mirror of
https://github.com/reactos/reactos.git
synced 2024-11-01 12:26:32 +00:00
ab528ac6ae
Fixed in x86 and ARM (this was already done in x64).
This is needed because thread preparation routine KxQueueReadyThread()
releases PRCB lock, but does not acquire it, so that the locking must
always be done outside the function, same as in all its other usage cases.
This fixes an assert from release PRCB routine, when booting x86 ReactOS
in SMP mode, because it attempts to release the lock when it is not
actually acquired.
Addendum to commit a011d19ed
.
+ Add an assert in KxQueueReadyThread() to ensure the PRCB lock is actually acquired.
361 lines
9.2 KiB
C
361 lines
9.2 KiB
C
/*
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* PROJECT: ReactOS Kernel
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* LICENSE: BSD - See COPYING.ARM in the top level directory
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* FILE: ntoskrnl/ke/arm/thrdini.c
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* PURPOSE: Implements thread context setup and startup for ARM machines
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* PROGRAMMERS: ReactOS Portable Systems Group
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*/
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/* INCLUDES *******************************************************************/
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#include <ntoskrnl.h>
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#define NDEBUG
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#include <debug.h>
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/* GLOBALS ********************************************************************/
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typedef struct _KSWITCHFRAME
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{
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PVOID ExceptionList;
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BOOLEAN ApcBypassDisable;
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PVOID RetAddr;
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} KSWITCHFRAME, *PKSWITCHFRAME;
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typedef struct _KUINIT_FRAME
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{
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KEXCEPTION_FRAME CtxSwitchFrame;
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KEXCEPTION_FRAME ExceptionFrame;
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KTRAP_FRAME TrapFrame;
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} KUINIT_FRAME, *PKUINIT_FRAME;
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typedef struct _KKINIT_FRAME
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{
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KEXCEPTION_FRAME CtxSwitchFrame;
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} KKINIT_FRAME, *PKKINIT_FRAME;
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/* FUNCTIONS ******************************************************************/
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VOID
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NTAPI
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KiThreadStartup(VOID);
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VOID
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FASTCALL
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KiSwitchThreads(
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IN PKTHREAD OldThread,
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IN PKTHREAD NewThread
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);
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/* FIXME: THIS IS TOTALLY BUSTED NOW */
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VOID
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NTAPI
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KiInitializeContextThread(IN PKTHREAD Thread,
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IN PKSYSTEM_ROUTINE SystemRoutine,
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IN PKSTART_ROUTINE StartRoutine,
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IN PVOID StartContext,
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IN PCONTEXT ContextPointer)
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{
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PKTRAP_FRAME TrapFrame;
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PKEXCEPTION_FRAME ExceptionFrame = NULL, CtxSwitchFrame;
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//
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// Check if this is a user thread
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//
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if (ContextPointer)
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{
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//
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// Setup the initial frame
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//
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PKUINIT_FRAME InitFrame;
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InitFrame = (PKUINIT_FRAME)((ULONG_PTR)Thread->InitialStack -
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sizeof(KUINIT_FRAME));
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//
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// Setup the Trap Frame and Exception frame
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//
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TrapFrame = &InitFrame->TrapFrame;
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ExceptionFrame = &InitFrame->ExceptionFrame;
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///
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// Zero out the trap frame and exception frame
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//
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RtlZeroMemory(TrapFrame, sizeof(KTRAP_FRAME));
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RtlZeroMemory(ExceptionFrame, sizeof(KEXCEPTION_FRAME));
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//
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// Set up a trap frame from the context
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//
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KeContextToTrapFrame(ContextPointer,
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ExceptionFrame,
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TrapFrame,
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ContextPointer->ContextFlags | CONTEXT_CONTROL,
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UserMode);
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//
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// Set the previous mode as user
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//
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//TrapFrame->PreviousMode = UserMode;
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Thread->PreviousMode = UserMode;
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//
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// Clear the return address
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//
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ExceptionFrame->Return = 0;
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//
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// Context switch frame to setup below
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//
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CtxSwitchFrame = &InitFrame->CtxSwitchFrame;
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}
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else
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{
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//
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// Set up the Initial Frame for the system thread
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//
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PKKINIT_FRAME InitFrame;
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InitFrame = (PKKINIT_FRAME)((ULONG_PTR)Thread->InitialStack -
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sizeof(KKINIT_FRAME));
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//
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// Set the previous mode as kernel
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//
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Thread->PreviousMode = KernelMode;
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//
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// Context switch frame to setup below
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//
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CtxSwitchFrame = &InitFrame->CtxSwitchFrame;
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}
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//
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// Now setup the context switch frame
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//
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CtxSwitchFrame->Return = (ULONG)KiThreadStartup;
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CtxSwitchFrame->R11 = (ULONG)(ExceptionFrame ? ExceptionFrame : CtxSwitchFrame);
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//
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// Set the parameters
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//
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CtxSwitchFrame->R4 = (ULONG)ContextPointer;
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CtxSwitchFrame->R5 = (ULONG)StartContext;
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CtxSwitchFrame->R6 = (ULONG)StartRoutine;
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CtxSwitchFrame->R7 = (ULONG)SystemRoutine;
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//
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// Save back the new value of the kernel stack
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//
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Thread->KernelStack = (PVOID)CtxSwitchFrame;
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}
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DECLSPEC_NORETURN
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VOID
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KiIdleLoop(VOID)
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{
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PKPRCB Prcb = KeGetCurrentPrcb();
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PKTHREAD OldThread, NewThread;
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/* Now loop forever */
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while (TRUE)
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{
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/* Start of the idle loop: disable interrupts */
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_enable();
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YieldProcessor();
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YieldProcessor();
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_disable();
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/* Check for pending timers, pending DPCs, or pending ready threads */
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if ((Prcb->DpcData[0].DpcQueueDepth) ||
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(Prcb->TimerRequest) ||
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(Prcb->DeferredReadyListHead.Next))
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{
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/* Quiesce the DPC software interrupt */
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HalClearSoftwareInterrupt(DISPATCH_LEVEL);
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/* Handle it */
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KiRetireDpcList(Prcb);
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}
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/* Check if a new thread is scheduled for execution */
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if (Prcb->NextThread)
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{
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/* Enable interrupts */
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_enable();
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/* Capture current thread data */
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OldThread = Prcb->CurrentThread;
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NewThread = Prcb->NextThread;
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/* Set new thread data */
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Prcb->NextThread = NULL;
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Prcb->CurrentThread = NewThread;
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/* The thread is now running */
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NewThread->State = Running;
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#ifdef CONFIG_SMP
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/* Do the swap at SYNCH_LEVEL */
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KfRaiseIrql(SYNCH_LEVEL);
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#endif
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/* Switch away from the idle thread */
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KiSwapContext(APC_LEVEL, OldThread);
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#ifdef CONFIG_SMP
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/* Go back to DISPATCH_LEVEL */
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KeLowerIrql(DISPATCH_LEVEL);
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#endif
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}
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else
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{
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/* Continue staying idle. Note the HAL returns with interrupts on */
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Prcb->PowerState.IdleFunction(&Prcb->PowerState);
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}
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}
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}
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BOOLEAN
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FASTCALL
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KiSwapContextExit(IN PKTHREAD OldThread,
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IN PKSWITCHFRAME SwitchFrame)
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{
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PKIPCR Pcr = (PKIPCR)KeGetPcr();
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PKPROCESS OldProcess, NewProcess;
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PKTHREAD NewThread;
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ARM_TTB_REGISTER TtbRegister;
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/* We are on the new thread stack now */
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NewThread = Pcr->Prcb.CurrentThread;
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/* Now we are the new thread. Check if it's in a new process */
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OldProcess = OldThread->ApcState.Process;
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NewProcess = NewThread->ApcState.Process;
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if (OldProcess != NewProcess)
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{
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TtbRegister.AsUlong = NewProcess->DirectoryTableBase[0];
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ASSERT(TtbRegister.Reserved == 0);
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KeArmTranslationTableRegisterSet(TtbRegister);
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}
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/* Increase thread context switches */
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NewThread->ContextSwitches++;
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/* DPCs shouldn't be active */
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if (Pcr->Prcb.DpcRoutineActive)
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{
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/* Crash the machine */
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KeBugCheckEx(ATTEMPTED_SWITCH_FROM_DPC,
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(ULONG_PTR)OldThread,
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(ULONG_PTR)NewThread,
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(ULONG_PTR)OldThread->InitialStack,
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0);
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}
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/* Kernel APCs may be pending */
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if (NewThread->ApcState.KernelApcPending)
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{
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/* Are APCs enabled? */
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if (!NewThread->SpecialApcDisable)
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{
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/* Request APC delivery */
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if (SwitchFrame->ApcBypassDisable) HalRequestSoftwareInterrupt(APC_LEVEL);
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return TRUE;
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}
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}
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/* Return */
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return FALSE;
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}
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VOID
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FASTCALL
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KiSwapContextEntry(IN PKSWITCHFRAME SwitchFrame,
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IN ULONG_PTR OldThreadAndApcFlag)
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{
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PKIPCR Pcr = (PKIPCR)KeGetPcr();
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PKTHREAD OldThread, NewThread;
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/* Save APC bypass disable */
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SwitchFrame->ApcBypassDisable = OldThreadAndApcFlag & 3;
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/* Increase context switch count and check if tracing is enabled */
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Pcr->Prcb.KeContextSwitches++;
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#if 0
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if (Pcr->PerfGlobalGroupMask)
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{
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/* We don't support this yet on x86 either */
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DPRINT1("WMI Tracing not supported\n");
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ASSERT(FALSE);
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}
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#endif // 0
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/* Get thread pointers */
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OldThread = (PKTHREAD)(OldThreadAndApcFlag & ~3);
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NewThread = Pcr->Prcb.CurrentThread;
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/* Get the old thread and set its kernel stack */
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OldThread->KernelStack = SwitchFrame;
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/* Do the switch */
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KiSwitchThreads(OldThread, NewThread->KernelStack);
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}
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VOID
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NTAPI
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KiDispatchInterrupt(VOID)
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{
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PKIPCR Pcr = (PKIPCR)KeGetPcr();
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PKPRCB Prcb = &Pcr->Prcb;
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PKTHREAD NewThread, OldThread;
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/* Disable interrupts */
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_disable();
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/* Check for pending timers, pending DPCs, or pending ready threads */
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if ((Prcb->DpcData[0].DpcQueueDepth) ||
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(Prcb->TimerRequest) ||
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(Prcb->DeferredReadyListHead.Next))
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{
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/* Retire DPCs while under the DPC stack */
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//KiRetireDpcListInDpcStack(Prcb, Prcb->DpcStack);
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// FIXME!!! //
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KiRetireDpcList(Prcb);
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}
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/* Re-enable interrupts */
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_enable();
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/* Check for quantum end */
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if (Prcb->QuantumEnd)
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{
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/* Handle quantum end */
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Prcb->QuantumEnd = FALSE;
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KiQuantumEnd();
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}
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else if (Prcb->NextThread)
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{
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/* Acquire the PRCB lock */
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KiAcquirePrcbLock(Prcb);
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/* Capture current thread data */
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OldThread = Prcb->CurrentThread;
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NewThread = Prcb->NextThread;
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/* Set new thread data */
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Prcb->NextThread = NULL;
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Prcb->CurrentThread = NewThread;
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/* The thread is now running */
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NewThread->State = Running;
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OldThread->WaitReason = WrDispatchInt;
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/* Make the old thread ready */
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KxQueueReadyThread(OldThread, Prcb);
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/* Swap to the new thread */
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KiSwapContext(APC_LEVEL, OldThread);
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}
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}
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/* EOF */
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