It's a recursive function over two variables. You can break it apart line-by-line to understand it:

```
sponge :: Int -> [a] -> [a]
```

Two arguments, one an `Int`

, one a list of some elements.

```
sponge 0 xs = xs
```

The base case. If the `Int`

argument is zero, just return the list argument unmodified.

```
sponge n [] = []
```

Another base case, if the list is empty, immediately return the empty list.

```
sponge n (x:xs) = sponge (n-1) xs
```

Finally, the inductive step. If the list is non-empty (i.e. made up of at least one element and a tail, denoted by `x:xs`

), then the result is `sponge`

called on `n-1`

and the tail of the list.

So what will this function do? It will return the tail of the list after dropping `n`

elements. It is the same as the `drop`

function:

```
> drop 10 [1..20]
[11,12,13,14,15,16,17,18,19,20]
```

And

```
> sponge 10 [1..20]
[11,12,13,14,15,16,17,18,19,20]
```

In fact, we can ask QuickCheck to confirm:

```
> quickCheck $ \n xs -> sponge n xs == drop n xs
*** Failed! Falsifiable (after 7 tests and 5 shrinks):
-1
[()]
```

Ah! They're different. When `n`

is negative! So we can modify the property relating the two functions:

```
> quickCheck $ \n xs -> n >= 0 ==> sponge n xs == drop n xs
+++ OK, passed 100 tests.
```

So your function behaves like drop, for cases when `n`

is positive.

Here's a trace of the intermediate values of `n`

and `xs`

, obtained via the hood debugger: