| static private Sleep ( int milliseconds ) : void | ||
| milliseconds | int | |
| return | void | |
private void EnterMyLockSpin()
{
int pc = Environment.ProcessorCount;
for (int i = 0; ; i++)
{
if (i < LockSpinCount && pc > 1)
{
Helpers.Spin(LockSpinCycles * (i + 1)); // Wait a few dozen instructions to let another processor release lock.
}
else if (i < (LockSpinCount + LockSleep0Count))
{
Helpers.Sleep(0); // Give up my quantum.
}
else
{
Helpers.Sleep(1); // Give up my quantum.
}
if (_myLock == 0 && Interlocked.CompareExchange(ref _myLock, 1, 0) == 0)
{
return;
}
}
}
private static void SpinWait(int SpinCount)
{
//Exponential backoff
if ((SpinCount < 5) && (Environment.ProcessorCount > 1))
{
Helpers.Spin(LockSpinCycles * SpinCount);
}
else if (SpinCount < MaxSpinCount - 3)
{
Helpers.Sleep(0);
}
else
{
Helpers.Sleep(1);
}
}
/// <summary>
/// Try acquire the lock with long path, this is usually called after the first path in Enter and
/// TryEnter failed The reason for short path is to make it inline in the run time which improves the
/// performance. This method assumed that the parameter are validated in Enter ir TryENter method
/// </summary>
/// <param name="millisecondsTimeout">The timeout milliseconds</param>
/// <param name="lockTaken">The lockTaken param</param>
private void ContinueTryEnter(int millisecondsTimeout, ref bool lockTaken)
{
// The fast path doesn't throw any exception, so we have to validate the parameters here
if (lockTaken)
{
lockTaken = false;
throw new System.ArgumentException(SR.SpinLock_TryReliableEnter_ArgumentException);
}
if (millisecondsTimeout < -1)
{
throw new ArgumentOutOfRangeException(
"millisecondsTimeout", millisecondsTimeout, SR.SpinLock_TryEnter_ArgumentOutOfRange);
}
uint startTime = 0;
if (millisecondsTimeout != Timeout.Infinite && millisecondsTimeout != 0)
{
startTime = TimeoutHelper.GetTime();
}
#if !FEATURE_PAL && !FEATURE_CORECLR // PAL doesn't support eventing, and we don't compile CDS providers for Coreclr
if (CdsSyncEtwBCLProvider.Log.IsEnabled())
{
CdsSyncEtwBCLProvider.Log.SpinLock_FastPathFailed(m_owner);
}
#endif
if (IsThreadOwnerTrackingEnabled)
{
// Slow path for enabled thread tracking mode
ContinueTryEnterWithThreadTracking(millisecondsTimeout, startTime, ref lockTaken);
return;
}
// then thread tracking is disabled
// In this case there are three ways to acquire the lock
// 1- the first way the thread either tries to get the lock if it's free or updates the waiters, if the turn >= the processors count then go to 3 else go to 2
// 2- In this step the waiter threads spins and tries to acquire the lock, the number of spin iterations and spin count is dependent on the thread turn
// the late the thread arrives the more it spins and less frequent it check the lock avilability
// Also the spins count is increases each iteration
// If the spins iterations finished and failed to acquire the lock, go to step 3
// 3- This is the yielding step, there are two ways of yielding Thread.Yield and Sleep(1)
// If the timeout is expired in after step 1, we need to decrement the waiters count before returning
int observedOwner;
int turn = int.MaxValue;
//***Step 1, take the lock or update the waiters
// try to acquire the lock directly if possible or update the waiters count
observedOwner = m_owner;
if ((observedOwner & LOCK_ANONYMOUS_OWNED) == LOCK_UNOWNED)
{
if (CompareExchange(ref m_owner, observedOwner | 1, observedOwner, ref lockTaken) == observedOwner)
{
return;
}
}
else //failed to acquire the lock,then try to update the waiters. If the waiters count reached the maximum, jsut break the loop to avoid overflow
{
if ((observedOwner & WAITERS_MASK) != MAXIMUM_WAITERS)
{
turn = (Interlocked.Add(ref m_owner, 2) & WAITERS_MASK) >> 1;
}
}
// Check the timeout.
if (millisecondsTimeout == 0 ||
(millisecondsTimeout != Timeout.Infinite &&
TimeoutHelper.UpdateTimeOut(startTime, millisecondsTimeout) <= 0))
{
DecrementWaiters();
return;
}
//***Step 2. Spinning
//lock acquired failed and waiters updated
int processorCount = PlatformHelper.ProcessorCount;
if (turn < processorCount)
{
int processFactor = 1;
for (int i = 1; i <= turn * SPINNING_FACTOR; i++)
{
SpinWait.Spin((turn + i) * SPINNING_FACTOR * processFactor);
if (processFactor < processorCount)
{
processFactor++;
}
observedOwner = m_owner;
if ((observedOwner & LOCK_ANONYMOUS_OWNED) == LOCK_UNOWNED)
{
int newOwner = (observedOwner & WAITERS_MASK) == 0 ? // Gets the number of waiters, if zero
observedOwner | 1 // don't decrement it. just set the lock bit, it is zzero because a previous call of Exit(false) ehich corrupted the waiters
: (observedOwner - 2) | 1; // otherwise decrement the waiters and set the lock bit
Contract.Assert((newOwner & WAITERS_MASK) >= 0);
if (CompareExchange(ref m_owner, newOwner, observedOwner, ref lockTaken) == observedOwner)
{
return;
}
}
}
}
// Check the timeout.
if (millisecondsTimeout != Timeout.Infinite && TimeoutHelper.UpdateTimeOut(startTime, millisecondsTimeout) <= 0)
{
DecrementWaiters();
return;
}
//*** Step 3, Yielding
//Sleep(1) every 50 yields
int yieldsoFar = 0;
while (true)
{
observedOwner = m_owner;
if ((observedOwner & LOCK_ANONYMOUS_OWNED) == LOCK_UNOWNED)
{
int newOwner = (observedOwner & WAITERS_MASK) == 0 ? // Gets the number of waiters, if zero
observedOwner | 1 // don't decrement it. just set the lock bit, it is zzero because a previous call of Exit(false) ehich corrupted the waiters
: (observedOwner - 2) | 1; // otherwise decrement the waiters and set the lock bit
Contract.Assert((newOwner & WAITERS_MASK) >= 0);
if (CompareExchange(ref m_owner, newOwner, observedOwner, ref lockTaken) == observedOwner)
{
return;
}
}
if (yieldsoFar % SLEEP_ONE_FREQUENCY == 0)
{
Helpers.Sleep(1);
}
else if (yieldsoFar % SLEEP_ZERO_FREQUENCY == 0)
{
Helpers.Sleep(0);
}
else
{
SpinWait.Yield();
}
if (yieldsoFar % TIMEOUT_CHECK_FREQUENCY == 0)
{
//Check the timeout.
if (millisecondsTimeout != Timeout.Infinite && TimeoutHelper.UpdateTimeOut(startTime, millisecondsTimeout) <= 0)
{
DecrementWaiters();
return;
}
}
yieldsoFar++;
}
}
/// <summary>
/// Blocks the current thread until the current <see cref="ManualResetEventSlim"/> is set, using a
/// 32-bit signed integer to measure the time interval, while observing a <see
/// cref="T:System.Threading.CancellationToken"/>.
/// </summary>
/// <param name="millisecondsTimeout">The number of milliseconds to wait, or <see
/// cref="Timeout.Infinite"/>(-1) to wait indefinitely.</param>
/// <param name="cancellationToken">The <see cref="T:System.Threading.CancellationToken"/> to
/// observe.</param>
/// <returns>true if the <see cref="System.Threading.ManualResetEventSlim"/> was set; otherwise,
/// false.</returns>
/// <exception cref="T:System.ArgumentOutOfRangeException"><paramref name="millisecondsTimeout"/> is a
/// negative number other than -1, which represents an infinite time-out.</exception>
/// <exception cref="T:System.InvalidOperationException">
/// The maximum number of waiters has been exceeded.
/// </exception>
/// <exception cref="T:System.Threading.OperationCanceledException"><paramref
/// name="cancellationToken"/> was canceled.</exception>
public bool Wait(int millisecondsTimeout, CancellationToken cancellationToken)
{
ThrowIfDisposed();
cancellationToken.ThrowIfCancellationRequested(); // an early convenience check
if (millisecondsTimeout < -1)
{
throw new ArgumentOutOfRangeException("millisecondsTimeout");
}
if (!IsSet)
{
if (millisecondsTimeout == 0)
{
// For 0-timeouts, we just return immediately.
return(false);
}
// We spin briefly before falling back to allocating and/or waiting on a true event.
uint startTime = 0;
bool bNeedTimeoutAdjustment = false;
int realMillisecondsTimeout = millisecondsTimeout; //this will be adjusted if necessary.
if (millisecondsTimeout != Timeout.Infinite)
{
// We will account for time spent spinning, so that we can decrement it from our
// timeout. In most cases the time spent in this section will be negligible. But
// we can't discount the possibility of our thread being switched out for a lengthy
// period of time. The timeout adjustments only take effect when and if we actually
// decide to block in the kernel below.
startTime = TimeoutHelper.GetTime();
bNeedTimeoutAdjustment = true;
}
//spin
int HOW_MANY_SPIN_BEFORE_YIELD = 10;
int HOW_MANY_YIELD_EVERY_SLEEP_0 = 5;
int HOW_MANY_YIELD_EVERY_SLEEP_1 = 20;
int spinCount = SpinCount;
for (int i = 0; i < spinCount; i++)
{
if (IsSet)
{
return(true);
}
else if (i < HOW_MANY_SPIN_BEFORE_YIELD)
{
if (i == HOW_MANY_SPIN_BEFORE_YIELD / 2)
{
SpinWait.Yield();
}
else
{
SpinWait.Spin(PlatformHelper.ProcessorCount * (4 << i));
}
}
else if (i % HOW_MANY_YIELD_EVERY_SLEEP_1 == 0)
{
Helpers.Sleep(1);
}
else if (i % HOW_MANY_YIELD_EVERY_SLEEP_0 == 0)
{
Helpers.Sleep(0);
}
else
{
SpinWait.Yield();
}
if (i >= 100 && i % 10 == 0) // check the cancellation token if the user passed a very large spin count
{
cancellationToken.ThrowIfCancellationRequested();
}
}
// Now enter the lock and wait.
EnsureLockObjectCreated();
// We must register and deregister the token outside of the lock, to avoid deadlocks.
using (cancellationToken.InternalRegisterWithoutEC(s_cancellationTokenCallback, this))
{
using (LockHolder.Hold(m_lock))
{
// Loop to cope with spurious wakeups from other waits being canceled
while (!IsSet)
{
// If our token was canceled, we must throw and exit.
cancellationToken.ThrowIfCancellationRequested();
//update timeout (delays in wait commencement are due to spinning and/or spurious wakeups from other waits being canceled)
if (bNeedTimeoutAdjustment)
{
realMillisecondsTimeout = TimeoutHelper.UpdateTimeOut(startTime, millisecondsTimeout);
if (realMillisecondsTimeout <= 0)
{
return(false);
}
}
// There is a race that Set will fail to see that there are waiters as Set does not take the lock,
// so after updating waiters, we must check IsSet again.
// Also, we must ensure there cannot be any reordering of the assignment to Waiters and the
// read from IsSet. This is guaranteed as Waiters{set;} involves an Interlocked.CompareExchange
// operation which provides a full memory barrier.
// If we see IsSet=false, then we are guaranteed that Set() will see that we are
// waiting and will pulse the monitor correctly.
Waiters = Waiters + 1;
if (IsSet) //This check must occur after updating Waiters.
{
Waiters--; //revert the increment.
return(true);
}
// Now finally perform the wait.
try
{
// ** the actual wait **
if (!m_condition.Wait(realMillisecondsTimeout))
{
return(false); //return immediately if the timeout has expired.
}
}
finally
{
// Clean up: we're done waiting.
Waiters = Waiters - 1;
}
// Now just loop back around, and the right thing will happen. Either:
// 1. We had a spurious wake-up due to some other wait being canceled via a different cancellationToken (rewait)
// or 2. the wait was successful. (the loop will break)
}
}
}
} // automatically disposes (and deregisters) the callback
return(true); //done. The wait was satisfied.
}
