?? slasd3.f
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SUBROUTINE SLASD3( NL, NR, SQRE, K, D, Q, LDQ, DSIGMA, U, LDU, U2,
$ LDU2, VT, LDVT, VT2, LDVT2, IDXC, CTOT, Z,
$ INFO )
*
* -- LAPACK auxiliary routine (version 3.1) --
* Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd..
* November 2006
*
* .. 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( * )
* ..
*
* 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.
*
* Arguments
* =========
*
* NL (input) INTEGER
* The row dimension of the upper block. NL >= 1.
*
* NR (input) INTEGER
* The row dimension of the lower block. NR >= 1.
*
* SQRE (input) 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.
*
* K (input) INTEGER
* The size of the secular equation, 1 =< K = < N.
*
* D (output) REAL array, dimension(K)
* On exit the square roots of the roots of the secular equation,
* in ascending order.
*
* Q (workspace) REAL array,
* dimension at least (LDQ,K).
*
* LDQ (input) INTEGER
* The leading dimension of the array Q. LDQ >= K.
*
* DSIGMA (input/output) 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.
*
* U (output) REAL array, dimension (LDU, N)
* The last N - K columns of this matrix contain the deflated
* left singular vectors.
*
* LDU (input) INTEGER
* The leading dimension of the array U. LDU >= N.
*
* U2 (input) REAL array, dimension (LDU2, N)
* The first K columns of this matrix contain the non-deflated
* left singular vectors for the split problem.
*
* LDU2 (input) INTEGER
* The leading dimension of the array U2. LDU2 >= N.
*
* VT (output) REAL array, dimension (LDVT, M)
* The last M - K columns of VT' contain the deflated
* right singular vectors.
*
* LDVT (input) INTEGER
* The leading dimension of the array VT. LDVT >= N.
*
* VT2 (input/output) REAL array, dimension (LDVT2, N)
* The first K columns of VT2' contain the non-deflated
* right singular vectors for the split problem.
*
* LDVT2 (input) INTEGER
* The leading dimension of the array VT2. LDVT2 >= N.
*
* IDXC (input) 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.
*
* CTOT (input) 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.
*
* Z (input/output) REAL array, dimension (K)
* The first K elements of this array contain the components
* of the deflation-adjusted updating row vector.
*
* INFO (output) INTEGER
* = 0: successful exit.
* < 0: if INFO = -i, the i-th argument had an illegal value.
* > 0: if INFO = 1, an singular value did not converge
*
* Further Details
* ===============
*
* Based on contributions by
* Ming Gu and Huan Ren, Computer Science Division, University of
* California at Berkeley, USA
*
* =====================================================================
*
* .. 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, the computation is terminated.
*
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
*
END
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