TaskScheduler TaskScheduler TaskScheduler TaskScheduler Class

Définition

Représente un objet qui gère les tâches de bas niveau de la mise en file d'attente de tâches sur des threads.Represents an object that handles the low-level work of queuing tasks onto threads.

public ref class TaskScheduler abstract
public abstract class TaskScheduler
type TaskScheduler = class
Public MustInherit Class TaskScheduler
Héritage
TaskSchedulerTaskSchedulerTaskSchedulerTaskScheduler

Exemples

L’exemple suivant provient de la exemples de programmation parallèle avec .NET Framework 4 sur le site Web MSDN Code Gallery.The following example is taken from the Samples for Parallel Programming with the .NET Framework 4 on the MSDN Code Gallery Web site. Il crée un planificateur de tâches personnalisée qui limite le nombre de threads utilisés par l’application.It creates a custom task scheduler that limits the number of threads used by the app. Ensuite, il lance les deux ensembles de tâches et affiche des informations sur la tâche et le thread sur lequel la tâche s’exécute.It then launches two sets of tasks and displays information about the task and the thread on which the task is executing.

using System;
using System.Collections.Generic;
using System.Threading;
using System.Threading.Tasks;

class Example
{
   static void Main()
   {
       // Create a scheduler that uses two threads. 
       LimitedConcurrencyLevelTaskScheduler lcts = new LimitedConcurrencyLevelTaskScheduler(2);
       List<Task> tasks = new List<Task>();
       
       // Create a TaskFactory and pass it our custom scheduler. 
       TaskFactory factory = new TaskFactory(lcts);
       CancellationTokenSource cts = new CancellationTokenSource();
       
       // Use our factory to run a set of tasks. 
       Object lockObj = new Object();
       int outputItem = 0;
       
       for (int tCtr = 0; tCtr <= 4; tCtr++) {
          int iteration = tCtr;
          Task t = factory.StartNew(() => {
                                       for (int i = 0; i < 1000; i++) {
                                          lock (lockObj) {
                                             Console.Write("{0} in task t-{1} on thread {2}   ", 
                                                           i, iteration, Thread.CurrentThread.ManagedThreadId);
                                             outputItem++;
                                             if (outputItem % 3 == 0)
                                                Console.WriteLine();
                                          }
                                       }                   
                                    }, cts.Token);
          tasks.Add(t);                      
      }
      // Use it to run a second set of tasks.                       
      for (int tCtr = 0; tCtr <= 4; tCtr++) {
         int iteration = tCtr;
         Task t1 = factory.StartNew(() => {
                                       for (int outer = 0; outer <= 10; outer++) {
                                          for (int i = 0x21; i <= 0x7E; i++) {
                                             lock (lockObj) {
                                                Console.Write("'{0}' in task t1-{1} on thread {2}   ", 
                                                              Convert.ToChar(i), iteration, Thread.CurrentThread.ManagedThreadId);
                                                outputItem++;
                                                if (outputItem % 3 == 0)
                                                   Console.WriteLine();
                                             } 
                                          }
                                       }                                           
                                    }, cts.Token);           
         tasks.Add(t1);
      }
      
      // Wait for the tasks to complete before displaying a completion message.
      Task.WaitAll(tasks.ToArray());
      cts.Dispose();
      Console.WriteLine("\n\nSuccessful completion.");
   }
}

// Provides a task scheduler that ensures a maximum concurrency level while 
// running on top of the thread pool.
public class LimitedConcurrencyLevelTaskScheduler : TaskScheduler
{
   // Indicates whether the current thread is processing work items.
   [ThreadStatic]
   private static bool _currentThreadIsProcessingItems;

  // The list of tasks to be executed 
   private readonly LinkedList<Task> _tasks = new LinkedList<Task>(); // protected by lock(_tasks)

   // The maximum concurrency level allowed by this scheduler. 
   private readonly int _maxDegreeOfParallelism;

   // Indicates whether the scheduler is currently processing work items. 
   private int _delegatesQueuedOrRunning = 0;

   // Creates a new instance with the specified degree of parallelism. 
   public LimitedConcurrencyLevelTaskScheduler(int maxDegreeOfParallelism)
   {
       if (maxDegreeOfParallelism < 1) throw new ArgumentOutOfRangeException("maxDegreeOfParallelism");
       _maxDegreeOfParallelism = maxDegreeOfParallelism;
   }

   // Queues a task to the scheduler. 
   protected sealed override void QueueTask(Task task)
   {
      // Add the task to the list of tasks to be processed.  If there aren't enough 
      // delegates currently queued or running to process tasks, schedule another. 
       lock (_tasks)
       {
           _tasks.AddLast(task);
           if (_delegatesQueuedOrRunning < _maxDegreeOfParallelism)
           {
               ++_delegatesQueuedOrRunning;
               NotifyThreadPoolOfPendingWork();
           }
       }
   }

   // Inform the ThreadPool that there's work to be executed for this scheduler. 
   private void NotifyThreadPoolOfPendingWork()
   {
       ThreadPool.UnsafeQueueUserWorkItem(_ =>
       {
           // Note that the current thread is now processing work items.
           // This is necessary to enable inlining of tasks into this thread.
           _currentThreadIsProcessingItems = true;
           try
           {
               // Process all available items in the queue.
               while (true)
               {
                   Task item;
                   lock (_tasks)
                   {
                       // When there are no more items to be processed,
                       // note that we're done processing, and get out.
                       if (_tasks.Count == 0)
                       {
                           --_delegatesQueuedOrRunning;
                           break;
                       }

                       // Get the next item from the queue
                       item = _tasks.First.Value;
                       _tasks.RemoveFirst();
                   }

                   // Execute the task we pulled out of the queue
                   base.TryExecuteTask(item);
               }
           }
           // We're done processing items on the current thread
           finally { _currentThreadIsProcessingItems = false; }
       }, null);
   }

   // Attempts to execute the specified task on the current thread. 
   protected sealed override bool TryExecuteTaskInline(Task task, bool taskWasPreviouslyQueued)
   {
       // If this thread isn't already processing a task, we don't support inlining
       if (!_currentThreadIsProcessingItems) return false;

       // If the task was previously queued, remove it from the queue
       if (taskWasPreviouslyQueued) 
          // Try to run the task. 
          if (TryDequeue(task)) 
            return base.TryExecuteTask(task);
          else
             return false; 
       else 
          return base.TryExecuteTask(task);
   }

   // Attempt to remove a previously scheduled task from the scheduler. 
   protected sealed override bool TryDequeue(Task task)
   {
       lock (_tasks) return _tasks.Remove(task);
   }

   // Gets the maximum concurrency level supported by this scheduler. 
   public sealed override int MaximumConcurrencyLevel { get { return _maxDegreeOfParallelism; } }

   // Gets an enumerable of the tasks currently scheduled on this scheduler. 
   protected sealed override IEnumerable<Task> GetScheduledTasks()
   {
       bool lockTaken = false;
       try
       {
           Monitor.TryEnter(_tasks, ref lockTaken);
           if (lockTaken) return _tasks;
           else throw new NotSupportedException();
       }
       finally
       {
           if (lockTaken) Monitor.Exit(_tasks);
       }
   }
}
// The following is a portion of the output from a single run of the example:
//    'T' in task t1-4 on thread 3   'U' in task t1-4 on thread 3   'V' in task t1-4 on thread 3   
//    'W' in task t1-4 on thread 3   'X' in task t1-4 on thread 3   'Y' in task t1-4 on thread 3   
//    'Z' in task t1-4 on thread 3   '[' in task t1-4 on thread 3   '\' in task t1-4 on thread 3   
//    ']' in task t1-4 on thread 3   '^' in task t1-4 on thread 3   '_' in task t1-4 on thread 3   
//    '`' in task t1-4 on thread 3   'a' in task t1-4 on thread 3   'b' in task t1-4 on thread 3   
//    'c' in task t1-4 on thread 3   'd' in task t1-4 on thread 3   'e' in task t1-4 on thread 3   
//    'f' in task t1-4 on thread 3   'g' in task t1-4 on thread 3   'h' in task t1-4 on thread 3   
//    'i' in task t1-4 on thread 3   'j' in task t1-4 on thread 3   'k' in task t1-4 on thread 3   
//    'l' in task t1-4 on thread 3   'm' in task t1-4 on thread 3   'n' in task t1-4 on thread 3   
//    'o' in task t1-4 on thread 3   'p' in task t1-4 on thread 3   ']' in task t1-2 on thread 4   
//    '^' in task t1-2 on thread 4   '_' in task t1-2 on thread 4   '`' in task t1-2 on thread 4   
//    'a' in task t1-2 on thread 4   'b' in task t1-2 on thread 4   'c' in task t1-2 on thread 4   
//    'd' in task t1-2 on thread 4   'e' in task t1-2 on thread 4   'f' in task t1-2 on thread 4   
//    'g' in task t1-2 on thread 4   'h' in task t1-2 on thread 4   'i' in task t1-2 on thread 4   
//    'j' in task t1-2 on thread 4   'k' in task t1-2 on thread 4   'l' in task t1-2 on thread 4   
//    'm' in task t1-2 on thread 4   'n' in task t1-2 on thread 4   'o' in task t1-2 on thread 4   
//    'p' in task t1-2 on thread 4   'q' in task t1-2 on thread 4   'r' in task t1-2 on thread 4   
//    's' in task t1-2 on thread 4   't' in task t1-2 on thread 4   'u' in task t1-2 on thread 4   
//    'v' in task t1-2 on thread 4   'w' in task t1-2 on thread 4   'x' in task t1-2 on thread 4   
//    'y' in task t1-2 on thread 4   'z' in task t1-2 on thread 4   '{' in task t1-2 on thread 4   
//    '|' in task t1-2 on thread 4   '}' in task t1-2 on thread 4   '~' in task t1-2 on thread 4   
//    'q' in task t1-4 on thread 3   'r' in task t1-4 on thread 3   's' in task t1-4 on thread 3   
//    't' in task t1-4 on thread 3   'u' in task t1-4 on thread 3   'v' in task t1-4 on thread 3   
//    'w' in task t1-4 on thread 3   'x' in task t1-4 on thread 3   'y' in task t1-4 on thread 3   
//    'z' in task t1-4 on thread 3   '{' in task t1-4 on thread 3   '|' in task t1-4 on thread 3  
Imports System.Collections.Generic
Imports System.Threading
Imports System.Threading.Tasks

Module Example
   Sub Main()
      ' Create a scheduler that uses two threads. 
      Dim lcts As New LimitedConcurrencyLevelTaskScheduler(2)
      Dim tasks As New List(Of Task)()
      
      ' Create a TaskFactory and pass it our custom scheduler. 
      Dim factory As New TaskFactory(lcts)
      Dim cts As New CancellationTokenSource()
      
      ' Use our factory to run a set of tasks. 
      Dim objLock As New Object()      
      Dim outputItem As Integer 
      For tCtr As Integer = 0 To 4
         Dim iteration As Integer = tCtr
         Dim t As Task = factory.StartNew(Sub()
                                             For i As Integer = 1 To 1000
                                                SyncLock objLock
                                                   Console.Write("{0} in task t-{1} on thread {2}   ", 
                                                   i, iteration, Thread.CurrentThread.ManagedThreadId)
                                                   outputItem += 1
                                                   If outputItem Mod 3 = 0 Then Console.WriteLine()
                                                End SyncLock
                                             Next 
                                          End Sub,
                                cts.Token)
         tasks.Add(t)
      Next 
      ' Use it to run a second set of tasks.                       
      For tCtr As Integer = 0 To 4
         Dim iteration As Integer = tCtr
         Dim t1 As Task = factory.StartNew(Sub()
                                              For outer As Integer = 0 To 10
                                                 For i As Integer = &h21 To &h7E
                                                    SyncLock objLock
                                                       Console.Write("'{0}' in task t1-{1} on thread {2}   ", 
                                                                     Convert.ToChar(i), iteration, Thread.CurrentThread.ManagedThreadId)
                                                       outputItem += 1
                                                       If outputItem Mod 3 = 0 Then Console.WriteLine()
                                                    End SyncLock 
                                                 Next     
                                              Next                                           
                                           End Sub,
                                cts.Token)           
         tasks.Add(t1)
      Next
      
      ' Wait for the tasks to complete before displaying a completion message.
      Task.WaitAll(tasks.ToArray())
      cts.Dispose()
      Console.WriteLine(vbCrLf + vbCrLf + "Successful completion.")
   End Sub 
End Module

' Provides a task scheduler that ensures a maximum concurrency level while 
' running on top of the thread pool.
Public Class LimitedConcurrencyLevelTaskScheduler : Inherits TaskScheduler
   ' Indicates whether the current thread is processing work items.
   <ThreadStatic()> Private Shared _currentThreadIsProcessingItems As Boolean 
   
   ' The list of tasks to be executed 
   Private ReadOnly _tasks As LinkedList(Of Task) = New LinkedList(Of Task)() 
   
   'The maximum concurrency level allowed by this scheduler. 
   Private ReadOnly _maxDegreeOfParallelism As Integer 
   
   ' Indicates whether the scheduler is currently processing work items. 
   Private _delegatesQueuedOrRunning As Integer = 0 ' protected by lock(_tasks)
   
   ' Creates a new instance with the specified degree of parallelism. 
   Public Sub New(ByVal maxDegreeOfParallelism As Integer)
      If (maxDegreeOfParallelism < 1) Then 
         Throw New ArgumentOutOfRangeException("maxDegreeOfParallelism")
      End If
         _maxDegreeOfParallelism = maxDegreeOfParallelism
   End Sub 

   ' Queues a task to the scheduler. 
   Protected Overrides Sub QueueTask(ByVal t As Task)
      ' Add the task to the list of tasks to be processed.  If there aren't enough 
      ' delegates currently queued or running to process tasks, schedule another. 
      SyncLock (_tasks)
         _tasks.AddLast(t)
         If (_delegatesQueuedOrRunning < _maxDegreeOfParallelism) Then
            _delegatesQueuedOrRunning = _delegatesQueuedOrRunning + 1
            NotifyThreadPoolOfPendingWork()
         End If 
      End SyncLock 
   End Sub 
   
   ' Inform the ThreadPool that there's work to be executed for this scheduler. 
   Private Sub NotifyThreadPoolOfPendingWork()
   
      ThreadPool.UnsafeQueueUserWorkItem(Sub()
                                            ' Note that the current thread is now processing work items. 
                                            ' This is necessary to enable inlining of tasks into this thread.
                                            _currentThreadIsProcessingItems = True 
                                            Try 
                                               ' Process all available items in the queue. 
                                               While (True)
                                                  Dim item As Task
                                                  SyncLock (_tasks)
                                                     ' When there are no more items to be processed, 
                                                     ' note that we're done processing, and get out. 
                                                     If (_tasks.Count = 0) Then
                                                        _delegatesQueuedOrRunning = _delegatesQueuedOrRunning - 1
                                                        Exit While 
                                                     End If 
   
                                                     ' Get the next item from the queue
                                                     item = _tasks.First.Value
                                                     _tasks.RemoveFirst()
                                                  End SyncLock 
   
                                                  ' Execute the task we pulled out of the queue 
                                                  MyBase.TryExecuteTask(item)
                                               End While 
                                               ' We're done processing items on the current thread 
                                            Finally
                                               _currentThreadIsProcessingItems = False 
                                            End Try 
                                         End Sub,
                                    Nothing)
   End Sub 
   
   ' Attempts to execute the specified task on the current thread. 
   Protected Overrides Function TryExecuteTaskInline(ByVal t As Task, 
                                                     ByVal taskWasPreviouslyQueued As Boolean) As Boolean 
      ' If this thread isn't already processing a task, we don't support inlining 
      If (Not _currentThreadIsProcessingItems) Then 
         Return False 
      End If 
   
      ' If the task was previously queued, remove it from the queue 
      If (taskWasPreviouslyQueued) Then
         ' Try to run the task. 
         If TryDequeue(t) Then 
            Return MyBase.TryExecuteTask(t)
         Else
            Return False 
         End If     
      Else 
         Return MyBase.TryExecuteTask(t)
      End If   
   End Function 
   
   ' Attempt to remove a previously scheduled task from the scheduler. 
   Protected Overrides Function TryDequeue(ByVal t As Task) As Boolean 
      SyncLock (_tasks)
         Return _tasks.Remove(t)
      End SyncLock 
   End Function 
   
   ' Gets the maximum concurrency level supported by this scheduler. 
   Public Overrides ReadOnly Property MaximumConcurrencyLevel As Integer 
      Get 
         Return _maxDegreeOfParallelism
      End Get 
   End Property 
   
   ' Gets an enumerable of the tasks currently scheduled on this scheduler. 
   Protected Overrides Function GetScheduledTasks() As IEnumerable(Of Task)
      Dim lockTaken As Boolean = False 
      Try
         Monitor.TryEnter(_tasks, lockTaken)
         If (lockTaken) Then 
            Return _tasks.ToArray()
         Else 
            Throw New NotSupportedException()
         End If 
      Finally 
         If (lockTaken) Then
            Monitor.Exit(_tasks)
         End If 
      End Try 
   End Function 
End Class 
' The following is a portion of the output from a single run of the example:
'    'T' in task t1-4 on thread 3   'U' in task t1-4 on thread 3   'V' in task t1-4 on thread 3   
'    'W' in task t1-4 on thread 3   'X' in task t1-4 on thread 3   'Y' in task t1-4 on thread 3   
'    'Z' in task t1-4 on thread 3   '[' in task t1-4 on thread 3   '\' in task t1-4 on thread 3   
'    ']' in task t1-4 on thread 3   '^' in task t1-4 on thread 3   '_' in task t1-4 on thread 3   
'    '`' in task t1-4 on thread 3   'a' in task t1-4 on thread 3   'b' in task t1-4 on thread 3   
'    'c' in task t1-4 on thread 3   'd' in task t1-4 on thread 3   'e' in task t1-4 on thread 3   
'    'f' in task t1-4 on thread 3   'g' in task t1-4 on thread 3   'h' in task t1-4 on thread 3   
'    'i' in task t1-4 on thread 3   'j' in task t1-4 on thread 3   'k' in task t1-4 on thread 3   
'    'l' in task t1-4 on thread 3   'm' in task t1-4 on thread 3   'n' in task t1-4 on thread 3   
'    'o' in task t1-4 on thread 3   'p' in task t1-4 on thread 3   ']' in task t1-2 on thread 4   
'    '^' in task t1-2 on thread 4   '_' in task t1-2 on thread 4   '`' in task t1-2 on thread 4   
'    'a' in task t1-2 on thread 4   'b' in task t1-2 on thread 4   'c' in task t1-2 on thread 4   
'    'd' in task t1-2 on thread 4   'e' in task t1-2 on thread 4   'f' in task t1-2 on thread 4   
'    'g' in task t1-2 on thread 4   'h' in task t1-2 on thread 4   'i' in task t1-2 on thread 4   
'    'j' in task t1-2 on thread 4   'k' in task t1-2 on thread 4   'l' in task t1-2 on thread 4   
'    'm' in task t1-2 on thread 4   'n' in task t1-2 on thread 4   'o' in task t1-2 on thread 4   
'    'p' in task t1-2 on thread 4   'q' in task t1-2 on thread 4   'r' in task t1-2 on thread 4   
'    's' in task t1-2 on thread 4   't' in task t1-2 on thread 4   'u' in task t1-2 on thread 4   
'    'v' in task t1-2 on thread 4   'w' in task t1-2 on thread 4   'x' in task t1-2 on thread 4   
'    'y' in task t1-2 on thread 4   'z' in task t1-2 on thread 4   '{' in task t1-2 on thread 4   
'    '|' in task t1-2 on thread 4   '}' in task t1-2 on thread 4   '~' in task t1-2 on thread 4   
'    'q' in task t1-4 on thread 3   'r' in task t1-4 on thread 3   's' in task t1-4 on thread 3   
'    't' in task t1-4 on thread 3   'u' in task t1-4 on thread 3   'v' in task t1-4 on thread 3   
'    'w' in task t1-4 on thread 3   'x' in task t1-4 on thread 3   'y' in task t1-4 on thread 3   
'    'z' in task t1-4 on thread 3   '{' in task t1-4 on thread 3   '|' in task t1-4 on thread 3  

En outre, plusieurs exemples de planificateurs de tâches sont disponibles dans la galerie de Code : Exemples de programmation parallèle avec .NET Framework 4.In addition, several sample task schedulers are available on Code Gallery: Samples for Parallel Programming with the .NET Framework 4.

Remarques

Une instance de la TaskScheduler classe représente un planificateur de tâches.An instance of the TaskScheduler class represents a task scheduler. Un planificateur de tâches s’assure que le travail d’une tâche est finalement exécuté.A task scheduler ensures that the work of a task is eventually executed.

Le planificateur de tâches par défaut est basé sur le pool de threads .NET Framework 4, qui fournit le vol de travail pour l'équilibrage de charge, l'injection/retrait du thread pour un débit maximal et une bonne performance globale.The default task scheduler is based on the .NET Framework 4 thread pool, which provides work-stealing for load-balancing, thread injection/retirement for maximum throughput, and overall good performance. Ce doit être suffisant pour la plupart des scénarios.It should be sufficient for most scenarios.

Le TaskScheduler classe sert également le point d’extension pour toute logique de planification personnalisable.The TaskScheduler class also serves as the extension point for all customizable scheduling logic. Cela inclut des mécanismes tels que comment planifier une tâche pour l’exécution et les tâches planifiées comment doit être exposée aux débogueurs.This includes mechanisms such as how to schedule a task for execution, and how scheduled tasks should be exposed to debuggers. Si vous avez besoin des fonctionnalités spéciales, vous pouvez créer un planificateur personnalisé et l’activer pour des tâches spécifiques ou des requêtes.If you require special functionality, you can create a custom scheduler and enable it for specific tasks or queries.

Dans cette rubrique :In this topic:
Le Planificateur de tâches par défaut et le pool de threadsThe default task scheduler and the thread pool
La file d’attente globale et les files d’attente localesThe global queue vs. local queues
Vol de travailWork stealing
Tâches longuesLong-running tasks
Incorporation de tâcheTask inlining
Spécification d’un contexte de synchronisationSpecifying a synchronization context

Le Planificateur de tâches par défaut et le pool de threadsThe default task scheduler and the thread pool

Le planificateur par défaut pour la bibliothèque parallèle de tâches et PLINQ utilise le pool de threads .NET Framework, qui est représenté par le ThreadPool (classe), à la file d’attente et les exécuter.The default scheduler for the Task Parallel Library and PLINQ uses the .NET Framework thread pool, which is represented by the ThreadPool class, to queue and execute work. Le pool de threads utilise les informations fournies par le Task type à prendre en charge efficacement le parallélisme affiné (unités éphémères de travail) et les tâches parallèles requêtes souvent représentent.The thread pool uses the information that is provided by the Task type to efficiently support the fine-grained parallelism (short-lived units of work) that parallel tasks and queries often represent.

La file d’attente globale et les files d’attente localesThe global queue vs. local queues

Le pool de threads gère une globale premier entré, premier sorti (FIFO) fonctionnent de la file d’attente pour les threads dans chaque domaine d’application.The thread pool maintains a global FIFO (first-in, first-out) work queue for threads in each application domain. Chaque fois qu’un programme appelle la ThreadPool.QueueUserWorkItem (ou ThreadPool.UnsafeQueueUserWorkItem) (méthode), le travail est dans cette file d’attente partagée et finalement retirer en file d’attente vers le thread suivant qui devient disponible.Whenever a program calls the ThreadPool.QueueUserWorkItem (or ThreadPool.UnsafeQueueUserWorkItem) method, the work is put on this shared queue and eventually de-queued onto the next thread that becomes available. À compter de .NET Framework 4, cette file d’attente a été améliorée pour utiliser un algorithme sans verrou qui ressemble à la ConcurrentQueue<T> classe.Starting with the .NET Framework 4, this queue has been improved to use a lock-free algorithm that resembles the ConcurrentQueue<T> class. À l’aide de cette implémentation sans verrou, le pool de threads passe moins de temps quand il met et enlève les éléments de travail.By using this lock-free implementation, the thread pool spends less time when it queues and de-queues work items. Ce gain de performances est disponible pour tous les programmes qui utilisent le pool de threads.This performance benefit is available to all programs that use the thread pool.

Les tâches de niveau supérieur, qui ne sont pas créées dans le contexte d’une autre tâche, sont mises en file d’attente globale comme tout autre élément de travail.Top-level tasks, which are tasks that are not created in the context of another task, are put on the global queue just like any other work item. Toutefois, les tâches imbriquées ou enfants, créées dans le contexte d'une autre tâche, sont gérées tout à fait différemment.However, nested or child tasks, which are created in the context of another task, are handled quite differently. Une tâche enfant ou imbriquée est placée dans une file d'attente locale qui est spécifique au thread sur lequel s'exécute la tâche parente.A child or nested task is put on a local queue that is specific to the thread on which the parent task is executing. La tâche parente peut être une tâche de niveau supérieur ou l'enfant d'une autre tâche.The parent task may be a top-level task or it also may be the child of another task. Quand ce thread est prêt pour exécuter davantage de travail, il regarde en premier dans la file d'attente locale.When this thread is ready for more work, it first looks in the local queue. Les éléments de travail qui s’y trouvent éventuellement peuvent être récupérés rapidement.If work items are waiting there, they can be accessed quickly. Les files d’attente locales sont accessibles par ordre dernier entré, premier sorti (LIFO) pour conserver la localité de cache et de réduire la contention.The local queues are accessed in last-in, first-out order (LIFO) to preserve cache locality and reduce contention. Pour plus d’informations sur les tâches enfants et imbriquées, consultez détachée tâches enfants attachées et.For more information about child tasks and nested tasks, see Attached and Detached Child Tasks.

L’utilisation de files d’attente locales non seulement réduit la pression sur la file d’attente globale, mais tire également parti de la localité des données.The use of local queues not only reduces pressure on the global queue, but also takes advantage of data locality. Éléments de travail local de file d’attente fréquemment des structures de données de référence qui sont physiquement près d’eux en mémoire.Work items in the local queue frequently reference data structures that are physically near one another in memory. Dans ce cas, les données sont déjà dans le cache après que la première tâche a exécuté et sont accessibles rapidement.In these cases, the data is already in the cache after the first task has run and can be accessed quickly. Les deux Parallel LINQ (PLINQ) et Parallel largement de classe utilisent des tâches imbriquées et tâches enfants et accomplissent des accélérations significatives à l’aide de files d’attente de travail locale.Both Parallel LINQ (PLINQ) and the Parallel class use nested tasks and child tasks extensively, and achieve significant speedups by using the local work queues.

Vol de travailWork stealing

À compter de .NET Framework 4, le pool de threads propose également un algorithme de vol de travail pour s’assurer qu’aucun thread ne soit inactif alors que d’autres ont du travail dans leurs files d’attente.Starting with the .NET Framework 4, the thread pool also features a work-stealing algorithm to help make sure that no threads are sitting idle while others still have work in their queues. Quand un thread de pool de threads est prêt à effectuer davantage de travail, il regarde successivement en tête de sa file d'attente locale, dans la file d'attente globale, puis dans les files d'attente locales d'autres threads.When a thread-pool thread is ready for more work, it first looks at the head of its local queue, then in the global queue, and then in the local queues of other threads. S’il trouve un élément de travail dans la file d’attente locale d’un autre thread, il applique d’abord des méthodes heuristiques pour s’assurer qu’il peut exécuter le travail efficacement.If it finds a work item in the local queue of another thread, it first applies heuristics to make sure that it can run the work efficiently. Si possible, il enlève l’élément de travail à partir de la fin (dans l’ordre FIFO).If it can, it de-queues the work item from the tail (in FIFO order). Cela réduit les conflits sur chaque file d'attente locale et permet de conserver la localité des données.This reduces contention on each local queue and preserves data locality. Cette architecture permet le thread pool équilibrer la charge de travailler de manière plus efficace que dans les versions précédentes.This architecture helps the thread pool load-balance work more efficiently than past versions did.

Tâches longuesLong-running tasks

Vous pouvez explicitement empêcher une tâche d’être mise en file d’attente locale.You may want to explicitly prevent a task from being put on a local queue. Par exemple, vous savez peut-être qu'un élément de travail particulier fonctionnera pour une durée relativement longue et sera à même de bloquer tous les autres éléments de travail sur la file d'attente locale.For example, you may know that a particular work item will run for a relatively long time and is likely to block all other work items on the local queue. Dans ce cas, vous pouvez spécifier l’option System.Threading.Tasks.TaskCreationOptions, qui indique au planificateur qu’un thread supplémentaire peut être nécessaire pour la tâche afin qu’elle n’entrave pas la progression d’autres threads ou éléments de travail sur la file d’attente locale.In this case, you can specify the System.Threading.Tasks.TaskCreationOptions option, which provides a hint to the scheduler that an additional thread might be required for the task so that it does not block the forward progress of other threads or work items on the local queue. À l’aide de cette option vous évitez le pool de threads complètement, d’inclure les files d’attente locales et globales.By using this option you avoid the thread pool completely, including the global and local queues.

Incorporation de tâcheTask inlining

Dans certains cas, quand un Task est attendue, elle peut être exécutée de façon synchrone sur le thread qui effectue l’opération d’attente.In some cases when a Task is waited on, it may be executed synchronously on the thread that is performing the wait operation. Cela améliore les performances en éliminant la nécessité d’un thread supplémentaire et à la place à l’aide du thread existant, qui aurait sinon bloqués.This enhances performance by preventing the need for an additional thread and instead using the existing thread, which would have blocked otherwise. Pour éviter des erreurs en raison de la réentrance, incorporation de tâche se produit uniquement lorsque la cible d’attente se trouve dans la file d’attente locale du thread pertinent.To prevent errors due to reentrancy, task inlining only occurs when the wait target is found in the relevant thread's local queue.

Spécification d’un contexte de synchronisationSpecifying a synchronization context

Vous pouvez utiliser la méthode TaskScheduler.FromCurrentSynchronizationContext pour spécifier qu’une tâche doit être planifiée pour fonctionner sur un thread particulier.You can use the TaskScheduler.FromCurrentSynchronizationContext method to specify that a task should be scheduled to run on a particular thread. Cela s'avère utile dans les infrastructures telles que Windows Forms et Windows Presentation Foundation où l'accès aux objets d'interface utilisateur est souvent restreint au code qui s'exécute sur le thread sur lequel l'objet d'interface utilisateur a été créé.This is useful in frameworks such as Windows Forms and Windows Presentation Foundation where access to user interface objects is often restricted to code that is running on the same thread on which the UI object was created.

L’exemple suivant utilise la TaskScheduler.FromCurrentSynchronizationContext méthode dans une application Windows Presentation Foundation (WPF) pour planifier une tâche sur le même thread que le contrôle d’interface utilisateur utilisateur a été créé.The following example uses the TaskScheduler.FromCurrentSynchronizationContext method in a Windows Presentation Foundation (WPF) app to schedule a task on the same thread that the user interface (UI) control was created on. L’exemple crée une mosaïque d’images qui sont sélectionnées au hasard à partir d’un répertoire spécifié.The example creates a mosaic of images that are randomly selected from a specified directory. Les objets WPF sont utilisés pour charger et redimensionner les images.The WPF objects are used to load and resize the images. Les pixels bruts sont ensuite transmis à une tâche qui utilise un For boucle pour écrire les données de pixels dans un grand tableau d’un octet.The raw pixels are then passed to a task that uses a For loop to write the pixel data into a large single-byte array. Aucune synchronisation n’est requise car aucun deux vignettes n’occupent les mêmes éléments de tableau.No synchronization is required because no two tiles occupy the same array elements. Les vignettes peuvent également être écrits dans n’importe quel ordre, car leur position est calculée indépendamment de toute autre vignette.The tiles can also be written in any order because their position is calculated independently of any other tile. Le grand tableau est ensuite transmis à une tâche qui s’exécute sur le thread d’interface utilisateur, dans lequel les données de pixels sont chargées dans un contrôle Image.The large array is then passed to a task that runs on the UI thread, where the pixel data is loaded into an Image control.

L’exemple déplace les données du thread d’interface utilisateur, il modifie à l’aide de boucles parallèles et Task objets et il repasse ensuite à une tâche qui s’exécute sur le thread d’interface utilisateur.The example moves data off the UI thread, modifies it by using parallel loops and Task objects, and then passes it back to a task that runs on the UI thread. Cette approche est utile lorsque vous devez utiliser la bibliothèque parallèle de tâches pour effectuer des opérations qui ne sont pas pris en charge par l’API WPF, ou ne sont pas suffisamment rapides.This approach is useful when you have to use the Task Parallel Library to perform operations that either are not supported by the WPF API, or are not sufficiently fast. Une autre façon de créer une mosaïque d’images dans WPF consiste à utiliser un System.Windows.Controls.WrapPanel contrôler et ajouter des images.Another way to create an image mosaic in WPF is to use a System.Windows.Controls.WrapPanel control and add images to it. Le WrapPanel gère le travail de positionnement des mosaïques.The WrapPanel handles the work of positioning the tiles. Toutefois, ce travail peut uniquement être effectué sur le thread d’interface utilisateur.However, this work can only be performed on the UI thread.

using System;
using System.Threading.Tasks;
using System.Windows;
using System.Windows.Media;
using System.Windows.Media.Imaging;

namespace WPF_CS1
{
    /// <summary>
    /// Interaction logic for MainWindow.xaml
    /// </summary>
    public partial class MainWindow : Window
    {
        private int fileCount;
        int colCount;
        int rowCount;
        private int tilePixelHeight;
        private int tilePixelWidth;
        private int largeImagePixelHeight;
        private int largeImagePixelWidth;
        private int largeImageStride;
        PixelFormat format;
        BitmapPalette palette = null;

        public MainWindow()
        {
            InitializeComponent();

            // For this example, values are hard-coded to a mosaic of 8x8 tiles.
            // Each tile is 50 pixels high and 66 pixels wide and 32 bits per pixel.
            colCount = 12;
            rowCount = 8;
            tilePixelHeight = 50;
            tilePixelWidth = 66;
            largeImagePixelHeight = tilePixelHeight * rowCount;
            largeImagePixelWidth = tilePixelWidth * colCount;
            largeImageStride = largeImagePixelWidth * (32 / 8);
            this.Width = largeImagePixelWidth + 40;
            image.Width = largeImagePixelWidth;
            image.Height = largeImagePixelHeight;


        }

        private void button_Click(object sender, RoutedEventArgs e)
        {

            // For best results use 1024 x 768 jpg files at 32bpp.
            string[] files = System.IO.Directory.GetFiles(@"C:\Users\Public\Pictures\Sample Pictures\", "*.jpg");

            fileCount = files.Length;
            Task<byte[]>[] images = new Task<byte[]>[fileCount];
            for (int i = 0; i < fileCount; i++)
            {
                int x = i;
                images[x] = Task.Factory.StartNew(() => LoadImage(files[x]));
            }

            // When they've all been loaded, tile them into a single byte array.
            var tiledImage = Task.Factory.ContinueWhenAll(
                images, (i) => TileImages(i));

            // We are currently on the UI thread. Save the sync context and pass it to
            // the next task so that it can access the UI control "image".
            var UISyncContext = TaskScheduler.FromCurrentSynchronizationContext();

            // On the UI thread, put the bytes into a bitmap and
            // display it in the Image control.
            var t3 = tiledImage.ContinueWith((antecedent) =>
            {
                // Get System DPI.
                Matrix m = PresentationSource.FromVisual(Application.Current.MainWindow)
                                            .CompositionTarget.TransformToDevice;
                double dpiX = m.M11;
                double dpiY = m.M22;

                BitmapSource bms = BitmapSource.Create(largeImagePixelWidth,
                    largeImagePixelHeight,
                    dpiX,
                    dpiY,
                    format,
                    palette, //use default palette
                    antecedent.Result,
                    largeImageStride);
                image.Source = bms;
            }, UISyncContext);
        }

        byte[] LoadImage(string filename)
        {
            // Use the WPF BitmapImage class to load and 
            // resize the bitmap. NOTE: Only 32bpp formats are supported correctly.
            // Support for additional color formats is left as an exercise
            // for the reader. For more information, see documentation for ColorConvertedBitmap.

            BitmapImage bitmapImage = new BitmapImage();
            bitmapImage.BeginInit();
            bitmapImage.UriSource = new Uri(filename);
            bitmapImage.DecodePixelHeight = tilePixelHeight;
            bitmapImage.DecodePixelWidth = tilePixelWidth;
            bitmapImage.EndInit();

            format = bitmapImage.Format;
            int size = (int)(bitmapImage.Height * bitmapImage.Width);
            int stride = (int)bitmapImage.Width * 4;
            byte[] dest = new byte[stride * tilePixelHeight];

            bitmapImage.CopyPixels(dest, stride, 0);

            return dest;
        }

        int Stride(int pixelWidth, int bitsPerPixel)
        {
            return (((pixelWidth * bitsPerPixel + 31) / 32) * 4);
        }

        // Map the individual image tiles to the large image
        // in parallel. Any kind of raw image manipulation can be
        // done here because we are not attempting to access any 
        // WPF controls from multiple threads.
        byte[] TileImages(Task<byte[]>[] sourceImages)
        {
            byte[] largeImage = new byte[largeImagePixelHeight * largeImageStride];
            int tileImageStride = tilePixelWidth * 4; // hard coded to 32bpp

            Random rand = new Random();
            Parallel.For(0, rowCount * colCount, (i) =>
            {
                // Pick one of the images at random for this tile.
                int cur = rand.Next(0, sourceImages.Length);
                byte[] pixels = sourceImages[cur].Result;

                // Get the starting index for this tile.
                int row = i / colCount;
                int col = (int)(i % colCount);
                int idx = ((row * (largeImageStride * tilePixelHeight)) + (col * tileImageStride));

                // Write the pixels for the current tile. The pixels are not contiguous
                // in the array, therefore we have to advance the index by the image stride
                // (minus the stride of the tile) for each scanline of the tile.
                int tileImageIndex = 0;
                for (int j = 0; j < tilePixelHeight; j++)
                {
                    // Write the next scanline for this tile.
                    for (int k = 0; k < tileImageStride; k++)
                    {
                        largeImage[idx++] = pixels[tileImageIndex++];
                    }
                    // Advance to the beginning of the next scanline.
                    idx += largeImageStride - tileImageStride;
                }
            });
            return largeImage;
        }
    }
}
Imports System.Threading.Tasks
Imports System.Windows
Imports System.Windows.Media
Imports System.Windows.Media.Imaging

Partial Public Class MainWindow : Inherits Window
    Dim fileCount As Integer
    Dim colCount As Integer
    Dim rowCount As Integer
    Dim tilePixelHeight As Integer
    Dim tilePixelWidth As Integer
    Dim largeImagePixelHeight As Integer
    Dim largeImagePixelWidth As Integer
    Dim largeImageStride As Integer
    Dim format As PixelFormat
    Dim palette As BitmapPalette = Nothing

    Public Sub New()
        InitializeComponent()

        ' For this example, values are hard-coded to a mosaic of 8x8 tiles.
        ' Each tile Is 50 pixels high and 66 pixels wide and 32 bits per pixel.
        colCount = 12
        rowCount = 8
        tilePixelHeight = 50
        tilePixelWidth = 66
        largeImagePixelHeight = tilePixelHeight * rowCount
        largeImagePixelWidth = tilePixelWidth * colCount
        largeImageStride = largeImagePixelWidth * (32 / 8)
        Me.Width = largeImagePixelWidth + 40
        image.Width = largeImagePixelWidth
        image.Height = largeImagePixelHeight
    End Sub

    Private Sub button_Click(sender As Object, e As RoutedEventArgs) _
        Handles button.Click

        ' For best results use 1024 x 768 jpg files at 32bpp.
        Dim files() As String = System.IO.Directory.GetFiles("C:\Users\Public\Pictures\Sample Pictures\", "*.jpg")

        fileCount = files.Length
        Dim images(fileCount - 1) As Task(Of Byte())
        For i As Integer = 0 To fileCount - 1
            Dim x As Integer = i
            images(x) = Task.Factory.StartNew(Function() LoadImage(files(x)))
        Next

        ' When they have all been loaded, tile them into a single byte array.
        'var tiledImage = Task.Factory.ContinueWhenAll(
        '        images, (i) >= TileImages(i));

        '        Dim tiledImage As Task(Of Byte()) = Task.Factory.ContinueWhenAll(images, Function(i As Task(Of Byte())) TileImages(i))
        Dim tiledImage = Task.Factory.ContinueWhenAll(images, Function(i As Task(Of Byte())()) TileImages(i))
        ' We are currently on the UI thread. Save the sync context and pass it to
        ' the next task so that it can access the UI control "image1".
        Dim UISyncContext = TaskScheduler.FromCurrentSynchronizationContext()

        ' On the UI thread, put the bytes into a bitmap and
        ' display it in the Image control.
        Dim t3 = tiledImage.ContinueWith(Sub(antecedent)
                                             ' Get System DPI.
                                             Dim m As Matrix = PresentationSource.FromVisual(Application.Current.MainWindow).CompositionTarget.TransformToDevice
                                             Dim dpiX As Double = m.M11
                                             Dim dpiY As Double = m.M22

                                             ' Use the default palette in creating the bitmap.
                                             Dim bms As BitmapSource = BitmapSource.Create(largeImagePixelWidth,
                                                                                           largeImagePixelHeight,
                                             dpiX,
                                             dpiY,
                                             format,
                                             palette,
                                             antecedent.Result,
                                             largeImageStride)
                                             image.Source = bms
                                         End Sub, UISyncContext)
    End Sub

    Public Function LoadImage(filename As String) As Byte()
        ' Use the WPF BitmapImage class to load and 
        ' resize the bitmap. NOTE: Only 32bpp formats are supported correctly.
        ' Support for additional color formats Is left as an exercise
        ' for the reader. For more information, see documentation for ColorConvertedBitmap.
        Dim bitmapImage As New BitmapImage()
        bitmapImage.BeginInit()
        bitmapImage.UriSource = New Uri(filename)
        bitmapImage.DecodePixelHeight = tilePixelHeight
        bitmapImage.DecodePixelWidth = tilePixelWidth
        bitmapImage.EndInit()

        format = bitmapImage.Format
        Dim size As Integer = CInt(bitmapImage.Height * bitmapImage.Width)
        Dim stride As Integer = CInt(bitmapImage.Width * 4)
        Dim dest(stride * tilePixelHeight - 1) As Byte

        bitmapImage.CopyPixels(dest, stride, 0)

        Return dest
    End Function

    Function Stride(pixelWidth As Integer, bitsPerPixel As Integer) As Integer
        Return (((pixelWidth * bitsPerPixel + 31) / 32) * 4)
    End Function

    ' Map the individual image tiles to the large image
    ' in parallel. Any kind of raw image manipulation can be
    ' done here because we are Not attempting to access any 
    ' WPF controls from multiple threads.
    Function TileImages(sourceImages As Task(Of Byte())()) As Byte()
        Dim largeImage(largeImagePixelHeight * largeImageStride - 1) As Byte
        Dim tileImageStride As Integer = tilePixelWidth * 4 ' hard coded To 32bpp

        Dim rand As New Random()
        Parallel.For(0, rowCount * colCount, Sub(i)
                                                 ' Pick one of the images at random for this tile.
                                                 Dim cur As Integer = rand.Next(0, sourceImages.Length)
                                                 Dim pixels() As Byte = sourceImages(cur).Result

                                                 ' Get the starting index for this tile.
                                                 Dim row As Integer = i \ colCount
                                                 Dim col As Integer = i Mod colCount
                                                 Dim idx As Integer = ((row * (largeImageStride * tilePixelHeight)) + (col * tileImageStride))

                                                 ' Write the pixels for the current tile. The pixels are Not contiguous
                                                 ' in the array, therefore we have to advance the index by the image stride
                                                 ' (minus the stride of the tile) for each scanline of the tile.
                                                 Dim tileImageIndex As Integer = 0
                                                 For j As Integer = 0 To tilePixelHeight - 1
                                                     ' Write the next scanline for this tile.
                                                     For k As Integer = 0 To tileImageStride - 1
                                                         largeImage(idx) = pixels(tileImageIndex)
                                                         idx += 1
                                                         tileImageIndex += 1
                                                     Next
                                                     ' Advance to the beginning of the next scanline.
                                                     idx += largeImageStride - tileImageStride
                                                 Next
                                             End Sub)
        Return largeImage
    End Function
End Class

Pour créer l’exemple, créez un projet d’application WPF dans Visual Studio et nommez-le WPF_CS1 (pour un C# projet WPF) ou WPF_VB1 (pour un projet WPF de Visual Basic).To create the example, create a WPF application project in Visual Studio and name it WPF_CS1 (for a C# WPF project) or WPF_VB1 (for a Visual Basic WPF project). Procédez comme suit :Then do the following:

  1. En mode conception, faites glisser un Image contrôle depuis la boîte à outils sur le coin supérieur gauche de l’aire de conception.In design view, drag an Image control from the Toolbox onto the upper left corner of the design surface. Dans le nom zone de texte de la propriétés fenêtre, le nom de l’image « contrôle ».In the Name textbox of the Properties window, name the control "image".

  2. Faites glisser un Button contrôle depuis la boîte à outils à la partie inférieure gauche de la fenêtre d’application.Drag a Button control from the Toolbox to the lower left part of the application window. Dans la vue XAML, spécifiez la Content propriété du bouton comme « Make une mosaïque » et spécifiez son Width propriété en tant que « 100 ».In XAML view, specify the Content property of the button as "Make a mosaic", and specify its Width property as "100". Connecter le Click événement avec le button_Click Gestionnaire d’événements défini dans le code de cet exemple en ajoutant Click="button_Click" à la <Button> élément.Connect the Click event with the button_Click event handler defined in the example's code by adding Click="button_Click" to the <Button> element. Dans le nom zone de texte de la propriétés fenêtre, le nom du bouton « contrôle ».In the Name textbox of the Properties window, name the control "button".

  3. Remplacez tout le contenu du fichier MainWindow.xaml.cs ou MainWindow.xaml.vb par le code à partir de cet exemple.Replace the entire contents of the MainWindow.xaml.cs or MainWindow.xaml.vb file with the code from this example. Pour un C# WPF de projet, assurez-vous que le nom de l’espace de travail correspond au nom de projet.For a C# WPF project, make sure that the name of the workspace matches the project name.

  4. L’exemple lit les images JPEG à partir d’un répertoire nommé C:\Users\Public\Pictures\Sample images\.The example reads JPEG images from a directory named C:\Users\Public\Pictures\Sample Pictures\. Créer le répertoire et placer des images qu’il contient ou modifier le chemin d’accès pour faire référence à un autre annuaire qui contient des images.Either create the directory and place some images in it, or change the path to refer to some other directory that contains images.

Cet exemple présente certaines limitations.This example has some limitations. Par exemple, les images de seulement 32-bits par pixel sont prises en charge ; les images dans d’autres formats sont endommagées par le BitmapImage l’objet au cours de l’opération de redimensionnement.For example, only 32-bits-per-pixel images are supported; images in other formats are corrupted by the BitmapImage object during the resizing operation. En outre, les images de la source doivent tous être supérieure à la taille de vignette.Also, the source images must all be larger than the tile size. En guise d’exercice supplémentaire, vous pouvez ajouter la fonctionnalité permettant de gérer plusieurs formats de pixels et tailles de fichiers.As a further exercise, you can add functionality to handle multiple pixel formats and file sizes.

Constructeurs

TaskScheduler() TaskScheduler() TaskScheduler() TaskScheduler()

Initialise la TaskScheduler.Initializes the TaskScheduler.

Propriétés

Current Current Current Current

Obtient le TaskScheduler associé à la tâche en cours d'exécution.Gets the TaskScheduler associated with the currently executing task.

Default Default Default Default

Obtient l'instance de TaskScheduler par défaut fournie par le .NET Framework.Gets the default TaskScheduler instance that is provided by the .NET Framework.

Id Id Id Id

Obtient l'ID unique pour ce TaskScheduler.Gets the unique ID for this TaskScheduler.

MaximumConcurrencyLevel MaximumConcurrencyLevel MaximumConcurrencyLevel MaximumConcurrencyLevel

Indique le niveau d'accès concurrentiel maximal que ce TaskScheduler peut prendre en charge.Indicates the maximum concurrency level this TaskScheduler is able to support.

Méthodes

Equals(Object) Equals(Object) Equals(Object) Equals(Object)

Détermine si l'objet spécifié est identique à l'objet actuel.Determines whether the specified object is equal to the current object.

(Inherited from Object)
Finalize() Finalize() Finalize() Finalize()

Libère toutes les ressources associées à ce planificateur.Frees all resources associated with this scheduler.

FromCurrentSynchronizationContext() FromCurrentSynchronizationContext() FromCurrentSynchronizationContext() FromCurrentSynchronizationContext()

Crée un TaskScheduler associé au SynchronizationContext en cours.Creates a TaskScheduler associated with the current SynchronizationContext.

GetHashCode() GetHashCode() GetHashCode() GetHashCode()

Fait office de fonction de hachage par défaut.Serves as the default hash function.

(Inherited from Object)
GetScheduledTasks() GetScheduledTasks() GetScheduledTasks() GetScheduledTasks()

Pour la prise en charge du débogueur uniquement, génère un énumérateur d'instances de Task actuellement en attente d'exécution dans la file d'attente sur le planificateur.For debugger support only, generates an enumerable of Task instances currently queued to the scheduler waiting to be executed.

GetType() GetType() GetType() GetType()

Obtient le Type de l'instance actuelle.Gets the Type of the current instance.

(Inherited from Object)
MemberwiseClone() MemberwiseClone() MemberwiseClone() MemberwiseClone()

Crée une copie superficielle de l'objet Object actuel.Creates a shallow copy of the current Object.

(Inherited from Object)
QueueTask(Task) QueueTask(Task) QueueTask(Task) QueueTask(Task)

Met en file d'attente une Task sur le planificateur.Queues a Task to the scheduler.

ToString() ToString() ToString() ToString()

Retourne une chaîne qui représente l'objet actuel.Returns a string that represents the current object.

(Inherited from Object)
TryDequeue(Task) TryDequeue(Task) TryDequeue(Task) TryDequeue(Task)

Tente de sortir de la file d'attente une Task qui était précédemment dans la file d'attente de ce planificateur.Attempts to dequeue a Task that was previously queued to this scheduler.

TryExecuteTask(Task) TryExecuteTask(Task) TryExecuteTask(Task) TryExecuteTask(Task)

Tente d'exécuter la Task fournie sur ce planificateur.Attempts to execute the provided Task on this scheduler.

TryExecuteTaskInline(Task, Boolean) TryExecuteTaskInline(Task, Boolean) TryExecuteTaskInline(Task, Boolean) TryExecuteTaskInline(Task, Boolean)

Détermine si la Task fournie peut être exécutée de façon synchrone dans cet appel et, si c'est le cas, l'exécute.Determines whether the provided Task can be executed synchronously in this call, and if it can, executes it.

Événements

UnobservedTaskException UnobservedTaskException UnobservedTaskException UnobservedTaskException

Se produit lorsque l’exception non prise en charge d’une tâche ayant échoué est sur le point de déclencher la stratégie de promotion d’exception, qui, par défaut, arrête le processus.Occurs when a faulted task's unobserved exception is about to trigger exception escalation policy, which, by default, would terminate the process.

S’applique à

Cohérence de thread

Tous les membres de l’abstraite TaskScheduler type sont thread-safe et peuvent être utilisés à partir de plusieurs threads simultanément.All members of the abstract TaskScheduler type are thread-safe and may be used from multiple threads concurrently.

Voir aussi