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NAME
     zgegv - compute for a pair of  N-by-N  complex  nonsymmetric
     matrices A and B, the generalized eigenvalues (alpha, beta),
     and optionally,

SYNOPSIS
     SUBROUTINE ZGEGV( JOBVL, JOBVR, N, A, LDA,  B,  LDB,  ALPHA,
               BETA, VL, LDVL, VR, LDVR, WORK, LWORK, RWORK, INFO
               )

     CHARACTER JOBVL, JOBVR

     INTEGER INFO, LDA, LDB, LDVL, LDVR, LWORK, N

     DOUBLE PRECISION RWORK( * )

     COMPLEX*16 A( LDA, * ), ALPHA( * ), B( LDB, * ), BETA( *  ),
               VL( LDVL, * ), VR( LDVR, * ), WORK( * )



     #include <sunperf.h>

     void zgegv(char jobvl, char jobvr, int n, doublecomplex *za,
               int lda, doublecomplex *zb, int ldb, doublecomplex
               *zalpha, doublecomplex *zbeta, doublecomplex  *vl,
               int ldvl, doublecomplex *vr, int ldvr, int *info);

PURPOSE
     ZGEGV computes for a pair  of  N-by-N  complex  nonsymmetric
     matrices A and B, the generalized eigenvalues (alpha, beta),
     and optionally, the left and/or right generalized  eigenvec-
     tors (VL and VR).

     A generalized eigenvalue for a pair of  matrices  (A,B)  is,
     roughly  speaking,  a  scalar  w or a ratio  alpha/beta = w,
     such that  A - w*B is singular.  It is  usually  represented
     as the pair (alpha,beta), as there is a reasonable interpre-
     tation for beta=0, and even for both  being  zero.   A  good
     beginning  reference  is the book, "Matrix Computations", by
     G. Golub & C. van Loan (Johns Hopkins U. Press)

     A right generalized eigenvector corresponding to a  general-
     ized eigenvalue  w  for a pair of matrices (A,B) is a vector
     r  such that  (A - w B) r = 0 .  A left  generalized  eigen-
     vector  is  a vector l such that l**H * (A - w B) = 0, where
     l**H is the
     conjugate-transpose of l.

     Note: this routine performs "full balancing" on A and  B  --
     see "Further Details", below.

ARGUMENTS
     JOBVL     (input) CHARACTER*1
               = 'N':  do not compute the left generalized eigen-
               vectors;
               = 'V':  compute the left generalized eigenvectors.

     JOBVR     (input) CHARACTER*1
               = 'N':   do  not  compute  the  right  generalized
               eigenvectors;
               = 'V':  compute the  right  generalized  eigenvec-
               tors.

     N         (input) INTEGER
               The order of the matrices A, B, VL, and VR.  N  >=
               0.

     A         (input/output) COMPLEX*16 array,  dimension  (LDA,
               N)
               On entry, the first of the pair of matrices  whose
               generalized  eigenvalues and (optionally) general-
               ized eigenvectors are to be  computed.   On  exit,
               the  contents  will  have  been destroyed.  (For a
               description of the contents  of  A  on  exit,  see
               "Further Details", below.)

     LDA       (input) INTEGER
               The leading dimension of A.  LDA >= max(1,N).

     B         (input/output) COMPLEX*16 array,  dimension  (LDB,
               N)
               On entry, the second of the pair of matrices whose
               generalized  eigenvalues and (optionally) general-
               ized eigenvectors are to be  computed.   On  exit,
               the  contents  will  have  been destroyed.  (For a
               description of the contents  of  B  on  exit,  see
               "Further Details", below.)

     LDB       (input) INTEGER
               The leading dimension of B.  LDB >= max(1,N).

     ALPHA     (output) COMPLEX*16 array, dimension (N)
               BETA    (output) COMPLEX*16 array,  dimension  (N)
               On  exit, ALPHA(j)/BETA(j), j=1,...,N, will be the
               generalized eigenvalues.

               Note: the quotients  ALPHA(j)/BETA(j)  may  easily
               over-  or underflow, and BETA(j) may even be zero.
               Thus, the user should avoid naively computing  the
               ratio  alpha/beta.   However, ALPHA will be always
               less than and usually comparable with  norm(A)  in
               magnitude,  and  BETA always less than and usually
               comparable with norm(B).

     VL        (output) COMPLEX*16 array, dimension (LDVL,N)
               If JOBVL = 'V', the left generalized eigenvectors.
               (See  "Purpose", above.)  Each eigenvector will be
               scaled so the largest component will have abs(real
               part)  +  abs(imag.  part)  = 1, *except* that for
               eigenvalues with alpha=beta=0, a zero vector  will
               be returned as the corresponding eigenvector.  Not
               referenced if JOBVL = 'N'.

     LDVL      (input) INTEGER
               The leading dimension of the matrix VL. LDVL >= 1,
               and if JOBVL = 'V', LDVL >= N.

     VR        (output) COMPLEX*16 array, dimension (LDVR,N)
               If JOBVL = 'V', the  right  generalized  eigenvec-
               tors.   (See  "Purpose", above.)  Each eigenvector
               will be scaled so the largest component will  have
               abs(real  part)  +  abs(imag.  part) = 1, *except*
               that for eigenvalues  with  alpha=beta=0,  a  zero
               vector  will  be  returned  as  the  corresponding
               eigenvector.  Not referenced if JOBVR = 'N'.

     LDVR      (input) INTEGER
               The leading dimension of the matrix VR. LDVR >= 1,
               and if JOBVR = 'V', LDVR >= N.

     WORK      (workspace/output)  COMPLEX*16  array,   dimension
               (LWORK)
               On exit, if INFO = 0, WORK(1) returns the  optimal
               LWORK.

     LWORK     (input) INTEGER
               The  dimension  of  the  array  WORK.   LWORK   >=
               max(1,2*N).  For good performance, LWORK must gen-
               erally be larger.  To compute the optimal value of
               LWORK,  call ILAENV to get blocksizes (for ZGEQRF,
               ZUNMQR, and CUNGQR.)  Then compute:  NB  -- MAX of
               the blocksizes for ZGEQRF, ZUNMQR, and CUNGQR; The
               optimal LWORK is  MAX( 2*N, N*(NB+1) ).

     RWORK     (workspace/output) DOUBLE PRECISION array,  dimen-
               sion (8*N)

     INFO      (output) INTEGER
               = 0:  successful exit
               < 0:  if INFO = -i, the i-th argument had an ille-
               gal value.
               =1,...,N:  The QZ iteration failed.  No  eigenvec-
               tors   have  been  calculated,  but  ALPHA(j)  and
               BETA(j) should be correct for  j=INFO+1,...,N.   >
               N:  errors that usually indicate LAPACK problems:
               =N+1: error return from ZGGBAL
               =N+2: error return from ZGEQRF
               =N+3: error return from ZUNMQR
               =N+4: error return from ZUNGQR
               =N+5: error return from ZGGHRD
               =N+6: error return from ZHGEQZ (other than  failed
               iteration) =N+7: error return from ZTGEVC
               =N+8: error return from ZGGBAK (computing VL)
               =N+9: error return from ZGGBAK (computing VR)
               =N+10: error return from ZLASCL (various calls)

FURTHER DETAILS
     Balancing
     ---------

     This driver calls ZGGBAL to both permute and scale rows  and
     columns  of  A and B.  The permutations PL and PR are chosen
     so that PL*A*PR and PL*B*R will be upper  triangular  except
     for  the  diagonal  blocks A(i:j,i:j) and B(i:j,i:j), with i
     and j as close together as possible.  The  diagonal  scaling
     matrices   DL   and   DR   are   chosen  so  that  the  pair
     DL*PL*A*PR*DR, DL*PL*B*PR*DR  have  elements  close  to  one
     (except for the elements that start out zero.)

     After the  eigenvalues  and  eigenvectors  of  the  balanced
     matrices have been computed, ZGGBAK transforms the eigenvec-
     tors back to what they would have been  (in  perfect  arith-
     metic) if they had not been balanced.

     Contents of A and B on Exit
     -------- -- - --- - -- ----

     If  any  eigenvectors  are  computed  (either  JOBVL='V'  or
     JOBVR='V'  or  both),  then  on exit the arrays A and B will
     contain the complex Schur form[*] of the "balanced" versions
     of  A and B.  If no eigenvectors are computed, then only the
     diagonal blocks will be correct.

     [*] In other words, upper triangular form.

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