/* Copyright (C) 2020 Daniel Schultz This file is part of FLINT. FLINT 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 "nmod_mpoly_factor.h" /* return 1: success 0: failed -1: exception (large exps) */ int nmod_mpoly_factor_irred_smprime_zippel( nmod_mpolyv_t fac, const nmod_mpoly_t A, const nmod_mpoly_factor_t lcAfac, const nmod_mpoly_t lcA, const nmod_mpoly_ctx_t ctx, flint_rand_t state) { int success; int alphas_tries_remaining, alphabetas_tries_remaining, alphabetas_length; const slong n = ctx->minfo->nvars - 1; slong i, j, k, r; mp_limb_t * alpha; n_poly_struct * alphabetas; nmod_mpoly_struct * Aevals; slong * degs, * degeval; nmod_mpolyv_t tfac; nmod_mpoly_t t, Acopy; nmod_mpoly_struct * newA; n_poly_t Abfc; n_bpoly_t Ab; n_tpoly_t Abfp; nmod_mpoly_t m, mpow; nmod_mpolyv_t new_lcs, lc_divs; FLINT_ASSERT(n > 1); FLINT_ASSERT(A->length > 1); FLINT_ASSERT(A->coeffs[0] == 1); FLINT_ASSERT(A->bits <= FLINT_BITS); if (ctx->mod.n < 7) return 0; nmod_mpoly_init(Acopy, ctx); nmod_mpoly_init(m, ctx); nmod_mpoly_init(mpow, ctx); nmod_mpolyv_init(new_lcs, ctx); nmod_mpolyv_init(lc_divs, ctx); n_poly_init(Abfc); n_tpoly_init(Abfp); n_bpoly_init(Ab); degs = (slong *) flint_malloc((n + 1)*sizeof(slong)); degeval = (slong *) flint_malloc((n + 1)*sizeof(slong)); alpha = (mp_limb_t *) flint_malloc(n*sizeof(mp_limb_t)); alphabetas = (n_poly_struct *) flint_malloc(n*sizeof(n_poly_struct)); Aevals = (nmod_mpoly_struct *) flint_malloc(n*sizeof(nmod_mpoly_struct)); for (i = 0; i < n; i++) { n_poly_init(alphabetas + i); nmod_mpoly_init(Aevals + i, ctx); } nmod_mpolyv_init(tfac, ctx); nmod_mpoly_init(t, ctx); /* init done */ alphabetas_length = 2; alphas_tries_remaining = 10; nmod_mpoly_degrees_si(degs, A, ctx); k = 0; for (i = 0; i <= n; i++) { k += degs[i]; if (ctx->mod.n < (ulong) k) { success = 0; goto cleanup; } } next_alpha: if (--alphas_tries_remaining < 0) { success = 0; goto cleanup; } for (i = 0; i < n; i++) alpha[i] = n_urandint(state, ctx->mod.n - 1) + 1; /* ensure degrees do not drop under evaluation */ for (i = n - 1; i >= 0; i--) { nmod_mpoly_evaluate_one_ui(Aevals + i, i == n - 1 ? A : Aevals + i + 1, i + 1, alpha[i], ctx); nmod_mpoly_degrees_si(degeval, Aevals + i, ctx); for (j = 0; j <= i; j++) if (degeval[j] != degs[j]) goto next_alpha; } /* make sure univar is squarefree */ nmod_mpoly_derivative(t, Aevals + 0, 0, ctx); if (!nmod_mpoly_gcd(t, t, Aevals + 0, ctx)) { success = -1; goto cleanup; } if (!nmod_mpoly_is_one(t, ctx)) goto next_alpha; alphabetas_tries_remaining = 2 + alphabetas_length; next_alphabetas: if (--alphabetas_tries_remaining < 0) { if (++alphabetas_length > 10) { success = 0; goto cleanup; } goto next_alpha; } for (i = 0; i < n; i++) { n_poly_fit_length(alphabetas + i, alphabetas_length); alphabetas[i].coeffs[0] = alpha[i]; for (j = 1; j < alphabetas_length; j++) alphabetas[i].coeffs[j] = n_urandint(state, ctx->mod.n); alphabetas[i].length = alphabetas_length; _n_poly_normalise(alphabetas + i); } _nmod_mpoly_eval_rest_to_n_bpoly(Ab, A, alphabetas, ctx); success = n_bpoly_mod_factor_smprime(Abfc, Abfp, Ab, 0, ctx->mod); if (!success) { FLINT_ASSERT(0 && "this should not happen"); goto next_alpha; } r = Abfp->length; if (r < 2) { nmod_mpolyv_fit_length(fac, 1, ctx); fac->length = 1; nmod_mpoly_set(fac->coeffs + 0, A, ctx); success = 1; goto cleanup; } nmod_mpolyv_fit_length(lc_divs, r, ctx); lc_divs->length = r; if (lcAfac->num > 0) { success = nmod_mpoly_factor_lcc_wang(lc_divs->coeffs, lcAfac, Abfc, Abfp->coeffs, r, alphabetas, ctx); if (!success) goto next_alphabetas; } else { for (i = 0; i < r; i++) nmod_mpoly_one(lc_divs->coeffs + i, ctx); } success = nmod_mpoly_divides(m, lcA, lc_divs->coeffs + 0, ctx); FLINT_ASSERT(success); for (i = 1; i < r; i++) { success = nmod_mpoly_divides(m, m, lc_divs->coeffs + i, ctx); FLINT_ASSERT(success); } nmod_mpoly_pow_ui(mpow, m, r - 1, ctx); if (nmod_mpoly_is_one(mpow, ctx)) { newA = (nmod_mpoly_struct *) A; } else { newA = Acopy; nmod_mpoly_mul(newA, A, mpow, ctx); } if (newA->bits > FLINT_BITS) { success = 0; goto cleanup; } nmod_mpoly_degrees_si(degs, newA, ctx); for (i = 0; i < n + 1; i++) { if (FLINT_BIT_COUNT(degs[i]) >= FLINT_BITS/3) { success = -1; goto cleanup; } } nmod_mpoly_set(t, mpow, ctx); for (i = n - 1; i >= 0; i--) { nmod_mpoly_evaluate_one_ui(t, mpow, i + 1, alpha[i], ctx); nmod_mpoly_swap(t, mpow, ctx); nmod_mpoly_mul(Aevals + i, Aevals + i, mpow, ctx); } nmod_mpolyv_fit_length(new_lcs, (n + 1)*r, ctx); i = n; for (j = 0; j < r; j++) { nmod_mpoly_mul(new_lcs->coeffs + i*r + j, lc_divs->coeffs + j, m, ctx); } for (i = n - 1; i >= 0; i--) { for (j = 0; j < r; j++) { nmod_mpoly_evaluate_one_ui(new_lcs->coeffs + i*r + j, new_lcs->coeffs + (i + 1)*r + j, i + 1, alpha[i], ctx); } } nmod_mpolyv_fit_length(fac, r, ctx); fac->length = r; for (i = 0; i < r; i++) { mp_limb_t q; FLINT_ASSERT(nmod_mpoly_is_ui(new_lcs->coeffs + 0*r + i, ctx)); FLINT_ASSERT(nmod_mpoly_length(new_lcs->coeffs + 0*r + i, ctx) == 1); _nmod_mpoly_set_n_bpoly_var1_zero(fac->coeffs + i, newA->bits, Abfp->coeffs + i, 0, ctx); FLINT_ASSERT(fac->coeffs[i].length > 0); q = nmod_inv(fac->coeffs[i].coeffs[0], ctx->mod); q = nmod_mul(q, new_lcs->coeffs[0*r + i].coeffs[0], ctx->mod); nmod_mpoly_scalar_mul_nmod_invertible(fac->coeffs + i, fac->coeffs + i, q, ctx); } nmod_mpolyv_fit_length(tfac, r, ctx); tfac->length = r; for (k = 1; k <= n; k++) { for (i = 0; i < r; i++) { _nmod_mpoly_set_lead0(tfac->coeffs + i, fac->coeffs + i, new_lcs->coeffs + k*r + i, ctx); } if (k > 2) { success = nmod_mpoly_hlift_zippel(k, tfac->coeffs, r, alpha, k < n ? Aevals + k : newA, degs, ctx, state); } else { success = nmod_mpoly_hlift(k, tfac->coeffs, r, alpha, k < n ? Aevals + k : newA, degs, ctx); } if (!success) goto next_alphabetas; nmod_mpolyv_swap(tfac, fac, ctx); } if (!nmod_mpoly_is_ui(m, ctx)) { for (i = 0; i < r; i++) { /* hlift should not have returned any large bits */ FLINT_ASSERT(fac->coeffs[i].bits <= FLINT_BITS); if (!nmod_mpolyl_content(t, fac->coeffs + i, 1, ctx)) { success = -1; goto cleanup; } success = nmod_mpoly_divides(fac->coeffs + i, fac->coeffs + i, t, ctx); FLINT_ASSERT(success); } } for (i = 0; i < r; i++) nmod_mpoly_make_monic(fac->coeffs + i, fac->coeffs + i, ctx); success = 1; cleanup: nmod_mpolyv_clear(new_lcs, ctx); nmod_mpolyv_clear(lc_divs, ctx); n_poly_clear(Abfc); n_tpoly_clear(Abfp); n_bpoly_clear(Ab); for (i = 0; i < n; i++) { nmod_mpoly_clear(Aevals + i, ctx); n_poly_clear(alphabetas + i); } flint_free(alphabetas); flint_free(alpha); flint_free(Aevals); flint_free(degs); flint_free(degeval); nmod_mpolyv_clear(tfac, ctx); nmod_mpoly_clear(t, ctx); nmod_mpoly_clear(Acopy, ctx); nmod_mpoly_clear(m, ctx); nmod_mpoly_clear(mpow, ctx); #if FLINT_WANT_ASSERT if (success) { nmod_mpoly_t prod; nmod_mpoly_init(prod, ctx); nmod_mpoly_one(prod, ctx); for (i = 0; i < fac->length; i++) nmod_mpoly_mul(prod, prod, fac->coeffs + i, ctx); FLINT_ASSERT(nmod_mpoly_equal(prod, A, ctx)); nmod_mpoly_clear(prod, ctx); } #endif return success; }