How can I tell if a string repeats itself in Python?
Here are some benchmarks for the various answers to this question. There were some surprising results, including wildly different performance depending on the string being tested.
Some functions were modified to work with Python 3 (mainly by replacing / with // to ensure integer division). If you see something wrong, want to add your function, or want to add another test string, ping @ZeroPiraeus in the Python chatroom.
In summary: there's about a 50x difference between the best- and worst-performing solutions for the large set of example data supplied by OP here (via this comment). David Zhang's solution is the clear winner, outperforming all others by around 5x for the large example set.
A couple of the answers are very slow in extremely large "no match" cases. Otherwise, the functions seem to be equally matched or clear winners depending on the test.
Here are the results, including plots made using matplotlib and seaborn to show the different distributions:
Corpus 1 (supplied examples - small set)
mean performance:
0.0003 david_zhang
0.0009 zero
0.0013 antti
0.0013 tigerhawk_2
0.0015 carpetpython
0.0029 tigerhawk_1
0.0031 davidism
0.0035 saksham
0.0046 shashank
0.0052 riad
0.0056 piotr
median performance:
0.0003 david_zhang
0.0008 zero
0.0013 antti
0.0013 tigerhawk_2
0.0014 carpetpython
0.0027 tigerhawk_1
0.0031 davidism
0.0038 saksham
0.0044 shashank
0.0054 riad
0.0058 piotr
Corpus 2 (supplied examples - large set)
mean performance:
0.0006 david_zhang
0.0036 tigerhawk_2
0.0036 antti
0.0037 zero
0.0039 carpetpython
0.0052 shashank
0.0056 piotr
0.0066 davidism
0.0120 tigerhawk_1
0.0177 riad
0.0283 saksham
median performance:
0.0004 david_zhang
0.0018 zero
0.0022 tigerhawk_2
0.0022 antti
0.0024 carpetpython
0.0043 davidism
0.0049 shashank
0.0055 piotr
0.0061 tigerhawk_1
0.0077 riad
0.0109 saksham
Corpus 3 (edge cases)
mean performance:
0.0123 shashank
0.0375 david_zhang
0.0376 piotr
0.0394 carpetpython
0.0479 antti
0.0488 tigerhawk_2
0.2269 tigerhawk_1
0.2336 davidism
0.7239 saksham
3.6265 zero
6.0111 riad
median performance:
0.0107 tigerhawk_2
0.0108 antti
0.0109 carpetpython
0.0135 david_zhang
0.0137 tigerhawk_1
0.0150 shashank
0.0229 saksham
0.0255 piotr
0.0721 davidism
0.1080 zero
1.8539 riad
The tests and raw results are available here.
Here's a solution using regular expressions.
import re
REPEATER = re.compile(r"(.+?)\1+$")
def repeated(s):
match = REPEATER.match(s)
return match.group(1) if match else None
Iterating over the examples in the question:
examples = [
'0045662100456621004566210045662100456621',
'0072992700729927007299270072992700729927',
'001443001443001443001443001443001443001443',
'037037037037037037037037037037037037037037037',
'047619047619047619047619047619047619047619',
'002457002457002457002457002457002457002457',
'001221001221001221001221001221001221001221',
'001230012300123001230012300123001230012300123',
'0013947001394700139470013947001394700139470013947',
'001001001001001001001001001001001001001001001001001',
'001406469760900140646976090014064697609',
'004608294930875576036866359447',
'00469483568075117370892018779342723',
'004739336492890995260663507109',
'001508295625942684766214177978883861236802413273',
'007518796992481203',
'0071942446043165467625899280575539568345323741',
'0434782608695652173913',
'0344827586206896551724137931',
'002481389578163771712158808933',
'002932551319648093841642228739',
'0035587188612099644128113879',
'003484320557491289198606271777',
'00115074798619102416570771',
]
for e in examples:
sub = repeated(e)
if sub:
print("%r: %r" % (e, sub))
else:
print("%r does not repeat." % e)
... produces this output:
'0045662100456621004566210045662100456621': '00456621'
'0072992700729927007299270072992700729927': '00729927'
'001443001443001443001443001443001443001443': '001443'
'037037037037037037037037037037037037037037037': '037'
'047619047619047619047619047619047619047619': '047619'
'002457002457002457002457002457002457002457': '002457'
'001221001221001221001221001221001221001221': '001221'
'001230012300123001230012300123001230012300123': '00123'
'0013947001394700139470013947001394700139470013947': '0013947'
'001001001001001001001001001001001001001001001001001': '001'
'001406469760900140646976090014064697609': '0014064697609'
'004608294930875576036866359447' does not repeat.
'00469483568075117370892018779342723' does not repeat.
'004739336492890995260663507109' does not repeat.
'001508295625942684766214177978883861236802413273' does not repeat.
'007518796992481203' does not repeat.
'0071942446043165467625899280575539568345323741' does not repeat.
'0434782608695652173913' does not repeat.
'0344827586206896551724137931' does not repeat.
'002481389578163771712158808933' does not repeat.
'002932551319648093841642228739' does not repeat.
'0035587188612099644128113879' does not repeat.
'003484320557491289198606271777' does not repeat.
'00115074798619102416570771' does not repeat.
The regular expression (.+?)\1+$ is divided into three parts:
(.+?)is a matching group containing at least one (but as few as possible) of any character (because+?is non-greedy).\1+checks for at least one repetition of the matching group in the first part.$checks for the end of the string, to ensure that there's no extra, non-repeating content after the repeated substrings (and usingre.match()ensures that there's no non-repeating text before the repeated substrings).
In Python 3.4 and later, you could drop the $ and use re.fullmatch() instead, or (in any Python at least as far back as 2.3) go the other way and use re.search() with the regex ^(.+?)\1+$, all of which are more down to personal taste than anything else.
Here's a concise solution which avoids regular expressions and slow in-Python loops:
def principal_period(s):
i = (s+s).find(s, 1, -1)
return None if i == -1 else s[:i]
See the Community Wiki answer started by @davidism for benchmark results. In summary,
David Zhang's solution is the clear winner, outperforming all others by at least 5x for the large example set.
(That answer's words, not mine.)
This is based on the observation that a string is periodic if and only if it is equal to a nontrivial rotation of itself. Kudos to @AleksiTorhamo for realizing that we can then recover the principal period from the index of the first occurrence of s in (s+s)[1:-1], and for informing me of the optional start and end arguments of Python's string.find.
You can make the observation that for a string to be considered repeating, its length must be divisible by the length of its repeated sequence. Given that, here is a solution that generates divisors of the length from 1 to n / 2 inclusive, divides the original string into substrings with the length of the divisors, and tests the equality of the result set:
from math import sqrt, floor
def divquot(n):
if n > 1:
yield 1, n
swapped = []
for d in range(2, int(floor(sqrt(n))) + 1):
q, r = divmod(n, d)
if r == 0:
yield d, q
swapped.append((q, d))
while swapped:
yield swapped.pop()
def repeats(s):
n = len(s)
for d, q in divquot(n):
sl = s[0:d]
if sl * q == s:
return sl
return None
EDIT: In Python 3, the / operator has changed to do float division by default. To get the int division from Python 2, you can use the // operator instead. Thank you to @TigerhawkT3 for bringing this to my attention.
The // operator performs integer division in both Python 2 and Python 3, so I've updated the answer to support both versions. The part where we test to see if all the substrings are equal is now a short-circuiting operation using all and a generator expression.
UPDATE: In response to a change in the original question, the code has now been updated to return the smallest repeating substring if it exists and None if it does not. @godlygeek has suggested using divmod to reduce the number of iterations on the divisors generator, and the code has been updated to match that as well. It now returns all positive divisors of n in ascending order, exclusive of n itself.
Further update for high performance: After multiple tests, I've come to the conclusion that simply testing for string equality has the best performance out of any slicing or iterator solution in Python. Thus, I've taken a leaf out of @TigerhawkT3 's book and updated my solution. It's now over 6x as fast as before, noticably faster than Tigerhawk's solution but slower than David's.