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441 lines
12 KiB
C
441 lines
12 KiB
C
/* slar1v.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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/* Subroutine */ int slar1v_(integer *n, integer *b1, integer *bn, real *
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lambda, real *d__, real *l, real *ld, real *lld, real *pivmin, real *
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gaptol, real *z__, logical *wantnc, integer *negcnt, real *ztz, real *
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mingma, integer *r__, integer *isuppz, real *nrminv, real *resid,
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real *rqcorr, real *work)
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{
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/* System generated locals */
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integer i__1;
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real r__1, r__2, r__3;
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/* Builtin functions */
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double sqrt(doublereal);
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/* Local variables */
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integer i__;
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real s;
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integer r1, r2;
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real eps, tmp;
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integer neg1, neg2, indp, inds;
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real dplus;
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extern doublereal slamch_(char *);
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integer indlpl, indumn;
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extern logical sisnan_(real *);
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real dminus;
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logical sawnan1, sawnan2;
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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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/* SLAR1V computes the (scaled) r-th column of the inverse of */
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/* the sumbmatrix in rows B1 through BN of the tridiagonal matrix */
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/* L D L^T - sigma I. When sigma is close to an eigenvalue, the */
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/* computed vector is an accurate eigenvector. Usually, r corresponds */
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/* to the index where the eigenvector is largest in magnitude. */
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/* The following steps accomplish this computation : */
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/* (a) Stationary qd transform, L D L^T - sigma I = L(+) D(+) L(+)^T, */
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/* (b) Progressive qd transform, L D L^T - sigma I = U(-) D(-) U(-)^T, */
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/* (c) Computation of the diagonal elements of the inverse of */
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/* L D L^T - sigma I by combining the above transforms, and choosing */
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/* r as the index where the diagonal of the inverse is (one of the) */
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/* largest in magnitude. */
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/* (d) Computation of the (scaled) r-th column of the inverse using the */
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/* twisted factorization obtained by combining the top part of the */
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/* the stationary and the bottom part of the progressive transform. */
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/* Arguments */
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/* ========= */
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/* N (input) INTEGER */
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/* The order of the matrix L D L^T. */
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/* B1 (input) INTEGER */
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/* First index of the submatrix of L D L^T. */
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/* BN (input) INTEGER */
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/* Last index of the submatrix of L D L^T. */
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/* LAMBDA (input) REAL */
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/* The shift. In order to compute an accurate eigenvector, */
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/* LAMBDA should be a good approximation to an eigenvalue */
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/* of L D L^T. */
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/* L (input) REAL array, dimension (N-1) */
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/* The (n-1) subdiagonal elements of the unit bidiagonal matrix */
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/* L, in elements 1 to N-1. */
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/* D (input) REAL array, dimension (N) */
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/* The n diagonal elements of the diagonal matrix D. */
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/* LD (input) REAL array, dimension (N-1) */
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/* The n-1 elements L(i)*D(i). */
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/* LLD (input) REAL array, dimension (N-1) */
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/* The n-1 elements L(i)*L(i)*D(i). */
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/* PIVMIN (input) REAL */
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/* The minimum pivot in the Sturm sequence. */
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/* GAPTOL (input) REAL */
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/* Tolerance that indicates when eigenvector entries are negligible */
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/* w.r.t. their contribution to the residual. */
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/* Z (input/output) REAL array, dimension (N) */
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/* On input, all entries of Z must be set to 0. */
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/* On output, Z contains the (scaled) r-th column of the */
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/* inverse. The scaling is such that Z(R) equals 1. */
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/* WANTNC (input) LOGICAL */
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/* Specifies whether NEGCNT has to be computed. */
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/* NEGCNT (output) INTEGER */
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/* If WANTNC is .TRUE. then NEGCNT = the number of pivots < pivmin */
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/* in the matrix factorization L D L^T, and NEGCNT = -1 otherwise. */
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/* ZTZ (output) REAL */
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/* The square of the 2-norm of Z. */
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/* MINGMA (output) REAL */
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/* The reciprocal of the largest (in magnitude) diagonal */
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/* element of the inverse of L D L^T - sigma I. */
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/* R (input/output) INTEGER */
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/* The twist index for the twisted factorization used to */
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/* compute Z. */
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/* On input, 0 <= R <= N. If R is input as 0, R is set to */
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/* the index where (L D L^T - sigma I)^{-1} is largest */
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/* in magnitude. If 1 <= R <= N, R is unchanged. */
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/* On output, R contains the twist index used to compute Z. */
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/* Ideally, R designates the position of the maximum entry in the */
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/* eigenvector. */
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/* ISUPPZ (output) INTEGER array, dimension (2) */
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/* The support of the vector in Z, i.e., the vector Z is */
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/* nonzero only in elements ISUPPZ(1) through ISUPPZ( 2 ). */
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/* NRMINV (output) REAL */
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/* NRMINV = 1/SQRT( ZTZ ) */
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/* RESID (output) REAL */
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/* The residual of the FP vector. */
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/* RESID = ABS( MINGMA )/SQRT( ZTZ ) */
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/* RQCORR (output) REAL */
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/* The Rayleigh Quotient correction to LAMBDA. */
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/* RQCORR = MINGMA*TMP */
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/* WORK (workspace) REAL array, dimension (4*N) */
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/* Further Details */
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/* =============== */
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/* Based on contributions by */
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/* Beresford Parlett, University of California, Berkeley, USA */
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/* Jim Demmel, University of California, Berkeley, USA */
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/* Inderjit Dhillon, University of Texas, Austin, USA */
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/* Osni Marques, LBNL/NERSC, USA */
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/* Christof Voemel, University of California, Berkeley, USA */
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/* ===================================================================== */
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/* .. Parameters .. */
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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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/* .. Intrinsic Functions .. */
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/* .. */
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/* .. Executable Statements .. */
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/* Parameter adjustments */
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--work;
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--isuppz;
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--z__;
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--lld;
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--ld;
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--l;
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--d__;
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/* Function Body */
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eps = slamch_("Precision");
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if (*r__ == 0) {
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r1 = *b1;
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r2 = *bn;
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} else {
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r1 = *r__;
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r2 = *r__;
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}
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/* Storage for LPLUS */
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indlpl = 0;
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/* Storage for UMINUS */
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indumn = *n;
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inds = (*n << 1) + 1;
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indp = *n * 3 + 1;
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if (*b1 == 1) {
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work[inds] = 0.f;
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} else {
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work[inds + *b1 - 1] = lld[*b1 - 1];
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}
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/* Compute the stationary transform (using the differential form) */
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/* until the index R2. */
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sawnan1 = FALSE_;
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neg1 = 0;
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s = work[inds + *b1 - 1] - *lambda;
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i__1 = r1 - 1;
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for (i__ = *b1; i__ <= i__1; ++i__) {
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dplus = d__[i__] + s;
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work[indlpl + i__] = ld[i__] / dplus;
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if (dplus < 0.f) {
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++neg1;
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}
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work[inds + i__] = s * work[indlpl + i__] * l[i__];
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s = work[inds + i__] - *lambda;
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/* L50: */
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}
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sawnan1 = sisnan_(&s);
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if (sawnan1) {
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goto L60;
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}
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i__1 = r2 - 1;
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for (i__ = r1; i__ <= i__1; ++i__) {
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dplus = d__[i__] + s;
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work[indlpl + i__] = ld[i__] / dplus;
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work[inds + i__] = s * work[indlpl + i__] * l[i__];
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s = work[inds + i__] - *lambda;
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/* L51: */
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}
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sawnan1 = sisnan_(&s);
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L60:
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if (sawnan1) {
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/* Runs a slower version of the above loop if a NaN is detected */
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neg1 = 0;
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s = work[inds + *b1 - 1] - *lambda;
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i__1 = r1 - 1;
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for (i__ = *b1; i__ <= i__1; ++i__) {
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dplus = d__[i__] + s;
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if (dabs(dplus) < *pivmin) {
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dplus = -(*pivmin);
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}
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work[indlpl + i__] = ld[i__] / dplus;
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if (dplus < 0.f) {
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++neg1;
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}
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work[inds + i__] = s * work[indlpl + i__] * l[i__];
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if (work[indlpl + i__] == 0.f) {
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work[inds + i__] = lld[i__];
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}
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s = work[inds + i__] - *lambda;
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/* L70: */
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}
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i__1 = r2 - 1;
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for (i__ = r1; i__ <= i__1; ++i__) {
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dplus = d__[i__] + s;
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if (dabs(dplus) < *pivmin) {
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dplus = -(*pivmin);
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}
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work[indlpl + i__] = ld[i__] / dplus;
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work[inds + i__] = s * work[indlpl + i__] * l[i__];
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if (work[indlpl + i__] == 0.f) {
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work[inds + i__] = lld[i__];
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}
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s = work[inds + i__] - *lambda;
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/* L71: */
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}
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}
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/* Compute the progressive transform (using the differential form) */
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/* until the index R1 */
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sawnan2 = FALSE_;
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neg2 = 0;
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work[indp + *bn - 1] = d__[*bn] - *lambda;
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i__1 = r1;
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for (i__ = *bn - 1; i__ >= i__1; --i__) {
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dminus = lld[i__] + work[indp + i__];
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tmp = d__[i__] / dminus;
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if (dminus < 0.f) {
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++neg2;
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}
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work[indumn + i__] = l[i__] * tmp;
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work[indp + i__ - 1] = work[indp + i__] * tmp - *lambda;
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/* L80: */
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}
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tmp = work[indp + r1 - 1];
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sawnan2 = sisnan_(&tmp);
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if (sawnan2) {
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/* Runs a slower version of the above loop if a NaN is detected */
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neg2 = 0;
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i__1 = r1;
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for (i__ = *bn - 1; i__ >= i__1; --i__) {
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dminus = lld[i__] + work[indp + i__];
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if (dabs(dminus) < *pivmin) {
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dminus = -(*pivmin);
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}
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tmp = d__[i__] / dminus;
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if (dminus < 0.f) {
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++neg2;
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}
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work[indumn + i__] = l[i__] * tmp;
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work[indp + i__ - 1] = work[indp + i__] * tmp - *lambda;
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if (tmp == 0.f) {
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work[indp + i__ - 1] = d__[i__] - *lambda;
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}
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/* L100: */
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}
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}
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/* Find the index (from R1 to R2) of the largest (in magnitude) */
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/* diagonal element of the inverse */
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*mingma = work[inds + r1 - 1] + work[indp + r1 - 1];
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if (*mingma < 0.f) {
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++neg1;
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}
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if (*wantnc) {
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*negcnt = neg1 + neg2;
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} else {
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*negcnt = -1;
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}
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if (dabs(*mingma) == 0.f) {
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*mingma = eps * work[inds + r1 - 1];
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}
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*r__ = r1;
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i__1 = r2 - 1;
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for (i__ = r1; i__ <= i__1; ++i__) {
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tmp = work[inds + i__] + work[indp + i__];
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if (tmp == 0.f) {
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tmp = eps * work[inds + i__];
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}
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if (dabs(tmp) <= dabs(*mingma)) {
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*mingma = tmp;
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*r__ = i__ + 1;
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}
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/* L110: */
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}
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/* Compute the FP vector: solve N^T v = e_r */
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isuppz[1] = *b1;
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isuppz[2] = *bn;
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z__[*r__] = 1.f;
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*ztz = 1.f;
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/* Compute the FP vector upwards from R */
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if (! sawnan1 && ! sawnan2) {
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i__1 = *b1;
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for (i__ = *r__ - 1; i__ >= i__1; --i__) {
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z__[i__] = -(work[indlpl + i__] * z__[i__ + 1]);
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if (((r__1 = z__[i__], dabs(r__1)) + (r__2 = z__[i__ + 1], dabs(
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r__2))) * (r__3 = ld[i__], dabs(r__3)) < *gaptol) {
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z__[i__] = 0.f;
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isuppz[1] = i__ + 1;
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goto L220;
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}
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*ztz += z__[i__] * z__[i__];
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/* L210: */
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}
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L220:
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;
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} else {
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/* Run slower loop if NaN occurred. */
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i__1 = *b1;
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for (i__ = *r__ - 1; i__ >= i__1; --i__) {
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if (z__[i__ + 1] == 0.f) {
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z__[i__] = -(ld[i__ + 1] / ld[i__]) * z__[i__ + 2];
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} else {
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z__[i__] = -(work[indlpl + i__] * z__[i__ + 1]);
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}
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if (((r__1 = z__[i__], dabs(r__1)) + (r__2 = z__[i__ + 1], dabs(
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r__2))) * (r__3 = ld[i__], dabs(r__3)) < *gaptol) {
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z__[i__] = 0.f;
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isuppz[1] = i__ + 1;
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goto L240;
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}
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*ztz += z__[i__] * z__[i__];
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/* L230: */
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}
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L240:
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;
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}
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/* Compute the FP vector downwards from R in blocks of size BLKSIZ */
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if (! sawnan1 && ! sawnan2) {
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i__1 = *bn - 1;
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for (i__ = *r__; i__ <= i__1; ++i__) {
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z__[i__ + 1] = -(work[indumn + i__] * z__[i__]);
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if (((r__1 = z__[i__], dabs(r__1)) + (r__2 = z__[i__ + 1], dabs(
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r__2))) * (r__3 = ld[i__], dabs(r__3)) < *gaptol) {
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z__[i__ + 1] = 0.f;
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isuppz[2] = i__;
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goto L260;
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}
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*ztz += z__[i__ + 1] * z__[i__ + 1];
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/* L250: */
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}
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L260:
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;
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} else {
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/* Run slower loop if NaN occurred. */
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i__1 = *bn - 1;
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for (i__ = *r__; i__ <= i__1; ++i__) {
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if (z__[i__] == 0.f) {
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z__[i__ + 1] = -(ld[i__ - 1] / ld[i__]) * z__[i__ - 1];
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} else {
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z__[i__ + 1] = -(work[indumn + i__] * z__[i__]);
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}
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if (((r__1 = z__[i__], dabs(r__1)) + (r__2 = z__[i__ + 1], dabs(
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r__2))) * (r__3 = ld[i__], dabs(r__3)) < *gaptol) {
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z__[i__ + 1] = 0.f;
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isuppz[2] = i__;
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goto L280;
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}
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*ztz += z__[i__ + 1] * z__[i__ + 1];
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/* L270: */
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}
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L280:
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;
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}
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/* Compute quantities for convergence test */
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tmp = 1.f / *ztz;
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*nrminv = sqrt(tmp);
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*resid = dabs(*mingma) * *nrminv;
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*rqcorr = *mingma * tmp;
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return 0;
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/* End of SLAR1V */
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} /* slar1v_ */
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