How do I print an integer with commas as thousands separators?
1234567 ⟶ 1,234,567
It does not need to be locale-specific to decide between periods and commas.
_
as the thousand separatorf'{value:_}' # For Python ≥3.6
,
as the thousand separator'{:,}'.format(value) # For Python ≥2.7
f'{value:,}' # For Python ≥3.6
import locale
locale.setlocale(locale.LC_ALL, '') # Use '' for auto, or force e.g. to 'en_US.UTF-8'
'{:n}'.format(value) # For Python ≥2.7
f'{value:n}' # For Python ≥3.6
Per Format Specification Mini-Language,
The
','
option signals the use of a comma for a thousands separator. For a locale aware separator, use the'n'
integer presentation type instead.
and:
The
'_'
option signals the use of an underscore for a thousands separator for floating point presentation types and for integer presentation type'd'
. For integer presentation types'b'
,'o'
,'x'
, and'X'
, underscores will be inserted every 4 digits.
f"{2 ** 64 - 1:,}"
Commented
Apr 19, 2017 at 15:03
I'm surprised that no one has mentioned that you can do this with f-strings in Python 3.6+ as easy as this:
>>> num = 10000000
>>> print(f"{num:,}")
10,000,000
... where the part after the colon is the format specifier. The comma is the separator character you want, so f"{num:_}"
uses underscores instead of a comma. Only "," and "_" is possible to use with this method.
This is equivalent of using format(num, ",")
for older versions of python 3.
This might look like magic when you see it the first time, but it's not. It's just part of the language, and something that's commonly needed enough to have a shortcut available. To read more about it, have a look at the group subcomponent.
str.format()
which works on all versions of python3, is almost as easy and doesn't use f-strings
I got this to work:
>>> import locale
>>> locale.setlocale(locale.LC_ALL, 'en_US')
'en_US'
>>> locale.format_string("%d", 1255000, grouping=True)
'1,255,000'
Sure, you don't need internationalization support, but it's clear, concise, and uses a built-in library.
P.S. That "%d" is the usual %-style formatter. You can have only one formatter, but it can be whatever you need in terms of field width and precision settings.
P.P.S. If you can't get locale
to work, I'd suggest a modified version of Mark's answer:
def intWithCommas(x):
if type(x) not in [type(0), type(0L)]:
raise TypeError("Parameter must be an integer.")
if x < 0:
return '-' + intWithCommas(-x)
result = ''
while x >= 1000:
x, r = divmod(x, 1000)
result = ",%03d%s" % (r, result)
return "%d%s" % (x, result)
Recursion is useful for the negative case, but one recursion per comma seems a bit excessive to me.
P.P.P.S. Older Pythons used format
instead of format_string
.
locale
, I use as little of it as I can.
Commented
Nov 30, 2009 at 23:32
setlocale
to use the default, which hopefully will be appropriate.
Commented
Nov 30, 2009 at 23:49
For inefficiency and unreadability it's hard to beat:
>>> import itertools
>>> s = '-1234567'
>>> ','.join(["%s%s%s" % (x[0], x[1] or '', x[2] or '') for x in itertools.izip_longest(s[::-1][::3], s[::-1][1::3], s[::-1][2::3])])[::-1].replace('-,','-')
lambda x: (lambda s: ','.join(["%s%s%s" % (x[0], x[1] or '', x[2] or '') for x in itertools.izip_longest(s[::-1][::3], s[::-1][1::3], s[::-1][2::3])])[::-1].replace('-,','-'))(str(x))
just to keep the obfuscation theme.
Here is the locale grouping code after removing irrelevant parts and cleaning it up a little:
(The following only works for integers)
def group(number):
s = '%d' % number
groups = []
while s and s[-1].isdigit():
groups.append(s[-3:])
s = s[:-3]
return s + ','.join(reversed(groups))
>>> group(-23432432434.34)
'-23,432,432,434'
There are already some good answers in here. I just want to add this for future reference. In python 2.7 there is going to be a format specifier for thousands separator. According to python docs it works like this
>>> '{:20,.2f}'.format(f)
'18,446,744,073,709,551,616.00'
In python3.1 you can do the same thing like this:
>>> format(1234567, ',d')
'1,234,567'
{:15,d}'.format(len(SortedList))
which worked perfectly.
Commented
Jul 25, 2020 at 1:15
Here's a one-line regex replacement:
re.sub("(\d)(?=(\d{3})+(?!\d))", r"\1,", "%d" % val)
Works only for inegral outputs:
import re
val = 1234567890
re.sub("(\d)(?=(\d{3})+(?!\d))", r"\1,", "%d" % val)
# Returns: '1,234,567,890'
val = 1234567890.1234567890
# Returns: '1,234,567,890'
Or for floats with less than 4 digits, change the format specifier to %.3f
:
re.sub("(\d)(?=(\d{3})+(?!\d))", r"\1,", "%.3f" % val)
# Returns: '1,234,567,890.123'
NB: Doesn't work correctly with more than three decimal digits as it will attempt to group the decimal part:
re.sub("(\d)(?=(\d{3})+(?!\d))", r"\1,", "%.5f" % val)
# Returns: '1,234,567,890.12,346'
Let's break it down:
re.sub(pattern, repl, string)
pattern = \
"(\d) # Find one digit...
(?= # that is followed by...
(\d{3})+ # one or more groups of three digits...
(?!\d) # which are not followed by any more digits.
)",
repl = \
r"\1,", # Replace that one digit by itself, followed by a comma,
# and continue looking for more matches later in the string.
# (re.sub() replaces all matches it finds in the input)
string = \
"%d" % val # Format the string as a decimal to begin with
This is what I do for floats. Although, honestly, I'm not sure which versions it works for - I'm using 2.7:
my_number = 4385893.382939491
my_string = '{:0,.2f}'.format(my_number)
Returns: 4,385,893.38
Update: I recently had an issue with this format (couldn't tell you the exact reason), but was able to fix it by dropping the 0
:
my_string = '{:,.2f}'.format(my_number)
You can also use '{:n}'.format( value )
for a locale representation. I think this is the simpliest way for a locale solution.
For more information, search for thousands
in Python DOC.
For currency, you can use locale.currency
, setting the flag grouping
:
Code
import locale
locale.setlocale( locale.LC_ALL, '' )
locale.currency( 1234567.89, grouping = True )
Output
'Portuguese_Brazil.1252'
'R$ 1.234.567,89'
Slightly expanding the answer of Ian Schneider:
If you want to use a custom thousands separator, the simplest solution is:
'{:,}'.format(value).replace(',', your_custom_thousands_separator)
'{:,.2f}'.format(123456789.012345).replace(',', ' ')
If you want the German representation like this, it gets a bit more complicated:
('{:,.2f}'.format(123456789.012345)
.replace(',', ' ') # 'save' the thousands separators
.replace('.', ',') # dot to comma
.replace(' ', '.')) # thousand separators to dot
'{:_.2f}'.format(12345.6789).replace('.', ',').replace('_', '.')
UPDATING: I'm sure there must be a standard library function for this, but it was fun to try to write it myself using recursion so here's what I came up with:
sep = ',' # some countries has '.' and Python 3 sees as float
if type(x) is not int and type(x) is not float:
raise TypeError("Not an number!")
if x < 0:
return '-' + intToStringWithCommas(-x)
elif x < 1000:
return str(x)
else:
return intToStringWithCommas(x / 1000) + sep + '%03d' % (x % 1000)
Having said that, if someone else does find a standard way to do it, you should use that instead.
From the comments to activestate recipe 498181 I reworked this:
import re
def thous(x, sep=',', dot='.'):
num, _, frac = str(x).partition(dot)
num = re.sub(r'(\d{3})(?=\d)', r'\1'+sep, num[::-1])[::-1]
if frac:
num += dot + frac
return num
It uses the regular expressions feature: lookahead i.e. (?=\d)
to make sure only groups of three digits that have a digit 'after' them get a comma. I say 'after' because the string is reverse at this point.
[::-1]
just reverses a string.
--
Integers (without decimal):
"{:,d}".format(1234567)
--
Floats (with decimal):
"{:,.2f}".format(1234567)
where the number before f
specifies the number of decimal places.
--
Bonus
Quick-and-dirty starter function for the Indian lakhs/crores numbering system (12,34,567):
from Python version 2.6 you can do this:
def format_builtin(n):
return format(n, ',')
For Python versions < 2.6 and just for your information, here are 2 manual solutions, they turn floats to ints but negative numbers work correctly:
def format_number_using_lists(number):
string = '%d' % number
result_list = list(string)
indexes = range(len(string))
for index in indexes[::-3][1:]:
if result_list[index] != '-':
result_list.insert(index+1, ',')
return ''.join(result_list)
few things to notice here:
And a more hardcore version:
def format_number_using_generators_and_list_comprehensions(number):
string = '%d' % number
generator = reversed(
[
value+',' if (index!=0 and value!='-' and index%3==0) else value
for index,value in enumerate(reversed(string))
]
)
return ''.join(generator)
I am a Python beginner, but an experienced programmer. I have Python 3.5, so I can just use the comma, but this is nonetheless an interesting programming exercise. Consider the case of an unsigned integer. The most readable Python program for adding thousands separators appears to be:
def add_commas(instr):
out = [instr[0]]
for i in range(1, len(instr)):
if (len(instr) - i) % 3 == 0:
out.append(',')
out.append(instr[i])
return ''.join(out)
It is also possible to use a list comprehension:
add_commas(instr):
rng = reversed(range(1, len(instr) + (len(instr) - 1)//3 + 1))
out = [',' if j%4 == 0 else instr[-(j - j//4)] for j in rng]
return ''.join(out)
This is shorter, and could be a one liner, but you will have to do some mental gymnastics to understand why it works. In both cases we get:
for i in range(1, 11):
instr = '1234567890'[:i]
print(instr, add_commas(instr))
1 1
12 12
123 123
1234 1,234
12345 12,345
123456 123,456
1234567 1,234,567
12345678 12,345,678
123456789 123,456,789
1234567890 1,234,567,890
The first version is the more sensible choice, if you want the program to be understood.
Here's one that works for floats too:
def float2comma(f):
s = str(abs(f)) # Convert to a string
decimalposition = s.find(".") # Look for decimal point
if decimalposition == -1:
decimalposition = len(s) # If no decimal, then just work from the end
out = ""
for i in range(decimalposition+1, len(s)): # do the decimal
if not (i-decimalposition-1) % 3 and i-decimalposition-1: out = out+","
out = out+s[i]
if len(out):
out = "."+out # add the decimal point if necessary
for i in range(decimalposition-1,-1,-1): # working backwards from decimal point
if not (decimalposition-i-1) % 3 and decimalposition-i-1: out = ","+out
out = s[i]+out
if f < 0:
out = "-"+out
return out
Usage Example:
>>> float2comma(10000.1111)
'10,000.111,1'
>>> float2comma(656565.122)
'656,565.122'
>>> float2comma(-656565.122)
'-656,565.122'
One liner for Python 2.5+ and Python 3 (positive int only):
''.join(reversed([x + (',' if i and not i % 3 else '') for i, x in enumerate(reversed(str(1234567)))]))
I'm using python 2.5 so I don't have access to the built-in formatting.
I looked at the Django code intcomma (intcomma_recurs in code below) and realized it's inefficient, because it's recursive and also compiling the regex on every run is not a good thing either. This is not necessary an 'issue' as django isn't really THAT focused on this kind of low-level performance. Also, I was expecting a factor of 10 difference in performance, but it's only 3 times slower.
Out of curiosity I implemented a few versions of intcomma to see what the performance advantages are when using regex. My test data concludes a slight advantage for this task, but surprisingly not much at all.
I also was pleased to see what I suspected: using the reverse xrange approach is unnecessary in the no-regex case, but it does make the code look slightly better at the cost of ~10% performance.
Also, I assume what you're passing in is a string and looks somewhat like a number. Results undetermined otherwise.
from __future__ import with_statement
from contextlib import contextmanager
import re,time
re_first_num = re.compile(r"\d")
def intcomma_noregex(value):
end_offset, start_digit, period = len(value),re_first_num.search(value).start(),value.rfind('.')
if period == -1:
period=end_offset
segments,_from_index,leftover = [],0,(period-start_digit) % 3
for _index in xrange(start_digit+3 if not leftover else start_digit+leftover,period,3):
segments.append(value[_from_index:_index])
_from_index=_index
if not segments:
return value
segments.append(value[_from_index:])
return ','.join(segments)
def intcomma_noregex_reversed(value):
end_offset, start_digit, period = len(value),re_first_num.search(value).start(),value.rfind('.')
if period == -1:
period=end_offset
_from_index,segments = end_offset,[]
for _index in xrange(period-3,start_digit,-3):
segments.append(value[_index:_from_index])
_from_index=_index
if not segments:
return value
segments.append(value[:_from_index])
return ','.join(reversed(segments))
re_3digits = re.compile(r'(?<=\d)\d{3}(?!\d)')
def intcomma(value):
segments,last_endoffset=[],len(value)
while last_endoffset > 3:
digit_group = re_3digits.search(value,0,last_endoffset)
if not digit_group:
break
segments.append(value[digit_group.start():last_endoffset])
last_endoffset=digit_group.start()
if not segments:
return value
if last_endoffset:
segments.append(value[:last_endoffset])
return ','.join(reversed(segments))
def intcomma_recurs(value):
"""
Converts an integer to a string containing commas every three digits.
For example, 3000 becomes '3,000' and 45000 becomes '45,000'.
"""
new = re.sub("^(-?\d+)(\d{3})", '\g<1>,\g<2>', str(value))
if value == new:
return new
else:
return intcomma(new)
@contextmanager
def timed(save_time_func):
begin=time.time()
try:
yield
finally:
save_time_func(time.time()-begin)
def testset_xsimple(func):
func('5')
def testset_simple(func):
func('567')
def testset_onecomma(func):
func('567890')
def testset_complex(func):
func('-1234567.024')
def testset_average(func):
func('-1234567.024')
func('567')
func('5674')
if __name__ == '__main__':
print 'Test results:'
for test_data in ('5','567','1234','1234.56','-253892.045'):
for func in (intcomma,intcomma_noregex,intcomma_noregex_reversed,intcomma_recurs):
print func.__name__,test_data,func(test_data)
times=[]
def overhead(x):
pass
for test_run in xrange(1,4):
for func in (intcomma,intcomma_noregex,intcomma_noregex_reversed,intcomma_recurs,overhead):
for testset in (testset_xsimple,testset_simple,testset_onecomma,testset_complex,testset_average):
for x in xrange(1000): # prime the test
testset(func)
with timed(lambda x:times.append(((test_run,func,testset),x))):
for x in xrange(50000):
testset(func)
for (test_run,func,testset),_delta in times:
print test_run,func.__name__,testset.__name__,_delta
And here are the test results:
intcomma 5 5
intcomma_noregex 5 5
intcomma_noregex_reversed 5 5
intcomma_recurs 5 5
intcomma 567 567
intcomma_noregex 567 567
intcomma_noregex_reversed 567 567
intcomma_recurs 567 567
intcomma 1234 1,234
intcomma_noregex 1234 1,234
intcomma_noregex_reversed 1234 1,234
intcomma_recurs 1234 1,234
intcomma 1234.56 1,234.56
intcomma_noregex 1234.56 1,234.56
intcomma_noregex_reversed 1234.56 1,234.56
intcomma_recurs 1234.56 1,234.56
intcomma -253892.045 -253,892.045
intcomma_noregex -253892.045 -253,892.045
intcomma_noregex_reversed -253892.045 -253,892.045
intcomma_recurs -253892.045 -253,892.045
1 intcomma testset_xsimple 0.0410001277924
1 intcomma testset_simple 0.0369999408722
1 intcomma testset_onecomma 0.213000059128
1 intcomma testset_complex 0.296000003815
1 intcomma testset_average 0.503000020981
1 intcomma_noregex testset_xsimple 0.134000062943
1 intcomma_noregex testset_simple 0.134999990463
1 intcomma_noregex testset_onecomma 0.190999984741
1 intcomma_noregex testset_complex 0.209000110626
1 intcomma_noregex testset_average 0.513000011444
1 intcomma_noregex_reversed testset_xsimple 0.124000072479
1 intcomma_noregex_reversed testset_simple 0.12700009346
1 intcomma_noregex_reversed testset_onecomma 0.230000019073
1 intcomma_noregex_reversed testset_complex 0.236999988556
1 intcomma_noregex_reversed testset_average 0.56299996376
1 intcomma_recurs testset_xsimple 0.348000049591
1 intcomma_recurs testset_simple 0.34600019455
1 intcomma_recurs testset_onecomma 0.625
1 intcomma_recurs testset_complex 0.773999929428
1 intcomma_recurs testset_average 1.6890001297
1 overhead testset_xsimple 0.0179998874664
1 overhead testset_simple 0.0190000534058
1 overhead testset_onecomma 0.0190000534058
1 overhead testset_complex 0.0190000534058
1 overhead testset_average 0.0309998989105
2 intcomma testset_xsimple 0.0360000133514
2 intcomma testset_simple 0.0369999408722
2 intcomma testset_onecomma 0.207999944687
2 intcomma testset_complex 0.302000045776
2 intcomma testset_average 0.523000001907
2 intcomma_noregex testset_xsimple 0.139999866486
2 intcomma_noregex testset_simple 0.141000032425
2 intcomma_noregex testset_onecomma 0.203999996185
2 intcomma_noregex testset_complex 0.200999975204
2 intcomma_noregex testset_average 0.523000001907
2 intcomma_noregex_reversed testset_xsimple 0.130000114441
2 intcomma_noregex_reversed testset_simple 0.129999876022
2 intcomma_noregex_reversed testset_onecomma 0.236000061035
2 intcomma_noregex_reversed testset_complex 0.241999864578
2 intcomma_noregex_reversed testset_average 0.582999944687
2 intcomma_recurs testset_xsimple 0.351000070572
2 intcomma_recurs testset_simple 0.352999925613
2 intcomma_recurs testset_onecomma 0.648999929428
2 intcomma_recurs testset_complex 0.808000087738
2 intcomma_recurs testset_average 1.81900000572
2 overhead testset_xsimple 0.0189998149872
2 overhead testset_simple 0.0189998149872
2 overhead testset_onecomma 0.0190000534058
2 overhead testset_complex 0.0179998874664
2 overhead testset_average 0.0299999713898
3 intcomma testset_xsimple 0.0360000133514
3 intcomma testset_simple 0.0360000133514
3 intcomma testset_onecomma 0.210000038147
3 intcomma testset_complex 0.305999994278
3 intcomma testset_average 0.493000030518
3 intcomma_noregex testset_xsimple 0.131999969482
3 intcomma_noregex testset_simple 0.136000156403
3 intcomma_noregex testset_onecomma 0.192999839783
3 intcomma_noregex testset_complex 0.202000141144
3 intcomma_noregex testset_average 0.509999990463
3 intcomma_noregex_reversed testset_xsimple 0.125999927521
3 intcomma_noregex_reversed testset_simple 0.126999855042
3 intcomma_noregex_reversed testset_onecomma 0.235999822617
3 intcomma_noregex_reversed testset_complex 0.243000030518
3 intcomma_noregex_reversed testset_average 0.56200003624
3 intcomma_recurs testset_xsimple 0.337000131607
3 intcomma_recurs testset_simple 0.342000007629
3 intcomma_recurs testset_onecomma 0.609999895096
3 intcomma_recurs testset_complex 0.75
3 intcomma_recurs testset_average 1.68300008774
3 overhead testset_xsimple 0.0189998149872
3 overhead testset_simple 0.018000125885
3 overhead testset_onecomma 0.018000125885
3 overhead testset_complex 0.0179998874664
3 overhead testset_average 0.0299999713898
I have found some issues with the dot separator in the previous top voted answers. I have designed a universal solution where you can use whatever you want as a thousand separator without modifying the locale. I know it's not the most elegant solution, but it gets the job done. Feel free to improve it !
def format_integer(number, thousand_separator='.'):
def reverse(string):
string = "".join(reversed(string))
return string
s = reverse(str(number))
count = 0
result = ''
for char in s:
count = count + 1
if count % 3 == 0:
if len(s) == count:
result = char + result
else:
result = thousand_separator + char + result
else:
result = char + result
return result
print(format_integer(50))
# 50
print(format_integer(500))
# 500
print(format_integer(50000))
# 50.000
print(format_integer(50000000))
# 50.000.000
babel module in python has feature to apply commas depending on the locale provided.
To install babel run the below command.
pip install babel
usage
format_currency(1234567.89, 'USD', locale='en_US')
# Output: $1,234,567.89
format_currency(1234567.89, 'USD', locale='es_CO')
# Output: US$ 1.234.567,89 (raw output US$\xa01.234.567,89)
format_currency(1234567.89, 'INR', locale='en_IN')
# Output: ₹12,34,567.89
Use separators and decimals together in float numbers : (In this example, two decimal places)
large_number = 4545454.26262666
print(f"Formatted: {large_number:,.2f}")
Result: Formatted: 4,545,454.26
This does money along with the commas
def format_money(money, presym='$', postsym=''):
fmt = '%0.2f' % money
dot = string.find(fmt, '.')
ret = []
if money < 0 :
ret.append('(')
p0 = 1
else :
p0 = 0
ret.append(presym)
p1 = (dot-p0) % 3 + p0
while True :
ret.append(fmt[p0:p1])
if p1 == dot : break
ret.append(',')
p0 = p1
p1 += 3
ret.append(fmt[dot:]) # decimals
ret.append(postsym)
if money < 0 : ret.append(')')
return ''.join(ret)
I have a python 2 and python 3 version of this code. I know that the question was asked for python 2 but now (8 years later lol) people will probably be using python 3.
Python 3 Code:
import random
number = str(random.randint(1, 10000000))
comma_placement = 4
print('The original number is: {}. '.format(number))
while True:
if len(number) % 3 == 0:
for i in range(0, len(number) // 3 - 1):
number = number[0:len(number) - comma_placement + 1] + ',' + number[len(number) - comma_placement + 1:]
comma_placement = comma_placement + 4
else:
for i in range(0, len(number) // 3):
number = number[0:len(number) - comma_placement + 1] + ',' + number[len(number) - comma_placement + 1:]
break
print('The new and improved number is: {}'.format(number))
Python 2 Code: (Edit. The python 2 code isn't working. I am thinking that the syntax is different).
import random
number = str(random.randint(1, 10000000))
comma_placement = 4
print 'The original number is: %s.' % (number)
while True:
if len(number) % 3 == 0:
for i in range(0, len(number) // 3 - 1):
number = number[0:len(number) - comma_placement + 1] + ',' + number[len(number) - comma_placement + 1:]
comma_placement = comma_placement + 4
else:
for i in range(0, len(number) // 3):
number = number[0:len(number) - comma_placement + 1] + ',' + number[len(number) - comma_placement + 1:]
break
print 'The new and improved number is: %s.' % (number)
Using f-strings, replace
, and format specifiers alone:
input = 100000
# Comma as thousands separator
f'{input:,}' # '100,000'
# Period as thousands separator
f'{input:,}'.replace(',', '.') # '100.000'
# Space as thousands separator
f'{input:,}'.replace(',', ' ') # '100 000'
Working with floats (e.g., currency):
# Comma as thousands separator and
# period as decimal separator
f'{input:,.2f}' # '100,000.00'
# Period as thousands separator and
# comma as decimal separator
f'{input:_.2f}'\
.replace('.', ',')\
.replace('_', '.') # '100.000,00'
# Space as thousands separator and
# comma as decimal separator
f'{input:_.2f}'\
.replace('.', ',')\
.replace('_', ' ') # '100 000,00'
# (The backslashes are just line breaks
# to line up the output for presentation)
If doing this in the wild, the next person looking at your code might appreciate if you leave a comment or put the code in a function. Mini-language code looks pretty cryptic to most mere mortals.
Here is another variant using a generator function that works for integers:
def ncomma(num):
def _helper(num):
# assert isinstance(numstr, basestring)
numstr = '%d' % num
for ii, digit in enumerate(reversed(numstr)):
if ii and ii % 3 == 0 and digit.isdigit():
yield ','
yield digit
return ''.join(reversed([n for n in _helper(num)]))
And here's a test:
>>> for i in (0, 99, 999, 9999, 999999, 1000000, -1, -111, -1111, -111111, -1000000):
... print i, ncomma(i)
...
0 0
99 99
999 999
9999 9,999
999999 999,999
1000000 1,000,000
-1 -1
-111 -111
-1111 -1,111
-111111 -111,111
-1000000 -1,000,000
Italy:
>>> import locale
>>> locale.setlocale(locale.LC_ALL,"")
'Italian_Italy.1252'
>>> f"{1000:n}"
'1.000'
Just subclass long
(or float
, or whatever). This is highly practical, because this way you can still use your numbers in math ops (and therefore existing code), but they will all print nicely in your terminal.
>>> class number(long):
def __init__(self, value):
self = value
def __repr__(self):
s = str(self)
l = [x for x in s if x in '1234567890']
for x in reversed(range(len(s)-1)[::3]):
l.insert(-x, ',')
l = ''.join(l[1:])
return ('-'+l if self < 0 else l)
>>> number(-100000)
-100,000
>>> number(-100)
-100
>>> number(-12345)
-12,345
>>> number(928374)
928,374
>>> 345
__repr__()
the correct method to override? I would suggest overriding __str__()
and leaving __repr__()
alone, because int(repr(number(928374)))
ought to work, but int()
will choke on the commas.
number(repr(number(928374)))
doesn't work, not int(repr(number(928374)))
. All the same, to make this approach work directly with print
, as the OP requested, the __str__()
method should be the one overridden rather than __repr__()
. Regardless, there appears to be a bug in the core comma insertion logic.
Commented
Oct 18, 2010 at 12:29