da/dfd/cstemr_8f_source.html

*> \brief \b CSTEMR

*

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

*

* Online html documentation available at

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

*

*> \htmlonly

*> Download CSTEMR + dependencies

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*> [ZIP]</a>

*> <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/cstemr.f">

*> [TXT]</a>

*> \endhtmlonly

*

*  Definition:

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

*

*       SUBROUTINE CSTEMR( JOBZ, RANGE, N, D, E, VL, VU, IL, IU,

*                          M, W, Z, LDZ, NZC, ISUPPZ, TRYRAC, WORK, LWORK,

*                          IWORK, LIWORK, INFO )

*

*       .. Scalar Arguments ..

*       CHARACTER          JOBZ, RANGE

*       LOGICAL            TRYRAC

*       INTEGER            IL, INFO, IU, LDZ, NZC, LIWORK, LWORK, M, N

*       REAL             VL, VU

*       ..

*       .. Array Arguments ..

*       INTEGER            ISUPPZ( * ), IWORK( * )

*       REAL               D( * ), E( * ), W( * ), WORK( * )

*       COMPLEX            Z( LDZ, * )

*       ..

*

*

*> \par Purpose:

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

*>

*> \verbatim

*>

*> CSTEMR computes selected eigenvalues and, optionally, eigenvectors

*> of a real symmetric tridiagonal matrix T. Any such unreduced matrix has

*> a well defined set of pairwise different real eigenvalues, the corresponding

*> real eigenvectors are pairwise orthogonal.

*>

*> The spectrum may be computed either completely or partially by specifying

*> either an interval (VL,VU] or a range of indices IL:IU for the desired

*> eigenvalues.

*>

*> Depending on the number of desired eigenvalues, these are computed either

*> by bisection or the dqds algorithm. Numerically orthogonal eigenvectors are

*> computed by the use of various suitable L D L^T factorizations near clusters

*> of close eigenvalues (referred to as RRRs, Relatively Robust

*> Representations). An informal sketch of the algorithm follows.

*>

*> For each unreduced block (submatrix) of T,

*>    (a) Compute T - sigma I  = L D L^T, so that L and D

*>        define all the wanted eigenvalues to high relative accuracy.

*>        This means that small relative changes in the entries of D and L

*>        cause only small relative changes in the eigenvalues and

*>        eigenvectors. The standard (unfactored) representation of the

*>        tridiagonal matrix T does not have this property in general.

*>    (b) Compute the eigenvalues to suitable accuracy.

*>        If the eigenvectors are desired, the algorithm attains full

*>        accuracy of the computed eigenvalues only right before

*>        the corresponding vectors have to be computed, see steps c) and d).

*>    (c) For each cluster of close eigenvalues, select a new

*>        shift close to the cluster, find a new factorization, and refine

*>        the shifted eigenvalues to suitable accuracy.

*>    (d) For each eigenvalue with a large enough relative separation compute

*>        the corresponding eigenvector by forming a rank revealing twisted

*>        factorization. Go back to (c) for any clusters that remain.

*>

*> For more details, see:

*> - Inderjit S. Dhillon and Beresford N. Parlett: "Multiple representations

*>   to compute orthogonal eigenvectors of symmetric tridiagonal matrices,"

*>   Linear Algebra and its Applications, 387(1), pp. 1-28, August 2004.

*> - Inderjit Dhillon and Beresford Parlett: "Orthogonal Eigenvectors and

*>   Relative Gaps," SIAM Journal on Matrix Analysis and Applications, Vol. 25,

*>   2004.  Also LAPACK Working Note 154.

*> - Inderjit Dhillon: "A new O(n^2) algorithm for the symmetric

*>   tridiagonal eigenvalue/eigenvector problem",

*>   Computer Science Division Technical Report No. UCB/CSD-97-971,

*>   UC Berkeley, May 1997.

*>

*> Further Details

*> 1.CSTEMR works only on machines which follow IEEE-754

*> floating-point standard in their handling of infinities and NaNs.

*> This permits the use of efficient inner loops avoiding a check for

*> zero divisors.

*>

*> 2. LAPACK routines can be used to reduce a complex Hermitean matrix to

*> real symmetric tridiagonal form.

*>

*> (Any complex Hermitean tridiagonal matrix has real values on its diagonal

*> and potentially complex numbers on its off-diagonals. By applying a

*> similarity transform with an appropriate diagonal matrix

*> diag(1,e^{i \phy_1}, ... , e^{i \phy_{n-1}}), the complex Hermitean

*> matrix can be transformed into a real symmetric matrix and complex

*> arithmetic can be entirely avoided.)

*>

*> While the eigenvectors of the real symmetric tridiagonal matrix are real,

*> the eigenvectors of original complex Hermitean matrix have complex entries

*> in general.

*> Since LAPACK drivers overwrite the matrix data with the eigenvectors,

*> CSTEMR accepts complex workspace to facilitate interoperability

*> with CUNMTR or CUPMTR.

*> \endverbatim

*

*  Arguments:

*  ==========

*

*> \param[in] JOBZ

*> \verbatim

*>          JOBZ is CHARACTER*1

*>          = 'N':  Compute eigenvalues only;

*>          = 'V':  Compute eigenvalues and eigenvectors.

*> \endverbatim

*>

*> \param[in] RANGE

*> \verbatim

*>          RANGE is CHARACTER*1

*>          = 'A': all eigenvalues will be found.

*>          = 'V': all eigenvalues in the half-open interval (VL,VU]

*>                 will be found.

*>          = 'I': the IL-th through IU-th eigenvalues will be found.

*> \endverbatim

*>

*> \param[in] N

*> \verbatim

*>          N is INTEGER

*>          The order of the matrix.  N >= 0.

*> \endverbatim

*>

*> \param[in,out] D

*> \verbatim

*>          D is REAL array, dimension (N)

*>          On entry, the N diagonal elements of the tridiagonal matrix

*>          T. On exit, D is overwritten.

*> \endverbatim

*>

*> \param[in,out] E

*> \verbatim

*>          E is REAL array, dimension (N)

*>          On entry, the (N-1) subdiagonal elements of the tridiagonal

*>          matrix T in elements 1 to N-1 of E. E(N) need not be set on

*>          input, but is used internally as workspace.

*>          On exit, E is overwritten.

*> \endverbatim

*>

*> \param[in] VL

*> \verbatim

*>          VL is REAL

*>

*>          If RANGE='V', the lower bound of the interval to

*>          be searched for eigenvalues. VL < VU.

*>          Not referenced if RANGE = 'A' or 'I'.

*> \endverbatim

*>

*> \param[in] VU

*> \verbatim

*>          VU is REAL

*>

*>          If RANGE='V', the upper bound of the interval to

*>          be searched for eigenvalues. VL < VU.

*>          Not referenced if RANGE = 'A' or 'I'.

*> \endverbatim

*>

*> \param[in] IL

*> \verbatim

*>          IL is INTEGER

*>

*>          If RANGE='I', the index of the

*>          smallest eigenvalue to be returned.

*>          1 <= IL <= IU <= N, if N > 0.

*>          Not referenced if RANGE = 'A' or 'V'.

*> \endverbatim

*>

*> \param[in] IU

*> \verbatim

*>          IU is INTEGER

*>

*>          If RANGE='I', the index of the

*>          largest eigenvalue to be returned.

*>          1 <= IL <= IU <= N, if N > 0.

*>          Not referenced if RANGE = 'A' or 'V'.

*> \endverbatim

*>

*> \param[out] M

*> \verbatim

*>          M is INTEGER

*>          The total number of eigenvalues found.  0 <= M <= N.

*>          If RANGE = 'A', M = N, and if RANGE = 'I', M = IU-IL+1.

*> \endverbatim

*>

*> \param[out] W

*> \verbatim

*>          W is REAL array, dimension (N)

*>          The first M elements contain the selected eigenvalues in

*>          ascending order.

*> \endverbatim

*>

*> \param[out] Z

*> \verbatim

*>          Z is COMPLEX array, dimension (LDZ, max(1,M) )

*>          If JOBZ = 'V', and if INFO = 0, then the first M columns of Z

*>          contain the orthonormal eigenvectors of the matrix T

*>          corresponding to the selected eigenvalues, with the i-th

*>          column of Z holding the eigenvector associated with W(i).

*>          If JOBZ = 'N', then Z is not referenced.

*>          Note: the user must ensure that at least max(1,M) columns are

*>          supplied in the array Z; if RANGE = 'V', the exact value of M

*>          is not known in advance and can be computed with a workspace

*>          query by setting NZC = -1, see below.

*> \endverbatim

*>

*> \param[in] LDZ

*> \verbatim

*>          LDZ is INTEGER

*>          The leading dimension of the array Z.  LDZ >= 1, and if

*>          JOBZ = 'V', then LDZ >= max(1,N).

*> \endverbatim

*>

*> \param[in] NZC

*> \verbatim

*>          NZC is INTEGER

*>          The number of eigenvectors to be held in the array Z.

*>          If RANGE = 'A', then NZC >= max(1,N).

*>          If RANGE = 'V', then NZC >= the number of eigenvalues in (VL,VU].

*>          If RANGE = 'I', then NZC >= IU-IL+1.

*>          If NZC = -1, then a workspace query is assumed; the

*>          routine calculates the number of columns of the array Z that

*>          are needed to hold the eigenvectors.

*>          This value is returned as the first entry of the Z array, and

*>          no error message related to NZC is issued by XERBLA.

*> \endverbatim

*>

*> \param[out] ISUPPZ

*> \verbatim

*>          ISUPPZ is INTEGER array, dimension ( 2*max(1,M) )

*>          The support of the eigenvectors in Z, i.e., the indices

*>          indicating the nonzero elements in Z. The i-th computed eigenvector

*>          is nonzero only in elements ISUPPZ( 2*i-1 ) through

*>          ISUPPZ( 2*i ). This is relevant in the case when the matrix

*>          is split. ISUPPZ is only accessed when JOBZ is 'V' and N > 0.

*> \endverbatim

*>

*> \param[in,out] TRYRAC

*> \verbatim

*>          TRYRAC is LOGICAL

*>          If TRYRAC = .TRUE., indicates that the code should check whether

*>          the tridiagonal matrix defines its eigenvalues to high relative

*>          accuracy.  If so, the code uses relative-accuracy preserving

*>          algorithms that might be (a bit) slower depending on the matrix.

*>          If the matrix does not define its eigenvalues to high relative

*>          accuracy, the code can uses possibly faster algorithms.

*>          If TRYRAC = .FALSE., the code is not required to guarantee

*>          relatively accurate eigenvalues and can use the fastest possible

*>          techniques.

*>          On exit, a .TRUE. TRYRAC will be set to .FALSE. if the matrix

*>          does not define its eigenvalues to high relative accuracy.

*> \endverbatim

*>

*> \param[out] WORK

*> \verbatim

*>          WORK is REAL array, dimension (LWORK)

*>          On exit, if INFO = 0, WORK(1) returns the optimal

*>          (and minimal) LWORK.

*> \endverbatim

*>

*> \param[in] LWORK

*> \verbatim

*>          LWORK is INTEGER

*>          The dimension of the array WORK. LWORK >= max(1,18*N)

*>          if JOBZ = 'V', and LWORK >= max(1,12*N) if JOBZ = 'N'.

*>          If LWORK = -1, then a workspace query is assumed; the routine

*>          only calculates the optimal size of the WORK array, returns

*>          this value as the first entry of the WORK array, and no error

*>          message related to LWORK is issued by XERBLA.

*> \endverbatim

*>

*> \param[out] IWORK

*> \verbatim

*>          IWORK is INTEGER array, dimension (LIWORK)

*>          On exit, if INFO = 0, IWORK(1) returns the optimal LIWORK.

*> \endverbatim

*>

*> \param[in] LIWORK

*> \verbatim

*>          LIWORK is INTEGER

*>          The dimension of the array IWORK.  LIWORK >= max(1,10*N)

*>          if the eigenvectors are desired, and LIWORK >= max(1,8*N)

*>          if only the eigenvalues are to be computed.

*>          If LIWORK = -1, then a workspace query is assumed; the

*>          routine only calculates the optimal size of the IWORK array,

*>          returns this value as the first entry of the IWORK array, and

*>          no error message related to LIWORK is issued by XERBLA.

*> \endverbatim

*>

*> \param[out] INFO

*> \verbatim

*>          INFO is INTEGER

*>          On exit, INFO

*>          = 0:  successful exit

*>          < 0:  if INFO = -i, the i-th argument had an illegal value

*>          > 0:  if INFO = 1X, internal error in SLARRE,

*>                if INFO = 2X, internal error in CLARRV.

*>                Here, the digit X = ABS( IINFO ) < 10, where IINFO is

*>                the nonzero error code returned by SLARRE or

*>                CLARRV, respectively.

*> \endverbatim

*

*  Authors:

*  ========

*

*> \author Univ. of Tennessee

*> \author Univ. of California Berkeley

*> \author Univ. of Colorado Denver

*> \author NAG Ltd.

*

*> \date June 2016

*

*> \ingroup complexOTHERcomputational

*

*> \par Contributors:

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

*>

*> Beresford Parlett, University of California, Berkeley, USA \n

*> Jim Demmel, University of California, Berkeley, USA \n

*> Inderjit Dhillon, University of Texas, Austin, USA \n

*> Osni Marques, LBNL/NERSC, USA \n

*> Christof Voemel, University of California, Berkeley, USA

*

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

      SUBROUTINE cstemr( JOBZ, RANGE, N, D, E, VL, VU, IL, IU,

     $                   M, W, Z, LDZ, NZC, ISUPPZ, TRYRAC, WORK, LWORK,

     $                   IWORK, LIWORK, INFO )

*

*  -- LAPACK computational routine (version 3.7.1) --

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

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

*     June 2016

*

*     .. Scalar Arguments ..

      CHARACTER          JOBZ, RANGE

      LOGICAL            TRYRAC

      INTEGER            IL, INFO, IU, LDZ, NZC, LIWORK, LWORK, M, N

      REAL             VL, VU

*     ..

*     .. Array Arguments ..

      INTEGER            ISUPPZ( * ), IWORK( * )

      REAL               D( * ), E( * ), W( * ), WORK( * )

      COMPLEX            Z( LDZ, * )

*     ..

*

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

*

*     .. Parameters ..

      REAL               ZERO, ONE, FOUR, MINRGP

      PARAMETER          ( ZERO = 0.0e0, one = 1.0e0,

     $                     four = 4.0e0,

     $                     minrgp = 3.0e-3 )

*     ..

*     .. Local Scalars ..

      LOGICAL            ALLEIG, INDEIG, LQUERY, VALEIG, WANTZ, ZQUERY

      INTEGER            I, IBEGIN, IEND, IFIRST, IIL, IINDBL, IINDW,

     $                   iindwk, iinfo, iinspl, iiu, ilast, in, indd,

     $                   inde2, inderr, indgp, indgrs, indwrk, itmp,

     $                   itmp2, j, jblk, jj, liwmin, lwmin, nsplit,

     $                   nzcmin, offset, wbegin, wend

      REAL               BIGNUM, CS, EPS, PIVMIN, R1, R2, RMAX, RMIN,

     $                   RTOL1, RTOL2, SAFMIN, SCALE, SMLNUM, SN,

     $                   thresh, tmp, tnrm, wl, wu

*     ..

*     ..

*     .. External Functions ..

      LOGICAL            LSAME

      REAL               SLAMCH, SLANST

      EXTERNAL           lsame, slamch, slanst

*     ..

*     .. External Subroutines ..

      EXTERNAL           clarrv, cswap, scopy, slae2, slaev2, slarrc,

     $                   slarre, slarrj, slarrr, slasrt, sscal, xerbla

*     ..

*     .. Intrinsic Functions ..

      INTRINSIC          max, min, sqrt


*     ..

*     .. Executable Statements ..

*

*     Test the input parameters.

*

      wantz = lsame( jobz, 'V' )

      alleig = lsame( range, 'A' )

      valeig = lsame( range, 'V' )

      indeig = lsame( range, 'I' )

*

      lquery = ( ( lwork.EQ.-1 ).OR.( liwork.EQ.-1 ) )

      zquery = ( nzc.EQ.-1 )


*     SSTEMR needs WORK of size 6*N, IWORK of size 3*N.

*     In addition, SLARRE needs WORK of size 6*N, IWORK of size 5*N.

*     Furthermore, CLARRV needs WORK of size 12*N, IWORK of size 7*N.

      IF( wantz ) THEN

         lwmin = 18*n

         liwmin = 10*n

      ELSE

*        need less workspace if only the eigenvalues are wanted

         lwmin = 12*n

         liwmin = 8*n

      ENDIF


      wl = zero

      wu = zero

      iil = 0

      iiu = 0

      nsplit = 0


      IF( valeig ) THEN

*        We do not reference VL, VU in the cases RANGE = 'I','A'

*        The interval (WL, WU] contains all the wanted eigenvalues.

*        It is either given by the user or computed in SLARRE.

         wl = vl

         wu = vu

      ELSEIF( indeig ) THEN

*        We do not reference IL, IU in the cases RANGE = 'V','A'

         iil = il

         iiu = iu

      ENDIF

*

      info = 0

      IF( .NOT.( wantz .OR. lsame( jobz, 'N' ) ) ) THEN

         info = -1

      ELSE IF( .NOT.( alleig .OR. valeig .OR. indeig ) ) THEN

         info = -2

      ELSE IF( n.LT.0 ) THEN

         info = -3

      ELSE IF( valeig .AND. n.GT.0 .AND. wu.LE.wl ) THEN

         info = -7

      ELSE IF( indeig .AND. ( iil.LT.1 .OR. iil.GT.n ) ) THEN

         info = -8

      ELSE IF( indeig .AND. ( iiu.LT.iil .OR. iiu.GT.n ) ) THEN

         info = -9

      ELSE IF( ldz.LT.1 .OR. ( wantz .AND. ldz.LT.n ) ) THEN

         info = -13

      ELSE IF( lwork.LT.lwmin .AND. .NOT.lquery ) THEN

         info = -17

      ELSE IF( liwork.LT.liwmin .AND. .NOT.lquery ) THEN

         info = -19

      END IF

*

*     Get machine constants.

*

      safmin = slamch( 'Safe minimum' )

      eps = slamch( 'Precision' )

      smlnum = safmin / eps

      bignum = one / smlnum

      rmin = sqrt( smlnum )

      rmax = min( sqrt( bignum ), one / sqrt( sqrt( safmin ) ) )

*

      IF( info.EQ.0 ) THEN

         work( 1 ) = lwmin

         iwork( 1 ) = liwmin

*

         IF( wantz .AND. alleig ) THEN

            nzcmin = n

         ELSE IF( wantz .AND. valeig ) THEN

            CALL slarrc( 'T', n, vl, vu, d, e, safmin,

     $                            nzcmin, itmp, itmp2, info )

         ELSE IF( wantz .AND. indeig ) THEN

            nzcmin = iiu-iil+1

         ELSE

*           WANTZ .EQ. FALSE.

            nzcmin = 0

         ENDIF

         IF( zquery .AND. info.EQ.0 ) THEN

            z( 1,1 ) = nzcmin

         ELSE IF( nzc.LT.nzcmin .AND. .NOT.zquery ) THEN

            info = -14

         END IF

      END IF


      IF( info.NE.0 ) THEN

*

         CALL xerbla( 'CSTEMR', -info )

*

         RETURN

      ELSE IF( lquery .OR. zquery ) THEN

         RETURN

      END IF

*

*     Handle N = 0, 1, and 2 cases immediately

*

      m = 0

      IF( n.EQ.0 )

     $   RETURN

*

      IF( n.EQ.1 ) THEN

         IF( alleig .OR. indeig ) THEN

            m = 1

            w( 1 ) = d( 1 )

         ELSE

            IF( wl.LT.d( 1 ) .AND. wu.GE.d( 1 ) ) THEN

               m = 1

               w( 1 ) = d( 1 )

            END IF

         END IF

         IF( wantz.AND.(.NOT.zquery) ) THEN

            z( 1, 1 ) = one

            isuppz(1) = 1

            isuppz(2) = 1

         END IF

         RETURN

      END IF

*

      IF( n.EQ.2 ) THEN

         IF( .NOT.wantz ) THEN

            CALL slae2( d(1), e(1), d(2), r1, r2 )

         ELSE IF( wantz.AND.(.NOT.zquery) ) THEN

            CALL slaev2( d(1), e(1), d(2), r1, r2, cs, sn )

         END IF

         IF( alleig.OR.

     $      (valeig.AND.(r2.GT.wl).AND.

     $                  (r2.LE.wu)).OR.

     $      (indeig.AND.(iil.EQ.1)) ) THEN

            m = m+1

            w( m ) = r2

            IF( wantz.AND.(.NOT.zquery) ) THEN

               z( 1, m ) = -sn

               z( 2, m ) = cs

*              Note: At most one of SN and CS can be zero.

               IF (sn.NE.zero) THEN

                  IF (cs.NE.zero) THEN

                     isuppz(2*m-1) = 1

                     isuppz(2*m) = 2

                  ELSE

                     isuppz(2*m-1) = 1

                     isuppz(2*m) = 1

                  END IF

               ELSE

                  isuppz(2*m-1) = 2

                  isuppz(2*m) = 2

               END IF

            ENDIF

         ENDIF

         IF( alleig.OR.

     $      (valeig.AND.(r1.GT.wl).AND.

     $                  (r1.LE.wu)).OR.

     $      (indeig.AND.(iiu.EQ.2)) ) THEN

            m = m+1

            w( m ) = r1

            IF( wantz.AND.(.NOT.zquery) ) THEN

               z( 1, m ) = cs

               z( 2, m ) = sn

*              Note: At most one of SN and CS can be zero.

               IF (sn.NE.zero) THEN

                  IF (cs.NE.zero) THEN

                     isuppz(2*m-1) = 1

                     isuppz(2*m) = 2

                  ELSE

                     isuppz(2*m-1) = 1

                     isuppz(2*m) = 1

                  END IF

               ELSE

                  isuppz(2*m-1) = 2

                  isuppz(2*m) = 2

               END IF

            ENDIF

         ENDIF

      ELSE


*        Continue with general N


         indgrs = 1

         inderr = 2*n + 1

         indgp = 3*n + 1

         indd = 4*n + 1

         inde2 = 5*n + 1

         indwrk = 6*n + 1

*

         iinspl = 1

         iindbl = n + 1

         iindw = 2*n + 1

         iindwk = 3*n + 1

*

*        Scale matrix to allowable range, if necessary.

*        The allowable range is related to the PIVMIN parameter; see the

*        comments in SLARRD.  The preference for scaling small values

*        up is heuristic; we expect users' matrices not to be close to the

*        RMAX threshold.

*

         scale = one

         tnrm = slanst( 'M', n, d, e )

         IF( tnrm.GT.zero .AND. tnrm.LT.rmin ) THEN

            scale = rmin / tnrm

         ELSE IF( tnrm.GT.rmax ) THEN

            scale = rmax / tnrm

         END IF

         IF( scale.NE.one ) THEN

            CALL sscal( n, scale, d, 1 )

            CALL sscal( n-1, scale, e, 1 )

            tnrm = tnrm*scale

            IF( valeig ) THEN

*              If eigenvalues in interval have to be found,

*              scale (WL, WU] accordingly

               wl = wl*scale

               wu = wu*scale

            ENDIF

         END IF

*

*        Compute the desired eigenvalues of the tridiagonal after splitting

*        into smaller subblocks if the corresponding off-diagonal elements

*        are small

*        THRESH is the splitting parameter for SLARRE

*        A negative THRESH forces the old splitting criterion based on the

*        size of the off-diagonal. A positive THRESH switches to splitting

*        which preserves relative accuracy.

*

         IF( tryrac ) THEN

*           Test whether the matrix warrants the more expensive relative approach.

            CALL slarrr( n, d, e, iinfo )

         ELSE

*           The user does not care about relative accurately eigenvalues

            iinfo = -1

         ENDIF

*        Set the splitting criterion

         IF (iinfo.EQ.0) THEN

            thresh = eps

         ELSE

            thresh = -eps

*           relative accuracy is desired but T does not guarantee it

            tryrac = .false.

         ENDIF

*

         IF( tryrac ) THEN

*           Copy original diagonal, needed to guarantee relative accuracy

            CALL scopy(n,d,1,work(indd),1)

         ENDIF

*        Store the squares of the offdiagonal values of T

         DO 5 j = 1, n-1

            work( inde2+j-1 ) = e(j)**2

 5    CONTINUE


*        Set the tolerance parameters for bisection

         IF( .NOT.wantz ) THEN

*           SLARRE computes the eigenvalues to full precision.

            rtol1 = four * eps

            rtol2 = four * eps

         ELSE

*           SLARRE computes the eigenvalues to less than full precision.

*           CLARRV will refine the eigenvalue approximations, and we only

*           need less accurate initial bisection in SLARRE.

*           Note: these settings do only affect the subset case and SLARRE

            rtol1 = max( sqrt(eps)*5.0e-2, four * eps )

            rtol2 = max( sqrt(eps)*5.0e-3, four * eps )

         ENDIF

         CALL slarre( range, n, wl, wu, iil, iiu, d, e,

     $             work(inde2), rtol1, rtol2, thresh, nsplit,

     $             iwork( iinspl ), m, w, work( inderr ),

     $             work( indgp ), iwork( iindbl ),

     $             iwork( iindw ), work( indgrs ), pivmin,

     $             work( indwrk ), iwork( iindwk ), iinfo )

         IF( iinfo.NE.0 ) THEN

            info = 10 + abs( iinfo )

            RETURN

         END IF

*        Note that if RANGE .NE. 'V', SLARRE computes bounds on the desired

*        part of the spectrum. All desired eigenvalues are contained in

*        (WL,WU]


         IF( wantz ) THEN

*

*           Compute the desired eigenvectors corresponding to the computed

*           eigenvalues

*

            CALL clarrv( n, wl, wu, d, e,

     $                pivmin, iwork( iinspl ), m,

     $                1, m, minrgp, rtol1, rtol2,

     $                w, work( inderr ), work( indgp ), iwork( iindbl ),

     $                iwork( iindw ), work( indgrs ), z, ldz,

     $                isuppz, work( indwrk ), iwork( iindwk ), iinfo )

            IF( iinfo.NE.0 ) THEN

               info = 20 + abs( iinfo )

               RETURN

            END IF

         ELSE

*           SLARRE computes eigenvalues of the (shifted) root representation

*           CLARRV returns the eigenvalues of the unshifted matrix.

*           However, if the eigenvectors are not desired by the user, we need

*           to apply the corresponding shifts from SLARRE to obtain the

*           eigenvalues of the original matrix.

            DO 20 j = 1, m

               itmp = iwork( iindbl+j-1 )

               w( j ) = w( j ) + e( iwork( iinspl+itmp-1 ) )

 20      CONTINUE

         END IF

*


         IF ( tryrac ) THEN

*           Refine computed eigenvalues so that they are relatively accurate

*           with respect to the original matrix T.

            ibegin = 1

            wbegin = 1

            DO 39  jblk = 1, iwork( iindbl+m-1 )

               iend = iwork( iinspl+jblk-1 )

               in = iend - ibegin + 1

               wend = wbegin - 1

*              check if any eigenvalues have to be refined in this block

 36         CONTINUE

               IF( wend.LT.m ) THEN

                  IF( iwork( iindbl+wend ).EQ.jblk ) THEN

                     wend = wend + 1

                     GO TO 36

                  END IF

               END IF

               IF( wend.LT.wbegin ) THEN

                  ibegin = iend + 1

                  GO TO 39

               END IF


               offset = iwork(iindw+wbegin-1)-1

               ifirst = iwork(iindw+wbegin-1)

               ilast = iwork(iindw+wend-1)

               rtol2 = four * eps

               CALL slarrj( in,

     $                   work(indd+ibegin-1), work(inde2+ibegin-1),

     $                   ifirst, ilast, rtol2, offset, w(wbegin),

     $                   work( inderr+wbegin-1 ),

     $                   work( indwrk ), iwork( iindwk ), pivmin,

     $                   tnrm, iinfo )

               ibegin = iend + 1

               wbegin = wend + 1

 39      CONTINUE

         ENDIF

*

*        If matrix was scaled, then rescale eigenvalues appropriately.

*

         IF( scale.NE.one ) THEN

            CALL sscal( m, one / scale, w, 1 )

         END IF

      END IF

*

*     If eigenvalues are not in increasing order, then sort them,

*     possibly along with eigenvectors.

*

      IF( nsplit.GT.1 .OR. n.EQ.2 ) THEN

         IF( .NOT. wantz ) THEN

            CALL slasrt( 'I', m, w, iinfo )

            IF( iinfo.NE.0 ) THEN

               info = 3

               RETURN

            END IF

         ELSE

            DO 60 j = 1, m - 1

               i = 0

               tmp = w( j )

               DO 50 jj = j + 1, m

                  IF( w( jj ).LT.tmp ) THEN

                     i = jj

                     tmp = w( jj )

                  END IF

 50            CONTINUE

               IF( i.NE.0 ) THEN

                  w( i ) = w( j )

                  w( j ) = tmp

                  IF( wantz ) THEN

                     CALL cswap( n, z( 1, i ), 1, z( 1, j ), 1 )

                     itmp = isuppz( 2*i-1 )

                     isuppz( 2*i-1 ) = isuppz( 2*j-1 )

                     isuppz( 2*j-1 ) = itmp

                     itmp = isuppz( 2*i )

                     isuppz( 2*i ) = isuppz( 2*j )

                     isuppz( 2*j ) = itmp

                  END IF

               END IF

 60         CONTINUE

         END IF

      ENDIF

*

*

      work( 1 ) = lwmin

      iwork( 1 ) = liwmin

      RETURN

*

*     End of CSTEMR

*

      END