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.
Take a peek at this implementation of a merge sort. Hope this helps. 


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. 


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. 


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 stackbased one in the first post is called the Online Mergesort and it gets the tiniest mention in an exercise in Knuth Vol 3] 


A simple, quick and "it works" way is to copy the linked list elements into a array, sort it and then recreate 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:
This one works for me: http://bitbucket.org/amitksaha/foobarscripts/src/f732216b9649/mergesortstruct.c 


A recursive version is straightforward. I'm currently working on an iterative one, but it's still buggy. 


I once have developed one for linked lists in Delphi: http://www.continuit.nl/index.php?LANGUAGE=EN&PAGE=DOCUMENTS_SORTING 


Here's another description, with an implementation in C 


Heavily based on the EXCELLENT code from: http://www.chiark.greenend.org.uk/~sgtatham/algorithms/listsort.html Trimmed slightly, and tidied:
NB: This is O(NLog(N)) guaranteed, and uses O(1) resources (no recursion, no stack, nothing). 


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





Wonder why it should be big challenge as it is stated here, here is a straightforward implementation in Java with out any "clever tricks".
Some more explanation here  http://www.dontforgettothink.com/2011/11/23/mergesortoflinkedlist 


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 nonrecursive 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.



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.



There's a nonrecursive linkedlist mergesort in mono eglib. The basic idea is that the controlloop for the various merges parallels the bitwiseincrement 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 mergetree need to be materialized into a temporary holding array. 


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. 

