right associative with precedence 47
for @{'cons $hd $tl}.
-notation "[ list0 x sep ; ]"
+notation "[ list0 term 19 x sep ; ]"
non associative with precedence 90
for ${fold right @'nil rec acc @{'cons $x $acc}}.
[ nil ⇒ False
| cons hd tl ⇒ a=hd ∨ mem A a tl
].
+
+lemma mem_append: ∀A,a,l1,l2.mem A a (l1@l2) →
+ mem ? a l1 ∨ mem ? a l2.
+#A #a #l1 elim l1
+ [#l2 #mema %2 @mema
+ |#b #tl #Hind #l2 *
+ [#eqab %1 %1 @eqab
+ |#Hmema cases (Hind ? Hmema) -Hmema #Hmema [%1 %2 //|%2 //]
+ ]
+ ]
+qed.
+
+lemma mem_append_l1: ∀A,a,l1,l2.mem A a l1 → mem A a (l1@l2).
+#A #a #l1 #l2 elim l1
+ [whd in ⊢ (%→?); @False_ind
+ |#b #tl #Hind * [#eqab %1 @eqab |#Hmema %2 @Hind //]
+ ]
+qed.
+
+lemma mem_append_l2: ∀A,a,l1,l2.mem A a l2 → mem A a (l1@l2).
+#A #a #l1 #l2 elim l1 [//|#b #tl #Hind #Hmema %2 @Hind //]
+qed.
+
+lemma mem_single: ∀A,a,b. mem A a [b] → a=b.
+#A #a #b * // @False_ind
+qed.
lemma mem_map: ∀A,B.∀f:A→B.∀l,b.
mem ? b (map … f l) → ∃a. mem ? a l ∧ f a = b.
]
] qed.
+lemma All_append: ∀A,P,l1,l2. All A P l1 → All A P l2 → All A P (l1@l2).
+#A #P #l1 elim l1 -l1 //
+#a #l1 #IHl1 #l2 * /3 width=1/
+qed.
+
+lemma All_inv_append: ∀A,P,l1,l2. All A P (l1@l2) → All A P l1 ∧ All A P l2.
+#A #P #l1 elim l1 -l1 /2 width=1/
+#a #l1 #IHl1 #l2 * #Ha #Hl12
+elim (IHl1 … Hl12) -IHl1 -Hl12 /3 width=1/
+qed-.
+
+(**************************** Allr ******************************)
+
let rec Allr (A:Type[0]) (R:relation A) (l:list A) on l : Prop ≝
match l with
[ nil ⇒ True
| cons a1 l ⇒ match l with [ nil ⇒ True | cons a2 _ ⇒ R a1 a2 ∧ Allr A R l ]
].
+lemma Allr_fwd_append_sn: ∀A,R,l1,l2. Allr A R (l1@l2) → Allr A R l1.
+#A #R #l1 elim l1 -l1 // #a1 * // #a2 #l1 #IHl1 #l2 * /3 width=2/
+qed-.
+
+lemma Allr_fwd_cons: ∀A,R,a,l. Allr A R (a::l) → Allr A R l.
+#A #R #a * // #a0 #l * //
+qed-.
+
(**************************** Exists *******************************)
let rec Exists (A:Type[0]) (P:A → Prop) (l:list A) on l : Prop ≝