A fairly canonical source on this question is Foldr Foldl Foldl' on the Haskell Wiki. In summary, depending on how strictly you can combine elements of the list and what the result of your fold is you may decide to choose either `foldr`

or `foldl'`

. It's rarely the right choice to choose `foldl`

.

Generally, this is a good example of how you have to keep in mind the laziness and strictness of your functions in order to compute efficiently in Haskell. In strict languages, tail-recursive definitions and TCO are the name of the game, but those kinds of definitions may be too "unproductive" (not lazy enough) for Haskell leading to the production of useless thunks and fewer opportunities for optimization.

## When to choose `foldr`

If the operation that *consumes* the result of your fold can operate lazily and your combining function is non-strict in its right argument, then `foldr`

is usually the right choice. The quintessential example of this is the `nonfold`

. First we see that `(:)`

is non-strict on the right

```
head (1 : undefined)
1
```

Then here's `nonfold`

written using `foldr`

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

Since `(:)`

creates lists lazily, an expression like `head . nonfoldr`

can be very efficient, requiring just one folding step and forcing just the head of the input list.

```
head (nonfoldr [1,2,3])
head (foldr (:) [] [1,2,3])
head (1 : foldr (:) [] [2,3])
1
```

### Short-circuiting

A very common place where laziness wins out is in short-circuiting computations. For instance, `lookup :: Eq a => a -> [a] -> Bool`

can be more productive by returning the moment it sees a match.

```
lookupr :: Eq a => a -> [a] -> Bool
lookupr x = foldr (\y inRest -> if x == y then True else inRest) False
```

The short-circuiting occurs because we discard `isRest`

in the first branch of the `if`

. The same thing implemented in `foldl'`

can't do that.

```
lookupl :: Eq a => a -> [a] -> Bool
lookupl x = foldl' (\wasHere y -> if wasHere then wasHere else x == y) False
lookupr 1 [1,2,3,4]
foldr fn False [1,2,3,4]
if 1 == 1 then True else (foldr fn False [2,3,4])
True
lookupl 1 [1,2,3,4]
foldl' fn False [1,2,3,4]
foldl' fn True [2,3,4]
foldl' fn True [3,4]
foldl' fn True [4]
foldl' fn True []
True
```

## When to choose `foldl'`

If the consuming operation or the combining requires that the entire list is processed before it can proceed, then `foldl'`

is usually the right choice. Often the best check for this situation is to ask yourself whether your combining function is strict---if it's strict in the first argument then your whole list must be forced anyway. The quintessential example of this is `sum`

```
sum :: Num a => [a] -> a
sum = foldl' (+) 0
```

since `(1 + 2)`

cannot be reasonably consumed prior to actually doing the addition (Haskell isn't smart enough to know that `1 + 2 >= 1`

without first evaluating `1 + 2`

) then we don't get any benefit from using `foldr`

. Instead, we'll use the *strict combining* property of `foldl'`

to make sure that we evaluate things as eagerly as needed

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

Note that if we pick `foldl`

here we don't get quite the right result. While `foldl`

has the same associativity as `foldl'`

, it doesn't force the combining operation with `seq`

like `foldl'`

does.

```
sumWrong :: Num a => [a] -> a
sumWrong = foldl (+) 0
sumWrong [1,2,3]
foldl (+) 0 [1,2,3]
foldl (+) (0 + 1) [2,3]
foldl (+) ((0 + 1) + 2) [3]
foldl (+) (((0 + 1) + 2) + 3) []
(((0 + 1) + 2) + 3)
((1 + 2) + 3)
(3 + 3)
6
```

## What happens when we choose wrong?

We get extra, useless thunks (space leak) if we choose `foldr`

or `foldl`

when in `foldl'`

sweet spot and we get extra, useless evaluation (time leak) if we choose `foldl'`

when `foldr`

would have been a better choice.

```
nonfoldl :: [a] -> [a]
nonfoldl = foldl (:) []
head (nonfoldl [1,2,3])
head (foldl (:) [] [1,2,3])
head (foldl (:) [1] [2,3])
head (foldl (:) [1,2] [3]) -- nonfoldr finished here, O(1)
head (foldl (:) [1,2,3] [])
head [1,2,3]
1 -- this is O(n)
sumR :: Num a => [a] -> a
sumR = foldr (+) 0
sumR [1,2,3]
foldr (+) 0 [1,2,3]
1 + foldr (+) 0 [2, 3] -- thunks begin
1 + (2 + foldr (+) 0 [3])
1 + (2 + (3 + foldr (+) 0)) -- O(n) thunks hanging about
1 + (2 + (3 + 0)))
1 + (2 + 3)
1 + 5
6 -- forced O(n) thunks
```