I want a
to be rounded to 13.95.
>>> a
13.949999999999999
>>> round(a, 2)
13.949999999999999
The round
function does not work the way I expected.
I want a
to be rounded to 13.95.
>>> a
13.949999999999999
>>> round(a, 2)
13.949999999999999
The round
function does not work the way I expected.
You are running into the old problem with floating point numbers that all numbers cannot be represented. The command line is just showing you the full floating point form from memory.
In floating point your rounded version is the same number. Since computers are binary, they store floating point numbers as an integer and then divide it by a power of two so 13.95 will be represented in a similar fashion to 125650429603636838/(2**53).
Double precision numbers have 53 bits (16 digits) of precision and regular floats have 24 bits (8 digits) of precision. The floating point in Python uses double precision to store the values.
For example,
>>> 125650429603636838/(2**53)
13.949999999999999
>>> 234042163/(2**24)
13.949999988079071
>>> a=13.946
>>> print(a)
13.946
>>> print("%.2f" % a)
13.95
>>> round(a,2)
13.949999999999999
>>> print("%.2f" % round(a,2))
13.95
>>> print("{0:.2f}".format(a))
13.95
>>> print("{0:.2f}".format(round(a,2)))
13.95
>>> print("{0:.15f}".format(round(a,2)))
13.949999999999999
If you are after only two decimal places as in currency then you have a couple of better choices: 1) Use integers and store values in cents, not dollars and then divide by 100 to convert to dollars. 2) Or use a fixed point number like decimal.
"%.2f" % round(a,2)
you can put in not only in printf, but also in such things like str()
– andilabs
Nov 1 '13 at 1:15
float
) is just the closest available approximation of the decimal number (that you are familiar with as a human being). There is no such (finitely representable) binary value as 0.245. It simply does not exist, and mathematically cannot exist. The binary value which is closest to 0.245 is slightly less than 0.245, so naturally it rounds down. Likewise, there is no such thing as 0.225 in binary, but the binary value which is closest to 0.225 is slightly greater than 0.225, so naturally it rounds up.
– John Y
Jun 14 '16 at 19:06
Decimal
, and that was one of the solutions presented in this answer. The other was to convert your quantities to integer and use integer arithmetic. Both of these approaches also appeared in other answers and comments.
– John Y
Jun 15 '16 at 19:45
There are new format specifications, String Format Specification Mini-Language:
You can do the same as:
"{0:.2f}".format(13.949999999999999)
Note that the above returns a string. In order to get as float, simply wrap with float(...)
:
float("{0:.2f}".format(13.949999999999999))
Note that wrapping with float()
doesn't change anything:
>>> x = 13.949999999999999999
>>> x
13.95
>>> g = float("{0:.2f}".format(x))
>>> g
13.95
>>> x == g
True
>>> h = round(x, 2)
>>> h
13.95
>>> x == h
True
'{0:,.2f}'.format(1333.949999999)
which prints '1,333.95'
.
– Stephen Blum
Jun 20 '14 at 2:41
f"Result is {result:.2f}"
– Andrey Semakin
2 days ago
The built-in round()
works just fine in Python 2.7 or later.
Example:
>>> round(14.22222223, 2)
14.22
Check out the documentation.
>>> round(2.675, 2) 2.67
docs.python.org/2/tutorial/floatingpoint.html
– danger89
Nov 6 '18 at 17:41
I feel that the simplest approach is to use the format()
function.
For example:
a = 13.949999999999999
format(a, '.2f')
13.95
This produces a float number as a string rounded to two decimal points.
Most numbers cannot be exactly represented in floats. If you want to round the number because that's what your mathematical formula or algorithm requires, then you want to use round. If you just want to restrict the display to a certain precision, then don't even use round and just format it as that string. (If you want to display it with some alternate rounding method, and there are tons, then you need to mix the two approaches.)
>>> "%.2f" % 3.14159
'3.14'
>>> "%.2f" % 13.9499999
'13.95'
And lastly, though perhaps most importantly, if you want exact math then you don't want floats at all. The usual example is dealing with money and to store 'cents' as an integer.
Try the code below:
>>> a = 0.99334
>>> a = int((a * 100) + 0.5) / 100.0 # Adding 0.5 rounds it up
>>> print a
0.99
round
function in the first place. For another thing, because this solution still uses floating point, the OP's original problem remains, even for the "corrected" version of this "solution".
– John Y
Jun 17 '14 at 22:54
round
function (which was used in the question).
– interjay
Sep 12 '14 at 22:55
round()
doesn't work as the OP mentioned.
– Pithikos
Feb 18 '15 at 13:28
Use
print"{:.2f}".format(a)
instead of
print"{0:.2f}".format(a)
Because the latter may lead to output errors when trying to output multiple variables (see comments).
With Python < 3 (e.g. 2.6 or 2.7), there are two ways to do so.
# Option one
older_method_string = "%.9f" % numvar
# Option two (note ':' before the '.9f')
newer_method_string = "{:.9f}".format(numvar)
But note that for Python versions above 3 (e.g. 3.2 or 3.3), option two is preferred.
For more information on option two, I suggest this link on string formatting from the Python documentation.
And for more information on option one, this link will suffice and has information on the various flags.
Reference: Convert floating point number to a certain precision, and then copy to string
You can modify the output format:
>>> a = 13.95
>>> a
13.949999999999999
>>> print "%.2f" % a
13.95
The rounding problem at input / output has been solved by Python 2.7.0 and 3.1 definitively.
Infinite test:
import random
for x in iter(random.random, None): # Verify FOREVER that rounding is fixed :-)
assert float(repr(x)) == x # Reversible repr() conversion.
assert len(repr(round(x, 10))) <= 12 # Smart decimal places in repr() after round.
if x >= 0.1: # Implicit rounding to 12 significant digits
assert str(x) == repr(round(x, 12)) # by str() is good enough for small errors.
y = 1000 * x # Decimal type is excessive for shopping
assert str(y) == repr(round(y, 12 - 3)) # in the supermaket with Python 2.7+ :-)
See the Release notes Python 2.7 - Other Language Changes the fourth paragraph:
Conversions between floating-point numbers and strings are now correctly rounded on most platforms. These conversions occur in many different places: str() on floats and complex numbers; the float and complex constructors; numeric formatting; serializing and de-serializing floats and complex numbers using the
marshal
,pickle
andjson
modules; parsing of float and imaginary literals in Python code; and Decimal-to-float conversion.Related to this, the repr() of a floating-point number x now returns a result based on the shortest decimal string that’s guaranteed to round back to x under correct rounding (with round-half-to-even rounding mode). Previously it gave a string based on rounding x to 17 decimal digits.
More information:: The formatting of float
before Python 2.7 was similar to the current numpy.float64
. Both types use the same 64 bit IEEE 754 double precision with 52 bit mantissa. A big difference is that np.float64.__repr__
is formatted frequently with an excessive decimal number so that no bit can be lost, but no valid IEEE 754 number exists between 13.949999999999999 and 13.950000000000001. The result is not nice and the conversion repr(float(number_as_string))
is not reversible. On the other hand: float.__repr__
is formatted so that every digit is important; the sequence is without gaps and the conversion is reversible. Simply: If you perhaps have a numpy.float64 number, convert it to normal float in order to be formatted for humans, not for numeric processors, otherwise nothing more is necessary with Python 2.7+.
float
(double precision) and normal round
, not about numpy.double and its conversion to string. Plain Python rounding really can not be done better than in Python 2.7. The most of answers has been written before 2.7, but they are obsoleted, though they were very good originally. This is the reason of my answer.
– hynekcer
Apr 15 '16 at 11:02
1
, except during "gradual underflow".
– Rick James
May 17 '17 at 4:16
In Python 2.7:
a = 13.949999999999999
output = float("%0.2f"%a)
print output
output
has the exact same value as a
, so you might as well have written print a
instead of print output
in the last line.
– Mark Dickinson
May 26 '18 at 6:12
13.95
. But so does print a
, for this particular value of a
, in Python 2.7, so it's not really clear what the point of the formatting step was.
– Mark Dickinson
Sep 23 '18 at 11:13
a == output
for the code you show? It gives True
for me, and I suspect it does for you, too.
– Mark Dickinson
Sep 23 '18 at 11:46
The Python tutorial has an appendix called Floating Point Arithmetic: Issues and Limitations. Read it. It explains what is happening and why Python is doing its best. It has even an example that matches yours. Let me quote a bit:
>>> 0.1 0.10000000000000001
you may be tempted to use the
round()
function to chop it back to the single digit you expect. But that makes no difference:>>> round(0.1, 1) 0.10000000000000001
The problem is that the binary floating-point value stored for
“0.1”
was already the best possible binary approximation to1/10
, so trying to round it again can’t make it better: it was already as good as it gets.Another consequence is that since
0.1
is not exactly1/10
, summing ten values of0.1
may not yield exactly1.0
, either:>>> sum = 0.0 >>> for i in range(10): ... sum += 0.1 ... >>> sum 0.99999999999999989
One alternative and solution to your problems would be using the decimal
module.
Nobody here seems to have mentioned it yet, so let me give an example in Python 3.6's f-string/template-string format, which I think is beautifully neat:
>>> f'{a:.2f}'
It works well with longer examples too, with operators and not needing parens:
>>> print(f'Completed in {time.time() - start:.2f}s')
It's doing exactly what you told it to do and is working correctly. Read more about floating point confusion and maybe try decimal objects instead.
As @Matt pointed out, Python 3.6 provides f-strings, and they can also use nested parameters:
value = 2.34558
precision = 2
width = 4
print(f'result: {value:{width}.{precision}f}')
which will display result: 2.35
For fixing the floating point in type-dynamic languages such as Python and JavaScript, I use this technique
# For example:
a = 70000
b = 0.14
c = a * b
print c # Prints 980.0000000002
# Try to fix
c = int(c * 10000)/100000
print c # Prints 980
You can also use Decimal as following:
from decimal import *
getcontext().prec = 6
Decimal(1) / Decimal(7)
# Results in 6 precision -> Decimal('0.142857')
getcontext().prec = 28
Decimal(1) / Decimal(7)
# Results in 28 precision -> Decimal('0.1428571428571428571428571429')
getcontext().prec = 6
works for just the scope of the function or all places?
– Julio Marins
Oct 4 '17 at 20:12
orig_float = 232569 / 16000.0
14.5355625
short_float = float("{:.2f}".format(orig_float))
14.54
from decimal import Decimal
def round_float(v, ndigits=2, rt_str=False):
d = Decimal(v)
v_str = ("{0:.%sf}" % ndigits).format(round(d, ndigits))
if rt_str:
return v_str
return Decimal(v_str)
Results:
Python 3.6.1 (default, Dec 11 2018, 17:41:10)
>>> round_float(3.1415926)
Decimal('3.14')
>>> round_float(3.1445926)
Decimal('3.14')
>>> round_float(3.1455926)
Decimal('3.15')
>>> round_float(3.1455926, rt_str=True)
'3.15'
>>> str(round_float(3.1455926))
'3.15'
You can use format operator for rounding the value up to 2 decimal places in python:
print(format(14.4499923, '.2f')) // output is 14.45
To round a number to a resolution, the best way is the following one, which can work with any resolution (0.01 for two decimals or even other steps):
>>> import numpy as np
>>> value = 13.949999999999999
>>> resolution = 0.01
>>> newValue = int(np.round(value/resolution))*resolution
>>> print newValue
13.95
>>> resolution = 0.5
>>> newValue = int(np.round(value/resolution))*resolution
>>> print newValue
14.0
numpy.round
accuracy/precision. So it requires to define it as int before multiplication with resolution. I updated the code. Thank you for that!
– iblasi
Apr 13 '16 at 16:28
numpy.float64
result of np.round to float
or simply to use round(value, 2)
. No valid IEEE 754 number exists between 13.949999999999999 (= 1395 / 100.) and 3.950000000000001 (= 1395 * .01). Why do you think that your method is the best? The original value 13.949999999999999289 (= value = round(value, 2)) is even more exact than your 13.95000000000000178 (printed by np.float96). More info also for numpy is now added to my answer that you probably downvoted by mistake. It wasn't about numpy originally.
– hynekcer
Apr 15 '16 at 13:04
int
you can also use float
for @szeitlin example. Thank you for your extra comment. (Sorry but I did not downvote you)
– iblasi
Apr 15 '16 at 20:49
It's simple like 1,2,3:
use decimal module for fast correctly-rounded decimal floating point arithmetic:
d=Decimal(10000000.0000009)
to achieve rounding:
d.quantize(Decimal('0.01'))
will results with Decimal('10000000.00')
def round_decimal(number, exponent='0.01'):
decimal_value = Decimal(number)
return decimal_value.quantize(Decimal(exponent))
OR
def round_decimal(number, decimal_places=2):
decimal_value = Decimal(number)
return decimal_value.quantize(Decimal(10) ** -decimal_places)
PS: critique of others: formatting is not rounding.
The method I use is that of string slicing. It's relatively quick and simple.
First, convert the float to a string, the choose the length you would like it to be.
float = str(float)[:5]
In the single line above, we've converted the value to a string, then kept the string only to its first four digits or characters (inclusive).
Hope that helps!
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