I'm reading through software foundation and they define equality as

Inductive eq {X:Type} : X -> X -> Prop :=
  | eq_refl : forall x, eq x x.

Notation "x == y" := (eq x y)
                       (at level 70, no associativity)
                     : type_scope.

I've been able to prove equality__leibniz_equality using tactics

Lemma equality__leibniz_equality : forall (X : Type) (x y: X),
  x == y -> forall P:X->Prop, P x -> P y.
  intros X x y H P evP. destruct H. apply evP.

However I also wanted to construct the proof object. This is what I tried:

Definition equality__leibniz_equality' : forall (X : Type) (x y: X),
  x == y -> forall P:X->Prop, P x -> P y :=
  fun (X:Type) (x y: X) (H: x==y) (P:X->Prop) (evP: P x) =>
  match H with
  | eq_refl a => evP

While destruct H worked in my first proof, because the tactic immediately repaced y by x, however pattern matching eq_refl a does not seem to have a similar effect, so that it seems that the information that x=y=a is lost, and I get stucked. Is there a way to construct the proof object?

3 Answers 3

Definition equality__leibniz_equality' : forall (X : Type) (x y: X),
  x == y -> forall P:X->Prop, P x -> P y :=
  fun (X:Type) (x y: X) (H: x==y) (P:X->Prop) =>
  match H with
  | eq_refl a => fun evP => evP

A better definition of eq which makes your definition pass is:

Inductive eq {X:Type} (x : X) : X -> Prop :=
  | eq_refl : eq x x.

You can use Print to look at the definition of any identifier. Or end the proof with Defined instead of Qed to compute with it or unfold it in another proof.


It may also be interesting to look at the elimination principles generated by Coq, and play with Check. With your definition:

Check eq_ind.
     : forall (X : Type) (P : X -> X -> Prop),
       (forall x : X, P x x) -> forall y y0 : X, eq y y0 -> P y y0

Check fun (X: Type)(Q: X -> Prop) =>
        eq_ind _ (fun x y  => Q x -> Q y) (fun x Hx => Hx). 

fun (X : Type) (Q : X -> Prop) =>
eq_ind X (fun x y : X => Q x -> Q y) (fun (x : X) (Hx : Q x) => Hx)
     : forall (X : Type) (Q : X -> Prop) (y y0 : X), eq y y0 -> Q y -> Q y0

You may also compare this version of eq with Coq's Logic.eq(cf. Li-yao Xia's answer) by asking for the type of Logic.eq_ind. Please note also there is no eq_rec nor eq_rect with your definition (in contrast to Logic.eq)

Definition equality__leibniz_equality'' (X : Type) (x y: X) (H : x == y) (P : X -> Prop)
  : P x -> P y :=
    match H with
    | eq_refl x0 => id
Lemma equality__leibniz_equality''' : forall (X : Type) (x y: X),
    x == y -> forall P:X -> Prop, P x -> P y.
  exact equality__leibniz_equality''.
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