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# Haskell - Foldr and Foldl further explanation and example

I've looked at different folds and folding in general as well as a few others and they explain it fairly well.

I'm still having trouble on how a lambda would work in this case.

``````foldr (\y ys -> ys ++ [y]) [] [1,2,3]
``````

Could someone go through that step by step and try to explain that to me.

And also how would `foldl` work as well.

-

## 4 Answers

Using

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

And

``````k y ys = ys ++ [y]
``````

Let's unpack:

``````foldr k [] [1,2,3]
= k 1 (foldr k [] [2,3]
= k 1 (k 2 (foldr k [] [3]))
= k 1 (k 2 (k 3 (foldr k [] [])))
= (k 2 (k 3 (foldr k [] []))) ++ [1]
= ((k 3 (foldr k [] [])) ++ [2]) ++ [1]
= (((foldr k [] []) ++ [3]) ++ [2]) ++ [1]
= ((([]) ++ [3]) ++ [2]) ++ [1]
= (([3]) ++ [2]) ++ [1]
= ([3,2]) ++ [1]
= [3,2,1]
``````
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foldr is an easy thing:

``````foldr :: (a->b->b) -> b -> [a] -> b
``````

It takes a function which is somehow similar to (:),

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

and a value which is similar to the empty list [],

``````[] :: [a]
``````

and replaces each : and [] in some list.

It looks like this:

``````foldr f e (1:2:3:[]) = 1 `f` (2 `f` (3 `f` e))
``````

You can imagine foldr as some state-machine-evaluator, too:

f is the transition,

``````f :: input -> state -> state
``````

and e is the start state.

``````e :: state
``````

foldr (foldRIGHT) runs the state-machine with the transition f and the start state e over the list of inputs, starting at the right end. Imagine f in infix notation as the pacman coming from-RIGHT.

foldl (foldLEFT) does the same from-LEFT, but the transition function, written in infix notation, takes its input argument from right. So the machine consumes the list starting at the left end. Pacman consumes the list from-LEFT with an open mouth to the right, because of the mouth (b->a->b) instead of (a->b->b).

``````foldl :: (b->a->b) -> b -> [a] -> b
``````

To make this clear, imagine the function minus as transition:

``````foldl (-) 100 [1]         = 99 = ((100)-1)
foldl (-) 100 [1,2]       = 97 = (( 99)-2) = (((100)-1)-2)
foldl (-) 100 [1,2,3]     = 94 = (( 97)-3)
foldl (-) 100 [1,2,3,4]   = 90 = (( 94)-4)
foldl (-) 100 [1,2,3,4,5] = 85 = (( 90)-5)

foldr (-) 100 [1]         = -99 = (1-(100))
foldr (-) 100 [2,1]       = 101 = (2-(-99)) = (2-(1-(100)))
foldr (-) 100 [3,2,1]     = -98 = (3-(101))
foldr (-) 100 [4,3,2,1]   = 102 = (4-(-98))
foldr (-) 100 [5,4,3,2,1] = -97 = (5-(102))
``````

You probably want to use foldr in situations, where the list can be infinite, and where the evaluation should be lazy:

``````foldr (either (\l (ls,rs)->(l:ls,rs))
(\r (ls,rs)->(ls,r:rs))
) ([],[]) :: [Either l r]->([l],[r])
``````

And you probably want to use the strict version of foldl, which is foldl', when you consume the whole list to produce its output. It might perform better and might prevent you from having stack-overflow or out-of-memory exceptions (depending on compiler) due to extreme long lists in combination with lazy evaluation:

``````foldl' (+) 0 [1..100000000] = 5000000050000000
foldl  (+) 0 [1..100000000] = error "stack overflow or out of memory" -- dont try in ghci
foldr  (+) 0 [1..100000000] = error "stack overflow or out of memory" -- dont try in ghci
``````

The first one –step by step– creates one entry of the list, evaluates it, and consumes it.

The second one creates a very long formula first, wasting memory with ((...((0+1)+2)+3)+...), and evaluates all of it afterwards.

The third one like the second, but with the other formula.

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+1 for explaining the semantics and giving an analogy. The other answers so far give only formal reduction, which is important, but for understanding at a conceptual level is even more important IMHO. – thSoft Feb 11 '13 at 13:20

The definition of `foldr` is:

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

So here's a step by step reduction of your example:

``````  foldr (\y ys -> ys ++ [y]) [] [1,2,3]
= (\y ys -> ys ++ [y]) 1 (foldr (\y ys -> ys ++ [y]) [] [2,3])
= (foldr (\y ys -> ys ++ [y]) [] [2,3]) ++ [1]
= (\y ys -> ys ++ [y]) 2 (foldr (\y ys -> ys ++ [y]) [] [3]) ++ [1]
= (foldr (\y ys -> ys ++ [y]) [] [3]) ++ [2] ++ [1]
= (\y ys -> ys ++ [y]) 3 (foldr (\y ys -> ys ++ [y]) [] []) ++ [2] ++ [1]
= (foldr (\y ys -> ys ++ [y]) [] []) ++ [3] ++ [2] ++ [1]
= [] ++ [3] ++ [2] ++ [1]
= [3,2,1]
``````
-

Infix notation will probably be clearer here.

Let's start with the definition:

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

For the sake of brevity, let's write `g` instead of `(\y ys -> ys ++ [y])`. The following lines are equivalent:

``````foldr g [] [1,2,3]
1 `g` (foldr g [] [2,3])
1 `g` (2 `g` (foldr g [] [3]))
1 `g` (2 `g` (3 `g` (foldr g [] [])))
1 `g` (2 `g` (3 `g` []))
(2 `g` (3 `g` [])) ++ [1]
(3 `g` []) ++ [2] ++ [1]
[3] ++ [2] ++ [1]
[3,2,1]
``````
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