(* *)
(**************************************************************************)
-include "basic_2/relocation/lift_neg.ma".
-include "basic_2/relocation/ldrop_ldrop.ma".
-include "basic_2/relocation/llpx_sn.ma".
+include "basic_2/multiple/frees.ma".
+include "basic_2/multiple/llpx_sn_alt_rec.ma".
(* LAZY SN POINTWISE EXTENSION OF A CONTEXT-SENSITIVE REALTION FOR TERMS ****)
-(* alternative definition of llpx_sn_alt *)
-inductive llpx_sn_alt (R:relation3 lenv term term): relation4 ynat term lenv lenv ≝
-| llpx_sn_alt_intro: ∀L1,L2,T,d.
- (∀I1,I2,K1,K2,V1,V2,i. d ≤ yinj i → (∀U. ⇧[i, 1] U ≡ T → ⊥) →
- ⇩[i] L1 ≡ K1.ⓑ{I1}V1 → ⇩[i] L2 ≡ K2.ⓑ{I2}V2 → I1 = I2 ∧ R K1 V1 V2
- ) →
- (∀I1,I2,K1,K2,V1,V2,i. d ≤ yinj i → (∀U. ⇧[i, 1] U ≡ T → ⊥) →
- ⇩[i] L1 ≡ K1.ⓑ{I1}V1 → ⇩[i] L2 ≡ K2.ⓑ{I2}V2 → llpx_sn_alt R 0 V1 K1 K2
- ) → |L1| = |L2| → llpx_sn_alt R d T L1 L2
-.
-
-(* Basic forward lemmas ******************************************************)
-
-lemma llpx_sn_alt_fwd_gen: ∀R,L1,L2,T,d. llpx_sn_alt R d T L1 L2 →
- |L1| = |L2| ∧
- ∀I1,I2,K1,K2,V1,V2,i. d ≤ yinj i → (∀U. ⇧[i, 1] U ≡ T → ⊥) →
- ⇩[i] L1 ≡ K1.ⓑ{I1}V1 → ⇩[i] L2 ≡ K2.ⓑ{I2}V2 →
- ∧∧ I1 = I2 & R K1 V1 V2 & llpx_sn_alt R 0 V1 K1 K2.
-#R #L1 #L2 #T #d * -L1 -L2 -T -d
-#L1 #L2 #T #d #IH1 #IH2 #HL12 @conj //
-#I1 #I2 #K1 #K2 #HLK1 #HLK2 #i #Hid #HnT #HLK1 #HLK2
-elim (IH1 … HnT HLK1 HLK2) -IH1 /4 width=8 by and3_intro/
-qed-.
-
-lemma llpx_sn_alt_fwd_length: ∀R,L1,L2,T,d. llpx_sn_alt R d T L1 L2 → |L1| = |L2|.
-#R #L1 #L2 #T #d * -L1 -L2 -T -d //
-qed-.
-
-fact llpx_sn_alt_fwd_lref_aux: ∀R,L1,L2,X,d. llpx_sn_alt R d X L1 L2 → ∀i. X = #i →
- ∨∨ |L1| ≤ i ∧ |L2| ≤ i
- | yinj i < d
- | ∃∃I,K1,K2,V1,V2. ⇩[i] L1 ≡ K1.ⓑ{I}V1 &
- ⇩[i] L2 ≡ K2.ⓑ{I}V2 &
- llpx_sn_alt R (yinj 0) V1 K1 K2 &
- R K1 V1 V2 & d ≤ yinj i.
-#R #L1 #L2 #X #d * -L1 -L2 -X -d
-#L1 #L2 #X #d #H1X #H2X #HL12 #i #H destruct
-elim (lt_or_ge i (|L1|)) /3 width=1 by or3_intro0, conj/
-elim (ylt_split i d) /3 width=1 by or3_intro1/
-#Hdi #HL1 elim (ldrop_O1_lt … HL1) #I1 #K1 #V1 #HLK1
-elim (ldrop_O1_lt L2 i) // #I2 #K2 #V2 #HLK2
-elim (H1X … HLK1 HLK2) -H1X /2 width=3 by nlift_lref_be_SO/ #H #HV12 destruct
-lapply (H2X … HLK1 HLK2) -H2X /2 width=3 by nlift_lref_be_SO/
-/3 width=9 by or3_intro2, ex5_5_intro/
-qed-.
-
-lemma llpx_sn_alt_fwd_lref: ∀R,L1,L2,d,i. llpx_sn_alt R d (#i) L1 L2 →
- ∨∨ |L1| ≤ i ∧ |L2| ≤ i
- | yinj i < d
- | ∃∃I,K1,K2,V1,V2. ⇩[i] L1 ≡ K1.ⓑ{I}V1 &
- ⇩[i] L2 ≡ K2.ⓑ{I}V2 &
- llpx_sn_alt R (yinj 0) V1 K1 K2 &
- R K1 V1 V2 & d ≤ yinj i.
-/2 width=3 by llpx_sn_alt_fwd_lref_aux/ qed-.
-
-(* Basic inversion lemmas ****************************************************)
-
-fact llpx_sn_alt_inv_flat_aux: ∀R,L1,L2,X,d. llpx_sn_alt R d X L1 L2 →
- ∀I,V,T. X = ⓕ{I}V.T →
- llpx_sn_alt R d V L1 L2 ∧ llpx_sn_alt R d T L1 L2.
-#R #L1 #L2 #X #d * -L1 -L2 -X -d
-#L1 #L2 #X #d #H1X #H2X #HL12
-#I #V #T #H destruct
-@conj @llpx_sn_alt_intro // -HL12
-/4 width=8 by nlift_flat_sn, nlift_flat_dx/
-qed-.
-
-lemma llpx_sn_alt_inv_flat: ∀R,I,L1,L2,V,T,d. llpx_sn_alt R d (ⓕ{I}V.T) L1 L2 →
- llpx_sn_alt R d V L1 L2 ∧ llpx_sn_alt R d T L1 L2.
-/2 width=4 by llpx_sn_alt_inv_flat_aux/ qed-.
-
-fact llpx_sn_alt_inv_bind_aux: ∀R,L1,L2,X,d. llpx_sn_alt R d X L1 L2 →
- ∀a,I,V,T. X = ⓑ{a,I}V.T →
- llpx_sn_alt R d V L1 L2 ∧ llpx_sn_alt R (⫯d) T (L1.ⓑ{I}V) (L2.ⓑ{I}V).
-#R #L1 #L2 #X #d * -L1 -L2 -X -d
-#L1 #L2 #X #d #H1X #H2X #HL12
-#a #I #V #T #H destruct
-@conj @llpx_sn_alt_intro [3,6: normalize /2 width=1 by eq_f2/ ] -HL12
-#I1 #I2 #K1 #K2 #W1 #W2 #i #Hdi #H #HLK1 #HLK2
-[1,2: /4 width=9 by nlift_bind_sn/ ]
-lapply (yle_inv_succ1 … Hdi) -Hdi * #Hdi #Hi
-lapply (ldrop_inv_drop1_lt … HLK1 ?) -HLK1 /2 width=1 by ylt_O/ #HLK1
-lapply (ldrop_inv_drop1_lt … HLK2 ?) -HLK2 /2 width=1 by ylt_O/ #HLK2
-[ @(H1X … HLK1 HLK2) | @(H2X … HLK1 HLK2) ] // -I1 -I2 -L1 -L2 -K1 -K2 -W1 -W2
-@nlift_bind_dx <plus_minus_m_m /2 width=2 by ylt_O/
-qed-.
-
-lemma llpx_sn_alt_inv_bind: ∀R,a,I,L1,L2,V,T,d. llpx_sn_alt R d (ⓑ{a,I}V.T) L1 L2 →
- llpx_sn_alt R d V L1 L2 ∧ llpx_sn_alt R (⫯d) T (L1.ⓑ{I}V) (L2.ⓑ{I}V).
-/2 width=4 by llpx_sn_alt_inv_bind_aux/ qed-.
-
-(* Basic properties **********************************************************)
-
-lemma llpx_sn_alt_intro_alt: ∀R,L1,L2,T,d. |L1| = |L2| →
- (∀I1,I2,K1,K2,V1,V2,i. d ≤ yinj i → (∀U. ⇧[i, 1] U ≡ T → ⊥) →
- ⇩[i] L1 ≡ K1.ⓑ{I1}V1 → ⇩[i] L2 ≡ K2.ⓑ{I2}V2 →
- ∧∧ I1 = I2 & R K1 V1 V2 & llpx_sn_alt R 0 V1 K1 K2
- ) → llpx_sn_alt R d T L1 L2.
-#R #L1 #L2 #T #d #HL12 #IH @llpx_sn_alt_intro // -HL12
-#I1 #I2 #K1 #K2 #HLK1 #HLK2 #i #Hid #HnT #HLK1 #HLK2
-elim (IH … HnT HLK1 HLK2) -IH -HnT -HLK1 -HLK2 /2 width=1 by conj/
-qed.
-
-lemma llpx_sn_alt_sort: ∀R,L1,L2,d,k. |L1| = |L2| → llpx_sn_alt R d (⋆k) L1 L2.
-#R #L1 #L2 #d #k #HL12 @llpx_sn_alt_intro // -HL12
-#I1 #I2 #K1 #K2 #V1 #V2 #i #_ #H elim (H (⋆k)) //
-qed.
-
-lemma llpx_sn_alt_gref: ∀R,L1,L2,d,p. |L1| = |L2| → llpx_sn_alt R d (§p) L1 L2.
-#R #L1 #L2 #d #p #HL12 @llpx_sn_alt_intro // -HL12
-#I1 #I2 #K1 #K2 #V1 #V2 #i #_ #H elim (H (§p)) //
-qed.
-
-lemma llpx_sn_alt_skip: ∀R,L1,L2,d,i. |L1| = |L2| → yinj i < d → llpx_sn_alt R d (#i) L1 L2.
-#R #L1 #L2 #d #i #HL12 #Hid @llpx_sn_alt_intro // -HL12
-#I1 #I2 #K1 #K2 #V1 #V2 #j #Hdj #H elim (H (#i)) -H
-/4 width=3 by lift_lref_lt, ylt_yle_trans, ylt_inv_inj/
-qed.
-
-lemma llpx_sn_alt_free: ∀R,L1,L2,d,i. |L1| ≤ i → |L2| ≤ i → |L1| = |L2| →
- llpx_sn_alt R d (#i) L1 L2.
-#R #L1 #L2 #d #i #HL1 #_ #HL12 @llpx_sn_alt_intro // -HL12
-#I1 #I2 #K1 #K2 #V1 #V2 #j #_ #H #HLK1 elim (H (#(i-1))) -H
-lapply (ldrop_fwd_length_lt2 … HLK1) -HLK1
-/3 width=3 by lift_lref_ge_minus, lt_to_le_to_lt/
-qed.
-
-lemma llpx_sn_alt_lref: ∀R,I,L1,L2,K1,K2,V1,V2,d,i. d ≤ yinj i →
- ⇩[i] L1 ≡ K1.ⓑ{I}V1 → ⇩[i] L2 ≡ K2.ⓑ{I}V2 →
- llpx_sn_alt R 0 V1 K1 K2 → R K1 V1 V2 →
- llpx_sn_alt R d (#i) L1 L2.
-#R #I #L1 #L2 #K1 #K2 #V1 #V2 #d #i #Hdi #HLK1 #HLK2 #HK12 #HV12 @llpx_sn_alt_intro
-[1,2: #Z1 #Z2 #Y1 #Y2 #X1 #X2 #j #Hdj #H #HLY1 #HLY2
- elim (lt_or_eq_or_gt i j) #Hij destruct
- [1,4: elim (H (#i)) -H /2 width=1 by lift_lref_lt/
- |2,5: lapply (ldrop_mono … HLY1 … HLK1) -HLY1 -HLK1 #H destruct
- lapply (ldrop_mono … HLY2 … HLK2) -HLY2 -HLK2 #H destruct /2 width=1 by conj/
- |3,6: elim (H (#(i-1))) -H /2 width=1 by lift_lref_ge_minus/
- ]
-| lapply (llpx_sn_alt_fwd_length … HK12) -HK12 #HK12
- @(ldrop_fwd_length_eq2 … HLK1 HLK2) normalize /2 width=1 by eq_f2/
-]
-qed.
-
-fact llpx_sn_alt_flat_aux: ∀R,I,L1,L2,V,d. llpx_sn_alt R d V L1 L2 →
- ∀Y1,Y2,T,m. llpx_sn_alt R m T Y1 Y2 →
- Y1 = L1 → Y2 = L2 → m = d →
- llpx_sn_alt R d (ⓕ{I}V.T) L1 L2.
-#R #I #L1 #L2 #V #d * -L1 -L2 -V -d #L1 #L2 #V #d #H1V #H2V #HL12
-#Y1 #Y2 #T #m * -Y1 -Y2 -T -m #Y1 #Y2 #T #m #H1T #H2T #_
-#HT1 #HY2 #Hm destruct
-@llpx_sn_alt_intro // -HL12
-#J1 #J2 #K1 #K2 #W1 #W2 #i #Hdi #HnVT #HLK1 #HLK2
-elim (nlift_inv_flat … HnVT) -HnVT /3 width=8 by/
-qed-.
-
-lemma llpx_sn_alt_flat: ∀R,I,L1,L2,V,T,d.
- llpx_sn_alt R d V L1 L2 → llpx_sn_alt R d T L1 L2 →
- llpx_sn_alt R d (ⓕ{I}V.T) L1 L2.
-/2 width=7 by llpx_sn_alt_flat_aux/ qed.
-
-fact llpx_sn_alt_bind_aux: ∀R,a,I,L1,L2,V,d. llpx_sn_alt R d V L1 L2 →
- ∀Y1,Y2,T,m. llpx_sn_alt R m T Y1 Y2 →
- Y1 = L1.ⓑ{I}V → Y2 = L2.ⓑ{I}V → m = ⫯d →
- llpx_sn_alt R d (ⓑ{a,I}V.T) L1 L2.
-#R #a #I #L1 #L2 #V #d * -L1 -L2 -V -d #L1 #L2 #V #d #H1V #H2V #HL12
-#Y1 #Y2 #T #m * -Y1 -Y2 -T -m #Y1 #Y2 #T #m #H1T #H2T #_
-#HT1 #HY2 #Hm destruct
-@llpx_sn_alt_intro // -HL12
-#J1 #J2 #K1 #K2 #W1 #W2 #i #Hdi #HnVT #HLK1 #HLK2
-elim (nlift_inv_bind … HnVT) -HnVT /3 width=8 by ldrop_drop, yle_succ/
-qed-.
-
-lemma llpx_sn_alt_bind: ∀R,a,I,L1,L2,V,T,d.
- llpx_sn_alt R d V L1 L2 →
- llpx_sn_alt R (⫯d) T (L1.ⓑ{I}V) (L2.ⓑ{I}V) →
- llpx_sn_alt R d (ⓑ{a,I}V.T) L1 L2.
-/2 width=7 by llpx_sn_alt_bind_aux/ qed.
+(* alternative definition of llpx_sn (not recursive) *)
+definition llpx_sn_alt: relation3 lenv term term → relation4 ynat term lenv lenv ≝
+ λR,l,T,L1,L2. |L1| = |L2| ∧
+ (∀I1,I2,K1,K2,V1,V2,i. l ≤ yinj i → L1 ⊢ i ϵ 𝐅*[l]⦃T⦄ →
+ ⬇[i] L1 ≡ K1.ⓑ{I1}V1 → ⬇[i] L2 ≡ K2.ⓑ{I2}V2 →
+ I1 = I2 ∧ R K1 V1 V2
+ ).
(* Main properties **********************************************************)
-theorem llpx_sn_lpx_sn_alt: ∀R,L1,L2,T,d. llpx_sn R d T L1 L2 → llpx_sn_alt R d T L1 L2.
-#R #L1 #L2 #T #d #H elim H -L1 -L2 -T -d
-/2 width=9 by llpx_sn_alt_sort, llpx_sn_alt_gref, llpx_sn_alt_skip, llpx_sn_alt_free, llpx_sn_alt_lref, llpx_sn_alt_flat, llpx_sn_alt_bind/
-qed.
-
-(* Main inversion lemmas ****************************************************)
-
-theorem llpx_sn_alt_inv_lpx_sn: ∀R,T,L1,L2,d. llpx_sn_alt R d T L1 L2 → llpx_sn R d T L1 L2.
-#R #T #L1 @(f2_ind … rfw … L1 T) -L1 -T #n #IH #L1 * *
-[1,3: /3 width=4 by llpx_sn_alt_fwd_length, llpx_sn_gref, llpx_sn_sort/
-| #i #Hn #L2 #d #H lapply (llpx_sn_alt_fwd_length … H)
- #HL12 elim (llpx_sn_alt_fwd_lref … H) -H
- [ * /2 width=1 by llpx_sn_free/
- | /2 width=1 by llpx_sn_skip/
- | * /4 width=9 by llpx_sn_lref, ldrop_fwd_rfw/
- ]
-| #a #I #V #T #Hn #L2 #d #H elim (llpx_sn_alt_inv_bind … H) -H
- /3 width=1 by llpx_sn_bind/
-| #I #V #T #Hn #L2 #d #H elim (llpx_sn_alt_inv_flat … H) -H
- /3 width=1 by llpx_sn_flat/
+theorem llpx_sn_llpx_sn_alt: ∀R,T,L1,L2,l. llpx_sn R l T L1 L2 → llpx_sn_alt R l T L1 L2.
+#R #U #L1 @(f2_ind … rfw … L1 U) -L1 -U
+#x #IHx #L1 #U #Hx #L2 #l #H elim (llpx_sn_inv_alt_r … H) -H
+#HL12 #IHU @conj //
+#I1 #I2 #K1 #K2 #V1 #V2 #i #Hli #H #HLK1 #HLK2 elim (frees_inv … H) -H
+[ -x #HnU elim (IHU … HnU HLK1 HLK2) -IHU -HnU -HLK1 -HLK2 /2 width=1 by conj/
+| * #J1 #K10 #W10 #j #Hlj #Hji #HnU #HLK10 <yminus_SO2 >yminus_inj >yminus_inj #HnW10 destruct
+ lapply (drop_fwd_drop2 … HLK10) #H
+ lapply (drop_conf_ge … H … HLK1 ?) -H /2 width=1 by ylt_fwd_le_succ1/ <minus_plus #HK10
+ elim (drop_O1_lt (Ⓕ) L2 j) [2: <HL12 /2 width=5 by drop_fwd_length_lt2/ ] #J2 #K20 #W20 #HLK20
+ lapply (drop_fwd_drop2 … HLK20) #H
+ lapply (drop_conf_ge … H … HLK2 ?) -H /2 width=1 by ylt_fwd_le_succ1/ <minus_plus #HK20
+ elim (IHx K10 W10 … K20 0 ?) -IHx -HL12 /3 width=6 by drop_fwd_rfw/
+ elim (IHU … HnU HLK10 HLK20) -IHU -HnU -HLK10 -HLK20 /2 width=6 by/
]
-qed-.
-
-(* Advanced properties ******************************************************)
-
-lemma llpx_sn_intro_alt: ∀R,L1,L2,T,d. |L1| = |L2| →
- (∀I1,I2,K1,K2,V1,V2,i. d ≤ yinj i → (∀U. ⇧[i, 1] U ≡ T → ⊥) →
- ⇩[i] L1 ≡ K1.ⓑ{I1}V1 → ⇩[i] L2 ≡ K2.ⓑ{I2}V2 →
- ∧∧ I1 = I2 & R K1 V1 V2 & llpx_sn R 0 V1 K1 K2
- ) → llpx_sn R d T L1 L2.
-#R #L1 #L2 #T #d #HL12 #IH @llpx_sn_alt_inv_lpx_sn
-@llpx_sn_alt_intro_alt // -HL12
-#I1 #I2 #K1 #K2 #HLK1 #HLK2 #i #Hid #HnT #HLK1 #HLK2
-elim (IH … HnT HLK1 HLK2) -IH -HnT -HLK1 -HLK2 /3 width=1 by llpx_sn_lpx_sn_alt, and3_intro/
qed.
-(* Advanced forward lemmas lemmas *******************************************)
-
-lemma llpx_sn_fwd_alt: ∀R,L1,L2,T,d. llpx_sn R d T L1 L2 →
- |L1| = |L2| ∧
- ∀I1,I2,K1,K2,V1,V2,i. d ≤ yinj i → (∀U. ⇧[i, 1] U ≡ T → ⊥) →
- ⇩[i] L1 ≡ K1.ⓑ{I1}V1 → ⇩[i] L2 ≡ K2.ⓑ{I2}V2 →
- ∧∧ I1 = I2 & R K1 V1 V2 & llpx_sn R 0 V1 K1 K2.
-#R #L1 #L2 #T #d #H lapply (llpx_sn_lpx_sn_alt … H) -H
-#H elim (llpx_sn_alt_fwd_gen … H) -H
-#HL12 #IH @conj //
-#I1 #I2 #K1 #K2 #HLK1 #HLK2 #i #Hid #HnT #HLK1 #HLK2
-elim (IH … HnT HLK1 HLK2) -IH -HnT -HLK1 -HLK2 /3 width=1 by llpx_sn_alt_inv_lpx_sn, and3_intro/
+theorem llpx_sn_alt_inv_llpx_sn: ∀R,T,L1,L2,l. llpx_sn_alt R l T L1 L2 → llpx_sn R l T L1 L2.
+#R #U #L1 @(f2_ind … rfw … L1 U) -L1 -U
+#x #IHx #L1 #U #Hx #L2 #l * #HL12 #IHU @llpx_sn_intro_alt_r //
+#I1 #I2 #K1 #K2 #V1 #V2 #i #Hli #HnU #HLK1 #HLK2 destruct
+elim (IHU … HLK1 HLK2) /3 width=2 by frees_eq/
+#H #HV12 @and3_intro // @IHx -IHx /3 width=6 by drop_fwd_rfw/
+lapply (drop_fwd_drop2 … HLK1) #H1
+lapply (drop_fwd_drop2 … HLK2) -HLK2 #H2
+@conj [ @(drop_fwd_length_eq1 … H1 H2) // ] -HL12
+#Z1 #Z2 #Y1 #Y2 #X1 #X2 #j #_
+>(minus_plus_m_m j (i+1)) in ⊢ (%→?); >commutative_plus <minus_plus
+<yminus_inj <yminus_inj >yminus_SO2
+#HnV1 #HKY1 #HKY2 (**) (* full auto too slow *)
+lapply (drop_trans_ge … H1 … HKY1 ?) -H1 -HKY1 // #HLY1
+lapply (drop_trans_ge … H2 … HKY2 ?) -H2 -HKY2 // #HLY2
+/4 width=9 by frees_be, yle_plus_dx2_trans, yle_succ_dx, ylt_inj/
qed-.
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