(* Title: HOL/Isar_examples/W_correct.thy
ID: $Id$
Author: Markus Wenzel, TU Muenchen
Correctness of Milner's type inference algorithm W (let-free version).
Based upon HOL/W0 by Dieter Nazareth and Tobias Nipkow.
*)
theory W_correct = Main + Type:;
section "Mini ML with type inference rules";
datatype
expr = Var nat | Abs expr | App expr expr;
text {* type inference rules *};
consts
has_type :: "(typ list * expr * typ) set";
syntax
"@has_type" :: "[typ list, expr, typ] => bool" ("((_) |-/ (_) :: (_))" [60, 0, 60] 60);
translations
"a |- e :: t" == "(a,e,t) : has_type";
inductive has_type
intrs [simp]
VarI: "n < length a ==> a |- Var n :: a ! n"
AbsI: "t1#a |- e :: t2 ==> a |- Abs e :: t1 -> t2"
AppI: "[| a |- e1 :: t2 -> t1; a |- e2 :: t2 |]
==> a |- App e1 e2 :: t1";
lemma has_type_subst_closed: "a |- e :: t ==> $s a |- e :: $s t";
proof -;
assume "a |- e :: t";
thus ?thesis (is "?P a e t");
proof (rule has_type.induct); (* FIXME induct method *)
fix a n;
assume "n < length a";
hence "n < length (map ($ s) a)"; by simp;
hence "map ($ s) a |- Var n :: map ($ s) a ! n"; by (rule has_type.VarI);
also; have "map ($ s) a ! n = $ s (a ! n)"; by (rule nth_map);
also; have "map ($ s) a = $ s a"; by (simp only: app_subst_list); (* FIXME unfold fails!? *)
finally; show "?P a (Var n) (a ! n)"; .;
next;
fix a e t1 t2;
assume "?P (t1 # a) e t2";
hence "$ s t1 # map ($ s) a |- e :: $ s t2"; by (simp add: app_subst_list);
hence "map ($ s) a |- Abs e :: $ s t1 -> $ s t2"; by (rule has_type.AbsI);
thus "?P a (Abs e) (t1 -> t2)"; by (simp add: app_subst_list);
next;
fix a e1 e2 t1 t2;
assume "?P a e1 (t2 -> t1)" "?P a e2 t2";
thus "?P a (App e1 e2) t1"; by simp;
qed;
qed;
section {* Type inference algorithm W *};
consts
W :: "[expr, typ list, nat] => (subst * typ * nat) maybe";
primrec
"W (Var i) a n =
(if i < length a then Ok(id_subst, a ! i, n) else Fail)"
"W (Abs e) a n =
((s, t, m) := W e (TVar n # a) (Suc n);
Ok(s, (s n) -> t, m))"
"W (App e1 e2) a n =
((s1, t1, m1) := W e1 a n;
(s2, t2, m2) := W e2 ($s1 a) m1;
u := mgu ($ s2 t1) (t2 -> TVar m2);
Ok ($u o $s2 o s1, $u (TVar m2), Suc m2))";
(* FIXME proper split att/mod *)
ML_setup {* Addsplits [split_bind]; *};
theorem W_correct: "W e a n = Ok (s, t, m) ==> $ s a |- e :: t";
proof -;
assume W_ok: "W e a n = Ok (s, t, m)";
have "ALL a s t m n . Ok (s, t, m) = W e a n --> $ s a |- e :: t" (is "?P e");
proof (induct e);
fix n; show "?P (Var n)"; by simp;
next;
fix e; assume hyp: "?P e";
show "?P (Abs e)";
proof (intro allI impI);
fix a s t m n;
assume "Ok (s, t, m) = W (Abs e) a n";
hence "EX t'. t = s n -> t' & Ok (s, t', m) = W e (TVar n # a) (Suc n)";
by (rule rev_mp) simp;
with hyp; show "$ s a |- Abs e :: t";
by (force intro: has_type.AbsI);
qed;
next;
fix e1 e2; assume hyp1: "?P e1" and hyp2: "?P e2";
show "?P (App e1 e2)";
proof (intro allI impI);
fix a s t m n; assume "Ok (s, t, m) = W (App e1 e2) a n";
hence "EX s1 t1 n1 s2 t2 n2 u.
s = $ u o $ s2 o s1 & t = u n2 &
mgu ($ s2 t1) (t2 -> TVar n2) = Ok u &
W e2 ($ s1 a) n1 = Ok (s2, t2, n2) &
W e1 a n = Ok (s1, t1, n1)"; by (rule rev_mp) (simp, force); (* FIXME force fails !??*)
thus "$ s a |- App e1 e2 :: t";
proof (elim exE conjE);
fix s1 t1 n1 s2 t2 n2 u;
assume s: "s = $ u o $ s2 o s1"
and t: "t = u n2"
and mgu_ok: "mgu ($ s2 t1) (t2 -> TVar n2) = Ok u"
and W1_ok: "W e1 a n = Ok (s1, t1, n1)"
and W2_ok: "W e2 ($ s1 a) n1 = Ok (s2, t2, n2)";
show ?thesis;
proof (rule has_type.AppI);
from s; have s': "$ u ($ s2 ($ s1 a)) = $s a"; by (simp add: subst_comp_tel o_def);
show "$s a |- e1 :: $ u t2 -> t";
proof -;
from hyp1 W1_ok [RS sym]; have "$ s1 a |- e1 :: t1"; by blast;
hence "$ u ($ s2 ($ s1 a)) |- e1 :: $ u ($ s2 t1)";
by (intro has_type_subst_closed);
with s' t mgu_ok; show ?thesis; by simp;
qed;
show "$ s a |- e2 :: $ u t2";
proof -;
from hyp2 W2_ok [RS sym]; have "$ s2 ($ s1 a) |- e2 :: t2"; by blast;
hence "$ u ($ s2 ($ s1 a)) |- e2 :: $ u t2";
by (rule has_type_subst_closed);
with s'; show ?thesis; by simp;
qed;
qed;
qed;
qed;
qed;
with W_ok [RS sym]; show ?thesis; by blast;
qed;
end;