I want to access the source code the built-in function round(), to allow me to create a very similar function. How can i access this source code and how easily will this be to edit / use?

The reason I am interested in doing this is that the built-in function round() converts an integer into float even when the number of digits is negative. For Example:




I want to create a function that returns an integer. I am sure there other methods of achieving the same result, but I want to see how the built in function achieves this task as I would expect this to be reasonably efficient.

  • 1
    don't know about round, but you can start your search here if we talking about cpython
    – Grigory
    Sep 6, 2017 at 15:07
  • 2
    The source will be in C, see Finding the source code for built-in Python functions? .. whats wrong with int(round(x)) ?
    – Alex K.
    Sep 6, 2017 at 15:07
  • @AlexK. for very large numbers this will create an error, due to the size limit on floats. Sep 6, 2017 at 15:13
  • @BryanOakley i did try that, cheers though... Sep 6, 2017 at 15:13
  • If you tried it, you should include that information in the question, along with why that didn't work for you. There's no way for us to know what you've tried or not tried unless you tell us. Sep 6, 2017 at 15:25

2 Answers 2


just expanding the comment from Mark Dickinson and to make sure I understand it myself, the CPython round function is spread over several parts of the code base.

round(number, ndigits) starts by looking up and invoking the __round__ method on the object. this is implemented by the C function builtin_round_impl in bltinmodule.c

for floats this invokes the float.__round__ method, which is implemented in float___round___impl in floatobject.c:1045 but there's a stub entry point in floatobject.c.h that I think is mostly maintained by Python's argument clinic tool. this header is also where its PyMethodDef is defined as FLOAT___ROUND___METHODDEF

the C function float___round___impl starts by checking if ndigits was not specified (i.e. nothing passed, or passed as None), in this case then it calls round from the C standard library (or the version from pymath.c as a fallback).

if ndigits is specified then it probably calls the version of double_round in floatobject.c:927. this works in 53bit precision, so adjusts floating point rounding modes and is generally pretty fiddly code, but basically it converts the double to a string with a given precision, and then converts back to a double

for a small number of platforms there's another version of double_round at floatobject.c:985 that does the obvious thing of basically round(x * 10**ndigits) / 10**ndigits, but these extra operations can reduce precision of the result

note that the higher precision version will give different answers to the version in NumPy and equivalent version in R, as commented on here. for example, round(0.075, 2) results in 0.07 with the builtin round, while numpy and R give 0.08. the easiest way I've found of seeing what's going on is by using the decimal module to see the full decimal expansion of the float:

from decimal import Decimal


gives: 0.0749999999999999972…, i.e. 0.075 can't be accurately represented by a (binary) floating point number and the closest number happens to be slightly smaller, and hence it rounds down to 0.07. while the implementation in numpy gives 0.08 because it effectively does round(0.075 * 100) / 100 and the intermediate value happens to round up, i.e:

print(Decimal(0.075 * 100))

giving exactly 7.5, which rounds exactly to 8.

  • Very thorough! I'd suggest replacing some of the source links with permalinks, else they'll become invalid if/when floatobject.c changes in the 3.7 branch. As for the last paragraph, there's a single correctly-rounded result for the round operation for any given input. Correct rounding is incredibly useful, in that it ensures reproducible arithmetic - if everyone had correctly-rounded round operations, then all of R, NumPy, Python would be giving the same results. Python definitely shouldn't deliberately give the wrong result just to match R and NumPy. Jul 11, 2019 at 16:52
  • There's also the aspect that as soon as you deviate from correct rounding, it becomes very unclear just what the correct answer is. In this particular case, NumPy gives the expected result for this operation, but there are cases where NumPy doesn't give the expected result for a round, too, and it's really hard to pin down exactly what the "expected result" means if you're not going to aim for correct rounding. If you are going to aim for correct rounding, the expected result is clear in all cases. Jul 11, 2019 at 16:54
  • @MarkDickinson this answer was partly motivated by stackoverflow.com/a/56974893/1358308 where I tried to explain where rounding errors were coming from. when I later actually tried to replicate Python's result in any other language I started to doubt that "doing the correct thing" was actually desirable
    – Sam Mason
    Jul 11, 2019 at 17:00
  • Right, but then what's the alternative? How do you come up with a specification for what is desirable? Note that e.g., np.round(0.545, 2) gives 0.55 (at least on my machine, and probably on yours, too). Should that be considered a bug in NumPy? Jul 11, 2019 at 17:01

The source seems to be: https://github.com/python/cpython/blob/master/Python/pymath.c

round(double x)
    double absx, y;
    absx = fabs(x);
    y = floor(absx);
    if (absx - y >= 0.5)
        y += 1.0;
    return copysign(y, x);

where copysign is:

copysign(double x, double y)
    /* use atan2 to distinguish -0. from 0. */
    if (y > 0. || (y == 0. && atan2(y, -1.) > 0.)) {
        return fabs(x);
    } else {
        return -fabs(x);
  • 2
    Unfortunately, that's not the source for Python's round function; it's the source for the fallback C round function for platforms that don't supply the C99 round function already (most do). (And similarly for copysign.) For the round implementation for the float type, start here Sep 10, 2017 at 12:10
  • @MarkDickinson I've added an answer expanding on your above comment, as you seem to have an interest in floating point I was wondering if I've got it about right
    – Sam Mason
    Jul 11, 2019 at 10:53
  • @MarkDickinson looks like this one may be more revealing on its implementation github.com/python/cpython/blob/…
    – nimig18
    Jun 6, 2021 at 4:47
  • @nimig18: Yep, that's the one. Note that the bulk of the work is in _Py_dg_dtoa and _Py_dg_strtod, and those are not simple functions. Jun 6, 2021 at 7:16

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