d1/d3d/sbbcsd_8f_source.html

 *> \brief \b SBBCSD
 *
 *  =========== DOCUMENTATION ===========
 *
 * Online html documentation available at
 *            http://www.netlib.org/lapack/explore-html/
 *
 *> \htmlonly
 *> Download SBBCSD + dependencies
 *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.tgz?format=tgz&filename=/lapack/lapack_routine/sbbcsd.f">
 *> [TGZ]</a>
 *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.zip?format=zip&filename=/lapack/lapack_routine/sbbcsd.f">
 *> [ZIP]</a>
 *> <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/sbbcsd.f">
 *> [TXT]</a>
 *> \endhtmlonly
 *
 *  Definition:
 *  ===========
 *
 *       SUBROUTINE SBBCSD( JOBU1, JOBU2, JOBV1T, JOBV2T, TRANS, M, P, Q,
 *                          THETA, PHI, U1, LDU1, U2, LDU2, V1T, LDV1T,
 *                          V2T, LDV2T, B11D, B11E, B12D, B12E, B21D, B21E,
 *                          B22D, B22E, WORK, LWORK, INFO )
 *
 *       .. Scalar Arguments ..
 *       CHARACTER          JOBU1, JOBU2, JOBV1T, JOBV2T, TRANS
 *       INTEGER            INFO, LDU1, LDU2, LDV1T, LDV2T, LWORK, M, P, Q
 *       ..
 *       .. Array Arguments ..
 *       REAL               B11D( * ), B11E( * ), B12D( * ), B12E( * ),
 *      $                   B21D( * ), B21E( * ), B22D( * ), B22E( * ),
 *      $                   PHI( * ), THETA( * ), WORK( * )
 *       REAL               U1( LDU1, * ), U2( LDU2, * ), V1T( LDV1T, * ),
 *      $                   V2T( LDV2T, * )
 *       ..
 *
 *
 *> \par Purpose:
 *  =============
 *>
 *> \verbatim
 *>
 *> SBBCSD computes the CS decomposition of an orthogonal matrix in
 *> bidiagonal-block form,
 *>
 *>
 *>     [ B11 | B12 0  0 ]
 *>     [  0  |  0 -I  0 ]
 *> X = [----------------]
 *>     [ B21 | B22 0  0 ]
 *>     [  0  |  0  0  I ]
 *>
 *>                               [  C | -S  0  0 ]
 *>                   [ U1 |    ] [  0 |  0 -I  0 ] [ V1 |    ]**T
 *>                 = [---------] [---------------] [---------]   .
 *>                   [    | U2 ] [  S |  C  0  0 ] [    | V2 ]
 *>                               [  0 |  0  0  I ]
 *>
 *> X is M-by-M, its top-left block is P-by-Q, and Q must be no larger
 *> than P, M-P, or M-Q. (If Q is not the smallest index, then X must be
 *> transposed and/or permuted. This can be done in constant time using
 *> the TRANS and SIGNS options. See SORCSD for details.)
 *>
 *> The bidiagonal matrices B11, B12, B21, and B22 are represented
 *> implicitly by angles THETA(1:Q) and PHI(1:Q-1).
 *>
 *> The orthogonal matrices U1, U2, V1T, and V2T are input/output.
 *> The input matrices are pre- or post-multiplied by the appropriate
 *> singular vector matrices.
 *> \endverbatim
 *
 *  Arguments:
 *  ==========
 *
 *> \param[in] JOBU1
 *> \verbatim
 *>          JOBU1 is CHARACTER
 *>          = 'Y':      U1 is updated;
 *>          otherwise:  U1 is not updated.
 *> \endverbatim
 *>
 *> \param[in] JOBU2
 *> \verbatim
 *>          JOBU2 is CHARACTER
 *>          = 'Y':      U2 is updated;
 *>          otherwise:  U2 is not updated.
 *> \endverbatim
 *>
 *> \param[in] JOBV1T
 *> \verbatim
 *>          JOBV1T is CHARACTER
 *>          = 'Y':      V1T is updated;
 *>          otherwise:  V1T is not updated.
 *> \endverbatim
 *>
 *> \param[in] JOBV2T
 *> \verbatim
 *>          JOBV2T is CHARACTER
 *>          = 'Y':      V2T is updated;
 *>          otherwise:  V2T is not updated.
 *> \endverbatim
 *>
 *> \param[in] TRANS
 *> \verbatim
 *>          TRANS is CHARACTER
 *>          = 'T':      X, U1, U2, V1T, and V2T are stored in row-major
 *>                      order;
 *>          otherwise:  X, U1, U2, V1T, and V2T are stored in column-
 *>                      major order.
 *> \endverbatim
 *>
 *> \param[in] M
 *> \verbatim
 *>          M is INTEGER
 *>          The number of rows and columns in X, the orthogonal matrix in
 *>          bidiagonal-block form.
 *> \endverbatim
 *>
 *> \param[in] P
 *> \verbatim
 *>          P is INTEGER
 *>          The number of rows in the top-left block of X. 0 <= P <= M.
 *> \endverbatim
 *>
 *> \param[in] Q
 *> \verbatim
 *>          Q is INTEGER
 *>          The number of columns in the top-left block of X.
 *>          0 <= Q <= MIN(P,M-P,M-Q).
 *> \endverbatim
 *>
 *> \param[in,out] THETA
 *> \verbatim
 *>          THETA is REAL array, dimension (Q)
 *>          On entry, the angles THETA(1),...,THETA(Q) that, along with
 *>          PHI(1), ...,PHI(Q-1), define the matrix in bidiagonal-block
 *>          form. On exit, the angles whose cosines and sines define the
 *>          diagonal blocks in the CS decomposition.
 *> \endverbatim
 *>
 *> \param[in,out] PHI
 *> \verbatim
 *>          PHI is REAL array, dimension (Q-1)
 *>          The angles PHI(1),...,PHI(Q-1) that, along with THETA(1),...,
 *>          THETA(Q), define the matrix in bidiagonal-block form.
 *> \endverbatim
 *>
 *> \param[in,out] U1
 *> \verbatim
 *>          U1 is REAL array, dimension (LDU1,P)
 *>          On entry, a P-by-P matrix. On exit, U1 is postmultiplied
 *>          by the left singular vector matrix common to [ B11 ; 0 ] and
 *>          [ B12 0 0 ; 0 -I 0 0 ].
 *> \endverbatim
 *>
 *> \param[in] LDU1
 *> \verbatim
 *>          LDU1 is INTEGER
 *>          The leading dimension of the array U1, LDU1 >= MAX(1,P).
 *> \endverbatim
 *>
 *> \param[in,out] U2
 *> \verbatim
 *>          U2 is REAL array, dimension (LDU2,M-P)
 *>          On entry, an (M-P)-by-(M-P) matrix. On exit, U2 is
 *>          postmultiplied by the left singular vector matrix common to
 *>          [ B21 ; 0 ] and [ B22 0 0 ; 0 0 I ].
 *> \endverbatim
 *>
 *> \param[in] LDU2
 *> \verbatim
 *>          LDU2 is INTEGER
 *>          The leading dimension of the array U2, LDU2 >= MAX(1,M-P).
 *> \endverbatim
 *>
 *> \param[in,out] V1T
 *> \verbatim
 *>          V1T is REAL array, dimension (LDV1T,Q)
 *>          On entry, a Q-by-Q matrix. On exit, V1T is premultiplied
 *>          by the transpose of the right singular vector
 *>          matrix common to [ B11 ; 0 ] and [ B21 ; 0 ].
 *> \endverbatim
 *>
 *> \param[in] LDV1T
 *> \verbatim
 *>          LDV1T is INTEGER
 *>          The leading dimension of the array V1T, LDV1T >= MAX(1,Q).
 *> \endverbatim
 *>
 *> \param[in,out] V2T
 *> \verbatim
 *>          V2T is REAL array, dimension (LDV2T,M-Q)
 *>          On entry, an (M-Q)-by-(M-Q) matrix. On exit, V2T is
 *>          premultiplied by the transpose of the right
 *>          singular vector matrix common to [ B12 0 0 ; 0 -I 0 ] and
 *>          [ B22 0 0 ; 0 0 I ].
 *> \endverbatim
 *>
 *> \param[in] LDV2T
 *> \verbatim
 *>          LDV2T is INTEGER
 *>          The leading dimension of the array V2T, LDV2T >= MAX(1,M-Q).
 *> \endverbatim
 *>
 *> \param[out] B11D
 *> \verbatim
 *>          B11D is REAL array, dimension (Q)
 *>          When SBBCSD converges, B11D contains the cosines of THETA(1),
 *>          ..., THETA(Q). If SBBCSD fails to converge, then B11D
 *>          contains the diagonal of the partially reduced top-left
 *>          block.
 *> \endverbatim
 *>
 *> \param[out] B11E
 *> \verbatim
 *>          B11E is REAL array, dimension (Q-1)
 *>          When SBBCSD converges, B11E contains zeros. If SBBCSD fails
 *>          to converge, then B11E contains the superdiagonal of the
 *>          partially reduced top-left block.
 *> \endverbatim
 *>
 *> \param[out] B12D
 *> \verbatim
 *>          B12D is REAL array, dimension (Q)
 *>          When SBBCSD converges, B12D contains the negative sines of
 *>          THETA(1), ..., THETA(Q). If SBBCSD fails to converge, then
 *>          B12D contains the diagonal of the partially reduced top-right
 *>          block.
 *> \endverbatim
 *>
 *> \param[out] B12E
 *> \verbatim
 *>          B12E is REAL array, dimension (Q-1)
 *>          When SBBCSD converges, B12E contains zeros. If SBBCSD fails
 *>          to converge, then B12E contains the subdiagonal of the
 *>          partially reduced top-right block.
 *> \endverbatim
 *>
 *> \param[out] B21D
 *> \verbatim
 *>          B21D is REAL array, dimension (Q)
 *>          When SBBCSD converges, B21D contains the negative sines of
 *>          THETA(1), ..., THETA(Q). If SBBCSD fails to converge, then
 *>          B21D contains the diagonal of the partially reduced bottom-left
 *>          block.
 *> \endverbatim
 *>
 *> \param[out] B21E
 *> \verbatim
 *>          B21E is REAL array, dimension (Q-1)
 *>          When SBBCSD converges, B21E contains zeros. If SBBCSD fails
 *>          to converge, then B21E contains the subdiagonal of the
 *>          partially reduced bottom-left block.
 *> \endverbatim
 *>
 *> \param[out] B22D
 *> \verbatim
 *>          B22D is REAL array, dimension (Q)
 *>          When SBBCSD converges, B22D contains the negative sines of
 *>          THETA(1), ..., THETA(Q). If SBBCSD fails to converge, then
 *>          B22D contains the diagonal of the partially reduced bottom-right
 *>          block.
 *> \endverbatim
 *>
 *> \param[out] B22E
 *> \verbatim
 *>          B22E is REAL array, dimension (Q-1)
 *>          When SBBCSD converges, B22E contains zeros. If SBBCSD fails
 *>          to converge, then B22E contains the subdiagonal of the
 *>          partially reduced bottom-right block.
 *> \endverbatim
 *>
 *> \param[out] WORK
 *> \verbatim
 *>          WORK is REAL array, dimension (MAX(1,LWORK))
 *>          On exit, if INFO = 0, WORK(1) returns the optimal LWORK.
 *> \endverbatim
 *>
 *> \param[in] LWORK
 *> \verbatim
 *>          LWORK is INTEGER
 *>          The dimension of the array WORK. LWORK >= MAX(1,8*Q).
 *>
 *>          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] INFO
 *> \verbatim
 *>          INFO is INTEGER
 *>          = 0:  successful exit.
 *>          < 0:  if INFO = -i, the i-th argument had an illegal value.
 *>          > 0:  if SBBCSD did not converge, INFO specifies the number
 *>                of nonzero entries in PHI, and B11D, B11E, etc.,
 *>                contain the partially reduced matrix.
 *> \endverbatim
 *
 *> \par Internal Parameters:
 *  =========================
 *>
 *> \verbatim
 *>  TOLMUL  REAL, default = MAX(10,MIN(100,EPS**(-1/8)))
 *>          TOLMUL controls the convergence criterion of the QR loop.
 *>          Angles THETA(i), PHI(i) are rounded to 0 or PI/2 when they
 *>          are within TOLMUL*EPS of either bound.
 *> \endverbatim
 *
 *> \par References:
 *  ================
 *>
 *>  [1] Brian D. Sutton. Computing the complete CS decomposition. Numer.
 *>      Algorithms, 50(1):33-65, 2009.
 *
 *  Authors:
 *  ========
 *
 *> \author Univ. of Tennessee
 *> \author Univ. of California Berkeley
 *> \author Univ. of Colorado Denver
 *> \author NAG Ltd.
 *
 *> \ingroup bbcsd
 *
 *  =====================================================================
       SUBROUTINE sbbcsd( JOBU1, JOBU2, JOBV1T, JOBV2T, TRANS, M, P, Q,
      $                   THETA, PHI, U1, LDU1, U2, LDU2, V1T, LDV1T,
      $                   V2T, LDV2T, B11D, B11E, B12D, B12E, B21D, B21E,
      $                   B22D, B22E, WORK, LWORK, INFO )
 *
 *  -- LAPACK computational routine --
 *  -- LAPACK is a software package provided by Univ. of Tennessee,    --
 *  -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--
 *
 *     .. Scalar Arguments ..
       CHARACTER          JOBU1, JOBU2, JOBV1T, JOBV2T, TRANS
       INTEGER            INFO, LDU1, LDU2, LDV1T, LDV2T, LWORK, M, P, Q
 *     ..
 *     .. Array Arguments ..
       REAL               B11D( * ), B11E( * ), B12D( * ), B12E( * ),
      $                   b21d( * ), b21e( * ), b22d( * ), b22e( * ),
      $                   phi( * ), theta( * ), work( * )
       REAL               U1( ldu1, * ), U2( ldu2, * ), V1T( ldv1t, * ),
      $                   v2t( ldv2t, * )
 *     ..
 *
 *  ===================================================================
 *
 *     .. Parameters ..
       INTEGER            MAXITR
       parameter( maxitr = 6 )
       REAL               HUNDRED, MEIGHTH, ONE, TEN, ZERO
       parameter( hundred = 100.0e0, meighth = -0.125e0,
      $                     one = 1.0e0, ten = 10.0e0, zero = 0.0e0 )
       REAL               NEGONE
       parameter( negone = -1.0e0 )
       REAL               PIOVER2
       parameter( piover2 = 1.57079632679489661923132169163975144210e0 )
 *     ..
 *     .. Local Scalars ..
       LOGICAL            COLMAJOR, LQUERY, RESTART11, RESTART12,
      $                   restart21, restart22, wantu1, wantu2, wantv1t,
      $                   wantv2t
       INTEGER            I, IMIN, IMAX, ITER, IU1CS, IU1SN, IU2CS,
      $                   iu2sn, iv1tcs, iv1tsn, iv2tcs, iv2tsn, j,
      $                   lworkmin, lworkopt, maxit, mini
       REAL               B11BULGE, B12BULGE, B21BULGE, B22BULGE, DUMMY,
      $                   eps, mu, nu, r, sigma11, sigma21,
      $                   temp, thetamax, thetamin, thresh, tol, tolmul,
      $                   unfl, x1, x2, y1, y2
 *
 *     .. External Subroutines ..
       EXTERNAL           slasr, sscal, sswap, slartgp, slartgs, slas2,
      $                   xerbla
 *     ..
 *     .. External Functions ..
       REAL               SLAMCH
       LOGICAL            LSAME
       EXTERNAL           lsame, slamch
 *     ..
 *     .. Intrinsic Functions ..
       INTRINSIC          abs, atan2, cos, max, min, sin, sqrt
 *     ..
 *     .. Executable Statements ..
 *
 *     Test input arguments
 *
       info = 0
       lquery = lwork .EQ. -1
       wantu1 = lsame( jobu1, 'Y' )
       wantu2 = lsame( jobu2, 'Y' )
       wantv1t = lsame( jobv1t, 'Y' )
       wantv2t = lsame( jobv2t, 'Y' )
       colmajor = .NOT. lsame( trans, 'T' )
 *
       IF( m .LT. 0 ) THEN
          info = -6
       ELSE IF( p .LT. 0 .OR. p .GT. m ) THEN
          info = -7
       ELSE IF( q .LT. 0 .OR. q .GT. m ) THEN
          info = -8
       ELSE IF( q .GT. p .OR. q .GT. m-p .OR. q .GT. m-q ) THEN
          info = -8
       ELSE IF( wantu1 .AND. ldu1 .LT. p ) THEN
          info = -12
       ELSE IF( wantu2 .AND. ldu2 .LT. m-p ) THEN
          info = -14
       ELSE IF( wantv1t .AND. ldv1t .LT. q ) THEN
          info = -16
       ELSE IF( wantv2t .AND. ldv2t .LT. m-q ) THEN
          info = -18
       END IF
 *
 *     Quick return if Q = 0
 *
       IF( info .EQ. 0 .AND. q .EQ. 0 ) THEN
          lworkmin = 1
          work(1) = lworkmin
          RETURN
       END IF
 *
 *     Compute workspace
 *
       IF( info .EQ. 0 ) THEN
          iu1cs = 1
          iu1sn = iu1cs + q
          iu2cs = iu1sn + q
          iu2sn = iu2cs + q
          iv1tcs = iu2sn + q
          iv1tsn = iv1tcs + q
          iv2tcs = iv1tsn + q
          iv2tsn = iv2tcs + q
          lworkopt = iv2tsn + q - 1
          lworkmin = lworkopt
          work(1) = lworkopt
          IF( lwork .LT. lworkmin .AND. .NOT. lquery ) THEN
             info = -28
          END IF
       END IF
 *
       IF( info .NE. 0 ) THEN
          CALL xerbla( 'SBBCSD', -info )
          RETURN
       ELSE IF( lquery ) THEN
          RETURN
       END IF
 *
 *     Get machine constants
 *
       eps = slamch( 'Epsilon' )
       unfl = slamch( 'Safe minimum' )
       tolmul = max( ten, min( hundred, eps**meighth ) )
       tol = tolmul*eps
       thresh = max( tol, maxitr*q*q*unfl )
 *
 *     Test for negligible sines or cosines
 *
       DO i = 1, q
          IF( theta(i) .LT. thresh ) THEN
             theta(i) = zero
          ELSE IF( theta(i) .GT. piover2-thresh ) THEN
             theta(i) = piover2
          END IF
       END DO
       DO i = 1, q-1
          IF( phi(i) .LT. thresh ) THEN
             phi(i) = zero
          ELSE IF( phi(i) .GT. piover2-thresh ) THEN
             phi(i) = piover2
          END IF
       END DO
 *
 *     Initial deflation
 *
       imax = q
       DO WHILE( imax .GT. 1 )
          IF( phi(imax-1) .NE. zero ) THEN
             EXIT
          END IF
          imax = imax - 1
       END DO
       imin = imax - 1
       IF  ( imin .GT. 1 ) THEN
          DO WHILE( phi(imin-1) .NE. zero )
             imin = imin - 1
             IF  ( imin .LE. 1 ) EXIT
          END DO
       END IF
 *
 *     Initialize iteration counter
 *
       maxit = maxitr*q*q
       iter = 0
 *
 *     Begin main iteration loop
 *
       DO WHILE( imax .GT. 1 )
 *
 *        Compute the matrix entries
 *
          b11d(imin) = cos( theta(imin) )
          b21d(imin) = -sin( theta(imin) )
          DO i = imin, imax - 1
             b11e(i) = -sin( theta(i) ) * sin( phi(i) )
             b11d(i+1) = cos( theta(i+1) ) * cos( phi(i) )
             b12d(i) = sin( theta(i) ) * cos( phi(i) )
             b12e(i) = cos( theta(i+1) ) * sin( phi(i) )
             b21e(i) = -cos( theta(i) ) * sin( phi(i) )
             b21d(i+1) = -sin( theta(i+1) ) * cos( phi(i) )
             b22d(i) = cos( theta(i) ) * cos( phi(i) )
             b22e(i) = -sin( theta(i+1) ) * sin( phi(i) )
          END DO
          b12d(imax) = sin( theta(imax) )
          b22d(imax) = cos( theta(imax) )
 *
 *        Abort if not converging; otherwise, increment ITER
 *
          IF( iter .GT. maxit ) THEN
             info = 0
             DO i = 1, q
                IF( phi(i) .NE. zero )
      $            info = info + 1
             END DO
             RETURN
          END IF
 *
          iter = iter + imax - imin
 *
 *        Compute shifts
 *
          thetamax = theta(imin)
          thetamin = theta(imin)
          DO i = imin+1, imax
             IF( theta(i) > thetamax )
      $         thetamax = theta(i)
             IF( theta(i) < thetamin )
      $         thetamin = theta(i)
          END DO
 *
          IF( thetamax .GT. piover2 - thresh ) THEN
 *
 *           Zero on diagonals of B11 and B22; induce deflation with a
 *           zero shift
 *
             mu = zero
             nu = one
 *
          ELSE IF( thetamin .LT. thresh ) THEN
 *
 *           Zero on diagonals of B12 and B22; induce deflation with a
 *           zero shift
 *
             mu = one
             nu = zero
 *
          ELSE
 *
 *           Compute shifts for B11 and B21 and use the lesser
 *
             CALL slas2( b11d(imax-1), b11e(imax-1), b11d(imax), sigma11,
      $                  dummy )
             CALL slas2( b21d(imax-1), b21e(imax-1), b21d(imax), sigma21,
      $                  dummy )
 *
             IF( sigma11 .LE. sigma21 ) THEN
                mu = sigma11
                nu = sqrt( one - mu**2 )
                IF( mu .LT. thresh ) THEN
                   mu = zero
                   nu = one
                END IF
             ELSE
                nu = sigma21
                mu = sqrt( 1.0 - nu**2 )
                IF( nu .LT. thresh ) THEN
                   mu = one
                   nu = zero
                END IF
             END IF
          END IF
 *
 *        Rotate to produce bulges in B11 and B21
 *
          IF( mu .LE. nu ) THEN
             CALL slartgs( b11d(imin), b11e(imin), mu,
      $                    work(iv1tcs+imin-1), work(iv1tsn+imin-1) )
          ELSE
             CALL slartgs( b21d(imin), b21e(imin), nu,
      $                    work(iv1tcs+imin-1), work(iv1tsn+imin-1) )
          END IF
 *
          temp = work(iv1tcs+imin-1)*b11d(imin) +
      $          work(iv1tsn+imin-1)*b11e(imin)
          b11e(imin) = work(iv1tcs+imin-1)*b11e(imin) -
      $                work(iv1tsn+imin-1)*b11d(imin)
          b11d(imin) = temp
          b11bulge = work(iv1tsn+imin-1)*b11d(imin+1)
          b11d(imin+1) = work(iv1tcs+imin-1)*b11d(imin+1)
          temp = work(iv1tcs+imin-1)*b21d(imin) +
      $          work(iv1tsn+imin-1)*b21e(imin)
          b21e(imin) = work(iv1tcs+imin-1)*b21e(imin) -
      $                work(iv1tsn+imin-1)*b21d(imin)
          b21d(imin) = temp
          b21bulge = work(iv1tsn+imin-1)*b21d(imin+1)
          b21d(imin+1) = work(iv1tcs+imin-1)*b21d(imin+1)
 *
 *        Compute THETA(IMIN)
 *
          theta( imin ) = atan2( sqrt( b21d(imin)**2+b21bulge**2 ),
      $                   sqrt( b11d(imin)**2+b11bulge**2 ) )
 *
 *        Chase the bulges in B11(IMIN+1,IMIN) and B21(IMIN+1,IMIN)
 *
          IF( b11d(imin)**2+b11bulge**2 .GT. thresh**2 ) THEN
             CALL slartgp( b11bulge, b11d(imin), work(iu1sn+imin-1),
      $                    work(iu1cs+imin-1), r )
          ELSE IF( mu .LE. nu ) THEN
             CALL slartgs( b11e( imin ), b11d( imin + 1 ), mu,
      $                    work(iu1cs+imin-1), work(iu1sn+imin-1) )
          ELSE
             CALL slartgs( b12d( imin ), b12e( imin ), nu,
      $                    work(iu1cs+imin-1), work(iu1sn+imin-1) )
          END IF
          IF( b21d(imin)**2+b21bulge**2 .GT. thresh**2 ) THEN
             CALL slartgp( b21bulge, b21d(imin), work(iu2sn+imin-1),
      $                    work(iu2cs+imin-1), r )
          ELSE IF( nu .LT. mu ) THEN
             CALL slartgs( b21e( imin ), b21d( imin + 1 ), nu,
      $                    work(iu2cs+imin-1), work(iu2sn+imin-1) )
          ELSE
             CALL slartgs( b22d(imin), b22e(imin), mu,
      $                    work(iu2cs+imin-1), work(iu2sn+imin-1) )
          END IF
          work(iu2cs+imin-1) = -work(iu2cs+imin-1)
          work(iu2sn+imin-1) = -work(iu2sn+imin-1)
 *
          temp = work(iu1cs+imin-1)*b11e(imin) +
      $          work(iu1sn+imin-1)*b11d(imin+1)
          b11d(imin+1) = work(iu1cs+imin-1)*b11d(imin+1) -
      $                  work(iu1sn+imin-1)*b11e(imin)
          b11e(imin) = temp
          IF( imax .GT. imin+1 ) THEN
             b11bulge = work(iu1sn+imin-1)*b11e(imin+1)
             b11e(imin+1) = work(iu1cs+imin-1)*b11e(imin+1)
          END IF
          temp = work(iu1cs+imin-1)*b12d(imin) +
      $          work(iu1sn+imin-1)*b12e(imin)
          b12e(imin) = work(iu1cs+imin-1)*b12e(imin) -
      $                work(iu1sn+imin-1)*b12d(imin)
          b12d(imin) = temp
          b12bulge = work(iu1sn+imin-1)*b12d(imin+1)
          b12d(imin+1) = work(iu1cs+imin-1)*b12d(imin+1)
          temp = work(iu2cs+imin-1)*b21e(imin) +
      $          work(iu2sn+imin-1)*b21d(imin+1)
          b21d(imin+1) = work(iu2cs+imin-1)*b21d(imin+1) -
      $                  work(iu2sn+imin-1)*b21e(imin)
          b21e(imin) = temp
          IF( imax .GT. imin+1 ) THEN
             b21bulge = work(iu2sn+imin-1)*b21e(imin+1)
             b21e(imin+1) = work(iu2cs+imin-1)*b21e(imin+1)
          END IF
          temp = work(iu2cs+imin-1)*b22d(imin) +
      $          work(iu2sn+imin-1)*b22e(imin)
          b22e(imin) = work(iu2cs+imin-1)*b22e(imin) -
      $                work(iu2sn+imin-1)*b22d(imin)
          b22d(imin) = temp
          b22bulge = work(iu2sn+imin-1)*b22d(imin+1)
          b22d(imin+1) = work(iu2cs+imin-1)*b22d(imin+1)
 *
 *        Inner loop: chase bulges from B11(IMIN,IMIN+2),
 *        B12(IMIN,IMIN+1), B21(IMIN,IMIN+2), and B22(IMIN,IMIN+1) to
 *        bottom-right
 *
          DO i = imin+1, imax-1
 *
 *           Compute PHI(I-1)
 *
             x1 = sin(theta(i-1))*b11e(i-1) + cos(theta(i-1))*b21e(i-1)
             x2 = sin(theta(i-1))*b11bulge + cos(theta(i-1))*b21bulge
             y1 = sin(theta(i-1))*b12d(i-1) + cos(theta(i-1))*b22d(i-1)
             y2 = sin(theta(i-1))*b12bulge + cos(theta(i-1))*b22bulge
 *
             phi(i-1) = atan2( sqrt(x1**2+x2**2), sqrt(y1**2+y2**2) )
 *
 *           Determine if there are bulges to chase or if a new direct
 *           summand has been reached
 *
             restart11 = b11e(i-1)**2 + b11bulge**2 .LE. thresh**2
             restart21 = b21e(i-1)**2 + b21bulge**2 .LE. thresh**2
             restart12 = b12d(i-1)**2 + b12bulge**2 .LE. thresh**2
             restart22 = b22d(i-1)**2 + b22bulge**2 .LE. thresh**2
 *
 *           If possible, chase bulges from B11(I-1,I+1), B12(I-1,I),
 *           B21(I-1,I+1), and B22(I-1,I). If necessary, restart bulge-
 *           chasing by applying the original shift again.
 *
             IF( .NOT. restart11 .AND. .NOT. restart21 ) THEN
                CALL slartgp( x2, x1, work(iv1tsn+i-1), work(iv1tcs+i-1),
      $                       r )
             ELSE IF( .NOT. restart11 .AND. restart21 ) THEN
                CALL slartgp( b11bulge, b11e(i-1), work(iv1tsn+i-1),
      $                       work(iv1tcs+i-1), r )
             ELSE IF( restart11 .AND. .NOT. restart21 ) THEN
                CALL slartgp( b21bulge, b21e(i-1), work(iv1tsn+i-1),
      $                       work(iv1tcs+i-1), r )
             ELSE IF( mu .LE. nu ) THEN
                CALL slartgs( b11d(i), b11e(i), mu, work(iv1tcs+i-1),
      $                       work(iv1tsn+i-1) )
             ELSE
                CALL slartgs( b21d(i), b21e(i), nu, work(iv1tcs+i-1),
      $                       work(iv1tsn+i-1) )
             END IF
             work(iv1tcs+i-1) = -work(iv1tcs+i-1)
             work(iv1tsn+i-1) = -work(iv1tsn+i-1)
             IF( .NOT. restart12 .AND. .NOT. restart22 ) THEN
                CALL slartgp( y2, y1, work(iv2tsn+i-1-1),
      $                       work(iv2tcs+i-1-1), r )
             ELSE IF( .NOT. restart12 .AND. restart22 ) THEN
                CALL slartgp( b12bulge, b12d(i-1), work(iv2tsn+i-1-1),
      $                       work(iv2tcs+i-1-1), r )
             ELSE IF( restart12 .AND. .NOT. restart22 ) THEN
                CALL slartgp( b22bulge, b22d(i-1), work(iv2tsn+i-1-1),
      $                       work(iv2tcs+i-1-1), r )
             ELSE IF( nu .LT. mu ) THEN
                CALL slartgs( b12e(i-1), b12d(i), nu, work(iv2tcs+i-1-1),
      $                       work(iv2tsn+i-1-1) )
             ELSE
                CALL slartgs( b22e(i-1), b22d(i), mu, work(iv2tcs+i-1-1),
      $                       work(iv2tsn+i-1-1) )
             END IF
 *
             temp = work(iv1tcs+i-1)*b11d(i) + work(iv1tsn+i-1)*b11e(i)
             b11e(i) = work(iv1tcs+i-1)*b11e(i) -
      $                work(iv1tsn+i-1)*b11d(i)
             b11d(i) = temp
             b11bulge = work(iv1tsn+i-1)*b11d(i+1)
             b11d(i+1) = work(iv1tcs+i-1)*b11d(i+1)
             temp = work(iv1tcs+i-1)*b21d(i) + work(iv1tsn+i-1)*b21e(i)
             b21e(i) = work(iv1tcs+i-1)*b21e(i) -
      $                work(iv1tsn+i-1)*b21d(i)
             b21d(i) = temp
             b21bulge = work(iv1tsn+i-1)*b21d(i+1)
             b21d(i+1) = work(iv1tcs+i-1)*b21d(i+1)
             temp = work(iv2tcs+i-1-1)*b12e(i-1) +
      $             work(iv2tsn+i-1-1)*b12d(i)
             b12d(i) = work(iv2tcs+i-1-1)*b12d(i) -
      $                work(iv2tsn+i-1-1)*b12e(i-1)
             b12e(i-1) = temp
             b12bulge = work(iv2tsn+i-1-1)*b12e(i)
             b12e(i) = work(iv2tcs+i-1-1)*b12e(i)
             temp = work(iv2tcs+i-1-1)*b22e(i-1) +
      $             work(iv2tsn+i-1-1)*b22d(i)
             b22d(i) = work(iv2tcs+i-1-1)*b22d(i) -
      $                work(iv2tsn+i-1-1)*b22e(i-1)
             b22e(i-1) = temp
             b22bulge = work(iv2tsn+i-1-1)*b22e(i)
             b22e(i) = work(iv2tcs+i-1-1)*b22e(i)
 *
 *           Compute THETA(I)
 *
             x1 = cos(phi(i-1))*b11d(i) + sin(phi(i-1))*b12e(i-1)
             x2 = cos(phi(i-1))*b11bulge + sin(phi(i-1))*b12bulge
             y1 = cos(phi(i-1))*b21d(i) + sin(phi(i-1))*b22e(i-1)
             y2 = cos(phi(i-1))*b21bulge + sin(phi(i-1))*b22bulge
 *
             theta(i) = atan2( sqrt(y1**2+y2**2), sqrt(x1**2+x2**2) )
 *
 *           Determine if there are bulges to chase or if a new direct
 *           summand has been reached
 *
             restart11 =   b11d(i)**2 + b11bulge**2 .LE. thresh**2
             restart12 = b12e(i-1)**2 + b12bulge**2 .LE. thresh**2
             restart21 =   b21d(i)**2 + b21bulge**2 .LE. thresh**2
             restart22 = b22e(i-1)**2 + b22bulge**2 .LE. thresh**2
 *
 *           If possible, chase bulges from B11(I+1,I), B12(I+1,I-1),
 *           B21(I+1,I), and B22(I+1,I-1). If necessary, restart bulge-
 *           chasing by applying the original shift again.
 *
             IF( .NOT. restart11 .AND. .NOT. restart12 ) THEN
                CALL slartgp( x2, x1, work(iu1sn+i-1), work(iu1cs+i-1),
      $                       r )
             ELSE IF( .NOT. restart11 .AND. restart12 ) THEN
                CALL slartgp( b11bulge, b11d(i), work(iu1sn+i-1),
      $                       work(iu1cs+i-1), r )
             ELSE IF( restart11 .AND. .NOT. restart12 ) THEN
                CALL slartgp( b12bulge, b12e(i-1), work(iu1sn+i-1),
      $                       work(iu1cs+i-1), r )
             ELSE IF( mu .LE. nu ) THEN
                CALL slartgs( b11e(i), b11d(i+1), mu, work(iu1cs+i-1),
      $                       work(iu1sn+i-1) )
             ELSE
                CALL slartgs( b12d(i), b12e(i), nu, work(iu1cs+i-1),
      $                       work(iu1sn+i-1) )
             END IF
             IF( .NOT. restart21 .AND. .NOT. restart22 ) THEN
                CALL slartgp( y2, y1, work(iu2sn+i-1), work(iu2cs+i-1),
      $                       r )
             ELSE IF( .NOT. restart21 .AND. restart22 ) THEN
                CALL slartgp( b21bulge, b21d(i), work(iu2sn+i-1),
      $                       work(iu2cs+i-1), r )
             ELSE IF( restart21 .AND. .NOT. restart22 ) THEN
                CALL slartgp( b22bulge, b22e(i-1), work(iu2sn+i-1),
      $                       work(iu2cs+i-1), r )
             ELSE IF( nu .LT. mu ) THEN
                CALL slartgs( b21e(i), b21e(i+1), nu, work(iu2cs+i-1),
      $                       work(iu2sn+i-1) )
             ELSE
                CALL slartgs( b22d(i), b22e(i), mu, work(iu2cs+i-1),
      $                       work(iu2sn+i-1) )
             END IF
             work(iu2cs+i-1) = -work(iu2cs+i-1)
             work(iu2sn+i-1) = -work(iu2sn+i-1)
 *
             temp = work(iu1cs+i-1)*b11e(i) + work(iu1sn+i-1)*b11d(i+1)
             b11d(i+1) = work(iu1cs+i-1)*b11d(i+1) -
      $                  work(iu1sn+i-1)*b11e(i)
             b11e(i) = temp
             IF( i .LT. imax - 1 ) THEN
                b11bulge = work(iu1sn+i-1)*b11e(i+1)
                b11e(i+1) = work(iu1cs+i-1)*b11e(i+1)
             END IF
             temp = work(iu2cs+i-1)*b21e(i) + work(iu2sn+i-1)*b21d(i+1)
             b21d(i+1) = work(iu2cs+i-1)*b21d(i+1) -
      $                  work(iu2sn+i-1)*b21e(i)
             b21e(i) = temp
             IF( i .LT. imax - 1 ) THEN
                b21bulge = work(iu2sn+i-1)*b21e(i+1)
                b21e(i+1) = work(iu2cs+i-1)*b21e(i+1)
             END IF
             temp = work(iu1cs+i-1)*b12d(i) + work(iu1sn+i-1)*b12e(i)
             b12e(i) = work(iu1cs+i-1)*b12e(i) - work(iu1sn+i-1)*b12d(i)
             b12d(i) = temp
             b12bulge = work(iu1sn+i-1)*b12d(i+1)
             b12d(i+1) = work(iu1cs+i-1)*b12d(i+1)
             temp = work(iu2cs+i-1)*b22d(i) + work(iu2sn+i-1)*b22e(i)
             b22e(i) = work(iu2cs+i-1)*b22e(i) - work(iu2sn+i-1)*b22d(i)
             b22d(i) = temp
             b22bulge = work(iu2sn+i-1)*b22d(i+1)
             b22d(i+1) = work(iu2cs+i-1)*b22d(i+1)
 *
          END DO
 *
 *        Compute PHI(IMAX-1)
 *
          x1 = sin(theta(imax-1))*b11e(imax-1) +
      $        cos(theta(imax-1))*b21e(imax-1)
          y1 = sin(theta(imax-1))*b12d(imax-1) +
      $        cos(theta(imax-1))*b22d(imax-1)
          y2 = sin(theta(imax-1))*b12bulge + cos(theta(imax-1))*b22bulge
 *
          phi(imax-1) = atan2( abs(x1), sqrt(y1**2+y2**2) )
 *
 *        Chase bulges from B12(IMAX-1,IMAX) and B22(IMAX-1,IMAX)
 *
          restart12 = b12d(imax-1)**2 + b12bulge**2 .LE. thresh**2
          restart22 = b22d(imax-1)**2 + b22bulge**2 .LE. thresh**2
 *
          IF( .NOT. restart12 .AND. .NOT. restart22 ) THEN
             CALL slartgp( y2, y1, work(iv2tsn+imax-1-1),
      $                    work(iv2tcs+imax-1-1), r )
          ELSE IF( .NOT. restart12 .AND. restart22 ) THEN
             CALL slartgp( b12bulge, b12d(imax-1), work(iv2tsn+imax-1-1),
      $                    work(iv2tcs+imax-1-1), r )
          ELSE IF( restart12 .AND. .NOT. restart22 ) THEN
             CALL slartgp( b22bulge, b22d(imax-1), work(iv2tsn+imax-1-1),
      $                    work(iv2tcs+imax-1-1), r )
          ELSE IF( nu .LT. mu ) THEN
             CALL slartgs( b12e(imax-1), b12d(imax), nu,
      $                    work(iv2tcs+imax-1-1), work(iv2tsn+imax-1-1) )
          ELSE
             CALL slartgs( b22e(imax-1), b22d(imax), mu,
      $                    work(iv2tcs+imax-1-1), work(iv2tsn+imax-1-1) )
          END IF
 *
          temp = work(iv2tcs+imax-1-1)*b12e(imax-1) +
      $          work(iv2tsn+imax-1-1)*b12d(imax)
          b12d(imax) = work(iv2tcs+imax-1-1)*b12d(imax) -
      $                work(iv2tsn+imax-1-1)*b12e(imax-1)
          b12e(imax-1) = temp
          temp = work(iv2tcs+imax-1-1)*b22e(imax-1) +
      $          work(iv2tsn+imax-1-1)*b22d(imax)
          b22d(imax) = work(iv2tcs+imax-1-1)*b22d(imax) -
      $                work(iv2tsn+imax-1-1)*b22e(imax-1)
          b22e(imax-1) = temp
 *
 *        Update singular vectors
 *
          IF( wantu1 ) THEN
             IF( colmajor ) THEN
                CALL slasr( 'R', 'V', 'F', p, imax-imin+1,
      $                     work(iu1cs+imin-1), work(iu1sn+imin-1),
      $                     u1(1,imin), ldu1 )
             ELSE
                CALL slasr( 'L', 'V', 'F', imax-imin+1, p,
      $                     work(iu1cs+imin-1), work(iu1sn+imin-1),
      $                     u1(imin,1), ldu1 )
             END IF
          END IF
          IF( wantu2 ) THEN
             IF( colmajor ) THEN
                CALL slasr( 'R', 'V', 'F', m-p, imax-imin+1,
      $                     work(iu2cs+imin-1), work(iu2sn+imin-1),
      $                     u2(1,imin), ldu2 )
             ELSE
                CALL slasr( 'L', 'V', 'F', imax-imin+1, m-p,
      $                     work(iu2cs+imin-1), work(iu2sn+imin-1),
      $                     u2(imin,1), ldu2 )
             END IF
          END IF
          IF( wantv1t ) THEN
             IF( colmajor ) THEN
                CALL slasr( 'L', 'V', 'F', imax-imin+1, q,
      $                     work(iv1tcs+imin-1), work(iv1tsn+imin-1),
      $                     v1t(imin,1), ldv1t )
             ELSE
                CALL slasr( 'R', 'V', 'F', q, imax-imin+1,
      $                     work(iv1tcs+imin-1), work(iv1tsn+imin-1),
      $                     v1t(1,imin), ldv1t )
             END IF
          END IF
          IF( wantv2t ) THEN
             IF( colmajor ) THEN
                CALL slasr( 'L', 'V', 'F', imax-imin+1, m-q,
      $                     work(iv2tcs+imin-1), work(iv2tsn+imin-1),
      $                     v2t(imin,1), ldv2t )
             ELSE
                CALL slasr( 'R', 'V', 'F', m-q, imax-imin+1,
      $                     work(iv2tcs+imin-1), work(iv2tsn+imin-1),
      $                     v2t(1,imin), ldv2t )
             END IF
          END IF
 *
 *        Fix signs on B11(IMAX-1,IMAX) and B21(IMAX-1,IMAX)
 *
          IF( b11e(imax-1)+b21e(imax-1) .GT. 0 ) THEN
             b11d(imax) = -b11d(imax)
             b21d(imax) = -b21d(imax)
             IF( wantv1t ) THEN
                IF( colmajor ) THEN
                   CALL sscal( q, negone, v1t(imax,1), ldv1t )
                ELSE
                   CALL sscal( q, negone, v1t(1,imax), 1 )
                END IF
             END IF
          END IF
 *
 *        Compute THETA(IMAX)
 *
          x1 = cos(phi(imax-1))*b11d(imax) +
      $        sin(phi(imax-1))*b12e(imax-1)
          y1 = cos(phi(imax-1))*b21d(imax) +
      $        sin(phi(imax-1))*b22e(imax-1)
 *
          theta(imax) = atan2( abs(y1), abs(x1) )
 *
 *        Fix signs on B11(IMAX,IMAX), B12(IMAX,IMAX-1), B21(IMAX,IMAX),
 *        and B22(IMAX,IMAX-1)
 *
          IF( b11d(imax)+b12e(imax-1) .LT. 0 ) THEN
             b12d(imax) = -b12d(imax)
             IF( wantu1 ) THEN
                IF( colmajor ) THEN
                   CALL sscal( p, negone, u1(1,imax), 1 )
                ELSE
                   CALL sscal( p, negone, u1(imax,1), ldu1 )
                END IF
             END IF
          END IF
          IF( b21d(imax)+b22e(imax-1) .GT. 0 ) THEN
             b22d(imax) = -b22d(imax)
             IF( wantu2 ) THEN
                IF( colmajor ) THEN
                   CALL sscal( m-p, negone, u2(1,imax), 1 )
                ELSE
                   CALL sscal( m-p, negone, u2(imax,1), ldu2 )
                END IF
             END IF
          END IF
 *
 *        Fix signs on B12(IMAX,IMAX) and B22(IMAX,IMAX)
 *
          IF( b12d(imax)+b22d(imax) .LT. 0 ) THEN
             IF( wantv2t ) THEN
                IF( colmajor ) THEN
                   CALL sscal( m-q, negone, v2t(imax,1), ldv2t )
                ELSE
                   CALL sscal( m-q, negone, v2t(1,imax), 1 )
                END IF
             END IF
          END IF
 *
 *        Test for negligible sines or cosines
 *
          DO i = imin, imax
             IF( theta(i) .LT. thresh ) THEN
                theta(i) = zero
             ELSE IF( theta(i) .GT. piover2-thresh ) THEN
                theta(i) = piover2
             END IF
          END DO
          DO i = imin, imax-1
             IF( phi(i) .LT. thresh ) THEN
                phi(i) = zero
             ELSE IF( phi(i) .GT. piover2-thresh ) THEN
                phi(i) = piover2
             END IF
          END DO
 *
 *        Deflate
 *
          IF (imax .GT. 1) THEN
             DO WHILE( phi(imax-1) .EQ. zero )
                imax = imax - 1
                IF (imax .LE. 1) EXIT
             END DO
          END IF
          IF( imin .GT. imax - 1 )
      $      imin = imax - 1
          IF (imin .GT. 1) THEN
             DO WHILE (phi(imin-1) .NE. zero)
                 imin = imin - 1
                 IF (imin .LE. 1) EXIT
             END DO
          END IF
 *
 *        Repeat main iteration loop
 *
       END DO
 *
 *     Postprocessing: order THETA from least to greatest
 *
       DO i = 1, q
 *
          mini = i
          thetamin = theta(i)
          DO j = i+1, q
             IF( theta(j) .LT. thetamin ) THEN
                mini = j
                thetamin = theta(j)
             END IF
          END DO
 *
          IF( mini .NE. i ) THEN
             theta(mini) = theta(i)
             theta(i) = thetamin
             IF( colmajor ) THEN
                IF( wantu1 )
      $            CALL sswap( p, u1(1,i), 1, u1(1,mini), 1 )
                IF( wantu2 )
      $            CALL sswap( m-p, u2(1,i), 1, u2(1,mini), 1 )
                IF( wantv1t )
      $            CALL sswap( q, v1t(i,1), ldv1t, v1t(mini,1), ldv1t )
                IF( wantv2t )
      $            CALL sswap( m-q, v2t(i,1), ldv2t, v2t(mini,1),
      $               ldv2t )
             ELSE
                IF( wantu1 )
      $            CALL sswap( p, u1(i,1), ldu1, u1(mini,1), ldu1 )
                IF( wantu2 )
      $            CALL sswap( m-p, u2(i,1), ldu2, u2(mini,1), ldu2 )
                IF( wantv1t )
      $            CALL sswap( q, v1t(1,i), 1, v1t(1,mini), 1 )
                IF( wantv2t )
      $            CALL sswap( m-q, v2t(1,i), 1, v2t(1,mini), 1 )
             END IF
          END IF
 *
       END DO
 *
       RETURN
 *
 *     End of SBBCSD
 *
       END

xerbla
subroutine xerbla(SRNAME, INFO)
XERBLA
Definition: xerbla.f:60

sswap
subroutine sswap(N, SX, INCX, SY, INCY)
SSWAP
Definition: sswap.f:82

slartgp
subroutine slartgp(F, G, CS, SN, R)
SLARTGP generates a plane rotation so that the diagonal is nonnegative.
Definition: slartgp.f:95

slartgs
subroutine slartgs(X, Y, SIGMA, CS, SN)
SLARTGS generates a plane rotation designed to introduce a bulge in implicit QR iteration for the bid...
Definition: slartgs.f:90

sscal
subroutine sscal(N, SA, SX, INCX)
SSCAL
Definition: sscal.f:79

slasr
subroutine slasr(SIDE, PIVOT, DIRECT, M, N, C, S, A, LDA)
SLASR applies a sequence of plane rotations to a general rectangular matrix.
Definition: slasr.f:199

slas2
subroutine slas2(F, G, H, SSMIN, SSMAX)
SLAS2 computes singular values of a 2-by-2 triangular matrix.
Definition: slas2.f:107

sbbcsd
subroutine sbbcsd(JOBU1, JOBU2, JOBV1T, JOBV2T, TRANS, M, P, Q, THETA, PHI, U1, LDU1, U2, LDU2, V1T, LDV1T, V2T, LDV2T, B11D, B11E, B12D, B12E, B21D, B21E, B22D, B22E, WORK, LWORK, INFO)
SBBCSD
Definition: sbbcsd.f:332