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Why Quick Sort preferred for Arrays and Merge Sort for Linked Lists?

Why is Quick Sort preferred for arrays?

Below are recursive and iterative implementations of Quick Sort and Merge Sort for arrays. Recursive Quick Sort for array. Iterative Quick Sort for arrays. Recursive Merge Sort for arrays Iterative Merge Sort for arrays

  • Quick Sort in its general form is an in-place sort (i.e. it doesn’t require any extra storage) whereas merge sort requires O(N) extra storage, N denoting the array size which may be quite expensive. Allocating and de-allocating the extra space used for merge sort increases the running time of the algorithm.
  • Comparing average complexity we find that both type of sorts have O(NlogN) average complexity but the constants differ. For arrays, merge sort loses due to the use of extra O(N) storage space.
  • Most practical implementations of Quick Sort use randomized version. The randomized version has expected time complexity of O(nLogn). The worst case is possible in randomized version also, but worst case doesn’t occur for a particular pattern (like sorted array) and randomized Quick Sort works well in practice.
  • Quick Sort is also a cache friendly sorting algorithm as it has good locality of reference when used for arrays.
  • Quick Sort is also tail recursive, therefore tail call optimizations is done.

Why is Merge Sort preferred for Linked Lists?

Below are implementations of Quicksort and Mergesort for singly and doubly linked lists. Quick Sort for Doubly Linked List Quick Sort for Singly Linked List Merge Sort for Singly Linked List Merge Sort for Doubly Linked List

  • In case of linked lists the case is different mainly due to difference in memory allocation of arrays and linked lists. Unlike arrays, linked list nodes may not be adjacent in memory.
  • Unlike array, in linked list, we can insert items in the middle in O(1) extra space and O(1) time if we are given reference/pointer to the previous node. Therefore merge operation of merge sort can be implemented without extra space for linked lists.
  • In arrays, we can do random access as elements are continuous in memory. Let us say we have an integer (4-byte) array A and let the address of A[0] be x then to access A[i], we can directly access the memory at (x + i*4). Unlike arrays, we can not do random access in linked list.
  • Quick Sort requires a lot of this kind of access. In linked list to access i’th index, we have to travel each and every node from the head to i’th node as we don’t have continuous block of memory. Therefore, the overhead increases for quick sort. Merge sort accesses data sequentially and the need of random access is low.

Quick Sort is generally preferred for arrays because it has good cache locality and can be easily implemented in-place, which means it doesn’t require any extra memory space beyond the original array. In Quick Sort, we can use the middle element as the pivot and partition the array into two sub-arrays around the pivot. This can be done by swapping elements, and the pivot can be placed in its final position in the sorted array. 

  1. This process of partitioning is done recursively until the entire array is sorted. The cache locality of Quick Sort is beneficial because it minimizes the number of cache misses, which improves performance.
  2. On the other hand, Merge Sort is generally preferred for linked lists because it doesn’t require random access to elements. In Merge Sort, we divide the linked list into two halves recursively until we have individual elements. Then, we merge the individual elements by comparing and linking them in a sorted order. 

The advantage of Merge Sort for linked lists is that it doesn’t require random access to elements, which is not efficient for linked lists since we need to traverse the list linearly. Also, Merge Sort is a stable sort, which means it maintains the relative order of equal elements in the sorted list. This is important for linked lists, where the original order of equal elements may be significant. However, Merge Sort requires extra memory space for the merge step, which can be a disadvantage in some cases.
 

Here are some advantages and disadvantages of Quick Sort and Merge Sort:

Quick Sort Advantages:

Fast and efficient for arrays, especially for large datasets.
In-place sorting which means it doesn’t require any extra memory space beyond the original array.
Good cache locality which minimizes the number of cache misses.
Easy to implement and widely used in practice.

Quick Sort Disadvantages:

  1. Not stable, which means it may change the relative order of equal elements in the sorted array.
  2. Worst-case time complexity is O(n^2), which occurs when the pivot is not chosen properly and the partitioning process doesn’t divide the array evenly.
  3. Not suitable for linked lists, as it requires random access to elements.

Merge Sort Advantages:

  1. Suitable for sorting large datasets and linked lists.
  2. Stable sort which means it maintains the relative order of equal elements in the sorted list.
  3. Guaranteed worst-case time complexity of O(n*log(n)).
  4. Memory efficient because it doesn’t require any extra memory space beyond the original data structure.

Merge Sort Disadvantages:

  1. Requires extra memory space for the merge step, which can be a disadvantage in some cases.
  2. Not as efficient as Quick Sort for small datasets.
  3. Not in-place sorting, which means it requires extra memory space for temporary arrays during the merging process.

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Thanks to Sayan Mukhopadhyay for providing initial draft for above article. Please write comments if you find anything incorrect, or you want to share more information about the topic discussed above.

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