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)
 Lemma gc1: forall (l : list nat),
 l<>nil -> list_max l = 0-> g_fun l=0.
 intros. induction l. unfold g_fun.  

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

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.

  • 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

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