Monitores
Monitor objetos expõem a capacidade de sincronizar o acesso a uma região de código, utilizando e liberar um bloquear de um objeto específico usando o Monitor.Enter, Monitor.TryEnter, and Monitor.sair métodos.Depois que você tem um bloquear em uma região de código, você pode usar o Monitor.Wait, Monitor.Pulse, and Monitor.PulseAll métodos.Aguarde libera o bloquear se ele é mantido e aguarda para ser notificado.Quando Aguarde é notificado, ele retorna e obtém o bloquear novamente.Ambos os Pulso and PulseAll sinal para o próximo segmento na fila de espera para continuar.
O Visual Basic SyncLock e translation from VPE for Csharp lock instruções de uso Monitor.Enter usar o bloquear e Monitor.Exit para liberá-lo. A vantagem de usar as declarações de linguagem é que tudo no lock ou SyncLock incluído no bloco de um Try demonstrativo. The Try demonstrativo possui um Finally bloco para garantir que o bloquear será liberado.
Monitor bloqueia objetos (isto é, tipos de referência), não os tipos de valor.Enquanto você pode passar um tipo de valor para Digite and Sair, ele for in a box separadamente para cada telefonar.Como cada telefonar cria um objeto separado, Digite nunca bloqueia e o código que ele está protegendo supostamente realmente não será sincronizado.Além disso, o objeto passado para Sair é diferente do objeto passado para Digite, so Monitor throws SynchronizationLockExceptioncom a mensagem "método de sincronização de objetos foi chamado um bloco de código não sincronizado." O exemplo a seguir ilustra esses problemas.
Private x As Integer
' The next line creates a generic object containing the value of
' x each time the code is executed, so that Enter never blocks.
Monitor.Enter(x)
Try
' Code that needs to be protected by the monitor.
Finally
' Always use Finally to ensure that you exit the Monitor.
' The following line creates another object containing
' the value of x, and throws SynchronizationLockException
' because the two objects do not match.
Monitor.Exit(x)
End Try
private int x;
// The next line creates a generic object containing the value of
// x each time the code is executed, so that Enter never blocks.
Monitor.Enter(x);
try {
// Code that needs to be protected by the monitor.
}
finally {
// Always use Finally to ensure that you exit the Monitor.
// The following line creates another object containing
// the value of x, and throws SynchronizationLockException
// because the two objects do not match.
Monitor.Exit(x);
}
Embora uma variável de tipo de valor pode ser caixa antes de chamar Digite and Sair, conforme mostrado no exemplo seguinte e passar o mesmo processador in a box objeto para sistema autônomo dois métodos, não há nenhuma vantagem de fazer isso.As alterações a variável não são refletidas na cópia do processador in a box e não é possível alterar o valor da cópia do processador in a box.
Private o As Object = x
private Object o = x;
É importante observar a distinção entre o uso de Monitor and WaitHandle objetos.Monitor objetos são puramente gerenciado, totalmente portátil e podem ser mais eficientes em termos de requisitos de recursos de sistema operacional.WaitHandle objetos representam objetos waitable do sistema operacional, são úteis para sincronização entre código gerenciado e e expõem alguns recursos avançados do sistema operacional, como a capacidade de esperar por vários objetos ao mesmo tempo.
O exemplo de código a seguir demonstra o uso combinado da Monitor classe (implementada com o lock e SyncLock instruções de compilador), o Interlocked classe e o AutoResetEvent classe.
Imports System
Imports System.Threading
Imports Microsoft.VisualBasic
' Note: The class whose internal public member is the synchronizing method
' is not public; none of the client code takes a lock on the Resource object.
' The member of the nonpublic class takes the lock on itself. Written this
' way, malicious code cannot take a lock on a public object.
Class SyncResource
Public Sub Access(threadNum As Int32)
' Uses Monitor class to enforce synchronization.
SyncLock Me
' Synchronized: Despite the next conditional, each thread
' waits on its predecessor.
If threadNum Mod 2 = 0 Then
Thread.Sleep(2000)
End If
Console.WriteLine("Start Synched Resource access (Thread={0})", threadNum)
Thread.Sleep(200)
Console.WriteLine("Stop Synched Resource access (Thread={0})", threadNum)
End SyncLock
End Sub 'Access
End Class 'SyncResource
' Without the lock, the method is called in the order in which
' threads reach it.
Class UnSyncResource
Public Sub Access(threadNum As Int32)
' Does not use Monitor class to enforce synchronization.
' The next call throws the thread order.
If threadNum Mod 2 = 0 Then
Thread.Sleep(2000)
End If
Console.WriteLine("Start UnSynched Resource access (Thread={0})", threadNum)
Thread.Sleep(200)
Console.WriteLine("Stop UnSynched Resource access (Thread={0})", threadNum)
End Sub 'Access
End Class 'UnSyncResource
Public Class App
Private Shared numAsyncOps As Int32 = 5
Private Shared asyncOpsAreDone As New AutoResetEvent(False)
Private Shared SyncRes As New SyncResource()
Private Shared UnSyncRes As New UnSyncResource()
Private Shared threadNum As Int32
Public Shared Sub Main()
For threadNum = 0 To 4
ThreadPool.QueueUserWorkItem(AddressOf SyncUpdateResource, threadNum)
Next threadNum
' Wait until this WaitHandle is signaled.
asyncOpsAreDone.WaitOne()
Console.WriteLine(ControlChars.Tab + ControlChars.Lf + "All synchronized operations have completed." + ControlChars.Lf)
' Reset the thread count for unsynchronized calls.
numAsyncOps = 5
For threadNum = 0 To 4
ThreadPool.QueueUserWorkItem(AddressOf UnSyncUpdateResource, threadNum)
Next threadNum
' Wait until this WaitHandle is signaled.
asyncOpsAreDone.WaitOne()
Console.WriteLine(ControlChars.Tab + ControlChars.Cr + "All unsynchronized thread operations have completed.")
End Sub 'Main
' The callback method's signature MUST match that of
' a System.Threading.TimerCallback delegate
' (it takes an Object parameter and returns void).
Shared Sub SyncUpdateResource(state As Object)
' This calls the internal synchronized method, passing
' a thread number.
SyncRes.Access(CType(state, Int32))
' Count down the number of methods that the threads have called.
' This must be synchronized, however; you cannot know which thread
' will access the value **before** another thread's incremented
' value has been stored into the variable.
If Interlocked.Decrement(numAsyncOps) = 0 Then
asyncOpsAreDone.Set()
' Announce to Main that in fact all thread calls are done.
End If
End Sub 'SyncUpdateResource
' The callback method's signature MUST match that of
' a System.Threading.TimerCallback delegate
' (it takes an Object parameter and returns void).
Shared Sub UnSyncUpdateResource(state As [Object])
' This calls the unsynchronized method, passing
' a thread number.
UnSyncRes.Access(CType(state, Int32))
' Count down the number of methods that the threads have called.
' This must be synchronized, however; you cannot know which thread
' will access the value **before** another thread's incremented
' value has been stored into the variable.
If Interlocked.Decrement(numAsyncOps) = 0 Then
asyncOpsAreDone.Set()
' Announce to Main that in fact all thread calls are done.
End If
End Sub 'UnSyncUpdateResource
End Class 'App
using System;
using System.Threading;
// Note: The class whose internal public member is the synchronizing
// method is not public; none of the client code takes a lock on the
// Resource object.The member of the nonpublic class takes the lock on
// itself. Written this way, malicious code cannot take a lock on
// a public object.
class SyncResource {
public void Access(Int32 threadNum) {
// Uses Monitor class to enforce synchronization.
lock (this) {
// Synchronized: Despite the next conditional, each thread
// waits on its predecessor.
if (threadNum % 2 == 0)
Thread.Sleep(2000);
Console.WriteLine("Start Synched Resource access (Thread={0})", threadNum);
Thread.Sleep(200);
Console.WriteLine("Stop Synched Resource access (Thread={0})", threadNum);
}
}
}
// Without the lock, the method is called in the order in which threads reach it.
class UnSyncResource {
public void Access(Int32 threadNum) {
// Does not use Monitor class to enforce synchronization.
// The next call throws the thread order.
if (threadNum % 2 == 0)
Thread.Sleep(2000);
Console.WriteLine("Start UnSynched Resource access (Thread={0})", threadNum);
Thread.Sleep(200);
Console.WriteLine("Stop UnSynched Resource access (Thread={0})", threadNum);
}
}
public class App {
static Int32 numAsyncOps = 5;
static AutoResetEvent asyncOpsAreDone = new AutoResetEvent(false);
static SyncResource SyncRes = new SyncResource();
static UnSyncResource UnSyncRes = new UnSyncResource();
public static void Main() {
for (Int32 threadNum = 0; threadNum < 5; threadNum++) {
ThreadPool.QueueUserWorkItem(new WaitCallback(SyncUpdateResource), threadNum);
}
// Wait until this WaitHandle is signaled.
asyncOpsAreDone.WaitOne();
Console.WriteLine("\t\nAll synchronized operations have completed.\t\n");
// Reset the thread count for unsynchronized calls.
numAsyncOps = 5;
for (Int32 threadNum = 0; threadNum < 5; threadNum++) {
ThreadPool.QueueUserWorkItem(new WaitCallback(UnSyncUpdateResource), threadNum);
}
// Wait until this WaitHandle is signaled.
asyncOpsAreDone.WaitOne();
Console.WriteLine("\t\nAll unsynchronized thread operations have completed.");
}
// The callback method's signature MUST match that of a
// System.Threading.TimerCallback delegate (it takes an Object
// parameter and returns void).
static void SyncUpdateResource(Object state) {
// This calls the internal synchronized method, passing
// a thread number.
SyncRes.Access((Int32) state);
// Count down the number of methods that the threads have called.
// This must be synchronized, however; you cannot know which thread
// will access the value **before** another thread's incremented
// value has been stored into the variable.
if (Interlocked.Decrement(ref numAsyncOps) == 0)
asyncOpsAreDone.Set();
// Announce to Main that in fact all thread calls are done.
}
// The callback method's signature MUST match that of a
// System.Threading.TimerCallback delegate (it takes an Object
// parameter and returns void).
static void UnSyncUpdateResource(Object state) {
// This calls the unsynchronized method, passing a thread number.
UnSyncRes.Access((Int32) state);
// Count down the number of methods that the threads have called.
// This must be synchronized, however; you cannot know which thread
// will access the value **before** another thread's incremented
// value has been stored into the variable.
if (Interlocked.Decrement(ref numAsyncOps) == 0)
asyncOpsAreDone.Set();
// Announce to Main that in fact all thread calls are done.
}
}
Consulte também
Referência
Outros recursos
Recursos e objetos de Threading
Date |
History |
Motivo |
---|---|---|
Julho de 2008 |
Esclarecimento adicional: SyncLock e lock instruções de uso Monitor.Enter e Exit. |
Comentários do cliente. |