# How can a sorting algorithm have a space complexity of O(1)?

I'm learning about different sorting algorithms and their time/space complexities and saw that algorithms such as bubble sort and insertion sort have a space complexity of O(1).

This struck me as weird, because surely the lowest space complexity possible would be O(n) (as in, the memory required to store the data set and nothing more)?

• The sort can be in-place, only using a fixed amount of extra space. An example is swap-sort. May 10, 2017 at 11:38
• The space complexity is only concerned with extra space, only required for the sorting, not the storage of the collection itself. In-place sorts usually only need space for one element during a swap. May 10, 2017 at 11:39
• The space complexity measured is the amount of auxiliary space needed for the operation. Input and output are not counted, because that wouldn't add much information and complicate discussion. May 10, 2017 at 11:39
• Ah, that's where I was getting confused. So bubble sort has a space complexity of O(1) because it compares a fixed size each time.
– user5303592
May 10, 2017 at 11:40
• I saw a joke sort algorithm for this that’s technically valid. For any element, X, in the set, sleep(X);print(X). Multithread and start for all elements at the same time. This is a pretty good O(1) sort algorithm, incredibly slow though may it be Mar 16, 2019 at 19:22

The space complexity is actually the additional space complexity used by your algorithm, i.e. the extra space that you need, apart from the initial space occupied by the data. Bubble-sort and insertion sort use only a constant additional space, apart from the original data, so they are O(1) in space complexity.

A sorting algorithm has space complexity O(1) by allocating a constant amount of space, such as a few variables for iteration and such, that are not proportional to the size of the input.

An example of sorting algorithm that is not O(1) in terms of space would be most implementations of mergesort, which allocate an auxiliary array, making it O(n). Quicksort might look like O(1) in theory, but the call stack counts like space and therefore it is said to be O(log n).

Examples of sorting algorithms with O(1) space complexity include: selection sort, insertion sort, shell sort and heapsort.

• Not to forget bubblesort. May 10, 2017 at 12:17
• Bubble sort has quadratic time complexity and other than in academic settings it is never used. May 10, 2017 at 12:18
• You are right, but this was not my point. It has a constant space complexity, a polynomial running time and is the first algorithm one would naively come up with. May 10, 2017 at 12:20
• Good to bring it up as a well-known algorithm that many readers of this site will have heard about, but as far as it being the first algorithm one would naively come up with, I'm not so sure. Maybe some people might. That would be an interesting study, come to think of it.... :) Sep 23, 2017 at 19:39
• I find selection sort and insertion sort better at introducing the concept of sorting. But it is a matter of preference. Apr 18, 2018 at 6:34

Bottom-up merge sort can be written in a such a way that it uses only constant extra space. This is an example of an asymptotically optimal sort (`O(n*log(n))`) while only using `O(1)` space.

Edit: This answer was kind of careless. Bottom up merge sort only uses `O(1)` space on a linked list. For a sort that uses `O(1)` space on an array, heapsort is your best bet. This is done by turning the array into a max heap in place, and then `delete-max` is called repeatedly with the value being stores at the back of the array. When the heap is empty, the array is sorted.

• While this is true, it doesn’t directly answer the question posted here. Perhaps this should be a comment? Sep 12, 2020 at 2:14
• I think you're right actually, might've jumped the gun on this one. I was just surprised no one had mentioned one of the few optimal O(1) sorts Sep 13, 2020 at 4:17