The following is syntactic sugar for your current solution:

```
def compose(x: A, y: A): Option[C] = for {
fx <- foo(x)
fy <- foo(y)
} yield bar(fx, fy)
```

Sometimes this approach is nicer than writing out `flatMap`

and `map`

, and sometimes it's not. You'll probably find that you pretty quickly develop strong preferences about this kind of thing. Either could be considered idiomatic Scala.

Since you've indicated that you're interested in the question more generally from the perspective of functional programming, however, it's worth noting that the solutions above are overkill in a sense. They take advantage of the fact that `Option`

is monadic, but for this operation you don't actually need all of that power—the fact that `Option`

has an applicative functor instance is enough. To summarize very informally, `flatMap`

gives you sequencing that you don't need here, since the computation of `fy`

doesn't depend on the computation of `fx`

. Using the applicative functor for `Option`

allows you to more clearly capture the fact that there's no dependency between the two computations.

The Scala standard library doesn't provide any kind of representation of applicative functors, but Scalaz does, and with Scalaz you could write your method like this (see the "appendix" of my answer here for some discussion of the syntax):

```
import scalaz._, Scalaz._
def compose(x: A, y: A): Option[C] = (foo(x) |@| foo(y))(bar)
```

This will produce the same result as the implementation above, but using a more appropriate abstraction.