d8/d97/cdrvev_8f_source.html

*> \brief \b CDRVEV

*

*  =========== DOCUMENTATION ===========

*

* Online html documentation available at

*            http://www.netlib.org/lapack/explore-html/

*

*  Definition:

*  ===========

*

*       SUBROUTINE CDRVEV( NSIZES, NN, NTYPES, DOTYPE, ISEED, THRESH,

*                          NOUNIT, A, LDA, H, W, W1, VL, LDVL, VR, LDVR,

*                          LRE, LDLRE, RESULT, WORK, NWORK, RWORK, IWORK,

*                          INFO )

*

*       .. Scalar Arguments ..

*       INTEGER            INFO, LDA, LDLRE, LDVL, LDVR, NOUNIT, NSIZES,

*      $                   NTYPES, NWORK

*       REAL               THRESH

*       ..

*       .. Array Arguments ..

*       LOGICAL            DOTYPE( * )

*       INTEGER            ISEED( 4 ), IWORK( * ), NN( * )

*       REAL               RESULT( 7 ), RWORK( * )

*       COMPLEX            A( LDA, * ), H( LDA, * ), LRE( LDLRE, * ),

*      $                   VL( LDVL, * ), VR( LDVR, * ), W( * ), W1( * ),

*      $                   WORK( * )

*       ..

*

*

*> \par Purpose:

*  =============

*>

*> \verbatim

*>

*>    CDRVEV  checks the nonsymmetric eigenvalue problem driver CGEEV.

*>

*>    When CDRVEV is called, a number of matrix "sizes" ("n's") and a

*>    number of matrix "types" are specified.  For each size ("n")

*>    and each type of matrix, one matrix will be generated and used

*>    to test the nonsymmetric eigenroutines.  For each matrix, 7

*>    tests will be performed:

*>

*>    (1)     | A * VR - VR * W | / ( n |A| ulp )

*>

*>      Here VR is the matrix of unit right eigenvectors.

*>      W is a diagonal matrix with diagonal entries W(j).

*>

*>    (2)     | A**H * VL - VL * W**H | / ( n |A| ulp )

*>

*>      Here VL is the matrix of unit left eigenvectors, A**H is the

*>      conjugate-transpose of A, and W is as above.

*>

*>    (3)     | |VR(i)| - 1 | / ulp and whether largest component real

*>

*>      VR(i) denotes the i-th column of VR.

*>

*>    (4)     | |VL(i)| - 1 | / ulp and whether largest component real

*>

*>      VL(i) denotes the i-th column of VL.

*>

*>    (5)     W(full) = W(partial)

*>

*>      W(full) denotes the eigenvalues computed when both VR and VL

*>      are also computed, and W(partial) denotes the eigenvalues

*>      computed when only W, only W and VR, or only W and VL are

*>      computed.

*>

*>    (6)     VR(full) = VR(partial)

*>

*>      VR(full) denotes the right eigenvectors computed when both VR

*>      and VL are computed, and VR(partial) denotes the result

*>      when only VR is computed.

*>

*>     (7)     VL(full) = VL(partial)

*>

*>      VL(full) denotes the left eigenvectors computed when both VR

*>      and VL are also computed, and VL(partial) denotes the result

*>      when only VL is computed.

*>

*>    The "sizes" are specified by an array NN(1:NSIZES); the value of

*>    each element NN(j) specifies one size.

*>    The "types" are specified by a logical array DOTYPE( 1:NTYPES );

*>    if DOTYPE(j) is .TRUE., then matrix type "j" will be generated.

*>    Currently, the list of possible types is:

*>

*>    (1)  The zero matrix.

*>    (2)  The identity matrix.

*>    (3)  A (transposed) Jordan block, with 1's on the diagonal.

*>

*>    (4)  A diagonal matrix with evenly spaced entries

*>         1, ..., ULP  and random complex angles.

*>         (ULP = (first number larger than 1) - 1 )

*>    (5)  A diagonal matrix with geometrically spaced entries

*>         1, ..., ULP  and random complex angles.

*>    (6)  A diagonal matrix with "clustered" entries 1, ULP, ..., ULP

*>         and random complex angles.

*>

*>    (7)  Same as (4), but multiplied by a constant near

*>         the overflow threshold

*>    (8)  Same as (4), but multiplied by a constant near

*>         the underflow threshold

*>

*>    (9)  A matrix of the form  U' T U, where U is unitary and

*>         T has evenly spaced entries 1, ..., ULP with random complex

*>         angles on the diagonal and random O(1) entries in the upper

*>         triangle.

*>

*>    (10) A matrix of the form  U' T U, where U is unitary and

*>         T has geometrically spaced entries 1, ..., ULP with random

*>         complex angles on the diagonal and random O(1) entries in

*>         the upper triangle.

*>

*>    (11) A matrix of the form  U' T U, where U is unitary and

*>         T has "clustered" entries 1, ULP,..., ULP with random

*>         complex angles on the diagonal and random O(1) entries in

*>         the upper triangle.

*>

*>    (12) A matrix of the form  U' T U, where U is unitary and

*>         T has complex eigenvalues randomly chosen from

*>         ULP < |z| < 1   and random O(1) entries in the upper

*>         triangle.

*>

*>    (13) A matrix of the form  X' T X, where X has condition

*>         SQRT( ULP ) and T has evenly spaced entries 1, ..., ULP

*>         with random complex angles on the diagonal and random O(1)

*>         entries in the upper triangle.

*>

*>    (14) A matrix of the form  X' T X, where X has condition

*>         SQRT( ULP ) and T has geometrically spaced entries

*>         1, ..., ULP with random complex angles on the diagonal

*>         and random O(1) entries in the upper triangle.

*>

*>    (15) A matrix of the form  X' T X, where X has condition

*>         SQRT( ULP ) and T has "clustered" entries 1, ULP,..., ULP

*>         with random complex angles on the diagonal and random O(1)

*>         entries in the upper triangle.

*>

*>    (16) A matrix of the form  X' T X, where X has condition

*>         SQRT( ULP ) and T has complex eigenvalues randomly chosen

*>         from ULP < |z| < 1 and random O(1) entries in the upper

*>         triangle.

*>

*>    (17) Same as (16), but multiplied by a constant

*>         near the overflow threshold

*>    (18) Same as (16), but multiplied by a constant

*>         near the underflow threshold

*>

*>    (19) Nonsymmetric matrix with random entries chosen from |z| < 1

*>         If N is at least 4, all entries in first two rows and last

*>         row, and first column and last two columns are zero.

*>    (20) Same as (19), but multiplied by a constant

*>         near the overflow threshold

*>    (21) Same as (19), but multiplied by a constant

*>         near the underflow threshold

*> \endverbatim

*

*  Arguments:

*  ==========

*

*> \param[in] NSIZES

*> \verbatim

*>          NSIZES is INTEGER

*>          The number of sizes of matrices to use.  If it is zero,

*>          CDRVEV does nothing.  It must be at least zero.

*> \endverbatim

*>

*> \param[in] NN

*> \verbatim

*>          NN is INTEGER array, dimension (NSIZES)

*>          An array containing the sizes to be used for the matrices.

*>          Zero values will be skipped.  The values must be at least

*>          zero.

*> \endverbatim

*>

*> \param[in] NTYPES

*> \verbatim

*>          NTYPES is INTEGER

*>          The number of elements in DOTYPE.   If it is zero, CDRVEV

*>          does nothing.  It must be at least zero.  If it is MAXTYP+1

*>          and NSIZES is 1, then an additional type, MAXTYP+1 is

*>          defined, which is to use whatever matrix is in A.  This

*>          is only useful if DOTYPE(1:MAXTYP) is .FALSE. and

*>          DOTYPE(MAXTYP+1) is .TRUE. .

*> \endverbatim

*>

*> \param[in] DOTYPE

*> \verbatim

*>          DOTYPE is LOGICAL array, dimension (NTYPES)

*>          If DOTYPE(j) is .TRUE., then for each size in NN a

*>          matrix of that size and of type j will be generated.

*>          If NTYPES is smaller than the maximum number of types

*>          defined (PARAMETER MAXTYP), then types NTYPES+1 through

*>          MAXTYP will not be generated.  If NTYPES is larger

*>          than MAXTYP, DOTYPE(MAXTYP+1) through DOTYPE(NTYPES)

*>          will be ignored.

*> \endverbatim

*>

*> \param[in,out] ISEED

*> \verbatim

*>          ISEED is INTEGER array, dimension (4)

*>          On entry ISEED specifies the seed of the random number

*>          generator. The array elements should be between 0 and 4095;

*>          if not they will be reduced mod 4096.  Also, ISEED(4) must

*>          be odd.  The random number generator uses a linear

*>          congruential sequence limited to small integers, and so

*>          should produce machine independent random numbers. The

*>          values of ISEED are changed on exit, and can be used in the

*>          next call to CDRVEV to continue the same random number

*>          sequence.

*> \endverbatim

*>

*> \param[in] THRESH

*> \verbatim

*>          THRESH is REAL

*>          A test will count as "failed" if the "error", computed as

*>          described above, exceeds THRESH.  Note that the error

*>          is scaled to be O(1), so THRESH should be a reasonably

*>          small multiple of 1, e.g., 10 or 100.  In particular,

*>          it should not depend on the precision (single vs. double)

*>          or the size of the matrix.  It must be at least zero.

*> \endverbatim

*>

*> \param[in] NOUNIT

*> \verbatim

*>          NOUNIT is INTEGER

*>          The FORTRAN unit number for printing out error messages

*>          (e.g., if a routine returns INFO not equal to 0.)

*> \endverbatim

*>

*> \param[out] A

*> \verbatim

*>          A is COMPLEX array, dimension (LDA, max(NN))

*>          Used to hold the matrix whose eigenvalues are to be

*>          computed.  On exit, A contains the last matrix actually used.

*> \endverbatim

*>

*> \param[in] LDA

*> \verbatim

*>          LDA is INTEGER

*>          The leading dimension of A, and H. LDA must be at

*>          least 1 and at least max(NN).

*> \endverbatim

*>

*> \param[out] H

*> \verbatim

*>          H is COMPLEX array, dimension (LDA, max(NN))

*>          Another copy of the test matrix A, modified by CGEEV.

*> \endverbatim

*>

*> \param[out] W

*> \verbatim

*>          W is COMPLEX array, dimension (max(NN))

*>          The eigenvalues of A. On exit, W are the eigenvalues of

*>          the matrix in A.

*> \endverbatim

*>

*> \param[out] W1

*> \verbatim

*>          W1 is COMPLEX array, dimension (max(NN))

*>          Like W, this array contains the eigenvalues of A,

*>          but those computed when CGEEV only computes a partial

*>          eigendecomposition, i.e. not the eigenvalues and left

*>          and right eigenvectors.

*> \endverbatim

*>

*> \param[out] VL

*> \verbatim

*>          VL is COMPLEX array, dimension (LDVL, max(NN))

*>          VL holds the computed left eigenvectors.

*> \endverbatim

*>

*> \param[in] LDVL

*> \verbatim

*>          LDVL is INTEGER

*>          Leading dimension of VL. Must be at least max(1,max(NN)).

*> \endverbatim

*>

*> \param[out] VR

*> \verbatim

*>          VR is COMPLEX array, dimension (LDVR, max(NN))

*>          VR holds the computed right eigenvectors.

*> \endverbatim

*>

*> \param[in] LDVR

*> \verbatim

*>          LDVR is INTEGER

*>          Leading dimension of VR. Must be at least max(1,max(NN)).

*> \endverbatim

*>

*> \param[out] LRE

*> \verbatim

*>          LRE is COMPLEX array, dimension (LDLRE, max(NN))

*>          LRE holds the computed right or left eigenvectors.

*> \endverbatim

*>

*> \param[in] LDLRE

*> \verbatim

*>          LDLRE is INTEGER

*>          Leading dimension of LRE. Must be at least max(1,max(NN)).

*> \endverbatim

*>

*> \param[out] RESULT

*> \verbatim

*>          RESULT is REAL array, dimension (7)

*>          The values computed by the seven tests described above.

*>          The values are currently limited to 1/ulp, to avoid

*>          overflow.

*> \endverbatim

*>

*> \param[out] WORK

*> \verbatim

*>          WORK is COMPLEX array, dimension (NWORK)

*> \endverbatim

*>

*> \param[in] NWORK

*> \verbatim

*>          NWORK is INTEGER

*>          The number of entries in WORK.  This must be at least

*>          5*NN(j)+2*NN(j)**2 for all j.

*> \endverbatim

*>

*> \param[out] RWORK

*> \verbatim

*>          RWORK is REAL array, dimension (2*max(NN))

*> \endverbatim

*>

*> \param[out] IWORK

*> \verbatim

*>          IWORK is INTEGER array, dimension (max(NN))

*> \endverbatim

*>

*> \param[out] INFO

*> \verbatim

*>          INFO is INTEGER

*>          If 0, then everything ran OK.

*>           -1: NSIZES < 0

*>           -2: Some NN(j) < 0

*>           -3: NTYPES < 0

*>           -6: THRESH < 0

*>           -9: LDA < 1 or LDA < NMAX, where NMAX is max( NN(j) ).

*>          -14: LDVL < 1 or LDVL < NMAX, where NMAX is max( NN(j) ).

*>          -16: LDVR < 1 or LDVR < NMAX, where NMAX is max( NN(j) ).

*>          -18: LDLRE < 1 or LDLRE < NMAX, where NMAX is max( NN(j) ).

*>          -21: NWORK too small.

*>          If  CLATMR, CLATMS, CLATME or CGEEV returns an error code,

*>              the absolute value of it is returned.

*>

*>-----------------------------------------------------------------------

*>

*>     Some Local Variables and Parameters:

*>     ---- ----- --------- --- ----------

*>

*>     ZERO, ONE       Real 0 and 1.

*>     MAXTYP          The number of types defined.

*>     NMAX            Largest value in NN.

*>     NERRS           The number of tests which have exceeded THRESH

*>     COND, CONDS,

*>     IMODE           Values to be passed to the matrix generators.

*>     ANORM           Norm of A; passed to matrix generators.

*>

*>     OVFL, UNFL      Overflow and underflow thresholds.

*>     ULP, ULPINV     Finest relative precision and its inverse.

*>     RTULP, RTULPI   Square roots of the previous 4 values.

*>

*>             The following four arrays decode JTYPE:

*>     KTYPE(j)        The general type (1-10) for type "j".

*>     KMODE(j)        The MODE value to be passed to the matrix

*>                     generator for type "j".

*>     KMAGN(j)        The order of magnitude ( O(1),

*>                     O(overflow^(1/2) ), O(underflow^(1/2) )

*>     KCONDS(j)       Selectw whether CONDS is to be 1 or

*>                     1/sqrt(ulp).  (0 means irrelevant.)

*> \endverbatim

*

*  Authors:

*  ========

*

*> \author Univ. of Tennessee

*> \author Univ. of California Berkeley

*> \author Univ. of Colorado Denver

*> \author NAG Ltd.

*

*> \date November 2011

*

*> \ingroup complex_eig

*

*  =====================================================================

      SUBROUTINE cdrvev( NSIZES, NN, NTYPES, DOTYPE, ISEED, THRESH,

     $                   nounit, a, lda, h, w, w1, vl, ldvl, vr, ldvr,

     $                   lre, ldlre, result, work, nwork, rwork, iwork,

     $                   info )

*

*  -- LAPACK test routine (version 3.4.0) --

*  -- LAPACK is a software package provided by Univ. of Tennessee,    --

*  -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--

*     November 2011

*

*     .. Scalar Arguments ..

      INTEGER            info, lda, ldlre, ldvl, ldvr, nounit, nsizes,

     $                   ntypes, nwork

      REAL               thresh

*     ..

*     .. Array Arguments ..

      LOGICAL            dotype( * )

      INTEGER            iseed( 4 ), iwork( * ), nn( * )

      REAL               result( 7 ), rwork( * )

      COMPLEX            a( lda, * ), h( lda, * ), lre( ldlre, * ),

     $                   vl( ldvl, * ), vr( ldvr, * ), w( * ), w1( * ),

     $                   work( * )

*     ..

*

*  =====================================================================

*

*     .. Parameters ..

      COMPLEX            czero

      parameter( czero = ( 0.0e+0, 0.0e+0 ) )

      COMPLEX            cone

      parameter( cone = ( 1.0e+0, 0.0e+0 ) )

      REAL               zero, one

      parameter( zero = 0.0e+0, one = 1.0e+0 )

      REAL               two

      parameter( two = 2.0e+0 )

      INTEGER            maxtyp

      parameter( maxtyp = 21 )

*     ..

*     .. Local Scalars ..

      LOGICAL            badnn

      CHARACTER*3        path

      INTEGER            iinfo, imode, itype, iwk, j, jcol, jj, jsize,

     $                   jtype, mtypes, n, nerrs, nfail, nmax,

     $                   nnwork, ntest, ntestf, ntestt

      REAL               anorm, cond, conds, ovfl, rtulp, rtulpi, tnrm,

     $                   ulp, ulpinv, unfl, vmx, vrmx, vtst

*     ..

*     .. Local Arrays ..

      INTEGER            idumma( 1 ), ioldsd( 4 ), kconds( maxtyp ),

     $                   kmagn( maxtyp ), kmode( maxtyp ),

     $                   ktype( maxtyp )

      REAL               res( 2 )

      COMPLEX            dum( 1 )

*     ..

*     .. External Functions ..

      REAL               scnrm2, slamch

      EXTERNAL           scnrm2, slamch

*     ..

*     .. External Subroutines ..

      EXTERNAL           cgeev, cget22, clacpy, clatme, clatmr, clatms,

     $                   claset, slabad, slasum, xerbla

*     ..

*     .. Intrinsic Functions ..

      INTRINSIC          abs, aimag, cmplx, max, min, REAL, sqrt

*     ..

*     .. Data statements ..

      DATA               ktype / 1, 2, 3, 5*4, 4*6, 6*6, 3*9 /

      DATA               kmagn / 3*1, 1, 1, 1, 2, 3, 4*1, 1, 1, 1, 1, 2,

     $                   3, 1, 2, 3 /

      DATA               kmode / 3*0, 4, 3, 1, 4, 4, 4, 3, 1, 5, 4, 3,

     $                   1, 5, 5, 5, 4, 3, 1 /

      DATA               kconds / 3*0, 5*0, 4*1, 6*2, 3*0 /

*     ..

*     .. Executable Statements ..

*

      path( 1: 1 ) = 'Complex precision'

      path( 2: 3 ) = 'EV'

*

*     Check for errors

*

      ntestt = 0

      ntestf = 0

      info = 0

*

*     Important constants

*

      badnn = .false.

      nmax = 0

      DO 10 j = 1, nsizes

         nmax = max( nmax, nn( j ) )

         IF( nn( j ).LT.0 )

     $      badnn = .true.

   10 continue

*

*     Check for errors

*

      IF( nsizes.LT.0 ) THEN

         info = -1

      ELSE IF( badnn ) THEN

         info = -2

      ELSE IF( ntypes.LT.0 ) THEN

         info = -3

      ELSE IF( thresh.LT.zero ) THEN

         info = -6

      ELSE IF( nounit.LE.0 ) THEN

         info = -7

      ELSE IF( lda.LT.1 .OR. lda.LT.nmax ) THEN

         info = -9

      ELSE IF( ldvl.LT.1 .OR. ldvl.LT.nmax ) THEN

         info = -14

      ELSE IF( ldvr.LT.1 .OR. ldvr.LT.nmax ) THEN

         info = -16

      ELSE IF( ldlre.LT.1 .OR. ldlre.LT.nmax ) THEN

         info = -28

      ELSE IF( 5*nmax+2*nmax**2.GT.nwork ) THEN

         info = -21

      END IF

*

      IF( info.NE.0 ) THEN

         CALL xerbla( 'CDRVEV', -info )

         return

      END IF

*

*     Quick return if nothing to do

*

      IF( nsizes.EQ.0 .OR. ntypes.EQ.0 )

     $   return

*

*     More Important constants

*

      unfl = slamch( 'Safe minimum' )

      ovfl = one / unfl

      CALL slabad( unfl, ovfl )

      ulp = slamch( 'Precision' )

      ulpinv = one / ulp

      rtulp = sqrt( ulp )

      rtulpi = one / rtulp

*

*     Loop over sizes, types

*

      nerrs = 0

*

      DO 270 jsize = 1, nsizes

         n = nn( jsize )

         IF( nsizes.NE.1 ) THEN

            mtypes = min( maxtyp, ntypes )

         ELSE

            mtypes = min( maxtyp+1, ntypes )

         END IF

*

         DO 260 jtype = 1, mtypes

            IF( .NOT.dotype( jtype ) )

     $         go to 260

*

*           Save ISEED in case of an error.

*

            DO 20 j = 1, 4

               ioldsd( j ) = iseed( j )

   20       continue

*

*           Compute "A"

*

*           Control parameters:

*

*           KMAGN  KCONDS  KMODE        KTYPE

*       =1  O(1)   1       clustered 1  zero

*       =2  large  large   clustered 2  identity

*       =3  small          exponential  Jordan

*       =4                 arithmetic   diagonal, (w/ eigenvalues)

*       =5                 random log   symmetric, w/ eigenvalues

*       =6                 random       general, w/ eigenvalues

*       =7                              random diagonal

*       =8                              random symmetric

*       =9                              random general

*       =10                             random triangular

*

            IF( mtypes.GT.maxtyp )

     $         go to 90

*

            itype = ktype( jtype )

            imode = kmode( jtype )

*

*           Compute norm

*

            go to( 30, 40, 50 )kmagn( jtype )

*

   30       continue

            anorm = one

            go to 60

*

   40       continue

            anorm = ovfl*ulp

            go to 60

*

   50       continue

            anorm = unfl*ulpinv

            go to 60

*

   60       continue

*

            CALL claset( 'Full', lda, n, czero, czero, a, lda )

            iinfo = 0

            cond = ulpinv

*

*           Special Matrices -- Identity & Jordan block

*

*              Zero

*

            IF( itype.EQ.1 ) THEN

               iinfo = 0

*

            ELSE IF( itype.EQ.2 ) THEN

*

*              Identity

*

               DO 70 jcol = 1, n

                  a( jcol, jcol ) = cmplx( anorm )

   70          continue

*

            ELSE IF( itype.EQ.3 ) THEN

*

*              Jordan Block

*

               DO 80 jcol = 1, n

                  a( jcol, jcol ) = cmplx( anorm )

                  IF( jcol.GT.1 )

     $               a( jcol, jcol-1 ) = cone

   80          continue

*

            ELSE IF( itype.EQ.4 ) THEN

*

*              Diagonal Matrix, [Eigen]values Specified

*

               CALL clatms( n, n, 'S', iseed, 'H', rwork, imode, cond,

     $                      anorm, 0, 0, 'N', a, lda, work( n+1 ),

     $                      iinfo )

*

            ELSE IF( itype.EQ.5 ) THEN

*

*              Hermitian, eigenvalues specified

*

               CALL clatms( n, n, 'S', iseed, 'H', rwork, imode, cond,

     $                      anorm, n, n, 'N', a, lda, work( n+1 ),

     $                      iinfo )

*

            ELSE IF( itype.EQ.6 ) THEN

*

*              General, eigenvalues specified

*

               IF( kconds( jtype ).EQ.1 ) THEN

                  conds = one

               ELSE IF( kconds( jtype ).EQ.2 ) THEN

                  conds = rtulpi

               ELSE

                  conds = zero

               END IF

*

               CALL clatme( n, 'D', iseed, work, imode, cond, cone,

     $                      'T', 'T', 'T', rwork, 4, conds, n, n,

     $                      anorm, a, lda, work( 2*n+1 ), iinfo )

*

            ELSE IF( itype.EQ.7 ) THEN

*

*              Diagonal, random eigenvalues

*

               CALL clatmr( n, n, 'D', iseed, 'N', work, 6, one, cone,

     $                      'T', 'N', work( n+1 ), 1, one,

     $                      work( 2*n+1 ), 1, one, 'N', idumma, 0, 0,

     $                      zero, anorm, 'NO', a, lda, iwork, iinfo )

*

            ELSE IF( itype.EQ.8 ) THEN

*

*              Symmetric, random eigenvalues

*

               CALL clatmr( n, n, 'D', iseed, 'H', work, 6, one, cone,

     $                      'T', 'N', work( n+1 ), 1, one,

     $                      work( 2*n+1 ), 1, one, 'N', idumma, n, n,

     $                      zero, anorm, 'NO', a, lda, iwork, iinfo )

*

            ELSE IF( itype.EQ.9 ) THEN

*

*              General, random eigenvalues

*

               CALL clatmr( n, n, 'D', iseed, 'N', work, 6, one, cone,

     $                      'T', 'N', work( n+1 ), 1, one,

     $                      work( 2*n+1 ), 1, one, 'N', idumma, n, n,

     $                      zero, anorm, 'NO', a, lda, iwork, iinfo )

               IF( n.GE.4 ) THEN

                  CALL claset( 'Full', 2, n, czero, czero, a, lda )

                  CALL claset( 'Full', n-3, 1, czero, czero, a( 3, 1 ),

     $                         lda )

                  CALL claset( 'Full', n-3, 2, czero, czero,

     $                         a( 3, n-1 ), lda )

                  CALL claset( 'Full', 1, n, czero, czero, a( n, 1 ),

     $                         lda )

               END IF

*

            ELSE IF( itype.EQ.10 ) THEN

*

*              Triangular, random eigenvalues

*

               CALL clatmr( n, n, 'D', iseed, 'N', work, 6, one, cone,

     $                      'T', 'N', work( n+1 ), 1, one,

     $                      work( 2*n+1 ), 1, one, 'N', idumma, n, 0,

     $                      zero, anorm, 'NO', a, lda, iwork, iinfo )

*

            ELSE

*

               iinfo = 1

            END IF

*

            IF( iinfo.NE.0 ) THEN

               WRITE( nounit, fmt = 9993 )'Generator', iinfo, n, jtype,

     $            ioldsd

               info = abs( iinfo )

               return

            END IF

*

   90       continue

*

*           Test for minimal and generous workspace

*

            DO 250 iwk = 1, 2

               IF( iwk.EQ.1 ) THEN

                  nnwork = 2*n

               ELSE

                  nnwork = 5*n + 2*n**2

               END IF

               nnwork = max( nnwork, 1 )

*

*              Initialize RESULT

*

               DO 100 j = 1, 7

                  result( j ) = -one

  100          continue

*

*              Compute eigenvalues and eigenvectors, and test them

*

               CALL clacpy( 'F', n, n, a, lda, h, lda )

               CALL cgeev( 'V', 'V', n, h, lda, w, vl, ldvl, vr, ldvr,

     $                     work, nnwork, rwork, iinfo )

               IF( iinfo.NE.0 ) THEN

                  result( 1 ) = ulpinv

                  WRITE( nounit, fmt = 9993 )'CGEEV1', iinfo, n, jtype,

     $               ioldsd

                  info = abs( iinfo )

                  go to 220

               END IF

*

*              Do Test (1)

*

               CALL cget22( 'N', 'N', 'N', n, a, lda, vr, ldvr, w, work,

     $                      rwork, res )

               result( 1 ) = res( 1 )

*

*              Do Test (2)

*

               CALL cget22( 'C', 'N', 'C', n, a, lda, vl, ldvl, w, work,

     $                      rwork, res )

               result( 2 ) = res( 1 )

*

*              Do Test (3)

*

               DO 120 j = 1, n

                  tnrm = scnrm2( n, vr( 1, j ), 1 )

                  result( 3 ) = max( result( 3 ),

     $                          min( ulpinv, abs( tnrm-one ) / ulp ) )

                  vmx = zero

                  vrmx = zero

                  DO 110 jj = 1, n

                     vtst = abs( vr( jj, j ) )

                     IF( vtst.GT.vmx )

     $                  vmx = vtst

                     IF( aimag( vr( jj, j ) ).EQ.zero .AND.

     $                   abs( REAL( VR( JJ, J ) ) ).GT.vrmx )

     $                   vrmx = abs( REAL( VR( JJ, J ) ) )

  110             continue

                  IF( vrmx / vmx.LT.one-two*ulp )

     $               result( 3 ) = ulpinv

  120          continue

*

*              Do Test (4)

*

               DO 140 j = 1, n

                  tnrm = scnrm2( n, vl( 1, j ), 1 )

                  result( 4 ) = max( result( 4 ),

     $                          min( ulpinv, abs( tnrm-one ) / ulp ) )

                  vmx = zero

                  vrmx = zero

                  DO 130 jj = 1, n

                     vtst = abs( vl( jj, j ) )

                     IF( vtst.GT.vmx )

     $                  vmx = vtst

                     IF( aimag( vl( jj, j ) ).EQ.zero .AND.

     $                   abs( REAL( VL( JJ, J ) ) ).GT.vrmx )

     $                   vrmx = abs( REAL( VL( JJ, J ) ) )

  130             continue

                  IF( vrmx / vmx.LT.one-two*ulp )

     $               result( 4 ) = ulpinv

  140          continue

*

*              Compute eigenvalues only, and test them

*

               CALL clacpy( 'F', n, n, a, lda, h, lda )

               CALL cgeev( 'N', 'N', n, h, lda, w1, dum, 1, dum, 1,

     $                     work, nnwork, rwork, iinfo )

               IF( iinfo.NE.0 ) THEN

                  result( 1 ) = ulpinv

                  WRITE( nounit, fmt = 9993 )'CGEEV2', iinfo, n, jtype,

     $               ioldsd

                  info = abs( iinfo )

                  go to 220

               END IF

*

*              Do Test (5)

*

               DO 150 j = 1, n

                  IF( w( j ).NE.w1( j ) )

     $               result( 5 ) = ulpinv

  150          continue

*

*              Compute eigenvalues and right eigenvectors, and test them

*

               CALL clacpy( 'F', n, n, a, lda, h, lda )

               CALL cgeev( 'N', 'V', n, h, lda, w1, dum, 1, lre, ldlre,

     $                     work, nnwork, rwork, iinfo )

               IF( iinfo.NE.0 ) THEN

                  result( 1 ) = ulpinv

                  WRITE( nounit, fmt = 9993 )'CGEEV3', iinfo, n, jtype,

     $               ioldsd

                  info = abs( iinfo )

                  go to 220

               END IF

*

*              Do Test (5) again

*

               DO 160 j = 1, n

                  IF( w( j ).NE.w1( j ) )

     $               result( 5 ) = ulpinv

  160          continue

*

*              Do Test (6)

*

               DO 180 j = 1, n

                  DO 170 jj = 1, n

                     IF( vr( j, jj ).NE.lre( j, jj ) )

     $                  result( 6 ) = ulpinv

  170             continue

  180          continue

*

*              Compute eigenvalues and left eigenvectors, and test them

*

               CALL clacpy( 'F', n, n, a, lda, h, lda )

               CALL cgeev( 'V', 'N', n, h, lda, w1, lre, ldlre, dum, 1,

     $                     work, nnwork, rwork, iinfo )

               IF( iinfo.NE.0 ) THEN

                  result( 1 ) = ulpinv

                  WRITE( nounit, fmt = 9993 )'CGEEV4', iinfo, n, jtype,

     $               ioldsd

                  info = abs( iinfo )

                  go to 220

               END IF

*

*              Do Test (5) again

*

               DO 190 j = 1, n

                  IF( w( j ).NE.w1( j ) )

     $               result( 5 ) = ulpinv

  190          continue

*

*              Do Test (7)

*

               DO 210 j = 1, n

                  DO 200 jj = 1, n

                     IF( vl( j, jj ).NE.lre( j, jj ) )

     $                  result( 7 ) = ulpinv

  200             continue

  210          continue

*

*              End of Loop -- Check for RESULT(j) > THRESH

*

  220          continue

*

               ntest = 0

               nfail = 0

               DO 230 j = 1, 7

                  IF( result( j ).GE.zero )

     $               ntest = ntest + 1

                  IF( result( j ).GE.thresh )

     $               nfail = nfail + 1

  230          continue

*

               IF( nfail.GT.0 )

     $            ntestf = ntestf + 1

               IF( ntestf.EQ.1 ) THEN

                  WRITE( nounit, fmt = 9999 )path

                  WRITE( nounit, fmt = 9998 )

                  WRITE( nounit, fmt = 9997 )

                  WRITE( nounit, fmt = 9996 )

                  WRITE( nounit, fmt = 9995 )thresh

                  ntestf = 2

               END IF

*

               DO 240 j = 1, 7

                  IF( result( j ).GE.thresh ) THEN

                     WRITE( nounit, fmt = 9994 )n, iwk, ioldsd, jtype,

     $                  j, result( j )

                  END IF

  240          continue

*

               nerrs = nerrs + nfail

               ntestt = ntestt + ntest

*

  250       continue

  260    continue

  270 continue

*

*     Summary

*

      CALL slasum( path, nounit, nerrs, ntestt )

*

 9999 format( / 1x, a3, ' -- Complex Eigenvalue-Eigenvector ',

     $      'Decomposition Driver', /

     $      ' Matrix types (see CDRVEV for details): ' )

*

 9998 format( / ' Special Matrices:', / '  1=Zero matrix.             ',

     $      '           ', '  5=Diagonal: geometr. spaced entries.',

     $      / '  2=Identity matrix.                    ', '  6=Diagona',

     $      'l: clustered entries.', / '  3=Transposed Jordan block.  ',

     $      '          ', '  7=Diagonal: large, evenly spaced.', / '  ',

     $      '4=Diagonal: evenly spaced entries.    ', '  8=Diagonal: s',

     $      'mall, evenly spaced.' )

 9997 format( ' Dense, Non-Symmetric Matrices:', / '  9=Well-cond., ev',

     $      'enly spaced eigenvals.', ' 14=Ill-cond., geomet. spaced e',

     $      'igenals.', / ' 10=Well-cond., geom. spaced eigenvals. ',

     $      ' 15=Ill-conditioned, clustered e.vals.', / ' 11=Well-cond',

     $      'itioned, clustered e.vals. ', ' 16=Ill-cond., random comp',

     $      'lex ', a6, / ' 12=Well-cond., random complex ', a6, '   ',

     $      ' 17=Ill-cond., large rand. complx ', a4, / ' 13=Ill-condi',

     $      'tioned, evenly spaced.     ', ' 18=Ill-cond., small rand.',

     $      ' complx ', a4 )

 9996 format( ' 19=Matrix with random O(1) entries.    ', ' 21=Matrix ',

     $      'with small random entries.', / ' 20=Matrix with large ran',

     $      'dom entries.   ', / )

 9995 format( ' Tests performed with test threshold =', f8.2,

     $      / / ' 1 = | A VR - VR W | / ( n |A| ulp ) ',

     $      / ' 2 = | conj-trans(A) VL - VL conj-trans(W) | /',

     $      ' ( n |A| ulp ) ', / ' 3 = | |VR(i)| - 1 | / ulp ',

     $      / ' 4 = | |VL(i)| - 1 | / ulp ',

     $      / ' 5 = 0 if W same no matter if VR or VL computed,',

     $      ' 1/ulp otherwise', /

     $      ' 6 = 0 if VR same no matter if VL computed,',

     $      '  1/ulp otherwise', /

     $      ' 7 = 0 if VL same no matter if VR computed,',

     $      '  1/ulp otherwise', / )

 9994 format( ' N=', i5, ', IWK=', i2, ', seed=', 4( i4, ',' ),

     $      ' type ', i2, ', test(', i2, ')=', g10.3 )

 9993 format( ' CDRVEV: ', a, ' returned INFO=', i6, '.', / 9x, 'N=',

     $      i6, ', JTYPE=', i6, ', ISEED=(', 3( i5, ',' ), i5, ')' )

*

      return

*

*     End of CDRVEV

*

      END