(* *)
(**************************************************************************)
-include "basic_2/notation/relations/predsnstar_4.ma".
-include "basic_2/relocation/lex.ma".
+include "basic_2/notation/relations/predsnstar_5.ma".
+include "static_2/relocation/lex.ma".
include "basic_2/rt_computation/cprs_ext.ma".
(* PARALLEL R-COMPUTATION FOR FULL LOCAL ENVIRONMENTS ***********************)
-definition lprs (h) (G): relation lenv ≝
- lex (λL.cpms h G L 0).
+definition lprs (h) (n) (G): relation lenv ≝
+ lex (λL.cpms h G L n).
interpretation
"parallel r-computation on all entries (local environment)"
- 'PRedSnStar h G L1 L2 = (lprs h G L1 L2).
+ 'PRedSnStar h n G L1 L2 = (lprs h n G L1 L2).
(* Basic properties *********************************************************)
(* Basic_2A1: uses: lprs_pair_refl *)
-lemma lprs_bind_refl_dx (h) (G): â\88\80L1,L2. â¦\83G, L1â¦\84 â\8a¢ â\9e¡*[h] L2 →
- â\88\80I. â¦\83G, L1.â\93\98{I}â¦\84 â\8a¢ â\9e¡*[h] L2.â\93\98{I}.
+lemma lprs_bind_refl_dx (h) (G): â\88\80L1,L2. â\9dªG,L1â\9d« â\8a¢ â\9e¡*[h,0] L2 →
+ â\88\80I. â\9dªG,L1.â\93\98[I]â\9d« â\8a¢ â\9e¡*[h,0] L2.â\93\98[I].
/2 width=1 by lex_bind_refl_dx/ qed.
-lemma lprs_pair (h) (G): â\88\80L1,L2. â¦\83G, L1â¦\84 â\8a¢ â\9e¡*[h] L2 →
- â\88\80V1,V2. â¦\83G, L1â¦\84 â\8a¢ V1 â\9e¡*[h] V2 →
- â\88\80I. â¦\83G, L1.â\93\91{I}V1â¦\84 â\8a¢ â\9e¡*[h] L2.â\93\91{I}V2.
+lemma lprs_pair (h) (G): â\88\80L1,L2. â\9dªG,L1â\9d« â\8a¢ â\9e¡*[h,0] L2 →
+ â\88\80V1,V2. â\9dªG,L1â\9d« â\8a¢ V1 â\9e¡*[h,0] V2 →
+ â\88\80I. â\9dªG,L1.â\93\91[I]V1â\9d« â\8a¢ â\9e¡*[h,0] L2.â\93\91[I]V2.
/2 width=1 by lex_pair/ qed.
-lemma lprs_refl (h) (G): â\88\80L. â¦\83G, Lâ¦\84 â\8a¢ â\9e¡*[h] L.
+lemma lprs_refl (h) (G): â\88\80L. â\9dªG,Lâ\9d« â\8a¢ â\9e¡*[h,0] L.
/2 width=1 by lex_refl/ qed.
(* Basic inversion lemmas ***************************************************)
(* Basic_2A1: uses: lprs_inv_atom1 *)
-lemma lprs_inv_atom_sn (h) (G): â\88\80L2. â¦\83G, â\8b\86â¦\84 â\8a¢ â\9e¡*[h] L2 → L2 = ⋆.
+lemma lprs_inv_atom_sn (h) (G): â\88\80L2. â\9dªG,â\8b\86â\9d« â\8a¢ â\9e¡*[h,0] L2 → L2 = ⋆.
/2 width=2 by lex_inv_atom_sn/ qed-.
(* Basic_2A1: was: lprs_inv_pair1 *)
lemma lprs_inv_pair_sn (h) (G):
- â\88\80I,K1,L2,V1. â¦\83G, K1.â\93\91{I}V1â¦\84 â\8a¢ â\9e¡*[h] L2 →
- â\88\83â\88\83K2,V2. â¦\83G, K1â¦\84 â\8a¢ â\9e¡*[h] K2 & â¦\83G, K1â¦\84 â\8a¢ V1 â\9e¡*[h] V2 & L2 = K2.â\93\91{I}V2.
+ â\88\80I,K1,L2,V1. â\9dªG,K1.â\93\91[I]V1â\9d« â\8a¢ â\9e¡*[h,0] L2 →
+ â\88\83â\88\83K2,V2. â\9dªG,K1â\9d« â\8a¢ â\9e¡*[h,0] K2 & â\9dªG,K1â\9d« â\8a¢ V1 â\9e¡*[h,0] V2 & L2 = K2.â\93\91[I]V2.
/2 width=1 by lex_inv_pair_sn/ qed-.
(* Basic_2A1: uses: lprs_inv_atom2 *)
-lemma lprs_inv_atom_dx (h) (G): â\88\80L1. â¦\83G, L1â¦\84 â\8a¢ â\9e¡*[h] ⋆ → L1 = ⋆.
+lemma lprs_inv_atom_dx (h) (G): â\88\80L1. â\9dªG,L1â\9d« â\8a¢ â\9e¡*[h,0] ⋆ → L1 = ⋆.
/2 width=2 by lex_inv_atom_dx/ qed-.
(* Basic_2A1: was: lprs_inv_pair2 *)
lemma lprs_inv_pair_dx (h) (G):
- â\88\80I,L1,K2,V2. â¦\83G, L1â¦\84 â\8a¢ â\9e¡*[h] K2.â\93\91{I}V2 →
- â\88\83â\88\83K1,V1. â¦\83G, K1â¦\84 â\8a¢ â\9e¡*[h] K2 & â¦\83G, K1â¦\84 â\8a¢ V1 â\9e¡*[h] V2 & L1 = K1.â\93\91{I}V1.
+ â\88\80I,L1,K2,V2. â\9dªG,L1â\9d« â\8a¢ â\9e¡*[h,0] K2.â\93\91[I]V2 →
+ â\88\83â\88\83K1,V1. â\9dªG,K1â\9d« â\8a¢ â\9e¡*[h,0] K2 & â\9dªG,K1â\9d« â\8a¢ V1 â\9e¡*[h,0] V2 & L1 = K1.â\93\91[I]V1.
/2 width=1 by lex_inv_pair_dx/ qed-.
(* Basic eliminators ********************************************************)
lemma lprs_ind (h) (G): ∀Q:relation lenv.
Q (⋆) (⋆) → (
∀I,K1,K2.
- â¦\83G, K1â¦\84 â\8a¢ â\9e¡*[h] K2 →
- Q K1 K2 → Q (K1.ⓘ{I}) (K2.ⓘ{I})
+ â\9dªG,K1â\9d« â\8a¢ â\9e¡*[h,0] K2 →
+ Q K1 K2 → Q (K1.ⓘ[I]) (K2.ⓘ[I])
) → (
∀I,K1,K2,V1,V2.
- â¦\83G, K1â¦\84 â\8a¢ â\9e¡*[h] K2 â\86\92 â¦\83G, K1â¦\84 â\8a¢ V1 â\9e¡*[h] V2 →
- Q K1 K2 → Q (K1.ⓑ{I}V1) (K2.ⓑ{I}V2)
+ â\9dªG,K1â\9d« â\8a¢ â\9e¡*[h,0] K2 â\86\92 â\9dªG,K1â\9d« â\8a¢ V1 â\9e¡*[h,0] V2 →
+ Q K1 K2 → Q (K1.ⓑ[I]V1) (K2.ⓑ[I]V2)
) →
- â\88\80L1,L2. â¦\83G, L1â¦\84 â\8a¢ â\9e¡*[h] L2 → Q L1 L2.
+ â\88\80L1,L2. â\9dªG,L1â\9d« â\8a¢ â\9e¡*[h,0] L2 → Q L1 L2.
/3 width=4 by lex_ind/ qed-.