Users of my software are complaining that in certain cases, there are obvious rounding errors (due to floating point representation issues):

>>> round(4.55, 1)
>>> '{:.60f}'.format(4.55)

I am considering replacing the current rounding functionality with the following:

>>> def round_human(val, ndigits):
...     return round(val * 10 ** ndigits) / 10 ** ndigits
>>> round_human(4.55, 1)

Or (the repr in there makes me uneasy, but as the numbers have already passed through numpy by this point, I'm not sure what better choice I have):

>>> def round_decimal(val, ndigits):
...     return float(Decimal(repr(val)).quantize(Decimal(10) ** -ndigits))
>>> round_decimal(4.55, 1)

Are there cases where either of these functions produce rounded results that look wrong to human inspection? I'm not worried about cases where ndigits is more than 3 or so.

Is there a better approach in general?

  • 3
    Why are you using round at all? Just print the number with the representation you want, don't round it.
    – wim
    Jan 4, 2017 at 4:07
  • It's difficult to say if there is a better approach without understanding more about your problem, or why you consider the original behaviour problematic. Jan 4, 2017 at 12:09
  • @wim do you mean something like '{:.1f}'.format(4.55) == '4.5'? Because that's still incorrect. @SimonByrne What's unclear about round(4.55, 1) == 4.5 being incorrect to the human eye? My users don't care about IEEE floating point, they just think we're bad at math. Jan 4, 2017 at 17:56
  • Yes, that's what I mean. It is not incorrect. The float float('4.55') is closer to the number 4.5 than it is to the number 4.6.
    – wim
    Jan 4, 2017 at 19:04
  • What do these numbers represent? Should they have been stored and manipulated in decimal from the start? Jan 4, 2017 at 19:24

2 Answers 2


You can use the following function for rounding; it usually works better than round() itself:

def my_round(x):
    return int(x*10+(0.5 if x > 0 else -0.5))/10
  • 1
    I'm not particularly interested in alternate implementations unless there's a demonstrated weakness that is fixed by the suggestion. In this case, I need the function to work for negative numbers. Jan 4, 2017 at 18:01
  • Okay. Still doesn't answer my question, since I'm asking about weaknesses in my (and your) proposed solution. I'm looking for failure cases that would work for round(x, 1) but fail for these. Jan 4, 2017 at 20:52

I realized that I could write a test to brute-force all of the interesting cases. The odd print statements in the test below produce the golden_dict, which is then manually inspected for the desired behavior.

def test_rounding(self):
    print '        golden_dict = {'

    golden_dict = {
        ('1.005', 2): 1.01,
        ('1.015', 2): 1.02,
        # ...
        ('1.95', 1): 2.0,

        for a, b, c in itertools.product(range(10), range(10), range(10)):
            s = '1.{}{}{}'.format(a, b, c).rstrip('0')
            self.assertEqual(s.lstrip('+'), repr(float(s)).rstrip('0'))

            for ndigits in [1, 2, 3]:
                q = decimal.Decimal('0.{}1'.format('0' * (ndigits-1)))
                g = golden_dict.get((s, ndigits), round(float(s), ndigits))

                rdp = show.round_decimal(float(s), ndigits)
                rdn = show.round_decimal(float('-' + s), ndigits)

                    self.assertEqual(rdp, -rdn)
                    self.assertEqual(rdp, g, \
                            "{}: {} != {}".format(s, rdp, g))
                    print '            ({!r:6}, {!r}): {!r},'\
                            .format(s, ndigits, rdp)
                    # Comment this raise out to produce the 
                    # entire golden_dict all at once.

        print '        }'

The function that worked best:

def round_decimal(val, places):
    s = repr(val)
    if places < 1:
        q = decimal.Decimal(10 ** -places)
        q = decimal.Decimal('0.{}1'.format('0' * (places-1)))
    f = float(decimal.Decimal(s).quantize(q, rounding=decimal.ROUND_HALF_UP))

    return f

This relies on python's magical repr(4.55) behavior, which is described here: https://docs.python.org/2/tutorial/floatingpoint.html and here https://bugs.python.org/issue1580 (this last one's a saga).

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