(* Author: Christian Urban, Xingyuan Zhang, Chunhan Wu *)
theory Closures
imports Derivatives
begin
section {* Closure properties of regular languages *}
abbreviation
regular :: "'a lang \<Rightarrow> bool"
where
"regular A \<equiv> \<exists>r. A = lang r"
subsection {* Closure under set operations *}
lemma closure_union [intro]:
assumes "regular A" "regular B"
shows "regular (A \<union> B)"
proof -
from assms obtain r1 r2::"'a rexp" where "lang r1 = A" "lang r2 = B" by auto
then have "A \<union> B = lang (Plus r1 r2)" by simp
then show "regular (A \<union> B)" by blast
qed
lemma closure_seq [intro]:
assumes "regular A" "regular B"
shows "regular (A \<cdot> B)"
proof -
from assms obtain r1 r2::"'a rexp" where "lang r1 = A" "lang r2 = B" by auto
then have "A \<cdot> B = lang (Times r1 r2)" by simp
then show "regular (A \<cdot> B)" by blast
qed
lemma closure_star [intro]:
assumes "regular A"
shows "regular (A\<star>)"
proof -
from assms obtain r::"'a rexp" where "lang r = A" by auto
then have "A\<star> = lang (Star r)" by simp
then show "regular (A\<star>)" by blast
qed
text {* Closure under complementation is proved via the
Myhill-Nerode theorem *}
lemma closure_complement [intro]:
fixes A::"('a::finite) lang"
assumes "regular A"
shows "regular (- A)"
proof -
from assms have "finite (UNIV // \<approx>A)" by (simp add: Myhill_Nerode)
then have "finite (UNIV // \<approx>(-A))" by (simp add: str_eq_def)
then show "regular (- A)" by (simp add: Myhill_Nerode)
qed
lemma closure_difference [intro]:
fixes A::"('a::finite) lang"
assumes "regular A" "regular B"
shows "regular (A - B)"
proof -
have "A - B = - (- A \<union> B)" by blast
moreover
have "regular (- (- A \<union> B))"
using assms by blast
ultimately show "regular (A - B)" by simp
qed
lemma closure_intersection [intro]:
fixes A::"('a::finite) lang"
assumes "regular A" "regular B"
shows "regular (A \<inter> B)"
proof -
have "A \<inter> B = - (- A \<union> - B)" by blast
moreover
have "regular (- (- A \<union> - B))"
using assms by blast
ultimately show "regular (A \<inter> B)" by simp
qed
subsection {* Closure under string reversal *}
fun
Rev :: "'a rexp \<Rightarrow> 'a rexp"
where
"Rev Zero = Zero"
| "Rev One = One"
| "Rev (Atom c) = Atom c"
| "Rev (Plus r1 r2) = Plus (Rev r1) (Rev r2)"
| "Rev (Times r1 r2) = Times (Rev r2) (Rev r1)"
| "Rev (Star r) = Star (Rev r)"
lemma rev_seq[simp]:
shows "rev ` (B \<cdot> A) = (rev ` A) \<cdot> (rev ` B)"
unfolding conc_def image_def
by (auto) (metis rev_append)+
lemma rev_star1:
assumes a: "s \<in> (rev ` A)\<star>"
shows "s \<in> rev ` (A\<star>)"
using a
proof(induct rule: star_induct)
case (append s1 s2)
have inj: "inj (rev::'a list \<Rightarrow> 'a list)" unfolding inj_on_def by auto
have "s1 \<in> rev ` A" "s2 \<in> rev ` (A\<star>)" by fact+
then obtain x1 x2 where "x1 \<in> A" "x2 \<in> A\<star>" and eqs: "s1 = rev x1" "s2 = rev x2" by auto
then have "x1 \<in> A\<star>" "x2 \<in> A\<star>" by (auto)
then have "x2 @ x1 \<in> A\<star>" by (auto)
then have "rev (x2 @ x1) \<in> rev ` A\<star>" using inj by (simp only: inj_image_mem_iff)
then show "s1 @ s2 \<in> rev ` A\<star>" using eqs by simp
qed (auto)
lemma rev_star2:
assumes a: "s \<in> A\<star>"
shows "rev s \<in> (rev ` A)\<star>"
using a
proof(induct rule: star_induct)
case (append s1 s2)
have inj: "inj (rev::'a list \<Rightarrow> 'a list)" unfolding inj_on_def by auto
have "s1 \<in> A"by fact
then have "rev s1 \<in> rev ` A" using inj by (simp only: inj_image_mem_iff)
then have "rev s1 \<in> (rev ` A)\<star>" by (auto)
moreover
have "rev s2 \<in> (rev ` A)\<star>" by fact
ultimately show "rev (s1 @ s2) \<in> (rev ` A)\<star>" by (auto)
qed (auto)
lemma rev_star [simp]:
shows " rev ` (A\<star>) = (rev ` A)\<star>"
using rev_star1 rev_star2 by auto
lemma rev_lang:
shows "rev ` (lang r) = lang (Rev r)"
by (induct r) (simp_all add: image_Un)
lemma closure_reversal [intro]:
assumes "regular A"
shows "regular (rev ` A)"
proof -
from assms obtain r::"'a rexp" where "A = lang r" by auto
then have "lang (Rev r) = rev ` A" by (simp add: rev_lang)
then show "regular (rev` A)" by blast
qed
subsection {* Closure under left-quotients *}
abbreviation
"Ders_lang A B \<equiv> \<Union>x \<in> A. Ders x B"
lemma closure_left_quotient:
assumes "regular A"
shows "regular (Ders_lang B A)"
proof -
from assms obtain r::"'a rexp" where eq: "lang r = A" by auto
have fin: "finite (pders_lang B r)" by (rule finite_pders_lang)
have "Ders_lang B (lang r) = (\<Union> lang ` (pders_lang B r))"
by (simp add: Ders_pders pders_lang_def)
also have "\<dots> = lang (\<Uplus>(pders_lang B r))" using fin by simp
finally have "Ders_lang B A = lang (\<Uplus>(pders_lang B r))" using eq
by simp
then show "regular (Ders_lang B A)" by auto
qed
end