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I learnt about quick sort and how it can be implemented in both Recursive and Iterative method.
In Iterative method :

  1. Push the range (0...n) into the stack
  2. Partition the given array with a pivot
  3. Pop the top element.
  4. Push the partitions ( index range ) into a stack if the range has more than one element
  5. Do the above 3 steps, till the stack is empty

And the recursive version is the normal one defined in wiki.

I learnt that recursive algorithms are always slower than their Iterative counterpart.
So, Which is method is preferred in terms of time complexity ( memory is not a concern )?
Which one is fast enough to use in Programming contest?
Is c++ STL sort() uses recursive approach?

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1  
you have already answered yourself. Recursive version is shorter and more clear. Iterative is faster and makes you simulate the recursion call stack. –  Vitalij Zadneprovskij Sep 23 '12 at 14:44
    
But my prof told that the recursion stack depth is same as stack which we use for storing partition range. So, how iterative one is significantly faster? –  sabari Sep 23 '12 at 14:46
    
@sabari: Your assumption about recursive being faster is wrong. I statistically tested these assumptions and editted the answer with the results. –  amit Sep 24 '12 at 8:06

2 Answers 2

up vote 10 down vote accepted

In terms of (asymptotic) time complexity - they are both the same.

"Recursive is slower then iterative" - the rational behind this statement is because of the overhead of the recursive stack (saving and restoring the environment between calls).
However -these are constant number of ops, while not changing the number of "iterations".

Both recursive and iterative quicksort are O(nlogn) average case and O(n^2) worst case.


EDIT:

just for the fun of it I ran a benchmark with the (java) code attahced to the post , and then I ran wilcoxon statistic test, to check what is the probability that the running times are indeed distinct

The results are conclusive (P_VALUE=2.6e-34, that means that the probability they are the same is 2.6*10^-34 - very not probable). But the answer is not what you expected.
The average of the iterative solution was 408.86 ms while of recursive was 236.81 ms

(Note - I used Integer and not int as argument to recursiveQsort() - otherwise the recursive would have achieved much better, because it doesn't have to box a lot of integers, which is also time consuming - I did it because the iterative solution has no choice but doing so.

Thus - your assumption is not true, the recursive solution is faster (for my machine and java for the very least) then the iterative one with P_VALUE=2.6e-34.

public static void recursvieQsort(int[] arr,Integer start, Integer end) { 
    if (end - start < 2) return; //stop clause
    int p = start + ((end-start)/2);
    p = partition(arr,p,start,end);
    recursvieQsort(arr, start, p);
    recursvieQsort(arr, p+1, end);

}

public static void iterativeQsort(int[] arr) { 
    Stack<Integer> stack = new Stack<Integer>();
    stack.push(0);
    stack.push(arr.length);
    while (!stack.isEmpty()) {
        int end = stack.pop();
        int start = stack.pop();
        if (end - start < 2) continue;
        int p = start + ((end-start)/2);
        p = partition(arr,p,start,end);

        stack.push(p+1);
        stack.push(end);

        stack.push(start);
        stack.push(p);

    }
}

private static int partition(int[] arr, int p, int start, int end) {
    int l = start;
    int h = end - 2;
    int piv = arr[p];
    swap(arr,p,end-1);

    while (l < h) {
        if (arr[l] < piv) {
            l++;
        } else if (arr[h] >= piv) { 
            h--;
        } else { 
            swap(arr,l,h);
        }
    }
    int idx = h;
    if (arr[h] < piv) idx++;
    swap(arr,end-1,idx);
    return idx;
}
private static void swap(int[] arr, int i, int j) { 
    int temp = arr[i];
    arr[i] = arr[j];
    arr[j] = temp;
}

public static void main(String... args) throws Exception {
    Random r = new Random(1);
    int SIZE = 1000000;
    int N = 100;
    int[] arr = new int[SIZE];
    int[] millisRecursive = new int[N];
    int[] millisIterative = new int[N];
    for (int t = 0; t < N; t++) { 
        for (int i = 0; i < SIZE; i++) { 
            arr[i] = r.nextInt(SIZE);
        }
        int[] tempArr = Arrays.copyOf(arr, arr.length);

        long start = System.currentTimeMillis();
        iterativeQsort(tempArr);
        millisIterative[t] = (int)(System.currentTimeMillis()-start);

        tempArr = Arrays.copyOf(arr, arr.length);

        start = System.currentTimeMillis();
        recursvieQsort(tempArr,0,arr.length);
        millisRecursive[t] = (int)(System.currentTimeMillis()-start);
    }
    int sum = 0;
    for (int x : millisRecursive) {
        System.out.println(x);
        sum += x;
    }
    System.out.println("end of recursive. AVG = " + ((double)sum)/millisRecursive.length);
    sum = 0;
    for (int x : millisIterative) {
        System.out.println(x);
        sum += x;
    }
    System.out.println("end of iterative. AVG = " + ((double)sum)/millisIterative.length);
}
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2  
Your test mainly is showing how efficient the Stack class is working, not how efficient the iterative version of quicksort is. You can use more a static, self written stack of for example 64 elements and the push and pop operations will be much faster. I guess that will be faster than the recursive one! And if you implement it the right way, you can sort 2^64 elements in the worst case, which is simply enough in practical applications. –  Argeman Sep 24 '12 at 8:23
3  
@Argeman: Thanks for your comment. This is actually the point of the benchmark - the stack solution is very dependent on the stack implementation while the call stack is pretty much optimized for its purpose already, and thus a recursive solution is not likely to be worse then an iterative one, unless you spend a lot of time optimizing the stack for specific purpose (and I doubt the difference will be significant enough to worth the time). As I said, it is just a "fun test" - the main idea behind the answer yet remains - the asymptotic time complexity is the same. –  amit Sep 24 '12 at 8:27
    
P.S. The broken printing format (and not using Arrays.toString()) is to fit the input expected by the wilcoxon online calculator in fon.hum.uva.nl/Service/Statistics/Wilcoxon_Test.html –  amit Sep 24 '12 at 8:32
    
@amit how did u run the "Wilcoxon signed-rank test"...Any tool that u have used ? –  Geek Sep 26 '12 at 8:20
    
@Geek: I put the on-line tool I used as a comment (The one starting with P.S). PythonXY also has it implemented as scipy.stats.wilcoxon –  amit Sep 26 '12 at 8:45

Recursion is NOT always slower than iteration. Quicksort is perfect example of it. The only way to do this in iterate way is create stack structure. So in other way do the same that the compiler do if we use recursion, and propably you will do this worse than compiler. Also there will be more jumps if you don't use recursion (to pop and push values to stack).

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Why do you have to jump in order to pop and push? –  Vitalij Zadneprovskij Sep 23 '12 at 19:56
    
If it's not inlined you (in most cases) need to call some functions, so it need to call. –  hauleth Sep 23 '12 at 20:12

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