author | wenzelm |
Mon, 28 Dec 2015 01:26:34 +0100 | |
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parent 61841 | 4d3527b94f2a |
child 62390 | 842917225d56 |
permissions | -rw-r--r-- |
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(* Title: HOL/Partial_Function.thy |
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Author: Alexander Krauss, TU Muenchen |
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*) |
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section \<open>Partial Function Definitions\<close> |
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theory Partial_Function |
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imports Complete_Partial_Order Fun_Def_Base Option |
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keywords "partial_function" :: thy_decl |
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begin |
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named_theorems partial_function_mono "monotonicity rules for partial function definitions" |
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ML_file "Tools/Function/partial_function.ML" |
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lemma (in ccpo) in_chain_finite: |
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assumes "Complete_Partial_Order.chain op \<le> A" "finite A" "A \<noteq> {}" |
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shows "\<Squnion>A \<in> A" |
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using assms(2,1,3) |
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proof induction |
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case empty thus ?case by simp |
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next |
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case (insert x A) |
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note chain = \<open>Complete_Partial_Order.chain op \<le> (insert x A)\<close> |
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show ?case |
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proof(cases "A = {}") |
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case True thus ?thesis by simp |
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next |
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case False |
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from chain have chain': "Complete_Partial_Order.chain op \<le> A" |
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by(rule chain_subset) blast |
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hence "\<Squnion>A \<in> A" using False by(rule insert.IH) |
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show ?thesis |
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proof(cases "x \<le> \<Squnion>A") |
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case True |
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have "\<Squnion>insert x A \<le> \<Squnion>A" using chain |
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by(rule ccpo_Sup_least)(auto simp add: True intro: ccpo_Sup_upper[OF chain']) |
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hence "\<Squnion>insert x A = \<Squnion>A" |
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by(rule antisym)(blast intro: ccpo_Sup_upper[OF chain] ccpo_Sup_least[OF chain']) |
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with \<open>\<Squnion>A \<in> A\<close> show ?thesis by simp |
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next |
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case False |
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with chainD[OF chain, of x "\<Squnion>A"] \<open>\<Squnion>A \<in> A\<close> |
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have "\<Squnion>insert x A = x" |
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by(auto intro: antisym ccpo_Sup_least[OF chain] order_trans[OF ccpo_Sup_upper[OF chain']] ccpo_Sup_upper[OF chain]) |
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thus ?thesis by simp |
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qed |
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qed |
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qed |
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subsection \<open>Axiomatic setup\<close> |
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text \<open>This techical locale constains the requirements for function |
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definitions with ccpo fixed points.\<close> |
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definition "fun_ord ord f g \<longleftrightarrow> (\<forall>x. ord (f x) (g x))" |
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definition "fun_lub L A = (\<lambda>x. L {y. \<exists>f\<in>A. y = f x})" |
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definition "img_ord f ord = (\<lambda>x y. ord (f x) (f y))" |
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definition "img_lub f g Lub = (\<lambda>A. g (Lub (f ` A)))" |
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lemma chain_fun: |
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assumes A: "chain (fun_ord ord) A" |
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shows "chain ord {y. \<exists>f\<in>A. y = f a}" (is "chain ord ?C") |
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proof (rule chainI) |
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fix x y assume "x \<in> ?C" "y \<in> ?C" |
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then obtain f g where fg: "f \<in> A" "g \<in> A" |
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and [simp]: "x = f a" "y = g a" by blast |
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from chainD[OF A fg] |
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show "ord x y \<or> ord y x" unfolding fun_ord_def by auto |
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qed |
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lemma call_mono[partial_function_mono]: "monotone (fun_ord ord) ord (\<lambda>f. f t)" |
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by (rule monotoneI) (auto simp: fun_ord_def) |
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lemma let_mono[partial_function_mono]: |
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"(\<And>x. monotone orda ordb (\<lambda>f. b f x)) |
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\<Longrightarrow> monotone orda ordb (\<lambda>f. Let t (b f))" |
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by (simp add: Let_def) |
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lemma if_mono[partial_function_mono]: "monotone orda ordb F |
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\<Longrightarrow> monotone orda ordb G |
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\<Longrightarrow> monotone orda ordb (\<lambda>f. if c then F f else G f)" |
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unfolding monotone_def by simp |
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definition "mk_less R = (\<lambda>x y. R x y \<and> \<not> R y x)" |
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locale partial_function_definitions = |
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fixes leq :: "'a \<Rightarrow> 'a \<Rightarrow> bool" |
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fixes lub :: "'a set \<Rightarrow> 'a" |
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assumes leq_refl: "leq x x" |
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assumes leq_trans: "leq x y \<Longrightarrow> leq y z \<Longrightarrow> leq x z" |
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assumes leq_antisym: "leq x y \<Longrightarrow> leq y x \<Longrightarrow> x = y" |
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assumes lub_upper: "chain leq A \<Longrightarrow> x \<in> A \<Longrightarrow> leq x (lub A)" |
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assumes lub_least: "chain leq A \<Longrightarrow> (\<And>x. x \<in> A \<Longrightarrow> leq x z) \<Longrightarrow> leq (lub A) z" |
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lemma partial_function_lift: |
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assumes "partial_function_definitions ord lb" |
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shows "partial_function_definitions (fun_ord ord) (fun_lub lb)" (is "partial_function_definitions ?ordf ?lubf") |
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proof - |
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interpret partial_function_definitions ord lb by fact |
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show ?thesis |
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proof |
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fix x show "?ordf x x" |
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unfolding fun_ord_def by (auto simp: leq_refl) |
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next |
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fix x y z assume "?ordf x y" "?ordf y z" |
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thus "?ordf x z" unfolding fun_ord_def |
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by (force dest: leq_trans) |
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next |
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fix x y assume "?ordf x y" "?ordf y x" |
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thus "x = y" unfolding fun_ord_def |
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by (force intro!: dest: leq_antisym) |
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next |
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fix A f assume f: "f \<in> A" and A: "chain ?ordf A" |
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thus "?ordf f (?lubf A)" |
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unfolding fun_lub_def fun_ord_def |
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by (blast intro: lub_upper chain_fun[OF A] f) |
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next |
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fix A :: "('b \<Rightarrow> 'a) set" and g :: "'b \<Rightarrow> 'a" |
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assume A: "chain ?ordf A" and g: "\<And>f. f \<in> A \<Longrightarrow> ?ordf f g" |
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show "?ordf (?lubf A) g" unfolding fun_lub_def fun_ord_def |
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by (blast intro: lub_least chain_fun[OF A] dest: g[unfolded fun_ord_def]) |
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qed |
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qed |
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lemma ccpo: assumes "partial_function_definitions ord lb" |
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shows "class.ccpo lb ord (mk_less ord)" |
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using assms unfolding partial_function_definitions_def mk_less_def |
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by unfold_locales blast+ |
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lemma partial_function_image: |
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assumes "partial_function_definitions ord Lub" |
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assumes inj: "\<And>x y. f x = f y \<Longrightarrow> x = y" |
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assumes inv: "\<And>x. f (g x) = x" |
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shows "partial_function_definitions (img_ord f ord) (img_lub f g Lub)" |
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proof - |
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let ?iord = "img_ord f ord" |
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let ?ilub = "img_lub f g Lub" |
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interpret partial_function_definitions ord Lub by fact |
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show ?thesis |
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proof |
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fix A x assume "chain ?iord A" "x \<in> A" |
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then have "chain ord (f ` A)" "f x \<in> f ` A" |
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by (auto simp: img_ord_def intro: chainI dest: chainD) |
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thus "?iord x (?ilub A)" |
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unfolding inv img_lub_def img_ord_def by (rule lub_upper) |
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next |
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fix A x assume "chain ?iord A" |
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and 1: "\<And>z. z \<in> A \<Longrightarrow> ?iord z x" |
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then have "chain ord (f ` A)" |
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by (auto simp: img_ord_def intro: chainI dest: chainD) |
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thus "?iord (?ilub A) x" |
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unfolding inv img_lub_def img_ord_def |
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by (rule lub_least) (auto dest: 1[unfolded img_ord_def]) |
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qed (auto simp: img_ord_def intro: leq_refl dest: leq_trans leq_antisym inj) |
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qed |
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context partial_function_definitions |
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begin |
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abbreviation "le_fun \<equiv> fun_ord leq" |
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abbreviation "lub_fun \<equiv> fun_lub lub" |
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abbreviation "fixp_fun \<equiv> ccpo.fixp lub_fun le_fun" |
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abbreviation "mono_body \<equiv> monotone le_fun leq" |
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abbreviation "admissible \<equiv> ccpo.admissible lub_fun le_fun" |
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text \<open>Interpret manually, to avoid flooding everything with facts about |
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orders\<close> |
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lemma ccpo: "class.ccpo lub_fun le_fun (mk_less le_fun)" |
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apply (rule ccpo) |
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apply (rule partial_function_lift) |
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apply (rule partial_function_definitions_axioms) |
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done |
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text \<open>The crucial fixed-point theorem\<close> |
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lemma mono_body_fixp: |
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"(\<And>x. mono_body (\<lambda>f. F f x)) \<Longrightarrow> fixp_fun F = F (fixp_fun F)" |
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by (rule ccpo.fixp_unfold[OF ccpo]) (auto simp: monotone_def fun_ord_def) |
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text \<open>Version with curry/uncurry combinators, to be used by package\<close> |
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lemma fixp_rule_uc: |
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fixes F :: "'c \<Rightarrow> 'c" and |
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U :: "'c \<Rightarrow> 'b \<Rightarrow> 'a" and |
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C :: "('b \<Rightarrow> 'a) \<Rightarrow> 'c" |
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assumes mono: "\<And>x. mono_body (\<lambda>f. U (F (C f)) x)" |
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assumes eq: "f \<equiv> C (fixp_fun (\<lambda>f. U (F (C f))))" |
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assumes inverse: "\<And>f. C (U f) = f" |
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shows "f = F f" |
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proof - |
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have "f = C (fixp_fun (\<lambda>f. U (F (C f))))" by (simp add: eq) |
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also have "... = C (U (F (C (fixp_fun (\<lambda>f. U (F (C f)))))))" |
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by (subst mono_body_fixp[of "%f. U (F (C f))", OF mono]) (rule refl) |
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also have "... = F (C (fixp_fun (\<lambda>f. U (F (C f)))))" by (rule inverse) |
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also have "... = F f" by (simp add: eq) |
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finally show "f = F f" . |
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qed |
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text \<open>Fixpoint induction rule\<close> |
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lemma fixp_induct_uc: |
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fixes F :: "'c \<Rightarrow> 'c" |
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and U :: "'c \<Rightarrow> 'b \<Rightarrow> 'a" |
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and C :: "('b \<Rightarrow> 'a) \<Rightarrow> 'c" |
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and P :: "('b \<Rightarrow> 'a) \<Rightarrow> bool" |
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assumes mono: "\<And>x. mono_body (\<lambda>f. U (F (C f)) x)" |
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and eq: "f \<equiv> C (fixp_fun (\<lambda>f. U (F (C f))))" |
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and inverse: "\<And>f. U (C f) = f" |
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and adm: "ccpo.admissible lub_fun le_fun P" |
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and bot: "P (\<lambda>_. lub {})" |
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and step: "\<And>f. P (U f) \<Longrightarrow> P (U (F f))" |
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shows "P (U f)" |
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unfolding eq inverse |
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apply (rule ccpo.fixp_induct[OF ccpo adm]) |
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apply (insert mono, auto simp: monotone_def fun_ord_def bot fun_lub_def)[2] |
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apply (rule_tac f5="C x" in step) |
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apply (simp add: inverse) |
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done |
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text \<open>Rules for @{term mono_body}:\<close> |
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lemma const_mono[partial_function_mono]: "monotone ord leq (\<lambda>f. c)" |
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by (rule monotoneI) (rule leq_refl) |
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end |
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subsection \<open>Flat interpretation: tailrec and option\<close> |
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definition |
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"flat_ord b x y \<longleftrightarrow> x = b \<or> x = y" |
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definition |
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"flat_lub b A = (if A \<subseteq> {b} then b else (THE x. x \<in> A - {b}))" |
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lemma flat_interpretation: |
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"partial_function_definitions (flat_ord b) (flat_lub b)" |
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proof |
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fix A x assume 1: "chain (flat_ord b) A" "x \<in> A" |
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show "flat_ord b x (flat_lub b A)" |
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proof cases |
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assume "x = b" |
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thus ?thesis by (simp add: flat_ord_def) |
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next |
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assume "x \<noteq> b" |
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with 1 have "A - {b} = {x}" |
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by (auto elim: chainE simp: flat_ord_def) |
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then have "flat_lub b A = x" |
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by (auto simp: flat_lub_def) |
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thus ?thesis by (auto simp: flat_ord_def) |
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qed |
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next |
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fix A z assume A: "chain (flat_ord b) A" |
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and z: "\<And>x. x \<in> A \<Longrightarrow> flat_ord b x z" |
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show "flat_ord b (flat_lub b A) z" |
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proof cases |
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assume "A \<subseteq> {b}" |
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thus ?thesis |
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by (auto simp: flat_lub_def flat_ord_def) |
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next |
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assume nb: "\<not> A \<subseteq> {b}" |
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then obtain y where y: "y \<in> A" "y \<noteq> b" by auto |
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with A have "A - {b} = {y}" |
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by (auto elim: chainE simp: flat_ord_def) |
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with nb have "flat_lub b A = y" |
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by (auto simp: flat_lub_def) |
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with z y show ?thesis by auto |
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qed |
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qed (auto simp: flat_ord_def) |
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lemma flat_ordI: "(x \<noteq> a \<Longrightarrow> x = y) \<Longrightarrow> flat_ord a x y" |
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by(auto simp add: flat_ord_def) |
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lemma flat_ord_antisym: "\<lbrakk> flat_ord a x y; flat_ord a y x \<rbrakk> \<Longrightarrow> x = y" |
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by(auto simp add: flat_ord_def) |
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lemma antisymP_flat_ord: "antisymP (flat_ord a)" |
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by(rule antisymI)(auto dest: flat_ord_antisym) |
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interpretation tailrec: |
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partial_function_definitions "flat_ord undefined" "flat_lub undefined" |
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rewrites "flat_lub undefined {} \<equiv> undefined" |
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by (rule flat_interpretation)(simp add: flat_lub_def) |
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interpretation option: |
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partial_function_definitions "flat_ord None" "flat_lub None" |
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rewrites "flat_lub None {} \<equiv> None" |
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by (rule flat_interpretation)(simp add: flat_lub_def) |
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changeset
|
294 |
|
51459
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|
295 |
abbreviation "tailrec_ord \<equiv> flat_ord undefined" |
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|
296 |
abbreviation "mono_tailrec \<equiv> monotone (fun_ord tailrec_ord) tailrec_ord" |
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|
297 |
|
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|
298 |
lemma tailrec_admissible: |
53949 | 299 |
"ccpo.admissible (fun_lub (flat_lub c)) (fun_ord (flat_ord c)) |
300 |
(\<lambda>a. \<forall>x. a x \<noteq> c \<longrightarrow> P x (a x))" |
|
53361
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|
301 |
proof(intro ccpo.admissibleI strip) |
51459
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changeset
|
302 |
fix A x |
53949 | 303 |
assume chain: "Complete_Partial_Order.chain (fun_ord (flat_ord c)) A" |
304 |
and P [rule_format]: "\<forall>f\<in>A. \<forall>x. f x \<noteq> c \<longrightarrow> P x (f x)" |
|
305 |
and defined: "fun_lub (flat_lub c) A x \<noteq> c" |
|
306 |
from defined obtain f where f: "f \<in> A" "f x \<noteq> c" |
|
51459
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diff
changeset
|
307 |
by(auto simp add: fun_lub_def flat_lub_def split: split_if_asm) |
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changeset
|
308 |
hence "P x (f x)" by(rule P) |
53949 | 309 |
moreover from chain f have "\<forall>f' \<in> A. f' x = c \<or> f' x = f x" |
51459
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changeset
|
310 |
by(auto 4 4 simp add: Complete_Partial_Order.chain_def flat_ord_def fun_ord_def) |
53949 | 311 |
hence "fun_lub (flat_lub c) A x = f x" |
51459
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|
312 |
using f by(auto simp add: fun_lub_def flat_lub_def) |
53949 | 313 |
ultimately show "P x (fun_lub (flat_lub c) A x)" by simp |
51459
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|
314 |
qed |
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changeset
|
315 |
|
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changeset
|
316 |
lemma fixp_induct_tailrec: |
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|
317 |
fixes F :: "'c \<Rightarrow> 'c" and |
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diff
changeset
|
318 |
U :: "'c \<Rightarrow> 'b \<Rightarrow> 'a" and |
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diff
changeset
|
319 |
C :: "('b \<Rightarrow> 'a) \<Rightarrow> 'c" and |
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parents:
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changeset
|
320 |
P :: "'b \<Rightarrow> 'a \<Rightarrow> bool" and |
bc3651180a09
add induction rule for partial_function (tailrec)
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parents:
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diff
changeset
|
321 |
x :: "'b" |
53949 | 322 |
assumes mono: "\<And>x. monotone (fun_ord (flat_ord c)) (flat_ord c) (\<lambda>f. U (F (C f)) x)" |
323 |
assumes eq: "f \<equiv> C (ccpo.fixp (fun_lub (flat_lub c)) (fun_ord (flat_ord c)) (\<lambda>f. U (F (C f))))" |
|
51459
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changeset
|
324 |
assumes inverse2: "\<And>f. U (C f) = f" |
53949 | 325 |
assumes step: "\<And>f x y. (\<And>x y. U f x = y \<Longrightarrow> y \<noteq> c \<Longrightarrow> P x y) \<Longrightarrow> U (F f) x = y \<Longrightarrow> y \<noteq> c \<Longrightarrow> P x y" |
51459
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parents:
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diff
changeset
|
326 |
assumes result: "U f x = y" |
53949 | 327 |
assumes defined: "y \<noteq> c" |
51459
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diff
changeset
|
328 |
shows "P x y" |
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parents:
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diff
changeset
|
329 |
proof - |
53949 | 330 |
have "\<forall>x y. U f x = y \<longrightarrow> y \<noteq> c \<longrightarrow> P x y" |
331 |
by(rule partial_function_definitions.fixp_induct_uc[OF flat_interpretation, of _ U F C, OF mono eq inverse2]) |
|
54630
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diff
changeset
|
332 |
(auto intro: step tailrec_admissible simp add: fun_lub_def flat_lub_def) |
51459
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diff
changeset
|
333 |
thus ?thesis using result defined by blast |
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|
334 |
qed |
bc3651180a09
add induction rule for partial_function (tailrec)
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parents:
48891
diff
changeset
|
335 |
|
51485
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diff
changeset
|
336 |
lemma admissible_image: |
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diff
changeset
|
337 |
assumes pfun: "partial_function_definitions le lub" |
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parents:
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diff
changeset
|
338 |
assumes adm: "ccpo.admissible lub le (P o g)" |
637aa1649ac7
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diff
changeset
|
339 |
assumes inj: "\<And>x y. f x = f y \<Longrightarrow> x = y" |
637aa1649ac7
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parents:
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diff
changeset
|
340 |
assumes inv: "\<And>x. f (g x) = x" |
637aa1649ac7
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diff
changeset
|
341 |
shows "ccpo.admissible (img_lub f g lub) (img_ord f le) P" |
53361
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parents:
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diff
changeset
|
342 |
proof (rule ccpo.admissibleI) |
51485
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diff
changeset
|
343 |
fix A assume "chain (img_ord f le) A" |
54630
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changeset
|
344 |
then have ch': "chain le (f ` A)" |
9061af4d5ebc
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parents:
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changeset
|
345 |
by (auto simp: img_ord_def intro: chainI dest: chainD) |
9061af4d5ebc
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changeset
|
346 |
assume "A \<noteq> {}" |
51485
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changeset
|
347 |
assume P_A: "\<forall>x\<in>A. P x" |
53361
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Andreas Lochbihler
parents:
52728
diff
changeset
|
348 |
have "(P o g) (lub (f ` A))" using adm ch' |
1cb7d3c0cf31
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parents:
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|
349 |
proof (rule ccpo.admissibleD) |
51485
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changeset
|
350 |
fix x assume "x \<in> f ` A" |
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changeset
|
351 |
with P_A show "(P o g) x" by (auto simp: inj[OF inv]) |
60758 | 352 |
qed(simp add: \<open>A \<noteq> {}\<close>) |
51485
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parents:
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diff
changeset
|
353 |
thus "P (img_lub f g lub A)" unfolding img_lub_def by simp |
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changeset
|
354 |
qed |
637aa1649ac7
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parents:
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diff
changeset
|
355 |
|
637aa1649ac7
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changeset
|
356 |
lemma admissible_fun: |
637aa1649ac7
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diff
changeset
|
357 |
assumes pfun: "partial_function_definitions le lub" |
637aa1649ac7
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parents:
51459
diff
changeset
|
358 |
assumes adm: "\<And>x. ccpo.admissible lub le (Q x)" |
637aa1649ac7
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krauss
parents:
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diff
changeset
|
359 |
shows "ccpo.admissible (fun_lub lub) (fun_ord le) (\<lambda>f. \<forall>x. Q x (f x))" |
53361
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parents:
52728
diff
changeset
|
360 |
proof (rule ccpo.admissibleI) |
51485
637aa1649ac7
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krauss
parents:
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diff
changeset
|
361 |
fix A :: "('b \<Rightarrow> 'a) set" |
637aa1649ac7
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krauss
parents:
51459
diff
changeset
|
362 |
assume Q: "\<forall>f\<in>A. \<forall>x. Q x (f x)" |
637aa1649ac7
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parents:
51459
diff
changeset
|
363 |
assume ch: "chain (fun_ord le) A" |
54630
9061af4d5ebc
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Andreas Lochbihler
parents:
53949
diff
changeset
|
364 |
assume "A \<noteq> {}" |
9061af4d5ebc
restrict admissibility to non-empty chains to allow more syntax-directed proof rules
Andreas Lochbihler
parents:
53949
diff
changeset
|
365 |
hence non_empty: "\<And>a. {y. \<exists>f\<in>A. y = f a} \<noteq> {}" by auto |
51485
637aa1649ac7
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krauss
parents:
51459
diff
changeset
|
366 |
show "\<forall>x. Q x (fun_lub lub A x)" |
637aa1649ac7
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krauss
parents:
51459
diff
changeset
|
367 |
unfolding fun_lub_def |
54630
9061af4d5ebc
restrict admissibility to non-empty chains to allow more syntax-directed proof rules
Andreas Lochbihler
parents:
53949
diff
changeset
|
368 |
by (rule allI, rule ccpo.admissibleD[OF adm chain_fun[OF ch] non_empty]) |
51485
637aa1649ac7
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krauss
parents:
51459
diff
changeset
|
369 |
(auto simp: Q) |
637aa1649ac7
added rudimentary induction rule for partial_function (heap)
krauss
parents:
51459
diff
changeset
|
370 |
qed |
637aa1649ac7
added rudimentary induction rule for partial_function (heap)
krauss
parents:
51459
diff
changeset
|
371 |
|
51459
bc3651180a09
add induction rule for partial_function (tailrec)
Andreas Lochbihler
parents:
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diff
changeset
|
372 |
|
40107 | 373 |
abbreviation "option_ord \<equiv> flat_ord None" |
374 |
abbreviation "mono_option \<equiv> monotone (fun_ord option_ord) option_ord" |
|
375 |
||
376 |
lemma bind_mono[partial_function_mono]: |
|
377 |
assumes mf: "mono_option B" and mg: "\<And>y. mono_option (\<lambda>f. C y f)" |
|
378 |
shows "mono_option (\<lambda>f. Option.bind (B f) (\<lambda>y. C y f))" |
|
379 |
proof (rule monotoneI) |
|
380 |
fix f g :: "'a \<Rightarrow> 'b option" assume fg: "fun_ord option_ord f g" |
|
381 |
with mf |
|
382 |
have "option_ord (B f) (B g)" by (rule monotoneD[of _ _ _ f g]) |
|
383 |
then have "option_ord (Option.bind (B f) (\<lambda>y. C y f)) (Option.bind (B g) (\<lambda>y. C y f))" |
|
384 |
unfolding flat_ord_def by auto |
|
385 |
also from mg |
|
386 |
have "\<And>y'. option_ord (C y' f) (C y' g)" |
|
387 |
by (rule monotoneD) (rule fg) |
|
388 |
then have "option_ord (Option.bind (B g) (\<lambda>y'. C y' f)) (Option.bind (B g) (\<lambda>y'. C y' g))" |
|
389 |
unfolding flat_ord_def by (cases "B g") auto |
|
390 |
finally (option.leq_trans) |
|
391 |
show "option_ord (Option.bind (B f) (\<lambda>y. C y f)) (Option.bind (B g) (\<lambda>y'. C y' g))" . |
|
392 |
qed |
|
393 |
||
43081 | 394 |
lemma flat_lub_in_chain: |
395 |
assumes ch: "chain (flat_ord b) A " |
|
396 |
assumes lub: "flat_lub b A = a" |
|
397 |
shows "a = b \<or> a \<in> A" |
|
398 |
proof (cases "A \<subseteq> {b}") |
|
399 |
case True |
|
400 |
then have "flat_lub b A = b" unfolding flat_lub_def by simp |
|
401 |
with lub show ?thesis by simp |
|
402 |
next |
|
403 |
case False |
|
404 |
then obtain c where "c \<in> A" and "c \<noteq> b" by auto |
|
405 |
{ fix z assume "z \<in> A" |
|
60758 | 406 |
from chainD[OF ch \<open>c \<in> A\<close> this] have "z = c \<or> z = b" |
407 |
unfolding flat_ord_def using \<open>c \<noteq> b\<close> by auto } |
|
43081 | 408 |
with False have "A - {b} = {c}" by auto |
409 |
with False have "flat_lub b A = c" by (auto simp: flat_lub_def) |
|
60758 | 410 |
with \<open>c \<in> A\<close> lub show ?thesis by simp |
43081 | 411 |
qed |
412 |
||
413 |
lemma option_admissible: "option.admissible (%(f::'a \<Rightarrow> 'b option). |
|
414 |
(\<forall>x y. f x = Some y \<longrightarrow> P x y))" |
|
53361
1cb7d3c0cf31
move admissible out of class ccpo to avoid unnecessary class predicate in foundational theorems
Andreas Lochbihler
parents:
52728
diff
changeset
|
415 |
proof (rule ccpo.admissibleI) |
43081 | 416 |
fix A :: "('a \<Rightarrow> 'b option) set" |
417 |
assume ch: "chain option.le_fun A" |
|
418 |
and IH: "\<forall>f\<in>A. \<forall>x y. f x = Some y \<longrightarrow> P x y" |
|
419 |
from ch have ch': "\<And>x. chain option_ord {y. \<exists>f\<in>A. y = f x}" by (rule chain_fun) |
|
420 |
show "\<forall>x y. option.lub_fun A x = Some y \<longrightarrow> P x y" |
|
421 |
proof (intro allI impI) |
|
422 |
fix x y assume "option.lub_fun A x = Some y" |
|
423 |
from flat_lub_in_chain[OF ch' this[unfolded fun_lub_def]] |
|
424 |
have "Some y \<in> {y. \<exists>f\<in>A. y = f x}" by simp |
|
425 |
then have "\<exists>f\<in>A. f x = Some y" by auto |
|
426 |
with IH show "P x y" by auto |
|
427 |
qed |
|
428 |
qed |
|
429 |
||
43082
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
430 |
lemma fixp_induct_option: |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
431 |
fixes F :: "'c \<Rightarrow> 'c" and |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
432 |
U :: "'c \<Rightarrow> 'b \<Rightarrow> 'a option" and |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
433 |
C :: "('b \<Rightarrow> 'a option) \<Rightarrow> 'c" and |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
434 |
P :: "'b \<Rightarrow> 'a \<Rightarrow> bool" |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
435 |
assumes mono: "\<And>x. mono_option (\<lambda>f. U (F (C f)) x)" |
46041
1e3ff542e83e
remove constant 'ccpo.lub', re-use constant 'Sup' instead
huffman
parents:
45297
diff
changeset
|
436 |
assumes eq: "f \<equiv> C (ccpo.fixp (fun_lub (flat_lub None)) (fun_ord option_ord) (\<lambda>f. U (F (C f))))" |
43082
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
437 |
assumes inverse2: "\<And>f. U (C f) = f" |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
438 |
assumes step: "\<And>f x y. (\<And>x y. U f x = Some y \<Longrightarrow> P x y) \<Longrightarrow> U (F f) x = Some y \<Longrightarrow> P x y" |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
439 |
assumes defined: "U f x = Some y" |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
440 |
shows "P x y" |
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
441 |
using step defined option.fixp_induct_uc[of U F C, OF mono eq inverse2 option_admissible] |
54630
9061af4d5ebc
restrict admissibility to non-empty chains to allow more syntax-directed proof rules
Andreas Lochbihler
parents:
53949
diff
changeset
|
442 |
unfolding fun_lub_def flat_lub_def by(auto 9 2) |
43082
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
443 |
|
60758 | 444 |
declaration \<open>Partial_Function.init "tailrec" @{term tailrec.fixp_fun} |
52728
470b579f35d2
derive specialized version of full fixpoint induction (with admissibility)
krauss
parents:
51485
diff
changeset
|
445 |
@{term tailrec.mono_body} @{thm tailrec.fixp_rule_uc} @{thm tailrec.fixp_induct_uc} |
61841
4d3527b94f2a
more general types Proof.method / context_tactic;
wenzelm
parents:
61605
diff
changeset
|
446 |
(SOME @{thm fixp_induct_tailrec[where c = undefined]})\<close> |
43082
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
447 |
|
60758 | 448 |
declaration \<open>Partial_Function.init "option" @{term option.fixp_fun} |
52728
470b579f35d2
derive specialized version of full fixpoint induction (with admissibility)
krauss
parents:
51485
diff
changeset
|
449 |
@{term option.mono_body} @{thm option.fixp_rule_uc} @{thm option.fixp_induct_uc} |
60758 | 450 |
(SOME @{thm fixp_induct_option})\<close> |
43082
8d0c44de9773
generic fixpoint induction (with explicit curry/uncurry predicates) and instance for option type
krauss
parents:
43081
diff
changeset
|
451 |
|
40252
029400b6c893
hide_const various constants, in particular to avoid ugly qualifiers in HOLCF
krauss
parents:
40107
diff
changeset
|
452 |
hide_const (open) chain |
40107 | 453 |
|
454 |
end |