Coq uses constructive logic, which means that if you try to fill out De Morgan's laws, you'll end up missing 2. Namely, you can't prove:

```
Theorem deMorgan_nand P Q (andPQ : ~(P /\ Q)) : P \/ Q.
Abort.
Theorem deMorgan_nall {A} (P : A -> Prop) (allPa : ~forall a, P a) : exists a, ~P a.
Abort.
```

This makes sense, because you've have to compute whether it was
the left or right item of the `or`

, which you can't do in general.

Looking at "Classical Mathematics for a Constructive World" (https://arxiv.org/pdf/1008.1213.pdf) has the definitions

```
Definition orW P Q := ~(~P /\ ~Q).
Definition exW {A} (P : A -> Prop) := ~forall a, ~P a.
```

similar to De Morgan's law. This suggests an alternative formulation.

```
Theorem deMorgan_nand P Q (andPQ : ~(P /\ Q)) : orW (~P) (~Q).
hnf; intros nnPQ; destruct nnPQ as [ nnP nnQ ].
apply nnP; clear nnP; hnf; intros p.
apply nnQ; clear nnQ; hnf; intros q.
apply (andPQ (conj p q)).
Qed.
Theorem deMorgan_nall {A} (P : A -> Prop) (allPa : ~forall a, P a) : exW (fun a => ~P a).
Abort.
```

But, it doesn't work with negating forall. In particular, it gets stuck on
trying to convert `~~P a`

into `P a`

. So, despite in the nand case
converting `~~P`

into `P`

, it doesn't seem to work with forall.
You can also show that there is some element of `a`

that has
`P a`

.

Similarly, you could try to show

```
Theorem deMorgan_nexn {A} (P : A -> Prop) (exPa : ~exists a, ~P a) : ~~forall a, P a.
Abort.
```

but that gets stuck in that once you have the argument `a`

,
the conclusion is no longer `False`

, so you can't use `~~P -> P`

.

So, if you can't prove `deMorgan_nall`

, is there any theorem like it?
Or is `~forall a, P a`

already as simplified as it can get?
More generally, when the conclusion is `False`

, that allows for using
the law of excluded middle (`P \/ ~P`

). Is there any counterpart
to that that works when the proposition takes an argument, that is
`P : A -> Prop`

instead of `P : Prop`

?