IDisposable.Dispose Metoda

Definice

Provede aplikací definované úlohy spojené s uvolněním nebo resetováním nespravovaných prostředků.

public:
 void Dispose();
public void Dispose ();
abstract member Dispose : unit -> unit
Public Sub Dispose ()

Příklady

Následující příklad ukazuje, jak můžete implementovat metodu Dispose .

#using <System.dll>
#using <System.Windows.Forms.dll>

using namespace System;
using namespace System::ComponentModel;
using namespace System::Windows::Forms;

// The following example demonstrates how to create a class that 
// implements the IDisposable interface and the IDisposable.Dispose
// method with finalization to clean up unmanaged resources. 
//
public ref class MyResource: public IDisposable
{
private:

   // Pointer to an external unmanaged resource.
   IntPtr handle;

   // A managed resource this class uses.
   Component^ component;

   // Track whether Dispose has been called.
   bool disposed;

public:
   // The class constructor.
   MyResource( IntPtr handle, Component^ component )
   {
      this->handle = handle;
      this->component = component;
      disposed = false;
   }

   // This method is called if the user explicitly disposes of the
   // object (by calling the Dispose method in other managed languages, 
   // or the destructor in C++). The compiler emits as a call to 
   // GC::SuppressFinalize( this ) for you, so there is no need to 
   // call it here.
   ~MyResource() 
   {
      // Dispose of managed resources.
      component->~Component();

      // Call C++ finalizer to clean up unmanaged resources.
      this->!MyResource();

      // Mark the class as disposed. This flag allows you to throw an
      // exception if a disposed object is accessed.
      disposed = true;
   }

   // Use interop to call the method necessary to clean up the 
   // unmanaged resource.
   //
   [System::Runtime::InteropServices::DllImport("Kernel32")]
   static Boolean CloseHandle( IntPtr handle );

   // The C++ finalizer destructor ensures that unmanaged resources get
   // released if the user releases the object without explicitly 
   // disposing of it.
   //
   !MyResource()
   {      
      // Call the appropriate methods to clean up unmanaged 
      // resources here. If disposing is false when Dispose(bool,
      // disposing) is called, only the following code is executed.
      CloseHandle( handle );
      handle = IntPtr::Zero;
   }

};

void main()
{
   // Insert code here to create and use the MyResource object.
   MyResource^ mr = gcnew MyResource((IntPtr) 42, (Component^) gcnew Button());
   mr->~MyResource();
}
using System;
using System.ComponentModel;

// The following example demonstrates how to create
// a resource class that implements the IDisposable interface
// and the IDisposable.Dispose method.

public class DisposeExample
{
    // A base class that implements IDisposable.
    // By implementing IDisposable, you are announcing that
    // instances of this type allocate scarce resources.
    public class MyResource: IDisposable
    {
        // Pointer to an external unmanaged resource.
        private IntPtr handle;
        // Other managed resource this class uses.
        private Component component = new Component();
        // Track whether Dispose has been called.
        private bool disposed = false;

        // The class constructor.
        public MyResource(IntPtr handle)
        {
            this.handle = handle;
        }

        // Implement IDisposable.
        // Do not make this method virtual.
        // A derived class should not be able to override this method.
        public void Dispose()
        {
            Dispose(disposing: true);
            // This object will be cleaned up by the Dispose method.
            // Therefore, you should call GC.SuppressFinalize to
            // take this object off the finalization queue
            // and prevent finalization code for this object
            // from executing a second time.
            GC.SuppressFinalize(this);
        }

        // Dispose(bool disposing) executes in two distinct scenarios.
        // If disposing equals true, the method has been called directly
        // or indirectly by a user's code. Managed and unmanaged resources
        // can be disposed.
        // If disposing equals false, the method has been called by the
        // runtime from inside the finalizer and you should not reference
        // other objects. Only unmanaged resources can be disposed.
        protected virtual void Dispose(bool disposing)
        {
            // Check to see if Dispose has already been called.
            if(!this.disposed)
            {
                // If disposing equals true, dispose all managed
                // and unmanaged resources.
                if(disposing)
                {
                    // Dispose managed resources.
                    component.Dispose();
                }

                // Call the appropriate methods to clean up
                // unmanaged resources here.
                // If disposing is false,
                // only the following code is executed.
                CloseHandle(handle);
                handle = IntPtr.Zero;

                // Note disposing has been done.
                disposed = true;
            }
        }

        // Use interop to call the method necessary
        // to clean up the unmanaged resource.
        [System.Runtime.InteropServices.DllImport("Kernel32")]
        private extern static Boolean CloseHandle(IntPtr handle);

        // Use C# finalizer syntax for finalization code.
        // This finalizer will run only if the Dispose method
        // does not get called.
        // It gives your base class the opportunity to finalize.
        // Do not provide finalizer in types derived from this class.
        ~MyResource()
        {
            // Do not re-create Dispose clean-up code here.
            // Calling Dispose(disposing: false) is optimal in terms of
            // readability and maintainability.
            Dispose(disposing: false);
        }
    }
    public static void Main()
    {
        // Insert code here to create
        // and use the MyResource object.
    }
}
// The following example demonstrates how to create
// a resource class that implements the IDisposable interface
// and the IDisposable.Dispose method.
open System
open System.ComponentModel
open System.Runtime.InteropServices

// Use interop to call the method necessary
// to clean up the unmanaged resource.
[<DllImport "Kernel32">]
extern Boolean CloseHandle(nativeint handle)

// A base class that implements IDisposable.
// By implementing IDisposable, you are announcing that
// instances of this type allocate scarce resources.
type MyResource(handle: nativeint) =
    // Pointer to an external unmanaged resource.
    let mutable handle = handle

    // Other managed resource this class uses.
    let comp = new Component()
    
    // Track whether Dispose has been called.
    let mutable disposed = false

    // Implement IDisposable.
    // Do not make this method virtual.
    // A derived class should not be able to override this method.
    interface IDisposable with
        member this.Dispose() =
            this.Dispose true
            // This object will be cleaned up by the Dispose method.
            // Therefore, you should call GC.SuppressFinalize to
            // take this object off the finalization queue
            // and prevent finalization code for this object
            // from executing a second time.
            GC.SuppressFinalize this

    // Dispose(bool disposing) executes in two distinct scenarios.
    // If disposing equals true, the method has been called directly
    // or indirectly by a user's code. Managed and unmanaged resources
    // can be disposed.
    // If disposing equals false, the method has been called by the
    // runtime from inside the finalizer and you should not reference
    // other objects. Only unmanaged resources can be disposed.
    abstract Dispose: bool -> unit
    override _.Dispose(disposing) =
        // Check to see if Dispose has already been called.
        if not disposed then
            // If disposing equals true, dispose all managed
            // and unmanaged resources.
            if disposing then
                // Dispose managed resources.
                comp.Dispose()

            // Call the appropriate methods to clean up
            // unmanaged resources here.
            // If disposing is false,
            // only the following code is executed.
            CloseHandle handle |> ignore
            handle <- IntPtr.Zero

            // Note disposing has been done.
            disposed <- true


    // This finalizer will run only if the Dispose method
    // does not get called.
    // It gives your base class the opportunity to finalize.
    // Do not provide finalizer in types derived from this class.
    override this.Finalize() =
        // Do not re-create Dispose clean-up code here.
        // Calling Dispose(disposing: false) is optimal in terms of
        // readability and maintainability.
        this.Dispose false
Imports System.ComponentModel

' The following example demonstrates how to create
' a resource class that implements the IDisposable interface
' and the IDisposable.Dispose method.
Public Class DisposeExample

   ' A class that implements IDisposable.
   ' By implementing IDisposable, you are announcing that
   ' instances of this type allocate scarce resources.
   Public Class MyResource
      Implements IDisposable
      ' Pointer to an external unmanaged resource.
      Private handle As IntPtr
      ' Other managed resource this class uses.
      Private component As component
      ' Track whether Dispose has been called.
      Private disposed As Boolean = False

      ' The class constructor.
      Public Sub New(ByVal handle As IntPtr)
         Me.handle = handle
      End Sub

      ' Implement IDisposable.
      ' Do not make this method virtual.
      ' A derived class should not be able to override this method.
      Public Overloads Sub Dispose() Implements IDisposable.Dispose
         Dispose(disposing:=True)
         ' This object will be cleaned up by the Dispose method.
         ' Therefore, you should call GC.SupressFinalize to
         ' take this object off the finalization queue
         ' and prevent finalization code for this object
         ' from executing a second time.
         GC.SuppressFinalize(Me)
      End Sub

      ' Dispose(bool disposing) executes in two distinct scenarios.
      ' If disposing equals true, the method has been called directly
      ' or indirectly by a user's code. Managed and unmanaged resources
      ' can be disposed.
      ' If disposing equals false, the method has been called by the
      ' runtime from inside the finalizer and you should not reference
      ' other objects. Only unmanaged resources can be disposed.
      Protected Overridable Overloads Sub Dispose(ByVal disposing As Boolean)
         ' Check to see if Dispose has already been called.
         If Not Me.disposed Then
            ' If disposing equals true, dispose all managed
            ' and unmanaged resources.
            If disposing Then
               ' Dispose managed resources.
               component.Dispose()
            End If

            ' Call the appropriate methods to clean up
            ' unmanaged resources here.
            ' If disposing is false,
            ' only the following code is executed.
            CloseHandle(handle)
            handle = IntPtr.Zero

            ' Note disposing has been done.
            disposed = True

         End If
      End Sub

      ' Use interop to call the method necessary
      ' to clean up the unmanaged resource.
      <System.Runtime.InteropServices.DllImport("Kernel32")> _
      Private Shared Function CloseHandle(ByVal handle As IntPtr) As [Boolean]
      End Function

      ' This finalizer will run only if the Dispose method
      ' does not get called.
      ' It gives your base class the opportunity to finalize.
      ' Do not provide finalize methods in types derived from this class.
      Protected Overrides Sub Finalize()
         ' Do not re-create Dispose clean-up code here.
         ' Calling Dispose(disposing:=False) is optimal in terms of
         ' readability and maintainability.
         Dispose(disposing:=False)
         MyBase.Finalize()
      End Sub
   End Class

   Public Shared Sub Main()
      ' Insert code here to create
      ' and use the MyResource object.
   End Sub

End Class

Poznámky

Pomocí této metody můžete zavřít nebo uvolnit nespravované prostředky, jako jsou soubory, datové proudy a popisovače uchovávané instancí třídy, která implementuje toto rozhraní. Podle konvence se tato metoda používá pro všechny úlohy spojené s uvolněním prostředků uložených objektem nebo přípravou objektu pro opakované použití.

Upozornění

Pokud používáte třídu, která implementuje IDisposable rozhraní, měli byste po dokončení použití třídy volat její Dispose implementaci. Další informace najdete v části "Použití objektu, který implementuje IDisposable" v tématu IDisposable .

Při implementaci této metody se ujistěte, že jsou uvolněny všechny uchovávané prostředky šířením volání v hierarchii obsahu. Pokud například objekt A přidělí objekt B a objekt B objekt C, pak implementace A Dispose musí volat Dispose na B, který musí zase volat Dispose na C.

Důležité

Kompilátor jazyka C++ podporuje deterministické odstranění prostředků a neumožňuje přímou implementaci Dispose metody.

Objekt musí také volat metodu Dispose své základní třídy, pokud základní třída implementuje IDisposable. Další informace o implementaci IDisposable základní třídy a jejích podtříd najdete v části IDisposable a hierarchie dědičnosti v IDisposable tématu.

Pokud je metoda objektu Dispose volána více než jednou, musí objekt ignorovat všechna volání po prvním z nich. Objekt nesmí vyvolat výjimku, pokud je jeho Dispose metoda volána vícekrát. Jiné metody instance než Dispose mohou vyvolat chybu ObjectDisposedException , pokud jsou prostředky již odstraněny.

Uživatelé můžou očekávat, že typ prostředku použije konkrétní konvenci k označení přiděleného stavu a uvolněného stavu. Příkladem jsou třídy streamu, které se tradičně považují za otevřené nebo uzavřené. Implementátor třídy, která má takovou konvenci, se může rozhodnout implementovat veřejnou metodu s přizpůsobeným názvem, například Close, která volá metodu Dispose .

Vzhledem k tomu, že Dispose metoda musí být volána explicitně, vždy existuje nebezpečí, že nespravované prostředky nebudou uvolněny, protože příjemce objektu nedokáže volat jeho Dispose metodu. Existují dva způsoby, jak se tomu vyhnout:

  • Zabalení spravovaného prostředku do objektu odvozeného z System.Runtime.InteropServices.SafeHandle. Vaše Dispose implementace pak zavolá Dispose metodu System.Runtime.InteropServices.SafeHandle instancí. Další informace najdete v části "The SafeHandle alternative" v tématu Object.Finalize .

  • Implementujte finalizační metodu pro volné prostředky, pokud Dispose není volána. Ve výchozím nastavení systém uvolňování paměti automaticky volá finalizátor objektu před uvolněním jeho paměti. Pokud Dispose však byla volána metoda, je obvykle zbytečné, aby systém uvolňování paměti volal finalizační metodu odstraněného objektu. Aby se zabránilo automatickému dokončování, Dispose mohou implementace volat metodu GC.SuppressFinalize .

Při použití objektu, který přistupuje k nespravovaným prostředkům, jako StreamWriterje , je dobrým postupem vytvořit instanci pomocí using příkazu. Příkaz using automaticky zavře datový proud a zavolá Dispose objekt po dokončení kódu, který ho používá. Příklad najdete ve StreamWriter třídě.

Platí pro

Viz také