12

Given a collection of distinct numbers, return all possible permutations.

For example, [1,2,3] have the following permutations:
[ [1,2,3], [1,3,2], [2,1,3], [2,3,1], [3,1,2], [3,2,1] ]

My Iterative Solution is :

public List<List<Integer>> permute(int[] nums) {
        List<List<Integer>> result = new ArrayList<>();
        result.add(new ArrayList<>());
        for(int i=0;i<nums.length;i++)
        {
            List<List<Integer>> temp = new ArrayList<>();
            for(List<Integer> a: result)
            {
                for(int j=0; j<=a.size();j++)
                {
                    a.add(j,nums[i]);
                    List<Integer> current = new ArrayList<>(a);
                    temp.add(current);
                    a.remove(j);
                }
            }
            result = new ArrayList<>(temp);
        }
        return result;
    }

My Recursive Solution is:

public List<List<Integer>> permuteRec(int[] nums) {
        List<List<Integer>> result = new ArrayList<List<Integer>>();
        if (nums == null || nums.length == 0) {
            return result;
        }
        makePermutations(nums, result, 0);
        return result;
    }


void makePermutations(int[] nums, List<List<Integer>> result, int start) {
    if (start >= nums.length) {
        List<Integer> temp = convertArrayToList(nums);
        result.add(temp);
    }
    for (int i = start; i < nums.length; i++) {
        swap(nums, start, i);
        makePermutations(nums, result, start + 1);
        swap(nums, start, i);
    }
}

private ArrayList<Integer> convertArrayToList(int[] num) {
        ArrayList<Integer> item = new ArrayList<Integer>();
        for (int h = 0; h < num.length; h++) {
            item.add(num[h]);
        }
        return item;
    }

According to me the time complexity(big-Oh) of my iterative solution is: n * n(n+1)/2~ O(n^3)
I am not able to figure out the time complexity of my recursive solution.
Can anyone explain complexity of both?

  • 3
    The number of permutations for n elements is n!, so an algorithm to produce all n! permutations would have time complexity O(n!). – rcgldr Jan 13 '17 at 5:15
  • for both recursion and iteration? – ojas Jan 13 '17 at 5:17
  • 1
    @OJASJUNEJA yes. It is the best conceivable runtime for this problem. Imagine if you have a magic generator that just spits out a permutation every 1 second. You would still need to wait n! seconds for this generator to finish because there are n! permutations. – nem035 Jan 13 '17 at 5:18
  • 1
    The method doesn't matter. For n sufficiently greater than k, then n! > k^n, so the time complexity is O(n!). One of the few expressions greater than n! is a double exponential, like n^(n^n). – rcgldr Jan 13 '17 at 5:25
  • The complexity is O(n!) == O(n**(n + 1/2)*exp(-n)) see en.wikipedia.org/wiki/Stirling's_approximation – Dmitry Bychenko Jan 13 '17 at 6:56
8

The recursive solution has a complexity of O(n!) as it is governed by the equation: T(n) = n * T(n-1) + O(1).

The iterative solution has three nested loops and hence has a complexity of O(n^3).

However, the iterative solution will not produce correct permutations for any number apart from 3.

For n = 3, you can see that n * (n - 1) * (n-2) = n!. The LHS is O(n^3) (or rather O(n^n) since n=3 here) and the RHS is O(n!).

For larger values of the size of the list, say n, you could have n nested loops and that will provide valid permutations. The complexity in that case will be O(n^n), and that is much larger than O(n!), or rather, n! < n^n. There is a rather nice relation called Stirling's approximation which explains this relation.

3

It's the output (which is huge) matters in this problem, not the routine's implementation. For n distinct items, there are n! permutations to be returned as the answer, and thus we have at least O(n!) complexity.

With a help of Stirling's approximation

 O(n!) = O(n^(1/2+n)/exp(n)) = O(sqrt(n) * (n/e)^n)

we can easily see, that O(n!) > O(n^c) for any constant c, that's why it doesn't matter if the implementation itself adds another O(n^3) since

 O(n!) + O(n^3) = O(n!)

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.