To complement the other answers with a bit of larger perspective: with lazy lists, using `foldl'`

in a function that returns a list is usually a bad idea. `foldl'`

is often useful when you are reducing a list to a strict (non-lazy) scalar value (e.g., summing a list). But when you're building a list as the result, `foldr`

is usually better, because of laziness; the `:`

constructor is lazy, so the list's tail isn't computed until it's actually needed.

In your case:

```
newList_foldr lst = foldr (\x acc -> x*2 : acc) [] lst
```

This is actually the same as `map (*2)`

:

```
newList_foldr lst = map (*2) lst
map f lst = foldr (\x acc -> f x : acc) [] lst
```

Evaluation (using the first, `map`

-less definition):

```
newList_foldr [1..10]
= foldr (\x acc -> x*2 : acc) [] [1..10]
= foldr (\x acc -> x*2 : acc) [] (1:[2..10])
= 1*2 : foldr (\x rest -> f x : acc) [] [2..10]
```

This is about as far Haskell will evaluate when `newList [1..10]`

is forced. It only evaluates any further if the consumer of this result demands it—and only as little as needed to satisfy the consumer. So for example:

```
firstElem [] = Nothing
firstElem (x:_) = Just x
firstElem (newList_foldr [1..10])
-- firstElem only needs to evaluate newList [1..10] enough to determine
-- which of its subcases applies—empty list or pair.
= firstElem (foldr (\x acc -> x*2 : acc) [] [1..10])
= firstElem (foldr (\x acc -> x*2 : acc) [] (1:[2..10]))
= firstElem (1*2 : foldr (\x rest -> f x : acc) [] [2..10])
-- firstElem doesn't need the tail, so it's never computed!
= Just (1*2)
```

This also means that the `foldr`

-based `newList`

can also work with infinite lists:

```
newList_foldr [1..] = [2,4..]
firstElem (newList_foldr [1..]) = 2
```

If you use `foldl'`

, on the other hand, you must always compute the whole lists, which also means that you can't work on infinite lists:

```
firstElem (newList_good [1..]) -- doesn't terminate
firstElem (newList_good [1..10])
= firstElem (foldl' (\acc x -> x*2 : acc) [] [1..10])
= firstElem (foldl' (\acc x -> x*2 : acc) [] (1:[2..10]))
= firstElem (foldl' (\acc x -> x*2 : acc) [2] [2..10])
-- we can't short circuit here because the [2] is "inside" the foldl', so
-- firstElem can't see it
= firstElem (foldl' (\acc x -> x*2 : acc) [2] (2:[3..10]))
= firstElem (foldl' (\acc x -> x*2 : acc) [4,2] [3..10])
...
= firstElem (foldl' (\acc x -> x*2 : acc) [18,16,14,12,10,8,6,4,2] (10:[]))
= firstElem (foldl' (\acc x -> x*2 : acc) [20,18,16,14,12,10,8,6,4,2] [])
= firstElem [20,18,16,14,12,10,8,6,4,2]
= firstElem (20:[18,16,14,12,10,8,6,4,2])
= Just 20
```

The `foldr`

-based algorithm took 4 steps to compute `firstElem_foldr (newList [1..10])`

, whereas the `foldl'`

-based one took in the order of 21 steps. What's worse is that the 4 steps is a constant cost, whereas the 21 is proportional to the length of the input list—`firstElem (newList_good [1..150000])`

takes 300,001 steps, while `firstElem (newList_foldr [1..150000]`

takes 5 steps, as does `firstElem (newList_foldr [1..]`

for that matter.

Note also that `firstElem (newList_foldr [1.10])`

runs in constant space as well as constant time (it has to; you need more than constant time to allocate more than constant space). The pro-`foldl`

truism from strict languages—"`foldl`

is tail recursive and runs in constant space, `foldr`

is not tail recursive and runs in linear space or worse"—is not true in Haskell.

`acc ++ [x*2]`

step in the example) is inefficient. stackoverflow.com/q/4769302/507803 stackoverflow.com/q/1435359/507803 – Heatsink Feb 18 '13 at 14:41`(++)`

is O(n),`(:)`

is O(1). Also`(++)`

needs the entire list to be evaluated so even though you're using strict fold, you're still building up a lot of thunks. – Cat Plus Plus Feb 18 '13 at 14:41