 0:
- *
- * line 7-EOF: Precomputed examples are tested.
- *
- * remaining lines : Each example is stored on 3+2*N lines, where N is
- * its dimension. The first line contains the dimension (a
- * single integer). The next N lines contain the matrix A, one
- * row per line. The next N lines contain the matrix B. The
- * next line contains the reciprocals of the eigenvalue
- * condition numbers. The last line contains the reciprocals of
- * the eigenvector condition numbers. The end of data is
- * indicated by dimension N=0. Even if no data is to be tested,
- * there must be at least one line containing N=0.
- *
- *-----------------------------------------------------------------------
- *
- * DGX input files:
- *
- * line 1: 'DGX' in columns 1 to 3.
- *
- * line 2: N, INTEGER
- * Value of N.
- *
- * line 3: NB, NBMIN, NX, NS, NBCOL, INTEGERs
- * These integer parameters determine how blocking is done
- * (see ILAENV for details)
- * NB : block size
- * NBMIN : minimum block size
- * NX : minimum dimension for blocking
- * NS : number of shifts in xHGEQR
- * NBCOL : minimum column dimension for blocking
- *
- * line 4: THRESH, REAL
- * The test threshold against which computed residuals are
- * compared. Should generally be in the range from 10. to 20.
- * Information will be printed about each test for which the
- * test ratio is greater than or equal to the threshold.
- *
- * line 5: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 6: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 6 was 2:
- *
- * line 7: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * If line 2 was 0:
- *
- * line 7-EOF: Precomputed examples are tested.
- *
- * remaining lines : Each example is stored on 3+2*N lines, where N is
- * its dimension. The first line contains the dimension (a
- * single integer). The next line contains an integer k such
- * that only the last k eigenvalues will be selected and appear
- * in the leading diagonal blocks of $A$ and $B$. The next N
- * lines contain the matrix A, one row per line. The next N
- * lines contain the matrix B. The last line contains the
- * reciprocal of the eigenvalue cluster condition number and the
- * reciprocal of the deflating subspace (associated with the
- * selected eigencluster) condition number. The end of data is
- * indicated by dimension N=0. Even if no data is to be tested,
- * there must be at least one line containing N=0.
- *
- *-----------------------------------------------------------------------
- *
- * DSB input file:
- *
- * line 2: NN, INTEGER
- * Number of values of N.
- *
- * line 3: NVAL, INTEGER array, dimension (NN)
- * The values for the matrix dimension N.
- *
- * line 4: NK, INTEGER
- * Number of values of K.
- *
- * line 5: KVAL, INTEGER array, dimension (NK)
- * The values for the matrix dimension K.
- *
- * line 6: THRESH
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 7: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 7 was 2:
- *
- * line 8: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 8-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'DSB'.
- *
- *-----------------------------------------------------------------------
- *
- * DBB input file:
- *
- * line 2: NN, INTEGER
- * Number of values of M and N.
- *
- * line 3: MVAL, INTEGER array, dimension (NN)
- * The values for the matrix row dimension M.
- *
- * line 4: NVAL, INTEGER array, dimension (NN)
- * The values for the matrix column dimension N.
- *
- * line 4: NK, INTEGER
- * Number of values of K.
- *
- * line 5: KVAL, INTEGER array, dimension (NK)
- * The values for the matrix bandwidth K.
- *
- * line 6: NPARMS, INTEGER
- * Number of values of the parameter NRHS
- *
- * line 7: NSVAL, INTEGER array, dimension (NPARMS)
- * The values for the number of right hand sides NRHS.
- *
- * line 8: THRESH
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 9: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 9 was 2:
- *
- * line 10: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 10-EOF: Lines specifying matrix types, as for SVD.
- * The 3-character path name is 'DBB'.
- *
- *-----------------------------------------------------------------------
- *
- * DEC input file:
- *
- * line 2: THRESH, REAL
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * lines 3-EOF:
- *
- * Input for testing the eigencondition routines consists of a set of
- * specially constructed test cases and their solutions. The data
- * format is not intended to be modified by the user.
- *
- *-----------------------------------------------------------------------
- *
- * DBL and DBK input files:
- *
- * line 1: 'DBL' in columns 1-3 to test SGEBAL, or 'DBK' in
- * columns 1-3 to test SGEBAK.
- *
- * The remaining lines consist of specially constructed test cases.
- *
- *-----------------------------------------------------------------------
- *
- * DGL and DGK input files:
- *
- * line 1: 'DGL' in columns 1-3 to test DGGBAL, or 'DGK' in
- * columns 1-3 to test DGGBAK.
- *
- * The remaining lines consist of specially constructed test cases.
- *
- *-----------------------------------------------------------------------
- *
- * GLM data file:
- *
- * line 1: 'GLM' in columns 1 to 3.
- *
- * line 2: NN, INTEGER
- * Number of values of M, P, and N.
- *
- * line 3: MVAL, INTEGER array, dimension(NN)
- * Values of M (row dimension).
- *
- * line 4: PVAL, INTEGER array, dimension(NN)
- * Values of P (row dimension).
- *
- * line 5: NVAL, INTEGER array, dimension(NN)
- * Values of N (column dimension), note M <= N <= M+P.
- *
- * line 6: THRESH, REAL
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 7: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 8: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 8 was 2:
- *
- * line 9: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 9-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'GLM' for the generalized
- * linear regression model routines.
- *
- *-----------------------------------------------------------------------
- *
- * GQR data file:
- *
- * line 1: 'GQR' in columns 1 to 3.
- *
- * line 2: NN, INTEGER
- * Number of values of M, P, and N.
- *
- * line 3: MVAL, INTEGER array, dimension(NN)
- * Values of M.
- *
- * line 4: PVAL, INTEGER array, dimension(NN)
- * Values of P.
- *
- * line 5: NVAL, INTEGER array, dimension(NN)
- * Values of N.
- *
- * line 6: THRESH, REAL
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 7: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 8: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 8 was 2:
- *
- * line 9: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 9-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'GQR' for the generalized
- * QR and RQ routines.
- *
- *-----------------------------------------------------------------------
- *
- * GSV data file:
- *
- * line 1: 'GSV' in columns 1 to 3.
- *
- * line 2: NN, INTEGER
- * Number of values of M, P, and N.
- *
- * line 3: MVAL, INTEGER array, dimension(NN)
- * Values of M (row dimension).
- *
- * line 4: PVAL, INTEGER array, dimension(NN)
- * Values of P (row dimension).
- *
- * line 5: NVAL, INTEGER array, dimension(NN)
- * Values of N (column dimension).
- *
- * line 6: THRESH, REAL
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 7: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 8: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 8 was 2:
- *
- * line 9: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 9-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'GSV' for the generalized
- * SVD routines.
- *
- *-----------------------------------------------------------------------
- *
- * LSE data file:
- *
- * line 1: 'LSE' in columns 1 to 3.
- *
- * line 2: NN, INTEGER
- * Number of values of M, P, and N.
- *
- * line 3: MVAL, INTEGER array, dimension(NN)
- * Values of M.
- *
- * line 4: PVAL, INTEGER array, dimension(NN)
- * Values of P.
- *
- * line 5: NVAL, INTEGER array, dimension(NN)
- * Values of N, note P <= N <= P+M.
- *
- * line 6: THRESH, REAL
- * Threshold value for the test ratios. Information will be
- * printed about each test for which the test ratio is greater
- * than or equal to the threshold.
- *
- * line 7: TSTERR, LOGICAL
- * Flag indicating whether or not to test the error exits for
- * the LAPACK routines and driver routines.
- *
- * line 8: NEWSD, INTEGER
- * A code indicating how to set the random number seed.
- * = 0: Set the seed to a default value before each run
- * = 1: Initialize the seed to a default value only before the
- * first run
- * = 2: Like 1, but use the seed values on the next line
- *
- * If line 8 was 2:
- *
- * line 9: INTEGER array, dimension (4)
- * Four integer values for the random number seed.
- *
- * lines 9-EOF: Lines specifying matrix types, as for NEP.
- * The 3-character path name is 'GSV' for the generalized
- * SVD routines.
- *
- *-----------------------------------------------------------------------
- *
- * NMAX is currently set to 132 and must be at least 12 for some of the
- * precomputed examples, and LWORK = NMAX*(5*NMAX+5)+1 in the parameter
- * statements below. For SVD, we assume NRHS may be as big as N. The
- * parameter NEED is set to 14 to allow for 14 N-by-N matrices for DGG.
- *
- * =====================================================================
- *
- * .. Parameters ..
- INTEGER NMAX
- PARAMETER ( NMAX = 132 )
- INTEGER NCMAX
- PARAMETER ( NCMAX = 20 )
- INTEGER NEED
- PARAMETER ( NEED = 14 )
- INTEGER LWORK
- PARAMETER ( LWORK = NMAX*( 5*NMAX+5 )+1 )
- INTEGER LIWORK
- PARAMETER ( LIWORK = NMAX*( 5*NMAX+20 ) )
- INTEGER MAXIN
- PARAMETER ( MAXIN = 20 )
- INTEGER MAXT
- PARAMETER ( MAXT = 30 )
- INTEGER NIN, NOUT
- PARAMETER ( NIN = 5, NOUT = 6 )
- * ..
- * .. Local Scalars ..
- LOGICAL DBB, DGG, DSB, FATAL, GLM, GQR, GSV, LSE, NEP,
- $ DBK, DBL, SEP, DES, DEV, DGK, DGL, DGS, DGV,
- $ DGX, DSX, SVD, DVX, DXV, TSTCHK, TSTDIF,
- $ TSTDRV, TSTERR
- CHARACTER C1
- CHARACTER*3 C3, PATH
- CHARACTER*6 VNAME
- CHARACTER*10 INTSTR
- CHARACTER*80 LINE
- INTEGER I, I1, IC, INFO, ITMP, K, LENP, MAXTYP, NEWSD,
- $ NK, NN, NPARMS, NRHS, NTYPES,
- $ VERS_MAJOR, VERS_MINOR, VERS_PATCH
- DOUBLE PRECISION EPS, S1, S2, THRESH, THRSHN
- * ..
- * .. Local Arrays ..
- LOGICAL DOTYPE( MAXT ), LOGWRK( NMAX )
- INTEGER IOLDSD( 4 ), ISEED( 4 ), IWORK( LIWORK ),
- $ KVAL( MAXIN ), MVAL( MAXIN ), MXBVAL( MAXIN ),
- $ NBCOL( MAXIN ), NBMIN( MAXIN ), NBVAL( MAXIN ),
- $ NSVAL( MAXIN ), NVAL( MAXIN ), NXVAL( MAXIN ),
- $ PVAL( MAXIN )
- INTEGER INMIN( MAXIN ), INWIN( MAXIN ), INIBL( MAXIN ),
- $ ISHFTS( MAXIN ), IACC22( MAXIN )
- DOUBLE PRECISION A( NMAX*NMAX, NEED ), B( NMAX*NMAX, 5 ),
- $ C( NCMAX*NCMAX, NCMAX*NCMAX ), D( NMAX, 12 ),
- $ RESULT( 500 ), TAUA( NMAX ), TAUB( NMAX ),
- $ WORK( LWORK ), X( 5*NMAX )
- * ..
- * .. External Functions ..
- LOGICAL LSAMEN
- DOUBLE PRECISION DLAMCH, DSECND
- EXTERNAL LSAMEN, DLAMCH, DSECND
- * ..
- * .. External Subroutines ..
- EXTERNAL ALAREQ, DCHKBB, DCHKBD, DCHKBK, DCHKBL, DCHKEC,
- $ DCHKGG, DCHKGK, DCHKGL, DCHKHS, DCHKSB, DCHKST,
- $ DCKGLM, DCKGQR, DCKGSV, DCKLSE, DDRGES, DDRGEV,
- $ DDRGSX, DDRGVX, DDRVBD, DDRVES, DDRVEV, DDRVGG,
- $ DDRVSG, DDRVST, DDRVSX, DDRVVX, DERRBD, DERRED,
- $ DERRGG, DERRHS, DERRST, ILAVER, XLAENV
- * ..
- * .. Intrinsic Functions ..
- INTRINSIC LEN, MIN
- * ..
- * .. Scalars in Common ..
- LOGICAL LERR, OK
- CHARACTER*6 SRNAMT
- INTEGER INFOT, MAXB, NPROC, NSHIFT, NUNIT, SELDIM,
- $ SELOPT
- * ..
- * .. Arrays in Common ..
- LOGICAL SELVAL( 20 )
- INTEGER IPARMS( 100 )
- DOUBLE PRECISION SELWI( 20 ), SELWR( 20 )
- * ..
- * .. Common blocks ..
- COMMON / CENVIR / NPROC, NSHIFT, MAXB
- COMMON / INFOC / INFOT, NUNIT, OK, LERR
- COMMON / SRNAMC / SRNAMT
- COMMON / SSLCT / SELOPT, SELDIM, SELVAL, SELWR, SELWI
- COMMON / ZLAENV / IPARMS
- * ..
- * .. Data statements ..
- DATA INTSTR / '0123456789' /
- DATA IOLDSD / 0, 0, 0, 1 /
- * ..
- * .. Executable Statements ..
- *
- S1 = DSECND( )
- FATAL = .FALSE.
- NUNIT = NOUT
- *
- * Return to here to read multiple sets of data
- *
- 10 CONTINUE
- *
- * Read the first line and set the 3-character test path
- *
- READ( NIN, FMT = '(A80)', END = 380 )LINE
- PATH = LINE( 1: 3 )
- NEP = LSAMEN( 3, PATH, 'NEP' ) .OR. LSAMEN( 3, PATH, 'DHS' )
- SEP = LSAMEN( 3, PATH, 'SEP' ) .OR. LSAMEN( 3, PATH, 'DST' ) .OR.
- $ LSAMEN( 3, PATH, 'DSG' )
- SVD = LSAMEN( 3, PATH, 'SVD' ) .OR. LSAMEN( 3, PATH, 'DBD' )
- DEV = LSAMEN( 3, PATH, 'DEV' )
- DES = LSAMEN( 3, PATH, 'DES' )
- DVX = LSAMEN( 3, PATH, 'DVX' )
- DSX = LSAMEN( 3, PATH, 'DSX' )
- DGG = LSAMEN( 3, PATH, 'DGG' )
- DGS = LSAMEN( 3, PATH, 'DGS' )
- DGX = LSAMEN( 3, PATH, 'DGX' )
- DGV = LSAMEN( 3, PATH, 'DGV' )
- DXV = LSAMEN( 3, PATH, 'DXV' )
- DSB = LSAMEN( 3, PATH, 'DSB' )
- DBB = LSAMEN( 3, PATH, 'DBB' )
- GLM = LSAMEN( 3, PATH, 'GLM' )
- GQR = LSAMEN( 3, PATH, 'GQR' ) .OR. LSAMEN( 3, PATH, 'GRQ' )
- GSV = LSAMEN( 3, PATH, 'GSV' )
- LSE = LSAMEN( 3, PATH, 'LSE' )
- DBL = LSAMEN( 3, PATH, 'DBL' )
- DBK = LSAMEN( 3, PATH, 'DBK' )
- DGL = LSAMEN( 3, PATH, 'DGL' )
- DGK = LSAMEN( 3, PATH, 'DGK' )
- *
- * Report values of parameters.
- *
- IF( PATH.EQ.' ' ) THEN
- GO TO 10
- ELSE IF( NEP ) THEN
- WRITE( NOUT, FMT = 9987 )
- ELSE IF( SEP ) THEN
- WRITE( NOUT, FMT = 9986 )
- ELSE IF( SVD ) THEN
- WRITE( NOUT, FMT = 9985 )
- ELSE IF( DEV ) THEN
- WRITE( NOUT, FMT = 9979 )
- ELSE IF( DES ) THEN
- WRITE( NOUT, FMT = 9978 )
- ELSE IF( DVX ) THEN
- WRITE( NOUT, FMT = 9977 )
- ELSE IF( DSX ) THEN
- WRITE( NOUT, FMT = 9976 )
- ELSE IF( DGG ) THEN
- WRITE( NOUT, FMT = 9975 )
- ELSE IF( DGS ) THEN
- WRITE( NOUT, FMT = 9964 )
- ELSE IF( DGX ) THEN
- WRITE( NOUT, FMT = 9965 )
- ELSE IF( DGV ) THEN
- WRITE( NOUT, FMT = 9963 )
- ELSE IF( DXV ) THEN
- WRITE( NOUT, FMT = 9962 )
- ELSE IF( DSB ) THEN
- WRITE( NOUT, FMT = 9974 )
- ELSE IF( DBB ) THEN
- WRITE( NOUT, FMT = 9967 )
- ELSE IF( GLM ) THEN
- WRITE( NOUT, FMT = 9971 )
- ELSE IF( GQR ) THEN
- WRITE( NOUT, FMT = 9970 )
- ELSE IF( GSV ) THEN
- WRITE( NOUT, FMT = 9969 )
- ELSE IF( LSE ) THEN
- WRITE( NOUT, FMT = 9968 )
- ELSE IF( DBL ) THEN
- *
- * DGEBAL: Balancing
- *
- CALL DCHKBL( NIN, NOUT )
- GO TO 10
- ELSE IF( DBK ) THEN
- *
- * DGEBAK: Back transformation
- *
- CALL DCHKBK( NIN, NOUT )
- GO TO 10
- ELSE IF( DGL ) THEN
- *
- * DGGBAL: Balancing
- *
- CALL DCHKGL( NIN, NOUT )
- GO TO 10
- ELSE IF( DGK ) THEN
- *
- * DGGBAK: Back transformation
- *
- CALL DCHKGK( NIN, NOUT )
- GO TO 10
- ELSE IF( LSAMEN( 3, PATH, 'DEC' ) ) THEN
- *
- * DEC: Eigencondition estimation
- *
- READ( NIN, FMT = * )THRESH
- CALL XLAENV( 1, 1 )
- CALL XLAENV( 12, 11 )
- CALL XLAENV( 13, 2 )
- CALL XLAENV( 14, 0 )
- CALL XLAENV( 15, 2 )
- CALL XLAENV( 16, 2 )
- TSTERR = .TRUE.
- CALL DCHKEC( THRESH, TSTERR, NIN, NOUT )
- GO TO 10
- ELSE
- WRITE( NOUT, FMT = 9992 )PATH
- GO TO 10
- END IF
- CALL ILAVER( VERS_MAJOR, VERS_MINOR, VERS_PATCH )
- WRITE( NOUT, FMT = 9972 ) VERS_MAJOR, VERS_MINOR, VERS_PATCH
- WRITE( NOUT, FMT = 9984 )
- *
- * Read the number of values of M, P, and N.
- *
- READ( NIN, FMT = * )NN
- IF( NN.LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' NN ', NN, 1
- NN = 0
- FATAL = .TRUE.
- ELSE IF( NN.GT.MAXIN ) THEN
- WRITE( NOUT, FMT = 9988 )' NN ', NN, MAXIN
- NN = 0
- FATAL = .TRUE.
- END IF
- *
- * Read the values of M
- *
- IF( .NOT.( DGX .OR. DXV ) ) THEN
- READ( NIN, FMT = * )( MVAL( I ), I = 1, NN )
- IF( SVD ) THEN
- VNAME = ' M '
- ELSE
- VNAME = ' N '
- END IF
- DO 20 I = 1, NN
- IF( MVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )VNAME, MVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( MVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )VNAME, MVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 20 CONTINUE
- WRITE( NOUT, FMT = 9983 )'M: ', ( MVAL( I ), I = 1, NN )
- END IF
- *
- * Read the values of P
- *
- IF( GLM .OR. GQR .OR. GSV .OR. LSE ) THEN
- READ( NIN, FMT = * )( PVAL( I ), I = 1, NN )
- DO 30 I = 1, NN
- IF( PVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' P ', PVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( PVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )' P ', PVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 30 CONTINUE
- WRITE( NOUT, FMT = 9983 )'P: ', ( PVAL( I ), I = 1, NN )
- END IF
- *
- * Read the values of N
- *
- IF( SVD .OR. DBB .OR. GLM .OR. GQR .OR. GSV .OR. LSE ) THEN
- READ( NIN, FMT = * )( NVAL( I ), I = 1, NN )
- DO 40 I = 1, NN
- IF( NVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' N ', NVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( NVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )' N ', NVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 40 CONTINUE
- ELSE
- DO 50 I = 1, NN
- NVAL( I ) = MVAL( I )
- 50 CONTINUE
- END IF
- IF( .NOT.( DGX .OR. DXV ) ) THEN
- WRITE( NOUT, FMT = 9983 )'N: ', ( NVAL( I ), I = 1, NN )
- ELSE
- WRITE( NOUT, FMT = 9983 )'N: ', NN
- END IF
- *
- * Read the number of values of K, followed by the values of K
- *
- IF( DSB .OR. DBB ) THEN
- READ( NIN, FMT = * )NK
- READ( NIN, FMT = * )( KVAL( I ), I = 1, NK )
- DO 60 I = 1, NK
- IF( KVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' K ', KVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( KVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )' K ', KVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 60 CONTINUE
- WRITE( NOUT, FMT = 9983 )'K: ', ( KVAL( I ), I = 1, NK )
- END IF
- *
- IF( DEV .OR. DES .OR. DVX .OR. DSX ) THEN
- *
- * For the nonsymmetric QR driver routines, only one set of
- * parameters is allowed.
- *
- READ( NIN, FMT = * )NBVAL( 1 ), NBMIN( 1 ), NXVAL( 1 ),
- $ INMIN( 1 ), INWIN( 1 ), INIBL(1), ISHFTS(1), IACC22(1)
- IF( NBVAL( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' NB ', NBVAL( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( NBMIN( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )'NBMIN ', NBMIN( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( NXVAL( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' NX ', NXVAL( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( INMIN( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' INMIN ', INMIN( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( INWIN( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' INWIN ', INWIN( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( INIBL( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' INIBL ', INIBL( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( ISHFTS( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' ISHFTS ', ISHFTS( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( IACC22( 1 ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' IACC22 ', IACC22( 1 ), 0
- FATAL = .TRUE.
- END IF
- CALL XLAENV( 1, NBVAL( 1 ) )
- CALL XLAENV( 2, NBMIN( 1 ) )
- CALL XLAENV( 3, NXVAL( 1 ) )
- CALL XLAENV(12, MAX( 11, INMIN( 1 ) ) )
- CALL XLAENV(13, INWIN( 1 ) )
- CALL XLAENV(14, INIBL( 1 ) )
- CALL XLAENV(15, ISHFTS( 1 ) )
- CALL XLAENV(16, IACC22( 1 ) )
- WRITE( NOUT, FMT = 9983 )'NB: ', NBVAL( 1 )
- WRITE( NOUT, FMT = 9983 )'NBMIN:', NBMIN( 1 )
- WRITE( NOUT, FMT = 9983 )'NX: ', NXVAL( 1 )
- WRITE( NOUT, FMT = 9983 )'INMIN: ', INMIN( 1 )
- WRITE( NOUT, FMT = 9983 )'INWIN: ', INWIN( 1 )
- WRITE( NOUT, FMT = 9983 )'INIBL: ', INIBL( 1 )
- WRITE( NOUT, FMT = 9983 )'ISHFTS: ', ISHFTS( 1 )
- WRITE( NOUT, FMT = 9983 )'IACC22: ', IACC22( 1 )
- *
- ELSEIF( DGS .OR. DGX .OR. DGV .OR. DXV ) THEN
- *
- * For the nonsymmetric generalized driver routines, only one set
- * of parameters is allowed.
- *
- READ( NIN, FMT = * )NBVAL( 1 ), NBMIN( 1 ), NXVAL( 1 ),
- $ NSVAL( 1 ), MXBVAL( 1 )
- IF( NBVAL( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' NB ', NBVAL( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( NBMIN( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )'NBMIN ', NBMIN( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( NXVAL( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' NX ', NXVAL( 1 ), 1
- FATAL = .TRUE.
- ELSE IF( NSVAL( 1 ).LT.2 ) THEN
- WRITE( NOUT, FMT = 9989 )' NS ', NSVAL( 1 ), 2
- FATAL = .TRUE.
- ELSE IF( MXBVAL( 1 ).LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )' MAXB ', MXBVAL( 1 ), 1
- FATAL = .TRUE.
- END IF
- CALL XLAENV( 1, NBVAL( 1 ) )
- CALL XLAENV( 2, NBMIN( 1 ) )
- CALL XLAENV( 3, NXVAL( 1 ) )
- CALL XLAENV( 4, NSVAL( 1 ) )
- CALL XLAENV( 8, MXBVAL( 1 ) )
- WRITE( NOUT, FMT = 9983 )'NB: ', NBVAL( 1 )
- WRITE( NOUT, FMT = 9983 )'NBMIN:', NBMIN( 1 )
- WRITE( NOUT, FMT = 9983 )'NX: ', NXVAL( 1 )
- WRITE( NOUT, FMT = 9983 )'NS: ', NSVAL( 1 )
- WRITE( NOUT, FMT = 9983 )'MAXB: ', MXBVAL( 1 )
- *
- ELSE IF( .NOT.DSB .AND. .NOT.GLM .AND. .NOT.GQR .AND. .NOT.
- $ GSV .AND. .NOT.LSE ) THEN
- *
- * For the other paths, the number of parameters can be varied
- * from the input file. Read the number of parameter values.
- *
- READ( NIN, FMT = * )NPARMS
- IF( NPARMS.LT.1 ) THEN
- WRITE( NOUT, FMT = 9989 )'NPARMS', NPARMS, 1
- NPARMS = 0
- FATAL = .TRUE.
- ELSE IF( NPARMS.GT.MAXIN ) THEN
- WRITE( NOUT, FMT = 9988 )'NPARMS', NPARMS, MAXIN
- NPARMS = 0
- FATAL = .TRUE.
- END IF
- *
- * Read the values of NB
- *
- IF( .NOT.DBB ) THEN
- READ( NIN, FMT = * )( NBVAL( I ), I = 1, NPARMS )
- DO 70 I = 1, NPARMS
- IF( NBVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' NB ', NBVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( NBVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )' NB ', NBVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 70 CONTINUE
- WRITE( NOUT, FMT = 9983 )'NB: ',
- $ ( NBVAL( I ), I = 1, NPARMS )
- END IF
- *
- * Read the values of NBMIN
- *
- IF( NEP .OR. SEP .OR. SVD .OR. DGG ) THEN
- READ( NIN, FMT = * )( NBMIN( I ), I = 1, NPARMS )
- DO 80 I = 1, NPARMS
- IF( NBMIN( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )'NBMIN ', NBMIN( I ), 0
- FATAL = .TRUE.
- ELSE IF( NBMIN( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )'NBMIN ', NBMIN( I ), NMAX
- FATAL = .TRUE.
- END IF
- 80 CONTINUE
- WRITE( NOUT, FMT = 9983 )'NBMIN:',
- $ ( NBMIN( I ), I = 1, NPARMS )
- ELSE
- DO 90 I = 1, NPARMS
- NBMIN( I ) = 1
- 90 CONTINUE
- END IF
- *
- * Read the values of NX
- *
- IF( NEP .OR. SEP .OR. SVD ) THEN
- READ( NIN, FMT = * )( NXVAL( I ), I = 1, NPARMS )
- DO 100 I = 1, NPARMS
- IF( NXVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' NX ', NXVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( NXVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )' NX ', NXVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 100 CONTINUE
- WRITE( NOUT, FMT = 9983 )'NX: ',
- $ ( NXVAL( I ), I = 1, NPARMS )
- ELSE
- DO 110 I = 1, NPARMS
- NXVAL( I ) = 1
- 110 CONTINUE
- END IF
- *
- * Read the values of NSHIFT (if DGG) or NRHS (if SVD
- * or DBB).
- *
- IF( SVD .OR. DBB .OR. DGG ) THEN
- READ( NIN, FMT = * )( NSVAL( I ), I = 1, NPARMS )
- DO 120 I = 1, NPARMS
- IF( NSVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' NS ', NSVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( NSVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )' NS ', NSVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 120 CONTINUE
- WRITE( NOUT, FMT = 9983 )'NS: ',
- $ ( NSVAL( I ), I = 1, NPARMS )
- ELSE
- DO 130 I = 1, NPARMS
- NSVAL( I ) = 1
- 130 CONTINUE
- END IF
- *
- * Read the values for MAXB.
- *
- IF( DGG ) THEN
- READ( NIN, FMT = * )( MXBVAL( I ), I = 1, NPARMS )
- DO 140 I = 1, NPARMS
- IF( MXBVAL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' MAXB ', MXBVAL( I ), 0
- FATAL = .TRUE.
- ELSE IF( MXBVAL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )' MAXB ', MXBVAL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 140 CONTINUE
- WRITE( NOUT, FMT = 9983 )'MAXB: ',
- $ ( MXBVAL( I ), I = 1, NPARMS )
- ELSE
- DO 150 I = 1, NPARMS
- MXBVAL( I ) = 1
- 150 CONTINUE
- END IF
- *
- * Read the values for INMIN.
- *
- IF( NEP ) THEN
- READ( NIN, FMT = * )( INMIN( I ), I = 1, NPARMS )
- DO 540 I = 1, NPARMS
- IF( INMIN( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' INMIN ', INMIN( I ), 0
- FATAL = .TRUE.
- END IF
- 540 CONTINUE
- WRITE( NOUT, FMT = 9983 )'INMIN: ',
- $ ( INMIN( I ), I = 1, NPARMS )
- ELSE
- DO 550 I = 1, NPARMS
- INMIN( I ) = 1
- 550 CONTINUE
- END IF
- *
- * Read the values for INWIN.
- *
- IF( NEP ) THEN
- READ( NIN, FMT = * )( INWIN( I ), I = 1, NPARMS )
- DO 560 I = 1, NPARMS
- IF( INWIN( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' INWIN ', INWIN( I ), 0
- FATAL = .TRUE.
- END IF
- 560 CONTINUE
- WRITE( NOUT, FMT = 9983 )'INWIN: ',
- $ ( INWIN( I ), I = 1, NPARMS )
- ELSE
- DO 570 I = 1, NPARMS
- INWIN( I ) = 1
- 570 CONTINUE
- END IF
- *
- * Read the values for INIBL.
- *
- IF( NEP ) THEN
- READ( NIN, FMT = * )( INIBL( I ), I = 1, NPARMS )
- DO 580 I = 1, NPARMS
- IF( INIBL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' INIBL ', INIBL( I ), 0
- FATAL = .TRUE.
- END IF
- 580 CONTINUE
- WRITE( NOUT, FMT = 9983 )'INIBL: ',
- $ ( INIBL( I ), I = 1, NPARMS )
- ELSE
- DO 590 I = 1, NPARMS
- INIBL( I ) = 1
- 590 CONTINUE
- END IF
- *
- * Read the values for ISHFTS.
- *
- IF( NEP ) THEN
- READ( NIN, FMT = * )( ISHFTS( I ), I = 1, NPARMS )
- DO 600 I = 1, NPARMS
- IF( ISHFTS( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' ISHFTS ', ISHFTS( I ), 0
- FATAL = .TRUE.
- END IF
- 600 CONTINUE
- WRITE( NOUT, FMT = 9983 )'ISHFTS: ',
- $ ( ISHFTS( I ), I = 1, NPARMS )
- ELSE
- DO 610 I = 1, NPARMS
- ISHFTS( I ) = 1
- 610 CONTINUE
- END IF
- *
- * Read the values for IACC22.
- *
- IF( NEP ) THEN
- READ( NIN, FMT = * )( IACC22( I ), I = 1, NPARMS )
- DO 620 I = 1, NPARMS
- IF( IACC22( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )' IACC22 ', IACC22( I ), 0
- FATAL = .TRUE.
- END IF
- 620 CONTINUE
- WRITE( NOUT, FMT = 9983 )'IACC22: ',
- $ ( IACC22( I ), I = 1, NPARMS )
- ELSE
- DO 630 I = 1, NPARMS
- IACC22( I ) = 1
- 630 CONTINUE
- END IF
- *
- * Read the values for NBCOL.
- *
- IF( DGG ) THEN
- READ( NIN, FMT = * )( NBCOL( I ), I = 1, NPARMS )
- DO 160 I = 1, NPARMS
- IF( NBCOL( I ).LT.0 ) THEN
- WRITE( NOUT, FMT = 9989 )'NBCOL ', NBCOL( I ), 0
- FATAL = .TRUE.
- ELSE IF( NBCOL( I ).GT.NMAX ) THEN
- WRITE( NOUT, FMT = 9988 )'NBCOL ', NBCOL( I ), NMAX
- FATAL = .TRUE.
- END IF
- 160 CONTINUE
- WRITE( NOUT, FMT = 9983 )'NBCOL:',
- $ ( NBCOL( I ), I = 1, NPARMS )
- ELSE
- DO 170 I = 1, NPARMS
- NBCOL( I ) = 1
- 170 CONTINUE
- END IF
- END IF
- *
- * Calculate and print the machine dependent constants.
- *
- WRITE( NOUT, FMT = * )
- EPS = DLAMCH( 'Underflow threshold' )
- WRITE( NOUT, FMT = 9981 )'underflow', EPS
- EPS = DLAMCH( 'Overflow threshold' )
- WRITE( NOUT, FMT = 9981 )'overflow ', EPS
- EPS = DLAMCH( 'Epsilon' )
- WRITE( NOUT, FMT = 9981 )'precision', EPS
- *
- * Read the threshold value for the test ratios.
- *
- READ( NIN, FMT = * )THRESH
- WRITE( NOUT, FMT = 9982 )THRESH
- IF( SEP .OR. SVD .OR. DGG ) THEN
- *
- * Read the flag that indicates whether to test LAPACK routines.
- *
- READ( NIN, FMT = * )TSTCHK
- *
- * Read the flag that indicates whether to test driver routines.
- *
- READ( NIN, FMT = * )TSTDRV
- END IF
- *
- * Read the flag that indicates whether to test the error exits.
- *
- READ( NIN, FMT = * )TSTERR
- *
- * Read the code describing how to set the random number seed.
- *
- READ( NIN, FMT = * )NEWSD
- *
- * If NEWSD = 2, read another line with 4 integers for the seed.
- *
- IF( NEWSD.EQ.2 )
- $ READ( NIN, FMT = * )( IOLDSD( I ), I = 1, 4 )
- *
- DO 180 I = 1, 4
- ISEED( I ) = IOLDSD( I )
- 180 CONTINUE
- *
- IF( FATAL ) THEN
- WRITE( NOUT, FMT = 9999 )
- STOP
- END IF
- *
- * Read the input lines indicating the test path and its parameters.
- * The first three characters indicate the test path, and the number
- * of test matrix types must be the first nonblank item in columns
- * 4-80.
- *
- 190 CONTINUE
- *
- IF( .NOT.( DGX .OR. DXV ) ) THEN
- *
- 200 CONTINUE
- READ( NIN, FMT = '(A80)', END = 380 )LINE
- C3 = LINE( 1: 3 )
- LENP = LEN( LINE )
- I = 3
- ITMP = 0
- I1 = 0
- 210 CONTINUE
- I = I + 1
- IF( I.GT.LENP ) THEN
- IF( I1.GT.0 ) THEN
- GO TO 240
- ELSE
- NTYPES = MAXT
- GO TO 240
- END IF
- END IF
- IF( LINE( I: I ).NE.' ' .AND. LINE( I: I ).NE.',' ) THEN
- I1 = I
- C1 = LINE( I1: I1 )
- *
- * Check that a valid integer was read
- *
- DO 220 K = 1, 10
- IF( C1.EQ.INTSTR( K: K ) ) THEN
- IC = K - 1
- GO TO 230
- END IF
- 220 CONTINUE
- WRITE( NOUT, FMT = 9991 )I, LINE
- GO TO 200
- 230 CONTINUE
- ITMP = 10*ITMP + IC
- GO TO 210
- ELSE IF( I1.GT.0 ) THEN
- GO TO 240
- ELSE
- GO TO 210
- END IF
- 240 CONTINUE
- NTYPES = ITMP
- *
- * Skip the tests if NTYPES is <= 0.
- *
- IF( .NOT.( DEV .OR. DES .OR. DVX .OR. DSX .OR. DGV .OR.
- $ DGS ) .AND. NTYPES.LE.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- GO TO 200
- END IF
- *
- ELSE
- IF( DXV )
- $ C3 = 'DXV'
- IF( DGX )
- $ C3 = 'DGX'
- END IF
- *
- * Reset the random number seed.
- *
- IF( NEWSD.EQ.0 ) THEN
- DO 250 K = 1, 4
- ISEED( K ) = IOLDSD( K )
- 250 CONTINUE
- END IF
- *
- IF( LSAMEN( 3, C3, 'DHS' ) .OR. LSAMEN( 3, C3, 'NEP' ) ) THEN
- *
- * -------------------------------------
- * NEP: Nonsymmetric Eigenvalue Problem
- * -------------------------------------
- * Vary the parameters
- * NB = block size
- * NBMIN = minimum block size
- * NX = crossover point
- * NS = number of shifts
- * MAXB = minimum submatrix size
- *
- MAXTYP = 21
- NTYPES = MIN( MAXTYP, NTYPES )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL XLAENV( 1, 1 )
- IF( TSTERR )
- $ CALL DERRHS( 'DHSEQR', NOUT )
- DO 270 I = 1, NPARMS
- CALL XLAENV( 1, NBVAL( I ) )
- CALL XLAENV( 2, NBMIN( I ) )
- CALL XLAENV( 3, NXVAL( I ) )
- CALL XLAENV(12, MAX( 11, INMIN( I ) ) )
- CALL XLAENV(13, INWIN( I ) )
- CALL XLAENV(14, INIBL( I ) )
- CALL XLAENV(15, ISHFTS( I ) )
- CALL XLAENV(16, IACC22( I ) )
- *
- IF( NEWSD.EQ.0 ) THEN
- DO 260 K = 1, 4
- ISEED( K ) = IOLDSD( K )
- 260 CONTINUE
- END IF
- WRITE( NOUT, FMT = 9961 )C3, NBVAL( I ), NBMIN( I ),
- $ NXVAL( I ), MAX( 11, INMIN(I)),
- $ INWIN( I ), INIBL( I ), ISHFTS( I ), IACC22( I )
- CALL DCHKHS( NN, NVAL, MAXTYP, DOTYPE, ISEED, THRESH, NOUT,
- $ A( 1, 1 ), NMAX, A( 1, 2 ), A( 1, 3 ),
- $ A( 1, 4 ), A( 1, 5 ), NMAX, A( 1, 6 ),
- $ A( 1, 7 ), D( 1, 1 ), D( 1, 2 ), D( 1, 3 ),
- $ D( 1, 4 ), A( 1, 8 ), A( 1, 9 ), A( 1, 10 ),
- $ A( 1, 11 ), A( 1, 12 ), D( 1, 5 ), WORK, LWORK,
- $ IWORK, LOGWRK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCHKHS', INFO
- 270 CONTINUE
- *
- ELSE IF( LSAMEN( 3, C3, 'DST' ) .OR. LSAMEN( 3, C3, 'SEP' ) ) THEN
- *
- * ----------------------------------
- * SEP: Symmetric Eigenvalue Problem
- * ----------------------------------
- * Vary the parameters
- * NB = block size
- * NBMIN = minimum block size
- * NX = crossover point
- *
- MAXTYP = 21
- NTYPES = MIN( MAXTYP, NTYPES )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL XLAENV( 1, 1 )
- CALL XLAENV( 9, 25 )
- IF( TSTERR )
- $ CALL DERRST( 'DST', NOUT )
- DO 290 I = 1, NPARMS
- CALL XLAENV( 1, NBVAL( I ) )
- CALL XLAENV( 2, NBMIN( I ) )
- CALL XLAENV( 3, NXVAL( I ) )
- *
- IF( NEWSD.EQ.0 ) THEN
- DO 280 K = 1, 4
- ISEED( K ) = IOLDSD( K )
- 280 CONTINUE
- END IF
- WRITE( NOUT, FMT = 9997 )C3, NBVAL( I ), NBMIN( I ),
- $ NXVAL( I )
- IF( TSTCHK ) THEN
- CALL DCHKST( NN, NVAL, MAXTYP, DOTYPE, ISEED, THRESH,
- $ NOUT, A( 1, 1 ), NMAX, A( 1, 2 ), D( 1, 1 ),
- $ D( 1, 2 ), D( 1, 3 ), D( 1, 4 ), D( 1, 5 ),
- $ D( 1, 6 ), D( 1, 7 ), D( 1, 8 ), D( 1, 9 ),
- $ D( 1, 10 ), D( 1, 11 ), A( 1, 3 ), NMAX,
- $ A( 1, 4 ), A( 1, 5 ), D( 1, 12 ), A( 1, 6 ),
- $ WORK, LWORK, IWORK, LIWORK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCHKST', INFO
- END IF
- IF( TSTDRV ) THEN
- CALL DDRVST( NN, NVAL, 18, DOTYPE, ISEED, THRESH, NOUT,
- $ A( 1, 1 ), NMAX, D( 1, 3 ), D( 1, 4 ),
- $ D( 1, 5 ), D( 1, 6 ), D( 1, 8 ), D( 1, 9 ),
- $ D( 1, 10 ), D( 1, 11 ), A( 1, 2 ), NMAX,
- $ A( 1, 3 ), D( 1, 12 ), A( 1, 4 ), WORK,
- $ LWORK, IWORK, LIWORK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DDRVST', INFO
- END IF
- 290 CONTINUE
- *
- ELSE IF( LSAMEN( 3, C3, 'DSG' ) ) THEN
- *
- * ----------------------------------------------
- * DSG: Symmetric Generalized Eigenvalue Problem
- * ----------------------------------------------
- * Vary the parameters
- * NB = block size
- * NBMIN = minimum block size
- * NX = crossover point
- *
- MAXTYP = 21
- NTYPES = MIN( MAXTYP, NTYPES )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL XLAENV( 9, 25 )
- DO 310 I = 1, NPARMS
- CALL XLAENV( 1, NBVAL( I ) )
- CALL XLAENV( 2, NBMIN( I ) )
- CALL XLAENV( 3, NXVAL( I ) )
- *
- IF( NEWSD.EQ.0 ) THEN
- DO 300 K = 1, 4
- ISEED( K ) = IOLDSD( K )
- 300 CONTINUE
- END IF
- WRITE( NOUT, FMT = 9997 )C3, NBVAL( I ), NBMIN( I ),
- $ NXVAL( I )
- IF( TSTCHK ) THEN
- CALL DDRVSG( NN, NVAL, MAXTYP, DOTYPE, ISEED, THRESH,
- $ NOUT, A( 1, 1 ), NMAX, A( 1, 2 ), NMAX,
- $ D( 1, 3 ), A( 1, 3 ), NMAX, A( 1, 4 ),
- $ A( 1, 5 ), A( 1, 6 ), A( 1, 7 ), WORK,
- $ LWORK, IWORK, LIWORK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DDRVSG', INFO
- END IF
- 310 CONTINUE
- *
- ELSE IF( LSAMEN( 3, C3, 'DBD' ) .OR. LSAMEN( 3, C3, 'SVD' ) ) THEN
- *
- * ----------------------------------
- * SVD: Singular Value Decomposition
- * ----------------------------------
- * Vary the parameters
- * NB = block size
- * NBMIN = minimum block size
- * NX = crossover point
- * NRHS = number of right hand sides
- *
- MAXTYP = 16
- NTYPES = MIN( MAXTYP, NTYPES )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL XLAENV( 1, 1 )
- CALL XLAENV( 9, 25 )
- *
- * Test the error exits
- *
- IF( TSTERR .AND. TSTCHK )
- $ CALL DERRBD( 'DBD', NOUT )
- IF( TSTERR .AND. TSTDRV )
- $ CALL DERRED( 'DBD', NOUT )
- *
- DO 330 I = 1, NPARMS
- NRHS = NSVAL( I )
- CALL XLAENV( 1, NBVAL( I ) )
- CALL XLAENV( 2, NBMIN( I ) )
- CALL XLAENV( 3, NXVAL( I ) )
- IF( NEWSD.EQ.0 ) THEN
- DO 320 K = 1, 4
- ISEED( K ) = IOLDSD( K )
- 320 CONTINUE
- END IF
- WRITE( NOUT, FMT = 9995 )C3, NBVAL( I ), NBMIN( I ),
- $ NXVAL( I ), NRHS
- IF( TSTCHK ) THEN
- CALL DCHKBD( NN, MVAL, NVAL, MAXTYP, DOTYPE, NRHS, ISEED,
- $ THRESH, A( 1, 1 ), NMAX, D( 1, 1 ),
- $ D( 1, 2 ), D( 1, 3 ), D( 1, 4 ), A( 1, 2 ),
- $ NMAX, A( 1, 3 ), A( 1, 4 ), A( 1, 5 ), NMAX,
- $ A( 1, 6 ), NMAX, A( 1, 7 ), A( 1, 8 ), WORK,
- $ LWORK, IWORK, NOUT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCHKBD', INFO
- END IF
- IF( TSTDRV )
- $ CALL DDRVBD( NN, MVAL, NVAL, MAXTYP, DOTYPE, ISEED,
- $ THRESH, A( 1, 1 ), NMAX, A( 1, 2 ), NMAX,
- $ A( 1, 3 ), NMAX, A( 1, 4 ), A( 1, 5 ),
- $ A( 1, 6 ), D( 1, 1 ), D( 1, 2 ), D( 1, 3 ),
- $ WORK, LWORK, IWORK, NOUT, INFO )
- 330 CONTINUE
- *
- ELSE IF( LSAMEN( 3, C3, 'DEV' ) ) THEN
- *
- * --------------------------------------------
- * DEV: Nonsymmetric Eigenvalue Problem Driver
- * DGEEV (eigenvalues and eigenvectors)
- * --------------------------------------------
- *
- MAXTYP = 21
- NTYPES = MIN( MAXTYP, NTYPES )
- IF( NTYPES.LE.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRED( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL DDRVEV( NN, NVAL, NTYPES, DOTYPE, ISEED, THRESH, NOUT,
- $ A( 1, 1 ), NMAX, A( 1, 2 ), D( 1, 1 ),
- $ D( 1, 2 ), D( 1, 3 ), D( 1, 4 ), A( 1, 3 ),
- $ NMAX, A( 1, 4 ), NMAX, A( 1, 5 ), NMAX, RESULT,
- $ WORK, LWORK, IWORK, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DGEEV', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( LSAMEN( 3, C3, 'DES' ) ) THEN
- *
- * --------------------------------------------
- * DES: Nonsymmetric Eigenvalue Problem Driver
- * DGEES (Schur form)
- * --------------------------------------------
- *
- MAXTYP = 21
- NTYPES = MIN( MAXTYP, NTYPES )
- IF( NTYPES.LE.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRED( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL DDRVES( NN, NVAL, NTYPES, DOTYPE, ISEED, THRESH, NOUT,
- $ A( 1, 1 ), NMAX, A( 1, 2 ), A( 1, 3 ),
- $ D( 1, 1 ), D( 1, 2 ), D( 1, 3 ), D( 1, 4 ),
- $ A( 1, 4 ), NMAX, RESULT, WORK, LWORK, IWORK,
- $ LOGWRK, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DGEES', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( LSAMEN( 3, C3, 'DVX' ) ) THEN
- *
- * --------------------------------------------------------------
- * DVX: Nonsymmetric Eigenvalue Problem Expert Driver
- * DGEEVX (eigenvalues, eigenvectors and condition numbers)
- * --------------------------------------------------------------
- *
- MAXTYP = 21
- NTYPES = MIN( MAXTYP, NTYPES )
- IF( NTYPES.LT.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRED( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL DDRVVX( NN, NVAL, NTYPES, DOTYPE, ISEED, THRESH, NIN,
- $ NOUT, A( 1, 1 ), NMAX, A( 1, 2 ), D( 1, 1 ),
- $ D( 1, 2 ), D( 1, 3 ), D( 1, 4 ), A( 1, 3 ),
- $ NMAX, A( 1, 4 ), NMAX, A( 1, 5 ), NMAX,
- $ D( 1, 5 ), D( 1, 6 ), D( 1, 7 ), D( 1, 8 ),
- $ D( 1, 9 ), D( 1, 10 ), D( 1, 11 ), D( 1, 12 ),
- $ RESULT, WORK, LWORK, IWORK, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DGEEVX', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( LSAMEN( 3, C3, 'DSX' ) ) THEN
- *
- * ---------------------------------------------------
- * DSX: Nonsymmetric Eigenvalue Problem Expert Driver
- * DGEESX (Schur form and condition numbers)
- * ---------------------------------------------------
- *
- MAXTYP = 21
- NTYPES = MIN( MAXTYP, NTYPES )
- IF( NTYPES.LT.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRED( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL DDRVSX( NN, NVAL, NTYPES, DOTYPE, ISEED, THRESH, NIN,
- $ NOUT, A( 1, 1 ), NMAX, A( 1, 2 ), A( 1, 3 ),
- $ D( 1, 1 ), D( 1, 2 ), D( 1, 3 ), D( 1, 4 ),
- $ D( 1, 5 ), D( 1, 6 ), A( 1, 4 ), NMAX,
- $ A( 1, 5 ), RESULT, WORK, LWORK, IWORK, LOGWRK,
- $ INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DGEESX', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( LSAMEN( 3, C3, 'DGG' ) ) THEN
- *
- * -------------------------------------------------
- * DGG: Generalized Nonsymmetric Eigenvalue Problem
- * -------------------------------------------------
- * Vary the parameters
- * NB = block size
- * NBMIN = minimum block size
- * NS = number of shifts
- * MAXB = minimum submatrix size
- * NBCOL = minimum column dimension for blocks
- *
- MAXTYP = 26
- NTYPES = MIN( MAXTYP, NTYPES )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- IF( TSTCHK .AND. TSTERR )
- $ CALL DERRGG( C3, NOUT )
- DO 350 I = 1, NPARMS
- CALL XLAENV( 1, NBVAL( I ) )
- CALL XLAENV( 2, NBMIN( I ) )
- CALL XLAENV( 4, NSVAL( I ) )
- CALL XLAENV( 8, MXBVAL( I ) )
- CALL XLAENV( 5, NBCOL( I ) )
- *
- IF( NEWSD.EQ.0 ) THEN
- DO 340 K = 1, 4
- ISEED( K ) = IOLDSD( K )
- 340 CONTINUE
- END IF
- WRITE( NOUT, FMT = 9996 )C3, NBVAL( I ), NBMIN( I ),
- $ NSVAL( I ), MXBVAL( I ), NBCOL( I )
- TSTDIF = .FALSE.
- THRSHN = 10.D0
- IF( TSTCHK ) THEN
- CALL DCHKGG( NN, NVAL, MAXTYP, DOTYPE, ISEED, THRESH,
- $ TSTDIF, THRSHN, NOUT, A( 1, 1 ), NMAX,
- $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), A( 1, 5 ),
- $ A( 1, 6 ), A( 1, 7 ), A( 1, 8 ), A( 1, 9 ),
- $ NMAX, A( 1, 10 ), A( 1, 11 ), A( 1, 12 ),
- $ D( 1, 1 ), D( 1, 2 ), D( 1, 3 ), D( 1, 4 ),
- $ D( 1, 5 ), D( 1, 6 ), A( 1, 13 ),
- $ A( 1, 14 ), WORK, LWORK, LOGWRK, RESULT,
- $ INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCHKGG', INFO
- END IF
- CALL XLAENV( 1, 1 )
- IF( TSTDRV ) THEN
- CALL DDRVGG( NN, NVAL, MAXTYP, DOTYPE, ISEED, THRESH,
- $ THRSHN, NOUT, A( 1, 1 ), NMAX, A( 1, 2 ),
- $ A( 1, 3 ), A( 1, 4 ), A( 1, 5 ), A( 1, 6 ),
- $ A( 1, 7 ), NMAX, A( 1, 8 ), D( 1, 1 ),
- $ D( 1, 2 ), D( 1, 3 ), D( 1, 4 ), D( 1, 5 ),
- $ D( 1, 6 ), A( 1, 13 ), A( 1, 14 ), WORK,
- $ LWORK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DDRVGG', INFO
- END IF
- 350 CONTINUE
- *
- ELSE IF( LSAMEN( 3, C3, 'DGS' ) ) THEN
- *
- * -------------------------------------------------
- * DGS: Generalized Nonsymmetric Eigenvalue Problem
- * DGGES (Schur form)
- * -------------------------------------------------
- *
- MAXTYP = 26
- NTYPES = MIN( MAXTYP, NTYPES )
- IF( NTYPES.LE.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRGG( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL DDRGES( NN, NVAL, MAXTYP, DOTYPE, ISEED, THRESH, NOUT,
- $ A( 1, 1 ), NMAX, A( 1, 2 ), A( 1, 3 ),
- $ A( 1, 4 ), A( 1, 7 ), NMAX, A( 1, 8 ),
- $ D( 1, 1 ), D( 1, 2 ), D( 1, 3 ), WORK, LWORK,
- $ RESULT, LOGWRK, INFO )
- *
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DDRGES', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( DGX ) THEN
- *
- * -------------------------------------------------
- * DGX: Generalized Nonsymmetric Eigenvalue Problem
- * DGGESX (Schur form and condition numbers)
- * -------------------------------------------------
- *
- MAXTYP = 5
- NTYPES = MAXTYP
- IF( NN.LT.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRGG( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL XLAENV( 5, 2 )
- CALL DDRGSX( NN, NCMAX, THRESH, NIN, NOUT, A( 1, 1 ), NMAX,
- $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), A( 1, 5 ),
- $ A( 1, 6 ), D( 1, 1 ), D( 1, 2 ), D( 1, 3 ),
- $ C( 1, 1 ), NCMAX*NCMAX, A( 1, 12 ), WORK,
- $ LWORK, IWORK, LIWORK, LOGWRK, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DDRGSX', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( LSAMEN( 3, C3, 'DGV' ) ) THEN
- *
- * -------------------------------------------------
- * DGV: Generalized Nonsymmetric Eigenvalue Problem
- * DGGEV (Eigenvalue/vector form)
- * -------------------------------------------------
- *
- MAXTYP = 26
- NTYPES = MIN( MAXTYP, NTYPES )
- IF( NTYPES.LE.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRGG( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL DDRGEV( NN, NVAL, MAXTYP, DOTYPE, ISEED, THRESH, NOUT,
- $ A( 1, 1 ), NMAX, A( 1, 2 ), A( 1, 3 ),
- $ A( 1, 4 ), A( 1, 7 ), NMAX, A( 1, 8 ),
- $ A( 1, 9 ), NMAX, D( 1, 1 ), D( 1, 2 ),
- $ D( 1, 3 ), D( 1, 4 ), D( 1, 5 ), D( 1, 6 ),
- $ WORK, LWORK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DDRGEV', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( DXV ) THEN
- *
- * -------------------------------------------------
- * DXV: Generalized Nonsymmetric Eigenvalue Problem
- * DGGEVX (eigenvalue/vector with condition numbers)
- * -------------------------------------------------
- *
- MAXTYP = 2
- NTYPES = MAXTYP
- IF( NN.LT.0 ) THEN
- WRITE( NOUT, FMT = 9990 )C3
- ELSE
- IF( TSTERR )
- $ CALL DERRGG( C3, NOUT )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- CALL DDRGVX( NN, THRESH, NIN, NOUT, A( 1, 1 ), NMAX,
- $ A( 1, 2 ), A( 1, 3 ), A( 1, 4 ), D( 1, 1 ),
- $ D( 1, 2 ), D( 1, 3 ), A( 1, 5 ), A( 1, 6 ),
- $ IWORK( 1 ), IWORK( 2 ), D( 1, 4 ), D( 1, 5 ),
- $ D( 1, 6 ), D( 1, 7 ), D( 1, 8 ), D( 1, 9 ),
- $ WORK, LWORK, IWORK( 3 ), LIWORK-2, RESULT,
- $ LOGWRK, INFO )
- *
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DDRGVX', INFO
- END IF
- WRITE( NOUT, FMT = 9973 )
- GO TO 10
- *
- ELSE IF( LSAMEN( 3, C3, 'DSB' ) ) THEN
- *
- * ------------------------------
- * DSB: Symmetric Band Reduction
- * ------------------------------
- *
- MAXTYP = 15
- NTYPES = MIN( MAXTYP, NTYPES )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- IF( TSTERR )
- $ CALL DERRST( 'DSB', NOUT )
- CALL DCHKSB( NN, NVAL, NK, KVAL, MAXTYP, DOTYPE, ISEED, THRESH,
- $ NOUT, A( 1, 1 ), NMAX, D( 1, 1 ), D( 1, 2 ),
- $ A( 1, 2 ), NMAX, WORK, LWORK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCHKSB', INFO
- *
- ELSE IF( LSAMEN( 3, C3, 'DBB' ) ) THEN
- *
- * ------------------------------
- * DBB: General Band Reduction
- * ------------------------------
- *
- MAXTYP = 15
- NTYPES = MIN( MAXTYP, NTYPES )
- CALL ALAREQ( C3, NTYPES, DOTYPE, MAXTYP, NIN, NOUT )
- DO 370 I = 1, NPARMS
- NRHS = NSVAL( I )
- *
- IF( NEWSD.EQ.0 ) THEN
- DO 360 K = 1, 4
- ISEED( K ) = IOLDSD( K )
- 360 CONTINUE
- END IF
- WRITE( NOUT, FMT = 9966 )C3, NRHS
- CALL DCHKBB( NN, MVAL, NVAL, NK, KVAL, MAXTYP, DOTYPE, NRHS,
- $ ISEED, THRESH, NOUT, A( 1, 1 ), NMAX,
- $ A( 1, 2 ), 2*NMAX, D( 1, 1 ), D( 1, 2 ),
- $ A( 1, 4 ), NMAX, A( 1, 5 ), NMAX, A( 1, 6 ),
- $ NMAX, A( 1, 7 ), WORK, LWORK, RESULT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCHKBB', INFO
- 370 CONTINUE
- *
- ELSE IF( LSAMEN( 3, C3, 'GLM' ) ) THEN
- *
- * -----------------------------------------
- * GLM: Generalized Linear Regression Model
- * -----------------------------------------
- *
- CALL XLAENV( 1, 1 )
- IF( TSTERR )
- $ CALL DERRGG( 'GLM', NOUT )
- CALL DCKGLM( NN, MVAL, PVAL, NVAL, NTYPES, ISEED, THRESH, NMAX,
- $ A( 1, 1 ), A( 1, 2 ), B( 1, 1 ), B( 1, 2 ), X,
- $ WORK, D( 1, 1 ), NIN, NOUT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCKGLM', INFO
- *
- ELSE IF( LSAMEN( 3, C3, 'GQR' ) ) THEN
- *
- * ------------------------------------------
- * GQR: Generalized QR and RQ factorizations
- * ------------------------------------------
- *
- CALL XLAENV( 1, 1 )
- IF( TSTERR )
- $ CALL DERRGG( 'GQR', NOUT )
- CALL DCKGQR( NN, MVAL, NN, PVAL, NN, NVAL, NTYPES, ISEED,
- $ THRESH, NMAX, A( 1, 1 ), A( 1, 2 ), A( 1, 3 ),
- $ A( 1, 4 ), TAUA, B( 1, 1 ), B( 1, 2 ), B( 1, 3 ),
- $ B( 1, 4 ), B( 1, 5 ), TAUB, WORK, D( 1, 1 ), NIN,
- $ NOUT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCKGQR', INFO
- *
- ELSE IF( LSAMEN( 3, C3, 'GSV' ) ) THEN
- *
- * ----------------------------------------------
- * GSV: Generalized Singular Value Decomposition
- * ----------------------------------------------
- *
- IF( TSTERR )
- $ CALL DERRGG( 'GSV', NOUT )
- CALL DCKGSV( NN, MVAL, PVAL, NVAL, NTYPES, ISEED, THRESH, NMAX,
- $ A( 1, 1 ), A( 1, 2 ), B( 1, 1 ), B( 1, 2 ),
- $ A( 1, 3 ), B( 1, 3 ), A( 1, 4 ), TAUA, TAUB,
- $ B( 1, 4 ), IWORK, WORK, D( 1, 1 ), NIN, NOUT,
- $ INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCKGSV', INFO
- *
- ELSE IF( LSAMEN( 3, C3, 'LSE' ) ) THEN
- *
- * --------------------------------------
- * LSE: Constrained Linear Least Squares
- * --------------------------------------
- *
- CALL XLAENV( 1, 1 )
- IF( TSTERR )
- $ CALL DERRGG( 'LSE', NOUT )
- CALL DCKLSE( NN, MVAL, PVAL, NVAL, NTYPES, ISEED, THRESH, NMAX,
- $ A( 1, 1 ), A( 1, 2 ), B( 1, 1 ), B( 1, 2 ), X,
- $ WORK, D( 1, 1 ), NIN, NOUT, INFO )
- IF( INFO.NE.0 )
- $ WRITE( NOUT, FMT = 9980 )'DCKLSE', INFO
- *
- ELSE
- WRITE( NOUT, FMT = * )
- WRITE( NOUT, FMT = * )
- WRITE( NOUT, FMT = 9992 )C3
- END IF
- IF( .NOT.( DGX .OR. DXV ) )
- $ GO TO 190
- 380 CONTINUE
- WRITE( NOUT, FMT = 9994 )
- S2 = DSECND( )
- WRITE( NOUT, FMT = 9993 )S2 - S1
- *
- 9999 FORMAT( / ' Execution not attempted due to input errors' )
- 9998 FORMAT( / / 1X, A3, ': NB =', I4, ', NBMIN =', I4, ', NX =', I4,
- $ ', NS =', I4, ', MAXB =', I4 )
- 9997 FORMAT( / / 1X, A3, ': NB =', I4, ', NBMIN =', I4, ', NX =', I4 )
- 9996 FORMAT( / / 1X, A3, ': NB =', I4, ', NBMIN =', I4, ', NS =', I4,
- $ ', MAXB =', I4, ', NBCOL =', I4 )
- 9995 FORMAT( / / 1X, A3, ': NB =', I4, ', NBMIN =', I4, ', NX =', I4,
- $ ', NRHS =', I4 )
- 9994 FORMAT( / / ' End of tests' )
- 9993 FORMAT( ' Total time used = ', F12.2, ' seconds', / )
- 9992 FORMAT( 1X, A3, ': Unrecognized path name' )
- 9991 FORMAT( / / ' *** Invalid integer value in column ', I2,
- $ ' of input', ' line:', / A79 )
- 9990 FORMAT( / / 1X, A3, ' routines were not tested' )
- 9989 FORMAT( ' Invalid input value: ', A6, '=', I6, '; must be >=',
- $ I6 )
- 9988 FORMAT( ' Invalid input value: ', A6, '=', I6, '; must be <=',
- $ I6 )
- 9987 FORMAT( ' Tests of the Nonsymmetric Eigenvalue Problem routines' )
- 9986 FORMAT( ' Tests of the Symmetric Eigenvalue Problem routines' )
- 9985 FORMAT( ' Tests of the Singular Value Decomposition routines' )
- 9984 FORMAT( / ' The following parameter values will be used:' )
- 9983 FORMAT( 4X, A6, 10I6, / 10X, 10I6 )
- 9982 FORMAT( / ' Routines pass computational tests if test ratio is ',
- $ 'less than', F8.2, / )
- 9981 FORMAT( ' Relative machine ', A, ' is taken to be', D16.6 )
- 9980 FORMAT( ' *** Error code from ', A6, ' = ', I4 )
- 9979 FORMAT( / ' Tests of the Nonsymmetric Eigenvalue Problem Driver',
- $ / ' DGEEV (eigenvalues and eigevectors)' )
- 9978 FORMAT( / ' Tests of the Nonsymmetric Eigenvalue Problem Driver',
- $ / ' DGEES (Schur form)' )
- 9977 FORMAT( / ' Tests of the Nonsymmetric Eigenvalue Problem Expert',
- $ ' Driver', / ' DGEEVX (eigenvalues, eigenvectors and',
- $ ' condition numbers)' )
- 9976 FORMAT( / ' Tests of the Nonsymmetric Eigenvalue Problem Expert',
- $ ' Driver', / ' DGEESX (Schur form and condition',
- $ ' numbers)' )
- 9975 FORMAT( / ' Tests of the Generalized Nonsymmetric Eigenvalue ',
- $ 'Problem routines' )
- 9974 FORMAT( ' Tests of DSBTRD', / ' (reduction of a symmetric band ',
- $ 'matrix to tridiagonal form)' )
- 9973 FORMAT( / 1X, 71( '-' ) )
- 9972 FORMAT( / ' LAPACK VERSION ', I1, '.', I1, '.', I1 )
- 9971 FORMAT( / ' Tests of the Generalized Linear Regression Model ',
- $ 'routines' )
- 9970 FORMAT( / ' Tests of the Generalized QR and RQ routines' )
- 9969 FORMAT( / ' Tests of the Generalized Singular Value',
- $ ' Decomposition routines' )
- 9968 FORMAT( / ' Tests of the Linear Least Squares routines' )
- 9967 FORMAT( ' Tests of DGBBRD', / ' (reduction of a general band ',
- $ 'matrix to real bidiagonal form)' )
- 9966 FORMAT( / / 1X, A3, ': NRHS =', I4 )
- 9965 FORMAT( / ' Tests of the Generalized Nonsymmetric Eigenvalue ',
- $ 'Problem Expert Driver DGGESX' )
- 9964 FORMAT( / ' Tests of the Generalized Nonsymmetric Eigenvalue ',
- $ 'Problem Driver DGGES' )
- 9963 FORMAT( / ' Tests of the Generalized Nonsymmetric Eigenvalue ',
- $ 'Problem Driver DGGEV' )
- 9962 FORMAT( / ' Tests of the Generalized Nonsymmetric Eigenvalue ',
- $ 'Problem Expert Driver DGGEVX' )
- 9961 FORMAT( / / 1X, A3, ': NB =', I4, ', NBMIN =', I4, ', NX =', I4,
- $ ', INMIN=', I4,
- $ ', INWIN =', I4, ', INIBL =', I4, ', ISHFTS =', I4,
- $ ', IACC22 =', I4)
- *
- * End of DCHKEE
- *
- END