CloverBootloader/rEFIt_UEFI/Platform/kext_patcher.cpp
SergeySlice 0143e228ee right way to patch kexts
Signed-off-by: SergeySlice <sergey.slice@gmail.com>
2020-07-23 22:14:20 +03:00

1613 lines
53 KiB
C++

/*
* Copyright (c) 2011-2012 Frank Peng. All rights reserved.
*
*/
#ifdef __cplusplus
extern "C" {
#endif
#include <Library/BaseLib.h>
#include <Library/BaseMemoryLib.h>
#include <Library/DebugLib.h>
#ifdef __cplusplus
}
#endif
#include <UefiLoader.h>
#include "Platform.h"
#include "kernel_patcher.h"
#define OLD_METHOD 0
#ifndef DEBUG_ALL
#define KEXT_DEBUG 1
#else
#define KEXT_DEBUG DEBUG_ALL
#endif
#if KEXT_DEBUG == 2
#define DBG(...) printf(__VA_ARGS__);
#elif KEXT_DEBUG == 1
#define DBG(...) DebugLog(KEXT_DEBUG, __VA_ARGS__)
#else
#define DBG(...)
#endif
// runtime debug
#define DBG_RT(...) if ((KernelAndKextPatches != NULL) && KernelAndKextPatches->KPDebug) { printf(__VA_ARGS__); }
//
// Searches Source for Search pattern of size SearchSize
// and returns the number of occurences.
//
UINTN SearchAndCount(const UINT8 *Source, UINT64 SourceSize, const UINT8 *Search, UINTN SearchSize)
{
UINTN NumFounds = 0;
const UINT8 *End = Source + SourceSize;
while (Source < End) {
if (CompareMem(Source, Search, SearchSize) == 0) {
NumFounds++;
Source += SearchSize;
} else {
Source++;
}
}
return NumFounds;
}
//
// Searches Source for Search pattern of size SearchSize
// and replaces it with Replace up to MaxReplaces times.
// If MaxReplaces <= 0, then there is no restriction on number of replaces.
// Replace should have the same size as Search.
// Returns number of replaces done.
//
UINTN SearchAndReplace(UINT8 *Source, UINT64 SourceSize, const UINT8 *Search, UINTN SearchSize, const UINT8 *Replace, INTN MaxReplaces)
{
UINTN NumReplaces = 0;
BOOLEAN NoReplacesRestriction = MaxReplaces <= 0;
// UINT8 *Begin = Source;
UINT8 *End = Source + SourceSize;
if (!Source || !Search || !Replace || !SearchSize) {
return 0;
}
while ((Source < End) && (NoReplacesRestriction || (MaxReplaces > 0))) {
if (CompareMem(Source, Search, SearchSize) == 0) {
// printf(" found pattern at %llx\n", (UINTN)(Source - Begin));
CopyMem(Source, Replace, SearchSize);
NumReplaces++;
MaxReplaces--;
Source += SearchSize;
} else {
Source++;
}
}
return NumReplaces;
}
BOOLEAN CompareMemMask(const UINT8 *Source, const UINT8 *Search, UINTN SearchSize, const UINT8 *Mask, UINTN MaskSize)
{
UINT8 M;
if (!Mask || MaskSize == 0) {
return !CompareMem(Source, Search, SearchSize);
}
for (UINTN Ind = 0; Ind < SearchSize; Ind++) {
if (Ind < MaskSize)
M = *Mask++;
else M = 0xFF;
if ((*Source++ & M) != (*Search++ & M)) {
return FALSE;
}
}
return TRUE;
}
VOID CopyMemMask(UINT8 *Dest, const UINT8 *Replace, const UINT8 *Mask, UINTN SearchSize)
{
UINT8 M, D;
// the procedure is called from SearchAndReplaceMask with own check but for future it is better to check twice
if (!Dest || !Replace) {
return;
}
if (!Mask) {
CopyMem(Dest, Replace, SearchSize); //old behavior
return;
}
for (UINTN Ind = 0; Ind < SearchSize; Ind++) {
M = *Mask++;
D = *Dest;
*Dest++ = ((D ^ *Replace++) & M) ^ D;
}
}
// search a pattern like
// call task or jmp address
//return the address next to the command
// 0 if not found
UINTN FindRelative32(const UINT8 *Source, UINTN Start, UINTN SourceSize, UINTN taskLocation)
{
INT32 Offset; //can be negative, so 0xFFFFFFFF == -1
for (UINTN i = Start; i < Start + SourceSize - 4; ++i) {
Offset = (INT32)((UINT32)Source[i] + ((UINT32)Source[i+1]<<8) + ((UINT32)Source[i+2]<<16) + ((UINT32)Source[i+3]<<24)); //should not use *(UINT32*) because of alignment
if (taskLocation == i + Offset + 4) {
return (i+4);
}
}
return 0;
}
UINTN FindSection(const UINT8 *Source, UINTN len, const UINT8* seg, const UINT8* sec)
{
BOOLEAN eq;
for (UINTN i = 0x20; i < len; i++) {
eq = TRUE;
for (UINTN j = 0; j < 16 && (sec[j] != 0); j++) {
if (Source[i + j] != sec[j]) {
eq = FALSE;
break;
}
}
if (eq) {
for (UINTN j = 0; j < 16 && (seg[j] != 0); j++) {
if (Source[i + 0x10 + j] != seg[j]) {
eq = FALSE;
break;
}
}
if (eq)
return i + 16;
}
}
return 0;
}
UINTN FindMemMask(const UINT8 *Source, UINTN SourceSize, const UINT8 *Search, UINTN SearchSize, const UINT8 *MaskSearch, UINTN MaskSize)
{
if (!Source || !Search || !SearchSize) {
return KERNEL_MAX_SIZE;
}
for (UINTN i = 0; i < SourceSize - SearchSize; ++i) {
if (CompareMemMask(&Source[i], Search, SearchSize, MaskSearch, MaskSize)) {
return i;
}
}
return KERNEL_MAX_SIZE;
}
UINTN SearchAndReplaceMask(UINT8 *Source, UINT64 SourceSize, const UINT8 *Search, const UINT8 *MaskSearch, UINTN SearchSize,
const UINT8 *Replace, const UINT8 *MaskReplace, INTN MaxReplaces)
{
UINTN NumReplaces = 0;
BOOLEAN NoReplacesRestriction = MaxReplaces <= 0;
UINT8 *End = Source + SourceSize;
if (!Source || !Search || !Replace || !SearchSize) {
return 0;
}
while ((Source < End) && (NoReplacesRestriction || (MaxReplaces > 0))) {
if (CompareMemMask((const UINT8 *)Source, Search, SearchSize, MaskSearch, SearchSize)) {
CopyMemMask(Source, Replace, MaskReplace, SearchSize);
NumReplaces++;
MaxReplaces--;
Source += SearchSize;
} else {
Source++;
}
}
return NumReplaces;
}
UINTN SearchAndReplaceTxt(UINT8 *Source, UINT64 SourceSize, UINT8 *Search, UINTN SearchSize, UINT8 *Replace, INTN MaxReplaces)
{
UINTN NumReplaces = 0;
UINTN Skip = 0;
BOOLEAN NoReplacesRestriction = MaxReplaces <= 0;
UINT8 *End = Source + SourceSize;
UINT8 *SearchEnd = Search + SearchSize;
UINT8 *Pos = NULL;
UINT8 *FirstMatch = Source;
if (!Source || !Search || !Replace || !SearchSize) {
return 0;
}
while (((Source + SearchSize) <= End) &&
(NoReplacesRestriction || (MaxReplaces > 0))) { // num replaces
while (*Source != '\0') { //comparison
Pos = Search;
FirstMatch = Source;
Skip = 0;
while (*Source != '\0' && Pos != SearchEnd) {
if (*Source <= 0x20) { //skip invisibles in sources
Source++;
Skip++;
continue;
}
if (*Source != *Pos) {
break;
}
// printf("%c", *Source);
Source++;
Pos++;
}
if (Pos == SearchEnd) { // pattern found
Pos = FirstMatch;
break;
}
else
Pos = NULL;
Source = FirstMatch + 1;
/* if (Pos != Search) {
printf("\n");
} */
}
if (!Pos) {
break;
}
CopyMem(Pos, Replace, SearchSize);
SetMem(Pos + SearchSize, Skip, 0x20); //fill skip places with spaces
NumReplaces++;
MaxReplaces--;
Source = FirstMatch + SearchSize + Skip;
}
return NumReplaces;
}
/** Global for storing KextBundleIdentifier */
CHAR8 gKextBundleIdentifier[256];
/** Extracts kext BundleIdentifier from given Plist into gKextBundleIdentifier */
VOID ExtractKextBundleIdentifier(CHAR8 *Plist)
{
CHAR8 *Tag;
CHAR8 *BIStart;
CHAR8 *BIEnd;
INTN DictLevel = 0;
gKextBundleIdentifier[0] = '\0';
// start with first <dict>
Tag = AsciiStrStr(Plist, "<dict>");
if (Tag == NULL) {
return;
}
Tag += 6;
DictLevel++;
while (*Tag != '\0') {
if (strncmp(Tag, "<dict>", 6) == 0) {
// opening dict
DictLevel++;
Tag += 6;
} else if (strncmp(Tag, "</dict>", 7) == 0) {
// closing dict
DictLevel--;
Tag += 7;
} else if (DictLevel == 1 && strncmp(Tag, "<key>CFBundleIdentifier</key>", 29) == 0) {
// BundleIdentifier is next <string>...</string>
BIStart = AsciiStrStr(Tag + 29, "<string>");
if (BIStart != NULL) {
BIStart += 8; // skip "<string>"
BIEnd = AsciiStrStr(BIStart, "</string>");
if (BIEnd != NULL && (UINTN)(BIEnd - BIStart + 1) < sizeof(gKextBundleIdentifier)) { // (UINTN)(BIEnd - BIStart + 1) = valid cast because BIEnd is > BIStart
CopyMem(gKextBundleIdentifier, BIStart, BIEnd - BIStart);
gKextBundleIdentifier[BIEnd - BIStart] = '\0';
return;
}
}
Tag++;
} else {
Tag++;
}
// advance to next tag
while (*Tag != '<' && *Tag != '\0') {
Tag++;
}
}
}
BOOLEAN
isPatchNameMatch (CHAR8 *BundleIdentifier, CHAR8 *Name)
{
BOOLEAN isBundle = (AsciiStrStr(Name, ".") != NULL);
return
isBundle
? (AsciiStrCmp(BundleIdentifier, Name) == 0)
: (AsciiStrStr(BundleIdentifier, Name) != NULL);
}
////////////////////////////////////
//
// ATIConnectors patch
//
// bcc9's patch: http://www.insanelymac.com/forum/index.php?showtopic=249642
//
// inited or not?
BOOLEAN ATIConnectorsPatchInited = FALSE;
// ATIConnectorsController's boundle IDs for
// 0: ATI version - Lion, SnowLeo 10.6.7 2011 MBP
// 1: AMD version - ML
CHAR8 ATIKextBundleId[2][64];
//
// Inits patcher: prepares ATIKextBundleIds.
//
VOID LOADER_ENTRY::ATIConnectorsPatchInit()
{
//
// prepar boundle ids
//
// Lion, SnowLeo 10.6.7 2011 MBP
snprintf(ATIKextBundleId[0],
sizeof(ATIKextBundleId[0]),
"com.apple.kext.ATI%sController", // when it was AsciiSPrint, %a was used with KPATIConnectorsController which is CHAR16 ??? Result is printing stop at first char <= 255
//now it is CHAR8*
KernelAndKextPatches->KPATIConnectorsController
);
// ML
snprintf(ATIKextBundleId[1],
sizeof(ATIKextBundleId[1]),
"com.apple.kext.AMD%sController", // when it was AsciiSPrint, %a was used with KPATIConnectorsController which is CHAR16 ??? Result is printing stop at first char <= 255
KernelAndKextPatches->KPATIConnectorsController
);
ATIConnectorsPatchInited = TRUE;
//DBG(L"Bundle1: %s\n", ATIKextBundleId[0]);
//DBG(L"Bundle2: %s\n", ATIKextBundleId[1]);
//gBS->Stall(10000000);
}
//
// Registers kexts that need force-load during WithKexts boot.
//
VOID LOADER_ENTRY::ATIConnectorsPatchRegisterKexts(void *FSInject_v, void *ForceLoadKexts_v)
{
FSINJECTION_PROTOCOL *FSInject = (FSINJECTION_PROTOCOL *)FSInject_v;
FSI_STRING_LIST *ForceLoadKexts = (FSI_STRING_LIST *)ForceLoadKexts_v;
// for future?
FSInject->AddStringToList(ForceLoadKexts,
PoolPrint(L"\\AMD%aController.kext\\Contents\\Info.plist", KernelAndKextPatches->KPATIConnectorsController)
);
// Lion, ML, SnowLeo 10.6.7 2011 MBP
FSInject->AddStringToList(ForceLoadKexts,
PoolPrint(L"\\ATI%aController.kext\\Contents\\Info.plist", KernelAndKextPatches->KPATIConnectorsController)
);
// SnowLeo
FSInject->AddStringToList(ForceLoadKexts, L"\\ATIFramebuffer.kext\\Contents\\Info.plist");
FSInject->AddStringToList(ForceLoadKexts, L"\\AMDFramebuffer.kext\\Contents\\Info.plist");
// dependencies
FSInject->AddStringToList(ForceLoadKexts, L"\\IOGraphicsFamily.kext\\Info.plist");
FSInject->AddStringToList(ForceLoadKexts, L"\\ATISupport.kext\\Contents\\Info.plist");
FSInject->AddStringToList(ForceLoadKexts, L"\\AMDSupport.kext\\Contents\\Info.plist");
FSInject->AddStringToList(ForceLoadKexts, L"\\AppleGraphicsControl.kext\\Info.plist");
FSInject->AddStringToList(ForceLoadKexts, L"\\AppleGraphicsControl.kext\\Contents\\PlugIns\\AppleGraphicsDeviceControl.kext\\Info.plist");
//as well IOAcceleratorFamily2
}
//
// Patch function.
//
VOID LOADER_ENTRY::ATIConnectorsPatch(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize)
{
UINTN Num = 0;
DBG_RT("\nATIConnectorsPatch: driverAddr = %llx, driverSize = %x\nController = %s\n",
(UINTN)Driver, DriverSize, KernelAndKextPatches->KPATIConnectorsController);
ExtractKextBundleIdentifier(InfoPlist);
DBG_RT("Kext: %s\n", gKextBundleIdentifier);
// number of occurences od Data should be 1
Num = SearchAndCount(Driver, DriverSize, KernelAndKextPatches->KPATIConnectorsData, KernelAndKextPatches->KPATIConnectorsDataLen);
if (Num > 1) {
// error message - shoud always be printed
printf("==> KPATIConnectorsData found %llu times in %s - skipping patching!\n", Num, gKextBundleIdentifier);
Stall(5*1000000);
return;
}
// patch
Num = SearchAndReplace(Driver,
DriverSize,
KernelAndKextPatches->KPATIConnectorsData,
KernelAndKextPatches->KPATIConnectorsDataLen,
KernelAndKextPatches->KPATIConnectorsPatch,
1);
if (Num > 0) {
DBG_RT("==> patched %llu times!\n", Num);
} else {
DBG_RT("==> NOT patched!\n");
}
Stall(5000000);
}
////////////////////////////////////
//
// AppleIntelCPUPM patch
//
// fLaked's SpeedStepper patch for Asus (and some other) boards:
// http://www.insanelymac.com/forum/index.php?showtopic=258611
//
// Credits: Samantha/RevoGirl/DHP
// http://www.insanelymac.com/forum/topic/253642-dsdt-for-asus-p8p67-m-pro/page__st__200#entry1681099
// Rehabman corrections 2014
//
const UINT8 MovlE2ToEcx[] = { 0xB9, 0xE2, 0x00, 0x00, 0x00 };
const UINT8 MovE2ToCx[] = { 0x66, 0xB9, 0xE2, 0x00 };
const UINT8 Wrmsr[] = { 0x0F, 0x30 };
VOID LOADER_ENTRY::AppleIntelCPUPMPatch(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize)
{
UINTN Index1;
UINTN Index2;
UINTN Count = 0;
UINTN Start = 0;
UINTN Size = DriverSize;
DBG_RT("\nAppleIntelCPUPMPatch: driverAddr = %llx, driverSize = %x\n", (UINTN)Driver, DriverSize);
// if (KernelAndKextPatches->KPDebug) {
// ExtractKextBundleIdentifier(InfoPlist);
// }
// DBG_RT("Kext: %s\n", gKextBundleIdentifier);
// we should scan only __text __TEXT | Slice -> do this
INTN textName = FindMem(Driver, DriverSize, kPrelinkTextSection, sizeof(kPrelinkTextSection));
if (textName > 0) {
SEGMENT *textSeg = (SEGMENT *)&Driver[textName];
Start = textSeg->fileoff;
Size = textSeg->filesize;
DBG("found __text [%llu,%llu]\n",Start, Size);
if (Start > DriverSize) Start = 0;
if (Size > DriverSize) {
Size = DriverSize;
}
}
for (Index1 = Start; Index1 < Start + Size; Index1++) {
// search for MovlE2ToEcx
if (CompareMem(Driver + Index1, MovlE2ToEcx, sizeof(MovlE2ToEcx)) == 0) {
// search for wrmsr in next few bytes
for (Index2 = Index1 + sizeof(MovlE2ToEcx); Index2 < Index1 + sizeof(MovlE2ToEcx) + 32; Index2++) {
if (Driver[Index2] == Wrmsr[0] && Driver[Index2 + 1] == Wrmsr[1]) {
// found it - patch it with nops
Count++;
Driver[Index2] = 0x90;
Driver[Index2 + 1] = 0x90;
DBG_RT(" %llu. patched at 0x%llx\n", Count, Index2);
break;
} else if ((Driver[Index2] == 0xC9 && Driver[Index2 + 1] == 0xC3) ||
(Driver[Index2] == 0x5D && Driver[Index2 + 1] == 0xC3) ||
(Driver[Index2] == 0xB9 && Driver[Index2 + 3] == 0 && Driver[Index2 + 4] == 0) ||
(Driver[Index2] == 0x66 && Driver[Index2 + 1] == 0xB9 && Driver[Index2 + 3] == 0)) {
// a leave/ret will cancel the search
// so will an intervening "mov[l] $xx, [e]cx"
break;
}
}
} else if (CompareMem(Driver + Index1, MovE2ToCx, sizeof(MovE2ToCx)) == 0) {
// search for wrmsr in next few bytes
for (Index2 = Index1 + sizeof(MovE2ToCx); Index2 < Index1 + sizeof(MovE2ToCx) + 32; Index2++) {
if (Driver[Index2] == Wrmsr[0] && Driver[Index2 + 1] == Wrmsr[1]) {
// found it - patch it with nops
Count++;
Driver[Index2] = 0x90;
Driver[Index2 + 1] = 0x90;
DBG_RT(" %llu. patched CX at 0x%llx\n", Count, Index2);
break;
} else if ((Driver[Index2] == 0xC9 && Driver[Index2 + 1] == 0xC3) ||
(Driver[Index2] == 0x5D && Driver[Index2 + 1] == 0xC3) ||
(Driver[Index2] == 0xB9 && Driver[Index2 + 3] == 0 && Driver[Index2 + 4] == 0) ||
(Driver[Index2] == 0x66 && Driver[Index2 + 1] == 0xB9 && Driver[Index2 + 3] == 0)) {
// a leave/ret will cancel the search
// so will an intervening "mov[l] $xx, [e]cx"
break;
}
}
}
}
DBG_RT("= %llu patches\n", Count);
Stall(5000000);
}
////////////////////////////////////
//
// AppleRTC patch to prevent CMOS reset
//
// http://www.insanelymac.com/forum/index.php?showtopic=253992
// http://www.insanelymac.com/forum/index.php?showtopic=276066
//
#if OLD_METHOD
const UINT8 LionSearch_X64[] = { 0x75, 0x30, 0x44, 0x89, 0xf8 };
const UINT8 LionReplace_X64[] = { 0xeb, 0x30, 0x44, 0x89, 0xf8 };
const UINT8 LionSearch_i386[] = { 0x75, 0x3d, 0x8b, 0x75, 0x08 };
const UINT8 LionReplace_i386[] = { 0xeb, 0x3d, 0x8b, 0x75, 0x08 };
const UINT8 MLSearch[] = { 0x75, 0x30, 0x89, 0xd8 };
const UINT8 MLReplace[] = { 0xeb, 0x30, 0x89, 0xd8 };
// SunKi: 10.9 - 10.14.3
const UINT8 MavMoj3Search[] = { 0x75, 0x2e, 0x0f, 0xb6 };
const UINT8 MavMoj3Replace[] = { 0xeb, 0x2e, 0x0f, 0xb6 };
// RodionS: 10.14.4+ / 10.15 DB1
const UINT8 Moj4CataSearch[] = { 0x75, 0x33, 0x0f, 0xb7 };
const UINT8 Moj4CataReplace[] = { 0xeb, 0x33, 0x0f, 0xb7 };
#endif
//
// We can not rely on OSVersion global variable for OS version detection,
// since in some cases it is not correct (install of ML from Lion, for example). -- AppleRTC patch is not needed for installation
// So, we'll use "brute-force" method - just try to patch.
// Actually, we'll at least check that if we can find only one instance of code that
// we are planning to patch.
//
VOID LOADER_ENTRY::AppleRTCPatch(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize)
{
#if OLD_METHOD
UINTN Num = 0;
UINTN NumLion_X64 = 0;
UINTN NumLion_i386 = 0;
UINTN NumML = 0;
UINTN NumMavMoj3 = 0;
UINTN NumMoj4 = 0;
DBG_RT("\nAppleRTCPatch: driverAddr = %llx, driverSize = %x\n", (UINTN)Driver, DriverSize);
if (KernelAndKextPatches->KPDebug) {
ExtractKextBundleIdentifier(InfoPlist);
}
DBG_RT("Kext: %s\n", gKextBundleIdentifier);
if (is64BitKernel) {
NumLion_X64 = SearchAndCount(Driver, DriverSize, LionSearch_X64, sizeof(LionSearch_X64));
NumML = SearchAndCount(Driver, DriverSize, MLSearch, sizeof(MLSearch));
NumMavMoj3 = SearchAndCount(Driver, DriverSize, MavMoj3Search, sizeof(MavMoj3Search));
NumMoj4 = SearchAndCount(Driver, DriverSize, Moj4CataSearch, sizeof(Moj4CataSearch));
} else {
NumLion_i386 = SearchAndCount(Driver, DriverSize, LionSearch_i386, sizeof(LionSearch_i386));
}
if (NumLion_X64 + NumLion_i386 + NumML + NumMavMoj3 + NumMoj4 > 1) {
// more then one pattern found - we do not know what to do with it
// and we'll skip it
printf("AppleRTCPatch: ERROR: multiple patterns found (LionX64: %llu, Lioni386: %llu, ML: %llu, MavMoj3: %llu, Moj4: %llu) - skipping patching!\n",
NumLion_X64, NumLion_i386, NumML, NumMavMoj3, NumMoj4);
Stall(5000000);
return;
}
if (NumLion_X64 == 1) {
Num = SearchAndReplace(Driver, DriverSize, LionSearch_X64, sizeof(LionSearch_X64), LionReplace_X64, 1);
DBG_RT("==> Lion X64: %llu replaces done.\n", Num);
} else if (NumLion_i386 == 1) {
Num = SearchAndReplace(Driver, DriverSize, LionSearch_i386, sizeof(LionSearch_i386), LionReplace_i386, 1);
DBG_RT("==> Lion i386: %llu replaces done.\n", Num);
} else if (NumML == 1) {
Num = SearchAndReplace(Driver, DriverSize, MLSearch, sizeof(MLSearch), MLReplace, 1);
DBG_RT("==> MountainLion X64: %llu replaces done.\n", Num);
} else if (NumMavMoj3 == 1) {
Num = SearchAndReplace(Driver, DriverSize, MavMoj3Search, sizeof(MavMoj3Search), MavMoj3Replace, 1);
DBG_RT("==> Mav/Yos/El/Sie/HS/Moj3 X64: %llu replaces done.\n", Num);
} else if (NumMoj4 == 1) {
Num = SearchAndReplace(Driver, DriverSize, Moj4CataSearch, sizeof(Moj4CataSearch), Moj4CataReplace, 1);
DBG_RT("==> Mojave4 X64: %llu replaces done.\n", Num);
} else {
DBG_RT("==> Patterns not found - patching NOT done.\n");
}
#else
//RodionS
UINTN procLocation = searchProcInDriver(Driver, DriverSize, "updateChecksum");
DBG("updateChecksum at 0x%llx", procLocation);
if (procLocation != 0) {
Driver[procLocation] = 0xC3;
DBG_RT("AppleRTC: patched\n");
} else {
DBG_RT("AppleRTC: not patched\n");
}
#endif
Stall(5000000);
}
///////////////////////////////////
//
// InjectKexts if no FakeSMC: Detect FakeSMC and if present then
// disable kext injection InjectKexts()
//
// not used since 4242
#if 0
VOID LOADER_ENTRY::CheckForFakeSMC(CHAR8 *InfoPlist)
{
if (OSFLAG_ISSET(Flags, OSFLAG_CHECKFAKESMC) &&
OSFLAG_ISSET(Flags, OSFLAG_WITHKEXTS)) {
if (AsciiStrStr(InfoPlist, "<string>org.netkas.driver.FakeSMC</string>") != NULL
|| AsciiStrStr(InfoPlist, "<string>org.netkas.FakeSMC</string>") != NULL
|| AsciiStrStr(InfoPlist, "<string>as.vit9696.VirtualSMC</string>") != NULL)
{
Flags = OSFLAG_UNSET(Flags, OSFLAG_WITHKEXTS);
DBG_RT("\nFakeSMC or VirtualSMC found, UNSET WITHKEXTS\n");
Stall(5000000);
}
}
}
#endif
////////////////////////////////////
//
// Dell SMBIOS Patch by syscl
//
// Remap SMBIOS Table 1 for both AppleSMBIOS and AppleACPIPlatform
//
// EB9D2D31-2D88-11D3-9A16-0090273F -> EB9D2D35-2D88-11D3-9A16-0090273F
//
STATIC UINT8 DELL_SMBIOS_GUID_Search[] = { 0x45, 0x42, 0x39, 0x44, 0x32, 0x44, 0x33, 0x31 };
STATIC UINT8 DELL_SMBIOS_GUID_Replace[] = { 0x45, 0x42, 0x39, 0x44, 0x32, 0x44, 0x33, 0x35 };
//
// EB9D2D31-2D88-11D3-9A16-0090273F is the standard SMBIOS Table Type 1 for
// all computers even though Apple.Inc should obey the rule
// that's why we can be so confident to write patch pattern this way - syscl
//
VOID LOADER_ENTRY::DellSMBIOSPatch(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize)
{
//
// syscl
// Note, smbios truncate issue only affects Broadwell platform and platform
// later than Broadwell thus we don't need to consider OS versinos earlier
// than Yosemite, they are all pure 64bit platforms
//
UINTN gPatchCount = 0;
DBG_RT("\nDellSMBIOSPatch: driverAddr = %llx, driverSize = %x\n", (UINTN)Driver, DriverSize);
if (KernelAndKextPatches->KPDebug)
{
ExtractKextBundleIdentifier(InfoPlist);
}
DBG_RT("Kext: %s\n", gKextBundleIdentifier);
//
// now, let's patch it!
//
gPatchCount = SearchAndReplace(Driver, DriverSize, DELL_SMBIOS_GUID_Search, sizeof(DELL_SMBIOS_GUID_Search), DELL_SMBIOS_GUID_Replace, 1);
if (gPatchCount >= 1)
{
DBG_RT("==> AppleSMBIOS: %llu replaces done.\n", gPatchCount);
}
else
{
DBG_RT("==> Patterns not found - patching NOT done.\n");
}
Stall(5000000);
}
////////////////////////////////////
//
// SNBE_AICPUPatch implemented by syscl
// Fix AppleIntelCPUPowerManagement on SandyBridge-E (c) omni, stinga11
//
VOID LOADER_ENTRY::SNBE_AICPUPatch(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize)
{
UINT32 i;
UINT64 os_ver = AsciiOSVersionToUint64(OSVersion);
DBG_RT("\nSNBE_AICPUPatch: driverAddr = %llx, driverSize = %x\n", (UINTN)Driver, DriverSize);
if (KernelAndKextPatches->KPDebug) {
ExtractKextBundleIdentifier(InfoPlist);
}
DBG_RT("Kext: %s\n", gKextBundleIdentifier);
// now let's patch it
if (os_ver < AsciiOSVersionToUint64("10.9") || os_ver >= AsciiOSVersionToUint64("10.14")) {
DBG("Unsupported macOS.\nSandyBridge-E requires macOS 10.9 - 10.13.x, aborted\n");
DBG("SNBE_AICPUPatch() <===FALSE\n");
return;
}
if (os_ver < AsciiOSVersionToUint64("10.10")) {
// 10.9.x
const UINT8 find[][3] = {
{ 0x84, 0x2F, 0x01 },
{ 0x3E, 0x75, 0x3A },
{ 0x84, 0x5F, 0x01 },
{ 0x74, 0x10, 0xB9 },
{ 0x75, 0x07, 0xB9 },
{ 0xFC, 0x02, 0x74 },
{ 0x01, 0x74, 0x58 }
};
const UINT8 repl[][3] = {
{ 0x85, 0x2F, 0x01 },
{ 0x3E, 0x90, 0x90 },
{ 0x85, 0x5F, 0x01 },
{ 0xEB, 0x10, 0xB9 },
{ 0xEB, 0x07, 0xB9 },
{ 0xFC, 0x02, 0xEB },
{ 0x01, 0xEB, 0x58 }
};
for (i = 0; i < 7; i++) {
if (SearchAndReplace(Driver, DriverSize, find[i], sizeof(find[i]), repl[i], 0)) {
DBG("SNBE_AICPUPatch (%d/7) applied\n", i);
} else {
DBG("SNBE_AICPUPatch (%d/7) not apply\n", i);
}
}
} else if (os_ver < AsciiOSVersionToUint64("10.11")) {
// 10.10.x
const UINT8 find[][3] = {
{ 0x3E, 0x75, 0x39 },
{ 0x74, 0x11, 0xB9 },
{ 0x01, 0x74, 0x56 }
};
const UINT8 repl[][3] = {
{ 0x3E, 0x90, 0x90 },
{ 0xEB, 0x11, 0xB9 },
{ 0x01, 0xEB, 0x56 }
};
for (i = 0; i < 3; i++) {
if (SearchAndReplace(Driver, DriverSize, find[i], sizeof(find[i]), repl[i], 0)) {
DBG("SNBE_AICPUPatch (%d/7) applied\n", i);
} else {
DBG("SNBE_AICPUPatch (%d/7) not apply\n", i);
}
}
const UINT8 find_1[] = { 0xFF, 0x0F, 0x84, 0x2D };
const UINT8 repl_1[] = { 0xFF, 0x0F, 0x85, 0x2D };
if (SearchAndReplace(Driver, DriverSize, find_1, sizeof(find_1), repl_1, 0)) {
DBG("SNBE_AICPUPatch (4/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (4/7) not apply\n");
}
const UINT8 find_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x84 };
const UINT8 repl_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x85 };
if (SearchAndReplace(Driver, DriverSize, find_2, sizeof(find_2), repl_2, 0)) {
DBG("SNBE_AICPUPatch (5/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (5/7) not apply\n");
}
const UINT8 find_3[] = { 0x02, 0x74, 0x0B, 0x41, 0x83, 0xFC, 0x03, 0x75, 0x22, 0xB9, 0x02, 0x06 };
const UINT8 repl_3[] = { 0x02, 0xEB, 0x0B, 0x41, 0x83, 0xFC, 0x03, 0x75, 0x22, 0xB9, 0x02, 0x06 };
if (SearchAndReplace(Driver, DriverSize, find_3, sizeof(find_3), repl_3, 0)) {
DBG("SNBE_AICPUPatch (6/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (6/7) not apply\n");
}
const UINT8 find_4[] = { 0x74, 0x0B, 0x41, 0x83, 0xFC, 0x03, 0x75, 0x11, 0xB9, 0x42, 0x06, 0x00 };
const UINT8 repl_4[] = { 0xEB, 0x0B, 0x41, 0x83, 0xFC, 0x03, 0x75, 0x11, 0xB9, 0x42, 0x06, 0x00 };
if (SearchAndReplace(Driver, DriverSize, find_4, sizeof(find_4), repl_4, 0)) {
DBG("SNBE_AICPUPatch (7/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (7/7) not apply\n");
}
} else if (os_ver < AsciiOSVersionToUint64("10.12")) {
// 10.11
const UINT8 find[][3] = {
{ 0x3E, 0x75, 0x39 },
{ 0x75, 0x11, 0xB9 },
{ 0x01, 0x74, 0x5F }
};
const UINT8 repl[][3] = {
{ 0x3E, 0x90, 0x90 },
{ 0xEB, 0x11, 0xB9 },
{ 0x01, 0xEB, 0x5F }
};
for (i = 0; i < 3; i++) {
if (SearchAndReplace(Driver, DriverSize, find[i], sizeof(find[i]), repl[i], 0)) {
DBG("SNBE_AICPUPatch (%d/7) applied\n", i);
} else {
DBG("SNBE_AICPUPatch (%d/7) not apply\n", i);
}
}
const UINT8 find_1[] = { 0xFF, 0x0F, 0x84, 0x2D };
const UINT8 repl_1[] = { 0xFF, 0x0F, 0x85, 0x2D };
if (SearchAndReplace(Driver, DriverSize, find_1, sizeof(find_1), repl_1, 0)) {
DBG("SNBE_AICPUPatch (4/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (4/7) not apply\n");
}
const UINT8 find_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x84 };
const UINT8 repl_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x85 };
if (SearchAndReplace(Driver, DriverSize, find_2, sizeof(find_2), repl_2, 0)) {
DBG("SNBE_AICPUPatch (5/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (5/7) not apply\n");
}
const UINT8 find_3[] = { 0xC9, 0x74, 0x16, 0x0F, 0x32, 0x48, 0x25, 0xFF, 0x0F, 0x00, 0x00, 0x48 };
const UINT8 repl_3[] = { 0xC9, 0xEB, 0x16, 0x0F, 0x32, 0x48, 0x25, 0xFF, 0x0F, 0x00, 0x00, 0x48 };
if (SearchAndReplace(Driver, DriverSize, find_3, sizeof(find_3), repl_3, 0)) {
DBG("SNBE_AICPUPatch (6/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (6/7) not apply\n");
}
const UINT8 find_4[] = { 0xC9, 0x74, 0x0C, 0x0F, 0x32, 0x83, 0xE0, 0x1F, 0x42, 0x89, 0x44, 0x3B };
const UINT8 repl_4[] = { 0xC9, 0xEB, 0x0C, 0x0F, 0x32, 0x83, 0xE0, 0x1F, 0x42, 0x89, 0x44, 0x3B };
if (SearchAndReplace(Driver, DriverSize, find_4, sizeof(find_4), repl_4, 0)) {
DBG("SNBE_AICPUPatch (7/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (7/7) not apply\n");
}
} else if (os_ver < AsciiOSVersionToUint64("10.13")) {
// 10.12
const UINT8 find[][3] = {
{ 0x01, 0x74, 0x61 },
{ 0x3E, 0x75, 0x38 },
{ 0x75, 0x11, 0xB9 }
};
const UINT8 repl[][3] = {
{ 0x01, 0xEB, 0x61 },
{ 0x3E, 0x90, 0x90 },
{ 0xEB, 0x11, 0xB9 }
};
for (i = 0; i < 3; i++) {
if (SearchAndReplace(Driver, DriverSize, find[i], sizeof(find[i]), repl[i], 0)) {
DBG("SNBE_AICPUPatch (%d/7) applied\n", i);
} else {
DBG("SNBE_AICPUPatch (%d/7) not apply\n", i);
}
}
const UINT8 find_1[] = { 0xFF, 0x0F, 0x84, 0x2D };
const UINT8 repl_1[] = { 0xFF, 0x0F, 0x85, 0x2D };
if (SearchAndReplace(Driver, DriverSize, find_1, sizeof(find_1), repl_1, 0)) {
DBG("SNBE_AICPUPatch (4/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (4/7) not apply\n");
}
const UINT8 find_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x84 };
const UINT8 repl_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x85 };
if (SearchAndReplace(Driver, DriverSize, find_2, sizeof(find_2), repl_2, 0)) {
DBG("SNBE_AICPUPatch (5/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (5/7) not apply\n");
}
const UINT8 find_3[] = { 0xC9, 0x74, 0x15, 0x0F, 0x32, 0x25, 0xFF, 0x0F, 0x00, 0x00, 0x48 };
const UINT8 repl_3[] = { 0xC9, 0xEB, 0x15, 0x0F, 0x32, 0x25, 0xFF, 0x0F, 0x00, 0x00, 0x48 };
if (SearchAndReplace(Driver, DriverSize, find_3, sizeof(find_3), repl_3, 0)) {
DBG("SNBE_AICPUPatch (6/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (6/7) not apply\n");
}
const UINT8 find_4[] = { 0xC9, 0x74, 0x0C, 0x0F, 0x32, 0x83, 0xE0, 0x1F, 0x42, 0x89, 0x44, 0x3B };
const UINT8 repl_4[] = { 0xC9, 0xEB, 0x0C, 0x0F, 0x32, 0x83, 0xE0, 0x1F, 0x42, 0x89, 0x44, 0x3B };
if (SearchAndReplace(Driver, DriverSize, find_4, sizeof(find_4), repl_4, 0)) {
DBG("SNBE_AICPUPatch (7/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (7/7) not apply\n");
}
} else if (os_ver < AsciiOSVersionToUint64("10.15")) {
// 10.13/10.14
const UINT8 find[][3] = {
{ 0x01, 0x74, 0x61 },
{ 0x3E, 0x75, 0x38 },
{ 0x75, 0x11, 0xB9 }
};
const UINT8 repl[][3] = {
{ 0x01, 0xEB, 0x61 },
{ 0x3E, 0x90, 0x90 },
{ 0xEB, 0x11, 0xB9 }
};
for (i = 0; i < 3; i++) {
if (SearchAndReplace(Driver, DriverSize, find[i], sizeof(find[i]), repl[i], 0)) {
DBG("SNBE_AICPUPatch (%d/7) applied\n", i);
} else {
DBG("SNBE_AICPUPatch (%d/7) not apply\n", i);
}
}
const UINT8 find_1[] = { 0xFF, 0x0F, 0x84, 0xD3 };
const UINT8 repl_1[] = { 0xFF, 0x0F, 0x85, 0xD3 };
if (SearchAndReplace(Driver, DriverSize, find_1, sizeof(find_1), repl_1, 0)) {
DBG("SNBE_AICPUPatch (4/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (4/7) not apply\n");
}
const UINT8 find_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x84 };
const UINT8 repl_2[] = { 0x01, 0x00, 0x01, 0x0F, 0x85 };
if (SearchAndReplace(Driver, DriverSize, find_2, sizeof(find_2), repl_2, 0)) {
DBG("SNBE_AICPUPatch (5/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (5/7) not apply\n");
}
const UINT8 find_3[] = { 0xC9, 0x74, 0x14, 0x0F, 0x32, 0x25, 0xFF, 0x0F, 0x00, 0x00, 0x6B };
const UINT8 repl_3[] = { 0xC9, 0xEB, 0x14, 0x0F, 0x32, 0x25, 0xFF, 0x0F, 0x00, 0x00, 0x6B};
if (SearchAndReplace(Driver, DriverSize, find_3, sizeof(find_3), repl_3, 0)) {
DBG("SNBE_AICPUPatch (6/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (6/7) not apply\n");
}
const UINT8 find_4[] = { 0xC9, 0x74, 0x0C, 0x0F, 0x32, 0x83, 0xE0, 0x1F, 0x42, 0x89, 0x44, 0x3B };
const UINT8 repl_4[] = { 0xC9, 0xEB, 0x0C, 0x0F, 0x32, 0x83, 0xE0, 0x1F, 0x42, 0x89, 0x44, 0x3B };
if (SearchAndReplace(Driver, DriverSize, find_4, sizeof(find_4), repl_4, 0)) {
DBG("SNBE_AICPUPatch (7/7) applied\n");
} else {
DBG("SNBE_AICPUPatch (7/7) not apply\n");
}
}
Stall(5000000);
}
////////////////////////////////////
//
// BDWE_IOPCIPatch implemented by syscl
// Fix Broadwell-E IOPCIFamily issue
//
// El Capitan
const UINT8 BroadwellE_IOPCI_Find_El[] = { 0x48, 0x81, 0xF9, 0x01, 0x00, 0x00, 0x40 };
const UINT8 BroadwellE_IOPCI_Repl_El[] = { 0x48, 0x81, 0xF9, 0x01, 0x00, 0x00, 0x80 };
// Sierra/High Sierra
const UINT8 BroadwellE_IOPCI_Find_SieHS[] = { 0x48, 0x81, 0xFB, 0x00, 0x00, 0x00, 0x40 };
const UINT8 BroadwellE_IOPCI_Repl_SieHS[] = { 0x48, 0x81, 0xFB, 0x00, 0x00, 0x00, 0x80 };
// Mojave
const UINT8 BroadwellE_IOPCI_Find_MojCata[] = { 0x48, 0x3D, 0x00, 0x00, 0x00, 0x40 };
const UINT8 BroadwellE_IOPCI_Repl_MojCata[] = { 0x48, 0x3D, 0x00, 0x00, 0x00, 0x80 };
VOID LOADER_ENTRY::BDWE_IOPCIPatch(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize)
{
UINTN count = 0;
UINT64 os_ver = AsciiOSVersionToUint64(OSVersion);
DBG_RT("\nBDWE_IOPCIPatch: driverAddr = %llx, driverSize = %x\n", (UINTN)Driver, DriverSize);
if (KernelAndKextPatches->KPDebug) {
ExtractKextBundleIdentifier(InfoPlist);
}
DBG_RT("Kext: %s\n", gKextBundleIdentifier);
//
// now, let's patch it!
//
if (os_ver < AsciiOSVersionToUint64("10.12")) {
count = SearchAndReplace(Driver, DriverSize, BroadwellE_IOPCI_Find_El, sizeof(BroadwellE_IOPCI_Find_El), BroadwellE_IOPCI_Repl_El, 0);
} else if (os_ver < AsciiOSVersionToUint64("10.14")) {
count = SearchAndReplace(Driver, DriverSize, BroadwellE_IOPCI_Find_SieHS, sizeof(BroadwellE_IOPCI_Find_SieHS), BroadwellE_IOPCI_Repl_SieHS, 0);
} else {
count = SearchAndReplace(Driver, DriverSize, BroadwellE_IOPCI_Find_MojCata, sizeof(BroadwellE_IOPCI_Find_MojCata), BroadwellE_IOPCI_Repl_MojCata, 0);
}
if (count) {
DBG_RT("==> IOPCIFamily: %llu replaces done.\n", count);
} else {
DBG_RT("==> Patterns not found - patching NOT done.\n");
}
Stall(5000000);
}
VOID LOADER_ENTRY::EightApplePatch(UINT8 *Driver, UINT32 DriverSize)
{
// UINTN procLen = 0;
DBG("8 apple patch\n");
UINTN procAddr = searchProcInDriver(Driver, DriverSize, "initFB");
UINTN verbose = searchProcInDriver(Driver, DriverSize, "gIOFBVerboseBoot");
UINTN patchLoc = FindRelative32(Driver, procAddr, 0x300, verbose-1);
if (patchLoc != 0 && Driver[patchLoc + 1] == 0x75) {
Driver[patchLoc + 1] = 0xEB;
DBG("8 apples patch success\n");
} else {
DBG("8 apples patch not found, loc=0x%llx\n", patchLoc);
// if (patchLoc != 0) {
// for (int i=0; i<10; ++i) {
// DBG_RT("%02x", Driver[patchLoc+i]);
// }
// DBG_RT("\n");
// } else if (procAddr != 0) {
// for (int i=0; i<10; ++i) {
// DBG_RT("%02x", Driver[procAddr+i]);
// }
// DBG_RT("\n");
// }
// DBG_RT(" procAddr=0x%llx\n", procAddr);
// DBG_RT(" verbose=0x%llx\n", verbose);
// Stall(20000000);
}
Stall(5000000);
}
////////////////////////////////////
//
// Place other kext patches here
//
// ...
////////////////////////////////////
//
// Generic kext patch functions
//
//
VOID LOADER_ENTRY::AnyKextPatch(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize, INT32 N)
{
UINTN Num = 0;
INTN Ind;
// if we modify value directly at KernelAndKextPatches->KextPatches[N].SearchLen, it will be wrong for next driver
UINTN SearchLen = KernelAndKextPatches->KextPatches[N].SearchLen;
DBG_RT("\nAnyKextPatch %d: driverAddr = %llx, driverSize = %x\nAnyKext = %s\n",
N, (UINTN)Driver, DriverSize, KernelAndKextPatches->KextPatches[N].Label);
DBG("\nAnyKextPatch %d: driverAddr = %llx, driverSize = %x\nLabel = %s\n",
N, (UINTN)Driver, DriverSize, KernelAndKextPatches->KextPatches[N].Label);
if (!KernelAndKextPatches->KextPatches[N].MenuItem.BValue) {
return;
}
if (!SearchLen ||
(SearchLen > DriverSize)) {
SearchLen = DriverSize;
}
if (KernelAndKextPatches->KPDebug) {
ExtractKextBundleIdentifier(InfoPlist);
}
DBG_RT("Kext: %s\n", gKextBundleIdentifier);
if (!KernelAndKextPatches->KextPatches[N].IsPlistPatch) {
// kext binary patch
DBG_RT("Binary patch\n");
bool once = false;
UINTN procLen = 0;
UINTN procAddr = searchProcInDriver(Driver, DriverSize, KernelAndKextPatches->KextPatches[N].ProcedureName);
if (SearchLen == DriverSize) {
procLen = DriverSize - procAddr;
once = true;
} else {
procLen = SearchLen;
}
UINT8 * curs = &Driver[procAddr];
UINTN j = 0;
while (j < DriverSize) {
if (!KernelAndKextPatches->KextPatches[N].StartPattern || //old behavior
CompareMemMask((const UINT8*)curs,
(const UINT8 *)KernelAndKextPatches->KextPatches[N].StartPattern,
KernelAndKextPatches->KextPatches[N].StartPatternLen,
(const UINT8 *)KernelAndKextPatches->KextPatches[N].StartMask,
KernelAndKextPatches->KextPatches[N].StartPatternLen)) {
DBG_RT(" StartPattern found\n");
Num = SearchAndReplaceMask(curs,
procLen,
(const UINT8*)KernelAndKextPatches->KextPatches[N].Data,
(const UINT8*)KernelAndKextPatches->KextPatches[N].MaskFind,
KernelAndKextPatches->KextPatches[N].DataLen,
(const UINT8*)KernelAndKextPatches->KextPatches[N].Patch,
(const UINT8*)KernelAndKextPatches->KextPatches[N].MaskReplace,
-1);
if (Num) {
curs += SearchLen - 1;
j += SearchLen - 1;
}
}
if (once ||
!KernelAndKextPatches->KextPatches[N].StartPattern ||
!KernelAndKextPatches->KextPatches[N].StartPatternLen) {
break;
}
j++; curs++;
}
} else {
// Info plist patch
DBG_RT("Info.plist data : '");
for (Ind = 0; Ind < KernelAndKextPatches->KextPatches[N].DataLen; Ind++) {
DBG_RT("%c", KernelAndKextPatches->KextPatches[N].Data[Ind]);
}
DBG_RT("' ->\n");
DBG_RT("Info.plist patch: '");
for (Ind = 0; Ind < KernelAndKextPatches->KextPatches[N].DataLen; Ind++) {
DBG_RT("%c", KernelAndKextPatches->KextPatches[N].Patch[Ind]);
}
DBG_RT("' \n");
Num = SearchAndReplaceTxt((UINT8*)InfoPlist,
InfoPlistSize,
KernelAndKextPatches->KextPatches[N].Data,
KernelAndKextPatches->KextPatches[N].DataLen,
KernelAndKextPatches->KextPatches[N].Patch,
-1);
}
if (KernelAndKextPatches->KPDebug) {
if (Num > 0) {
DBG_RT("==> patched %llu times!\n", Num);
} else {
DBG_RT("==> NOT patched!\n");
}
gBS->Stall(2000000);
}
}
//
// Called from SetFSInjection(), before boot.efi is started,
// to allow patchers to prepare FSInject to force load needed kexts.
//
VOID LOADER_ENTRY::KextPatcherRegisterKexts(void *FSInject_v, void *ForceLoadKexts)
{
FSINJECTION_PROTOCOL *FSInject = (FSINJECTION_PROTOCOL *)FSInject_v;
if (KernelAndKextPatches->KPATIConnectorsController != NULL) {
ATIConnectorsPatchRegisterKexts(FSInject_v, ForceLoadKexts);
}
for (INTN i = 0; i < KernelAndKextPatches->NrKexts; i++) {
FSInject->AddStringToList((FSI_STRING_LIST*)ForceLoadKexts,
PoolPrint(L"\\%a.kext\\Contents\\Info.plist",
KernelAndKextPatches->KextPatches[i].Name) );
}
}
//
// PatchKext is called for every kext from prelinked kernel (kernelcache) or from DevTree (booting with drivers).
// Add kext detection code here and call kext specific patch function.
//
VOID LOADER_ENTRY::PatchKext(UINT8 *Driver, UINT32 DriverSize, CHAR8 *InfoPlist, UINT32 InfoPlistSize)
{
if (KernelAndKextPatches->KPATIConnectorsController != NULL) {
//
// ATIConnectors
//
if (!ATIConnectorsPatchInited) {
ATIConnectorsPatchInit();
}
if ( AsciiStrStr(InfoPlist, ATIKextBundleId[0]) != NULL // ATI boundle id
|| AsciiStrStr(InfoPlist, ATIKextBundleId[1]) != NULL // AMD boundle id
|| AsciiStrStr(InfoPlist, "com.apple.kext.ATIFramebuffer") != NULL // SnowLeo
|| AsciiStrStr(InfoPlist, "com.apple.kext.AMDFramebuffer") != NULL //Maverics
) {
ATIConnectorsPatch(Driver, DriverSize, InfoPlist, InfoPlistSize);
return;
}
}
ExtractKextBundleIdentifier(InfoPlist);
if (KernelAndKextPatches->KPAppleIntelCPUPM &&
(AsciiStrStr(InfoPlist,
"<string>com.apple.driver.AppleIntelCPUPowerManagement</string>") != NULL)) {
//
// AppleIntelCPUPM
//
AppleIntelCPUPMPatch(Driver, DriverSize, InfoPlist, InfoPlistSize);
} else if (KernelAndKextPatches->KPAppleRTC &&
(AsciiStrStr(InfoPlist, "com.apple.driver.AppleRTC") != NULL)) {
//
// AppleRTC
//
AppleRTCPatch(Driver, DriverSize, InfoPlist, InfoPlistSize);
} else if (KernelAndKextPatches->KPDELLSMBIOS &&
(AsciiStrStr(InfoPlist, "com.apple.driver.AppleSMBIOS") != NULL)) {
//
// DellSMBIOSPatch
//
DBG_RT("Remap SMBIOS Table require, AppleSMBIOS...\n");
DellSMBIOSPatch(Driver, DriverSize, InfoPlist, InfoPlistSize);
} else if (KernelAndKextPatches->KPDELLSMBIOS &&
(AsciiStrStr(InfoPlist, "com.apple.driver.AppleACPIPlatform") != NULL)) {
//
// DellSMBIOS
//
// AppleACPIPlatform
//
DellSMBIOSPatch(Driver, DriverSize, InfoPlist, InfoPlistSize);
} else if (gBDWEIOPCIFixRequire && (AsciiStrStr(InfoPlist, "com.apple.iokit.IOPCIFamily") != NULL)) {
//
// Broadwell-E IOPCIFamily Patch
//
BDWE_IOPCIPatch(Driver, DriverSize, InfoPlist, InfoPlistSize);
} else if (gSNBEAICPUFixRequire && (AsciiStrStr(InfoPlist, "com.apple.driver.AppleIntelCPUPowerManagement") != NULL)) {
//
// SandyBridge-E AppleIntelCPUPowerManagement Patch implemented by syscl
//
SNBE_AICPUPatch(Driver, DriverSize, InfoPlist, InfoPlistSize);
} else if (KernelAndKextPatches->EightApple &&
/* (AsciiStrStr(InfoPlist, "com.apple.iokit.IOGraphicsFamily") != NULL) && */
(AsciiStrStr(InfoPlist, "I/O Kit Graphics Family") != NULL)) {
//
// Patch against 8 apple glitch
//
DBG_RT("Patch 8 apple required, IOGraphicsFamily...\n");
EightApplePatch(Driver, DriverSize);
Stall(10000000);
}
//com.apple.iokit.IOGraphicsFamily
for (INT32 i = 0; i < KernelAndKextPatches->NrKexts; i++) {
CHAR8 *Name = KernelAndKextPatches->KextPatches[i].Name;
BOOLEAN isBundle = (AsciiStrStr(Name, ".") != NULL);
if ((KernelAndKextPatches->KextPatches[i].DataLen > 0) &&
isBundle?(AsciiStrCmp(gKextBundleIdentifier, Name) == 0):(AsciiStrStr(gKextBundleIdentifier, Name) != NULL)) {
// (AsciiStrStr(InfoPlist, KernelAndKextPatches->KextPatches[i].Name) != NULL)) {
DBG_RT("\n\nPatch kext: %s\n", KernelAndKextPatches->KextPatches[i].Name);
AnyKextPatch(Driver, DriverSize, InfoPlist, InfoPlistSize, i);
}
}
}
//
// Returns parsed hex integer key.
// Plist - kext pist
// Key - key to find
// WholePlist - _PrelinkInfoDictionary, used to find referenced values
//
// Searches for Key in Plist and it's value:
// a) <integer ID="26" size="64">0x2b000</integer>
// returns 0x2b000
// b) <integer IDREF="26"/>
// searches for <integer ID="26"... from WholePlist
// and returns value from that referenced field
//
// Whole function is here since we should avoid ParseXML() and it's
// memory allocations during ExitBootServices(). And it seems that
// ParseXML() does not support IDREF.
// This func is hard to read and debug and probably not reliable,
// but it seems it works.
//
UINT64 GetPlistHexValue(CONST CHAR8 *Plist, CONST CHAR8 *Key, CONST CHAR8 *WholePlist)
{
CHAR8 *Value;
CHAR8 *IntTag;
UINT64 NumValue = 0;
CHAR8 *IDStart;
CHAR8 *IDEnd;
UINTN IDLen;
CHAR8 Buffer[48];
//static INTN DbgCount = 0;
// search for Key
Value = AsciiStrStr(Plist, Key);
if (Value == NULL) {
//DBG(L"\nNo key: %s\n", Key);
return 0;
}
// search for <integer
IntTag = AsciiStrStr(Value, "<integer");
if (IntTag == NULL) {
DBG("\nNo integer\n");
return 0;
}
// find <integer end
Value = AsciiStrStr(IntTag, ">");
if (Value == NULL) {
DBG("\nNo <integer end\n");
return 0;
}
if (Value[-1] != '/') {
// normal case: value is here
NumValue = AsciiStrHexToUint64(Value + 1);
return NumValue;
}
// it might be a reference: IDREF="173"/>
Value = AsciiStrStr(IntTag, "<integer IDREF=\"");
if (Value != IntTag) {
DBG("\nNo <integer IDREF=\"\n");
return 0;
}
// compose <integer ID="xxx" in the Buffer
IDStart = AsciiStrStr(IntTag, "\"") + 1;
IDEnd = AsciiStrStr(IDStart, "\"");
IDLen = IDEnd - IDStart;
/*
if (DbgCount < 3) {
AsciiStrnCpy(Buffer, Value, sizeof(Buffer) - 1);
DBG(L"\nRef: '%s'\n", Buffer);
}
*/
if (IDLen > 8) {
DBG("\nIDLen too big\n");
return 0;
}
AsciiStrCpyS(Buffer, 48, "<integer ID=\"");
AsciiStrnCatS(Buffer, 48, IDStart, IDLen);
AsciiStrCatS(Buffer, 48, "\"");
/*
if (DbgCount < 3) {
DBG(L"Searching: '%s'\n", Buffer);
}
*/
// and search whole plist for ID
IntTag = AsciiStrStr(WholePlist, Buffer);
if (IntTag == NULL) {
DBG("\nNo %s\n", Buffer);
return 0;
}
// got it. find closing >
/*
if (DbgCount < 3) {
AsciiStrnCpy(Buffer, IntTag, sizeof(Buffer) - 1);
DBG(L"Found: '%s'\n", Buffer);
}
*/
Value = AsciiStrStr(IntTag, ">");
if (Value == NULL) {
DBG("\nNo <integer end\n");
return 0;
}
if (Value[-1] == '/') {
DBG("\nInvalid <integer IDREF end\n");
return 0;
}
// we should have value now
NumValue = AsciiStrHexToUint64(Value + 1);
/*
if (DbgCount < 3) {
AsciiStrnCpy(Buffer, IntTag, sizeof(Buffer) - 1);
DBG(L"Found num: %hhX\n", NumValue);
gBS->Stall(10000000);
}
DbgCount++;
*/
return NumValue;
}
//
// Iterates over kexts in kernelcache
// and calls PatchKext() for each.
//
// PrelinkInfo section contains following plist, without spaces:
// <dict>
// <key>_PrelinkInfoDictionary</key>
// <array>
// <!-- start of kext Info.plist -->
// <dict>
// <key>CFBundleName</key>
// <string>MAC Framework Pseudoextension</string>
// <key>_PrelinkExecutableLoadAddr</key>
// <integer size="64">0xffffff7f8072f000</integer>
// <!-- Kext size -->
// <key>_PrelinkExecutableSize</key>
// <integer size="64">0x3d0</integer>
// <!-- Kext address -->
// <key>_PrelinkExecutableSourceAddr</key>
// <integer size="64">0xffffff80009a3000</integer>
// ...
// </dict>
// <!-- start of next kext Info.plist -->
// <dict>
// ...
// </dict>
// ...
VOID LOADER_ENTRY::PatchPrelinkedKexts()
{
CHAR8 *WholePlist;
CHAR8 *DictPtr;
CHAR8 *InfoPlistStart = NULL;
CHAR8 *InfoPlistEnd = NULL;
INTN DictLevel = 0;
CHAR8 SavedValue;
//INTN DbgCount = 0;
UINT32 KextAddr;
UINT32 KextSize;
WholePlist = (CHAR8*)(UINTN)PrelinkInfoAddr;
//
// Detect FakeSMC and if present then
// disable kext injection InjectKexts().
// There is some bug in the folowing code that
// searches for individual kexts in prelink info
// and FakeSMC is not found on my SnowLeo although
// it is present in kernelcache.
// But searching through the whole prelink info
// works and that's the reason why it is here.
//
//Slice
// I see no reason to disable kext injection if FakeSMC found in cache
//since rev4240 we have manual kext inject disable
// CheckForFakeSMC(WholePlist);
DictPtr = WholePlist;
while ((DictPtr = AsciiStrStr(DictPtr, "dict>")) != NULL) {
if (DictPtr[-1] == '<') {
// opening dict
DictLevel++;
if (DictLevel == 2) {
// kext start
InfoPlistStart = DictPtr - 1;
}
} else if (DictPtr[-2] == '<' && DictPtr[-1] == '/') {
// closing dict
if (DictLevel == 2 && InfoPlistStart != NULL) {
// kext end
InfoPlistEnd = DictPtr + 5 /* "dict>" */;
// terminate Info.plist with 0
SavedValue = *InfoPlistEnd;
*InfoPlistEnd = '\0';
// get kext address from _PrelinkExecutableSourceAddr
// truncate to 32 bit to get physical addr
KextAddr = (UINT32)GetPlistHexValue(InfoPlistStart, kPrelinkExecutableSourceKey, WholePlist);
// KextAddr is always relative to 0x200000
// and if KernelSlide is != 0 then KextAddr must be adjusted
KextAddr += KernelSlide;
// and adjust for AptioFixDrv's KernelRelocBase
KextAddr += (UINT32)KernelRelocBase;
KextSize = (UINT32)GetPlistHexValue(InfoPlistStart, kPrelinkExecutableSizeKey, WholePlist);
/*if (DbgCount < 3
|| DbgCount == 100 || DbgCount == 101 || DbgCount == 102
) {
DBG(L"\n\nKext: St = %hhX, Size = %hhX\n", KextAddr, KextSize);
DBG(L"Info: St = %p, End = %p\n%s\n", InfoPlistStart, InfoPlistEnd, InfoPlistStart);
gBS->Stall(20000000);
}
*/
// patch it
PatchKext(
(UINT8*)(UINTN)KextAddr,
KextSize,
InfoPlistStart,
(UINT32)(InfoPlistEnd - InfoPlistStart)
);
// return saved char
*InfoPlistEnd = SavedValue;
//DbgCount++;
}
DictLevel--;
}
DictPtr += 5;
}
}
//
// Iterates over kexts loaded by booter
// and calls PatchKext() for each.
//
VOID LOADER_ENTRY::PatchLoadedKexts()
{
DTEntry MMEntry;
_BooterKextFileInfo *KextFileInfo;
CHAR8 *PropName;
_DeviceTreeBuffer *PropEntry;
CHAR8 SavedValue;
CHAR8 *InfoPlist;
OpaqueDTPropertyIterator OPropIter;
DTPropertyIterator PropIter = &OPropIter;
//UINTN DbgCount = 0;
DBG("\nPatchLoadedKexts ... dtRoot = %llx\n", (UINTN)dtRoot);
if (!dtRoot || !dtLength) {
return;
}
DTInit(dtRoot, dtLength);
if (!EFI_ERROR(DTLookupEntry(NULL,"/chosen/memory-map", &MMEntry))) {
if (!EFI_ERROR(DTCreatePropertyIterator(MMEntry, PropIter))) {
while (!EFI_ERROR(DTIterateProperties(PropIter, &PropName))) {
//DBG(L"Prop: %s\n", PropName);
if (AsciiStrStr(PropName,"Driver-")) {
// PropEntry _DeviceTreeBuffer is the value of Driver-XXXXXX property
PropEntry = (_DeviceTreeBuffer*)(((UINT8*)PropIter->CurrentProperty) + sizeof(DeviceTreeNodeProperty));
//if (DbgCount < 3) DBG(L"%s: paddr = %hhX, length = %hhX\n", PropName, PropEntry->paddr, PropEntry->length);
// PropEntry->paddr points to _BooterKextFileInfo
KextFileInfo = (_BooterKextFileInfo *)(UINTN)PropEntry->paddr;
// Info.plist should be terminated with 0, but will also do it just in case
InfoPlist = (CHAR8*)(UINTN)KextFileInfo->infoDictPhysAddr;
SavedValue = InfoPlist[KextFileInfo->infoDictLength];
InfoPlist[KextFileInfo->infoDictLength] = '\0';
PatchKext(
(UINT8*)(UINTN)KextFileInfo->executablePhysAddr,
KextFileInfo->executableLength,
InfoPlist,
KextFileInfo->infoDictLength
);
InfoPlist[KextFileInfo->infoDictLength] = SavedValue;
}
//if(AsciiStrStr(PropName,"DriversPackage-")!=0)
//{
// DBG(L"Found %s\n", PropName);
// break;
//}
}
}
}
}
//
// Entry for all kext patches.
// Will iterate through kext in prelinked kernel (kernelcache)
// or DevTree (drivers boot) and do patches.
//
VOID LOADER_ENTRY::KextPatcherStart()
{
// if (isKernelcache) {
DBG_RT("Patching kernelcache ...\n");
Stall(2000000);
PatchPrelinkedKexts();
// } else {
DBG_RT("Patching loaded kexts ...\n");
Stall(2000000);
PatchLoadedKexts();
// }
}