(* T-BOUND CONTEXT-SENSITIVE PARALLEL RT-TRANSITION FOR TERMS ***************)
(* Basic_2A1: includes: cpr *)
-definition cpm (n) (h): relation4 genv lenv term term ≝
- λG,L,T1,T2. ∃∃c. 𝐑𝐓⦃n, c⦄ & ⦃G, L⦄ ⊢ T1 ⬈[eq_t, c, h] T2.
+definition cpm (h) (G) (L) (n): relation2 term term ≝
+ λT1,T2. ∃∃c. 𝐑𝐓⦃n, c⦄ & ⦃G, L⦄ ⊢ T1 ⬈[eq_t, c, h] T2.
interpretation
- "semi-counted context-sensitive parallel rt-transition (term)"
- 'PRed n h G L T1 T2 = (cpm n h G L T1 T2).
+ "t-bound context-sensitive parallel rt-transition (term)"
+ 'PRed n h G L T1 T2 = (cpm h G L n T1 T2).
interpretation
"context-sensitive parallel r-transition (term)"
- 'PRed h G L T1 T2 = (cpm O h G L T1 T2).
+ 'PRed h G L T1 T2 = (cpm h G L O T1 T2).
(* Basic properties *********************************************************)
qed.
(* Basic_2A1: includes: cpr_zeta *)
-lemma cpm_zeta: ∀n,h,G,L,V,T1,T,T2. ⦃G, L.ⓓV⦄ ⊢ T1 ➡[n, h] T →
- ⬆*[1] T2 ≘ T → ⦃G, L⦄ ⊢ +ⓓV.T1 ➡[n, h] T2.
-#n #h #G #L #V #T1 #T #T2 *
+lemma cpm_zeta (n) (h) (G) (L):
+ ∀T1,T. ⬆*[1] T ≘ T1 → ∀T2. ⦃G, L⦄ ⊢ T ➡[n,h] T2 →
+ ∀V. ⦃G, L⦄ ⊢ +ⓓV.T1 ➡[n, h] T2.
+#n #h #G #L #T1 #T #HT1 #T2 *
/3 width=5 by cpg_zeta, isrt_plus_O2, ex2_intro/
qed.
/6 width=9 by cpg_theta, isrt_plus_O2, isrt_max, isr_shift, ex2_intro/
qed.
-(* Basic properties on r-transition *****************************************)
+(* Basic properties with r-transition ***************************************)
+(* Note: this is needed by cpms_ind_sn and cpms_ind_dx *)
(* Basic_1: includes by definition: pr0_refl *)
(* Basic_2A1: includes: cpr_atom *)
-lemma cpr_refl: ∀h,G,L. reflexive … (cpm 0 h G L).
+lemma cpr_refl: ∀h,G,L. reflexive … (cpm h G L 0).
/3 width=3 by cpg_refl, ex2_intro/ qed.
(* Basic inversion lemmas ***************************************************)
| ∃∃s. T2 = ⋆(next h s) & J = Sort s & n = 1
| ∃∃K,V1,V2. ⦃G, K⦄ ⊢ V1 ➡[n, h] V2 & ⬆*[1] V2 ≘ T2 &
L = K.ⓓV1 & J = LRef 0
- | ∃∃k,K,V1,V2. ⦃G, K⦄ ⊢ V1 ➡[k, h] V2 & ⬆*[1] V2 ≘ T2 &
- L = K.ⓛV1 & J = LRef 0 & n = ↑k
+ | ∃∃m,K,V1,V2. ⦃G, K⦄ ⊢ V1 ➡[m, h] V2 & ⬆*[1] V2 ≘ T2 &
+ L = K.ⓛV1 & J = LRef 0 & n = ↑m
| ∃∃I,K,T,i. ⦃G, K⦄ ⊢ #i ➡[n, h] T & ⬆*[1] T ≘ T2 &
L = K.ⓘ{I} & J = LRef (↑i).
#n #h #J #G #L #T2 * #c #Hc #H elim (cpg_inv_atom1 … H) -H *
| #cV #K #V1 #V2 #HV12 #HVT2 #H1 #H2 #H3 destruct
/4 width=6 by or5_intro2, ex4_3_intro, ex2_intro/
| #cV #K #V1 #V2 #HV12 #HVT2 #H1 #H2 #H3 destruct
- elim (isrt_inv_plus_SO_dx … Hc) -Hc // #k #Hc #H destruct
+ elim (isrt_inv_plus_SO_dx … Hc) -Hc // #m #Hc #H destruct
/4 width=9 by or5_intro3, ex5_4_intro, ex2_intro/
| #I #K #V2 #i #HV2 #HVT2 #H1 #H2 destruct
/4 width=8 by or5_intro4, ex4_4_intro, ex2_intro/
qed-.
lemma cpm_inv_sort1: ∀n,h,G,L,T2,s. ⦃G, L⦄ ⊢ ⋆s ➡[n,h] T2 →
- â\88¨â\88¨ T2 = â\8b\86s â\88§ n = 0
- | T2 = ⋆(next h s) ∧ n = 1.
-#n #h #G #L #T2 #s * #c #Hc #H elim (cpg_inv_sort1 … H) -H *
-#H1 #H2 destruct
-/4 width=1 by isrt_inv_01, isrt_inv_00, or_introl, or_intror, conj/
+ â\88§â\88§ T2 = â\8b\86(((next h)^n) s) & n â\89¤ 1.
+#n #h #G #L #T2 #s * #c #Hc #H
+elim (cpg_inv_sort1 … H) -H * #H1 #H2 destruct
+[ lapply (isrt_inv_00 … Hc) | lapply (isrt_inv_01 … Hc) ] -Hc
+#H destruct /2 width=1 by conj/
qed-.
lemma cpm_inv_zero1: ∀n,h,G,L,T2. ⦃G, L⦄ ⊢ #0 ➡[n, h] T2 →
∨∨ T2 = #0 ∧ n = 0
| ∃∃K,V1,V2. ⦃G, K⦄ ⊢ V1 ➡[n, h] V2 & ⬆*[1] V2 ≘ T2 &
L = K.ⓓV1
- | ∃∃k,K,V1,V2. ⦃G, K⦄ ⊢ V1 ➡[k, h] V2 & ⬆*[1] V2 ≘ T2 &
- L = K.ⓛV1 & n = ↑k.
+ | ∃∃m,K,V1,V2. ⦃G, K⦄ ⊢ V1 ➡[m, h] V2 & ⬆*[1] V2 ≘ T2 &
+ L = K.ⓛV1 & n = ↑m.
#n #h #G #L #T2 * #c #Hc #H elim (cpg_inv_zero1 … H) -H *
[ #H1 #H2 destruct /4 width=1 by isrt_inv_00, or3_intro0, conj/
| #cV #K #V1 #V2 #HV12 #HVT2 #H1 #H2 destruct
/4 width=8 by or3_intro1, ex3_3_intro, ex2_intro/
| #cV #K #V1 #V2 #HV12 #HVT2 #H1 #H2 destruct
- elim (isrt_inv_plus_SO_dx … Hc) -Hc // #k #Hc #H destruct
+ elim (isrt_inv_plus_SO_dx … Hc) -Hc // #m #Hc #H destruct
/4 width=8 by or3_intro2, ex4_4_intro, ex2_intro/
]
qed-.
lemma cpm_inv_bind1: ∀n,h,p,I,G,L,V1,T1,U2. ⦃G, L⦄ ⊢ ⓑ{p,I}V1.T1 ➡[n, h] U2 →
∨∨ ∃∃V2,T2. ⦃G, L⦄ ⊢ V1 ➡[h] V2 & ⦃G, L.ⓑ{I}V1⦄ ⊢ T1 ➡[n, h] T2 &
U2 = ⓑ{p,I}V2.T2
- | â\88\83â\88\83T. â¦\83G, L.â\93\93V1â¦\84 â\8a¢ T1 â\9e¡[n, h] T & â¬\86*[1] U2 â\89\98 T &
+ | â\88\83â\88\83T. â¬\86*[1] T â\89\98 T1 & â¦\83G, Lâ¦\84 â\8a¢ T â\9e¡[n, h] U2 &
p = true & I = Abbr.
#n #h #p #I #G #L #V1 #T1 #U2 * #c #Hc #H elim (cpg_inv_bind1 … H) -H *
[ #cV #cT #V2 #T2 #HV12 #HT12 #H1 #H2 destruct
elim (isrt_inv_max … Hc) -Hc #nV #nT #HcV #HcT #H destruct
elim (isrt_inv_shift … HcV) -HcV #HcV #H destruct
/4 width=5 by ex3_2_intro, ex2_intro, or_introl/
-| #cT #T2 #HT12 #HUT2 #H1 #H2 #H3 destruct
- /5 width=3 by isrt_inv_plus_O_dx, ex4_intro, ex2_intro, or_intror/
+| #cT #T2 #HT21 #HTU2 #H1 #H2 #H3 destruct
+ /5 width=5 by isrt_inv_plus_O_dx, ex4_intro, ex2_intro, or_intror/
]
qed-.
lemma cpm_inv_abbr1: ∀n,h,p,G,L,V1,T1,U2. ⦃G, L⦄ ⊢ ⓓ{p}V1.T1 ➡[n, h] U2 →
∨∨ ∃∃V2,T2. ⦃G, L⦄ ⊢ V1 ➡[h] V2 & ⦃G, L.ⓓV1⦄ ⊢ T1 ➡[n, h] T2 &
U2 = ⓓ{p}V2.T2
- | ∃∃T. ⦃G, L.ⓓV1⦄ ⊢ T1 ➡[n, h] T & ⬆*[1] U2 ≘ T & p = true.
-#n #h #p #G #L #V1 #T1 #U2 * #c #Hc #H elim (cpg_inv_abbr1 … H) -H *
-[ #cV #cT #V2 #T2 #HV12 #HT12 #H1 #H2 destruct
- elim (isrt_inv_max … Hc) -Hc #nV #nT #HcV #HcT #H destruct
- elim (isrt_inv_shift … HcV) -HcV #HcV #H destruct
- /4 width=5 by ex3_2_intro, ex2_intro, or_introl/
-| #cT #T2 #HT12 #HUT2 #H1 #H2 destruct
- /5 width=3 by isrt_inv_plus_O_dx, ex3_intro, ex2_intro, or_intror/
+ | ∃∃T. ⬆*[1] T ≘ T1 & ⦃G, L⦄ ⊢ T ➡[n, h] U2 & p = true.
+#n #h #p #G #L #V1 #T1 #U2 #H
+elim (cpm_inv_bind1 … H) -H
+[ /3 width=1 by or_introl/
+| * /3 width=3 by ex3_intro, or_intror/
]
qed-.
lemma cpm_inv_abst1: ∀n,h,p,G,L,V1,T1,U2. ⦃G, L⦄ ⊢ ⓛ{p}V1.T1 ➡[n, h] U2 →
∃∃V2,T2. ⦃G, L⦄ ⊢ V1 ➡[h] V2 & ⦃G, L.ⓛV1⦄ ⊢ T1 ➡[n, h] T2 &
U2 = ⓛ{p}V2.T2.
-#n #h #p #G #L #V1 #T1 #U2 * #c #Hc #H elim (cpg_inv_abst1 … H) -H
-#cV #cT #V2 #T2 #HV12 #HT12 #H1 #H2 destruct
-elim (isrt_inv_max … Hc) -Hc #nV #nT #HcV #HcT #H destruct
-elim (isrt_inv_shift … HcV) -HcV #HcV #H destruct
-/3 width=5 by ex3_2_intro, ex2_intro/
+#n #h #p #G #L #V1 #T1 #U2 #H
+elim (cpm_inv_bind1 … H) -H
+[ /3 width=1 by or_introl/
+| * #T #_ #_ #_ #H destruct
+]
qed-.
(* Basic_1: includes: pr0_gen_appl pr2_gen_appl *)
∨∨ ∃∃V2,T2. ⦃G, L⦄ ⊢ V1 ➡[n, h] V2 & ⦃G, L⦄ ⊢ U1 ➡[n, h] T2 &
U2 = ⓝV2.T2
| ⦃G, L⦄ ⊢ U1 ➡[n, h] U2
- | ∃∃k. ⦃G, L⦄ ⊢ V1 ➡[k, h] U2 & n = ↑k.
+ | ∃∃m. ⦃G, L⦄ ⊢ V1 ➡[m, h] U2 & n = ↑m.
#n #h #G #L #V1 #U1 #U2 * #c #Hc #H elim (cpg_inv_cast1 … H) -H *
[ #cV #cT #V2 #T2 #HV12 #HT12 #HcVT #H1 #H2 destruct
elim (isrt_inv_max … Hc) -Hc #nV #nT #HcV #HcT #H destruct
| #cU #U12 #H destruct
/4 width=3 by isrt_inv_plus_O_dx, or3_intro1, ex2_intro/
| #cU #H12 #H destruct
- elim (isrt_inv_plus_SO_dx … Hc) -Hc // #k #Hc #H destruct
+ elim (isrt_inv_plus_SO_dx … Hc) -Hc // #m #Hc #H destruct
/4 width=3 by or3_intro2, ex2_intro/
]
qed-.
#n #h #I #G #L #V1 #T1 #T * #c #Hc #H #p elim (cpg_fwd_bind1_minus … H p) -H
/3 width=4 by ex2_2_intro, ex2_intro/
qed-.
+
+(* Basic eliminators ********************************************************)
+
+lemma cpm_ind (h): ∀Q:relation5 nat genv lenv term term.
+ (∀I,G,L. Q 0 G L (⓪{I}) (⓪{I})) →
+ (∀G,L,s. Q 1 G L (⋆s) (⋆(next h s))) →
+ (∀n,G,K,V1,V2,W2. ⦃G, K⦄ ⊢ V1 ➡[n, h] V2 → Q n G K V1 V2 →
+ ⬆*[1] V2 ≘ W2 → Q n G (K.ⓓV1) (#0) W2
+ ) → (∀n,G,K,V1,V2,W2. ⦃G, K⦄ ⊢ V1 ➡[n, h] V2 → Q n G K V1 V2 →
+ ⬆*[1] V2 ≘ W2 → Q (↑n) G (K.ⓛV1) (#0) W2
+ ) → (∀n,I,G,K,T,U,i. ⦃G, K⦄ ⊢ #i ➡[n, h] T → Q n G K (#i) T →
+ ⬆*[1] T ≘ U → Q n G (K.ⓘ{I}) (#↑i) (U)
+ ) → (∀n,p,I,G,L,V1,V2,T1,T2. ⦃G, L⦄ ⊢ V1 ➡[h] V2 → ⦃G, L.ⓑ{I}V1⦄ ⊢ T1 ➡[n, h] T2 →
+ Q 0 G L V1 V2 → Q n G (L.ⓑ{I}V1) T1 T2 → Q n G L (ⓑ{p,I}V1.T1) (ⓑ{p,I}V2.T2)
+ ) → (∀n,G,L,V1,V2,T1,T2. ⦃G, L⦄ ⊢ V1 ➡[h] V2 → ⦃G, L⦄ ⊢ T1 ➡[n, h] T2 →
+ Q 0 G L V1 V2 → Q n G L T1 T2 → Q n G L (ⓐV1.T1) (ⓐV2.T2)
+ ) → (∀n,G,L,V1,V2,T1,T2. ⦃G, L⦄ ⊢ V1 ➡[n, h] V2 → ⦃G, L⦄ ⊢ T1 ➡[n, h] T2 →
+ Q n G L V1 V2 → Q n G L T1 T2 → Q n G L (ⓝV1.T1) (ⓝV2.T2)
+ ) → (∀n,G,L,V,T1,T,T2. ⬆*[1] T ≘ T1 → ⦃G, L⦄ ⊢ T ➡[n, h] T2 →
+ Q n G L T T2 → Q n G L (+ⓓV.T1) T2
+ ) → (∀n,G,L,V,T1,T2. ⦃G, L⦄ ⊢ T1 ➡[n, h] T2 →
+ Q n G L T1 T2 → Q n G L (ⓝV.T1) T2
+ ) → (∀n,G,L,V1,V2,T. ⦃G, L⦄ ⊢ V1 ➡[n, h] V2 →
+ Q n G L V1 V2 → Q (↑n) G L (ⓝV1.T) V2
+ ) → (∀n,p,G,L,V1,V2,W1,W2,T1,T2. ⦃G, L⦄ ⊢ V1 ➡[h] V2 → ⦃G, L⦄ ⊢ W1 ➡[h] W2 → ⦃G, L.ⓛW1⦄ ⊢ T1 ➡[n, h] T2 →
+ Q 0 G L V1 V2 → Q 0 G L W1 W2 → Q n G (L.ⓛW1) T1 T2 →
+ Q n G L (ⓐV1.ⓛ{p}W1.T1) (ⓓ{p}ⓝW2.V2.T2)
+ ) → (∀n,p,G,L,V1,V,V2,W1,W2,T1,T2. ⦃G, L⦄ ⊢ V1 ➡[h] V → ⦃G, L⦄ ⊢ W1 ➡[h] W2 → ⦃G, L.ⓓW1⦄ ⊢ T1 ➡[n, h] T2 →
+ Q 0 G L V1 V → Q 0 G L W1 W2 → Q n G (L.ⓓW1) T1 T2 →
+ ⬆*[1] V ≘ V2 → Q n G L (ⓐV1.ⓓ{p}W1.T1) (ⓓ{p}W2.ⓐV2.T2)
+ ) →
+ ∀n,G,L,T1,T2. ⦃G, L⦄ ⊢ T1 ➡[n, h] T2 → Q n G L T1 T2.
+#h #Q #IH1 #IH2 #IH3 #IH4 #IH5 #IH6 #IH7 #IH8 #IH9 #IH10 #IH11 #IH12 #IH13 #n #G #L #T1 #T2
+* #c #HC #H generalize in match HC; -HC generalize in match n; -n
+elim H -c -G -L -T1 -T2
+[ #I #G #L #n #H <(isrt_inv_00 … H) -H //
+| #G #L #s #n #H <(isrt_inv_01 … H) -H //
+| /3 width=4 by ex2_intro/
+| #c #G #L #V1 #V2 #W2 #HV12 #HVW2 #IH #x #H
+ elim (isrt_inv_plus_SO_dx … H) -H // #n #Hc #H destruct
+ /3 width=4 by ex2_intro/
+| /3 width=4 by ex2_intro/
+| #cV #cT #p #I #G #L #V1 #V2 #T1 #T2 #HV12 #HT12 #IHV #IHT #n #H
+ elim (isrt_inv_max_shift_sn … H) -H #HcV #HcT
+ /3 width=3 by ex2_intro/
+| #cV #cT #G #L #V1 #V2 #T1 #T2 #HV12 #HT12 #IHV #IHT #n #H
+ elim (isrt_inv_max_shift_sn … H) -H #HcV #HcT
+ /3 width=3 by ex2_intro/
+| #cU #cT #G #L #U1 #U2 #T1 #T2 #HUT #HU12 #HT12 #IHU #IHT #n #H
+ elim (isrt_inv_max_eq_t … H) -H // #HcV #HcT
+ /3 width=3 by ex2_intro/
+| #c #G #L #V #T1 #T #T2 #HT1 #HT2 #IH #n #H
+ lapply (isrt_inv_plus_O_dx … H ?) -H // #Hc
+ /3 width=4 by ex2_intro/
+| #c #G #L #U #T1 #T2 #HT12 #IH #n #H
+ lapply (isrt_inv_plus_O_dx … H ?) -H // #Hc
+ /3 width=3 by ex2_intro/
+| #c #G #L #U1 #U2 #T #HU12 #IH #x #H
+ elim (isrt_inv_plus_SO_dx … H) -H // #n #Hc #H destruct
+ /3 width=3 by ex2_intro/
+| #cV #cW #cT #p #G #L #V1 #V2 #W1 #W2 #T1 #T2 #HV12 #HW12 #HT12 #IHV #IHW #IHT #n #H
+ lapply (isrt_inv_plus_O_dx … H ?) -H // >max_shift #H
+ elim (isrt_inv_max_shift_sn … H) -H #H #HcT
+ elim (isrt_O_inv_max … H) -H #HcV #HcW
+ /3 width=3 by ex2_intro/
+| #cV #cW #cT #p #G #L #V1 #V #V2 #W1 #W2 #T1 #T2 #HV1 #HV2 #HW12 #HT12 #IHV #IHW #IHT #n #H
+ lapply (isrt_inv_plus_O_dx … H ?) -H // >max_shift #H
+ elim (isrt_inv_max_shift_sn … H) -H #H #HcT
+ elim (isrt_O_inv_max … H) -H #HcV #HcW
+ /3 width=4 by ex2_intro/
+]
+qed-.