1 (**************************************************************************)
4 (* ||A|| A project by Andrea Asperti *)
6 (* ||I|| Developers: *)
7 (* ||T|| The HELM team. *)
8 (* ||A|| http://helm.cs.unibo.it *)
10 (* \ / This file is distributed under the terms of the *)
11 (* v GNU General Public License Version 2 *)
13 (**************************************************************************)
15 include "pts_dummy/rc_hsat.ma".
16 include "basics/core_notation/napart_2.ma".
18 (* THE EVALUATION *************************************************************)
20 (* The arity of a term t in an environment E *)
21 let rec aa E t on t ≝ match t with
23 | Rel i ⇒ nth i … E SORT
24 | App M N ⇒ pred (aa E M)
25 | Lambda N M ⇒ let Q ≝ aa E N in ABST Q (aa (Q::E) M)
26 | Prod N M ⇒ aa ((aa E N)::E) M
30 interpretation "arity assignment (term)" 'Eval1 t E = (aa E t).
32 (* The arity of a type context *)
33 let rec caa E G on G ≝ match G with
35 | cons t F ⇒ let D ≝ caa E F in 〚t〛_[D] :: D
38 interpretation "arity assignment (type context)" 'Eval1 G E = (caa E G).
40 lemma aa_app: ∀M,N,E. 〚App M N〛_[E] = pred (〚M〛_[E]).
43 lemma aa_lambda: ∀M,N,E. 〚Lambda N M〛_[E] = ABST (〚N〛_[E]) (〚M〛_[〚N〛_[E]::E]).
46 lemma aa_prod: ∀M,N,E. 〚Prod N M〛_[E] = 〚M〛_[〚N〛_[E]::E].
49 lemma aa_rel_lt: ∀D,E,i. (S i) ≤ |E| → 〚Rel i〛_[E @ D] = 〚Rel i〛_[E].
50 #D #E (elim E) -E [1: #i #Hie (elim (not_le_Sn_O i)) #Hi (elim (Hi Hie)) ]
51 #C #F #IHE #i (elim i) -i // #i #_ #Hie @IHE @le_S_S_to_le @Hie
54 lemma aa_rel_ge: ∀D,E,i. (S i) ≰ |E| →
55 〚Rel i〛_[E @ D] = 〚Rel (i-|E|)〛_[D].
56 #D #E (elim E) -E [ normalize // ]
57 #C #F #IHE #i (elim i) -i [1: -IHE #Hie (elim Hie) -Hie #Hie (elim (Hie ?)) /2/ ]
58 normalize #i #_ #Hie @IHE /2/
61 (* weakeing and thinning lemma arity assignment *)
62 (* NOTE: >commutative_plus comes from |a::b| ↦ S |b| rather than |b| + 1 *)
63 lemma aa_lift: ∀E,Ep,t,Ek.
64 〚lift t (|Ek|) (|Ep|)〛_[Ek @ Ep @ E] = 〚t〛_[Ek @ E].
67 | #i #Ek @(leb_elim (S i) (|Ek|)) #Hik
68 [ >(lift_rel_lt … Hik) >(aa_rel_lt … Hik) >(aa_rel_lt … Hik) //
69 | >(lift_rel_ge … Hik) >(aa_rel_ge … Hik) <associative_append
70 >(aa_rel_ge …) (>length_append)
71 [ >arith2 // @not_lt_to_le /2/ | @(arith3 … Hik) ]
74 | #N #M #IHN #IHM #Ek >lift_lambda >aa_lambda
75 >commutative_plus >(IHM (? :: ?)) /3/
76 | #N #M #IHN #IHM #Ek >lift_prod >aa_prod
77 >commutative_plus >(IHM (? :: ?)) /3/
82 (* substitution lemma arity assignment *)
83 (* NOTE: >commutative_plus comes from |a::b| ↦ S |b| rather than |b| + 1 *)
84 lemma aa_subst: ∀v,E,t,Ek. 〚t[|Ek|≝v]〛_[Ek @ E] = 〚t〛_[Ek @ 〚v〛_[E]::E].
87 | #i #Ek @(leb_elim (S i) (|Ek|)) #H1ik
88 [ >(aa_rel_lt … H1ik) >(subst_rel1 … H1ik) >(aa_rel_lt … H1ik) //
89 | @(eqb_elim i (|Ek|)) #H2ik
90 [ >(aa_rel_ge … H1ik) >H2ik -H2ik H1ik >subst_rel2
91 >(aa_lift ? ? ? ([])) <minus_n_n /2/
92 | (lapply (arith4 … H1ik H2ik)) -H1ik H2ik #Hik
93 (>(subst_rel3 … Hik)) (>aa_rel_ge) [2: /2/ ]
94 <(associative_append ? ? ([?]) ?)
95 >aa_rel_ge >length_append (>commutative_plus)
96 [ <minus_plus // | @not_le_to_not_le_S_S /2/ ]
100 | #N #M #IHN #IHM #Ek >subst_lambda > aa_lambda
101 >commutative_plus >(IHM (? :: ?)) /3/
102 | #N #M #IHN #IHM #Ek >subst_prod > aa_prod
103 >commutative_plus >(IHM (? :: ?)) /4/
127 (* extensional equality of the interpretations *)
128 definition eveq: T → T → Prop ≝ λt1,t2. ∀E,K. 〚t1〛_[E, K] ≅ 〚t2〛_[E, K].
131 "extensional equality of the type interpretations"
132 'napart t1 t2 = (eveq t1 t2).
135 axiom ev_lift_0_S: ∀t,p,C,E,K. 〚lift t 0 (S p)〛_[C::E, K] ≅ 〚lift t 0 p〛_[E, K].
137 theorem tj_ev: ∀G,t,u. G ⊢t:u → ∀E,l. l ∈ 〚G〛_[E] → t[l] ∈ 〚u[l]〛_[[], []].
138 #G #t #u #tjtu (elim tjtu) -G t u tjtu
139 [ #i #j #_ #E #l #_ >tsubst_sort >tsubst_sort /2 by SAT0_sort/
140 | #G #u #n #tju #IHu #E #l (elim l) -l (normalize)
142 | #hd #tl #_ #H (elim H) -H #Hhd #Htl
143 >lift_0 >delift // >lift_0
147 (@mem_rceq_trans) [3: @symmetric_rceq @ev_lift_0_S | skip ]
151 theorem tj_sn: ∀G,A,B. G ⊢A:B → SN A.
152 #G #A #B #tjAB lapply (tj_trc … tjAB (nil ?) (nil ?)) -tjAB (normalize) /3/
157 theorem tev_rel_S: ∀i,R,H. 〚Rel (S i)〛_(R::H) = 〚Rel i〛_(H).
161 theorem append_cons: ∀(A:Type[0]). ∀(l1,l2:list A). ∀a.
162 (a :: l1) @ l2 = a :: (l1 @ l2).