import functools
from collections import Iterable
from numbers import Integral
import numpy as np
def assert_eq(x, y, check_nnz=True, compare_dtype=True, **kwargs):
from .coo import COO
assert x.shape == y.shape
if compare_dtype:
assert x.dtype == y.dtype
check_equal = np.array_equal \
if np.issubdtype(x.dtype, np.integer) and np.issubdtype(y.dtype, np.integer) \
else functools.partial(np.allclose, equal_nan=True)
if isinstance(x, COO):
assert is_canonical(x)
if isinstance(y, COO):
assert is_canonical(y)
if isinstance(x, COO) and isinstance(y, COO) and check_nnz:
assert np.array_equal(x.coords, y.coords) and check_equal(x.data, y.data, **kwargs)
return
if hasattr(x, 'todense'):
xx = x.todense()
if check_nnz:
assert_nnz(x, xx)
else:
xx = x
if hasattr(y, 'todense'):
yy = y.todense()
if check_nnz:
assert_nnz(y, yy)
else:
yy = y
assert check_equal(xx, yy, **kwargs)
def assert_nnz(s, x):
fill_value = s.fill_value if hasattr(s, 'fill_value') else _zero_of_dtype(s.dtype)
assert np.sum(~equivalent(x, fill_value)) == s.nnz
def is_canonical(x):
return not x.shape or ((np.diff(x.linear_loc()) > 0).all() and not equivalent(x.data, x.fill_value).any())
def _zero_of_dtype(dtype):
"""
Creates a ()-shaped 0-dimensional zero array of a given dtype.
Parameters
----------
dtype : numpy.dtype
The dtype for the array.
Returns
-------
np.ndarray
The zero array.
"""
return np.zeros((), dtype=dtype)[()]
[docs]def random(
shape,
density=0.01,
random_state=None,
data_rvs=None,
format='coo',
fill_value=None
):
""" Generate a random sparse multidimensional array
Parameters
----------
shape: Tuple[int]
Shape of the array
density: float, optional
Density of the generated array.
random_state : Union[numpy.random.RandomState, int], optional
Random number generator or random seed. If not given, the
singleton numpy.random will be used. This random state will be used
for sampling the sparsity structure, but not necessarily for sampling
the values of the structurally nonzero entries of the matrix.
data_rvs : Callable
Data generation callback. Must accept one single parameter: number of
:code:`nnz` elements, and return one single NumPy array of exactly
that length.
format : str
The format to return the output array in.
fill_value : scalar
The fill value of the output array.
Returns
-------
SparseArray
The generated random matrix.
See Also
--------
:obj:`scipy.sparse.rand`
Equivalent Scipy function.
:obj:`numpy.random.rand`
Similar Numpy function.
Examples
--------
>>> from sparse import random
>>> from scipy import stats
>>> rvs = lambda x: stats.poisson(25, loc=10).rvs(x, random_state=np.random.RandomState(1))
>>> s = random((2, 3, 4), density=0.25, random_state=np.random.RandomState(1), data_rvs=rvs)
>>> s.todense() # doctest: +NORMALIZE_WHITESPACE
array([[[ 0, 0, 0, 0],
[ 0, 34, 0, 0],
[33, 34, 0, 29]],
<BLANKLINE>
[[30, 0, 0, 34],
[ 0, 0, 0, 0],
[ 0, 0, 0, 0]]])
"""
# Copied, in large part, from scipy.sparse.random
# See https://github.com/scipy/scipy/blob/master/LICENSE.txt
from .coo import COO
elements = np.prod(shape)
nnz = int(elements * density)
if random_state is None:
random_state = np.random
elif isinstance(random_state, Integral):
random_state = np.random.RandomState(random_state)
if data_rvs is None:
data_rvs = random_state.rand
# Use the algorithm from python's random.sample for k < mn/3.
if elements < 3 * nnz:
ind = random_state.choice(elements, size=nnz, replace=False)
else:
ind = np.empty(nnz, dtype=np.min_scalar_type(elements - 1))
selected = set()
for i in range(nnz):
j = random_state.randint(elements)
while j in selected:
j = random_state.randint(elements)
selected.add(j)
ind[i] = j
data = data_rvs(nnz)
ar = COO(ind[None, :], data, shape=nnz, fill_value=fill_value).reshape(shape)
return ar.asformat(format)
def isscalar(x):
from .sparse_array import SparseArray
return not isinstance(x, SparseArray) and np.isscalar(x)
def random_value_array(value, fraction):
def replace_values(n):
i = int(n * fraction)
ar = np.empty((n,), dtype=np.float_)
ar[:i] = value
ar[i:] = np.random.rand(n - i)
return ar
return replace_values
def normalize_axis(axis, ndim):
"""
Normalize negative axis indices to their positive counterpart for a given
number of dimensions.
Parameters
----------
axis : Union[int, Iterable[int], None]
The axis indices.
ndim : int
Number of dimensions to normalize axis indices against.
Returns
-------
axis
The normalized axis indices.
"""
if axis is None:
return None
if isinstance(axis, Integral):
axis = int(axis)
if axis < 0:
axis += ndim
if axis >= ndim or axis < 0:
raise ValueError('Invalid axis index %d for ndim=%d' % (axis, ndim))
return axis
if isinstance(axis, Iterable):
if not all(isinstance(a, Integral) for a in axis):
raise ValueError("axis %s not understood" % axis)
return tuple(normalize_axis(a, ndim) for a in axis)
raise ValueError("axis %s not understood" % axis)
def equivalent(x, y):
"""
Checks the equivalence of two scalars or arrays with broadcasting. Assumes
a consistent dtype.
Parameters
----------
x : scalar or numpy.ndarray
y : scalar or numpy.ndarray
Returns
-------
equivalent : scalar or numpy.ndarray
The element-wise comparison of where two arrays are equivalent.
Examples
--------
>>> equivalent(1, 1)
True
>>> equivalent(np.nan, np.nan + 1)
True
>>> equivalent(1, 2)
False
>>> equivalent(np.inf, np.inf)
True
>>> equivalent(np.PZERO, np.NZERO)
True
"""
x = np.asarray(x)
y = np.asarray(y)
# Can't contain NaNs
if any(np.issubdtype(x.dtype, t) for t in
[np.integer, np.bool_, np.character]):
return x == y
# Can contain NaNs
# FIXME: Complex floats and np.void with multiple values can't be compared properly.
return (x == y) | ((x != x) & (y != y))
def check_zero_fill_value(*args):
"""
Checks if all the arguments have zero fill-values.
Parameters
----------
args : Iterable[SparseArray]
Raises
------
ValueError
If all arguments don't have zero fill-values.
Examples
--------
>>> import sparse
>>> s1 = sparse.random((10,), density=0.5)
>>> s2 = sparse.random((10,), density=0.5, fill_value=0.5)
>>> check_zero_fill_value(s1)
>>> check_zero_fill_value(s2)
Traceback (most recent call last):
...
ValueError: This operation requires zero fill values, but argument 0 had a fill value of 0.5.
>>> check_zero_fill_value(s1, s2)
Traceback (most recent call last):
...
ValueError: This operation requires zero fill values, but argument 1 had a fill value of 0.5.
"""
for i, arg in enumerate(args):
if (hasattr(arg, 'fill_value') and
not equivalent(arg.fill_value, _zero_of_dtype(arg.dtype))):
raise ValueError('This operation requires zero fill values, '
'but argument {:d} had a fill value of {!s}.'.format(i, arg.fill_value))
def check_consistent_fill_value(arrays):
"""
Checks if all the arguments have consistent fill-values.
Parameters
----------
args : Iterable[SparseArray]
Raises
------
ValueError
If all elements of :code:`arrays` don't have the same fill-value.
Examples
--------
>>> import sparse
>>> s1 = sparse.random((10,), density=0.5, fill_value=0.1)
>>> s2 = sparse.random((10,), density=0.5, fill_value=0.5)
>>> check_consistent_fill_value([s1, s1])
>>> check_consistent_fill_value([s1, s2]) # doctest: +NORMALIZE_WHITESPACE
Traceback (most recent call last):
...
ValueError: This operation requires consistent fill-values, but argument 1 had a fill value of 0.5,\
which is different from a fill_value of 0.1 in the first argument.
"""
arrays = list(arrays)
from .sparse_array import SparseArray
if not all(isinstance(s, SparseArray) for s in arrays):
raise ValueError('All arrays must be instances of SparseArray.')
if len(arrays) == 0:
raise ValueError('At least one array required.')
fv = arrays[0].fill_value
for i, arg in enumerate(arrays):
if not equivalent(fv, arg.fill_value):
raise ValueError('This operation requires consistent fill-values, '
'but argument {:d} had a fill value of {!s}, which '
'is different from a fill_value of {!s} in the first '
'argument.'.format(i, arg.fill_value, fv))