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I am trying to make a merge sort algorithm with the stl library but am having some issues. Below is the code I am using

template <typename Item, typename SizeType>
void merge_sort(Item array[], SizeType size){
    size_t n1; //Size of the first subarray
    size_t n2; //Size of the second subarray

    if(size > 1){
        //Compute the size of the subarrays
        n1 = size/2;
        n2 = size - n1;

        //create the temp array.
        int* n1Temp = new int[n1];
        int* n2Temp = new int[n2];
        int i;
        for(i = 0; i < n1; i++)
            n1Temp[i] = array[i];
        for(i = 0; i < n2; i++)
            n2Temp[i] = array[i + n1];

        //recursive calls
        merge_sort(n1Temp, n1);//sort from array[0] through array[n1 - 1] 
        merge_sort(n2Temp, n2);//sort from array[n1] to the end

        //Merge the two sorted halves.
        vector<int> v(array, array + size);
        merge(n1Temp, n1Temp + n1, n2Temp, n2Temp + n2, v.begin());     
        copy(v.begin(), v.end(), array);//copy the vector back to the array

        delete[] n1Temp;
        delete[] n2Temp;
    }
}

The code sorts fine but the problem is that it acts like a O(n^2) algorithm instead of O(n \log n), which is due to the creation of the vector in each merge sort call (I think). I tried removing the vector and just using an array in the merge function which can be seen below

    //Merge the two sorted halves.
    int* finalArray = new int[n1 + n2];
    merge(n1Temp, n1Temp + n1, n2Temp, n2Temp + n2, begin(finalArray)); 
    array = finalArray;

But this gets me nothing but errors. Is there any thing I can do to salvage my merge sort algorithm?

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1  
Why not merge n1temp and n2temp directly back into array? –  Vaughn Cato Dec 1 '12 at 15:29
1  
merge(n1Temp, n1Temp + n1, n2Temp, n2Temp + n2, array); should work - what errors do you get with this? –  user93353 Dec 1 '12 at 15:31
    
That does work! Both of you guys are right. The errors I was getting was because I was trying to use an iterator with the pointer array. –  rioneye Dec 1 '12 at 15:53
    
But still use std::vector<>, only for the partitions rather than the target merge. –  WhozCraig Dec 1 '12 at 18:50

1 Answer 1

up vote 4 down vote accepted

As both Vaughn and user93353 pointed out, you should be able to merge directly into the target array at each merge-point. But you can still use std::vector<> to make this significantly easier on yourself.

Also, your temp arrays are of direct type 'int', and I'm fairly sure that was intended to be the type of the template parameter Item. I'm not sure what the SizeType parameter is for, but I left it in case you had special ideas for it. Whatever it is, it better be compatible with size_t :

template <typename Item, typename SizeType>
void merge_sort(Item array[], SizeType size)
{
    if(size > 1)
    {
        //Compute the size of the subarrays
        size_t n1 = size/2;

        //create the temp array
        std::vector<Item> n1Temp(array, array+n1);
        std::vector<Item> n2Temp(array+n1, array+size);

        //recursive calls
        merge_sort(&n1Temp[0], n1);       //sort array[0] through array[n1-1]
        merge_sort(&n2Temp[0], size-n1);  //sort array[n1] through array[size-1]

        // merge the sorted halves
        std::merge(n1Temp.begin(), n1Temp.end(),
                   n2Temp.begin(), n2Temp.end(), array);
    }
}

The above technique splits the sub-sequences top-down via copy, then merges in-place the split-copies into the original array. You can reduce this algorithm by one sublist allocation time (but no less space) by doing the splits on the original array, then merging into temp-space and copying after, which i think you were trying to do in the first place:

template <typename Item>
void merge_sort(Item ar[], size_t n)
{
    if (n > 1)
    {
        // Compute the size of the subarrays
        size_t n1 = n/2;

        // invoke recursion on the submerges
        merge_sort(ar, n1);      //sort array[0] through array[n1-1]
        merge_sort(ar+n1, n-n1); //sort array[n1] through array[size-1]

        // create merge-buffer
        std::vector<Item> mrg;
        std::merge(ar, ar+n1, ar+n1, ar+n, back_inserter(mrg));
        std::copy(mrg.begin(), mrg.end(), ar);
    }
}

General Iterator-Based Solution

For a general solution that allows even more flexibility you can define your merge-sort based on iterators rather than Item pointers. It gets a little more hairy, but the benefits are very std-lib-ish.

template <typename Iterator>
void merge_sort(Iterator first, Iterator last)
{
    typedef typename std::iterator_traits<Iterator>::value_type value_type;
    typedef typename std::iterator_traits<Iterator>::difference_type difference_type;

    difference_type n = std::distance(first, last)/2;
    if (n == 0)
        return;

    // invoke recursion on the submerges
    merge_sort(first, first + n);
    merge_sort(first + n, last);

    // create merge-buffer
    std::vector<value_type> mrg(std::distance(first, last));
    std::merge(first, first+n, first+n, last, mrg.begin());
    std::copy(mrg.begin(), mrg.end(), first);
}

Finally, if you find yourself sorting a ton of fixed-length C-arrays you may find the following helpful (it uses the general-iterator solution above):

// front-loader for C arrays
template<typename Item, size_t N>
void merge_sort(Item (&ar)[N])
{
    merge_sort(std::begin(ar), std::end(ar));
}

It make the following code rather convenient:

int arr[1024];
... fill arr ...
merge_sort(arr);
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