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[helm.git] / matita / matita / contribs / lambdadelta / static_2 / static / rex.ma

diff --git a/matita/matita/contribs/lambdadelta/static_2/static/rex.ma b/matita/matita/contribs/lambdadelta/static_2/static/rex.ma
index 515e24bef730445b73a2579592925d7808501a60..0848e850358c8878053c135b7aa41bb1e85af4c2 100644 (file)
--- a/matita/matita/contribs/lambdadelta/static_2/static/rex.ma
+++ b/matita/matita/contribs/lambdadelta/static_2/static/rex.ma
@@ -21,7 +21,7 @@ include "static_2/static/frees.ma".
 (* GENERIC EXTENSION ON REFERRED ENTRIES OF A CONTEXT-SENSITIVE REALTION ****)
 
 definition rex (R) (T): relation lenv ≝
-               λL1,L2. ∃∃f. L1 ⊢ 𝐅*⦃T⦄ ≘ f & L1 ⪤[cext2 R, cfull, f] L2.
+               λL1,L2. ∃∃f. L1 ⊢ 𝐅*⦃T⦄ ≘ f & L1 ⪤[cext2 R,cfull,f] L2.
 
 interpretation "generic extension on referred entries (local environment)"
    'Relation R T L1 L2 = (rex R T L1 L2).
@@ -30,32 +30,32 @@ definition R_confluent2_rex: relation4 (relation3 lenv term term)
                                        (relation3 lenv term term) … ≝
                              λR1,R2,RP1,RP2.
                              ∀L0,T0,T1. R1 L0 T0 T1 → ∀T2. R2 L0 T0 T2 →
-                             ∀L1. L0 ⪤[RP1, T0] L1 → ∀L2. L0 ⪤[RP2, T0] L2 →
+                             ∀L1. L0 ⪤[RP1,T0] L1 → ∀L2. L0 ⪤[RP2,T0] L2 →
                              ∃∃T. R2 L1 T1 T & R1 L2 T2 T.
 
 definition rex_confluent: relation … ≝
                           λR1,R2. 
-                          ∀K1,K,V1. K1 ⪤[R1, V1] K → ∀V. R1 K1 V1 V →
-                          ∀K2. K ⪤[R2, V] K2 → K ⪤[R2, V1] K2.
+                          ∀K1,K,V1. K1 ⪤[R1,V1] K → ∀V. R1 K1 V1 V →
+                          ∀K2. K ⪤[R2,V] K2 → K ⪤[R2,V1] K2.
 
 definition rex_transitive: relation3 ? (relation3 ?? term) … ≝
                            λR1,R2,R3.
-                           ∀K1,K,V1. K1 ⪤[R1, V1] K →
+                           ∀K1,K,V1. K1 ⪤[R1,V1] K →
                            ∀V. R1 K1 V1 V → ∀V2. R2 K V V2 → R3 K1 V1 V2.
 
 (* Basic inversion lemmas ***************************************************)
 
-lemma rex_inv_atom_sn (R): ∀Y2,T. ⋆ ⪤[R, T] Y2 → Y2 = ⋆.
+lemma rex_inv_atom_sn (R): ∀Y2,T. ⋆ ⪤[R,T] Y2 → Y2 = ⋆.
 #R #Y2 #T * /2 width=4 by sex_inv_atom1/
 qed-.
 
-lemma rex_inv_atom_dx (R): ∀Y1,T. Y1 ⪤[R, T] ⋆ → Y1 = ⋆.
+lemma rex_inv_atom_dx (R): ∀Y1,T. Y1 ⪤[R,T] ⋆ → Y1 = ⋆.
 #R #I #Y1 * /2 width=4 by sex_inv_atom2/
 qed-.
 
-lemma rex_inv_sort (R): ∀Y1,Y2,s. Y1 ⪤[R, ⋆s] Y2 →
+lemma rex_inv_sort (R): ∀Y1,Y2,s. Y1 ⪤[R,⋆s] Y2 →
                         ∨∨ Y1 = ⋆ ∧ Y2 = ⋆
-                         | ∃∃I1,I2,L1,L2. L1 ⪤[R, ⋆s] L2 &
+                         | ∃∃I1,I2,L1,L2. L1 ⪤[R,⋆s] L2 &
                                           Y1 = L1.ⓘ{I1} & Y2 = L2.ⓘ{I2}.
 #R * [ | #Y1 #I1 ] #Y2 #s * #f #H1 #H2
 [ lapply (sex_inv_atom1 … H2) -H2 /3 width=1 by or_introl, conj/
@@ -66,11 +66,11 @@ lemma rex_inv_sort (R): ∀Y1,Y2,s. Y1 ⪤[R, ⋆s] Y2 →
 ]
 qed-.
 
-lemma rex_inv_zero (R): ∀Y1,Y2. Y1 ⪤[R, #0] Y2 →
+lemma rex_inv_zero (R): ∀Y1,Y2. Y1 ⪤[R,#0] Y2 →
                         ∨∨ Y1 = ⋆ ∧ Y2 = ⋆
-                         | ∃∃I,L1,L2,V1,V2. L1 ⪤[R, V1] L2 & R L1 V1 V2 &
+                         | ∃∃I,L1,L2,V1,V2. L1 ⪤[R,V1] L2 & R L1 V1 V2 &
                                             Y1 = L1.ⓑ{I}V1 & Y2 = L2.ⓑ{I}V2
-                         | ∃∃f,I,L1,L2. 𝐈⦃f⦄ & L1 ⪤[cext2 R, cfull, f] L2 &
+                         | ∃∃f,I,L1,L2. 𝐈⦃f⦄ & L1 ⪤[cext2 R,cfull,f] L2 &
                                         Y1 = L1.ⓤ{I} & Y2 = L2.ⓤ{I}.
 #R * [ | #Y1 * #I1 [ | #X ] ] #Y2 * #f #H1 #H2
 [ lapply (sex_inv_atom1 … H2) -H2 /3 width=1 by or3_intro0, conj/
@@ -84,9 +84,9 @@ lemma rex_inv_zero (R): ∀Y1,Y2. Y1 ⪤[R, #0] Y2 →
 ]
 qed-.
 
-lemma rex_inv_lref (R): ∀Y1,Y2,i. Y1 ⪤[R, #↑i] Y2 →
+lemma rex_inv_lref (R): ∀Y1,Y2,i. Y1 ⪤[R,#↑i] Y2 →
                         ∨∨ Y1 = ⋆ ∧ Y2 = ⋆
-                         | ∃∃I1,I2,L1,L2. L1 ⪤[R, #i] L2 &
+                         | ∃∃I1,I2,L1,L2. L1 ⪤[R,#i] L2 &
                                           Y1 = L1.ⓘ{I1} & Y2 = L2.ⓘ{I2}.
 #R * [ | #Y1 #I1 ] #Y2 #i * #f #H1 #H2
 [ lapply (sex_inv_atom1 … H2) -H2 /3 width=1 by or_introl, conj/
@@ -96,9 +96,9 @@ lemma rex_inv_lref (R): ∀Y1,Y2,i. Y1 ⪤[R, #↑i] Y2 →
 ]
 qed-.
 
-lemma rex_inv_gref (R): ∀Y1,Y2,l. Y1 ⪤[R, §l] Y2 →
+lemma rex_inv_gref (R): ∀Y1,Y2,l. Y1 ⪤[R,§l] Y2 →
                         ∨∨ Y1 = ⋆ ∧ Y2 = ⋆
-                         | ∃∃I1,I2,L1,L2. L1 ⪤[R, §l] L2 &
+                         | ∃∃I1,I2,L1,L2. L1 ⪤[R,§l] L2 &
                                           Y1 = L1.ⓘ{I1} & Y2 = L2.ⓘ{I2}.
 #R * [ | #Y1 #I1 ] #Y2 #l * #f #H1 #H2
 [ lapply (sex_inv_atom1 … H2) -H2 /3 width=1 by or_introl, conj/
@@ -110,39 +110,39 @@ lemma rex_inv_gref (R): ∀Y1,Y2,l. Y1 ⪤[R, §l] Y2 →
 qed-.
 
 (* Basic_2A1: uses: llpx_sn_inv_bind llpx_sn_inv_bind_O *)
-lemma rex_inv_bind (R): ∀p,I,L1,L2,V1,V2,T. L1 ⪤[R, ⓑ{p,I}V1.T] L2 → R L1 V1 V2 →
-                        ∧∧ L1 ⪤[R, V1] L2 & L1.ⓑ{I}V1 ⪤[R, T] L2.ⓑ{I}V2.
+lemma rex_inv_bind (R): ∀p,I,L1,L2,V1,V2,T. L1 ⪤[R,ⓑ{p,I}V1.T] L2 → R L1 V1 V2 →
+                        ∧∧ L1 ⪤[R,V1] L2 & L1.ⓑ{I}V1 ⪤[R,T] L2.ⓑ{I}V2.
 #R #p #I #L1 #L2 #V1 #V2 #T * #f #Hf #HL #HV elim (frees_inv_bind … Hf) -Hf
 /6 width=6 by sle_sex_trans, sex_inv_tl, ext2_pair, sor_inv_sle_dx, sor_inv_sle_sn, ex2_intro, conj/
 qed-.
 
 (* Basic_2A1: uses: llpx_sn_inv_flat *)
-lemma rex_inv_flat (R): ∀I,L1,L2,V,T. L1 ⪤[R, ⓕ{I}V.T] L2 →
-                        ∧∧ L1 ⪤[R, V] L2 & L1 ⪤[R, T] L2.
+lemma rex_inv_flat (R): ∀I,L1,L2,V,T. L1 ⪤[R,ⓕ{I}V.T] L2 →
+                        ∧∧ L1 ⪤[R,V] L2 & L1 ⪤[R,T] L2.
 #R #I #L1 #L2 #V #T * #f #Hf #HL elim (frees_inv_flat … Hf) -Hf
 /5 width=6 by sle_sex_trans, sor_inv_sle_dx, sor_inv_sle_sn, ex2_intro, conj/
 qed-.
 
 (* Advanced inversion lemmas ************************************************)
 
-lemma rex_inv_sort_bind_sn (R): ∀I1,K1,L2,s. K1.ⓘ{I1} ⪤[R, ⋆s] L2 →
-                                ∃∃I2,K2. K1 ⪤[R, ⋆s] K2 & L2 = K2.ⓘ{I2}.
+lemma rex_inv_sort_bind_sn (R): ∀I1,K1,L2,s. K1.ⓘ{I1} ⪤[R,⋆s] L2 →
+                                ∃∃I2,K2. K1 ⪤[R,⋆s] K2 & L2 = K2.ⓘ{I2}.
 #R #I1 #K1 #L2 #s #H elim (rex_inv_sort … H) -H *
 [ #H destruct
 | #Z1 #I2 #Y1 #K2 #Hs #H1 #H2 destruct /2 width=4 by ex2_2_intro/
 ]
 qed-.
 
-lemma rex_inv_sort_bind_dx (R): ∀I2,K2,L1,s. L1 ⪤[R, ⋆s] K2.ⓘ{I2} →
-                                ∃∃I1,K1. K1 ⪤[R, ⋆s] K2 & L1 = K1.ⓘ{I1}.
+lemma rex_inv_sort_bind_dx (R): ∀I2,K2,L1,s. L1 ⪤[R,⋆s] K2.ⓘ{I2} →
+                                ∃∃I1,K1. K1 ⪤[R,⋆s] K2 & L1 = K1.ⓘ{I1}.
 #R #I2 #K2 #L1 #s #H elim (rex_inv_sort … H) -H *
 [ #_ #H destruct
 | #I1 #Z2 #K1 #Y2 #Hs #H1 #H2 destruct /2 width=4 by ex2_2_intro/
 ]
 qed-.
 
-lemma rex_inv_zero_pair_sn (R): ∀I,L2,K1,V1. K1.ⓑ{I}V1 ⪤[R, #0] L2 →
-                                ∃∃K2,V2. K1 ⪤[R, V1] K2 & R K1 V1 V2 &
+lemma rex_inv_zero_pair_sn (R): ∀I,L2,K1,V1. K1.ⓑ{I}V1 ⪤[R,#0] L2 →
+                                ∃∃K2,V2. K1 ⪤[R,V1] K2 & R K1 V1 V2 &
                                          L2 = K2.ⓑ{I}V2.
 #R #I #L2 #K1 #V1 #H elim (rex_inv_zero … H) -H *
 [ #H destruct
@@ -152,8 +152,8 @@ lemma rex_inv_zero_pair_sn (R): ∀I,L2,K1,V1. K1.ⓑ{I}V1 ⪤[R, #0] L2 →
 ]
 qed-.
 
-lemma rex_inv_zero_pair_dx (R): ∀I,L1,K2,V2. L1 ⪤[R, #0] K2.ⓑ{I}V2 →
-                                ∃∃K1,V1. K1 ⪤[R, V1] K2 & R K1 V1 V2 &
+lemma rex_inv_zero_pair_dx (R): ∀I,L1,K2,V2. L1 ⪤[R,#0] K2.ⓑ{I}V2 →
+                                ∃∃K1,V1. K1 ⪤[R,V1] K2 & R K1 V1 V2 &
                                          L1 = K1.ⓑ{I}V1.
 #R #I #L1 #K2 #V2 #H elim (rex_inv_zero … H) -H *
 [ #_ #H destruct
@@ -163,8 +163,8 @@ lemma rex_inv_zero_pair_dx (R): ∀I,L1,K2,V2. L1 ⪤[R, #0] K2.ⓑ{I}V2 →
 ]
 qed-.
 
-lemma rex_inv_zero_unit_sn (R): ∀I,K1,L2. K1.ⓤ{I} ⪤[R, #0] L2 →
-                                ∃∃f,K2. 𝐈⦃f⦄ & K1 ⪤[cext2 R, cfull, f] K2 &
+lemma rex_inv_zero_unit_sn (R): ∀I,K1,L2. K1.ⓤ{I} ⪤[R,#0] L2 →
+                                ∃∃f,K2. 𝐈⦃f⦄ & K1 ⪤[cext2 R,cfull,f] K2 &
                                         L2 = K2.ⓤ{I}.
 #R #I #K1 #L2 #H elim (rex_inv_zero … H) -H *
 [ #H destruct
@@ -173,8 +173,8 @@ lemma rex_inv_zero_unit_sn (R): ∀I,K1,L2. K1.ⓤ{I} ⪤[R, #0] L2 →
 ]
 qed-.
 
-lemma rex_inv_zero_unit_dx (R): ∀I,L1,K2. L1 ⪤[R, #0] K2.ⓤ{I} →
-                                ∃∃f,K1. 𝐈⦃f⦄ & K1 ⪤[cext2 R, cfull, f] K2 &
+lemma rex_inv_zero_unit_dx (R): ∀I,L1,K2. L1 ⪤[R,#0] K2.ⓤ{I} →
+                                ∃∃f,K1. 𝐈⦃f⦄ & K1 ⪤[cext2 R,cfull,f] K2 &
                                         L1 = K1.ⓤ{I}.
 #R #I #L1 #K2 #H elim (rex_inv_zero … H) -H *
 [ #_ #H destruct
@@ -183,32 +183,32 @@ lemma rex_inv_zero_unit_dx (R): ∀I,L1,K2. L1 ⪤[R, #0] K2.ⓤ{I} →
 ]
 qed-.
 
-lemma rex_inv_lref_bind_sn (R): ∀I1,K1,L2,i. K1.ⓘ{I1} ⪤[R, #↑i] L2 →
-                                ∃∃I2,K2. K1 ⪤[R, #i] K2 & L2 = K2.ⓘ{I2}.
+lemma rex_inv_lref_bind_sn (R): ∀I1,K1,L2,i. K1.ⓘ{I1} ⪤[R,#↑i] L2 →
+                                ∃∃I2,K2. K1 ⪤[R,#i] K2 & L2 = K2.ⓘ{I2}.
 #R #I1 #K1 #L2 #i #H elim (rex_inv_lref … H) -H *
 [ #H destruct
 | #Z1 #I2 #Y1 #K2 #Hi #H1 #H2 destruct /2 width=4 by ex2_2_intro/
 ]
 qed-.
 
-lemma rex_inv_lref_bind_dx (R): ∀I2,K2,L1,i. L1 ⪤[R, #↑i] K2.ⓘ{I2} →
-                                ∃∃I1,K1. K1 ⪤[R, #i] K2 & L1 = K1.ⓘ{I1}.
+lemma rex_inv_lref_bind_dx (R): ∀I2,K2,L1,i. L1 ⪤[R,#↑i] K2.ⓘ{I2} →
+                                ∃∃I1,K1. K1 ⪤[R,#i] K2 & L1 = K1.ⓘ{I1}.
 #R #I2 #K2 #L1 #i #H elim (rex_inv_lref … H) -H *
 [ #_ #H destruct
 | #I1 #Z2 #K1 #Y2 #Hi #H1 #H2 destruct /2 width=4 by ex2_2_intro/
 ]
 qed-.
 
-lemma rex_inv_gref_bind_sn (R): ∀I1,K1,L2,l. K1.ⓘ{I1} ⪤[R, §l] L2 →
-                                ∃∃I2,K2. K1 ⪤[R, §l] K2 & L2 = K2.ⓘ{I2}.
+lemma rex_inv_gref_bind_sn (R): ∀I1,K1,L2,l. K1.ⓘ{I1} ⪤[R,§l] L2 →
+                                ∃∃I2,K2. K1 ⪤[R,§l] K2 & L2 = K2.ⓘ{I2}.
 #R #I1 #K1 #L2 #l #H elim (rex_inv_gref … H) -H *
 [ #H destruct
 | #Z1 #I2 #Y1 #K2 #Hl #H1 #H2 destruct /2 width=4 by ex2_2_intro/
 ]
 qed-.
 
-lemma rex_inv_gref_bind_dx (R): ∀I2,K2,L1,l. L1 ⪤[R, §l] K2.ⓘ{I2} →
-                                ∃∃I1,K1. K1 ⪤[R, §l] K2 & L1 = K1.ⓘ{I1}.
+lemma rex_inv_gref_bind_dx (R): ∀I2,K2,L1,l. L1 ⪤[R,§l] K2.ⓘ{I2} →
+                                ∃∃I1,K1. K1 ⪤[R,§l] K2 & L1 = K1.ⓘ{I1}.
 #R #I2 #K2 #L1 #l #H elim (rex_inv_gref … H) -H *
 [ #_ #H destruct
 | #I1 #Z2 #K1 #Y2 #Hl #H1 #H2 destruct /2 width=4 by ex2_2_intro/
@@ -218,30 +218,30 @@ qed-.
 (* Basic forward lemmas *****************************************************)
 
 lemma rex_fwd_zero_pair (R): ∀I,K1,K2,V1,V2.
-                             K1.ⓑ{I}V1 ⪤[R, #0] K2.ⓑ{I}V2 → K1 ⪤[R, V1] K2.
+                             K1.ⓑ{I}V1 ⪤[R,#0] K2.ⓑ{I}V2 → K1 ⪤[R,V1] K2.
 #R #I #K1 #K2 #V1 #V2 #H
 elim (rex_inv_zero_pair_sn … H) -H #Y #X #HK12 #_ #H destruct //
 qed-.
 
 (* Basic_2A1: uses: llpx_sn_fwd_pair_sn llpx_sn_fwd_bind_sn llpx_sn_fwd_flat_sn *)
-lemma rex_fwd_pair_sn (R): ∀I,L1,L2,V,T. L1 ⪤[R, ②{I}V.T] L2 → L1 ⪤[R, V] L2.
+lemma rex_fwd_pair_sn (R): ∀I,L1,L2,V,T. L1 ⪤[R,②{I}V.T] L2 → L1 ⪤[R,V] L2.
 #R * [ #p ] #I #L1 #L2 #V #T * #f #Hf #HL
 [ elim (frees_inv_bind … Hf) | elim (frees_inv_flat … Hf) ] -Hf
 /4 width=6 by sle_sex_trans, sor_inv_sle_sn, ex2_intro/
 qed-.
 
 (* Basic_2A1: uses: llpx_sn_fwd_bind_dx llpx_sn_fwd_bind_O_dx *)
-lemma rex_fwd_bind_dx (R): ∀p,I,L1,L2,V1,V2,T. L1 ⪤[R, ⓑ{p,I}V1.T] L2 →
-                           R L1 V1 V2 → L1.ⓑ{I}V1 ⪤[R, T] L2.ⓑ{I}V2.
+lemma rex_fwd_bind_dx (R): ∀p,I,L1,L2,V1,V2,T. L1 ⪤[R,ⓑ{p,I}V1.T] L2 →
+                           R L1 V1 V2 → L1.ⓑ{I}V1 ⪤[R,T] L2.ⓑ{I}V2.
 #R #p #I #L1 #L2 #V1 #V2 #T #H #HV elim (rex_inv_bind … H HV) -H -HV //
 qed-.
 
 (* Basic_2A1: uses: llpx_sn_fwd_flat_dx *)
-lemma rex_fwd_flat_dx (R): ∀I,L1,L2,V,T. L1 ⪤[R, ⓕ{I}V.T] L2 → L1 ⪤[R, T] L2.
+lemma rex_fwd_flat_dx (R): ∀I,L1,L2,V,T. L1 ⪤[R,ⓕ{I}V.T] L2 → L1 ⪤[R,T] L2.
 #R #I #L1 #L2 #V #T #H elim (rex_inv_flat … H) -H //
 qed-.
 
-lemma rex_fwd_dx (R): ∀I2,L1,K2,T. L1 ⪤[R, T] K2.ⓘ{I2} →
+lemma rex_fwd_dx (R): ∀I2,L1,K2,T. L1 ⪤[R,T] K2.ⓘ{I2} →
                       ∃∃I1,K1. L1 = K1.ⓘ{I1}.
 #R #I2 #L1 #K2 #T * #f elim (pn_split f) * #g #Hg #_ #Hf destruct
 [ elim (sex_inv_push2 … Hf) | elim (sex_inv_next2 … Hf) ] -Hf #I1 #K1 #_ #_ #H destruct
@@ -250,63 +250,63 @@ qed-.
 
 (* Basic properties *********************************************************)
 
-lemma rex_atom (R): ∀I. ⋆ ⪤[R, ⓪{I}] ⋆.
+lemma rex_atom (R): ∀I. ⋆ ⪤[R,⓪{I}] ⋆.
 #R * /3 width=3 by frees_sort, frees_atom, frees_gref, sex_atom, ex2_intro/
 qed.
 
 lemma rex_sort (R): ∀I1,I2,L1,L2,s.
-                    L1 ⪤[R, ⋆s] L2 → L1.ⓘ{I1} ⪤[R, ⋆s] L2.ⓘ{I2}.
+                    L1 ⪤[R,⋆s] L2 → L1.ⓘ{I1} ⪤[R,⋆s] L2.ⓘ{I2}.
 #R #I1 #I2 #L1 #L2 #s * #f #Hf #H12
 lapply (frees_inv_sort … Hf) -Hf
 /4 width=3 by frees_sort, sex_push, isid_push, ex2_intro/
 qed.
 
-lemma rex_pair (R): ∀I,L1,L2,V1,V2. L1 ⪤[R, V1] L2 →
-                    R L1 V1 V2 → L1.ⓑ{I}V1 ⪤[R, #0] L2.ⓑ{I}V2.
+lemma rex_pair (R): ∀I,L1,L2,V1,V2. L1 ⪤[R,V1] L2 →
+                    R L1 V1 V2 → L1.ⓑ{I}V1 ⪤[R,#0] L2.ⓑ{I}V2.
 #R #I1 #I2 #L1 #L2 #V1 *
 /4 width=3 by ext2_pair, frees_pair, sex_next, ex2_intro/
 qed.
 
-lemma rex_unit (R): ∀f,I,L1,L2. 𝐈⦃f⦄ → L1 ⪤[cext2 R, cfull, f] L2 →
-                    L1.ⓤ{I} ⪤[R, #0] L2.ⓤ{I}.
+lemma rex_unit (R): ∀f,I,L1,L2. 𝐈⦃f⦄ → L1 ⪤[cext2 R,cfull,f] L2 →
+                    L1.ⓤ{I} ⪤[R,#0] L2.ⓤ{I}.
 /4 width=3 by frees_unit, sex_next, ext2_unit, ex2_intro/ qed.
 
 lemma rex_lref (R): ∀I1,I2,L1,L2,i.
-                    L1 ⪤[R, #i] L2 → L1.ⓘ{I1} ⪤[R, #↑i] L2.ⓘ{I2}.
+                    L1 ⪤[R,#i] L2 → L1.ⓘ{I1} ⪤[R,#↑i] L2.ⓘ{I2}.
 #R #I1 #I2 #L1 #L2 #i * /3 width=3 by sex_push, frees_lref, ex2_intro/
 qed.
 
 lemma rex_gref (R): ∀I1,I2,L1,L2,l.
-                    L1 ⪤[R, §l] L2 → L1.ⓘ{I1} ⪤[R, §l] L2.ⓘ{I2}.
+                    L1 ⪤[R,§l] L2 → L1.ⓘ{I1} ⪤[R,§l] L2.ⓘ{I2}.
 #R #I1 #I2 #L1 #L2 #l * #f #Hf #H12
 lapply (frees_inv_gref … Hf) -Hf
 /4 width=3 by frees_gref, sex_push, isid_push, ex2_intro/
 qed.
 
 lemma rex_bind_repl_dx (R): ∀I,I1,L1,L2,T.
-                            L1.ⓘ{I} ⪤[R, T] L2.ⓘ{I1} →
+                            L1.ⓘ{I} ⪤[R,T] L2.ⓘ{I1} →
                             ∀I2. cext2 R L1 I I2 →
-                            L1.ⓘ{I} ⪤[R, T] L2.ⓘ{I2}.
+                            L1.ⓘ{I} ⪤[R,T] L2.ⓘ{I2}.
 #R #I #I1 #L1 #L2 #T * #f #Hf #HL12 #I2 #HR
 /3 width=5 by sex_pair_repl, ex2_intro/
 qed-.
 
 (* Basic_2A1: uses: llpx_sn_co *)
 lemma rex_co (R1) (R2): (∀L,T1,T2. R1 L T1 T2 → R2 L T1 T2) →
-                        ∀L1,L2,T. L1 ⪤[R1, T] L2 → L1 ⪤[R2, T] L2.
+                        ∀L1,L2,T. L1 ⪤[R1,T] L2 → L1 ⪤[R2,T] L2.
 #R1 #R2 #HR #L1 #L2 #T * /5 width=7 by sex_co, cext2_co, ex2_intro/
 qed-.
 
 lemma rex_isid (R1) (R2): ∀L1,L2,T1,T2.
                           (∀f. L1 ⊢ 𝐅*⦃T1⦄ ≘ f → 𝐈⦃f⦄) →
                           (∀f. 𝐈⦃f⦄ → L1 ⊢ 𝐅*⦃T2⦄ ≘ f) →
-                          L1 ⪤[R1, T1] L2 → L1 ⪤[R2, T2] L2.
+                          L1 ⪤[R1,T1] L2 → L1 ⪤[R2,T2] L2.
 #R1 #R2 #L1 #L2 #T1 #T2 #H1 #H2 *
 /4 width=7 by sex_co_isid, ex2_intro/
 qed-.
 
 lemma rex_unit_sn (R1) (R2): 
-                  ∀I,K1,L2. K1.ⓤ{I} ⪤[R1, #0] L2 → K1.ⓤ{I} ⪤[R2, #0] L2.
+                  ∀I,K1,L2. K1.ⓤ{I} ⪤[R1,#0] L2 → K1.ⓤ{I} ⪤[R2,#0] L2.
 #R1 #R2 #I #K1 #L2 #H
 elim (rex_inv_zero_unit_sn … H) -H #f #K2 #Hf #HK12 #H destruct
 /3 width=7 by rex_unit, sex_co_isid/