/*============================================================================= This file is part of FLINT. FLINT 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 2 of the License, or (at your option) any later version. FLINT 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 FLINT; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA =============================================================================*/ /****************************************************************************** Copyright (C) 2010 Sebastian Pancratz Copyright (C) 2010 William Hart ******************************************************************************/ #include #include #include "flint.h" #include "nmod_vec.h" #include "nmod_poly.h" void _nmod_poly_pow_trunc_binexp(mp_ptr res, mp_srcptr poly, ulong e, slong trunc, nmod_t mod) { ulong bit = ~((~UWORD(0)) >> 1); mp_ptr v = _nmod_vec_init(trunc); mp_ptr R, S, T; /* Set bits to the bitmask with a 1 one place lower than the msb of e */ while ((bit & e) == UWORD(0)) bit >>= 1; bit >>= 1; /* Trial run without any polynomial arithmetic to determine the parity of the number of swaps; then set R and S accordingly */ { unsigned int swaps = 0U; ulong bit2 = bit; if ((bit2 & e)) swaps = ~swaps; while (bit2 >>= 1) if ((bit2 & e) == UWORD(0)) swaps = ~swaps; if (swaps == 0U) { R = res; S = v; } else { R = v; S = res; } } /* We unroll the first step of the loop, referring to {poly, len} */ _nmod_poly_mullow(R, poly, trunc, poly, trunc, trunc, mod); if ((bit & e)) { _nmod_poly_mullow(S, R, trunc, poly, trunc, trunc, mod); T = R; R = S; S = T; } while ((bit >>= 1)) { if ((bit & e)) { _nmod_poly_mullow(S, R, trunc, R, trunc, trunc, mod); _nmod_poly_mullow(R, S, trunc, poly, trunc, trunc, mod); } else { _nmod_poly_mullow(S, R, trunc, R, trunc, trunc, mod); T = R; R = S; S = T; } } _nmod_vec_clear(v); } void nmod_poly_pow_trunc_binexp(nmod_poly_t res, const nmod_poly_t poly, ulong e, slong trunc) { const slong len = poly->length; mp_ptr p; int pcopy = 0; if (len < 2 || e < UWORD(3) || trunc == 0) { if (len == 0 || trunc == 0) nmod_poly_zero(res); else if (len == 1) { nmod_poly_fit_length(res, 1); res->coeffs[0] = n_powmod2_ui_preinv(poly->coeffs[0], e, poly->mod.n, poly->mod.ninv); res->length = 1; _nmod_poly_normalise(res); } else if (e == UWORD(0)) { nmod_poly_set_coeff_ui(res, 0, UWORD(1)); res->length = 1; _nmod_poly_normalise(res); } else if (e == UWORD(1)) { nmod_poly_set(res, poly); nmod_poly_truncate(res, trunc); } else /* e == UWORD(2) */ nmod_poly_mullow(res, poly, poly, trunc); return; } if (poly->length < trunc) { p = _nmod_vec_init(trunc); flint_mpn_copyi(p, poly->coeffs, poly->length); flint_mpn_zero(p + poly->length, trunc - poly->length); pcopy = 1; } else p = poly->coeffs; if (res != poly || pcopy) { nmod_poly_fit_length(res, trunc); _nmod_poly_pow_trunc_binexp(res->coeffs, p, e, trunc, poly->mod); } else { nmod_poly_t t; nmod_poly_init2(t, poly->mod.n, trunc); _nmod_poly_pow_trunc_binexp(t->coeffs, p, e, trunc, poly->mod); nmod_poly_swap(res, t); nmod_poly_clear(t); } if (pcopy) _nmod_vec_clear(p); res->length = trunc; _nmod_poly_normalise(res); }