# Why `foldl1` runs out of memory yet `foldr1` works just fine?

I wrote `last` function by using `foldl1` and `foldr1`.

``````lastr :: [a] -> a
lastr = foldr1 (flip const)

lastl :: [a] -> a
lastl = foldl1 (flip const)
``````

They just work fine for short lists. But when I tried with a very long list, [1..10^8], lastr returns the solution in 6.94 sec yet lastl ran out of memory.

Definition of foldr1 and foldl1 are (to my understanding)

``````foldr1 f [x] = x
foldr1 f (x:xs) = f x \$ foldr1 f xs
``````

and

``````foldl1 f [x] = x
foldl1 f (x:y:ys)=foldl1 f \$ f x y : ys
``````

Seen from these, foldl1 seems to use less memory than foldr1 because foldr1 needs to keep an expression like `f x1 \$ f x2 \$ f x3 \$ f x4 \$...` while foldl1 can just calculate `f x y` everytime and store it as a head element of a list in stead of holding it until it gets to 10^8.

Could anyone tell me what is wrong with my argument?

-
foldl is lazy, foldr is strict, try \$ fold1' hackage.haskell.org/packages/archive/base/latest/doc/html/… –  DiegoNolan Apr 30 '13 at 19:28
@DiegoNolan `foldr` is not strict. It's a lot more lazy than `foldl` depending on how you measure laziness. –  sepp2k Apr 30 '13 at 19:44
`(flip const) x y` is just `y`. There is nothing to accumulate. –  n.m. Apr 30 '13 at 20:28

The right fold can start producing immediately if the combining function is lazy in its second argument. A simplistic example:

``````foldr1 (++) ["one", "two", "three", ...]
~> "one" ++ foldr1 (++) ["two", "three", ...]
``````

and the first part of the result is immediately accessible without further evaluating the second argument of `(++)`. That needs only be evaluated when the first part is consumed. Often, the first part can then already be garbage-collected.

In the example with `f = flip const` as the combining function, we have a different situation, that is strict(1) in its second argument, but doesn't need to evaluate it at all. And it ignores its first. That is also good for right folds. Here it goes

``````foldr1 f [x1, x2, x3, ... ]
~> f x1 (foldr1 f [x2, x3, ... ])
``````

and now the outermost `f` can immediately evaluated

``````    ~> foldr1 f [x2, x3, ... ]
~> f x2 (foldr1 f [x3, ... ])
~> foldr1 f [x3, ... ]
``````

and at each step, the outermost `f` can always be immediately evaluated (completely), and one list element thrown away.

If the list is given by a generator that can create it in constant space when sequentially consumed,

``````last = foldr1 (flip const)
``````

can run in constant space.

With the left fold, things are different. Since that is tail-recursive

``````foldl1 f (x:y:zs) = foldl f x (y:zs) = foldl f (f x y) zs
``````

it cannot return anything before the fold has reached the end of the list. In particular, a left fold can never terminate on an infinite list.

Now, looking at our case `f = flip const`, we find

``````foldl1 f [x1, x2, x3, x4, ...]
~> foldl f x1 [x2, x3, x4, ... ]
~> foldl f (f x1 x2) [x3, x4, ... ]
~> foldl f (f (f x1 x2) x3) [x4, ... ]
``````

Of course it would be possible to immediately evaluate `f x1 x2` to `x2`, and then `f x2 x3 = x3`, but that is only possible for this special `f`.

Since `foldl` is a general higher order function, it cannot evaluate the intermediate results before they are needed, since it is possible that the intermediate results never are needed - and in fact, they are never needed here, at the end of the list, one gets an expression

``````f (f (f (f ...y3) y2) y1) y0
~> y0
``````

and then the outermost `f` can be evaluated without looking at the huge thunk of nested `f`s that builds the first argument.

`foldl` (resp. `foldl1`) cannot know that it would have been far more efficient to evaluate the intermediate results immediately.

The strict left folds, `foldl'` and `foldl1'` do that, they evaluate the intermediate results to weak head normal form (to the outermost value constructor or lambda), and

``````last = foldl1' (flip const)
``````

would also be very efficient.

But, since the intermediate results are evaluated further than with `foldr`, they would be a little less efficient, and, importantly, if any list element is `⊥`, the `foldl1'` version would return `⊥`:

``````foldl1' f [x1, ⊥, x3, x4]
~> foldl' f x1 [⊥, x3, x4]
~> case f x1 ⊥ of
pattern    -- that causes ⊥
~> ⊥
``````

whereas the `foldr1` version has no problem with that, since it doesn't inspect the list elements or intermediate results at all.

(1) That `f` is strict in its second argument means that

``````f x ⊥ = ⊥
``````

Since `f` simply returns its second argument, that is evidently the case.

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Thank you very much for your very detailed answer! I learned a lot (including why foldr could work for infinite lists)! I have not studied modules and stuff, so I do not have foldl1'. Is it possible to implement foldl1' only with Prelude functions? Also, what do you mean by `⊥`? I have never seen that character. Again, thank you very much for your great answer! –  Tengu Apr 30 '13 at 23:10
You can implement `foldl1'` with only `Prelude` functions, what you need is `seq`. It's easier to just `import Data.List` to get it (and `foldl'`), though. `foldl' f z = lgo z where lgo x [] = x; lgo x (y:ys) = let w = f x y in w `seq` lgo w ys` is pretty much how `foldl'` is defined, then `foldl1' f (x:xs) = foldl' f x xs` gives you `foldl1'`. These definitions do not force the evaluation of the initial value, if that is desired, one needs to add a `seq` for that. `⊥` is "bottom", a symbol denoting nonterminating computations/undefined/errors. –  Daniel Fischer May 1 '13 at 9:33
I see. Thank you very much!!! –  Tengu May 2 '13 at 20:42