So, I\'m working to teach myself Scala, and one of the things I\'ve been playing with is the Stream
class. I tried to use a naïve translation of the classic Haskell
a match {case x#::xs =>...
is about the same as val (x, xs) = (a.head, a.tail)
. So the difference between the bad version and the good one, is that in that in the bad version, you're calling a.tail
and b.tail
right at the start, instead of just use them to build the tail of the resulting stream. Furthermore when you use them at the right of #::
(not pattern matching, but building the result, as in #:: merge(a.b.tail)
you are not actually calling merge, that will be done only later, when accessing the tail of the returned Stream. So in the good version, a call to merge does not call tail
at all. In the bad version, it calls it right at start.
Now if you consider numbers, or even a simplified version, say 1 #:: merge(numbers, anotherStream)
, when you call you call tail
on that (as take(10)
will), merge
has to be evaluated. You call tail
on numbers
, which call merge
with numbers
as parameters, which calls tails
on numbers
, which calls merge
, which calls tail
...
By contrast, in super lazy Haskell, when you pattern match, it does barely any work. When you do case l of x:xs
, it will evaluate l
just enough to know whether it is an empty list or a cons.
If it is indeed a cons, x
and xs
will be available as two thunks, functions that will eventually give access, later, to content. The closest equivalent in Scala would be to just test empty
.
Note also that in Scala Stream, while the tail
is lazy, the head
is not. When you have a (non empty) Stream, the head has to be known. Which means that when you get the tail of the stream, itself a stream, its head, that is the second element of the original stream, has to be computed. This is sometimes problematic, but in your example, you fail before even getting there.
Note that you can do what you want by defining a better pattern matcher for Stream
:
Here's a bit I just pulled together in a Scala Worksheet:
object HammingTest {
// A convenience object for stream pattern matching
object #:: {
class TailWrapper[+A](s: Stream[A]) {
def unwrap = s.tail
}
object TailWrapper {
implicit def unwrap[A](wrapped: TailWrapper[A]) = wrapped.unwrap
}
def unapply[A](s: Stream[A]): Option[(A, TailWrapper[A])] = {
if (s.isEmpty) None
else {
Some(s.head, new TailWrapper(s))
}
}
}
def merge(a: Stream[BigInt], b: Stream[BigInt]): Stream[BigInt] =
(a, b) match {
case (x #:: xs, y #:: ys) =>
if (x < y) x #:: merge(xs, b)
else if (y < x) y #:: merge(a, ys)
else x #:: merge(xs, ys)
} //> merge: (a: Stream[BigInt], b: Stream[BigInt])Stream[BigInt]
lazy val numbers: Stream[BigInt] =
1 #:: merge(numbers map { _ * 2 }, merge(numbers map { _ * 3 }, numbers map { _ * 5 }))
//> numbers : Stream[BigInt] = <lazy>
numbers.take(10).toList //> res0: List[BigInt] = List(1, 2, 3, 4, 5, 6, 8, 9, 10, 12)
}
Now you just need to make sure that Scala finds your object #::
instead of the one in Stream.class
whenever it's doing pattern matching. To facilitate that, it might be best to use a different name like #>:
or ##::
and then just remember to always use that name when pattern matching.
If you ever need to match the empty stream, use case Stream.Empty
. Using case Stream()
will attempt to evaluate your entire stream there in the pattern match, which will lead to sadness.