(**************************************************************************)
include "basic_2/notation/relations/sn_6.ma".
-include "basic_2/substitution/lleq.ma".
+include "basic_2/multiple/lleq.ma".
include "basic_2/reduction/lpx.ma".
(* SN EXTENDED STRONGLY NORMALIZING LOCAL ENVIRONMENTS **********************)
definition lsx: ∀h. sd h → relation4 ynat term genv lenv ≝
- λh,g,d,T,G. SN … (lpx h g G) (lleq d T).
+ λh,o,l,T,G. SN … (lpx h o G) (lleq l T).
interpretation
"extended strong normalization (local environment)"
- 'SN h g d T G L = (lsx h g T d G L).
+ 'SN h o l T G L = (lsx h o T l G L).
(* Basic eliminators ********************************************************)
-lemma lsx_ind: ∀h,g,G,T,d. ∀R:predicate lenv.
- (∀L1. G ⊢ ⬊*[h, g, T, d] L1 →
- (∀L2. ⦃G, L1⦄ ⊢ ➡[h, g] L2 → (L1 ≡[T, d] L2 → ⊥) → R L2) →
+lemma lsx_ind: ∀h,o,G,T,l. ∀R:predicate lenv.
+ (∀L1. G ⊢ ⬊*[h, o, T, l] L1 →
+ (∀L2. ⦃G, L1⦄ ⊢ ➡[h, o] L2 → (L1 ≡[T, l] L2 → ⊥) → R L2) →
R L1
) →
- ∀L. G ⊢ ⬊*[h, g, T, d] L → R L.
-#h #g #G #T #d #R #H0 #L1 #H elim H -L1
+ ∀L. G ⊢ ⬊*[h, o, T, l] L → R L.
+#h #o #G #T #l #R #H0 #L1 #H elim H -L1
/5 width=1 by lleq_sym, SN_intro/
qed-.
(* Basic properties *********************************************************)
-lemma lsx_intro: ∀h,g,G,L1,T,d.
- (∀L2. ⦃G, L1⦄ ⊢ ➡[h, g] L2 → (L1 ≡[T, d] L2 → ⊥) → G ⊢ ⬊*[h, g, T, d] L2) →
- G ⊢ ⬊*[h, g, T, d] L1.
+lemma lsx_intro: ∀h,o,G,L1,T,l.
+ (∀L2. ⦃G, L1⦄ ⊢ ➡[h, o] L2 → (L1 ≡[T, l] L2 → ⊥) → G ⊢ ⬊*[h, o, T, l] L2) →
+ G ⊢ ⬊*[h, o, T, l] L1.
/5 width=1 by lleq_sym, SN_intro/ qed.
-lemma lsx_atom: ∀h,g,G,T,d. G ⊢ ⬊*[h, g, T, d] ⋆.
-#h #g #G #T #d @lsx_intro
+lemma lsx_atom: ∀h,o,G,T,l. G ⊢ ⬊*[h, o, T, l] ⋆.
+#h #o #G #T #l @lsx_intro
#X #H #HT lapply (lpx_inv_atom1 … H) -H
#H destruct elim HT -HT //
qed.
-lemma lsx_sort: ∀h,g,G,L,d,k. G ⊢ ⬊*[h, g, ⋆k, d] L.
-#h #g #G #L1 #d #k @lsx_intro
+lemma lsx_sort: ∀h,o,G,L,l,s. G ⊢ ⬊*[h, o, ⋆s, l] L.
+#h #o #G #L1 #l #s @lsx_intro
#L2 #HL12 #H elim H -H
/3 width=4 by lpx_fwd_length, lleq_sort/
qed.
-lemma lsx_gref: ∀h,g,G,L,d,p. G ⊢ ⬊*[h, g, §p, d] L.
-#h #g #G #L1 #d #p @lsx_intro
+lemma lsx_gref: ∀h,o,G,L,l,p. G ⊢ ⬊*[h, o, §p, l] L.
+#h #o #G #L1 #l #p @lsx_intro
#L2 #HL12 #H elim H -H
/3 width=4 by lpx_fwd_length, lleq_gref/
qed.
-lemma lsx_ge_up: ∀h,g,G,L,T,U,dt,d,e. dt ≤ yinj d + yinj e →
- â\87§[d, e] T â\89¡ U â\86\92 G â\8a¢ â¬\8a*[h, g, U, dt] L â\86\92 G â\8a¢ â¬\8a*[h, g, U, d] L.
-#h #g #G #L #T #U #dt #d #e #Hdtde #HTU #H @(lsx_ind … H) -L
+lemma lsx_ge_up: ∀h,o,G,L,T,U,lt,l,k. lt ≤ yinj l + yinj k →
+ â¬\86[l, k] T â\89¡ U â\86\92 G â\8a¢ â¬\8a*[h, o, U, lt] L â\86\92 G â\8a¢ â¬\8a*[h, o, U, l] L.
+#h #o #G #L #T #U #lt #l #k #Hltlm #HTU #H @(lsx_ind … H) -L
/5 width=7 by lsx_intro, lleq_ge_up/
qed-.
-lemma lsx_ge: ∀h,g,G,L,T,d1,d2. d1 ≤ d2 →
- G ⊢ ⬊*[h, g, T, d1] L → G ⊢ ⬊*[h, g, T, d2] L.
-#h #g #G #L #T #d1 #d2 #Hd12 #H @(lsx_ind … H) -L
+lemma lsx_ge: ∀h,o,G,L,T,l1,l2. l1 ≤ l2 →
+ G ⊢ ⬊*[h, o, T, l1] L → G ⊢ ⬊*[h, o, T, l2] L.
+#h #o #G #L #T #l1 #l2 #Hl12 #H @(lsx_ind … H) -L
/5 width=7 by lsx_intro, lleq_ge/
qed-.
(* Basic forward lemmas *****************************************************)
-lemma lsx_fwd_bind_sn: ∀h,g,a,I,G,L,V,T,d. G ⊢ ⬊*[h, g, ⓑ{a,I}V.T, d] L →
- G ⊢ ⬊*[h, g, V, d] L.
-#h #g #a #I #G #L #V #T #d #H @(lsx_ind … H) -L
+lemma lsx_fwd_bind_sn: ∀h,o,a,I,G,L,V,T,l. G ⊢ ⬊*[h, o, ⓑ{a,I}V.T, l] L →
+ G ⊢ ⬊*[h, o, V, l] L.
+#h #o #a #I #G #L #V #T #l #H @(lsx_ind … H) -L
#L1 #_ #IHL1 @lsx_intro
#L2 #HL12 #HV @IHL1 /3 width=4 by lleq_fwd_bind_sn/
qed-.
-lemma lsx_fwd_flat_sn: ∀h,g,I,G,L,V,T,d. G ⊢ ⬊*[h, g, ⓕ{I}V.T, d] L →
- G ⊢ ⬊*[h, g, V, d] L.
-#h #g #I #G #L #V #T #d #H @(lsx_ind … H) -L
+lemma lsx_fwd_flat_sn: ∀h,o,I,G,L,V,T,l. G ⊢ ⬊*[h, o, ⓕ{I}V.T, l] L →
+ G ⊢ ⬊*[h, o, V, l] L.
+#h #o #I #G #L #V #T #l #H @(lsx_ind … H) -L
#L1 #_ #IHL1 @lsx_intro
#L2 #HL12 #HV @IHL1 /3 width=3 by lleq_fwd_flat_sn/
qed-.
-lemma lsx_fwd_flat_dx: ∀h,g,I,G,L,V,T,d. G ⊢ ⬊*[h, g, ⓕ{I}V.T, d] L →
- G ⊢ ⬊*[h, g, T, d] L.
-#h #g #I #G #L #V #T #d #H @(lsx_ind … H) -L
+lemma lsx_fwd_flat_dx: ∀h,o,I,G,L,V,T,l. G ⊢ ⬊*[h, o, ⓕ{I}V.T, l] L →
+ G ⊢ ⬊*[h, o, T, l] L.
+#h #o #I #G #L #V #T #l #H @(lsx_ind … H) -L
#L1 #_ #IHL1 @lsx_intro
#L2 #HL12 #HV @IHL1 /3 width=3 by lleq_fwd_flat_dx/
qed-.
-lemma lsx_fwd_pair_sn: ∀h,g,I,G,L,V,T,d. G ⊢ ⬊*[h, g, ②{I}V.T, d] L →
- G ⊢ ⬊*[h, g, V, d] L.
-#h #g * /2 width=4 by lsx_fwd_bind_sn, lsx_fwd_flat_sn/
+lemma lsx_fwd_pair_sn: ∀h,o,I,G,L,V,T,l. G ⊢ ⬊*[h, o, ②{I}V.T, l] L →
+ G ⊢ ⬊*[h, o, V, l] L.
+#h #o * /2 width=4 by lsx_fwd_bind_sn, lsx_fwd_flat_sn/
qed-.
(* Basic inversion lemmas ***************************************************)
-lemma lsx_inv_flat: ∀h,g,I,G,L,V,T,d. G ⊢ ⬊*[h, g, ⓕ{I}V.T, d] L →
- G ⊢ ⬊*[h, g, V, d] L ∧ G ⊢ ⬊*[h, g, T, d] L.
+lemma lsx_inv_flat: ∀h,o,I,G,L,V,T,l. G ⊢ ⬊*[h, o, ⓕ{I}V.T, l] L →
+ G ⊢ ⬊*[h, o, V, l] L ∧ G ⊢ ⬊*[h, o, T, l] L.
/3 width=3 by lsx_fwd_flat_sn, lsx_fwd_flat_dx, conj/ qed-.
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