/*============================================================================= 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) 2007 David Howden Copyright (C) 2007, 2008, 2009, 2010 William Hart Copyright (C) 2008 Richard Howell-Peak Copyright (C) 2011 Fredrik Johansson ******************************************************************************/ #include "nmod_poly.h" #include "ulong_extras.h" void nmod_poly_factor_squarefree(nmod_poly_factor_t res, const nmod_poly_t f) { nmod_poly_t f_d, g, g_1; mp_limb_t p; slong deg, i; if (f->length <= 1) { res->num = 0; return; } if (f->length == 2) { nmod_poly_factor_insert(res, f, 1); return; } p = nmod_poly_modulus(f); deg = nmod_poly_degree(f); /* Step 1, look at f', if it is zero then we are done since f = h(x)^p for some particular h(x), clearly f(x) = sum a_k x^kp, k <= deg(f) */ nmod_poly_init(g_1, p); nmod_poly_init(f_d, p); nmod_poly_init(g, p); nmod_poly_derivative(f_d, f); /* Case 1 */ if (nmod_poly_is_zero(f_d)) { nmod_poly_factor_t new_res; nmod_poly_t h; nmod_poly_init(h, p); for (i = 0; i <= deg / p; i++) /* this will be an integer since f'=0 */ { nmod_poly_set_coeff_ui(h, i, nmod_poly_get_coeff_ui(f, i * p)); } /* Now run square-free on h, and return it to the pth power */ nmod_poly_factor_init(new_res); nmod_poly_factor_squarefree(new_res, h); nmod_poly_factor_pow(new_res, p); nmod_poly_factor_concat(res, new_res); nmod_poly_clear(h); nmod_poly_factor_clear(new_res); } else { nmod_poly_t h, z; nmod_poly_gcd(g, f, f_d); nmod_poly_div(g_1, f, g); i = 1; nmod_poly_init(h, p); nmod_poly_init(z, p); /* Case 2 */ while (!nmod_poly_is_one(g_1)) { nmod_poly_gcd(h, g_1, g); nmod_poly_div(z, g_1, h); /* out <- out.z */ if (z->length > 1) { nmod_poly_factor_insert(res, z, 1); nmod_poly_make_monic(res->p + (res->num - 1), res->p + (res->num - 1)); if (res->num) res->exp[res->num - 1] *= i; } i++; nmod_poly_set(g_1, h); nmod_poly_div(g, g, h); } nmod_poly_clear(h); nmod_poly_clear(z); nmod_poly_make_monic(g, g); if (!nmod_poly_is_one(g)) { /* so now we multiply res with square-free(g^1/p) ^ p */ nmod_poly_t g_p; /* g^(1/p) */ nmod_poly_factor_t new_res_2; nmod_poly_init(g_p, p); for (i = 0; i <= nmod_poly_degree(g) / p; i++) nmod_poly_set_coeff_ui(g_p, i, nmod_poly_get_coeff_ui(g, i*p)); nmod_poly_factor_init(new_res_2); /* square-free(g^(1/p)) */ nmod_poly_factor_squarefree(new_res_2, g_p); nmod_poly_factor_pow(new_res_2, p); nmod_poly_factor_concat(res, new_res_2); nmod_poly_clear(g_p); nmod_poly_factor_clear(new_res_2); } } nmod_poly_clear(g_1); nmod_poly_clear(f_d); nmod_poly_clear(g); }