lexing: comparison thys/Spec.thy

equal deleted inserted replaced

-:e752d84225ec
+:8bb064045b4e
 theory Spec
 imports RegLangs
 begin
+section \<open>"Plain" Values\<close>
-section {* "Plain" Values *}
 datatype val =
 Void
 | Char char
 | Seq val val
 | Right val
 | Left val
 | Stars "val list"
-section {* The string behind a value *}
+section \<open>The string behind a value\<close>
 fun
 flat :: "val \<Rightarrow> string"
 where
 "flat (Void) = []"
 lemma flat_Stars [simp]:
 "flat (Stars vs) = flats vs"
 by (induct vs) (auto)
-section {* Lexical Values *}
+section \<open>Lexical Values\<close>
 inductive
 Prf :: "val \<Rightarrow> rexp \<Rightarrow> bool" ("\<Turnstile> _ : _" [100, 100] 100)
 where
 "\<lbrakk>\<Turnstile> v1 : r1; \<Turnstile> v2 : r2\<rbrakk> \<Longrightarrow> \<Turnstile>  Seq v1 v2 : SEQ r1 r2"
 | "\<Turnstile> v1 : r1 \<Longrightarrow> \<Turnstile> Left v1 : ALT r1 r2"
 | "\<Turnstile> v2 : r2 \<Longrightarrow> \<Turnstile> Right v2 : ALT r1 r2"
 | "\<Turnstile> Void : ONE"
-| "\<Turnstile> Char c : CHAR c"
+| "\<Turnstile> Char c : CH c"
 | "\<forall>v \<in> set vs. \<Turnstile> v : r \<and> flat v \<noteq> [] \<Longrightarrow> \<Turnstile> Stars vs : STAR r"
 inductive_cases Prf_elims:
 "\<Turnstile> v : ZERO"
 "\<Turnstile> v : SEQ r1 r2"
 "\<Turnstile> v : ALT r1 r2"
 "\<Turnstile> v : ONE"
-"\<Turnstile> v : CHAR c"
+"\<Turnstile> v : CH c"
 "\<Turnstile> vs : STAR r"
 lemma Prf_Stars_appendE:
 assumes "\<Turnstile> Stars (vs1 @ vs2) : STAR r"
 shows "\<Turnstile> Stars vs1 : STAR r \<and> \<Turnstile> Stars vs2 : STAR r"
 shows "L(r) = {flat v | v. \<Turnstile> v : r}"
 using L_flat_Prf1 L_flat_Prf2 by blast
-section {* Sets of Lexical Values *}
+section \<open>Sets of Lexical Values\<close>
-text {*
+text \<open>
 Shows that lexical values are finite for a given regex and string.
-*}
+\<close>
 definition
 LV :: "rexp \<Rightarrow> string \<Rightarrow> val set"
 where  "LV r s \<equiv> {v. \<Turnstile> v : r \<and> flat v = s}"
 lemma LV_simps:
 shows "LV ZERO s = {}"
 and   "LV ONE s = (if s = [] then {Void} else {})"
-and   "LV (CHAR c) s = (if s = [c] then {Char c} else {})"
+and   "LV (CH c) s = (if s = [c] then {Char c} else {})"
 and   "LV (ALT r1 r2) s = Left ` LV r1 s \<union> Right ` LV r2 s"
 unfolding LV_def
 by (auto intro: Prf.intros elim: Prf.cases)
 show "finite (LV ZERO s)" by (simp add: LV_simps)
 next
 case (ONE s)
 show "finite (LV ONE s)" by (simp add: LV_simps)
 next
-case (CHAR c s)
+case (CH c s)
-show "finite (LV (CHAR c) s)" by (simp add: LV_simps)
+show "finite (LV (CH c) s)" by (simp add: LV_simps)
 next
 case (ALT r1 r2 s)
 then show "finite (LV (ALT r1 r2) s)" by (simp add: LV_simps)
 next
 case (SEQ r1 r2 s)
 then show "finite (LV (STAR r) s)" by (simp add: LV_STAR_finite)
 qed
-section {* Our inductive POSIX Definition *}
+section \<open>Our inductive POSIX Definition\<close>
 inductive
 Posix :: "string \<Rightarrow> rexp \<Rightarrow> val \<Rightarrow> bool" ("_ \<in> _ \<rightarrow> _" [100, 100, 100] 100)
 where
 Posix_ONE: "[] \<in> ONE \<rightarrow> Void"
-| Posix_CHAR: "[c] \<in> (CHAR c) \<rightarrow> (Char c)"
+| Posix_CH: "[c] \<in> (CH c) \<rightarrow> (Char c)"
 | Posix_ALT1: "s \<in> r1 \<rightarrow> v \<Longrightarrow> s \<in> (ALT r1 r2) \<rightarrow> (Left v)"
 | Posix_ALT2: "\<lbrakk>s \<in> r2 \<rightarrow> v; s \<notin> L(r1)\<rbrakk> \<Longrightarrow> s \<in> (ALT r1 r2) \<rightarrow> (Right v)"
 | Posix_SEQ: "\<lbrakk>s1 \<in> r1 \<rightarrow> v1; s2 \<in> r2 \<rightarrow> v2;
 \<not>(\<exists>s\<^sub>3 s\<^sub>4. s\<^sub>3 \<noteq> [] \<and> s\<^sub>3 @ s\<^sub>4 = s2 \<and> (s1 @ s\<^sub>3) \<in> L r1 \<and> s\<^sub>4 \<in> L r2)\<rbrakk> \<Longrightarrow>
 (s1 @ s2) \<in> (SEQ r1 r2) \<rightarrow> (Seq v1 v2)"
 | Posix_STAR2: "[] \<in> STAR r \<rightarrow> Stars []"
 inductive_cases Posix_elims:
 "s \<in> ZERO \<rightarrow> v"
 "s \<in> ONE \<rightarrow> v"
-"s \<in> CHAR c \<rightarrow> v"
+"s \<in> CH c \<rightarrow> v"
 "s \<in> ALT r1 r2 \<rightarrow> v"
 "s \<in> SEQ r1 r2 \<rightarrow> v"
 "s \<in> STAR r \<rightarrow> v"
 lemma Posix1:
 assumes "s \<in> r \<rightarrow> v"
 shows "s \<in> L r" "flat v = s"
 using assms
-by (induct s r v rule: Posix.induct)
+by(induct s r v rule: Posix.induct)
 (auto simp add: Sequ_def)
-text {*
+text \<open>
 For a give value and string, our Posix definition
 determines a unique value.
-*}
+\<close>
 lemma Posix_determ:
 assumes "s \<in> r \<rightarrow> v1" "s \<in> r \<rightarrow> v2"
 shows "v1 = v2"
 using assms
 proof (induct s r v1 arbitrary: v2 rule: Posix.induct)
 case (Posix_ONE v2)
 have "[] \<in> ONE \<rightarrow> v2" by fact
 then show "Void = v2" by cases auto
 next
-case (Posix_CHAR c v2)
+case (Posix_CH c v2)
-have "[c] \<in> CHAR c \<rightarrow> v2" by fact
+have "[c] \<in> CH c \<rightarrow> v2" by fact
 then show "Char c = v2" by cases auto
 next
 case (Posix_ALT1 s r1 v r2 v2)
 have "s \<in> ALT r1 r2 \<rightarrow> v2" by fact
 moreover
 have "[] \<in> STAR r \<rightarrow> v2" by fact
 then show "Stars [] = v2" by cases (auto simp add: Posix1)
 qed
-text {*
+text \<open>
 Our POSIX values are lexical values.
-*}
+\<close>
 lemma Posix_LV:
 assumes "s \<in> r \<rightarrow> v"
 shows "v \<in> LV r s"
 using assms unfolding LV_def

changeset 361	8bb064045b4e
parent 359	fedc16924b76
child 365	ec5e4fe4cc70