Just for Background I am a Haskell and FP Beginner, self-learning.

I was going through folds on Learn You a Haskell for great good.

In this I came across this function

``````map' :: (a -> b) -> [a] -> [b]
map' f xs = foldr (\x acc -> f x : acc) [] xs
``````

Everything is good but as far as I understood the first parameter of the lambda `x` matches with `[]` and second `acc` matches with `xs`. Right? The confusion starts with the author saying that `Then, we prepend it to the accumulator, which is was [].` How is the second parameter `acc` matching with `[]` which is the first argument? Doesn't make sense.

But his implementation is working while mine (with [] and xs interchanged as parameters) is giving a big error

``````Practice.hs:88:41:
Couldn't match type `a' with `b'
`a' is a rigid type variable bound by
the type signature for map' :: (a -> b) -> [a] -> [b]
at Practice.hs:87:9
`b' is a rigid type variable bound by
the type signature for map' :: (a -> b) -> [a] -> [b]
at Practice.hs:87:9
Expected type: [b]
Actual type: [a]
In the second argument of `foldr', namely `xs'
In the expression: foldr (\ x acc -> f x : acc) xs []
In an equation for map':
map' f xs = foldr (\ x acc -> f x : acc) xs []
``````

What am I missing here? Does `foldr` use `flip` internally? Or did I just understood it all incorrectly?

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Hmm, I'm not sure what you mean by "matches with". Eventually, in your example, the given function gets called with `[]` in it's second argument. – David Young Feb 11 '14 at 3:20
The lambda is not applied to `[]` and `xs`. Instead it's the first argument to `foldr`. The second and third arguments to `foldr` are `[]` and `xs` respectively. – Tom Ellis Feb 11 '14 at 10:06
@DavidYoung What I meant was that it looked to me that the first parameter(to lambda) corresponded to first argument(The `[]`) like in imperative programming. I had forgotten that the lambda was also an argument to `foldr` alongwith the other 2 arguments. And it was upto `foldr` to apply it to its 2 other arguments. Just like @TomEllis said. – Aseem Bansal Feb 11 '14 at 17:13
@TomEllis You should make that comment into an answer. That was the main thing that I had overlooked which led to this question. – Aseem Bansal Feb 11 '14 at 17:15
OK, I made it an answer. – Tom Ellis Feb 11 '14 at 17:26

The lambda is not applied to `[]` and `xs`. Instead it's the first argument to `foldr`. The second and third arguments to foldr are `[]` and `xs` respectively.

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Begin with the type of `foldr`, from Hoogle.

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

From this, it is apparent that the second argument of the lambda must match the second argument to `foldr`, i.e. `acc` matches `[]` and `x` is an element of `xs`, because the first argument of the lambda has type `a`, and the third argument of `foldr` has type `[a]`.

Note that `foldl` and `foldr` have different signatures, and hence the arguments in the lambda are swapped.

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This helped me understand the usefulness of type signature and proved that what was happening was right. But it didn't solve the overall confusion. Still thanks. It helped. – Aseem Bansal Feb 11 '14 at 17:22

Might be simplest to just look at the implementation of `foldr`:

``````foldr            :: (a -> b -> b) -> b -> [a] -> b
foldr k z = go
where
go []     = z
go (y:ys) = y `k` go ys
``````

Then take a simple example like:

``````foldr (+) 0 [0, 1, 2, 4]
``````

And follow exactly what happens as it recurses and generates the "spine".

Image of a `foldr` spine:

I'd recommend tracing what happens using pen and paper.

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Nice graphic, did you make that or find it somewhere? – Eric Feb 11 '14 at 3:50
I was hoping you had a nifty program to do that for you! – Eric Feb 11 '14 at 4:20
@Eric well, there is: youtube.com/watch?v=X4-212uMgy8 (Vacuum), but the OP should learn this by using pen and paper. – bitemyapp Feb 11 '14 at 4:21
Pretty, but this answer omits any reference whatsoever to the context in which the OP is stuck. – enough rep to comment Feb 11 '14 at 13:49

It helps to look at what the "symbolic" form of the fold functions looks like. If we have a list of arbitrary elements `[b1, b2, b3, b4]` and initial element `a` then:

``````foldr f a [b1, b2, b3, b4] = f b1 (f b2 (f b3 (f b4 a)))
``````

Conversely the foldl would look like.

``````foldl f a [b1, b2, b3, b4] = f (f (f (f a b1) b2) b3) b4
``````

This of course ignores the laziness component of the execution, but the general idea still holds.

In your function you fold a function of two arguments which pushes a an element transformed under `f` onto a cons list.

``````map' f xs = foldr (\x acc -> f x : acc) [] xs
``````

Expanding this out where (`xs=[x0,x1,...,xn]`) like above yields:

``````map' f xs = (f x0 : (f x1 : (f x2 : ... (f xn : []))))
``````

Where the ellipsis is just pseudocode for the all the elements in between. We see is just precisely the element wise map. Hope that helps build intuition.

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`foldr g z [a,b,c,...,n] == g a (g b (g c (... (g n z)...)))` seems more visually apparent for me, but YMMV. :) – Will Ness Feb 11 '14 at 9:06
This expansion really helped me understand what is going on. But the following sentence looked like a tongue twister to me. `In your function you fold a function of two arguments which pushes a an element transformed under f onto a cons list.` Just to be clear about this, here`your function` is `map'` and `a function` is the lambda. Correct? – Aseem Bansal Feb 11 '14 at 17:25
@AseemBansal (since Stephen is off-line, I'll answer) yes. The lambda expression defines a function of two arguments. BTW I prefer `r` ("recursive result") instead of `acc` ("accumulator"), which is more suitable for left folds. mnemonics. :) – Will Ness Feb 11 '14 at 17:47

Yet another explanation, using long variable names for effect:

``````map :: (a -> b) -> [a] -> [b]
map f = foldr step []
where
-- If you have an incomplete solution to your problem, and the first
-- element of the input list, what is the last step you need to finish?
step elem incompleteSolution = f elem : incompleteSolution
``````

The neat thing about using functions like `foldr` is that when you write your `step` function, the second argument to `step` will be the correct result for a smaller version of your problem.

One useful way to think of it is to imagine that `foldr` has already solved nearly all of your problem, but it's still missing the last step. For example, if you're trying to solve `map f (x:xs)`, picture that `foldr` has already computed the solution for `map f xs`. Using that incomplete solution, `f` and `x`, what is the final step you need to perform to arrive at the complete solution? Well, as the code snippet illustrates, you apply `f` to `x`, and put that in front of the incomplete solution, and you're done.

The magic of `foldr` is that once you've figured out what to write for `step`, and what to use for the `[]` base case, then you're done. Your `step` function doesn't concern itself with the input list—all it can see is one input list element and an incomplete solution.

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