In a "normal" merge sort, you divide the array by 2, until reaching a depth of log2n
and then start merging. Each merge of two arrays of size m
would also take 2m
operations.
This gets you to the following formula (in timing analysis):
n/2 * 2 + n/4 * 4 + ... 1 * n = n * log2n
Now if you do a three-way merge, you will divide the array by 3. The difference with the previous method is twofold:
- The depth of division is now
log3n
.
- During merge, instead of comparing 2 elements, you need to find the minimum of 3 elements.
This means that, in the most basic implementation, you will get such a formula:
n/3 * 2*3 + n/9 * 2*9 + ... 1 * 2*n = 2 * n * log3n
Note that 2 is multiplied because finding the minimum of three elements consists of 2 operations.
Asymptotically, these two are both Θ(nlogn)
. However, perhaps (I haven't tried) in practice the three-way merge sort would give better performance because of its log3n
. Nevertheless, since log2n
for n = 1000000 is a mere 20, and log3n
for the same number is 12.5, I doubt this optimization would be really effective unless n
is quite large.
With a clever implementation, a k-way merge may indeed have a nice impact on merge sort. The idea is that once you find the minimum of k
elements, you already know the relationship between the rest of the k-1
elements that are not minimum. So once consuming that minimum element from its respective list, you need only compare the new value of that list and find its ordering with respect to the remaining k-1
elements. Using a heap, this would be quite trivial.
Be sure to also see Jerry's answer. I agree with him that the true power of multiway merge comes from dealing with multiple disks and parallel processing.