As you point out, `(fun x => eq_refl x) 2`

is *not* actually different from `eq_refl 2`

, since both expressions compute to the same thing.

Answering your second question is a bit delicate, because it can be interpreted in many different ways. Here's one possibility (which I think is the one you had in mind):

Are there any type `T`

and terms `x y : T`

, such that there is a proof `e`

of `@eq T x y`

in the empty context that does *not* compute to `@eq_refl T z`

(where `z : T`

is the result of computing `x`

and `y`

)?

I believe that the answer to this question is no. It should be possible to prove it formally by arguing that, since Coq's theory is strongly normalizing, `e`

must have a normal form `e'`

, and that all normal forms that have type `eq`

must be `eq_refl`

.

Note that, if drop the requirement that `e`

is typed in the empty context, this does not hold anymore. For instance, consider the proof term of `forall n, n + 0 = n`

.

```
Fixpoint plus_n_0 n : n + 0 = n :=
match n return n + 0 = n with
| 0 => eq_refl 0
| S n' => match plus_n_0 n' in _ = m return S (n' + 0) = S m with
| eq_refl => eq_refl (S (n' + 0))
end
end.
```

In the successor branch, we use the `match`

to produce a proof of `S (n' + 0) = S n'`

which does *not* compute to `eq_refl`

. This happens because the `match`

cannot reduce the `plus_n_0 n'`

term, since it's a function applied to a variable. However, if we apply `plus_n_0`

to any concrete natural number (say, `1729`

), the resulting proof will compute to `eq_refl 1729`

(try it!).

Another thing worth pointing out is that, when arguing that every closed proof of equality computes to `eq_refl`

, we had to reason *outside* of Coq's logic, appealing to a normalization argument that we cannot phrase as a Coq proposition: note that, because Coq identifies terms up to convertibility, there's no way of writing a proposition `P : nat -> Prop`

such that `P n`

holds if and only if `n`

is a Coq term in normal form.

Given this fact, you may wonder if there's anyway of establishing that result *inside* Coq's logic; that is,

```
forall T (x : T) (e : x = x), e = eq_refl x,
```

or, paraphrased in English, "every proof of equality is equal to `eq_refl`

". As it turns out, this statement is *independent* of Coq's logic, which means that it cannot be proved nor disproved within Coq itself.

It may seem at first that this contradicts what I said earlier. But recall that we can always add new axioms to Coq's logic if they don't contradict results that can be proved inside the logic. This means that it is perfectly fine to assume that there exists *some* type `T`

, *some* term `x : T`

, and *some* proof `e`

of `x = x`

such that `e <> eq_refl x`

. If we added this axiom, then the argument I gave earlier would no longer apply, since there would be normal forms of equality proofs that would be syntactically different from `eq_refl`

(namely, `e`

).

The fact that we cannot establish this result inside Coq's logic (and similar formal systems, such as Martin-Löf's type theory) is exactly what enables homotopy type theory. HoTT postulates the existence of the univalence axiom, which allows one to produce provably different proofs of equality.

**Edit** It is important to remember that there are two notions of equality in Coq: *definitional equality* (i.e., terms that are equal by simplification) and *propositional equality* (i.e., terms that we can relate by `=`

). Definitionally equal terms are interchangeable for Coq, whereas propositionally equal terms must be exchanged with an explicit rewriting step (or using the `match`

statement, as seen above).

I was a bit lax in the discussion above about the difference between these two variants. There are cases where proofs of equality are propositionally equal even if they aren't so definitionally. For instance, consider the following alternate proof of reflexivity for `nat`

:

```
Fixpoint eq_refl_nat (n : nat) : n = n :=
match n return n = n with
| 0 => eq_refl 0
| S n' => match eq_refl_nat n' in _ = m return S n' = S m with
| eq_refl => eq_refl (S n')
end
end.
```

The term `eq_refl_nat`

is *not* definitionally equal to `eq_refl`

: we cannot obtain `eq_refl`

from `eq_refl_nat`

just by simplification. However, both are *propositionally* equal: as it turns out, for `nat`

, it is possible to show that `forall n (e : n = n), e = eq_refl`

. (As I mentioned above, this cannot be shown for arbitrary Coq types.)