Just a simple algorithm to sort small integers, but it must be O(n).
closed as not a real question by markus, BalusC, Sean Vieira, Bo Persson, Dori Oct 6 '11 at 22:25It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center. If this question can be reworded to fit the rules in the help center, please edit the question. 


A radix sort is one approach that's 


Of course the fine print in the definition of O(n) there gets you. The radix sort, eg, is really n*log(n) when you figure that you must create a deeper tree as you accommodate more values  they just manage to define it as O(n) by the trick of capping the number of values to be sorted. There's no way to really beat n*log(n) in the general sense. Eg, for 8bit values I can easily achieve O(n) by simply having a 256entry array. But if I go to, say, even 32bit values then I must have an array with 4G entries, and the address decoder for the memory chip for that array will have grown with log(n) of the size of the memory chip. Yes, I can say that the version with 4G entries is O(n), but at a electronic level the addressing is log(n) slower and more complex. Additionally, the buses inside the chip must drive more current and it will take longer for a memory cell, once "read", to dump its contents onto the bus. And all those effects are log(n). 


See this page for some ways of achieving this. 


Simply put :
A great resource are these Wikipedia tables. Have a look at the second one. 


To the best of my knowledge, comparison based sorting algorithms share a lower bound of O(nlogn). To achieve O(n), we probably can't use any comparison based algorithms. Also, the input must bear additional properties. In your example, small integers, I guess, means that the integers fall within a specified range. If that were the case, you could try bucket/radix sort algorithm, which does not require any comparisons. For a simple example, suppose you have n integers to be sorted, all of which belong to the interval [1, 1000]. You just make 1000 buckets, and go over the n integers, if the integer is equal to 500, it goes to bucket 500, etc. Finally you concatenate all the buckets to obtain the sorted list. This algorithm takes O(n). 


The optimum for comparison based sort is O(n*log(n)), the proof is not very difficult. BUT you may use counting sort, which is enumeration based or very similar bucket sort... You may also use radix sort, but it is not sort itself. Radix sort only iteratively calls some other stable sort... 

