# How can Timsort beat the O(n log n) sorting bound in some cases?

I heard that Timsort breaks the O(n log n) bound for some cases taking advantages of data pattern. How it is possible? Can anyone explain me in detail? If it is true then Timsort will always take less comparison than quick sort because on real life data there is some pattern except data is truly random?

Can we use some kind of tricks to break O(n log n) bound on avg case for comparison sorts?

• en.wikipedia.org/wiki/Timsort – Marc B Feb 16 '14 at 5:58
• The entropy of a random permutation is n log n so no, we can't do better on average – Niklas B. Feb 16 '14 at 6:10
• @Niklas This holds only of you have no additional information about the underlying data which is rarely the case. – pentadecagon Feb 16 '14 at 8:17
• @pentadecagon if we analyze average case, we aggregate the runtime over all possible permutations, so this is exactly the case here – Niklas B. Feb 16 '14 at 13:44
• @pentadecagon: That's not what OP asked. OP asked for avg case and truly random data. – Niklas B. Feb 16 '14 at 14:15

It depends on what you mean by average here. Within the field of CS, average has a very precise meaning: The mean over all possible input sets, assuming each possible input set has the same probability. This definition is convenient, because it's precise and quite easy to handle, but in some cases not the most useful one, because real word data typically is different from random numbers, so an arguably better definition of average would be: The mean over all real-world input sets. But this is not very precise and won't work in a scientific context, so you won't find this in academia. The difference of both definitions is huge: In real world data, you can reasonably assume that there is a fixed percentage `K1` of input sets that can be sorted in linear time by something like timsort. For random data, the percentage `K2(n)` that can be sorted in linear time goes to zero very quickly, like `K2=Exp(-n)`, with `n` being the size of the input set. So the precise, academic answer to you question is No, you cannot improve the average case. The answer from a real-world engineer would be Maybe, it depends, we can try. And they do.