Development/Tutorials/Python introduction to signals and slots: Difference between revisions
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emit() is an object method, the self parameter is therefor automatically inserted by the python interpreter. The next argument is the signal we would like to emit, for example it could have been SIGNAL("myfirstsignal()") if we wanted to emit a signal with that name. The next parameters is optional parameters that can be sent with the signal, will come | emit() is an object method, the self parameter is therefor automatically inserted by the python interpreter. The next argument is the signal we would like to emit, for example it could have been SIGNAL("myfirstsignal()") if we wanted to emit a signal with that name. The next parameters is optional parameters that can be sent with the signal, will come back to that in more detail later. | ||
'''Example''' | '''Example''' |
Revision as of 14:40, 15 January 2007
Abstract
The signal and slot architecture is design to simplify communication between objects. It's a fact that GUI programming is mostly event driven. The traditionally approach to event driven programming is to use callbaks. Callbacks have a number of limitations that Qt tries to solve with it's signal and slot architecture. The concept is that every object can emit signals. For example when a button is clicked it emits a “clicked()” signal. Signals does not do anything alone, but when connected to a slot the code in the slot will be executed every time the signal is emitted. In python every function is a slot. It's possible to connect one signal to multiple slots
Prerequisites
General understanding of the python programming language. No prior knowledge of QT is required.
Connecting signals and slots.
We use the QObject.connect() method to connect signals and slots.
bool connect (QObject, SIGNAL(), callable, Qt.ConnectionType = Qt.AutoConnection)
The first argument is the name of the object that is emitting the signal. The second argument is the signal, and the third argument is the slot. The slot has to bee a python callable object. Note that only QObjects and objects inheriting from QObject can emit signals.
Example
from PyQt4.QtGui import *
from PyQt4.QtCore import *
import sys
- First we create a QApplication and QPushButton
app=QApplication(sys.argv)
exitButton=QPushButton("Exit")
- Here we connect the exitButton's "clicked()" signals to the app's exit method.
- This will have the effect that every time some one clicks the exitButton
- the app.exit method will execute and the application will close.
QObject.connect(exitButton,SIGNAL("clicked()"),app.exit)
exitButton.show()
- Start the evnt loop
sys.exit(app.exec_())
Emitting signals
Only QObjects and objects inheriting from QObject can emit signals. To emit a signal we use the QObject.emit() method.
QObject.emit (self, SIGNAL(), ...)
emit() is an object method, the self parameter is therefor automatically inserted by the python interpreter. The next argument is the signal we would like to emit, for example it could have been SIGNAL("myfirstsignal()") if we wanted to emit a signal with that name. The next parameters is optional parameters that can be sent with the signal, will come back to that in more detail later.
Example
from time import time
from PyQt4.QtCore import *
class A (QObject):
def __init__(self):
QObject.__init__(self)
def afunc (self):
self.emit(SIGNAL("doSomePrinting()"))
def bfunc(self):
print "Hello World!"
if __name__=="__main__":
app=QCoreApplication(sys.argv)
a=A()
QObject.connect(a,SIGNAL("doSomePrinting()"),a.bfunc)
a.afunc()
sys.exit(app.exec_())
Signals and slots with parameters
The signal and slots mechanism is type safe. In C++ this implies that both the number of arguments and the type of the arguments in a signal must match the arguments in the receiving slot. In Qt's Signal and slots architecture the receiving slot can actually have fewer parameters than the emitted signal, the extra arguments will then be ignored. Because of pythons dynamically typed nature it not possible to do any type checking in advance. It is therefor important to make sure that the emitted object is of the expected type or of a type that can be automatically converted to the expected type. For example a python string will automatically be converted to QString. If we send a object of an incompatible type we will get an runtime error.
Example
from PyQt4.QtGui import *
from PyQt4.QtCore import *
import sys
def printNumber(number):
print number
if __name__=="__main__":
#First we create a QApplication and QPushButton
app=QApplication(sys.argv)
slider=QSlider(Qt.Horizontal)
QObject.connect(slider,SIGNAL("valueChanged(int)"),printNumber)
slider.show()
#Start the evnt loop
sys.exit(app.exec_())
Python objects as parameters
It's possible to send a python object of any type using PyQt_PyObject in the signature. This is recommended when both signal and slot is implemented in python. By using PyQt_PyObject we avoid unnecessary conversions between python objects and C++ types and it more consistent with python dynamically typed nature.
Example
import sys
from time import time
from PyQt4.QtCore import *
class A (QObject):
def __init__(self):
QObject.__init__(self)
def send (self):
msg=[1234,"1234",{1:2}]
self.emit(SIGNAL("asignal(PyQt_PyObject)"),msg)
def recive(self,msg):
print msg
def p(msg): print int(time()-start),msg
if __name__=="__main__":
app=QCoreApplication(sys.argv)
a=A()
QObject.connect(a,SIGNAL("asignal(PyQt_PyObject)"),a.recive)
a.send()
sys.exit(app.exec_())
Short-circuit Signal
PyQt4 have a special type of signal called a short-circuit Signal. This signal implicitly declare all arguments to be of type PyQt_PyObject. Short-circuited signals does not have argument lists or parentheses. Short-circuited signals can only connected to python slots.
The same example as above, using short-circuited signals.
import sys
from time import time
from PyQt4.QtCore import *
class A (QObject):
def __init__(self):
QObject.__init__(self)
def send (self):
msg=[1234,"1234",{1:2}]
self.emit(SIGNAL("asignal"),msg)
def recive(self,msg):
print msg
def p(msg): print int(time()-start),msg
if __name__=="__main__":
app=QCoreApplication(sys.argv)
a=A()
QObject.connect(a,SIGNAL("asignal"),a.recive)
a.send()
sys.exit(app.exec_())
Signals and slots and threading
To send signal across threads we have to use the Qt.QueuedConnection parameter. Without this parameter the code will be executed in the same thread.
import sys
from time import time
from PyQt4.QtCore import *
class A (QThread):
def __init__(self):
QThread.__init__(self)
def afunc (self):
p("starting in a()")
self.emit(SIGNAL("asignal"))
p("finished in a()")
def bfunc(self):
p("starting in b()")
self.sleep(3)
p("finished in b()")
def run(self):
self.exec_()
def p(msg): print str(int(time()-start)) + "s",msg
if __name__=="__main__":
start=time()
p("starting in __main__")
app=QCoreApplication(sys.argv)
a=A()
a.start()
QObject.connect(a,SIGNAL("asignal"),a.bfunc,Qt.QueuedConnection)
a.afunc()
p("finished in __main__")
sys.exit(app.exec_())
Output:
0s starting in __main__
0s starting in a()
0s finished in a()
0s finished in __main__
0s starting in b()
3s finished in b()
without Qt.QueuedConnection the example will output:
0s starting in __main__
0s starting in a()
0s starting in b()
3s finished in b()
3s finished in a()
3s finished in __main__