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Consider such class:

class Foo<T>
{
   private T myField;
   public void Set(T x)
   {
      myField = x;
   }
}

And then you instantiate it with T equal to int, bool (value types) and String, List.

How may instantiations will be created and how they would look like?

I am interested in Java and C#.

From what I read Java would create one general class with basically casting, while in C# there would be two classes for int and bool plus single one for String and List because they are reference values (is this true? what about static fields?).

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closed as unclear what you're asking by Servy, Sotirios Delimanolis, gunr2171, LarsTech, Rob Watts May 20 at 19:07

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1  
Instances of what? Instantiations aren't created. –  Sotirios Delimanolis May 20 at 18:14
1  
What you're describing isn't even valid in Java - you can't create Foo<int>. And in C# List is a generic type, assuming you mean System.Collections.Generic.List. –  Jon Skeet May 20 at 18:15
1  
Are you coming from a C++ background, perhaps? Your question doesn't really make sense for C# and Java. –  Tim S. May 20 at 18:15
    
@TimS. I am simply curious about mechanism of using generics (from compiler POV), because unlike C++ (yes, this is my background) generic classes are precompiled and then used. –  greenoldman May 20 at 18:17
1  
Are you maybe referring to the type definitions? That is, I can manually create 1000 instances of Foo<int> via var myIntFoo = new Foo<int>(), but there's only 1 type definition (upon which information about the method bodies, reflection information, stuff in the System.Type representation, maybe even static members)? Are you asking that if I have both a Foo<int> and a Foo<bool>, is any of the type information shared between them or essentially duplicated? –  Chris Sinclair May 20 at 18:24

4 Answers 4

up vote 8 down vote accepted

Note here I'm assuming regular CLR - no AOT etc.

At the IL level: there is one definition of Foo<T>; the IL is identical (shared) no matter the T.

At the JIT level: the type is jitted (per generic parameter) once for all (shared) reference-type parameters, and once each (separately) value-type parameters. So the JIT for Foo<string> and Foo<List<...>> is shared, and a separate JIT for each of Foo<int> and Foo<bool>.

The number of objects/instances created is identical to the number of new Foo<...>(...) calls (or Activator.CreateInstance(...) etc).

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Thank you very much! –  greenoldman May 20 at 18:30
    
I did not know the multiple Foo<?>s were actually created at the JIT, not the IL compile phase, useful information. Thanks –  Ivaylo Slavov May 20 at 18:46
1  
@IvayloSlavov just note that some AOT compilers do ... tricks there. –  Marc Gravell May 20 at 18:48
    
I assume so. I know since .NET 4.0 we have more dynamic behavior of static members (being kinda JITTED). Does your post apply to pre-4.0 versions of the CLR also (the 2.0 version, 1.1 did not support generics at all)? –  Ivaylo Slavov May 20 at 18:49
1  
@IvayloSlavov yes; the exception is things like iOS compilers, that don't use JIT at runtime –  Marc Gravell May 20 at 18:54

In the JVM, there is one and only one class: the one that results from type erasure.

In the CLR, a closed type is constructed for each value of the type parameter, each with its own distinct copies of static fields; JIT code sharing between closed types with reference-typed arguments is an implementation optimization. Therefore, while Foo<String> and Foo<List> might reference the same JIT-translated method implementation, they are not the same type and would have distinct static fields.

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Java Generics are implemented by "type erasure".

The compiler creates one class Foo<T>, which essentially has the code Foo<Object> would have. It is not like a C++ template where a new class is instantiated based on the types. It's quicker to compile than the C++ version, but does prevent some optimizations from occurring at compile time. I believe the main rationale for this system was the desire to maintain compatibility with pre-Generics Java.

The type parameters, e.g. the Integer in Foo<Integer> are only used at compile time to issue an error if the programmer attempts to pass a Bar in, and to allow the compiler to assume that functions returning T will return a T, whereas in pre-Generics Java the programmer would have to cast the result. It is also worth noting that none of the methods of Foo<Integer> will actually check that their arguments are Integers unless the programmer writes this explicitly.

As for static fields, because there is only one Foo instead of separate Foos for different specializations, the type variable is "non-static" and attempting to declare a static member of type T doesn't make sense. On my compiler, it fails with the error "non-static type variable T cannot be referenced from a static context".

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Java and .NET handle generics differently. Let's take a look at the following piece of code:

public class Foo<T>
{
    private static Object staticMember;

    public T getStaticMember() { 
        return (T) staticMember; 
    }

    private T instanceMember;

    public T getInstanceMember() {
        return instanceMember;
    }

    public Foo(T value)
    {
        if (staticMember == null) 
        {
            staticMember = value;
        }
        this.instanceMember = value;
    }        
}

This is not good code in terms of quality, but for the sake of the example, it is a working piece of code for both Java and C#.

In Java, the runtime only knows about the class Foo. So the following code

Foo<Integer> foo = new Foo<Integer>(3);
System.out.println(foo.getStaticMember()); // >> 3
System.out.println(foo.getInstanceMember()); // >> 3

will actually be compiled to something similar:

Foo foo = new Foo(3);
System.out.println(((Integer) foo.getInstanceMember()).toString()); // 3
System.out.println(((Integer) foo.getStaticMember()).toString()); // 3

As you can see, the generic is translated into type cast for the static member.

The following code then will fail in Java with a runtime exception:

Foo<Integer> foo1 = new Foo<Integer>(3);
Foo<String> foo2 = new Foo<String>("This is a string");
System.out.println(foo1.getInstanceMember()); // >> 3
System.out.println(foo2.getInstanceMember()); // >> This is a string
System.out.println(foo1.getStaticMember()); // >> 3
System.out.println(foo2.getStaticMember()); // Invalid cast exception

because it will be treated as:

Foo foo1 = new Foo(3);
Foo foo2 = new Foo("This is a string");
System.out.println(((Integer) foo1.getInstanceMember()).toString()); // >> 3
System.out.println(((String) foo2.getInstanceMember()).toString()); 
// >> This is a string
System.out.println(((Integer) foo1.getStaticMember()).toString()); // >> 3
System.out.println(((String) foo2.getStaticMember()).toString()); 
// Invalid cast exception

The last line would attempt to cast the static member, which is Integer to String.

The above code will work fine in C#, printing respectively:

3
3
This is a string
This is a string

Why?

How Java works

In Java, the compiler creates the Foo class as a raw type, ignoring any generic information in the type definition. This is known as type erasure (also explained in Samuel Edwin Ward's answer). The compiler, will try to detect (or better said - guess) the type usages and attempt compensate the type erasure by adding type casts in the generated code, analyzing the uses of the class in order to achieve this. So, in general, the result will be as if the type Foo was generic. The problem is that the type Foo exists only once, and its staticMember is one and the same instance that is shared between Foo<Integer> and Foo<String>.

How .NET works

In .NET, the Foo<int> and Foo<string> declarations result in generating distinct types during compile time (actually in the JIT phase, as Marc Gravell and Jeffrey Hantin clarify in their respective answers). So, the Foo<string> class is a completely different type than the Foo<int>. This causes each of them to have its own staticMember property, so it is guaranteed that the Foo<string>.staticMember is always of the string type, and the Foo<int>.staticMember is a completely different member of an int type.

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Your class does not compile with javac 1.7.0_55: "non-static type variable T cannot be referenced from a static context". –  Samuel Edwin Ward May 20 at 20:15
    
@SamuelEdwinWard, you are correct, thanks for pointing out. I must have used too much C# stuff. I updated the code. This error is a good addition to the topic, that in Java generics should not be used for static members. –  Ivaylo Slavov May 20 at 20:33
    
Wow, thank you (and thank you all), with so many great answers it is hard to pick one to mark as the accepted one. I hope you don't mind I will stick with Marc Gravell, who was first to answer. –  greenoldman May 22 at 8:33
    
@greenoldman, no problem. After all, the point of the site is to serve as a knowledge base for causes and solutions to technical problems, so more than one answer is actually very common here. –  Ivaylo Slavov May 22 at 8:39

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