theory QuotList
imports QuotScript List
begin
fun
list_rel
where
"list_rel R [] [] = True"
| "list_rel R (x#xs) [] = False"
| "list_rel R [] (x#xs) = False"
| "list_rel R (x#xs) (y#ys) = (R x y \<and> list_rel R xs ys)"
lemma list_equivp:
assumes a: "equivp R"
shows "equivp (list_rel R)"
unfolding equivp_def
apply(rule allI)+
apply(induct_tac x y rule: list_induct2')
apply(simp_all add: expand_fun_eq)
apply(metis list_rel.simps(1) list_rel.simps(2))
apply(metis list_rel.simps(1) list_rel.simps(2))
apply(rule iffI)
apply(rule allI)
apply(case_tac x)
apply(simp_all)
using a
apply(unfold equivp_def)
apply(auto)[1]
apply(metis list_rel.simps(4))
done
lemma list_rel_rel:
assumes q: "Quotient R Abs Rep"
shows "list_rel R r s = (list_rel R r r \<and> list_rel R s s \<and> (map Abs r = map Abs s))"
apply(induct r s rule: list_induct2')
apply(simp_all)
using Quotient_rel[OF q]
apply(metis)
done
lemma list_quotient:
assumes q: "Quotient R Abs Rep"
shows "Quotient (list_rel R) (map Abs) (map Rep)"
unfolding Quotient_def
apply(rule conjI)
apply(rule allI)
apply(induct_tac a)
apply(simp)
apply(simp add: Quotient_abs_rep[OF q])
apply(rule conjI)
apply(rule allI)
apply(induct_tac a)
apply(simp)
apply(simp)
apply(simp add: Quotient_REP_reflp[OF q])
apply(rule allI)+
apply(rule list_rel_rel[OF q])
done
lemma cons_prs:
assumes q: "Quotient R Abs Rep"
shows "(map Abs) ((Rep h) # (map Rep t)) = h # t"
by (induct t) (simp_all add: Quotient_abs_rep[OF q])
lemma cons_rsp:
assumes q: "Quotient R Abs Rep"
shows "(R ===> list_rel R ===> list_rel R) op # op #"
by (auto)
lemma nil_prs:
assumes q: "Quotient R Abs Rep"
shows "map Abs [] \<equiv> []"
by (simp)
lemma nil_rsp:
assumes q: "Quotient R Abs Rep"
shows "list_rel R [] []"
by simp
lemma map_prs:
assumes a: "Quotient R1 abs1 rep1"
and b: "Quotient R2 abs2 rep2"
shows "(map abs2) (map ((abs1 ---> rep2) f) (map rep1 l)) = map f l"
by (induct l) (simp_all add: Quotient_abs_rep[OF a] Quotient_abs_rep[OF b])
(* We need an ho version *)
lemma map_rsp:
assumes q1: "Quotient R1 Abs1 Rep1"
and q2: "Quotient R2 Abs2 Rep2"
and a: "(R1 ===> R2) f1 f2"
and b: "list_rel R1 l1 l2"
shows "list_rel R2 (map f1 l1) (map f2 l2)"
using b a
by (induct l1 l2 rule: list_induct2') (simp_all)
lemma foldr_prs:
assumes a: "Quotient R1 abs1 rep1"
and b: "Quotient R2 abs2 rep2"
shows "abs2 (foldr ((abs1 ---> abs2 ---> rep2) f) (map rep1 l) (rep2 e)) = foldr f l e"
by (induct l) (simp_all add: Quotient_abs_rep[OF a] Quotient_abs_rep[OF b])
lemma foldl_prs:
assumes a: "Quotient R1 abs1 rep1"
and b: "Quotient R2 abs2 rep2"
shows "abs1 (foldl ((abs1 ---> abs2 ---> rep1) f) (rep1 e) (map rep2 l)) = foldl f e l"
by (induct l arbitrary:e) (simp_all add: Quotient_abs_rep[OF a] Quotient_abs_rep[OF b])
(* TODO: Rest are unused *)
lemma LIST_map_id:
shows "map (\<lambda>x. x) = (\<lambda>x. x)"
by simp
lemma list_rel_EQ:
shows "list_rel (op =) \<equiv> (op =)"
apply(rule eq_reflection)
unfolding expand_fun_eq
apply(rule allI)+
apply(induct_tac x xa rule: list_induct2')
apply(simp_all)
done
lemma list_rel_REFL:
assumes a: "\<And>x y. R x y = (R x = R y)"
shows "list_rel R x x"
by (induct x) (auto simp add: a)
end