Type.GetType Method

Definition

Gets a Type object that represents the specified type.

Overloads

GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean, Boolean)

Gets the type with the specified name, specifying whether to perform a case-sensitive search and whether to throw an exception if the type is not found, and optionally providing custom methods to resolve the assembly and the type.

GetType()

Gets the current Type.

GetType(String)

Gets the Type with the specified name, performing a case-sensitive search.

GetType(String, Boolean)

Gets the Type with the specified name, performing a case-sensitive search and specifying whether to throw an exception if the type is not found.

GetType(String, Boolean, Boolean)

Gets the Type with the specified name, specifying whether to throw an exception if the type is not found and whether to perform a case-sensitive search.

GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>)

Gets the type with the specified name, optionally providing custom methods to resolve the assembly and the type.

GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean)

Gets the type with the specified name, specifying whether to throw an exception if the type is not found, and optionally providing custom methods to resolve the assembly and the type.

GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean, Boolean)

Gets the type with the specified name, specifying whether to perform a case-sensitive search and whether to throw an exception if the type is not found, and optionally providing custom methods to resolve the assembly and the type.

public:
 static Type ^ GetType(System::String ^ typeName, Func<System::Reflection::AssemblyName ^, System::Reflection::Assembly ^> ^ assemblyResolver, Func<System::Reflection::Assembly ^, System::String ^, bool, Type ^> ^ typeResolver, bool throwOnError, bool ignoreCase);
public static Type? GetType (string typeName, Func<System.Reflection.AssemblyName,System.Reflection.Assembly?>? assemblyResolver, Func<System.Reflection.Assembly?,string,bool,Type?>? typeResolver, bool throwOnError, bool ignoreCase);
public static Type GetType (string typeName, Func<System.Reflection.AssemblyName,System.Reflection.Assembly> assemblyResolver, Func<System.Reflection.Assembly,string,bool,Type> typeResolver, bool throwOnError, bool ignoreCase);
static member GetType : string * Func<System.Reflection.AssemblyName, System.Reflection.Assembly> * Func<System.Reflection.Assembly, string, bool, Type> * bool * bool -> Type
Public Shared Function GetType (typeName As String, assemblyResolver As Func(Of AssemblyName, Assembly), typeResolver As Func(Of Assembly, String, Boolean, Type), throwOnError As Boolean, ignoreCase As Boolean) As Type

Parameters

typeName
String

The name of the type to get. If the typeResolver parameter is provided, the type name can be any string that typeResolver is capable of resolving. If the assemblyResolver parameter is provided or if standard type resolution is used, typeName must be an assembly-qualified name (see AssemblyQualifiedName), unless the type is in the currently executing assembly or in mscorlib.dll/System.Private.CoreLib.dll, in which case it's sufficient to supply the type name qualified by its namespace.

assemblyResolver
Func<AssemblyName,Assembly>

A method that locates and returns the assembly that is specified in typeName. The assembly name is passed to assemblyResolver as an AssemblyName object. If typeName does not contain the name of an assembly, assemblyResolver is not called. If assemblyResolver is not supplied, standard assembly resolution is performed.

Caution: Don't pass methods from unknown or untrusted callers. Doing so could result in elevation of privilege for malicious code. Use only methods that you provide or that you are familiar with.

typeResolver
Func<Assembly,String,Boolean,Type>

A method that locates and returns the type that is specified by typeName from the assembly that is returned by assemblyResolver or by standard assembly resolution. If no assembly is provided, the method can provide one. The method also takes a parameter that specifies whether to perform a case-insensitive search; the value of ignoreCase is passed to that parameter.

Caution: Don't pass methods from unknown or untrusted callers.

throwOnError
Boolean

true to throw an exception if the type cannot be found; false to return null. Specifying false also suppresses some other exception conditions, but not all of them. See the Exceptions section.

ignoreCase
Boolean

true to perform a case-insensitive search for typeName, false to perform a case-sensitive search for typeName.

Returns

The type with the specified name. If the type is not found, the throwOnError parameter specifies whether null is returned or an exception is thrown. In some cases, an exception is thrown regardless of the value of throwOnError. See the Exceptions section.

Exceptions

typeName is null.

A class initializer is invoked and throws an exception.

throwOnError is true and the type is not found.

-or-

throwOnError is true and typeName contains invalid characters, such as an embedded tab.

-or-

throwOnError is true and typeName is an empty string.

-or-

throwOnError is true and typeName represents an array type with an invalid size.

-or-

typeName represents an array of TypedReference.

An error occurs when typeName is parsed into a type name and an assembly name (for example, when the simple type name includes an unescaped special character).

-or-

throwOnError is true and typeName contains invalid syntax (for example, "MyType[,*,]").

-or-

typeName represents a generic type that has a pointer type, a ByRef type, or Void as one of its type arguments.

-or-

typeName represents a generic type that has an incorrect number of type arguments.

-or-

typeName represents a generic type, and one of its type arguments does not satisfy the constraints for the corresponding type parameter.

throwOnError is true and the assembly or one of its dependencies was not found.

The assembly or one of its dependencies was found, but could not be loaded.

-or-

typeName contains an invalid assembly name.

-or-

typeName is a valid assembly name without a type name.

The assembly or one of its dependencies is not a valid assembly for the currently loaded runtime.

Remarks

For more information about this API, see Supplemental API remarks for Type.GetType.

Applies to

GetType()

Gets the current Type.

public:
 Type ^ GetType();
public:
 virtual Type ^ GetType();
public Type GetType ();
override this.GetType : unit -> Type
Public Function GetType () As Type

Returns

The current Type.

Implements

Exceptions

A class initializer is invoked and throws an exception.

See also

Applies to

GetType(String)

Gets the Type with the specified name, performing a case-sensitive search.

public:
 static Type ^ GetType(System::String ^ typeName);
public static Type GetType (string typeName);
public static Type? GetType (string typeName);
static member GetType : string -> Type
Public Shared Function GetType (typeName As String) As Type

Parameters

typeName
String

The assembly-qualified name of the type to get. See AssemblyQualifiedName. If the type is in the currently executing assembly or in mscorlib.dll/System.Private.CoreLib.dll, it's sufficient to supply the type name qualified by its namespace.

Returns

The type with the specified name, if found; otherwise, null.

Exceptions

typeName is null.

A class initializer is invoked and throws an exception.

typeName represents a generic type that has a pointer type, a ByRef type, or Void as one of its type arguments.

-or-

typeName represents a generic type that has an incorrect number of type arguments.

-or-

typeName represents a generic type, and one of its type arguments does not satisfy the constraints for the corresponding type parameter.

typeName represents an invalid type, for example, an array of TypedReference.

The assembly or one of its dependencies was found, but could not be loaded.

Note: In .NET for Windows Store apps or the Portable Class Library, catch the base class exception, IOException, instead.

The assembly is not valid for the currently loaded runtime.

Examples

The following example retrieves the type of System.Int32 and uses that type object to display the FullName property of System.Int32.

using namespace System;

int main()
{
   try {
      // Get the type of a specified class.
      Type^ myType1 = Type::GetType( "System.Int32" );
      Console::WriteLine( "The full name is {0}.\n", myType1->FullName );
   }
   catch ( TypeLoadException^ e ) {
       Console::WriteLine("{0}: Unable to load type System.Int32",
                          e->GetType()->Name);
   }

   try {
      // Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
      Type^ myType2 = Type::GetType( "NoneSuch", true );
      Console::WriteLine( "The full name is {0}.", myType2->FullName );
   }
   catch ( TypeLoadException^ e ) {
       Console::WriteLine("{0}: Unable to load type NoneSuch",
                          e->GetType()->Name);
   }

}
// The example displays the following output:
//       The full name is System.Int32.
//
//       TypeLoadException: Unable to load type NoneSuch
using System;

class Example
{
     public static void Main()
     {
         try {
             // Get the type of a specified class.
             Type myType1 = Type.GetType("System.Int32");
             Console.WriteLine("The full name is {0}.\n", myType1.FullName);
         }
         catch (TypeLoadException e)
         {
            Console.WriteLine("{0}: Unable to load type System.Int32", e.GetType().Name);
         }

         try {
             // Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
             Type myType2 = Type.GetType("NoneSuch", true);
             Console.WriteLine("The full name is {0}.", myType2.FullName);
         }
         catch(TypeLoadException e) {
            Console.WriteLine("{0}: Unable to load type NoneSuch", e.GetType().Name);
         }
     }
}
// The example displays the following output:
//       The full name is System.Int32.
//
//       TypeLoadException: Unable to load type NoneSuch
open System

try
    // Get the type of a specified class.
    let myType1 = Type.GetType "System.Int32"
    printfn $"The full name is {myType1.FullName}.\n"
with :? TypeLoadException as e ->
    printfn $"{e.GetType().Name}: Unable to load type System.Int32"

try
    // Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
    let myType2 = Type.GetType("NoneSuch", true)
    printfn $"The full name is {myType2.FullName}."
with :? TypeLoadException as e ->
    printfn $"{e.GetType().Name}: Unable to load type NoneSuch"
// The example displays the following output:
//       The full name is System.Int32.
//
//       TypeLoadException: Unable to load type NoneSuch
Class Example
     Public Shared Sub Main()
         Try
             ' Get the type of the specified class.
             Dim myType1 As Type = Type.GetType("System.Int32")
             Console.WriteLine("The full name is {0}.", myType1.FullName)
         Catch e As TypeLoadException
             Console.WriteLine("{0}: Unable to load type System.Int32",
                               e.GetType().Name)
         End Try

         Console.WriteLine()

         Try
             ' Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
             Dim myType2 As Type = Type.GetType("NoneSuch", True)
             Console.WriteLine("The full name is {0}.", myType2.FullName)
         Catch e As TypeLoadException
             Console.WriteLine("{0}: Unable to load type NoneSuch", e.GetType().Name)
         End Try
     End Sub
End Class
' The example displays the following output:
'       The full name is System.Int32.
'
'       TypeLoadException: Unable to load type NoneSuch

Remarks

You can use the GetType method to obtain a Type object for a type in another assembly if you know its assembly-qualified name, which can be obtained from AssemblyQualifiedName. GetType causes loading of the assembly specified in typeName. You can also load an assembly using the Assembly.Load method, and then use the Assembly.GetType or Assembly.GetTypes method to get Type objects. If a type is in an assembly known to your program at compile time, it's more efficient to use typeof in C# or the GetType operator in Visual Basic.

Note

If typeName cannot be found, the call to the GetType(String) method returns null. It does not throw an exception. To control whether an exception is thrown, call an overload of the GetType method that has a throwOnError parameter.

GetType only works on assemblies loaded from disk. If you call GetType to look up a type defined in a dynamic assembly defined using the System.Reflection.Emit services, you might get inconsistent behavior. The behavior depends on whether the dynamic assembly is persistent, that is, created using the RunAndSave or Save access modes of the System.Reflection.Emit.AssemblyBuilderAccess enumeration. If the dynamic assembly is persistent and has been written to disk before GetType is called, the loader finds the saved assembly on disk, loads that assembly, and retrieves the type from that assembly. If the assembly has not been saved to disk when GetType is called, the method returns null. GetType does not understand transient dynamic assemblies; therefore, calling GetType to retrieve a type in a transient dynamic assembly returns null.

To use GetType on a dynamic module, subscribe to the AppDomain.AssemblyResolve event and call GetType before saving. Otherwise, you will get two copies of the assembly in memory.

The following table shows what members of a base class are returned by the Get methods when reflecting on a type.

Member Type Static Non-Static
Constructor No No
Field No Yes. A field is always hide-by-name-and-signature.
Event Not applicable The common type system rule is that the inheritance is the same as that of the methods that implement the property. Reflection treats properties as hide-by-name-and-signature. See note 2 below.
Method No Yes. A method (both virtual and non-virtual) can be hide-by-name or hide-by-name-and-signature.
Nested Type No No
Property Not applicable The common type system rule is that the inheritance is the same as that of the methods that implement the property. Reflection treats properties as hide-by-name-and-signature. See note 2 below.
  1. Hide-by-name-and-signature considers all of the parts of the signature, including custom modifiers, return types, parameter types, sentinels, and unmanaged calling conventions. This is a binary comparison.

  2. For reflection, properties and events are hide-by-name-and-signature. If you have a property with both a get and a set accessor in the base class, but the derived class has only a get accessor, the derived class property hides the base class property, and you will not be able to access the setter on the base class.

  3. Custom attributes are not part of the common type system.

Arrays or COM types are not searched for unless they have already been loaded into the table of available classes.

typeName can be the type name qualified by its namespace or an assembly-qualified name that includes an assembly name specification. See AssemblyQualifiedName.

If typeName includes the namespace but not the assembly name, this method searches only the calling object's assembly and mscorlib.dll/System.Private.CoreLib.dll, in that order. If typeName is fully qualified with the partial or complete assembly name, this method searches in the specified assembly. If the assembly has a strong name, a complete assembly name is required.

The AssemblyQualifiedName property returns a fully qualified type name including nested types, the assembly name, and generic type arguments. All compilers that support the common language runtime will emit the simple name of a nested class, and reflection constructs a mangled name when queried, in accordance with the following conventions.

Note

Processor architecture is part of assembly identity, and can be specified as part of assembly name strings. For example, "ProcessorArchitecture=msil". However, it's not included in the string returned by the AssemblyQualifiedName property, for compatibility reasons. You can also load types by creating an AssemblyName object and passing it to an appropriate overload of the Load method. You can then use the Assembly.GetType method to load types from the assembly. See also AssemblyName.ProcessorArchitecture.

Delimiter Meaning
Backslash (\) Escape character.
Backtick (`) Precedes one or more digits representing the number of type parameters, located at the end of the name of a generic type.
Brackets ([]) Enclose a generic type argument list, for a constructed generic type; within a type argument list, enclose an assembly-qualified type.
Comma (,) Precedes the Assembly name.
Period (.) Denotes namespace identifiers.
Plus sign (+) Precedes a nested class.

For example, the fully qualified name for a class might look like this:

TopNamespace.SubNameSpace.ContainingClass+NestedClass,MyAssembly

If the namespace were TopNamespace.Sub+Namespace, then the string would have to precede the plus sign (+) with an escape character (\) to prevent it from being interpreted as a nesting separator. Reflection emits this string as follows:

TopNamespace.Sub\+Namespace.ContainingClass+NestedClass,MyAssembly

A "++" becomes "\+\+", and a "\" becomes "\\".

This qualified name can be persisted and later used to load the Type. To search for and load a Type, use GetType either with the type name only or with the assembly qualified type name. GetType with the type name only will look for the Type in the caller's assembly and then in the System assembly. GetType with the assembly qualified type name will look for the Type in any assembly.

Type names may include trailing characters that denote additional information about the type, such as whether the type is a reference type, a pointer type or an array type. To retrieve the type name without these trailing characters, use t.GetElementType().ToString(), where t is the type.

Spaces are relevant in all type name components except the assembly name. In the assembly name, spaces before the ',' separator are relevant, but spaces after the ',' separator are ignored.

The name of a generic type ends with a backtick (`) followed by digits representing the number of generic type arguments. The purpose of this name mangling is to allow compilers to support generic types with the same name but with different numbers of type parameters, occurring in the same scope. For example, reflection returns the mangled names Tuple`1 and Tuple`2 from the generic methods Tuple(Of T) and Tuple(Of T0, T1) in Visual Basic, or Tuple<T> and Tuple<T0, T1> in Visual C#.

For generic types, the type argument list is enclosed in brackets, and the type arguments are separated by commas. For example, a generic Dictionary<TKey,TValue> has two type parameters. A Dictionary<TKey,TValue> of MyType with keys of type String might be represented as follows:

System.Collections.Generic.Dictionary`2[System.String,MyType]

To specify an assembly-qualified type within a type argument list, enclose the assembly-qualified type within brackets. Otherwise, the commas that separate the parts of the assembly-qualified name are interpreted as delimiting additional type arguments. For example, a Dictionary<TKey,TValue> of MyType fromMyAssembly.dll, with keys of type String, might be specified as follows:

Type.GetType("System.Collections.Generic.Dictionary`2[System.String,[MyType,MyAssembly]]")

Note

An assembly-qualified type can be enclosed in brackets only when it appears within a type parameter list. The rules for searching assemblies for qualified and unqualified types in type parameter lists are the same as the rules for qualified and unqualified nongeneric types.

Nullable types are a special case of generic types. For example, a nullable Int32 is represented by the string "System.Nullable`1[System.Int32]".

Note

In C#, C++, and Visual Basic you can also get nullable types using type operators. For example, the nullable Boolean type is returned by typeof(Nullable<bool>) in C#, by Nullable<Boolean>::typeid in C++, and by GetType(Nullable(Of Boolean)) in Visual Basic.

The following table shows the syntax you use with GetType for various types.

To Get Use
A nullable Int32 Type.GetType("System.Nullable`1[System.Int32]")
An unmanaged pointer to MyType Type.GetType("MyType*")
An unmanaged pointer to a pointer to MyType Type.GetType("MyType**")
A managed pointer or reference to MyType Type.GetType("MyType&"). Note that unlike pointers, references are limited to one level.
A parent class and a nested class Type.GetType("MyParentClass+MyNestedClass")
A one-dimensional array with a lower bound of 0 Type.GetType("MyType[]")
A one-dimensional array with an unknown lower bound Type.GetType("MyType[*]")
An n-dimensional array A comma (,) inside the brackets a total of n-1 times. For example, System.Object[,,] represents a three-dimensional Object array.
An array of one-dimensional arrays Type.GetType("MyType[][]")
A rectangular two-dimensional array with unknown lower bounds Type.GetType("MyType[,]")
A generic type with one type argument Type.GetType("MyGenericType`1[MyType]")
A generic type with two type arguments Type.GetType("MyGenericType`2[MyType,AnotherType]")
A generic type with two assembly-qualified type arguments Type.GetType("MyGenericType`2[[MyType,MyAssembly],[AnotherType,AnotherAssembly]]")
An assembly-qualified generic type with an assembly-qualified type argument Type.GetType("MyGenericType`1[[MyType,MyAssembly]],MyGenericTypeAssembly")
A generic type whose type argument is a generic type with two type arguments Type.GetType("MyGenericType`1[AnotherGenericType`2[MyType,AnotherType]]")

See also

Applies to

GetType(String, Boolean)

Gets the Type with the specified name, performing a case-sensitive search and specifying whether to throw an exception if the type is not found.

public:
 static Type ^ GetType(System::String ^ typeName, bool throwOnError);
public static Type GetType (string typeName, bool throwOnError);
public static Type? GetType (string typeName, bool throwOnError);
static member GetType : string * bool -> Type
Public Shared Function GetType (typeName As String, throwOnError As Boolean) As Type

Parameters

typeName
String

The assembly-qualified name of the type to get. See AssemblyQualifiedName. If the type is in the currently executing assembly or in mscorlib.dll/System.Private.CoreLib.dll, it's sufficient to supply the type name qualified by its namespace.

throwOnError
Boolean

true to throw an exception if the type cannot be found; false to return null. Specifying false also suppresses some other exception conditions, but not all of them. See the Exceptions section.

Returns

The type with the specified name. If the type is not found, the throwOnError parameter specifies whether null is returned or an exception is thrown. In some cases, an exception is thrown regardless of the value of throwOnError. See the Exceptions section.

Exceptions

typeName is null.

A class initializer is invoked and throws an exception.

throwOnError is true and the type is not found.

-or-

throwOnError is true and typeName contains invalid characters, such as an embedded tab.

-or-

throwOnError is true and typeName is an empty string.

-or-

throwOnError is true and typeName represents an array type with an invalid size.

-or-

typeName represents an array of TypedReference.

throwOnError is true and typeName contains invalid syntax. For example, "MyType[,*,]".

-or-

typeName represents a generic type that has a pointer type, a ByRef type, or Void as one of its type arguments.

-or-

typeName represents a generic type that has an incorrect number of type arguments.

-or-

typeName represents a generic type, and one of its type arguments does not satisfy the constraints for the corresponding type parameter.

throwOnError is true and the assembly or one of its dependencies was not found.

The assembly or one of its dependencies was found, but could not be loaded.

Note: In .NET for Windows Store apps or the Portable Class Library, catch the base class exception, IOException, instead.

The assembly or one of its dependencies is not valid for the currently loaded runtime.

Examples

The following example retrieves the type of System.Int32 and uses that type object to display the FullName property of System.Int32. If a type object refers to an assembly that does not exist, this example throws an exception.

using namespace System;

int main()
{
   try {
      // Get the type of a specified class.
      Type^ myType1 = Type::GetType( "System.Int32" );
      Console::WriteLine( "The full name is {0}.\n", myType1->FullName );
   }
   catch ( TypeLoadException^ e ) {
       Console::WriteLine("{0}: Unable to load type System.Int32",
                          e->GetType()->Name);
   }

   try {
      // Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
      Type^ myType2 = Type::GetType( "NoneSuch", true );
      Console::WriteLine( "The full name is {0}.", myType2->FullName );
   }
   catch ( TypeLoadException^ e ) {
       Console::WriteLine("{0}: Unable to load type NoneSuch",
                          e->GetType()->Name);
   }

}
// The example displays the following output:
//       The full name is System.Int32.
//
//       TypeLoadException: Unable to load type NoneSuch
using System;

class Example
{
     public static void Main()
     {
         try {
             // Get the type of a specified class.
             Type myType1 = Type.GetType("System.Int32");
             Console.WriteLine("The full name is {0}.\n", myType1.FullName);
         }
         catch (TypeLoadException e)
         {
            Console.WriteLine("{0}: Unable to load type System.Int32", e.GetType().Name);
         }

         try {
             // Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
             Type myType2 = Type.GetType("NoneSuch", true);
             Console.WriteLine("The full name is {0}.", myType2.FullName);
         }
         catch(TypeLoadException e) {
            Console.WriteLine("{0}: Unable to load type NoneSuch", e.GetType().Name);
         }
     }
}
// The example displays the following output:
//       The full name is System.Int32.
//
//       TypeLoadException: Unable to load type NoneSuch
open System

try
    // Get the type of a specified class.
    let myType1 = Type.GetType "System.Int32"
    printfn $"The full name is {myType1.FullName}.\n"
with :? TypeLoadException as e ->
    printfn $"{e.GetType().Name}: Unable to load type System.Int32"

try
    // Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
    let myType2 = Type.GetType("NoneSuch", true)
    printfn $"The full name is {myType2.FullName}."
with :? TypeLoadException as e ->
    printfn $"{e.GetType().Name}: Unable to load type NoneSuch"
// The example displays the following output:
//       The full name is System.Int32.
//
//       TypeLoadException: Unable to load type NoneSuch
Class Example
     Public Shared Sub Main()
         Try
             ' Get the type of the specified class.
             Dim myType1 As Type = Type.GetType("System.Int32")
             Console.WriteLine("The full name is {0}.", myType1.FullName)
         Catch e As TypeLoadException
             Console.WriteLine("{0}: Unable to load type System.Int32",
                               e.GetType().Name)
         End Try

         Console.WriteLine()

         Try
             ' Since NoneSuch does not exist in this assembly, GetType throws a TypeLoadException.
             Dim myType2 As Type = Type.GetType("NoneSuch", True)
             Console.WriteLine("The full name is {0}.", myType2.FullName)
         Catch e As TypeLoadException
             Console.WriteLine("{0}: Unable to load type NoneSuch", e.GetType().Name)
         End Try
     End Sub
End Class
' The example displays the following output:
'       The full name is System.Int32.
'
'       TypeLoadException: Unable to load type NoneSuch

Remarks

You can use the GetType method to obtain a Type object for a type in another assembly if you know its assembly-qualified name, which can be obtained from AssemblyQualifiedName. GetType causes loading of the assembly specified in typeName. You can also load an assembly using the Assembly.Load method, and then use the Assembly.GetType or Assembly.GetTypes method to get Type objects. If a type is in an assembly known to your program at compile time, it's more efficient to use typeof in C# or the GetType operator in Visual Basic.

GetType only works on assemblies loaded from disk. If you call GetType to look up a type defined in a dynamic assembly defined using the System.Reflection.Emit services, you might get inconsistent behavior. The behavior depends on whether the dynamic assembly is persistent, that is, created using the RunAndSave or Save access modes of the System.Reflection.Emit.AssemblyBuilderAccess enumeration. If the dynamic assembly is persistent and has been written to disk before GetType is called, the loader finds the saved assembly on disk, loads that assembly, and retrieves the type from that assembly. If the assembly has not been saved to disk when GetType is called, the method returns null. GetType does not understand transient dynamic assemblies; therefore, calling GetType to retrieve a type in a transient dynamic assembly returns null.

To use GetType on a dynamic module, subscribe to the AppDomain.AssemblyResolve event and call GetType before saving. Otherwise, you will get two copies of the assembly in memory.

The throwOnError parameter specifies what happens when the type is not found, and also suppresses certain other exception conditions, as described in the Exceptions section. Some exceptions are thrown regardless of the value of throwOnError. For example, if the type is found but cannot be loaded, a TypeLoadException is thrown even if throwOnError is false.

The following table shows what members of a base class are returned by the Get methods when reflecting on a type.

Member Type Static Non-Static
Constructor No No
Field No Yes. A field is always hide-by-name-and-signature.
Event Not applicable The common type system rule is that the inheritance is the same as that of the methods that implement the property. Reflection treats properties as hide-by-name-and-signature. See note 2 below.
Method No Yes. A method (both virtual and non-virtual) can be hide-by-name or hide-by-name-and-signature.
Nested Type No No
Property Not applicable The common type system rule is that the inheritance is the same as that of the methods that implement the property. Reflection treats properties as hide-by-name-and-signature. See note 2 below.
  1. Hide-by-name-and-signature considers all of the parts of the signature, including custom modifiers, return types, parameter types, sentinels, and unmanaged calling conventions. This is a binary comparison.

  2. For reflection, properties and events are hide-by-name-and-signature. If you have a property with both a get and a set accessor in the base class, but the derived class has only a get accessor, the derived class property hides the base class property, and you will not be able to access the setter on the base class.

  3. Custom attributes are not part of the common type system.

Arrays or COM types are not searched for unless they have already been loaded into the table of available classes.

typeName can be the type name qualified by its namespace or an assembly-qualified name that includes an assembly name specification. See AssemblyQualifiedName.

If typeName includes the namespace but not the assembly name, this method searches only the calling object's assembly and mscorlib.dll/System.Private.CoreLib.dll, in that order. If typeName is fully qualified with the partial or complete assembly name, this method searches in the specified assembly. If the assembly has a strong name, a complete assembly name is required.

The AssemblyQualifiedName property returns a fully qualified type name including nested types, the assembly name, and generic arguments. All compilers that support the common language runtime will emit the simple name of a nested class, and reflection constructs a mangled name when queried, in accordance with the following conventions.

Note

Processor architecture is part of assembly identity, and can be specified as part of assembly name strings. For example, "ProcessorArchitecture=msil". However, it's not included in the string returned by the AssemblyQualifiedName property, for compatibility reasons. You can also load types by creating an AssemblyName object and passing it to an appropriate overload of the Load method. You can then use the Assembly.GetType method to load types from the assembly. See also AssemblyName.ProcessorArchitecture.

Delimiter Meaning
Backslash (\) Escape character.
Backtick (`) Precedes one or more digits representing the number of type parameters, located at the end of the name of a generic type.
Brackets ([]) Enclose a generic type argument list, for a constructed generic type; within a type argument list, enclose an assembly-qualified type.
Comma (,) Precedes the Assembly name.
Period (.) Denotes namespace identifiers.
Plus sign (+) Precedes a nested class.

For example, the fully qualified name for a class might look like this:

TopNamespace.SubNameSpace.ContainingClass+NestedClass,MyAssembly

If the namespace were TopNamespace.Sub+Namespace, then the string would have to precede the plus sign (+) with an escape character (\) to prevent it from being interpreted as a nesting separator. Reflection emits this string as follows:

TopNamespace.Sub\+Namespace.ContainingClass+NestedClass,MyAssembly

A "++" becomes "\+\+", and a "\" becomes "\\".

This qualified name can be persisted and later used to load the Type. To search for and load a Type, use GetType either with the type name only or with the assembly qualified type name. GetType with the type name only will look for the Type in the caller's assembly and then in the System assembly. GetType with the assembly qualified type name will look for the Type in any assembly.

Type names may include trailing characters that denote additional information about the type, such as whether the type is a reference type, a pointer type or an array type. To retrieve the type name without these trailing characters, use t.GetElementType().ToString(), where t is the type.

Spaces are relevant in all type name components except the assembly name. In the assembly name, spaces before the ',' separator are relevant, but spaces after the ',' separator are ignored.

The name of a generic type ends with a backtick (`) followed by digits representing the number of generic type arguments. The purpose of this name mangling is to allow compilers to support generic types with the same name but with different numbers of type parameters, occurring in the same scope. For example, reflection returns the mangled names Tuple`1 and Tuple`2 from the generic methods Tuple(Of T) and Tuple(Of T0, T1) in Visual Basic, or Tuple<T> and Tuple<T0, T1> in Visual C#.

For generic types, the type argument list is enclosed in brackets, and the type arguments are separated by commas. For example, a generic Dictionary<TKey,TValue> has two type parameters. A Dictionary<TKey,TValue> of MyType with keys of type String might be represented as follows:

System.Collections.Generic.Dictionary`2[System.String,MyType]

To specify an assembly-qualified type within a type argument list, enclose the assembly-qualified type within brackets. Otherwise, the commas that separate the parts of the assembly-qualified name are interpreted as delimiting additional type arguments. For example, a Dictionary<TKey,TValue> of MyType from MyAssembly.dll, with keys of type String, might be specified as follows:

Type.GetType("System.Collections.Generic.Dictionary`2[System.String,[MyType,MyAssembly]]")

Note

An assembly-qualified type can be enclosed in brackets only when it appears within a type parameter list. The rules for searching assemblies for qualified and unqualified types in type parameter lists are the same as the rules for qualified and unqualified nongeneric types.

Nullable types are a special case of generic types. For example, a nullable Int32 is represented by the string "System.Nullable`1[System.Int32]".

Note

In C#, C++, and Visual Basic you can also get nullable types using type operators. For example, the nullable Boolean type is returned by typeof(Nullable<bool>) in C#, by Nullable<Boolean>::typeid in C++, and by GetType(Nullable(Of Boolean)) in Visual Basic.

The following table shows the syntax you use with GetType for various types.

To Get Use
A nullable Int32 Type.GetType("System.Nullable`1[System.Int32]")
An unmanaged pointer to MyType Type.GetType("MyType*")
An unmanaged pointer to a pointer to MyType Type.GetType("MyType**")
A managed pointer or reference to MyType Type.GetType("MyType&"). Note that unlike pointers, references are limited to one level.
A parent class and a nested class Type.GetType("MyParentClass+MyNestedClass")
A one-dimensional array with a lower bound of 0 Type.GetType("MyArray[]")
A one-dimensional array with an unknown lower bound Type.GetType("MyArray[*]")
An n-dimensional array A comma (,) inside the brackets a total of n-1 times. For example, System.Object[,,] represents a three-dimensional Object array.
A two-dimensional array's array Type.GetType("MyArray[][]")
A rectangular two-dimensional array with unknown lower bounds Type.GetType("MyArray[,]")
A generic type with one type argument Type.GetType("MyGenericType`1[MyType]")
A generic type with two type arguments Type.GetType("MyGenericType`2[MyType,AnotherType]")
A generic type with two assembly-qualified type arguments Type.GetType("MyGenericType`2[[MyType,MyAssembly],[AnotherType,AnotherAssembly]]")
An assembly-qualified generic type with an assembly-qualified type argument Type.GetType("MyGenericType`1[[MyType,MyAssembly]],MyGenericTypeAssembly")
A generic type whose type argument is a generic type with two type arguments Type.GetType("MyGenericType`1[AnotherGenericType`2[MyType,AnotherType]]")

See also

Applies to

GetType(String, Boolean, Boolean)

Gets the Type with the specified name, specifying whether to throw an exception if the type is not found and whether to perform a case-sensitive search.

public:
 static Type ^ GetType(System::String ^ typeName, bool throwOnError, bool ignoreCase);
public static Type GetType (string typeName, bool throwOnError, bool ignoreCase);
public static Type? GetType (string typeName, bool throwOnError, bool ignoreCase);
static member GetType : string * bool * bool -> Type
Public Shared Function GetType (typeName As String, throwOnError As Boolean, ignoreCase As Boolean) As Type

Parameters

typeName
String

The assembly-qualified name of the type to get. See AssemblyQualifiedName. If the type is in the currently executing assembly or in mscorlib.dll/System.Private.CoreLib.dll, it's sufficient to supply the type name qualified by its namespace.

throwOnError
Boolean

true to throw an exception if the type cannot be found; false to return null. Specifying false also suppresses some other exception conditions, but not all of them. See the Exceptions section.

ignoreCase
Boolean

true to perform a case-insensitive search for typeName, false to perform a case-sensitive search for typeName.

Returns

The type with the specified name. If the type is not found, the throwOnError parameter specifies whether null is returned or an exception is thrown. In some cases, an exception is thrown regardless of the value of throwOnError. See the Exceptions section.

Exceptions

typeName is null.

A class initializer is invoked and throws an exception.

throwOnError is true and the type is not found.

-or-

throwOnError is true and typeName contains invalid characters, such as an embedded tab.

-or-

throwOnError is true and typeName is an empty string.

-or-

throwOnError is true and typeName represents an array type with an invalid size.

-or-

typeName represents an array of TypedReference.

throwOnError is true and typeName contains invalid syntax. For example, "MyType[,*,]".

-or-

typeName represents a generic type that has a pointer type, a ByRef type, or Void as one of its type arguments.

-or-

typeName represents a generic type that has an incorrect number of type arguments.

-or-

typeName represents a generic type, and one of its type arguments does not satisfy the constraints for the corresponding type parameter.

throwOnError is true and the assembly or one of its dependencies was not found.

The assembly or one of its dependencies was found, but could not be loaded.

The assembly is not valid for the currently loaded runtime.

Remarks

You can use the GetType method to obtain a Type object for a type in another assembly if you know its assembly-qualified name, which can be obtained from AssemblyQualifiedName. GetType causes loading of the assembly specified in typeName. You can also load an assembly using the Assembly.Load method, and then use the Assembly.GetType or Assembly.GetTypes method to get Type objects. If a type is in an assembly known to your program at compile time, it's more efficient to use typeof in C# or the GetType operator in Visual Basic.

GetType only works on assemblies loaded from disk. If you call GetType to look up a type defined in a dynamic assembly defined using the System.Reflection.Emit services, you might get inconsistent behavior. The behavior depends on whether the dynamic assembly is persistent, that is, created using the RunAndSave or Save access modes of the System.Reflection.Emit.AssemblyBuilderAccess enumeration. If the dynamic assembly is persistent and has been written to disk before GetType is called, the loader finds the saved assembly on disk, loads that assembly, and retrieves the type from that assembly. If the assembly has not been saved to disk when GetType is called, the method returns null. GetType does not understand transient dynamic assemblies; therefore, calling GetType to retrieve a type in a transient dynamic assembly returns null.

To use GetType on a dynamic module, subscribe to the AppDomain.AssemblyResolve event and call GetType before saving. Otherwise, you will get two copies of the assembly in memory.

The throwOnError parameter specifies what happens when the type is not found, and also suppresses certain other exception conditions, as described in the Exceptions section. Some exceptions are thrown regardless of the value of throwOnError. For example, if the type is found but cannot be loaded, a TypeLoadException is thrown even if throwOnError is false.

The following table shows what members of a base class are returned by the Get methods when reflecting on a type.

Member Type Static Non-Static
Constructor No No
Field No Yes. A field is always hide-by-name-and-signature.
Event Not applicable The common type system rule is that the inheritance is the same as that of the methods that implement the property. Reflection treats properties as hide-by-name-and-signature. See note 2 below.
Method No Yes. A method (both virtual and non-virtual) can be hide-by-name or hide-by-name-and-signature.
Nested Type No No
Property Not applicable The common type system rule is that the inheritance is the same as that of the methods that implement the property. Reflection treats properties as hide-by-name-and-signature. See note 2 below.
  1. Hide-by-name-and-signature considers all of the parts of the signature, including custom modifiers, return types, parameter types, sentinels, and unmanaged calling conventions. This is a binary comparison.

  2. For reflection, properties and events are hide-by-name-and-signature. If you have a property with both a get and a set accessor in the base class, but the derived class has only a get accessor, the derived class property hides the base class property, and you will not be able to access the setter on the base class.

  3. Custom attributes are not part of the common type system.

Arrays or COM types are not searched for unless they have already been loaded into the table of available classes.

typeName can be the type name qualified by its namespace or an assembly-qualified name that includes an assembly name specification. See AssemblyQualifiedName.

If typeName includes the namespace but not the assembly name, this method searches only the calling object's assembly and mscorlib.dll/System.Private.CoreLib.dll, in that order. If typeName is fully qualified with the partial or complete assembly name, this method searches in the specified assembly. If the assembly has a strong name, a complete assembly name is required.

The AssemblyQualifiedName property returns a fully qualified type name including nested types, the assembly name, and type arguments. All compilers that support the common language runtime will emit the simple name of a nested class, and reflection constructs a mangled name when queried, in accordance with the following conventions.

Note

Processor architecture is part of assembly identity, and can be specified as part of assembly name strings. For example, "ProcessorArchitecture=msil". However, it's not included in the string returned by the AssemblyQualifiedName property, for compatibility reasons. You can also load types by creating an AssemblyName object and passing it to an appropriate overload of the Load method. You can then use the Assembly.GetType method to load types from the assembly. See also AssemblyName.ProcessorArchitecture.

Delimiter Meaning
Backslash (\) Escape character.
Backtick (`) Precedes one or more digits representing the number of type parameters, located at the end of the name of a generic type.
Brackets ([]) Enclose a generic type argument list, for a constructed generic type; within a type argument list, enclose an assembly-qualified type.
Comma (,) Precedes the Assembly name.
Period (.) Denotes namespace identifiers.
Plus sign (+) Precedes a nested class.

For example, the fully qualified name for a class might look like this:

TopNamespace.SubNameSpace.ContainingClass+NestedClass,MyAssembly

If the namespace were TopNamespace.Sub+Namespace, then the string would have to precede the plus sign (+) with an escape character (\) to prevent it from being interpreted as a nesting separator. Reflection emits this string as follows:

TopNamespace.Sub\+Namespace.ContainingClass+NestedClass,MyAssembly

A "++" becomes "\+\+", and a "\" becomes "\\".

This qualified name can be persisted and later used to load the Type. To search for and load a Type, use GetType either with the type name only or with the assembly qualified type name. GetType with the type name only will look for the Type in the caller's assembly and then in the System assembly. GetType with the assembly qualified type name will look for the Type in any assembly.

Type names may include trailing characters that denote additional information about the type, such as whether the type is a reference type, a pointer type or an array type. To retrieve the type name without these trailing characters, use t.GetElementType().ToString(), where t is the type.

Spaces are relevant in all type name components except the assembly name. In the assembly name, spaces before the ',' separator are relevant, but spaces after the ',' separator are ignored.

The name of a generic type ends with a backtick (`) followed by digits representing the number of generic type arguments. The purpose of this name mangling is to allow compilers to support generic types with the same name but with different numbers of type parameters, occurring in the same scope. For example, reflection returns the mangled names Tuple`1 and Tuple`2 from the generic methods Tuple(Of T) and Tuple(Of T0, T1) in Visual Basic, or Tuple<T> and Tuple<T0, T1> in Visual C#.

For generic types, the type argument list is enclosed in brackets, and the type arguments are separated by commas. For example, a generic Dictionary<TKey,TValue> has two type parameters. A Dictionary<TKey,TValue> of MyType with keys of type String might be represented as follows:

System.Collections.Generic.Dictionary`2[System.String,MyType]

To specify an assembly-qualified type within a type argument list, enclose the assembly-qualified type within brackets. Otherwise, the commas that separate the parts of the assembly-qualified name are interpreted as delimiting additional type arguments. For example, a Dictionary<TKey,TValue> of MyType from MyAssembly.dll, with keys of type String, might be specified as follows:

Type.GetType("System.Collections.Generic.Dictionary`2[System.String,[MyType,MyAssembly]]")

Note

An assembly-qualified type can be enclosed in brackets only when it appears within a type parameter list. The rules for searching assemblies for qualified and unqualified types in type parameter lists are the same as the rules for qualified and unqualified nongeneric types.

Nullable types are a special case of generic types. For example, a nullable Int32 is represented by the string "System.Nullable`1[System.Int32]".

Note

In C#, C++, and Visual Basic you can also get nullable types using type operators. For example, the nullable Boolean type is returned by typeof(Nullable<bool>) in C#, by Nullable<Boolean>::typeid in C++, and by GetType(Nullable(Of Boolean)) in Visual Basic.

The following table shows the syntax you use with GetType for various types.

To Get Use
A nullable Int32 Type.GetType("System.Nullable`1[System.Int32]")
An unmanaged pointer to MyType Type.GetType("MyType*")
An unmanaged pointer to a pointer to MyType Type.GetType("MyType**")
A managed pointer or reference to MyType Type.GetType("MyType&"). Note that unlike pointers, references are limited to one level.
A parent class and a nested class Type.GetType("MyParentClass+MyNestedClass")
A one-dimensional array with a lower bound of 0 Type.GetType("MyArray[]")
A one-dimensional array with an unknown lower bound Type.GetType("MyArray[*]")
An n-dimensional array A comma (,) inside the brackets a total of n-1 times. For example, System.Object[,,] represents a three-dimensional Object array.
A two-dimensional array's array Type.GetType("MyArray[][]")
A rectangular two-dimensional array with unknown lower bounds Type.GetType("MyArray[,]")
A generic type with one type argument Type.GetType("MyGenericType`1[MyType]")
A generic type with two type arguments Type.GetType("MyGenericType`2[MyType,AnotherType]")
A generic type with two assembly-qualified type arguments Type.GetType("MyGenericType`2[[MyType,MyAssembly],[AnotherType,AnotherAssembly]]")
An assembly-qualified generic type with an assembly-qualified type argument Type.GetType("MyGenericType`1[[MyType,MyAssembly]],MyGenericTypeAssembly")
A generic type whose type argument is a generic type with two type arguments Type.GetType("MyGenericType`1[AnotherGenericType`2[MyType,AnotherType]]")

See also

Applies to

GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>)

Gets the type with the specified name, optionally providing custom methods to resolve the assembly and the type.

public:
 static Type ^ GetType(System::String ^ typeName, Func<System::Reflection::AssemblyName ^, System::Reflection::Assembly ^> ^ assemblyResolver, Func<System::Reflection::Assembly ^, System::String ^, bool, Type ^> ^ typeResolver);
public static Type? GetType (string typeName, Func<System.Reflection.AssemblyName,System.Reflection.Assembly?>? assemblyResolver, Func<System.Reflection.Assembly?,string,bool,Type?>? typeResolver);
public static Type GetType (string typeName, Func<System.Reflection.AssemblyName,System.Reflection.Assembly> assemblyResolver, Func<System.Reflection.Assembly,string,bool,Type> typeResolver);
static member GetType : string * Func<System.Reflection.AssemblyName, System.Reflection.Assembly> * Func<System.Reflection.Assembly, string, bool, Type> -> Type
Public Shared Function GetType (typeName As String, assemblyResolver As Func(Of AssemblyName, Assembly), typeResolver As Func(Of Assembly, String, Boolean, Type)) As Type

Parameters

typeName
String

The name of the type to get. If the typeResolver parameter is provided, the type name can be any string that typeResolver is capable of resolving. If the assemblyResolver parameter is provided or if standard type resolution is used, typeName must be an assembly-qualified name (see AssemblyQualifiedName), unless the type is in the currently executing assembly or in mscorlib.dll/System.Private.CoreLib.dll, in which case it's sufficient to supply the type name qualified by its namespace.

assemblyResolver
Func<AssemblyName,Assembly>

A method that locates and returns the assembly that is specified in typeName. The assembly name is passed to assemblyResolver as an AssemblyName object. If typeName does not contain the name of an assembly, assemblyResolver is not called. If assemblyResolver is not supplied, standard assembly resolution is performed.

Caution: Don't pass methods from unknown or untrusted callers. Doing so could result in elevation of privilege for malicious code. Use only methods that you provide or that you are familiar with.

typeResolver
Func<Assembly,String,Boolean,Type>

A method that locates and returns the type that is specified by typeName from the assembly that is returned by assemblyResolver or by standard assembly resolution. If no assembly is provided, the typeResolver method can provide one. The method also takes a parameter that specifies whether to perform a case-insensitive search; false is passed to that parameter.

Caution: Don't pass methods from unknown or untrusted callers.

Returns

The type with the specified name, or null if the type is not found.

Exceptions

typeName is null.

A class initializer is invoked and throws an exception.

An error occurs when typeName is parsed into a type name and an assembly name (for example, when the simple type name includes an unescaped special character).

-or-

typeName represents a generic type that has a pointer type, a ByRef type, or Void as one of its type arguments.

-or-

typeName represents a generic type that has an incorrect number of type arguments.

-or-

typeName represents a generic type, and one of its type arguments does not satisfy the constraints for the corresponding type parameter.

typeName represents an invalid type, for example, an array of TypedReference.

The assembly or one of its dependencies was found, but could not be loaded.

-or-

typeName contains an invalid assembly name.

-or-

typeName is a valid assembly name without a type name.

The assembly or one of its dependencies is not valid for the currently loaded runtime.

Remarks

Usage scenarios for this method and details about the assemblyResolver and typeResolver parameters can be found in the GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean, Boolean) method overload.

Note

If typeName cannot be found, the call to the GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>) method returns null. It does not throw an exception. To control whether an exception is thrown, call an overload of the GetType method that has a throwOnError parameter.

Calling this method overload is the same as calling the GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean, Boolean) method overload and specifying false for the throwOnError and ignoreCase parameters.

Applies to

GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean)

Gets the type with the specified name, specifying whether to throw an exception if the type is not found, and optionally providing custom methods to resolve the assembly and the type.

public:
 static Type ^ GetType(System::String ^ typeName, Func<System::Reflection::AssemblyName ^, System::Reflection::Assembly ^> ^ assemblyResolver, Func<System::Reflection::Assembly ^, System::String ^, bool, Type ^> ^ typeResolver, bool throwOnError);
public static Type? GetType (string typeName, Func<System.Reflection.AssemblyName,System.Reflection.Assembly?>? assemblyResolver, Func<System.Reflection.Assembly?,string,bool,Type?>? typeResolver, bool throwOnError);
public static Type GetType (string typeName, Func<System.Reflection.AssemblyName,System.Reflection.Assembly> assemblyResolver, Func<System.Reflection.Assembly,string,bool,Type> typeResolver, bool throwOnError);
static member GetType : string * Func<System.Reflection.AssemblyName, System.Reflection.Assembly> * Func<System.Reflection.Assembly, string, bool, Type> * bool -> Type
Public Shared Function GetType (typeName As String, assemblyResolver As Func(Of AssemblyName, Assembly), typeResolver As Func(Of Assembly, String, Boolean, Type), throwOnError As Boolean) As Type

Parameters

typeName
String

The name of the type to get. If the typeResolver parameter is provided, the type name can be any string that typeResolver is capable of resolving. If the assemblyResolver parameter is provided or if standard type resolution is used, typeName must be an assembly-qualified name (see AssemblyQualifiedName), unless the type is in the currently executing assembly or in mscorlib.dll/System.Private.CoreLib.dll, in which case it's sufficient to supply the type name qualified by its namespace.

assemblyResolver
Func<AssemblyName,Assembly>

A method that locates and returns the assembly that is specified in typeName. The assembly name is passed to assemblyResolver as an AssemblyName object. If typeName does not contain the name of an assembly, assemblyResolver is not called. If assemblyResolver is not supplied, standard assembly resolution is performed.

Caution: Don't pass methods from unknown or untrusted callers. Doing so could result in elevation of privilege for malicious code. Use only methods that you provide or that you are familiar with.

typeResolver
Func<Assembly,String,Boolean,Type>

A method that locates and returns the type that is specified by typeName from the assembly that is returned by assemblyResolver or by standard assembly resolution. If no assembly is provided, the method can provide one. The method also takes a parameter that specifies whether to perform a case-insensitive search; false is passed to that parameter.

Caution: Don't pass methods from unknown or untrusted callers.

throwOnError
Boolean

true to throw an exception if the type cannot be found; false to return null. Specifying false also suppresses some other exception conditions, but not all of them. See the Exceptions section.

Returns

The type with the specified name. If the type is not found, the throwOnError parameter specifies whether null is returned or an exception is thrown. In some cases, an exception is thrown regardless of the value of throwOnError. See the Exceptions section.

Exceptions

typeName is null.

A class initializer is invoked and throws an exception.

throwOnError is true and the type is not found.

-or-

throwOnError is true and typeName contains invalid characters, such as an embedded tab.

-or-

throwOnError is true and typeName is an empty string.

-or-

throwOnError is true and typeName represents an array type with an invalid size.

-or-

typeName represents an array of TypedReference.

An error occurs when typeName is parsed into a type name and an assembly name (for example, when the simple type name includes an unescaped special character).

-or-

throwOnError is true and typeName contains invalid syntax (for example, "MyType[,*,]").

-or-

typeName represents a generic type that has a pointer type, a ByRef type, or Void as one of its type arguments.

-or-

typeName represents a generic type that has an incorrect number of type arguments.

-or-

typeName represents a generic type, and one of its type arguments does not satisfy the constraints for the corresponding type parameter.

throwOnError is true and the assembly or one of its dependencies was not found.

-or-

typeName contains an invalid assembly name.

-or-

typeName is a valid assembly name without a type name.

The assembly or one of its dependencies was found, but could not be loaded.

The assembly or one of its dependencies is not valid for the currently loaded runtime.

Remarks

Usage scenarios for this method and details about the assemblyResolver and typeResolver parameters can be found in the GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean, Boolean) method overload.

Calling this method overload is the same as calling the GetType(String, Func<AssemblyName,Assembly>, Func<Assembly,String,Boolean,Type>, Boolean, Boolean) method overload and specifying false for the ignoreCase parameter.

Applies to