In Python, how do you find the number of digits in an integer?

1I don't understand your question. Did you mean the size of an integer? Do you want to find the number of digits? Please clarify. – batbrat Feb 3 '10 at 4:59
If you want the length of an integer as in the number of digits in the integer, you can always convert it to string like str(133)
and find its length like len(str(123))
.

19Of course, if you're looking for the number of digits, this will produce a result that's too large for negative numbers, since it will count the negative sign. – Chris Upchurch Feb 3 '10 at 5:03

39Hey, this is a slow solution. I did a factorial of a random 6 digit number, and found its length. This method took 95.891 seconds. And
Math.log10
method took only 7.486343383789062e05 seconds, approximately 1501388 times faster! – FadedCoder Mar 19 '17 at 16:30 
1This isn't just slow, but consumes way more memory and can cause trouble in large numbers. use
Math.log10
instead. – Peyman Mar 30 at 8:36
Without conversion to string
import math
digits = int(math.log10(n))+1
To also handle zero and negative numbers
import math
if n > 0:
digits = int(math.log10(n))+1
elif n == 0:
digits = 1
else:
digits = int(math.log10(n))+2 # +1 if you don't count the ''
You'd probably want to put that in a function :)
Here are some benchmarks. The len(str())
is already behind for even quite small numbers
timeit math.log10(2**8)
1000000 loops, best of 3: 746 ns per loop
timeit len(str(2**8))
1000000 loops, best of 3: 1.1 µs per loop
timeit math.log10(2**100)
1000000 loops, best of 3: 775 ns per loop
timeit len(str(2**100))
100000 loops, best of 3: 3.2 µs per loop
timeit math.log10(2**10000)
1000000 loops, best of 3: 844 ns per loop
timeit len(str(2**10000))
100 loops, best of 3: 10.3 ms per loop

5Using log10 for this is a mathematician's solution; using len(str()) is a programmer's solution, and is clearer and simpler. – Glenn Maynard Feb 3 '10 at 7:01

69@Glenn: I certainly hope you aren't implying this is a bad solution. The programmer's naive O(log10 n) solution works well in adhoc, prototyping code  but I'd much rather see mathematicians elegant O(1) solution in production code or a public API. +1 for gnibbler. – Juliet Feb 3 '10 at 8:48

5@gnibbler: +1. Never realized that log10 can be used to find the magnitude of a number. Wish I could upvote more then once :). – Abbas Dec 20 '10 at 18:10

15Hi! I go something strange, can Anyone of You please explain me why
int(math.log10(x)) +1
for99999999999999999999999999999999999999999999999999999999999999999999999
(71 nines) returns 72 ? I thought that I could rely on log10 method but I have to use len(str(x)) instead :( – Marecky Mar 4 '12 at 1:19 
6I believe i know the reason for the strange behaviour, it is due to floating point inaccuracies eg.
math.log10(999999999999999)
is equal to14.999999999999998
soint(math.log10(999999999999999))
becomes14
. But thenmath.log10(9999999999999999)
is equal to16.0
. Maybe usinground
is a solution to this problem. – jamylak Apr 6 '12 at 1:22
All math.log10 solutions will give you problems.
math.log10 is fast but gives problem when your number is greater than 999999999999997. This is because the float have too many .9s, causing the result to round up.
The solution is to use a while counter method for numbers above that threshold.
To make this even faster, create 10^16, 10^17 so on so forth and store as variables in a list. That way, it is like a table lookup.
def getIntegerPlaces(theNumber):
if theNumber <= 999999999999997:
return int(math.log10(theNumber)) + 1
else:
counter = 15
while theNumber >= 10**counter:
counter += 1
return counter

Thank you. That is a good counterexample for
math.log10
. It's interesting to see how binary representation flips the values giving mathematically incorrect result. – WloHu Aug 28 '18 at 12:31 

2

1"It is dangerous to rely on floatingpoint operations giving exact results"  Mark Dickinson, a member of core Python development team bugs.python.org/issue3724 – Sreeragh A R Jun 6 at 5:18
Python 2.*
int
s take either 4 or 8 bytes (32 or 64 bits), depending on your Python build. sys.maxint
(2**311
for 32bit ints, 2**631
for 64bit ints) will tell you which of the two possibilities obtains.
In Python 3, int
s (like long
s in Python 2) can take arbitrary sizes up to the amount of available memory; sys.getsizeof
gives you a good indication for any given value, although it does also count some fixed overhead:
>>> import sys
>>> sys.getsizeof(0)
12
>>> sys.getsizeof(2**99)
28
If, as other answers suggests, you're thinking about some string representation of the integer value, then just take the len
of that representation, be it in base 10 or otherwise!

Sorry this answer got minused. It is informative and to the plausible point of the question (if it were only more specific about which 'len' is desired). +1 – mjv Feb 3 '10 at 5:36

It's been several years since this question was asked, but I have compiled a benchmark of several methods to calculate the length of an integer.
def libc_size(i):
return libc.snprintf(buf, 100, c_char_p(b'%i'), i) # equivalent to `return snprintf(buf, 100, "%i", i);`
def str_size(i):
return len(str(i)) # Length of `i` as a string
def math_size(i):
return 1 + math.floor(math.log10(i)) # 1 + floor of log10 of i
def exp_size(i):
return int("{:.5e}".format(i).split("e")[1]) + 1 # e.g. `1e10` > `10` + 1 > 11
def mod_size(i):
return len("%i" % i) # Uses string modulo instead of str(i)
def fmt_size(i):
return len("{0}".format(i)) # Same as above but str.format
(the libc function requires some setup, which I haven't included)
size_exp
is thanks to Brian Preslopsky, size_str
is thanks to GeekTantra, and size_math
is thanks to John La Rooy
Here are the results:
Time for libc size: 1.2204 μs
Time for string size: 309.41 ns
Time for math size: 329.54 ns
Time for exp size: 1.4902 μs
Time for mod size: 249.36 ns
Time for fmt size: 336.63 ns
In order of speed (fastest first):
+ mod_size (1.000000x)
+ str_size (1.240835x)
+ math_size (1.321577x)
+ fmt_size (1.350007x)
+ libc_size (4.894290x)
+ exp_size (5.976219x)
(Disclaimer: the function is run on inputs 1 to 1,000,000)
Here are the results for sys.maxsize  100000
to sys.maxsize
:
Time for libc size: 1.4686 μs
Time for string size: 395.76 ns
Time for math size: 485.94 ns
Time for exp size: 1.6826 μs
Time for mod size: 364.25 ns
Time for fmt size: 453.06 ns
In order of speed (fastest first):
+ mod_size (1.000000x)
+ str_size (1.086498x)
+ fmt_size (1.243817x)
+ math_size (1.334066x)
+ libc_size (4.031780x)
+ exp_size (4.619188x)
As you can see, mod_size
(len("%i" % i)
) is the fastest, slightly faster than using str(i)
and significantly faster than others.

You really should include the libc setup,
libc = ctyle.CDLL('libc.so.6', use_errno=True)
(guessing this is it). And it doesn't work for numbers greater thansys.maxsize
because floating point numbers can't be "very large". So any number above that, I guess you're stuck with one of the slower methods. – Torxed Oct 27 '19 at 0:39
Let the number be n
then the number of digits in n
is given by:
math.floor(math.log10(n))+1
Note that this will give correct answers for +ve integers < 10e15. Beyond that the precision limits of the return type of math.log10
kicks in and the answer may be off by 1. I would simply use len(str(n))
beyond that; this requires O(log(n))
time which is same as iterating over powers of 10.
Thanks to @SetiVolkylany for bringing my attenstion to this limitation. Its amazing how seemingly correct solutions have caveats in implementation details.

1It does not work if n outside of range [999999999999997, 999999999999997] – PADYMKO Mar 11 '17 at 13:16

@SetiVolkylany, I tested it till 50 digits for python2.7 and 3.5. Just do a
assert list(range(1,51)) == [math.floor(math.log10(n))+1 for n in (10**e for e in range(50))]
. – BiGYaN Mar 12 '17 at 19:28 
2try it with the Python2.7 or the Python3.5
>>> math.floor(math.log10(999999999999997))+1 15.0 >>> math.floor(math.log10(999999999999998))+1 16.0
. Look my answer stackoverflow.com/a/42736085/6003870. – PADYMKO Mar 13 '17 at 9:11
Well, without converting to string I would do something like:
def lenDigits(x):
"""
Assumes int(x)
"""
x = abs(x)
if x < 10:
return 1
return 1 + lenDigits(x / 10)
Minimalist recursion FTW

1
As mentioned the dear user @Calvintwr, the function math.log10
has problem in a number outside of a range [999999999999997, 999999999999997], where we get floating point errors. I had this problem with the JavaScript (the Google V8 and the NodeJS) and the C (the GNU GCC compiler), so a 'purely mathematically'
solution is impossible here.
Based on this gist and the answer the dear user @Calvintwr
import math
def get_count_digits(number: int):
"""Return number of digits in a number."""
if number == 0:
return 1
number = abs(number)
if number <= 999999999999997:
return math.floor(math.log10(number)) + 1
count = 0
while number:
count += 1
number //= 10
return count
I tested it on numbers with length up to 20 (inclusive) and all right. It must be enough, because the length max integer number on a 64bit system is 19 (len(str(sys.maxsize)) == 19
).
assert get_count_digits(99999999999999999999) == 20
assert get_count_digits(10000000000000000000) == 20
assert get_count_digits(9999999999999999999) == 19
assert get_count_digits(1000000000000000000) == 19
assert get_count_digits(999999999999999999) == 18
assert get_count_digits(100000000000000000) == 18
assert get_count_digits(99999999999999999) == 17
assert get_count_digits(10000000000000000) == 17
assert get_count_digits(9999999999999999) == 16
assert get_count_digits(1000000000000000) == 16
assert get_count_digits(999999999999999) == 15
assert get_count_digits(100000000000000) == 15
assert get_count_digits(99999999999999) == 14
assert get_count_digits(10000000000000) == 14
assert get_count_digits(9999999999999) == 13
assert get_count_digits(1000000000000) == 13
assert get_count_digits(999999999999) == 12
assert get_count_digits(100000000000) == 12
assert get_count_digits(99999999999) == 11
assert get_count_digits(10000000000) == 11
assert get_count_digits(9999999999) == 10
assert get_count_digits(1000000000) == 10
assert get_count_digits(999999999) == 9
assert get_count_digits(100000000) == 9
assert get_count_digits(99999999) == 8
assert get_count_digits(10000000) == 8
assert get_count_digits(9999999) == 7
assert get_count_digits(1000000) == 7
assert get_count_digits(999999) == 6
assert get_count_digits(100000) == 6
assert get_count_digits(99999) == 5
assert get_count_digits(10000) == 5
assert get_count_digits(9999) == 4
assert get_count_digits(1000) == 4
assert get_count_digits(999) == 3
assert get_count_digits(100) == 3
assert get_count_digits(99) == 2
assert get_count_digits(10) == 2
assert get_count_digits(9) == 1
assert get_count_digits(1) == 1
assert get_count_digits(0) == 1
assert get_count_digits(1) == 1
assert get_count_digits(9) == 1
assert get_count_digits(10) == 2
assert get_count_digits(99) == 2
assert get_count_digits(100) == 3
assert get_count_digits(999) == 3
assert get_count_digits(1000) == 4
assert get_count_digits(9999) == 4
assert get_count_digits(10000) == 5
assert get_count_digits(99999) == 5
assert get_count_digits(100000) == 6
assert get_count_digits(999999) == 6
assert get_count_digits(1000000) == 7
assert get_count_digits(9999999) == 7
assert get_count_digits(10000000) == 8
assert get_count_digits(99999999) == 8
assert get_count_digits(100000000) == 9
assert get_count_digits(999999999) == 9
assert get_count_digits(1000000000) == 10
assert get_count_digits(9999999999) == 10
assert get_count_digits(10000000000) == 11
assert get_count_digits(99999999999) == 11
assert get_count_digits(100000000000) == 12
assert get_count_digits(999999999999) == 12
assert get_count_digits(1000000000000) == 13
assert get_count_digits(9999999999999) == 13
assert get_count_digits(10000000000000) == 14
assert get_count_digits(99999999999999) == 14
assert get_count_digits(100000000000000) == 15
assert get_count_digits(999999999999999) == 15
assert get_count_digits(1000000000000000) == 16
assert get_count_digits(9999999999999999) == 16
assert get_count_digits(10000000000000000) == 17
assert get_count_digits(99999999999999999) == 17
assert get_count_digits(100000000000000000) == 18
assert get_count_digits(999999999999999999) == 18
assert get_count_digits(1000000000000000000) == 19
assert get_count_digits(9999999999999999999) == 19
assert get_count_digits(10000000000000000000) == 20
assert get_count_digits(99999999999999999999) == 20
All example of codes tested with the Python 3.5
Count the number of digits w/o convert integer to a string:
x=123
x=abs(x)
i = 0
while x >= 10**i:
i +=1
# i is the number of digits
For posterity, no doubt by far the slowest solution to this problem:
def num_digits(num, number_of_calls=1):
"Returns the number of digits of an integer num."
if num == 0 or num == 1:
return 1 if number_of_calls == 1 else 0
else:
return 1 + num_digits(num/10, number_of_calls+1)
Assuming you are asking for the largest number you can store in an integer, the value is implementation dependent. I suggest that you don't think in that way when using python. In any case, quite a large value can be stored in a python 'integer'. Remember, Python uses duck typing!
Edit: I gave my answer before the clarification that the asker wanted the number of digits. For that, I agree with the method suggested by the accepted answer. Nothing more to add!
It can be done for integers quickly by using:
len(str(abs(1234567890)))
Which gets the length of the string of the absolute value of "1234567890"
abs
returns the number WITHOUT any negatives (only the magnitude of the number), str
casts/converts it to a string and len
returns the string length of that string.
If you want it to work for floats, you can use either of the following:
# Ignore all after decimal place
len(str(abs(0.1234567890)).split(".")[0])
# Ignore just the decimal place
len(str(abs(0.1234567890)))1
For future reference.

I think it would be simpler to truncate the input number itself (e. g. with a cast to
int
) than to truncate its decimal string representation:len(str(abs(int(0.1234567890))))
returns 1. – David Foerster Jul 12 '17 at 11:21 
No, that wouldn't work. If you turn 0.17 into an integer you get 0 and the length of that would be different to the length of 0.17 – Frogboxe Jul 12 '17 at 11:26

In the first case, by truncating everything from and including the decimal point off the string representation you're effectively calculating the length of the integral part of the number, which is what my suggestion does too. For 0.17 both solutions return 1. – David Foerster Jul 12 '17 at 11:32
Here is a bulky but fast version :
def nbdigit ( x ):
if x >= 10000000000000000 : # 17 
return len( str( x ))
if x < 100000000 : # 1  8
if x < 10000 : # 1  4
if x < 100 : return (x >= 10)+1
else : return (x >= 1000)+3
else: # 5  8
if x < 1000000 : return (x >= 100000)+5
else : return (x >= 10000000)+7
else: # 9  16
if x < 1000000000000 : # 9  12
if x < 10000000000 : return (x >= 1000000000)+9
else : return (x >= 100000000000)+11
else: # 13  16
if x < 100000000000000 : return (x >= 10000000000000)+13
else : return (x >= 1000000000000000)+15
Only 5 comparisons for not too big numbers.
On my computer it is about 30% faster than the math.log10
version and 5% faster than the len( str())
one.
Ok... no so attractive if you don't use it furiously.
And here is the set of numbers I used to test/measure my function:
n = [ int( (i+1)**( 17/7. )) for i in xrange( 1000000 )] + [0,10**161,10**16,10**16+1]
NB: it does not manage negative numbers, but the adaptation is easy...
Format in scientific notation and pluck off the exponent:
int("{:.5e}".format(1000000).split("e")[1]) + 1
I don't know about speed, but it's simple.
Please note the number of significant digits after the decimal (the "5" in the ".5e" can be an issue if it rounds up the decimal part of the scientific notation to another digit. I set it arbitrarily large, but could reflect the length of the largest number you know about.
def count_digit(number):
if number >= 10:
count = 2
else:
count = 1
while number//10 > 9:
count += 1
number = number//10
return count

While this code may solve the question, including an explanation of how and why this solves the problem would really help to improve the quality of your post, and probably result in more upvotes. Remember that you are answering the question for readers in the future, not just the person asking now. Please edit your answer to add explanations and give an indication of what limitations and assumptions apply. – Adrian Mole Apr 21 at 16:57
If you have to ask an user to give input and then you have to count how many numbers are there then you can follow this:
count_number = input('Please enter a number\t')
print(len(count_number))
Note: Never take an int as user input.

A rather specific case you describe here as it is actually related to the length of a string. Also, I could enter any nonnumeric character and you would still believe it is a number. – Ben May 1 at 18:01
My code for the same is as follows;i have used the log10 method:
from math import *
def digit_count(number):
if number>1 and round(log10(number))>=log10(number) and number%10!=0 :
return round(log10(number))
elif number>1 and round(log10(number))<log10(number) and number%10!=0:
return round(log10(number))+1
elif number%10==0 and number!=0:
return int(log10(number)+1)
elif number==1 or number==0:
return 1
I had to specify in case of 1 and 0 because log10(1)=0 and log10(0)=ND and hence the condition mentioned isn't satisfied. However, this code works only for whole numbers.
def digits(n)
count = 0
if n == 0:
return 1
if n < 0:
n *= 1
while (n >= 10**count):
count += 1
n += n%10
return count
print(digits(25)) # Should print 2
print(digits(144)) # Should print 3
print(digits(1000)) # Should print 4
print(digits(0)) # Should print 1
Top answers are saying mathlog10 faster but I got results that suggest len(str(n)) is faster.
arr = []
for i in range(5000000):
arr.append(random.randint(0,12345678901234567890))
%%timeit
for n in arr:
len(str(n))
//2.72 s ± 304 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
%%timeit
for n in arr:
int(math.log10(n))+1
//3.13 s ± 545 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
Besides, I haven't added logic to the math way to return accurate results and I can only imagine it slows it even more.
I have no idea how the previous answers proved the maths way is faster though.
>>> a=12345
>>> a.__str__().__len__()
5

6

8@ghostdog74 Just because there's an electrical socket, doesn't mean you have to stick your fingers in it. – user97370 Feb 3 '10 at 5:48

3so if you are so against it, why don't you tell me what's wrong with using it? – ghostdog74 Feb 3 '10 at 5:51

11"Magic" __ methods are there for Python internals to call back into, not for your code to call directly. It's the Hollywood Framework pattern: don't call us, we'll call you. But the intent of this framework is that these are magic methods for the standard Python builtins to make use of, so that your class can customize the behavior of the builtin. If it is a method for your code to call directly, give the method a non"__" name. This clearly separates those methods that are intended for programmer consumption, vs. those that are provided for callback from Python builtins. – PaulMcG Feb 3 '10 at 6:08

7It'sa bad idea because everyone else in the known universe uses str() and len(). This is being different for the sake of being different, which is inherently a bad thingnot to mention it's just ugly as hell. 1. – Glenn Maynard Feb 3 '10 at 7:04