/* Copyright (C) 2013 Fredrik Johansson This file is part of Arb. Arb is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License (LGPL) as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. See . */ #include "arb_poly.h" /* (a + bx^c)^g where a = f[0] and b = f[flen-1] */ void _arb_poly_binomial_pow_arb_series(arb_ptr h, arb_srcptr f, slong flen, const arb_t g, slong len, slong prec) { slong i, j, d; arb_t t; arb_init(t); d = flen - 1; arb_pow(h, f, g, prec); arb_div(t, f + d, f, prec); for (i = 1, j = d; j < len; i++, j += d) { arb_sub_ui(h + j, g, i - 1, prec); arb_mul(h + j, h + j, h + j - d, prec); arb_mul(h + j, h + j, t, prec); arb_div_ui(h + j, h + j, i, prec); } if (d > 1) { for (i = 1; i < len; i++) if (i % d != 0) arb_zero(h + i); } arb_clear(t); return; } void _arb_poly_pow_arb_series(arb_ptr h, arb_srcptr f, slong flen, const arb_t g, slong len, slong prec) { int f_binomial, g_exact, g_int; while (flen > 0 && arb_is_zero(f + flen - 1)) flen--; if (flen <= 1) { arb_pow(h, f, g, prec); _arb_vec_zero(h + 1, len - 1); return; } g_exact = arb_is_exact(g); g_int = arb_is_int(g); f_binomial = _arb_vec_is_zero(f + 1, flen - 2); /* g = small integer */ if (g_exact && g_int && arf_cmpabs_2exp_si(arb_midref(g), FLINT_BITS - 1) < 0) { slong e, hlen; e = arf_get_si(arb_midref(g), ARF_RND_DOWN); hlen = poly_pow_length(flen, FLINT_ABS(e), len); if (e >= 0) { _arb_poly_pow_ui_trunc_binexp(h, f, flen, e, hlen, prec); _arb_vec_zero(h + hlen, len - hlen); return; } else if (!f_binomial) { arb_ptr t; t = _arb_vec_init(hlen); _arb_poly_pow_ui_trunc_binexp(t, f, flen, -e, hlen, prec); _arb_poly_inv_series(h, t, hlen, len, prec); _arb_vec_clear(t, hlen); return; } } /* (a + bx^c)^g */ if (f_binomial) { _arb_poly_binomial_pow_arb_series(h, f, flen, g, len, prec); return; } /* g = +/- 1/2 */ if (g_exact && arf_cmpabs_2exp_si(arb_midref(g), -1) == 0) { if (arf_sgn(arb_midref(g)) > 0) _arb_poly_sqrt_series(h, f, flen, len, prec); else _arb_poly_rsqrt_series(h, f, flen, len, prec); return; } /* f^g = exp(g*log(f)) */ _arb_poly_log_series(h, f, flen, len, prec); _arb_vec_scalar_mul(h, h, len, g, prec); _arb_poly_exp_series(h, h, len, len, prec); } void arb_poly_pow_arb_series(arb_poly_t h, const arb_poly_t f, const arb_t g, slong len, slong prec) { slong flen; flen = f->length; flen = FLINT_MIN(flen, len); if (len == 0) { arb_poly_zero(h); return; } if (arb_is_zero(g)) { arb_poly_one(h); return; } if (flen == 0) { arb_poly_zero(h); return; } if (f == h) { arb_poly_t t; arb_poly_init2(t, len); _arb_poly_pow_arb_series(t->coeffs, f->coeffs, flen, g, len, prec); _arb_poly_set_length(t, len); _arb_poly_normalise(t); arb_poly_swap(t, h); arb_poly_clear(t); } else { arb_poly_fit_length(h, len); _arb_poly_pow_arb_series(h->coeffs, f->coeffs, flen, g, len, prec); _arb_poly_set_length(h, len); _arb_poly_normalise(h); } }