(* Basic_1: was: ldrop_mono *)
theorem ldrop_mono: ∀d,e,L,L1. ↓[d, e] L ≡ L1 →
∀L2. ↓[d, e] L ≡ L2 → L1 = L2.
-#d #e #L #L1 #H elim H -H d e L L1
+#d #e #L #L1 #H elim H -d -e -L -L1
[ #d #e #L2 #H
- >(ldrop_inv_atom1 … H) -H L2 //
+ >(ldrop_inv_atom1 … H) -L2 //
| #K #I #V #L2 #HL12
- <(ldrop_inv_refl … HL12) -HL12 L2 //
+ <(ldrop_inv_refl … HL12) -L2 //
| #L #K #I #V #e #_ #IHLK #L2 #H
- lapply (ldrop_inv_ldrop1 … H ?) -H /2/
+ lapply (ldrop_inv_ldrop1 … H ?) -H // /2 width=1/
| #L #K1 #I #T #V1 #d #e #_ #HVT1 #IHLK1 #X #H
- elim (ldrop_inv_skip1 … H ?) -H // <minus_plus_m_m #K2 #V2 #HLK2 #HVT2 #H destruct -X
- >(lift_inj … HVT1 … HVT2) -HVT1 HVT2
- >(IHLK1 … HLK2) -IHLK1 HLK2 //
+ elim (ldrop_inv_skip1 … H ?) -H // <minus_plus_m_m #K2 #V2 #HLK2 #HVT2 #H destruct
+ >(lift_inj … HVT1 … HVT2) -HVT1 -HVT2
+ >(IHLK1 … HLK2) -IHLK1 -HLK2 //
]
-qed.
+qed-.
(* Basic_1: was: ldrop_conf_ge *)
theorem ldrop_conf_ge: ∀d1,e1,L,L1. ↓[d1, e1] L ≡ L1 →
∀e2,L2. ↓[0, e2] L ≡ L2 → d1 + e1 ≤ e2 →
↓[0, e2 - e1] L1 ≡ L2.
-#d1 #e1 #L #L1 #H elim H -H d1 e1 L L1
+#d1 #e1 #L #L1 #H elim H -d1 -e1 -L -L1
[ #d #e #e2 #L2 #H
- >(ldrop_inv_atom1 … H) -H L2 //
+ >(ldrop_inv_atom1 … H) -L2 //
| //
| #L #K #I #V #e #_ #IHLK #e2 #L2 #H #He2
- lapply (ldrop_inv_ldrop1 … H ?) -H /2/ #HL2
- <minus_plus_comm /3/
+ lapply (ldrop_inv_ldrop1 … H ?) -H /2 width=2/ #HL2
+ <minus_plus >minus_minus_comm /3 width=1/
| #L #K #I #V1 #V2 #d #e #_ #_ #IHLK #e2 #L2 #H #Hdee2
lapply (transitive_le 1 … Hdee2) // #He2
lapply (ldrop_inv_ldrop1 … H ?) -H // -He2 #HL2
lapply (transitive_le (1 + e) … Hdee2) // #Hee2
- @ldrop_ldrop_lt >minus_minus_comm /3/ (**) (* explicit constructor *)
+ @ldrop_ldrop_lt >minus_minus_comm /3 width=1/ (**) (* explicit constructor *)
]
qed.
e2 < d1 → let d ≝ d1 - e2 - 1 in
∃∃K1,V1. ↓[0, e2] L1 ≡ K1. 𝕓{I} V1 &
↓[d, e1] K2 ≡ K1 & ↑[d, e1] V1 ≡ V2.
-#d1 #e1 #L #L1 #H elim H -H d1 e1 L L1
+#d1 #e1 #L #L1 #H elim H -d1 -e1 -L -L1
[ #d #e #e2 #K2 #I #V2 #H
lapply (ldrop_inv_atom1 … H) -H #H destruct
| #L #I #V #e2 #K2 #J #V2 #_ #H
elim (lt_zero_false … H)
| #L1 #L2 #I #V1 #V2 #d #e #HL12 #HV12 #IHL12 #e2 #K2 #J #V #H #He2d
elim (ldrop_inv_O1 … H) -H *
- [ -IHL12 He2d #H1 #H2 destruct -e2 K2 J V /2 width=5/
+ [ -IHL12 -He2d #H1 #H2 destruct /2 width=5/
| -HL12 -HV12 #He #HLK
- elim (IHL12 … HLK ?) -IHL12 HLK [ <minus_minus /3 width=5/ | /2/ ] (**) (* a bit slow *)
+ elim (IHL12 … HLK ?) -IHL12 -HLK [ <minus_minus /3 width=5/ | /2 width=1/ ] (**) (* a bit slow *)
]
]
qed.
theorem ldrop_trans_le: ∀d1,e1,L1,L. ↓[d1, e1] L1 ≡ L →
∀e2,L2. ↓[0, e2] L ≡ L2 → e2 ≤ d1 →
∃∃L0. ↓[0, e2] L1 ≡ L0 & ↓[d1 - e2, e1] L0 ≡ L2.
-#d1 #e1 #L1 #L #H elim H -H d1 e1 L1 L
+#d1 #e1 #L1 #L #H elim H -d1 -e1 -L1 -L
[ #d #e #e2 #L2 #H
- >(ldrop_inv_atom1 … H) -H L2 /2/
+ >(ldrop_inv_atom1 … H) -L2 /2 width=3/
| #K #I #V #e2 #L2 #HL2 #H
- lapply (le_O_to_eq_O … H) -H #H destruct -e2 /2/
+ lapply (le_n_O_to_eq … H) -H #H destruct /2 width=3/
| #L1 #L2 #I #V #e #_ #IHL12 #e2 #L #HL2 #H
- lapply (le_O_to_eq_O … H) -H #H destruct -e2;
- elim (IHL12 … HL2 ?) -IHL12 HL2 // #L0 #H #HL0
- lapply (ldrop_inv_refl … H) -H #H destruct -L1 /3 width=5/
+ lapply (le_n_O_to_eq … H) -H #H destruct
+ elim (IHL12 … HL2 ?) -IHL12 -HL2 // #L0 #H #HL0
+ lapply (ldrop_inv_refl … H) -H #H destruct /3 width=5/
| #L1 #L2 #I #V1 #V2 #d #e #HL12 #HV12 #IHL12 #e2 #L #H #He2d
elim (ldrop_inv_O1 … H) -H *
- [ -He2d IHL12 #H1 #H2 destruct -e2 L /3 width=5/
- | -HL12 HV12 #He2 #HL2
- elim (IHL12 … HL2 ?) -IHL12 HL2 L2
- [ >minus_le_minus_minus_comm // /3/ | /2/ ]
+ [ -He2d -IHL12 #H1 #H2 destruct /3 width=5/
+ | -HL12 -HV12 #He2 #HL2
+ elim (IHL12 … HL2 ?) -L2 [ >minus_le_minus_minus_comm // /3 width=3/ | /2 width=1/ ]
]
]
qed.
(* Basic_1: was: ldrop_trans_ge *)
theorem ldrop_trans_ge: ∀d1,e1,L1,L. ↓[d1, e1] L1 ≡ L →
∀e2,L2. ↓[0, e2] L ≡ L2 → d1 ≤ e2 → ↓[0, e1 + e2] L1 ≡ L2.
-#d1 #e1 #L1 #L #H elim H -H d1 e1 L1 L
+#d1 #e1 #L1 #L #H elim H -d1 -e1 -L1 -L
[ #d #e #e2 #L2 #H
- >(ldrop_inv_atom1 … H) -H L2 //
+ >(ldrop_inv_atom1 … H) -H -L2 //
| //
-| /3/
+| /3 width=1/
| #L1 #L2 #I #V1 #V2 #d #e #H_ #_ #IHL12 #e2 #L #H #Hde2
lapply (lt_to_le_to_lt 0 … Hde2) // #He2
lapply (lt_to_le_to_lt … (e + e2) He2 ?) // #Hee2
lapply (ldrop_inv_ldrop1 … H ?) -H // #HL2
- @ldrop_ldrop_lt // >le_plus_minus // @IHL12 /2/ (**) (* explicit constructor *)
+ @ldrop_ldrop_lt // >le_plus_minus // @IHL12 /2 width=1/ (**) (* explicit constructor *)
]
qed.