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https://github.com/CloverHackyColor/CloverBootloader.git
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329 lines
10 KiB
C
329 lines
10 KiB
C
/** @file
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Install a fake VGABIOS service handler (real mode Int10h) for the buggy
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Windows 2008 R2 SP1 UEFI guest.
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The handler is never meant to be directly executed by a VCPU; it's there for
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the internal real mode emulator of Windows 2008 R2 SP1.
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The code is based on Ralf Brown's Interrupt List:
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<http://www.cs.cmu.edu/~ralf/files.html>
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<http://www.ctyme.com/rbrown.htm>
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Copyright (C) 2014, Red Hat, Inc.
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Copyright (c) 2013 - 2014, Intel Corporation. All rights reserved.<BR>
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SPDX-License-Identifier: BSD-2-Clause-Patent
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**/
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#include <IndustryStandard/LegacyVgaBios.h>
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#include <Library/DebugLib.h>
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#include <Library/PciLib.h>
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#include <Library/PrintLib.h>
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#include <OvmfPlatforms.h>
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#include "Qemu.h"
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#include "VbeShim.h"
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#pragma pack (1)
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typedef struct {
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UINT16 Offset;
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UINT16 Segment;
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} IVT_ENTRY;
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#pragma pack ()
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//
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// This string is displayed by Windows 2008 R2 SP1 in the Screen Resolution,
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// Advanced Settings dialog. It should be short.
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//
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STATIC CONST CHAR8 mProductRevision[] = "OVMF Int10h (fake)";
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/**
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Install the VBE Info and VBE Mode Info structures, and the VBE service
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handler routine in the C segment. Point the real-mode Int10h interrupt vector
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to the handler. The only advertised mode is 1024x768x32.
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@param[in] CardName Name of the video card to be exposed in the
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Product Name field of the VBE Info structure. The
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parameter must originate from a
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QEMU_VIDEO_CARD.Name field.
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@param[in] FrameBufferBase Guest-physical base address of the video card's
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frame buffer.
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**/
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VOID
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InstallVbeShim (
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IN CONST CHAR16 *CardName,
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IN EFI_PHYSICAL_ADDRESS FrameBufferBase
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)
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{
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EFI_PHYSICAL_ADDRESS Segment0, SegmentC, SegmentF;
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UINTN Segment0Pages;
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IVT_ENTRY *Int0x10;
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EFI_STATUS Segment0AllocationStatus;
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UINT16 HostBridgeDevId;
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UINTN Pam1Address;
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UINT8 Pam1;
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UINTN SegmentCPages;
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VBE_INFO *VbeInfoFull;
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VBE_INFO_BASE *VbeInfo;
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UINT8 *Ptr;
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UINTN Printed;
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VBE_MODE_INFO *VbeModeInfo;
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if ((PcdGet8 (PcdNullPointerDetectionPropertyMask) & (BIT0|BIT7)) == BIT0) {
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DEBUG ((
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DEBUG_WARN,
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"%a: page 0 protected, not installing VBE shim\n",
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__func__
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));
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DEBUG ((
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DEBUG_WARN,
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"%a: page 0 protection prevents Windows 7 from booting anyway\n",
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__func__
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));
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return;
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}
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Segment0 = 0x00000;
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SegmentC = 0xC0000;
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SegmentF = 0xF0000;
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//
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// Attempt to cover the real mode IVT with an allocation. This is a UEFI
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// driver, hence the arch protocols have been installed previously. Among
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// those, the CPU arch protocol has configured the IDT, so we can overwrite
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// the IVT used in real mode.
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//
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// The allocation request may fail, eg. if LegacyBiosDxe has already run.
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//
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Segment0Pages = 1;
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Int0x10 = (IVT_ENTRY *)(UINTN)(Segment0 + 0x10 * sizeof (IVT_ENTRY));
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Segment0AllocationStatus = gBS->AllocatePages (
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AllocateAddress,
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EfiBootServicesCode,
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Segment0Pages,
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&Segment0
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);
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if (EFI_ERROR (Segment0AllocationStatus)) {
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EFI_PHYSICAL_ADDRESS Handler;
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//
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// Check if a video BIOS handler has been installed previously -- we
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// shouldn't override a real video BIOS with our shim, nor our own shim if
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// it's already present.
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//
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Handler = (Int0x10->Segment << 4) + Int0x10->Offset;
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if ((Handler >= SegmentC) && (Handler < SegmentF)) {
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DEBUG ((
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DEBUG_INFO,
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"%a: Video BIOS handler found at %04x:%04x\n",
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__func__,
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Int0x10->Segment,
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Int0x10->Offset
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));
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return;
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}
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//
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// Otherwise we'll overwrite the Int10h vector, even though we may not own
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// the page at zero.
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//
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DEBUG ((
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DEBUG_INFO,
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"%a: failed to allocate page at zero: %r\n",
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__func__,
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Segment0AllocationStatus
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));
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} else {
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//
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// We managed to allocate the page at zero. SVN r14218 guarantees that it
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// is NUL-filled.
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//
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ASSERT (Int0x10->Segment == 0x0000);
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ASSERT (Int0x10->Offset == 0x0000);
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}
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//
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// Put the shim in place first.
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//
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// Start by determining the address of the PAM1 register.
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//
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HostBridgeDevId = PcdGet16 (PcdOvmfHostBridgePciDevId);
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switch (HostBridgeDevId) {
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case INTEL_82441_DEVICE_ID:
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Pam1Address = PMC_REGISTER_PIIX4 (PIIX4_PAM1);
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break;
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case INTEL_Q35_MCH_DEVICE_ID:
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Pam1Address = DRAMC_REGISTER_Q35 (MCH_PAM1);
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break;
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case MICROVM_PSEUDO_DEVICE_ID:
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return;
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default:
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DEBUG ((
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DEBUG_ERROR,
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"%a: unknown host bridge device ID: 0x%04x\n",
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__func__,
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HostBridgeDevId
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));
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ASSERT (FALSE);
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if (!EFI_ERROR (Segment0AllocationStatus)) {
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gBS->FreePages (Segment0, Segment0Pages);
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}
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return;
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}
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//
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// low nibble covers 0xC0000 to 0xC3FFF
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// high nibble covers 0xC4000 to 0xC7FFF
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// bit1 in each nibble is Write Enable
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// bit0 in each nibble is Read Enable
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//
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Pam1 = PciRead8 (Pam1Address);
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PciWrite8 (Pam1Address, Pam1 | (BIT1 | BIT0));
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//
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// We never added memory space during PEI or DXE for the C segment, so we
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// don't need to (and can't) allocate from there. Also, guest operating
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// systems will see a hole in the UEFI memory map there.
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//
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SegmentCPages = 4;
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ASSERT (sizeof mVbeShim <= EFI_PAGES_TO_SIZE (SegmentCPages));
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CopyMem ((VOID *)(UINTN)SegmentC, mVbeShim, sizeof mVbeShim);
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//
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// Fill in the VBE INFO structure.
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//
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VbeInfoFull = (VBE_INFO *)(UINTN)SegmentC;
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VbeInfo = &VbeInfoFull->Base;
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Ptr = VbeInfoFull->Buffer;
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CopyMem (VbeInfo->Signature, "VESA", 4);
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VbeInfo->VesaVersion = 0x0300;
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VbeInfo->OemNameAddress = (UINT32)SegmentC << 12 | (UINT16)(UINTN)Ptr;
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CopyMem (Ptr, "QEMU", 5);
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Ptr += 5;
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VbeInfo->Capabilities = BIT0; // DAC can be switched into 8-bit mode
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VbeInfo->ModeListAddress = (UINT32)SegmentC << 12 | (UINT16)(UINTN)Ptr;
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*(UINT16 *)Ptr = 0x00f1; // mode number
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Ptr += 2;
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*(UINT16 *)Ptr = 0xFFFF; // mode list terminator
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Ptr += 2;
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VbeInfo->VideoMem64K = (UINT16)((1024 * 768 * 4 + 65535) / 65536);
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VbeInfo->OemSoftwareVersion = 0x0000;
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VbeInfo->VendorNameAddress = (UINT32)SegmentC << 12 | (UINT16)(UINTN)Ptr;
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CopyMem (Ptr, "OVMF", 5);
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Ptr += 5;
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VbeInfo->ProductNameAddress = (UINT32)SegmentC << 12 | (UINT16)(UINTN)Ptr;
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Printed = AsciiSPrint (
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(CHAR8 *)Ptr,
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sizeof VbeInfoFull->Buffer - (Ptr - VbeInfoFull->Buffer),
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"%s",
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CardName
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);
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Ptr += Printed + 1;
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VbeInfo->ProductRevAddress = (UINT32)SegmentC << 12 | (UINT16)(UINTN)Ptr;
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CopyMem (Ptr, mProductRevision, sizeof mProductRevision);
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Ptr += sizeof mProductRevision;
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ASSERT (sizeof VbeInfoFull->Buffer >= Ptr - VbeInfoFull->Buffer);
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ZeroMem (Ptr, sizeof VbeInfoFull->Buffer - (Ptr - VbeInfoFull->Buffer));
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//
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// Fil in the VBE MODE INFO structure.
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//
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VbeModeInfo = (VBE_MODE_INFO *)(VbeInfoFull + 1);
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//
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// bit0: mode supported by present hardware configuration
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// bit1: optional information available (must be =1 for VBE v1.2+)
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// bit3: set if color, clear if monochrome
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// bit4: set if graphics mode, clear if text mode
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// bit5: mode is not VGA-compatible
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// bit7: linear framebuffer mode supported
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//
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VbeModeInfo->ModeAttr = BIT7 | BIT5 | BIT4 | BIT3 | BIT1 | BIT0;
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//
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// bit0: exists
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// bit1: bit1: readable
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// bit2: writeable
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//
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VbeModeInfo->WindowAAttr = BIT2 | BIT1 | BIT0;
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VbeModeInfo->WindowBAttr = 0x00;
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VbeModeInfo->WindowGranularityKB = 0x0040;
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VbeModeInfo->WindowSizeKB = 0x0040;
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VbeModeInfo->WindowAStartSegment = 0xA000;
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VbeModeInfo->WindowBStartSegment = 0x0000;
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VbeModeInfo->WindowPositioningAddress = 0x0000;
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VbeModeInfo->BytesPerScanLine = 1024 * 4;
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VbeModeInfo->Width = 1024;
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VbeModeInfo->Height = 768;
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VbeModeInfo->CharCellWidth = 8;
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VbeModeInfo->CharCellHeight = 16;
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VbeModeInfo->NumPlanes = 1;
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VbeModeInfo->BitsPerPixel = 32;
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VbeModeInfo->NumBanks = 1;
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VbeModeInfo->MemoryModel = 6; // direct color
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VbeModeInfo->BankSizeKB = 0;
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VbeModeInfo->NumImagePagesLessOne = 0;
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VbeModeInfo->Vbe3 = 0x01;
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VbeModeInfo->RedMaskSize = 8;
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VbeModeInfo->RedMaskPos = 16;
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VbeModeInfo->GreenMaskSize = 8;
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VbeModeInfo->GreenMaskPos = 8;
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VbeModeInfo->BlueMaskSize = 8;
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VbeModeInfo->BlueMaskPos = 0;
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VbeModeInfo->ReservedMaskSize = 8;
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VbeModeInfo->ReservedMaskPos = 24;
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//
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// bit1: Bytes in reserved field may be used by application
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//
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VbeModeInfo->DirectColorModeInfo = BIT1;
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VbeModeInfo->LfbAddress = (UINT32)FrameBufferBase;
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VbeModeInfo->OffScreenAddress = 0;
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VbeModeInfo->OffScreenSizeKB = 0;
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VbeModeInfo->BytesPerScanLineLinear = 1024 * 4;
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VbeModeInfo->NumImagesLessOneBanked = 0;
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VbeModeInfo->NumImagesLessOneLinear = 0;
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VbeModeInfo->RedMaskSizeLinear = 8;
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VbeModeInfo->RedMaskPosLinear = 16;
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VbeModeInfo->GreenMaskSizeLinear = 8;
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VbeModeInfo->GreenMaskPosLinear = 8;
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VbeModeInfo->BlueMaskSizeLinear = 8;
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VbeModeInfo->BlueMaskPosLinear = 0;
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VbeModeInfo->ReservedMaskSizeLinear = 8;
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VbeModeInfo->ReservedMaskPosLinear = 24;
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VbeModeInfo->MaxPixelClockHz = 0;
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ZeroMem (VbeModeInfo->Reserved, sizeof VbeModeInfo->Reserved);
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//
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// Clear Write Enable (bit1), keep Read Enable (bit0) set
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//
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PciWrite8 (Pam1Address, (Pam1 & ~BIT1) | BIT0);
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//
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// Second, point the Int10h vector at the shim.
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//
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Int0x10->Segment = (UINT16)((UINT32)SegmentC >> 4);
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Int0x10->Offset = (UINT16)((UINTN)(VbeModeInfo + 1) - SegmentC);
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DEBUG ((DEBUG_INFO, "%a: VBE shim installed\n", __func__));
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}
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