def __init__(self):
super(DataViewer, self).__init__()
self.comboList = ComboList.ComboList()
self.settings = SettingsWidget()
self.calcPlot = CalculatorPlot(parent=self)
self.setupGUI()
# default plots will be drawn with multiple y and single x
self.mainAxis = 'x'
self.sliderParam = self.settings.config()['Main parameters']['slider']
self.timeParam = self.settings.config()['Main parameters']['time']
# no legend at first (there is no data)
self.legend = None
self.currentDataSetName = None
# cursors are movable items to point the failure points
self.cursors = []
self.dataSetButtons = {} # list of items in the dataset section of the menu bar
'''
Note:
indices = piece of all data indices, corresponding to the
values interval, contrained by the slider
THE VIEWER PLOTTS DATA using indices!!!!
'''
self.data = None # dictionary with full current data set
self.indices = None # array with indices for the current interval
self.comments = {}
self.allComments = {}
self.allData = {} # here we keep data for different datasets
self.allCursors = {} # cursors for different dataset
self.allIndices = {} # contains all truncated indices
self.allSampleLengths = {}
self.allUnits = {}
# self.settings.okButton.pressed.connect(self.settings.hide)
self.exitButton.triggered.connect(sys.exit)
self.settingsButton.triggered.connect(self.settings.show)
self.loadButton.triggered.connect(self.requestLoad)
self.addSceneButton.triggered.connect(self.addSceneToCombo)
self.showComboDataButton.triggered.connect(self.comboList.show)
self.calcPlotButton.triggered.connect(self.runCalcPlot)
self.calcPlotButton.setDisabled(True)
####
# connect cursors
self.plt.sigRangeChanged.connect(self.scaleCursors)
self.addPointButton.triggered.connect(self.addCursor)
self.removePointButton.triggered.connect(self.removeCursor)
self.drawCirclesButton.triggered.connect(self.plotMohrCircles)
# Finally enable the save button
self.saveButton.triggered.connect(self.save)
self.setStatus('Ready')
class DataViewer(QtGui.QWidget):
def __init__(self):
super(DataViewer, self).__init__()
self.comboList = ComboList.ComboList()
self.settings = SettingsWidget()
self.calcPlot = CalculatorPlot(parent=self)
self.setupGUI()
# default plots will be drawn with multiple y and single x
self.mainAxis = 'x'
self.sliderParam = self.settings.config()['Main parameters']['slider']
self.timeParam = self.settings.config()['Main parameters']['time']
# no legend at first (there is no data)
self.legend = None
self.currentDataSetName = None
# cursors are movable items to point the failure points
self.cursors = []
self.dataSetButtons = {} # list of items in the dataset section of the menu bar
'''
Note:
indices = piece of all data indices, corresponding to the
values interval, contrained by the slider
THE VIEWER PLOTTS DATA using indices!!!!
'''
self.data = None # dictionary with full current data set
self.indices = None # array with indices for the current interval
self.comments = {}
self.allComments = {}
self.allData = {} # here we keep data for different datasets
self.allCursors = {} # cursors for different dataset
self.allIndices = {} # contains all truncated indices
self.allSampleLengths = {}
self.allUnits = {}
# self.settings.okButton.pressed.connect(self.settings.hide)
self.exitButton.triggered.connect(sys.exit)
self.settingsButton.triggered.connect(self.settings.show)
self.loadButton.triggered.connect(self.requestLoad)
self.addSceneButton.triggered.connect(self.addSceneToCombo)
self.showComboDataButton.triggered.connect(self.comboList.show)
self.calcPlotButton.triggered.connect(self.runCalcPlot)
self.calcPlotButton.setDisabled(True)
####
# connect cursors
self.plt.sigRangeChanged.connect(self.scaleCursors)
self.addPointButton.triggered.connect(self.addCursor)
self.removePointButton.triggered.connect(self.removeCursor)
self.drawCirclesButton.triggered.connect(self.plotMohrCircles)
# Finally enable the save button
self.saveButton.triggered.connect(self.save)
self.setStatus('Ready')
def showComboList(self):
self.comboList.show()
self.comboList.activateWindow()
def checkForLastDir(self):
'''
tries to open file 'lastdir'
if it exists, returns the contents,
else returns none
'''
try:
with open('lastdir','r') as f:
return f.read()
except IOError:
return ''
def makeLastDir(self,filename):
'''
gets directory name from file absolute path
create file 'lastdir' and writes
'''
with open('lastdir','w') as f:
f.write(os.path.dirname(filename))
def requestLoad(self):
'''
opens file manager, gets filename,
calls load
'''
self.lastdir = self.checkForLastDir()
# second par - name of file dialog window
# third parameter - default file name
# forth parameter - file filter. types separated by ';;'
filename = QtGui.QFileDialog.getOpenFileName(self, "",
"%s"%(self.lastdir), "*.clf;;MAT files (*.mat)")
self.load(filename)
def load(self,filename):
'''
opens file manager, reads data from file,
calls generateList to put into GUI
'''
headerexpr = self.settings.msWidget.getHeaderExpr()
slengthexpr = self.settings.msWidget.getSampleLengthExpr()
if filename[0] == '': return
if filename[1] == 'MAT files (*.mat)':
self.data = pymat.load(filename[0])
elif filename[1] == u'*.clf':
tup = readclf.readclf(filename[0],
headerexpr=headerexpr,
lengthexpr=slengthexpr)
if tup==None:
reply = QtGui.QMessageBox.warning(self,
'Wrong header',
BadHeaderMessage, QtGui.QMessageBox.Ok )
IOError('Cannot read this file.')
data,comments,length = tup
else: raise IOError('Cannot read this file format.')
# this is to remember this name when we wanna save file
self.makeLastDir(filename[0]) # extract filename from absolute path
self.filename = os.path.basename(filename[0])
# remove extension from name
self.filename = os.path.splitext(self.filename)[0]
# Separate all digital data and units
units = data['Units']
del data['Units']
self.data = data
# self.setParameters()
# self.connectParameters()
isNew = True
if self.filename in self.allData.keys():
isNew = False
self.allData[self.filename] = data
# get one name from array to get length of the data
key = data.keys()[0]
l = self.data[key].shape[0]
self.allSampleLengths[self.filename] = length
self.allIndices[self.filename] = np.arange(l)
self.allComments[self.filename] = comments
self.allUnits[self.filename] = units
self.addDataSet(self.filename,isNew)
def addDataSet(self,name,isNew=True):
print 'Modifying GUI: adding data set button'
if isNew:
dataSetButton = QtGui.QAction(name,self,checkable=True)
dataSetButton.setActionGroup(self.dataSetGroup)
dataSetButton.setChecked(True)
self.dataSetMenu.addAction(dataSetButton)
self.dataSetButtons[name] = dataSetButton
dataSetButton.triggered.connect(lambda: self.setCurrentDataSet(name))
self.allCursors[name] = []
self.setCurrentDataSet(name)
def setCurrentDataSet(self,name):
print 'New data set is chosen'
# if we switch to a different data set (if it's not the first),
# remember cursors for the old one
if self.currentDataSetName:
print 'Saving old data'
self.allIndices[self.currentDataSetName] = self.indices
self.allCursors[self.currentDataSetName] = self.cursors
self.allComments[self.currentDataSetName] = self.comments
print 'Setting new data'
# set current data dictionaries to new values
self.currentDataSetName = name
self.data = self.allData[name]
self.units = self.allUnits[name]
self.sampleLength = self.allSampleLengths[name]
self.indices = self.allIndices[name]
self.dataSetMenu.setDefaultAction(self.dataSetButtons[name])
self.cursors = self.allCursors[name]
self.comments = self.allComments[name]
self.setParameters()
self.connectParameters()
# self.mcSettings.setAvailableVariables(self.data.keys())
self.settings.mcWidget.setAvailableVariables(self.data.keys())
self.calcPlotButton.setDisabled(False)
if self.calcPlot.active:
print 'Calculator active'
self.calcPlot.setData(self.data)
self.updatePlot()
def save(self):
self.lastdir = self.checkForLastDir()
# second par - name of file dialog window
# third parameter - default file name
# forth parameter - file filter. types separated by ';;'
filename = pg.QtGui.QFileDialog.getSaveFileName(self,
"Save to MATLAB format", "%s%s"%(self.lastdir,self.currentDataSetName), "MAT files (*.mat)")
if filename[0] == '': return
pymat.save(filename[0],self.data)
def connectParameters(self):
'''
Makes new connection of list entries with plot after
loading a new dataset.
'Parameter' with name Time is default if it's in the list
Default Interval variable is set to Time
'''
# set default values for modifying parameters
self.modparams.param('Parameter').setValue(self.timeParam)
# self.modparams.param('Interval').setValue('Time')
# connect signals to updating functions
self.tree.sigStateChanged.connect(self.bindCursors)
self.tree.sigStateChanged.connect(self.updatePlot)
self.slider.sigRangeChanged.connect(self.truncate)
# self.modparams.param('Interval').sigValueChanged.connect(self.updatePlot)
self.modparams.param('min').sigValueChanged.connect(self.setTicks)
self.modparams.param('max').sigValueChanged.connect(self.setTicks)
self.modparams.param('Parameter').sigValueChanged.connect(self.updatePlot)
self.modparams.param('Plot vs.').sigValueChanged.connect(self.setMainAxis)
# connection with trend computations
self.tree.sigStateChanged.connect(self.setTrendParameter)
self.modparams.param('Parameter').sigValueChanged.connect(self.checkTrendUpdates)
self.modparams.param('Plot vs.').sigValueChanged.connect(self.setTrendParameter)
self.computeTrendFlag.sigValueChanged.connect(self.checkTrendUpdates)
self.trendParameter.sigValueChanged.connect(self.setTrendParameter)
# connect Null parameter
self.nullFlag.sigValueChanged.connect(self.updatePlot)
### enable cursors buttons
self.addPointButton.setEnabled(True)
self.removePointButton.setEnabled(True)
self.drawCirclesButton.setEnabled(True)
def addCursor(self):
print 'adding a Cursor'
viewrange = self.plt.viewRange()
# print viewrange
rangeX = [viewrange[0][0],viewrange[0][1]]
rangeY = [viewrange[1][0],viewrange[1][1]]
pos = [(rangeX[0] + rangeX[1])/2,(rangeY[0] + rangeY[1])/2]
xSize = float(rangeX[1]-rangeX[0])/50*800/self.plt.width()
ySize = float(rangeY[1]-rangeY[0])/50*800/self.plt.height()
Cursor = CursorItem.CursorItem(pos,[xSize,ySize],pen=(4,9))
self.cursors.append(Cursor)
self.allCursors[self.currentDataSetName] = self.cursors
# bind cursor if there is something to plot
plotlist = self.activeEntries()
if len(plotlist)>0:
self.bindCursors()
self.updatePlot()
def removeCursor(self):
if len(self.cursors)>0:
self.cursors.pop(-1)
self.updatePlot()
def plotMohrCircles(self):
global CirclesWidget
CirclesWidget = MohrCircles.MohrCircles()
params = self.settings.mcWidget.parameters()
b = params[3] # biot coef
names = []
PorePressure = []
AxialStress = []
ConfiningStress = []
ncircles = 0
for DataSet in self.allCursors.keys():
cursors = self.allCursors[DataSet]
data = self.allData[DataSet]
if cursors == []:
continue
else:
indices = []
for cursor in cursors:
indices.append(cursor.index)
ncircles += 1
Sig1 = data[params[0]][cursor.index] #axial stress
if params[1]=='0':
Pc = 0
else:
Pc = data[params[1]][cursor.index] # confining press
if params[2]=='0':
Pu = 0
else:
Pu = data[params[2]][cursor.index] # pore pressure
sigma1 = Sig1 - b*Pu
sigma3 = Pc - b*Pu
CirclesWidget.addData(max(sigma1,sigma3),min(sigma1,sigma3),name=DataSet +'_'+ str(ncircles))
if ncircles == 0: return 0
CirclesWidget.start()
CirclesWidget.show()
CirclesWidget.activateWindow()
def scaleCursors(self):
'''
make cursors circles of an appropriate size when scaling plot
'''
viewrange = self.plt.viewRange()
rangeX = [viewrange[0][0],viewrange[0][1]]
rangeY = [viewrange[1][0],viewrange[1][1]]
xSize = float(rangeX[1]-rangeX[0])/50*800/self.plt.width()
ySize = float(rangeY[1]-rangeY[0])/50*800/self.plt.height()
size = np.array([xSize,ySize])
for cursor in self.cursors:
oldSize = cursor.getSize() # workaround to force the cursor stay on the same place
cursor.translate(oldSize/2,snap=None)
cursor.setSize(size)
cursor.translate(-size/2,snap=None)
def drawCursors(self):
'''
add cursors again after clearing the plot window
'''
for cursor in self.cursors:
self.plt.addItem(cursor)
def bindCursors(self):
'''
make cursor slide along data
'''
# print self.sender()
try:
plotlist = self.activeEntries()
if self.mainAxis == 'y':
xlabel = plotlist[-1]
ylabel = self.modparams.param('Parameter').value()
elif self.mainAxis == 'x':
ylabel = plotlist[-1]
xlabel = self.modparams.param('Parameter').value()
x = self.data[xlabel][self.indices]
y = self.data[ylabel][self.indices]
for cursor in self.cursors:
cursor.setData(x,y)
except: pass
def checkTrendUpdates(self):
if self.computeTrendFlag.value():
self.computeTrend()
self.updatePlot()
def setTrendParameter(self):
entries = self.activeEntries()
for i in entries: pass
if entries != []: self.trendParameter.setValue(i)
self.checkTrendUpdates()
def truncate(self):
interval = self.slider.interval()
arr = self.data[self.sliderParam]
self.indices = (arr>=interval[0]) & (arr <= interval[1])
self.checkTrendUpdates()
self.updatePlot()
def setMainAxis(self):
self.mainAxis = self.modparams.param('Plot vs.').value()
self.updatePlot()
def updateLimits(self):
interval = self.slider.interval()
self.modparams.param('min').sigValueChanged.disconnect(self.setTicks)
self.modparams.param('max').sigValueChanged.disconnect(self.setTicks)
self.modparams.param('min').setValue(interval[0])
self.modparams.param('max').setValue(interval[1])
self.modparams.param('min').sigValueChanged.connect(self.setTicks)
self.modparams.param('max').sigValueChanged.connect(self.setTicks)
def setTicks(self):
'''
sets ticks to state coressponding to Interval min/max
values, when they are manually changed
'''
scale = self.data[self.sliderParam].max()
values = [float(self.modparams.param('min').value())/scale,
float(self.modparams.param('max').value())/scale
]
self.slider.setInterval(values)
self.updatePlot()
def updatePlot(self):
'''
updates plot
'''
self.setAxisScale()
self.updateLimits()
### Ready to update
# self.setAutoFillBackground(True)
self.clearPlotWindow()
self.drawCursors()
self.plt.showGrid(x=True, y=True)
if self.mainAxis == 'x':
self.plotVersusX()
if self.mainAxis == 'y':
self.plotVersusY()
if self.computeTrendFlag.value():
self.plotTrend()
if self.calcPlot.active:
self.calcPlot.indices = self.indices
self.calcPlot.plot()
def plotVersusX(self):
'''
plot when we have sevaral y's versus of x.
'''
# Get variables to plot
data = self.data
plotlist = self.activeEntries()
xlabel = self.modparams.param('Parameter').value()
null = self.nullFlag.value()
for i in range(len(plotlist)):
ylabel = plotlist[i]
color = self.tree.colors[ylabel].getColor()
linestyle = pg.mkPen(color=color, width=3)
yunits = self.units[ylabel]
xdata = data[xlabel][self.indices]
ydata = data[ylabel][self.indices]
if null: ydata -= ydata[0]
self.plt.plot(xdata, ydata,
pen=linestyle, name=plotlist[i])
self.plt.setLabel('left', plotlist[i],units=yunits,
**AxisLabelStyle)
xunits = self.units[xlabel]
self.plt.setLabel('bottom', xlabel,units=xunits,**AxisLabelStyle)
# if len(plotlist)>0: self.bindCursors(data[xlabel],data[ylabel])
def plotVersusY(self):
'''
plot when we have sevaral y's versus of x.
'''
# Get variables to plot
data = self.data
plotlist = self.activeEntries()
ylabel = self.modparams.param('Parameter').value()
yunits = self.units[ylabel]
null = self.nullFlag.value()
for i in range(len(plotlist)):
xlabel = plotlist[i]
color = self.tree.colors[xlabel].getColor()
linestyle = pg.mkPen(color=color, width=3)
xunits = self.units[xlabel]
xdata = data[xlabel][self.indices]
ydata = data[ylabel][self.indices]
if null: xdata -= xdata[0]
self.plt.plot(xdata, ydata,
pen=linestyle, name=plotlist[i])
self.plt.setLabel('bottom', xlabel,units=xunits,**AxisLabelStyle)
self.plt.setLabel('left', ylabel,units=yunits,**AxisLabelStyle)
def plotTrend(self):
'''
plots linear trend
'''
if self.mainAxis == 'x':
xpar = self.modparams.param('Parameter').value()
ypar = self.trendParameter.value()
self.plt.setLabel('bottom', xpar)
if self.mainAxis == 'y':
xpar = self.trendParameter.value()
ypar = self.modparams.param('Parameter').value()
x = self.data[xpar][self.indices]
y = self.slope*x + self.intersection
self.plt.plot(x,y,pen=TrendPen, name='%s Trend'%(self.trendParameter.value()))
self.plt.setLabel('bottom', xpar)
self.plt.setLabel('left', ypar)
def clearPlotWindow(self):
'''
clears plot from data. clears legend.
if there is no legend creates it
'''
# default legend position
position = [30,30]
# clear plot area
self.plt.clear()
# remove old legend
if self.legend:
position = self.legend.pos()
self.legend.scene().removeItem(self.legend)
# creadte new legend
self.plt.addLegend([90,20],offset=position)
self.legend = self.plt.legend
def setAxisScale(self):
'''
sets scale to the interval axis. if time, sets minimum value to 0,
because it could have been cleared
'''
# interval_parameter = self.modparams.param('Interval').value()
interval_parameter = self.sliderParam
if interval_parameter == self.timeParam:
self.slider.setRange(0,max(self.data[self.timeParam]))
else:
self.slider.setRange(min(self.data[interval_parameter]),max(self.data[interval_parameter]))
def activeEntries(self):
'''
returns a list of active entries in the data bar
'''
plotlist = []
# for i in self.data.keys():
# if self.params.param(i).value() == True:
for item in self.data.keys():
if self.tree.boxes[item].value() == True:
plotlist.append(item)
return plotlist
def setParameters(self):
print 'Modifying GUI: adding parameters to plot'
# set modifying parameters
self.modparamlist = ModifyingParameters
self.modparamlist[1]['values'] = self.data.keys() # Parameter
# self.modparamlist[2]['values'] = self.data.keys() # Interval
self.modparamlist[5]['children'][1]['values'] = self.data.keys() # Trend parameter
# create parameter class instances()
# self.params = Parameter.create(name='Data', type='group',children=self.paramlist)
self.modparams = Parameter.create(name='Options', type='group',children=self.modparamlist)
self.tree.clear()
self.tree.addItems(self.data.keys(),DataViewerTreeColors)
# self.tree.setParameters(self.params, showTop=True)
self.modtree.setParameters(self.modparams, showTop=True)
self.assignAttributes() # to get shorter names
def assignAttributes(self):
'''
assign parameters from modparams tree to class DataViewer
attributes to shorten code
'''
self.nullFlag = self.modparams.param('Null')
# assign chilren of 'Linear Trend' group to class attributes
self.computeTrendFlag = self.modparams.param('Linear Trend').children()[0]
self.trendParameter = self.modparams.param('Linear Trend').children()[1]
self.trendSlope = self.modparams.param('Linear Trend').children()[2]
self.trendIntersection = self.modparams.param('Linear Trend').children()[3]
def setupGUI(self):
pg.setConfigOption('background', (255,255,255))
pg.setConfigOption('foreground',(0,0,0))
self.setWindowIcon(QtGui.QIcon('images/Logo.png'))
# Global widget where we place our layout
self.layout = QtGui.QVBoxLayout()
self.layout.setContentsMargins(0,0,0,0)
self.layout.setSpacing(0)
self.setLayout(self.layout)
# Create and add menu bar
self.menuBar = QtGui.QMenuBar()
self.fileMenu = self.menuBar.addMenu('File')
self.viewMenu = self.menuBar.addMenu('View')
self.dataSetMenu = self.menuBar.addMenu('Dataset')
self.mohrMenu = self.menuBar.addMenu('Mohr\' Circles')
self.comboPlotMenu = self.menuBar.addMenu('Combo plot')
self.prefMenu = self.menuBar.addMenu('Preferences')
self.dataSetGroup = QtGui.QActionGroup(self)
# create status bar
self.layout.addWidget(self.menuBar,0)
self.layout.setMenuBar(self.menuBar)
# create submenu items
self.loadButton = QtGui.QAction('Load',self)
self.saveButton = QtGui.QAction('Save',self)
self.exitButton = QtGui.QAction('Exit',self,shortcut="Alt+F4")
self.calcPlotButton = QtGui.QAction('Calculator',self)
self.autoScaleButton = QtGui.QAction('Auto scale',self)
self.addPointButton = QtGui.QAction('Add point',self,shortcut='Ctrl+Q')
self.removePointButton = QtGui.QAction('Remove point',self,shortcut='Ctrl+R')
self.drawCirclesButton = QtGui.QAction('Draw Mohr\'s Circles',self,shortcut='Alt+M')
self.showComboDataButton = QtGui.QAction('Show',self,shortcut='Ctrl+Shift+C')
self.addSceneButton = QtGui.QAction('Add scene',self,shortcut='Ctrl+C')
self.settingsButton = QtGui.QAction('Settings',self)
self.addPointButton.setEnabled(False)
self.removePointButton.setEnabled(False)
self.drawCirclesButton.setEnabled(False)
# Add buttons to submenus
self.fileMenu.addAction(self.loadButton)
self.fileMenu.addAction(self.saveButton)
self.fileMenu.addAction(self.exitButton)
self.mohrMenu.addAction(self.addPointButton)
self.mohrMenu.addAction(self.removePointButton)
self.mohrMenu.addAction(self.drawCirclesButton)
self.viewMenu.addAction(self.calcPlotButton)
self.viewMenu.addAction(self.autoScaleButton)
self.comboPlotMenu.addAction(self.showComboDataButton)
self.comboPlotMenu.addAction(self.addSceneButton)
self.prefMenu.addAction(self.settingsButton)
# splitter is a widget, which handles the layout
# it splits the main window into parameter window
# and the plotting area
self.splitter = QtGui.QSplitter()
self.splitter.setOrientation(QtCore.Qt.Horizontal)
self.layout.addWidget(self.splitter)
# tree is a list of parameters to plot
self.tree = CParameterTree.CParameterTree(name='Data')
# modtree is a list of governing parameters to modify plot
self.modtree = ParameterTree(showHeader=False)
# sublayout is were we place our plot and slider
self.sublayout = pg.GraphicsLayoutWidget()
# treesplitter splits parameter window into 2 halfs
self.treesplitter = QtGui.QSplitter()
self.buttonsplitter = QtGui.QSplitter()
self.treesplitter.setOrientation(QtCore.Qt.Vertical)
self.treesplitter.addWidget(self.tree)
self.treesplitter.addWidget(self.modtree)
self.treesplitter.setSizes([int(self.height()*0.7),
int(self.height()*0.3),
20])
self.treesplitter.setStretchFactor(0, 0)
self.treesplitter.setStretchFactor(1, 0.9)
self.splitter.addWidget(self.treesplitter)
self.splitter.addWidget(self.sublayout)
self.splitter.setSizes([int(self.width()*0.4), int(self.width()*0.6)])
self.splitter.setStretchFactor(0, 0)
self.splitter.setStretchFactor(1, 1)
self.plt = self.sublayout.addPlot()
setup_plot(self.plt)
self.plt.setLabel('bottom', 'X Axis',**AxisLabelStyle)
self.plt.setLabel('left', 'Y Axis',**AxisLabelStyle)
self.plt.enableAutoRange(enable=True)
self.autoScaleButton.triggered.connect(self.plt.enableAutoRange)
# self.slider = self.createSlider()
self.slider = SliderWidget()
self.sublayout.nextRow()
self.sublayout.addItem(self.slider)
self.sublayout.nextRow()
self.statusBar = QtGui.QStatusBar()
self.treesplitter.addWidget(self.statusBar)
self.setGeometry(80, 50, 800, 600)
self.treesplitter.setStretchFactor(2, 0)
self.treesplitter.setCollapsible(2, 0)
self.statusBar.setSizePolicy(QtGui.QSizePolicy.Ignored,
QtGui.QSizePolicy.Fixed)
self.setGeometry(80, 30, 1000, 700)
def setStatus(self,message):
self.statusBar.showMessage(message)
print message
def computeTrend(self):
'''
computer linear trend a and b and
from truncated data.
'''
if self.mainAxis == 'x': # if multiple plots vs x
xpar = self.modparams.param('Parameter').value()
ypar = self.trendParameter.value()
if self.mainAxis == 'y': # if multiple plots vs y
ypar = self.modparams.param('Parameter').value()
xpar = self.trendParameter.value()
x = self.data[xpar][self.indices]
y = self.data[ypar][self.indices]
A = np.array([x, np.ones(len(y))]).T
## Solves the equation a x = b by computing a vector x that
## minimizes the Euclidean 2-norm || b - a x ||^2.
self.slope,self.intersection = np.linalg.lstsq(A,y)[0]
self.trendSlope.setValue(self.slope)
self.trendIntersection.setValue(self.intersection)
def createSlider(self):
slider = pg.GradientEditorItem(orientation='top', allowAdd=False)
# print slider.__dict__
# slider.tickPen = pg.mkPen(color=(255,255,255))
slider.tickSize = 0
# print slider.gradRect
slider.rectSize = 0
for i in slider.ticks:
slider.setTickColor(i, QtGui.QColor(150,150,150))
return slider
def closeEvent(self,event):
'''
When pressing X button, show quit dialog.
if yes, closes the window and ends the process
'''
# reply = QtGui.QMessageBox.question(self, 'Quit Dataviewer',
# "Are you sure to quit?", QtGui.QMessageBox.Yes |
# QtGui.QMessageBox.No, QtGui.QMessageBox.No)
# if reply == QtGui.QMessageBox.Yes:
# sys.exit()
# event.accept()
# else:
# event.ignore()
sys.exit()
def addSceneToCombo(self):
print 'adding scene to Combo plot'
rootname = self.currentDataSetName
for item in self.plt.listDataItems():
name = rootname+'_'+item.name()
x = item.xData
y = item.yData
self.comboList.addItem(name,x,y)
def runCalcPlot(self):
self.calcPlot.active = True
self.calcPlot.setData(self.data)
self.calcPlot.show()
self.calcPlot.activateWindow()
