I am currently working on a project for my algorithms class and am at a bit of a standstill. We were assigned to do improvements to merge sort, that was in the book, by implementing specific changes. I have worked fine through the first 2 changes but the 3'rd one is killer.

Merge sort, the one we are improving, copies the contents of the input array into the temporary array, and then copies the temporary array back into the input array. So it recursively sorts the input array, placing the two sorted halves into the temporary array. And then it merges the two halves in the temporary array together, placing the sorted sequence into the input array as it goes.

The improvement is that this double copying is wasteful can be done without. His hint is that: We can make it so that each call to Merge only copies in one direction, but the calls to Merge alternate the direction.

This is supposedly done by blurring the lines between the original and temporary array.

I am not really looking for code as I am confident that I can code this. I just have no idea what i'm supposed to be doing. The professor is gone for the day so I can't ask him until next week when I have his course again.

Has anyone done something like this before? Or can decipher and put it into laymans terms for me :P

The first improvement, simply has it use insertion sort whenever an Array gets small enough that it will benefit greatly, timewise, from doing so.

The second improvement stops allocating two dynamic arrays (the 2 halves that are sorted) and instead allocates 1 array of size n and that is what is used instead of the two dynamic arrays. That's that last one I did. The code for that is :

```
//#include "InsertionSort.h"
#define INSERTION_CUTOFF 250
#include <limits.h> // needed for INT_MAX (the sentinel)
void merge3(int* inputArray, int p, int q, int r, int* tempArray)
{
int i,j,k;
for (i = p; i <= r; i++)
{
tempArray[i] = inputArray[i];
}
i = p;
j = q+1;
k = p;
while (i <= q && j <= r)
{
if (tempArray[i] <= tempArray[j])
{
inputArray[k++] = tempArray[i++];
}
else
{
inputArray[k++] = tempArray[j++];
}
}
}//merge3()
void mergeSort3Helper(int* inputArray, int p, int r, int* tempArray)
{
if (r - p < INSERTION_CUTOFF)
{
insertionSort(inputArray,p,r);
return;
}
int q = (p+r-1)/2;
mergeSort3Helper(inputArray,p,q,tempArray);
mergeSort3Helper(inputArray,q+1,r,tempArray);
merge3(inputArray,p,q,r,tempArray);
}//mergeSort3Helper()
void mergeSort3(int* inputArray, int p, int r)
{
if (r-p < 1)
{
return;
}
if (r - p < INSERTION_CUTOFF)
{
insertionSort(inputArray,p,r);
return;
}
int* tempArray = malloc((r-p)+1*sizeof(int));
tempArray[r+1] = INT_MAX;
mergeSort3Helper(inputArray,p,r,tempArray);
// This version of merge sort should allocate all the extra space
// needed for merging just once, at the very beginning, instead of
// within each call to merge3().
}//mergeSort3()
```