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I have written a program to print all the permutations of the string using backtracking method.

# include <stdio.h>
/* Function to swap values at two pointers */
void swap (char *x, char *y)
    char temp;
    temp = *x;
    *x = *y;
    *y = temp;

/* Function to print permutations of string
   This function takes three parameters:
   1. String
   2. Starting index of the string
   3. Ending index of the string. */

void permute(char *a, int i, int n) 
   int j; 
   if (i == n)
     printf("%s\n", a);
        for (j = i; j <= n; j++)
              swap((a+i), (a+j));
              permute(a, i+1, n);
              swap((a+i), (a+j)); //backtrack

/* Driver program to test above functions */
int main()
   char a[] = "ABC";  
   permute(a, 0, 2);
   return 0;

What would be time complexity here.Isn't it o(n2).How to check the time complexity in case of recursion? Correct me if I am wrong.


share|improve this question
There are n! permutations of n elements, so the complexity is at least O(n!). – Daniel Fischer Jan 16 '13 at 7:03
for (j = i+1; j < n; j++) plus permute(a, 0, 3); in main() – wildplasser Jan 16 '13 at 11:14
I have given detailed explanation in C# here. Have a look at here. Did not noticed that I can comment here, so added this link in the below answer earlier. – Srigopal Chitrapu Oct 3 '14 at 3:37
up vote 3 down vote accepted

The complexity is O(N*N!), You have N! permutations, and you get all of them.
In addition, each permutation requires you to print it, which is O(N) - so totaling in O(N*N!)

share|improve this answer
permutation : O(N!) – kaitian Jan 16 '13 at 8:24
@kaitian: There are O(N!) permutations indeed, but the code also prints every one of those. Each is of length N, thus you need to write a string of length N for every permutation, which results in total time complexity of O(N * N!) – amit Jan 16 '13 at 8:25
yes, you are right~~~ what I want to say is that, complexity of permutations are always O(N!) even if you cut some branches off. C++ STL has achieved a non-recursive version called next_permutatin. By the way, N is very small for N! Haha – kaitian Jan 16 '13 at 8:30
It seems this isn't the complexity of that program - please see my answer below. – ringø Jan 17 '13 at 9:06
@ring0: The "answer below" ignore printf - no reason to do so, the program includes it. Each printf is O(N) - resulting in O(N * N!) run time. – amit Jan 17 '13 at 9:09

My answer is going to focus on methodology since that's what the explicit question is about. For the answer to this specific problem see others' answer such as amit's.

When you are trying to evaluate complexity on algorithms with recursion, you should start counting just as you would with an iterative one. However, when you encounter recursive calls, you don't know yet what the exact cost is. Just write the cost of the line as a function and still count the number of times it's going to run.

For example (Note that this code is dumb, it's just here for the example and does not do anything meaningful - feel free to edit and replace it with something better as long as it keeps the main point):

int f(int n){ //Note total cost as C(n)
  if(n==1) return 0; //Runs once, constant cost
  int i;
  int result = 0; //Runs once, constant cost
    int j;
    result += i; //Runs n times, constant cost
      result+=i*j; //Runs n^2 times, constant cost
  result+= f(n/2); //Runs once, cost C(n/2)
  return result;

Adding it up, you end up with a recursive formula like C(n) = n^2 + n + 1 + C(n/2) and C(1) = 1. The next step is to try and change it to bound it by a direct expression. From there depending on your formula you can apply many different mathematical tricks.

For our example:

For n>=2: C(n) <= 2n^2 + C(n/2)

since C is monotone, let's consider C'(p)= C(2^p): C'(p)<= 2*2^2p + C'(p-1)

which is a typical sum expression (not convenient to write here so let's skip to next step), that we can bound: C'(p)<=2p*2^2p + C'(0)

turning back to C(n)<=2*log(n)*n^2 + C(1)

Hence runtime in O(log n * n^2)

share|improve this answer
it helps.Thanks – starkk92 Jan 16 '13 at 11:52

The exact number of permutations via this program is (for a string of length N)

  • start : N p. starting each N-1 p. etc...
  • number of permutations is N + N(N-1) + N(N-1)(N-2) + ... + N(N-1)...(2) (ends with 2 since the next call just returns)
  • or N(1+(N-1)(1+(N-2)(1+(N-3)(1+...3(1+2)...))))

Which is roughly 2N!

Adding a counter in the for loop (removing the printf) matches the formula

  • N=3 : 9
  • N=4 : 40
  • N=5 : 205
  • N=6 : 1236 ...

The time complexity is O(N!)

share|improve this answer
No reason to ignore the printf, it is part of the program and each invokation of it is O(N). – amit Jan 17 '13 at 9:09
printf is an extension of the processing for each permutation. It is a linear process that doesn't grow by itself anywhere near N! when N grows. See the big O notation. – ringø Jan 17 '13 at 9:21
So? Note it is not O(N! + N), it is O(N! * N), Note that N!*N is asymptotically larger then N!, (lim (N->infinity) N!*N/N! = lim (N->infinity) N = infinity). By definition of big O, it means N!*N is NOT in O(N!). I do agree there are N! permutations of course, I disagree you can "ignore" the printf function from the analysis. – amit Jan 17 '13 at 9:24
So if an algorithm goes according to the function f(n) = n*n it's O(n²) but if each of its iteration does printf it's O(n³)? I don't think so. – ringø Jan 17 '13 at 9:28
It depends what it prints, if it prints something that its length is O(n) - then yes. How printf works? It iterates over all characters in the array/string and print each of them to screen, so inside your algorithm you have a function that iterates n more times. If this loop in the function is called n^2 times, you actually have n^3 operations. – amit Jan 17 '13 at 9:31

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