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"""
Utilities that manipulate strides to achieve desirable effects.
An explanation of strides can be found in the "ndarray.rst" file in the
NumPy reference guide.
"""
import numpy as np
from numpy.core.numeric import normalize_axis_tuple
from numpy.core.overrides import array_function_dispatch, set_module
__all__ = ['broadcast_to', 'broadcast_arrays', 'broadcast_shapes']
class DummyArray:
"""Dummy object that just exists to hang __array_interface__ dictionaries
and possibly keep alive a reference to a base array.
"""
def __init__(self, interface, base=None):
self.__array_interface__ = interface
self.base = base
def _maybe_view_as_subclass(original_array, new_array):
if type(original_array) is not type(new_array):
# if input was an ndarray subclass and subclasses were OK,
# then view the result as that subclass.
new_array = new_array.view(type=type(original_array))
# Since we have done something akin to a view from original_array, we
# should let the subclass finalize (if it has it implemented, i.e., is
# not None).
if new_array.__array_finalize__:
new_array.__array_finalize__(original_array)
return new_array
def as_strided(x, shape=None, strides=None, subok=False, writeable=True):
"""
Create a view into the array with the given shape and strides.
.. warning:: This function has to be used with extreme care, see notes.
Parameters
----------
x : ndarray
Array to create a new.
shape : sequence of int, optional
The shape of the new array. Defaults to ``x.shape``.
strides : sequence of int, optional
The strides of the new array. Defaults to ``x.strides``.
subok : bool, optional
.. versionadded:: 1.10
If True, subclasses are preserved.
writeable : bool, optional
.. versionadded:: 1.12
If set to False, the returned array will always be readonly.
Otherwise it will be writable if the original array was. It
is advisable to set this to False if possible (see Notes).
Returns
-------
view : ndarray
See also
--------
broadcast_to : broadcast an array to a given shape.
reshape : reshape an array.
lib.stride_tricks.sliding_window_view :
userfriendly and safe function for the creation of sliding window views.
Notes
-----
``as_strided`` creates a view into the array given the exact strides
and shape. This means it manipulates the internal data structure of
ndarray and, if done incorrectly, the array elements can point to
invalid memory and can corrupt results or crash your program.
It is advisable to always use the original ``x.strides`` when
calculating new strides to avoid reliance on a contiguous memory
layout.
Furthermore, arrays created with this function often contain self
overlapping memory, so that two elements are identical.
Vectorized write operations on such arrays will typically be
unpredictable. They may even give different results for small, large,
or transposed arrays.
Since writing to these arrays has to be tested and done with great
care, you may want to use ``writeable=False`` to avoid accidental write
operations.
For these reasons it is advisable to avoid ``as_strided`` when
possible.
"""
# first convert input to array, possibly keeping subclass
x = np.array(x, copy=False, subok=subok)
interface = dict(x.__array_interface__)
if shape is not None:
interface['shape'] = tuple(shape)
if strides is not None:
interface['strides'] = tuple(strides)
array = np.asarray(DummyArray(interface, base=x))
# The route via `__interface__` does not preserve structured
# dtypes. Since dtype should remain unchanged, we set it explicitly.
array.dtype = x.dtype
view = _maybe_view_as_subclass(x, array)
if view.flags.writeable and not writeable:
view.flags.writeable = False
return view
def _sliding_window_view_dispatcher(x, window_shape, axis=None, *,
subok=None, writeable=None):
return (x,)
@array_function_dispatch(_sliding_window_view_dispatcher)
def sliding_window_view(x, window_shape, axis=None, *,
subok=False, writeable=False):
"""
Create a sliding window view into the array with the given window shape.
Also known as rolling or moving window, the window slides across all
dimensions of the array and extracts subsets of the array at all window
positions.
.. versionadded:: 1.20.0
Parameters
----------
x : array_like
Array to create the sliding window view from.
window_shape : int or tuple of int
Size of window over each axis that takes part in the sliding window.
If `axis` is not present, must have same length as the number of input
array dimensions. Single integers `i` are treated as if they were the
tuple `(i,)`.
axis : int or tuple of int, optional
Axis or axes along which the sliding window is applied.
By default, the sliding window is applied to all axes and
`window_shape[i]` will refer to axis `i` of `x`.
If `axis` is given as a `tuple of int`, `window_shape[i]` will refer to
the axis `axis[i]` of `x`.
Single integers `i` are treated as if they were the tuple `(i,)`.
subok : bool, optional
If True, sub-classes will be passed-through, otherwise the returned
array will be forced to be a base-class array (default).
writeable : bool, optional
When true, allow writing to the returned view. The default is false,
as this should be used with caution: the returned view contains the
same memory location multiple times, so writing to one location will
cause others to change.
Returns
-------
view : ndarray
Sliding window view of the array. The sliding window dimensions are
inserted at the end, and the original dimensions are trimmed as
required by the size of the sliding window.
That is, ``view.shape = x_shape_trimmed + window_shape``, where
``x_shape_trimmed`` is ``x.shape`` with every entry reduced by one less
than the corresponding window size.
See Also
--------
lib.stride_tricks.as_strided: A lower-level and less safe routine for
creating arbitrary views from custom shape and strides.
broadcast_to: broadcast an array to a given shape.
Notes
-----
For many applications using a sliding window view can be convenient, but
potentially very slow. Often specialized solutions exist, for example:
- `scipy.signal.fftconvolve`
- filtering functions in `scipy.ndimage`
- moving window functions provided by
`bottleneck <https://github.com/pydata/bottleneck>`_.
As a rough estimate, a sliding window approach with an input size of `N`
and a window size of `W` will scale as `O(N*W)` where frequently a special
algorithm can achieve `O(N)`. That means that the sliding window variant
for a window size of 100 can be a 100 times slower than a more specialized
version.
Nevertheless, for small window sizes, when no custom algorithm exists, or
as a prototyping and developing tool, this function can be a good solution.
Examples
--------
>>> x = np.arange(6)
>>> x.shape
(6,)
>>> v = sliding_window_view(x, 3)
>>> v.shape
(4, 3)
>>> v
array([[0, 1, 2],
[1, 2, 3],
[2, 3, 4],
[3, 4, 5]])
This also works in more dimensions, e.g.
>>> i, j = np.ogrid[:3, :4]
>>> x = 10*i + j
>>> x.shape
(3, 4)
>>> x
array([[ 0, 1, 2, 3],
[10, 11, 12, 13],
[20, 21, 22, 23]])
>>> shape = (2,2)
>>> v = sliding_window_view(x, shape)
>>> v.shape
(2, 3, 2, 2)
>>> v
array([[[[ 0, 1],
[10, 11]],
[[ 1, 2],
[11, 12]],
[[ 2, 3],
[12, 13]]],
[[[10, 11],
[20, 21]],
[[11, 12],
[21, 22]],
[[12, 13],
[22, 23]]]])
The axis can be specified explicitly:
>>> v = sliding_window_view(x, 3, 0)
>>> v.shape
(1, 4, 3)
>>> v
array([[[ 0, 10, 20],
[ 1, 11, 21],
[ 2, 12, 22],
[ 3, 13, 23]]])
The same axis can be used several times. In that case, every use reduces
the corresponding original dimension:
>>> v = sliding_window_view(x, (2, 3), (1, 1))
>>> v.shape
(3, 1, 2, 3)
>>> v
array([[[[ 0, 1, 2],
[ 1, 2, 3]]],
[[[10, 11, 12],
[11, 12, 13]]],
[[[20, 21, 22],
[21, 22, 23]]]])
Combining with stepped slicing (`::step`), this can be used to take sliding
views which skip elements:
>>> x = np.arange(7)
>>> sliding_window_view(x, 5)[:, ::2]
array([[0, 2, 4],
[1, 3, 5],
[2, 4, 6]])
or views which move by multiple elements
>>> x = np.arange(7)
>>> sliding_window_view(x, 3)[::2, :]
array([[0, 1, 2],
[2, 3, 4],
[4, 5, 6]])
A common application of `sliding_window_view` is the calculation of running
statistics. The simplest example is the
`moving average <https://en.wikipedia.org/wiki/Moving_average>`_:
>>> x = np.arange(6)
>>> x.shape
(6,)
>>> v = sliding_window_view(x, 3)
>>> v.shape
(4, 3)
>>> v
array([[0, 1, 2],
[1, 2, 3],
[2, 3, 4],
[3, 4, 5]])
>>> moving_average = v.mean(axis=-1)
>>> moving_average
array([1., 2., 3., 4.])
Note that a sliding window approach is often **not** optimal (see Notes).
"""
window_shape = (tuple(window_shape)
if np.iterable(window_shape)
else (window_shape,))
# first convert input to array, possibly keeping subclass
x = np.array(x, copy=False, subok=subok)
window_shape_array = np.array(window_shape)
if np.any(window_shape_array < 0):
raise ValueError('`window_shape` cannot contain negative values')
if axis is None:
axis = tuple(range(x.ndim))
if len(window_shape) != len(axis):
raise ValueError(f'Since axis is `None`, must provide '
f'window_shape for all dimensions of `x`; '
f'got {len(window_shape)} window_shape elements '
f'and `x.ndim` is {x.ndim}.')
else:
axis = normalize_axis_tuple(axis, x.ndim, allow_duplicate=True)
if len(window_shape) != len(axis):
raise ValueError(f'Must provide matching length window_shape and '
f'axis; got {len(window_shape)} window_shape '
f'elements and {len(axis)} axes elements.')
out_strides = x.strides + tuple(x.strides[ax] for ax in axis)
# note: same axis can be windowed repeatedly
x_shape_trimmed = list(x.shape)
for ax, dim in zip(axis, window_shape):
if x_shape_trimmed[ax] < dim:
raise ValueError(
'window shape cannot be larger than input array shape')
x_shape_trimmed[ax] -= dim - 1
out_shape = tuple(x_shape_trimmed) + window_shape
return as_strided(x, strides=out_strides, shape=out_shape,
subok=subok, writeable=writeable)
def _broadcast_to(array, shape, subok, readonly):
shape = tuple(shape) if np.iterable(shape) else (shape,)
array = np.array(array, copy=False, subok=subok)
if not shape and array.shape:
raise ValueError('cannot broadcast a non-scalar to a scalar array')
if any(size < 0 for size in shape):
raise ValueError('all elements of broadcast shape must be non-'
'negative')
extras = []
it = np.nditer(
(array,), flags=['multi_index', 'refs_ok', 'zerosize_ok'] + extras,
op_flags=['readonly'], itershape=shape, order='C')
with it:
# never really has writebackifcopy semantics
broadcast = it.itviews[0]
result = _maybe_view_as_subclass(array, broadcast)
# In a future version this will go away
if not readonly and array.flags._writeable_no_warn:
result.flags.writeable = True
result.flags._warn_on_write = True
return result
def _broadcast_to_dispatcher(array, shape, subok=None):
return (array,)
@array_function_dispatch(_broadcast_to_dispatcher, module='numpy')
def broadcast_to(array, shape, subok=False):
"""Broadcast an array to a new shape.
Parameters
----------
array : array_like
The array to broadcast.
shape : tuple or int
The shape of the desired array. A single integer ``i`` is interpreted
as ``(i,)``.
subok : bool, optional
If True, then sub-classes will be passed-through, otherwise
the returned array will be forced to be a base-class array (default).
Returns
-------
broadcast : array
A readonly view on the original array with the given shape. It is
typically not contiguous. Furthermore, more than one element of a
broadcasted array may refer to a single memory location.
Raises
------
ValueError
If the array is not compatible with the new shape according to NumPy's
broadcasting rules.
See Also
--------
broadcast
broadcast_arrays
broadcast_shapes
Notes
-----
.. versionadded:: 1.10.0
Examples
--------
>>> x = np.array([1, 2, 3])
>>> np.broadcast_to(x, (3, 3))
array([[1, 2, 3],
[1, 2, 3],
[1, 2, 3]])
"""
return _broadcast_to(array, shape, subok=subok, readonly=True)
def _broadcast_shape(*args):
"""Returns the shape of the arrays that would result from broadcasting the
supplied arrays against each other.
"""
# use the old-iterator because np.nditer does not handle size 0 arrays
# consistently
b = np.broadcast(*args[:32])
# unfortunately, it cannot handle 32 or more arguments directly
for pos in range(32, len(args), 31):
# ironically, np.broadcast does not properly handle np.broadcast
# objects (it treats them as scalars)
# use broadcasting to avoid allocating the full array
b = broadcast_to(0, b.shape)
b = np.broadcast(b, *args[pos:(pos + 31)])
return b.shape
@set_module('numpy')
def broadcast_shapes(*args):
"""
Broadcast the input shapes into a single shape.
:ref:`Learn more about broadcasting here <basics.broadcasting>`.
.. versionadded:: 1.20.0
Parameters
----------
`*args` : tuples of ints, or ints
The shapes to be broadcast against each other.
Returns
-------
tuple
Broadcasted shape.
Raises
------
ValueError
If the shapes are not compatible and cannot be broadcast according
to NumPy's broadcasting rules.
See Also
--------
broadcast
broadcast_arrays
broadcast_to
Examples
--------
>>> np.broadcast_shapes((1, 2), (3, 1), (3, 2))
(3, 2)
>>> np.broadcast_shapes((6, 7), (5, 6, 1), (7,), (5, 1, 7))
(5, 6, 7)
"""
arrays = [np.empty(x, dtype=[]) for x in args]
return _broadcast_shape(*arrays)
def _broadcast_arrays_dispatcher(*args, subok=None):
return args
@array_function_dispatch(_broadcast_arrays_dispatcher, module='numpy')
def broadcast_arrays(*args, subok=False):
"""
Broadcast any number of arrays against each other.
Parameters
----------
`*args` : array_likes
The arrays to broadcast.
subok : bool, optional
If True, then sub-classes will be passed-through, otherwise
the returned arrays will be forced to be a base-class array (default).
Returns
-------
broadcasted : list of arrays
These arrays are views on the original arrays. They are typically
not contiguous. Furthermore, more than one element of a
broadcasted array may refer to a single memory location. If you need
to write to the arrays, make copies first. While you can set the
``writable`` flag True, writing to a single output value may end up
changing more than one location in the output array.
.. deprecated:: 1.17
The output is currently marked so that if written to, a deprecation
warning will be emitted. A future version will set the
``writable`` flag False so writing to it will raise an error.
See Also
--------
broadcast
broadcast_to
broadcast_shapes
Examples
--------
>>> x = np.array([[1,2,3]])
>>> y = np.array([[4],[5]])
>>> np.broadcast_arrays(x, y)
[array([[1, 2, 3],
[1, 2, 3]]), array([[4, 4, 4],
[5, 5, 5]])]
Here is a useful idiom for getting contiguous copies instead of
non-contiguous views.
>>> [np.array(a) for a in np.broadcast_arrays(x, y)]
[array([[1, 2, 3],
[1, 2, 3]]), array([[4, 4, 4],
[5, 5, 5]])]
"""
# nditer is not used here to avoid the limit of 32 arrays.
# Otherwise, something like the following one-liner would suffice:
# return np.nditer(args, flags=['multi_index', 'zerosize_ok'],
# order='C').itviews
args = [np.array(_m, copy=False, subok=subok) for _m in args]
shape = _broadcast_shape(*args)
if all(array.shape == shape for array in args):
# Common case where nothing needs to be broadcasted.
return args
return [_broadcast_to(array, shape, subok=subok, readonly=False)
for array in args]
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