forked from Mirror/Ryujinx
5131b71437
* add RecyclableMemoryStream dependency and MemoryStreamManager * organize BinaryReader/BinaryWriter extensions * add StreamExtensions to reduce need for BinaryWriter * simple replacments of MemoryStream with RecyclableMemoryStream * add write ReadOnlySequence<byte> support to IVirtualMemoryManager * avoid 0-length array creation * rework IpcMessage and related types to greatly reduce memory allocation by using RecylableMemoryStream, keeping streams around longer, avoiding their creation when possible, and avoiding creation of BinaryReader and BinaryWriter when possible * reduce LINQ-induced memory allocations with custom methods to query KPriorityQueue * use RecyclableMemoryStream in StreamUtils, and use StreamUtils in EmbeddedResources * add constants for nanosecond/millisecond conversions * code formatting * XML doc adjustments * fix: StreamExtension.WriteByte not writing non-zero values for lengths <= 16 * XML Doc improvements. Implement StreamExtensions.WriteByte() block writes for large-enough count values. * add copyless path for StreamExtension.Write(ReadOnlySpan<int>) * add default implementation of IVirtualMemoryManager.Write(ulong, ReadOnlySequence<byte>); remove previous explicit implementations * code style fixes * remove LINQ completely from KScheduler/KPriorityQueue by implementing a custom struct-based enumerator
138 lines
No EOL
4 KiB
C#
138 lines
No EOL
4 KiB
C#
using Ryujinx.HLE.HOS.Kernel.Common;
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using Ryujinx.Horizon.Common;
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using System;
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using System.Collections.Generic;
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namespace Ryujinx.HLE.HOS.Kernel.Threading
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{
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class KSynchronization
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{
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private KernelContext _context;
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public KSynchronization(KernelContext context)
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{
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_context = context;
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}
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public Result WaitFor(Span<KSynchronizationObject> syncObjs, long timeout, out int handleIndex)
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{
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handleIndex = 0;
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Result result = KernelResult.TimedOut;
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_context.CriticalSection.Enter();
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// Check if objects are already signaled before waiting.
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for (int index = 0; index < syncObjs.Length; index++)
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{
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if (!syncObjs[index].IsSignaled())
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{
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continue;
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}
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handleIndex = index;
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_context.CriticalSection.Leave();
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return Result.Success;
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}
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if (timeout == 0)
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{
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_context.CriticalSection.Leave();
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return result;
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}
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KThread currentThread = KernelStatic.GetCurrentThread();
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if (currentThread.ShallBeTerminated ||
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currentThread.SchedFlags == ThreadSchedState.TerminationPending)
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{
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result = KernelResult.ThreadTerminating;
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}
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else if (currentThread.SyncCancelled)
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{
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currentThread.SyncCancelled = false;
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result = KernelResult.Cancelled;
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}
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else
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{
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LinkedListNode<KThread>[] syncNodes = syncObjs.Length == 0 ? Array.Empty<LinkedListNode<KThread>>() : new LinkedListNode<KThread>[syncObjs.Length];
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for (int index = 0; index < syncObjs.Length; index++)
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{
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syncNodes[index] = syncObjs[index].AddWaitingThread(currentThread);
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}
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currentThread.WaitingSync = true;
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currentThread.SignaledObj = null;
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currentThread.ObjSyncResult = result;
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currentThread.Reschedule(ThreadSchedState.Paused);
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if (timeout > 0)
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{
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_context.TimeManager.ScheduleFutureInvocation(currentThread, timeout);
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}
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_context.CriticalSection.Leave();
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currentThread.WaitingSync = false;
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if (timeout > 0)
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{
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_context.TimeManager.UnscheduleFutureInvocation(currentThread);
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}
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_context.CriticalSection.Enter();
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result = currentThread.ObjSyncResult;
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handleIndex = -1;
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for (int index = 0; index < syncObjs.Length; index++)
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{
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syncObjs[index].RemoveWaitingThread(syncNodes[index]);
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if (syncObjs[index] == currentThread.SignaledObj)
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{
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handleIndex = index;
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}
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}
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}
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_context.CriticalSection.Leave();
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return result;
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}
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public void SignalObject(KSynchronizationObject syncObj)
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{
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_context.CriticalSection.Enter();
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if (syncObj.IsSignaled())
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{
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LinkedListNode<KThread> node = syncObj.WaitingThreads.First;
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while (node != null)
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{
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KThread thread = node.Value;
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if ((thread.SchedFlags & ThreadSchedState.LowMask) == ThreadSchedState.Paused)
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{
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thread.SignaledObj = syncObj;
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thread.ObjSyncResult = Result.Success;
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thread.Reschedule(ThreadSchedState.Running);
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}
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node = node.Next;
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}
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}
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_context.CriticalSection.Leave();
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}
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}
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} |