Which sorting algorithm works best on mostly sorted data?
closed as too broad by Henk Holterman, hexacyanide, Ilya, toniedzwiedz, Toji Oct 23 '13 at 19:58
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Guessing from lack of context  you are asking about an inmemory sort with no requirement to spill intermediate results to disk? – Jonathan Leffler Oct 20 '08 at 22:03

1According to these animations insertion sorting works best on mostly sorted data. – dopple Apr 3 '12 at 9:53
Based on the highly scientific method of watching animated gifs I would say Insertion and Bubble sorts are good candidates.

16

5Bubble sort is terrible. It is always O(n^2). At least take that out of your answer for it to be right please. – jjnguy Oct 20 '08 at 22:03

75jjnguy, that is just plain wrong. I think you need to retake your algorithms class. On nearly sorted data (it's adaptive case) it is O(N). However, it takes 2 passes through the data and Insertion only takes 1 for nearly sorted data, which makes Insertion the winner. Bubble is still good though – mmcdole Oct 21 '08 at 1:59

3Performance degrades really badly if your data is ever not nearly sorted though. I would still not use it, personally. – Blorgbeard Oct 21 '08 at 4:39

5That link was broken when I tried it. Try this instead: sortingalgorithms.com – Michael La Voie Jul 31 '09 at 20:06
Only a few items => INSERTION SORT
Items are mostly sorted already => INSERTION SORT
Concerned about worstcase scenarios => HEAP SORT
Interested in a good averagecase result => QUICKSORT
Items are drawn from a dense universe => BUCKET SORT
Desire to write as little code as possible => INSERTION SORT

1That is exactly the kind of answer I have been looking for, I read books but I don't seem to find any clear explanation for selection of alogorithms at particular cases, could you please elaborate this or pass a link so that i can dog into it a little more? Thanks – Simran kaur Jun 24 '14 at 3:53

6You should add "Data is already sorted by another criterion => MERGE SORT" – Jim Hunziker Jan 22 '16 at 18:23
timsort
Timsort is "an adaptive, stable, natural mergesort" with "supernatural performance on many
kinds of partially ordered arrays (less than lg(N!) comparisons needed, and
as few as N1)". Python's builtin sort()
has used this algorithm for some time, apparently with good results. It's specifically designed to detect and take advantage of partially sorted subsequences in the input, which often occur in real datasets. It is often the case in the real world that comparisons are much more expensive than swapping items in a list, since one typically just swaps pointers, which very often makes timsort an excellent choice. However, if you know that your comparisons are always very cheap (writing a toy program to sort 32bit integers, for instance), other algorithms exist that are likely to perform better. The easiest way to take advantage of timsort is of course to use Python, but since Python is open source you might also be able to borrow the code. Alternately, the description above contains more than enough detail to write your own implementation.

16

Here's the Java implementation coming in JDK7: cr.openjdk.java.net/~martin/webrevs/openjdk7/timsort/raw_files/… – Tim Aug 9 '09 at 15:06

log(n!) is not fast. wolframalpha.com/input/?i=plot[log(N!),{N,0,1000}] – Behrooz Dec 10 '09 at 10:36

9@J.F. Sebastian: timsort is much faster than
lg(n!)
comparisons on an almostsorted array, all the way down toO(n)
!  @behrooz: No comparison sort can have an average case of better thanO(n log n)
, andlg(n!)
isO(n log n)
. So timsort's worst case is asymptotically no worse than that of any other comparison sort. Furthermore its best case is better than or equal to any other comparison sort. – Artelius Dec 12 '09 at 0:14 
3Timsort is still O(nlogn) in the worst case, but its goodcases are quite pleasing. Here's a comparison, with some graphs: stromberg.dnsalias.org/~strombrg/sortcomparison Note that timsort in Cython wasn't nearly as fast as Python's built in timsort in C. – user1277476 Aug 16 '12 at 21:35
Insertion sort with the following behavior:
 For each element
k
in slots1..n
, first check whetherel[k] >= el[k1]
. If so, go to next element. (Obviously skip the first element.)  If not, use binarysearch in elements
1..k1
to determine the insertion location, then scoot the elements over. (You might do this only ifk>T
whereT
is some threshold value; with smallk
this is overkill.)
This method makes the least number of comparisons.

I think bubble sort might beat this if the number of unsorted elements is very small (like, one or two), but in general this strikes me as probably the best solution. – Sol Oct 20 '08 at 21:55

Because of step 1, for any elements that are already sorted there is exactly one compare and zero datamoves, which is obviously the best you can do. Step 2 is the one you could improve on, but bubble will move the same number of elements and might have more compares, depending on your impl. – Jason Cohen Oct 20 '08 at 22:00

Actually, on further thought I think bubble sort is stronger than I was thinking. It's actually a fairly tricky question. For instance, if you take the case where the list is entirely sorted except the element which should be last is first, bubble sort will vastly outperform what you describe. – Sol Oct 20 '08 at 22:22

I tried to implement this but the binary search is not much of an improvement since you still have to move the entire block to insert the element. So instead of 2xrange you get range + logb(range). – this Jan 20 '14 at 9:41
Try introspective sort. http://en.wikipedia.org/wiki/Introsort
It's quicksort based, but it avoids the worst case behaviour that quicksort has for nearly sorted lists.
The trick is that this sortalgorithm detects the cases where quicksort goes into worstcase mode and switches to heap or merge sort. Nearly sorted partitions are detected by some non naiive partition method and small partitions are handled using insertion sort.
You get the best of all major sorting algorithms for the cost of a more code and complexity. And you can be sure you'll never run into worst case behaviour no matter how your data looks like.
If you're a C++ programmer check your std::sort algorithm. It may already use introspective sort internally.
Splaysort is an obscure sorting method based on splay trees, a type of adaptive binary tree. Splaysort is good not only for partially sorted data, but also partially reversesorted data, or indeed any data that has any kind of preexisting order. It is O(nlogn) in the general case, and O(n) in the case where the data is sorted in some way (forward, reverse, organpipe, etc.).
Its great advantage over insertion sort is that it doesn't revert to O(n^2) behaviour when the data isn't sorted at all, so you don't need to be absolutely sure that the data is partially sorted before using it.
Its disadvantage is the extra space overhead of the splay tree structure it needs, as well as the time required to build and destroy the splay tree. But depending on the size of data and amount of presortedness that you expect, the overhead may be worth it for the increase in speed.
A paper on splaysort was published in SoftwarePractice & Experience.
Dijkstra's smoothsort is a great sort on alreadysorted data. It's a heapsort variant that runs in O(n lg n) worstcase and O(n) bestcase. I wrote an analysis of the algorithm, in case you're curious how it works.
Natural mergesort is another really good one for this  it's a bottomup mergesort variant that works by treating the input as the concatenation of multiple different sorted ranges, then using the merge algorithm to join them together. You repeat this process until all of the input range is sorted. This runs in O(n) time if the data is already sorted and O(n lg n) worstcase. It's very elegant, though in practice it isn't as good as some other adaptive sorts like Timsort or smoothsort.

what’s are the runtime constants of smoothsort compared to other sorting algorithms? (i.e. runtime(smoothsort) / runtime(insertionsort) for the same data) – Arne Babenhauserheide May 2 '17 at 23:03
Insertion sort takes time O(n + the number of inversions).
An inversion is a pair (i, j)
such that i < j && a[i] > a[j]
. That is, an outoforder pair.
One measure of being "almost sorted" is the number of inversionsone could take "almost sorted data" to mean data with few inversions. If one knows the number of inversions to be linear (for instance, you have just appended O(1) elements to a sorted list), insertion sort takes O(n) time.
If elements are already sorted or there are only few elements, it would be a perfect use case for Insertion Sort!
As everyone else said, be careful of naive Quicksort  that can have O(N^2) performance on sorted or nearly sorted data. Nevertheless, with an appropriate algorithm for choice of pivot (either random or medianofthree  see Choosing a Pivot for Quicksort), Quicksort will still work sanely.
In general, the difficulty with choosing algorithms such as insert sort is in deciding when the data is sufficiently out of order that Quicksort really would be quicker.
I'm not going to pretend to have all the answers here, because I think getting at the actual answers may require coding up the algorithms and profiling them against representative data samples. But I've been thinking about this question all evening, and here's what's occurred to me so far, and some guesses about what works best where.
Let N be the number of items total, M be the number outoforder.
Bubble sort will have to make something like 2*M+1 passes through all N items. If M is very small (0, 1, 2?), I think this will be very hard to beat.
If M is small (say less than log N), insertion sort will have great average performance. However, unless there's a trick I'm not seeing, it will have very bad worst case performance. (Right? If the last item in the order comes first, then you have to insert every single item, as far as I can see, which will kill the performance.) I'm guessing there's a more reliable sorting algorithm out there for this case, but I don't know what it is.
If M is bigger (say equal or great than log N), introspective sort is almost certainly best.
Exception to all of that: If you actually know ahead of time which elements are unsorted, then your best bet will be to pull those items out, sort them using introspective sort, and merge the two sorted lists together into one sorted list. If you could quickly figure out which items are out of order, this would be a good general solution as well  but I haven't been able to figure out a simple way to do this.
Further thoughts (overnight): If M+1 < N/M, then you can scan the list looking for a run of N/M in a row which are sorted, and then expand that run in either direction to find the outoforder items. That will take at most 2N comparisons. You can then sort the unsorted items, and do a sorted merge on the two lists. Total comparisons should less than something like 4N+M log2(M), which is going to beat any nonspecialized sorting routine, I think. (Even further thought: this is trickier than I was thinking, but I still think it's reasonably possible.)
Another interpretation of the question is that there may be many of outoforder items, but they are very close to where they should be in the list. (Imagine starting with a sorted list and swapping every other item with the one that comes after it.) In that case I think bubble sort performs very well  I think the number of passes will be proportional to the furthest out of place an item is. Insertion sort will work poorly, because every out of order item will trigger an insertion. I suspect introspective sort or something like that will work well, too.
If you are in need of specific implementation for sorting algorithms, data structures or anything that have a link to the above, could I recommend you the excellent "Data Structures and Algorithms" project on CodePlex?
It will have everything you need without reinventing the wheel.
Just my little grain of salt.
This nice collection of sorting algorithms for this purpose in the answers, seems to lack Gnome Sort, which would also be suitable, and probably requires the least implementation effort.
Insertion sort is best case O(n) on sorted input. And it is very close on mostly sorted input (better than quick sort).
ponder Try Heap. I believe it's the most consistent of the O(n lg n) sorts.

Consistency is not of concern here. Heapsort will give O(n lg n) even on sorted data, and is not really adaptive. Viable options can be: Insertion sort, Timsort and Bubblesort. – Max Feb 13 '13 at 7:39
Bubblesort (or, safer yet, bidirectional bubble sort) is likely ideal for mostly sorted lists, though I bet a tweaked combsort (with a much lower initial gap size) would be a little faster when the list wasn't quite as perfectly sorted. Comb sort degrades to bubblesort.
well it depends on use case. If you know which elements is changed, remove and insert will be the best case as far as I am concerned.

This "as far as I am concerned" test of algorithm efficiency brightened up my day :) Being serious, though, when writing "remove and insert" did you mean Insertion Sort (which was already mentioned in previous answers), or do you offer a new kind of algorithm? If so, please expand your answer. – yoniLavi Apr 21 '15 at 13:05
Bubble sort is definitely the winner The next one on the radar would be insertion sort.

4post your answer with an explanation; – user1542476 Sep 21 '12 at 13:22

1I would suggest you have a look at the available answers before posting to avoid duplicates. – angainor Sep 21 '12 at 21:49
Keep away from QuickSort  its very inefficient for presorted data. Insertion sort handles almost sorted data well by moving as few values as possible.

1 Every industrial implementation of Quicksort has a reasonable pivot selection – Stephan Eggermont Jan 21 '09 at 23:27

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