This is a good (and fairly simple) application for the kind of generic programming techniques exemplified in shapeless.

Given your definition,

```
object CombinatorParser extends RegexParsers {
lazy val a = "a"
lazy val b = "b"
lazy val c = "c"
lazy val content = a ~ b ~ c
}
```

We can recursively define a type class that will flatten it's results as follows,

```
import CombinatorParser._
```

First we define a trait which (abstractly) flattens an arbitrary match `M`

to a `List[String]`

,

```
trait Flatten[M] extends (M => List[String]) {
def apply(m : M) : List[String]
}
```

Then we provide type class instances for all the shapes of `M`

that we're interested in: in this case, `String`

, `A ~ B`

and `ParseResult[T]`

(where `A`

, `B`

and `T`

are all types for which there are `Flatten`

instances),

```
// Flatten instance for String
implicit def flattenString = new Flatten[String] {
def apply(m : String) = List(m)
}
// Flatten instance for `A ~ B`. Requires Flatten instances for `A` and `B`.
implicit def flattenPattern[A, B]
(implicit flattenA : Flatten[A], flattenB : Flatten[B]) =
new Flatten[A ~ B] {
def apply(m : A ~ B) = m match {
case a ~ b => flattenA(a) ::: flattenB(b)
}
}
// Flatten instance for ParseResult[T]. Requires a Flatten instance for T.
implicit def flattenParseResult[T]
(implicit flattenT : Flatten[T]) = new Flatten[ParseResult[T]] {
def apply(p : ParseResult[T]) = (p map flattenT) getOrElse Nil
}
```

Finally we can define a convenience function to simplify applying `Flatten`

instances to parse results,

```
def flatten[P](p : P)(implicit flatten : Flatten[P]) = flatten(p)
```

And now we're ready to go,

```
val testChar = "abc"
val output = parseAll(content, testChar)
println(output) // ((a~b)~c) but I want List(a, b, c)
val flattenedOutput = flatten(output)
println(flattenedOutput) // List(a, b, c)
```