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.

`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