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I'm fairly familiar with algorithm analysis and can tell the Big-O of most algorithms I work with. But I've been stuck for hours unable to come up with the Big-O for this code I write.

Basically it's a method to generate permutations for a string. It works by making each character in the string the first character and combine it with the permutations of the substring less that character (recursively).

If I put in the code to count the number of iterations, I've got something between O(N!) and O(N^N). But I couldn't figure out how to analyse it mentally. Any suggestion is much appreciated!

import java.util.ArrayList;
import java.util.List;

public class Permutation {

   int count = 0;

   List<String> findPermutations(String str) {
      List<String> permutations = new ArrayList<String>();
      if (str.length() <= 1) { 
         count++;
         permutations.add(str);
         return permutations;
      }
      for (int i = 0; i < str.length(); i++) {
         String sub = str.substring(0, i) + str.substring(i + 1);
         for (String permOfSub : findPermutations(sub)) {
            count++;
            permutations.add(str.charAt(i) + permOfSub);
         }
      }
      return permutations;
   }

   public static void main(String[] args) {
      for (String s : new String[] {"a", "ab", "abc", "abcd", "abcde", "abcdef", "abcdefg", "abcdefgh"}) {
         Permutation p = new Permutation();
         p.findPermutations(s);
         System.out.printf("Count %d vs N! %d%n", p.count, fact(s.length()));
      }
   }

   private static int fact(int i) {
      return i <= 1 ? i : i * fact(i-1);
   }
}

Edit 1: add test program

Edit 2: add count++ in base case

1 Answer 1

4

The recurrence equation: T(n) = n*(T(n-1) + (n-1)!), T(1) = 1 where n = str.length.

WolframAlfa says that the solution is n*(1)n i.e., n*n!.

The above assumes that all string operations are O(1). Otherwise if the cost of String sub = ... and permutations.add(str.charAt(i) + permOfSub) lines is considered O(n) then the equation is:

T(n+1)=(n+1)*(n + T(n) + n!*(n+1))

T(n) ~ (n*n+2*n-1)*n! i.e., O(n!*n*n)

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  • You are forgetting the +O(n) term at each level for iterating over the existing elements. This makes your answer off by a factor of n. Jul 11, 2012 at 4:24
  • Thanks, I've updated the question to include the test program. Basically I increase a count in the innermost loop and print out its value after completion vs N!. Turn out count is always exactly equal to N! * (N-1). For example of the string is 'abc', N! is 3x2x1 = 6, count is 12. I still can't figure out where the N-1 comes from.
    – auron
    Jul 11, 2012 at 4:31
  • BTW, thanks for pointing out WolframAlpha. I didn't know it could do that. So cool!
    – auron
    Jul 11, 2012 at 4:33
  • @templatetypedef: It is a habit from python to ignore cost of couple of functions that are implemented in C compared to the cost of pure Python loop
    – jfs
    Jul 11, 2012 at 4:41
  • @templatetypedef it's off by a factor of (n-1) as per my test program; I don't understand why that's the case though nor do I understand the logic behind your assertion that it's off by n. Can you help elaborate? Thank you!
    – auron
    Jul 11, 2012 at 4:41

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