ReaderWriterLock Klasse
Definition
Wichtig
Einige Informationen beziehen sich auf Vorabversionen, die vor dem Release ggf. grundlegend überarbeitet werden. Microsoft übernimmt hinsichtlich der hier bereitgestellten Informationen keine Gewährleistungen, seien sie ausdrücklich oder konkludent.
Definiert eine Sperre, die einen Writer und mehrere Reader unterstützt.
public ref class ReaderWriterLock sealed : System::Runtime::ConstrainedExecution::CriticalFinalizerObject
public ref class ReaderWriterLock sealed
public sealed class ReaderWriterLock : System.Runtime.ConstrainedExecution.CriticalFinalizerObject
public sealed class ReaderWriterLock
[System.Runtime.InteropServices.ComVisible(true)]
public sealed class ReaderWriterLock : System.Runtime.ConstrainedExecution.CriticalFinalizerObject
type ReaderWriterLock = class
inherit CriticalFinalizerObject
type ReaderWriterLock = class
[<System.Runtime.InteropServices.ComVisible(true)>]
type ReaderWriterLock = class
inherit CriticalFinalizerObject
Public NotInheritable Class ReaderWriterLock
Inherits CriticalFinalizerObject
Public NotInheritable Class ReaderWriterLock
- Vererbung
- Vererbung
-
ReaderWriterLock
- Attribute
Beispiele
Im folgenden Beispiel wird veranschaulicht, wie sie einen ReaderWriterLock verwenden, um eine freigegebene Ressource zu schützen, einen ganzzahligen Wert namens resource
, der gleichzeitig gelesen und ausschließlich von mehreren Threads geschrieben wird. Beachten Sie, dass der ReaderWriterLock auf Klassenebene deklariert ist, sodass es für alle Threads sichtbar ist.
// This example shows a ReaderWriterLock protecting a shared
// resource that is read concurrently and written exclusively
// by multiple threads.
// The complete code is located in the ReaderWriterLock
// class topic.
using namespace System;
using namespace System::Threading;
public ref class Test
{
public:
// Declaring the ReaderWriterLock at the class level
// makes it visible to all threads.
static ReaderWriterLock^ rwl = gcnew ReaderWriterLock;
// For this example, the shared resource protected by the
// ReaderWriterLock is just an integer.
static int resource = 0;
literal int numThreads = 26;
static bool running = true;
// Statistics.
static int readerTimeouts = 0;
static int writerTimeouts = 0;
static int reads = 0;
static int writes = 0;
static void ThreadProc()
{
Random^ rnd = gcnew Random;
// As long as a thread runs, it randomly selects
// various ways to read and write from the shared
// resource. Each of the methods demonstrates one
// or more features of ReaderWriterLock.
while ( running )
{
double action = rnd->NextDouble();
if ( action < .8 )
ReadFromResource( 10 );
else
if ( action < .81 )
ReleaseRestore( rnd, 50 );
else
if ( action < .90 )
UpgradeDowngrade( rnd, 100 );
else
WriteToResource( rnd, 100 );
}
}
// Shows how to request and release a reader lock, and
// how to handle time-outs.
static void ReadFromResource( int timeOut )
{
try
{
rwl->AcquireReaderLock( timeOut );
try
{
// It is safe for this thread to read from
// the shared resource.
Display( String::Format( "reads resource value {0}", resource ) );
Interlocked::Increment( reads );
}
finally
{
// Ensure that the lock is released.
rwl->ReleaseReaderLock();
}
}
catch ( ApplicationException^ )
{
// The reader lock request timed out.
Interlocked::Increment( readerTimeouts );
}
}
// Shows how to request and release the writer lock, and
// how to handle time-outs.
static void WriteToResource( Random^ rnd, int timeOut )
{
try
{
rwl->AcquireWriterLock( timeOut );
try
{
// It is safe for this thread to read or write
// from the shared resource.
resource = rnd->Next( 500 );
Display( String::Format( "writes resource value {0}", resource ) );
Interlocked::Increment( writes );
}
finally
{
// Ensure that the lock is released.
rwl->ReleaseWriterLock();
}
}
catch ( ApplicationException^ )
{
// The writer lock request timed out.
Interlocked::Increment( writerTimeouts );
}
}
// Shows how to request a reader lock, upgrade the
// reader lock to the writer lock, and downgrade to a
// reader lock again.
static void UpgradeDowngrade( Random^ rnd, int timeOut )
{
try
{
rwl->AcquireReaderLock( timeOut );
try
{
// It is safe for this thread to read from
// the shared resource.
Display( String::Format( "reads resource value {0}", resource ) );
Interlocked::Increment( reads );
// If it is necessary to write to the resource,
// you must either release the reader lock and
// then request the writer lock, or upgrade the
// reader lock. Note that upgrading the reader lock
// puts the thread in the write queue, behind any
// other threads that might be waiting for the
// writer lock.
try
{
LockCookie lc = rwl->UpgradeToWriterLock( timeOut );
try
{
// It is safe for this thread to read or write
// from the shared resource.
resource = rnd->Next( 500 );
Display( String::Format( "writes resource value {0}", resource ) );
Interlocked::Increment( writes );
}
finally
{
// Ensure that the lock is released.
rwl->DowngradeFromWriterLock( lc );
}
}
catch ( ApplicationException^ )
{
// The upgrade request timed out.
Interlocked::Increment( writerTimeouts );
}
// When the lock has been downgraded, it is
// still safe to read from the resource.
Display( String::Format( "reads resource value {0}", resource ) );
Interlocked::Increment( reads );
}
finally
{
// Ensure that the lock is released.
rwl->ReleaseReaderLock();
}
}
catch ( ApplicationException^ )
{
// The reader lock request timed out.
Interlocked::Increment( readerTimeouts );
}
}
// Shows how to release all locks and later restore
// the lock state. Shows how to use sequence numbers
// to determine whether another thread has obtained
// a writer lock since this thread last accessed the
// resource.
static void ReleaseRestore( Random^ rnd, int timeOut )
{
int lastWriter;
try
{
rwl->AcquireReaderLock( timeOut );
try
{
// It is safe for this thread to read from
// the shared resource. Cache the value. (You
// might do this if reading the resource is
// an expensive operation.)
int resourceValue = resource;
Display( String::Format( "reads resource value {0}", resourceValue ) );
Interlocked::Increment( reads );
// Save the current writer sequence number.
lastWriter = rwl->WriterSeqNum;
// Release the lock, and save a cookie so the
// lock can be restored later.
LockCookie lc = rwl->ReleaseLock();
// Wait for a random interval (up to a
// quarter of a second), and then restore
// the previous state of the lock. Note that
// there is no timeout on the Restore method.
Thread::Sleep( rnd->Next( 250 ) );
rwl->RestoreLock( lc );
// Check whether other threads obtained the
// writer lock in the interval. If not, then
// the cached value of the resource is still
// valid.
if ( rwl->AnyWritersSince( lastWriter ) )
{
resourceValue = resource;
Interlocked::Increment( reads );
Display( String::Format( "resource has changed {0}", resourceValue ) );
}
else
{
Display( String::Format( "resource has not changed {0}", resourceValue ) );
}
}
finally
{
// Ensure that the lock is released.
rwl->ReleaseReaderLock();
}
}
catch ( ApplicationException^ )
{
// The reader lock request timed out.
Interlocked::Increment( readerTimeouts );
}
}
// Helper method briefly displays the most recent
// thread action. Comment out calls to Display to
// get a better idea of throughput.
static void Display( String^ msg )
{
Console::Write( "Thread {0} {1}. \r", Thread::CurrentThread->Name, msg );
}
};
int main()
{
array<String^>^args = Environment::GetCommandLineArgs();
// Start a series of threads. Each thread randomly
// performs reads and writes on the shared resource.
array<Thread^>^t = gcnew array<Thread^>(Test::numThreads);
for ( int i = 0; i < Test::numThreads; i++ )
{
t[ i ] = gcnew Thread( gcnew ThreadStart( Test::ThreadProc ) );
t[ i ]->Name = gcnew String( Convert::ToChar( i + 65 ),1 );
t[ i ]->Start();
if ( i > 10 )
Thread::Sleep( 300 );
}
// Tell the threads to shut down, then wait until they all
// finish.
Test::running = false;
for ( int i = 0; i < Test::numThreads; i++ )
{
t[ i ]->Join();
}
// Display statistics.
Console::WriteLine( "\r\n {0} reads, {1} writes, {2} reader time-outs, {3} writer time-outs.", Test::reads, Test::writes, Test::readerTimeouts, Test::writerTimeouts );
Console::WriteLine( "Press ENTER to exit." );
Console::ReadLine();
return 0;
}
// The complete code is located in the ReaderWriterLock class topic.
using System;
using System.Threading;
public class Example
{
static ReaderWriterLock rwl = new ReaderWriterLock();
// Define the shared resource protected by the ReaderWriterLock.
static int resource = 0;
const int numThreads = 26;
static bool running = true;
// Statistics.
static int readerTimeouts = 0;
static int writerTimeouts = 0;
static int reads = 0;
static int writes = 0;
public static void Main()
{
// Start a series of threads to randomly read from and
// write to the shared resource.
Thread[] t = new Thread[numThreads];
for (int i = 0; i < numThreads; i++){
t[i] = new Thread(new ThreadStart(ThreadProc));
t[i].Name = new String((char)(i + 65), 1);
t[i].Start();
if (i > 10)
Thread.Sleep(300);
}
// Tell the threads to shut down and wait until they all finish.
running = false;
for (int i = 0; i < numThreads; i++)
t[i].Join();
// Display statistics.
Console.WriteLine("\n{0} reads, {1} writes, {2} reader time-outs, {3} writer time-outs.",
reads, writes, readerTimeouts, writerTimeouts);
Console.Write("Press ENTER to exit... ");
Console.ReadLine();
}
static void ThreadProc()
{
Random rnd = new Random();
// Randomly select a way for the thread to read and write from the shared
// resource.
while (running) {
double action = rnd.NextDouble();
if (action < .8)
ReadFromResource(10);
else if (action < .81)
ReleaseRestore(rnd, 50);
else if (action < .90)
UpgradeDowngrade(rnd, 100);
else
WriteToResource(rnd, 100);
}
}
// Request and release a reader lock, and handle time-outs.
static void ReadFromResource(int timeOut)
{
try {
rwl.AcquireReaderLock(timeOut);
try {
// It is safe for this thread to read from the shared resource.
Display("reads resource value " + resource);
Interlocked.Increment(ref reads);
}
finally {
// Ensure that the lock is released.
rwl.ReleaseReaderLock();
}
}
catch (ApplicationException) {
// The reader lock request timed out.
Interlocked.Increment(ref readerTimeouts);
}
}
// Request and release the writer lock, and handle time-outs.
static void WriteToResource(Random rnd, int timeOut)
{
try {
rwl.AcquireWriterLock(timeOut);
try {
// It's safe for this thread to access from the shared resource.
resource = rnd.Next(500);
Display("writes resource value " + resource);
Interlocked.Increment(ref writes);
}
finally {
// Ensure that the lock is released.
rwl.ReleaseWriterLock();
}
}
catch (ApplicationException) {
// The writer lock request timed out.
Interlocked.Increment(ref writerTimeouts);
}
}
// Requests a reader lock, upgrades the reader lock to the writer
// lock, and downgrades it to a reader lock again.
static void UpgradeDowngrade(Random rnd, int timeOut)
{
try {
rwl.AcquireReaderLock(timeOut);
try {
// It's safe for this thread to read from the shared resource.
Display("reads resource value " + resource);
Interlocked.Increment(ref reads);
// To write to the resource, either release the reader lock and
// request the writer lock, or upgrade the reader lock. Upgrading
// the reader lock puts the thread in the write queue, behind any
// other threads that might be waiting for the writer lock.
try {
LockCookie lc = rwl.UpgradeToWriterLock(timeOut);
try {
// It's safe for this thread to read or write from the shared resource.
resource = rnd.Next(500);
Display("writes resource value " + resource);
Interlocked.Increment(ref writes);
}
finally {
// Ensure that the lock is released.
rwl.DowngradeFromWriterLock(ref lc);
}
}
catch (ApplicationException) {
// The upgrade request timed out.
Interlocked.Increment(ref writerTimeouts);
}
// If the lock was downgraded, it's still safe to read from the resource.
Display("reads resource value " + resource);
Interlocked.Increment(ref reads);
}
finally {
// Ensure that the lock is released.
rwl.ReleaseReaderLock();
}
}
catch (ApplicationException) {
// The reader lock request timed out.
Interlocked.Increment(ref readerTimeouts);
}
}
// Release all locks and later restores the lock state.
// Uses sequence numbers to determine whether another thread has
// obtained a writer lock since this thread last accessed the resource.
static void ReleaseRestore(Random rnd, int timeOut)
{
int lastWriter;
try {
rwl.AcquireReaderLock(timeOut);
try {
// It's safe for this thread to read from the shared resource,
// so read and cache the resource value.
int resourceValue = resource; // Cache the resource value.
Display("reads resource value " + resourceValue);
Interlocked.Increment(ref reads);
// Save the current writer sequence number.
lastWriter = rwl.WriterSeqNum;
// Release the lock and save a cookie so the lock can be restored later.
LockCookie lc = rwl.ReleaseLock();
// Wait for a random interval and then restore the previous state of the lock.
Thread.Sleep(rnd.Next(250));
rwl.RestoreLock(ref lc);
// Check whether other threads obtained the writer lock in the interval.
// If not, then the cached value of the resource is still valid.
if (rwl.AnyWritersSince(lastWriter)) {
resourceValue = resource;
Interlocked.Increment(ref reads);
Display("resource has changed " + resourceValue);
}
else {
Display("resource has not changed " + resourceValue);
}
}
finally {
// Ensure that the lock is released.
rwl.ReleaseReaderLock();
}
}
catch (ApplicationException) {
// The reader lock request timed out.
Interlocked.Increment(ref readerTimeouts);
}
}
// Helper method briefly displays the most recent thread action.
static void Display(string msg)
{
Console.Write("Thread {0} {1}. \r", Thread.CurrentThread.Name, msg);
}
}
' The complete code is located in the ReaderWriterLock class topic.
Imports System.Threading
Public Module Example
Private rwl As New ReaderWriterLock()
' Define the shared resource protected by the ReaderWriterLock.
Private resource As Integer = 0
Const numThreads As Integer = 26
Private running As Boolean = True
' Statistics.
Private readerTimeouts As Integer = 0
Private writerTimeouts As Integer = 0
Private reads As Integer = 0
Private writes As Integer = 0
Public Sub Main()
' Start a series of threads to randomly read from and
' write to the shared resource.
Dim t(numThreads - 1) As Thread
Dim i As Integer
For i = 0 To numThreads - 1
t(i) = New Thread(New ThreadStart(AddressOf ThreadProc))
t(i).Name = Chr(i + 65)
t(i).Start()
If i > 10 Then
Thread.Sleep(300)
End If
Next
' Tell the threads to shut down and wait until they all finish.
running = False
For i = 0 To numThreads - 1
t(i).Join()
Next
' Display statistics.
Console.WriteLine(vbCrLf & "{0} reads, {1} writes, {2} reader time-outs, {3} writer time-outs.",
reads, writes, readerTimeouts, writerTimeouts)
Console.Write("Press ENTER to exit... ")
Console.ReadLine()
End Sub
Sub ThreadProc()
Dim rnd As New Random
' Randomly select a way for the thread to read and write from the shared
' resource.
While running
Dim action As Double = rnd.NextDouble()
If action < 0.8 Then
ReadFromResource(10)
ElseIf action < 0.81 Then
ReleaseRestore(rnd, 50)
ElseIf action < 0.9 Then
UpgradeDowngrade(rnd, 100)
Else
WriteToResource(rnd, 100)
End If
End While
End Sub
' Request and release a reader lock, and handle time-outs.
Sub ReadFromResource(timeOut As Integer)
Try
rwl.AcquireReaderLock(timeOut)
Try
' It's safe for this thread to read from the shared resource.
Display("reads resource value " & resource)
Interlocked.Increment(reads)
Finally
' Ensure that the lock is released.
rwl.ReleaseReaderLock()
End Try
Catch ex As ApplicationException
' The reader lock request timed out.
Interlocked.Increment(readerTimeouts)
End Try
End Sub
' Request and release the writer lock, and handle time-outs.
Sub WriteToResource(rnd As Random, timeOut As Integer)
Try
rwl.AcquireWriterLock(timeOut)
Try
' It's safe for this thread to read or write from the shared resource.
resource = rnd.Next(500)
Display("writes resource value " & resource)
Interlocked.Increment(writes)
Finally
' Ensure that the lock is released.
rwl.ReleaseWriterLock()
End Try
Catch ex As ApplicationException
' The writer lock request timed out.
Interlocked.Increment(writerTimeouts)
End Try
End Sub
' Requests a reader lock, upgrades the reader lock to the writer
' lock, and downgrades it to a reader lock again.
Sub UpgradeDowngrade(rnd As Random, timeOut As Integer)
Try
rwl.AcquireReaderLock(timeOut)
Try
' It's safe for this thread to read from the shared resource.
Display("reads resource value " & resource)
Interlocked.Increment(reads)
' To write to the resource, either release the reader lock and
' request the writer lock, or upgrade the reader lock. Upgrading
' the reader lock puts the thread in the write queue, behind any
' other threads that might be waiting for the writer lock.
Try
Dim lc As LockCookie = rwl.UpgradeToWriterLock(timeOut)
Try
' It's safe for this thread to read or write from the shared resource.
resource = rnd.Next(500)
Display("writes resource value " & resource)
Interlocked.Increment(writes)
Finally
' Ensure that the lock is released.
rwl.DowngradeFromWriterLock(lc)
End Try
Catch ex As ApplicationException
' The upgrade request timed out.
Interlocked.Increment(writerTimeouts)
End Try
' If the lock was downgraded, it's still safe to read from the resource.
Display("reads resource value " & resource)
Interlocked.Increment(reads)
Finally
' Ensure that the lock is released.
rwl.ReleaseReaderLock()
End Try
Catch ex As ApplicationException
' The reader lock request timed out.
Interlocked.Increment(readerTimeouts)
End Try
End Sub
' Release all locks and later restores the lock state.
' Uses sequence numbers to determine whether another thread has
' obtained a writer lock since this thread last accessed the resource.
Sub ReleaseRestore(rnd As Random ,timeOut As Integer)
Dim lastWriter As Integer
Try
rwl.AcquireReaderLock(timeOut)
Try
' It's safe for this thread to read from the shared resource,
' so read and cache the resource value.
Dim resourceValue As Integer = resource
Display("reads resource value " & resourceValue)
Interlocked.Increment(reads)
' Save the current writer sequence number.
lastWriter = rwl.WriterSeqNum
' Release the lock and save a cookie so the lock can be restored later.
Dim lc As LockCookie = rwl.ReleaseLock()
' Wait for a random interval and then restore the previous state of the lock.
Thread.Sleep(rnd.Next(250))
rwl.RestoreLock(lc)
' Check whether other threads obtained the writer lock in the interval.
' If not, then the cached value of the resource is still valid.
If rwl.AnyWritersSince(lastWriter) Then
resourceValue = resource
Interlocked.Increment(reads)
Display("resource has changed " & resourceValue)
Else
Display("resource has not changed " & resourceValue)
End If
Finally
' Ensure that the lock is released.
rwl.ReleaseReaderLock()
End Try
Catch ex As ApplicationException
' The reader lock request timed out.
Interlocked.Increment(readerTimeouts)
End Try
End Sub
' Helper method briefly displays the most recent thread action.
Sub Display(msg As String)
Console.Write("Thread {0} {1}. " & vbCr, Thread.CurrentThread.Name, msg)
End Sub
End Module
Hinweise
Wichtig
Die .NET Framework verfügt über zwei Reader-Writer-Sperren und ReaderWriterLockSlimReaderWriterLock. ReaderWriterLockSlim wird für alle Neuentwicklungen empfohlen. ReaderWriterLockSlim ähnelt ReaderWriterLock, verfügt aber über vereinfachte Regeln für Rekursion sowie für Upgrade und Downgrade des Sperrstatus. ReaderWriterLockSlim vermeidet viele potenzielle Deadlocks. Darüber hinaus ist die Leistung von ReaderWriterLockSlim wesentlich besser als die von ReaderWriterLock.
ReaderWriterLock wird verwendet, um den Zugriff auf eine Ressource zu synchronisieren. Es ermöglicht jederzeit den gleichzeitigen Lesezugriff für mehrere Threads oder den Schreibzugriff für einen einzelnen Thread. In einer Situation, in der eine Ressource selten geändert wird, bietet ein ReaderWriterLock
einen besseren Durchsatz als eine einfache einmalige Sperre, z. B Monitor. .
ReaderWriterLock
funktioniert am besten, wenn die meisten Zugriffe gelesen werden, während Schreibvorgänge selten und von kurzer Dauer sind. Mehrere Leser wechseln sich mit einzelnen Autoren ab, sodass weder Leser noch Autoren für lange Zeiträume blockiert werden.
Hinweis
Wenn Sie Lese- oder Schreibsperren für lange Zeiträume halten, werden andere Threads verhungern. Um eine optimale Leistung zu erzielen, sollten Sie Ihre Anwendung umstrukturieren, um die Dauer von Schreibvorgängen zu minimieren.
Ein Thread kann eine Lese- oder Schreibsperre enthalten, aber nicht beide gleichzeitig. Anstatt eine Lesersperre freizugeben, um die Writer-Sperre abzurufen, können Sie und DowngradeFromWriterLockverwendenUpgradeToWriterLock.
Rekursive Sperranforderungen erhöhen die Sperranzahl für eine Sperre.
Leser und Autoren werden separat in die Warteschlange gestellt. Wenn ein Thread die Writer-Sperre freigibt, werden allen Threads, die zu diesem Zeitpunkt in der Leserwarteschlange warten, Lesersperren gewährt. wenn alle diese Lesersperren freigegeben wurden, wird dem nächsten Thread, der in der Writer-Warteschlange wartet, falls vorhanden, die Writer-Sperre erteilt usw. Mit anderen Worten, ReaderWriterLock
wechselt zwischen einer Sammlung von Lesern und einem Schreiber.
Während ein Thread in der Writer-Warteschlange darauf wartet, dass aktive Lesersperren freigegeben werden, sammeln sich Threads, die neue Lesersperren anfordern, in der Leserwarteschlange an. Ihren Anträgen wird nicht stattgegeben, auch wenn sie den gleichzeitigen Zugriff mit vorhandenen Lesersperren teilen könnten; Dies trägt dazu bei, Autoren vor unbegrenzter Blockierung durch Leser zu schützen.
Die meisten Methoden zum Abrufen von Sperren für Einnahmetimeoutwerte ReaderWriterLock
. Verwenden Sie Timeouts, um Deadlocks in Ihrer Anwendung zu vermeiden. Beispielsweise kann ein Thread die Writer-Sperre für eine Ressource abrufen und dann eine Lesersperre für eine zweite Ressource anfordern. In der Zwischenzeit kann ein anderer Thread die Writer-Sperre für die zweite Ressource abrufen und eine Lesersperre für die erste anfordern. Sofern keine Timeouts verwendet werden, werden die Threads deadlockt.
Wenn das Timeoutintervall abläuft und die Sperranforderung nicht gewährt wurde, gibt die -Methode das Steuerelement an den aufrufenden Thread zurück, indem ein ApplicationExceptionausgelöst wird. Ein Thread kann diese Ausnahme abfangen und bestimmen, welche Aktion als Nächstes ausgeführt werden soll.
Timeouts werden in Millisekunden ausgedrückt. Wenn Sie ein System.TimeSpan verwenden, um das Timeout anzugeben, ist der verwendete Wert die Gesamtanzahl ganzer Millisekunden, die durch dargestellt TimeSpanwerden. Die folgende Tabelle zeigt die gültigen Timeoutwerte in Millisekunden.
Wert | BESCHREIBUNG |
---|---|
-1 | Der Thread wartet, bis die Sperre abgerufen wird, unabhängig davon, wie lange sie dauert. Für Methoden, die ganzzahlige Timeouts angeben, kann die Konstante Infinite verwendet werden. |
0 | Der Thread wartet nicht, bis die Sperre abgerufen wird. Wenn die Sperre nicht sofort abgerufen werden kann, gibt die -Methode zurück. |
>0 | Die Anzahl der Millisekunden, die gewartet werden soll. |
Mit Ausnahme von -1 sind negative Timeoutwerte nicht zulässig. Wenn Sie eine andere negative ganze Zahl als -1 angeben, wird stattdessen ein Timeoutwert von 0 verwendet. (Das heißt, die Methode gibt ohne Warten zurück, wenn die Sperre nicht sofort abgerufen werden kann.) Wenn Sie einen TimeSpan angeben, der eine negative Anzahl anderer Millisekunden als -1 darstellt, ArgumentOutOfRangeException wird ausgelöst.
Konstruktoren
ReaderWriterLock() |
Initialisiert eine neue Instanz der ReaderWriterLock-Klasse. |
Eigenschaften
IsReaderLockHeld |
Ruft einen Wert ab, der angibt, ob der aktuelle Thread eine Lesesperre besitzt. |
IsWriterLockHeld |
Ruft einen Wert ab, der angibt, ob der aktuelle Thread die Schreibsperre enthält. |
WriterSeqNum |
Ruft die aktuelle Sequenznummer ab. |
Methoden
AcquireReaderLock(Int32) |
Erhält eine Lesesperre unter Verwendung eines Int32-Werts für das Timeout. |
AcquireReaderLock(TimeSpan) |
Erhält eine Lesesperre unter Verwendung eines TimeSpan-Werts für das Timeout. |
AcquireWriterLock(Int32) |
Erhält die Schreibsperre unter Verwendung eines Int32-Werts für das Timeout. |
AcquireWriterLock(TimeSpan) |
Erhält die Schreibsperre unter Verwendung eines TimeSpan-Werts für das Timeout. |
AnyWritersSince(Int32) |
Gibt an, ob einem Thread die Schreibsperre erteilt wurde, seitdem die Sequenznummer erhalten wurde. |
DowngradeFromWriterLock(LockCookie) |
Stellt den Sperrstatus des Threads mit dem Status vor dem Aufruf von UpgradeToWriterLock(Int32) wieder her. |
Equals(Object) |
Bestimmt, ob das angegebene Objekt gleich dem aktuellen Objekt ist. (Geerbt von Object) |
Finalize() |
Stellt das Freigeben von Ressourcen und das Ausführen anderer Garbage Collector-Vorgänge sicher, wenn der Garbage Collector das ReaderWriterLock-Objekt verarbeitet. |
GetHashCode() |
Fungiert als Standardhashfunktion. (Geerbt von Object) |
GetType() |
Ruft den Type der aktuellen Instanz ab. (Geerbt von Object) |
MemberwiseClone() |
Erstellt eine flache Kopie des aktuellen Object. (Geerbt von Object) |
ReleaseLock() |
Hebt die Sperre unabhängig davon auf, wie oft dem Thread die Sperre zugewiesen wurde. |
ReleaseReaderLock() |
Verringert die Sperrenanzahl. |
ReleaseWriterLock() |
Verringert die Sperrenanzahl für die Schreibsperre. |
RestoreLock(LockCookie) |
Stellt den Sperrstatus des Threads mit dem Status vor dem Aufruf von ReleaseLock() wieder her. |
ToString() |
Gibt eine Zeichenfolge zurück, die das aktuelle Objekt darstellt. (Geerbt von Object) |
UpgradeToWriterLock(Int32) |
Wandelt eine Lesesperre unter Verwendung eines Int32-Werts für das Timeout in eine Schreibsperre um. |
UpgradeToWriterLock(TimeSpan) |
Wandelt eine Lesesperre unter Verwendung eines |
Gilt für:
Threadsicherheit
Dieser Typ ist threadsicher.