A couple things:

- Rather than
`Math.round()`

, try `Math.floor()`

; in your
implementation `Math.round()`

gives the first element (at index 0)
and the last element less of a chance than all the other elements
(.5/len vs. 1/len). Note that on the first iteration, you input `arr.length - 1`

for `arr.length`

elements.
- If you're going to have a
`required`

variable, you might as well make it optional, in that it defaults to the length of the array: ```
shuffle = (arr,
required=arr.length)
```

- You return the entire array even though you only shuffled the last elements. Consider instead returning
`arr[arr.length - required ..]`

- What if
`required`

isn't in the range `[0,arr.length]`

?

Putting it all together (and adding some flair):

```
shuffle = (arr, required=arr.length) ->
randInt = (n) -> Math.floor n * Math.random()
required = arr.length if required > arr.length
return arr[randInt(arr.length)] if required <= 1
for i in [arr.length - 1 .. arr.length - required]
index = randInt(i+1)
# Exchange the last unshuffled element with the
# selected element; reduces algorithm to O(n) time
[arr[index], arr[i]] = [arr[i], arr[index]]
# returns only the slice that we shuffled
arr[arr.length - required ..]
# Let's test how evenly distributed it really is
counter = [0,0,0,0,0,0]
permutations = ["1,2,3","1,3,2","2,1,3","2,3,1","3,2,1","3,1,2"]
for i in [1..12000]
x = shuffle([1,2,3])
counter[permutations.indexOf("#{x}")] += 1
alert counter
```