# How to prove this DeMorgan law without using automation tactics in Coq?

This is the law I'm trying to prove here:

``````Goal forall (X : Type) (p : X -> Prop), (exists x, ~ p x) <-> ~ (forall x, p x).
``````

Here's my code up to a point where I don't know in which direction to head:

``````Proof.
intros. split.
- intros. destruct H as [x H]. intros nh. apply H. apply (nh x).
- intros H.
``````

What is shown as the subgoal and the premises I have seem to be provable, but what's the move?

I've tried going with `exfalso.`, to `apply H.` afterwards. Which gives me another premise of `x : X` and a subgoal of `px`.

Don't know what to do after. Thanks for the help!

• Congratulations! You just got a grasp that the `<-` direction is not provable in intuitionistic logic. Coming up with a witness for the existential requires a variant of the axiom of choice. That’s why intuitionistic logic requires both quantifiers ∃ and ∀: none is definable in terms of the other one. Oct 1 at 15:14
• @Maëlan Thank you! Oct 1 at 15:38
• @Maëlan Actually, the reverse implication only requires to principle of the excluded middle `forall P, P \/ ~ P`, which is weaker than the axiom of choice. Oct 1 at 16:30

The right-to-left direction is not provable in intuitionistic logic. Coming up with a witness for the existential requires any axiom that moves you to classical logic. For instance, with the principle of excluded middle:

``````Axiom excluded_middle : forall (P : Prop), P \/ ~ P.

Goal  forall (X : Type) (p : X -> Prop),
(exists x, ~ p x) <-> ~ (forall x, p x).
Proof.
intros. split.
- intros. destruct H as [x H]. intros nh. apply H. apply (nh x).
- intros Hnfapx.
(* new hyp:  Hnfapx : ~ (forall x, p x) *)
pose proof (excluded_middle (exists x, ~ p x)) as [? | Hnexnpx]; [assumption|].
(* new hyp:  Hnexnpx : ~ (exists x, ~ p x)
from this (and excluded middle again) we can deduce (forall x, p x)
exfalso. apply Hnfapx. intros x.
(* new hyp:  x : X
goal:     p x *)
pose proof (excluded_middle (p x)) as [? | Hnpx]; [assumption|].
(* new hyp:   Hnpx : ~ p x
so there exists x such that ~ p x