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This question got me wondering about where the concrete implementaiton of a generic method actually comes into existence. I've tried the google but am not coming up with the right search.

If we take this simple example:

class Program
    public static T GetDefault<T>()
        return default(T);

    static void Main(string[] args)
        int i = GetDefault<int>();
        double d = GetDefault<double>();
        string s = GetDefault<string>();

in my head I've always assumed that at some point it results in an implementation with the 3 necessary concrete implementations such that, in naive pseudo mangling, we would have this logical concrete implementaiton where the specific types used result in the correct stack allocations etc.

class Program
    static void Main(string[] args)
        int i = GetDefaultSystemInt32();
        double d = GetDefaultSystemFloat64();
        string s = GetDefaultSystemString();

    static int GetDefaultSystemInt32()
        int i = 0;
        return i;
    static double GetDefaultSystemFloat64()
        double d = 0.0;
        return d;
    static string GetDefaultSystemString()
        string s = null;
        return s;

Looking at the IL for the generic program it is still expressed in terms of generic types:

.method public hidebysig static !!T  GetDefault<T>() cil managed
  // Code size       15 (0xf)
  .maxstack  1
  .locals init ([0] !!T CS$1$0000,
           [1] !!T CS$0$0001)
  IL_0000:  nop
  IL_0001:  ldloca.s   CS$0$0001
  IL_0003:  initobj    !!T
  IL_0009:  ldloc.1
  IL_000a:  stloc.0
  IL_000b:  br.s       IL_000d
  IL_000d:  ldloc.0
  IL_000e:  ret
} // end of method Program::GetDefault

So how and at what point is it decided that an int, and then a double and then a string have to be allocated on the stack and returned to the caller? Is this an operation of the JIT process? Am I looking at this in the completely wrong light?

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Like me, you appear to be thinking about this in C++ terms. I don't know the answer but do recall reading some unexpected facts about generics in C#. –  Jonathan Wood Oct 16 '13 at 18:10
You're looking it right, IL supports generics. The great advance is that classes in already compiled assemblies still supports generics. (like the whole .NET framework) –  Jeroen van Langen Oct 16 '13 at 18:13
@Jonathan Wood Totally looking at this from the perspective of how C++ mangles method names! –  dkackman Oct 16 '13 at 18:16
Note, that although the current CLR does some specialization for concrete type parameters at runtime, it could work differently with one method being JIT-compiled for all possible types. The concept of generics does not dictate runtime implementation at all. –  usr Oct 16 '13 at 18:17

2 Answers 2

up vote 69 down vote accepted

In C#, the concepts of generic types and methods is supported by the runtime itself. The C# compiler does not need to actually create a concrete version of a generic method.

The actual "concrete" generic method is created at runtime by the JIT, and does not exist in the IL. The first time a generic method is used with a type, the JIT will see if it's been created, and if not, construct the appropriate method for that generic type.

This is one of the fundamental differences between generics and things like templates in C++. It's also the main reason for many of the limitations with generics - since the compiler isn't actually creating the runtime implementation for types, the interface restrictions are handled by compile time constraints, which make generics a bit more limiting than templates in C++ in terms of potential use cases. However, the fact that they are supported in the runtime itself allows creation of generic types and usage from libraries possible in ways that aren't supported in C++ and other compile-time created template implementations.

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Indeed, a qualitative difference between C++ templates and C# generics is that were it not for time and memory constraints, it would be possible for a relatively small executable file to produce instances of an unlimited number of recognizably-different types (e.g. a program could take an input string of arbitrary length (e.g. "FRED") and create an instance of type F<R<E<D<thingBase>>>>. –  supercat Oct 16 '13 at 18:39
Good answer Reed. Any reference material that describes this that you know of? –  dkackman Oct 16 '13 at 18:57
@dkackman I'd read through artima.com/intv/generics.html It's discussed there. –  Reed Copsey Oct 16 '13 at 19:08
To add to Reed's last paragraph, one such case is using a generic (from a library perhaps) with a type that was created after the generic was compiled. To do that with c++ the compiler would need the source of the template code. –  frozenkoi Oct 16 '13 at 19:27

The actual machine code for a generic method is created, as always, when the method is jitted. At that point, the jitter first checks if a suitable candidate was jitted before. Which is very commonly the case, the code for a method whose concrete runtime type T is a reference type needs to be generated only once and is suitable for every possible reference type T. The constraints on T ensure that this machine code is always valid, previously checked by the C# compiler.

Additional copies may be generated for T's that are value types, their machine code is different because T values are not simple pointers anymore.

So yes, in your case you'll end up with three distinct methods. The <string> version would be useable for any reference type but you don't have others. And the <int> and <double> versions fit the "T's that are value types" category.

Otherwise an excellent example, the return values of these methods are passed back to the caller differently. On the x64 jitter, the string version returns the value with the RAX register, like any returned pointer value, the int version returns with the EAX register, the double version returns with the XMM0 register.

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