# Finding if a string is an iterative substring?

I have a string S. How can I find if the string follows S = nT.

Examples:
Function should return true if
1) S = "abab"
2) S = "abcdabcd"
3) S = "abcabcabc"
4) S = "zzxzzxzzx"

But if S="abcb" returns false.

I though maybe we can repeatedly call KMP on substrings of S and then decide.

eg: for "abab": call on KMP on "a". it returns 2(two instances). now 2*len("a")!=len(s)
call on KMP on "ab". it returns 2. now 2*len("ab")==len(s) so return true

Can you suggest any better algorithms?

-
Am I missing something, or is it faster to just try one substring per factor of `strlen(S)`? KMP doesn't find k substring matches any faster than you could call `memcmp` k times, I don't think it's useful here since we want to test for a particular substring at a particular position. –  Steve Jessop Jan 14 '11 at 22:56
Similar question: stackoverflow.com/questions/859739/duplicate-text-finding/… –  Crispy Jan 14 '11 at 22:57
It's a tricky one, great question :) –  biziclop Jan 14 '11 at 23:15
Every string follows the pattern, if `n` allowed to be 1. –  caf Jan 15 '11 at 6:20

I can think of a heuristic, only call KMP on a sub string if Len(original string)/Len of(sub string) is a positive integer.

Also the maximum length of the sub string has to be less than N/2.

## EDIT

Using these Heuristics Iwrote the follwing python code because my C is rusty at the moment

``````oldstr='ABCDABCD'

for i in xrange(0,len(oldstr)/2):
newslice=oldstr[0:i+1]
if newslice*(len(oldstr)/len(newslice)) == oldstr:
print 'pattern found', newslice
break
``````
-

You actually only need to care about testing substring lengths that are equal to the full string length divided by a prime number. The reason is: If S contains n copies of T, and n is not prime, then n = ab, and so S actually also contains a copies of bT (where "bT" means "T repeated b times"). This is an extension of anijhaw's answer.

``````int primes[] = { 2, 3, 5, 7, 11, 13, 17 };  /* There are one or two more... ;) */
int nPrimes = sizeof primes / sizeof primes[0];

/* Passing in the string length instead of assuming ASCIIZ strings means we
* don't have to modify the string in-place or allocate memory for new copies
* to handle recursion. */
int is_iterative(char *s, int len) {
int i, j;
for (i = 0; i < nPrimes && primes[i] < len; ++i) {
if (len % primes[i] == 0) {
int sublen = len / primes[i];
/* Is it possible that s consists of repeats of length sublen? */
for (j = sublen; j < len; j += sublen) {
if (memcmp(s, s + j, sublen)) {
break;
}
}

if (j == len) {
/* All length-sublen substrings are equal.  We could stop here
* (meaning e.g. "abababab" will report a correct, but
* non-minimal repeated substring of length 4), but let's
* recurse to see if an even shorter repeated substring
* can be found. */
return is_iterative(s, sublen);
}
}
}

return len;     /* Could not be broken into shorter, repeated substrings */
}
``````

Notice that when recursing to find even shorter repeated substrings, we don't need to check the entire string again, just the first larger repeat -- since we've already established that the remaining large repeats are, well, repeats of the first one. :)

-

I don't see that the KMP algorithm helps in this case. It is not a matter of determining where to begin the next match. It seems that one way to reduce the search time is to start with the longest possibility (half the length) and work downward. The only lengths that neeed to be tested are lengths that evenly divide into the total length. Here is an example in Ruby. I should add that I realize the question was tagged as `C`, but this was just a simple way to show the algorithm I was thinking about (and allowed me to test that it worked).

``````class String
def IsPattern( )
len = self.length
testlen = len / 2
# the fastest is to start with two entries and work down
while ( testlen > 0 )
# if this is not an even divisor then it can't fit the pattern
if ( len % testlen == 0 )
# evenly divides, so it may match
if ( self == self[0..testlen-1] * ( len / testlen ))
return true
end

end
testlen = testlen - 1
end
# must not have matched
false
end
end

if __FILE__ == \$0

ARGV.each do |str|
puts "%s, %s" % [str, str.IsPattern ? "true" : "false" ]
end

end

[C:\test]ruby patterntest.rb a aa abab abcdabcd abcabcabc zzxzzxzzx abcd
a, false
aa, true
abab, true
abcdabcd, true
abcabcabc, true
zzxzzxzzx, true
abcd, false
``````
-
Hey Mark, I used a similar idea, in the answer above perhaps you can check it out. Thanks –  anijhaw Jan 14 '11 at 23:52
@anijhaw, Indeed it is the same. I thought about the question while finishing up work. Then typed up the example and posted it. At the itme, I didn't see your example code. +1 –  Mark Wilkins Jan 15 '11 at 0:22

I suppose you could try the following algorithm:

Lets `L` to be a possible substring length which generates the original word. For `L` from `1` to `strlen(s)/2` check if the first character acquires in all `L*i` positions for `i` from 1 to `strlen(s)/L`. If it does then it could be a possible solution and you should check it with `memcmp`, if not try the next `L`. Of course you can skip some `L` values which are not dividing `strlen(s)`.

-

Try this:

``````    char s[] = "abcabcabcabc";
int nStringLength = strlen (s);
int nMaxCheckLength = nStringLength / 2;
int nThisOffset;
int nNumberOfSubStrings;
char cMustMatch;
char cCompare;
BOOL bThisSubStringLengthRepeats;
// Check all sub string lengths up to half the total length
for (int nSubStringLength = 1;  nSubStringLength <= nMaxCheckLength;  nSubStringLength++)
{
// How many substrings will there be?
nNumberOfSubStrings = nStringLength / nSubStringLength;

// Only check substrings that fit exactly
if (nSubStringLength * nNumberOfSubStrings == nStringLength)
{
// Assume it's going to be ok
bThisSubStringLengthRepeats = TRUE;

// check each character in substring
for (nThisOffset = 0;  nThisOffset < nSubStringLength;  nThisOffset++)
{
// What must it be?
cMustMatch = s [nThisOffset];

// check each substring's char in that position
for (int nSubString = 1;  nSubString < nNumberOfSubStrings;  nSubString++)
{
cCompare = s [(nSubString * nSubStringLength) + nThisOffset];
// Don't bother checking more if this doesn't match
if (cCompare != cMustMatch)
{
bThisSubStringLengthRepeats = FALSE;
break;
}
}

// Stop checking this substring
if (!bThisSubStringLengthRepeats)
{
break;
}
}

// We have found a match!
if (bThisSubStringLengthRepeats)
{
return TRUE;
}
}
}

// We went through the whole lot, but no matches found
return FALSE;
``````
-

This is Java code but you should get the idea:

``````        String str = "ababcababc";
int repPos = 0;
int repLen = 0;
for( int i = 0; i < str.length(); i++ ) {
if( repLen == 0 ) {
repLen = 1;
} else {
char c = str.charAt( i );
if( c == str.charAt( repPos ) ) {
repPos = ++repPos % repLen;
} else {
repLen = i+1;
}
}
}
``````

This will return the length of the shortest repeating chunk or the length of the string if there's no repetition.

-

You can build the suffix array of the string, sort it.
Now look for series of ever doubling suffixes and when you've reached one that's the size of the entire string (S) the first in the series will give you T.

For example:

``````abcd <-- T
abcdabcd <-- S
bcd
bcdabcd
cd
cdabcd
d
dabcd

x
xzzx
xzzxzzx
zx
zxzzx
zxzzxzzx
zzx <-- T
zzxzzx
zzxzzxzzx <-- S

a
apa
apapa
apapapa
pa <-- T
papa
papapa <-- Another T, not detected by this algo
papapapa <-- S
``````
-
What's the runtime complexity of this algorithm? Is it better than brute-force or iterated KMP? –  templatetypedef Jan 15 '11 at 6:47
@templatetypedef : assuming n = len(S) then: brute force is O(n^3), iterated KPM is O(n^2) and the above would be O(n^2logn + n^2) –  Eugen Constantin Dinca Jan 15 '11 at 7:59
@templatetypedef: as a side note I think this solution is a lot simpler to implement than KMP. –  Eugen Constantin Dinca Jan 18 '11 at 0:38