(* Title: HOL/Lambda/WeakNorm.thy
ID: $Id$
Author: Stefan Berghofer
Copyright 2003 TU Muenchen
*)
header {* Weak normalization for simply-typed lambda calculus *}
theory WeakNorm imports Type begin
text {*
Formalization by Stefan Berghofer. Partly based on a paper proof by
Felix Joachimski and Ralph Matthes \cite{Matthes-Joachimski-AML}.
*}
subsection {* Terms in normal form *}
definition
listall :: "('a \<Rightarrow> bool) \<Rightarrow> 'a list \<Rightarrow> bool"
"listall P xs == (\<forall>i. i < length xs \<longrightarrow> P (xs ! i))"
declare listall_def [extraction_expand]
theorem listall_nil: "listall P []"
by (simp add: listall_def)
theorem listall_nil_eq [simp]: "listall P [] = True"
by (iprover intro: listall_nil)
theorem listall_cons: "P x \<Longrightarrow> listall P xs \<Longrightarrow> listall P (x # xs)"
apply (simp add: listall_def)
apply (rule allI impI)+
apply (case_tac i)
apply simp+
done
theorem listall_cons_eq [simp]: "listall P (x # xs) = (P x \<and> listall P xs)"
apply (rule iffI)
prefer 2
apply (erule conjE)
apply (erule listall_cons)
apply assumption
apply (unfold listall_def)
apply (rule conjI)
apply (erule_tac x=0 in allE)
apply simp
apply simp
apply (rule allI)
apply (erule_tac x="Suc i" in allE)
apply simp
done
lemma listall_conj1: "listall (\<lambda>x. P x \<and> Q x) xs \<Longrightarrow> listall P xs"
by (induct xs) simp_all
lemma listall_conj2: "listall (\<lambda>x. P x \<and> Q x) xs \<Longrightarrow> listall Q xs"
by (induct xs) simp_all
lemma listall_app: "listall P (xs @ ys) = (listall P xs \<and> listall P ys)"
apply (induct xs)
apply (rule iffI, simp, simp)
apply (rule iffI, simp, simp)
done
lemma listall_snoc [simp]: "listall P (xs @ [x]) = (listall P xs \<and> P x)"
apply (rule iffI)
apply (simp add: listall_app)+
done
lemma listall_cong [cong, extraction_expand]:
"xs = ys \<Longrightarrow> listall P xs = listall P ys"
-- {* Currently needed for strange technical reasons *}
by (unfold listall_def) simp
consts NF :: "dB set"
inductive NF
intros
App: "listall (\<lambda>t. t \<in> NF) ts \<Longrightarrow> Var x \<degree>\<degree> ts \<in> NF"
Abs: "t \<in> NF \<Longrightarrow> Abs t \<in> NF"
monos listall_def
lemma nat_eq_dec: "\<And>n::nat. m = n \<or> m \<noteq> n"
apply (induct m)
apply (case_tac n)
apply (case_tac [3] n)
apply (simp only: nat.simps, iprover?)+
done
lemma nat_le_dec: "\<And>n::nat. m < n \<or> \<not> (m < n)"
apply (induct m)
apply (case_tac n)
apply (case_tac [3] n)
apply (simp del: simp_thms, iprover?)+
done
lemma App_NF_D: assumes NF: "Var n \<degree>\<degree> ts \<in> NF"
shows "listall (\<lambda>t. t \<in> NF) ts" using NF
by cases simp_all
subsection {* Properties of @{text NF} *}
lemma Var_NF: "Var n \<in> NF"
apply (subgoal_tac "Var n \<degree>\<degree> [] \<in> NF")
apply simp
apply (rule NF.App)
apply simp
done
lemma subst_terms_NF: "listall (\<lambda>t. t \<in> NF) ts \<Longrightarrow>
listall (\<lambda>t. \<forall>i j. t[Var i/j] \<in> NF) ts \<Longrightarrow>
listall (\<lambda>t. t \<in> NF) (map (\<lambda>t. t[Var i/j]) ts)"
by (induct ts) simp_all
lemma subst_Var_NF: "t \<in> NF \<Longrightarrow> t[Var i/j] \<in> NF"
apply (induct fixing: i j set: NF)
apply simp
apply (frule listall_conj1)
apply (drule listall_conj2)
apply (drule_tac i=i and j=j in subst_terms_NF)
apply assumption
apply (rule_tac m=x and n=j in nat_eq_dec [THEN disjE, standard])
apply simp
apply (erule NF.App)
apply (rule_tac m=j and n=x in nat_le_dec [THEN disjE, standard])
apply simp
apply (iprover intro: NF.App)
apply simp
apply (iprover intro: NF.App)
apply simp
apply (iprover intro: NF.Abs)
done
lemma app_Var_NF: "t \<in> NF \<Longrightarrow> \<exists>t'. t \<degree> Var i \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF"
apply (induct set: NF)
apply (simplesubst app_last) --{*Using @{text subst} makes extraction fail*}
apply (rule exI)
apply (rule conjI)
apply (rule rtrancl_refl)
apply (rule NF.App)
apply (drule listall_conj1)
apply (simp add: listall_app)
apply (rule Var_NF)
apply (rule exI)
apply (rule conjI)
apply (rule rtrancl_into_rtrancl)
apply (rule rtrancl_refl)
apply (rule beta)
apply (erule subst_Var_NF)
done
lemma lift_terms_NF: "listall (\<lambda>t. t \<in> NF) ts \<Longrightarrow>
listall (\<lambda>t. \<forall>i. lift t i \<in> NF) ts \<Longrightarrow>
listall (\<lambda>t. t \<in> NF) (map (\<lambda>t. lift t i) ts)"
by (induct ts) simp_all
lemma lift_NF: "t \<in> NF \<Longrightarrow> lift t i \<in> NF"
apply (induct fixing: i set: NF)
apply (frule listall_conj1)
apply (drule listall_conj2)
apply (drule_tac i=i in lift_terms_NF)
apply assumption
apply (rule_tac m=x and n=i in nat_le_dec [THEN disjE, standard])
apply simp
apply (rule NF.App)
apply assumption
apply simp
apply (rule NF.App)
apply assumption
apply simp
apply (rule NF.Abs)
apply simp
done
subsection {* Main theorems *}
lemma norm_list:
assumes f_compat: "\<And>t t'. t \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<Longrightarrow> f t \<rightarrow>\<^sub>\<beta>\<^sup>* f t'"
and f_NF: "\<And>t. t \<in> NF \<Longrightarrow> f t \<in> NF"
and uNF: "u \<in> NF" and uT: "e \<turnstile> u : T"
shows "\<And>Us. e\<langle>i:T\<rangle> \<tturnstile> as : Us \<Longrightarrow>
listall (\<lambda>t. \<forall>e T' u i. e\<langle>i:T\<rangle> \<turnstile> t : T' \<longrightarrow>
u \<in> NF \<longrightarrow> e \<turnstile> u : T \<longrightarrow> (\<exists>t'. t[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF)) as \<Longrightarrow>
\<exists>as'. \<forall>j. Var j \<degree>\<degree> map (\<lambda>t. f (t[u/i])) as \<rightarrow>\<^sub>\<beta>\<^sup>*
Var j \<degree>\<degree> map f as' \<and> Var j \<degree>\<degree> map f as' \<in> NF"
(is "\<And>Us. _ \<Longrightarrow> listall ?R as \<Longrightarrow> \<exists>as'. ?ex Us as as'")
proof (induct as rule: rev_induct)
case (Nil Us)
with Var_NF have "?ex Us [] []" by simp
thus ?case ..
next
case (snoc b bs Us)
have "e\<langle>i:T\<rangle> \<tturnstile> bs @ [b] : Us" .
then obtain Vs W where Us: "Us = Vs @ [W]"
and bs: "e\<langle>i:T\<rangle> \<tturnstile> bs : Vs" and bT: "e\<langle>i:T\<rangle> \<turnstile> b : W"
by (rule types_snocE)
from snoc have "listall ?R bs" by simp
with bs have "\<exists>bs'. ?ex Vs bs bs'" by (rule snoc)
then obtain bs' where
bsred: "\<And>j. Var j \<degree>\<degree> map (\<lambda>t. f (t[u/i])) bs \<rightarrow>\<^sub>\<beta>\<^sup>* Var j \<degree>\<degree> map f bs'"
and bsNF: "\<And>j. Var j \<degree>\<degree> map f bs' \<in> NF" by iprover
from snoc have "?R b" by simp
with bT and uNF and uT have "\<exists>b'. b[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* b' \<and> b' \<in> NF"
by iprover
then obtain b' where bred: "b[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* b'" and bNF: "b' \<in> NF"
by iprover
from bsNF [of 0] have "listall (\<lambda>t. t \<in> NF) (map f bs')"
by (rule App_NF_D)
moreover have "f b' \<in> NF" by (rule f_NF)
ultimately have "listall (\<lambda>t. t \<in> NF) (map f (bs' @ [b']))"
by simp
hence "\<And>j. Var j \<degree>\<degree> map f (bs' @ [b']) \<in> NF" by (rule NF.App)
moreover from bred have "f (b[u/i]) \<rightarrow>\<^sub>\<beta>\<^sup>* f b'"
by (rule f_compat)
with bsred have
"\<And>j. (Var j \<degree>\<degree> map (\<lambda>t. f (t[u/i])) bs) \<degree> f (b[u/i]) \<rightarrow>\<^sub>\<beta>\<^sup>*
(Var j \<degree>\<degree> map f bs') \<degree> f b'" by (rule rtrancl_beta_App)
ultimately have "?ex Us (bs @ [b]) (bs' @ [b'])" by simp
thus ?case ..
qed
lemma subst_type_NF:
"\<And>t e T u i. t \<in> NF \<Longrightarrow> e\<langle>i:U\<rangle> \<turnstile> t : T \<Longrightarrow> u \<in> NF \<Longrightarrow> e \<turnstile> u : U \<Longrightarrow> \<exists>t'. t[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF"
(is "PROP ?P U" is "\<And>t e T u i. _ \<Longrightarrow> PROP ?Q t e T u i U")
proof (induct U)
fix T t
let ?R = "\<lambda>t. \<forall>e T' u i.
e\<langle>i:T\<rangle> \<turnstile> t : T' \<longrightarrow> u \<in> NF \<longrightarrow> e \<turnstile> u : T \<longrightarrow> (\<exists>t'. t[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF)"
assume MI1: "\<And>T1 T2. T = T1 \<Rightarrow> T2 \<Longrightarrow> PROP ?P T1"
assume MI2: "\<And>T1 T2. T = T1 \<Rightarrow> T2 \<Longrightarrow> PROP ?P T2"
assume "t \<in> NF"
thus "\<And>e T' u i. PROP ?Q t e T' u i T"
proof induct
fix e T' u i assume uNF: "u \<in> NF" and uT: "e \<turnstile> u : T"
{
case (App ts x e_ T'_ u_ i_)
assume "e\<langle>i:T\<rangle> \<turnstile> Var x \<degree>\<degree> ts : T'"
then obtain Us
where varT: "e\<langle>i:T\<rangle> \<turnstile> Var x : Us \<Rrightarrow> T'"
and argsT: "e\<langle>i:T\<rangle> \<tturnstile> ts : Us"
by (rule var_app_typesE)
from nat_eq_dec show "\<exists>t'. (Var x \<degree>\<degree> ts)[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF"
proof
assume eq: "x = i"
show ?thesis
proof (cases ts)
case Nil
with eq have "(Var x \<degree>\<degree> [])[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* u" by simp
with Nil and uNF show ?thesis by simp iprover
next
case (Cons a as)
with argsT obtain T'' Ts where Us: "Us = T'' # Ts"
by (cases Us) (rule FalseE, simp+)
from varT and Us have varT: "e\<langle>i:T\<rangle> \<turnstile> Var x : T'' \<Rightarrow> Ts \<Rrightarrow> T'"
by simp
from varT eq have T: "T = T'' \<Rightarrow> Ts \<Rrightarrow> T'" by cases auto
with uT have uT': "e \<turnstile> u : T'' \<Rightarrow> Ts \<Rrightarrow> T'" by simp
from argsT Us Cons have argsT': "e\<langle>i:T\<rangle> \<tturnstile> as : Ts" by simp
from argsT Us Cons have argT: "e\<langle>i:T\<rangle> \<turnstile> a : T''" by simp
from argT uT refl have aT: "e \<turnstile> a[u/i] : T''" by (rule subst_lemma)
from App and Cons have "listall ?R as" by simp (iprover dest: listall_conj2)
with lift_preserves_beta' lift_NF uNF uT argsT'
have "\<exists>as'. \<forall>j. Var j \<degree>\<degree> map (\<lambda>t. lift (t[u/i]) 0) as \<rightarrow>\<^sub>\<beta>\<^sup>*
Var j \<degree>\<degree> map (\<lambda>t. lift t 0) as' \<and>
Var j \<degree>\<degree> map (\<lambda>t. lift t 0) as' \<in> NF" by (rule norm_list)
then obtain as' where
asred: "Var 0 \<degree>\<degree> map (\<lambda>t. lift (t[u/i]) 0) as \<rightarrow>\<^sub>\<beta>\<^sup>*
Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as'"
and asNF: "Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as' \<in> NF" by iprover
from App and Cons have "?R a" by simp
with argT and uNF and uT have "\<exists>a'. a[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* a' \<and> a' \<in> NF"
by iprover
then obtain a' where ared: "a[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* a'" and aNF: "a' \<in> NF" by iprover
from uNF have "lift u 0 \<in> NF" by (rule lift_NF)
hence "\<exists>u'. lift u 0 \<degree> Var 0 \<rightarrow>\<^sub>\<beta>\<^sup>* u' \<and> u' \<in> NF" by (rule app_Var_NF)
then obtain u' where ured: "lift u 0 \<degree> Var 0 \<rightarrow>\<^sub>\<beta>\<^sup>* u'" and u'NF: "u' \<in> NF"
by iprover
from T and u'NF have "\<exists>ua. u'[a'/0] \<rightarrow>\<^sub>\<beta>\<^sup>* ua \<and> ua \<in> NF"
proof (rule MI1)
have "e\<langle>0:T''\<rangle> \<turnstile> lift u 0 \<degree> Var 0 : Ts \<Rrightarrow> T'"
proof (rule typing.App)
from uT' show "e\<langle>0:T''\<rangle> \<turnstile> lift u 0 : T'' \<Rightarrow> Ts \<Rrightarrow> T'" by (rule lift_type)
show "e\<langle>0:T''\<rangle> \<turnstile> Var 0 : T''" by (rule typing.Var) simp
qed
with ured show "e\<langle>0:T''\<rangle> \<turnstile> u' : Ts \<Rrightarrow> T'" by (rule subject_reduction')
from ared aT show "e \<turnstile> a' : T''" by (rule subject_reduction')
qed
then obtain ua where uared: "u'[a'/0] \<rightarrow>\<^sub>\<beta>\<^sup>* ua" and uaNF: "ua \<in> NF"
by iprover
from ared have "(lift u 0 \<degree> Var 0)[a[u/i]/0] \<rightarrow>\<^sub>\<beta>\<^sup>* (lift u 0 \<degree> Var 0)[a'/0]"
by (rule subst_preserves_beta2')
also from ured have "(lift u 0 \<degree> Var 0)[a'/0] \<rightarrow>\<^sub>\<beta>\<^sup>* u'[a'/0]"
by (rule subst_preserves_beta')
also note uared
finally have "(lift u 0 \<degree> Var 0)[a[u/i]/0] \<rightarrow>\<^sub>\<beta>\<^sup>* ua" .
hence uared': "u \<degree> a[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* ua" by simp
from T have "\<exists>r. (Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as')[ua/0] \<rightarrow>\<^sub>\<beta>\<^sup>* r \<and> r \<in> NF"
proof (rule MI2)
have "e\<langle>0:Ts \<Rrightarrow> T'\<rangle> \<turnstile> Var 0 \<degree>\<degree> map (\<lambda>t. lift (t[u/i]) 0) as : T'"
proof (rule list_app_typeI)
show "e\<langle>0:Ts \<Rrightarrow> T'\<rangle> \<turnstile> Var 0 : Ts \<Rrightarrow> T'" by (rule typing.Var) simp
from uT argsT' have "e \<tturnstile> map (\<lambda>t. t[u/i]) as : Ts"
by (rule substs_lemma)
hence "e\<langle>0:Ts \<Rrightarrow> T'\<rangle> \<tturnstile> map (\<lambda>t. lift t 0) (map (\<lambda>t. t[u/i]) as) : Ts"
by (rule lift_types)
thus "e\<langle>0:Ts \<Rrightarrow> T'\<rangle> \<tturnstile> map (\<lambda>t. lift (t[u/i]) 0) as : Ts"
by (simp_all add: map_compose [symmetric] o_def)
qed
with asred show "e\<langle>0:Ts \<Rrightarrow> T'\<rangle> \<turnstile> Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as' : T'"
by (rule subject_reduction')
from argT uT refl have "e \<turnstile> a[u/i] : T''" by (rule subst_lemma)
with uT' have "e \<turnstile> u \<degree> a[u/i] : Ts \<Rrightarrow> T'" by (rule typing.App)
with uared' show "e \<turnstile> ua : Ts \<Rrightarrow> T'" by (rule subject_reduction')
qed
then obtain r where rred: "(Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as')[ua/0] \<rightarrow>\<^sub>\<beta>\<^sup>* r"
and rnf: "r \<in> NF" by iprover
from asred have
"(Var 0 \<degree>\<degree> map (\<lambda>t. lift (t[u/i]) 0) as)[u \<degree> a[u/i]/0] \<rightarrow>\<^sub>\<beta>\<^sup>*
(Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as')[u \<degree> a[u/i]/0]"
by (rule subst_preserves_beta')
also from uared' have "(Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as')[u \<degree> a[u/i]/0] \<rightarrow>\<^sub>\<beta>\<^sup>*
(Var 0 \<degree>\<degree> map (\<lambda>t. lift t 0) as')[ua/0]" by (rule subst_preserves_beta2')
also note rred
finally have "(Var 0 \<degree>\<degree> map (\<lambda>t. lift (t[u/i]) 0) as)[u \<degree> a[u/i]/0] \<rightarrow>\<^sub>\<beta>\<^sup>* r" .
with rnf Cons eq show ?thesis
by (simp add: map_compose [symmetric] o_def) iprover
qed
next
assume neq: "x \<noteq> i"
from App have "listall ?R ts" by (iprover dest: listall_conj2)
with TrueI TrueI uNF uT argsT
have "\<exists>ts'. \<forall>j. Var j \<degree>\<degree> map (\<lambda>t. t[u/i]) ts \<rightarrow>\<^sub>\<beta>\<^sup>* Var j \<degree>\<degree> ts' \<and>
Var j \<degree>\<degree> ts' \<in> NF" (is "\<exists>ts'. ?ex ts'")
by (rule norm_list [of "\<lambda>t. t", simplified])
then obtain ts' where NF: "?ex ts'" ..
from nat_le_dec show ?thesis
proof
assume "i < x"
with NF show ?thesis by simp iprover
next
assume "\<not> (i < x)"
with NF neq show ?thesis by (simp add: subst_Var) iprover
qed
qed
next
case (Abs r e_ T'_ u_ i_)
assume absT: "e\<langle>i:T\<rangle> \<turnstile> Abs r : T'"
then obtain R S where "e\<langle>0:R\<rangle>\<langle>Suc i:T\<rangle> \<turnstile> r : S" by (rule abs_typeE) simp
moreover have "lift u 0 \<in> NF" by (rule lift_NF)
moreover have "e\<langle>0:R\<rangle> \<turnstile> lift u 0 : T" by (rule lift_type)
ultimately have "\<exists>t'. r[lift u 0/Suc i] \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF" by (rule Abs)
thus "\<exists>t'. Abs r[u/i] \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF"
by simp (iprover intro: rtrancl_beta_Abs NF.Abs)
}
qed
qed
consts -- {* A computationally relevant copy of @{term "e \<turnstile> t : T"} *}
rtyping :: "((nat \<Rightarrow> type) \<times> dB \<times> type) set"
abbreviation
rtyping_rel :: "(nat \<Rightarrow> type) \<Rightarrow> dB \<Rightarrow> type \<Rightarrow> bool" ("_ |-\<^sub>R _ : _" [50, 50, 50] 50)
"e |-\<^sub>R t : T == (e, t, T) \<in> rtyping"
const_syntax (xsymbols)
rtyping_rel ("_ \<turnstile>\<^sub>R _ : _" [50, 50, 50] 50)
inductive rtyping
intros
Var: "e x = T \<Longrightarrow> e \<turnstile>\<^sub>R Var x : T"
Abs: "e\<langle>0:T\<rangle> \<turnstile>\<^sub>R t : U \<Longrightarrow> e \<turnstile>\<^sub>R Abs t : (T \<Rightarrow> U)"
App: "e \<turnstile>\<^sub>R s : T \<Rightarrow> U \<Longrightarrow> e \<turnstile>\<^sub>R t : T \<Longrightarrow> e \<turnstile>\<^sub>R (s \<degree> t) : U"
lemma rtyping_imp_typing: "e \<turnstile>\<^sub>R t : T \<Longrightarrow> e \<turnstile> t : T"
apply (induct set: rtyping)
apply (erule typing.Var)
apply (erule typing.Abs)
apply (erule typing.App)
apply assumption
done
theorem type_NF:
assumes "e \<turnstile>\<^sub>R t : T"
shows "\<exists>t'. t \<rightarrow>\<^sub>\<beta>\<^sup>* t' \<and> t' \<in> NF" using prems
proof induct
case Var
show ?case by (iprover intro: Var_NF)
next
case Abs
thus ?case by (iprover intro: rtrancl_beta_Abs NF.Abs)
next
case (App T U e s t)
from App obtain s' t' where
sred: "s \<rightarrow>\<^sub>\<beta>\<^sup>* s'" and sNF: "s' \<in> NF"
and tred: "t \<rightarrow>\<^sub>\<beta>\<^sup>* t'" and tNF: "t' \<in> NF" by iprover
have "\<exists>u. (Var 0 \<degree> lift t' 0)[s'/0] \<rightarrow>\<^sub>\<beta>\<^sup>* u \<and> u \<in> NF"
proof (rule subst_type_NF)
have "lift t' 0 \<in> NF" by (rule lift_NF)
hence "listall (\<lambda>t. t \<in> NF) [lift t' 0]" by (rule listall_cons) (rule listall_nil)
hence "Var 0 \<degree>\<degree> [lift t' 0] \<in> NF" by (rule NF.App)
thus "Var 0 \<degree> lift t' 0 \<in> NF" by simp
show "e\<langle>0:T \<Rightarrow> U\<rangle> \<turnstile> Var 0 \<degree> lift t' 0 : U"
proof (rule typing.App)
show "e\<langle>0:T \<Rightarrow> U\<rangle> \<turnstile> Var 0 : T \<Rightarrow> U"
by (rule typing.Var) simp
from tred have "e \<turnstile> t' : T"
by (rule subject_reduction') (rule rtyping_imp_typing)
thus "e\<langle>0:T \<Rightarrow> U\<rangle> \<turnstile> lift t' 0 : T"
by (rule lift_type)
qed
from sred show "e \<turnstile> s' : T \<Rightarrow> U"
by (rule subject_reduction') (rule rtyping_imp_typing)
qed
then obtain u where ured: "s' \<degree> t' \<rightarrow>\<^sub>\<beta>\<^sup>* u" and unf: "u \<in> NF" by simp iprover
from sred tred have "s \<degree> t \<rightarrow>\<^sub>\<beta>\<^sup>* s' \<degree> t'" by (rule rtrancl_beta_App)
hence "s \<degree> t \<rightarrow>\<^sub>\<beta>\<^sup>* u" using ured by (rule rtrancl_trans)
with unf show ?case by iprover
qed
subsection {* Extracting the program *}
declare NF.induct [ind_realizer]
declare rtrancl.induct [ind_realizer irrelevant]
declare rtyping.induct [ind_realizer]
lemmas [extraction_expand] = trans_def conj_assoc listall_cons_eq
extract type_NF
lemma rtranclR_rtrancl_eq: "((a, b) \<in> rtranclR r) = ((a, b) \<in> rtrancl (Collect r))"
apply (rule iffI)
apply (erule rtranclR.induct)
apply (rule rtrancl_refl)
apply (erule rtrancl_into_rtrancl)
apply (erule CollectI)
apply (erule rtrancl.induct)
apply (rule rtranclR.rtrancl_refl)
apply (erule rtranclR.rtrancl_into_rtrancl)
apply (erule CollectD)
done
lemma NFR_imp_NF: "(nf, t) \<in> NFR \<Longrightarrow> t \<in> NF"
apply (erule NFR.induct)
apply (rule NF.intros)
apply (simp add: listall_def)
apply (erule NF.intros)
done
text_raw {*
\begin{figure}
\renewcommand{\isastyle}{\scriptsize\it}%
@{thm [display,eta_contract=false,margin=100] subst_type_NF_def}
\renewcommand{\isastyle}{\small\it}%
\caption{Program extracted from @{text subst_type_NF}}
\label{fig:extr-subst-type-nf}
\end{figure}
\begin{figure}
\renewcommand{\isastyle}{\scriptsize\it}%
@{thm [display,margin=100] subst_Var_NF_def}
@{thm [display,margin=100] app_Var_NF_def}
@{thm [display,margin=100] lift_NF_def}
@{thm [display,eta_contract=false,margin=100] type_NF_def}
\renewcommand{\isastyle}{\small\it}%
\caption{Program extracted from lemmas and main theorem}
\label{fig:extr-type-nf}
\end{figure}
*}
text {*
The program corresponding to the proof of the central lemma, which
performs substitution and normalization, is shown in Figure
\ref{fig:extr-subst-type-nf}. The correctness
theorem corresponding to the program @{text "subst_type_NF"} is
@{thm [display,margin=100] subst_type_NF_correctness
[simplified rtranclR_rtrancl_eq Collect_mem_eq, no_vars]}
where @{text NFR} is the realizability predicate corresponding to
the datatype @{text NFT}, which is inductively defined by the rules
\pagebreak
@{thm [display,margin=90] NFR.App [of ts nfs x] NFR.Abs [of nf t]}
The programs corresponding to the main theorem @{text "type_NF"}, as
well as to some lemmas, are shown in Figure \ref{fig:extr-type-nf}.
The correctness statement for the main function @{text "type_NF"} is
@{thm [display,margin=100] type_NF_correctness
[simplified rtranclR_rtrancl_eq Collect_mem_eq, no_vars]}
where the realizability predicate @{text "rtypingR"} corresponding to the
computationally relevant version of the typing judgement is inductively
defined by the rules
@{thm [display,margin=100] rtypingR.Var [no_vars]
rtypingR.Abs [of ty, no_vars] rtypingR.App [of ty e s T U ty' t]}
*}
subsection {* Generating executable code *}
consts_code
arbitrary :: "'a" ("(error \"arbitrary\")")
arbitrary :: "'a \<Rightarrow> 'b" ("(fn '_ => error \"arbitrary\")")
code_constapp
"arbitrary :: 'a" ml (target_atom "(error \"arbitrary\")")
"arbitrary :: 'a \<Rightarrow> 'b" ml (target_atom "(fn '_ => error \"arbitrary\")")
code_module Norm
contains
test = "type_NF"
text {*
The following functions convert between Isabelle's built-in {\tt term}
datatype and the generated {\tt dB} datatype. This allows to
generate example terms using Isabelle's parser and inspect
normalized terms using Isabelle's pretty printer.
*}
ML {*
fun nat_of_int 0 = Norm.id_0
| nat_of_int n = Norm.Suc (nat_of_int (n-1));
fun int_of_nat Norm.id_0 = 0
| int_of_nat (Norm.Suc n) = 1 + int_of_nat n;
fun dBtype_of_typ (Type ("fun", [T, U])) =
Norm.Fun (dBtype_of_typ T, dBtype_of_typ U)
| dBtype_of_typ (TFree (s, _)) = (case explode s of
["'", a] => Norm.Atom (nat_of_int (ord a - 97))
| _ => error "dBtype_of_typ: variable name")
| dBtype_of_typ _ = error "dBtype_of_typ: bad type";
fun dB_of_term (Bound i) = Norm.dB_Var (nat_of_int i)
| dB_of_term (t $ u) = Norm.App (dB_of_term t, dB_of_term u)
| dB_of_term (Abs (_, _, t)) = Norm.Abs (dB_of_term t)
| dB_of_term _ = error "dB_of_term: bad term";
fun term_of_dB Ts (Type ("fun", [T, U])) (Norm.Abs dBt) =
Abs ("x", T, term_of_dB (T :: Ts) U dBt)
| term_of_dB Ts _ dBt = term_of_dB' Ts dBt
and term_of_dB' Ts (Norm.dB_Var n) = Bound (int_of_nat n)
| term_of_dB' Ts (Norm.App (dBt, dBu)) =
let val t = term_of_dB' Ts dBt
in case fastype_of1 (Ts, t) of
Type ("fun", [T, U]) => t $ term_of_dB Ts T dBu
| _ => error "term_of_dB: function type expected"
end
| term_of_dB' _ _ = error "term_of_dB: term not in normal form";
fun typing_of_term Ts e (Bound i) =
Norm.Var (e, nat_of_int i, dBtype_of_typ (List.nth (Ts, i)))
| typing_of_term Ts e (t $ u) = (case fastype_of1 (Ts, t) of
Type ("fun", [T, U]) => Norm.rtypingT_App (e, dB_of_term t,
dBtype_of_typ T, dBtype_of_typ U, dB_of_term u,
typing_of_term Ts e t, typing_of_term Ts e u)
| _ => error "typing_of_term: function type expected")
| typing_of_term Ts e (Abs (s, T, t)) =
let val dBT = dBtype_of_typ T
in Norm.rtypingT_Abs (e, dBT, dB_of_term t,
dBtype_of_typ (fastype_of1 (T :: Ts, t)),
typing_of_term (T :: Ts) (Norm.shift e Norm.id_0 dBT) t)
end
| typing_of_term _ _ _ = error "typing_of_term: bad term";
fun dummyf _ = error "dummy";
*}
text {*
We now try out the extracted program @{text "type_NF"} on some example terms.
*}
ML {*
val sg = sign_of (the_context());
fun rd s = read_cterm sg (s, TypeInfer.logicT);
val ct1 = rd "%f. ((%f x. f (f (f x))) ((%f x. f (f (f (f x)))) f))";
val (dB1, _) = Norm.type_NF (typing_of_term [] dummyf (term_of ct1));
val ct1' = cterm_of sg (term_of_dB [] (#T (rep_cterm ct1)) dB1);
val ct2 = rd
"%f x. (%x. f x x) ((%x. f x x) ((%x. f x x) ((%x. f x x) ((%x. f x x) ((%x. f x x) x)))))";
val (dB2, _) = Norm.type_NF (typing_of_term [] dummyf (term_of ct2));
val ct2' = cterm_of sg (term_of_dB [] (#T (rep_cterm ct2)) dB2);
*}
end