Type signatures would really go a long way here. Let's start with the simplest one, `inc`

:

```
inc :: Num a => a -> a
inc x = x + 1
```

This is easy to derive because `+ 1`

has type `Num a => a -> a`

, and you can check this in GHCi with `:type (+1)`

. Next, let's look at the function `twice`

. It's obvious that the `n`

passed in has to be a function, since it's applied to both `a`

and `n a`

. Because it's applied to `n a`

and `a`

, both of these expressions must have the same type, and `n`

must have only one parameter, so we can say that `twice`

has the type

```
twice :: (a -> a) -> a -> a
twice n a = n (n a)
```

Now we can figure out `n`

. It takes a tuple `(h, s, x)`

as an argument and is called recursively. `h`

has to be a function of two arguments, since it's applied to `s`

and `x`

, and `s`

is unknown without more context. `x`

has to be both a `Num a => a`

and an `Ord a => a`

due to its use with `< 1`

and `-1`

, so we can write the signature as

```
n :: (Num a, Ord a) => (b -> a -> c, b, a) -> c
n (h, s, x) = if x < 1 then h s x else n (h, h s, x - 1)
```

Notice that I removed some unnecessary parens here. Finally, we can figure out the type of `cost`

, which is simply `n`

's return type:

```
cost :: (Num a, Ord a) => a
cost = n (twice, inc, 3)
```

But what would this return? For starters, it's re-write `n`

's definition but with `twice`

, `inc`

, and `3`

substituted in:

```
if 3 < 1
then twice inc 3
else n (twice, twice inc, 3 - 1)
```

Obviously `3 < 1`

is false, so let's reduce `n (twice, twice inc, 3 - 1)`

:

```
if 2 < 1
then twice (twice inc) 2
else n (twice, twice (twice inc), 2 - 1)
```

Same story here, `2 < 1`

is false, so let's continue to reduce:

```
if 1 < 1
then twice (twice (twice inc)) 1
else n (twice, twice (twice (twice inc)), 1 - 1)
```

Nothing new on this step, one more try:

```
if 0 < 1
then twice (twice (twice (twice inc))) 0
else n (twice, twice (twice (twice (twice inc))), 0 - 1)
```

Here we have `0 < 1`

, so we then choose the branch of `twice (twice (twice (twice inc))) 2`

. To solve this, just plug in `inc`

and `0`

into the definition of `twice`

:

```
twice (twice (twice (twice inc))) 0
= twice (twice (twice (inc . inc))) 0
= twice (twice (inc . inc . inc . inc)) 0
= twice (inc . inc . inc . inc . inc . inc . inc . inc) 0
= (inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc) 0
= 16
```

And we now can't reduce this expression any more! So the entire chain of reductions is

```
cost = n (twice, inc, 3)
= if 3 < 1
then twice inc 3
else n (twice, twice inc, 3 - 1)
= n (twice, twice inc, 2)
= if 2 < 1
then twice (twice inc) 2
else n (twice, twice (twice inc), 2 - 1)
= n (twice, twice (twice inc), 1)
= if 1 < 1
then twice (twice (twice inc)) 1
else n (twice, twice (twice (twice inc)), 1 - 1)
= n (twice, twice (twice (twice inc)), 0)
= if 0 < 1
then twice (twice (twice (twice inc))) 0
else n (twice, twice (twice (twice (twice inc))), 0 - 1)
= twice (twice (twice (twice inc))) 0
= inc (inc 0)
= inc (0 + 1)
= (inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc) 0
= 16
```

(To keep things readable I've used `twice f = f . f`

instead of `twice f x = f (f x)`

, but these definitions are equivalent)