## Applicative Functors

What you are asking for is an applicative functor for a future. See scalaz **Applicative Builder** pattern. It should be rather trivial to roll your own on the back of `zip`

```
(f0 |@| f1 |@| f2)(g) //g is function (Class1, Class2, Class3) => Z
```

This is equivalent to the direct applicative:

```
(f0 <***> (f1, f2))(g)
```

Scalaz ships with a *banana braces* method which forms a tuple from the target and the arguments (i.e. what you asked for). So your solution will be:

```
f0 <|**|> (f1, f2) //that. is. all.
```

You get all this simply by defining a typeclass instance for the following typeclass:

```
trait Apply[Z[_]] {
def apply[A, B](f: Z[A => B], a: Z[A]): Z[B]
}
```

So for future this looks like:

```
implicit val FutureApply = new Apply[Future] {
def apply[A, B](f: Future[A => B], a: Future[A]): Future[B] =
(f zip a) map { case (fn, a1) => fn(a1) }
}
}
```

(Actually you'd need `Pure`

and `Functor`

as well. Might as well implement `Bind`

whilst you're at it - see appendix)

The great thing about this pattern is that you will start to see it everywhere (e.g. in `Option`

, in `Validation`

, in `List`

etc). For example, the cartesian product of 2 streams is:

```
s1 <|*|> s2
```

## Notes

*All the above assuming scalaz 6, doubtless scalaz 7 for 2.10 will ship with these typeclasses by default. *`Pure`

has been renamed `Pointed`

in scalaz7.

## Appendix

Other type class instances for future:

```
implicit val FuturePure = new Pure[Future] {
def pure[A](a: =>A): Future[A] = Future { a }
}
implicit val FutureBind = new Bind[Future] {
def bind[A, B](a: Future[A], f: A => Future[B]): Future[B] = a flatMap f
}
implicit val FutureFunctor = new Functor[Future] {
def map[A, B](a: Future[A], f: A => B): Future[B] = a map f
}
```

`f`

of type`(A, B, ...) => Z`

and you want toliftit to a function of type`(F[A], F[B], ...) => F[Z]`

, you need applicative. In your case,`f = (_, _, _)`

and`F = Future`

. – missingfaktor Jun 22 '12 at 14:27