I need a quick algorithm to select a random 5 elements from a generic list. For example, I'd like to get a random 5 elements from a List.

Iterate through and for each element make the probability of selection = (number needed)/(number left) So if you had 40 items, the first would have a 5/40 chance of being selected. If it is, the next has a 4/39 chance, otherwise it has a 5/39 chance. By the time you get to the end you will have your 5 items, and often you'll have all of them before that. 


Using linq:



This is actually a harder problem than it sounds like, mainly because many mathematicallycorrect solutions will fail to actually allow you to hit all the possibilities (more on this below). First, here are some easytoimplement, correctifyouhaveatrulyrandomnumber generator: (0) Kyle's answer, which is O(n). (1) Generate a list of n pairs [(0, rand), (1, rand), (2, rand), ...], sort them by the second coordinate, and use the first k (for you, k=5) indices to get your random subset. I think this is easy to implement, although it is O(n log n) time. (2) Init an empty list s = [] that will grow to be the indices of k random elements. Choose a number r in {0, 1, 2, ..., n1} at random, r = rand % n, and add this to s. Next take r = rand % (n1) and stick in s; add to r the # elements less than it in s to avoid collisions. Next take r = rand % (n2), and do the same thing, etc. until you have k distinct elements in s. This has worstcase running time O(k^2). So for k << n, this can be faster. If you keep s sorted and track which contiguous intervals it has, you can implement it in O(k log k), but it's more work. @Kyle  you're right, on second thought I agree with your answer. I hastily read it at first, and mistakenly thought you were indicating to sequentially choose each element with fixed probability k/n, which would have been wrong  but your adaptive approach appears correct to me. Sorry about that. Ok, and now for the kicker: asymptotically (for fixed k, n growing), there are n^k/k! choices of k element subset out of n elements [this is an approximation of (n choose k)]. If n is large, and k is not very small, then these numbers are huge. The best cycle length you can hope for in any standard 32 bit random number generator is 2^32 = 256^4. So if we have a list of 1000 elements, and we want to choose 5 at random, there's no way a standard random number generator will hit all the possibilities. However, as long as you're ok with a choice that works fine for smaller sets, and always "looks" random, then these algorithms should be ok. Addendum: After writing this, I realized that it's tricky to implement idea (2) correctly, so I wanted to clarify this answer. To get O(k log k) time, you need an arraylike structure that supports O(log m) searches and inserts  a balanced binary tree can do this. Using such a structure to build up an array called s, here is some pseudopython:
I suggest running through a few sample cases to see how this efficiently implements the above English explanation. 


I think the selected answer is correct and pretty sweet. I implemented it differently though, as I also wanted the result in random order.






From Dragons in the Algorithm, an interpretation in C#:
This algorithm will select unique indicies of the items list. 


You can use this but the ordering will happen on client side



I just ran into this problem, and some more google searching brought me to the problem of randomly shuffling a list: http://en.wikipedia.org/wiki/FisherYates_shuffle To completely randomly shuffle your list (in place) you do this: To shuffle an array a of n elements (indices 0..n1):
If you only need the first 5 elements, then instead of running i all the way from n1 to 1, you only need to run it to n5 (ie: n5) Lets say you need k items, This becomes:
Each item that is selected is swapped toward the end of the array, so the k elements selected are the last k elements of the array. This takes time O(k), where k is the number of randomly selected elements you need. Further, if you don't want to modify your initial list, you can write down all your swaps in a temporary list, reverse that list, and apply them again, thus performing the inverse set of swaps and returning you your initial list without changing the O(k) running time. Finally, for the real stickler, if (n == k), you should stop at 1, not nk, as the randomly chosen integer will always be 0. 


Was thinking about comment by @JohnShedletsky on the accepted answer regarding (paraphrase):
Basically, you should be able to generate The Method
If you wanted to be even more efficient, you would probably use a The Unit TestAnd to make sure we don't have any collisions, etc.



The simple solution I use (probably not good for large lists): Copy the list into temporary list, then in loop randomly select Item from temp list and put it in selected items list while removing it form temp list (so it can't be reselected). Example:



Selecting N random items from a group shouldn't have anything to do with order! Randomness is about unpredictability and not about shuffling positions in a group. All the answers that deal with some kinda ordering is bound to be less efficient than the ones that do not. Since efficiency is the key here, I will post something that doesn't change the order of items too much. 1) If you need true random values which means there is no restriction on which elements to choose from (ie, once chosen item can be reselected):
If you set the exception flag off, then you can choose random items any number of times.
This should be pretty fast, as it has nothing to check. 2) If you need individual members from the group with no repetition, then I would rely on a dictionary (as many have pointed out already).
The code is a bit lengthier than other dictionary approaches here because I'm not only adding, but also removing from list, so its kinda two loops. You can see here that I have not reordered anything at all when
3) If you need truly distinct random values from your group by taking into account the duplicates in the original group, then you may use the same approach as above, but a
The
Some of the extension methods I have used:
If its all about performance with tens of 1000s of items in the list having to be iterated 10000 times, then you may want to have faster random class than Edit: If you need to rearrange order of returned items as well, then there's nothing that can beat dhakim's FisherYates approach  short, sweet and simple.. 


why not something like this:



It is a lot harder than one would think. See the great Article "Shuffling" from Jeff. I did write a very short article on that subject including C# code: 


Based on Kyle's answer, here's my c# implementation.



This is the best I could come up with on a first cut:
Using a list of randoms within a range of 1  total list count and then simply pulling those items in the list seemed to be the best way, but using the Dictionary to ensure uniqueness is something I'm still mulling over. Also note I used a string list, replace as needed. 


I recently did this on my project using an idea similar to Tyler's point 1.
Usage:



Here's my approach (full text here http://krkadev.blogspot.com/2010/08/randomnumberswithoutrepetition.html ). It should run in O(K) instead of O(N), where K is the number of wanted elements and N is the size of the list to choose from:



This isn't as elegant or efficient as the accepted solution, but it's quick to write up. First, permute the array randomly, then select the first K elements. In python,



This method may be equivalent to Kyle's. Say your list is of size n and you want k elements.
Works like a charm :) Alex Gilbert 


I combined several of the above answers to create a Lazilyevaluated extension method. My testing showed that Kyle's approach (Order(N)) is many times slower than drzaus' use of a set to propose the random indices to choose (Order(K)). The former performs many more calls to the random number generator, plus iterates more times over the items. The goals of my implementation were: 1) Do not realize the full list if given an IEnumerable that is not an IList. If I am given a sequence of a zillion items, I do not want to run out of memory. Use Kyle's approach for an online solution. 2) If I can tell that it is an IList, use drzaus' approach, with a twist. If K is more than half of N, I risk thrashing as I choose many random indices again and again and have to skip them. Thus I compose a list of the indices to NOT keep. 3) I guarantee that the items will be returned in the same order that they were encountered. Kyle's algorithm required no alteration. drzaus' algorithm required that I not emit items in the order that the random indices are chosen. I gather all the indices into a SortedSet, then emit items in sorted index order. 4) If K is large compared to N and I invert the sense of the set, then I enumerate all items and test if the index is not in the set. This means that I lose the Order(K) run time, but since K is close to N in these cases, I do not lose much. Here is the code:
I use a specialized random number generator, but you can just use C#'s Random if you want. (FastRandom was written by Colin Green and is part of SharpNEAT. It has a period of 2^1281 which is better than many RNGs.) Here are the unit tests:


