There is nothing about it in wikipedia.
Anyone knows that?
I only want to know the average Big-O Complexity of that algorithm.
The performance of the gnome sort algorithm is at least
Sorry if this is hard to follow.
Here is a simple comparison of bubble and gnome sort of an array of random values, values in reverse order, 3 concatenated arrays of ordered values and ordered values. Gnome sort on average seems to be a bit cheaper on the comparison side of things.
Note that the comparisons/swaps when sorting random values is always a bit different, but close to these results.
N = 100, attempts = 1000
bubble sort: comparisons = 8791794, swaps = 2474088
gnome sort: comparisons = 5042930, swaps = 2474088
bubble sort: comparisons = 9900000, swaps = 4950000
gnome sort: comparisons = 9900000, swaps = 4950000
3 ordered sets:
bubble sort: comparisons = 6435000, swaps = 1584000
gnome sort: comparisons = 3267000, swaps = 1584000
bubble sort: comparisons = 99000, swaps = 0
gnome sort: comparisons = 99000, swaps = 0
... And here is the code used to get these results:
Obviously this is not a full test by far, but it gives an idea.
"Average" cannot really be answered without looking at the input data. If you know what you are sorting you could do some analysis to get a better idea how it would perform in your application.
It seems intuitive to me that if insertion sort has an average-case running time that is O(n^2), and gnome sort is a slightly worse version of insertion sort, then gnome sort's average running time would also be O(n^2) (well, Θ(n^2)).
This pdf has this to say about insertion-sort's average-case running time of Θ(n^2):
The same reasoning would apply to gnome sort. You know gnome sort can't be better because the "gnome" first has to scan backwards (via swapping) to find where the item goes (equivalent to insertion sort's scan forward), and then has to walk back up the list looking at elements that it's already sorted. Any run-time differences between scanning methods I believe are negligible to the complexity bound, but I'll defer to you to prove it.
Rather the contrary, Wikipedia says it's O(n2), and from the description, I can't see how there would be any real doubt about that.