|apply H;constructor 1]
|intros;elim l
[apply (ex_intro ? ? O);intros;unfold;intro;elim (in_list_nil ? ? H1)
- |elim H;elim (decidable_eq_nat a t)
- [apply (ex_intro ? ? (S a));intros;intro;elim (in_cons_case ? ? ? ? H4)
- [rewrite < H5 in H2;rewrite < H2 in H3;apply (not_le_Sn_n ? H3)
- |elim H5;elim (H1 m ? H7);apply (le_S_S_to_le ? ? (le_S ? ? H3))]
- |cut ((leb a t) = true \lor (leb a t) = false)
- [elim Hcut
- [apply (ex_intro ? ? (S t));intros;intro;
- elim (in_cons_case ? ? ? ? H5)
- [rewrite > H6 in H4;apply (not_le_Sn_n ? H4)
- |elim H6;elim (H1 m ? H8);apply (trans_le a t m)
- [lapply (leb_to_Prop a t);rewrite > H3 in Hletin;assumption
- |apply (le_S_S_to_le t m (le_S (S t) m H4))]]
- |apply (ex_intro ? ? a);intros;intro;elim (in_cons_case ? ? ? ? H5)
- [lapply (leb_to_Prop a t);rewrite > H3 in Hletin;
- simplify in Hletin;lapply (not_le_to_lt ? ? Hletin);
- unfold in Hletin1;rewrite < H6 in Hletin;apply (Hletin H4)
- |elim H6;elim (H1 ? H4 H8)]]
- |elim (leb a t);autobatch]]]]
+ |elim H;
+ apply (ex_intro ? ? (S (max a t))).
+ intros.unfold. intro.
+ elim (in_cons_case ? ? ? ? H3)
+ [rewrite > H4 in H2.autobatch
+ |elim H4.apply (H1 m ? H6).
+ apply (trans_le ? (max a t));autobatch]]]
qed.
(*** lemmata on well-formedness ***)
(*** some exotic inductions and related lemmas ***)
+lemma O_lt_t_len: \forall T.O < (t_len T).
+intros;elim T
+ [1,2,3:simplify;apply le_n
+ |*:simplify;apply lt_O_S]
+qed.
+
+(*
lemma not_t_len_lt_SO : \forall T.\lnot (t_len T) < (S O).
intros;elim T
[1,2,3:simplify;unfold;intro;unfold in H;elim (not_le_Sn_n ? H)
[1,3:simplify in H2;apply H1;apply (trans_lt ? ? ? ? H2);unfold;constructor 1
|*:simplify in H2;apply H;apply (trans_lt ? ? ? ? H2);unfold;constructor 1]]
qed.
+*)
lemma Typ_len_ind : \forall P:Typ \to Prop.
(\forall U.(\forall V.((t_len V) < (t_len U)) \to (P V))
[intros;apply (Hcut ? H ? (t_len T));reflexivity
|intros 4;generalize in match T;apply (nat_elim1 n);intros;
generalize in match H2;elim t
- [1,2,3:apply H;intros;simplify in H4;elim (not_t_len_lt_SO ? H4)
+ [1,2,3:apply H;intros;simplify in H4;elim (lt_to_not_le ? ? H4 (O_lt_t_len ?))
|*:apply H;intros;apply (H1 (t_len V))
[1,3:rewrite > H5;assumption
|*:reflexivity]]]
lemma t_len_arrow1 : \forall T1,T2.(t_len T1) < (t_len (Arrow T1 T2)).
intros.simplify.
-(* FIXME!!! BUG?!?! *)
-cut ((max (t_len T1) (t_len T2)) = match (leb (t_len T1) (t_len T2)) with
- [ false ⇒ (t_len T2)
- | true ⇒ (t_len T1) ])
- [rewrite > Hcut;cut ((leb (t_len T1) (t_len T2)) = false \lor
- (leb (t_len T1) (t_len T2)) = true)
- [lapply (leb_to_Prop (t_len T1) (t_len T2));elim Hcut1
- [rewrite > H;rewrite > H in Hletin;simplify;constructor 1
- |rewrite > H;rewrite > H in Hletin;simplify;simplify in Hletin;
- unfold;apply le_S_S;assumption]
- |elim (leb (t_len T1) (t_len T2));autobatch]
- |elim T1;simplify;reflexivity]
+apply le_S_S.apply le_m_max_m_n.
qed.
lemma t_len_arrow2 : \forall T1,T2.(t_len T2) < (t_len (Arrow T1 T2)).
intros.simplify.
-(* FIXME!!! BUG?!?! *)
-cut ((max (t_len T1) (t_len T2)) = match (leb (t_len T1) (t_len T2)) with
- [ false \Rightarrow (t_len T2)
- | true \Rightarrow (t_len T1) ])
- [rewrite > Hcut;cut ((leb (t_len T1) (t_len T2)) = false \lor
- (leb (t_len T1) (t_len T2)) = true)
- [lapply (leb_to_Prop (t_len T1) (t_len T2));elim Hcut1
- [rewrite > H;rewrite > H in Hletin;simplify;simplify in Hletin;
- lapply (not_le_to_lt ? ? Hletin);unfold in Hletin1;unfold;
- constructor 2;assumption
- |rewrite > H;simplify;unfold;constructor 1]
- |elim (leb (t_len T1) (t_len T2));autobatch]
- |elim T1;simplify;reflexivity]
+apply le_S_S.apply le_n_max_m_n.
qed.
lemma t_len_forall1 : \forall T1,T2.(t_len T1) < (t_len (Forall T1 T2)).
intros.simplify.
-(* FIXME!!! BUG?!?! *)
-cut ((max (t_len T1) (t_len T2)) = match (leb (t_len T1) (t_len T2)) with
- [ false \Rightarrow (t_len T2)
- | true \Rightarrow (t_len T1) ])
- [rewrite > Hcut;cut ((leb (t_len T1) (t_len T2)) = false \lor
- (leb (t_len T1) (t_len T2)) = true)
- [lapply (leb_to_Prop (t_len T1) (t_len T2));elim Hcut1
- [rewrite > H;rewrite > H in Hletin;simplify;constructor 1
- |rewrite > H;rewrite > H in Hletin;simplify;simplify in Hletin;
- unfold;apply le_S_S;assumption]
- |elim (leb (t_len T1) (t_len T2));autobatch]
- |elim T1;simplify;reflexivity]
+apply le_S_S.apply le_m_max_m_n.
qed.
lemma t_len_forall2 : \forall T1,T2.(t_len T2) < (t_len (Forall T1 T2)).
intros.simplify.
-(* FIXME!!! BUG?!?! *)
-cut ((max (t_len T1) (t_len T2)) = match (leb (t_len T1) (t_len T2)) with
- [ false \Rightarrow (t_len T2)
- | true \Rightarrow (t_len T1) ])
- [rewrite > Hcut;cut ((leb (t_len T1) (t_len T2)) = false \lor
- (leb (t_len T1) (t_len T2)) = true)
- [lapply (leb_to_Prop (t_len T1) (t_len T2));elim Hcut1
- [rewrite > H;rewrite > H in Hletin;simplify;simplify in Hletin;
- lapply (not_le_to_lt ? ? Hletin);unfold in Hletin1;unfold;
- constructor 2;assumption
- |rewrite > H;simplify;unfold;constructor 1]
- |elim (leb (t_len T1) (t_len T2));autobatch]
- |elim T1;simplify;reflexivity]
+apply le_S_S.apply le_n_max_m_n.
qed.
lemma eq_t_len_TFree_subst : \forall T,n,X.(t_len T) =
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