--- /dev/null
+#include "clapack.h"
+
+/* Subroutine */ int slaed6_(integer *kniter, logical *orgati, real *rho,
+ real *d__, real *z__, real *finit, real *tau, integer *info)
+{
+ /* System generated locals */
+ integer i__1;
+ real r__1, r__2, r__3, r__4;
+
+ /* Builtin functions */
+ double sqrt(doublereal), log(doublereal), pow_ri(real *, integer *);
+
+ /* Local variables */
+ real a, b, c__, f;
+ integer i__;
+ real fc, df, ddf, lbd, eta, ubd, eps, base;
+ integer iter;
+ real temp, temp1, temp2, temp3, temp4;
+ logical scale;
+ integer niter;
+ real small1, small2, sminv1, sminv2, dscale[3], sclfac;
+ extern doublereal slamch_(char *);
+ real zscale[3], erretm, sclinv;
+
+
+/* -- LAPACK routine (version 3.1.1) -- */
+/* Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd.. */
+/* February 2007 */
+
+/* .. Scalar Arguments .. */
+/* .. */
+/* .. Array Arguments .. */
+/* .. */
+
+/* Purpose */
+/* ======= */
+
+/* SLAED6 computes the positive or negative root (closest to the origin) */
+/* of */
+/* z(1) z(2) z(3) */
+/* f(x) = rho + --------- + ---------- + --------- */
+/* d(1)-x d(2)-x d(3)-x */
+
+/* It is assumed that */
+
+/* if ORGATI = .true. the root is between d(2) and d(3); */
+/* otherwise it is between d(1) and d(2) */
+
+/* This routine will be called by SLAED4 when necessary. In most cases, */
+/* the root sought is the smallest in magnitude, though it might not be */
+/* in some extremely rare situations. */
+
+/* Arguments */
+/* ========= */
+
+/* KNITER (input) INTEGER */
+/* Refer to SLAED4 for its significance. */
+
+/* ORGATI (input) LOGICAL */
+/* If ORGATI is true, the needed root is between d(2) and */
+/* d(3); otherwise it is between d(1) and d(2). See */
+/* SLAED4 for further details. */
+
+/* RHO (input) REAL */
+/* Refer to the equation f(x) above. */
+
+/* D (input) REAL array, dimension (3) */
+/* D satisfies d(1) < d(2) < d(3). */
+
+/* Z (input) REAL array, dimension (3) */
+/* Each of the elements in z must be positive. */
+
+/* FINIT (input) REAL */
+/* The value of f at 0. It is more accurate than the one */
+/* evaluated inside this routine (if someone wants to do */
+/* so). */
+
+/* TAU (output) REAL */
+/* The root of the equation f(x). */
+
+/* INFO (output) INTEGER */
+/* = 0: successful exit */
+/* > 0: if INFO = 1, failure to converge */
+
+/* Further Details */
+/* =============== */
+
+/* 30/06/99: Based on contributions by */
+/* Ren-Cang Li, Computer Science Division, University of California */
+/* at Berkeley, USA */
+
+/* 10/02/03: This version has a few statements commented out for thread safety */
+/* (machine parameters are computed on each entry). SJH. */
+
+/* 05/10/06: Modified from a new version of Ren-Cang Li, use */
+/* Gragg-Thornton-Warner cubic convergent scheme for better stability. */
+
+/* ===================================================================== */
+
+/* .. Parameters .. */
+/* .. */
+/* .. External Functions .. */
+/* .. */
+/* .. Local Arrays .. */
+/* .. */
+/* .. Local Scalars .. */
+/* .. */
+/* .. Intrinsic Functions .. */
+/* .. */
+/* .. Executable Statements .. */
+
+ /* Parameter adjustments */
+ --z__;
+ --d__;
+
+ /* Function Body */
+ *info = 0;
+
+ if (*orgati) {
+ lbd = d__[2];
+ ubd = d__[3];
+ } else {
+ lbd = d__[1];
+ ubd = d__[2];
+ }
+ if (*finit < 0.f) {
+ lbd = 0.f;
+ } else {
+ ubd = 0.f;
+ }
+
+ niter = 1;
+ *tau = 0.f;
+ if (*kniter == 2) {
+ if (*orgati) {
+ temp = (d__[3] - d__[2]) / 2.f;
+ c__ = *rho + z__[1] / (d__[1] - d__[2] - temp);
+ a = c__ * (d__[2] + d__[3]) + z__[2] + z__[3];
+ b = c__ * d__[2] * d__[3] + z__[2] * d__[3] + z__[3] * d__[2];
+ } else {
+ temp = (d__[1] - d__[2]) / 2.f;
+ c__ = *rho + z__[3] / (d__[3] - d__[2] - temp);
+ a = c__ * (d__[1] + d__[2]) + z__[1] + z__[2];
+ b = c__ * d__[1] * d__[2] + z__[1] * d__[2] + z__[2] * d__[1];
+ }
+/* Computing MAX */
+ r__1 = dabs(a), r__2 = dabs(b), r__1 = max(r__1,r__2), r__2 = dabs(
+ c__);
+ temp = dmax(r__1,r__2);
+ a /= temp;
+ b /= temp;
+ c__ /= temp;
+ if (c__ == 0.f) {
+ *tau = b / a;
+ } else if (a <= 0.f) {
+ *tau = (a - sqrt((r__1 = a * a - b * 4.f * c__, dabs(r__1)))) / (
+ c__ * 2.f);
+ } else {
+ *tau = b * 2.f / (a + sqrt((r__1 = a * a - b * 4.f * c__, dabs(
+ r__1))));
+ }
+ if (*tau < lbd || *tau > ubd) {
+ *tau = (lbd + ubd) / 2.f;
+ }
+ if (d__[1] == *tau || d__[2] == *tau || d__[3] == *tau) {
+ *tau = 0.f;
+ } else {
+ temp = *finit + *tau * z__[1] / (d__[1] * (d__[1] - *tau)) + *tau
+ * z__[2] / (d__[2] * (d__[2] - *tau)) + *tau * z__[3] / (
+ d__[3] * (d__[3] - *tau));
+ if (temp <= 0.f) {
+ lbd = *tau;
+ } else {
+ ubd = *tau;
+ }
+ if (dabs(*finit) <= dabs(temp)) {
+ *tau = 0.f;
+ }
+ }
+ }
+
+/* get machine parameters for possible scaling to avoid overflow */
+
+/* modified by Sven: parameters SMALL1, SMINV1, SMALL2, */
+/* SMINV2, EPS are not SAVEd anymore between one call to the */
+/* others but recomputed at each call */
+
+ eps = slamch_("Epsilon");
+ base = slamch_("Base");
+ i__1 = (integer) (log(slamch_("SafMin")) / log(base) / 3.f);
+ small1 = pow_ri(&base, &i__1);
+ sminv1 = 1.f / small1;
+ small2 = small1 * small1;
+ sminv2 = sminv1 * sminv1;
+
+/* Determine if scaling of inputs necessary to avoid overflow */
+/* when computing 1/TEMP**3 */
+
+ if (*orgati) {
+/* Computing MIN */
+ r__3 = (r__1 = d__[2] - *tau, dabs(r__1)), r__4 = (r__2 = d__[3] - *
+ tau, dabs(r__2));
+ temp = dmin(r__3,r__4);
+ } else {
+/* Computing MIN */
+ r__3 = (r__1 = d__[1] - *tau, dabs(r__1)), r__4 = (r__2 = d__[2] - *
+ tau, dabs(r__2));
+ temp = dmin(r__3,r__4);
+ }
+ scale = FALSE_;
+ if (temp <= small1) {
+ scale = TRUE_;
+ if (temp <= small2) {
+
+/* Scale up by power of radix nearest 1/SAFMIN**(2/3) */
+
+ sclfac = sminv2;
+ sclinv = small2;
+ } else {
+
+/* Scale up by power of radix nearest 1/SAFMIN**(1/3) */
+
+ sclfac = sminv1;
+ sclinv = small1;
+ }
+
+/* Scaling up safe because D, Z, TAU scaled elsewhere to be O(1) */
+
+ for (i__ = 1; i__ <= 3; ++i__) {
+ dscale[i__ - 1] = d__[i__] * sclfac;
+ zscale[i__ - 1] = z__[i__] * sclfac;
+/* L10: */
+ }
+ *tau *= sclfac;
+ lbd *= sclfac;
+ ubd *= sclfac;
+ } else {
+
+/* Copy D and Z to DSCALE and ZSCALE */
+
+ for (i__ = 1; i__ <= 3; ++i__) {
+ dscale[i__ - 1] = d__[i__];
+ zscale[i__ - 1] = z__[i__];
+/* L20: */
+ }
+ }
+
+ fc = 0.f;
+ df = 0.f;
+ ddf = 0.f;
+ for (i__ = 1; i__ <= 3; ++i__) {
+ temp = 1.f / (dscale[i__ - 1] - *tau);
+ temp1 = zscale[i__ - 1] * temp;
+ temp2 = temp1 * temp;
+ temp3 = temp2 * temp;
+ fc += temp1 / dscale[i__ - 1];
+ df += temp2;
+ ddf += temp3;
+/* L30: */
+ }
+ f = *finit + *tau * fc;
+
+ if (dabs(f) <= 0.f) {
+ goto L60;
+ }
+ if (f <= 0.f) {
+ lbd = *tau;
+ } else {
+ ubd = *tau;
+ }
+
+/* Iteration begins -- Use Gragg-Thornton-Warner cubic convergent */
+/* scheme */
+
+/* It is not hard to see that */
+
+/* 1) Iterations will go up monotonically */
+/* if FINIT < 0; */
+
+/* 2) Iterations will go down monotonically */
+/* if FINIT > 0. */
+
+ iter = niter + 1;
+
+ for (niter = iter; niter <= 40; ++niter) {
+
+ if (*orgati) {
+ temp1 = dscale[1] - *tau;
+ temp2 = dscale[2] - *tau;
+ } else {
+ temp1 = dscale[0] - *tau;
+ temp2 = dscale[1] - *tau;
+ }
+ a = (temp1 + temp2) * f - temp1 * temp2 * df;
+ b = temp1 * temp2 * f;
+ c__ = f - (temp1 + temp2) * df + temp1 * temp2 * ddf;
+/* Computing MAX */
+ r__1 = dabs(a), r__2 = dabs(b), r__1 = max(r__1,r__2), r__2 = dabs(
+ c__);
+ temp = dmax(r__1,r__2);
+ a /= temp;
+ b /= temp;
+ c__ /= temp;
+ if (c__ == 0.f) {
+ eta = b / a;
+ } else if (a <= 0.f) {
+ eta = (a - sqrt((r__1 = a * a - b * 4.f * c__, dabs(r__1)))) / (
+ c__ * 2.f);
+ } else {
+ eta = b * 2.f / (a + sqrt((r__1 = a * a - b * 4.f * c__, dabs(
+ r__1))));
+ }
+ if (f * eta >= 0.f) {
+ eta = -f / df;
+ }
+
+ *tau += eta;
+ if (*tau < lbd || *tau > ubd) {
+ *tau = (lbd + ubd) / 2.f;
+ }
+
+ fc = 0.f;
+ erretm = 0.f;
+ df = 0.f;
+ ddf = 0.f;
+ for (i__ = 1; i__ <= 3; ++i__) {
+ temp = 1.f / (dscale[i__ - 1] - *tau);
+ temp1 = zscale[i__ - 1] * temp;
+ temp2 = temp1 * temp;
+ temp3 = temp2 * temp;
+ temp4 = temp1 / dscale[i__ - 1];
+ fc += temp4;
+ erretm += dabs(temp4);
+ df += temp2;
+ ddf += temp3;
+/* L40: */
+ }
+ f = *finit + *tau * fc;
+ erretm = (dabs(*finit) + dabs(*tau) * erretm) * 8.f + dabs(*tau) * df;
+ if (dabs(f) <= eps * erretm) {
+ goto L60;
+ }
+ if (f <= 0.f) {
+ lbd = *tau;
+ } else {
+ ubd = *tau;
+ }
+/* L50: */
+ }
+ *info = 1;
+L60:
+
+/* Undo scaling */
+
+ if (scale) {
+ *tau *= sclinv;
+ }
+ return 0;
+
+/* End of SLAED6 */
+
+} /* slaed6_ */