Esempio n. 1
0
    def _createtWidgets(self):
        '''Creates all the widgets'''

        # Make the views
        self.plot = Plot(self)
        self.rate = RateView(parent=self)
        self.exchange = ExchangeView(parent=self)
        self.peak = PeakView(parent=self)
        self.scale = ScaleView(parent=self)

        # Create the model controller
        self.control = Controller(self)

        # Attach models to the views
        self.rate.setModel(self.control.rate)
        self.exchange.setModel(self.control.exchange, self.control.numpeaks)
        self.peak.setModel(self.control.peak)
        self.scale.setModel(self.control.scale)

        # Init the UI of all the views
        self.rate.initUI()
        self.exchange.initUI()
        self.peak.initUI()
        self.scale.initUI()

        # Last, make inter-view connections
        self.rate.makeConnections()
        self.exchange.makeConnections()
        self.peak.makeConnections()
        self.scale.makeConnections()
        self.plot.makeConnections()

        # The window will own a button to clear raw data
        self.clear = QPushButton('Clear Raw Data', self)
        self.clear.setToolTip(ttt('Remove raw data from the plot '
                                  'if there is any'))
Esempio n. 2
0
class MainWindow(QMainWindow):
    '''The main window of the program'''

    def __init__(self):
        '''Initialize the main window and it's parents'''
        super(MainWindow, self).__init__()
        self._createtWidgets()
        self._initUI()
        self._makeMenu()
        self._makeConnections()
        self.fileName = None
        self.pdfName = None
        self.scriptName = None
        self.expName = None
        self.rawName = None
        self.rawExpName = None

        # Set initial number of peaks
        self.exchange.setNumPeaks(2)
        # Set matrix to symmetric by default
        self.exchange.setMatrixSymmetry(True)
        # Set the initial window.  
        self.scale.setValue(1900, 2100, False)
        # Default to rate in units of THz
        self.rate.setUnit('THz')
        # Clear button starts off inactive
        self.clear.setEnabled(False)

    def _createtWidgets(self):
        '''Creates all the widgets'''

        # Make the views
        self.plot = Plot(self)
        self.rate = RateView(parent=self)
        self.exchange = ExchangeView(parent=self)
        self.peak = PeakView(parent=self)
        self.scale = ScaleView(parent=self)

        # Create the model controller
        self.control = Controller(self)

        # Attach models to the views
        self.rate.setModel(self.control.rate)
        self.exchange.setModel(self.control.exchange, self.control.numpeaks)
        self.peak.setModel(self.control.peak)
        self.scale.setModel(self.control.scale)

        # Init the UI of all the views
        self.rate.initUI()
        self.exchange.initUI()
        self.peak.initUI()
        self.scale.initUI()

        # Last, make inter-view connections
        self.rate.makeConnections()
        self.exchange.makeConnections()
        self.peak.makeConnections()
        self.scale.makeConnections()
        self.plot.makeConnections()

        # The window will own a button to clear raw data
        self.clear = QPushButton('Clear Raw Data', self)
        self.clear.setToolTip(ttt('Remove raw data from the plot '
                                  'if there is any'))

    def _initUI(self):
        '''Sets up the layout of the window'''

        # Define a central widget and a layout for the window
        self.setCentralWidget(QWidget())
        self.mainLayout = QHBoxLayout()
        self.setWindowTitle('Spectral Exchange')

        # Make a layout for all the parameter views
        params = QVBoxLayout()
        params.addWidget(self.rate)
        params.addWidget(self.exchange)
        params.addWidget(self.peak)

        # Add the parameter dialog
        self.mainLayout.addLayout(params)

        # Add the plot 
        plot_lim = QVBoxLayout()
        plot_lim.addWidget(self.plot)
        lim_clear = QHBoxLayout()
        lim_clear.addWidget(self.scale)
        lim_clear.addWidget(self.clear)
        plot_lim.addLayout(lim_clear)
        self.mainLayout.addLayout(plot_lim)

        # Add the widgets to the central widget
        self.centralWidget().setLayout(self.mainLayout)

    def _makeConnections(self):
        '''Connect the widgets to each other'''

        # When the controller says plot, plot
        self.control.plotSpectrum.connect(self.plot.plotCalculatedData)

        # When the controller says resize x limits, do so
        self.control.newXLimits.connect(self.plot.changeScale)

        # Clear raw data if pushed
        self.clear.clicked.connect(self.clearRawData)

        # If the plot is clicked, send info to the scale widget
        self.plot.pointPicked.connect(self.scale.setSelection)

    def _makeMenu(self):
        '''Makes the menu bar for this widget'''
        # Get the menu bar object
        self.menu = self.menuBar()
        self.fileMenu = self.menu.addMenu('&File')

        # Open action
        open = QAction('&Open', self)
        open.setShortcuts(QKeySequence.Open)
        open.triggered.connect(self.openFromInput)
        open.setToolTip('Open an already made input file')
        self.fileMenu.addAction(open)

        # Save action
        save = QAction('&Save', self)
        save.setShortcuts(QKeySequence.Save)
        save.triggered.connect(self.saveToInput)
        save.setToolTip('Save settings to an input file')
        self.fileMenu.addAction(save)

        # Save action
        saveas = QAction('Save As', self)
        saveas.triggered.connect(self.saveToInputAs)
        save.setToolTip('Save settings to an input file of a new name')
        self.fileMenu.addAction(saveas)

        # Save action
        savepdf = QAction('Save as PDF', self)
        savepdf.triggered.connect(self.saveAsPDF)
        save.setToolTip('Save image to a PDF')
        self.fileMenu.addAction(savepdf)

        # Menu separator
        self.fileMenu.addSeparator()

        # Import action
        imp = QAction('&Import raw XY data', self)
        imp.setShortcut(QKeySequence('Ctrl+I'))
        imp.triggered.connect(self.importRawData)
        imp.setToolTip('Import raw data an plot alongside calculated data')
        self.fileMenu.addAction(imp)

        # Export action
        raw = QAction('Export raw XY data', self)
        raw.triggered.connect(self.exportRawData)
        raw.setToolTip('Export raw data to a file for use elsewhere')
        self.fileMenu.addAction(raw)

        # Export action
        exp = QAction('&Export calculated XY data', self)
        exp.setShortcut(QKeySequence('Ctrl+E'))
        exp.triggered.connect(self.exportXYData)
        exp.setToolTip('Export calculated data to a file for use elsewhere')
        self.fileMenu.addAction(exp)

        # Make script action
        scr = QAction('Make Sc&ript', self)
        scr.setShortcut(QKeySequence('Ctrl+R'))
        scr.triggered.connect(self.makeScript)
        scr.setToolTip('Create a python script that directly recreates this '
                       'spectrum')
        self.fileMenu.addAction(scr)

        # Menu separator
        self.fileMenu.addSeparator()

        # Quit action
        quit = QAction('&Quit', self)
        quit.setShortcuts(QKeySequence.Quit)
        quit.triggered.connect(QApplication.instance().quit)
        self.fileMenu.addAction(quit)

    #######
    # SLOTS
    #######

    def clearRawData(self):
        '''Clear the raw data from the plot'''
        self.plot.clearRawData()
        self.clear.setEnabled(False)

    def openFromInput(self):
        '''Open parameters from an input file'''
        filter = 'Input Files (*.inp);;All (*)'
        s = QFileDialog.getOpenFileName(self, 'Input File Name',
                                              '', filter)
        # Continue unless the user hit cancel
        if not s[0]:
            return
        fileName = s[0]

        # Read given input file
        try:
            args = read_input(fileName)
        except ReaderError as r:  # Error reading the input file
            error.showMessage(str(r))

        # Set the number of peaks
        npeaks = len(args.num)
        if npeaks < 2:
            error.showMessage('Need at least 2 peaks for exchange')
            return
        elif npeaks > 4:
            error.showMessage('This GUI can only handle up to 4 peaks. '
                              'Use the command-line version for an arbitrary '
                              'number of peaks')
            return
        self.exchange.setNumPeaks(npeaks)

        # Set the exchange
        matrix = ZMat(npeaks, args.exchanges, args.exchange_rates,
                      args.symmetric_exchange)
        self.exchange.setMatrixSymmetry(args.symmetric_exchange)
        self.exchange.setMatrix(matrix)

        # Set the rate
        if 'lifetime' in args:
            self.rate.setUnit(args.lifetime[1])
            self.rate.setRate(args.lifetime[0])
        else:
            self.rate.setUnit(args.rate[1])
            self.rate.setRate(args.rate[0])

        # Set the peak data
        self.peak.setPeaks(args.vib, args.Gamma_Lorentz, args.Gamma_Gauss,
                           args.heights)

        # Plot this data
        self.control.setDataForPlot()

        # Plot raw data if it exists
        if args.raw is not None:
            self.rawName = args.rawName
            self.plot.setRawData(args.raw)
            self.plot.plotRawData()
            self.clear.setEnabled(True)

        # Set the limits
        self.scale.setValue(args.xlim[0], args.xlim[1], args.reverse)

    def saveToInput(self):
        '''Save current settings to current input file if available'''
        if not self.control.hasPlot:
            error.showMessage('Cannot save.. there is no data to save yet')
            return
        if self.fileName is None:
            self.saveToInputAs()
        else:
            self.inputGen(self.fileName)

    def saveToInputAs(self):
        '''Save current settings to an input file of specified name'''
        if not self.control.hasPlot:
            error.showMessage('Cannot save.. there is no data to save yet')
            return
        filter = 'Input Files (*.inp);;All (*)'
        d = '' if self.fileName is None else self.fileName
        s = QFileDialog.getSaveFileName(self, 'Input File Name',
                                              d, filter)
        # Continue unless the user hit cancel
        if not s[0]:
            return
        self.fileName = s[0]

        # Generate the input file
        self.inputGen(self.fileName)

    def saveAsPDF(self):
        '''Save plot as a PDF'''
        if not self.control.hasPlot:
            error.showMessage('Cannot save.. there is no data to save yet')
            return
        filter = 'PDF Documents (*.pdf);;All (*)'
        d = '' if self.pdfName is None else self.pdfName
        s = QFileDialog.getSaveFileName(self, 'PDF File Name',
                                              d, filter)
        # Continue unless the user hit cancel
        if not s[0]:
            return
        self.pdfName = s[0]

        # Set up the PDF printer
        printer = QPrinter()
        printer.setOutputFormat(QPrinter.PdfFormat)
        printer.setOrientation(QPrinter.Landscape)
        printer.setOutputFileName(self.pdfName)
        printer.setCreator('RAPID')

        # Send to the plot for printing
        p = QPainter()
        p.begin(printer)
        x, y = self.plot.calculatedData()
        plt = pgplot(x, y,
                     antialias=True,
                     connect='all',
                     pen={'color': 'b', 'width': 0})
        plt.setLabel('bottom', "Frequency (Wavenumbers, cm<sup>-1</sup>)")
        plt.getAxis('bottom').setPen('k')
        plt.setLabel('left', "Intensity (Normalized)")
        plt.getAxis('left').setPen('k')
        plt.setYRange(0, 1.1, padding=0)
        plt.invertX(self.plot.reversed)
        plt.setBackground('w')  # White

        # The raw (experimental) data, if any
        if self.plot.rawData is not None:
            data = self.plot.getRawData()
            x, y = data[:,0], data[:,1]
            curve2 = PlotCurveItem(x, y,
                                   antialias=True,
                                   connect='all',
                                   pen={'color': 'g', 'width': 0})
            plt.addItem(curve2)
        plt.render(p)
        p.end()

    def exportXYData(self):
        '''Export current spectrum to XY data'''
        if not self.control.hasPlot:
            error.showMessage('Cannot export.. there is no data to export yet')
            return
        filter = 'Data Files (*.txt *.data);;All (*)'
        d = '' if self.expName is None else self.expName
        s = QFileDialog.getSaveFileName(self, 'Calculated XY Data File Name',
                                              d, filter)
        # Continue unless the user hit cancel
        if not s[0]:
            return
        self.expName = s[0]

        # Grab the XY data from the plot
        x, y = self.plot.calculatedData()
        # Save in a standard format
        try:
            write_data(x, y, self.expName)
        except (IOError, OSError) as e:
            error.showMessage(str(e))

    def exportRawData(self):
        '''Export current raw data to XY data'''
        if self.plot.rawData is None:
            error.showMessage('Cannot export.. there is no raw data to export yet')
            return
        filter = 'Data Files (*.txt *.data);;All (*)'
        d = '' if self.rawExpName is None else self.rawExpName
        s = QFileDialog.getSaveFileName(self, 'Raw XY Data File Name',
                                              d, filter)
        # Continue unless the user hit cancel
        if not s[0]:
            return
        self.rawExpName = s[0]

        # Grab the raw XY data from the plot
        data = self.plot.getRawData()
        # Save in a standard format
        try:
            write_data(data[:,0], data[:,1], self.rawExpName)
        except (IOError, OSError) as e:
            error.showMessage(str(e))

    def importRawData(self):
        '''Import data from an XY file'''
        filter = 'Data Files (*.txt *.data);;All (*)'
        d = '' if self.rawName is None else self.rawName
        s = QFileDialog.getOpenFileName(self, 'Raw XY Data File Name',
                                              d, filter)
        # Continue unless the user hit cancel
        if not s[0]:
            return
        self.rawName = s[0]

        # Load raw data and plot in a second curve
        rawData = loadtxt(str(self.rawName))
        self.plot.setRawData(rawData)
        self.plot.plotRawData()
        self.clear.setEnabled(True)

    def makeScript(self):
        '''Open parameters from an input file'''
        if not self.control.hasPlot:
            error.showMessage('Cannot save.. there is no data to save yet')
            return
        filter = 'Python Scripts (*.py)'
        d = '' if self.scriptName is None else self.scriptName
        s = QFileDialog.getSaveFileName(self, 'Python Script File Name',
                                              d, filter)
        # Continue unless the user hit cancel
        if not s[0]:
            return
        self.scriptName = s[0]

        # Get parameters needed
        xlim, rev, oldp, newp = self.control.getParametersForScript()
        x, y = self.plot.calculatedData()
        if self.clear.isEnabled():
            raw = self.plot.rawData
        else:
            raw = None
        save_script(x, y, raw, xlim, rev, oldp, newp, self.scriptName)

    def inputGen(self, fileName):
        '''Generate an input file'''

        # Open file for writing        
        try:
            fl = open(fileName, 'w')
        except (IOError, OSError) as e:
            error.showError(str(e))

        # Generate a template string to print
        s = dedent('''\
            # The rate or lifetime of the reaction
            {rate}

            # The exchange matrix
            {exchange}

            # The peak data
            {peaks}

            # The plot limits
            {limits}

            # Raw input file, if any
            {raw}
            ''')

        # Get the parameters from the underlying data
        xlim, rev, rate, exchange, peaks = self.control.getParametersForInput()

        # Create the rate string
        if rate[1] in ('s', 'ns', 'ps', 'fs'):
            lr = 'lifetime'
        else:
            lr = 'rate'
        ratestr = '{0} {1[0]:.3G} {1[1]}'.format(lr, rate)

        # Create exchange string
        exstr = []
        if not exchange[2]:
            exstr.append('nosym')
        f = 'exchange {0:d} {1:d} {2:.3f}'
        for indx, r in zip(exchange[1], exchange[0]):
            exstr.append(f.format(indx[0]+1, indx[1]+1, r))
        exstr = '\n'.join(exstr)

        # Create peak string
        peakstr = []
        f = 'peak {0:.2f} {1:.3f} L={2:.3f} G={3:.3f}'
        for p, l, g, h in zip(peaks[0], peaks[1], peaks[2], peaks[3]):
            peakstr.append(f.format(p, h, l, g))
        peakstr = '\n'.join(peakstr)
            
        # Create the limits string
        limitstr = 'xlim {0[0]:d} {0[1]:d}'.format(xlim)
        if rev:
            limitstr += '\nreverse'

        # Create the IO string
        if self.rawName is not None:
            rawstr = 'raw {0}'.format(self.rawName)
        else:
            rawstr = ''

        # Write the string to file
        fl.write(s.format(rate=ratestr, peaks=peakstr, limits=limitstr,
                          exchange=exstr, raw=rawstr))

        # Close file
        fl.close()