(* Title: HOL/List.thy
ID: $Id$
Author: Tobias Nipkow
*)
header {* The datatype of finite lists *}
theory List
imports PreList
begin
datatype 'a list =
Nil ("[]")
| Cons 'a "'a list" (infixr "#" 65)
subsection{*Basic list processing functions*}
consts
"@" :: "'a list => 'a list => 'a list" (infixr 65)
filter:: "('a => bool) => 'a list => 'a list"
concat:: "'a list list => 'a list"
foldl :: "('b => 'a => 'b) => 'b => 'a list => 'b"
foldr :: "('a => 'b => 'b) => 'a list => 'b => 'b"
hd:: "'a list => 'a"
tl:: "'a list => 'a list"
last:: "'a list => 'a"
butlast :: "'a list => 'a list"
set :: "'a list => 'a set"
list_all2 :: "('a => 'b => bool) => 'a list => 'b list => bool"
map :: "('a=>'b) => ('a list => 'b list)"
nth :: "'a list => nat => 'a" (infixl "!" 100)
list_update :: "'a list => nat => 'a => 'a list"
take:: "nat => 'a list => 'a list"
drop:: "nat => 'a list => 'a list"
takeWhile :: "('a => bool) => 'a list => 'a list"
dropWhile :: "('a => bool) => 'a list => 'a list"
rev :: "'a list => 'a list"
zip :: "'a list => 'b list => ('a * 'b) list"
upt :: "nat => nat => nat list" ("(1[_..</_'])")
remdups :: "'a list => 'a list"
remove1 :: "'a => 'a list => 'a list"
null:: "'a list => bool"
"distinct":: "'a list => bool"
replicate :: "nat => 'a => 'a list"
rotate1 :: "'a list \<Rightarrow> 'a list"
rotate :: "nat \<Rightarrow> 'a list \<Rightarrow> 'a list"
splice :: "'a list \<Rightarrow> 'a list \<Rightarrow> 'a list"
sublist :: "'a list => nat set => 'a list"
(* For efficiency *)
mem :: "'a => 'a list => bool" (infixl 55)
list_inter :: "'a list \<Rightarrow> 'a list \<Rightarrow> 'a list"
list_ex :: "('a \<Rightarrow> bool) \<Rightarrow> 'a list \<Rightarrow> bool"
list_all:: "('a => bool) => ('a list => bool)"
itrev :: "'a list \<Rightarrow> 'a list \<Rightarrow> 'a list"
filtermap :: "('a \<Rightarrow> 'b option) \<Rightarrow> 'a list \<Rightarrow> 'b list"
map_filter :: "('a => 'b) => ('a => bool) => 'a list => 'b list"
abbreviation
upto:: "nat => nat => nat list" ("(1[_../_])")
"[i..j] == [i..<(Suc j)]"
nonterminals lupdbinds lupdbind
syntax
-- {* list Enumeration *}
"@list" :: "args => 'a list" ("[(_)]")
-- {* Special syntax for filter *}
"@filter" :: "[pttrn, 'a list, bool] => 'a list" ("(1[_:_./ _])")
-- {* list update *}
"_lupdbind":: "['a, 'a] => lupdbind" ("(2_ :=/ _)")
"" :: "lupdbind => lupdbinds" ("_")
"_lupdbinds" :: "[lupdbind, lupdbinds] => lupdbinds" ("_,/ _")
"_LUpdate" :: "['a, lupdbinds] => 'a" ("_/[(_)]" [900,0] 900)
translations
"[x, xs]" == "x#[xs]"
"[x]" == "x#[]"
"[x:xs . P]"== "filter (%x. P) xs"
"_LUpdate xs (_lupdbinds b bs)"== "_LUpdate (_LUpdate xs b) bs"
"xs[i:=x]" == "list_update xs i x"
syntax (xsymbols)
"@filter" :: "[pttrn, 'a list, bool] => 'a list"("(1[_\<in>_ ./ _])")
syntax (HTML output)
"@filter" :: "[pttrn, 'a list, bool] => 'a list"("(1[_\<in>_ ./ _])")
text {*
Function @{text size} is overloaded for all datatypes. Users may
refer to the list version as @{text length}. *}
abbreviation
length :: "'a list => nat"
"length == size"
primrec
"hd(x#xs) = x"
primrec
"tl([]) = []"
"tl(x#xs) = xs"
primrec
"null([]) = True"
"null(x#xs) = False"
primrec
"last(x#xs) = (if xs=[] then x else last xs)"
primrec
"butlast []= []"
"butlast(x#xs) = (if xs=[] then [] else x#butlast xs)"
primrec
"set [] = {}"
"set (x#xs) = insert x (set xs)"
primrec
"map f [] = []"
"map f (x#xs) = f(x)#map f xs"
primrec
append_Nil:"[]@ys = ys"
append_Cons: "(x#xs)@ys = x#(xs@ys)"
primrec
"rev([]) = []"
"rev(x#xs) = rev(xs) @ [x]"
primrec
"filter P [] = []"
"filter P (x#xs) = (if P x then x#filter P xs else filter P xs)"
primrec
foldl_Nil:"foldl f a [] = a"
foldl_Cons: "foldl f a (x#xs) = foldl f (f a x) xs"
primrec
"foldr f [] a = a"
"foldr f (x#xs) a = f x (foldr f xs a)"
primrec
"concat([]) = []"
"concat(x#xs) = x @ concat(xs)"
primrec
drop_Nil:"drop n [] = []"
drop_Cons: "drop n (x#xs) = (case n of 0 => x#xs | Suc(m) => drop m xs)"
-- {*Warning: simpset does not contain this definition, but separate
theorems for @{text "n = 0"} and @{text "n = Suc k"} *}
primrec
take_Nil:"take n [] = []"
take_Cons: "take n (x#xs) = (case n of 0 => [] | Suc(m) => x # take m xs)"
-- {*Warning: simpset does not contain this definition, but separate
theorems for @{text "n = 0"} and @{text "n = Suc k"} *}
primrec
nth_Cons:"(x#xs)!n = (case n of 0 => x | (Suc k) => xs!k)"
-- {*Warning: simpset does not contain this definition, but separate
theorems for @{text "n = 0"} and @{text "n = Suc k"} *}
primrec
"[][i:=v] = []"
"(x#xs)[i:=v] = (case i of 0 => v # xs | Suc j => x # xs[j:=v])"
primrec
"takeWhile P [] = []"
"takeWhile P (x#xs) = (if P x then x#takeWhile P xs else [])"
primrec
"dropWhile P [] = []"
"dropWhile P (x#xs) = (if P x then dropWhile P xs else x#xs)"
primrec
"zip xs [] = []"
zip_Cons: "zip xs (y#ys) = (case xs of [] => [] | z#zs => (z,y)#zip zs ys)"
-- {*Warning: simpset does not contain this definition, but separate
theorems for @{text "xs = []"} and @{text "xs = z # zs"} *}
primrec
upt_0: "[i..<0] = []"
upt_Suc: "[i..<(Suc j)] = (if i <= j then [i..<j] @ [j] else [])"
primrec
"distinct [] = True"
"distinct (x#xs) = (x ~: set xs \<and> distinct xs)"
primrec
"remdups [] = []"
"remdups (x#xs) = (if x : set xs then remdups xs else x # remdups xs)"
primrec
"remove1 x [] = []"
"remove1 x (y#xs) = (if x=y then xs else y # remove1 x xs)"
primrec
replicate_0: "replicate 0 x = []"
replicate_Suc: "replicate (Suc n) x = x # replicate n x"
defs
rotate1_def: "rotate1 xs == (case xs of [] \<Rightarrow> [] | x#xs \<Rightarrow> xs @ [x])"
rotate_def: "rotate n == rotate1 ^ n"
list_all2_def:
"list_all2 P xs ys ==
length xs = length ys \<and> (\<forall>(x, y) \<in> set (zip xs ys). P x y)"
sublist_def:
"sublist xs A == map fst (filter (%p. snd p : A) (zip xs [0..<size xs]))"
primrec
"splice [] ys = ys"
"splice (x#xs) ys = (if ys=[] then x#xs else x # hd ys # splice xs (tl ys))"
-- {*Warning: simpset does not contain the second eqn but a derived one. *}
primrec
"x mem [] = False"
"x mem (y#ys) = (if y=x then True else x mem ys)"
primrec
"list_inter [] bs = []"
"list_inter (a#as) bs =
(if a \<in> set bs then a#(list_inter as bs) else list_inter as bs)"
primrec
"list_all P [] = True"
"list_all P (x#xs) = (P(x) \<and> list_all P xs)"
primrec
"list_ex P [] = False"
"list_ex P (x#xs) = (P x \<or> list_ex P xs)"
primrec
"filtermap f [] = []"
"filtermap f (x#xs) =
(case f x of None \<Rightarrow> filtermap f xs
| Some y \<Rightarrow> y # (filtermap f xs))"
primrec
"map_filter f P [] = []"
"map_filter f P (x#xs) = (if P x then f x # map_filter f P xs else
map_filter f P xs)"
primrec
"itrev [] ys = ys"
"itrev (x#xs) ys = itrev xs (x#ys)"
lemma not_Cons_self [simp]: "xs \<noteq> x # xs"
by (induct xs) auto
lemmas not_Cons_self2 [simp] = not_Cons_self [symmetric]
lemma neq_Nil_conv: "(xs \<noteq> []) = (\<exists>y ys. xs = y # ys)"
by (induct xs) auto
lemma length_induct:
"(!!xs. \<forall>ys. length ys < length xs --> P ys ==> P xs) ==> P xs"
by (rule measure_induct [of length]) iprover
subsubsection {* @{text length} *}
text {*
Needs to come before @{text "@"} because of theorem @{text
append_eq_append_conv}.
*}
lemma length_append [simp]: "length (xs @ ys) = length xs + length ys"
by (induct xs) auto
lemma length_map [simp]: "length (map f xs) = length xs"
by (induct xs) auto
lemma length_rev [simp]: "length (rev xs) = length xs"
by (induct xs) auto
lemma length_tl [simp]: "length (tl xs) = length xs - 1"
by (cases xs) auto
lemma length_0_conv [iff]: "(length xs = 0) = (xs = [])"
by (induct xs) auto
lemma length_greater_0_conv [iff]: "(0 < length xs) = (xs \<noteq> [])"
by (induct xs) auto
lemma length_Suc_conv:
"(length xs = Suc n) = (\<exists>y ys. xs = y # ys \<and> length ys = n)"
by (induct xs) auto
lemma Suc_length_conv:
"(Suc n = length xs) = (\<exists>y ys. xs = y # ys \<and> length ys = n)"
apply (induct xs, simp, simp)
apply blast
done
lemma impossible_Cons [rule_format]:
"length xs <= length ys --> xs = x # ys = False"
apply (induct xs, auto)
done
lemma list_induct2[consumes 1]: "\<And>ys.
\<lbrakk> length xs = length ys;
P [] [];
\<And>x xs y ys. \<lbrakk> length xs = length ys; P xs ys \<rbrakk> \<Longrightarrow> P (x#xs) (y#ys) \<rbrakk>
\<Longrightarrow> P xs ys"
apply(induct xs)
apply simp
apply(case_tac ys)
apply simp
apply(simp)
done
subsubsection {* @{text "@"} -- append *}
lemma append_assoc [simp]: "(xs @ ys) @ zs = xs @ (ys @ zs)"
by (induct xs) auto
lemma append_Nil2 [simp]: "xs @ [] = xs"
by (induct xs) auto
lemma append_is_Nil_conv [iff]: "(xs @ ys = []) = (xs = [] \<and> ys = [])"
by (induct xs) auto
lemma Nil_is_append_conv [iff]: "([] = xs @ ys) = (xs = [] \<and> ys = [])"
by (induct xs) auto
lemma append_self_conv [iff]: "(xs @ ys = xs) = (ys = [])"
by (induct xs) auto
lemma self_append_conv [iff]: "(xs = xs @ ys) = (ys = [])"
by (induct xs) auto
lemma append_eq_append_conv [simp]:
"!!ys. length xs = length ys \<or> length us = length vs
==> (xs@us = ys@vs) = (xs=ys \<and> us=vs)"
apply (induct xs)
apply (case_tac ys, simp, force)
apply (case_tac ys, force, simp)
done
lemma append_eq_append_conv2: "!!ys zs ts.
(xs @ ys = zs @ ts) =
(EX us. xs = zs @ us & us @ ys = ts | xs @ us = zs & ys = us@ ts)"
apply (induct xs)
apply fastsimp
apply(case_tac zs)
apply simp
apply fastsimp
done
lemma same_append_eq [iff]: "(xs @ ys = xs @ zs) = (ys = zs)"
by simp
lemma append1_eq_conv [iff]: "(xs @ [x] = ys @ [y]) = (xs = ys \<and> x = y)"
by simp
lemma append_same_eq [iff]: "(ys @ xs = zs @ xs) = (ys = zs)"
by simp
lemma append_self_conv2 [iff]: "(xs @ ys = ys) = (xs = [])"
using append_same_eq [of _ _ "[]"] by auto
lemma self_append_conv2 [iff]: "(ys = xs @ ys) = (xs = [])"
using append_same_eq [of "[]"] by auto
lemma hd_Cons_tl [simp]: "xs \<noteq> [] ==> hd xs # tl xs = xs"
by (induct xs) auto
lemma hd_append: "hd (xs @ ys) = (if xs = [] then hd ys else hd xs)"
by (induct xs) auto
lemma hd_append2 [simp]: "xs \<noteq> [] ==> hd (xs @ ys) = hd xs"
by (simp add: hd_append split: list.split)
lemma tl_append: "tl (xs @ ys) = (case xs of [] => tl ys | z#zs => zs @ ys)"
by (simp split: list.split)
lemma tl_append2 [simp]: "xs \<noteq> [] ==> tl (xs @ ys) = tl xs @ ys"
by (simp add: tl_append split: list.split)
lemma Cons_eq_append_conv: "x#xs = ys@zs =
(ys = [] & x#xs = zs | (EX ys'. x#ys' = ys & xs = ys'@zs))"
by(cases ys) auto
lemma append_eq_Cons_conv: "(ys@zs = x#xs) =
(ys = [] & zs = x#xs | (EX ys'. ys = x#ys' & ys'@zs = xs))"
by(cases ys) auto
text {* Trivial rules for solving @{text "@"}-equations automatically. *}
lemma eq_Nil_appendI: "xs = ys ==> xs = [] @ ys"
by simp
lemma Cons_eq_appendI:
"[| x # xs1 = ys; xs = xs1 @ zs |] ==> x # xs = ys @ zs"
by (drule sym) simp
lemma append_eq_appendI:
"[| xs @ xs1 = zs; ys = xs1 @ us |] ==> xs @ ys = zs @ us"
by (drule sym) simp
text {*
Simplification procedure for all list equalities.
Currently only tries to rearrange @{text "@"} to see if
- both lists end in a singleton list,
- or both lists end in the same list.
*}
ML_setup {*
local
val append_assoc = thm "append_assoc";
val append_Nil = thm "append_Nil";
val append_Cons = thm "append_Cons";
val append1_eq_conv = thm "append1_eq_conv";
val append_same_eq = thm "append_same_eq";
fun last (cons as Const("List.list.Cons",_) $ _ $ xs) =
(case xs of Const("List.list.Nil",_) => cons | _ => last xs)
| last (Const("List.op @",_) $ _ $ ys) = last ys
| last t = t;
fun list1 (Const("List.list.Cons",_) $ _ $ Const("List.list.Nil",_)) = true
| list1 _ = false;
fun butlast ((cons as Const("List.list.Cons",_) $ x) $ xs) =
(case xs of Const("List.list.Nil",_) => xs | _ => cons $ butlast xs)
| butlast ((app as Const("List.op @",_) $ xs) $ ys) = app $ butlast ys
| butlast xs = Const("List.list.Nil",fastype_of xs);
val rearr_ss = HOL_basic_ss addsimps [append_assoc, append_Nil, append_Cons];
fun list_eq sg ss (F as (eq as Const(_,eqT)) $ lhs $ rhs) =
let
val lastl = last lhs and lastr = last rhs;
fun rearr conv =
let
val lhs1 = butlast lhs and rhs1 = butlast rhs;
val Type(_,listT::_) = eqT
val appT = [listT,listT] ---> listT
val app = Const("List.op @",appT)
val F2 = eq $ (app$lhs1$lastl) $ (app$rhs1$lastr)
val eq = HOLogic.mk_Trueprop (HOLogic.mk_eq (F,F2));
val thm = Goal.prove sg [] [] eq
(K (simp_tac (Simplifier.inherit_context ss rearr_ss) 1));
in SOME ((conv RS (thm RS trans)) RS eq_reflection) end;
in
if list1 lastl andalso list1 lastr then rearr append1_eq_conv
else if lastl aconv lastr then rearr append_same_eq
else NONE
end;
in
val list_eq_simproc =
Simplifier.simproc (Theory.sign_of (the_context ())) "list_eq" ["(xs::'a list) = ys"] list_eq;
end;
Addsimprocs [list_eq_simproc];
*}
subsubsection {* @{text map} *}
lemma map_ext: "(!!x. x : set xs --> f x = g x) ==> map f xs = map g xs"
by (induct xs) simp_all
lemma map_ident [simp]: "map (\<lambda>x. x) = (\<lambda>xs. xs)"
by (rule ext, induct_tac xs) auto
lemma map_append [simp]: "map f (xs @ ys) = map f xs @ map f ys"
by (induct xs) auto
lemma map_compose: "map (f o g) xs = map f (map g xs)"
by (induct xs) (auto simp add: o_def)
lemma rev_map: "rev (map f xs) = map f (rev xs)"
by (induct xs) auto
lemma map_eq_conv[simp]: "(map f xs = map g xs) = (!x : set xs. f x = g x)"
by (induct xs) auto
lemma map_cong [recdef_cong]:
"xs = ys ==> (!!x. x : set ys ==> f x = g x) ==> map f xs = map g ys"
-- {* a congruence rule for @{text map} *}
by simp
lemma map_is_Nil_conv [iff]: "(map f xs = []) = (xs = [])"
by (cases xs) auto
lemma Nil_is_map_conv [iff]: "([] = map f xs) = (xs = [])"
by (cases xs) auto
lemma map_eq_Cons_conv:
"(map f xs = y#ys) = (\<exists>z zs. xs = z#zs \<and> f z = y \<and> map f zs = ys)"
by (cases xs) auto
lemma Cons_eq_map_conv:
"(x#xs = map f ys) = (\<exists>z zs. ys = z#zs \<and> x = f z \<and> xs = map f zs)"
by (cases ys) auto
lemmas map_eq_Cons_D = map_eq_Cons_conv [THEN iffD1]
lemmas Cons_eq_map_D = Cons_eq_map_conv [THEN iffD1]
declare map_eq_Cons_D [dest!] Cons_eq_map_D [dest!]
lemma ex_map_conv:
"(EX xs. ys = map f xs) = (ALL y : set ys. EX x. y = f x)"
by(induct ys, auto simp add: Cons_eq_map_conv)
lemma map_eq_imp_length_eq:
"!!xs. map f xs = map f ys ==> length xs = length ys"
apply (induct ys)
apply simp
apply(simp (no_asm_use))
apply clarify
apply(simp (no_asm_use))
apply fast
done
lemma map_inj_on:
"[| map f xs = map f ys; inj_on f (set xs Un set ys) |]
==> xs = ys"
apply(frule map_eq_imp_length_eq)
apply(rotate_tac -1)
apply(induct rule:list_induct2)
apply simp
apply(simp)
apply (blast intro:sym)
done
lemma inj_on_map_eq_map:
"inj_on f (set xs Un set ys) \<Longrightarrow> (map f xs = map f ys) = (xs = ys)"
by(blast dest:map_inj_on)
lemma map_injective:
"!!xs. map f xs = map f ys ==> inj f ==> xs = ys"
by (induct ys) (auto dest!:injD)
lemma inj_map_eq_map[simp]: "inj f \<Longrightarrow> (map f xs = map f ys) = (xs = ys)"
by(blast dest:map_injective)
lemma inj_mapI: "inj f ==> inj (map f)"
by (iprover dest: map_injective injD intro: inj_onI)
lemma inj_mapD: "inj (map f) ==> inj f"
apply (unfold inj_on_def, clarify)
apply (erule_tac x = "[x]" in ballE)
apply (erule_tac x = "[y]" in ballE, simp, blast)
apply blast
done
lemma inj_map[iff]: "inj (map f) = inj f"
by (blast dest: inj_mapD intro: inj_mapI)
lemma inj_on_mapI: "inj_on f (\<Union>(set ` A)) \<Longrightarrow> inj_on (map f) A"
apply(rule inj_onI)
apply(erule map_inj_on)
apply(blast intro:inj_onI dest:inj_onD)
done
lemma map_idI: "(\<And>x. x \<in> set xs \<Longrightarrow> f x = x) \<Longrightarrow> map f xs = xs"
by (induct xs, auto)
lemma map_fun_upd [simp]: "y \<notin> set xs \<Longrightarrow> map (f(y:=v)) xs = map f xs"
by (induct xs) auto
lemma map_fst_zip[simp]:
"length xs = length ys \<Longrightarrow> map fst (zip xs ys) = xs"
by (induct rule:list_induct2, simp_all)
lemma map_snd_zip[simp]:
"length xs = length ys \<Longrightarrow> map snd (zip xs ys) = ys"
by (induct rule:list_induct2, simp_all)
subsubsection {* @{text rev} *}
lemma rev_append [simp]: "rev (xs @ ys) = rev ys @ rev xs"
by (induct xs) auto
lemma rev_rev_ident [simp]: "rev (rev xs) = xs"
by (induct xs) auto
lemma rev_swap: "(rev xs = ys) = (xs = rev ys)"
by auto
lemma rev_is_Nil_conv [iff]: "(rev xs = []) = (xs = [])"
by (induct xs) auto
lemma Nil_is_rev_conv [iff]: "([] = rev xs) = (xs = [])"
by (induct xs) auto
lemma rev_singleton_conv [simp]: "(rev xs = [x]) = (xs = [x])"
by (cases xs) auto
lemma singleton_rev_conv [simp]: "([x] = rev xs) = (xs = [x])"
by (cases xs) auto
lemma rev_is_rev_conv [iff]: "!!ys. (rev xs = rev ys) = (xs = ys)"
apply (induct xs, force)
apply (case_tac ys, simp, force)
done
lemma inj_on_rev[iff]: "inj_on rev A"
by(simp add:inj_on_def)
lemma rev_induct [case_names Nil snoc]:
"[| P []; !!x xs. P xs ==> P (xs @ [x]) |] ==> P xs"
apply(simplesubst rev_rev_ident[symmetric])
apply(rule_tac list = "rev xs" in list.induct, simp_all)
done
ML {* val rev_induct_tac = induct_thm_tac (thm "rev_induct") *}-- "compatibility"
lemma rev_exhaust [case_names Nil snoc]:
"(xs = [] ==> P) ==>(!!ys y. xs = ys @ [y] ==> P) ==> P"
by (induct xs rule: rev_induct) auto
lemmas rev_cases = rev_exhaust
lemma rev_eq_Cons_iff[iff]: "(rev xs = y#ys) = (xs = rev ys @ [y])"
by(rule rev_cases[of xs]) auto
subsubsection {* @{text set} *}
lemma finite_set [iff]: "finite (set xs)"
by (induct xs) auto
lemma set_append [simp]: "set (xs @ ys) = (set xs \<union> set ys)"
by (induct xs) auto
lemma hd_in_set[simp]: "xs \<noteq> [] \<Longrightarrow> hd xs : set xs"
by(cases xs) auto
lemma set_subset_Cons: "set xs \<subseteq> set (x # xs)"
by auto
lemma set_ConsD: "y \<in> set (x # xs) \<Longrightarrow> y=x \<or> y \<in> set xs"
by auto
lemma set_empty [iff]: "(set xs = {}) = (xs = [])"
by (induct xs) auto
lemma set_empty2[iff]: "({} = set xs) = (xs = [])"
by(induct xs) auto
lemma set_rev [simp]: "set (rev xs) = set xs"
by (induct xs) auto
lemma set_map [simp]: "set (map f xs) = f`(set xs)"
by (induct xs) auto
lemma set_filter [simp]: "set (filter P xs) = {x. x : set xs \<and> P x}"
by (induct xs) auto
lemma set_upt [simp]: "set[i..<j] = {k. i \<le> k \<and> k < j}"
apply (induct j, simp_all)
apply (erule ssubst, auto)
done
lemma in_set_conv_decomp: "(x : set xs) = (\<exists>ys zs. xs = ys @ x # zs)"
proof (induct xs)
case Nil show ?case by simp
case (Cons a xs)
show ?case
proof
assume "x \<in> set (a # xs)"
with prems show "\<exists>ys zs. a # xs = ys @ x # zs"
by (simp, blast intro: Cons_eq_appendI)
next
assume "\<exists>ys zs. a # xs = ys @ x # zs"
then obtain ys zs where eq: "a # xs = ys @ x # zs" by blast
show "x \<in> set (a # xs)"
by (cases ys, auto simp add: eq)
qed
qed
lemma in_set_conv_decomp_first:
"(x : set xs) = (\<exists>ys zs. xs = ys @ x # zs \<and> x \<notin> set ys)"
proof (induct xs)
case Nil show ?case by simp
next
case (Cons a xs)
show ?case
proof cases
assume "x = a" thus ?case using Cons by force
next
assume "x \<noteq> a"
show ?case
proof
assume "x \<in> set (a # xs)"
from prems show "\<exists>ys zs. a # xs = ys @ x # zs \<and> x \<notin> set ys"
by(fastsimp intro!: Cons_eq_appendI)
next
assume "\<exists>ys zs. a # xs = ys @ x # zs \<and> x \<notin> set ys"
then obtain ys zs where eq: "a # xs = ys @ x # zs" by blast
show "x \<in> set (a # xs)" by (cases ys, auto simp add: eq)
qed
qed
qed
lemmas split_list = in_set_conv_decomp[THEN iffD1, standard]
lemmas split_list_first = in_set_conv_decomp_first[THEN iffD1, standard]
lemma finite_list: "finite A ==> EX l. set l = A"
apply (erule finite_induct, auto)
apply (rule_tac x="x#l" in exI, auto)
done
lemma card_length: "card (set xs) \<le> length xs"
by (induct xs) (auto simp add: card_insert_if)
subsubsection {* @{text filter} *}
lemma filter_append [simp]: "filter P (xs @ ys) = filter P xs @ filter P ys"
by (induct xs) auto
lemma rev_filter: "rev (filter P xs) = filter P (rev xs)"
by (induct xs) simp_all
lemma filter_filter [simp]: "filter P (filter Q xs) = filter (\<lambda>x. Q x \<and> P x) xs"
by (induct xs) auto
lemma length_filter_le [simp]: "length (filter P xs) \<le> length xs"
by (induct xs) (auto simp add: le_SucI)
lemma sum_length_filter_compl:
"length(filter P xs) + length(filter (%x. ~P x) xs) = length xs"
by(induct xs) simp_all
lemma filter_True [simp]: "\<forall>x \<in> set xs. P x ==> filter P xs = xs"
by (induct xs) auto
lemma filter_False [simp]: "\<forall>x \<in> set xs. \<not> P x ==> filter P xs = []"
by (induct xs) auto
lemma filter_empty_conv: "(filter P xs = []) = (\<forall>x\<in>set xs. \<not> P x)"
by (induct xs) simp_all
lemma filter_id_conv: "(filter P xs = xs) = (\<forall>x\<in>set xs. P x)"
apply (induct xs)
apply auto
apply(cut_tac P=P and xs=xs in length_filter_le)
apply simp
done
lemma filter_map:
"filter P (map f xs) = map f (filter (P o f) xs)"
by (induct xs) simp_all
lemma length_filter_map[simp]:
"length (filter P (map f xs)) = length(filter (P o f) xs)"
by (simp add:filter_map)
lemma filter_is_subset [simp]: "set (filter P xs) \<le> set xs"
by auto
lemma length_filter_less:
"\<lbrakk> x : set xs; ~ P x \<rbrakk> \<Longrightarrow> length(filter P xs) < length xs"
proof (induct xs)
case Nil thus ?case by simp
next
case (Cons x xs) thus ?case
apply (auto split:split_if_asm)
using length_filter_le[of P xs] apply arith
done
qed
lemma length_filter_conv_card:
"length(filter p xs) = card{i. i < length xs & p(xs!i)}"
proof (induct xs)
case Nil thus ?case by simp
next
case (Cons x xs)
let ?S = "{i. i < length xs & p(xs!i)}"
have fin: "finite ?S" by(fast intro: bounded_nat_set_is_finite)
show ?case (is "?l = card ?S'")
proof (cases)
assume "p x"
hence eq: "?S' = insert 0 (Suc ` ?S)"
by(auto simp add: nth_Cons image_def split:nat.split elim:lessE)
have "length (filter p (x # xs)) = Suc(card ?S)"
using Cons by simp
also have "\<dots> = Suc(card(Suc ` ?S))" using fin
by (simp add: card_image inj_Suc)
also have "\<dots> = card ?S'" using eq fin
by (simp add:card_insert_if) (simp add:image_def)
finally show ?thesis .
next
assume "\<not> p x"
hence eq: "?S' = Suc ` ?S"
by(auto simp add: nth_Cons image_def split:nat.split elim:lessE)
have "length (filter p (x # xs)) = card ?S"
using Cons by simp
also have "\<dots> = card(Suc ` ?S)" using fin
by (simp add: card_image inj_Suc)
also have "\<dots> = card ?S'" using eq fin
by (simp add:card_insert_if)
finally show ?thesis .
qed
qed
lemma Cons_eq_filterD:
"x#xs = filter P ys \<Longrightarrow>
\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs"
(is "_ \<Longrightarrow> \<exists>us vs. ?P ys us vs")
proof(induct ys)
case Nil thus ?case by simp
next
case (Cons y ys)
show ?case (is "\<exists>x. ?Q x")
proof cases
assume Py: "P y"
show ?thesis
proof cases
assume xy: "x = y"
show ?thesis
proof from Py xy Cons(2) show "?Q []" by simp qed
next
assume "x \<noteq> y" with Py Cons(2) show ?thesis by simp
qed
next
assume Py: "\<not> P y"
with Cons obtain us vs where 1 : "?P (y#ys) (y#us) vs" by fastsimp
show ?thesis (is "? us. ?Q us")
proof show "?Q (y#us)" using 1 by simp qed
qed
qed
lemma filter_eq_ConsD:
"filter P ys = x#xs \<Longrightarrow>
\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs"
by(rule Cons_eq_filterD) simp
lemma filter_eq_Cons_iff:
"(filter P ys = x#xs) =
(\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs)"
by(auto dest:filter_eq_ConsD)
lemma Cons_eq_filter_iff:
"(x#xs = filter P ys) =
(\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs)"
by(auto dest:Cons_eq_filterD)
lemma filter_cong[recdef_cong]:
"xs = ys \<Longrightarrow> (\<And>x. x \<in> set ys \<Longrightarrow> P x = Q x) \<Longrightarrow> filter P xs = filter Q ys"
apply simp
apply(erule thin_rl)
by (induct ys) simp_all
subsubsection {* @{text concat} *}
lemma concat_append [simp]: "concat (xs @ ys) = concat xs @ concat ys"
by (induct xs) auto
lemma concat_eq_Nil_conv [simp]: "(concat xss = []) = (\<forall>xs \<in> set xss. xs = [])"
by (induct xss) auto
lemma Nil_eq_concat_conv [simp]: "([] = concat xss) = (\<forall>xs \<in> set xss. xs = [])"
by (induct xss) auto
lemma set_concat [simp]: "set (concat xs) = \<Union>(set ` set xs)"
by (induct xs) auto
lemma map_concat: "map f (concat xs) = concat (map (map f) xs)"
by (induct xs) auto
lemma filter_concat: "filter p (concat xs) = concat (map (filter p) xs)"
by (induct xs) auto
lemma rev_concat: "rev (concat xs) = concat (map rev (rev xs))"
by (induct xs) auto
subsubsection {* @{text nth} *}
lemma nth_Cons_0 [simp]: "(x # xs)!0 = x"
by auto
lemma nth_Cons_Suc [simp]: "(x # xs)!(Suc n) = xs!n"
by auto
declare nth.simps [simp del]
lemma nth_append:
"!!n. (xs @ ys)!n = (if n < length xs then xs!n else ys!(n - length xs))"
apply (induct "xs", simp)
apply (case_tac n, auto)
done
lemma nth_append_length [simp]: "(xs @ x # ys) ! length xs = x"
by (induct "xs") auto
lemma nth_append_length_plus[simp]: "(xs @ ys) ! (length xs + n) = ys ! n"
by (induct "xs") auto
lemma nth_map [simp]: "!!n. n < length xs ==> (map f xs)!n = f(xs!n)"
apply (induct xs, simp)
apply (case_tac n, auto)
done
lemma hd_conv_nth: "xs \<noteq> [] \<Longrightarrow> hd xs = xs!0"
by(cases xs) simp_all
lemma list_eq_iff_nth_eq:
"!!ys. (xs = ys) = (length xs = length ys \<and> (ALL i<length xs. xs!i = ys!i))"
apply(induct xs)
apply simp apply blast
apply(case_tac ys)
apply simp
apply(simp add:nth_Cons split:nat.split)apply blast
done
lemma set_conv_nth: "set xs = {xs!i | i. i < length xs}"
apply (induct xs, simp, simp)
apply safe
apply (rule_tac x = 0 in exI, simp)
apply (rule_tac x = "Suc i" in exI, simp)
apply (case_tac i, simp)
apply (rename_tac j)
apply (rule_tac x = j in exI, simp)
done
lemma in_set_conv_nth: "(x \<in> set xs) = (\<exists>i < length xs. xs!i = x)"
by(auto simp:set_conv_nth)
lemma list_ball_nth: "[| n < length xs; !x : set xs. P x|] ==> P(xs!n)"
by (auto simp add: set_conv_nth)
lemma nth_mem [simp]: "n < length xs ==> xs!n : set xs"
by (auto simp add: set_conv_nth)
lemma all_nth_imp_all_set:
"[| !i < length xs. P(xs!i); x : set xs|] ==> P x"
by (auto simp add: set_conv_nth)
lemma all_set_conv_all_nth:
"(\<forall>x \<in> set xs. P x) = (\<forall>i. i < length xs --> P (xs ! i))"
by (auto simp add: set_conv_nth)
subsubsection {* @{text list_update} *}
lemma length_list_update [simp]: "!!i. length(xs[i:=x]) = length xs"
by (induct xs) (auto split: nat.split)
lemma nth_list_update:
"!!i j. i < length xs==> (xs[i:=x])!j = (if i = j then x else xs!j)"
by (induct xs) (auto simp add: nth_Cons split: nat.split)
lemma nth_list_update_eq [simp]: "i < length xs ==> (xs[i:=x])!i = x"
by (simp add: nth_list_update)
lemma nth_list_update_neq [simp]: "!!i j. i \<noteq> j ==> xs[i:=x]!j = xs!j"
by (induct xs) (auto simp add: nth_Cons split: nat.split)
lemma list_update_overwrite [simp]:
"!!i. i < size xs ==> xs[i:=x, i:=y] = xs[i:=y]"
by (induct xs) (auto split: nat.split)
lemma list_update_id[simp]: "!!i. i < length xs ==> xs[i := xs!i] = xs"
apply (induct xs, simp)
apply(simp split:nat.splits)
done
lemma list_update_beyond[simp]: "\<And>i. length xs \<le> i \<Longrightarrow> xs[i:=x] = xs"
apply (induct xs)
apply simp
apply (case_tac i)
apply simp_all
done
lemma list_update_same_conv:
"!!i. i < length xs ==> (xs[i := x] = xs) = (xs!i = x)"
by (induct xs) (auto split: nat.split)
lemma list_update_append1:
"!!i. i < size xs \<Longrightarrow> (xs @ ys)[i:=x] = xs[i:=x] @ ys"
apply (induct xs, simp)
apply(simp split:nat.split)
done
lemma list_update_append:
"!!n. (xs @ ys) [n:= x] =
(if n < length xs then xs[n:= x] @ ys else xs @ (ys [n-length xs:= x]))"
by (induct xs) (auto split:nat.splits)
lemma list_update_length [simp]:
"(xs @ x # ys)[length xs := y] = (xs @ y # ys)"
by (induct xs, auto)
lemma update_zip:
"!!i xy xs. length xs = length ys ==>
(zip xs ys)[i:=xy] = zip (xs[i:=fst xy]) (ys[i:=snd xy])"
by (induct ys) (auto, case_tac xs, auto split: nat.split)
lemma set_update_subset_insert: "!!i. set(xs[i:=x]) <= insert x (set xs)"
by (induct xs) (auto split: nat.split)
lemma set_update_subsetI: "[| set xs <= A; x:A |] ==> set(xs[i := x]) <= A"
by (blast dest!: set_update_subset_insert [THEN subsetD])
lemma set_update_memI: "!!n. n < length xs \<Longrightarrow> x \<in> set (xs[n := x])"
by (induct xs) (auto split:nat.splits)
subsubsection {* @{text last} and @{text butlast} *}
lemma last_snoc [simp]: "last (xs @ [x]) = x"
by (induct xs) auto
lemma butlast_snoc [simp]: "butlast (xs @ [x]) = xs"
by (induct xs) auto
lemma last_ConsL: "xs = [] \<Longrightarrow> last(x#xs) = x"
by(simp add:last.simps)
lemma last_ConsR: "xs \<noteq> [] \<Longrightarrow> last(x#xs) = last xs"
by(simp add:last.simps)
lemma last_append: "last(xs @ ys) = (if ys = [] then last xs else last ys)"
by (induct xs) (auto)
lemma last_appendL[simp]: "ys = [] \<Longrightarrow> last(xs @ ys) = last xs"
by(simp add:last_append)
lemma last_appendR[simp]: "ys \<noteq> [] \<Longrightarrow> last(xs @ ys) = last ys"
by(simp add:last_append)
lemma hd_rev: "xs \<noteq> [] \<Longrightarrow> hd(rev xs) = last xs"
by(rule rev_exhaust[of xs]) simp_all
lemma last_rev: "xs \<noteq> [] \<Longrightarrow> last(rev xs) = hd xs"
by(cases xs) simp_all
lemma last_in_set[simp]: "as \<noteq> [] \<Longrightarrow> last as \<in> set as"
by (induct as) auto
lemma length_butlast [simp]: "length (butlast xs) = length xs - 1"
by (induct xs rule: rev_induct) auto
lemma butlast_append:
"!!ys. butlast (xs @ ys) = (if ys = [] then butlast xs else xs @ butlast ys)"
by (induct xs) auto
lemma append_butlast_last_id [simp]:
"xs \<noteq> [] ==> butlast xs @ [last xs] = xs"
by (induct xs) auto
lemma in_set_butlastD: "x : set (butlast xs) ==> x : set xs"
by (induct xs) (auto split: split_if_asm)
lemma in_set_butlast_appendI:
"x : set (butlast xs) | x : set (butlast ys) ==> x : set (butlast (xs @ ys))"
by (auto dest: in_set_butlastD simp add: butlast_append)
lemma last_drop[simp]: "!!n. n < length xs \<Longrightarrow> last (drop n xs) = last xs"
apply (induct xs)
apply simp
apply (auto split:nat.split)
done
lemma last_conv_nth: "xs\<noteq>[] \<Longrightarrow> last xs = xs!(length xs - 1)"
by(induct xs)(auto simp:neq_Nil_conv)
subsubsection {* @{text take} and @{text drop} *}
lemma take_0 [simp]: "take 0 xs = []"
by (induct xs) auto
lemma drop_0 [simp]: "drop 0 xs = xs"
by (induct xs) auto
lemma take_Suc_Cons [simp]: "take (Suc n) (x # xs) = x # take n xs"
by simp
lemma drop_Suc_Cons [simp]: "drop (Suc n) (x # xs) = drop n xs"
by simp
declare take_Cons [simp del] and drop_Cons [simp del]
lemma take_Suc: "xs ~= [] ==> take (Suc n) xs = hd xs # take n (tl xs)"
by(clarsimp simp add:neq_Nil_conv)
lemma drop_Suc: "drop (Suc n) xs = drop n (tl xs)"
by(cases xs, simp_all)
lemma drop_tl: "!!n. drop n (tl xs) = tl(drop n xs)"
by(induct xs, simp_all add:drop_Cons drop_Suc split:nat.split)
lemma nth_via_drop: "!!n. drop n xs = y#ys \<Longrightarrow> xs!n = y"
apply (induct xs, simp)
apply(simp add:drop_Cons nth_Cons split:nat.splits)
done
lemma take_Suc_conv_app_nth:
"!!i. i < length xs \<Longrightarrow> take (Suc i) xs = take i xs @ [xs!i]"
apply (induct xs, simp)
apply (case_tac i, auto)
done
lemma drop_Suc_conv_tl:
"!!i. i < length xs \<Longrightarrow> (xs!i) # (drop (Suc i) xs) = drop i xs"
apply (induct xs, simp)
apply (case_tac i, auto)
done
lemma length_take [simp]: "!!xs. length (take n xs) = min (length xs) n"
by (induct n) (auto, case_tac xs, auto)
lemma length_drop [simp]: "!!xs. length (drop n xs) = (length xs - n)"
by (induct n) (auto, case_tac xs, auto)
lemma take_all [simp]: "!!xs. length xs <= n ==> take n xs = xs"
by (induct n) (auto, case_tac xs, auto)
lemma drop_all [simp]: "!!xs. length xs <= n ==> drop n xs = []"
by (induct n) (auto, case_tac xs, auto)
lemma take_append [simp]:
"!!xs. take n (xs @ ys) = (take n xs @ take (n - length xs) ys)"
by (induct n) (auto, case_tac xs, auto)
lemma drop_append [simp]:
"!!xs. drop n (xs @ ys) = drop n xs @ drop (n - length xs) ys"
by (induct n) (auto, case_tac xs, auto)
lemma take_take [simp]: "!!xs n. take n (take m xs) = take (min n m) xs"
apply (induct m, auto)
apply (case_tac xs, auto)
apply (case_tac n, auto)
done
lemma drop_drop [simp]: "!!xs. drop n (drop m xs) = drop (n + m) xs"
apply (induct m, auto)
apply (case_tac xs, auto)
done
lemma take_drop: "!!xs n. take n (drop m xs) = drop m (take (n + m) xs)"
apply (induct m, auto)
apply (case_tac xs, auto)
done
lemma drop_take: "!!m n. drop n (take m xs) = take (m-n) (drop n xs)"
apply(induct xs)
apply simp
apply(simp add: take_Cons drop_Cons split:nat.split)
done
lemma append_take_drop_id [simp]: "!!xs. take n xs @ drop n xs = xs"
apply (induct n, auto)
apply (case_tac xs, auto)
done
lemma take_eq_Nil[simp]: "!!n. (take n xs = []) = (n = 0 \<or> xs = [])"
apply(induct xs)
apply simp
apply(simp add:take_Cons split:nat.split)
done
lemma drop_eq_Nil[simp]: "!!n. (drop n xs = []) = (length xs <= n)"
apply(induct xs)
apply simp
apply(simp add:drop_Cons split:nat.split)
done
lemma take_map: "!!xs. take n (map f xs) = map f (take n xs)"
apply (induct n, auto)
apply (case_tac xs, auto)
done
lemma drop_map: "!!xs. drop n (map f xs) = map f (drop n xs)"
apply (induct n, auto)
apply (case_tac xs, auto)
done
lemma rev_take: "!!i. rev (take i xs) = drop (length xs - i) (rev xs)"
apply (induct xs, auto)
apply (case_tac i, auto)
done
lemma rev_drop: "!!i. rev (drop i xs) = take (length xs - i) (rev xs)"
apply (induct xs, auto)
apply (case_tac i, auto)
done
lemma nth_take [simp]: "!!n i. i < n ==> (take n xs)!i = xs!i"
apply (induct xs, auto)
apply (case_tac n, blast)
apply (case_tac i, auto)
done
lemma nth_drop [simp]:
"!!xs i. n + i <= length xs ==> (drop n xs)!i = xs!(n + i)"
apply (induct n, auto)
apply (case_tac xs, auto)
done
lemma hd_drop_conv_nth: "\<lbrakk> xs \<noteq> []; n < length xs \<rbrakk> \<Longrightarrow> hd(drop n xs) = xs!n"
by(simp add: hd_conv_nth)
lemma set_take_subset: "\<And>n. set(take n xs) \<subseteq> set xs"
by(induct xs)(auto simp:take_Cons split:nat.split)
lemma set_drop_subset: "\<And>n. set(drop n xs) \<subseteq> set xs"
by(induct xs)(auto simp:drop_Cons split:nat.split)
lemma in_set_takeD: "x : set(take n xs) \<Longrightarrow> x : set xs"
using set_take_subset by fast
lemma in_set_dropD: "x : set(drop n xs) \<Longrightarrow> x : set xs"
using set_drop_subset by fast
lemma append_eq_conv_conj:
"!!zs. (xs @ ys = zs) = (xs = take (length xs) zs \<and> ys = drop (length xs) zs)"
apply (induct xs, simp, clarsimp)
apply (case_tac zs, auto)
done
lemma take_add [rule_format]:
"\<forall>i. i+j \<le> length(xs) --> take (i+j) xs = take i xs @ take j (drop i xs)"
apply (induct xs, auto)
apply (case_tac i, simp_all)
done
lemma append_eq_append_conv_if:
"!! ys\<^isub>1. (xs\<^isub>1 @ xs\<^isub>2 = ys\<^isub>1 @ ys\<^isub>2) =
(if size xs\<^isub>1 \<le> size ys\<^isub>1
then xs\<^isub>1 = take (size xs\<^isub>1) ys\<^isub>1 \<and> xs\<^isub>2 = drop (size xs\<^isub>1) ys\<^isub>1 @ ys\<^isub>2
else take (size ys\<^isub>1) xs\<^isub>1 = ys\<^isub>1 \<and> drop (size ys\<^isub>1) xs\<^isub>1 @ xs\<^isub>2 = ys\<^isub>2)"
apply(induct xs\<^isub>1)
apply simp
apply(case_tac ys\<^isub>1)
apply simp_all
done
lemma take_hd_drop:
"!!n. n < length xs \<Longrightarrow> take n xs @ [hd (drop n xs)] = take (n+1) xs"
apply(induct xs)
apply simp
apply(simp add:drop_Cons split:nat.split)
done
lemma id_take_nth_drop:
"i < length xs \<Longrightarrow> xs = take i xs @ xs!i # drop (Suc i) xs"
proof -
assume si: "i < length xs"
hence "xs = take (Suc i) xs @ drop (Suc i) xs" by auto
moreover
from si have "take (Suc i) xs = take i xs @ [xs!i]"
apply (rule_tac take_Suc_conv_app_nth) by arith
ultimately show ?thesis by auto
qed
lemma upd_conv_take_nth_drop:
"i < length xs \<Longrightarrow> xs[i:=a] = take i xs @ a # drop (Suc i) xs"
proof -
assume i: "i < length xs"
have "xs[i:=a] = (take i xs @ xs!i # drop (Suc i) xs)[i:=a]"
by(rule arg_cong[OF id_take_nth_drop[OF i]])
also have "\<dots> = take i xs @ a # drop (Suc i) xs"
using i by (simp add: list_update_append)
finally show ?thesis .
qed
subsubsection {* @{text takeWhile} and @{text dropWhile} *}
lemma takeWhile_dropWhile_id [simp]: "takeWhile P xs @ dropWhile P xs = xs"
by (induct xs) auto
lemma takeWhile_append1 [simp]:
"[| x:set xs; ~P(x)|] ==> takeWhile P (xs @ ys) = takeWhile P xs"
by (induct xs) auto
lemma takeWhile_append2 [simp]:
"(!!x. x : set xs ==> P x) ==> takeWhile P (xs @ ys) = xs @ takeWhile P ys"
by (induct xs) auto
lemma takeWhile_tail: "\<not> P x ==> takeWhile P (xs @ (x#l)) = takeWhile P xs"
by (induct xs) auto
lemma dropWhile_append1 [simp]:
"[| x : set xs; ~P(x)|] ==> dropWhile P (xs @ ys) = (dropWhile P xs)@ys"
by (induct xs) auto
lemma dropWhile_append2 [simp]:
"(!!x. x:set xs ==> P(x)) ==> dropWhile P (xs @ ys) = dropWhile P ys"
by (induct xs) auto
lemma set_take_whileD: "x : set (takeWhile P xs) ==> x : set xs \<and> P x"
by (induct xs) (auto split: split_if_asm)
lemma takeWhile_eq_all_conv[simp]:
"(takeWhile P xs = xs) = (\<forall>x \<in> set xs. P x)"
by(induct xs, auto)
lemma dropWhile_eq_Nil_conv[simp]:
"(dropWhile P xs = []) = (\<forall>x \<in> set xs. P x)"
by(induct xs, auto)
lemma dropWhile_eq_Cons_conv:
"(dropWhile P xs = y#ys) = (xs = takeWhile P xs @ y # ys & \<not> P y)"
by(induct xs, auto)
text{* The following two lemmmas could be generalized to an arbitrary
property. *}
lemma takeWhile_neq_rev: "\<lbrakk>distinct xs; x \<in> set xs\<rbrakk> \<Longrightarrow>
takeWhile (\<lambda>y. y \<noteq> x) (rev xs) = rev (tl (dropWhile (\<lambda>y. y \<noteq> x) xs))"
by(induct xs) (auto simp: takeWhile_tail[where l="[]"])
lemma dropWhile_neq_rev: "\<lbrakk>distinct xs; x \<in> set xs\<rbrakk> \<Longrightarrow>
dropWhile (\<lambda>y. y \<noteq> x) (rev xs) = x # rev (takeWhile (\<lambda>y. y \<noteq> x) xs)"
apply(induct xs)
apply simp
apply auto
apply(subst dropWhile_append2)
apply auto
done
lemma takeWhile_not_last:
"\<lbrakk> xs \<noteq> []; distinct xs\<rbrakk> \<Longrightarrow> takeWhile (\<lambda>y. y \<noteq> last xs) xs = butlast xs"
apply(induct xs)
apply simp
apply(case_tac xs)
apply(auto)
done
lemma takeWhile_cong [recdef_cong]:
"[| l = k; !!x. x : set l ==> P x = Q x |]
==> takeWhile P l = takeWhile Q k"
by (induct k fixing: l, simp_all)
lemma dropWhile_cong [recdef_cong]:
"[| l = k; !!x. x : set l ==> P x = Q x |]
==> dropWhile P l = dropWhile Q k"
by (induct k fixing: l, simp_all)
subsubsection {* @{text zip} *}
lemma zip_Nil [simp]: "zip [] ys = []"
by (induct ys) auto
lemma zip_Cons_Cons [simp]: "zip (x # xs) (y # ys) = (x, y) # zip xs ys"
by simp
declare zip_Cons [simp del]
lemma zip_Cons1:
"zip (x#xs) ys = (case ys of [] \<Rightarrow> [] | y#ys \<Rightarrow> (x,y)#zip xs ys)"
by(auto split:list.split)
lemma length_zip [simp]:
"!!xs. length (zip xs ys) = min (length xs) (length ys)"
apply (induct ys, simp)
apply (case_tac xs, auto)
done
lemma zip_append1:
"!!xs. zip (xs @ ys) zs =
zip xs (take (length xs) zs) @ zip ys (drop (length xs) zs)"
apply (induct zs, simp)
apply (case_tac xs, simp_all)
done
lemma zip_append2:
"!!ys. zip xs (ys @ zs) =
zip (take (length ys) xs) ys @ zip (drop (length ys) xs) zs"
apply (induct xs, simp)
apply (case_tac ys, simp_all)
done
lemma zip_append [simp]:
"[| length xs = length us; length ys = length vs |] ==>
zip (xs@ys) (us@vs) = zip xs us @ zip ys vs"
by (simp add: zip_append1)
lemma zip_rev:
"length xs = length ys ==> zip (rev xs) (rev ys) = rev (zip xs ys)"
by (induct rule:list_induct2, simp_all)
lemma nth_zip [simp]:
"!!i xs. [| i < length xs; i < length ys|] ==> (zip xs ys)!i = (xs!i, ys!i)"
apply (induct ys, simp)
apply (case_tac xs)
apply (simp_all add: nth.simps split: nat.split)
done
lemma set_zip:
"set (zip xs ys) = {(xs!i, ys!i) | i. i < min (length xs) (length ys)}"
by (simp add: set_conv_nth cong: rev_conj_cong)
lemma zip_update:
"length xs = length ys ==> zip (xs[i:=x]) (ys[i:=y]) = (zip xs ys)[i:=(x,y)]"
by (rule sym, simp add: update_zip)
lemma zip_replicate [simp]:
"!!j. zip (replicate i x) (replicate j y) = replicate (min i j) (x,y)"
apply (induct i, auto)
apply (case_tac j, auto)
done
lemma take_zip:
"!!xs ys. take n (zip xs ys) = zip (take n xs) (take n ys)"
apply (induct n)
apply simp
apply (case_tac xs, simp)
apply (case_tac ys, simp_all)
done
lemma drop_zip:
"!!xs ys. drop n (zip xs ys) = zip (drop n xs) (drop n ys)"
apply (induct n)
apply simp
apply (case_tac xs, simp)
apply (case_tac ys, simp_all)
done
subsubsection {* @{text list_all2} *}
lemma list_all2_lengthD [intro?]:
"list_all2 P xs ys ==> length xs = length ys"
by (simp add: list_all2_def)
lemma list_all2_Nil [iff,code]: "list_all2 P [] ys = (ys = [])"
by (simp add: list_all2_def)
lemma list_all2_Nil2[iff]: "list_all2 P xs [] = (xs = [])"
by (simp add: list_all2_def)
lemma list_all2_Cons [iff,code]:
"list_all2 P (x # xs) (y # ys) = (P x y \<and> list_all2 P xs ys)"
by (auto simp add: list_all2_def)
lemma list_all2_Cons1:
"list_all2 P (x # xs) ys = (\<exists>z zs. ys = z # zs \<and> P x z \<and> list_all2 P xs zs)"
by (cases ys) auto
lemma list_all2_Cons2:
"list_all2 P xs (y # ys) = (\<exists>z zs. xs = z # zs \<and> P z y \<and> list_all2 P zs ys)"
by (cases xs) auto
lemma list_all2_rev [iff]:
"list_all2 P (rev xs) (rev ys) = list_all2 P xs ys"
by (simp add: list_all2_def zip_rev cong: conj_cong)
lemma list_all2_rev1:
"list_all2 P (rev xs) ys = list_all2 P xs (rev ys)"
by (subst list_all2_rev [symmetric]) simp
lemma list_all2_append1:
"list_all2 P (xs @ ys) zs =
(EX us vs. zs = us @ vs \<and> length us = length xs \<and> length vs = length ys \<and>
list_all2 P xs us \<and> list_all2 P ys vs)"
apply (simp add: list_all2_def zip_append1)
apply (rule iffI)
apply (rule_tac x = "take (length xs) zs" in exI)
apply (rule_tac x = "drop (length xs) zs" in exI)
apply (force split: nat_diff_split simp add: min_def, clarify)
apply (simp add: ball_Un)
done
lemma list_all2_append2:
"list_all2 P xs (ys @ zs) =
(EX us vs. xs = us @ vs \<and> length us = length ys \<and> length vs = length zs \<and>
list_all2 P us ys \<and> list_all2 P vs zs)"
apply (simp add: list_all2_def zip_append2)
apply (rule iffI)
apply (rule_tac x = "take (length ys) xs" in exI)
apply (rule_tac x = "drop (length ys) xs" in exI)
apply (force split: nat_diff_split simp add: min_def, clarify)
apply (simp add: ball_Un)
done
lemma list_all2_append:
"length xs = length ys \<Longrightarrow>
list_all2 P (xs@us) (ys@vs) = (list_all2 P xs ys \<and> list_all2 P us vs)"
by (induct rule:list_induct2, simp_all)
lemma list_all2_appendI [intro?, trans]:
"\<lbrakk> list_all2 P a b; list_all2 P c d \<rbrakk> \<Longrightarrow> list_all2 P (a@c) (b@d)"
by (simp add: list_all2_append list_all2_lengthD)
lemma list_all2_conv_all_nth:
"list_all2 P xs ys =
(length xs = length ys \<and> (\<forall>i < length xs. P (xs!i) (ys!i)))"
by (force simp add: list_all2_def set_zip)
lemma list_all2_trans:
assumes tr: "!!a b c. P1 a b ==> P2 b c ==> P3 a c"
shows "!!bs cs. list_all2 P1 as bs ==> list_all2 P2 bs cs ==> list_all2 P3 as cs"
(is "!!bs cs. PROP ?Q as bs cs")
proof (induct as)
fix x xs bs assume I1: "!!bs cs. PROP ?Q xs bs cs"
show "!!cs. PROP ?Q (x # xs) bs cs"
proof (induct bs)
fix y ys cs assume I2: "!!cs. PROP ?Q (x # xs) ys cs"
show "PROP ?Q (x # xs) (y # ys) cs"
by (induct cs) (auto intro: tr I1 I2)
qed simp
qed simp
lemma list_all2_all_nthI [intro?]:
"length a = length b \<Longrightarrow> (\<And>n. n < length a \<Longrightarrow> P (a!n) (b!n)) \<Longrightarrow> list_all2 P a b"
by (simp add: list_all2_conv_all_nth)
lemma list_all2I:
"\<forall>x \<in> set (zip a b). split P x \<Longrightarrow> length a = length b \<Longrightarrow> list_all2 P a b"
by (simp add: list_all2_def)
lemma list_all2_nthD:
"\<lbrakk> list_all2 P xs ys; p < size xs \<rbrakk> \<Longrightarrow> P (xs!p) (ys!p)"
by (simp add: list_all2_conv_all_nth)
lemma list_all2_nthD2:
"\<lbrakk>list_all2 P xs ys; p < size ys\<rbrakk> \<Longrightarrow> P (xs!p) (ys!p)"
by (frule list_all2_lengthD) (auto intro: list_all2_nthD)
lemma list_all2_map1:
"list_all2 P (map f as) bs = list_all2 (\<lambda>x y. P (f x) y) as bs"
by (simp add: list_all2_conv_all_nth)
lemma list_all2_map2:
"list_all2 P as (map f bs) = list_all2 (\<lambda>x y. P x (f y)) as bs"
by (auto simp add: list_all2_conv_all_nth)
lemma list_all2_refl [intro?]:
"(\<And>x. P x x) \<Longrightarrow> list_all2 P xs xs"
by (simp add: list_all2_conv_all_nth)
lemma list_all2_update_cong:
"\<lbrakk> i<size xs; list_all2 P xs ys; P x y \<rbrakk> \<Longrightarrow> list_all2 P (xs[i:=x]) (ys[i:=y])"
by (simp add: list_all2_conv_all_nth nth_list_update)
lemma list_all2_update_cong2:
"\<lbrakk>list_all2 P xs ys; P x y; i < length ys\<rbrakk> \<Longrightarrow> list_all2 P (xs[i:=x]) (ys[i:=y])"
by (simp add: list_all2_lengthD list_all2_update_cong)
lemma list_all2_takeI [simp,intro?]:
"\<And>n ys. list_all2 P xs ys \<Longrightarrow> list_all2 P (take n xs) (take n ys)"
apply (induct xs)
apply simp
apply (clarsimp simp add: list_all2_Cons1)
apply (case_tac n)
apply auto
done
lemma list_all2_dropI [simp,intro?]:
"\<And>n bs. list_all2 P as bs \<Longrightarrow> list_all2 P (drop n as) (drop n bs)"
apply (induct as, simp)
apply (clarsimp simp add: list_all2_Cons1)
apply (case_tac n, simp, simp)
done
lemma list_all2_mono [intro?]:
"\<And>y. list_all2 P x y \<Longrightarrow> (\<And>x y. P x y \<Longrightarrow> Q x y) \<Longrightarrow> list_all2 Q x y"
apply (induct x, simp)
apply (case_tac y, auto)
done
subsubsection {* @{text foldl} and @{text foldr} *}
lemma foldl_append [simp]:
"!!a. foldl f a (xs @ ys) = foldl f (foldl f a xs) ys"
by (induct xs) auto
lemma foldr_append[simp]: "foldr f (xs @ ys) a = foldr f xs (foldr f ys a)"
by (induct xs) auto
lemma foldl_cong [recdef_cong]:
"[| a = b; l = k; !!a x. x : set l ==> f a x = g a x |]
==> foldl f a l = foldl g b k"
by (induct k fixing: a b l, simp_all)
lemma foldr_cong [recdef_cong]:
"[| a = b; l = k; !!a x. x : set l ==> f x a = g x a |]
==> foldr f l a = foldr g k b"
by (induct k fixing: a b l, simp_all)
lemma foldr_foldl: "foldr f xs a = foldl (%x y. f y x) a (rev xs)"
by (induct xs) auto
lemma foldl_foldr: "foldl f a xs = foldr (%x y. f y x) (rev xs) a"
by (simp add: foldr_foldl [of "%x y. f y x" "rev xs"])
text {*
Note: @{text "n \<le> foldl (op +) n ns"} looks simpler, but is more
difficult to use because it requires an additional transitivity step.
*}
lemma start_le_sum: "!!n::nat. m <= n ==> m <= foldl (op +) n ns"
by (induct ns) auto
lemma elem_le_sum: "!!n::nat. n : set ns ==> n <= foldl (op +) 0 ns"
by (force intro: start_le_sum simp add: in_set_conv_decomp)
lemma sum_eq_0_conv [iff]:
"!!m::nat. (foldl (op +) m ns = 0) = (m = 0 \<and> (\<forall>n \<in> set ns. n = 0))"
by (induct ns) auto
subsubsection {* @{text upto} *}
lemma upt_rec[code]: "[i..<j] = (if i<j then i#[Suc i..<j] else [])"
-- {* simp does not terminate! *}
by (induct j) auto
lemma upt_conv_Nil [simp]: "j <= i ==> [i..<j] = []"
by (subst upt_rec) simp
lemma upt_eq_Nil_conv[simp]: "([i..<j] = []) = (j = 0 \<or> j <= i)"
by(induct j)simp_all
lemma upt_eq_Cons_conv:
"!!x xs. ([i..<j] = x#xs) = (i < j & i = x & [i+1..<j] = xs)"
apply(induct j)
apply simp
apply(clarsimp simp add: append_eq_Cons_conv)
apply arith
done
lemma upt_Suc_append: "i <= j ==> [i..<(Suc j)] = [i..<j]@[j]"
-- {* Only needed if @{text upt_Suc} is deleted from the simpset. *}
by simp
lemma upt_conv_Cons: "i < j ==> [i..<j] = i # [Suc i..<j]"
apply(rule trans)
apply(subst upt_rec)
prefer 2 apply (rule refl, simp)
done
lemma upt_add_eq_append: "i<=j ==> [i..<j+k] = [i..<j]@[j..<j+k]"
-- {* LOOPS as a simprule, since @{text "j <= j"}. *}
by (induct k) auto
lemma length_upt [simp]: "length [i..<j] = j - i"
by (induct j) (auto simp add: Suc_diff_le)
lemma nth_upt [simp]: "i + k < j ==> [i..<j] ! k = i + k"
apply (induct j)
apply (auto simp add: less_Suc_eq nth_append split: nat_diff_split)
done
lemma hd_upt[simp]: "i < j \<Longrightarrow> hd[i..<j] = i"
by(simp add:upt_conv_Cons)
lemma last_upt[simp]: "i < j \<Longrightarrow> last[i..<j] = j - 1"
apply(cases j)
apply simp
by(simp add:upt_Suc_append)
lemma take_upt [simp]: "!!i. i+m <= n ==> take m [i..<n] = [i..<i+m]"
apply (induct m, simp)
apply (subst upt_rec)
apply (rule sym)
apply (subst upt_rec)
apply (simp del: upt.simps)
done
lemma drop_upt[simp]: "drop m [i..<j] = [i+m..<j]"
apply(induct j)
apply auto
apply arith
done
lemma map_Suc_upt: "map Suc [m..<n] = [Suc m..n]"
by (induct n) auto
lemma nth_map_upt: "!!i. i < n-m ==> (map f [m..<n]) ! i = f(m+i)"
apply (induct n m rule: diff_induct)
prefer 3 apply (subst map_Suc_upt[symmetric])
apply (auto simp add: less_diff_conv nth_upt)
done
lemma nth_take_lemma:
"!!xs ys. k <= length xs ==> k <= length ys ==>
(!!i. i < k --> xs!i = ys!i) ==> take k xs = take k ys"
apply (atomize, induct k)
apply (simp_all add: less_Suc_eq_0_disj all_conj_distrib, clarify)
txt {* Both lists must be non-empty *}
apply (case_tac xs, simp)
apply (case_tac ys, clarify)
apply (simp (no_asm_use))
apply clarify
txt {* prenexing's needed, not miniscoping *}
apply (simp (no_asm_use) add: all_simps [symmetric] del: all_simps)
apply blast
done
lemma nth_equalityI:
"[| length xs = length ys; ALL i < length xs. xs!i = ys!i |] ==> xs = ys"
apply (frule nth_take_lemma [OF le_refl eq_imp_le])
apply (simp_all add: take_all)
done
(* needs nth_equalityI *)
lemma list_all2_antisym:
"\<lbrakk> (\<And>x y. \<lbrakk>P x y; Q y x\<rbrakk> \<Longrightarrow> x = y); list_all2 P xs ys; list_all2 Q ys xs \<rbrakk>
\<Longrightarrow> xs = ys"
apply (simp add: list_all2_conv_all_nth)
apply (rule nth_equalityI, blast, simp)
done
lemma take_equalityI: "(\<forall>i. take i xs = take i ys) ==> xs = ys"
-- {* The famous take-lemma. *}
apply (drule_tac x = "max (length xs) (length ys)" in spec)
apply (simp add: le_max_iff_disj take_all)
done
lemma take_Cons':
"take n (x # xs) = (if n = 0 then [] else x # take (n - 1) xs)"
by (cases n) simp_all
lemma drop_Cons':
"drop n (x # xs) = (if n = 0 then x # xs else drop (n - 1) xs)"
by (cases n) simp_all
lemma nth_Cons': "(x # xs)!n = (if n = 0 then x else xs!(n - 1))"
by (cases n) simp_all
lemmas take_Cons_number_of = take_Cons'[of "number_of v",standard]
lemmas drop_Cons_number_of = drop_Cons'[of "number_of v",standard]
lemmas nth_Cons_number_of = nth_Cons'[of _ _ "number_of v",standard]
declare take_Cons_number_of [simp]
drop_Cons_number_of [simp]
nth_Cons_number_of [simp]
subsubsection {* @{text "distinct"} and @{text remdups} *}
lemma distinct_append [simp]:
"distinct (xs @ ys) = (distinct xs \<and> distinct ys \<and> set xs \<inter> set ys = {})"
by (induct xs) auto
lemma distinct_rev[simp]: "distinct(rev xs) = distinct xs"
by(induct xs) auto
lemma set_remdups [simp]: "set (remdups xs) = set xs"
by (induct xs) (auto simp add: insert_absorb)
lemma distinct_remdups [iff]: "distinct (remdups xs)"
by (induct xs) auto
lemma remdups_eq_nil_iff [simp]: "(remdups x = []) = (x = [])"
by (induct x, auto)
lemma remdups_eq_nil_right_iff [simp]: "([] = remdups x) = (x = [])"
by (induct x, auto)
lemma length_remdups_leq[iff]: "length(remdups xs) <= length xs"
by (induct xs) auto
lemma length_remdups_eq[iff]:
"(length (remdups xs) = length xs) = (remdups xs = xs)"
apply(induct xs)
apply auto
apply(subgoal_tac "length (remdups xs) <= length xs")
apply arith
apply(rule length_remdups_leq)
done
lemma distinct_map:
"distinct(map f xs) = (distinct xs & inj_on f (set xs))"
by (induct xs) auto
lemma distinct_filter [simp]: "distinct xs ==> distinct (filter P xs)"
by (induct xs) auto
lemma distinct_upt[simp]: "distinct[i..<j]"
by (induct j) auto
lemma distinct_take[simp]: "\<And>i. distinct xs \<Longrightarrow> distinct (take i xs)"
apply(induct xs)
apply simp
apply (case_tac i)
apply simp_all
apply(blast dest:in_set_takeD)
done
lemma distinct_drop[simp]: "\<And>i. distinct xs \<Longrightarrow> distinct (drop i xs)"
apply(induct xs)
apply simp
apply (case_tac i)
apply simp_all
done
lemma distinct_list_update:
assumes d: "distinct xs" and a: "a \<notin> set xs - {xs!i}"
shows "distinct (xs[i:=a])"
proof (cases "i < length xs")
case True
with a have "a \<notin> set (take i xs @ xs ! i # drop (Suc i) xs) - {xs!i}"
apply (drule_tac id_take_nth_drop) by simp
with d True show ?thesis
apply (simp add: upd_conv_take_nth_drop)
apply (drule subst [OF id_take_nth_drop]) apply assumption
apply simp apply (cases "a = xs!i") apply simp by blast
next
case False with d show ?thesis by auto
qed
text {* It is best to avoid this indexed version of distinct, but
sometimes it is useful. *}
lemma distinct_conv_nth:
"distinct xs = (\<forall>i < size xs. \<forall>j < size xs. i \<noteq> j --> xs!i \<noteq> xs!j)"
apply (induct xs, simp, simp)
apply (rule iffI, clarsimp)
apply (case_tac i)
apply (case_tac j, simp)
apply (simp add: set_conv_nth)
apply (case_tac j)
apply (clarsimp simp add: set_conv_nth, simp)
apply (rule conjI)
apply (clarsimp simp add: set_conv_nth)
apply (erule_tac x = 0 in allE, simp)
apply (erule_tac x = "Suc i" in allE, simp, clarsimp)
apply (erule_tac x = "Suc i" in allE, simp)
apply (erule_tac x = "Suc j" in allE, simp)
done
lemma nth_eq_iff_index_eq:
"\<lbrakk> distinct xs; i < length xs; j < length xs \<rbrakk> \<Longrightarrow> (xs!i = xs!j) = (i = j)"
by(auto simp: distinct_conv_nth)
lemma distinct_card: "distinct xs ==> card (set xs) = size xs"
by (induct xs) auto
lemma card_distinct: "card (set xs) = size xs ==> distinct xs"
proof (induct xs)
case Nil thus ?case by simp
next
case (Cons x xs)
show ?case
proof (cases "x \<in> set xs")
case False with Cons show ?thesis by simp
next
case True with Cons.prems
have "card (set xs) = Suc (length xs)"
by (simp add: card_insert_if split: split_if_asm)
moreover have "card (set xs) \<le> length xs" by (rule card_length)
ultimately have False by simp
thus ?thesis ..
qed
qed
lemma length_remdups_concat:
"length(remdups(concat xss)) = card(\<Union>xs \<in> set xss. set xs)"
by(simp add: distinct_card[symmetric])
subsubsection {* @{text remove1} *}
lemma remove1_append:
"remove1 x (xs @ ys) =
(if x \<in> set xs then remove1 x xs @ ys else xs @ remove1 x ys)"
by (induct xs) auto
lemma set_remove1_subset: "set(remove1 x xs) <= set xs"
apply(induct xs)
apply simp
apply simp
apply blast
done
lemma set_remove1_eq [simp]: "distinct xs ==> set(remove1 x xs) = set xs - {x}"
apply(induct xs)
apply simp
apply simp
apply blast
done
lemma remove1_filter_not[simp]:
"\<not> P x \<Longrightarrow> remove1 x (filter P xs) = filter P xs"
by(induct xs) auto
lemma notin_set_remove1[simp]: "x ~: set xs ==> x ~: set(remove1 y xs)"
apply(insert set_remove1_subset)
apply fast
done
lemma distinct_remove1[simp]: "distinct xs ==> distinct(remove1 x xs)"
by (induct xs) simp_all
subsubsection {* @{text replicate} *}
lemma length_replicate [simp]: "length (replicate n x) = n"
by (induct n) auto
lemma map_replicate [simp]: "map f (replicate n x) = replicate n (f x)"
by (induct n) auto
lemma replicate_app_Cons_same:
"(replicate n x) @ (x # xs) = x # replicate n x @ xs"
by (induct n) auto
lemma rev_replicate [simp]: "rev (replicate n x) = replicate n x"
apply (induct n, simp)
apply (simp add: replicate_app_Cons_same)
done
lemma replicate_add: "replicate (n + m) x = replicate n x @ replicate m x"
by (induct n) auto
text{* Courtesy of Matthias Daum: *}
lemma append_replicate_commute:
"replicate n x @ replicate k x = replicate k x @ replicate n x"
apply (simp add: replicate_add [THEN sym])
apply (simp add: add_commute)
done
lemma hd_replicate [simp]: "n \<noteq> 0 ==> hd (replicate n x) = x"
by (induct n) auto
lemma tl_replicate [simp]: "n \<noteq> 0 ==> tl (replicate n x) = replicate (n - 1) x"
by (induct n) auto
lemma last_replicate [simp]: "n \<noteq> 0 ==> last (replicate n x) = x"
by (atomize (full), induct n) auto
lemma nth_replicate[simp]: "!!i. i < n ==> (replicate n x)!i = x"
apply (induct n, simp)
apply (simp add: nth_Cons split: nat.split)
done
text{* Courtesy of Matthias Daum (2 lemmas): *}
lemma take_replicate[simp]: "take i (replicate k x) = replicate (min i k) x"
apply (case_tac "k \<le> i")
apply (simp add: min_def)
apply (drule not_leE)
apply (simp add: min_def)
apply (subgoal_tac "replicate k x = replicate i x @ replicate (k - i) x")
apply simp
apply (simp add: replicate_add [symmetric])
done
lemma drop_replicate[simp]: "!!i. drop i (replicate k x) = replicate (k-i) x"
apply (induct k)
apply simp
apply clarsimp
apply (case_tac i)
apply simp
apply clarsimp
done
lemma set_replicate_Suc: "set (replicate (Suc n) x) = {x}"
by (induct n) auto
lemma set_replicate [simp]: "n \<noteq> 0 ==> set (replicate n x) = {x}"
by (fast dest!: not0_implies_Suc intro!: set_replicate_Suc)
lemma set_replicate_conv_if: "set (replicate n x) = (if n = 0 then {} else {x})"
by auto
lemma in_set_replicateD: "x : set (replicate n y) ==> x = y"
by (simp add: set_replicate_conv_if split: split_if_asm)
subsubsection{*@{text rotate1} and @{text rotate}*}
lemma rotate_simps[simp]: "rotate1 [] = [] \<and> rotate1 (x#xs) = xs @ [x]"
by(simp add:rotate1_def)
lemma rotate0[simp]: "rotate 0 = id"
by(simp add:rotate_def)
lemma rotate_Suc[simp]: "rotate (Suc n) xs = rotate1(rotate n xs)"
by(simp add:rotate_def)
lemma rotate_add:
"rotate (m+n) = rotate m o rotate n"
by(simp add:rotate_def funpow_add)
lemma rotate_rotate: "rotate m (rotate n xs) = rotate (m+n) xs"
by(simp add:rotate_add)
lemma rotate1_rotate_swap: "rotate1 (rotate n xs) = rotate n (rotate1 xs)"
by(simp add:rotate_def funpow_swap1)
lemma rotate1_length01[simp]: "length xs <= 1 \<Longrightarrow> rotate1 xs = xs"
by(cases xs) simp_all
lemma rotate_length01[simp]: "length xs <= 1 \<Longrightarrow> rotate n xs = xs"
apply(induct n)
apply simp
apply (simp add:rotate_def)
done
lemma rotate1_hd_tl: "xs \<noteq> [] \<Longrightarrow> rotate1 xs = tl xs @ [hd xs]"
by(simp add:rotate1_def split:list.split)
lemma rotate_drop_take:
"rotate n xs = drop (n mod length xs) xs @ take (n mod length xs) xs"
apply(induct n)
apply simp
apply(simp add:rotate_def)
apply(cases "xs = []")
apply (simp)
apply(case_tac "n mod length xs = 0")
apply(simp add:mod_Suc)
apply(simp add: rotate1_hd_tl drop_Suc take_Suc)
apply(simp add:mod_Suc rotate1_hd_tl drop_Suc[symmetric] drop_tl[symmetric]
take_hd_drop linorder_not_le)
done
lemma rotate_conv_mod: "rotate n xs = rotate (n mod length xs) xs"
by(simp add:rotate_drop_take)
lemma rotate_id[simp]: "n mod length xs = 0 \<Longrightarrow> rotate n xs = xs"
by(simp add:rotate_drop_take)
lemma length_rotate1[simp]: "length(rotate1 xs) = length xs"
by(simp add:rotate1_def split:list.split)
lemma length_rotate[simp]: "!!xs. length(rotate n xs) = length xs"
by (induct n) (simp_all add:rotate_def)
lemma distinct1_rotate[simp]: "distinct(rotate1 xs) = distinct xs"
by(simp add:rotate1_def split:list.split) blast
lemma distinct_rotate[simp]: "distinct(rotate n xs) = distinct xs"
by (induct n) (simp_all add:rotate_def)
lemma rotate_map: "rotate n (map f xs) = map f (rotate n xs)"
by(simp add:rotate_drop_take take_map drop_map)
lemma set_rotate1[simp]: "set(rotate1 xs) = set xs"
by(simp add:rotate1_def split:list.split)
lemma set_rotate[simp]: "set(rotate n xs) = set xs"
by (induct n) (simp_all add:rotate_def)
lemma rotate1_is_Nil_conv[simp]: "(rotate1 xs = []) = (xs = [])"
by(simp add:rotate1_def split:list.split)
lemma rotate_is_Nil_conv[simp]: "(rotate n xs = []) = (xs = [])"
by (induct n) (simp_all add:rotate_def)
lemma rotate_rev:
"rotate n (rev xs) = rev(rotate (length xs - (n mod length xs)) xs)"
apply(simp add:rotate_drop_take rev_drop rev_take)
apply(cases "length xs = 0")
apply simp
apply(cases "n mod length xs = 0")
apply simp
apply(simp add:rotate_drop_take rev_drop rev_take)
done
lemma hd_rotate_conv_nth: "xs \<noteq> [] \<Longrightarrow> hd(rotate n xs) = xs!(n mod length xs)"
apply(simp add:rotate_drop_take hd_append hd_drop_conv_nth hd_conv_nth)
apply(subgoal_tac "length xs \<noteq> 0")
prefer 2 apply simp
using mod_less_divisor[of "length xs" n] by arith
subsubsection {* @{text sublist} --- a generalization of @{text nth} to sets *}
lemma sublist_empty [simp]: "sublist xs {} = []"
by (auto simp add: sublist_def)
lemma sublist_nil [simp]: "sublist [] A = []"
by (auto simp add: sublist_def)
lemma length_sublist:
"length(sublist xs I) = card{i. i < length xs \<and> i : I}"
by(simp add: sublist_def length_filter_conv_card cong:conj_cong)
lemma sublist_shift_lemma_Suc:
"!!is. map fst (filter (%p. P(Suc(snd p))) (zip xs is)) =
map fst (filter (%p. P(snd p)) (zip xs (map Suc is)))"
apply(induct xs)
apply simp
apply (case_tac "is")
apply simp
apply simp
done
lemma sublist_shift_lemma:
"map fst [p:zip xs [i..<i + length xs] . snd p : A] =
map fst [p:zip xs [0..<length xs] . snd p + i : A]"
by (induct xs rule: rev_induct) (simp_all add: add_commute)
lemma sublist_append:
"sublist (l @ l') A = sublist l A @ sublist l' {j. j + length l : A}"
apply (unfold sublist_def)
apply (induct l' rule: rev_induct, simp)
apply (simp add: upt_add_eq_append[of 0] zip_append sublist_shift_lemma)
apply (simp add: add_commute)
done
lemma sublist_Cons:
"sublist (x # l) A = (if 0:A then [x] else []) @ sublist l {j. Suc j : A}"
apply (induct l rule: rev_induct)
apply (simp add: sublist_def)
apply (simp del: append_Cons add: append_Cons[symmetric] sublist_append)
done
lemma set_sublist: "!!I. set(sublist xs I) = {xs!i|i. i<size xs \<and> i \<in> I}"
apply(induct xs)
apply simp
apply(auto simp add:sublist_Cons nth_Cons split:nat.split elim: lessE)
apply(erule lessE)
apply auto
apply(erule lessE)
apply auto
done
lemma set_sublist_subset: "set(sublist xs I) \<subseteq> set xs"
by(auto simp add:set_sublist)
lemma notin_set_sublistI[simp]: "x \<notin> set xs \<Longrightarrow> x \<notin> set(sublist xs I)"
by(auto simp add:set_sublist)
lemma in_set_sublistD: "x \<in> set(sublist xs I) \<Longrightarrow> x \<in> set xs"
by(auto simp add:set_sublist)
lemma sublist_singleton [simp]: "sublist [x] A = (if 0 : A then [x] else [])"
by (simp add: sublist_Cons)
lemma distinct_sublistI[simp]: "!!I. distinct xs \<Longrightarrow> distinct(sublist xs I)"
apply(induct xs)
apply simp
apply(auto simp add:sublist_Cons)
done
lemma sublist_upt_eq_take [simp]: "sublist l {..<n} = take n l"
apply (induct l rule: rev_induct, simp)
apply (simp split: nat_diff_split add: sublist_append)
done
lemma filter_in_sublist: "\<And>s. distinct xs \<Longrightarrow>
filter (%x. x \<in> set(sublist xs s)) xs = sublist xs s"
proof (induct xs)
case Nil thus ?case by simp
next
case (Cons a xs)
moreover hence "!x. x: set xs \<longrightarrow> x \<noteq> a" by auto
ultimately show ?case by(simp add: sublist_Cons cong:filter_cong)
qed
subsubsection {* @{const splice} *}
lemma splice_Nil2[simp]:
"splice xs [] = xs"
by (cases xs) simp_all
lemma splice_Cons_Cons[simp]:
"splice (x#xs) (y#ys) = x # y # splice xs ys"
by simp
declare splice.simps(2)[simp del]
subsubsection{*Sets of Lists*}
subsubsection {* @{text lists}: the list-forming operator over sets *}
consts lists :: "'a set => 'a list set"
inductive "lists A"
intros
Nil [intro!]: "[]: lists A"
Cons [intro!]: "[| a: A;l: lists A|] ==> a#l : lists A"
inductive_cases listsE [elim!]: "x#l : lists A"
lemma lists_mono [mono]: "A \<subseteq> B ==> lists A \<subseteq> lists B"
by (unfold lists.defs) (blast intro!: lfp_mono)
lemma lists_IntI:
assumes l: "l: lists A" shows "l: lists B ==> l: lists (A Int B)" using l
by induct blast+
lemma lists_Int_eq [simp]: "lists (A \<inter> B) = lists A \<inter> lists B"
proof (rule mono_Int [THEN equalityI])
show "mono lists" by (simp add: mono_def lists_mono)
show "lists A \<inter> lists B \<subseteq> lists (A \<inter> B)" by (blast intro: lists_IntI)
qed
lemma append_in_lists_conv [iff]:
"(xs @ ys : lists A) = (xs : lists A \<and> ys : lists A)"
by (induct xs) auto
lemma in_lists_conv_set: "(xs : lists A) = (\<forall>x \<in> set xs. x : A)"
-- {* eliminate @{text lists} in favour of @{text set} *}
by (induct xs) auto
lemma in_listsD [dest!]: "xs \<in> lists A ==> \<forall>x\<in>set xs. x \<in> A"
by (rule in_lists_conv_set [THEN iffD1])
lemma in_listsI [intro!]: "\<forall>x\<in>set xs. x \<in> A ==> xs \<in> lists A"
by (rule in_lists_conv_set [THEN iffD2])
lemma lists_UNIV [simp]: "lists UNIV = UNIV"
by auto
subsubsection {* For efficiency *}
text{* Only use @{text mem} for generating executable code. Otherwise
use @{prop"x : set xs"} instead --- it is much easier to reason about.
The same is true for @{const list_all} and @{const list_ex}: write
@{text"\<forall>x\<in>set xs"} and @{text"\<exists>x\<in>set xs"} instead because the HOL
quantifiers are aleady known to the automatic provers. In fact, the declarations in the Code subsection make sure that @{text"\<in>"}, @{text"\<forall>x\<in>set xs"}
and @{text"\<exists>x\<in>set xs"} are implemented efficiently.
The functions @{const itrev}, @{const filtermap} and @{const
map_filter} are just there to generate efficient code. Do not use them
for modelling and proving. *}
lemma mem_iff: "(x mem xs) = (x : set xs)"
by (induct xs) auto
lemma list_inter_conv: "set(list_inter xs ys) = set xs \<inter> set ys"
by (induct xs) auto
lemma list_all_iff: "list_all P xs = (\<forall>x \<in> set xs. P x)"
by (induct xs) auto
lemma list_all_append [simp]:
"list_all P (xs @ ys) = (list_all P xs \<and> list_all P ys)"
by (induct xs) auto
lemma list_all_rev [simp]: "list_all P (rev xs) = list_all P xs"
by (simp add: list_all_iff)
lemma list_ex_iff: "list_ex P xs = (\<exists>x \<in> set xs. P x)"
by (induct xs) simp_all
lemma itrev[simp]: "ALL ys. itrev xs ys = rev xs @ ys"
by (induct xs) simp_all
lemma filtermap_conv:
"filtermap f xs = map (%x. the(f x)) (filter (%x. f x \<noteq> None) xs)"
by (induct xs) (simp_all split: option.split)
lemma map_filter_conv[simp]: "map_filter f P xs = map f (filter P xs)"
by (induct xs) auto
subsubsection {* Code generation *}
text{* Defaults for generating efficient code for some standard functions. *}
lemmas in_set_code[code unfold] = mem_iff[symmetric, THEN eq_reflection]
lemma rev_code[code unfold]: "rev xs == itrev xs []"
by simp
lemma distinct_Cons_mem[code]: "distinct (x#xs) = (~(x mem xs) \<and> distinct xs)"
by (simp add:mem_iff)
lemma remdups_Cons_mem[code]:
"remdups (x#xs) = (if x mem xs then remdups xs else x # remdups xs)"
by (simp add:mem_iff)
lemma list_inter_Cons_mem[code]: "list_inter (a#as) bs =
(if a mem bs then a#(list_inter as bs) else list_inter as bs)"
by(simp add:mem_iff)
text{* For implementing bounded quantifiers over lists by
@{const list_ex}/@{const list_all}: *}
lemmas list_bex_code[code unfold] = list_ex_iff[symmetric, THEN eq_reflection]
lemmas list_ball_code[code unfold] = list_all_iff[symmetric, THEN eq_reflection]
subsubsection{* Inductive definition for membership *}
consts ListMem :: "('a \<times> 'a list)set"
inductive ListMem
intros
elem: "(x,x#xs) \<in> ListMem"
insert: "(x,xs) \<in> ListMem \<Longrightarrow> (x,y#xs) \<in> ListMem"
lemma ListMem_iff: "((x,xs) \<in> ListMem) = (x \<in> set xs)"
apply (rule iffI)
apply (induct set: ListMem)
apply auto
apply (induct xs)
apply (auto intro: ListMem.intros)
done
subsubsection{*Lists as Cartesian products*}
text{*@{text"set_Cons A Xs"}: the set of lists with head drawn from
@{term A} and tail drawn from @{term Xs}.*}
constdefs
set_Cons :: "'a set \<Rightarrow> 'a list set \<Rightarrow> 'a list set"
"set_Cons A XS == {z. \<exists>x xs. z = x#xs & x \<in> A & xs \<in> XS}"
lemma set_Cons_sing_Nil [simp]: "set_Cons A {[]} = (%x. [x])`A"
by (auto simp add: set_Cons_def)
text{*Yields the set of lists, all of the same length as the argument and
with elements drawn from the corresponding element of the argument.*}
consts listset :: "'a set list \<Rightarrow> 'a list set"
primrec
"listset [] = {[]}"
"listset(A#As) = set_Cons A (listset As)"
subsection{*Relations on Lists*}
subsubsection {* Length Lexicographic Ordering *}
text{*These orderings preserve well-foundedness: shorter lists
precede longer lists. These ordering are not used in dictionaries.*}
consts lexn :: "('a * 'a)set => nat => ('a list * 'a list)set"
--{*The lexicographic ordering for lists of the specified length*}
primrec
"lexn r 0 = {}"
"lexn r (Suc n) =
(prod_fun (%(x,xs). x#xs) (%(x,xs). x#xs) ` (r <*lex*> lexn r n)) Int
{(xs,ys). length xs = Suc n \<and> length ys = Suc n}"
constdefs
lex :: "('a \<times> 'a) set => ('a list \<times> 'a list) set"
"lex r == \<Union>n. lexn r n"
--{*Holds only between lists of the same length*}
lenlex :: "('a \<times> 'a) set => ('a list \<times> 'a list) set"
"lenlex r == inv_image (less_than <*lex*> lex r) (%xs. (length xs, xs))"
--{*Compares lists by their length and then lexicographically*}
lemma wf_lexn: "wf r ==> wf (lexn r n)"
apply (induct n, simp, simp)
apply(rule wf_subset)
prefer 2 apply (rule Int_lower1)
apply(rule wf_prod_fun_image)
prefer 2 apply (rule inj_onI, auto)
done
lemma lexn_length:
"!!xs ys. (xs, ys) : lexn r n ==> length xs = n \<and> length ys = n"
by (induct n) auto
lemma wf_lex [intro!]: "wf r ==> wf (lex r)"
apply (unfold lex_def)
apply (rule wf_UN)
apply (blast intro: wf_lexn, clarify)
apply (rename_tac m n)
apply (subgoal_tac "m \<noteq> n")
prefer 2 apply blast
apply (blast dest: lexn_length not_sym)
done
lemma lexn_conv:
"lexn r n =
{(xs,ys). length xs = n \<and> length ys = n \<and>
(\<exists>xys x y xs' ys'. xs= xys @ x#xs' \<and> ys= xys @ y # ys' \<and> (x, y):r)}"
apply (induct n, simp)
apply (simp add: image_Collect lex_prod_def, safe, blast)
apply (rule_tac x = "ab # xys" in exI, simp)
apply (case_tac xys, simp_all, blast)
done
lemma lex_conv:
"lex r =
{(xs,ys). length xs = length ys \<and>
(\<exists>xys x y xs' ys'. xs = xys @ x # xs' \<and> ys = xys @ y # ys' \<and> (x, y):r)}"
by (force simp add: lex_def lexn_conv)
lemma wf_lenlex [intro!]: "wf r ==> wf (lenlex r)"
by (unfold lenlex_def) blast
lemma lenlex_conv:
"lenlex r = {(xs,ys). length xs < length ys |
length xs = length ys \<and> (xs, ys) : lex r}"
by (simp add: lenlex_def diag_def lex_prod_def measure_def inv_image_def)
lemma Nil_notin_lex [iff]: "([], ys) \<notin> lex r"
by (simp add: lex_conv)
lemma Nil2_notin_lex [iff]: "(xs, []) \<notin> lex r"
by (simp add:lex_conv)
lemma Cons_in_lex [simp]:
"((x # xs, y # ys) : lex r) =
((x, y) : r \<and> length xs = length ys | x = y \<and> (xs, ys) : lex r)"
apply (simp add: lex_conv)
apply (rule iffI)
prefer 2 apply (blast intro: Cons_eq_appendI, clarify)
apply (case_tac xys, simp, simp)
apply blast
done
subsubsection {* Lexicographic Ordering *}
text {* Classical lexicographic ordering on lists, ie. "a" < "ab" < "b".
This ordering does \emph{not} preserve well-foundedness.
Author: N. Voelker, March 2005. *}
constdefs
lexord :: "('a * 'a)set \<Rightarrow> ('a list * 'a list) set"
"lexord r == {(x,y). \<exists> a v. y = x @ a # v \<or>
(\<exists> u a b v w. (a,b) \<in> r \<and> x = u @ (a # v) \<and> y = u @ (b # w))}"
lemma lexord_Nil_left[simp]: "([],y) \<in> lexord r = (\<exists> a x. y = a # x)"
by (unfold lexord_def, induct_tac y, auto)
lemma lexord_Nil_right[simp]: "(x,[]) \<notin> lexord r"
by (unfold lexord_def, induct_tac x, auto)
lemma lexord_cons_cons[simp]:
"((a # x, b # y) \<in> lexord r) = ((a,b)\<in> r | (a = b & (x,y)\<in> lexord r))"
apply (unfold lexord_def, safe, simp_all)
apply (case_tac u, simp, simp)
apply (case_tac u, simp, clarsimp, blast, blast, clarsimp)
apply (erule_tac x="b # u" in allE)
by force
lemmas lexord_simps = lexord_Nil_left lexord_Nil_right lexord_cons_cons
lemma lexord_append_rightI: "\<exists> b z. y = b # z \<Longrightarrow> (x, x @ y) \<in> lexord r"
by (induct_tac x, auto)
lemma lexord_append_left_rightI:
"(a,b) \<in> r \<Longrightarrow> (u @ a # x, u @ b # y) \<in> lexord r"
by (induct_tac u, auto)
lemma lexord_append_leftI: " (u,v) \<in> lexord r \<Longrightarrow> (x @ u, x @ v) \<in> lexord r"
by (induct x, auto)
lemma lexord_append_leftD:
"\<lbrakk> (x @ u, x @ v) \<in> lexord r; (! a. (a,a) \<notin> r) \<rbrakk> \<Longrightarrow> (u,v) \<in> lexord r"
by (erule rev_mp, induct_tac x, auto)
lemma lexord_take_index_conv:
"((x,y) : lexord r) =
((length x < length y \<and> take (length x) y = x) \<or>
(\<exists>i. i < min(length x)(length y) & take i x = take i y & (x!i,y!i) \<in> r))"
apply (unfold lexord_def Let_def, clarsimp)
apply (rule_tac f = "(% a b. a \<or> b)" in arg_cong2)
apply auto
apply (rule_tac x="hd (drop (length x) y)" in exI)
apply (rule_tac x="tl (drop (length x) y)" in exI)
apply (erule subst, simp add: min_def)
apply (rule_tac x ="length u" in exI, simp)
apply (rule_tac x ="take i x" in exI)
apply (rule_tac x ="x ! i" in exI)
apply (rule_tac x ="y ! i" in exI, safe)
apply (rule_tac x="drop (Suc i) x" in exI)
apply (drule sym, simp add: drop_Suc_conv_tl)
apply (rule_tac x="drop (Suc i) y" in exI)
by (simp add: drop_Suc_conv_tl)
-- {* lexord is extension of partial ordering List.lex *}
lemma lexord_lex: " (x,y) \<in> lex r = ((x,y) \<in> lexord r \<and> length x = length y)"
apply (rule_tac x = y in spec)
apply (induct_tac x, clarsimp)
by (clarify, case_tac x, simp, force)
lemma lexord_irreflexive: "(! x. (x,x) \<notin> r) \<Longrightarrow> (y,y) \<notin> lexord r"
by (induct y, auto)
lemma lexord_trans:
"\<lbrakk> (x, y) \<in> lexord r; (y, z) \<in> lexord r; trans r \<rbrakk> \<Longrightarrow> (x, z) \<in> lexord r"
apply (erule rev_mp)+
apply (rule_tac x = x in spec)
apply (rule_tac x = z in spec)
apply ( induct_tac y, simp, clarify)
apply (case_tac xa, erule ssubst)
apply (erule allE, erule allE) -- {* avoid simp recursion *}
apply (case_tac x, simp, simp)
apply (case_tac x, erule allE, erule allE, simp)
apply (erule_tac x = listb in allE)
apply (erule_tac x = lista in allE, simp)
apply (unfold trans_def)
by blast
lemma lexord_transI: "trans r \<Longrightarrow> trans (lexord r)"
by (rule transI, drule lexord_trans, blast)
lemma lexord_linear: "(! a b. (a,b)\<in> r | a = b | (b,a) \<in> r) \<Longrightarrow> (x,y) : lexord r | x = y | (y,x) : lexord r"
apply (rule_tac x = y in spec)
apply (induct_tac x, rule allI)
apply (case_tac x, simp, simp)
apply (rule allI, case_tac x, simp, simp)
by blast
subsubsection{*Lifting a Relation on List Elements to the Lists*}
consts listrel :: "('a * 'a)set => ('a list * 'a list)set"
inductive "listrel(r)"
intros
Nil: "([],[]) \<in> listrel r"
Cons: "[| (x,y) \<in> r; (xs,ys) \<in> listrel r |] ==> (x#xs, y#ys) \<in> listrel r"
inductive_cases listrel_Nil1 [elim!]: "([],xs) \<in> listrel r"
inductive_cases listrel_Nil2 [elim!]: "(xs,[]) \<in> listrel r"
inductive_cases listrel_Cons1 [elim!]: "(y#ys,xs) \<in> listrel r"
inductive_cases listrel_Cons2 [elim!]: "(xs,y#ys) \<in> listrel r"
lemma listrel_mono: "r \<subseteq> s \<Longrightarrow> listrel r \<subseteq> listrel s"
apply clarify
apply (erule listrel.induct)
apply (blast intro: listrel.intros)+
done
lemma listrel_subset: "r \<subseteq> A \<times> A \<Longrightarrow> listrel r \<subseteq> lists A \<times> lists A"
apply clarify
apply (erule listrel.induct, auto)
done
lemma listrel_refl: "refl A r \<Longrightarrow> refl (lists A) (listrel r)"
apply (simp add: refl_def listrel_subset Ball_def)
apply (rule allI)
apply (induct_tac x)
apply (auto intro: listrel.intros)
done
lemma listrel_sym: "sym r \<Longrightarrow> sym (listrel r)"
apply (auto simp add: sym_def)
apply (erule listrel.induct)
apply (blast intro: listrel.intros)+
done
lemma listrel_trans: "trans r \<Longrightarrow> trans (listrel r)"
apply (simp add: trans_def)
apply (intro allI)
apply (rule impI)
apply (erule listrel.induct)
apply (blast intro: listrel.intros)+
done
theorem equiv_listrel: "equiv A r \<Longrightarrow> equiv (lists A) (listrel r)"
by (simp add: equiv_def listrel_refl listrel_sym listrel_trans)
lemma listrel_Nil [simp]: "listrel r `` {[]} = {[]}"
by (blast intro: listrel.intros)
lemma listrel_Cons:
"listrel r `` {x#xs} = set_Cons (r``{x}) (listrel r `` {xs})";
by (auto simp add: set_Cons_def intro: listrel.intros)
subsection{*Miscellany*}
subsubsection {* Characters and strings *}
datatype nibble =
Nibble0 | Nibble1 | Nibble2 | Nibble3 | Nibble4 | Nibble5 | Nibble6 | Nibble7
| Nibble8 | Nibble9 | NibbleA | NibbleB | NibbleC | NibbleD | NibbleE | NibbleF
datatype char = Char nibble nibble
-- "Note: canonical order of character encoding coincides with standard term ordering"
types string = "char list"
syntax
"_Char" :: "xstr => char" ("CHR _")
"_String" :: "xstr => string" ("_")
parse_ast_translation {*
let
val constants = Syntax.Appl o map Syntax.Constant;
fun mk_nib n = "Nibble" ^ chr (n + (if n <= 9 then ord "0" else ord "A" - 10));
fun mk_char c =
if Symbol.is_ascii c andalso Symbol.is_printable c then
constants ["Char", mk_nib (ord c div 16), mk_nib (ord c mod 16)]
else error ("Printable ASCII character expected: " ^ quote c);
fun mk_string [] = Syntax.Constant "Nil"
| mk_string (c :: cs) = Syntax.Appl [Syntax.Constant "Cons", mk_char c, mk_string cs];
fun char_ast_tr [Syntax.Variable xstr] =
(case Syntax.explode_xstr xstr of
[c] => mk_char c
| _ => error ("Single character expected: " ^ xstr))
| char_ast_tr asts = raise AST ("char_ast_tr", asts);
fun string_ast_tr [Syntax.Variable xstr] =
(case Syntax.explode_xstr xstr of
[] => constants [Syntax.constrainC, "Nil", "string"]
| cs => mk_string cs)
| string_ast_tr asts = raise AST ("string_tr", asts);
in [("_Char", char_ast_tr), ("_String", string_ast_tr)] end;
*}
ML {*
fun int_of_nibble h =
if "0" <= h andalso h <= "9" then ord h - ord "0"
else if "A" <= h andalso h <= "F" then ord h - ord "A" + 10
else raise Match;
fun nibble_of_int i =
if i <= 9 then chr (ord "0" + i) else chr (ord "A" + i - 10);
*}
print_ast_translation {*
let
fun dest_nib (Syntax.Constant c) =
(case explode c of
["N", "i", "b", "b", "l", "e", h] => int_of_nibble h
| _ => raise Match)
| dest_nib _ = raise Match;
fun dest_chr c1 c2 =
let val c = chr (dest_nib c1 * 16 + dest_nib c2)
in if Symbol.is_printable c then c else raise Match end;
fun dest_char (Syntax.Appl [Syntax.Constant "Char", c1, c2]) = dest_chr c1 c2
| dest_char _ = raise Match;
fun xstr cs = Syntax.Appl [Syntax.Constant "_xstr", Syntax.Variable (Syntax.implode_xstr cs)];
fun char_ast_tr' [c1, c2] = Syntax.Appl [Syntax.Constant "_Char", xstr [dest_chr c1 c2]]
| char_ast_tr' _ = raise Match;
fun list_ast_tr' [args] = Syntax.Appl [Syntax.Constant "_String",
xstr (map dest_char (Syntax.unfold_ast "_args" args))]
| list_ast_tr' ts = raise Match;
in [("Char", char_ast_tr'), ("@list", list_ast_tr')] end;
*}
subsubsection {* Code generator setup *}
ML {*
local
fun list_codegen thy defs gr dep thyname b t =
let val (gr', ps) = foldl_map (Codegen.invoke_codegen thy defs dep thyname false)
(gr, HOLogic.dest_list t)
in SOME (gr', Pretty.list "[" "]" ps) end handle TERM _ => NONE;
fun dest_nibble (Const (s, _)) = int_of_nibble (unprefix "List.nibble.Nibble" s)
| dest_nibble _ = raise Match;
fun char_codegen thy defs gr dep thyname b (Const ("List.char.Char", _) $ c1 $ c2) =
(let val c = chr (dest_nibble c1 * 16 + dest_nibble c2)
in if Symbol.is_printable c then SOME (gr, Pretty.quote (Pretty.str c))
else NONE
end handle Fail _ => NONE | Match => NONE)
| char_codegen thy defs gr dep thyname b _ = NONE;
in
val list_codegen_setup =
Codegen.add_codegen "list_codegen" list_codegen #>
Codegen.add_codegen "char_codegen" char_codegen #>
fold (CodegenPackage.add_pretty_list "Nil" "Cons") [
("ml", (7, "::")),
("haskell", (5, ":"))];
end;
*}
types_code
"list" ("_ list")
attach (term_of) {*
val term_of_list = HOLogic.mk_list;
*}
attach (test) {*
fun gen_list' aG i j = frequency
[(i, fn () => aG j :: gen_list' aG (i-1) j), (1, fn () => [])] ()
and gen_list aG i = gen_list' aG i i;
*}
"char" ("string")
attach (term_of) {*
val nibbleT = Type ("List.nibble", []);
fun term_of_char c =
Const ("List.char.Char", nibbleT --> nibbleT --> Type ("List.char", [])) $
Const ("List.nibble.Nibble" ^ nibble_of_int (ord c div 16), nibbleT) $
Const ("List.nibble.Nibble" ^ nibble_of_int (ord c mod 16), nibbleT);
*}
attach (test) {*
fun gen_char i = chr (random_range (ord "a") (Int.min (ord "a" + i, ord "z")));
*}
consts_code "Cons" ("(_ ::/ _)")
code_alias
"List.op @" "List.append"
"List.op mem" "List.member"
code_generate Nil Cons
code_syntax_tyco
list
ml ("_ list")
haskell (target_atom "[_]")
code_syntax_const
Nil
ml (target_atom "[]")
haskell (target_atom "[]")
setup list_codegen_setup
setup CodegenPackage.rename_inconsistent
end