mirror of
https://github.com/reactos/reactos.git
synced 2024-12-27 09:34:43 +00:00
604 lines
14 KiB
C
604 lines
14 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/trapc.c
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* PURPOSE: Implements the various trap handlers for ARM exceptions
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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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/* FUNCTIONS ******************************************************************/
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#if 0
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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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PKPCR Pcr = (PKPCR)KeGetPcr();
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PKPRCB Prcb = Pcr->Prcb;
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PKTHREAD OldThread, NewThread;
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//
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// Loop forever... that's why this is an idle loop
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//
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DPRINT1("[IDLE LOOP]\n");
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while (TRUE);
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while (TRUE)
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{
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//
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// Cycle interrupts
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//
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_disable();
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_enable();
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//
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// Check if there's DPC work to do
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//
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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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//
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// Clear the pending interrupt
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//
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HalClearSoftwareInterrupt(DISPATCH_LEVEL);
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//
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// Retire DPCs
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//
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KiRetireDpcList(Prcb);
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}
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//
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// Check if there's a thread to schedule
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//
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if (Prcb->NextThread)
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{
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//
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// Out with the old, in with the new...
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//
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OldThread = Prcb->CurrentThread;
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NewThread = Prcb->NextThread;
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Prcb->CurrentThread = NewThread;
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Prcb->NextThread = NULL;
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//
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// Update thread state
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//
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NewThread->State = Running;
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//
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// Swap to the new thread
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// On ARM we call KiSwapContext instead of KiSwapContextInternal,
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// because we're calling this from C code and not assembly.
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// This is similar to how it gets called for unwaiting, on x86
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//
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KiSwapContext(OldThread, NewThread);
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}
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else
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{
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//
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// Go into WFI (sleep more)
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//
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KeArmWaitForInterrupt();
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}
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}
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}
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#endif
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VOID
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NTAPI
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KiSwapProcess(IN PKPROCESS NewProcess,
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IN PKPROCESS OldProcess)
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{
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ARM_TTB_REGISTER TtbRegister;
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DPRINT1("Swapping from: %p (%16s) to %p (%16s)\n",
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OldProcess, ((PEPROCESS)OldProcess)->ImageFileName,
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NewProcess, ((PEPROCESS)NewProcess)->ImageFileName);
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//
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// Update the page directory base
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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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// FIXME: Flush the TLB
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//
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DPRINT1("Survived!\n");
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while (TRUE);
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}
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#if 0
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BOOLEAN
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KiSwapContextInternal(IN PKTHREAD OldThread,
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IN PKTHREAD NewThread)
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{
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PKIPCR Pcr = (PKIPCR)KeGetPcr();
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PKPRCB Prcb = Pcr->Prcb;
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PKPROCESS OldProcess, NewProcess;
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DPRINT1("SWAP\n");
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while (TRUE);
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//
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// Increase context switch count
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//
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Pcr->ContextSwitches++;
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//
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// Check if WMI tracing is enabled
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//
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if (Pcr->PerfGlobalGroupMask)
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{
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//
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// We don't support this yet on x86 either
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//
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DPRINT1("WMI Tracing not supported\n");
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ASSERT(FALSE);
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}
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//
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// Check if the processes are also different
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//
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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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//
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// Check if address space switch is needed
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//
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if (OldProcess->DirectoryTableBase[0] !=
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NewProcess->DirectoryTableBase[0])
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{
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//
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// FIXME-USER: Support address space switch
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//
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DPRINT1("Address space switch not implemented\n");
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ASSERT(FALSE);
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}
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}
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//
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// Increase thread context switches
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//
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NewThread->ContextSwitches++;
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#if 0 // I don't buy this
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//
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// Set us as the current thread
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// NOTE: On RISC Platforms, there is both a KPCR CurrentThread, and a
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// KPRCB CurrentThread.
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// The latter is set just like on x86-based builds, the former is only set
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// when actually doing the context switch (here).
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// Recall that the reason for the latter is due to the fact that the KPCR
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// is shared with user-mode (read-only), so that information is exposed
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// there as well.
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//
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Pcr->CurrentThread = NewThread;
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#endif
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//
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// DPCs shouldn't be active
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//
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if (Prcb->DpcRoutineActive)
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{
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//
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// Crash the machine
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//
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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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//
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// Kernel APCs may be pending
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//
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if (NewThread->ApcState.KernelApcPending)
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{
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//
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// Are APCs enabled?
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//
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if (NewThread->SpecialApcDisable == 0)
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{
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//
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// Request APC delivery
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//
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HalRequestSoftwareInterrupt(APC_LEVEL);
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return TRUE;
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}
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}
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//
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// Return
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//
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return FALSE;
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}
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#endif
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VOID
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KiApcInterrupt(VOID)
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{
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KPROCESSOR_MODE PreviousMode;
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KEXCEPTION_FRAME ExceptionFrame;
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PKTRAP_FRAME TrapFrame = KeGetCurrentThread()->TrapFrame;
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DPRINT1("[APC TRAP]\n");
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while (TRUE);
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//
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// Isolate previous mode
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//
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PreviousMode = KiGetPreviousMode(TrapFrame);
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//
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// FIXME-USER: Handle APC interrupt while in user-mode
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//
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if (PreviousMode == UserMode) ASSERT(FALSE);
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//
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// Disable interrupts
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//
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_disable();
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//
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// Clear APC interrupt
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//
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HalClearSoftwareInterrupt(APC_LEVEL);
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//
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// Re-enable interrupts
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//
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_enable();
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//
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// Deliver APCs
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//
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KiDeliverApc(PreviousMode, &ExceptionFrame, TrapFrame);
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}
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#if 0
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VOID
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KiDispatchInterrupt(VOID)
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{
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PKIPCR Pcr;
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PKPRCB Prcb;
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PKTHREAD NewThread, OldThread;
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DPRINT1("[DPC TRAP]\n");
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while (TRUE);
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//
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// Get the PCR and disable interrupts
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//
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Pcr = (PKIPCR)KeGetPcr();
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Prcb = Pcr->Prcb;
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_disable();
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//
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//Check if we have to deliver DPCs, timers, or deferred threads
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//
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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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//
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// Retire DPCs
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//
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KiRetireDpcList(Prcb);
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}
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//
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// Re-enable interrupts
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//
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_enable();
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//
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// Check for quantum end
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//
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if (Prcb->QuantumEnd)
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{
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//
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// Handle quantum end
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//
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Prcb->QuantumEnd = FALSE;
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KiQuantumEnd();
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return;
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}
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//
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// Check if we have a thread to swap to
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//
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if (Prcb->NextThread)
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{
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//
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// Next is now current
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//
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OldThread = Prcb->CurrentThread;
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NewThread = Prcb->NextThread;
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Prcb->CurrentThread = NewThread;
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Prcb->NextThread = NULL;
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//
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// Update thread states
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//
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NewThread->State = Running;
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OldThread->WaitReason = WrDispatchInt;
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//
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// Make the old thread ready
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//
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KxQueueReadyThread(OldThread, Prcb);
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//
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// Swap to the new thread
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// On ARM we call KiSwapContext instead of KiSwapContextInternal,
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// because we're calling this from C code and not assembly.
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// This is similar to how it gets called for unwaiting, on x86
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//
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KiSwapContext(OldThread, NewThread);
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}
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}
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#endif
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VOID
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KiInterruptHandler(IN PKTRAP_FRAME TrapFrame,
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IN ULONG Reserved)
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{
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KIRQL OldIrql, Irql;
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ULONG InterruptCause;//, InterruptMask;
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PKIPCR Pcr;
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PKTRAP_FRAME OldTrapFrame;
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ASSERT(TrapFrame->Reserved == 0xBADB0D00);
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//
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// Increment interrupt count
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//
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Pcr = (PKIPCR)KeGetPcr();
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Pcr->Prcb.InterruptCount++;
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//
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// Get the old IRQL
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//
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OldIrql = KeGetCurrentIrql();
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TrapFrame->PreviousIrql = OldIrql;
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//
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// Get the interrupt source
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//
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InterruptCause = HalGetInterruptSource();
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//DPRINT1("[INT] (%x) @ %p %p\n", InterruptCause, TrapFrame->SvcLr, TrapFrame->Pc);
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//
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// Get the new IRQL and Interrupt Mask
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//
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/// FIXME: use a global table in ntoskrnl instead of HAL?
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//Irql = Pcr->IrqlMask[InterruptCause];
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//InterruptMask = Pcr->IrqlTable[Irql];
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Irql = 0;
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__debugbreak();
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//
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// Raise to the new IRQL
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//
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KfRaiseIrql(Irql);
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//
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// The clock ISR wants the trap frame as a parameter
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//
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OldTrapFrame = KeGetCurrentThread()->TrapFrame;
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KeGetCurrentThread()->TrapFrame = TrapFrame;
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//
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// Check if this interrupt is at DISPATCH or higher
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//
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if (Irql > DISPATCH_LEVEL)
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{
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//
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// FIXME-TODO: Switch to interrupt stack
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//
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//DPRINT1("[ISR]\n");
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}
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else
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{
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//
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// We know this is APC or DPC.
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//
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//DPRINT1("[DPC/APC]\n");
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HalClearSoftwareInterrupt(Irql);
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}
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//
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// Call the registered interrupt routine
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//
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/// FIXME: this should probably go into a table in ntoskrnl
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//Pcr->InterruptRoutine[Irql]();
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__debugbreak();
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ASSERT(KeGetCurrentThread()->TrapFrame == TrapFrame);
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KeGetCurrentThread()->TrapFrame = OldTrapFrame;
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// DPRINT1("[ISR RETURN]\n");
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//
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// Restore IRQL and interrupts
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//
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KeLowerIrql(OldIrql);
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_enable();
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}
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NTSTATUS
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KiPrefetchAbortHandler(IN PKTRAP_FRAME TrapFrame)
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{
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PVOID Address = (PVOID)KeArmFaultAddressRegisterGet();
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ASSERT(TrapFrame->Reserved == 0xBADB0D00);
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ULONG Instruction = *(PULONG)TrapFrame->Pc;
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ULONG DebugType, Parameter0;
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EXCEPTION_RECORD ExceptionRecord;
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DPRINT1("[PREFETCH ABORT] (%x) @ %p/%p/%p\n",
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KeArmInstructionFaultStatusRegisterGet(), Address, TrapFrame->Lr, TrapFrame->Pc);
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while (TRUE);
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//
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// What we *SHOULD* do is look at the instruction fault status register
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// and see if it's equal to 2 (debug trap). Unfortunately QEMU doesn't seem
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// to emulate this behaviour properly, so we use a workaround.
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//
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//if (KeArmInstructionFaultStatusRegisterGet() == 2)
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if (Instruction & 0xE1200070) // BKPT
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{
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//
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// Okay, we know this is a breakpoint, extract the index
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//
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DebugType = Instruction & 0xF;
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if (DebugType == BREAKPOINT_PRINT)
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{
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//
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// Debug Service
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//
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Parameter0 = TrapFrame->R0;
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TrapFrame->Pc += sizeof(ULONG);
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}
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else
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{
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//
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// Standard INT3 (emulate x86 behavior)
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//
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Parameter0 = STATUS_SUCCESS;
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}
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//
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// Build the exception record
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//
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ExceptionRecord.ExceptionCode = STATUS_BREAKPOINT;
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ExceptionRecord.ExceptionFlags = 0;
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ExceptionRecord.ExceptionRecord = NULL;
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ExceptionRecord.ExceptionAddress = (PVOID)TrapFrame->Pc;
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ExceptionRecord.NumberParameters = 3;
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//
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// Build the parameters
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//
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ExceptionRecord.ExceptionInformation[0] = Parameter0;
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ExceptionRecord.ExceptionInformation[1] = TrapFrame->R1;
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ExceptionRecord.ExceptionInformation[2] = TrapFrame->R2;
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//
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// Dispatch the exception
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//
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KiDispatchException(&ExceptionRecord,
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NULL,
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TrapFrame,
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KiGetPreviousMode(TrapFrame),
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TRUE);
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//
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// We're done
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//
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return STATUS_SUCCESS;
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}
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//
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// Unhandled
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//
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UNIMPLEMENTED;
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ASSERT(FALSE);
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return STATUS_SUCCESS;
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}
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NTSTATUS
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KiDataAbortHandler(IN PKTRAP_FRAME TrapFrame)
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{
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NTSTATUS Status;
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PVOID Address = (PVOID)KeArmFaultAddressRegisterGet();
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ASSERT(TrapFrame->Reserved == 0xBADB0D00);
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DPRINT1("[ABORT] (%x) @ %p/%p/%p\n",
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KeArmFaultStatusRegisterGet(), Address, TrapFrame->Lr, TrapFrame->Pc);
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while (TRUE);
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//
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// Check if this is a page fault
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//
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if (KeArmFaultStatusRegisterGet() == 21 || KeArmFaultStatusRegisterGet() == 23)
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{
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Status = MmAccessFault(KeArmFaultStatusRegisterGet(),
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Address,
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KiGetPreviousMode(TrapFrame),
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TrapFrame);
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if (NT_SUCCESS(Status)) return Status;
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}
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//
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// Unhandled
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//
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UNIMPLEMENTED;
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ASSERT(FALSE);
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return STATUS_SUCCESS;
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}
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VOID
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KiSoftwareInterruptHandler(IN PKTRAP_FRAME TrapFrame)
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{
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PKTHREAD Thread;
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KPROCESSOR_MODE PreviousMode;
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ULONG Instruction;
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ASSERT(TrapFrame->Reserved == 0xBADB0D00);
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DPRINT1("[SWI] @ %p/%p\n", TrapFrame->Lr, TrapFrame->Pc);
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while (TRUE);
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//
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// Get the current thread
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//
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Thread = KeGetCurrentThread();
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//
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// Isolate previous mode
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//
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PreviousMode = KiGetPreviousMode(TrapFrame);
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//
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// Save old previous mode
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//
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TrapFrame->PreviousMode = PreviousMode;
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TrapFrame->TrapFrame = (ULONG_PTR)Thread->TrapFrame;
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//
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// Save previous mode and trap frame
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//
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Thread->TrapFrame = TrapFrame;
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Thread->PreviousMode = PreviousMode;
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//
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// Read the opcode
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//
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Instruction = *(PULONG)(TrapFrame->Pc - sizeof(ULONG));
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//
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// Call the service call dispatcher
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//
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KiSystemService(Thread, TrapFrame, Instruction);
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}
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NTSTATUS
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KiUndefinedExceptionHandler(IN PKTRAP_FRAME TrapFrame)
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{
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ASSERT(TrapFrame->Reserved == 0xBADB0D00);
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//
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// This should never happen
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//
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DPRINT1("[UNDEF] @ %p/%p\n", TrapFrame->Lr, TrapFrame->Pc);
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UNIMPLEMENTED;
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ASSERT(FALSE);
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return STATUS_SUCCESS;
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}
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