What controls where an event can be called? - c#

Say I have a class like this:
public class FauxIdentityForm
{
public Guid FormID { get; set; }
public event EventHandler Closed;
public void TheObjectWasClosed(EventArgs e)
{
Closed(this, e);
}
}
It is fine for me to call the Closed Event inside the TheObjectWasClosed method. But if, in a different class (even in the same file), I have a method like this:
public void CallTheEvent()
{
FauxIdentityForm _formIdentity = new FauxIdentityForm {FormID = Guid.NewGuid()};
_formIdentity.Closed(_formIdentity, null); // <-- Does not compile!
}
The call to Closed is shot down by the compiler (it wants me to only use += and -=).
So, is actually calling the event only allowed inside the class? Is that the limitation?
If so, is there anyway around it? And if not, why did the creators of C# do this? (It makes working with events very hard sometimes. I imagine there is a good reason and it is probably saving me from myself, but I would like to know it.)

It's complicated :)
What you're using is called a field-like event. When you declare one of those in your class, you're creating a field and an event. When you "call the event" you're actually invoking the delegate referred to by the field. As it's a private field, you have access to it within the class (and any nested types), but not outside.
Events themselves in C# only support add and remove operations. From the outside, callers can only subscribe to an event and unsubscribe from it. They can't raise it, or find out anything about who's subscribed. Of course, the class can provide a method which will raise the event, but the other class can't access the backing field for the event
I've written this up in more detail in an article about events and delegates.

In fact, Closed(this, e); is nothing but calling invoke on a private delegate. This is why only the class can call it.
C# hides all the complexity from you and it creates a private delegate of type event for you (you can use ILDASM to see all this).
This is private so it is not even protected. This is why it is recommended to use a protected method to raise the event so the subclasses could have access to the event.

So, is actually calling the event only allowed inside the class? Is that the limitation?
Yes
If so, is there anyway around it?
Only with the consent (help) from the FauxIdentityForm class. It could have a public OnClosed() method.
An Event is a lot like a property, one of its main purposes is encapsulation and that is what you ran into.

Related

ObservableDictionary event raiser

I'm studying some examples provided by Microsoft for win8 development. I opened BasicControls sample and noticed LayoutAwarePage class and more precisely ObservableDictionary class. Reading about implementing events and raising them I can't see who's responsible to raise MapChangedEventHandler event. Based on parameters I believe that private void InvokeMapChanged(CollectionChange change, K key) method do this. But according to MSDN we need to provide a protected method that begins with On which doesn't occur in ObservableDictionary.
So, who raises MapChangedEventHandler?
An event in a class can be raised from within the class without need of an additional method to that.
So, if MapChangedEventHandler is an event, it can be called from inside the class just by this:
if (MapChangedEventHandler != null)
MapChangedEventHandler( parameters );
The only motive I can see (I'm not an expert) to the existance of those OnWhatever methods is to allow raising events from outside the class, or from some derived class, since events can only be raised from inside the declaring class.
Those OnWhatever methods must be some good practice (not a rule, nor a compiler rule).
Maybe they also take care of some additional stuff together with raising the event.
If they are not provided, probably they are not meant to be called from outside or from a derived class.
By the way, the MapChangedEventHandler is not an event. It's a delegate.
Events can be of that type, but their names are independant.
Like this:
class TestClass
{
these are the events of the class:
public event MapChangedEventHandler SomeEvent1;
public event MapChangedEventHandler SomeEvent2;
public event MapChangedEventHandler SomeEvent3;
//now this method calls the events (events can only be raised from inside the class)
public void SomeMethod()
{
//do lots of stuff
if (SomeEvent1 != null) SomeEvent1(whatever arguments it takes);
//do other stuff
if (SomeEvent2 != null) SomeEvent2(another arguments);
}
//now, if you want to let derived classes to raise events...
protected void OnSomeEvent3(Same Parameters As MapChangedEventHandler)
{
if (SomeEvent3 != null) SomeEvent3(parameters);
}
}

different delegate uses

Possible Duplicate:
What is the difference between a delegate and events?
Possible Duplicate:
Difference between events and delegates and its respective applications
(copied from this duplicate)
When i have to raise an event i do this
public delegate void LogUserActivity(Guid orderGUID);
public event LogUserActivity ActivityLog;
even this works
public delegate void LogUserActivity(Guid orderGUID);
public LogUserActivity ActivityLog;
What is the difference between two of them
There are three things here:
Declaring a delegate type
Creating a public variable of a delegate type
Creating a public event of a delegate type
The variable is just a normal variable - anyone can read from it, assign to it etc. An event only exposes subscribe/unsubscribe abilities to the outside world. A field-like event as you've shown here effectively has a "default" subscribe/unsubscribe behaviour, stored in a field with the same name. Within the declaring class, you access the field; outside you access the event.
I have an article about events and delegates which explains in more detail.
EDIT: To answer the comment, you can easily initialize a field-like event with a "no-op" handler:
public event LogUserActivity ActivityLog = delegate{};
Events and public delegates differ in one big way that keeps me from using public delegates in most cases:
Event:
obj.ActivityLog = null; // invalid
Public Delegate:
obj.ActivityLog = null; // valid
This matters, because I only want the subscriber to add/remove themselves from the list in most cases. I don't want other objects unhooking events from other subscribers.
In cases where the delegate is less of an event and more of a callback, I tend to use public methods to do this and keep the public delegate from being exposed directly:
obj.RegisterActivityCallback(...)
An event is an abstraction over a delegate, just as a property is an abstraction over a field. And - just like a property - an event allows you to gain fine control over what happens when a handler is added/removed:
public event LogUserActivity ActivityLog
{
add { ... }
remove { ... }
}
Indeed, your event may not have a delegate backing it at all, just like a property may not necessarily have a field backing it.
In the first case you can assign multiple listeners to your ActivityLog event as in:
logger.ActivityLog += new LogUserActivity(Listener1);
logger.ActivityLog += new LogUserActivity(Listener2);
Both methods (Listener1 and Listener2) will be called when the event is fired. In the second case you are not creating an event but a delegate. In this case you can only assign one listener:
logger.ActivityLog = new LogUserActivity(Listener1);
In this case you do not fire an event but instead you call the delegate. An event is really just a chain of delegates that are called in turn.
to add to all the previous answers, An event IS a delegate, of a specific type. A delegate is a type that is designed to act as a "smart" function pointer, or, putting it another way, as a smart "wrapper" for a function pointer, that allows the compiler to intelligently decide at compile time whether the function(s) you are sticking into the delegate are consistent with the uses you are making of the delegate (consistency is based on the function signature).
An event is a delegate with a specific signature, specifically, one that does not return anything (returns void), and takes two parameters, a System.object, to hold a reference to whatever object triggered the event, and an instance of some type derived from System.EventArgs, to hold whatever other data the event needs to carry with it from the initialtor to the handler.

WPF - Why there is no "OnDataContextChanged" overridable method?

The FrameworkElement object has DataContextChanged event. However, there is no OnDataContextChanged method that can be overridden.
Any ideas why?
If a method is virtual, then the user has the option to either augment the base functionalty by calling the base class method or replace the base class functionality by failing to call the base class method. For OnEvent() methods, if you don't call the base class method then the event will not be raised (that's the responsibility of the base class method.) If the base class performs some kind of state management inside of the OnEvent method, this means that the derived class can accidentally invalidate the state of the object if the user chooses to omit a call to the base class method. Documentation can specify "please always call the base class method", but there's no way to enforce it.
When I see an event that doesn't have a virtual OnEvent() method, I usually assume the method performs some kind of internal state management and the designers of the class want to guarantee their state management runs. This isn't the case in FrameworkElement, and it's not the only event that doesn't follow the pattern, so I'm curious what the reasoning is.
I dug around in Reflector to see if I could discover a reason. There is an OnDataContextChanged() method, but it's a dependency property change handler and doesn't follow the standard event pattern. This is probably the reason for not making it protected virtual. It's non-standard, so it would be confusing. It's static, so you wouldn't be able to override it anyway. Since it's called automatically by the dependency property framework and you are unable to override it, I believe we have the reason why it's private instead of static virtual.
You could use a different pattern to expose the normal event pattern:
class FrameworkElement
{
// difference: use DataContextPropertyChanged as the change callback
public static readonly DependencyProperty DataContextProperty = ...
protected virtual void OnDataContextChanged(...)
{
// raise the DataContextChanged event
}
private static void DataContextPropertyChanged(...)
{
((FrameworkElement)d).OnDataContextChanged(...);
}
}
My guess why they didn't do this? Usually you call OnEvent() to raise the event. The event is automatically raised when DataContext changes, and it doesn't make sense for you to raise it at any other time.
Good question.
I'm just guessing, but looking in Reflector I'd say it's just laziness, perhaps with a pinch of (unfounded?) performance concerns. FrameworkElement has a generic EventHandlersStore which is responsible for maintaining event information (delegates) for a whole bunch of events. The add and remove logic in the CLR events (such as DataContextChanged) simple call into the EventHandlersStore with the appropriate key.
There is a generic RaiseDependencyPropertyChanged method that is called to raise all different sorts of events. There is also a private OnDataContextChanged method that calls the RaiseDependencyPropertyChanged method. However, it is static and registered as part of the d-prop metadata.
So, in short, I see no technical reason not to include an overridable OnDataContextChanged method. Just looks like a short-cut in implementation to me.
Is this merely academic, or are you trying to achieve something here?
Silverlight Note:
At of Silverlight Beta 4 there IS no DataContextChanged event (well its not public at least).
The Microsoft Connect bug report has been marked as 'Fixed' but with no indication of what that actually means.
In the meantime you need a workaround such as this one from CodeProject - which is very simple and should be easy to switch out if Microsoft ever actually makes the event public.
Dependency properties usually don't have corresponding virtual methods for raising the event because it's expected that the change events will be managed by the dependecy property system itself.
What you can override however, to handle any dependency property changing is DependencyObject.OnPropertyChanged like so:
class MyClass : FrameworkElement {
protected override void OnPropertyChanged(DependencyPropertyChangedEventArgs e) {
base.OnPropertyChanged(e);
if (e.Property == FrameworkElement.DataContextProperty) {
// do something with e.NewValue/e.OldValue
}
}
}

Is it possible to raise an event on an object, from outside that object, without a custom function

public class a
{
public event eventhandler test;
public void RaiseTest(){//fire test}
}
Is it possible to raise test on this class, from outside this class, without calling the method?
Basically I have a large number of events which must be raised based on an external source, and do not want to create a Raise() function for each one.
Is it possible to create a generic Raise() that accepts the event to be raised as a parameter? therefore it would still be called from inside the class?
You can do this via Reflection, but it is less than obvious. If you declare an event in C#, a field will be added to the class with the event name + "Event". If you call GetValue on the field, it will return a MulticastDelegate instance.
Once you have the MulticastDelegate, you can get the invocation list, and invoke each member in turn:
EventArgs e = new EventArgs(myClassInstance); // Create appropriate EventArgs
MulticastDelegate eventDelagate =
this.GetType().GetField(theEventName + "Event",
System.Reflection.BindingFlags.Instance |
System.Reflection.BindingFlags.NonPublic).GetValue(myClassInstance) as MulticastDelegate;
Delegate[] delegates = eventDelagate.GetInvocationList();
foreach (Delegate del in delegates) {
del.Method.Invoke(del.Target, new object[] { myClassInstance, e });
}
Note that this requires getting a NonPublic field from the instance, so it will only work in full trust, and is very limited.
Is it possible to create a generic Raise() that accepts the event to be raised as a parameter? therefore it would still be called from inside the class?
Yes. It would be fairly easy to modify the above code to do this. Just replace "myClassInstance" with this. This will actually allow this to work properly in full trust, as well, since the NonPublic BindingFlag will no longer be an issue.
Is it possible to raise test on this class, from outside this class, without calling the method?
Short answer : no.
Only the class declaring the event can raise it
Is it possible to create a generic Raise() that accepts the event to be raised as a parameter? therefore it would still be called from inside the class?
I don't think so, at least not easily... Even using reflection, there is no EventInfo.Invoke method. AFAIK, the only way to raise the event is statically from within the class
EDIT: actually it can be done (see Reed's answer), but with the limitation that the app has to run in full trust.

Understanding events and event handlers in C#

I understand the purpose of events, especially within the context of creating user interfaces. I think this is the prototype for creating an event:
public void EventName(object sender, EventArgs e);
What do event handlers do, why are they needed, and how do I to create one?
To understand event handlers, you need to understand delegates. In C#, you can think of a delegate as a pointer (or a reference) to a method. This is useful because the pointer can be passed around as a value.
The central concept of a delegate is its signature, or shape. That is (1) the return type and (2) the input arguments. For example, if we create a delegate void MyDelegate(object sender, EventArgs e), it can only point to methods which return void, and take an object and EventArgs. Kind of like a square hole and a square peg. So we say these methods have the same signature, or shape, as the delegate.
So knowing how to create a reference to a method, let's think about the purpose of events: we want to cause some code to be executed when something happens elsewhere in the system - or "handle the event". To do this, we create specific methods for the code we want to be executed. The glue between the event and the methods to be executed are the delegates. The event must internally store a "list" of pointers to the methods to call when the event is raised.* Of course, to be able to call a method, we need to know what arguments to pass to it! We use the delegate as the "contract" between the event and all the specific methods that will be called.
So the default EventHandler (and many like it) represents a specific shape of method (again, void/object-EventArgs). When you declare an event, you are saying which shape of method (EventHandler) that event will invoke, by specifying a delegate:
//This delegate can be used to point to methods
//which return void and take a string.
public delegate void MyEventHandler(string foo);
//This event can cause any method which conforms
//to MyEventHandler to be called.
public event MyEventHandler SomethingHappened;
//Here is some code I want to be executed
//when SomethingHappened fires.
void HandleSomethingHappened(string foo)
{
//Do some stuff
}
//I am creating a delegate (pointer) to HandleSomethingHappened
//and adding it to SomethingHappened's list of "Event Handlers".
myObj.SomethingHappened += new MyEventHandler(HandleSomethingHappened);
//To raise the event within a method.
SomethingHappened("bar");
(*This is the key to events in .NET and peels away the "magic" - an event is really, under the covers, just a list of methods of the same "shape". The list is stored where the event lives. When the event is "raised", it's really just "go through this list of methods and call each one, using these values as the parameters". Assigning an event handler is just a prettier, easier way of adding your method to this list of methods to be called).
C# knows two terms, delegate and event. Let's start with the first one.
Delegate
A delegate is a reference to a method. Just like you can create a reference to an instance:
MyClass instance = myFactory.GetInstance();
You can use a delegate to create an reference to a method:
Action myMethod = myFactory.GetInstance;
Now that you have this reference to a method, you can call the method via the reference:
MyClass instance = myMethod();
But why would you? You can also just call myFactory.GetInstance() directly. In this case you can. However, there are many cases to think about where you don't want the rest of the application to have knowledge of myFactory or to call myFactory.GetInstance() directly.
An obvious one is if you want to be able to replace myFactory.GetInstance() into myOfflineFakeFactory.GetInstance() from one central place (aka factory method pattern).
Factory method pattern
So, if you have a TheOtherClass class and it needs to use the myFactory.GetInstance(), this is how the code will look like without delegates (you'll need to let TheOtherClass know about the type of your myFactory):
TheOtherClass toc;
//...
toc.SetFactory(myFactory);
class TheOtherClass
{
public void SetFactory(MyFactory factory)
{
// set here
}
}
If you'd use delegates, you don't have to expose the type of my factory:
TheOtherClass toc;
//...
Action factoryMethod = myFactory.GetInstance;
toc.SetFactoryMethod(factoryMethod);
class TheOtherClass
{
public void SetFactoryMethod(Action factoryMethod)
{
// set here
}
}
Thus, you can give a delegate to some other class to use, without exposing your type to them. The only thing you're exposing is the signature of your method (how many parameters you have and such).
"Signature of my method", where did I hear that before? O yes, interfaces!!! interfaces describe the signature of a whole class. Think of delegates as describing the signature of only one method!
Another large difference between an interface and a delegate is that when you're writing your class, you don't have to say to C# "this method implements that type of delegate". With interfaces, you do need to say "this class implements that type of an interface".
Further, a delegate reference can (with some restrictions, see below) reference multiple methods (called MulticastDelegate). This means that when you call the delegate, multiple explicitly-attached methods will be executed. An object reference can always only reference to one object.
The restrictions for a MulticastDelegate are that the (method/delegate) signature should not have any return value (void) and the keywords out and ref is not used in the signature. Obviously, you can't call two methods that return a number and expect them to return the same number. Once the signature complies, the delegate is automatically a MulticastDelegate.
Event
Events are just properties (like the get;set; properties to instance fields) which expose subscription to the delegate from other objects. These properties, however, don't support get;set;. Instead, they support add; remove;
So you can have:
Action myField;
public event Action MyProperty
{
add { myField += value; }
remove { myField -= value; }
}
Usage in UI (WinForms,WPF,UWP So on)
So, now we know that a delegate is a reference to a method and that we can have an event to let the world know that they can give us their methods to be referenced from our delegate, and we are a UI button, then: we can ask anyone who is interested in whether I was clicked, to register their method with us (via the event we exposed). We can use all those methods that were given to us and reference them by our delegate. And then, we'll wait and wait.... until a user comes and clicks on that button, then we'll have enough reason to invoke the delegate. And because the delegate references all those methods given to us, all those methods will be invoked. We don't know what those methods do, nor we know which class implements those methods. All we do care about is that someone was interested in us being clicked, and gave us a reference to a method that complied with our desired signature.
Java
Languages like Java don't have delegates. They use interfaces instead. The way they do that is to ask anyone who is interested in 'us being clicked', to implement a certain interface (with a certain method we can call), then give us the whole instance that implements the interface. We keep a list of all objects implementing this interface and can call their 'certain method we can call' whenever we get clicked.
That is actually the declaration for an event handler - a method that will get called when an event is fired. To create an event, you'd write something like this:
public class Foo
{
public event EventHandler MyEvent;
}
And then you can subscribe to the event like this:
Foo foo = new Foo();
foo.MyEvent += new EventHandler(this.OnMyEvent);
With OnMyEvent() defined like this:
private void OnMyEvent(object sender, EventArgs e)
{
MessageBox.Show("MyEvent fired!");
}
Whenever Foo fires off MyEvent, then your OnMyEvent handler will be called.
You don't always have to use an instance of EventArgs as the second parameter. If you want to include additional information, you can use a class derived from EventArgs (EventArgs is the base by convention). For example, if you look at some of the events defined on Control in WinForms, or FrameworkElement in WPF, you can see examples of events that pass additional information to the event handlers.
Here is a code example which may help:
using System;
using System.Collections.Generic;
using System.Text;
namespace Event_Example
{
// First we have to define a delegate that acts as a signature for the
// function that is ultimately called when the event is triggered.
// You will notice that the second parameter is of MyEventArgs type.
// This object will contain information about the triggered event.
public delegate void MyEventHandler(object source, MyEventArgs e);
// This is a class which describes the event to the class that receives it.
// An EventArgs class must always derive from System.EventArgs.
public class MyEventArgs : EventArgs
{
private string EventInfo;
public MyEventArgs(string Text) {
EventInfo = Text;
}
public string GetInfo() {
return EventInfo;
}
}
// This next class is the one which contains an event and triggers it
// once an action is performed. For example, lets trigger this event
// once a variable is incremented over a particular value. Notice the
// event uses the MyEventHandler delegate to create a signature
// for the called function.
public class MyClass
{
public event MyEventHandler OnMaximum;
private int i;
private int Maximum = 10;
public int MyValue
{
get { return i; }
set
{
if(value <= Maximum) {
i = value;
}
else
{
// To make sure we only trigger the event if a handler is present
// we check the event to make sure it's not null.
if(OnMaximum != null) {
OnMaximum(this, new MyEventArgs("You've entered " +
value.ToString() +
", but the maximum is " +
Maximum.ToString()));
}
}
}
}
}
class Program
{
// This is the actual method that will be assigned to the event handler
// within the above class. This is where we perform an action once the
// event has been triggered.
static void MaximumReached(object source, MyEventArgs e) {
Console.WriteLine(e.GetInfo());
}
static void Main(string[] args) {
// Now lets test the event contained in the above class.
MyClass MyObject = new MyClass();
MyObject.OnMaximum += new MyEventHandler(MaximumReached);
for(int x = 0; x <= 15; x++) {
MyObject.MyValue = x;
}
Console.ReadLine();
}
}
}
Just to add to the existing great answers here - building on the code in the accepted one, which uses a delegate void MyEventHandler(string foo)...
Because the compiler knows the delegate type of the SomethingHappened event, this:
myObj.SomethingHappened += HandleSomethingHappened;
Is totally equivalent to:
myObj.SomethingHappened += new MyEventHandler(HandleSomethingHappened);
And handlers can also be unregistered with -= like this:
// -= removes the handler from the event's list of "listeners":
myObj.SomethingHappened -= HandleSomethingHappened;
For completeness' sake, raising the event can be done like this, only in the class that owns the event:
//Firing the event is done by simply providing the arguments to the event:
var handler = SomethingHappened; // thread-local copy of the event
if (handler != null) // the event is null if there are no listeners!
{
handler("Hi there!");
}
The thread-local copy of the handler is needed to make sure the invocation is thread-safe - otherwise a thread could go and unregister the last handler for the event immediately after we checked if it was null, and we would have a "fun" NullReferenceException there.
C# 6 introduced a nice short hand for this pattern. It uses the null propagation operator.
SomethingHappened?.Invoke("Hi there!");
My understanding of the events is;
Delegate:
A variable to hold reference to method / methods to be executed. This makes it possible to pass around methods like a variable.
Steps for creating and calling the event:
The event is an instance of a delegate
Since an event is an instance of a delegate, then we have to first define the delegate.
Assign the method / methods to be executed when the event is fired (Calling the delegate)
Fire the event (Call the delegate)
Example:
using System;
namespace test{
class MyTestApp{
//The Event Handler declaration
public delegate void EventHandler();
//The Event declaration
public event EventHandler MyHandler;
//The method to call
public void Hello(){
Console.WriteLine("Hello World of events!");
}
public static void Main(){
MyTestApp TestApp = new MyTestApp();
//Assign the method to be called when the event is fired
TestApp.MyHandler = new EventHandler(TestApp.Hello);
//Firing the event
if (TestApp.MyHandler != null){
TestApp.MyHandler();
}
}
}
}
//This delegate can be used to point to methods
//which return void and take a string.
public delegate void MyDelegate(string foo);
//This event can cause any method which conforms
//to MyEventHandler to be called.
public event MyDelegate MyEvent;
//Here is some code I want to be executed
//when SomethingHappened fires.
void MyEventHandler(string foo)
{
//Do some stuff
}
//I am creating a delegate (pointer) to HandleSomethingHappened
//and adding it to SomethingHappened's list of "Event Handlers".
myObj.MyEvent += new MyDelegate (MyEventHandler);
publisher: where the events happen. Publisher should specify which delegate the class is using and generate necessary arguments, pass those arguments and itself to the delegate.
subscriber: where the response happen. Subscriber should specify methods to respond to events. These methods should take the same type of arguments as the delegate. Subscriber then add this method to publisher's delegate.
Therefore, when the event happen in publisher, delegate will receive some event arguments (data, etc), but publisher has no idea what will happen with all these data. Subscribers can create methods in their own class to respond to events in publisher's class, so that subscribers can respond to publisher's events.
I recently made an example of how to use events in c#, and posted it on my blog. I tried to make it as clear as possible, with a very simple example. In case it might help anyone, here it is: http://www.konsfik.com/using-events-in-csharp/
It includes description and source code (with lots of comments), and it mainly focuses on a proper (template - like) usage of events and event handlers.
Some key points are:
Events are like "sub - types of delegates", only more constrained (in a good way). In fact an event's declaration always includes a delegate (EventHandlers are a type of delegate).
Event Handlers are specific types of delegates (you may think of them as a template), which force the user to create events which have a specific "signature". The signature is of the format: (object sender, EventArgs eventarguments).
You may create your own sub-class of EventArgs, in order to include any type of information the event needs to convey. It is not necessary to use EventHandlers when using events. You may completely skip them and use your own kind of delegate in their place.
One key difference between using events and delegates, is that events can only be invoked from within the class that they were declared in, even though they may be declared as public. This is a very important distinction, because it allows your events to be exposed so that they are "connected" to external methods, while at the same time they are protected from "external misuse".
Another thing to know about, in some cases, you have to use the Delegates/Events when you need a low level of coupling !
If you want to use a component in several place in application, you need to make a component with low level of coupling and the specific unconcerned LOGIC must be delegated OUTSIDE of your component ! This ensures that you have a decoupled system and a cleaner code.
In SOLID principle this is the "D", (Dependency inversion principle).
Also known as "IoC", Inversion of control.
You can make "IoC" with Events, Delegates and DI (Dependency Injection).
It's easy to access a method in a child class. But more difficult to access a method in a parent class from child. You have to pass the parent reference to the child ! (or use DI with Interface)
Delegates/Events allows us to communicate from the child to the parent without reference !
In this diagram above, I do not use Delegate/Event and the parent component B has to have a reference of the parent component A to execute the unconcerned business logic in method of A. (high level of coupling)
With this approach, I would have to put all the references of all components that use component B ! :(
In this diagram above, I use Delegate/Event and the component B doesn't have to known A. (low level of coupling)
And you can use your component B anywhere in your application !
I agree with KE50 except that I view the 'event' keyword as an alias for 'ActionCollection' since the event holds a collection of actions to be performed (ie. the delegate).
using System;
namespace test{
class MyTestApp{
//The Event Handler declaration
public delegate void EventAction();
//The Event Action Collection
//Equivalent to
// public List<EventAction> EventActions=new List<EventAction>();
//
public event EventAction EventActions;
//An Action
public void Hello(){
Console.WriteLine("Hello World of events!");
}
//Another Action
public void Goodbye(){
Console.WriteLine("Goodbye Cruel World of events!");
}
public static void Main(){
MyTestApp TestApp = new MyTestApp();
//Add actions to the collection
TestApp.EventActions += TestApp.Hello;
TestApp.EventActions += TestApp.Goodbye;
//Invoke all event actions
if (TestApp.EventActions!= null){
//this peculiar syntax hides the invoke
TestApp.EventActions();
//using the 'ActionCollection' idea:
// foreach(EventAction action in TestApp.EventActions)
// action.Invoke();
}
}
}
}
Great technical answers in the post! I have nothing technically to add to that.
One of the main reasons why new features appear in languages and software in general is marketing or company politics! :-) This must not be under estimated!
I think this applies to certain extend to delegates and events too! i find them useful and add value to the C# language, but on the other hand the Java language decided not to use them! they decided that whatever you are solving with delegates you can already solve with existing features of the language i.e. interfaces e.g.
Now around 2001 Microsoft released the .NET framework and the C# language as a competitor solution to Java, so it was good to have NEW FEATURES that Java doesn't have.
DELEGATES, EVENTS(EVENT HANDLERS/EVENT LISTENERS), CONCEPTS(MULTICASTING/BROADCASTING), ACTION & FUNC
This will be a long one but its the simplest explanation, the problem this is such a nuisance of a topic is because people are just using different words to explain the same thing
First of all, you should know a few things
DELEGATES: It's nothing but a list of methods, why create a list? because when your code is being executed, that list is taken and every method there is executed one by one, just don't listen to textbook definitions take this and you will be all right
also called :
a pointer to a function
a wrapper for a method that can send and receive methods just like a variable
to create a delegate you go
[[access modifier] delegate [return type] [delegate name]([parameters])]
example: public delegate int demo(int a);
now to execute all these methods stored in a list called delegate, you go
1. demo.invoke(a);
2. demo(a); ..... both are valid
using the dot and explicitly saying invoke shines in async programming where you use beginInvoke, but that is out of the scope of this topic
there is one more thing called "Creating an object of the delegate/instantiate Delegate" which is pretty much as it sounds but just to avoid confusion it goes like (for the above example )
example : demo del = new demo(); (or) Public demo del = null;
to add any method to the list called delegate you go += and you also need to remove it once the "requirements of the methods are met" you go -=
(requirements of the methods are met mean you no longer need the method to be active or aka "listening") if you don't remove it, it could cause a "memory leak" meaning your computers ram will be eaten alive, technically allocated memory will not be released
example: say there is a method
public int calculate (int c)
to add this method to delegate you go
1. del = calculate;
2. del += calculate; .... all are valid
to remove
del -= calculate
first of all notice the similarities between the delegate and the method, the return type(output) and the input/parameters are the same, and that is a rule you just cannot add any random or a bunch of methods in a delegate it needs to follow the input-output rule
now why are there 2 different ways to do one thing, the only thing different is the assignment operators (+, =), this introduces a new topic called
EVENTS
which is nothing but a constrained version of a Delegate, It's still a List of methods don't confuse when people explain these terminologies, they change the name, so stick with this to understand
what is the constraint? you cannot do this del = calculate;
what's the harm in it, say a bunch of methods are added to the Delegate(List), you do that 👆 all are wiped out and only a single method "calculate" remains, so to prevent that Events are used,
Event Syntax
Public Event demo del = null;
One more thing you cannot do with events is invoke the delegate directly like demo.invoke since its public it can be accessed and invoked but with events, it can't
now you just add the methods to the event (a special type of delegate)
when to use an event vs a delegate, depends on your situation but pragmatically events are popular
few more keywords
MULTICASTING: nothing but adding more than one method to a delegate
BROADCASTING: adding more than one method to an event
PUBLISHER: the one that executes the method (term used in broadcasting), only a single entity
SUBSCRIBER: The methods that are being executed, can be multiple
LISTENER: the same thing as a subscriber but the term is used in multicasting
EVENT HANDLER: same thing as a subscriber/event listener so what the difference? it's basically the same thing, some say an eventlistener detect for the event to occur and the event handler "handles" or execute the code, ITS THE SAME THING PRACTICALLY!
action and func are just delegates that have been created and instantiated so 2 lines of code in a word, the difference is just in return types
ACTION: does not return anything while taking 0 or more than 1 input
FUNC: returns one thing and takes in parameters
if you don't do good with reading here is the best video on this topic
https://www.youtube.com/playlist?list=PLFt_AvWsXl0dliMtpZC8Qd_ru26785Ih_

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