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Assume P: nat -> T -> Prop is a proposition that for any given t: T,

  • either there exists a k: nat such that P holds for all numbers greater than or equal to k and no number less than k.
  • or P k t is false for all k : nat.

I want to define min_k : T -> nat + undef to be the minimum number k such that P k t holds, and undef otherwise.

Is that even possible? I tried to define something like

Definition halts (t : T) := exists k : nat, P k t.

Or maybe

Definition halts (t : T) := exists! k : nat, (~ P k t /\ P (S k) t).

and then use it like

Definition min_k (t : T) := match halts T with
  | True => ??
  | False => undef
end.

but I don't know how to go further from there.

Any ideas would be appreciated.

2 Answers 2

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You can't match on a Prop. If you want to do case analysis then you need something in Type, typically bool or something like sumbool or sumor. In other words, you can do what you want as long as you have a pretty strong hypothesis.

Variable T : Type.
Variable P : nat -> T -> Prop.

Hypothesis PProperty : forall (t : T),
  {k : nat | forall n, (k <= n -> P n t) /\ (n < k -> ~ P n t)}
  +
  {forall k, ~ P k t}.

Definition min_k (t : T) : option nat :=
  match PProperty t with
  | inleft kH => Some (proj1_sig kH)
  | inright _ => None
  end.

Crucially, this wouldn't have worked if PProperty was a Prop disjunction, i.e., if it was of the form _ \/ _ instead of the form _ + { _ }.

By the way, the idiomatic way of describing foo + undef in Coq is to use option foo, which is what I did above, but you can adapt it as you wish.

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  • Thank you for your answer. can I ask for a reference to read more about the proj1_sig? Nov 6 at 8:46
  • I think the hypothesis can be simplified with a trivial one that is correct for any P in classical logic. Hypothesis PProperty : forall (t : T), {k : nat | (P k t) /\ forall n, (n < k -> ~ P n t)} + {forall k, ~ P k t}. Nov 6 at 9:42
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    In general if you don't know what something does you can Check proj1_sig to see its type, Print proj1_sig to see its definition, or even Locate proj1_sig to find out where it is defined. The latter is useful to see if there are some helpful comments in the code next to the definition. In this case there are: we see that proj1_sig is the first projection of sig, which is a Type version of exists _, _. So proj1_sig kH gives you the k for which the property holds.
    – Ana Borges
    Nov 6 at 14:58
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    It depends on what you mean by "classical logic". Usually I'd say it means "Coq + forall P : Prop, P \/ ~ P". Note that this is weaker than forall P : Prop, {P} + {~ P}, which I believe is what you need to assume in order to obtain your PProperty. You can still work under the stronger assumption, but be aware of which axioms you under.
    – Ana Borges
    Nov 6 at 15:07
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In addition to Ana's excellent answer, I think it is worth pointing out that option nat is essentially the same thing as {k : nat | ...} + {forall k, ~ P k t} if you erase the proofs of the latter type: in the first case (Some or inleft), you get a natural number out; in the second (None or inright) you get nothing at all.

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  • Wow. I didn't look at it that way! Thank you for pointing out this point. But I am struggling to understand what does it mean being the same thing. The ... in the left side should be true I think if we want it to be all of nat? Nov 8 at 9:41
  • @KamyarMirzavaziri Just to make things simple, consider the following declaration: Inductive t (P : nat -> Prop) : Type := inleft : forall n, P n -> t P | inright : (forall n, ~ P n) -> t P. By choosing the value of P appropriately, you can obtain a type that is pretty much like the one you had in PProperty. Each constructor of this type takes as an argument a proof that a certain proposition holds. If you remove these two arguments from the declaration, you end up with a definition that is isomorphic to option nat. Nov 13 at 19:36

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