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I am practicing writing sorting algorithms as part of some interview preparation, and I am wondering if anybody can help me spot why this quick sort is not very fast? It appears to have the correct runtime complexity, but it is slower than my merge sort by a constant factor of about 2. I would also appreciate any comments that would improve my code that don't necessarily answer the question.

Thanks a lot for your help! Please don't hesitate to let me know if I have made any etiquette mistakes. This is my first question here.

private class QuickSort implements Sort {

        public int[] sortItems(int[] ts) {
            List<Integer> toSort = new ArrayList<Integer>();
            for (int i : ts) {
            toSort = partition(toSort);
            int[] ret = new int[ts.length];
            for (int i = 0; i < toSort.size(); i++) {
                ret[i] = toSort.get(i);
            return ret;

        private List<Integer> partition(List<Integer> toSort) {
            if (toSort.size() <= 1)
                return toSort;
            int pivotIndex = myRandom.nextInt(toSort.size());
            Integer pivot = toSort.get(pivotIndex);
            List<Integer> left = new ArrayList<Integer>();
            List<Integer> right = new ArrayList<Integer>();
            for (int i : toSort) {
                if (i > pivot)
            left = partition(left);
            right = partition(right);
            return left;


Thanks a ton, everybody who helped!

This is my much improved class for posterity:

private class QuickSort implements Sort {

        public int[] sortItems(int[] ts) {
            int[] ret = ts.clone();
            return ret;

        private void partition(int[] toSort,int start,int end) {
            if(end-start<1) return;
            int pivotIndex = start+myRandom.nextInt(end-start);
            int pivot = toSort[pivotIndex];
            int curSorted = start;
            for(int j = start+1; j < end; j++) {
                if(toSort[j]<pivot) {
            // Now pivot is at curSorted
share|improve this question
Just throwing this out there, but quick sort is actually fastest when the array's numbers are completely random, as opposed to merge sort in which case the order doesn't matter. – sj755 Jan 1 '11 at 7:06
I suggest you have a look at the quick sort code in Collections. It is fairly fast and efficient. Or you could just use it. – Peter Lawrey Jan 1 '11 at 9:53
+1 for the title irony :) – Jops Apr 13 '13 at 5:19

3 Answers 3

up vote 9 down vote accepted

One of the biggest advantages of Quicksort is that it can be implemented as an in-place algorithm. Don't create new lists, sort the elements in-place instead.

share|improve this answer
as well , see if your input is not nearly sorted! – TalentTuner Jan 1 '11 at 7:05
@Saurabh: There's really no reason to do that. Quicksort only exhibits perverse quadratic performance for sorted input if you always select the leftmost element as the pivot. With a randomly selected or median-of-three pivot, this isn't a problem (in the OP's code, the pivot is selected randomly). – James McNellis Jan 1 '11 at 7:08
@James: Even though what you say is accurate, randomly selecting the pivot has inputs (depending on the random choices) for which the performance will degrade. So even though Saurabh's comments are not entirely accurate, the motivation for the comment is still worthy of consideration: pathological data/corner cases etc. – Aryabhatta Jan 6 '11 at 21:29
@Moron: Kind of. The fact that for some inputs, certain Quicksort implementations have quadratic time complexity is just a known fact about the algorithm. That's not really pathological. It is, however, pathological, when it takes quadratic time to sort already sorted input, because it's unreasonable. For most use cases, it's quite likely that the data will already be sorted or mostly sorted. The likelihood of random pivot selection requiring quadratic time to sort a sequence is much, much lower (almost insignificant). – James McNellis Jan 6 '11 at 21:36
That said, if I recall correctly, this is one of several reasons that Bob Sedgewick used to demonstrate why a median-of-three pivot selection is in most cases preferable to a random pivot selection. – James McNellis Jan 6 '11 at 21:37

In addition to not reusing lists, you convert between Integer and int in each step:

        for (int i : toSort) {  // converts from Integer to int
            if (i > pivot)
                right.add(i);  // converts from int to Integer
                left.add(i);   // converts from int to Integer

Note that conversion from int to Integer in general requires a new object to be created.

And finally random.nextInt() might be a non-trivial operation. Perhaps it would be better to only select a random pivot if the toSort exceeds a certain size and use a simpler pivor selection strategy otherwise (Measure it!).

share|improve this answer

I suggest the following optimizations:

First, you should use insertion sort for small n, I'd say when n<10, but test it out and find the sweet spot.

Second, as James suggested, the sorting should be done in place. The way you do this is by passing around indices in the recursive call, along with the original array. eg you have the array a and the indices 0 and 20. If the pivot is then in index 9, the recursive calls would be: partition(a, 0, 8) and partition(a, 10, 20).

Third, you might consider writing your own simple pseudopolynomial random number generator, instead of using the one provided by Java. However, I suggest trying the other optimizations first, as they could very well be enough.

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