A canonical example of the usefulness of recursive algebraic data types and the lazy evaluation is a game algorithm, e.g. as shown in the famous WhyFP paper by John Hughes (*Comp. J., Vol. 32, No. 2, 1989*).

Implementing it with Scala, and using lazily evaluated `Stream[Tree[A]]`

for each subtree of a game leads to `trait Tree[A]`

with a definition:

```
sealed trait Tree[A]
case class Branch[A](ts: Stream[Tree[A]]) extends Tree[A]
case class Leaf[A](a: A) extends Tree[A]
```

Now a lazily evaluated, possibly infinite, game can be presented as:

```
gameTree(b: Board): Tree[Board] =
if (b.isAtEndPos) Leaf(b)
else Branch(b.emptySlots.toStream.map((pos: Int) => gameTree(b addTic pos)))
```

and you can implement a pruning, scoring and parallelization strategy to the
the actual algorithm, that is for example *minimax* which does the job, and
evaluates the parts of the tree which are necessary:

```
def maximize(tree: Tree[Board]): Int = tree match {
case Leaf(board) => board.score
case Branch(subgames) =>
subgames.map((tree: Tree[Board]) => minimize(tree)).max
} ...
def minimize // symmetrically
```

However, the infinite stream introduces a significant performance penalty, and solving identical game tree using eager list (`ts: List[Tree[A]]`

) is 25 times more efficient.

Is there any way to use Streams or lazy structures in Scala effectively in similar situations?

Edit: added some performance results, and actual code: In link is the lazy version.

Lazy version (scala 2.9.1):
`Time for gametree creation: 0.031s and for finding the solution 133.216s.`

No conversions in the tree creation, i.e. mapping over sets in *minimax*
`Time for gametree creation: 4.791s and for finding the solution 6.088s.`

Converting to list in the gameTree creation
`Time for gametree creation: 4.438s and for finding the solution 5.601s.`

`Stream`

s: 0.024s/6.568s,`List`

s: 4.189s/5.382s. So`Stream`

s are faster for me (when you add up both times). – Philippe Feb 20 '12 at 18:22