Online algorithm for checking palindrome in a stream
Last Updated :
11 Feb, 2025
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Given a stream of characters (characters are received one by one), write a function that prints ‘Yes’ if a character makes the complete string palindrome, else prints ‘No’.
Examples:
Input: str[] = "abcba"
Output: a Yes // "a" is palindrome
b No // "ab" is not palindrome
c No // "abc" is not palindrome
b No // "abcb" is not palindrome
a Yes // "abcba" is palindrome
Input: str[] = "aabaacaabaa"
Output: a Yes // "a" is palindrome
a Yes // "aa" is palindrome
b No // "aab" is not palindrome
a No // "aaba" is not palindrome
a Yes // "aabaa" is palindrome
c No // "aabaac" is not palindrome
a No // "aabaaca" is not palindrome
a No // "aabaacaa" is not palindrome
b No // "aabaacaab" is not palindrome
a No // "aabaacaaba" is not palindrome
a Yes // "aabaacaabaa" is palindrome
Let input string be str[0..n-1].
A Simple Solution is to do following for every character str[i] in input string. Check if substring str[0…i] is palindrome, then print yes, else print no.
A Better Solution is to use the idea of Rolling Hash used in Rabin Karp algorithm. The idea is to keep track of reverse of first half and second half (we also use first half and reverse of second half) for every index. Below is complete algorithm.
1) The first character is always a palindrome, so print yes for
first character.
2) Initialize reverse of first half as "a" and second half as "b".
Let the hash value of first half reverse be 'firstr' and that of
second half be 'second'.
3) Iterate through string starting from second character, do following
for every character str[i], i.e., i varies from 1 to n-1.
a) If 'firstr' and 'second' are same, then character by character
check the substring ending with current character and print
"Yes" if palindrome.
Note that if hash values match, then strings need not be same.
For example, hash values of "ab" and "ba" are same, but strings
are different. That is why we check complete string after hash.
b) Update 'firstr' and 'second' for next iteration.
If 'i' is even, then add next character to the beginning of
'firstr' and end of second half and update
hash values.
If 'i' is odd, then keep 'firstr' as it is, remove leading
character from second and append a next
character at end.
Let us see all steps for example
string “abcba” Initial values of ‘firstr’ and ‘second’
firstr’ = hash(“a”), ‘second’ = hash(“b”) Start from second character, i.e., i = 1
- Compare ‘firstr’ and ‘second’, they don’t match, so print no.
- Calculate hash values for next iteration, i.e., i = 2
Since i is odd, ‘firstr’ is not changed and ‘second’ becomes hash(“c”) i = 2
- Compare ‘firstr’ and ‘second’, they don’t match, so print no.
- Calculate hash values for next iteration, i.e., i = 3
Since i is even, ‘firstr’ becomes hash(“ba”) and ‘second’ becomes hash(“cb”) i = 3
- Compare ‘first’ and ‘second’, they don’t match, so print no.
- Calculate hash values for next iteration, i.e., i = 4
Since i is odd, ‘firstr’ is not changed and ‘second’ becomes hash(“ba”) i = 4
- ‘firstr’ and ‘second’ match, compare the whole strings, they match, so print yes
- We don’t need to calculate next hash values as this is last index The idea of using rolling hashes is, next hash value can be calculated from previous in O(1) time by just doing some constant number of arithmetic operations. Below are the implementations of above approach.
// C++ program for online algorithm for palindrome checking
#include<bits/stdc++.h>
using namespace std;
// d is the number of characters in input alphabet
#define d 256
// q is a prime number used for evaluating Rabin Karp's Rolling hash
#define q 103
void checkPalindromes(string str)
{
// Length of input string
int N = str.size();
// A single character is always a palindrome
cout << str[0] << " Yes" << endl;
// Return if string has only one character
if (N == 1) return;
// Initialize first half reverse and second half for
// as firstr and second characters
int firstr = str[0] % q;
int second = str[1] % q;
int h = 1, i, j;
// Now check for palindromes from second character
// onward
for (i=1; i<N; i++)
{
// If the hash values of 'firstr' and 'second'
// match, then only check individual characters
if (firstr == second)
{
/* Check if str[0..i] is palindrome using
simple character by character match */
for (j = 0; j < i/2; j++)
{
if (str[j] != str[i-j])
break;
}
(j == i/2)? cout << str[i] << " Yes" << endl: cout << str[i] << " No" << endl;
}
else cout << str[i] << " No" << endl;
// Calculate hash values for next iteration.
// Don't calculate hash for next characters if
// this is the last character of string
if (i != N-1)
{
// If i is even (next i is odd)
if (i%2 == 0)
{
// Add next character after first half at beginning
// of 'firstr'
h = (h*d) % q;
firstr = (firstr + h*str[i/2])%q;
// Add next character after second half at the end
// of second half.
second = (second*d + str[i+1])%q;
}
else
{
// If next i is odd (next i is even) then we
// need not to change firstr, we need to remove
// first character of second and append a
// character to it.
second = (d*(second + q - str[(i+1)/2]*h)%q
+ str[i+1])%q;
}
}
}
}
/* Driver program to test above function */
int main()
{
string txt = "aabaacaabaa";
checkPalindromes(txt);
return 0;
}
// The code is contributed by Nidhi goel.
// C program for online algorithm for palindrome checking
#include<stdio.h>
#include<string.h>
// d is the number of characters in input alphabet
#define d 256
// q is a prime number used for evaluating Rabin Karp's Rolling hash
#define q 103
void checkPalindromes(char str[])
{
// Length of input string
int N = strlen(str);
// A single character is always a palindrome
printf("%c Yes\n", str[0]);
// Return if string has only one character
if (N == 1) return;
// Initialize first half reverse and second half for
// as firstr and second characters
int firstr = str[0] % q;
int second = str[1] % q;
int h = 1, i, j;
// Now check for palindromes from second character
// onward
for (i=1; i<N; i++)
{
// If the hash values of 'firstr' and 'second'
// match, then only check individual characters
if (firstr == second)
{
/* Check if str[0..i] is palindrome using
simple character by character match */
for (j = 0; j < i/2; j++)
{
if (str[j] != str[i-j])
break;
}
(j == i/2)? printf("%c Yes\n", str[i]):
printf("%c No\n", str[i]);
}
else printf("%c No\n", str[i]);
// Calculate hash values for next iteration.
// Don't calculate hash for next characters if
// this is the last character of string
if (i != N-1)
{
// If i is even (next i is odd)
if (i%2 == 0)
{
// Add next character after first half at beginning
// of 'firstr'
h = (h*d) % q;
firstr = (firstr + h*str[i/2])%q;
// Add next character after second half at the end
// of second half.
second = (second*d + str[i+1])%q;
}
else
{
// If next i is odd (next i is even) then we
// need not to change firstr, we need to remove
// first character of second and append a
// character to it.
second = (d*(second + q - str[(i+1)/2]*h)%q
+ str[i+1])%q;
}
}
}
}
/* Driver program to test above function */
int main()
{
char *txt = "aabaacaabaa";
checkPalindromes(txt);
getchar();
return 0;
}
// Java program for online algorithm for
// palindrome checking
public class GFG
{
// d is the number of characters in
// input alphabet
static final int d = 256;
// q is a prime number used for
// evaluating Rabin Karp's Rolling hash
static final int q = 103;
static void checkPalindromes(String str)
{
// Length of input string
int N = str.length();
// A single character is always a palindrome
System.out.println(str.charAt(0)+" Yes");
// Return if string has only one character
if (N == 1) return;
// Initialize first half reverse and second
// half for as firstr and second characters
int firstr = str.charAt(0) % q;
int second = str.charAt(1) % q;
int h = 1, i, j;
// Now check for palindromes from second
// character onward
for (i = 1; i < N; i++)
{
// If the hash values of 'firstr' and
// 'second' match, then only check
// individual characters
if (firstr == second)
{
/* Check if str[0..i] is palindrome
using simple character by character
match */
for (j = 0; j < i/2; j++)
{
if (str.charAt(j) != str.charAt(i
- j))
break;
}
System.out.println((j == i/2) ?
str.charAt(i) + " Yes": str.charAt(i)+
" No");
}
else System.out.println(str.charAt(i)+ " No");
// Calculate hash values for next iteration.
// Don't calculate hash for next characters
// if this is the last character of string
if (i != N - 1)
{
// If i is even (next i is odd)
if (i % 2 == 0)
{
// Add next character after first
// half at beginning of 'firstr'
h = (h * d) % q;
firstr = (firstr + h *str.charAt(i /
2)) % q;
// Add next character after second
// half at the end of second half.
second = (second * d + str.charAt(i +
1)) % q;
}
else
{
// If next i is odd (next i is even)
// then we need not to change firstr,
// we need to remove first character
// of second and append a character
// to it.
second = (d * (second + q - str.charAt(
(i + 1) / 2) * h) % q +
str.charAt(i + 1)) % q;
}
}
}
}
/* Driver program to test above function */
public static void main(String args[])
{
String txt = "aabaacaabaa";
checkPalindromes(txt);
}
}
// This code is contributed by Sumit Ghosh
# Python program Online algorithm for checking palindrome
# in a stream
# d is the number of characters in input alphabet
d = 256
# q is a prime number used for evaluating Rabin Karp's
# Rolling hash
q = 103
def checkPalindromes(string):
# Length of input string
N = len(string)
# A single character is always a palindrome
print string[0] + " Yes"
# Return if string has only one character
if N == 1:
return
# Initialize first half reverse and second half for
# as firstr and second characters
firstr = ord(string[0]) % q
second = ord(string[1]) % q
h = 1
i = 0
j = 0
# Now check for palindromes from second character
# onward
for i in xrange(1,N):
# If the hash values of 'firstr' and 'second'
# match, then only check individual characters
if firstr == second:
# Check if str[0..i] is palindrome using
# simple character by character match
for j in xrange(0,i/2):
if string[j] != string[i-j]:
break
j += 1
if j == i/2:
print string[i] + " Yes"
else:
print string[i] + " No"
else:
print string[i] + " No"
# Calculate hash values for next iteration.
# Don't calculate hash for next characters if
# this is the last character of string
if i != N-1:
# If i is even (next i is odd)
if i % 2 == 0:
# Add next character after first half at
# beginning of 'firstr'
h = (h*d) % q
firstr = (firstr + h*ord(string[i/2]))%q
# Add next character after second half at
# the end of second half.
second = (second*d + ord(string[i+1]))%q
else:
# If next i is odd (next i is even) then we
# need not to change firstr, we need to remove
# first character of second and append a
# character to it.
second = (d*(second + q - ord(string[(i+1)/2])*h)%q
+ ord(string[i+1]))%q
# Driver program
txt = "aabaacaabaa"
checkPalindromes(txt)
# This code is contributed by Bhavya Jain
// C# program for online algorithm for
// palindrome checking
using System;
class GFG
{
// d is the number of characters
// in input alphabet
public const int d = 256;
// q is a prime number used for
// evaluating Rabin Karp's Rolling hash
public const int q = 103;
public static void checkPalindromes(string str)
{
// Length of input string
int N = str.Length;
// A single character is always
// a palindrome
Console.WriteLine(str[0] + " Yes");
// Return if string has only
// one character
if (N == 1)
{
return;
}
// Initialize first half reverse and second
// half for as firstr and second characters
int firstr = str[0] % q;
int second = str[1] % q;
int h = 1, i, j;
// Now check for palindromes from
// second character onward
for (i = 1; i < N; i++)
{
// If the hash values of 'firstr'
// and 'second' match, then only
// check individual characters
if (firstr == second)
{
/* Check if str[0..i] is palindrome
using simple character by character
match */
for (j = 0; j < i / 2; j++)
{
if (str[j] != str[i - j])
{
break;
}
}
Console.WriteLine((j == i / 2) ? str[i] +
" Yes": str[i] + " No");
}
else
{
Console.WriteLine(str[i] + " No");
}
// Calculate hash values for next iteration.
// Don't calculate hash for next characters
// if this is the last character of string
if (i != N - 1)
{
// If i is even (next i is odd)
if (i % 2 == 0)
{
// Add next character after first
// half at beginning of 'firstr'
h = (h * d) % q;
firstr = (firstr + h * str[i / 2]) % q;
// Add next character after second
// half at the end of second half.
second = (second * d + str[i + 1]) % q;
}
else
{
// If next i is odd (next i is even)
// then we need not to change firstr,
// we need to remove first character
// of second and append a character
// to it.
second = (d * (second + q - str[(i + 1) / 2] *
h) % q + str[i + 1]) % q;
}
}
}
}
// Driver Code
public static void Main(string[] args)
{
string txt = "aabaacaabaa";
checkPalindromes(txt);
}
}
// This code is contributed by Shrikant13
// JavaScript program to check palindromic prefixes
// Function for checking palindromic prefixes
function checkPalindromes(str) {
// d is the number of characters in input alphabet
var d = 256;
// q is a prime number used for evaluating Rabin-Karp's Rolling hash
var q = 103;
var n = str.length;
console.log(str.charAt(0) + " Yes");
if (n == 1) {
return;
}
// Initialize first half reverse and second half for as firstr and second characters
var firstr = str.charCodeAt(0) % q;
var second = str.charCodeAt(1) % q;
var h = 1, i, j;
// Now check for palindromes from second character onward
for (var i = 1; i < n; i++) {
// If the hash values of 'firstr' and 'second' match, then check individual characters
if (firstr === second) {
// Check if str[0..i] is palindrome using simple character-by-character match
for (j = 0; j < i / 2; j++) {
if (str.charAt(j) !== str.charAt(i - j)) {
break;
}
}
console.log((j === Math.floor(i / 2)) ? str.charAt(i) + " Yes" : str.charAt(i) + " No");
} else {
console.log(str.charAt(i) + " No");
}
// Calculate hash values for the next iteration.
if (i !== n - 1) {
// If i is even (next i is odd)
if (i % 2 === 0) {
// Add next character after first half at beginning of 'firstr'
h = (h * d) % q;
firstr = (firstr + h * str.charCodeAt(i / 2)) % q;
// Add next character after second half at the end of second half.
second = (second * d + str.charCodeAt(i + 1)) % q;
} else {
// If next i is odd (next i is even)
// then we need not change firstr,
// we need to remove first character of second and append a character to it.
second = (d * (second + q - str.charCodeAt((i + 1) / 2) * h) % q +
str.charCodeAt(i + 1)) % q;
}
}
}
}
// Driver code
var txt = "aabaacaabaa";
checkPalindromes(txt);
<?php
// PHP program to delete elements from array.
// Function for deleting k elements
function checkPalindromes($str) {
// d is the number of characters in the input alphabet
$d = 256;
// q is a prime number used for evaluating Rabin Karp's Rolling hash
$q = 103;
$n = strlen($str);
echo $str[0] . " Yes\n";
if ($n == 1) {
return;
}
// Initialize first half reverse and second
// half for as firstr and second characters
$firstr = ord($str[0]) % $q;
$second = ord($str[1]) % $q;
$h = 1;
$i = 0;
$j = 0;
// Now check for palindromes from second
// character onward
for ($i = 1; $i < $n; $i++) {
// If the hash values of 'firstr' and 'second'
// match, then only check individual characters
if ($firstr == $second) {
// Check if str[0..i] is palindrome
// using simple character by character match
for ($j = 0; $j < $i / 2; $j++) {
if ($str[$j] != $str[$i - $j]) {
break;
}
}
if ($j == $i / 2) {
echo $str[$i] . " Yes\n";
} else {
echo $str[$i] . " No\n";
}
} else {
echo $str[$i] . " No\n";
}
// Calculate hash values for the next iteration.
// Don't calculate the hash for the next characters
// if this is the last character of the string
if ($i != $n - 1) {
// If i is even (next i is odd)
if ($i % 2 == 0) {
// Add the next character after the first
// half at the beginning of 'firstr'
$h = ($h * $d) % $q;
$firstr = ($firstr + $h * ord($str[$i / 2])) % $q;
// Add the next character after the second
// half at the end of the second half.
$second = ($second * $d + ord($str[$i + 1])) % $q;
} else {
// If next i is odd (next i is even)
// then we need not change firstr,
// we need to remove the first character
// of the second and append a character to it.
$second = ($d * ($second + $q - ord($str[($i + 1) / 2]) * $h) % $q
+ ord($str[$i + 1])) % $q;
}
}
}
}
// Driver code
$txt = "aabaacaabaa";
checkPalindromes($txt);
?>
Output
a Yes a Yes b No a No a Yes c No a No a No b No a No a Yes
The worst case time complexity of the above solution remains O(n*n), but in general, it works much better than simple approach as we avoid complete substring comparison most of the time by first comparing hash values.
The worst case occurs for input strings with all same characters like “aaaaaa”.
Space Complexity: O(1)
The algorithm uses a fixed number of variables (which is independent of the size of the input string). Hence, the space complexity of the algorithm is O(1).
