/// <summary>
/// Schedule 'callback' to be called in the next GC. If the callback returns true it is
/// rescheduled for the next Gen 2 GC. Otherwise the callbacks stop.
///
/// NOTE: This callback will be kept alive until either the callback function returns false,
/// or the target object dies.
/// </summary>
public static void Register(Func <object, bool> callback, object targetObj)
{
// Create a unreachable object that remembers the callback function and target object.
Gen2GcCallback gcCallback = new Gen2GcCallback();
gcCallback.Setup(callback, targetObj);
}
private void Restock(out object returnBuffer)
{
lock (this)
{
if (!this.m_FreeList.TryPop(out returnBuffer))
{
if (this.m_restockSize == 0)
{
Gen2GcCallback.Register(new Func <object, bool>(PinnableBufferCache.Gen2GcCallbackFunc), this);
}
this.m_moreThanFreeListNeeded = true;
PinnableBufferCacheEventSource.Log.AllocateBufferFreeListEmpty(this.m_CacheName, this.m_NotGen2.Count);
if (this.m_NotGen2.Count == 0)
{
this.CreateNewBuffers();
}
int index = this.m_NotGen2.Count - 1;
if (GC.GetGeneration(this.m_NotGen2[index]) < GC.MaxGeneration && GC.GetGeneration(this.m_NotGen2[0]) == GC.MaxGeneration)
{
index = 0;
}
returnBuffer = this.m_NotGen2[index];
this.m_NotGen2.RemoveAt(index);
if (PinnableBufferCacheEventSource.Log.IsEnabled() && GC.GetGeneration(returnBuffer) < GC.MaxGeneration)
{
PinnableBufferCacheEventSource.Log.AllocateBufferFromNotGen2(this.m_CacheName, this.m_NotGen2.Count);
}
if (!this.AgePendingBuffers() && this.m_NotGen2.Count == this.m_restockSize / 2)
{
PinnableBufferCacheEventSource.Log.DebugMessage("Proactively adding more buffers to aging pool");
this.CreateNewBuffers();
}
}
}
}
/// <summary>
/// Called when we don't have any buffers in our free list to give out.
/// </summary>
/// <returns></returns>
private void Restock(out object returnBuffer)
{
lock (this)
{
// Try again after getting the lock as another thread could have just filled the free list. If we don't check
// then we unnecessarily grab a new set of buffers because we think we are out.
if (m_FreeList.TryPop(out returnBuffer))
{
return;
}
// Lazy init, Ask that TrimFreeListIfNeeded be called on every Gen 2 GC.
if (m_restockSize == 0)
{
Gen2GcCallback.Register(Gen2GcCallbackFunc, this);
}
// Indicate to the trimming policy that the free list is insufficent.
m_moreThanFreeListNeeded = true;
PinnableBufferCacheEventSource.Log.AllocateBufferFreeListEmpty(m_CacheName, m_NotGen2.Count);
// Get more buffers if needed.
if (m_NotGen2.Count == 0)
{
CreateNewBuffers();
}
// We have no buffers in the aged freelist, so get one from the newer list. Try to pick the best one.
// Debug.Assert(m_NotGen2.Count != 0);
int idx = m_NotGen2.Count - 1;
if (GC.GetGeneration(m_NotGen2[idx]) < GC.MaxGeneration && GC.GetGeneration(m_NotGen2[0]) == GC.MaxGeneration)
{
idx = 0;
}
returnBuffer = m_NotGen2[idx];
m_NotGen2.RemoveAt(idx);
// Remember any sub-optimial buffer so we don't put it on the free list when it gets freed.
if (PinnableBufferCacheEventSource.Log.IsEnabled() && GC.GetGeneration(returnBuffer) < GC.MaxGeneration)
{
PinnableBufferCacheEventSource.Log.AllocateBufferFromNotGen2(m_CacheName, m_NotGen2.Count);
}
// If we have a Gen1 collection, then everything on m_NotGen2 should have aged. Move them to the m_Free list.
if (!AgePendingBuffers())
{
// Before we could age at set of buffers, we have handed out half of them.
// This implies we should be proactive about allocating more (since we will trim them if we over-allocate).
if (m_NotGen2.Count == m_restockSize / 2)
{
PinnableBufferCacheEventSource.Log.DebugMessage("Proactively adding more buffers to aging pool");
CreateNewBuffers();
}
}
}
}
// Token: 0x06003BB7 RID: 15287 RVA: 0x000E1148 File Offset: 0x000DF348
public static void Register(Func <object, bool> callback, object targetObj)
{
Gen2GcCallback gen2GcCallback = new Gen2GcCallback();
gen2GcCallback.Setup(callback, targetObj);
}
private static void GateThreadStart()
{
bool disableStarvationDetection =
AppContextConfigHelper.GetBooleanConfig("System.Threading.ThreadPool.DisableStarvationDetection", false);
bool debuggerBreakOnWorkStarvation =
AppContextConfigHelper.GetBooleanConfig("System.Threading.ThreadPool.DebugBreakOnWorkerStarvation", false);
// The first reading is over a time range other than what we are focusing on, so we do not use the read other
// than to send it to any runtime-specific implementation that may also use the CPU utilization.
CpuUtilizationReader cpuUtilizationReader = default;
_ = cpuUtilizationReader.CurrentUtilization;
PortableThreadPool threadPoolInstance = ThreadPoolInstance;
LowLevelLock threadAdjustmentLock = threadPoolInstance._threadAdjustmentLock;
DelayHelper delayHelper = default;
if (BlockingConfig.IsCooperativeBlockingEnabled)
{
// Initialize memory usage and limits, and register to update them on gen 2 GCs
threadPoolInstance.OnGen2GCCallback();
Gen2GcCallback.Register(threadPoolInstance.OnGen2GCCallback);
}
while (true)
{
RunGateThreadEvent.WaitOne();
int currentTimeMs = Environment.TickCount;
delayHelper.SetGateActivitiesTime(currentTimeMs);
while (true)
{
bool wasSignaledToWake = DelayEvent.WaitOne((int)delayHelper.GetNextDelay(currentTimeMs));
currentTimeMs = Environment.TickCount;
// Thread count adjustment for cooperative blocking
do
{
PendingBlockingAdjustment pendingBlockingAdjustment = threadPoolInstance._pendingBlockingAdjustment;
if (pendingBlockingAdjustment == PendingBlockingAdjustment.None)
{
delayHelper.ClearBlockingAdjustmentDelay();
break;
}
bool previousDelayElapsed = false;
if (delayHelper.HasBlockingAdjustmentDelay)
{
previousDelayElapsed =
delayHelper.HasBlockingAdjustmentDelayElapsed(currentTimeMs, wasSignaledToWake);
if (pendingBlockingAdjustment == PendingBlockingAdjustment.WithDelayIfNecessary &&
!previousDelayElapsed)
{
break;
}
}
uint nextDelayMs = threadPoolInstance.PerformBlockingAdjustment(previousDelayElapsed);
if (nextDelayMs <= 0)
{
delayHelper.ClearBlockingAdjustmentDelay();
}
else
{
delayHelper.SetBlockingAdjustmentTimeAndDelay(currentTimeMs, nextDelayMs);
}
} while (false);
//
// Periodic gate activities
//
if (!delayHelper.ShouldPerformGateActivities(currentTimeMs, wasSignaledToWake))
{
continue;
}
if (ThreadPool.EnableWorkerTracking && NativeRuntimeEventSource.Log.IsEnabled())
{
NativeRuntimeEventSource.Log.ThreadPoolWorkingThreadCount(
(uint)threadPoolInstance.GetAndResetHighWatermarkCountOfThreadsProcessingUserCallbacks());
}
int cpuUtilization = cpuUtilizationReader.CurrentUtilization;
threadPoolInstance._cpuUtilization = cpuUtilization;
bool needGateThreadForRuntime = ThreadPool.PerformRuntimeSpecificGateActivities(cpuUtilization);
if (!disableStarvationDetection &&
threadPoolInstance._pendingBlockingAdjustment == PendingBlockingAdjustment.None &&
threadPoolInstance._separated.numRequestedWorkers > 0 &&
SufficientDelaySinceLastDequeue(threadPoolInstance))
{
bool addWorker = false;
threadAdjustmentLock.Acquire();
try
{
// Don't add a thread if we're at max or if we are already in the process of adding threads.
// This logic is slightly different from the native implementation in CoreCLR because there are
// no retired threads. In the native implementation, when hill climbing reduces the thread count
// goal, threads that are stopped from processing work are switched to "retired" state, and they
// don't count towards the equivalent existing thread count. In this implementation, the
// existing thread count includes any worker thread that has not yet exited, including those
// stopped from working by hill climbing, so here the number of threads processing work, instead
// of the number of existing threads, is compared with the goal. There may be alternative
// solutions, for now this is only to maintain consistency in behavior.
ThreadCounts counts = threadPoolInstance._separated.counts;
if (counts.NumProcessingWork < threadPoolInstance._maxThreads &&
counts.NumProcessingWork >= threadPoolInstance._separated.numThreadsGoal)
{
if (debuggerBreakOnWorkStarvation)
{
Debugger.Break();
}
short newNumThreadsGoal = (short)(counts.NumProcessingWork + 1);
threadPoolInstance._separated.numThreadsGoal = newNumThreadsGoal;
HillClimbing.ThreadPoolHillClimber.ForceChange(
newNumThreadsGoal,
HillClimbing.StateOrTransition.Starvation);
addWorker = true;
}
}
finally
{
threadAdjustmentLock.Release();
}
if (addWorker)
{
WorkerThread.MaybeAddWorkingWorker(threadPoolInstance);
}
}
if (!needGateThreadForRuntime &&
threadPoolInstance._separated.numRequestedWorkers <= 0 &&
threadPoolInstance._pendingBlockingAdjustment == PendingBlockingAdjustment.None &&
Interlocked.Decrement(ref threadPoolInstance._separated.gateThreadRunningState) <= GetRunningStateForNumRuns(0))
{
break;
}
}
}
}
