(* Title: HOL/Basic_BNFs.thy
Author: Dmitriy Traytel, TU Muenchen
Author: Andrei Popescu, TU Muenchen
Author: Jasmin Blanchette, TU Muenchen
Copyright 2012
Registration of basic types as bounded natural functors.
*)
section \<open>Registration of Basic Types as Bounded Natural Functors\<close>
theory Basic_BNFs
imports BNF_Def
begin
inductive_set setl :: "'a + 'b \<Rightarrow> 'a set" for s :: "'a + 'b" where
"s = Inl x \<Longrightarrow> x \<in> setl s"
inductive_set setr :: "'a + 'b \<Rightarrow> 'b set" for s :: "'a + 'b" where
"s = Inr x \<Longrightarrow> x \<in> setr s"
lemma sum_set_defs[code]:
"setl = (\<lambda>x. case x of Inl z => {z} | _ => {})"
"setr = (\<lambda>x. case x of Inr z => {z} | _ => {})"
by (auto simp: fun_eq_iff intro: setl.intros setr.intros elim: setl.cases setr.cases split: sum.splits)
lemma rel_sum_simps[code, simp]:
"rel_sum R1 R2 (Inl a1) (Inl b1) = R1 a1 b1"
"rel_sum R1 R2 (Inl a1) (Inr b2) = False"
"rel_sum R1 R2 (Inr a2) (Inl b1) = False"
"rel_sum R1 R2 (Inr a2) (Inr b2) = R2 a2 b2"
by (auto intro: rel_sum.intros elim: rel_sum.cases)
inductive
pred_sum :: "('a \<Rightarrow> bool) \<Rightarrow> ('b \<Rightarrow> bool) \<Rightarrow> 'a + 'b \<Rightarrow> bool" for P1 P2
where
"P1 a \<Longrightarrow> pred_sum P1 P2 (Inl a)"
| "P2 b \<Longrightarrow> pred_sum P1 P2 (Inr b)"
lemma pred_sum_inject[code, simp]:
"pred_sum P1 P2 (Inl a) \<longleftrightarrow> P1 a"
"pred_sum P1 P2 (Inr b) \<longleftrightarrow> P2 b"
by (simp add: pred_sum.simps)+
bnf "'a + 'b"
map: map_sum
sets: setl setr
bd: natLeq
wits: Inl Inr
rel: rel_sum
pred: pred_sum
proof -
show "map_sum id id = id" by (rule map_sum.id)
next
fix f1 :: "'o \<Rightarrow> 's" and f2 :: "'p \<Rightarrow> 't" and g1 :: "'s \<Rightarrow> 'q" and g2 :: "'t \<Rightarrow> 'r"
show "map_sum (g1 o f1) (g2 o f2) = map_sum g1 g2 o map_sum f1 f2"
by (rule map_sum.comp[symmetric])
next
fix x and f1 :: "'o \<Rightarrow> 'q" and f2 :: "'p \<Rightarrow> 'r" and g1 g2
assume a1: "\<And>z. z \<in> setl x \<Longrightarrow> f1 z = g1 z" and
a2: "\<And>z. z \<in> setr x \<Longrightarrow> f2 z = g2 z"
thus "map_sum f1 f2 x = map_sum g1 g2 x"
proof (cases x)
case Inl thus ?thesis using a1 by (clarsimp simp: sum_set_defs(1))
next
case Inr thus ?thesis using a2 by (clarsimp simp: sum_set_defs(2))
qed
next
fix f1 :: "'o \<Rightarrow> 'q" and f2 :: "'p \<Rightarrow> 'r"
show "setl o map_sum f1 f2 = image f1 o setl"
by (rule ext, unfold o_apply) (simp add: sum_set_defs(1) split: sum.split)
next
fix f1 :: "'o \<Rightarrow> 'q" and f2 :: "'p \<Rightarrow> 'r"
show "setr o map_sum f1 f2 = image f2 o setr"
by (rule ext, unfold o_apply) (simp add: sum_set_defs(2) split: sum.split)
next
show "card_order natLeq" by (rule natLeq_card_order)
next
show "cinfinite natLeq" by (rule natLeq_cinfinite)
next
fix x :: "'o + 'p"
show "|setl x| \<le>o natLeq"
apply (rule ordLess_imp_ordLeq)
apply (rule finite_iff_ordLess_natLeq[THEN iffD1])
by (simp add: sum_set_defs(1) split: sum.split)
next
fix x :: "'o + 'p"
show "|setr x| \<le>o natLeq"
apply (rule ordLess_imp_ordLeq)
apply (rule finite_iff_ordLess_natLeq[THEN iffD1])
by (simp add: sum_set_defs(2) split: sum.split)
next
fix R1 R2 S1 S2
show "rel_sum R1 R2 OO rel_sum S1 S2 \<le> rel_sum (R1 OO S1) (R2 OO S2)"
by (force elim: rel_sum.cases)
next
fix R S
show "rel_sum R S = (\<lambda>x y.
\<exists>z. (setl z \<subseteq> {(x, y). R x y} \<and> setr z \<subseteq> {(x, y). S x y}) \<and>
map_sum fst fst z = x \<and> map_sum snd snd z = y)"
unfolding sum_set_defs relcompp.simps conversep.simps fun_eq_iff
by (fastforce elim: rel_sum.cases split: sum.splits)
qed (auto simp: sum_set_defs fun_eq_iff pred_sum.simps split: sum.splits)
inductive_set fsts :: "'a \<times> 'b \<Rightarrow> 'a set" for p :: "'a \<times> 'b" where
"fst p \<in> fsts p"
inductive_set snds :: "'a \<times> 'b \<Rightarrow> 'b set" for p :: "'a \<times> 'b" where
"snd p \<in> snds p"
lemma prod_set_defs[code]: "fsts = (\<lambda>p. {fst p})" "snds = (\<lambda>p. {snd p})"
by (auto intro: fsts.intros snds.intros elim: fsts.cases snds.cases)
inductive
rel_prod :: "('a \<Rightarrow> 'b \<Rightarrow> bool) \<Rightarrow> ('c \<Rightarrow> 'd \<Rightarrow> bool) \<Rightarrow> 'a \<times> 'c \<Rightarrow> 'b \<times> 'd \<Rightarrow> bool" for R1 R2
where
"\<lbrakk>R1 a b; R2 c d\<rbrakk> \<Longrightarrow> rel_prod R1 R2 (a, c) (b, d)"
inductive
pred_prod :: "('a \<Rightarrow> bool) \<Rightarrow> ('b \<Rightarrow> bool) \<Rightarrow> 'a \<times> 'b \<Rightarrow> bool" for P1 P2
where
"\<lbrakk>P1 a; P2 b\<rbrakk> \<Longrightarrow> pred_prod P1 P2 (a, b)"
lemma rel_prod_inject [code, simp]:
"rel_prod R1 R2 (a, b) (c, d) \<longleftrightarrow> R1 a c \<and> R2 b d"
by (auto intro: rel_prod.intros elim: rel_prod.cases)
lemma pred_prod_inject [code, simp]:
"pred_prod P1 P2 (a, b) \<longleftrightarrow> P1 a \<and> P2 b"
by (auto intro: pred_prod.intros elim: pred_prod.cases)
lemma rel_prod_conv:
"rel_prod R1 R2 = (\<lambda>(a, b) (c, d). R1 a c \<and> R2 b d)"
by (rule ext, rule ext) auto
definition
pred_fun :: "('a \<Rightarrow> bool) \<Rightarrow> ('b \<Rightarrow> bool) \<Rightarrow> ('a \<Rightarrow> 'b) \<Rightarrow> bool"
where
"pred_fun A B = (\<lambda>f. \<forall>x. A x \<longrightarrow> B (f x))"
lemma pred_funI: "(\<And>x. A x \<Longrightarrow> B (f x)) \<Longrightarrow> pred_fun A B f"
unfolding pred_fun_def by simp
bnf "'a \<times> 'b"
map: map_prod
sets: fsts snds
bd: natLeq
rel: rel_prod
pred: pred_prod
proof (unfold prod_set_defs)
show "map_prod id id = id" by (rule map_prod.id)
next
fix f1 f2 g1 g2
show "map_prod (g1 o f1) (g2 o f2) = map_prod g1 g2 o map_prod f1 f2"
by (rule map_prod.comp[symmetric])
next
fix x f1 f2 g1 g2
assume "\<And>z. z \<in> {fst x} \<Longrightarrow> f1 z = g1 z" "\<And>z. z \<in> {snd x} \<Longrightarrow> f2 z = g2 z"
thus "map_prod f1 f2 x = map_prod g1 g2 x" by (cases x) simp
next
fix f1 f2
show "(\<lambda>x. {fst x}) o map_prod f1 f2 = image f1 o (\<lambda>x. {fst x})"
by (rule ext, unfold o_apply) simp
next
fix f1 f2
show "(\<lambda>x. {snd x}) o map_prod f1 f2 = image f2 o (\<lambda>x. {snd x})"
by (rule ext, unfold o_apply) simp
next
show "card_order natLeq" by (rule natLeq_card_order)
next
show "cinfinite natLeq" by (rule natLeq_cinfinite)
next
fix x
show "|{fst x}| \<le>o natLeq"
by (rule ordLess_imp_ordLeq) (simp add: finite_iff_ordLess_natLeq[symmetric])
next
fix x
show "|{snd x}| \<le>o natLeq"
by (rule ordLess_imp_ordLeq) (simp add: finite_iff_ordLess_natLeq[symmetric])
next
fix R1 R2 S1 S2
show "rel_prod R1 R2 OO rel_prod S1 S2 \<le> rel_prod (R1 OO S1) (R2 OO S2)" by auto
next
fix R S
show "rel_prod R S = (\<lambda>x y.
\<exists>z. ({fst z} \<subseteq> {(x, y). R x y} \<and> {snd z} \<subseteq> {(x, y). S x y}) \<and>
map_prod fst fst z = x \<and> map_prod snd snd z = y)"
unfolding prod_set_defs rel_prod_inject relcompp.simps conversep.simps fun_eq_iff
by auto
qed auto
bnf "'a \<Rightarrow> 'b"
map: "op \<circ>"
sets: range
bd: "natLeq +c |UNIV :: 'a set|"
rel: "rel_fun op ="
pred: "pred_fun (\<lambda>_. True)"
proof
fix f show "id \<circ> f = id f" by simp
next
fix f g show "op \<circ> (g \<circ> f) = op \<circ> g \<circ> op \<circ> f"
unfolding comp_def[abs_def] ..
next
fix x f g
assume "\<And>z. z \<in> range x \<Longrightarrow> f z = g z"
thus "f \<circ> x = g \<circ> x" by auto
next
fix f show "range \<circ> op \<circ> f = op ` f \<circ> range"
by (auto simp add: fun_eq_iff)
next
show "card_order (natLeq +c |UNIV| )" (is "_ (_ +c ?U)")
apply (rule card_order_csum)
apply (rule natLeq_card_order)
by (rule card_of_card_order_on)
(* *)
show "cinfinite (natLeq +c ?U)"
apply (rule cinfinite_csum)
apply (rule disjI1)
by (rule natLeq_cinfinite)
next
fix f :: "'d => 'a"
have "|range f| \<le>o | (UNIV::'d set) |" (is "_ \<le>o ?U") by (rule card_of_image)
also have "?U \<le>o natLeq +c ?U" by (rule ordLeq_csum2) (rule card_of_Card_order)
finally show "|range f| \<le>o natLeq +c ?U" .
next
fix R S
show "rel_fun op = R OO rel_fun op = S \<le> rel_fun op = (R OO S)" by (auto simp: rel_fun_def)
next
fix R
show "rel_fun op = R = (\<lambda>x y.
\<exists>z. range z \<subseteq> {(x, y). R x y} \<and> fst \<circ> z = x \<and> snd \<circ> z = y)"
unfolding rel_fun_def subset_iff by (force simp: fun_eq_iff[symmetric])
qed (auto simp: pred_fun_def)
end