# foldl is tail recursive, so how come foldr runs faster than foldl?

I wanted to test foldl vs foldr. From what I've seen you should use foldl over foldr when ever you can due to tail reccursion optimization.

This makes sense. However, after running this test I am confused:

foldr (takes 0.057s when using time command):

``````a::a -> [a] -> [a]
a x = ([x] ++ )

main = putStrLn(show ( sum (foldr a [] [0.. 100000])))
``````

foldl (takes 0.089s when using time command):

``````b::[b] -> b -> [b]
b xs = ( ++ xs). (\y->[y])

main = putStrLn(show ( sum (foldl b [] [0.. 100000])))
``````

It's clear that this example is trivial, but I am confused as to why foldr is beating foldl. Shouldn't this be a clear case where foldl wins?

• Incidentally, I would use the list constructor to write `a` as `a = (:)` – John L Aug 7 '10 at 15:13
• yes. The only reason I made it as ([x] ++ ) was to try and make a and b be as close as possible, so as to compare the folding as closely as I could – Ori Aug 8 '10 at 5:01
• ... and `b` as `b = flip (:)`. – Will Ness Sep 5 '14 at 10:41

## 7 Answers

Welcome to the world of lazy evaluation.

When you think about it in terms of strict evaluation, foldl looks "good" and foldr looks "bad" because foldl is tail recursive, but foldr would have to build a tower in the stack so it can process the last item first.

However, lazy evaluation turns the tables. Take, for example, the definition of the map function:

``````map :: (a -> b) -> [a] -> [b]
map _ []     = []
map f (x:xs) = f x : map f xs
``````

This wouldn't be too good if Haskell used strict evaluation, since it would have to compute the tail first, then prepend the item (for all items in the list). The only way to do it efficiently would be to build the elements in reverse, it seems.

However, thanks to Haskell's lazy evaluation, this map function is actually efficient. Lists in Haskell can be thought of as generators, and this map function generates its first item by applying f to the first item of the input list. When it needs a second item, it just does the same thing again (without using extra space).

It turns out that `map` can be described in terms of `foldr`:

``````map f xs = foldr (\x ys -> f x : ys) [] xs
``````

It's hard to tell by looking at it, but lazy evaluation kicks in because foldr can give `f` its first argument right away:

``````foldr f z []     = z
foldr f z (x:xs) = f x (foldr f z xs)
``````

Because the `f` defined by `map` can return the first item of the result list using solely the first parameter, the fold can operate lazily in constant space.

Now, lazy evaluation does bite back. For instance, try running sum [1..1000000]. It yields a stack overflow. Why should it? It should just evaluate from left to right, right?

Let's look at how Haskell evaluates it:

``````foldl f z []     = z
foldl f z (x:xs) = foldl f (f z x) xs

sum = foldl (+) 0

sum [1..1000000] = foldl (+) 0 [1..1000000]
= foldl (+) ((+) 0 1) [2..1000000]
= foldl (+) ((+) ((+) 0 1) 2) [3..1000000]
= foldl (+) ((+) ((+) ((+) 0 1) 2) 3) [4..1000000]
...
= (+) ((+) ((+) (...) 999999) 1000000)
``````

Haskell is too lazy to perform the additions as it goes. Instead, it ends up with a tower of unevaluated thunks that have to be forced to get a number. The stack overflow occurs during this evaluation, since it has to recurse deeply to evaluate all the thunks.

Fortunately, there is a special function in Data.List called `foldl'` that operates strictly. `foldl' (+) 0 [1..1000000]` will not stack overflow. (Note: I tried replacing `foldl` with `foldl'` in your test, but it actually made it run slower.)

• Good to note that `sum` will usually work, due to strictness analysis. – singpolyma Oct 22 '12 at 18:46
• "The only way to do it efficiently would be to build the elements in reverse, it seems." not if your compiler performs tail recursion modulo cons optimization. :) Then it works just like guarded recursion with a strict data constructor. – Will Ness Oct 24 '12 at 19:04
• @WillNess: Does GHC not have that optimization? – Elliot Cameron Feb 14 '14 at 13:40
• @3noch not as far as I know. but it mostly just doesn't apply, since Haskell is lazy and, as I hinted above, lazy guarded recursion is equivalent to it. and, correction: it should read lazy data constructor, I think: in `map f (x:xs) = f x : map f xs`, the recursion of `map` is guarded by the lazy list constructor `:`. If `:` were strict, there wouldn't be any guarding, just plain recursion. I think a comma is missing there: "... then it works just like guarded recursion, (even if) with a strict data constructor" - if the TRMCO is present. – Will Ness Feb 14 '14 at 16:59
• I have a doubt .. You said in last foldl example : "Haskell is too lazy to go ahead and perform the additions, so this yields a stack overflow"... I think foldl takes lots of memory because of new and new thunks and so run out of memory, rather than running out of stack memory.. that is why.. foldr crashes instantly as stack memory is smaller than total system memory.. – Ashish Negi Jul 2 '15 at 15:04

EDIT: Upon looking at this problem again, I think all current explanations are somewhat insufficient so I've written a longer explanation.

The difference is in how `foldl` and `foldr` apply their reduction function. Looking at the `foldr` case, we can expand it as

``````foldr (\x -> [x] ++ ) [] [0..10000]
 ++ foldr a [] [1..10000]
 ++ ( ++ foldr a [] [2..10000])
...
``````

This list is processed by `sum`, which consumes it as follows:

``````sum = foldl' (+) 0
foldl' (+) 0 ( ++ ( ++ ... ++ ))
foldl' (+) 0 (0 :  ++ ... ++ )     -- get head of list from '++' definition
foldl' (+) 0 ( ++  ++ ... ++ )  -- add accumulator and head of list
foldl' (+) 0 (1 :  ++ ... ++ )
foldl' (+) 1 ( ++ ... ++ )
...
``````

I've left out the details of the list concatenation, but this is how the reduction proceeds. The important part is that everything gets processed in order to minimize list traversals. The `foldr` only traverses the list once, the concatenations don't require continuous list traversals, and `sum` finally consumes the list in one pass. Critically, the head of the list is available from `foldr` immediately to `sum`, so `sum` can begin working immediately and values can be gc'd as they are generated. With fusion frameworks such as `vector`, even the intermediate lists will likely be fused away.

Contrast this to the `foldl` function:

``````b xs = ( ++xs) . (\y->[y])
foldl b [] [0..10000]
foldl b (  ++ [] ) [1..10000]
foldl b (  ++ ( ++ []) ) [2..10000]
foldl b (  ++ ( ++ ( ++ [])) ) [3..10000]
...
``````

Note that now the head of the list isn't available until `foldl` has finished. This means that the entire list must be constructed in memory before `sum` can begin to work. This is much less efficient overall. Running the two versions with `+RTS -s` shows miserable garbage collection performance from the foldl version.

This is also a case where `foldl'` will not help. The added strictness of `foldl'` doesn't change the way the intermediate list is created. The head of the list remains unavailable until foldl' has finished, so the result will still be slower than with `foldr`.

I use the following rule to determine the best choice of `fold`

• For folds that are a reduction, use `foldl'` (e.g. this will be the only/final traversal)
• Otherwise use `foldr`.
• Don't use `foldl`.

In most cases `foldr` is the best fold function because the traversal direction is optimal for lazy evaluation of lists. It's also the only one capable of processing infinite lists. The extra strictness of `foldl'` can make it faster in some cases, but this is dependent on how you'll use that structure and how lazy it is.

• Unfortunately, `sum` uses foldl, not foldl' (unless they fixed that recently). – Joey Adams Aug 7 '10 at 17:58
• Wishful thinking on my part. The argument still stands; you just need to replace the accumulator with a giant thunk. – John L Aug 9 '10 at 15:45
• `foldl1' (+) [1..100000000]` performs near-instantaneously, whereas all the other folds take a few seconds or result in a stack overflow. – Mateen Ulhaq Jan 15 at 11:34

The problem is that tail recursion optimization is a memory optimization, not a execution time optimization!

Tail recursion optimization avoids the need to remember values for each recursive call.

So, foldl is in fact "good" and foldr is "bad".

For example, considering the definitions of foldr and foldl:

``````foldl f z [] = z
foldl f z (x:xs) = foldl f (z `f` x) xs

foldr f z [] = z
foldr f z (x:xs) = x `f` (foldr f z xs)
``````

That's how the expression "foldl (+) 0 [1,2,3]" is evaluated:

``````foldl (+) 0 [1, 2, 3]
foldl (+) (0+1) [2, 3]
foldl (+) ((0+1)+2) 
foldl (+) (((0+1)+2)+3) [ ]
(((0+1)+2)+3)
((1+2)+3)
(3+3)
6
``````

Note that foldl doesn't remember the values 0, 1, 2..., but pass the whole expression (((0+1)+2)+3) as argument lazily and don't evaluates it until the last evaluation of foldl, where it reaches the base case and returns the value passed as the second parameter (z) wich isn't evaluated yet.

On the other hand, that's how foldr works:

``````foldr (+) 0 [1, 2, 3]
1 + (foldr (+) 0 [2, 3])
1 + (2 + (foldr (+) 0 ))
1 + (2 + (3 + (foldr (+) 0 [])))
1 + (2 + (3 + 0)))
1 + (2 + 3)
1 + 5
6
``````

The important difference here is that where foldl evaluates the whole expression in the last call, avoiding the need to come back to reach remembered values, foldr no. foldr remember one integer for each call and performs a addition in each call.

Is important to bear in mind that foldr and foldl are not always equivalents. For instance, try to compute this expressions in hugs:

``````foldr (&&) True (False:(repeat True))

foldl (&&) True (False:(repeat True))
``````

foldr and foldl are equivalent only under certain conditions described here

(sorry for my bad english)

I don't think anyone's actually said the real answer on this one yet, unless I'm missing something (which may well be true and welcomed with downvotes).

I think the biggest different in this case is that `foldr` builds the list like this:

 ++ ( ++ ( ++ (... ++ )))

Whereas `foldl` builds the list like this:

((( ++ ) ++ ) ++ ... ) ++ ) ++ ) ++ 

The difference in subtle, but notice that in the `foldr` version `++` always has only one list element as its left argument. With the `foldl` version, there are up to 999999 elements in `++`'s left argument (on average around 500000), but only one element in the right argument.

However, `++` takes time proportional to the size of the left argument, as it has to look though the entire left argument list to the end and then repoint that last element to the first element of the right argument (at best, perhaps it actually needs to do a copy). The right argument list is unchanged, so it doesn't matter how big it is.

That's why the `foldl` version is much slower. It's got nothing to do with laziness in my opinion.

• foldr is taking less time for OP. – Ashish Negi Jul 2 '15 at 14:41
• @Clinton It makes sense. But does your answer only explains the specific example of OP or the general difference between `foldl` and `foldr`? To me OP picked up a bad example to begin with because the two folding functions are drastically different. – dhu Feb 23 '18 at 17:41

For a, the `[0.. 100000]` list needs to be expanded right away so that foldr can start with the last element. Then as it folds things together, the intermediate results are

``````
[99999, 100000]
[99998, 99999, 100000]
...
[0.. 100000] -- i.e., the original list
``````

Because nobody is allowed to change this list value (Haskell is a pure functional language), the compiler is free to reuse the value. The intermediate values, like `[99999, 100000]` can even be simply pointers into the expanded `[0.. 100000]` list instead of separate lists.

For b, look at the intermediate values:

``````
[0, 1]
[0, 1, 2]
...
[0, 1, ..., 99999]
[0.. 100000]
``````

Each of those intermediate lists can't be reused, because if you change the end of the list then you've changed any other values that point to it. So you're creating a bunch of extra lists that take time to build in memory. So in this case you spend a lot more time allocating and filling in these lists that are intermediate values.

Since you're just making a copy of the list, a runs faster because it starts by expanding the full list and then just keeps moving a pointer from the back of the list to the front.

Neither `foldl` nor `foldr` is tail optimized. It is only `foldl'`.

But in your case using `++` with `foldl'` is not good idea because successive evaluation of `++` will cause traversing growing accumulator again and again.

Well, let me rewrite your functions in a way that difference should be obvious -

``````a :: a -> [a] -> [a]
a = (:)

b :: [b] -> b -> [b]
b = flip (:)
``````

You see that b is more complex than a. If you want to be precise `a` needs one reduction step for value to be calculated, but `b` needs two. That makes the time difference you are measuring, in second example twice as much reductions must be performed.

//edit: But time complexity is the same, so I wouldn't bother about it much.

• I tried changing it to `a = flip \$ flip (:)` and that didn't change the execution time noticeably, so I don't think that flipping the arguments to accommodate foldl is the problem. – Harold L Aug 7 '10 at 8:54