| author | blanchet |
| Fri, 05 Sep 2014 00:41:01 +0200 | |
| changeset 58187 | d2ddd401d74d |
| parent 46953 | 2b6e55924af3 |
| child 58871 | c399ae4b836f |
| permissions | -rw-r--r-- |
| 1478 | 1 |
(* Title: ZF/Finite.thy |
2 |
Author: Lawrence C Paulson, Cambridge University Computer Laboratory |
|
| 516 | 3 |
Copyright 1994 University of Cambridge |
4 |
||
| 46953 | 5 |
prove: b \<in> Fin(A) ==> inj(b,b) \<subseteq> surj(b,b) |
| 516 | 6 |
*) |
7 |
||
| 13328 | 8 |
header{*Finite Powerset Operator and Finite Function Space*}
|
9 |
||
|
26056
6a0801279f4c
Made theory names in ZF disjoint from HOL theory names to allow loading both developments
krauss
parents:
24893
diff
changeset
|
10 |
theory Finite imports Inductive_ZF Epsilon Nat_ZF begin |
|
9491
1a36151ee2fc
natify, a coercion to reduce the number of type constraints in arithmetic
paulson
parents:
6053
diff
changeset
|
11 |
|
|
1a36151ee2fc
natify, a coercion to reduce the number of type constraints in arithmetic
paulson
parents:
6053
diff
changeset
|
12 |
(*The natural numbers as a datatype*) |
| 13194 | 13 |
rep_datatype |
14 |
elimination natE |
|
|
32960
69916a850301
eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents:
26056
diff
changeset
|
15 |
induction nat_induct |
|
69916a850301
eliminated hard tabulators, guessing at each author's individual tab-width;
wenzelm
parents:
26056
diff
changeset
|
16 |
case_eqns nat_case_0 nat_case_succ |
| 13194 | 17 |
recursor_eqns recursor_0 recursor_succ |
|
9491
1a36151ee2fc
natify, a coercion to reduce the number of type constraints in arithmetic
paulson
parents:
6053
diff
changeset
|
18 |
|
|
1a36151ee2fc
natify, a coercion to reduce the number of type constraints in arithmetic
paulson
parents:
6053
diff
changeset
|
19 |
|
| 534 | 20 |
consts |
| 13194 | 21 |
Fin :: "i=>i" |
22 |
FiniteFun :: "[i,i]=>i" ("(_ -||>/ _)" [61, 60] 60)
|
|
| 534 | 23 |
|
| 516 | 24 |
inductive |
| 46820 | 25 |
domains "Fin(A)" \<subseteq> "Pow(A)" |
| 13194 | 26 |
intros |
| 46820 | 27 |
emptyI: "0 \<in> Fin(A)" |
| 46953 | 28 |
consI: "[| a \<in> A; b \<in> Fin(A) |] ==> cons(a,b) \<in> Fin(A)" |
| 13194 | 29 |
type_intros empty_subsetI cons_subsetI PowI |
| 46471 | 30 |
type_elims PowD [elim_format] |
| 534 | 31 |
|
32 |
inductive |
|
| 46820 | 33 |
domains "FiniteFun(A,B)" \<subseteq> "Fin(A*B)" |
| 13194 | 34 |
intros |
| 46820 | 35 |
emptyI: "0 \<in> A -||> B" |
| 46953 | 36 |
consI: "[| a \<in> A; b \<in> B; h \<in> A -||> B; a \<notin> domain(h) |] |
| 46820 | 37 |
==> cons(<a,b>,h) \<in> A -||> B" |
| 13194 | 38 |
type_intros Fin.intros |
39 |
||
40 |
||
| 13356 | 41 |
subsection {* Finite Powerset Operator *}
|
| 13194 | 42 |
|
| 46820 | 43 |
lemma Fin_mono: "A<=B ==> Fin(A) \<subseteq> Fin(B)" |
| 13194 | 44 |
apply (unfold Fin.defs) |
45 |
apply (rule lfp_mono) |
|
46 |
apply (rule Fin.bnd_mono)+ |
|
47 |
apply blast |
|
48 |
done |
|
49 |
||
| 46820 | 50 |
(* @{term"A \<in> Fin(B) ==> A \<subseteq> B"} *)
|
| 45602 | 51 |
lemmas FinD = Fin.dom_subset [THEN subsetD, THEN PowD] |
| 13194 | 52 |
|
53 |
(** Induction on finite sets **) |
|
54 |
||
| 46820 | 55 |
(*Discharging @{term"x\<notin>y"} entails extra work*)
|
| 13524 | 56 |
lemma Fin_induct [case_names 0 cons, induct set: Fin]: |
| 46953 | 57 |
"[| b \<in> Fin(A); |
| 13194 | 58 |
P(0); |
| 46953 | 59 |
!!x y. [| x \<in> A; y \<in> Fin(A); x\<notin>y; P(y) |] ==> P(cons(x,y)) |
| 13194 | 60 |
|] ==> P(b)" |
61 |
apply (erule Fin.induct, simp) |
|
| 46953 | 62 |
apply (case_tac "a \<in> b") |
| 13194 | 63 |
apply (erule cons_absorb [THEN ssubst], assumption) (*backtracking!*) |
64 |
apply simp |
|
65 |
done |
|
66 |
||
|
13203
fac77a839aa2
Tidying up. Mainly moving proofs from Main.thy to other (Isar) theory files.
paulson
parents:
13194
diff
changeset
|
67 |
|
| 13194 | 68 |
(** Simplification for Fin **) |
69 |
declare Fin.intros [simp] |
|
70 |
||
|
13203
fac77a839aa2
Tidying up. Mainly moving proofs from Main.thy to other (Isar) theory files.
paulson
parents:
13194
diff
changeset
|
71 |
lemma Fin_0: "Fin(0) = {0}"
|
|
fac77a839aa2
Tidying up. Mainly moving proofs from Main.thy to other (Isar) theory files.
paulson
parents:
13194
diff
changeset
|
72 |
by (blast intro: Fin.emptyI dest: FinD) |
|
fac77a839aa2
Tidying up. Mainly moving proofs from Main.thy to other (Isar) theory files.
paulson
parents:
13194
diff
changeset
|
73 |
|
| 13194 | 74 |
(*The union of two finite sets is finite.*) |
| 46953 | 75 |
lemma Fin_UnI [simp]: "[| b \<in> Fin(A); c \<in> Fin(A) |] ==> b \<union> c \<in> Fin(A)" |
| 13194 | 76 |
apply (erule Fin_induct) |
77 |
apply (simp_all add: Un_cons) |
|
78 |
done |
|
79 |
||
80 |
||
81 |
(*The union of a set of finite sets is finite.*) |
|
| 46820 | 82 |
lemma Fin_UnionI: "C \<in> Fin(Fin(A)) ==> \<Union>(C) \<in> Fin(A)" |
| 13194 | 83 |
by (erule Fin_induct, simp_all) |
84 |
||
85 |
(*Every subset of a finite set is finite.*) |
|
| 46953 | 86 |
lemma Fin_subset_lemma [rule_format]: "b \<in> Fin(A) ==> \<forall>z. z<=b \<longrightarrow> z \<in> Fin(A)" |
| 13194 | 87 |
apply (erule Fin_induct) |
88 |
apply (simp add: subset_empty_iff) |
|
89 |
apply (simp add: subset_cons_iff distrib_simps, safe) |
|
| 13784 | 90 |
apply (erule_tac b = z in cons_Diff [THEN subst], simp) |
| 13194 | 91 |
done |
92 |
||
| 46953 | 93 |
lemma Fin_subset: "[| c<=b; b \<in> Fin(A) |] ==> c \<in> Fin(A)" |
| 13194 | 94 |
by (blast intro: Fin_subset_lemma) |
95 |
||
| 46953 | 96 |
lemma Fin_IntI1 [intro,simp]: "b \<in> Fin(A) ==> b \<inter> c \<in> Fin(A)" |
| 13194 | 97 |
by (blast intro: Fin_subset) |
98 |
||
| 46953 | 99 |
lemma Fin_IntI2 [intro,simp]: "c \<in> Fin(A) ==> b \<inter> c \<in> Fin(A)" |
| 13194 | 100 |
by (blast intro: Fin_subset) |
101 |
||
102 |
lemma Fin_0_induct_lemma [rule_format]: |
|
| 46953 | 103 |
"[| c \<in> Fin(A); b \<in> Fin(A); P(b); |
104 |
!!x y. [| x \<in> A; y \<in> Fin(A); x \<in> y; P(y) |] ==> P(y-{x})
|
|
| 46820 | 105 |
|] ==> c<=b \<longrightarrow> P(b-c)" |
| 13194 | 106 |
apply (erule Fin_induct, simp) |
107 |
apply (subst Diff_cons) |
|
108 |
apply (simp add: cons_subset_iff Diff_subset [THEN Fin_subset]) |
|
109 |
done |
|
110 |
||
111 |
lemma Fin_0_induct: |
|
| 46953 | 112 |
"[| b \<in> Fin(A); |
| 13194 | 113 |
P(b); |
| 46953 | 114 |
!!x y. [| x \<in> A; y \<in> Fin(A); x \<in> y; P(y) |] ==> P(y-{x})
|
| 13194 | 115 |
|] ==> P(0)" |
116 |
apply (rule Diff_cancel [THEN subst]) |
|
| 46820 | 117 |
apply (blast intro: Fin_0_induct_lemma) |
| 13194 | 118 |
done |
119 |
||
120 |
(*Functions from a finite ordinal*) |
|
| 46953 | 121 |
lemma nat_fun_subset_Fin: "n \<in> nat ==> n->A \<subseteq> Fin(nat*A)" |
| 13194 | 122 |
apply (induct_tac "n") |
123 |
apply (simp add: subset_iff) |
|
124 |
apply (simp add: succ_def mem_not_refl [THEN cons_fun_eq]) |
|
125 |
apply (fast intro!: Fin.consI) |
|
126 |
done |
|
127 |
||
128 |
||
| 13356 | 129 |
subsection{*Finite Function Space*}
|
| 13194 | 130 |
|
131 |
lemma FiniteFun_mono: |
|
| 46820 | 132 |
"[| A<=C; B<=D |] ==> A -||> B \<subseteq> C -||> D" |
| 13194 | 133 |
apply (unfold FiniteFun.defs) |
134 |
apply (rule lfp_mono) |
|
135 |
apply (rule FiniteFun.bnd_mono)+ |
|
136 |
apply (intro Fin_mono Sigma_mono basic_monos, assumption+) |
|
137 |
done |
|
138 |
||
| 46820 | 139 |
lemma FiniteFun_mono1: "A<=B ==> A -||> A \<subseteq> B -||> B" |
| 13194 | 140 |
by (blast dest: FiniteFun_mono) |
141 |
||
| 46953 | 142 |
lemma FiniteFun_is_fun: "h \<in> A -||>B ==> h \<in> domain(h) -> B" |
| 13194 | 143 |
apply (erule FiniteFun.induct, simp) |
144 |
apply (simp add: fun_extend3) |
|
145 |
done |
|
146 |
||
| 46953 | 147 |
lemma FiniteFun_domain_Fin: "h \<in> A -||>B ==> domain(h) \<in> Fin(A)" |
| 13269 | 148 |
by (erule FiniteFun.induct, simp, simp) |
| 13194 | 149 |
|
| 45602 | 150 |
lemmas FiniteFun_apply_type = FiniteFun_is_fun [THEN apply_type] |
| 13194 | 151 |
|
152 |
(*Every subset of a finite function is a finite function.*) |
|
153 |
lemma FiniteFun_subset_lemma [rule_format]: |
|
| 46953 | 154 |
"b \<in> A-||>B ==> \<forall>z. z<=b \<longrightarrow> z \<in> A-||>B" |
| 13194 | 155 |
apply (erule FiniteFun.induct) |
156 |
apply (simp add: subset_empty_iff FiniteFun.intros) |
|
157 |
apply (simp add: subset_cons_iff distrib_simps, safe) |
|
| 13784 | 158 |
apply (erule_tac b = z in cons_Diff [THEN subst]) |
| 13194 | 159 |
apply (drule spec [THEN mp], assumption) |
160 |
apply (fast intro!: FiniteFun.intros) |
|
161 |
done |
|
162 |
||
| 46953 | 163 |
lemma FiniteFun_subset: "[| c<=b; b \<in> A-||>B |] ==> c \<in> A-||>B" |
| 13194 | 164 |
by (blast intro: FiniteFun_subset_lemma) |
165 |
||
166 |
(** Some further results by Sidi O. Ehmety **) |
|
167 |
||
| 46953 | 168 |
lemma fun_FiniteFunI [rule_format]: "A \<in> Fin(X) ==> \<forall>f. f \<in> A->B \<longrightarrow> f \<in> A-||>B" |
| 13194 | 169 |
apply (erule Fin.induct) |
| 13269 | 170 |
apply (simp add: FiniteFun.intros, clarify) |
| 46953 | 171 |
apply (case_tac "a \<in> b") |
| 13194 | 172 |
apply (simp add: cons_absorb) |
| 46820 | 173 |
apply (subgoal_tac "restrict (f,b) \<in> b -||> B") |
| 13194 | 174 |
prefer 2 apply (blast intro: restrict_type2) |
175 |
apply (subst fun_cons_restrict_eq, assumption) |
|
176 |
apply (simp add: restrict_def lam_def) |
|
| 46820 | 177 |
apply (blast intro: apply_funtype FiniteFun.intros |
| 13194 | 178 |
FiniteFun_mono [THEN [2] rev_subsetD]) |
179 |
done |
|
180 |
||
| 46953 | 181 |
lemma lam_FiniteFun: "A \<in> Fin(X) ==> (\<lambda>x\<in>A. b(x)) \<in> A -||> {b(x). x \<in> A}"
|
| 13194 | 182 |
by (blast intro: fun_FiniteFunI lam_funtype) |
183 |
||
184 |
lemma FiniteFun_Collect_iff: |
|
| 46953 | 185 |
"f \<in> FiniteFun(A, {y \<in> B. P(y)})
|
|
46821
ff6b0c1087f2
Using mathematical notation for <-> and cardinal arithmetic
paulson
parents:
46820
diff
changeset
|
186 |
\<longleftrightarrow> f \<in> FiniteFun(A,B) & (\<forall>x\<in>domain(f). P(f`x))" |
| 13194 | 187 |
apply auto |
188 |
apply (blast intro: FiniteFun_mono [THEN [2] rev_subsetD]) |
|
189 |
apply (blast dest: Pair_mem_PiD FiniteFun_is_fun) |
|
| 46820 | 190 |
apply (rule_tac A1="domain(f)" in |
| 13194 | 191 |
subset_refl [THEN [2] FiniteFun_mono, THEN subsetD]) |
192 |
apply (fast dest: FiniteFun_domain_Fin Fin.dom_subset [THEN subsetD]) |
|
193 |
apply (rule fun_FiniteFunI) |
|
194 |
apply (erule FiniteFun_domain_Fin) |
|
195 |
apply (rule_tac B = "range (f) " in fun_weaken_type) |
|
196 |
apply (blast dest: FiniteFun_is_fun range_of_fun range_type apply_equality)+ |
|
197 |
done |
|
198 |
||
| 14883 | 199 |
|
200 |
subsection{*The Contents of a Singleton Set*}
|
|
201 |
||
| 24893 | 202 |
definition |
203 |
contents :: "i=>i" where |
|
| 14883 | 204 |
"contents(X) == THE x. X = {x}"
|
205 |
||
206 |
lemma contents_eq [simp]: "contents ({x}) = x"
|
|
207 |
by (simp add: contents_def) |
|
208 |
||
| 516 | 209 |
end |