# Just a universally quantified hypotesis in coq proof

Another hard goal (for me, of course) is the following:

``````Goal ~(forall P Q: nat -> Prop,
(exists x, P x) /\ (exists x, Q x) ->
(exists x, P x /\ Q x)).
Proof.
``````

I absolutely have no idea of what could I do. If I introduce something, I get a universal quantifier in the hypotesis, and then I can't do anything with it.

I suppose that it exists a standard way for managing such kind of situations, but I was not able to find it out.

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To progress in that proof, you will have to exhibit an instance of `P` and an instance of `Q` such that your hypothesis produces a contradiction.

A simple way to go is to use:

``````P : fun x => x = 0
Q : fun x => x = 1
``````

In order to work with the hypothesis introduced, you might want to use the tactic `specialize`:

``````Goal ~(forall P Q : nat -> Prop,
(exists x, P x) /\ (exists x, Q x) ->
(exists x, P x /\ Q x)).
Proof.
intro H.
specialize (H (fun x => x = 0) (fun x => x = 1)).
``````

It allows you to apply one of your hypothesis on some input (when the hypothesis is a function). From now on, you should be able to derive a contradiction easily.

Alternatively to `specialize`, you can also do:

``````  pose proof (H (fun x => x = 0) (fun x => x = 1)) as Happlied.
``````

Which will conserve H and give you another term `Happlied` (you choose the name) for the application.

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The answer of Ptival did the trick. Here is the code of the complete proof:

``````Goal ~(forall P Q: nat -> Prop,
(exists x, P x) /\ (exists x, Q x) ->
(exists x, P x /\ Q x)).
Proof.
unfold not. intros.
destruct (H (fun x => x = 0) (fun x => x = 1)).
split.
exists 0. reflexivity.
exists 1. reflexivity.
destruct H0. rewrite H0 in H1. inversion H1.
Qed.
``````

Thank you!

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