| author | wenzelm |
| Wed, 04 Dec 2013 18:59:20 +0100 | |
| changeset 54667 | 4dd08fe126ba |
| parent 53822 | 6304b12c7627 |
| child 54246 | 8fdb4dc08ed1 |
| permissions | -rw-r--r-- |
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(* Title: HOL/BNF/BNF_GFP.thy |
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Author: Dmitriy Traytel, TU Muenchen |
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3 |
Copyright 2012 |
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4 |
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added new (co)datatype package + theories of ordinals and cardinals (with Dmitriy and Andrei)
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5 |
Greatest fixed point operation on bounded natural functors. |
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6 |
*) |
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7 |
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header {* Greatest Fixed Point Operation on Bounded Natural Functors *}
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added new (co)datatype package + theories of ordinals and cardinals (with Dmitriy and Andrei)
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9 |
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added new (co)datatype package + theories of ordinals and cardinals (with Dmitriy and Andrei)
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theory BNF_GFP |
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imports BNF_FP_Base Equiv_Relations_More "~~/src/HOL/Library/Sublist" |
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12 |
keywords |
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"codatatype" :: thy_decl and |
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"primcorecursive" :: thy_goal and |
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"primcorec" :: thy_decl |
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begin |
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lemma sum_case_expand_Inr: "f o Inl = g \<Longrightarrow> f x = sum_case g (f o Inr) x" |
19 |
by (auto split: sum.splits) |
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(co)rec is (just as the (un)fold) the unique morphism;
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lemma sum_case_expand_Inr': "f o Inl = g \<Longrightarrow> h = f o Inr \<longleftrightarrow> sum_case g h = f" |
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some new lemmas towards getting rid of in_bd BNF property; tuned
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by (metis sum_case_o_inj(1,2) surjective_sum) |
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(co)rec is (just as the (un)fold) the unique morphism;
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| 49312 | 24 |
lemma converse_Times: "(A \<times> B) ^-1 = B \<times> A" |
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by auto |
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27 |
lemma equiv_proj: |
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assumes e: "equiv A R" and "z \<in> R" |
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shows "(proj R o fst) z = (proj R o snd) z" |
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30 |
proof - |
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from assms(2) have z: "(fst z, snd z) \<in> R" by auto |
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with e have "\<And>x. (fst z, x) \<in> R \<Longrightarrow> (snd z, x) \<in> R" "\<And>x. (snd z, x) \<in> R \<Longrightarrow> (fst z, x) \<in> R" |
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unfolding equiv_def sym_def trans_def by blast+ |
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then show ?thesis unfolding proj_def[abs_def] by auto |
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qed |
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(* Operators: *) |
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38 |
definition image2 where "image2 A f g = {(f a, g a) | a. a \<in> A}"
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lemma Id_onD: "(a, b) \<in> Id_on A \<Longrightarrow> a = b" |
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unfolding Id_on_def by simp |
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lemma Id_onD': "x \<in> Id_on A \<Longrightarrow> fst x = snd x" |
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unfolding Id_on_def by auto |
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lemma Id_on_fst: "x \<in> Id_on A \<Longrightarrow> fst x \<in> A" |
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unfolding Id_on_def by auto |
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lemma Id_on_UNIV: "Id_on UNIV = Id" |
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unfolding Id_on_def by auto |
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lemma Id_on_Comp: "Id_on A = Id_on A O Id_on A" |
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unfolding Id_on_def by auto |
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lemma Id_on_Gr: "Id_on A = Gr A id" |
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unfolding Id_on_def Gr_def by auto |
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lemma Id_on_UNIV_I: "x = y \<Longrightarrow> (x, y) \<in> Id_on UNIV" |
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unfolding Id_on_def by auto |
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| 49312 | 61 |
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lemma image2_eqI: "\<lbrakk>b = f x; c = g x; x \<in> A\<rbrakk> \<Longrightarrow> (b, c) \<in> image2 A f g" |
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unfolding image2_def by auto |
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lemma IdD: "(a, b) \<in> Id \<Longrightarrow> a = b" |
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by auto |
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lemma image2_Gr: "image2 A f g = (Gr A f)^-1 O (Gr A g)" |
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unfolding image2_def Gr_def by auto |
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lemma GrD1: "(x, fx) \<in> Gr A f \<Longrightarrow> x \<in> A" |
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unfolding Gr_def by simp |
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lemma GrD2: "(x, fx) \<in> Gr A f \<Longrightarrow> f x = fx" |
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unfolding Gr_def by simp |
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lemma Gr_incl: "Gr A f \<subseteq> A <*> B \<longleftrightarrow> f ` A \<subseteq> B" |
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unfolding Gr_def by auto |
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lemma in_rel_Collect_split_eq: "in_rel (Collect (split X)) = X" |
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81 |
unfolding fun_eq_iff by auto |
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lemma Collect_split_in_rel_leI: "X \<subseteq> Y \<Longrightarrow> X \<subseteq> Collect (split (in_rel Y))" |
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by auto |
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596baae88a88
got rid of the set based relator---use (binary) predicate based relator instead
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lemma Collect_split_in_rel_leE: "X \<subseteq> Collect (split (in_rel Y)) \<Longrightarrow> (X \<subseteq> Y \<Longrightarrow> R) \<Longrightarrow> R" |
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by force |
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88 |
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596baae88a88
got rid of the set based relator---use (binary) predicate based relator instead
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lemma Collect_split_in_relI: "x \<in> X \<Longrightarrow> x \<in> Collect (split (in_rel X))" |
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by auto |
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596baae88a88
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596baae88a88
got rid of the set based relator---use (binary) predicate based relator instead
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lemma conversep_in_rel: "(in_rel R)\<inverse>\<inverse> = in_rel (R\<inverse>)" |
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unfolding fun_eq_iff by auto |
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596baae88a88
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lemma relcompp_in_rel: "in_rel R OO in_rel S = in_rel (R O S)" |
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596baae88a88
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unfolding fun_eq_iff by auto |
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596baae88a88
got rid of the set based relator---use (binary) predicate based relator instead
traytel
parents:
51850
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596baae88a88
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lemma in_rel_Gr: "in_rel (Gr A f) = Grp A f" |
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596baae88a88
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unfolding Gr_def Grp_def fun_eq_iff by auto |
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596baae88a88
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lemma in_rel_Id_on_UNIV: "in_rel (Id_on UNIV) = op =" |
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596baae88a88
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102 |
unfolding fun_eq_iff by auto |
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596baae88a88
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103 |
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definition relImage where |
105 |
"relImage R f \<equiv> {(f a1, f a2) | a1 a2. (a1,a2) \<in> R}"
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definition relInvImage where |
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"relInvImage A R f \<equiv> {(a1, a2) | a1 a2. a1 \<in> A \<and> a2 \<in> A \<and> (f a1, f a2) \<in> R}"
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lemma relImage_Gr: |
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"\<lbrakk>R \<subseteq> A \<times> A\<rbrakk> \<Longrightarrow> relImage R f = (Gr A f)^-1 O R O Gr A f" |
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unfolding relImage_def Gr_def relcomp_def by auto |
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lemma relInvImage_Gr: "\<lbrakk>R \<subseteq> B \<times> B\<rbrakk> \<Longrightarrow> relInvImage A R f = Gr A f O R O (Gr A f)^-1" |
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unfolding Gr_def relcomp_def image_def relInvImage_def by auto |
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lemma relImage_mono: |
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"R1 \<subseteq> R2 \<Longrightarrow> relImage R1 f \<subseteq> relImage R2 f" |
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unfolding relImage_def by auto |
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lemma relInvImage_mono: |
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"R1 \<subseteq> R2 \<Longrightarrow> relInvImage A R1 f \<subseteq> relInvImage A R2 f" |
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unfolding relInvImage_def by auto |
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lemma relInvImage_Id_on: |
126 |
"(\<And>a1 a2. f a1 = f a2 \<longleftrightarrow> a1 = a2) \<Longrightarrow> relInvImage A (Id_on B) f \<subseteq> Id" |
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unfolding relInvImage_def Id_on_def by auto |
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lemma relInvImage_UNIV_relImage: |
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"R \<subseteq> relInvImage UNIV (relImage R f) f" |
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unfolding relInvImage_def relImage_def by auto |
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lemma equiv_Image: "equiv A R \<Longrightarrow> (\<And>a b. (a, b) \<in> R \<Longrightarrow> a \<in> A \<and> b \<in> A \<and> R `` {a} = R `` {b})"
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unfolding equiv_def refl_on_def Image_def by (auto intro: transD symD) |
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lemma relImage_proj: |
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assumes "equiv A R" |
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shows "relImage R (proj R) \<subseteq> Id_on (A//R)" |
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unfolding relImage_def Id_on_def |
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using proj_iff[OF assms] equiv_class_eq_iff[OF assms] |
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by (auto simp: proj_preserves) |
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lemma relImage_relInvImage: |
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assumes "R \<subseteq> f ` A <*> f ` A" |
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shows "relImage (relInvImage A R f) f = R" |
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using assms unfolding relImage_def relInvImage_def by fastforce |
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lemma subst_Pair: "P x y \<Longrightarrow> a = (x, y) \<Longrightarrow> P (fst a) (snd a)" |
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by simp |
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lemma fst_diag_id: "(fst \<circ> (%x. (x, x))) z = id z" |
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by simp |
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lemma snd_diag_id: "(snd \<circ> (%x. (x, x))) z = id z" |
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by simp |
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lemma image_convolD: "\<lbrakk>(a, b) \<in> <f, g> ` X\<rbrakk> \<Longrightarrow> \<exists>x. x \<in> X \<and> a = f x \<and> b = g x" |
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unfolding convol_def by auto |
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(*Extended Sublist*) |
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definition prefCl where |
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import Sublist rather than PrefixOrder to avoid unnecessary class instantiation
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"prefCl Kl = (\<forall> kl1 kl2. prefixeq kl1 kl2 \<and> kl2 \<in> Kl \<longrightarrow> kl1 \<in> Kl)" |
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definition PrefCl where |
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import Sublist rather than PrefixOrder to avoid unnecessary class instantiation
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"PrefCl A n = (\<forall>kl kl'. kl \<in> A n \<and> prefixeq kl' kl \<longrightarrow> (\<exists>m\<le>n. kl' \<in> A m))" |
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lemma prefCl_UN: |
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"\<lbrakk>\<And>n. PrefCl A n\<rbrakk> \<Longrightarrow> prefCl (\<Union>n. A n)" |
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unfolding prefCl_def PrefCl_def by fastforce |
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definition Succ where "Succ Kl kl = {k . kl @ [k] \<in> Kl}"
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definition Shift where "Shift Kl k = {kl. k # kl \<in> Kl}"
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definition shift where "shift lab k = (\<lambda>kl. lab (k # kl))" |
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lemma empty_Shift: "\<lbrakk>[] \<in> Kl; k \<in> Succ Kl []\<rbrakk> \<Longrightarrow> [] \<in> Shift Kl k" |
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unfolding Shift_def Succ_def by simp |
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lemma Shift_clists: "Kl \<subseteq> Field (clists r) \<Longrightarrow> Shift Kl k \<subseteq> Field (clists r)" |
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unfolding Shift_def clists_def Field_card_of by auto |
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lemma Shift_prefCl: "prefCl Kl \<Longrightarrow> prefCl (Shift Kl k)" |
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unfolding prefCl_def Shift_def |
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proof safe |
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fix kl1 kl2 |
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import Sublist rather than PrefixOrder to avoid unnecessary class instantiation
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assume "\<forall>kl1 kl2. prefixeq kl1 kl2 \<and> kl2 \<in> Kl \<longrightarrow> kl1 \<in> Kl" |
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"prefixeq kl1 kl2" "k # kl2 \<in> Kl" |
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import Sublist rather than PrefixOrder to avoid unnecessary class instantiation
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187 |
thus "k # kl1 \<in> Kl" using Cons_prefixeq_Cons[of k kl1 k kl2] by blast |
| 49312 | 188 |
qed |
189 |
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lemma not_in_Shift: "kl \<notin> Shift Kl x \<Longrightarrow> x # kl \<notin> Kl" |
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191 |
unfolding Shift_def by simp |
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192 |
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lemma SuccD: "k \<in> Succ Kl kl \<Longrightarrow> kl @ [k] \<in> Kl" |
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unfolding Succ_def by simp |
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lemmas SuccE = SuccD[elim_format] |
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lemma SuccI: "kl @ [k] \<in> Kl \<Longrightarrow> k \<in> Succ Kl kl" |
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unfolding Succ_def by simp |
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lemma ShiftD: "kl \<in> Shift Kl k \<Longrightarrow> k # kl \<in> Kl" |
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202 |
unfolding Shift_def by simp |
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204 |
lemma Succ_Shift: "Succ (Shift Kl k) kl = Succ Kl (k # kl)" |
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205 |
unfolding Succ_def Shift_def by auto |
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lemma Nil_clists: "{[]} \<subseteq> Field (clists r)"
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unfolding clists_def Field_card_of by auto |
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209 |
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210 |
lemma Cons_clists: |
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211 |
"\<lbrakk>x \<in> Field r; xs \<in> Field (clists r)\<rbrakk> \<Longrightarrow> x # xs \<in> Field (clists r)" |
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212 |
unfolding clists_def Field_card_of by auto |
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213 |
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lemma length_Cons: "length (x # xs) = Suc (length xs)" |
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215 |
by simp |
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216 |
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217 |
lemma length_append_singleton: "length (xs @ [x]) = Suc (length xs)" |
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218 |
by simp |
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219 |
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220 |
(*injection into the field of a cardinal*) |
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221 |
definition "toCard_pred A r f \<equiv> inj_on f A \<and> f ` A \<subseteq> Field r \<and> Card_order r" |
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222 |
definition "toCard A r \<equiv> SOME f. toCard_pred A r f" |
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223 |
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224 |
lemma ex_toCard_pred: |
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225 |
"\<lbrakk>|A| \<le>o r; Card_order r\<rbrakk> \<Longrightarrow> \<exists> f. toCard_pred A r f" |
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226 |
unfolding toCard_pred_def |
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227 |
using card_of_ordLeq[of A "Field r"] |
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228 |
ordLeq_ordIso_trans[OF _ card_of_unique[of "Field r" r], of "|A|"] |
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229 |
by blast |
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230 |
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231 |
lemma toCard_pred_toCard: |
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232 |
"\<lbrakk>|A| \<le>o r; Card_order r\<rbrakk> \<Longrightarrow> toCard_pred A r (toCard A r)" |
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233 |
unfolding toCard_def using someI_ex[OF ex_toCard_pred] . |
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234 |
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235 |
lemma toCard_inj: "\<lbrakk>|A| \<le>o r; Card_order r; x \<in> A; y \<in> A\<rbrakk> \<Longrightarrow> |
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236 |
toCard A r x = toCard A r y \<longleftrightarrow> x = y" |
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237 |
using toCard_pred_toCard unfolding inj_on_def toCard_pred_def by blast |
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239 |
lemma toCard: "\<lbrakk>|A| \<le>o r; Card_order r; b \<in> A\<rbrakk> \<Longrightarrow> toCard A r b \<in> Field r" |
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240 |
using toCard_pred_toCard unfolding toCard_pred_def by blast |
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241 |
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242 |
definition "fromCard A r k \<equiv> SOME b. b \<in> A \<and> toCard A r b = k" |
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244 |
lemma fromCard_toCard: |
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245 |
"\<lbrakk>|A| \<le>o r; Card_order r; b \<in> A\<rbrakk> \<Longrightarrow> fromCard A r (toCard A r b) = b" |
|
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unfolding fromCard_def by (rule some_equality) (auto simp add: toCard_inj) |
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247 |
||
248 |
(* pick according to the weak pullback *) |
|
249 |
definition pickWP where |
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"pickWP A p1 p2 b1 b2 \<equiv> SOME a. a \<in> A \<and> p1 a = b1 \<and> p2 a = b2" |
| 49312 | 251 |
|
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lemma pickWP_pred: |
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assumes "wpull A B1 B2 f1 f2 p1 p2" and |
|
254 |
"b1 \<in> B1" and "b2 \<in> B2" and "f1 b1 = f2 b2" |
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shows "\<exists> a. a \<in> A \<and> p1 a = b1 \<and> p2 a = b2" |
256 |
using assms unfolding wpull_def by blast |
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| 49312 | 257 |
|
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lemma pickWP: |
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assumes "wpull A B1 B2 f1 f2 p1 p2" and |
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"b1 \<in> B1" and "b2 \<in> B2" and "f1 b1 = f2 b2" |
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shows "pickWP A p1 p2 b1 b2 \<in> A" |
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"p1 (pickWP A p1 p2 b1 b2) = b1" |
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"p2 (pickWP A p1 p2 b1 b2) = b2" |
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| 51446 | 264 |
unfolding pickWP_def using assms someI_ex[OF pickWP_pred] by fastforce+ |
| 49312 | 265 |
|
266 |
lemma Inl_Field_csum: "a \<in> Field r \<Longrightarrow> Inl a \<in> Field (r +c s)" |
|
267 |
unfolding Field_card_of csum_def by auto |
|
268 |
||
269 |
lemma Inr_Field_csum: "a \<in> Field s \<Longrightarrow> Inr a \<in> Field (r +c s)" |
|
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unfolding Field_card_of csum_def by auto |
|
271 |
||
272 |
lemma nat_rec_0: "f = nat_rec f1 (%n rec. f2 n rec) \<Longrightarrow> f 0 = f1" |
|
273 |
by auto |
|
274 |
||
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lemma nat_rec_Suc: "f = nat_rec f1 (%n rec. f2 n rec) \<Longrightarrow> f (Suc n) = f2 n (f n)" |
|
276 |
by auto |
|
277 |
||
278 |
lemma list_rec_Nil: "f = list_rec f1 (%x xs rec. f2 x xs rec) \<Longrightarrow> f [] = f1" |
|
279 |
by auto |
|
280 |
||
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lemma list_rec_Cons: "f = list_rec f1 (%x xs rec. f2 x xs rec) \<Longrightarrow> f (x # xs) = f2 x xs (f xs)" |
|
282 |
by auto |
|
283 |
||
284 |
lemma not_arg_cong_Inr: "x \<noteq> y \<Longrightarrow> Inr x \<noteq> Inr y" |
|
285 |
by simp |
|
286 |
||
| 51925 | 287 |
lemma Collect_splitD: "x \<in> Collect (split A) \<Longrightarrow> A (fst x) (snd x)" |
288 |
by auto |
|
289 |
||
| 52731 | 290 |
definition image2p where |
291 |
"image2p f g R = (\<lambda>x y. \<exists>x' y'. R x' y' \<and> f x' = x \<and> g y' = y)" |
|
292 |
||
293 |
lemma image2pI: "R x y \<Longrightarrow> (image2p f g R) (f x) (g y)" |
|
294 |
unfolding image2p_def by blast |
|
295 |
||
296 |
lemma image2p_eqI: "\<lbrakk>fx = f x; gy = g y; R x y\<rbrakk> \<Longrightarrow> (image2p f g R) fx gy" |
|
297 |
unfolding image2p_def by blast |
|
298 |
||
299 |
lemma image2pE: "\<lbrakk>(image2p f g R) fx gy; (\<And>x y. fx = f x \<Longrightarrow> gy = g y \<Longrightarrow> R x y \<Longrightarrow> P)\<rbrakk> \<Longrightarrow> P" |
|
300 |
unfolding image2p_def by blast |
|
301 |
||
302 |
lemma fun_rel_iff_geq_image2p: "(fun_rel R S) f g = (image2p f g R \<le> S)" |
|
303 |
unfolding fun_rel_def image2p_def by auto |
|
304 |
||
305 |
lemma convol_image_image2p: "<f o fst, g o snd> ` Collect (split R) \<subseteq> Collect (split (image2p f g R))" |
|
306 |
unfolding convol_def image2p_def by fastforce |
|
307 |
||
308 |
lemma fun_rel_image2p: "(fun_rel R (image2p f g R)) f g" |
|
309 |
unfolding fun_rel_def image2p_def by auto |
|
310 |
||
|
49309
f20b24214ac2
split basic BNFs into really basic ones and others, and added Andreas Lochbihler's "option" BNF
blanchet
parents:
49308
diff
changeset
|
311 |
ML_file "Tools/bnf_gfp_util.ML" |
|
f20b24214ac2
split basic BNFs into really basic ones and others, and added Andreas Lochbihler's "option" BNF
blanchet
parents:
49308
diff
changeset
|
312 |
ML_file "Tools/bnf_gfp_tactics.ML" |
|
f20b24214ac2
split basic BNFs into really basic ones and others, and added Andreas Lochbihler's "option" BNF
blanchet
parents:
49308
diff
changeset
|
313 |
ML_file "Tools/bnf_gfp.ML" |
|
f20b24214ac2
split basic BNFs into really basic ones and others, and added Andreas Lochbihler's "option" BNF
blanchet
parents:
49308
diff
changeset
|
314 |
|
|
48975
7f79f94a432c
added new (co)datatype package + theories of ordinals and cardinals (with Dmitriy and Andrei)
blanchet
parents:
diff
changeset
|
315 |
end |