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This post has the comment if you need to call the method multiple times, use reflection once to find it, then assign it to a delegate, and then call the delegate..

  • How and why does this delegate work faster? Can anyone has some example?
  • Can I call this caching? If so, are there any other method than this caching method with delegate?


I came up with an example of using delegate here.

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5 Answers 5

up vote 4 down vote accepted

A delegate is simply a pointer to a function. If you're using reflection (at all) there is generally a lot of overhead associated with it. By finding this methods address once and assigning that address to your delegate variable, you are in effect caching it.

So, it's not the "delegate" type that works faster, it's just that you're "computing" once and "using" it multiple times that grants you the speed increase.

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A delegate is not a pointer. Managed C# code does not have pointers. It has references. No variable in managed C# code holds memory addresses (unless you're doing some nasty work intentionally meant for that). –  Neowizard Jun 21 '11 at 19:02
@Neowizard I appreciate the nit-picking, however I call a spade a spade. –  Brandon Moretz Jun 21 '11 at 19:05
@Brandon think about the lambda () => x++; where x is a local var in the method defining the lambda. If a delegate is just a pointer, then where is this lambda stored in memory and why is there a reference to x there? Like Haris said, delegates are not pointers they are objects who hold an instance (or more accurately a instance scope) and a method (call it a pointer to a method if you must). The concept of Lambda/Delegate is derived from functional programming where the concept of pointers usually doesn't even exists. –  Neowizard Jun 21 '11 at 19:11
@Neowizard the concept is the same, and has been the same since Dennis Ritchie introduced it via the "C" language. In your example, "x" is a local variable scoped to that particular function, it DOES NOT have anything to do with the "owning" function entry point being an ADDRESS in memory. Call that address a "reference" or a "pointer", it does not matter. –  Brandon Moretz Jun 21 '11 at 19:20
@Brandon that's just it, I'm not calling the address anything, there is no address to begin with. Saying that a delegate is a pointer to a function is like saying that C# String is no different then C's char*, and if that's what you're saying then this is not the right place for this mild debate to begin with. –  Neowizard Jun 21 '11 at 19:31


Probably the best docs on MSDN :)

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Obviously it will work faster because of the reduced overheard caused by reflection. If you follow the tip, you won't go for reflection each time rather you will store reference in a delegate and hence you are reducing cost by not redoing the reflection. So yes, it will act like caching i guess once you are storing reference in a delegate in a sense that you won't have to go to reflection again

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Fist off, this is not caching. You are not saving a copy of the method in a "closer" location, you're just holding on to a reference to that method.

Think about the steps needed to take in order to call a method using reflection (accessing the reflation data from the assembly, looking up the method/namespace/class by name and more...), the last step is getting a reference (and don't let anyone tell you that a delegate is a pointer!) to the method and invoking it. When you use a delegate you only take the last step, and save yourself all that headache that comes with reflection.

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+1 for the first sentence –  nawfal Apr 28 '13 at 5:30

Isn't it obvious. You load the assembly into your app domain; create an instance of the type, and then create a delegate pointing to that instance's method...

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