Thread.AllocateDataSlot Méthode
Définition
Important
Certaines informations portent sur la préversion du produit qui est susceptible d’être en grande partie modifiée avant sa publication. Microsoft exclut toute garantie, expresse ou implicite, concernant les informations fournies ici.
Alloue un emplacement de données sans nom sur tous les threads. Pour de meilleures performances, utilisez plutôt des champs marqués avec l’attribut ThreadStaticAttribute .
public:
static LocalDataStoreSlot ^ AllocateDataSlot();public static LocalDataStoreSlot AllocateDataSlot();static member AllocateDataSlot : unit -> LocalDataStoreSlotPublic Shared Function AllocateDataSlot () As LocalDataStoreSlotRetours
Emplacement de données nommé alloué sur tous les threads.
Exemples
Cette section contient deux exemples de code. Le premier exemple montre comment utiliser un champ marqué avec l’attribut ThreadStaticAttribute pour contenir des informations spécifiques au thread. Le deuxième exemple montre comment utiliser un emplacement de données pour effectuer la même opération.
Premier exemple
L’exemple suivant montre comment utiliser un champ marqué avec ThreadStaticAttribute pour contenir des informations spécifiques au thread. Cette technique offre de meilleures performances que la technique présentée dans le deuxième exemple.
using System;
using System.Threading;
class Test
{
static void Main()
{
for(int i = 0; i < 3; i++)
{
Thread newThread = new Thread(ThreadData.ThreadStaticDemo);
newThread.Start();
}
}
}
class ThreadData
{
[ThreadStatic]
static int threadSpecificData;
public static void ThreadStaticDemo()
{
// Store the managed thread id for each thread in the static
// variable.
threadSpecificData = Thread.CurrentThread.ManagedThreadId;
// Allow other threads time to execute the same code, to show
// that the static data is unique to each thread.
Thread.Sleep( 1000 );
// Display the static data.
Console.WriteLine( "Data for managed thread {0}: {1}",
Thread.CurrentThread.ManagedThreadId, threadSpecificData );
}
}
/* This code example produces output similar to the following:
Data for managed thread 4: 4
Data for managed thread 5: 5
Data for managed thread 3: 3
*/
open System
open System.Threading
type ThreadData() =
// Create a static variable to hold the data for each thread.
[<ThreadStatic; DefaultValue>]
static val mutable private threadSpecificData : int
static member ThreadStaticDemo() =
// Store the managed thread id for each thread in the static
// variable.
ThreadData.threadSpecificData <- Thread.CurrentThread.ManagedThreadId
// Allow other threads time to execute the same code, to show
// that the static data is unique to each thread.
Thread.Sleep 1000
// Display the static data.
printfn $"Data for managed thread {Thread.CurrentThread.ManagedThreadId}: {ThreadData.threadSpecificData}"
for i = 0 to 2 do
let newThread = Thread ThreadData.ThreadStaticDemo
newThread.Start()
// This code example produces output similar to the following:
// Data for managed thread 4: 4
// Data for managed thread 5: 5
// Data for managed thread 3: 3
Imports System.Threading
Class Test
<MTAThread> _
Shared Sub Main()
For i As Integer = 1 To 3
Dim newThread As New Thread(AddressOf ThreadData.ThreadStaticDemo)
newThread.Start()
Next i
End Sub
End Class
Class ThreadData
<ThreadStatic> _
Shared threadSpecificData As Integer
Shared Sub ThreadStaticDemo()
' Store the managed thread id for each thread in the static
' variable.
threadSpecificData = Thread.CurrentThread.ManagedThreadId
' Allow other threads time to execute the same code, to show
' that the static data is unique to each thread.
Thread.Sleep( 1000 )
' Display the static data.
Console.WriteLine( "Data for managed thread {0}: {1}", _
Thread.CurrentThread.ManagedThreadId, threadSpecificData )
End Sub
End Class
' This code example produces output similar to the following:
'
'Data for managed thread 4: 4
'Data for managed thread 5: 5
'Data for managed thread 3: 3
Deuxième exemple
L’exemple de code suivant montre comment utiliser un emplacement de données pour stocker des informations spécifiques au thread.
using System;
using System.Threading;
class Test
{
static void Main()
{
Thread[] newThreads = new Thread[4];
for(int i = 0; i < newThreads.Length; i++)
{
newThreads[i] = new Thread(
new ThreadStart(Slot.SlotTest));
newThreads[i].Start();
}
}
}
class Slot
{
static Random randomGenerator;
static LocalDataStoreSlot localSlot;
static Slot()
{
randomGenerator = new Random();
localSlot = Thread.AllocateDataSlot();
}
public static void SlotTest()
{
// Set different data in each thread's data slot.
Thread.SetData(localSlot, randomGenerator.Next(1, 200));
// Write the data from each thread's data slot.
Console.WriteLine("Data in thread_{0}'s data slot: {1,3}",
AppDomain.GetCurrentThreadId().ToString(),
Thread.GetData(localSlot).ToString());
// Allow other threads time to execute SetData to show
// that a thread's data slot is unique to the thread.
Thread.Sleep(1000);
Console.WriteLine("Data in thread_{0}'s data slot: {1,3}",
AppDomain.GetCurrentThreadId().ToString(),
Thread.GetData(localSlot).ToString());
}
}
open System
open System.Threading
module Slot =
let randomGenerator = Random()
let localSlot = Thread.AllocateDataSlot()
let slotTest () =
// Set different data in each thread's data slot.
Thread.SetData(localSlot, randomGenerator.Next(1, 200))
// Write the data from each thread's data slot.
printfn $"Data in thread_{AppDomain.GetCurrentThreadId()}'s data slot: {Thread.GetData localSlot, 3}"
// Allow other threads time to execute SetData to show
// that a thread's data slot is unique to the thread.
Thread.Sleep 1000
printfn $"Data in thread_{AppDomain.GetCurrentThreadId()}'s data slot: {Thread.GetData localSlot, 3}"
let newThreads =
[| for _ = 0 to 3 do
let thread = Thread Slot.slotTest
thread.Start()
thread |]
Imports System.Threading
Class Test
<MTAThread> _
Shared Sub Main()
Dim newThreads(3) As Thread
For i As Integer = 0 To newThreads.Length - 1
newThreads(i) = New Thread(AddressOf Slot.SlotTest)
newThreads(i).Start()
Next i
End Sub
End Class
Public Class Slot
Shared randomGenerator As Random
Shared localSlot As LocalDataStoreSlot
Shared Sub New()
randomGenerator = new Random()
localSlot = Thread.AllocateDataSlot()
End Sub
Shared Sub SlotTest()
' Set different data in each thread's data slot.
Thread.SetData(localSlot, randomGenerator.Next(1, 200))
' Write the data from each thread's data slot.
Console.WriteLine("Data in thread_{0}'s data slot: {1,3}", _
AppDomain.GetCurrentThreadId().ToString(), _
Thread.GetData(localSlot).ToString())
' Allow other threads time to execute SetData to show
' that a thread's data slot is unique to the thread.
Thread.Sleep(1000)
' Write the data from each thread's data slot.
Console.WriteLine("Data in thread_{0}'s data slot: {1,3}", _
AppDomain.GetCurrentThreadId().ToString(), _
Thread.GetData(localSlot).ToString())
End Sub
End Class
Remarques
Important
.NET Framework fournit deux mécanismes d’utilisation du stockage local de thread (TLS) : les champs statiques relatifs aux threads (c’est-à-dire les champs marqués avec l’attribut ThreadStaticAttribute) et les emplacements de données. Les champs statiques relatifs aux threads offrent de meilleures performances que les emplacements de données et permettent la vérification du type au moment de la compilation. Pour plus d’informations sur l’utilisation de TLS, consultez Stockage local thread : Thread-Relative champs statiques et emplacements de données.
L’emplacement est alloué sur tous les threads.
Les threads utilisent un mécanisme de mémoire de magasin local pour stocker des données spécifiques aux threads. Le Common Language Runtime alloue un tableau de magasins de données à plusieurs emplacements à chaque processus lors de sa création. Le thread peut allouer un emplacement de données dans le magasin de données, stocker et récupérer une valeur de données dans l’emplacement, et libérer l’emplacement pour la réutilisation après l’expiration du thread. Les emplacements de données sont uniques par thread. Aucun autre thread (pas même un thread enfant) ne peut obtenir ces données.