If you're willing to put up with a bit of abstract algebra, there's a nice generalization here: `Iterable[_]`

is a *monoid* under concatenation, where a monoid's just a set of things (iterable collections, in this case) and an addition-like operation (concatenation) with some simple properties and an identity element (the empty collection).

Similarly, if `A`

is a monoid, then `Option[A]`

is also a monoid under a slightly more general version of your `merge`

:

```
Some(xs) + Some(ys) == Some(xs + ys)
Some(xs) + None == Some(xs)
None + Some(ys) == Some(ys)
None + None == None
```

(Note that we need the fact that `A`

is a monoid to know what to do in the first line.)

The Scalaz library captures all these generalizations in its `Monoid`

type class, which lets you write your `merge`

like this:

```
import scalaz._, Scalaz._
def merge(i1: Option[Iterable[_]], i2: Option[Iterable[_]]) = i1 |+| i2
```

Which works as expected:

```
scala> merge(Some(1 to 5), None)
res0: Option[Iterable[_]] = Some(Range(1, 2, 3, 4, 5))
scala> merge(Some(1 to 5), Some(4 :: 3 :: 2 :: 1 :: Nil))
res1: Option[Iterable[_]] = Some(Vector(1, 2, 3, 4, 5, 4, 3, 2, 1))
scala> merge(None, None)
res2: Option[Iterable[_]] = None
```

(Note that there are other operations that would give valid `Monoid`

instances for `Iterable`

and `Option`

, but yours are the most commonly used, and the ones that Scalaz provides by default.)