# Why I can't use exact P if P is a Prop?

I am trying to prove contraposition. And my proof is like the following. It doesn't work.

``````Theorem contrapositive : forall (P Q : Prop),
(P -> Q) -> (~Q -> ~P).
Proof.
intros.
destruct H0.
apply H.
Fail exact P. Abort.
``````

My question is, after `apply H`, I get the following goal

``````1 goal
P, Q : Prop
H : P -> Q
______________________________________(1/1)
P
``````

So, IMO, we have to prove `P`, and we have a `P` in our hypothesis. So why can't we just use `exact P`?

To have `P : Prop` in your assumptions is not the same as having a `p : P` in your assumptions.
If the goal is to prove `P`, `exact x` must be used with `x` as a term of type `P`, i.e, a proof of `P`. `P` is not a proof of `P`.
• `P : Prop` means "let `P` be an arbitrary proposition". It could be true, it could be false.
• `p : P` means "let `p` be a proof of `P`". That's what means that `P` is true.
• Just a comment on this proof. After "intros. destruct H0." your proof is in a dead-end, but the initial statement was provable. You should try inserting an extra "intros H1." before the `destruct H0.` step and see what happens. In this case, it is important to remember that we wanted to prove the negation of `P`. The premature use of `destruct H0` forgets this information, which is crucial for the rest of the proof.