/* multifit/fdfridge.c * * Copyright (C) 2014 Patrick Alken * * 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 static int fdfridge_f(const gsl_vector * x, void * params, gsl_vector * f); static int fdfridge_df(const gsl_vector * x, void * params, gsl_matrix * J); gsl_multifit_fdfridge * gsl_multifit_fdfridge_alloc (const gsl_multifit_fdfsolver_type * T, const size_t n, const size_t p) { gsl_multifit_fdfridge * work; work = calloc(1, sizeof(gsl_multifit_fdfridge)); if (work == NULL) { GSL_ERROR_VAL("failed to allocate workspace", GSL_ENOMEM, 0); } work->s = gsl_multifit_fdfsolver_alloc (T, n + p, p); if (work->s == NULL) { gsl_multifit_fdfridge_free(work); GSL_ERROR_VAL("failed to allocate space for fdfsolver", GSL_ENOMEM, 0); } work->wts = gsl_vector_alloc(n + p); if (work->wts == NULL) { gsl_multifit_fdfridge_free(work); GSL_ERROR_VAL("failed to allocate space for weight vector", GSL_ENOMEM, 0); } work->f = gsl_vector_alloc(n); if (work->f == NULL) { gsl_multifit_fdfridge_free(work); GSL_ERROR_VAL("failed to allocate space for f vector", GSL_ENOMEM, 0); } work->n = n; work->p = p; work->lambda = 0.0; /* initialize weights to 1 (for augmented portion of vector) */ gsl_vector_set_all(work->wts, 1.0); return work; } /* gsl_multifit_fdfridge_alloc() */ void gsl_multifit_fdfridge_free(gsl_multifit_fdfridge *work) { if (work->s) gsl_multifit_fdfsolver_free(work->s); if (work->wts) gsl_vector_free(work->wts); if (work->f) gsl_vector_free(work->f); free(work); } const char * gsl_multifit_fdfridge_name(const gsl_multifit_fdfridge * w) { return gsl_multifit_fdfsolver_name(w->s); } gsl_vector * gsl_multifit_fdfridge_position (const gsl_multifit_fdfridge * w) { return gsl_multifit_fdfsolver_position(w->s); } gsl_vector * gsl_multifit_fdfridge_residual (const gsl_multifit_fdfridge * w) { return gsl_multifit_fdfsolver_residual(w->s); } size_t gsl_multifit_fdfridge_niter (const gsl_multifit_fdfridge * w) { return w->s->niter; } int gsl_multifit_fdfridge_set (gsl_multifit_fdfridge * w, gsl_multifit_function_fdf * f, const gsl_vector * x, const double lambda) { return gsl_multifit_fdfridge_wset(w, f, x, lambda, NULL); } /* gsl_multifit_fdfridge_set() */ int gsl_multifit_fdfridge_wset (gsl_multifit_fdfridge * w, gsl_multifit_function_fdf * f, const gsl_vector * x, const double lambda, const gsl_vector * wts) { const size_t n = w->n; const size_t p = w->p; if (n != f->n || p != f->p) { GSL_ERROR ("function size does not match solver", GSL_EBADLEN); } else if (p != x->size) { GSL_ERROR ("vector length does not match solver", GSL_EBADLEN); } else if (wts != NULL && n != wts->size) { GSL_ERROR ("weight vector length does not match solver", GSL_EBADLEN); } else { int status; gsl_vector_view wv = gsl_vector_subvector(w->wts, 0, n); /* save user defined fdf */ w->fdf = f; /* build modified fdf for Tikhonov terms */ w->fdftik.f = &fdfridge_f; w->fdftik.df = &fdfridge_df; w->fdftik.n = n + p; /* add p for Tikhonov terms */ w->fdftik.p = p; w->fdftik.params = (void *) w; /* store damping parameter */ w->lambda = lambda; w->L = NULL; if (wts) { /* copy weight vector into user portion of w->wts */ gsl_vector_memcpy(&wv.vector, wts); status = gsl_multifit_fdfsolver_wset(w->s, &(w->fdftik), x, w->wts); } else { status = gsl_multifit_fdfsolver_wset(w->s, &(w->fdftik), x, NULL); } /* update function/Jacobian evaluations */ f->nevalf = w->fdftik.nevalf; f->nevaldf = w->fdftik.nevaldf; return status; } } /* gsl_multifit_fdfridge_wset() */ int gsl_multifit_fdfridge_set2 (gsl_multifit_fdfridge * w, gsl_multifit_function_fdf * f, const gsl_vector * x, const gsl_vector * lambda) { return gsl_multifit_fdfridge_wset2(w, f, x, lambda, NULL); } /* gsl_multifit_fdfridge_set2() */ int gsl_multifit_fdfridge_wset2 (gsl_multifit_fdfridge * w, gsl_multifit_function_fdf * f, const gsl_vector * x, const gsl_vector * lambda, const gsl_vector * wts) { const size_t n = w->n; const size_t p = w->p; if (n != f->n || p != f->p) { GSL_ERROR ("function size does not match solver", GSL_EBADLEN); } else if (p != x->size) { GSL_ERROR ("vector length does not match solver", GSL_EBADLEN); } else if (lambda->size != p) { GSL_ERROR ("lambda vector size does not match solver", GSL_EBADLEN); } else if (wts != NULL && n != wts->size) { GSL_ERROR ("weight vector length does not match solver", GSL_EBADLEN); } else { int status; gsl_vector_view wv = gsl_vector_subvector(w->wts, 0, n); /* save user defined fdf */ w->fdf = f; w->fdf->nevalf = 0; w->fdf->nevaldf = 0; /* build modified fdf for Tikhonov terms */ w->fdftik.f = &fdfridge_f; w->fdftik.df = &fdfridge_df; w->fdftik.n = n + p; /* add p for Tikhonov terms */ w->fdftik.p = p; w->fdftik.params = (void *) w; /* store damping matrix */ w->lambda = 0.0; w->L_diag = lambda; w->L = NULL; if (wts) { /* copy weight vector into user portion */ gsl_vector_memcpy(&wv.vector, wts); status = gsl_multifit_fdfsolver_wset(w->s, &(w->fdftik), x, w->wts); } else { status = gsl_multifit_fdfsolver_wset(w->s, &(w->fdftik), x, NULL); } /* update function/Jacobian evaluations */ f->nevalf = w->fdftik.nevalf; f->nevaldf = w->fdftik.nevaldf; return status; } } /* gsl_multifit_fdfridge_wset2() */ int gsl_multifit_fdfridge_set3 (gsl_multifit_fdfridge * w, gsl_multifit_function_fdf * f, const gsl_vector * x, const gsl_matrix * L) { return gsl_multifit_fdfridge_wset3(w, f, x, L, NULL); } /* gsl_multifit_fdfridge_set3() */ int gsl_multifit_fdfridge_wset3 (gsl_multifit_fdfridge * w, gsl_multifit_function_fdf * f, const gsl_vector * x, const gsl_matrix * L, const gsl_vector * wts) { const size_t n = w->n; const size_t p = w->p; if (n != f->n || p != f->p) { GSL_ERROR ("function size does not match solver", GSL_EBADLEN); } else if (p != x->size) { GSL_ERROR ("vector length does not match solver", GSL_EBADLEN); } else if (L->size2 != p) { GSL_ERROR ("L matrix size2 does not match solver", GSL_EBADLEN); } else if (wts != NULL && n != wts->size) { GSL_ERROR ("weight vector length does not match solver", GSL_EBADLEN); } else { int status; gsl_vector_view wv = gsl_vector_subvector(w->wts, 0, n); /* save user defined fdf */ w->fdf = f; w->fdf->nevalf = 0; w->fdf->nevaldf = 0; /* build modified fdf for Tikhonov terms */ w->fdftik.f = &fdfridge_f; w->fdftik.df = &fdfridge_df; w->fdftik.n = n + p; /* add p for Tikhonov terms */ w->fdftik.p = p; w->fdftik.params = (void *) w; /* store damping matrix */ w->lambda = 0.0; w->L_diag = NULL; w->L = L; if (wts) { /* copy weight vector into user portion */ gsl_vector_memcpy(&wv.vector, wts); status = gsl_multifit_fdfsolver_wset(w->s, &(w->fdftik), x, w->wts); } else { status = gsl_multifit_fdfsolver_wset(w->s, &(w->fdftik), x, NULL); } /* update function/Jacobian evaluations */ f->nevalf = w->fdftik.nevalf; f->nevaldf = w->fdftik.nevaldf; return status; } } /* gsl_multifit_fdfridge_wset3() */ int gsl_multifit_fdfridge_iterate (gsl_multifit_fdfridge * w) { int status = gsl_multifit_fdfsolver_iterate(w->s); /* update function/Jacobian evaluations */ w->fdf->nevalf = w->fdftik.nevalf; w->fdf->nevaldf = w->fdftik.nevaldf; return status; } int gsl_multifit_fdfridge_driver (gsl_multifit_fdfridge * w, const size_t maxiter, const double xtol, const double gtol, const double ftol, int *info) { int status = gsl_multifit_fdfsolver_driver(w->s, maxiter, xtol, gtol, ftol, info); return status; } /* gsl_multifit_fdfridge_driver() */ /* fdfridge_f() Callback function to provide residuals, including extra p Tikhonov terms. The residual vector will have the form: f~ = [ f ] [ \lambda x ] where f is the user supplied residuals, x are the model parameters, and \lambda is the Tikhonov damping parameter Inputs: x - model parameters (size p) params - pointer to fdfridge workspace f - (output) (n+p) vector to store f~ */ static int fdfridge_f(const gsl_vector * x, void * params, gsl_vector * f) { int status; gsl_multifit_fdfridge *w = (gsl_multifit_fdfridge *) params; const size_t n = w->n; const size_t p = w->p; gsl_vector_view f_user = gsl_vector_subvector(f, 0, n); gsl_vector_view f_tik = gsl_vector_subvector(f, n, p); /* call user callback function to get residual vector f */ status = gsl_multifit_eval_wf(w->fdf, x, NULL, &f_user.vector); if (status) return status; if (w->L_diag) { /* store diag(L_diag) x in Tikhonov portion of f~ */ gsl_vector_memcpy(&f_tik.vector, x); gsl_vector_mul(&f_tik.vector, w->L_diag); } else if (w->L) { /* store Lx in Tikhonov portion of f~ */ gsl_blas_dgemv(CblasNoTrans, 1.0, w->L, x, 0.0, &f_tik.vector); } else { /* store \lambda x in Tikhonov portion of f~ */ gsl_vector_memcpy(&f_tik.vector, x); gsl_vector_scale(&f_tik.vector, w->lambda); } return GSL_SUCCESS; } /* fdfridge_f() */ static int fdfridge_df(const gsl_vector * x, void * params, gsl_matrix * J) { int status; gsl_multifit_fdfridge *w = (gsl_multifit_fdfridge *) params; const size_t n = w->n; const size_t p = w->p; gsl_matrix_view J_user = gsl_matrix_submatrix(J, 0, 0, n, p); gsl_matrix_view J_tik = gsl_matrix_submatrix(J, n, 0, p, p); gsl_vector_view diag = gsl_matrix_diagonal(&J_tik.matrix); /* compute Jacobian */ if (w->fdf->df) status = gsl_multifit_eval_wdf(w->fdf, x, NULL, &J_user.matrix); else { /* compute f(x) and then finite difference Jacobian */ status = gsl_multifit_eval_wf(w->fdf, x, NULL, w->f); status += gsl_multifit_fdfsolver_dif_df(x, NULL, w->fdf, w->f, &J_user.matrix); } if (status) return status; if (w->L_diag) { /* store diag(L_diag) in Tikhonov portion of J */ gsl_matrix_set_zero(&J_tik.matrix); gsl_vector_memcpy(&diag.vector, w->L_diag); } else if (w->L) { /* store L in Tikhonov portion of J */ gsl_matrix_memcpy(&J_tik.matrix, w->L); } else { /* store \lambda I_p in Tikhonov portion of J */ gsl_matrix_set_zero(&J_tik.matrix); gsl_vector_set_all(&diag.vector, w->lambda); } return GSL_SUCCESS; } /* fdfridge_df() */