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The code for the myAny function in this question uses foldr. It stops processing an infinite list when the predicate is satisfied.

I rewrote it using foldl:

myAny :: (a -> Bool) -> [a] -> Bool
myAny p list = foldl step False list
   where
      step acc item = p item || acc

(Note that the arguments to the step function are correctly reversed.)

However, it no longer stops processing infinite lists.

I attempted to trace the function's execution as in Apocalisp's answer:

myAny even [1..]
foldl step False [1..]
step (foldl step False [2..]) 1
even 1 || (foldl step False [2..])
False  || (foldl step False [2..])
foldl step False [2..]
step (foldl step False [3..]) 2
even 2 || (foldl step False [3..])
True   || (foldl step False [3..])
True

However, this is not the way the function behaves. How is this wrong?

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4 Answers 4

up vote 96 down vote accepted

How folds differ seems to be a frequent source of confusion, so here's a more general overview:

Consider folding a list of n values [x1, x2, x3, x4 ... xn ] with some function f and seed z.

foldl is:

  • Left associative: f ( ... (f (f (f (f z x1) x2) x3) x4) ...) xn
  • Tail recursive: It iterates through the list, producing the value afterwards
  • Lazy: Nothing is evaluated until the result is needed
  • Backwards: foldl (flip (:)) [] reverses a list.

foldr is:

  • Right associative: f x1 (f x2 (f x3 (f x4 ... (f xn z) ... )))
  • Recursive into an argument: Each iteration applies f to the next value and the result of folding the rest of the list.
  • Lazy: Nothing is evaluated until the result is needed
  • Forwards: foldr (:) [] returns a list unchanged.

There's a slightly subtle point here that trips people up sometimes: Because foldl is backwards each application of f is added to the outside of the result; and because it is lazy, nothing is evaluated until the result is required. This means that to compute any part of the result, Haskell first iterates through the entire list constructing an expression of nested function applications, then evaluates the outermost function, evaluating its arguments as needed. If f always uses its first argument, this means Haskell has to recurse all the way down to the innermost term, then work backwards computing each application of f.

This is obviously a far cry from the efficient tail-recursion most functional programmers know and love!

In fact, even though foldl is technically tail-recursive, because the entire result expression is built before evaluating anything, foldl can cause a stack overflow!

On the other hand, consider foldr. It's also lazy, but because it runs forwards, each application of f is added to the inside of the result. So, to compute the result, Haskell constructs a single function application, the second argument of which is the rest of the folded list. If f is lazy in its second argument--a data constructor, for instance--the result will be incrementally lazy, with each step of the fold computed only when some part of the result that needs it is evaluated.

So we can see why foldr sometimes works on infinite lists when foldl doesn't: The former can lazily convert an infinite list into another lazy infinite data structure, whereas the latter must inspect the entire list to generate any part of the result. On the other hand, foldr with a function that needs both arguments immediately, such as (+), works (or rather, doesn't work) much like foldl, building a huge expression before evaluating it.

So the two important points to note are these:

  • foldr can transform one lazy recursive data structure into another.
  • Otherwise, lazy folds will crash with a stack overflow on large or infinite lists.

You may have noticed that it sounds like foldr can do everything foldl can, plus more. This is true! In fact, foldl is nearly useless!

But what if we want to produce a non-lazy result by folding over a large (but not infinite) list? For this, we want a strict fold, which the standard libraries thoughfully provide:

foldl' is:

  • Left associative: f ( ... (f (f (f (f z x1) x2) x3) x4) ...) xn
  • Tail recursive: It iterates through the list, producing the value afterwards
  • Strict: Each function application is evaluated along the way
  • Backwards: foldl' (flip (:)) [] reverses a list.

Because foldl' is strict, to compute the result Haskell will evaluate f at each step, instead of letting the left argument accumulate a huge, unevaluated expression. This gives us the usual, efficient tail recursion we want! In other words:

  • foldl' can fold large lists efficiently.
  • foldl' will hang in an infinite loop (not cause a stack overflow) on an infinite list.

The Haskell wiki has a page discussing this, as well.

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I came here because I am curious why foldr is better than foldl in Haskell, while the opposite is true in Erlang (which I learned before Haskell). Since Erlang is not lazy and functions are not curried, so foldl in Erlang behaves like foldl' above. This is a great answer! Good job and thanks! –  Asuka Kenji - Siu Ching Pong - Mar 2 at 14:53
myAny even [1..]
foldl step False [1..]
foldl step (step False 1) [2..]
foldl step (step (step False 1) 2) [3..]
foldl step (step (step (step False 1) 2) 3) [4..]

etc.

Intuitively, foldl is always on the "outside" or on the "left" so it gets expanded first. Ad infinitum.

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Thanks. This helped me get a mental picture of how foldl works. –  titaniumdecoy Jun 21 '10 at 23:56

You can see on Haskell's documentation here that foldl is tail-recursive and will never end ever if passed an infinite list, since it calls itself on the next parameter before returning a value...

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I dont know Haskell, but in Scheme, fold-right will always 'act' on the last element of a list first. Thus is will not work for cyclic list (which is the same as an infinite one).

I am not sure if fold-right can be written tail-recursive, but for any cyclic list you should get a stack overflow. fold-left OTOH is normally implemented with tail recursion, and will just get stuck in an infinite loop, if not terminating it early.

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5  
Laziness complicates matters somewhat, compared to non-lazy languages like Scheme--if you're curious, see my answer. –  C. A. McCann Jun 21 '10 at 14:40

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