def check_fields(self):
self.ELECTRONENERGY = congruence.checkStrictlyPositiveNumber(
self.ELECTRONENERGY, "Electron Energy")
if not self.METHOD == 1:
self.ELECTRONENERGYSPREAD = congruence.checkPositiveNumber(
self.ELECTRONENERGYSPREAD, "Electron Energy Spread")
self.ELECTRONCURRENT = congruence.checkStrictlyPositiveNumber(
self.ELECTRONCURRENT, "Electron Current")
self.ELECTRONBEAMSIZEH = congruence.checkPositiveNumber(
self.ELECTRONBEAMSIZEH, "Electron Beam Size H")
self.ELECTRONBEAMSIZEV = congruence.checkPositiveNumber(
self.ELECTRONBEAMSIZEV, "Electron Beam Size V")
self.ELECTRONBEAMDIVERGENCEH = congruence.checkPositiveNumber(
self.ELECTRONBEAMDIVERGENCEH, "Electron Beam Divergence H")
self.ELECTRONBEAMDIVERGENCEV = congruence.checkPositiveNumber(
self.ELECTRONBEAMDIVERGENCEV, "Electron Beam Divergence V")
self.PERIODID = congruence.checkStrictlyPositiveNumber(
self.PERIODID, "Period ID")
self.NPERIODS = congruence.checkStrictlyPositiveNumber(
self.NPERIODS, "Number of Periods")
self.DISTANCE = congruence.checkPositiveNumber(self.DISTANCE,
"Distance to slit")
self.GAPH = congruence.checkPositiveNumber(self.GAPH, "Slit gap H")
self.GAPV = congruence.checkPositiveNumber(self.GAPV, "Slit gap V")
self.KMIN = congruence.checkPositiveNumber(self.KMIN, "K Min")
self.KMAX = congruence.checkStrictlyPositiveNumber(self.KMAX, "K Max")
congruence.checkLessThan(self.KMIN, self.KMAX, "K Min", "K Max")
self.KPOINTS = congruence.checkStrictlyPositiveNumber(
self.KPOINTS, "Number of K Points")
def get_range(self, beam_to_plot, var_x):
if self.x_range == 0:
x_max = 0
x_min = 0
x, good_only = beam_to_plot.getshcol((var_x, 10))
x_to_plot = copy.deepcopy(x)
go = numpy.where(good_only == 1)
lo = numpy.where(good_only != 1)
if self.rays == 0:
x_max = numpy.array(x_to_plot[0:], float).max()
x_min = numpy.array(x_to_plot[0:], float).min()
elif self.rays == 1:
x_max = numpy.array(x_to_plot[go], float).max()
x_min = numpy.array(x_to_plot[go], float).min()
elif self.rays == 2:
x_max = numpy.array(x_to_plot[lo], float).max()
x_min = numpy.array(x_to_plot[lo], float).min()
xrange = [x_min, x_max]
else:
congruence.checkLessThan(self.x_range_min, self.x_range_max,
"X range min", "X range max")
factor1 = ShadowPlot.get_factor(var_x, self.workspace_units_to_cm)
xrange = [self.x_range_min / factor1, self.x_range_max / factor1]
return xrange
def get_ranges(self, beam_to_plot, var_x, var_y):
xrange = None
yrange = None
factor1 = ShadowPlot.get_factor(var_x, self.workspace_units_to_cm)
factor2 = ShadowPlot.get_factor(var_y, self.workspace_units_to_cm)
if self.x_range == 0 and self.y_range == 0:
pass
else:
if self.x_range == 1:
congruence.checkLessThan(self.x_range_min, self.x_range_max,
"X range min", "X range max")
xrange = [
self.x_range_min / factor1, self.x_range_max / factor1
]
if self.y_range == 1:
congruence.checkLessThan(self.y_range_min, self.y_range_max,
"Y range min", "Y range max")
yrange = [
self.y_range_min / factor2, self.y_range_max / factor2
]
return xrange, yrange
def checkFields(self):
self.number_of_rays = congruence.checkPositiveNumber(self.number_of_rays, "Number of rays")
self.seed = congruence.checkPositiveNumber(self.seed, "Seed")
self.e_min = congruence.checkPositiveNumber(self.e_min, "Minimum energy")
self.e_max = congruence.checkPositiveNumber(self.e_max, "Maximum energy")
congruence.checkLessThan(self.e_min, self.e_max, "Minimum energy", "Maximum energy")
self.max_number_of_rejected_rays = congruence.checkPositiveNumber(self.max_number_of_rejected_rays,
"Max Number of Rejected Rays")
self.slit_distance = congruence.checkPositiveNumber(self.slit_distance, "Horizontal half-divergence from [+]")
self.min_x = congruence.checkNumber(self.min_x, "Min X/Min Xp")
self.max_x = congruence.checkNumber(self.max_x, "Max X/Max Xp")
self.min_z = congruence.checkNumber(self.min_z, "Min X/Min Xp")
self.max_z = congruence.checkNumber(self.max_z, "Max X/Max Xp")
self.energy = congruence.checkPositiveNumber(self.energy, "Energy")
self.electron_current = congruence.checkPositiveNumber(self.electron_current, "Electron Current")
self.sigma_x = congruence.checkPositiveNumber(self.sigma_x, "Sigma x")
self.sigma_z = congruence.checkPositiveNumber(self.sigma_z, "Sigma z")
self.emittance_x = congruence.checkPositiveNumber(self.emittance_x, "Emittance x")
self.emittance_z = congruence.checkPositiveNumber(self.emittance_z, "Emittance z")
self.distance_from_waist_x = congruence.checkNumber(self.distance_from_waist_x, "Distance from waist x")
self.distance_from_waist_z = congruence.checkNumber(self.distance_from_waist_z, "Distance from waist z")
self.number_of_periods = congruence.checkStrictlyPositiveNumber(self.number_of_periods, "Number of periods")
self.k_value = congruence.checkStrictlyPositiveNumber(self.k_value, "K value")
self.id_period = congruence.checkStrictlyPositiveNumber(self.id_period, "ID period")
if self.optimize_source_combo == 1:
congruence.checkFile(self.file_with_phase_space_volume)
if self.type_combo == 1:
congruence.checkUrl(self.file_with_b_vs_y)
elif self.type_combo == 2:
congruence.checkUrl(self.file_with_harmonics)
def check_fields(self):
self.NPERIODS = congruence.checkStrictlyPositiveNumber(
self.NPERIODS, "Number of Periods")
self.ENERGY = congruence.checkStrictlyPositiveNumber(
self.ENERGY, "Beam Energy")
self.PHOT_ENERGY_MIN = congruence.checkPositiveNumber(
self.PHOT_ENERGY_MIN, "Min Photon Energy")
self.PHOT_ENERGY_MAX = congruence.checkStrictlyPositiveNumber(
self.PHOT_ENERGY_MAX, "Max Photon Energy")
congruence.checkLessThan(self.PHOT_ENERGY_MIN, self.PHOT_ENERGY_MAX,
"Min Photon Energy", "Max Photon Energy")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(
self.NPOINTS, "Number of Energy Points")
self.CURRENT = congruence.checkStrictlyPositiveNumber(
self.CURRENT, "Electron Beam Current")
if self.FIELD == 0:
self.ULAMBDA = congruence.checkStrictlyPositiveNumber(
self.ULAMBDA, "Wiggler period")
self.K = congruence.checkStrictlyPositiveNumber(self.K, "K")
self.NTRAJPOINTS = congruence.checkStrictlyPositiveNumber(
self.NTRAJPOINTS, "Number of traj points per period")
elif self.FIELD == 1:
self.ULAMBDA = congruence.checkStrictlyPositiveNumber(
self.ULAMBDA, "Wiggler period")
self.NTRAJPOINTS = congruence.checkStrictlyPositiveNumber(
self.NTRAJPOINTS, "Number of traj points per period")
congruence.checkFile(self.FILE)
elif self.FIELD == 2:
congruence.checkFile(self.FILE)
def check_fields(self):
self.ENERGY = congruence.checkStrictlyPositiveNumber(
self.ENERGY, "Electron Energy")
self.CURRENT = congruence.checkStrictlyPositiveNumber(
self.CURRENT, "Current")
self.ENERGY_SPREAD = congruence.checkStrictlyPositiveNumber(
self.ENERGY_SPREAD, "Energy Spread")
self.SIGX = congruence.checkPositiveNumber(self.SIGX, "Sigma X")
self.SIGY = congruence.checkPositiveNumber(self.SIGY, "Sigma Y")
self.SIGX1 = congruence.checkPositiveNumber(self.SIGX1, "Sigma X'")
self.SIGY1 = congruence.checkPositiveNumber(self.SIGY1, "Sigma Y'")
self.PERIOD = congruence.checkStrictlyPositiveNumber(
self.PERIOD, "Period length")
self.NP = congruence.checkStrictlyPositiveNumber(
self.NP, "Number of periods")
self.EMIN = congruence.checkPositiveNumber(self.EMIN,
"E1 minimum energy")
self.EMAX = congruence.checkStrictlyPositiveNumber(
self.EMAX, "E1 maximum energy")
congruence.checkLessThan(self.EMIN, self.EMAX, "E1 minimum energy",
"E1 maximum energy")
self.N = congruence.checkStrictlyPositiveNumber(
self.N, "Number of Energy Points")
self.HARMONIC_FROM = congruence.checkStrictlyPositiveNumber(
self.HARMONIC_FROM, "Minimum harmonic number")
self.HARMONIC_TO = congruence.checkStrictlyPositiveNumber(
self.HARMONIC_TO, "Maximum harmonic number")
congruence.checkLessThan(self.HARMONIC_FROM, self.HARMONIC_TO,
"Minimum harmonic number",
"Maximum harmonic number")
self.HARMONIC_STEP = congruence.checkStrictlyPositiveNumber(
self.HARMONIC_STEP, "Harmonic step size")
self.NEKS = congruence.checkPositiveNumber(self.NEKS, "Intrinsic NEKS")
def check_fields(self):
self.DESCRIPTOR = congruence.checkEmptyString(self.DESCRIPTOR,
"formula")
if self.MAT_FLAG == 1:
self.DENSITY = congruence.checkStrictlyPositiveNumber(
self.DENSITY, "density")
if self.GRID > 0:
self.GRIDSTART = congruence.checkPositiveNumber(
self.GRIDSTART, "Starting Energy")
if self.GRID == 1:
self.GRIDEND = congruence.checkStrictlyPositiveNumber(
self.GRIDEND, "Energy to")
congruence.checkLessThan(self.GRIDSTART, self.GRIDEND,
"Starting Energy", "Energy to")
self.GRIDN = congruence.checkStrictlyPositiveNumber(
self.GRIDN, "Number of points")
if self.CALCULATE >= 7 and self.CALCULATE <= 9:
self.ROUGH = congruence.checkPositiveNumber(
self.ROUGH, "Roughness")
self.THETA1 = congruence.checkPositiveNumber(
self.THETA1, "Starting Graz angle")
if self.THETAGRID == 1:
self.THETA2 = congruence.checkStrictlyPositiveNumber(
self.THETA2, "Graz angle to")
congruence.checkLessThan(self.THETA1, self.THETA2,
"Starting Graz angle",
"Graz angle to")
self.THETAN = congruence.checkStrictlyPositiveNumber(
self.THETAN, "Number of angular points")
else:
self.THETAGRID = 0
def checkFields(self):
self.number_of_rays = congruence.checkPositiveNumber(self.number_of_rays, "Number of rays")
self.seed = congruence.checkPositiveNumber(self.seed, "Seed")
self.e_min = congruence.checkPositiveNumber(self.e_min, "Minimum energy")
self.e_max = congruence.checkPositiveNumber(self.e_max, "Maximum energy")
congruence.checkLessThan(self.e_min, self.e_max, "Minimum energy", "Maximum energy")
self.sigma_x = congruence.checkPositiveNumber(self.sigma_x, "Sigma x")
self.sigma_z = congruence.checkPositiveNumber(self.sigma_z, "Sigma z")
self.emittance_x = congruence.checkPositiveNumber(self.emittance_x, "Emittance x")
self.emittance_z = congruence.checkPositiveNumber(self.emittance_z, "Emittance z")
self.distance_from_waist_x = congruence.checkPositiveNumber(self.distance_from_waist_x, "Distance from waist x")
self.distance_from_waist_z = congruence.checkPositiveNumber(self.distance_from_waist_z, "Distance from waist z")
self.energy = congruence.checkPositiveNumber(self.energy, "Energy")
self.magnetic_radius = congruence.checkPositiveNumber(self.magnetic_radius, "Magnetic radius")
self.horizontal_half_divergence_from = congruence.checkPositiveNumber(self.horizontal_half_divergence_from,
"Horizontal half-divergence from [+]")
self.horizontal_half_divergence_to = congruence.checkPositiveNumber(self.horizontal_half_divergence_to,
"Horizontal half-divergence to [-]")
self.max_vertical_half_divergence_from = congruence.checkPositiveNumber(self.max_vertical_half_divergence_from,
"Max vertical half-divergence from [+]")
self.max_vertical_half_divergence_to = congruence.checkPositiveNumber(self.max_vertical_half_divergence_to,
"Max vertical half-divergence to [-]")
if self.optimize_source > 0:
self.max_number_of_rejected_rays = congruence.checkPositiveNumber(self.max_number_of_rejected_rays,
"Max number of rejected rays")
congruence.checkFile(self.optimize_file_name)
def checkFields(self):
self.number_of_rays = congruence.checkPositiveNumber(self.number_of_rays, "Number of rays")
self.seed = congruence.checkPositiveNumber(self.seed, "Seed")
self.e_min = congruence.checkPositiveNumber(self.e_min, "Minimum energy")
self.e_max = congruence.checkPositiveNumber(self.e_max, "Maximum energy")
congruence.checkLessThan(self.e_min, self.e_max, "Minimum energy", "Maximum energy")
self.max_number_of_rejected_rays = congruence.checkPositiveNumber(self.max_number_of_rejected_rays,
"Max Number of Rejected Rays")
self.slit_distance = congruence.checkPositiveNumber(self.slit_distance, "Horizontal half-divergence from [+]")
self.min_x = congruence.checkNumber(self.min_x, "Min X/Min Xp")
self.max_x = congruence.checkNumber(self.max_x, "Max X/Max Xp")
self.min_z = congruence.checkNumber(self.min_z, "Min X/Min Xp")
self.max_z = congruence.checkNumber(self.max_z, "Max X/Max Xp")
self.energy = congruence.checkPositiveNumber(self.energy, "Energy")
self.electron_current = congruence.checkPositiveNumber(self.electron_current, "Electron Current")
self.sigma_x = congruence.checkPositiveNumber(self.sigma_x, "Sigma x")
self.sigma_z = congruence.checkPositiveNumber(self.sigma_z, "Sigma z")
self.emittance_x = congruence.checkPositiveNumber(self.emittance_x, "Emittance x")
self.emittance_z = congruence.checkPositiveNumber(self.emittance_z, "Emittance z")
self.distance_from_waist_x = congruence.checkNumber(self.distance_from_waist_x, "Distance from waist x")
self.distance_from_waist_z = congruence.checkNumber(self.distance_from_waist_z, "Distance from waist z")
self.number_of_periods = congruence.checkStrictlyPositiveNumber(self.number_of_periods, "Number of periods")
self.k_value = congruence.checkStrictlyPositiveNumber(self.k_value, "K value")
self.id_period = congruence.checkStrictlyPositiveNumber(self.id_period, "ID period")
if self.optimize_source_combo == 1:
congruence.checkFile(self.file_with_phase_space_volume)
if self.type_combo == 1:
congruence.checkFile(self.file_with_b_vs_y)
elif self.type_combo == 2:
congruence.checkFile(self.file_with_harmonics)
def check_fields(self):
self.ENERGY = congruence.checkStrictlyPositiveNumber(
self.ENERGY, "Beam Energy")
self.CUR = congruence.checkStrictlyPositiveNumber(
self.CUR, "Beam Current")
self.PERIOD = congruence.checkStrictlyPositiveNumber(
self.PERIOD, "Period")
self.N = congruence.checkStrictlyPositiveNumber(
self.N, "Number of Periods")
self.KX = congruence.checkNumber(self.KX, "Kx")
self.KY = congruence.checkNumber(self.KY, "Ky")
self.EMIN = congruence.checkPositiveNumber(self.EMIN, "Min Energy")
self.EMAX = congruence.checkStrictlyPositiveNumber(
self.EMAX, "Max Energy")
congruence.checkLessThan(self.EMIN, self.EMAX, "Min Energy",
"Max Energy")
self.NEE = congruence.checkStrictlyPositiveNumber(
self.NEE, "Number of energy steps")
self.D = congruence.checkPositiveNumber(self.D, "Distance")
self.XPC = congruence.checkNumber(self.XPC, "X-pos")
self.YPC = congruence.checkNumber(self.YPC, "Y-pos")
self.XPS = congruence.checkNumber(self.XPS, "X slit")
self.YPS = congruence.checkNumber(self.YPS, "Y Slit")
self.NXP = congruence.checkStrictlyPositiveNumber(
self.NXP, "Integration points X")
self.NYP = congruence.checkStrictlyPositiveNumber(
self.NYP, "Integration points Y")
def checkFields(self):
self.number_of_rays = congruence.checkPositiveNumber(self.number_of_rays, "Number of rays")
self.seed = congruence.checkPositiveNumber(self.seed, "Seed")
self.e_min = congruence.checkPositiveNumber(self.e_min, "Minimum energy")
self.e_max = congruence.checkPositiveNumber(self.e_max, "Maximum energy")
congruence.checkLessThan(self.e_min, self.e_max, "Minimum energy", "Maximum energy")
self.sigma_x = congruence.checkPositiveNumber(self.sigma_x, "Sigma x")
self.sigma_z = congruence.checkPositiveNumber(self.sigma_z, "Sigma z")
self.emittance_x = congruence.checkPositiveNumber(self.emittance_x, "Emittance x")
self.emittance_z = congruence.checkPositiveNumber(self.emittance_z, "Emittance z")
self.distance_from_waist_x = congruence.checkPositiveNumber(self.distance_from_waist_x, "Distance from waist x")
self.distance_from_waist_z = congruence.checkPositiveNumber(self.distance_from_waist_z, "Distance from waist z")
self.energy = congruence.checkPositiveNumber(self.energy, "Energy")
self.magnetic_radius = congruence.checkPositiveNumber(self.magnetic_radius, "Magnetic radius")
self.horizontal_half_divergence_from = congruence.checkPositiveNumber(self.horizontal_half_divergence_from,
"Horizontal half-divergence from [+]")
self.horizontal_half_divergence_to = congruence.checkPositiveNumber(self.horizontal_half_divergence_to,
"Horizontal half-divergence to [-]")
self.max_vertical_half_divergence_from = congruence.checkPositiveNumber(self.max_vertical_half_divergence_from,
"Max vertical half-divergence from [+]")
self.max_vertical_half_divergence_to = congruence.checkPositiveNumber(self.max_vertical_half_divergence_to,
"Max vertical half-divergence to [-]")
if self.optimize_source > 0:
self.max_number_of_rejected_rays = congruence.checkPositiveNumber(self.max_number_of_rejected_rays,
"Max number of rejected rays")
congruence.checkFile(self.optimize_file_name)
def get_ranges(self, beam_to_plot, var_x, var_y):
xrange = None
yrange = None
factor1 = ShadowPlot.get_factor(var_x, self.workspace_units_to_cm)
factor2 = ShadowPlot.get_factor(var_y, self.workspace_units_to_cm)
if self.x_range == 0 and self.y_range == 0:
if self.cartesian_axis == 1:
x_max = 0
y_max = 0
x_min = 0
y_min = 0
x, y, good_only = beam_to_plot.getshcol((var_x, var_y, 10))
x_to_plot = copy.deepcopy(x)
y_to_plot = copy.deepcopy(y)
go = numpy.where(good_only == 1)
lo = numpy.where(good_only != 1)
if self.rays == 0:
x_max = numpy.array(x_to_plot[0:], float).max()
y_max = numpy.array(y_to_plot[0:], float).max()
x_min = numpy.array(x_to_plot[0:], float).min()
y_min = numpy.array(y_to_plot[0:], float).min()
elif self.rays == 1:
x_max = numpy.array(x_to_plot[go], float).max()
y_max = numpy.array(y_to_plot[go], float).max()
x_min = numpy.array(x_to_plot[go], float).min()
y_min = numpy.array(y_to_plot[go], float).min()
elif self.rays == 2:
x_max = numpy.array(x_to_plot[lo], float).max()
y_max = numpy.array(y_to_plot[lo], float).max()
x_min = numpy.array(x_to_plot[lo], float).min()
y_min = numpy.array(y_to_plot[lo], float).min()
xrange = [x_min, x_max]
yrange = [y_min, y_max]
else:
if self.x_range == 1:
congruence.checkLessThan(self.x_range_min, self.x_range_max,
"X range min", "X range max")
xrange = [
self.x_range_min / factor1, self.x_range_max / factor1
]
if self.y_range == 1:
congruence.checkLessThan(self.y_range_min, self.y_range_max,
"Y range min", "Y range max")
yrange = [
self.y_range_min / factor2, self.y_range_max / factor2
]
return xrange, yrange
def check_fields(self):
self.MILLER_INDEX_H = congruence.checkNumber(self.MILLER_INDEX_H,
"Miller index H")
self.MILLER_INDEX_K = congruence.checkNumber(self.MILLER_INDEX_K,
"Miller index K")
self.MILLER_INDEX_L = congruence.checkNumber(self.MILLER_INDEX_L,
"Miller index L")
self.TEMPER = congruence.checkNumber(self.TEMPER, "Temperature factor")
if self.SCAN == 0 or self.SCAN == 3:
self.SCANFROM = congruence.checkPositiveNumber(
self.SCANFROM, "Min Scan value")
self.SCANTO = congruence.checkStrictlyPositiveNumber(
self.SCANTO, "Max Scan value")
else:
self.SCANFROM = congruence.checkNumber(self.SCANFROM,
"Min Scan value")
self.SCANTO = congruence.checkNumber(self.SCANTO, "Max Scan value")
congruence.checkLessThan(self.SCANFROM, self.SCANTO, "Min Scan value",
"Max Scan value")
self.SCANPOINTS = congruence.checkStrictlyPositiveNumber(
self.SCANPOINTS, "Scan points")
if self.SCAN < 4:
self.ENERGY = congruence.checkStrictlyPositiveNumber(
self.ENERGY, "Fix value")
else:
self.ENERGY = congruence.checkNumber(self.ENERGY, "Fix value")
if self.MOSAIC == 0: #perfect
self.ASYMMETRY_ANGLE = congruence.checkNumber(
self.ASYMMETRY_ANGLE, "Asymmetry angle")
self.THICKNESS = congruence.checkStrictlyPositiveNumber(
self.THICKNESS, "Crystal thickness")
elif self.MOSAIC == 1: #mosaic
self.THICKNESS = congruence.checkStrictlyPositiveNumber(
self.THICKNESS, "Crystal thickness")
self.MOSAIC_FWHM = congruence.checkNumber(self.MOSAIC_FWHM,
"Mosaicity")
elif self.MOSAIC == 2 or self.MOSAIC == 3: #bent ML/PP
self.ASYMMETRY_ANGLE = congruence.checkNumber(
self.ASYMMETRY_ANGLE, "Asymmetry angle")
self.THICKNESS = congruence.checkStrictlyPositiveNumber(
self.THICKNESS, "Crystal thickness")
self.RSAG = congruence.checkStrictlyPositiveNumber(
self.RSAG, "R Sagittal")
self.RMER = congruence.checkStrictlyPositiveNumber(
self.RMER, "R meridional")
if self.ANISOTROPY == 0:
self.POISSON = congruence.checkStrictlyPositiveNumber(
self.POISSON, "Poisson Ratio")
elif self.ANISOTROPY == 2:
congruence.checkEmptyString(self.CUT, "Valong; Vnorm; Vperp")
elif self.ANISOTROPY == 3:
congruence.checkFile(self.FILECOMPLIANCE)
def check_fields(self):
self.TEMPERATURE = congruence.checkPositiveNumber(
self.TEMPERATURE, "Temperature")
self.E_MIN = congruence.checkPositiveNumber(self.E_MIN, "Min Energy")
self.E_MAX = congruence.checkStrictlyPositiveNumber(
self.E_MAX, "Max Energy")
congruence.checkLessThan(self.E_MIN, self.E_MAX, "Min Energy",
"Max Energy")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(
self.NPOINTS, "Number of Points")
def check_fields(self):
self.DESCRIPTOR = congruence.checkEmptyString(self.DESCRIPTOR, "formula")
if self.GRID > 0:
self.GRIDSTART = congruence.checkPositiveNumber(self.GRIDSTART, "Starting Energy")
if self.GRID == 1:
self.GRIDEND = congruence.checkStrictlyPositiveNumber(self.GRIDEND, "Energy to")
congruence.checkLessThan(self.GRIDSTART, self.GRIDEND, "Starting Energy", "Energy to")
self.GRIDN = congruence.checkStrictlyPositiveNumber(self.GRIDN, "Number of points")
def check_fields(self):
self.DESCRIPTOR = congruence.checkEmptyString(self.DESCRIPTOR,
"formula")
self.GRIDSTART = congruence.checkPositiveNumber(
self.GRIDSTART, "Q from")
self.GRIDEND = congruence.checkStrictlyPositiveNumber(
self.GRIDEND, "Q to")
congruence.checkLessThan(self.GRIDSTART, self.GRIDEND, "Q from",
"Q to")
self.GRIDN = congruence.checkStrictlyPositiveNumber(
self.GRIDN, "Number of q Points")
def check_fields(self):
self.HMILLER = congruence.checkNumber(self.HMILLER, "h miller index")
self.KMILLER = congruence.checkNumber(self.KMILLER, "k miller index")
self.LMILLER = congruence.checkNumber(self.LMILLER, "l miller index")
self.TEMPER = congruence.checkNumber(self.TEMPER, "Temperature factor")
self.ENERGY = congruence.checkPositiveNumber(self.ENERGY, "Energy from")
self.ENERGY_END = congruence.checkStrictlyPositiveNumber(self.ENERGY_END, "Energy to")
congruence.checkLessThan(self.ENERGY, self.ENERGY_END, "Energy from", "Energy to")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.NPOINTS, "Number of Points")
def check_fields(self):
self.DESCRIPTOR = congruence.checkEmptyString(self.DESCRIPTOR, "formula")
if self.MAT_FLAG == 1:
self.DENSITY = congruence.checkStrictlyPositiveNumber(self.DENSITY, "density")
if self.GRID > 0:
self.GRIDSTART = congruence.checkPositiveNumber(self.GRIDSTART, "Starting Energy")
if self.GRID == 1:
self.GRIDEND = congruence.checkStrictlyPositiveNumber(self.GRIDEND, "Energy to")
congruence.checkLessThan(self.GRIDSTART, self.GRIDEND, "Starting Energy", "Energy to")
self.GRIDN = congruence.checkStrictlyPositiveNumber(self.GRIDN, "Number of points")
def check_fields(self):
self.ENERGY = congruence.checkStrictlyPositiveNumber(self.ENERGY, "Energy")
self.MILLER_INDEX_H = congruence.checkNumber(self.MILLER_INDEX_H, "Miller index H")
self.MILLER_INDEX_K = congruence.checkNumber(self.MILLER_INDEX_K, "Miller index K")
self.MILLER_INDEX_L = congruence.checkNumber(self.MILLER_INDEX_L, "Miller index L")
self.ASYMMETRY_ANGLE = congruence.checkNumber(self.ASYMMETRY_ANGLE, "Asymmetry angle")
self.THICKNESS = congruence.checkStrictlyPositiveNumber(self.THICKNESS, "Crystal thickness")
self.TEMPERATURE = congruence.checkNumber(self.TEMPERATURE, "Crystal temperature")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.NPOINTS, "Number of points")
if self.SCALE == 1:
self.XFROM = congruence.checkNumber(self.XFROM, "Theta min")
self.XTO = congruence.checkNumber(self.XTO, "Theta max")
congruence.checkLessThan(self.XFROM, self.XTO, "Theta min", "Theta max")
def check_fields(self):
self.HMILLER = congruence.checkNumber(self.HMILLER, "h miller index")
self.KMILLER = congruence.checkNumber(self.KMILLER, "k miller index")
self.LMILLER = congruence.checkNumber(self.LMILLER, "l miller index")
self.TEMPER = congruence.checkNumber(self.TEMPER, "Temperature factor")
self.ENERGY = congruence.checkPositiveNumber(self.ENERGY,
"Energy from")
self.ENERGY_END = congruence.checkStrictlyPositiveNumber(
self.ENERGY_END, "Energy to")
congruence.checkLessThan(self.ENERGY, self.ENERGY_END, "Energy from",
"Energy to")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(
self.NPOINTS, "Number of Points")
def get_range(self, wavefront_to_plot, var_x):
if self.x_range == 0:
if var_x == 1: # horizontal
x_max = wavefront_to_plot.mesh.xFin
x_min = wavefront_to_plot.mesh.xStart
else:
x_max = wavefront_to_plot.mesh.yFin
x_min = wavefront_to_plot.mesh.yStart
xrange = [x_min * TO_UM, x_max * TO_UM]
else:
congruence.checkLessThan(self.x_range_min, self.x_range_max,
"Range min", "Range max")
xrange = [self.x_range_min, self.x_range_max]
return xrange
def check_fields(self):
self.ELECTRONENERGY = congruence.checkStrictlyPositiveNumber(self.ELECTRONENERGY, "Electron Energy")
if not self.METHOD == 1: self.ELECTRONENERGYSPREAD = congruence.checkPositiveNumber(self.ELECTRONENERGYSPREAD, "Electron Energy Spread")
self.ELECTRONCURRENT = congruence.checkStrictlyPositiveNumber(self.ELECTRONCURRENT, "Electron Current")
self.ELECTRONBEAMSIZEH = congruence.checkPositiveNumber(self.ELECTRONBEAMSIZEH, "Electron Beam Size H")
self.ELECTRONBEAMSIZEV = congruence.checkPositiveNumber(self.ELECTRONBEAMSIZEV, "Electron Beam Size V")
self.ELECTRONBEAMDIVERGENCEH = congruence.checkPositiveNumber(self.ELECTRONBEAMDIVERGENCEH, "Electron Beam Divergence H")
self.ELECTRONBEAMDIVERGENCEV = congruence.checkPositiveNumber(self.ELECTRONBEAMDIVERGENCEV, "Electron Beam Divergence V")
self.PERIODID = congruence.checkStrictlyPositiveNumber(self.PERIODID, "Period ID")
self.NPERIODS = congruence.checkStrictlyPositiveNumber(self.NPERIODS, "Number of Periods")
self.DISTANCE = congruence.checkPositiveNumber(self.DISTANCE, "Distance to slit")
self.GAPH = congruence.checkPositiveNumber(self.GAPH, "Slit gap H")
self.GAPV = congruence.checkPositiveNumber(self.GAPV, "Slit gap V")
self.KMIN = congruence.checkPositiveNumber(self.KMIN, "K Min")
self.KMAX = congruence.checkStrictlyPositiveNumber(self.KMAX, "K Max")
congruence.checkLessThan(self.KMIN, self.KMAX, "K Min", "K Max")
self.KPOINTS = congruence.checkStrictlyPositiveNumber(self.KPOINTS, "Number of K Points")
def get_ranges(self):
xrange = None
yrange = None
factor1 = self.workspace_units_to_mm
factor2 = self.workspace_units_to_mm
if self.x_range == 1:
congruence.checkLessThan(self.x_range_min, self.x_range_max, "X range min", "X range max")
xrange = [self.x_range_min / factor1, self.x_range_max / factor1]
if self.y_range == 1:
congruence.checkLessThan(self.y_range_min, self.y_range_max, "Y range min", "Y range max")
yrange = [self.y_range_min / factor2, self.y_range_max / factor2]
return xrange, yrange
def check_fields(self):
self.ENERGY = congruence.checkStrictlyPositiveNumber(self.ENERGY, "Beam Energy")
self.CUR = congruence.checkStrictlyPositiveNumber(self.CUR, "Beam Current")
self.PERIOD = congruence.checkStrictlyPositiveNumber(self.PERIOD, "Period")
self.N = congruence.checkStrictlyPositiveNumber(self.N, "Number of Periods")
self.KX = congruence.checkNumber(self.KX, "Kx")
self.KY = congruence.checkNumber(self.KY, "Ky")
self.EMIN = congruence.checkPositiveNumber(self.EMIN, "Min Energy")
self.EMAX = congruence.checkStrictlyPositiveNumber(self.EMAX, "Max Energy")
congruence.checkLessThan(self.EMIN, self.EMAX, "Min Energy", "Max Energy")
self.NEE = congruence.checkStrictlyPositiveNumber(self.NEE, "Number of energy steps")
self.D = congruence.checkPositiveNumber(self.D, "Distance")
self.XPC = congruence.checkNumber(self.XPC, "X-pos")
self.YPC = congruence.checkNumber(self.YPC, "Y-pos")
self.XPS = congruence.checkNumber(self.XPS, "X slit")
self.YPS = congruence.checkNumber(self.YPS, "Y Slit")
self.NXP = congruence.checkStrictlyPositiveNumber(self.NXP, "Integration points X")
self.NYP = congruence.checkStrictlyPositiveNumber(self.NYP, "Integration points Y")
def check_fields(self):
self.ELECTRONENERGY = congruence.checkStrictlyPositiveNumber(
self.ELECTRONENERGY, "Electron Energy")
if not self.METHOD == 1:
self.ELECTRONENERGYSPREAD = congruence.checkPositiveNumber(
self.ELECTRONENERGYSPREAD, "Electron Energy Spread")
self.ELECTRONCURRENT = congruence.checkStrictlyPositiveNumber(
self.ELECTRONCURRENT, "Electron Current")
self.ELECTRONBEAMSIZEH = congruence.checkPositiveNumber(
self.ELECTRONBEAMSIZEH, "Electron Beam Size H")
self.ELECTRONBEAMSIZEV = congruence.checkPositiveNumber(
self.ELECTRONBEAMSIZEV, "Electron Beam Size V")
self.ELECTRONBEAMDIVERGENCEH = congruence.checkPositiveNumber(
self.ELECTRONBEAMDIVERGENCEH, "Electron Beam Divergence H")
self.ELECTRONBEAMDIVERGENCEV = congruence.checkPositiveNumber(
self.ELECTRONBEAMDIVERGENCEV, "Electron Beam Divergence V")
self.PERIODID = congruence.checkStrictlyPositiveNumber(
self.PERIODID, "Period ID")
self.NPERIODS = congruence.checkStrictlyPositiveNumber(
self.NPERIODS, "Number of Periods")
self.KV = congruence.checkPositiveNumber(self.KV, "Kv")
self.KH = congruence.checkPositiveNumber(self.KH, "Kh")
self.KPHASE = congruence.checkNumber(self.KPHASE, "KPHASE")
self.DISTANCE = congruence.checkPositiveNumber(self.DISTANCE,
"Distance to slit")
self.GAPH = congruence.checkPositiveNumber(self.GAPH, "Slit gap H")
self.GAPV = congruence.checkPositiveNumber(self.GAPV, "Slit gap V")
self.GAPH_CENTER = congruence.checkPositiveNumber(
self.GAPH_CENTER, "Slit center H")
self.GAPV_CENTER = congruence.checkPositiveNumber(
self.GAPV_CENTER, "Slit center V")
self.PHOTONENERGYMIN = congruence.checkPositiveNumber(
self.PHOTONENERGYMIN, "photon Energy Min")
self.PHOTONENERGYMAX = congruence.checkStrictlyPositiveNumber(
self.PHOTONENERGYMAX, "photon Energy Max")
congruence.checkLessThan(self.PHOTONENERGYMIN, self.PHOTONENERGYMAX,
"photon Energy Min", "photon Energy Max")
self.PHOTONENERGYPOINTS = congruence.checkStrictlyPositiveNumber(
self.PHOTONENERGYPOINTS, "photon Energy Points")
if self.METHOD == 1: # URGENT
congruence.checkLessThan(self.PHOTONENERGYPOINTS, 4701,
"Number of energy points", "4701")
def check_fields(self):
self.ENERGY = congruence.checkStrictlyPositiveNumber(self.ENERGY, "Electron Energy")
self.CURRENT = congruence.checkStrictlyPositiveNumber(self.CURRENT, "Current")
self.ENERGY_SPREAD = congruence.checkStrictlyPositiveNumber(self.ENERGY_SPREAD, "Energy Spread")
self.SIGX = congruence.checkPositiveNumber(self.SIGX , "Sigma X")
self.SIGY = congruence.checkPositiveNumber(self.SIGY , "Sigma Y")
self.SIGX1 = congruence.checkPositiveNumber(self.SIGX1, "Sigma X'")
self.SIGY1 = congruence.checkPositiveNumber(self.SIGY1, "Sigma Y'")
self.PERIOD = congruence.checkStrictlyPositiveNumber(self.PERIOD, "Period length")
self.NP = congruence.checkStrictlyPositiveNumber(self.NP, "Number of periods")
self.EMIN = congruence.checkPositiveNumber(self.EMIN, "E1 minimum energy")
self.EMAX = congruence.checkStrictlyPositiveNumber(self.EMAX, "E1 maximum energy")
congruence.checkLessThan(self.EMIN, self.EMAX, "E1 minimum energy", "E1 maximum energy")
self.N = congruence.checkStrictlyPositiveNumber(self.N, "Number of Energy Points")
self.HARMONIC_FROM = congruence.checkStrictlyPositiveNumber(self.HARMONIC_FROM, "Minimum harmonic number")
self.HARMONIC_TO = congruence.checkStrictlyPositiveNumber(self.HARMONIC_TO, "Maximum harmonic number")
congruence.checkLessThan(self.HARMONIC_FROM, self.HARMONIC_TO, "Minimum harmonic number", "Maximum harmonic number")
self.HARMONIC_STEP = congruence.checkStrictlyPositiveNumber(self.HARMONIC_STEP, "Harmonic step size")
self.NEKS = congruence.checkPositiveNumber(self.NEKS , "Intrinsic NEKS")
def check_fields(self):
self.NPERIODS = congruence.checkStrictlyPositiveNumber(self.NPERIODS, "Number of Periods")
self.ENERGY = congruence.checkStrictlyPositiveNumber(self.ENERGY, "Beam Energy")
self.PHOT_ENERGY_MIN = congruence.checkPositiveNumber(self.PHOT_ENERGY_MIN, "Min Photon Energy")
self.PHOT_ENERGY_MAX = congruence.checkStrictlyPositiveNumber(self.PHOT_ENERGY_MAX, "Max Photon Energy")
congruence.checkLessThan(self.PHOT_ENERGY_MIN, self.PHOT_ENERGY_MAX, "Min Photon Energy", "Max Photon Energy")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.NPOINTS, "Number of Energy Points")
self.CURRENT = congruence.checkStrictlyPositiveNumber(self.CURRENT, "Electron Beam Current")
if self.FIELD == 0:
self.ULAMBDA = congruence.checkStrictlyPositiveNumber(self.ULAMBDA, "Wiggler period")
self.K = congruence.checkStrictlyPositiveNumber(self.K, "K")
self.NTRAJPOINTS = congruence.checkStrictlyPositiveNumber(self.NTRAJPOINTS, "Number of traj points per period")
elif self.FIELD == 1:
self.ULAMBDA = congruence.checkStrictlyPositiveNumber(self.ULAMBDA, "Wiggler period")
self.NTRAJPOINTS = congruence.checkStrictlyPositiveNumber(self.NTRAJPOINTS, "Number of traj points per period")
congruence.checkUrl(self.FILE)
elif self.FIELD == 2:
congruence.checkUrl(self.FILE)
def check_fields(self):
self.ELECTRONENERGY = congruence.checkStrictlyPositiveNumber(self.ELECTRONENERGY, "Electron Energy")
if not self.METHOD == 1: self.ELECTRONENERGYSPREAD = congruence.checkPositiveNumber(self.ELECTRONENERGYSPREAD, "Electron Energy Spread")
self.ELECTRONCURRENT = congruence.checkStrictlyPositiveNumber(self.ELECTRONCURRENT, "Electron Current")
self.ELECTRONBEAMSIZEH = congruence.checkPositiveNumber(self.ELECTRONBEAMSIZEH, "Electron Beam Size H")
self.ELECTRONBEAMSIZEV = congruence.checkPositiveNumber(self.ELECTRONBEAMSIZEV, "Electron Beam Size V")
self.ELECTRONBEAMDIVERGENCEH = congruence.checkPositiveNumber(self.ELECTRONBEAMDIVERGENCEH, "Electron Beam Divergence H")
self.ELECTRONBEAMDIVERGENCEV = congruence.checkPositiveNumber(self.ELECTRONBEAMDIVERGENCEV, "Electron Beam Divergence V")
self.PERIODID = congruence.checkStrictlyPositiveNumber(self.PERIODID, "Period ID")
self.NPERIODS = congruence.checkStrictlyPositiveNumber(self.NPERIODS, "Number of Periods")
self.KV = congruence.checkPositiveNumber(self.KV, "Kv")
self.DISTANCE = congruence.checkPositiveNumber(self.DISTANCE, "Distance to slit")
self.GAPH = congruence.checkPositiveNumber(self.GAPH, "Slit gap H")
self.GAPV = congruence.checkPositiveNumber(self.GAPV, "Slit gap V")
self.PHOTONENERGYMIN = congruence.checkPositiveNumber(self.PHOTONENERGYMIN, "photon Energy Min")
self.PHOTONENERGYMAX = congruence.checkStrictlyPositiveNumber(self.PHOTONENERGYMAX, "photon Energy Max")
congruence.checkLessThan(self.PHOTONENERGYMIN, self.PHOTONENERGYMAX, "photon Energy Min", "photon Energy Max")
self.PHOTONENERGYPOINTS = congruence.checkStrictlyPositiveNumber(self.PHOTONENERGYPOINTS, "photon Energy Points")
if sys.platform == 'linux' and self.METHOD == 2:
raise Exception("SRW calculation code not supported under Linux")
def check_fields(self):
self.MILLER_INDEX_H = congruence.checkNumber(self.MILLER_INDEX_H, "Miller index H")
self.MILLER_INDEX_K = congruence.checkNumber(self.MILLER_INDEX_K, "Miller index K")
self.MILLER_INDEX_L = congruence.checkNumber(self.MILLER_INDEX_L, "Miller index L")
self.TEMPER = congruence.checkNumber(self.TEMPER, "Temperature factor")
if self.SCAN == 0 or self.SCAN == 3:
self.SCANFROM = congruence.checkPositiveNumber(self.SCANFROM, "Min Scan value")
self.SCANTO = congruence.checkStrictlyPositiveNumber(self.SCANTO, "Max Scan value")
else:
self.SCANFROM = congruence.checkNumber(self.SCANFROM, "Min Scan value")
self.SCANTO = congruence.checkNumber(self.SCANTO, "Max Scan value")
congruence.checkLessThan(self.SCANFROM, self.SCANTO, "Min Scan value", "Max Scan value")
self.SCANPOINTS = congruence.checkStrictlyPositiveNumber(self.SCANPOINTS, "Scan points")
if self.SCAN < 4:
self.ENERGY = congruence.checkStrictlyPositiveNumber(self.ENERGY , "Fix value")
else:
self.ENERGY = congruence.checkNumber(self.ENERGY , "Fix value")
if self.MOSAIC == 0: #perfect
self.ASYMMETRY_ANGLE = congruence.checkNumber(self.ASYMMETRY_ANGLE, "Asymmetry angle")
self.THICKNESS = congruence.checkStrictlyPositiveNumber(self.THICKNESS, "Crystal thickness")
elif self.MOSAIC == 1: #mosaic
self.THICKNESS = congruence.checkStrictlyPositiveNumber(self.THICKNESS, "Crystal thickness")
self.MOSAIC_FWHM = congruence.checkNumber(self.MOSAIC_FWHM, "Mosaicity")
elif self.MOSAIC == 2 or self.MOSAIC == 3: #bent ML/PP
self.ASYMMETRY_ANGLE = congruence.checkNumber(self.ASYMMETRY_ANGLE, "Asymmetry angle")
self.THICKNESS = congruence.checkStrictlyPositiveNumber(self.THICKNESS, "Crystal thickness")
self.RSAG = congruence.checkStrictlyPositiveNumber(self.RSAG, "R Sagittal")
self.RMER = congruence.checkStrictlyPositiveNumber(self.RMER, "R meridional")
if self.ANISOTROPY == 0:
self.POISSON = congruence.checkStrictlyPositiveNumber(self.POISSON, "Poisson Ratio")
elif self.ANISOTROPY == 2:
congruence.checkEmptyString(self.CUT, "Valong; Vnorm; Vperp")
elif self.ANISOTROPY == 3:
congruence.checkFile(self.FILECOMPLIANCE)
def check_fields(self):
if self.RB_CHOICE == 0:
self.MACHINE_R_M = congruence.checkStrictlyPositiveNumber(self.MACHINE_R_M, "Magnetic Radius")
else:
self.BFIELD_T = congruence.checkStrictlyPositiveNumber(self.BFIELD_T, "Magnetic Field")
self.BEAM_ENERGY_GEV = congruence.checkStrictlyPositiveNumber(self.BEAM_ENERGY_GEV, "Beam Energy")
self.CURRENT_A = congruence.checkStrictlyPositiveNumber(self.CURRENT_A, "Beam Current")
self.HOR_DIV_MRAD = congruence.checkPositiveNumber(self.HOR_DIV_MRAD, "Horizontal div Theta")
self.PHOT_ENERGY_MIN = congruence.checkPositiveNumber(self.PHOT_ENERGY_MIN, "Min Photon Energy")
self.PHOT_ENERGY_MAX = congruence.checkStrictlyPositiveNumber(self.PHOT_ENERGY_MAX, "Max Photon Energy")
congruence.checkLessThan(self.PHOT_ENERGY_MIN, self.PHOT_ENERGY_MAX, "Min Photon Energy", "Max Photon Energy")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.NPOINTS, "Number of Energy Points")
self.PSI_MRAD_PLOT = congruence.checkNumber(self.PSI_MRAD_PLOT, "Max Psi for angular plots")
if self.VER_DIV == 2:
self.PSI_MIN = congruence.checkNumber(self.PSI_MIN, "Min Photon Energy")
self.PSI_MAX = congruence.checkNumber(self.PSI_MAX, "Max Photon Max")
congruence.checkLessThan(self.PSI_MIN, self.PSI_MAX, "Psi Min", "Psi Max")
elif self.VER_DIV == 3:
self.PSI_MIN = congruence.checkNumber(self.PSI_MIN, "Min Photon Energy")
def check_fields(self):
if self.RB_CHOICE == 0:
self.MACHINE_R_M = congruence.checkStrictlyPositiveNumber(self.MACHINE_R_M, "Magnetic Radius")
else:
self.BFIELD_T = congruence.checkStrictlyPositiveNumber(self.BFIELD_T, "Magnetic Field")
self.BEAM_ENERGY_GEV = congruence.checkStrictlyPositiveNumber(self.BEAM_ENERGY_GEV, "Beam Energy")
self.CURRENT_A = congruence.checkStrictlyPositiveNumber(self.CURRENT_A, "Beam Current")
self.HOR_DIV_MRAD = congruence.checkPositiveNumber(self.HOR_DIV_MRAD, "Horizontal div Theta")
self.PHOT_ENERGY_MIN = congruence.checkPositiveNumber(self.PHOT_ENERGY_MIN, "Min Photon Energy")
self.PHOT_ENERGY_MAX = congruence.checkStrictlyPositiveNumber(self.PHOT_ENERGY_MAX, "Max Photon Energy")
congruence.checkLessThan(self.PHOT_ENERGY_MIN, self.PHOT_ENERGY_MAX, "Min Photon Energy", "Max Photon Energy")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.NPOINTS, "Number of Energy Points")
self.PSI_MRAD_PLOT = congruence.checkNumber(self.PSI_MRAD_PLOT, "Max Psi for angular plots")
if self.VER_DIV == 2:
self.PSI_MIN = congruence.checkNumber(self.PSI_MIN, "Min Photon Energy")
self.PSI_MAX = congruence.checkNumber(self.PSI_MAX, "Max Photon Max")
congruence.checkLessThan(self.PSI_MIN, self.PSI_MAX, "Psi Min", "Psi Max")
elif self.VER_DIV == 3:
self.PSI_MIN = congruence.checkNumber(self.PSI_MIN, "Min Photon Energy")
def check_fields(self):
self.ENERGY = congruence.checkStrictlyPositiveNumber(
self.ENERGY, "Energy")
self.MILLER_INDEX_H = congruence.checkNumber(self.MILLER_INDEX_H,
"Miller index H")
self.MILLER_INDEX_K = congruence.checkNumber(self.MILLER_INDEX_K,
"Miller index K")
self.MILLER_INDEX_L = congruence.checkNumber(self.MILLER_INDEX_L,
"Miller index L")
self.ASYMMETRY_ANGLE = congruence.checkNumber(self.ASYMMETRY_ANGLE,
"Asymmetry angle")
self.THICKNESS = congruence.checkStrictlyPositiveNumber(
self.THICKNESS, "Crystal thickness")
self.TEMPERATURE = congruence.checkNumber(self.TEMPERATURE,
"Crystal temperature")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(
self.NPOINTS, "Number of points")
if self.SCALE == 1:
self.XFROM = congruence.checkNumber(self.XFROM, "Theta min")
self.XTO = congruence.checkNumber(self.XTO, "Theta max")
congruence.checkLessThan(self.XFROM, self.XTO, "Theta min",
"Theta max")
def check_fields(self):
self.DESCRIPTOR = congruence.checkEmptyString(self.DESCRIPTOR, "formula")
if self.MAT_FLAG == 1:
self.DENSITY = congruence.checkStrictlyPositiveNumber(self.DENSITY, "density")
if self.GRID > 0:
self.GRIDSTART = congruence.checkPositiveNumber(self.GRIDSTART, "Starting Energy")
if self.GRID == 1:
self.GRIDEND = congruence.checkStrictlyPositiveNumber(self.GRIDEND, "Energy to")
congruence.checkLessThan(self.GRIDSTART, self.GRIDEND, "Starting Energy", "Energy to")
self.GRIDN = congruence.checkStrictlyPositiveNumber(self.GRIDN, "Number of points")
if self.CALCULATE >= 7 and self.CALCULATE <= 9:
self.ROUGH = congruence.checkPositiveNumber(self.ROUGH, "Roughness")
self.THETA1 = congruence.checkPositiveNumber(self.THETA1, "Starting Graz angle")
if self.THETAGRID == 1:
self.THETA2 = congruence.checkStrictlyPositiveNumber(self.THETA2, "Graz angle to")
congruence.checkLessThan(self.THETA1, self.THETA2, "Starting Graz angle", "Graz angle to")
self.THETAN = congruence.checkStrictlyPositiveNumber(self.THETAN, "Number of angular points")
else:
self.THETAGRID = 0
def check_fields(self):
self.ENERGY = congruence.checkStrictlyPositiveNumber(self.ENERGY, "Electron Energy")
self.CURRENT = congruence.checkStrictlyPositiveNumber(self.CURRENT, "Current")
self.ENERGY_SPREAD = congruence.checkStrictlyPositiveNumber(self.ENERGY_SPREAD, "Energy Spread")
self.SIGX = congruence.checkPositiveNumber(self.SIGX , "Sigma X")
self.SIGY = congruence.checkPositiveNumber(self.SIGY , "Sigma Y")
self.SIGX1 = congruence.checkPositiveNumber(self.SIGX1, "Sigma X'")
self.SIGY1 = congruence.checkPositiveNumber(self.SIGY1, "Sigma Y'")
self.PERIOD = congruence.checkStrictlyPositiveNumber(self.PERIOD, "Period length")
self.NP = congruence.checkStrictlyPositiveNumber(self.NP, "Number of periods")
self.EMIN = congruence.checkPositiveNumber(self.EMIN, "E1 minimum energy")
self.EMAX = congruence.checkStrictlyPositiveNumber(self.EMAX, "E1 maximum energy")
congruence.checkLessThan(self.EMIN, self.EMAX, "E1 minimum energy", "E1 maximum energy")
self.N = congruence.checkStrictlyPositiveNumber(self.N, "Number of Energy Points")
self.DISTANCE = congruence.checkPositiveNumber(self.DISTANCE, "Distance to slit")
self.XPS = congruence.checkPositiveNumber(self.XPS, "Aperture Width H")
self.YPS = congruence.checkPositiveNumber(self.YPS, "Aperture Height V")
self.XPC = congruence.checkPositiveNumber(self.XPC, "Aperture Center H")
self.YPC = congruence.checkPositiveNumber(self.YPC, "Aperture Center V")
self.HARMONIC_FROM = congruence.checkStrictlyPositiveNumber(self.HARMONIC_FROM, "Minimum harmonic number")
self.HARMONIC_TO = congruence.checkStrictlyPositiveNumber(self.HARMONIC_TO, "Maximum harmonic number")
congruence.checkLessThan(self.HARMONIC_FROM, self.HARMONIC_TO, "Minimum harmonic number", "Maximum harmonic number")
self.HARMONIC_STEP = congruence.checkStrictlyPositiveNumber(self.HARMONIC_STEP, "Harmonic step size")
self.NEKS = congruence.checkStrictlyPositiveNumber(self.NEKS, "Neks OR % Helicity")
def check_fields(self):
self.DESCRIPTOR = congruence.checkEmptyString(self.DESCRIPTOR, "formula")
self.GRIDSTART = congruence.checkPositiveNumber(self.GRIDSTART, "Q from")
self.GRIDEND = congruence.checkStrictlyPositiveNumber(self.GRIDEND, "Q to")
congruence.checkLessThan(self.GRIDSTART, self.GRIDEND, "Q from", "Q to")
self.GRIDN = congruence.checkStrictlyPositiveNumber(self.GRIDN, "Number of q Points")
def check_fields(self):
if self.SOURCE == 1:
self.ENER_MIN = congruence.checkPositiveNumber(self.ENER_MIN, "Energy from")
self.ENER_MAX = congruence.checkStrictlyPositiveNumber(self.ENER_MAX, "Energy to")
congruence.checkLessThan(self.ENER_MIN, self.ENER_MAX, "Energy from", "Energy to")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.ENER_N, "Energy Points")
elif self.SOURCE == 2:
congruence.checkFile(self.SOURCE_FILE)
if self.NELEMENTS >= 1:
self.EL1_FOR = congruence.checkEmptyString(self.EL1_FOR, "1st oe formula")
if self.EL1_FLAG == 0: # filter
self.EL1_THI = congruence.checkStrictlyPositiveNumber(self.EL1_THI, "1st oe filter thickness")
elif self.EL1_FLAG == 1: # mirror
self.EL1_ANG = congruence.checkStrictlyPositiveNumber(self.EL1_ANG, "1st oe mirror angle")
self.EL1_ROU = congruence.checkPositiveNumber(self.EL1_ROU, "1st oe mirror roughness")
if not self.EL1_DEN.strip() == "?":
self.EL1_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL1_DEN, "1st oe density")), "1st oe density"))
if self.NELEMENTS >= 2:
self.EL2_FOR = congruence.checkEmptyString(self.EL2_FOR, "2nd oe formula")
if self.EL2_FLAG == 0: # filter
self.EL2_THI = congruence.checkStrictlyPositiveNumber(self.EL2_THI, "2nd oe filter thickness")
elif self.EL2_FLAG == 1: # mirror
self.EL2_ANG = congruence.checkStrictlyPositiveNumber(self.EL2_ANG, "2nd oe mirror angle")
self.EL2_ROU = congruence.checkPositiveNumber(self.EL2_ROU, "2nd oe mirror roughness")
if not self.EL2_DEN.strip() == "?":
self.EL2_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL2_DEN, "2nd oe density")), "2nd oe density"))
if self.NELEMENTS >= 3:
self.EL3_FOR = congruence.checkEmptyString(self.EL3_FOR, "3rd oe formula")
if self.EL3_FLAG == 0: # filter
self.EL3_THI = congruence.checkStrictlyPositiveNumber(self.EL3_THI, "3rd oe filter thickness")
elif self.EL3_FLAG == 1: # mirror
self.EL3_ANG = congruence.checkStrictlyPositiveNumber(self.EL3_ANG, "3rd oe mirror angle")
self.EL3_ROU = congruence.checkPositiveNumber(self.EL3_ROU, "3rd oe mirror roughness")
if not self.EL3_DEN.strip() == "?":
self.EL3_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL3_DEN, "3rd oe density")), "3rd oe density"))
if self.NELEMENTS >= 4:
self.EL4_FOR = congruence.checkEmptyString(self.EL4_FOR, "4th oe formula")
if self.EL4_FLAG == 0: # filter
self.EL4_THI = congruence.checkStrictlyPositiveNumber(self.EL4_THI, "4th oe filter thickness")
elif self.EL4_FLAG == 1: # mirror
self.EL4_ANG = congruence.checkStrictlyPositiveNumber(self.EL4_ANG, "4th oe mirror angle")
self.EL4_ROU = congruence.checkPositiveNumber(self.EL4_ROU, "4th oe mirror roughness")
if not self.EL4_DEN.strip() == "?":
self.EL4_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL4_DEN, "4th oe density")), "4th oe density"))
if self.NELEMENTS >= 5:
self.EL5_FOR = congruence.checkEmptyString(self.EL5_FOR, "5th oe formula")
if self.EL5_FLAG == 0: # filter
self.EL5_THI = congruence.checkStrictlyPositiveNumber(self.EL5_THI, "5th oe filter thickness")
elif self.EL5_FLAG == 1: # mirror
self.EL5_ANG = congruence.checkStrictlyPositiveNumber(self.EL5_ANG, "5th oe mirror angle")
self.EL5_ROU = congruence.checkPositiveNumber(self.EL5_ROU, "5th oe mirror roughness")
if not self.EL5_DEN.strip() == "?":
self.EL5_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL5_DEN, "5th oe density")), "5th oe density"))
def check_fields(self):
if self.SOURCE == 1:
self.ENER_MIN = congruence.checkPositiveNumber(self.ENER_MIN, "Energy from")
self.ENER_MAX = congruence.checkStrictlyPositiveNumber(self.ENER_MAX, "Energy to")
congruence.checkLessThan(self.ENER_MIN, self.ENER_MAX, "Energy from", "Energy to")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.ENER_N, "Energy Points")
elif self.SOURCE == 2:
congruence.checkFile(self.SOURCE_FILE)
if self.NELEMENTS >= 1:
self.EL1_FOR = congruence.checkEmptyString(self.EL1_FOR, "1st oe formula")
if self.EL1_FLAG == 0: # filter
self.EL1_THI = congruence.checkStrictlyPositiveNumber(self.EL1_THI, "1st oe filter thickness")
elif self.EL1_FLAG == 1: # mirror
self.EL1_ANG = congruence.checkStrictlyPositiveNumber(self.EL1_ANG, "1st oe mirror angle")
self.EL1_ROU = congruence.checkPositiveNumber(self.EL1_ROU, "1st oe mirror roughness")
if not self.EL1_DEN.strip() == "?":
self.EL1_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL1_DEN, "1st oe density")), "1st oe density"))
if self.NELEMENTS >= 2:
self.EL2_FOR = congruence.checkEmptyString(self.EL2_FOR, "2nd oe formula")
if self.EL2_FLAG == 0: # filter
self.EL2_THI = congruence.checkStrictlyPositiveNumber(self.EL2_THI, "2nd oe filter thickness")
elif self.EL2_FLAG == 1: # mirror
self.EL2_ANG = congruence.checkStrictlyPositiveNumber(self.EL2_ANG, "2nd oe mirror angle")
self.EL2_ROU = congruence.checkPositiveNumber(self.EL2_ROU, "2nd oe mirror roughness")
if not self.EL2_DEN.strip() == "?":
self.EL2_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL2_DEN, "2nd oe density")), "2nd oe density"))
if self.NELEMENTS >= 3:
self.EL3_FOR = congruence.checkEmptyString(self.EL3_FOR, "3rd oe formula")
if self.EL3_FLAG == 0: # filter
self.EL3_THI = congruence.checkStrictlyPositiveNumber(self.EL3_THI, "3rd oe filter thickness")
elif self.EL3_FLAG == 1: # mirror
self.EL3_ANG = congruence.checkStrictlyPositiveNumber(self.EL3_ANG, "3rd oe mirror angle")
self.EL3_ROU = congruence.checkPositiveNumber(self.EL3_ROU, "3rd oe mirror roughness")
if not self.EL3_DEN.strip() == "?":
self.EL3_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL3_DEN, "3rd oe density")), "3rd oe density"))
if self.NELEMENTS >= 4:
self.EL4_FOR = congruence.checkEmptyString(self.EL4_FOR, "4th oe formula")
if self.EL4_FLAG == 0: # filter
self.EL4_THI = congruence.checkStrictlyPositiveNumber(self.EL4_THI, "4th oe filter thickness")
elif self.EL4_FLAG == 1: # mirror
self.EL4_ANG = congruence.checkStrictlyPositiveNumber(self.EL4_ANG, "4th oe mirror angle")
self.EL4_ROU = congruence.checkPositiveNumber(self.EL4_ROU, "4th oe mirror roughness")
if not self.EL4_DEN.strip() == "?":
self.EL4_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL4_DEN, "4th oe density")), "4th oe density"))
if self.NELEMENTS >= 5:
self.EL5_FOR = congruence.checkEmptyString(self.EL5_FOR, "5th oe formula")
if self.EL5_FLAG == 0: # filter
self.EL5_THI = congruence.checkStrictlyPositiveNumber(self.EL5_THI, "5th oe filter thickness")
elif self.EL5_FLAG == 1: # mirror
self.EL5_ANG = congruence.checkStrictlyPositiveNumber(self.EL5_ANG, "5th oe mirror angle")
self.EL5_ROU = congruence.checkPositiveNumber(self.EL5_ROU, "5th oe mirror roughness")
if not self.EL5_DEN.strip() == "?":
self.EL5_DEN = str(congruence.checkStrictlyPositiveNumber(float(congruence.checkNumber(self.EL5_DEN, "5th oe density")), "5th oe density"))
def calculate_total_filter(self):
try:
congruence.checkStrictlyPositiveNumber(self.energy_from,
"Energy From")
congruence.checkStrictlyPositiveNumber(self.energy_to, "Energy to")
congruence.checkStrictlyPositiveNumber(self.energy_nr,
"Nr. of energies")
congruence.checkLessThan(self.energy_from, self.energy_to,
"Energy From", "Energy to")
energies = numpy.linspace(self.energy_from, self.energy_to,
self.energy_nr)
total_filter = numpy.ones((self.energy_nr, 2))
total_filter[:, 0] = energies
self.__add_data_to_total_filter(total_filter, self.ref_1,
self.n_ref_1, self.check_ref_1)
self.__add_data_to_total_filter(total_filter, self.ref_2,
self.n_ref_2, self.check_ref_2)
self.__add_data_to_total_filter(total_filter, self.ref_3,
self.n_ref_3, self.check_ref_3)
self.__add_data_to_total_filter(total_filter, self.dif_1,
self.n_dif_1, self.check_dif_1)
self.__add_data_to_total_filter(total_filter, self.dif_2,
self.n_dif_2, self.check_dif_2)
self.__add_data_to_total_filter(total_filter, self.mul_1,
self.n_mul_1, self.check_mul_1)
self.__add_data_to_total_filter(total_filter, self.mul_2,
self.n_mul_2, self.check_mul_2)
self.__add_data_to_total_filter(total_filter,
self.pow_1,
0,
self.check_pow_1,
absorbed=self.abs_tran == 0)
total_filter[numpy.where(numpy.isnan(total_filter))] = 0.0
if not total_filter[:, 1].sum() == total_filter.shape[0]:
self.filter_plot.clear()
self.filter_plot.addCurve(total_filter[:, 0],
total_filter[:, 1],
replace=True,
legend="Total Filter")
self.filter_plot.setGraphXLabel("Energy [eV]")
self.filter_plot.setGraphYLabel("Intensity Factor")
self.filter_plot.setGraphTitle("Total Filter")
calculated_data = DataExchangeObject("ShadowOui_Thermal",
"TOTAL_FILTER")
calculated_data.add_content("total_filter", total_filter)
self.send("Total Filter", calculated_data)
else:
raise ValueError("Calculation not possibile: no input data")
except Exception as e:
QMessageBox.critical(self, "Error", str(e), QMessageBox.Ok)
if self.IS_DEVELOP: raise e
def check_fields(self):
self.TEMPERATURE = congruence.checkPositiveNumber(self.TEMPERATURE, "Temperature")
self.E_MIN = congruence.checkPositiveNumber(self.E_MIN, "Min Energy")
self.E_MAX = congruence.checkStrictlyPositiveNumber(self.E_MAX, "Max Energy")
congruence.checkLessThan(self.E_MIN, self.E_MAX, "Min Energy", "Max Energy")
self.NPOINTS = congruence.checkStrictlyPositiveNumber(self.NPOINTS, "Number of Points")
