| Quellcodebibliothek Statistik Leitseite products/Sources/formale Sprachen/Isabelle/HOL/ (Beweissystem Isabelle Version 2025-1©) Datei vom 16.11.2025 mit Größe 93 kB |
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Quelle Euclidean_Rings.thy Sprache: Isabelle |
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(* Title: HOL/Euclidean_Rgins.thy Author: Manuel Eberl, TU Muenchen Author: Florian Haftmann, TU Muenchen *) section ‹Division in euclidean (semi)rings› theory Euclidean_Rings imports Int Lattices_Big begin subsection ‹Euclidean (semi)rings with explicit division and remainder› class euclidean_semiring = semidom_modulo + fixes euclidean_size :: "'a \ assumes size_0 [simp]: "euclidean_size 0 = 0" assumes mod_size_less: "b \ assumes size_mult_mono: "b \ begin lemma euclidean_size_eq_0_iff [simp]: "euclidean_size b = 0 \ proof assume "b = 0" then show "euclidean_size b = 0" by simp next assume "euclidean_size b = 0" show "b = 0" proof (rule ccontr) assume "b \ with mod_size_less have "euclidean_size (b mod b) < euclidean_size b" . with ‹euclidean_size b = 0› show False by simp qed qed lemma euclidean_size_greater_0_iff [simp]: "euclidean_size b > 0 \ using euclidean_size_eq_0_iff [symmetric, of b] by safe simp lemma size_mult_mono': "b \ by (subst mult.commute) (rule size_mult_mono) lemma dvd_euclidean_size_eq_imp_dvd: assumes "a \ and "b dvd a" shows "a dvd b" proof (rule ccontr) assume "\ hence "b mod a \ then have "b mod a \ from ‹b dvd a› have "b dvd b mod a" by (simp add: dvd_mod_iff) then obtain c where "b mod a = b * c" unfolding dvd_def by blast with ‹b mod a ≠ 0› have "c \ with ‹b mod a = b * c› have "euclidean_size (b mod a) \ using size_mult_mono by force moreover from ‹¬ a dvd b› and ‹a ≠ 0› have "euclidean_size (b mod a) < euclidean_size a" using mod_size_less by blast ultimately show False using ‹euclidean_size a = euclidean_size b› by simp qed lemma euclidean_size_times_unit: assumes "is_unit a" shows "euclidean_size (a * b) = euclidean_size b" proof (rule antisym) from assms have [simp]: "a \ thus "euclidean_size (a * b) \ from assms have "is_unit (1 div a)" by simp hence "1 div a \ hence "euclidean_size (a * b) \ by (rule size_mult_mono') also from assms have "(1 div a) * (a * b) = b" by (simp add: algebra_simps unit_div_mult_swap) finally show "euclidean_size (a * b) \ qed lemma euclidean_size_unit: "is_unit a \ using euclidean_size_times_unit [of a 1] by simp lemma unit_iff_euclidean_size: "is_unit a \ proof safe assume A: "a \ show "is_unit a" by (rule dvd_euclidean_size_eq_imp_dvd [OF A B]) simp_all qed (auto intro: euclidean_size_unit) lemma euclidean_size_times_nonunit: assumes "a \ shows "euclidean_size b < euclidean_size (a * b)" proof (rule ccontr) assume "\ with size_mult_mono'[OF assms(1), of b] have eq: "euclidean_size (a * b) = euclidean_size b" by simp have "a * b dvd b" by (rule dvd_euclidean_size_eq_imp_dvd [OF _ eq]) (use assms in simp_all) hence "a * b dvd 1 * b" by simp with ‹b ≠ 0› have "is_unit a" by (subst (asm) dvd_times_right_cancel_iff) with assms(3) show False by contradiction qed lemma dvd_imp_size_le: assumes "a dvd b" "b \ shows "euclidean_size a \ using assms by (auto simp: size_mult_mono) lemma dvd_proper_imp_size_less: assumes "a dvd b" "\ shows "euclidean_size a < euclidean_size b" proof - from assms(1) obtain c where "b = a * c" by (erule dvdE) hence z: "b = c * a" by (simp add: mult.commute) from z assms have "\ with z assms show ?thesis by (auto intro!: euclidean_size_times_nonunit) qed lemma unit_imp_mod_eq_0: "a mod b = 0" if "is_unit b" using that by (simp add: mod_eq_0_iff_dvd unit_imp_dvd) lemma mod_eq_self_iff_div_eq_0: "a mod b = a \ proof assume ?P with div_mult_mod_eq [of a b] show ?Q by auto next assume ?Q with div_mult_mod_eq [of a b] show ?P by simp qed lemma coprime_mod_left_iff [simp]: "coprime (a mod b) b \ by (rule iffI; rule coprimeI) (use that in ‹auto dest!: dvd_mod_imp_dvd coprime_common_divisor simp add: dvd_mod_iff›) lemma coprime_mod_right_iff [simp]: "coprime a (b mod a) \ using that coprime_mod_left_iff [of a b] by (simp add: ac_simps) end class euclidean_ring = idom_modulo + euclidean_semiring begin lemma dvd_diff_commute [ac_simps]: "a dvd c - b \ proof - have "a dvd c - b \ by (subst dvd_mult_unit_iff) simp_all then show ?thesis by simp qed end subsection ‹Euclidean (semi)rings with cancel rules› class euclidean_semiring_cancel = euclidean_semiring + assumes div_mult_self1 [simp]: "b \ and div_mult_mult1 [simp]: "c \ begin lemma div_mult_self2 [simp]: assumes "b \ shows "(a + b * c) div b = c + a div b" using assms div_mult_self1 [of b a c] by (simp add: mult.commute) lemma div_mult_self3 [simp]: assumes "b \ shows "(c * b + a) div b = c + a div b" using assms by (simp add: add.commute) lemma div_mult_self4 [simp]: assumes "b \ shows "(b * c + a) div b = c + a div b" using assms by (simp add: add.commute) lemma mod_mult_self1 [simp]: "(a + c * b) mod b = a mod b" proof (cases "b = 0") case True then show ?thesis by simp next case False have "a + c * b = (a + c * b) div b * b + (a + c * b) mod b" by (simp add: div_mult_mod_eq) also from False div_mult_self1 [of b a c] have "\ by (simp add: algebra_simps) finally have "a = a div b * b + (a + c * b) mod b" by (simp add: add.commute [of a] add.assoc distrib_right) then have "a div b * b + (a + c * b) mod b = a div b * b + a mod b" by (simp add: div_mult_mod_eq) then show ?thesis by simp qed lemma mod_mult_self2 [simp]: "(a + b * c) mod b = a mod b" by (simp add: mult.commute [of b]) lemma mod_mult_self3 [simp]: "(c * b + a) mod b = a mod b" by (simp add: add.commute) lemma mod_mult_self4 [simp]: "(b * c + a) mod b = a mod b" by (simp add: add.commute) lemma mod_mult_self1_is_0 [simp]: "b * a mod b = 0" using mod_mult_self2 [of 0 b a] by simp lemma mod_mult_self2_is_0 [simp]: "a * b mod b = 0" using mod_mult_self1 [of 0 a b] by simp lemma div_add_self1: assumes "b \ shows "(b + a) div b = a div b + 1" using assms div_mult_self1 [of b a 1] by (simp add: add.commute) lemma div_add_self2: assumes "b \ shows "(a + b) div b = a div b + 1" using assms div_add_self1 [of b a] by (simp add: add.commute) lemma mod_add_self1 [simp]: "(b + a) mod b = a mod b" using mod_mult_self1 [of a 1 b] by (simp add: add.commute) lemma mod_add_self2 [simp]: "(a + b) mod b = a mod b" using mod_mult_self1 [of a 1 b] by simp lemma mod_div_trivial [simp]: "a mod b div b = 0" proof (cases "b = 0") assume "b = 0" thus ?thesis by simp next assume "b \ hence "a div b + a mod b div b = (a mod b + a div b * b) div b" by (rule div_mult_self1 [symmetric]) also have "\ by (simp only: mod_div_mult_eq) also have "\ by simp finally show ?thesis by (rule add_left_imp_eq) qed lemma mod_mod_trivial [simp]: "a mod b mod b = a mod b" proof - have "a mod b mod b = (a mod b + a div b * b) mod b" by (simp only: mod_mult_self1) also have "\ by (simp only: mod_div_mult_eq) finally show ?thesis . qed lemma mod_mod_cancel: assumes "c dvd b" shows "a mod b mod c = a mod c" proof - from ‹c dvd b› obtain k where "b = c * k" by (rule dvdE) have "a mod b mod c = a mod (c * k) mod c" by (simp only: ‹b = c * k›) also have "\ by (simp only: mod_mult_self1) also have "\ by (simp only: ac_simps) also have "\ by (simp only: div_mult_mod_eq) finally show ?thesis . qed lemma div_mult_mult2 [simp]: "c \ by (drule div_mult_mult1) (simp add: mult.commute) lemma div_mult_mult1_if [simp]: "(c * a) div (c * b) = (if c = 0 then 0 else a div b)" by simp_all lemma mod_mult_mult1: "(c * a) mod (c * b) = c * (a mod b)" proof (cases "c = 0") case True then show ?thesis by simp next case False from div_mult_mod_eq have "((c * a) div (c * b)) * (c * b) + (c * a) mod (c * b) = c * a" . with False have "c * ((a div b) * b + a mod b) + (c * a) mod (c * b) = c * a + c * (a mod b)" by (simp add: algebra_simps) with div_mult_mod_eq show ?thesis by simp qed lemma mod_mult_mult2: "(a * c) mod (b * c) = (a mod b) * c" using mod_mult_mult1 [of c a b] by (simp add: mult.commute) lemma mult_mod_left: "(a mod b) * c = (a * c) mod (b * c)" by (fact mod_mult_mult2 [symmetric]) lemma mult_mod_right: "c * (a mod b) = (c * a) mod (c * b)" by (fact mod_mult_mult1 [symmetric]) lemma dvd_mod: "k dvd m \ unfolding dvd_def by (auto simp add: mod_mult_mult1) lemma div_plus_div_distrib_dvd_left: "c dvd a \ by (cases "c = 0") auto lemma div_plus_div_distrib_dvd_right: "c dvd b \ using div_plus_div_distrib_dvd_left [of c b a] by (simp add: ac_simps) lemma sum_div_partition: ‹(∑a∈A. f a) div b = (∑a∈A ∩ {a. b dvd f a}. f a div b) + (∑a∈A ∩ {a. ¬ b dvd f a}. f a) div b› if ‹finite A› proof - have ‹A = A ∩ {a. b dvd f a} ∪ A ∩ {a. ¬ b dvd f a}› by auto then have ‹(∑a∈A. f a) = (∑a∈A ∩ {a. b dvd f a} ∪ A ∩ {a. ¬ b dvd f a}. f a)› by simp also have ‹… = (∑a∈A ∩ {a. b dvd f a}. f a) + (∑a∈A ∩ {a. ¬ b dvd f a}. f a)› using ‹finite A› by (auto intro: sum.union_inter_neutral) finally have *: ‹sum f A = sum f (A ∩ {a. b dvd f a}) + sum f (A ∩ {a. ¬ b dvd f a})› . define B where B: ‹B = A ∩ {a. b dvd f a}› with ‹finite A› have ‹finite B› and ‹a ∈ B ==> b dvd f a› for a by simp_all then have ‹(∑a∈B. f a) div b = (∑a∈B. f a div b)› and ‹b dvd (∑a∈B. f a)› by induction (simp_all add: div_plus_div_distrib_dvd_left) then show ?thesis using * by (simp add: B div_plus_div_distrib_dvd_left) qed named_theorems mod_simps text ‹Addition respects modular equivalence.› lemma mod_add_left_eq [mod_simps]: "(a mod c + b) mod c = (a + b) mod c" proof - have "(a + b) mod c = (a div c * c + a mod c + b) mod c" by (simp only: div_mult_mod_eq) also have "\ by (simp only: ac_simps) also have "\ by (rule mod_mult_self1) finally show ?thesis by (rule sym) qed lemma mod_add_right_eq [mod_simps]: "(a + b mod c) mod c = (a + b) mod c" using mod_add_left_eq [of b c a] by (simp add: ac_simps) lemma mod_add_eq: "(a mod c + b mod c) mod c = (a + b) mod c" by (simp add: mod_add_left_eq mod_add_right_eq) lemma mod_sum_eq [mod_simps]: "(\ proof (induct A rule: infinite_finite_induct) case (insert i A) then have "(\ = (f i mod a + (∑i∈A. f i mod a)) mod a" by simp also have "\ by (simp add: mod_simps) also have "\ by (simp add: insert.hyps) finally show ?case by (simp add: insert.hyps mod_simps) qed simp_all lemma mod_add_cong: assumes "a mod c = a' mod c" assumes "b mod c = b' mod c" shows "(a + b) mod c = (a' + b') mod c" proof - have "(a mod c + b mod c) mod c = (a' mod c + b' mod c) mod c" unfolding assms .. then show ?thesis by (simp add: mod_add_eq) qed text ‹Multiplication respects modular equivalence.› lemma mod_mult_left_eq [mod_simps]: "((a mod c) * b) mod c = (a * b) mod c" proof - have "(a * b) mod c = ((a div c * c + a mod c) * b) mod c" by (simp only: div_mult_mod_eq) also have "\ by (simp only: algebra_simps) also have "\ by (rule mod_mult_self1) finally show ?thesis by (rule sym) qed lemma mod_mult_right_eq [mod_simps]: "(a * (b mod c)) mod c = (a * b) mod c" using mod_mult_left_eq [of b c a] by (simp add: ac_simps) lemma mod_mult_eq: "((a mod c) * (b mod c)) mod c = (a * b) mod c" by (simp add: mod_mult_left_eq mod_mult_right_eq) lemma mod_prod_eq [mod_simps]: "(\ proof (induct A rule: infinite_finite_induct) case (insert i A) then have "(\ = (f i mod a * (∏i∈A. f i mod a)) mod a" by simp also have "\ by (simp add: mod_simps) also have "\ by (simp add: insert.hyps) finally show ?case by (simp add: insert.hyps mod_simps) qed simp_all lemma mod_mult_cong: assumes "a mod c = a' mod c" assumes "b mod c = b' mod c" shows "(a * b) mod c = (a' * b') mod c" proof - have "(a mod c * (b mod c)) mod c = (a' mod c * (b' mod c)) mod c" unfolding assms .. then show ?thesis by (simp add: mod_mult_eq) qed text ‹Exponentiation respects modular equivalence.› lemma power_mod [mod_simps]: "((a mod b) ^ n) mod b = (a ^ n) mod b" proof (induct n) case 0 then show ?case by simp next case (Suc n) have "(a mod b) ^ Suc n mod b = (a mod b) * ((a mod b) ^ n mod b) mod b" by (simp add: mod_mult_right_eq) with Suc show ?case by (simp add: mod_mult_left_eq mod_mult_right_eq) qed lemma power_diff_power_eq: ‹a ^ m div a ^ n = (if n ≤ m then a ^ (m - n) else 1 div a ^ (n - m))› if ‹a ≠ 0› proof (cases ‹n ≤ m›) case True with that power_diff [symmetric, of a n m] show ?thesis by simp next case False then obtain q where n: ‹n = m + Suc q› by (auto simp add: not_le dest: less_imp_Suc_add) then have ‹a ^ m div a ^ n = (a ^ m * 1) div (a ^ m * a ^ Suc q)› by (simp add: power_add ac_simps) moreover from that have ‹a ^ m ≠ 0› by simp ultimately have ‹a ^ m div a ^ n = 1 div a ^ Suc q› by (subst (asm) div_mult_mult1) simp with False n show ?thesis by simp qed end class euclidean_ring_cancel = euclidean_ring + euclidean_semiring_cancel begin subclass idom_divide .. lemma div_minus_minus [simp]: "(- a) div (- b) = a div b" using div_mult_mult1 [of "- 1" a b] by simp lemma mod_minus_minus [simp]: "(- a) mod (- b) = - (a mod b)" using mod_mult_mult1 [of "- 1" a b] by simp lemma div_minus_right: "a div (- b) = (- a) div b" using div_minus_minus [of "- a" b] by simp lemma mod_minus_right: "a mod (- b) = - ((- a) mod b)" using mod_minus_minus [of "- a" b] by simp lemma div_minus1_right [simp]: "a div (- 1) = - a" using div_minus_right [of a 1] by simp lemma mod_minus1_right [simp]: "a mod (- 1) = 0" using mod_minus_right [of a 1] by simp text ‹Negation respects modular equivalence.› lemma mod_minus_eq [mod_simps]: "(- (a mod b)) mod b = (- a) mod b" proof - have "(- a) mod b = (- (a div b * b + a mod b)) mod b" by (simp only: div_mult_mod_eq) also have "\ by (simp add: ac_simps) also have "\ by (rule mod_mult_self1) finally show ?thesis by (rule sym) qed lemma mod_minus_cong: assumes "a mod b = a' mod b" shows "(- a) mod b = (- a') mod b" proof - have "(- (a mod b)) mod b = (- (a' mod b)) mod b" unfolding assms .. then show ?thesis by (simp add: mod_minus_eq) qed text ‹Subtraction respects modular equivalence.› lemma mod_diff_left_eq [mod_simps]: "(a mod c - b) mod c = (a - b) mod c" using mod_add_cong [of a c "a mod c" "- b" "- b"] by simp lemma mod_diff_right_eq [mod_simps]: "(a - b mod c) mod c = (a - b) mod c" using mod_add_cong [of a c a "- b" "- (b mod c)"] mod_minus_cong [of "b mod c" c b] by simp lemma mod_diff_eq: "(a mod c - b mod c) mod c = (a - b) mod c" using mod_add_cong [of a c "a mod c" "- b" "- (b mod c)"] mod_minus_cong [of "b mod c" c b] by simp lemma mod_diff_cong: assumes "a mod c = a' mod c" assumes "b mod c = b' mod c" shows "(a - b) mod c = (a' - b') mod c" using assms mod_add_cong [of a c a' "- b" "- b'"] mod_minus_cong [of b c "b'"] by simp lemma minus_mod_self2 [simp]: "(a - b) mod b = a mod b" using mod_diff_right_eq [of a b b] by (simp add: mod_diff_right_eq) lemma minus_mod_self1 [simp]: "(b - a) mod b = - a mod b" using mod_add_self2 [of "- a" b] by simp lemma mod_eq_dvd_iff: "a mod c = b mod c \ proof assume ?P then have "(a mod c - b mod c) mod c = 0" by simp then show ?Q by (simp add: dvd_eq_mod_eq_0 mod_simps) next assume ?Q then obtain d where d: "a - b = c * d" .. then have "a = c * d + b" by (simp add: algebra_simps) then show ?P by simp qed lemma mod_eqE: assumes "a mod c = b mod c" obtains d where "b = a + c * d" proof - from assms have "c dvd a - b" by (simp add: mod_eq_dvd_iff) then obtain d where "a - b = c * d" .. then have "b = a + c * - d" by (simp add: algebra_simps) with that show thesis . qed lemma invertible_coprime: "coprime a c" if "a * b mod c = 1" by (rule coprimeI) (use that dvd_mod_iff [of _ c "a * b"] in auto) end subsection ‹Uniquely determined division› class unique_euclidean_semiring = euclidean_semiring + assumes euclidean_size_mult: ‹euclidean_size (a * b) = euclidean_size a * euclidean_size b› fixes division_segment :: ‹'a \ assumes is_unit_division_segment [simp]: ‹is_unit (division_segment a)› and division_segment_mult: ‹a ≠ 0 ==> b ≠ 0 ==> division_segment (a * b) = division_segment a * division_segment b› and division_segment_mod: ‹b ≠ 0 ==> ¬ b dvd a ==> division_segment (a mod b) = division_segment b› assumes div_bounded: ‹b ≠ 0 ==> division_segment r = division_segment b ==> euclidean_size r < euclidean_size b ==> (q * b + r) div b = q› begin lemma division_segment_not_0 [simp]: ‹division_segment a ≠ 0› using is_unit_division_segment [of a] is_unitE [of ‹division_segment a›] by blast lemma euclidean_relationI [case_names by0 divides euclidean_relation]: ‹(a div b, a mod b) = (q, r)› if by0: ‹b = 0 ==> q = 0 ∧ r = a› and divides: ‹b ≠ 0 ==> b dvd a ==> r = 0 ∧ a = q * b› and euclidean_relation: ‹b ≠ 0 ==> ¬ b dvd a ==> division_segment r = division_segment b ∧ euclidean_size r < euclidean_size b ∧ a = q * b + r› proof (cases ‹b = 0›) case True with by0 show ?thesis by simp next case False show ?thesis proof (cases ‹b dvd a›) case True with ‹b ≠ 0› divides show ?thesis by simp next case False with ‹b ≠ 0› euclidean_relation have ‹division_segment r = division_segment b› ‹euclidean_size r < euclidean_size b› ‹a = q * b + r› by simp_all from ‹b ≠ 0› ‹division_segment r = division_segment b› ‹euclidean_size r < euclidean_size b› have ‹(q * b + r) div b = q› by (rule div_bounded) with ‹a = q * b + r› have ‹q = a div b› by simp from ‹a = q * b + r› have ‹a div b * b + a mod b = q * b + r› by (simp add: div_mult_mod_eq) with ‹q = a div b› have ‹q * b + a mod b = q * b + r› by simp then have ‹r = a mod b› by simp with ‹q = a div b› show ?thesis by simp qed qed subclass euclidean_semiring_cancel proof fix a b c assume ‹b ≠ 0› have ‹((a + c * b) div b, (a + c * b) mod b) = (c + a div b, a mod b)› proof (induction rule: euclidean_relationI) case by0 with ‹b ≠ 0› show ?case by simp next case divides then show ?case by (simp add: algebra_simps dvd_add_left_iff) next case euclidean_relation then have ‹¬ b dvd a› by (simp add: dvd_add_left_iff) have ‹a mod b + (b * c + b * (a div b)) = b * c + ((a div b) * b + a mod b)› by (simp add: ac_simps) with ‹b ≠ 0› have *: ‹a mod b + (b * c + b * (a div b)) = b * c + a› by (simp add: div_mult_mod_eq) from ‹¬ b dvd a› euclidean_relation show ?case by (simp_all add: algebra_simps division_segment_mod mod_size_less *) qed then show ‹(a + c * b) div b = c + a div b› by simp next fix a b c assume ‹c ≠ 0› have ‹((c * a) div (c * b), (c * a) mod (c * b)) = (a div b, c * (a mod b))› proof (induction rule: euclidean_relationI) case by0 with ‹c ≠ 0› show ?case by simp next case divides then show ?case by (auto simp add: algebra_simps) next case euclidean_relation then have ‹b ≠ 0› ‹a mod b ≠ 0› by (simp_all add: mod_eq_0_iff_dvd) have ‹c * (a mod b) + b * (c * (a div b)) = c * ((a div b) * b + a mod b)› by (simp add: algebra_simps) with ‹b ≠ 0› have *: ‹c * (a mod b) + b * (c * (a div b)) = c * a› by (simp add: div_mult_mod_eq) from ‹b ≠ 0› ‹c ≠ 0› have ‹euclidean_size c * euclidean_size (a mod b) < euclidean_size c * euclidean_size b› using mod_size_less [of b a] by simp with euclidean_relation ‹b ≠ 0› ‹a mod b ≠ 0› show ?case by (simp add: algebra_simps division_segment_mult division_segment_mod euclidean_size_ qed then show ‹(c * a) div (c * b) = a div b› by simp qed lemma div_eq_0_iff: ‹a div b = 0 ⟷ euclidean_size a < euclidean_size b ∨ b = 0› (is "_ \ if ‹division_segment a = division_segment b› proof (cases ‹a = 0 ∨ b = 0›) case True then show ?thesis by auto next case False then have ‹a ≠ 0› ‹b ≠ 0› by simp_all have ‹a div b = 0 ⟷ euclidean_size a < euclidean_size b› proof assume ‹a div b = 0› then have ‹a mod b = a› using div_mult_mod_eq [of a b] by simp with ‹b ≠ 0› mod_size_less [of b a] show ‹euclidean_size a < euclidean_size b› by simp next assume ‹euclidean_size a < euclidean_size b› have ‹(a div b, a mod b) = (0, a)› proof (induction rule: euclidean_relationI) case by0 show ?case by simp next case divides with ‹euclidean_size a < euclidean_size b› show ?case using dvd_imp_size_le [of b a] ‹a ≠ 0› by simp next case euclidean_relation with ‹euclidean_size a < euclidean_size b› that show ?case by simp qed then show ‹a div b = 0› by simp qed with ‹b ≠ 0› show ?thesis by simp qed lemma div_mult1_eq: ‹(a * b) div c = a * (b div c) + a * (b mod c) div c› proof - have *: ‹(a * b) mod c + (a * (c * (b div c)) + c * (a * (b mod c) div c)) = a * b› (is ‹?A + (?B + ?C) = _›) proof - have ‹?A = a * (b mod c) mod c› by (simp add: mod_mult_right_eq) then have ‹?C + ?A = a * (b mod c)› by (simp add: mult_div_mod_eq) then have ‹?B + (?C + ?A) = a * (c * (b div c) + (b mod c))› by (simp add: algebra_simps) also have ‹… = a * b› by (simp add: mult_div_mod_eq) finally show ?thesis by (simp add: algebra_simps) qed have ‹((a * b) div c, (a * b) mod c) = (a * (b div c) + a * (b mod c) div c, (a * b) mod c)› proof (induction rule: euclidean_relationI) case by0 then show ?case by simp next case divides with * show ?case by (simp add: algebra_simps) next case euclidean_relation with * show ?case by (simp add: division_segment_mod mod_size_less algebra_simps) qed then show ?thesis by simp qed lemma div_add1_eq: ‹(a + b) div c = a div c + b div c + (a mod c + b mod c) div c› proof - have *: ‹(a + b) mod c + (c * (a div c) + (c * (b div c) + c * ((a mod c + b mod c) div c))) = a + b› (is ‹?A + (?B + (?C + ?D)) = _›) proof - have ‹?A + (?B + (?C + ?D)) = ?A + ?D + (?B + ?C)› by (simp add: ac_simps) also have ‹?A + ?D = (a mod c + b mod c) mod c + ?D› by (simp add: mod_add_eq) also have ‹… = a mod c + b mod c› by (simp add: mod_mult_div_eq) finally have ‹?A + (?B + (?C + ?D)) = (a mod c + ?B) + (b mod c + ?C)› by (simp add: ac_simps) then show ?thesis by (simp add: mod_mult_div_eq) qed have ‹((a + b) div c, (a + b) mod c) = (a div c + b div c + (a mod c + b mod c) div c, (a + b) mod c)› proof (induction rule: euclidean_relationI) case by0 then show ?case by simp next case divides with * show ?case by (simp add: algebra_simps) next case euclidean_relation with * show ?case by (simp add: division_segment_mod mod_size_less algebra_simps) qed then show ?thesis by simp qed end class unique_euclidean_ring = euclidean_ring + unique_euclidean_semiring begin subclass euclidean_ring_cancel .. end subsection ‹Division on 🍋‹nat›› instantiation nat :: normalization_semidom begin definition normalize_nat :: ‹nat ==> nat› where [simp]: ‹normalize = (id :: nat ==> nat)› definition unit_factor_nat :: ‹nat ==> nat› where ‹unit_factor n = of_bool (n > 0)› for n :: nat lemma unit_factor_simps [simp]: ‹unit_factor 0 = (0::nat)› ‹unit_factor (Suc n) = 1› by (simp_all add: unit_factor_nat_def) definition divide_nat :: ‹nat ==> nat ==> nat› where ‹m div n = (if n = 0 then 0 else Max {k. k * n ≤ m})› for m n :: nat instance by standard (auto simp add: divide_nat_def ac_simps unit_factor_nat_def intro: Max_eqI) end lemma coprime_Suc_0_left [simp]: "coprime (Suc 0) n" using coprime_1_left [of n] by simp lemma coprime_Suc_0_right [simp]: "coprime n (Suc 0)" using coprime_1_right [of n] by simp lemma coprime_common_divisor_nat: "coprime a b \ for a b :: nat by (drule coprime_common_divisor [of _ _ x]) simp_all instantiation nat :: unique_euclidean_semiring begin definition euclidean_size_nat :: ‹nat ==> nat› where [simp]: ‹euclidean_size_nat = id› definition division_segment_nat :: ‹nat ==> nat› where [simp]: ‹division_segment n = 1› for n :: nat definition modulo_nat :: ‹nat ==> nat ==> nat› where ‹m mod n = m - (m div n * n)› for m n :: nat instance proof fix m n :: nat have ex: "\ by (rule exI [of _ 0]) simp have fin: "finite {k. k * n \ proof - from that have "{k. k * n \ by (cases n) auto then show ?thesis by (rule finite_subset) simp qed have mult_div_unfold: "n * (m div n) = Max {l. l \ proof (cases "n = 0") case True moreover have "{l. l = 0 \ by auto ultimately show ?thesis by simp next case False with ex [of m] fin have "n * Max {k. k * n \ by (auto simp add: nat_mult_max_right intro: hom_Max_commute) also have "times n ` {k. k * n \ by (auto simp add: ac_simps elim!: dvdE) finally show ?thesis using False by (simp add: divide_nat_def ac_simps) qed have less_eq: "m div n * n \ by (auto simp add: mult_div_unfold ac_simps intro: Max.boundedI) then show "m div n * n + m mod n = m" by (simp add: modulo_nat_def) assume "n \ show "euclidean_size (m mod n) < euclidean_size n" proof - have "m < Suc (m div n) * n" proof (rule ccontr) assume "\ then have "Suc (m div n) * n \ by (simp add: not_less) moreover from ‹n ≠ 0› have "Max {k. k * n \ by (simp add: divide_nat_def) with ‹n ≠ 0› ex fin have "\ by auto ultimately have "Suc (m div n) < Suc (m div n)" by blast then show False by simp qed with ‹n ≠ 0› show ?thesis by (simp add: modulo_nat_def) qed show "euclidean_size m \ using ‹n ≠ 0› by (cases n) simp_all fix q r :: nat show "(q * n + r) div n = q" if "euclidean_size r < euclidean_size n" proof - from that have "r < n" by simp have "k \ proof (rule ccontr) assume "\ then have "q < k" by simp then obtain l where "k = Suc (q + l)" by (auto simp add: less_iff_Suc_add) with ‹r < n› that show False by (simp add: algebra_simps) qed with ‹n ≠ 0› ex fin show ?thesis by (auto simp add: divide_nat_def Max_eq_iff) qed qed simp_all end lemma euclidean_relation_natI [case_names by0 divides euclidean_relation]: ‹(m div n, m mod n) = (q, r)› if by0: ‹n = 0 ==> q = 0 ∧ r = m› and divides: ‹n > 0 ==> n dvd m ==> r = 0 ∧ m = q * n› and euclidean_relation: ‹n > 0 ==> ¬ n dvd m ==> r < n ∧ m = q * n + r› for m n q r :: nat by (rule euclidean_relationI) (use that in simp_all) lemma div_nat_eqI: ‹m div n = q› if ‹n * q ≤ m› and ‹m < n * Suc q› for m n q :: nat proof - have ‹(m div n, m mod n) = (q, m - n * q)› proof (induction rule: euclidean_relation_natI) case by0 with that show ?case by simp next case divides from ‹n dvd m› obtain s where ‹m = n * s› .. with ‹n > 0› that have ‹s < Suc q› by (simp only: mult_less_cancel1) with ‹m = n * s› ‹n > 0› that have ‹q = s› by simp with ‹m = n * s› show ?case by (simp add: ac_simps) next case euclidean_relation with that show ?case by (simp add: ac_simps) qed then show ?thesis by simp qed lemma mod_nat_eqI: ‹m mod n = r› if ‹r < n› and ‹r ≤ m› and ‹n dvd m - r› for m n r :: nat proof - have ‹(m div n, m mod n) = ((m - r) div n, r)› proof (induction rule: euclidean_relation_natI) case by0 with that show ?case by simp next case divides from that dvd_minus_add [of r ‹m› 1 n] have ‹n dvd m + (n - r)› by simp with divides have ‹n dvd n - r› by (simp add: dvd_add_right_iff) then have ‹n ≤ n - r› by (rule dvd_imp_le) (use ‹r < n› in simp) with ‹n > 0› have ‹r = 0› by simp with ‹n > 0› that show ?case by simp next case euclidean_relation with that show ?case by (simp add: ac_simps) qed then show ?thesis by simp qed text ‹Tool support› ML ‹ structure Cancel_Div_Mod_Nat = Cancel_Div_Mod ( val div_name = 🍋‹divide›; val mod_name = 🍋‹modulo›; val mk_binop = HOLogic.mk_binop; val dest_plus = HOLogic.dest_bin 🍋‹Groups.plus› HOLogic.natT; val mk_sum = Arith_Data.mk_sum; fun dest_sum tm = if HOLogic.is_zero tm then [] else (case try HOLogic.dest_Suc tm of SOME t => HOLogic.Suc_zero :: dest_sum t | NONE => (case try dest_plus tm of SOME (t, u) => dest_sum t @ dest_sum u | NONE => [tm])); val div_mod_eqs = map mk_meta_eq @{thms cancel_div_mod_rules}; val prove_eq_sums = Arith_Data.prove_conv2 all_tac (Arith_Data.simp_all_tac @{thms add_0_left add_0_right ac_simps}) ) › simproc_setup cancel_div_mod_nat ("(m::nat) + n") = ‹K Cancel_Div_Mod_Nat.proc› lemma div_mult_self_is_m [simp]: "m * n div n = m" if "n > 0" for m n :: nat using that by simp lemma div_mult_self1_is_m [simp]: "n * m div n = m" if "n > 0" for m n :: nat using that by simp lemma mod_less_divisor [simp]: "m mod n < n" if "n > 0" for m n :: nat using mod_size_less [of n m] that by simp lemma mod_le_divisor [simp]: "m mod n \ using that by (auto simp add: le_less) lemma div_times_less_eq_dividend [simp]: "m div n * n \ by (simp add: minus_mod_eq_div_mult [symmetric]) lemma times_div_less_eq_dividend [simp]: "n * (m div n) \ using div_times_less_eq_dividend [of m n] by (simp add: ac_simps) lemma dividend_less_div_times: "m < n + (m div n) * n" if "0 < n" for m n :: nat proof - from that have "m mod n < n" by simp then show ?thesis by (simp add: minus_mod_eq_div_mult [symmetric]) qed lemma dividend_less_times_div: "m < n + n * (m div n)" if "0 < n" for m n :: nat using dividend_less_div_times [of n m] that by (simp add: ac_simps) lemma mod_Suc_le_divisor [simp]: "m mod Suc n \ using mod_less_divisor [of "Suc n" m] by arith lemma mod_less_eq_dividend [simp]: "m mod n \ proof (rule add_leD2) from div_mult_mod_eq have "m div n * n + m mod n = m" . then show "m div n * n + m mod n \ qed lemma div_less [simp]: "m div n = 0" and mod_less [simp]: "m mod n = m" if "m < n" for m n :: nat using that by (auto intro: div_nat_eqI mod_nat_eqI) lemma split_div: ‹P (m div n) ⟷ (n = 0 ⟶ P 0) ∧ (n ≠ 0 ⟶ (∀i j. j < n ∧ m = n * i + j ⟶ P i))› (is ?div) and split_mod: ‹Q (m mod n) ⟷ (n = 0 ⟶ Q m) ∧ (n ≠ 0 ⟶ (∀i j. j < n ∧ m = n * i + j ⟶ Q j))› (is ?mod) for m n :: nat proof - have *: ‹R (m div n) (m mod n) ⟷ (n = 0 ⟶ R 0 m) ∧ (n ≠ 0 ⟶ (∀i j. j < n ∧ m = n * i + j ⟶ R i j))› for R by (cases ‹n = 0›) auto from * [of ‹λq _. P q›] show ?div . from * [of ‹λ_ r. Q r›] show ?mod . qed declare split_div [of _ _ ‹numeral n›, linarith_split] for n declare split_mod [of _ _ ‹numeral n›, linarith_split] for n lemma split_div': "P (m div n) \ proof (cases "n = 0") case True then show ?thesis by simp next case False then have "n * q \ by (auto intro: div_nat_eqI dividend_less_times_div) then show ?thesis by auto qed lemma le_div_geq: "m div n = Suc ((m - n) div n)" if "0 < n" and "n \ proof - from ‹n ≤ m› obtain q where "m = n + q" by (auto simp add: le_iff_add) with ‹0 < n› show ?thesis by (simp add: div_add_self1) qed lemma le_mod_geq: "m mod n = (m - n) mod n" if "n \ proof - from ‹n ≤ m› obtain q where "m = n + q" by (auto simp add: le_iff_add) then show ?thesis by simp qed lemma div_if: "m div n = (if m < n \ by (simp add: le_div_geq) lemma mod_if: "m mod n = (if m < n then m else (m - n) mod n)" for m n :: nat by (simp add: le_mod_geq) lemma div_eq_0_iff: "m div n = 0 \ by (simp add: div_eq_0_iff) lemma div_greater_zero_iff: "m div n > 0 \ using div_eq_0_iff [of m n] by auto lemma mod_greater_zero_iff_not_dvd: "m mod n > 0 \ by (simp add: dvd_eq_mod_eq_0) lemma div_by_Suc_0 [simp]: "m div Suc 0 = m" using div_by_1 [of m] by simp lemma mod_by_Suc_0 [simp]: "m mod Suc 0 = 0" using mod_by_1 [of m] by simp lemma div2_Suc_Suc [simp]: "Suc (Suc m) div 2 = Suc (m div 2)" by (simp add: numeral_2_eq_2 le_div_geq) lemma Suc_n_div_2_gt_zero [simp]: "0 < Suc n div 2" if "n > 0" for n :: nat using that by (cases n) simp_all lemma div_2_gt_zero [simp]: "0 < n div 2" if "Suc 0 < n" for n :: nat using that Suc_n_div_2_gt_zero [of "n - 1"] by simp lemma mod2_Suc_Suc [simp]: "Suc (Suc m) mod 2 = m mod 2" by (simp add: numeral_2_eq_2 le_mod_geq) lemma add_self_div_2 [simp]: "(m + m) div 2 = m" for m :: nat by (simp add: mult_2 [symmetric]) lemma add_self_mod_2 [simp]: "(m + m) mod 2 = 0" for m :: nat by (simp add: mult_2 [symmetric]) lemma mod2_gr_0 [simp]: "0 < m mod 2 \ proof - have "m mod 2 < 2" by (rule mod_less_divisor) simp then have "m mod 2 = 0 \ by arith then show ?thesis by auto qed lemma mod_Suc_eq [mod_simps]: "Suc (m mod n) mod n = Suc m mod n" proof - have "(m mod n + 1) mod n = (m + 1) mod n" by (simp only: mod_simps) then show ?thesis by simp qed lemma mod_Suc_Suc_eq [mod_simps]: "Suc (Suc (m mod n)) mod n = Suc (Suc m) mod n" proof - have "(m mod n + 2) mod n = (m + 2) mod n" by (simp only: mod_simps) then show ?thesis by simp qed lemma Suc_mod_mult_self1 [simp]: "Suc (m + k * n) mod n = Suc m mod n" and Suc_mod_mult_self2 [simp]: "Suc (m + n * k) mod n = Suc m mod n" and Suc_mod_mult_self3 [simp]: "Suc (k * n + m) mod n = Suc m mod n" and Suc_mod_mult_self4 [simp]: "Suc (n * k + m) mod n = Suc m mod n" by (subst mod_Suc_eq [symmetric], simp add: mod_simps)+ lemma Suc_0_mod_eq [simp]: "Suc 0 mod n = of_bool (n \ by (cases n) simp_all lemma div_mult2_eq: ‹m div (n * q) = (m div n) div q› (is ?Q) and mod_mult2_eq: ‹m mod (n * q) = n * (m div n mod q) + m mod n› (is ?R) for m n q :: nat proof - have ‹(m div (n * q), m mod (n * q)) = ((m div n) div q, n * (m div n mod q) + m mod n)› proof (induction rule: euclidean_relation_natI) case by0 then show ?case by auto next case divides from ‹n * q dvd m› obtain t where ‹m = n * q * t› .. with ‹n * q > 0› show ?case by (simp add: algebra_simps) next case euclidean_relation then have ‹n > 0› ‹q > 0› by simp_all from ‹n > 0› have ‹m mod n < n› by (rule mod_less_divisor) from ‹q > 0› have ‹m div n mod q < q› by (rule mod_less_divisor) then obtain s where ‹q = Suc (m div n mod q + s)› by (blast dest: less_imp_Suc_add) moreover have ‹m mod n + n * (m div n mod q) < n * Suc (m div n mod q + s)› using ‹m mod n < n› by (simp add: add_mult_distrib2) ultimately have ‹m mod n + n * (m div n mod q) < n * q› by simp then show ?case by (simp add: algebra_simps flip: add_mult_distrib2) qed then show ?Q and ?R by simp_all qed lemma div_le_mono: "m div k \ proof - from that obtain q where "n = m + q" by (auto simp add: le_iff_add) then show ?thesis by (simp add: div_add1_eq [of m q k]) qed text ‹Antimonotonicity of 🍋‹divide› in second argument› lemma div_le_mono2: "k div n \ using that proof (induct k arbitrary: m rule: less_induct) case (less k) show ?case proof (cases "n \ case False then show ?thesis by simp next case True have "(k - n) div n \ using less.prems by (blast intro: div_le_mono diff_le_mono2) also have "\ using ‹n ≤ k› less.prems less.hyps [of "k - m" m] by simp finally show ?thesis using ‹n ≤ k› less.prems by (simp add: le_div_geq) qed qed lemma div_le_dividend [simp]: "m div n \ using div_le_mono2 [of 1 n m] by (cases "n = 0") simp_all lemma div_less_dividend [simp]: "m div n < m" if "1 < n" and "0 < m" for m n :: nat using that proof (induct m rule: less_induct) case (less m) show ?case proof (cases "n < m") case False with less show ?thesis by (cases "n = m") simp_all next case True then show ?thesis using less.hyps [of "m - n"] less.prems by (simp add: le_div_geq) qed qed lemma div_eq_dividend_iff: "m div n = m \ proof assume "n = 1" then show "m div n = m" by simp next assume P: "m div n = m" show "n = 1" proof (rule ccontr) have "n \ by (rule ccontr) (use that P in auto) moreover assume "n \ ultimately have "n > 1" by simp with that have "m div n < m" by simp with P show False by simp qed qed lemma less_mult_imp_div_less: "m div n < i" if "m < i * n" for m n i :: nat proof - from that have "i * n > 0" by (cases "i * n = 0") simp_all then have "i > 0" and "n > 0" by simp_all have "m div n * n \ by simp then have "m div n * n < i * n" using that by (rule le_less_trans) with ‹n > 0› show ?thesis by simp qed lemma div_less_iff_less_mult: ‹m div q < n ⟷ m < n * q› (is ‹?P ⟷ ?Q›) if ‹q > 0› for m n q :: nat proof assume ?Q then show ?P by (rule less_mult_imp_div_less) next assume ?P then obtain h where ‹n = Suc (m div q + h)› using less_natE by blast moreover have ‹m < m + (Suc h * q - m mod q)› using that by (simp add: trans_less_add1) ultimately show ?Q by (simp add: algebra_simps flip: minus_mod_eq_mult_div) qed lemma less_eq_div_iff_mult_less_eq: ‹m ≤ n div q ⟷ m * q ≤ n› if ‹q > 0› for m n q :: nat using div_less_iff_less_mult [of q n m] that by auto lemma div_Suc: ‹Suc m div n = (if Suc m mod n = 0 then Suc (m div n) else m div n)› proof (cases ‹n = 0 ∨ n = 1›) case True then show ?thesis by auto next case False then have ‹n > 1› by simp then have ‹Suc m div n = m div n + Suc (m mod n) div n› using div_add1_eq [of m 1 n] by simp also have ‹Suc (m mod n) div n = of_bool (n dvd Suc m)› proof (cases ‹n dvd Suc m›) case False moreover have ‹Suc (m mod n) ≠ n› proof (rule ccontr) assume ‹¬ Suc (m mod n) ≠ n› then have ‹m mod n = n - Suc 0› by simp with ‹n > 1› have ‹(m + 1) mod n = 0› by (subst mod_add_left_eq [symmetric]) simp then have ‹n dvd Suc m› by auto with False show False .. qed moreover have ‹Suc (m mod n) ≤ n› using ‹n > 1› by (simp add: Suc_le_eq) ultimately show ?thesis by (simp add: div_eq_0_iff) next case True then obtain q where q: ‹Suc m = n * q› .. moreover have ‹q > 0› by (rule ccontr) (use q in simp) ultimately have ‹m mod n = n - Suc 0› using ‹n > 1› mult_le_cancel1 [of n ‹Suc 0› q] by (auto intro: mod_nat_eqI) with True ‹n > 1› show ?thesis by simp qed finally show ?thesis by (simp add: mod_greater_zero_iff_not_dvd) qed lemma mod_Suc: ‹Suc m mod n = (if Suc (m mod n) = n then 0 else Suc (m mod n))› proof (cases ‹n = 0›) case True then show ?thesis by simp next case False moreover have ‹Suc m mod n = Suc (m mod n) mod n› by (simp add: mod_simps) ultimately show ?thesis by (auto intro!: mod_nat_eqI intro: neq_le_trans simp add: Suc_le_eq) qed lemma Suc_times_mod_eq: "Suc (m * n) mod m = 1" if "Suc 0 < m" using that by (simp add: mod_Suc) lemma Suc_times_numeral_mod_eq [simp]: "Suc (numeral k * n) mod numeral k = 1" if "numeral k \ by (rule Suc_times_mod_eq) (use that in simp) lemma Suc_div_le_mono [simp]: "m div n \ by (simp add: div_le_mono) text ‹These lemmas collapse some needless occurrences of Suc: at least three Sucs, since two and fewer are rewritten back to Suc again! We already have some rules to simplify operands smaller than 3.› lemma div_Suc_eq_div_add3 [simp]: "m div Suc (Suc (Suc n)) = m div (3 + n)" by (simp add: Suc3_eq_add_3) lemma mod_Suc_eq_mod_add3 [simp]: "m mod Suc (Suc (Suc n)) = m mod (3 + n)" by (simp add: Suc3_eq_add_3) lemma Suc_div_eq_add3_div: "Suc (Suc (Suc m)) div n = (3 + m) div n" by (simp add: Suc3_eq_add_3) lemma Suc_mod_eq_add3_mod: "Suc (Suc (Suc m)) mod n = (3 + m) mod n" by (simp add: Suc3_eq_add_3) lemmas Suc_div_eq_add3_div_numeral [simp] = Suc_div_eq_add3_div [of _ "numeral v"] for v lemmas Suc_mod_eq_add3_mod_numeral [simp] = Suc_mod_eq_add3_mod [of _ "numeral v"] for v lemma (in field_char_0) of_nat_div: "of_nat (m div n) = ((of_nat m - of_nat (m mod n)) / of_nat n)" proof - have "of_nat (m div n) = ((of_nat (m div n * n + m mod n) - of_nat (m mod n)) / o unfolding of_nat_add by (cases "n = 0") simp_all then show ?thesis by simp qed text ‹An ``induction'' law for modulus arithmetic.› lemma mod_induct [consumes 3, case_names step]: "P m" if "P n" and "n < p" and "m < p" and step: "\ using ‹m < p› proof (induct m) case 0 show ?case proof (rule ccontr) assume "\ from ‹n < p› have "0 < p" by simp from ‹n < p› obtain m where "0 < m" and "p = n + m" by (blast dest: less_imp_add_positive) with ‹P n› have "P (p - m)" by simp moreover have "\ using ‹0 < m› proof (induct m) case 0 then show ?case by simp next case (Suc m) show ?case proof assume P: "P (p - Suc m)" with ‹¬ P 0› have "Suc m < p" by (auto intro: ccontr) then have "Suc (p - Suc m) = p - m" by arith moreover from ‹0 < p› have "p - Suc m < p" by arith with P step have "P ((Suc (p - Suc m)) mod p)" by blast ultimately show False using ‹¬ P 0› Suc.hyps by (cases "m = 0") simp_all qed qed ultimately show False by blast qed next case (Suc m) then have "m < p" and mod: "Suc m mod p = Suc m" by simp_all from ‹m < p› have "P m" by (rule Suc.hyps) with ‹m < p› have "P (Suc m mod p)" by (rule step) with mod show ?case by simp qed lemma funpow_mod_eq: 🍋‹contributor ‹Lars Noschinski›› ‹(f ^^ (m mod n)) x = (f ^^ m) x› if ‹(f ^^ n) x = x› proof - have ‹(f ^^ m) x = (f ^^ (m mod n + m div n * n)) x› by simp also have ‹… = (f ^^ (m mod n)) (((f ^^ n) ^^ (m div n)) x)› by (simp only: funpow_add funpow_mult ac_simps) simp also have ‹((f ^^ n) ^^ q) x = x› for q by (induction q) (use ‹(f ^^ n) x = x› in simp_all) finally show ?thesis by simp qed lemma mod_eq_dvd_iff_nat: ‹m mod q = n mod q ⟷ q dvd m - n› (is ‹?P ⟷ ?Q›) if ‹m ≥ n› for m n q :: nat proof assume ?Q then obtain s where ‹m - n = q * s› .. with that have ‹m = q * s + n› by simp then show ?P by simp next assume ?P have ‹m - n = m div q * q + m mod q - (n div q * q + n mod q)› by simp also have ‹… = q * (m div q - n div q)› by (simp only: algebra_simps ‹?P›) finally show ?Q .. qed lemma mod_eq_iff_dvd_symdiff_nat: ‹m mod q = n mod q ⟷ q dvd nat ∣int m - int n∣› by (auto simp add: abs_if mod_eq_dvd_iff_nat nat_diff_distrib dest: sym intro: sym) lemma mod_eq_nat1E: fixes m n q :: nat assumes "m mod q = n mod q" and "m \ obtains s where "m = n + q * s" proof - from assms have "q dvd m - n" by (simp add: mod_eq_dvd_iff_nat) then obtain s where "m - n = q * s" .. with ‹m ≥ n› have "m = n + q * s" by simp with that show thesis . qed lemma mod_eq_nat2E: fixes m n q :: nat assumes "m mod q = n mod q" and "n \ obtains s where "n = m + q * s" using assms mod_eq_nat1E [of n q m] by (auto simp add: ac_simps) lemma nat_mod_eq_iff: "(x::nat) mod n = y mod n \ proof assume H: "x mod n = y mod n" { assume xy: "x \ from H have th: "y mod n = x mod n" by simp from mod_eq_nat1E [OF th xy] obtain q where "y = x + n * q" . then have "x + n * q = y + n * 0" by simp then have "\ by blast } moreover { assume xy: "y \ from mod_eq_nat1E [OF H xy] obtain q where "x = y + n * q" . then have "x + n * 0 = y + n * q" by simp then have "\ by blast } ultimately show ?rhs using linear[of x y] by blast next assume ?rhs then obtain q1 q2 where q12: "x + n * q1 = y + n * q2" by blast hence "(x + n * q1) mod n = (y + n * q2) mod n" by simp thus ?lhs by simp qed subsection ‹Division on 🍋‹int›› text ‹ The following specification of integer division rounds towards minus infinity and is advocated by Donald Knuth. See \cite{leijen01} for an overview and terminology of different possibilities to specify integer division; there division rounding towards minus infinitiy is named ``F-division''. › subsubsection ‹Basic instantiation› instantiation int :: "{normalization_semidom, idom_modulo}" begin definition normalize_int :: ‹int ==> int› where [simp]: ‹normalize = (abs :: int ==> int)› definition unit_factor_int :: ‹int ==> int› where [simp]: ‹unit_factor = (sgn :: int ==> int)› definition divide_int :: ‹int ==> int ==> int› where ‹k div l = (sgn k * sgn l * int (nat ∣k∣ div nat ∣l∣) - of_bool (l ≠ 0 ∧ sgn k ≠ sgn l ∧ ¬ l dvd k))› lemma divide_int_unfold: ‹(sgn k * int m) div (sgn l * int n) = (sgn k * sgn l * int (m div n) - of_bool ((k = 0 ⟷ m = 0) ∧ l ≠ 0 ∧ n ≠ 0 ∧ sgn k ≠ sgn l ∧ ¬ n dvd m))› by (simp add: divide_int_def sgn_mult nat_mult_distrib abs_mult sgn_eq_0_iff ac_simps) definition modulo_int :: ‹int ==> int ==> int› where ‹k mod l = sgn k * int (nat ∣k∣ mod nat ∣l∣) + l * of_bool (sgn k ≠ sgn l ∧ ¬ l dvd k)› lemma modulo_int_unfold: ‹(sgn k * int m) mod (sgn l * int n) = sgn k * int (m mod (of_bool (l ≠ 0) * n)) + (sgn l * int n) * of_bool ((k = 0 ⟷ m = 0) ∧ sgn k ≠ sgn l ∧ ¬ n dvd m)› by (auto simp add: modulo_int_def sgn_mult abs_mult) instance proof fix k :: int show "k div 0 = 0" by (simp add: divide_int_def) next fix k l :: int assume "l \ obtain n m and s t where k: "k = sgn s * int n" and l: "l = sgn t * int m" by (blast intro: int_sgnE elim: that) then have "k * l = sgn (s * t) * int (n * m)" by (simp add: ac_simps sgn_mult) with k l ‹l ≠ 0› show "k * l div l = k" by (simp only: divide_int_unfold) (auto simp add: algebra_simps sgn_mult sgn_1_pos sgn_0_0) next fix k l :: int obtain n m and s t where "k = sgn s * int n" and "l = sgn t * int m" by (blast intro: int_sgnE elim: that) then show "k div l * l + k mod l = k" by (simp add: divide_int_unfold modulo_int_unfold algebra_simps modulo_nat_def of_nat_d qed (auto simp add: sgn_mult mult_sgn_abs abs_eq_iff') end lemma of_int_div: "b dvd a \ by (elim dvdE) (auto simp: divide_simps mult_ac) subsubsection ‹Algebraic foundations› lemma coprime_int_iff [simp]: "coprime (int m) (int n) \ proof assume ?P show ?Q proof (rule coprimeI) fix q assume "q dvd m" "q dvd n" then have "int q dvd int m" "int q dvd int n" by simp_all with ‹?P› have "is_unit (int q)" by (rule coprime_common_divisor) then show "is_unit q" by simp qed next assume ?Q show ?P proof (rule coprimeI) fix k assume "k dvd int m" "k dvd int n" then have "nat \ by simp_all with ‹?Q› have "is_unit (nat \ by (rule coprime_common_divisor) then show "is_unit k" by simp qed qed lemma coprime_abs_left_iff [simp]: "coprime \ using coprime_normalize_left_iff [of k l] by simp lemma coprime_abs_right_iff [simp]: "coprime k \ using coprime_abs_left_iff [of l k] by (simp add: ac_simps) lemma coprime_nat_abs_left_iff [simp]: "coprime (nat \ proof - define m where "m = nat \ then have "\ by simp moreover have "coprime k (int n) \ by simp ultimately show ?thesis by simp qed lemma coprime_nat_abs_right_iff [simp]: "coprime n (nat \ using coprime_nat_abs_left_iff [of k n] by (simp add: ac_simps) lemma coprime_common_divisor_int: "coprime a b \ for a b :: int by (drule coprime_common_divisor [of _ _ x]) simp_all subsubsection ‹Basic conversions› lemma div_abs_eq_div_nat: "\ by (auto simp add: divide_int_def) lemma div_eq_div_abs: ‹k div l = sgn k * sgn l * (∣k∣ div ∣l∣) - of_bool (l ≠ 0 ∧ sgn k ≠ sgn l ∧ ¬ l dvd k)› for k l :: int by (simp add: divide_int_def [of k l] div_abs_eq_div_nat) lemma div_abs_eq: ‹∣k∣ div ∣l∣ = sgn k * sgn l * (k div l + of_bool (sgn k ≠ sgn l ∧ ¬ l dvd k))› for k l :: int by (simp add: div_eq_div_abs [of k l] ac_simps) lemma mod_abs_eq_div_nat: "\ by (simp add: modulo_int_def) lemma mod_eq_mod_abs: ‹k mod l = sgn k * (∣k∣ mod ∣l∣) + l * of_bool (sgn k ≠ sgn l ∧ ¬ l dvd k)› for k l :: int by (simp add: modulo_int_def [of k l] mod_abs_eq_div_nat) lemma mod_abs_eq: ‹∣k∣ mod ∣l∣ = sgn k * (k mod l - l * of_bool (sgn k ≠ sgn l ∧ ¬ l dvd k))› for k l :: int by (auto simp: mod_eq_mod_abs [of k l]) lemma div_sgn_abs_cancel: fixes k l v :: int assumes "v \ shows "(sgn v * \ using assms by (simp add: sgn_mult abs_mult sgn_0_0 divide_int_def [of "sgn v * \ lemma div_eq_sgn_abs: fixes k l v :: int assumes "sgn k = sgn l" shows "k div l = \ using assms by (auto simp add: div_abs_eq) lemma div_dvd_sgn_abs: fixes k l :: int assumes "l dvd k" shows "k div l = (sgn k * sgn l) * (\ using assms by (auto simp add: div_abs_eq ac_simps) lemma div_noneq_sgn_abs: fixes k l :: int assumes "l \ assumes "sgn k \ shows "k div l = - (\ using assms by (auto simp add: div_abs_eq ac_simps sgn_0_0 dest!: sgn_not_eq_imp) subsubsection ‹Euclidean division› instantiation int :: unique_euclidean_ring begin definition euclidean_size_int :: "int \ where [simp]: "euclidean_size_int = (nat \ definition division_segment_int :: "int \ where "division_segment_int k = (if k \ lemma division_segment_eq_sgn: "division_segment k = sgn k" if "k \ using that by (simp add: division_segment_int_def) lemma abs_division_segment [simp]: "\ by (simp add: division_segment_int_def) lemma abs_mod_less: "\ proof - obtain n m and s t where "k = sgn s * int n" and "l = sgn t * int m" by (blast intro: int_sgnE elim: that) with that show ?thesis by (auto simp add: modulo_int_unfold abs_mult mod_greater_zero_iff_not_dvd simp flip: right_diff_distrib dest!: sgn_not_eq_imp) (simp add: sgn_0_0) qed lemma sgn_mod: "sgn (k mod l) = sgn l" if "l \ proof - obtain n m and s t where "k = sgn s * int n" and "l = sgn t * int m" by (blast intro: int_sgnE elim: that) with that show ?thesis by (auto simp add: modulo_int_unfold sgn_mult mod_greater_zero_iff_not_dvd simp flip: right_diff_distrib dest!: sgn_not_eq_imp) qed instance proof fix k l :: int show "division_segment (k mod l) = division_segment l" if "l \ using that by (simp add: division_segment_eq_sgn dvd_eq_mod_eq_0 sgn_mod) next fix l q r :: int obtain n m and s t where l: "l = sgn s * int n" and q: "q = sgn t * int m" by (blast intro: int_sgnE elim: that) assume ‹l ≠ 0› with l have "s \ by (simp_all add: sgn_0_0) assume "division_segment r = division_segment l" moreover have "r = sgn r * \ by (simp add: sgn_mult_abs) moreover define u where "u = nat \ ultimately have "r = sgn l * int u" using division_segment_eq_sgn ‹l ≠ 0› by (cases "r = 0") simp_all with l ‹n > 0› have r: "r = sgn s * int u" by (simp add: sgn_mult) assume "euclidean_size r < euclidean_size l" with l r ‹s ≠ 0› have "u < n" by (simp add: abs_mult) show "(q * l + r) div l = q" proof (cases "q = 0 \ case True then show ?thesis proof assume "q = 0" then show ?thesis using l r ‹u < n› by (simp add: divide_int_unfold) next assume "r = 0" from ‹r = 0› have *: "q * l + r = sgn (t * s) * int (n * m)" using q l by (simp add: ac_simps sgn_mult) from ‹s ≠ 0› ‹n > 0› show ?thesis by (simp only: *, simp only: * q l divide_int_unfold) (auto simp add: sgn_mult ac_simps) qed next case False with q r have "t \ by (simp_all add: sgn_0_0) moreover from ‹0 < m› ‹u < n› have "u \ using mult_le_less_imp_less [of 1 m u n] by simp ultimately have *: "q * l + r = sgn (s * t) * int (if t < 0 then m * n - u else m * n + u)" using l q r by (simp add: sgn_mult algebra_simps of_nat_diff) have "(m * n - u) div n = m - 1" if "u > 0" using ‹0 < m› ‹u < n› that by (auto intro: div_nat_eqI simp add: algebra_simps) moreover have "n dvd m * n - u \ using ‹u ≤ m * n› dvd_diffD1 [of n "m * n" u] by auto ultimately show ?thesis using ‹s ≠ 0› ‹m > 0› ‹u > 0› ‹u < n› ‹u ≤ m * n› by (simp only: *, simp only: l q divide_int_unfold) (auto simp add: sgn_mult sgn_0_0 sgn_1_pos algebra_simps dest: dvd_imp_le) qed qed (use mult_le_mono2 [of 1] in ‹auto simp add: division_segment_int_def not_le zero_less_ end lemma euclidean_relation_intI [case_names by0 divides euclidean_relation]: --> -------------------- --> maximum size reached --> --------------------
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2026-04-02