One interesting way of looking at this matter involves not picking `filter`

as a primitive notion. There is a Haskell type class called `Filterable`

which is aptly described as:

Like `Functor`

, but it [includes] `Maybe`

effects.

Formally, the class `Filterable`

represents a functor from **Kleisli Maybe** to **Hask**.

The morphism mapping of the "functor from `Kleisli Maybe`

to **Hask**" is captured by the `mapMaybe`

method of the class, which is indeed a generalisation of the homonymous `Data.Maybe`

function:

```
mapMaybe :: Filterable f => (a -> Maybe b) -> f a -> f b
```

The class laws are simply the appropriate functor laws (note that `Just`

and `(<=<)`

are, respectively, identity and composition in **Kleisli Maybe**):

```
mapMaybe Just = id
mapMaybe (g <=< f) = mapMaybe g . mapMaybe f
```

The class can also be expressed in terms of `catMaybes`

...

```
catMaybes :: Filterable f => f (Maybe a) -> f a
```

... which is interdefinable with `mapMaybe`

(cf. the analogous relationship between `sequenceA`

and `traverse`

)...

```
catMaybes = mapMaybe id
mapMaybe g = catMaybes . fmap g
```

... and amounts to a natural transformation between the **Hask** endofunctors `Compose f Maybe`

and `f`

.

What does all of that have to do with your question? Firstly, a functor is a morphism between categories, and a natural transformation is a morphism between functors. That being so, it is possible to talk of morphisms here in a sense that is less boring than the "morphisms in **Hask**" one. You won't necessarily *want* to do so, but in any case it is an existing vantage point.

Secondly, `filter`

is, unsurprisingly, also a method of `Filterable`

, its default definition being:

```
filter :: Filterable f => (a -> Bool) -> f a -> f a
filter p = mapMaybe $ \a -> if p a then Just a else Nothing
```

Or, to spell it using another cute combinator:

```
filter p = mapMaybe (ensure p)
```

That indirectly gives `filter`

a place in this particular constellation of categorical notions.