(* *)
(**************************************************************************)
-include "ground_2/notation/relations/rafter_3.ma".
-include "ground_2/lib/streams_hdtl.ma".
-include "ground_2/relocation/nstream_at.ma".
+include "ground_2/relocation/nstream_istot.ma".
+include "ground_2/relocation/rtmap_after.ma".
(* RELOCATION N-STREAM ******************************************************)
-let corec compose: nstream → nstream → nstream ≝ ?.
-#t1 * #b2 #t2 @(seq … (t1@❴b2❵)) @(compose ? t2) -compose -t2
-@(tln … (⫯b2) t1)
-qed.
+corec definition compose: rtmap → rtmap → rtmap.
+#f2 * #n1 #f1 @(seq … (f2@❨n1❩)) @(compose ? f1) -compose -f1
+@(⫰*[↑n1] f2)
+defined.
interpretation "functional composition (nstream)"
- 'compose t1 t2 = (compose t1 t2).
-
-coinductive after: relation3 nstream nstream nstream ≝
-| after_zero: ∀t1,t2,t,b1,b2,b.
- after t1 t2 t →
- b1 = 0 → b2 = 0 → b = 0 →
- after (b1@t1) (b2@t2) (b@t)
-| after_skip: ∀t1,t2,t,b1,b2,b,a2,a.
- after t1 (a2@t2) (a@t) →
- b1 = 0 → b2 = ⫯a2 → b = ⫯a →
- after (b1@t1) (b2@t2) (b@t)
-| after_drop: ∀t1,t2,t,b1,b,a1,a.
- after (a1@t1) t2 (a@t) →
- b1 = ⫯a1 → b = ⫯a →
- after (b1@t1) t2 (b@t)
-.
-
-interpretation "relational composition (nstream)"
- 'RAfter t1 t2 t = (after t1 t2 t).
+ 'compose f2 f1 = (compose f2 f1).
(* Basic properies on compose ***********************************************)
-lemma compose_unfold: ∀t1,t2,a2. t1∘(a2@t2) = t1@❴a2❵@tln … (⫯a2) t1∘t2.
-#t1 #t2 #a2 >(stream_expand … (t1∘(a2@t2))) normalize //
+lemma compose_rew: ∀f2,f1,n1. f2@❨n1❩⨮(⫰*[↑n1]f2)∘f1 = f2∘(n1⨮f1).
+#f2 #f1 #n1 <(stream_rew … (f2∘(n1⨮f1))) normalize //
qed.
-lemma compose_drop: ∀t1,t2,t,a1,a. (a1@t1)∘t2 = a@t → (⫯a1@t1)∘t2 = ⫯a@t.
-#t1 * #a2 #t2 #t #a1 #a >compose_unfold >compose_unfold
-#H destruct normalize //
+lemma compose_next: ∀f2,f1,f. f2∘f1 = f → (↑f2)∘f1 = ↑f.
+#f2 * #n1 #f1 #f <compose_rew <compose_rew
+* -f <tls_S1 /2 width=1 by eq_f2/
qed.
(* Basic inversion lemmas on compose ****************************************)
-lemma compose_inv_unfold: ∀t1,t2,t,a2,a. t1∘(a2@t2) = a@t →
- t1@❴a2❵ = a ∧ tln … (⫯a2) t1∘t2 = t.
-#t1 #t2 #t #a2 #a >(stream_expand … (t1∘(a2@t2))) normalize
+lemma compose_inv_rew: ∀f2,f1,f,n1,n. f2∘(n1⨮f1) = n⨮f →
+ f2@❨n1❩ = n ∧ (⫰*[↑n1]f2)∘f1 = f.
+#f2 #f1 #f #n1 #n <(stream_rew … (f2∘(n1⨮f1))) normalize
#H destruct /2 width=1 by conj/
qed-.
-lemma compose_inv_O2: ∀t1,t2,t,a1,a. (a1@t1)∘(O@t2) = a@t →
- a = a1 ∧ t1∘t2 = t.
-#t1 #t2 #t #a1 #a >compose_unfold
+lemma compose_inv_O2: ∀f2,f1,f,n2,n. (n2⨮f2)∘(⫯f1) = n⨮f →
+ n2 = n ∧ f2∘f1 = f.
+#f2 #f1 #f #n2 #n <compose_rew
#H destruct /2 width=1 by conj/
qed-.
-lemma compose_inv_S2: ∀t1,t2,t,a1,a2,a. (a1@t1)∘(⫯a2@t2) = a@t →
- a = ⫯(a1+t1@❴a2❵) ∧ t1∘(a2@t2) = t1@❴a2❵@t.
-#t1 #t2 #t #a1 #a2 #a >compose_unfold
-#H destruct /2 width=1 by conj/
+lemma compose_inv_S2: ∀f2,f1,f,n2,n1,n. (n2⨮f2)∘(↑n1⨮f1) = n⨮f →
+ ↑(n2+f2@❨n1❩) = n ∧ f2∘(n1⨮f1) = f2@❨n1❩⨮f.
+#f2 #f1 #f #n2 #n1 #n <compose_rew
+#H destruct <tls_S1 /2 width=1 by conj/
qed-.
-lemma compose_inv_S1: ∀t1,t2,t,a1,a2,a. (⫯a1@t1)∘(a2@t2) = a@t →
- a = ⫯((a1@t1)@❴a2❵) ∧ (a1@t1)∘(a2@t2) = (a1@t1)@❴a2❵@t.
-#t1 #t2 #t #a1 #a2 #a >compose_unfold
-#H destruct /2 width=1 by conj/
+lemma compose_inv_S1: ∀f2,f1,f,n1,n. (↑f2)∘(n1⨮f1) = n⨮f →
+ ↑(f2@❨n1❩) = n ∧ f2∘(n1⨮f1) = f2@❨n1❩⨮f.
+#f2 #f1 #f #n1 #n <compose_rew
+#H destruct <tls_S1 /2 width=1 by conj/
qed-.
-(* Basic properties on after ************************************************)
+(* Specific properties on after *********************************************)
-lemma after_O2: ∀t1,t2,t. t1 ⊚ t2 ≡ t →
- ∀b. b@t1 ⊚ O@t2 ≡ b@t.
-#t1 #t2 #t #Ht #b elim b -b /2 width=5 by after_drop, after_zero/
+lemma after_O2: ∀f2,f1,f. f2 ⊚ f1 ≘ f →
+ ∀n. n⨮f2 ⊚ ⫯f1 ≘ n⨮f.
+#f2 #f1 #f #Hf #n elim n -n /2 width=7 by after_refl, after_next/
qed.
-lemma after_S2: ∀t1,t2,t,b2,b. t1 ⊚ b2@t2 ≡ b@t →
- ∀b1. b1@t1 ⊚ ⫯b2@t2 ≡ ⫯(b1+b)@t.
-#t1 #t2 #t #b2 #b #Ht #b1 elim b1 -b1 /2 width=5 by after_drop, after_skip/
+lemma after_S2: ∀f2,f1,f,n1,n. f2 ⊚ n1⨮f1 ≘ n⨮f →
+ ∀n2. n2⨮f2 ⊚ ↑n1⨮f1 ≘ ↑(n2+n)⨮f.
+#f2 #f1 #f #n1 #n #Hf #n2 elim n2 -n2 /2 width=7 by after_next, after_push/
qed.
-lemma after_apply: ∀b2,t1,t2,t. (tln … (⫯b2) t1) ⊚ t2 ≡ t → t1 ⊚ b2@t2 ≡ t1@❴b2❵@t.
-#b2 elim b2 -b2
+lemma after_apply: ∀n1,f2,f1,f. (⫰*[↑n1] f2) ⊚ f1 ≘ f → f2 ⊚ n1⨮f1 ≘ f2@❨n1❩⨮f.
+#n1 elim n1 -n1
[ * /2 width=1 by after_O2/
-| #b2 #IH * /3 width=1 by after_S2/
+| #n1 #IH * /3 width=1 by after_S2/
]
qed-.
-let corec after_total_aux: ∀t1,t2,t. t1 ∘ t2 = t → t1 ⊚ t2 ≡ t ≝ ?.
-* #a1 #t1 * #a2 #t2 * #a #t cases a1 -a1
-[ cases a2 -a2
- [ #H cases (compose_inv_O2 … H) -H
- /3 width=1 by after_zero/
- | #a2 #H cases (compose_inv_S2 … H) -H
- /3 width=5 by after_skip, eq_f/
+corec lemma after_total_aux: ∀f2,f1,f. f2 ∘ f1 = f → f2 ⊚ f1 ≘ f.
+* #n2 #f2 * #n1 #f1 * #n #f cases n2 -n2
+[ cases n1 -n1
+ [ #H cases (compose_inv_O2 … H) -H /3 width=7 by after_refl, eq_f2/
+ | #n1 #H cases (compose_inv_S2 … H) -H * -n /3 width=7 by after_push/
]
-| #a1 #H cases (compose_inv_S1 … H) -H
- /3 width=5 by after_drop, eq_f/
+| #n2 >next_rew #H cases (compose_inv_S1 … H) -H * -n /3 width=5 by after_next/
]
qed-.
-theorem after_total: ∀t2,t1. t1 ⊚ t2 ≡ t1 ∘ t2.
+theorem after_total: ∀f1,f2. f2 ⊚ f1 ≘ f2 ∘ f1.
/2 width=1 by after_total_aux/ qed.
-(* Basic inversion lemmas on after ******************************************)
-
-fact after_inv_O1_aux: ∀t1,t2,t. t1 ⊚ t2 ≡ t → ∀u1. t1 = 0@u1 →
- (∃∃u2,u. u1 ⊚ u2 ≡ u & t2 = 0@u2 & t = 0@u) ∨
- ∃∃u2,u,b2,b. u1 ⊚ b2@u2 ≡ b@u & t2 = ⫯b2@u2 & t = ⫯b@u.
-#t1 #t2 #t * -t1 -t2 -t #t1 #t2 #t #b1
-[ #b2 #b #Ht #H1 #H2 #H3 #u1 #H destruct /3 width=5 by ex3_2_intro, or_introl/
-| #b2 #b #a2 #a #Ht #H1 #H2 #H3 #u1 #H destruct /3 width=7 by ex3_4_intro, or_intror/
-| #b #a1 #a #_ #H1 #H3 #u1 #H destruct
-]
-qed-.
-
-fact after_inv_O1_aux2: ∀t1,t2,t,b1,b2,b. b1@t1 ⊚ b2@t2 ≡ b@t → b1 = 0 →
- (∧∧ t1 ⊚ t2 ≡ t & b2 = 0 & b = 0) ∨
- ∃∃a2,a. t1 ⊚ a2@t2 ≡ a@t & b2 = ⫯a2 & b = ⫯a.
-#t1 #t2 #t #b1 #b2 #b #Ht #H elim (after_inv_O1_aux … Ht) -Ht [4: // |2: skip ] *
-[ #u2 #u #Hu #H1 #H2 destruct /3 width=1 by and3_intro, or_introl/
-| #u2 #u #a2 #a #Hu #H1 #H2 destruct /3 width=5 by ex3_2_intro, or_intror/
-]
-qed-.
-
-lemma after_inv_O1: ∀u1,t2,t. 0@u1 ⊚ t2 ≡ t →
- (∃∃u2,u. u1 ⊚ u2 ≡ u & t2 = 0@u2 & t = 0@u) ∨
- ∃∃u2,u,b2,b. u1 ⊚ b2@u2 ≡ b@u & t2 = ⫯b2@u2 & t = ⫯b@u.
-/2 width=3 by after_inv_O1_aux/ qed-.
-
-fact after_inv_zero_aux2: ∀t1,t2,t,b1,b2,b. b1@t1 ⊚ b2@t2 ≡ b@t → b1 = 0 → b2 = 0 →
- t1 ⊚ t2 ≡ t ∧ b = 0.
-#t1 #t2 #t #b1 #b2 #b #Ht #H1 #H2 elim (after_inv_O1_aux2 … Ht H1) -Ht -H1 *
-[ /2 width=1 by conj/
-| #a1 #a2 #_ #H0 destruct
-]
-qed-.
-
-lemma after_inv_zero: ∀u1,u2,t. 0@u1 ⊚ 0@u2 ≡ t →
- ∃∃u. u1 ⊚ u2 ≡ u & t = 0@u.
-#u1 #u2 #t #H elim (after_inv_O1 … H) -H *
-[ #x2 #u #Hu #H1 #H2 destruct /2 width=3 by ex2_intro/
-| #x2 #u #a2 #a #Hu #H destruct
-]
-qed-.
-
-fact after_inv_skip_aux2: ∀t1,t2,t,b1,b2,b. b1@t1 ⊚ b2@t2 ≡ b@t → b1 = 0 → ∀a2. b2 = ⫯a2 →
- ∃∃a. t1 ⊚ a2@t2 ≡ a@t & b = ⫯a.
-#t1 #t2 #t #b1 #b2 #b #Ht #H1 #a2 #H2 elim (after_inv_O1_aux2 … Ht H1) -Ht -H1 *
-[ #_ #H0 destruct
-| #x2 #x #H #H0 #H1 destruct /2 width=3 by ex2_intro/
-]
-qed-.
-
-lemma after_inv_skip: ∀u1,u2,t,b2. 0@u1 ⊚ ⫯b2@u2 ≡ t →
- ∃∃u,b. u1 ⊚ b2@u2 ≡ b@u & t = ⫯b@u.
-#u1 #u2 * #b #t #b2 #Ht elim (after_inv_skip_aux2 … Ht) [2,4: // |3: skip ] -Ht
-#a #Ht #H destruct /2 width=4 by ex2_2_intro/
-qed-.
-
-fact after_inv_S1_aux: ∀t1,t2,t. t1 ⊚ t2 ≡ t → ∀u1,b1. t1 = ⫯b1@u1 →
- ∃∃u,b. b1@u1 ⊚ t2 ≡ b@u & t = ⫯b@u.
-#t1 #t2 #t * -t1 -t2 -t #t1 #t2 #t #b1
-[ #b2 #b #_ #H1 #H2 #H3 #u1 #a1 #H destruct
-| #b2 #b #a2 #a #_ #H1 #H2 #H3 #u1 #a1 #H destruct
-| #b #a1 #a #Ht #H1 #H3 #u1 #x1 #H destruct /2 width=4 by ex2_2_intro/
-]
-qed-.
-
-fact after_inv_S1_aux2: ∀t1,t2,t,b1,b. b1@t1 ⊚ t2 ≡ b@t → ∀a1. b1 = ⫯a1 →
- ∃∃a. a1@t1 ⊚ t2 ≡ a@t & b = ⫯a.
-#t1 #t2 #t #b1 #b #Ht #a #H elim (after_inv_S1_aux … Ht) -Ht [4: // |2,3: skip ]
-#u #x #Hu #H0 destruct /2 width=3 by ex2_intro/
-qed-.
-
-lemma after_inv_S1: ∀u1,t2,t,b1. ⫯b1@u1 ⊚ t2 ≡ t →
- ∃∃u,b. b1@u1 ⊚ t2 ≡ b@u & t = ⫯b@u.
-/2 width=3 by after_inv_S1_aux/ qed-.
-
-fact after_inv_drop_aux2: ∀t1,t2,t,a1,a. a1@t1 ⊚ t2 ≡ a@t → ∀b1,b. a1 = ⫯b1 → a = ⫯b →
- b1@t1 ⊚ t2 ≡ b@t.
-#t1 #t2 #t #a1 #a #Ht #b1 #b #H1 #H elim (after_inv_S1_aux2 … Ht … H1) -a1
-#x #Ht #Hx destruct //
-qed-.
-
-lemma after_inv_drop: ∀t1,t2,t,b1,b. ⫯b1@t1 ⊚ t2 ≡ ⫯b@t → b1@t1 ⊚ t2 ≡ b@t.
-/2 width=5 by after_inv_drop_aux2/ qed-.
-
-fact after_inv_O3_aux1: ∀t1,t2,t. t1 ⊚ t2 ≡ t → ∀u. t = 0@u →
- ∃∃u1,u2. u1 ⊚ u2 ≡ u & t1 = 0@u1 & t2 = 0@u2.
-#t1 #t2 #t * -t1 -t2 -t #t1 #t2 #t #b1
-[ #b2 #b #Ht #H1 #H2 #H3 #u #H destruct /2 width=5 by ex3_2_intro/
-| #b2 #b #a2 #a #_ #H1 #H2 #H3 #u #H destruct
-| #b #a1 #a #_ #H1 #H3 #u #H destruct
-]
-qed-.
-
-fact after_inv_O3_aux2: ∀t1,t2,t,b1,b2,b. b1@t1 ⊚ b2@t2 ≡ b@t → b = 0 →
- ∧∧ t1 ⊚ t2 ≡ t & b1 = 0 & b2 = 0.
-#t1 #t2 #t #b1 #b2 #b #Ht #H1 elim (after_inv_O3_aux1 … Ht) [2: // |3: skip ] -b
-#u1 #u2 #Ht #H1 #H2 destruct /2 width=1 by and3_intro/
-qed-.
-
-lemma after_inv_O3: ∀t1,t2,u. t1 ⊚ t2 ≡ 0@u →
- ∃∃u1,u2. u1 ⊚ u2 ≡ u & t1 = 0@u1 & t2 = 0@u2.
-/2 width=3 by after_inv_O3_aux1/ qed-.
-
-fact after_inv_S3_aux1: ∀t1,t2,t. t1 ⊚ t2 ≡ t → ∀u,b. t = ⫯b@u →
- (∃∃u1,u2,b2. u1 ⊚ b2@u2 ≡ b@u & t1 = 0@u1 & t2 = ⫯b2@u2) ∨
- ∃∃u1,b1. b1@u1 ⊚ t2 ≡ b@u & t1 = ⫯b1@u1.
-#t1 #t2 #t * -t1 -t2 -t #t1 #t2 #t #b1
-[ #b2 #b #_ #H1 #H2 #H3 #u #a #H destruct
-| #b2 #b #a2 #a #HT #H1 #H2 #H3 #u #x #H destruct /3 width=6 by ex3_3_intro, or_introl/
-| #b #a1 #a #HT #H1 #H3 #u #x #H destruct /3 width=4 by ex2_2_intro, or_intror/
-]
-qed-.
-
-fact after_inv_S3_aux2: ∀t1,t2,t,a1,a2,a. a1@t1 ⊚ a2@t2 ≡ a@t → ∀b. a = ⫯b →
- (∃∃b2. t1 ⊚ b2@t2 ≡ b@t & a1 = 0 & a2 = ⫯b2) ∨
- ∃∃b1. b1@t1 ⊚ a2@t2 ≡ b@t & a1 = ⫯b1.
-#t1 #t2 #t #a1 #a2 #a #Ht #b #H elim (after_inv_S3_aux1 … Ht) [3: // |4,5: skip ] -a *
-[ #u1 #u2 #b2 #Ht #H1 #H2 destruct /3 width=3 by ex3_intro, or_introl/
-| #u1 #b1 #Ht #H1 destruct /3 width=3 by ex2_intro, or_intror/
-]
-qed-.
-
-lemma after_inv_S3: ∀t1,t2,u,b. t1 ⊚ t2 ≡ ⫯b@u →
- (∃∃u1,u2,b2. u1 ⊚ b2@u2 ≡ b@u & t1 = 0@u1 & t2 = ⫯b2@u2) ∨
- ∃∃u1,b1. b1@u1 ⊚ t2 ≡ b@u & t1 = ⫯b1@u1.
-/2 width=3 by after_inv_S3_aux1/ qed-.
-
-(* Advanced inversion lemmas on after ***************************************)
-
-fact after_inv_O2_aux2: ∀t1,t2,t,a1,a2,a. a1@t1 ⊚ a2@t2 ≡ a@t → a2 = 0 →
- a1 = a ∧ t1 ⊚ t2 ≡ t.
-#t1 #t2 #t #a1 #a2 elim a1 -a1
-[ #a #H #H2 elim (after_inv_zero_aux2 … H … H2) -a2 /2 width=1 by conj/
-| #a1 #IH #a #H #H2 elim (after_inv_S1_aux2 … H) -H [3: // |2: skip ]
- #b #H #H1 elim (IH … H) // -a2
- #H2 destruct /2 width=1 by conj/
-]
-qed-.
-
-lemma after_inv_O2: ∀t1,u2,t. t1 ⊚ 0@u2 ≡ t →
- ∃∃u1,u,a. t1 = a@u1 & t = a@u & u1 ⊚ u2 ≡ u.
-* #a1 #t1 #t2 * #a #t #H elim (after_inv_O2_aux2 … H) -H //
-/2 width=6 by ex3_3_intro/
-qed-.
+(* Specific inversion lemmas on after ***************************************)
-lemma after_inv_const: ∀a,t1,b2,u2,t. a@t1 ⊚ b2@u2 ≡ a@t → b2 = 0.
-#a elim a -a
-[ #t1 #b2 #u2 #t #H elim (after_inv_O3 … H) -H
- #u1 #x2 #_ #_ #H destruct //
-| #a #IH #t1 #b2 #u2 #t #H elim (after_inv_S1 … H) -H
- #x #b #Hx #H destruct >(IH … Hx) -t1 -u2 -x -b2 -b //
+lemma after_inv_xpx: ∀f2,g2,f,n2,n. n2⨮f2 ⊚ g2 ≘ n⨮f → ∀f1. ⫯f1 = g2 →
+ f2 ⊚ f1 ≘ f ∧ n2 = n.
+#f2 #g2 #f #n2 elim n2 -n2
+[ #n #Hf #f1 #H2 elim (after_inv_ppx … Hf … H2) -g2 [2,3: // ]
+ #g #Hf #H elim (push_inv_seq_dx … H) -H destruct /2 width=1 by conj/
+| #n2 #IH #n #Hf #f1 #H2 elim (after_inv_nxx … Hf) -Hf [2,3: // ]
+ #g1 #Hg #H1 elim (next_inv_seq_dx … H1) -H1
+ #x #Hx #H destruct elim (IH … Hg) [2,3: // ] -IH -Hg
+ #H destruct /2 width=1 by conj/
]
qed-.
-lemma after_inv_S2: ∀t1,t2,t,a1,a2,a. a1@t1 ⊚ ⫯a2@t2 ≡ a@t → ∀b. a = ⫯(a1+b) →
- t1 ⊚ a2@t2 ≡ b@t.
-#t1 #t2 #t #a1 elim a1 -a1
-[ #a2 #a #Ht #b #Hb
- elim (after_inv_skip_aux2 … Ht) -Ht [3,4: // |2: skip ]
- #c #Ht #Hc destruct //
-| #a1 #IH #a2 #a #Ht #b #Hb
- lapply (after_inv_drop_aux2 … Ht … Hb) -a [ // | skip ]
- /2 width=3 by/
-]
-qed-.
-
-(* Forward lemmas on application ********************************************)
-
-lemma after_at_fwd: ∀t,i1,i. @⦃i1, t⦄ ≡ i → ∀t2,t1. t2 ⊚ t1 ≡ t →
- ∃∃i2. @⦃i1, t1⦄ ≡ i2 & @⦃i2, t2⦄ ≡ i.
-#t #i1 #i #H elim H -t -i1 -i
-[ #t #t2 #t1 #H elim (after_inv_O3 … H) -H
- /2 width=3 by at_zero, ex2_intro/
-| #t #i1 #i #_ #IH #t2 #t1 #H elim (after_inv_O3 … H) -H
- #u2 #u1 #Hu #H1 #H2 destruct elim (IH … Hu) -t
- /3 width=3 by at_S1, ex2_intro/
-| #t #b #i1 #i #_ #IH #t2 #t1 #H elim (after_inv_S3 … H) -H *
- [ #u2 #u1 #b2 #Hu #H1 #H2 destruct elim (IH … Hu) -t -b
- /3 width=3 by at_S1, at_lift, ex2_intro/
- | #u1 #b1 #Hu #H destruct elim (IH … Hu) -t -b
- /3 width=3 by at_lift, ex2_intro/
- ]
+lemma after_inv_xnx: ∀f2,g2,f,n2,n. n2⨮f2 ⊚ g2 ≘ n⨮f → ∀f1. ↑f1 = g2 →
+ ∃∃m. f2 ⊚ f1 ≘ m⨮f & ↑(n2+m) = n.
+#f2 #g2 #f #n2 elim n2 -n2
+[ #n #Hf #f1 #H2 elim (after_inv_pnx … Hf … H2) -g2 [2,3: // ]
+ #g #Hf #H elim (next_inv_seq_dx … H) -H
+ #x #Hx #Hg destruct /2 width=3 by ex2_intro/
+| #n2 #IH #n #Hf #f1 #H2 elim (after_inv_nxx … Hf) -Hf [2,3: // ]
+ #g #Hg #H elim (next_inv_seq_dx … H) -H
+ #x #Hx #H destruct elim (IH … Hg) -IH -Hg [2,3: // ]
+ #m #Hf #Hm destruct /2 width=3 by ex2_intro/
]
qed-.
-lemma after_at1_fwd: ∀t1,i1,i2. @⦃i1, t1⦄ ≡ i2 → ∀t2,t. t2 ⊚ t1 ≡ t →
- ∃∃i. @⦃i2, t2⦄ ≡ i & @⦃i1, t⦄ ≡ i.
-#t1 #i1 #i2 #H elim H -t1 -i1 -i2
-[ #t1 #t2 #t #H elim (after_inv_O2 … H) -H /2 width=3 by ex2_intro/
-| #t1 #i1 #i2 #_ #IH * #b2 elim b2 -b2
- [ #t2 #t #H elim (after_inv_zero … H) -H
- #u #Hu #H destruct elim (IH … Hu) -t1
- /3 width=3 by at_S1, at_skip, ex2_intro/
- | -IH #b2 #IH #t2 #t #H elim (after_inv_S1 … H) -H
- #u #b #Hu #H destruct elim (IH … Hu) -t1
- /3 width=3 by at_lift, ex2_intro/
- ]
-| #t1 #b1 #i1 #i2 #_ #IH * #b2 elim b2 -b2
- [ #t2 #t #H elim (after_inv_skip … H) -H
- #u #a #Hu #H destruct elim (IH … Hu) -t1 -b1
- /3 width=3 by at_S1, at_lift, ex2_intro/
- | -IH #b2 #IH #t2 #t #H elim (after_inv_S1 … H) -H
- #u #b #Hu #H destruct elim (IH … Hu) -t1 -b1
- /3 width=3 by at_lift, ex2_intro/
- ]
+lemma after_inv_const: ∀f2,f1,f,n1,n. n⨮f2 ⊚ n1⨮f1 ≘ n⨮f → f2 ⊚ f1 ≘ f ∧ 0 = n1.
+#f2 #f1 #f #n1 #n elim n -n
+[ #H elim (after_inv_pxp … H) -H [ |*: // ]
+ #g2 #Hf #H elim (push_inv_seq_dx … H) -H /2 width=1 by conj/
+| #n #IH #H lapply (after_inv_nxn … H ????) -H /2 width=5 by/
]
qed-.
-lemma after_fwd_at: ∀t1,t2,i1,i2,i. @⦃i1, t1⦄ ≡ i2 → @⦃i2, t2⦄ ≡ i →
- ∀t. t2 ⊚ t1 ≡ t → @⦃i1, t⦄ ≡ i.
-#t1 #t2 #i1 #i2 #i #Hi1 #Hi2 #t #Ht elim (after_at1_fwd … Hi1 … Ht) -t1
-#j #H #Hj >(at_mono … H … Hi2) -i2 //
-qed-.
-
-lemma after_fwd_at1: ∀t2,t,i1,i2,i. @⦃i1, t⦄ ≡ i → @⦃i2, t2⦄ ≡ i →
- ∀t1. t2 ⊚ t1 ≡ t → @⦃i1, t1⦄ ≡ i2.
-#t2 #t #i1 #i2 #i #Hi1 #Hi2 #t1 #Ht elim (after_at_fwd … Hi1 … Ht) -t
-#j1 #Hij1 #H >(at_inj … Hi2 … H) -i //
-qed-.
-
-lemma after_fwd_at2: ∀t,i1,i. @⦃i1, t⦄ ≡ i → ∀t1,i2. @⦃i1, t1⦄ ≡ i2 →
- ∀t2. t2 ⊚ t1 ≡ t → @⦃i2, t2⦄ ≡ i.
-#t #i1 #i #H elim H -t -i1 -i
-[ #t #t1 #i2 #Ht1 #t2 #H elim (after_inv_O3 … H) -H
- #u2 #u1 #_ #H1 #H2 destruct >(at_inv_OOx … Ht1) -t -u1 -i2 //
-| #t #i1 #i #_ #IH #t1 #i2 #Ht1 #t2 #H elim (after_inv_O3 … H) -H
- #u2 #u1 #Hu #H1 #H2 destruct elim (at_inv_SOx … Ht1) -Ht1
- /3 width=3 by at_skip/
-| #t #b #i1 #i #_ #IH #t1 #i2 #Ht1 #t2 #H elim (after_inv_S3 … H) -H *
- [ #u2 #u1 #a1 #Hu #H1 #H2 destruct elim (at_inv_xSx … Ht1) -Ht1
- /3 width=3 by at_skip/
- | #u2 #a2 #Hu #H destruct /3 width=3 by at_lift/
- ]
-]
-qed-.
+lemma after_inv_total: ∀f2,f1,f. f2 ⊚ f1 ≘ f → f2 ∘ f1 ≡ f.
+/2 width=4 by after_mono/ qed-.
-(* Advanced forward lemmas on after *****************************************)
+(* Specific forward lemmas on after *****************************************)
-lemma after_fwd_hd: ∀t1,t2,t,a2,a. t1 ⊚ a2@t2 ≡ a@t → a = t1@❴a2❵.
-#t1 #t2 #t #a2 #a #Ht lapply (after_fwd_at … 0 … Ht) -Ht [4: // | // |2,3: skip ]
+lemma after_fwd_hd: ∀f2,f1,f,n1,n. f2 ⊚ n1⨮f1 ≘ n⨮f → f2@❨n1❩ = n.
+#f2 #f1 #f #n1 #n #H lapply (after_fwd_at ? n1 0 … H) -H [1,2,3: // ]
/3 width=2 by at_inv_O1, sym_eq/
qed-.
-lemma after_fwd_tl: ∀t,t2,a2,t1,a1,a. a1@t1 ⊚ a2@t2 ≡ a@t →
- tln … a2 t1 ⊚ t2 ≡ t.
-#t #t2 #a2 elim a2 -a2
-[ #t1 #a1 #a #Ht elim (after_inv_O2_aux2 … Ht) -Ht //
-| #a2 #IH * #b1 #t1 #a1 #a #Ht
- lapply (after_fwd_hd … Ht) #Ha
- lapply (after_inv_S2 … Ht … Ha) -a
- /2 width=3 by/
-]
-qed-.
-
-lemma after_inv_apply: ∀t1,t2,t,a1,a2,a. a1@t1 ⊚ a2@t2 ≡ a@t →
- a = (a1@t1)@❴a2❵ ∧ tln … a2 t1 ⊚ t2 ≡ t.
-/3 width=3 by after_fwd_tl, after_fwd_hd, conj/ qed-.
-
-(* Main properties on after *************************************************)
-
-let corec after_trans1: ∀t1,t2,t0. t1 ⊚ t2 ≡ t0 →
- ∀t3,t4. t0 ⊚ t3 ≡ t4 →
- ∀t. t2 ⊚ t3 ≡ t → t1 ⊚ t ≡ t4 ≝ ?.
-#t1 #t2 #t0 * -t1 -t2 -t0 #t1 #t2 #t0 #b1 [1,2: #b2 ] #b0
-[ #Ht0 #H1 #H2 #H0 * #b3 #t3 * #b4 #t4 #Ht4 * #b #t #Ht
- cases (after_inv_O1_aux2 … Ht4 H0) -Ht4 -H0 *
- [ #Ht4 #H3 #H4 cases (after_inv_zero_aux2 … Ht H2 H3) -Ht -H2 -H3
- #Ht #H /3 width=6 by after_zero/
- | #a0 #a4 #Ht4 #H3 #H4 cases (after_inv_skip_aux2 … Ht H2 … H3) -Ht -H2 -H3
- #a #Ht3 #H /3 width=6 by after_skip/
- ]
-| #a2 #a0 #Ht0 #H1 #H2 #H0 #t3 * #b4 #t4 #Ht4 cases (after_inv_S1_aux2 … Ht4 … H0) -Ht4 -H0
- #a4 #Ht4 #H4 * #b #t #H cases (after_inv_S1_aux2 … H … H2) -H -H2
- #a #Ht3 #H /3 width=6 by after_skip/
-| #a1 #a0 #Ht0 #H1 #H0 #t3 * #b4 #t4 #Ht4 cases (after_inv_S1_aux2 … Ht4 … H0) -Ht4 -H0
- #a4 #Ht4 #H4 * #b #t #Ht /3 width=6 by after_drop/
-]
-qed-.
-
-let corec after_trans2: ∀t1,t0,t4. t1 ⊚ t0 ≡ t4 →
- ∀t2, t3. t2 ⊚ t3 ≡ t0 →
- ∀t. t1 ⊚ t2 ≡ t → t ⊚ t3 ≡ t4 ≝ ?.
-#t1 #t0 #t4 * -t1 -t0 -t4 #t1 #t0 #t4 #b1 [1,2: #b0 ] #b4
-[ #Ht4 #H1 #H0 #H4 * #b2 #t2 * #b3 #t3 #Ht0 * #b #t #Ht
- cases (after_inv_O3_aux2 … Ht0 H0) -b0
- #Ht0 #H2 #H3 cases (after_inv_zero_aux2 … Ht H1 H2) -b1 -b2
- #Ht #H /3 width=6 by after_zero/
-| #a0 #a4 #Ht4 #H1 #H0 #H4 * #b2 #t2 * #b3 #t3 #Ht0 * #b #t #Ht
- cases (after_inv_S3_aux2 … Ht0 … H0) -b0 *
- [ #a3 #Ht0 #H2 #H3 cases (after_inv_zero_aux2 … Ht H1 H2) -b1 -b2
- #Ht #H /3 width=6 by after_skip/
- | #a2 #Ht0 #H2 cases (after_inv_skip_aux2 … Ht H1 … H2) -b1 -b2
- #a #Ht #H /3 width=6 by after_drop/
- ]
-| #a1 #a4 #Ht4 #H1 #H4 * #b2 #t2 * #b3 #t3 #Ht0 * #b #t #Ht
- cases (after_inv_S1_aux2 … Ht … H1) -b1
- #a #Ht #H /3 width=6 by after_drop/
+lemma after_fwd_tls: ∀f,f1,n1,f2,n2,n. n2⨮f2 ⊚ n1⨮f1 ≘ n⨮f →
+ (⫰*[n1]f2) ⊚ f1 ≘ f.
+#f #f1 #n1 elim n1 -n1
+[ #f2 #n2 #n #H elim (after_inv_xpx … H) -H //
+| #n1 #IH * #m1 #f2 #n2 #n #H elim (after_inv_xnx … H) -H [2,3: // ]
+ #m #Hm #H destruct /2 width=3 by/
]
qed-.
-let corec after_mono: ∀t1,t2,x. t1 ⊚ t2 ≡ x → ∀y. t1 ⊚ t2 ≡ y → x ≐ y ≝ ?.
-* #a1 #t1 * #a2 #t2 * #c #x #Hx * #d #y #Hy
-cases (after_inv_apply … Hx) -Hx #Hc #Hx
-cases (after_inv_apply … Hy) -Hy #Hd #Hy
-/3 width=4 by eq_sec/
-qed-.
+lemma after_inv_apply: ∀f2,f1,f,n2,n1,n. n2⨮f2 ⊚ n1⨮f1 ≘ n⨮f →
+ (n2⨮f2)@❨n1❩ = n ∧ (⫰*[n1]f2) ⊚ f1 ≘ f.
+/3 width=3 by after_fwd_tls, after_fwd_hd, conj/ qed-.
-let corec after_inj: ∀t1,x,t. t1 ⊚ x ≡ t → ∀y. t1 ⊚ y ≡ t → x ≐ y ≝ ?.
-* #a1 #t1 * #c #x * #a #t #Hx * #d #y #Hy
-cases (after_inv_apply … Hx) -Hx #Hc #Hx
-cases (after_inv_apply … Hy) -Hy #Hd
-cases (apply_inj_aux … Hc Hd) #Hy -a -d /3 width=4 by eq_sec/
-qed-.
+(* Properties on apply ******************************************************)
-(* Main inversion lemmas on after *******************************************)
-
-theorem after_inv_total: ∀t1,t2,t. t1 ⊚ t2 ≡ t → t1 ∘ t2 ≐ t.
-/2 width=4 by after_mono/ qed-.
+lemma compose_apply (f2) (f1) (i): f2@❨f1@❨i❩❩ = (f2∘f1)@❨i❩.
+/4 width=6 by after_fwd_at, at_inv_total, sym_eq/ qed.
projects / helm.git / blobdiff