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import os
import sys
import textwrap
import types
import re
import warnings
from numpy.core.numerictypes import issubclass_, issubsctype, issubdtype
from numpy.core.overrides import set_module
from numpy.core import ndarray, ufunc, asarray
import numpy as np
__all__ = [
'issubclass_', 'issubsctype', 'issubdtype', 'deprecate',
'deprecate_with_doc', 'get_include', 'info', 'source', 'who',
'lookfor', 'byte_bounds', 'safe_eval'
]
def get_include():
"""
Return the directory that contains the NumPy \\*.h header files.
Extension modules that need to compile against NumPy should use this
function to locate the appropriate include directory.
Notes
-----
When using ``distutils``, for example in ``setup.py``.
::
import numpy as np
...
Extension('extension_name', ...
include_dirs=[np.get_include()])
...
"""
import numpy
if numpy.show_config is None:
# running from numpy source directory
d = os.path.join(os.path.dirname(numpy.__file__), 'core', 'include')
else:
# using installed numpy core headers
import numpy.core as core
d = os.path.join(os.path.dirname(core.__file__), 'include')
return d
def _set_function_name(func, name):
func.__name__ = name
return func
class _Deprecate:
"""
Decorator class to deprecate old functions.
Refer to `deprecate` for details.
See Also
--------
deprecate
"""
def __init__(self, old_name=None, new_name=None, message=None):
self.old_name = old_name
self.new_name = new_name
self.message = message
def __call__(self, func, *args, **kwargs):
"""
Decorator call. Refer to ``decorate``.
"""
old_name = self.old_name
new_name = self.new_name
message = self.message
if old_name is None:
try:
old_name = func.__name__
except AttributeError:
old_name = func.__name__
if new_name is None:
depdoc = "`%s` is deprecated!" % old_name
else:
depdoc = "`%s` is deprecated, use `%s` instead!" % \
(old_name, new_name)
if message is not None:
depdoc += "\n" + message
def newfunc(*args,**kwds):
"""`arrayrange` is deprecated, use `arange` instead!"""
warnings.warn(depdoc, DeprecationWarning, stacklevel=2)
return func(*args, **kwds)
newfunc = _set_function_name(newfunc, old_name)
doc = func.__doc__
if doc is None:
doc = depdoc
else:
lines = doc.expandtabs().split('\n')
indent = _get_indent(lines[1:])
if lines[0].lstrip():
# Indent the original first line to let inspect.cleandoc()
# dedent the docstring despite the deprecation notice.
doc = indent * ' ' + doc
else:
# Remove the same leading blank lines as cleandoc() would.
skip = len(lines[0]) + 1
for line in lines[1:]:
if len(line) > indent:
break
skip += len(line) + 1
doc = doc[skip:]
depdoc = textwrap.indent(depdoc, ' ' * indent)
doc = '\n\n'.join([depdoc, doc])
newfunc.__doc__ = doc
try:
d = func.__dict__
except AttributeError:
pass
else:
newfunc.__dict__.update(d)
return newfunc
def _get_indent(lines):
"""
Determines the leading whitespace that could be removed from all the lines.
"""
indent = sys.maxsize
for line in lines:
content = len(line.lstrip())
if content:
indent = min(indent, len(line) - content)
if indent == sys.maxsize:
indent = 0
return indent
def deprecate(*args, **kwargs):
"""
Issues a DeprecationWarning, adds warning to `old_name`'s
docstring, rebinds ``old_name.__name__`` and returns the new
function object.
This function may also be used as a decorator.
Parameters
----------
func : function
The function to be deprecated.
old_name : str, optional
The name of the function to be deprecated. Default is None, in
which case the name of `func` is used.
new_name : str, optional
The new name for the function. Default is None, in which case the
deprecation message is that `old_name` is deprecated. If given, the
deprecation message is that `old_name` is deprecated and `new_name`
should be used instead.
message : str, optional
Additional explanation of the deprecation. Displayed in the
docstring after the warning.
Returns
-------
old_func : function
The deprecated function.
Examples
--------
Note that ``olduint`` returns a value after printing Deprecation
Warning:
>>> olduint = np.deprecate(np.uint)
DeprecationWarning: `uint64` is deprecated! # may vary
>>> olduint(6)
6
"""
# Deprecate may be run as a function or as a decorator
# If run as a function, we initialise the decorator class
# and execute its __call__ method.
if args:
fn = args[0]
args = args[1:]
return _Deprecate(*args, **kwargs)(fn)
else:
return _Deprecate(*args, **kwargs)
def deprecate_with_doc(msg):
"""
Deprecates a function and includes the deprecation in its docstring.
This function is used as a decorator. It returns an object that can be
used to issue a DeprecationWarning, by passing the to-be decorated
function as argument, this adds warning to the to-be decorated function's
docstring and returns the new function object.
See Also
--------
deprecate : Decorate a function such that it issues a `DeprecationWarning`
Parameters
----------
msg : str
Additional explanation of the deprecation. Displayed in the
docstring after the warning.
Returns
-------
obj : object
"""
return _Deprecate(message=msg)
#--------------------------------------------
# Determine if two arrays can share memory
#--------------------------------------------
def byte_bounds(a):
"""
Returns pointers to the end-points of an array.
Parameters
----------
a : ndarray
Input array. It must conform to the Python-side of the array
interface.
Returns
-------
(low, high) : tuple of 2 integers
The first integer is the first byte of the array, the second
integer is just past the last byte of the array. If `a` is not
contiguous it will not use every byte between the (`low`, `high`)
values.
Examples
--------
>>> I = np.eye(2, dtype='f'); I.dtype
dtype('float32')
>>> low, high = np.byte_bounds(I)
>>> high - low == I.size*I.itemsize
True
>>> I = np.eye(2); I.dtype
dtype('float64')
>>> low, high = np.byte_bounds(I)
>>> high - low == I.size*I.itemsize
True
"""
ai = a.__array_interface__
a_data = ai['data'][0]
astrides = ai['strides']
ashape = ai['shape']
bytes_a = asarray(a).dtype.itemsize
a_low = a_high = a_data
if astrides is None:
# contiguous case
a_high += a.size * bytes_a
else:
for shape, stride in zip(ashape, astrides):
if stride < 0:
a_low += (shape-1)*stride
else:
a_high += (shape-1)*stride
a_high += bytes_a
return a_low, a_high
#-----------------------------------------------------------------------------
# Function for output and information on the variables used.
#-----------------------------------------------------------------------------
def who(vardict=None):
"""
Print the NumPy arrays in the given dictionary.
If there is no dictionary passed in or `vardict` is None then returns
NumPy arrays in the globals() dictionary (all NumPy arrays in the
namespace).
Parameters
----------
vardict : dict, optional
A dictionary possibly containing ndarrays. Default is globals().
Returns
-------
out : None
Returns 'None'.
Notes
-----
Prints out the name, shape, bytes and type of all of the ndarrays
present in `vardict`.
Examples
--------
>>> a = np.arange(10)
>>> b = np.ones(20)
>>> np.who()
Name Shape Bytes Type
===========================================================
a 10 80 int64
b 20 160 float64
Upper bound on total bytes = 240
>>> d = {'x': np.arange(2.0), 'y': np.arange(3.0), 'txt': 'Some str',
... 'idx':5}
>>> np.who(d)
Name Shape Bytes Type
===========================================================
x 2 16 float64
y 3 24 float64
Upper bound on total bytes = 40
"""
if vardict is None:
frame = sys._getframe().f_back
vardict = frame.f_globals
sta = []
cache = {}
for name in vardict.keys():
if isinstance(vardict[name], ndarray):
var = vardict[name]
idv = id(var)
if idv in cache.keys():
namestr = name + " (%s)" % cache[idv]
original = 0
else:
cache[idv] = name
namestr = name
original = 1
shapestr = " x ".join(map(str, var.shape))
bytestr = str(var.nbytes)
sta.append([namestr, shapestr, bytestr, var.dtype.name,
original])
maxname = 0
maxshape = 0
maxbyte = 0
totalbytes = 0
for k in range(len(sta)):
val = sta[k]
if maxname < len(val[0]):
maxname = len(val[0])
if maxshape < len(val[1]):
maxshape = len(val[1])
if maxbyte < len(val[2]):
maxbyte = len(val[2])
if val[4]:
totalbytes += int(val[2])
if len(sta) > 0:
sp1 = max(10, maxname)
sp2 = max(10, maxshape)
sp3 = max(10, maxbyte)
prval = "Name %s Shape %s Bytes %s Type" % (sp1*' ', sp2*' ', sp3*' ')
print(prval + "\n" + "="*(len(prval)+5) + "\n")
for k in range(len(sta)):
val = sta[k]
print("%s %s %s %s %s %s %s" % (val[0], ' '*(sp1-len(val[0])+4),
val[1], ' '*(sp2-len(val[1])+5),
val[2], ' '*(sp3-len(val[2])+5),
val[3]))
print("\nUpper bound on total bytes = %d" % totalbytes)
return
#-----------------------------------------------------------------------------
# NOTE: pydoc defines a help function which works similarly to this
# except it uses a pager to take over the screen.
# combine name and arguments and split to multiple lines of width
# characters. End lines on a comma and begin argument list indented with
# the rest of the arguments.
def _split_line(name, arguments, width):
firstwidth = len(name)
k = firstwidth
newstr = name
sepstr = ", "
arglist = arguments.split(sepstr)
for argument in arglist:
if k == firstwidth:
addstr = ""
else:
addstr = sepstr
k = k + len(argument) + len(addstr)
if k > width:
k = firstwidth + 1 + len(argument)
newstr = newstr + ",\n" + " "*(firstwidth+2) + argument
else:
newstr = newstr + addstr + argument
return newstr
_namedict = None
_dictlist = None
# Traverse all module directories underneath globals
# to see if something is defined
def _makenamedict(module='numpy'):
module = __import__(module, globals(), locals(), [])
thedict = {module.__name__:module.__dict__}
dictlist = [module.__name__]
totraverse = [module.__dict__]
while True:
if len(totraverse) == 0:
break
thisdict = totraverse.pop(0)
for x in thisdict.keys():
if isinstance(thisdict[x], types.ModuleType):
modname = thisdict[x].__name__
if modname not in dictlist:
moddict = thisdict[x].__dict__
dictlist.append(modname)
totraverse.append(moddict)
thedict[modname] = moddict
return thedict, dictlist
def _info(obj, output=sys.stdout):
"""Provide information about ndarray obj.
Parameters
----------
obj : ndarray
Must be ndarray, not checked.
output
Where printed output goes.
Notes
-----
Copied over from the numarray module prior to its removal.
Adapted somewhat as only numpy is an option now.
Called by info.
"""
extra = ""
tic = ""
bp = lambda x: x
cls = getattr(obj, '__class__', type(obj))
nm = getattr(cls, '__name__', cls)
strides = obj.strides
endian = obj.dtype.byteorder
print("class: ", nm, file=output)
print("shape: ", obj.shape, file=output)
print("strides: ", strides, file=output)
print("itemsize: ", obj.itemsize, file=output)
print("aligned: ", bp(obj.flags.aligned), file=output)
print("contiguous: ", bp(obj.flags.contiguous), file=output)
print("fortran: ", obj.flags.fortran, file=output)
print(
"data pointer: %s%s" % (hex(obj.ctypes._as_parameter_.value), extra),
file=output
)
print("byteorder: ", end=' ', file=output)
if endian in ['|', '=']:
print("%s%s%s" % (tic, sys.byteorder, tic), file=output)
byteswap = False
elif endian == '>':
print("%sbig%s" % (tic, tic), file=output)
byteswap = sys.byteorder != "big"
else:
print("%slittle%s" % (tic, tic), file=output)
byteswap = sys.byteorder != "little"
print("byteswap: ", bp(byteswap), file=output)
print("type: %s" % obj.dtype, file=output)
@set_module('numpy')
def info(object=None, maxwidth=76, output=sys.stdout, toplevel='numpy'):
"""
Get help information for a function, class, or module.
Parameters
----------
object : object or str, optional
Input object or name to get information about. If `object` is a
numpy object, its docstring is given. If it is a string, available
modules are searched for matching objects. If None, information
about `info` itself is returned.
maxwidth : int, optional
Printing width.
output : file like object, optional
File like object that the output is written to, default is
``stdout``. The object has to be opened in 'w' or 'a' mode.
toplevel : str, optional
Start search at this level.
See Also
--------
source, lookfor
Notes
-----
When used interactively with an object, ``np.info(obj)`` is equivalent
to ``help(obj)`` on the Python prompt or ``obj?`` on the IPython
prompt.
Examples
--------
>>> np.info(np.polyval) # doctest: +SKIP
polyval(p, x)
Evaluate the polynomial p at x.
...
When using a string for `object` it is possible to get multiple results.
>>> np.info('fft') # doctest: +SKIP
*** Found in numpy ***
Core FFT routines
...
*** Found in numpy.fft ***
fft(a, n=None, axis=-1)
...
*** Repeat reference found in numpy.fft.fftpack ***
*** Total of 3 references found. ***
"""
global _namedict, _dictlist
# Local import to speed up numpy's import time.
import pydoc
import inspect
if (hasattr(object, '_ppimport_importer') or
hasattr(object, '_ppimport_module')):
object = object._ppimport_module
elif hasattr(object, '_ppimport_attr'):
object = object._ppimport_attr
if object is None:
info(info)
elif isinstance(object, ndarray):
_info(object, output=output)
elif isinstance(object, str):
if _namedict is None:
_namedict, _dictlist = _makenamedict(toplevel)
numfound = 0
objlist = []
for namestr in _dictlist:
try:
obj = _namedict[namestr][object]
if id(obj) in objlist:
print("\n "
"*** Repeat reference found in %s *** " % namestr,
file=output
)
else:
objlist.append(id(obj))
print(" *** Found in %s ***" % namestr, file=output)
info(obj)
print("-"*maxwidth, file=output)
numfound += 1
except KeyError:
pass
if numfound == 0:
print("Help for %s not found." % object, file=output)
else:
print("\n "
"*** Total of %d references found. ***" % numfound,
file=output
)
elif inspect.isfunction(object) or inspect.ismethod(object):
name = object.__name__
try:
arguments = str(inspect.signature(object))
except Exception:
arguments = "()"
if len(name+arguments) > maxwidth:
argstr = _split_line(name, arguments, maxwidth)
else:
argstr = name + arguments
print(" " + argstr + "\n", file=output)
print(inspect.getdoc(object), file=output)
elif inspect.isclass(object):
name = object.__name__
try:
arguments = str(inspect.signature(object))
except Exception:
arguments = "()"
if len(name+arguments) > maxwidth:
argstr = _split_line(name, arguments, maxwidth)
else:
argstr = name + arguments
print(" " + argstr + "\n", file=output)
doc1 = inspect.getdoc(object)
if doc1 is None:
if hasattr(object, '__init__'):
print(inspect.getdoc(object.__init__), file=output)
else:
print(inspect.getdoc(object), file=output)
methods = pydoc.allmethods(object)
public_methods = [meth for meth in methods if meth[0] != '_']
if public_methods:
print("\n\nMethods:\n", file=output)
for meth in public_methods:
thisobj = getattr(object, meth, None)
if thisobj is not None:
methstr, other = pydoc.splitdoc(
inspect.getdoc(thisobj) or "None"
)
print(" %s -- %s" % (meth, methstr), file=output)
elif hasattr(object, '__doc__'):
print(inspect.getdoc(object), file=output)
@set_module('numpy')
def source(object, output=sys.stdout):
"""
Print or write to a file the source code for a NumPy object.
The source code is only returned for objects written in Python. Many
functions and classes are defined in C and will therefore not return
useful information.
Parameters
----------
object : numpy object
Input object. This can be any object (function, class, module,
...).
output : file object, optional
If `output` not supplied then source code is printed to screen
(sys.stdout). File object must be created with either write 'w' or
append 'a' modes.
See Also
--------
lookfor, info
Examples
--------
>>> np.source(np.interp) #doctest: +SKIP
In file: /usr/lib/python2.6/dist-packages/numpy/lib/function_base.py
def interp(x, xp, fp, left=None, right=None):
\"\"\".... (full docstring printed)\"\"\"
if isinstance(x, (float, int, number)):
return compiled_interp([x], xp, fp, left, right).item()
else:
return compiled_interp(x, xp, fp, left, right)
The source code is only returned for objects written in Python.
>>> np.source(np.array) #doctest: +SKIP
Not available for this object.
"""
# Local import to speed up numpy's import time.
import inspect
try:
print("In file: %s\n" % inspect.getsourcefile(object), file=output)
print(inspect.getsource(object), file=output)
except Exception:
print("Not available for this object.", file=output)
# Cache for lookfor: {id(module): {name: (docstring, kind, index), ...}...}
# where kind: "func", "class", "module", "object"
# and index: index in breadth-first namespace traversal
_lookfor_caches = {}
# regexp whose match indicates that the string may contain a function
# signature
_function_signature_re = re.compile(r"[a-z0-9_]+\(.*[,=].*\)", re.I)
@set_module('numpy')
def lookfor(what, module=None, import_modules=True, regenerate=False,
output=None):
"""
Do a keyword search on docstrings.
A list of objects that matched the search is displayed,
sorted by relevance. All given keywords need to be found in the
docstring for it to be returned as a result, but the order does
not matter.
Parameters
----------
what : str
String containing words to look for.
module : str or list, optional
Name of module(s) whose docstrings to go through.
import_modules : bool, optional
Whether to import sub-modules in packages. Default is True.
regenerate : bool, optional
Whether to re-generate the docstring cache. Default is False.
output : file-like, optional
File-like object to write the output to. If omitted, use a pager.
See Also
--------
source, info
Notes
-----
Relevance is determined only roughly, by checking if the keywords occur
in the function name, at the start of a docstring, etc.
Examples
--------
>>> np.lookfor('binary representation') # doctest: +SKIP
Search results for 'binary representation'
------------------------------------------
numpy.binary_repr
Return the binary representation of the input number as a string.
numpy.core.setup_common.long_double_representation
Given a binary dump as given by GNU od -b, look for long double
numpy.base_repr
Return a string representation of a number in the given base system.
...
"""
import pydoc
# Cache
cache = _lookfor_generate_cache(module, import_modules, regenerate)
# Search
# XXX: maybe using a real stemming search engine would be better?
found = []
whats = str(what).lower().split()
if not whats:
return
for name, (docstring, kind, index) in cache.items():
if kind in ('module', 'object'):
# don't show modules or objects
continue
doc = docstring.lower()
if all(w in doc for w in whats):
found.append(name)
# Relevance sort
# XXX: this is full Harrison-Stetson heuristics now,
# XXX: it probably could be improved
kind_relevance = {'func': 1000, 'class': 1000,
'module': -1000, 'object': -1000}
def relevance(name, docstr, kind, index):
r = 0
# do the keywords occur within the start of the docstring?
first_doc = "\n".join(docstr.lower().strip().split("\n")[:3])
r += sum([200 for w in whats if w in first_doc])
# do the keywords occur in the function name?
r += sum([30 for w in whats if w in name])
# is the full name long?
r += -len(name) * 5
# is the object of bad type?
r += kind_relevance.get(kind, -1000)
# is the object deep in namespace hierarchy?
r += -name.count('.') * 10
r += max(-index / 100, -100)
return r
def relevance_value(a):
return relevance(a, *cache[a])
found.sort(key=relevance_value)
# Pretty-print
s = "Search results for '%s'" % (' '.join(whats))
help_text = [s, "-"*len(s)]
for name in found[::-1]:
doc, kind, ix = cache[name]
doclines = [line.strip() for line in doc.strip().split("\n")
if line.strip()]
# find a suitable short description
try:
first_doc = doclines[0].strip()
if _function_signature_re.search(first_doc):
first_doc = doclines[1].strip()
except IndexError:
first_doc = ""
help_text.append("%s\n %s" % (name, first_doc))
if not found:
help_text.append("Nothing found.")
# Output
if output is not None:
output.write("\n".join(help_text))
elif len(help_text) > 10:
pager = pydoc.getpager()
pager("\n".join(help_text))
else:
print("\n".join(help_text))
def _lookfor_generate_cache(module, import_modules, regenerate):
"""
Generate docstring cache for given module.
Parameters
----------
module : str, None, module
Module for which to generate docstring cache
import_modules : bool
Whether to import sub-modules in packages.
regenerate : bool
Re-generate the docstring cache
Returns
-------
cache : dict {obj_full_name: (docstring, kind, index), ...}
Docstring cache for the module, either cached one (regenerate=False)
or newly generated.
"""
# Local import to speed up numpy's import time.
import inspect
from io import StringIO
if module is None:
module = "numpy"
if isinstance(module, str):
try:
__import__(module)
except ImportError:
return {}
module = sys.modules[module]
elif isinstance(module, list) or isinstance(module, tuple):
cache = {}
for mod in module:
cache.update(_lookfor_generate_cache(mod, import_modules,
regenerate))
return cache
if id(module) in _lookfor_caches and not regenerate:
return _lookfor_caches[id(module)]
# walk items and collect docstrings
cache = {}
_lookfor_caches[id(module)] = cache
seen = {}
index = 0
stack = [(module.__name__, module)]
while stack:
name, item = stack.pop(0)
if id(item) in seen:
continue
seen[id(item)] = True
index += 1
kind = "object"
if inspect.ismodule(item):
kind = "module"
try:
_all = item.__all__
except AttributeError:
_all = None
# import sub-packages
if import_modules and hasattr(item, '__path__'):
for pth in item.__path__:
for mod_path in os.listdir(pth):
this_py = os.path.join(pth, mod_path)
init_py = os.path.join(pth, mod_path, '__init__.py')
if (os.path.isfile(this_py) and
mod_path.endswith('.py')):
to_import = mod_path[:-3]
elif os.path.isfile(init_py):
to_import = mod_path
else:
continue
if to_import == '__init__':
continue
try:
old_stdout = sys.stdout
old_stderr = sys.stderr
try:
sys.stdout = StringIO()
sys.stderr = StringIO()
__import__("%s.%s" % (name, to_import))
finally:
sys.stdout = old_stdout
sys.stderr = old_stderr
# Catch SystemExit, too
except BaseException:
continue
for n, v in _getmembers(item):
try:
item_name = getattr(v, '__name__', "%s.%s" % (name, n))
mod_name = getattr(v, '__module__', None)
except NameError:
# ref. SWIG's global cvars
# NameError: Unknown C global variable
item_name = "%s.%s" % (name, n)
mod_name = None
if '.' not in item_name and mod_name:
item_name = "%s.%s" % (mod_name, item_name)
if not item_name.startswith(name + '.'):
# don't crawl "foreign" objects
if isinstance(v, ufunc):
# ... unless they are ufuncs
pass
else:
continue
elif not (inspect.ismodule(v) or _all is None or n in _all):
continue
stack.append(("%s.%s" % (name, n), v))
elif inspect.isclass(item):
kind = "class"
for n, v in _getmembers(item):
stack.append(("%s.%s" % (name, n), v))
elif hasattr(item, "__call__"):
kind = "func"
try:
doc = inspect.getdoc(item)
except NameError:
# ref SWIG's NameError: Unknown C global variable
doc = None
if doc is not None:
cache[name] = (doc, kind, index)
return cache
def _getmembers(item):
import inspect
try:
members = inspect.getmembers(item)
except Exception:
members = [(x, getattr(item, x)) for x in dir(item)
if hasattr(item, x)]
return members
def safe_eval(source):
"""
Protected string evaluation.
Evaluate a string containing a Python literal expression without
allowing the execution of arbitrary non-literal code.
Parameters
----------
source : str
The string to evaluate.
Returns
-------
obj : object
The result of evaluating `source`.
Raises
------
SyntaxError
If the code has invalid Python syntax, or if it contains
non-literal code.
Examples
--------
>>> np.safe_eval('1')
1
>>> np.safe_eval('[1, 2, 3]')
[1, 2, 3]
>>> np.safe_eval('{"foo": ("bar", 10.0)}')
{'foo': ('bar', 10.0)}
>>> np.safe_eval('import os')
Traceback (most recent call last):
...
SyntaxError: invalid syntax
>>> np.safe_eval('open("/home/user/.ssh/id_dsa").read()')
Traceback (most recent call last):
...
ValueError: malformed node or string: <_ast.Call object at 0x...>
"""
# Local import to speed up numpy's import time.
import ast
return ast.literal_eval(source)
def _median_nancheck(data, result, axis, out):
"""
Utility function to check median result from data for NaN values at the end
and return NaN in that case. Input result can also be a MaskedArray.
Parameters
----------
data : array
Input data to median function
result : Array or MaskedArray
Result of median function
axis : int
Axis along which the median was computed.
out : ndarray, optional
Output array in which to place the result.
Returns
-------
median : scalar or ndarray
Median or NaN in axes which contained NaN in the input.
"""
if data.size == 0:
return result
n = np.isnan(data.take(-1, axis=axis))
# masked NaN values are ok
if np.ma.isMaskedArray(n):
n = n.filled(False)
if result.ndim == 0:
if n == True:
if out is not None:
out[...] = data.dtype.type(np.nan)
result = out
else:
result = data.dtype.type(np.nan)
elif np.count_nonzero(n.ravel()) > 0:
result[n] = np.nan
return result
def _opt_info():
"""
Returns a string contains the supported CPU features by the current build.
The string format can be explained as follows:
- dispatched features that are supported by the running machine
end with `*`.
- dispatched features that are "not" supported by the running machine
end with `?`.
- remained features are representing the baseline.
"""
from numpy.core._multiarray_umath import (
__cpu_features__, __cpu_baseline__, __cpu_dispatch__
)
if len(__cpu_baseline__) == 0 and len(__cpu_dispatch__) == 0:
return ''
enabled_features = ' '.join(__cpu_baseline__)
for feature in __cpu_dispatch__:
if __cpu_features__[feature]:
enabled_features += f" {feature}*"
else:
enabled_features += f" {feature}?"
return enabled_features
#-----------------------------------------------------------------------------
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