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haskell-igraph-0.8.0: igraph/src/dlasq5.c

/*  -- translated by f2c (version 20100827).
   You must link the resulting object file with libf2c:
	on Microsoft Windows system, link with libf2c.lib;
	on Linux or Unix systems, link with .../path/to/libf2c.a -lm
	or, if you install libf2c.a in a standard place, with -lf2c -lm
	-- in that order, at the end of the command line, as in
		cc *.o -lf2c -lm
	Source for libf2c is in /netlib/f2c/libf2c.zip, e.g.,

		http://www.netlib.org/f2c/libf2c.zip
*/

#include "f2c.h"

/* > \brief \b DLASQ5 computes one dqds transform in ping-pong form. Used by sbdsqr and sstegr.   

    =========== DOCUMENTATION ===========   

   Online html documentation available at   
              http://www.netlib.org/lapack/explore-html/   

   > \htmlonly   
   > Download DLASQ5 + dependencies   
   > <a href="http://www.netlib.org/cgi-bin/netlibfiles.tgz?format=tgz&filename=/lapack/lapack_routine/dlasq5.
f">   
   > [TGZ]</a>   
   > <a href="http://www.netlib.org/cgi-bin/netlibfiles.zip?format=zip&filename=/lapack/lapack_routine/dlasq5.
f">   
   > [ZIP]</a>   
   > <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/dlasq5.
f">   
   > [TXT]</a>   
   > \endhtmlonly   

    Definition:   
    ===========   

         SUBROUTINE DLASQ5( I0, N0, Z, PP, TAU, SIGMA, DMIN, DMIN1, DMIN2, DN,   
                            DNM1, DNM2, IEEE, EPS )   

         LOGICAL            IEEE   
         INTEGER            I0, N0, PP   
         DOUBLE PRECISION   DMIN, DMIN1, DMIN2, DN, DNM1, DNM2, TAU, SIGMA, EPS   
         DOUBLE PRECISION   Z( * )   


   > \par Purpose:   
    =============   
   >   
   > \verbatim   
   >   
   > DLASQ5 computes one dqds transform in ping-pong form, one   
   > version for IEEE machines another for non IEEE machines.   
   > \endverbatim   

    Arguments:   
    ==========   

   > \param[in] I0   
   > \verbatim   
   >          I0 is INTEGER   
   >        First index.   
   > \endverbatim   
   >   
   > \param[in] N0   
   > \verbatim   
   >          N0 is INTEGER   
   >        Last index.   
   > \endverbatim   
   >   
   > \param[in] Z   
   > \verbatim   
   >          Z is DOUBLE PRECISION array, dimension ( 4*N )   
   >        Z holds the qd array. EMIN is stored in Z(4*N0) to avoid   
   >        an extra argument.   
   > \endverbatim   
   >   
   > \param[in] PP   
   > \verbatim   
   >          PP is INTEGER   
   >        PP=0 for ping, PP=1 for pong.   
   > \endverbatim   
   >   
   > \param[in] TAU   
   > \verbatim   
   >          TAU is DOUBLE PRECISION   
   >        This is the shift.   
   > \endverbatim   
   >   
   > \param[in] SIGMA   
   > \verbatim   
   >          SIGMA is DOUBLE PRECISION   
   >        This is the accumulated shift up to this step.   
   > \endverbatim   
   >   
   > \param[out] DMIN   
   > \verbatim   
   >          DMIN is DOUBLE PRECISION   
   >        Minimum value of d.   
   > \endverbatim   
   >   
   > \param[out] DMIN1   
   > \verbatim   
   >          DMIN1 is DOUBLE PRECISION   
   >        Minimum value of d, excluding D( N0 ).   
   > \endverbatim   
   >   
   > \param[out] DMIN2   
   > \verbatim   
   >          DMIN2 is DOUBLE PRECISION   
   >        Minimum value of d, excluding D( N0 ) and D( N0-1 ).   
   > \endverbatim   
   >   
   > \param[out] DN   
   > \verbatim   
   >          DN is DOUBLE PRECISION   
   >        d(N0), the last value of d.   
   > \endverbatim   
   >   
   > \param[out] DNM1   
   > \verbatim   
   >          DNM1 is DOUBLE PRECISION   
   >        d(N0-1).   
   > \endverbatim   
   >   
   > \param[out] DNM2   
   > \verbatim   
   >          DNM2 is DOUBLE PRECISION   
   >        d(N0-2).   
   > \endverbatim   
   >   
   > \param[in] IEEE   
   > \verbatim   
   >          IEEE is LOGICAL   
   >        Flag for IEEE or non IEEE arithmetic.   
   > \endverbatim   

   > \param[in] EPS   
   > \verbatim   
   >          EPS is DOUBLE PRECISION   
   >        This is the value of epsilon used.   
   > \endverbatim   
   >   
    Authors:   
    ========   

   > \author Univ. of Tennessee   
   > \author Univ. of California Berkeley   
   > \author Univ. of Colorado Denver   
   > \author NAG Ltd.   

   > \date September 2012   

   > \ingroup auxOTHERcomputational   

    =====================================================================   
   Subroutine */ int igraphdlasq5_(integer *i0, integer *n0, doublereal *z__, 
	integer *pp, doublereal *tau, doublereal *sigma, doublereal *dmin__, 
	doublereal *dmin1, doublereal *dmin2, doublereal *dn, doublereal *
	dnm1, doublereal *dnm2, logical *ieee, doublereal *eps)
{
    /* System generated locals */
    integer i__1;
    doublereal d__1, d__2;

    /* Local variables */
    doublereal d__;
    integer j4, j4p2;
    doublereal emin, temp, dthresh;


/*  -- LAPACK computational routine (version 3.4.2) --   
    -- LAPACK is a software package provided by Univ. of Tennessee,    --   
    -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--   
       September 2012   


    =====================================================================   


       Parameter adjustments */
    --z__;

    /* Function Body */
    if (*n0 - *i0 - 1 <= 0) {
	return 0;
    }

    dthresh = *eps * (*sigma + *tau);
    if (*tau < dthresh * .5) {
	*tau = 0.;
    }
    if (*tau != 0.) {
	j4 = (*i0 << 2) + *pp - 3;
	emin = z__[j4 + 4];
	d__ = z__[j4] - *tau;
	*dmin__ = d__;
	*dmin1 = -z__[j4];

	if (*ieee) {

/*        Code for IEEE arithmetic. */

	    if (*pp == 0) {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 2] = d__ + z__[j4 - 1];
		    temp = z__[j4 + 1] / z__[j4 - 2];
		    d__ = d__ * temp - *tau;
		    *dmin__ = min(*dmin__,d__);
		    z__[j4] = z__[j4 - 1] * temp;
/* Computing MIN */
		    d__1 = z__[j4];
		    emin = min(d__1,emin);
/* L10: */
		}
	    } else {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 3] = d__ + z__[j4];
		    temp = z__[j4 + 2] / z__[j4 - 3];
		    d__ = d__ * temp - *tau;
		    *dmin__ = min(*dmin__,d__);
		    z__[j4 - 1] = z__[j4] * temp;
/* Computing MIN */
		    d__1 = z__[j4 - 1];
		    emin = min(d__1,emin);
/* L20: */
		}
	    }

/*        Unroll last two steps. */

	    *dnm2 = d__;
	    *dmin2 = *dmin__;
	    j4 = (*n0 - 2 << 2) - *pp;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm2 + z__[j4p2];
	    z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
	    *dnm1 = z__[j4p2 + 2] * (*dnm2 / z__[j4 - 2]) - *tau;
	    *dmin__ = min(*dmin__,*dnm1);

	    *dmin1 = *dmin__;
	    j4 += 4;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm1 + z__[j4p2];
	    z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
	    *dn = z__[j4p2 + 2] * (*dnm1 / z__[j4 - 2]) - *tau;
	    *dmin__ = min(*dmin__,*dn);

	} else {

/*        Code for non IEEE arithmetic. */

	    if (*pp == 0) {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 2] = d__ + z__[j4 - 1];
		    if (d__ < 0.) {
			return 0;
		    } else {
			z__[j4] = z__[j4 + 1] * (z__[j4 - 1] / z__[j4 - 2]);
			d__ = z__[j4 + 1] * (d__ / z__[j4 - 2]) - *tau;
		    }
		    *dmin__ = min(*dmin__,d__);
/* Computing MIN */
		    d__1 = emin, d__2 = z__[j4];
		    emin = min(d__1,d__2);
/* L30: */
		}
	    } else {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 3] = d__ + z__[j4];
		    if (d__ < 0.) {
			return 0;
		    } else {
			z__[j4 - 1] = z__[j4 + 2] * (z__[j4] / z__[j4 - 3]);
			d__ = z__[j4 + 2] * (d__ / z__[j4 - 3]) - *tau;
		    }
		    *dmin__ = min(*dmin__,d__);
/* Computing MIN */
		    d__1 = emin, d__2 = z__[j4 - 1];
		    emin = min(d__1,d__2);
/* L40: */
		}
	    }

/*        Unroll last two steps. */

	    *dnm2 = d__;
	    *dmin2 = *dmin__;
	    j4 = (*n0 - 2 << 2) - *pp;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm2 + z__[j4p2];
	    if (*dnm2 < 0.) {
		return 0;
	    } else {
		z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
		*dnm1 = z__[j4p2 + 2] * (*dnm2 / z__[j4 - 2]) - *tau;
	    }
	    *dmin__ = min(*dmin__,*dnm1);

	    *dmin1 = *dmin__;
	    j4 += 4;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm1 + z__[j4p2];
	    if (*dnm1 < 0.) {
		return 0;
	    } else {
		z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
		*dn = z__[j4p2 + 2] * (*dnm1 / z__[j4 - 2]) - *tau;
	    }
	    *dmin__ = min(*dmin__,*dn);

	}
    } else {
/*     This is the version that sets d's to zero if they are small enough */
	j4 = (*i0 << 2) + *pp - 3;
	emin = z__[j4 + 4];
	d__ = z__[j4] - *tau;
	*dmin__ = d__;
	*dmin1 = -z__[j4];
	if (*ieee) {

/*     Code for IEEE arithmetic. */

	    if (*pp == 0) {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 2] = d__ + z__[j4 - 1];
		    temp = z__[j4 + 1] / z__[j4 - 2];
		    d__ = d__ * temp - *tau;
		    if (d__ < dthresh) {
			d__ = 0.;
		    }
		    *dmin__ = min(*dmin__,d__);
		    z__[j4] = z__[j4 - 1] * temp;
/* Computing MIN */
		    d__1 = z__[j4];
		    emin = min(d__1,emin);
/* L50: */
		}
	    } else {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 3] = d__ + z__[j4];
		    temp = z__[j4 + 2] / z__[j4 - 3];
		    d__ = d__ * temp - *tau;
		    if (d__ < dthresh) {
			d__ = 0.;
		    }
		    *dmin__ = min(*dmin__,d__);
		    z__[j4 - 1] = z__[j4] * temp;
/* Computing MIN */
		    d__1 = z__[j4 - 1];
		    emin = min(d__1,emin);
/* L60: */
		}
	    }

/*     Unroll last two steps. */

	    *dnm2 = d__;
	    *dmin2 = *dmin__;
	    j4 = (*n0 - 2 << 2) - *pp;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm2 + z__[j4p2];
	    z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
	    *dnm1 = z__[j4p2 + 2] * (*dnm2 / z__[j4 - 2]) - *tau;
	    *dmin__ = min(*dmin__,*dnm1);

	    *dmin1 = *dmin__;
	    j4 += 4;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm1 + z__[j4p2];
	    z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
	    *dn = z__[j4p2 + 2] * (*dnm1 / z__[j4 - 2]) - *tau;
	    *dmin__ = min(*dmin__,*dn);

	} else {

/*     Code for non IEEE arithmetic. */

	    if (*pp == 0) {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 2] = d__ + z__[j4 - 1];
		    if (d__ < 0.) {
			return 0;
		    } else {
			z__[j4] = z__[j4 + 1] * (z__[j4 - 1] / z__[j4 - 2]);
			d__ = z__[j4 + 1] * (d__ / z__[j4 - 2]) - *tau;
		    }
		    if (d__ < dthresh) {
			d__ = 0.;
		    }
		    *dmin__ = min(*dmin__,d__);
/* Computing MIN */
		    d__1 = emin, d__2 = z__[j4];
		    emin = min(d__1,d__2);
/* L70: */
		}
	    } else {
		i__1 = *n0 - 3 << 2;
		for (j4 = *i0 << 2; j4 <= i__1; j4 += 4) {
		    z__[j4 - 3] = d__ + z__[j4];
		    if (d__ < 0.) {
			return 0;
		    } else {
			z__[j4 - 1] = z__[j4 + 2] * (z__[j4] / z__[j4 - 3]);
			d__ = z__[j4 + 2] * (d__ / z__[j4 - 3]) - *tau;
		    }
		    if (d__ < dthresh) {
			d__ = 0.;
		    }
		    *dmin__ = min(*dmin__,d__);
/* Computing MIN */
		    d__1 = emin, d__2 = z__[j4 - 1];
		    emin = min(d__1,d__2);
/* L80: */
		}
	    }

/*     Unroll last two steps. */

	    *dnm2 = d__;
	    *dmin2 = *dmin__;
	    j4 = (*n0 - 2 << 2) - *pp;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm2 + z__[j4p2];
	    if (*dnm2 < 0.) {
		return 0;
	    } else {
		z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
		*dnm1 = z__[j4p2 + 2] * (*dnm2 / z__[j4 - 2]) - *tau;
	    }
	    *dmin__ = min(*dmin__,*dnm1);

	    *dmin1 = *dmin__;
	    j4 += 4;
	    j4p2 = j4 + (*pp << 1) - 1;
	    z__[j4 - 2] = *dnm1 + z__[j4p2];
	    if (*dnm1 < 0.) {
		return 0;
	    } else {
		z__[j4] = z__[j4p2 + 2] * (z__[j4p2] / z__[j4 - 2]);
		*dn = z__[j4p2 + 2] * (*dnm1 / z__[j4 - 2]) - *tau;
	    }
	    *dmin__ = min(*dmin__,*dn);

	}
    }

    z__[j4 + 2] = *dn;
    z__[(*n0 << 2) - *pp] = emin;
    return 0;

/*     End of DLASQ5 */

} /* igraphdlasq5_ */