I've tried searching this and can't find a satisfactory answer.

I want to take a list/array of numbers and round them all to n significant figures. I have written a function to do this, but I was wondering if there is a standard method for this? I've searched but can't find it. Example:

In:  [  0.0, -1.2366e22, 1.2544444e-15, 0.001222 ], n=2
Out: [ 0.00, -1.24e22,        1.25e-15,  1.22e-3 ]


  • 2
    The basic question is what do you want it for. Why do you want to limit the precision in intermediate calculations, instead of doing them in full precision and just round/print rounded in the very end?
    – ev-br
    Sep 20, 2013 at 11:36
  • 2
    If it helps I need to return high precision values from a function calculated at convenient input values. Input values may cover a number of orders of magnitude and must allow for 0 values, -/+ve values and -/+ve exponents, as above. In this case, by "convenient" I mean values rounded to n significant figures. Thus I need these rounded values pre-calculation. My application aside, rounding to significant figures is a fundamental task, your comment would suggest we have no use for functions like around(x,n), round(x,n) ... etc.
    – dmon
    Sep 20, 2013 at 13:11
  • 1
    Answer to your question stackoverflow.com/questions/3410976/…, but with base python. Apr 7, 2016 at 19:45

13 Answers 13


Testing all of the already proposed solutions, I find they either

  1. convert to and from strings, which is inefficient
  2. can't handle negative numbers
  3. can't handle arrays
  4. have some numerical errors.

Here's my attempt at a solution which should handle all of these things. (Edit 2020-03-18: added np.asarray as suggested by A. West.)

def signif(x, p):
    x = np.asarray(x)
    x_positive = np.where(np.isfinite(x) & (x != 0), np.abs(x), 10**(p-1))
    mags = 10 ** (p - 1 - np.floor(np.log10(x_positive)))
    return np.round(x * mags) / mags


def scottgigante(x, p):
    x_positive = np.where(np.isfinite(x) & (x != 0), np.abs(x), 10**(p-1))
    mags = 10 ** (p - 1 - np.floor(np.log10(x_positive)))
    return np.round(x * mags) / mags

def awest(x,p):
    return float(f'%.{p-1}e'%x)

def denizb(x,p):
    return float(('%.' + str(p-1) + 'e') % x)

def autumn(x, p):
    return np.format_float_positional(x, precision=p, unique=False, fractional=False, trim='k')

def greg(x, p):
    return round(x, -int(np.floor(np.sign(x) * np.log10(abs(x)))) + p-1)

def user11336338(x, p):         
    xr = (np.floor(np.log10(np.abs(x)))).astype(int)
    return xr

def dmon(x, p):
    if np.all(np.isfinite(x)):
        eset = np.seterr(all='ignore')
        mags = 10.0**np.floor(np.log10(np.abs(x)))  # omag's
        x = np.around(x/mags,p-1)*mags             # round(val/omag)*omag
        x = np.where(np.isnan(x), 0.0, x)           # 0.0 -> nan -> 0.0
    return x

def seanlake(x, p):
    __logBase10of2 = 3.010299956639811952137388947244930267681898814621085413104274611e-1
    xsgn = np.sign(x)
    absx = xsgn * x
    mantissa, binaryExponent = np.frexp( absx )

    decimalExponent = __logBase10of2 * binaryExponent
    omag = np.floor(decimalExponent)

    mantissa *= 10.0**(decimalExponent - omag)

    if mantissa < 1.0:
        mantissa *= 10.0
        omag -= 1.0

    return xsgn * np.around( mantissa, decimals=p - 1 ) * 10.0**omag

solns = [scottgigante, awest, denizb, autumn, greg, user11336338, dmon, seanlake]

xs = [
    1.114, # positive, round down
    1.115, # positive, round up
    -1.114, # negative
    1.114e-30, # extremely small
    1.114e30, # extremely large
    0, # zero
    float('inf'), # infinite
    [1.114, 1.115e-30], # array input
p = 3

print('input:', xs)
for soln in solns:
    print(f'{soln.__name__}', end=': ')
    for x in xs:
            print(soln(x, p), end=', ')
        except Exception as e:
            print(type(e).__name__, end=', ')


input: [1.114, 1.115, -1.114, 1.114e-30, 1.114e+30, 0, inf, [1.114, 1.115e-30]]
scottgigante: 1.11, 1.12, -1.11, 1.11e-30, 1.11e+30, 0.0, inf, [1.11e+00 1.12e-30], 
awest: 1.11, 1.11, -1.11, 1.11e-30, 1.11e+30, 0.0, inf, TypeError, 
denizb: 1.11, 1.11, -1.11, 1.11e-30, 1.11e+30, 0.0, inf, TypeError, 
autumn: 1.11, 1.11, -1.11, 0.00000000000000000000000000000111, 1110000000000000000000000000000., 0.00, inf, TypeError, 
greg: 1.11, 1.11, -1.114, 1.11e-30, 1.11e+30, ValueError, OverflowError, TypeError, 
user11336338: 1.11, 1.12, -1.11, 1.1100000000000002e-30, 1.1100000000000001e+30, nan, nan, [1.11e+00 1.12e-30], 
dmon: 1.11, 1.12, -1.11, 1.1100000000000002e-30, 1.1100000000000001e+30, 0.0, inf, [1.11e+00 1.12e-30], 
seanlake: 1.11, 1.12, -1.11, 1.1100000000000002e-30, 1.1100000000000001e+30, 0.0, inf, ValueError, 


def test_soln(soln):
        soln(np.linspace(1, 100, 1000), 3)
    except Exception:
        [soln(x, 3) for x in np.linspace(1, 100, 1000)]

for soln in solns:
    %timeit test_soln(soln)


135 µs ± 15.3 µs per loop (mean ± std. dev. of 7 runs, 10000 loops each)
2.23 ms ± 430 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
2.18 ms ± 352 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
2.92 ms ± 206 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
14.1 ms ± 1.21 ms per loop (mean ± std. dev. of 7 runs, 100 loops each)
157 µs ± 50.1 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
142 µs ± 8.52 µs per loop (mean ± std. dev. of 7 runs, 10000 loops each)
20.7 ms ± 994 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
  • 2
    Love this! However your method only works for numpy arrays at the query: x!=0. Maybe add if not isinstance(x, np.ndarray): x = np.array(x)
    – A. West
    Mar 16, 2020 at 15:32
  • you are a hero!
    – JVGD
    Mar 12, 2021 at 10:04

Most of the solutions given here either (a) don't give correct significant figures, or (b) are unnecessarily complex.

If your goal is display formatting, then numpy.format_float_positional supports the desired behaviour directly. The following fragment returns the float x formatted to 4 significant figures, with scientific notation suppressed.

import numpy as np
np.format_float_positional(x, precision=4, unique=False, fractional=False, trim='k')
> 12340.

First a criticism: you're counting the number of significant figures wrong. In your example you want n=3, not 2.

It is possible to get around most of the edge cases by letting numpy library functions handle them if you use the function that makes the binary version of this algorithm simple: frexp. As a bonus, this algorithm will also run much faster because it never calls the log function.

#The following constant was computed in maxima 5.35.1 using 64 bigfloat digits of precision
__logBase10of2 = 3.010299956639811952137388947244930267681898814621085413104274611e-1

import numpy as np

def RoundToSigFigs_fp( x, sigfigs ):
Rounds the value(s) in x to the number of significant figures in sigfigs.
Return value has the same type as x.

sigfigs must be an integer type and store a positive value.
x must be a real value or an array like object containing only real values.
if not ( type(sigfigs) is int or type(sigfigs) is long or
         isinstance(sigfigs, np.integer) ):
    raise TypeError( "RoundToSigFigs_fp: sigfigs must be an integer." )

if sigfigs <= 0:
    raise ValueError( "RoundToSigFigs_fp: sigfigs must be positive." )

if not np.all(np.isreal( x )):
    raise TypeError( "RoundToSigFigs_fp: all x must be real." )

#temporarily suppres floating point errors
errhanddict = np.geterr()

matrixflag = False
if isinstance(x, np.matrix): #Convert matrices to arrays
    matrixflag = True
    x = np.asarray(x)

xsgn = np.sign(x)
absx = xsgn * x
mantissas, binaryExponents = np.frexp( absx )

decimalExponents = __logBase10of2 * binaryExponents
omags = np.floor(decimalExponents)

mantissas *= 10.0**(decimalExponents - omags)

if type(mantissas) is float or isinstance(mantissas, np.floating):
    if mantissas < 1.0:
        mantissas *= 10.0
        omags -= 1.0
else: #elif np.all(np.isreal( mantissas )):
    fixmsk = mantissas < 1.0, 
    mantissas[fixmsk] *= 10.0
    omags[fixmsk] -= 1.0

result = xsgn * np.around( mantissas, decimals=sigfigs - 1 ) * 10.0**omags
if matrixflag:
    result = np.matrix(result, copy=False)

return result

And it handles all of your cases correctly, including infinite, nan, 0.0, and a subnormal number:

>>> eglist = [  0.0, -1.2366e22, 1.2544444e-15, 0.001222, 0.0, 
...        float("nan"), float("inf"), float.fromhex("0x4.23p-1028"), 
...        0.5555, 1.5444, 1.72340, 1.256e-15, 10.555555  ]
>>> eglist
[0.0, -1.2366e+22, 1.2544444e-15, 0.001222, 0.0, 
nan, inf, 1.438203867284623e-309, 
0.5555, 1.5444, 1.7234, 1.256e-15, 10.555555]
>>> RoundToSigFigs(eglist, 3)
array([  0.00000000e+000,  -1.24000000e+022,   1.25000000e-015,
         1.22000000e-003,   0.00000000e+000,               nan,
                     inf,   1.44000000e-309,   5.56000000e-001,
         1.54000000e+000,   1.72000000e+000,   1.26000000e-015,
>>> RoundToSigFigs(eglist, 1)
array([  0.00000000e+000,  -1.00000000e+022,   1.00000000e-015,
         1.00000000e-003,   0.00000000e+000,               nan,
                     inf,   1.00000000e-309,   6.00000000e-001,
         2.00000000e+000,   2.00000000e+000,   1.00000000e-015,

Edit: 2016/10/12 I found an edge case that the original code handled wrong. I have placed a fuller version of the code in a GitHub repository.

Edit: 2019/03/01 Replace with recoded version.

Edit: 2020/11/19 Replace with vectorized version from Github that handles arrays. Note that preserving input data types, where possible, was also a goal of this code.

  • 2
    The constant __logBase10of2 has far more precision than a float, and the python interpreter will truncate most of that. Nov 12, 2015 at 17:54
  • 2
    Indeed, that is so. The thing is that the float precision can change at some point, and this provides a small amount of future proofing. Even better would be to use Python's decimal package, with its tunable precision, to calculate it before converting to floating point.
    – Sean Lake
    Mar 11, 2016 at 5:32
  • omags is not defined in the inline example. The longer example you linked to doesn't run in python 3.
    – rob
    Feb 27, 2019 at 20:33
  • 1
    @rob I just submitted a major reworking of the linked code. In all of my tests with Python 3.6 none of them failed, even before I reworked the code.
    – Sean Lake
    Feb 28, 2019 at 16:58

Is numpy.set_printoptions what you're looking for?

import numpy as np
print np.array([  0.0, -1.2366e22, 1.2544444e-15, 0.001222 ])


[  0.00e+00  -1.24e+22   1.25e-15   1.22e-03]


numpy.around appears to solve aspects of this problem if you're trying to transform the data. However, it doesn't do what you want in cases where the exponent is negative.

  • 1
    Not really. I looked at this, but I actually want the results for manipulation. I was thinking I could convert to string, using something like this and convert back, but this seems messy and likely extremely slow when applied to large arrays.
    – dmon
    Sep 20, 2013 at 11:19
  • @dmon why are you talking about this kind or awkward solution if you already have one? Sep 20, 2013 at 15:28
  • 2
    @Simon. Its a short simple question. "Is there a STANDARD WAY way of rounding m numbers to n significant figures?" A perfectly fine answer is "no there is not"!! I don't really know what point you're trying to make
    – dmon
    Sep 20, 2013 at 17:40
  • 1
    @dmon Your question is clear enough. But the print/read method is not likely to bring you the standard method you are looking for. I haven't found any either, for that matter. Only a mail mentioning a proposal. Sep 20, 2013 at 20:37

From the example numbers you have I think you mean significant figures rather than decimal places (-1.2366e22 to 0 decimal places is still -1.2366e22).

This piece of code works for me, I've always thought there should be an inbuilt function though:

def Round_To_n(x, n):
    return round(x, -int(np.floor(np.sign(x) * np.log10(abs(x)))) + n)

>>> Round_To_n(1.2544444e-15,2)

>>> Round_To_n(2.128282321e3, 6)
  • Hi Greg. Yes typo in my question sorry, will fix. My title clearly states significant figures though. Also, as stated, I have written a function to do this, what I'm asking is if there is a built in function, or a standard method to round to significant figures? It's starting to appear as thought there is not, which is a perfectly good answer. Finally your function fails for my first two test cases! Cheers for trying dude!
    – dmon
    Sep 20, 2013 at 15:09

Okay, so reasonably safe to say this is not allowed for in standard functionality. To close this off then, this is my attempt at a robust solution. It's rather ugly/non-pythonic and prob illustrates better then anything why I asked this question, so please feel free to correct or beat :)

import numpy as np

def round2SignifFigs(vals,n):
    (list, int) -> numpy array
    (numpy array, int) -> numpy array

    In: a list/array of values
    Out: array of values rounded to n significant figures

    Does not accept: inf, nan, complex

    >>> m = [0.0, -1.2366e22, 1.2544444e-15, 0.001222]
    >>> round2SignifFigs(m,2)
    array([  0.00e+00,  -1.24e+22,   1.25e-15,   1.22e-03])

    if np.all(np.isfinite(vals)) and np.all(np.isreal((vals))):
        eset = np.seterr(all='ignore')
        mags = 10.0**np.floor(np.log10(np.abs(vals)))  # omag's
        vals = np.around(vals/mags,n)*mags             # round(val/omag)*omag
        vals[np.where(np.isnan(vals))] = 0.0           # 0.0 -> nan -> 0.0
        raise IOError('Input must be real and finite')
    return vals

Nearest I get to neat does not account for 0.0, nan, inf or complex:

>>> omag      = lambda x: 10**np.floor(np.log10(np.abs(x)))
>>> signifFig = lambda x, n: (np.around(x/omag(x),n)*omag(x))


>>> m = [0.0, -1.2366e22, 1.2544444e-15, 0.001222]
>>> signifFig(m,2)
array([ nan, -1.24e+22,   1.25e-15,   1.22e-03])

Here is a version of Autumns answer which is vectorized so it can be applied to an array of floats not just a single float.

x = np.array([12345.6, 12.5673])
def sf4(x):
    x = float(np.format_float_positional(x, precision=4, unique=False, fractional=False,trim='k'))
    return x
vec_sf4 = np.vectorize(sf4)


>>>np.array([12350., 12.57])

There is a simple solution that uses the logic built into pythons string formatting system:

def round_sig(f, p):
    return float(('%.' + str(p) + 'e') % f)

Test with the following example:

for f in [0.01, 0.1, 1, 10, 100, 1000, 1000]:
    f *= 1.23456789
    print('%e --> %f' % (f, round_sig(f,3)))

which yields:

1.234568e-02 --> 0.012350
1.234568e-01 --> 0.123500
1.234568e+00 --> 1.235000
1.234568e+01 --> 12.350000
1.234568e+02 --> 123.500000
1.234568e+03 --> 1235.000000
1.234568e+03 --> 1235.000000

Best of luck!

(If you like lambdas use:

round_sig = lambda f,p: float(('%.' + str(p) + 'e') % f)



I got quite frustrated after scouring the internet and not finding an answer for this, so I wrote my own piece of code. Hope this is what you're looking for

import numpy as np
from numpy import ma

exp = np.floor(ma.log10(abs(X)).filled(0))
ans = np.round(X*10**-exp, sigfigs-1) * 10**exp

Just plug in your np array X and the required number of significant figures. Cheers!


I like Greg's very short effective routine above. However, it suffers from two drawbacks. One is that it doesn't work for x<0, not for me anyway. (That np.sign(x) should be removed.) Another is that it does not work if x is an array. I've fixed both of those problems with the routine below. Notice that I've changed the definition of n.

import numpy as np

def Round_n_sig_dig(x, n):

    xr = (np.floor(np.log10(np.abs(x)))).astype(int)
    return xr    

For Scalars

sround = lambda x,p: float(f'%.{p-1}e'%x)


>>> print( sround(123.45, 2) )

For Arrays

Use Scott Gigante's signif(x, p) fig1 fig2


For (display-) formatting in exponential notation, numpy.format_float_scientific(x, precision = n) (where x is the number to be formatted) seems to work well. The method returns a string. (This is similar to @Autumn's answer)

Here is an example:

>>> x = 7.92398e+05
>>> print(numpy.format_float_scientific(x, precision = 3))

Here, the argument precision = n fixes the number of decimals in the mantissa (by rounding off). It is possible to re-convert back this to float type...and that would obviously keep only the digits present in the string. It would be converted to a positional float format though... more work would be required - so I guess the re-conversion is probably quite a bad idea for large set of numbers.

Also, this doesn't work with iterables...look the docs up for more info.

  • @MarkParris I seem to have mentioned that.
    – amzon-ex
    Jun 15, 2020 at 15:43

One more solution which works well. Doing the test from @ScottGigante, it would be second best with a timing of 1.75ms.

import math

def sig_dig(x, n_sig_dig = 5):
  num_of_digits = len(str(x).replace(".", ""))
  if n_sig_dig >= num_of_digits:
      return x
  n = math.floor(math.log10(abs(x)) + 1 - n_sig_dig)
  result = round(x * 10**(-n)) * 10**n
  return result

And if it should be applied also to list/arrays you can vectorize it as

sig_dig_vec = np.vectorize(sig_dig)

Credit: answer inspired by this post

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge that you have read and understand our privacy policy and code of conduct.

Not the answer you're looking for? Browse other questions tagged or ask your own question.