slasd3()

subroutine slasd3	(	integer	NL,
		integer	NR,
		integer	SQRE,
		integer	K,
		real, dimension( * )	D,
		real, dimension( ldq, * )	Q,
		integer	LDQ,
		real, dimension( * )	DSIGMA,
		real, dimension( ldu, * )	U,
		integer	LDU,
		real, dimension( ldu2, * )	U2,
		integer	LDU2,
		real, dimension( ldvt, * )	VT,
		integer	LDVT,
		real, dimension( ldvt2, * )	VT2,
		integer	LDVT2,
		integer, dimension( * )	IDXC,
		integer, dimension( * )	CTOT,
		real, dimension( * )	Z,
		integer	INFO
	)

SLASD3 finds all square roots of the roots of the secular equation, as defined by the values in D and Z, and then updates the singular vectors by matrix multiplication. Used by sbdsdc.

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Purpose:

 SLASD3 finds all the square roots of the roots of the secular
 equation, as defined by the values in D and Z.  It makes the
 appropriate calls to SLASD4 and then updates the singular
 vectors by matrix multiplication.

 This code makes very mild assumptions about floating point
 arithmetic. It will work on machines with a guard digit in
 add/subtract, or on those binary machines without guard digits
 which subtract like the Cray XMP, Cray YMP, Cray C 90, or Cray 2.
 It could conceivably fail on hexadecimal or decimal machines
 without guard digits, but we know of none.

 SLASD3 is called from SLASD1.

Parameters

[in]	NL	NL is INTEGER The row dimension of the upper block. NL >= 1.
[in]	NR	NR is INTEGER The row dimension of the lower block. NR >= 1.
[in]	SQRE	SQRE is INTEGER = 0: the lower block is an NR-by-NR square matrix. = 1: the lower block is an NR-by-(NR+1) rectangular matrix. The bidiagonal matrix has N = NL + NR + 1 rows and M = N + SQRE >= N columns.
[in]	K	K is INTEGER The size of the secular equation, 1 =< K = < N.
[out]	D	D is REAL array, dimension(K) On exit the square roots of the roots of the secular equation, in ascending order.
[out]	Q	Q is REAL array, dimension (LDQ,K)
[in]	LDQ	LDQ is INTEGER The leading dimension of the array Q. LDQ >= K.
[in,out]	DSIGMA	DSIGMA is REAL array, dimension(K) The first K elements of this array contain the old roots of the deflated updating problem. These are the poles of the secular equation.
[out]	U	U is REAL array, dimension (LDU, N) The last N - K columns of this matrix contain the deflated left singular vectors.
[in]	LDU	LDU is INTEGER The leading dimension of the array U. LDU >= N.
[in]	U2	U2 is REAL array, dimension (LDU2, N) The first K columns of this matrix contain the non-deflated left singular vectors for the split problem.
[in]	LDU2	LDU2 is INTEGER The leading dimension of the array U2. LDU2 >= N.
[out]	VT	VT is REAL array, dimension (LDVT, M) The last M - K columns of VT**T contain the deflated right singular vectors.
[in]	LDVT	LDVT is INTEGER The leading dimension of the array VT. LDVT >= N.
[in,out]	VT2	VT2 is REAL array, dimension (LDVT2, N) The first K columns of VT2**T contain the non-deflated right singular vectors for the split problem.
[in]	LDVT2	LDVT2 is INTEGER The leading dimension of the array VT2. LDVT2 >= N.
[in]	IDXC	IDXC is INTEGER array, dimension (N) The permutation used to arrange the columns of U (and rows of VT) into three groups: the first group contains non-zero entries only at and above (or before) NL +1; the second contains non-zero entries only at and below (or after) NL+2; and the third is dense. The first column of U and the row of VT are treated separately, however. The rows of the singular vectors found by SLASD4 must be likewise permuted before the matrix multiplies can take place.
[in]	CTOT	CTOT is INTEGER array, dimension (4) A count of the total number of the various types of columns in U (or rows in VT), as described in IDXC. The fourth column type is any column which has been deflated.
[in,out]	Z	Z is REAL array, dimension (K) The first K elements of this array contain the components of the deflation-adjusted updating row vector.
[out]	INFO	INFO is INTEGER = 0: successful exit. < 0: if INFO = -i, the i-th argument had an illegal value. > 0: if INFO = 1, a singular value did not converge

Author

Univ. of Tennessee

Univ. of California Berkeley

Univ. of Colorado Denver

NAG Ltd.

Date

June 2017

Contributors:

Ming Gu and Huan Ren, Computer Science Division, University of California at Berkeley, USA

Definition at line 226 of file slasd3.f.

*
*  -- LAPACK auxiliary 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 2017
*
*     .. Scalar Arguments ..
      INTEGER            INFO, K, LDQ, LDU, LDU2, LDVT, LDVT2, NL, NR,
     $                   SQRE
*     ..
*     .. Array Arguments ..
      INTEGER            CTOT( * ), IDXC( * )
      REAL               D( * ), DSIGMA( * ), Q( LDQ, * ), U( LDU, * ),
     $                   U2( LDU2, * ), VT( LDVT, * ), VT2( LDVT2, * ),
     $                   Z( * )
*     ..
*
*  =====================================================================
*
*     .. Parameters ..
      REAL               ONE, ZERO, NEGONE
      parameter( one = 1.0e+0, zero = 0.0e+0,
     $                     negone = -1.0e+0 )
*     ..
*     .. Local Scalars ..
      INTEGER            CTEMP, I, J, JC, KTEMP, M, N, NLP1, NLP2, NRP1
      REAL               RHO, TEMP
*     ..
*     .. External Functions ..
      REAL               SLAMC3, SNRM2
      EXTERNAL           slamc3, snrm2
*     ..
*     .. External Subroutines ..
      EXTERNAL           scopy, sgemm, slacpy, slascl, slasd4, xerbla
*     ..
*     .. Intrinsic Functions ..
      INTRINSIC          abs, sign, sqrt
*     ..
*     .. Executable Statements ..
*
*     Test the input parameters.
*
      info = 0
*
      IF( nl.LT.1 ) THEN
         info = -1
      ELSE IF( nr.LT.1 ) THEN
         info = -2
      ELSE IF( ( sqre.NE.1 ) .AND. ( sqre.NE.0 ) ) THEN
         info = -3
      END IF
*
      n = nl + nr + 1
      m = n + sqre
      nlp1 = nl + 1
      nlp2 = nl + 2
*
      IF( ( k.LT.1 ) .OR. ( k.GT.n ) ) THEN
         info = -4
      ELSE IF( ldq.LT.k ) THEN
         info = -7
      ELSE IF( ldu.LT.n ) THEN
         info = -10
      ELSE IF( ldu2.LT.n ) THEN
         info = -12
      ELSE IF( ldvt.LT.m ) THEN
         info = -14
      ELSE IF( ldvt2.LT.m ) THEN
         info = -16
      END IF
      IF( info.NE.0 ) THEN
         CALL xerbla( 'SLASD3', -info )
         RETURN
      END IF
*
*     Quick return if possible
*
      IF( k.EQ.1 ) THEN
         d( 1 ) = abs( z( 1 ) )
         CALL scopy( m, vt2( 1, 1 ), ldvt2, vt( 1, 1 ), ldvt )
         IF( z( 1 ).GT.zero ) THEN
            CALL scopy( n, u2( 1, 1 ), 1, u( 1, 1 ), 1 )
         ELSE
            DO 10 i = 1, n
               u( i, 1 ) = -u2( i, 1 )
   10       CONTINUE
         END IF
         RETURN
      END IF
*
*     Modify values DSIGMA(i) to make sure all DSIGMA(i)-DSIGMA(j) can
*     be computed with high relative accuracy (barring over/underflow).
*     This is a problem on machines without a guard digit in
*     add/subtract (Cray XMP, Cray YMP, Cray C 90 and Cray 2).
*     The following code replaces DSIGMA(I) by 2*DSIGMA(I)-DSIGMA(I),
*     which on any of these machines zeros out the bottommost
*     bit of DSIGMA(I) if it is 1; this makes the subsequent
*     subtractions DSIGMA(I)-DSIGMA(J) unproblematic when cancellation
*     occurs. On binary machines with a guard digit (almost all
*     machines) it does not change DSIGMA(I) at all. On hexadecimal
*     and decimal machines with a guard digit, it slightly
*     changes the bottommost bits of DSIGMA(I). It does not account
*     for hexadecimal or decimal machines without guard digits
*     (we know of none). We use a subroutine call to compute
*     2*DSIGMA(I) to prevent optimizing compilers from eliminating
*     this code.
*
      DO 20 i = 1, k
         dsigma( i ) = slamc3( dsigma( i ), dsigma( i ) ) - dsigma( i )
   20 CONTINUE
*
*     Keep a copy of Z.
*
      CALL scopy( k, z, 1, q, 1 )
*
*     Normalize Z.
*
      rho = snrm2( k, z, 1 )
      CALL slascl( 'G', 0, 0, rho, one, k, 1, z, k, info )
      rho = rho*rho
*
*     Find the new singular values.
*
      DO 30 j = 1, k
         CALL slasd4( k, j, dsigma, z, u( 1, j ), rho, d( j ),
     $                vt( 1, j ), info )
*
*        If the zero finder fails, report the convergence failure.
*
         IF( info.NE.0 ) THEN
            RETURN
         END IF
   30 CONTINUE
*
*     Compute updated Z.
*
      DO 60 i = 1, k
         z( i ) = u( i, k )*vt( i, k )
         DO 40 j = 1, i - 1
            z( i ) = z( i )*( u( i, j )*vt( i, j ) /
     $               ( dsigma( i )-dsigma( j ) ) /
     $               ( dsigma( i )+dsigma( j ) ) )
   40    CONTINUE
         DO 50 j = i, k - 1
            z( i ) = z( i )*( u( i, j )*vt( i, j ) /
     $               ( dsigma( i )-dsigma( j+1 ) ) /
     $               ( dsigma( i )+dsigma( j+1 ) ) )
   50    CONTINUE
         z( i ) = sign( sqrt( abs( z( i ) ) ), q( i, 1 ) )
   60 CONTINUE
*
*     Compute left singular vectors of the modified diagonal matrix,
*     and store related information for the right singular vectors.
*
      DO 90 i = 1, k
         vt( 1, i ) = z( 1 ) / u( 1, i ) / vt( 1, i )
         u( 1, i ) = negone
         DO 70 j = 2, k
            vt( j, i ) = z( j ) / u( j, i ) / vt( j, i )
            u( j, i ) = dsigma( j )*vt( j, i )
   70    CONTINUE
         temp = snrm2( k, u( 1, i ), 1 )
         q( 1, i ) = u( 1, i ) / temp
         DO 80 j = 2, k
            jc = idxc( j )
            q( j, i ) = u( jc, i ) / temp
   80    CONTINUE
   90 CONTINUE
*
*     Update the left singular vector matrix.
*
      IF( k.EQ.2 ) THEN
         CALL sgemm( 'N', 'N', n, k, k, one, u2, ldu2, q, ldq, zero, u,
     $               ldu )
         GO TO 100
      END IF
      IF( ctot( 1 ).GT.0 ) THEN
         CALL sgemm( 'N', 'N', nl, k, ctot( 1 ), one, u2( 1, 2 ), ldu2,
     $               q( 2, 1 ), ldq, zero, u( 1, 1 ), ldu )
         IF( ctot( 3 ).GT.0 ) THEN
            ktemp = 2 + ctot( 1 ) + ctot( 2 )
            CALL sgemm( 'N', 'N', nl, k, ctot( 3 ), one, u2( 1, ktemp ),
     $                  ldu2, q( ktemp, 1 ), ldq, one, u( 1, 1 ), ldu )
         END IF
      ELSE IF( ctot( 3 ).GT.0 ) THEN
         ktemp = 2 + ctot( 1 ) + ctot( 2 )
         CALL sgemm( 'N', 'N', nl, k, ctot( 3 ), one, u2( 1, ktemp ),
     $               ldu2, q( ktemp, 1 ), ldq, zero, u( 1, 1 ), ldu )
      ELSE
         CALL slacpy( 'F', nl, k, u2, ldu2, u, ldu )
      END IF
      CALL scopy( k, q( 1, 1 ), ldq, u( nlp1, 1 ), ldu )
      ktemp = 2 + ctot( 1 )
      ctemp = ctot( 2 ) + ctot( 3 )
      CALL sgemm( 'N', 'N', nr, k, ctemp, one, u2( nlp2, ktemp ), ldu2,
     $            q( ktemp, 1 ), ldq, zero, u( nlp2, 1 ), ldu )
*
*     Generate the right singular vectors.
*
  100 CONTINUE
      DO 120 i = 1, k
         temp = snrm2( k, vt( 1, i ), 1 )
         q( i, 1 ) = vt( 1, i ) / temp
         DO 110 j = 2, k
            jc = idxc( j )
            q( i, j ) = vt( jc, i ) / temp
  110    CONTINUE
  120 CONTINUE
*
*     Update the right singular vector matrix.
*
      IF( k.EQ.2 ) THEN
         CALL sgemm( 'N', 'N', k, m, k, one, q, ldq, vt2, ldvt2, zero,
     $               vt, ldvt )
         RETURN
      END IF
      ktemp = 1 + ctot( 1 )
      CALL sgemm( 'N', 'N', k, nlp1, ktemp, one, q( 1, 1 ), ldq,
     $            vt2( 1, 1 ), ldvt2, zero, vt( 1, 1 ), ldvt )
      ktemp = 2 + ctot( 1 ) + ctot( 2 )
      IF( ktemp.LE.ldvt2 )
     $   CALL sgemm( 'N', 'N', k, nlp1, ctot( 3 ), one, q( 1, ktemp ),
     $               ldq, vt2( ktemp, 1 ), ldvt2, one, vt( 1, 1 ),
     $               ldvt )
*
      ktemp = ctot( 1 ) + 1
      nrp1 = nr + sqre
      IF( ktemp.GT.1 ) THEN
         DO 130 i = 1, k
            q( i, ktemp ) = q( i, 1 )
  130    CONTINUE
         DO 140 i = nlp2, m
            vt2( ktemp, i ) = vt2( 1, i )
  140    CONTINUE
      END IF
      ctemp = 1 + ctot( 2 ) + ctot( 3 )
      CALL sgemm( 'N', 'N', k, nrp1, ctemp, one, q( 1, ktemp ), ldq,
     $            vt2( ktemp, nlp2 ), ldvt2, zero, vt( 1, nlp2 ), ldvt )
*
      RETURN
*
*     End of SLASD3
*

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