diff -r d2ed455fa3d2 -r 7b6beb7e99c1 src/HOL/Library/List_Prefix.thy --- a/src/HOL/Library/List_Prefix.thy Mon Sep 03 11:54:21 2012 +0200 +++ /dev/null Thu Jan 01 00:00:00 1970 +0000 @@ -1,382 +0,0 @@ -(* Title: HOL/Library/List_Prefix.thy - Author: Tobias Nipkow and Markus Wenzel, TU Muenchen -*) - -header {* List prefixes and postfixes *} - -theory List_Prefix -imports List Main -begin - -subsection {* Prefix order on lists *} - -instantiation list :: (type) "{order, bot}" -begin - -definition - prefix_def: "xs \ ys \ (\zs. ys = xs @ zs)" - -definition - strict_prefix_def: "xs < ys \ xs \ ys \ xs \ (ys::'a list)" - -definition - "bot = []" - -instance proof -qed (auto simp add: prefix_def strict_prefix_def bot_list_def) - -end - -lemma prefixI [intro?]: "ys = xs @ zs ==> xs \ ys" - unfolding prefix_def by blast - -lemma prefixE [elim?]: - assumes "xs \ ys" - obtains zs where "ys = xs @ zs" - using assms unfolding prefix_def by blast - -lemma strict_prefixI' [intro?]: "ys = xs @ z # zs ==> xs < ys" - unfolding strict_prefix_def prefix_def by blast - -lemma strict_prefixE' [elim?]: - assumes "xs < ys" - obtains z zs where "ys = xs @ z # zs" -proof - - from `xs < ys` obtain us where "ys = xs @ us" and "xs \ ys" - unfolding strict_prefix_def prefix_def by blast - with that show ?thesis by (auto simp add: neq_Nil_conv) -qed - -lemma strict_prefixI [intro?]: "xs \ ys ==> xs \ ys ==> xs < (ys::'a list)" - unfolding strict_prefix_def by blast - -lemma strict_prefixE [elim?]: - fixes xs ys :: "'a list" - assumes "xs < ys" - obtains "xs \ ys" and "xs \ ys" - using assms unfolding strict_prefix_def by blast - - -subsection {* Basic properties of prefixes *} - -theorem Nil_prefix [iff]: "[] \ xs" - by (simp add: prefix_def) - -theorem prefix_Nil [simp]: "(xs \ []) = (xs = [])" - by (induct xs) (simp_all add: prefix_def) - -lemma prefix_snoc [simp]: "(xs \ ys @ [y]) = (xs = ys @ [y] \ xs \ ys)" -proof - assume "xs \ ys @ [y]" - then obtain zs where zs: "ys @ [y] = xs @ zs" .. - show "xs = ys @ [y] \ xs \ ys" - by (metis append_Nil2 butlast_append butlast_snoc prefixI zs) -next - assume "xs = ys @ [y] \ xs \ ys" - then show "xs \ ys @ [y]" - by (metis order_eq_iff order_trans prefixI) -qed - -lemma Cons_prefix_Cons [simp]: "(x # xs \ y # ys) = (x = y \ xs \ ys)" - by (auto simp add: prefix_def) - -lemma less_eq_list_code [code]: - "([]\'a\{equal, ord} list) \ xs \ True" - "(x\'a\{equal, ord}) # xs \ [] \ False" - "(x\'a\{equal, ord}) # xs \ y # ys \ x = y \ xs \ ys" - by simp_all - -lemma same_prefix_prefix [simp]: "(xs @ ys \ xs @ zs) = (ys \ zs)" - by (induct xs) simp_all - -lemma same_prefix_nil [iff]: "(xs @ ys \ xs) = (ys = [])" - by (metis append_Nil2 append_self_conv order_eq_iff prefixI) - -lemma prefix_prefix [simp]: "xs \ ys ==> xs \ ys @ zs" - by (metis order_le_less_trans prefixI strict_prefixE strict_prefixI) - -lemma append_prefixD: "xs @ ys \ zs \ xs \ zs" - by (auto simp add: prefix_def) - -theorem prefix_Cons: "(xs \ y # ys) = (xs = [] \ (\zs. xs = y # zs \ zs \ ys))" - by (cases xs) (auto simp add: prefix_def) - -theorem prefix_append: - "(xs \ ys @ zs) = (xs \ ys \ (\us. xs = ys @ us \ us \ zs))" - apply (induct zs rule: rev_induct) - apply force - apply (simp del: append_assoc add: append_assoc [symmetric]) - apply (metis append_eq_appendI) - done - -lemma append_one_prefix: - "xs \ ys ==> length xs < length ys ==> xs @ [ys ! length xs] \ ys" - unfolding prefix_def - by (metis Cons_eq_appendI append_eq_appendI append_eq_conv_conj - eq_Nil_appendI nth_drop') - -theorem prefix_length_le: "xs \ ys ==> length xs \ length ys" - by (auto simp add: prefix_def) - -lemma prefix_same_cases: - "(xs\<^isub>1::'a list) \ ys \ xs\<^isub>2 \ ys \ xs\<^isub>1 \ xs\<^isub>2 \ xs\<^isub>2 \ xs\<^isub>1" - unfolding prefix_def by (metis append_eq_append_conv2) - -lemma set_mono_prefix: "xs \ ys \ set xs \ set ys" - by (auto simp add: prefix_def) - -lemma take_is_prefix: "take n xs \ xs" - unfolding prefix_def by (metis append_take_drop_id) - -lemma map_prefixI: "xs \ ys \ map f xs \ map f ys" - by (auto simp: prefix_def) - -lemma prefix_length_less: "xs < ys \ length xs < length ys" - by (auto simp: strict_prefix_def prefix_def) - -lemma strict_prefix_simps [simp, code]: - "xs < [] \ False" - "[] < x # xs \ True" - "x # xs < y # ys \ x = y \ xs < ys" - by (simp_all add: strict_prefix_def cong: conj_cong) - -lemma take_strict_prefix: "xs < ys \ take n xs < ys" - apply (induct n arbitrary: xs ys) - apply (case_tac ys, simp_all)[1] - apply (metis order_less_trans strict_prefixI take_is_prefix) - done - -lemma not_prefix_cases: - assumes pfx: "\ ps \ ls" - obtains - (c1) "ps \ []" and "ls = []" - | (c2) a as x xs where "ps = a#as" and "ls = x#xs" and "x = a" and "\ as \ xs" - | (c3) a as x xs where "ps = a#as" and "ls = x#xs" and "x \ a" -proof (cases ps) - case Nil then show ?thesis using pfx by simp -next - case (Cons a as) - note c = `ps = a#as` - show ?thesis - proof (cases ls) - case Nil then show ?thesis by (metis append_Nil2 pfx c1 same_prefix_nil) - next - case (Cons x xs) - show ?thesis - proof (cases "x = a") - case True - have "\ as \ xs" using pfx c Cons True by simp - with c Cons True show ?thesis by (rule c2) - next - case False - with c Cons show ?thesis by (rule c3) - qed - qed -qed - -lemma not_prefix_induct [consumes 1, case_names Nil Neq Eq]: - assumes np: "\ ps \ ls" - and base: "\x xs. P (x#xs) []" - and r1: "\x xs y ys. x \ y \ P (x#xs) (y#ys)" - and r2: "\x xs y ys. \ x = y; \ xs \ ys; P xs ys \ \ P (x#xs) (y#ys)" - shows "P ps ls" using np -proof (induct ls arbitrary: ps) - case Nil then show ?case - by (auto simp: neq_Nil_conv elim!: not_prefix_cases intro!: base) -next - case (Cons y ys) - then have npfx: "\ ps \ (y # ys)" by simp - then obtain x xs where pv: "ps = x # xs" - by (rule not_prefix_cases) auto - show ?case by (metis Cons.hyps Cons_prefix_Cons npfx pv r1 r2) -qed - - -subsection {* Parallel lists *} - -definition - parallel :: "'a list => 'a list => bool" (infixl "\" 50) where - "(xs \ ys) = (\ xs \ ys \ \ ys \ xs)" - -lemma parallelI [intro]: "\ xs \ ys ==> \ ys \ xs ==> xs \ ys" - unfolding parallel_def by blast - -lemma parallelE [elim]: - assumes "xs \ ys" - obtains "\ xs \ ys \ \ ys \ xs" - using assms unfolding parallel_def by blast - -theorem prefix_cases: - obtains "xs \ ys" | "ys < xs" | "xs \ ys" - unfolding parallel_def strict_prefix_def by blast - -theorem parallel_decomp: - "xs \ ys ==> \as b bs c cs. b \ c \ xs = as @ b # bs \ ys = as @ c # cs" -proof (induct xs rule: rev_induct) - case Nil - then have False by auto - then show ?case .. -next - case (snoc x xs) - show ?case - proof (rule prefix_cases) - assume le: "xs \ ys" - then obtain ys' where ys: "ys = xs @ ys'" .. - show ?thesis - proof (cases ys') - assume "ys' = []" - then show ?thesis by (metis append_Nil2 parallelE prefixI snoc.prems ys) - next - fix c cs assume ys': "ys' = c # cs" - then show ?thesis - by (metis Cons_eq_appendI eq_Nil_appendI parallelE prefixI - same_prefix_prefix snoc.prems ys) - qed - next - assume "ys < xs" then have "ys \ xs @ [x]" by (simp add: strict_prefix_def) - with snoc have False by blast - then show ?thesis .. - next - assume "xs \ ys" - with snoc obtain as b bs c cs where neq: "(b::'a) \ c" - and xs: "xs = as @ b # bs" and ys: "ys = as @ c # cs" - by blast - from xs have "xs @ [x] = as @ b # (bs @ [x])" by simp - with neq ys show ?thesis by blast - qed -qed - -lemma parallel_append: "a \ b \ a @ c \ b @ d" - apply (rule parallelI) - apply (erule parallelE, erule conjE, - induct rule: not_prefix_induct, simp+)+ - done - -lemma parallel_appendI: "xs \ ys \ x = xs @ xs' \ y = ys @ ys' \ x \ y" - by (simp add: parallel_append) - -lemma parallel_commute: "a \ b \ b \ a" - unfolding parallel_def by auto - - -subsection {* Postfix order on lists *} - -definition - postfix :: "'a list => 'a list => bool" ("(_/ >>= _)" [51, 50] 50) where - "(xs >>= ys) = (\zs. xs = zs @ ys)" - -lemma postfixI [intro?]: "xs = zs @ ys ==> xs >>= ys" - unfolding postfix_def by blast - -lemma postfixE [elim?]: - assumes "xs >>= ys" - obtains zs where "xs = zs @ ys" - using assms unfolding postfix_def by blast - -lemma postfix_refl [iff]: "xs >>= xs" - by (auto simp add: postfix_def) -lemma postfix_trans: "\xs >>= ys; ys >>= zs\ \ xs >>= zs" - by (auto simp add: postfix_def) -lemma postfix_antisym: "\xs >>= ys; ys >>= xs\ \ xs = ys" - by (auto simp add: postfix_def) - -lemma Nil_postfix [iff]: "xs >>= []" - by (simp add: postfix_def) -lemma postfix_Nil [simp]: "([] >>= xs) = (xs = [])" - by (auto simp add: postfix_def) - -lemma postfix_ConsI: "xs >>= ys \ x#xs >>= ys" - by (auto simp add: postfix_def) -lemma postfix_ConsD: "xs >>= y#ys \ xs >>= ys" - by (auto simp add: postfix_def) - -lemma postfix_appendI: "xs >>= ys \ zs @ xs >>= ys" - by (auto simp add: postfix_def) -lemma postfix_appendD: "xs >>= zs @ ys \ xs >>= ys" - by (auto simp add: postfix_def) - -lemma postfix_is_subset: "xs >>= ys ==> set ys \ set xs" -proof - - assume "xs >>= ys" - then obtain zs where "xs = zs @ ys" .. - then show ?thesis by (induct zs) auto -qed - -lemma postfix_ConsD2: "x#xs >>= y#ys ==> xs >>= ys" -proof - - assume "x#xs >>= y#ys" - then obtain zs where "x#xs = zs @ y#ys" .. - then show ?thesis - by (induct zs) (auto intro!: postfix_appendI postfix_ConsI) -qed - -lemma postfix_to_prefix [code]: "xs >>= ys \ rev ys \ rev xs" -proof - assume "xs >>= ys" - then obtain zs where "xs = zs @ ys" .. - then have "rev xs = rev ys @ rev zs" by simp - then show "rev ys <= rev xs" .. -next - assume "rev ys <= rev xs" - then obtain zs where "rev xs = rev ys @ zs" .. - then have "rev (rev xs) = rev zs @ rev (rev ys)" by simp - then have "xs = rev zs @ ys" by simp - then show "xs >>= ys" .. -qed - -lemma distinct_postfix: "distinct xs \ xs >>= ys \ distinct ys" - by (clarsimp elim!: postfixE) - -lemma postfix_map: "xs >>= ys \ map f xs >>= map f ys" - by (auto elim!: postfixE intro: postfixI) - -lemma postfix_drop: "as >>= drop n as" - unfolding postfix_def - apply (rule exI [where x = "take n as"]) - apply simp - done - -lemma postfix_take: "xs >>= ys \ xs = take (length xs - length ys) xs @ ys" - by (clarsimp elim!: postfixE) - -lemma parallelD1: "x \ y \ \ x \ y" - by blast - -lemma parallelD2: "x \ y \ \ y \ x" - by blast - -lemma parallel_Nil1 [simp]: "\ x \ []" - unfolding parallel_def by simp - -lemma parallel_Nil2 [simp]: "\ [] \ x" - unfolding parallel_def by simp - -lemma Cons_parallelI1: "a \ b \ a # as \ b # bs" - by auto - -lemma Cons_parallelI2: "\ a = b; as \ bs \ \ a # as \ b # bs" - by (metis Cons_prefix_Cons parallelE parallelI) - -lemma not_equal_is_parallel: - assumes neq: "xs \ ys" - and len: "length xs = length ys" - shows "xs \ ys" - using len neq -proof (induct rule: list_induct2) - case Nil - then show ?case by simp -next - case (Cons a as b bs) - have ih: "as \ bs \ as \ bs" by fact - show ?case - proof (cases "a = b") - case True - then have "as \ bs" using Cons by simp - then show ?thesis by (rule Cons_parallelI2 [OF True ih]) - next - case False - then show ?thesis by (rule Cons_parallelI1) - qed -qed - -end