* PROJECT: ReactOS kernel
* FILE: ntoskrnl/kdbg/kdb.c
* PURPOSE: Kernel Debugger
- *
+ *
* PROGRAMMERS: Gregor Anich
*/
-
+
/* INCLUDES ******************************************************************/
#include <ntoskrnl.h>
"SIMD Fault"
};
+ULONG
+NTAPI
+KiSsFromTrapFrame(IN PKTRAP_FRAME TrapFrame);
+
+ULONG
+NTAPI
+KiEspFromTrapFrame(IN PKTRAP_FRAME TrapFrame);
+
+VOID
+NTAPI
+KiSsToTrapFrame(IN PKTRAP_FRAME TrapFrame,
+ IN ULONG Ss);
+
+VOID
+NTAPI
+KiEspToTrapFrame(IN PKTRAP_FRAME TrapFrame,
+ IN ULONG Esp);
+
/* FUNCTIONS *****************************************************************/
+STATIC VOID
+KdbpTrapFrameToKdbTrapFrame(PKTRAP_FRAME TrapFrame, PKDB_KTRAP_FRAME KdbTrapFrame)
+{
+ /* Copy the TrapFrame only up to Eflags and zero the rest*/
+ RtlCopyMemory(&KdbTrapFrame->Tf, TrapFrame, FIELD_OFFSET(KTRAP_FRAME, HardwareEsp));
+ RtlZeroMemory((PVOID)((ULONG_PTR)&KdbTrapFrame->Tf + FIELD_OFFSET(KTRAP_FRAME, HardwareEsp)),
+ sizeof (KTRAP_FRAME) - FIELD_OFFSET(KTRAP_FRAME, HardwareEsp));
+ asm volatile(
+ "movl %%cr0, %0" "\n\t"
+ "movl %%cr2, %1" "\n\t"
+ "movl %%cr3, %2" "\n\t"
+ "movl %%cr4, %3" "\n\t"
+ : "=r"(KdbTrapFrame->Cr0), "=r"(KdbTrapFrame->Cr2),
+ "=r"(KdbTrapFrame->Cr3), "=r"(KdbTrapFrame->Cr4));
+
+ KdbTrapFrame->Tf.HardwareEsp = KiEspFromTrapFrame(TrapFrame);
+ KdbTrapFrame->Tf.HardwareSegSs = (USHORT)(KiSsFromTrapFrame(TrapFrame) & 0xFFFF);
+
+
+ /* FIXME: copy v86 registers if TrapFrame is a V86 trapframe */
+}
+
+STATIC VOID
+KdbpKdbTrapFrameToTrapFrame(PKDB_KTRAP_FRAME KdbTrapFrame, PKTRAP_FRAME TrapFrame)
+{
+ /* Copy the TrapFrame only up to Eflags and zero the rest*/
+ RtlCopyMemory(TrapFrame, &KdbTrapFrame->Tf, FIELD_OFFSET(KTRAP_FRAME, HardwareEsp));
+
+ /* FIXME: write cr0, cr2, cr3 and cr4 (not needed atm) */
+
+ KiSsToTrapFrame(TrapFrame, KdbTrapFrame->Tf.HardwareSegSs);
+ KiEspToTrapFrame(TrapFrame, KdbTrapFrame->Tf.HardwareEsp);
+
+ /* FIXME: copy v86 registers if TrapFrame is a V86 trapframe */
+}
+
/*!\brief Overwrites the instruction at \a Address with \a NewInst and stores
* the old instruction in *OldInst.
*
/* Get the protection for the address. */
Protect = MmGetPageProtect(Process, (PVOID)PAGE_ROUND_DOWN(Address));
-
+
/* Return if that page isn't present. */
if (Protect & PAGE_NOACCESS)
{
return STATUS_MEMORY_NOT_ALLOCATED;
}
-
+
/* Attach to the process */
if (CurrentProcess != Process)
{
- KeStackAttachProcess(EPROCESS_TO_KPROCESS(Process), &ApcState);
+ KeStackAttachProcess(&Process->Pcb, &ApcState);
}
/* Make the page writeable if it is read only. */
MmSetPageProtect(Process, (PVOID)PAGE_ROUND_DOWN(Address),
(Protect & ~(PAGE_READONLY|PAGE_EXECUTE|PAGE_EXECUTE_READ)) | PAGE_READWRITE);
}
-
+
/* Copy the old instruction back to the caller. */
if (OldInst != NULL)
{
return Status;
}
}
-
+
/* Copy the new instruction in its place. */
Status = KdbpSafeWriteMemory((PUCHAR)Address, &NewInst, 1);
-
+
/* Restore the page protection. */
if (Protect & (PAGE_READONLY|PAGE_EXECUTE|PAGE_EXECUTE_READ))
{
MmSetPageProtect(Process, (PVOID)PAGE_ROUND_DOWN(Address), Protect);
}
-
+
/* Detach from process */
if (CurrentProcess != Process)
{
KdbpShouldStepOverInstruction(ULONG_PTR Eip)
{
UCHAR Mem[3];
- INT i = 0;
+ UINT i = 0;
if (!NT_SUCCESS(KdbpSafeReadMemory(Mem, (PVOID)Eip, sizeof (Mem))))
{
- KdbpPrint("Couldn't access memory at 0x%x\n", (UINT)Eip);
+ KdbpPrint("Couldn't access memory at 0x%p\n", Eip);
return FALSE;
}
BOOLEAN
KdbpStepIntoInstruction(ULONG_PTR Eip)
{
- struct __attribute__((packed)) {
- USHORT Limit;
- ULONG Base;
- } Idtr;
+ KDESCRIPTOR Idtr;
UCHAR Mem[2];
INT IntVect;
ULONG IntDesc[2];
/* Read memory */
if (!NT_SUCCESS(KdbpSafeReadMemory(Mem, (PVOID)Eip, sizeof (Mem))))
{
- /*KdbpPrint("Couldn't access memory at 0x%x\n", (UINT)Eip);*/
+ /*KdbpPrint("Couldn't access memory at 0x%p\n", Eip);*/
return FALSE;
}
IntVect = 3;
else if (Mem[0] == 0xcd)
IntVect = Mem[1];
- else if (Mem[0] == 0xce && KdbCurrentTrapFrame->Tf.Eflags & (1<<11)) /* 1 << 11 is the overflow flag */
+ else if (Mem[0] == 0xce && KdbCurrentTrapFrame->Tf.EFlags & (1<<11)) /* 1 << 11 is the overflow flag */
IntVect = 4;
else
return FALSE;
}
/* Read the interrupt descriptor table register */
- asm volatile("sidt %0" : : "m"(Idtr));
+ asm volatile("sidt %0" : : "m"(Idtr.Limit));
if (IntVect >= (Idtr.Limit + 1) / 8)
{
/*KdbpPrint("IDT does not contain interrupt vector %d\n.", IntVect);*/
/* Get the interrupt descriptor */
if (!NT_SUCCESS(KdbpSafeReadMemory(IntDesc, (PVOID)(Idtr.Base + (IntVect * 8)), sizeof (IntDesc))))
{
- /*KdbpPrint("Couldn't access memory at 0x%x\n", (UINT)Idtr.Base + (IntVect * 8));*/
+ /*KdbpPrint("Couldn't access memory at 0x%p\n", (ULONG_PTR)Idtr.Base + (IntVect * 8));*/
return FALSE;
}
-
+
/* Check descriptor and get target eip (16 bit interrupt/trap gates not supported) */
if ((IntDesc[1] & (1 << 15)) == 0) /* not present */
{
{
return FALSE;
}
-
+
bp = KdbBreakPoints + BreakPointNr;
if (Address != NULL)
*Address = bp->Address;
{
if ((Address % Size) != 0)
{
- KdbpPrint("Address (0x%x) must be aligned to a multiple of the size (%d)\n", Address, Size);
+ KdbpPrint("Address (0x%p) must be aligned to a multiple of the size (%d)\n", Address, Size);
return STATUS_UNSUCCESSFUL;
}
if (AccessType == KdbAccessExec && Size != 1)
{
return STATUS_UNSUCCESSFUL;
}
-
+
/* Parse conditon expression string and duplicate it */
if (ConditionExpression != NULL)
{
}
else
{
- for (i = 0; i < RTL_NUMBER_OF(KdbBreakPoints); i++)
+ for (i = 0; i < (LONG)RTL_NUMBER_OF(KdbBreakPoints); i++)
{
if (KdbBreakPoints[i].Type == KdbBreakPointNone)
break;
}
}
- ASSERT(i < RTL_NUMBER_OF(KdbBreakPoints));
-
+ ASSERT(i < (LONG)RTL_NUMBER_OF(KdbBreakPoints));
+
/* Set the breakpoint */
ASSERT(KdbCurrentProcess != NULL);
KdbBreakPoints[i].Type = Type;
KdbBreakPoints[i].Data.Hw.AccessType = AccessType;
}
KdbBreakPointCount++;
-
+
if (Type != KdbBreakPointTemporary)
KdbpPrint("Breakpoint %d inserted.\n", i);
KdbpPrint("Breakpoint %d deleted.\n", BreakPointNr);
BreakPoint->Type = KdbBreakPointNone;
KdbBreakPointCount--;
-
+
return TRUE;
}
IN ULONG ExpNr,
IN PKTRAP_FRAME TrapFrame)
{
- INT i;
+ UINT i;
ASSERT(ExpNr == 1 || ExpNr == 3);
if (ExpNr == 3) /* Software interrupt */
}
}
}
-
+
return -1;
}
KdbpPrint("Invalid breakpoint: %d\n", BreakPointNr);
return FALSE;
}
-
+
if (BreakPoint->Enabled == TRUE)
{
KdbpPrint("Breakpoint %d is already enabled.\n", BreakPointNr);
0xCC, &BreakPoint->Data.SavedInstruction);
if (!NT_SUCCESS(Status))
{
- KdbpPrint("Couldn't access memory at 0x%x\n", BreakPoint->Address);
+ KdbpPrint("Couldn't access memory at 0x%p\n", BreakPoint->Address);
return FALSE;
}
KdbSwBreakPoints[KdbSwBreakPointCount++] = BreakPoint;
IN LONG BreakPointNr OPTIONAL,
IN OUT PKDB_BREAKPOINT BreakPoint OPTIONAL)
{
- INT i;
+ UINT i;
NTSTATUS Status;
-
+
if (BreakPointNr < 0)
{
ASSERT(BreakPoint != NULL);
KdbpPrint("Couldn't restore original instruction.\n");
return FALSE;
}
-
+
for (i = 0; i < KdbSwBreakPointCount; i++)
{
if (KdbSwBreakPoints[i] == BreakPoint)
break;
}
}
- if (i != -1) /* not found */
+ if (i != (UINT)-1) /* not found */
ASSERT(0);
}
else
{
ASSERT(BreakPoint->Type == KdbBreakPointHardware);
-
+
/* Clear the breakpoint. */
KdbTrapFrame.Tf.Dr7 &= ~(0x3 << (BreakPoint->Data.Hw.DebugReg * 2));
if ((KdbTrapFrame.Tf.Dr7 & 0xFF) == 0)
break;
}
}
- if (i != -1) /* not found */
+ if (i != (UINT)-1) /* not found */
ASSERT(0);
}
IN BOOLEAN FirstChance,
OUT KDB_ENTER_CONDITION *Condition)
{
- if (ExceptionNr >= RTL_NUMBER_OF(KdbEnterConditions))
+ if (ExceptionNr >= (LONG)RTL_NUMBER_OF(KdbEnterConditions))
return FALSE;
*Condition = KdbEnterConditions[ExceptionNr][FirstChance ? 0 : 1];
{
if (ExceptionNr < 0)
{
- for (ExceptionNr = 0; ExceptionNr < RTL_NUMBER_OF(KdbEnterConditions); ExceptionNr++)
+ for (ExceptionNr = 0; ExceptionNr < (LONG)RTL_NUMBER_OF(KdbEnterConditions); ExceptionNr++)
{
if (ExceptionNr == 1 || ExceptionNr == 8 ||
ExceptionNr == 9 || ExceptionNr == 15) /* Reserved exceptions */
}
else
{
- if (ExceptionNr >= RTL_NUMBER_OF(KdbEnterConditions) ||
+ if (ExceptionNr >= (LONG)RTL_NUMBER_OF(KdbEnterConditions) ||
ExceptionNr == 1 || ExceptionNr == 8 || /* Do not allow changing of the debug */
ExceptionNr == 9 || ExceptionNr == 15) /* trap or reserved exceptions */
{
KdbpPrint("Cannot attach to thread within another process while executing a DPC.\n");
return FALSE;
}
-
+
/* Save the current thread's context (if we previously attached to a thread) */
if (KdbCurrentThread != KdbOriginalThread)
{
ASSERT(KdbCurrentTrapFrame == &KdbThreadTrapFrame);
- RtlCopyMemory(KdbCurrentThread->Tcb.TrapFrame, &KdbCurrentTrapFrame->Tf, sizeof (KTRAP_FRAME));
+ KdbpKdbTrapFrameToTrapFrame(KdbCurrentTrapFrame, KdbCurrentThread->Tcb.TrapFrame);
}
else
{
/* Switch to the thread's context */
if (Thread != KdbOriginalThread)
{
- ASSERT(Thread->Tcb.TrapFrame != NULL);
- RtlCopyMemory(&KdbThreadTrapFrame.Tf, Thread->Tcb.TrapFrame, sizeof (KTRAP_FRAME));
- asm volatile(
- "movl %%cr0, %0" "\n\t"
- "movl %%cr2, %1" "\n\t"
- "movl %%cr3, %2" "\n\t"
- "movl %%cr4, %3" "\n\t"
- : "=r"(KdbTrapFrame.Cr0), "=r"(KdbTrapFrame.Cr2),
- "=r"(KdbTrapFrame.Cr3), "=r"(KdbTrapFrame.Cr4));
+ if (Thread->Tcb.TrapFrame == NULL)
+ {
+ KdbpPrint("Threads TrapFrame is NULL! Cannot attach.\n");
+ return FALSE;
+ }
+ KdbpTrapFrameToKdbTrapFrame(Thread->Tcb.TrapFrame, &KdbThreadTrapFrame);
KdbCurrentTrapFrame = &KdbThreadTrapFrame;
}
else /* Switching back to original thread */
}
if (KdbOriginalProcess != Process)
{
- KeStackAttachProcess(EPROCESS_TO_KPROCESS(Process), &KdbApcState);
+ KeStackAttachProcess(&Process->Pcb, &KdbApcState);
}
KdbCurrentProcess = Process;
}
*/
STATIC VOID
KdbpInternalEnter()
-{
+{
PETHREAD Thread;
PVOID SavedInitialStack, SavedStackBase, SavedKernelStack;
ULONG SavedStackLimit;
-
+
KbdDisableMouse();
if (KdpDebugMode.Screen)
{
IN OUT PKTRAP_FRAME TrapFrame,
IN BOOLEAN FirstChance)
{
- ULONG ExpNr = (ULONG)TrapFrame->DebugArgMark;
+ ULONG ExpNr = (ULONG)TrapFrame->DbgArgMark;
KDB_ENTER_CONDITION EnterCondition;
KD_CONTINUE_TYPE ContinueType = kdHandleException;
PKDB_BREAKPOINT BreakPoint;
ul = min(ExpNr, RTL_NUMBER_OF(KdbEnterConditions) - 1);
EnterCondition = KdbEnterConditions[ul][FirstChance ? 0 : 1];
if (EnterCondition == KdbDoNotEnter ||
- (EnterCondition == KdbEnterFromUmode && PreviousMode != UserMode) ||
+ (EnterCondition == KdbEnterFromUmode && PreviousMode == KernelMode) ||
(EnterCondition == KdbEnterFromKmode && PreviousMode != KernelMode))
{
EnterConditionMet = FALSE;
{
Resume = TRUE; /* Set the resume flag when continuing execution */
}
-
+
/*
* When a temporary breakpoint is hit we have to make sure that we are
* in the same context in which it was set, otherwise it could happen
else if (BreakPoint->Type == KdbBreakPointTemporary &&
BreakPoint->Process == KdbCurrentProcess)
{
- ASSERT((TrapFrame->Eflags & X86_EFLAGS_TF) == 0);
-
+ ASSERT((TrapFrame->EFlags & X86_EFLAGS_TF) == 0);
+
/*
* Delete the temporary breakpoint which was used to step over or into the instruction.
*/
if ((KdbSingleStepOver && !KdbpStepOverInstruction(TrapFrame->Eip)) ||
(!KdbSingleStepOver && !KdbpStepIntoInstruction(TrapFrame->Eip)))
{
- TrapFrame->Eflags |= X86_EFLAGS_TF;
+ TrapFrame->EFlags |= X86_EFLAGS_TF;
}
goto continue_execution; /* return */
}
BreakPoint->Type == KdbBreakPointTemporary)
{
ASSERT(ExpNr == 3);
- TrapFrame->Eflags |= X86_EFLAGS_TF;
+ TrapFrame->EFlags |= X86_EFLAGS_TF;
KdbBreakPointToReenable = BreakPoint;
}
-
+
/*
* Make sure that the breakpoint should be triggered in this context
*/
{
goto continue_execution; /* return */
}
-
+
/*
* Check if the condition for the breakpoint is met.
*/
if (BreakPoint->Condition != NULL)
{
/* Setup the KDB trap frame */
- RtlCopyMemory(&KdbTrapFrame.Tf, TrapFrame, sizeof (KTRAP_FRAME));
- asm volatile(
- "movl %%cr0, %0" "\n\t"
- "movl %%cr2, %1" "\n\t"
- "movl %%cr3, %2" "\n\t"
- "movl %%cr4, %3" "\n\t"
- : "=r"(KdbTrapFrame.Cr0), "=r"(KdbTrapFrame.Cr2),
- "=r"(KdbTrapFrame.Cr3), "=r"(KdbTrapFrame.Cr4));
+ KdbpTrapFrameToKdbTrapFrame(TrapFrame, &KdbTrapFrame);
ull = 0;
if (!KdbpRpnEvaluateParsedExpression(BreakPoint->Condition, &KdbTrapFrame, &ull, NULL, NULL))
if (BreakPoint->Type == KdbBreakPointSoftware)
{
DbgPrint("Entered debugger on breakpoint #%d: EXEC 0x%04x:0x%08x\n",
- KdbLastBreakPointNr, TrapFrame->Cs & 0xffff, TrapFrame->Eip);
+ KdbLastBreakPointNr, TrapFrame->SegCs & 0xffff, TrapFrame->Eip);
}
else if (BreakPoint->Type == KdbBreakPointHardware)
{
/* Unset TF if we are no longer single stepping. */
if (KdbNumSingleSteps == 0)
- TrapFrame->Eflags &= ~X86_EFLAGS_TF;
+ TrapFrame->EFlags &= ~X86_EFLAGS_TF;
goto continue_execution; /* return */
}
if ((KdbSingleStepOver && KdbpStepOverInstruction(TrapFrame->Eip)) ||
(!KdbSingleStepOver && KdbpStepIntoInstruction(TrapFrame->Eip)))
{
- TrapFrame->Eflags &= ~X86_EFLAGS_TF;
+ TrapFrame->EFlags &= ~X86_EFLAGS_TF;
}
else
{
- TrapFrame->Eflags |= X86_EFLAGS_TF;
+ TrapFrame->EFlags |= X86_EFLAGS_TF;
}
goto continue_execution; /* return */
}
- TrapFrame->Eflags &= ~X86_EFLAGS_TF;
+ TrapFrame->EFlags &= ~X86_EFLAGS_TF;
KdbEnteredOnSingleStep = TRUE;
}
else
}
DbgPrint("Entered debugger on embedded INT3 at 0x%04x:0x%08x.\n",
- TrapFrame->Cs & 0xffff, TrapFrame->Eip - 1);
+ TrapFrame->SegCs & 0xffff, TrapFrame->Eip - 1);
}
else
{
if (ExpNr == 14)
{
/* FIXME: Add noexec memory stuff */
- ULONG Cr2, Err;
+ ULONG_PTR Cr2;
+ ULONG Err;
asm volatile("movl %%cr2, %0" : "=r"(Cr2));
- Err = TrapFrame->ErrorCode;
- DbgPrint("Memory at 0x%x could not be %s: ", Cr2, (Err & (1 << 1)) ? "written" : "read");
+ Err = TrapFrame->ErrCode;
+ DbgPrint("Memory at 0x%p could not be %s: ", Cr2, (Err & (1 << 1)) ? "written" : "read");
if ((Err & (1 << 0)) == 0)
DbgPrint("Page not present.\n");
else
}
}
}
-
+
/* Once we enter the debugger we do not expect any more single steps to happen */
KdbNumSingleSteps = 0;
-
+
/* Update the current process pointer */
KdbCurrentProcess = KdbOriginalProcess = PsGetCurrentProcess();
KdbCurrentThread = KdbOriginalThread = PsGetCurrentThread();
KdbCurrentTrapFrame = &KdbTrapFrame;
/* Setup the KDB trap frame */
- RtlCopyMemory(&KdbTrapFrame.Tf, TrapFrame, sizeof(KTRAP_FRAME));
- asm volatile(
- "movl %%cr0, %0" "\n\t"
- "movl %%cr2, %1" "\n\t"
- "movl %%cr3, %2" "\n\t"
- "movl %%cr4, %3" "\n\t"
- : "=r"(KdbTrapFrame.Cr0), "=r"(KdbTrapFrame.Cr2),
- "=r"(KdbTrapFrame.Cr3), "=r"(KdbTrapFrame.Cr4));
+ KdbpTrapFrameToKdbTrapFrame(TrapFrame, &KdbTrapFrame);
/* Enter critical section */
Ke386SaveFlags(OldEflags);
if ((KdbSingleStepOver && KdbpStepOverInstruction(KdbCurrentTrapFrame->Tf.Eip)) ||
(!KdbSingleStepOver && KdbpStepIntoInstruction(KdbCurrentTrapFrame->Tf.Eip)))
{
- ASSERT((KdbCurrentTrapFrame->Tf.Eflags & X86_EFLAGS_TF) == 0);
- /*KdbCurrentTrapFrame->Tf.Eflags &= ~X86_EFLAGS_TF;*/
+ ASSERT((KdbCurrentTrapFrame->Tf.EFlags & X86_EFLAGS_TF) == 0);
+ /*KdbCurrentTrapFrame->Tf.EFlags &= ~X86_EFLAGS_TF;*/
}
else
{
- KdbCurrentTrapFrame->Tf.Eflags |= X86_EFLAGS_TF;
+ KdbCurrentTrapFrame->Tf.EFlags |= X86_EFLAGS_TF;
}
}
/* Save the current thread's trapframe */
if (KdbCurrentTrapFrame == &KdbThreadTrapFrame)
{
- RtlCopyMemory(KdbCurrentThread->Tcb.TrapFrame, KdbCurrentTrapFrame, sizeof (KTRAP_FRAME));
+ KdbpKdbTrapFrameToTrapFrame(KdbCurrentTrapFrame, KdbCurrentThread->Tcb.TrapFrame);
}
/* Detach from attached process */
}
/* Update the exception TrapFrame */
- RtlCopyMemory(TrapFrame, &KdbTrapFrame.Tf, sizeof(KTRAP_FRAME));
-#if 0
- asm volatile(
- "movl %0, %%cr0" "\n\t"
- "movl %1, %%cr2" "\n\t"
- "movl %2, %%cr3" "\n\t"
- "movl %3, %%cr4" "\n\t"
- : : "r"(KdbTrapFrame.Cr0), "r"(KdbTrapFrame.Cr2),
- "r"(KdbTrapFrame.Cr3), "r"(KdbTrapFrame.Cr4));
-#endif
+ KdbpKdbTrapFrameToTrapFrame(&KdbTrapFrame, TrapFrame);
/* Decrement the entry count */
InterlockedDecrement(&KdbEntryCount);
/* Set the RF flag so we don't trigger the same breakpoint again. */
if (Resume)
{
- TrapFrame->Eflags |= X86_EFLAGS_RF;
+ TrapFrame->EFlags |= X86_EFLAGS_RF;
}
-
+
/* Clear dr6 status flags. */
TrapFrame->Dr6 &= ~0x0000e00f;
KdbDeleteProcessHook(IN PEPROCESS Process)
{
KdbSymFreeProcessSymbols(Process);
-
+
/* FIXME: Delete breakpoints for process */
}
p2 += 8;
KdbDebugState |= KD_DEBUG_KDNOECHO;
}
-
+
p1 = p2;
}
}
+
+NTSTATUS
+KdbpSafeReadMemory(OUT PVOID Dest,
+ IN PVOID Src,
+ IN ULONG Bytes)
+{
+ NTSTATUS Status = STATUS_SUCCESS;
+
+ _SEH_TRY
+ {
+ RtlCopyMemory(Dest,
+ Src,
+ Bytes);
+ }
+ _SEH_HANDLE
+ {
+ Status = _SEH_GetExceptionCode();
+ }
+ _SEH_END;
+
+ return Status;
+}
+
+NTSTATUS
+KdbpSafeWriteMemory(OUT PVOID Dest,
+ IN PVOID Src,
+ IN ULONG Bytes)
+{
+ NTSTATUS Status = STATUS_SUCCESS;
+
+ _SEH_TRY
+ {
+ RtlCopyMemory(Dest,
+ Src,
+ Bytes);
+ }
+ _SEH_HANDLE
+ {
+ Status = _SEH_GetExceptionCode();
+ }
+ _SEH_END;
+
+ return Status;
+}