In the end of the "5. Full OTT" section of Towards Observational Type Theory the authors show how to define coercible-under-constructors indexed data types in OTT. The idea is basically to turn indexed data types into parameterized like this:

```
data IFin : ℕ -> Set where
zero : ∀ {n} -> IFin (suc n)
suc : ∀ {n} -> IFin n -> IFin (suc n)
data PFin (m : ℕ) : Set where
zero : ∀ {n} -> suc n ≡ m -> PFin m
suc : ∀ {n} -> suc n ≡ m -> PFin n -> PFin m
```

Conor also mentions this technique at the bottom of observational type theory (delivery):

The fix, of course, is to do what the GADT people did, and define inductive families explicitly upto propositional equality. And then of course you can transport them, by transisitivity.

However a type checker in Haskell is aware of equality constraints in scope and actually uses them during type checking. E.g. we can write

```
f :: a ~ b => a -> b
f x = x
```

It doesn't work so in type theory, since it's not enough to have a proof of `a ~ b`

in scope to be able to rewrite by this equation: that proof also must be `refl`

, because in the presense of a false hypothesis type checking becomes undecidable due to termination issues (something like this). So when you pattern match on `Fin m`

in Haskell `m`

gets rewritten to `suc n`

in each branch, but that can't happen in type theory, instead you're left with an explicit proof of `suc n ~ m`

. In OTT it's not possible to pattern match on proofs at all, hence you can neither pretend the proof is `refl`

nor actually require that. It's only possible to supply the proof to `coerce`

or just ignore it.

This makes it very hard to write anything that involves indexed data types. E.g. the usual three-lines (including the type signature) `lookup`

for vectors becomes this beast:

```
vlookupₑ : ∀ {n m a} {α : Level a} {A : Univ α} -> ⟦ n ≅ m ⇒ fin n ⇒ vec A m ⇒ A ⟧
vlookupₑ p (fzeroₑ q) (vconsₑ r x xs) = x
vlookupₑ {n} {m} p (fsucₑ {n′} q i) (vconsₑ {m′} r x xs) =
vlookupₑ (left (suc n′) {m} {suc m′} (trans (suc n′) {n} {m} q p) r) i xs
vlookupₑ {n} {m} p (fzeroₑ {n′} q) (vnilₑ r) =
⊥-elim $ left (suc n′) {m} {0} (trans (suc n′) {n} {m} q p) r
vlookupₑ {n} {m} p (fsucₑ {n′} q i) (vnilₑ r) =
⊥-elim $ left (suc n′) {m} {0} (trans (suc n′) {n} {m} q p) r
vlookup : ∀ {n a} {α : Level a} {A : Univ α} -> Fin n -> Vec A n -> ⟦ A ⟧
vlookup {n} = vlookupₑ (refl n)
```

It could be a bit simplified, since if two elements of a data type that has decidable equality are observably equal, then they are also equal in the usual intensional sense, and natural numbers do have decidable equality, so we can coerce all the equations to their intensional counterparts and pattern match on them, but that would break some computational properties of `vlookup`

and is verbose anyway. It's nearly impossible to deal in more complicated cases with indices which equality cannot be decided.

Is my reasoning correct? How is pattern matching in OTT meant to work? If this is a problem indeed, are there any ways to mitigate it?