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Ryujinx/Ryujinx.HLE/HOS/Kernel/KThread.cs
Alex Barney 9cb57fb4bb Adjust naming conventions for Ryujinx and ChocolArm64 projects (#484)
* Change naming convention for Ryujinx project

* Change naming convention for ChocolArm64 project

* Fix NaN

* Remove unneeded this. from Ryujinx project

* Adjust naming from new PRs

* Name changes based on feedback

* How did this get removed?

* Rebasing fix

* Change FP enum case

* Remove prefix from ChocolArm64 classes - Part 1

* Remove prefix from ChocolArm64 classes - Part 2

* Fix alignment from last commit's renaming

* Rename namespaces

* Rename stragglers

* Fix alignment

* Rename OpCode class

* Missed a few

* Adjust alignment
2018-10-30 22:43:02 -03:00

883 lines
No EOL
26 KiB
C#

using ChocolArm64;
using System;
using System.Collections.Generic;
using System.Linq;
using static Ryujinx.HLE.HOS.ErrorCode;
namespace Ryujinx.HLE.HOS.Kernel
{
class KThread : KSynchronizationObject, IKFutureSchedulerObject
{
public CpuThread Context { get; private set; }
public long AffinityMask { get; set; }
public int ThreadId { get; private set; }
public KSynchronizationObject SignaledObj;
public long CondVarAddress { get; set; }
public long MutexAddress { get; set; }
public Process Owner { get; private set; }
public long LastScheduledTicks { get; set; }
public LinkedListNode<KThread>[] SiblingsPerCore { get; private set; }
private LinkedListNode<KThread> WithholderNode;
private LinkedList<KThread> MutexWaiters;
private LinkedListNode<KThread> MutexWaiterNode;
public KThread MutexOwner { get; private set; }
public int ThreadHandleForUserMutex { get; set; }
private ThreadSchedState ForcePauseFlags;
public int ObjSyncResult { get; set; }
public int DynamicPriority { get; set; }
public int CurrentCore { get; set; }
public int BasePriority { get; set; }
public int PreferredCore { get; set; }
private long AffinityMaskOverride;
private int PreferredCoreOverride;
private int AffinityOverrideCount;
public ThreadSchedState SchedFlags { get; private set; }
public bool ShallBeTerminated { get; private set; }
public bool SyncCancelled { get; set; }
public bool WaitingSync { get; set; }
private bool HasExited;
public bool WaitingInArbitration { get; set; }
private KScheduler Scheduler;
private KSchedulingData SchedulingData;
public long LastPc { get; set; }
public KThread(
CpuThread Thread,
Process Process,
Horizon System,
int ProcessorId,
int Priority,
int ThreadId) : base(System)
{
this.ThreadId = ThreadId;
Context = Thread;
Owner = Process;
PreferredCore = ProcessorId;
Scheduler = System.Scheduler;
SchedulingData = System.Scheduler.SchedulingData;
SiblingsPerCore = new LinkedListNode<KThread>[KScheduler.CpuCoresCount];
MutexWaiters = new LinkedList<KThread>();
AffinityMask = 1 << ProcessorId;
DynamicPriority = BasePriority = Priority;
CurrentCore = PreferredCore;
}
public long Start()
{
long Result = MakeError(ErrorModule.Kernel, KernelErr.ThreadTerminating);
System.CriticalSectionLock.Lock();
if (!ShallBeTerminated)
{
KThread CurrentThread = System.Scheduler.GetCurrentThread();
while (SchedFlags != ThreadSchedState.TerminationPending &&
CurrentThread.SchedFlags != ThreadSchedState.TerminationPending &&
!CurrentThread.ShallBeTerminated)
{
if ((SchedFlags & ThreadSchedState.LowNibbleMask) != ThreadSchedState.None)
{
Result = MakeError(ErrorModule.Kernel, KernelErr.InvalidState);
break;
}
if (CurrentThread.ForcePauseFlags == ThreadSchedState.None)
{
if (Owner != null && ForcePauseFlags != ThreadSchedState.None)
{
CombineForcePauseFlags();
}
SetNewSchedFlags(ThreadSchedState.Running);
Result = 0;
break;
}
else
{
CurrentThread.CombineForcePauseFlags();
System.CriticalSectionLock.Unlock();
System.CriticalSectionLock.Lock();
if (CurrentThread.ShallBeTerminated)
{
break;
}
}
}
}
System.CriticalSectionLock.Unlock();
return Result;
}
public void Exit()
{
System.CriticalSectionLock.Lock();
ForcePauseFlags &= ~ThreadSchedState.ExceptionalMask;
ExitImpl();
System.CriticalSectionLock.Unlock();
}
private void ExitImpl()
{
System.CriticalSectionLock.Lock();
SetNewSchedFlags(ThreadSchedState.TerminationPending);
HasExited = true;
Signal();
System.CriticalSectionLock.Unlock();
}
public long Sleep(long Timeout)
{
System.CriticalSectionLock.Lock();
if (ShallBeTerminated || SchedFlags == ThreadSchedState.TerminationPending)
{
System.CriticalSectionLock.Unlock();
return MakeError(ErrorModule.Kernel, KernelErr.ThreadTerminating);
}
SetNewSchedFlags(ThreadSchedState.Paused);
if (Timeout > 0)
{
System.TimeManager.ScheduleFutureInvocation(this, Timeout);
}
System.CriticalSectionLock.Unlock();
if (Timeout > 0)
{
System.TimeManager.UnscheduleFutureInvocation(this);
}
return 0;
}
public void Yield()
{
System.CriticalSectionLock.Lock();
if (SchedFlags != ThreadSchedState.Running)
{
System.CriticalSectionLock.Unlock();
System.Scheduler.ContextSwitch();
return;
}
if (DynamicPriority < KScheduler.PrioritiesCount)
{
//Move current thread to the end of the queue.
SchedulingData.Reschedule(DynamicPriority, CurrentCore, this);
}
Scheduler.ThreadReselectionRequested = true;
System.CriticalSectionLock.Unlock();
System.Scheduler.ContextSwitch();
}
public void YieldWithLoadBalancing()
{
System.CriticalSectionLock.Lock();
int Prio = DynamicPriority;
int Core = CurrentCore;
if (SchedFlags != ThreadSchedState.Running)
{
System.CriticalSectionLock.Unlock();
System.Scheduler.ContextSwitch();
return;
}
KThread NextThreadOnCurrentQueue = null;
if (DynamicPriority < KScheduler.PrioritiesCount)
{
//Move current thread to the end of the queue.
SchedulingData.Reschedule(Prio, Core, this);
Func<KThread, bool> Predicate = x => x.DynamicPriority == Prio;
NextThreadOnCurrentQueue = SchedulingData.ScheduledThreads(Core).FirstOrDefault(Predicate);
}
IEnumerable<KThread> SuitableCandidates()
{
foreach (KThread Thread in SchedulingData.SuggestedThreads(Core))
{
int SrcCore = Thread.CurrentCore;
if (SrcCore >= 0)
{
KThread SelectedSrcCore = Scheduler.CoreContexts[SrcCore].SelectedThread;
if (SelectedSrcCore == Thread || ((SelectedSrcCore?.DynamicPriority ?? 2) < 2))
{
continue;
}
}
//If the candidate was scheduled after the current thread, then it's not worth it,
//unless the priority is higher than the current one.
if (NextThreadOnCurrentQueue.LastScheduledTicks >= Thread.LastScheduledTicks ||
NextThreadOnCurrentQueue.DynamicPriority < Thread.DynamicPriority)
{
yield return Thread;
}
}
}
KThread Dst = SuitableCandidates().FirstOrDefault(x => x.DynamicPriority <= Prio);
if (Dst != null)
{
SchedulingData.TransferToCore(Dst.DynamicPriority, Core, Dst);
Scheduler.ThreadReselectionRequested = true;
}
if (this != NextThreadOnCurrentQueue)
{
Scheduler.ThreadReselectionRequested = true;
}
System.CriticalSectionLock.Unlock();
System.Scheduler.ContextSwitch();
}
public void YieldAndWaitForLoadBalancing()
{
System.CriticalSectionLock.Lock();
if (SchedFlags != ThreadSchedState.Running)
{
System.CriticalSectionLock.Unlock();
System.Scheduler.ContextSwitch();
return;
}
int Core = CurrentCore;
SchedulingData.TransferToCore(DynamicPriority, -1, this);
KThread SelectedThread = null;
if (!SchedulingData.ScheduledThreads(Core).Any())
{
foreach (KThread Thread in SchedulingData.SuggestedThreads(Core))
{
if (Thread.CurrentCore < 0)
{
continue;
}
KThread FirstCandidate = SchedulingData.ScheduledThreads(Thread.CurrentCore).FirstOrDefault();
if (FirstCandidate == Thread)
{
continue;
}
if (FirstCandidate == null || FirstCandidate.DynamicPriority >= 2)
{
SchedulingData.TransferToCore(Thread.DynamicPriority, Core, Thread);
SelectedThread = Thread;
}
break;
}
}
if (SelectedThread != this)
{
Scheduler.ThreadReselectionRequested = true;
}
System.CriticalSectionLock.Unlock();
System.Scheduler.ContextSwitch();
}
public void SetPriority(int Priority)
{
System.CriticalSectionLock.Lock();
BasePriority = Priority;
UpdatePriorityInheritance();
System.CriticalSectionLock.Unlock();
}
public long SetActivity(bool Pause)
{
long Result = 0;
System.CriticalSectionLock.Lock();
ThreadSchedState LowNibble = SchedFlags & ThreadSchedState.LowNibbleMask;
if (LowNibble != ThreadSchedState.Paused && LowNibble != ThreadSchedState.Running)
{
System.CriticalSectionLock.Unlock();
return MakeError(ErrorModule.Kernel, KernelErr.InvalidState);
}
System.CriticalSectionLock.Lock();
if (!ShallBeTerminated && SchedFlags != ThreadSchedState.TerminationPending)
{
if (Pause)
{
//Pause, the force pause flag should be clear (thread is NOT paused).
if ((ForcePauseFlags & ThreadSchedState.ForcePauseFlag) == 0)
{
ForcePauseFlags |= ThreadSchedState.ForcePauseFlag;
CombineForcePauseFlags();
}
else
{
Result = MakeError(ErrorModule.Kernel, KernelErr.InvalidState);
}
}
else
{
//Unpause, the force pause flag should be set (thread is paused).
if ((ForcePauseFlags & ThreadSchedState.ForcePauseFlag) != 0)
{
ThreadSchedState OldForcePauseFlags = ForcePauseFlags;
ForcePauseFlags &= ~ThreadSchedState.ForcePauseFlag;
if ((OldForcePauseFlags & ~ThreadSchedState.ForcePauseFlag) == ThreadSchedState.None)
{
ThreadSchedState OldSchedFlags = SchedFlags;
SchedFlags &= ThreadSchedState.LowNibbleMask;
AdjustScheduling(OldSchedFlags);
}
}
else
{
Result = MakeError(ErrorModule.Kernel, KernelErr.InvalidState);
}
}
}
System.CriticalSectionLock.Unlock();
System.CriticalSectionLock.Unlock();
return Result;
}
public void CancelSynchronization()
{
System.CriticalSectionLock.Lock();
if ((SchedFlags & ThreadSchedState.LowNibbleMask) != ThreadSchedState.Paused || !WaitingSync)
{
SyncCancelled = true;
}
else if (WithholderNode != null)
{
System.Withholders.Remove(WithholderNode);
SetNewSchedFlags(ThreadSchedState.Running);
WithholderNode = null;
SyncCancelled = true;
}
else
{
SignaledObj = null;
ObjSyncResult = (int)MakeError(ErrorModule.Kernel, KernelErr.Cancelled);
SetNewSchedFlags(ThreadSchedState.Running);
SyncCancelled = false;
}
System.CriticalSectionLock.Unlock();
}
public long SetCoreAndAffinityMask(int NewCore, long NewAffinityMask)
{
System.CriticalSectionLock.Lock();
bool UseOverride = AffinityOverrideCount != 0;
//The value -3 is "do not change the preferred core".
if (NewCore == -3)
{
NewCore = UseOverride ? PreferredCoreOverride : PreferredCore;
if ((NewAffinityMask & (1 << NewCore)) == 0)
{
System.CriticalSectionLock.Unlock();
return MakeError(ErrorModule.Kernel, KernelErr.InvalidMaskValue);
}
}
if (UseOverride)
{
PreferredCoreOverride = NewCore;
AffinityMaskOverride = NewAffinityMask;
}
else
{
long OldAffinityMask = AffinityMask;
PreferredCore = NewCore;
AffinityMask = NewAffinityMask;
if (OldAffinityMask != NewAffinityMask)
{
int OldCore = CurrentCore;
if (CurrentCore >= 0 && ((AffinityMask >> CurrentCore) & 1) == 0)
{
if (PreferredCore < 0)
{
CurrentCore = HighestSetCore(AffinityMask);
}
else
{
CurrentCore = PreferredCore;
}
}
AdjustSchedulingForNewAffinity(OldAffinityMask, OldCore);
}
}
System.CriticalSectionLock.Unlock();
return 0;
}
private static int HighestSetCore(long Mask)
{
for (int Core = KScheduler.CpuCoresCount - 1; Core >= 0; Core--)
{
if (((Mask >> Core) & 1) != 0)
{
return Core;
}
}
return -1;
}
private void CombineForcePauseFlags()
{
ThreadSchedState OldFlags = SchedFlags;
ThreadSchedState LowNibble = SchedFlags & ThreadSchedState.LowNibbleMask;
SchedFlags = LowNibble | ForcePauseFlags;
AdjustScheduling(OldFlags);
}
private void SetNewSchedFlags(ThreadSchedState NewFlags)
{
System.CriticalSectionLock.Lock();
ThreadSchedState OldFlags = SchedFlags;
SchedFlags = (OldFlags & ThreadSchedState.HighNibbleMask) | NewFlags;
if ((OldFlags & ThreadSchedState.LowNibbleMask) != NewFlags)
{
AdjustScheduling(OldFlags);
}
System.CriticalSectionLock.Unlock();
}
public void ReleaseAndResume()
{
System.CriticalSectionLock.Lock();
if ((SchedFlags & ThreadSchedState.LowNibbleMask) == ThreadSchedState.Paused)
{
if (WithholderNode != null)
{
System.Withholders.Remove(WithholderNode);
SetNewSchedFlags(ThreadSchedState.Running);
WithholderNode = null;
}
else
{
SetNewSchedFlags(ThreadSchedState.Running);
}
}
System.CriticalSectionLock.Unlock();
}
public void Reschedule(ThreadSchedState NewFlags)
{
System.CriticalSectionLock.Lock();
ThreadSchedState OldFlags = SchedFlags;
SchedFlags = (OldFlags & ThreadSchedState.HighNibbleMask) |
(NewFlags & ThreadSchedState.LowNibbleMask);
AdjustScheduling(OldFlags);
System.CriticalSectionLock.Unlock();
}
public void AddMutexWaiter(KThread Requester)
{
AddToMutexWaitersList(Requester);
Requester.MutexOwner = this;
UpdatePriorityInheritance();
}
public void RemoveMutexWaiter(KThread Thread)
{
if (Thread.MutexWaiterNode?.List != null)
{
MutexWaiters.Remove(Thread.MutexWaiterNode);
}
Thread.MutexOwner = null;
UpdatePriorityInheritance();
}
public KThread RelinquishMutex(long MutexAddress, out int Count)
{
Count = 0;
if (MutexWaiters.First == null)
{
return null;
}
KThread NewMutexOwner = null;
LinkedListNode<KThread> CurrentNode = MutexWaiters.First;
do
{
//Skip all threads that are not waiting for this mutex.
while (CurrentNode != null && CurrentNode.Value.MutexAddress != MutexAddress)
{
CurrentNode = CurrentNode.Next;
}
if (CurrentNode == null)
{
break;
}
LinkedListNode<KThread> NextNode = CurrentNode.Next;
MutexWaiters.Remove(CurrentNode);
CurrentNode.Value.MutexOwner = NewMutexOwner;
if (NewMutexOwner != null)
{
//New owner was already selected, re-insert on new owner list.
NewMutexOwner.AddToMutexWaitersList(CurrentNode.Value);
}
else
{
//New owner not selected yet, use current thread.
NewMutexOwner = CurrentNode.Value;
}
Count++;
CurrentNode = NextNode;
}
while (CurrentNode != null);
if (NewMutexOwner != null)
{
UpdatePriorityInheritance();
NewMutexOwner.UpdatePriorityInheritance();
}
return NewMutexOwner;
}
private void UpdatePriorityInheritance()
{
//If any of the threads waiting for the mutex has
//higher priority than the current thread, then
//the current thread inherits that priority.
int HighestPriority = BasePriority;
if (MutexWaiters.First != null)
{
int WaitingDynamicPriority = MutexWaiters.First.Value.DynamicPriority;
if (WaitingDynamicPriority < HighestPriority)
{
HighestPriority = WaitingDynamicPriority;
}
}
if (HighestPriority != DynamicPriority)
{
int OldPriority = DynamicPriority;
DynamicPriority = HighestPriority;
AdjustSchedulingForNewPriority(OldPriority);
if (MutexOwner != null)
{
//Remove and re-insert to ensure proper sorting based on new priority.
MutexOwner.MutexWaiters.Remove(MutexWaiterNode);
MutexOwner.AddToMutexWaitersList(this);
MutexOwner.UpdatePriorityInheritance();
}
}
}
private void AddToMutexWaitersList(KThread Thread)
{
LinkedListNode<KThread> NextPrio = MutexWaiters.First;
int CurrentPriority = Thread.DynamicPriority;
while (NextPrio != null && NextPrio.Value.DynamicPriority <= CurrentPriority)
{
NextPrio = NextPrio.Next;
}
if (NextPrio != null)
{
Thread.MutexWaiterNode = MutexWaiters.AddBefore(NextPrio, Thread);
}
else
{
Thread.MutexWaiterNode = MutexWaiters.AddLast(Thread);
}
}
private void AdjustScheduling(ThreadSchedState OldFlags)
{
if (OldFlags == SchedFlags)
{
return;
}
if (OldFlags == ThreadSchedState.Running)
{
//Was running, now it's stopped.
if (CurrentCore >= 0)
{
SchedulingData.Unschedule(DynamicPriority, CurrentCore, this);
}
for (int Core = 0; Core < KScheduler.CpuCoresCount; Core++)
{
if (Core != CurrentCore && ((AffinityMask >> Core) & 1) != 0)
{
SchedulingData.Unsuggest(DynamicPriority, Core, this);
}
}
}
else if (SchedFlags == ThreadSchedState.Running)
{
//Was stopped, now it's running.
if (CurrentCore >= 0)
{
SchedulingData.Schedule(DynamicPriority, CurrentCore, this);
}
for (int Core = 0; Core < KScheduler.CpuCoresCount; Core++)
{
if (Core != CurrentCore && ((AffinityMask >> Core) & 1) != 0)
{
SchedulingData.Suggest(DynamicPriority, Core, this);
}
}
}
Scheduler.ThreadReselectionRequested = true;
}
private void AdjustSchedulingForNewPriority(int OldPriority)
{
if (SchedFlags != ThreadSchedState.Running)
{
return;
}
//Remove thread from the old priority queues.
if (CurrentCore >= 0)
{
SchedulingData.Unschedule(OldPriority, CurrentCore, this);
}
for (int Core = 0; Core < KScheduler.CpuCoresCount; Core++)
{
if (Core != CurrentCore && ((AffinityMask >> Core) & 1) != 0)
{
SchedulingData.Unsuggest(OldPriority, Core, this);
}
}
//Add thread to the new priority queues.
KThread CurrentThread = Scheduler.GetCurrentThread();
if (CurrentCore >= 0)
{
if (CurrentThread == this)
{
SchedulingData.SchedulePrepend(DynamicPriority, CurrentCore, this);
}
else
{
SchedulingData.Schedule(DynamicPriority, CurrentCore, this);
}
}
for (int Core = 0; Core < KScheduler.CpuCoresCount; Core++)
{
if (Core != CurrentCore && ((AffinityMask >> Core) & 1) != 0)
{
SchedulingData.Suggest(DynamicPriority, Core, this);
}
}
Scheduler.ThreadReselectionRequested = true;
}
private void AdjustSchedulingForNewAffinity(long OldAffinityMask, int OldCore)
{
if (SchedFlags != ThreadSchedState.Running || DynamicPriority >= KScheduler.PrioritiesCount)
{
return;
}
//Remove from old queues.
for (int Core = 0; Core < KScheduler.CpuCoresCount; Core++)
{
if (((OldAffinityMask >> Core) & 1) != 0)
{
if (Core == OldCore)
{
SchedulingData.Unschedule(DynamicPriority, Core, this);
}
else
{
SchedulingData.Unsuggest(DynamicPriority, Core, this);
}
}
}
//Insert on new queues.
for (int Core = 0; Core < KScheduler.CpuCoresCount; Core++)
{
if (((AffinityMask >> Core) & 1) != 0)
{
if (Core == CurrentCore)
{
SchedulingData.Schedule(DynamicPriority, Core, this);
}
else
{
SchedulingData.Suggest(DynamicPriority, Core, this);
}
}
}
Scheduler.ThreadReselectionRequested = true;
}
public override bool IsSignaled()
{
return HasExited;
}
public void ClearExclusive()
{
Owner.Memory.ClearExclusive(CurrentCore);
}
public void TimeUp()
{
System.CriticalSectionLock.Lock();
SetNewSchedFlags(ThreadSchedState.Running);
System.CriticalSectionLock.Unlock();
}
}
}