It depends how **costly** is the expression being evaluated is. On current architectures, two expressions involving few to dozens, even hundreds of instructions cannot be evaluated in parallel efficiently. So you should always make sure that the amount of work you're executing isn't shadowed by the cost of parallelization itself.

With this disclaimer in mind, in Scala 2.10 you can use `Future`

s to accomplish this:

```
val f = future { e1 }
val g = future { e2 }
(Await.result(f), Await.result(g))
```

Note that this style of computations is discouraged (and the above is deliberately overly verbose!), because it involves blocking, and blocking on platform such as the JVM, where there is no concept of efficient continuations, is often costly (though the situations where it is applicable is beyond the scope of this answer, and probably of this answerer). In most cases you should install a callback on the future which is called once its value becomes available. You can do this instead:

```
val h = for {
x <- f
y <- g
} yield (x, y)
```

where `h`

above is a new future which will contain a tuple of values once both become available.

You could rewrite your function `par_tuple`

to either:

```
def par_tuple[E1, E2](e1: =>E1, e2: =>E2): Future[(E1, E2)] = {
val f = future { e1 }
val g = future { e2 }
val h: Future[(E1, E2)] = for {
x <- f
y <- g
} yield (x, y)
h
}
```

This method returns a `Future`

of the tuple you want - an object which will eventually hold the tuple with your expressions. You can compose this future further with other computations, or if you're sure you want to block, you can have another variant:

```
def par_tuple_blocking[E1, E2](e1: =>E1, e2: =>E2): (E1, E2) = Await.result(par_tuple(e1, e2))
```

which blocks until the tuple becomes available in the future.

See more about futures, callbacks and blocking here.