When I use Expression.Lambda( ... ).Compile() in order to create a delegate from an expression tree, the result is a delegate of which the first argument is Closure.

public static Func<T, T, T> CreateTest<T>()
    ParameterExpression a = Expression.Parameter( typeof( T ) );
    ParameterExpression b = Expression.Parameter( typeof( T ) );
    Expression addition = Expression.Add( a, b );

    return (Func<T, T, T>)Expression.Lambda( addition, a, b ).Compile();


// 'addition' equals
// Int32 lambda_method(
//     System.Runtime.CompilerServices.Closure,
//     Int32,
//     Int32 )
Func<int, int, int> addition = DelegateHelper.CreateTest<int>();
int result = addition( 5, 5 );

I can easily call the delegate through ordinary code without passing a Closure object, but where does this Closure come from?

How can I call this delegate dynamically?

// The following does not work.
// Exception: MethodInfo must be a runtime MethodInfo object.    
MethodInfo additionMethod = addition.Method;
int result = (int)additionMethod.Invoke( null, new object[] { 5, 5 } );

Using expression trees it looks like I have to pass the Closure object.

PropertyInfo methodProperty
    = typeof( Delegate ).GetProperty( "Method", typeof( MethodInfo ) );
MemberExpression getDelegateMethod
    = Expression.Property( Expression.Constant( addition ), methodProperty );
Func<MethodInfo> getMethodInfo
    = (Func<MethodInfo>)Expression.Lambda( getDelegateMethod ).Compile();
// Incorrect number of arguments supplied for call to method
// 'Int32 lambda_method(System.Runtime.CompilerServices.Closure, Int32, Int32)'
Expression call
    = Expression.Call(
        Expression.Constant( 5 ), Expression.Constant( 5 ) );

This is a simplified example which doesn't make sense in its own right. What I am actually trying to achieve is to be able to wrap e.g. Func<Action<SomeObject>> with Func<Action<object>>. I can already do this for non nested delegates. This is useful during reflection, as discussed here.

How should I correctly initialize this Closure object, or how do I prevent it from being there?

  • 1
    @JonSkeet: I'll do my best, the problem is the total example is quite complex. I am attempting to call a previously compiled delegate recursively. While I try to extract a small subset of the problem, here you can already find the entire function. – Steven Jeuris Oct 28 '11 at 22:07
  • Yeah, making it shorter would certainly help :) – Jon Skeet Oct 28 '11 at 22:08
  • @JonSkeet: As a bit more information, the goal would be to allow creating wrapper functions so e.g. Action<Action<SomeType>> could be wrapped by Action<Action<object>>. This continues on my previous implementation which can only do this for Action<SomeType> to Action<object>. – Steven Jeuris Oct 28 '11 at 22:09
  • You realize that's not type-safe, right? Action<T> is contravariant, but Action<Action<T>> is effectively covariant. – Jon Skeet Oct 28 '11 at 22:10
  • Yes I do, but I use it during reflection where I know the types correspond, but I don't want to know about the specific types so I can support any type. I blogged about it in detail here. – Steven Jeuris Oct 28 '11 at 22:12

The Closure type you see is an implementation detail. The MSDN is pretty explicit about it:

This API supports the .NET Framework infrastructure and is not intended to be used directly from your code. Represents the runtime state of a dynamically generated method.

An expression tree can have a state.

The Closure instance will contain all the non literal constants that the lambda expression, well, closes over. It can also contain a chain of delegates for nested lambdas in expression trees.

To achieve this, the expression tree compiler uses a cute little trick. It generates in memory code using a DynamicMethod, that is by definition static. Yet, they're creating a delegate that is “closed over its first argument”. Meaning that the CLR will pass the target field of the delegate as a first argument of the static method, so you don't have to. Effectively hiding the Closure argument from you.

The solution to your problem is simple, don't try to call the method, invoke the delegate, either by using Delegate.DynamicInvoke when you're using reflection, or Expression.Invoke in the context of an expression tree.

  • This is great, thanks! My function was working recursively by calling itself with a new MethodInfo. I created a new one which accepts a delegate instead and uses Expression.Invoke to call it. After some major refactoring I'll commit the changes. I can now successfully wrap e.g. Func<SomeType, Func<int>> with Func<SomeType, Func<EnumType>>. Generic calculations with strong typed enums. :) Loving it. IEnumerable<FlagsEnum> setFlags = EnumHelper<FlagsEnum>.GetFlaggedValues( flags ); – Steven Jeuris Oct 30 '11 at 15:23
  • K, this is possible in .NET 4.0 using Enum as well, but I can use this 'delegate wrapper' in plenty of other scenarios. I did a short efficiency comparison with Enum and the difference is negligible. – Steven Jeuris Oct 31 '11 at 1:39

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