X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=matita%2Fmatita%2Fcontribs%2Flambdadelta%2Fstatic_2%2Frelocation%2Flifts.ma;h=1b383569934c5ff49afe90c9b24b45705b723590;hb=89fc31fc5cc01e8860cf67a8e096c24125370d31;hp=060f3b8057d843e509201ed69a526d62895c6f01;hpb=0d1dc967bc12041b9d23ee945db9dd91335e8c1d;p=helm.git

diff --git a/matita/matita/contribs/lambdadelta/static_2/relocation/lifts.ma b/matita/matita/contribs/lambdadelta/static_2/relocation/lifts.ma
index 060f3b805..1b3835699 100644
--- a/matita/matita/contribs/lambdadelta/static_2/relocation/lifts.ma
+++ b/matita/matita/contribs/lambdadelta/static_2/relocation/lifts.ma
@@ -24,7 +24,7 @@ include "static_2/syntax/term.ma".
 *)
 inductive lifts: rtmap → relation term ≝
 | lifts_sort: ∀f,s. lifts f (⋆s) (⋆s)
-| lifts_lref: ∀f,i1,i2. @⦃i1, f⦄ ≘ i2 → lifts f (#i1) (#i2)
+| lifts_lref: ∀f,i1,i2. @⦃i1,f⦄ ≘ i2 → lifts f (#i1) (#i2)
 | lifts_gref: ∀f,l. lifts f (§l) (§l)
 | lifts_bind: ∀f,p,I,V1,V2,T1,T2.
               lifts f V1 V2 → lifts (⫯f) T1 T2 →
@@ -41,28 +41,32 @@ interpretation "generic relocation (term)"
    'RLiftStar f T1 T2 = (lifts f T1 T2).
 
 definition liftable2_sn: predicate (relation term) ≝
-                         λR. ∀T1,T2. R T1 T2 → ∀f,U1. ⬆*[f] T1 ≘ U1 → 
-                         ∃∃U2. ⬆*[f] T2 ≘ U2 & R U1 U2.
+                         λR. ∀T1,T2. R T1 T2 → ∀f,U1. ⇧*[f] T1 ≘ U1 → 
+                         ∃∃U2. ⇧*[f] T2 ≘ U2 & R U1 U2.
 
 definition deliftable2_sn: predicate (relation term) ≝
-                           λR. ∀U1,U2. R U1 U2 → ∀f,T1. ⬆*[f] T1 ≘ U1 →
-                           ∃∃T2. ⬆*[f] T2 ≘ U2 & R T1 T2.
+                           λR. ∀U1,U2. R U1 U2 → ∀f,T1. ⇧*[f] T1 ≘ U1 →
+                           ∃∃T2. ⇧*[f] T2 ≘ U2 & R T1 T2.
 
 definition liftable2_bi: predicate (relation term) ≝
-                         λR. ∀T1,T2. R T1 T2 → ∀f,U1. ⬆*[f] T1 ≘ U1 → 
-                         ∀U2. ⬆*[f] T2 ≘ U2 → R U1 U2.
+                         λR. ∀T1,T2. R T1 T2 → ∀f,U1. ⇧*[f] T1 ≘ U1 → 
+                         ∀U2. ⇧*[f] T2 ≘ U2 → R U1 U2.
 
 definition deliftable2_bi: predicate (relation term) ≝
-                           λR. ∀U1,U2. R U1 U2 → ∀f,T1. ⬆*[f] T1 ≘ U1 →
-                           ∀T2. ⬆*[f] T2 ≘ U2 → R T1 T2.
+                           λR. ∀U1,U2. R U1 U2 → ∀f,T1. ⇧*[f] T1 ≘ U1 →
+                           ∀T2. ⇧*[f] T2 ≘ U2 → R T1 T2.
+
+definition liftable2_dx: predicate (relation term) ≝
+                         λR. ∀T1,T2. R T1 T2 → ∀f,U2. ⇧*[f] T2 ≘ U2 →
+                         ∃∃U1. ⇧*[f] T1 ≘ U1 & R U1 U2.
 
 definition deliftable2_dx: predicate (relation term) ≝
-                           λR. ∀U1,U2. R U1 U2 → ∀f,T2. ⬆*[f] T2 ≘ U2 →
-                           ∃∃T1. ⬆*[f] T1 ≘ U1 & R T1 T2.
+                           λR. ∀U1,U2. R U1 U2 → ∀f,T2. ⇧*[f] T2 ≘ U2 →
+                           ∃∃T1. ⇧*[f] T1 ≘ U1 & R T1 T2.
 
 (* Basic inversion lemmas ***************************************************)
 
-fact lifts_inv_sort1_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀s. X = ⋆s → Y = ⋆s.
+fact lifts_inv_sort1_aux: ∀f,X,Y. ⇧*[f] X ≘ Y → ∀s. X = ⋆s → Y = ⋆s.
 #f #X #Y * -f -X -Y //
 [ #f #i1 #i2 #_ #x #H destruct
 | #f #p #I #V1 #V2 #T1 #T2 #_ #_ #x #H destruct
@@ -72,11 +76,11 @@ qed-.
 
 (* Basic_1: was: lift1_sort *)
 (* Basic_2A1: includes: lift_inv_sort1 *)
-lemma lifts_inv_sort1: ∀f,Y,s. ⬆*[f] ⋆s ≘ Y → Y = ⋆s.
+lemma lifts_inv_sort1: ∀f,Y,s. ⇧*[f] ⋆s ≘ Y → Y = ⋆s.
 /2 width=4 by lifts_inv_sort1_aux/ qed-.
 
-fact lifts_inv_lref1_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀i1. X = #i1 →
-                          ∃∃i2. @⦃i1, f⦄ ≘ i2 & Y = #i2.
+fact lifts_inv_lref1_aux: ∀f,X,Y. ⇧*[f] X ≘ Y → ∀i1. X = #i1 →
+                          ∃∃i2. @⦃i1,f⦄ ≘ i2 & Y = #i2.
 #f #X #Y * -f -X -Y
 [ #f #s #x #H destruct
 | #f #i1 #i2 #Hi12 #x #H destruct /2 width=3 by ex2_intro/
@@ -88,11 +92,11 @@ qed-.
 
 (* Basic_1: was: lift1_lref *)
 (* Basic_2A1: includes: lift_inv_lref1 lift_inv_lref1_lt lift_inv_lref1_ge *)
-lemma lifts_inv_lref1: ∀f,Y,i1. ⬆*[f] #i1 ≘ Y →
-                       ∃∃i2. @⦃i1, f⦄ ≘ i2 & Y = #i2.
+lemma lifts_inv_lref1: ∀f,Y,i1. ⇧*[f] #i1 ≘ Y →
+                       ∃∃i2. @⦃i1,f⦄ ≘ i2 & Y = #i2.
 /2 width=3 by lifts_inv_lref1_aux/ qed-.
 
-fact lifts_inv_gref1_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀l. X = §l → Y = §l.
+fact lifts_inv_gref1_aux: ∀f,X,Y. ⇧*[f] X ≘ Y → ∀l. X = §l → Y = §l.
 #f #X #Y * -f -X -Y //
 [ #f #i1 #i2 #_ #x #H destruct
 | #f #p #I #V1 #V2 #T1 #T2 #_ #_ #x #H destruct
@@ -101,12 +105,12 @@ fact lifts_inv_gref1_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀l. X = §l → Y = §
 qed-.
 
 (* Basic_2A1: includes: lift_inv_gref1 *)
-lemma lifts_inv_gref1: ∀f,Y,l. ⬆*[f] §l ≘ Y → Y = §l.
+lemma lifts_inv_gref1: ∀f,Y,l. ⇧*[f] §l ≘ Y → Y = §l.
 /2 width=4 by lifts_inv_gref1_aux/ qed-.
 
-fact lifts_inv_bind1_aux: ∀f,X,Y. ⬆*[f] X ≘ Y →
+fact lifts_inv_bind1_aux: ∀f,X,Y. ⇧*[f] X ≘ Y →
                           ∀p,I,V1,T1. X = ⓑ{p,I}V1.T1 →
-                          ∃∃V2,T2. ⬆*[f] V1 ≘ V2 & ⬆*[⫯f] T1 ≘ T2 &
+                          ∃∃V2,T2. ⇧*[f] V1 ≘ V2 & ⇧*[⫯f] T1 ≘ T2 &
                                    Y = ⓑ{p,I}V2.T2.
 #f #X #Y * -f -X -Y
 [ #f #s #q #J #W1 #U1 #H destruct
@@ -119,14 +123,14 @@ qed-.
 
 (* Basic_1: was: lift1_bind *)
 (* Basic_2A1: includes: lift_inv_bind1 *)
-lemma lifts_inv_bind1: ∀f,p,I,V1,T1,Y. ⬆*[f] ⓑ{p,I}V1.T1 ≘ Y →
-                       ∃∃V2,T2. ⬆*[f] V1 ≘ V2 & ⬆*[⫯f] T1 ≘ T2 &
+lemma lifts_inv_bind1: ∀f,p,I,V1,T1,Y. ⇧*[f] ⓑ{p,I}V1.T1 ≘ Y →
+                       ∃∃V2,T2. ⇧*[f] V1 ≘ V2 & ⇧*[⫯f] T1 ≘ T2 &
                                 Y = ⓑ{p,I}V2.T2.
 /2 width=3 by lifts_inv_bind1_aux/ qed-.
 
-fact lifts_inv_flat1_aux: ∀f:rtmap. ∀X,Y. ⬆*[f] X ≘ Y →
+fact lifts_inv_flat1_aux: ∀f:rtmap. ∀X,Y. ⇧*[f] X ≘ Y →
                           ∀I,V1,T1. X = ⓕ{I}V1.T1 →
-                          ∃∃V2,T2. ⬆*[f] V1 ≘ V2 & ⬆*[f] T1 ≘ T2 &
+                          ∃∃V2,T2. ⇧*[f] V1 ≘ V2 & ⇧*[f] T1 ≘ T2 &
                                    Y = ⓕ{I}V2.T2.
 #f #X #Y * -f -X -Y
 [ #f #s #J #W1 #U1 #H destruct
@@ -139,12 +143,12 @@ qed-.
 
 (* Basic_1: was: lift1_flat *)
 (* Basic_2A1: includes: lift_inv_flat1 *)
-lemma lifts_inv_flat1: ∀f:rtmap. ∀I,V1,T1,Y. ⬆*[f] ⓕ{I}V1.T1 ≘ Y →
-                       ∃∃V2,T2. ⬆*[f] V1 ≘ V2 & ⬆*[f] T1 ≘ T2 &
+lemma lifts_inv_flat1: ∀f:rtmap. ∀I,V1,T1,Y. ⇧*[f] ⓕ{I}V1.T1 ≘ Y →
+                       ∃∃V2,T2. ⇧*[f] V1 ≘ V2 & ⇧*[f] T1 ≘ T2 &
                                 Y = ⓕ{I}V2.T2.
 /2 width=3 by lifts_inv_flat1_aux/ qed-.
 
-fact lifts_inv_sort2_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀s. Y = ⋆s → X = ⋆s.
+fact lifts_inv_sort2_aux: ∀f,X,Y. ⇧*[f] X ≘ Y → ∀s. Y = ⋆s → X = ⋆s.
 #f #X #Y * -f -X -Y //
 [ #f #i1 #i2 #_ #x #H destruct
 | #f #p #I #V1 #V2 #T1 #T2 #_ #_ #x #H destruct
@@ -154,11 +158,11 @@ qed-.
 
 (* Basic_1: includes: lift_gen_sort *)
 (* Basic_2A1: includes: lift_inv_sort2 *)
-lemma lifts_inv_sort2: ∀f,X,s. ⬆*[f] X ≘ ⋆s → X = ⋆s.
+lemma lifts_inv_sort2: ∀f,X,s. ⇧*[f] X ≘ ⋆s → X = ⋆s.
 /2 width=4 by lifts_inv_sort2_aux/ qed-.
 
-fact lifts_inv_lref2_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀i2. Y = #i2 →
-                          ∃∃i1. @⦃i1, f⦄ ≘ i2 & X = #i1.
+fact lifts_inv_lref2_aux: ∀f,X,Y. ⇧*[f] X ≘ Y → ∀i2. Y = #i2 →
+                          ∃∃i1. @⦃i1,f⦄ ≘ i2 & X = #i1.
 #f #X #Y * -f -X -Y
 [ #f #s #x #H destruct
 | #f #i1 #i2 #Hi12 #x #H destruct /2 width=3 by ex2_intro/
@@ -170,11 +174,11 @@ qed-.
 
 (* Basic_1: includes: lift_gen_lref lift_gen_lref_lt lift_gen_lref_false lift_gen_lref_ge *)
 (* Basic_2A1: includes: lift_inv_lref2 lift_inv_lref2_lt lift_inv_lref2_be lift_inv_lref2_ge lift_inv_lref2_plus *)
-lemma lifts_inv_lref2: ∀f,X,i2. ⬆*[f] X ≘ #i2 →
-                       ∃∃i1. @⦃i1, f⦄ ≘ i2 & X = #i1.
+lemma lifts_inv_lref2: ∀f,X,i2. ⇧*[f] X ≘ #i2 →
+                       ∃∃i1. @⦃i1,f⦄ ≘ i2 & X = #i1.
 /2 width=3 by lifts_inv_lref2_aux/ qed-.
 
-fact lifts_inv_gref2_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀l. Y = §l → X = §l.
+fact lifts_inv_gref2_aux: ∀f,X,Y. ⇧*[f] X ≘ Y → ∀l. Y = §l → X = §l.
 #f #X #Y * -f -X -Y //
 [ #f #i1 #i2 #_ #x #H destruct
 | #f #p #I #V1 #V2 #T1 #T2 #_ #_ #x #H destruct
@@ -183,12 +187,12 @@ fact lifts_inv_gref2_aux: ∀f,X,Y. ⬆*[f] X ≘ Y → ∀l. Y = §l → X = §
 qed-.
 
 (* Basic_2A1: includes: lift_inv_gref1 *)
-lemma lifts_inv_gref2: ∀f,X,l. ⬆*[f] X ≘ §l → X = §l.
+lemma lifts_inv_gref2: ∀f,X,l. ⇧*[f] X ≘ §l → X = §l.
 /2 width=4 by lifts_inv_gref2_aux/ qed-.
 
-fact lifts_inv_bind2_aux: ∀f,X,Y. ⬆*[f] X ≘ Y →
+fact lifts_inv_bind2_aux: ∀f,X,Y. ⇧*[f] X ≘ Y →
                           ∀p,I,V2,T2. Y = ⓑ{p,I}V2.T2 →
-                          ∃∃V1,T1. ⬆*[f] V1 ≘ V2 & ⬆*[⫯f] T1 ≘ T2 &
+                          ∃∃V1,T1. ⇧*[f] V1 ≘ V2 & ⇧*[⫯f] T1 ≘ T2 &
                                    X = ⓑ{p,I}V1.T1.
 #f #X #Y * -f -X -Y
 [ #f #s #q #J #W2 #U2 #H destruct
@@ -201,14 +205,14 @@ qed-.
 
 (* Basic_1: includes: lift_gen_bind *)
 (* Basic_2A1: includes: lift_inv_bind2 *)
-lemma lifts_inv_bind2: ∀f,p,I,V2,T2,X. ⬆*[f] X ≘ ⓑ{p,I}V2.T2 →
-                       ∃∃V1,T1. ⬆*[f] V1 ≘ V2 & ⬆*[⫯f] T1 ≘ T2 &
+lemma lifts_inv_bind2: ∀f,p,I,V2,T2,X. ⇧*[f] X ≘ ⓑ{p,I}V2.T2 →
+                       ∃∃V1,T1. ⇧*[f] V1 ≘ V2 & ⇧*[⫯f] T1 ≘ T2 &
                                 X = ⓑ{p,I}V1.T1.
 /2 width=3 by lifts_inv_bind2_aux/ qed-.
 
-fact lifts_inv_flat2_aux: ∀f:rtmap. ∀X,Y. ⬆*[f] X ≘ Y →
+fact lifts_inv_flat2_aux: ∀f:rtmap. ∀X,Y. ⇧*[f] X ≘ Y →
                           ∀I,V2,T2. Y = ⓕ{I}V2.T2 →
-                          ∃∃V1,T1. ⬆*[f] V1 ≘ V2 & ⬆*[f] T1 ≘ T2 &
+                          ∃∃V1,T1. ⇧*[f] V1 ≘ V2 & ⇧*[f] T1 ≘ T2 &
                                    X = ⓕ{I}V1.T1.
 #f #X #Y * -f -X -Y
 [ #f #s #J #W2 #U2 #H destruct
@@ -221,16 +225,16 @@ qed-.
 
 (* Basic_1: includes: lift_gen_flat *)
 (* Basic_2A1: includes: lift_inv_flat2 *)
-lemma lifts_inv_flat2: ∀f:rtmap. ∀I,V2,T2,X. ⬆*[f] X ≘ ⓕ{I}V2.T2 →
-                       ∃∃V1,T1. ⬆*[f] V1 ≘ V2 & ⬆*[f] T1 ≘ T2 &
+lemma lifts_inv_flat2: ∀f:rtmap. ∀I,V2,T2,X. ⇧*[f] X ≘ ⓕ{I}V2.T2 →
+                       ∃∃V1,T1. ⇧*[f] V1 ≘ V2 & ⇧*[f] T1 ≘ T2 &
                                 X = ⓕ{I}V1.T1.
 /2 width=3 by lifts_inv_flat2_aux/ qed-.
 
 (* Advanced inversion lemmas ************************************************)
 
-lemma lifts_inv_atom1: ∀f,I,Y. ⬆*[f] ⓪{I} ≘ Y →
+lemma lifts_inv_atom1: ∀f,I,Y. ⇧*[f] ⓪{I} ≘ Y →
                        ∨∨ ∃∃s. I = Sort s & Y = ⋆s
-                        | ∃∃i,j. @⦃i, f⦄ ≘ j & I = LRef i & Y = #j
+                        | ∃∃i,j. @⦃i,f⦄ ≘ j & I = LRef i & Y = #j
                         | ∃∃l. I = GRef l & Y = §l.
 #f * #n #Y #H
 [ lapply (lifts_inv_sort1 … H)
@@ -239,9 +243,9 @@ lemma lifts_inv_atom1: ∀f,I,Y. ⬆*[f] ⓪{I} ≘ Y →
 ] -H /3 width=5 by or3_intro0, or3_intro1, or3_intro2, ex3_2_intro, ex2_intro/
 qed-.
 
-lemma lifts_inv_atom2: ∀f,I,X. ⬆*[f] X ≘ ⓪{I} →
+lemma lifts_inv_atom2: ∀f,I,X. ⇧*[f] X ≘ ⓪{I} →
                        ∨∨ ∃∃s. X = ⋆s & I = Sort s
-                        | ∃∃i,j. @⦃i, f⦄ ≘ j & X = #i & I = LRef j
+                        | ∃∃i,j. @⦃i,f⦄ ≘ j & X = #i & I = LRef j
                         | ∃∃l. X = §l & I = GRef l.
 #f * #n #X #H
 [ lapply (lifts_inv_sort2 … H)
@@ -251,7 +255,7 @@ lemma lifts_inv_atom2: ∀f,I,X. ⬆*[f] X ≘ ⓪{I} →
 qed-.
 
 (* Basic_2A1: includes: lift_inv_pair_xy_x *)
-lemma lifts_inv_pair_xy_x: ∀f,I,V,T. ⬆*[f] ②{I}V.T ≘ V → ⊥.
+lemma lifts_inv_pair_xy_x: ∀f,I,V,T. ⇧*[f] ②{I}V.T ≘ V → ⊥.
 #f #J #V elim V -V
 [ * #i #U #H
   [ lapply (lifts_inv_sort2 … H) -H #H destruct
@@ -268,7 +272,7 @@ qed-.
 
 (* Basic_1: includes: thead_x_lift_y_y *)
 (* Basic_2A1: includes: lift_inv_pair_xy_y *)
-lemma lifts_inv_pair_xy_y: ∀I,T,V,f. ⬆*[f] ②{I}V.T ≘ T → ⊥.
+lemma lifts_inv_pair_xy_y: ∀I,T,V,f. ⇧*[f] ②{I}V.T ≘ T → ⊥.
 #J #T elim T -T
 [ * #i #W #f #H
   [ lapply (lifts_inv_sort2 … H) -H #H destruct
@@ -283,24 +287,40 @@ lemma lifts_inv_pair_xy_y: ∀I,T,V,f. ⬆*[f] ②{I}V.T ≘ T → ⊥.
 ]
 qed-.
 
+lemma lifts_inv_push_zero_sn (f):
+      ∀X. ⇧*[⫯f]#0 ≘ X → #0 = X.
+#f #X #H
+elim (lifts_inv_lref1 … H) -H #i #Hi #H destruct
+lapply (at_inv_ppx … Hi ???) -Hi //
+qed-.
+
+lemma lifts_inv_push_succ_sn (f) (i1):
+      ∀X. ⇧*[⫯f]#(↑i1) ≘ X →
+      ∃∃i2. ⇧*[f]#i1 ≘ #i2 & #(↑i2) = X.
+#f #i1 #X #H
+elim (lifts_inv_lref1 … H) -H #j #Hij #H destruct
+elim (at_inv_npx … Hij) -Hij [|*: // ] #i2 #Hi12 #H destruct
+/3 width=3 by lifts_lref, ex2_intro/
+qed-.
+
 (* Inversion lemmas with uniform relocations ********************************)
 
-lemma lifts_inv_lref1_uni: ∀l,Y,i. ⬆*[l] #i ≘ Y → Y = #(l+i).
+lemma lifts_inv_lref1_uni: ∀l,Y,i. ⇧*[l] #i ≘ Y → Y = #(l+i).
 #l #Y #i1 #H elim (lifts_inv_lref1 … H) -H /4 width=4 by at_mono, eq_f/
 qed-.
 
-lemma lifts_inv_lref2_uni: ∀l,X,i2. ⬆*[l] X ≘ #i2 →
+lemma lifts_inv_lref2_uni: ∀l,X,i2. ⇧*[l] X ≘ #i2 →
                            ∃∃i1. X = #i1 & i2 = l + i1.
 #l #X #i2 #H elim (lifts_inv_lref2 … H) -H
 /3 width=3 by at_inv_uni, ex2_intro/
 qed-.
 
-lemma lifts_inv_lref2_uni_ge: ∀l,X,i. ⬆*[l] X ≘ #(l + i) → X = #i.
+lemma lifts_inv_lref2_uni_ge: ∀l,X,i. ⇧*[l] X ≘ #(l + i) → X = #i.
 #l #X #i2 #H elim (lifts_inv_lref2_uni … H) -H
 #i1 #H1 #H2 destruct /4 width=2 by injective_plus_r, eq_f, sym_eq/
 qed-.
 
-lemma lifts_inv_lref2_uni_lt: ∀l,X,i. ⬆*[l] X ≘ #i → i < l → ⊥.
+lemma lifts_inv_lref2_uni_lt: ∀l,X,i. ⇧*[l] X ≘ #i → i < l → ⊥.
 #l #X #i2 #H elim (lifts_inv_lref2_uni … H) -H
 #i1 #_ #H1 #H2 destruct /2 width=4 by lt_le_false/
 qed-.
@@ -308,14 +328,14 @@ qed-.
 (* Basic forward lemmas *****************************************************)
 
 (* Basic_2A1: includes: lift_inv_O2 *)
-lemma lifts_fwd_isid: ∀f,T1,T2. ⬆*[f] T1 ≘ T2 → 𝐈⦃f⦄ → T1 = T2.
+lemma lifts_fwd_isid: ∀f,T1,T2. ⇧*[f] T1 ≘ T2 → 𝐈⦃f⦄ → T1 = T2.
 #f #T1 #T2 #H elim H -f -T1 -T2
 /4 width=3 by isid_inv_at_mono, isid_push, eq_f2, eq_f/
 qed-.
 
 (* Basic_2A1: includes: lift_fwd_pair1 *)
-lemma lifts_fwd_pair1: ∀f:rtmap. ∀I,V1,T1,Y. ⬆*[f] ②{I}V1.T1 ≘ Y →
-                       ∃∃V2,T2. ⬆*[f] V1 ≘ V2 & Y = ②{I}V2.T2.
+lemma lifts_fwd_pair1: ∀f:rtmap. ∀I,V1,T1,Y. ⇧*[f] ②{I}V1.T1 ≘ Y →
+                       ∃∃V2,T2. ⇧*[f] V1 ≘ V2 & Y = ②{I}V2.T2.
 #f * [ #p ] #I #V1 #T1 #Y #H
 [ elim (lifts_inv_bind1 … H) -H /2 width=4 by ex2_2_intro/
 | elim (lifts_inv_flat1 … H) -H /2 width=4 by ex2_2_intro/
@@ -323,8 +343,8 @@ lemma lifts_fwd_pair1: ∀f:rtmap. ∀I,V1,T1,Y. ⬆*[f] ②{I}V1.T1 ≘ Y →
 qed-.
 
 (* Basic_2A1: includes: lift_fwd_pair2 *)
-lemma lifts_fwd_pair2: ∀f:rtmap. ∀I,V2,T2,X. ⬆*[f] X ≘ ②{I}V2.T2 →
-                       ∃∃V1,T1. ⬆*[f] V1 ≘ V2 & X = ②{I}V1.T1.
+lemma lifts_fwd_pair2: ∀f:rtmap. ∀I,V2,T2,X. ⇧*[f] X ≘ ②{I}V2.T2 →
+                       ∃∃V1,T1. ⇧*[f] V1 ≘ V2 & X = ②{I}V1.T1.
 #f * [ #p ] #I #V2 #T2 #X #H
 [ elim (lifts_inv_bind2 … H) -H /2 width=4 by ex2_2_intro/
 | elim (lifts_inv_flat2 … H) -H /2 width=4 by ex2_2_intro/
@@ -333,29 +353,34 @@ qed-.
 
 (* Basic properties *********************************************************)
 
+lemma liftable2_sn_dx (R): symmetric … R → liftable2_sn R → liftable2_dx R.
+#R #H2R #H1R #T1 #T2 #HT12 #f #U2 #HTU2
+elim (H1R … T1 … HTU2) -H1R /3 width=3 by ex2_intro/
+qed-.
+
 lemma deliftable2_sn_dx (R): symmetric … R → deliftable2_sn R → deliftable2_dx R.
 #R #H2R #H1R #U1 #U2 #HU12 #f #T2 #HTU2
 elim (H1R … U1 … HTU2) -H1R /3 width=3 by ex2_intro/
 qed-.
 
-lemma lifts_eq_repl_back: ∀T1,T2. eq_repl_back … (λf. ⬆*[f] T1 ≘ T2).
+lemma lifts_eq_repl_back: ∀T1,T2. eq_repl_back … (λf. ⇧*[f] T1 ≘ T2).
 #T1 #T2 #f1 #H elim H -T1 -T2 -f1
 /4 width=5 by lifts_flat, lifts_bind, lifts_lref, at_eq_repl_back, eq_push/
 qed-.
 
-lemma lifts_eq_repl_fwd: ∀T1,T2. eq_repl_fwd … (λf. ⬆*[f] T1 ≘ T2).
+lemma lifts_eq_repl_fwd: ∀T1,T2. eq_repl_fwd … (λf. ⇧*[f] T1 ≘ T2).
 #T1 #T2 @eq_repl_sym /2 width=3 by lifts_eq_repl_back/ (**) (* full auto fails *)
 qed-.
 
 (* Basic_1: includes: lift_r *)
 (* Basic_2A1: includes: lift_refl *)
-lemma lifts_refl: ∀T,f. 𝐈⦃f⦄ → ⬆*[f] T ≘ T.
+lemma lifts_refl: ∀T,f. 𝐈⦃f⦄ → ⇧*[f] T ≘ T.
 #T elim T -T *
 /4 width=3 by lifts_flat, lifts_bind, lifts_lref, isid_inv_at, isid_push/
 qed.
 
 (* Basic_2A1: includes: lift_total *)
-lemma lifts_total: ∀T1,f. ∃T2. ⬆*[f] T1 ≘ T2.
+lemma lifts_total: ∀T1,f. ∃T2. ⇧*[f] T1 ≘ T2.
 #T1 elim T1 -T1 *
 /3 width=2 by lifts_lref, lifts_sort, lifts_gref, ex_intro/
 [ #p ] #I #V1 #T1 #IHV1 #IHT1 #f
@@ -365,24 +390,24 @@ elim (IHV1 f) -IHV1 #V2 #HV12
 ]
 qed-.
 
-lemma lifts_push_zero (f): ⬆*[⫯f]#O ≘ #0.
+lemma lifts_push_zero (f): ⇧*[⫯f]#0 ≘ #0.
 /2 width=1 by lifts_lref/ qed.
 
-lemma lifts_push_lref (f) (i1) (i2): ⬆*[f]#i1 ≘ #i2 → ⬆*[⫯f]#(↑i1) ≘ #(↑i2).
+lemma lifts_push_lref (f) (i1) (i2): ⇧*[f]#i1 ≘ #i2 → ⇧*[⫯f]#(↑i1) ≘ #(↑i2).
 #f1 #i1 #i2 #H
 elim (lifts_inv_lref1 … H) -H #j #Hij #H destruct
 /3 width=7 by lifts_lref, at_push/
 qed.
 
-lemma lifts_lref_uni: ∀l,i. ⬆*[l] #i ≘ #(l+i).
+lemma lifts_lref_uni: ∀l,i. ⇧*[l] #i ≘ #(l+i).
 #l elim l -l /2 width=1 by lifts_lref/
 qed.
 
 (* Basic_1: includes: lift_free (right to left) *)
 (* Basic_2A1: includes: lift_split *)
-lemma lifts_split_trans: ∀f,T1,T2. ⬆*[f] T1 ≘ T2 →
+lemma lifts_split_trans: ∀f,T1,T2. ⇧*[f] T1 ≘ T2 →
                          ∀f1,f2. f2 ⊚ f1 ≘ f →
-                         ∃∃T. ⬆*[f1] T1 ≘ T & ⬆*[f2] T ≘ T2.
+                         ∃∃T. ⇧*[f1] T1 ≘ T & ⇧*[f2] T ≘ T2.
 #f #T1 #T2 #H elim H -f -T1 -T2
 [ /3 width=3 by lifts_sort, ex2_intro/
 | #f #i1 #i2 #Hi #f1 #f2 #Ht elim (after_at_fwd … Hi … Ht) -Hi -Ht
@@ -398,9 +423,9 @@ lemma lifts_split_trans: ∀f,T1,T2. ⬆*[f] T1 ≘ T2 →
 qed-.
 
 (* Note: apparently, this was missing in Basic_2A1 *)
-lemma lifts_split_div: ∀f1,T1,T2. ⬆*[f1] T1 ≘ T2 →
+lemma lifts_split_div: ∀f1,T1,T2. ⇧*[f1] T1 ≘ T2 →
                        ∀f2,f. f2 ⊚ f1 ≘ f →
-                       ∃∃T. ⬆*[f2] T2 ≘ T & ⬆*[f] T1 ≘ T.
+                       ∃∃T. ⇧*[f2] T2 ≘ T & ⇧*[f] T1 ≘ T.
 #f1 #T1 #T2 #H elim H -f1 -T1 -T2
 [ /3 width=3 by lifts_sort, ex2_intro/
 | #f1 #i1 #i2 #Hi #f2 #f #Ht elim (after_at1_fwd … Hi … Ht) -Hi -Ht
@@ -417,7 +442,7 @@ qed-.
 
 (* Basic_1: includes: dnf_dec2 dnf_dec *)
 (* Basic_2A1: includes: is_lift_dec *)
-lemma is_lifts_dec: ∀T2,f. Decidable (∃T1. ⬆*[f] T1 ≘ T2).
+lemma is_lifts_dec: ∀T2,f. Decidable (∃T1. ⇧*[f] T1 ≘ T2).
 #T1 elim T1 -T1
 [ * [1,3: /3 width=2 by lifts_sort, lifts_gref, ex_intro, or_introl/ ]
   #i2 #f elim (is_at_dec f i2) //
@@ -451,7 +476,7 @@ qed-.
 
 (* Properties with uniform relocation ***************************************)
 
-lemma lifts_uni: ∀n1,n2,T,U. ⬆*[𝐔❴n1❵∘𝐔❴n2❵] T ≘ U → ⬆*[n1+n2] T ≘ U.
+lemma lifts_uni: ∀n1,n2,T,U. ⇧*[𝐔❴n1❵∘𝐔❴n2❵] T ≘ U → ⇧*[n1+n2] T ≘ U.
 /3 width=4 by lifts_eq_repl_back, after_inv_total/ qed.
 
 (* Basic_2A1: removed theorems 14: