Your question is a bit vague, as you don't specify what `D`

and `R`

are, and where you are stuck in your proof. Try providing a minimal working example, with an explicit `fail`

tactic for where you're stuck in the proof.

In *classical logic* (the one you're use to in maths), as you have the *excluded middle* rule, you can always do a case analysis on whether something is true or false. In vanilla Coq, built for *intuitionistic logic*, it's not the case. Your result is actually *not provable* if the predicate `R`

is not decidable (if it's not either true or false on every input : `forall (x:D), R x \/ ~R x`

), if the type D is not empty.

Try adding the decidability of R as an hypothesis and reprove it. It should follow more or less this structure (the key being the case analysis on whether `(R y)`

is true or false) :

```
Parameter D: Set.
Parameter R: D -> Prop.
Lemma yourGoal :
(forall x, R x \/ ~ R x) -> (* Decidability of R *)
~ ( exists x, ~ (R x) )->
forall y, (R y).
Proof.
intros Hdec Hex y. (* naming the hypothesis for convenience *)
specialize (Hdec y).
destruct Hdec as [H_Ry_is_true | H_Ry_is_false]. (* case analysis, creates two goals *)
+ (* (R y) is true, which is our goal. *)
assumption.
+ (* (R y) is false, which contradicts Hex *)
exfalso. (* transform your goal into False *)
apply Hex.
(* should be easy from here, using the [exists] tactic *)
Qed.
```

Ps: this exact result (and its link with excluded middle) is mentioned in Software foundations, which is a great resource to learn Coq and logic : https://softwarefoundations.cis.upenn.edu/lf-current/Logic.html#not_exists_dist