Say I have a method that turns a (function on two elements) into a (function on two sequences):

```
def seqed[T](f: (T,T) => T): (Seq[T], Seq[T]) => Seq[T] = (_,_).zipped map f
```

In words, the resulting function takes two sequences `xs`

and `ys`

, and creates a new sequence consisting of `(xs(0) f ys(0), xs(1) f ys(1), ...)`

So, for example, if `xss`

is `Seq(Seq(1,2),Seq(3,4))`

and `f`

is `(a: Int, b: Int) => a + b`

, we can invoke it thus:

```
xss reduceLeft seqed(f) // Seq(4, 6)
```

or with an anonymous function:

```
xss reduceLeft seqed[Int](_+_)
```

This is pretty good; it would be nice to get rid of the `[Int]`

type argument but I don't see how (any ideas?).

To make it feel a bit more like the `tupled`

method, I also tried the enrich-my-library pattern:

```
class SeqFunction[T](f: (T,T) => T) {
def seqed: (Seq[T], Seq[T]) => Seq[T] = (_,_).zipped map f
}
implicit def seqFunction[T](f: (T,T) => T) = new SeqFunction(f)
```

For a pre-defined function this works great, but it's ugly with anonymous ones

```
xss reduceLeft f.seqed
xss reduceLeft ((_:Int) + (_:Int)).seqed
```

Is there another way I can reformulate this so that the types are inferred, and I can use syntax something like:

```
// pseudocode
xss reduceLeft (_+_).seqed // ... or failing that
xss reduceLeft (_+_).seqed[Int]
```

? Or am I asking too much of type inference?

`scala`

and other static typed languages. Maybe that's not exactly on topic, but anyway, I found it extremely interesting. – 4e6 Nov 30 '11 at 21:24