Ejemplo n.º 1
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 def setup_method(self, method):
     # Create three signals with dimensions:
     # s1 : <BaseSignal, title: , dimensions: (4, 3, 2|2, 3)>
     # s2 : <BaseSignal, title: , dimensions: (2, 3|4, 3, 2)>
     # s12 : <BaseSignal, title: , dimensions: (2, 3|4, 3, 2)>
     # Where s12 data is transposed in respect to s2
     dc1 = np.random.random((2, 3, 4, 3, 2))
     dc2 = np.rollaxis(np.rollaxis(dc1, -1), -1)
     s1 = signals.BaseSignal(dc1.copy())
     s2 = signals.BaseSignal(dc2)
     s12 = signals.BaseSignal(dc1.copy())
     for i, axis in enumerate(s1.axes_manager._axes):
         if i < 3:
             axis.navigate = True
         else:
             axis.navigate = False
     for i, axis in enumerate(s2.axes_manager._axes):
         if i < 2:
             axis.navigate = True
         else:
             axis.navigate = False
     for i, axis in enumerate(s12.axes_manager._axes):
         if i < 3:
             axis.navigate = False
         else:
             axis.navigate = True
     self.s1 = s1
     self.s2 = s2
     self.s12 = s12
Ejemplo n.º 2
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def test_error_axes():
    rng = np.random.RandomState(123)
    s = signals.BaseSignal(rng.random((20, 100)))

    with pytest.raises(AttributeError,
                       match="not possible to decompose a dataset"):
        s.decomposition()
Ejemplo n.º 3
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 def setup_method(self, method):
     s = signals.BaseSignal(np.zeros(1))
     self.factors = np.ones([2, 3])
     self.loadings = np.ones([2, 3])
     s.learning_results.factors = self.factors.copy()
     s.learning_results.loadings = self.loadings.copy()
     self.s = s
Ejemplo n.º 4
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def _create_signal(shape, dim, dtype, metadata):
    data = np.arange(np.product(shape)).reshape(shape).astype(dtype)
    if dim == 1:
        if len(shape) > 2:
            s = signals.EELSSpectrum(data)
            if metadata:
                s.set_microscope_parameters(beam_energy=100.,
                                            convergence_angle=1.,
                                            collection_angle=10.)
        else:
            s = signals.EDSTEMSpectrum(data)
            if metadata:
                s.set_microscope_parameters(beam_energy=100.,
                                            live_time=1.,
                                            tilt_stage=2.,
                                            azimuth_angle=3.,
                                            elevation_angle=4.,
                                            energy_resolution_MnKa=5.)
    else:
        s = signals.BaseSignal(data).transpose(signal_axes=dim)
    if metadata:
        s.metadata.General.date = "2016-08-06"
        s.metadata.General.time = "10:55:00"
        s.metadata.General.title = "Test title"
    for i, axis in enumerate(s.axes_manager._axes):
        i += 1
        axis.offset = i * 0.5
        axis.scale = i * 100
        axis.name = "%i" % i
        if axis.navigate:
            axis.units = "m"
        else:
            axis.units = "eV"

    return s
Ejemplo n.º 5
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 def _read_signal_from_group(self, name, group, load_to_memory=True):
     self._log.debug('Calling _read_signal_from_group')
     from hyperspy import signals
     # Extract essential data:
     data = group.get('data')
     if load_to_memory:
         data = np.asanyarray(data)
     # EMD does not have a standard way to describe the signal axis.
     # Therefore we return a BaseSignal
     signal = signals.BaseSignal(data)
     # Set signal properties:
     signal.set_signal_origin = group.attrs.get('signal_origin', '')
     signal.set_signal_type = group.attrs.get('signal_type', '')
     # Iterate over all dimensions:
     for i in range(len(data.shape)):
         dim = group.get('dim{}'.format(i + 1))
         axis = signal.axes_manager._axes[i]
         axis.name = dim.attrs.get('name', '')
         units = re.findall('[^_\W]+', dim.attrs.get('units', ''))
         axis.units = ''.join(units)
         try:
             axis.scale = dim[1] - dim[0]
             axis.offset = dim[0]
         # Hyperspy then uses defaults (1.0 and 0.0)!
         except (IndexError, TypeError) as e:
             self._log.warning(
                 'Could not calculate scale/offset of axis {}: {}'.format(
                     i, e))
     # Extract metadata:
     metadata = {}
     for key, value in group.attrs.items():
         metadata[key] = value
     # Add signal:
     self.add_signal(signal, name, metadata)
Ejemplo n.º 6
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 def setup_method(self, method):
     self.s = signals.BaseSignal(np.random.rand(1, 2, 3, 4, 5, 6))
     for ax, name in zip(self.s.axes_manager._axes, 'abcdef'):
         ax.name = name
     # just to make sure in case default changes
     self.s.axes_manager.set_signal_dimension(6)
     self.s.estimate_poissonian_noise_variance()
Ejemplo n.º 7
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 def setUp(self):
     s = signals.BaseSignal(np.zeros(1))
     self.factors = np.ones([2, 3])
     self.loadings = np.ones([2, 3])
     s.learning_results.factors = self.factors.copy()
     s.learning_results.loadings = self.loadings.copy()
     s.learning_results.bss_factors = self.factors.copy()
     s.learning_results.bss_loadings = self.loadings.copy()
     self.s = s
Ejemplo n.º 8
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def test_ragged_slicing(slice_):
    array_ragged = np.empty((2, 3), dtype=object)
    for iy, ix in np.ndindex(array_ragged.shape):
        array_ragged[iy, ix] = np.random.randint(0,
                                                 20,
                                                 size=np.random.randint(2, 10))

    s = signals.BaseSignal(array_ragged, ragged=True)
    s_lazy = s.as_lazy()
    np.testing.assert_allclose(s.inav[slice_].data[0],
                               s_lazy.inav[slice_].data[0])
Ejemplo n.º 9
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 def test_broadcast_in_place(self):
     s1 = self.s1
     s1.axes_manager.set_signal_dimension(1)  # (3|2)
     s2 = signals.BaseSignal(np.ones((4, 2, 4, 3)))
     s2c = s2
     s2.axes_manager.set_signal_dimension(2)  # (3, 4| 2, 4)
     print(s2)
     print(s1)
     s2 += s1
     assert_array_equal(s2.data, 2 * np.ones((4, 2, 4, 3)))
     nt.assert_is(s2, s2c)
Ejemplo n.º 10
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 def test_broadcast_in_place(self):
     s1 = self.s1
     s1 = s1.transpose(signal_axes=1)
     s2 = signals.BaseSignal(np.ones((4, 2, 4, 3)))
     s2 = s2.transpose(signal_axes=2)
     s2c = s2
     print(s2)
     print(s1)
     s2 += s1
     assert_array_equal(s2.data, 2 * np.ones((4, 2, 4, 3)))
     nt.assert_is(s2, s2c)
Ejemplo n.º 11
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    def _read_signal_from_group(self, name, group, lazy=False):
        self._log.debug('Calling _read_signal_from_group')
        from hyperspy import signals
        # Extract essential data:
        data = group.get('data')
        if lazy:
            data = da.from_array(data, chunks=data.chunks)
        else:
            data = np.asanyarray(data)
        # EMD does not have a standard way to describe the signal axis.
        # Therefore we return a BaseSignal
        signal = signals.BaseSignal(data)
        # Set signal properties:
        signal.set_signal_origin = group.attrs.get('signal_origin', '')
        signal.set_signal_type = group.attrs.get('signal_type', '')
        # Iterate over all dimensions:
        for i in range(len(data.shape)):
            dim = group.get('dim{}'.format(i + 1))
            axis = signal.axes_manager._axes[i]
            axis_name = dim.attrs.get('name', '')
            if isinstance(axis_name, bytes):
                axis_name = axis_name.decode('utf-8')
            axis.name = axis_name

            axis_units = dim.attrs.get('units', '')
            if isinstance(axis_units, bytes):
                axis_units = axis_units.decode('utf-8')
            units = re.findall(r'[^_\W]+', axis_units)
            axis.units = ''.join(units)
            try:
                if len(dim) == 1:
                    axis.scale = 1.
                    self._log.warning(
                        'Could not calculate scale of axis {}. '
                        'Setting scale to 1'.format(i))
                else:
                    axis.scale = dim[1] - dim[0]
                axis.offset = dim[0]
            # HyperSpy then uses defaults (1.0 and 0.0)!
            except (IndexError, TypeError) as e:
                self._log.warning(
                    'Could not calculate scale/offset of '
                    'axis {}: {}'.format(i, e))
        # Extract metadata:
        metadata = {}
        for key, value in group.attrs.items():
            metadata[key] = value
        if signal.data.dtype == np.object:
            self._log.warning('HyperSpy could not load the data in {}, '
                              'skipping it'.format(name))
        else:
            # Add signal:
            self.add_signal(signal, name, metadata)
Ejemplo n.º 12
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 def test_broadcast_in_place(self):
     if self.s1._lazy:
         pytest.skip("Inplace not supported by LazySignals")
     s1 = self.s1
     s1 = s1.transpose(signal_axes=1)
     s2 = signals.BaseSignal(np.ones((4, 2, 4, 3)))
     s2 = s2.transpose(signal_axes=2)
     s2c = s2
     print(s2)
     print(s1)
     s2 += s1
     assert_array_equal(s2.data, 2 * np.ones((4, 2, 4, 3)))
     assert s2 is s2c
Ejemplo n.º 13
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 def setup_method(self, method):
     s = signals.BaseSignal(np.empty(1))
     s.learning_results.explained_variance_ratio = np.asarray([
         10e-1,
         5e-2,
         9e-3,
         1e-3,
         9e-5,
         5e-5,
         3.0e-5,
         2.2e-5,
         1.9e-5,
         1.8e-5,
         1.7e-5,
         1.6e-5,
     ])
     self.s = s
Ejemplo n.º 14
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 def setup_method(self, method):
     self.signal = signals.BaseSignal(np.arange(10))
     self.signal.axes_manager.set_signal_dimension(1)
     self.signal.axes_manager[0].scale = 0.5
     self.signal.axes_manager[0].offset = 0.25
     self.data = self.signal.data.copy()
Ejemplo n.º 15
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 def setup_method(self, method):
     self.signal = signals.BaseSignal(np.arange(24).reshape((2, 3, 4)))
     self.data = self.signal.data.copy()
     self.signal.axes_manager._axes[0].navigate = False
     self.signal.axes_manager._axes[1].navigate = True
     self.signal.axes_manager._axes[2].navigate = False
Ejemplo n.º 16
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 def denoised_data_to_signal(self):
     signal = signals.BaseSignal(self.Y)
     if self.signal_type == "spectrum":
         return signal.as_signal1D(2)
     if self.signal_type == "image":
         return signal.as_signal2D((1,2))
Ejemplo n.º 17
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 def setUp(self):
     s = signals.BaseSignal(np.empty(1))
     self.s = s
Ejemplo n.º 18
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 def setup_method(self, method):
     s = signals.BaseSignal(np.empty(1))
     self.s = s
Ejemplo n.º 19
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 def setUp(self):
     self.signal = signals.BaseSignal(np.arange(24).reshape((2, 3, 4)))
     self.data = self.signal.data.copy()
     self.signal.axes_manager.set_signal_dimension(0)
Ejemplo n.º 20
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def test_error_axes():
    s = signals.BaseSignal(generate_low_rank_matrix())

    with pytest.raises(AttributeError, match="not possible to decompose a dataset"):
        s.decomposition()
Ejemplo n.º 21
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def test_lazy_to_device():
    s = signals.BaseSignal(np.arange(10)).as_lazy()
    with pytest.raises(BaseException):
        s.to_device()
Ejemplo n.º 22
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 def setup_method(self, method):
     self.signal = signals.BaseSignal(np.arange(24).reshape((2, 3, 4))).T
     self.data = self.signal.data.copy()
Ejemplo n.º 23
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 def setup_method(self, method):
     self.signal = signals.BaseSignal(
         np.arange(2**5).reshape((2, 2, 2, 2, 2)))
     self.signal.axes_manager.set_signal_dimension(1)
     self.data = self.signal.data.copy()
Ejemplo n.º 24
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def test_squeeze(shape):
    s = signals.BaseSignal(np.random.random(shape))
    s2 = s.transpose(signal_axes=[0, 1, 2])
    s3 = s2.squeeze()
    assert s2.data.squeeze().shape == s3.data.shape
    assert s3.axes_manager.shape == (8, 6, 2, 7)
Ejemplo n.º 25
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def test_to_host():
    data = np.arange(10)
    s = signals.BaseSignal(data)
    s.to_host()
    s.data is data
Ejemplo n.º 26
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    def estimate_parameters(self,
                            signal,
                            x1,
                            x2,
                            only_current=False,
                            out=False):
        """Estimate the parameters by the two area method

        Parameters
        ----------
        signal : Signal1D instance
        x1 : float
            Defines the left limit of the spectral range to use for the
            estimation.
        x2 : float
            Defines the right limit of the spectral range to use for the
            estimation.

        only_current : bool
            If False, estimates the parameters for the full dataset.
        out : bool
            If True, returns the result arrays directly without storing in the
            parameter maps/values. The returned order is (A, r).

        Returns
        -------
        {bool, tuple of values}

        """
        super(PowerLaw, self)._estimate_parameters(signal)
        axis = signal.axes_manager.signal_axes[0]
        i1, i2 = axis.value_range_to_indices(x1, x2)
        if not (i2 + i1) % 2 == 0:
            i2 -= 1
        if i2 == i1:
            i2 += 2
        i3 = (i2 + i1) // 2
        x1 = axis.index2value(i1)
        x2 = axis.index2value(i2)
        x3 = axis.index2value(i3)
        if only_current is True:
            s = signal.get_current_signal()
        else:
            s = signal
        if s._lazy:
            import dask.array as da
            log = da.log
            I1 = s.isig[i1:i3].integrate1D(2j).data
            I2 = s.isig[i3:i2].integrate1D(2j).data
        else:
            shape = s.data.shape[:-1]
            I1_s = signals.BaseSignal(np.empty(shape, dtype='float'))
            I2_s = signals.BaseSignal(np.empty(shape, dtype='float'))
            # Use the `out` parameters to avoid doing the deepcopy
            s.isig[i1:i3].integrate1D(2j, out=I1_s)
            s.isig[i3:i2].integrate1D(2j, out=I2_s)
            I1 = I1_s.data
            I2 = I2_s.data
            log = np.log
        with np.errstate(divide='raise'):
            try:
                r = 2 * log(I1 / I2) / log(x2 / x1)
                k = 1 - r
                A = k * I2 / (x2**k - x3**k)
                if s._lazy:
                    r = r.map_blocks(np.nan_to_num)
                    A = A.map_blocks(np.nan_to_num)
                else:
                    r = np.nan_to_num(r)
                    A = np.nan_to_num(A)
            except (RuntimeWarning, FloatingPointError):
                _logger.warning('Power law paramaters estimation failed '
                                'because of a "divide by zero" error.')
                return False
        if only_current is True:
            self.r.value = r
            self.A.value = A
            return True
        if out:
            return A, r
        else:
            if self.A.map is None:
                self._create_arrays()
            self.A.map['values'][:] = A
            self.A.map['is_set'][:] = True
            self.r.map['values'][:] = r
            self.r.map['is_set'][:] = True
            self.fetch_stored_values()
            return True