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| (* | |
| Authors: Jose Divasón | |
| Sebastiaan Joosten | |
| René Thiemann | |
| Akihisa Yamada | |
| *) | |
| subsection \<open>Reconstruction of Integer Factorization\<close> | |
| text \<open>We implemented Zassenhaus reconstruction-algorithm, i.e., given a factorization of $f$ mod $p^n$, | |
| the aim is to reconstruct a factorization of $f$ over the integers.\<close> | |
| theory Reconstruction | |
| imports | |
| Berlekamp_Hensel | |
| Polynomial_Factorization.Gauss_Lemma | |
| Polynomial_Factorization.Dvd_Int_Poly | |
| Polynomial_Factorization.Gcd_Rat_Poly | |
| Degree_Bound | |
| Factor_Bound | |
| Sublist_Iteration | |
| Poly_Mod | |
| begin | |
| hide_const coeff monom | |
| paragraph \<open>Misc lemmas\<close> | |
| lemma foldr_of_Cons[simp]: "foldr Cons xs ys = xs @ ys" by (induct xs, auto) | |
| lemma foldr_map_prod[simp]: | |
| "foldr (\<lambda>x. map_prod (f x) (g x)) xs base = (foldr f xs (fst base), foldr g xs (snd base))" | |
| by (induct xs, auto) | |
| paragraph \<open>The main part\<close> | |
| context poly_mod | |
| begin | |
| definition inv_Mp :: "int poly \<Rightarrow> int poly" where | |
| "inv_Mp = map_poly inv_M" | |
| definition mul_const :: "int poly \<Rightarrow> int \<Rightarrow> int" where | |
| "mul_const p c = (coeff p 0 * c) mod m" | |
| fun prod_list_m :: "int poly list \<Rightarrow> int poly" where | |
| "prod_list_m (f # fs) = Mp (f * prod_list_m fs)" | |
| | "prod_list_m [] = 1" | |
| context | |
| fixes sl_impl :: "(int poly, int \<times> int poly list, 'state)subseqs_foldr_impl" | |
| and m2 :: "int" | |
| begin | |
| definition inv_M2 :: "int \<Rightarrow> int" where | |
| "inv_M2 = (\<lambda> x. if x \<le> m2 then x else x - m)" | |
| definition inv_Mp2 :: "int poly \<Rightarrow> int poly" where | |
| "inv_Mp2 = map_poly inv_M2" | |
| partial_function (tailrec) reconstruction :: "'state \<Rightarrow> int poly \<Rightarrow> int poly | |
| \<Rightarrow> int \<Rightarrow> nat \<Rightarrow> nat \<Rightarrow> int poly list \<Rightarrow> int poly list | |
| \<Rightarrow> (int \<times> (int poly list)) list \<Rightarrow> int poly list" where | |
| "reconstruction state u luu lu d r vs res cands = (case cands of Nil | |
| \<Rightarrow> let d' = Suc d | |
| in if d' + d' > r then (u # res) else | |
| (case next_subseqs_foldr sl_impl state of (cands,state') \<Rightarrow> | |
| reconstruction state' u luu lu d' r vs res cands) | |
| | (lv',ws) # cands' \<Rightarrow> let | |
| lv = inv_M2 lv' \<comment> \<open>\<open>lv\<close> is last coefficient of \<open>vb\<close> below\<close> | |
| in if lv dvd coeff luu 0 then let | |
| vb = inv_Mp2 (Mp (smult lu (prod_list_m ws))) | |
| in if vb dvd luu then | |
| let pp_vb = primitive_part vb; | |
| u' = u div pp_vb; | |
| r' = r - length ws; | |
| res' = pp_vb # res | |
| in if d + d > r' | |
| then u' # res' | |
| else let | |
| lu' = lead_coeff u'; | |
| vs' = fold remove1 ws vs; | |
| (cands'', state') = subseqs_foldr sl_impl (lu',[]) vs' d | |
| in reconstruction state' u' (smult lu' u') lu' d r' vs' res' cands'' | |
| else reconstruction state u luu lu d r vs res cands' | |
| else reconstruction state u luu lu d r vs res cands')" | |
| end | |
| end | |
| declare poly_mod.reconstruction.simps[code] | |
| declare poly_mod.prod_list_m.simps[code] | |
| declare poly_mod.mul_const_def[code] | |
| declare poly_mod.inv_M2_def[code] | |
| declare poly_mod.inv_Mp2_def[code_unfold] | |
| declare poly_mod.inv_Mp_def[code_unfold] | |
| definition zassenhaus_reconstruction_generic :: | |
| "(int poly, int \<times> int poly list, 'state) subseqs_foldr_impl | |
| \<Rightarrow> int poly list \<Rightarrow> int \<Rightarrow> nat \<Rightarrow> int poly \<Rightarrow> int poly list" where | |
| "zassenhaus_reconstruction_generic sl_impl vs p n f = (let | |
| lf = lead_coeff f; | |
| pn = p^n; | |
| (_, state) = subseqs_foldr sl_impl (lf,[]) vs 0 | |
| in | |
| poly_mod.reconstruction pn sl_impl (pn div 2) state f (smult lf f) lf 0 (length vs) vs [] [])" | |
| lemma coeff_mult_0: "coeff (f * g) 0 = coeff f 0 * coeff g 0" | |
| by (metis poly_0_coeff_0 poly_mult) | |
| lemma lead_coeff_factor: assumes u: "u = v * (w :: 'a ::idom poly)" | |
| shows "smult (lead_coeff u) u = (smult (lead_coeff w) v) * (smult (lead_coeff v) w)" | |
| "lead_coeff (smult (lead_coeff w) v) = lead_coeff u" "lead_coeff (smult (lead_coeff v) w) = lead_coeff u" | |
| unfolding u by (auto simp: lead_coeff_mult lead_coeff_smult) | |
| lemma not_irreducible\<^sub>d_lead_coeff_factors: assumes "\<not> irreducible\<^sub>d (u :: 'a :: idom poly)" "degree u \<noteq> 0" | |
| shows "\<exists> f g. smult (lead_coeff u) u = f * g \<and> lead_coeff f = lead_coeff u \<and> lead_coeff g = lead_coeff u | |
| \<and> degree f < degree u \<and> degree g < degree u" | |
| proof - | |
| from assms[unfolded irreducible\<^sub>d_def, simplified] | |
| obtain v w where deg: "degree v < degree u" "degree w < degree u" and u: "u = v * w" by auto | |
| define f where "f = smult (lead_coeff w) v" | |
| define g where "g = smult (lead_coeff v) w" | |
| note lf = lead_coeff_factor[OF u, folded f_def g_def] | |
| show ?thesis | |
| proof (intro exI conjI, (rule lf)+) | |
| show "degree f < degree u" "degree g < degree u" unfolding f_def g_def using deg u by auto | |
| qed | |
| qed | |
| lemma mset_subseqs_size: "mset ` {ys. ys \<in> set (subseqs xs) \<and> length ys = n} = | |
| {ws. ws \<subseteq># mset xs \<and> size ws = n}" | |
| proof (induct xs arbitrary: n) | |
| case (Cons x xs n) | |
| show ?case (is "?l = ?r") | |
| proof (cases n) | |
| case 0 | |
| thus ?thesis by (auto simp: Let_def) | |
| next | |
| case (Suc m) | |
| have "?r = {ws. ws \<subseteq># mset (x # xs)} \<inter> {ps. size ps = n}" by auto | |
| also have "{ws. ws \<subseteq># mset (x # xs)} = {ps. ps \<subseteq># mset xs} \<union> ((\<lambda> ps. ps + {#x#}) ` {ps. ps \<subseteq># mset xs})" | |
| by (simp add: multiset_subset_insert) | |
| also have "\<dots> \<inter> {ps. size ps = n} = {ps. ps \<subseteq># mset xs \<and> size ps = n} | |
| \<union> ((\<lambda> ps. ps + {#x#}) ` {ps. ps \<subseteq># mset xs \<and> size ps = m})" unfolding Suc by auto | |
| finally have id: "?r = | |
| {ps. ps \<subseteq># mset xs \<and> size ps = n} \<union> (\<lambda>ps. ps + {#x#}) ` {ps. ps \<subseteq># mset xs \<and> size ps = m}" . | |
| have "?l = mset ` {ys \<in> set (subseqs xs). length ys = Suc m} | |
| \<union> mset ` {ys \<in> (#) x ` set (subseqs xs). length ys = Suc m}" | |
| unfolding Suc by (auto simp: Let_def) | |
| also have "mset ` {ys \<in> (#) x ` set (subseqs xs). length ys = Suc m} | |
| = (\<lambda>ps. ps + {#x#}) ` mset ` {ys \<in> set (subseqs xs). length ys = m}" by force | |
| finally have id': "?l = mset ` {ys \<in> set (subseqs xs). length ys = Suc m} \<union> | |
| (\<lambda>ps. ps + {#x#}) ` mset ` {ys \<in> set (subseqs xs). length ys = m}" . | |
| show ?thesis unfolding id id' Cons[symmetric] unfolding Suc by simp | |
| qed | |
| qed auto | |
| context poly_mod_2 | |
| begin | |
| lemma prod_list_m[simp]: "prod_list_m fs = Mp (prod_list fs)" | |
| by (induct fs, auto) | |
| lemma inv_Mp_coeff: "coeff (inv_Mp f) n = inv_M (coeff f n)" | |
| unfolding inv_Mp_def | |
| by (rule coeff_map_poly, insert m1, auto simp: inv_M_def) | |
| lemma Mp_inv_Mp_id[simp]: "Mp (inv_Mp f) = Mp f" | |
| unfolding poly_eq_iff Mp_coeff inv_Mp_coeff by simp | |
| lemma inv_Mp_rev: assumes bnd: "\<And> n. 2 * abs (coeff f n) < m" | |
| shows "inv_Mp (Mp f) = f" | |
| proof (rule poly_eqI) | |
| fix n | |
| define c where "c = coeff f n" | |
| from bnd[of n, folded c_def] have bnd: "2 * abs c < m" by auto | |
| show "coeff (inv_Mp (Mp f)) n = coeff f n" unfolding inv_Mp_coeff Mp_coeff c_def[symmetric] | |
| using inv_M_rev[OF bnd] . | |
| qed | |
| lemma mul_const_commute_below: "mul_const x (mul_const y z) = mul_const y (mul_const x z)" | |
| unfolding mul_const_def by (metis mod_mult_right_eq mult.left_commute) | |
| context | |
| fixes p n | |
| and sl_impl :: "(int poly, int \<times> int poly list, 'state)subseqs_foldr_impl" | |
| and sli :: "int \<times> int poly list \<Rightarrow> int poly list \<Rightarrow> nat \<Rightarrow> 'state \<Rightarrow> bool" | |
| assumes prime: "prime p" | |
| and m: "m = p^n" | |
| and n: "n \<noteq> 0" | |
| and sl_impl: "correct_subseqs_foldr_impl (\<lambda>x. map_prod (mul_const x) (Cons x)) sl_impl sli" | |
| begin | |
| private definition "test_dvd_exec lu u ws = (\<not> inv_Mp (Mp (smult lu (prod_mset ws))) dvd smult lu u)" | |
| private definition "test_dvd u ws = (\<forall> v l. v dvd u \<longrightarrow> 0 < degree v \<longrightarrow> degree v < degree u | |
| \<longrightarrow> \<not> v =m smult l (prod_mset ws))" | |
| private definition "large_m u vs = (\<forall> v n. v dvd u \<longrightarrow> degree v \<le> degree_bound vs \<longrightarrow> 2 * abs (coeff v n) < m)" | |
| lemma large_m_factor: "large_m u vs \<Longrightarrow> v dvd u \<Longrightarrow> large_m v vs" | |
| unfolding large_m_def using dvd_trans by auto | |
| lemma test_dvd_factor: assumes u: "u \<noteq> 0" and test: "test_dvd u ws" and vu: "v dvd u" | |
| shows "test_dvd v ws" | |
| proof - | |
| from vu obtain w where uv: "u = v * w" unfolding dvd_def by auto | |
| from u have deg: "degree u = degree v + degree w" unfolding uv | |
| by (subst degree_mult_eq, auto) | |
| show ?thesis unfolding test_dvd_def | |
| proof (intro allI impI, goal_cases) | |
| case (1 f l) | |
| from 1(1) have fu: "f dvd u" unfolding uv by auto | |
| from 1(3) have deg: "degree f < degree u" unfolding deg by auto | |
| from test[unfolded test_dvd_def, rule_format, OF fu 1(2) deg] | |
| show ?case . | |
| qed | |
| qed | |
| lemma coprime_exp_mod: "coprime lu p \<Longrightarrow> prime p \<Longrightarrow> n \<noteq> 0 \<Longrightarrow> lu mod p ^ n \<noteq> 0" | |
| by (auto simp add: abs_of_pos prime_gt_0_int) | |
| interpretation correct_subseqs_foldr_impl "\<lambda>x. map_prod (mul_const x) (Cons x)" sl_impl sli by fact | |
| lemma reconstruction: assumes | |
| res: "reconstruction sl_impl m2 state u (smult lu u) lu d r vs res cands = fs" | |
| and f: "f = u * prod_list res" | |
| and meas: "meas = (r - d, cands)" | |
| and dr: "d + d \<le> r" | |
| and r: "r = length vs" | |
| and cands: "set cands \<subseteq> S (lu,[]) vs d" | |
| and d0: "d = 0 \<Longrightarrow> cands = []" | |
| and lu: "lu = lead_coeff u" | |
| and factors: "unique_factorization_m u (lu,mset vs)" | |
| and sf: "poly_mod.square_free_m p u" | |
| and cop: "coprime lu p" | |
| and norm: "\<And> v. v \<in> set vs \<Longrightarrow> Mp v = v" | |
| and tests: "\<And> ws. ws \<subseteq># mset vs \<Longrightarrow> ws \<noteq> {#} \<Longrightarrow> | |
| size ws < d \<or> size ws = d \<and> ws \<notin> (mset o snd) ` set cands | |
| \<Longrightarrow> test_dvd u ws" | |
| and irr: "\<And> f. f \<in> set res \<Longrightarrow> irreducible\<^sub>d f" | |
| and deg: "degree u > 0" | |
| and cands_ne: "cands \<noteq> [] \<Longrightarrow> d < r" | |
| and large: "\<forall> v n. v dvd smult lu u \<longrightarrow> degree v \<le> degree_bound vs | |
| \<longrightarrow> 2 * abs (coeff v n) < m" | |
| and f0: "f \<noteq> 0" | |
| and state: "sli (lu,[]) vs d state" | |
| and m2: "m2 = m div 2" | |
| shows "f = prod_list fs \<and> (\<forall> fi \<in> set fs. irreducible\<^sub>d fi)" | |
| proof - | |
| from large have large: "large_m (smult lu u) vs" unfolding large_m_def by auto | |
| interpret p: poly_mod_prime p using prime by unfold_locales | |
| define R where "R \<equiv> measures [ | |
| \<lambda> (n :: nat,cds :: (int \<times> int poly list) list). n, | |
| \<lambda> (n,cds). length cds]" | |
| have wf: "wf R" unfolding R_def by simp | |
| have mset_snd_S: "\<And> vs lu d. (mset \<circ> snd) ` S (lu,[]) vs d = | |
| { ws. ws \<subseteq># mset vs \<and> size ws = d}" | |
| by (fold mset_subseqs_size image_comp, unfold S_def image_Collect, auto) | |
| have inv_M2[simp]: "inv_M2 m2 = inv_M" unfolding inv_M2_def m2 inv_M_def | |
| by (intro ext, auto) | |
| have inv_Mp2[simp]: "inv_Mp2 m2 = inv_Mp" unfolding inv_Mp2_def inv_Mp_def by simp | |
| have p_Mp[simp]: "\<And> f. p.Mp (Mp f) = p.Mp f" using m p.m1 n Mp_Mp_pow_is_Mp by blast | |
| { | |
| fix u lu vs | |
| assume eq: "Mp u = Mp (smult lu (prod_mset vs))" and cop: "coprime lu p" and size: "size vs \<noteq> 0" | |
| and mi: "\<And> v. v \<in># vs \<Longrightarrow> irreducible\<^sub>d_m v \<and> monic v" | |
| from cop p.m1 have lu0: "lu \<noteq> 0" by auto | |
| from size have "vs \<noteq> {#}" by auto | |
| then obtain v vs' where vs_v: "vs = vs' + {#v#}" by (cases vs, auto) | |
| have mon: "monic (prod_mset vs)" | |
| by (rule monic_prod_mset, insert mi, auto) | |
| hence vs0: "prod_mset vs \<noteq> 0" by (metis coeff_0 zero_neq_one) | |
| from mon have l_vs: "lead_coeff (prod_mset vs) = 1" . | |
| have deg_ws: "degree_m (smult lu (prod_mset vs)) = degree (smult lu (prod_mset vs))" | |
| by (rule degree_m_eq[OF _ m1], unfold lead_coeff_smult, | |
| insert cop n p.m1 l_vs, auto simp: m) | |
| with eq have "degree_m u = degree (smult lu (prod_mset vs))" by auto | |
| also have "\<dots> = degree (prod_mset vs' * v)" unfolding degree_smult_eq vs_v using lu0 by (simp add:ac_simps) | |
| also have "\<dots> = degree (prod_mset vs') + degree v" | |
| by (rule degree_mult_eq, insert vs0[unfolded vs_v], auto) | |
| also have "\<dots> \<ge> degree v" by simp | |
| finally have deg_v: "degree v \<le> degree_m u" . | |
| from mi[unfolded vs_v, of v] have "irreducible\<^sub>d_m v" by auto | |
| hence "0 < degree_m v" unfolding irreducible\<^sub>d_m_def by auto | |
| also have "\<dots> \<le> degree v" by (rule degree_m_le) | |
| also have "\<dots> \<le> degree_m u" by (rule deg_v) | |
| also have "\<dots> \<le> degree u" by (rule degree_m_le) | |
| finally have "degree u > 0" by auto | |
| } note deg_non_zero = this | |
| { | |
| fix u :: "int poly" and vs :: "int poly list" and d :: nat | |
| assume deg_u: "degree u > 0" | |
| and cop: "coprime (lead_coeff u) p" | |
| and uf: "unique_factorization_m u (lead_coeff u, mset vs)" | |
| and sf: "p.square_free_m u" | |
| and norm: "\<And> v. v \<in> set vs \<Longrightarrow> Mp v = v" | |
| and d: "size (mset vs) < d + d" | |
| and tests: "\<And> ws. ws \<subseteq># mset vs \<Longrightarrow> ws \<noteq> {#} \<Longrightarrow> size ws < d \<Longrightarrow> test_dvd u ws" | |
| from deg_u have u0: "u \<noteq> 0" by auto | |
| have "irreducible\<^sub>d u" | |
| proof (rule irreducible\<^sub>dI[OF deg_u]) | |
| fix q q' :: "int poly" | |
| assume deg: "degree q > 0" "degree q < degree u" "degree q' > 0" "degree q' < degree u" | |
| and uq: "u = q * q'" | |
| then have qu: "q dvd u" and q'u: "q' dvd u" by auto | |
| from u0 have deg_u: "degree u = degree q + degree q'" unfolding uq | |
| by (subst degree_mult_eq, auto) | |
| from coprime_lead_coeff_factor[OF prime cop[unfolded uq]] | |
| have cop_q: "coprime (lead_coeff q) p" "coprime (lead_coeff q') p" by auto | |
| from unique_factorization_m_factor[OF prime uf[unfolded uq] _ _ n m, folded uq, | |
| OF cop sf] | |
| obtain fs gs l where uf_q: "unique_factorization_m q (lead_coeff q, fs)" | |
| and uf_q': "unique_factorization_m q' (lead_coeff q', gs)" | |
| and Mf_eq: "Mf (l, mset vs) = Mf (lead_coeff q * lead_coeff q', fs + gs)" | |
| and fs_id: "image_mset Mp fs = fs" | |
| and gs_id: "image_mset Mp gs = gs" by auto | |
| from Mf_eq fs_id gs_id have "image_mset Mp (mset vs) = fs + gs" | |
| unfolding Mf_def by auto | |
| also have "image_mset Mp (mset vs) = mset vs" using norm by (induct vs, auto) | |
| finally have eq: "mset vs = fs + gs" by simp | |
| from uf_q[unfolded unique_factorization_m_alt_def factorization_m_def split] | |
| have q_eq: "q =m smult (lead_coeff q) (prod_mset fs)" by auto | |
| have "degree_m q = degree q" | |
| by (rule degree_m_eq[OF _ m1], insert cop_q(1) n p.m1, unfold m, | |
| auto simp:) | |
| with q_eq have degm_q: "degree q = degree (Mp (smult (lead_coeff q) (prod_mset fs)))" by auto | |
| with deg have fs_nempty: "fs \<noteq> {#}" | |
| by (cases fs; cases "lead_coeff q = 0"; auto simp: Mp_def) | |
| from uf_q'[unfolded unique_factorization_m_alt_def factorization_m_def split] | |
| have q'_eq: "q' =m smult (lead_coeff q') (prod_mset gs)" by auto | |
| have "degree_m q' = degree q'" | |
| by (rule degree_m_eq[OF _ m1], insert cop_q(2) n p.m1, unfold m, | |
| auto simp:) | |
| with q'_eq have degm_q': "degree q' = degree (Mp (smult (lead_coeff q') (prod_mset gs)))" by auto | |
| with deg have gs_nempty: "gs \<noteq> {#}" | |
| by (cases gs; cases "lead_coeff q' = 0"; auto simp: Mp_def) | |
| from eq have size: "size fs + size gs = size (mset vs)" by auto | |
| with d have choice: "size fs < d \<or> size gs < d" by auto | |
| from choice show False | |
| proof | |
| assume fs: "size fs < d" | |
| from eq have sub: "fs \<subseteq># mset vs" using mset_subset_eq_add_left[of fs gs] by auto | |
| have "test_dvd u fs" | |
| by (rule tests[OF sub fs_nempty, unfolded Nil], insert fs, auto) | |
| from this[unfolded test_dvd_def] uq deg q_eq show False by auto | |
| next | |
| assume gs: "size gs < d" | |
| from eq have sub: "gs \<subseteq># mset vs" using mset_subset_eq_add_left[of fs gs] by auto | |
| have "test_dvd u gs" | |
| by (rule tests[OF sub gs_nempty, unfolded Nil], insert gs, auto) | |
| from this[unfolded test_dvd_def] uq deg q'_eq show False unfolding uq by auto | |
| qed | |
| qed | |
| } note irreducible\<^sub>d_via_tests = this | |
| show ?thesis using assms(1-16) large state | |
| proof (induct meas arbitrary: u lu d r vs res cands state rule: wf_induct[OF wf]) | |
| case (1 meas u lu d r vs res cands state) | |
| note IH = 1(1)[rule_format] | |
| note res = 1(2)[unfolded reconstruction.simps[where cands = cands]] | |
| note f = 1(3) | |
| note meas = 1(4) | |
| note dr = 1(5) | |
| note r = 1(6) | |
| note cands = 1(7) | |
| note d0 = 1(8) | |
| note lu = 1(9) | |
| note factors = 1(10) | |
| note sf = 1(11) | |
| note cop = 1(12) | |
| note norm = 1(13) | |
| note tests = 1(14) | |
| note irr = 1(15) | |
| note deg_u = 1(16) | |
| note cands_empty = 1(17) | |
| note large = 1(18) | |
| note state = 1(19) | |
| from unique_factorization_m_zero[OF factors] | |
| have Mlu0: "M lu \<noteq> 0" by auto | |
| from Mlu0 have lu0: "lu \<noteq> 0" by auto | |
| from this[unfolded lu] have u0: "u \<noteq> 0" by auto | |
| from unique_factorization_m_imp_factorization[OF factors] | |
| have fact: "factorization_m u (lu,mset vs)" by auto | |
| from this[unfolded factorization_m_def split] norm | |
| have vs: "u =m smult lu (prod_list vs)" and | |
| vs_mi: "\<And> f. f\<in>#mset vs \<Longrightarrow> irreducible\<^sub>d_m f \<and> monic f" by auto | |
| let ?luu = "smult lu u" | |
| show ?case | |
| proof (cases cands) | |
| case Nil | |
| note res = res[unfolded this] | |
| let ?d' = "Suc d" | |
| show ?thesis | |
| proof (cases "r < ?d' + ?d'") | |
| case True | |
| with res have fs: "fs = u # res" by (simp add: Let_def) | |
| from True[unfolded r] have size: "size (mset vs) < ?d' + ?d'" by auto | |
| have "irreducible\<^sub>d u" | |
| by (rule irreducible\<^sub>d_via_tests[OF deg_u cop[unfolded lu] factors(1)[unfolded lu] | |
| sf norm size tests], auto simp: Nil) | |
| with fs f irr show ?thesis by simp | |
| next | |
| case False | |
| with dr have dr: "?d' + ?d' \<le> r" and dr': "?d' < r" by auto | |
| obtain state' cands' where sln: "next_subseqs_foldr sl_impl state = (cands',state')" by force | |
| from next_subseqs_foldr[OF sln state] have state': "sli (lu,[]) vs (Suc d) state'" | |
| and cands': "set cands' = S (lu,[]) vs (Suc d)" by auto | |
| let ?new = "subseqs_length mul_const lu ?d' vs" | |
| have R: "((r - Suc d, cands'), meas) \<in> R" unfolding meas R_def using False by auto | |
| from res False sln | |
| have fact: "reconstruction sl_impl m2 state' u ?luu lu ?d' r vs res cands' = fs" by auto | |
| show ?thesis | |
| proof (rule IH[OF R fact f refl dr r _ _ lu factors sf cop norm _ irr deg_u dr' large state'], goal_cases) | |
| case (4 ws) | |
| show ?case | |
| proof (cases "size ws = Suc d") | |
| case False | |
| with 4 have "size ws < Suc d" by auto | |
| thus ?thesis by (intro tests[OF 4(1-2)], unfold Nil, auto) | |
| next | |
| case True | |
| from 4(3)[unfolded cands' mset_snd_S] True 4(1) show ?thesis by auto | |
| qed | |
| qed (auto simp: cands') | |
| qed | |
| next | |
| case (Cons c cds) | |
| with d0 have d0: "d > 0" by auto | |
| obtain lv' ws where c: "c = (lv',ws)" by force | |
| let ?lv = "inv_M lv'" | |
| define vb where "vb \<equiv> inv_Mp (Mp (smult lu (prod_list ws)))" | |
| note res = res[unfolded Cons c list.simps split] | |
| from cands[unfolded Cons c S_def] have ws: "ws \<in> set (subseqs vs)" "length ws = d" | |
| and lv'': "lv' = foldr mul_const ws lu" by auto | |
| from subseqs_sub_mset[OF ws(1)] have ws_vs: "mset ws \<subseteq># mset vs" "set ws \<subseteq> set vs" | |
| using set_mset_mono subseqs_length_simple_False by auto fastforce | |
| have mon_ws: "monic (prod_mset (mset ws))" | |
| by (rule monic_prod_mset, insert ws_vs vs_mi, auto) | |
| have l_ws: "lead_coeff (prod_mset (mset ws)) = 1" using mon_ws . | |
| have lv': "M lv' = M (coeff (smult lu (prod_list ws)) 0)" | |
| unfolding lv'' coeff_smult | |
| by (induct ws arbitrary: lu, auto simp: mul_const_def M_def coeff_mult_0) | |
| (metis mod_mult_right_eq mult.left_commute) | |
| show ?thesis | |
| proof (cases "?lv dvd coeff ?luu 0 \<and> vb dvd ?luu") | |
| case False | |
| have ndvd: "\<not> vb dvd ?luu" | |
| proof | |
| assume dvd: "vb dvd ?luu" | |
| hence "coeff vb 0 dvd coeff ?luu 0" by (metis coeff_mult_0 dvd_def) | |
| with dvd False have "?lv \<noteq> coeff vb 0" by auto | |
| also have "lv' = M lv'" using ws(2) d0 unfolding lv'' | |
| by (cases ws, force, simp add: M_def mul_const_def) | |
| also have "inv_M (M lv') = coeff vb 0" unfolding vb_def inv_Mp_coeff Mp_coeff lv' by simp | |
| finally show False by simp | |
| qed | |
| from False res | |
| have res: "reconstruction sl_impl m2 state u ?luu lu d r vs res cds = fs" | |
| unfolding vb_def Let_def by auto | |
| have R: "((r - d, cds), meas) \<in> R" unfolding meas Cons R_def by auto | |
| from cands have cands: "set cds \<subseteq> S (lu,[]) vs d" | |
| unfolding Cons by auto | |
| show ?thesis | |
| proof (rule IH[OF R res f refl dr r cands _ lu factors sf cop norm _ irr deg_u _ large state], goal_cases) | |
| case (3 ws') | |
| show ?case | |
| proof (cases "ws' = mset ws") | |
| case False | |
| show ?thesis | |
| by (rule tests[OF 3(1-2)], insert 3(3) False, force simp: Cons c) | |
| next | |
| case True | |
| have test: "test_dvd_exec lu u ws'" | |
| unfolding True test_dvd_exec_def using ndvd unfolding vb_def by simp | |
| show ?thesis unfolding test_dvd_def | |
| proof (intro allI impI notI, goal_cases) | |
| case (1 v l) | |
| note deg_v = 1(2-3) | |
| from 1(1) obtain w where u: "u = v * w" unfolding dvd_def by auto | |
| from u0 have deg: "degree u = degree v + degree w" unfolding u | |
| by (subst degree_mult_eq, auto) | |
| define v' where "v' = smult (lead_coeff w) v" | |
| define w' where "w' = smult (lead_coeff v) w" | |
| let ?ws = "smult (lead_coeff w * l) (prod_mset ws')" | |
| from arg_cong[OF 1(4), of "\<lambda> f. Mp (smult (lead_coeff w) f)"] | |
| have v'_ws': "Mp v' = Mp ?ws" unfolding v'_def | |
| by simp | |
| from lead_coeff_factor[OF u, folded v'_def w'_def] | |
| have prod: "?luu = v' * w'" and lc: "lead_coeff v' = lu" and "lead_coeff w' = lu" | |
| unfolding lu by auto | |
| with lu0 have lc0: "lead_coeff v \<noteq> 0" "lead_coeff w \<noteq> 0" unfolding v'_def w'_def by auto | |
| from deg_v have deg_w: "0 < degree w" "degree w < degree u" unfolding deg by auto | |
| from deg_v deg_w lc0 | |
| have deg: "0 < degree v'" "degree v' < degree u" "0 < degree w'" "degree w' < degree u" | |
| unfolding v'_def w'_def by auto | |
| from prod have v_dvd: "v' dvd ?luu" by auto | |
| with test[unfolded test_dvd_exec_def] | |
| have neq: "v' \<noteq> inv_Mp (Mp (smult lu (prod_mset ws')))" by auto | |
| have deg_m_v': "degree_m v' = degree v'" | |
| by (rule degree_m_eq[OF _ m1], unfold lc m, | |
| insert cop prime n coprime_exp_mod, auto) | |
| with v'_ws' have "degree v' = degree_m ?ws" by simp | |
| also have "\<dots> \<le> degree_m (prod_mset ws')" by (rule degree_m_smult_le) | |
| also have "\<dots> = degree_m (prod_list ws)" unfolding True by simp | |
| also have "\<dots> \<le> degree (prod_list ws)" by (rule degree_m_le) | |
| also have "\<dots> \<le> degree_bound vs" | |
| using ws_vs(1) ws(2) dr[unfolded r] degree_bound by auto | |
| finally have "degree v' \<le> degree_bound vs" . | |
| from inv_Mp_rev[OF large[unfolded large_m_def, rule_format, OF v_dvd this]] | |
| have inv: "inv_Mp (Mp v') = v'" by simp | |
| from arg_cong[OF v'_ws', of inv_Mp, unfolded inv] | |
| have v': "v' = inv_Mp (Mp ?ws)" by auto | |
| have deg_ws: "degree_m ?ws = degree ?ws" | |
| proof (rule degree_m_eq[OF _ m1], | |
| unfold lead_coeff_smult True l_ws, rule) | |
| assume "lead_coeff w * l * 1 mod m = 0" | |
| hence 0: "M (lead_coeff w * l) = 0" unfolding M_def by simp | |
| have "Mp ?ws = Mp (smult (M (lead_coeff w * l)) (prod_mset ws'))" by simp | |
| also have "\<dots> = 0" unfolding 0 by simp | |
| finally have "Mp ?ws = 0" by simp | |
| hence "v' = 0" unfolding v' by (simp add: inv_Mp_def) | |
| with deg show False by auto | |
| qed | |
| from arg_cong[OF v', of "\<lambda> f. lead_coeff (Mp f)", simplified] | |
| have "M lu = M (lead_coeff v')" using lc by simp | |
| also have "\<dots> = lead_coeff (Mp v')" | |
| by (rule degree_m_eq_lead_coeff[OF deg_m_v', symmetric]) | |
| also have "\<dots> = lead_coeff (Mp ?ws)" | |
| using arg_cong[OF v', of "\<lambda> f. lead_coeff (Mp f)"] by simp | |
| also have "\<dots> = M (lead_coeff ?ws)" | |
| by (rule degree_m_eq_lead_coeff[OF deg_ws]) | |
| also have "\<dots> = M (lead_coeff w * l)" unfolding lead_coeff_smult True l_ws by simp | |
| finally have id: "M lu = M (lead_coeff w * l)" . | |
| note v' | |
| also have "Mp ?ws = Mp (smult (M (lead_coeff w * l)) (prod_mset ws'))" by simp | |
| also have "\<dots> = Mp (smult lu (prod_mset ws'))" unfolding id[symmetric] by simp | |
| finally show False using neq by simp | |
| qed | |
| qed | |
| qed (insert d0 Cons cands_empty, auto) | |
| next | |
| case True | |
| define pp_vb where "pp_vb \<equiv> primitive_part vb" | |
| define u' where "u' \<equiv> u div pp_vb" | |
| define lu' where "lu' \<equiv> lead_coeff u'" | |
| let ?luu' = "smult lu' u'" | |
| define vs' where "vs' \<equiv> fold remove1 ws vs" | |
| obtain state' cands' where slc: "subseqs_foldr sl_impl (lu',[]) vs' d = (cands', state')" by force | |
| from subseqs_foldr[OF slc] have state': "sli (lu',[]) vs' d state'" | |
| and cands': "set cands' = S (lu',[]) vs' d" by auto | |
| let ?res' = "pp_vb # res" | |
| let ?r' = "r - length ws" | |
| note defs = vb_def pp_vb_def u'_def lu'_def vs'_def slc | |
| from fold_remove1_mset[OF subseqs_sub_mset[OF ws(1)]] | |
| have vs_split: "mset vs = mset vs' + mset ws" unfolding vs'_def by auto | |
| hence vs'_diff: "mset vs' = mset vs - mset ws" and ws_sub: "mset ws \<subseteq># mset vs" by auto | |
| from arg_cong[OF vs_split, of size] | |
| have r': "?r' = length vs'" unfolding defs r by simp | |
| from arg_cong[OF vs_split, of prod_mset] | |
| have prod_vs: "prod_list vs = prod_list vs' * prod_list ws" by simp | |
| from arg_cong[OF vs_split, of set_mset] have set_vs: "set vs = set vs' \<union> set ws" by auto | |
| note inv = inverse_mod_coprime_exp[OF m prime n] | |
| note p_inv = p.inverse_mod_coprime[OF prime] | |
| from True res slc | |
| have res: "(if ?r' < d + d then u' # ?res' else reconstruction sl_impl m2 state' | |
| u' ?luu' lu' d ?r' vs' ?res' cands') = fs" | |
| unfolding Let_def defs by auto | |
| from True have dvd: "vb dvd ?luu" by simp | |
| from dvd_smult_int[OF lu0 this] have ppu: "pp_vb dvd u" unfolding defs by simp | |
| hence u: "u = pp_vb * u'" unfolding u'_def | |
| by (metis dvdE mult_eq_0_iff nonzero_mult_div_cancel_left) | |
| hence uu': "u' dvd u" unfolding dvd_def by auto | |
| have f: "f = u' * prod_list ?res'" using f u by auto | |
| let ?fact = "smult lu (prod_mset (mset ws))" | |
| have Mp_vb: "Mp vb = Mp (smult lu (prod_list ws))" unfolding vb_def by simp | |
| have pp_vb_vb: "smult (content vb) pp_vb = vb" unfolding pp_vb_def by (rule content_times_primitive_part) | |
| { | |
| have "smult (content vb) u = (smult (content vb) pp_vb) * u'" unfolding u by simp | |
| also have "smult (content vb) pp_vb = vb" by fact | |
| finally have "smult (content vb) u = vb * u'" by simp | |
| from arg_cong[OF this, of Mp] | |
| have "Mp (Mp vb * u') = Mp (smult (content vb) u)" by simp | |
| hence "Mp (smult (content vb) u) = Mp (?fact * u')" unfolding Mp_vb by simp | |
| } note prod = this | |
| from arg_cong[OF this, of p.Mp] | |
| have prod': "p.Mp (smult (content vb) u) = p.Mp (?fact * u')" by simp | |
| from dvd have "lead_coeff vb dvd lead_coeff (smult lu u)" | |
| by (metis dvd_def lead_coeff_mult) | |
| hence ldvd: "lead_coeff vb dvd lu * lu" unfolding lead_coeff_smult lu by simp | |
| from cop have cop_lu: "coprime (lu * lu) p" | |
| by simp | |
| from coprime_divisors [OF ldvd dvd_refl] cop_lu | |
| have cop_lvb: "coprime (lead_coeff vb) p" by simp | |
| then have cop_vb: "coprime (content vb) p" | |
| by (auto intro: coprime_divisors[OF content_dvd_coeff dvd_refl]) | |
| from u have "u' dvd u" unfolding dvd_def by auto | |
| hence "lead_coeff u' dvd lu" unfolding lu by (metis dvd_def lead_coeff_mult) | |
| from coprime_divisors[OF this dvd_refl] cop | |
| have "coprime (lead_coeff u') p" by simp | |
| hence "coprime (lu * lead_coeff u') p" and cop_lu': "coprime lu' p" | |
| using cop by (auto simp: lu'_def) | |
| hence cop': "coprime (lead_coeff (?fact * u')) p" | |
| unfolding lead_coeff_mult lead_coeff_smult l_ws by simp | |
| have "p.square_free_m (smult (content vb) u)" using cop_vb sf p_inv | |
| by (auto intro!: p.square_free_m_smultI) | |
| from p.square_free_m_cong[OF this prod'] | |
| have sf': "p.square_free_m (?fact * u')" by simp | |
| from p.square_free_m_factor[OF this] | |
| have sf_u': "p.square_free_m u'" by simp | |
| have "unique_factorization_m (smult (content vb) u) (lu * content vb, mset vs)" | |
| using cop_vb factors inv by (auto intro: unique_factorization_m_smult) | |
| from unique_factorization_m_cong[OF this prod] | |
| have uf: "unique_factorization_m (?fact * u') (lu * content vb, mset vs)" . | |
| { | |
| from unique_factorization_m_factor[OF prime uf cop' sf' n m] | |
| obtain fs gs where uf1: "unique_factorization_m ?fact (lu, fs)" | |
| and uf2: "unique_factorization_m u' (lu', gs)" | |
| and eq: "Mf (lu * content vb, mset vs) = Mf (lu * lead_coeff u', fs + gs)" | |
| unfolding lead_coeff_smult l_ws lu'_def | |
| by auto | |
| have "factorization_m ?fact (lu, mset ws)" | |
| unfolding factorization_m_def split using set_vs vs_mi norm by auto | |
| with uf1[unfolded unique_factorization_m_alt_def] have "Mf (lu,mset ws) = Mf (lu, fs)" | |
| by blast | |
| hence fs_ws: "image_mset Mp fs = image_mset Mp (mset ws)" unfolding Mf_def split by auto | |
| from eq[unfolded Mf_def split] | |
| have "image_mset Mp (mset vs) = image_mset Mp fs + image_mset Mp gs" by auto | |
| from this[unfolded fs_ws vs_split] have gs: "image_mset Mp gs = image_mset Mp (mset vs')" | |
| by (simp add: ac_simps) | |
| from uf1 have uf1: "unique_factorization_m ?fact (lu, mset ws)" | |
| unfolding unique_factorization_m_def Mf_def split fs_ws by simp | |
| from uf2 have uf2: "unique_factorization_m u' (lu', mset vs')" | |
| unfolding unique_factorization_m_def Mf_def split gs by simp | |
| note uf1 uf2 | |
| } | |
| hence factors: "unique_factorization_m u' (lu', mset vs')" | |
| "unique_factorization_m ?fact (lu, mset ws)" by auto | |
| have lu': "lu' = lead_coeff u'" unfolding lu'_def by simp | |
| have vb0: "vb \<noteq> 0" using dvd lu0 u0 by auto | |
| from ws(2) have size_ws: "size (mset ws) = d" by auto | |
| with d0 have size_ws0: "size (mset ws) \<noteq> 0" by auto | |
| then obtain w ws' where ws_w: "ws = w # ws'" by (cases ws, auto) | |
| from Mp_vb have Mp_vb': "Mp vb = Mp (smult lu (prod_mset (mset ws)))" by auto | |
| have deg_vb: "degree vb > 0" | |
| by (rule deg_non_zero[OF Mp_vb' cop size_ws0 vs_mi], insert vs_split, auto) | |
| also have "degree vb = degree pp_vb" using arg_cong[OF pp_vb_vb, of degree] | |
| unfolding degree_smult_eq using vb0 by auto | |
| finally have deg_pp: "degree pp_vb > 0" by auto | |
| hence pp_vb0: "pp_vb \<noteq> 0" by auto | |
| from factors(1)[unfolded unique_factorization_m_alt_def factorization_m_def] | |
| have eq_u': "Mp u' = Mp (smult lu' (prod_mset (mset vs')))" by auto | |
| from r'[unfolded ws(2)] dr have "length vs' + d = r" by auto | |
| from this cands_empty[unfolded Cons] have "size (mset vs') \<noteq> 0" by auto | |
| from deg_non_zero[OF eq_u' cop_lu' this vs_mi] | |
| have deg_u': "degree u' > 0" unfolding vs_split by auto | |
| have irr_pp: "irreducible\<^sub>d pp_vb" | |
| proof (rule irreducible\<^sub>dI[OF deg_pp]) | |
| fix q r :: "int poly" | |
| assume deg_q: "degree q > 0" "degree q < degree pp_vb" | |
| and deg_r: "degree r > 0" "degree r < degree pp_vb" | |
| and pp_qr: "pp_vb = q * r" | |
| then have qvb: "q dvd pp_vb" by auto | |
| from dvd_trans[OF qvb ppu] have qu: "q dvd u" . | |
| have "degree pp_vb = degree q + degree r" unfolding pp_qr | |
| by (subst degree_mult_eq, insert pp_qr pp_vb0, auto) | |
| have uf: "unique_factorization_m (smult (content vb) pp_vb) (lu, mset ws)" | |
| unfolding pp_vb_vb | |
| by (rule unique_factorization_m_cong[OF factors(2)], insert Mp_vb, auto) | |
| from unique_factorization_m_smultD[OF uf inv] cop_vb | |
| have uf: "unique_factorization_m pp_vb (lu * inverse_mod (content vb) m, mset ws)" by auto | |
| from ppu have "lead_coeff pp_vb dvd lu" unfolding lu by (metis dvd_def lead_coeff_mult) | |
| from coprime_divisors[OF this dvd_refl] cop | |
| have cop_pp: "coprime (lead_coeff pp_vb) p" by simp | |
| from coprime_lead_coeff_factor[OF prime cop_pp[unfolded pp_qr]] | |
| have cop_qr: "coprime (lead_coeff q) p" "coprime (lead_coeff r) p" by auto | |
| from p.square_free_m_factor[OF sf[unfolded u]] | |
| have sf_pp: "p.square_free_m pp_vb" by simp | |
| from unique_factorization_m_factor[OF prime uf[unfolded pp_qr] _ _ n m, | |
| folded pp_qr, OF cop_pp sf_pp] | |
| obtain fs gs l where uf_q: "unique_factorization_m q (lead_coeff q, fs)" | |
| and uf_r: "unique_factorization_m r (lead_coeff r, gs)" | |
| and Mf_eq: "Mf (l, mset ws) = Mf (lead_coeff q * lead_coeff r, fs + gs)" | |
| and fs_id: "image_mset Mp fs = fs" | |
| and gs_id: "image_mset Mp gs = gs" by auto | |
| from Mf_eq have "image_mset Mp (mset ws) = image_mset Mp fs + image_mset Mp gs" | |
| unfolding Mf_def by auto | |
| also have "image_mset Mp (mset ws) = mset ws" using norm ws_vs(2) by (induct ws, auto) | |
| finally have eq: "mset ws = image_mset Mp fs + image_mset Mp gs" by simp | |
| from arg_cong[OF this, of size, unfolded size_ws] have size: "size fs + size gs = d" by auto | |
| from uf_q[unfolded unique_factorization_m_alt_def factorization_m_def split] | |
| have q_eq: "q =m smult (lead_coeff q) (prod_mset fs)" by auto | |
| have "degree_m q = degree q" | |
| by (rule degree_m_eq[OF _ m1], insert cop_qr(1) n p.m1, unfold m, | |
| auto simp:) | |
| with q_eq have degm_q: "degree q = degree (Mp (smult (lead_coeff q) (prod_mset fs)))" by auto | |
| with deg_q have fs_nempty: "fs \<noteq> {#}" | |
| by (cases fs; cases "lead_coeff q = 0"; auto simp: Mp_def) | |
| from uf_r[unfolded unique_factorization_m_alt_def factorization_m_def split] | |
| have r_eq: "r =m smult (lead_coeff r) (prod_mset gs)" by auto | |
| have "degree_m r = degree r" | |
| by (rule degree_m_eq[OF _ m1], insert cop_qr(2) n p.m1, unfold m, | |
| auto simp:) | |
| with r_eq have degm_r: "degree r = degree (Mp (smult (lead_coeff r) (prod_mset gs)))" by auto | |
| with deg_r have gs_nempty: "gs \<noteq> {#}" | |
| by (cases gs; cases "lead_coeff r = 0"; auto simp: Mp_def) | |
| from gs_nempty have "size gs \<noteq> 0" by auto | |
| with size have size_fs: "size fs < d" by linarith | |
| note * = tests[unfolded test_dvd_def, rule_format, OF _ fs_nempty _ qu, of "lead_coeff q"] | |
| from ppu have "degree pp_vb \<le> degree u" | |
| using dvd_imp_degree_le u0 by blast | |
| with deg_q q_eq size_fs | |
| have "\<not> fs \<subseteq># mset vs" by (auto dest!:*) | |
| thus False unfolding vs_split eq fs_id gs_id using mset_subset_eq_add_left[of fs "mset vs' + gs"] | |
| by (auto simp: ac_simps) | |
| qed | |
| { | |
| fix ws' | |
| assume *: "ws' \<subseteq># mset vs'" "ws' \<noteq> {#}" | |
| "size ws' < d \<or> size ws' = d \<and> ws' \<notin> (mset \<circ> snd) ` set cands'" | |
| from *(1) have "ws' \<subseteq># mset vs" unfolding vs_split | |
| by (simp add: subset_mset.add_increasing2) | |
| from tests[OF this *(2)] *(3)[unfolded cands' mset_snd_S] *(1) | |
| have "test_dvd u ws'" by auto | |
| from test_dvd_factor[OF u0 this[unfolded lu] uu'] | |
| have "test_dvd u' ws'" . | |
| } note tests' = this | |
| show ?thesis | |
| proof (cases "?r' < d + d") | |
| case True | |
| with res have res: "fs = u' # ?res'" by auto | |
| from True r' have size: "size (mset vs') < d + d" by auto | |
| have "irreducible\<^sub>d u'" | |
| by (rule irreducible\<^sub>d_via_tests[OF deg_u' cop_lu'[unfolded lu'] factors(1)[unfolded lu'] | |
| sf_u' norm size tests'], insert set_vs, auto) | |
| with f res irr irr_pp show ?thesis by auto | |
| next | |
| case False | |
| have res: "reconstruction sl_impl m2 state' u' ?luu' lu' d ?r' vs' ?res' cands' = fs" | |
| using False res by auto | |
| from False have dr: "d + d \<le> ?r'" by auto | |
| from False dr r r' d0 ws Cons have le: "?r' - d < r - d" by (cases ws, auto) | |
| hence R: "((?r' - d, cands'), meas) \<in> R" unfolding meas R_def by simp | |
| have dr': "d < ?r'" using le False ws(2) by linarith | |
| have luu': "lu' dvd lu" using \<open>lead_coeff u' dvd lu\<close> unfolding lu' . | |
| have "large_m (smult lu' u') vs" | |
| by (rule large_m_factor[OF large dvd_dvd_smult], insert uu' luu') | |
| moreover have "degree_bound vs' \<le> degree_bound vs" | |
| unfolding vs'_def degree_bound_def by (rule max_factor_degree_mono) | |
| ultimately have large': "large_m (smult lu' u') vs'" unfolding large_m_def by auto | |
| show ?thesis | |
| by (rule IH[OF R res f refl dr r' _ _ lu' factors(1) sf_u' cop_lu' norm tests' _ deg_u' | |
| dr' large' state'], insert irr irr_pp d0 Cons set_vs, auto simp: cands') | |
| qed | |
| qed | |
| qed | |
| qed | |
| qed | |
| end | |
| end | |
| (* select implementation of subseqs *) | |
| definition zassenhaus_reconstruction :: | |
| "int poly list \<Rightarrow> int \<Rightarrow> nat \<Rightarrow> int poly \<Rightarrow> int poly list" where | |
| "zassenhaus_reconstruction vs p n f = (let | |
| mul = poly_mod.mul_const (p^n); | |
| sl_impl = my_subseqs.impl (\<lambda>x. map_prod (mul x) (Cons x)) | |
| in zassenhaus_reconstruction_generic sl_impl vs p n f)" | |
| context | |
| fixes p n f hs | |
| assumes prime: "prime p" | |
| and cop: "coprime (lead_coeff f) p" | |
| and sf: "poly_mod.square_free_m p f" | |
| and deg: "degree f > 0" | |
| and bh: "berlekamp_hensel p n f = hs" | |
| and bnd: "2 * \<bar>lead_coeff f\<bar> * factor_bound f (degree_bound hs) < p ^ n" | |
| begin | |
| private lemma n: "n \<noteq> 0" | |
| proof | |
| assume n: "n = 0" | |
| hence pn: "p^n = 1" by auto | |
| let ?f = "smult (lead_coeff f) f" | |
| let ?d = "degree_bound hs" | |
| have f: "f \<noteq> 0" using deg by auto | |
| hence "lead_coeff f \<noteq> 0" by auto | |
| hence lf: "abs (lead_coeff f) > 0" by auto | |
| obtain c d where c: "factor_bound f (degree_bound hs) = c" "abs (lead_coeff f) = d" by auto | |
| { | |
| assume *: "1 \<le> c" "2 * d * c < 1" "0 < d" | |
| hence "1 \<le> d" by auto | |
| from mult_mono[OF this *(1)] * have "1 \<le> d * c" by auto | |
| hence "2 * d * c \<ge> 2" by auto | |
| with * have False by auto | |
| } note tedious = this | |
| have "1 \<le> factor_bound f ?d" | |
| using factor_bound[OF f, of 1 ?d 0] by auto | |
| also have "\<dots> = 0" using bnd unfolding pn | |
| using factor_bound_ge_0[of f "degree_bound hs", OF f] lf unfolding c | |
| by (cases "c \<ge> 1"; insert tedious, auto) | |
| finally show False by simp | |
| qed | |
| interpretation p: poly_mod_prime p using prime by unfold_locales | |
| lemma zassenhaus_reconstruction_generic: | |
| assumes sl_impl: "correct_subseqs_foldr_impl (\<lambda>v. map_prod (poly_mod.mul_const (p^n) v) (Cons v)) sl_impl sli" | |
| and res: "zassenhaus_reconstruction_generic sl_impl hs p n f = fs" | |
| shows "f = prod_list fs \<and> (\<forall> fi \<in> set fs. irreducible\<^sub>d fi)" | |
| proof - | |
| let ?lc = "lead_coeff f" | |
| let ?ff = "smult ?lc f" | |
| let ?q = "p^n" | |
| have p1: "p > 1" using prime unfolding prime_int_iff by simp | |
| interpret poly_mod_2 "p^n" using p1 n unfolding poly_mod_2_def by simp | |
| obtain cands state where slc: "subseqs_foldr sl_impl (lead_coeff f, []) hs 0 = (cands, state)" by force | |
| interpret correct_subseqs_foldr_impl "\<lambda>x. map_prod (mul_const x) (Cons x)" sl_impl sli by fact | |
| from subseqs_foldr[OF slc] have state: "sli (lead_coeff f, []) hs 0 state" by auto | |
| from res[unfolded zassenhaus_reconstruction_generic_def bh split Let_def slc fst_conv] | |
| have res: "reconstruction sl_impl (?q div 2) state f ?ff ?lc 0 (length hs) hs [] [] = fs" by auto | |
| from p.berlekamp_hensel_unique[OF cop sf bh n] | |
| have ufact: "unique_factorization_m f (?lc, mset hs)" by simp | |
| note bh = p.berlekamp_hensel[OF cop sf bh n] | |
| from deg have f0: "f \<noteq> 0" and lf0: "?lc \<noteq> 0" by auto | |
| hence ff0: "?ff \<noteq> 0" by auto | |
| have bnd: "\<forall>g k. g dvd ?ff \<longrightarrow> degree g \<le> degree_bound hs \<longrightarrow> 2 * \<bar>coeff g k\<bar> < p ^ n" | |
| proof (intro allI impI, goal_cases) | |
| case (1 g k) | |
| from factor_bound_smult[OF f0 lf0 1, of k] | |
| have "\<bar>coeff g k\<bar> \<le> \<bar>?lc\<bar> * factor_bound f (degree_bound hs)" . | |
| hence "2 * \<bar>coeff g k\<bar> \<le> 2 * \<bar>?lc\<bar> * factor_bound f (degree_bound hs)" by auto | |
| also have "\<dots> < p^n" using bnd . | |
| finally show ?case . | |
| qed | |
| note bh' = bh[unfolded factorization_m_def split] | |
| have deg_f: "degree_m f = degree f" | |
| using cop unique_factorization_m_zero [OF ufact] n | |
| by (auto simp add: M_def intro: degree_m_eq [OF _ m1]) | |
| have mon_hs: "monic (prod_list hs)" using bh' by (auto intro: monic_prod_list) | |
| have Mlc: "M ?lc \<in> {1 ..< p^n}" | |
| by (rule prime_cop_exp_poly_mod[OF prime cop n]) | |
| hence "?lc \<noteq> 0" by auto | |
| hence f0: "f \<noteq> 0" by auto | |
| have degm: "degree_m (smult ?lc (prod_list hs)) = degree (smult ?lc (prod_list hs))" | |
| by (rule degree_m_eq[OF _ m1], insert n bh mon_hs Mlc, auto simp: M_def) | |
| from reconstruction[OF prime refl n sl_impl res _ refl _ refl _ refl refl ufact sf | |
| cop _ _ _ deg _ bnd f0] bh(2) state | |
| show ?thesis by simp | |
| qed | |
| lemma zassenhaus_reconstruction_irreducible\<^sub>d: | |
| assumes res: "zassenhaus_reconstruction hs p n f = fs" | |
| shows "f = prod_list fs \<and> (\<forall> fi \<in> set fs. irreducible\<^sub>d fi)" | |
| by (rule zassenhaus_reconstruction_generic[OF my_subseqs.impl_correct | |
| res[unfolded zassenhaus_reconstruction_def Let_def]]) | |
| corollary zassenhaus_reconstruction: | |
| assumes pr: "primitive f" | |
| assumes res: "zassenhaus_reconstruction hs p n f = fs" | |
| shows "f = prod_list fs \<and> (\<forall> fi \<in> set fs. irreducible fi)" | |
| using zassenhaus_reconstruction_irreducible\<^sub>d[OF res] pr | |
| irreducible_primitive_connect[OF primitive_prod_list] | |
| by auto | |
| end | |
| end | |