Events

Basic usage

Events are objects that contain data (arguments and keyword arguments) about the message being sent to a receiving component. Events are triggered by using the fire() method of any registered component.

Some events in circuits are fired implicitly by the circuits core like the started event used in the tutorial or explicitly by components while handling some other event. Once fired, events are dispatched to the components that are interested in these events (components whose event handlers match events of interest).

Events are usually fired on one or more channels, allowing components to gather in “interest groups”. This is especially useful if you want to reuse basic components such as a TCPServer. A TCPServer component fires a read event for every package of data that it receives. If we did not have support for channels, it would be very difficult to build two servers in a single process without their read events colliding.

Using channels, we can put one server and all components interested in its events on one channel, and another server and the components interested in this other server’s events on another channel.

Components are associated with a channel by setting their channel class or instance attribute.

See also

Component

Besides having a name, events carry additional arbitrary information. This information is passed as arguments or keyword arguments to the constructor. It is then delivered to the event handler method that must have exactly the same number of arguments and keyword arguments. Of course, as is usual in Python, you can also pass additional information by setting attributes of the event object, though this usage pattern is discouraged.

Filtering

Events can be filtered by stopping other event handlers from continuing to process the event.

To do this, simply call the stop() method.

Example:

@handler("foo")
def stop_foo(self, event, *args, **kwargs):
    event.stop()

Here any other event handlers also listening to “foo” will not be processed.

Note

It’s important to use priority event handlers here in this case as all event handlers and events run with the same priority unless explicitly told otherwise.

Changed in version 3.0: In circuits 2.x you declared your event handler to be a filter by using @handler(filter=True) and returned a True-ish value from the respective event handler to achieve the same effect. This is no longer the case in circuits 3.x Please use event.stop() as noted above.

Events as result collectors

Apart from delivering information to handlers, event objects may also collect information. If a handler returns something that is not None, it is stored in the event’s value attribute. If a second (or any subsequent) handler invocation also returns a value, the values are stored as a list. Note that the value attribute is of type Value and you must access its property value to access the data stored (collected_information = event.value.value).

The collected information can be accessed by handlers in order to find out about any return values from the previously invoked handlers. More useful though, is the possibility to access the information after all handlers have been invoked. After all handlers have run successfully (i.e. no handler has thrown an error) circuits may generate an event that indicates the successful handling. This event has the name of the event just handled with “Success” appended. So if the event is called Identify then the success event is called IdentifySuccess. Success events aren’t delivered by default. If you want successful handling to be indicated for an event, you have to set the optional attribute success of this event to True.

The handler for a success event must be defined with two arguments. When invoked, the first argument is the event just having been handled successfully and the second argument is (as a convenience) what has been collected in event.value.value (note that the first argument may not be called event, for an explanation of this restriction as well as for an explanation why the method is called identify_success see the section on handlers).

 1#!/usr/bin/env python
 2
 3from circuits import Component, Debugger, Event
 4
 5
 6class Identify(Event):
 7
 8    """Identify Event"""
 9
10    success = True
11
12
13class Pound(Component):
14
15    def __init__(self):
16        super(Pound, self).__init__()
17
18        Debugger().register(self)
19        Bob().register(self)
20        Fred().register(self)
21
22    def started(self, *args):
23        self.fire(Identify())
24
25    def Identify_success(self, evt, result):
26        if not isinstance(result, list):
27            result = [result]
28        print "In pound:"
29        for name in result:
30            print name
31
32
33class Dog(Component):
34
35    def Identify(self):
36        return self.__class__.__name__
37
38
39class Bob(Dog):
40
41    """Bob"""
42
43
44class Fred(Dog):
45
46    """Fred"""
47
48Pound().run()

Download handler_returns.py

Advanced usage

Sometimes it may be necessary to take some action when all state changes triggered by an event are in effect. In this case it is not sufficient to wait for the completion of all handlers for this particular event. Rather, we also have to wait until all events that have been fired by those handlers have been processed (and again wait for the events fired by those events’ handlers, and so on). To support this scenario, circuits can fire a Complete event. The usage is similar to the previously described success event. Details can be found in the API description of circuits.core.events.Event.