IsImplicitlyDereferenced Class

Definition

Indicates that the modified garbage collection reference represents a reference parameter within a method signature. This class cannot be inherited.

public ref class IsImplicitlyDereferenced abstract sealed
public static class IsImplicitlyDereferenced
type IsImplicitlyDereferenced = class
Public Class IsImplicitlyDereferenced
Inheritance
IsImplicitlyDereferenced

Examples

The following example demonstrates how to emit an IsImplicitlyDereferenced object into an assembly using reflection.



#using <mscorlib.dll>

using namespace System;
using namespace System::Reflection;
using namespace System::Reflection::Emit;
using namespace System::Runtime::CompilerServices;
using namespace System::Threading;


ref class CodeEmitter
{
private:
    AssemblyBuilder^ asmBuilder;
    String^ asmName;
    ModuleBuilder^ modBuilder;


    void prepareAssembly(String^ name){
        
        // Check the input.
        if(!name){
        
            throw gcnew ArgumentNullException("AssemblyName");
        }

        asmName = name;

        // Create an AssemblyName object and set the name.
        AssemblyName^ asmName = gcnew AssemblyName();

        asmName->Name = name;

        // Use the AppDomain class to create an AssemblyBuilder instance.

        AppDomain^ currentDomain = Thread::GetDomain();

        asmBuilder = currentDomain->DefineDynamicAssembly(asmName,AssemblyBuilderAccess::RunAndSave);

        // Create a dynamic module.
        modBuilder = asmBuilder->DefineDynamicModule(name);
    }


public:

    // Constructor.
    CodeEmitter(String ^ AssemblyName){

        prepareAssembly(AssemblyName);
    }

    // Create a new type.
    TypeBuilder^ CreateType(String^ name){
       
        // Check the input.
        if(!name){
        
            throw gcnew ArgumentNullException("AssemblyName");
        }

        return modBuilder->DefineType( name );
    }

    // Write the assembly.
    void WriteAssembly(MethodBuilder^ entryPoint){
    
        // Check the input.
        if(!entryPoint){
        
            throw gcnew ArgumentNullException("entryPoint");
        }

        asmBuilder->SetEntryPoint( entryPoint );
        asmBuilder->Save( asmName );
    }

};

void main()
{

    // Create a CodeEmitter to handle assembly creation.
    CodeEmitter ^ e = gcnew CodeEmitter("program.exe");

    // Create a new type.
    TypeBuilder^ mainClass = e->CreateType("MainClass");
    
    // Create a new method.
    MethodBuilder^ mBuilder = mainClass->DefineMethod("mainMethod", MethodAttributes::Static);

    // Create an ILGenerator and emit IL for 
    // a simple "Hello World." program.
    ILGenerator^ ilGen = mBuilder->GetILGenerator();

    ilGen->Emit(OpCodes::Ldstr, "Hello World");

    array<Type^>^mType = {String::typeid};

    MethodInfo^ writeMI = Console::typeid->GetMethod( "WriteLine", mType );

    ilGen->EmitCall(OpCodes::Call, writeMI, nullptr );

    ilGen->Emit( OpCodes::Ret );

    /////////////////////////////////////////////////
    /////////////////////////////////////////////////
    // Apply a required custom modifier
    // to a field.
    /////////////////////////////////////////////////
    /////////////////////////////////////////////////

    array<Type^>^fType = {IsImplicitlyDereferenced::typeid};

    mainClass->DefineField("modifiedInteger", Type::GetType("System.IntPtr"), fType, nullptr, FieldAttributes::Private);

    // Create the type.
    mainClass->CreateType();

    // Write the assembly using a reference to 
    // the entry point.
    e->WriteAssembly(mBuilder);

    Console::WriteLine(L"Assembly created.");
}

Remarks

The C++ compiler uses the IsImplicitlyDereferenced modifier to distinguish reference classes that are passed by managed reference from those passed by managed pointer. The IsImplicitlyDereferenced class and its partner, the IsExplicitlyDereferenced class, disambiguate reference parameters from pointer parameters.

Compilers emit custom modifiers within metadata to change the way that the just-in-time (JIT) compiler handles values when the default behavior is not appropriate. When the JIT compiler encounters a custom modifier, it handles the value in the way that the modifier specifies. Compilers can apply custom modifiers to methods, parameters, and return values. The JIT compiler must respond to required modifiers but can ignore optional modifiers.

You can emit custom modifiers into metadata using one of the following techniques:

Applies to