theory Positions

  imports "Lexer" 

begin

section {* Position in values *}

fun 

  at :: "val \<Rightarrow> nat list \<Rightarrow> val"

where

  "at v [] = v"

| "at (Left v) (0#ps)= at v ps"

| "at (Right v) (Suc 0#ps)= at v ps"

| "at (Seq v1 v2) (0#ps)= at v1 ps"

| "at (Seq v1 v2) (Suc 0#ps)= at v2 ps"

| "at (Stars vs) (n#ps)= at (nth vs n) ps"

fun Pos :: "val \<Rightarrow> (nat list) set"

where

  "Pos (Void) = {[]}"

| "Pos (Char c) = {[]}"

| "Pos (Left v) = {[]} \<union> {0#ps | ps. ps \<in> Pos v}"

| "Pos (Right v) = {[]} \<union> {1#ps | ps. ps \<in> Pos v}"

| "Pos (Seq v1 v2) = {[]} \<union> {0#ps | ps. ps \<in> Pos v1} \<union> {1#ps | ps. ps \<in> Pos v2}" 

| "Pos (Stars []) = {[]}"

| "Pos (Stars (v#vs)) = {[]} \<union> {0#ps | ps. ps \<in> Pos v} \<union> {Suc n#ps | n ps. n#ps \<in> Pos (Stars vs)}"

lemma Pos_stars:

  "Pos (Stars vs) = {[]} \<union> (\<Union>n < length vs. {n#ps | ps. ps \<in> Pos (vs ! n)})"

apply(induct vs)

apply(simp) 

apply(simp)

apply(simp add: insert_ident)

apply(rule subset_antisym)

apply(auto)

apply(auto)[1]

using less_Suc_eq_0_disj by auto

lemma Pos_empty:

  shows "[] \<in> Pos v"

by (induct v rule: Pos.induct)(auto)

fun intlen :: "'a list \<Rightarrow> int"

where

  "intlen [] = 0"

| "intlen (x#xs) = 1 + intlen xs"

  shows "0 \<le> intlen xs"

by (induct xs)(auto)

lemma intlen_append:

  shows "intlen (xs @ ys) = intlen xs + intlen ys"

by (induct xs arbitrary: ys) (auto)

lemma intlen_length:

  assumes "length xs < length ys"

  shows "intlen xs < intlen ys"

using assms

apply(induct xs arbitrary: ys)

apply(auto)

apply(case_tac ys)

apply(simp_all)

by (smt Suc_lessE intlen.simps(2) length_Suc_conv)

definition pflat_len :: "val \<Rightarrow> nat list => int"

where

  "pflat_len v p \<equiv> (if p \<in> Pos v then intlen (flat (at v p)) else -1)"

lemma pflat_len_simps:

  shows "pflat_len (Seq v1 v2) (0#p) = pflat_len v1 p"

  and   "pflat_len (Seq v1 v2) (Suc 0#p) = pflat_len v2 p"

  and   "pflat_len (Left v) (0#p) = pflat_len v p"

  and   "pflat_len (Left v) (Suc 0#p) = -1"

  and   "pflat_len (Right v) (Suc 0#p) = pflat_len v p"

  and   "pflat_len (Right v) (0#p) = -1"

  and   "pflat_len (Stars (v#vs)) (Suc n#p) = pflat_len (Stars vs) (n#p)"

  and   "pflat_len (Stars (v#vs)) (0#p) = pflat_len v p"

  and   "pflat_len v [] = intlen (flat v)"

by (auto simp add: pflat_len_def Pos_empty)

lemma pflat_len_Stars_simps:

  assumes "n < length vs"

  shows "pflat_len (Stars vs) (n#p) = pflat_len (vs!n) p"

using assms 

apply(induct vs arbitrary: n p)

apply(auto simp add: less_Suc_eq_0_disj pflat_len_simps)

done

lemma outside_lemma:

  assumes "p \<notin> Pos v1 \<union> Pos v2"

  shows "pflat_len v1 p = pflat_len v2 p"

using assms by (auto simp add: pflat_len_def)

section {* Orderings *}

definition prefix_list:: "'a list \<Rightarrow> 'a list \<Rightarrow> bool" ("_ \<sqsubseteq>pre _")

where

  "ps1 \<sqsubseteq>pre ps2 \<equiv> \<exists>ps'. ps1 @ps' = ps2"

definition sprefix_list:: "'a list \<Rightarrow> 'a list \<Rightarrow> bool" ("_ \<sqsubset>spre _")

where

  "ps1 \<sqsubset>spre ps2 \<equiv> ps1 \<sqsubseteq>pre ps2 \<and> ps1 \<noteq> ps2"

inductive lex_list :: "nat list \<Rightarrow> nat list \<Rightarrow> bool" ("_ \<sqsubset>lex _")

where

  "[] \<sqsubset>lex (p#ps)"

| "ps1 \<sqsubset>lex ps2 \<Longrightarrow> (p#ps1) \<sqsubset>lex (p#ps2)"

| "p1 < p2 \<Longrightarrow> (p1#ps1) \<sqsubset>lex (p2#ps2)"

lemma lex_irrfl:

  fixes ps1 ps2 :: "nat list"

  assumes "ps1 \<sqsubset>lex ps2"

  shows "ps1 \<noteq> ps2"

using assms

apply(induct rule: lex_list.induct)

apply(auto)

done

lemma lex_simps [simp]:

  fixes xs ys :: "nat list"

  shows "[] \<sqsubset>lex ys \<longleftrightarrow> ys \<noteq> []"

  and   "xs \<sqsubset>lex [] \<longleftrightarrow> False"

  and   "(x # xs) \<sqsubset>lex (y # ys) \<longleftrightarrow> (x < y \<or> (\<not> y < x \<and> xs \<sqsubset>lex ys))"

apply -

apply (metis lex_irrfl lex_list.intros(1) list.exhaust)

using lex_list.cases apply blast

using lex_list.cases lex_list.intros(2) lex_list.intros(3) not_less_iff_gr_or_eq by fastforce

lemma lex_trans:

  fixes ps1 ps2 ps3 :: "nat list"

  assumes "ps1 \<sqsubset>lex ps2" "ps2 \<sqsubset>lex ps3"

  shows "ps1 \<sqsubset>lex ps3"

using assms

apply(induct arbitrary: ps3 rule: lex_list.induct)

apply(erule lex_list.cases)

apply(simp_all)

apply(rotate_tac 2)

apply(erule lex_list.cases)

apply(simp_all)

apply(erule lex_list.cases)

apply(simp_all)

done

lemma trichotomous:

  fixes p q :: "nat list"

  shows "p = q \<or> p \<sqsubset>lex q \<or> q \<sqsubset>lex p"

apply(induct p arbitrary: q)

apply(auto)

apply(case_tac q)

apply(auto)

done

section {* Ordering of values according to Okui & Suzuki *}

definition val_ord:: "val \<Rightarrow> nat list \<Rightarrow> val \<Rightarrow> bool" ("_ \<sqsubset>val _ _")

where

  "v1 \<sqsubset>val p v2 \<equiv> (p \<in> Pos v1 \<and> 

                    pflat_len v1 p > pflat_len v2 p \<and>

                   (\<forall>q \<in> Pos v1 \<union> Pos v2. q \<sqsubset>lex p \<longrightarrow> pflat_len v1 q = pflat_len v2 q))"

definition val_ord_ex:: "val \<Rightarrow> val \<Rightarrow> bool" ("_ :\<sqsubset>val _")

where

  "v1 :\<sqsubset>val v2 \<equiv> (\<exists>p. v1 \<sqsubset>val p v2)"

definition val_ord_ex1:: "val \<Rightarrow> val \<Rightarrow> bool" ("_ :\<sqsubseteq>val _")

where

  "v1 :\<sqsubseteq>val v2 \<equiv> v1 :\<sqsubset>val v2 \<or> v1 = v2"

lemma val_ord_shorterI:

  assumes "length (flat v') < length (flat v)"

  shows "v :\<sqsubset>val v'" 

using assms

unfolding val_ord_ex_def

by (metis Pos_empty intlen_length lex_simps(2) pflat_len_simps(9) val_ord_def)

lemma val_ord_spreI:

  assumes "(flat v') \<sqsubset>spre (flat v)"

  shows "v :\<sqsubset>val v'" 

using assms

apply(rule_tac val_ord_shorterI)

by (metis append_eq_conv_conj le_less_linear prefix_list_def sprefix_list_def take_all)

lemma val_ord_LeftI:

  assumes "v :\<sqsubset>val v'" "flat v = flat v'"

  shows "(Left v) :\<sqsubset>val (Left v')" 

using assms(1)

unfolding val_ord_ex_def

apply(auto)

apply(rule_tac x="0#p" in exI)

using assms(2)

apply(auto simp add: val_ord_def pflat_len_simps)

done

lemma val_ord_RightI:

  assumes "v :\<sqsubset>val v'" "flat v = flat v'"

  shows "(Right v) :\<sqsubset>val (Right v')" 

using assms(1)

unfolding val_ord_ex_def

apply(auto)

apply(rule_tac x="Suc 0#p" in exI)

using assms(2)

apply(auto simp add: val_ord_def pflat_len_simps)

done

lemma val_ord_LeftE:

  assumes "(Left v1) :\<sqsubset>val (Left v2)"

  shows "v1 :\<sqsubset>val v2"

using assms

apply(simp add: val_ord_ex_def)

apply(erule exE)

apply(case_tac "p = []")

apply(simp add: val_ord_def)

apply(auto simp add: pflat_len_simps)

apply(rule_tac x="[]" in exI)

apply(simp add: Pos_empty pflat_len_simps)

apply(auto simp add: pflat_len_simps val_ord_def)

apply(rule_tac x="ps" in exI)

apply(auto)

apply(drule_tac x="0#q" in bspec)

apply(simp)

apply(simp add: pflat_len_simps)

apply(drule_tac x="0#q" in bspec)

apply(simp)

apply(simp add: pflat_len_simps)

done

lemma val_ord_RightE:

  assumes "(Right v1) :\<sqsubset>val (Right v2)"

  shows "v1 :\<sqsubset>val v2"

using assms

apply(simp add: val_ord_ex_def)

apply(erule exE)

apply(case_tac "p = []")

apply(simp add: val_ord_def)

apply(auto simp add: pflat_len_simps)

apply(rule_tac x="[]" in exI)

apply(simp add: Pos_empty pflat_len_simps)

apply(auto simp add: pflat_len_simps val_ord_def)

apply(rule_tac x="ps" in exI)

apply(auto)

apply(drule_tac x="Suc 0#q" in bspec)

apply(simp)

apply(simp add: pflat_len_simps)

apply(drule_tac x="Suc 0#q" in bspec)

apply(simp)

apply(simp add: pflat_len_simps)

done

lemma val_ord_SeqI1:

  assumes "v1 :\<sqsubset>val v1'" "flat (Seq v1 v2) = flat (Seq v1' v2')"

  shows "(Seq v1 v2) :\<sqsubset>val (Seq v1' v2')" 

using assms(1)

apply(subst (asm) val_ord_ex_def)

apply(subst (asm) val_ord_def)

apply(clarify)

apply(subst val_ord_ex_def)

apply(rule_tac x="0#p" in exI)

apply(subst val_ord_def)

apply(rule conjI)

apply(simp)

apply(rule conjI)

apply(simp add: pflat_len_simps)

apply(rule ballI)

apply(rule impI)

apply(simp only: Pos.simps)

apply(auto)[1]

apply(simp add: pflat_len_simps)

using assms(2)

apply(simp)

apply(auto simp add: pflat_len_simps)[2]

done

lemma val_ord_SeqI2:

  assumes "v2 :\<sqsubset>val v2'" "flat v2 = flat v2'"

  shows "(Seq v v2) :\<sqsubset>val (Seq v v2')" 

using assms(1)

apply(subst (asm) val_ord_ex_def)

apply(subst (asm) val_ord_def)

apply(clarify)

apply(subst val_ord_ex_def)

apply(rule_tac x="Suc 0#p" in exI)

apply(subst val_ord_def)

apply(rule conjI)

apply(simp)

apply(rule conjI)

apply(simp add: pflat_len_simps)

apply(rule ballI)

apply(rule impI)

apply(simp only: Pos.simps)

apply(auto)[1]

apply(simp add: pflat_len_simps)

using assms(2)

apply(simp)

apply(auto simp add: pflat_len_simps)

done

lemma val_ord_SeqE:

  assumes "(Seq v1 v2) :\<sqsubset>val (Seq v1' v2')" 

  shows "v1 :\<sqsubset>val v1' \<or> v2 :\<sqsubset>val v2'"

using assms

apply(simp add: val_ord_ex_def)

apply(erule exE)

apply(case_tac p)

apply(simp add: val_ord_def)

apply(auto simp add: pflat_len_simps intlen_append)[1]

apply(rule_tac x="[]" in exI)

apply(drule_tac x="[]" in spec)

apply(simp add: Pos_empty pflat_len_simps)

apply(case_tac a)

apply(rule disjI1)

apply(simp add: val_ord_def)

apply(auto simp add: pflat_len_simps intlen_append)[1]

apply(rule_tac x="list" in exI)

apply(simp)

apply(rule ballI)

apply(rule impI)

apply(drule_tac x="0#q" in bspec)

apply(simp)

apply(simp add: pflat_len_simps)

apply(case_tac nat)

apply(rule disjI2)

apply(simp add: val_ord_def)

apply(auto simp add: pflat_len_simps intlen_append)

apply(rule_tac x="list" in exI)

apply(simp add: Pos_empty)

apply(rule ballI)

apply(rule impI)

apply(drule_tac x="Suc 0#q" in bspec)

apply(simp)

apply(simp add: pflat_len_simps)

apply(simp add: val_ord_def)

done

lemma val_ord_StarsI:

  assumes "v1 :\<sqsubset>val v2" "flat (Stars (v1#vs1)) = flat (Stars (v2#vs2))"

  shows "(Stars (v1#vs1)) :\<sqsubset>val (Stars (v2#vs2))" 

using assms(1)

apply(subst (asm) val_ord_ex_def)

apply(subst (asm) val_ord_def)

apply(clarify)

apply(subst val_ord_ex_def)

apply(subst val_ord_def)

apply(rule_tac x="0#p" in exI)

apply(simp add: pflat_len_Stars_simps pflat_len_simps)

using assms(2)

apply(simp add: pflat_len_simps intlen_append)

apply(auto simp add: pflat_len_Stars_simps pflat_len_simps)

done

lemma val_ord_StarsI2:

  assumes "(Stars vs1) :\<sqsubset>val (Stars vs2)" "flat (Stars vs1) = flat (Stars vs2)"

  shows "(Stars (v#vs1)) :\<sqsubset>val (Stars (v#vs2))" 

using assms(1)

apply(subst (asm) val_ord_ex_def)

apply(subst (asm) val_ord_def)

apply(clarify)

apply(subst val_ord_ex_def)

apply(subst val_ord_def)

apply(case_tac p)

apply(simp add: pflat_len_simps)

apply(rule_tac x="[]" in exI)

apply(simp add: pflat_len_Stars_simps pflat_len_simps intlen_append)

apply(rule_tac x="Suc a#list" in exI)

apply(simp add: pflat_len_Stars_simps pflat_len_simps)

using assms(2)

apply(simp add: pflat_len_simps intlen_append)

apply(auto simp add: pflat_len_Stars_simps pflat_len_simps)

done

lemma val_ord_Stars_appendI:

  assumes "Stars vs1 :\<sqsubset>val Stars vs2" "flat (Stars vs1) = flat (Stars vs2)"

  shows "Stars (vs @ vs1) :\<sqsubset>val Stars (vs @ vs2)"

using assms

apply(induct vs)

apply(simp)

apply(simp add: val_ord_StarsI2)

done

lemma val_ord_StarsE2:

  assumes "Stars (v # vs1) :\<sqsubset>val Stars (v # vs2)"

  shows "Stars vs1 :\<sqsubset>val Stars vs2"

using assms

apply(subst (asm) val_ord_ex_def)

apply(erule exE)

apply(case_tac p)

apply(simp)

apply(simp add: val_ord_def pflat_len_simps intlen_append)

apply(subst val_ord_ex_def)

apply(rule_tac x="[]" in exI)

apply(simp add: val_ord_def pflat_len_simps Pos_empty)

apply(simp)

apply(case_tac a)

apply(clarify)

apply(auto simp add: pflat_len_simps val_ord_def pflat_len_def)[1]

apply(clarify)

apply(simp add: val_ord_ex_def)

apply(rule_tac x="nat#list" in exI)

apply(auto simp add: val_ord_def pflat_len_simps intlen_append)[1]

apply(case_tac q)

apply(simp add: val_ord_def pflat_len_simps intlen_append)

apply(clarify)

apply(drule_tac x="Suc a # lista" in bspec)

apply(simp)

apply(auto simp add: val_ord_def pflat_len_simps intlen_append)[1]

apply(case_tac q)

apply(simp add: val_ord_def pflat_len_simps intlen_append)

apply(clarify)

apply(drule_tac x="Suc a # lista" in bspec)

apply(simp)

apply(auto simp add: val_ord_def pflat_len_simps intlen_append)[1]

done

lemma val_ord_Stars_appendE:

  assumes "Stars (vs @ vs1) :\<sqsubset>val Stars (vs @ vs2)"

  shows "Stars vs1 :\<sqsubset>val Stars vs2"

using assms

apply(induct vs)

apply(simp)

apply(simp add: val_ord_StarsE2)

done

lemma val_ord_Stars_append_eq:

  assumes "flat (Stars vs1) = flat (Stars vs2)"

  shows "Stars (vs @ vs1) :\<sqsubset>val Stars (vs @ vs2) \<longleftrightarrow> Stars vs1 :\<sqsubset>val Stars vs2"

using assms

apply(rule_tac iffI)

apply(erule val_ord_Stars_appendE)

apply(rule val_ord_Stars_appendI)

apply(auto)

done

lemma val_ord_trans:

  assumes "v1 :\<sqsubset>val v2" "v2 :\<sqsubset>val v3"

  shows "v1 :\<sqsubset>val v3"

using assms

unfolding val_ord_ex_def

apply(clarify)

apply(subgoal_tac "p = pa \<or> p \<sqsubset>lex pa \<or> pa \<sqsubset>lex p")

prefer 2

apply(rule trichotomous)

apply(erule disjE)

apply(simp)

apply(rule_tac x="pa" in exI)

apply(subst val_ord_def)

apply(rule conjI)

apply(simp add: val_ord_def)

apply(auto)[1]

apply(simp add: val_ord_def)

apply(simp add: val_ord_def)

apply(auto)[1]

using outside_lemma apply blast

apply(simp add: val_ord_def)

apply(auto)[1]

using outside_lemma apply force

apply auto[1]

apply(simp add: val_ord_def)

apply(auto)[1]

apply (metis (no_types, hide_lams) lex_trans outside_lemma)

apply(simp add: val_ord_def)

apply(auto)[1]