(* Title: HOL/Algebra/FiniteProduct.thy Author: Clemens Ballarin, started 19 November 2002 This file is largely based on HOL/Finite_Set.thy. *) theory FiniteProduct imports Group begin subsection ‹Product Operator for Commutative Monoids› subsubsection ‹Inductive Definition of a Relation for Products over Sets› text ‹Instantiation of locale ‹LC› of theory ‹Finite_Set› is not possible, because here we have explicit typing rules like ‹x ∈ carrier G›. We introduce an explicit argument for the domain ‹D›.› inductive_set foldSetD :: "['a set, 'b ⇒ 'a ⇒ 'a, 'a] ⇒ ('b set * 'a) set" for D :: "'a set" and f :: "'b ⇒ 'a ⇒ 'a" and e :: 'a where emptyI [intro]: "e ∈ D ⟹ ({}, e) ∈ foldSetD D f e" | insertI [intro]: "⟦x ∉ A; f x y ∈ D; (A, y) ∈ foldSetD D f e⟧ ⟹ (insert x A, f x y) ∈ foldSetD D f e" inductive_cases empty_foldSetDE [elim!]: "({}, x) ∈ foldSetD D f e" definition foldD :: "['a set, 'b ⇒ 'a ⇒ 'a, 'a, 'b set] ⇒ 'a" where "foldD D f e A = (THE x. (A, x) ∈ foldSetD D f e)" lemma foldSetD_closed: "(A, z) ∈ foldSetD D f e ⟹ z ∈ D" by (erule foldSetD.cases) auto lemma Diff1_foldSetD: "⟦(A - {x}, y) ∈ foldSetD D f e; x ∈ A; f x y ∈ D⟧ ⟹ (A, f x y) ∈ foldSetD D f e" by (metis Diff_insert_absorb foldSetD.insertI mk_disjoint_insert) lemma foldSetD_imp_finite [simp]: "(A, x) ∈ foldSetD D f e ⟹ finite A" by (induct set: foldSetD) auto lemma finite_imp_foldSetD: "⟦finite A; e ∈ D; ⋀x y. ⟦x ∈ A; y ∈ D⟧ ⟹ f x y ∈ D⟧ ⟹ ∃x. (A, x) ∈ foldSetD D f e" proof (induct set: finite) case empty then show ?case by auto next case (insert x F) then obtain y where y: "(F, y) ∈ foldSetD D f e" by auto with insert have "y ∈ D" by (auto dest: foldSetD_closed) with y and insert have "(insert x F, f x y) ∈ foldSetD D f e" by (intro foldSetD.intros) auto then show ?case .. qed lemma foldSetD_backwards: assumes "A ≠ {}" "(A, z) ∈ foldSetD D f e" shows "∃x y. x ∈ A ∧ (A - { x }, y) ∈ foldSetD D f e ∧ z = f x y" using assms(2) by (cases) (simp add: assms(1), metis Diff_insert_absorb insertI1) subsubsection ‹Left-Commutative Operations› locale LCD = fixes B :: "'b set" and D :: "'a set" and f :: "'b ⇒ 'a ⇒ 'a" (infixl "⋅" 70) assumes left_commute: "⟦x ∈ B; y ∈ B; z ∈ D⟧ ⟹ x ⋅ (y ⋅ z) = y ⋅ (x ⋅ z)" and f_closed [simp, intro!]: "!!x y. ⟦x ∈ B; y ∈ D⟧ ⟹ f x y ∈ D" lemma (in LCD) foldSetD_closed [dest]: "(A, z) ∈ foldSetD D f e ⟹ z ∈ D" by (erule foldSetD.cases) auto lemma (in LCD) Diff1_foldSetD: "⟦(A - {x}, y) ∈ foldSetD D f e; x ∈ A; A ⊆ B⟧ ⟹ (A, f x y) ∈ foldSetD D f e" by (meson Diff1_foldSetD f_closed local.foldSetD_closed subsetCE) lemma (in LCD) finite_imp_foldSetD: "⟦finite A; A ⊆ B; e ∈ D⟧ ⟹ ∃x. (A, x) ∈ foldSetD D f e" proof (induct set: finite) case empty then show ?case by auto next case (insert x F) then obtain y where y: "(F, y) ∈ foldSetD D f e" by auto with insert have "y ∈ D" by auto with y and insert have "(insert x F, f x y) ∈ foldSetD D f e" by (intro foldSetD.intros) auto then show ?case .. qed lemma (in LCD) foldSetD_determ_aux: assumes "e ∈ D" and A: "card A < n" "A ⊆ B" "(A, x) ∈ foldSetD D f e" "(A, y) ∈ foldSetD D f e" shows "y = x" using A proof (induction n arbitrary: A x y) case 0 then show ?case by auto next case (Suc n) then consider "card A = n" | "card A < n" by linarith then show ?case proof cases case 1 show ?thesis using foldSetD.cases [OF ‹(A,x) ∈ foldSetD D (⋅) e›] proof cases case 1 then show ?thesis using ‹(A,y) ∈ foldSetD D (⋅) e› by auto next case (2 x' A' y') note A' = this show ?thesis using foldSetD.cases [OF ‹(A,y) ∈ foldSetD D (⋅) e›] proof cases case 1 then show ?thesis using ‹(A,x) ∈ foldSetD D (⋅) e› by auto next case (2 x'' A'' y'') note A'' = this show ?thesis proof (cases "x' = x''") case True show ?thesis proof (cases "y' = y''") case True then show ?thesis using A' A'' ‹x' = x''› by (blast elim!: equalityE) next case False then show ?thesis using A' A'' ‹x' = x''› by (metis ‹card A = n› Suc.IH Suc.prems(2) card_insert_disjoint foldSetD_imp_finite insert_eq_iff insert_subset lessI) qed next case False then have *: "A' - {x''} = A'' - {x'}" "x'' ∈ A'" "x' ∈ A''" using A' A'' by fastforce+ then have "A' = insert x'' A'' - {x'}" using ‹x' ∉ A'› by blast then have card: "card A' ≤ card A''" using A' A'' * by (metis card_Suc_Diff1 eq_refl foldSetD_imp_finite) obtain u where u: "(A' - {x''}, u) ∈ foldSetD D (⋅) e" using finite_imp_foldSetD [of "A' - {x''}"] A' Diff_insert ‹A ⊆ B› ‹e ∈ D› by fastforce have "y' = f x'' u" using Diff1_foldSetD [OF u] ‹x'' ∈ A'› ‹card A = n› A' Suc.IH ‹A ⊆ B› by auto then have "(A'' - {x'}, u) ∈ foldSetD D f e" using "*"(1) u by auto then have "y'' = f x' u" using A'' by (metis * ‹card A = n› A'(1) Diff1_foldSetD Suc.IH ‹A ⊆ B› card card_Suc_Diff1 card_insert_disjoint foldSetD_imp_finite insert_subset le_imp_less_Suc) then show ?thesis using A' A'' by (metis ‹A ⊆ B› ‹y' = x'' ⋅ u› insert_subset left_commute local.foldSetD_closed u) qed qed qed next case 2 with Suc show ?thesis by blast qed qed lemma (in LCD) foldSetD_determ: "⟦(A, x) ∈ foldSetD D f e; (A, y) ∈ foldSetD D f e; e ∈ D; A ⊆ B⟧ ⟹ y = x" by (blast intro: foldSetD_determ_aux [rule_format]) lemma (in LCD) foldD_equality: "⟦(A, y) ∈ foldSetD D f e; e ∈ D; A ⊆ B⟧ ⟹ foldD D f e A = y" by (unfold foldD_def) (blast intro: foldSetD_determ) lemma foldD_empty [simp]: "e ∈ D ⟹ foldD D f e {} = e" by (unfold foldD_def) blast lemma (in LCD) foldD_insert_aux: "⟦x ∉ A; x ∈ B; e ∈ D; A ⊆ B⟧ ⟹ ((insert x A, v) ∈ foldSetD D f e) ⟷ (∃y. (A, y) ∈ foldSetD D f e ∧ v = f x y)" apply auto by (metis Diff_insert_absorb f_closed finite_Diff foldSetD.insertI foldSetD_determ foldSetD_imp_finite insert_subset local.finite_imp_foldSetD local.foldSetD_closed) lemma (in LCD) foldD_insert: assumes "finite A" "x ∉ A" "x ∈ B" "e ∈ D" "A ⊆ B" shows "foldD D f e (insert x A) = f x (foldD D f e A)" proof - have "(THE v. ∃y. (A, y) ∈ foldSetD D (⋅) e ∧ v = x ⋅ y) = x ⋅ (THE y. (A, y) ∈ foldSetD D (⋅) e)" by (rule the_equality) (use assms foldD_def foldD_equality foldD_def finite_imp_foldSetD in ‹metis+›) then show ?thesis unfolding foldD_def using assms by (simp add: foldD_insert_aux) qed lemma (in LCD) foldD_closed [simp]: "⟦finite A; e ∈ D; A ⊆ B⟧ ⟹ foldD D f e A ∈ D" proof (induct set: finite) case empty then show ?case by simp next case insert then show ?case by (simp add: foldD_insert) qed lemma (in LCD) foldD_commute: "⟦finite A; x ∈ B; e ∈ D; A ⊆ B⟧ ⟹ f x (foldD D f e A) = foldD D f (f x e) A" by (induct set: finite) (auto simp add: left_commute foldD_insert) lemma Int_mono2: "⟦A ⊆ C; B ⊆ C⟧ ⟹ A Int B ⊆ C" by blast lemma (in LCD) foldD_nest_Un_Int: "⟦finite A; finite C; e ∈ D; A ⊆ B; C ⊆ B⟧ ⟹ foldD D f (foldD D f e C) A = foldD D f (foldD D f e (A Int C)) (A Un C)" proof (induction set: finite) case (insert x F) then show ?case by (simp add: foldD_insert foldD_commute Int_insert_left insert_absorb Int_mono2) qed simp lemma (in LCD) foldD_nest_Un_disjoint: "⟦finite A; finite B; A Int B = {}; e ∈ D; A ⊆ B; C ⊆ B⟧ ⟹ foldD D f e (A Un B) = foldD D f (foldD D f e B) A" by (simp add: foldD_nest_Un_Int) ― ‹Delete rules to do with ‹foldSetD› relation.› declare foldSetD_imp_finite [simp del] empty_foldSetDE [rule del] foldSetD.intros [rule del] declare (in LCD) foldSetD_closed [rule del] text ‹Commutative Monoids› text ‹ We enter a more restrictive context, with ‹f :: 'a ⇒ 'a ⇒ 'a› instead of ‹'b ⇒ 'a ⇒ 'a›. › locale ACeD = fixes D :: "'a set" and f :: "'a ⇒ 'a ⇒ 'a" (infixl "⋅" 70) and e :: 'a assumes ident [simp]: "x ∈ D ⟹ x ⋅ e = x" and commute: "⟦x ∈ D; y ∈ D⟧ ⟹ x ⋅ y = y ⋅ x" and assoc: "⟦x ∈ D; y ∈ D; z ∈ D⟧ ⟹ (x ⋅ y) ⋅ z = x ⋅ (y ⋅ z)" and e_closed [simp]: "e ∈ D" and f_closed [simp]: "⟦x ∈ D; y ∈ D⟧ ⟹ x ⋅ y ∈ D" lemma (in ACeD) left_commute: "⟦x ∈ D; y ∈ D; z ∈ D⟧ ⟹ x ⋅ (y ⋅ z) = y ⋅ (x ⋅ z)" proof - assume D: "x ∈ D" "y ∈ D" "z ∈ D" then have "x ⋅ (y ⋅ z) = (y ⋅ z) ⋅ x" by (simp add: commute) also from D have "... = y ⋅ (z ⋅ x)" by (simp add: assoc) also from D have "z ⋅ x = x ⋅ z" by (simp add: commute) finally show ?thesis . qed lemmas (in ACeD) AC = assoc commute left_commute lemma (in ACeD) left_ident [simp]: "x ∈ D ⟹ e ⋅ x = x" proof - assume "x ∈ D" then have "x ⋅ e = x" by (rule ident) with ‹x ∈ D› show ?thesis by (simp add: commute) qed lemma (in ACeD) foldD_Un_Int: "⟦finite A; finite B; A ⊆ D; B ⊆ D⟧ ⟹ foldD D f e A ⋅ foldD D f e B = foldD D f e (A Un B) ⋅ foldD D f e (A Int B)" proof (induction set: finite) case empty then show ?case by(simp add: left_commute LCD.foldD_closed [OF LCD.intro [of D]]) next case (insert x F) then show ?case by(simp add: AC insert_absorb Int_insert_left Int_mono2 LCD.foldD_insert [OF LCD.intro [of D]] LCD.foldD_closed [OF LCD.intro [of D]]) qed lemma (in ACeD) foldD_Un_disjoint: "⟦finite A; finite B; A Int B = {}; A ⊆ D; B ⊆ D⟧ ⟹ foldD D f e (A Un B) = foldD D f e A ⋅ foldD D f e B" by (simp add: foldD_Un_Int left_commute LCD.foldD_closed [OF LCD.intro [of D]]) subsubsection ‹Products over Finite Sets› definition finprod :: "[('b, 'm) monoid_scheme, 'a ⇒ 'b, 'a set] ⇒ 'b" where "finprod G f A = (if finite A then foldD (carrier G) (mult G ∘ f) 𝟭⇘G⇙ A else 𝟭⇘G⇙)" syntax "_finprod" :: "index ⇒ idt ⇒ 'a set ⇒ 'b ⇒ 'b" ("(3⨂__∈_. _)" [1000, 0, 51, 10] 10) translations "⨂⇘G⇙i∈A. b" ⇌ "CONST finprod G (%i. b) A" ― ‹Beware of argument permutation!› lemma (in comm_monoid) finprod_empty [simp]: "finprod G f {} = 𝟭" by (simp add: finprod_def) lemma (in comm_monoid) finprod_infinite[simp]: "¬ finite A ⟹ finprod G f A = 𝟭" by (simp add: finprod_def) declare funcsetI [intro] funcset_mem [dest] context comm_monoid begin lemma finprod_insert [simp]: assumes "finite F" "a ∉ F" "f ∈ F → carrier G" "f a ∈ carrier G" shows "finprod G f (insert a F) = f a ⊗ finprod G f F" proof - have "finprod G f (insert a F) = foldD (carrier G) ((⊗) ∘ f) 𝟭 (insert a F)" by (simp add: finprod_def assms) also have "... = ((⊗) ∘ f) a (foldD (carrier G) ((⊗) ∘ f) 𝟭 F)" by (rule LCD.foldD_insert [OF LCD.intro [of "insert a F"]]) (use assms in ‹auto simp: m_lcomm Pi_iff›) also have "... = f a ⊗ finprod G f F" using ‹finite F› by (auto simp add: finprod_def) finally show ?thesis . qed lemma finprod_one_eqI: "(⋀x. x ∈ A ⟹ f x = 𝟭) ⟹ finprod G f A = 𝟭" proof (induct A rule: infinite_finite_induct) case empty show ?case by simp next case (insert a A) have "(λi. 𝟭) ∈ A → carrier G" by auto with insert show ?case by simp qed simp lemma finprod_one [simp]: "(⨂i∈A. 𝟭) = 𝟭" by (simp add: finprod_one_eqI) lemma finprod_closed [simp]: fixes A assumes f: "f ∈ A → carrier G" shows "finprod G f A ∈ carrier G" using f proof (induct A rule: infinite_finite_induct) case empty show ?case by simp next case (insert a A) then have a: "f a ∈ carrier G" by fast from insert have A: "f ∈ A → carrier G" by fast from insert A a show ?case by simp qed simp lemma funcset_Int_left [simp, intro]: "⟦f ∈ A → C; f ∈ B → C⟧ ⟹ f ∈ A Int B → C" by fast lemma funcset_Un_left [iff]: "(f ∈ A Un B → C) = (f ∈ A → C ∧ f ∈ B → C)" by fast lemma finprod_Un_Int: "⟦finite A; finite B; g ∈ A → carrier G; g ∈ B → carrier G⟧ ⟹ finprod G g (A Un B) ⊗ finprod G g (A Int B) = finprod G g A ⊗ finprod G g B" ― ‹The reversed orientation looks more natural, but LOOPS as a simprule!› proof (induct set: finite) case empty then show ?case by simp next case (insert a A) then have a: "g a ∈ carrier G" by fast from insert have A: "g ∈ A → carrier G" by fast from insert A a show ?case by (simp add: m_ac Int_insert_left insert_absorb Int_mono2) qed lemma finprod_Un_disjoint: "⟦finite A; finite B; A Int B = {}; g ∈ A → carrier G; g ∈ B → carrier G⟧ ⟹ finprod G g (A Un B) = finprod G g A ⊗ finprod G g B" by (metis Pi_split_domain finprod_Un_Int finprod_closed finprod_empty r_one) lemma finprod_multf [simp]: "⟦f ∈ A → carrier G; g ∈ A → carrier G⟧ ⟹ finprod G (λx. f x ⊗ g x) A = (finprod G f A ⊗ finprod G g A)" proof (induct A rule: infinite_finite_induct) case empty show ?case by simp next case (insert a A) then have fA: "f ∈ A → carrier G" by fast from insert have fa: "f a ∈ carrier G" by fast from insert have gA: "g ∈ A → carrier G" by fast from insert have ga: "g a ∈ carrier G" by fast from insert have fgA: "(%x. f x ⊗ g x) ∈ A → carrier G" by (simp add: Pi_def) show ?case by (simp add: insert fA fa gA ga fgA m_ac) qed simp lemma finprod_cong': "⟦A = B; g ∈ B → carrier G; !!i. i ∈ B ⟹ f i = g i⟧ ⟹ finprod G f A = finprod G g B" proof - assume prems: "A = B" "g ∈ B → carrier G" "!!i. i ∈ B ⟹ f i = g i" show ?thesis proof (cases "finite B") case True then have "!!A. ⟦A = B; g ∈ B → carrier G; !!i. i ∈ B ⟹ f i = g i⟧ ⟹ finprod G f A = finprod G g B" proof induct case empty thus ?case by simp next case (insert x B) then have "finprod G f A = finprod G f (insert x B)" by simp also from insert have "... = f x ⊗ finprod G f B" proof (intro finprod_insert) show "finite B" by fact next show "x ∉ B" by fact next assume "x ∉ B" "!!i. i ∈ insert x B ⟹ f i = g i" "g ∈ insert x B → carrier G" thus "f ∈ B → carrier G" by fastforce next assume "x ∉ B" "!!i. i ∈ insert x B ⟹ f i = g i" "g ∈ insert x B → carrier G" thus "f x ∈ carrier G" by fastforce qed also from insert have "... = g x ⊗ finprod G g B" by fastforce also from insert have "... = finprod G g (insert x B)" by (intro finprod_insert [THEN sym]) auto finally show ?case . qed with prems show ?thesis by simp next case False with prems show ?thesis by simp qed qed lemma finprod_cong: "⟦A = B; f ∈ B → carrier G = True; ⋀i. i ∈ B =simp=> f i = g i⟧ ⟹ finprod G f A = finprod G g B" (* This order of prems is slightly faster (3%) than the last two swapped. *) by (rule finprod_cong') (auto simp add: simp_implies_def) text ‹Usually, if this rule causes a failed congruence proof error, the reason is that the premise ‹g ∈ B → carrier G› cannot be shown. Adding @{thm [source] Pi_def} to the simpset is often useful. For this reason, @{thm [source] finprod_cong} is not added to the simpset by default. › end declare funcsetI [rule del] funcset_mem [rule del] context comm_monoid begin lemma finprod_0 [simp]: "f ∈ {0::nat} → carrier G ⟹ finprod G f {..0} = f 0" by (simp add: Pi_def) lemma finprod_0': "f ∈ {..n} → carrier G ⟹ (f 0) ⊗ finprod G f {Suc 0..n} = finprod G f {..n}" proof - assume A: "f ∈ {.. n} → carrier G" hence "(f 0) ⊗ finprod G f {Suc 0..n} = finprod G f {..0} ⊗ finprod G f {Suc 0..n}" using finprod_0[of f] by (simp add: funcset_mem) also have " ... = finprod G f ({..0} ∪ {Suc 0..n})" using finprod_Un_disjoint[of "{..0}" "{Suc 0..n}" f] A by (simp add: funcset_mem) also have " ... = finprod G f {..n}" by (simp add: atLeastAtMost_insertL atMost_atLeast0) finally show ?thesis . qed lemma finprod_Suc [simp]: "f ∈ {..Suc n} → carrier G ⟹ finprod G f {..Suc n} = (f (Suc n) ⊗ finprod G f {..n})" by (simp add: Pi_def atMost_Suc) lemma finprod_Suc2: "f ∈ {..Suc n} → carrier G ⟹ finprod G f {..Suc n} = (finprod G (%i. f (Suc i)) {..n} ⊗ f 0)" proof (induct n) case 0 thus ?case by (simp add: Pi_def) next case Suc thus ?case by (simp add: m_assoc Pi_def) qed lemma finprod_Suc3: assumes "f ∈ {..n :: nat} → carrier G" shows "finprod G f {.. n} = (f n) ⊗ finprod G f {..< n}" proof (cases "n = 0") case True thus ?thesis using assms atMost_Suc by simp next case False then obtain k where "n = Suc k" using not0_implies_Suc by blast thus ?thesis using finprod_Suc[of f k] assms atMost_Suc lessThan_Suc_atMost by simp qed lemma finprod_reindex: ✐‹contributor ‹Jeremy Avigad›› "f ∈ (h ` A) → carrier G ⟹ inj_on h A ⟹ finprod G f (h ` A) = finprod G (λx. f (h x)) A" proof (induct A rule: infinite_finite_induct) case (infinite A) hence "¬ finite (h ` A)" using finite_imageD by blast with ‹¬ finite A› show ?case by simp qed (auto simp add: Pi_def) lemma finprod_const: ✐‹contributor ‹Jeremy Avigad›› assumes a [simp]: "a ∈ carrier G" shows "finprod G (λx. a) A = a [^] card A" proof (induct A rule: infinite_finite_induct) case (insert b A) show ?case proof (subst finprod_insert[OF insert(1-2)]) show "a ⊗ (⨂x∈A. a) = a [^] card (insert b A)" by (insert insert, auto, subst m_comm, auto) qed auto qed auto lemma finprod_singleton: ✐‹contributor ‹Jesus Aransay›› assumes i_in_A: "i ∈ A" and fin_A: "finite A" and f_Pi: "f ∈ A → carrier G" shows "(⨂j∈A. if i = j then f j else 𝟭) = f i" using i_in_A finprod_insert [of "A - {i}" i "(λj. if i = j then f j else 𝟭)"] fin_A f_Pi finprod_one [of "A - {i}"] finprod_cong [of "A - {i}" "A - {i}" "(λj. if i = j then f j else 𝟭)" "(λi. 𝟭)"] unfolding Pi_def simp_implies_def by (force simp add: insert_absorb) lemma finprod_singleton_swap: assumes i_in_A: "i ∈ A" and fin_A: "finite A" and f_Pi: "f ∈ A → carrier G" shows "(⨂j∈A. if j = i then f j else 𝟭) = f i" using finprod_singleton [OF assms] by (simp add: eq_commute) lemma finprod_mono_neutral_cong_left: assumes "finite B" and "A ⊆ B" and 1: "⋀i. i ∈ B - A ⟹ h i = 𝟭" and gh: "⋀x. x ∈ A ⟹ g x = h x" and h: "h ∈ B → carrier G" shows "finprod G g A = finprod G h B" proof- have eq: "A ∪ (B - A) = B" using ‹A ⊆ B› by blast have d: "A ∩ (B - A) = {}" using ‹A ⊆ B› by blast from ‹finite B› ‹A ⊆ B› have f: "finite A" "finite (B - A)" by (auto intro: finite_subset) have "h ∈ A → carrier G" "h ∈ B - A → carrier G" using assms by (auto simp: image_subset_iff_funcset) moreover have "finprod G g A = finprod G h A ⊗ finprod G h (B - A)" proof - have "finprod G h (B - A) = 𝟭" using "1" finprod_one_eqI by blast moreover have "finprod G g A = finprod G h A" using ‹h ∈ A → carrier G› finprod_cong' gh by blast ultimately show ?thesis by (simp add: ‹h ∈ A → carrier G›) qed ultimately show ?thesis by (simp add: finprod_Un_disjoint [OF f d, unfolded eq]) qed lemma finprod_mono_neutral_cong_right: assumes "finite B" and "A ⊆ B" "⋀i. i ∈ B - A ⟹ g i = 𝟭" "⋀x. x ∈ A ⟹ g x = h x" "g ∈ B → carrier G" shows "finprod G g B = finprod G h A" using assms by (auto intro!: finprod_mono_neutral_cong_left [symmetric]) lemma finprod_mono_neutral_cong: assumes [simp]: "finite B" "finite A" and *: "⋀i. i ∈ B - A ⟹ h i = 𝟭" "⋀i. i ∈ A - B ⟹ g i = 𝟭" and gh: "⋀x. x ∈ A ∩ B ⟹ g x = h x" and g: "g ∈ A → carrier G" and h: "h ∈ B → carrier G" shows "finprod G g A = finprod G h B" proof- have "finprod G g A = finprod G g (A ∩ B)" by (rule finprod_mono_neutral_cong_right) (use assms in auto) also have "… = finprod G h (A ∩ B)" by (rule finprod_cong) (use assms in auto) also have "… = finprod G h B" by (rule finprod_mono_neutral_cong_left) (use assms in auto) finally show ?thesis . qed end (* Jeremy Avigad. This should be generalized to arbitrary groups, not just commutative ones, using Lagrange's theorem. *) lemma (in comm_group) power_order_eq_one: assumes fin [simp]: "finite (carrier G)" and a [simp]: "a ∈ carrier G" shows "a [^] card(carrier G) = one G" proof - have "(⨂x∈carrier G. x) = (⨂x∈carrier G. a ⊗ x)" by (subst (2) finprod_reindex [symmetric], auto simp add: Pi_def inj_on_cmult surj_const_mult) also have "… = (⨂x∈carrier G. a) ⊗ (⨂x∈carrier G. x)" by (auto simp add: finprod_multf Pi_def) also have "(⨂x∈carrier G. a) = a [^] card(carrier G)" by (auto simp add: finprod_const) finally show ?thesis by auto qed lemma (in comm_monoid) finprod_UN_disjoint: assumes "finite I" "⋀i. i ∈ I ⟹ finite (A i)" "pairwise (λi j. disjnt (A i) (A j)) I" "⋀i x. i ∈ I ⟹ x ∈ A i ⟹ g x ∈ carrier G" shows "finprod G g (⋃(A ` I)) = finprod G (λi. finprod G g (A i)) I" using assms proof (induction set: finite) case empty then show ?case by force next case (insert i I) then show ?case unfolding pairwise_def disjnt_def apply clarsimp apply (subst finprod_Un_disjoint) apply (fastforce intro!: funcsetI finprod_closed)+ done qed lemma (in comm_monoid) finprod_Union_disjoint: "⟦finite C; ⋀A. A ∈ C ⟹ finite A ∧ (∀x∈A. f x ∈ carrier G); pairwise disjnt C⟧ ⟹ finprod G f (⋃C) = finprod G (finprod G f) C" by (frule finprod_UN_disjoint [of C id f]) auto end