(* Basic inversion lemmas ***************************************************)
-lemma sor_inv_ppx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g → ∀f1,f2. ↑f1 = g1 → ↑f2 = g2 →
- â\88\83â\88\83f. f1 â\8b\93 f2 â\89¡ f & ↑f = g.
+lemma sor_inv_ppx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g → ∀f1,f2. ↑f1 = g1 → ↑f2 = g2 →
+ â\88\83â\88\83f. f1 â\8b\93 f2 â\89\98 f & ↑f = g.
#g1 #g2 #g * -g1 -g2 -g
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0 #x1 #x2 #Hx1 #Hx2 destruct
try (>(injective_push … Hx1) -x1) try (>(injective_next … Hx1) -x1)
/2 width=3 by ex2_intro/
qed-.
-lemma sor_inv_npx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g → ∀f1,f2. ⫯f1 = g1 → ↑f2 = g2 →
- â\88\83â\88\83f. f1 â\8b\93 f2 â\89¡ f & ⫯f = g.
+lemma sor_inv_npx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g → ∀f1,f2. ⫯f1 = g1 → ↑f2 = g2 →
+ â\88\83â\88\83f. f1 â\8b\93 f2 â\89\98 f & ⫯f = g.
#g1 #g2 #g * -g1 -g2 -g
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0 #x1 #x2 #Hx1 #Hx2 destruct
try (>(injective_push … Hx1) -x1) try (>(injective_next … Hx1) -x1)
/2 width=3 by ex2_intro/
qed-.
-lemma sor_inv_pnx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g → ∀f1,f2. ↑f1 = g1 → ⫯f2 = g2 →
- â\88\83â\88\83f. f1 â\8b\93 f2 â\89¡ f & ⫯f = g.
+lemma sor_inv_pnx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g → ∀f1,f2. ↑f1 = g1 → ⫯f2 = g2 →
+ â\88\83â\88\83f. f1 â\8b\93 f2 â\89\98 f & ⫯f = g.
#g1 #g2 #g * -g1 -g2 -g
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0 #x1 #x2 #Hx1 #Hx2 destruct
try (>(injective_push … Hx1) -x1) try (>(injective_next … Hx1) -x1)
/2 width=3 by ex2_intro/
qed-.
-lemma sor_inv_nnx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g → ∀f1,f2. ⫯f1 = g1 → ⫯f2 = g2 →
- â\88\83â\88\83f. f1 â\8b\93 f2 â\89¡ f & ⫯f = g.
+lemma sor_inv_nnx: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g → ∀f1,f2. ⫯f1 = g1 → ⫯f2 = g2 →
+ â\88\83â\88\83f. f1 â\8b\93 f2 â\89\98 f & ⫯f = g.
#g1 #g2 #g * -g1 -g2 -g
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0 #x1 #x2 #Hx1 #Hx2 destruct
try (>(injective_push … Hx1) -x1) try (>(injective_next … Hx1) -x1)
(* Advanced inversion lemmas ************************************************)
-lemma sor_inv_ppn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_ppn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f1,f2,f. ↑f1 = g1 → ↑f2 = g2 → ⫯f = g → ⊥.
#g1 #g2 #g #H #f1 #f2 #f #H1 #H2 #H0
elim (sor_inv_ppx … H … H1 H2) -g1 -g2 #x #_ #H destruct
/2 width=3 by discr_push_next/
qed-.
-lemma sor_inv_nxp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_nxp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f1,f. ⫯f1 = g1 → ↑f = g → ⊥.
#g1 #g2 #g #H #f1 #f #H1 #H0
elim (pn_split g2) * #f2 #H2
/2 width=3 by discr_next_push/
qed-.
-lemma sor_inv_xnp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_xnp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f2,f. ⫯f2 = g2 → ↑f = g → ⊥.
#g1 #g2 #g #H #f2 #f #H2 #H0
elim (pn_split g1) * #f1 #H1
/2 width=3 by discr_next_push/
qed-.
-lemma sor_inv_ppp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
- â\88\80f1,f2,f. â\86\91f1 = g1 â\86\92 â\86\91f2 = g2 â\86\92 â\86\91f = g â\86\92 f1 â\8b\93 f2 â\89¡ f.
+lemma sor_inv_ppp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
+ â\88\80f1,f2,f. â\86\91f1 = g1 â\86\92 â\86\91f2 = g2 â\86\92 â\86\91f = g â\86\92 f1 â\8b\93 f2 â\89\98 f.
#g1 #g2 #g #H #f1 #f2 #f #H1 #H2 #H0
elim (sor_inv_ppx … H … H1 H2) -g1 -g2 #x #Hx #H destruct
<(injective_push … H) -f //
qed-.
-lemma sor_inv_npn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
- â\88\80f1,f2,f. ⫯f1 = g1 â\86\92 â\86\91f2 = g2 â\86\92 ⫯f = g â\86\92 f1 â\8b\93 f2 â\89¡ f.
+lemma sor_inv_npn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
+ â\88\80f1,f2,f. ⫯f1 = g1 â\86\92 â\86\91f2 = g2 â\86\92 ⫯f = g â\86\92 f1 â\8b\93 f2 â\89\98 f.
#g1 #g2 #g #H #f1 #f2 #f #H1 #H2 #H0
elim (sor_inv_npx … H … H1 H2) -g1 -g2 #x #Hx #H destruct
<(injective_next … H) -f //
qed-.
-lemma sor_inv_pnn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
- â\88\80f1,f2,f. â\86\91f1 = g1 â\86\92 ⫯f2 = g2 â\86\92 ⫯f = g â\86\92 f1 â\8b\93 f2 â\89¡ f.
+lemma sor_inv_pnn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
+ â\88\80f1,f2,f. â\86\91f1 = g1 â\86\92 ⫯f2 = g2 â\86\92 ⫯f = g â\86\92 f1 â\8b\93 f2 â\89\98 f.
#g1 #g2 #g #H #f1 #f2 #f #H1 #H2 #H0
elim (sor_inv_pnx … H … H1 H2) -g1 -g2 #x #Hx #H destruct
<(injective_next … H) -f //
qed-.
-lemma sor_inv_nnn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
- â\88\80f1,f2,f. ⫯f1 = g1 â\86\92 ⫯f2 = g2 â\86\92 ⫯f = g â\86\92 f1 â\8b\93 f2 â\89¡ f.
+lemma sor_inv_nnn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
+ â\88\80f1,f2,f. ⫯f1 = g1 â\86\92 ⫯f2 = g2 â\86\92 ⫯f = g â\86\92 f1 â\8b\93 f2 â\89\98 f.
#g1 #g2 #g #H #f1 #f2 #f #H1 #H2 #H0
elim (sor_inv_nnx … H … H1 H2) -g1 -g2 #x #Hx #H destruct
<(injective_next … H) -f //
qed-.
-lemma sor_inv_pxp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_pxp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f1,f. ↑f1 = g1 → ↑f = g →
- â\88\83â\88\83f2. f1 â\8b\93 f2 â\89¡ f & ↑f2 = g2.
+ â\88\83â\88\83f2. f1 â\8b\93 f2 â\89\98 f & ↑f2 = g2.
#g1 #g2 #g #H #f1 #f #H1 #H0
elim (pn_split g2) * #f2 #H2
[ /3 width=7 by sor_inv_ppp, ex2_intro/
]
qed-.
-lemma sor_inv_xpp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_xpp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f2,f. ↑f2 = g2 → ↑f = g →
- â\88\83â\88\83f1. f1 â\8b\93 f2 â\89¡ f & ↑f1 = g1.
+ â\88\83â\88\83f1. f1 â\8b\93 f2 â\89\98 f & ↑f1 = g1.
#g1 #g2 #g #H #f2 #f #H2 #H0
elim (pn_split g1) * #f1 #H1
[ /3 width=7 by sor_inv_ppp, ex2_intro/
]
qed-.
-lemma sor_inv_pxn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_pxn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f1,f. ↑f1 = g1 → ⫯f = g →
- â\88\83â\88\83f2. f1 â\8b\93 f2 â\89¡ f & ⫯f2 = g2.
+ â\88\83â\88\83f2. f1 â\8b\93 f2 â\89\98 f & ⫯f2 = g2.
#g1 #g2 #g #H #f1 #f #H1 #H0
elim (pn_split g2) * #f2 #H2
[ elim (sor_inv_ppn … H … H1 H2 H0)
]
qed-.
-lemma sor_inv_xpn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_xpn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f2,f. ↑f2 = g2 → ⫯f = g →
- â\88\83â\88\83f1. f1 â\8b\93 f2 â\89¡ f & ⫯f1 = g1.
+ â\88\83â\88\83f1. f1 â\8b\93 f2 â\89\98 f & ⫯f1 = g1.
#g1 #g2 #g #H #f2 #f #H2 #H0
elim (pn_split g1) * #f1 #H1
[ elim (sor_inv_ppn … H … H1 H2 H0)
]
qed-.
-lemma sor_inv_xxp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g → ∀f. ↑f = g →
- â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89¡ f & ↑f1 = g1 & ↑f2 = g2.
+lemma sor_inv_xxp: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g → ∀f. ↑f = g →
+ â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89\98 f & ↑f1 = g1 & ↑f2 = g2.
#g1 #g2 #g #H #f #H0
elim (pn_split g1) * #f1 #H1
[ elim (sor_inv_pxp … H … H1 H0) -g /2 width=5 by ex3_2_intro/
]
qed-.
-lemma sor_inv_nxn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_nxn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f1,f. ⫯f1 = g1 → ⫯f = g →
- (â\88\83â\88\83f2. f1 â\8b\93 f2 â\89¡ f & ↑f2 = g2) ∨
- â\88\83â\88\83f2. f1 â\8b\93 f2 â\89¡ f & ⫯f2 = g2.
+ (â\88\83â\88\83f2. f1 â\8b\93 f2 â\89\98 f & ↑f2 = g2) ∨
+ â\88\83â\88\83f2. f1 â\8b\93 f2 â\89\98 f & ⫯f2 = g2.
#g1 #g2 elim (pn_split g2) *
/4 width=7 by sor_inv_npn, sor_inv_nnn, ex2_intro, or_intror, or_introl/
qed-.
-lemma sor_inv_xnn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g →
+lemma sor_inv_xnn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g →
∀f2,f. ⫯f2 = g2 → ⫯f = g →
- (â\88\83â\88\83f1. f1 â\8b\93 f2 â\89¡ f & ↑f1 = g1) ∨
- â\88\83â\88\83f1. f1 â\8b\93 f2 â\89¡ f & ⫯f1 = g1.
+ (â\88\83â\88\83f1. f1 â\8b\93 f2 â\89\98 f & ↑f1 = g1) ∨
+ â\88\83â\88\83f1. f1 â\8b\93 f2 â\89\98 f & ⫯f1 = g1.
#g1 elim (pn_split g1) *
/4 width=7 by sor_inv_pnn, sor_inv_nnn, ex2_intro, or_intror, or_introl/
qed-.
-lemma sor_inv_xxn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g → ∀f. ⫯f = g →
- â\88¨â\88¨ â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89¡ f & ⫯f1 = g1 & ↑f2 = g2
- | â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89¡ f & ↑f1 = g1 & ⫯f2 = g2
- | â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89¡ f & ⫯f1 = g1 & ⫯f2 = g2.
+lemma sor_inv_xxn: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g → ∀f. ⫯f = g →
+ â\88¨â\88¨ â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89\98 f & ⫯f1 = g1 & ↑f2 = g2
+ | â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89\98 f & ↑f1 = g1 & ⫯f2 = g2
+ | â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89\98 f & ⫯f1 = g1 & ⫯f2 = g2.
#g1 #g2 #g #H #f #H0
elim (pn_split g1) * #f1 #H1
[ elim (sor_inv_pxn … H … H1 H0) -g
(* Main inversion lemmas ****************************************************)
-corec theorem sor_mono: â\88\80f1,f2,x,y. f1 â\8b\93 f2 â\89¡ x â\86\92 f1 â\8b\93 f2 â\89¡ y → x ≗ y.
+corec theorem sor_mono: â\88\80f1,f2,x,y. f1 â\8b\93 f2 â\89\98 x â\86\92 f1 â\8b\93 f2 â\89\98 y → x ≗ y.
#f1 #f2 #x #y * -f1 -f2 -x
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0 #H
[ cases (sor_inv_ppx … H … H1 H2)
(* Basic properties *********************************************************)
-corec lemma sor_eq_repl_back1: â\88\80f2,f. eq_repl_back â\80¦ (λf1. f1 â\8b\93 f2 â\89¡ f).
+corec lemma sor_eq_repl_back1: â\88\80f2,f. eq_repl_back â\80¦ (λf1. f1 â\8b\93 f2 â\89\98 f).
#f2 #f #f1 * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0 #x #Hx
try cases (eq_inv_px … Hx … H1) try cases (eq_inv_nx … Hx … H1) -g1
/3 width=7 by sor_pp, sor_np, sor_pn, sor_nn/
qed-.
-lemma sor_eq_repl_fwd1: â\88\80f2,f. eq_repl_fwd â\80¦ (λf1. f1 â\8b\93 f2 â\89¡ f).
+lemma sor_eq_repl_fwd1: â\88\80f2,f. eq_repl_fwd â\80¦ (λf1. f1 â\8b\93 f2 â\89\98 f).
#f2 #f @eq_repl_sym /2 width=3 by sor_eq_repl_back1/
qed-.
-corec lemma sor_eq_repl_back2: â\88\80f1,f. eq_repl_back â\80¦ (λf2. f1 â\8b\93 f2 â\89¡ f).
+corec lemma sor_eq_repl_back2: â\88\80f1,f. eq_repl_back â\80¦ (λf2. f1 â\8b\93 f2 â\89\98 f).
#f1 #f #f2 * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf #H #H2 #H0 #x #Hx
try cases (eq_inv_px … Hx … H2) try cases (eq_inv_nx … Hx … H2) -g2
/3 width=7 by sor_pp, sor_np, sor_pn, sor_nn/
qed-.
-lemma sor_eq_repl_fwd2: â\88\80f1,f. eq_repl_fwd â\80¦ (λf2. f1 â\8b\93 f2 â\89¡ f).
+lemma sor_eq_repl_fwd2: â\88\80f1,f. eq_repl_fwd â\80¦ (λf2. f1 â\8b\93 f2 â\89\98 f).
#f1 #f @eq_repl_sym /2 width=3 by sor_eq_repl_back2/
qed-.
-corec lemma sor_eq_repl_back3: â\88\80f1,f2. eq_repl_back â\80¦ (λf. f1 â\8b\93 f2 â\89¡ f).
+corec lemma sor_eq_repl_back3: â\88\80f1,f2. eq_repl_back â\80¦ (λf. f1 â\8b\93 f2 â\89\98 f).
#f1 #f2 #f * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf #H #H2 #H0 #x #Hx
try cases (eq_inv_px … Hx … H0) try cases (eq_inv_nx … Hx … H0) -g
/3 width=7 by sor_pp, sor_np, sor_pn, sor_nn/
qed-.
-lemma sor_eq_repl_fwd3: â\88\80f1,f2. eq_repl_fwd â\80¦ (λf. f1 â\8b\93 f2 â\89¡ f).
+lemma sor_eq_repl_fwd3: â\88\80f1,f2. eq_repl_fwd â\80¦ (λf. f1 â\8b\93 f2 â\89\98 f).
#f1 #f2 @eq_repl_sym /2 width=3 by sor_eq_repl_back3/
qed-.
-corec lemma sor_refl: ∀f. f ⋓ f ≡ f.
+corec lemma sor_idem: ∀f. f ⋓ f ≘ f.
#f cases (pn_split f) * #g #H
[ @(sor_pp … H H H) | @(sor_nn … H H H) ] -H //
qed.
-corec lemma sor_sym: ∀f1,f2,f. f1 ⋓ f2 ≡ f → f2 ⋓ f1 ≡ f.
+corec lemma sor_comm: ∀f1,f2,f. f1 ⋓ f2 ≘ f → f2 ⋓ f1 ≘ f.
#f1 #f2 #f * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf * * * -g1 -g2 -g
[ @sor_pp | @sor_pn | @sor_np | @sor_nn ] /2 width=7 by/
(* Properties with tail *****************************************************)
-lemma sor_tl: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f â\86\92 ⫱f1 â\8b\93 ⫱f2 â\89¡ ⫱f.
+lemma sor_tl: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f â\86\92 ⫱f1 â\8b\93 ⫱f2 â\89\98 ⫱f.
#f1 cases (pn_split f1) * #g1 #H1
#f2 cases (pn_split f2) * #g2 #H2
#f #Hf
] -Hf #g #Hg #H destruct //
qed.
-lemma sor_xxn_tl: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89¡ g → ∀f. ⫯f = g →
- (â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89¡ f & ⫯f1 = g1 & ⫱g2 = f2) ∨
- (â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89¡ f & ⫱g1 = f1 & ⫯f2 = g2).
+lemma sor_xxn_tl: â\88\80g1,g2,g. g1 â\8b\93 g2 â\89\98 g → ∀f. ⫯f = g →
+ (â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89\98 f & ⫯f1 = g1 & ⫱g2 = f2) ∨
+ (â\88\83â\88\83f1,f2. f1 â\8b\93 f2 â\89\98 f & ⫱g1 = f1 & ⫯f2 = g2).
#g1 #g2 #g #H #f #H0 elim (sor_inv_xxn … H … H0) -H -H0 *
/3 width=5 by ex3_2_intro, or_introl, or_intror/
qed-.
+lemma sor_xnx_tl: ∀g1,g2,g. g1 ⋓ g2 ≘ g → ∀f2. ⫯f2 = g2 →
+ ∃∃f1,f. f1 ⋓ f2 ≘ f & ⫱g1 = f1 & ⫯f = g.
+#g1 elim (pn_split g1) * #f1 #H1 #g2 #g #H #f2 #H2
+[ elim (sor_inv_pnx … H … H1 H2) | elim (sor_inv_nnx … H … H1 H2) ] -g2
+/3 width=5 by ex3_2_intro/
+qed-.
+
+lemma sor_nxx_tl: ∀g1,g2,g. g1 ⋓ g2 ≘ g → ∀f1. ⫯f1 = g1 →
+ ∃∃f2,f. f1 ⋓ f2 ≘ f & ⫱g2 = f2 & ⫯f = g.
+#g1 #g2 elim (pn_split g2) * #f2 #H2 #g #H #f1 #H1
+[ elim (sor_inv_npx … H … H1 H2) | elim (sor_inv_nnx … H … H1 H2) ] -g1
+/3 width=5 by ex3_2_intro/
+qed-.
+
(* Properties with iterated tail ********************************************)
-lemma sor_tls: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f →
- â\88\80n. ⫱*[n]f1 â\8b\93 ⫱*[n]f2 â\89¡ ⫱*[n]f.
+lemma sor_tls: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f →
+ â\88\80n. ⫱*[n]f1 â\8b\93 ⫱*[n]f2 â\89\98 ⫱*[n]f.
#f1 #f2 #f #Hf #n elim n -n /2 width=1 by sor_tl/
qed.
(* Properies with test for identity *****************************************)
-corec lemma sor_isid_sn: â\88\80f1. ð\9d\90\88â¦\83f1â¦\84 â\86\92 â\88\80f2. f1 â\8b\93 f2 â\89¡ f2.
+corec lemma sor_isid_sn: â\88\80f1. ð\9d\90\88â¦\83f1â¦\84 â\86\92 â\88\80f2. f1 â\8b\93 f2 â\89\98 f2.
#f1 * -f1
#f1 #g1 #Hf1 #H1 #f2 cases (pn_split f2) *
/3 width=7 by sor_pp, sor_pn/
qed.
-corec lemma sor_isid_dx: â\88\80f2. ð\9d\90\88â¦\83f2â¦\84 â\86\92 â\88\80f1. f1 â\8b\93 f2 â\89¡ f1.
+corec lemma sor_isid_dx: â\88\80f2. ð\9d\90\88â¦\83f2â¦\84 â\86\92 â\88\80f1. f1 â\8b\93 f2 â\89\98 f1.
#f2 * -f2
#f2 #g2 #Hf2 #H2 #f1 cases (pn_split f1) *
/3 width=7 by sor_pp, sor_np/
qed.
-lemma sor_isid: â\88\80f1,f2,f. ð\9d\90\88â¦\83f1â¦\84 â\86\92 ð\9d\90\88â¦\83f2â¦\84 â\86\92 ð\9d\90\88â¦\83fâ¦\84 â\86\92 f1 â\8b\93 f2 â\89¡ f.
+lemma sor_isid: â\88\80f1,f2,f. ð\9d\90\88â¦\83f1â¦\84 â\86\92 ð\9d\90\88â¦\83f2â¦\84 â\86\92 ð\9d\90\88â¦\83fâ¦\84 â\86\92 f1 â\8b\93 f2 â\89\98 f.
/4 width=3 by sor_eq_repl_back2, sor_eq_repl_back1, isid_inv_eq_repl/ qed.
+(* Inversion lemmas with tail ***********************************************)
+
+lemma sor_inv_tl_sn: ∀f1,f2,f. ⫱f1 ⋓ f2 ≘ f → f1 ⋓ ⫯f2 ≘ ⫯f.
+#f1 #f2 #f elim (pn_split f1) *
+#g1 #H destruct /2 width=7 by sor_pn, sor_nn/
+qed-.
+
+lemma sor_inv_tl_dx: ∀f1,f2,f. f1 ⋓ ⫱f2 ≘ f → ⫯f1 ⋓ f2 ≘ ⫯f.
+#f1 #f2 #f elim (pn_split f2) *
+#g2 #H destruct /2 width=7 by sor_np, sor_nn/
+qed-.
+
(* Inversion lemmas with test for identity **********************************)
-lemma sor_isid_inv_sn: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → 𝐈⦃f1⦄ → f2 ≗ f.
+lemma sor_isid_inv_sn: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → 𝐈⦃f1⦄ → f2 ≗ f.
/3 width=4 by sor_isid_sn, sor_mono/
qed-.
-lemma sor_isid_inv_dx: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → 𝐈⦃f2⦄ → f1 ≗ f.
+lemma sor_isid_inv_dx: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → 𝐈⦃f2⦄ → f1 ≗ f.
/3 width=4 by sor_isid_dx, sor_mono/
qed-.
-corec lemma sor_fwd_isid1: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → 𝐈⦃f⦄ → 𝐈⦃f1⦄.
+corec lemma sor_fwd_isid1: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → 𝐈⦃f⦄ → 𝐈⦃f1⦄.
#f1 #f2 #f * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H #Hg
[ /4 width=6 by isid_inv_push, isid_push/ ]
cases (isid_inv_next … Hg … H)
qed-.
-corec lemma sor_fwd_isid2: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → 𝐈⦃f⦄ → 𝐈⦃f2⦄.
+corec lemma sor_fwd_isid2: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → 𝐈⦃f⦄ → 𝐈⦃f2⦄.
#f1 #f2 #f * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H #Hg
[ /4 width=6 by isid_inv_push, isid_push/ ]
cases (isid_inv_next … Hg … H)
qed-.
-lemma sor_inv_isid3: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → 𝐈⦃f⦄ → 𝐈⦃f1⦄ ∧ 𝐈⦃f2⦄.
+lemma sor_inv_isid3: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → 𝐈⦃f⦄ → 𝐈⦃f1⦄ ∧ 𝐈⦃f2⦄.
/3 width=4 by sor_fwd_isid2, sor_fwd_isid1, conj/ qed-.
(* Properties with finite colength assignment *******************************)
-lemma sor_fcla_ex: â\88\80f1,n1. ð\9d\90\82â¦\83f1â¦\84 â\89¡ n1 â\86\92 â\88\80f2,n2. ð\9d\90\82â¦\83f2â¦\84 â\89¡ n2 →
- â\88\83â\88\83f,n. f1 â\8b\93 f2 â\89¡ f & ð\9d\90\82â¦\83fâ¦\84 â\89¡ n & (n1 ∨ n2) ≤ n & n ≤ n1 + n2.
+lemma sor_fcla_ex: â\88\80f1,n1. ð\9d\90\82â¦\83f1â¦\84 â\89\98 n1 â\86\92 â\88\80f2,n2. ð\9d\90\82â¦\83f2â¦\84 â\89\98 n2 →
+ â\88\83â\88\83f,n. f1 â\8b\93 f2 â\89\98 f & ð\9d\90\82â¦\83fâ¦\84 â\89\98 n & (n1 ∨ n2) ≤ n & n ≤ n1 + n2.
#f1 #n1 #Hf1 elim Hf1 -f1 -n1 /3 width=6 by sor_isid_sn, ex4_2_intro/
#f1 #n1 #Hf1 #IH #f2 #n2 * -f2 -n2 /3 width=6 by fcla_push, fcla_next, ex4_2_intro, sor_isid_dx/
#f2 #n2 #Hf2 elim (IH … Hf2) -IH -Hf2 -Hf1 [2,4: #f #n <plus_n_Sm ] (**) (* full auto fails *)
]
qed-.
-lemma sor_fcla: â\88\80f1,n1. ð\9d\90\82â¦\83f1â¦\84 â\89¡ n1 â\86\92 â\88\80f2,n2. ð\9d\90\82â¦\83f2â¦\84 â\89¡ n2 â\86\92 â\88\80f. f1 â\8b\93 f2 â\89¡ f →
- â\88\83â\88\83n. ð\9d\90\82â¦\83fâ¦\84 â\89¡ n & (n1 ∨ n2) ≤ n & n ≤ n1 + n2.
+lemma sor_fcla: â\88\80f1,n1. ð\9d\90\82â¦\83f1â¦\84 â\89\98 n1 â\86\92 â\88\80f2,n2. ð\9d\90\82â¦\83f2â¦\84 â\89\98 n2 â\86\92 â\88\80f. f1 â\8b\93 f2 â\89\98 f →
+ â\88\83â\88\83n. ð\9d\90\82â¦\83fâ¦\84 â\89\98 n & (n1 ∨ n2) ≤ n & n ≤ n1 + n2.
#f1 #n1 #Hf1 #f2 #n2 #Hf2 #f #Hf elim (sor_fcla_ex … Hf1 … Hf2) -Hf1 -Hf2
/4 width=6 by sor_mono, fcla_eq_repl_back, ex3_intro/
qed-.
(* Forward lemmas with finite colength **************************************)
-lemma sor_fwd_fcla_sn_ex: â\88\80f,n. ð\9d\90\82â¦\83fâ¦\84 â\89¡ n â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89¡ f →
- â\88\83â\88\83n1. ð\9d\90\82â¦\83f1â¦\84 â\89¡ n1 & n1 ≤ n.
+lemma sor_fwd_fcla_sn_ex: â\88\80f,n. ð\9d\90\82â¦\83fâ¦\84 â\89\98 n â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89\98 f →
+ â\88\83â\88\83n1. ð\9d\90\82â¦\83f1â¦\84 â\89\98 n1 & n1 ≤ n.
#f #n #H elim H -f -n
[ /4 width=4 by sor_fwd_isid1, fcla_isid, ex2_intro/
| #f #n #_ #IH #f1 #f2 #H
]
qed-.
-lemma sor_fwd_fcla_dx_ex: â\88\80f,n. ð\9d\90\82â¦\83fâ¦\84 â\89¡ n â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89¡ f →
- â\88\83â\88\83n2. ð\9d\90\82â¦\83f2â¦\84 â\89¡ n2 & n2 ≤ n.
-/3 width=4 by sor_fwd_fcla_sn_ex, sor_sym/ qed-.
+lemma sor_fwd_fcla_dx_ex: â\88\80f,n. ð\9d\90\82â¦\83fâ¦\84 â\89\98 n â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89\98 f →
+ â\88\83â\88\83n2. ð\9d\90\82â¦\83f2â¦\84 â\89\98 n2 & n2 ≤ n.
+/3 width=4 by sor_fwd_fcla_sn_ex, sor_comm/ qed-.
(* Properties with test for finite colength *********************************)
-lemma sor_isfin_ex: â\88\80f1,f2. ð\9d\90\85â¦\83f1â¦\84 â\86\92 ð\9d\90\85â¦\83f2â¦\84 â\86\92 â\88\83â\88\83f. f1 â\8b\93 f2 â\89¡ f & 𝐅⦃f⦄.
+lemma sor_isfin_ex: â\88\80f1,f2. ð\9d\90\85â¦\83f1â¦\84 â\86\92 ð\9d\90\85â¦\83f2â¦\84 â\86\92 â\88\83â\88\83f. f1 â\8b\93 f2 â\89\98 f & 𝐅⦃f⦄.
#f1 #f2 * #n1 #H1 * #n2 #H2 elim (sor_fcla_ex … H1 … H2) -H1 -H2
/3 width=4 by ex2_intro, ex_intro/
qed-.
-lemma sor_isfin: â\88\80f1,f2. ð\9d\90\85â¦\83f1â¦\84 â\86\92 ð\9d\90\85â¦\83f2â¦\84 â\86\92 â\88\80f. f1 â\8b\93 f2 â\89¡ f → 𝐅⦃f⦄.
+lemma sor_isfin: â\88\80f1,f2. ð\9d\90\85â¦\83f1â¦\84 â\86\92 ð\9d\90\85â¦\83f2â¦\84 â\86\92 â\88\80f. f1 â\8b\93 f2 â\89\98 f → 𝐅⦃f⦄.
#f1 #f2 #Hf1 #Hf2 #f #Hf elim (sor_isfin_ex … Hf1 … Hf2) -Hf1 -Hf2
/3 width=6 by sor_mono, isfin_eq_repl_back/
qed-.
(* Forward lemmas with test for finite colength *****************************)
-lemma sor_fwd_isfin_sn: â\88\80f. ð\9d\90\85â¦\83fâ¦\84 â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89¡ f → 𝐅⦃f1⦄.
+lemma sor_fwd_isfin_sn: â\88\80f. ð\9d\90\85â¦\83fâ¦\84 â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89\98 f → 𝐅⦃f1⦄.
#f * #n #Hf #f1 #f2 #H
elim (sor_fwd_fcla_sn_ex … Hf … H) -f -f2 /2 width=2 by ex_intro/
qed-.
-lemma sor_fwd_isfin_dx: â\88\80f. ð\9d\90\85â¦\83fâ¦\84 â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89¡ f → 𝐅⦃f2⦄.
+lemma sor_fwd_isfin_dx: â\88\80f. ð\9d\90\85â¦\83fâ¦\84 â\86\92 â\88\80f1,f2. f1 â\8b\93 f2 â\89\98 f → 𝐅⦃f2⦄.
#f * #n #Hf #f1 #f2 #H
elim (sor_fwd_fcla_dx_ex … Hf … H) -f -f1 /2 width=2 by ex_intro/
qed-.
(* Inversion lemmas with test for finite colength ***************************)
-lemma sor_inv_isfin3: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → 𝐅⦃f⦄ → 𝐅⦃f1⦄ ∧ 𝐅⦃f2⦄.
+lemma sor_inv_isfin3: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → 𝐅⦃f⦄ → 𝐅⦃f1⦄ ∧ 𝐅⦃f2⦄.
/3 width=4 by sor_fwd_isfin_dx, sor_fwd_isfin_sn, conj/ qed-.
(* Inversion lemmas with inclusion ******************************************)
-corec lemma sor_inv_sle_sn: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → f1 ⊆ f.
+corec lemma sor_inv_sle_sn: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → f1 ⊆ f.
#f1 #f2 #f * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0
/3 width=5 by sle_push, sle_next, sle_weak/
qed-.
-corec lemma sor_inv_sle_dx: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89¡ f → f2 ⊆ f.
+corec lemma sor_inv_sle_dx: â\88\80f1,f2,f. f1 â\8b\93 f2 â\89\98 f → f2 ⊆ f.
#f1 #f2 #f * -f1 -f2 -f
#f1 #f2 #f #g1 #g2 #g #Hf #H1 #H2 #H0
/3 width=5 by sle_push, sle_next, sle_weak/
qed-.
+lemma sor_inv_sle_sn_trans: ∀f1,f2,f. f1 ⋓ f2 ≘ f → ∀g. g ⊆ f1 → g ⊆ f.
+/3 width=4 by sor_inv_sle_sn, sle_trans/ qed-.
+
+lemma sor_inv_sle_dx_trans: ∀f1,f2,f. f1 ⋓ f2 ≘ f → ∀g. g ⊆ f2 → g ⊆ f.
+/3 width=4 by sor_inv_sle_dx, sle_trans/ qed-.
+
+axiom sor_inv_sle: ∀f1,f2,f. f1 ⋓ f2 ≘ f → ∀g. f1 ⊆ g → f2 ⊆ g → f ⊆ g.
+
(* Properties with inclusion ************************************************)
-lemma sor_sle_sn: ∀f1,f2,f. f1 ⋓ f2 ≡ f → ∀g. g ⊆ f1 → g ⊆ f.
-/3 width=4 by sor_inv_sle_sn, sle_trans/ qed.
+corec lemma sor_sle_dx: ∀f1,f2. f1 ⊆ f2 → f1 ⋓ f2 ≘ f2.
+#f1 #f2 * -f1 -f2 /3 width=7 by sor_pp, sor_nn, sor_pn/
+qed.
+
+corec lemma sor_sle_sn: ∀f1,f2. f1 ⊆ f2 → f2 ⋓ f1 ≘ f2.
+#f1 #f2 * -f1 -f2 /3 width=7 by sor_pp, sor_nn, sor_np/
+qed.
+
+(* Main properties **********************************************************)
+
+axiom monotonic_sle_sor: ∀f1,g1. f1 ⊆ g1 → ∀f2,g2. f2 ⊆ g2 →
+ ∀f. f1 ⋓ f2 ≘ f → ∀g. g1 ⋓ g2 ≘ g → f ⊆ g.
+
+axiom sor_assoc_dx: ∀f0,f3,f4. f0 ⋓ f3 ≘ f4 →
+ ∀f1,f2. f1 ⋓ f2 ≘ f0 →
+ ∀f. f2 ⋓ f3 ≘ f → f1 ⋓ f ≘ f4.
+
+axiom sor_assoc_sn: ∀f1,f0,f4. f1 ⋓ f0 ≘ f4 →
+ ∀f2, f3. f2 ⋓ f3 ≘ f0 →
+ ∀f. f1 ⋓ f2 ≘ f → f ⋓ f3 ≘ f4.
+
+lemma sor_comm_23: ∀f0,f1,f2,f3,f4,f.
+ f0⋓f4 ≘ f1 → f1⋓f2 ≘ f → f0⋓f2 ≘ f3 → f3⋓f4 ≘ f.
+/4 width=6 by sor_comm, sor_assoc_dx/ qed-.
+
+corec theorem sor_comm_23_idem: ∀f0,f1,f2. f0 ⋓ f1 ≘ f2 →
+ ∀f. f1 ⋓ f2 ≘ f → f1 ⋓ f0 ≘ f.
+#f0 #f1 #f2 * -f0 -f1 -f2
+#f0 #f1 #f2 #g0 #g1 #g2 #Hf2 #H0 #H1 #H2 #g #Hg
+[ cases (sor_inv_ppx … Hg … H1 H2)
+| cases (sor_inv_pnx … Hg … H1 H2)
+| cases (sor_inv_nnx … Hg … H1 H2)
+| cases (sor_inv_nnx … Hg … H1 H2)
+] -g2 #f #Hf #H
+/3 width=7 by sor_nn, sor_np, sor_pn, sor_pp/
+qed-.
+
+corec theorem sor_coll_dx: ∀f1,f2,f. f1 ⋓ f2 ≘ f → ∀g1,g2,g. g1 ⋓ g2 ≘ g →
+ ∀g0. g1 ⋓ g0 ≘ f1 → g2 ⋓ g0 ≘ f2 → g ⋓ g0 ≘ f.
+#f1 #f2 #f cases (pn_split f) * #x #Hx #Hf #g1 #g2 #g #Hg #g0 #Hf1 #Hf2
+[ cases (sor_inv_xxp … Hf … Hx) -Hf #x1 #x2 #Hf #Hx1 #Hx2
+ cases (sor_inv_xxp … Hf1 … Hx1) -f1 #y1 #y0 #Hf1 #Hy1 #Hy0
+ cases (sor_inv_xpp … Hf2 … Hy0 … Hx2) -f2 #y2 #Hf2 #Hy2
+ cases (sor_inv_ppx … Hg … Hy1 Hy2) -g1 -g2 #y #Hg #Hy
+ @(sor_pp … Hy Hy0 Hx) -g -g0 -f /2 width=8 by/
+| cases (pn_split g) * #y #Hy
+ [ cases (sor_inv_xxp … Hg … Hy) -Hg #y1 #y2 #Hg #Hy1 #Hy2
+ cases (sor_xxn_tl … Hf … Hx) * #x1 #x2 #_ #Hx1 #Hx2
+ [ cases (sor_inv_pxn … Hf1 … Hy1 Hx1) -g1 #y0 #Hf1 #Hy0
+ cases (sor_inv_pnx … Hf2 … Hy2 Hy0) -g2 -x2 #x2 #Hf2 #Hx2
+ | cases (sor_inv_pxn … Hf2 … Hy2 Hx2) -g2 #y0 #Hf2 #Hy0
+ cases (sor_inv_pnx … Hf1 … Hy1 Hy0) -g1 -x1 #x1 #Hf1 #Hx1
+ ]
+ lapply (sor_inv_nnn … Hf … Hx1 Hx2 Hx) -f1 -f2 #Hf
+ @(sor_pn … Hy Hy0 Hx) -g -g0 -f /2 width=8 by/
+ | lapply (sor_tl … Hf) -Hf #Hf
+ lapply (sor_tl … Hg) -Hg #Hg
+ lapply (sor_tl … Hf1) -Hf1 #Hf1
+ lapply (sor_tl … Hf2) -Hf2 #Hf2
+ cases (pn_split g0) * #y0 #Hy0
+ [ @(sor_np … Hy Hy0 Hx) /2 width=8 by/
+ | @(sor_nn … Hy Hy0 Hx) /2 width=8 by/
+ ]
+ ]
+]
+qed-.
-lemma sor_sle_dx: ∀f1,f2,f. f1 ⋓ f2 ≡ f → ∀g. g ⊆ f2 → g ⊆ f.
-/3 width=4 by sor_inv_sle_dx, sle_trans/ qed.
+corec theorem sor_distr_dx: ∀g0,g1,g2,g. g1 ⋓ g2 ≘ g →
+ ∀f1,f2,f. g1 ⋓ g0 ≘ f1 → g2 ⋓ g0 ≘ f2 → g ⋓ g0 ≘ f →
+ f1 ⋓ f2 ≘ f.
+#g0 cases (pn_split g0) * #y0 #H0 #g1 #g2 #g
+[ * -g1 -g2 -g #y1 #y2 #y #g1 #g2 #g #Hy #Hy1 #Hy2 #Hy #f1 #f2 #f #Hf1 #Hf2 #Hf
+ [ cases (sor_inv_ppx … Hf1 … Hy1 H0) -g1
+ cases (sor_inv_ppx … Hf2 … Hy2 H0) -g2
+ cases (sor_inv_ppx … Hf … Hy H0) -g
+ | cases (sor_inv_npx … Hf1 … Hy1 H0) -g1
+ cases (sor_inv_ppx … Hf2 … Hy2 H0) -g2
+ cases (sor_inv_npx … Hf … Hy H0) -g
+ | cases (sor_inv_ppx … Hf1 … Hy1 H0) -g1
+ cases (sor_inv_npx … Hf2 … Hy2 H0) -g2
+ cases (sor_inv_npx … Hf … Hy H0) -g
+ | cases (sor_inv_npx … Hf1 … Hy1 H0) -g1
+ cases (sor_inv_npx … Hf2 … Hy2 H0) -g2
+ cases (sor_inv_npx … Hf … Hy H0) -g
+ ] -g0 #y #Hy #H #y2 #Hy2 #H2 #y1 #Hy1 #H1
+ /3 width=8 by sor_nn, sor_np, sor_pn, sor_pp/
+| #H #f1 #f2 #f #Hf1 #Hf2 #Hf
+ cases (sor_xnx_tl … Hf1 … H0) -Hf1
+ cases (sor_xnx_tl … Hf2 … H0) -Hf2
+ cases (sor_xnx_tl … Hf … H0) -Hf
+ -g0 #y #x #Hx #Hy #H #y2 #x2 #Hx2 #Hy2 #H2 #y1 #x1 #Hx1 #Hy1 #H1
+ /4 width=8 by sor_tl, sor_nn/
+]
+qed-.