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WaitOrTimerCallback (Delegado)

Representa un método al que se debe llamar cuando un WaitHandle está señalado o se agota su tiempo de espera.

Espacio de nombres: System.Threading
Ensamblado: mscorlib (en mscorlib.dll)

[ComVisibleAttribute(true)] 
public delegate void WaitOrTimerCallback (
	Object state,
	bool timedOut
)
/** @delegate */
/** @attribute ComVisibleAttribute(true) */ 
public delegate void WaitOrTimerCallback (
	Object state, 
	boolean timedOut
)
No aplicable.

Parámetros

state

Objeto que contiene la información que va a utilizar el método de devolución de llamadas cada vez que se ejecute.

timedOut

true si WaitHandle ha agotado el tiempo de espera; false si estaba señalado.

WaitOrTimerCallback representa un método de devolución de llamadas que se desea ejecutar cuando un identificador de espera registrado agota el tiempo de espera o está marcado. Cree el delegado pasando el método de devolución de llamadas al constructor WaitOrTimerCallback. El método debe tener la firma que se muestra aquí.

Cree el identificador de espera registrado pasando el delegado de WaitOrTimerCallback y un WaitHandle a ThreadPool.RegisterWaitForSingleObject. El método de devolución de llamadas se ejecuta cada vez que WaitHandle agota el tiempo de espera o se señala.

NotaNota:

Los usuarios de Visual Basic pueden omitir el constructor WaitOrTimerCallback y utilizar simplemente el operador AddressOf al pasar el método de devolución de llamadas a RegisterWaitForSingleObject. Visual Basic llama automáticamente al constructor de delegados correcto.

Si desea pasar información al método de devolución de llamadas, cree un objeto con la información necesaria y páselo a RegisterWaitForSingleObject al crear el identificador de espera registrado. Cada vez que se ejecuta el método de devolución de llamadas, el parámetro state contiene este objeto.

Para obtener más información sobre cómo utilizar métodos de devolución de llamada para sincronizar subprocesos de grupo de subprocesos, vea Grupo de subprocesos administrados.

using System;
using System.Threading;

// TaskInfo contains data that will be passed to the callback
// method.
public class TaskInfo {
    public RegisteredWaitHandle Handle = null;
    public string OtherInfo = "default";
}

public class Example {
    public static void Main(string[] args) {
        // The main thread uses AutoResetEvent to signal the
        // registered wait handle, which executes the callback
        // method.
        AutoResetEvent ev = new AutoResetEvent(false);

        TaskInfo ti = new TaskInfo();
        ti.OtherInfo = "First task";
        // The TaskInfo for the task includes the registered wait
        // handle returned by RegisterWaitForSingleObject.  This
        // allows the wait to be terminated when the object has
        // been signaled once (see WaitProc).
        ti.Handle = ThreadPool.RegisterWaitForSingleObject(
            ev,
            new WaitOrTimerCallback(WaitProc),
            ti,
            1000,
            false
        );

        // The main thread waits three seconds, to demonstrate the
        // time-outs on the queued thread, and then signals.
        Thread.Sleep(3100);
        Console.WriteLine("Main thread signals.");
        ev.Set();

        // The main thread sleeps, which should give the callback
        // method time to execute.  If you comment out this line, the
        // program usually ends before the ThreadPool thread can execute.
        Thread.Sleep(1000);
        // If you start a thread yourself, you can wait for it to end
        // by calling Thread.Join.  This option is not available with 
        // thread pool threads.
    }
   
    // The callback method executes when the registered wait times out,
    // or when the WaitHandle (in this case AutoResetEvent) is signaled.
    // WaitProc unregisters the WaitHandle the first time the event is 
    // signaled.
    public static void WaitProc(object state, bool timedOut) {
        // The state object must be cast to the correct type, because the
        // signature of the WaitOrTimerCallback delegate specifies type
        // Object.
        TaskInfo ti = (TaskInfo) state;

        string cause = "TIMED OUT";
        if (!timedOut) {
            cause = "SIGNALED";
            // If the callback method executes because the WaitHandle is
            // signaled, stop future execution of the callback method
            // by unregistering the WaitHandle.
            if (ti.Handle != null)
                ti.Handle.Unregister(null);
        } 

        Console.WriteLine("WaitProc( {0} ) executes on thread {1}; cause = {2}.",
            ti.OtherInfo, 
            Thread.CurrentThread.GetHashCode().ToString(), 
            cause
        );
    }
}

import System.*;
import System.Threading.*;
import System.Threading.Thread;

// TaskInfo contains data that will be passed to the callback
// method.
public class TaskInfo
{
    public RegisteredWaitHandle handle = null;
    public String otherInfo = "default";
} //TaskInfo

public class Example
{
    public static void main(String[] args)
    {
        // The main thread uses AutoResetEvent to signal the
        // registered wait Handle, which executes the callback
        // method.
        AutoResetEvent ev = new AutoResetEvent(false);
        TaskInfo ti = new TaskInfo();

        ti.otherInfo = "First task";

        // The TaskInfo for the task includes the registered wait
        // Handle returned by RegisterWaitForSingleObject.  This
        // allows the wait to be terminated when the object has
        // been signaled once (see WaitProc).
        ti.handle = ThreadPool.RegisterWaitForSingleObject(ev, 
            new WaitOrTimerCallback(WaitProc), ti, 1000, false);

        // The main thread waits three seconds, to demonstrate the
        // time-outs on the queued thread, and then signals.
        Thread.Sleep(3100);
        Console.WriteLine("Main thread signals.");
        ev.Set();

        // The main thread sleeps, which should give the callback
        // method time to execute.  If you comment out this line, the
        // program usually ends before the ThreadPool thread can execute.
        Thread.Sleep(1000);
        // If you start a thread yourself, you can wait for it to end
        // by calling Thread.Join.  This option is not available with 
        // thread pool threads.
    } //main

    // The callback method executes when the registered wait times out,
    // or when the WaitHandle (in this case AutoResetEvent) is signaled.
    // WaitProc unregisters the WaitHandle the first time the event is 
    // signaled.
    public static void WaitProc(Object state, boolean timedOut)
    {
        // The state object must be cast to the correct type, because the
        // signature of the WaitOrTimerCallback delegate specifies type
        // Object.
        TaskInfo ti = ((TaskInfo)(state));
        String cause = "TIMED OUT";

        if (!(timedOut)) {
            cause = "SIGNALED";

            // If the callback method executes because the WaitHandle is
            // signaled, stop future execution of the callback method
            // by unregistering the WaitHandle.
            if (ti.handle != null) {
                ti.handle.Unregister(null);
            }
        }

        Console.WriteLine("WaitProc( {0} ) executes " 
            + "on thread {1}; cause = {2}.",
            ti.otherInfo, 
            String.valueOf(Thread.get_CurrentThread().GetHashCode()),cause);
    } //WaitProc
} //Example

Windows 98, Windows 2000 Service Pack 4, Windows Millennium, Windows Server 2003, Windows XP Media Center, Windows XP Professional x64, Windows XP SP2, Windows XP Starter

Microsoft .NET Framework 3.0 es compatible con Windows Vista, Microsoft Windows XP SP2 y Windows Server 2003 SP1.

.NET Framework

Compatible con: 3.0, 2.0, 1.1, 1.0
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