author | paulson <lp15@cam.ac.uk> |
Mon, 28 Aug 2017 20:33:08 +0100 | |
changeset 66537 | e2249cd6df67 |
parent 63982 | 4c4049e3bad8 |
child 67443 | 3abf6a722518 |
permissions | -rw-r--r-- |
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(* Title: HOL/Finite_Set.thy |
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Author: Tobias Nipkow |
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Author: Lawrence C Paulson |
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Author: Markus Wenzel |
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Author: Jeremy Avigad |
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Author: Andrei Popescu |
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*) |
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section \<open>Finite sets\<close> |
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theory Finite_Set |
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imports Product_Type Sum_Type Fields |
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begin |
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subsection \<open>Predicate for finite sets\<close> |
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|
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context notes [[inductive_internals]] |
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begin |
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inductive finite :: "'a set \<Rightarrow> bool" |
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where |
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emptyI [simp, intro!]: "finite {}" |
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| insertI [simp, intro!]: "finite A \<Longrightarrow> finite (insert a A)" |
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end |
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simproc_setup finite_Collect ("finite (Collect P)") = \<open>K Set_Comprehension_Pointfree.simproc\<close> |
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declare [[simproc del: finite_Collect]] |
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lemma finite_induct [case_names empty insert, induct set: finite]: |
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\<comment> \<open>Discharging \<open>x \<notin> F\<close> entails extra work.\<close> |
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assumes "finite F" |
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assumes "P {}" |
|
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and insert: "\<And>x F. finite F \<Longrightarrow> x \<notin> F \<Longrightarrow> P F \<Longrightarrow> P (insert x F)" |
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shows "P F" |
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using \<open>finite F\<close> |
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proof induct |
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show "P {}" by fact |
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next |
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fix x F |
|
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assume F: "finite F" and P: "P F" |
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show "P (insert x F)" |
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proof cases |
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assume "x \<in> F" |
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then have "insert x F = F" by (rule insert_absorb) |
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with P show ?thesis by (simp only:) |
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next |
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assume "x \<notin> F" |
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from F this P show ?thesis by (rule insert) |
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qed |
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qed |
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||
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lemma infinite_finite_induct [case_names infinite empty insert]: |
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assumes infinite: "\<And>A. \<not> finite A \<Longrightarrow> P A" |
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and empty: "P {}" |
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and insert: "\<And>x F. finite F \<Longrightarrow> x \<notin> F \<Longrightarrow> P F \<Longrightarrow> P (insert x F)" |
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shows "P A" |
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proof (cases "finite A") |
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case False |
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with infinite show ?thesis . |
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next |
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case True |
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then show ?thesis by (induct A) (fact empty insert)+ |
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qed |
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||
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subsubsection \<open>Choice principles\<close> |
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|
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lemma ex_new_if_finite: \<comment> "does not depend on def of finite at all" |
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assumes "\<not> finite (UNIV :: 'a set)" and "finite A" |
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shows "\<exists>a::'a. a \<notin> A" |
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proof - |
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from assms have "A \<noteq> UNIV" by blast |
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then show ?thesis by blast |
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qed |
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||
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text \<open>A finite choice principle. Does not need the SOME choice operator.\<close> |
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|
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lemma finite_set_choice: "finite A \<Longrightarrow> \<forall>x\<in>A. \<exists>y. P x y \<Longrightarrow> \<exists>f. \<forall>x\<in>A. P x (f x)" |
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proof (induct rule: finite_induct) |
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case empty |
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then show ?case by simp |
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next |
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case (insert a A) |
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then obtain f b where f: "\<forall>x\<in>A. P x (f x)" and ab: "P a b" |
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by auto |
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show ?case (is "\<exists>f. ?P f") |
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proof |
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show "?P (\<lambda>x. if x = a then b else f x)" |
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using f ab by auto |
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qed |
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qed |
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||
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subsubsection \<open>Finite sets are the images of initial segments of natural numbers\<close> |
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|
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lemma finite_imp_nat_seg_image_inj_on: |
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assumes "finite A" |
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shows "\<exists>(n::nat) f. A = f ` {i. i < n} \<and> inj_on f {i. i < n}" |
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using assms |
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proof induct |
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case empty |
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show ?case |
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proof |
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show "\<exists>f. {} = f ` {i::nat. i < 0} \<and> inj_on f {i. i < 0}" |
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by simp |
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qed |
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next |
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case (insert a A) |
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have notinA: "a \<notin> A" by fact |
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from insert.hyps obtain n f where "A = f ` {i::nat. i < n}" "inj_on f {i. i < n}" |
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by blast |
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then have "insert a A = f(n:=a) ` {i. i < Suc n}" and "inj_on (f(n:=a)) {i. i < Suc n}" |
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using notinA by (auto simp add: image_def Ball_def inj_on_def less_Suc_eq) |
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then show ?case by blast |
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qed |
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||
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lemma nat_seg_image_imp_finite: "A = f ` {i::nat. i < n} \<Longrightarrow> finite A" |
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proof (induct n arbitrary: A) |
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case 0 |
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then show ?case by simp |
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next |
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case (Suc n) |
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let ?B = "f ` {i. i < n}" |
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have finB: "finite ?B" by (rule Suc.hyps[OF refl]) |
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show ?case |
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proof (cases "\<exists>k<n. f n = f k") |
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case True |
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then have "A = ?B" |
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using Suc.prems by (auto simp:less_Suc_eq) |
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then show ?thesis |
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using finB by simp |
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next |
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case False |
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then have "A = insert (f n) ?B" |
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using Suc.prems by (auto simp:less_Suc_eq) |
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then show ?thesis using finB by simp |
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qed |
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qed |
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||
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lemma finite_conv_nat_seg_image: "finite A \<longleftrightarrow> (\<exists>n f. A = f ` {i::nat. i < n})" |
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by (blast intro: nat_seg_image_imp_finite dest: finite_imp_nat_seg_image_inj_on) |
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lemma finite_imp_inj_to_nat_seg: |
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assumes "finite A" |
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shows "\<exists>f n. f ` A = {i::nat. i < n} \<and> inj_on f A" |
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proof - |
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from finite_imp_nat_seg_image_inj_on [OF \<open>finite A\<close>] |
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obtain f and n :: nat where bij: "bij_betw f {i. i<n} A" |
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by (auto simp: bij_betw_def) |
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let ?f = "the_inv_into {i. i<n} f" |
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have "inj_on ?f A \<and> ?f ` A = {i. i<n}" |
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by (fold bij_betw_def) (rule bij_betw_the_inv_into[OF bij]) |
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then show ?thesis by blast |
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qed |
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||
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lemma finite_Collect_less_nat [iff]: "finite {n::nat. n < k}" |
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by (fastforce simp: finite_conv_nat_seg_image) |
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lemma finite_Collect_le_nat [iff]: "finite {n::nat. n \<le> k}" |
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by (simp add: le_eq_less_or_eq Collect_disj_eq) |
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subsubsection \<open>Finiteness and common set operations\<close> |
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lemma rev_finite_subset: "finite B \<Longrightarrow> A \<subseteq> B \<Longrightarrow> finite A" |
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proof (induct arbitrary: A rule: finite_induct) |
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case empty |
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then show ?case by simp |
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next |
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case (insert x F A) |
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have A: "A \<subseteq> insert x F" and r: "A - {x} \<subseteq> F \<Longrightarrow> finite (A - {x})" |
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by fact+ |
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show "finite A" |
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proof cases |
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assume x: "x \<in> A" |
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with A have "A - {x} \<subseteq> F" by (simp add: subset_insert_iff) |
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with r have "finite (A - {x})" . |
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then have "finite (insert x (A - {x}))" .. |
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also have "insert x (A - {x}) = A" |
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using x by (rule insert_Diff) |
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finally show ?thesis . |
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next |
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show ?thesis when "A \<subseteq> F" |
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using that by fact |
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assume "x \<notin> A" |
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with A show "A \<subseteq> F" |
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by (simp add: subset_insert_iff) |
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qed |
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qed |
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||
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lemma finite_subset: "A \<subseteq> B \<Longrightarrow> finite B \<Longrightarrow> finite A" |
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by (rule rev_finite_subset) |
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|
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lemma finite_UnI: |
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assumes "finite F" and "finite G" |
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shows "finite (F \<union> G)" |
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using assms by induct simp_all |
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|
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lemma finite_Un [iff]: "finite (F \<union> G) \<longleftrightarrow> finite F \<and> finite G" |
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by (blast intro: finite_UnI finite_subset [of _ "F \<union> G"]) |
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|
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lemma finite_insert [simp]: "finite (insert a A) \<longleftrightarrow> finite A" |
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proof - |
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have "finite {a} \<and> finite A \<longleftrightarrow> finite A" by simp |
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then have "finite ({a} \<union> A) \<longleftrightarrow> finite A" by (simp only: finite_Un) |
|
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then show ?thesis by simp |
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qed |
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||
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lemma finite_Int [simp, intro]: "finite F \<or> finite G \<Longrightarrow> finite (F \<inter> G)" |
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by (blast intro: finite_subset) |
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lemma finite_Collect_conjI [simp, intro]: |
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"finite {x. P x} \<or> finite {x. Q x} \<Longrightarrow> finite {x. P x \<and> Q x}" |
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by (simp add: Collect_conj_eq) |
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lemma finite_Collect_disjI [simp]: |
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"finite {x. P x \<or> Q x} \<longleftrightarrow> finite {x. P x} \<and> finite {x. Q x}" |
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by (simp add: Collect_disj_eq) |
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||
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lemma finite_Diff [simp, intro]: "finite A \<Longrightarrow> finite (A - B)" |
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by (rule finite_subset, rule Diff_subset) |
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lemma finite_Diff2 [simp]: |
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assumes "finite B" |
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shows "finite (A - B) \<longleftrightarrow> finite A" |
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proof - |
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have "finite A \<longleftrightarrow> finite ((A - B) \<union> (A \<inter> B))" |
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by (simp add: Un_Diff_Int) |
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also have "\<dots> \<longleftrightarrow> finite (A - B)" |
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using \<open>finite B\<close> by simp |
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finally show ?thesis .. |
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qed |
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||
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lemma finite_Diff_insert [iff]: "finite (A - insert a B) \<longleftrightarrow> finite (A - B)" |
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proof - |
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have "finite (A - B) \<longleftrightarrow> finite (A - B - {a})" by simp |
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moreover have "A - insert a B = A - B - {a}" by auto |
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ultimately show ?thesis by simp |
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qed |
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||
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lemma finite_compl [simp]: |
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"finite (A :: 'a set) \<Longrightarrow> finite (- A) \<longleftrightarrow> finite (UNIV :: 'a set)" |
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by (simp add: Compl_eq_Diff_UNIV) |
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|
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lemma finite_Collect_not [simp]: |
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"finite {x :: 'a. P x} \<Longrightarrow> finite {x. \<not> P x} \<longleftrightarrow> finite (UNIV :: 'a set)" |
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by (simp add: Collect_neg_eq) |
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||
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lemma finite_Union [simp, intro]: |
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"finite A \<Longrightarrow> (\<And>M. M \<in> A \<Longrightarrow> finite M) \<Longrightarrow> finite (\<Union>A)" |
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by (induct rule: finite_induct) simp_all |
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||
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lemma finite_UN_I [intro]: |
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"finite A \<Longrightarrow> (\<And>a. a \<in> A \<Longrightarrow> finite (B a)) \<Longrightarrow> finite (\<Union>a\<in>A. B a)" |
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by (induct rule: finite_induct) simp_all |
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|
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lemma finite_UN [simp]: "finite A \<Longrightarrow> finite (UNION A B) \<longleftrightarrow> (\<forall>x\<in>A. finite (B x))" |
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by (blast intro: finite_subset) |
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lemma finite_Inter [intro]: "\<exists>A\<in>M. finite A \<Longrightarrow> finite (\<Inter>M)" |
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by (blast intro: Inter_lower finite_subset) |
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|
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lemma finite_INT [intro]: "\<exists>x\<in>I. finite (A x) \<Longrightarrow> finite (\<Inter>x\<in>I. A x)" |
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by (blast intro: INT_lower finite_subset) |
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|
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lemma finite_imageI [simp, intro]: "finite F \<Longrightarrow> finite (h ` F)" |
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by (induct rule: finite_induct) simp_all |
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|
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lemma finite_image_set [simp]: "finite {x. P x} \<Longrightarrow> finite {f x |x. P x}" |
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by (simp add: image_Collect [symmetric]) |
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lemma finite_image_set2: |
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"finite {x. P x} \<Longrightarrow> finite {y. Q y} \<Longrightarrow> finite {f x y |x y. P x \<and> Q y}" |
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by (rule finite_subset [where B = "\<Union>x \<in> {x. P x}. \<Union>y \<in> {y. Q y}. {f x y}"]) auto |
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|
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lemma finite_imageD: |
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assumes "finite (f ` A)" and "inj_on f A" |
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shows "finite A" |
|
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using assms |
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proof (induct "f ` A" arbitrary: A) |
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case empty |
284 |
then show ?case by simp |
|
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next |
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case (insert x B) |
|
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then have B_A: "insert x B = f ` A" |
288 |
by simp |
|
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then obtain y where "x = f y" and "y \<in> A" |
|
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by blast |
|
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from B_A \<open>x \<notin> B\<close> have "B = f ` A - {x}" |
|
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by blast |
|
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with B_A \<open>x \<notin> B\<close> \<open>x = f y\<close> \<open>inj_on f A\<close> \<open>y \<in> A\<close> have "B = f ` (A - {y})" |
|
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by (simp add: inj_on_image_set_diff Set.Diff_subset) |
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moreover from \<open>inj_on f A\<close> have "inj_on f (A - {y})" |
296 |
by (rule inj_on_diff) |
|
297 |
ultimately have "finite (A - {y})" |
|
298 |
by (rule insert.hyps) |
|
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then show "finite A" |
|
300 |
by simp |
|
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qed |
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|
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lemma finite_image_iff: "inj_on f A \<Longrightarrow> finite (f ` A) \<longleftrightarrow> finite A" |
304 |
using finite_imageD by blast |
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|
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lemma finite_surj: "finite A \<Longrightarrow> B \<subseteq> f ` A \<Longrightarrow> finite B" |
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by (erule finite_subset) (rule finite_imageI) |
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|
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lemma finite_range_imageI: "finite (range g) \<Longrightarrow> finite (range (\<lambda>x. f (g x)))" |
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by (drule finite_imageI) (simp add: range_composition) |
13825 | 311 |
|
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lemma finite_subset_image: |
313 |
assumes "finite B" |
|
314 |
shows "B \<subseteq> f ` A \<Longrightarrow> \<exists>C\<subseteq>A. finite C \<and> B = f ` C" |
|
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using assms |
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316 |
proof induct |
63404 | 317 |
case empty |
318 |
then show ?case by simp |
|
41656 | 319 |
next |
63404 | 320 |
case insert |
321 |
then show ?case |
|
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by (clarsimp simp del: image_insert simp add: image_insert [symmetric]) blast (* slow *) |
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qed |
324 |
||
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lemma finite_vimage_IntI: "finite F \<Longrightarrow> inj_on h A \<Longrightarrow> finite (h -` F \<inter> A)" |
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apply (induct rule: finite_induct) |
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apply simp_all |
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apply (subst vimage_insert) |
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apply (simp add: finite_subset [OF inj_on_vimage_singleton] Int_Un_distrib2) |
13825 | 330 |
done |
331 |
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332 |
lemma finite_finite_vimage_IntI: |
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assumes "finite F" |
334 |
and "\<And>y. y \<in> F \<Longrightarrow> finite ((h -` {y}) \<inter> A)" |
|
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shows "finite (h -` F \<inter> A)" |
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proof - |
d50b993b4fb9
Removal of redundant lemmas (diff_less_iff, diff_le_iff) and of the abbreviation Exp. Addition of some new material.
paulson <lp15@cam.ac.uk>
parents:
61681
diff
changeset
|
337 |
have *: "h -` F \<inter> A = (\<Union> y\<in>F. (h -` {y}) \<inter> A)" |
d50b993b4fb9
Removal of redundant lemmas (diff_less_iff, diff_le_iff) and of the abbreviation Exp. Addition of some new material.
paulson <lp15@cam.ac.uk>
parents:
61681
diff
changeset
|
338 |
by blast |
d50b993b4fb9
Removal of redundant lemmas (diff_less_iff, diff_le_iff) and of the abbreviation Exp. Addition of some new material.
paulson <lp15@cam.ac.uk>
parents:
61681
diff
changeset
|
339 |
show ?thesis |
d50b993b4fb9
Removal of redundant lemmas (diff_less_iff, diff_le_iff) and of the abbreviation Exp. Addition of some new material.
paulson <lp15@cam.ac.uk>
parents:
61681
diff
changeset
|
340 |
by (simp only: * assms finite_UN_I) |
d50b993b4fb9
Removal of redundant lemmas (diff_less_iff, diff_le_iff) and of the abbreviation Exp. Addition of some new material.
paulson <lp15@cam.ac.uk>
parents:
61681
diff
changeset
|
341 |
qed |
d50b993b4fb9
Removal of redundant lemmas (diff_less_iff, diff_le_iff) and of the abbreviation Exp. Addition of some new material.
paulson <lp15@cam.ac.uk>
parents:
61681
diff
changeset
|
342 |
|
63404 | 343 |
lemma finite_vimageI: "finite F \<Longrightarrow> inj h \<Longrightarrow> finite (h -` F)" |
43991 | 344 |
using finite_vimage_IntI[of F h UNIV] by auto |
345 |
||
63404 | 346 |
lemma finite_vimageD': "finite (f -` A) \<Longrightarrow> A \<subseteq> range f \<Longrightarrow> finite A" |
347 |
by (auto simp add: subset_image_iff intro: finite_subset[rotated]) |
|
59519
2fb0c0fc62a3
add more general version of finite_vimageD
Andreas Lochbihler
parents:
59504
diff
changeset
|
348 |
|
63404 | 349 |
lemma finite_vimageD: "finite (h -` F) \<Longrightarrow> surj h \<Longrightarrow> finite F" |
350 |
by (auto dest: finite_vimageD') |
|
34111
1b015caba46c
add lemmas rev_finite_subset, finite_vimageD, finite_vimage_iff
huffman
parents:
34007
diff
changeset
|
351 |
|
1b015caba46c
add lemmas rev_finite_subset, finite_vimageD, finite_vimage_iff
huffman
parents:
34007
diff
changeset
|
352 |
lemma finite_vimage_iff: "bij h \<Longrightarrow> finite (h -` F) \<longleftrightarrow> finite F" |
1b015caba46c
add lemmas rev_finite_subset, finite_vimageD, finite_vimage_iff
huffman
parents:
34007
diff
changeset
|
353 |
unfolding bij_def by (auto elim: finite_vimageD finite_vimageI) |
1b015caba46c
add lemmas rev_finite_subset, finite_vimageD, finite_vimage_iff
huffman
parents:
34007
diff
changeset
|
354 |
|
41656 | 355 |
lemma finite_Collect_bex [simp]: |
356 |
assumes "finite A" |
|
357 |
shows "finite {x. \<exists>y\<in>A. Q x y} \<longleftrightarrow> (\<forall>y\<in>A. finite {x. Q x y})" |
|
358 |
proof - |
|
359 |
have "{x. \<exists>y\<in>A. Q x y} = (\<Union>y\<in>A. {x. Q x y})" by auto |
|
360 |
with assms show ?thesis by simp |
|
361 |
qed |
|
12396 | 362 |
|
41656 | 363 |
lemma finite_Collect_bounded_ex [simp]: |
364 |
assumes "finite {y. P y}" |
|
365 |
shows "finite {x. \<exists>y. P y \<and> Q x y} \<longleftrightarrow> (\<forall>y. P y \<longrightarrow> finite {x. Q x y})" |
|
366 |
proof - |
|
63404 | 367 |
have "{x. \<exists>y. P y \<and> Q x y} = (\<Union>y\<in>{y. P y}. {x. Q x y})" |
368 |
by auto |
|
369 |
with assms show ?thesis |
|
370 |
by simp |
|
41656 | 371 |
qed |
29920 | 372 |
|
63404 | 373 |
lemma finite_Plus: "finite A \<Longrightarrow> finite B \<Longrightarrow> finite (A <+> B)" |
41656 | 374 |
by (simp add: Plus_def) |
17022 | 375 |
|
63404 | 376 |
lemma finite_PlusD: |
31080 | 377 |
fixes A :: "'a set" and B :: "'b set" |
378 |
assumes fin: "finite (A <+> B)" |
|
379 |
shows "finite A" "finite B" |
|
380 |
proof - |
|
63404 | 381 |
have "Inl ` A \<subseteq> A <+> B" |
382 |
by auto |
|
383 |
then have "finite (Inl ` A :: ('a + 'b) set)" |
|
384 |
using fin by (rule finite_subset) |
|
385 |
then show "finite A" |
|
386 |
by (rule finite_imageD) (auto intro: inj_onI) |
|
31080 | 387 |
next |
63404 | 388 |
have "Inr ` B \<subseteq> A <+> B" |
389 |
by auto |
|
390 |
then have "finite (Inr ` B :: ('a + 'b) set)" |
|
391 |
using fin by (rule finite_subset) |
|
392 |
then show "finite B" |
|
393 |
by (rule finite_imageD) (auto intro: inj_onI) |
|
31080 | 394 |
qed |
395 |
||
63404 | 396 |
lemma finite_Plus_iff [simp]: "finite (A <+> B) \<longleftrightarrow> finite A \<and> finite B" |
41656 | 397 |
by (auto intro: finite_PlusD finite_Plus) |
31080 | 398 |
|
41656 | 399 |
lemma finite_Plus_UNIV_iff [simp]: |
400 |
"finite (UNIV :: ('a + 'b) set) \<longleftrightarrow> finite (UNIV :: 'a set) \<and> finite (UNIV :: 'b set)" |
|
401 |
by (subst UNIV_Plus_UNIV [symmetric]) (rule finite_Plus_iff) |
|
12396 | 402 |
|
40786
0a54cfc9add3
gave more standard finite set rules simp and intro attribute
nipkow
parents:
40716
diff
changeset
|
403 |
lemma finite_SigmaI [simp, intro]: |
63404 | 404 |
"finite A \<Longrightarrow> (\<And>a. a\<in>A \<Longrightarrow> finite (B a)) \<Longrightarrow> finite (SIGMA a:A. B a)" |
405 |
unfolding Sigma_def by blast |
|
12396 | 406 |
|
51290 | 407 |
lemma finite_SigmaI2: |
408 |
assumes "finite {x\<in>A. B x \<noteq> {}}" |
|
409 |
and "\<And>a. a \<in> A \<Longrightarrow> finite (B a)" |
|
410 |
shows "finite (Sigma A B)" |
|
411 |
proof - |
|
63404 | 412 |
from assms have "finite (Sigma {x\<in>A. B x \<noteq> {}} B)" |
413 |
by auto |
|
414 |
also have "Sigma {x:A. B x \<noteq> {}} B = Sigma A B" |
|
415 |
by auto |
|
51290 | 416 |
finally show ?thesis . |
417 |
qed |
|
418 |
||
63404 | 419 |
lemma finite_cartesian_product: "finite A \<Longrightarrow> finite B \<Longrightarrow> finite (A \<times> B)" |
15402 | 420 |
by (rule finite_SigmaI) |
421 |
||
12396 | 422 |
lemma finite_Prod_UNIV: |
41656 | 423 |
"finite (UNIV :: 'a set) \<Longrightarrow> finite (UNIV :: 'b set) \<Longrightarrow> finite (UNIV :: ('a \<times> 'b) set)" |
424 |
by (simp only: UNIV_Times_UNIV [symmetric] finite_cartesian_product) |
|
12396 | 425 |
|
15409
a063687d24eb
new and stronger lemmas and improved simplification for finite sets
paulson
parents:
15402
diff
changeset
|
426 |
lemma finite_cartesian_productD1: |
42207 | 427 |
assumes "finite (A \<times> B)" and "B \<noteq> {}" |
428 |
shows "finite A" |
|
429 |
proof - |
|
430 |
from assms obtain n f where "A \<times> B = f ` {i::nat. i < n}" |
|
431 |
by (auto simp add: finite_conv_nat_seg_image) |
|
63404 | 432 |
then have "fst ` (A \<times> B) = fst ` f ` {i::nat. i < n}" |
433 |
by simp |
|
60758 | 434 |
with \<open>B \<noteq> {}\<close> have "A = (fst \<circ> f) ` {i::nat. i < n}" |
56154
f0a927235162
more complete set of lemmas wrt. image and composition
haftmann
parents:
55096
diff
changeset
|
435 |
by (simp add: image_comp) |
63404 | 436 |
then have "\<exists>n f. A = f ` {i::nat. i < n}" |
437 |
by blast |
|
42207 | 438 |
then show ?thesis |
439 |
by (auto simp add: finite_conv_nat_seg_image) |
|
440 |
qed |
|
15409
a063687d24eb
new and stronger lemmas and improved simplification for finite sets
paulson
parents:
15402
diff
changeset
|
441 |
|
a063687d24eb
new and stronger lemmas and improved simplification for finite sets
paulson
parents:
15402
diff
changeset
|
442 |
lemma finite_cartesian_productD2: |
42207 | 443 |
assumes "finite (A \<times> B)" and "A \<noteq> {}" |
444 |
shows "finite B" |
|
445 |
proof - |
|
446 |
from assms obtain n f where "A \<times> B = f ` {i::nat. i < n}" |
|
447 |
by (auto simp add: finite_conv_nat_seg_image) |
|
63404 | 448 |
then have "snd ` (A \<times> B) = snd ` f ` {i::nat. i < n}" |
449 |
by simp |
|
60758 | 450 |
with \<open>A \<noteq> {}\<close> have "B = (snd \<circ> f) ` {i::nat. i < n}" |
56154
f0a927235162
more complete set of lemmas wrt. image and composition
haftmann
parents:
55096
diff
changeset
|
451 |
by (simp add: image_comp) |
63404 | 452 |
then have "\<exists>n f. B = f ` {i::nat. i < n}" |
453 |
by blast |
|
42207 | 454 |
then show ?thesis |
455 |
by (auto simp add: finite_conv_nat_seg_image) |
|
456 |
qed |
|
15409
a063687d24eb
new and stronger lemmas and improved simplification for finite sets
paulson
parents:
15402
diff
changeset
|
457 |
|
57025 | 458 |
lemma finite_cartesian_product_iff: |
459 |
"finite (A \<times> B) \<longleftrightarrow> (A = {} \<or> B = {} \<or> (finite A \<and> finite B))" |
|
460 |
by (auto dest: finite_cartesian_productD1 finite_cartesian_productD2 finite_cartesian_product) |
|
461 |
||
63404 | 462 |
lemma finite_prod: |
48175
fea68365c975
add finiteness lemmas for 'a * 'b and 'a set
Andreas Lochbihler
parents:
48128
diff
changeset
|
463 |
"finite (UNIV :: ('a \<times> 'b) set) \<longleftrightarrow> finite (UNIV :: 'a set) \<and> finite (UNIV :: 'b set)" |
57025 | 464 |
using finite_cartesian_product_iff[of UNIV UNIV] by simp |
48175
fea68365c975
add finiteness lemmas for 'a * 'b and 'a set
Andreas Lochbihler
parents:
48128
diff
changeset
|
465 |
|
63404 | 466 |
lemma finite_Pow_iff [iff]: "finite (Pow A) \<longleftrightarrow> finite A" |
12396 | 467 |
proof |
468 |
assume "finite (Pow A)" |
|
63404 | 469 |
then have "finite ((\<lambda>x. {x}) ` A)" |
63612 | 470 |
by (blast intro: finite_subset) (* somewhat slow *) |
63404 | 471 |
then show "finite A" |
472 |
by (rule finite_imageD [unfolded inj_on_def]) simp |
|
12396 | 473 |
next |
474 |
assume "finite A" |
|
41656 | 475 |
then show "finite (Pow A)" |
35216 | 476 |
by induct (simp_all add: Pow_insert) |
12396 | 477 |
qed |
478 |
||
63404 | 479 |
corollary finite_Collect_subsets [simp, intro]: "finite A \<Longrightarrow> finite {B. B \<subseteq> A}" |
41656 | 480 |
by (simp add: Pow_def [symmetric]) |
29918 | 481 |
|
48175
fea68365c975
add finiteness lemmas for 'a * 'b and 'a set
Andreas Lochbihler
parents:
48128
diff
changeset
|
482 |
lemma finite_set: "finite (UNIV :: 'a set set) \<longleftrightarrow> finite (UNIV :: 'a set)" |
63404 | 483 |
by (simp only: finite_Pow_iff Pow_UNIV[symmetric]) |
48175
fea68365c975
add finiteness lemmas for 'a * 'b and 'a set
Andreas Lochbihler
parents:
48128
diff
changeset
|
484 |
|
63404 | 485 |
lemma finite_UnionD: "finite (\<Union>A) \<Longrightarrow> finite A" |
41656 | 486 |
by (blast intro: finite_subset [OF subset_Pow_Union]) |
15392 | 487 |
|
63404 | 488 |
lemma finite_set_of_finite_funs: |
489 |
assumes "finite A" "finite B" |
|
490 |
shows "finite {f. \<forall>x. (x \<in> A \<longrightarrow> f x \<in> B) \<and> (x \<notin> A \<longrightarrow> f x = d)}" (is "finite ?S") |
|
491 |
proof - |
|
53820 | 492 |
let ?F = "\<lambda>f. {(a,b). a \<in> A \<and> b = f a}" |
63404 | 493 |
have "?F ` ?S \<subseteq> Pow(A \<times> B)" |
494 |
by auto |
|
495 |
from finite_subset[OF this] assms have 1: "finite (?F ` ?S)" |
|
496 |
by simp |
|
53820 | 497 |
have 2: "inj_on ?F ?S" |
63612 | 498 |
by (fastforce simp add: inj_on_def set_eq_iff fun_eq_iff) (* somewhat slow *) |
63404 | 499 |
show ?thesis |
500 |
by (rule finite_imageD [OF 1 2]) |
|
53820 | 501 |
qed |
15392 | 502 |
|
58195 | 503 |
lemma not_finite_existsD: |
504 |
assumes "\<not> finite {a. P a}" |
|
505 |
shows "\<exists>a. P a" |
|
506 |
proof (rule classical) |
|
63404 | 507 |
assume "\<not> ?thesis" |
58195 | 508 |
with assms show ?thesis by auto |
509 |
qed |
|
510 |
||
511 |
||
60758 | 512 |
subsubsection \<open>Further induction rules on finite sets\<close> |
41656 | 513 |
|
514 |
lemma finite_ne_induct [case_names singleton insert, consumes 2]: |
|
515 |
assumes "finite F" and "F \<noteq> {}" |
|
516 |
assumes "\<And>x. P {x}" |
|
517 |
and "\<And>x F. finite F \<Longrightarrow> F \<noteq> {} \<Longrightarrow> x \<notin> F \<Longrightarrow> P F \<Longrightarrow> P (insert x F)" |
|
518 |
shows "P F" |
|
63404 | 519 |
using assms |
46898
1570b30ee040
tuned proofs -- eliminated pointless chaining of facts after 'interpret';
wenzelm
parents:
46146
diff
changeset
|
520 |
proof induct |
63404 | 521 |
case empty |
522 |
then show ?case by simp |
|
41656 | 523 |
next |
63404 | 524 |
case (insert x F) |
525 |
then show ?case by cases auto |
|
41656 | 526 |
qed |
527 |
||
528 |
lemma finite_subset_induct [consumes 2, case_names empty insert]: |
|
529 |
assumes "finite F" and "F \<subseteq> A" |
|
63612 | 530 |
and empty: "P {}" |
41656 | 531 |
and insert: "\<And>a F. finite F \<Longrightarrow> a \<in> A \<Longrightarrow> a \<notin> F \<Longrightarrow> P F \<Longrightarrow> P (insert a F)" |
532 |
shows "P F" |
|
63404 | 533 |
using \<open>finite F\<close> \<open>F \<subseteq> A\<close> |
46898
1570b30ee040
tuned proofs -- eliminated pointless chaining of facts after 'interpret';
wenzelm
parents:
46146
diff
changeset
|
534 |
proof induct |
41656 | 535 |
show "P {}" by fact |
31441 | 536 |
next |
41656 | 537 |
fix x F |
63404 | 538 |
assume "finite F" and "x \<notin> F" and P: "F \<subseteq> A \<Longrightarrow> P F" and i: "insert x F \<subseteq> A" |
41656 | 539 |
show "P (insert x F)" |
540 |
proof (rule insert) |
|
541 |
from i show "x \<in> A" by blast |
|
542 |
from i have "F \<subseteq> A" by blast |
|
543 |
with P show "P F" . |
|
544 |
show "finite F" by fact |
|
545 |
show "x \<notin> F" by fact |
|
546 |
qed |
|
547 |
qed |
|
548 |
||
549 |
lemma finite_empty_induct: |
|
550 |
assumes "finite A" |
|
63612 | 551 |
and "P A" |
41656 | 552 |
and remove: "\<And>a A. finite A \<Longrightarrow> a \<in> A \<Longrightarrow> P A \<Longrightarrow> P (A - {a})" |
553 |
shows "P {}" |
|
554 |
proof - |
|
63404 | 555 |
have "P (A - B)" if "B \<subseteq> A" for B :: "'a set" |
41656 | 556 |
proof - |
63404 | 557 |
from \<open>finite A\<close> that have "finite B" |
558 |
by (rule rev_finite_subset) |
|
60758 | 559 |
from this \<open>B \<subseteq> A\<close> show "P (A - B)" |
41656 | 560 |
proof induct |
561 |
case empty |
|
60758 | 562 |
from \<open>P A\<close> show ?case by simp |
41656 | 563 |
next |
564 |
case (insert b B) |
|
565 |
have "P (A - B - {b})" |
|
566 |
proof (rule remove) |
|
63404 | 567 |
from \<open>finite A\<close> show "finite (A - B)" |
568 |
by induct auto |
|
569 |
from insert show "b \<in> A - B" |
|
570 |
by simp |
|
571 |
from insert show "P (A - B)" |
|
572 |
by simp |
|
41656 | 573 |
qed |
63404 | 574 |
also have "A - B - {b} = A - insert b B" |
575 |
by (rule Diff_insert [symmetric]) |
|
41656 | 576 |
finally show ?case . |
577 |
qed |
|
578 |
qed |
|
579 |
then have "P (A - A)" by blast |
|
580 |
then show ?thesis by simp |
|
31441 | 581 |
qed |
582 |
||
58195 | 583 |
lemma finite_update_induct [consumes 1, case_names const update]: |
584 |
assumes finite: "finite {a. f a \<noteq> c}" |
|
63404 | 585 |
and const: "P (\<lambda>a. c)" |
586 |
and update: "\<And>a b f. finite {a. f a \<noteq> c} \<Longrightarrow> f a = c \<Longrightarrow> b \<noteq> c \<Longrightarrow> P f \<Longrightarrow> P (f(a := b))" |
|
58195 | 587 |
shows "P f" |
63404 | 588 |
using finite |
589 |
proof (induct "{a. f a \<noteq> c}" arbitrary: f) |
|
590 |
case empty |
|
591 |
with const show ?case by simp |
|
58195 | 592 |
next |
593 |
case (insert a A) |
|
594 |
then have "A = {a'. (f(a := c)) a' \<noteq> c}" and "f a \<noteq> c" |
|
595 |
by auto |
|
60758 | 596 |
with \<open>finite A\<close> have "finite {a'. (f(a := c)) a' \<noteq> c}" |
58195 | 597 |
by simp |
598 |
have "(f(a := c)) a = c" |
|
599 |
by simp |
|
60758 | 600 |
from insert \<open>A = {a'. (f(a := c)) a' \<noteq> c}\<close> have "P (f(a := c))" |
58195 | 601 |
by simp |
63404 | 602 |
with \<open>finite {a'. (f(a := c)) a' \<noteq> c}\<close> \<open>(f(a := c)) a = c\<close> \<open>f a \<noteq> c\<close> |
603 |
have "P ((f(a := c))(a := f a))" |
|
58195 | 604 |
by (rule update) |
605 |
then show ?case by simp |
|
606 |
qed |
|
607 |
||
63561
fba08009ff3e
add lemmas contributed by Peter Gammie
Andreas Lochbihler
parents:
63404
diff
changeset
|
608 |
lemma finite_subset_induct' [consumes 2, case_names empty insert]: |
fba08009ff3e
add lemmas contributed by Peter Gammie
Andreas Lochbihler
parents:
63404
diff
changeset
|
609 |
assumes "finite F" and "F \<subseteq> A" |
63612 | 610 |
and empty: "P {}" |
611 |
and insert: "\<And>a F. \<lbrakk>finite F; a \<in> A; F \<subseteq> A; a \<notin> F; P F \<rbrakk> \<Longrightarrow> P (insert a F)" |
|
63561
fba08009ff3e
add lemmas contributed by Peter Gammie
Andreas Lochbihler
parents:
63404
diff
changeset
|
612 |
shows "P F" |
63915 | 613 |
using assms(1,2) |
614 |
proof induct |
|
615 |
show "P {}" by fact |
|
616 |
next |
|
617 |
fix x F |
|
618 |
assume "finite F" and "x \<notin> F" and |
|
619 |
P: "F \<subseteq> A \<Longrightarrow> P F" and i: "insert x F \<subseteq> A" |
|
620 |
show "P (insert x F)" |
|
621 |
proof (rule insert) |
|
622 |
from i show "x \<in> A" by blast |
|
623 |
from i have "F \<subseteq> A" by blast |
|
624 |
with P show "P F" . |
|
625 |
show "finite F" by fact |
|
626 |
show "x \<notin> F" by fact |
|
627 |
show "F \<subseteq> A" by fact |
|
63561
fba08009ff3e
add lemmas contributed by Peter Gammie
Andreas Lochbihler
parents:
63404
diff
changeset
|
628 |
qed |
fba08009ff3e
add lemmas contributed by Peter Gammie
Andreas Lochbihler
parents:
63404
diff
changeset
|
629 |
qed |
fba08009ff3e
add lemmas contributed by Peter Gammie
Andreas Lochbihler
parents:
63404
diff
changeset
|
630 |
|
58195 | 631 |
|
61799 | 632 |
subsection \<open>Class \<open>finite\<close>\<close> |
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
633 |
|
63612 | 634 |
class finite = |
635 |
assumes finite_UNIV: "finite (UNIV :: 'a set)" |
|
27430 | 636 |
begin |
637 |
||
61076 | 638 |
lemma finite [simp]: "finite (A :: 'a set)" |
26441 | 639 |
by (rule subset_UNIV finite_UNIV finite_subset)+ |
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
640 |
|
61076 | 641 |
lemma finite_code [code]: "finite (A :: 'a set) \<longleftrightarrow> True" |
40922
4d0f96a54e76
adding code equation for finiteness of finite types
bulwahn
parents:
40786
diff
changeset
|
642 |
by simp |
4d0f96a54e76
adding code equation for finiteness of finite types
bulwahn
parents:
40786
diff
changeset
|
643 |
|
27430 | 644 |
end |
645 |
||
46898
1570b30ee040
tuned proofs -- eliminated pointless chaining of facts after 'interpret';
wenzelm
parents:
46146
diff
changeset
|
646 |
instance prod :: (finite, finite) finite |
61169 | 647 |
by standard (simp only: UNIV_Times_UNIV [symmetric] finite_cartesian_product finite) |
26146 | 648 |
|
63404 | 649 |
lemma inj_graph: "inj (\<lambda>f. {(x, y). y = f x})" |
650 |
by (rule inj_onI) (auto simp add: set_eq_iff fun_eq_iff) |
|
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
651 |
|
26146 | 652 |
instance "fun" :: (finite, finite) finite |
653 |
proof |
|
63404 | 654 |
show "finite (UNIV :: ('a \<Rightarrow> 'b) set)" |
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
655 |
proof (rule finite_imageD) |
63404 | 656 |
let ?graph = "\<lambda>f::'a \<Rightarrow> 'b. {(x, y). y = f x}" |
657 |
have "range ?graph \<subseteq> Pow UNIV" |
|
658 |
by simp |
|
26792 | 659 |
moreover have "finite (Pow (UNIV :: ('a * 'b) set))" |
660 |
by (simp only: finite_Pow_iff finite) |
|
661 |
ultimately show "finite (range ?graph)" |
|
662 |
by (rule finite_subset) |
|
63404 | 663 |
show "inj ?graph" |
664 |
by (rule inj_graph) |
|
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
665 |
qed |
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
666 |
qed |
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
667 |
|
46898
1570b30ee040
tuned proofs -- eliminated pointless chaining of facts after 'interpret';
wenzelm
parents:
46146
diff
changeset
|
668 |
instance bool :: finite |
61169 | 669 |
by standard (simp add: UNIV_bool) |
44831 | 670 |
|
45962 | 671 |
instance set :: (finite) finite |
61169 | 672 |
by standard (simp only: Pow_UNIV [symmetric] finite_Pow_iff finite) |
45962 | 673 |
|
46898
1570b30ee040
tuned proofs -- eliminated pointless chaining of facts after 'interpret';
wenzelm
parents:
46146
diff
changeset
|
674 |
instance unit :: finite |
61169 | 675 |
by standard (simp add: UNIV_unit) |
44831 | 676 |
|
46898
1570b30ee040
tuned proofs -- eliminated pointless chaining of facts after 'interpret';
wenzelm
parents:
46146
diff
changeset
|
677 |
instance sum :: (finite, finite) finite |
61169 | 678 |
by standard (simp only: UNIV_Plus_UNIV [symmetric] finite_Plus finite) |
27981 | 679 |
|
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
680 |
|
60758 | 681 |
subsection \<open>A basic fold functional for finite sets\<close> |
15392 | 682 |
|
60758 | 683 |
text \<open>The intended behaviour is |
63404 | 684 |
\<open>fold f z {x\<^sub>1, \<dots>, x\<^sub>n} = f x\<^sub>1 (\<dots> (f x\<^sub>n z)\<dots>)\<close> |
685 |
if \<open>f\<close> is ``left-commutative'': |
|
60758 | 686 |
\<close> |
15392 | 687 |
|
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
688 |
locale comp_fun_commute = |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
689 |
fixes f :: "'a \<Rightarrow> 'b \<Rightarrow> 'b" |
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
690 |
assumes comp_fun_commute: "f y \<circ> f x = f x \<circ> f y" |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
691 |
begin |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
692 |
|
51489 | 693 |
lemma fun_left_comm: "f y (f x z) = f x (f y z)" |
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
694 |
using comp_fun_commute by (simp add: fun_eq_iff) |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
695 |
|
63404 | 696 |
lemma commute_left_comp: "f y \<circ> (f x \<circ> g) = f x \<circ> (f y \<circ> g)" |
51489 | 697 |
by (simp add: o_assoc comp_fun_commute) |
698 |
||
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
699 |
end |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
700 |
|
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
701 |
inductive fold_graph :: "('a \<Rightarrow> 'b \<Rightarrow> 'b) \<Rightarrow> 'b \<Rightarrow> 'a set \<Rightarrow> 'b \<Rightarrow> bool" |
63404 | 702 |
for f :: "'a \<Rightarrow> 'b \<Rightarrow> 'b" and z :: 'b |
63612 | 703 |
where |
704 |
emptyI [intro]: "fold_graph f z {} z" |
|
705 |
| insertI [intro]: "x \<notin> A \<Longrightarrow> fold_graph f z A y \<Longrightarrow> fold_graph f z (insert x A) (f x y)" |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
706 |
|
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
707 |
inductive_cases empty_fold_graphE [elim!]: "fold_graph f z {} x" |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
708 |
|
63404 | 709 |
definition fold :: "('a \<Rightarrow> 'b \<Rightarrow> 'b) \<Rightarrow> 'b \<Rightarrow> 'a set \<Rightarrow> 'b" |
710 |
where "fold f z A = (if finite A then (THE y. fold_graph f z A y) else z)" |
|
15392 | 711 |
|
63404 | 712 |
text \<open> |
713 |
A tempting alternative for the definiens is |
|
714 |
@{term "if finite A then THE y. fold_graph f z A y else e"}. |
|
715 |
It allows the removal of finiteness assumptions from the theorems |
|
716 |
\<open>fold_comm\<close>, \<open>fold_reindex\<close> and \<open>fold_distrib\<close>. |
|
717 |
The proofs become ugly. It is not worth the effort. (???) |
|
718 |
\<close> |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
719 |
|
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
720 |
lemma finite_imp_fold_graph: "finite A \<Longrightarrow> \<exists>x. fold_graph f z A x" |
63404 | 721 |
by (induct rule: finite_induct) auto |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
722 |
|
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
723 |
|
63404 | 724 |
subsubsection \<open>From @{const fold_graph} to @{term fold}\<close> |
15392 | 725 |
|
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
726 |
context comp_fun_commute |
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
727 |
begin |
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
728 |
|
51489 | 729 |
lemma fold_graph_finite: |
730 |
assumes "fold_graph f z A y" |
|
731 |
shows "finite A" |
|
732 |
using assms by induct simp_all |
|
733 |
||
36045 | 734 |
lemma fold_graph_insertE_aux: |
735 |
"fold_graph f z A y \<Longrightarrow> a \<in> A \<Longrightarrow> \<exists>y'. y = f a y' \<and> fold_graph f z (A - {a}) y'" |
|
736 |
proof (induct set: fold_graph) |
|
63404 | 737 |
case emptyI |
738 |
then show ?case by simp |
|
739 |
next |
|
740 |
case (insertI x A y) |
|
741 |
show ?case |
|
36045 | 742 |
proof (cases "x = a") |
63404 | 743 |
case True |
744 |
with insertI show ?thesis by auto |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
745 |
next |
63404 | 746 |
case False |
36045 | 747 |
then obtain y' where y: "y = f a y'" and y': "fold_graph f z (A - {a}) y'" |
748 |
using insertI by auto |
|
42875 | 749 |
have "f x y = f a (f x y')" |
36045 | 750 |
unfolding y by (rule fun_left_comm) |
42875 | 751 |
moreover have "fold_graph f z (insert x A - {a}) (f x y')" |
60758 | 752 |
using y' and \<open>x \<noteq> a\<close> and \<open>x \<notin> A\<close> |
36045 | 753 |
by (simp add: insert_Diff_if fold_graph.insertI) |
63404 | 754 |
ultimately show ?thesis |
755 |
by fast |
|
15392 | 756 |
qed |
63404 | 757 |
qed |
36045 | 758 |
|
759 |
lemma fold_graph_insertE: |
|
760 |
assumes "fold_graph f z (insert x A) v" and "x \<notin> A" |
|
761 |
obtains y where "v = f x y" and "fold_graph f z A y" |
|
63404 | 762 |
using assms by (auto dest: fold_graph_insertE_aux [OF _ insertI1]) |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
763 |
|
63404 | 764 |
lemma fold_graph_determ: "fold_graph f z A x \<Longrightarrow> fold_graph f z A y \<Longrightarrow> y = x" |
36045 | 765 |
proof (induct arbitrary: y set: fold_graph) |
63404 | 766 |
case emptyI |
767 |
then show ?case by fast |
|
768 |
next |
|
36045 | 769 |
case (insertI x A y v) |
60758 | 770 |
from \<open>fold_graph f z (insert x A) v\<close> and \<open>x \<notin> A\<close> |
36045 | 771 |
obtain y' where "v = f x y'" and "fold_graph f z A y'" |
772 |
by (rule fold_graph_insertE) |
|
63404 | 773 |
from \<open>fold_graph f z A y'\<close> have "y' = y" |
774 |
by (rule insertI) |
|
775 |
with \<open>v = f x y'\<close> show "v = f x y" |
|
776 |
by simp |
|
777 |
qed |
|
15392 | 778 |
|
63404 | 779 |
lemma fold_equality: "fold_graph f z A y \<Longrightarrow> fold f z A = y" |
51489 | 780 |
by (cases "finite A") (auto simp add: fold_def intro: fold_graph_determ dest: fold_graph_finite) |
15392 | 781 |
|
42272 | 782 |
lemma fold_graph_fold: |
783 |
assumes "finite A" |
|
784 |
shows "fold_graph f z A (fold f z A)" |
|
785 |
proof - |
|
63404 | 786 |
from assms have "\<exists>x. fold_graph f z A x" |
787 |
by (rule finite_imp_fold_graph) |
|
42272 | 788 |
moreover note fold_graph_determ |
63404 | 789 |
ultimately have "\<exists>!x. fold_graph f z A x" |
790 |
by (rule ex_ex1I) |
|
791 |
then have "fold_graph f z A (The (fold_graph f z A))" |
|
792 |
by (rule theI') |
|
793 |
with assms show ?thesis |
|
794 |
by (simp add: fold_def) |
|
42272 | 795 |
qed |
36045 | 796 |
|
61799 | 797 |
text \<open>The base case for \<open>fold\<close>:\<close> |
15392 | 798 |
|
63404 | 799 |
lemma (in -) fold_infinite [simp]: "\<not> finite A \<Longrightarrow> fold f z A = z" |
800 |
by (auto simp: fold_def) |
|
51489 | 801 |
|
63404 | 802 |
lemma (in -) fold_empty [simp]: "fold f z {} = z" |
803 |
by (auto simp: fold_def) |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
804 |
|
63404 | 805 |
text \<open>The various recursion equations for @{const fold}:\<close> |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
806 |
|
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
807 |
lemma fold_insert [simp]: |
42875 | 808 |
assumes "finite A" and "x \<notin> A" |
809 |
shows "fold f z (insert x A) = f x (fold f z A)" |
|
810 |
proof (rule fold_equality) |
|
51489 | 811 |
fix z |
63404 | 812 |
from \<open>finite A\<close> have "fold_graph f z A (fold f z A)" |
813 |
by (rule fold_graph_fold) |
|
814 |
with \<open>x \<notin> A\<close> have "fold_graph f z (insert x A) (f x (fold f z A))" |
|
815 |
by (rule fold_graph.insertI) |
|
816 |
then show "fold_graph f z (insert x A) (f x (fold f z A))" |
|
817 |
by simp |
|
42875 | 818 |
qed |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
819 |
|
51489 | 820 |
declare (in -) empty_fold_graphE [rule del] fold_graph.intros [rule del] |
61799 | 821 |
\<comment> \<open>No more proofs involve these.\<close> |
51489 | 822 |
|
63404 | 823 |
lemma fold_fun_left_comm: "finite A \<Longrightarrow> f x (fold f z A) = fold f (f x z) A" |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
824 |
proof (induct rule: finite_induct) |
63404 | 825 |
case empty |
826 |
then show ?case by simp |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
827 |
next |
63404 | 828 |
case insert |
829 |
then show ?case |
|
51489 | 830 |
by (simp add: fun_left_comm [of x]) |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
831 |
qed |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
832 |
|
63404 | 833 |
lemma fold_insert2: "finite A \<Longrightarrow> x \<notin> A \<Longrightarrow> fold f z (insert x A) = fold f (f x z) A" |
51489 | 834 |
by (simp add: fold_fun_left_comm) |
15392 | 835 |
|
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
836 |
lemma fold_rec: |
42875 | 837 |
assumes "finite A" and "x \<in> A" |
838 |
shows "fold f z A = f x (fold f z (A - {x}))" |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
839 |
proof - |
63404 | 840 |
have A: "A = insert x (A - {x})" |
841 |
using \<open>x \<in> A\<close> by blast |
|
842 |
then have "fold f z A = fold f z (insert x (A - {x}))" |
|
843 |
by simp |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
844 |
also have "\<dots> = f x (fold f z (A - {x}))" |
60758 | 845 |
by (rule fold_insert) (simp add: \<open>finite A\<close>)+ |
15535 | 846 |
finally show ?thesis . |
847 |
qed |
|
848 |
||
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
849 |
lemma fold_insert_remove: |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
850 |
assumes "finite A" |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
851 |
shows "fold f z (insert x A) = f x (fold f z (A - {x}))" |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
852 |
proof - |
63404 | 853 |
from \<open>finite A\<close> have "finite (insert x A)" |
854 |
by auto |
|
855 |
moreover have "x \<in> insert x A" |
|
856 |
by auto |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
857 |
ultimately have "fold f z (insert x A) = f x (fold f z (insert x A - {x}))" |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
858 |
by (rule fold_rec) |
63404 | 859 |
then show ?thesis |
860 |
by simp |
|
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
861 |
qed |
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
862 |
|
57598 | 863 |
lemma fold_set_union_disj: |
864 |
assumes "finite A" "finite B" "A \<inter> B = {}" |
|
865 |
shows "Finite_Set.fold f z (A \<union> B) = Finite_Set.fold f (Finite_Set.fold f z A) B" |
|
63404 | 866 |
using assms(2,1,3) by induct simp_all |
57598 | 867 |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
868 |
end |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
869 |
|
63404 | 870 |
text \<open>Other properties of @{const fold}:\<close> |
48619 | 871 |
|
872 |
lemma fold_image: |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
873 |
assumes "inj_on g A" |
51489 | 874 |
shows "fold f z (g ` A) = fold (f \<circ> g) z A" |
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
875 |
proof (cases "finite A") |
63404 | 876 |
case False |
877 |
with assms show ?thesis |
|
878 |
by (auto dest: finite_imageD simp add: fold_def) |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
879 |
next |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
880 |
case True |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
881 |
have "fold_graph f z (g ` A) = fold_graph (f \<circ> g) z A" |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
882 |
proof |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
883 |
fix w |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
884 |
show "fold_graph f z (g ` A) w \<longleftrightarrow> fold_graph (f \<circ> g) z A w" (is "?P \<longleftrightarrow> ?Q") |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
885 |
proof |
63404 | 886 |
assume ?P |
887 |
then show ?Q |
|
888 |
using assms |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
889 |
proof (induct "g ` A" w arbitrary: A) |
63404 | 890 |
case emptyI |
891 |
then show ?case by (auto intro: fold_graph.emptyI) |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
892 |
next |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
893 |
case (insertI x A r B) |
63404 | 894 |
from \<open>inj_on g B\<close> \<open>x \<notin> A\<close> \<open>insert x A = image g B\<close> obtain x' A' |
895 |
where "x' \<notin> A'" and [simp]: "B = insert x' A'" "x = g x'" "A = g ` A'" |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
896 |
by (rule inj_img_insertE) |
63404 | 897 |
from insertI.prems have "fold_graph (f \<circ> g) z A' r" |
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
898 |
by (auto intro: insertI.hyps) |
60758 | 899 |
with \<open>x' \<notin> A'\<close> have "fold_graph (f \<circ> g) z (insert x' A') ((f \<circ> g) x' r)" |
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
900 |
by (rule fold_graph.insertI) |
63404 | 901 |
then show ?case |
902 |
by simp |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
903 |
qed |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
904 |
next |
63404 | 905 |
assume ?Q |
906 |
then show ?P |
|
907 |
using assms |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
908 |
proof induct |
63404 | 909 |
case emptyI |
910 |
then show ?case |
|
911 |
by (auto intro: fold_graph.emptyI) |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
912 |
next |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
913 |
case (insertI x A r) |
63404 | 914 |
from \<open>x \<notin> A\<close> insertI.prems have "g x \<notin> g ` A" |
915 |
by auto |
|
916 |
moreover from insertI have "fold_graph f z (g ` A) r" |
|
917 |
by simp |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
918 |
ultimately have "fold_graph f z (insert (g x) (g ` A)) (f (g x) r)" |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
919 |
by (rule fold_graph.insertI) |
63404 | 920 |
then show ?case |
921 |
by simp |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
922 |
qed |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
923 |
qed |
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
924 |
qed |
63404 | 925 |
with True assms show ?thesis |
926 |
by (auto simp add: fold_def) |
|
51598
5dbe537087aa
generalized lemma fold_image thanks to Peter Lammich
haftmann
parents:
51546
diff
changeset
|
927 |
qed |
15392 | 928 |
|
49724 | 929 |
lemma fold_cong: |
930 |
assumes "comp_fun_commute f" "comp_fun_commute g" |
|
63404 | 931 |
and "finite A" |
932 |
and cong: "\<And>x. x \<in> A \<Longrightarrow> f x = g x" |
|
51489 | 933 |
and "s = t" and "A = B" |
934 |
shows "fold f s A = fold g t B" |
|
49724 | 935 |
proof - |
63404 | 936 |
have "fold f s A = fold g s A" |
937 |
using \<open>finite A\<close> cong |
|
938 |
proof (induct A) |
|
939 |
case empty |
|
940 |
then show ?case by simp |
|
49724 | 941 |
next |
63404 | 942 |
case insert |
60758 | 943 |
interpret f: comp_fun_commute f by (fact \<open>comp_fun_commute f\<close>) |
944 |
interpret g: comp_fun_commute g by (fact \<open>comp_fun_commute g\<close>) |
|
49724 | 945 |
from insert show ?case by simp |
946 |
qed |
|
947 |
with assms show ?thesis by simp |
|
948 |
qed |
|
949 |
||
950 |
||
60758 | 951 |
text \<open>A simplified version for idempotent functions:\<close> |
15480 | 952 |
|
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
953 |
locale comp_fun_idem = comp_fun_commute + |
51489 | 954 |
assumes comp_fun_idem: "f x \<circ> f x = f x" |
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
955 |
begin |
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
956 |
|
42869
43b0f61f56d0
use point-free characterization for locale fun_left_comm_idem
haftmann
parents:
42809
diff
changeset
|
957 |
lemma fun_left_idem: "f x (f x z) = f x z" |
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
958 |
using comp_fun_idem by (simp add: fun_eq_iff) |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
959 |
|
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
960 |
lemma fold_insert_idem: |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
961 |
assumes fin: "finite A" |
51489 | 962 |
shows "fold f z (insert x A) = f x (fold f z A)" |
15480 | 963 |
proof cases |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
964 |
assume "x \<in> A" |
63404 | 965 |
then obtain B where "A = insert x B" and "x \<notin> B" |
966 |
by (rule set_insert) |
|
967 |
then show ?thesis |
|
968 |
using assms by (simp add: comp_fun_idem fun_left_idem) |
|
15480 | 969 |
next |
63404 | 970 |
assume "x \<notin> A" |
971 |
then show ?thesis |
|
972 |
using assms by simp |
|
15480 | 973 |
qed |
974 |
||
51489 | 975 |
declare fold_insert [simp del] fold_insert_idem [simp] |
28853
69eb69659bf3
Added new fold operator and renamed the old oe to fold_image.
nipkow
parents:
28823
diff
changeset
|
976 |
|
63404 | 977 |
lemma fold_insert_idem2: "finite A \<Longrightarrow> fold f z (insert x A) = fold f (f x z) A" |
51489 | 978 |
by (simp add: fold_fun_left_comm) |
15484 | 979 |
|
26041
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
980 |
end |
c2e15e65165f
locales ACf, ACIf, ACIfSL and ACIfSLlin have been abandoned in favour of the existing algebraic classes ab_semigroup_mult, ab_semigroup_idem_mult, lower_semilattice (resp. uper_semilattice) and linorder
haftmann
parents:
25571
diff
changeset
|
981 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
982 |
|
61799 | 983 |
subsubsection \<open>Liftings to \<open>comp_fun_commute\<close> etc.\<close> |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
984 |
|
63404 | 985 |
lemma (in comp_fun_commute) comp_comp_fun_commute: "comp_fun_commute (f \<circ> g)" |
986 |
by standard (simp_all add: comp_fun_commute) |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
987 |
|
63404 | 988 |
lemma (in comp_fun_idem) comp_comp_fun_idem: "comp_fun_idem (f \<circ> g)" |
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
989 |
by (rule comp_fun_idem.intro, rule comp_comp_fun_commute, unfold_locales) |
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
990 |
(simp_all add: comp_fun_idem) |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
991 |
|
63404 | 992 |
lemma (in comp_fun_commute) comp_fun_commute_funpow: "comp_fun_commute (\<lambda>x. f x ^^ g x)" |
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
993 |
proof |
63404 | 994 |
show "f y ^^ g y \<circ> f x ^^ g x = f x ^^ g x \<circ> f y ^^ g y" for x y |
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
995 |
proof (cases "x = y") |
63404 | 996 |
case True |
997 |
then show ?thesis by simp |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
998 |
next |
63404 | 999 |
case False |
1000 |
show ?thesis |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1001 |
proof (induct "g x" arbitrary: g) |
63404 | 1002 |
case 0 |
1003 |
then show ?case by simp |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1004 |
next |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1005 |
case (Suc n g) |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1006 |
have hyp1: "f y ^^ g y \<circ> f x = f x \<circ> f y ^^ g y" |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1007 |
proof (induct "g y" arbitrary: g) |
63404 | 1008 |
case 0 |
1009 |
then show ?case by simp |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1010 |
next |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1011 |
case (Suc n g) |
63040 | 1012 |
define h where "h z = g z - 1" for z |
63404 | 1013 |
with Suc have "n = h y" |
1014 |
by simp |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1015 |
with Suc have hyp: "f y ^^ h y \<circ> f x = f x \<circ> f y ^^ h y" |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1016 |
by auto |
63404 | 1017 |
from Suc h_def have "g y = Suc (h y)" |
1018 |
by simp |
|
1019 |
then show ?case |
|
1020 |
by (simp add: comp_assoc hyp) (simp add: o_assoc comp_fun_commute) |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1021 |
qed |
63040 | 1022 |
define h where "h z = (if z = x then g x - 1 else g z)" for z |
63404 | 1023 |
with Suc have "n = h x" |
1024 |
by simp |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1025 |
with Suc have "f y ^^ h y \<circ> f x ^^ h x = f x ^^ h x \<circ> f y ^^ h y" |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1026 |
by auto |
63404 | 1027 |
with False h_def have hyp2: "f y ^^ g y \<circ> f x ^^ h x = f x ^^ h x \<circ> f y ^^ g y" |
1028 |
by simp |
|
1029 |
from Suc h_def have "g x = Suc (h x)" |
|
1030 |
by simp |
|
1031 |
then show ?case |
|
1032 |
by (simp del: funpow.simps add: funpow_Suc_right o_assoc hyp2) (simp add: comp_assoc hyp1) |
|
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1033 |
qed |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1034 |
qed |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1035 |
qed |
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1036 |
|
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1037 |
|
60758 | 1038 |
subsubsection \<open>Expressing set operations via @{const fold}\<close> |
49723
bbc2942ba09f
alternative simplification of ^^ to the righthand side;
haftmann
parents:
48891
diff
changeset
|
1039 |
|
63404 | 1040 |
lemma comp_fun_commute_const: "comp_fun_commute (\<lambda>_. f)" |
1041 |
by standard rule |
|
51489 | 1042 |
|
63404 | 1043 |
lemma comp_fun_idem_insert: "comp_fun_idem insert" |
1044 |
by standard auto |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1045 |
|
63404 | 1046 |
lemma comp_fun_idem_remove: "comp_fun_idem Set.remove" |
1047 |
by standard auto |
|
31992 | 1048 |
|
63404 | 1049 |
lemma (in semilattice_inf) comp_fun_idem_inf: "comp_fun_idem inf" |
1050 |
by standard (auto simp add: inf_left_commute) |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1051 |
|
63404 | 1052 |
lemma (in semilattice_sup) comp_fun_idem_sup: "comp_fun_idem sup" |
1053 |
by standard (auto simp add: sup_left_commute) |
|
31992 | 1054 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1055 |
lemma union_fold_insert: |
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1056 |
assumes "finite A" |
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1057 |
shows "A \<union> B = fold insert B A" |
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1058 |
proof - |
63404 | 1059 |
interpret comp_fun_idem insert |
1060 |
by (fact comp_fun_idem_insert) |
|
1061 |
from \<open>finite A\<close> show ?thesis |
|
1062 |
by (induct A arbitrary: B) simp_all |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1063 |
qed |
31992 | 1064 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1065 |
lemma minus_fold_remove: |
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1066 |
assumes "finite A" |
46146
6baea4fca6bd
incorporated various theorems from theory More_Set into corpus
haftmann
parents:
46033
diff
changeset
|
1067 |
shows "B - A = fold Set.remove B A" |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1068 |
proof - |
63404 | 1069 |
interpret comp_fun_idem Set.remove |
1070 |
by (fact comp_fun_idem_remove) |
|
1071 |
from \<open>finite A\<close> have "fold Set.remove B A = B - A" |
|
63612 | 1072 |
by (induct A arbitrary: B) auto (* slow *) |
46146
6baea4fca6bd
incorporated various theorems from theory More_Set into corpus
haftmann
parents:
46033
diff
changeset
|
1073 |
then show ?thesis .. |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1074 |
qed |
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1075 |
|
51489 | 1076 |
lemma comp_fun_commute_filter_fold: |
1077 |
"comp_fun_commute (\<lambda>x A'. if P x then Set.insert x A' else A')" |
|
63404 | 1078 |
proof - |
48619 | 1079 |
interpret comp_fun_idem Set.insert by (fact comp_fun_idem_insert) |
61169 | 1080 |
show ?thesis by standard (auto simp: fun_eq_iff) |
48619 | 1081 |
qed |
1082 |
||
49758
718f10c8bbfc
use Set.filter instead of Finite_Set.filter, which is removed then
kuncar
parents:
49757
diff
changeset
|
1083 |
lemma Set_filter_fold: |
48619 | 1084 |
assumes "finite A" |
49758
718f10c8bbfc
use Set.filter instead of Finite_Set.filter, which is removed then
kuncar
parents:
49757
diff
changeset
|
1085 |
shows "Set.filter P A = fold (\<lambda>x A'. if P x then Set.insert x A' else A') {} A" |
63404 | 1086 |
using assms |
1087 |
by induct |
|
1088 |
(auto simp add: Set.filter_def comp_fun_commute.fold_insert[OF comp_fun_commute_filter_fold]) |
|
49758
718f10c8bbfc
use Set.filter instead of Finite_Set.filter, which is removed then
kuncar
parents:
49757
diff
changeset
|
1089 |
|
63404 | 1090 |
lemma inter_Set_filter: |
49758
718f10c8bbfc
use Set.filter instead of Finite_Set.filter, which is removed then
kuncar
parents:
49757
diff
changeset
|
1091 |
assumes "finite B" |
718f10c8bbfc
use Set.filter instead of Finite_Set.filter, which is removed then
kuncar
parents:
49757
diff
changeset
|
1092 |
shows "A \<inter> B = Set.filter (\<lambda>x. x \<in> A) B" |
63404 | 1093 |
using assms |
1094 |
by induct (auto simp: Set.filter_def) |
|
48619 | 1095 |
|
1096 |
lemma image_fold_insert: |
|
1097 |
assumes "finite A" |
|
1098 |
shows "image f A = fold (\<lambda>k A. Set.insert (f k) A) {} A" |
|
1099 |
proof - |
|
63404 | 1100 |
interpret comp_fun_commute "\<lambda>k A. Set.insert (f k) A" |
1101 |
by standard auto |
|
1102 |
show ?thesis |
|
1103 |
using assms by (induct A) auto |
|
48619 | 1104 |
qed |
1105 |
||
1106 |
lemma Ball_fold: |
|
1107 |
assumes "finite A" |
|
1108 |
shows "Ball A P = fold (\<lambda>k s. s \<and> P k) True A" |
|
1109 |
proof - |
|
63404 | 1110 |
interpret comp_fun_commute "\<lambda>k s. s \<and> P k" |
1111 |
by standard auto |
|
1112 |
show ?thesis |
|
1113 |
using assms by (induct A) auto |
|
48619 | 1114 |
qed |
1115 |
||
1116 |
lemma Bex_fold: |
|
1117 |
assumes "finite A" |
|
1118 |
shows "Bex A P = fold (\<lambda>k s. s \<or> P k) False A" |
|
1119 |
proof - |
|
63404 | 1120 |
interpret comp_fun_commute "\<lambda>k s. s \<or> P k" |
1121 |
by standard auto |
|
1122 |
show ?thesis |
|
1123 |
using assms by (induct A) auto |
|
48619 | 1124 |
qed |
1125 |
||
63404 | 1126 |
lemma comp_fun_commute_Pow_fold: "comp_fun_commute (\<lambda>x A. A \<union> Set.insert x ` A)" |
63612 | 1127 |
by (clarsimp simp: fun_eq_iff comp_fun_commute_def) blast (* somewhat slow *) |
48619 | 1128 |
|
1129 |
lemma Pow_fold: |
|
1130 |
assumes "finite A" |
|
1131 |
shows "Pow A = fold (\<lambda>x A. A \<union> Set.insert x ` A) {{}} A" |
|
1132 |
proof - |
|
63404 | 1133 |
interpret comp_fun_commute "\<lambda>x A. A \<union> Set.insert x ` A" |
1134 |
by (rule comp_fun_commute_Pow_fold) |
|
1135 |
show ?thesis |
|
1136 |
using assms by (induct A) (auto simp: Pow_insert) |
|
48619 | 1137 |
qed |
1138 |
||
1139 |
lemma fold_union_pair: |
|
1140 |
assumes "finite B" |
|
1141 |
shows "(\<Union>y\<in>B. {(x, y)}) \<union> A = fold (\<lambda>y. Set.insert (x, y)) A B" |
|
1142 |
proof - |
|
63404 | 1143 |
interpret comp_fun_commute "\<lambda>y. Set.insert (x, y)" |
1144 |
by standard auto |
|
1145 |
show ?thesis |
|
1146 |
using assms by (induct arbitrary: A) simp_all |
|
48619 | 1147 |
qed |
1148 |
||
63404 | 1149 |
lemma comp_fun_commute_product_fold: |
1150 |
"finite B \<Longrightarrow> comp_fun_commute (\<lambda>x z. fold (\<lambda>y. Set.insert (x, y)) z B)" |
|
1151 |
by standard (auto simp: fold_union_pair [symmetric]) |
|
48619 | 1152 |
|
1153 |
lemma product_fold: |
|
63404 | 1154 |
assumes "finite A" "finite B" |
51489 | 1155 |
shows "A \<times> B = fold (\<lambda>x z. fold (\<lambda>y. Set.insert (x, y)) z B) {} A" |
63404 | 1156 |
using assms unfolding Sigma_def |
1157 |
by (induct A) |
|
1158 |
(simp_all add: comp_fun_commute.fold_insert[OF comp_fun_commute_product_fold] fold_union_pair) |
|
48619 | 1159 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1160 |
context complete_lattice |
31992 | 1161 |
begin |
1162 |
||
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1163 |
lemma inf_Inf_fold_inf: |
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1164 |
assumes "finite A" |
51489 | 1165 |
shows "inf (Inf A) B = fold inf B A" |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1166 |
proof - |
63404 | 1167 |
interpret comp_fun_idem inf |
1168 |
by (fact comp_fun_idem_inf) |
|
1169 |
from \<open>finite A\<close> fold_fun_left_comm show ?thesis |
|
1170 |
by (induct A arbitrary: B) (simp_all add: inf_commute fun_eq_iff) |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1171 |
qed |
31992 | 1172 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1173 |
lemma sup_Sup_fold_sup: |
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1174 |
assumes "finite A" |
51489 | 1175 |
shows "sup (Sup A) B = fold sup B A" |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1176 |
proof - |
63404 | 1177 |
interpret comp_fun_idem sup |
1178 |
by (fact comp_fun_idem_sup) |
|
1179 |
from \<open>finite A\<close> fold_fun_left_comm show ?thesis |
|
1180 |
by (induct A arbitrary: B) (simp_all add: sup_commute fun_eq_iff) |
|
31992 | 1181 |
qed |
1182 |
||
63404 | 1183 |
lemma Inf_fold_inf: "finite A \<Longrightarrow> Inf A = fold inf top A" |
1184 |
using inf_Inf_fold_inf [of A top] by (simp add: inf_absorb2) |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1185 |
|
63404 | 1186 |
lemma Sup_fold_sup: "finite A \<Longrightarrow> Sup A = fold sup bot A" |
1187 |
using sup_Sup_fold_sup [of A bot] by (simp add: sup_absorb2) |
|
31992 | 1188 |
|
46146
6baea4fca6bd
incorporated various theorems from theory More_Set into corpus
haftmann
parents:
46033
diff
changeset
|
1189 |
lemma inf_INF_fold_inf: |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1190 |
assumes "finite A" |
63404 | 1191 |
shows "inf B (INFIMUM A f) = fold (inf \<circ> f) B A" (is "?inf = ?fold") |
1192 |
proof - |
|
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
1193 |
interpret comp_fun_idem inf by (fact comp_fun_idem_inf) |
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
1194 |
interpret comp_fun_idem "inf \<circ> f" by (fact comp_comp_fun_idem) |
63404 | 1195 |
from \<open>finite A\<close> have "?fold = ?inf" |
1196 |
by (induct A arbitrary: B) (simp_all add: inf_left_commute) |
|
1197 |
then show ?thesis .. |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1198 |
qed |
31992 | 1199 |
|
46146
6baea4fca6bd
incorporated various theorems from theory More_Set into corpus
haftmann
parents:
46033
diff
changeset
|
1200 |
lemma sup_SUP_fold_sup: |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1201 |
assumes "finite A" |
63404 | 1202 |
shows "sup B (SUPREMUM A f) = fold (sup \<circ> f) B A" (is "?sup = ?fold") |
1203 |
proof - |
|
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
1204 |
interpret comp_fun_idem sup by (fact comp_fun_idem_sup) |
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
1205 |
interpret comp_fun_idem "sup \<circ> f" by (fact comp_comp_fun_idem) |
63404 | 1206 |
from \<open>finite A\<close> have "?fold = ?sup" |
1207 |
by (induct A arbitrary: B) (simp_all add: sup_left_commute) |
|
1208 |
then show ?thesis .. |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1209 |
qed |
31992 | 1210 |
|
63404 | 1211 |
lemma INF_fold_inf: "finite A \<Longrightarrow> INFIMUM A f = fold (inf \<circ> f) top A" |
1212 |
using inf_INF_fold_inf [of A top] by simp |
|
31992 | 1213 |
|
63404 | 1214 |
lemma SUP_fold_sup: "finite A \<Longrightarrow> SUPREMUM A f = fold (sup \<circ> f) bot A" |
1215 |
using sup_SUP_fold_sup [of A bot] by simp |
|
31992 | 1216 |
|
1217 |
end |
|
1218 |
||
1219 |
||
60758 | 1220 |
subsection \<open>Locales as mini-packages for fold operations\<close> |
34007
aea892559fc5
tuned lattices theory fragements; generlized some lemmas from sets to lattices
haftmann
parents:
33960
diff
changeset
|
1221 |
|
60758 | 1222 |
subsubsection \<open>The natural case\<close> |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1223 |
|
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1224 |
locale folding = |
63612 | 1225 |
fixes f :: "'a \<Rightarrow> 'b \<Rightarrow> 'b" and z :: "'b" |
42871
1c0b99f950d9
names of fold_set locales resemble name of characteristic property more closely
haftmann
parents:
42869
diff
changeset
|
1226 |
assumes comp_fun_commute: "f y \<circ> f x = f x \<circ> f y" |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1227 |
begin |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1228 |
|
54870 | 1229 |
interpretation fold?: comp_fun_commute f |
63612 | 1230 |
by standard (use comp_fun_commute in \<open>simp add: fun_eq_iff\<close>) |
54867
c21a2465cac1
prefer ephemeral interpretation over interpretation in proof contexts;
haftmann
parents:
54611
diff
changeset
|
1231 |
|
51489 | 1232 |
definition F :: "'a set \<Rightarrow> 'b" |
63404 | 1233 |
where eq_fold: "F A = fold f z A" |
51489 | 1234 |
|
61169 | 1235 |
lemma empty [simp]:"F {} = z" |
51489 | 1236 |
by (simp add: eq_fold) |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1237 |
|
61169 | 1238 |
lemma infinite [simp]: "\<not> finite A \<Longrightarrow> F A = z" |
51489 | 1239 |
by (simp add: eq_fold) |
63404 | 1240 |
|
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1241 |
lemma insert [simp]: |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1242 |
assumes "finite A" and "x \<notin> A" |
51489 | 1243 |
shows "F (insert x A) = f x (F A)" |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1244 |
proof - |
51489 | 1245 |
from fold_insert assms |
1246 |
have "fold f z (insert x A) = f x (fold f z A)" by simp |
|
60758 | 1247 |
with \<open>finite A\<close> show ?thesis by (simp add: eq_fold fun_eq_iff) |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1248 |
qed |
63404 | 1249 |
|
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1250 |
lemma remove: |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1251 |
assumes "finite A" and "x \<in> A" |
51489 | 1252 |
shows "F A = f x (F (A - {x}))" |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1253 |
proof - |
60758 | 1254 |
from \<open>x \<in> A\<close> obtain B where A: "A = insert x B" and "x \<notin> B" |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1255 |
by (auto dest: mk_disjoint_insert) |
60758 | 1256 |
moreover from \<open>finite A\<close> A have "finite B" by simp |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1257 |
ultimately show ?thesis by simp |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1258 |
qed |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1259 |
|
63404 | 1260 |
lemma insert_remove: "finite A \<Longrightarrow> F (insert x A) = f x (F (A - {x}))" |
1261 |
by (cases "x \<in> A") (simp_all add: remove insert_absorb) |
|
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1262 |
|
34007
aea892559fc5
tuned lattices theory fragements; generlized some lemmas from sets to lattices
haftmann
parents:
33960
diff
changeset
|
1263 |
end |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1264 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1265 |
|
60758 | 1266 |
subsubsection \<open>With idempotency\<close> |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1267 |
|
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1268 |
locale folding_idem = folding + |
51489 | 1269 |
assumes comp_fun_idem: "f x \<circ> f x = f x" |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1270 |
begin |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1271 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1272 |
declare insert [simp del] |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1273 |
|
54870 | 1274 |
interpretation fold?: comp_fun_idem f |
61169 | 1275 |
by standard (insert comp_fun_commute comp_fun_idem, simp add: fun_eq_iff) |
54867
c21a2465cac1
prefer ephemeral interpretation over interpretation in proof contexts;
haftmann
parents:
54611
diff
changeset
|
1276 |
|
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1277 |
lemma insert_idem [simp]: |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1278 |
assumes "finite A" |
51489 | 1279 |
shows "F (insert x A) = f x (F A)" |
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1280 |
proof - |
51489 | 1281 |
from fold_insert_idem assms |
1282 |
have "fold f z (insert x A) = f x (fold f z A)" by simp |
|
60758 | 1283 |
with \<open>finite A\<close> show ?thesis by (simp add: eq_fold fun_eq_iff) |
35719
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1284 |
qed |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1285 |
|
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1286 |
end |
99b6152aedf5
split off theory Big_Operators from theory Finite_Set
haftmann
parents:
35577
diff
changeset
|
1287 |
|
35817
d8b8527102f5
added locales folding_one_(idem); various streamlining and tuning
haftmann
parents:
35796
diff
changeset
|
1288 |
|
60758 | 1289 |
subsection \<open>Finite cardinality\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1290 |
|
60758 | 1291 |
text \<open> |
51489 | 1292 |
The traditional definition |
63404 | 1293 |
@{prop "card A \<equiv> LEAST n. \<exists>f. A = {f i |i. i < n}"} |
51489 | 1294 |
is ugly to work with. |
1295 |
But now that we have @{const fold} things are easy: |
|
60758 | 1296 |
\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1297 |
|
61890
f6ded81f5690
abandoned attempt to unify sublocale and interpretation into global theories
haftmann
parents:
61810
diff
changeset
|
1298 |
global_interpretation card: folding "\<lambda>_. Suc" 0 |
61778 | 1299 |
defines card = "folding.F (\<lambda>_. Suc) 0" |
1300 |
by standard rule |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1301 |
|
63404 | 1302 |
lemma card_infinite: "\<not> finite A \<Longrightarrow> card A = 0" |
51489 | 1303 |
by (fact card.infinite) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1304 |
|
63404 | 1305 |
lemma card_empty: "card {} = 0" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1306 |
by (fact card.empty) |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1307 |
|
63404 | 1308 |
lemma card_insert_disjoint: "finite A \<Longrightarrow> x \<notin> A \<Longrightarrow> card (insert x A) = Suc (card A)" |
51489 | 1309 |
by (fact card.insert) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1310 |
|
63404 | 1311 |
lemma card_insert_if: "finite A \<Longrightarrow> card (insert x A) = (if x \<in> A then card A else Suc (card A))" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1312 |
by auto (simp add: card.insert_remove card.remove) |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1313 |
|
63404 | 1314 |
lemma card_ge_0_finite: "card A > 0 \<Longrightarrow> finite A" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1315 |
by (rule ccontr) simp |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1316 |
|
63404 | 1317 |
lemma card_0_eq [simp]: "finite A \<Longrightarrow> card A = 0 \<longleftrightarrow> A = {}" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1318 |
by (auto dest: mk_disjoint_insert) |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1319 |
|
63404 | 1320 |
lemma finite_UNIV_card_ge_0: "finite (UNIV :: 'a set) \<Longrightarrow> card (UNIV :: 'a set) > 0" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1321 |
by (rule ccontr) simp |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1322 |
|
63404 | 1323 |
lemma card_eq_0_iff: "card A = 0 \<longleftrightarrow> A = {} \<or> \<not> finite A" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1324 |
by auto |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1325 |
|
63404 | 1326 |
lemma card_range_greater_zero: "finite (range f) \<Longrightarrow> card (range f) > 0" |
63365 | 1327 |
by (rule ccontr) (simp add: card_eq_0_iff) |
1328 |
||
63404 | 1329 |
lemma card_gt_0_iff: "0 < card A \<longleftrightarrow> A \<noteq> {} \<and> finite A" |
1330 |
by (simp add: neq0_conv [symmetric] card_eq_0_iff) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1331 |
|
63404 | 1332 |
lemma card_Suc_Diff1: "finite A \<Longrightarrow> x \<in> A \<Longrightarrow> Suc (card (A - {x})) = card A" |
1333 |
apply (rule insert_Diff [THEN subst, where t = A]) |
|
63612 | 1334 |
apply assumption |
63404 | 1335 |
apply (simp del: insert_Diff_single) |
1336 |
done |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1337 |
|
63404 | 1338 |
lemma card_insert_le_m1: "n > 0 \<Longrightarrow> card y \<le> n - 1 \<Longrightarrow> card (insert x y) \<le> n" |
60762 | 1339 |
apply (cases "finite y") |
63612 | 1340 |
apply (cases "x \<in> y") |
1341 |
apply (auto simp: insert_absorb) |
|
60762 | 1342 |
done |
1343 |
||
63404 | 1344 |
lemma card_Diff_singleton: "finite A \<Longrightarrow> x \<in> A \<Longrightarrow> card (A - {x}) = card A - 1" |
51489 | 1345 |
by (simp add: card_Suc_Diff1 [symmetric]) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1346 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1347 |
lemma card_Diff_singleton_if: |
51489 | 1348 |
"finite A \<Longrightarrow> card (A - {x}) = (if x \<in> A then card A - 1 else card A)" |
1349 |
by (simp add: card_Diff_singleton) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1350 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1351 |
lemma card_Diff_insert[simp]: |
51489 | 1352 |
assumes "finite A" and "a \<in> A" and "a \<notin> B" |
1353 |
shows "card (A - insert a B) = card (A - B) - 1" |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1354 |
proof - |
63404 | 1355 |
have "A - insert a B = (A - B) - {a}" |
1356 |
using assms by blast |
|
1357 |
then show ?thesis |
|
1358 |
using assms by (simp add: card_Diff_singleton) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1359 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1360 |
|
63404 | 1361 |
lemma card_insert: "finite A \<Longrightarrow> card (insert x A) = Suc (card (A - {x}))" |
51489 | 1362 |
by (fact card.insert_remove) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1363 |
|
63404 | 1364 |
lemma card_insert_le: "finite A \<Longrightarrow> card A \<le> card (insert x A)" |
1365 |
by (simp add: card_insert_if) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1366 |
|
63404 | 1367 |
lemma card_Collect_less_nat[simp]: "card {i::nat. i < n} = n" |
1368 |
by (induct n) (simp_all add:less_Suc_eq Collect_disj_eq) |
|
41987 | 1369 |
|
63404 | 1370 |
lemma card_Collect_le_nat[simp]: "card {i::nat. i \<le> n} = Suc n" |
1371 |
using card_Collect_less_nat[of "Suc n"] by (simp add: less_Suc_eq_le) |
|
41987 | 1372 |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1373 |
lemma card_mono: |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1374 |
assumes "finite B" and "A \<subseteq> B" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1375 |
shows "card A \<le> card B" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1376 |
proof - |
63404 | 1377 |
from assms have "finite A" |
1378 |
by (auto intro: finite_subset) |
|
1379 |
then show ?thesis |
|
1380 |
using assms |
|
1381 |
proof (induct A arbitrary: B) |
|
1382 |
case empty |
|
1383 |
then show ?case by simp |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1384 |
next |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1385 |
case (insert x A) |
63404 | 1386 |
then have "x \<in> B" |
1387 |
by simp |
|
1388 |
from insert have "A \<subseteq> B - {x}" and "finite (B - {x})" |
|
1389 |
by auto |
|
1390 |
with insert.hyps have "card A \<le> card (B - {x})" |
|
1391 |
by auto |
|
1392 |
with \<open>finite A\<close> \<open>x \<notin> A\<close> \<open>finite B\<close> \<open>x \<in> B\<close> show ?case |
|
1393 |
by simp (simp only: card.remove) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1394 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1395 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1396 |
|
63404 | 1397 |
lemma card_seteq: "finite B \<Longrightarrow> (\<And>A. A \<subseteq> B \<Longrightarrow> card B \<le> card A \<Longrightarrow> A = B)" |
1398 |
apply (induct rule: finite_induct) |
|
63612 | 1399 |
apply simp |
63404 | 1400 |
apply clarify |
1401 |
apply (subgoal_tac "finite A \<and> A - {x} \<subseteq> F") |
|
1402 |
prefer 2 apply (blast intro: finite_subset, atomize) |
|
1403 |
apply (drule_tac x = "A - {x}" in spec) |
|
63648 | 1404 |
apply (simp add: card_Diff_singleton_if split: if_split_asm) |
63404 | 1405 |
apply (case_tac "card A", auto) |
1406 |
done |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1407 |
|
63404 | 1408 |
lemma psubset_card_mono: "finite B \<Longrightarrow> A < B \<Longrightarrow> card A < card B" |
1409 |
apply (simp add: psubset_eq linorder_not_le [symmetric]) |
|
1410 |
apply (blast dest: card_seteq) |
|
1411 |
done |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1412 |
|
51489 | 1413 |
lemma card_Un_Int: |
63404 | 1414 |
assumes "finite A" "finite B" |
51489 | 1415 |
shows "card A + card B = card (A \<union> B) + card (A \<inter> B)" |
63404 | 1416 |
using assms |
1417 |
proof (induct A) |
|
1418 |
case empty |
|
1419 |
then show ?case by simp |
|
51489 | 1420 |
next |
63404 | 1421 |
case insert |
1422 |
then show ?case |
|
51489 | 1423 |
by (auto simp add: insert_absorb Int_insert_left) |
1424 |
qed |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1425 |
|
63404 | 1426 |
lemma card_Un_disjoint: "finite A \<Longrightarrow> finite B \<Longrightarrow> A \<inter> B = {} \<Longrightarrow> card (A \<union> B) = card A + card B" |
1427 |
using card_Un_Int [of A B] by simp |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1428 |
|
59336 | 1429 |
lemma card_Un_le: "card (A \<union> B) \<le> card A + card B" |
63404 | 1430 |
apply (cases "finite A") |
1431 |
apply (cases "finite B") |
|
63612 | 1432 |
apply (use le_iff_add card_Un_Int in blast) |
63404 | 1433 |
apply simp |
1434 |
apply simp |
|
1435 |
done |
|
59336 | 1436 |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1437 |
lemma card_Diff_subset: |
63404 | 1438 |
assumes "finite B" |
1439 |
and "B \<subseteq> A" |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1440 |
shows "card (A - B) = card A - card B" |
63915 | 1441 |
using assms |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1442 |
proof (cases "finite A") |
63404 | 1443 |
case False |
1444 |
with assms show ?thesis |
|
1445 |
by simp |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1446 |
next |
63404 | 1447 |
case True |
1448 |
with assms show ?thesis |
|
1449 |
by (induct B arbitrary: A) simp_all |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1450 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1451 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1452 |
lemma card_Diff_subset_Int: |
63404 | 1453 |
assumes "finite (A \<inter> B)" |
1454 |
shows "card (A - B) = card A - card (A \<inter> B)" |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1455 |
proof - |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1456 |
have "A - B = A - A \<inter> B" by auto |
63404 | 1457 |
with assms show ?thesis |
1458 |
by (simp add: card_Diff_subset) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1459 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1460 |
|
40716 | 1461 |
lemma diff_card_le_card_Diff: |
63404 | 1462 |
assumes "finite B" |
1463 |
shows "card A - card B \<le> card (A - B)" |
|
1464 |
proof - |
|
40716 | 1465 |
have "card A - card B \<le> card A - card (A \<inter> B)" |
1466 |
using card_mono[OF assms Int_lower2, of A] by arith |
|
63404 | 1467 |
also have "\<dots> = card (A - B)" |
1468 |
using assms by (simp add: card_Diff_subset_Int) |
|
40716 | 1469 |
finally show ?thesis . |
1470 |
qed |
|
1471 |
||
63404 | 1472 |
lemma card_Diff1_less: "finite A \<Longrightarrow> x \<in> A \<Longrightarrow> card (A - {x}) < card A" |
1473 |
by (rule Suc_less_SucD) (simp add: card_Suc_Diff1 del: card_Diff_insert) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1474 |
|
63404 | 1475 |
lemma card_Diff2_less: "finite A \<Longrightarrow> x \<in> A \<Longrightarrow> y \<in> A \<Longrightarrow> card (A - {x} - {y}) < card A" |
1476 |
apply (cases "x = y") |
|
1477 |
apply (simp add: card_Diff1_less del:card_Diff_insert) |
|
1478 |
apply (rule less_trans) |
|
1479 |
prefer 2 apply (auto intro!: card_Diff1_less simp del: card_Diff_insert) |
|
1480 |
done |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1481 |
|
63404 | 1482 |
lemma card_Diff1_le: "finite A \<Longrightarrow> card (A - {x}) \<le> card A" |
1483 |
by (cases "x \<in> A") (simp_all add: card_Diff1_less less_imp_le) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1484 |
|
63404 | 1485 |
lemma card_psubset: "finite B \<Longrightarrow> A \<subseteq> B \<Longrightarrow> card A < card B \<Longrightarrow> A < B" |
1486 |
by (erule psubsetI) blast |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1487 |
|
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1488 |
lemma card_le_inj: |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1489 |
assumes fA: "finite A" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1490 |
and fB: "finite B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1491 |
and c: "card A \<le> card B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1492 |
shows "\<exists>f. f ` A \<subseteq> B \<and> inj_on f A" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1493 |
using fA fB c |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1494 |
proof (induct arbitrary: B rule: finite_induct) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1495 |
case empty |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1496 |
then show ?case by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1497 |
next |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1498 |
case (insert x s t) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1499 |
then show ?case |
63404 | 1500 |
proof (induct rule: finite_induct [OF insert.prems(1)]) |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1501 |
case 1 |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1502 |
then show ?case by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1503 |
next |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1504 |
case (2 y t) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1505 |
from "2.prems"(1,2,5) "2.hyps"(1,2) have cst: "card s \<le> card t" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1506 |
by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1507 |
from "2.prems"(3) [OF "2.hyps"(1) cst] |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1508 |
obtain f where "f ` s \<subseteq> t" "inj_on f s" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1509 |
by blast |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1510 |
with "2.prems"(2) "2.hyps"(2) show ?case |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1511 |
apply - |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1512 |
apply (rule exI[where x = "\<lambda>z. if z = x then y else f z"]) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1513 |
apply (auto simp add: inj_on_def) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1514 |
done |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1515 |
qed |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1516 |
qed |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1517 |
|
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1518 |
lemma card_subset_eq: |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1519 |
assumes fB: "finite B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1520 |
and AB: "A \<subseteq> B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1521 |
and c: "card A = card B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1522 |
shows "A = B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1523 |
proof - |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1524 |
from fB AB have fA: "finite A" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1525 |
by (auto intro: finite_subset) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1526 |
from fA fB have fBA: "finite (B - A)" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1527 |
by auto |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1528 |
have e: "A \<inter> (B - A) = {}" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1529 |
by blast |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1530 |
have eq: "A \<union> (B - A) = B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1531 |
using AB by blast |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1532 |
from card_Un_disjoint[OF fA fBA e, unfolded eq c] have "card (B - A) = 0" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1533 |
by arith |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1534 |
then have "B - A = {}" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1535 |
unfolding card_eq_0_iff using fA fB by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1536 |
with AB show "A = B" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1537 |
by blast |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1538 |
qed |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1539 |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1540 |
lemma insert_partition: |
63404 | 1541 |
"x \<notin> F \<Longrightarrow> \<forall>c1 \<in> insert x F. \<forall>c2 \<in> insert x F. c1 \<noteq> c2 \<longrightarrow> c1 \<inter> c2 = {} \<Longrightarrow> x \<inter> \<Union>F = {}" |
63612 | 1542 |
by auto (* somewhat slow *) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1543 |
|
63404 | 1544 |
lemma finite_psubset_induct [consumes 1, case_names psubset]: |
1545 |
assumes finite: "finite A" |
|
1546 |
and major: "\<And>A. finite A \<Longrightarrow> (\<And>B. B \<subset> A \<Longrightarrow> P B) \<Longrightarrow> P A" |
|
36079
fa0e354e6a39
simplified induction case in finite_psubset_induct; tuned the proof that uses this induction principle
Christian Urban <urbanc@in.tum.de>
parents:
36045
diff
changeset
|
1547 |
shows "P A" |
63404 | 1548 |
using finite |
36079
fa0e354e6a39
simplified induction case in finite_psubset_induct; tuned the proof that uses this induction principle
Christian Urban <urbanc@in.tum.de>
parents:
36045
diff
changeset
|
1549 |
proof (induct A taking: card rule: measure_induct_rule) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1550 |
case (less A) |
36079
fa0e354e6a39
simplified induction case in finite_psubset_induct; tuned the proof that uses this induction principle
Christian Urban <urbanc@in.tum.de>
parents:
36045
diff
changeset
|
1551 |
have fin: "finite A" by fact |
63404 | 1552 |
have ih: "card B < card A \<Longrightarrow> finite B \<Longrightarrow> P B" for B by fact |
1553 |
have "P B" if "B \<subset> A" for B |
|
1554 |
proof - |
|
1555 |
from that have "card B < card A" |
|
1556 |
using psubset_card_mono fin by blast |
|
36079
fa0e354e6a39
simplified induction case in finite_psubset_induct; tuned the proof that uses this induction principle
Christian Urban <urbanc@in.tum.de>
parents:
36045
diff
changeset
|
1557 |
moreover |
63404 | 1558 |
from that have "B \<subseteq> A" |
1559 |
by auto |
|
1560 |
then have "finite B" |
|
1561 |
using fin finite_subset by blast |
|
1562 |
ultimately show ?thesis using ih by simp |
|
1563 |
qed |
|
36079
fa0e354e6a39
simplified induction case in finite_psubset_induct; tuned the proof that uses this induction principle
Christian Urban <urbanc@in.tum.de>
parents:
36045
diff
changeset
|
1564 |
with fin show "P A" using major by blast |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1565 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1566 |
|
63404 | 1567 |
lemma finite_induct_select [consumes 1, case_names empty select]: |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1568 |
assumes "finite S" |
63404 | 1569 |
and "P {}" |
1570 |
and select: "\<And>T. T \<subset> S \<Longrightarrow> P T \<Longrightarrow> \<exists>s\<in>S - T. P (insert s T)" |
|
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1571 |
shows "P S" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1572 |
proof - |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1573 |
have "0 \<le> card S" by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1574 |
then have "\<exists>T \<subseteq> S. card T = card S \<and> P T" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1575 |
proof (induct rule: dec_induct) |
63404 | 1576 |
case base with \<open>P {}\<close> |
1577 |
show ?case |
|
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1578 |
by (intro exI[of _ "{}"]) auto |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1579 |
next |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1580 |
case (step n) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1581 |
then obtain T where T: "T \<subseteq> S" "card T = n" "P T" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1582 |
by auto |
60758 | 1583 |
with \<open>n < card S\<close> have "T \<subset> S" "P T" |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1584 |
by auto |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1585 |
with select[of T] obtain s where "s \<in> S" "s \<notin> T" "P (insert s T)" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1586 |
by auto |
60758 | 1587 |
with step(2) T \<open>finite S\<close> show ?case |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1588 |
by (intro exI[of _ "insert s T"]) (auto dest: finite_subset) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1589 |
qed |
60758 | 1590 |
with \<open>finite S\<close> show "P S" |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1591 |
by (auto dest: card_subset_eq) |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1592 |
qed |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
54148
diff
changeset
|
1593 |
|
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1594 |
lemma remove_induct [case_names empty infinite remove]: |
63404 | 1595 |
assumes empty: "P ({} :: 'a set)" |
1596 |
and infinite: "\<not> finite B \<Longrightarrow> P B" |
|
1597 |
and remove: "\<And>A. finite A \<Longrightarrow> A \<noteq> {} \<Longrightarrow> A \<subseteq> B \<Longrightarrow> (\<And>x. x \<in> A \<Longrightarrow> P (A - {x})) \<Longrightarrow> P A" |
|
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1598 |
shows "P B" |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1599 |
proof (cases "finite B") |
63612 | 1600 |
case False |
63404 | 1601 |
then show ?thesis by (rule infinite) |
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1602 |
next |
63612 | 1603 |
case True |
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1604 |
define A where "A = B" |
63612 | 1605 |
with True have "finite A" "A \<subseteq> B" |
1606 |
by simp_all |
|
63404 | 1607 |
then show "P A" |
1608 |
proof (induct "card A" arbitrary: A) |
|
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1609 |
case 0 |
63404 | 1610 |
then have "A = {}" by auto |
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1611 |
with empty show ?case by simp |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1612 |
next |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1613 |
case (Suc n A) |
63404 | 1614 |
from \<open>A \<subseteq> B\<close> and \<open>finite B\<close> have "finite A" |
1615 |
by (rule finite_subset) |
|
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1616 |
moreover from Suc.hyps have "A \<noteq> {}" by auto |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1617 |
moreover note \<open>A \<subseteq> B\<close> |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1618 |
moreover have "P (A - {x})" if x: "x \<in> A" for x |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1619 |
using x Suc.prems \<open>Suc n = card A\<close> by (intro Suc) auto |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1620 |
ultimately show ?case by (rule remove) |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1621 |
qed |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1622 |
qed |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1623 |
|
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1624 |
lemma finite_remove_induct [consumes 1, case_names empty remove]: |
63404 | 1625 |
fixes P :: "'a set \<Rightarrow> bool" |
63612 | 1626 |
assumes "finite B" |
1627 |
and "P {}" |
|
1628 |
and "\<And>A. finite A \<Longrightarrow> A \<noteq> {} \<Longrightarrow> A \<subseteq> B \<Longrightarrow> (\<And>x. x \<in> A \<Longrightarrow> P (A - {x})) \<Longrightarrow> P A" |
|
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1629 |
defines "B' \<equiv> B" |
63404 | 1630 |
shows "P B'" |
1631 |
by (induct B' rule: remove_induct) (simp_all add: assms) |
|
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1632 |
|
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1633 |
|
63404 | 1634 |
text \<open>Main cardinality theorem.\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1635 |
lemma card_partition [rule_format]: |
63404 | 1636 |
"finite C \<Longrightarrow> finite (\<Union>C) \<Longrightarrow> (\<forall>c\<in>C. card c = k) \<Longrightarrow> |
1637 |
(\<forall>c1 \<in> C. \<forall>c2 \<in> C. c1 \<noteq> c2 \<longrightarrow> c1 \<inter> c2 = {}) \<Longrightarrow> |
|
1638 |
k * card C = card (\<Union>C)" |
|
63612 | 1639 |
proof (induct rule: finite_induct) |
1640 |
case empty |
|
1641 |
then show ?case by simp |
|
1642 |
next |
|
1643 |
case (insert x F) |
|
1644 |
then show ?case |
|
1645 |
by (simp add: card_Un_disjoint insert_partition finite_subset [of _ "\<Union>(insert _ _)"]) |
|
1646 |
qed |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1647 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1648 |
lemma card_eq_UNIV_imp_eq_UNIV: |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1649 |
assumes fin: "finite (UNIV :: 'a set)" |
63404 | 1650 |
and card: "card A = card (UNIV :: 'a set)" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1651 |
shows "A = (UNIV :: 'a set)" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1652 |
proof |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1653 |
show "A \<subseteq> UNIV" by simp |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1654 |
show "UNIV \<subseteq> A" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1655 |
proof |
63404 | 1656 |
show "x \<in> A" for x |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1657 |
proof (rule ccontr) |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1658 |
assume "x \<notin> A" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1659 |
then have "A \<subset> UNIV" by auto |
63404 | 1660 |
with fin have "card A < card (UNIV :: 'a set)" |
1661 |
by (fact psubset_card_mono) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1662 |
with card show False by simp |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1663 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1664 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1665 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1666 |
|
63404 | 1667 |
text \<open>The form of a finite set of given cardinality\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1668 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1669 |
lemma card_eq_SucD: |
63404 | 1670 |
assumes "card A = Suc k" |
1671 |
shows "\<exists>b B. A = insert b B \<and> b \<notin> B \<and> card B = k \<and> (k = 0 \<longrightarrow> B = {})" |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1672 |
proof - |
63404 | 1673 |
have fin: "finite A" |
1674 |
using assms by (auto intro: ccontr) |
|
1675 |
moreover have "card A \<noteq> 0" |
|
1676 |
using assms by auto |
|
1677 |
ultimately obtain b where b: "b \<in> A" |
|
1678 |
by auto |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1679 |
show ?thesis |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1680 |
proof (intro exI conjI) |
63404 | 1681 |
show "A = insert b (A - {b})" |
1682 |
using b by blast |
|
1683 |
show "b \<notin> A - {b}" |
|
1684 |
by blast |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1685 |
show "card (A - {b}) = k" and "k = 0 \<longrightarrow> A - {b} = {}" |
63612 | 1686 |
using assms b fin by (fastforce dest: mk_disjoint_insert)+ |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1687 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1688 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1689 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1690 |
lemma card_Suc_eq: |
63404 | 1691 |
"card A = Suc k \<longleftrightarrow> |
1692 |
(\<exists>b B. A = insert b B \<and> b \<notin> B \<and> card B = k \<and> (k = 0 \<longrightarrow> B = {}))" |
|
1693 |
apply (auto elim!: card_eq_SucD) |
|
1694 |
apply (subst card.insert) |
|
63612 | 1695 |
apply (auto simp add: intro:ccontr) |
63404 | 1696 |
done |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1697 |
|
61518
ff12606337e9
new lemmas about topology, etc., for Cauchy integral formula
paulson
parents:
61169
diff
changeset
|
1698 |
lemma card_1_singletonE: |
63404 | 1699 |
assumes "card A = 1" |
1700 |
obtains x where "A = {x}" |
|
61518
ff12606337e9
new lemmas about topology, etc., for Cauchy integral formula
paulson
parents:
61169
diff
changeset
|
1701 |
using assms by (auto simp: card_Suc_eq) |
ff12606337e9
new lemmas about topology, etc., for Cauchy integral formula
paulson
parents:
61169
diff
changeset
|
1702 |
|
63099
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1703 |
lemma is_singleton_altdef: "is_singleton A \<longleftrightarrow> card A = 1" |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1704 |
unfolding is_singleton_def |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1705 |
by (auto elim!: card_1_singletonE is_singletonE simp del: One_nat_def) |
af0e964aad7b
Moved material from AFP/Randomised_Social_Choice to distribution
eberlm
parents:
63040
diff
changeset
|
1706 |
|
63404 | 1707 |
lemma card_le_Suc_iff: |
1708 |
"finite A \<Longrightarrow> Suc n \<le> card A = (\<exists>a B. A = insert a B \<and> a \<notin> B \<and> n \<le> card B \<and> finite B)" |
|
1709 |
by (fastforce simp: card_Suc_eq less_eq_nat.simps(2) insert_eq_iff |
|
1710 |
dest: subset_singletonD split: nat.splits if_splits) |
|
44744 | 1711 |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1712 |
lemma finite_fun_UNIVD2: |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1713 |
assumes fin: "finite (UNIV :: ('a \<Rightarrow> 'b) set)" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1714 |
shows "finite (UNIV :: 'b set)" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1715 |
proof - |
63404 | 1716 |
from fin have "finite (range (\<lambda>f :: 'a \<Rightarrow> 'b. f arbitrary))" for arbitrary |
46146
6baea4fca6bd
incorporated various theorems from theory More_Set into corpus
haftmann
parents:
46033
diff
changeset
|
1717 |
by (rule finite_imageI) |
63404 | 1718 |
moreover have "UNIV = range (\<lambda>f :: 'a \<Rightarrow> 'b. f arbitrary)" for arbitrary |
46146
6baea4fca6bd
incorporated various theorems from theory More_Set into corpus
haftmann
parents:
46033
diff
changeset
|
1719 |
by (rule UNIV_eq_I) auto |
63404 | 1720 |
ultimately show "finite (UNIV :: 'b set)" |
1721 |
by simp |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1722 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1723 |
|
48063
f02b4302d5dd
remove duplicate lemma card_unit in favor of Finite_Set.card_UNIV_unit
huffman
parents:
47221
diff
changeset
|
1724 |
lemma card_UNIV_unit [simp]: "card (UNIV :: unit set) = 1" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1725 |
unfolding UNIV_unit by simp |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1726 |
|
57447
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1727 |
lemma infinite_arbitrarily_large: |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1728 |
assumes "\<not> finite A" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1729 |
shows "\<exists>B. finite B \<and> card B = n \<and> B \<subseteq> A" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1730 |
proof (induction n) |
63404 | 1731 |
case 0 |
1732 |
show ?case by (intro exI[of _ "{}"]) auto |
|
1733 |
next |
|
57447
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1734 |
case (Suc n) |
63404 | 1735 |
then obtain B where B: "finite B \<and> card B = n \<and> B \<subseteq> A" .. |
60758 | 1736 |
with \<open>\<not> finite A\<close> have "A \<noteq> B" by auto |
57447
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1737 |
with B have "B \<subset> A" by auto |
63404 | 1738 |
then have "\<exists>x. x \<in> A - B" |
1739 |
by (elim psubset_imp_ex_mem) |
|
1740 |
then obtain x where x: "x \<in> A - B" .. |
|
57447
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1741 |
with B have "finite (insert x B) \<and> card (insert x B) = Suc n \<and> insert x B \<subseteq> A" |
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1742 |
by auto |
63404 | 1743 |
then show "\<exists>B. finite B \<and> card B = Suc n \<and> B \<subseteq> A" .. |
57447
87429bdecad5
import more stuff from the CLT proof; base the lborel measure on interval_measure; remove lebesgue measure
hoelzl
parents:
57025
diff
changeset
|
1744 |
qed |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1745 |
|
63404 | 1746 |
|
60758 | 1747 |
subsubsection \<open>Cardinality of image\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1748 |
|
63404 | 1749 |
lemma card_image_le: "finite A \<Longrightarrow> card (f ` A) \<le> card A" |
54570 | 1750 |
by (induct rule: finite_induct) (simp_all add: le_SucI card_insert_if) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1751 |
|
63915 | 1752 |
lemma card_image: "inj_on f A \<Longrightarrow> card (f ` A) = card A" |
1753 |
proof (induct A rule: infinite_finite_induct) |
|
1754 |
case (infinite A) |
|
1755 |
then have "\<not> finite (f ` A)" by (auto dest: finite_imageD) |
|
1756 |
with infinite show ?case by simp |
|
1757 |
qed simp_all |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1758 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1759 |
lemma bij_betw_same_card: "bij_betw f A B \<Longrightarrow> card A = card B" |
63612 | 1760 |
by (auto simp: card_image bij_betw_def) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1761 |
|
63404 | 1762 |
lemma endo_inj_surj: "finite A \<Longrightarrow> f ` A \<subseteq> A \<Longrightarrow> inj_on f A \<Longrightarrow> f ` A = A" |
1763 |
by (simp add: card_seteq card_image) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1764 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1765 |
lemma eq_card_imp_inj_on: |
63404 | 1766 |
assumes "finite A" "card(f ` A) = card A" |
1767 |
shows "inj_on f A" |
|
1768 |
using assms |
|
54570 | 1769 |
proof (induct rule:finite_induct) |
63404 | 1770 |
case empty |
1771 |
show ?case by simp |
|
54570 | 1772 |
next |
1773 |
case (insert x A) |
|
63404 | 1774 |
then show ?case |
1775 |
using card_image_le [of A f] by (simp add: card_insert_if split: if_splits) |
|
54570 | 1776 |
qed |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1777 |
|
63404 | 1778 |
lemma inj_on_iff_eq_card: "finite A \<Longrightarrow> inj_on f A \<longleftrightarrow> card (f ` A) = card A" |
54570 | 1779 |
by (blast intro: card_image eq_card_imp_inj_on) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1780 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1781 |
lemma card_inj_on_le: |
63404 | 1782 |
assumes "inj_on f A" "f ` A \<subseteq> B" "finite B" |
1783 |
shows "card A \<le> card B" |
|
54570 | 1784 |
proof - |
63404 | 1785 |
have "finite A" |
1786 |
using assms by (blast intro: finite_imageD dest: finite_subset) |
|
1787 |
then show ?thesis |
|
1788 |
using assms by (force intro: card_mono simp: card_image [symmetric]) |
|
54570 | 1789 |
qed |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1790 |
|
59504
8c6747dba731
New lemmas and a bit of tidying up.
paulson <lp15@cam.ac.uk>
parents:
59336
diff
changeset
|
1791 |
lemma surj_card_le: "finite A \<Longrightarrow> B \<subseteq> f ` A \<Longrightarrow> card B \<le> card A" |
8c6747dba731
New lemmas and a bit of tidying up.
paulson <lp15@cam.ac.uk>
parents:
59336
diff
changeset
|
1792 |
by (blast intro: card_image_le card_mono le_trans) |
8c6747dba731
New lemmas and a bit of tidying up.
paulson <lp15@cam.ac.uk>
parents:
59336
diff
changeset
|
1793 |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1794 |
lemma card_bij_eq: |
63404 | 1795 |
"inj_on f A \<Longrightarrow> f ` A \<subseteq> B \<Longrightarrow> inj_on g B \<Longrightarrow> g ` B \<subseteq> A \<Longrightarrow> finite A \<Longrightarrow> finite B |
1796 |
\<Longrightarrow> card A = card B" |
|
1797 |
by (auto intro: le_antisym card_inj_on_le) |
|
1798 |
||
1799 |
lemma bij_betw_finite: "bij_betw f A B \<Longrightarrow> finite A \<longleftrightarrow> finite B" |
|
1800 |
unfolding bij_betw_def using finite_imageD [of f A] by auto |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1801 |
|
63404 | 1802 |
lemma inj_on_finite: "inj_on f A \<Longrightarrow> f ` A \<le> B \<Longrightarrow> finite B \<Longrightarrow> finite A" |
1803 |
using finite_imageD finite_subset by blast |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1804 |
|
63404 | 1805 |
lemma card_vimage_inj: "inj f \<Longrightarrow> A \<subseteq> range f \<Longrightarrow> card (f -` A) = card A" |
1806 |
by (auto 4 3 simp: subset_image_iff inj_vimage_image_eq |
|
1807 |
intro: card_image[symmetric, OF subset_inj_on]) |
|
55020 | 1808 |
|
41656 | 1809 |
|
60758 | 1810 |
subsubsection \<open>Pigeonhole Principles\<close> |
37466 | 1811 |
|
63404 | 1812 |
lemma pigeonhole: "card A > card (f ` A) \<Longrightarrow> \<not> inj_on f A " |
1813 |
by (auto dest: card_image less_irrefl_nat) |
|
37466 | 1814 |
|
1815 |
lemma pigeonhole_infinite: |
|
63404 | 1816 |
assumes "\<not> finite A" and "finite (f`A)" |
1817 |
shows "\<exists>a0\<in>A. \<not> finite {a\<in>A. f a = f a0}" |
|
1818 |
using assms(2,1) |
|
1819 |
proof (induct "f`A" arbitrary: A rule: finite_induct) |
|
1820 |
case empty |
|
1821 |
then show ?case by simp |
|
1822 |
next |
|
1823 |
case (insert b F) |
|
1824 |
show ?case |
|
1825 |
proof (cases "finite {a\<in>A. f a = b}") |
|
1826 |
case True |
|
1827 |
with \<open>\<not> finite A\<close> have "\<not> finite (A - {a\<in>A. f a = b})" |
|
1828 |
by simp |
|
1829 |
also have "A - {a\<in>A. f a = b} = {a\<in>A. f a \<noteq> b}" |
|
1830 |
by blast |
|
1831 |
finally have "\<not> finite {a\<in>A. f a \<noteq> b}" . |
|
1832 |
from insert(3)[OF _ this] insert(2,4) show ?thesis |
|
1833 |
by simp (blast intro: rev_finite_subset) |
|
37466 | 1834 |
next |
63404 | 1835 |
case False |
1836 |
then have "{a \<in> A. f a = b} \<noteq> {}" by force |
|
1837 |
with False show ?thesis by blast |
|
37466 | 1838 |
qed |
1839 |
qed |
|
1840 |
||
1841 |
lemma pigeonhole_infinite_rel: |
|
63404 | 1842 |
assumes "\<not> finite A" |
1843 |
and "finite B" |
|
1844 |
and "\<forall>a\<in>A. \<exists>b\<in>B. R a b" |
|
1845 |
shows "\<exists>b\<in>B. \<not> finite {a:A. R a b}" |
|
37466 | 1846 |
proof - |
63404 | 1847 |
let ?F = "\<lambda>a. {b\<in>B. R a b}" |
1848 |
from finite_Pow_iff[THEN iffD2, OF \<open>finite B\<close>] have "finite (?F ` A)" |
|
1849 |
by (blast intro: rev_finite_subset) |
|
1850 |
from pigeonhole_infinite [where f = ?F, OF assms(1) this] |
|
63612 | 1851 |
obtain a0 where "a0 \<in> A" and infinite: "\<not> finite {a\<in>A. ?F a = ?F a0}" .. |
63404 | 1852 |
obtain b0 where "b0 \<in> B" and "R a0 b0" |
1853 |
using \<open>a0 \<in> A\<close> assms(3) by blast |
|
63612 | 1854 |
have "finite {a\<in>A. ?F a = ?F a0}" if "finite {a\<in>A. R a b0}" |
63404 | 1855 |
using \<open>b0 \<in> B\<close> \<open>R a0 b0\<close> that by (blast intro: rev_finite_subset) |
63612 | 1856 |
with infinite \<open>b0 \<in> B\<close> show ?thesis |
63404 | 1857 |
by blast |
37466 | 1858 |
qed |
1859 |
||
1860 |
||
60758 | 1861 |
subsubsection \<open>Cardinality of sums\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1862 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1863 |
lemma card_Plus: |
63404 | 1864 |
assumes "finite A" "finite B" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1865 |
shows "card (A <+> B) = card A + card B" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1866 |
proof - |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1867 |
have "Inl`A \<inter> Inr`B = {}" by fast |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1868 |
with assms show ?thesis |
63404 | 1869 |
by (simp add: Plus_def card_Un_disjoint card_image) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1870 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1871 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1872 |
lemma card_Plus_conv_if: |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1873 |
"card (A <+> B) = (if finite A \<and> finite B then card A + card B else 0)" |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1874 |
by (auto simp add: card_Plus) |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1875 |
|
63404 | 1876 |
text \<open>Relates to equivalence classes. Based on a theorem of F. Kammüller.\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1877 |
|
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1878 |
lemma dvd_partition: |
63404 | 1879 |
assumes f: "finite (\<Union>C)" |
1880 |
and "\<forall>c\<in>C. k dvd card c" "\<forall>c1\<in>C. \<forall>c2\<in>C. c1 \<noteq> c2 \<longrightarrow> c1 \<inter> c2 = {}" |
|
1881 |
shows "k dvd card (\<Union>C)" |
|
54570 | 1882 |
proof - |
63404 | 1883 |
have "finite C" |
54570 | 1884 |
by (rule finite_UnionD [OF f]) |
63404 | 1885 |
then show ?thesis |
1886 |
using assms |
|
54570 | 1887 |
proof (induct rule: finite_induct) |
63404 | 1888 |
case empty |
1889 |
show ?case by simp |
|
54570 | 1890 |
next |
63404 | 1891 |
case insert |
1892 |
then show ?case |
|
54570 | 1893 |
apply simp |
1894 |
apply (subst card_Un_disjoint) |
|
63612 | 1895 |
apply (auto simp add: disjoint_eq_subset_Compl) |
54570 | 1896 |
done |
1897 |
qed |
|
1898 |
qed |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1899 |
|
63404 | 1900 |
|
60758 | 1901 |
subsubsection \<open>Relating injectivity and surjectivity\<close> |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1902 |
|
63404 | 1903 |
lemma finite_surj_inj: |
1904 |
assumes "finite A" "A \<subseteq> f ` A" |
|
1905 |
shows "inj_on f A" |
|
54570 | 1906 |
proof - |
63404 | 1907 |
have "f ` A = A" |
54570 | 1908 |
by (rule card_seteq [THEN sym]) (auto simp add: assms card_image_le) |
1909 |
then show ?thesis using assms |
|
1910 |
by (simp add: eq_card_imp_inj_on) |
|
1911 |
qed |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1912 |
|
63612 | 1913 |
lemma finite_UNIV_surj_inj: "finite(UNIV:: 'a set) \<Longrightarrow> surj f \<Longrightarrow> inj f" |
1914 |
for f :: "'a \<Rightarrow> 'a" |
|
63404 | 1915 |
by (blast intro: finite_surj_inj subset_UNIV) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1916 |
|
63612 | 1917 |
lemma finite_UNIV_inj_surj: "finite(UNIV:: 'a set) \<Longrightarrow> inj f \<Longrightarrow> surj f" |
1918 |
for f :: "'a \<Rightarrow> 'a" |
|
63404 | 1919 |
by (fastforce simp:surj_def dest!: endo_inj_surj) |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1920 |
|
63404 | 1921 |
corollary infinite_UNIV_nat [iff]: "\<not> finite (UNIV :: nat set)" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1922 |
proof |
51489 | 1923 |
assume "finite (UNIV :: nat set)" |
63404 | 1924 |
with finite_UNIV_inj_surj [of Suc] show False |
1925 |
by simp (blast dest: Suc_neq_Zero surjD) |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1926 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1927 |
|
63404 | 1928 |
lemma infinite_UNIV_char_0: "\<not> finite (UNIV :: 'a::semiring_char_0 set)" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1929 |
proof |
51489 | 1930 |
assume "finite (UNIV :: 'a set)" |
1931 |
with subset_UNIV have "finite (range of_nat :: 'a set)" |
|
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1932 |
by (rule finite_subset) |
51489 | 1933 |
moreover have "inj (of_nat :: nat \<Rightarrow> 'a)" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1934 |
by (simp add: inj_on_def) |
51489 | 1935 |
ultimately have "finite (UNIV :: nat set)" |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1936 |
by (rule finite_imageD) |
51489 | 1937 |
then show False |
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1938 |
by simp |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1939 |
qed |
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
1940 |
|
49758
718f10c8bbfc
use Set.filter instead of Finite_Set.filter, which is removed then
kuncar
parents:
49757
diff
changeset
|
1941 |
hide_const (open) Finite_Set.fold |
46033 | 1942 |
|
61810 | 1943 |
|
63404 | 1944 |
subsection \<open>Infinite Sets\<close> |
61810 | 1945 |
|
1946 |
text \<open> |
|
1947 |
Some elementary facts about infinite sets, mostly by Stephan Merz. |
|
1948 |
Beware! Because "infinite" merely abbreviates a negation, these |
|
1949 |
lemmas may not work well with \<open>blast\<close>. |
|
1950 |
\<close> |
|
1951 |
||
1952 |
abbreviation infinite :: "'a set \<Rightarrow> bool" |
|
1953 |
where "infinite S \<equiv> \<not> finite S" |
|
1954 |
||
1955 |
text \<open> |
|
1956 |
Infinite sets are non-empty, and if we remove some elements from an |
|
1957 |
infinite set, the result is still infinite. |
|
1958 |
\<close> |
|
1959 |
||
1960 |
lemma infinite_imp_nonempty: "infinite S \<Longrightarrow> S \<noteq> {}" |
|
1961 |
by auto |
|
1962 |
||
1963 |
lemma infinite_remove: "infinite S \<Longrightarrow> infinite (S - {a})" |
|
1964 |
by simp |
|
1965 |
||
1966 |
lemma Diff_infinite_finite: |
|
63404 | 1967 |
assumes "finite T" "infinite S" |
61810 | 1968 |
shows "infinite (S - T)" |
63404 | 1969 |
using \<open>finite T\<close> |
61810 | 1970 |
proof induct |
63404 | 1971 |
from \<open>infinite S\<close> show "infinite (S - {})" |
1972 |
by auto |
|
61810 | 1973 |
next |
1974 |
fix T x |
|
1975 |
assume ih: "infinite (S - T)" |
|
1976 |
have "S - (insert x T) = (S - T) - {x}" |
|
1977 |
by (rule Diff_insert) |
|
63404 | 1978 |
with ih show "infinite (S - (insert x T))" |
61810 | 1979 |
by (simp add: infinite_remove) |
1980 |
qed |
|
1981 |
||
1982 |
lemma Un_infinite: "infinite S \<Longrightarrow> infinite (S \<union> T)" |
|
1983 |
by simp |
|
1984 |
||
1985 |
lemma infinite_Un: "infinite (S \<union> T) \<longleftrightarrow> infinite S \<or> infinite T" |
|
1986 |
by simp |
|
1987 |
||
1988 |
lemma infinite_super: |
|
63404 | 1989 |
assumes "S \<subseteq> T" |
1990 |
and "infinite S" |
|
61810 | 1991 |
shows "infinite T" |
1992 |
proof |
|
1993 |
assume "finite T" |
|
63404 | 1994 |
with \<open>S \<subseteq> T\<close> have "finite S" by (simp add: finite_subset) |
1995 |
with \<open>infinite S\<close> show False by simp |
|
61810 | 1996 |
qed |
1997 |
||
1998 |
proposition infinite_coinduct [consumes 1, case_names infinite]: |
|
1999 |
assumes "X A" |
|
63404 | 2000 |
and step: "\<And>A. X A \<Longrightarrow> \<exists>x\<in>A. X (A - {x}) \<or> infinite (A - {x})" |
61810 | 2001 |
shows "infinite A" |
2002 |
proof |
|
2003 |
assume "finite A" |
|
63404 | 2004 |
then show False |
2005 |
using \<open>X A\<close> |
|
61810 | 2006 |
proof (induction rule: finite_psubset_induct) |
2007 |
case (psubset A) |
|
2008 |
then obtain x where "x \<in> A" "X (A - {x}) \<or> infinite (A - {x})" |
|
2009 |
using local.step psubset.prems by blast |
|
2010 |
then have "X (A - {x})" |
|
2011 |
using psubset.hyps by blast |
|
2012 |
show False |
|
2013 |
apply (rule psubset.IH [where B = "A - {x}"]) |
|
63612 | 2014 |
apply (use \<open>x \<in> A\<close> in blast) |
63404 | 2015 |
apply (simp add: \<open>X (A - {x})\<close>) |
2016 |
done |
|
61810 | 2017 |
qed |
2018 |
qed |
|
2019 |
||
2020 |
text \<open> |
|
2021 |
For any function with infinite domain and finite range there is some |
|
2022 |
element that is the image of infinitely many domain elements. In |
|
2023 |
particular, any infinite sequence of elements from a finite set |
|
2024 |
contains some element that occurs infinitely often. |
|
2025 |
\<close> |
|
2026 |
||
2027 |
lemma inf_img_fin_dom': |
|
63404 | 2028 |
assumes img: "finite (f ` A)" |
2029 |
and dom: "infinite A" |
|
61810 | 2030 |
shows "\<exists>y \<in> f ` A. infinite (f -` {y} \<inter> A)" |
2031 |
proof (rule ccontr) |
|
2032 |
have "A \<subseteq> (\<Union>y\<in>f ` A. f -` {y} \<inter> A)" by auto |
|
63404 | 2033 |
moreover assume "\<not> ?thesis" |
61810 | 2034 |
with img have "finite (\<Union>y\<in>f ` A. f -` {y} \<inter> A)" by blast |
63404 | 2035 |
ultimately have "finite A" by (rule finite_subset) |
61810 | 2036 |
with dom show False by contradiction |
2037 |
qed |
|
2038 |
||
2039 |
lemma inf_img_fin_domE': |
|
2040 |
assumes "finite (f ` A)" and "infinite A" |
|
2041 |
obtains y where "y \<in> f`A" and "infinite (f -` {y} \<inter> A)" |
|
2042 |
using assms by (blast dest: inf_img_fin_dom') |
|
2043 |
||
2044 |
lemma inf_img_fin_dom: |
|
2045 |
assumes img: "finite (f`A)" and dom: "infinite A" |
|
2046 |
shows "\<exists>y \<in> f`A. infinite (f -` {y})" |
|
63404 | 2047 |
using inf_img_fin_dom'[OF assms] by auto |
61810 | 2048 |
|
2049 |
lemma inf_img_fin_domE: |
|
2050 |
assumes "finite (f`A)" and "infinite A" |
|
2051 |
obtains y where "y \<in> f`A" and "infinite (f -` {y})" |
|
2052 |
using assms by (blast dest: inf_img_fin_dom) |
|
2053 |
||
63404 | 2054 |
proposition finite_image_absD: "finite (abs ` S) \<Longrightarrow> finite S" |
2055 |
for S :: "'a::linordered_ring set" |
|
61810 | 2056 |
by (rule ccontr) (auto simp: abs_eq_iff vimage_def dest: inf_img_fin_dom) |
2057 |
||
35722
69419a09a7ff
moved cardinality to Finite_Set as far as appropriate; added locales for fold_image
haftmann
parents:
35719
diff
changeset
|
2058 |
end |