EventHandler is a full-featured event library for Crystal.
It supports:
- Defining events
- Defining handlers that will run in response to events
- Emitting (triggering) events
Each handler can run synchronously or asynchronously, run one or more times, and be added at the beginning or end of queue, or into a specific position.
Subclassing events is also supported, as well as sending events through Channels and blocking/waiting for events.
Add the dependency to shard.yml
:
dependencies:
event_handler:
github: crystallabs/event_handler
version: ~> 1.0
Here is a basic example that defines and emits events. More detailed usage instructions are provided further below.
require "event_handler"
# Define an event named ClickedEvent with two arguments
EventHandler.event ClickedEvent, x : Int32, y : Int32
class MyClass
include EventHandler
def initialize
# Define a handler that will run in response to the event
on(::ClickedEvent) do |e|
puts "Clicked on position x=#{e.x}, y=#{e.y}"
end
end
end
# Trigger the event on the object:
my = MyClass.new
my.emit ClickedEvent, 10, 20 #=> "Clicked on position x=10, y=20"
Or another example:
require "event_handler"
# Define an event inside a namespace (MyClass::TestEvent)
class MyClass
include EventHandler
event TestEvent, message : String, status : Bool
end
my = MyClass.new
# Add a Proc as event handler
handler = ->(e : MyClass::TestEvent) do
puts "Activated on #{e.class}. Message is '#{e.message}' and status is #{e.status}"
end
my.on MyClass::TestEvent, handler
# Emit the event
my.emit MyClass::TestEvent, "Hello, World!", true
#=> Activated on MyClass::TestEvent. Message is 'Hello, World!' and status is true
# Remove the handler
my.off MyClass::TestEvent, handler
# Or remove all handlers for an event at once
my.off MyClass::TestEvent
An event can be defined via the convenient event
macro or manually.
Using event
creates an event class which inherits from base class EventHandler::Event
:
EventHandler.event ClickedEvent, x : Int32, y : Int32
It is a shorthand for the following line:
class_record ClickedEvent < ::EventHandler::Event, x : Int32, y : Int32
(class_record
is EventHandler's variant of Crystal's macro record
; it creates classes instead of structs.)
If additional modification to the class is necessary, class can be reopened:
EventHandler.event ClickedEvent, x : Int32, y : Int32
class ClickedEvent < EventHandler::Event
property test : String?
end
Or the whole event class can be created manually; it only needs to inherit from EventHandler::Event
:
class ClickedEvent < EventHandler::Event
getter x : Int32
getter y : Int32
property test : String?
def initialize(@x, @y)
end
end
Subclassing also works as expected:
EventHandler.event ClickedEvent, x : Int32, y : Int32
class DoubleClickedEvent < ClickedEvent
end
Event handlers can be added in a number of ways.
Using a block:
my = MyClass.new
my.on ClickedEvent do |e|
p "Hello"
end
Using a Proc:
my = MyClass.new
# With Proc ->(){} syntax
handler = ->(e : ClickedEvent) do
p "Hello"
nil
end
# With Proc.new syntax
handler = Proc(ClickedEvent, Nil).new do |e|
p "Hello"
end
my.on ClickedEvent, handler
Using an aliased type for Proc called Handler
, eliminating the need to repeat type information:
my = MyClass.new
handler = ClickedEvent::Handler.new do |e|
p "Hello"
end
my.on ClickedEvent, handler
Using an existing method:
my = MyClass.new
def on_clicked(e : ClickedEvent) : Nil
p "Hello"
end
my.on ClickedEvent, ->on_clicked(ClickedEvent)
Using a variation of the last example, where if an object method is used, self
is preserved as expected:
class MyClass
include EventHandler
event ClickedEvent, x : Int32, y : Int32
def on_clicked(e : ClickedEvent)
p "Hello", e.x, e.y, self
nil
end
end
my = MyClass.new
my.on ClickedEvent, ->my.on_clicked(ClickedEvent)
Using a handler "wrapper" object explicitly (otherwise it would be created and used implicitly):
my = MyClass.new
handler = ->(e : ClickedEvent) do
p "Hello"
nil
end
wrapper = EventHandler::Wrapper.new(handler: handler, once: false, async: false, at: -1)
my.on ClickedEvent, wrapper
Using a variation of the last example with an aliased type for Wrapper:
my = MyClass.new
# With block
wrapper = ClickedEvent::Wrapper.new(once: false, async: false, at: -1) do |e|
p "Hello"
end
# With Proc
handler = ->(e : ClickedEvent) do
p "Hello"
nil
end
wrapper = ClickedEvent::Wrapper.new(handler: handler, once: false, async: false, at: -1)
my.on ClickedEvent, wrapper
Using a variation of the last example, where wrapper object is obtained from a call
to on()
and then reused to add the same handler the second time:
my = MyClass.new
handler = ->(e : ClickedEvent) do
p "Hello"
nil
end
wrapper = my.on ClickedEvent, handler
my.on ClickedEvent, wrapper
Using a Channel:
my = MyClass.new
# With Channel(T)
channel = Channel(ClickedEvent).new
# With an aliased type
channel = ClickedEvent::Channel.new
my.on ClickedEvent, channel
When on
is invoked with a channel, it implicitly creates and
adds an event handler which forwards received events into the channel.
All of the above methods for adding handlers support arguments once
, async
, and at
.
once
specifies whether the handler should run only once and then be automatically removed.
Default is false. In the future this option may be replaced with times
which specifies
how many times to run before being removed.
As a convenience for adding handlers that should run only once, there is a method
named once
available instead of the usual on
. These two calls are equivalent:
my.on ClickedEvent, handler, once: true, async: true, at: -1
my.once ClickedEvent, handler, async: true, at: -1
async
specifies whether a handler should run synchronously or asynchronously. If
no specific value is provided, global default from EventHandler.async
is used.
Default (EventHandler.async?
) is false. You can either modify this default,
or specify async
on a per-on
basis.
at
specifies the index in the list of handlers where new handler should be inserted.
While it is possible to specify the exact position, usually this value is
0
(EventHandler.at_beginning
) to insert at the beginning or -1
(EventHandler.at_end
)
to insert at the end of list. Default is EventHandler.at_end
.
Events can be emitted using emit
in one of three ways:
By listing the event class and arguments one after another:
my.emit ClickedEvent, 10, 20
By listing the event class and event instance one after another:
my.emit ClickedEvent, ClickedEvent.new 10, 20
By creating an event instance and providing it as the single argument:
my.emit ClickedEvent.new 10, 20
The handler methods will always receive one argument - the event object
with packed arguments. The return value from emit
is that object.
As mentioned, handlers always receive one argument - the event object with packed arguments.
When an event is emitted using any of the available variants, such as:
my.emit ClickedEvent, x: 10, y: 20
The arguments are directly accessible as getters on the event object:
my.on ClickedEvent do |e|
puts "Clicked on position x=#{e.x}, y=#{e.y}"
end
All handlers are defined with Nil as their return type and their return value is ignored.
my.on ClickedEvent do |e|
p "Hello"
end
If event handlers should produce a return value, the recommended way is to subclass Event into one that contains a return value, which the handlers will update:
require "event_handler"
class EventWithRetval < ::EventHandler::Event
property return_value : Int32 = 0
end
class_record ClickedEvent < EventWithRetval, x : Int32, y : Int32
class MyClass
include ::EventHandler
end
c = MyClass.new
c.on(ClickedEvent) { |e| e.return_value += e.x + e.y }
event = c.emit ClickedEvent, 1,2
p event.return_value #=> 3
c.emit ClickedEvent, event
p event.return_value #=> 6
c.emit event
p event.return_value #=> 9
Please note the above example will work correctly as long as event handlers are invoked synchronously. Running one or more handlers asynchronously and checking for the return value after all handlers have finished execution is currently not addressed as part of built-in functionality.
To inspect the current list of installed handlers for an event, use handlers
:
my.handlers ClickedEvent
my.handlers(ClickedEvent).size
my.handlers(ClickedEvent).empty?
Please note that handlers
exposes the Array containing the list of handlers.
Modifying the array will directly modify the list of handlers defined for an event. This should only be done with due caution.
Event handlers can be removed in one of five ways:
By handler Proc:
handler = ClickedEvent::Handler.new do |e|
p "Hello"
end
my.on ClickedEvent, handler
my.off ClickedEvent, handler
By handler hash:
handler = ClickedEvent::Handler.new do |e|
p "Hello"
end
hash = handler.hash
my.on ClickedEvent, handler
my.off ClickedEvent, hash
By handler wrapper object:
handler = ClickedEvent::Handler.new {
p "Hello"
}
wrapper = my.on ClickedEvent, handler
my.off ClickedEvent, wrapper
Internally, handlers are always removed from events by removing their wrapper object.
When wrappers are created implicitly by on
, each invocation of on
gives handler a new wrapper object even if the same handler is added multiple
times for the same event. A call to
off()
will find the first instance of this handler, then remove all
instances of its wrapper from the list (there will be only one), and then
invoke RemoveHandlerEvent
with that instance as argument.
If a handler is added to an event more than once, it will be necessary to call
off()
multiple times to remove all instances.
When handlers are added by using their wrappers directly, multiple identical
wrapper objects will be present in the list.
When off()
is used to remove such handlers, all instances of their wrapper
will be removed from the list (there will be more than one) and RemoveHandlerEvent
will be invoked with the last removed instance as argument.
Whether off(Event, handler | hash)
should be removing handlers by
wrapper (like it does now) or by handler, and whether off()
should remove
all instances (like it does now) or at most one, is still being considered.
By handler index in the handlers
Array:
my.off ClickedEvent, at: 0
By removing all handlers at once:
# With off
my.off ClickedEvent
# With remove_all_handlers
my.remove_all_handlers ClickedEvent
When all handlers are removed at once, RemoveHandlerEvent
s will be emitted as
expected, and any multiple identical wrappers will be removed according to the
above-documented behavior.
If emitting RemoveHandlerEvent
events should be disabled when removing all handlers,
provide argument emit to off
or remove_all_handlers
, or use
EventHandler.emit_on_remove_all?
and EventHandler.emit_on_remove_all=
to change the default behavior.
There are three built-in events:
AddHandlerEvent
- Event emitted after a handler is added for any event, including itself.
RemoveHandlerEvent
- Event emitted after a handler is removed from any event, including itself.
AnyEvent
- Event emitted on any event. Adding a handler for this event allows listening for all emitted events and their arguments.
As mentioned, a wrapper object is implicitly created around a handler on every on
, to encapsulate the handler and its
subscription options (the values of once?
, async?
, and at
).
When AddHandlerEvent
or RemoveHandlerEvent
are emitted, they are invoked with the
handlers' Wrapper
object as argument.
This allows listeners on these two meta events full insight into the added or removed handlers and their subscription data.
Emitted events can also be sent through Channels. EventHandler comes with convenience types and functions for this purpose:
Channels can be created with Channel(T) or an aliased type:
# With Channel(T)
channel = Channel(ClickedEvent).new
# With an aliased type
channel = ClickedEvent::Channel.new
Invoking on
with a Channel argument will implicitly create a handler that
forwards emitted events to the Channel:
my.on ClickedEvent, channel, async: true
The same behavior can also be implemented manually:
channel = Channel(ClickedEvent).new
my.on ClickedEvent, async: true do |e|
channel.send e
end
A complete example:
require "event_handler"
EventHandler.event ClickedEvent, x : Int32, y : Int32
class My
include EventHandler
end
my = My.new
# Create a channel, wait for event, and print it
channel = ClickedEvent::Channel.new
my.once ClickedEvent, channel, async: true
my.emit(ClickedEvent, 1,2)
p channel.receive
# Same as above, implemented manually
channel = Channel(ClickedEvent).new
my.once ClickedEvent, async: true do |e|
channel.send e
end
my.emit(ClickedEvent, 1,2)
p channel.receive
Using Channels, it is also possible to wait for events.
The above example already shows blocking on channel.receive
.
The same effect can be achieved using convenience method wait
and
avoiding visible use of Channels:
e = my.wait(ClickedEvent)
wait
can also be invoked with code. The accepted syntax and
arguments are the same as for once
:
# With a block
my.wait ClickedEvent do |e|
p "Hello"
end
# With a Proc
handler = ClickedEvent::Handler.new do |e|
p "Hello"
end
my.wait ClickedEvent, handler
# With a method
def on_clicked(e : ClickedEvent) : Nil
p "Hello"
end
my.wait(ClickedEvent, ->on_clicked(ClickedEvent))
When waiting for events with code, two handlers are involved:
The first, visible one is the handler provided to
wait
, containing code to execute once the event arrives.
wait
argument async controls whether this handler will
run synchronously or asynchronously after the event has been
waited. This is consistent with the usual behavior and the
default value is false
(EventHandler.async?
).
The other, implicit one is the handler automatically created
and added to the list of event handlers. Once the event is
emitted and this handler runs, it will forward the received
event into the Channel.
wait
argument async_send controls whether the event emitter
will block on channel.send
or it will execute it in
a new fiber. The default value is false
(EventHandler.async_send?
).
Event classes can be subclassed with no restrictions:
require "event_handler"
EventHandler.event ClickedEvent, x : Int32, y : Int32
class DoubleClickedEvent < ClickedEvent
end
class TripleClickedEvent < DoubleClickedEvent
def initialize(@x : Int32, @y : Int32)
@z = 0
end
def initialize(@x : Int32, @y : Int32, @z : Int32)
end
end
class My
include EventHandler
def initialize
on(ClickedEvent) {|e| p e }
on(DoubleClickedEvent) {|e| p e }
on(TripleClickedEvent) {|e| p e }
end
end
my = My.new
my.emit ClickedEvent, 1, 2
my.emit DoubleClickedEvent, 3, 4
my.emit TripleClickedEvent, 5, 6
my.emit TripleClickedEvent, 7, 8, 9
Here is an example of an Event subclass that counts the number of times the event was instantiated:
require "event_handler"
abstract class EventWithCount < ::EventHandler::Event
class_property count : UInt64 = 0
def initialize
@@count += 1
end
end
class ClickedEvent < EventWithCount
getter x : Int32
getter y : Int32
def initialize(@x, @y)
super()
end
end
class My; include EventHandler end
my = My.new
4.times { my.emit ClickedEvent, 1, 2 }
p ClickedEvent.count #=> 4
Run crystal docs
as usual, then open file docs/index.html
.
Also, see examples in the directory examples/
.
Run crystal spec
as usual.
Also, see examples in the directory examples/
.
-
All the fine folks on Libera.Chat IRC channel #crystal-lang and on Crystal's Gitter channel https://gitter.im/crystal-lang/crystal
-
Blacksmoke16 for a workable event model design
-
Asterite, Absolutejam, and Tenebrousedge for additional discussion
List of interesting or similar projects in no particular order:
-
https://github.com/Papierkorb/cute - Event-centric pub/sub model for objects inspired by the Qt framework
-
https://github.com/hugoabonizio/event_emitter.cr - Idiomatic asynchronous event-driven architecture
-
https://github.com/vladfaust/callbacks.cr - Expressive callbacks module for Crystal
-
https://github.com/anykeyh/await_async - Provide await and async methods to Crystal
-
https://github.com/firejox/CrSignals - Signals/slots notification library in Crystal
-
https://github.com/crystal-community/future.cr - Provides delay, future, and lazy convenient methods
For licensing to use in your next project, consider https://perens.com/2020/10/06/post-open-source-license-early-draft/ and https://licenseuse.org/.