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312 lines
8.3 KiB
312 lines
8.3 KiB
/*++
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Copyright (c) 1989 Microsoft Corporation
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Module Name:
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abiosc.c
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Abstract:
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This module implements ROM BIOS support C routines for i386 NT.
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Author:
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Shie-Lin Tzong (shielint) 10-Sept-1992
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Environment:
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Kernel mode.
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Revision History:
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--*/
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#include "ki.h"
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#pragma hdrstop
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#include "vdmntos.h"
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#ifdef ALLOC_PRAGMA
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#pragma alloc_text(PAGE,Ke386CallBios)
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#endif
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//
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// Never change these equates without checking biosa.asm
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//
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#define V86_CODE_ADDRESS 0x10000
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#define INT_OPCODE 0xcd
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#define V86_BOP_OPCODE 0xfec4c4
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#define V86_STACK_POINTER 0x1ffe
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#define IOPM_OFFSET FIELD_OFFSET(KTSS, IoMaps[0].IoMap)
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#define VDM_TIB_ADDRESS 0x12000
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#define INT_10_TEB 0x13000
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//
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// External References
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//
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PVOID Ki386IopmSaveArea;
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VOID
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Ki386SetupAndExitToV86Code (
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PVOID ExecutionAddress
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);
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NTSTATUS
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Ke386CallBios (
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IN ULONG BiosCommand,
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IN OUT PCONTEXT BiosArguments
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)
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/*++
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Routine Description:
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This function invokes specified ROM BIOS code by executing
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"INT BiosCommand." Before executing the BIOS code, this function
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will setup VDM context, change stack pointer ...etc. If for some reason
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the operation fails, a status code will be returned. Otherwise, this
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function always returns success regardless of the result of the BIOS
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call.
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N.B. This implementation relies on the fact that the direct
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I/O access operations between apps are serialized by win user.
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Arguments:
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BiosCommand - Supplies which ROM BIOS function to invoke.
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BiosArguments - Supplies a pointer to the context which will be used
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to invoke ROM BIOS.
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Return Value:
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NTSTATUS code to specify the failure.
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--*/
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{
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PVDM_TIB VdmTib;
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PUCHAR BaseAddress = (PUCHAR)V86_CODE_ADDRESS;
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PTEB UserInt10Teb = (PTEB)INT_10_TEB;
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PKTSS Tss;
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PKPROCESS Process;
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PKTHREAD Thread;
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USHORT OldIopmOffset, OldIoMapBase;
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PVDM_PROCESS_OBJECTS VdmObjects;
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ULONG ContextLength;
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BOOLEAN ThreadDebugActive;
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//
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// Map in ROM BIOS area to perform the int 10 code
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//
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try {
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RtlZeroMemory(UserInt10Teb, sizeof(TEB));
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//
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// Write "Int BiosCommand; bop" to reserved user space (0x1000).
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// Later control will transfer to the user space to execute
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// these two instructions.
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//
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*BaseAddress++ = INT_OPCODE;
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*BaseAddress++ = (UCHAR)BiosCommand;
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*(PULONG)BaseAddress = V86_BOP_OPCODE;
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//
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// Set up Vdm(v86) context to execute the int BiosCommand
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// instruction by copying user supplied context to VdmContext
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// and updating the control registers to predefined values.
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//
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//
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// We want to use a constant number for the int10.
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//
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// Create a fake TEB so we can switch the thread to it while we
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// do an int10
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//
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UserInt10Teb->Vdm = (PVOID)VDM_TIB_ADDRESS;
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VdmTib = (PVDM_TIB)VDM_TIB_ADDRESS;
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RtlZeroMemory(VdmTib, sizeof(VDM_TIB));
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VdmTib->Size = sizeof(VDM_TIB);
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*FIXED_NTVDMSTATE_LINEAR_PC_AT = 0;
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//
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// extended registers are never going to matter to
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// an Int10 call, so only copy the old part of the
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// context record.
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//
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ContextLength = FIELD_OFFSET(CONTEXT, ExtendedRegisters);
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RtlCopyMemory(&(VdmTib->VdmContext), BiosArguments, ContextLength);
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VdmTib->VdmContext.SegCs = (ULONG)BaseAddress >> 4;
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VdmTib->VdmContext.SegSs = (ULONG)BaseAddress >> 4;
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VdmTib->VdmContext.Eip = 0;
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VdmTib->VdmContext.Esp = 2 * PAGE_SIZE - sizeof(ULONG);
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VdmTib->VdmContext.EFlags |= EFLAGS_V86_MASK | EFLAGS_INTERRUPT_MASK;
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VdmTib->VdmContext.ContextFlags = CONTEXT_FULL;
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} except (EXCEPTION_EXECUTE_HANDLER) {
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return GetExceptionCode();
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}
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//
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// The vdm kernel code finds the Tib by looking at a pointer cached in
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// kernel memory, which was probed at Vdm creation time. Since the
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// creation semantics for this vdm are peculiar, we do something similar
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// here.
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//
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//
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// We never get here on a process that is a real vdm. If we do,
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// bad things will happen (pool leak, failure to execute dos and
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// windows apps).
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//
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ASSERT(PsGetCurrentProcess()->VdmObjects == NULL);
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VdmObjects = ExAllocatePoolWithTag (NonPagedPool,
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sizeof(VDM_PROCESS_OBJECTS),
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' eK'
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);
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//
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// Since we are doing this on behalf of CSR not a user process, we aren't
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// charging quota.
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//
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if (VdmObjects == NULL) {
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return STATUS_NO_MEMORY;
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}
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//
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// We are only initializing the VdmTib pointer, because that's the only
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// part of the VdmObjects we use for ROM calls. We aren't set up
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// to simulate interrupts, or any of the other stuff that would be done
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// in a conventional vdm
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//
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RtlZeroMemory( VdmObjects, sizeof(VDM_PROCESS_OBJECTS));
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VdmObjects->VdmTib = VdmTib;
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PsGetCurrentProcess()->VdmObjects = VdmObjects;
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//
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// Since we are going to v86 mode and accessing some I/O ports, we
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// need to make sure the IopmOffset is set correctly across context
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// swap and the I/O bit map has all the bits cleared.
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// N.B. This implementation assumes that there is only one full
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// screen DOS app and the io access between full screen DOS
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// app and the server code is serialized by win user. That
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// means even we change the IOPM, the full screen dos app won't
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// be able to run on this IOPM.
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// * In another words, IF THERE IS
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// * MORE THAN ONE FULL SCREEN DOS APPS, THIS CODE IS BROKEN.*
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//
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// NOTE This code works on the assumption that winuser serializes
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// direct I/O access operations.
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//
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//
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// Call the bios from the processor which booted the machine.
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//
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Thread = KeGetCurrentThread();
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KeSetSystemAffinityThread(1);
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Tss = KeGetPcr()->TSS;
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//
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// Save away the original IOPM bit map and clear all the IOPM bits
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// to allow v86 int 10 code to access ALL the io ports.
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//
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//
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// Make sure there are at least 2 IOPM maps.
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//
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ASSERT(KeGetPcr()->GDT[KGDT_TSS / 8].LimitLow >= (0x2000 + IOPM_OFFSET - 1));
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RtlCopyMemory (Ki386IopmSaveArea,
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(PVOID)&Tss->IoMaps[0].IoMap,
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PAGE_SIZE * 2
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);
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RtlZeroMemory ((PVOID)&Tss->IoMaps[0].IoMap, PAGE_SIZE * 2);
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Process = Thread->ApcState.Process;
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OldIopmOffset = Process->IopmOffset;
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OldIoMapBase = Tss->IoMapBase;
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Process->IopmOffset = (USHORT)(IOPM_OFFSET); // Set Process IoPmOffset before
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Tss->IoMapBase = (USHORT)(IOPM_OFFSET); // updating Tss IoMapBase
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//
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// The context setup for the BIOS will not have valid debug registers
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// in it, don't try to load them.
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//
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ThreadDebugActive = Thread->DebugActive;
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Thread->DebugActive = FALSE;
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KeGetPcr()->DebugActive = FALSE;
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//
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// Call ASM routine to switch stack to exit to v86 mode to
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// run Int BiosCommand.
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//
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Ki386SetupAndExitToV86Code(UserInt10Teb);
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//
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// After we return from v86 mode, the control comes here.
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//
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// Restore Thread's DebugActive flag.
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//
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KeGetPcr()->DebugActive = ThreadDebugActive;
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Thread->DebugActive = ThreadDebugActive;
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//
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// Restore old IOPM
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//
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RtlCopyMemory ((PVOID)&Tss->IoMaps[0].IoMap,
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Ki386IopmSaveArea,
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PAGE_SIZE * 2
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);
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Process->IopmOffset = OldIopmOffset;
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Tss->IoMapBase = OldIoMapBase;
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//
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// Restore old affinity for current thread.
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//
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KeRevertToUserAffinityThread();
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//
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// Copy 16 bit vdm context back to caller.
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//
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// Extended register state is not going to matter,
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// so copy only the old part of the context record.
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//
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ContextLength = FIELD_OFFSET(CONTEXT, ExtendedRegisters);
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RtlCopyMemory(BiosArguments, &(VdmTib->VdmContext), ContextLength);
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BiosArguments->ContextFlags = CONTEXT_FULL;
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//
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// Free the pool used for the VdmTib pointer
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//
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PsGetCurrentProcess()->VdmObjects = NULL;
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ExFreePool(VdmObjects);
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return STATUS_SUCCESS;
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}
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