# Merge Sort a Linked List

I was recently brushing up on some fundamentals and found merge sorting a linked list to be a pretty good challenge. If you have a good implementation then show it off here.

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Have a look, explained both recursive and Iterative approach. javabypatel.blogspot.in/2015/12/merge-sort-linked-list.html – Jayesh Dec 29 '15 at 20:06

Wonder why it should be big challenge as it is stated here, here is a straightforward implementation in Java with out any "clever tricks".

``````//The main function
public Node merge_sort(Node head) {
if(head == null || head.next == null) { return head; }
Node middle = getMiddle(head);      //get the middle of the list
Node sHalf = middle.next; middle.next = null;   //split the list into two halfs

return merge(merge_sort(head),merge_sort(sHalf));  //recurse on that
}

//Merge subroutine to merge two sorted lists
public Node merge(Node a, Node b) {
Node dummyHead, curr; dummyHead = new Node(); curr = dummyHead;
while(a !=null && b!= null) {
if(a.info <= b.info) { curr.next = a; a = a.next; }
else { curr.next = b; b = b.next; }
curr = curr.next;
}
curr.next = (a == null) ? b : a;
}

//Finding the middle element of the list for splitting
public Node getMiddle(Node head) {
if(head == null) { return head; }
Node slow, fast; slow = fast = head;
while(fast.next != null && fast.next.next != null) {
slow = slow.next; fast = fast.next.next;
}
return slow;
}
``````

Some more explanation here - http://www.dontforgettothink.com/2011/11/23/merge-sort-of-linked-list

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excellently easy... – L.E. Jul 28 '13 at 16:55
don't try cleaver tricks at home – poolie Aug 5 '13 at 2:53
Very readable code! – Chuntao Lu Apr 4 '14 at 3:29

A simpler/clearer implementation might be the recursive implementation, from which the NLog(N) execution time is more clear.

``````typedef struct _aList {
struct _aList* next;
struct _aList* prev; // Optional.
// some data
} aList;

aList* merge_sort_list_recursive(aList *list,int (*compare)(aList *one,aList *two))
{
// Trivial case.
if (!list || !list->next)
return list;

aList *right = list,
*temp  = list,
*last  = list,
*result = 0,
*next   = 0,
*tail   = 0;

// Find halfway through the list (by running two pointers, one at twice the speed of the other).
while (temp && temp->next)
{
last = right;
right = right->next;
temp = temp->next->next;
}

// Break the list in two. (prev pointers are broken here, but we fix later)
last->next = 0;

// Recurse on the two smaller lists:
list = merge_sort_list_recursive(list, compare);
right = merge_sort_list_recursive(right, compare);

// Merge:
while (list || right)
{
// Take from empty lists, or compare:
if (!right) {
next = list;
list = list->next;
} else if (!list) {
next = right;
right = right->next;
} else if (compare(list, right) < 0) {
next = list;
list = list->next;
} else {
next = right;
right = right->next;
}
if (!result) {
result=next;
} else {
tail->next=next;
}
next->prev = tail;  // Optional.
tail = next;
}
return result;
}
``````

NB: This has a Log(N) storage requirement for the recursion. Performance should be roughly comparable with the other strategy I posted. There is a potential optimisation here by running the merge loop while (list && right), and simple appending the remaining list (since we don't really care about the end of the lists; knowing that they're merged suffices).

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Heavily based on the EXCELLENT code from: http://www.chiark.greenend.org.uk/~sgtatham/algorithms/listsort.html

Trimmed slightly, and tidied:

``````
typedef struct _aList {
struct _aList* next;
struct _aList* prev; // Optional.
// some data
} aList;

aList *merge_sort_list(aList *list,int (*compare)(aList *one,aList *two))
{
int listSize=1,numMerges,leftSize,rightSize;
aList *tail,*left,*right,*next;
if (!list || !list->next) return list;  // Trivial case

do { // For each power of two<=list length
numMerges=0,left=list;tail=list=0; // Start at the start

while (left) { // Do this list_len/listSize times:
numMerges++,right=left,leftSize=0,rightSize=listSize;
// Cut list into two halves (but don't overrun)
while (right && leftSize<listSize) leftSize++,right=right->next;
// Run through the lists appending onto what we have so far.
while (leftSize>0 || (rightSize>0 && right)) {
// Left empty, take right OR Right empty, take left, OR compare.
if (!leftSize)                  {next=right;right=right->next;rightSize--;}
else if (!rightSize || !right)  {next=left;left=left->next;leftSize--;}
else if (compare(left,right)<0) {next=left;left=left->next;leftSize--;}
else                            {next=right;right=right->next;rightSize--;}
// Update pointers to keep track of where we are:
if (tail) tail->next=next;  else list=next;
// Sort prev pointer
next->prev=tail; // Optional.
tail=next;
}
// Right is now AFTER the list we just sorted, so start the next sort there.
left=right;
}
// Terminate the list, double the list-sort size.
tail->next=0,listSize<<=1;
} while (numMerges>1); // If we only did one merge, then we just sorted the whole list.
return list;
}

``````

NB: This is O(NLog(N)) guaranteed, and uses O(1) resources (no recursion, no stack, nothing).

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I thought I'd try this code on my own Linked List. For some reason it runs slower than the recursive version over an int list of 10 million items. It took around 6-7 seconds for the recursive version and around 10 for this one? – Matt Jul 18 '11 at 5:01
No surprise. The recursive one uses extra storage to speed things up. – Dave Gamble Apr 8 '12 at 12:04

One interesting way is to maintain a stack, and only merge if the list on the stack has the same number of elements, and otherwise push the list, until you run out of elements in the incoming list, and then merge up the stack.

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The simplest is from Gonnet + Baeza Yates Handbook of Algorithms. You call it with the number of sorted elements you want, which recursively gets bisected until it reaches a request for a size one list which you then just peel off the front of the original list. These all get merged up into a full sized sorted list.

[Note that the cool stack-based one in the first post is called the Online Mergesort and it gets the tiniest mention in an exercise in Knuth Vol 3]

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Here's an alternative recursive version. This does not need to step along the list to split it: we supply a pointer to a head element (which is not part of the sort) and a length, and the recursive function returns a pointer to the end of the sorted list.

``````element* mergesort(element *head,long lengtho)
{
long count1=(lengtho/2), count2=(lengtho-count1);
element *next1,*next2,*tail1,*tail2,*tail;
if (lengtho<=1) return head->next;  /* Trivial case. */

tail2 = mergesort(tail1,count2);
next2 = tail1->next;
tail1->next = tail2->next; /* in case this ends up as the tail */
while (1) {
if(cmp(next1,next2)<=0) {
tail->next=next1; tail=next1;
if(--count1==0) { tail->next=next2; return tail2; }
next1=next1->next;
} else {
tail->next=next2; tail=next2;
if(--count2==0) { tail->next=next1; return tail1; }
next2=next2->next;
}
}
}
``````
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I came up with essentially the same implementation, except with pointers-to-pointers instead of dummy nodes, thinking clearly my innovative code must be a quantum leap in computer science. Nothing new under the sun I suppose. Any suggestions for a clean way of speeding up the mostly pre-sorted case? – doynax Jan 6 '14 at 7:35

I'd been obsessing over optimizing clutter for this algorithm and below is what I've finally arrived at. Lot of other code on Internet and StackOverflow is horribly bad. There are people trying to get middle point of the list, doing recursion, having multiple loops for left over nodes, maintaining counts of ton of things - ALL of which is unnecessary. MergeSort naturally fits to linked list and algorithm can be beautiful and compact but it's not trivial to get to that state.

Below code maintains minimum number of variables and has minimum number of logical steps needed for the algorithm (i.e. without making code unmaintainable/unreadable) as far as I know. However I haven't tried to minimize LOC and kept as much white space as necessary to keep things readable. I've tested this code through fairly rigorous unit tests.

Note that this answer combines few techniques from other answer http://stackoverflow.com/a/3032462/207661. While the code is in C#, it should be trivial to convert in to C++, Java, etc.

``````SingleListNode<T> SortLinkedList<T>(SingleListNode<T> head) where T : IComparable<T>
{
int blockSize = 1, blockCount;
do
{
//Maintain two lists pointing to two blocks, left and right
SingleListNode<T> left = head, right = head, tail = null;
head = null; //Start a new list
blockCount = 0;

//Walk through entire list in blocks of size blockCount
while (left != null)
{
blockCount++;

//Advance right to start of next block, measure size of left list while doing so
int leftSize = 0, rightSize = blockSize;
for (;leftSize < blockSize && right != null; ++leftSize)
right = right.Next;

//Merge two list until their individual ends
bool leftEmpty = leftSize == 0, rightEmpty = rightSize == 0 || right == null;
while (!leftEmpty || !rightEmpty)
{
SingleListNode<T> smaller;
//Using <= instead of < gives us sort stability
if (rightEmpty || (!leftEmpty && left.Value.CompareTo(right.Value) <= 0))
{
smaller = left; left = left.Next; --leftSize;
leftEmpty = leftSize == 0;
}
else
{
smaller = right; right = right.Next; --rightSize;
rightEmpty = rightSize == 0 || right == null;
}

//Update new list
if (tail != null)
tail.Next = smaller;
else
tail = smaller;
}

//right now points to next block for left
left = right;
}

//terminate new list, take care of case when input list is null
if (tail != null)
tail.Next = null;

//Lg n iterations
blockSize <<= 1;

} while (blockCount > 1);

}
``````

Points of interest

• There is no special handling for cases like null list of list of 1 etc required. These cases "just works".
• Lot of "standard" algorithms texts have two loops to go over leftover elements to handle the case when one list is shorter than other. Above code eliminates need for it.
• We make sure sort is stable
• The inner while loop which is a hot spot evaluates 3 expressions per iteration on average which I think is minimum one can do.

Update: @ideasman42 has translated above code to C/C++ along with suggestions for fixing comments and bit more improvement. Above code is now up to date with these.

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This is absolutely brilliant ! I converted it to Delphi and it works very nice. Thank you, sir ! – Marus Nebunu May 7 '15 at 11:43
The comments look like they're not updated to match the code. They refer to variables which don't exist in the code `p q & k` which (I think) should be `left right & block_size` respectively. – ideasman42 May 23 '15 at 5:30
Made an improved version of this answer: gist.github.com/ideasman42/5921b0edfc6aa41a9ce0 1) Use a pointer to the tail (remove 2x conditional checks, reduces code-size). 2) Avoid re-assigning empty values the size doesn't change. 3) Corrected comments. – ideasman42 May 23 '15 at 6:12
Thanks @ideaman42. I've added one improvement in above code. For tail_p, there is no direct C# equivalent so it stays same :(. – ShitalShah May 24 '15 at 11:08
While this is quite good, the version from Mono's eglib performs slightly faster in my tests (optimized C) ~10-20%, See: stackoverflow.com/a/18246901/432509 – ideasman42 Jun 10 '15 at 13:17

I decided to test the examples here, and also one more approach, originally written by Jonathan Cunningham in Pop-11. I coded all the approaches in C# and did a comparison with a range of different list sizes. I compared the Mono eglib approach by Raja R Harinath, the C# code by Shital Shah, the Java approach by Jayadev, the recursive and non-recursive versions by David Gamble, the first C code by Ed Wynn (this crashed with my sample dataset, I didn't debug), and Cunningham's version. Full code here: https://gist.github.com/314e572808f29adb0e41.git.

Mono eglib is based on a similar idea to Cunningham's and is of comparable speed, unless the list happens to be sorted already, in which case Cunningham's approach is much much faster (if its partially sorted, the eglib is slightly faster). The eglib code uses a fixed table to hold the merge sort recursion, whereas Cunningham's approach works by using increasing levels of recursion - so it starts out using no recursion, then 1-deep recursion, then 2-deep recursion and so on, according to how many steps are needed to do the sort. I find the Cunningham code a little easier to follow and there is no guessing involved in how big to make the recursion table, so it gets my vote. The other approaches I tried from this page were two or more times slower.

Here is the C# port of the Pop-11 sort:

``````/// <summary>
/// Sort a linked list in place. Returns the sorted list.
/// Originally by Jonathan Cunningham in Pop-11, May 1981.
/// Ported to C# by Jon Meyer.
/// </summary>
public class ListSorter<T> where T : IComparable<T> {
SingleListNode<T> workNode = new SingleListNode<T>(default(T));
SingleListNode<T> list;

/// <summary>
/// Sorts a linked list. Returns the sorted list.
/// </summary>
public SingleListNode<T> Sort(SingleListNode<T> head) {
if (head == null) throw new NullReferenceException("head");

var run = GetRun(); // get first run
// As we progress, we increase the recursion depth.
var n = 1;
while (list != null) {
var run2 = GetSequence(n);
run = Merge(run, run2);
n++;
}
return run;
}

// Get the longest run of ordered elements from list.
// The run is returned, and list is updated to point to the
// first out-of-order element.
SingleListNode<T> GetRun() {
var run = list; // the return result is the original list
var prevNode = list;
var prevItem = list.Value;

list = list.Next; // advance to the next item
while (list != null) {
var comp = prevItem.CompareTo(list.Value);
if (comp > 0) {
// reached end of sequence
prevNode.Next = null;
break;
}
prevItem = list.Value;
prevNode = list;
list = list.Next;
}
return run;
}

// Generates a sequence of Merge and GetRun() operations.
// If n is 1, returns GetRun()
// If n is 2, returns Merge(GetRun(), GetRun())
// If n is 3, returns Merge(Merge(GetRun(), GetRun()),
//                          Merge(GetRun(), GetRun()))
// and so on.
SingleListNode<T> GetSequence(int n) {
if (n < 2) {
return GetRun();
} else {
n--;
var run1 = GetSequence(n);
if (list == null) return run1;
var run2 = GetSequence(n);
return Merge(run1, run2);
}
}

// Given two ordered lists this returns a list that is the
// result of merging the two lists in-place (modifying the pairs
// in list1 and list2).
SingleListNode<T> Merge(SingleListNode<T> list1, SingleListNode<T> list2) {
// we reuse a single work node to hold the result.
// Simplifies the number of test cases in the code below.
var prevNode = workNode;
while (true) {
if (list1.Value.CompareTo(list2.Value) <= 0) {
// list1 goes first
prevNode.Next = list1;
prevNode = list1;
if ((list1 = list1.Next) == null) {
// reached end of list1 - join list2 to prevNode
prevNode.Next = list2;
break;
}
} else {        // same but for list2
prevNode.Next = list2;
prevNode = list2;
if ((list2 = list2.Next) == null) {
prevNode.Next = list1;
break;
}
}
}

// the result is in the back of the workNode
return workNode.Next;
}
}
``````
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Here is my implementation of Knuth's "List merge sort" (Algorithm 5.2.4L from Vol.3 of TAOCP, 2nd ed.). I'll add some comments at the end, but here's a summary:

On random input, it runs a bit faster than Simon Tatham's code (see Dave Gamble's non-recursive answer, with a link) but a bit slower than Dave Gamble's recursive code. It's harder to understand than either. At least in my implementation, it requires each element to have TWO pointers to elements. (An alternative would be one pointer and a boolean flag.) So, it's probably not a useful approach. However, one distinctive point is that it runs very fast if the input has long stretches that are already sorted.

``````element *knuthsort(element *list)
{ /* This is my attempt at implementing Knuth's Algorithm 5.2.4L "List merge sort"
from Vol.3 of TAOCP, 2nd ed. */
element *p, *pnext, *q, *qnext, head1, head2, *s, *t;
if(!list) return NULL;

L1: /* This is the clever L1 from exercise 12, p.167, solution p.647. */
for(p=list, pnext=p->next; pnext; p=pnext, pnext=p->next) {
if( cmp(p,pnext) > 0 ) { t->next=NULL; t->spare=pnext; t=p; }
}
t->next=NULL; t->spare=NULL; p->spare=NULL;

L2: /* begin a new pass: */
q=t->next;
p=s->next;

L3: /* compare: */
if( cmp(p,q) > 0 ) goto L6;
L4: /* add p onto the current end, s: */
if(s->next) s->next=p; else s->spare=p;
s=p;
if(p->next) { p=p->next; goto L3; }
else p=p->spare;
L5: /* complete the sublist by adding q and all its successors: */
s->next=q; s=t;
for(qnext=q->next; qnext; q=qnext, qnext=q->next);
t=q; q=q->spare;
goto L8;
L6: /* add q onto the current end, s: */
if(s->next) s->next=q; else s->spare=q;
s=q;
if(q->next) { q=q->next; goto L3; }
else q=q->spare;
L7: /* complete the sublist by adding p and all its successors: */
s->next=p;
s=t;
for(pnext=p->next; pnext; p=pnext, pnext=p->next);
t=p; p=p->spare;
L8: /* is this end of the pass? */
if(q) goto L3;
if(s->next) s->next=p; else s->spare=p;
t->next=NULL; t->spare=NULL;
goto L2;
}
``````
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The overall strategy is that we hold two chains of sublists, extending from the two dummy elements head1 and head2. A sublist is known to be sorted. We make several passes, merging the first sublist from head1 with the first from head2, then the second with the second, and so on. (It is essential that there are equal numbers of sublists, or one extra in head1's chain.) The newly merged sublists are attached alternately to the first and second chain, in place, stably, and without recursion. – Ed Wynn Jul 14 '12 at 19:18
A significant quirk of this implementation is that it uses a second pointer, e->spare, with each element. Before the end of a sublist, e->next gives the next element. At the end, e->next is NULL. The start of the next sublist (if any) is given by e->spare. At the end of the sort, the entire list is linked via ->next. Knuth's pseudo-code used array indices instead of pointers, and a negative index announced the end of a sublist (and the absolute value gave the next sublist's start). – Ed Wynn Jul 14 '12 at 19:19
Step L1 arranges the input list into sublists. A "vanilla" version starts with all sublists of length 1. The "clever" version here keeps any ordered sequences in the input list. In particular, if the list is sorted on arrival, the sort terminates after (n-1) comparisons. The clever version therefore gives a massive saving on sorted input, and a lesser saving on input that has some bias towards being sorted. On random input, the clever version is usually very slightly faster (by a couple of percent) although it uses more comparisons. – Ed Wynn Jul 14 '12 at 19:20
As I said at the start, I'm not expecting anyone to like this as an algorithm (unless you often sort an almost-perfectly-sorted list). I've added this (to a fairly old post) to save you the trouble and disappointment I've just gone through ;-) – Ed Wynn Jul 14 '12 at 19:24

There's a non-recursive linked-list mergesort in mono eglib.

The basic idea is that the control-loop for the various merges parallels the bitwise-increment of a binary integer. There are O(n) merges to "insert" n nodes into the merge tree, and the rank of those merges corresponds to the binary digit that gets incremented. Using this analogy, only O(log n) nodes of the merge-tree need to be materialized into a temporary holding array.

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This is the best implementation I've found so far, made a portable implementation of it (which can be included directly, with addition of optiona `thunk` argument ~ like `qsort_r`). See gist.github.com/ideasman42/… – ideasman42 Jun 10 '15 at 13:17

A top down approach wastes time scanning lists to split them. This example code and HP / Microsoft std::list::sort both use the same basic algorithm. A bottom up, non-recursive, merge sort that uses a small (26 to 32) array of pointers to the first nodes of a list, where array[i] is either 0 or points to a list of size 2 to the power i. On my system, Intel 2600K 3.4ghz, it can sort 4 million nodes with 32 bit unsigned integers as data in about 1 second.

``````NODE * MergeLists(NODE *, NODE *); /* prototype */

/* sort a list using array of pointers to list       */
/* aList[i] == NULL or ptr to list with 2^i nodes    */

#define NUMLISTS 32             /* number of lists */
NODE * SortList(NODE *pList)
{
NODE * aList[NUMLISTS];         /* array of lists */
NODE * pNode;
NODE * pNext;
int i;
if(pList == NULL)           /* check for empty list */
return NULL;
for(i = 0; i < NUMLISTS; i++)   /* init array */
aList[i] = NULL;
pNode = pList;              /* merge nodes into array */
while(pNode != NULL){
pNext = pNode->next;
pNode->next = NULL;
for(i = 0; (i < NUMLISTS) && (aList[i] != NULL); i++){
pNode = MergeLists(aList[i], pNode);
aList[i] = NULL;
}
if(i == NUMLISTS)   /* don't go beyond end of array */
i--;
aList[i] = pNode;
pNode = pNext;
}
pNode = NULL;           /* merge array into one list */
for(i = 0; i < NUMLISTS; i++)
pNode = MergeLists(aList[i], pNode);
return pNode;
}

/* merge two already sorted lists                    */
/* compare uses pSrc2 < pSrc1 to follow the STL rule */
/*   of only using < and not <=                      */
NODE * MergeLists(NODE *pSrc1, NODE *pSrc2)
{
NODE *pDst = NULL;          /* destination head ptr */
NODE **ppDst = &pDst;       /* ptr to head or prev->next */
if(pSrc1 == NULL)
return pSrc2;
if(pSrc2 == NULL)
return pSrc1;
while(1){
if(pSrc2->data < pSrc1->data){  /* if src2 < src1 */
*ppDst = pSrc2;
pSrc2 = *(ppDst = &(pSrc2->next));
if(pSrc2 == NULL){
*ppDst = pSrc1;
break;
}
} else {                        /* src1 <= src2 */
*ppDst = pSrc1;
pSrc1 = *(ppDst = &(pSrc1->next));
if(pSrc1 == NULL){
*ppDst = pSrc2;
break;
}
}
}
return pDst;
}
``````
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You can use that implementation of merge sort and write your own functions to interface with the linked list as if it were an array.

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One of the drawback of the merge sort is that it uses up O(n) space to store the data. i.e. when you merge the two sublists For linked list, this can be avoided by keep changing the next pointer in the list node. The last implementation seems neat but fails to consider it.

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``````public int[] msort(int[] a) {
if (a.Length > 1) {
int min = a.Length / 2;
int max = min;

int[] b = new int[min];
int[] c = new int[max]; // dividing main array into two half arrays
for (int i = 0; i < min; i++) {
b[i] = a[i];
}

for (int i = min; i < min + max; i++) {
c[i - min] = a[i];
}

b = msort(b);
c = msort(c);

int x = 0;
int y = 0;
int z = 0;

while (b.Length != y && c.Length != z) {
if (b[y] < c[z]) {
a[x] = b[y];
//r--
x++;
y++;
} else {
a[x] = c[z];
x++;
z++;
}
}

while (b.Length != y) {
a[x] = b[y];
x++;
y++;
}

while (c.Length != z) {
a[x] = c[z];
x++;
z++;
}
}

return a;
}
``````
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i think this 1 is perfect!!!!!!!!!! – Pramod Jul 7 '11 at 13:06

A simple, quick and "it works" way is to copy the linked list elements into a array, sort it and then re-create the linked list back. However, such a solution won't work straight away if you have got for than one member in your node, such as:

``````struct node {
int data1;
int data2;
struct node *next;
};
``````

This one works for me: http://bitbucket.org/amitksaha/foobar-scripts/src/f732216b9649/merge-sort-struct.c

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This is definitely not how to sort a linked list. The existence of the stable, guaranteed NLog(N), O(1) resource mergesort means that if you HAVE data in a linked list, you should DEFINITELY NOT copy it out. (Unless you have specific circumstances, such as the availability of a radix sort). – Dave Gamble Jun 13 '10 at 14:33