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"""Array printing function | |
$Id: arrayprint.py,v 1.9 2005/09/13 13:58:44 teoliphant Exp $ | |
""" | |
__all__ = ["array2string", "array_str", "array_repr", "set_string_function", | |
"set_printoptions", "get_printoptions", "printoptions", | |
"format_float_positional", "format_float_scientific"] | |
__docformat__ = 'restructuredtext' | |
# | |
# Written by Konrad Hinsen <[email protected]> | |
# last revision: 1996-3-13 | |
# modified by Jim Hugunin 1997-3-3 for repr's and str's (and other details) | |
# and by Perry Greenfield 2000-4-1 for numarray | |
# and by Travis Oliphant 2005-8-22 for numpy | |
# Note: Both scalartypes.c.src and arrayprint.py implement strs for numpy | |
# scalars but for different purposes. scalartypes.c.src has str/reprs for when | |
# the scalar is printed on its own, while arrayprint.py has strs for when | |
# scalars are printed inside an ndarray. Only the latter strs are currently | |
# user-customizable. | |
import functools | |
import numbers | |
try: | |
from _thread import get_ident | |
except ImportError: | |
from _dummy_thread import get_ident | |
import numpy as np | |
from . import numerictypes as _nt | |
from .umath import absolute, isinf, isfinite, isnat | |
from . import multiarray | |
from .multiarray import (array, dragon4_positional, dragon4_scientific, | |
datetime_as_string, datetime_data, ndarray, | |
set_legacy_print_mode) | |
from .fromnumeric import any | |
from .numeric import concatenate, asarray, errstate | |
from .numerictypes import (longlong, intc, int_, float_, complex_, bool_, | |
flexible) | |
from .overrides import array_function_dispatch, set_module | |
import operator | |
import warnings | |
import contextlib | |
_format_options = { | |
'edgeitems': 3, # repr N leading and trailing items of each dimension | |
'threshold': 1000, # total items > triggers array summarization | |
'floatmode': 'maxprec', | |
'precision': 8, # precision of floating point representations | |
'suppress': False, # suppress printing small floating values in exp format | |
'linewidth': 75, | |
'nanstr': 'nan', | |
'infstr': 'inf', | |
'sign': '-', | |
'formatter': None, | |
'legacy': False} | |
def _make_options_dict(precision=None, threshold=None, edgeitems=None, | |
linewidth=None, suppress=None, nanstr=None, infstr=None, | |
sign=None, formatter=None, floatmode=None, legacy=None): | |
""" make a dictionary out of the non-None arguments, plus sanity checks """ | |
options = {k: v for k, v in locals().items() if v is not None} | |
if suppress is not None: | |
options['suppress'] = bool(suppress) | |
modes = ['fixed', 'unique', 'maxprec', 'maxprec_equal'] | |
if floatmode not in modes + [None]: | |
raise ValueError("floatmode option must be one of " + | |
", ".join('"{}"'.format(m) for m in modes)) | |
if sign not in [None, '-', '+', ' ']: | |
raise ValueError("sign option must be one of ' ', '+', or '-'") | |
if legacy not in [None, False, '1.13']: | |
warnings.warn("legacy printing option can currently only be '1.13' or " | |
"`False`", stacklevel=3) | |
if threshold is not None: | |
# forbid the bad threshold arg suggested by stack overflow, gh-12351 | |
if not isinstance(threshold, numbers.Number): | |
raise TypeError("threshold must be numeric") | |
if np.isnan(threshold): | |
raise ValueError("threshold must be non-NAN, try " | |
"sys.maxsize for untruncated representation") | |
if precision is not None: | |
# forbid the bad precision arg as suggested by issue #18254 | |
try: | |
options['precision'] = operator.index(precision) | |
except TypeError as e: | |
raise TypeError('precision must be an integer') from e | |
return options | |
def set_printoptions(precision=None, threshold=None, edgeitems=None, | |
linewidth=None, suppress=None, nanstr=None, infstr=None, | |
formatter=None, sign=None, floatmode=None, *, legacy=None): | |
""" | |
Set printing options. | |
These options determine the way floating point numbers, arrays and | |
other NumPy objects are displayed. | |
Parameters | |
---------- | |
precision : int or None, optional | |
Number of digits of precision for floating point output (default 8). | |
May be None if `floatmode` is not `fixed`, to print as many digits as | |
necessary to uniquely specify the value. | |
threshold : int, optional | |
Total number of array elements which trigger summarization | |
rather than full repr (default 1000). | |
To always use the full repr without summarization, pass `sys.maxsize`. | |
edgeitems : int, optional | |
Number of array items in summary at beginning and end of | |
each dimension (default 3). | |
linewidth : int, optional | |
The number of characters per line for the purpose of inserting | |
line breaks (default 75). | |
suppress : bool, optional | |
If True, always print floating point numbers using fixed point | |
notation, in which case numbers equal to zero in the current precision | |
will print as zero. If False, then scientific notation is used when | |
absolute value of the smallest number is < 1e-4 or the ratio of the | |
maximum absolute value to the minimum is > 1e3. The default is False. | |
nanstr : str, optional | |
String representation of floating point not-a-number (default nan). | |
infstr : str, optional | |
String representation of floating point infinity (default inf). | |
sign : string, either '-', '+', or ' ', optional | |
Controls printing of the sign of floating-point types. If '+', always | |
print the sign of positive values. If ' ', always prints a space | |
(whitespace character) in the sign position of positive values. If | |
'-', omit the sign character of positive values. (default '-') | |
formatter : dict of callables, optional | |
If not None, the keys should indicate the type(s) that the respective | |
formatting function applies to. Callables should return a string. | |
Types that are not specified (by their corresponding keys) are handled | |
by the default formatters. Individual types for which a formatter | |
can be set are: | |
- 'bool' | |
- 'int' | |
- 'timedelta' : a `numpy.timedelta64` | |
- 'datetime' : a `numpy.datetime64` | |
- 'float' | |
- 'longfloat' : 128-bit floats | |
- 'complexfloat' | |
- 'longcomplexfloat' : composed of two 128-bit floats | |
- 'numpystr' : types `numpy.string_` and `numpy.unicode_` | |
- 'object' : `np.object_` arrays | |
Other keys that can be used to set a group of types at once are: | |
- 'all' : sets all types | |
- 'int_kind' : sets 'int' | |
- 'float_kind' : sets 'float' and 'longfloat' | |
- 'complex_kind' : sets 'complexfloat' and 'longcomplexfloat' | |
- 'str_kind' : sets 'numpystr' | |
floatmode : str, optional | |
Controls the interpretation of the `precision` option for | |
floating-point types. Can take the following values | |
(default maxprec_equal): | |
* 'fixed': Always print exactly `precision` fractional digits, | |
even if this would print more or fewer digits than | |
necessary to specify the value uniquely. | |
* 'unique': Print the minimum number of fractional digits necessary | |
to represent each value uniquely. Different elements may | |
have a different number of digits. The value of the | |
`precision` option is ignored. | |
* 'maxprec': Print at most `precision` fractional digits, but if | |
an element can be uniquely represented with fewer digits | |
only print it with that many. | |
* 'maxprec_equal': Print at most `precision` fractional digits, | |
but if every element in the array can be uniquely | |
represented with an equal number of fewer digits, use that | |
many digits for all elements. | |
legacy : string or `False`, optional | |
If set to the string `'1.13'` enables 1.13 legacy printing mode. This | |
approximates numpy 1.13 print output by including a space in the sign | |
position of floats and different behavior for 0d arrays. If set to | |
`False`, disables legacy mode. Unrecognized strings will be ignored | |
with a warning for forward compatibility. | |
.. versionadded:: 1.14.0 | |
See Also | |
-------- | |
get_printoptions, printoptions, set_string_function, array2string | |
Notes | |
----- | |
`formatter` is always reset with a call to `set_printoptions`. | |
Use `printoptions` as a context manager to set the values temporarily. | |
Examples | |
-------- | |
Floating point precision can be set: | |
>>> np.set_printoptions(precision=4) | |
>>> np.array([1.123456789]) | |
[1.1235] | |
Long arrays can be summarised: | |
>>> np.set_printoptions(threshold=5) | |
>>> np.arange(10) | |
array([0, 1, 2, ..., 7, 8, 9]) | |
Small results can be suppressed: | |
>>> eps = np.finfo(float).eps | |
>>> x = np.arange(4.) | |
>>> x**2 - (x + eps)**2 | |
array([-4.9304e-32, -4.4409e-16, 0.0000e+00, 0.0000e+00]) | |
>>> np.set_printoptions(suppress=True) | |
>>> x**2 - (x + eps)**2 | |
array([-0., -0., 0., 0.]) | |
A custom formatter can be used to display array elements as desired: | |
>>> np.set_printoptions(formatter={'all':lambda x: 'int: '+str(-x)}) | |
>>> x = np.arange(3) | |
>>> x | |
array([int: 0, int: -1, int: -2]) | |
>>> np.set_printoptions() # formatter gets reset | |
>>> x | |
array([0, 1, 2]) | |
To put back the default options, you can use: | |
>>> np.set_printoptions(edgeitems=3, infstr='inf', | |
... linewidth=75, nanstr='nan', precision=8, | |
... suppress=False, threshold=1000, formatter=None) | |
Also to temporarily override options, use `printoptions` as a context manager: | |
>>> with np.printoptions(precision=2, suppress=True, threshold=5): | |
... np.linspace(0, 10, 10) | |
array([ 0. , 1.11, 2.22, ..., 7.78, 8.89, 10. ]) | |
""" | |
opt = _make_options_dict(precision, threshold, edgeitems, linewidth, | |
suppress, nanstr, infstr, sign, formatter, | |
floatmode, legacy) | |
# formatter is always reset | |
opt['formatter'] = formatter | |
_format_options.update(opt) | |
# set the C variable for legacy mode | |
if _format_options['legacy'] == '1.13': | |
set_legacy_print_mode(113) | |
# reset the sign option in legacy mode to avoid confusion | |
_format_options['sign'] = '-' | |
elif _format_options['legacy'] is False: | |
set_legacy_print_mode(0) | |
def get_printoptions(): | |
""" | |
Return the current print options. | |
Returns | |
------- | |
print_opts : dict | |
Dictionary of current print options with keys | |
- precision : int | |
- threshold : int | |
- edgeitems : int | |
- linewidth : int | |
- suppress : bool | |
- nanstr : str | |
- infstr : str | |
- formatter : dict of callables | |
- sign : str | |
For a full description of these options, see `set_printoptions`. | |
See Also | |
-------- | |
set_printoptions, printoptions, set_string_function | |
""" | |
return _format_options.copy() | |
def printoptions(*args, **kwargs): | |
"""Context manager for setting print options. | |
Set print options for the scope of the `with` block, and restore the old | |
options at the end. See `set_printoptions` for the full description of | |
available options. | |
Examples | |
-------- | |
>>> from numpy.testing import assert_equal | |
>>> with np.printoptions(precision=2): | |
... np.array([2.0]) / 3 | |
array([0.67]) | |
The `as`-clause of the `with`-statement gives the current print options: | |
>>> with np.printoptions(precision=2) as opts: | |
... assert_equal(opts, np.get_printoptions()) | |
See Also | |
-------- | |
set_printoptions, get_printoptions | |
""" | |
opts = np.get_printoptions() | |
try: | |
np.set_printoptions(*args, **kwargs) | |
yield np.get_printoptions() | |
finally: | |
np.set_printoptions(**opts) | |
def _leading_trailing(a, edgeitems, index=()): | |
""" | |
Keep only the N-D corners (leading and trailing edges) of an array. | |
Should be passed a base-class ndarray, since it makes no guarantees about | |
preserving subclasses. | |
""" | |
axis = len(index) | |
if axis == a.ndim: | |
return a[index] | |
if a.shape[axis] > 2*edgeitems: | |
return concatenate(( | |
_leading_trailing(a, edgeitems, index + np.index_exp[ :edgeitems]), | |
_leading_trailing(a, edgeitems, index + np.index_exp[-edgeitems:]) | |
), axis=axis) | |
else: | |
return _leading_trailing(a, edgeitems, index + np.index_exp[:]) | |
def _object_format(o): | |
""" Object arrays containing lists should be printed unambiguously """ | |
if type(o) is list: | |
fmt = 'list({!r})' | |
else: | |
fmt = '{!r}' | |
return fmt.format(o) | |
def repr_format(x): | |
return repr(x) | |
def str_format(x): | |
return str(x) | |
def _get_formatdict(data, *, precision, floatmode, suppress, sign, legacy, | |
formatter, **kwargs): | |
# note: extra arguments in kwargs are ignored | |
# wrapped in lambdas to avoid taking a code path with the wrong type of data | |
formatdict = { | |
'bool': lambda: BoolFormat(data), | |
'int': lambda: IntegerFormat(data), | |
'float': lambda: FloatingFormat( | |
data, precision, floatmode, suppress, sign, legacy=legacy), | |
'longfloat': lambda: FloatingFormat( | |
data, precision, floatmode, suppress, sign, legacy=legacy), | |
'complexfloat': lambda: ComplexFloatingFormat( | |
data, precision, floatmode, suppress, sign, legacy=legacy), | |
'longcomplexfloat': lambda: ComplexFloatingFormat( | |
data, precision, floatmode, suppress, sign, legacy=legacy), | |
'datetime': lambda: DatetimeFormat(data, legacy=legacy), | |
'timedelta': lambda: TimedeltaFormat(data), | |
'object': lambda: _object_format, | |
'void': lambda: str_format, | |
'numpystr': lambda: repr_format} | |
# we need to wrap values in `formatter` in a lambda, so that the interface | |
# is the same as the above values. | |
def indirect(x): | |
return lambda: x | |
if formatter is not None: | |
fkeys = [k for k in formatter.keys() if formatter[k] is not None] | |
if 'all' in fkeys: | |
for key in formatdict.keys(): | |
formatdict[key] = indirect(formatter['all']) | |
if 'int_kind' in fkeys: | |
for key in ['int']: | |
formatdict[key] = indirect(formatter['int_kind']) | |
if 'float_kind' in fkeys: | |
for key in ['float', 'longfloat']: | |
formatdict[key] = indirect(formatter['float_kind']) | |
if 'complex_kind' in fkeys: | |
for key in ['complexfloat', 'longcomplexfloat']: | |
formatdict[key] = indirect(formatter['complex_kind']) | |
if 'str_kind' in fkeys: | |
formatdict['numpystr'] = indirect(formatter['str_kind']) | |
for key in formatdict.keys(): | |
if key in fkeys: | |
formatdict[key] = indirect(formatter[key]) | |
return formatdict | |
def _get_format_function(data, **options): | |
""" | |
find the right formatting function for the dtype_ | |
""" | |
dtype_ = data.dtype | |
dtypeobj = dtype_.type | |
formatdict = _get_formatdict(data, **options) | |
if issubclass(dtypeobj, _nt.bool_): | |
return formatdict['bool']() | |
elif issubclass(dtypeobj, _nt.integer): | |
if issubclass(dtypeobj, _nt.timedelta64): | |
return formatdict['timedelta']() | |
else: | |
return formatdict['int']() | |
elif issubclass(dtypeobj, _nt.floating): | |
if issubclass(dtypeobj, _nt.longfloat): | |
return formatdict['longfloat']() | |
else: | |
return formatdict['float']() | |
elif issubclass(dtypeobj, _nt.complexfloating): | |
if issubclass(dtypeobj, _nt.clongfloat): | |
return formatdict['longcomplexfloat']() | |
else: | |
return formatdict['complexfloat']() | |
elif issubclass(dtypeobj, (_nt.unicode_, _nt.string_)): | |
return formatdict['numpystr']() | |
elif issubclass(dtypeobj, _nt.datetime64): | |
return formatdict['datetime']() | |
elif issubclass(dtypeobj, _nt.object_): | |
return formatdict['object']() | |
elif issubclass(dtypeobj, _nt.void): | |
if dtype_.names is not None: | |
return StructuredVoidFormat.from_data(data, **options) | |
else: | |
return formatdict['void']() | |
else: | |
return formatdict['numpystr']() | |
def _recursive_guard(fillvalue='...'): | |
""" | |
Like the python 3.2 reprlib.recursive_repr, but forwards *args and **kwargs | |
Decorates a function such that if it calls itself with the same first | |
argument, it returns `fillvalue` instead of recursing. | |
Largely copied from reprlib.recursive_repr | |
""" | |
def decorating_function(f): | |
repr_running = set() | |
def wrapper(self, *args, **kwargs): | |
key = id(self), get_ident() | |
if key in repr_running: | |
return fillvalue | |
repr_running.add(key) | |
try: | |
return f(self, *args, **kwargs) | |
finally: | |
repr_running.discard(key) | |
return wrapper | |
return decorating_function | |
# gracefully handle recursive calls, when object arrays contain themselves | |
def _array2string(a, options, separator=' ', prefix=""): | |
# The formatter __init__s in _get_format_function cannot deal with | |
# subclasses yet, and we also need to avoid recursion issues in | |
# _formatArray with subclasses which return 0d arrays in place of scalars | |
data = asarray(a) | |
if a.shape == (): | |
a = data | |
if a.size > options['threshold']: | |
summary_insert = "..." | |
data = _leading_trailing(data, options['edgeitems']) | |
else: | |
summary_insert = "" | |
# find the right formatting function for the array | |
format_function = _get_format_function(data, **options) | |
# skip over "[" | |
next_line_prefix = " " | |
# skip over array( | |
next_line_prefix += " "*len(prefix) | |
lst = _formatArray(a, format_function, options['linewidth'], | |
next_line_prefix, separator, options['edgeitems'], | |
summary_insert, options['legacy']) | |
return lst | |
def _array2string_dispatcher( | |
a, max_line_width=None, precision=None, | |
suppress_small=None, separator=None, prefix=None, | |
style=None, formatter=None, threshold=None, | |
edgeitems=None, sign=None, floatmode=None, suffix=None, | |
*, legacy=None): | |
return (a,) | |
def array2string(a, max_line_width=None, precision=None, | |
suppress_small=None, separator=' ', prefix="", | |
style=np._NoValue, formatter=None, threshold=None, | |
edgeitems=None, sign=None, floatmode=None, suffix="", | |
*, legacy=None): | |
""" | |
Return a string representation of an array. | |
Parameters | |
---------- | |
a : ndarray | |
Input array. | |
max_line_width : int, optional | |
Inserts newlines if text is longer than `max_line_width`. | |
Defaults to ``numpy.get_printoptions()['linewidth']``. | |
precision : int or None, optional | |
Floating point precision. | |
Defaults to ``numpy.get_printoptions()['precision']``. | |
suppress_small : bool, optional | |
Represent numbers "very close" to zero as zero; default is False. | |
Very close is defined by precision: if the precision is 8, e.g., | |
numbers smaller (in absolute value) than 5e-9 are represented as | |
zero. | |
Defaults to ``numpy.get_printoptions()['suppress']``. | |
separator : str, optional | |
Inserted between elements. | |
prefix : str, optional | |
suffix : str, optional | |
The length of the prefix and suffix strings are used to respectively | |
align and wrap the output. An array is typically printed as:: | |
prefix + array2string(a) + suffix | |
The output is left-padded by the length of the prefix string, and | |
wrapping is forced at the column ``max_line_width - len(suffix)``. | |
It should be noted that the content of prefix and suffix strings are | |
not included in the output. | |
style : _NoValue, optional | |
Has no effect, do not use. | |
.. deprecated:: 1.14.0 | |
formatter : dict of callables, optional | |
If not None, the keys should indicate the type(s) that the respective | |
formatting function applies to. Callables should return a string. | |
Types that are not specified (by their corresponding keys) are handled | |
by the default formatters. Individual types for which a formatter | |
can be set are: | |
- 'bool' | |
- 'int' | |
- 'timedelta' : a `numpy.timedelta64` | |
- 'datetime' : a `numpy.datetime64` | |
- 'float' | |
- 'longfloat' : 128-bit floats | |
- 'complexfloat' | |
- 'longcomplexfloat' : composed of two 128-bit floats | |
- 'void' : type `numpy.void` | |
- 'numpystr' : types `numpy.string_` and `numpy.unicode_` | |
Other keys that can be used to set a group of types at once are: | |
- 'all' : sets all types | |
- 'int_kind' : sets 'int' | |
- 'float_kind' : sets 'float' and 'longfloat' | |
- 'complex_kind' : sets 'complexfloat' and 'longcomplexfloat' | |
- 'str_kind' : sets 'numpystr' | |
threshold : int, optional | |
Total number of array elements which trigger summarization | |
rather than full repr. | |
Defaults to ``numpy.get_printoptions()['threshold']``. | |
edgeitems : int, optional | |
Number of array items in summary at beginning and end of | |
each dimension. | |
Defaults to ``numpy.get_printoptions()['edgeitems']``. | |
sign : string, either '-', '+', or ' ', optional | |
Controls printing of the sign of floating-point types. If '+', always | |
print the sign of positive values. If ' ', always prints a space | |
(whitespace character) in the sign position of positive values. If | |
'-', omit the sign character of positive values. | |
Defaults to ``numpy.get_printoptions()['sign']``. | |
floatmode : str, optional | |
Controls the interpretation of the `precision` option for | |
floating-point types. | |
Defaults to ``numpy.get_printoptions()['floatmode']``. | |
Can take the following values: | |
- 'fixed': Always print exactly `precision` fractional digits, | |
even if this would print more or fewer digits than | |
necessary to specify the value uniquely. | |
- 'unique': Print the minimum number of fractional digits necessary | |
to represent each value uniquely. Different elements may | |
have a different number of digits. The value of the | |
`precision` option is ignored. | |
- 'maxprec': Print at most `precision` fractional digits, but if | |
an element can be uniquely represented with fewer digits | |
only print it with that many. | |
- 'maxprec_equal': Print at most `precision` fractional digits, | |
but if every element in the array can be uniquely | |
represented with an equal number of fewer digits, use that | |
many digits for all elements. | |
legacy : string or `False`, optional | |
If set to the string `'1.13'` enables 1.13 legacy printing mode. This | |
approximates numpy 1.13 print output by including a space in the sign | |
position of floats and different behavior for 0d arrays. If set to | |
`False`, disables legacy mode. Unrecognized strings will be ignored | |
with a warning for forward compatibility. | |
.. versionadded:: 1.14.0 | |
Returns | |
------- | |
array_str : str | |
String representation of the array. | |
Raises | |
------ | |
TypeError | |
if a callable in `formatter` does not return a string. | |
See Also | |
-------- | |
array_str, array_repr, set_printoptions, get_printoptions | |
Notes | |
----- | |
If a formatter is specified for a certain type, the `precision` keyword is | |
ignored for that type. | |
This is a very flexible function; `array_repr` and `array_str` are using | |
`array2string` internally so keywords with the same name should work | |
identically in all three functions. | |
Examples | |
-------- | |
>>> x = np.array([1e-16,1,2,3]) | |
>>> np.array2string(x, precision=2, separator=',', | |
... suppress_small=True) | |
'[0.,1.,2.,3.]' | |
>>> x = np.arange(3.) | |
>>> np.array2string(x, formatter={'float_kind':lambda x: "%.2f" % x}) | |
'[0.00 1.00 2.00]' | |
>>> x = np.arange(3) | |
>>> np.array2string(x, formatter={'int':lambda x: hex(x)}) | |
'[0x0 0x1 0x2]' | |
""" | |
overrides = _make_options_dict(precision, threshold, edgeitems, | |
max_line_width, suppress_small, None, None, | |
sign, formatter, floatmode, legacy) | |
options = _format_options.copy() | |
options.update(overrides) | |
if options['legacy'] == '1.13': | |
if style is np._NoValue: | |
style = repr | |
if a.shape == () and a.dtype.names is None: | |
return style(a.item()) | |
elif style is not np._NoValue: | |
# Deprecation 11-9-2017 v1.14 | |
warnings.warn("'style' argument is deprecated and no longer functional" | |
" except in 1.13 'legacy' mode", | |
DeprecationWarning, stacklevel=3) | |
if options['legacy'] != '1.13': | |
options['linewidth'] -= len(suffix) | |
# treat as a null array if any of shape elements == 0 | |
if a.size == 0: | |
return "[]" | |
return _array2string(a, options, separator, prefix) | |
def _extendLine(s, line, word, line_width, next_line_prefix, legacy): | |
needs_wrap = len(line) + len(word) > line_width | |
if legacy != '1.13': | |
# don't wrap lines if it won't help | |
if len(line) <= len(next_line_prefix): | |
needs_wrap = False | |
if needs_wrap: | |
s += line.rstrip() + "\n" | |
line = next_line_prefix | |
line += word | |
return s, line | |
def _extendLine_pretty(s, line, word, line_width, next_line_prefix, legacy): | |
""" | |
Extends line with nicely formatted (possibly multi-line) string ``word``. | |
""" | |
words = word.splitlines() | |
if len(words) == 1 or legacy == '1.13': | |
return _extendLine(s, line, word, line_width, next_line_prefix, legacy) | |
max_word_length = max(len(word) for word in words) | |
if (len(line) + max_word_length > line_width and | |
len(line) > len(next_line_prefix)): | |
s += line.rstrip() + '\n' | |
line = next_line_prefix + words[0] | |
indent = next_line_prefix | |
else: | |
indent = len(line)*' ' | |
line += words[0] | |
for word in words[1::]: | |
s += line.rstrip() + '\n' | |
line = indent + word | |
suffix_length = max_word_length - len(words[-1]) | |
line += suffix_length*' ' | |
return s, line | |
def _formatArray(a, format_function, line_width, next_line_prefix, | |
separator, edge_items, summary_insert, legacy): | |
"""formatArray is designed for two modes of operation: | |
1. Full output | |
2. Summarized output | |
""" | |
def recurser(index, hanging_indent, curr_width): | |
""" | |
By using this local function, we don't need to recurse with all the | |
arguments. Since this function is not created recursively, the cost is | |
not significant | |
""" | |
axis = len(index) | |
axes_left = a.ndim - axis | |
if axes_left == 0: | |
return format_function(a[index]) | |
# when recursing, add a space to align with the [ added, and reduce the | |
# length of the line by 1 | |
next_hanging_indent = hanging_indent + ' ' | |
if legacy == '1.13': | |
next_width = curr_width | |
else: | |
next_width = curr_width - len(']') | |
a_len = a.shape[axis] | |
show_summary = summary_insert and 2*edge_items < a_len | |
if show_summary: | |
leading_items = edge_items | |
trailing_items = edge_items | |
else: | |
leading_items = 0 | |
trailing_items = a_len | |
# stringify the array with the hanging indent on the first line too | |
s = '' | |
# last axis (rows) - wrap elements if they would not fit on one line | |
if axes_left == 1: | |
# the length up until the beginning of the separator / bracket | |
if legacy == '1.13': | |
elem_width = curr_width - len(separator.rstrip()) | |
else: | |
elem_width = curr_width - max(len(separator.rstrip()), len(']')) | |
line = hanging_indent | |
for i in range(leading_items): | |
word = recurser(index + (i,), next_hanging_indent, next_width) | |
s, line = _extendLine_pretty( | |
s, line, word, elem_width, hanging_indent, legacy) | |
line += separator | |
if show_summary: | |
s, line = _extendLine( | |
s, line, summary_insert, elem_width, hanging_indent, legacy) | |
if legacy == '1.13': | |
line += ", " | |
else: | |
line += separator | |
for i in range(trailing_items, 1, -1): | |
word = recurser(index + (-i,), next_hanging_indent, next_width) | |
s, line = _extendLine_pretty( | |
s, line, word, elem_width, hanging_indent, legacy) | |
line += separator | |
if legacy == '1.13': | |
# width of the separator is not considered on 1.13 | |
elem_width = curr_width | |
word = recurser(index + (-1,), next_hanging_indent, next_width) | |
s, line = _extendLine_pretty( | |
s, line, word, elem_width, hanging_indent, legacy) | |
s += line | |
# other axes - insert newlines between rows | |
else: | |
s = '' | |
line_sep = separator.rstrip() + '\n'*(axes_left - 1) | |
for i in range(leading_items): | |
nested = recurser(index + (i,), next_hanging_indent, next_width) | |
s += hanging_indent + nested + line_sep | |
if show_summary: | |
if legacy == '1.13': | |
# trailing space, fixed nbr of newlines, and fixed separator | |
s += hanging_indent + summary_insert + ", \n" | |
else: | |
s += hanging_indent + summary_insert + line_sep | |
for i in range(trailing_items, 1, -1): | |
nested = recurser(index + (-i,), next_hanging_indent, | |
next_width) | |
s += hanging_indent + nested + line_sep | |
nested = recurser(index + (-1,), next_hanging_indent, next_width) | |
s += hanging_indent + nested | |
# remove the hanging indent, and wrap in [] | |
s = '[' + s[len(hanging_indent):] + ']' | |
return s | |
try: | |
# invoke the recursive part with an initial index and prefix | |
return recurser(index=(), | |
hanging_indent=next_line_prefix, | |
curr_width=line_width) | |
finally: | |
# recursive closures have a cyclic reference to themselves, which | |
# requires gc to collect (gh-10620). To avoid this problem, for | |
# performance and PyPy friendliness, we break the cycle: | |
recurser = None | |
def _none_or_positive_arg(x, name): | |
if x is None: | |
return -1 | |
if x < 0: | |
raise ValueError("{} must be >= 0".format(name)) | |
return x | |
class FloatingFormat: | |
""" Formatter for subtypes of np.floating """ | |
def __init__(self, data, precision, floatmode, suppress_small, sign=False, | |
*, legacy=None): | |
# for backcompatibility, accept bools | |
if isinstance(sign, bool): | |
sign = '+' if sign else '-' | |
self._legacy = legacy | |
if self._legacy == '1.13': | |
# when not 0d, legacy does not support '-' | |
if data.shape != () and sign == '-': | |
sign = ' ' | |
self.floatmode = floatmode | |
if floatmode == 'unique': | |
self.precision = None | |
else: | |
self.precision = precision | |
self.precision = _none_or_positive_arg(self.precision, 'precision') | |
self.suppress_small = suppress_small | |
self.sign = sign | |
self.exp_format = False | |
self.large_exponent = False | |
self.fillFormat(data) | |
def fillFormat(self, data): | |
# only the finite values are used to compute the number of digits | |
finite_vals = data[isfinite(data)] | |
# choose exponential mode based on the non-zero finite values: | |
abs_non_zero = absolute(finite_vals[finite_vals != 0]) | |
if len(abs_non_zero) != 0: | |
max_val = np.max(abs_non_zero) | |
min_val = np.min(abs_non_zero) | |
with errstate(over='ignore'): # division can overflow | |
if max_val >= 1.e8 or (not self.suppress_small and | |
(min_val < 0.0001 or max_val/min_val > 1000.)): | |
self.exp_format = True | |
# do a first pass of printing all the numbers, to determine sizes | |
if len(finite_vals) == 0: | |
self.pad_left = 0 | |
self.pad_right = 0 | |
self.trim = '.' | |
self.exp_size = -1 | |
self.unique = True | |
self.min_digits = None | |
elif self.exp_format: | |
trim, unique = '.', True | |
if self.floatmode == 'fixed' or self._legacy == '1.13': | |
trim, unique = 'k', False | |
strs = (dragon4_scientific(x, precision=self.precision, | |
unique=unique, trim=trim, sign=self.sign == '+') | |
for x in finite_vals) | |
frac_strs, _, exp_strs = zip(*(s.partition('e') for s in strs)) | |
int_part, frac_part = zip(*(s.split('.') for s in frac_strs)) | |
self.exp_size = max(len(s) for s in exp_strs) - 1 | |
self.trim = 'k' | |
self.precision = max(len(s) for s in frac_part) | |
self.min_digits = self.precision | |
self.unique = unique | |
# for back-compat with np 1.13, use 2 spaces & sign and full prec | |
if self._legacy == '1.13': | |
self.pad_left = 3 | |
else: | |
# this should be only 1 or 2. Can be calculated from sign. | |
self.pad_left = max(len(s) for s in int_part) | |
# pad_right is only needed for nan length calculation | |
self.pad_right = self.exp_size + 2 + self.precision | |
else: | |
trim, unique = '.', True | |
if self.floatmode == 'fixed': | |
trim, unique = 'k', False | |
strs = (dragon4_positional(x, precision=self.precision, | |
fractional=True, | |
unique=unique, trim=trim, | |
sign=self.sign == '+') | |
for x in finite_vals) | |
int_part, frac_part = zip(*(s.split('.') for s in strs)) | |
if self._legacy == '1.13': | |
self.pad_left = 1 + max(len(s.lstrip('-+')) for s in int_part) | |
else: | |
self.pad_left = max(len(s) for s in int_part) | |
self.pad_right = max(len(s) for s in frac_part) | |
self.exp_size = -1 | |
self.unique = unique | |
if self.floatmode in ['fixed', 'maxprec_equal']: | |
self.precision = self.min_digits = self.pad_right | |
self.trim = 'k' | |
else: | |
self.trim = '.' | |
self.min_digits = 0 | |
if self._legacy != '1.13': | |
# account for sign = ' ' by adding one to pad_left | |
if self.sign == ' ' and not any(np.signbit(finite_vals)): | |
self.pad_left += 1 | |
# if there are non-finite values, may need to increase pad_left | |
if data.size != finite_vals.size: | |
neginf = self.sign != '-' or any(data[isinf(data)] < 0) | |
nanlen = len(_format_options['nanstr']) | |
inflen = len(_format_options['infstr']) + neginf | |
offset = self.pad_right + 1 # +1 for decimal pt | |
self.pad_left = max(self.pad_left, nanlen - offset, inflen - offset) | |
def __call__(self, x): | |
if not np.isfinite(x): | |
with errstate(invalid='ignore'): | |
if np.isnan(x): | |
sign = '+' if self.sign == '+' else '' | |
ret = sign + _format_options['nanstr'] | |
else: # isinf | |
sign = '-' if x < 0 else '+' if self.sign == '+' else '' | |
ret = sign + _format_options['infstr'] | |
return ' '*(self.pad_left + self.pad_right + 1 - len(ret)) + ret | |
if self.exp_format: | |
return dragon4_scientific(x, | |
precision=self.precision, | |
min_digits=self.min_digits, | |
unique=self.unique, | |
trim=self.trim, | |
sign=self.sign == '+', | |
pad_left=self.pad_left, | |
exp_digits=self.exp_size) | |
else: | |
return dragon4_positional(x, | |
precision=self.precision, | |
min_digits=self.min_digits, | |
unique=self.unique, | |
fractional=True, | |
trim=self.trim, | |
sign=self.sign == '+', | |
pad_left=self.pad_left, | |
pad_right=self.pad_right) | |
def format_float_scientific(x, precision=None, unique=True, trim='k', | |
sign=False, pad_left=None, exp_digits=None, | |
min_digits=None): | |
""" | |
Format a floating-point scalar as a decimal string in scientific notation. | |
Provides control over rounding, trimming and padding. Uses and assumes | |
IEEE unbiased rounding. Uses the "Dragon4" algorithm. | |
Parameters | |
---------- | |
x : python float or numpy floating scalar | |
Value to format. | |
precision : non-negative integer or None, optional | |
Maximum number of digits to print. May be None if `unique` is | |
`True`, but must be an integer if unique is `False`. | |
unique : boolean, optional | |
If `True`, use a digit-generation strategy which gives the shortest | |
representation which uniquely identifies the floating-point number from | |
other values of the same type, by judicious rounding. If `precision` | |
is given fewer digits than necessary can be printed. If `min_digits` | |
is given more can be printed, in which cases the last digit is rounded | |
with unbiased rounding. | |
If `False`, digits are generated as if printing an infinite-precision | |
value and stopping after `precision` digits, rounding the remaining | |
value with unbiased rounding | |
trim : one of 'k', '.', '0', '-', optional | |
Controls post-processing trimming of trailing digits, as follows: | |
* 'k' : keep trailing zeros, keep decimal point (no trimming) | |
* '.' : trim all trailing zeros, leave decimal point | |
* '0' : trim all but the zero before the decimal point. Insert the | |
zero if it is missing. | |
* '-' : trim trailing zeros and any trailing decimal point | |
sign : boolean, optional | |
Whether to show the sign for positive values. | |
pad_left : non-negative integer, optional | |
Pad the left side of the string with whitespace until at least that | |
many characters are to the left of the decimal point. | |
exp_digits : non-negative integer, optional | |
Pad the exponent with zeros until it contains at least this many digits. | |
If omitted, the exponent will be at least 2 digits. | |
min_digits : non-negative integer or None, optional | |
Minimum number of digits to print. This only has an effect for | |
`unique=True`. In that case more digits than necessary to uniquely | |
identify the value may be printed and rounded unbiased. | |
-- versionadded:: 1.21.0 | |
Returns | |
------- | |
rep : string | |
The string representation of the floating point value | |
See Also | |
-------- | |
format_float_positional | |
Examples | |
-------- | |
>>> np.format_float_scientific(np.float32(np.pi)) | |
'3.1415927e+00' | |
>>> s = np.float32(1.23e24) | |
>>> np.format_float_scientific(s, unique=False, precision=15) | |
'1.230000071797338e+24' | |
>>> np.format_float_scientific(s, exp_digits=4) | |
'1.23e+0024' | |
""" | |
precision = _none_or_positive_arg(precision, 'precision') | |
pad_left = _none_or_positive_arg(pad_left, 'pad_left') | |
exp_digits = _none_or_positive_arg(exp_digits, 'exp_digits') | |
min_digits = _none_or_positive_arg(min_digits, 'min_digits') | |
if min_digits > 0 and precision > 0 and min_digits > precision: | |
raise ValueError("min_digits must be less than or equal to precision") | |
return dragon4_scientific(x, precision=precision, unique=unique, | |
trim=trim, sign=sign, pad_left=pad_left, | |
exp_digits=exp_digits, min_digits=min_digits) | |
def format_float_positional(x, precision=None, unique=True, | |
fractional=True, trim='k', sign=False, | |
pad_left=None, pad_right=None, min_digits=None): | |
""" | |
Format a floating-point scalar as a decimal string in positional notation. | |
Provides control over rounding, trimming and padding. Uses and assumes | |
IEEE unbiased rounding. Uses the "Dragon4" algorithm. | |
Parameters | |
---------- | |
x : python float or numpy floating scalar | |
Value to format. | |
precision : non-negative integer or None, optional | |
Maximum number of digits to print. May be None if `unique` is | |
`True`, but must be an integer if unique is `False`. | |
unique : boolean, optional | |
If `True`, use a digit-generation strategy which gives the shortest | |
representation which uniquely identifies the floating-point number from | |
other values of the same type, by judicious rounding. If `precision` | |
is given fewer digits than necessary can be printed, or if `min_digits` | |
is given more can be printed, in which cases the last digit is rounded | |
with unbiased rounding. | |
If `False`, digits are generated as if printing an infinite-precision | |
value and stopping after `precision` digits, rounding the remaining | |
value with unbiased rounding | |
fractional : boolean, optional | |
If `True`, the cutoffs of `precision` and `min_digits` refer to the | |
total number of digits after the decimal point, including leading | |
zeros. | |
If `False`, `precision` and `min_digits` refer to the total number of | |
significant digits, before or after the decimal point, ignoring leading | |
zeros. | |
trim : one of 'k', '.', '0', '-', optional | |
Controls post-processing trimming of trailing digits, as follows: | |
* 'k' : keep trailing zeros, keep decimal point (no trimming) | |
* '.' : trim all trailing zeros, leave decimal point | |
* '0' : trim all but the zero before the decimal point. Insert the | |
zero if it is missing. | |
* '-' : trim trailing zeros and any trailing decimal point | |
sign : boolean, optional | |
Whether to show the sign for positive values. | |
pad_left : non-negative integer, optional | |
Pad the left side of the string with whitespace until at least that | |
many characters are to the left of the decimal point. | |
pad_right : non-negative integer, optional | |
Pad the right side of the string with whitespace until at least that | |
many characters are to the right of the decimal point. | |
min_digits : non-negative integer or None, optional | |
Minimum number of digits to print. Only has an effect if `unique=True` | |
in which case additional digits past those necessary to uniquely | |
identify the value may be printed, rounding the last additional digit. | |
-- versionadded:: 1.21.0 | |
Returns | |
------- | |
rep : string | |
The string representation of the floating point value | |
See Also | |
-------- | |
format_float_scientific | |
Examples | |
-------- | |
>>> np.format_float_positional(np.float32(np.pi)) | |
'3.1415927' | |
>>> np.format_float_positional(np.float16(np.pi)) | |
'3.14' | |
>>> np.format_float_positional(np.float16(0.3)) | |
'0.3' | |
>>> np.format_float_positional(np.float16(0.3), unique=False, precision=10) | |
'0.3000488281' | |
""" | |
precision = _none_or_positive_arg(precision, 'precision') | |
pad_left = _none_or_positive_arg(pad_left, 'pad_left') | |
pad_right = _none_or_positive_arg(pad_right, 'pad_right') | |
min_digits = _none_or_positive_arg(min_digits, 'min_digits') | |
if not fractional and precision == 0: | |
raise ValueError("precision must be greater than 0 if " | |
"fractional=False") | |
if min_digits > 0 and precision > 0 and min_digits > precision: | |
raise ValueError("min_digits must be less than or equal to precision") | |
return dragon4_positional(x, precision=precision, unique=unique, | |
fractional=fractional, trim=trim, | |
sign=sign, pad_left=pad_left, | |
pad_right=pad_right, min_digits=min_digits) | |
class IntegerFormat: | |
def __init__(self, data): | |
if data.size > 0: | |
max_str_len = max(len(str(np.max(data))), | |
len(str(np.min(data)))) | |
else: | |
max_str_len = 0 | |
self.format = '%{}d'.format(max_str_len) | |
def __call__(self, x): | |
return self.format % x | |
class BoolFormat: | |
def __init__(self, data, **kwargs): | |
# add an extra space so " True" and "False" have the same length and | |
# array elements align nicely when printed, except in 0d arrays | |
self.truestr = ' True' if data.shape != () else 'True' | |
def __call__(self, x): | |
return self.truestr if x else "False" | |
class ComplexFloatingFormat: | |
""" Formatter for subtypes of np.complexfloating """ | |
def __init__(self, x, precision, floatmode, suppress_small, | |
sign=False, *, legacy=None): | |
# for backcompatibility, accept bools | |
if isinstance(sign, bool): | |
sign = '+' if sign else '-' | |
floatmode_real = floatmode_imag = floatmode | |
if legacy == '1.13': | |
floatmode_real = 'maxprec_equal' | |
floatmode_imag = 'maxprec' | |
self.real_format = FloatingFormat( | |
x.real, precision, floatmode_real, suppress_small, | |
sign=sign, legacy=legacy | |
) | |
self.imag_format = FloatingFormat( | |
x.imag, precision, floatmode_imag, suppress_small, | |
sign='+', legacy=legacy | |
) | |
def __call__(self, x): | |
r = self.real_format(x.real) | |
i = self.imag_format(x.imag) | |
# add the 'j' before the terminal whitespace in i | |
sp = len(i.rstrip()) | |
i = i[:sp] + 'j' + i[sp:] | |
return r + i | |
class _TimelikeFormat: | |
def __init__(self, data): | |
non_nat = data[~isnat(data)] | |
if len(non_nat) > 0: | |
# Max str length of non-NaT elements | |
max_str_len = max(len(self._format_non_nat(np.max(non_nat))), | |
len(self._format_non_nat(np.min(non_nat)))) | |
else: | |
max_str_len = 0 | |
if len(non_nat) < data.size: | |
# data contains a NaT | |
max_str_len = max(max_str_len, 5) | |
self._format = '%{}s'.format(max_str_len) | |
self._nat = "'NaT'".rjust(max_str_len) | |
def _format_non_nat(self, x): | |
# override in subclass | |
raise NotImplementedError | |
def __call__(self, x): | |
if isnat(x): | |
return self._nat | |
else: | |
return self._format % self._format_non_nat(x) | |
class DatetimeFormat(_TimelikeFormat): | |
def __init__(self, x, unit=None, timezone=None, casting='same_kind', | |
legacy=False): | |
# Get the unit from the dtype | |
if unit is None: | |
if x.dtype.kind == 'M': | |
unit = datetime_data(x.dtype)[0] | |
else: | |
unit = 's' | |
if timezone is None: | |
timezone = 'naive' | |
self.timezone = timezone | |
self.unit = unit | |
self.casting = casting | |
self.legacy = legacy | |
# must be called after the above are configured | |
super().__init__(x) | |
def __call__(self, x): | |
if self.legacy == '1.13': | |
return self._format_non_nat(x) | |
return super().__call__(x) | |
def _format_non_nat(self, x): | |
return "'%s'" % datetime_as_string(x, | |
unit=self.unit, | |
timezone=self.timezone, | |
casting=self.casting) | |
class TimedeltaFormat(_TimelikeFormat): | |
def _format_non_nat(self, x): | |
return str(x.astype('i8')) | |
class SubArrayFormat: | |
def __init__(self, format_function): | |
self.format_function = format_function | |
def __call__(self, arr): | |
if arr.ndim <= 1: | |
return "[" + ", ".join(self.format_function(a) for a in arr) + "]" | |
return "[" + ", ".join(self.__call__(a) for a in arr) + "]" | |
class StructuredVoidFormat: | |
""" | |
Formatter for structured np.void objects. | |
This does not work on structured alias types like np.dtype(('i4', 'i2,i2')), | |
as alias scalars lose their field information, and the implementation | |
relies upon np.void.__getitem__. | |
""" | |
def __init__(self, format_functions): | |
self.format_functions = format_functions | |
def from_data(cls, data, **options): | |
""" | |
This is a second way to initialize StructuredVoidFormat, using the raw data | |
as input. Added to avoid changing the signature of __init__. | |
""" | |
format_functions = [] | |
for field_name in data.dtype.names: | |
format_function = _get_format_function(data[field_name], **options) | |
if data.dtype[field_name].shape != (): | |
format_function = SubArrayFormat(format_function) | |
format_functions.append(format_function) | |
return cls(format_functions) | |
def __call__(self, x): | |
str_fields = [ | |
format_function(field) | |
for field, format_function in zip(x, self.format_functions) | |
] | |
if len(str_fields) == 1: | |
return "({},)".format(str_fields[0]) | |
else: | |
return "({})".format(", ".join(str_fields)) | |
def _void_scalar_repr(x): | |
""" | |
Implements the repr for structured-void scalars. It is called from the | |
scalartypes.c.src code, and is placed here because it uses the elementwise | |
formatters defined above. | |
""" | |
return StructuredVoidFormat.from_data(array(x), **_format_options)(x) | |
_typelessdata = [int_, float_, complex_, bool_] | |
if issubclass(intc, int): | |
_typelessdata.append(intc) | |
if issubclass(longlong, int): | |
_typelessdata.append(longlong) | |
def dtype_is_implied(dtype): | |
""" | |
Determine if the given dtype is implied by the representation of its values. | |
Parameters | |
---------- | |
dtype : dtype | |
Data type | |
Returns | |
------- | |
implied : bool | |
True if the dtype is implied by the representation of its values. | |
Examples | |
-------- | |
>>> np.core.arrayprint.dtype_is_implied(int) | |
True | |
>>> np.array([1, 2, 3], int) | |
array([1, 2, 3]) | |
>>> np.core.arrayprint.dtype_is_implied(np.int8) | |
False | |
>>> np.array([1, 2, 3], np.int8) | |
array([1, 2, 3], dtype=int8) | |
""" | |
dtype = np.dtype(dtype) | |
if _format_options['legacy'] == '1.13' and dtype.type == bool_: | |
return False | |
# not just void types can be structured, and names are not part of the repr | |
if dtype.names is not None: | |
return False | |
return dtype.type in _typelessdata | |
def dtype_short_repr(dtype): | |
""" | |
Convert a dtype to a short form which evaluates to the same dtype. | |
The intent is roughly that the following holds | |
>>> from numpy import * | |
>>> dt = np.int64([1, 2]).dtype | |
>>> assert eval(dtype_short_repr(dt)) == dt | |
""" | |
if dtype.names is not None: | |
# structured dtypes give a list or tuple repr | |
return str(dtype) | |
elif issubclass(dtype.type, flexible): | |
# handle these separately so they don't give garbage like str256 | |
return "'%s'" % str(dtype) | |
typename = dtype.name | |
# quote typenames which can't be represented as python variable names | |
if typename and not (typename[0].isalpha() and typename.isalnum()): | |
typename = repr(typename) | |
return typename | |
def _array_repr_implementation( | |
arr, max_line_width=None, precision=None, suppress_small=None, | |
array2string=array2string): | |
"""Internal version of array_repr() that allows overriding array2string.""" | |
if max_line_width is None: | |
max_line_width = _format_options['linewidth'] | |
if type(arr) is not ndarray: | |
class_name = type(arr).__name__ | |
else: | |
class_name = "array" | |
skipdtype = dtype_is_implied(arr.dtype) and arr.size > 0 | |
prefix = class_name + "(" | |
suffix = ")" if skipdtype else "," | |
if (_format_options['legacy'] == '1.13' and | |
arr.shape == () and not arr.dtype.names): | |
lst = repr(arr.item()) | |
elif arr.size > 0 or arr.shape == (0,): | |
lst = array2string(arr, max_line_width, precision, suppress_small, | |
', ', prefix, suffix=suffix) | |
else: # show zero-length shape unless it is (0,) | |
lst = "[], shape=%s" % (repr(arr.shape),) | |
arr_str = prefix + lst + suffix | |
if skipdtype: | |
return arr_str | |
dtype_str = "dtype={})".format(dtype_short_repr(arr.dtype)) | |
# compute whether we should put dtype on a new line: Do so if adding the | |
# dtype would extend the last line past max_line_width. | |
# Note: This line gives the correct result even when rfind returns -1. | |
last_line_len = len(arr_str) - (arr_str.rfind('\n') + 1) | |
spacer = " " | |
if _format_options['legacy'] == '1.13': | |
if issubclass(arr.dtype.type, flexible): | |
spacer = '\n' + ' '*len(class_name + "(") | |
elif last_line_len + len(dtype_str) + 1 > max_line_width: | |
spacer = '\n' + ' '*len(class_name + "(") | |
return arr_str + spacer + dtype_str | |
def _array_repr_dispatcher( | |
arr, max_line_width=None, precision=None, suppress_small=None): | |
return (arr,) | |
def array_repr(arr, max_line_width=None, precision=None, suppress_small=None): | |
""" | |
Return the string representation of an array. | |
Parameters | |
---------- | |
arr : ndarray | |
Input array. | |
max_line_width : int, optional | |
Inserts newlines if text is longer than `max_line_width`. | |
Defaults to ``numpy.get_printoptions()['linewidth']``. | |
precision : int, optional | |
Floating point precision. | |
Defaults to ``numpy.get_printoptions()['precision']``. | |
suppress_small : bool, optional | |
Represent numbers "very close" to zero as zero; default is False. | |
Very close is defined by precision: if the precision is 8, e.g., | |
numbers smaller (in absolute value) than 5e-9 are represented as | |
zero. | |
Defaults to ``numpy.get_printoptions()['suppress']``. | |
Returns | |
------- | |
string : str | |
The string representation of an array. | |
See Also | |
-------- | |
array_str, array2string, set_printoptions | |
Examples | |
-------- | |
>>> np.array_repr(np.array([1,2])) | |
'array([1, 2])' | |
>>> np.array_repr(np.ma.array([0.])) | |
'MaskedArray([0.])' | |
>>> np.array_repr(np.array([], np.int32)) | |
'array([], dtype=int32)' | |
>>> x = np.array([1e-6, 4e-7, 2, 3]) | |
>>> np.array_repr(x, precision=6, suppress_small=True) | |
'array([0.000001, 0. , 2. , 3. ])' | |
""" | |
return _array_repr_implementation( | |
arr, max_line_width, precision, suppress_small) | |
def _guarded_repr_or_str(v): | |
if isinstance(v, bytes): | |
return repr(v) | |
return str(v) | |
def _array_str_implementation( | |
a, max_line_width=None, precision=None, suppress_small=None, | |
array2string=array2string): | |
"""Internal version of array_str() that allows overriding array2string.""" | |
if (_format_options['legacy'] == '1.13' and | |
a.shape == () and not a.dtype.names): | |
return str(a.item()) | |
# the str of 0d arrays is a special case: It should appear like a scalar, | |
# so floats are not truncated by `precision`, and strings are not wrapped | |
# in quotes. So we return the str of the scalar value. | |
if a.shape == (): | |
# obtain a scalar and call str on it, avoiding problems for subclasses | |
# for which indexing with () returns a 0d instead of a scalar by using | |
# ndarray's getindex. Also guard against recursive 0d object arrays. | |
return _guarded_repr_or_str(np.ndarray.__getitem__(a, ())) | |
return array2string(a, max_line_width, precision, suppress_small, ' ', "") | |
def _array_str_dispatcher( | |
a, max_line_width=None, precision=None, suppress_small=None): | |
return (a,) | |
def array_str(a, max_line_width=None, precision=None, suppress_small=None): | |
""" | |
Return a string representation of the data in an array. | |
The data in the array is returned as a single string. This function is | |
similar to `array_repr`, the difference being that `array_repr` also | |
returns information on the kind of array and its data type. | |
Parameters | |
---------- | |
a : ndarray | |
Input array. | |
max_line_width : int, optional | |
Inserts newlines if text is longer than `max_line_width`. | |
Defaults to ``numpy.get_printoptions()['linewidth']``. | |
precision : int, optional | |
Floating point precision. | |
Defaults to ``numpy.get_printoptions()['precision']``. | |
suppress_small : bool, optional | |
Represent numbers "very close" to zero as zero; default is False. | |
Very close is defined by precision: if the precision is 8, e.g., | |
numbers smaller (in absolute value) than 5e-9 are represented as | |
zero. | |
Defaults to ``numpy.get_printoptions()['suppress']``. | |
See Also | |
-------- | |
array2string, array_repr, set_printoptions | |
Examples | |
-------- | |
>>> np.array_str(np.arange(3)) | |
'[0 1 2]' | |
""" | |
return _array_str_implementation( | |
a, max_line_width, precision, suppress_small) | |
# needed if __array_function__ is disabled | |
_array2string_impl = getattr(array2string, '__wrapped__', array2string) | |
_default_array_str = functools.partial(_array_str_implementation, | |
array2string=_array2string_impl) | |
_default_array_repr = functools.partial(_array_repr_implementation, | |
array2string=_array2string_impl) | |
def set_string_function(f, repr=True): | |
""" | |
Set a Python function to be used when pretty printing arrays. | |
Parameters | |
---------- | |
f : function or None | |
Function to be used to pretty print arrays. The function should expect | |
a single array argument and return a string of the representation of | |
the array. If None, the function is reset to the default NumPy function | |
to print arrays. | |
repr : bool, optional | |
If True (default), the function for pretty printing (``__repr__``) | |
is set, if False the function that returns the default string | |
representation (``__str__``) is set. | |
See Also | |
-------- | |
set_printoptions, get_printoptions | |
Examples | |
-------- | |
>>> def pprint(arr): | |
... return 'HA! - What are you going to do now?' | |
... | |
>>> np.set_string_function(pprint) | |
>>> a = np.arange(10) | |
>>> a | |
HA! - What are you going to do now? | |
>>> _ = a | |
>>> # [0 1 2 3 4 5 6 7 8 9] | |
We can reset the function to the default: | |
>>> np.set_string_function(None) | |
>>> a | |
array([0, 1, 2, 3, 4, 5, 6, 7, 8, 9]) | |
`repr` affects either pretty printing or normal string representation. | |
Note that ``__repr__`` is still affected by setting ``__str__`` | |
because the width of each array element in the returned string becomes | |
equal to the length of the result of ``__str__()``. | |
>>> x = np.arange(4) | |
>>> np.set_string_function(lambda x:'random', repr=False) | |
>>> x.__str__() | |
'random' | |
>>> x.__repr__() | |
'array([0, 1, 2, 3])' | |
""" | |
if f is None: | |
if repr: | |
return multiarray.set_string_function(_default_array_repr, 1) | |
else: | |
return multiarray.set_string_function(_default_array_str, 0) | |
else: | |
return multiarray.set_string_function(f, repr) | |