public bool TryEnter(TimeSpan timeout)
{
AsyncWaitHandle asyncWaitHandle = this.EnterCore();
if (asyncWaitHandle == null)
{
return(true);
}
else
{
bool flag = !asyncWaitHandle.Wait(timeout);
if (!this.aborted)
{
if (flag && !this.RemoveWaiter(asyncWaitHandle))
{
flag = false;
}
return(!flag);
}
else
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
}
}
public bool EnterAsync(TimeSpan timeout, FastAsyncCallback callback, object state)
{
bool flag;
lock (this.ThisLock)
{
if (!this.aborted)
{
if (this.count >= this.maxCount)
{
AsyncWaitHandle asyncWaitHandle = new AsyncWaitHandle();
this.Waiters.Enqueue(asyncWaitHandle);
return(asyncWaitHandle.WaitAsync(ThreadNeutralSemaphore.EnteredAsyncCallback, new ThreadNeutralSemaphore.EnterAsyncData(this, asyncWaitHandle, callback, state), timeout));
}
else
{
ThreadNeutralSemaphore threadNeutralSemaphore = this;
threadNeutralSemaphore.count = threadNeutralSemaphore.count + 1;
flag = true;
}
}
else
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
}
return(flag);
}
private AsyncWaitHandle EnterCore()
{
AsyncWaitHandle asyncWaitHandle;
lock (this.ThisLock)
{
if (!this.aborted)
{
if (this.count >= this.maxCount)
{
AsyncWaitHandle asyncWaitHandle1 = new AsyncWaitHandle();
this.Waiters.Enqueue(asyncWaitHandle1);
return(asyncWaitHandle1);
}
else
{
ThreadNeutralSemaphore threadNeutralSemaphore = this;
threadNeutralSemaphore.count = threadNeutralSemaphore.count + 1;
asyncWaitHandle = null;
}
}
else
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
}
return(asyncWaitHandle);
}
public bool TryEnter(TimeSpan timeout)
{
AsyncWaitHandle waiter = EnterCore();
if (waiter != null)
{
bool timedOut = !waiter.Wait(timeout);
if (this.aborted)
{
throw Fx.Exception.AsError(CreateObjectAbortedException());
}
if (timedOut && !RemoveWaiter(waiter))
{
// The timeout raced with Exit and exit won.
// We've successfully entered.
timedOut = false;
}
return(!timedOut);
}
return(true);
}
public EnterAsyncData(ThreadNeutralSemaphore semaphore, AsyncWaitHandle waiter, FastAsyncCallback callback, object state)
{
this.Waiter = waiter;
this.Semaphore = semaphore;
this.Callback = callback;
this.State = state;
}
public bool EnterAsync(TimeSpan timeout, FastAsyncCallback callback, object state)
{
Fx.Assert(callback != null, "must have a non-null call back for async purposes");
AsyncWaitHandle waiter = null;
lock (this.ThisLock)
{
if (this.aborted)
{
throw Fx.Exception.AsError(CreateObjectAbortedException());
}
if (this.count < this.maxCount)
{
this.count++;
return(true);
}
waiter = new AsyncWaitHandle();
this.Waiters.Enqueue(waiter);
}
return(waiter.WaitAsync(EnteredAsyncCallback, new EnterAsyncData(this, waiter, callback, state), timeout));
}
public void Abort()
{
lock (this.ThisLock)
{
if (!this.aborted)
{
this.aborted = true;
if (this.waiters != null)
{
while (this.waiters.Count > 0)
{
AsyncWaitHandle asyncWaitHandle = this.waiters.Dequeue();
asyncWaitHandle.Set();
}
}
}
}
}
private static void OnTimerComplete(object state)
{
AsyncWaitHandle.AsyncWaiter asyncWaiter = (AsyncWaitHandle.AsyncWaiter)state;
AsyncWaitHandle parent = asyncWaiter.Parent;
bool flag = false;
lock (parent.syncObject)
{
if (parent.asyncWaiters != null && parent.asyncWaiters.Remove(asyncWaiter))
{
asyncWaiter.TimedOut = true;
}
}
asyncWaiter.CancelTimer();
if (flag)
{
asyncWaiter.Call();
}
}
public bool EnterAsync(TimeSpan timeout, FastAsyncCallback callback, object state)
{
AsyncWaitHandle item = null;
lock (this.ThisLock)
{
if (this.aborted)
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
if (this.count < this.maxCount)
{
this.count++;
return true;
}
item = new AsyncWaitHandle();
this.Waiters.Enqueue(item);
}
return item.WaitAsync(EnteredAsyncCallback, new EnterAsyncData(this, item, callback, state), timeout);
}
private bool RemoveWaiter(AsyncWaitHandle waiter)
{
bool flag = false;
lock (this.ThisLock)
{
for (int i = this.Waiters.Count; i > 0; i--)
{
AsyncWaitHandle asyncWaitHandle = this.Waiters.Dequeue();
if (!object.ReferenceEquals(asyncWaitHandle, waiter))
{
this.Waiters.Enqueue(asyncWaitHandle);
}
else
{
}
}
}
return(flag);
}
public bool EnterAsync(TimeSpan timeout, FastAsyncCallback callback, object state)
{
AsyncWaitHandle item = null;
lock (this.ThisLock)
{
if (this.aborted)
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
if (this.count < this.maxCount)
{
this.count++;
return(true);
}
item = new AsyncWaitHandle();
this.Waiters.Enqueue(item);
}
return(item.WaitAsync(EnteredAsyncCallback, new EnterAsyncData(this, item, callback, state), timeout));
}
private AsyncWaitHandle EnterCore()
{
AsyncWaitHandle handle;
lock (this.ThisLock)
{
if (this.aborted)
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
if (this.count < this.maxCount)
{
this.count++;
return(null);
}
handle = new AsyncWaitHandle();
this.Waiters.Enqueue(handle);
}
return(handle);
}
public bool TryEnter(TimeSpan timeout)
{
AsyncWaitHandle waiter = this.EnterCore();
if (waiter == null)
{
return(true);
}
bool flag = !waiter.Wait(timeout);
if (this.aborted)
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
if (flag && !this.RemoveWaiter(waiter))
{
flag = false;
}
return(!flag);
}
private static void OnTimerComplete(object state)
{
AsyncWaiter item = (AsyncWaiter)state;
AsyncWaitHandle parent = item.Parent;
bool flag = false;
lock (parent.syncObject)
{
if ((parent.asyncWaiters != null) && parent.asyncWaiters.Remove(item))
{
item.TimedOut = true;
flag = true;
}
}
item.CancelTimer();
if (flag)
{
item.Call();
}
}
// Abort the ThreadNeutralSemaphore object.
public void Abort()
{
lock (this.ThisLock)
{
if (this.aborted)
{
return;
}
this.aborted = true;
if (this.waiters != null)
{
while (this.waiters.Count > 0)
{
AsyncWaitHandle waiter = this.waiters.Dequeue();
waiter.Set();
}
}
}
}
// remove a waiter from our queue. Returns true if successful. Used to implement timeouts.
bool RemoveWaiter(AsyncWaitHandle waiter)
{
bool removed = false;
lock (this.ThisLock)
{
for (int i = this.Waiters.Count; i > 0; i--)
{
AsyncWaitHandle temp = this.Waiters.Dequeue();
if (object.ReferenceEquals(temp, waiter))
{
removed = true;
}
else
{
this.Waiters.Enqueue(temp);
}
}
}
return(removed);
}
public int Exit()
{
int num;
int num1 = -1;
lock (this.ThisLock)
{
if (!this.aborted)
{
if (this.count != 0)
{
if (this.waiters == null || this.waiters.Count == 0)
{
ThreadNeutralSemaphore threadNeutralSemaphore = this;
threadNeutralSemaphore.count = threadNeutralSemaphore.count - 1;
num = this.count;
}
else
{
AsyncWaitHandle asyncWaitHandle = this.waiters.Dequeue();
num1 = this.count;
asyncWaitHandle.Set();
return(num1);
}
}
else
{
string invalidSemaphoreExit = InternalSR.InvalidSemaphoreExit;
throw Fx.Exception.AsError(new SynchronizationLockException(invalidSemaphoreExit));
}
}
else
{
num = num1;
}
}
return(num);
}
static void OnTimerComplete(object state)
{
AsyncWaiter waiter = (AsyncWaiter)state;
AsyncWaitHandle thisPtr = waiter.Parent;
bool callWaiter = false;
lock (thisPtr.syncObject)
{
// If still in the waiting list (that means it hasn't been signaled)
if (thisPtr.asyncWaiters != null && thisPtr.asyncWaiters.Remove(waiter))
{
waiter.TimedOut = true;
callWaiter = true;
}
}
waiter.CancelTimer();
if (callWaiter)
{
waiter.Call();
}
}
AsyncWaitHandle SetupIdleWaiter(ref bool ownsLock)
{
AsyncWaitHandle idleEvent = new AsyncWaitHandle(EventResetMode.ManualReset);
lock (this.activeOperationsLock)
{
if (this.idleWaiters == null)
{
this.idleWaiters = new List<AsyncWaitHandle>();
}
this.idleWaiters.Add(idleEvent);
}
ReleaseLock(ref ownsLock);
return idleEvent;
}
private AsyncWaitHandle EnterCore(ref object token, ref bool ownsLock)
{
AsyncWaitHandle item = null;
lock (this.ThisLock)
{
if (this.owned)
{
if (token == null)
{
item = new AsyncWaitHandle();
this.Waiters.Add(item);
return item;
}
return (AsyncWaitHandle) token;
}
try
{
}
finally
{
this.owned = true;
ownsLock = true;
}
}
return item;
}
public BindReclaimedLockAsyncResult(InstancePersistenceContext context, AsyncWaitHandle wait, TimeSpan timeout, AsyncCallback callback, object state) : base(callback, state)
{
this.context = context;
if (wait.WaitAsync(waitComplete, this, timeout))
{
this.context.ConcludeBindReclaimedLockHelper();
base.Complete(true);
}
}
public bool EnterAsync(TimeSpan timeout, FastAsyncCallback callback, object state)
{
Fx.Assert(callback != null, "must have a non-null call back for async purposes");
AsyncWaitHandle waiter = null;
lock (this.ThisLock)
{
if (this.aborted)
{
throw Fx.Exception.AsError(CreateObjectAbortedException());
}
if (this.count < this.maxCount)
{
this.count++;
return true;
}
waiter = new AsyncWaitHandle();
this.Waiters.Enqueue(waiter);
}
return waiter.WaitAsync(EnteredAsyncCallback, new EnterAsyncData(this, waiter, callback, state), timeout);
}
internal BindReclaimedLockException(AsyncWaitHandle markerWaitHandle) : base(SRCore.BindReclaimedLockException)
{
this.MarkerWaitHandle = markerWaitHandle;
}
BookmarkResumptionResult ResumeProtocolBookmarkCore(Bookmark bookmark, object value, BookmarkScope bookmarkScope, bool bufferedReceiveEnabled, ref AsyncWaitHandle waitHandle, ref bool ownsLock)
{
Fx.Assert(this.state == State.Active, "WorkflowServiceInstance.State should be State.Active at this point.");
BookmarkResumptionResult result;
if (bookmarkScope == null)
{
result = this.Controller.ScheduleBookmarkResumption(bookmark, value);
}
else
{
result = this.Controller.ScheduleBookmarkResumption(bookmark, value, bookmarkScope);
}
if (result == BookmarkResumptionResult.NotReady && !bufferedReceiveEnabled)
{
if (waitHandle == null)
{
waitHandle = new AsyncWaitHandle();
}
else
{
waitHandle.Reset();
}
// Creation doesn't require the lock since it is guarded
// by the executor lock.
if (this.nextIdleWaiters == null)
{
this.nextIdleWaiters = new List<AsyncWaitHandle>();
}
lock (this.activeOperationsLock)
{
this.nextIdleWaiters.Add(waitHandle);
}
// We release the lock here so that the workflow will continue to process
// until the NextIdle waiters get notified
ReleaseLock(ref ownsLock);
}
return result;
}
private bool CleanupIdleWaiter(AsyncWaitHandle idleEvent, Exception waitException, ref bool ownsLock)
{
lock (this.activeOperationsLock)
{
if (!this.idleWaiters.Remove(idleEvent) && (waitException is TimeoutException))
{
ownsLock = true;
return false;
}
}
return true;
}
public bool EnterAsync(TimeSpan timeout, FastAsyncCallback callback, object state)
{
bool flag;
lock (this.ThisLock)
{
if (!this.aborted)
{
if (this.count >= this.maxCount)
{
AsyncWaitHandle asyncWaitHandle = new AsyncWaitHandle();
this.Waiters.Enqueue(asyncWaitHandle);
return asyncWaitHandle.WaitAsync(ThreadNeutralSemaphore.EnteredAsyncCallback, new ThreadNeutralSemaphore.EnterAsyncData(this, asyncWaitHandle, callback, state), timeout);
}
else
{
ThreadNeutralSemaphore threadNeutralSemaphore = this;
threadNeutralSemaphore.count = threadNeutralSemaphore.count + 1;
flag = true;
}
}
else
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
}
return flag;
}
// The token returned here must be fed to all Enter calls
// and finally to CleanupWaiter by the thread that calls
// SetupWaiter. If the enter goes async (such as EnterAsync
// might) then the caller should NOT call cleanup in the async
// callback.
public void SetupWaiter(bool isAbortPriority, ref object token)
{
lock (ThisLock)
{
try
{
}
finally
{
token = new AsyncWaitHandle();
if (isAbortPriority)
{
this.Waiters.Insert(0, token);
}
else
{
this.Waiters.Add(token);
}
}
}
}
bool CheckState(ref bool ownsLock)
{
if (this.instance.state == State.Active && !this.instance.isRunnable)
{
this.instance.RunCore();
}
// If instance state is non-Active, the AcquireOnIdle will succeed (WSI is doing nothing),
// the caller is responsible for dealing with state vs. operation.
// For instance, ResumeBookmark will call ValidateStateForResumeProtocolBookmark.
if (this.instance.state == State.Active && this.instance.Controller.State == WorkflowInstanceState.Runnable)
{
this.idleEvent = this.instance.SetupIdleWaiter(ref ownsLock);
try
{
if (this.idleEvent.WaitAsync(idleReceivedCallback, this, this.timeoutHelper.RemainingTime()))
{
ownsLock = true;
}
else
{
return false;
}
}
catch (Exception e)
{
if (Fx.IsFatal(e))
{
throw;
}
if (this.instance.CleanupIdleWaiter(this.idleEvent, e, ref ownsLock))
{
throw;
}
}
}
return true;
}
private AsyncWaitHandle EnterCore()
{
AsyncWaitHandle asyncWaitHandle;
lock (this.ThisLock)
{
if (!this.aborted)
{
if (this.count >= this.maxCount)
{
AsyncWaitHandle asyncWaitHandle1 = new AsyncWaitHandle();
this.Waiters.Enqueue(asyncWaitHandle1);
return asyncWaitHandle1;
}
else
{
ThreadNeutralSemaphore threadNeutralSemaphore = this;
threadNeutralSemaphore.count = threadNeutralSemaphore.count + 1;
asyncWaitHandle = null;
}
}
else
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
}
return asyncWaitHandle;
}
private bool WaitForCanPersist()
{
if (this.instance.Controller.IsPersistable)
{
return true;
}
this.instance.Controller.PauseWhenPersistable();
this.mustWait = false;
if (this.instance.IsIdle)
{
if (this.checkCanPersistEvent == null)
{
this.checkCanPersistEvent = new AsyncWaitHandle(EventResetMode.AutoReset);
}
this.instance.AddCheckCanPersistWaiter(this);
this.mustWait = true;
}
this.instance.ReleaseLock(ref this.ownsLock);
if (!this.mustWait)
{
return this.HandleWaitEvent();
}
if (onWaitEvent == null)
{
onWaitEvent = new Action<object, TimeoutException>(WorkflowServiceInstance.WaitForCanPersistAsyncResult.OnWaitEvent);
}
return (this.checkCanPersistEvent.WaitAsync(onWaitEvent, this, this.timeoutHelper.RemainingTime()) && this.HandleWaitEvent());
}
public AsyncWaiter(AsyncWaitHandle parent, Action<object, TimeoutException> callback, object state)
{
this.Parent = parent;
this.callback = callback;
this.state = state;
}
public AsyncWaiter(AsyncWaitHandle parent, Action <object, TimeoutException> callback, object state)
{
this.Parent = parent;
this.callback = callback;
this.state = state;
}
private bool RemoveWaiter(AsyncWaitHandle waiter)
{
bool flag = false;
lock (this.ThisLock)
{
for (int i = this.Waiters.Count; i > 0; i--)
{
AsyncWaitHandle objA = this.Waiters.Dequeue();
if (object.ReferenceEquals(objA, waiter))
{
flag = true;
}
else
{
this.Waiters.Enqueue(objA);
}
}
}
return flag;
}
public void EnsureAsyncWaitHandle()
{
this.receivedReplyEvent = new AsyncWaitHandle();
}
internal LockResolutionMarker(InstanceHandle instanceHandle, long instanceVersion) : base(instanceHandle)
{
this.waitHandle = new AsyncWaitHandle(EventResetMode.ManualReset);
this.InstanceVersion = instanceVersion;
}
public PendingOperationAsyncResult(bool isFirstRequest, TimeSpan timeout, AsyncCallback callback, object state)
: base(callback, state)
{
this.isFirstRequest = isFirstRequest;
this.timeout = timeout;
if (!this.isFirstRequest)
{
this.waitHandle = new AsyncWaitHandle(EventResetMode.ManualReset);
}
}
public void SetInteriorTransaction(Transaction interiorTransaction, bool needsCommit)
{
if (this.waitForTransaction != null)
{
throw Fx.Exception.AsError(new InvalidOperationException(SRCore.ExecuteMustBeNested));
}
bool flag = false;
try
{
this.waitForTransaction = new AsyncWaitHandle(EventResetMode.ManualReset);
interiorTransaction.EnlistVolatile((ISinglePhaseNotification) this, EnlistmentOptions.None);
flag = true;
}
finally
{
if (!flag)
{
if (this.waitForTransaction != null)
{
this.waitForTransaction.Set();
}
}
else if (needsCommit)
{
this.transactionToCommit = (CommittableTransaction) interiorTransaction;
}
}
}
bool WaitForCanPersist()
{
if (this.instance.Controller.IsPersistable)
{
return true;
}
this.instance.Controller.PauseWhenPersistable();
this.mustWait = false;
if (this.instance.IsIdle)
{
if (this.checkCanPersistEvent == null)
{
this.checkCanPersistEvent = new AsyncWaitHandle(EventResetMode.AutoReset);
}
// Will be signaled when WF is paused.
this.instance.AddCheckCanPersistWaiter(this);
this.mustWait = true;
}
this.instance.ReleaseLock(ref this.ownsLock);
if (this.mustWait)
{
if (onWaitEvent == null)
{
onWaitEvent = new Action<object, TimeoutException>(OnWaitEvent);
}
if (this.checkCanPersistEvent.WaitAsync(onWaitEvent, this, this.timeoutHelper.RemainingTime()))
{
return HandleWaitEvent();
}
else
{
return false;
}
}
else
{
return HandleWaitEvent();
}
}
AsyncWaitHandle LoadInProgressWaitHandle(InstanceKey key)
{
AsyncWaitHandle waitHandle = null;
if (key != null)
{
lock (ThisLock)
{
this.loadsInProgress.TryGetValue(key, out waitHandle);
if (waitHandle == null)
{
AsyncWaitHandle newWaitHandle = new AsyncWaitHandle(EventResetMode.ManualReset);
this.loadsInProgress.Add(key, newWaitHandle);
}
}
}
return waitHandle;
}
AsyncWaitHandle EnterCore(ref object token, ref bool ownsLock)
{
AsyncWaitHandle waiter = null;
lock (ThisLock)
{
if (this.owned)
{
if (token == null)
{
waiter = new AsyncWaitHandle();
this.Waiters.Add(waiter);
}
else
{
waiter = (AsyncWaitHandle)token;
}
}
else
{
try
{
}
finally
{
this.owned = true;
ownsLock = true;
}
}
}
return waiter;
}
internal WorkflowHostingResponseContext()
{
this.responseWaitHandle = new AsyncWaitHandle(EventResetMode.AutoReset);
}
bool CleanupIdleWaiter(AsyncWaitHandle idleEvent, Exception waitException, ref bool ownsLock)
{
lock (this.activeOperationsLock)
{
if (!this.idleWaiters.Remove(idleEvent))
{
// If it wasn't in the list that means we ----d between throwing from Wait
// and setting the event. This thread now is responsible for the lock.
if (waitException is TimeoutException)
{
// In the case of Timeout we let setting the event win and signal to
// ---- the exception
ownsLock = true;
return false;
}
}
}
return true;
}
private void InitializePersistenceProviderDirectory()
{
bool flag;
WorkflowServiceBehavior behavior = this.Host.Description.Behaviors.Find<WorkflowServiceBehavior>();
int defaultMaxConcurrentInstances = ServiceThrottlingBehavior.DefaultMaxConcurrentInstances;
ServiceThrottlingBehavior behavior2 = this.Host.Description.Behaviors.Find<ServiceThrottlingBehavior>();
if (behavior2 != null)
{
defaultMaxConcurrentInstances = behavior2.MaxConcurrentInstances;
}
if (this.InstanceStore != null)
{
this.PersistenceProviderDirectory = new System.ServiceModel.Activities.Dispatcher.PersistenceProviderDirectory(this.InstanceStore, this.owner, this.instanceMetadataChanges, behavior.Activity, this.Host, DurableConsistencyScope.Global, defaultMaxConcurrentInstances);
}
else
{
this.PersistenceProviderDirectory = new System.ServiceModel.Activities.Dispatcher.PersistenceProviderDirectory(behavior.Activity, this.Host, defaultMaxConcurrentInstances);
}
lock (this.thisLock)
{
flag = this.state == 3;
}
if (flag)
{
if (this.handle != null)
{
this.handle.Free();
}
this.PersistenceProviderDirectory.Abort();
}
if ((this.InstanceStore != null) && !flag)
{
this.waitForStoreEventsLoop = new AsyncWaitHandle(EventResetMode.ManualReset);
this.BeginWaitAndHandleStoreEvents(waitAndHandleStoreEventsCallback, this);
}
}
void InitializePersistenceProviderDirectory()
{
int maxInstances = ServiceThrottlingBehavior.DefaultMaxConcurrentInstances;
ServiceThrottlingBehavior serviceThrottlingBehavior = Host.Description.Behaviors.Find<ServiceThrottlingBehavior>();
if (serviceThrottlingBehavior != null)
{
maxInstances = serviceThrottlingBehavior.MaxConcurrentInstances;
}
if (InstanceStore != null)
{
PersistenceProviderDirectory = new PersistenceProviderDirectory(InstanceStore, this.owner, this.instanceMetadataChanges, this.workflowDefinitionProvider, Host, DurableConsistencyScope.Global, maxInstances);
}
else
{
PersistenceProviderDirectory = new PersistenceProviderDirectory(this.workflowDefinitionProvider, Host, maxInstances);
}
bool aborted;
lock (this.thisLock)
{
aborted = this.state == States.Aborted;
}
if (aborted)
{
if (this.handle != null)
{
this.handle.Free();
}
PersistenceProviderDirectory.Abort();
}
// Start listening to store event
if (InstanceStore != null && !aborted)
{
this.waitForStoreEventsLoop = new AsyncWaitHandle(EventResetMode.ManualReset);
BeginWaitAndHandleStoreEvents(waitAndHandleStoreEventsCallback, this);
}
}
// remove a waiter from our queue. Returns true if successful. Used to implement timeouts.
bool RemoveWaiter(AsyncWaitHandle waiter)
{
bool removed = false;
lock (this.ThisLock)
{
for (int i = this.Waiters.Count; i > 0; i--)
{
AsyncWaitHandle temp = this.Waiters.Dequeue();
if (object.ReferenceEquals(temp, waiter))
{
removed = true;
}
else
{
this.Waiters.Enqueue(temp);
}
}
}
return removed;
}
public EnterAsyncData(ThreadNeutralSemaphore semaphore, AsyncWaitHandle waiter, FastAsyncCallback callback, object state)
{
this.Waiter = waiter;
this.Semaphore = semaphore;
this.Callback = callback;
this.State = state;
}
AsyncWaitHandle EnterCore()
{
AsyncWaitHandle waiter;
lock (this.ThisLock)
{
if (this.aborted)
{
throw Fx.Exception.AsError(CreateObjectAbortedException());
}
if (this.count < this.maxCount)
{
this.count++;
return null;
}
waiter = new AsyncWaitHandle();
this.Waiters.Enqueue(waiter);
}
return waiter;
}
private AsyncWaitHandle EnterCore()
{
AsyncWaitHandle handle;
lock (this.ThisLock)
{
if (this.aborted)
{
throw Fx.Exception.AsError(this.CreateObjectAbortedException());
}
if (this.count < this.maxCount)
{
this.count++;
return null;
}
handle = new AsyncWaitHandle();
this.Waiters.Enqueue(handle);
}
return handle;
}
public bool Wait(TimeSpan timeout)
{
bool flag;
if (!this.isSignaled || this.isSignaled && this.resetMode == EventResetMode.AutoReset)
{
lock (this.syncObject)
{
if (!this.isSignaled || this.resetMode != EventResetMode.AutoReset)
{
if (!this.isSignaled)
{
bool flag1 = false;
try
{
try
{
}
finally
{
AsyncWaitHandle asyncWaitHandle = this;
asyncWaitHandle.syncWaiterCount = asyncWaitHandle.syncWaiterCount + 1;
flag1 = true;
}
if (timeout != TimeSpan.MaxValue)
{
if (!Monitor.Wait(this.syncObject, timeout))
{
flag = false;
return(flag);
}
}
else
{
if (!Monitor.Wait(this.syncObject, -1))
{
flag = false;
return(flag);
}
}
}
finally
{
if (flag1)
{
AsyncWaitHandle asyncWaitHandle1 = this;
asyncWaitHandle1.syncWaiterCount = asyncWaitHandle1.syncWaiterCount - 1;
}
}
}
}
else
{
this.isSignaled = false;
}
return(true);
}
return(flag);
}
return(true);
}