def test_assert_warns_type():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(category=UserWarning):
warnsA()
warnsC()
with assert_warns(category=DeprecationWarning):
warnsB()
def test_assert_warns_type():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(category=UserWarning):
warnsA()
warnsC()
with assert_warns(category=DeprecationWarning):
warnsB()
def test_assert_warns_full_message():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(message="Warning A!"):
warnsA()
with assert_warns(message="Warning B!"):
warnsB()
with assert_warns(message="Warning C!"):
warnsC()
with assert_warns(message=["Warning A!", "Warning B!", "Warning C!"]):
warnsA()
warnsB()
warnsC()
def test_assert_warns_full_message():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(message="Warning A!"):
warnsA()
with assert_warns(message="Warning B!"):
warnsB()
with assert_warns(message="Warning C!"):
warnsC()
with assert_warns(message=["Warning A!", "Warning B!", "Warning C!"]):
warnsA()
warnsB()
warnsC()
def test_convert_to_units_unsupported_units(self, same_units):
with assert_warns(message="not supported for conversion.",
category=UserWarning):
self.am.convert_units('navigation',
units='toto',
same_units=same_units)
assert_deep_almost_equal(self.am._get_axes_dicts(), self.axes_list)
def test_min_not_in_window(self):
# If I use a much lower window, this is the value that has to be
# returned as threshold.
s = self.spectrum
with assert_warns("No inflexion point could be found in some " "positions that have been marked with nans."):
data = s.estimate_elastic_scattering_threshold(window=1.5, tol=0.001).data
nt.assert_true(np.all(np.isnan(data)))
def test(self):
s = self.signal
sAl = s.get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
assert sAl.axes_manager.signal_dimension == 0
np.testing.assert_allclose(24.99516, sAl.data[0, 0, 0], atol=1e-3)
sAl = s.inav[0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data[0, 0], atol=1e-3)
sAl = s.inav[0, 0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data[0], atol=1e-3)
sAl = s.inav[0, 0, 0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data, atol=1e-3)
s.axes_manager[-1].offset = 1.0
with assert_warns(message="C_Ka is not in the data energy range."):
sC = s.get_lines_intensity(["C_Ka"], plot_result=False)
assert len(sC) == 0
assert sAl.metadata.Sample.elements == ["Al"]
assert sAl.metadata.Sample.xray_lines == ["Al_Ka"]
def test_converted_compact_scale_units(self):
self.uc.units = 'micron'
with assert_warns(message="not supported for conversion.",
category=UserWarning):
self.uc._convert_compact_units()
assert self.uc.units == 'micron'
nt.assert_almost_equal(self.uc.scale, 1.0E-3)
def test_assert_warns_partial_message():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(message="Warning"):
warnsA()
warnsB()
warnsC()
def test_assert_warns_partial_message():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(message="Warning"):
warnsA()
warnsB()
warnsC()
def test_ignore_conversion(self):
assert self.uc._ignore_conversion(t.Undefined)
with assert_warns(
message="not supported for conversion.",
category=UserWarning):
assert self.uc._ignore_conversion('unit_not_supported')
assert not self.uc._ignore_conversion('m')
def test_assert_warns_regex_message():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(message="Warning .?!"):
warnsA()
warnsB()
warnsC()
def test_assert_warns_regex_message():
with all_warnings():
warnings.simplefilter("error")
with assert_warns(message="Warning .?!"):
warnsA()
warnsB()
warnsC()
def test_units_not_supported_by_pint_warning_raised2(self):
# raising a warning, not converting scale
self.axis.units = 'µm'
with assert_warns(message="not supported for conversion.",
category=UserWarning):
self.axis.convert_to_units('toto')
nt.assert_almost_equal(self.axis.scale, 12E-12)
assert self.axis.units == 'µm'
def test_converted_compact_scale_units(self):
self.uc.units = 'micron'
with assert_warns(
message="not supported for conversion.",
category=UserWarning):
self.uc._convert_compact_units()
assert self.uc.units == 'micron'
nt.assert_almost_equal(self.uc.scale, 1.0E-3)
def test_convert_to_units_unsupported_units(self, same_units):
with assert_warns(
message="not supported for conversion.",
category=UserWarning):
self.am.convert_units('navigation', units='toto',
same_units=same_units)
assert_deep_almost_equal(self.am._get_axes_dicts(),
self.axes_list)
def test_units_not_supported_by_pint_warning_raised2(self):
# raising a warning, not converting scale
self.axis.units = 'µm'
with assert_warns(
message="not supported for conversion.",
category=UserWarning):
self.axis.convert_to_units('toto')
nt.assert_almost_equal(self.axis.scale, 12E-12)
assert self.axis.units == 'µm'
def test_min_not_in_window(self):
# If I use a much lower window, this is the value that has to be
# returned as threshold.
s = self.signal
with assert_warns("No inflexion point could be found in some "
"positions that have been marked with nans."):
data = s.estimate_elastic_scattering_threshold(window=1.5,
tol=0.001).data
nt.assert_true(np.all(np.isnan(data)))
def test_assert_warns_type_fails():
with all_warnings():
warnings.simplefilter("error")
try:
with assert_warns(category=UserWarning):
warnsB()
except ValueError:
pass
else:
raise ValueError("Expected warning to give error!")
def test_assert_warns_message_fails():
with all_warnings():
warnings.simplefilter("error")
try:
with assert_warns(message="Warning [AB]!"):
warnsC()
except ValueError:
pass
else:
raise AssertionError("ValueError expected!")
with all_warnings():
warnings.simplefilter("error")
try:
with assert_warns(message="Warning A! Too much"):
warnsA()
except ValueError:
pass
else:
raise ValueError("ValueError expected!")
def test_assert_warns_type_fails():
with all_warnings():
warnings.simplefilter("error")
try:
with assert_warns(category=UserWarning):
warnsB()
except ValueError:
pass
else:
raise ValueError("Expected warning to give error!")
def test_assert_warns_message_fails():
with all_warnings():
warnings.simplefilter("error")
try:
with assert_warns(message="Warning [AB]!"):
warnsC()
except ValueError:
pass
else:
raise AssertionError("ValueError expected!")
with all_warnings():
warnings.simplefilter("error")
try:
with assert_warns(message="Warning A! Too much"):
warnsA()
except ValueError:
pass
else:
raise ValueError("ValueError expected!")
def test_calibrate_energy_resolution(self):
s = self.s
m = s.create_model()
m.fit()
m.fit_background()
reso = (s.metadata.Acquisition_instrument.TEM.Detector.EDS.energy_resolution_MnKa,)
s.set_microscope_parameters(energy_resolution_MnKa=150)
with assert_warns(message=r"Energy resolution \(FWHM at Mn Ka\) " "changed from"):
m.calibrate_energy_axis(calibrate="resolution")
nt.assert_true(
np.allclose(s.metadata.Acquisition_instrument.TEM.Detector.EDS.energy_resolution_MnKa, reso, atol=1)
)
def test_calibrate_energy_resolution(self):
s = self.s
m = s.create_model()
m.fit()
m.fit_background()
reso = s.metadata.Acquisition_instrument.TEM.Detector.EDS.\
energy_resolution_MnKa,
s.set_microscope_parameters(energy_resolution_MnKa=150)
with assert_warns(message=r"Energy resolution \(FWHM at Mn Ka\) "
"changed from"):
m.calibrate_energy_axis(calibrate='resolution')
nt.assert_true(np.allclose(
s.metadata.Acquisition_instrument.TEM.Detector.EDS.
energy_resolution_MnKa, reso, atol=1))
def test_calibrate_xray_weight(self):
s = self.s
s1 = utils_eds.xray_lines_model(
elements=["Co"],
weight_percents=[50],
energy_axis={"units": "keV", "size": 400, "scale": 0.01, "name": "E", "offset": 4.9},
)
s = s + s1 / 50
m = s.create_model()
m.fit()
with assert_warns(message="The X-ray line expected to be in the model " "was not found"):
m.calibrate_xray_lines(calibrate="sub_weight", xray_lines=["Fe_Ka"], bound=100)
nt.assert_true(np.allclose(0.0347, m["Fe_Kb"].A.value, atol=1e-3))
def test(self):
s = self.signal
sAl = s.get_lines_intensity(["Al_Ka"], plot_result=False, integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data[0, 0, 0], atol=1e-3)
sAl = s.inav[0].get_lines_intensity(["Al_Ka"], plot_result=False, integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data[0, 0], atol=1e-3)
sAl = s.inav[0, 0].get_lines_intensity(["Al_Ka"], plot_result=False, integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data[0], atol=1e-3)
sAl = s.inav[0, 0, 0].get_lines_intensity(["Al_Ka"], plot_result=False, integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data, atol=1e-3)
s.axes_manager[-1].offset = 1.0
with assert_warns(message="C_Ka is not in the data energy range."):
sC = s.get_lines_intensity(["C_Ka"], plot_result=False)
nt.assert_equal(len(sC), 0)
nt.assert_equal(sAl.metadata.Sample.elements, ["Al"])
nt.assert_equal(sAl.metadata.Sample.xray_lines, ["Al_Ka"])
def test(self):
s = self.signal
# get_lines_intensity() should raise TypeError when
# xray_lines is a string or a dictionary
for bad_iter in ["Al_Kb", {"A": "Al_Kb", "B": "Ca_Ka"}]:
assert_raises(TypeError,
s.get_lines_intensity,
xray_lines=bad_iter,
plot_result=False)
# get_lines_intensity() should succeed and return a list
# when xray_lines is an iterable (other than a str or dict)
good_iter = {
"tuple": ("Al_Kb", "Ca_Ka"),
"list": ["Al_Kb", "Ca_Ka"],
"set": set(["Al_Kb", "Ca_Ka"])
}
for itr in good_iter:
assert isinstance(s.get_lines_intensity(
xray_lines=good_iter[itr],
plot_result=False), list), \
"get_lines_intensity() trouble with {}".format( itr )
sAl = s.get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
assert sAl.axes_manager.signal_dimension == 0
np.testing.assert_allclose(24.99516, sAl.data[0, 0, 0], atol=1e-3)
sAl = s.inav[0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data[0, 0], atol=1e-3)
sAl = s.inav[0, 0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data[0], atol=1e-3)
sAl = s.inav[0, 0, 0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
np.testing.assert_allclose(24.99516, sAl.data, atol=1e-3)
s.axes_manager[-1].offset = 1.0
with assert_warns(message="C_Ka is not in the data energy range."):
sC = s.get_lines_intensity(["C_Ka"], plot_result=False)
assert len(sC) == 0
assert sAl.metadata.Sample.elements == ["Al"]
assert sAl.metadata.Sample.xray_lines == ["Al_Ka"]
def test_calibrate_xray_weight(self):
s = self.s
s1 = utils_eds.xray_lines_model(
elements=['Co'],
weight_percents=[50],
energy_axis={'units': 'keV', 'size': 400,
'scale': 0.01, 'name': 'E',
'offset': 4.9})
s = (s + s1 / 50)
m = s.create_model()
m.fit()
with assert_warns(message='The X-ray line expected to be in the model '
'was not found'):
m.calibrate_xray_lines(calibrate='sub_weight',
xray_lines=['Fe_Ka'], bound=100)
np.testing.assert_allclose(0.0347, m['Fe_Kb'].A.value,
atol=1e-3)
def test_guess_units_from_mode(self):
from hyperspy.io_plugins.fei import _guess_units_from_mode, \
convert_xml_to_dict, get_xml_info_from_emi
fname0_emi = os.path.join(
self.dirpathold, '64x64_TEM_images_acquire.emi')
fname0_ser = os.path.join(
self.dirpathold, '64x64_TEM_images_acquire_1.ser')
objects = get_xml_info_from_emi(fname0_emi)
header0, data0 = load_ser_file(fname0_ser)
objects_dict = convert_xml_to_dict(objects[0])
unit = _guess_units_from_mode(objects_dict, header0)
nt.assert_equal(unit, 'meters')
# objects is empty dictionary
with assert_warns(
message="The navigation axes units could not be determined.",
category=UserWarning):
unit = _guess_units_from_mode({}, header0)
nt.assert_equal(unit, 'meters')
def test_guess_units_from_mode(self):
from hyperspy.io_plugins.fei import _guess_units_from_mode, \
convert_xml_to_dict, get_xml_info_from_emi
fname0_emi = os.path.join(self.dirpathold,
'64x64_TEM_images_acquire.emi')
fname0_ser = os.path.join(self.dirpathold,
'64x64_TEM_images_acquire_1.ser')
objects = get_xml_info_from_emi(fname0_emi)
header0, data0 = load_ser_file(fname0_ser)
objects_dict = convert_xml_to_dict(objects[0])
unit = _guess_units_from_mode(objects_dict, header0)
assert unit == 'meters'
# objects is empty dictionary
with assert_warns(
message="The navigation axes units could not be determined.",
category=UserWarning):
unit = _guess_units_from_mode({}, header0)
assert unit == 'meters'
def test(self):
s = self.signal
sAl = s.get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
nt.assert_true(np.allclose(24.99516, sAl.data[0, 0, 0], atol=1e-3))
sAl = s.inav[0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
nt.assert_true(np.allclose(24.99516, sAl.data[0, 0], atol=1e-3))
sAl = s.inav[0, 0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
nt.assert_true(np.allclose(24.99516, sAl.data[0], atol=1e-3))
sAl = s.inav[0, 0, 0].get_lines_intensity(["Al_Ka"],
plot_result=False,
integration_windows=5)[0]
nt.assert_true(np.allclose(24.99516, sAl.data, atol=1e-3))
s.axes_manager[-1].offset = 1.0
with assert_warns(message="C_Ka is not in the data energy range."):
sC = s.get_lines_intensity(["C_Ka"], plot_result=False)
nt.assert_equal(len(sC), 0)
nt.assert_true(sAl.metadata.Sample.elements, ["Al"])
nt.assert_true(sAl.metadata.Sample.xray_lines, ["Al_Ka"])
def test_ignore_conversion(self):
assert self.uc._ignore_conversion(t.Undefined)
with assert_warns(message="not supported for conversion.",
category=UserWarning):
assert self.uc._ignore_conversion('unit_not_supported')
assert not self.uc._ignore_conversion('m')
