# Non-Recursive Merge Sort

Can someone explain in English how does Non-Recursive merge sort works ?

Thanks

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While bobbymcr provides a good answer, also note that recursion and iteration are formally equivalent. See stackoverflow.com/questions/159590/… –  Adam Rosenfield Oct 13 '09 at 2:15

Loop through the elements and make every adjacent group of two sorted by swapping the two when necessary.

Now, dealing with groups of two groups (any two, most likely adjacent groups, but you could use the first and last groups) merge them into one group be selecting the lowest valued element from each group repeatedly until all 4 elements are merged into a group of 4. Now, you have nothing but groups of 4 plus a possible remainder. Using a loop around the previous logic, do it all again except this time work in groups of 4. This loop runs until there is only one group.

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can this be done in place? –  DarthVader Oct 13 '09 at 2:18
Mergesort can be done in-place, but it is generally "hard" to do this. –  bobbymcr Oct 13 '09 at 2:30
The one on Algorithmist doesn't look to hard. However you'll lose some locality if you are sorting a dataset too large to fit in memory –  John La Rooy Oct 13 '09 at 2:38
Ah you are talking about mergesort as opposed to bottom-up mergesort –  John La Rooy Oct 13 '09 at 2:39
I m asking about non recursive merge sort which bottom-up is non recursive merge sort. –  DarthVader Oct 13 '09 at 3:06

Non-recursive merge sort works by considering window sizes of 1,2,4,8,16..2^n over the input array. For each window ('k' in code below), all adjacent pairs of windows are merged into a temporary space, then put back into the array.

Here is my single function, C-based, non-recursive merge sort. Input and output are in 'a'. Temporary storage in 'b'. One day, I'd like to have a version that was in-place:

``````float a[50000000],b[50000000];
void mergesort (long num)
{
int rght, wid, rend;
int i,j,m,t;

for (int k=1; k < num; k *= 2 ) {
for (int left=0; left+k < num; left += k*2 ) {
rght = left + k;
rend = rght + k;
if (rend > num) rend = num;
m = left; i = left; j = rght;
while (i < rght && j < rend) {
if (a[i] <= a[j]) {
b[m] = a[i]; i++;
} else {
b[m] = a[j]; j++;
}
m++;
}
while (i < rght) {
b[m]=a[i];
i++; m++;
}
while (j < rend) {
b[m]=a[j];
j++; m++;
}
for (m=left; m < rend; m++) {
a[m] = b[m];
}
}
}
}
``````

By the way, it is also very easy to prove this is O(n log n). The outer loop over window size grows as power of two, so k has log n iterations. While there are many windows covered by inner loop, together, all windows for a given k exactly cover the input array, so inner loop is O(n). Combining inner and outer loops: O(n)*O(log n) = O(n log n).

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Both recursive and non-recursive merge sort have same time complexity of O(nlog(n)). This is because both the approaches use stack in one or the other manner.

In non-recursive approach the user/programmer defines and uses stack

In Recursive approach stack is used internally by the system to store return address of the function which is called recursively

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Because merge sort always does its partitioning and sorting operations in the same sequence, regardless of the initial ordering of items in the data set, there's no need to use a stack to keep track of the next operation. All one needs is the size of the known-to-be-sorted partitions (`part_size`, initially 1) and the index of the first such partition to be merged (`next_part`, initially zero). For each "step", merge partitions of size `part_size` starting at `next_part` and `next_part+part_size`, then bump `next_part` by `part_size*2`. If that would fall off the end of the array,... –  supercat Apr 4 '13 at 21:55
...double `part_size` and set `next_part` to zero. No need for recursion. –  supercat Apr 4 '13 at 21:55

Quoting from Algorithmist:

Bottom-up merge sort is a non-recursive variant of the merge sort, in which the array is sorted by a sequence of passes. During each pass, the array is divided into blocks of size m. (Initially, m = 1). Every two adjacent blocks are merged (as in normal merge sort), and the next pass is made with a twice larger value of m.

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is it still nlogn? –  DarthVader Oct 13 '09 at 2:15
Yes, every kind of mergesort is n log(n). –  bobbymcr Oct 13 '09 at 2:20

The main reason you would want to use a non-recursive MergeSort is to avoid recursion stack overflow. I for example am trying to sort 100 million records, each record about 1 kByte in length (= 100 gigabytes), in alphanumeric order. An order(N^2) sort would take 10^16 operations, ie it would take decades to run even at 0.1 microsecond per compare operation. An order (N log(N)) Merge Sort will take less than 10^10 operations or less than an hour to run at the same operational speed. However, in the recursive version of MergeSort, the 100 million element sort results in 50-million recursive calls to the MergeSort( ). At a few hundred bytes per stack recursion, this overflows the recursion stack even though the process easily fits within heap memory. Doing the Merge sort using dynamically allocated memory on the heap-- I am using the code provided by Rama Hoetzlein above, but I am using dynamically allocated memory on the heap instead of using the stack-- I can sort my 100 million records with the non-recursive merge sort and I don't overflow the stack. An appropriate conversation for website "Stack Overflow"!

PS: Thanks for the code, Rama Hoetzlein.

PPS: 100 gigabytes on the heap?!! Well, it's a virtual heap on a Hadoop cluster, and the MergeSort will be implemented in parallel on several machines sharing the load...

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