import warnings
import pytest
import inspect
from functools import partial
import numpy as np
from numpy._core.numeric import normalize_axis_tuple
from numpy.exceptions import AxisError, ComplexWarning
from numpy.lib._nanfunctions_impl import _nan_mask, _replace_nan
from numpy.testing import (
assert_, assert_equal, assert_almost_equal, assert_raises,
assert_raises_regex, assert_array_equal, suppress_warnings
)
# Test data
_ndat = np.array([[0.6244, np.nan, 0.2692, 0.0116, np.nan, 0.1170],
[0.5351, -0.9403, np.nan, 0.2100, 0.4759, 0.2833],
[np.nan, np.nan, np.nan, 0.1042, np.nan, -0.5954],
[0.1610, np.nan, np.nan, 0.1859, 0.3146, np.nan]])
# Rows of _ndat with nans removed
_rdat = [np.array([0.6244, 0.2692, 0.0116, 0.1170]),
np.array([0.5351, -0.9403, 0.2100, 0.4759, 0.2833]),
np.array([0.1042, -0.5954]),
np.array([0.1610, 0.1859, 0.3146])]
# Rows of _ndat with nans converted to ones
_ndat_ones = np.array([[0.6244, 1.0, 0.2692, 0.0116, 1.0, 0.1170],
[0.5351, -0.9403, 1.0, 0.2100, 0.4759, 0.2833],
[1.0, 1.0, 1.0, 0.1042, 1.0, -0.5954],
[0.1610, 1.0, 1.0, 0.1859, 0.3146, 1.0]])
# Rows of _ndat with nans converted to zeros
_ndat_zeros = np.array([[0.6244, 0.0, 0.2692, 0.0116, 0.0, 0.1170],
[0.5351, -0.9403, 0.0, 0.2100, 0.4759, 0.2833],
[0.0, 0.0, 0.0, 0.1042, 0.0, -0.5954],
[0.1610, 0.0, 0.0, 0.1859, 0.3146, 0.0]])
class TestSignatureMatch:
NANFUNCS = {
np.nanmin: np.amin,
np.nanmax: np.amax,
np.nanargmin: np.argmin,
np.nanargmax: np.argmax,
np.nansum: np.sum,
np.nanprod: np.prod,
np.nancumsum: np.cumsum,
np.nancumprod: np.cumprod,
np.nanmean: np.mean,
np.nanmedian: np.median,
np.nanpercentile: np.percentile,
np.nanquantile: np.quantile,
np.nanvar: np.var,
np.nanstd: np.std,
}
IDS = [k.__name__ for k in NANFUNCS]
@staticmethod
def get_signature(func, default="..."):
"""Construct a signature and replace all default parameter-values."""
prm_list = []
signature = inspect.signature(func)
for prm in signature.parameters.values():
if prm.default is inspect.Parameter.empty:
prm_list.append(prm)
else:
prm_list.append(prm.replace(default=default))
return inspect.Signature(prm_list)
@pytest.mark.parametrize("nan_func,func", NANFUNCS.items(), ids=IDS)
def test_signature_match(self, nan_func, func):
# Ignore the default parameter-values as they can sometimes differ
# between the two functions (*e.g.* one has `False` while the other
# has `np._NoValue`)
signature = self.get_signature(func)
nan_signature = self.get_signature(nan_func)
np.testing.assert_equal(signature, nan_signature)
def test_exhaustiveness(self):
"""Validate that all nan functions are actually tested."""
np.testing.assert_equal(
set(self.IDS), set(np.lib._nanfunctions_impl.__all__)
)
class TestNanFunctions_MinMax:
nanfuncs = [np.nanmin, np.nanmax]
stdfuncs = [np.min, np.max]
def test_mutation(self):
# Check that passed array is not modified.
ndat = _ndat.copy()
for f in self.nanfuncs:
f(ndat)
assert_equal(ndat, _ndat)
def test_keepdims(self):
mat = np.eye(3)
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
for axis in [None, 0, 1]:
tgt = rf(mat, axis=axis, keepdims=True)
res = nf(mat, axis=axis, keepdims=True)
assert_(res.ndim == tgt.ndim)
def test_out(self):
mat = np.eye(3)
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
resout = np.zeros(3)
tgt = rf(mat, axis=1)
res = nf(mat, axis=1, out=resout)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
def test_dtype_from_input(self):
codes = 'efdgFDG'
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
for c in codes:
mat = np.eye(3, dtype=c)
tgt = rf(mat, axis=1).dtype.type
res = nf(mat, axis=1).dtype.type
assert_(res is tgt)
# scalar case
tgt = rf(mat, axis=None).dtype.type
res = nf(mat, axis=None).dtype.type
assert_(res is tgt)
def test_result_values(self):
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
tgt = [rf(d) for d in _rdat]
res = nf(_ndat, axis=1)
assert_almost_equal(res, tgt)
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
@pytest.mark.parametrize("array", [
np.array(np.nan),
np.full((3, 3), np.nan),
], ids=["0d", "2d"])
def test_allnans(self, axis, dtype, array):
if axis is not None and array.ndim == 0:
pytest.skip(f"`axis != None` not supported for 0d arrays")
array = array.astype(dtype)
match = "All-NaN slice encountered"
for func in self.nanfuncs:
with pytest.warns(RuntimeWarning, match=match):
out = func(array, axis=axis)
assert np.isnan(out).all()
assert out.dtype == array.dtype
def test_masked(self):
mat = np.ma.fix_invalid(_ndat)
msk = mat._mask.copy()
for f in [np.nanmin]:
res = f(mat, axis=1)
tgt = f(_ndat, axis=1)
assert_equal(res, tgt)
assert_equal(mat._mask, msk)
assert_(not np.isinf(mat).any())
def test_scalar(self):
for f in self.nanfuncs:
assert_(f(0.) == 0.)
def test_subclass(self):
class MyNDArray(np.ndarray):
pass
# Check that it works and that type and
# shape are preserved
mine = np.eye(3).view(MyNDArray)
for f in self.nanfuncs:
res = f(mine, axis=0)
assert_(isinstance(res, MyNDArray))
assert_(res.shape == (3,))
res = f(mine, axis=1)
assert_(isinstance(res, MyNDArray))
assert_(res.shape == (3,))
res = f(mine)
assert_(res.shape == ())
# check that rows of nan are dealt with for subclasses (#4628)
mine[1] = np.nan
for f in self.nanfuncs:
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
res = f(mine, axis=0)
assert_(isinstance(res, MyNDArray))
assert_(not np.any(np.isnan(res)))
assert_(len(w) == 0)
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
res = f(mine, axis=1)
assert_(isinstance(res, MyNDArray))
assert_(np.isnan(res[1]) and not np.isnan(res[0])
and not np.isnan(res[2]))
assert_(len(w) == 1, 'no warning raised')
assert_(issubclass(w[0].category, RuntimeWarning))
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
res = f(mine)
assert_(res.shape == ())
assert_(res != np.nan)
assert_(len(w) == 0)
def test_object_array(self):
arr = np.array([[1.0, 2.0], [np.nan, 4.0], [np.nan, np.nan]], dtype=object)
assert_equal(np.nanmin(arr), 1.0)
assert_equal(np.nanmin(arr, axis=0), [1.0, 2.0])
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
# assert_equal does not work on object arrays of nan
assert_equal(list(np.nanmin(arr, axis=1)), [1.0, 4.0, np.nan])
assert_(len(w) == 1, 'no warning raised')
assert_(issubclass(w[0].category, RuntimeWarning))
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
def test_initial(self, dtype):
class MyNDArray(np.ndarray):
pass
ar = np.arange(9).astype(dtype)
ar[:5] = np.nan
for f in self.nanfuncs:
initial = 100 if f is np.nanmax else 0
ret1 = f(ar, initial=initial)
assert ret1.dtype == dtype
assert ret1 == initial
ret2 = f(ar.view(MyNDArray), initial=initial)
assert ret2.dtype == dtype
assert ret2 == initial
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
def test_where(self, dtype):
class MyNDArray(np.ndarray):
pass
ar = np.arange(9).reshape(3, 3).astype(dtype)
ar[0, :] = np.nan
where = np.ones_like(ar, dtype=np.bool)
where[:, 0] = False
for f in self.nanfuncs:
reference = 4 if f is np.nanmin else 8
ret1 = f(ar, where=where, initial=5)
assert ret1.dtype == dtype
assert ret1 == reference
ret2 = f(ar.view(MyNDArray), where=where, initial=5)
assert ret2.dtype == dtype
assert ret2 == reference
class TestNanFunctions_ArgminArgmax:
nanfuncs = [np.nanargmin, np.nanargmax]
def test_mutation(self):
# Check that passed array is not modified.
ndat = _ndat.copy()
for f in self.nanfuncs:
f(ndat)
assert_equal(ndat, _ndat)
def test_result_values(self):
for f, fcmp in zip(self.nanfuncs, [np.greater, np.less]):
for row in _ndat:
with suppress_warnings() as sup:
sup.filter(RuntimeWarning, "invalid value encountered in")
ind = f(row)
val = row[ind]
# comparing with NaN is tricky as the result
# is always false except for NaN != NaN
assert_(not np.isnan(val))
assert_(not fcmp(val, row).any())
assert_(not np.equal(val, row[:ind]).any())
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
@pytest.mark.parametrize("array", [
np.array(np.nan),
np.full((3, 3), np.nan),
], ids=["0d", "2d"])
def test_allnans(self, axis, dtype, array):
if axis is not None and array.ndim == 0:
pytest.skip(f"`axis != None` not supported for 0d arrays")
array = array.astype(dtype)
for func in self.nanfuncs:
with pytest.raises(ValueError, match="All-NaN slice encountered"):
func(array, axis=axis)
def test_empty(self):
mat = np.zeros((0, 3))
for f in self.nanfuncs:
for axis in [0, None]:
assert_raises_regex(
ValueError,
"attempt to get argm.. of an empty sequence",
f, mat, axis=axis)
for axis in [1]:
res = f(mat, axis=axis)
assert_equal(res, np.zeros(0))
def test_scalar(self):
for f in self.nanfuncs:
assert_(f(0.) == 0.)
def test_subclass(self):
class MyNDArray(np.ndarray):
pass
# Check that it works and that type and
# shape are preserved
mine = np.eye(3).view(MyNDArray)
for f in self.nanfuncs:
res = f(mine, axis=0)
assert_(isinstance(res, MyNDArray))
assert_(res.shape == (3,))
res = f(mine, axis=1)
assert_(isinstance(res, MyNDArray))
assert_(res.shape == (3,))
res = f(mine)
assert_(res.shape == ())
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
def test_keepdims(self, dtype):
ar = np.arange(9).astype(dtype)
ar[:5] = np.nan
for f in self.nanfuncs:
reference = 5 if f is np.nanargmin else 8
ret = f(ar, keepdims=True)
assert ret.ndim == ar.ndim
assert ret == reference
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
def test_out(self, dtype):
ar = np.arange(9).astype(dtype)
ar[:5] = np.nan
for f in self.nanfuncs:
out = np.zeros((), dtype=np.intp)
reference = 5 if f is np.nanargmin else 8
ret = f(ar, out=out)
assert ret is out
assert ret == reference
_TEST_ARRAYS = {
"0d": np.array(5),
"1d": np.array([127, 39, 93, 87, 46])
}
for _v in _TEST_ARRAYS.values():
_v.setflags(write=False)
@pytest.mark.parametrize(
"dtype",
np.typecodes["AllInteger"] + np.typecodes["AllFloat"] + "O",
)
@pytest.mark.parametrize("mat", _TEST_ARRAYS.values(), ids=_TEST_ARRAYS.keys())
class TestNanFunctions_NumberTypes:
nanfuncs = {
np.nanmin: np.min,
np.nanmax: np.max,
np.nanargmin: np.argmin,
np.nanargmax: np.argmax,
np.nansum: np.sum,
np.nanprod: np.prod,
np.nancumsum: np.cumsum,
np.nancumprod: np.cumprod,
np.nanmean: np.mean,
np.nanmedian: np.median,
np.nanvar: np.var,
np.nanstd: np.std,
}
nanfunc_ids = [i.__name__ for i in nanfuncs]
@pytest.mark.parametrize("nanfunc,func", nanfuncs.items(), ids=nanfunc_ids)
@np.errstate(over="ignore")
def test_nanfunc(self, mat, dtype, nanfunc, func):
mat = mat.astype(dtype)
tgt = func(mat)
out = nanfunc(mat)
assert_almost_equal(out, tgt)
if dtype == "O":
assert type(out) is type(tgt)
else:
assert out.dtype == tgt.dtype
@pytest.mark.parametrize(
"nanfunc,func",
[(np.nanquantile, np.quantile), (np.nanpercentile, np.percentile)],
ids=["nanquantile", "nanpercentile"],
)
def test_nanfunc_q(self, mat, dtype, nanfunc, func):
mat = mat.astype(dtype)
if mat.dtype.kind == "c":
assert_raises(TypeError, func, mat, q=1)
assert_raises(TypeError, nanfunc, mat, q=1)
else:
tgt = func(mat, q=1)
out = nanfunc(mat, q=1)
assert_almost_equal(out, tgt)
if dtype == "O":
assert type(out) is type(tgt)
else:
assert out.dtype == tgt.dtype
@pytest.mark.parametrize(
"nanfunc,func",
[(np.nanvar, np.var), (np.nanstd, np.std)],
ids=["nanvar", "nanstd"],
)
def test_nanfunc_ddof(self, mat, dtype, nanfunc, func):
mat = mat.astype(dtype)
tgt = func(mat, ddof=0.5)
out = nanfunc(mat, ddof=0.5)
assert_almost_equal(out, tgt)
if dtype == "O":
assert type(out) is type(tgt)
else:
assert out.dtype == tgt.dtype
@pytest.mark.parametrize(
"nanfunc", [np.nanvar, np.nanstd]
)
def test_nanfunc_correction(self, mat, dtype, nanfunc):
mat = mat.astype(dtype)
assert_almost_equal(
nanfunc(mat, correction=0.5), nanfunc(mat, ddof=0.5)
)
err_msg = "ddof and correction can't be provided simultaneously."
with assert_raises_regex(ValueError, err_msg):
nanfunc(mat, ddof=0.5, correction=0.5)
with assert_raises_regex(ValueError, err_msg):
nanfunc(mat, ddof=1, correction=0)
class SharedNanFunctionsTestsMixin:
def test_mutation(self):
# Check that passed array is not modified.
ndat = _ndat.copy()
for f in self.nanfuncs:
f(ndat)
assert_equal(ndat, _ndat)
def test_keepdims(self):
mat = np.eye(3)
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
for axis in [None, 0, 1]:
tgt = rf(mat, axis=axis, keepdims=True)
res = nf(mat, axis=axis, keepdims=True)
assert_(res.ndim == tgt.ndim)
def test_out(self):
mat = np.eye(3)
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
resout = np.zeros(3)
tgt = rf(mat, axis=1)
res = nf(mat, axis=1, out=resout)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
def test_dtype_from_dtype(self):
mat = np.eye(3)
codes = 'efdgFDG'
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
for c in codes:
with suppress_warnings() as sup:
if nf in {np.nanstd, np.nanvar} and c in 'FDG':
# Giving the warning is a small bug, see gh-8000
sup.filter(ComplexWarning)
tgt = rf(mat, dtype=np.dtype(c), axis=1).dtype.type
res = nf(mat, dtype=np.dtype(c), axis=1).dtype.type
assert_(res is tgt)
# scalar case
tgt = rf(mat, dtype=np.dtype(c), axis=None).dtype.type
res = nf(mat, dtype=np.dtype(c), axis=None).dtype.type
assert_(res is tgt)
def test_dtype_from_char(self):
mat = np.eye(3)
codes = 'efdgFDG'
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
for c in codes:
with suppress_warnings() as sup:
if nf in {np.nanstd, np.nanvar} and c in 'FDG':
# Giving the warning is a small bug, see gh-8000
sup.filter(ComplexWarning)
tgt = rf(mat, dtype=c, axis=1).dtype.type
res = nf(mat, dtype=c, axis=1).dtype.type
assert_(res is tgt)
# scalar case
tgt = rf(mat, dtype=c, axis=None).dtype.type
res = nf(mat, dtype=c, axis=None).dtype.type
assert_(res is tgt)
def test_dtype_from_input(self):
codes = 'efdgFDG'
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
for c in codes:
mat = np.eye(3, dtype=c)
tgt = rf(mat, axis=1).dtype.type
res = nf(mat, axis=1).dtype.type
assert_(res is tgt, "res %s, tgt %s" % (res, tgt))
# scalar case
tgt = rf(mat, axis=None).dtype.type
res = nf(mat, axis=None).dtype.type
assert_(res is tgt)
def test_result_values(self):
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
tgt = [rf(d) for d in _rdat]
res = nf(_ndat, axis=1)
assert_almost_equal(res, tgt)
def test_scalar(self):
for f in self.nanfuncs:
assert_(f(0.) == 0.)
def test_subclass(self):
class MyNDArray(np.ndarray):
pass
# Check that it works and that type and
# shape are preserved
array = np.eye(3)
mine = array.view(MyNDArray)
for f in self.nanfuncs:
expected_shape = f(array, axis=0).shape
res = f(mine, axis=0)
assert_(isinstance(res, MyNDArray))
assert_(res.shape == expected_shape)
expected_shape = f(array, axis=1).shape
res = f(mine, axis=1)
assert_(isinstance(res, MyNDArray))
assert_(res.shape == expected_shape)
expected_shape = f(array).shape
res = f(mine)
assert_(isinstance(res, MyNDArray))
assert_(res.shape == expected_shape)
class TestNanFunctions_SumProd(SharedNanFunctionsTestsMixin):
nanfuncs = [np.nansum, np.nanprod]
stdfuncs = [np.sum, np.prod]
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
@pytest.mark.parametrize("array", [
np.array(np.nan),
np.full((3, 3), np.nan),
], ids=["0d", "2d"])
def test_allnans(self, axis, dtype, array):
if axis is not None and array.ndim == 0:
pytest.skip(f"`axis != None` not supported for 0d arrays")
array = array.astype(dtype)
for func, identity in zip(self.nanfuncs, [0, 1]):
out = func(array, axis=axis)
assert np.all(out == identity)
assert out.dtype == array.dtype
def test_empty(self):
for f, tgt_value in zip([np.nansum, np.nanprod], [0, 1]):
mat = np.zeros((0, 3))
tgt = [tgt_value]*3
res = f(mat, axis=0)
assert_equal(res, tgt)
tgt = []
res = f(mat, axis=1)
assert_equal(res, tgt)
tgt = tgt_value
res = f(mat, axis=None)
assert_equal(res, tgt)
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
def test_initial(self, dtype):
ar = np.arange(9).astype(dtype)
ar[:5] = np.nan
for f in self.nanfuncs:
reference = 28 if f is np.nansum else 3360
ret = f(ar, initial=2)
assert ret.dtype == dtype
assert ret == reference
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
def test_where(self, dtype):
ar = np.arange(9).reshape(3, 3).astype(dtype)
ar[0, :] = np.nan
where = np.ones_like(ar, dtype=np.bool)
where[:, 0] = False
for f in self.nanfuncs:
reference = 26 if f is np.nansum else 2240
ret = f(ar, where=where, initial=2)
assert ret.dtype == dtype
assert ret == reference
class TestNanFunctions_CumSumProd(SharedNanFunctionsTestsMixin):
nanfuncs = [np.nancumsum, np.nancumprod]
stdfuncs = [np.cumsum, np.cumprod]
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
@pytest.mark.parametrize("array", [
np.array(np.nan),
np.full((3, 3), np.nan)
], ids=["0d", "2d"])
def test_allnans(self, axis, dtype, array):
if axis is not None and array.ndim == 0:
pytest.skip(f"`axis != None` not supported for 0d arrays")
array = array.astype(dtype)
for func, identity in zip(self.nanfuncs, [0, 1]):
out = func(array)
assert np.all(out == identity)
assert out.dtype == array.dtype
def test_empty(self):
for f, tgt_value in zip(self.nanfuncs, [0, 1]):
mat = np.zeros((0, 3))
tgt = tgt_value*np.ones((0, 3))
res = f(mat, axis=0)
assert_equal(res, tgt)
tgt = mat
res = f(mat, axis=1)
assert_equal(res, tgt)
tgt = np.zeros(0)
res = f(mat, axis=None)
assert_equal(res, tgt)
def test_keepdims(self):
for f, g in zip(self.nanfuncs, self.stdfuncs):
mat = np.eye(3)
for axis in [None, 0, 1]:
tgt = f(mat, axis=axis, out=None)
res = g(mat, axis=axis, out=None)
assert_(res.ndim == tgt.ndim)
for f in self.nanfuncs:
d = np.ones((3, 5, 7, 11))
# Randomly set some elements to NaN:
rs = np.random.RandomState(0)
d[rs.rand(*d.shape) < 0.5] = np.nan
res = f(d, axis=None)
assert_equal(res.shape, (1155,))
for axis in np.arange(4):
res = f(d, axis=axis)
assert_equal(res.shape, (3, 5, 7, 11))
def test_result_values(self):
for axis in (-2, -1, 0, 1, None):
tgt = np.cumprod(_ndat_ones, axis=axis)
res = np.nancumprod(_ndat, axis=axis)
assert_almost_equal(res, tgt)
tgt = np.cumsum(_ndat_zeros,axis=axis)
res = np.nancumsum(_ndat, axis=axis)
assert_almost_equal(res, tgt)
def test_out(self):
mat = np.eye(3)
for nf, rf in zip(self.nanfuncs, self.stdfuncs):
resout = np.eye(3)
for axis in (-2, -1, 0, 1):
tgt = rf(mat, axis=axis)
res = nf(mat, axis=axis, out=resout)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
class TestNanFunctions_MeanVarStd(SharedNanFunctionsTestsMixin):
nanfuncs = [np.nanmean, np.nanvar, np.nanstd]
stdfuncs = [np.mean, np.var, np.std]
def test_dtype_error(self):
for f in self.nanfuncs:
for dtype in [np.bool, np.int_, np.object_]:
assert_raises(TypeError, f, _ndat, axis=1, dtype=dtype)
def test_out_dtype_error(self):
for f in self.nanfuncs:
for dtype in [np.bool, np.int_, np.object_]:
out = np.empty(_ndat.shape[0], dtype=dtype)
assert_raises(TypeError, f, _ndat, axis=1, out=out)
def test_ddof(self):
nanfuncs = [np.nanvar, np.nanstd]
stdfuncs = [np.var, np.std]
for nf, rf in zip(nanfuncs, stdfuncs):
for ddof in [0, 1]:
tgt = [rf(d, ddof=ddof) for d in _rdat]
res = nf(_ndat, axis=1, ddof=ddof)
assert_almost_equal(res, tgt)
def test_ddof_too_big(self):
nanfuncs = [np.nanvar, np.nanstd]
stdfuncs = [np.var, np.std]
dsize = [len(d) for d in _rdat]
for nf, rf in zip(nanfuncs, stdfuncs):
for ddof in range(5):
with suppress_warnings() as sup:
sup.record(RuntimeWarning)
sup.filter(ComplexWarning)
tgt = [ddof >= d for d in dsize]
res = nf(_ndat, axis=1, ddof=ddof)
assert_equal(np.isnan(res), tgt)
if any(tgt):
assert_(len(sup.log) == 1)
else:
assert_(len(sup.log) == 0)
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
@pytest.mark.parametrize("array", [
np.array(np.nan),
np.full((3, 3), np.nan),
], ids=["0d", "2d"])
def test_allnans(self, axis, dtype, array):
if axis is not None and array.ndim == 0:
pytest.skip(f"`axis != None` not supported for 0d arrays")
array = array.astype(dtype)
match = "(Degrees of freedom <= 0 for slice.)|(Mean of empty slice)"
for func in self.nanfuncs:
with pytest.warns(RuntimeWarning, match=match):
out = func(array, axis=axis)
assert np.isnan(out).all()
# `nanvar` and `nanstd` convert complex inputs to their
# corresponding floating dtype
if func is np.nanmean:
assert out.dtype == array.dtype
else:
assert out.dtype == np.abs(array).dtype
def test_empty(self):
mat = np.zeros((0, 3))
for f in self.nanfuncs:
for axis in [0, None]:
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
assert_(np.isnan(f(mat, axis=axis)).all())
assert_(len(w) == 1)
assert_(issubclass(w[0].category, RuntimeWarning))
for axis in [1]:
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
assert_equal(f(mat, axis=axis), np.zeros([]))
assert_(len(w) == 0)
@pytest.mark.parametrize("dtype", np.typecodes["AllFloat"])
def test_where(self, dtype):
ar = np.arange(9).reshape(3, 3).astype(dtype)
ar[0, :] = np.nan
where = np.ones_like(ar, dtype=np.bool)
where[:, 0] = False
for f, f_std in zip(self.nanfuncs, self.stdfuncs):
reference = f_std(ar[where][2:])
dtype_reference = dtype if f is np.nanmean else ar.real.dtype
ret = f(ar, where=where)
assert ret.dtype == dtype_reference
np.testing.assert_allclose(ret, reference)
def test_nanstd_with_mean_keyword(self):
# Setting the seed to make the test reproducible
rng = np.random.RandomState(1234)
A = rng.randn(10, 20, 5) + 0.5
A[:, 5, :] = np.nan
mean_out = np.zeros((10, 1, 5))
std_out = np.zeros((10, 1, 5))
mean = np.nanmean(A,
out=mean_out,
axis=1,
keepdims=True)
# The returned object should be the object specified during calling
assert mean_out is mean
std = np.nanstd(A,
out=std_out,
axis=1,
keepdims=True,
mean=mean)
# The returned object should be the object specified during calling
assert std_out is std
# Shape of returned mean and std should be same
assert std.shape == mean.shape
assert std.shape == (10, 1, 5)
# Output should be the same as from the individual algorithms
std_old = np.nanstd(A, axis=1, keepdims=True)
assert std_old.shape == mean.shape
assert_almost_equal(std, std_old)
_TIME_UNITS = (
"Y", "M", "W", "D", "h", "m", "s", "ms", "us", "ns", "ps", "fs", "as"
)
# All `inexact` + `timdelta64` type codes
_TYPE_CODES = list(np.typecodes["AllFloat"])
_TYPE_CODES += [f"m8[{unit}]" for unit in _TIME_UNITS]
class TestNanFunctions_Median:
def test_mutation(self):
# Check that passed array is not modified.
ndat = _ndat.copy()
np.nanmedian(ndat)
assert_equal(ndat, _ndat)
def test_keepdims(self):
mat = np.eye(3)
for axis in [None, 0, 1]:
tgt = np.median(mat, axis=axis, out=None, overwrite_input=False)
res = np.nanmedian(mat, axis=axis, out=None, overwrite_input=False)
assert_(res.ndim == tgt.ndim)
d = np.ones((3, 5, 7, 11))
# Randomly set some elements to NaN:
w = np.random.random((4, 200)) * np.array(d.shape)[:, None]
w = w.astype(np.intp)
d[tuple(w)] = np.nan
with suppress_warnings() as sup:
sup.filter(RuntimeWarning)
res = np.nanmedian(d, axis=None, keepdims=True)
assert_equal(res.shape, (1, 1, 1, 1))
res = np.nanmedian(d, axis=(0, 1), keepdims=True)
assert_equal(res.shape, (1, 1, 7, 11))
res = np.nanmedian(d, axis=(0, 3), keepdims=True)
assert_equal(res.shape, (1, 5, 7, 1))
res = np.nanmedian(d, axis=(1,), keepdims=True)
assert_equal(res.shape, (3, 1, 7, 11))
res = np.nanmedian(d, axis=(0, 1, 2, 3), keepdims=True)
assert_equal(res.shape, (1, 1, 1, 1))
res = np.nanmedian(d, axis=(0, 1, 3), keepdims=True)
assert_equal(res.shape, (1, 1, 7, 1))
@pytest.mark.parametrize(
argnames='axis',
argvalues=[
None,
1,
(1, ),
(0, 1),
(-3, -1),
]
)
@pytest.mark.filterwarnings("ignore:All-NaN slice:RuntimeWarning")
def test_keepdims_out(self, axis):
d = np.ones((3, 5, 7, 11))
# Randomly set some elements to NaN:
w = np.random.random((4, 200)) * np.array(d.shape)[:, None]
w = w.astype(np.intp)
d[tuple(w)] = np.nan
if axis is None:
shape_out = (1,) * d.ndim
else:
axis_norm = normalize_axis_tuple(axis, d.ndim)
shape_out = tuple(
1 if i in axis_norm else d.shape[i] for i in range(d.ndim))
out = np.empty(shape_out)
result = np.nanmedian(d, axis=axis, keepdims=True, out=out)
assert result is out
assert_equal(result.shape, shape_out)
def test_out(self):
mat = np.random.rand(3, 3)
nan_mat = np.insert(mat, [0, 2], np.nan, axis=1)
resout = np.zeros(3)
tgt = np.median(mat, axis=1)
res = np.nanmedian(nan_mat, axis=1, out=resout)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
# 0-d output:
resout = np.zeros(())
tgt = np.median(mat, axis=None)
res = np.nanmedian(nan_mat, axis=None, out=resout)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
res = np.nanmedian(nan_mat, axis=(0, 1), out=resout)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
def test_small_large(self):
# test the small and large code paths, current cutoff 400 elements
for s in [5, 20, 51, 200, 1000]:
d = np.random.randn(4, s)
# Randomly set some elements to NaN:
w = np.random.randint(0, d.size, size=d.size // 5)
d.ravel()[w] = np.nan
d[:,0] = 1. # ensure at least one good value
# use normal median without nans to compare
tgt = []
for x in d:
nonan = np.compress(~np.isnan(x), x)
tgt.append(np.median(nonan, overwrite_input=True))
assert_array_equal(np.nanmedian(d, axis=-1), tgt)
def test_result_values(self):
tgt = [np.median(d) for d in _rdat]
res = np.nanmedian(_ndat, axis=1)
assert_almost_equal(res, tgt)
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", _TYPE_CODES)
def test_allnans(self, dtype, axis):
mat = np.full((3, 3), np.nan).astype(dtype)
with suppress_warnings() as sup:
sup.record(RuntimeWarning)
output = np.nanmedian(mat, axis=axis)
assert output.dtype == mat.dtype
assert np.isnan(output).all()
if axis is None:
assert_(len(sup.log) == 1)
else:
assert_(len(sup.log) == 3)
# Check scalar
scalar = np.array(np.nan).astype(dtype)[()]
output_scalar = np.nanmedian(scalar)
assert output_scalar.dtype == scalar.dtype
assert np.isnan(output_scalar)
if axis is None:
assert_(len(sup.log) == 2)
else:
assert_(len(sup.log) == 4)
def test_empty(self):
mat = np.zeros((0, 3))
for axis in [0, None]:
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
assert_(np.isnan(np.nanmedian(mat, axis=axis)).all())
assert_(len(w) == 1)
assert_(issubclass(w[0].category, RuntimeWarning))
for axis in [1]:
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
assert_equal(np.nanmedian(mat, axis=axis), np.zeros([]))
assert_(len(w) == 0)
def test_scalar(self):
assert_(np.nanmedian(0.) == 0.)
def test_extended_axis_invalid(self):
d = np.ones((3, 5, 7, 11))
assert_raises(AxisError, np.nanmedian, d, axis=-5)
assert_raises(AxisError, np.nanmedian, d, axis=(0, -5))
assert_raises(AxisError, np.nanmedian, d, axis=4)
assert_raises(AxisError, np.nanmedian, d, axis=(0, 4))
assert_raises(ValueError, np.nanmedian, d, axis=(1, 1))
def test_float_special(self):
with suppress_warnings() as sup:
sup.filter(RuntimeWarning)
for inf in [np.inf, -np.inf]:
a = np.array([[inf, np.nan], [np.nan, np.nan]])
assert_equal(np.nanmedian(a, axis=0), [inf, np.nan])
assert_equal(np.nanmedian(a, axis=1), [inf, np.nan])
assert_equal(np.nanmedian(a), inf)
# minimum fill value check
a = np.array([[np.nan, np.nan, inf],
[np.nan, np.nan, inf]])
assert_equal(np.nanmedian(a), inf)
assert_equal(np.nanmedian(a, axis=0), [np.nan, np.nan, inf])
assert_equal(np.nanmedian(a, axis=1), inf)
# no mask path
a = np.array([[inf, inf], [inf, inf]])
assert_equal(np.nanmedian(a, axis=1), inf)
a = np.array([[inf, 7, -inf, -9],
[-10, np.nan, np.nan, 5],
[4, np.nan, np.nan, inf]],
dtype=np.float32)
if inf > 0:
assert_equal(np.nanmedian(a, axis=0), [4., 7., -inf, 5.])
assert_equal(np.nanmedian(a), 4.5)
else:
assert_equal(np.nanmedian(a, axis=0), [-10., 7., -inf, -9.])
assert_equal(np.nanmedian(a), -2.5)
assert_equal(np.nanmedian(a, axis=-1), [-1., -2.5, inf])
for i in range(0, 10):
for j in range(1, 10):
a = np.array([([np.nan] * i) + ([inf] * j)] * 2)
assert_equal(np.nanmedian(a), inf)
assert_equal(np.nanmedian(a, axis=1), inf)
assert_equal(np.nanmedian(a, axis=0),
([np.nan] * i) + [inf] * j)
a = np.array([([np.nan] * i) + ([-inf] * j)] * 2)
assert_equal(np.nanmedian(a), -inf)
assert_equal(np.nanmedian(a, axis=1), -inf)
assert_equal(np.nanmedian(a, axis=0),
([np.nan] * i) + [-inf] * j)
class TestNanFunctions_Percentile:
def test_mutation(self):
# Check that passed array is not modified.
ndat = _ndat.copy()
np.nanpercentile(ndat, 30)
assert_equal(ndat, _ndat)
def test_keepdims(self):
mat = np.eye(3)
for axis in [None, 0, 1]:
tgt = np.percentile(mat, 70, axis=axis, out=None,
overwrite_input=False)
res = np.nanpercentile(mat, 70, axis=axis, out=None,
overwrite_input=False)
assert_(res.ndim == tgt.ndim)
d = np.ones((3, 5, 7, 11))
# Randomly set some elements to NaN:
w = np.random.random((4, 200)) * np.array(d.shape)[:, None]
w = w.astype(np.intp)
d[tuple(w)] = np.nan
with suppress_warnings() as sup:
sup.filter(RuntimeWarning)
res = np.nanpercentile(d, 90, axis=None, keepdims=True)
assert_equal(res.shape, (1, 1, 1, 1))
res = np.nanpercentile(d, 90, axis=(0, 1), keepdims=True)
assert_equal(res.shape, (1, 1, 7, 11))
res = np.nanpercentile(d, 90, axis=(0, 3), keepdims=True)
assert_equal(res.shape, (1, 5, 7, 1))
res = np.nanpercentile(d, 90, axis=(1,), keepdims=True)
assert_equal(res.shape, (3, 1, 7, 11))
res = np.nanpercentile(d, 90, axis=(0, 1, 2, 3), keepdims=True)
assert_equal(res.shape, (1, 1, 1, 1))
res = np.nanpercentile(d, 90, axis=(0, 1, 3), keepdims=True)
assert_equal(res.shape, (1, 1, 7, 1))
@pytest.mark.parametrize('q', [7, [1, 7]])
@pytest.mark.parametrize(
argnames='axis',
argvalues=[
None,
1,
(1,),
(0, 1),
(-3, -1),
]
)
@pytest.mark.filterwarnings("ignore:All-NaN slice:RuntimeWarning")
def test_keepdims_out(self, q, axis):
d = np.ones((3, 5, 7, 11))
# Randomly set some elements to NaN:
w = np.random.random((4, 200)) * np.array(d.shape)[:, None]
w = w.astype(np.intp)
d[tuple(w)] = np.nan
if axis is None:
shape_out = (1,) * d.ndim
else:
axis_norm = normalize_axis_tuple(axis, d.ndim)
shape_out = tuple(
1 if i in axis_norm else d.shape[i] for i in range(d.ndim))
shape_out = np.shape(q) + shape_out
out = np.empty(shape_out)
result = np.nanpercentile(d, q, axis=axis, keepdims=True, out=out)
assert result is out
assert_equal(result.shape, shape_out)
@pytest.mark.parametrize("weighted", [False, True])
def test_out(self, weighted):
mat = np.random.rand(3, 3)
nan_mat = np.insert(mat, [0, 2], np.nan, axis=1)
resout = np.zeros(3)
if weighted:
w_args = {"weights": np.ones_like(mat), "method": "inverted_cdf"}
nan_w_args = {
"weights": np.ones_like(nan_mat), "method": "inverted_cdf"
}
else:
w_args = dict()
nan_w_args = dict()
tgt = np.percentile(mat, 42, axis=1, **w_args)
res = np.nanpercentile(nan_mat, 42, axis=1, out=resout, **nan_w_args)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
# 0-d output:
resout = np.zeros(())
tgt = np.percentile(mat, 42, axis=None, **w_args)
res = np.nanpercentile(
nan_mat, 42, axis=None, out=resout, **nan_w_args
)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
res = np.nanpercentile(
nan_mat, 42, axis=(0, 1), out=resout, **nan_w_args
)
assert_almost_equal(res, resout)
assert_almost_equal(res, tgt)
def test_complex(self):
arr_c = np.array([0.5+3.0j, 2.1+0.5j, 1.6+2.3j], dtype='G')
assert_raises(TypeError, np.nanpercentile, arr_c, 0.5)
arr_c = np.array([0.5+3.0j, 2.1+0.5j, 1.6+2.3j], dtype='D')
assert_raises(TypeError, np.nanpercentile, arr_c, 0.5)
arr_c = np.array([0.5+3.0j, 2.1+0.5j, 1.6+2.3j], dtype='F')
assert_raises(TypeError, np.nanpercentile, arr_c, 0.5)
@pytest.mark.parametrize("weighted", [False, True])
@pytest.mark.parametrize("use_out", [False, True])
def test_result_values(self, weighted, use_out):
if weighted:
percentile = partial(np.percentile, method="inverted_cdf")
nanpercentile = partial(np.nanpercentile, method="inverted_cdf")
def gen_weights(d):
return np.ones_like(d)
else:
percentile = np.percentile
nanpercentile = np.nanpercentile
def gen_weights(d):
return None
tgt = [percentile(d, 28, weights=gen_weights(d)) for d in _rdat]
out = np.empty_like(tgt) if use_out else None
res = nanpercentile(_ndat, 28, axis=1,
weights=gen_weights(_ndat), out=out)
assert_almost_equal(res, tgt)
# Transpose the array to fit the output convention of numpy.percentile
tgt = np.transpose([percentile(d, (28, 98), weights=gen_weights(d))
for d in _rdat])
out = np.empty_like(tgt) if use_out else None
res = nanpercentile(_ndat, (28, 98), axis=1,
weights=gen_weights(_ndat), out=out)
assert_almost_equal(res, tgt)
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", np.typecodes["Float"])
@pytest.mark.parametrize("array", [
np.array(np.nan),
np.full((3, 3), np.nan),
], ids=["0d", "2d"])
def test_allnans(self, axis, dtype, array):
if axis is not None and array.ndim == 0:
pytest.skip(f"`axis != None` not supported for 0d arrays")
array = array.astype(dtype)
with pytest.warns(RuntimeWarning, match="All-NaN slice encountered"):
out = np.nanpercentile(array, 60, axis=axis)
assert np.isnan(out).all()
assert out.dtype == array.dtype
def test_empty(self):
mat = np.zeros((0, 3))
for axis in [0, None]:
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
assert_(np.isnan(np.nanpercentile(mat, 40, axis=axis)).all())
assert_(len(w) == 1)
assert_(issubclass(w[0].category, RuntimeWarning))
for axis in [1]:
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter('always')
assert_equal(np.nanpercentile(mat, 40, axis=axis), np.zeros([]))
assert_(len(w) == 0)
def test_scalar(self):
assert_equal(np.nanpercentile(0., 100), 0.)
a = np.arange(6)
r = np.nanpercentile(a, 50, axis=0)
assert_equal(r, 2.5)
assert_(np.isscalar(r))
def test_extended_axis_invalid(self):
d = np.ones((3, 5, 7, 11))
assert_raises(AxisError, np.nanpercentile, d, q=5, axis=-5)
assert_raises(AxisError, np.nanpercentile, d, q=5, axis=(0, -5))
assert_raises(AxisError, np.nanpercentile, d, q=5, axis=4)
assert_raises(AxisError, np.nanpercentile, d, q=5, axis=(0, 4))
assert_raises(ValueError, np.nanpercentile, d, q=5, axis=(1, 1))
def test_multiple_percentiles(self):
perc = [50, 100]
mat = np.ones((4, 3))
nan_mat = np.nan * mat
# For checking consistency in higher dimensional case
large_mat = np.ones((3, 4, 5))
large_mat[:, 0:2:4, :] = 0
large_mat[:, :, 3:] *= 2
for axis in [None, 0, 1]:
for keepdim in [False, True]:
with suppress_warnings() as sup:
sup.filter(RuntimeWarning, "All-NaN slice encountered")
val = np.percentile(mat, perc, axis=axis, keepdims=keepdim)
nan_val = np.nanpercentile(nan_mat, perc, axis=axis,
keepdims=keepdim)
assert_equal(nan_val.shape, val.shape)
val = np.percentile(large_mat, perc, axis=axis,
keepdims=keepdim)
nan_val = np.nanpercentile(large_mat, perc, axis=axis,
keepdims=keepdim)
assert_equal(nan_val, val)
megamat = np.ones((3, 4, 5, 6))
assert_equal(
np.nanpercentile(megamat, perc, axis=(1, 2)).shape, (2, 3, 6)
)
@pytest.mark.parametrize("nan_weight", [0, 1, 2, 3, 1e200])
def test_nan_value_with_weight(self, nan_weight):
x = [1, np.nan, 2, 3]
result = np.float64(2.0)
q_unweighted = np.nanpercentile(x, 50, method="inverted_cdf")
assert_equal(q_unweighted, result)
# The weight value at the nan position should not matter.
w = [1.0, nan_weight, 1.0, 1.0]
q_weighted = np.nanpercentile(x, 50, weights=w, method="inverted_cdf")
assert_equal(q_weighted, result)
@pytest.mark.parametrize("axis", [0, 1, 2])
def test_nan_value_with_weight_ndim(self, axis):
# Create a multi-dimensional array to test
np.random.seed(1)
x_no_nan = np.random.random(size=(100, 99, 2))
# Set some places to NaN (not particularly smart) so there is always
# some non-Nan.
x = x_no_nan.copy()
x[np.arange(99), np.arange(99), 0] = np.nan
p = np.array([[20., 50., 30], [70, 33, 80]])
# We just use ones as weights, but replace it with 0 or 1e200 at the
# NaN positions below.
weights = np.ones_like(x)
# For comparison use weighted normal percentile with nan weights at
# 0 (and no NaNs); not sure this is strictly identical but should be
# sufficiently so (if a percentile lies exactly on a 0 value).
weights[np.isnan(x)] = 0
p_expected = np.percentile(
x_no_nan, p, axis=axis, weights=weights, method="inverted_cdf")
p_unweighted = np.nanpercentile(
x, p, axis=axis, method="inverted_cdf")
# The normal and unweighted versions should be identical:
assert_equal(p_unweighted, p_expected)
weights[np.isnan(x)] = 1e200 # huge value, shouldn't matter
p_weighted = np.nanpercentile(
x, p, axis=axis, weights=weights, method="inverted_cdf")
assert_equal(p_weighted, p_expected)
# Also check with out passed:
out = np.empty_like(p_weighted)
res = np.nanpercentile(
x, p, axis=axis, weights=weights, out=out, method="inverted_cdf")
assert res is out
assert_equal(out, p_expected)
class TestNanFunctions_Quantile:
# most of this is already tested by TestPercentile
@pytest.mark.parametrize("weighted", [False, True])
def test_regression(self, weighted):
ar = np.arange(24).reshape(2, 3, 4).astype(float)
ar[0][1] = np.nan
if weighted:
w_args = {"weights": np.ones_like(ar), "method": "inverted_cdf"}
else:
w_args = dict()
assert_equal(np.nanquantile(ar, q=0.5, **w_args),
np.nanpercentile(ar, q=50, **w_args))
assert_equal(np.nanquantile(ar, q=0.5, axis=0, **w_args),
np.nanpercentile(ar, q=50, axis=0, **w_args))
assert_equal(np.nanquantile(ar, q=0.5, axis=1, **w_args),
np.nanpercentile(ar, q=50, axis=1, **w_args))
assert_equal(np.nanquantile(ar, q=[0.5], axis=1, **w_args),
np.nanpercentile(ar, q=[50], axis=1, **w_args))
assert_equal(np.nanquantile(ar, q=[0.25, 0.5, 0.75], axis=1, **w_args),
np.nanpercentile(ar, q=[25, 50, 75], axis=1, **w_args))
def test_basic(self):
x = np.arange(8) * 0.5
assert_equal(np.nanquantile(x, 0), 0.)
assert_equal(np.nanquantile(x, 1), 3.5)
assert_equal(np.nanquantile(x, 0.5), 1.75)
def test_complex(self):
arr_c = np.array([0.5+3.0j, 2.1+0.5j, 1.6+2.3j], dtype='G')
assert_raises(TypeError, np.nanquantile, arr_c, 0.5)
arr_c = np.array([0.5+3.0j, 2.1+0.5j, 1.6+2.3j], dtype='D')
assert_raises(TypeError, np.nanquantile, arr_c, 0.5)
arr_c = np.array([0.5+3.0j, 2.1+0.5j, 1.6+2.3j], dtype='F')
assert_raises(TypeError, np.nanquantile, arr_c, 0.5)
def test_no_p_overwrite(self):
# this is worth retesting, because quantile does not make a copy
p0 = np.array([0, 0.75, 0.25, 0.5, 1.0])
p = p0.copy()
np.nanquantile(np.arange(100.), p, method="midpoint")
assert_array_equal(p, p0)
p0 = p0.tolist()
p = p.tolist()
np.nanquantile(np.arange(100.), p, method="midpoint")
assert_array_equal(p, p0)
@pytest.mark.parametrize("axis", [None, 0, 1])
@pytest.mark.parametrize("dtype", np.typecodes["Float"])
@pytest.mark.parametrize("array", [
np.array(np.nan),
np.full((3, 3), np.nan),
], ids=["0d", "2d"])
def test_allnans(self, axis, dtype, array):
if axis is not None and array.ndim == 0:
pytest.skip(f"`axis != None` not supported for 0d arrays")
array = array.astype(dtype)
with pytest.warns(RuntimeWarning, match="All-NaN slice encountered"):
out = np.nanquantile(array, 1, axis=axis)
assert np.isnan(out).all()
assert out.dtype == array.dtype
@pytest.mark.parametrize("arr, expected", [
# array of floats with some nans
(np.array([np.nan, 5.0, np.nan, np.inf]),
np.array([False, True, False, True])),
# int64 array that can't possibly have nans
(np.array([1, 5, 7, 9], dtype=np.int64),
True),
# bool array that can't possibly have nans
(np.array([False, True, False, True]),
True),
# 2-D complex array with nans
(np.array([[np.nan, 5.0],
[np.nan, np.inf]], dtype=np.complex64),
np.array([[False, True],
[False, True]])),
])
def test__nan_mask(arr, expected):
for out in [None, np.empty(arr.shape, dtype=np.bool)]:
actual = _nan_mask(arr, out=out)
assert_equal(actual, expected)
# the above won't distinguish between True proper
# and an array of True values; we want True proper
# for types that can't possibly contain NaN
if type(expected) is not np.ndarray:
assert actual is True
def test__replace_nan():
""" Test that _replace_nan returns the original array if there are no
NaNs, not a copy.
"""
for dtype in [np.bool, np.int32, np.int64]:
arr = np.array([0, 1], dtype=dtype)
result, mask = _replace_nan(arr, 0)
assert mask is None
# do not make a copy if there are no nans
assert result is arr
for dtype in [np.float32, np.float64]:
arr = np.array([0, 1], dtype=dtype)
result, mask = _replace_nan(arr, 2)
assert (mask == False).all()
# mask is not None, so we make a copy
assert result is not arr
assert_equal(result, arr)
arr_nan = np.array([0, 1, np.nan], dtype=dtype)
result_nan, mask_nan = _replace_nan(arr_nan, 2)
assert_equal(mask_nan, np.array([False, False, True]))
assert result_nan is not arr_nan
assert_equal(result_nan, np.array([0, 1, 2]))
assert np.isnan(arr_nan[-1])