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I sorted a million random positive long numbers about 20 digits in length using my implementations of Merge sort and Radix sort. The merge sort is significantly, almost 6 times, faster than the Radix sort.

I understand the time complexity of Radix sort also depends on the number of digits of the integers, but my merge implementation is beating my Radix implementation on all input sizes.

I am using my own queue class that has constant time push() and pop() in my radix sort. I am using arrays in the merge sort. Does this have something to do with this?

public static void RadixSort(long arr[]) {
            //Using 10 queues for each digit from 0-9.
    Queue q[] = new Queue[10];

    for (int i = 0; i < 10; i++)
        q[i] = new Queue();

    boolean allNumbersNotBucketed = true;
    long divisor = 1;

    while (allNumbersNotBucketed) {
        allNumbersNotBucketed = false;

        for (int i = 0; i < arr.length; i++) {
            long digit = (arr[i] / divisor) % 10;

            q[(int) digit].enqueue(arr[i]);
                            //Put number into appropriate queue.

            if(digit > 0) allNumbersNotBucketed = true;
        int pos = 0;
        divisor *= 10;
        for (int i = 0; i < 10; i++) 
            while (!q[i].isEmpty())
                      arr[pos++] = q[i].dequeue();
            //Put queue contents back into array

Here is the merge sort

public static void mergeSort(long[] a) {
    long[] tmp = new long[a.length];
    mergeSort(a, tmp, 0, a.length - 1);

private static void mergeSort(long[] a, long[] tmp, int left, int right) {
    if (left < right) {
        int center = (left + right) / 2;
        mergeSort(a, tmp, left, center);    //Divide 0 to middle
        mergeSort(a, tmp, center + 1, right); // Divide middle to center
        merge(a, tmp, left, center + 1, right); //Merge sorted lists

private static void merge(long[] a, long[] tmp, int left, int right,
        int rightEnd) {
    long leftEnd = right - 1;
    int k = left;
    long num = rightEnd - left + 1;

    //Put smallest element into tmp while both lists
    //are non empty.
    while (left <= leftEnd && right <= rightEnd)
        if (a[left] < a[right])
            tmp[k++] = a[left++];
            tmp[k++] = a[right++];

    while (left <= leftEnd)
        // Copy rest of first half
        tmp[k++] = a[left++];

    while (right <= rightEnd)
        // Copy rest of right half
        tmp[k++] = a[right++];

    // Copy tmp back
    for (long i = 0; i < num; i++, rightEnd--)
        a[rightEnd] = tmp[rightEnd];

EDIT: I was rather stupidly using a LinkedList style Queue. I changed it to use a native array and now the merge sort is only twice as fast as compared to 6 times as fast earlier. The merge sort is still faster even for numbers only 10 digits long. I guess the BigO constants are in play here. Multiple million function calls to push() and pop() could also be to blame here.

share|improve this question
can we see the implementation of your merge and radix sort –  exexzian Feb 8 '14 at 2:32
When you measure actual implementations then often the constants hidden by the BigOh become important. It's easy to do things that kill performance, and "my own queue class" is not a good sign. –  Adam Feb 8 '14 at 2:34
Without seeing your implementations, there's no way to tell what the problem is. –  Jim Mischel Feb 8 '14 at 3:33
The whole premise of radix sort is use direct addressing for everything. Ie., arrays and memory offsets ONLY. You should never use things like queues or linked lists for radix sorts! –  RBarryYoung Feb 8 '14 at 21:34
You can checkout my implementation, no need for linked lists: github.com/thomasjungblut/thomasjungblut-common/blob/master/src/… –  Thomas Jungblut Feb 8 '14 at 21:41

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