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(* Title: HOL/Lifting.thy
Author: Brian Huffman and Ondrej Kuncar
Author: Cezary Kaliszyk and Christian Urban
*)
header {* Lifting package *}
theory Lifting
imports Equiv_Relations Transfer
keywords
"parametric" and
"print_quot_maps" "print_quotients" :: diag and
"lift_definition" :: thy_goal and
"setup_lifting" "lifting_forget" "lifting_update" :: thy_decl
begin
subsection {* Function map *}
context
begin
interpretation lifting_syntax .
lemma map_fun_id:
"(id ---> id) = id"
by (simp add: fun_eq_iff)
subsection {* Other predicates on relations *}
definition left_total :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> bool"
where "left_total R \<longleftrightarrow> (\<forall>x. \<exists>y. R x y)"
lemma left_totalI:
"(\<And>x. \<exists>y. R x y) \<Longrightarrow> left_total R"
unfolding left_total_def by blast
lemma left_totalE:
assumes "left_total R"
obtains "(\<And>x. \<exists>y. R x y)"
using assms unfolding left_total_def by blast
lemma bi_total_iff: "bi_total A = (right_total A \<and> left_total A)"
unfolding left_total_def right_total_def bi_total_def by blast
lemma bi_total_conv_left_right: "bi_total R \<longleftrightarrow> left_total R \<and> right_total R"
by(simp add: left_total_def right_total_def bi_total_def)
definition left_unique :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> bool"
where "left_unique R \<longleftrightarrow> (\<forall>x y z. R x z \<longrightarrow> R y z \<longrightarrow> x = y)"
lemma left_unique_transfer [transfer_rule]:
assumes [transfer_rule]: "right_total A"
assumes [transfer_rule]: "right_total B"
assumes [transfer_rule]: "bi_unique A"
shows "((A ===> B ===> op=) ===> implies) left_unique left_unique"
using assms unfolding left_unique_def[abs_def] right_total_def bi_unique_def rel_fun_def
by metis
lemma bi_unique_iff: "bi_unique A = (right_unique A \<and> left_unique A)"
unfolding left_unique_def right_unique_def bi_unique_def by blast
lemma bi_unique_conv_left_right: "bi_unique R \<longleftrightarrow> left_unique R \<and> right_unique R"
by(auto simp add: left_unique_def right_unique_def bi_unique_def)
lemma left_uniqueI: "(\<And>x y z. \<lbrakk> A x z; A y z \<rbrakk> \<Longrightarrow> x = y) \<Longrightarrow> left_unique A"
unfolding left_unique_def by blast
lemma left_uniqueD: "\<lbrakk> left_unique A; A x z; A y z \<rbrakk> \<Longrightarrow> x = y"
unfolding left_unique_def by blast
lemma left_total_fun:
"\<lbrakk>left_unique A; left_total B\<rbrakk> \<Longrightarrow> left_total (A ===> B)"
unfolding left_total_def rel_fun_def
apply (rule allI, rename_tac f)
apply (rule_tac x="\<lambda>y. SOME z. B (f (THE x. A x y)) z" in exI)
apply clarify
apply (subgoal_tac "(THE x. A x y) = x", simp)
apply (rule someI_ex)
apply (simp)
apply (rule the_equality)
apply assumption
apply (simp add: left_unique_def)
done
lemma left_unique_fun:
"\<lbrakk>left_total A; left_unique B\<rbrakk> \<Longrightarrow> left_unique (A ===> B)"
unfolding left_total_def left_unique_def rel_fun_def
by (clarify, rule ext, fast)
lemma left_total_eq: "left_total op=" unfolding left_total_def by blast
lemma left_unique_eq: "left_unique op=" unfolding left_unique_def by blast
lemma [simp]:
shows left_unique_conversep: "left_unique A\<inverse>\<inverse> \<longleftrightarrow> right_unique A"
and right_unique_conversep: "right_unique A\<inverse>\<inverse> \<longleftrightarrow> left_unique A"
by(auto simp add: left_unique_def right_unique_def)
lemma [simp]:
shows left_total_conversep: "left_total A\<inverse>\<inverse> \<longleftrightarrow> right_total A"
and right_total_conversep: "right_total A\<inverse>\<inverse> \<longleftrightarrow> left_total A"
by(simp_all add: left_total_def right_total_def)
subsection {* Quotient Predicate *}
definition
"Quotient R Abs Rep T \<longleftrightarrow>
(\<forall>a. Abs (Rep a) = a) \<and>
(\<forall>a. R (Rep a) (Rep a)) \<and>
(\<forall>r s. R r s \<longleftrightarrow> R r r \<and> R s s \<and> Abs r = Abs s) \<and>
T = (\<lambda>x y. R x x \<and> Abs x = y)"
lemma QuotientI:
assumes "\<And>a. Abs (Rep a) = a"
and "\<And>a. R (Rep a) (Rep a)"
and "\<And>r s. R r s \<longleftrightarrow> R r r \<and> R s s \<and> Abs r = Abs s"
and "T = (\<lambda>x y. R x x \<and> Abs x = y)"
shows "Quotient R Abs Rep T"
using assms unfolding Quotient_def by blast
context
fixes R Abs Rep T
assumes a: "Quotient R Abs Rep T"
begin
lemma Quotient_abs_rep: "Abs (Rep a) = a"
using a unfolding Quotient_def
by simp
lemma Quotient_rep_reflp: "R (Rep a) (Rep a)"
using a unfolding Quotient_def
by blast
lemma Quotient_rel:
"R r r \<and> R s s \<and> Abs r = Abs s \<longleftrightarrow> R r s" -- {* orientation does not loop on rewriting *}
using a unfolding Quotient_def
by blast
lemma Quotient_cr_rel: "T = (\<lambda>x y. R x x \<and> Abs x = y)"
using a unfolding Quotient_def
by blast
lemma Quotient_refl1: "R r s \<Longrightarrow> R r r"
using a unfolding Quotient_def
by fast
lemma Quotient_refl2: "R r s \<Longrightarrow> R s s"
using a unfolding Quotient_def
by fast
lemma Quotient_rel_rep: "R (Rep a) (Rep b) \<longleftrightarrow> a = b"
using a unfolding Quotient_def
by metis
lemma Quotient_rep_abs: "R r r \<Longrightarrow> R (Rep (Abs r)) r"
using a unfolding Quotient_def
by blast
lemma Quotient_rep_abs_eq: "R t t \<Longrightarrow> R \<le> op= \<Longrightarrow> Rep (Abs t) = t"
using a unfolding Quotient_def
by blast
lemma Quotient_rep_abs_fold_unmap:
assumes "x' \<equiv> Abs x" and "R x x" and "Rep x' \<equiv> Rep' x'"
shows "R (Rep' x') x"
proof -
have "R (Rep x') x" using assms(1-2) Quotient_rep_abs by auto
then show ?thesis using assms(3) by simp
qed
lemma Quotient_Rep_eq:
assumes "x' \<equiv> Abs x"
shows "Rep x' \<equiv> Rep x'"
by simp
lemma Quotient_rel_abs: "R r s \<Longrightarrow> Abs r = Abs s"
using a unfolding Quotient_def
by blast
lemma Quotient_rel_abs2:
assumes "R (Rep x) y"
shows "x = Abs y"
proof -
from assms have "Abs (Rep x) = Abs y" by (auto intro: Quotient_rel_abs)
then show ?thesis using assms(1) by (simp add: Quotient_abs_rep)
qed
lemma Quotient_symp: "symp R"
using a unfolding Quotient_def using sympI by (metis (full_types))
lemma Quotient_transp: "transp R"
using a unfolding Quotient_def using transpI by (metis (full_types))
lemma Quotient_part_equivp: "part_equivp R"
by (metis Quotient_rep_reflp Quotient_symp Quotient_transp part_equivpI)
end
lemma identity_quotient: "Quotient (op =) id id (op =)"
unfolding Quotient_def by simp
text {* TODO: Use one of these alternatives as the real definition. *}
lemma Quotient_alt_def:
"Quotient R Abs Rep T \<longleftrightarrow>
(\<forall>a b. T a b \<longrightarrow> Abs a = b) \<and>
(\<forall>b. T (Rep b) b) \<and>
(\<forall>x y. R x y \<longleftrightarrow> T x (Abs x) \<and> T y (Abs y) \<and> Abs x = Abs y)"
apply safe
apply (simp (no_asm_use) only: Quotient_def, fast)
apply (simp (no_asm_use) only: Quotient_def, fast)
apply (simp (no_asm_use) only: Quotient_def, fast)
apply (simp (no_asm_use) only: Quotient_def, fast)
apply (simp (no_asm_use) only: Quotient_def, fast)
apply (simp (no_asm_use) only: Quotient_def, fast)
apply (rule QuotientI)
apply simp
apply metis
apply simp
apply (rule ext, rule ext, metis)
done
lemma Quotient_alt_def2:
"Quotient R Abs Rep T \<longleftrightarrow>
(\<forall>a b. T a b \<longrightarrow> Abs a = b) \<and>
(\<forall>b. T (Rep b) b) \<and>
(\<forall>x y. R x y \<longleftrightarrow> T x (Abs y) \<and> T y (Abs x))"
unfolding Quotient_alt_def by (safe, metis+)
lemma Quotient_alt_def3:
"Quotient R Abs Rep T \<longleftrightarrow>
(\<forall>a b. T a b \<longrightarrow> Abs a = b) \<and> (\<forall>b. T (Rep b) b) \<and>
(\<forall>x y. R x y \<longleftrightarrow> (\<exists>z. T x z \<and> T y z))"
unfolding Quotient_alt_def2 by (safe, metis+)
lemma Quotient_alt_def4:
"Quotient R Abs Rep T \<longleftrightarrow>
(\<forall>a b. T a b \<longrightarrow> Abs a = b) \<and> (\<forall>b. T (Rep b) b) \<and> R = T OO conversep T"
unfolding Quotient_alt_def3 fun_eq_iff by auto
lemma fun_quotient:
assumes 1: "Quotient R1 abs1 rep1 T1"
assumes 2: "Quotient R2 abs2 rep2 T2"
shows "Quotient (R1 ===> R2) (rep1 ---> abs2) (abs1 ---> rep2) (T1 ===> T2)"
using assms unfolding Quotient_alt_def2
unfolding rel_fun_def fun_eq_iff map_fun_apply
by (safe, metis+)
lemma apply_rsp:
fixes f g::"'a \<Rightarrow> 'c"
assumes q: "Quotient R1 Abs1 Rep1 T1"
and a: "(R1 ===> R2) f g" "R1 x y"
shows "R2 (f x) (g y)"
using a by (auto elim: rel_funE)
lemma apply_rsp':
assumes a: "(R1 ===> R2) f g" "R1 x y"
shows "R2 (f x) (g y)"
using a by (auto elim: rel_funE)
lemma apply_rsp'':
assumes "Quotient R Abs Rep T"
and "(R ===> S) f f"
shows "S (f (Rep x)) (f (Rep x))"
proof -
from assms(1) have "R (Rep x) (Rep x)" by (rule Quotient_rep_reflp)
then show ?thesis using assms(2) by (auto intro: apply_rsp')
qed
subsection {* Quotient composition *}
lemma Quotient_compose:
assumes 1: "Quotient R1 Abs1 Rep1 T1"
assumes 2: "Quotient R2 Abs2 Rep2 T2"
shows "Quotient (T1 OO R2 OO conversep T1) (Abs2 \<circ> Abs1) (Rep1 \<circ> Rep2) (T1 OO T2)"
using assms unfolding Quotient_alt_def4 by fastforce
lemma equivp_reflp2:
"equivp R \<Longrightarrow> reflp R"
by (erule equivpE)
subsection {* Respects predicate *}
definition Respects :: "('a \<Rightarrow> 'a \<Rightarrow> bool) \<Rightarrow> 'a set"
where "Respects R = {x. R x x}"
lemma in_respects: "x \<in> Respects R \<longleftrightarrow> R x x"
unfolding Respects_def by simp
subsection {* Invariant *}
definition invariant :: "('a \<Rightarrow> bool) \<Rightarrow> 'a \<Rightarrow> 'a \<Rightarrow> bool"
where "invariant R = (\<lambda>x y. R x \<and> x = y)"
lemma invariant_to_eq:
assumes "invariant P x y"
shows "x = y"
using assms by (simp add: invariant_def)
lemma rel_fun_eq_invariant: "(op= ===> Lifting.invariant P) = Lifting.invariant (\<lambda>f. \<forall>x. P(f x))"
unfolding invariant_def rel_fun_def by auto
lemma rel_fun_invariant_rel:
shows "((invariant R) ===> S) = (\<lambda>f g. \<forall>x. R x \<longrightarrow> S (f x) (g x))"
by (auto simp add: invariant_def rel_fun_def)
lemma invariant_same_args:
shows "invariant P x x \<equiv> P x"
using assms by (auto simp add: invariant_def)
lemma invariant_transfer [transfer_rule]:
assumes [transfer_rule]: "bi_unique A"
shows "((A ===> op=) ===> A ===> A ===> op=) Lifting.invariant Lifting.invariant"
unfolding invariant_def[abs_def] by transfer_prover
lemma UNIV_typedef_to_Quotient:
assumes "type_definition Rep Abs UNIV"
and T_def: "T \<equiv> (\<lambda>x y. x = Rep y)"
shows "Quotient (op =) Abs Rep T"
proof -
interpret type_definition Rep Abs UNIV by fact
from Abs_inject Rep_inverse Abs_inverse T_def show ?thesis
by (fastforce intro!: QuotientI fun_eq_iff)
qed
lemma UNIV_typedef_to_equivp:
fixes Abs :: "'a \<Rightarrow> 'b"
and Rep :: "'b \<Rightarrow> 'a"
assumes "type_definition Rep Abs (UNIV::'a set)"
shows "equivp (op=::'a\<Rightarrow>'a\<Rightarrow>bool)"
by (rule identity_equivp)
lemma typedef_to_Quotient:
assumes "type_definition Rep Abs S"
and T_def: "T \<equiv> (\<lambda>x y. x = Rep y)"
shows "Quotient (invariant (\<lambda>x. x \<in> S)) Abs Rep T"
proof -
interpret type_definition Rep Abs S by fact
from Rep Abs_inject Rep_inverse Abs_inverse T_def show ?thesis
by (auto intro!: QuotientI simp: invariant_def fun_eq_iff)
qed
lemma typedef_to_part_equivp:
assumes "type_definition Rep Abs S"
shows "part_equivp (invariant (\<lambda>x. x \<in> S))"
proof (intro part_equivpI)
interpret type_definition Rep Abs S by fact
show "\<exists>x. invariant (\<lambda>x. x \<in> S) x x" using Rep by (auto simp: invariant_def)
next
show "symp (invariant (\<lambda>x. x \<in> S))" by (auto intro: sympI simp: invariant_def)
next
show "transp (invariant (\<lambda>x. x \<in> S))" by (auto intro: transpI simp: invariant_def)
qed
lemma open_typedef_to_Quotient:
assumes "type_definition Rep Abs {x. P x}"
and T_def: "T \<equiv> (\<lambda>x y. x = Rep y)"
shows "Quotient (invariant P) Abs Rep T"
using typedef_to_Quotient [OF assms] by simp
lemma open_typedef_to_part_equivp:
assumes "type_definition Rep Abs {x. P x}"
shows "part_equivp (invariant P)"
using typedef_to_part_equivp [OF assms] by simp
text {* Generating transfer rules for quotients. *}
context
fixes R Abs Rep T
assumes 1: "Quotient R Abs Rep T"
begin
lemma Quotient_right_unique: "right_unique T"
using 1 unfolding Quotient_alt_def right_unique_def by metis
lemma Quotient_right_total: "right_total T"
using 1 unfolding Quotient_alt_def right_total_def by metis
lemma Quotient_rel_eq_transfer: "(T ===> T ===> op =) R (op =)"
using 1 unfolding Quotient_alt_def rel_fun_def by simp
lemma Quotient_abs_induct:
assumes "\<And>y. R y y \<Longrightarrow> P (Abs y)" shows "P x"
using 1 assms unfolding Quotient_def by metis
end
text {* Generating transfer rules for total quotients. *}
context
fixes R Abs Rep T
assumes 1: "Quotient R Abs Rep T" and 2: "reflp R"
begin
lemma Quotient_bi_total: "bi_total T"
using 1 2 unfolding Quotient_alt_def bi_total_def reflp_def by auto
lemma Quotient_id_abs_transfer: "(op = ===> T) (\<lambda>x. x) Abs"
using 1 2 unfolding Quotient_alt_def reflp_def rel_fun_def by simp
lemma Quotient_total_abs_induct: "(\<And>y. P (Abs y)) \<Longrightarrow> P x"
using 1 2 assms unfolding Quotient_alt_def reflp_def by metis
lemma Quotient_total_abs_eq_iff: "Abs x = Abs y \<longleftrightarrow> R x y"
using Quotient_rel [OF 1] 2 unfolding reflp_def by simp
end
text {* Generating transfer rules for a type defined with @{text "typedef"}. *}
context
fixes Rep Abs A T
assumes type: "type_definition Rep Abs A"
assumes T_def: "T \<equiv> (\<lambda>(x::'a) (y::'b). x = Rep y)"
begin
lemma typedef_left_unique: "left_unique T"
unfolding left_unique_def T_def
by (simp add: type_definition.Rep_inject [OF type])
lemma typedef_bi_unique: "bi_unique T"
unfolding bi_unique_def T_def
by (simp add: type_definition.Rep_inject [OF type])
(* the following two theorems are here only for convinience *)
lemma typedef_right_unique: "right_unique T"
using T_def type Quotient_right_unique typedef_to_Quotient
by blast
lemma typedef_right_total: "right_total T"
using T_def type Quotient_right_total typedef_to_Quotient
by blast
lemma typedef_rep_transfer: "(T ===> op =) (\<lambda>x. x) Rep"
unfolding rel_fun_def T_def by simp
end
text {* Generating the correspondence rule for a constant defined with
@{text "lift_definition"}. *}
lemma Quotient_to_transfer:
assumes "Quotient R Abs Rep T" and "R c c" and "c' \<equiv> Abs c"
shows "T c c'"
using assms by (auto dest: Quotient_cr_rel)
text {* Proving reflexivity *}
lemma Quotient_to_left_total:
assumes q: "Quotient R Abs Rep T"
and r_R: "reflp R"
shows "left_total T"
using r_R Quotient_cr_rel[OF q] unfolding left_total_def by (auto elim: reflpE)
lemma Quotient_composition_ge_eq:
assumes "left_total T"
assumes "R \<ge> op="
shows "(T OO R OO T\<inverse>\<inverse>) \<ge> op="
using assms unfolding left_total_def by fast
lemma Quotient_composition_le_eq:
assumes "left_unique T"
assumes "R \<le> op="
shows "(T OO R OO T\<inverse>\<inverse>) \<le> op="
using assms unfolding left_unique_def by blast
lemma left_total_composition: "left_total R \<Longrightarrow> left_total S \<Longrightarrow> left_total (R OO S)"
unfolding left_total_def OO_def by fast
lemma left_unique_composition: "left_unique R \<Longrightarrow> left_unique S \<Longrightarrow> left_unique (R OO S)"
unfolding left_unique_def OO_def by blast
lemma invariant_le_eq:
"invariant P \<le> op=" unfolding invariant_def by blast
lemma reflp_ge_eq:
"reflp R \<Longrightarrow> R \<ge> op=" unfolding reflp_def by blast
lemma ge_eq_refl:
"R \<ge> op= \<Longrightarrow> R x x" by blast
text {* Proving a parametrized correspondence relation *}
definition POS :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> ('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> bool" where
"POS A B \<equiv> A \<le> B"
definition NEG :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> ('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> bool" where
"NEG A B \<equiv> B \<le> A"
(*
The following two rules are here because we don't have any proper
left-unique ant left-total relations. Left-unique and left-total
assumptions show up in distributivity rules for the function type.
*)
lemma bi_unique_left_unique[transfer_rule]: "bi_unique R \<Longrightarrow> left_unique R"
unfolding bi_unique_def left_unique_def by blast
lemma bi_total_left_total[transfer_rule]: "bi_total R \<Longrightarrow> left_total R"
unfolding bi_total_def left_total_def by blast
lemma pos_OO_eq:
shows "POS (A OO op=) A"
unfolding POS_def OO_def by blast
lemma pos_eq_OO:
shows "POS (op= OO A) A"
unfolding POS_def OO_def by blast
lemma neg_OO_eq:
shows "NEG (A OO op=) A"
unfolding NEG_def OO_def by auto
lemma neg_eq_OO:
shows "NEG (op= OO A) A"
unfolding NEG_def OO_def by blast
lemma POS_trans:
assumes "POS A B"
assumes "POS B C"
shows "POS A C"
using assms unfolding POS_def by auto
lemma NEG_trans:
assumes "NEG A B"
assumes "NEG B C"
shows "NEG A C"
using assms unfolding NEG_def by auto
lemma POS_NEG:
"POS A B \<equiv> NEG B A"
unfolding POS_def NEG_def by auto
lemma NEG_POS:
"NEG A B \<equiv> POS B A"
unfolding POS_def NEG_def by auto
lemma POS_pcr_rule:
assumes "POS (A OO B) C"
shows "POS (A OO B OO X) (C OO X)"
using assms unfolding POS_def OO_def by blast
lemma NEG_pcr_rule:
assumes "NEG (A OO B) C"
shows "NEG (A OO B OO X) (C OO X)"
using assms unfolding NEG_def OO_def by blast
lemma POS_apply:
assumes "POS R R'"
assumes "R f g"
shows "R' f g"
using assms unfolding POS_def by auto
text {* Proving a parametrized correspondence relation *}
lemma fun_mono:
assumes "A \<ge> C"
assumes "B \<le> D"
shows "(A ===> B) \<le> (C ===> D)"
using assms unfolding rel_fun_def by blast
lemma pos_fun_distr: "((R ===> S) OO (R' ===> S')) \<le> ((R OO R') ===> (S OO S'))"
unfolding OO_def rel_fun_def by blast
lemma functional_relation: "right_unique R \<Longrightarrow> left_total R \<Longrightarrow> \<forall>x. \<exists>!y. R x y"
unfolding right_unique_def left_total_def by blast
lemma functional_converse_relation: "left_unique R \<Longrightarrow> right_total R \<Longrightarrow> \<forall>y. \<exists>!x. R x y"
unfolding left_unique_def right_total_def by blast
lemma neg_fun_distr1:
assumes 1: "left_unique R" "right_total R"
assumes 2: "right_unique R'" "left_total R'"
shows "(R OO R' ===> S OO S') \<le> ((R ===> S) OO (R' ===> S')) "
using functional_relation[OF 2] functional_converse_relation[OF 1]
unfolding rel_fun_def OO_def
apply clarify
apply (subst all_comm)
apply (subst all_conj_distrib[symmetric])
apply (intro choice)
by metis
lemma neg_fun_distr2:
assumes 1: "right_unique R'" "left_total R'"
assumes 2: "left_unique S'" "right_total S'"
shows "(R OO R' ===> S OO S') \<le> ((R ===> S) OO (R' ===> S'))"
using functional_converse_relation[OF 2] functional_relation[OF 1]
unfolding rel_fun_def OO_def
apply clarify
apply (subst all_comm)
apply (subst all_conj_distrib[symmetric])
apply (intro choice)
by metis
subsection {* Domains *}
lemma composed_equiv_rel_invariant:
assumes "left_unique R"
assumes "(R ===> op=) P P'"
assumes "Domainp R = P''"
shows "(R OO Lifting.invariant P' OO R\<inverse>\<inverse>) = Lifting.invariant (inf P'' P)"
using assms unfolding OO_def conversep_iff Domainp_iff[abs_def] left_unique_def rel_fun_def invariant_def
fun_eq_iff by blast
lemma composed_equiv_rel_eq_invariant:
assumes "left_unique R"
assumes "Domainp R = P"
shows "(R OO op= OO R\<inverse>\<inverse>) = Lifting.invariant P"
using assms unfolding OO_def conversep_iff Domainp_iff[abs_def] left_unique_def invariant_def
fun_eq_iff is_equality_def by metis
lemma pcr_Domainp_par_left_total:
assumes "Domainp B = P"
assumes "left_total A"
assumes "(A ===> op=) P' P"
shows "Domainp (A OO B) = P'"
using assms
unfolding Domainp_iff[abs_def] OO_def bi_unique_def left_total_def rel_fun_def
by (fast intro: fun_eq_iff)
lemma pcr_Domainp_par:
assumes "Domainp B = P2"
assumes "Domainp A = P1"
assumes "(A ===> op=) P2' P2"
shows "Domainp (A OO B) = (inf P1 P2')"
using assms unfolding rel_fun_def Domainp_iff[abs_def] OO_def
by (fast intro: fun_eq_iff)
definition rel_pred_comp :: "('a => 'b => bool) => ('b => bool) => 'a => bool"
where "rel_pred_comp R P \<equiv> \<lambda>x. \<exists>y. R x y \<and> P y"
lemma pcr_Domainp:
assumes "Domainp B = P"
shows "Domainp (A OO B) = (\<lambda>x. \<exists>y. A x y \<and> P y)"
using assms by blast
lemma pcr_Domainp_total:
assumes "bi_total B"
assumes "Domainp A = P"
shows "Domainp (A OO B) = P"
using assms unfolding bi_total_def
by fast
lemma Quotient_to_Domainp:
assumes "Quotient R Abs Rep T"
shows "Domainp T = (\<lambda>x. R x x)"
by (simp add: Domainp_iff[abs_def] Quotient_cr_rel[OF assms])
lemma invariant_to_Domainp:
assumes "Quotient (Lifting.invariant P) Abs Rep T"
shows "Domainp T = P"
by (simp add: invariant_def Domainp_iff[abs_def] Quotient_cr_rel[OF assms])
end
subsection {* ML setup *}
ML_file "Tools/Lifting/lifting_util.ML"
ML_file "Tools/Lifting/lifting_info.ML"
setup Lifting_Info.setup
lemmas [reflexivity_rule] =
order_refl[of "op="] invariant_le_eq Quotient_composition_le_eq
Quotient_composition_ge_eq
left_total_eq left_unique_eq left_total_composition left_unique_composition
left_total_fun left_unique_fun
(* setup for the function type *)
declare fun_quotient[quot_map]
declare fun_mono[relator_mono]
lemmas [relator_distr] = pos_fun_distr neg_fun_distr1 neg_fun_distr2
ML_file "Tools/Lifting/lifting_term.ML"
ML_file "Tools/Lifting/lifting_def.ML"
ML_file "Tools/Lifting/lifting_setup.ML"
hide_const (open) invariant POS NEG
end