Minimum rotations required to get the same string Last Updated : 25 Jul, 2022 Comments Improve Suggest changes Like Article Like Report Given a string, we need to find the minimum number of rotations required to get the same string. Examples: Input : s = "geeks" Output : 5 Input : s = "aaaa" Output : 1 The idea is based on below post.A Program to check if strings are rotations of each other or not Step 1 : Initialize result = 0 (Here result is count of rotations) Step 2 : Take a temporary string equals to original string concatenated with itself. Step 3 : Now take the substring of temporary string of size same as original string starting from second character (or index 1). Step 4 : Increase the count. Step 5 : Check whether the substring becomes equal to original string. If yes, then break the loop. Else go to step 2 and repeat it from the next index. Implementation: C++ // C++ program to determine minimum number // of rotations required to yield same // string. #include <iostream> using namespace std; // Returns count of rotations to get the // same string back. int findRotations(string str) { // tmp is the concatenated string. string tmp = str + str; int n = str.length(); for (int i = 1; i <= n; i++) { // substring from i index of original // string size. string substring = tmp.substr(i, str.size()); // if substring matches with original string // then we will come out of the loop. if (str == substring) return i; } return n; } // Driver code int main() { string str = "abc"; cout << findRotations(str) << endl; return 0; } Java // Java program to determine minimum number // of rotations required to yield same // string. import java.util.*; class GFG { // Returns count of rotations to get the // same string back. static int findRotations(String str) { // tmp is the concatenated string. String tmp = str + str; int n = str.length(); for (int i = 1; i <= n; i++) { // substring from i index of original // string size. String substring = tmp.substring( i, i+str.length()); // if substring matches with original string // then we will come out of the loop. if (str.equals(substring)) return i; } return n; } // Driver Method public static void main(String[] args) { String str = "aaaa"; System.out.println(findRotations(str)); } } /* This code is contributed by Mr. Somesh Awasthi */ Python3 # Python 3 program to determine minimum # number of rotations required to yield # same string. # Returns count of rotations to get the # same string back. def findRotations(str): # tmp is the concatenated string. tmp = str + str n = len(str) for i in range(1, n + 1): # substring from i index of # original string size. substring = tmp[i: i+n] # if substring matches with # original string then we will # come out of the loop. if (str == substring): return i return n # Driver code if __name__ == '__main__': str = "abc" print(findRotations(str)) # This code is contributed # by 29AjayKumar. C# // C# program to determine minimum number // of rotations required to yield same // string. using System; class GFG { // Returns count of rotations to get // the same string back. static int findRotations(String str) { // tmp is the concatenated string. String tmp = str + str; int n = str.Length; for (int i = 1; i <= n; i++) { // substring from i index of // original string size. String substring = tmp.Substring(i, str.Length); // if substring matches with // original string then we will // come out of the loop. if (str == substring) return i; } return n; } // Driver Method public static void Main() { String str = "abc"; Console.Write(findRotations(str)); } } // This code is contributed by nitin mittal. PHP <?php // PHP program to determine minimum // number of rotations required to // yield same string. // Returns count of rotations // to get the same string back. function findRotations($str) { // tmp is the concatenated string. $tmp = ($str + $str); $n = strlen($str); for ( $i = 1; $i <= $n; $i++) { // substring from i index // of original string size. $substring = $tmp.substr($i, strlen($str)); // if substring matches with // original string then we will // come out of the loop. if ($str == $substring) return $i; } return $n; } // Driver code $str = "abc"; echo findRotations($str), "\n"; // This code is contributed // by Sachin ?> JavaScript <script> // javascript program to determine minimum number // of rotations required to yield same // string. // Returns count of rotations to get the // same string back. function findRotations( str) { // tmp is the concatenated string. var tmp = str + str; var n = str.length; for (var i = 1; i <= n; i++) { // substring from i index of original // string size. var substring = tmp.substring(i ,str.length); // if substring matches with original string // then we will come out of the loop. if (str===(substring)) return i; } return n; } // Driver Method var str = "abc"; document.write(findRotations(str)); // This code contributed by gauravrajput1 </script> Output3 Time Complexity: O(n2)Auxiliary Space : O(n) We can solve this problem without using any temporary variable as extra space . We will traverse the original string and at each position we partition it and concatenate the right substring and left substring and check whether it is equal to original string Implementation: C++ // C++ program to determine minimum number // of rotations required to yield same // string. #include <iostream> using namespace std; // Returns count of rotations to get the // same string back. int findRotations(string str) { int ans = 0; //to store the answer int n = str.length(); //length of the string //All the length where we can partition for(int i=1;i<n-1;i++) { //right part + left part = rotated string // we are checking whether the rotated string is equal to //original string if(str.substr(i,n-i) + str.substr(0,i) == str) { ans = i; break; } } if(ans == 0) return n; return ans; } // Driver code int main() { string str = "abc"; cout << findRotations(str) << endl; return 0; } Java // Java program to determine minimum number // of rotations required to yield same // string. import java.util.*; class GFG { // Returns count of rotations to get the // same string back. static int findRotations(String str) { int ans = 0; //to store the answer int n = str.length(); //length of the string //All the length where we can partition for(int i=1;i<str.length()-1;i++) { //right part + left part = rotated string // we are checking whether the rotated string is equal to //original string if(str.substring(i, str.length()-i) + str.substring(0, i) == str) { ans = i; break; } } if(ans == 0) return n; return ans; } // Driver Method public static void main(String[] args) { String str = "abc"; System.out.println(findRotations(str)); } } // This code is contributed by Aarti_Rathi Python3 # Python program to determine minimum number # of rotations required to yield same # string. # Returns count of rotations to get the # same string back. def findRotations(Str): ans = 0 # to store the answer n = len(Str) # length of the String # All the length where we can partition for i in range(1 , len(Str) - 1): # right part + left part = rotated String # we are checking whether the rotated String is equal to # original String if(Str[i: n] + Str[0: i] == Str): ans = i break if(ans == 0): return n return ans # Driver code Str = "abc" print(findRotations(Str)) # This code is contributed by shinjanpatra C# // C# program to determine minimum number // of rotations required to yield same // string. using System; class GFG { // Returns count of rotations to get // the same string back. static int findRotations(String str) { int ans = 0; //to store the answer int n = str.Length; //length of the string //All the length where we can partition for(int i=1;i<str.Length-1;i++) { //right part + left part = rotated string // we are checking whether the rotated string is equal to //original string if(str.Substring(i,n-i) + str.Substring(0,i) == str) { ans = i; break; } } if(ans == 0) return n; return ans; } // Driver Method public static void Main() { String str = "abc"; Console.Write(findRotations(str)); } } // This code is contributed by Aarti_Rathi JavaScript <script> // JavaScript program to determine minimum number // of rotations required to yield same // string. // Returns count of rotations to get the // same string back. function findRotations(str) { let ans = 0; // to store the answer let n = str.length; // length of the string // All the length where we can partition for(let i = 1; i < str.length - 1; i++) { // right part + left part = rotated string // we are checking whether the rotated string is equal to // original string if(str.substr(i, n - i) + str.substr(0, i) == str) { ans = i; break; } } if(ans == 0) return n; return ans; } // Driver code let str = "abc"; document.write(findRotations(str),"</br>"); // This code is contributed by shinjanpatra </script> Output3 Time Complexity: O(n2)Auxiliary Space: O(1) Alternate Implementation in Python : C++ // C++ program to determine minimum // number of rotations required to yield // same string. #include <iostream> using namespace std; // Driver program int main() { string String = "aaaa"; string check = ""; for(int r = 1; r < String.length() + 1; r++) { // checking the input after each rotation check = String.substr(0, r) + String.substr(r, String.length()-r); // following if statement checks if input is // equals to check , if yes it will print r and // break out of the loop if(check == String){ cout<<r; break; } } return 0; } // This code is contributed by shinjanpatra Java /*package whatever //do not write package name here */ import java.io.*; class GFG { public static void main (String[] args) { String string = "aaaa"; String check = ""; for(int r = 1; r < string.length() + 1; r++) { // checking the input after each rotation check = string.substring(0, r) + string.substring(r, string.length()); // following if statement checks if input is // equals to check , if yes it will print r and // break out of the loop if(check.equals(string)){ System.out.println(r); break; } } } } Python3 # Python 3 program to determine minimum # number of rotations required to yield # same string. # input string = 'aaaa' check = '' for r in range(1, len(string)+1): # checking the input after each rotation check = string[r:] + string[:r] # following if statement checks if input is # equals to check , if yes it will print r and # break out of the loop if check == string: print(r) break # This code is contributed # by nagasowmyanarayanan. C# // C# program to determine minimum number // of rotations required to yield same // string. using System; class GFG { // Driver Method public static void Main() { String str = "aaaa"; String check = ""; for(int r = 1; r < str.Length + 1; r++) { // checking the input after each rotation check = str.Substring(0, r) + str.Substring(r, str.Length-r); // following if statement checks if input is // equals to check , if yes it will print r and // break out of the loop if(check == str){ Console.Write(r); break; } } } } // This code is contributed by Aarti_Rathi JavaScript <script> // JavaScript program to determine minimum // number of rotations required to yield // same string. // input let string = 'aaaa' let check = '' for(let r=1;r<string.length+1;r++){ // checking the input after each rotation check = string.substring(r) + string.substring(0,r) // following if statement checks if input is // equals to check , if yes it will print r and // break out of the loop if(check == string){ document.write(r) break } } // This code is contributed // by shinjanpatra </script> Output1 Time Complexity: O(n2), n as length of stringAuxiliary Space: O(n), n as length of string Comment More infoAdvertise with us Next Article Analysis of Algorithms F freaky.ju Improve Article Tags : DSA rotation Similar Reads Basics & PrerequisitesLogic Building ProblemsLogic building is about creating clear, step-by-step methods to solve problems using simple rules and principles. 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