# Is there an O(n) integer sorting algorithm?

The last week I stumbled over this paper where the authors mention on the second page:

Note that this yields a linear running time for integer edge weights.

The same on the third page:

This yields a linear running time for integer edge weights and O(m log n) for comparison-based sorting.

And on the 8th page:

In particular, using fast integer sorting would probably accelerate GPA considerably.

Does this mean that there is a O(n) sorting algorithm under special circumstances for integer values? Or is this a specialty of graph theory?

PS:
It could be that reference  could be helpful because on the first page they say:

Further improvements have been achieved for [..] graph classes such as integer edge weights , [...]

• To see why special circumstances can help, consider the case of sorting a million integers between 0 and 9. You can simply count how many of each digit there are, and afterward simply put the digits in the right order based on their counts. This is the basis of counting sort. – polygenelubricants Feb 28 '10 at 19:57
• thanks to all of you! I learned a lot. See here for some Java benchmarks I made up on this question: karussell.wordpress.com/2010/03/01/… – Karussell Mar 2 '10 at 8:33
• I made one of these as a joke (tinylittlelife.org/?p=261). To spoil the punchline, it accomplishes this by treating the input as an array of bits instead of bytes and "sorting" it into the form 000000111111. – Ian Jun 14 '17 at 15:15

Yes, radix sort and counting sort are O(N). They are NOT comparison-based sorts, which have been proven to have Ω(N log N) lower bound.

To be precise, radix sort is O(kN), where k is the number of digits in the values to be sorted. Counting sort is O(N + k), where k is the range of the numbers to be sorted.

There are specific applications where k is small enough that both radix sort and counting sort exhibit linear-time performance in practice.

• Lower bounds are always expressed as Ω. Saying an O lower bound has no semantic meaning. Otherwise +1. – Billy ONeal Feb 28 '10 at 19:33
• They're only O(n) if the biggest possible value of the integers is less than or equal to n - otherwise they're O(max_int), no? – sepp2k Feb 28 '10 at 19:38
• @sepp2k I added the k in there for clarification. – polygenelubricants Feb 28 '10 at 19:45
• That's just semantics. Digits doesn't have to be base 10. I can set it to be base 256, and that's essentially the same as your argument. – polygenelubricants Feb 28 '10 at 20:09
• @David "Radix sort's efficiency is thus O(kn) for n keys of k digits. Since k is normally on the order of log n, it might appear that radix sort does not really beat the O(n log n) time of the best comparison sorts. However, the O(n log n) time of the best comparison sorts counts the number of comparisons, and the fastest time possible for a comparison is k. If we count the number of primitive operations, then merge sort (or other fast comparison sorts) execute in O(kn log n) time." – polygenelubricants Mar 1 '10 at 16:38

Comparison sorts must be at least Ω(n log n) on average.

However, counting sort and radix sort scale linearly with input size – because they are not comparison sorts, they exploit the fixed structure of the inputs.

Counting sort: http://en.wikipedia.org/wiki/Counting_sort if your integers are fairly small. Radix sort if you have bigger numbers (this is basically a generalization of counting sort, or an optimization for bigger numbers if you will): http://en.wikipedia.org/wiki/Radix_sort

There is also bucket sort: http://en.wikipedia.org/wiki/Bucket_sort

While not very practical (mainly due to the large memory overhead), I thought I would mention Abacus (Bead) Sort as another interesting linear time sorting algorithm.

• The big-O may be attractive, but when implemented in software, this sort performs about 10x slower than quicksort. – AShelly Mar 22 '12 at 20:50

These hardware-based sorting algorithms:

Laser Domino Sorting Algorithm - a thought experiment by me based on Counting Sort with an intention to achieve O(n) time complexity over Counting Sort's O(n + k).

Adding a little more detail - Practically the best sorting algorithm till date is not O(n) , but 0(n\sqrt {\log \log n}) .