Is there a sorting algorithm that can sort n distinct integers from 3 to 4n in O(n) time?
I have been trying this problem for an hour now and I have no idea what to do.
Any tips?
First of all, comparison based sorting algorithms cannot do better than a worst case time complexity of O(nlogn), so don't use any of them. As it is homework, look at: Hope this helps. 


Yes, as with most optimisations, you can trade space for time, as per the following pseudocode:
Here's how it works:
Of course, it requires O(n) space whereas some other sorts may be able to run inplace but, since you didn't place a restriction on that (and your question has explicitly limited the range to the point where it's workable^{(a)}), I'm assuming that's okay. ^{(a)} It would most likely not be workable without a restricted range, simply because the space required may be massive. 


Thread sort! Send each item of the array in a separate thread, tell the thread to sleep for a number of milliseconds equal to the square of the integer value, as the threads wake up have them add their item to an array. 


I created an algorithm I called the "shift sort" which operates in O(n) given a few constraints. It can be found at http://sumofchoices.com/projects/sort.php If you want a more traditional algorithm, use the bucket, radix, or counting algorithm. 


Since your range is So the first you do is zero the auxiliary array then make one pass over the original array, storing each number in Next consider two numbers 1) 2) Therefore, traversing the auxiliary array in rowmajor order and taking nonzero values will give you a sorted sequence.
EDIT: But I like paxdiablo's solution more 


But is it possible to given an array 


http://www.cs.rutgers.edu/~muthu/soradix.pdf Basically, the procedure is bucket sorting where the auxiliary data of the list associated to each bucket (i.e. the links among elements in the list) is implemented by pseudo pointers in P instead of storing it explicitly in the bit memory (which lacks of wordlevel parallelism and is inefficient in access). It is worth noting that the buckets’ lists implemented with pseudo pointers are spread over an area that is larger than the one we would obtain with explicit pointers (that is because each pseudo pointer has a key of log n bits while an explicit pointer would have only log d bits). 


m
is the number of possible values, you can doO(n+m)
withO(m)
memory overhead (i.e. bucket/radix sort) – Mark Peters Nov 8 '11 at 4:36