As for the second part of your question:

```
reverse :: [a] -> [a]
reverse = foldl (flip (:)) []
```

First, make sure you understand `foldl`

. It's a powerful high-order function, which means it can be used to implement a lot of other functions (`sum`

,`map`

,`filter`

and of course `reverse`

). You can read about it here.

Now, let's take a look at a simpler version:

```
reverse :: [a] -> [a]
reverse xs = foldl (\ys y -> y:ys) [] xs
```

`\ys y -> y:ys`

is a very simple function: it takes a list (`ys`

) and a value (`y`

) and insert the value before the list (`y:ys`

). So our course of plan is: start with the empty list (`[]`

), insert the first item in `xs`

to its left, take the result and insert the second item to its left and so on.

Let's simulate it with a simple list - `[1,2,3]`

:

We start with the empty list - `[]`

Add the first item (`1`

) to it's left: `[1]`

Add the second item (`2`

) to the left of `[1]`

: `[2,1]`

Add the third item (`3`

) to the left of `[2,1]`

: `[3,2,1]`

And we've successfully reversed `[1,2,3]`

.

Now, `flip`

is a function that takes a function and "flips" it's arguments. so if `subtract a b`

is `a-b`

, then `(flip subtract) a b`

is equal to `subtract b a`

- `b-a`

. So if `(:)`

is a function that takes an item `y`

and a list `ys`

and adds the item to the beginning of the list, then `flip (:)`

is the same function with flipped arguments - it takes a list and an item, much like our function - `\ys y -> y:ys`

. So we can replace the two of them:

```
reverse :: [a] -> [a]
reverse xs = foldl (flip (:)) [] xs
```

And now we write in pointfree style and eliminate `xs`

from both sides of the equation and get the final version:

```
reverse :: [a] -> [a]
reverse = foldl (flip (:)) []
```