X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=matita%2Fmatita%2Fcontribs%2Flambdadelta%2Fbasic_2%2Frt_computation%2Frsx.ma;h=35e326136b35ddf0c997fdd4b22a9fe466264cd4;hb=57ae1762497a5f3ea75740e2908e04adb8642cc2;hp=81e3d915426ee3bde30c5c46902c2984857aac24;hpb=bd53c4e895203eb049e75434f638f26b5a161a2b;p=helm.git

diff --git a/matita/matita/contribs/lambdadelta/basic_2/rt_computation/rsx.ma b/matita/matita/contribs/lambdadelta/basic_2/rt_computation/rsx.ma
index 81e3d9154..35e326136 100644
--- a/matita/matita/contribs/lambdadelta/basic_2/rt_computation/rsx.ma
+++ b/matita/matita/contribs/lambdadelta/basic_2/rt_computation/rsx.ma
@@ -22,18 +22,18 @@ definition rsx (h) (G) (T): predicate lenv ≝
            SN … (lpx h G) (reqx T).
 
 interpretation
-   "strong normalization for unbound context-sensitive parallel rt-transition on referred entries (local environment)"
-   'PRedTySNStrong h T G L = (rsx h G T L).
+  "strong normalization for unbound context-sensitive parallel rt-transition on referred entries (local environment)"
+  'PRedTySNStrong h T G L = (rsx h G T L).
 
 (* Basic eliminators ********************************************************)
 
 (* Basic_2A1: uses: lsx_ind *)
-lemma rsx_ind (h) (G) (T) (Q:predicate lenv):
-      (∀L1. G ⊢ ⬈*[h,T] 𝐒❪L1❫ →
-            (∀L2. ❪G,L1❫ ⊢ ⬈[h] L2 → (L1 ≛[T] L2 → ⊥) → Q L2) →
-            Q L1
+lemma rsx_ind (h) (G) (T) (Q:predicate …):
+      (∀L1. G ⊢ ⬈*𝐒[h,T] L1 →
+        (∀L2. ❪G,L1❫ ⊢ ⬈[h] L2 → (L1 ≛[T] L2 → ⊥) → Q L2) →
+        Q L1
       ) →
-      ∀L. G ⊢ ⬈*[h,T] 𝐒❪L❫ →  Q L.
+      ∀L. G ⊢ ⬈*𝐒[h,T] L →  Q L.
 #h #G #T #Q #H0 #L1 #H elim H -L1
 /5 width=1 by SN_intro/
 qed-.
@@ -43,16 +43,16 @@ qed-.
 (* Basic_2A1: uses: lsx_intro *)
 lemma rsx_intro (h) (G) (T):
       ∀L1.
-      (∀L2. ❪G,L1❫ ⊢ ⬈[h] L2 → (L1 ≛[T] L2 → ⊥) → G ⊢ ⬈*[h,T] 𝐒❪L2❫) →
-      G ⊢ ⬈*[h,T] 𝐒❪L1❫.
+      (∀L2. ❪G,L1❫ ⊢ ⬈[h] L2 → (L1 ≛[T] L2 → ⊥) → G ⊢ ⬈*𝐒[h,T] L2) →
+      G ⊢ ⬈*𝐒[h,T] L1.
 /5 width=1 by SN_intro/ qed.
 
 (* Basic forward lemmas *****************************************************)
 
 (* Basic_2A1: uses: lsx_fwd_pair_sn lsx_fwd_bind_sn lsx_fwd_flat_sn *)
 lemma rsx_fwd_pair_sn (h) (G):
-      ∀I,L,V,T. G ⊢ ⬈*[h,②[I]V.T] 𝐒❪L❫ →
-      G ⊢ ⬈*[h,V] 𝐒❪L❫.
+      ∀I,L,V,T. G ⊢ ⬈*𝐒[h,②[I]V.T] L →
+      G ⊢ ⬈*𝐒[h,V] L.
 #h #G #I #L #V #T #H
 @(rsx_ind … H) -L #L1 #_ #IHL1
 @rsx_intro #L2 #HL12 #HnL12
@@ -61,8 +61,8 @@ qed-.
 
 (* Basic_2A1: uses: lsx_fwd_flat_dx *)
 lemma rsx_fwd_flat_dx (h) (G):
-      ∀I,L,V,T. G ⊢ ⬈*[h,ⓕ[I]V.T] 𝐒❪L❫ →
-      G ⊢ ⬈*[h,T] 𝐒❪L❫.
+      ∀I,L,V,T. G ⊢ ⬈*𝐒[h,ⓕ[I]V.T] L →
+      G ⊢ ⬈*𝐒[h,T] L.
 #h #G #I #L #V #T #H
 @(rsx_ind … H) -L #L1 #_ #IHL1
 @rsx_intro #L2 #HL12 #HnL12
@@ -70,23 +70,23 @@ lemma rsx_fwd_flat_dx (h) (G):
 qed-.
 
 fact rsx_fwd_pair_aux (h) (G):
-     ∀L. G ⊢ ⬈*[h,#0] 𝐒❪L❫ →
-     ∀I,K,V. L = K.ⓑ[I]V → G ⊢ ⬈*[h,V] 𝐒❪K❫.
+     ∀L. G ⊢ ⬈*𝐒[h,#0] L →
+     ∀I,K,V. L = K.ⓑ[I]V → G ⊢ ⬈*𝐒[h,V] K.
 #h #G #L #H
 @(rsx_ind … H) -L #L1 #_ #IH #I #K1 #V #H destruct
 /5 width=5 by lpx_pair, rsx_intro, reqx_fwd_zero_pair/
 qed-.
 
 lemma rsx_fwd_pair (h) (G):
-      ∀I,K,V. G ⊢ ⬈*[h,#0] 𝐒❪K.ⓑ[I]V❫ → G ⊢ ⬈*[h,V] 𝐒❪K❫.
+      ∀I,K,V. G ⊢ ⬈*𝐒[h,#0] K.ⓑ[I]V → G ⊢ ⬈*𝐒[h,V] K.
 /2 width=4 by rsx_fwd_pair_aux/ qed-.
 
 (* Basic inversion lemmas ***************************************************)
 
 (* Basic_2A1: uses: lsx_inv_flat *)
 lemma rsx_inv_flat (h) (G):
-      ∀I,L,V,T. G ⊢ ⬈*[h,ⓕ[I]V.T] 𝐒❪L❫ →
-      ∧∧ G ⊢ ⬈*[h,V] 𝐒❪L❫ & G ⊢ ⬈*[h,T] 𝐒❪L❫.
+      ∀I,L,V,T. G ⊢ ⬈*𝐒[h,ⓕ[I]V.T] L →
+      ∧∧ G ⊢ ⬈*𝐒[h,V] L & G ⊢ ⬈*𝐒[h,T] L.
 /3 width=3 by rsx_fwd_pair_sn, rsx_fwd_flat_dx, conj/ qed-.
 
 (* Basic_2A1: removed theorems 9: