# How to pretty-print a numpy.array without scientific notation and with given precision?

I'm curious, whether there is any way to print formatted `numpy.arrays`, e.g., in a way similar to this:

``````x = 1.23456
print '%.3f' % x
``````

If I want to print the `numpy.array` of floats, it prints several decimals, often in 'scientific' format, which is rather hard to read even for low-dimensional arrays. However, `numpy.array` apparently has to be printed as a string, i.e., with `%s`. Is there a solution for this?

• this discussion also might interest the ones who end up here via google search. Nov 6, 2018 at 22:13

You can use `set_printoptions` to set the precision of the output:

``````import numpy as np
x=np.random.random(10)
print(x)
# [ 0.07837821  0.48002108  0.41274116  0.82993414  0.77610352  0.1023732
#   0.51303098  0.4617183   0.33487207  0.71162095]

np.set_printoptions(precision=3)
print(x)
# [ 0.078  0.48   0.413  0.83   0.776  0.102  0.513  0.462  0.335  0.712]
``````

And `suppress` suppresses the use of scientific notation for small numbers:

``````y=np.array([1.5e-10,1.5,1500])
print(y)
# [  1.500e-10   1.500e+00   1.500e+03]
np.set_printoptions(suppress=True)
print(y)
# [    0.      1.5  1500. ]
``````

See the docs for set_printoptions for other options.

To apply print options locally, using NumPy 1.15.0 or later, you could use the numpy.printoptions context manager. For example, inside the `with-suite` `precision=3` and `suppress=True` are set:

``````x = np.random.random(10)
with np.printoptions(precision=3, suppress=True):
print(x)
# [ 0.073  0.461  0.689  0.754  0.624  0.901  0.049  0.582  0.557  0.348]
``````

But outside the `with-suite` the print options are back to default settings:

``````print(x)
# [ 0.07334334  0.46132615  0.68935231  0.75379645  0.62424021  0.90115836
#   0.04879837  0.58207504  0.55694118  0.34768638]
``````

If you are using an earlier version of NumPy, you can create the context manager yourself. For example,

``````import numpy as np
import contextlib

@contextlib.contextmanager
def printoptions(*args, **kwargs):
original = np.get_printoptions()
np.set_printoptions(*args, **kwargs)
try:
yield
finally:
np.set_printoptions(**original)

x = np.random.random(10)
with printoptions(precision=3, suppress=True):
print(x)
# [ 0.073  0.461  0.689  0.754  0.624  0.901  0.049  0.582  0.557  0.348]
``````

To prevent zeros from being stripped from the end of floats:

`np.set_printoptions` now has a `formatter` parameter which allows you to specify a format function for each type.

``````np.set_printoptions(formatter={'float': '{: 0.3f}'.format})
print(x)
``````

which prints

``````[ 0.078  0.480  0.413  0.830  0.776  0.102  0.513  0.462  0.335  0.712]
``````

``````[ 0.078  0.48   0.413  0.83   0.776  0.102  0.513  0.462  0.335  0.712]
``````
• is there a means to apply the formatting to only the specific print statement (as opposed to setting a general output format used by all print statements)?
– bph
Mar 28, 2013 at 15:03
• @Hiett: There is no NumPy function to set print options for just one `print`, but you could use a context manager to make something similar. I've edited the post above to show what I mean. Mar 28, 2013 at 15:19
• your `np.set_printoptions(precision=3)` suppress the end zeros.. how do you get them to display like this `[ 0.078 0.480 0.413 0.830 0.776 0.102 0.513 0.462 0.335 0.712]`? Jul 27, 2013 at 15:16
• @Norfeldt: I've added a way to do this above. Jul 27, 2013 at 16:39
• This works great. As a side note, you can also use `set_printoptions` if you want a string representation and not necessarily use `print`. You can just call `__str__()` of the numpy array instance and you will get the formatted string as per the printoptions you set. Mar 28, 2015 at 12:24

You can get a subset of the `np.set_printoptions` functionality from the `np.array_str` command, which applies only to a single print statement.

http://docs.scipy.org/doc/numpy/reference/generated/numpy.array_str.html

For example:

``````In [27]: x = np.array([[1.1, 0.9, 1e-6]]*3)

In [28]: print x
[[  1.10000000e+00   9.00000000e-01   1.00000000e-06]
[  1.10000000e+00   9.00000000e-01   1.00000000e-06]
[  1.10000000e+00   9.00000000e-01   1.00000000e-06]]

In [29]: print np.array_str(x, precision=2)
[[  1.10e+00   9.00e-01   1.00e-06]
[  1.10e+00   9.00e-01   1.00e-06]
[  1.10e+00   9.00e-01   1.00e-06]]

In [30]: print np.array_str(x, precision=2, suppress_small=True)
[[ 1.1  0.9  0. ]
[ 1.1  0.9  0. ]
[ 1.1  0.9  0. ]]
``````
• Likely the most simple and efficient option as it doesn't introduce a permanent change in `printoptions`, nor requires a costly loop or a `with` construction. The possibility to format elements should be integrated into numpy directly (can't understand why it is not the case).
– mins
Oct 25, 2020 at 11:11

Unutbu gave a really complete answer (they got a +1 from me too), but here is a lo-tech alternative:

``````>>> x=np.random.randn(5)
>>> x
array([ 0.25276524,  2.28334499, -1.88221637,  0.69949927,  1.0285625 ])
>>> ['{:.2f}'.format(i) for i in x]
['0.25', '2.28', '-1.88', '0.70', '1.03']
``````

As a function (using the `format()` syntax for formatting):

``````def ndprint(a, format_string ='{0:.2f}'):
print [format_string.format(v,i) for i,v in enumerate(a)]
``````

Usage:

``````>>> ndprint(x)
['0.25', '2.28', '-1.88', '0.70', '1.03']

>>> ndprint(x, '{:10.4e}')
['2.5277e-01', '2.2833e+00', '-1.8822e+00', '6.9950e-01', '1.0286e+00']

>>> ndprint(x, '{:.8g}')
['0.25276524', '2.283345', '-1.8822164', '0.69949927', '1.0285625']
``````

The index of the array is accessible in the format string:

``````>>> ndprint(x, 'Element[{1:d}]={0:.2f}')
['Element[0]=0.25', 'Element[1]=2.28', 'Element[2]=-1.88', 'Element[3]=0.70', 'Element[4]=1.03']
``````

FYI Numpy 1.15 (release date pending) will include a context manager for setting print options locally. This means that the following will work the same as the corresponding example in the accepted answer (by unutbu and Neil G) without having to write your own context manager. E.g., using their example:

``````x = np.random.random(10)
with np.printoptions(precision=3, suppress=True):
print(x)
# [ 0.073  0.461  0.689  0.754  0.624  0.901  0.049  0.582  0.557  0.348]
``````

The gem that makes it all too easy to obtain the result as a string (in today's numpy versions) is hidden in denis answer: `np.array2string`

``````>>> import numpy as np
>>> x=np.random.random(10)
>>> np.array2string(x, formatter={'float_kind':'{0:.3f}'.format})
'[0.599 0.847 0.513 0.155 0.844 0.753 0.920 0.797 0.427 0.420]'
``````

Years later, another one is below. But for everyday use I just

``````np.set_printoptions( threshold=20, edgeitems=10, linewidth=140,
formatter = dict( float = lambda x: "%.3g" % x ))  # float arrays %.3g
``````

``````''' printf( "... %.3g ... %.1f  ...", arg, arg ... ) for numpy arrays too

Example:
printf( """ x: %.3g   A: %.1f   s: %s   B: %s """,
x,        A,        "str",  B )

If `x` and `A` are numbers, this is like `"format" % (x, A, "str", B)` in python.
If they're numpy arrays, each element is printed in its own format:
`x`: e.g. [ 1.23 1.23e-6 ... ]  3 digits
`A`: [ [ 1 digit after the decimal point ... ] ... ]
with the current `np.set_printoptions()`. For example, with
np.set_printoptions( threshold=100, edgeitems=3, suppress=True )
only the edges of big `x` and `A` are printed.
`B` is printed as `str(B)`, for any `B` -- a number, a list, a numpy object ...

`printf()` tries to handle too few or too many arguments sensibly,
but this is iffy and subject to change.

How it works:
numpy has a function `np.array2string( A, "%.3g" )` (simplifying a bit).
`printf()` splits the format string, and for format / arg pairs
format: % d e f g
arg: try `np.asanyarray()`
-->  %s  np.array2string( arg, format )
Other formats and non-ndarray args are left alone, formatted as usual.

Notes:

`printf( ... end= file= )` are passed on to the python `print()` function.

Only formats `% [optional width . precision] d e f g` are implemented,
not `%(varname)format` .

%d truncates floats, e.g. 0.9 and -0.9 to 0; %.0f rounds, 0.9 to 1 .
%g is the same as %.6g, 6 digits.
%% is a single "%" character.

The function `sprintf()` returns a long string. For example,
title = sprintf( "%s  m %g  n %g  X %.3g",
__file__, m, n, X )
print( title )
...
pl.title( title )

Module globals:
_fmt = "%.3g"  # default for extra args
_squeeze = np.squeeze  # (n,1) (1,n) -> (n,) print in 1 line not n

http://docs.scipy.org/doc/numpy/reference/generated/numpy.set_printoptions.html
http://docs.python.org/2.7/library/stdtypes.html#string-formatting

'''
# http://stackoverflow.com/questions/2891790/pretty-printing-of-numpy-array

#...............................................................................
from __future__ import division, print_function
import re
import numpy as np

__version__ = "2014-02-03 feb denis"

_splitformat = re.compile( r'''(
%
(?<! %% )  # not %%
-? [ \d . ]*  # optional width.precision
\w
)''', re.X )
# ... %3.0f  ... %g  ... %-10s ...
# -> ['...' '%3.0f' '...' '%g' '...' '%-10s' '...']
# odd len, first or last may be ""

_fmt = "%.3g"  # default for extra args
_squeeze = np.squeeze  # (n,1) (1,n) -> (n,) print in 1 line not n

#...............................................................................
def printf( format, *args, **kwargs ):
print( sprintf( format, *args ), **kwargs )  # end= file=

printf.__doc__ = __doc__

def sprintf( format, *args ):
""" sprintf( "text %.3g text %4.1f ... %s ... ", numpy arrays or ... )
%[defg] array -> np.array2string( formatter= )
"""
args = list(args)
if not isinstance( format, basestring ):
args = [format] + args
format = ""

tf = _splitformat.split( format )  # [ text %e text %f ... ]
nfmt = len(tf) // 2
nargs = len(args)
if nargs < nfmt:
args += (nfmt - nargs) * ["?arg?"]
elif nargs > nfmt:
tf += (nargs - nfmt) * [_fmt, " "]  # default _fmt

for j, arg in enumerate( args ):
fmt = tf[ 2*j + 1 ]
if arg is None \
or isinstance( arg, basestring ) \
or (hasattr( arg, "__iter__" ) and len(arg) == 0):
tf[ 2*j + 1 ] = "%s"  # %f -> %s, not error
continue
args[j], isarray = _tonumpyarray(arg)
if isarray  and fmt[-1] in "defgEFG":
tf[ 2*j + 1 ] = "%s"
fmtfunc = (lambda x: fmt % x)
formatter = dict( float_kind=fmtfunc, int=fmtfunc )
args[j] = np.array2string( args[j], formatter=formatter )
try:
return "".join(tf) % tuple(args)
except TypeError:  # shouldn't happen
print( "error: tf %s  types %s" % (tf, map( type, args )))
raise

def _tonumpyarray( a ):
""" a, isarray = _tonumpyarray( a )
->  scalar, False
np.asanyarray(a), float or int
a, False
"""
a = getattr( a, "value", a )  # cvxpy
if np.isscalar(a):
return a, False
if hasattr( a, "__iter__" )  and len(a) == 0:
return a, False
try:
# map .value ?
a = np.asanyarray( a )
except ValueError:
return a, False
if hasattr( a, "dtype" )  and a.dtype.kind in "fi":  # complex ?
if callable( _squeeze ):
a = _squeeze( a )  # np.squeeze
return a, True
else:
return a, False

#...............................................................................
if __name__ == "__main__":
import sys

n = 5
seed = 0
# run this.py n= ...  in sh or ipython
for arg in sys.argv[1:]:
exec( arg )
np.set_printoptions( 1, threshold=4, edgeitems=2, linewidth=80, suppress=True )
np.random.seed(seed)

A = np.random.exponential( size=(n,n) ) ** 10
x = A[0]

printf( "x: %.3g  \nA: %.1f  \ns: %s  \nB: %s ",
x,         A,         "str",   A )
printf( "x %%d: %d", x )
printf( "x %%.0f: %.0f", x )
printf( "x %%.1e: %.1e", x )
printf( "x %%g: %g", x )
printf( "x %%s uses np printoptions: %s", x )

printf( "x with default _fmt: ", x )
printf( "no args" )
printf( "too few args: %g %g", x )
printf( x )
printf( x, x )
printf( None )
printf( "[]:", [] )
printf( "[3]:", [3] )
printf( np.array( [] ))
printf( [[]] )  # squeeze
``````

And here is what I use, and it's pretty uncomplicated:

``````print(np.vectorize("%.2f".__mod__)(sparse))
``````

The numpy arrays have the method `round(precision)` which returns a new numpy array with elements rounded accordingly.

``````import numpy as np

x = np.random.random([5,5])
print(x.round(3))
``````
• This worked for me when passing the array to a matplotlib ylabel, thanks
– Hans
Apr 22, 2020 at 13:10

Was surprised to not see `around` method mentioned - means no messing with print options.

``````import numpy as np

x = np.random.random([5,5])
print(np.around(x,decimals=3))

Output:
[[0.475 0.239 0.183 0.991 0.171]
[0.231 0.188 0.235 0.335 0.049]
[0.87  0.212 0.219 0.9   0.3  ]
[0.628 0.791 0.409 0.5   0.319]
[0.614 0.84  0.812 0.4   0.307]]
``````
• But it does mean creating a second copy of the array each time you want to print it out, which might dissuade some use cases. Jan 14, 2021 at 12:59

I often want different columns to have different formats. Here is how I print a simple 2D array using some variety in the formatting by converting (slices of) my NumPy array to a tuple:

``````import numpy as np
dat = np.random.random((10,11))*100  # Array of random values between 0 and 100
print(dat)                           # Lines get truncated and are hard to read
for i in range(10):
print((4*"%6.2f"+7*"%9.4f") % tuple(dat[i,:]))
``````

I find that the usual float format {:9.5f} works properly -- suppressing small-value e-notations -- when displaying a list or an array using a loop. But that format sometimes fails to suppress its e-notation when a formatter has several items in a single print statement. For example:

``````import numpy as np
np.set_printoptions(suppress=True)
a3 = 4E-3
a4 = 4E-4
a5 = 4E-5
a6 = 4E-6
a7 = 4E-7
a8 = 4E-8
#--first, display separate numbers-----------
print('Case 3:  a3, a4, a5:             {:9.5f}{:9.5f}{:9.5f}'.format(a3,a4,a5))
print('Case 4:  a3, a4, a5, a6:         {:9.5f}{:9.5f}{:9.5f}{:9.5}'.format(a3,a4,a5,a6))
print('Case 5:  a3, a4, a5, a6, a7:     {:9.5f}{:9.5f}{:9.5f}{:9.5}{:9.5f}'.format(a3,a4,a5,a6,a7))
print('Case 6:  a3, a4, a5, a6, a7, a8: {:9.5f}{:9.5f}{:9.5f}{:9.5f}{:9.5}{:9.5f}'.format(a3,a4,a5,a6,a7,a8))
#---second, display a list using a loop----------
myList = [a3,a4,a5,a6,a7,a8]
print('List 6:  a3, a4, a5, a6, a7, a8: ', end='')
for x in myList:
print('{:9.5f}'.format(x), end='')
print()
#---third, display a numpy array using a loop------------
myArray = np.array(myList)
print('Array 6: a3, a4, a5, a6, a7, a8: ', end='')
for x in myArray:
print('{:9.5f}'.format(x), end='')
print()
``````

My results show the bug in cases 4, 5, and 6:

``````Case 3:  a3, a4, a5:               0.00400  0.00040  0.00004
Case 4:  a3, a4, a5, a6:           0.00400  0.00040  0.00004    4e-06
Case 5:  a3, a4, a5, a6, a7:       0.00400  0.00040  0.00004    4e-06  0.00000
Case 6:  a3, a4, a5, a6, a7, a8:   0.00400  0.00040  0.00004  0.00000    4e-07  0.00000
List 6:  a3, a4, a5, a6, a7, a8:   0.00400  0.00040  0.00004  0.00000  0.00000  0.00000
Array 6: a3, a4, a5, a6, a7, a8:   0.00400  0.00040  0.00004  0.00000  0.00000  0.00000
``````

I have no explanation for this, and therefore I always use a loop for floating output of multiple values.

I use

``````def np_print(array,fmt="10.5f"):
print (array.size*("{:"+fmt+"}")).format(*array)
``````

It's not difficult to modify it for multi-dimensional arrays.

`numpy.char.mod` may also be useful, depending on the details of your application e.g.:`numpy.char.mod('Value=%4.2f', numpy.arange(5, 10, 0.1))` will return a string array with elements "Value=5.00", "Value=5.10" etc. (as a somewhat contrived example).

Yet another option is to use the `decimal` module:

``````import numpy as np
from decimal import *

arr = np.array([  56.83,  385.3 ,    6.65,  126.63,   85.76,  192.72,  112.81, 10.55])
arr2 = [str(Decimal(i).quantize(Decimal('.01'))) for i in arr]

# ['56.83', '385.30', '6.65', '126.63', '85.76', '192.72', '112.81', '10.55']
``````