def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setValues([100.0])
# Widgets
self._widget.valuesChanged.connect(self.fieldChanged)
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(1, float("inf"), 0)
self._widget.setEnabled(False)
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(0, 1000, 0)
self._widget.setValues([123])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
class RelativeUncertaintyTerminationField(TerminationFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(0.1, 100.0, 1)
self._widget.setEnabled(True)
self._widget.setValues([5.0])
self._suffix.setChecked(True)
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Relative uncertainty (%)"
def description(self):
return "Relative statistical uncertainty (3*sigma) of the intensity of the x-ray line"
def widget(self):
return self._widget
def relativeUncertainties(self):
if not self._suffix.isChecked():
return []
else:
return tuple(value * 0.01 for value in self._widget.values())
def setRelativeUncertainties(self, relative_uncertainties):
self._suffix.setChecked(True)
self._widget.setValues(
[value * 100.0 for value in relative_uncertainties])
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
decimals = tolerance_to_decimals(math.degrees(SampleBase.AZIMUTH_TOLERANCE_rad))
self._widget.setRange(0.0, 360.0, decimals)
self._widget.setValues([0.0])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
decimals = tolerance_to_decimals(BeamBase.ENERGY_TOLERANCE_eV) + 3
self._widget.setRange(0, 1000, decimals)
self._widget.setValues([20.0])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def __init__(self, title):
self._title = title
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(1, float("inf"), 0)
self._widget.setValues([2])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(0.1, 100.0, 1)
self._widget.setEnabled(True)
self._widget.setValues([5.0])
self._suffix.setChecked(True)
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
class InclusionDiameterField(MultiValueFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setValues([100.0])
# Widgets
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Diameter(s) [nm]"
def widget(self):
return self._widget
def toleranceMeter(self):
return self._widget.bottom()
def setToleranceMeter(self, tolerance_m):
decimals = tolerance_to_decimals(tolerance_m * 1e9)
self._widget.setRange(tolerance_m, float("inf"), decimals)
def diametersMeter(self):
return np.array(self._widget.values()) * 1e-9
def setDiametersMeter(self, diameters_m):
values = np.array(diameters_m) * 1e9
self._widget.setValues(values)
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
tolerance = VerticalLayerSample.DEPTH_TOLERANCE_m * 1e9
decimals = tolerance_to_decimals(tolerance)
self._widget.setRange(tolerance, float("inf"), decimals)
self._widget.setEnabled(False)
self._suffix = QtWidgets.QCheckBox("infinite")
self._suffix.setChecked(True)
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
self._suffix.stateChanged.connect(self._on_infinite_changed)
class NumberTrajectoriesTerminationField(TerminationFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(1, float("inf"), 0)
self._widget.setEnabled(False)
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Number of trajectories"
def widget(self):
return self._widget
def numbersTrajectories(self):
if not self._suffix.isChecked():
return [1e38]
else:
return self._widget.values()
def setNumbersTrajectories(self, numbers_trajectories):
self._suffix.setChecked(True)
self._widget.setValues(numbers_trajectories)
class TiltField(MultiValueFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
decimals = tolerance_to_decimals(math.degrees(SampleBase.TILT_TOLERANCE_rad))
self._widget.setRange(-180.0, 180.0, decimals)
self._widget.setValues([0.0])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Tilt(s) [\u00b0]"
def description(self):
return "Tilt around the x-axis"
def widget(self):
return self._widget
def tiltsDegree(self):
return self._widget.values()
def setTiltsDegree(self, tilts_deg):
self._widget.setValues(tilts_deg)
class SimulationTimeTerminationField(TerminationFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(1, float("inf"), 0)
self._widget.setEnabled(False)
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Simulation time [s]"
def widget(self):
return self._widget
def simulationTimesSecond(self):
if not self._suffix.isChecked():
return [1e38]
else:
return self._widget.values()
def setSimulationTimesSecond(self, simulation_times):
self._suffix.setChecked(True)
self._widget.setValues(simulation_times)
class CField(MultiValueFieldBase):
def __init__(self, title):
self._title = title
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(0.0, 0.2, 2)
self._widget.setValues([0.2])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return self._title
def description(self):
return "Elastic scattering parameter"
def widget(self):
return self._widget
def setValues(self, c1s):
self._widget.setValues(c1s)
def values(self):
return self._widget.values()
class DiameterField(MultiValueFieldBase, ToleranceMixin):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setValues([100.0])
# Widgets
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Diameter(s) FWHM [nm]"
def description(self):
return "The diameter corresponds to the full width at half maximum (FWHM) of a two dimensional Gaussian distribution"
def widget(self):
return self._widget
def setToleranceMeter(self, tolerance_m):
super().setToleranceMeter(tolerance_m)
decimals = tolerance_to_decimals(tolerance_m * 1e9)
self._widget.setRange(tolerance_m, float("inf"), decimals)
def diametersMeter(self):
return np.array(self._widget.values()) * 1e-9
def setDiametersMeter(self, diameters_m):
values = np.array(diameters_m) * 1e9
self._widget.setValues(values)
class EnergyField(MultiValueFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
decimals = tolerance_to_decimals(BeamBase.ENERGY_TOLERANCE_eV) + 3
self._widget.setRange(0, 1000, decimals)
self._widget.setValues([20.0])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Energies [keV]"
def widget(self):
return self._widget
def energiesEV(self):
return np.array(self._widget.values()) * 1e3
def setEnergiesEV(self, energies_eV):
energies_eV = np.array(energies_eV) / 1e3
self._widget.setValues(energies_eV)
class XraySplittingFactorField(MultiValueFieldBase):
def __init__(self, title):
self._title = title
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(1, float("inf"), 0)
self._widget.setValues([2])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return self._title
def widget(self):
return self._widget
def splittingFactors(self):
return self._widget.values()
def createEditor(self, parent, option, index):
column = index.column()
if column == 0:
editor = MaterialListWidget(parent)
editor.setMaximumHeight(parent.height())
editor.setMinimumSize(editor.sizeHint())
return editor
elif column == 1:
editor = ColoredMultiFloatLineEdit(parent)
tolerance = Layer.THICKNESS_TOLERANCE_m * 1e9
decimals = tolerance_to_decimals(tolerance)
editor.setRange(tolerance, float("inf"), decimals)
return editor
class FooField(MultiValueFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(0, 1000, 0)
self._widget.setValues([123])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Foo"
def widget(self):
return self._widget
def foos(self):
return self._widget.values()
def setFoos(self, foos):
self._widget.setValues(foos)
class NumberTrajectoriesField(MultiValueFieldBase):
def __init__(self):
super().__init__()
# widgets
self._widget = ColoredMultiFloatLineEdit()
self._widget.setRange(25, 1e9, 0)
self._widget.setValues([10000])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Number of trajectories"
def widget(self):
return self._widget
def numbersTrajectories(self):
return self._widget.values()
def setNumbersTrajectories(self, numbers_trajectories):
self._widget.setValues(numbers_trajectories)
class AzimuthField(MultiValueFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
decimals = tolerance_to_decimals(math.degrees(SampleBase.AZIMUTH_TOLERANCE_rad))
self._widget.setRange(0.0, 360.0, decimals)
self._widget.setValues([0.0])
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
def title(self):
return "Azimuth(s) [\u00b0]"
def widget(self):
return self._widget
def azimuthsDegree(self):
return self._widget.values()
def setAzimuthsDegree(self, azimuths_deg):
self._widget.setValues(azimuths_deg)
def coloredmultifloatlineedit():
widget = ColoredMultiFloatLineEdit()
widget.setRange(10.0, 50.0, 2)
return widget
class DepthField(MultiValueFieldBase):
def __init__(self):
super().__init__()
# Widgets
self._widget = ColoredMultiFloatLineEdit()
tolerance = VerticalLayerSample.DEPTH_TOLERANCE_m * 1e9
decimals = tolerance_to_decimals(tolerance)
self._widget.setRange(tolerance, float("inf"), decimals)
self._widget.setEnabled(False)
self._suffix = QtWidgets.QCheckBox("infinite")
self._suffix.setChecked(True)
# Signals
self._widget.valuesChanged.connect(self.fieldChanged)
self._suffix.stateChanged.connect(self._on_infinite_changed)
def _on_infinite_changed(self):
is_infinite = self._suffix.isChecked()
self._widget.setValues([])
self._widget.setEnabled(not is_infinite)
self.fieldChanged.emit()
def title(self):
return "Depth(s) [nm]"
def widget(self):
return self._widget
def suffixWidget(self):
return self._suffix
def isValid(self):
if self._suffix.isChecked():
return True
return super().isValid()
def depthsMeter(self):
if self._suffix.isChecked():
return (float("inf"), )
else:
return np.array(self._widget.values()) * 1e-9
def setDepthsMeter(self, depths_m):
values = np.array(depths_m) * 1e9
self._widget.setValues(values)
self._suffix.setChecked(False)