Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I trying to use coq as a programming language with dependent type. I created the following small program:

Inductive Good : list nat -> Set := 
  | GoodNonEmpty : forall h t, Good (h :: t).

Definition get_first(l : list nat)(good : Good l) : nat := 
  match l with
    | h :: t => h
    | nil => 
      match good with 
      end
  end. 

I defined a type for non empty list and create a function which gets the first element of such a list provided there's a proof that it's not empty. I handle well the case where head items consists of two items, but I can't handle the impossible case of empty list. How can I do this in coq?

share|improve this question
up vote 5 down vote accepted

One way to do it that is simpler than your try is:

Definition get_first (l : list nat) (good : Good l) : nat :=
  match good with
  | GoodNonEmpty h _ => h
  end.

Here is a way to do it in the way you wanted to do it. You'll notice it is very verbose to prove that "Good nil" does not exist, inlined.

Definition get_first (l : list nat) (good : Good l) : nat :=
  (
    match l as l' return (Good l' -> nat) with
    | nil =>
      fun (goodnil : Good nil) =>
        (
          match goodnil in (Good l'') return (nil = l'' -> nat) with
          | GoodNonEmpty h t =>
            fun H => False_rect _ (nil_cons H)
          end
        )
        (@eq_refl _ nil)
    | h :: _ => fun _ => h
    end
  ) good.

You can surely define some of that outside and reuse it. I am not aware of the best practices though. Maybe someone can come with a shorter way to do the same thing.


EDIT:

By the way, you can get to pretty much the same result, in a much easier way, in proof mode:

Definition get_first' (l : list nat) (good : Good l) : nat.
Proof.
  destruct l. inversion good. exact n.
Defined.

You can then:

Print get_first'.

To see how Coq defines it. However, for more involved things, you might be better off following what gdsfhl from the #coq IRC channel proposed as a solution:

http://paste.in.ua/4782/

You can see that he uses the refine tactic to provide part of the skeleton of the term to write, and defer the missing proofs.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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