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941 lines
21 KiB
941 lines
21 KiB
#include "clapack.h" |
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|
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/* Subroutine */ int dlaed4_(integer *n, integer *i__, doublereal *d__, |
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doublereal *z__, doublereal *delta, doublereal *rho, doublereal *dlam, |
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integer *info) |
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{ |
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/* System generated locals */ |
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integer i__1; |
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doublereal d__1; |
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|
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/* Builtin functions */ |
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double sqrt(doublereal); |
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|
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/* Local variables */ |
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doublereal a, b, c__; |
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integer j; |
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doublereal w; |
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integer ii; |
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doublereal dw, zz[3]; |
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integer ip1; |
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doublereal del, eta, phi, eps, tau, psi; |
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integer iim1, iip1; |
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doublereal dphi, dpsi; |
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integer iter; |
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doublereal temp, prew, temp1, dltlb, dltub, midpt; |
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integer niter; |
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logical swtch; |
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extern /* Subroutine */ int dlaed5_(integer *, doublereal *, doublereal *, |
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doublereal *, doublereal *, doublereal *), dlaed6_(integer *, |
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logical *, doublereal *, doublereal *, doublereal *, doublereal *, |
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doublereal *, integer *); |
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logical swtch3; |
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extern doublereal dlamch_(char *); |
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logical orgati; |
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doublereal erretm, rhoinv; |
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|
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/* -- LAPACK routine (version 3.1) -- */ |
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/* Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd.. */ |
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/* November 2006 */ |
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|
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/* .. Scalar Arguments .. */ |
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/* .. */ |
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/* .. Array Arguments .. */ |
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/* .. */ |
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|
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/* Purpose */ |
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/* ======= */ |
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|
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/* This subroutine computes the I-th updated eigenvalue of a symmetric */ |
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/* rank-one modification to a diagonal matrix whose elements are */ |
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/* given in the array d, and that */ |
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|
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/* D(i) < D(j) for i < j */ |
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|
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/* and that RHO > 0. This is arranged by the calling routine, and is */ |
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/* no loss in generality. The rank-one modified system is thus */ |
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|
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/* diag( D ) + RHO * Z * Z_transpose. */ |
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|
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/* where we assume the Euclidean norm of Z is 1. */ |
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|
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/* The method consists of approximating the rational functions in the */ |
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/* secular equation by simpler interpolating rational functions. */ |
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|
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/* Arguments */ |
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/* ========= */ |
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|
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/* N (input) INTEGER */ |
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/* The length of all arrays. */ |
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|
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/* I (input) INTEGER */ |
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/* The index of the eigenvalue to be computed. 1 <= I <= N. */ |
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|
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/* D (input) DOUBLE PRECISION array, dimension (N) */ |
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/* The original eigenvalues. It is assumed that they are in */ |
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/* order, D(I) < D(J) for I < J. */ |
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|
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/* Z (input) DOUBLE PRECISION array, dimension (N) */ |
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/* The components of the updating vector. */ |
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|
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/* DELTA (output) DOUBLE PRECISION array, dimension (N) */ |
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/* If N .GT. 2, DELTA contains (D(j) - lambda_I) in its j-th */ |
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/* component. If N = 1, then DELTA(1) = 1. If N = 2, see DLAED5 */ |
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/* for detail. The vector DELTA contains the information necessary */ |
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/* to construct the eigenvectors by DLAED3 and DLAED9. */ |
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|
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/* RHO (input) DOUBLE PRECISION */ |
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/* The scalar in the symmetric updating formula. */ |
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|
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/* DLAM (output) DOUBLE PRECISION */ |
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/* The computed lambda_I, the I-th updated eigenvalue. */ |
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|
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/* INFO (output) INTEGER */ |
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/* = 0: successful exit */ |
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/* > 0: if INFO = 1, the updating process failed. */ |
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|
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/* Internal Parameters */ |
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/* =================== */ |
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/* Logical variable ORGATI (origin-at-i?) is used for distinguishing */ |
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/* whether D(i) or D(i+1) is treated as the origin. */ |
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|
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/* ORGATI = .true. origin at i */ |
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/* ORGATI = .false. origin at i+1 */ |
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|
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/* Logical variable SWTCH3 (switch-for-3-poles?) is for noting */ |
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/* if we are working with THREE poles! */ |
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|
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/* MAXIT is the maximum number of iterations allowed for each */ |
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/* eigenvalue. */ |
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|
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/* Further Details */ |
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/* =============== */ |
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|
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/* Based on contributions by */ |
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/* Ren-Cang Li, Computer Science Division, University of California */ |
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/* at Berkeley, USA */ |
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|
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/* ===================================================================== */ |
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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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/* .. Local Arrays .. */ |
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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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|
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/* Since this routine is called in an inner loop, we do no argument */ |
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/* checking. */ |
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|
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/* Quick return for N=1 and 2. */ |
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|
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/* Parameter adjustments */ |
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--delta; |
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--z__; |
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--d__; |
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|
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/* Function Body */ |
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*info = 0; |
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if (*n == 1) { |
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|
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/* Presumably, I=1 upon entry */ |
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*dlam = d__[1] + *rho * z__[1] * z__[1]; |
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delta[1] = 1.; |
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return 0; |
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} |
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if (*n == 2) { |
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dlaed5_(i__, &d__[1], &z__[1], &delta[1], rho, dlam); |
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return 0; |
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} |
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/* Compute machine epsilon */ |
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eps = dlamch_("Epsilon"); |
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rhoinv = 1. / *rho; |
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|
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/* The case I = N */ |
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|
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if (*i__ == *n) { |
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|
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/* Initialize some basic variables */ |
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ii = *n - 1; |
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niter = 1; |
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|
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/* Calculate initial guess */ |
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midpt = *rho / 2.; |
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|
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/* If ||Z||_2 is not one, then TEMP should be set to */ |
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/* RHO * ||Z||_2^2 / TWO */ |
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i__1 = *n; |
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for (j = 1; j <= i__1; ++j) { |
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delta[j] = d__[j] - d__[*i__] - midpt; |
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/* L10: */ |
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} |
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psi = 0.; |
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i__1 = *n - 2; |
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for (j = 1; j <= i__1; ++j) { |
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psi += z__[j] * z__[j] / delta[j]; |
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/* L20: */ |
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} |
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c__ = rhoinv + psi; |
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w = c__ + z__[ii] * z__[ii] / delta[ii] + z__[*n] * z__[*n] / delta[* |
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n]; |
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|
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if (w <= 0.) { |
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temp = z__[*n - 1] * z__[*n - 1] / (d__[*n] - d__[*n - 1] + *rho) |
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+ z__[*n] * z__[*n] / *rho; |
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if (c__ <= temp) { |
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tau = *rho; |
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} else { |
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del = d__[*n] - d__[*n - 1]; |
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a = -c__ * del + z__[*n - 1] * z__[*n - 1] + z__[*n] * z__[*n] |
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; |
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b = z__[*n] * z__[*n] * del; |
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if (a < 0.) { |
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tau = b * 2. / (sqrt(a * a + b * 4. * c__) - a); |
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} else { |
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tau = (a + sqrt(a * a + b * 4. * c__)) / (c__ * 2.); |
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} |
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} |
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/* It can be proved that */ |
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/* D(N)+RHO/2 <= LAMBDA(N) < D(N)+TAU <= D(N)+RHO */ |
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|
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dltlb = midpt; |
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dltub = *rho; |
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} else { |
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del = d__[*n] - d__[*n - 1]; |
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a = -c__ * del + z__[*n - 1] * z__[*n - 1] + z__[*n] * z__[*n]; |
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b = z__[*n] * z__[*n] * del; |
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if (a < 0.) { |
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tau = b * 2. / (sqrt(a * a + b * 4. * c__) - a); |
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} else { |
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tau = (a + sqrt(a * a + b * 4. * c__)) / (c__ * 2.); |
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} |
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/* It can be proved that */ |
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/* D(N) < D(N)+TAU < LAMBDA(N) < D(N)+RHO/2 */ |
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dltlb = 0.; |
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dltub = midpt; |
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} |
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i__1 = *n; |
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for (j = 1; j <= i__1; ++j) { |
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delta[j] = d__[j] - d__[*i__] - tau; |
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/* L30: */ |
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} |
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/* Evaluate PSI and the derivative DPSI */ |
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dpsi = 0.; |
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psi = 0.; |
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erretm = 0.; |
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i__1 = ii; |
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for (j = 1; j <= i__1; ++j) { |
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temp = z__[j] / delta[j]; |
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psi += z__[j] * temp; |
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dpsi += temp * temp; |
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erretm += psi; |
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/* L40: */ |
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} |
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erretm = abs(erretm); |
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|
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/* Evaluate PHI and the derivative DPHI */ |
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temp = z__[*n] / delta[*n]; |
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phi = z__[*n] * temp; |
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dphi = temp * temp; |
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erretm = (-phi - psi) * 8. + erretm - phi + rhoinv + abs(tau) * (dpsi |
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+ dphi); |
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w = rhoinv + phi + psi; |
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/* Test for convergence */ |
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if (abs(w) <= eps * erretm) { |
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*dlam = d__[*i__] + tau; |
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goto L250; |
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} |
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if (w <= 0.) { |
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dltlb = max(dltlb,tau); |
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} else { |
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dltub = min(dltub,tau); |
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} |
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/* Calculate the new step */ |
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++niter; |
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c__ = w - delta[*n - 1] * dpsi - delta[*n] * dphi; |
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a = (delta[*n - 1] + delta[*n]) * w - delta[*n - 1] * delta[*n] * ( |
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dpsi + dphi); |
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b = delta[*n - 1] * delta[*n] * w; |
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if (c__ < 0.) { |
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c__ = abs(c__); |
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} |
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if (c__ == 0.) { |
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/* ETA = B/A */ |
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/* ETA = RHO - TAU */ |
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eta = dltub - tau; |
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} else if (a >= 0.) { |
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eta = (a + sqrt((d__1 = a * a - b * 4. * c__, abs(d__1)))) / (c__ |
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* 2.); |
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} else { |
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eta = b * 2. / (a - sqrt((d__1 = a * a - b * 4. * c__, abs(d__1))) |
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); |
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} |
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/* Note, eta should be positive if w is negative, and */ |
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/* eta should be negative otherwise. However, */ |
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/* if for some reason caused by roundoff, eta*w > 0, */ |
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/* we simply use one Newton step instead. This way */ |
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/* will guarantee eta*w < 0. */ |
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if (w * eta > 0.) { |
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eta = -w / (dpsi + dphi); |
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} |
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temp = tau + eta; |
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if (temp > dltub || temp < dltlb) { |
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if (w < 0.) { |
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eta = (dltub - tau) / 2.; |
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} else { |
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eta = (dltlb - tau) / 2.; |
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} |
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} |
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i__1 = *n; |
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for (j = 1; j <= i__1; ++j) { |
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delta[j] -= eta; |
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/* L50: */ |
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} |
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tau += eta; |
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|
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/* Evaluate PSI and the derivative DPSI */ |
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dpsi = 0.; |
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psi = 0.; |
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erretm = 0.; |
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i__1 = ii; |
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for (j = 1; j <= i__1; ++j) { |
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temp = z__[j] / delta[j]; |
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psi += z__[j] * temp; |
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dpsi += temp * temp; |
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erretm += psi; |
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/* L60: */ |
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} |
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erretm = abs(erretm); |
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|
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/* Evaluate PHI and the derivative DPHI */ |
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temp = z__[*n] / delta[*n]; |
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phi = z__[*n] * temp; |
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dphi = temp * temp; |
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erretm = (-phi - psi) * 8. + erretm - phi + rhoinv + abs(tau) * (dpsi |
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+ dphi); |
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w = rhoinv + phi + psi; |
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|
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/* Main loop to update the values of the array DELTA */ |
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iter = niter + 1; |
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for (niter = iter; niter <= 30; ++niter) { |
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|
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/* Test for convergence */ |
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if (abs(w) <= eps * erretm) { |
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*dlam = d__[*i__] + tau; |
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goto L250; |
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} |
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if (w <= 0.) { |
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dltlb = max(dltlb,tau); |
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} else { |
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dltub = min(dltub,tau); |
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} |
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|
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/* Calculate the new step */ |
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|
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c__ = w - delta[*n - 1] * dpsi - delta[*n] * dphi; |
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a = (delta[*n - 1] + delta[*n]) * w - delta[*n - 1] * delta[*n] * |
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(dpsi + dphi); |
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b = delta[*n - 1] * delta[*n] * w; |
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if (a >= 0.) { |
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eta = (a + sqrt((d__1 = a * a - b * 4. * c__, abs(d__1)))) / ( |
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c__ * 2.); |
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} else { |
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eta = b * 2. / (a - sqrt((d__1 = a * a - b * 4. * c__, abs( |
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d__1)))); |
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} |
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|
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/* Note, eta should be positive if w is negative, and */ |
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/* eta should be negative otherwise. However, */ |
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/* if for some reason caused by roundoff, eta*w > 0, */ |
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/* we simply use one Newton step instead. This way */ |
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/* will guarantee eta*w < 0. */ |
|
|
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if (w * eta > 0.) { |
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eta = -w / (dpsi + dphi); |
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} |
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temp = tau + eta; |
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if (temp > dltub || temp < dltlb) { |
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if (w < 0.) { |
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eta = (dltub - tau) / 2.; |
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} else { |
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eta = (dltlb - tau) / 2.; |
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} |
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} |
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i__1 = *n; |
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for (j = 1; j <= i__1; ++j) { |
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delta[j] -= eta; |
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/* L70: */ |
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} |
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tau += eta; |
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|
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/* Evaluate PSI and the derivative DPSI */ |
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|
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dpsi = 0.; |
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psi = 0.; |
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erretm = 0.; |
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i__1 = ii; |
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for (j = 1; j <= i__1; ++j) { |
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temp = z__[j] / delta[j]; |
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psi += z__[j] * temp; |
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dpsi += temp * temp; |
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erretm += psi; |
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/* L80: */ |
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} |
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erretm = abs(erretm); |
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|
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/* Evaluate PHI and the derivative DPHI */ |
|
|
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temp = z__[*n] / delta[*n]; |
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phi = z__[*n] * temp; |
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dphi = temp * temp; |
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erretm = (-phi - psi) * 8. + erretm - phi + rhoinv + abs(tau) * ( |
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dpsi + dphi); |
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|
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w = rhoinv + phi + psi; |
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/* L90: */ |
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} |
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/* Return with INFO = 1, NITER = MAXIT and not converged */ |
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*info = 1; |
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*dlam = d__[*i__] + tau; |
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goto L250; |
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/* End for the case I = N */ |
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} else { |
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/* The case for I < N */ |
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niter = 1; |
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ip1 = *i__ + 1; |
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|
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/* Calculate initial guess */ |
|
|
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del = d__[ip1] - d__[*i__]; |
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midpt = del / 2.; |
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i__1 = *n; |
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for (j = 1; j <= i__1; ++j) { |
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delta[j] = d__[j] - d__[*i__] - midpt; |
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/* L100: */ |
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} |
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|
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psi = 0.; |
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i__1 = *i__ - 1; |
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for (j = 1; j <= i__1; ++j) { |
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psi += z__[j] * z__[j] / delta[j]; |
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/* L110: */ |
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} |
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|
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phi = 0.; |
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i__1 = *i__ + 2; |
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for (j = *n; j >= i__1; --j) { |
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phi += z__[j] * z__[j] / delta[j]; |
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/* L120: */ |
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} |
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c__ = rhoinv + psi + phi; |
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w = c__ + z__[*i__] * z__[*i__] / delta[*i__] + z__[ip1] * z__[ip1] / |
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delta[ip1]; |
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|
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if (w > 0.) { |
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|
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/* d(i)< the ith eigenvalue < (d(i)+d(i+1))/2 */ |
|
|
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/* We choose d(i) as origin. */ |
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|
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orgati = TRUE_; |
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a = c__ * del + z__[*i__] * z__[*i__] + z__[ip1] * z__[ip1]; |
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b = z__[*i__] * z__[*i__] * del; |
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if (a > 0.) { |
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tau = b * 2. / (a + sqrt((d__1 = a * a - b * 4. * c__, abs( |
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d__1)))); |
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} else { |
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tau = (a - sqrt((d__1 = a * a - b * 4. * c__, abs(d__1)))) / ( |
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c__ * 2.); |
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} |
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dltlb = 0.; |
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dltub = midpt; |
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} else { |
|
|
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/* (d(i)+d(i+1))/2 <= the ith eigenvalue < d(i+1) */ |
|
|
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/* We choose d(i+1) as origin. */ |
|
|
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orgati = FALSE_; |
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a = c__ * del - z__[*i__] * z__[*i__] - z__[ip1] * z__[ip1]; |
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b = z__[ip1] * z__[ip1] * del; |
|
if (a < 0.) { |
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tau = b * 2. / (a - sqrt((d__1 = a * a + b * 4. * c__, abs( |
|
d__1)))); |
|
} else { |
|
tau = -(a + sqrt((d__1 = a * a + b * 4. * c__, abs(d__1)))) / |
|
(c__ * 2.); |
|
} |
|
dltlb = -midpt; |
|
dltub = 0.; |
|
} |
|
|
|
if (orgati) { |
|
i__1 = *n; |
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for (j = 1; j <= i__1; ++j) { |
|
delta[j] = d__[j] - d__[*i__] - tau; |
|
/* L130: */ |
|
} |
|
} else { |
|
i__1 = *n; |
|
for (j = 1; j <= i__1; ++j) { |
|
delta[j] = d__[j] - d__[ip1] - tau; |
|
/* L140: */ |
|
} |
|
} |
|
if (orgati) { |
|
ii = *i__; |
|
} else { |
|
ii = *i__ + 1; |
|
} |
|
iim1 = ii - 1; |
|
iip1 = ii + 1; |
|
|
|
/* Evaluate PSI and the derivative DPSI */ |
|
|
|
dpsi = 0.; |
|
psi = 0.; |
|
erretm = 0.; |
|
i__1 = iim1; |
|
for (j = 1; j <= i__1; ++j) { |
|
temp = z__[j] / delta[j]; |
|
psi += z__[j] * temp; |
|
dpsi += temp * temp; |
|
erretm += psi; |
|
/* L150: */ |
|
} |
|
erretm = abs(erretm); |
|
|
|
/* Evaluate PHI and the derivative DPHI */ |
|
|
|
dphi = 0.; |
|
phi = 0.; |
|
i__1 = iip1; |
|
for (j = *n; j >= i__1; --j) { |
|
temp = z__[j] / delta[j]; |
|
phi += z__[j] * temp; |
|
dphi += temp * temp; |
|
erretm += phi; |
|
/* L160: */ |
|
} |
|
|
|
w = rhoinv + phi + psi; |
|
|
|
/* W is the value of the secular function with */ |
|
/* its ii-th element removed. */ |
|
|
|
swtch3 = FALSE_; |
|
if (orgati) { |
|
if (w < 0.) { |
|
swtch3 = TRUE_; |
|
} |
|
} else { |
|
if (w > 0.) { |
|
swtch3 = TRUE_; |
|
} |
|
} |
|
if (ii == 1 || ii == *n) { |
|
swtch3 = FALSE_; |
|
} |
|
|
|
temp = z__[ii] / delta[ii]; |
|
dw = dpsi + dphi + temp * temp; |
|
temp = z__[ii] * temp; |
|
w += temp; |
|
erretm = (phi - psi) * 8. + erretm + rhoinv * 2. + abs(temp) * 3. + |
|
abs(tau) * dw; |
|
|
|
/* Test for convergence */ |
|
|
|
if (abs(w) <= eps * erretm) { |
|
if (orgati) { |
|
*dlam = d__[*i__] + tau; |
|
} else { |
|
*dlam = d__[ip1] + tau; |
|
} |
|
goto L250; |
|
} |
|
|
|
if (w <= 0.) { |
|
dltlb = max(dltlb,tau); |
|
} else { |
|
dltub = min(dltub,tau); |
|
} |
|
|
|
/* Calculate the new step */ |
|
|
|
++niter; |
|
if (! swtch3) { |
|
if (orgati) { |
|
/* Computing 2nd power */ |
|
d__1 = z__[*i__] / delta[*i__]; |
|
c__ = w - delta[ip1] * dw - (d__[*i__] - d__[ip1]) * (d__1 * |
|
d__1); |
|
} else { |
|
/* Computing 2nd power */ |
|
d__1 = z__[ip1] / delta[ip1]; |
|
c__ = w - delta[*i__] * dw - (d__[ip1] - d__[*i__]) * (d__1 * |
|
d__1); |
|
} |
|
a = (delta[*i__] + delta[ip1]) * w - delta[*i__] * delta[ip1] * |
|
dw; |
|
b = delta[*i__] * delta[ip1] * w; |
|
if (c__ == 0.) { |
|
if (a == 0.) { |
|
if (orgati) { |
|
a = z__[*i__] * z__[*i__] + delta[ip1] * delta[ip1] * |
|
(dpsi + dphi); |
|
} else { |
|
a = z__[ip1] * z__[ip1] + delta[*i__] * delta[*i__] * |
|
(dpsi + dphi); |
|
} |
|
} |
|
eta = b / a; |
|
} else if (a <= 0.) { |
|
eta = (a - sqrt((d__1 = a * a - b * 4. * c__, abs(d__1)))) / ( |
|
c__ * 2.); |
|
} else { |
|
eta = b * 2. / (a + sqrt((d__1 = a * a - b * 4. * c__, abs( |
|
d__1)))); |
|
} |
|
} else { |
|
|
|
/* Interpolation using THREE most relevant poles */ |
|
|
|
temp = rhoinv + psi + phi; |
|
if (orgati) { |
|
temp1 = z__[iim1] / delta[iim1]; |
|
temp1 *= temp1; |
|
c__ = temp - delta[iip1] * (dpsi + dphi) - (d__[iim1] - d__[ |
|
iip1]) * temp1; |
|
zz[0] = z__[iim1] * z__[iim1]; |
|
zz[2] = delta[iip1] * delta[iip1] * (dpsi - temp1 + dphi); |
|
} else { |
|
temp1 = z__[iip1] / delta[iip1]; |
|
temp1 *= temp1; |
|
c__ = temp - delta[iim1] * (dpsi + dphi) - (d__[iip1] - d__[ |
|
iim1]) * temp1; |
|
zz[0] = delta[iim1] * delta[iim1] * (dpsi + (dphi - temp1)); |
|
zz[2] = z__[iip1] * z__[iip1]; |
|
} |
|
zz[1] = z__[ii] * z__[ii]; |
|
dlaed6_(&niter, &orgati, &c__, &delta[iim1], zz, &w, &eta, info); |
|
if (*info != 0) { |
|
goto L250; |
|
} |
|
} |
|
|
|
/* Note, eta should be positive if w is negative, and */ |
|
/* eta should be negative otherwise. However, */ |
|
/* if for some reason caused by roundoff, eta*w > 0, */ |
|
/* we simply use one Newton step instead. This way */ |
|
/* will guarantee eta*w < 0. */ |
|
|
|
if (w * eta >= 0.) { |
|
eta = -w / dw; |
|
} |
|
temp = tau + eta; |
|
if (temp > dltub || temp < dltlb) { |
|
if (w < 0.) { |
|
eta = (dltub - tau) / 2.; |
|
} else { |
|
eta = (dltlb - tau) / 2.; |
|
} |
|
} |
|
|
|
prew = w; |
|
|
|
i__1 = *n; |
|
for (j = 1; j <= i__1; ++j) { |
|
delta[j] -= eta; |
|
/* L180: */ |
|
} |
|
|
|
/* Evaluate PSI and the derivative DPSI */ |
|
|
|
dpsi = 0.; |
|
psi = 0.; |
|
erretm = 0.; |
|
i__1 = iim1; |
|
for (j = 1; j <= i__1; ++j) { |
|
temp = z__[j] / delta[j]; |
|
psi += z__[j] * temp; |
|
dpsi += temp * temp; |
|
erretm += psi; |
|
/* L190: */ |
|
} |
|
erretm = abs(erretm); |
|
|
|
/* Evaluate PHI and the derivative DPHI */ |
|
|
|
dphi = 0.; |
|
phi = 0.; |
|
i__1 = iip1; |
|
for (j = *n; j >= i__1; --j) { |
|
temp = z__[j] / delta[j]; |
|
phi += z__[j] * temp; |
|
dphi += temp * temp; |
|
erretm += phi; |
|
/* L200: */ |
|
} |
|
|
|
temp = z__[ii] / delta[ii]; |
|
dw = dpsi + dphi + temp * temp; |
|
temp = z__[ii] * temp; |
|
w = rhoinv + phi + psi + temp; |
|
erretm = (phi - psi) * 8. + erretm + rhoinv * 2. + abs(temp) * 3. + ( |
|
d__1 = tau + eta, abs(d__1)) * dw; |
|
|
|
swtch = FALSE_; |
|
if (orgati) { |
|
if (-w > abs(prew) / 10.) { |
|
swtch = TRUE_; |
|
} |
|
} else { |
|
if (w > abs(prew) / 10.) { |
|
swtch = TRUE_; |
|
} |
|
} |
|
|
|
tau += eta; |
|
|
|
/* Main loop to update the values of the array DELTA */ |
|
|
|
iter = niter + 1; |
|
|
|
for (niter = iter; niter <= 30; ++niter) { |
|
|
|
/* Test for convergence */ |
|
|
|
if (abs(w) <= eps * erretm) { |
|
if (orgati) { |
|
*dlam = d__[*i__] + tau; |
|
} else { |
|
*dlam = d__[ip1] + tau; |
|
} |
|
goto L250; |
|
} |
|
|
|
if (w <= 0.) { |
|
dltlb = max(dltlb,tau); |
|
} else { |
|
dltub = min(dltub,tau); |
|
} |
|
|
|
/* Calculate the new step */ |
|
|
|
if (! swtch3) { |
|
if (! swtch) { |
|
if (orgati) { |
|
/* Computing 2nd power */ |
|
d__1 = z__[*i__] / delta[*i__]; |
|
c__ = w - delta[ip1] * dw - (d__[*i__] - d__[ip1]) * ( |
|
d__1 * d__1); |
|
} else { |
|
/* Computing 2nd power */ |
|
d__1 = z__[ip1] / delta[ip1]; |
|
c__ = w - delta[*i__] * dw - (d__[ip1] - d__[*i__]) * |
|
(d__1 * d__1); |
|
} |
|
} else { |
|
temp = z__[ii] / delta[ii]; |
|
if (orgati) { |
|
dpsi += temp * temp; |
|
} else { |
|
dphi += temp * temp; |
|
} |
|
c__ = w - delta[*i__] * dpsi - delta[ip1] * dphi; |
|
} |
|
a = (delta[*i__] + delta[ip1]) * w - delta[*i__] * delta[ip1] |
|
* dw; |
|
b = delta[*i__] * delta[ip1] * w; |
|
if (c__ == 0.) { |
|
if (a == 0.) { |
|
if (! swtch) { |
|
if (orgati) { |
|
a = z__[*i__] * z__[*i__] + delta[ip1] * |
|
delta[ip1] * (dpsi + dphi); |
|
} else { |
|
a = z__[ip1] * z__[ip1] + delta[*i__] * delta[ |
|
*i__] * (dpsi + dphi); |
|
} |
|
} else { |
|
a = delta[*i__] * delta[*i__] * dpsi + delta[ip1] |
|
* delta[ip1] * dphi; |
|
} |
|
} |
|
eta = b / a; |
|
} else if (a <= 0.) { |
|
eta = (a - sqrt((d__1 = a * a - b * 4. * c__, abs(d__1)))) |
|
/ (c__ * 2.); |
|
} else { |
|
eta = b * 2. / (a + sqrt((d__1 = a * a - b * 4. * c__, |
|
abs(d__1)))); |
|
} |
|
} else { |
|
|
|
/* Interpolation using THREE most relevant poles */ |
|
|
|
temp = rhoinv + psi + phi; |
|
if (swtch) { |
|
c__ = temp - delta[iim1] * dpsi - delta[iip1] * dphi; |
|
zz[0] = delta[iim1] * delta[iim1] * dpsi; |
|
zz[2] = delta[iip1] * delta[iip1] * dphi; |
|
} else { |
|
if (orgati) { |
|
temp1 = z__[iim1] / delta[iim1]; |
|
temp1 *= temp1; |
|
c__ = temp - delta[iip1] * (dpsi + dphi) - (d__[iim1] |
|
- d__[iip1]) * temp1; |
|
zz[0] = z__[iim1] * z__[iim1]; |
|
zz[2] = delta[iip1] * delta[iip1] * (dpsi - temp1 + |
|
dphi); |
|
} else { |
|
temp1 = z__[iip1] / delta[iip1]; |
|
temp1 *= temp1; |
|
c__ = temp - delta[iim1] * (dpsi + dphi) - (d__[iip1] |
|
- d__[iim1]) * temp1; |
|
zz[0] = delta[iim1] * delta[iim1] * (dpsi + (dphi - |
|
temp1)); |
|
zz[2] = z__[iip1] * z__[iip1]; |
|
} |
|
} |
|
dlaed6_(&niter, &orgati, &c__, &delta[iim1], zz, &w, &eta, |
|
info); |
|
if (*info != 0) { |
|
goto L250; |
|
} |
|
} |
|
|
|
/* Note, eta should be positive if w is negative, and */ |
|
/* eta should be negative otherwise. However, */ |
|
/* if for some reason caused by roundoff, eta*w > 0, */ |
|
/* we simply use one Newton step instead. This way */ |
|
/* will guarantee eta*w < 0. */ |
|
|
|
if (w * eta >= 0.) { |
|
eta = -w / dw; |
|
} |
|
temp = tau + eta; |
|
if (temp > dltub || temp < dltlb) { |
|
if (w < 0.) { |
|
eta = (dltub - tau) / 2.; |
|
} else { |
|
eta = (dltlb - tau) / 2.; |
|
} |
|
} |
|
|
|
i__1 = *n; |
|
for (j = 1; j <= i__1; ++j) { |
|
delta[j] -= eta; |
|
/* L210: */ |
|
} |
|
|
|
tau += eta; |
|
prew = w; |
|
|
|
/* Evaluate PSI and the derivative DPSI */ |
|
|
|
dpsi = 0.; |
|
psi = 0.; |
|
erretm = 0.; |
|
i__1 = iim1; |
|
for (j = 1; j <= i__1; ++j) { |
|
temp = z__[j] / delta[j]; |
|
psi += z__[j] * temp; |
|
dpsi += temp * temp; |
|
erretm += psi; |
|
/* L220: */ |
|
} |
|
erretm = abs(erretm); |
|
|
|
/* Evaluate PHI and the derivative DPHI */ |
|
|
|
dphi = 0.; |
|
phi = 0.; |
|
i__1 = iip1; |
|
for (j = *n; j >= i__1; --j) { |
|
temp = z__[j] / delta[j]; |
|
phi += z__[j] * temp; |
|
dphi += temp * temp; |
|
erretm += phi; |
|
/* L230: */ |
|
} |
|
|
|
temp = z__[ii] / delta[ii]; |
|
dw = dpsi + dphi + temp * temp; |
|
temp = z__[ii] * temp; |
|
w = rhoinv + phi + psi + temp; |
|
erretm = (phi - psi) * 8. + erretm + rhoinv * 2. + abs(temp) * 3. |
|
+ abs(tau) * dw; |
|
if (w * prew > 0. && abs(w) > abs(prew) / 10.) { |
|
swtch = ! swtch; |
|
} |
|
|
|
/* L240: */ |
|
} |
|
|
|
/* Return with INFO = 1, NITER = MAXIT and not converged */ |
|
|
|
*info = 1; |
|
if (orgati) { |
|
*dlam = d__[*i__] + tau; |
|
} else { |
|
*dlam = d__[ip1] + tau; |
|
} |
|
|
|
} |
|
|
|
L250: |
|
|
|
return 0; |
|
|
|
/* End of DLAED4 */ |
|
|
|
} /* dlaed4_ */
|
|
|