Starting from this quote of Skeet:

It's not a way of shuffling that I like, mostly on the grounds that it's O(n log n) for no good reason when it's easy to implement an O(n) shuffle. The code in the question "works" by basically giving a random (**hopefully unique!**) number to each element, then ordering the elements according to that number.

I'll go on a little explaining the reason for the **hopefully unique!**

Now, from the Enumerable.OrderBy:

This method performs a stable sort; that is, if the keys of two elements are equal, the order of the elements is preserved

This is very important! What happens if two elements "receive" the same random number? It happens that they remain in the same order they are in the array. Now, what is the possibility for this to happen? It is difficult to calculate exactly, but there is the Birthday Problem that is exactly this problem.

Now, is it real? Is it true?

As always, when in doubt, write some lines of program: http://pastebin.com/5CDnUxPG

This little block of code shuffles an array of 3 elements a certain number of times using the Fisher-Yates algorithm done backward, the Fisher-Yates algorithm done forward (in the wiki page there are two pseudo-code algorithms... They produce equivalent results, but one is done from first to last element, while the other is done from last to first element), the naive wrong algorithm of http://blog.codinghorror.com/the-danger-of-naivete/ and using the `.OrderBy(x => r.Next())`

and the `.OrderBy(x => r.Next(someValue))`

.

Now, Random.Next is

A 32-bit signed integer that is greater than or equal to 0 and less than MaxValue.

so it's equivalent to

```
OrderBy(x => r.Next(int.MaxValue))
```

To test if this problem exists, we could enlarge the array (something very slow) or simply reduce the maximum value of the random number generator (`int.MaxValue`

isn't a "special" number... It is simply a very big number). In the end, if the algorithm isn't biased by the stableness of the `OrderBy`

, then any range of values should give the same result.

The program then tests some values, in the range 1...4096. Looking at the result, it's quite clear that for low values (< 128), the algorithm is very biased (4-8%). With 3 values you need at least `r.Next(1024)`

. If you make the array bigger (4 or 5), then even `r.Next(1024)`

isn't enough. I'm not an expert in shuffling and in math, but I think that for each extra bit of length of the array, you need 2 extra bits of maximum value (because the birthday paradox is connected to the sqrt(numvalues)), so that if the maximum value is 2^31, I'll say that you should be able to sort arrays up to 2^12/2^13 bits (4096-8192 elements)