def __init__(self, view, uistack):
self._view = view
self._view.start.clicked.connect(self.start)
self._view.pause.clicked.connect(self.pause)
self._view.load.clicked.connect(self.load)
self._view.save.clicked.connect(self.save)
self._view.done.clicked.connect(self.done)
self._model = PrehistorySimulation(5, 1.0, 3, 23)
self._worker = SimThread(self._model)
self._worker.tick.connect(self.tick)
self._worker.simstarted.connect(self.started)
self._worker.simstopped.connect(self.stopped)
self._ticks = 0
self._worker.start()
self._display = PrehistoryDisplay(self._model)
self._view.content.setLayout(QGridLayout())
self._view.content.layout().addWidget(self._display)
self._view.rotate.setValue(self._display.rotate)
self._view.rotate.sliderMoved.connect(self.rotate)
self._view.pause.setVisible(False)
self._uistack = uistack
def __init__(self, view, uistack, listitemclass):
self._view = view
self._view.start.clicked.connect(self.start)
self._view.pause.clicked.connect(self.pause)
self._view.done.clicked.connect(self.done)
self._view.load.clicked.connect(self.load)
self._view.save.clicked.connect(self.save)
self._model = PlanetSimulation(6400, 6, 1.0, 3, 23, 1.145, 5, 125, 125)
self._worker = SimThread(self._model)
self._worker.tick.connect(self.tick)
self._worker.simstarted.connect(self.started)
self._worker.simstopped.connect(self.stopped)
self._ticks = 0
self._worker.start()
self._display = PlanetDisplay(self._model, self.selecttile)
self._view.continents.setNum(self._model.continents)
self._view.percent.setNum(self._model.land)
self._view.content.setLayout(QGridLayout())
self._view.content.layout().addWidget(self._display)
self._listitemclass = listitemclass
self._view.rotate.setValue(self._display.rotate)
self._view.rotate.sliderMoved.connect(self.rotate)
self._view.aspect.setCurrentIndex(self._display.aspect)
self._view.aspect.currentIndexChanged[int].connect(self.aspect)
self._view.pause.setVisible(False)
self._uistack = uistack
def __init__(self, parent = None):
'''
Constructor
'''
QMainWindow.__init__(self, parent)
self.setupUi(self)
# helper vars
self.simThread = SimThread(mainwindow=self)
self.sources = []
self.module = None
self.detector = None
self.allRays = []
self.simulationSessionStarted = False
self.tableItemChanging = False
self.figures = []
self.colors = ['white','red','green','blue','yellow','light blue','magenta','black']
self.colorsRGB = [[1,1,1],
[1,0,0],
[0,1,0],
[0,0,1],
[1,1,0],
[0,1,1],
[1,0,1],
[0,0,0]]
# setup connections
self.connect(self.actionAbout_FOXSISIM_2, SIGNAL('triggered()'),self.about)
self.sourceSignalMapper = QSignalMapper() # needed to map combobox signals to table widget slots
self.connect(self.sourceSignalMapper,SIGNAL('mapped(int)'),self.tableWidget_2_sourceTypeChanged)
self.connect(self.tabWidget, SIGNAL('currentChanged(int)'),self.tabWidget_currentChanged)
self.connect(self.tableWidget, SIGNAL('itemChanged(QTableWidgetItem *)'), self.tableWidget_itemChanged)
self.connect(self.tableWidget_2, SIGNAL('itemChanged(QTableWidgetItem *)'), self.tableWidget_2_itemChanged)
self.connect(self.toolButton, SIGNAL('clicked()'), self.toolButton_clicked)
self.connect(self.toolButton_2, SIGNAL('clicked()'), self.toolButton_2_clicked)
self.connect(self.toolButton_3, SIGNAL('clicked()'), self.toolButton_3_clicked)
self.connect(self.toolButton_4, SIGNAL('clicked()'), self.toolButton_4_clicked)
self.connect(self.toolButton_5, SIGNAL('clicked()'), self.toolButton_5_clicked)
self.connect(self.toolButton_6, SIGNAL('clicked()'), self.toolButton_6_clicked)
self.connect(self.toolButton_7, SIGNAL('clicked()'), self.toolButton_7_clicked)
self.connect(self.toolButton_8, SIGNAL('clicked()'), self.toolButton_8_clicked)
self.connect(self.doubleSpinBox, SIGNAL('valueChanged(double)'), self.doubleSpinBox_valueChanged)
self.connect(self.pushButton, SIGNAL('clicked()'), self.pushButton_clicked)
self.connect(self.pushButton_2, SIGNAL('clicked()'), self.pushButton_2_clicked)
self.connect(self.pushButton_3, SIGNAL('clicked()'), self.pushButton_3_clicked)
self.connect(self.pushButton_4, SIGNAL('clicked()'), self.pushButton_4_clicked)
self.connect(self.pushButton_5, SIGNAL('clicked()'), self.pushButton_5_clicked)
self.connect(self.pushButton_6, SIGNAL('clicked()'), self.pushButton_6_clicked)
self.connect(self, SIGNAL('startSimulation'), self.simThread.start)
self.connect(self.simThread, SIGNAL('updateSimulationProgress'), self.updateSimulationProgress)
self.connect(self.simThread, SIGNAL('simulationStarted'), self.simulationStarted)
self.connect(self.simThread, SIGNAL('simulationDone'), self.simulationDone)
self.connect(self.spinBox, SIGNAL('valueChanged(int)'), self.updateRaysToSimulate)
self.connect(self, SIGNAL('updateRaysToSimulate'), self.updateRaysToSimulate)
# set defaults
self.setModuleDefaults()
self.setSourceDefaults()
def create(self, gridsize=None):
if self._model is not None:
self._worker.stop()
self._worker.wait()
layout = self._view.content.layout()
if layout.count():
layout.removeItem(layout.itemAt(0))
if self._view.randomize.checkState() == Qt.Checked:
# Randomize values, but favor Earth-like ones.
self._view.spin.setCurrentIndex(random.choice([0,1,1,2,2,2,3,3]))
self._view.tilt.setValue(randomspinvalue(self._view.tilt, 23))
self._view.land.setValue(randomspinvalue(self._view.land, 29))
self._view.atmt.setValue(randomtime())
self._view.lifet.setValue(randomtime())
self._view.peoplet.setValue(randomtime())
r, g = self.radii_and_grid_sizes[self._view.radius.currentIndex()]
land_r = math.sqrt(0.04 * self._view.land.value())
self._model = WorldSimulation(r, gridsize or g, self.day_hours[self._view.spin.currentIndex()], self._view.tilt.value(), land_r, self._view.atmt.value(), self._view.lifet.value(), self._view.peoplet.value())
self._worker = SimThread(self._model)
self._worker.tick.connect(self.tick)
self._worker.simstarted.connect(self.started)
self._worker.simstopped.connect(self.stopped)
self._worker.start()
self._display = WorldDisplay(self._model, self.selecttile)
self._view.content.setLayout(QGridLayout())
self._view.content.layout().addWidget(self._display)
self._view.rotate.setValue(self._display.rotate)
self._view.rotate.sliderMoved.connect(self.rotate)
self._view.aspect.setCurrentIndex(self._display.aspect)
self._view.aspect.currentIndexChanged[int].connect(self.aspect)
self._view.start.setVisible(True)
self._view.start.setEnabled(True)
self._view.pause.setVisible(False)
self._view.done.setEnabled(True)
class MainWindow(QMainWindow, Ui_MainWindow):
'''
classdocs
'''
def __init__(self, parent = None):
'''
Constructor
'''
QMainWindow.__init__(self, parent)
self.setupUi(self)
# helper vars
self.simThread = SimThread(mainwindow=self)
self.sources = []
self.module = None
self.detector = None
self.allRays = []
self.simulationSessionStarted = False
self.tableItemChanging = False
self.figures = []
self.colors = ['white','red','green','blue','yellow','light blue','magenta','black']
self.colorsRGB = [[1,1,1],
[1,0,0],
[0,1,0],
[0,0,1],
[1,1,0],
[0,1,1],
[1,0,1],
[0,0,0]]
# setup connections
self.connect(self.actionAbout_FOXSISIM_2, SIGNAL('triggered()'),self.about)
self.sourceSignalMapper = QSignalMapper() # needed to map combobox signals to table widget slots
self.connect(self.sourceSignalMapper,SIGNAL('mapped(int)'),self.tableWidget_2_sourceTypeChanged)
self.connect(self.tabWidget, SIGNAL('currentChanged(int)'),self.tabWidget_currentChanged)
self.connect(self.tableWidget, SIGNAL('itemChanged(QTableWidgetItem *)'), self.tableWidget_itemChanged)
self.connect(self.tableWidget_2, SIGNAL('itemChanged(QTableWidgetItem *)'), self.tableWidget_2_itemChanged)
self.connect(self.toolButton, SIGNAL('clicked()'), self.toolButton_clicked)
self.connect(self.toolButton_2, SIGNAL('clicked()'), self.toolButton_2_clicked)
self.connect(self.toolButton_3, SIGNAL('clicked()'), self.toolButton_3_clicked)
self.connect(self.toolButton_4, SIGNAL('clicked()'), self.toolButton_4_clicked)
self.connect(self.toolButton_5, SIGNAL('clicked()'), self.toolButton_5_clicked)
self.connect(self.toolButton_6, SIGNAL('clicked()'), self.toolButton_6_clicked)
self.connect(self.toolButton_7, SIGNAL('clicked()'), self.toolButton_7_clicked)
self.connect(self.toolButton_8, SIGNAL('clicked()'), self.toolButton_8_clicked)
self.connect(self.doubleSpinBox, SIGNAL('valueChanged(double)'), self.doubleSpinBox_valueChanged)
self.connect(self.pushButton, SIGNAL('clicked()'), self.pushButton_clicked)
self.connect(self.pushButton_2, SIGNAL('clicked()'), self.pushButton_2_clicked)
self.connect(self.pushButton_3, SIGNAL('clicked()'), self.pushButton_3_clicked)
self.connect(self.pushButton_4, SIGNAL('clicked()'), self.pushButton_4_clicked)
self.connect(self.pushButton_5, SIGNAL('clicked()'), self.pushButton_5_clicked)
self.connect(self.pushButton_6, SIGNAL('clicked()'), self.pushButton_6_clicked)
self.connect(self, SIGNAL('startSimulation'), self.simThread.start)
self.connect(self.simThread, SIGNAL('updateSimulationProgress'), self.updateSimulationProgress)
self.connect(self.simThread, SIGNAL('simulationStarted'), self.simulationStarted)
self.connect(self.simThread, SIGNAL('simulationDone'), self.simulationDone)
self.connect(self.spinBox, SIGNAL('valueChanged(int)'), self.updateRaysToSimulate)
self.connect(self, SIGNAL('updateRaysToSimulate'), self.updateRaysToSimulate)
# set defaults
self.setModuleDefaults()
self.setSourceDefaults()
def closeEvent(self, event):
'''
Performs shutdown tasks
'''
for fig in self.figures:
fig.close()
event.accept()
def about(self):
'''
Calls a message box displaying the 'About'
'''
QMessageBox.about(self, 'About FOXSISIM',
u'''FOXSISIM
Copyright \N{COPYRIGHT SIGN} 2011 Robert Taylor, Steven Christe
The FOXSI Optics Simulation Tool (foxsisim) is a python tool to simulate grazing incidence optics response to light sources of different wavelengths. This graphical user interface is a frontend for the foxsisim module.''')
def setModuleDefaults(self):
'''
Sets all default values in Module tab
'''
# spin boxes
self.doubleSpinBox.setValue(defaultFocalLength)
self.doubleSpinBox_2.setValue(defaultSegmentLength)
self.doubleSpinBox_3.setValue(defaultDetectorOffset)
self.doubleSpinBox_4.setValue(defaultDetectorWidth)
self.doubleSpinBox_5.setValue(defaultDetectorHeight)
self.spinBox_2.setValue(defaultDetectorReso[0])
self.spinBox_3.setValue(defaultDetectorReso[1])
# module radii/angle table
self.tableWidget.setRowCount(len(defaultRadii))
for i,radius in enumerate(defaultRadii):
r = QString.number(radius,precision=precision)
self.tableWidget.setItem(i,0,QTableWidgetItem(r)) # angle is autofilled by tableWidget_itemChanged()
def setSourceDefaults(self):
'''
Sets all defaults in Sources tab
'''
# source table
self.insertSourceRow(0)
type = self.tableWidget_2.cellWidget(0,0)
type.setCurrentIndex(type.findText(defaultSourceType))
center = QString(str(defaultSourceCenter[0])+','+str(defaultSourceCenter[1])+','+str(defaultSourceCenter[2]))
self.tableWidget_2.setItem(0,1,QTableWidgetItem(center))
self.tableWidget_2.setItem(0,3,QTableWidgetItem(QString.number(defaultSourceWidth,precision=precision)))
self.tableWidget_2.setItem(0,4,QTableWidgetItem(QString.number(defaultSourceHeight,precision=precision)))
color = self.tableWidget_2.cellWidget(0,5)
color.setCurrentIndex(color.findText(defaultSourceColor))
def insertModuleRow(self, i):
'''
Insert a row into the module radii/angles table
'''
self.tableWidget.blockSignals(True) # no signals emitted during row creation
self.tableWidget.insertRow(i)
self.tableWidget.setItem(i,0,QTableWidgetItem(QString('')))
self.tableWidget.setItem(i,1,QTableWidgetItem(QString('')))
self.tableWidget.blockSignals(False)
def insertSourceRow(self, i):
'''
Insert a row into the sources table
'''
self.tableWidget_2.blockSignals(True) # no signals emitted during row creation
self.tableWidget_2.insertRow(i)
type = QComboBox()
type.addItems(['atinf', 'point', 'nonpoint'])
color = QComboBox()
color.addItems(self.colors)
self.tableWidget_2.setCellWidget(i,0,type)
self.tableWidget_2.setItem(i,1,QTableWidgetItem(QString('')))
self.tableWidget_2.setItem(i,2,QTableWidgetItem(QString('')))
self.tableWidget_2.setItem(i,3,QTableWidgetItem(QString('')))
self.tableWidget_2.setItem(i,4,QTableWidgetItem(QString('')))
self.tableWidget_2.setCellWidget(i,5,color)
self.tableWidget_2.blockSignals(False)
# connect signal from the type widget to the mapper which then will emit a 'mapped(i)' signal
self.connect(type,SIGNAL('currentIndexChanged(int)'),self.sourceSignalMapper,SLOT('map()'))
self.updateSourceSignalMapper()
def updateSourceSignalMapper(self):
'''
Ensures the signal mappings are all correct
'''
for i in range(self.tableWidget_2.rowCount()):
type = self.tableWidget_2.cellWidget(i,0)
self.sourceSignalMapper.removeMappings(type)
self.sourceSignalMapper.setMapping(type,i)
def createModule(self):
'''
Returns a Module object based on gui input values
'''
# get radii and angles
radii,angles = [],[]
for i in range(self.tableWidget.rowCount()):
r,rvalid = self.tableWidget.item(i,0).text().toDouble()
a,avalid = self.tableWidget.item(i,1).text().toDouble()
if rvalid and avalid:
radii.append(r)
angles.append(a)
# radii need to be in decending order
import operator
indices = [i for (i,j) in sorted(enumerate(radii), key=operator.itemgetter(1), reverse=True)] #@UnusedVariable
radii = [radii[i] for i in indices]
angles = [angles[i] for i in indices]
# get other value
seglen = self.doubleSpinBox_2.value()
focal = self.doubleSpinBox.value()
# return module
try: return Module(seglen=seglen,focal=focal,radii=radii,angles=angles)
except:
QMessageBox.warning(self,'Warning','Could not create module. Check input values.')
return None
def createDetector(self):
'''
Returns a Detector object based on gui input values
'''
focal = self.doubleSpinBox.value()
seglen = self.doubleSpinBox_2.value()
offset = self.doubleSpinBox_3.value()
center = [0,0,focal+seglen+offset]
width = self.doubleSpinBox_4.value()
height = self.doubleSpinBox_5.value()
reso = [self.spinBox_2.value(),self.spinBox_3.value()]
try: return Detector(center=center, width=width, height=height, reso=reso)
except:
QMessageBox.warning(self,'Warning','Could not create detector. Check input values.')
return None
def createSource(self, row):
'''
Returns a Source object from row i in the sources table
'''
# get input
type = str(self.tableWidget_2.cellWidget(row,0).currentText())
center = self.str2List(self.tableWidget_2.item(row,1).text())
normal = self.str2List(self.tableWidget_2.item(row,2).text())
width = self.str2Num(self.tableWidget_2.item(row,3).text())
height= self.str2Num(self.tableWidget_2.item(row,4).text())
colorText = str(self.tableWidget_2.cellWidget(row,5).currentText())
color = self.colorsRGB[self.colors.index(colorText)]
try:
if type == 'atinf' or type == 'nonpoint':
return Source(center=center, width=width, height=height, normal=normal, type=type, color=color)
elif type == 'point':
return Source(center=center, type=type, color=color)
except:
QMessageBox.warning(self,'Warning','Could not create source at row '+str(row+1)+'. Check input values.')
return None
def tabWidget_currentChanged(self, index):
'''
Slot for tab change in tabWidget.
'''
# if we arent in the middle of simulation session
if not self.simulationSessionStarted:
# update module/detector/sources
if index != 0:
self.module = self.createModule()
self.detector = self.createDetector()
if index != 1:
self.sources = []
for row in range(self.tableWidget_2.rowCount()):
source = self.createSource(row)
if source is not None: self.sources.append(source)
# update source list for scatterplot
if index == 2:
self.listWidget.clear()
for source in self.sources:
self.listWidget.addItem(QString(source.type+' at ['+self.list2Str(source.center)+']'))
self.listWidget.selectAll()
# update 'rays to simulate'
if index == 2: self.emit(SIGNAL('updateRaysToSimulate'))
def tableWidget_itemChanged(self,item):
'''
Slot for item change in module radii/angles table
'''
# prevent infinite recursion
if self.tableItemChanging: return
self.tableItemChanging = True
# get location
row = item.row()
col = item.column()
# get double float
if len(item.text()) > 0:
number,valid = item.text().toDouble()
if not valid:
QMessageBox.warning(self,'Warning','Invalid input')
item.setText('')
number = None
else: number = None
# if autocalculation is checked
if self.checkBox.isChecked():
if number is None: # set the other column to none
self.tableWidget.setItem(row,(col+1)%2,QTableWidgetItem(''))
elif col == 0: # radius changed
focal = self.doubleSpinBox.value()
angle = calcShellAngle(number,focal)
item = QTableWidgetItem(QString.number(angle,precision=precision))
self.tableWidget.setItem(row,1,item)
elif col == 1: # angle changed
focal = self.doubleSpinBox.value()
radius = calcShellRadius(number,focal)
item = QTableWidgetItem(QString.number(radius,precision=precision))
self.tableWidget.setItem(row,0,item)
else: # invalid index
print('error: update tableWidget_itemChanged method')
# reset the recursion preventer
self.tableItemChanging = False
def tableWidget_2_sourceTypeChanged(self,row):
'''
Slot for value change in type combo box in sources table
'''
pass
def tableWidget_2_itemChanged(self,item):
'''
Slot for item change in sources table
'''
# prevent infinite recursion
if self.tableItemChanging: return
self.tableItemChanging = True
# get location and row items
row = item.row()
col = item.column()
typeWidget = self.tableWidget_2.cellWidget(row,0)
centerItem = self.tableWidget_2.item(row,1)
normalItem = self.tableWidget_2.item(row,2)
widthItem = self.tableWidget_2.item(row,3)
heightItem = self.tableWidget_2.item(row,4)
#colorWidget = self.tableWidget_2.cellWidget(row,5)
type = typeWidget.currentText()
center = self.str2List(centerItem.text())
normal = self.str2List(normalItem.text())
width = self.str2Num(widthItem.text())
height = self.str2Num(heightItem.text())
#color = colorWidget.currentText()
# check validity of entire row's input
invalidInput = False
if len(centerItem.text()) > 0 and (center is None or len(center) != 3):
center = None
invalidInput = True
if len(normalItem.text()) > 0 and (normal is None or len(normal) != 3):
normal = None
invalidInput = True
if len(widthItem.text()) > 0 and (width is None or width < 0):
width = None
invalidInput = True
if len(heightItem.text()) > 0 and (height is None or height < 0):
height = None
invalidInput = True
if invalidInput: QMessageBox.warning(self,'Warning','Invalid input')
# if autocalculation is checked
if self.checkBox_2.isChecked():
if col == 1 and center is not None: # center changed
normal = [-x for x in center]
elif col == 2 and normal is not None: # normal changed
center = [-x for x in normal]
# source width/height is autocalculated when atinf
if type == QString('atinf') and normal is not None and normal[2] > 0:
ny = np.array([normal[0],0,normal[2]])
ang = angleBetweenVectors(ny,np.array([0,0,1]))
try: dims = self.module.getDims()
except: dims = self.createModule().getDims()
radius = dims[0] # radius at wide end of module
width = 2*radius*cos(ang)
height = 2*radius # TODO: find the proper way to calculate this
# check that center is in negative z region
if center is not None and center[2] >= 0:
QMessageBox.warning(self,'Warning','Source center point should have a negative z value')
# change items
self.tableWidget_2.setItem(row,1,QTableWidgetItem(self.list2Str(center)))
self.tableWidget_2.setItem(row,2,QTableWidgetItem(self.list2Str(normal)))
self.tableWidget_2.setItem(row,3,QTableWidgetItem(self.num2Str(width)))
self.tableWidget_2.setItem(row,4,QTableWidgetItem(self.num2Str(height)))
# reset the recursion preventer
self.tableItemChanging = False
def str2Num(self,str):
'''
Takes a QString and returns a double
'''
if str == QString(''): return None
num,valid = str.toDouble()
if not valid: return None
return num
def num2Str(self,num):
'''
Takes a number and returns a string
'''
if num is None: return QString('')
return QString.number(num,precision=precision)
def str2List(self,str):
'''
Takes a string of from 'x,y,z' and returns list [x,y,z]
'''
try:
arr = str.split(',')
return [float(s) for s in arr]
except: return None
def list2Str(self,list):
'''
Takes a list of form [x,y,z] and returns string 'x,y,z'
'''
if list is None: return QString('') # return empty string if None is passed
arr = [QString.number(x,precision=precision)+',' for x in list]
arr[-1].remove(-1,1)
arr = [str(q) for q in arr]
return ''.join(arr)
def toolButton_clicked(self):
'''
Slot for toolButton. Adds a row to the sources table.
'''
row = self.tableWidget_2.rowCount()
self.insertSourceRow(row)
self.updateSourceSignalMapper()
def toolButton_2_clicked(self):
'''
Slot for toolButton_2. Removes a row from the sources table.
'''
row = self.tableWidget_2.currentRow()
if row < 0:
row = self.tableWidget_2.rowCount()-1
self.sourceSignalMapper.removeMappings(self.tableWidget_2.cellWidget(row,0))
self.tableWidget_2.removeRow(row)
self.updateSourceSignalMapper()
def toolButton_3_clicked(self):
'''
Slot for toolButton_3. Adds a row to the module radii/angles table.
'''
row = self.tableWidget.rowCount()
self.insertModuleRow(row)
def toolButton_4_clicked(self):
'''
Slot for toolButton_4. Removes a row from the module radii/angles table.
'''
row = self.tableWidget.currentRow()
if row < 0:
row = self.tableWidget.rowCount()-1
self.tableWidget.removeRow(row)
def toolButton_5_clicked(self):
'''
Slot for toolButton_5. Moves a row up in the module radii/angles table.
'''
row = self.tableWidget.currentRow()
if row > 0 and row < self.tableWidget.rowCount():
self.insertModuleRow(row+1)
self.tableWidget.setItem(row+1,0,self.tableWidget.item(row-1,0).clone())
self.tableWidget.setItem(row+1,1,self.tableWidget.item(row-1,1).clone())
self.tableWidget.removeRow(row-1)
def toolButton_6_clicked(self):
'''
Slot for toolButton_6. Moves a row down in the module radii/angles table.
'''
row = self.tableWidget.currentRow()
col = self.tableWidget.currentColumn()
if row >= 0 and row+1 < self.tableWidget.rowCount():
self.insertModuleRow(row+2)
self.tableWidget.setItem(row+2,0,self.tableWidget.item(row,0).clone())
self.tableWidget.setItem(row+2,1,self.tableWidget.item(row,1).clone())
self.tableWidget.removeRow(row)
self.tableWidget.setCurrentCell(row+1,col)
def toolButton_7_clicked(self):
'''
Slot for toolButton_7. Moves a row up in the sources table.
'''
row = self.tableWidget_2.currentRow()
if row > 0 and row < self.tableWidget_2.rowCount():
self.insertSourceRow(row+1)
self.tableWidget_2.cellWidget(row+1,0).setCurrentIndex(self.tableWidget_2.cellWidget(row-1,0).currentIndex())
self.tableWidget_2.setItem(row+1,1,self.tableWidget_2.item(row-1,1).clone())
self.tableWidget_2.setItem(row+1,2,self.tableWidget_2.item(row-1,2).clone())
self.tableWidget_2.setItem(row+1,3,self.tableWidget_2.item(row-1,3).clone())
self.tableWidget_2.setItem(row+1,4,self.tableWidget_2.item(row-1,4).clone())
self.tableWidget_2.cellWidget(row+1,5).setCurrentIndex(self.tableWidget_2.cellWidget(row-1,5).currentIndex())
self.sourceSignalMapper.removeMappings(self.tableWidget_2.cellWidget(row-1,0))
self.tableWidget_2.removeRow(row-1)
self.updateSourceSignalMapper()
def toolButton_8_clicked(self):
'''
Slot for toolButton_8. Moves a row down in the sources table.
'''
row = self.tableWidget_2.currentRow()
col = self.tableWidget_2.currentColumn()
if row >= 0 and row+1 < self.tableWidget_2.rowCount():
self.insertSourceRow(row+2)
self.tableWidget_2.cellWidget(row+2,0).setCurrentIndex(self.tableWidget_2.cellWidget(row,0).currentIndex())
self.tableWidget_2.setItem(row+2,1,self.tableWidget_2.item(row,1).clone())
self.tableWidget_2.setItem(row+2,2,self.tableWidget_2.item(row,2).clone())
self.tableWidget_2.setItem(row+2,3,self.tableWidget_2.item(row,3).clone())
self.tableWidget_2.setItem(row+2,4,self.tableWidget_2.item(row,4).clone())
self.tableWidget_2.cellWidget(row+2,5).setCurrentIndex(self.tableWidget_2.cellWidget(row,5).currentIndex())
self.sourceSignalMapper.removeMappings(self.tableWidget_2.cellWidget(row,0))
self.tableWidget_2.removeRow(row)
self.tableWidget_2.setCurrentCell(row+1,col)
self.updateSourceSignalMapper()
def doubleSpinBox_valueChanged(self,value):
'''
Slot for change in value of focal length
'''
# if autocalculation is on, recalc angles
if self.checkBox.isChecked():
for row in range(self.tableWidget.rowCount()):
item = self.tableWidget.item(row,0) # radius item
self.tableWidget_itemChanged(item)
def pushButton_clicked(self):
'''
Slot for pushButton. Simulate.
'''
if self.module is None:
QMessageBox.warning(self,'Invalid module settings')
elif self.detector is None:
QMessageBox.warning(self,'Invalid detector settings')
elif len(self.sources) == 0:
QMessageBox.warning(self,'Invalid source settings')
else:
self.raysPerSource = self.spinBox.value()
self.emit(SIGNAL('startSimulation'))
def pushButton_2_clicked(self):
'''
Slot for pushButton_2. Reset simulation.
'''
# stop thread if needed
self.simThread.blockSignals(True)
self.simThread.stopped = True
self.simThread.wait()
self.simThread.blockSignals(False)
# delete rays and update display
self.allRays = []
self.simulationDone()
# ungray other tabs
self.tab.setEnabled(True)
self.tab_2.setEnabled(True)
# indicate that the sim session has ended (module/detector/source settings can be changed)
self.simulationSessionStarted = False
def pushButton_3_clicked(self):
'''
Slot for pushButton_3. Detector pixel plot.
'''
window = QWidget()
plot(self.detector)
plt.show()
#window.setWindowTitle('Detector Pixel Plot')
#l = QVBoxLayout(window)
#canv = MplCanvas(window, width=5, height=5, dpi=100)
#l.addWidget(canv)
#self.detector.plotImage(canv.axes)
#window.show()
#self.figures.append(window)
def pushButton_4_clicked(self):
'''
Slot for pushButton_4. Scatter plot.
'''
# just plot the rays from the selected sources
qindices = self.listWidget.selectedIndexes()
rays = []
for qi in qindices:
source = self.sources[qi.row()]
for ray in self.detector.rays:
if ray.tag is source:
rays.append(ray)
# color bounce option
colorBounces = self.checkBox_3.isChecked()
# create window
window = QWidget()
window.setWindowTitle('Scatter Plot')
l = QVBoxLayout(window)
canv = MplCanvas(window, width=5, height=5, dpi=100)
scatterHist(rays, figure=canv.figure, colorBounces=colorBounces)
l.addWidget(canv)
window.show()
self.figures.append(window)
def pushButton_5_clicked(self):
'''
Slot for pushButton_5. Plot module cross section.
'''
window = QWidget()
window.setWindowTitle('Module Cross Section')
l = QVBoxLayout(window)
canv = MplCanvas(window, width=8, height=2, dpi=100)
l.addWidget(canv)
module = self.createModule()
module.plot2D(canv.axes,'b')
window.show()
self.figures.append(window)
def pushButton_6_clicked(self):
'''
Slot for pushButton_6. Stop simulation.
'''
self.simThread.stopped = True
def updateRaysToSimulate(self):
'''
Slot of spinBox. Number of rays per source changed.
'''
raysPerSource = self.spinBox.value()
self.label_8.setText(QString(str(raysPerSource*len(self.sources))))
def updateSimulationProgress(self,progressbar,simulated):
'''
Slot for updating the progress bar
'''
self.progressBar.setValue(progressbar)
num,valid = self.label_11.text().toInt() #@UnusedVariable
self.label_11.setText(QString(str(num+simulated)))
def simulationStarted(self):
'''
Slot that disables majority of gui when a simulation is in progress
'''
self.simulationSessionStarted = True
# gray out buttons on sim tab
self.pushButton.setEnabled(False)
self.spinBox.setEnabled(False)
self.groupBox_2.setEnabled(False)
self.groupBox_3.setEnabled(False)
# gray out other tabs
self.tab.setEnabled(False)
self.tab_2.setEnabled(False)
def simulationDone(self):
'''
Slot that reenables the simulation tab, but not the other tabs
'''
# ungray the buttons on the sim tab
self.pushButton.setEnabled(True)
self.spinBox.setEnabled(True)
self.groupBox_2.setEnabled(True)
self.groupBox_3.setEnabled(True)
# reset progress bar to zero and make sure 'total simulated' is accurate
self.progressBar.setValue(0)
self.label_11.setText(QString.number(len(self.allRays)))
class WorldPresenter(object):
radii_and_grid_sizes = [
(2100, 4),
(3700, 5),
(6400, 6),
(11000, 7),
(19000, 8)]
day_hours = [8, 12, 24, 48]
def __init__(self, view, uistack, listitemclass):
self._view = view
self._view.randomize.stateChanged.connect(self.randomized)
self._view.create.clicked.connect(self.create)
self._view.start.clicked.connect(self.start)
self._view.pause.clicked.connect(self.pause)
self._view.done.clicked.connect(self.done)
self._view.load.clicked.connect(self.load)
self._view.save.clicked.connect(self.save)
self._listitemclass = listitemclass
self._uistack = uistack
self._model = None
self._view.randomize.setCheckState(Qt.Checked)
self._view.start.setVisible(True)
self._view.start.setEnabled(False)
self._view.pause.setVisible(False)
self._view.done.setEnabled(True)
def randomized(self, value):
randomize = value == Qt.Checked
for param in [self._view.spin, self._view.tilt, self._view.land, self._view.atmt, self._view.lifet, self._view.peoplet]:
param.setEnabled(not randomize)
def create(self, gridsize=None):
if self._model is not None:
self._worker.stop()
self._worker.wait()
layout = self._view.content.layout()
if layout.count():
layout.removeItem(layout.itemAt(0))
if self._view.randomize.checkState() == Qt.Checked:
# Randomize values, but favor Earth-like ones.
self._view.spin.setCurrentIndex(random.choice([0,1,1,2,2,2,3,3]))
self._view.tilt.setValue(randomspinvalue(self._view.tilt, 23))
self._view.land.setValue(randomspinvalue(self._view.land, 29))
self._view.atmt.setValue(randomtime())
self._view.lifet.setValue(randomtime())
self._view.peoplet.setValue(randomtime())
r, g = self.radii_and_grid_sizes[self._view.radius.currentIndex()]
land_r = math.sqrt(0.04 * self._view.land.value())
self._model = WorldSimulation(r, gridsize or g, self.day_hours[self._view.spin.currentIndex()], self._view.tilt.value(), land_r, self._view.atmt.value(), self._view.lifet.value(), self._view.peoplet.value())
self._worker = SimThread(self._model)
self._worker.tick.connect(self.tick)
self._worker.simstarted.connect(self.started)
self._worker.simstopped.connect(self.stopped)
self._worker.start()
self._display = WorldDisplay(self._model, self.selecttile)
self._view.content.setLayout(QGridLayout())
self._view.content.layout().addWidget(self._display)
self._view.rotate.setValue(self._display.rotate)
self._view.rotate.sliderMoved.connect(self.rotate)
self._view.aspect.setCurrentIndex(self._display.aspect)
self._view.aspect.currentIndexChanged[int].connect(self.aspect)
self._view.start.setVisible(True)
self._view.start.setEnabled(True)
self._view.pause.setVisible(False)
self._view.done.setEnabled(True)
def selecttile(self, tile):
self._display.invalidate()
self._view.content.update()
self._view.details.clear()
if tile is not None:
rock = self._listitemclass(['Layers'])
for layer in reversed(tile.layers):
name = self._listitemclass([layer.rock['name']])
name.setToolTip(0, repr({ 'thickness': layer.thickness,
'rock': layer.rock }))
rock.addChild(name)
self._view.details.addTopLevelItem(rock)
if tile.elevation > 0 and tile.climate:
climate = self._listitemclass([climatenames[tile.climate.koeppen]])
climate.setToolTip(0, repr({ 'temperature': tile.climate.temperature,
'precipitation': tile.climate.precipitation }))
self._view.details.addTopLevelItem(climate)
populated = self._model.populated
if tile in populated:
heritage, count = populated[tile]
population = self._listitemclass([popstr(count)])
def ancestors(h, p):
item = self._listitemclass([h.name])
for a in h.ancestry or []:
ancestors(a, item)
p.addChild(item)
ancestors(heritage, population)
self._view.details.addTopLevelItem(population)
def rotate(self, value):
if self._model is None: return
self._display.rotate = value
self._view.content.update()
def aspect(self, value):
if self._model is None: return
self._display.aspect = value
self._display.invalidate()
self._view.content.update()
def load(self):
filename = QFileDialog.getOpenFileName(self._view,
'Load simulation state',
'',
'*{0}'.format(Data.EXTENSION))[0]
if len(filename) > 0:
data = Data.load(filename)
self.create(data['gridsize'])
self._model.loaddata(data)
self._view.content.update()
self.tick()
def save(self):
if self._model is None: return
filename = QFileDialog.getSaveFileName(self._view,
'Save simulation state',
'',
'*{0}'.format(Data.EXTENSION))[0]
if len(filename) > 0:
self._model.save(filename)
def done(self):
if self._model is not None:
self._worker.stop()
self._worker.wait()
self._uistack.pop()
def started(self):
self._view.start.setVisible(False)
self._view.pause.setVisible(True)
self._view.pause.setEnabled(True)
self._view.done.setEnabled(False)
def stopped(self):
self._view.start.setVisible(True)
self._view.start.setEnabled(True)
self._view.pause.setVisible(False)
self._view.done.setEnabled(True)
def start(self):
if self._model is None: return
self._view.start.setEnabled(False)
self._view.done.setEnabled(False)
self._worker.simulate(True)
def pause(self):
if self._model is None: return
self._view.pause.setEnabled(False)
self._worker.simulate(False)
def tick(self):
self._view.years.setText(self._model.years)
self._view.population.setText(self._model.population)
self._display.invalidate()
self._view.content.update()
def __init__(self, parent=None):
'''
Constructor
'''
QMainWindow.__init__(self, parent)
self.setupUi(self)
# helper vars
self.simThread = SimThread(mainwindow=self)
self.sources = []
self.module = None
self.detector = None
self.allRays = []
self.simulationSessionStarted = False
self.tableItemChanging = False
self.figures = []
self.colors = [
'white', 'red', 'green', 'blue', 'yellow', 'light blue', 'magenta',
'black'
]
self.colorsRGB = [[1, 1, 1], [1, 0, 0], [0, 1, 0], [0, 0, 1],
[1, 1, 0], [0, 1, 1], [1, 0, 1], [0, 0, 0]]
# setup connections
self.connect(self.actionAbout_FOXSISIM_2, SIGNAL('triggered()'),
self.about)
self.sourceSignalMapper = QSignalMapper(
) # needed to map combobox signals to table widget slots
self.connect(self.sourceSignalMapper, SIGNAL('mapped(int)'),
self.tableWidget_2_sourceTypeChanged)
self.connect(self.tabWidget, SIGNAL('currentChanged(int)'),
self.tabWidget_currentChanged)
self.connect(self.tableWidget,
SIGNAL('itemChanged(QTableWidgetItem *)'),
self.tableWidget_itemChanged)
self.connect(self.tableWidget_2,
SIGNAL('itemChanged(QTableWidgetItem *)'),
self.tableWidget_2_itemChanged)
self.connect(self.toolButton, SIGNAL('clicked()'),
self.toolButton_clicked)
self.connect(self.toolButton_2, SIGNAL('clicked()'),
self.toolButton_2_clicked)
self.connect(self.toolButton_3, SIGNAL('clicked()'),
self.toolButton_3_clicked)
self.connect(self.toolButton_4, SIGNAL('clicked()'),
self.toolButton_4_clicked)
self.connect(self.toolButton_5, SIGNAL('clicked()'),
self.toolButton_5_clicked)
self.connect(self.toolButton_6, SIGNAL('clicked()'),
self.toolButton_6_clicked)
self.connect(self.toolButton_7, SIGNAL('clicked()'),
self.toolButton_7_clicked)
self.connect(self.toolButton_8, SIGNAL('clicked()'),
self.toolButton_8_clicked)
self.connect(self.doubleSpinBox, SIGNAL('valueChanged(double)'),
self.doubleSpinBox_valueChanged)
self.connect(self.pushButton, SIGNAL('clicked()'),
self.pushButton_clicked)
self.connect(self.pushButton_2, SIGNAL('clicked()'),
self.pushButton_2_clicked)
self.connect(self.pushButton_3, SIGNAL('clicked()'),
self.pushButton_3_clicked)
self.connect(self.pushButton_4, SIGNAL('clicked()'),
self.pushButton_4_clicked)
self.connect(self.pushButton_5, SIGNAL('clicked()'),
self.pushButton_5_clicked)
self.connect(self.pushButton_6, SIGNAL('clicked()'),
self.pushButton_6_clicked)
self.connect(self, SIGNAL('startSimulation'), self.simThread.start)
self.connect(self.simThread, SIGNAL('updateSimulationProgress'),
self.updateSimulationProgress)
self.connect(self.simThread, SIGNAL('simulationStarted'),
self.simulationStarted)
self.connect(self.simThread, SIGNAL('simulationDone'),
self.simulationDone)
self.connect(self.spinBox, SIGNAL('valueChanged(int)'),
self.updateRaysToSimulate)
self.connect(self, SIGNAL('updateRaysToSimulate'),
self.updateRaysToSimulate)
# set defaults
self.setModuleDefaults()
self.setSourceDefaults()
class MainWindow(QMainWindow, Ui_MainWindow):
'''
classdocs
'''
def __init__(self, parent=None):
'''
Constructor
'''
QMainWindow.__init__(self, parent)
self.setupUi(self)
# helper vars
self.simThread = SimThread(mainwindow=self)
self.sources = []
self.module = None
self.detector = None
self.allRays = []
self.simulationSessionStarted = False
self.tableItemChanging = False
self.figures = []
self.colors = [
'white', 'red', 'green', 'blue', 'yellow', 'light blue', 'magenta',
'black'
]
self.colorsRGB = [[1, 1, 1], [1, 0, 0], [0, 1, 0], [0, 0, 1],
[1, 1, 0], [0, 1, 1], [1, 0, 1], [0, 0, 0]]
# setup connections
self.connect(self.actionAbout_FOXSISIM_2, SIGNAL('triggered()'),
self.about)
self.sourceSignalMapper = QSignalMapper(
) # needed to map combobox signals to table widget slots
self.connect(self.sourceSignalMapper, SIGNAL('mapped(int)'),
self.tableWidget_2_sourceTypeChanged)
self.connect(self.tabWidget, SIGNAL('currentChanged(int)'),
self.tabWidget_currentChanged)
self.connect(self.tableWidget,
SIGNAL('itemChanged(QTableWidgetItem *)'),
self.tableWidget_itemChanged)
self.connect(self.tableWidget_2,
SIGNAL('itemChanged(QTableWidgetItem *)'),
self.tableWidget_2_itemChanged)
self.connect(self.toolButton, SIGNAL('clicked()'),
self.toolButton_clicked)
self.connect(self.toolButton_2, SIGNAL('clicked()'),
self.toolButton_2_clicked)
self.connect(self.toolButton_3, SIGNAL('clicked()'),
self.toolButton_3_clicked)
self.connect(self.toolButton_4, SIGNAL('clicked()'),
self.toolButton_4_clicked)
self.connect(self.toolButton_5, SIGNAL('clicked()'),
self.toolButton_5_clicked)
self.connect(self.toolButton_6, SIGNAL('clicked()'),
self.toolButton_6_clicked)
self.connect(self.toolButton_7, SIGNAL('clicked()'),
self.toolButton_7_clicked)
self.connect(self.toolButton_8, SIGNAL('clicked()'),
self.toolButton_8_clicked)
self.connect(self.doubleSpinBox, SIGNAL('valueChanged(double)'),
self.doubleSpinBox_valueChanged)
self.connect(self.pushButton, SIGNAL('clicked()'),
self.pushButton_clicked)
self.connect(self.pushButton_2, SIGNAL('clicked()'),
self.pushButton_2_clicked)
self.connect(self.pushButton_3, SIGNAL('clicked()'),
self.pushButton_3_clicked)
self.connect(self.pushButton_4, SIGNAL('clicked()'),
self.pushButton_4_clicked)
self.connect(self.pushButton_5, SIGNAL('clicked()'),
self.pushButton_5_clicked)
self.connect(self.pushButton_6, SIGNAL('clicked()'),
self.pushButton_6_clicked)
self.connect(self, SIGNAL('startSimulation'), self.simThread.start)
self.connect(self.simThread, SIGNAL('updateSimulationProgress'),
self.updateSimulationProgress)
self.connect(self.simThread, SIGNAL('simulationStarted'),
self.simulationStarted)
self.connect(self.simThread, SIGNAL('simulationDone'),
self.simulationDone)
self.connect(self.spinBox, SIGNAL('valueChanged(int)'),
self.updateRaysToSimulate)
self.connect(self, SIGNAL('updateRaysToSimulate'),
self.updateRaysToSimulate)
# set defaults
self.setModuleDefaults()
self.setSourceDefaults()
def closeEvent(self, event):
'''
Performs shutdown tasks
'''
for fig in self.figures:
fig.close()
event.accept()
def about(self):
'''
Calls a message box displaying the 'About'
'''
QMessageBox.about(
self, 'About FOXSISIM', u'''FOXSISIM
Copyright \N{COPYRIGHT SIGN} 2011 Robert Taylor, Steven Christe
The FOXSI Optics Simulation Tool (foxsisim) is a python tool to simulate grazing incidence optics response to light sources of different wavelengths. This graphical user interface is a frontend for the foxsisim module.'''
)
def setModuleDefaults(self):
'''
Sets all default values in Module tab
'''
# spin boxes
self.doubleSpinBox.setValue(defaultFocalLength)
self.doubleSpinBox_2.setValue(defaultSegmentLength)
self.doubleSpinBox_3.setValue(defaultDetectorOffset)
self.doubleSpinBox_4.setValue(defaultDetectorWidth)
self.doubleSpinBox_5.setValue(defaultDetectorHeight)
self.spinBox_2.setValue(defaultDetectorReso[0])
self.spinBox_3.setValue(defaultDetectorReso[1])
# module radii/angle table
self.tableWidget.setRowCount(len(defaultRadii))
for i, radius in enumerate(defaultRadii):
r = QString.number(radius, precision=precision)
self.tableWidget.setItem(i, 0, QTableWidgetItem(
r)) # angle is autofilled by tableWidget_itemChanged()
def setSourceDefaults(self):
'''
Sets all defaults in Sources tab
'''
# source table
self.insertSourceRow(0)
type = self.tableWidget_2.cellWidget(0, 0)
type.setCurrentIndex(type.findText(defaultSourceType))
center = QString(
str(defaultSourceCenter[0]) + ',' + str(defaultSourceCenter[1]) +
',' + str(defaultSourceCenter[2]))
self.tableWidget_2.setItem(0, 1, QTableWidgetItem(center))
self.tableWidget_2.setItem(
0, 3,
QTableWidgetItem(
QString.number(defaultSourceWidth, precision=precision)))
self.tableWidget_2.setItem(
0, 4,
QTableWidgetItem(
QString.number(defaultSourceHeight, precision=precision)))
color = self.tableWidget_2.cellWidget(0, 5)
color.setCurrentIndex(color.findText(defaultSourceColor))
def insertModuleRow(self, i):
'''
Insert a row into the module radii/angles table
'''
self.tableWidget.blockSignals(
True) # no signals emitted during row creation
self.tableWidget.insertRow(i)
self.tableWidget.setItem(i, 0, QTableWidgetItem(QString('')))
self.tableWidget.setItem(i, 1, QTableWidgetItem(QString('')))
self.tableWidget.blockSignals(False)
def insertSourceRow(self, i):
'''
Insert a row into the sources table
'''
self.tableWidget_2.blockSignals(
True) # no signals emitted during row creation
self.tableWidget_2.insertRow(i)
type = QComboBox()
type.addItems(['atinf', 'point', 'nonpoint'])
color = QComboBox()
color.addItems(self.colors)
self.tableWidget_2.setCellWidget(i, 0, type)
self.tableWidget_2.setItem(i, 1, QTableWidgetItem(QString('')))
self.tableWidget_2.setItem(i, 2, QTableWidgetItem(QString('')))
self.tableWidget_2.setItem(i, 3, QTableWidgetItem(QString('')))
self.tableWidget_2.setItem(i, 4, QTableWidgetItem(QString('')))
self.tableWidget_2.setCellWidget(i, 5, color)
self.tableWidget_2.blockSignals(False)
# connect signal from the type widget to the mapper which then will emit a 'mapped(i)' signal
self.connect(type, SIGNAL('currentIndexChanged(int)'),
self.sourceSignalMapper, SLOT('map()'))
self.updateSourceSignalMapper()
def updateSourceSignalMapper(self):
'''
Ensures the signal mappings are all correct
'''
for i in range(self.tableWidget_2.rowCount()):
type = self.tableWidget_2.cellWidget(i, 0)
self.sourceSignalMapper.removeMappings(type)
self.sourceSignalMapper.setMapping(type, i)
def createModule(self):
'''
Returns a Module object based on gui input values
'''
# get radii and angles
radii, angles = [], []
for i in range(self.tableWidget.rowCount()):
r, rvalid = self.tableWidget.item(i, 0).text().toDouble()
a, avalid = self.tableWidget.item(i, 1).text().toDouble()
if rvalid and avalid:
radii.append(r)
angles.append(a)
# radii need to be in decending order
import operator
indices = [
i for (i, j) in sorted(
enumerate(radii), key=operator.itemgetter(1), reverse=True)
] #@UnusedVariable
radii = [radii[i] for i in indices]
angles = [angles[i] for i in indices]
# get other value
seglen = self.doubleSpinBox_2.value()
focal = self.doubleSpinBox.value()
# return module
try:
return Module(seglen=seglen,
focal=focal,
radii=radii,
angles=angles)
except:
QMessageBox.warning(
self, 'Warning',
'Could not create module. Check input values.')
return None
def createDetector(self):
'''
Returns a Detector object based on gui input values
'''
focal = self.doubleSpinBox.value()
seglen = self.doubleSpinBox_2.value()
offset = self.doubleSpinBox_3.value()
center = [0, 0, focal + seglen + offset]
width = self.doubleSpinBox_4.value()
height = self.doubleSpinBox_5.value()
reso = [self.spinBox_2.value(), self.spinBox_3.value()]
try:
return Detector(center=center,
width=width,
height=height,
reso=reso)
except:
QMessageBox.warning(
self, 'Warning',
'Could not create detector. Check input values.')
return None
def createSource(self, row):
'''
Returns a Source object from row i in the sources table
'''
# get input
type = str(self.tableWidget_2.cellWidget(row, 0).currentText())
center = self.str2List(self.tableWidget_2.item(row, 1).text())
normal = self.str2List(self.tableWidget_2.item(row, 2).text())
width = self.str2Num(self.tableWidget_2.item(row, 3).text())
height = self.str2Num(self.tableWidget_2.item(row, 4).text())
colorText = str(self.tableWidget_2.cellWidget(row, 5).currentText())
color = self.colorsRGB[self.colors.index(colorText)]
try:
if type == 'atinf' or type == 'nonpoint':
return Source(center=center,
width=width,
height=height,
normal=normal,
type=type,
color=color)
elif type == 'point':
return Source(center=center, type=type, color=color)
except:
QMessageBox.warning(
self, 'Warning', 'Could not create source at row ' +
str(row + 1) + '. Check input values.')
return None
def tabWidget_currentChanged(self, index):
'''
Slot for tab change in tabWidget.
'''
# if we arent in the middle of simulation session
if not self.simulationSessionStarted:
# update module/detector/sources
if index != 0:
self.module = self.createModule()
self.detector = self.createDetector()
if index != 1:
self.sources = []
for row in range(self.tableWidget_2.rowCount()):
source = self.createSource(row)
if source is not None: self.sources.append(source)
# update source list for scatterplot
if index == 2:
self.listWidget.clear()
for source in self.sources:
self.listWidget.addItem(
QString(source.type + ' at [' +
self.list2Str(source.center) + ']'))
self.listWidget.selectAll()
# update 'rays to simulate'
if index == 2: self.emit(SIGNAL('updateRaysToSimulate'))
def tableWidget_itemChanged(self, item):
'''
Slot for item change in module radii/angles table
'''
# prevent infinite recursion
if self.tableItemChanging: return
self.tableItemChanging = True
# get location
row = item.row()
col = item.column()
# get double float
if len(item.text()) > 0:
number, valid = item.text().toDouble()
if not valid:
QMessageBox.warning(self, 'Warning', 'Invalid input')
item.setText('')
number = None
else:
number = None
# if autocalculation is checked
if self.checkBox.isChecked():
if number is None: # set the other column to none
self.tableWidget.setItem(row, (col + 1) % 2,
QTableWidgetItem(''))
elif col == 0: # radius changed
focal = self.doubleSpinBox.value()
angle = calcShellAngle(number, focal)
item = QTableWidgetItem(
QString.number(angle, precision=precision))
self.tableWidget.setItem(row, 1, item)
elif col == 1: # angle changed
focal = self.doubleSpinBox.value()
radius = calcShellRadius(number, focal)
item = QTableWidgetItem(
QString.number(radius, precision=precision))
self.tableWidget.setItem(row, 0, item)
else: # invalid index
print('error: update tableWidget_itemChanged method')
# reset the recursion preventer
self.tableItemChanging = False
def tableWidget_2_sourceTypeChanged(self, row):
'''
Slot for value change in type combo box in sources table
'''
pass
def tableWidget_2_itemChanged(self, item):
'''
Slot for item change in sources table
'''
# prevent infinite recursion
if self.tableItemChanging: return
self.tableItemChanging = True
# get location and row items
row = item.row()
col = item.column()
typeWidget = self.tableWidget_2.cellWidget(row, 0)
centerItem = self.tableWidget_2.item(row, 1)
normalItem = self.tableWidget_2.item(row, 2)
widthItem = self.tableWidget_2.item(row, 3)
heightItem = self.tableWidget_2.item(row, 4)
#colorWidget = self.tableWidget_2.cellWidget(row,5)
type = typeWidget.currentText()
center = self.str2List(centerItem.text())
normal = self.str2List(normalItem.text())
width = self.str2Num(widthItem.text())
height = self.str2Num(heightItem.text())
#color = colorWidget.currentText()
# check validity of entire row's input
invalidInput = False
if len(centerItem.text()) > 0 and (center is None or len(center) != 3):
center = None
invalidInput = True
if len(normalItem.text()) > 0 and (normal is None or len(normal) != 3):
normal = None
invalidInput = True
if len(widthItem.text()) > 0 and (width is None or width < 0):
width = None
invalidInput = True
if len(heightItem.text()) > 0 and (height is None or height < 0):
height = None
invalidInput = True
if invalidInput: QMessageBox.warning(self, 'Warning', 'Invalid input')
# if autocalculation is checked
if self.checkBox_2.isChecked():
if col == 1 and center is not None: # center changed
normal = [-x for x in center]
elif col == 2 and normal is not None: # normal changed
center = [-x for x in normal]
# source width/height is autocalculated when atinf
if type == QString(
'atinf') and normal is not None and normal[2] > 0:
ny = np.array([normal[0], 0, normal[2]])
ang = angleBetweenVectors(ny, np.array([0, 0, 1]))
try:
dims = self.module.getDims()
except:
dims = self.createModule().getDims()
radius = dims[0] # radius at wide end of module
width = 2 * radius * cos(ang)
height = 2 * radius # TODO: find the proper way to calculate this
# check that center is in negative z region
if center is not None and center[2] >= 0:
QMessageBox.warning(
self, 'Warning',
'Source center point should have a negative z value')
# change items
self.tableWidget_2.setItem(row, 1,
QTableWidgetItem(self.list2Str(center)))
self.tableWidget_2.setItem(row, 2,
QTableWidgetItem(self.list2Str(normal)))
self.tableWidget_2.setItem(row, 3,
QTableWidgetItem(self.num2Str(width)))
self.tableWidget_2.setItem(row, 4,
QTableWidgetItem(self.num2Str(height)))
# reset the recursion preventer
self.tableItemChanging = False
def str2Num(self, str):
'''
Takes a QString and returns a double
'''
if str == QString(''): return None
num, valid = str.toDouble()
if not valid: return None
return num
def num2Str(self, num):
'''
Takes a number and returns a string
'''
if num is None: return QString('')
return QString.number(num, precision=precision)
def str2List(self, str):
'''
Takes a string of from 'x,y,z' and returns list [x,y,z]
'''
try:
arr = str.split(',')
return [float(s) for s in arr]
except:
return None
def list2Str(self, list):
'''
Takes a list of form [x,y,z] and returns string 'x,y,z'
'''
if list is None:
return QString('') # return empty string if None is passed
arr = [QString.number(x, precision=precision) + ',' for x in list]
arr[-1].remove(-1, 1)
arr = [str(q) for q in arr]
return ''.join(arr)
def toolButton_clicked(self):
'''
Slot for toolButton. Adds a row to the sources table.
'''
row = self.tableWidget_2.rowCount()
self.insertSourceRow(row)
self.updateSourceSignalMapper()
def toolButton_2_clicked(self):
'''
Slot for toolButton_2. Removes a row from the sources table.
'''
row = self.tableWidget_2.currentRow()
if row < 0:
row = self.tableWidget_2.rowCount() - 1
self.sourceSignalMapper.removeMappings(
self.tableWidget_2.cellWidget(row, 0))
self.tableWidget_2.removeRow(row)
self.updateSourceSignalMapper()
def toolButton_3_clicked(self):
'''
Slot for toolButton_3. Adds a row to the module radii/angles table.
'''
row = self.tableWidget.rowCount()
self.insertModuleRow(row)
def toolButton_4_clicked(self):
'''
Slot for toolButton_4. Removes a row from the module radii/angles table.
'''
row = self.tableWidget.currentRow()
if row < 0:
row = self.tableWidget.rowCount() - 1
self.tableWidget.removeRow(row)
def toolButton_5_clicked(self):
'''
Slot for toolButton_5. Moves a row up in the module radii/angles table.
'''
row = self.tableWidget.currentRow()
if row > 0 and row < self.tableWidget.rowCount():
self.insertModuleRow(row + 1)
self.tableWidget.setItem(row + 1, 0,
self.tableWidget.item(row - 1, 0).clone())
self.tableWidget.setItem(row + 1, 1,
self.tableWidget.item(row - 1, 1).clone())
self.tableWidget.removeRow(row - 1)
def toolButton_6_clicked(self):
'''
Slot for toolButton_6. Moves a row down in the module radii/angles table.
'''
row = self.tableWidget.currentRow()
col = self.tableWidget.currentColumn()
if row >= 0 and row + 1 < self.tableWidget.rowCount():
self.insertModuleRow(row + 2)
self.tableWidget.setItem(row + 2, 0,
self.tableWidget.item(row, 0).clone())
self.tableWidget.setItem(row + 2, 1,
self.tableWidget.item(row, 1).clone())
self.tableWidget.removeRow(row)
self.tableWidget.setCurrentCell(row + 1, col)
def toolButton_7_clicked(self):
'''
Slot for toolButton_7. Moves a row up in the sources table.
'''
row = self.tableWidget_2.currentRow()
if row > 0 and row < self.tableWidget_2.rowCount():
self.insertSourceRow(row + 1)
self.tableWidget_2.cellWidget(row + 1, 0).setCurrentIndex(
self.tableWidget_2.cellWidget(row - 1, 0).currentIndex())
self.tableWidget_2.setItem(
row + 1, 1,
self.tableWidget_2.item(row - 1, 1).clone())
self.tableWidget_2.setItem(
row + 1, 2,
self.tableWidget_2.item(row - 1, 2).clone())
self.tableWidget_2.setItem(
row + 1, 3,
self.tableWidget_2.item(row - 1, 3).clone())
self.tableWidget_2.setItem(
row + 1, 4,
self.tableWidget_2.item(row - 1, 4).clone())
self.tableWidget_2.cellWidget(row + 1, 5).setCurrentIndex(
self.tableWidget_2.cellWidget(row - 1, 5).currentIndex())
self.sourceSignalMapper.removeMappings(
self.tableWidget_2.cellWidget(row - 1, 0))
self.tableWidget_2.removeRow(row - 1)
self.updateSourceSignalMapper()
def toolButton_8_clicked(self):
'''
Slot for toolButton_8. Moves a row down in the sources table.
'''
row = self.tableWidget_2.currentRow()
col = self.tableWidget_2.currentColumn()
if row >= 0 and row + 1 < self.tableWidget_2.rowCount():
self.insertSourceRow(row + 2)
self.tableWidget_2.cellWidget(row + 2, 0).setCurrentIndex(
self.tableWidget_2.cellWidget(row, 0).currentIndex())
self.tableWidget_2.setItem(row + 2, 1,
self.tableWidget_2.item(row, 1).clone())
self.tableWidget_2.setItem(row + 2, 2,
self.tableWidget_2.item(row, 2).clone())
self.tableWidget_2.setItem(row + 2, 3,
self.tableWidget_2.item(row, 3).clone())
self.tableWidget_2.setItem(row + 2, 4,
self.tableWidget_2.item(row, 4).clone())
self.tableWidget_2.cellWidget(row + 2, 5).setCurrentIndex(
self.tableWidget_2.cellWidget(row, 5).currentIndex())
self.sourceSignalMapper.removeMappings(
self.tableWidget_2.cellWidget(row, 0))
self.tableWidget_2.removeRow(row)
self.tableWidget_2.setCurrentCell(row + 1, col)
self.updateSourceSignalMapper()
def doubleSpinBox_valueChanged(self, value):
'''
Slot for change in value of focal length
'''
# if autocalculation is on, recalc angles
if self.checkBox.isChecked():
for row in range(self.tableWidget.rowCount()):
item = self.tableWidget.item(row, 0) # radius item
self.tableWidget_itemChanged(item)
def pushButton_clicked(self):
'''
Slot for pushButton. Simulate.
'''
if self.module is None:
QMessageBox.warning(self, 'Invalid module settings')
elif self.detector is None:
QMessageBox.warning(self, 'Invalid detector settings')
elif len(self.sources) == 0:
QMessageBox.warning(self, 'Invalid source settings')
else:
self.raysPerSource = self.spinBox.value()
self.emit(SIGNAL('startSimulation'))
def pushButton_2_clicked(self):
'''
Slot for pushButton_2. Reset simulation.
'''
# stop thread if needed
self.simThread.blockSignals(True)
self.simThread.stopped = True
self.simThread.wait()
self.simThread.blockSignals(False)
# delete rays and update display
self.allRays = []
self.simulationDone()
# ungray other tabs
self.tab.setEnabled(True)
self.tab_2.setEnabled(True)
# indicate that the sim session has ended (module/detector/source settings can be changed)
self.simulationSessionStarted = False
def pushButton_3_clicked(self):
'''
Slot for pushButton_3. Detector pixel plot.
'''
window = QWidget()
plot(self.detector)
plt.show()
#window.setWindowTitle('Detector Pixel Plot')
#l = QVBoxLayout(window)
#canv = MplCanvas(window, width=5, height=5, dpi=100)
#l.addWidget(canv)
#self.detector.plotImage(canv.axes)
#window.show()
#self.figures.append(window)
def pushButton_4_clicked(self):
'''
Slot for pushButton_4. Scatter plot.
'''
# just plot the rays from the selected sources
qindices = self.listWidget.selectedIndexes()
rays = []
for qi in qindices:
source = self.sources[qi.row()]
for ray in self.detector.rays:
if ray.tag is source:
rays.append(ray)
# color bounce option
colorBounces = self.checkBox_3.isChecked()
# create window
window = QWidget()
window.setWindowTitle('Scatter Plot')
l = QVBoxLayout(window)
canv = MplCanvas(window, width=5, height=5, dpi=100)
scatterHist(rays, figure=canv.figure, colorBounces=colorBounces)
l.addWidget(canv)
window.show()
self.figures.append(window)
def pushButton_5_clicked(self):
'''
Slot for pushButton_5. Plot module cross section.
'''
window = QWidget()
window.setWindowTitle('Module Cross Section')
l = QVBoxLayout(window)
canv = MplCanvas(window, width=8, height=2, dpi=100)
l.addWidget(canv)
module = self.createModule()
module.plot2D(canv.axes, 'b')
window.show()
self.figures.append(window)
def pushButton_6_clicked(self):
'''
Slot for pushButton_6. Stop simulation.
'''
self.simThread.stopped = True
def updateRaysToSimulate(self):
'''
Slot of spinBox. Number of rays per source changed.
'''
raysPerSource = self.spinBox.value()
self.label_8.setText(QString(str(raysPerSource * len(self.sources))))
def updateSimulationProgress(self, progressbar, simulated):
'''
Slot for updating the progress bar
'''
self.progressBar.setValue(progressbar)
num, valid = self.label_11.text().toInt() #@UnusedVariable
self.label_11.setText(QString(str(num + simulated)))
def simulationStarted(self):
'''
Slot that disables majority of gui when a simulation is in progress
'''
self.simulationSessionStarted = True
# gray out buttons on sim tab
self.pushButton.setEnabled(False)
self.spinBox.setEnabled(False)
self.groupBox_2.setEnabled(False)
self.groupBox_3.setEnabled(False)
# gray out other tabs
self.tab.setEnabled(False)
self.tab_2.setEnabled(False)
def simulationDone(self):
'''
Slot that reenables the simulation tab, but not the other tabs
'''
# ungray the buttons on the sim tab
self.pushButton.setEnabled(True)
self.spinBox.setEnabled(True)
self.groupBox_2.setEnabled(True)
self.groupBox_3.setEnabled(True)
# reset progress bar to zero and make sure 'total simulated' is accurate
self.progressBar.setValue(0)
self.label_11.setText(QString.number(len(self.allRays)))
class PrehistoryPresenter(object):
def __init__(self, view, uistack):
self._view = view
self._view.start.clicked.connect(self.start)
self._view.pause.clicked.connect(self.pause)
self._view.load.clicked.connect(self.load)
self._view.save.clicked.connect(self.save)
self._view.done.clicked.connect(self.done)
self._model = PrehistorySimulation(5, 1.0, 3, 23)
self._worker = SimThread(self._model)
self._worker.tick.connect(self.tick)
self._worker.simstarted.connect(self.started)
self._worker.simstopped.connect(self.stopped)
self._ticks = 0
self._worker.start()
self._display = PrehistoryDisplay(self._model)
self._view.content.setLayout(QGridLayout())
self._view.content.layout().addWidget(self._display)
self._view.rotate.setValue(self._display.rotate)
self._view.rotate.sliderMoved.connect(self.rotate)
self._view.pause.setVisible(False)
self._uistack = uistack
def rotate(self, value):
self._display.rotate = value
self._view.content.update()
def load(self):
filename = QFileDialog.getOpenFileName(self._view,
'Load simulation state',
'',
'*{0}'.format(Data.EXTENSION))[0]
if len(filename) > 0:
self._model.load(filename)
self._display.invalidate()
self._view.content.update()
def save(self):
filename = QFileDialog.getSaveFileName(self._view,
'Save simulation state',
'',
'*{0}'.format(Data.EXTENSION))[0]
if len(filename) > 0:
self._model.save(filename)
def done(self):
self._uistack.pop()
def started(self):
self._view.start.setVisible(False)
self._view.pause.setVisible(True)
self._view.pause.setEnabled(True)
self._view.done.setEnabled(False)
def stopped(self):
self._view.start.setVisible(True)
self._view.start.setEnabled(True)
self._view.pause.setVisible(False)
self._view.done.setEnabled(True)
def start(self):
self._view.start.setEnabled(False)
self._view.done.setEnabled(False)
self._worker.simulate(True)
def pause(self):
self._view.pause.setEnabled(False)
self._worker.simulate(False)
def tick(self):
self._ticks += 1
self._view.ticks.setNum(self._ticks)
self._view.races.setNum(self._model.peoples)
self._display.invalidate()
self._view.content.update()
class TectonicsPresenter(object):
def __init__(self, view, uistack, listitemclass):
self._view = view
self._view.start.clicked.connect(self.start)
self._view.pause.clicked.connect(self.pause)
self._view.done.clicked.connect(self.done)
self._view.load.clicked.connect(self.load)
self._view.save.clicked.connect(self.save)
self._model = PlanetSimulation(6400, 6, 1.0, 3, 23, 1.145, 5, 125, 125)
self._worker = SimThread(self._model)
self._worker.tick.connect(self.tick)
self._worker.simstarted.connect(self.started)
self._worker.simstopped.connect(self.stopped)
self._ticks = 0
self._worker.start()
self._display = PlanetDisplay(self._model, self.selecttile)
self._view.continents.setNum(self._model.continents)
self._view.percent.setNum(self._model.land)
self._view.content.setLayout(QGridLayout())
self._view.content.layout().addWidget(self._display)
self._listitemclass = listitemclass
self._view.rotate.setValue(self._display.rotate)
self._view.rotate.sliderMoved.connect(self.rotate)
self._view.aspect.setCurrentIndex(self._display.aspect)
self._view.aspect.currentIndexChanged[int].connect(self.aspect)
self._view.pause.setVisible(False)
self._uistack = uistack
def selecttile(self, tile):
self._view.details.clear()
if tile is not None:
for layer in reversed(tile.layers):
name = self._listitemclass(layer.rock['name'])
name.setToolTip(repr({ 'thickness': layer.thickness,
'rock': layer.rock }))
self._view.details.addItem(name)
def rotate(self, value):
self._display.rotate = value
self._view.content.update()
def aspect(self, value):
self._display.aspect = value
self._display.invalidate()
self._view.content.update()
def load(self):
filename = QFileDialog.getOpenFileName(self._view,
'Load simulation state',
'',
'*{0}'.format(Data.EXTENSION))[0]
if len(filename) > 0:
self._model.load(filename)
self._view.content.update()
self._ticks = -1
self.tick()
def save(self):
filename = QFileDialog.getSaveFileName(self._view,
'Save simulation state',
'',
'*{0}'.format(Data.EXTENSION))[0]
if len(filename) > 0:
self._model.save(filename)
def done(self):
self._worker.stop()
self._worker.wait()
self._uistack.pop()
def started(self):
self._view.start.setVisible(False)
self._view.pause.setVisible(True)
self._view.pause.setEnabled(True)
self._view.done.setEnabled(False)
def stopped(self):
self._view.start.setVisible(True)
self._view.start.setEnabled(True)
self._view.pause.setVisible(False)
self._view.done.setEnabled(True)
def start(self):
self._view.start.setEnabled(False)
self._view.done.setEnabled(False)
self._worker.simulate(True)
def pause(self):
self._view.pause.setEnabled(False)
self._worker.simulate(False)
def tick(self):
self._ticks += 1
self._view.ticks.setNum(self._ticks)
self._view.continents.setNum(self._model.continents)
self._view.percent.setNum(self._model.land)
self._display.invalidate()
self._view.content.update()
