# Shell sort running time on pre-sorted list (best case)

I'm confused on the running time of shell sort if the list is pre-sorted (best case). Is it O(n) or O(n log n)?

``````    for(k=n/2; k>0; k/=2)
for(i=k; i<n; i++)
for(j=i;j>k; j-=k)
if(a[j-k]>a[j]) swap
else break;
``````

Shell sort is based on insertion sort, and insertion sort has O(n) running time for pre-sorted list, however, by introducing gaps (outermost loop), I don't know if it makes the running time of shell sort O(n log n) for pre-sorted list.

Thank's for the help

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In the best case when the data is already ordered, the innermost loop will never swap. It will always immediately break, since the left value is known to be smaller than the right value:

``````for(k=n/2; k>0; k/=2)
for(i=k; i<n; i++)
for(j=i;j>k; j-=k)
if(false) swap
else break;
``````

So, the algorithm collapses to this:

``````for(k=n/2; k>0; k/=2)
for(i=k; i<n; i++)
no_op()
``````

The best case then becomes:

``````O((n - n/2) + (n - n/4) + (n - n/8) + ... + (n - 1))
= O(nlog(n) - n)
= O(nlog(n))
``````

That said, according to Wikipedia, some other variants of Shell Sort do have an O(N) best case.

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I think (at least as normally implemented) it's approximately O(n log n), though the exact number is going to depend on the progression you use.

For example, in the first iteration you invoke insertion sort, let's say, five times, each sorting every fifth element. Since each of these is linear on the number of elements sorted, you get linear complexity overall.

In the next iteration you invoke insertion sort, say, twice, sorting every other element. Again, linear overall.

In the third, you do insertion sort on every element, again linear.

In short, you have a linear algorithm invoked a (roughly) logarithmic number of times, so it should be about O(n log n) overall. That assumes some sort of geometric progression in the step sizes you use, which is common but (perhaps) not absolutely required.

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