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In Python, how to check if a string only contains certain characters?

I need to check a string containing only a..z, 0..9, and . (period) and no other character.

I could iterate over each character and check the character is a..z or 0..9, or . but that would be slow.

I am not clear now how to do it with a regular expression.

Is this correct? Can you suggest a simpler regular expression or a more efficient approach.

#Valid chars . a-z 0-9 
def check(test_str):
    import re
    # returns None if no position in the string matches the pattern
    #pattern to search for any character other then . a-z 0-9
    pattern = r'[^\.a-z0-9]'
    if, test_str):
        #Character other then . a-z 0-9 was found
        print 'Invalid : %r' % (test_str,)
        #No character other then . a-z 0-9 was found
        print 'Valid   : %r' % (test_str,)


Valid   : "abcde.1"
Invalid : "abcde.1#"
Invalid : "ABCDE.12"
Invalid : "_-/>"!@#12345abcde<"
share|improve this question
Looks fine to me. You don't need the backslash before the . if you're in a character class, but that's only a one character saving ;) – chrispy Aug 24 '09 at 16:26
** YOU HAVE ACCEPTED A BUGGY ANSWER ** – John Machin Aug 25 '09 at 1:19
@Ingenutrix, John indeed found a bug in my answer. I think his solution is the best. – Nadia Alramli Aug 25 '09 at 13:00
Changed accepted answer from Nadia's to John Machin. – Yeah.Right. Aug 25 '09 at 16:30
up vote 16 down vote accepted

Final(?) edit

Answer, wrapped up in a function, with annotated interactive session:

>>> import re
>>> def special_match(strg, search=re.compile(r'[^a-z0-9.]').search):
...     return not bool(search(strg))
>>> special_match("")
>>> special_match("az09.")
>>> special_match("az09.\n")
# The above test case is to catch out any attempt to use re.match()
# with a `$` instead of `\Z` -- see point (6) below.
>>> special_match("az09.#")
>>> special_match("az09.X")

Note: There is a comparison with using re.match() further down in this answer. Further timings show that match() would win with much longer strings; match() seems to have a much larger overhead than search() when the final answer is True; this is puzzling (perhaps it's the cost of returning a MatchObject instead of None) and may warrant further rummaging.

==== Earlier text ====

The [previously] accepted answer could use a few improvements:

(1) Presentation gives the appearance of being the result of an interactive Python session:


but match() doesn't return True

(2) For use with match(), the ^ at the start of the pattern is redundant, and appears to be slightly slower than the same pattern without the ^

(3) Should foster the use of raw string automatically unthinkingly for any re pattern

(4) The backslash in front of the dot/period is redundant

(5) Slower than the OP's code!

prompt>rem OP's version -- NOTE: OP used raw string!

prompt>\python26\python -mtimeit -s"t='jsdlfjdsf12324..3432jsdflsdf';import
re;reg=re.compile(r'[^a-z0-9\.]')" "not bool("
1000000 loops, best of 3: 1.43 usec per loop

prompt>rem OP's version w/o backslash

prompt>\python26\python -mtimeit -s"t='jsdlfjdsf12324..3432jsdflsdf';import
re;reg=re.compile(r'[^a-z0-9.]')" "not bool("
1000000 loops, best of 3: 1.44 usec per loop

prompt>rem cleaned-up version of accepted answer

prompt>\python26\python -mtimeit -s"t='jsdlfjdsf12324..3432jsdflsdf';import
re;reg=re.compile(r'[a-z0-9.]+\Z')" "bool(reg.match(t))"
100000 loops, best of 3: 2.07 usec per loop

prompt>rem accepted answer

prompt>\python26\python -mtimeit -s"t='jsdlfjdsf12324..3432jsdflsdf';import
re;reg=re.compile('^[a-z0-9\.]+$')" "bool(reg.match(t))"
100000 loops, best of 3: 2.08 usec per loop

(6) Can produce the wrong answer!!

>>> import re
>>> bool(re.compile('^[a-z0-9\.]+$').match('1234\n'))
True # uh-oh
>>> bool(re.compile('^[a-z0-9\.]+\Z').match('1234\n'))
share|improve this answer
+1 Thanks for correcting my answer. I forgot that match checks for a match only at the beginning of the string. Ingenutrix, I think you should select this answer as accepted. – Nadia Alramli Aug 25 '09 at 12:59
WOW. Getting another solution after accepting one. @John Machin, thanks for taking this up. Could you please just put the final cleaned up solution at top of your post. All these different (though great posts) will probably be confusing for another newbie who comes here searching for the final solution. Please do not change or remove anything in your post, it is great to see your explanation thru your steps. They are very informative. Thanks. – Yeah.Right. Aug 25 '09 at 14:22
@Nadia: That was very gracious of you. Thanks! @Ingenutrix: Cleaned up as requested. – John Machin Aug 25 '09 at 15:41
Hopefully final! – Yeah.Right. Aug 25 '09 at 16:30

Here's a simple, pure-Python implementation. It should be used when performance is not critical (included for future Googlers).

import string
allowed = set(string.ascii_lowercase + string.digits + '.')

def check(test_str):
    set(test_str) <= allowed

Regarding performance, iteration will probably be the fastest method. Regexes have to iterate through a state machine, and the set equality solution has to build a temporary set. However, the difference is unlikely to matter much. If performance of this function is very important, write it as a C extension module with a switch statement (which will be compiled to a jump table).

Here's a C implementation, which uses if statements due to space constraints. If you absolutely need the tiny bit of extra speed, write out the switch-case. In my tests, it performs very well (2 seconds vs 9 seconds in benchmarks against the regex).

#include <Python.h>

static PyObject *check(PyObject *self, PyObject *args)
        const char *s;
        Py_ssize_t count, ii;
        char c;
        if (0 == PyArg_ParseTuple (args, "s#", &s, &count)) {
                return NULL;
        for (ii = 0; ii < count; ii++) {
                c = s[ii];
                if ((c < '0' && c != '.') || c > 'z') {
                if (c > '9' && c < 'a') {


PyDoc_STRVAR (DOC, "Fast stringcheck");
static PyMethodDef PROCEDURES[] = {
        {"check", (PyCFunction) (check), METH_VARARGS, NULL},
        {NULL, NULL}
initstringcheck (void) {
        Py_InitModule3 ("stringcheck", PROCEDURES, DOC);

Include it in your

from distutils.core import setup, Extension
ext_modules = [
    Extension ('stringcheck', ['stringcheck.c']),

Use as:

>>> from stringcheck import check
>>> check("abc")
>>> check("ABC")
share|improve this answer
@sth: Oh, of course. Sorry about that. – John Millikin Aug 24 '09 at 16:28
I can't say that I like downvoting a solution as a reaction to "it's slower than my/another solution". If it's wrong, downvoting makes sense. But even in "code golf" questions, any answer that's not the smallest doesn't get downvoted, it just won't get as many upvotes over time. – Adam V Aug 24 '09 at 17:22
@Adam, you are correct. I felt that I had to downvote it because unfortunately most users have the instinct to blindly upvote solutions just because they are on the top without reading others. Just look at Mark's solution which is obviously very slow – Nadia Alramli Aug 24 '09 at 17:28
@John Millikin: -1 Your solution doesn't check for '.' AND it fails if the input contains '\x00'. What was that about your cat? – John Machin Aug 25 '09 at 4:33
A failure would be if the function returned "true" for invalid text. An exception is unexpected, but does not allow execution to proceed along the code path for a correct string, and is thus not a failure. If data is pulled into the program from an external source, such as from a file or database, it is user input and should be checked before use. That includes checking that a string is valid UTF-8 (or whatever encoding is used for storage). – John Millikin Aug 25 '09 at 16:01

Simpler approach? A little more Pythonic?

>>> ok = "0123456789abcdef"
>>> all(c in ok for c in "123456abc")
>>> all(c in ok for c in "hello world")

It certainly isn't the most efficient, but it's sure readable.

share|improve this answer
ok = dict.fromkeys("012345789abcdef") might speed it up without hurting readability much. – J.F. Sebastian Aug 25 '09 at 22:21
@J.F.Sebastian: On my system the trick with dict.fromkeys and using a long and a short test-string it is only 1 to 3 % faster. (using python 3.3) – erik Jul 20 '15 at 23:11
@erik: use bytes.translate for speed. See the discussion in the comments and the performance comparison in the answer – J.F. Sebastian Jul 21 '15 at 2:57

EDIT: Changed the regular expression to exclude A-Z

Regular expression solution is the fastest pure python solution so far

>>> timeit.Timer("reg.match('jsdlfjdsf12324..3432jsdflsdf')", "import re; reg=re.compile('^[a-z0-9\.]+$')").timeit()

Compared to other solutions:

>>> timeit.Timer("set('jsdlfjdsf12324..3432jsdflsdf') <= allowed", "import string; allowed = set(string.ascii_lowercase + string.digits + '.')").timeit()
>>> timeit.Timer("all(c in allowed for c in 'jsdlfjdsf12324..3432jsdflsdf')", "import string; allowed = set(string.ascii_lowercase + string.digits + '.')").timeit()

If you want to allow empty strings then change it to:


Under request I'm going to return the other part of the answer. But please note that the following accept A-Z range.

You can use isalnum

test_str.replace('.', '').isalnum()

>>> 'test123.3'.replace('.', '').isalnum()
>>> 'test123-3'.replace('.', '').isalnum()

EDIT Using isalnum is much more efficient than the set solution

>>> timeit.Timer("'jsdlfjdsf12324..3432jsdflsdf'.replace('.', '').isalnum()").timeit()

EDIT2 John gave an example where the above doesn't work. I changed the solution to overcome this special case by using encode

test_str.replace('.', '').encode('ascii', 'replace').isalnum()

And it is still almost 3 times faster than the set solution

timeit.Timer("u'ABC\u0131\u0661'.encode('ascii', 'replace').replace('.','').isalnum()", "import string; allowed = set(string.ascii_lowercase + string.digits + '.')").timeit()

In my opinion using regular expressions is the best to solve this problem

share|improve this answer
Looks like this doesn't work properly: u"ABC\u0131\u0661".replace('.','').isalnum() -> True, but should be False for the OP's test – John Millikin Aug 24 '09 at 17:08
Very interesting! Thx for speed details btw, uppercase check should fail, but that is a minor issue >>> 'A.a'.lower().replace('.', '').isalnum() True Can you please update your non-encode, encode and regex solutions to exclude A-Z. (minor issue but you guys seem to be so way ahead on this then I am, I don't want to place .lower(). at wrong place and mess up the answer) My primary concern was to be sure my solution is correct but I am sure glad I posted the problem here as speed is very important. This check will be done a few million times, and having seen the speed results, it does matter! – Yeah.Right. Aug 24 '09 at 17:34
!! I think I was wrong about A.a'.lower().replace('.', '').isalnum()..this best left to you experts. – Yeah.Right. Aug 24 '09 at 17:36
@Ingenutrix, I updated the regular expression to exclude A-Z – Nadia Alramli Aug 24 '09 at 17:39
Nadia, your earlier detailed post was far more informative and educational, (even if it deviated a bit from the question). If you can restore it, please do. Just reading thru it helps newbies like me. – Yeah.Right. Aug 24 '09 at 17:59

Definitely looks correct; should be efficient too as it's early-out (as opposed to checking every letter to see if they are all valid, it finds the earliest invalid character).

share|improve this answer

This has already been answered satisfactorily, but for people coming across this after the fact, I have done some profiling of several different methods of accomplishing this. In my case I wanted uppercase hex digits, so modify as necessary to suit your needs.

Here are my test implementations:

import re

hex_digits = set("ABCDEF1234567890")
hex_match = re.compile(r'^[A-F0-9]+$')
hex_search = re.compile(r'[^A-F0-9]')

def test_set(input):
    return set(input) <= hex_digits

def test_not_any(input):
    return not any(c not in hex_digits for c in input)

def test_re_match1(input):
    return bool(re.compile(r'^[A-F0-9]+$').match(input))

def test_re_match2(input):
    return bool(hex_match.match(input))

def test_re_match3(input):
    return bool(re.match(r'^[A-F0-9]+$', input))

def test_re_search1(input):
    return not bool(re.compile(r'[^A-F0-9]').search(input))

def test_re_search2(input):
    return not bool(

def test_re_search3(input):
    return not bool(re.match(r'[^A-F0-9]', input))

And the tests, in Python 3.4.0 on Mac OS X:

import cProfile
import pstats
import random

# generate a list of 10000 random hex strings between 10 and 10009 characters long
# this takes a little time; be patient
tests = [ ''.join(random.choice("ABCDEF1234567890") for _ in range(l)) for l in range(10, 10010) ]

# set up profiling, then start collecting stats
test_pr = cProfile.Profile(timeunit=0.000001)

# run the test functions against each item in tests. 
# this takes a little time; be patient
for t in tests:
    for tf in [test_set, test_not_any, 
               test_re_match1, test_re_match2, test_re_match3,
               test_re_search1, test_re_search2, test_re_search3]:
        _ = tf(t)

# stop collecting stats

# we create our own pstats.Stats object to filter 
# out some stuff we don't care about seeing
test_stats = pstats.Stats(test_pr)

# normally, stats are printed with the format %8.3f, 
# but I want more significant digits
# so this monkey patch handles that
def _f8(x):
    return "%11.6f" % x

def _print_title(self):
    print('   ncalls     tottime     percall     cumtime     percall', end=' ',

pstats.f8 = _f8
pstats.Stats.print_title = _print_title

# sort by cumulative time (then secondary sort by name), ascending
# then print only our test implementation function calls:
test_stats.sort_stats('cumtime', 'name').reverse_order().print_stats("test_*")

which gave the following results:

         50335004 function calls in 13.428 seconds

   Ordered by: cumulative time, function name
   List reduced from 20 to 8 due to restriction 

   ncalls     tottime     percall     cumtime     percall filename:lineno(function)
    10000    0.005233    0.000001    0.367360    0.000037 :1(test_re_match2)
    10000    0.006248    0.000001    0.378853    0.000038 :1(test_re_match3)
    10000    0.010710    0.000001    0.395770    0.000040 :1(test_re_match1)
    10000    0.004578    0.000000    0.467386    0.000047 :1(test_re_search2)
    10000    0.005994    0.000001    0.475329    0.000048 :1(test_re_search3)
    10000    0.008100    0.000001    0.482209    0.000048 :1(test_re_search1)
    10000    0.863139    0.000086    0.863139    0.000086 :1(test_set)
    10000    0.007414    0.000001    9.962580    0.000996 :1(test_not_any)


The number of times that function was called
the total time spent in the given function, excluding time made to sub-functions
the quotient of tottime divided by ncalls
the cumulative time spent in this and all subfunctions
the quotient of cumtime divided by primitive calls

The columns we actually care about are cumtime and percall, as that shows us the actual time taken from function entry to exit. As we can see, regex match and search are not massively different.

It is faster not to bother compiling the regex if you would have compiled it every time. It is about 7.5% faster to compile once than every time, but only 2.5% faster to compile than to not compile.

test_set was twice as slow as re_search and thrice as slow as re_match

test_not_any was a full order of magnitude slower than test_set

TL;DR: Use re.match or

share|improve this answer

protected by Community May 21 '14 at 15:12

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