Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Why is this a compile time error?

public TCastTo CastMe<TSource, TCastTo>(TSource i)
     return (TCastTo)i;


annot convert type 'TSource' to 'TCastTo'

And why is this a runtime error?

public TCastTo CastMe<TSource, TCastTo>(TSource i)
     return (TCastTo)(object)i;

int a = 4;
long b = CastMe<int, long>(a); // InvalidCastException

// this contrived example works
int aa = 4;
int bb = CastMe<int, int>(aa);

// this also works, the problem is limited to value types
string s = "foo";
object o = CastMe<string, object>(s);

I've searched SO and the internet for an answer to this and found lots of explanations on similar generic related casting issues, but I can't find anything on this particular simple case.

share|improve this question

3 Answers 3

up vote 19 down vote accepted

Why is this a compile time error?

The problem is that every possible combination of value types has different rules for what a cast means. Casting a 64 bit double to a 16 bit int is completely different code from casting a decimal to a float, and so on. The number of possibilities is enormous. So think like the compiler. What code is the compiler supposed to generate for your program?

The compiler would have to generate code that starts the compiler again at runtime, does a fresh analysis of the types, and dynamically emits the appropriate code.

That seems like perhaps more work and less performance than you expected to get with generics, so we simply outlaw it. If what you really want is for the compiler to start up again and do an analysis of the types, use "dynamic" in C# 4; that's what it does.

And why is this a runtime error?

Same reason.

A boxed int may only be unboxed to int (or int?), for the same reason as above; if the CLR tried to do every possible conversion from a boxed value type to every other possible value type then essentially it has to run a compiler again at runtime. That would be unexpectedly slow.

So why is it not an error for reference types?

Because every reference type conversion is the same as every other reference type conversion: you interrogate the object to see if it is derived from or identical to the desired type. If it's not, you throw an exception (if doing a cast) or result in null/false (if using the "as/is" operators). The rules are consistent for reference types in a way that they are not for value types. Remember reference types know their own type. Value types do not; with value types, the variable doing the storage is the only thing that knows the type semantics that apply to those bits. Value types contain their values and no additional information. Reference types contain their values plus lots of extra data.

For more information see my article on the subject:


share|improve this answer
How does the performance of dynamic compare to creating and compiling an expression tree (and caching the resulting delegate)? –  Ben Voigt Apr 7 '11 at 22:23
@Ben: That's precisely what dynamic does; the DLR performs the type analysis, constructs an expression tree, compiles it and caches the result. The next time the code is encountered, the DLR consults its cache, determines if the types match close enough to re-use the cached state, and reuses it if possible. –  Eric Lippert Apr 7 '11 at 22:28
@Eric: Ok, then which is more efficient, the DLR cache lookup, or fetching a static member of a generic class? It seems that when the type is known as a generic parameter, doing the expression tree stuff explicitly may be slightly faster than entrusting it to dynamic. –  Ben Voigt Apr 7 '11 at 22:31
@Ben: Sure, perhaps. Does it matter? Asking which kind of expression tree compilation is "more efficient" is rather like asking which 1970's Cadillac is more fuel efficient. If you care about fuel efficiency, don't be driving a 1970's Caddy in the first place. Any solution involving an expression tree is going to be orders of magnitude more expensive than doing a statically-determined cast. Expression trees are heavyweight. –  Eric Lippert Apr 7 '11 at 22:36
@Eric, don't you mean using the "as" operator? (if using the "as" operator) –  Mark Coleman Apr 7 '11 at 22:51

C# uses one cast syntax for multiple different underlying operations:

  • upcast
  • downcast
  • boxing
  • unboxing
  • numeric conversion
  • user-defined conversion

In generic context, the compiler has no way of knowing which of those is correct, and they all generate different MSIL, so it bails out.

By writing return (TCastTo)(object)i; instead, you force the compiler to do an upcast to object, followed by a downcast to TCastTo. The compiler will generate code, but if that wasn't the right way to convert the types in question, you'll get a runtime error.

Code Sample:

public static class DefaultConverter<TInput, TOutput>
    private static Converter<TInput, TOutput> cached;

    static DefaultConverter()
        ParameterExpression p = Expression.Parameter(typeof(TSource));
        cached = Expression.Lambda<Converter<TSource, TCastTo>(Expression.Convert(p, typeof(TCastTo), p).Compile();

    public static Converter<TInput, TOutput> Instance { return cached; }

public static class DefaultConverter<TOutput>
     public static TOutput ConvertBen<TInput>(TInput from) { return DefaultConverter<TInput, TOutput>.Instance.Invoke(from); }
     public static TOutput ConvertEric(dynamic from) { return from; }

Eric's way sure is shorter, but I think mine should be faster.

share|improve this answer
I sort of regret asking this now because further exploring suggests generics aren't really involved here. As in C# even string s = "s"; Type t = (Type)s; is a compile time error. And this is a runtime error: int a = 4; long b = (long)(object)a;, so I can get both errors without using generics. Possibly generics do throw some kind of unseen wrench in there? –  Matt Greer Apr 7 '11 at 22:27
@Matt: (Unconstrained) generics prevent the compiler from making any attempt to figure out what conversion you need. But doing the wrong style conversion causes failure whether generics were involved or not. –  Ben Voigt Apr 7 '11 at 22:30

The compile error is caused because TSource cannot be implicitly cast to TCastTo. The two types may share a branch on their inheritance tree, but there is no guarantee. If you wanted to call only types that did share an ancestor, you should modify the CastMe() signature to use the ancestor type instead of generics.

The runtime error example avoids the error in your first example by first casting the TSource i to an object, something all objects in C# derive from. While the compiler doesn't complain (because object -> something that derives from it, could be valid), the behaviour of casting via (Type)variable syntax will throw if the cast is invalid. (The same problem that the compiler prevented from happening in example 1).

Another solution, which does something similar to what you're looking for...

    public static T2 CastTo<T, T2>(T input, Func<T, T2> convert)
        return convert(input);

You'd call it like this.

int a = 314;
long b = CastTo(a, i=>(long)i);

Hopefully this helps.

share|improve this answer
I don't entirely understand why long b = (long)someInt; works, but long b = (long)((object)someInt); doesn't. What about casting the int to object first breaks the cast to long? Do you know? –  qes Apr 7 '11 at 22:24
Because the first one means numeric conversion, and the second one means unboxing (conversion from object to a value type is always unboxing, conversion from object to a reference type is always a downcast). Since a numeric conversion is needed, the code that causes unboxing just doesn't work. –  Ben Voigt Apr 7 '11 at 22:28
The (object)someInt does something called Boxing. It essentially wraps the int (value type) inside an object reference type. You're essentially trying to cast a reference type to a value type in your example. –  Jon Apr 7 '11 at 22:29
The word "implicitly" doesn't belong in your answer. @Matt has an explicit cast, which still fails. –  Ben Voigt Apr 9 '11 at 1:56

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.