Let's have a look at the complexity of the algorithms:

A) Quicksort: would take worse case **O(n²)** average **O(n log n)**

B) Bubble Sort: would take **O(n²)**

C) Selection Sort: would take **O(n²)**

D) Insertion Sort: would take **O(k* n)** if k is constant = **O(n)**

So **D** has the best performance.
(for each of the k elements: O(log n) to find the position to insert to + O(n) to insert)

But since Quicksort is known to have a small konstant faktor and is in average O(n log n), it is most likely faster for "bigger" k values.

**Extra:**

E) merge sort : would take **2 * O(k log k) + O(n)**

- sort the k elements at the front
**O(k log k)**
- sort the k elements at the end
**O(k log k)**
- merge the 3 lists
**O(n)**

Over all that makes for constant k **O(n)** so based on complexity the same as Insertion Sort.

But if you look at it with k not constant:

*merge sort:* **O(k log k) + O(n)**

*Insertion Sort:* **O(k* n)**

So insertion sort would be faster.

**Arguments against merge sort:**

In general merge sort is **not** inplace (insertion sort is), so you would need extra space or a very clever implemenattion variant that manages to do it inplace without much overhead in complexity.

`k`

being significantly smaller than`n`

? Otherwise you could make`k = n/2`

and the whole array would be unsorted... Also is`K`

and`k`

the same thing?wouldbe the fastest, with O(2klogk + n) (=O(n) for const. k) for merge-sorting the two unsorted segments and then merging the three parts.2more comments