Some explanations are in order!

*What is the id function for? What is the role of? Why should we need it here?*

`id`

is the identity function, `id x = x`

, and is used as the equivalent of zero when building up a chain of functions with function composition, `(.)`

. You can find it defined in the Prelude.

*In the above example, id function is the accumulator in the lambda function?*

The accumulator is a function that is being built up via repeated function application. There's no explicit lambda, since we name the accumulator, `step`

. You can write it with a lambda if you want:

```
foldl f a bs = foldr (\b g x -> g (f x b)) id bs a
```

Or as Graham Hutton would write:

*foldr's prototype is foldr :: (a -> b -> b) -> b -> [a] -> b*

A Haskell programmer would say that the **type** of `foldr`

is `(a -> b -> b) -> b -> [a] -> b`

.

*and the first parameter is a function which need two parameters, but the step function in the myFoldl's implementation uses 3 parameters, I'm complelely confused*

This is confusing and magical! We play a trick and replace the accumulator with a function, which is in turn applied to the initial value to yield a result.

Graham Hutton explains the trick to turn `foldl`

into `foldr`

in the above article. We start by writing down a recursive definition of `foldl`

:

```
foldl :: (a -> b -> a) -> a -> [b] -> a
foldl f v [] = v
foldl f v (x : xs) = foldl f (f v x) xs
```

And then refactor it via the static argument transformation on `f`

:

```
foldl :: (a -> b -> a) -> a -> [b] -> a
foldl f v xs = g xs v
where
g [] v = v
g (x:xs) v = g xs (f v x)
```

Let's now rewrite `g`

so as to float the `v`

inwards:

```
foldl f v xs = g xs v
where
g [] = \v -> v
g (x:xs) = \v -> g xs (f v x)
```

Which is the same as thinking of `g`

as a function of one argument, that returns a function:

```
foldl f v xs = g xs v
where
g [] = id
g (x:xs) = \v -> g xs (f v x)
```

Now we have `g`

, a function that recursively walks a list, apply some function `f`

. The final value is the identity function, and each step results in a function as well.

*But*, we have handy already a very similar recursive function on lists, `foldr`

!

This looks like a very similar recursive scheme to our `g`

function. Now the trick: using all the available magic at hand (aka Bird, Meertens and Malcolm) we apply a special rule, the **universal property of fold**, which is an equivalence between two deﬁnitions for a function `g`

that processes lists, stated as:

So, the universal property of folds states that:

```
g = foldr k v
```

where `g`

must be equivalent to the two equations, for some `k`

and `v`

:

```
g [] = v
g (x:xs) = k x (g xs)
```

From our earlier foldl designs, we know `v == id`

. For the second equation though, we need
to **calculate** the definition of `k`

:

```
g (x:xs) = k x (g xs)
<=> g (x:xs) v = k x (g xs) v -- accumulator of functions
<=> g xs (f v x) = k x (g xs) v -- definition of foldl
<= g' (f v x) = k x g' v -- generalize (g xs) to g'
<=> k = \x g' -> (\a -> g' (f v x)) -- expand k. recursion captured in g'
```

Which, substituting our calculated definitions of `k`

and `v`

yields a
definition of foldl as:

```
foldl :: (a -> b -> a) -> a -> [b] -> a
foldl f v xs =
foldr
(\x g -> (\a -> g (f v x)))
id
xs
v
```

The recursive `g`

is replaced with the foldr combinator, and the accumulator becomes a function built via a chain of compositions of `f`

at each element of the list, in reverse order (so we fold left instead of right).

This is definitely somewhat advanced, so to deeply understand this transformation, the *universal property of folds*, that makes the transformation possible, I recommend Hutton's tutorial, linked below.

*References*