mirror of
https://github.com/reactos/reactos.git
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054c11a02c
Cause a corresponding bug check to occur for the reason of the user context flag being zero (a system thread), instead of using DbgBreakPoint.
517 lines
15 KiB
C
517 lines
15 KiB
C
/*
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* COPYRIGHT: See COPYING in the top level directory
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* PROJECT: ReactOS kernel
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* FILE: ntoskrnl/ke/i386/thrdini.c
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* PURPOSE: i386 Thread Context Creation
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* PROGRAMMER: Alex Ionescu (alex@relsoft.net)
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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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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 _KSTART_FRAME
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{
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PKSYSTEM_ROUTINE SystemRoutine;
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PKSTART_ROUTINE StartRoutine;
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PVOID StartContext;
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BOOLEAN UserThread;
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} KSTART_FRAME, *PKSTART_FRAME;
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typedef struct _KUINIT_FRAME
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{
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KSWITCHFRAME CtxSwitchFrame;
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KSTART_FRAME StartFrame;
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KTRAP_FRAME TrapFrame;
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FX_SAVE_AREA FxSaveArea;
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} KUINIT_FRAME, *PKUINIT_FRAME;
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typedef struct _KKINIT_FRAME
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{
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KSWITCHFRAME CtxSwitchFrame;
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KSTART_FRAME StartFrame;
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FX_SAVE_AREA FxSaveArea;
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} KKINIT_FRAME, *PKKINIT_FRAME;
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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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VOID
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FASTCALL
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KiRetireDpcListInDpcStack(
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IN PKPRCB Prcb,
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IN PVOID DpcStack
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);
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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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{
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PKTRAP_FRAME TrapFrame;
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PKSTART_FRAME StartFrame;
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PKUINIT_FRAME InitFrame;
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/* Get the start and trap frames */
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InitFrame = KeGetCurrentThread()->KernelStack;
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StartFrame = &InitFrame->StartFrame;
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TrapFrame = &InitFrame->TrapFrame;
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/* Lower to APC level */
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KfLowerIrql(APC_LEVEL);
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/* Call the system routine */
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StartFrame->SystemRoutine(StartFrame->StartRoutine, StartFrame->StartContext);
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/* If we returned, we better be a user thread */
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if (!StartFrame->UserThread)
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{
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KeBugCheck(NO_USER_MODE_CONTEXT);
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}
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/* Exit to user-mode */
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KiServiceExit2(TrapFrame);
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}
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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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PFX_SAVE_AREA FxSaveArea;
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PFXSAVE_FORMAT FxSaveFormat;
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PKSTART_FRAME StartFrame;
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PKSWITCHFRAME CtxSwitchFrame;
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PKTRAP_FRAME TrapFrame;
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CONTEXT LocalContext;
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PCONTEXT Context = NULL;
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ULONG ContextFlags;
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/* Check if this is a With-Context Thread */
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if (ContextPointer)
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{
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/* Set up the Initial Frame */
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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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/* Copy over the context we got */
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RtlCopyMemory(&LocalContext, ContextPointer, sizeof(CONTEXT));
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Context = &LocalContext;
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ContextFlags = CONTEXT_CONTROL;
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/* Zero out the trap frame and save area */
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RtlZeroMemory(&InitFrame->TrapFrame,
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KTRAP_FRAME_LENGTH + sizeof(FX_SAVE_AREA));
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/* Setup the Fx Area */
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FxSaveArea = &InitFrame->FxSaveArea;
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/* Check if we support FXsr */
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if (KeI386FxsrPresent)
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{
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/* Get the FX Save Format Area */
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FxSaveFormat = (PFXSAVE_FORMAT)Context->ExtendedRegisters;
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/* Set an initial state */
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FxSaveFormat->ControlWord = 0x27F;
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FxSaveFormat->StatusWord = 0;
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FxSaveFormat->TagWord = 0;
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FxSaveFormat->ErrorOffset = 0;
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FxSaveFormat->ErrorSelector = 0;
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FxSaveFormat->DataOffset = 0;
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FxSaveFormat->DataSelector = 0;
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FxSaveFormat->MXCsr = 0x1F80;
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}
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else
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{
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/* Setup the regular save area */
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Context->FloatSave.ControlWord = 0x27F;
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Context->FloatSave.StatusWord = 0;
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Context->FloatSave.TagWord = -1;
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Context->FloatSave.ErrorOffset = 0;
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Context->FloatSave.ErrorSelector = 0;
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Context->FloatSave.DataOffset =0;
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Context->FloatSave.DataSelector = 0;
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}
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/* Check if the CPU has NPX */
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if (KeI386NpxPresent)
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{
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/* Set an intial NPX State */
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Context->FloatSave.Cr0NpxState = 0;
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FxSaveArea->Cr0NpxState = 0;
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FxSaveArea->NpxSavedCpu = 0;
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/* Now set the context flags depending on XMM support */
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ContextFlags |= (KeI386FxsrPresent) ? CONTEXT_EXTENDED_REGISTERS :
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CONTEXT_FLOATING_POINT;
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/* Set the Thread's NPX State */
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Thread->NpxState = NPX_STATE_NOT_LOADED;
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Thread->Header.NpxIrql = PASSIVE_LEVEL;
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}
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else
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{
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/* We'll use emulation */
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FxSaveArea->Cr0NpxState = CR0_EM;
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Thread->NpxState = NPX_STATE_NOT_LOADED &~ CR0_MP;
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}
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/* Disable any debug registers */
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Context->ContextFlags &= ~CONTEXT_DEBUG_REGISTERS;
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/* Setup the Trap Frame */
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TrapFrame = &InitFrame->TrapFrame;
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/* Set up a trap frame from the context. */
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KeContextToTrapFrame(Context,
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NULL,
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TrapFrame,
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Context->ContextFlags | ContextFlags,
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UserMode);
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/* Set SS, DS, ES's RPL Mask properly */
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TrapFrame->HardwareSegSs |= RPL_MASK;
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TrapFrame->SegDs |= RPL_MASK;
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TrapFrame->SegEs |= RPL_MASK;
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TrapFrame->Dr7 = 0;
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/* Set the debug mark */
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TrapFrame->DbgArgMark = 0xBADB0D00;
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/* Set the previous mode as user */
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TrapFrame->PreviousPreviousMode = UserMode;
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/* Terminate the Exception Handler List */
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TrapFrame->ExceptionList = EXCEPTION_CHAIN_END;
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/* Setup the Stack for KiThreadStartup and Context Switching */
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StartFrame = &InitFrame->StartFrame;
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CtxSwitchFrame = &InitFrame->CtxSwitchFrame;
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/* Tell the thread it will run in User Mode */
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Thread->PreviousMode = UserMode;
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/* Tell KiThreadStartup of that too */
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StartFrame->UserThread = TRUE;
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}
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else
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{
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/* Set up the Initial Frame for the system thread */
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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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/* Setup the Fx Area */
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FxSaveArea = &InitFrame->FxSaveArea;
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RtlZeroMemory(FxSaveArea, sizeof(FX_SAVE_AREA));
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/* Check if we have Fxsr support */
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if (KeI386FxsrPresent)
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{
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/* Set the stub FX area */
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FxSaveArea->U.FxArea.ControlWord = 0x27F;
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FxSaveArea->U.FxArea.MXCsr = 0x1F80;
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}
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else
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{
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/* Set the stub FN area */
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FxSaveArea->U.FnArea.ControlWord = 0x27F;
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FxSaveArea->U.FnArea.TagWord = -1;
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}
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/* No NPX State */
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Thread->NpxState = NPX_STATE_NOT_LOADED;
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/* Setup the Stack for KiThreadStartup and Context Switching */
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StartFrame = &InitFrame->StartFrame;
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CtxSwitchFrame = &InitFrame->CtxSwitchFrame;
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/* Tell the thread it will run in Kernel Mode */
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Thread->PreviousMode = KernelMode;
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/* Tell KiThreadStartup of that too */
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StartFrame->UserThread = FALSE;
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}
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/* Now setup the remaining data for KiThreadStartup */
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StartFrame->StartContext = StartContext;
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StartFrame->StartRoutine = StartRoutine;
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StartFrame->SystemRoutine = SystemRoutine;
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/* And set up the Context Switch Frame */
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CtxSwitchFrame->RetAddr = KiThreadStartup;
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CtxSwitchFrame->ApcBypassDisable = TRUE;
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CtxSwitchFrame->ExceptionList = EXCEPTION_CHAIN_END;
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/* Save back the new value of the kernel stack. */
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Thread->KernelStack = (PVOID)CtxSwitchFrame;
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}
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VOID
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FASTCALL
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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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/* Switch away from the idle thread */
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KiSwapContext(APC_LEVEL, OldThread);
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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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/* We are on the new thread stack now */
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NewThread = Pcr->PrcbData.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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/* Check if there is a different LDT */
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if (*(PULONGLONG)&OldProcess->LdtDescriptor != *(PULONGLONG)&NewProcess->LdtDescriptor)
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{
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if (NewProcess->LdtDescriptor.LimitLow)
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{
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KeSetGdtSelector(KGDT_LDT,
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((PULONG)&NewProcess->LdtDescriptor)[0],
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((PULONG)&NewProcess->LdtDescriptor)[1]);
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Ke386SetLocalDescriptorTable(KGDT_LDT);
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}
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else
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{
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Ke386SetLocalDescriptorTable(0);
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}
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}
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/* Switch address space and flush TLB */
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__writecr3(NewProcess->DirectoryTableBase[0]);
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}
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/* Clear GS */
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Ke386SetGs(0);
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/* Set the TEB */
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KiSetTebBase((PKPCR)Pcr, NewThread->Teb);
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/* Set new TSS fields */
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Pcr->TSS->Esp0 = (ULONG_PTR)NewThread->InitialStack;
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if (!((KeGetTrapFrame(NewThread))->EFlags & EFLAGS_V86_MASK))
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{
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Pcr->TSS->Esp0 -= (FIELD_OFFSET(KTRAP_FRAME, V86Gs) - FIELD_OFFSET(KTRAP_FRAME, HardwareSegSs));
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}
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Pcr->TSS->Esp0 -= NPX_FRAME_LENGTH;
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Pcr->TSS->IoMapBase = NewProcess->IopmOffset;
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/* Increase thread context switches */
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NewThread->ContextSwitches++;
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/* Load data from switch frame */
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Pcr->NtTib.ExceptionList = SwitchFrame->ExceptionList;
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/* DPCs shouldn't be active */
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if (Pcr->PrcbData.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)
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HalRequestSoftwareInterrupt(APC_LEVEL);
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else
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return TRUE;
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}
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}
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/* Return stating that no kernel APCs are pending*/
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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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ULONG Cr0, NewCr0;
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/* Save APC bypass disable */
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SwitchFrame->ApcBypassDisable = OldThreadAndApcFlag & 3;
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SwitchFrame->ExceptionList = Pcr->NtTib.ExceptionList;
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/* Increase context switch count and check if tracing is enabled */
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Pcr->ContextSwitches++;
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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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/* Get thread pointers */
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OldThread = (PKTHREAD)(OldThreadAndApcFlag & ~3);
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NewThread = Pcr->PrcbData.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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/* ISRs can change FPU state, so disable interrupts while checking */
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_disable();
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/* Get current and new CR0 and check if they've changed */
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Cr0 = __readcr0();
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NewCr0 = NewThread->NpxState |
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(Cr0 & ~(CR0_MP | CR0_EM | CR0_TS)) |
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KiGetThreadNpxArea(NewThread)->Cr0NpxState;
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if (Cr0 != NewCr0) __writecr0(NewCr0);
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/* Now enable interrupts and do the switch */
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_enable();
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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->PrcbData;
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PVOID OldHandler;
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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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/* Switch to safe execution context */
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OldHandler = Pcr->NtTib.ExceptionList;
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Pcr->NtTib.ExceptionList = EXCEPTION_CHAIN_END;
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/* Retire DPCs while under the DPC stack */
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KiRetireDpcListInDpcStack(Prcb, Prcb->DpcStack);
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/* Restore context */
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Pcr->NtTib.ExceptionList = OldHandler;
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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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/* 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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