# complexity of mergesort with linked list

i have code for mergesort using linked list,it works fine,my question what is complexity of this algorithm?is it O(nlog(n))?also is it stable?i am interested because as i know mergesort is stable,what about using linked list?if we have elements with some equal with each-other,does this code preserve orders of elements?thanks a lot

``````#include<stdio.h>
#include <stdlib.h>
struct node
{
int number;
struct node *next;

};
struct node *addnode(int number,struct node *next);
struct node *merge(struct node *one,struct node *two);

int main(void){
struct node *current;
struct node *next;
int test[]={8,3,1,4,2,5,7,0,11,14,6};
int n=sizeof(test)/sizeof(test[0]);
int i;
for (i=0;i<n;i++)
i=0;
printf("before----after sort \n");
printf("%4d\t%4d\n",test[i++],current->number);

/* free list */
next=current->next;free(current);
return 0;
}

struct node *addnode(int number,struct node* next){
struct node *tnode;
tnode=(struct node*)malloc(sizeof(*tnode));
if(tnode!=NULL){
tnode->number=number;
tnode->next=next;
}

return tnode;
}

}
}

}
else
{

}

}
``````
-
What analysis have you done so far? You can answer your own question by running the algorithm on different inputs and plotting the runtime, as well as checking whether it's stable. – templatetypedef Mar 8 '12 at 20:33
Questions like "what is the complexity of mergesort?" and "is mergesort stable" are trivially easy to answer with websearch. – David Heffernan Mar 8 '12 at 20:47
@DavidHeffernan: The OP seems to be aware of Mergesort's complexity and stability in general, but is wondering about this specific implementation. – ruakh Mar 8 '12 at 20:51
@templatetypedef : this would only give the average time complexity. – user677656 Mar 8 '12 at 22:58

You've got a typo in your code. With it corrected, it is indeed stable, and of `O(n log n)` cpxty. Although to be sure, you really should reimplement your `merge` as a loop instead of recursion. C doesn't have tail call optimization (right?), so this can mess things up there:

``````struct node *mergesort(struct node *head){

}
}
``````

And while we're at it, change your workflow from

``````    return merge(mergesort(head_one),mergesort(head_two));
``````

to

``````    struct node *p1, *p2;
// ......
return merge(p1,p2);
``````
-
+1: You're right. I've deleted my answer. – ruakh Mar 9 '12 at 12:19
+1 Thanks for looking into this :-) – Jason Mar 9 '12 at 14:33

How not to implement mergesort for linked lists

• do not recursively bisect the list - random access isn't free
• do not divide into sublists of size `1` and `n - 1`, as explained by ruakh

How to implement mergesort for linked lists

Instead of using bisection, build the lists up by maintaining a stack of already sorted sublists. That is, start by pushing lists of size `1` to the stack and merge down until you reach a list of greater size; you don't actually need to store the list sizes if you can figure out the math behind that.

The sorting algorithm will be stable iff the merge function is. A stable version would build the merged list from scratch by always taking a single element from the lists, and using the first list in case of equality. An unstable, but better performing version would add to the merged list in chunks, avoiding unnecessary re-linking after each element.

-
recursively bisecting singly-linked list into halves adds `O(n log n)` complexity to the algorithm. I.e., a constant factor here (after the typo is fixed; see my answer). Building your own stack explicitly is fine if you do it better than a compiler writer already did. But you don't need it, to build your sorted list in a bottom up manner - you only need `log n` passes over the list with a size parameter `n` of `2,4,8, ...`, each time relink-merging in-place chunks of size `n` under assumption that chunks of `n/2` size are already sorted. cf. Richard O'Keefe such code in Prolog and Scheme. – Will Ness Mar 9 '12 at 11:25
... so this indeed is a great idea! That way there's no split, only merge. :) – Will Ness Mar 9 '12 at 21:48
@WillNess: the actual performance gain will depend on the specific use case, of course, but I've seen runtime cut in half by replacing a recursive version with a stack-based one; also, the stack-based version is on-line, ie great when reading data from disk (or other sources with latency)... – Christoph Mar 10 '12 at 0:14
aha, on-line - so you mean to merge chunks as soon as possible, in a "skewed" fashion. That way it's also more "incremental", having the minimal element so far, while the input is being consumed. Nice. It is also possible to initial-partition according to "runs" in order, with varying length, re-linking on discovery even for descending ones. But on in-memory input all this is unnecessary, stack isn't needed, and you just complete full scans of the list with 2,4,8... scheme, merging the chunks up pairwise, until only one's left. All in a loop of course, no recursion. – Will Ness Mar 10 '12 at 8:44

Mergesort means split&merge. The splitting in the fragment below is not perfect (it leads to quadratic behavior on equally distributed runlengths, see the comment from Christoph)), but it will do the trick:

``````#include <stdio.h>
#include <string.h>

struct llist {
struct llist *next;
};

int llist_cmp(struct llist *l, struct llist *r);
struct llist * llist_split(struct llist **hnd
, int (*cmp)(struct llist *l, struct llist *r) );
struct llist * llist_merge(struct llist *one, struct llist *two
, int (*cmp)(struct llist *l, struct llist *r) );
struct llist * llist_sort(struct llist *ptr
, int (*cmp)(struct llist *l, struct llist *r) );

struct llist * llist_split(struct llist **hnd, int (*cmp)(struct llist *l, struct llist *r) )
{
struct llist *this, *save, **tail;

for (save=NULL, tail = &save; this = *hnd; ) {
if (! this->next) break;
if ( cmp( this, this->next) <= 0) { hnd = &this->next; continue; }
*tail = this->next;
this->next = this->next->next;
tail = &(*tail)->next;
*tail = NULL;
}
return save;
}

struct llist * llist_merge(struct llist *one, struct llist *two, int (*cmp)(struct llist *l, struct llist *r) )
{
struct llist *result, **tail;

for (result=NULL, tail = &result; one && two; tail = &(*tail)->next ) {
if (cmp(one,two) <=0) { *tail = one; one=one->next; }
else { *tail = two; two=two->next; }
}
*tail = one ? one: two;
return result;
}
struct llist * llist_sort(struct llist *ptr, int (*cmp)(struct llist *l, struct llist *r) )
{
struct llist *save;

save=llist_split(&ptr, cmp);
if (!save) return ptr;

save = llist_sort(save, cmp);

return llist_merge(ptr, save, cmp);
}

int llist_cmp(struct llist *l, struct llist *r)

{
if (!l) return 1;
if (!r) return -1;
}

struct llist lists[] =
{{ lists+1, "one" }
,{ lists+2, "two" }
,{ lists+3, "three" }
,{ lists+4, "four" }
,{ lists+5, "five" }
,{ lists+6, "six" }
,{ lists+7, "seven" }
,{ lists+8, "eight" }
,{ lists+9, "nine" }
,{ NULL, "ten" }
};

int main()
{
struct llist *root,*tmp;

root = lists;

fprintf(stdout, "## %s\n", "initial:" );
for (tmp=root; tmp; tmp=tmp->next) {