mirror of
https://github.com/CloverHackyColor/CloverBootloader.git
synced 2024-11-24 11:45:27 +01:00
609 lines
19 KiB
C
609 lines
19 KiB
C
/**
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Methods for setting callback jump from kernel entry point, callback, fixes to kernel boot image.
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by dmazar
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**/
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#include <IndustryStandard/AppleHibernate.h>
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#include <Library/UefiLib.h>
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#include <Library/BaseMemoryLib.h>
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#include <Library/DebugLib.h>
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#include <Library/MachoLib.h>
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#include <Library/OcMiscLib.h>
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#include <Library/OcStringLib.h>
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#include <Library/UefiBootServicesTableLib.h>
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#include <Library/UefiRuntimeServicesTableLib.h>
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#include <Library/DevicePathLib.h>
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#include "Config.h"
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#include "BootFixes.h"
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#include "AsmFuncs.h"
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#include "BootArgs.h"
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#include "CustomSlide.h"
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#include "MemoryMap.h"
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#include "RtShims.h"
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#include "VMem.h"
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// DBG_TO: 0=no debug, 1=serial, 2=console
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// serial requires
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// [PcdsFixedAtBuild]
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// gEfiMdePkgTokenSpaceGuid.PcdDebugPropertyMask|0x07
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// gEfiMdePkgTokenSpaceGuid.PcdDebugPrintErrorLevel|0xFFFFFFFF
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// in package DSC file
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#define DBG_TO 0
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#if DBG_TO == 2
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#define DBG(...) AsciiPrint(__VA_ARGS__);
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#elif DBG_TO == 1
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#define DBG(...) DebugPrint(1, __VA_ARGS__);
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#else
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#define DBG(...)
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#endif
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EFI_PHYSICAL_ADDRESS gSysTableRtArea;
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EFI_PHYSICAL_ADDRESS gRelocatedSysTableRtArea;
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BOOLEAN gHibernateWake;
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BOOLEAN gDumpMemArgPresent;
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BOOLEAN gSlideArgPresent;
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BOOLEAN gHasBrokenS4MemoryMap;
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BOOLEAN gHasBrokenS4Allocator;
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//
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// Buffer and size for original kernel entry code
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//
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STATIC UINT8 mOrigKernelCode[32];
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STATIC UINTN mOrigKernelCodeSize;
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//
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// Buffer for virtual address map - only for RT areas
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// Note: DescriptorSize is usually > sizeof(EFI_MEMORY_DESCRIPTOR),
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// so this buffer can hold less than 64 descriptors
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//
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STATIC EFI_MEMORY_DESCRIPTOR mVirtualMemoryMap[64];
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STATIC UINTN mVirtualMapSize;
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STATIC UINTN mVirtualMapDescriptorSize;
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/** Fixes stuff when booting without relocation block. Called when boot.efi jumps to kernel. */
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STATIC
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VOID
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UpdateEnvironmentForBooting (
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UINTN BootArgs
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)
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{
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AMF_BOOT_ARGUMENTS *BA;
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UINTN MemoryMapSize;
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EFI_MEMORY_DESCRIPTOR *MemoryMap;
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UINTN DescriptorSize;
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BA = GetBootArgs ((VOID *)BootArgs);
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//
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// Restore the variables we tempered with to support custom slides.
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//
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RestoreCustomSlideOverrides (BA);
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MemoryMapSize = *BA->MemoryMapSize;
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MemoryMap = (EFI_MEMORY_DESCRIPTOR *)(UINTN)(*BA->MemoryMap);
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DescriptorSize = *BA->MemoryMapDescriptorSize;
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//
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// We must restore EfiRuntimeServicesCode memory areas, because otherwise
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// RuntimeServices won't be executable.
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//
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RestoreProtectedRtMemoryTypes (MemoryMapSize, DescriptorSize, MemoryMap);
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}
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/** Fixes stuff when waking from hibernate without relocation block. Called when boot.efi jumps to kernel. */
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STATIC
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VOID
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UpdateEnvironmentForHibernateWake (
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UINTN ImageHeaderPage
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)
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{
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IOHibernateImageHeader *ImageHeader;
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IOHibernateHandoff *Handoff;
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ImageHeader = (IOHibernateImageHeader *)(ImageHeaderPage << EFI_PAGE_SHIFT);
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//
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// Pass our relocated copy of system table
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//
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ImageHeader->systemTableOffset = (UINT32)(UINTN)(gRelocatedSysTableRtArea - ImageHeader->runtimePages);
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//
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// When reusing the original memory mapping we do not have to restore memory protection types & attributes,
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// since the new memory map is discarded anyway.
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// Otherwise we must restore memory map types just like at a normal boot, because MMIO regions are not
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// mapped as executable by XNU.
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//
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// Due to a non-contiguous RT_Code/RT_Data areas (thanks to NVRAM hack) the original areas
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// will not be unmapped and this will result in a memory leak if some new runtime pages are added.
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// But even that should not cause crashes.
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//
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Handoff = (IOHibernateHandoff *)((UINTN)ImageHeader->handoffPages << EFI_PAGE_SHIFT);
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while (Handoff->type != kIOHibernateHandoffTypeEnd) {
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if (Handoff->type == kIOHibernateHandoffTypeMemoryMap) {
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if (gHasBrokenS4MemoryMap) {
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//
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// Some firmwares provide us a (supposedly) invalid memory map, which results in
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// broken NVRAM and crashes after waking from hibernation. These firmwares for
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// whatever reason have code to ensure the same memory map over the reboots, and
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// it is a way some Windows versions hibernate. While terrible, we just discard
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// the new memory map here, and let XNU use what it has.
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//
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Handoff->type = kIOHibernateHandoffType;
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} else {
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//
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// boot.efi removes any memory from the memory map but the one with runtime attribute.
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//
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RestoreProtectedRtMemoryTypes (Handoff->bytecount, mVirtualMapDescriptorSize, (EFI_MEMORY_DESCRIPTOR *)Handoff->data);
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}
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break;
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}
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Handoff = (IOHibernateHandoff *)(UINTN)((UINTN)Handoff + sizeof(Handoff) + Handoff->bytecount);
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}
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}
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VOID
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ApplyFirmwareQuirks (
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IN EFI_HANDLE ImageHandle,
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IN EFI_SYSTEM_TABLE *SystemTable
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)
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{
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//
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// Detect broken firmwares.
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//
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if (SystemTable->FirmwareVendor) {
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if (!StrCmp (SystemTable->FirmwareVendor, L"American Megatrends")) {
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//
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// All APTIO firmwares provide invalid memory map after waking from
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// hibernation. This results in not working NVRAM or crashes.
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// FIXME: Find the root cause of the problem.
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//
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gHasBrokenS4MemoryMap = TRUE;
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} else if (!StrCmp (SystemTable->FirmwareVendor, L"INSYDE Corp.")) {
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//
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// At least some INSYDE firmwares have NVRAM issues just like APTIO.
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// Some are heard not to, but we are not aware of it.
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// FIXME: In addition to that we have difficulties allocating RtShims
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// on INSYDE, some address lead to reboots after hibernate wake.
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//
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gHasBrokenS4MemoryMap = TRUE;
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gHasBrokenS4Allocator = TRUE;
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}
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}
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}
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VOID
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ReadBooterArguments (
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CHAR16 *Options,
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UINTN OptionsSize
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)
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{
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CHAR8 BootArgsVar[BOOT_LINE_LENGTH];
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UINTN BootArgsVarLen = BOOT_LINE_LENGTH;
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EFI_STATUS Status;
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UINTN LastIndex;
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CHAR16 Last;
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if (Options && OptionsSize > 0) {
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//
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// Just in case we do not have 0-termination.
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// This may cut some data with unexpected options, but it is not like we care.
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//
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LastIndex = OptionsSize - 1;
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Last = Options[LastIndex];
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Options[LastIndex] = '\0';
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UnicodeStrToAsciiStrS (Options, BootArgsVar, BOOT_LINE_LENGTH);
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if (GetArgumentFromCommandLine (BootArgsVar, "slide=", L_STR_LEN ("slide="))) {
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gSlideArgPresent = TRUE;
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}
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#if APTIOFIX_ALLOW_MEMORY_DUMP_ARG == 1
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if (GetArgumentFromCommandLine (BootArgsVar, "-aptiodump", L_STR_LEN ("-aptiodump"))) {
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gDumpMemArgPresent = TRUE;
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}
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#endif
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//
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// Options do not belong to us, restore the changed value
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//
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Options[LastIndex] = Last;
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}
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//
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// Important to avoid triggering boot-args wrapper too early
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//
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Status = OrgGetVariable (
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L"boot-args",
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&gEfiAppleBootGuid,
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NULL, &BootArgsVarLen,
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&BootArgsVar[0]
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);
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if (!EFI_ERROR (Status) && BootArgsVarLen > 0) {
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//
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// Just in case we do not have 0-termination
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//
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BootArgsVar[BootArgsVarLen-1] = '\0';
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if (GetArgumentFromCommandLine (BootArgsVar, "slide=", L_STR_LEN ("slide="))) {
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gSlideArgPresent = TRUE;
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}
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#if APTIOFIX_ALLOW_MEMORY_DUMP_ARG == 1
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if (GetArgumentFromCommandLine (BootArgsVar, "-aptiodump", L_STR_LEN ("-aptiodump"))) {
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gDumpMemArgPresent = TRUE;
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}
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#endif
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}
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}
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/** Saves current 64 bit state and copies JumpToKernel32 function to higher mem
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* (for copying kernel back to proper place and jumping back to it).
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*/
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EFI_STATUS
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PrepareJumpFromKernel (
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VOID
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)
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{
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EFI_STATUS Status;
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EFI_PHYSICAL_ADDRESS HigherMem;
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UINTN Size;
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//
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// Check if already prepared.
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//
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if (JumpToKernel32Addr != 0) {
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DEBUG ((DEBUG_VERBOSE, "PrepareJumpFromKernel() - already prepared\n"));
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return EFI_SUCCESS;
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}
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//
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// Save current 64bit state - will be restored later in callback from kernel jump.
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//
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AsmPrepareJumpFromKernel ();
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//
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// Allocate higher memory for JumpToKernel code.
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// Must be 32-bit to access via a relative jump.
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//
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HigherMem = BASE_4GB;
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Status = AllocatePagesFromTop (EfiBootServicesCode, 1, &HigherMem, FALSE);
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if (Status != EFI_SUCCESS) {
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Print (L"AMF: Failed to allocate JumpToKernel memory - %r\n", Status);
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return Status;
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}
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//
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// And relocate it to higher mem.
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//
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JumpToKernel32Addr = HigherMem + ( (UINT8 *)&JumpToKernel32 - (UINT8 *)&JumpToKernel );
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JumpToKernel64Addr = HigherMem + ( (UINT8 *)&JumpToKernel64 - (UINT8 *)&JumpToKernel );
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Size = (UINT8 *)&JumpToKernelEnd - (UINT8 *)&JumpToKernel;
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if (Size > EFI_PAGES_TO_SIZE (1)) {
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Print (L"AMF: JumpToKernel32 size is too big - %ld\n", Size);
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return EFI_BUFFER_TOO_SMALL;
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}
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CopyMem ((VOID *)(UINTN)HigherMem, (VOID *)&JumpToKernel, Size);
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DEBUG ((DEBUG_VERBOSE, "PrepareJumpFromKernel(): JumpToKernel relocated from %p, to %x, size = %x\n",
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&JumpToKernel, HigherMem, Size));
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DEBUG ((DEBUG_VERBOSE, "JumpToKernel32 relocated from %p, to %x\n", &JumpToKernel32, JumpToKernel32Addr));
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DEBUG ((DEBUG_VERBOSE, "JumpToKernel64 relocated from %p, to %x\n", &JumpToKernel64, JumpToKernel64Addr));
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DEBUG ((DEBUG_VERBOSE, "SavedCR3 = %x, SavedGDTR = %x, SavedIDTR = %x\n", SavedCR3, SavedGDTR, SavedIDTR));
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DEBUG ((DEBUG_VERBOSE, "PrepareJumpFromKernel(): JumpToKernel relocated from %p, to %x, size = %x\n",
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&JumpToKernel, HigherMem, Size));
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//
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// Allocate 1 RT data page for copy of EFI system table for kernel.
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// This one also has to be 32-bit due to XNU BootArgs structure.
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//
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gSysTableRtArea = BASE_4GB;
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Status = AllocatePagesFromTop (EfiRuntimeServicesData, 1, &gSysTableRtArea, FALSE);
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if (Status != EFI_SUCCESS) {
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Print (L"AMF: Failed to allocate system table memory - %r\n", Status);
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return Status;
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}
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DEBUG ((DEBUG_VERBOSE, "gSysTableRtArea = %lx\n", gSysTableRtArea));
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//
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// Copy sys table to the new location.
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//
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CopyMem ((VOID *)(UINTN)gSysTableRtArea, gST, gST->Hdr.HeaderSize);
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return Status;
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}
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/** Patches kernel entry point with jump to AsmJumpFromKernel (AsmFuncsX64). This will then call KernelEntryPatchJumpBack. */
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EFI_STATUS
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KernelEntryPatchJump (
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UINT32 KernelEntry
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)
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{
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//
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// Size of EntryPatchCode code
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//
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mOrigKernelCodeSize = (UINT8*)&EntryPatchCodeEnd - (UINT8*)&EntryPatchCode;
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if (mOrigKernelCodeSize > sizeof (mOrigKernelCode)) {
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return EFI_NOT_FOUND;
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}
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//
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// Save original kernel entry code
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//
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CopyMem ((VOID *)mOrigKernelCode, (VOID *)(UINTN)KernelEntry, mOrigKernelCodeSize);
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//
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// Copy EntryPatchCode code to kernel entry address
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//
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CopyMem ((VOID *)(UINTN)KernelEntry, (VOID *)&EntryPatchCode, mOrigKernelCodeSize);
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//
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// Pass KernelEntry to assembler funcs.
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// This is not needed really, since asm code will determine kernel entry address from the stack.
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//
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AsmKernelEntry = KernelEntry;
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return EFI_SUCCESS;
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}
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/** Reads kernel entry from Mach-O load command and patches it with jump to AsmJumpFromKernel. */
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EFI_STATUS
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KernelEntryFromMachOPatchJump (
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VOID *MachOImage,
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UINTN SlideAddr
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)
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{
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UINTN KernelEntry;
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KernelEntry = MachoRuntimeGetEntryAddress (MachOImage);
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if (KernelEntry == 0) {
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return EFI_NOT_FOUND;
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}
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if (SlideAddr > 0) {
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KernelEntry += SlideAddr;
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}
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return KernelEntryPatchJump ((UINT32)KernelEntry);
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}
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/** Callback called when boot.efi jumps to kernel. */
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UINTN
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EFIAPI
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KernelEntryPatchJumpBack (
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UINTN Args,
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BOOLEAN ModeX64
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)
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{
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if (gHibernateWake) {
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UpdateEnvironmentForHibernateWake (Args);
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} else {
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UpdateEnvironmentForBooting (Args);
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}
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//
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// Restore original kernel entry code.
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//
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CopyMem ((VOID *)(UINTN)AsmKernelEntry, (VOID *)mOrigKernelCode, mOrigKernelCodeSize);
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return Args;
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}
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/** Copies RT flagged areas to separate memmap, defines virtual to phisycal address mapping
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* and calls SetVirtualAddressMap() only with that partial memmap.
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*
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* About partial memmap:
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* Some UEFIs are converting pointers to virtual addresses even if they do not
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* point to regions with RT flag. This means that those UEFIs are using
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* Desc->VirtualStart even for non-RT regions. Linux had issues with this:
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* http://git.kernel.org/?p=linux/kernel/git/torvalds/linux-2.6.git;a=commit;h=7cb00b72876ea2451eb79d468da0e8fb9134aa8a
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* They are doing it Windows way now - copying RT descriptors to separate
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* mem map and passing that stripped map to SetVirtualAddressMap().
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* We'll do the same, although it seems that just assigning
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* VirtualStart = PhysicalStart for non-RT areas also does the job.
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*
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* About virtual to phisycal mappings:
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* Also adds virtual to phisycal address mappings for RT areas. This is needed since
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* SetVirtualAddressMap() does not work on my Aptio without that. Probably because some driver
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* has a bug and is trying to access new virtual addresses during the change.
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* Linux and Windows are doing the same thing and problem is
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* not visible there.
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*/
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EFI_STATUS
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ExecSetVirtualAddressesToMemMap (
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IN UINTN MemoryMapSize,
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IN UINTN DescriptorSize,
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IN UINT32 DescriptorVersion,
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IN EFI_MEMORY_DESCRIPTOR *MemoryMap
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)
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{
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UINTN NumEntries;
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UINTN Index;
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EFI_MEMORY_DESCRIPTOR *Desc;
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EFI_MEMORY_DESCRIPTOR *VirtualDesc;
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EFI_STATUS Status;
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PAGE_MAP_AND_DIRECTORY_POINTER *PageTable;
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UINTN Flags;
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UINTN BlockSize;
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Desc = MemoryMap;
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NumEntries = MemoryMapSize / DescriptorSize;
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VirtualDesc = mVirtualMemoryMap;
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mVirtualMapSize = 0;
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mVirtualMapDescriptorSize = DescriptorSize;
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DEBUG ((DEBUG_VERBOSE, "ExecSetVirtualAddressesToMemMap: Size=%d, Addr=%p, DescSize=%d\n", MemoryMapSize, MemoryMap, DescriptorSize));
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//
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// Get current VM page table
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//
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GetCurrentPageTable (&PageTable, &Flags);
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for (Index = 0; Index < NumEntries; Index++) {
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//
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// Some UEFIs end up with "reserved" area with EFI_MEMORY_RUNTIME flag set when Intel HD3000 or HD4000 is used.
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// For example, on GA-H81N-D2H there is a single 1 GB descriptor:
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// 000000009F800000-00000000DF9FFFFF 0000000000040200 8000000000000000
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//
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// All known boot.efi starting from at least 10.5.8 properly handle this flag and do not assign virtual addresses
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// to reserved descriptors.
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// However, the issue was with AptioFix itself, which did not check for EfiReservedMemoryType and replaced
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// it by EfiMemoryMappedIO to prevent boot.efi relocations.
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//
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// The relevant discussion and the original fix can be found here:
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// http://web.archive.org/web/20141111124211/http://www.projectosx.com:80/forum/lofiversion/index.php/t2428-450.html
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// https://sourceforge.net/p/cloverefiboot/code/605/
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//
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// Since it is not the bug in boot.efi, AptioMemoryFix only needs to properly handle EfiReservedMemoryType with
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// EFI_MEMORY_RUNTIME attribute set, and there is no reason to mess with the memory map passed to boot.efi.
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//
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if (Desc->Type != EfiReservedMemoryType && (Desc->Attribute & EFI_MEMORY_RUNTIME) != 0) {
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//
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// Check if there is enough space in mVirtualMemoryMap.
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//
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if (mVirtualMapSize + DescriptorSize > sizeof(mVirtualMemoryMap)) {
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DEBUG ((DEBUG_INFO, "ERROR: too much mem map RT areas\n"));
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return EFI_OUT_OF_RESOURCES;
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}
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//
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// Copy region with EFI_MEMORY_RUNTIME flag to mVirtualMemoryMap.
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//
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CopyMem ((VOID*)VirtualDesc, (VOID*)Desc, DescriptorSize);
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//
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// Define virtual to phisical mapping.
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//
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DEBUG ((DEBUG_VERBOSE, "Map pages: %lx (%x) -> %lx\n", Desc->VirtualStart, Desc->NumberOfPages, Desc->PhysicalStart));
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VmMapVirtualPages (PageTable, Desc->VirtualStart, Desc->NumberOfPages, Desc->PhysicalStart);
|
|
|
|
//
|
|
// Next mVirtualMemoryMap slot.
|
|
//
|
|
VirtualDesc = NEXT_MEMORY_DESCRIPTOR (VirtualDesc, DescriptorSize);
|
|
mVirtualMapSize += DescriptorSize;
|
|
|
|
//
|
|
// Remember future physical address for the relocated system table.
|
|
//
|
|
BlockSize = EFI_PAGES_TO_SIZE ((UINTN)Desc->NumberOfPages);
|
|
if (Desc->PhysicalStart <= gSysTableRtArea && gSysTableRtArea < (Desc->PhysicalStart + BlockSize)) {
|
|
//
|
|
// Future physical = VirtualStart & 0x7FFFFFFFFF
|
|
//
|
|
gRelocatedSysTableRtArea = (Desc->VirtualStart & 0x7FFFFFFFFF) + (gSysTableRtArea - Desc->PhysicalStart);
|
|
}
|
|
}
|
|
|
|
Desc = NEXT_MEMORY_DESCRIPTOR (Desc, DescriptorSize);
|
|
}
|
|
|
|
VmFlushCaches ();
|
|
|
|
DEBUG ((DEBUG_VERBOSE, "ExecSetVirtualAddressesToMemMap: Size=%d, Addr=%p, DescSize=%d\nSetVirtualAddressMap ... ",
|
|
mVirtualMapSize, MemoryMap, DescriptorSize));
|
|
Status = gRT->SetVirtualAddressMap (mVirtualMapSize, DescriptorSize, DescriptorVersion, mVirtualMemoryMap);
|
|
DEBUG ((DEBUG_VERBOSE, "%r\n", Status));
|
|
|
|
return Status;
|
|
}
|
|
|
|
VOID
|
|
CopyEfiSysTableToRtArea (
|
|
IN OUT UINT32 *EfiSystemTable
|
|
)
|
|
{
|
|
EFI_SYSTEM_TABLE *Src;
|
|
EFI_SYSTEM_TABLE *Dest;
|
|
|
|
Src = (EFI_SYSTEM_TABLE*)(UINTN)*EfiSystemTable;
|
|
Dest = (EFI_SYSTEM_TABLE*)(UINTN)gSysTableRtArea;
|
|
|
|
CopyMem (Dest, Src, Src->Hdr.HeaderSize);
|
|
|
|
*EfiSystemTable = (UINT32)(UINTN)Dest;
|
|
}
|
|
|
|
/**
|
|
Returns the length of PathName.
|
|
|
|
@param[in] FilePath The file Device Path node to inspect.
|
|
|
|
**/
|
|
UINTN
|
|
FileDevicePathNameLen (IN CONST FILEPATH_DEVICE_PATH *FilePath)
|
|
{
|
|
UINTN Size;
|
|
UINTN Len;
|
|
|
|
if (!FilePath) {
|
|
return 0;
|
|
}
|
|
|
|
if (!IsDevicePathValid (&FilePath->Header, 0)) {
|
|
return 0;
|
|
}
|
|
|
|
Size = DevicePathNodeLength (FilePath) - SIZE_OF_FILEPATH_DEVICE_PATH;
|
|
//
|
|
// Account for more than one termination character.
|
|
//
|
|
Len = (Size / sizeof (*FilePath->PathName)) - 1;
|
|
while (Len > 0 && FilePath->PathName[Len - 1] == L'\0') {
|
|
--Len;
|
|
}
|
|
|
|
return Len;
|
|
}
|
|
|
|
|
|
EFI_LOADED_IMAGE_PROTOCOL *
|
|
GetAppleBootLoadedImage (
|
|
EFI_HANDLE ImageHandle
|
|
)
|
|
{
|
|
EFI_STATUS Status;
|
|
EFI_LOADED_IMAGE_PROTOCOL *LoadedImage = NULL;
|
|
EFI_DEVICE_PATH_PROTOCOL *CurrNode = NULL;
|
|
FILEPATH_DEVICE_PATH *LastNode = NULL;
|
|
BOOLEAN IsMacOS = FALSE;
|
|
UINTN PathLen = 0;
|
|
UINTN BootPathLen = L_STR_LEN ("boot.efi");
|
|
UINTN Index;
|
|
|
|
Status = gBS->HandleProtocol (ImageHandle, &gEfiLoadedImageProtocolGuid, (VOID **)&LoadedImage);
|
|
|
|
if (!EFI_ERROR (Status) && LoadedImage->FilePath) {
|
|
for (CurrNode = LoadedImage->FilePath; !IsDevicePathEnd (CurrNode); CurrNode = NextDevicePathNode (CurrNode)) {
|
|
if (CurrNode->Type == MEDIA_DEVICE_PATH && CurrNode->SubType == MEDIA_FILEPATH_DP) {
|
|
LastNode = (FILEPATH_DEVICE_PATH *)CurrNode;
|
|
}
|
|
}
|
|
|
|
if (LastNode) {
|
|
//
|
|
// Detect macOS by boot.efi in the bootloader name.
|
|
//
|
|
PathLen = FileDevicePathNameLen (LastNode);
|
|
if (PathLen >= BootPathLen) {
|
|
Index = PathLen - BootPathLen;
|
|
IsMacOS = (Index == 0 || LastNode->PathName[Index - 1] == L'\\')
|
|
&& !CompareMem (&LastNode->PathName[Index], L"boot.efi", L_STR_SIZE (L"boot.efi"));
|
|
}
|
|
}
|
|
}
|
|
|
|
return IsMacOS ? LoadedImage : NULL;
|
|
}
|