/* slasq4.f -- translated by f2c (version 20061008). 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" #include "blaswrap.h" /* Subroutine */ int slasq4_(integer *i0, integer *n0, real *z__, integer *pp, integer *n0in, real *dmin__, real *dmin1, real *dmin2, real *dn, real *dn1, real *dn2, real *tau, integer *ttype, real *g) { /* System generated locals */ integer i__1; real r__1, r__2; /* Builtin functions */ double sqrt(doublereal); /* Local variables */ real s, a2, b1, b2; integer i4, nn, np; real gam, gap1, gap2; /* -- LAPACK routine (version 3.2) -- */ /* -- Contributed by Osni Marques of the Lawrence Berkeley National -- */ /* -- Laboratory and Beresford Parlett of the Univ. of California at -- */ /* -- Berkeley -- */ /* -- November 2008 -- */ /* -- LAPACK is a software package provided by Univ. of Tennessee, -- */ /* -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..-- */ /* .. Scalar Arguments .. */ /* .. */ /* .. Array Arguments .. */ /* .. */ /* Purpose */ /* ======= */ /* SLASQ4 computes an approximation TAU to the smallest eigenvalue */ /* using values of d from the previous transform. */ /* I0 (input) INTEGER */ /* First index. */ /* N0 (input) INTEGER */ /* Last index. */ /* Z (input) REAL array, dimension ( 4*N ) */ /* Z holds the qd array. */ /* PP (input) INTEGER */ /* PP=0 for ping, PP=1 for pong. */ /* NOIN (input) INTEGER */ /* The value of N0 at start of EIGTEST. */ /* DMIN (input) REAL */ /* Minimum value of d. */ /* DMIN1 (input) REAL */ /* Minimum value of d, excluding D( N0 ). */ /* DMIN2 (input) REAL */ /* Minimum value of d, excluding D( N0 ) and D( N0-1 ). */ /* DN (input) REAL */ /* d(N) */ /* DN1 (input) REAL */ /* d(N-1) */ /* DN2 (input) REAL */ /* d(N-2) */ /* TAU (output) REAL */ /* This is the shift. */ /* TTYPE (output) INTEGER */ /* Shift type. */ /* G (input/output) REAL */ /* G is passed as an argument in order to save its value between */ /* calls to SLASQ4. */ /* Further Details */ /* =============== */ /* CNST1 = 9/16 */ /* ===================================================================== */ /* .. Parameters .. */ /* .. */ /* .. Local Scalars .. */ /* .. */ /* .. Intrinsic Functions .. */ /* .. */ /* .. Executable Statements .. */ /* A negative DMIN forces the shift to take that absolute value */ /* TTYPE records the type of shift. */ /* Parameter adjustments */ --z__; /* Function Body */ if (*dmin__ <= 0.f) { *tau = -(*dmin__); *ttype = -1; return 0; } nn = (*n0 << 2) + *pp; if (*n0in == *n0) { /* No eigenvalues deflated. */ if (*dmin__ == *dn || *dmin__ == *dn1) { b1 = sqrt(z__[nn - 3]) * sqrt(z__[nn - 5]); b2 = sqrt(z__[nn - 7]) * sqrt(z__[nn - 9]); a2 = z__[nn - 7] + z__[nn - 5]; /* Cases 2 and 3. */ if (*dmin__ == *dn && *dmin1 == *dn1) { gap2 = *dmin2 - a2 - *dmin2 * .25f; if (gap2 > 0.f && gap2 > b2) { gap1 = a2 - *dn - b2 / gap2 * b2; } else { gap1 = a2 - *dn - (b1 + b2); } if (gap1 > 0.f && gap1 > b1) { /* Computing MAX */ r__1 = *dn - b1 / gap1 * b1, r__2 = *dmin__ * .5f; s = dmax(r__1,r__2); *ttype = -2; } else { s = 0.f; if (*dn > b1) { s = *dn - b1; } if (a2 > b1 + b2) { /* Computing MIN */ r__1 = s, r__2 = a2 - (b1 + b2); s = dmin(r__1,r__2); } /* Computing MAX */ r__1 = s, r__2 = *dmin__ * .333f; s = dmax(r__1,r__2); *ttype = -3; } } else { /* Case 4. */ *ttype = -4; s = *dmin__ * .25f; if (*dmin__ == *dn) { gam = *dn; a2 = 0.f; if (z__[nn - 5] > z__[nn - 7]) { return 0; } b2 = z__[nn - 5] / z__[nn - 7]; np = nn - 9; } else { np = nn - (*pp << 1); b2 = z__[np - 2]; gam = *dn1; if (z__[np - 4] > z__[np - 2]) { return 0; } a2 = z__[np - 4] / z__[np - 2]; if (z__[nn - 9] > z__[nn - 11]) { return 0; } b2 = z__[nn - 9] / z__[nn - 11]; np = nn - 13; } /* Approximate contribution to norm squared from I < NN-1. */ a2 += b2; i__1 = (*i0 << 2) - 1 + *pp; for (i4 = np; i4 >= i__1; i4 += -4) { if (b2 == 0.f) { goto L20; } b1 = b2; if (z__[i4] > z__[i4 - 2]) { return 0; } b2 *= z__[i4] / z__[i4 - 2]; a2 += b2; if (dmax(b2,b1) * 100.f < a2 || .563f < a2) { goto L20; } /* L10: */ } L20: a2 *= 1.05f; /* Rayleigh quotient residual bound. */ if (a2 < .563f) { s = gam * (1.f - sqrt(a2)) / (a2 + 1.f); } } } else if (*dmin__ == *dn2) { /* Case 5. */ *ttype = -5; s = *dmin__ * .25f; /* Compute contribution to norm squared from I > NN-2. */ np = nn - (*pp << 1); b1 = z__[np - 2]; b2 = z__[np - 6]; gam = *dn2; if (z__[np - 8] > b2 || z__[np - 4] > b1) { return 0; } a2 = z__[np - 8] / b2 * (z__[np - 4] / b1 + 1.f); /* Approximate contribution to norm squared from I < NN-2. */ if (*n0 - *i0 > 2) { b2 = z__[nn - 13] / z__[nn - 15]; a2 += b2; i__1 = (*i0 << 2) - 1 + *pp; for (i4 = nn - 17; i4 >= i__1; i4 += -4) { if (b2 == 0.f) { goto L40; } b1 = b2; if (z__[i4] > z__[i4 - 2]) { return 0; } b2 *= z__[i4] / z__[i4 - 2]; a2 += b2; if (dmax(b2,b1) * 100.f < a2 || .563f < a2) { goto L40; } /* L30: */ } L40: a2 *= 1.05f; } if (a2 < .563f) { s = gam * (1.f - sqrt(a2)) / (a2 + 1.f); } } else { /* Case 6, no information to guide us. */ if (*ttype == -6) { *g += (1.f - *g) * .333f; } else if (*ttype == -18) { *g = .083250000000000005f; } else { *g = .25f; } s = *g * *dmin__; *ttype = -6; } } else if (*n0in == *n0 + 1) { /* One eigenvalue just deflated. Use DMIN1, DN1 for DMIN and DN. */ if (*dmin1 == *dn1 && *dmin2 == *dn2) { /* Cases 7 and 8. */ *ttype = -7; s = *dmin1 * .333f; if (z__[nn - 5] > z__[nn - 7]) { return 0; } b1 = z__[nn - 5] / z__[nn - 7]; b2 = b1; if (b2 == 0.f) { goto L60; } i__1 = (*i0 << 2) - 1 + *pp; for (i4 = (*n0 << 2) - 9 + *pp; i4 >= i__1; i4 += -4) { a2 = b1; if (z__[i4] > z__[i4 - 2]) { return 0; } b1 *= z__[i4] / z__[i4 - 2]; b2 += b1; if (dmax(b1,a2) * 100.f < b2) { goto L60; } /* L50: */ } L60: b2 = sqrt(b2 * 1.05f); /* Computing 2nd power */ r__1 = b2; a2 = *dmin1 / (r__1 * r__1 + 1.f); gap2 = *dmin2 * .5f - a2; if (gap2 > 0.f && gap2 > b2 * a2) { /* Computing MAX */ r__1 = s, r__2 = a2 * (1.f - a2 * 1.01f * (b2 / gap2) * b2); s = dmax(r__1,r__2); } else { /* Computing MAX */ r__1 = s, r__2 = a2 * (1.f - b2 * 1.01f); s = dmax(r__1,r__2); *ttype = -8; } } else { /* Case 9. */ s = *dmin1 * .25f; if (*dmin1 == *dn1) { s = *dmin1 * .5f; } *ttype = -9; } } else if (*n0in == *n0 + 2) { /* Two eigenvalues deflated. Use DMIN2, DN2 for DMIN and DN. */ /* Cases 10 and 11. */ if (*dmin2 == *dn2 && z__[nn - 5] * 2.f < z__[nn - 7]) { *ttype = -10; s = *dmin2 * .333f; if (z__[nn - 5] > z__[nn - 7]) { return 0; } b1 = z__[nn - 5] / z__[nn - 7]; b2 = b1; if (b2 == 0.f) { goto L80; } i__1 = (*i0 << 2) - 1 + *pp; for (i4 = (*n0 << 2) - 9 + *pp; i4 >= i__1; i4 += -4) { if (z__[i4] > z__[i4 - 2]) { return 0; } b1 *= z__[i4] / z__[i4 - 2]; b2 += b1; if (b1 * 100.f < b2) { goto L80; } /* L70: */ } L80: b2 = sqrt(b2 * 1.05f); /* Computing 2nd power */ r__1 = b2; a2 = *dmin2 / (r__1 * r__1 + 1.f); gap2 = z__[nn - 7] + z__[nn - 9] - sqrt(z__[nn - 11]) * sqrt(z__[ nn - 9]) - a2; if (gap2 > 0.f && gap2 > b2 * a2) { /* Computing MAX */ r__1 = s, r__2 = a2 * (1.f - a2 * 1.01f * (b2 / gap2) * b2); s = dmax(r__1,r__2); } else { /* Computing MAX */ r__1 = s, r__2 = a2 * (1.f - b2 * 1.01f); s = dmax(r__1,r__2); } } else { s = *dmin2 * .25f; *ttype = -11; } } else if (*n0in > *n0 + 2) { /* Case 12, more than two eigenvalues deflated. No information. */ s = 0.f; *ttype = -12; } *tau = s; return 0; /* End of SLASQ4 */ } /* slasq4_ */