0

I am using function(list_max l) from standard library and proving following lemma. I am facing problem at following point, Plz guide me.

 Fixpoint g_fun (l : list nat) :=
  match l with
 | nil => 1
 | b::nil=> b
 | b::t => gcd b (g_fun t)
end.
 Lemma gc1: forall (l : list nat),
 l<>nil -> list_max l = 0-> g_fun l=0.
 Proof.
 intros. induction l. unfold g_fun.  

 
1
  • Guide: Please learn to write in English and to articulate yourself. – paladin Jul 10 at 17:31
1

I haven't tried it, but I think I would prove two auxiliary lemmas first:

  1. if list_max l = 0, then l is a list with only zeros [EDIT: or l is empty]; proving this will likely go through list_max_le.
  2. g_fun [n; n; ...; n] = g_fun [n]; this should be a simple induction together with Nat.gcd_diag.

If l is empty, your lemma is actually false, because list_max nil = 0 and g_fun nil = 1. Otherwise the lemma is an easy corollary of these two facts.

7
  • I have proved your first suggested lemma ( Lemma list_m0 l : list_max l = 0 -> forall a, nth a l 0 = 0.) But when I write second lemma(Lemma gcdn_n: forall (n : nat) (l : list nat), g_fun [n; n; ...; n] = g_fun [n]). I get Syntax Error: Lexer: Undefined token. – joshan beha Jul 11 at 5:54
  • @joshanbeha, Yes, the notation [n; n; ...; n] doesn't actually exist. You can represent it in several ways, but since you used forall a, nth a l 0 = 0 in your first lemma, it's probably a good idea to use forall a, nth a l n = n in your second one. – ana-borges Jul 11 at 10:50
  • I am applying command (rewrite <- Nat.eq_le_incl) to convert nth a l n = n to nth a l n <= n. But get message (setoid rewrite failed). How I can convert equality relation into less or equal relation? – joshan beha Jul 11 at 17:48
  • Lemma n_gcd l n : g_fun l = n -> forall a, nth a l n = n. Proof. intros n0 a. destruct (le_gt_dec (length l) a) as [h1 | h2]. rewrite nth_overflow. auto. assumption. – joshan beha Jul 11 at 18:10
  • 1. You should apply Nat.eq_le_incl , not rewrite. The statement n <= m is not an equality or an equivalence. 2. The Lemma n_gcd you wrote in the last comment is not true. The gcd of a list can be n without the list being composed only of n. For example, g_fun (1 :: 2 :: nil) is 1, but 1 :: 2 :: nil has an element that is different from 1. What I suggested you prove was actually the other direction of that implication, and it only holds when l is nonempty: l <> nil -> (forall a, nth a l n = n) -> g_fun l = n. – ana-borges Jul 11 at 19:17

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.