/* claic1.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" /* Table of constant values */ static integer c__1 = 1; /* Subroutine */ int claic1_(integer *job, integer *j, complex *x, real *sest, complex *w, complex *gamma, real *sestpr, complex *s, complex *c__) { /* System generated locals */ real r__1, r__2; complex q__1, q__2, q__3, q__4, q__5, q__6; /* Builtin functions */ double c_abs(complex *); void r_cnjg(complex *, complex *), c_sqrt(complex *, complex *); double sqrt(doublereal); void c_div(complex *, complex *, complex *); /* Local variables */ real b, t, s1, s2, scl, eps, tmp; complex sine; real test, zeta1, zeta2; complex alpha; extern /* Complex */ VOID cdotc_(complex *, integer *, complex *, integer *, complex *, integer *); real norma, absgam, absalp; extern doublereal slamch_(char *); complex cosine; real absest; /* -- LAPACK auxiliary routine (version 3.2) -- */ /* Univ. of Tennessee, Univ. of California Berkeley and NAG Ltd.. */ /* November 2006 */ /* .. Scalar Arguments .. */ /* .. */ /* .. Array Arguments .. */ /* .. */ /* Purpose */ /* ======= */ /* CLAIC1 applies one step of incremental condition estimation in */ /* its simplest version: */ /* Let x, twonorm(x) = 1, be an approximate singular vector of an j-by-j */ /* lower triangular matrix L, such that */ /* twonorm(L*x) = sest */ /* Then CLAIC1 computes sestpr, s, c such that */ /* the vector */ /* [ s*x ] */ /* xhat = [ c ] */ /* is an approximate singular vector of */ /* [ L 0 ] */ /* Lhat = [ w' gamma ] */ /* in the sense that */ /* twonorm(Lhat*xhat) = sestpr. */ /* Depending on JOB, an estimate for the largest or smallest singular */ /* value is computed. */ /* Note that [s c]' and sestpr**2 is an eigenpair of the system */ /* diag(sest*sest, 0) + [alpha gamma] * [ conjg(alpha) ] */ /* [ conjg(gamma) ] */ /* where alpha = conjg(x)'*w. */ /* Arguments */ /* ========= */ /* JOB (input) INTEGER */ /* = 1: an estimate for the largest singular value is computed. */ /* = 2: an estimate for the smallest singular value is computed. */ /* J (input) INTEGER */ /* Length of X and W */ /* X (input) COMPLEX array, dimension (J) */ /* The j-vector x. */ /* SEST (input) REAL */ /* Estimated singular value of j by j matrix L */ /* W (input) COMPLEX array, dimension (J) */ /* The j-vector w. */ /* GAMMA (input) COMPLEX */ /* The diagonal element gamma. */ /* SESTPR (output) REAL */ /* Estimated singular value of (j+1) by (j+1) matrix Lhat. */ /* S (output) COMPLEX */ /* Sine needed in forming xhat. */ /* C (output) COMPLEX */ /* Cosine needed in forming xhat. */ /* ===================================================================== */ /* .. Parameters .. */ /* .. */ /* .. Local Scalars .. */ /* .. */ /* .. Intrinsic Functions .. */ /* .. */ /* .. External Functions .. */ /* .. */ /* .. Executable Statements .. */ /* Parameter adjustments */ --w; --x; /* Function Body */ eps = slamch_("Epsilon"); cdotc_(&q__1, j, &x[1], &c__1, &w[1], &c__1); alpha.r = q__1.r, alpha.i = q__1.i; absalp = c_abs(&alpha); absgam = c_abs(gamma); absest = dabs(*sest); if (*job == 1) { /* Estimating largest singular value */ /* special cases */ if (*sest == 0.f) { s1 = dmax(absgam,absalp); if (s1 == 0.f) { s->r = 0.f, s->i = 0.f; c__->r = 1.f, c__->i = 0.f; *sestpr = 0.f; } else { q__1.r = alpha.r / s1, q__1.i = alpha.i / s1; s->r = q__1.r, s->i = q__1.i; q__1.r = gamma->r / s1, q__1.i = gamma->i / s1; c__->r = q__1.r, c__->i = q__1.i; r_cnjg(&q__4, s); q__3.r = s->r * q__4.r - s->i * q__4.i, q__3.i = s->r * q__4.i + s->i * q__4.r; r_cnjg(&q__6, c__); q__5.r = c__->r * q__6.r - c__->i * q__6.i, q__5.i = c__->r * q__6.i + c__->i * q__6.r; q__2.r = q__3.r + q__5.r, q__2.i = q__3.i + q__5.i; c_sqrt(&q__1, &q__2); tmp = q__1.r; q__1.r = s->r / tmp, q__1.i = s->i / tmp; s->r = q__1.r, s->i = q__1.i; q__1.r = c__->r / tmp, q__1.i = c__->i / tmp; c__->r = q__1.r, c__->i = q__1.i; *sestpr = s1 * tmp; } return 0; } else if (absgam <= eps * absest) { s->r = 1.f, s->i = 0.f; c__->r = 0.f, c__->i = 0.f; tmp = dmax(absest,absalp); s1 = absest / tmp; s2 = absalp / tmp; *sestpr = tmp * sqrt(s1 * s1 + s2 * s2); return 0; } else if (absalp <= eps * absest) { s1 = absgam; s2 = absest; if (s1 <= s2) { s->r = 1.f, s->i = 0.f; c__->r = 0.f, c__->i = 0.f; *sestpr = s2; } else { s->r = 0.f, s->i = 0.f; c__->r = 1.f, c__->i = 0.f; *sestpr = s1; } return 0; } else if (absest <= eps * absalp || absest <= eps * absgam) { s1 = absgam; s2 = absalp; if (s1 <= s2) { tmp = s1 / s2; scl = sqrt(tmp * tmp + 1.f); *sestpr = s2 * scl; q__2.r = alpha.r / s2, q__2.i = alpha.i / s2; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; s->r = q__1.r, s->i = q__1.i; q__2.r = gamma->r / s2, q__2.i = gamma->i / s2; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; c__->r = q__1.r, c__->i = q__1.i; } else { tmp = s2 / s1; scl = sqrt(tmp * tmp + 1.f); *sestpr = s1 * scl; q__2.r = alpha.r / s1, q__2.i = alpha.i / s1; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; s->r = q__1.r, s->i = q__1.i; q__2.r = gamma->r / s1, q__2.i = gamma->i / s1; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; c__->r = q__1.r, c__->i = q__1.i; } return 0; } else { /* normal case */ zeta1 = absalp / absest; zeta2 = absgam / absest; b = (1.f - zeta1 * zeta1 - zeta2 * zeta2) * .5f; r__1 = zeta1 * zeta1; c__->r = r__1, c__->i = 0.f; if (b > 0.f) { r__1 = b * b; q__4.r = r__1 + c__->r, q__4.i = c__->i; c_sqrt(&q__3, &q__4); q__2.r = b + q__3.r, q__2.i = q__3.i; c_div(&q__1, c__, &q__2); t = q__1.r; } else { r__1 = b * b; q__3.r = r__1 + c__->r, q__3.i = c__->i; c_sqrt(&q__2, &q__3); q__1.r = q__2.r - b, q__1.i = q__2.i; t = q__1.r; } q__3.r = alpha.r / absest, q__3.i = alpha.i / absest; q__2.r = -q__3.r, q__2.i = -q__3.i; q__1.r = q__2.r / t, q__1.i = q__2.i / t; sine.r = q__1.r, sine.i = q__1.i; q__3.r = gamma->r / absest, q__3.i = gamma->i / absest; q__2.r = -q__3.r, q__2.i = -q__3.i; r__1 = t + 1.f; q__1.r = q__2.r / r__1, q__1.i = q__2.i / r__1; cosine.r = q__1.r, cosine.i = q__1.i; r_cnjg(&q__4, &sine); q__3.r = sine.r * q__4.r - sine.i * q__4.i, q__3.i = sine.r * q__4.i + sine.i * q__4.r; r_cnjg(&q__6, &cosine); q__5.r = cosine.r * q__6.r - cosine.i * q__6.i, q__5.i = cosine.r * q__6.i + cosine.i * q__6.r; q__2.r = q__3.r + q__5.r, q__2.i = q__3.i + q__5.i; c_sqrt(&q__1, &q__2); tmp = q__1.r; q__1.r = sine.r / tmp, q__1.i = sine.i / tmp; s->r = q__1.r, s->i = q__1.i; q__1.r = cosine.r / tmp, q__1.i = cosine.i / tmp; c__->r = q__1.r, c__->i = q__1.i; *sestpr = sqrt(t + 1.f) * absest; return 0; } } else if (*job == 2) { /* Estimating smallest singular value */ /* special cases */ if (*sest == 0.f) { *sestpr = 0.f; if (dmax(absgam,absalp) == 0.f) { sine.r = 1.f, sine.i = 0.f; cosine.r = 0.f, cosine.i = 0.f; } else { r_cnjg(&q__2, gamma); q__1.r = -q__2.r, q__1.i = -q__2.i; sine.r = q__1.r, sine.i = q__1.i; r_cnjg(&q__1, &alpha); cosine.r = q__1.r, cosine.i = q__1.i; } /* Computing MAX */ r__1 = c_abs(&sine), r__2 = c_abs(&cosine); s1 = dmax(r__1,r__2); q__1.r = sine.r / s1, q__1.i = sine.i / s1; s->r = q__1.r, s->i = q__1.i; q__1.r = cosine.r / s1, q__1.i = cosine.i / s1; c__->r = q__1.r, c__->i = q__1.i; r_cnjg(&q__4, s); q__3.r = s->r * q__4.r - s->i * q__4.i, q__3.i = s->r * q__4.i + s->i * q__4.r; r_cnjg(&q__6, c__); q__5.r = c__->r * q__6.r - c__->i * q__6.i, q__5.i = c__->r * q__6.i + c__->i * q__6.r; q__2.r = q__3.r + q__5.r, q__2.i = q__3.i + q__5.i; c_sqrt(&q__1, &q__2); tmp = q__1.r; q__1.r = s->r / tmp, q__1.i = s->i / tmp; s->r = q__1.r, s->i = q__1.i; q__1.r = c__->r / tmp, q__1.i = c__->i / tmp; c__->r = q__1.r, c__->i = q__1.i; return 0; } else if (absgam <= eps * absest) { s->r = 0.f, s->i = 0.f; c__->r = 1.f, c__->i = 0.f; *sestpr = absgam; return 0; } else if (absalp <= eps * absest) { s1 = absgam; s2 = absest; if (s1 <= s2) { s->r = 0.f, s->i = 0.f; c__->r = 1.f, c__->i = 0.f; *sestpr = s1; } else { s->r = 1.f, s->i = 0.f; c__->r = 0.f, c__->i = 0.f; *sestpr = s2; } return 0; } else if (absest <= eps * absalp || absest <= eps * absgam) { s1 = absgam; s2 = absalp; if (s1 <= s2) { tmp = s1 / s2; scl = sqrt(tmp * tmp + 1.f); *sestpr = absest * (tmp / scl); r_cnjg(&q__4, gamma); q__3.r = q__4.r / s2, q__3.i = q__4.i / s2; q__2.r = -q__3.r, q__2.i = -q__3.i; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; s->r = q__1.r, s->i = q__1.i; r_cnjg(&q__3, &alpha); q__2.r = q__3.r / s2, q__2.i = q__3.i / s2; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; c__->r = q__1.r, c__->i = q__1.i; } else { tmp = s2 / s1; scl = sqrt(tmp * tmp + 1.f); *sestpr = absest / scl; r_cnjg(&q__4, gamma); q__3.r = q__4.r / s1, q__3.i = q__4.i / s1; q__2.r = -q__3.r, q__2.i = -q__3.i; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; s->r = q__1.r, s->i = q__1.i; r_cnjg(&q__3, &alpha); q__2.r = q__3.r / s1, q__2.i = q__3.i / s1; q__1.r = q__2.r / scl, q__1.i = q__2.i / scl; c__->r = q__1.r, c__->i = q__1.i; } return 0; } else { /* normal case */ zeta1 = absalp / absest; zeta2 = absgam / absest; /* Computing MAX */ r__1 = zeta1 * zeta1 + 1.f + zeta1 * zeta2, r__2 = zeta1 * zeta2 + zeta2 * zeta2; norma = dmax(r__1,r__2); /* See if root is closer to zero or to ONE */ test = (zeta1 - zeta2) * 2.f * (zeta1 + zeta2) + 1.f; if (test >= 0.f) { /* root is close to zero, compute directly */ b = (zeta1 * zeta1 + zeta2 * zeta2 + 1.f) * .5f; r__1 = zeta2 * zeta2; c__->r = r__1, c__->i = 0.f; r__2 = b * b; q__2.r = r__2 - c__->r, q__2.i = -c__->i; r__1 = b + sqrt(c_abs(&q__2)); q__1.r = c__->r / r__1, q__1.i = c__->i / r__1; t = q__1.r; q__2.r = alpha.r / absest, q__2.i = alpha.i / absest; r__1 = 1.f - t; q__1.r = q__2.r / r__1, q__1.i = q__2.i / r__1; sine.r = q__1.r, sine.i = q__1.i; q__3.r = gamma->r / absest, q__3.i = gamma->i / absest; q__2.r = -q__3.r, q__2.i = -q__3.i; q__1.r = q__2.r / t, q__1.i = q__2.i / t; cosine.r = q__1.r, cosine.i = q__1.i; *sestpr = sqrt(t + eps * 4.f * eps * norma) * absest; } else { /* root is closer to ONE, shift by that amount */ b = (zeta2 * zeta2 + zeta1 * zeta1 - 1.f) * .5f; r__1 = zeta1 * zeta1; c__->r = r__1, c__->i = 0.f; if (b >= 0.f) { q__2.r = -c__->r, q__2.i = -c__->i; r__1 = b * b; q__5.r = r__1 + c__->r, q__5.i = c__->i; c_sqrt(&q__4, &q__5); q__3.r = b + q__4.r, q__3.i = q__4.i; c_div(&q__1, &q__2, &q__3); t = q__1.r; } else { r__1 = b * b; q__3.r = r__1 + c__->r, q__3.i = c__->i; c_sqrt(&q__2, &q__3); q__1.r = b - q__2.r, q__1.i = -q__2.i; t = q__1.r; } q__3.r = alpha.r / absest, q__3.i = alpha.i / absest; q__2.r = -q__3.r, q__2.i = -q__3.i; q__1.r = q__2.r / t, q__1.i = q__2.i / t; sine.r = q__1.r, sine.i = q__1.i; q__3.r = gamma->r / absest, q__3.i = gamma->i / absest; q__2.r = -q__3.r, q__2.i = -q__3.i; r__1 = t + 1.f; q__1.r = q__2.r / r__1, q__1.i = q__2.i / r__1; cosine.r = q__1.r, cosine.i = q__1.i; *sestpr = sqrt(t + 1.f + eps * 4.f * eps * norma) * absest; } r_cnjg(&q__4, &sine); q__3.r = sine.r * q__4.r - sine.i * q__4.i, q__3.i = sine.r * q__4.i + sine.i * q__4.r; r_cnjg(&q__6, &cosine); q__5.r = cosine.r * q__6.r - cosine.i * q__6.i, q__5.i = cosine.r * q__6.i + cosine.i * q__6.r; q__2.r = q__3.r + q__5.r, q__2.i = q__3.i + q__5.i; c_sqrt(&q__1, &q__2); tmp = q__1.r; q__1.r = sine.r / tmp, q__1.i = sine.i / tmp; s->r = q__1.r, s->i = q__1.i; q__1.r = cosine.r / tmp, q__1.i = cosine.i / tmp; c__->r = q__1.r, c__->i = q__1.i; return 0; } } return 0; /* End of CLAIC1 */ } /* claic1_ */