I have the following code:

Func<string, bool> comparer = delegate(string value) {
    return value != "0";

However, the following does not compile:

var comparer = delegate(string value) {
    return value != "0";

Why can't the compiler figure out it is a Func<string, bool>? It takes one string parameter, and returns a boolean. Instead, it gives me the error:

Cannot assign anonymous method to an implicitly-typed local variable.

I have one guess and that is if the var version compiled, it would lack consistency if I had the following:

var comparer = delegate(string arg1, string arg2, string arg3, string arg4, string arg5) {
    return false;

The above wouldn't make sense since Func<> allows only up to 4 arguments (in .NET 3.5, which is what I am using). Perhaps someone could clarify the problem. Thanks.

  • 3
    Note about your 4 arguments argument, in .NET 4, Func<> accepts up to 16 arguments. Commented Feb 11, 2011 at 4:23
  • Thanks for the clarification. I'm using .NET 3.5.
    – Marlon
    Commented Feb 11, 2011 at 4:24
  • 9
    Why would make the compiler think that's a Func<string, bool>? It looks like a Converter<string, bool> to me!
    – Ben Voigt
    Commented Feb 11, 2011 at 4:46
  • possible duplicate of Why can't c# use inline anonymous lambdas or delegates?
    – nawfal
    Commented May 29, 2013 at 13:08
  • 3
    sometimes I miss VB .. Dim comparer = Function(value$) value <> "0"
    – Slai
    Commented Apr 28, 2016 at 14:37

9 Answers 9


UPDATE: This answer was written over ten years ago and should be considered to be of historical interest; in C# 10 the compiler will infer some delegate types.

Others have already pointed out that there are infinitely many possible delegate types that you could have meant; what is so special about Func that it deserves to be the default instead of Predicate or Action or any other possibility? And, for lambdas, why is it obvious that the intention is to choose the delegate form, rather than the expression tree form?

But we could say that Func is special, and that the inferred type of a lambda or anonymous method is Func of something. We'd still have all kinds of problems. What types would you like to be inferred for the following cases?

var x1 = (ref int y)=>123;

There is no Func<T> type that takes a ref anything.

var x2 = y=>123;

We don't know the type of the formal parameter, though we do know the return. (Or do we? Is the return int? long? short? byte?)

var x3 = (int y)=>null;

We don't know the return type, but it can't be void. The return type could be any reference type or any nullable value type.

var x4 = (int y)=>{ throw new Exception(); }

Again, we don't know the return type, and this time it can be void.

var x5 = (int y)=> q += y;

Is that intended to be a void-returning statement lambda or something that returns the value that was assigned to q? Both are legal; which should we choose?

Now, you might say, well, just don't support any of those features. Just support "normal" cases where the types can be worked out. That doesn't help. How does that make my life easier? If the feature works sometimes and fails sometimes then I still have to write the code to detect all of those failure situations and give a meaningful error message for each. We still have to specify all that behaviour, document it, write tests for it, and so on. This is a very expensive feature that saves the user maybe half a dozen keystrokes. We have better ways to add value to the language than spending a lot of time writing test cases for a feature that doesn't work half the time and doesn't provide hardly any benefit in cases where it does work.

The situation where it is actually useful is:

var xAnon = (int y)=>new { Y = y };

because there is no "speakable" type for that thing. But we have this problem all the time, and we just use method type inference to deduce the type:

Func<A, R> WorkItOut<A, R>(Func<A, R> f) { return f; }
var xAnon = WorkItOut((int y)=>new { Y = y });

and now method type inference works out what the func type is.

  • 49
    When are you going to compile your SO answers into a book? I'd buy it :)
    – Matt Greer
    Commented Feb 11, 2011 at 16:13
  • 13
    I second the proposal for an Eric Lippert book of SO answers. Suggested title: "Reflections From The Stack" Commented Feb 17, 2011 at 20:54
  • 27
    @Eric: Good answer, but it's slightly misleading to illustrate this as something that's not possible, as this actually works completely fine in D. It's just that you guys didn't choose to give delegate literals their own type, and instead made them depend on their contexts... so IMHO the answer should be "because that's how we made it" more than anything else. :)
    – user541686
    Commented Aug 1, 2011 at 11:24
  • 5
    @abstractdissonance I note also that the compiler is open source. If you care about this feature then you can donate the necessary time and effort to make it happen. I encourage you to submit a pull request. Commented Jun 17, 2017 at 18:41
  • 8
    @AbstractDissonance: We measured the cost in terms of the limited resources: developers and time. This responsibility was not granted by god; it was imposed by the vice president of the developer division. The notion that somehow the C# team could ignore a budget process is a strange one. I assure you, tradeoffs were and still are made by the careful, thoughtful consideration of experts who had the C# communities expressed wishes, the strategic mission for Microsoft, and their own excellent taste in design in mind. Commented Jun 18, 2017 at 14:01

Only Eric Lippert knows for sure, but I think it's because the signature of the delegate type doesn't uniquely determine the type.

Consider your example:

var comparer = delegate(string value) { return value != "0"; };

Here are two possible inferences for what the var should be:

Predicate<string> comparer  = delegate(string value) { return value != "0"; };  // okay
Func<string, bool> comparer = delegate(string value) { return value != "0"; };  // also okay

Which one should the compiler infer? There's no good reason to choose one or the other. And although a Predicate<T> is functionally equivalent to a Func<T, bool>, they are still different types at the level of the .NET type system. The compiler therefore cannot unambiguously resolve the delegate type, and must fail the type inference.

  • 1
    I'm sure quite a few other people at Microsoft also know for sure. ;) But yes, you allude to a chief reason, the compile time type cannot be determined because there is none. Section 8.5.1 of the language specification specifically highlights this reason for disallowing anonymous functions from being used in implicitly typed variable declarations. Commented Feb 11, 2011 at 4:47
  • 3
    Yep. And even worse, for lambdas we don't even know if it is going to a delegate type; it might be an expression tree. Commented Feb 11, 2011 at 6:45
  • For anyone interested, I wrote up a bit more about this and how the C# and F# approaches contrast at mindscapehq.com/blog/index.php/2011/02/23/…
    – itowlson
    Commented Feb 23, 2011 at 23:33
  • why can't the compiler just fabricate a new unique type like C++ does for its lambda function
    – Weipeng
    Commented Jul 25, 2018 at 17:29
  • How do they differ "at the level of the .NET type system"?
    – arao6
    Commented Dec 1, 2019 at 8:39

Eric Lippert has an old post about it where he says

And in fact the C# 2.0 specification calls this out. Method group expressions and anonymous method expressions are typeless expressions in C# 2.0, and lambda expressions join them in C# 3.0. Therefore it is illegal for them to appear "naked" on the right hand side of an implicit declaration.

  • And this is underscored by section 8.5.1 of the language specification. "The initializer expression must have a compile-time type" in order to be used for a implicitly typed local variable. Commented Feb 11, 2011 at 4:49

Different delegates are considered different types. e.g., Action is different than MethodInvoker, and an instance of Action can't be assigned to a variable of type MethodInvoker.

So, given an anonymous delegate (or lambda) like () => {}, is it an Action or a MethodInvoker? The compiler can't tell.

Similarly, if I declare a delegate type taking a string argument and returning a bool, how would the compiler know you really wanted a Func<string, bool> instead of my delegate type? It can't infer the delegate type.


The following points are from the MSDN regarding Implicitly Typed Local Variables:

  1. var can only be used when a local variable is declared and initialized in the same statement; the variable cannot be initialized to null, or to a method group or an anonymous function.
  2. The var keyword instructs the compiler to infer the type of the variable from the expression on the right side of the initialization statement.
  3. It is important to understand that the var keyword does not mean "variant" and does not indicate that the variable is loosely typed, or late-bound. It just means that the compiler determines and assigns the most appropriate type.

MSDN Reference: Implicitly Typed Local Variables

Considering the following regarding Anonymous Methods:

  1. Anonymous methods enable you to omit the parameter list.

MSDN Reference: Anonymous Methods

I would suspect that since the anonymous method may actually have different method signatures, the compiler is unable to properly infer what the most appropriate type to assign would be.


My post doesn't answer the actual question, but it does answer the underlying question of :

"How do I avoid having to type out some fugly type like Func<string, string, int, CustomInputType, bool, ReturnType>?" [1]

Being the lazy/hacky programmer that I am, I experimented with using Func<dynamic, object> - which takes a single input parameter and returns an object.

For multiple arguments, you can use it like so:

dynamic myParams = new ExpandoObject();
myParams.arg0 = "whatever";
myParams.arg1 = 3;
Func<dynamic, object> y = (dynObj) =>
    return dynObj.arg0.ToUpper() + (dynObj.arg1 * 45); //screw type casting, amirite?

Tip: You can use Action<dynamic> if you don't need to return an object.

Yeah I know it probably goes against your programming principles, but this makes sense to me and probably some Python coders.

I'm pretty novice at delegates... just wanted to share what I learned.

[1] This assumes that you aren't calling a method that requires a predefined Func as a parameter, in which case, you'll have to type that fugly string :/


Other answers were correct at the time they were written, but starting from C# 10.0 (from 2021), the compiler can infer a suitable delegate type (like some Func<...>, Action<...> or generated delegate type) in such cases.

See C# 10 Features - Lambda improvements.

var comparer = delegate(string value) {
    return value != "0";
};   // OK in C# 10.0, picks 'Func<string, bool>' in this case

Of course the more usual syntax is to us =>, so:

var comparer = (string value) => {
    return value != "0";
};   // OK in C# 10.0, picks 'Func<string, bool>' in this case
  • Or even shorter var comparer = (string value) => value != "0";
    – wertzui
    Commented Sep 21, 2022 at 7:28

How is about that?

var item = new
        toolisn = 100,
        LangId = "ENG",
        toolPath = (Func<int, string, string>) delegate(int toolisn, string LangId)
              var path = "/Content/Tool_" + toolisn + "_" + LangId + "/story.html";
              return File.Exists(Server.MapPath(path)) ? "<a style=\"vertical-align:super\" href=\"" + path + "\" target=\"_blank\">execute example</a> " : "";

string result = item.toolPath(item.toolisn, item.LangId);

I would like to share my experience over here.

I was having a Task based void method, and I was invoking that method from somewhere else and storing the return value in variable.

I was doing that test purpose, but later on I realized that it was a void task method and it is not returning any response.

I removed that variable storing code and it worked.


var test = await function(argument1);


await function(argument1);

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