# Optimal Quicksort for Single Linked List

I am working on implementing a quicksort function to sort singly linked lists. What algorithm would I have to use to accomplish this ? For a linked list it would take worst case O(N) for each comparison, instead of the usual O(1) for arrays. So what would the worst case complexity be ?

To sum up, what modifications do I need to make to the quicksort algorithm to have an optimal sorting algorithm and what would be the worst case complexity of the algorithm ?

Thanks!

I have an implementation below:

``````public static SingleLinkedList quickSort(SingleLinkedList list, SLNode first, SLNode last)
{
if (first != null && last != null)
{
SLNode p = partition(list, first, last) ;
quickSort(list,first,p) ;
quickSort(list,p.succ, last) ;
}
return list ;
}

public static SLLNode partition(SinlgleLinkedList list, SLNode first, SLNode last)
{

SLNode p = first ;
SLNode ptr = p.succ ;

while (ptr!=null)
{
if (ptr.data.compareToIgnoreCase(p.data)<0)
{
String pivot = p.data ;
p.data =  ptr.data ;
ptr.data = p.succ.data ;
p.succ.data = pivot ;
p = p.succ ;
}
ptr = ptr.succ ;
}
return p ;
}
``````
• Basically, don't use quicksort with a linked-list style data structure. You want mergesort. Quicksort will always perform poorly for any data structure where random access is O(n). – Yuushi Feb 11 '13 at 4:40
• I am specifically trying to implement quicksort for learning purposes. – AndroidDev93 Feb 11 '13 at 4:43
• you could use `qsort (x:xs) = qsort (filter (< x) xs) ++ [x] ++ qsort (filter (>= x) xs)` algorithm though some consider that it is not "true" quicksort because the partioning is not inplace. – jfs Feb 11 '13 at 4:57
• Don't move data between nodes, rearrange nodes instead. When partitioning, build two separate lists out of existing nodes and then join them. – n.m. Feb 11 '13 at 6:17
• @Yuushi pls see code below. With care, Quicksort does not need general random access, so it's performance is fine on linked lists. – Gene Feb 11 '13 at 6:47

Mergesort is more natural to implement for linked lists, but you can do quicksort very nicely. Below is one in C I've used in several applications.

It's a common myth that you can't do Quicksort efficiently with lists. This just isn't true, although careful implementation is required.

To answer your question, the Quicksort algorithm for lists is essentially the same as for arrays. Pick a pivot (the code below uses the head of the list), partition into two lists about the pivot, then recursively sort those lists and append the results with pivot in the middle. What is a bit non-obvious is that the append operation can be done with no extra pass over the list if you add a parameter for a list to be appended as-is at the tail of the sorted result. In the base case, appending this list requires no work.

It turns out that if comparisons are cheap, mergesort tends to run a little faster because quicksort spends more time fiddling with pointers. However if comparisons are expensive, then quicksort often runs faster because it needs fewer of them.

If `NODE *list` is the head of the initial list, then you can sort it with

``````qs(list, NULL, &list);
``````

Here is the sort code. Note a chunk of it is an optimization for already-sorted lists. This optimization can be deleted if these cases are infrequent.

``````void qs(NODE * hd, NODE * tl, NODE ** rtn)
{
int nlo, nhi;
NODE *lo, *hi, *q, *p;

/* Invariant:  Return head sorted with `tl' appended. */
while (hd != NULL) {

nlo = nhi = 0;
lo = hi = NULL;
q = hd;
p = hd->next;

/* Start optimization for O(n) behavior on sorted and reverse-of-sorted lists */
while (p != NULL && LEQ(p, hd)) {
hd->next = hi;
hi = hd;
++nhi;
hd = p;
p = p->next;
}

/* If entire list was ascending, we're done. */
if (p == NULL) {
*rtn = hd;
hd->next = hi;
q->next = tl;
return;
}
/* End optimization.  Can be deleted if desired. */

/* Partition and count sizes. */
while (p != NULL) {
q = p->next;
if (LEQ(p, hd)) {
p->next = lo;
lo = p;
++nlo;
} else {
p->next = hi;
hi = p;
++nhi;
}
p = q;
}

/* Recur to establish invariant for sublists of hd,
choosing shortest list first to limit stack. */
if (nlo < nhi) {
qs(lo, hd, rtn);
rtn = &hd->next;
hd = hi;        /* Eliminated tail-recursive call. */
} else {
qs(hi, tl, &hd->next);
tl = hd;
hd = lo;        /* Eliminated tail-recursive call. */
}
}
/* Base case of recurrence. Invariant is easy here. */
*rtn = tl;
}
``````
• You could eke out a bit more efficiency by swapping whole sublists of elements about the pivot, rather than individual elements, since swapping sublists would be O(1) in a Linked List. Really only relevant if your bottleneck is in memory writes though. – Andy Jan 9 '14 at 22:59
• @Andork Thanks. Good idea. This code is so pretty though (especially without the special case for sorted lists), I will – Gene Jan 9 '14 at 23:14
• yeah, the code was a lot smaller than I expected! – Andy Jan 10 '14 at 4:27

You can use quicksort and do not loose the O(n*log(n)) expected behaviour. The trick is simple - put the nodes into the array, sort array of nodes, relink them in correct order.

• why the -1? This is the best way how you can do this, because quicksorting linkedlist as a structure simply does not make much sense... – malejpavouk Jun 10 '14 at 11:07
• The assumption is that we want to directly sort a linked-list using quicksort, not to convert it to something else first, sort that, then convert it back. There may technically be a loophole in the question, but that's why it's an assumption, and not a fact. – Dukeling Jun 11 '14 at 21:41
• elegant solution that doesn't lose any asymptotic performance – alternative Apr 14 '15 at 13:33

Here is a java implementation. It uses the head as the pivot. This can further be improved by avoiding the scanning of the left sublist before appending the right sublist, but it works. This is O(nLogn) too.

``````public class QuickSortLinkedList {

//Base Case
//Partition Strategy
//Chose first element as pivot and move all elements smaller than the pivot at the end of LL
//So the order will be pivot, elements smaller than or equal to pivot, elements larger than pivot
//Example: 9,13,10,6,9,8,11 => 9,13,10,9,11,6,8  and the method will return a pointer to 11

//The elements to the right of pivot were all smaller than pivot after partioned
//Example: LeftPartition  = 6->8->null
ListNode leftPartition = partitionedElement.next;

//The elements to the left of pivot were all large , so they go in right partition
//Example: rightPartition = 9->13->10->9->11->null
partitionedElement.next = null;

//But there can be edge cases
//Example: 3,5,3,4,5-null => after partition , list is unchanged and last element 5 is returned
//in this case leftPartition: 3->null and rightPartition 5,3,4,5-null
if(leftPartition == null){
}

//Now Recursively sort
rightPartition = sortList(rightPartition);
leftPartition = sortList(leftPartition);

//After sorting append rightPartition to leftPartition
ListNode iterator = leftPartition;
while(iterator.next!=null)
iterator = iterator.next;
iterator.next = rightPartition;

return leftPartition;
}

//Base case

else
}

else{
ListNode lastElementSwapped = (pivot.next.val>=pivot.val)?pivot.next:pivot;

while(i!=null && i.next !=null){

if(i.next.val >= pivot.val){
if(i.next == lastElementSwapped.next){
lastElementSwapped = lastElementSwapped.next;
}
else{
ListNode temp = lastElementSwapped.next;
lastElementSwapped.next = i.next;
i.next = i.next.next;
lastElementSwapped = lastElementSwapped.next;
lastElementSwapped.next = temp;
}
}

i = i.next;

}
return lastElementSwapped;
}

}
}
``````