I'm trying to use heterogenous equality to prove statements involving this indexed datatype:

```
data Counter : ℕ → Set where
cut : (i j : ℕ) → Counter (suc i + j)
```

I was able to write my proofs using `Relation.Binary.HeterogenousEquality.≅-Reasoning`

, but only by assuming the following congruence property:

```
Counter-cong : ∀ {n n′} {k : Counter n} {k′ : Counter n′} →
{A : ℕ → Set} → (f : ∀{n} → Counter n → A n) →
k ≅ k′ → f k ≅ f k′
Counter-cong f k≅k′ = {!!}
```

However, I can't pattern match on `k≅k′`

being `refl`

without getting the following error message from the type checker:

```
Refuse to solve heterogeneous constraint
k : Counter n =?= k′ : Counter n′
```

and if I try to do a case analysis on `k≅k′`

(i.e. by using `C-c C-c`

from the Emacs frontend) to make sure all the implicit arguments are properly matched with respect to their constraints imposed by the `refl`

, I get

```
Cannot decide whether there should be a case for the constructor
refl, since the unification gets stuck on unifying the
inferred indices
[{.Level.zero}, {Counter n}, k]
with the expected indices
[{.Level.zero}, {Counter n′}, k′]
```

(if you're interested, here are some non-relevant background: Eliminating subst to prove equality)

`data Counter (n : ℕ) : Set where cut : (i j : ℕ) → (i+j+1=n : suc (i + j) ≡ n) → Counter n`