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I want to remove digits from a float to have a fixed number of digits after the dot, like:

1.923328437452 → 1.923

I need to output as a string to another function, not print.

Also I want to ignore the lost digits, not round them.

That's a lot of upvotes for an incorrect solution! One of those strange Stackoverflow rarities. I wonder if there's a badge for it... – tumultous_rooster Nov 3, 2014 at 18:51 It is just appalling how many wrong answers (and upvotes for the wrong answers) there are for this question. – nullstellensatz Feb 4, 2015 at 13:33

First, the function, for those who just want some copy-and-paste code:

def truncate(f, n):
    '''Truncates/pads a float f to n decimal places without rounding'''
    s = '{}'.format(f)
    if 'e' in s or 'E' in s:
        return '{0:.{1}f}'.format(f, n)
    i, p, d = s.partition('.')
    return '.'.join([i, (d+'0'*n)[:n]])

This is valid in Python 2.7 and 3.1+. For older versions, it's not possible to get the same "intelligent rounding" effect (at least, not without a lot of complicated code), but rounding to 12 decimal places before truncation will work much of the time:

def truncate(f, n):
    '''Truncates/pads a float f to n decimal places without rounding'''
    s = '%.12f' % f
    i, p, d = s.partition('.')
    return '.'.join([i, (d+'0'*n)[:n]])

Explanation

The core of the underlying method is to convert the value to a string at full precision and then just chop off everything beyond the desired number of characters. The latter step is easy; it can be done either with string manipulation

i, p, d = s.partition('.')
'.'.join([i, (d+'0'*n)[:n]])

or the decimal module

str(Decimal(s).quantize(Decimal((0, (1,), -n)), rounding=ROUND_DOWN))

The first step, converting to a string, is quite difficult because there are some pairs of floating point literals (i.e. what you write in the source code) which both produce the same binary representation and yet should be truncated differently. For example, consider 0.3 and 0.29999999999999998. If you write 0.3 in a Python program, the compiler encodes it using the IEEE floating-point format into the sequence of bits (assuming a 64-bit float)

0011111111010011001100110011001100110011001100110011001100110011

This is the closest value to 0.3 that can accurately be represented as an IEEE float. But if you write 0.29999999999999998 in a Python program, the compiler translates it into exactly the same value. In one case, you meant it to be truncated (to one digit) as 0.3, whereas in the other case you meant it to be truncated as 0.2, but Python can only give one answer. This is a fundamental limitation of Python, or indeed any programming language without lazy evaluation. The truncation function only has access to the binary value stored in the computer's memory, not the string you actually typed into the source code.1

If you decode the sequence of bits back into a decimal number, again using the IEEE 64-bit floating-point format, you get

0.2999999999999999888977697537484345957637...

so a naive implementation would come up with 0.2 even though that's probably not what you want. For more on floating-point representation error, see the Python tutorial.

It's very rare to be working with a floating-point value that is so close to a round number and yet is intentionally not equal to that round number. So when truncating, it probably makes sense to choose the "nicest" decimal representation out of all that could correspond to the value in memory. Python 2.7 and up (but not 3.0) includes a sophisticated algorithm to do just that, which we can access through the default string formatting operation.

'{}'.format(f)

The only caveat is that this acts like a g format specification, in the sense that it uses exponential notation (1.23e+4) if the number is large or small enough. So the method has to catch this case and handle it differently. There are a few cases where using an f format specification instead causes a problem, such as trying to truncate 3e-10 to 28 digits of precision (it produces 0.0000000002999999999999999980), and I'm not yet sure how best to handle those.

If you actually are working with floats that are very close to round numbers but intentionally not equal to them (like 0.29999999999999998 or 99.959999999999994), this will produce some false positives, i.e. it'll round numbers that you didn't want rounded. In that case the solution is to specify a fixed precision.

'{0:.{1}f}'.format(f, sys.float_info.dig + n + 2)

The number of digits of precision to use here doesn't really matter, it only needs to be large enough to ensure that any rounding performed in the string conversion doesn't "bump up" the value to its nice decimal representation. I think sys.float_info.dig + n + 2 may be enough in all cases, but if not that 2 might have to be increased, and it doesn't hurt to do so.

In earlier versions of Python (up to 2.6, or 3.0), the floating point number formatting was a lot more crude, and would regularly produce things like

1.1000000000000001

If this is your situation, if you do want to use "nice" decimal representations for truncation, all you can do (as far as I know) is pick some number of digits, less than the full precision representable by a float, and round the number to that many digits before truncating it. A typical choice is 12,

'%.12f' % f

but you can adjust this to suit the numbers you're using.

1Well... I lied. Technically, you can instruct Python to re-parse its own source code and extract the part corresponding to the first argument you pass to the truncation function. If that argument is a floating-point literal, you can just cut it off a certain number of places after the decimal point and return that. However this strategy doesn't work if the argument is a variable, which makes it fairly useless. The following is presented for entertainment value only:

def trunc_introspect(f, n):
    '''Truncates/pads the float f to n decimal places by looking at the caller's source code'''
    current_frame = None
    caller_frame = None
    s = inspect.stack()
        current_frame = s[0]
        caller_frame = s[1]
        gen = tokenize.tokenize(io.BytesIO(caller_frame[4][caller_frame[5]].encode('utf-8')).readline)
        for token_type, token_string, _, _, _ in gen:
            if token_type == tokenize.NAME and token_string == current_frame[3]:
                next(gen) # left parenthesis
                token_type, token_string, _, _, _ = next(gen) # float literal
                if token_type == tokenize.NUMBER:
                        cut_point = token_string.index('.') + n + 1
                    except ValueError: # no decimal in string
                        return token_string + '.' + '0' * n
                    else:
                        if len(token_string) < cut_point:
                            token_string += '0' * (cut_point - len(token_string))
                        return token_string[:cut_point]
                else:
                    raise ValueError('Unable to find floating-point literal (this probably means you called {} with a variable)'.format(current_frame[3]))
                break
    finally:
        del s, current_frame, caller_frame

Generalizing this to handle the case where you pass in a variable seems like a lost cause, since you'd have to trace backwards through the program's execution until you find the floating-point literal which gave the variable its value. If there even is one. Most variables will be initialized from user input or mathematical expressions, in which case the binary representation is all there is.

@RohithRNair Off the top of my head, the same way you'd apply any other function that operates on individual elements (i.e. applymap()). Maybe there's a way to make the whole operation more efficient, but that would be a matter for a separate question. – David Z Jul 24, 2018 at 9:52 applymap() is taking a lot time since my dataframes are really big. I am trying to compare two dataframes for differences but the floating point precision is skewing my output from the desired. Like you said, I will raise a separate question for the same. Thanks. – codeslord Jul 25, 2018 at 6:35 @RohithRNair Ah, well if you're trying to compare two dataframes for differences, ask about that instead. Truncating the values (which is what this question is about) is not the best way to do it. – David Z Jul 25, 2018 at 6:44 @Mehrdad Oh, I misunderstood, I thought you were saying that all negative numbers regardless of their magnitude get truncated to (some variant of) zero. Anyway, I can see why a person might want to omit the negative sign from the result in some cases, but because floating-point zeros are generally signed, I think a sensible default is to leave the sign there. For comparison, '{}'.format(-0.0) produces '-0.0'; I'm basically maintaining that behavior. If you want a variant of this that strips the sign when the result is zero, it shouldn't be hard to develop one. – David Z Aug 29, 2018 at 8:01

The result of round is a float, so watch out (example is from Python 2.6):

>>> round(1.923328437452, 3)
1.923
>>> round(1.23456, 3)
1.2350000000000001

You will be better off when using a formatted string:

>>> "%.3f" % 1.923328437452
'1.923'
>>> "%.3f" % 1.23456
'1.235'
                @Ahmad not necessarily. The example here is from Python 2.6 (note the date of the answer). The string formatting was improved in Python 2.7/3.1, that's probably why you get different results. Nevertheless, floating point numbers will often have unexpected string representations, see: docs.python.org/3.6/tutorial/floatingpoint.html
– Ferdinand Beyer
                May 22, 2018 at 18:08
                Simple and pythonic. 4 is the size of the whole number though, not only the digits after the dot.
– GaTTaCa
                Dec 11, 2013 at 19:48
                So if the user enters for example 2, you'll have a decimal dot . at the end of the string - not really a good solution I think.
– Zelphir Kaltstahl
                Mar 2, 2016 at 10:28
                Genius! been searching for half and hour for a smiple solution for numbers but seems the right one is in the strings :))
– Emad
                Oct 8, 2021 at 2:45
with localcontext() as ctx:
    ctx.rounding = ROUND_DOWN
    print Decimal('1.923328437452').quantize(Decimal('0.001'))

or shorter:

from decimal import Decimal as D, ROUND_DOWN
D('1.923328437452').quantize(D('0.001'), rounding=ROUND_DOWN)

Update

Usually the problem is not in truncating floats itself, but in the improper usage of float numbers before rounding.

For example: int(0.7*3*100)/100 == 2.09.

If you are forced to use floats (say, you're accelerating your code with numba), it's better to use cents as "internal representation" of prices: (70*3 == 210) and multiply/divide the inputs/outputs.

@markroxor, not sure what exactly you're asking about. As a sidenote, usually the problem is not with the rounding itself, but with the improper usage of float numbers before rounding. Eg int(0.7*3*100)/100 == 2.09. Where did my 1 cent go? – Antony Hatchkins Mar 25, 2019 at 9:40 Getting ImportError: cannot import name 'D', I believe you wanted to make a named import no ? – Overdrivr Apr 28, 2020 at 8:49 If the num provided is an integer this throws an IndexError due to the missing . in the number. Using partition you could get around this special case. a, dot, b = str(num).partition('.') return a + dot + b[:digits] – Alex Telon Sep 19, 2022 at 9:11

So many of the answers given for this question are just completely wrong. They either round up floats (rather than truncate) or do not work for all cases.

This is the top Google result when I search for 'Python truncate float', a concept which is really straightforward, and which deserves better answers. I agree with Hatchkins that using the decimal module is the pythonic way of doing this, so I give here a function which I think answers the question correctly, and which works as expected for all cases.

As a side-note, fractional values, in general, cannot be represented exactly by binary floating point variables (see here for a discussion of this), which is why my function returns a string.

from decimal import Decimal, localcontext, ROUND_DOWN
def truncate(number, places):
    if not isinstance(places, int):
        raise ValueError("Decimal places must be an integer.")
    if places < 1:
        raise ValueError("Decimal places must be at least 1.")
    # If you want to truncate to 0 decimal places, just do int(number).
    with localcontext() as context:
        context.rounding = ROUND_DOWN
        exponent = Decimal(str(10 ** - places))
        return Decimal(str(number)).quantize(exponent).to_eng_string()
                Thank you! I didn't think a correct and complete answer would be so hard to find for such a common need... Never seen so many up votes for incorrect answers.
– scūriolus
                Dec 1, 2022 at 16:34
                As I understand 1e-3 will truncate to 3 digits after dot. I liked this answer but it doesn't seems to work for 4 and 5.
– egvo
                Aug 26, 2019 at 12:35
def truncate(number, decimals=0):
    if decimals < 0:
        raise ValueError('truncate received an invalid value of decimals ({})'.format(decimals))
    elif decimals == 0:
        return trunc(number)
    else:
        factor = float(10**decimals)
        return trunc(number*factor)/factor
                This only truncates with positive numbers, negative numbers will round down (away from zero).
– Aaron D
                Dec 9, 2016 at 11:07

Just wanted to mention that the old "make round() with floor()" trick of

round(f) = floor(f+0.5)

can be turned around to make floor() from round()

floor(f) = round(f-0.5)

Although both these rules break around negative numbers, so using it is less than ideal:

def trunc(f, n):
    if f > 0:
        return "%.*f" % (n, (f - 0.5*10**-n))
    elif f == 0:
        return "%.*f" % (n, f)
    elif f < 0:
        return "%.*f" % (n, (f + 0.5*10**-n))
    param: value: takes a float
    param: precision: int, number of decimal places
    returns a float
    x = 10.0**precision
    num = int(value * x)/ x
    return num
precision(1.923328437452, 3)
def truncate_float(value, digits_after_point=2):
    pow_10 = 10 ** digits_after_point
    return (float(int(value * pow_10))) / pow_10
>>> truncate_float(1.14333, 2)
>>> truncate_float(1.14777, 2)
>>> truncate_float(1.14777, 4)
>>> 1.1477
def truncate(number, digits) -> float:
    stepper = 10.0 ** digits
    return math.trunc(stepper * number) / stepper
df['trunc'] = df['float_val'].apply(lambda x: truncate(x,1))
df['trunc']=df['trunc'].map('{:.1f}'.format)

int(16.5); this will give an integer value of 16, i.e. trunc, won't be able to specify decimals, but guess you can do that by

import math;
def trunc(invalue, digits):
    return int(invalue*math.pow(10,digits))/math.pow(10,digits);
def truncate_float(number, length):
    """Truncate float numbers, up to the number specified
    in length that must be an integer"""
    number = number * pow(10, length)
    number = int(number)
    number = float(number)
    number /= pow(10, length)
    return number

There is an easy workaround in python 3. Where to cut I defined with an help variable decPlace to make it easy to adapt.

f = 1.12345
decPlace= 4
f_cut = int(f * 10**decPlace) /10**decPlace

Output:

f = 1.1234

Hope it helps.

Most answers are way too complicated in my opinion, how about this?

digits = 2  # Specify how many digits you want
fnum = '122.485221'
truncated_float = float(fnum[:fnum.find('.') + digits + 1])
>>> 122.48

Simply scanning for the index of '.' and truncate as desired (no rounding). Convert string to float as final step.

Or in your case if you get a float as input and want a string as output:

fnum = str(122.485221)  # convert float to string first
truncated_float = fnum[:fnum.find('.') + digits + 1]  # string output
                Your proposal is problematic if the number being truncating is small since you would waste a lot precision with the leading 0 to the right of the decimal point. But this problem is endemic to the problem as stated. What I'm trying to say is that significant figures is the real answer.
– overcoil
                Apr 9, 2020 at 18:52

The core idea given here seems to me to be the best approach for this problem. Unfortunately, it has received less votes while the later answer that has more votes is not complete (as observed in the comments). Hopefully, the implementation below provides a short and complete solution for truncation.

def trunc(num, digits):
    l = str(float(num)).split('.')
    digits = min(len(l[1]), digits)
    return l[0] + '.' + l[1][:digits]

which should take care of all corner cases found here and here.

I think a better version would be just to find the index of decimal point . and then to take the string slice accordingly:

def truncate(number, n_digits:int=1)->float:
    :param number: real number ℝ
    :param n_digits: Maximum number of digits after the decimal point after truncation
    :return: truncated floating point number with at least one digit after decimal point
    decimalIndex = str(number).find('.')
    if decimalIndex == -1:
        return float(number)
    else:
        return float(str(number)[:decimalIndex+n_digits+1])
>>> 1.923

By multiplying the number by 1000 (10 ^ 3 for 3 digits) we shift the decimal point 3 places to the right and get 1923.3284374520001. When we convert that to an int the fractional part 3284374520001 will be discarded. Then we undo the shifting of the decimal point again by dividing by 1000 which returns 1.923.

1.923

Alternatively, the following will give you the same result and it is more efficient. If you need two decimal for example just change 1000 to 100:

int(n * 1000) / 1000.0

Something simple enough to fit in a list-comprehension, with no libraries or other external dependencies. For Python >=3.6, it's very simple to write with f-strings.

The idea is to let the string-conversion do the rounding to one more place than you need and then chop off the last digit.

>>> nout = 3  # desired number of digits in output
>>> [f'{x:.{nout+1}f}'[:-1] for x in [2/3, 4/5, 8/9, 9/8, 5/4, 3/2]]
['0.666', '0.800', '0.888', '1.125', '1.250', '1.500']

Of course, there is rounding happening here (namely for the fourth digit), but rounding at some point is unvoidable. In case the transition between truncation and rounding is relevant, here's a slightly better example:

>>> nacc = 6  # desired accuracy (maximum 15!)
>>> nout = 3  # desired number of digits in output
>>> [f'{x:.{nacc}f}'[:-(nacc-nout)] for x in [2.9999, 2.99999, 2.999999, 2.9999999]]
>>> ['2.999', '2.999', '2.999', '3.000']

Bonus: removing zeros on the right

>>> nout = 3  # desired number of digits in output
>>> [f'{x:.{nout+1}f}'[:-1].rstrip('0') for x in [2/3, 4/5, 8/9, 9/8, 5/4, 3/2]]
['0.666', '0.8', '0.888', '1.125', '1.25', '1.5']

Am also a python newbie and after making use of some bits and pieces here, I offer my two cents

print str(int(time.time()))+str(datetime.now().microsecond)[:3]

str(int(time.time())) will take the time epoch as int and convert it to string and join with... str(datetime.now().microsecond)[:3] which returns the microseconds only, convert to string and truncate to first 3 chars