isabelle: src/HOL/List.thy@adeac3cbb659 (annotated)

13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	1	(* Title: HOL/List.thy
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	2	Author: Tobias Nipkow
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	3	*)
ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	4
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	5	header {* The datatype of finite lists *}
13122 c63612ffb186 oops; wenzelm parents: 13114 diff changeset	6
15131 c69542757a4d New theory header syntax. nipkow parents: 15113 diff changeset	7	theory List
30952 7ab2716dd93b power operation on functions with syntax o^; power operation on relations with syntax ^^ haftmann parents: 30949 diff changeset	8	imports Plain Presburger Recdef ATP_Linkup
31055 2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	9	uses ("Tools/list_code.ML")
15131 c69542757a4d New theory header syntax. nipkow parents: 15113 diff changeset	10	begin
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	11
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	12	datatype 'a list =
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	13	Nil ("[]")
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	14	\| Cons 'a "'a list" (infixr "#" 65)
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	15
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	16	subsection{Basic list processing functions}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	17
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	18	consts
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	19	filter:: "('a => bool) => 'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	20	concat:: "'a list list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	21	foldl :: "('b => 'a => 'b) => 'b => 'a list => 'b"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	22	foldr :: "('a => 'b => 'b) => 'a list => 'b => 'b"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	23	hd:: "'a list => 'a"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	24	tl:: "'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	25	last:: "'a list => 'a"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	26	butlast :: "'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	27	set :: "'a list => 'a set"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	28	map :: "('a=>'b) => ('a list => 'b list)"
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	29	listsum :: "'a list => 'a::monoid_add"
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	30	list_update :: "'a list => nat => 'a => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	31	take:: "nat => 'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	32	drop:: "nat => 'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	33	takeWhile :: "('a => bool) => 'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	34	dropWhile :: "('a => bool) => 'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	35	rev :: "'a list => 'a list"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	36	zip :: "'a list => 'b list => ('a * 'b) list"
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	37	upt :: "nat => nat => nat list" ("(1[_..</_'])")
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	38	remdups :: "'a list => 'a list"
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	39	remove1 :: "'a => 'a list => 'a list"
27693 73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	40	removeAll :: "'a => 'a list => 'a list"
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	41	"distinct":: "'a list => bool"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	42	replicate :: "nat => 'a => 'a list"
19390 6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	43	splice :: "'a list \<Rightarrow> 'a list \<Rightarrow> 'a list"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	44
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	45
13146 f43153b63361 * empty log message * nipkow parents: 13145 diff changeset	46	nonterminals lupdbinds lupdbind
5077 71043526295f * HOL/List: new function list_update written xs[i:=v] that updates the i-th nipkow parents: 4643 diff changeset	47
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	48	syntax
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	49	-- {* list Enumeration *}
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	50	"@list" :: "args => 'a list" ("[(_)]")
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	51
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	52	-- {* Special syntax for filter *}
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	53	"@filter" :: "[pttrn, 'a list, bool] => 'a list" ("(1[_<-_./ _])")
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	54
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	55	-- {* list update *}
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	56	"_lupdbind":: "['a, 'a] => lupdbind" ("(2_ :=/ _)")
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	57	"" :: "lupdbind => lupdbinds" ("_")
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	58	"_lupdbinds" :: "[lupdbind, lupdbinds] => lupdbinds" ("_,/ _")
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	59	"_LUpdate" :: "['a, lupdbinds] => 'a" ("_/[(_)]" [900,0] 900)
5077 71043526295f * HOL/List: new function list_update written xs[i:=v] that updates the i-th nipkow parents: 4643 diff changeset	60
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	61	translations
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	62	"[x, xs]" == "x#[xs]"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	63	"[x]" == "x#[]"
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	64	"[x<-xs . P]"== "filter (%x. P) xs"
923 ff1574a81019 new version of HOL with curried function application clasohm parents: diff changeset	65
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	66	"_LUpdate xs (_lupdbinds b bs)"== "_LUpdate (_LUpdate xs b) bs"
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	67	"xs[i:=x]" == "list_update xs i x"
5077 71043526295f * HOL/List: new function list_update written xs[i:=v] that updates the i-th nipkow parents: 4643 diff changeset	68
5427 26c9a7c0b36b Arith: less_diff_conv nipkow parents: 5425 diff changeset	69
12114 a8e860c86252 eliminated old "symbols" syntax, use "xsymbols" instead; wenzelm parents: 10832 diff changeset	70	syntax (xsymbols)
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	71	"@filter" :: "[pttrn, 'a list, bool] => 'a list"("(1[_\<leftarrow>_ ./ _])")
14565 c6dc17aab88a use more symbols in HTML output kleing parents: 14538 diff changeset	72	syntax (HTML output)
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	73	"@filter" :: "[pttrn, 'a list, bool] => 'a list"("(1[_\<leftarrow>_ ./ _])")
3342 ec3b55fcb165 New operator "lists" for formalizing sets of lists paulson parents: 3320 diff changeset	74
ec3b55fcb165 New operator "lists" for formalizing sets of lists paulson parents: 3320 diff changeset	75
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	76	text {*
14589 feae7b5fd425 tuned document; wenzelm parents: 14565 diff changeset	77	Function @{text size} is overloaded for all datatypes. Users may
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	78	refer to the list version as @{text length}. *}
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	79
19363 667b5ea637dd refined 'abbreviation'; wenzelm parents: 19302 diff changeset	80	abbreviation
21404 eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	81	length :: "'a list => nat" where
19363 667b5ea637dd refined 'abbreviation'; wenzelm parents: 19302 diff changeset	82	"length == size"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	83
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	84	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	85	"hd(x#xs) = x"
10dd989282fd indentation paulson parents: 15305 diff changeset	86
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	87	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	88	"tl([]) = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	89	"tl(x#xs) = xs"
10dd989282fd indentation paulson parents: 15305 diff changeset	90
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	91	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	92	"last(x#xs) = (if xs=[] then x else last xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	93
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	94	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	95	"butlast []= []"
10dd989282fd indentation paulson parents: 15305 diff changeset	96	"butlast(x#xs) = (if xs=[] then [] else x#butlast xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	97
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	98	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	99	"set [] = {}"
10dd989282fd indentation paulson parents: 15305 diff changeset	100	"set (x#xs) = insert x (set xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	101
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	102	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	103	"map f [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	104	"map f (x#xs) = f(x)#map f xs"
10dd989282fd indentation paulson parents: 15305 diff changeset	105
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	106	primrec
25559 f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	107	append :: "'a list \<Rightarrow> 'a list \<Rightarrow> 'a list" (infixr "@" 65)
f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	108	where
f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	109	append_Nil:"[] @ ys = ys"
f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	110	\| append_Cons: "(x#xs) @ ys = x # xs @ ys"
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	111
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	112	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	113	"rev([]) = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	114	"rev(x#xs) = rev(xs) @ [x]"
10dd989282fd indentation paulson parents: 15305 diff changeset	115
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	116	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	117	"filter P [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	118	"filter P (x#xs) = (if P x then x#filter P xs else filter P xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	119
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	120	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	121	foldl_Nil:"foldl f a [] = a"
10dd989282fd indentation paulson parents: 15305 diff changeset	122	foldl_Cons: "foldl f a (x#xs) = foldl f (f a x) xs"
10dd989282fd indentation paulson parents: 15305 diff changeset	123
8000 acafa0f15131 added foldr paulson parents: 7224 diff changeset	124	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	125	"foldr f [] a = a"
10dd989282fd indentation paulson parents: 15305 diff changeset	126	"foldr f (x#xs) a = f x (foldr f xs a)"
10dd989282fd indentation paulson parents: 15305 diff changeset	127
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	128	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	129	"concat([]) = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	130	"concat(x#xs) = x @ concat(xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	131
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	132	primrec
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	133	"listsum [] = 0"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	134	"listsum (x # xs) = x + listsum xs"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	135
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	136	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	137	drop_Nil:"drop n [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	138	drop_Cons: "drop n (x#xs) = (case n of 0 => x#xs \| Suc(m) => drop m xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	139	-- {*Warning: simpset does not contain this definition, but separate
10dd989282fd indentation paulson parents: 15305 diff changeset	140	theorems for @{text "n = 0"} and @{text "n = Suc k"} *}
10dd989282fd indentation paulson parents: 15305 diff changeset	141
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	142	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	143	take_Nil:"take n [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	144	take_Cons: "take n (x#xs) = (case n of 0 => [] \| Suc(m) => x # take m xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	145	-- {*Warning: simpset does not contain this definition, but separate
10dd989282fd indentation paulson parents: 15305 diff changeset	146	theorems for @{text "n = 0"} and @{text "n = Suc k"} *}
10dd989282fd indentation paulson parents: 15305 diff changeset	147
29822 c45845743f04 authentic syntax for List.nth haftmann parents: 29782 diff changeset	148	primrec nth :: "'a list => nat => 'a" (infixl "!" 100) where
c45845743f04 authentic syntax for List.nth haftmann parents: 29782 diff changeset	149	nth_Cons: "(x#xs)!n = (case n of 0 => x \| (Suc k) => xs!k)"
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	150	-- {*Warning: simpset does not contain this definition, but separate
10dd989282fd indentation paulson parents: 15305 diff changeset	151	theorems for @{text "n = 0"} and @{text "n = Suc k"} *}
10dd989282fd indentation paulson parents: 15305 diff changeset	152
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	153	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	154	"[][i:=v] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	155	"(x#xs)[i:=v] = (case i of 0 => v # xs \| Suc j => x # xs[j:=v])"
10dd989282fd indentation paulson parents: 15305 diff changeset	156
10dd989282fd indentation paulson parents: 15305 diff changeset	157	primrec
10dd989282fd indentation paulson parents: 15305 diff changeset	158	"takeWhile P [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	159	"takeWhile P (x#xs) = (if P x then x#takeWhile P xs else [])"
10dd989282fd indentation paulson parents: 15305 diff changeset	160
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	161	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	162	"dropWhile P [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	163	"dropWhile P (x#xs) = (if P x then dropWhile P xs else x#xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	164
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	165	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	166	"zip xs [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	167	zip_Cons: "zip xs (y#ys) = (case xs of [] => [] \| z#zs => (z,y)#zip zs ys)"
10dd989282fd indentation paulson parents: 15305 diff changeset	168	-- {*Warning: simpset does not contain this definition, but separate
10dd989282fd indentation paulson parents: 15305 diff changeset	169	theorems for @{text "xs = []"} and @{text "xs = z # zs"} *}
10dd989282fd indentation paulson parents: 15305 diff changeset	170
5427 26c9a7c0b36b Arith: less_diff_conv nipkow parents: 5425 diff changeset	171	primrec
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	172	upt_0: "[i..<0] = []"
6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	173	upt_Suc: "[i..<(Suc j)] = (if i <= j then [i..<j] @ [j] else [])"
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	174
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	175	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	176	"distinct [] = True"
10dd989282fd indentation paulson parents: 15305 diff changeset	177	"distinct (x#xs) = (x ~: set xs \<and> distinct xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	178
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	179	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	180	"remdups [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	181	"remdups (x#xs) = (if x : set xs then remdups xs else x # remdups xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	182
5183 89f162de39cf Adapted to new datatype package. berghofe parents: 5162 diff changeset	183	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	184	"remove1 x [] = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	185	"remove1 x (y#xs) = (if x=y then xs else y # remove1 x xs)"
10dd989282fd indentation paulson parents: 15305 diff changeset	186
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	187	primrec
27693 73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	188	"removeAll x [] = []"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	189	"removeAll x (y#xs) = (if x=y then removeAll x xs else y # removeAll x xs)"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	190
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	191	primrec
15307 10dd989282fd indentation paulson parents: 15305 diff changeset	192	replicate_0: "replicate 0 x = []"
10dd989282fd indentation paulson parents: 15305 diff changeset	193	replicate_Suc: "replicate (Suc n) x = x # replicate n x"
10dd989282fd indentation paulson parents: 15305 diff changeset	194
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	195	definition
21404 eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	196	rotate1 :: "'a list \<Rightarrow> 'a list" where
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	197	"rotate1 xs = (case xs of [] \<Rightarrow> [] \| x#xs \<Rightarrow> xs @ [x])"
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	198
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	199	definition
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	200	rotate :: "nat \<Rightarrow> 'a list \<Rightarrow> 'a list" where
30971 7fbebf75b3ef funpow and relpow with shared "^^" syntax haftmann parents: 30952 diff changeset	201	"rotate n = rotate1 ^^ n"
21404 eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	202
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	203	definition
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	204	list_all2 :: "('a => 'b => bool) => 'a list => 'b list => bool" where
28562 4e74209f113e `code func` now just `code` haftmann parents: 28537 diff changeset	205	[code del]: "list_all2 P xs ys =
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	206	(length xs = length ys \<and> (\<forall>(x, y) \<in> set (zip xs ys). P x y))"
21404 eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	207
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	208	definition
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	209	sublist :: "'a list => nat set => 'a list" where
eb85850d3eb7 more robust syntax for definition/abbreviation/notation; wenzelm parents: 21211 diff changeset	210	"sublist xs A = map fst (filter (\<lambda>p. snd p \<in> A) (zip xs [0..<size xs]))"
17086 0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	211
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	212	primrec
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	213	"splice [] ys = ys"
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	214	"splice (x#xs) ys = (if ys=[] then x#xs else x # hd ys # splice xs (tl ys))"
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	215	-- {Warning: simpset does not contain the second eqn but a derived one. }
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	216
26771 1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	217	text{*
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	218	\begin{figure}[htbp]
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	219	\fbox{
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	220	\begin{tabular}{l}
27381 19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	221	@{lemma "[a,b]@[c,d] = [a,b,c,d]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	222	@{lemma "length [a,b,c] = 3" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	223	@{lemma "set [a,b,c] = {a,b,c}" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	224	@{lemma "map f [a,b,c] = [f a, f b, f c]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	225	@{lemma "rev [a,b,c] = [c,b,a]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	226	@{lemma "hd [a,b,c,d] = a" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	227	@{lemma "tl [a,b,c,d] = [b,c,d]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	228	@{lemma "last [a,b,c,d] = d" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	229	@{lemma "butlast [a,b,c,d] = [a,b,c]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	230	@{lemma[source] "filter (\<lambda>n::nat. n<2) [0,2,1] = [0,1]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	231	@{lemma "concat [[a,b],[c,d,e],[],[f]] = [a,b,c,d,e,f]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	232	@{lemma "foldl f x [a,b,c] = f (f (f x a) b) c" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	233	@{lemma "foldr f [a,b,c] x = f a (f b (f c x))" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	234	@{lemma "zip [a,b,c] [x,y,z] = [(a,x),(b,y),(c,z)]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	235	@{lemma "zip [a,b] [x,y,z] = [(a,x),(b,y)]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	236	@{lemma "splice [a,b,c] [x,y,z] = [a,x,b,y,c,z]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	237	@{lemma "splice [a,b,c,d] [x,y] = [a,x,b,y,c,d]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	238	@{lemma "take 2 [a,b,c,d] = [a,b]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	239	@{lemma "take 6 [a,b,c,d] = [a,b,c,d]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	240	@{lemma "drop 2 [a,b,c,d] = [c,d]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	241	@{lemma "drop 6 [a,b,c,d] = []" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	242	@{lemma "takeWhile (%n::nat. n<3) [1,2,3,0] = [1,2]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	243	@{lemma "dropWhile (%n::nat. n<3) [1,2,3,0] = [3,0]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	244	@{lemma "distinct [2,0,1::nat]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	245	@{lemma "remdups [2,0,2,1::nat,2] = [0,1,2]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	246	@{lemma "remove1 2 [2,0,2,1::nat,2] = [0,2,1,2]" by simp}\\
27693 73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	247	@{lemma "removeAll 2 [2,0,2,1::nat,2] = [0,1]" by simp}\\
27381 19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	248	@{lemma "nth [a,b,c,d] 2 = c" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	249	@{lemma "[a,b,c,d][2 := x] = [a,b,x,d]" by simp}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	250	@{lemma "sublist [a,b,c,d,e] {0,2,3} = [a,c,d]" by (simp add:sublist_def)}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	251	@{lemma "rotate1 [a,b,c,d] = [b,c,d,a]" by (simp add:rotate1_def)}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	252	@{lemma "rotate 3 [a,b,c,d] = [d,a,b,c]" by (simp add:rotate1_def rotate_def nat_number)}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	253	@{lemma "replicate 4 a = [a,a,a,a]" by (simp add:nat_number)}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	254	@{lemma "[2..<5] = [2,3,4]" by (simp add:nat_number)}\\
19ae7064f00f @{lemma}: 'by' keyword; wenzelm parents: 27368 diff changeset	255	@{lemma "listsum [1,2,3::nat] = 6" by simp}
26771 1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	256	\end{tabular}}
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	257	\caption{Characteristic examples}
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	258	\label{fig:Characteristic}
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	259	\end{figure}
29927 ae8f42c245b2 Added nitpick attribute, and fixed typo. blanchet parents: 29856 diff changeset	260	Figure~\ref{fig:Characteristic} shows characteristic examples
26771 1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	261	that should give an intuitive understanding of the above functions.
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	262	*}
1d67ab20f358 Added documentation nipkow parents: 26749 diff changeset	263
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	264	text{* The following simple sort functions are intended for proofs,
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	265	not for efficient implementations. *}
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	266
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	267	context linorder
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	268	begin
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	269
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	270	fun sorted :: "'a list \<Rightarrow> bool" where
24697 b37d3980da3c fixed haftmann bug nipkow parents: 24657 diff changeset	271	"sorted [] \<longleftrightarrow> True" \|
b37d3980da3c fixed haftmann bug nipkow parents: 24657 diff changeset	272	"sorted [x] \<longleftrightarrow> True" \|
25062 af5ef0d4d655 global class syntax haftmann parents: 24902 diff changeset	273	"sorted (x#y#zs) \<longleftrightarrow> x <= y \<and> sorted (y#zs)"
24697 b37d3980da3c fixed haftmann bug nipkow parents: 24657 diff changeset	274
25559 f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	275	primrec insort :: "'a \<Rightarrow> 'a list \<Rightarrow> 'a list" where
24697 b37d3980da3c fixed haftmann bug nipkow parents: 24657 diff changeset	276	"insort x [] = [x]" \|
25062 af5ef0d4d655 global class syntax haftmann parents: 24902 diff changeset	277	"insort x (y#ys) = (if x <= y then (x#y#ys) else y#(insort x ys))"
24697 b37d3980da3c fixed haftmann bug nipkow parents: 24657 diff changeset	278
25559 f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	279	primrec sort :: "'a list \<Rightarrow> 'a list" where
24697 b37d3980da3c fixed haftmann bug nipkow parents: 24657 diff changeset	280	"sort [] = []" \|
b37d3980da3c fixed haftmann bug nipkow parents: 24657 diff changeset	281	"sort (x#xs) = insort x (sort xs)"
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	282
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	283	end
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	284
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	285
23388 77645da0db85 tuned proofs: avoid implicit prems; wenzelm parents: 23279 diff changeset	286	subsubsection {* List comprehension *}
23192 ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	287
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	288	text{* Input syntax for Haskell-like list comprehension notation.
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	289	Typical example: @{text"[(x,y). x \<leftarrow> xs, y \<leftarrow> ys, x \<noteq> y]"},
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	290	the list of all pairs of distinct elements from @{text xs} and @{text ys}.
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	291	The syntax is as in Haskell, except that @{text"\|"} becomes a dot
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	292	(like in Isabelle's set comprehension): @{text"[e. x \<leftarrow> xs, \<dots>]"} rather than
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	293	\verb![e\| x <- xs, ...]!.
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	294
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	295	The qualifiers after the dot are
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	296	\begin{description}
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	297	\item[generators] @{text"p \<leftarrow> xs"},
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	298	where @{text p} is a pattern and @{text xs} an expression of list type, or
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	299	\item[guards] @{text"b"}, where @{text b} is a boolean expression.
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	300	%\item[local bindings] @ {text"let x = e"}.
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	301	\end{description}
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	302
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	303	Just like in Haskell, list comprehension is just a shorthand. To avoid
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	304	misunderstandings, the translation into desugared form is not reversed
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	305	upon output. Note that the translation of @{text"[e. x \<leftarrow> xs]"} is
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	306	optmized to @{term"map (%x. e) xs"}.
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	307
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	308	It is easy to write short list comprehensions which stand for complex
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	309	expressions. During proofs, they may become unreadable (and
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	310	mangled). In such cases it can be advisable to introduce separate
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	311	definitions for the list comprehensions in question. *}
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	312
23209 098a23702aba * empty log message * nipkow parents: 23192 diff changeset	313	(*
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	314	Proper theorem proving support would be nice. For example, if
23192 ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	315	@{text"set[f x y. x \<leftarrow> xs, y \<leftarrow> ys, P x y]"}
ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	316	produced something like
23209 098a23702aba * empty log message * nipkow parents: 23192 diff changeset	317	@{term"{z. EX x: set xs. EX y:set ys. P x y \<and> z = f x y}"}.
098a23702aba * empty log message * nipkow parents: 23192 diff changeset	318	*)
098a23702aba * empty log message * nipkow parents: 23192 diff changeset	319
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	320	nonterminals lc_qual lc_quals
23192 ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	321
ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	322	syntax
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	323	"_listcompr" :: "'a \<Rightarrow> lc_qual \<Rightarrow> lc_quals \<Rightarrow> 'a list" ("[_ . __")
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	324	"_lc_gen" :: "'a \<Rightarrow> 'a list \<Rightarrow> lc_qual" ("_ <- _")
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	325	"_lc_test" :: "bool \<Rightarrow> lc_qual" ("_")
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	326	("_lc_let" :: "letbinds => lc_qual" ("let _"))
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	327	"_lc_end" :: "lc_quals" ("]")
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	328	"_lc_quals" :: "lc_qual \<Rightarrow> lc_quals \<Rightarrow> lc_quals" (", __")
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	329	"_lc_abs" :: "'a => 'b list => 'b list"
23192 ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	330
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	331	(* These are easier than ML code but cannot express the optimized
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	332	translation of [e. p<-xs]
23192 ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	333	translations
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	334	"[e. p<-xs]" => "concat(map (_lc_abs p [e]) xs)"
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	335	"_listcompr e (_lc_gen p xs) (_lc_quals Q Qs)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	336	=> "concat (map (_lc_abs p (_listcompr e Q Qs)) xs)"
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	337	"[e. P]" => "if P then [e] else []"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	338	"_listcompr e (_lc_test P) (_lc_quals Q Qs)"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	339	=> "if P then (_listcompr e Q Qs) else []"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	340	"_listcompr e (_lc_let b) (_lc_quals Q Qs)"
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	341	=> "_Let b (_listcompr e Q Qs)"
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	342	*)
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	343
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	344	syntax (xsymbols)
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	345	"_lc_gen" :: "'a \<Rightarrow> 'a list \<Rightarrow> lc_qual" ("_ \<leftarrow> _")
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	346	syntax (HTML output)
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	347	"_lc_gen" :: "'a \<Rightarrow> 'a list \<Rightarrow> lc_qual" ("_ \<leftarrow> _")
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	348
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	349	parse_translation (advanced) {*
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	350	let
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	351	val NilC = Syntax.const @{const_name Nil};
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	352	val ConsC = Syntax.const @{const_name Cons};
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	353	val mapC = Syntax.const @{const_name map};
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	354	val concatC = Syntax.const @{const_name concat};
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	355	val IfC = Syntax.const @{const_name If};
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	356	fun singl x = ConsC $ x $ NilC;
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	357
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	358	fun pat_tr ctxt p e opti = (* %x. case x of p => e \| _ => [] *)
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	359	let
29281 b22ccb3998db eliminated OldTerm.add_term_free_names; wenzelm parents: 29270 diff changeset	360	val x = Free (Name.variant (fold Term.add_free_names [p, e] []) "x", dummyT);
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	361	val e = if opti then singl e else e;
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	362	val case1 = Syntax.const "_case1" $ p $ e;
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	363	val case2 = Syntax.const "_case1" $ Syntax.const Term.dummy_patternN
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	364	$ NilC;
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	365	val cs = Syntax.const "_case2" $ case1 $ case2
31784 bd3486c57ba3 tuned interfaces of datatype module haftmann parents: 31723 diff changeset	366	val ft = DatatypeCase.case_tr false Datatype.info_of_constr
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	367	ctxt [x, cs]
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	368	in lambda x ft end;
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	369
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	370	fun abs_tr ctxt (p as Free(s,T)) e opti =
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	371	let val thy = ProofContext.theory_of ctxt;
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	372	val s' = Sign.intern_const thy s
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	373	in if Sign.declared_const thy s'
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	374	then (pat_tr ctxt p e opti, false)
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	375	else (lambda p e, true)
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	376	end
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	377	\| abs_tr ctxt p e opti = (pat_tr ctxt p e opti, false);
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	378
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	379	fun lc_tr ctxt [e, Const("_lc_test",_)$b, qs] =
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	380	let val res = case qs of Const("_lc_end",_) => singl e
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	381	\| Const("_lc_quals",_)$q$qs => lc_tr ctxt [e,q,qs];
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	382	in IfC $ b $ res $ NilC end
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	383	\| lc_tr ctxt [e, Const("_lc_gen",_) $ p $ es, Const("_lc_end",_)] =
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	384	(case abs_tr ctxt p e true of
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	385	(f,true) => mapC $ f $ es
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	386	\| (f, false) => concatC $ (mapC $ f $ es))
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	387	\| lc_tr ctxt [e, Const("_lc_gen",_) $ p $ es, Const("_lc_quals",_)$q$qs] =
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	388	let val e' = lc_tr ctxt [e,q,qs];
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	389	in concatC $ (mapC $ (fst(abs_tr ctxt p e' false)) $ es) end
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	390
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	391	in [("_listcompr", lc_tr)] end
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	392	*}
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	393
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	394	(*
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	395	term "[(x,y,z). b]"
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	396	term "[(x,y,z). x\<leftarrow>xs]"
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	397	term "[e x y. x\<leftarrow>xs, y\<leftarrow>ys]"
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	398	term "[(x,y,z). x<a, x>b]"
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	399	term "[(x,y,z). x\<leftarrow>xs, x>b]"
f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	400	term "[(x,y,z). x<a, x\<leftarrow>xs]"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	401	term "[(x,y). Cons True x \<leftarrow> xs]"
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	402	term "[(x,y,z). Cons x [] \<leftarrow> xs]"
23240 7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	403	term "[(x,y,z). x<a, x>b, x=d]"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	404	term "[(x,y,z). x<a, x>b, y\<leftarrow>ys]"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	405	term "[(x,y,z). x<a, x\<leftarrow>xs,y>b]"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	406	term "[(x,y,z). x<a, x\<leftarrow>xs, y\<leftarrow>ys]"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	407	term "[(x,y,z). x\<leftarrow>xs, x>b, y<a]"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	408	term "[(x,y,z). x\<leftarrow>xs, x>b, y\<leftarrow>ys]"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	409	term "[(x,y,z). x\<leftarrow>xs, y\<leftarrow>ys,y>x]"
7077dc80a14b tuned list comprehension nipkow parents: 23235 diff changeset	410	term "[(x,y,z). x\<leftarrow>xs, y\<leftarrow>ys,z\<leftarrow>zs]"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	411	term "[(x,y). x\<leftarrow>xs, let xx = x+x, y\<leftarrow>ys, y \<noteq> xx]"
23192 ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	412	*)
ec73b9707d48 Moved list comprehension into List nipkow parents: 23096 diff changeset	413
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	414	subsubsection {* @{const Nil} and @{const Cons} *}
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	415
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	416	lemma not_Cons_self [simp]:
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	417	"xs \<noteq> x # xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	418	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	419
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	420	lemmas not_Cons_self2 [simp] = not_Cons_self [symmetric]
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	421
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	422	lemma neq_Nil_conv: "(xs \<noteq> []) = (\<exists>y ys. xs = y # ys)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	423	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	424
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	425	lemma length_induct:
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	426	"(\<And>xs. \<forall>ys. length ys < length xs \<longrightarrow> P ys \<Longrightarrow> P xs) \<Longrightarrow> P xs"
17589 58eeffd73be1 renamed rules to iprover nipkow parents: 17501 diff changeset	427	by (rule measure_induct [of length]) iprover
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	428
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	429
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	430	subsubsection {* @{const length} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	431
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	432	text {*
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	433	Needs to come before @{text "@"} because of theorem @{text
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	434	append_eq_append_conv}.
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	435	*}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	436
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	437	lemma length_append [simp]: "length (xs @ ys) = length xs + length ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	438	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	439
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	440	lemma length_map [simp]: "length (map f xs) = length xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	441	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	442
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	443	lemma length_rev [simp]: "length (rev xs) = length xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	444	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	445
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	446	lemma length_tl [simp]: "length (tl xs) = length xs - 1"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	447	by (cases xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	448
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	449	lemma length_0_conv [iff]: "(length xs = 0) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	450	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	451
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	452	lemma length_greater_0_conv [iff]: "(0 < length xs) = (xs \<noteq> [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	453	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	454
23479 10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	455	lemma length_pos_if_in_set: "x : set xs \<Longrightarrow> length xs > 0"
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	456	by auto
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	457
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	458	lemma length_Suc_conv:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	459	"(length xs = Suc n) = (\<exists>y ys. xs = y # ys \<and> length ys = n)"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	460	by (induct xs) auto
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	461
14025 d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	462	lemma Suc_length_conv:
d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	463	"(Suc n = length xs) = (\<exists>y ys. xs = y # ys \<and> length ys = n)"
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	464	apply (induct xs, simp, simp)
14025 d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	465	apply blast
d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	466	done
d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	467
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	468	lemma impossible_Cons: "length xs <= length ys ==> xs = x # ys = False"
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	469	by (induct xs) auto
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	470
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	471	lemma list_induct2 [consumes 1, case_names Nil Cons]:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	472	"length xs = length ys \<Longrightarrow> P [] [] \<Longrightarrow>
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	473	(\<And>x xs y ys. length xs = length ys \<Longrightarrow> P xs ys \<Longrightarrow> P (x#xs) (y#ys))
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	474	\<Longrightarrow> P xs ys"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	475	proof (induct xs arbitrary: ys)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	476	case Nil then show ?case by simp
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	477	next
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	478	case (Cons x xs ys) then show ?case by (cases ys) simp_all
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	479	qed
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	480
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	481	lemma list_induct3 [consumes 2, case_names Nil Cons]:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	482	"length xs = length ys \<Longrightarrow> length ys = length zs \<Longrightarrow> P [] [] [] \<Longrightarrow>
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	483	(\<And>x xs y ys z zs. length xs = length ys \<Longrightarrow> length ys = length zs \<Longrightarrow> P xs ys zs \<Longrightarrow> P (x#xs) (y#ys) (z#zs))
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	484	\<Longrightarrow> P xs ys zs"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	485	proof (induct xs arbitrary: ys zs)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	486	case Nil then show ?case by simp
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	487	next
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	488	case (Cons x xs ys zs) then show ?case by (cases ys, simp_all)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	489	(cases zs, simp_all)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	490	qed
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	491
22493 db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	492	lemma list_induct2':
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	493	"\<lbrakk> P [] [];
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	494	\<And>x xs. P (x#xs) [];
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	495	\<And>y ys. P [] (y#ys);
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	496	\<And>x xs y ys. P xs ys \<Longrightarrow> P (x#xs) (y#ys) \<rbrakk>
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	497	\<Longrightarrow> P xs ys"
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	498	by (induct xs arbitrary: ys) (case_tac x, auto)+
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	499
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	500	lemma neq_if_length_neq: "length xs \<noteq> length ys \<Longrightarrow> (xs = ys) == False"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	501	by (rule Eq_FalseI) auto
24037 0a41d2ebc0cd proper simproc_setup for "list_neq"; wenzelm parents: 23983 diff changeset	502
0a41d2ebc0cd proper simproc_setup for "list_neq"; wenzelm parents: 23983 diff changeset	503	simproc_setup list_neq ("(xs::'a list) = ys") = {*
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	504	(*
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	505	Reduces xs=ys to False if xs and ys cannot be of the same length.
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	506	This is the case if the atomic sublists of one are a submultiset
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	507	of those of the other list and there are fewer Cons's in one than the other.
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	508	*)
24037 0a41d2ebc0cd proper simproc_setup for "list_neq"; wenzelm parents: 23983 diff changeset	509
0a41d2ebc0cd proper simproc_setup for "list_neq"; wenzelm parents: 23983 diff changeset	510	let
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	511
29856 984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	512	fun len (Const(@{const_name Nil},_)) acc = acc
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	513	\| len (Const(@{const_name Cons},_) $ _ $ xs) (ts,n) = len xs (ts,n+1)
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	514	\| len (Const(@{const_name append},_) $ xs $ ys) acc = len xs (len ys acc)
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	515	\| len (Const(@{const_name rev},_) $ xs) acc = len xs acc
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	516	\| len (Const(@{const_name map},_) $ _ $ xs) acc = len xs acc
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	517	\| len t (ts,n) = (t::ts,n);
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	518
24037 0a41d2ebc0cd proper simproc_setup for "list_neq"; wenzelm parents: 23983 diff changeset	519	fun list_neq _ ss ct =
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	520	let
24037 0a41d2ebc0cd proper simproc_setup for "list_neq"; wenzelm parents: 23983 diff changeset	521	val (Const(_,eqT) $ lhs $ rhs) = Thm.term_of ct;
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	522	val (ls,m) = len lhs ([],0) and (rs,n) = len rhs ([],0);
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	523	fun prove_neq() =
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	524	let
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	525	val Type(_,listT::_) = eqT;
22994 02440636214f abstract size function in hologic.ML haftmann parents: 22940 diff changeset	526	val size = HOLogic.size_const listT;
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	527	val eq_len = HOLogic.mk_eq (size $ lhs, size $ rhs);
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	528	val neq_len = HOLogic.mk_Trueprop (HOLogic.Not $ eq_len);
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	529	val thm = Goal.prove (Simplifier.the_context ss) [] [] neq_len
22633 a47e4fd7ebc1 tuned haftmann parents: 22551 diff changeset	530	(K (simp_tac (Simplifier.inherit_context ss @{simpset}) 1));
a47e4fd7ebc1 tuned haftmann parents: 22551 diff changeset	531	in SOME (thm RS @{thm neq_if_length_neq}) end
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	532	in
23214 dc23c062b58c renamed gen_submultiset to submultiset; wenzelm parents: 23212 diff changeset	533	if m < n andalso submultiset (op aconv) (ls,rs) orelse
dc23c062b58c renamed gen_submultiset to submultiset; wenzelm parents: 23212 diff changeset	534	n < m andalso submultiset (op aconv) (rs,ls)
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	535	then prove_neq() else NONE
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	536	end;
24037 0a41d2ebc0cd proper simproc_setup for "list_neq"; wenzelm parents: 23983 diff changeset	537	in list_neq end;
22143 cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	538	*}
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	539
cf58486ca11b Added simproc list_neq (prompted by an application) nipkow parents: 21911 diff changeset	540
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	541	subsubsection {* @{text "@"} -- append *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	542
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	543	lemma append_assoc [simp]: "(xs @ ys) @ zs = xs @ (ys @ zs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	544	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	545
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	546	lemma append_Nil2 [simp]: "xs @ [] = xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	547	by (induct xs) auto
3507 157be29ad5ba Improved length = size translation. nipkow parents: 3465 diff changeset	548
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	549	lemma append_is_Nil_conv [iff]: "(xs @ ys = []) = (xs = [] \<and> ys = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	550	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	551
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	552	lemma Nil_is_append_conv [iff]: "([] = xs @ ys) = (xs = [] \<and> ys = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	553	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	554
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	555	lemma append_self_conv [iff]: "(xs @ ys = xs) = (ys = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	556	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	557
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	558	lemma self_append_conv [iff]: "(xs = xs @ ys) = (ys = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	559	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	560
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	561	lemma append_eq_append_conv [simp, noatp]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	562	"length xs = length ys \<or> length us = length vs
13883 0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	563	==> (xs@us = ys@vs) = (xs=ys \<and> us=vs)"
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	564	apply (induct xs arbitrary: ys)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	565	apply (case_tac ys, simp, force)
144f45277d5a misc tidying paulson parents: 14187 diff changeset	566	apply (case_tac ys, force, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	567	done
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	568
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	569	lemma append_eq_append_conv2: "(xs @ ys = zs @ ts) =
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	570	(EX us. xs = zs @ us & us @ ys = ts \| xs @ us = zs & ys = us@ ts)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	571	apply (induct xs arbitrary: ys zs ts)
14495 e2a1c31cf6d3 Added append_eq_append_conv2 nipkow parents: 14402 diff changeset	572	apply fastsimp
e2a1c31cf6d3 Added append_eq_append_conv2 nipkow parents: 14402 diff changeset	573	apply(case_tac zs)
e2a1c31cf6d3 Added append_eq_append_conv2 nipkow parents: 14402 diff changeset	574	apply simp
e2a1c31cf6d3 Added append_eq_append_conv2 nipkow parents: 14402 diff changeset	575	apply fastsimp
e2a1c31cf6d3 Added append_eq_append_conv2 nipkow parents: 14402 diff changeset	576	done
e2a1c31cf6d3 Added append_eq_append_conv2 nipkow parents: 14402 diff changeset	577
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	578	lemma same_append_eq [iff]: "(xs @ ys = xs @ zs) = (ys = zs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	579	by simp
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	580
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	581	lemma append1_eq_conv [iff]: "(xs @ [x] = ys @ [y]) = (xs = ys \<and> x = y)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	582	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	583
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	584	lemma append_same_eq [iff]: "(ys @ xs = zs @ xs) = (ys = zs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	585	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	586
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	587	lemma append_self_conv2 [iff]: "(xs @ ys = ys) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	588	using append_same_eq [of _ _ "[]"] by auto
3507 157be29ad5ba Improved length = size translation. nipkow parents: 3465 diff changeset	589
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	590	lemma self_append_conv2 [iff]: "(ys = xs @ ys) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	591	using append_same_eq [of "[]"] by auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	592
24286 7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	593	lemma hd_Cons_tl [simp,noatp]: "xs \<noteq> [] ==> hd xs # tl xs = xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	594	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	595
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	596	lemma hd_append: "hd (xs @ ys) = (if xs = [] then hd ys else hd xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	597	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	598
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	599	lemma hd_append2 [simp]: "xs \<noteq> [] ==> hd (xs @ ys) = hd xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	600	by (simp add: hd_append split: list.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	601
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	602	lemma tl_append: "tl (xs @ ys) = (case xs of [] => tl ys \| z#zs => zs @ ys)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	603	by (simp split: list.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	604
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	605	lemma tl_append2 [simp]: "xs \<noteq> [] ==> tl (xs @ ys) = tl xs @ ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	606	by (simp add: tl_append split: list.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	607
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	608
14300 bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	609	lemma Cons_eq_append_conv: "x#xs = ys@zs =
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	610	(ys = [] & x#xs = zs \| (EX ys'. x#ys' = ys & xs = ys'@zs))"
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	611	by(cases ys) auto
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	612
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	613	lemma append_eq_Cons_conv: "(ys@zs = x#xs) =
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	614	(ys = [] & zs = x#xs \| (EX ys'. ys = x#ys' & ys'@zs = xs))"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	615	by(cases ys) auto
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	616
14300 bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	617
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	618	text {* Trivial rules for solving @{text "@"}-equations automatically. *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	619
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	620	lemma eq_Nil_appendI: "xs = ys ==> xs = [] @ ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	621	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	622
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	623	lemma Cons_eq_appendI:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	624	"[\| x # xs1 = ys; xs = xs1 @ zs \|] ==> x # xs = ys @ zs"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	625	by (drule sym) simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	626
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	627	lemma append_eq_appendI:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	628	"[\| xs @ xs1 = zs; ys = xs1 @ us \|] ==> xs @ ys = zs @ us"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	629	by (drule sym) simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	630
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	631
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	632	text {*
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	633	Simplification procedure for all list equalities.
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	634	Currently only tries to rearrange @{text "@"} to see if
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	635	- both lists end in a singleton list,
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	636	- or both lists end in the same list.
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	637	*}
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	638
26480 544cef16045b replaced 'ML_setup' by 'ML'; wenzelm parents: 26442 diff changeset	639	ML {*
3507 157be29ad5ba Improved length = size translation. nipkow parents: 3465 diff changeset	640	local
157be29ad5ba Improved length = size translation. nipkow parents: 3465 diff changeset	641
29856 984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	642	fun last (cons as Const(@{const_name Cons},_) $ _ $ xs) =
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	643	(case xs of Const(@{const_name Nil},_) => cons \| _ => last xs)
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	644	\| last (Const(@{const_name append},_) $ _ $ ys) = last ys
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	645	\| last t = t;
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	646
29856 984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	647	fun list1 (Const(@{const_name Cons},_) $ _ $ Const(@{const_name Nil},_)) = true
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	648	\| list1 _ = false;
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	649
29856 984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	650	fun butlast ((cons as Const(@{const_name Cons},_) $ x) $ xs) =
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	651	(case xs of Const(@{const_name Nil},_) => xs \| _ => cons $ butlast xs)
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	652	\| butlast ((app as Const(@{const_name append},_) $ xs) $ ys) = app $ butlast ys
984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	653	\| butlast xs = Const(@{const_name Nil},fastype_of xs);
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	654
22633 a47e4fd7ebc1 tuned haftmann parents: 22551 diff changeset	655	val rearr_ss = HOL_basic_ss addsimps [@{thm append_assoc},
a47e4fd7ebc1 tuned haftmann parents: 22551 diff changeset	656	@{thm append_Nil}, @{thm append_Cons}];
16973 b2a894562b8f simprocs: Simplifier.inherit_bounds; wenzelm parents: 16965 diff changeset	657
20044 92cc2f4c7335 simprocs: no theory argument -- use simpset context instead; wenzelm parents: 19890 diff changeset	658	fun list_eq ss (F as (eq as Const(_,eqT)) $ lhs $ rhs) =
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	659	let
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	660	val lastl = last lhs and lastr = last rhs;
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	661	fun rearr conv =
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	662	let
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	663	val lhs1 = butlast lhs and rhs1 = butlast rhs;
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	664	val Type(_,listT::_) = eqT
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	665	val appT = [listT,listT] ---> listT
29856 984191be0357 const_name antiquotations huffman parents: 29829 diff changeset	666	val app = Const(@{const_name append},appT)
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	667	val F2 = eq $ (app$lhs1$lastl) $ (app$rhs1$lastr)
13480 bb72bd43c6c3 use Tactic.prove instead of prove_goalw_cterm in internal proofs! wenzelm parents: 13462 diff changeset	668	val eq = HOLogic.mk_Trueprop (HOLogic.mk_eq (F,F2));
20044 92cc2f4c7335 simprocs: no theory argument -- use simpset context instead; wenzelm parents: 19890 diff changeset	669	val thm = Goal.prove (Simplifier.the_context ss) [] [] eq
17877 67d5ab1cb0d8 Simplifier.inherit_context instead of Simplifier.inherit_bounds; wenzelm parents: 17830 diff changeset	670	(K (simp_tac (Simplifier.inherit_context ss rearr_ss) 1));
15531 08c8dad8e399 Deleted Library.option type. skalberg parents: 15489 diff changeset	671	in SOME ((conv RS (thm RS trans)) RS eq_reflection) end;
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	672
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	673	in
22633 a47e4fd7ebc1 tuned haftmann parents: 22551 diff changeset	674	if list1 lastl andalso list1 lastr then rearr @{thm append1_eq_conv}
a47e4fd7ebc1 tuned haftmann parents: 22551 diff changeset	675	else if lastl aconv lastr then rearr @{thm append_same_eq}
15531 08c8dad8e399 Deleted Library.option type. skalberg parents: 15489 diff changeset	676	else NONE
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	677	end;
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	678
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	679	in
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	680
56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	681	val list_eq_simproc =
32010 cb1a1c94b4cd more antiquotations; wenzelm parents: 32007 diff changeset	682	Simplifier.simproc @{theory} "list_eq" ["(xs::'a list) = ys"] (K list_eq);
13462 56610e2ba220 sane interface for simprocs; wenzelm parents: 13366 diff changeset	683
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	684	end;
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	685
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	686	Addsimprocs [list_eq_simproc];
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	687	*}
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	688
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	689
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	690	subsubsection {* @{text map} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	691
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	692	lemma map_ext: "(!!x. x : set xs --> f x = g x) ==> map f xs = map g xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	693	by (induct xs) simp_all
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	694
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	695	lemma map_ident [simp]: "map (\<lambda>x. x) = (\<lambda>xs. xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	696	by (rule ext, induct_tac xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	697
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	698	lemma map_append [simp]: "map f (xs @ ys) = map f xs @ map f ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	699	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	700
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	701	lemma map_compose: "map (f o g) xs = map f (map g xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	702	by (induct xs) (auto simp add: o_def)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	703
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	704	lemma rev_map: "rev (map f xs) = map f (rev xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	705	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	706
13737 e564c3d2d174 added a few lemmas nipkow parents: 13601 diff changeset	707	lemma map_eq_conv[simp]: "(map f xs = map g xs) = (!x : set xs. f x = g x)"
e564c3d2d174 added a few lemmas nipkow parents: 13601 diff changeset	708	by (induct xs) auto
e564c3d2d174 added a few lemmas nipkow parents: 13601 diff changeset	709
19770 be5c23ebe1eb HOL/Tools/function_package: Added support for mutual recursive definitions. krauss parents: 19623 diff changeset	710	lemma map_cong [fundef_cong, recdef_cong]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	711	"xs = ys ==> (!!x. x : set ys ==> f x = g x) ==> map f xs = map g ys"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	712	-- {* a congruence rule for @{text map} *}
13737 e564c3d2d174 added a few lemmas nipkow parents: 13601 diff changeset	713	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	714
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	715	lemma map_is_Nil_conv [iff]: "(map f xs = []) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	716	by (cases xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	717
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	718	lemma Nil_is_map_conv [iff]: "([] = map f xs) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	719	by (cases xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	720
18447 da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	721	lemma map_eq_Cons_conv:
14025 d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	722	"(map f xs = y#ys) = (\<exists>z zs. xs = z#zs \<and> f z = y \<and> map f zs = ys)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	723	by (cases xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	724
18447 da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	725	lemma Cons_eq_map_conv:
14025 d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	726	"(x#xs = map f ys) = (\<exists>z zs. ys = z#zs \<and> x = f z \<and> xs = map f zs)"
d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	727	by (cases ys) auto
d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	728
18447 da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	729	lemmas map_eq_Cons_D = map_eq_Cons_conv [THEN iffD1]
da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	730	lemmas Cons_eq_map_D = Cons_eq_map_conv [THEN iffD1]
da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	731	declare map_eq_Cons_D [dest!] Cons_eq_map_D [dest!]
da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	732
14111 993471c762b8 Some new thm (ex_map_conv?) nipkow parents: 14099 diff changeset	733	lemma ex_map_conv:
993471c762b8 Some new thm (ex_map_conv?) nipkow parents: 14099 diff changeset	734	"(EX xs. ys = map f xs) = (ALL y : set ys. EX x. y = f x)"
18447 da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	735	by(induct ys, auto simp add: Cons_eq_map_conv)
14111 993471c762b8 Some new thm (ex_map_conv?) nipkow parents: 14099 diff changeset	736
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	737	lemma map_eq_imp_length_eq:
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	738	assumes "map f xs = map f ys"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	739	shows "length xs = length ys"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	740	using assms proof (induct ys arbitrary: xs)
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	741	case Nil then show ?case by simp
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	742	next
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	743	case (Cons y ys) then obtain z zs where xs: "xs = z # zs" by auto
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	744	from Cons xs have "map f zs = map f ys" by simp
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	745	moreover with Cons have "length zs = length ys" by blast
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	746	with xs show ?case by simp
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	747	qed
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	748
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	749	lemma map_inj_on:
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	750	"[\| map f xs = map f ys; inj_on f (set xs Un set ys) \|]
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	751	==> xs = ys"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	752	apply(frule map_eq_imp_length_eq)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	753	apply(rotate_tac -1)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	754	apply(induct rule:list_induct2)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	755	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	756	apply(simp)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	757	apply (blast intro:sym)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	758	done
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	759
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	760	lemma inj_on_map_eq_map:
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	761	"inj_on f (set xs Un set ys) \<Longrightarrow> (map f xs = map f ys) = (xs = ys)"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	762	by(blast dest:map_inj_on)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	763
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	764	lemma map_injective:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	765	"map f xs = map f ys ==> inj f ==> xs = ys"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	766	by (induct ys arbitrary: xs) (auto dest!:injD)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	767
14339 ec575b7bde7a * empty log message * nipkow parents: 14338 diff changeset	768	lemma inj_map_eq_map[simp]: "inj f \<Longrightarrow> (map f xs = map f ys) = (xs = ys)"
ec575b7bde7a * empty log message * nipkow parents: 14338 diff changeset	769	by(blast dest:map_injective)
ec575b7bde7a * empty log message * nipkow parents: 14338 diff changeset	770
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	771	lemma inj_mapI: "inj f ==> inj (map f)"
17589 58eeffd73be1 renamed rules to iprover nipkow parents: 17501 diff changeset	772	by (iprover dest: map_injective injD intro: inj_onI)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	773
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	774	lemma inj_mapD: "inj (map f) ==> inj f"
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	775	apply (unfold inj_on_def, clarify)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	776	apply (erule_tac x = "[x]" in ballE)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	777	apply (erule_tac x = "[y]" in ballE, simp, blast)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	778	apply blast
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	779	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	780
14339 ec575b7bde7a * empty log message * nipkow parents: 14338 diff changeset	781	lemma inj_map[iff]: "inj (map f) = inj f"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	782	by (blast dest: inj_mapD intro: inj_mapI)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	783
15303 eedbb8d22ca2 added lemmas nipkow parents: 15302 diff changeset	784	lemma inj_on_mapI: "inj_on f (\<Union>(set ` A)) \<Longrightarrow> inj_on (map f) A"
eedbb8d22ca2 added lemmas nipkow parents: 15302 diff changeset	785	apply(rule inj_onI)
eedbb8d22ca2 added lemmas nipkow parents: 15302 diff changeset	786	apply(erule map_inj_on)
eedbb8d22ca2 added lemmas nipkow parents: 15302 diff changeset	787	apply(blast intro:inj_onI dest:inj_onD)
eedbb8d22ca2 added lemmas nipkow parents: 15302 diff changeset	788	done
eedbb8d22ca2 added lemmas nipkow parents: 15302 diff changeset	789
14343 6bc647f472b9 map_idI kleing parents: 14339 diff changeset	790	lemma map_idI: "(\<And>x. x \<in> set xs \<Longrightarrow> f x = x) \<Longrightarrow> map f xs = xs"
6bc647f472b9 map_idI kleing parents: 14339 diff changeset	791	by (induct xs, auto)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	792
14402 4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	793	lemma map_fun_upd [simp]: "y \<notin> set xs \<Longrightarrow> map (f(y:=v)) xs = map f xs"
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	794	by (induct xs) auto
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	795
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	796	lemma map_fst_zip[simp]:
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	797	"length xs = length ys \<Longrightarrow> map fst (zip xs ys) = xs"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	798	by (induct rule:list_induct2, simp_all)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	799
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	800	lemma map_snd_zip[simp]:
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	801	"length xs = length ys \<Longrightarrow> map snd (zip xs ys) = ys"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	802	by (induct rule:list_induct2, simp_all)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	803
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	804
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	805	subsubsection {* @{text rev} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	806
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	807	lemma rev_append [simp]: "rev (xs @ ys) = rev ys @ rev xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	808	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	809
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	810	lemma rev_rev_ident [simp]: "rev (rev xs) = xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	811	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	812
15870 4320bce5873f more on rev kleing parents: 15868 diff changeset	813	lemma rev_swap: "(rev xs = ys) = (xs = rev ys)"
4320bce5873f more on rev kleing parents: 15868 diff changeset	814	by auto
4320bce5873f more on rev kleing parents: 15868 diff changeset	815
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	816	lemma rev_is_Nil_conv [iff]: "(rev xs = []) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	817	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	818
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	819	lemma Nil_is_rev_conv [iff]: "([] = rev xs) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	820	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	821
15870 4320bce5873f more on rev kleing parents: 15868 diff changeset	822	lemma rev_singleton_conv [simp]: "(rev xs = [x]) = (xs = [x])"
4320bce5873f more on rev kleing parents: 15868 diff changeset	823	by (cases xs) auto
4320bce5873f more on rev kleing parents: 15868 diff changeset	824
4320bce5873f more on rev kleing parents: 15868 diff changeset	825	lemma singleton_rev_conv [simp]: "([x] = rev xs) = (xs = [x])"
4320bce5873f more on rev kleing parents: 15868 diff changeset	826	by (cases xs) auto
4320bce5873f more on rev kleing parents: 15868 diff changeset	827
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	828	lemma rev_is_rev_conv [iff]: "(rev xs = rev ys) = (xs = ys)"
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	829	apply (induct xs arbitrary: ys, force)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	830	apply (case_tac ys, simp, force)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	831	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	832
15439 71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	833	lemma inj_on_rev[iff]: "inj_on rev A"
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	834	by(simp add:inj_on_def)
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	835
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	836	lemma rev_induct [case_names Nil snoc]:
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	837	"[\| P []; !!x xs. P xs ==> P (xs @ [x]) \|] ==> P xs"
15489 d136af442665 Replaced application of subst by simplesubst in proof of rev_induct berghofe parents: 15439 diff changeset	838	apply(simplesubst rev_rev_ident[symmetric])
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	839	apply(rule_tac list = "rev xs" in list.induct, simp_all)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	840	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	841
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	842	lemma rev_exhaust [case_names Nil snoc]:
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	843	"(xs = [] ==> P) ==>(!!ys y. xs = ys @ [y] ==> P) ==> P"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	844	by (induct xs rule: rev_induct) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	845
13366 114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	846	lemmas rev_cases = rev_exhaust
114b7c14084a moved stuff from Main.thy; wenzelm parents: 13187 diff changeset	847
18423 d7859164447f new lemmas nipkow parents: 18336 diff changeset	848	lemma rev_eq_Cons_iff[iff]: "(rev xs = y#ys) = (xs = rev ys @ [y])"
d7859164447f new lemmas nipkow parents: 18336 diff changeset	849	by(rule rev_cases[of xs]) auto
d7859164447f new lemmas nipkow parents: 18336 diff changeset	850
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	851
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	852	subsubsection {* @{text set} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	853
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	854	lemma finite_set [iff]: "finite (set xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	855	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	856
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	857	lemma set_append [simp]: "set (xs @ ys) = (set xs \<union> set ys)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	858	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	859
17830 695a2365d32f added hd lemma nipkow parents: 17765 diff changeset	860	lemma hd_in_set[simp]: "xs \<noteq> [] \<Longrightarrow> hd xs : set xs"
695a2365d32f added hd lemma nipkow parents: 17765 diff changeset	861	by(cases xs) auto
14099 55d244f3c86d added fold_red, o2l, postfix, some thms oheimb parents: 14050 diff changeset	862
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	863	lemma set_subset_Cons: "set xs \<subseteq> set (x # xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	864	by auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	865
14099 55d244f3c86d added fold_red, o2l, postfix, some thms oheimb parents: 14050 diff changeset	866	lemma set_ConsD: "y \<in> set (x # xs) \<Longrightarrow> y=x \<or> y \<in> set xs"
55d244f3c86d added fold_red, o2l, postfix, some thms oheimb parents: 14050 diff changeset	867	by auto
55d244f3c86d added fold_red, o2l, postfix, some thms oheimb parents: 14050 diff changeset	868
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	869	lemma set_empty [iff]: "(set xs = {}) = (xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	870	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	871
15245 5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	872	lemma set_empty2[iff]: "({} = set xs) = (xs = [])"
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	873	by(induct xs) auto
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	874
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	875	lemma set_rev [simp]: "set (rev xs) = set xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	876	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	877
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	878	lemma set_map [simp]: "set (map f xs) = f`(set xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	879	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	880
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	881	lemma set_filter [simp]: "set (filter P xs) = {x. x : set xs \<and> P x}"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	882	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	883
32417 e87d9c78910c tuned code generation for lists nipkow parents: 32415 diff changeset	884	lemma set_upt [simp]: "set[i..<j] = {i..<j}"
e87d9c78910c tuned code generation for lists nipkow parents: 32415 diff changeset	885	by (induct j) (simp_all add: atLeastLessThanSuc)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	886
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	887
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	888	lemma split_list: "x : set xs \<Longrightarrow> \<exists>ys zs. xs = ys @ x # zs"
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	889	proof (induct xs)
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	890	case Nil thus ?case by simp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	891	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	892	case Cons thus ?case by (auto intro: Cons_eq_appendI)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	893	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	894
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	895	lemma in_set_conv_decomp: "x \<in> set xs \<longleftrightarrow> (\<exists>ys zs. xs = ys @ x # zs)"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	896	by (auto elim: split_list)
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	897
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	898	lemma split_list_first: "x : set xs \<Longrightarrow> \<exists>ys zs. xs = ys @ x # zs \<and> x \<notin> set ys"
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	899	proof (induct xs)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	900	case Nil thus ?case by simp
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	901	next
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	902	case (Cons a xs)
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	903	show ?case
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	904	proof cases
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	905	assume "x = a" thus ?case using Cons by fastsimp
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	906	next
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	907	assume "x \<noteq> a" thus ?case using Cons by(fastsimp intro!: Cons_eq_appendI)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	908	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	909	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	910
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	911	lemma in_set_conv_decomp_first:
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	912	"(x : set xs) = (\<exists>ys zs. xs = ys @ x # zs \<and> x \<notin> set ys)"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	913	by (auto dest!: split_list_first)
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	914
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	915	lemma split_list_last: "x : set xs \<Longrightarrow> \<exists>ys zs. xs = ys @ x # zs \<and> x \<notin> set zs"
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	916	proof (induct xs rule:rev_induct)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	917	case Nil thus ?case by simp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	918	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	919	case (snoc a xs)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	920	show ?case
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	921	proof cases
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	922	assume "x = a" thus ?case using snoc by simp (metis ex_in_conv set_empty2)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	923	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	924	assume "x \<noteq> a" thus ?case using snoc by fastsimp
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	925	qed
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	926	qed
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	927
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	928	lemma in_set_conv_decomp_last:
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	929	"(x : set xs) = (\<exists>ys zs. xs = ys @ x # zs \<and> x \<notin> set zs)"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	930	by (auto dest!: split_list_last)
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	931
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	932	lemma split_list_prop: "\<exists>x \<in> set xs. P x \<Longrightarrow> \<exists>ys x zs. xs = ys @ x # zs & P x"
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	933	proof (induct xs)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	934	case Nil thus ?case by simp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	935	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	936	case Cons thus ?case
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	937	by(simp add:Bex_def)(metis append_Cons append.simps(1))
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	938	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	939
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	940	lemma split_list_propE:
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	941	assumes "\<exists>x \<in> set xs. P x"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	942	obtains ys x zs where "xs = ys @ x # zs" and "P x"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	943	using split_list_prop [OF assms] by blast
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	944
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	945	lemma split_list_first_prop:
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	946	"\<exists>x \<in> set xs. P x \<Longrightarrow>
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	947	\<exists>ys x zs. xs = ys@x#zs \<and> P x \<and> (\<forall>y \<in> set ys. \<not> P y)"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	948	proof (induct xs)
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	949	case Nil thus ?case by simp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	950	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	951	case (Cons x xs)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	952	show ?case
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	953	proof cases
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	954	assume "P x"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	955	thus ?thesis by simp
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	956	(metis Un_upper1 contra_subsetD in_set_conv_decomp_first self_append_conv2 set_append)
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	957	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	958	assume "\<not> P x"
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	959	hence "\<exists>x\<in>set xs. P x" using Cons(2) by simp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	960	thus ?thesis using `\<not> P x` Cons(1) by (metis append_Cons set_ConsD)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	961	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	962	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	963
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	964	lemma split_list_first_propE:
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	965	assumes "\<exists>x \<in> set xs. P x"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	966	obtains ys x zs where "xs = ys @ x # zs" and "P x" and "\<forall>y \<in> set ys. \<not> P y"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	967	using split_list_first_prop [OF assms] by blast
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	968
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	969	lemma split_list_first_prop_iff:
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	970	"(\<exists>x \<in> set xs. P x) \<longleftrightarrow>
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	971	(\<exists>ys x zs. xs = ys@x#zs \<and> P x \<and> (\<forall>y \<in> set ys. \<not> P y))"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	972	by (rule, erule split_list_first_prop) auto
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	973
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	974	lemma split_list_last_prop:
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	975	"\<exists>x \<in> set xs. P x \<Longrightarrow>
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	976	\<exists>ys x zs. xs = ys@x#zs \<and> P x \<and> (\<forall>z \<in> set zs. \<not> P z)"
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	977	proof(induct xs rule:rev_induct)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	978	case Nil thus ?case by simp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	979	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	980	case (snoc x xs)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	981	show ?case
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	982	proof cases
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	983	assume "P x" thus ?thesis by (metis emptyE set_empty)
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	984	next
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	985	assume "\<not> P x"
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	986	hence "\<exists>x\<in>set xs. P x" using snoc(2) by simp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	987	thus ?thesis using `\<not> P x` snoc(1) by fastsimp
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	988	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	989	qed
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	990
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	991	lemma split_list_last_propE:
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	992	assumes "\<exists>x \<in> set xs. P x"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	993	obtains ys x zs where "xs = ys @ x # zs" and "P x" and "\<forall>z \<in> set zs. \<not> P z"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	994	using split_list_last_prop [OF assms] by blast
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	995
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	996	lemma split_list_last_prop_iff:
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	997	"(\<exists>x \<in> set xs. P x) \<longleftrightarrow>
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	998	(\<exists>ys x zs. xs = ys@x#zs \<and> P x \<and> (\<forall>z \<in> set zs. \<not> P z))"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	999	by (metis split_list_last_prop [where P=P] in_set_conv_decomp)
26073 0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	1000
0e70d3bd2eb4 more lemmas nipkow parents: 25966 diff changeset	1001	lemma finite_list: "finite A ==> EX xs. set xs = A"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	1002	by (erule finite_induct)
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	1003	(auto simp add: set.simps(2) [symmetric] simp del: set.simps(2))
13508 890d736b93a5 Frederic Blanqui's new "guard" examples paulson parents: 13480 diff changeset	1004
14388 04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	1005	lemma card_length: "card (set xs) \<le> length xs"
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	1006	by (induct xs) (auto simp add: card_insert_if)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1007
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1008	lemma set_minus_filter_out:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1009	"set xs - {y} = set (filter (\<lambda>x. \<not> (x = y)) xs)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1010	by (induct xs) auto
15168 33a08cfc3ae5 new functions for sets of lists paulson parents: 15140 diff changeset	1011
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1012	subsubsection {* @{text filter} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1013
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1014	lemma filter_append [simp]: "filter P (xs @ ys) = filter P xs @ filter P ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1015	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1016
15305 0bd9eedaa301 added lemmas nipkow parents: 15304 diff changeset	1017	lemma rev_filter: "rev (filter P xs) = filter P (rev xs)"
0bd9eedaa301 added lemmas nipkow parents: 15304 diff changeset	1018	by (induct xs) simp_all
0bd9eedaa301 added lemmas nipkow parents: 15304 diff changeset	1019
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1020	lemma filter_filter [simp]: "filter P (filter Q xs) = filter (\<lambda>x. Q x \<and> P x) xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1021	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1022
16998 e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1023	lemma length_filter_le [simp]: "length (filter P xs) \<le> length xs"
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1024	by (induct xs) (auto simp add: le_SucI)
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1025
18423 d7859164447f new lemmas nipkow parents: 18336 diff changeset	1026	lemma sum_length_filter_compl:
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1027	"length(filter P xs) + length(filter (%x. ~P x) xs) = length xs"
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1028	by(induct xs) simp_all
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1029
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1030	lemma filter_True [simp]: "\<forall>x \<in> set xs. P x ==> filter P xs = xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1031	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1032
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1033	lemma filter_False [simp]: "\<forall>x \<in> set xs. \<not> P x ==> filter P xs = []"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1034	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1035
16998 e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1036	lemma filter_empty_conv: "(filter P xs = []) = (\<forall>x\<in>set xs. \<not> P x)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1037	by (induct xs) simp_all
16998 e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1038
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1039	lemma filter_id_conv: "(filter P xs = xs) = (\<forall>x\<in>set xs. P x)"
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1040	apply (induct xs)
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1041	apply auto
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1042	apply(cut_tac P=P and xs=xs in length_filter_le)
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1043	apply simp
e0050191e2d1 Added filter lemma nipkow parents: 16973 diff changeset	1044	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1045
16965 46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1046	lemma filter_map:
46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1047	"filter P (map f xs) = map f (filter (P o f) xs)"
46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1048	by (induct xs) simp_all
46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1049
46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1050	lemma length_filter_map[simp]:
46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1051	"length (filter P (map f xs)) = length(filter (P o f) xs)"
46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1052	by (simp add:filter_map)
46697fa536ab added map_filter lemmas nipkow parents: 16770 diff changeset	1053
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1054	lemma filter_is_subset [simp]: "set (filter P xs) \<le> set xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1055	by auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1056
15246 0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1057	lemma length_filter_less:
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1058	"\<lbrakk> x : set xs; ~ P x \<rbrakk> \<Longrightarrow> length(filter P xs) < length xs"
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1059	proof (induct xs)
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1060	case Nil thus ?case by simp
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1061	next
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1062	case (Cons x xs) thus ?case
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1063	apply (auto split:split_if_asm)
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1064	using length_filter_le[of P xs] apply arith
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1065	done
0984a2c2868b added and renamed nipkow parents: 15245 diff changeset	1066	qed
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1067
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1068	lemma length_filter_conv_card:
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1069	"length(filter p xs) = card{i. i < length xs & p(xs!i)}"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1070	proof (induct xs)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1071	case Nil thus ?case by simp
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1072	next
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1073	case (Cons x xs)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1074	let ?S = "{i. i < length xs & p(xs!i)}"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1075	have fin: "finite ?S" by(fast intro: bounded_nat_set_is_finite)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1076	show ?case (is "?l = card ?S'")
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1077	proof (cases)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1078	assume "p x"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1079	hence eq: "?S' = insert 0 (Suc ` ?S)"
25162 ad4d5365d9d8 went back to >0 nipkow parents: 25157 diff changeset	1080	by(auto simp: image_def split:nat.split dest:gr0_implies_Suc)
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1081	have "length (filter p (x # xs)) = Suc(card ?S)"
23388 77645da0db85 tuned proofs: avoid implicit prems; wenzelm parents: 23279 diff changeset	1082	using Cons `p x` by simp
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1083	also have "\<dots> = Suc(card(Suc ` ?S))" using fin
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1084	by (simp add: card_image inj_Suc)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1085	also have "\<dots> = card ?S'" using eq fin
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1086	by (simp add:card_insert_if) (simp add:image_def)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1087	finally show ?thesis .
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1088	next
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1089	assume "\<not> p x"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1090	hence eq: "?S' = Suc ` ?S"
25162 ad4d5365d9d8 went back to >0 nipkow parents: 25157 diff changeset	1091	by(auto simp add: image_def split:nat.split elim:lessE)
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1092	have "length (filter p (x # xs)) = card ?S"
23388 77645da0db85 tuned proofs: avoid implicit prems; wenzelm parents: 23279 diff changeset	1093	using Cons `\<not> p x` by simp
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1094	also have "\<dots> = card(Suc ` ?S)" using fin
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1095	by (simp add: card_image inj_Suc)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1096	also have "\<dots> = card ?S'" using eq fin
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1097	by (simp add:card_insert_if)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1098	finally show ?thesis .
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1099	qed
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1100	qed
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1101
17629 f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1102	lemma Cons_eq_filterD:
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1103	"x#xs = filter P ys \<Longrightarrow>
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1104	\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs"
19585 70a1ce3b23ae removed 'concl is' patterns; wenzelm parents: 19487 diff changeset	1105	(is "_ \<Longrightarrow> \<exists>us vs. ?P ys us vs")
17629 f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1106	proof(induct ys)
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1107	case Nil thus ?case by simp
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1108	next
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1109	case (Cons y ys)
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1110	show ?case (is "\<exists>x. ?Q x")
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1111	proof cases
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1112	assume Py: "P y"
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1113	show ?thesis
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1114	proof cases
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1115	assume "x = y"
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1116	with Py Cons.prems have "?Q []" by simp
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1117	then show ?thesis ..
17629 f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1118	next
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1119	assume "x \<noteq> y"
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1120	with Py Cons.prems show ?thesis by simp
17629 f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1121	qed
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1122	next
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1123	assume "\<not> P y"
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1124	with Cons obtain us vs where "?P (y#ys) (y#us) vs" by fastsimp
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1125	then have "?Q (y#us)" by simp
5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1126	then show ?thesis ..
17629 f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1127	qed
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1128	qed
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1129
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1130	lemma filter_eq_ConsD:
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1131	"filter P ys = x#xs \<Longrightarrow>
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1132	\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs"
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1133	by(rule Cons_eq_filterD) simp
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1134
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1135	lemma filter_eq_Cons_iff:
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1136	"(filter P ys = x#xs) =
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1137	(\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs)"
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1138	by(auto dest:filter_eq_ConsD)
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1139
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1140	lemma Cons_eq_filter_iff:
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1141	"(x#xs = filter P ys) =
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1142	(\<exists>us vs. ys = us @ x # vs \<and> (\<forall>u\<in>set us. \<not> P u) \<and> P x \<and> xs = filter P vs)"
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1143	by(auto dest:Cons_eq_filterD)
f8ea8068c6d9 a few new filter lemmas nipkow parents: 17589 diff changeset	1144
19770 be5c23ebe1eb HOL/Tools/function_package: Added support for mutual recursive definitions. krauss parents: 19623 diff changeset	1145	lemma filter_cong[fundef_cong, recdef_cong]:
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1146	"xs = ys \<Longrightarrow> (\<And>x. x \<in> set ys \<Longrightarrow> P x = Q x) \<Longrightarrow> filter P xs = filter Q ys"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1147	apply simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1148	apply(erule thin_rl)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1149	by (induct ys) simp_all
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1150
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1151
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1152	subsubsection {* List partitioning *}
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1153
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1154	primrec partition :: "('a \<Rightarrow> bool) \<Rightarrow>'a list \<Rightarrow> 'a list \<times> 'a list" where
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1155	"partition P [] = ([], [])"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1156	\| "partition P (x # xs) =
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1157	(let (yes, no) = partition P xs
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1158	in if P x then (x # yes, no) else (yes, x # no))"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1159
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1160	lemma partition_filter1:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1161	"fst (partition P xs) = filter P xs"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1162	by (induct xs) (auto simp add: Let_def split_def)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1163
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1164	lemma partition_filter2:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1165	"snd (partition P xs) = filter (Not o P) xs"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1166	by (induct xs) (auto simp add: Let_def split_def)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1167
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1168	lemma partition_P:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1169	assumes "partition P xs = (yes, no)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1170	shows "(\<forall>p \<in> set yes. P p) \<and> (\<forall>p \<in> set no. \<not> P p)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1171	proof -
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1172	from assms have "yes = fst (partition P xs)" and "no = snd (partition P xs)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1173	by simp_all
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1174	then show ?thesis by (simp_all add: partition_filter1 partition_filter2)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1175	qed
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1176
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1177	lemma partition_set:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1178	assumes "partition P xs = (yes, no)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1179	shows "set yes \<union> set no = set xs"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1180	proof -
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1181	from assms have "yes = fst (partition P xs)" and "no = snd (partition P xs)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1182	by simp_all
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1183	then show ?thesis by (auto simp add: partition_filter1 partition_filter2)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1184	qed
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1185
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	1186
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1187	subsubsection {* @{text concat} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1188
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1189	lemma concat_append [simp]: "concat (xs @ ys) = concat xs @ concat ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1190	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1191
18447 da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	1192	lemma concat_eq_Nil_conv [simp]: "(concat xss = []) = (\<forall>xs \<in> set xss. xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1193	by (induct xss) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1194
18447 da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	1195	lemma Nil_eq_concat_conv [simp]: "([] = concat xss) = (\<forall>xs \<in> set xss. xs = [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1196	by (induct xss) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1197
24308 700e745994c1 removed set_concat_map and improved set_concat nipkow parents: 24286 diff changeset	1198	lemma set_concat [simp]: "set (concat xs) = (UN x:set xs. set x)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1199	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1200
24476 f7ad9fbbeeaa turned list comprehension translations into ML to optimize base case nipkow parents: 24471 diff changeset	1201	lemma concat_map_singleton[simp]: "concat(map (%x. [f x]) xs) = map f xs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1202	by (induct xs) auto
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1203
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1204	lemma map_concat: "map f (concat xs) = concat (map (map f) xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1205	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1206
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1207	lemma filter_concat: "filter p (concat xs) = concat (map (filter p) xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1208	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1209
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1210	lemma rev_concat: "rev (concat xs) = concat (map rev (rev xs))"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1211	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1212
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1213
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1214	subsubsection {* @{text nth} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1215
29827 c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1216	lemma nth_Cons_0 [simp, code]: "(x # xs)!0 = x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1217	by auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1218
29827 c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1219	lemma nth_Cons_Suc [simp, code]: "(x # xs)!(Suc n) = xs!n"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1220	by auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1221
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1222	declare nth.simps [simp del]
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1223
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1224	lemma nth_append:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1225	"(xs @ ys)!n = (if n < length xs then xs!n else ys!(n - length xs))"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1226	apply (induct xs arbitrary: n, simp)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1227	apply (case_tac n, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1228	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1229
14402 4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1230	lemma nth_append_length [simp]: "(xs @ x # ys) ! length xs = x"
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1231	by (induct xs) auto
14402 4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1232
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1233	lemma nth_append_length_plus[simp]: "(xs @ ys) ! (length xs + n) = ys ! n"
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	1234	by (induct xs) auto
14402 4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1235
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1236	lemma nth_map [simp]: "n < length xs ==> (map f xs)!n = f(xs!n)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1237	apply (induct xs arbitrary: n, simp)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1238	apply (case_tac n, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1239	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1240
18423 d7859164447f new lemmas nipkow parents: 18336 diff changeset	1241	lemma hd_conv_nth: "xs \<noteq> [] \<Longrightarrow> hd xs = xs!0"
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1242	by(cases xs) simp_all
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1243
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	1244
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	1245	lemma list_eq_iff_nth_eq:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1246	"(xs = ys) = (length xs = length ys \<and> (ALL i<length xs. xs!i = ys!i))"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1247	apply(induct xs arbitrary: ys)
24632 779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	1248	apply force
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	1249	apply(case_tac ys)
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	1250	apply simp
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	1251	apply(simp add:nth_Cons split:nat.split)apply blast
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	1252	done
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	1253
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1254	lemma set_conv_nth: "set xs = {xs!i \| i. i < length xs}"
15251 bb6f072c8d10 converted some induct_tac to induct paulson parents: 15246 diff changeset	1255	apply (induct xs, simp, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1256	apply safe
24632 779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	1257	apply (metis nat_case_0 nth.simps zero_less_Suc)
779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	1258	apply (metis less_Suc_eq_0_disj nth_Cons_Suc)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1259	apply (case_tac i, simp)
24632 779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	1260	apply (metis diff_Suc_Suc nat_case_Suc nth.simps zero_less_diff)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1261	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1262
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1263	lemma in_set_conv_nth: "(x \<in> set xs) = (\<exists>i < length xs. xs!i = x)"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1264	by(auto simp:set_conv_nth)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1265
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1266	lemma list_ball_nth: "[\| n < length xs; !x : set xs. P x\|] ==> P(xs!n)"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1267	by (auto simp add: set_conv_nth)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1268
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1269	lemma nth_mem [simp]: "n < length xs ==> xs!n : set xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1270	by (auto simp add: set_conv_nth)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1271
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1272	lemma all_nth_imp_all_set:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1273	"[\| !i < length xs. P(xs!i); x : set xs\|] ==> P x"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1274	by (auto simp add: set_conv_nth)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1275
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1276	lemma all_set_conv_all_nth:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1277	"(\<forall>x \<in> set xs. P x) = (\<forall>i. i < length xs --> P (xs ! i))"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1278	by (auto simp add: set_conv_nth)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1279
25296 c187b7422156 rev_nth kleing parents: 25287 diff changeset	1280	lemma rev_nth:
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1281	"n < size xs \<Longrightarrow> rev xs ! n = xs ! (length xs - Suc n)"
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1282	proof (induct xs arbitrary: n)
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1283	case Nil thus ?case by simp
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1284	next
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1285	case (Cons x xs)
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1286	hence n: "n < Suc (length xs)" by simp
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1287	moreover
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1288	{ assume "n < length xs"
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1289	with n obtain n' where "length xs - n = Suc n'"
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1290	by (cases "length xs - n", auto)
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1291	moreover
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1292	then have "length xs - Suc n = n'" by simp
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1293	ultimately
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1294	have "xs ! (length xs - Suc n) = (x # xs) ! (length xs - n)" by simp
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1295	}
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1296	ultimately
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1297	show ?case by (clarsimp simp add: Cons nth_append)
c187b7422156 rev_nth kleing parents: 25287 diff changeset	1298	qed
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1299
31159 bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1300	lemma Skolem_list_nth:
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1301	"(ALL i<k. EX x. P i x) = (EX xs. size xs = k & (ALL i<k. P i (xs!i)))"
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1302	(is "_ = (EX xs. ?P k xs)")
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1303	proof(induct k)
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1304	case 0 show ?case by simp
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1305	next
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1306	case (Suc k)
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1307	show ?case (is "?L = ?R" is "_ = (EX xs. ?P' xs)")
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1308	proof
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1309	assume "?R" thus "?L" using Suc by auto
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1310	next
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1311	assume "?L"
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1312	with Suc obtain x xs where "?P k xs & P k x" by (metis less_Suc_eq)
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1313	hence "?P'(xs@[x])" by(simp add:nth_append less_Suc_eq)
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1314	thus "?R" ..
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1315	qed
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1316	qed
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1317
bac0d673b6d6 new lemma nipkow parents: 31154 diff changeset	1318
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1319	subsubsection {* @{text list_update} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1320
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1321	lemma length_list_update [simp]: "length(xs[i:=x]) = length xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1322	by (induct xs arbitrary: i) (auto split: nat.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1323
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1324	lemma nth_list_update:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1325	"i < length xs==> (xs[i:=x])!j = (if i = j then x else xs!j)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1326	by (induct xs arbitrary: i j) (auto simp add: nth_Cons split: nat.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1327
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1328	lemma nth_list_update_eq [simp]: "i < length xs ==> (xs[i:=x])!i = x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1329	by (simp add: nth_list_update)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1330
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1331	lemma nth_list_update_neq [simp]: "i \<noteq> j ==> xs[i:=x]!j = xs!j"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1332	by (induct xs arbitrary: i j) (auto simp add: nth_Cons split: nat.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1333
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1334	lemma list_update_id[simp]: "xs[i := xs!i] = xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1335	by (induct xs arbitrary: i) (simp_all split:nat.splits)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1336
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1337	lemma list_update_beyond[simp]: "length xs \<le> i \<Longrightarrow> xs[i:=x] = xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1338	apply (induct xs arbitrary: i)
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1339	apply simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1340	apply (case_tac i)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1341	apply simp_all
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1342	done
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1343
31077 28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1344	lemma list_update_nonempty[simp]: "xs[k:=x] = [] \<longleftrightarrow> xs=[]"
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1345	by(metis length_0_conv length_list_update)
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1346
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1347	lemma list_update_same_conv:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1348	"i < length xs ==> (xs[i := x] = xs) = (xs!i = x)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1349	by (induct xs arbitrary: i) (auto split: nat.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1350
14187 26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1351	lemma list_update_append1:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1352	"i < size xs \<Longrightarrow> (xs @ ys)[i:=x] = xs[i:=x] @ ys"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1353	apply (induct xs arbitrary: i, simp)
14187 26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1354	apply(simp split:nat.split)
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1355	done
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1356
15868 9634b3f9d910 more about list_update kleing parents: 15693 diff changeset	1357	lemma list_update_append:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1358	"(xs @ ys) [n:= x] =
15868 9634b3f9d910 more about list_update kleing parents: 15693 diff changeset	1359	(if n < length xs then xs[n:= x] @ ys else xs @ (ys [n-length xs:= x]))"
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1360	by (induct xs arbitrary: n) (auto split:nat.splits)
15868 9634b3f9d910 more about list_update kleing parents: 15693 diff changeset	1361
14402 4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1362	lemma list_update_length [simp]:
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1363	"(xs @ x # ys)[length xs := y] = (xs @ y # ys)"
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1364	by (induct xs, auto)
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	1365
31264 2662d1cdc51f more lemmas nipkow parents: 31258 diff changeset	1366	lemma map_update: "map f (xs[k:= y]) = (map f xs)[k := f y]"
2662d1cdc51f more lemmas nipkow parents: 31258 diff changeset	1367	by(induct xs arbitrary: k)(auto split:nat.splits)
2662d1cdc51f more lemmas nipkow parents: 31258 diff changeset	1368
2662d1cdc51f more lemmas nipkow parents: 31258 diff changeset	1369	lemma rev_update:
2662d1cdc51f more lemmas nipkow parents: 31258 diff changeset	1370	"k < length xs \<Longrightarrow> rev (xs[k:= y]) = (rev xs)[length xs - k - 1 := y]"
2662d1cdc51f more lemmas nipkow parents: 31258 diff changeset	1371	by (induct xs arbitrary: k) (auto simp: list_update_append split:nat.splits)
2662d1cdc51f more lemmas nipkow parents: 31258 diff changeset	1372
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1373	lemma update_zip:
31080 21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1374	"(zip xs ys)[i:=xy] = zip (xs[i:=fst xy]) (ys[i:=snd xy])"
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1375	by (induct ys arbitrary: i xy xs) (auto, case_tac xs, auto split: nat.split)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1376
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1377	lemma set_update_subset_insert: "set(xs[i:=x]) <= insert x (set xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1378	by (induct xs arbitrary: i) (auto split: nat.split)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1379
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1380	lemma set_update_subsetI: "[\| set xs <= A; x:A \|] ==> set(xs[i := x]) <= A"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1381	by (blast dest!: set_update_subset_insert [THEN subsetD])
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1382
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1383	lemma set_update_memI: "n < length xs \<Longrightarrow> x \<in> set (xs[n := x])"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1384	by (induct xs arbitrary: n) (auto split:nat.splits)
15868 9634b3f9d910 more about list_update kleing parents: 15693 diff changeset	1385
31077 28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1386	lemma list_update_overwrite[simp]:
24796 529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1387	"xs [i := x, i := y] = xs [i := y]"
31077 28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1388	apply (induct xs arbitrary: i) apply simp
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1389	apply (case_tac i, simp_all)
24796 529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1390	done
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1391
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1392	lemma list_update_swap:
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1393	"i \<noteq> i' \<Longrightarrow> xs [i := x, i' := x'] = xs [i' := x', i := x]"
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1394	apply (induct xs arbitrary: i i')
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1395	apply simp
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1396	apply (case_tac i, case_tac i')
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1397	apply auto
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1398	apply (case_tac i')
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1399	apply auto
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1400	done
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1401
29827 c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1402	lemma list_update_code [code]:
c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1403	"[][i := y] = []"
c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1404	"(x # xs)[0 := y] = y # xs"
c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1405	"(x # xs)[Suc i := y] = x # xs[i := y]"
c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1406	by simp_all
c82b3e8a4daf code theorems for nth, list_update haftmann parents: 29822 diff changeset	1407
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1408
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1409	subsubsection {* @{text last} and @{text butlast} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1410
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1411	lemma last_snoc [simp]: "last (xs @ [x]) = x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1412	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1413
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1414	lemma butlast_snoc [simp]: "butlast (xs @ [x]) = xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1415	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1416
14302 6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1417	lemma last_ConsL: "xs = [] \<Longrightarrow> last(x#xs) = x"
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1418	by(simp add:last.simps)
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1419
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1420	lemma last_ConsR: "xs \<noteq> [] \<Longrightarrow> last(x#xs) = last xs"
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1421	by(simp add:last.simps)
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1422
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1423	lemma last_append: "last(xs @ ys) = (if ys = [] then last xs else last ys)"
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1424	by (induct xs) (auto)
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1425
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1426	lemma last_appendL[simp]: "ys = [] \<Longrightarrow> last(xs @ ys) = last xs"
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1427	by(simp add:last_append)
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1428
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1429	lemma last_appendR[simp]: "ys \<noteq> [] \<Longrightarrow> last(xs @ ys) = last ys"
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1430	by(simp add:last_append)
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	1431
17762 478869f444ca new hd/rev/last lemmas nipkow parents: 17724 diff changeset	1432	lemma hd_rev: "xs \<noteq> [] \<Longrightarrow> hd(rev xs) = last xs"
478869f444ca new hd/rev/last lemmas nipkow parents: 17724 diff changeset	1433	by(rule rev_exhaust[of xs]) simp_all
478869f444ca new hd/rev/last lemmas nipkow parents: 17724 diff changeset	1434
478869f444ca new hd/rev/last lemmas nipkow parents: 17724 diff changeset	1435	lemma last_rev: "xs \<noteq> [] \<Longrightarrow> last(rev xs) = hd xs"
478869f444ca new hd/rev/last lemmas nipkow parents: 17724 diff changeset	1436	by(cases xs) simp_all
478869f444ca new hd/rev/last lemmas nipkow parents: 17724 diff changeset	1437
17765 e3cd31bc2e40 added last in set lemma nipkow parents: 17762 diff changeset	1438	lemma last_in_set[simp]: "as \<noteq> [] \<Longrightarrow> last as \<in> set as"
e3cd31bc2e40 added last in set lemma nipkow parents: 17762 diff changeset	1439	by (induct as) auto
17762 478869f444ca new hd/rev/last lemmas nipkow parents: 17724 diff changeset	1440
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1441	lemma length_butlast [simp]: "length (butlast xs) = length xs - 1"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1442	by (induct xs rule: rev_induct) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1443
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1444	lemma butlast_append:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1445	"butlast (xs @ ys) = (if ys = [] then butlast xs else xs @ butlast ys)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1446	by (induct xs arbitrary: ys) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1447
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1448	lemma append_butlast_last_id [simp]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1449	"xs \<noteq> [] ==> butlast xs @ [last xs] = xs"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1450	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1451
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1452	lemma in_set_butlastD: "x : set (butlast xs) ==> x : set xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1453	by (induct xs) (auto split: split_if_asm)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1454
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1455	lemma in_set_butlast_appendI:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1456	"x : set (butlast xs) \| x : set (butlast ys) ==> x : set (butlast (xs @ ys))"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1457	by (auto dest: in_set_butlastD simp add: butlast_append)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1458
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1459	lemma last_drop[simp]: "n < length xs \<Longrightarrow> last (drop n xs) = last xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1460	apply (induct xs arbitrary: n)
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1461	apply simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1462	apply (auto split:nat.split)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1463	done
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1464
30128 365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1465	lemma last_conv_nth: "xs\<noteq>[] \<Longrightarrow> last xs = xs!(length xs - 1)"
17589 58eeffd73be1 renamed rules to iprover nipkow parents: 17501 diff changeset	1466	by(induct xs)(auto simp:neq_Nil_conv)
58eeffd73be1 renamed rules to iprover nipkow parents: 17501 diff changeset	1467
30128 365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1468	lemma butlast_conv_take: "butlast xs = take (length xs - 1) xs"
26584 46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1469	by (induct xs, simp, case_tac xs, simp_all)
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1470
31077 28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1471	lemma last_list_update:
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1472	"xs \<noteq> [] \<Longrightarrow> last(xs[k:=x]) = (if k = size xs - 1 then x else last xs)"
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1473	by (auto simp: last_conv_nth)
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1474
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1475	lemma butlast_list_update:
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1476	"butlast(xs[k:=x]) =
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1477	(if k = size xs - 1 then butlast xs else (butlast xs)[k:=x])"
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1478	apply(cases xs rule:rev_cases)
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1479	apply simp
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1480	apply(simp add:list_update_append split:nat.splits)
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1481	done
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1482
24796 529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1483
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1484	subsubsection {* @{text take} and @{text drop} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1485
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1486	lemma take_0 [simp]: "take 0 xs = []"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1487	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1488
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1489	lemma drop_0 [simp]: "drop 0 xs = xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1490	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1491
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1492	lemma take_Suc_Cons [simp]: "take (Suc n) (x # xs) = x # take n xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1493	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1494
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1495	lemma drop_Suc_Cons [simp]: "drop (Suc n) (x # xs) = drop n xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1496	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1497
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1498	declare take_Cons [simp del] and drop_Cons [simp del]
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1499
30128 365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1500	lemma take_1_Cons [simp]: "take 1 (x # xs) = [x]"
365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1501	unfolding One_nat_def by simp
365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1502
365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1503	lemma drop_1_Cons [simp]: "drop 1 (x # xs) = xs"
365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1504	unfolding One_nat_def by simp
365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1505
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1506	lemma take_Suc: "xs ~= [] ==> take (Suc n) xs = hd xs # take n (tl xs)"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1507	by(clarsimp simp add:neq_Nil_conv)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1508
14187 26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1509	lemma drop_Suc: "drop (Suc n) xs = drop n (tl xs)"
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1510	by(cases xs, simp_all)
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1511
26584 46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1512	lemma take_tl: "take n (tl xs) = tl (take (Suc n) xs)"
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1513	by (induct xs arbitrary: n) simp_all
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1514
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1515	lemma drop_tl: "drop n (tl xs) = tl(drop n xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1516	by(induct xs arbitrary: n, simp_all add:drop_Cons drop_Suc split:nat.split)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1517
26584 46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1518	lemma tl_take: "tl (take n xs) = take (n - 1) (tl xs)"
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1519	by (cases n, simp, cases xs, auto)
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1520
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1521	lemma tl_drop: "tl (drop n xs) = drop n (tl xs)"
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1522	by (simp only: drop_tl)
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1523
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1524	lemma nth_via_drop: "drop n xs = y#ys \<Longrightarrow> xs!n = y"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1525	apply (induct xs arbitrary: n, simp)
14187 26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1526	apply(simp add:drop_Cons nth_Cons split:nat.splits)
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1527	done
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1528
13913 b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1529	lemma take_Suc_conv_app_nth:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1530	"i < length xs \<Longrightarrow> take (Suc i) xs = take i xs @ [xs!i]"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1531	apply (induct xs arbitrary: i, simp)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1532	apply (case_tac i, auto)
13913 b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1533	done
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1534
14591 7be4d5dadf15 lemma drop_Suc_conv_tl added. mehta parents: 14589 diff changeset	1535	lemma drop_Suc_conv_tl:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1536	"i < length xs \<Longrightarrow> (xs!i) # (drop (Suc i) xs) = drop i xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1537	apply (induct xs arbitrary: i, simp)
14591 7be4d5dadf15 lemma drop_Suc_conv_tl added. mehta parents: 14589 diff changeset	1538	apply (case_tac i, auto)
7be4d5dadf15 lemma drop_Suc_conv_tl added. mehta parents: 14589 diff changeset	1539	done
7be4d5dadf15 lemma drop_Suc_conv_tl added. mehta parents: 14589 diff changeset	1540
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1541	lemma length_take [simp]: "length (take n xs) = min (length xs) n"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1542	by (induct n arbitrary: xs) (auto, case_tac xs, auto)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1543
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1544	lemma length_drop [simp]: "length (drop n xs) = (length xs - n)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1545	by (induct n arbitrary: xs) (auto, case_tac xs, auto)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1546
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1547	lemma take_all [simp]: "length xs <= n ==> take n xs = xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1548	by (induct n arbitrary: xs) (auto, case_tac xs, auto)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1549
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1550	lemma drop_all [simp]: "length xs <= n ==> drop n xs = []"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1551	by (induct n arbitrary: xs) (auto, case_tac xs, auto)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1552
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1553	lemma take_append [simp]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1554	"take n (xs @ ys) = (take n xs @ take (n - length xs) ys)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1555	by (induct n arbitrary: xs) (auto, case_tac xs, auto)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1556
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1557	lemma drop_append [simp]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1558	"drop n (xs @ ys) = drop n xs @ drop (n - length xs) ys"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1559	by (induct n arbitrary: xs) (auto, case_tac xs, auto)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1560
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1561	lemma take_take [simp]: "take n (take m xs) = take (min n m) xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1562	apply (induct m arbitrary: xs n, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1563	apply (case_tac xs, auto)
15236 f289e8ba2bb3 Proofs needed to be updated because induction now preserves name of nipkow parents: 15176 diff changeset	1564	apply (case_tac n, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1565	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1566
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1567	lemma drop_drop [simp]: "drop n (drop m xs) = drop (n + m) xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1568	apply (induct m arbitrary: xs, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1569	apply (case_tac xs, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1570	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1571
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1572	lemma take_drop: "take n (drop m xs) = drop m (take (n + m) xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1573	apply (induct m arbitrary: xs n, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1574	apply (case_tac xs, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1575	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1576
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1577	lemma drop_take: "drop n (take m xs) = take (m-n) (drop n xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1578	apply(induct xs arbitrary: m n)
14802 e05116289ff9 added drop_take:thm nipkow parents: 14770 diff changeset	1579	apply simp
e05116289ff9 added drop_take:thm nipkow parents: 14770 diff changeset	1580	apply(simp add: take_Cons drop_Cons split:nat.split)
e05116289ff9 added drop_take:thm nipkow parents: 14770 diff changeset	1581	done
e05116289ff9 added drop_take:thm nipkow parents: 14770 diff changeset	1582
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1583	lemma append_take_drop_id [simp]: "take n xs @ drop n xs = xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1584	apply (induct n arbitrary: xs, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1585	apply (case_tac xs, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1586	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1587
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1588	lemma take_eq_Nil[simp]: "(take n xs = []) = (n = 0 \<or> xs = [])"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1589	apply(induct xs arbitrary: n)
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1590	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1591	apply(simp add:take_Cons split:nat.split)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1592	done
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1593
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1594	lemma drop_eq_Nil[simp]: "(drop n xs = []) = (length xs <= n)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1595	apply(induct xs arbitrary: n)
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1596	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1597	apply(simp add:drop_Cons split:nat.split)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1598	done
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1599
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1600	lemma take_map: "take n (map f xs) = map f (take n xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1601	apply (induct n arbitrary: xs, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1602	apply (case_tac xs, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1603	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1604
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1605	lemma drop_map: "drop n (map f xs) = map f (drop n xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1606	apply (induct n arbitrary: xs, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1607	apply (case_tac xs, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1608	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1609
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1610	lemma rev_take: "rev (take i xs) = drop (length xs - i) (rev xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1611	apply (induct xs arbitrary: i, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1612	apply (case_tac i, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1613	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1614
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1615	lemma rev_drop: "rev (drop i xs) = take (length xs - i) (rev xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1616	apply (induct xs arbitrary: i, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1617	apply (case_tac i, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1618	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1619
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1620	lemma nth_take [simp]: "i < n ==> (take n xs)!i = xs!i"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1621	apply (induct xs arbitrary: i n, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1622	apply (case_tac n, blast)
144f45277d5a misc tidying paulson parents: 14187 diff changeset	1623	apply (case_tac i, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1624	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1625
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1626	lemma nth_drop [simp]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1627	"n + i <= length xs ==> (drop n xs)!i = xs!(n + i)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1628	apply (induct n arbitrary: xs i, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1629	apply (case_tac xs, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1630	done
3507 157be29ad5ba Improved length = size translation. nipkow parents: 3465 diff changeset	1631
26584 46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1632	lemma butlast_take:
30128 365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1633	"n <= length xs ==> butlast (take n xs) = take (n - 1) xs"
26584 46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1634	by (simp add: butlast_conv_take min_max.inf_absorb1 min_max.inf_absorb2)
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1635
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1636	lemma butlast_drop: "butlast (drop n xs) = drop n (butlast xs)"
30128 365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1637	by (simp add: butlast_conv_take drop_take add_ac)
26584 46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1638
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1639	lemma take_butlast: "n < length xs ==> take n (butlast xs) = take n xs"
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1640	by (simp add: butlast_conv_take min_max.inf_absorb1)
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1641
46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1642	lemma drop_butlast: "drop n (butlast xs) = butlast (drop n xs)"
30128 365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	1643	by (simp add: butlast_conv_take drop_take add_ac)
26584 46f3b89b2445 move lemmas from Word/BinBoolList.thy to List.thy huffman parents: 26480 diff changeset	1644
18423 d7859164447f new lemmas nipkow parents: 18336 diff changeset	1645	lemma hd_drop_conv_nth: "\<lbrakk> xs \<noteq> []; n < length xs \<rbrakk> \<Longrightarrow> hd(drop n xs) = xs!n"
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1646	by(simp add: hd_conv_nth)
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1647
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1648	lemma set_take_subset: "set(take n xs) \<subseteq> set xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1649	by(induct xs arbitrary: n)(auto simp:take_Cons split:nat.split)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1650
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1651	lemma set_drop_subset: "set(drop n xs) \<subseteq> set xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1652	by(induct xs arbitrary: n)(auto simp:drop_Cons split:nat.split)
14025 d9b155757dc8 * empty log message * nipkow parents: 13913 diff changeset	1653
14187 26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1654	lemma in_set_takeD: "x : set(take n xs) \<Longrightarrow> x : set xs"
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1655	using set_take_subset by fast
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1656
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1657	lemma in_set_dropD: "x : set(drop n xs) \<Longrightarrow> x : set xs"
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1658	using set_drop_subset by fast
26dfcd0ac436 Added new theorems nipkow parents: 14111 diff changeset	1659
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1660	lemma append_eq_conv_conj:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1661	"(xs @ ys = zs) = (xs = take (length xs) zs \<and> ys = drop (length xs) zs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1662	apply (induct xs arbitrary: zs, simp, clarsimp)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1663	apply (case_tac zs, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1664	done
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1665
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1666	lemma take_add:
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1667	"i+j \<le> length(xs) \<Longrightarrow> take (i+j) xs = take i xs @ take j (drop i xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1668	apply (induct xs arbitrary: i, auto)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1669	apply (case_tac i, simp_all)
14050 826037db30cd new theorem paulson parents: 14025 diff changeset	1670	done
826037db30cd new theorem paulson parents: 14025 diff changeset	1671
14300 bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1672	lemma append_eq_append_conv_if:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1673	"(xs\<^isub>1 @ xs\<^isub>2 = ys\<^isub>1 @ ys\<^isub>2) =
14300 bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1674	(if size xs\<^isub>1 \<le> size ys\<^isub>1
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1675	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
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1676	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)"
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1677	apply(induct xs\<^isub>1 arbitrary: ys\<^isub>1)
14300 bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1678	apply simp
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1679	apply(case_tac ys\<^isub>1)
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1680	apply simp_all
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1681	done
bf8b8c9425c3 * empty log message * nipkow parents: 14247 diff changeset	1682
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1683	lemma take_hd_drop:
30079 293b896b9c25 make proofs work whether or not One_nat_def is a simp rule; replace 1 with Suc 0 in the rhs of some simp rules huffman parents: 30008 diff changeset	1684	"n < length xs \<Longrightarrow> take n xs @ [hd (drop n xs)] = take (Suc n) xs"
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1685	apply(induct xs arbitrary: n)
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1686	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1687	apply(simp add:drop_Cons split:nat.split)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1688	done
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	1689
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1690	lemma id_take_nth_drop:
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1691	"i < length xs \<Longrightarrow> xs = take i xs @ xs!i # drop (Suc i) xs"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1692	proof -
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1693	assume si: "i < length xs"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1694	hence "xs = take (Suc i) xs @ drop (Suc i) xs" by auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1695	moreover
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1696	from si have "take (Suc i) xs = take i xs @ [xs!i]"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1697	apply (rule_tac take_Suc_conv_app_nth) by arith
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1698	ultimately show ?thesis by auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1699	qed
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1700
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1701	lemma upd_conv_take_nth_drop:
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1702	"i < length xs \<Longrightarrow> xs[i:=a] = take i xs @ a # drop (Suc i) xs"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1703	proof -
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1704	assume i: "i < length xs"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1705	have "xs[i:=a] = (take i xs @ xs!i # drop (Suc i) xs)[i:=a]"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1706	by(rule arg_cong[OF id_take_nth_drop[OF i]])
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1707	also have "\<dots> = take i xs @ a # drop (Suc i) xs"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1708	using i by (simp add: list_update_append)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1709	finally show ?thesis .
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1710	qed
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1711
24796 529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1712	lemma nth_drop':
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1713	"i < length xs \<Longrightarrow> xs ! i # drop (Suc i) xs = drop i xs"
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1714	apply (induct i arbitrary: xs)
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1715	apply (simp add: neq_Nil_conv)
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1716	apply (erule exE)+
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1717	apply simp
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1718	apply (case_tac xs)
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1719	apply simp_all
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1720	done
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	1721
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1722
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1723	subsubsection {* @{text takeWhile} and @{text dropWhile} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1724
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1725	lemma takeWhile_dropWhile_id [simp]: "takeWhile P xs @ dropWhile P xs = xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1726	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1727
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1728	lemma takeWhile_append1 [simp]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1729	"[\| x:set xs; ~P(x)\|] ==> takeWhile P (xs @ ys) = takeWhile P xs"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1730	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1731
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1732	lemma takeWhile_append2 [simp]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1733	"(!!x. x : set xs ==> P x) ==> takeWhile P (xs @ ys) = xs @ takeWhile P ys"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1734	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1735
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1736	lemma takeWhile_tail: "\<not> P x ==> takeWhile P (xs @ (x#l)) = takeWhile P xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1737	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1738
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1739	lemma dropWhile_append1 [simp]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1740	"[\| x : set xs; ~P(x)\|] ==> dropWhile P (xs @ ys) = (dropWhile P xs)@ys"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1741	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1742
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1743	lemma dropWhile_append2 [simp]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1744	"(!!x. x:set xs ==> P(x)) ==> dropWhile P (xs @ ys) = dropWhile P ys"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1745	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1746
23971 e6d505d5b03d renamed lemma "set_take_whileD" to "set_takeWhileD" krauss parents: 23740 diff changeset	1747	lemma set_takeWhileD: "x : set (takeWhile P xs) ==> x : set xs \<and> P x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1748	by (induct xs) (auto split: split_if_asm)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1749
13913 b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1750	lemma takeWhile_eq_all_conv[simp]:
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1751	"(takeWhile P xs = xs) = (\<forall>x \<in> set xs. P x)"
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1752	by(induct xs, auto)
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1753
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1754	lemma dropWhile_eq_Nil_conv[simp]:
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1755	"(dropWhile P xs = []) = (\<forall>x \<in> set xs. P x)"
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1756	by(induct xs, auto)
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1757
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1758	lemma dropWhile_eq_Cons_conv:
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1759	"(dropWhile P xs = y#ys) = (xs = takeWhile P xs @ y # ys & \<not> P y)"
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1760	by(induct xs, auto)
b3ed67af04b8 Added take/dropWhile thms nipkow parents: 13883 diff changeset	1761
31077 28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1762	lemma distinct_takeWhile[simp]: "distinct xs ==> distinct (takeWhile P xs)"
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1763	by (induct xs) (auto dest: set_takeWhileD)
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1764
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1765	lemma distinct_dropWhile[simp]: "distinct xs ==> distinct (dropWhile P xs)"
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1766	by (induct xs) auto
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1767
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	1768
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1769	text{* The following two lemmmas could be generalized to an arbitrary
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1770	property. *}
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1771
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1772	lemma takeWhile_neq_rev: "\<lbrakk>distinct xs; x \<in> set xs\<rbrakk> \<Longrightarrow>
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1773	takeWhile (\<lambda>y. y \<noteq> x) (rev xs) = rev (tl (dropWhile (\<lambda>y. y \<noteq> x) xs))"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1774	by(induct xs) (auto simp: takeWhile_tail[where l="[]"])
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1775
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1776	lemma dropWhile_neq_rev: "\<lbrakk>distinct xs; x \<in> set xs\<rbrakk> \<Longrightarrow>
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1777	dropWhile (\<lambda>y. y \<noteq> x) (rev xs) = x # rev (takeWhile (\<lambda>y. y \<noteq> x) xs)"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1778	apply(induct xs)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1779	apply simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1780	apply auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1781	apply(subst dropWhile_append2)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1782	apply auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1783	done
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	1784
18423 d7859164447f new lemmas nipkow parents: 18336 diff changeset	1785	lemma takeWhile_not_last:
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1786	"\<lbrakk> xs \<noteq> []; distinct xs\<rbrakk> \<Longrightarrow> takeWhile (\<lambda>y. y \<noteq> last xs) xs = butlast xs"
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1787	apply(induct xs)
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1788	apply simp
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1789	apply(case_tac xs)
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1790	apply(auto)
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1791	done
d7859164447f new lemmas nipkow parents: 18336 diff changeset	1792
19770 be5c23ebe1eb HOL/Tools/function_package: Added support for mutual recursive definitions. krauss parents: 19623 diff changeset	1793	lemma takeWhile_cong [fundef_cong, recdef_cong]:
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	1794	"[\| l = k; !!x. x : set l ==> P x = Q x \|]
1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	1795	==> takeWhile P l = takeWhile Q k"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1796	by (induct k arbitrary: l) (simp_all)
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	1797
19770 be5c23ebe1eb HOL/Tools/function_package: Added support for mutual recursive definitions. krauss parents: 19623 diff changeset	1798	lemma dropWhile_cong [fundef_cong, recdef_cong]:
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	1799	"[\| l = k; !!x. x : set l ==> P x = Q x \|]
1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	1800	==> dropWhile P l = dropWhile Q k"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1801	by (induct k arbitrary: l, simp_all)
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	1802
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1803
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1804	subsubsection {* @{text zip} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1805
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1806	lemma zip_Nil [simp]: "zip [] ys = []"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1807	by (induct ys) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1808
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1809	lemma zip_Cons_Cons [simp]: "zip (x # xs) (y # ys) = (x, y) # zip xs ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1810	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1811
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1812	declare zip_Cons [simp del]
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1813
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1814	lemma zip_Cons1:
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1815	"zip (x#xs) ys = (case ys of [] \<Rightarrow> [] \| y#ys \<Rightarrow> (x,y)#zip xs ys)"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1816	by(auto split:list.split)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	1817
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1818	lemma length_zip [simp]:
22493 db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1819	"length (zip xs ys) = min (length xs) (length ys)"
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1820	by (induct xs ys rule:list_induct2') auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1821
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1822	lemma zip_append1:
22493 db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1823	"zip (xs @ ys) zs =
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1824	zip xs (take (length xs) zs) @ zip ys (drop (length xs) zs)"
22493 db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1825	by (induct xs zs rule:list_induct2') auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1826
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1827	lemma zip_append2:
22493 db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1828	"zip xs (ys @ zs) =
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1829	zip (take (length ys) xs) ys @ zip (drop (length ys) xs) zs"
22493 db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1830	by (induct xs ys rule:list_induct2') auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1831
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1832	lemma zip_append [simp]:
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1833	"[\| length xs = length us; length ys = length vs \|] ==>
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1834	zip (xs@ys) (us@vs) = zip xs us @ zip ys vs"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1835	by (simp add: zip_append1)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1836
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1837	lemma zip_rev:
14247 cb32eb89bddd * empty log message * nipkow parents: 14208 diff changeset	1838	"length xs = length ys ==> zip (rev xs) (rev ys) = rev (zip xs ys)"
cb32eb89bddd * empty log message * nipkow parents: 14208 diff changeset	1839	by (induct rule:list_induct2, simp_all)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1840
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1841	lemma map_zip_map:
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1842	"map f (zip (map g xs) ys) = map (%(x,y). f(g x, y)) (zip xs ys)"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1843	apply(induct xs arbitrary:ys) apply simp
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1844	apply(case_tac ys)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1845	apply simp_all
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1846	done
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1847
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1848	lemma map_zip_map2:
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1849	"map f (zip xs (map g ys)) = map (%(x,y). f(x, g y)) (zip xs ys)"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1850	apply(induct xs arbitrary:ys) apply simp
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1851	apply(case_tac ys)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1852	apply simp_all
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1853	done
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	1854
31080 21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1855	text{* Courtesy of Andreas Lochbihler: *}
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1856	lemma zip_same_conv_map: "zip xs xs = map (\<lambda>x. (x, x)) xs"
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1857	by(induct xs) auto
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1858
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1859	lemma nth_zip [simp]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1860	"[\| i < length xs; i < length ys\|] ==> (zip xs ys)!i = (xs!i, ys!i)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1861	apply (induct ys arbitrary: i xs, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1862	apply (case_tac xs)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1863	apply (simp_all add: nth.simps split: nat.split)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1864	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1865
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1866	lemma set_zip:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1867	"set (zip xs ys) = {(xs!i, ys!i) \| i. i < min (length xs) (length ys)}"
31080 21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1868	by(simp add: set_conv_nth cong: rev_conj_cong)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1869
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1870	lemma zip_update:
31080 21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1871	"zip (xs[i:=x]) (ys[i:=y]) = (zip xs ys)[i:=(x,y)]"
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	1872	by(rule sym, simp add: update_zip)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1873
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1874	lemma zip_replicate [simp]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1875	"zip (replicate i x) (replicate j y) = replicate (min i j) (x,y)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1876	apply (induct i arbitrary: j, auto)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1877	apply (case_tac j, auto)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1878	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1879
19487 d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1880	lemma take_zip:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1881	"take n (zip xs ys) = zip (take n xs) (take n ys)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1882	apply (induct n arbitrary: xs ys)
19487 d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1883	apply simp
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1884	apply (case_tac xs, simp)
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1885	apply (case_tac ys, simp_all)
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1886	done
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1887
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1888	lemma drop_zip:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1889	"drop n (zip xs ys) = zip (drop n xs) (drop n ys)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	1890	apply (induct n arbitrary: xs ys)
19487 d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1891	apply simp
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1892	apply (case_tac xs, simp)
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1893	apply (case_tac ys, simp_all)
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1894	done
d5e79a41bce0 added zip/take/drop lemmas nipkow parents: 19390 diff changeset	1895
22493 db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1896	lemma set_zip_leftD:
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1897	"(x,y)\<in> set (zip xs ys) \<Longrightarrow> x \<in> set xs"
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1898	by (induct xs ys rule:list_induct2') auto
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1899
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1900	lemma set_zip_rightD:
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1901	"(x,y)\<in> set (zip xs ys) \<Longrightarrow> y \<in> set ys"
db930e490fe5 added another rule for simultaneous induction, and lemmas for zip krauss parents: 22422 diff changeset	1902	by (induct xs ys rule:list_induct2') auto
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1903
23983 79dc793bec43 Added lemmas nipkow parents: 23971 diff changeset	1904	lemma in_set_zipE:
79dc793bec43 Added lemmas nipkow parents: 23971 diff changeset	1905	"(x,y) : set(zip xs ys) \<Longrightarrow> (\<lbrakk> x : set xs; y : set ys \<rbrakk> \<Longrightarrow> R) \<Longrightarrow> R"
79dc793bec43 Added lemmas nipkow parents: 23971 diff changeset	1906	by(blast dest: set_zip_leftD set_zip_rightD)
79dc793bec43 Added lemmas nipkow parents: 23971 diff changeset	1907
29829 9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1908	lemma zip_map_fst_snd:
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1909	"zip (map fst zs) (map snd zs) = zs"
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1910	by (induct zs) simp_all
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1911
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1912	lemma zip_eq_conv:
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1913	"length xs = length ys \<Longrightarrow> zip xs ys = zs \<longleftrightarrow> map fst zs = xs \<and> map snd zs = ys"
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1914	by (auto simp add: zip_map_fst_snd)
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1915
9acb915a62fa code theorems for nth, list_update haftmann parents: 29827 diff changeset	1916
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	1917	subsubsection {* @{text list_all2} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1918
14316 91b897b9a2dc added some [intro?] and [trans] for list_all2 lemmas kleing parents: 14302 diff changeset	1919	lemma list_all2_lengthD [intro?]:
91b897b9a2dc added some [intro?] and [trans] for list_all2 lemmas kleing parents: 14302 diff changeset	1920	"list_all2 P xs ys ==> length xs = length ys"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1921	by (simp add: list_all2_def)
19607 07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	1922
19787 b949911ecff5 improved code lemmas haftmann parents: 19770 diff changeset	1923	lemma list_all2_Nil [iff, code]: "list_all2 P [] ys = (ys = [])"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1924	by (simp add: list_all2_def)
19607 07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	1925
19787 b949911ecff5 improved code lemmas haftmann parents: 19770 diff changeset	1926	lemma list_all2_Nil2 [iff, code]: "list_all2 P xs [] = (xs = [])"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1927	by (simp add: list_all2_def)
19607 07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	1928
07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	1929	lemma list_all2_Cons [iff, code]:
07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	1930	"list_all2 P (x # xs) (y # ys) = (P x y \<and> list_all2 P xs ys)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1931	by (auto simp add: list_all2_def)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1932
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1933	lemma list_all2_Cons1:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1934	"list_all2 P (x # xs) ys = (\<exists>z zs. ys = z # zs \<and> P x z \<and> list_all2 P xs zs)"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1935	by (cases ys) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1936
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1937	lemma list_all2_Cons2:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1938	"list_all2 P xs (y # ys) = (\<exists>z zs. xs = z # zs \<and> P z y \<and> list_all2 P zs ys)"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1939	by (cases xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1940
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	1941	lemma list_all2_rev [iff]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1942	"list_all2 P (rev xs) (rev ys) = list_all2 P xs ys"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1943	by (simp add: list_all2_def zip_rev cong: conj_cong)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1944
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1945	lemma list_all2_rev1:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1946	"list_all2 P (rev xs) ys = list_all2 P xs (rev ys)"
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1947	by (subst list_all2_rev [symmetric]) simp
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1948
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1949	lemma list_all2_append1:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1950	"list_all2 P (xs @ ys) zs =
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1951	(EX us vs. zs = us @ vs \<and> length us = length xs \<and> length vs = length ys \<and>
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1952	list_all2 P xs us \<and> list_all2 P ys vs)"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1953	apply (simp add: list_all2_def zip_append1)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1954	apply (rule iffI)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1955	apply (rule_tac x = "take (length xs) zs" in exI)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1956	apply (rule_tac x = "drop (length xs) zs" in exI)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1957	apply (force split: nat_diff_split simp add: min_def, clarify)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1958	apply (simp add: ball_Un)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1959	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1960
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1961	lemma list_all2_append2:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1962	"list_all2 P xs (ys @ zs) =
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1963	(EX us vs. xs = us @ vs \<and> length us = length ys \<and> length vs = length zs \<and>
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1964	list_all2 P us ys \<and> list_all2 P vs zs)"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1965	apply (simp add: list_all2_def zip_append2)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1966	apply (rule iffI)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1967	apply (rule_tac x = "take (length ys) xs" in exI)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1968	apply (rule_tac x = "drop (length ys) xs" in exI)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	1969	apply (force split: nat_diff_split simp add: min_def, clarify)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1970	apply (simp add: ball_Un)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1971	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1972
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1973	lemma list_all2_append:
14247 cb32eb89bddd * empty log message * nipkow parents: 14208 diff changeset	1974	"length xs = length ys \<Longrightarrow>
cb32eb89bddd * empty log message * nipkow parents: 14208 diff changeset	1975	list_all2 P (xs@us) (ys@vs) = (list_all2 P xs ys \<and> list_all2 P us vs)"
cb32eb89bddd * empty log message * nipkow parents: 14208 diff changeset	1976	by (induct rule:list_induct2, simp_all)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1977
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1978	lemma list_all2_appendI [intro?, trans]:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1979	"\<lbrakk> list_all2 P a b; list_all2 P c d \<rbrakk> \<Longrightarrow> list_all2 P (a@c) (b@d)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	1980	by (simp add: list_all2_append list_all2_lengthD)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	1981
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1982	lemma list_all2_conv_all_nth:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1983	"list_all2 P xs ys =
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1984	(length xs = length ys \<and> (\<forall>i < length xs. P (xs!i) (ys!i)))"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	1985	by (force simp add: list_all2_def set_zip)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	1986
13883 0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1987	lemma list_all2_trans:
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1988	assumes tr: "!!a b c. P1 a b ==> P2 b c ==> P3 a c"
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1989	shows "!!bs cs. list_all2 P1 as bs ==> list_all2 P2 bs cs ==> list_all2 P3 as cs"
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1990	(is "!!bs cs. PROP ?Q as bs cs")
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1991	proof (induct as)
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1992	fix x xs bs assume I1: "!!bs cs. PROP ?Q xs bs cs"
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1993	show "!!cs. PROP ?Q (x # xs) bs cs"
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1994	proof (induct bs)
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1995	fix y ys cs assume I2: "!!cs. PROP ?Q (x # xs) ys cs"
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1996	show "PROP ?Q (x # xs) (y # ys) cs"
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1997	by (induct cs) (auto intro: tr I1 I2)
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1998	qed simp
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	1999	qed simp
0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	2000
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2001	lemma list_all2_all_nthI [intro?]:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2002	"length a = length b \<Longrightarrow> (\<And>n. n < length a \<Longrightarrow> P (a!n) (b!n)) \<Longrightarrow> list_all2 P a b"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2003	by (simp add: list_all2_conv_all_nth)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2004
14395 cc96cc06abf9 new theorem paulson parents: 14388 diff changeset	2005	lemma list_all2I:
cc96cc06abf9 new theorem paulson parents: 14388 diff changeset	2006	"\<forall>x \<in> set (zip a b). split P x \<Longrightarrow> length a = length b \<Longrightarrow> list_all2 P a b"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2007	by (simp add: list_all2_def)
14395 cc96cc06abf9 new theorem paulson parents: 14388 diff changeset	2008
14328 fd063037fdf5 list_all2_nthD no good as [intro?] kleing parents: 14327 diff changeset	2009	lemma list_all2_nthD:
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2010	"\<lbrakk> list_all2 P xs ys; p < size xs \<rbrakk> \<Longrightarrow> P (xs!p) (ys!p)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2011	by (simp add: list_all2_conv_all_nth)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2012
14302 6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	2013	lemma list_all2_nthD2:
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	2014	"\<lbrakk>list_all2 P xs ys; p < size ys\<rbrakk> \<Longrightarrow> P (xs!p) (ys!p)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2015	by (frule list_all2_lengthD) (auto intro: list_all2_nthD)
14302 6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	2016
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2017	lemma list_all2_map1:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2018	"list_all2 P (map f as) bs = list_all2 (\<lambda>x y. P (f x) y) as bs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2019	by (simp add: list_all2_conv_all_nth)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2020
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2021	lemma list_all2_map2:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2022	"list_all2 P as (map f bs) = list_all2 (\<lambda>x y. P x (f y)) as bs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2023	by (auto simp add: list_all2_conv_all_nth)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2024
14316 91b897b9a2dc added some [intro?] and [trans] for list_all2 lemmas kleing parents: 14302 diff changeset	2025	lemma list_all2_refl [intro?]:
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2026	"(\<And>x. P x x) \<Longrightarrow> list_all2 P xs xs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2027	by (simp add: list_all2_conv_all_nth)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2028
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2029	lemma list_all2_update_cong:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2030	"\<lbrakk> i<size xs; list_all2 P xs ys; P x y \<rbrakk> \<Longrightarrow> list_all2 P (xs[i:=x]) (ys[i:=y])"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2031	by (simp add: list_all2_conv_all_nth nth_list_update)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2032
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2033	lemma list_all2_update_cong2:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2034	"\<lbrakk>list_all2 P xs ys; P x y; i < length ys\<rbrakk> \<Longrightarrow> list_all2 P (xs[i:=x]) (ys[i:=y])"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2035	by (simp add: list_all2_lengthD list_all2_update_cong)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2036
14302 6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	2037	lemma list_all2_takeI [simp,intro?]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2038	"list_all2 P xs ys \<Longrightarrow> list_all2 P (take n xs) (take n ys)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2039	apply (induct xs arbitrary: n ys)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2040	apply simp
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2041	apply (clarsimp simp add: list_all2_Cons1)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2042	apply (case_tac n)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2043	apply auto
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2044	done
14302 6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	2045
6c24235e8d5d * empty log message * nipkow parents: 14300 diff changeset	2046	lemma list_all2_dropI [simp,intro?]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2047	"list_all2 P as bs \<Longrightarrow> list_all2 P (drop n as) (drop n bs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2048	apply (induct as arbitrary: n bs, simp)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2049	apply (clarsimp simp add: list_all2_Cons1)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2050	apply (case_tac n, simp, simp)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2051	done
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2052
14327 9cd4dea593e3 list_all2_mono should not be [trans] kleing parents: 14316 diff changeset	2053	lemma list_all2_mono [intro?]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2054	"list_all2 P xs ys \<Longrightarrow> (\<And>xs ys. P xs ys \<Longrightarrow> Q xs ys) \<Longrightarrow> list_all2 Q xs ys"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2055	apply (induct xs arbitrary: ys, simp)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2056	apply (case_tac ys, auto)
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2057	done
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2058
22551 e52f5400e331 paraphrasing equality haftmann parents: 22539 diff changeset	2059	lemma list_all2_eq:
e52f5400e331 paraphrasing equality haftmann parents: 22539 diff changeset	2060	"xs = ys \<longleftrightarrow> list_all2 (op =) xs ys"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2061	by (induct xs ys rule: list_induct2') auto
22551 e52f5400e331 paraphrasing equality haftmann parents: 22539 diff changeset	2062
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2063
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	2064	subsubsection {* @{text foldl} and @{text foldr} *}
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2065
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2066	lemma foldl_append [simp]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2067	"foldl f a (xs @ ys) = foldl f (foldl f a xs) ys"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2068	by (induct xs arbitrary: a) auto
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2069
14402 4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2070	lemma foldr_append[simp]: "foldr f (xs @ ys) a = foldr f xs (foldr f ys a)"
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2071	by (induct xs) auto
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2072
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2073	lemma foldr_map: "foldr g (map f xs) a = foldr (g o f) xs a"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2074	by(induct xs) simp_all
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2075
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2076	text{* For efficient code generation: avoid intermediate list. *}
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	2077	lemma foldl_map[code_unfold]:
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2078	"foldl g a (map f xs) = foldl (%a x. g a (f x)) a xs"
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2079	by(induct xs arbitrary:a) simp_all
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2080
31930 3107b9af1fb3 lemma foldl_apply_inv haftmann parents: 31784 diff changeset	2081	lemma foldl_apply_inv:
3107b9af1fb3 lemma foldl_apply_inv haftmann parents: 31784 diff changeset	2082	assumes "\<And>x. g (h x) = x"
3107b9af1fb3 lemma foldl_apply_inv haftmann parents: 31784 diff changeset	2083	shows "foldl f (g s) xs = g (foldl (\<lambda>s x. h (f (g s) x)) s xs)"
3107b9af1fb3 lemma foldl_apply_inv haftmann parents: 31784 diff changeset	2084	by (rule sym, induct xs arbitrary: s) (simp_all add: assms)
3107b9af1fb3 lemma foldl_apply_inv haftmann parents: 31784 diff changeset	2085
19770 be5c23ebe1eb HOL/Tools/function_package: Added support for mutual recursive definitions. krauss parents: 19623 diff changeset	2086	lemma foldl_cong [fundef_cong, recdef_cong]:
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	2087	"[\| a = b; l = k; !!a x. x : set l ==> f a x = g a x \|]
1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	2088	==> foldl f a l = foldl g b k"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2089	by (induct k arbitrary: a b l) simp_all
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	2090
19770 be5c23ebe1eb HOL/Tools/function_package: Added support for mutual recursive definitions. krauss parents: 19623 diff changeset	2091	lemma foldr_cong [fundef_cong, recdef_cong]:
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	2092	"[\| a = b; l = k; !!a x. x : set l ==> f x a = g x a \|]
1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	2093	==> foldr f l a = foldr g k b"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2094	by (induct k arbitrary: a b l) simp_all
18336 1a2e30b37ed3 Added recdef congruence rules for bounded quantifiers and commonly used krauss parents: 18049 diff changeset	2095
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2096	lemma (in semigroup_add) foldl_assoc:
25062 af5ef0d4d655 global class syntax haftmann parents: 24902 diff changeset	2097	shows "foldl op+ (x+y) zs = x + (foldl op+ y zs)"
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2098	by (induct zs arbitrary: y) (simp_all add:add_assoc)
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2099
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2100	lemma (in monoid_add) foldl_absorb0:
25062 af5ef0d4d655 global class syntax haftmann parents: 24902 diff changeset	2101	shows "x + (foldl op+ 0 zs) = foldl op+ x zs"
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2102	by (induct zs) (simp_all add:foldl_assoc)
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2103
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2104
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2105	text{* The ``First Duality Theorem'' in Bird \& Wadler: *}
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2106
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2107	lemma foldl_foldr1_lemma:
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2108	"foldl op + a xs = a + foldr op + xs (0\<Colon>'a::monoid_add)"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2109	by (induct xs arbitrary: a) (auto simp:add_assoc)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2110
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2111	corollary foldl_foldr1:
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2112	"foldl op + 0 xs = foldr op + xs (0\<Colon>'a::monoid_add)"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2113	by (simp add:foldl_foldr1_lemma)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2114
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2115
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2116	text{* The ``Third Duality Theorem'' in Bird \& Wadler: *}
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2117
14402 4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2118	lemma foldr_foldl: "foldr f xs a = foldl (%x y. f y x) a (rev xs)"
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2119	by (induct xs) auto
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2120
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2121	lemma foldl_foldr: "foldl f a xs = foldr (%x y. f y x) (rev xs) a"
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2122	by (simp add: foldr_foldl [of "%x y. f y x" "rev xs"])
4201e1916482 moved lemmas from MicroJava/Comp/AuxLemmas.thy to List.thy nipkow parents: 14395 diff changeset	2123
25062 af5ef0d4d655 global class syntax haftmann parents: 24902 diff changeset	2124	lemma (in ab_semigroup_add) foldr_conv_foldl: "foldr op + xs a = foldl op + a xs"
24471 d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2125	by (induct xs, auto simp add: foldl_assoc add_commute)
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2126
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2127	text {*
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2128	Note: @{text "n \<le> foldl (op +) n ns"} looks simpler, but is more
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2129	difficult to use because it requires an additional transitivity step.
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2130	*}
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2131
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2132	lemma start_le_sum: "(m::nat) <= n ==> m <= foldl (op +) n ns"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2133	by (induct ns arbitrary: n) auto
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2134
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2135	lemma elem_le_sum: "(n::nat) : set ns ==> n <= foldl (op +) 0 ns"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2136	by (force intro: start_le_sum simp add: in_set_conv_decomp)
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2137
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2138	lemma sum_eq_0_conv [iff]:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2139	"(foldl (op +) (m::nat) ns = 0) = (m = 0 \<and> (\<forall>n \<in> set ns. n = 0))"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2140	by (induct ns arbitrary: m) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2141
24471 d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2142	lemma foldr_invariant:
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2143	"\<lbrakk>Q x ; \<forall> x\<in> set xs. P x; \<forall> x y. P x \<and> Q y \<longrightarrow> Q (f x y) \<rbrakk> \<Longrightarrow> Q (foldr f xs x)"
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2144	by (induct xs, simp_all)
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2145
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2146	lemma foldl_invariant:
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2147	"\<lbrakk>Q x ; \<forall> x\<in> set xs. P x; \<forall> x y. P x \<and> Q y \<longrightarrow> Q (f y x) \<rbrakk> \<Longrightarrow> Q (foldl f x xs)"
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2148	by (induct xs arbitrary: x, simp_all)
d7cf53c1085f removed unused theorems ; added lifting properties for foldr and foldl chaieb parents: 24461 diff changeset	2149
31455 2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2150	text {* @{const foldl} and @{const concat} *}
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2151
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2152	lemma foldl_conv_concat:
29782 02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2153	"foldl (op @) xs xss = xs @ concat xss"
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2154	proof (induct xss arbitrary: xs)
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2155	case Nil show ?case by simp
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2156	next
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2157	interpret monoid_add "[]" "op @" proof qed simp_all
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2158	case Cons then show ?case by (simp add: foldl_absorb0)
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2159	qed
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2160
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2161	lemma concat_conv_foldl: "concat xss = foldl (op @) [] xss"
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2162	by (simp add: foldl_conv_concat)
02e76245e5af dropped global Nil/Append interpretation haftmann parents: 29626 diff changeset	2163
31455 2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2164	text {* @{const Finite_Set.fold} and @{const foldl} *}
2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2165
2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2166	lemma (in fun_left_comm_idem) fold_set:
2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2167	"fold f y (set xs) = foldl (\<lambda>y x. f x y) y xs"
2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2168	by (rule sym, induct xs arbitrary: y) (simp_all add: fold_fun_comm)
2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2169
32681 adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2170	lemma (in ab_semigroup_idem_mult) fold1_set:
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2171	assumes "xs \<noteq> []"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2172	shows "fold1 times (set xs) = foldl times (hd xs) (tl xs)"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2173	proof -
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2174	interpret fun_left_comm_idem times by (fact fun_left_comm_idem)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2175	from assms obtain y ys where xs: "xs = y # ys"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2176	by (cases xs) auto
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2177	show ?thesis
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2178	proof (cases "set ys = {}")
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2179	case True with xs show ?thesis by simp
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2180	next
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2181	case False
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2182	then have "fold1 times (insert y (set ys)) = fold times y (set ys)"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2183	by (simp only: finite_set fold1_eq_fold_idem)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2184	with xs show ?thesis by (simp add: fold_set mult_commute)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2185	qed
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2186	qed
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2187
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2188	lemma (in lattice) Inf_fin_set_fold [code_unfold]:
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2189	"Inf_fin (set (x # xs)) = foldl inf x xs"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2190	proof -
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2191	interpret ab_semigroup_idem_mult "inf :: 'a \<Rightarrow> 'a \<Rightarrow> 'a"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2192	by (fact ab_semigroup_idem_mult_inf)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2193	show ?thesis
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2194	by (simp add: Inf_fin_def fold1_set del: set.simps)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2195	qed
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2196
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2197	lemma (in lattice) Sup_fin_set_fold [code_unfold]:
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2198	"Sup_fin (set (x # xs)) = foldl sup x xs"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2199	proof -
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2200	interpret ab_semigroup_idem_mult "sup :: 'a \<Rightarrow> 'a \<Rightarrow> 'a"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2201	by (fact ab_semigroup_idem_mult_sup)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2202	show ?thesis
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2203	by (simp add: Sup_fin_def fold1_set del: set.simps)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2204	qed
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2205
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2206	lemma (in linorder) Min_fin_set_fold [code_unfold]:
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2207	"Min (set (x # xs)) = foldl min x xs"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2208	proof -
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2209	interpret ab_semigroup_idem_mult "min :: 'a \<Rightarrow> 'a \<Rightarrow> 'a"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2210	by (fact ab_semigroup_idem_mult_min)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2211	show ?thesis
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2212	by (simp add: Min_def fold1_set del: set.simps)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2213	qed
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2214
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2215	lemma (in linorder) Max_fin_set_fold [code_unfold]:
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2216	"Max (set (x # xs)) = foldl max x xs"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2217	proof -
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2218	interpret ab_semigroup_idem_mult "max :: 'a \<Rightarrow> 'a \<Rightarrow> 'a"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2219	by (fact ab_semigroup_idem_mult_max)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2220	show ?thesis
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2221	by (simp add: Max_def fold1_set del: set.simps)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2222	qed
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2223
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2224	lemma (in complete_lattice) Inf_set_fold [code_unfold]:
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2225	"Inf (set xs) = foldl inf top xs"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2226	by (cases xs)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2227	(simp_all add: Inf_fin_Inf [symmetric] Inf_fin_set_fold
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2228	inf_commute del: set.simps, simp add: top_def)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2229
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2230	lemma (in complete_lattice) Sup_set_fold [code_unfold]:
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2231	"Sup (set xs) = foldl sup bot xs"
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2232	by (cases xs)
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2233	(simp_all add: Sup_fin_Sup [symmetric] Sup_fin_set_fold
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	2234	sup_commute del: set.simps, simp add: bot_def)
31455 2754a0dadccc lemma about List.foldl and Finite_Set.fold haftmann parents: 31363 diff changeset	2235
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2236
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2237	subsubsection {* List summation: @{const listsum} and @{text"\<Sum>"}*}
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2238
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2239	lemma listsum_append [simp]: "listsum (xs @ ys) = listsum xs + listsum ys"
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2240	by (induct xs) (simp_all add:add_assoc)
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2241
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2242	lemma listsum_rev [simp]:
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2243	fixes xs :: "'a\<Colon>comm_monoid_add list"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2244	shows "listsum (rev xs) = listsum xs"
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2245	by (induct xs) (simp_all add:add_ac)
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2246
31022 a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2247	lemma listsum_map_remove1:
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2248	fixes f :: "'a \<Rightarrow> ('b::comm_monoid_add)"
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2249	shows "x : set xs \<Longrightarrow> listsum(map f xs) = f x + listsum(map f (remove1 x xs))"
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2250	by (induct xs)(auto simp add:add_ac)
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2251
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2252	lemma list_size_conv_listsum:
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2253	"list_size f xs = listsum (map f xs) + size xs"
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2254	by(induct xs) auto
a438b4516dd3 added listsum lemmas nipkow parents: 30971 diff changeset	2255
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2256	lemma listsum_foldr: "listsum xs = foldr (op +) xs 0"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2257	by (induct xs) auto
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2258
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2259	lemma length_concat: "length (concat xss) = listsum (map length xss)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2260	by (induct xss) simp_all
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2261
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2262	text{* For efficient code generation ---
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2263	@{const listsum} is not tail recursive but @{const foldl} is. *}
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	2264	lemma listsum[code_unfold]: "listsum xs = foldl (op +) 0 xs"
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2265	by(simp add:listsum_foldr foldl_foldr1)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2266
31077 28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	2267	lemma distinct_listsum_conv_Setsum:
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	2268	"distinct xs \<Longrightarrow> listsum xs = Setsum(set xs)"
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	2269	by (induct xs) simp_all
28dd6fd3d184 more lemmas nipkow parents: 31055 diff changeset	2270
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	2271
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2272	text{* Some syntactic sugar for summing a function over a list: *}
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2273
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2274	syntax
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2275	"_listsum" :: "pttrn => 'a list => 'b => 'b" ("(3SUM _<-_. _)" [0, 51, 10] 10)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2276	syntax (xsymbols)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2277	"_listsum" :: "pttrn => 'a list => 'b => 'b" ("(3\<Sum>_\<leftarrow>_. _)" [0, 51, 10] 10)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2278	syntax (HTML output)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2279	"_listsum" :: "pttrn => 'a list => 'b => 'b" ("(3\<Sum>_\<leftarrow>_. _)" [0, 51, 10] 10)
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2280
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2281	translations -- {* Beware of argument permutation! *}
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2282	"SUM x<-xs. b" == "CONST listsum (map (%x. b) xs)"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2283	"\<Sum>x\<leftarrow>xs. b" == "CONST listsum (map (%x. b) xs)"
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2284
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2285	lemma listsum_triv: "(\<Sum>x\<leftarrow>xs. r) = of_nat (length xs) * r"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2286	by (induct xs) (simp_all add: left_distrib)
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2287
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2288	lemma listsum_0 [simp]: "(\<Sum>x\<leftarrow>xs. 0) = 0"
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2289	by (induct xs) (simp_all add: left_distrib)
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2290
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2291	text{* For non-Abelian groups @{text xs} needs to be reversed on one side: *}
423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2292	lemma uminus_listsum_map:
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2293	fixes f :: "'a \<Rightarrow> 'b\<Colon>ab_group_add"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2294	shows "- listsum (map f xs) = (listsum (map (uminus o f) xs))"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	2295	by (induct xs) simp_all
23096 423ad2fe9f76 * empty log message * nipkow parents: 23060 diff changeset	2296
31258 43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2297	lemma listsum_addf:
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2298	fixes f g :: "'a \<Rightarrow> 'b::comm_monoid_add"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2299	shows "(\<Sum>x\<leftarrow>xs. f x + g x) = listsum (map f xs) + listsum (map g xs)"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2300	by (induct xs) (simp_all add: algebra_simps)
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2301
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2302	lemma listsum_subtractf:
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2303	fixes f g :: "'a \<Rightarrow> 'b::ab_group_add"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2304	shows "(\<Sum>x\<leftarrow>xs. f x - g x) = listsum (map f xs) - listsum (map g xs)"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2305	by (induct xs) simp_all
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2306
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2307	lemma listsum_const_mult:
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2308	fixes f :: "'a \<Rightarrow> 'b::semiring_0"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2309	shows "(\<Sum>x\<leftarrow>xs. c * f x) = c * (\<Sum>x\<leftarrow>xs. f x)"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2310	by (induct xs, simp_all add: algebra_simps)
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2311
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2312	lemma listsum_mult_const:
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2313	fixes f :: "'a \<Rightarrow> 'b::semiring_0"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2314	shows "(\<Sum>x\<leftarrow>xs. f x * c) = (\<Sum>x\<leftarrow>xs. f x) * c"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2315	by (induct xs, simp_all add: algebra_simps)
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2316
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2317	lemma listsum_abs:
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2318	fixes xs :: "'a::pordered_ab_group_add_abs list"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2319	shows "\<bar>listsum xs\<bar> \<le> listsum (map abs xs)"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2320	by (induct xs, simp, simp add: order_trans [OF abs_triangle_ineq])
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2321
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2322	lemma listsum_mono:
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2323	fixes f g :: "'a \<Rightarrow> 'b::{comm_monoid_add, pordered_ab_semigroup_add}"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2324	shows "(\<And>x. x \<in> set xs \<Longrightarrow> f x \<le> g x) \<Longrightarrow> (\<Sum>x\<leftarrow>xs. f x) \<le> (\<Sum>x\<leftarrow>xs. g x)"
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2325	by (induct xs, simp, simp add: add_mono)
43a418a41317 listsum lemmas huffman parents: 31201 diff changeset	2326
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2327
24645 1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	2328	subsubsection {* @{text upt} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2329
17090 603f23d71ada small mods to code lemmas nipkow parents: 17086 diff changeset	2330	lemma upt_rec[code]: "[i..<j] = (if i<j then i#[Suc i..<j] else [])"
603f23d71ada small mods to code lemmas nipkow parents: 17086 diff changeset	2331	-- {* simp does not terminate! *}
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2332	by (induct j) auto
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2333
32005 c369417be055 made upt/upto executable on nat/int by simp nipkow parents: 31998 diff changeset	2334	lemmas upt_rec_number_of[simp] = upt_rec[of "number_of m" "number_of n", standard]
c369417be055 made upt/upto executable on nat/int by simp nipkow parents: 31998 diff changeset	2335
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	2336	lemma upt_conv_Nil [simp]: "j <= i ==> [i..<j] = []"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2337	by (subst upt_rec) simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2338
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	2339	lemma upt_eq_Nil_conv[simp]: "([i..<j] = []) = (j = 0 \<or> j <= i)"
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2340	by(induct j)simp_all
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2341
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2342	lemma upt_eq_Cons_conv:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2343	"([i..<j] = x#xs) = (i < j & i = x & [i+1..<j] = xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2344	apply(induct j arbitrary: x xs)
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2345	apply simp
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2346	apply(clarsimp simp add: append_eq_Cons_conv)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2347	apply arith
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2348	done
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2349
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	2350	lemma upt_Suc_append: "i <= j ==> [i..<(Suc j)] = [i..<j]@[j]"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2351	-- {* Only needed if @{text upt_Suc} is deleted from the simpset. *}
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2352	by simp
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2353
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	2354	lemma upt_conv_Cons: "i < j ==> [i..<j] = i # [Suc i..<j]"
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	2355	by (simp add: upt_rec)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2356
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	2357	lemma upt_add_eq_append: "i<=j ==> [i..<j+k] = [i..<j]@[j..<j+k]"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2358	-- {* LOOPS as a simprule, since @{text "j <= j"}. *}
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2359	by (induct k) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2360
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	2361	lemma length_upt [simp]: "length [i..<j] = j - i"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2362	by (induct j) (auto simp add: Suc_diff_le)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2363
15425 6356d2523f73 [ .. (] -> [ ..< ] nipkow parents: 15392 diff changeset	2364	lemma nth_upt [simp]: "i + k < j ==> [i..<j] ! k = i + k"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2365	apply (induct j)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2366	apply (auto simp add: less_Suc_eq nth_append split: nat_diff_split)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2367	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2368
17906 719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2369
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2370	lemma hd_upt[simp]: "i < j \<Longrightarrow> hd[i..<j] = i"
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2371	by(simp add:upt_conv_Cons)
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2372
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2373	lemma last_upt[simp]: "i < j \<Longrightarrow> last[i..<j] = j - 1"
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2374	apply(cases j)
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2375	apply simp
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2376	by(simp add:upt_Suc_append)
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2377
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2378	lemma take_upt [simp]: "i+m <= n ==> take m [i..<n] = [i..<i+m]"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2379	apply (induct m arbitrary: i, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2380	apply (subst upt_rec)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2381	apply (rule sym)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2382	apply (subst upt_rec)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2383	apply (simp del: upt.simps)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2384	done
3507 157be29ad5ba Improved length = size translation. nipkow parents: 3465 diff changeset	2385
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2386	lemma drop_upt[simp]: "drop m [i..<j] = [i+m..<j]"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2387	apply(induct j)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2388	apply auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2389	done
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2390
24645 1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	2391	lemma map_Suc_upt: "map Suc [m..<n] = [Suc m..<Suc n]"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2392	by (induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2393
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2394	lemma nth_map_upt: "i < n-m ==> (map f [m..<n]) ! i = f(m+i)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2395	apply (induct n m arbitrary: i rule: diff_induct)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2396	prefer 3 apply (subst map_Suc_upt[symmetric])
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2397	apply (auto simp add: less_diff_conv nth_upt)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2398	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2399
13883 0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	2400	lemma nth_take_lemma:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2401	"k <= length xs ==> k <= length ys ==>
13883 0451e0fb3f22 Re-structured some proofs in order to get rid of rule_format attribute. berghofe parents: 13863 diff changeset	2402	(!!i. i < k --> xs!i = ys!i) ==> take k xs = take k ys"
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2403	apply (atomize, induct k arbitrary: xs ys)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	2404	apply (simp_all add: less_Suc_eq_0_disj all_conj_distrib, clarify)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2405	txt {* Both lists must be non-empty *}
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	2406	apply (case_tac xs, simp)
144f45277d5a misc tidying paulson parents: 14187 diff changeset	2407	apply (case_tac ys, clarify)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2408	apply (simp (no_asm_use))
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2409	apply clarify
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2410	txt {* prenexing's needed, not miniscoping *}
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2411	apply (simp (no_asm_use) add: all_simps [symmetric] del: all_simps)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2412	apply blast
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2413	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2414
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2415	lemma nth_equalityI:
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2416	"[\| length xs = length ys; ALL i < length xs. xs!i = ys!i \|] ==> xs = ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2417	apply (frule nth_take_lemma [OF le_refl eq_imp_le])
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2418	apply (simp_all add: take_all)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2419	done
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2420
24796 529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2421	lemma map_nth:
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2422	"map (\<lambda>i. xs ! i) [0..<length xs] = xs"
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2423	by (rule nth_equalityI, auto)
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2424
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2425	(* needs nth_equalityI *)
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2426	lemma list_all2_antisym:
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2427	"\<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>
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2428	\<Longrightarrow> xs = ys"
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2429	apply (simp add: list_all2_conv_all_nth)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	2430	apply (rule nth_equalityI, blast, simp)
13863 ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2431	done
ec901a432ea1 more about list_all2 kleing parents: 13737 diff changeset	2432
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2433	lemma take_equalityI: "(\<forall>i. take i xs = take i ys) ==> xs = ys"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2434	-- {* The famous take-lemma. *}
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2435	apply (drule_tac x = "max (length xs) (length ys)" in spec)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2436	apply (simp add: le_max_iff_disj take_all)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2437	done
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2438
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2439
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2440	lemma take_Cons':
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2441	"take n (x # xs) = (if n = 0 then [] else x # take (n - 1) xs)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2442	by (cases n) simp_all
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2443
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2444	lemma drop_Cons':
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2445	"drop n (x # xs) = (if n = 0 then x # xs else drop (n - 1) xs)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2446	by (cases n) simp_all
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2447
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2448	lemma nth_Cons': "(x # xs)!n = (if n = 0 then x else xs!(n - 1))"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2449	by (cases n) simp_all
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2450
18622 4524643feecc theorems need names paulson parents: 18490 diff changeset	2451	lemmas take_Cons_number_of = take_Cons'[of "number_of v",standard]
4524643feecc theorems need names paulson parents: 18490 diff changeset	2452	lemmas drop_Cons_number_of = drop_Cons'[of "number_of v",standard]
4524643feecc theorems need names paulson parents: 18490 diff changeset	2453	lemmas nth_Cons_number_of = nth_Cons'[of _ _ "number_of v",standard]
4524643feecc theorems need names paulson parents: 18490 diff changeset	2454
4524643feecc theorems need names paulson parents: 18490 diff changeset	2455	declare take_Cons_number_of [simp]
4524643feecc theorems need names paulson parents: 18490 diff changeset	2456	drop_Cons_number_of [simp]
4524643feecc theorems need names paulson parents: 18490 diff changeset	2457	nth_Cons_number_of [simp]
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2458
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2459
32415 1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2460	subsubsection {* @{text upto}: interval-list on @{typ int} *}
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2461
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2462	(* FIXME make upto tail recursive? *)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2463
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2464	function upto :: "int \<Rightarrow> int \<Rightarrow> int list" ("(1[_../_])") where
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2465	"upto i j = (if i \<le> j then i # [i+1..j] else [])"
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2466	by auto
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2467	termination
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2468	by(relation "measure(%(i::int,j). nat(j - i + 1))") auto
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2469
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2470	declare upto.simps[code, simp del]
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2471
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2472	lemmas upto_rec_number_of[simp] =
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2473	upto.simps[of "number_of m" "number_of n", standard]
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2474
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2475	lemma upto_empty[simp]: "j < i \<Longrightarrow> [i..j] = []"
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2476	by(simp add: upto.simps)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2477
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2478	lemma set_upto[simp]: "set[i..j] = {i..j}"
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2479	apply(induct i j rule:upto.induct)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2480	apply(simp add: upto.simps simp_from_to)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2481	done
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2482
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2483
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	2484	subsubsection {* @{text "distinct"} and @{text remdups} *}
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2485
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2486	lemma distinct_append [simp]:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2487	"distinct (xs @ ys) = (distinct xs \<and> distinct ys \<and> set xs \<inter> set ys = {})"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2488	by (induct xs) auto
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2489
15305 0bd9eedaa301 added lemmas nipkow parents: 15304 diff changeset	2490	lemma distinct_rev[simp]: "distinct(rev xs) = distinct xs"
0bd9eedaa301 added lemmas nipkow parents: 15304 diff changeset	2491	by(induct xs) auto
0bd9eedaa301 added lemmas nipkow parents: 15304 diff changeset	2492
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2493	lemma set_remdups [simp]: "set (remdups xs) = set xs"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2494	by (induct xs) (auto simp add: insert_absorb)
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2495
1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2496	lemma distinct_remdups [iff]: "distinct (remdups xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2497	by (induct xs) auto
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2498
25287 094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2499	lemma distinct_remdups_id: "distinct xs ==> remdups xs = xs"
094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2500	by (induct xs, auto)
094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2501
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	2502	lemma remdups_id_iff_distinct [simp]: "remdups xs = xs \<longleftrightarrow> distinct xs"
a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	2503	by (metis distinct_remdups distinct_remdups_id)
25287 094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2504
24566 2bfa0215904c added lemma nipkow parents: 24526 diff changeset	2505	lemma finite_distinct_list: "finite A \<Longrightarrow> EX xs. set xs = A & distinct xs"
24632 779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	2506	by (metis distinct_remdups finite_list set_remdups)
24566 2bfa0215904c added lemma nipkow parents: 24526 diff changeset	2507
15072 4861bf6af0b4 new material courtesy of Norbert Voelker paulson parents: 15064 diff changeset	2508	lemma remdups_eq_nil_iff [simp]: "(remdups x = []) = (x = [])"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2509	by (induct x, auto)
15072 4861bf6af0b4 new material courtesy of Norbert Voelker paulson parents: 15064 diff changeset	2510
4861bf6af0b4 new material courtesy of Norbert Voelker paulson parents: 15064 diff changeset	2511	lemma remdups_eq_nil_right_iff [simp]: "([] = remdups x) = (x = [])"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2512	by (induct x, auto)
15072 4861bf6af0b4 new material courtesy of Norbert Voelker paulson parents: 15064 diff changeset	2513
15245 5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2514	lemma length_remdups_leq[iff]: "length(remdups xs) <= length xs"
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2515	by (induct xs) auto
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2516
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2517	lemma length_remdups_eq[iff]:
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2518	"(length (remdups xs) = length xs) = (remdups xs = xs)"
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2519	apply(induct xs)
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2520	apply auto
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2521	apply(subgoal_tac "length (remdups xs) <= length xs")
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2522	apply arith
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2523	apply(rule length_remdups_leq)
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2524	done
5a21d9a8f14b Added a few lemmas nipkow parents: 15236 diff changeset	2525
18490 434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2526
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2527	lemma distinct_map:
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2528	"distinct(map f xs) = (distinct xs & inj_on f (set xs))"
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2529	by (induct xs) auto
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2530
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2531
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2532	lemma distinct_filter [simp]: "distinct xs ==> distinct (filter P xs)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2533	by (induct xs) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2534
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2535	lemma distinct_upt[simp]: "distinct[i..<j]"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2536	by (induct j) auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2537
32415 1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2538	lemma distinct_upto[simp]: "distinct[i..j]"
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2539	apply(induct i j rule:upto.induct)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2540	apply(subst upto.simps)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2541	apply(simp)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2542	done
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	2543
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2544	lemma distinct_take[simp]: "distinct xs \<Longrightarrow> distinct (take i xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2545	apply(induct xs arbitrary: i)
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2546	apply simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2547	apply (case_tac i)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2548	apply simp_all
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2549	apply(blast dest:in_set_takeD)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2550	done
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2551
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2552	lemma distinct_drop[simp]: "distinct xs \<Longrightarrow> distinct (drop i xs)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2553	apply(induct xs arbitrary: i)
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2554	apply simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2555	apply (case_tac i)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2556	apply simp_all
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2557	done
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2558
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2559	lemma distinct_list_update:
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2560	assumes d: "distinct xs" and a: "a \<notin> set xs - {xs!i}"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2561	shows "distinct (xs[i:=a])"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2562	proof (cases "i < length xs")
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2563	case True
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2564	with a have "a \<notin> set (take i xs @ xs ! i # drop (Suc i) xs) - {xs!i}"
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2565	apply (drule_tac id_take_nth_drop) by simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2566	with d True show ?thesis
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2567	apply (simp add: upd_conv_take_nth_drop)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2568	apply (drule subst [OF id_take_nth_drop]) apply assumption
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2569	apply simp apply (cases "a = xs!i") apply simp by blast
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2570	next
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2571	case False with d show ?thesis by auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2572	qed
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2573
31363 7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2574	lemma distinct_concat:
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2575	assumes "distinct xs"
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2576	and "\<And> ys. ys \<in> set xs \<Longrightarrow> distinct ys"
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2577	and "\<And> ys zs. \<lbrakk> ys \<in> set xs ; zs \<in> set xs ; ys \<noteq> zs \<rbrakk> \<Longrightarrow> set ys \<inter> set zs = {}"
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2578	shows "distinct (concat xs)"
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2579	using assms by (induct xs) auto
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2580
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2581	text {* It is best to avoid this indexed version of distinct, but
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2582	sometimes it is useful. *}
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2583
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2584	lemma distinct_conv_nth:
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	2585	"distinct xs = (\<forall>i < size xs. \<forall>j < size xs. i \<noteq> j --> xs!i \<noteq> xs!j)"
15251 bb6f072c8d10 converted some induct_tac to induct paulson parents: 15246 diff changeset	2586	apply (induct xs, simp, simp)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	2587	apply (rule iffI, clarsimp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2588	apply (case_tac i)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	2589	apply (case_tac j, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2590	apply (simp add: set_conv_nth)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2591	apply (case_tac j)
24648 1e8053a6d725 metis too slow paulson parents: 24645 diff changeset	2592	apply (clarsimp simp add: set_conv_nth, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2593	apply (rule conjI)
24648 1e8053a6d725 metis too slow paulson parents: 24645 diff changeset	2594	(*TOO SLOW
24632 779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	2595	apply (metis Zero_neq_Suc gr0_conv_Suc in_set_conv_nth lessI less_trans_Suc nth_Cons' nth_Cons_Suc)
24648 1e8053a6d725 metis too slow paulson parents: 24645 diff changeset	2596	*)
1e8053a6d725 metis too slow paulson parents: 24645 diff changeset	2597	apply (clarsimp simp add: set_conv_nth)
1e8053a6d725 metis too slow paulson parents: 24645 diff changeset	2598	apply (erule_tac x = 0 in allE, simp)
1e8053a6d725 metis too slow paulson parents: 24645 diff changeset	2599	apply (erule_tac x = "Suc i" in allE, simp, clarsimp)
25130 d91391a8705b avoid very slow metis invocation; wenzelm parents: 25112 diff changeset	2600	(*TOO SLOW
24632 779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	2601	apply (metis Suc_Suc_eq lessI less_trans_Suc nth_Cons_Suc)
25130 d91391a8705b avoid very slow metis invocation; wenzelm parents: 25112 diff changeset	2602	*)
d91391a8705b avoid very slow metis invocation; wenzelm parents: 25112 diff changeset	2603	apply (erule_tac x = "Suc i" in allE, simp)
d91391a8705b avoid very slow metis invocation; wenzelm parents: 25112 diff changeset	2604	apply (erule_tac x = "Suc j" in allE, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2605	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2606
18490 434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2607	lemma nth_eq_iff_index_eq:
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2608	"\<lbrakk> distinct xs; i < length xs; j < length xs \<rbrakk> \<Longrightarrow> (xs!i = xs!j) = (i = j)"
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2609	by(auto simp: distinct_conv_nth)
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2610
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2611	lemma distinct_card: "distinct xs ==> card (set xs) = size xs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	2612	by (induct xs) auto
14388 04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2613
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2614	lemma card_distinct: "card (set xs) = size xs ==> distinct xs"
14388 04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2615	proof (induct xs)
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2616	case Nil thus ?case by simp
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2617	next
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2618	case (Cons x xs)
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2619	show ?case
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2620	proof (cases "x \<in> set xs")
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2621	case False with Cons show ?thesis by simp
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2622	next
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2623	case True with Cons.prems
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2624	have "card (set xs) = Suc (length xs)"
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2625	by (simp add: card_insert_if split: split_if_asm)
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2626	moreover have "card (set xs) \<le> length xs" by (rule card_length)
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2627	ultimately have False by simp
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2628	thus ?thesis ..
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2629	qed
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2630	qed
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	2631
25287 094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2632	lemma not_distinct_decomp: "~ distinct ws ==> EX xs ys zs y. ws = xs@[y]@ys@[y]@zs"
094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2633	apply (induct n == "length ws" arbitrary:ws) apply simp
094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2634	apply(case_tac ws) apply simp
094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2635	apply (simp split:split_if_asm)
094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2636	apply (metis Cons_eq_appendI eq_Nil_appendI split_list)
094dab519ff5 added lemmas nipkow parents: 25277 diff changeset	2637	done
18490 434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2638
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2639	lemma length_remdups_concat:
434e34392c40 new lemmas nipkow parents: 18451 diff changeset	2640	"length(remdups(concat xss)) = card(\<Union>xs \<in> set xss. set xs)"
24308 700e745994c1 removed set_concat_map and improved set_concat nipkow parents: 24286 diff changeset	2641	by(simp add: set_concat distinct_card[symmetric])
17906 719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2642
719364f5179b added 2 lemmas nipkow parents: 17877 diff changeset	2643
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	2644	subsubsection {* @{text remove1} *}
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2645
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2646	lemma remove1_append:
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2647	"remove1 x (xs @ ys) =
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2648	(if x \<in> set xs then remove1 x xs @ ys else xs @ remove1 x ys)"
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2649	by (induct xs) auto
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2650
23479 10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2651	lemma in_set_remove1[simp]:
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2652	"a \<noteq> b \<Longrightarrow> a : set(remove1 b xs) = (a : set xs)"
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2653	apply (induct xs)
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2654	apply auto
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2655	done
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2656
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2657	lemma set_remove1_subset: "set(remove1 x xs) <= set xs"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2658	apply(induct xs)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2659	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2660	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2661	apply blast
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2662	done
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2663
17724 e969fc0a4925 simprules need names paulson parents: 17629 diff changeset	2664	lemma set_remove1_eq [simp]: "distinct xs ==> set(remove1 x xs) = set xs - {x}"
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2665	apply(induct xs)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2666	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2667	apply simp
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2668	apply blast
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2669	done
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2670
23479 10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2671	lemma length_remove1:
30128 365ee7319b86 revert some Suc 0 lemmas back to their original forms; added some simp rules for (1::nat) huffman parents: 30079 diff changeset	2672	"length(remove1 x xs) = (if x : set xs then length xs - 1 else length xs)"
23479 10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2673	apply (induct xs)
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2674	apply (auto dest!:length_pos_if_in_set)
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2675	done
10adbdcdc65b new lemmas nipkow parents: 23388 diff changeset	2676
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2677	lemma remove1_filter_not[simp]:
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2678	"\<not> P x \<Longrightarrow> remove1 x (filter P xs) = filter P xs"
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2679	by(induct xs) auto
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2680
15110 78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2681	lemma notin_set_remove1[simp]: "x ~: set xs ==> x ~: set(remove1 y xs)"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2682	apply(insert set_remove1_subset)
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2683	apply fast
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2684	done
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2685
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2686	lemma distinct_remove1[simp]: "distinct xs ==> distinct(remove1 x xs)"
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2687	by (induct xs) simp_all
78b5636eabc7 Added a number of new thms and the new function remove1 nipkow parents: 15072 diff changeset	2688
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2689
27693 73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2690	subsubsection {* @{text removeAll} *}
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2691
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2692	lemma removeAll_append[simp]:
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2693	"removeAll x (xs @ ys) = removeAll x xs @ removeAll x ys"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2694	by (induct xs) auto
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2695
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2696	lemma set_removeAll[simp]: "set(removeAll x xs) = set xs - {x}"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2697	by (induct xs) auto
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2698
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2699	lemma removeAll_id[simp]: "x \<notin> set xs \<Longrightarrow> removeAll x xs = xs"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2700	by (induct xs) auto
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2701
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2702	(* Needs count:: 'a \<Rightarrow> a' list \<Rightarrow> nat
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2703	lemma length_removeAll:
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2704	"length(removeAll x xs) = length xs - count x xs"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2705	*)
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2706
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2707	lemma removeAll_filter_not[simp]:
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2708	"\<not> P x \<Longrightarrow> removeAll x (filter P xs) = filter P xs"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2709	by(induct xs) auto
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2710
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2711
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2712	lemma distinct_remove1_removeAll:
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2713	"distinct xs ==> remove1 x xs = removeAll x xs"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2714	by (induct xs) simp_all
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2715
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2716	lemma map_removeAll_inj_on: "inj_on f (insert x (set xs)) \<Longrightarrow>
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2717	map f (removeAll x xs) = removeAll (f x) (map f xs)"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2718	by (induct xs) (simp_all add:inj_on_def)
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2719
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2720	lemma map_removeAll_inj: "inj f \<Longrightarrow>
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2721	map f (removeAll x xs) = removeAll (f x) (map f xs)"
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2722	by(metis map_removeAll_inj_on subset_inj_on subset_UNIV)
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2723
73253a4e3ee2 added removeAll nipkow parents: 27381 diff changeset	2724
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	2725	subsubsection {* @{text replicate} *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2726
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2727	lemma length_replicate [simp]: "length (replicate n x) = n"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2728	by (induct n) auto
13124 6e1decd8a7a9 new thm distinct_conv_nth nipkow parents: 13122 diff changeset	2729
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2730	lemma map_replicate [simp]: "map f (replicate n x) = replicate n (f x)"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2731	by (induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2732
31363 7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2733	lemma map_replicate_const:
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2734	"map (\<lambda> x. k) lst = replicate (length lst) k"
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2735	by (induct lst) auto
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2736
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2737	lemma replicate_app_Cons_same:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2738	"(replicate n x) @ (x # xs) = x # replicate n x @ xs"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2739	by (induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2740
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2741	lemma rev_replicate [simp]: "rev (replicate n x) = replicate n x"
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	2742	apply (induct n, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2743	apply (simp add: replicate_app_Cons_same)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2744	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2745
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2746	lemma replicate_add: "replicate (n + m) x = replicate n x @ replicate m x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2747	by (induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2748
16397 c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2749	text{* Courtesy of Matthias Daum: *}
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2750	lemma append_replicate_commute:
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2751	"replicate n x @ replicate k x = replicate k x @ replicate n x"
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2752	apply (simp add: replicate_add [THEN sym])
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2753	apply (simp add: add_commute)
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2754	done
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2755
31080 21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	2756	text{* Courtesy of Andreas Lochbihler: *}
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	2757	lemma filter_replicate:
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	2758	"filter P (replicate n x) = (if P x then replicate n x else [])"
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	2759	by(induct n) auto
21ffc770ebc0 lemmas by Andreas Lochbihler nipkow parents: 31077 diff changeset	2760
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2761	lemma hd_replicate [simp]: "n \<noteq> 0 ==> hd (replicate n x) = x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2762	by (induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2763
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2764	lemma tl_replicate [simp]: "n \<noteq> 0 ==> tl (replicate n x) = replicate (n - 1) x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2765	by (induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2766
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2767	lemma last_replicate [simp]: "n \<noteq> 0 ==> last (replicate n x) = x"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2768	by (atomize (full), induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2769
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2770	lemma nth_replicate[simp]: "i < n ==> (replicate n x)!i = x"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2771	apply (induct n arbitrary: i, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2772	apply (simp add: nth_Cons split: nat.split)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2773	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2774
16397 c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2775	text{* Courtesy of Matthias Daum (2 lemmas): *}
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2776	lemma take_replicate[simp]: "take i (replicate k x) = replicate (min i k) x"
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2777	apply (case_tac "k \<le> i")
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2778	apply (simp add: min_def)
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2779	apply (drule not_leE)
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2780	apply (simp add: min_def)
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2781	apply (subgoal_tac "replicate k x = replicate i x @ replicate (k - i) x")
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2782	apply simp
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2783	apply (simp add: replicate_add [symmetric])
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2784	done
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2785
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2786	lemma drop_replicate[simp]: "drop i (replicate k x) = replicate (k-i) x"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2787	apply (induct k arbitrary: i)
16397 c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2788	apply simp
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2789	apply clarsimp
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2790	apply (case_tac i)
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2791	apply simp
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2792	apply clarsimp
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2793	done
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2794
c047008f88d4 added lemmas nipkow parents: 15870 diff changeset	2795
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2796	lemma set_replicate_Suc: "set (replicate (Suc n) x) = {x}"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2797	by (induct n) auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2798
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2799	lemma set_replicate [simp]: "n \<noteq> 0 ==> set (replicate n x) = {x}"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2800	by (fast dest!: not0_implies_Suc intro!: set_replicate_Suc)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2801
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2802	lemma set_replicate_conv_if: "set (replicate n x) = (if n = 0 then {} else {x})"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2803	by auto
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2804
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2805	lemma in_set_replicateD: "x : set (replicate n y) ==> x = y"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2806	by (simp add: set_replicate_conv_if split: split_if_asm)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2807
24796 529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2808	lemma replicate_append_same:
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2809	"replicate i x @ [x] = x # replicate i x"
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2810	by (induct i) simp_all
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2811
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2812	lemma map_replicate_trivial:
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2813	"map (\<lambda>i. x) [0..<i] = replicate i x"
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2814	by (induct i) (simp_all add: replicate_append_same)
529e458f84d2 added some lemmas haftmann parents: 24748 diff changeset	2815
31363 7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2816	lemma concat_replicate_trivial[simp]:
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2817	"concat (replicate i []) = []"
7493b571b37d Added theorems about distinct & concat, map & replicate and concat & replicate hoelzl parents: 31264 diff changeset	2818	by (induct i) (auto simp add: map_replicate_const)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2819
28642 658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2820	lemma replicate_empty[simp]: "(replicate n x = []) \<longleftrightarrow> n=0"
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2821	by (induct n) auto
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2822
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2823	lemma empty_replicate[simp]: "([] = replicate n x) \<longleftrightarrow> n=0"
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2824	by (induct n) auto
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2825
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2826	lemma replicate_eq_replicate[simp]:
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2827	"(replicate m x = replicate n y) \<longleftrightarrow> (m=n & (m\<noteq>0 \<longrightarrow> x=y))"
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2828	apply(induct m arbitrary: n)
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2829	apply simp
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2830	apply(induct_tac n)
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2831	apply auto
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2832	done
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2833
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	2834
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	2835	subsubsection{@{text rotate1} and @{text rotate}}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2836
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2837	lemma rotate_simps[simp]: "rotate1 [] = [] \<and> rotate1 (x#xs) = xs @ [x]"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2838	by(simp add:rotate1_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2839
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2840	lemma rotate0[simp]: "rotate 0 = id"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2841	by(simp add:rotate_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2842
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2843	lemma rotate_Suc[simp]: "rotate (Suc n) xs = rotate1(rotate n xs)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2844	by(simp add:rotate_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2845
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2846	lemma rotate_add:
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2847	"rotate (m+n) = rotate m o rotate n"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2848	by(simp add:rotate_def funpow_add)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2849
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2850	lemma rotate_rotate: "rotate m (rotate n xs) = rotate (m+n) xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2851	by(simp add:rotate_add)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2852
18049 156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2853	lemma rotate1_rotate_swap: "rotate1 (rotate n xs) = rotate n (rotate1 xs)"
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2854	by(simp add:rotate_def funpow_swap1)
156bba334c12 A few new lemmas nipkow parents: 17956 diff changeset	2855
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2856	lemma rotate1_length01[simp]: "length xs <= 1 \<Longrightarrow> rotate1 xs = xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2857	by(cases xs) simp_all
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2858
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2859	lemma rotate_length01[simp]: "length xs <= 1 \<Longrightarrow> rotate n xs = xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2860	apply(induct n)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2861	apply simp
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2862	apply (simp add:rotate_def)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2863	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2864
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2865	lemma rotate1_hd_tl: "xs \<noteq> [] \<Longrightarrow> rotate1 xs = tl xs @ [hd xs]"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2866	by(simp add:rotate1_def split:list.split)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2867
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2868	lemma rotate_drop_take:
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2869	"rotate n xs = drop (n mod length xs) xs @ take (n mod length xs) xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2870	apply(induct n)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2871	apply simp
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2872	apply(simp add:rotate_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2873	apply(cases "xs = []")
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2874	apply (simp)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2875	apply(case_tac "n mod length xs = 0")
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2876	apply(simp add:mod_Suc)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2877	apply(simp add: rotate1_hd_tl drop_Suc take_Suc)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2878	apply(simp add:mod_Suc rotate1_hd_tl drop_Suc[symmetric] drop_tl[symmetric]
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2879	take_hd_drop linorder_not_le)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2880	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2881
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2882	lemma rotate_conv_mod: "rotate n xs = rotate (n mod length xs) xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2883	by(simp add:rotate_drop_take)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2884
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2885	lemma rotate_id[simp]: "n mod length xs = 0 \<Longrightarrow> rotate n xs = xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2886	by(simp add:rotate_drop_take)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2887
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2888	lemma length_rotate1[simp]: "length(rotate1 xs) = length xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2889	by(simp add:rotate1_def split:list.split)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2890
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2891	lemma length_rotate[simp]: "length(rotate n xs) = length xs"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2892	by (induct n arbitrary: xs) (simp_all add:rotate_def)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2893
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2894	lemma distinct1_rotate[simp]: "distinct(rotate1 xs) = distinct xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2895	by(simp add:rotate1_def split:list.split) blast
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2896
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2897	lemma distinct_rotate[simp]: "distinct(rotate n xs) = distinct xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2898	by (induct n) (simp_all add:rotate_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2899
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2900	lemma rotate_map: "rotate n (map f xs) = map f (rotate n xs)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2901	by(simp add:rotate_drop_take take_map drop_map)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2902
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2903	lemma set_rotate1[simp]: "set(rotate1 xs) = set xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2904	by(simp add:rotate1_def split:list.split)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2905
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2906	lemma set_rotate[simp]: "set(rotate n xs) = set xs"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2907	by (induct n) (simp_all add:rotate_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2908
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2909	lemma rotate1_is_Nil_conv[simp]: "(rotate1 xs = []) = (xs = [])"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2910	by(simp add:rotate1_def split:list.split)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2911
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2912	lemma rotate_is_Nil_conv[simp]: "(rotate n xs = []) = (xs = [])"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	2913	by (induct n) (simp_all add:rotate_def)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2914
15439 71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2915	lemma rotate_rev:
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2916	"rotate n (rev xs) = rev(rotate (length xs - (n mod length xs)) xs)"
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2917	apply(simp add:rotate_drop_take rev_drop rev_take)
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2918	apply(cases "length xs = 0")
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2919	apply simp
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2920	apply(cases "n mod length xs = 0")
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2921	apply simp
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2922	apply(simp add:rotate_drop_take rev_drop rev_take)
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2923	done
71c0f98e31f1 made diff_less a simp rule nipkow parents: 15426 diff changeset	2924
18423 d7859164447f new lemmas nipkow parents: 18336 diff changeset	2925	lemma hd_rotate_conv_nth: "xs \<noteq> [] \<Longrightarrow> hd(rotate n xs) = xs!(n mod length xs)"
d7859164447f new lemmas nipkow parents: 18336 diff changeset	2926	apply(simp add:rotate_drop_take hd_append hd_drop_conv_nth hd_conv_nth)
d7859164447f new lemmas nipkow parents: 18336 diff changeset	2927	apply(subgoal_tac "length xs \<noteq> 0")
d7859164447f new lemmas nipkow parents: 18336 diff changeset	2928	prefer 2 apply simp
d7859164447f new lemmas nipkow parents: 18336 diff changeset	2929	using mod_less_divisor[of "length xs" n] by arith
d7859164447f new lemmas nipkow parents: 18336 diff changeset	2930
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2931
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	2932	subsubsection {* @{text sublist} --- a generalization of @{text nth} to sets *}
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2933
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2934	lemma sublist_empty [simp]: "sublist xs {} = []"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2935	by (auto simp add: sublist_def)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2936
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2937	lemma sublist_nil [simp]: "sublist [] A = []"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2938	by (auto simp add: sublist_def)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2939
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2940	lemma length_sublist:
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2941	"length(sublist xs I) = card{i. i < length xs \<and> i : I}"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2942	by(simp add: sublist_def length_filter_conv_card cong:conj_cong)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2943
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2944	lemma sublist_shift_lemma_Suc:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2945	"map fst (filter (%p. P(Suc(snd p))) (zip xs is)) =
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2946	map fst (filter (%p. P(snd p)) (zip xs (map Suc is)))"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2947	apply(induct xs arbitrary: "is")
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2948	apply simp
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2949	apply (case_tac "is")
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2950	apply simp
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2951	apply simp
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2952	done
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2953
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2954	lemma sublist_shift_lemma:
23279 e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	2955	"map fst [p<-zip xs [i..<i + length xs] . snd p : A] =
e39dd93161d9 tuned list comprehension, changed filter syntax from : to <- nipkow parents: 23246 diff changeset	2956	map fst [p<-zip xs [0..<length xs] . snd p + i : A]"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2957	by (induct xs rule: rev_induct) (simp_all add: add_commute)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2958
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2959	lemma sublist_append:
15168 33a08cfc3ae5 new functions for sets of lists paulson parents: 15140 diff changeset	2960	"sublist (l @ l') A = sublist l A @ sublist l' {j. j + length l : A}"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2961	apply (unfold sublist_def)
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	2962	apply (induct l' rule: rev_induct, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2963	apply (simp add: upt_add_eq_append[of 0] zip_append sublist_shift_lemma)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2964	apply (simp add: add_commute)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2965	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2966
f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2967	lemma sublist_Cons:
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2968	"sublist (x # l) A = (if 0:A then [x] else []) @ sublist l {j. Suc j : A}"
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2969	apply (induct l rule: rev_induct)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2970	apply (simp add: sublist_def)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2971	apply (simp del: append_Cons add: append_Cons[symmetric] sublist_append)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2972	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2973
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2974	lemma set_sublist: "set(sublist xs I) = {xs!i\|i. i<size xs \<and> i \<in> I}"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2975	apply(induct xs arbitrary: I)
25162 ad4d5365d9d8 went back to >0 nipkow parents: 25157 diff changeset	2976	apply(auto simp: sublist_Cons nth_Cons split:nat.split dest!: gr0_implies_Suc)
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2977	done
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2978
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2979	lemma set_sublist_subset: "set(sublist xs I) \<subseteq> set xs"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2980	by(auto simp add:set_sublist)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2981
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2982	lemma notin_set_sublistI[simp]: "x \<notin> set xs \<Longrightarrow> x \<notin> set(sublist xs I)"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2983	by(auto simp add:set_sublist)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2984
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2985	lemma in_set_sublistD: "x \<in> set(sublist xs I) \<Longrightarrow> x \<in> set xs"
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2986	by(auto simp add:set_sublist)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2987
13142 1ebd8ed5a1a0 tuned document; wenzelm parents: 13124 diff changeset	2988	lemma sublist_singleton [simp]: "sublist [x] A = (if 0 : A then [x] else [])"
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	2989	by (simp add: sublist_Cons)
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	2990
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2991
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2992	lemma distinct_sublistI[simp]: "distinct xs \<Longrightarrow> distinct(sublist xs I)"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	2993	apply(induct xs arbitrary: I)
15281 bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2994	apply simp
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2995	apply(auto simp add:sublist_Cons)
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2996	done
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2997
bd4611956c7b More lemmas nipkow parents: 15251 diff changeset	2998
15045 d59f7e2e18d3 Moved to new m<..<n syntax for set intervals. nipkow parents: 14981 diff changeset	2999	lemma sublist_upt_eq_take [simp]: "sublist l {..<n} = take n l"
14208 144f45277d5a misc tidying paulson parents: 14187 diff changeset	3000	apply (induct l rule: rev_induct, simp)
13145 59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	3001	apply (simp split: nat_diff_split add: sublist_append)
59bc43b51aa2 * empty log message * nipkow parents: 13142 diff changeset	3002	done
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	3003
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	3004	lemma filter_in_sublist:
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	3005	"distinct xs \<Longrightarrow> filter (%x. x \<in> set(sublist xs s)) xs = sublist xs s"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	3006	proof (induct xs arbitrary: s)
17501 acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	3007	case Nil thus ?case by simp
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	3008	next
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	3009	case (Cons a xs)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	3010	moreover hence "!x. x: set xs \<longrightarrow> x \<noteq> a" by auto
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	3011	ultimately show ?case by(simp add: sublist_Cons cong:filter_cong)
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	3012	qed
acbebb72e85a added a number of lemmas nipkow parents: 17090 diff changeset	3013
13114 f2b00262bdfc converted; wenzelm parents: 12887 diff changeset	3014
19390 6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3015	subsubsection {* @{const splice} *}
6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3016
19607 07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	3017	lemma splice_Nil2 [simp, code]:
19390 6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3018	"splice xs [] = xs"
6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3019	by (cases xs) simp_all
6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3020
19607 07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	3021	lemma splice_Cons_Cons [simp, code]:
19390 6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3022	"splice (x#xs) (y#ys) = x # y # splice xs ys"
6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3023	by simp
6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3024
19607 07eeb832f28d introduced characters for code generator; some improved code lemmas for some list functions haftmann parents: 19585 diff changeset	3025	declare splice.simps(2) [simp del, code del]
19390 6c7383f80ad1 Added function "splice" nipkow parents: 19363 diff changeset	3026
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	3027	lemma length_splice[simp]: "length(splice xs ys) = length xs + length ys"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	3028	apply(induct xs arbitrary: ys) apply simp
22793 dc13dfd588b2 new lemma splice_length nipkow parents: 22633 diff changeset	3029	apply(case_tac ys)
dc13dfd588b2 new lemma splice_length nipkow parents: 22633 diff changeset	3030	apply auto
dc13dfd588b2 new lemma splice_length nipkow parents: 22633 diff changeset	3031	done
dc13dfd588b2 new lemma splice_length nipkow parents: 22633 diff changeset	3032
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3033
31557 4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3034	subsubsection {* (In)finiteness *}
28642 658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3035
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3036	lemma finite_maxlen:
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3037	"finite (M::'a list set) ==> EX n. ALL s:M. size s < n"
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3038	proof (induct rule: finite.induct)
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3039	case emptyI show ?case by simp
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3040	next
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3041	case (insertI M xs)
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3042	then obtain n where "\<forall>s\<in>M. length s < n" by blast
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3043	hence "ALL s:insert xs M. size s < max n (size xs) + 1" by auto
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3044	thus ?case ..
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3045	qed
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3046
31557 4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3047	lemma finite_lists_length_eq:
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3048	assumes "finite A"
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3049	shows "finite {xs. set xs \<subseteq> A \<and> length xs = n}" (is "finite (?S n)")
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3050	proof(induct n)
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3051	case 0 show ?case by simp
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3052	next
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3053	case (Suc n)
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3054	have "?S (Suc n) = (\<Union>x\<in>A. (\<lambda>xs. x#xs) ` ?S n)"
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3055	by (auto simp:length_Suc_conv)
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3056	then show ?case using `finite A`
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3057	by (auto intro: finite_imageI Suc) (* FIXME metis? *)
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3058	qed
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3059
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3060	lemma finite_lists_length_le:
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3061	assumes "finite A" shows "finite {xs. set xs \<subseteq> A \<and> length xs \<le> n}"
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3062	(is "finite ?S")
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3063	proof-
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3064	have "?S = (\<Union>n\<in>{0..n}. {xs. set xs \<subseteq> A \<and> length xs = n})" by auto
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3065	thus ?thesis by (auto intro: finite_lists_length_eq[OF `finite A`])
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3066	qed
4e36f2f17c63 two finiteness lemmas by Robert Himmelmann nipkow parents: 31455 diff changeset	3067
28642 658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3068	lemma infinite_UNIV_listI: "~ finite(UNIV::'a list set)"
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3069	apply(rule notI)
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3070	apply(drule finite_maxlen)
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3071	apply (metis UNIV_I length_replicate less_not_refl)
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3072	done
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3073
658b598d8af4 added lemmas nipkow parents: 28562 diff changeset	3074
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3075	subsection {Sorting}
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3076
24617 bc484b2671fd sorting nipkow parents: 24616 diff changeset	3077	text{* Currently it is not shown that @{const sort} returns a
bc484b2671fd sorting nipkow parents: 24616 diff changeset	3078	permutation of its input because the nicest proof is via multisets,
bc484b2671fd sorting nipkow parents: 24616 diff changeset	3079	which are not yet available. Alternatively one could define a function
bc484b2671fd sorting nipkow parents: 24616 diff changeset	3080	that counts the number of occurrences of an element in a list and use
bc484b2671fd sorting nipkow parents: 24616 diff changeset	3081	that instead of multisets to state the correctness property. *}
bc484b2671fd sorting nipkow parents: 24616 diff changeset	3082
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3083	context linorder
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3084	begin
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3085
25062 af5ef0d4d655 global class syntax haftmann parents: 24902 diff changeset	3086	lemma sorted_Cons: "sorted (x#xs) = (sorted xs & (ALL y:set xs. x <= y))"
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3087	apply(induct xs arbitrary: x) apply simp
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3088	by simp (blast intro: order_trans)
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3089
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3090	lemma sorted_append:
25062 af5ef0d4d655 global class syntax haftmann parents: 24902 diff changeset	3091	"sorted (xs@ys) = (sorted xs & sorted ys & (\<forall>x \<in> set xs. \<forall>y \<in> set ys. x\<le>y))"
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3092	by (induct xs) (auto simp add:sorted_Cons)
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3093
31201 3dde56615750 new lemma nipkow parents: 31159 diff changeset	3094	lemma sorted_nth_mono:
3dde56615750 new lemma nipkow parents: 31159 diff changeset	3095	"sorted xs \<Longrightarrow> i <= j \<Longrightarrow> j < length xs \<Longrightarrow> xs!i <= xs!j"
3dde56615750 new lemma nipkow parents: 31159 diff changeset	3096	by (induct xs arbitrary: i j) (auto simp:nth_Cons' sorted_Cons)
3dde56615750 new lemma nipkow parents: 31159 diff changeset	3097
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3098	lemma set_insort: "set(insort x xs) = insert x (set xs)"
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3099	by (induct xs) auto
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3100
24617 bc484b2671fd sorting nipkow parents: 24616 diff changeset	3101	lemma set_sort[simp]: "set(sort xs) = set xs"
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3102	by (induct xs) (simp_all add:set_insort)
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3103
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3104	lemma distinct_insort: "distinct (insort x xs) = (x \<notin> set xs \<and> distinct xs)"
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3105	by(induct xs)(auto simp:set_insort)
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3106
24617 bc484b2671fd sorting nipkow parents: 24616 diff changeset	3107	lemma distinct_sort[simp]: "distinct (sort xs) = distinct xs"
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3108	by(induct xs)(simp_all add:distinct_insort set_sort)
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3109
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3110	lemma sorted_insort: "sorted (insort x xs) = sorted xs"
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3111	apply (induct xs)
24650 e2930fa53538 tuned nipkow parents: 24648 diff changeset	3112	apply(auto simp:sorted_Cons set_insort)
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3113	done
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3114
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3115	theorem sorted_sort[simp]: "sorted (sort xs)"
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3116	by (induct xs) (auto simp:sorted_insort)
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3117
26143 314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3118	lemma insort_is_Cons: "\<forall>x\<in>set xs. a \<le> x \<Longrightarrow> insort a xs = a # xs"
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3119	by (cases xs) auto
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3120
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3121	lemma sorted_remove1: "sorted xs \<Longrightarrow> sorted (remove1 a xs)"
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3122	by (induct xs, auto simp add: sorted_Cons)
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3123
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3124	lemma insort_remove1: "\<lbrakk> a \<in> set xs; sorted xs \<rbrakk> \<Longrightarrow> insort a (remove1 a xs) = xs"
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3125	by (induct xs, auto simp add: sorted_Cons insort_is_Cons)
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3126
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3127	lemma sorted_remdups[simp]:
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3128	"sorted l \<Longrightarrow> sorted (remdups l)"
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3129	by (induct l) (auto simp: sorted_Cons)
314c0bcb7df7 Added useful general lemmas from the work with the HeapMonad bulwahn parents: 26073 diff changeset	3130
24645 1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3131	lemma sorted_distinct_set_unique:
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3132	assumes "sorted xs" "distinct xs" "sorted ys" "distinct ys" "set xs = set ys"
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3133	shows "xs = ys"
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3134	proof -
26734 a92057c1ee21 dropped some metis calls haftmann parents: 26584 diff changeset	3135	from assms have 1: "length xs = length ys" by (auto dest!: distinct_card)
24645 1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3136	from assms show ?thesis
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3137	proof(induct rule:list_induct2[OF 1])
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3138	case 1 show ?case by simp
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3139	next
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3140	case 2 thus ?case by (simp add:sorted_Cons)
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3141	(metis Diff_insert_absorb antisym insertE insert_iff)
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3142	qed
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3143	qed
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3144
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3145	lemma finite_sorted_distinct_unique:
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3146	shows "finite A \<Longrightarrow> EX! xs. set xs = A & sorted xs & distinct xs"
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3147	apply(drule finite_distinct_list)
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3148	apply clarify
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3149	apply(rule_tac a="sort xs" in ex1I)
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3150	apply (auto simp: sorted_distinct_set_unique)
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3151	done
1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3152
29626 6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3153	lemma sorted_take:
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3154	"sorted xs \<Longrightarrow> sorted (take n xs)"
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3155	proof (induct xs arbitrary: n rule: sorted.induct)
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3156	case 1 show ?case by simp
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3157	next
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3158	case 2 show ?case by (cases n) simp_all
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3159	next
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3160	case (3 x y xs)
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3161	then have "x \<le> y" by simp
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3162	show ?case proof (cases n)
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3163	case 0 then show ?thesis by simp
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3164	next
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3165	case (Suc m)
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3166	with 3 have "sorted (take m (y # xs))" by simp
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3167	with Suc `x \<le> y` show ?thesis by (cases m) simp_all
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3168	qed
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3169	qed
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3170
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3171	lemma sorted_drop:
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3172	"sorted xs \<Longrightarrow> sorted (drop n xs)"
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3173	proof (induct xs arbitrary: n rule: sorted.induct)
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3174	case 1 show ?case by simp
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3175	next
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3176	case 2 show ?case by (cases n) simp_all
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3177	next
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3178	case 3 then show ?case by (cases n) simp_all
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3179	qed
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3180
6f8aada233c1 sorted_take, sorted_drop haftmann parents: 29509 diff changeset	3181
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3182	end
fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3183
25277 95128fcdd7e8 added lemmas nipkow parents: 25221 diff changeset	3184	lemma sorted_upt[simp]: "sorted[i..<j]"
95128fcdd7e8 added lemmas nipkow parents: 25221 diff changeset	3185	by (induct j) (simp_all add:sorted_append)
95128fcdd7e8 added lemmas nipkow parents: 25221 diff changeset	3186
32415 1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	3187	lemma sorted_upto[simp]: "sorted[i..j]"
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	3188	apply(induct i j rule:upto.induct)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	3189	apply(subst upto.simps)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	3190	apply(simp add:sorted_Cons)
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	3191	done
1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	3192
24616 fac3dd4ade83 sorting nipkow parents: 24566 diff changeset	3193
25069 081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3194	subsubsection {* @{text sorted_list_of_set} *}
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3195
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3196	text{* This function maps (finite) linearly ordered sets to sorted
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3197	lists. Warning: in most cases it is not a good idea to convert from
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3198	sets to lists but one should convert in the other direction (via
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3199	@{const set}). *}
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3200
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3201
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3202	context linorder
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3203	begin
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3204
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3205	definition
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3206	sorted_list_of_set :: "'a set \<Rightarrow> 'a list" where
28562 4e74209f113e `code func` now just `code` haftmann parents: 28537 diff changeset	3207	[code del]: "sorted_list_of_set A == THE xs. set xs = A & sorted xs & distinct xs"
25069 081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3208
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3209	lemma sorted_list_of_set[simp]: "finite A \<Longrightarrow>
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3210	set(sorted_list_of_set A) = A &
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3211	sorted(sorted_list_of_set A) & distinct(sorted_list_of_set A)"
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3212	apply(simp add:sorted_list_of_set_def)
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3213	apply(rule the1I2)
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3214	apply(simp_all add: finite_sorted_distinct_unique)
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3215	done
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3216
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3217	lemma sorted_list_of_empty[simp]: "sorted_list_of_set {} = []"
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3218	unfolding sorted_list_of_set_def
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3219	apply(subst the_equality[of _ "[]"])
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3220	apply simp_all
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3221	done
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3222
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3223	end
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3224
081189141a6e added sorted_list_of_set nipkow parents: 25062 diff changeset	3225
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	3226	subsubsection {* @{text lists}: the list-forming operator over sets *}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3227
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3228	inductive_set
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3229	lists :: "'a set => 'a list set"
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3230	for A :: "'a set"
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3231	where
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3232	Nil [intro!]: "[]: lists A"
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3233	\| Cons [intro!,noatp]: "[\| a: A; l: lists A\|] ==> a#l : lists A"
24286 7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3234
7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3235	inductive_cases listsE [elim!,noatp]: "x#l : lists A"
7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3236	inductive_cases listspE [elim!,noatp]: "listsp A (x # l)"
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3237
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3238	lemma listsp_mono [mono]: "A \<le> B ==> listsp A \<le> listsp B"
26795 a27607030a1c - Explicitely applied predicate1I in a few proofs, because it is no longer berghofe parents: 26771 diff changeset	3239	by (rule predicate1I, erule listsp.induct, blast+)
a27607030a1c - Explicitely applied predicate1I in a few proofs, because it is no longer berghofe parents: 26771 diff changeset	3240
a27607030a1c - Explicitely applied predicate1I in a few proofs, because it is no longer berghofe parents: 26771 diff changeset	3241	lemmas lists_mono = listsp_mono [to_set pred_subset_eq]
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3242
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3243	lemma listsp_infI:
ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3244	assumes l: "listsp A l" shows "listsp B l ==> listsp (inf A B) l" using l
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3245	by induct blast+
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3246
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3247	lemmas lists_IntI = listsp_infI [to_set]
ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3248
ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3249	lemma listsp_inf_eq [simp]: "listsp (inf A B) = inf (listsp A) (listsp B)"
ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3250	proof (rule mono_inf [where f=listsp, THEN order_antisym])
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3251	show "mono listsp" by (simp add: mono_def listsp_mono)
26795 a27607030a1c - Explicitely applied predicate1I in a few proofs, because it is no longer berghofe parents: 26771 diff changeset	3252	show "inf (listsp A) (listsp B) \<le> listsp (inf A B)" by (blast intro!: listsp_infI predicate1I)
14388 04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	3253	qed
04f04408b99b lemmas about card (set xs) kleing parents: 14343 diff changeset	3254
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3255	lemmas listsp_conj_eq [simp] = listsp_inf_eq [simplified inf_fun_eq inf_bool_eq]
ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3256
26795 a27607030a1c - Explicitely applied predicate1I in a few proofs, because it is no longer berghofe parents: 26771 diff changeset	3257	lemmas lists_Int_eq [simp] = listsp_inf_eq [to_set pred_equals_eq]
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3258
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3259	lemma append_in_listsp_conv [iff]:
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3260	"(listsp A (xs @ ys)) = (listsp A xs \<and> listsp A ys)"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3261	by (induct xs) auto
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3262
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3263	lemmas append_in_lists_conv [iff] = append_in_listsp_conv [to_set]
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3264
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3265	lemma in_listsp_conv_set: "(listsp A xs) = (\<forall>x \<in> set xs. A x)"
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3266	-- {* eliminate @{text listsp} in favour of @{text set} *}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3267	by (induct xs) auto
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3268
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3269	lemmas in_lists_conv_set = in_listsp_conv_set [to_set]
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3270
24286 7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3271	lemma in_listspD [dest!,noatp]: "listsp A xs ==> \<forall>x\<in>set xs. A x"
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3272	by (rule in_listsp_conv_set [THEN iffD1])
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3273
24286 7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3274	lemmas in_listsD [dest!,noatp] = in_listspD [to_set]
7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3275
7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3276	lemma in_listspI [intro!,noatp]: "\<forall>x\<in>set xs. A x ==> listsp A xs"
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3277	by (rule in_listsp_conv_set [THEN iffD2])
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3278
24286 7619080e49f0 ATP blacklisting is now in theory data, attribute noatp paulson parents: 24219 diff changeset	3279	lemmas in_listsI [intro!,noatp] = in_listspI [to_set]
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3280
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3281	lemma lists_UNIV [simp]: "lists UNIV = UNIV"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3282	by auto
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3283
17086 0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3284
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3285
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3286	subsubsection{* Inductive definition for membership *}
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3287
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3288	inductive ListMem :: "'a \<Rightarrow> 'a list \<Rightarrow> bool"
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3289	where
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3290	elem: "ListMem x (x # xs)"
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3291	\| insert: "ListMem x xs \<Longrightarrow> ListMem x (y # xs)"
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3292
96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3293	lemma ListMem_iff: "(ListMem x xs) = (x \<in> set xs)"
17086 0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3294	apply (rule iffI)
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3295	apply (induct set: ListMem)
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3296	apply auto
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3297	apply (induct xs)
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3298	apply (auto intro: ListMem.intros)
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3299	done
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3300
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3301
0eb0c9259dd7 added quite a few functions for code generation nipkow parents: 16998 diff changeset	3302
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	3303	subsubsection{Lists as Cartesian products}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3304
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3305	text{*@{text"set_Cons A Xs"}: the set of lists with head drawn from
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3306	@{term A} and tail drawn from @{term Xs}.*}
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3307
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3308	constdefs
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3309	set_Cons :: "'a set \<Rightarrow> 'a list set \<Rightarrow> 'a list set"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3310	"set_Cons A XS == {z. \<exists>x xs. z = x#xs & x \<in> A & xs \<in> XS}"
28562 4e74209f113e `code func` now just `code` haftmann parents: 28537 diff changeset	3311	declare set_Cons_def [code del]
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3312
17724 e969fc0a4925 simprules need names paulson parents: 17629 diff changeset	3313	lemma set_Cons_sing_Nil [simp]: "set_Cons A {[]} = (%x. [x])`A"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3314	by (auto simp add: set_Cons_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3315
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3316	text{*Yields the set of lists, all of the same length as the argument and
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3317	with elements drawn from the corresponding element of the argument.*}
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3318
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3319	consts listset :: "'a set list \<Rightarrow> 'a list set"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3320	primrec
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3321	"listset [] = {[]}"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3322	"listset(A#As) = set_Cons A (listset As)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3323
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3324
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3325	subsection{Relations on Lists}
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3326
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3327	subsubsection {* Length Lexicographic Ordering *}
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3328
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3329	text{*These orderings preserve well-foundedness: shorter lists
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3330	precede longer lists. These ordering are not used in dictionaries.*}
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3331
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3332	consts lexn :: "('a * 'a)set => nat => ('a list * 'a list)set"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3333	--{The lexicographic ordering for lists of the specified length}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3334	primrec
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3335	"lexn r 0 = {}"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3336	"lexn r (Suc n) =
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3337	(prod_fun (%(x,xs). x#xs) (%(x,xs). x#xs) ` (r <lex> lexn r n)) Int
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3338	{(xs,ys). length xs = Suc n \<and> length ys = Suc n}"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3339
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3340	constdefs
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3341	lex :: "('a \<times> 'a) set => ('a list \<times> 'a list) set"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3342	"lex r == \<Union>n. lexn r n"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3343	--{Holds only between lists of the same length}
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3344
15693 3a67e61c6e96 tuned Map, renamed lex stuff in List. nipkow parents: 15656 diff changeset	3345	lenlex :: "('a \<times> 'a) set => ('a list \<times> 'a list) set"
3a67e61c6e96 tuned Map, renamed lex stuff in List. nipkow parents: 15656 diff changeset	3346	"lenlex r == inv_image (less_than <lex> lex r) (%xs. (length xs, xs))"
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3347	--{Compares lists by their length and then lexicographically}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3348
28562 4e74209f113e `code func` now just `code` haftmann parents: 28537 diff changeset	3349	declare lex_def [code del]
27106 ff27dc6e7d05 removed some dubious code lemmas haftmann parents: 26975 diff changeset	3350
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3351
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3352	lemma wf_lexn: "wf r ==> wf (lexn r n)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3353	apply (induct n, simp, simp)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3354	apply(rule wf_subset)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3355	prefer 2 apply (rule Int_lower1)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3356	apply(rule wf_prod_fun_image)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3357	prefer 2 apply (rule inj_onI, auto)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3358	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3359
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3360	lemma lexn_length:
24526 7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	3361	"(xs, ys) : lexn r n ==> length xs = n \<and> length ys = n"
7fa202789bf6 tuned lemma; replaced !! by arbitrary nipkow parents: 24476 diff changeset	3362	by (induct n arbitrary: xs ys) auto
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3363
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3364	lemma wf_lex [intro!]: "wf r ==> wf (lex r)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3365	apply (unfold lex_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3366	apply (rule wf_UN)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3367	apply (blast intro: wf_lexn, clarify)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3368	apply (rename_tac m n)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3369	apply (subgoal_tac "m \<noteq> n")
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3370	prefer 2 apply blast
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3371	apply (blast dest: lexn_length not_sym)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3372	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3373
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3374	lemma lexn_conv:
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3375	"lexn r n =
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3376	{(xs,ys). length xs = n \<and> length ys = n \<and>
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3377	(\<exists>xys x y xs' ys'. xs= xys @ x#xs' \<and> ys= xys @ y # ys' \<and> (x, y):r)}"
18423 d7859164447f new lemmas nipkow parents: 18336 diff changeset	3378	apply (induct n, simp)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3379	apply (simp add: image_Collect lex_prod_def, safe, blast)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3380	apply (rule_tac x = "ab # xys" in exI, simp)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3381	apply (case_tac xys, simp_all, blast)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3382	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3383
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3384	lemma lex_conv:
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3385	"lex r =
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3386	{(xs,ys). length xs = length ys \<and>
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3387	(\<exists>xys x y xs' ys'. xs = xys @ x # xs' \<and> ys = xys @ y # ys' \<and> (x, y):r)}"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3388	by (force simp add: lex_def lexn_conv)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3389
15693 3a67e61c6e96 tuned Map, renamed lex stuff in List. nipkow parents: 15656 diff changeset	3390	lemma wf_lenlex [intro!]: "wf r ==> wf (lenlex r)"
3a67e61c6e96 tuned Map, renamed lex stuff in List. nipkow parents: 15656 diff changeset	3391	by (unfold lenlex_def) blast
3a67e61c6e96 tuned Map, renamed lex stuff in List. nipkow parents: 15656 diff changeset	3392
3a67e61c6e96 tuned Map, renamed lex stuff in List. nipkow parents: 15656 diff changeset	3393	lemma lenlex_conv:
3a67e61c6e96 tuned Map, renamed lex stuff in List. nipkow parents: 15656 diff changeset	3394	"lenlex r = {(xs,ys). length xs < length ys \|
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3395	length xs = length ys \<and> (xs, ys) : lex r}"
30198 922f944f03b2 name changes nipkow parents: 30128 diff changeset	3396	by (simp add: lenlex_def Id_on_def lex_prod_def inv_image_def)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3397
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3398	lemma Nil_notin_lex [iff]: "([], ys) \<notin> lex r"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3399	by (simp add: lex_conv)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3400
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3401	lemma Nil2_notin_lex [iff]: "(xs, []) \<notin> lex r"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3402	by (simp add:lex_conv)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3403
18447 da548623916a removed or modified some instances of [iff] paulson parents: 18423 diff changeset	3404	lemma Cons_in_lex [simp]:
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3405	"((x # xs, y # ys) : lex r) =
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3406	((x, y) : r \<and> length xs = length ys \| x = y \<and> (xs, ys) : lex r)"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3407	apply (simp add: lex_conv)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3408	apply (rule iffI)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3409	prefer 2 apply (blast intro: Cons_eq_appendI, clarify)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3410	apply (case_tac xys, simp, simp)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3411	apply blast
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3412	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3413
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3414
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3415	subsubsection {* Lexicographic Ordering *}
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3416
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3417	text {* Classical lexicographic ordering on lists, ie. "a" < "ab" < "b".
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3418	This ordering does \emph{not} preserve well-foundedness.
17090 603f23d71ada small mods to code lemmas nipkow parents: 17086 diff changeset	3419	Author: N. Voelker, March 2005. *}
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3420
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3421	constdefs
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3422	lexord :: "('a * 'a)set \<Rightarrow> ('a list * 'a list) set"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3423	"lexord r == {(x,y). \<exists> a v. y = x @ a # v \<or>
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3424	(\<exists> u a b v w. (a,b) \<in> r \<and> x = u @ (a # v) \<and> y = u @ (b # w))}"
28562 4e74209f113e `code func` now just `code` haftmann parents: 28537 diff changeset	3425	declare lexord_def [code del]
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3426
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3427	lemma lexord_Nil_left[simp]: "([],y) \<in> lexord r = (\<exists> a x. y = a # x)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3428	by (unfold lexord_def, induct_tac y, auto)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3429
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3430	lemma lexord_Nil_right[simp]: "(x,[]) \<notin> lexord r"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3431	by (unfold lexord_def, induct_tac x, auto)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3432
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3433	lemma lexord_cons_cons[simp]:
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3434	"((a # x, b # y) \<in> lexord r) = ((a,b)\<in> r \| (a = b & (x,y)\<in> lexord r))"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3435	apply (unfold lexord_def, safe, simp_all)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3436	apply (case_tac u, simp, simp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3437	apply (case_tac u, simp, clarsimp, blast, blast, clarsimp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3438	apply (erule_tac x="b # u" in allE)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3439	by force
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3440
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3441	lemmas lexord_simps = lexord_Nil_left lexord_Nil_right lexord_cons_cons
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3442
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3443	lemma lexord_append_rightI: "\<exists> b z. y = b # z \<Longrightarrow> (x, x @ y) \<in> lexord r"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3444	by (induct_tac x, auto)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3445
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3446	lemma lexord_append_left_rightI:
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3447	"(a,b) \<in> r \<Longrightarrow> (u @ a # x, u @ b # y) \<in> lexord r"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3448	by (induct_tac u, auto)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3449
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3450	lemma lexord_append_leftI: " (u,v) \<in> lexord r \<Longrightarrow> (x @ u, x @ v) \<in> lexord r"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3451	by (induct x, auto)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3452
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3453	lemma lexord_append_leftD:
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3454	"\<lbrakk> (x @ u, x @ v) \<in> lexord r; (! a. (a,a) \<notin> r) \<rbrakk> \<Longrightarrow> (u,v) \<in> lexord r"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3455	by (erule rev_mp, induct_tac x, auto)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3456
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3457	lemma lexord_take_index_conv:
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3458	"((x,y) : lexord r) =
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3459	((length x < length y \<and> take (length x) y = x) \<or>
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3460	(\<exists>i. i < min(length x)(length y) & take i x = take i y & (x!i,y!i) \<in> r))"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3461	apply (unfold lexord_def Let_def, clarsimp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3462	apply (rule_tac f = "(% a b. a \<or> b)" in arg_cong2)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3463	apply auto
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3464	apply (rule_tac x="hd (drop (length x) y)" in exI)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3465	apply (rule_tac x="tl (drop (length x) y)" in exI)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3466	apply (erule subst, simp add: min_def)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3467	apply (rule_tac x ="length u" in exI, simp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3468	apply (rule_tac x ="take i x" in exI)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3469	apply (rule_tac x ="x ! i" in exI)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3470	apply (rule_tac x ="y ! i" in exI, safe)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3471	apply (rule_tac x="drop (Suc i) x" in exI)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3472	apply (drule sym, simp add: drop_Suc_conv_tl)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3473	apply (rule_tac x="drop (Suc i) y" in exI)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3474	by (simp add: drop_Suc_conv_tl)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3475
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3476	-- {* lexord is extension of partial ordering List.lex *}
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3477	lemma lexord_lex: " (x,y) \<in> lex r = ((x,y) \<in> lexord r \<and> length x = length y)"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3478	apply (rule_tac x = y in spec)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3479	apply (induct_tac x, clarsimp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3480	by (clarify, case_tac x, simp, force)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3481
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3482	lemma lexord_irreflexive: "(! x. (x,x) \<notin> r) \<Longrightarrow> (y,y) \<notin> lexord r"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3483	by (induct y, auto)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3484
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3485	lemma lexord_trans:
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3486	"\<lbrakk> (x, y) \<in> lexord r; (y, z) \<in> lexord r; trans r \<rbrakk> \<Longrightarrow> (x, z) \<in> lexord r"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3487	apply (erule rev_mp)+
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3488	apply (rule_tac x = x in spec)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3489	apply (rule_tac x = z in spec)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3490	apply ( induct_tac y, simp, clarify)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3491	apply (case_tac xa, erule ssubst)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3492	apply (erule allE, erule allE) -- {* avoid simp recursion *}
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3493	apply (case_tac x, simp, simp)
24632 779fc4fcbf8b metis now available in PreList paulson parents: 24617 diff changeset	3494	apply (case_tac x, erule allE, erule allE, simp)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3495	apply (erule_tac x = listb in allE)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3496	apply (erule_tac x = lista in allE, simp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3497	apply (unfold trans_def)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3498	by blast
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3499
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3500	lemma lexord_transI: "trans r \<Longrightarrow> trans (lexord r)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3501	by (rule transI, drule lexord_trans, blast)
15656 988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3502
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3503	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"
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3504	apply (rule_tac x = y in spec)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3505	apply (induct_tac x, rule allI)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3506	apply (case_tac x, simp, simp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3507	apply (rule allI, case_tac x, simp, simp)
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3508	by blast
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3509
988f91b9c4ef lexicographic order by Norbert Voelker paulson parents: 15570 diff changeset	3510
21103 367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3511	subsection {* Lexicographic combination of measure functions *}
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3512
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3513	text {* These are useful for termination proofs *}
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3514
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3515	definition
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3516	"measures fs = inv_image (lex less_than) (%a. map (%f. f a) fs)"
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3517
21106 51599a81b308 Added "recdef_wf" and "simp" attribute to "wf_measures" krauss parents: 21103 diff changeset	3518	lemma wf_measures[recdef_wf, simp]: "wf (measures fs)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3519	unfolding measures_def
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3520	by blast
21103 367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3521
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3522	lemma in_measures[simp]:
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3523	"(x, y) \<in> measures [] = False"
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3524	"(x, y) \<in> measures (f # fs)
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3525	= (f x < f y \<or> (f x = f y \<and> (x, y) \<in> measures fs))"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3526	unfolding measures_def
0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3527	by auto
21103 367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3528
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3529	lemma measures_less: "f x < f y ==> (x, y) \<in> measures (f#fs)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3530	by simp
21103 367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3531
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3532	lemma measures_lesseq: "f x <= f y ==> (x, y) \<in> measures fs ==> (x, y) \<in> measures (f#fs)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3533	by auto
21103 367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3534
367b4ad7c7cc Added "measures" combinator for lexicographic combinations of multiple measures. krauss parents: 21079 diff changeset	3535
15392 290bc97038c7 First step in reorganizing Finite_Set nipkow parents: 15307 diff changeset	3536	subsubsection{Lifting a Relation on List Elements to the Lists}
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3537
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3538	inductive_set
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3539	listrel :: "('a * 'a)set => ('a list * 'a list)set"
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3540	for r :: "('a * 'a)set"
22262 96ba62dff413 Adapted to new inductive definition package. berghofe parents: 22143 diff changeset	3541	where
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3542	Nil: "([],[]) \<in> listrel r"
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3543	\| Cons: "[\| (x,y) \<in> r; (xs,ys) \<in> listrel r \|] ==> (x#xs, y#ys) \<in> listrel r"
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3544
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3545	inductive_cases listrel_Nil1 [elim!]: "([],xs) \<in> listrel r"
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3546	inductive_cases listrel_Nil2 [elim!]: "(xs,[]) \<in> listrel r"
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3547	inductive_cases listrel_Cons1 [elim!]: "(y#ys,xs) \<in> listrel r"
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3548	inductive_cases listrel_Cons2 [elim!]: "(xs,y#ys) \<in> listrel r"
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3549
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3550
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3551	lemma listrel_mono: "r \<subseteq> s \<Longrightarrow> listrel r \<subseteq> listrel s"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3552	apply clarify
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3553	apply (erule listrel.induct)
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3554	apply (blast intro: listrel.intros)+
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3555	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3556
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3557	lemma listrel_subset: "r \<subseteq> A \<times> A \<Longrightarrow> listrel r \<subseteq> lists A \<times> lists A"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3558	apply clarify
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3559	apply (erule listrel.induct, auto)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3560	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3561
30198 922f944f03b2 name changes nipkow parents: 30128 diff changeset	3562	lemma listrel_refl_on: "refl_on A r \<Longrightarrow> refl_on (lists A) (listrel r)"
922f944f03b2 name changes nipkow parents: 30128 diff changeset	3563	apply (simp add: refl_on_def listrel_subset Ball_def)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3564	apply (rule allI)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3565	apply (induct_tac x)
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3566	apply (auto intro: listrel.intros)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3567	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3568
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3569	lemma listrel_sym: "sym r \<Longrightarrow> sym (listrel r)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3570	apply (auto simp add: sym_def)
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3571	apply (erule listrel.induct)
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3572	apply (blast intro: listrel.intros)+
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3573	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3574
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3575	lemma listrel_trans: "trans r \<Longrightarrow> trans (listrel r)"
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3576	apply (simp add: trans_def)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3577	apply (intro allI)
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3578	apply (rule impI)
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3579	apply (erule listrel.induct)
d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3580	apply (blast intro: listrel.intros)+
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3581	done
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3582
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3583	theorem equiv_listrel: "equiv A r \<Longrightarrow> equiv (lists A) (listrel r)"
30198 922f944f03b2 name changes nipkow parents: 30128 diff changeset	3584	by (simp add: equiv_def listrel_refl_on listrel_sym listrel_trans)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3585
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3586	lemma listrel_Nil [simp]: "listrel r `` {[]} = {[]}"
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3587	by (blast intro: listrel.intros)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3588
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3589	lemma listrel_Cons:
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3590	"listrel r `` {x#xs} = set_Cons (r``{x}) (listrel r `` {xs})";
23740 d7f18c837ce7 Adapted to new package for inductive sets. berghofe parents: 23554 diff changeset	3591	by (auto simp add: set_Cons_def intro: listrel.intros)
15302 a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3592
a643fcbc3468 Restructured List and added "rotate" nipkow parents: 15281 diff changeset	3593
26749 397a1aeede7d * New attribute "termination_simp": Simp rules for termination proofs krauss parents: 26734 diff changeset	3594	subsection {* Size function *}
397a1aeede7d * New attribute "termination_simp": Simp rules for termination proofs krauss parents: 26734 diff changeset	3595
26875 e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3596	lemma [measure_function]: "is_measure f \<Longrightarrow> is_measure (list_size f)"
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3597	by (rule is_measure_trivial)
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3598
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3599	lemma [measure_function]: "is_measure f \<Longrightarrow> is_measure (option_size f)"
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3600	by (rule is_measure_trivial)
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3601
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3602	lemma list_size_estimation[termination_simp]:
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3603	"x \<in> set xs \<Longrightarrow> y < f x \<Longrightarrow> y < list_size f xs"
26749 397a1aeede7d * New attribute "termination_simp": Simp rules for termination proofs krauss parents: 26734 diff changeset	3604	by (induct xs) auto
397a1aeede7d * New attribute "termination_simp": Simp rules for termination proofs krauss parents: 26734 diff changeset	3605
26875 e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3606	lemma list_size_estimation'[termination_simp]:
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3607	"x \<in> set xs \<Longrightarrow> y \<le> f x \<Longrightarrow> y \<le> list_size f xs"
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3608	by (induct xs) auto
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3609
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3610	lemma list_size_map[simp]: "list_size f (map g xs) = list_size (f o g) xs"
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3611	by (induct xs) auto
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3612
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3613	lemma list_size_pointwise[termination_simp]:
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3614	"(\<And>x. x \<in> set xs \<Longrightarrow> f x < g x) \<Longrightarrow> list_size f xs \<le> list_size g xs"
e18574413bc4 Measure functions can now be declared via special rules, allowing for a krauss parents: 26795 diff changeset	3615	by (induct xs) force+
26749 397a1aeede7d * New attribute "termination_simp": Simp rules for termination proofs krauss parents: 26734 diff changeset	3616
31048 ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3617
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3618	subsection {* Code generator *}
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3619
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3620	subsubsection {* Setup *}
15064 4f3102b50197 - Moved code generator setup for lists from Main.thy to List.thy berghofe parents: 15045 diff changeset	3621
31055 2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3622	use "Tools/list_code.ML"
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3623
31048 ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3624	code_type list
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3625	(SML "_ list")
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3626	(OCaml "_ list")
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3627	(Haskell "![_]")
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3628
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3629	code_const Nil
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3630	(SML "[]")
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3631	(OCaml "[]")
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3632	(Haskell "[]")
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3633
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3634	code_instance list :: eq
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3635	(Haskell -)
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3636
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3637	code_const "eq_class.eq \<Colon> 'a\<Colon>eq list \<Rightarrow> 'a list \<Rightarrow> bool"
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3638	(Haskell infixl 4 "==")
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3639
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3640	code_reserved SML
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3641	list
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3642
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3643	code_reserved OCaml
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3644	list
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3645
16770 1f1b1fae30e4 Auxiliary functions to be used in generated code are now defined using "attach". berghofe parents: 16634 diff changeset	3646	types_code
1f1b1fae30e4 Auxiliary functions to be used in generated code are now defined using "attach". berghofe parents: 16634 diff changeset	3647	"list" ("_ list")
1f1b1fae30e4 Auxiliary functions to be used in generated code are now defined using "attach". berghofe parents: 16634 diff changeset	3648	attach (term_of) {*
21760 78248dda3a90 fixed term_of_list; wenzelm parents: 21754 diff changeset	3649	fun term_of_list f T = HOLogic.mk_list T o map f;
16770 1f1b1fae30e4 Auxiliary functions to be used in generated code are now defined using "attach". berghofe parents: 16634 diff changeset	3650	*}
1f1b1fae30e4 Auxiliary functions to be used in generated code are now defined using "attach". berghofe parents: 16634 diff changeset	3651	attach (test) {*
25885 6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3652	fun gen_list' aG aT i j = frequency
6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3653	[(i, fn () =>
6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3654	let
6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3655	val (x, t) = aG j;
6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3656	val (xs, ts) = gen_list' aG aT (i-1) j
6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3657	in (x :: xs, fn () => HOLogic.cons_const aT $ t () $ ts ()) end),
6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3658	(1, fn () => ([], fn () => HOLogic.nil_const aT))] ()
6fbc3f54f819 New interface for test data generators. berghofe parents: 25591 diff changeset	3659	and gen_list aG aT i = gen_list' aG aT i i;
16770 1f1b1fae30e4 Auxiliary functions to be used in generated code are now defined using "attach". berghofe parents: 16634 diff changeset	3660	*}
31048 ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3661
ac146fc38b51 refined HOL string theories and corresponding ML fragments haftmann parents: 31022 diff changeset	3662	consts_code Cons ("(_ ::/ _)")
20588 c847c56edf0c added operational equality haftmann parents: 20503 diff changeset	3663
20453 855f07fabd76 final syntax for some Isar code generator keywords haftmann parents: 20439 diff changeset	3664	setup {*
855f07fabd76 final syntax for some Isar code generator keywords haftmann parents: 20439 diff changeset	3665	let
31055 2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3666	fun list_codegen thy defs dep thyname b t gr =
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3667	let
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3668	val ts = HOLogic.dest_list t;
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3669	val (_, gr') = Codegen.invoke_tycodegen thy defs dep thyname false
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3670	(fastype_of t) gr;
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3671	val (ps, gr'') = fold_map
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3672	(Codegen.invoke_codegen thy defs dep thyname false) ts gr'
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3673	in SOME (Pretty.list "[" "]" ps, gr'') end handle TERM _ => NONE;
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3674	in
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3675	fold (List_Code.add_literal_list) ["SML", "OCaml", "Haskell"]
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3676	#> Codegen.add_codegen "list_codegen" list_codegen
2cf6efca6c71 proper structures for list and string code generation stuff haftmann parents: 31048 diff changeset	3677	end
20453 855f07fabd76 final syntax for some Isar code generator keywords haftmann parents: 20439 diff changeset	3678	*}
15064 4f3102b50197 - Moved code generator setup for lists from Main.thy to List.thy berghofe parents: 15045 diff changeset	3679
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3680
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3681	subsubsection {* Generation of efficient code *}
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3682
25221 5ded95dda5df append/member: more light-weight way to declare authentic syntax; wenzelm parents: 25215 diff changeset	3683	primrec
25559 f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	3684	member :: "'a \<Rightarrow> 'a list \<Rightarrow> bool" (infixl "mem" 55)
f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	3685	where
f14305fb698c authentic primrec haftmann parents: 25502 diff changeset	3686	"x mem [] \<longleftrightarrow> False"
28515 b26ba1b1dbda dropped superfluous if haftmann parents: 28370 diff changeset	3687	\| "x mem (y#ys) \<longleftrightarrow> x = y \<or> x mem ys"
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3688
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3689	primrec
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3690	null:: "'a list \<Rightarrow> bool"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3691	where
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3692	"null [] = True"
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3693	\| "null (x#xs) = False"
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3694
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3695	primrec
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3696	list_inter :: "'a list \<Rightarrow> 'a list \<Rightarrow> 'a list"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3697	where
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3698	"list_inter [] bs = []"
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3699	\| "list_inter (a#as) bs =
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3700	(if a \<in> set bs then a # list_inter as bs else list_inter as bs)"
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3701
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3702	primrec
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3703	list_all :: "('a \<Rightarrow> bool) \<Rightarrow> ('a list \<Rightarrow> bool)"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3704	where
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3705	"list_all P [] = True"
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3706	\| "list_all P (x#xs) = (P x \<and> list_all P xs)"
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3707
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3708	primrec
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3709	list_ex :: "('a \<Rightarrow> bool) \<Rightarrow> 'a list \<Rightarrow> bool"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3710	where
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3711	"list_ex P [] = False"
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3712	\| "list_ex P (x#xs) = (P x \<or> list_ex P xs)"
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3713
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3714	primrec
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3715	filtermap :: "('a \<Rightarrow> 'b option) \<Rightarrow> 'a list \<Rightarrow> 'b list"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3716	where
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3717	"filtermap f [] = []"
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3718	\| "filtermap f (x#xs) =
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3719	(case f x of None \<Rightarrow> filtermap f xs
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3720	\| Some y \<Rightarrow> y # filtermap f xs)"
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3721
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3722	primrec
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3723	map_filter :: "('a \<Rightarrow> 'b) \<Rightarrow> ('a \<Rightarrow> bool) \<Rightarrow> 'a list \<Rightarrow> 'b list"
57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3724	where
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3725	"map_filter f P [] = []"
26442 57fb6a8b099e restructuring; explicit case names for rule list_induct2 haftmann parents: 26300 diff changeset	3726	\| "map_filter f P (x#xs) =
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3727	(if P x then f x # map_filter f P xs else map_filter f P xs)"
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3728
28789 5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3729	primrec
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3730	length_unique :: "'a list \<Rightarrow> nat"
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3731	where
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3732	"length_unique [] = 0"
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3733	\| "length_unique (x#xs) =
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3734	(if x \<in> set xs then length_unique xs else Suc (length_unique xs))"
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3735
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3736	text {*
21754 6316163ae934 moved char/string syntax to Tools/string_syntax.ML; wenzelm parents: 21548 diff changeset	3737	Only use @{text mem} for generating executable code. Otherwise use
6316163ae934 moved char/string syntax to Tools/string_syntax.ML; wenzelm parents: 21548 diff changeset	3738	@{prop "x : set xs"} instead --- it is much easier to reason about.
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3739	The same is true for @{const list_all} and @{const list_ex}: write
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3740	@{text "\<forall>x\<in>set xs"} and @{text "\<exists>x\<in>set xs"} instead because the HOL
21754 6316163ae934 moved char/string syntax to Tools/string_syntax.ML; wenzelm parents: 21548 diff changeset	3741	quantifiers are aleady known to the automatic provers. In fact, the
6316163ae934 moved char/string syntax to Tools/string_syntax.ML; wenzelm parents: 21548 diff changeset	3742	declarations in the code subsection make sure that @{text "\<in>"},
6316163ae934 moved char/string syntax to Tools/string_syntax.ML; wenzelm parents: 21548 diff changeset	3743	@{text "\<forall>x\<in>set xs"} and @{text "\<exists>x\<in>set xs"} are implemented
6316163ae934 moved char/string syntax to Tools/string_syntax.ML; wenzelm parents: 21548 diff changeset	3744	efficiently.
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3745
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3746	Efficient emptyness check is implemented by @{const null}.
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3747
23060 0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3748	The functions @{const filtermap} and @{const map_filter} are just
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3749	there to generate efficient code. Do not use
21754 6316163ae934 moved char/string syntax to Tools/string_syntax.ML; wenzelm parents: 21548 diff changeset	3750	them for modelling and proving.
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3751	*}
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3752
23060 0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3753	lemma rev_foldl_cons [code]:
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3754	"rev xs = foldl (\<lambda>xs x. x # xs) [] xs"
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3755	proof (induct xs)
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3756	case Nil then show ?case by simp
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3757	next
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3758	case Cons
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3759	{
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3760	fix x xs ys
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3761	have "foldl (\<lambda>xs x. x # xs) ys xs @ [x]
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3762	= foldl (\<lambda>xs x. x # xs) (ys @ [x]) xs"
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3763	by (induct xs arbitrary: ys) auto
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3764	}
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3765	note aux = this
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3766	show ?case by (induct xs) (auto simp add: Cons aux)
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3767	qed
0c0b03d0ec7e improved code for rev haftmann parents: 23029 diff changeset	3768
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3769	lemma mem_iff [code_post]:
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3770	"x mem xs \<longleftrightarrow> x \<in> set xs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3771	by (induct xs) auto
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3772
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3773	lemmas in_set_code [code_unfold] = mem_iff [symmetric]
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3774
31154 f919b8e67413 preprocessing must consider eq haftmann parents: 31080 diff changeset	3775	lemma empty_null:
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3776	"xs = [] \<longleftrightarrow> null xs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3777	by (cases xs) simp_all
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3778
32069 6d28bbd33e2c prefer code_inline over code_unfold; use code_unfold_post where appropriate haftmann parents: 31998 diff changeset	3779	lemma [code_unfold]:
31154 f919b8e67413 preprocessing must consider eq haftmann parents: 31080 diff changeset	3780	"eq_class.eq xs [] \<longleftrightarrow> null xs"
f919b8e67413 preprocessing must consider eq haftmann parents: 31080 diff changeset	3781	by (simp add: eq empty_null)
f919b8e67413 preprocessing must consider eq haftmann parents: 31080 diff changeset	3782
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3783	lemmas null_empty [code_post] =
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3784	empty_null [symmetric]
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3785
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3786	lemma list_inter_conv:
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3787	"set (list_inter xs ys) = set xs \<inter> set ys"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3788	by (induct xs) auto
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3789
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3790	lemma list_all_iff [code_post]:
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3791	"list_all P xs \<longleftrightarrow> (\<forall>x \<in> set xs. P x)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3792	by (induct xs) auto
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3793
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3794	lemmas list_ball_code [code_unfold] = list_all_iff [symmetric]
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3795
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3796	lemma list_all_append [simp]:
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3797	"list_all P (xs @ ys) \<longleftrightarrow> (list_all P xs \<and> list_all P ys)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3798	by (induct xs) auto
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3799
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3800	lemma list_all_rev [simp]:
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3801	"list_all P (rev xs) \<longleftrightarrow> list_all P xs"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3802	by (simp add: list_all_iff)
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3803
22506 c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3804	lemma list_all_length:
c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3805	"list_all P xs \<longleftrightarrow> (\<forall>n < length xs. P (xs ! n))"
c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3806	unfolding list_all_iff by (auto intro: all_nth_imp_all_set)
c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3807
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3808	lemma list_ex_iff [code_post]:
22422 ee19cdb07528 stepping towards uniform lattice theory development in HOL haftmann parents: 22262 diff changeset	3809	"list_ex P xs \<longleftrightarrow> (\<exists>x \<in> set xs. P x)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3810	by (induct xs) simp_all
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3811
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3812	lemmas list_bex_code [code_unfold] =
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3813	list_ex_iff [symmetric]
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3814
22506 c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3815	lemma list_ex_length:
c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3816	"list_ex P xs \<longleftrightarrow> (\<exists>n < length xs. P (xs ! n))"
c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3817	unfolding list_ex_iff set_conv_nth by auto
c78f1d924bfe two further properties about lists haftmann parents: 22493 diff changeset	3818
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3819	lemma filtermap_conv:
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3820	"filtermap f xs = map (\<lambda>x. the (f x)) (filter (\<lambda>x. f x \<noteq> None) xs)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3821	by (induct xs) (simp_all split: option.split)
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3822
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3823	lemma map_filter_conv [simp]:
580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3824	"map_filter f P xs = map f (filter P xs)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3825	by (induct xs) auto
21061 580dfc999ef6 added normal post setup; cleaned up "execution" constants haftmann parents: 21046 diff changeset	3826
32069 6d28bbd33e2c prefer code_inline over code_unfold; use code_unfold_post where appropriate haftmann parents: 31998 diff changeset	3827	lemma length_remdups_length_unique [code_unfold]:
28789 5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3828	"length (remdups xs) = length_unique xs"
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3829	by (induct xs) simp_all
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3830
32681 adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	3831	declare INFI_def [code_unfold]
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	3832	declare SUPR_def [code_unfold]
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	3833
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	3834	declare set_map [symmetric, code_unfold]
adeac3cbb659 lemma relating fold1 and foldl; code_unfold rules for Inf_fin, Sup_fin, Min, Max, Inf, Sup haftmann parents: 32422 diff changeset	3835
28789 5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3836	hide (open) const length_unique
5a404273ea8f added length_unique operation for code generation haftmann parents: 28708 diff changeset	3837
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	3838
2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	3839	text {* Code for bounded quantification and summation over nats. *}
21891 b4e4ea3db161 added code lemmas for quantification over bounded nats haftmann parents: 21871 diff changeset	3840
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3841	lemma atMost_upto [code_unfold]:
28072 a45e8c872dc1 It appears that the code generator (Stefan's) needs some laws that appear superfluous: {..n} = set ... nipkow parents: 28068 diff changeset	3842	"{..n} = set [0..<Suc n]"
a45e8c872dc1 It appears that the code generator (Stefan's) needs some laws that appear superfluous: {..n} = set ... nipkow parents: 28068 diff changeset	3843	by auto
a45e8c872dc1 It appears that the code generator (Stefan's) needs some laws that appear superfluous: {..n} = set ... nipkow parents: 28068 diff changeset	3844
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3845	lemma atLeast_upt [code_unfold]:
28072 a45e8c872dc1 It appears that the code generator (Stefan's) needs some laws that appear superfluous: {..n} = set ... nipkow parents: 28068 diff changeset	3846	"{..<n} = set [0..<n]"
a45e8c872dc1 It appears that the code generator (Stefan's) needs some laws that appear superfluous: {..n} = set ... nipkow parents: 28068 diff changeset	3847	by auto
a45e8c872dc1 It appears that the code generator (Stefan's) needs some laws that appear superfluous: {..n} = set ... nipkow parents: 28068 diff changeset	3848
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3849	lemma greaterThanLessThan_upt [code_unfold]:
21891 b4e4ea3db161 added code lemmas for quantification over bounded nats haftmann parents: 21871 diff changeset	3850	"{n<..<m} = set [Suc n..<m]"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3851	by auto
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3852
32417 e87d9c78910c tuned code generation for lists nipkow parents: 32415 diff changeset	3853	lemmas atLeastLessThan_upt [code_unfold] = set_upt [symmetric]
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3854
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3855	lemma greaterThanAtMost_upt [code_unfold]:
24645 1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3856	"{n<..m} = set [Suc n..<Suc m]"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3857	by auto
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3858
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3859	lemma atLeastAtMost_upt [code_unfold]:
24645 1af302128da2 Generalized [_.._] from nat to linear orders nipkow parents: 24640 diff changeset	3860	"{n..m} = set [n..<Suc m]"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3861	by auto
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3862
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3863	lemma all_nat_less_eq [code_unfold]:
21891 b4e4ea3db161 added code lemmas for quantification over bounded nats haftmann parents: 21871 diff changeset	3864	"(\<forall>m<n\<Colon>nat. P m) \<longleftrightarrow> (\<forall>m \<in> {0..<n}. P m)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3865	by auto
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3866
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3867	lemma ex_nat_less_eq [code_unfold]:
21891 b4e4ea3db161 added code lemmas for quantification over bounded nats haftmann parents: 21871 diff changeset	3868	"(\<exists>m<n\<Colon>nat. P m) \<longleftrightarrow> (\<exists>m \<in> {0..<n}. P m)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3869	by auto
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3870
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3871	lemma all_nat_less [code_unfold]:
21891 b4e4ea3db161 added code lemmas for quantification over bounded nats haftmann parents: 21871 diff changeset	3872	"(\<forall>m\<le>n\<Colon>nat. P m) \<longleftrightarrow> (\<forall>m \<in> {0..n}. P m)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3873	by auto
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3874
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3875	lemma ex_nat_less [code_unfold]:
21891 b4e4ea3db161 added code lemmas for quantification over bounded nats haftmann parents: 21871 diff changeset	3876	"(\<exists>m\<le>n\<Colon>nat. P m) \<longleftrightarrow> (\<exists>m \<in> {0..n}. P m)"
24349 0dd8782fb02d Final mods for list comprehension nipkow parents: 24335 diff changeset	3877	by auto
22799 ed7d53db2170 moved code generation pretty integers and characters to separate theories haftmann parents: 22793 diff changeset	3878
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3879	lemma setsum_set_distinct_conv_listsum:
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3880	"distinct xs \<Longrightarrow> setsum f (set xs) = listsum (map f xs)"
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3881	by (induct xs) simp_all
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3882
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3883	lemma setsum_set_upt_conv_listsum [code_unfold]:
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3884	"setsum f (set [m..<n]) = listsum (map f [m..<n])"
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3885	by (rule setsum_set_distinct_conv_listsum) simp
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3886
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3887
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3888	text {* Code for summation over ints. *}
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3889
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3890	lemma greaterThanLessThan_upto [code_unfold]:
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3891	"{i<..<j::int} = set [i+1..j - 1]"
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3892	by auto
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3893
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3894	lemma atLeastLessThan_upto [code_unfold]:
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3895	"{i..<j::int} = set [i..j - 1]"
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3896	by auto
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3897
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3898	lemma greaterThanAtMost_upto [code_unfold]:
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3899	"{i<..j::int} = set [i+1..j]"
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3900	by auto
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3901
32415 1dddf2f64266 got rid of complicated class finite_intvl_succ and defined "upto" directly on int, the only instance of the class. nipkow parents: 32078 diff changeset	3902	lemmas atLeastAtMost_upto [code_unfold] = set_upto[symmetric]
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3903
31998 2c7a24f74db9 code attributes use common underscore convention haftmann parents: 31930 diff changeset	3904	lemma setsum_set_upto_conv_listsum [code_unfold]:
27715 087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3905	"setsum f (set [i..j::int]) = listsum (map f [i..j])"
087db5aacac3 made setsum executable on int. nipkow parents: 27693 diff changeset	3906	by (rule setsum_set_distinct_conv_listsum) simp
24449 2f05cb7fed85 added (code) lemmas for setsum and foldl nipkow parents: 24349 diff changeset	3907
32422 46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3908
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3909	text {* Optimized code for @{text"\<forall>i\<in>{a..b::int}"} and @{text"\<forall>n:{a..<b::nat}"}
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3910	and similiarly for @{text"\<exists>"}. *}
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3911
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3912	function all_from_to_nat :: "(nat \<Rightarrow> bool) \<Rightarrow> nat \<Rightarrow> nat \<Rightarrow> bool" where
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3913	"all_from_to_nat P i j =
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3914	(if i < j then if P i then all_from_to_nat P (i+1) j else False
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3915	else True)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3916	by auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3917	termination
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3918	by (relation "measure(%(P,i,j). j - i)") auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3919
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3920	declare all_from_to_nat.simps[simp del]
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3921
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3922	lemma all_from_to_nat_iff_ball:
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3923	"all_from_to_nat P i j = (ALL n : {i ..< j}. P n)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3924	proof(induct P i j rule:all_from_to_nat.induct)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3925	case (1 P i j)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3926	let ?yes = "i < j & P i"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3927	show ?case
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3928	proof (cases)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3929	assume ?yes
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3930	hence "all_from_to_nat P i j = (P i & all_from_to_nat P (i+1) j)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3931	by(simp add: all_from_to_nat.simps)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3932	also have "... = (P i & (ALL n : {i+1 ..< j}. P n))" using `?yes` 1 by simp
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3933	also have "... = (ALL n : {i ..< j}. P n)" (is "?L = ?R")
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3934	proof
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3935	assume L: ?L
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3936	show ?R
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3937	proof clarify
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3938	fix n assume n: "n : {i..<j}"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3939	show "P n"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3940	proof cases
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3941	assume "n = i" thus "P n" using L by simp
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3942	next
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3943	assume "n ~= i"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3944	hence "i+1 <= n" using n by auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3945	thus "P n" using L n by simp
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3946	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3947	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3948	next
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3949	assume R: ?R thus ?L using `?yes` 1 by auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3950	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3951	finally show ?thesis .
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3952	next
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3953	assume "~?yes" thus ?thesis by(auto simp add: all_from_to_nat.simps)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3954	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3955	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3956
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3957
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3958	lemma list_all_iff_all_from_to_nat[code_unfold]:
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3959	"list_all P [i..<j] = all_from_to_nat P i j"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3960	by(simp add: all_from_to_nat_iff_ball list_all_iff)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3961
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3962	lemma list_ex_iff_not_all_from_to_not_nat[code_unfold]:
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3963	"list_ex P [i..<j] = (~all_from_to_nat (%x. ~P x) i j)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3964	by(simp add: all_from_to_nat_iff_ball list_ex_iff)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3965
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3966
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3967	function all_from_to_int :: "(int \<Rightarrow> bool) \<Rightarrow> int \<Rightarrow> int \<Rightarrow> bool" where
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3968	"all_from_to_int P i j =
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3969	(if i <= j then if P i then all_from_to_int P (i+1) j else False
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3970	else True)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3971	by auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3972	termination
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3973	by (relation "measure(%(P,i,j). nat(j - i + 1))") auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3974
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3975	declare all_from_to_int.simps[simp del]
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3976
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3977	lemma all_from_to_int_iff_ball:
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3978	"all_from_to_int P i j = (ALL n : {i .. j}. P n)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3979	proof(induct P i j rule:all_from_to_int.induct)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3980	case (1 P i j)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3981	let ?yes = "i <= j & P i"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3982	show ?case
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3983	proof (cases)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3984	assume ?yes
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3985	hence "all_from_to_int P i j = (P i & all_from_to_int P (i+1) j)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3986	by(simp add: all_from_to_int.simps)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3987	also have "... = (P i & (ALL n : {i+1 .. j}. P n))" using `?yes` 1 by simp
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3988	also have "... = (ALL n : {i .. j}. P n)" (is "?L = ?R")
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3989	proof
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3990	assume L: ?L
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3991	show ?R
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3992	proof clarify
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3993	fix n assume n: "n : {i..j}"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3994	show "P n"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3995	proof cases
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3996	assume "n = i" thus "P n" using L by simp
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3997	next
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3998	assume "n ~= i"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	3999	hence "i+1 <= n" using n by auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4000	thus "P n" using L n by simp
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4001	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4002	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4003	next
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4004	assume R: ?R thus ?L using `?yes` 1 by auto
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4005	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4006	finally show ?thesis .
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4007	next
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4008	assume "~?yes" thus ?thesis by(auto simp add: all_from_to_int.simps)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4009	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4010	qed
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4011
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4012	lemma list_all_iff_all_from_to_int[code_unfold]:
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4013	"list_all P [i..j] = all_from_to_int P i j"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4014	by(simp add: all_from_to_int_iff_ball list_all_iff)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4015
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4016	lemma list_ex_iff_not_all_from_to_not_int[code_unfold]:
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4017	"list_ex P [i..j] = (~ all_from_to_int (%x. ~P x) i j)"
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4018	by(simp add: all_from_to_int_iff_ball list_ex_iff)
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4019
46fc4d4ff4c0 code generator: quantifiers over {_.._::int} and {_..<_::nat} nipkow parents: 32417 diff changeset	4020
23388 77645da0db85 tuned proofs: avoid implicit prems; wenzelm parents: 23279 diff changeset	4021	end

author	haftmann
	Thu, 24 Sep 2009 18:29:29 +0200
changeset 32681	adeac3cbb659
parent 32422	46fc4d4ff4c0
child 32960	69916a850301
permissions	-rw-r--r--