`Fold`

are a general set of commonly used functions which traverse recursive data structures and typically result in a single value (reference). On sequences and lists, FoldLeft (in a general sense) is tail-recursive and as such, it can be optimized. FoldRight is not tail-recursive and thus can not be tail-call optimized. It does potentially have the benefit of being able to be applied to infinite series however.

The implementation of `foldLeft`

and `foldRight`

from the scala libraries (pirated from @dhg's answer) reflect this optimization/lack-there-of. `foldLeft`

has been manually tail-call optimized using a while loop. `foldRight`

can not be.

```
override /*TraversableLike*/
def foldLeft[B](z: B)(f: (B, A) => B): B = {
var acc = z
var these = this
while (!these.isEmpty) {
acc = f(acc, these.head)
these = these.tail
}
acc
}
override /*IterableLike*/
def foldRight[B](z: B)(f: (A, B) => B): B =
if (this.isEmpty) z
else f(head, tail.foldRight(z)(f))
```

I believe there is a section in Programming in Scala, Second Edition by Odersky, Spoon, Venners on folds which describes how `foldLeft`

on Lists is tail-recursive while it may be possible to `foldRight`

on infinite lists. Unfortunately, I do not have it on me at the moment in order to provide page numbers, etc. If not, it isn't very difficult to prove this.

See also the section of folds in Learn You a Haskell for Great Good by Miran Lipovača

Back when we were dealing with recursion, we noticed a theme
throughout many of the recursive functions that operated on lists.
Usually, we'd have an edge case for the empty list. We'd introduce the
x:xs pattern and then we'd do some action that involves a single
element and the rest of the list. It turns out this is a very common
pattern, so a couple of very useful functions were introduced to
encapsulate it. These functions are called folds.

`def foldRight[B](z: B)(op: (A, B) => B): B = reversed.foldLeft(z)((x, y) => op(y, x))`

. Isn't there a heuristic to punt to /:? – som-snytt Dec 29 '12 at 0:41