610 lines
18 KiB
C
610 lines
18 KiB
C
/* dlasd2.f -- translated by f2c (version 20061008).
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You must link the resulting object file with libf2c:
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on Microsoft Windows system, link with libf2c.lib;
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on Linux or Unix systems, link with .../path/to/libf2c.a -lm
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or, if you install libf2c.a in a standard place, with -lf2c -lm
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-- in that order, at the end of the command line, as in
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cc *.o -lf2c -lm
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Source for libf2c is in /netlib/f2c/libf2c.zip, e.g.,
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http://www.netlib.org/f2c/libf2c.zip
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*/
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#include "clapack.h"
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/* Table of constant values */
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static integer c__1 = 1;
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static doublereal c_b30 = 0.;
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/* Subroutine */ int dlasd2_(integer *nl, integer *nr, integer *sqre, integer
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*k, doublereal *d__, doublereal *z__, doublereal *alpha, doublereal *
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beta, doublereal *u, integer *ldu, doublereal *vt, integer *ldvt,
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doublereal *dsigma, doublereal *u2, integer *ldu2, doublereal *vt2,
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integer *ldvt2, integer *idxp, integer *idx, integer *idxc, integer *
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idxq, integer *coltyp, integer *info)
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{
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/* System generated locals */
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integer u_dim1, u_offset, u2_dim1, u2_offset, vt_dim1, vt_offset,
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vt2_dim1, vt2_offset, i__1;
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doublereal d__1, d__2;
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/* Local variables */
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doublereal c__;
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integer i__, j, m, n;
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doublereal s;
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integer k2;
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doublereal z1;
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integer ct, jp;
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doublereal eps, tau, tol;
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integer psm[4], nlp1, nlp2, idxi, idxj;
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extern /* Subroutine */ int drot_(integer *, doublereal *, integer *,
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doublereal *, integer *, doublereal *, doublereal *);
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integer ctot[4], idxjp;
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extern /* Subroutine */ int dcopy_(integer *, doublereal *, integer *,
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doublereal *, integer *);
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integer jprev;
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extern doublereal dlapy2_(doublereal *, doublereal *), dlamch_(char *);
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extern /* Subroutine */ int dlamrg_(integer *, integer *, doublereal *,
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integer *, integer *, integer *), dlacpy_(char *, integer *,
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integer *, doublereal *, integer *, doublereal *, integer *), dlaset_(char *, integer *, integer *, doublereal *,
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doublereal *, doublereal *, integer *), xerbla_(char *,
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integer *);
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doublereal hlftol;
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/* -- LAPACK auxiliary routine (version 3.2) -- */
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/* Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd.. */
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/* November 2006 */
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/* .. Scalar Arguments .. */
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/* .. */
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/* .. Array Arguments .. */
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/* .. */
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/* Purpose */
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/* ======= */
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/* DLASD2 merges the two sets of singular values together into a single */
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/* sorted set. Then it tries to deflate the size of the problem. */
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/* There are two ways in which deflation can occur: when two or more */
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/* singular values are close together or if there is a tiny entry in the */
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/* Z vector. For each such occurrence the order of the related secular */
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/* equation problem is reduced by one. */
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/* DLASD2 is called from DLASD1. */
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/* Arguments */
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/* ========= */
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/* NL (input) INTEGER */
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/* The row dimension of the upper block. NL >= 1. */
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/* NR (input) INTEGER */
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/* The row dimension of the lower block. NR >= 1. */
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/* SQRE (input) INTEGER */
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/* = 0: the lower block is an NR-by-NR square matrix. */
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/* = 1: the lower block is an NR-by-(NR+1) rectangular matrix. */
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/* The bidiagonal matrix has N = NL + NR + 1 rows and */
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/* M = N + SQRE >= N columns. */
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/* K (output) INTEGER */
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/* Contains the dimension of the non-deflated matrix, */
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/* This is the order of the related secular equation. 1 <= K <=N. */
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/* D (input/output) DOUBLE PRECISION array, dimension(N) */
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/* On entry D contains the singular values of the two submatrices */
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/* to be combined. On exit D contains the trailing (N-K) updated */
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/* singular values (those which were deflated) sorted into */
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/* increasing order. */
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/* Z (output) DOUBLE PRECISION array, dimension(N) */
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/* On exit Z contains the updating row vector in the secular */
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/* equation. */
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/* ALPHA (input) DOUBLE PRECISION */
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/* Contains the diagonal element associated with the added row. */
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/* BETA (input) DOUBLE PRECISION */
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/* Contains the off-diagonal element associated with the added */
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/* row. */
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/* U (input/output) DOUBLE PRECISION array, dimension(LDU,N) */
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/* On entry U contains the left singular vectors of two */
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/* submatrices in the two square blocks with corners at (1,1), */
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/* (NL, NL), and (NL+2, NL+2), (N,N). */
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/* On exit U contains the trailing (N-K) updated left singular */
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/* vectors (those which were deflated) in its last N-K columns. */
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/* LDU (input) INTEGER */
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/* The leading dimension of the array U. LDU >= N. */
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/* VT (input/output) DOUBLE PRECISION array, dimension(LDVT,M) */
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/* On entry VT' contains the right singular vectors of two */
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/* submatrices in the two square blocks with corners at (1,1), */
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/* (NL+1, NL+1), and (NL+2, NL+2), (M,M). */
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/* On exit VT' contains the trailing (N-K) updated right singular */
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/* vectors (those which were deflated) in its last N-K columns. */
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/* In case SQRE =1, the last row of VT spans the right null */
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/* space. */
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/* LDVT (input) INTEGER */
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/* The leading dimension of the array VT. LDVT >= M. */
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/* DSIGMA (output) DOUBLE PRECISION array, dimension (N) */
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/* Contains a copy of the diagonal elements (K-1 singular values */
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/* and one zero) in the secular equation. */
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/* U2 (output) DOUBLE PRECISION array, dimension(LDU2,N) */
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/* Contains a copy of the first K-1 left singular vectors which */
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/* will be used by DLASD3 in a matrix multiply (DGEMM) to solve */
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/* for the new left singular vectors. U2 is arranged into four */
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/* blocks. The first block contains a column with 1 at NL+1 and */
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/* zero everywhere else; the second block contains non-zero */
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/* entries only at and above NL; the third contains non-zero */
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/* entries only below NL+1; and the fourth is dense. */
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/* LDU2 (input) INTEGER */
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/* The leading dimension of the array U2. LDU2 >= N. */
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/* VT2 (output) DOUBLE PRECISION array, dimension(LDVT2,N) */
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/* VT2' contains a copy of the first K right singular vectors */
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/* which will be used by DLASD3 in a matrix multiply (DGEMM) to */
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/* solve for the new right singular vectors. VT2 is arranged into */
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/* three blocks. The first block contains a row that corresponds */
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/* to the special 0 diagonal element in SIGMA; the second block */
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/* contains non-zeros only at and before NL +1; the third block */
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/* contains non-zeros only at and after NL +2. */
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/* LDVT2 (input) INTEGER */
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/* The leading dimension of the array VT2. LDVT2 >= M. */
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/* IDXP (workspace) INTEGER array dimension(N) */
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/* This will contain the permutation used to place deflated */
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/* values of D at the end of the array. On output IDXP(2:K) */
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/* points to the nondeflated D-values and IDXP(K+1:N) */
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/* points to the deflated singular values. */
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/* IDX (workspace) INTEGER array dimension(N) */
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/* This will contain the permutation used to sort the contents of */
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/* D into ascending order. */
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/* IDXC (output) INTEGER array dimension(N) */
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/* This will contain the permutation used to arrange the columns */
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/* of the deflated U matrix into three groups: the first group */
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/* contains non-zero entries only at and above NL, the second */
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/* contains non-zero entries only below NL+2, and the third is */
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/* dense. */
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/* IDXQ (input/output) INTEGER array dimension(N) */
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/* This contains the permutation which separately sorts the two */
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/* sub-problems in D into ascending order. Note that entries in */
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/* the first hlaf of this permutation must first be moved one */
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/* position backward; and entries in the second half */
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/* must first have NL+1 added to their values. */
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/* COLTYP (workspace/output) INTEGER array dimension(N) */
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/* As workspace, this will contain a label which will indicate */
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/* which of the following types a column in the U2 matrix or a */
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/* row in the VT2 matrix is: */
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/* 1 : non-zero in the upper half only */
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/* 2 : non-zero in the lower half only */
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/* 3 : dense */
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/* 4 : deflated */
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/* On exit, it is an array of dimension 4, with COLTYP(I) being */
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/* the dimension of the I-th type columns. */
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/* INFO (output) INTEGER */
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/* = 0: successful exit. */
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/* < 0: if INFO = -i, the i-th argument had an illegal value. */
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/* Further Details */
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/* =============== */
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/* Based on contributions by */
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/* Ming Gu and Huan Ren, Computer Science Division, University of */
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/* California at Berkeley, USA */
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/* ===================================================================== */
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/* .. Parameters .. */
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/* .. */
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/* .. Local Arrays .. */
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/* .. */
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/* .. Local Scalars .. */
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/* .. */
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/* .. External Functions .. */
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/* .. */
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/* .. External Subroutines .. */
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/* .. */
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/* .. Intrinsic Functions .. */
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/* .. */
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/* .. Executable Statements .. */
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/* Test the input parameters. */
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/* Parameter adjustments */
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--d__;
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--z__;
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u_dim1 = *ldu;
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u_offset = 1 + u_dim1;
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u -= u_offset;
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vt_dim1 = *ldvt;
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vt_offset = 1 + vt_dim1;
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vt -= vt_offset;
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--dsigma;
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u2_dim1 = *ldu2;
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u2_offset = 1 + u2_dim1;
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u2 -= u2_offset;
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vt2_dim1 = *ldvt2;
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vt2_offset = 1 + vt2_dim1;
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vt2 -= vt2_offset;
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--idxp;
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--idx;
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--idxc;
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--idxq;
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--coltyp;
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/* Function Body */
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*info = 0;
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if (*nl < 1) {
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*info = -1;
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} else if (*nr < 1) {
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*info = -2;
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} else if (*sqre != 1 && *sqre != 0) {
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*info = -3;
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}
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n = *nl + *nr + 1;
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m = n + *sqre;
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if (*ldu < n) {
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*info = -10;
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} else if (*ldvt < m) {
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*info = -12;
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} else if (*ldu2 < n) {
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*info = -15;
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} else if (*ldvt2 < m) {
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*info = -17;
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}
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if (*info != 0) {
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i__1 = -(*info);
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xerbla_("DLASD2", &i__1);
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return 0;
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}
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nlp1 = *nl + 1;
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nlp2 = *nl + 2;
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/* Generate the first part of the vector Z; and move the singular */
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/* values in the first part of D one position backward. */
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z1 = *alpha * vt[nlp1 + nlp1 * vt_dim1];
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z__[1] = z1;
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for (i__ = *nl; i__ >= 1; --i__) {
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z__[i__ + 1] = *alpha * vt[i__ + nlp1 * vt_dim1];
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d__[i__ + 1] = d__[i__];
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idxq[i__ + 1] = idxq[i__] + 1;
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/* L10: */
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}
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/* Generate the second part of the vector Z. */
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i__1 = m;
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for (i__ = nlp2; i__ <= i__1; ++i__) {
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z__[i__] = *beta * vt[i__ + nlp2 * vt_dim1];
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/* L20: */
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}
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/* Initialize some reference arrays. */
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i__1 = nlp1;
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for (i__ = 2; i__ <= i__1; ++i__) {
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coltyp[i__] = 1;
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/* L30: */
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}
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i__1 = n;
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for (i__ = nlp2; i__ <= i__1; ++i__) {
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coltyp[i__] = 2;
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/* L40: */
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}
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/* Sort the singular values into increasing order */
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i__1 = n;
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for (i__ = nlp2; i__ <= i__1; ++i__) {
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idxq[i__] += nlp1;
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/* L50: */
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}
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/* DSIGMA, IDXC, IDXC, and the first column of U2 */
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/* are used as storage space. */
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i__1 = n;
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for (i__ = 2; i__ <= i__1; ++i__) {
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dsigma[i__] = d__[idxq[i__]];
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u2[i__ + u2_dim1] = z__[idxq[i__]];
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idxc[i__] = coltyp[idxq[i__]];
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/* L60: */
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}
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dlamrg_(nl, nr, &dsigma[2], &c__1, &c__1, &idx[2]);
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i__1 = n;
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for (i__ = 2; i__ <= i__1; ++i__) {
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idxi = idx[i__] + 1;
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d__[i__] = dsigma[idxi];
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z__[i__] = u2[idxi + u2_dim1];
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coltyp[i__] = idxc[idxi];
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/* L70: */
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}
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/* Calculate the allowable deflation tolerance */
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eps = dlamch_("Epsilon");
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/* Computing MAX */
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d__1 = abs(*alpha), d__2 = abs(*beta);
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tol = max(d__1,d__2);
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/* Computing MAX */
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d__2 = (d__1 = d__[n], abs(d__1));
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tol = eps * 8. * max(d__2,tol);
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/* There are 2 kinds of deflation -- first a value in the z-vector */
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/* is small, second two (or more) singular values are very close */
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/* together (their difference is small). */
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/* If the value in the z-vector is small, we simply permute the */
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/* array so that the corresponding singular value is moved to the */
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/* end. */
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/* If two values in the D-vector are close, we perform a two-sided */
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/* rotation designed to make one of the corresponding z-vector */
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/* entries zero, and then permute the array so that the deflated */
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/* singular value is moved to the end. */
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/* If there are multiple singular values then the problem deflates. */
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/* Here the number of equal singular values are found. As each equal */
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/* singular value is found, an elementary reflector is computed to */
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/* rotate the corresponding singular subspace so that the */
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/* corresponding components of Z are zero in this new basis. */
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*k = 1;
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k2 = n + 1;
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i__1 = n;
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for (j = 2; j <= i__1; ++j) {
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if ((d__1 = z__[j], abs(d__1)) <= tol) {
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/* Deflate due to small z component. */
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--k2;
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idxp[k2] = j;
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coltyp[j] = 4;
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if (j == n) {
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goto L120;
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}
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} else {
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jprev = j;
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goto L90;
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}
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/* L80: */
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}
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L90:
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j = jprev;
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L100:
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++j;
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if (j > n) {
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goto L110;
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}
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if ((d__1 = z__[j], abs(d__1)) <= tol) {
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/* Deflate due to small z component. */
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--k2;
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idxp[k2] = j;
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coltyp[j] = 4;
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} else {
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/* Check if singular values are close enough to allow deflation. */
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if ((d__1 = d__[j] - d__[jprev], abs(d__1)) <= tol) {
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/* Deflation is possible. */
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s = z__[jprev];
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c__ = z__[j];
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/* Find sqrt(a**2+b**2) without overflow or */
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/* destructive underflow. */
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tau = dlapy2_(&c__, &s);
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c__ /= tau;
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s = -s / tau;
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z__[j] = tau;
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z__[jprev] = 0.;
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/* Apply back the Givens rotation to the left and right */
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/* singular vector matrices. */
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idxjp = idxq[idx[jprev] + 1];
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idxj = idxq[idx[j] + 1];
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if (idxjp <= nlp1) {
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--idxjp;
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}
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if (idxj <= nlp1) {
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--idxj;
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}
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drot_(&n, &u[idxjp * u_dim1 + 1], &c__1, &u[idxj * u_dim1 + 1], &
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c__1, &c__, &s);
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drot_(&m, &vt[idxjp + vt_dim1], ldvt, &vt[idxj + vt_dim1], ldvt, &
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c__, &s);
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if (coltyp[j] != coltyp[jprev]) {
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coltyp[j] = 3;
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}
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coltyp[jprev] = 4;
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--k2;
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idxp[k2] = jprev;
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jprev = j;
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} else {
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++(*k);
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u2[*k + u2_dim1] = z__[jprev];
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dsigma[*k] = d__[jprev];
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idxp[*k] = jprev;
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jprev = j;
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}
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}
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goto L100;
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L110:
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/* Record the last singular value. */
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++(*k);
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u2[*k + u2_dim1] = z__[jprev];
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dsigma[*k] = d__[jprev];
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idxp[*k] = jprev;
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L120:
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/* Count up the total number of the various types of columns, then */
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/* form a permutation which positions the four column types into */
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/* four groups of uniform structure (although one or more of these */
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/* groups may be empty). */
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for (j = 1; j <= 4; ++j) {
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ctot[j - 1] = 0;
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/* L130: */
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}
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i__1 = n;
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for (j = 2; j <= i__1; ++j) {
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ct = coltyp[j];
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++ctot[ct - 1];
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/* L140: */
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}
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/* PSM(*) = Position in SubMatrix (of types 1 through 4) */
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psm[0] = 2;
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psm[1] = ctot[0] + 2;
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psm[2] = psm[1] + ctot[1];
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psm[3] = psm[2] + ctot[2];
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|
|
|
/* Fill out the IDXC array so that the permutation which it induces */
|
|
/* will place all type-1 columns first, all type-2 columns next, */
|
|
/* then all type-3's, and finally all type-4's, starting from the */
|
|
/* second column. This applies similarly to the rows of VT. */
|
|
|
|
i__1 = n;
|
|
for (j = 2; j <= i__1; ++j) {
|
|
jp = idxp[j];
|
|
ct = coltyp[jp];
|
|
idxc[psm[ct - 1]] = j;
|
|
++psm[ct - 1];
|
|
/* L150: */
|
|
}
|
|
|
|
/* Sort the singular values and corresponding singular vectors into */
|
|
/* DSIGMA, U2, and VT2 respectively. The singular values/vectors */
|
|
/* which were not deflated go into the first K slots of DSIGMA, U2, */
|
|
/* and VT2 respectively, while those which were deflated go into the */
|
|
/* last N - K slots, except that the first column/row will be treated */
|
|
/* separately. */
|
|
|
|
i__1 = n;
|
|
for (j = 2; j <= i__1; ++j) {
|
|
jp = idxp[j];
|
|
dsigma[j] = d__[jp];
|
|
idxj = idxq[idx[idxp[idxc[j]]] + 1];
|
|
if (idxj <= nlp1) {
|
|
--idxj;
|
|
}
|
|
dcopy_(&n, &u[idxj * u_dim1 + 1], &c__1, &u2[j * u2_dim1 + 1], &c__1);
|
|
dcopy_(&m, &vt[idxj + vt_dim1], ldvt, &vt2[j + vt2_dim1], ldvt2);
|
|
/* L160: */
|
|
}
|
|
|
|
/* Determine DSIGMA(1), DSIGMA(2) and Z(1) */
|
|
|
|
dsigma[1] = 0.;
|
|
hlftol = tol / 2.;
|
|
if (abs(dsigma[2]) <= hlftol) {
|
|
dsigma[2] = hlftol;
|
|
}
|
|
if (m > n) {
|
|
z__[1] = dlapy2_(&z1, &z__[m]);
|
|
if (z__[1] <= tol) {
|
|
c__ = 1.;
|
|
s = 0.;
|
|
z__[1] = tol;
|
|
} else {
|
|
c__ = z1 / z__[1];
|
|
s = z__[m] / z__[1];
|
|
}
|
|
} else {
|
|
if (abs(z1) <= tol) {
|
|
z__[1] = tol;
|
|
} else {
|
|
z__[1] = z1;
|
|
}
|
|
}
|
|
|
|
/* Move the rest of the updating row to Z. */
|
|
|
|
i__1 = *k - 1;
|
|
dcopy_(&i__1, &u2[u2_dim1 + 2], &c__1, &z__[2], &c__1);
|
|
|
|
/* Determine the first column of U2, the first row of VT2 and the */
|
|
/* last row of VT. */
|
|
|
|
dlaset_("A", &n, &c__1, &c_b30, &c_b30, &u2[u2_offset], ldu2);
|
|
u2[nlp1 + u2_dim1] = 1.;
|
|
if (m > n) {
|
|
i__1 = nlp1;
|
|
for (i__ = 1; i__ <= i__1; ++i__) {
|
|
vt[m + i__ * vt_dim1] = -s * vt[nlp1 + i__ * vt_dim1];
|
|
vt2[i__ * vt2_dim1 + 1] = c__ * vt[nlp1 + i__ * vt_dim1];
|
|
/* L170: */
|
|
}
|
|
i__1 = m;
|
|
for (i__ = nlp2; i__ <= i__1; ++i__) {
|
|
vt2[i__ * vt2_dim1 + 1] = s * vt[m + i__ * vt_dim1];
|
|
vt[m + i__ * vt_dim1] = c__ * vt[m + i__ * vt_dim1];
|
|
/* L180: */
|
|
}
|
|
} else {
|
|
dcopy_(&m, &vt[nlp1 + vt_dim1], ldvt, &vt2[vt2_dim1 + 1], ldvt2);
|
|
}
|
|
if (m > n) {
|
|
dcopy_(&m, &vt[m + vt_dim1], ldvt, &vt2[m + vt2_dim1], ldvt2);
|
|
}
|
|
|
|
/* The deflated singular values and their corresponding vectors go */
|
|
/* into the back of D, U, and V respectively. */
|
|
|
|
if (n > *k) {
|
|
i__1 = n - *k;
|
|
dcopy_(&i__1, &dsigma[*k + 1], &c__1, &d__[*k + 1], &c__1);
|
|
i__1 = n - *k;
|
|
dlacpy_("A", &n, &i__1, &u2[(*k + 1) * u2_dim1 + 1], ldu2, &u[(*k + 1)
|
|
* u_dim1 + 1], ldu);
|
|
i__1 = n - *k;
|
|
dlacpy_("A", &i__1, &m, &vt2[*k + 1 + vt2_dim1], ldvt2, &vt[*k + 1 +
|
|
vt_dim1], ldvt);
|
|
}
|
|
|
|
/* Copy CTOT into COLTYP for referencing in DLASD3. */
|
|
|
|
for (j = 1; j <= 4; ++j) {
|
|
coltyp[j] = ctot[j - 1];
|
|
/* L190: */
|
|
}
|
|
|
|
return 0;
|
|
|
|
/* End of DLASD2 */
|
|
|
|
} /* dlasd2_ */
|