isabelle: src/HOL/ex/Abstract_NAT.thy@bdc2c6b40bf2 (annotated)

44603 a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	1	(* Title: HOL/ex/Abstract_NAT.thy
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	2	Author: Makarius
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	3	*)
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	4
23253 b1f3f53c60b5 tuned comments; wenzelm parents: 21404 diff changeset	5	header {* Abstract Natural Numbers primitive recursion *}
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	6
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	7	theory Abstract_NAT
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	8	imports Main
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	9	begin
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	10
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	11	text {* Axiomatic Natural Numbers (Peano) -- a monomorphic theory. *}
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	12
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	13	locale NAT =
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	14	fixes zero :: 'n
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	15	and succ :: "'n \<Rightarrow> 'n"
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	16	assumes succ_inject [simp]: "(succ m = succ n) = (m = n)"
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	17	and succ_neq_zero [simp]: "succ m \<noteq> zero"
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	18	and induct [case_names zero succ, induct type: 'n]:
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	19	"P zero \<Longrightarrow> (\<And>n. P n \<Longrightarrow> P (succ n)) \<Longrightarrow> P n"
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	20	begin
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	21
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	22	lemma zero_neq_succ [simp]: "zero \<noteq> succ m"
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	23	by (rule succ_neq_zero [symmetric])
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	24
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	25
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	26	text {* \medskip Primitive recursion as a (functional) relation -- polymorphic! *}
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	27
44603 a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	28	inductive Rec :: "'a \<Rightarrow> ('n \<Rightarrow> 'a \<Rightarrow> 'a) \<Rightarrow> 'n \<Rightarrow> 'a \<Rightarrow> bool"
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	29	for e :: 'a and r :: "'n \<Rightarrow> 'a \<Rightarrow> 'a"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	30	where
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	31	Rec_zero: "Rec e r zero e"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	32	\| Rec_succ: "Rec e r m n \<Longrightarrow> Rec e r (succ m) (r m n)"
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	33
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	34	lemma Rec_functional:
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	35	fixes x :: 'n
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	36	shows "\<exists>!y::'a. Rec e r x y"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	37	proof -
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	38	let ?R = "Rec e r"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	39	show ?thesis
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	40	proof (induct x)
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	41	case zero
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	42	show "\<exists>!y. ?R zero y"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	43	proof
21392 e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	44	show "?R zero e" ..
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	45	fix y assume "?R zero y"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	46	then show "y = e" by cases simp_all
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	47	qed
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	48	next
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	49	case (succ m)
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	50	from `\<exists>!y. ?R m y`
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	51	obtain y where y: "?R m y"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	52	and yy': "\<And>y'. ?R m y' \<Longrightarrow> y = y'" by blast
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	53	show "\<exists>!z. ?R (succ m) z"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	54	proof
21392 e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	55	from y show "?R (succ m) (r m y)" ..
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	56	fix z assume "?R (succ m) z"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	57	then obtain u where "z = r m u" and "?R m u" by cases simp_all
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	58	with yy' show "z = r m y" by (simp only:)
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	59	qed
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	60	qed
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	61	qed
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	62
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	63
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	64	text {* \medskip The recursion operator -- polymorphic! *}
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	65
44603 a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	66	definition rec :: "'a \<Rightarrow> ('n \<Rightarrow> 'a \<Rightarrow> 'a) \<Rightarrow> 'n \<Rightarrow> 'a"
a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	67	where "rec e r x = (THE y. Rec e r x y)"
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	68
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	69	lemma rec_eval:
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	70	assumes Rec: "Rec e r x y"
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	71	shows "rec e r x = y"
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	72	unfolding rec_def
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	73	using Rec_functional and Rec by (rule the1_equality)
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	74
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	75	lemma rec_zero [simp]: "rec e r zero = e"
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	76	proof (rule rec_eval)
21392 e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	77	show "Rec e r zero e" ..
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	78	qed
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	79
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	80	lemma rec_succ [simp]: "rec e r (succ m) = r m (rec e r m)"
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	81	proof (rule rec_eval)
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	82	let ?R = "Rec e r"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	83	have "?R m (rec e r m)"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	84	unfolding rec_def using Rec_functional by (rule theI')
21392 e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	85	then show "?R (succ m) (r m (rec e r m))" ..
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	86	qed
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	87
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	88
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	89	text {* \medskip Example: addition (monomorphic) *}
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	90
44603 a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	91	definition add :: "'n \<Rightarrow> 'n \<Rightarrow> 'n"
a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	92	where "add m n = rec n (\<lambda>_ k. succ k) m"
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	93
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	94	lemma add_zero [simp]: "add zero n = n"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	95	and add_succ [simp]: "add (succ m) n = succ (add m n)"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	96	unfolding add_def by simp_all
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	97
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	98	lemma add_assoc: "add (add k m) n = add k (add m n)"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	99	by (induct k) simp_all
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	100
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	101	lemma add_zero_right: "add m zero = m"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	102	by (induct m) simp_all
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	103
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	104	lemma add_succ_right: "add m (succ n) = succ (add m n)"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	105	by (induct m) simp_all
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	106
21392 e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	107	lemma "add (succ (succ (succ zero))) (succ (succ zero)) =
e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	108	succ (succ (succ (succ (succ zero))))"
e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	109	by simp
e571e84cbe89 tuned proofs; wenzelm parents: 21368 diff changeset	110
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	111
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	112	text {* \medskip Example: replication (polymorphic) *}
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	113
44603 a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	114	definition repl :: "'n \<Rightarrow> 'a \<Rightarrow> 'a list"
a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	115	where "repl n x = rec [] (\<lambda>_ xs. x # xs) n"
21368 bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	116
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	117	lemma repl_zero [simp]: "repl zero x = []"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	118	and repl_succ [simp]: "repl (succ n) x = x # repl n x"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	119	unfolding repl_def by simp_all
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	120
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	121	lemma "repl (succ (succ (succ zero))) True = [True, True, True]"
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	122	by simp
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	123
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	124	end
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	125
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	126
bffb2240d03f converted to 'inductive2'; wenzelm parents: 20713 diff changeset	127	text {* \medskip Just see that our abstract specification makes sense \dots *}
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	128
29234 60f7fb56f8cd More porting to new locales. ballarin parents: 23775 diff changeset	129	interpretation NAT 0 Suc
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	130	proof (rule NAT.intro)
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	131	fix m n
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	132	show "(Suc m = Suc n) = (m = n)" by simp
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	133	show "Suc m \<noteq> 0" by simp
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	134	fix P
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	135	assume zero: "P 0"
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	136	and succ: "\<And>n. P n \<Longrightarrow> P (Suc n)"
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	137	show "P n"
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	138	proof (induct n)
44603 a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	139	case 0
a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	140	show ?case by (rule zero)
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	141	next
44603 a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	142	case Suc
a6f9a70d655d tuned document; wenzelm parents: 29234 diff changeset	143	then show ?case by (rule succ)
19087 8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	144	qed
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	145	qed
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	146
8d83af663714 Abstract Natural Numbers with polymorphic recursion. wenzelm parents: diff changeset	147	end

author	haftmann
	Sat, 05 Jul 2014 11:01:53 +0200
changeset 57514	bdc2c6b40bf2
parent 44603	a6f9a70d655d
child 58889	5b7a9633cfa8
permissions	-rw-r--r--