src/HOL/Lifting.thy
author huffman
Tue Apr 03 22:31:00 2012 +0200 (2012-04-03)
changeset 47325 ec6187036495
parent 47308 9caab698dbe4
child 47351 0193e663a19e
child 47435 e1b761c216ac
permissions -rw-r--r--
new transfer proof method
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(*  Title:      HOL/Lifting.thy
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    Author:     Brian Huffman and Ondrej Kuncar
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    Author:     Cezary Kaliszyk and Christian Urban
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*)
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header {* Lifting package *}
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theory Lifting
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imports Plain Equiv_Relations Transfer
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keywords
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  "print_quotmaps" "print_quotients" :: diag and
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  "lift_definition" :: thy_goal and
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  "setup_lifting" :: thy_decl
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uses
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  ("Tools/Lifting/lifting_info.ML")
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  ("Tools/Lifting/lifting_term.ML")
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  ("Tools/Lifting/lifting_def.ML")
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  ("Tools/Lifting/lifting_setup.ML")
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begin
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subsection {* Function map *}
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notation map_fun (infixr "--->" 55)
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lemma map_fun_id:
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  "(id ---> id) = id"
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  by (simp add: fun_eq_iff)
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subsection {* Quotient Predicate *}
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definition
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  "Quotient R Abs Rep T \<longleftrightarrow>
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     (\<forall>a. Abs (Rep a) = a) \<and> 
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     (\<forall>a. R (Rep a) (Rep a)) \<and>
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     (\<forall>r s. R r s \<longleftrightarrow> R r r \<and> R s s \<and> Abs r = Abs s) \<and>
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     T = (\<lambda>x y. R x x \<and> Abs x = y)"
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lemma QuotientI:
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  assumes "\<And>a. Abs (Rep a) = a"
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    and "\<And>a. R (Rep a) (Rep a)"
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    and "\<And>r s. R r s \<longleftrightarrow> R r r \<and> R s s \<and> Abs r = Abs s"
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    and "T = (\<lambda>x y. R x x \<and> Abs x = y)"
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  shows "Quotient R Abs Rep T"
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  using assms unfolding Quotient_def by blast
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lemma Quotient_abs_rep:
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  assumes a: "Quotient R Abs Rep T"
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  shows "Abs (Rep a) = a"
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  using a
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  unfolding Quotient_def
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  by simp
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lemma Quotient_rep_reflp:
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  assumes a: "Quotient R Abs Rep T"
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  shows "R (Rep a) (Rep a)"
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  using a
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  unfolding Quotient_def
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  by blast
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lemma Quotient_rel:
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  assumes a: "Quotient R Abs Rep T"
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  shows "R r r \<and> R s s \<and> Abs r = Abs s \<longleftrightarrow> R r s" -- {* orientation does not loop on rewriting *}
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  using a
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  unfolding Quotient_def
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  by blast
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lemma Quotient_cr_rel:
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  assumes a: "Quotient R Abs Rep T"
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  shows "T = (\<lambda>x y. R x x \<and> Abs x = y)"
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  using a
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  unfolding Quotient_def
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  by blast
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lemma Quotient_refl1: 
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  assumes a: "Quotient R Abs Rep T" 
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  shows "R r s \<Longrightarrow> R r r"
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  using a unfolding Quotient_def 
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  by fast
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lemma Quotient_refl2: 
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  assumes a: "Quotient R Abs Rep T" 
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  shows "R r s \<Longrightarrow> R s s"
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  using a unfolding Quotient_def 
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  by fast
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lemma Quotient_rel_rep:
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  assumes a: "Quotient R Abs Rep T"
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  shows "R (Rep a) (Rep b) \<longleftrightarrow> a = b"
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  using a
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  unfolding Quotient_def
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  by metis
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lemma Quotient_rep_abs:
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  assumes a: "Quotient R Abs Rep T"
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  shows "R r r \<Longrightarrow> R (Rep (Abs r)) r"
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  using a unfolding Quotient_def
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  by blast
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lemma Quotient_rel_abs:
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  assumes a: "Quotient R Abs Rep T"
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  shows "R r s \<Longrightarrow> Abs r = Abs s"
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  using a unfolding Quotient_def
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  by blast
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lemma Quotient_symp:
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  assumes a: "Quotient R Abs Rep T"
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  shows "symp R"
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  using a unfolding Quotient_def using sympI by (metis (full_types))
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lemma Quotient_transp:
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  assumes a: "Quotient R Abs Rep T"
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  shows "transp R"
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  using a unfolding Quotient_def using transpI by (metis (full_types))
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lemma Quotient_part_equivp:
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  assumes a: "Quotient R Abs Rep T"
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  shows "part_equivp R"
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by (metis Quotient_rep_reflp Quotient_symp Quotient_transp a part_equivpI)
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lemma identity_quotient: "Quotient (op =) id id (op =)"
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unfolding Quotient_def by simp 
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lemma Quotient_alt_def:
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  "Quotient R Abs Rep T \<longleftrightarrow>
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    (\<forall>a b. T a b \<longrightarrow> Abs a = b) \<and>
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    (\<forall>b. T (Rep b) b) \<and>
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    (\<forall>x y. R x y \<longleftrightarrow> T x (Abs x) \<and> T y (Abs y) \<and> Abs x = Abs y)"
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apply safe
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apply (simp (no_asm_use) only: Quotient_def, fast)
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apply (simp (no_asm_use) only: Quotient_def, fast)
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apply (simp (no_asm_use) only: Quotient_def, fast)
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apply (simp (no_asm_use) only: Quotient_def, fast)
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apply (simp (no_asm_use) only: Quotient_def, fast)
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apply (simp (no_asm_use) only: Quotient_def, fast)
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apply (rule QuotientI)
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apply simp
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apply metis
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apply simp
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apply (rule ext, rule ext, metis)
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done
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lemma Quotient_alt_def2:
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  "Quotient R Abs Rep T \<longleftrightarrow>
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    (\<forall>a b. T a b \<longrightarrow> Abs a = b) \<and>
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    (\<forall>b. T (Rep b) b) \<and>
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    (\<forall>x y. R x y \<longleftrightarrow> T x (Abs y) \<and> T y (Abs x))"
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  unfolding Quotient_alt_def by (safe, metis+)
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lemma fun_quotient:
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  assumes 1: "Quotient R1 abs1 rep1 T1"
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  assumes 2: "Quotient R2 abs2 rep2 T2"
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  shows "Quotient (R1 ===> R2) (rep1 ---> abs2) (abs1 ---> rep2) (T1 ===> T2)"
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  using assms unfolding Quotient_alt_def2
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  unfolding fun_rel_def fun_eq_iff map_fun_apply
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  by (safe, metis+)
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lemma apply_rsp:
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  fixes f g::"'a \<Rightarrow> 'c"
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  assumes q: "Quotient R1 Abs1 Rep1 T1"
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  and     a: "(R1 ===> R2) f g" "R1 x y"
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  shows "R2 (f x) (g y)"
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  using a by (auto elim: fun_relE)
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lemma apply_rsp':
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  assumes a: "(R1 ===> R2) f g" "R1 x y"
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  shows "R2 (f x) (g y)"
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  using a by (auto elim: fun_relE)
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lemma apply_rsp'':
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  assumes "Quotient R Abs Rep T"
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  and "(R ===> S) f f"
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  shows "S (f (Rep x)) (f (Rep x))"
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proof -
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  from assms(1) have "R (Rep x) (Rep x)" by (rule Quotient_rep_reflp)
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  then show ?thesis using assms(2) by (auto intro: apply_rsp')
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qed
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subsection {* Quotient composition *}
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lemma Quotient_compose:
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  assumes 1: "Quotient R1 Abs1 Rep1 T1"
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  assumes 2: "Quotient R2 Abs2 Rep2 T2"
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  shows "Quotient (T1 OO R2 OO conversep T1) (Abs2 \<circ> Abs1) (Rep1 \<circ> Rep2) (T1 OO T2)"
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proof -
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  from 1 have Abs1: "\<And>a b. T1 a b \<Longrightarrow> Abs1 a = b"
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    unfolding Quotient_alt_def by simp
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  from 1 have Rep1: "\<And>b. T1 (Rep1 b) b"
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    unfolding Quotient_alt_def by simp
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  from 2 have Abs2: "\<And>a b. T2 a b \<Longrightarrow> Abs2 a = b"
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    unfolding Quotient_alt_def by simp
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  from 2 have Rep2: "\<And>b. T2 (Rep2 b) b"
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    unfolding Quotient_alt_def by simp
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  from 2 have R2:
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    "\<And>x y. R2 x y \<longleftrightarrow> T2 x (Abs2 x) \<and> T2 y (Abs2 y) \<and> Abs2 x = Abs2 y"
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    unfolding Quotient_alt_def by simp
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  show ?thesis
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    unfolding Quotient_alt_def
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    apply simp
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    apply safe
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    apply (drule Abs1, simp)
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    apply (erule Abs2)
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    apply (rule pred_compI)
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    apply (rule Rep1)
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    apply (rule Rep2)
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    apply (rule pred_compI, assumption)
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    apply (drule Abs1, simp)
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    apply (clarsimp simp add: R2)
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    apply (rule pred_compI, assumption)
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    apply (drule Abs1, simp)+
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    apply (clarsimp simp add: R2)
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    apply (drule Abs1, simp)+
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    apply (clarsimp simp add: R2)
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    apply (rule pred_compI, assumption)
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    apply (rule pred_compI [rotated])
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    apply (erule conversepI)
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    apply (drule Abs1, simp)+
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    apply (simp add: R2)
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    done
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qed
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subsection {* Invariant *}
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definition invariant :: "('a \<Rightarrow> bool) \<Rightarrow> 'a \<Rightarrow> 'a \<Rightarrow> bool" 
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  where "invariant R = (\<lambda>x y. R x \<and> x = y)"
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lemma invariant_to_eq:
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  assumes "invariant P x y"
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  shows "x = y"
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using assms by (simp add: invariant_def)
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lemma fun_rel_eq_invariant:
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  shows "((invariant R) ===> S) = (\<lambda>f g. \<forall>x. R x \<longrightarrow> S (f x) (g x))"
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by (auto simp add: invariant_def fun_rel_def)
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lemma invariant_same_args:
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  shows "invariant P x x \<equiv> P x"
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using assms by (auto simp add: invariant_def)
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lemma copy_type_to_Quotient:
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  assumes "type_definition Rep Abs UNIV"
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  and T_def: "T \<equiv> (\<lambda>x y. Abs x = y)"
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  shows "Quotient (op =) Abs Rep T"
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proof -
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  interpret type_definition Rep Abs UNIV by fact
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  from Abs_inject Rep_inverse T_def show ?thesis by (auto intro!: QuotientI)
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qed
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lemma copy_type_to_equivp:
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  fixes Abs :: "'a \<Rightarrow> 'b"
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  and Rep :: "'b \<Rightarrow> 'a"
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  assumes "type_definition Rep Abs (UNIV::'a set)"
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  shows "equivp (op=::'a\<Rightarrow>'a\<Rightarrow>bool)"
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by (rule identity_equivp)
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lemma invariant_type_to_Quotient:
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  assumes "type_definition Rep Abs {x. P x}"
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  and T_def: "T \<equiv> (\<lambda>x y. (invariant P) x x \<and> Abs x = y)"
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  shows "Quotient (invariant P) Abs Rep T"
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proof -
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  interpret type_definition Rep Abs "{x. P x}" by fact
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  from Rep Abs_inject Rep_inverse T_def show ?thesis by (auto intro!: QuotientI simp: invariant_def)
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qed
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lemma invariant_type_to_part_equivp:
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  assumes "type_definition Rep Abs {x. P x}"
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  shows "part_equivp (invariant P)"
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proof (intro part_equivpI)
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  interpret type_definition Rep Abs "{x. P x}" by fact
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  show "\<exists>x. invariant P x x" using Rep by (auto simp: invariant_def)
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next
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  show "symp (invariant P)" by (auto intro: sympI simp: invariant_def)
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next
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  show "transp (invariant P)" by (auto intro: transpI simp: invariant_def)
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qed
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subsection {* ML setup *}
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text {* Auxiliary data for the lifting package *}
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use "Tools/Lifting/lifting_info.ML"
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setup Lifting_Info.setup
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declare [[map "fun" = (fun_rel, fun_quotient)]]
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use "Tools/Lifting/lifting_term.ML"
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use "Tools/Lifting/lifting_def.ML"
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use "Tools/Lifting/lifting_setup.ML"
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hide_const (open) invariant
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end