#/*########################################################################## # Copyright (C) 2004-2015 V.A. Sole, European Synchrotron Radiation Facility # # This file is part of the PyMca X-ray Fluorescence Toolkit developed at # the ESRF by the Software group. # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the "Software"), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN # THE SOFTWARE. # #############################################################################*/ """ """ __author__ = "V.A. Sole - ESRF Data Analysis" __contact__ = "sole@esrf.fr" __license__ = "MIT" __copyright__ = "European Synchrotron Radiation Facility, Grenoble, France" import numpy try: from PyMca5 import Plugin1DBase except ImportError: from . import Plugin1DBase try: from PyMca5.PyMcaPhysics.xas import XASClass from PyMca5.PyMcaGui.physics.xas import XASWindow except ImportError: print("XASPlugin problem") class XASPlugin(Plugin1DBase.Plugin1DBase): def __init__(self, plotWindow, **kw): Plugin1DBase.Plugin1DBase.__init__(self, plotWindow, **kw) self.methodDict = {} text = "Configure normalization parameters." function = self.configure info = text icon = None self.methodDict["Configure"] =[function, info, icon] text = "Replace all curves by normalized ones." function = self.getNormalization info = text icon = None self.methodDict["Normalize"] =[function, info, icon] text = "Replace all curves by their EXAFS FTs." function = self.getFT info = text icon = None self.methodDict["FT"] =[function, info, icon] text = "Replace all curves by their EXAFS Signal." function = self.getSignal0 info = text icon = None self.methodDict["EXAFS"] =[function, info, icon] text = "Replace all curves by their EXAFS Signal." function = self.getSignal1 info = text icon = None self.methodDict["EXAFS * k"] =[function, info, icon] text = "Replace all curves by their EXAFS Signal." function = self.getSignal2 info = text icon = None self.methodDict["EXAFS * k^2"] =[function, info, icon] text = "Replace all curves by their EXAFS Signal." function = self.getSignal3 info = text icon = None self.methodDict["EXAFS * k^3"] =[function, info, icon] self.analyzer = XASClass.XASClass() self.widget = None #Methods to be implemented by the plugin def getMethods(self, plottype=None): """ A list with the NAMES associated to the callable methods that are applicable to the specified plot. Plot type can be "SCAN", "MCA", None, ... """ names = list(self.methodDict.keys()) names.sort() return names def getMethodToolTip(self, name): """ Returns the help associated to the particular method name or None. """ return self.methodDict[name][1] def getMethodPixmap(self, name): """ Returns the pixmap associated to the particular method name or None. """ return self.methodDict[name][2] def applyMethod(self, name): """ The plugin is asked to apply the method associated to name. """ self.methodDict[name][0]() return def configure(self): #get active curve activeCurve = self.getActiveCurve() if activeCurve is None: raise ValueError("Please select an active curve") return x, y, legend0, info = activeCurve xmin, xmax = self.getGraphXLimits() idx = (x >= xmin) & (x <= xmax) x = x[idx] y = y[idx] if self.widget is None: self._createWidget() self.widget.setSpectrum(x, y) oldConfiguration = self.analyzer.getConfiguration() self.widget.setConfiguration(oldConfiguration) ret = self.widget.exec_() if ret: # it should be already configured pass else: self.analyzer.setConfiguration(oldConfiguration) def _createWidget(self): parent = None self.widget = XASWindow.XASDialog(parent, analyzer=self.analyzer) def processAllCurves(self): # for the time being we do not calculate just # what is asked but everything results = [] curves = self.getMonotonicCurves() for curve in curves: x, y, legend, info = curve[0:4] self.analyzer.setSpectrum(x, y) ddict = self.analyzer.processSpectrum() results.append([ddict, legend, info]) return results def getNormalization(self): xlabel="Energy (eV)" ylabel="Absorption (a.u.)" results = self.processAllCurves() n = len(results) i = 0 for result in results: ddict, legend, info = result idx = (ddict["NormalizedEnergy"] >= ddict["NormalizedPlotMin"]) & \ (ddict["NormalizedEnergy"] <= ddict["NormalizedPlotMax"]) x = ddict["NormalizedEnergy"][idx] y = ddict["NormalizedMu"][idx] if i == 0: replace = True else: replace = False i += 1 if i == n: replot = True else: replot = False self.addCurve(x, y, legend, info, xlabel=xlabel, ylabel=ylabel, replot=replot, replace=replace) def getFT(self): xlabel="R (Angstrom)" ylabel="Intensity (a.u.)" results = self.processAllCurves() n = len(results) i = 0 for result in results: ddict, legend, info = result x = ddict["FT"]["FTRadius"] y = ddict["FT"]["FTIntensity"] if i == 0: replace = True else: replace = False i += 1 if i == n: replot = True else: replot = False self.addCurve(x, y, legend, info, xlabel=xlabel, ylabel=ylabel, replot=replot, replace=replace) def getSignal(self, weight=0): xlabel="K" weight = int(weight) if weight == 0: ylabel = "Signal" elif weight == 1: ylabel = "Signal * k" else: ylabel = "Signal * k^%d" % int(weight) results = self.processAllCurves() n = len(results) i = 0 for result in results: ddict, legend, info = result idx = (ddict["EXAFSKValues"] >= ddict["KMin"]) & \ (ddict["EXAFSKValues"] <= ddict["KMax"]) x = ddict["EXAFSKValues"][idx] if ddict["KWeight"] != weight: y = ddict["EXAFSNormalized"][idx] * (pow(x, weight-ddict["KWeight"])) else: y = ddict["EXAFSNormalized"][idx] if i == 0: replace = True else: replace = False i += 1 if i == n: replot = True else: replot = False self.addCurve(x, y, legend, info, xlabel=xlabel, ylabel=ylabel, replot=replot, replace=replace) def getSignal0(self): self.getSignal(0) def getSignal1(self): self.getSignal(1) def getSignal2(self): self.getSignal(2) def getSignal3(self): self.getSignal(3) def XASNormalize(self): #all curves curves = self.getAllCurves() nCurves = len(curves) if nCurves < 1: raise ValueError("At least one curve needed") return #get active curve activeCurve = self.getActiveCurve() if activeCurve is None: raise ValueError("Please select an active curve") return x, y, legend0, info = activeCurve #sort the values idx = numpy.argsort(x, kind='mergesort') x0 = numpy.take(x, idx) y0 = numpy.take(y, idx) xmin, xmax = self.getGraphXLimits() # get calculation parameters if self.widget is None: self._createWidget() parameters = self.parameters if parameters['auto_edge']: edge = None else: edge = parameters['edge_energy'] energy = x pre_edge_regions = parameters['pre_edge']['regions'] post_edge_regions = parameters['post_edge']['regions'] algorithm ='polynomial' algorithm_parameters = {} algorithm_parameters['pre_edge_order'] = parameters['pre_edge']\ ['polynomial'] algorithm_parameters['post_edge_order'] = parameters['post_edge']\ ['polynomial'] i = 0 lastCurve = None for curve in curves: x, y, legend, info = curve[0:4] #take the portion ox x between limits idx = numpy.nonzero((x>=xmin) & (x<=xmax))[0] if not len(idx): #no overlap continue x = numpy.take(x, idx) y = numpy.take(y, idx) idx = numpy.nonzero((x0>=x.min()) & (x0<=x.max()))[0] if not len(idx): #no overlap continue xi = numpy.take(x0, idx) yi = numpy.take(y0, idx) #perform interpolation xi.shape = -1, 1 yw = SpecfitFuns.interpol([x], y, xi, yi.min()) # try: ... except: here? yw.shape = -1 xi.shape = -1 x, y = XASNormalization.XASNormalization(yw, energy=xi, edge=edge, pre_edge_regions=pre_edge_regions, post_edge_regions=post_edge_regions, algorithm=algorithm, algorithm_parameters=algorithm_parameters)[0:2] # if i == 0: replace = True replot = True i = 1 else: replot = False replace = False newLegend = " ".join(legend.split(" ")[:-1]) if not newLegend.startswith('Norm.'): newLegend = "Norm. " + newLegend self.addCurve(x, y, legend=newLegend, info=info, replot=replot, replace=replace) lastCurve = [x, y, newLegend] self.addCurve(lastCurve[0], lastCurve[1], legend=lastCurve[2], info=info, replot=True, replace=False) MENU_TEXT = "XAS" def getPlugin1DInstance(plotWindow, **kw): ob = XASPlugin(plotWindow) return ob if __name__ == "__main__": import sys import os from PyMca5.PyMcaGui import PyMcaQt as qt from PyMca5.PyMcaGui.pymca import ScanWindow from PyMca5.PyMcaIO import specfilewrapper as specfile from PyMca5.PyMcaDataDir import PYMCA_DATA_DIR if len(sys.argv) > 1: fileName = sys.argv[1] else: fileName = os.path.join(PYMCA_DATA_DIR, "EXAFS_Ge.dat") data = specfile.Specfile(fileName)[0].data()[-2:, :] energy = data[0, :] mu = data[1, :] app = qt.QApplication([]) plot = ScanWindow.ScanWindow() plot.pluginsToolButton.setPluginDirectoryList([os.path.dirname(__file__)]) plot.pluginsToolButton.getPlugins() plot.addCurve(energy, mu, os.path.basename(fileName), resetzoom=True) plot.show() plugin = getPlugin1DInstance(plot) for method in plugin.getMethods(): print(method, ":", plugin.getMethodToolTip(method)) #plugin.applyMethod(plugin.getMethods()[1]) app.exec_()