ILGenerator.Emit Metode

Definisi

Ruang nama:

System.Reflection.Emit

Rakitan:

System.Reflection.Emit.ILGeneration.dll

Menempatkan instruksi ke aliran Microsoft Intermediate Language (MSIL) untuk kompilator just-in-time (JIT).

Overload

Emit(OpCode, LocalBuilder)	Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti oleh indeks variabel lokal yang diberikan.
Emit(OpCode, Type)	Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti dengan token metadata untuk jenis yang diberikan.
Emit(OpCode, String)	Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti oleh token metadata untuk string yang diberikan.
Emit(OpCode, Single)	Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, SByte)	Menempatkan instruksi dan argumen karakter yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, MethodInfo)	Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti oleh token metadata untuk metode yang diberikan.
Emit(OpCode, SignatureHelper)	Menempatkan instruksi yang ditentukan dan token tanda tangan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, Label[])	Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) dan meninggalkan ruang untuk menyertakan label ketika perbaikan selesai.
Emit(OpCode, FieldInfo)	Menempatkan instruksi dan token metadata yang ditentukan untuk bidang yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, ConstructorInfo)	Menempatkan instruksi dan token metadata yang ditentukan untuk konstruktor yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, Int64)	Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, Int32)	Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, Int16)	Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, Double)	Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode, Byte)	Menempatkan instruksi dan argumen karakter yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).
Emit(OpCode)	Menempatkan instruksi yang ditentukan ke aliran instruksi.
Emit(OpCode, Label)	Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) dan meninggalkan ruang untuk menyertakan label ketika perbaikan selesai.

Emit(OpCode, LocalBuilder)

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti oleh indeks variabel lokal yang diberikan.

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::Reflection::Emit::LocalBuilder ^ local);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, System.Reflection.Emit.LocalBuilder local);

abstract member Emit : System.Reflection.Emit.OpCode * System.Reflection.Emit.LocalBuilder -> unit

Public MustOverride Sub Emit (opcode As OpCode, local As LocalBuilder)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

local

LocalBuilder

Variabel lokal.

Pengecualian

ArgumentException

Metode local induk parameter tidak cocok dengan metode yang terkait dengan ini ILGenerator.

ArgumentNullException

localadalah null.

InvalidOperationException

opcode adalah instruksi byte tunggal, dan local mewakili variabel lokal dengan indeks yang lebih besar dari Byte.MaxValue.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, Type)

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti dengan token metadata untuk jenis yang diberikan.

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, Type ^ cls);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, Type cls);

abstract member Emit : System.Reflection.Emit.OpCode * Type -> unit

Public MustOverride Sub Emit (opcode As OpCode, cls As Type)

Parameter

opcode

OpCode

Instruksi MSIL yang akan diletakkan ke aliran.

cls

Type

Type.

Pengecualian

ArgumentNullException

clsadalah null.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi. Lokasi cls direkam sehingga token dapat di-patch jika perlu saat mempertahankan modul ke file portable executable (PE).

Emit(OpCode, String)

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti oleh token metadata untuk string yang diberikan.

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::String ^ str);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, string str);

abstract member Emit : System.Reflection.Emit.OpCode * string -> unit

Public MustOverride Sub Emit (opcode As OpCode, str As String)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

str

String

yang String akan dipancarkan.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi. Lokasi str direkam untuk perbaikan di masa mendatang jika modul dipertahankan ke file portable executable (PE).

Emit(OpCode, Single)

Sumber:

ILGenerator.cs

Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, float arg);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, float arg);

abstract member Emit : System.Reflection.Emit.OpCode * single -> unit

Public MustOverride Sub Emit (opcode As OpCode, arg As Single)

Parameter

opcode

OpCode

Instruksi MSIL yang akan diletakkan ke aliran.

arg

Single

Argumen Single didorong ke aliran segera setelah instruksi.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, SByte)

Sumber:

ILGenerator.cs

Penting

API ini bukan kompatibel CLS.

Menempatkan instruksi dan argumen karakter yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 void Emit(System::Reflection::Emit::OpCode opcode, System::SByte arg);

[System.CLSCompliant(false)]
public void Emit (System.Reflection.Emit.OpCode opcode, sbyte arg);

[<System.CLSCompliant(false)>]
member this.Emit : System.Reflection.Emit.OpCode * sbyte -> unit

Public Sub Emit (opcode As OpCode, arg As SByte)

Parameter

opcode

OpCode

Instruksi MSIL yang akan diletakkan ke aliran.

arg

SByte

Argumen karakter didorong ke aliran segera setelah instruksi.

Atribut

CLSCompliantAttribute

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, MethodInfo)

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) diikuti oleh token metadata untuk metode yang diberikan.

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::Reflection::MethodInfo ^ meth);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, System.Reflection.MethodInfo meth);

abstract member Emit : System.Reflection.Emit.OpCode * System.Reflection.MethodInfo -> unit

Public MustOverride Sub Emit (opcode As OpCode, meth As MethodInfo)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

meth

MethodInfo

mewakili MethodInfo metode .

Pengecualian

ArgumentNullException

methadalah null.

NotSupportedException

meth adalah metode generik yang IsGenericMethodDefinition propertinya adalah false.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Lokasi meth direkam sehingga aliran instruksi dapat di-patch jika perlu saat mempertahankan modul ke file portable executable (PE).

Jika meth mewakili metode generik, itu harus menjadi definisi metode generik. Artinya, properti MethodInfo.IsGenericMethodDefinition-nya harus true.

Emit(OpCode, SignatureHelper)

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan dan token tanda tangan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::Reflection::Emit::SignatureHelper ^ signature);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, System.Reflection.Emit.SignatureHelper signature);

abstract member Emit : System.Reflection.Emit.OpCode * System.Reflection.Emit.SignatureHelper -> unit

Public MustOverride Sub Emit (opcode As OpCode, signature As SignatureHelper)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

signature

SignatureHelper

Pembantu untuk membuat token tanda tangan.

Pengecualian

ArgumentNullException

signatureadalah null.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, Label[])

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) dan meninggalkan ruang untuk menyertakan label ketika perbaikan selesai.

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, cli::array <System::Reflection::Emit::Label> ^ labels);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, System.Reflection.Emit.Label[] labels);

abstract member Emit : System.Reflection.Emit.OpCode * System.Reflection.Emit.Label[] -> unit

Public MustOverride Sub Emit (opcode As OpCode, labels As Label())

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

labels

Label[]

Array objek label yang akan dicabangkan dari lokasi ini. Semua label akan digunakan.

Pengecualian

ArgumentNullException

conadalah null. Pengecualian ini baru di .NET Framework 4.

Contoh

Sampel kode di bawah ini menggambarkan pembuatan metode dinamis dengan tabel lompat. Tabel lompat dibangun menggunakan array .Label

using namespace System;
using namespace System::Threading;
using namespace System::Reflection;
using namespace System::Reflection::Emit;
Type^ BuildMyType()
{
   AppDomain^ myDomain = Thread::GetDomain();
   AssemblyName^ myAsmName = gcnew AssemblyName;
   myAsmName->Name = "MyDynamicAssembly";
   AssemblyBuilder^ myAsmBuilder = myDomain->DefineDynamicAssembly( myAsmName, AssemblyBuilderAccess::Run );
   ModuleBuilder^ myModBuilder = myAsmBuilder->DefineDynamicModule( "MyJumpTableDemo" );
   TypeBuilder^ myTypeBuilder = myModBuilder->DefineType( "JumpTableDemo", TypeAttributes::Public );
   array<Type^>^temp0 = {int::typeid};
   MethodBuilder^ myMthdBuilder = myTypeBuilder->DefineMethod( "SwitchMe", static_cast<MethodAttributes>(MethodAttributes::Public | MethodAttributes::Static), String::typeid, temp0 );
   ILGenerator^ myIL = myMthdBuilder->GetILGenerator();
   Label defaultCase = myIL->DefineLabel();
   Label endOfMethod = myIL->DefineLabel();
   
   // We are initializing our jump table. Note that the labels
   // will be placed later using the MarkLabel method.
   array<Label>^jumpTable = gcnew array<Label>(5);
   jumpTable[ 0 ] = myIL->DefineLabel();
   jumpTable[ 1 ] = myIL->DefineLabel();
   jumpTable[ 2 ] = myIL->DefineLabel();
   jumpTable[ 3 ] = myIL->DefineLabel();
   jumpTable[ 4 ] = myIL->DefineLabel();
   
   // arg0, the number we passed, is pushed onto the stack.
   // In this case, due to the design of the code sample,
   // the value pushed onto the stack happens to match the
   // index of the label (in IL terms, the index of the offset
   // in the jump table). If this is not the case, such as
   // when switching based on non-integer values, rules for the correspondence
   // between the possible case values and each index of the offsets
   // must be established outside of the ILGenerator::Emit calls,
   // much as a compiler would.
   myIL->Emit( OpCodes::Ldarg_0 );
   myIL->Emit( OpCodes::Switch, jumpTable );
   
   // Branch on default case
   myIL->Emit( OpCodes::Br_S, defaultCase );
   
   // Case arg0 = 0
   myIL->MarkLabel( jumpTable[ 0 ] );
   myIL->Emit( OpCodes::Ldstr, "are no bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 1
   myIL->MarkLabel( jumpTable[ 1 ] );
   myIL->Emit( OpCodes::Ldstr, "is one banana" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 2
   myIL->MarkLabel( jumpTable[ 2 ] );
   myIL->Emit( OpCodes::Ldstr, "are two bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 3
   myIL->MarkLabel( jumpTable[ 3 ] );
   myIL->Emit( OpCodes::Ldstr, "are three bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 4
   myIL->MarkLabel( jumpTable[ 4 ] );
   myIL->Emit( OpCodes::Ldstr, "are four bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Default case
   myIL->MarkLabel( defaultCase );
   myIL->Emit( OpCodes::Ldstr, "are many bananas" );
   myIL->MarkLabel( endOfMethod );
   myIL->Emit( OpCodes::Ret );
   return myTypeBuilder->CreateType();
}

int main()
{
   Type^ myType = BuildMyType();
   Console::Write( "Enter an integer between 0 and 5: " );
   int theValue = Convert::ToInt32( Console::ReadLine() );
   Console::WriteLine( "---" );
   Object^ myInstance = Activator::CreateInstance( myType, gcnew array<Object^>(0) );
   array<Object^>^temp1 = {theValue};
   Console::WriteLine( "Yes, there {0} today!", myType->InvokeMember( "SwitchMe", BindingFlags::InvokeMethod, nullptr, myInstance, temp1 ) );
}

using System;
using System.Threading;
using System.Reflection;
using System.Reflection.Emit;

class DynamicJumpTableDemo
{
   public static Type BuildMyType()
   {
    AppDomain myDomain = Thread.GetDomain();
    AssemblyName myAsmName = new AssemblyName();
    myAsmName.Name = "MyDynamicAssembly";

    AssemblyBuilder myAsmBuilder = myDomain.DefineDynamicAssembly(
                        myAsmName,
                        AssemblyBuilderAccess.Run);
    ModuleBuilder myModBuilder = myAsmBuilder.DefineDynamicModule(
                        "MyJumpTableDemo");

    TypeBuilder myTypeBuilder = myModBuilder.DefineType("JumpTableDemo",
                            TypeAttributes.Public);
    MethodBuilder myMthdBuilder = myTypeBuilder.DefineMethod("SwitchMe",
                             MethodAttributes.Public |
                             MethodAttributes.Static,
                                             typeof(string),
                                             new Type[] {typeof(int)});

    ILGenerator myIL = myMthdBuilder.GetILGenerator();

    Label defaultCase = myIL.DefineLabel();	
    Label endOfMethod = myIL.DefineLabel();	

    // We are initializing our jump table. Note that the labels
    // will be placed later using the MarkLabel method.

    Label[] jumpTable = new Label[] { myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel() };

    // arg0, the number we passed, is pushed onto the stack.
    // In this case, due to the design of the code sample,
    // the value pushed onto the stack happens to match the
    // index of the label (in IL terms, the index of the offset
    // in the jump table). If this is not the case, such as
    // when switching based on non-integer values, rules for the correspondence
    // between the possible case values and each index of the offsets
    // must be established outside of the ILGenerator.Emit calls,
    // much as a compiler would.

    myIL.Emit(OpCodes.Ldarg_0);
    myIL.Emit(OpCodes.Switch, jumpTable);
    
    // Branch on default case
    myIL.Emit(OpCodes.Br_S, defaultCase);

    // Case arg0 = 0
    myIL.MarkLabel(jumpTable[0]);
    myIL.Emit(OpCodes.Ldstr, "are no bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 1
    myIL.MarkLabel(jumpTable[1]);
    myIL.Emit(OpCodes.Ldstr, "is one banana");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 2
    myIL.MarkLabel(jumpTable[2]);
    myIL.Emit(OpCodes.Ldstr, "are two bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 3
    myIL.MarkLabel(jumpTable[3]);
    myIL.Emit(OpCodes.Ldstr, "are three bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 4
    myIL.MarkLabel(jumpTable[4]);
    myIL.Emit(OpCodes.Ldstr, "are four bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Default case
    myIL.MarkLabel(defaultCase);
    myIL.Emit(OpCodes.Ldstr, "are many bananas");

    myIL.MarkLabel(endOfMethod);
    myIL.Emit(OpCodes.Ret);
    
    return myTypeBuilder.CreateType();
   }

   public static void Main()
   {
    Type myType = BuildMyType();
    
    Console.Write("Enter an integer between 0 and 5: ");
    int theValue = Convert.ToInt32(Console.ReadLine());

    Console.WriteLine("---");
    Object myInstance = Activator.CreateInstance(myType, new object[0]);	
    Console.WriteLine("Yes, there {0} today!", myType.InvokeMember("SwitchMe",
                               BindingFlags.InvokeMethod,
                               null,
                               myInstance,
                               new object[] {theValue}));
   }
}

Imports System.Threading
Imports System.Reflection
Imports System.Reflection.Emit

 _

Class DynamicJumpTableDemo
   
   Public Shared Function BuildMyType() As Type

      Dim myDomain As AppDomain = Thread.GetDomain()
      Dim myAsmName As New AssemblyName()
      myAsmName.Name = "MyDynamicAssembly"
      
      Dim myAsmBuilder As AssemblyBuilder = myDomain.DefineDynamicAssembly(myAsmName, _
                            AssemblyBuilderAccess.Run)
      Dim myModBuilder As ModuleBuilder = myAsmBuilder.DefineDynamicModule("MyJumpTableDemo")
      
      Dim myTypeBuilder As TypeBuilder = myModBuilder.DefineType("JumpTableDemo", _
                                 TypeAttributes.Public)
      Dim myMthdBuilder As MethodBuilder = myTypeBuilder.DefineMethod("SwitchMe", _
                        MethodAttributes.Public Or MethodAttributes.Static, _
                        GetType(String), New Type() {GetType(Integer)})
      
      Dim myIL As ILGenerator = myMthdBuilder.GetILGenerator()
      
      Dim defaultCase As Label = myIL.DefineLabel()
      Dim endOfMethod As Label = myIL.DefineLabel()
      
      ' We are initializing our jump table. Note that the labels
      ' will be placed later using the MarkLabel method. 

      Dim jumpTable() As Label = {myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel()}
      
      ' arg0, the number we passed, is pushed onto the stack.
      ' In this case, due to the design of the code sample,
      ' the value pushed onto the stack happens to match the
      ' index of the label (in IL terms, the index of the offset
      ' in the jump table). If this is not the case, such as
      ' when switching based on non-integer values, rules for the correspondence
      ' between the possible case values and each index of the offsets
      ' must be established outside of the ILGenerator.Emit calls,
      ' much as a compiler would.

      myIL.Emit(OpCodes.Ldarg_0)
      myIL.Emit(OpCodes.Switch, jumpTable)
      
      ' Branch on default case
      myIL.Emit(OpCodes.Br_S, defaultCase)
      
      ' Case arg0 = 0
      myIL.MarkLabel(jumpTable(0))
      myIL.Emit(OpCodes.Ldstr, "are no bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 1
      myIL.MarkLabel(jumpTable(1))
      myIL.Emit(OpCodes.Ldstr, "is one banana")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 2
      myIL.MarkLabel(jumpTable(2))
      myIL.Emit(OpCodes.Ldstr, "are two bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 3
      myIL.MarkLabel(jumpTable(3))
      myIL.Emit(OpCodes.Ldstr, "are three bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 4
      myIL.MarkLabel(jumpTable(4))
      myIL.Emit(OpCodes.Ldstr, "are four bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Default case
      myIL.MarkLabel(defaultCase)
      myIL.Emit(OpCodes.Ldstr, "are many bananas")
      
      myIL.MarkLabel(endOfMethod)
      myIL.Emit(OpCodes.Ret)
      
      Return myTypeBuilder.CreateType()

   End Function 'BuildMyType
    
   
   Public Shared Sub Main()

      Dim myType As Type = BuildMyType()
      
      Console.Write("Enter an integer between 0 and 5: ")
      Dim theValue As Integer = Convert.ToInt32(Console.ReadLine())
      
      Console.WriteLine("---")
      Dim myInstance As [Object] = Activator.CreateInstance(myType, New Object() {})
      Console.WriteLine("Yes, there {0} today!", myType.InvokeMember("SwitchMe", _
                         BindingFlags.InvokeMethod, Nothing, _
                             myInstance, New Object() {theValue}))

   End Sub

End Class

Keterangan

Memancarkan tabel sakelar.

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Label dibuat menggunakan DefineLabel dan lokasinya dalam aliran diperbaiki dengan menggunakan MarkLabel. Jika instruksi byte tunggal digunakan, label dapat mewakili lompatan paling banyak 127 byte di sepanjang aliran. opcode harus mewakili instruksi cabang. Karena cabang adalah instruksi relatif, label akan diganti dengan offset yang benar ke cabang selama proses perbaikan.

Emit(OpCode, FieldInfo)

Sumber:

ILGenerator.cs

Menempatkan instruksi dan token metadata yang ditentukan untuk bidang yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::Reflection::FieldInfo ^ field);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, System.Reflection.FieldInfo field);

abstract member Emit : System.Reflection.Emit.OpCode * System.Reflection.FieldInfo -> unit

Public MustOverride Sub Emit (opcode As OpCode, field As FieldInfo)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

field

FieldInfo

yang FieldInfo mewakili bidang.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi. Lokasi field direkam sehingga aliran instruksi dapat di-patch jika perlu saat mempertahankan modul ke file portable executable (PE).

Emit(OpCode, ConstructorInfo)

Sumber:

ILGenerator.cs

Menempatkan token instruksi dan metadata yang ditentukan untuk konstruktor yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::Reflection::ConstructorInfo ^ con);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, System.Reflection.ConstructorInfo con);

abstract member Emit : System.Reflection.Emit.OpCode * System.Reflection.ConstructorInfo -> unit

Public MustOverride Sub Emit (opcode As OpCode, con As ConstructorInfo)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

con

ConstructorInfo

ConstructorInfo mewakili konstruktor.

Pengecualian

ArgumentNullException

conadalah null. Pengecualian ini baru di .NET Framework 4.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Lokasi con direkam sehingga aliran instruksi dapat di-patch jika perlu saat mempertahankan modul ke file portable executable (PE).

Emit(OpCode, Int64)

Sumber:

ILGenerator.cs

Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, long arg);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, long arg);

abstract member Emit : System.Reflection.Emit.OpCode * int64 -> unit

Public MustOverride Sub Emit (opcode As OpCode, arg As Long)

Parameter

opcode

OpCode

Instruksi MSIL untuk diletakkan ke aliran.

arg

Int64

Argumen numerik didorong ke aliran segera setelah instruksi.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, Int32)

Sumber:

ILGenerator.cs

Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, int arg);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, int arg);

abstract member Emit : System.Reflection.Emit.OpCode * int -> unit

Public MustOverride Sub Emit (opcode As OpCode, arg As Integer)

Parameter

opcode

OpCode

Instruksi MSIL untuk diletakkan ke aliran.

arg

Int32

Argumen numerik didorong ke aliran segera setelah instruksi.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, Int16)

Sumber:

ILGenerator.cs

Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, short arg);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, short arg);

abstract member Emit : System.Reflection.Emit.OpCode * int16 -> unit

Public MustOverride Sub Emit (opcode As OpCode, arg As Short)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

arg

Int16

Argumen Int didorong ke aliran segera setelah instruksi.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, Double)

Sumber:

ILGenerator.cs

Menempatkan instruksi dan argumen numerik yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, double arg);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, double arg);

abstract member Emit : System.Reflection.Emit.OpCode * double -> unit

Public MustOverride Sub Emit (opcode As OpCode, arg As Double)

Parameter

opcode

OpCode

Instruksi MSIL untuk diletakkan ke aliran. Ditentukan dalam OpCodes enumerasi.

arg

Double

Argumen numerik didorong ke aliran segera setelah instruksi.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode, Byte)

Sumber:

ILGenerator.cs

Menempatkan instruksi dan argumen karakter yang ditentukan ke aliran instruksi bahasa perantara Microsoft (MSIL).

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::Byte arg);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, byte arg);

abstract member Emit : System.Reflection.Emit.OpCode * byte -> unit

Public MustOverride Sub Emit (opcode As OpCode, arg As Byte)

Parameter

opcode

OpCode

Instruksi MSIL untuk diletakkan ke aliran.

arg

Byte

Argumen karakter didorong ke aliran segera setelah instruksi.

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Emit(OpCode)

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan ke aliran instruksi.

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode);

public abstract void Emit (System.Reflection.Emit.OpCode opcode);

abstract member Emit : System.Reflection.Emit.OpCode -> unit

Public MustOverride Sub Emit (opcode As OpCode)

Parameter

opcode

OpCode

Instruksi Microsoft Intermediate Language (MSIL) untuk dimasukkan ke aliran.

Contoh

Sampel kode di bawah ini menunjukkan penggunaan Emit untuk menghasilkan output MSIL melalui instans ILGenerator.

using namespace System;
using namespace System::Threading;
using namespace System::Reflection;
using namespace System::Reflection::Emit;
Type^ BuildMyType()
{
   AppDomain^ myDomain = Thread::GetDomain();
   AssemblyName^ myAsmName = gcnew AssemblyName;
   myAsmName->Name = "MyDynamicAssembly";
   AssemblyBuilder^ myAsmBuilder = myDomain->DefineDynamicAssembly( myAsmName, AssemblyBuilderAccess::Run );
   ModuleBuilder^ myModBuilder = myAsmBuilder->DefineDynamicModule( "MyJumpTableDemo" );
   TypeBuilder^ myTypeBuilder = myModBuilder->DefineType( "JumpTableDemo", TypeAttributes::Public );
   array<Type^>^temp0 = {int::typeid};
   MethodBuilder^ myMthdBuilder = myTypeBuilder->DefineMethod( "SwitchMe", static_cast<MethodAttributes>(MethodAttributes::Public | MethodAttributes::Static), String::typeid, temp0 );
   ILGenerator^ myIL = myMthdBuilder->GetILGenerator();
   Label defaultCase = myIL->DefineLabel();
   Label endOfMethod = myIL->DefineLabel();
   
   // We are initializing our jump table. Note that the labels
   // will be placed later using the MarkLabel method.
   array<Label>^jumpTable = gcnew array<Label>(5);
   jumpTable[ 0 ] = myIL->DefineLabel();
   jumpTable[ 1 ] = myIL->DefineLabel();
   jumpTable[ 2 ] = myIL->DefineLabel();
   jumpTable[ 3 ] = myIL->DefineLabel();
   jumpTable[ 4 ] = myIL->DefineLabel();
   
   // arg0, the number we passed, is pushed onto the stack.
   // In this case, due to the design of the code sample,
   // the value pushed onto the stack happens to match the
   // index of the label (in IL terms, the index of the offset
   // in the jump table). If this is not the case, such as
   // when switching based on non-integer values, rules for the correspondence
   // between the possible case values and each index of the offsets
   // must be established outside of the ILGenerator::Emit calls,
   // much as a compiler would.
   myIL->Emit( OpCodes::Ldarg_0 );
   myIL->Emit( OpCodes::Switch, jumpTable );
   
   // Branch on default case
   myIL->Emit( OpCodes::Br_S, defaultCase );
   
   // Case arg0 = 0
   myIL->MarkLabel( jumpTable[ 0 ] );
   myIL->Emit( OpCodes::Ldstr, "are no bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 1
   myIL->MarkLabel( jumpTable[ 1 ] );
   myIL->Emit( OpCodes::Ldstr, "is one banana" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 2
   myIL->MarkLabel( jumpTable[ 2 ] );
   myIL->Emit( OpCodes::Ldstr, "are two bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 3
   myIL->MarkLabel( jumpTable[ 3 ] );
   myIL->Emit( OpCodes::Ldstr, "are three bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 4
   myIL->MarkLabel( jumpTable[ 4 ] );
   myIL->Emit( OpCodes::Ldstr, "are four bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Default case
   myIL->MarkLabel( defaultCase );
   myIL->Emit( OpCodes::Ldstr, "are many bananas" );
   myIL->MarkLabel( endOfMethod );
   myIL->Emit( OpCodes::Ret );
   return myTypeBuilder->CreateType();
}

int main()
{
   Type^ myType = BuildMyType();
   Console::Write( "Enter an integer between 0 and 5: " );
   int theValue = Convert::ToInt32( Console::ReadLine() );
   Console::WriteLine( "---" );
   Object^ myInstance = Activator::CreateInstance( myType, gcnew array<Object^>(0) );
   array<Object^>^temp1 = {theValue};
   Console::WriteLine( "Yes, there {0} today!", myType->InvokeMember( "SwitchMe", BindingFlags::InvokeMethod, nullptr, myInstance, temp1 ) );
}

using System;
using System.Threading;
using System.Reflection;
using System.Reflection.Emit;

class DynamicJumpTableDemo
{
   public static Type BuildMyType()
   {
    AppDomain myDomain = Thread.GetDomain();
    AssemblyName myAsmName = new AssemblyName();
    myAsmName.Name = "MyDynamicAssembly";

    AssemblyBuilder myAsmBuilder = myDomain.DefineDynamicAssembly(
                        myAsmName,
                        AssemblyBuilderAccess.Run);
    ModuleBuilder myModBuilder = myAsmBuilder.DefineDynamicModule(
                        "MyJumpTableDemo");

    TypeBuilder myTypeBuilder = myModBuilder.DefineType("JumpTableDemo",
                            TypeAttributes.Public);
    MethodBuilder myMthdBuilder = myTypeBuilder.DefineMethod("SwitchMe",
                             MethodAttributes.Public |
                             MethodAttributes.Static,
                                             typeof(string),
                                             new Type[] {typeof(int)});

    ILGenerator myIL = myMthdBuilder.GetILGenerator();

    Label defaultCase = myIL.DefineLabel();	
    Label endOfMethod = myIL.DefineLabel();	

    // We are initializing our jump table. Note that the labels
    // will be placed later using the MarkLabel method.

    Label[] jumpTable = new Label[] { myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel() };

    // arg0, the number we passed, is pushed onto the stack.
    // In this case, due to the design of the code sample,
    // the value pushed onto the stack happens to match the
    // index of the label (in IL terms, the index of the offset
    // in the jump table). If this is not the case, such as
    // when switching based on non-integer values, rules for the correspondence
    // between the possible case values and each index of the offsets
    // must be established outside of the ILGenerator.Emit calls,
    // much as a compiler would.

    myIL.Emit(OpCodes.Ldarg_0);
    myIL.Emit(OpCodes.Switch, jumpTable);
    
    // Branch on default case
    myIL.Emit(OpCodes.Br_S, defaultCase);

    // Case arg0 = 0
    myIL.MarkLabel(jumpTable[0]);
    myIL.Emit(OpCodes.Ldstr, "are no bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 1
    myIL.MarkLabel(jumpTable[1]);
    myIL.Emit(OpCodes.Ldstr, "is one banana");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 2
    myIL.MarkLabel(jumpTable[2]);
    myIL.Emit(OpCodes.Ldstr, "are two bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 3
    myIL.MarkLabel(jumpTable[3]);
    myIL.Emit(OpCodes.Ldstr, "are three bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 4
    myIL.MarkLabel(jumpTable[4]);
    myIL.Emit(OpCodes.Ldstr, "are four bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Default case
    myIL.MarkLabel(defaultCase);
    myIL.Emit(OpCodes.Ldstr, "are many bananas");

    myIL.MarkLabel(endOfMethod);
    myIL.Emit(OpCodes.Ret);
    
    return myTypeBuilder.CreateType();
   }

   public static void Main()
   {
    Type myType = BuildMyType();
    
    Console.Write("Enter an integer between 0 and 5: ");
    int theValue = Convert.ToInt32(Console.ReadLine());

    Console.WriteLine("---");
    Object myInstance = Activator.CreateInstance(myType, new object[0]);	
    Console.WriteLine("Yes, there {0} today!", myType.InvokeMember("SwitchMe",
                               BindingFlags.InvokeMethod,
                               null,
                               myInstance,
                               new object[] {theValue}));
   }
}

Imports System.Threading
Imports System.Reflection
Imports System.Reflection.Emit

 _

Class DynamicJumpTableDemo
   
   Public Shared Function BuildMyType() As Type

      Dim myDomain As AppDomain = Thread.GetDomain()
      Dim myAsmName As New AssemblyName()
      myAsmName.Name = "MyDynamicAssembly"
      
      Dim myAsmBuilder As AssemblyBuilder = myDomain.DefineDynamicAssembly(myAsmName, _
                            AssemblyBuilderAccess.Run)
      Dim myModBuilder As ModuleBuilder = myAsmBuilder.DefineDynamicModule("MyJumpTableDemo")
      
      Dim myTypeBuilder As TypeBuilder = myModBuilder.DefineType("JumpTableDemo", _
                                 TypeAttributes.Public)
      Dim myMthdBuilder As MethodBuilder = myTypeBuilder.DefineMethod("SwitchMe", _
                        MethodAttributes.Public Or MethodAttributes.Static, _
                        GetType(String), New Type() {GetType(Integer)})
      
      Dim myIL As ILGenerator = myMthdBuilder.GetILGenerator()
      
      Dim defaultCase As Label = myIL.DefineLabel()
      Dim endOfMethod As Label = myIL.DefineLabel()
      
      ' We are initializing our jump table. Note that the labels
      ' will be placed later using the MarkLabel method. 

      Dim jumpTable() As Label = {myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel()}
      
      ' arg0, the number we passed, is pushed onto the stack.
      ' In this case, due to the design of the code sample,
      ' the value pushed onto the stack happens to match the
      ' index of the label (in IL terms, the index of the offset
      ' in the jump table). If this is not the case, such as
      ' when switching based on non-integer values, rules for the correspondence
      ' between the possible case values and each index of the offsets
      ' must be established outside of the ILGenerator.Emit calls,
      ' much as a compiler would.

      myIL.Emit(OpCodes.Ldarg_0)
      myIL.Emit(OpCodes.Switch, jumpTable)
      
      ' Branch on default case
      myIL.Emit(OpCodes.Br_S, defaultCase)
      
      ' Case arg0 = 0
      myIL.MarkLabel(jumpTable(0))
      myIL.Emit(OpCodes.Ldstr, "are no bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 1
      myIL.MarkLabel(jumpTable(1))
      myIL.Emit(OpCodes.Ldstr, "is one banana")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 2
      myIL.MarkLabel(jumpTable(2))
      myIL.Emit(OpCodes.Ldstr, "are two bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 3
      myIL.MarkLabel(jumpTable(3))
      myIL.Emit(OpCodes.Ldstr, "are three bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 4
      myIL.MarkLabel(jumpTable(4))
      myIL.Emit(OpCodes.Ldstr, "are four bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Default case
      myIL.MarkLabel(defaultCase)
      myIL.Emit(OpCodes.Ldstr, "are many bananas")
      
      myIL.MarkLabel(endOfMethod)
      myIL.Emit(OpCodes.Ret)
      
      Return myTypeBuilder.CreateType()

   End Function 'BuildMyType
    
   
   Public Shared Sub Main()

      Dim myType As Type = BuildMyType()
      
      Console.Write("Enter an integer between 0 and 5: ")
      Dim theValue As Integer = Convert.ToInt32(Console.ReadLine())
      
      Console.WriteLine("---")
      Dim myInstance As [Object] = Activator.CreateInstance(myType, New Object() {})
      Console.WriteLine("Yes, there {0} today!", myType.InvokeMember("SwitchMe", _
                         BindingFlags.InvokeMethod, Nothing, _
                             myInstance, New Object() {theValue}))

   End Sub

End Class

Keterangan

opcode Jika parameter memerlukan argumen, pemanggil harus memastikan bahwa panjang argumen cocok dengan panjang parameter yang dideklarasikan. Jika tidak, hasilnya tidak akan dapat diprediksi. Misalnya, jika instruksi Emit memerlukan operand 2-byte dan pemanggil memasok operand 4-byte, runtime akan memancarkan dua byte tambahan ke aliran instruksi. Byte tambahan ini akan menjadi Nop instruksi.

Nilai instruksi didefinisikan dalam OpCodes.

Emit(OpCode, Label)

Sumber:

ILGenerator.cs

Menempatkan instruksi yang ditentukan ke aliran bahasa perantara Microsoft (MSIL) dan meninggalkan ruang untuk menyertakan label saat perbaikan selesai.

public:
 abstract void Emit(System::Reflection::Emit::OpCode opcode, System::Reflection::Emit::Label label);

public abstract void Emit (System.Reflection.Emit.OpCode opcode, System.Reflection.Emit.Label label);

abstract member Emit : System.Reflection.Emit.OpCode * System.Reflection.Emit.Label -> unit

Public MustOverride Sub Emit (opcode As OpCode, label As Label)

Parameter

opcode

OpCode

Instruksi MSIL yang akan dipancarkan ke aliran.

label

Label

Label yang akan dicabangkan dari lokasi ini.

Contoh

Sampel kode di bawah ini menggambarkan pembuatan metode dinamis dengan tabel lompat. Tabel lompat dibangun menggunakan array .Label

using namespace System;
using namespace System::Threading;
using namespace System::Reflection;
using namespace System::Reflection::Emit;
Type^ BuildMyType()
{
   AppDomain^ myDomain = Thread::GetDomain();
   AssemblyName^ myAsmName = gcnew AssemblyName;
   myAsmName->Name = "MyDynamicAssembly";
   AssemblyBuilder^ myAsmBuilder = myDomain->DefineDynamicAssembly( myAsmName, AssemblyBuilderAccess::Run );
   ModuleBuilder^ myModBuilder = myAsmBuilder->DefineDynamicModule( "MyJumpTableDemo" );
   TypeBuilder^ myTypeBuilder = myModBuilder->DefineType( "JumpTableDemo", TypeAttributes::Public );
   array<Type^>^temp0 = {int::typeid};
   MethodBuilder^ myMthdBuilder = myTypeBuilder->DefineMethod( "SwitchMe", static_cast<MethodAttributes>(MethodAttributes::Public | MethodAttributes::Static), String::typeid, temp0 );
   ILGenerator^ myIL = myMthdBuilder->GetILGenerator();
   Label defaultCase = myIL->DefineLabel();
   Label endOfMethod = myIL->DefineLabel();
   
   // We are initializing our jump table. Note that the labels
   // will be placed later using the MarkLabel method.
   array<Label>^jumpTable = gcnew array<Label>(5);
   jumpTable[ 0 ] = myIL->DefineLabel();
   jumpTable[ 1 ] = myIL->DefineLabel();
   jumpTable[ 2 ] = myIL->DefineLabel();
   jumpTable[ 3 ] = myIL->DefineLabel();
   jumpTable[ 4 ] = myIL->DefineLabel();
   
   // arg0, the number we passed, is pushed onto the stack.
   // In this case, due to the design of the code sample,
   // the value pushed onto the stack happens to match the
   // index of the label (in IL terms, the index of the offset
   // in the jump table). If this is not the case, such as
   // when switching based on non-integer values, rules for the correspondence
   // between the possible case values and each index of the offsets
   // must be established outside of the ILGenerator::Emit calls,
   // much as a compiler would.
   myIL->Emit( OpCodes::Ldarg_0 );
   myIL->Emit( OpCodes::Switch, jumpTable );
   
   // Branch on default case
   myIL->Emit( OpCodes::Br_S, defaultCase );
   
   // Case arg0 = 0
   myIL->MarkLabel( jumpTable[ 0 ] );
   myIL->Emit( OpCodes::Ldstr, "are no bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 1
   myIL->MarkLabel( jumpTable[ 1 ] );
   myIL->Emit( OpCodes::Ldstr, "is one banana" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 2
   myIL->MarkLabel( jumpTable[ 2 ] );
   myIL->Emit( OpCodes::Ldstr, "are two bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 3
   myIL->MarkLabel( jumpTable[ 3 ] );
   myIL->Emit( OpCodes::Ldstr, "are three bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Case arg0 = 4
   myIL->MarkLabel( jumpTable[ 4 ] );
   myIL->Emit( OpCodes::Ldstr, "are four bananas" );
   myIL->Emit( OpCodes::Br_S, endOfMethod );
   
   // Default case
   myIL->MarkLabel( defaultCase );
   myIL->Emit( OpCodes::Ldstr, "are many bananas" );
   myIL->MarkLabel( endOfMethod );
   myIL->Emit( OpCodes::Ret );
   return myTypeBuilder->CreateType();
}

int main()
{
   Type^ myType = BuildMyType();
   Console::Write( "Enter an integer between 0 and 5: " );
   int theValue = Convert::ToInt32( Console::ReadLine() );
   Console::WriteLine( "---" );
   Object^ myInstance = Activator::CreateInstance( myType, gcnew array<Object^>(0) );
   array<Object^>^temp1 = {theValue};
   Console::WriteLine( "Yes, there {0} today!", myType->InvokeMember( "SwitchMe", BindingFlags::InvokeMethod, nullptr, myInstance, temp1 ) );
}

using System;
using System.Threading;
using System.Reflection;
using System.Reflection.Emit;

class DynamicJumpTableDemo
{
   public static Type BuildMyType()
   {
    AppDomain myDomain = Thread.GetDomain();
    AssemblyName myAsmName = new AssemblyName();
    myAsmName.Name = "MyDynamicAssembly";

    AssemblyBuilder myAsmBuilder = myDomain.DefineDynamicAssembly(
                        myAsmName,
                        AssemblyBuilderAccess.Run);
    ModuleBuilder myModBuilder = myAsmBuilder.DefineDynamicModule(
                        "MyJumpTableDemo");

    TypeBuilder myTypeBuilder = myModBuilder.DefineType("JumpTableDemo",
                            TypeAttributes.Public);
    MethodBuilder myMthdBuilder = myTypeBuilder.DefineMethod("SwitchMe",
                             MethodAttributes.Public |
                             MethodAttributes.Static,
                                             typeof(string),
                                             new Type[] {typeof(int)});

    ILGenerator myIL = myMthdBuilder.GetILGenerator();

    Label defaultCase = myIL.DefineLabel();	
    Label endOfMethod = myIL.DefineLabel();	

    // We are initializing our jump table. Note that the labels
    // will be placed later using the MarkLabel method.

    Label[] jumpTable = new Label[] { myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel(),
                      myIL.DefineLabel() };

    // arg0, the number we passed, is pushed onto the stack.
    // In this case, due to the design of the code sample,
    // the value pushed onto the stack happens to match the
    // index of the label (in IL terms, the index of the offset
    // in the jump table). If this is not the case, such as
    // when switching based on non-integer values, rules for the correspondence
    // between the possible case values and each index of the offsets
    // must be established outside of the ILGenerator.Emit calls,
    // much as a compiler would.

    myIL.Emit(OpCodes.Ldarg_0);
    myIL.Emit(OpCodes.Switch, jumpTable);
    
    // Branch on default case
    myIL.Emit(OpCodes.Br_S, defaultCase);

    // Case arg0 = 0
    myIL.MarkLabel(jumpTable[0]);
    myIL.Emit(OpCodes.Ldstr, "are no bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 1
    myIL.MarkLabel(jumpTable[1]);
    myIL.Emit(OpCodes.Ldstr, "is one banana");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 2
    myIL.MarkLabel(jumpTable[2]);
    myIL.Emit(OpCodes.Ldstr, "are two bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 3
    myIL.MarkLabel(jumpTable[3]);
    myIL.Emit(OpCodes.Ldstr, "are three bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Case arg0 = 4
    myIL.MarkLabel(jumpTable[4]);
    myIL.Emit(OpCodes.Ldstr, "are four bananas");
    myIL.Emit(OpCodes.Br_S, endOfMethod);

    // Default case
    myIL.MarkLabel(defaultCase);
    myIL.Emit(OpCodes.Ldstr, "are many bananas");

    myIL.MarkLabel(endOfMethod);
    myIL.Emit(OpCodes.Ret);
    
    return myTypeBuilder.CreateType();
   }

   public static void Main()
   {
    Type myType = BuildMyType();
    
    Console.Write("Enter an integer between 0 and 5: ");
    int theValue = Convert.ToInt32(Console.ReadLine());

    Console.WriteLine("---");
    Object myInstance = Activator.CreateInstance(myType, new object[0]);	
    Console.WriteLine("Yes, there {0} today!", myType.InvokeMember("SwitchMe",
                               BindingFlags.InvokeMethod,
                               null,
                               myInstance,
                               new object[] {theValue}));
   }
}

Imports System.Threading
Imports System.Reflection
Imports System.Reflection.Emit

 _

Class DynamicJumpTableDemo
   
   Public Shared Function BuildMyType() As Type

      Dim myDomain As AppDomain = Thread.GetDomain()
      Dim myAsmName As New AssemblyName()
      myAsmName.Name = "MyDynamicAssembly"
      
      Dim myAsmBuilder As AssemblyBuilder = myDomain.DefineDynamicAssembly(myAsmName, _
                            AssemblyBuilderAccess.Run)
      Dim myModBuilder As ModuleBuilder = myAsmBuilder.DefineDynamicModule("MyJumpTableDemo")
      
      Dim myTypeBuilder As TypeBuilder = myModBuilder.DefineType("JumpTableDemo", _
                                 TypeAttributes.Public)
      Dim myMthdBuilder As MethodBuilder = myTypeBuilder.DefineMethod("SwitchMe", _
                        MethodAttributes.Public Or MethodAttributes.Static, _
                        GetType(String), New Type() {GetType(Integer)})
      
      Dim myIL As ILGenerator = myMthdBuilder.GetILGenerator()
      
      Dim defaultCase As Label = myIL.DefineLabel()
      Dim endOfMethod As Label = myIL.DefineLabel()
      
      ' We are initializing our jump table. Note that the labels
      ' will be placed later using the MarkLabel method. 

      Dim jumpTable() As Label = {myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel(), _
                  myIL.DefineLabel()}
      
      ' arg0, the number we passed, is pushed onto the stack.
      ' In this case, due to the design of the code sample,
      ' the value pushed onto the stack happens to match the
      ' index of the label (in IL terms, the index of the offset
      ' in the jump table). If this is not the case, such as
      ' when switching based on non-integer values, rules for the correspondence
      ' between the possible case values and each index of the offsets
      ' must be established outside of the ILGenerator.Emit calls,
      ' much as a compiler would.

      myIL.Emit(OpCodes.Ldarg_0)
      myIL.Emit(OpCodes.Switch, jumpTable)
      
      ' Branch on default case
      myIL.Emit(OpCodes.Br_S, defaultCase)
      
      ' Case arg0 = 0
      myIL.MarkLabel(jumpTable(0))
      myIL.Emit(OpCodes.Ldstr, "are no bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 1
      myIL.MarkLabel(jumpTable(1))
      myIL.Emit(OpCodes.Ldstr, "is one banana")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 2
      myIL.MarkLabel(jumpTable(2))
      myIL.Emit(OpCodes.Ldstr, "are two bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 3
      myIL.MarkLabel(jumpTable(3))
      myIL.Emit(OpCodes.Ldstr, "are three bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Case arg0 = 4
      myIL.MarkLabel(jumpTable(4))
      myIL.Emit(OpCodes.Ldstr, "are four bananas")
      myIL.Emit(OpCodes.Br_S, endOfMethod)
      
      ' Default case
      myIL.MarkLabel(defaultCase)
      myIL.Emit(OpCodes.Ldstr, "are many bananas")
      
      myIL.MarkLabel(endOfMethod)
      myIL.Emit(OpCodes.Ret)
      
      Return myTypeBuilder.CreateType()

   End Function 'BuildMyType
    
   
   Public Shared Sub Main()

      Dim myType As Type = BuildMyType()
      
      Console.Write("Enter an integer between 0 and 5: ")
      Dim theValue As Integer = Convert.ToInt32(Console.ReadLine())
      
      Console.WriteLine("---")
      Dim myInstance As [Object] = Activator.CreateInstance(myType, New Object() {})
      Console.WriteLine("Yes, there {0} today!", myType.InvokeMember("SwitchMe", _
                         BindingFlags.InvokeMethod, Nothing, _
                             myInstance, New Object() {theValue}))

   End Sub

End Class

Keterangan

Nilai instruksi didefinisikan dalam OpCodes enumerasi.

Label dibuat menggunakan DefineLabel, dan lokasinya dalam aliran diperbaiki dengan menggunakan MarkLabel. Jika instruksi byte tunggal digunakan, label dapat mewakili lompatan paling banyak 127 byte di sepanjang aliran. opcode harus mewakili instruksi cabang. Karena cabang adalah instruksi relatif, label akan diganti dengan offset yang benar ke cabang selama proses perbaikan.