I would like to define an equality on `CoList (Maybe Nat)`

s that only takes the `just`

s into account. Of course, I can't just go from `CoList (Maybe A)`

to `CoList A`

, because that wouldn't necessarily be productive.

My question, then, is how could I define such an equivalence relation (with no eye towards decideability)? Does it help, if I can regard infinite `just`

tails as non-equivalent?

@gallais, below, suggests I should be able to naïvely define this relation:

```
open import Data.Colist
open import Data.Maybe
open import Coinduction
open import Relation.Binary
module _ where
infix 4 _∼_
data _∼_ {A : Set} : Colist (Maybe A) → Colist (Maybe A) → Set where
end : [] ∼ []
nothingˡ : ∀ {xs ys} → ∞ (♭ xs ∼ ys) → nothing ∷ xs ∼ ys
nothingʳ : ∀ {xs ys} → ∞ (xs ∼ ♭ ys) → xs ∼ nothing ∷ ys
justs : ∀ {x xs ys} → ∞ (♭ xs ∼ ♭ ys) → just x ∷ xs ∼ just x ∷ ys
```

but proving it's transitive gets into (expected) problems from the termination checker:

```
refl : ∀ {A} → Reflexive (_∼_ {A})
refl {A} {[]} = end
refl {A} {just x ∷ xs} = justs (♯ refl)
refl {A} {nothing ∷ xs} = nothingˡ (♯ nothingʳ (♯ refl)) -- note how I could have defined this the other way round as well...
drop-nothingˡ : ∀ {A xs} {ys : Colist (Maybe A)} → nothing ∷ xs ∼ ys → ♭ xs ∼ ys
drop-nothingˡ (nothingˡ x) = ♭ x
drop-nothingˡ (nothingʳ x) = nothingʳ (♯ drop-nothingˡ (♭ x))
trans : ∀ {A} → Transitive (_∼_ {A})
trans end end = end
trans end (nothingʳ e2) = nothingʳ e2
trans (nothingˡ e1) e2 = nothingˡ (♯ trans (♭ e1) e2)
trans (nothingʳ e1) (nothingˡ e2) = trans (♭ e1) (♭ e2) -- This is where the problem is
trans (nothingʳ e1) (nothingʳ e2) = nothingʳ (♯ trans (♭ e1) (drop-nothingˡ (♭ e2)))
trans (justs e1) (nothingʳ e2) = nothingʳ (♯ trans (justs e1) (♭ e2))
trans (justs e1) (justs e2) = justs (♯ (trans (♭ e1) (♭ e2)))
```

So I tried making the case where both sides are `nothing`

less ambiguous (like how @Vitus suggested):

```
module _ where
infix 4 _∼_
data _∼_ {A : Set} : Colist (Maybe A) → Colist (Maybe A) → Set where
end : [] ∼ []
nothings : ∀ {xs ys} → ∞ (♭ xs ∼ ♭ ys) → nothing ∷ xs ∼ nothing ∷ ys
nothingˡ : ∀ {xs y ys} → ∞ (♭ xs ∼ just y ∷ ys) → nothing ∷ xs ∼ just y ∷ ys
nothingʳ : ∀ {x xs ys} → ∞ (just x ∷ xs ∼ ♭ ys) → just x ∷ xs ∼ nothing ∷ ys
justs : ∀ {x xs ys} → ∞ (♭ xs ∼ ♭ ys) → just x ∷ xs ∼ just x ∷ ys
refl : ∀ {A} → Reflexive (_∼_ {A})
refl {A} {[]} = end
refl {A} {just x ∷ xs} = justs (♯ refl)
refl {A} {nothing ∷ xs} = nothings (♯ refl)
sym : ∀ {A} → Symmetric (_∼_ {A})
sym end = end
sym (nothings xs∼ys) = nothings (♯ sym (♭ xs∼ys))
sym (nothingˡ xs∼ys) = nothingʳ (♯ sym (♭ xs∼ys))
sym (nothingʳ xs∼ys) = nothingˡ (♯ sym (♭ xs∼ys))
sym (justs xs∼ys) = justs (♯ sym (♭ xs∼ys))
trans : ∀ {A} → Transitive (_∼_ {A})
trans end ys∼zs = ys∼zs
trans (nothings xs∼ys) (nothings ys∼zs) = nothings (♯ trans (♭ xs∼ys) (♭ ys∼zs))
trans (nothings xs∼ys) (nothingˡ ys∼zs) = nothingˡ (♯ trans (♭ xs∼ys) (♭ ys∼zs))
trans (nothingˡ xs∼ys) (nothingʳ ys∼zs) = nothings (♯ trans (♭ xs∼ys) (♭ ys∼zs))
trans (nothingˡ xs∼ys) (justs ys∼zs) = nothingˡ (♯ trans (♭ xs∼ys) (justs ys∼zs))
trans (nothingʳ xs∼ys) (nothings ys∼zs) = nothingʳ (♯ trans (♭ xs∼ys) (♭ ys∼zs))
trans {A} {just x ∷ xs} {nothing ∷ ys} {just z ∷ zs} (nothingʳ xs∼ys) (nothingˡ ys∼zs) = ?
trans (justs xs∼ys) (nothingʳ ys∼zs) = nothingʳ (♯ trans (justs xs∼ys) (♭ ys∼zs))
trans (justs xs∼ys) (justs ys∼zs) = justs (♯ trans (♭ xs∼ys) (♭ ys∼zs))
```

but now I don't know how to define the problematic case of `trans`

(the one where I left a hole)

`3 < 5`

or`{1,2,3} < {1,2,3,4,5}`

or`5 | 10`

. None of those are symmetric, because a symmetric ordering turns into an equivalence relation. I'd expect subcolist to mean that the colists use the same elements in the same order, possibly with additional stuff in the middle. Reading your question more carefully (I was in a rush before) I realize that I'd completely misunderstood what you wanted, and just reacted to the Symmetric proof above. Sorry for the confusion! – copumpkin Jan 13 '13 at 21:53`nothing`

s. Both gallais's and Vitus's types easily allow for example to prove that`repeat nothing ∼ <any infinite Colist>`

, and I think that having a "collapsing element" like that will prevent an equivalence relation from being defined (since transitivity through that element will be impossible). The question is then to find what we're missing in the definition. We could use mixed induction-coinduction and demand finite`nothings`

but is that too limiting? Only option? – copumpkin Jan 26 '13 at 18:04`Colist`

and to work exclusively on`Stream`

s, since that's where the problem arises. I'm going to think about it some more and then maybe write up an answer if I figure anything out. – copumpkin Jan 26 '13 at 18:05