What is the best way to randomize an array of strings with .NET? My array contains about 500 strings and I'd like to create a new Array
with the same strings but in a random order.
Please include a C# example in your answer.

If you're on .NET 3.5, you can use the following IEnumerable coolness (VB.NET, not C#, but the idea should be clear...):
Edit: OK and here's the corresponding VB.NET code:
Second edit, in response to remarks that System.Random "isn't threadsafe" and "only suitable for toy apps" due to returning a timebased sequence: as used in my example, Random() is perfectly threadsafe, unless you're allowing the routine in which you randomize the array to be reentered, in which case you'll need something like Also, it should be wellunderstood that System.Random as a source of entropy isn't very strong. As noted in the MSDN documentation, you should use something derived from
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The following implementation uses the FisherYates algorithm. It runs in O(n) time and shuffles in place, so is better performing than the 'sort by random' technique, although it is more lines of code. See here for some comparative performance measurements. I have used System.Random, which is fine for noncryptographic purposes.*
Usage:
* For longer arrays, in order to make the (extremely large) number of permutations equally probable it would be necessary to run a pseudorandom number generator (PRNG) through many iterations for each swap to produce enough entropy. For a 500element array only a very small fraction of the possible 500! permutations will be possible to obtain using a PRNG. Nevertheless, the FisherYates algorithm is unbiased and therefore the shuffle will be as good as the RNG you use. 


You're looking for a shuffling algorithm, right? Okay, there are two ways to do this: the cleverbutpeoplealwaysseemtomisunderstanditandgetitwrongsomaybeitsnotthatcleverafterall way, and the dumbasrocksbutwhocaresbecauseitworks way. Dumb way
This algorithm works well, but make sure that your random number generator is unlikely to tag two strings with the same number. Because of the socalled Birthday Paradox, this happens more often than you might expect. Its time complexity is O(n log n). Clever wayI'll describe this as a recursive algorithm:
The iterative equivalent is to walk an iterator through the array, swapping with random elements as you go along, but notice that you cannot swap with an element after the one that the iterator points to. This is a very common mistake, and leads to a biased shuffle. Time complexity is O(n). 





You can also make an extention method out of Matt Howells. Example.
Then you can just use it like:



Just thinking off the top of my head, you could do this:



This post has already been pretty well answered  use a Durstenfeld implementation of the FisherYates shuffle for a fast and unbiased result. There have even been some implementations posted, though I note some are actually incorrect. I wrote a couple of posts a while back about implementing full and partial shuffles using this technique, and (this second link is where I'm hoping to add value) also a followup post about how to check whether your implementation is unbiased, which can be used to check any shuffle algorithm. You can see at the end of the second post the effect of a simple mistake in the random number selection can make. 


Generate an array of random floats or ints of the same length. Sort that array, and do corresponding swaps on your target array. This yields a truly independent sort. 


Randomizing the array is intensive as you have to shift around a bunch of strings. Why not just randomly read from the array? In the worst case you could even create a wrapper class with a getNextString(). If you really do need to create a random array then you could do something like
The *5 is arbitrary. 




Jacco, your solution ising a custom IComparer isn't safe. The Sort routines require the comparer to conform to several requirements in order to function properly. First among them is consistency. If the comparer is called on the same pair of objects, it must always return the same result. (the comparison must also be transitive). Failure to meet these requirements can cause any number of problems in the sorting routine including the possibility of an infinite loop. Regarding the solutions that associate a random numeric value with each entry and then sort by that value, these are lead to an inherent bias in the output because any time two entries are assigned the same numeric value, the randomness of the output will be compromised. (In a "stable" sort routine, whichever is first in the input will be first in the output. Array.Sort doesn't happen to be stable, but there is still a bias based on the partitioning done by the Quicksort algorithm). You need to do some thinking about what level of randomness you require. If you are running a poker site where you need cryptographic levels of randomness to protect against a determined attacker you have very different requirements from someone who just wants to randomize a song playlist. For songlist shuffling, there's no problem using a seeded PRNG (like System.Random). For a poker site, it's not even an option and you need to think about the problem a lot harder than anyone is going to do for you on stackoverflow. (using a cryptographic RNG is only the beginning, you need to ensure that your algorithm doesn't introduce a bias, that you have sufficient sources of entropy, and that you don't expose any internal state that would compromise subsequent randomness). 


The Best Answer:



Ok, this is clearly a bump from my side (apologizes...), but I often use a quite general and cryptographically strong method.
Shuffle() is an extension on any IEnumerable so getting, say, numbers from 0 to 1000 in random order in a list can be done with
This method also wont give any surprises when it comes to sorting, since the sort value is generated and remembered exactly once per element in the sequence. 


HOW can i implement same thing on my button text i.e .text=chr(n+48) to shuffle text on each button Dim n As Integer = 0



You don't need complicated algorithms. Just one simple line:
Note that we need to convert the Also, mind that this is not efficient for very large arrays! Otherwise it's clean & simple. 


Here's a simple way using OLINQ:


