I'd say, that foxcub's answer is wrong. To prove that I will introduce a helpful definition for a perfectly shuffled list (call it array or sequence or whatever you want).

*Definition: Assume we have a List *`L`

containing the elements `a1, a2 ... an`

and the indexes `1, 2, 3..... n`

. If we expose the `L`

to a shuffle operation (to which internals we have no access) `L`

is perfectly shuffled if and only if by knowing indexes of some k (`k< n`

) elements we can't deduce the indexes of remaining `n-k`

elements. That is the remaining `n-k`

elements are equally probable to be revealed at any of the remaining `n-k`

indexes.

Example: if we have a four element list `[a, b, c, d]`

and after shuffling it, we know that its first element is `a`

(`[a, .., .., ..]`

) than the probability for any of the elements `b, c, d`

to occur in, let's say, the third cell equals `1/3`

.

Now, the smallest list for which the algorithm does not fulfil the definition has three elements. But the algorithm converts it to a 4-element list anyway, so we will try to show its incorrectness for a 4-element list.

Consider an input `L = [a, b, c, d]`

Following the first run of the algorithm the L will be divided into `l1 = [a, c]`

and `l2 = [b, d]`

. After shuffling these two sublists (but before merging into the four-element result) we can get four equally probable 2-elements lists:

```
l1shuffled = [a , c] l2shuffled = [b , d]
l1shuffled = [a , c] l2shuffled = [d , b]
l1shuffled = [c , a] l2shuffled = [b , d]
l1shuffled = [c , a] l2shuffled = [d , b]
```

Now try to answer two questions.

**1. What is the probability that after merging into the final result **`a`

will be the first element of the list.

Simply enough, we can see that only two of the four pairs above (again, equally probable) can give such a result (`p1 = 1/2`

). For each of these pairs `heads`

must be drawed during first flipping in the merge routine (`p2 = 1/2`

). Thus the probability for having `a`

as the first element of the `Lshuffled`

is `p = p1*p2 = 1/4`

, which is correct.

**2. Knowing that **`a`

is on the first position of the `Lshuffled`

, what is the probability of having `c`

(we could as well choose `b`

or `d`

without loss of generality) on the second position of the `Lshuffled`

Now, according to the above definition of a perfectly shuffled list, the answer should be `1/3`

, since there are three numbers to put in the three remaining cells in the list

Let's see if the algorithm assures that.

After choosing `1`

as the first element of the `Lshuffled`

we would now have either:

`l1shuffled = [c] l2shuffled = [b, d]`

or:

`l1shuffled = [c] l2shuffled = [d, b]`

The probability of choosing `3`

in both cases is equal to the probability of flipping `heads`

(`p3 = 1/2`

), thus the probability of having `3`

as the second element of `Lshuffled`

, when knowing that the first element element of `Lshuffled`

is `1`

equals `1/2`

. `1/2 != 1/3`

which ends the proof of **the incorrectness of the algorithm.**

The interesting part is that the algorithm fullfils the necessary (but not sufficient) condition for a perfect shuffle, namely:

*Given a list of *`n`

elements, for every index `k`

(`<n`

), for every element `ak`

: after shuffling the list `m`

times, if we have counted the times when `ak`

occured on the `k`

index, this count will tend to `m/n`

by probability, with `m`

tending to infinity.

store a number for each node all at the same timein O(log n) extra storage space_, but he needs not store the numbers at the same time. – TBohne May 2 '14 at 18:01