/* multiroots/hybridj.c * * Copyright (C) 1996, 1997, 1998, 1999, 2000, 2007 Brian Gough * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or (at * your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include #include #include #include #include #include #include #include #include "dogleg.c" typedef struct { size_t iter; size_t ncfail; size_t ncsuc; size_t nslow1; size_t nslow2; double fnorm; double delta; gsl_matrix *q; gsl_matrix *r; gsl_vector *tau; gsl_vector *diag; gsl_vector *qtf; gsl_vector *newton; gsl_vector *gradient; gsl_vector *x_trial; gsl_vector *f_trial; gsl_vector *df; gsl_vector *qtdf; gsl_vector *rdx; gsl_vector *w; gsl_vector *v; } hybridj_state_t; static int hybridj_alloc (void *vstate, size_t n); static int hybridj_set (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx); static int hybridsj_set (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx); static int hybridj_set_impl (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx, int scale); static int hybridj_iterate (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx); static void hybridj_free (void *vstate); static int hybridj_iterate_impl (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx, int scale); static int hybridj_alloc (void *vstate, size_t n) { hybridj_state_t *state = (hybridj_state_t *) vstate; gsl_matrix *q, *r; gsl_vector *tau, *diag, *qtf, *newton, *gradient, *x_trial, *f_trial, *df, *qtdf, *rdx, *w, *v; q = gsl_matrix_calloc (n, n); if (q == 0) { GSL_ERROR ("failed to allocate space for q", GSL_ENOMEM); } state->q = q; r = gsl_matrix_calloc (n, n); if (r == 0) { gsl_matrix_free (q); GSL_ERROR ("failed to allocate space for r", GSL_ENOMEM); } state->r = r; tau = gsl_vector_calloc (n); if (tau == 0) { gsl_matrix_free (q); gsl_matrix_free (r); GSL_ERROR ("failed to allocate space for tau", GSL_ENOMEM); } state->tau = tau; diag = gsl_vector_calloc (n); if (diag == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); GSL_ERROR ("failed to allocate space for diag", GSL_ENOMEM); } state->diag = diag; qtf = gsl_vector_calloc (n); if (qtf == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); GSL_ERROR ("failed to allocate space for qtf", GSL_ENOMEM); } state->qtf = qtf; newton = gsl_vector_calloc (n); if (newton == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); GSL_ERROR ("failed to allocate space for newton", GSL_ENOMEM); } state->newton = newton; gradient = gsl_vector_calloc (n); if (gradient == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); GSL_ERROR ("failed to allocate space for gradient", GSL_ENOMEM); } state->gradient = gradient; x_trial = gsl_vector_calloc (n); if (x_trial == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); gsl_vector_free (gradient); GSL_ERROR ("failed to allocate space for x_trial", GSL_ENOMEM); } state->x_trial = x_trial; f_trial = gsl_vector_calloc (n); if (f_trial == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); gsl_vector_free (gradient); gsl_vector_free (x_trial); GSL_ERROR ("failed to allocate space for f_trial", GSL_ENOMEM); } state->f_trial = f_trial; df = gsl_vector_calloc (n); if (df == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); gsl_vector_free (gradient); gsl_vector_free (x_trial); gsl_vector_free (f_trial); GSL_ERROR ("failed to allocate space for df", GSL_ENOMEM); } state->df = df; qtdf = gsl_vector_calloc (n); if (qtdf == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); gsl_vector_free (gradient); gsl_vector_free (x_trial); gsl_vector_free (f_trial); gsl_vector_free (df); GSL_ERROR ("failed to allocate space for qtdf", GSL_ENOMEM); } state->qtdf = qtdf; rdx = gsl_vector_calloc (n); if (rdx == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); gsl_vector_free (gradient); gsl_vector_free (x_trial); gsl_vector_free (f_trial); gsl_vector_free (df); gsl_vector_free (qtdf); GSL_ERROR ("failed to allocate space for rdx", GSL_ENOMEM); } state->rdx = rdx; w = gsl_vector_calloc (n); if (w == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); gsl_vector_free (gradient); gsl_vector_free (x_trial); gsl_vector_free (f_trial); gsl_vector_free (df); gsl_vector_free (qtdf); gsl_vector_free (rdx); GSL_ERROR ("failed to allocate space for w", GSL_ENOMEM); } state->w = w; v = gsl_vector_calloc (n); if (v == 0) { gsl_matrix_free (q); gsl_matrix_free (r); gsl_vector_free (tau); gsl_vector_free (diag); gsl_vector_free (qtf); gsl_vector_free (newton); gsl_vector_free (gradient); gsl_vector_free (x_trial); gsl_vector_free (f_trial); gsl_vector_free (df); gsl_vector_free (qtdf); gsl_vector_free (rdx); gsl_vector_free (w); GSL_ERROR ("failed to allocate space for v", GSL_ENOMEM); } state->v = v; return GSL_SUCCESS; } static int hybridj_set (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx) { int status = hybridj_set_impl (vstate, fdf, x, f, J, dx, 0); return status ; } static int hybridsj_set (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx) { int status = hybridj_set_impl (vstate, fdf, x, f, J, dx, 1); return status ; } static int hybridj_set_impl (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx, int scale) { hybridj_state_t *state = (hybridj_state_t *) vstate; gsl_matrix *q = state->q; gsl_matrix *r = state->r; gsl_vector *tau = state->tau; gsl_vector *diag = state->diag; GSL_MULTIROOT_FN_EVAL_F_DF (fdf, x, f, J); state->iter = 1; state->fnorm = enorm (f); state->ncfail = 0; state->ncsuc = 0; state->nslow1 = 0; state->nslow2 = 0; gsl_vector_set_all (dx, 0.0); /* Store column norms in diag */ if (scale) compute_diag (J, diag); else gsl_vector_set_all (diag, 1.0); /* Set delta to factor |D x| or to factor if |D x| is zero */ state->delta = compute_delta (diag, x); /* Factorize J into QR decomposition */ gsl_linalg_QR_decomp (J, tau); gsl_linalg_QR_unpack (J, tau, q, r); return GSL_SUCCESS; } static int hybridj_iterate (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx) { int status = hybridj_iterate_impl (vstate, fdf, x, f, J, dx, 0); return status; } static int hybridsj_iterate (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx) { int status = hybridj_iterate_impl (vstate, fdf, x, f, J, dx, 1); return status; } static int hybridj_iterate_impl (void *vstate, gsl_multiroot_function_fdf * fdf, gsl_vector * x, gsl_vector * f, gsl_matrix * J, gsl_vector * dx, int scale) { hybridj_state_t *state = (hybridj_state_t *) vstate; const double fnorm = state->fnorm; gsl_matrix *q = state->q; gsl_matrix *r = state->r; gsl_vector *tau = state->tau; gsl_vector *diag = state->diag; gsl_vector *qtf = state->qtf; gsl_vector *x_trial = state->x_trial; gsl_vector *f_trial = state->f_trial; gsl_vector *df = state->df; gsl_vector *qtdf = state->qtdf; gsl_vector *rdx = state->rdx; gsl_vector *w = state->w; gsl_vector *v = state->v; double prered, actred; double pnorm, fnorm1, fnorm1p; double ratio; double p1 = 0.1, p5 = 0.5, p001 = 0.001, p0001 = 0.0001; /* Compute qtf = Q^T f */ compute_qtf (q, f, qtf); /* Compute dogleg step */ dogleg (r, qtf, diag, state->delta, state->newton, state->gradient, dx); /* Take a trial step */ compute_trial_step (x, dx, state->x_trial); pnorm = scaled_enorm (diag, dx); if (state->iter == 1) { if (pnorm < state->delta) { state->delta = pnorm; } } /* Evaluate function at x + p */ { int status = GSL_MULTIROOT_FN_EVAL_F (fdf, x_trial, f_trial); if (status != GSL_SUCCESS) { return GSL_EBADFUNC; } } /* Set df = f_trial - f */ compute_df (f_trial, f, df); /* Compute the scaled actual reduction */ fnorm1 = enorm (f_trial); actred = compute_actual_reduction (fnorm, fnorm1); /* Compute rdx = R dx */ compute_rdx (r, dx, rdx); /* Compute the scaled predicted reduction phi1p = |Q^T f + R dx| */ fnorm1p = enorm_sum (qtf, rdx); prered = compute_predicted_reduction (fnorm, fnorm1p); /* Compute the ratio of the actual to predicted reduction */ if (prered > 0) { ratio = actred / prered; } else { ratio = 0; } /* Update the step bound */ if (ratio < p1) { state->ncsuc = 0; state->ncfail++; state->delta *= p5; } else { state->ncfail = 0; state->ncsuc++; if (ratio >= p5 || state->ncsuc > 1) state->delta = GSL_MAX (state->delta, pnorm / p5); if (fabs (ratio - 1) <= p1) state->delta = pnorm / p5; } /* Test for successful iteration */ if (ratio >= p0001) { gsl_vector_memcpy (x, x_trial); gsl_vector_memcpy (f, f_trial); state->fnorm = fnorm1; state->iter++; } /* Determine the progress of the iteration */ state->nslow1++; if (actred >= p001) state->nslow1 = 0; if (actred >= p1) state->nslow2 = 0; if (state->ncfail == 2) { { int status = GSL_MULTIROOT_FN_EVAL_DF (fdf, x, J); if (status != GSL_SUCCESS) { return GSL_EBADFUNC; } } state->nslow2++; if (state->iter == 1) { if (scale) compute_diag (J, diag); state->delta = compute_delta (diag, x); } else { if (scale) update_diag (J, diag); } /* Factorize J into QR decomposition */ gsl_linalg_QR_decomp (J, tau); gsl_linalg_QR_unpack (J, tau, q, r); return GSL_SUCCESS; } /* Compute qtdf = Q^T df, w = (Q^T df - R dx)/|dx|, v = D^2 dx/|dx| */ compute_qtf (q, df, qtdf); compute_wv (qtdf, rdx, dx, diag, pnorm, w, v); /* Rank-1 update of the jacobian Q'R' = Q(R + w v^T) */ gsl_linalg_QR_update (q, r, w, v); /* No progress as measured by jacobian evaluations */ if (state->nslow2 == 5) { return GSL_ENOPROGJ; } /* No progress as measured by function evaluations */ if (state->nslow1 == 10) { return GSL_ENOPROG; } return GSL_SUCCESS; } static void hybridj_free (void *vstate) { hybridj_state_t *state = (hybridj_state_t *) vstate; gsl_vector_free (state->v); gsl_vector_free (state->w); gsl_vector_free (state->rdx); gsl_vector_free (state->qtdf); gsl_vector_free (state->df); gsl_vector_free (state->f_trial); gsl_vector_free (state->x_trial); gsl_vector_free (state->gradient); gsl_vector_free (state->newton); gsl_vector_free (state->qtf); gsl_vector_free (state->diag); gsl_vector_free (state->tau); gsl_matrix_free (state->r); gsl_matrix_free (state->q); } static const gsl_multiroot_fdfsolver_type hybridj_type = { "hybridj", /* name */ sizeof (hybridj_state_t), &hybridj_alloc, &hybridj_set, &hybridj_iterate, &hybridj_free }; static const gsl_multiroot_fdfsolver_type hybridsj_type = { "hybridsj", /* name */ sizeof (hybridj_state_t), &hybridj_alloc, &hybridsj_set, &hybridsj_iterate, &hybridj_free }; const gsl_multiroot_fdfsolver_type *gsl_multiroot_fdfsolver_hybridj = &hybridj_type; const gsl_multiroot_fdfsolver_type *gsl_multiroot_fdfsolver_hybridsj = &hybridsj_type;