# How can I write reverse by foldr efficiently in Haskell?

Note that the trivial solution

``````reverse a = foldr (\b c -> c ++ [b] ) [] a
``````

is not very efficient, because of the quadratic growth in complexity. If have tried to use the usual foldl to foldr conversion (blindly), but my attempt

``````foldr (\b g x -> g ((\x old -> x:old) x b)) id list []
``````

did not work as I expected.

-

Try this:

``````reverse bs = foldr (\b g x -> g (b : x)) id bs []
``````

Though it's usually really better to write it using foldl':

``````reverse = foldl' (flip (:)) []
``````
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Hi FUZxxl, could you please explain, why and how that works? – Chris Oct 23 '11 at 7:13
Chris: Let's just say: The accumulator has type [a] -> [a]. It's basically building up a lot of encapsulated lambdas, that add the list's elements to the front of what's passed - []. – FUZxxl Oct 23 '11 at 7:59
@Chris I personally prefer it in point-free notation, it is more readable (to me) that way: `reverse xs = foldr f id xs [] where f x r = r . (x:)`. So when the result of `foldr f id xs` is finally applied on `[]`, the `f x1 r1` is called, which produces `r1 . (x1:) \$ []` at which point `r1` is forced. In the end the whole chain `id.(xn:). ... .(x2:).(x1:)` is applied to `[]`. This uses the standard Haskell way of encoding the open-ended (aka "difference-") lists as chains of list-producing functions, `:: [a] -> [a]`. Same is used in `Data.Sequence` I believe. – Will Ness Feb 13 '12 at 9:07
This is one of those rare cases where `foldl'` is not better. The action of blindly applying a lazy constructor is never delayed because there is never any benefit to doing so. In the event that the code produced is actually different, it can only be worse. – dfeuer Sep 2 '15 at 20:30

Consider the following:

``````foldr (<>) seed [x1, x2, ... xn] == x1 <> (x2 <> (... <> (xn <> seed)))
``````

Let's just "cut" it into pieces:

``````(x1 <>) (x2 <>) ... (xn <>)  seed
``````

Now we have this bunch of functions, let's compose them:

``````(x1 <>).(x2 <>). ... .(xn <>).id \$ seed
``````

`((.), id)` it's `Endo` monoid, so

``````foldr (<>) seed xs == (appEndo . foldr (mappend.Endo.(<>)) mempty \$ xs) seed
``````

For left fold we need just `Dual` monoid.

``````leftFold (<>) seed xs = (appEndo . getDual . foldr (mappend . Dual . Endo . (<>)) mempty \$ xs) seed
``````

`(<>) = (:)` and `seed = []`

``````reverse' xs = (appEndo . getDual . foldr (mappend . Dual . Endo . (:)) mempty \$ xs) []
``````

Or simple:

``````reverse' xs = (appEndo . foldr (flip mappend . Endo . (:)) mempty \$ xs) []
reverse' xs = (foldr (flip (.) . (:)) id \$ xs) []
reverse' = flip (foldr (flip (.) . (:)) id) []
``````
-

Basically, you need to transform 1:2:3:[] into (3:).(2:).(1:) and apply it to []. Thus:

``````reverse' xs = foldr (\x g -> g.(x:)) id xs []
``````

The meaning of the accumulated g here is that it acts on its argument by appending the reversed partial tail of xs to it.

For the 1:2:3:[] example, in the last step x will be 3 and g will be (2:).(1:).

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``````foldl (\acc x -> x:acc) [] [1,2,3]
``````
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Please re-read the question, it is foldr not foldl – Rohit Sharma Dec 6 '14 at 14:27
Wrong place for answer, but just what I was looking for. – praetoriaen Sep 8 '15 at 23:08
I want to say that I realized that my answer was not correct very long time ago, but to my amazement many people have already voted it up (in total I got 5 votes up and 5 votes down). I think sometime people land to this page when looking for exactly this answer, thus I decided to keep it here because in the end it is all about helping others to find answers they are looking for. – ivan_a Oct 3 '15 at 18:09

old question, I know, but is there anything non-optimal about this approach, it seems like foldr would be faster due to lazy evaluation and the code is fairly concise:

`````` reverse' :: [a] -> [a]
reverse' = foldr (\x acc -> acc ++ [x]) []
``````

is (++) significantly slower than (:), which requires a few logical twists as shown in FUZxxl's answer

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This implementation is O(n^2) on the length of the list. At every step the current `acc` becomes garbage and a new list is created with `x` as the last element. Lazy evaluation only changes when this happens. In a strict language it would happen prior to `reverse'` returning. In Haskell it will occur when you force the result list. – Andrew Myers Dec 19 '15 at 21:33
ah, that makes perfect sense. Did not think about the fact that it would create a new list at each iteration. Thanks! – low_ghost Dec 19 '15 at 23:02
Some statically-available `++` applications can come out in the wash, but here they'll all actually happen and you will pay dearly for them. – dfeuer Dec 20 '15 at 0:22