# Periodic Binary Strings

Is there any efficient algorithms to check whether a binary string is periodic or not?

Let S be a binary string and H be the set of sub strings of S. Then S is said to be periodic if it can be obtained by concatenating one or more times, at least one h in H, also h != S .

-
H can be the set of all prefixes p of S, with len(S) mod len(p) == 0. – chill Nov 24 '11 at 8:26
@chill Yes, doing like that we can reduce the size of H. – pkvprakash Nov 24 '11 at 8:32
we dont have to check for all the prefixes , but all prefixes p , with len(p)*2 = len(S) – pkvprakash Nov 24 '11 at 8:43
No, the period may be shorter, example "abababababab". – chill Nov 24 '11 at 8:49
In the above example when prefix length is 2 then we can determine the string as periodic. We don't have to go beyond 6. – pkvprakash Nov 24 '11 at 9:18

Initial string S with length Len. Double the string (really we need S + half of S). Search for occurrence of initial string S in doubled string SS, beginning from 2nd position, ending at Len/2 + 1. If such occurence exists with position P, then S is periodic with period P - 1.

S = abbaabbaabba Len = 12 SS = abbaabbaabbaabbaabbaabba

Searching from 2nd to 7th position, S found at P=5, period = 4

S = abaabaabaabb SS = abaabaabaabbabaabaabaabb

S doesn't occur in SS (except for 1 and L+1), no period exists

P.S. Note due to useful Venkatesh comment: We need to add minimal possible periodic unit, it's length is L/2 for even-size strings, and maximum divisor of L for odd-size strings (if length is prime number, string cannot be periodic). Simple factorization methods have O(N^1/2) complexity, more complex - O(N^1/4), so sometimes it is worth to factorize length to avoid unnecessary comparison of long strings.

-
it doesn't work for: 1110111011, where P=4 – Pentium10 Jan 22 '14 at 12:49
@Pentium10 Are you really observing 1110111011 substring at 4th position in <> part of <1110111011111011>1011 superstring? – MBo Jan 22 '14 at 17:15
No, but in this case the string to find is: 1110, that's what repeats itself. – Pentium10 Jan 22 '14 at 17:59
This problem assumes full (true? don't know exact term from stringology) periodicity S=(X)^n, rather than S=(X)^nY, because string should be obtained by concatenation pattern some times – MBo Jan 22 '14 at 18:29
@MBo if length of S is odd, Should I check from 2 to ceil(length / 2 + 1) or floor(length / 2 + 1) ? – Venkatesh Nov 17 '14 at 14:02

I'm pretty sure it is possible to improve on this, but I would have started by breaking the length of S (I'll call that L) to prime factors, and checking for a period of length of S/f for each prime factor f (len(h) must divide len(S) and I'm since not looking for the shortest possible h, prime L/len(h) is enough).

As to improvements, random check order would help in some circumstances (to prevent constructing input for worse case scenarios, etc.).

-

First of all for this to happen it's necessary that length(h) divides length(S).

If k = length(S)/length(h), then for a given k it's easy to check whether the string is periodic.

Indeed, it's periodic if the number represented by S is divisible by 100..0100..0...100..0. That's the number which is of length length(S), has k blocks of equal length and each block has only the highest bit set.

-
private static boolean isPeriodic(String string) {
int stringLength = string.length();
if (stringLength <= 1) {
return false;
}
boolean flag = true;

for (int i = 1; i <= stringLength / 2; i++) {
if (string.length() % i == 0) {
if (flag && i > 1) {
return flag;
}
flag = true;
for (int j = i; j < stringLength;) {

if ((j + i) <= stringLength) {

if (string.substring(0, i).equals(
string.substring(j, j + i))) {
j = j + i;
continue;
} else {
flag = false;
break;

}
} else {
break;
}

}
}

}
return flag;
}
-

Here is an implementation of a O(m + (n-1)) algorithm (where m is the input length, and n is the cycle length).

Based of the Knuth Morris Pratt algorithm, it iterates over the input string, checking to see if the substring input[0:i] is a repeated pattern. If it finds a character in the input string that isn't in the pattern, then i is updated to become the index of that character. This means characters in the string are not compared more than once.

public static String findSequence(String input) {
out: for (int i = 0; i < input.length();) {
for (int j = i; j < input.length(); j++) {
if(input.charAt(j % (i+1)) != input.charAt(j)) {
i = j;
continue out;
}
}
return (String) input.subSequence(0, i + 1);
}
return ""; // Impossible
}
-