Upstream
/
CloverBootloader
mirror of https://github.com/CloverHackyColor/CloverBootloader.git
1
0
Fork 0
Code Issues Packages Projects Releases Wiki Activity
CloverBootloader/rEFIt_UEFI/Platform/Nvram.cpp

1569 lines
50 KiB
C++
Executable File
Raw Blame History

/**
* Module for work with runtime (RT, NVRAM) vars,
* determining default boot volume (Startup disk)
* and (kid of) persistent RT support with nvram.plist on CloverEFI.
* dmazar, 2012
*/
#include <Platform.h> // Only use angled for Platform, else, xcode project won't compile
#include "../include/OSTypes.h"
#include "Nvram.h"
#include "BootOptions.h"
#include "guid.h"
#include "../gui/REFIT_MENU_SCREEN.h"
#include "../Platform/Volumes.h"
#include "../Platform/Settings.h"
#ifndef DEBUG_ALL
#define DEBUG_SET 1
#else
#define DEBUG_SET DEBUG_ALL
#endif
#if DEBUG_SET == 0
#define DBG(...)
#else
#define DBG(...) DebugLog (DEBUG_SET, __VA_ARGS__)
#endif
// for saving nvram.plist and it's data
TagDict* gNvramDict;
//
// vars filled after call to GetEfiBootDeviceFromNvram ()
//
// always contains original efi-boot-device-data
EFI_DEVICE_PATH *gEfiBootDeviceData;
// if gEfiBootDeviceData starts with MemoryMapped node, then gBootCampHD = "BootCampHD" var, otherwise == NULL
EFI_DEVICE_PATH *gBootCampHD;
// contains only volume dev path from gEfiBootDeviceData or gBootCampHD
EFI_DEVICE_PATH *gEfiBootVolume;
// contains file path from gEfiBootDeviceData or gBootCampHD (if exists)
CHAR16 *gEfiBootLoaderPath;
// contains GPT GUID from gEfiBootDeviceData or gBootCampHD (if exists)
EFI_GUID *gEfiBootDeviceGuid;
// Lilu / OpenCore
//EFI_GUID gOcVendorVariableGuid = { 0x4D1FDA02, 0x38C7, 0x4A6A, { 0x9C, 0xC6, 0x4B, 0xCC, 0xA8, 0xB3, 0x01, 0x02 } };
//EFI_GUID gOcReadOnlyVariableGuid = { 0xE09B9297, 0x7928, 0x4440, { 0x9A, 0xAB, 0xD1, 0xF8, 0x53, 0x6F, 0xBF, 0x0A } };
//EFI_GUID gOcWriteOnlyVariableGuid = { 0xF0B9AF8F, 0x2222, 0x4840, { 0x8A, 0x37, 0xEC, 0xF7, 0xCC, 0x8C, 0x12, 0xE1 } };
// Ozmosis
EFI_GUID mOzmosisProprietary1Guid = { 0x1F8E0C02, 0x58A9, 0x4E34, { 0xAE, 0x22, 0x2B, 0x63, 0x74, 0x5F, 0xA1, 0x01 } };
EFI_GUID mOzmosisProprietary2Guid = { 0x9480E8A1, 0x1793, 0x46C9, { 0x91, 0xD8, 0x11, 0x08, 0xDB, 0xA4, 0x73, 0x1C } };
// BootChime
extern EFI_GUID gBootChimeVendorVariableGuid;
//Apple variables
extern EFI_GUID gAppleCoreStorageVariableGuid;
extern EFI_GUID gAppleTamperResistantBootVariableGuid;
extern EFI_GUID gAppleWirelessNetworkVariableGuid;
extern EFI_GUID gApplePersonalizationVariableGuid;
extern EFI_GUID gAppleNetbootVariableGuid;
extern EFI_GUID gAppleSecureBootVariableGuid;
extern EFI_GUID gAppleTamperResistantBootSecureVariableGuid;
extern EFI_GUID gAppleTamperResistantBootEfiUserVariableGuid;
APPLE_SMC_IO_PROTOCOL *gAppleSmc = NULL;
/** returns given time as miliseconds.
* assumes 31 days per month, so it's not correct,
* but is enough for basic checks.
*/
UINT64
GetEfiTimeInMs (
IN EFI_TIME *T
)
{
UINT64 TimeMs;
TimeMs = T->Year - 1900;
// is 64bit multiply workign in 32 bit?
TimeMs = MultU64x32 (TimeMs, 12) + T->Month;
TimeMs = MultU64x32 (TimeMs, 31) + T->Day; // counting with 31 day
TimeMs = MultU64x32 (TimeMs, 24) + T->Hour;
TimeMs = MultU64x32 (TimeMs, 60) + T->Minute;
TimeMs = MultU64x32 (TimeMs, 60) + T->Second;
TimeMs = MultU64x32 (TimeMs, 1000) + DivU64x32(T->Nanosecond, 1000000);
return TimeMs;
}
/** Reads and returns value of NVRAM variable. */
void *GetNvramVariable(
IN CONST CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
OUT UINT32 *Attributes OPTIONAL,
OUT UINTN *DataSize OPTIONAL)
{
EFI_STATUS Status;
void *Data = NULL;
//
// Pass in a zero size buffer to find the required buffer size.
//
UINTN IntDataSize = 0;
Status = gRT->GetVariable (VariableName, VendorGuid, Attributes, &IntDataSize, NULL);
if (IntDataSize == 0) {
return NULL;
}
if (Status == EFI_BUFFER_TOO_SMALL) {
//
// Allocate the buffer to return
//
Data = (__typeof__(Data))AllocateZeroPool(IntDataSize + 1);
if (Data != NULL) {
//
// Read variable into the allocated buffer.
//
Status = gRT->GetVariable (VariableName, VendorGuid, Attributes, &IntDataSize, Data);
if (EFI_ERROR(Status)) {
FreePool(Data);
IntDataSize = 0;
Data = NULL;
}
}
}
if (DataSize != NULL) {
*DataSize = IntDataSize;
}
return Data;
}
/** Reads and returns value of NVRAM variable. */
XString8 GetNvramVariableAsXString8(
IN CONST CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
OUT UINT32 *Attributes OPTIONAL)
{
EFI_STATUS Status;
XString8 returnValue;
//
// Pass in a zero size buffer to find the required buffer size.
//
UINTN IntDataSize = 0;
Status = gRT->GetVariable (VariableName, VendorGuid, Attributes, &IntDataSize, NULL);
if (IntDataSize == 0) {
return NullXString8;
}
if (Status == EFI_BUFFER_TOO_SMALL) {
//
// Read variable into the allocated buffer.
//
Status = gRT->GetVariable(VariableName, VendorGuid, Attributes, &IntDataSize, returnValue.dataSized(IntDataSize+1));
if (EFI_ERROR(Status)) {
IntDataSize = 0;
returnValue.setEmpty();
}
}
returnValue.dataSized(IntDataSize+1)[IntDataSize] = 0;
returnValue.updateSize();
return returnValue;
}
/** Sets NVRAM variable. Does nothing if variable with the same data and attributes already exists. */
EFI_STATUS
SetNvramVariable (
IN CONST CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
IN UINT32 Attributes,
IN UINTN DataSize,
IN CONST void *Data
)
{
EFI_STATUS Status = EFI_SUCCESS;
void *OldData;
UINTN OldDataSize = 0;
UINT32 OldAttributes = 0;
DBG("SetNvramVariable (%ls, guid, 0x%X, %lld):", VariableName, Attributes, DataSize);
OldData = (__typeof__(OldData))GetNvramVariable(VariableName, VendorGuid, &OldAttributes, &OldDataSize);
if (OldData != NULL) {
// var already exists - check if it equal to new value
DBG(" exists(0x%X, %lld)", OldAttributes, OldDataSize);
if ((OldAttributes == Attributes) &&
(OldDataSize == DataSize) &&
(CompareMem (OldData, Data, DataSize) == 0)) {
// it's the same - do nothing
DBG(", equal -> not writing again.\n");
FreePool(OldData);
return EFI_SUCCESS;
}
FreePool(OldData);
// not the same - delete previous one if attributes are different
if (OldAttributes != Attributes) {
Status = DeleteNvramVariable(VariableName, VendorGuid);
DBG(", diff. attr: deleting old (%s)", efiStrError(Status));
}else{
DBG(", not equal");
}
}
// DBG("\n"); // for debug without Status
Status = gRT->SetVariable(VariableName, VendorGuid, Attributes, DataSize, (void*)Data); // CONST missing in EFI_SET_VARIABLE->SetVariable
DBG(" -> writing new (%s)\n", efiStrError(Status));
return Status;
}
EFI_STATUS
SetNvramXString8 (
IN CONST CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
IN UINT32 Attributes,
const XString8& s
)
{
return SetNvramVariable(VariableName, VendorGuid, Attributes, s.sizeInBytes(), (void*)s.c_str());
}
/** Sets NVRAM variable. Does nothing if variable with the same name already exists. */
EFI_STATUS
AddNvramVariable (
IN CONST CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
IN UINT32 Attributes,
IN UINTN DataSize,
IN const void *Data
)
{
EFI_STATUS Status;
void *OldData;
DBG("AddNvramVariable (%ls, guid, 0x%X, %lld):", VariableName, Attributes, DataSize);
OldData = (__typeof__(OldData))GetNvramVariable(VariableName, VendorGuid, NULL, NULL);
if (OldData == NULL) {
// set new value
Status = gRT->SetVariable(VariableName, VendorGuid, Attributes, DataSize, Data);
DBG(" -> writing new (%s)\n", efiStrError(Status));
} else {
FreePool(OldData);
DBG(" -> already exists, abort\n");
Status = EFI_ABORTED;
}
return Status;
}
EFI_STATUS
AddNvramXString8(
IN CONST CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
IN UINT32 Attributes,
const XString8& s
)
{
return AddNvramVariable(VariableName, VendorGuid, Attributes, s.sizeInBytes(), (void*)s.c_str());
}
/** Deletes NVRAM variable. */
EFI_STATUS
DeleteNvramVariable (
IN CONST CHAR16 *VariableName,
IN EFI_GUID *VendorGuid
)
{
EFI_STATUS Status;
// Delete: attributes and data size = 0
Status = gRT->SetVariable (VariableName, VendorGuid, 0, 0, NULL);
DBG("DeleteNvramVariable (%ls, guid = %s):\n", VariableName, efiStrError(Status));
return Status;
}
BOOLEAN
IsDeletableVariable (
IN CHAR16 *Name,
IN EFI_GUID *Guid
)
{
// Apple GUIDs
if (CompareGuid(Guid, &gEfiAppleVendorGuid) ||
CompareGuid(Guid, &gEfiAppleBootGuid) ||
CompareGuid(Guid, &gAppleCoreStorageVariableGuid) ||
CompareGuid(Guid, &gAppleTamperResistantBootVariableGuid) ||
CompareGuid(Guid, &gAppleWirelessNetworkVariableGuid) ||
CompareGuid(Guid, &gApplePersonalizationVariableGuid) ||
CompareGuid(Guid, &gAppleNetbootVariableGuid) ||
CompareGuid(Guid, &gAppleSecureBootVariableGuid) ||
CompareGuid(Guid, &gAppleTamperResistantBootSecureVariableGuid) ||
CompareGuid(Guid, &gAppleTamperResistantBootEfiUserVariableGuid)) {
return TRUE;
// Disable Clover Boot Options from being deleted
// Global variable boot options
/*} else if (CompareGuid (Guid, &gEfiGlobalVariableGuid)) {
// Only erase boot and driver entries for BDS
// I.e. BootOrder, Boot####, DriverOrder, Driver####
if (!StrnCmp (Name, L"Boot", StrLen(L"Boot")) ||
!StrnCmp (Name, L"Driver", StrLen(L"Driver"))) {
return TRUE;
}*/
// Lilu / OpenCore extensions
} else if (CompareGuid (Guid, &gOcVendorVariableGuid) ||
CompareGuid(Guid, &gOcReadOnlyVariableGuid) ||
CompareGuid(Guid, &gOcWriteOnlyVariableGuid)) {
return TRUE;
// Ozmozis extensions
} else if (CompareGuid (Guid, &mOzmosisProprietary1Guid) ||
CompareGuid (Guid, &mOzmosisProprietary2Guid)) {
return TRUE;
// BootChime
} else if (CompareGuid (Guid, &gBootChimeVendorVariableGuid)) {
return TRUE;
}
return FALSE;
}
#ifdef JIEF_DEBUG
EFI_STATUS
DumpNvram()
{
EFI_STATUS Status = EFI_NOT_FOUND;
EFI_GUID Guid;
XStringW Name = L""_XSW;
UINTN Size;
DbgHeader("DumpNvram");
ZeroMem (&Guid, sizeof(Guid));
do {
Size = Name.sizeInBytes();
Status = gRT->GetNextVariableName(&Size, Name.dataSized(Size+1), &Guid);
if (Status == EFI_BUFFER_TOO_SMALL) {
Status = gRT->GetNextVariableName (&Size, Name.dataSized(Size+1), &Guid);
}
if ( !EFI_ERROR(Status) ) {
XString8 s = GetNvramVariableAsXString8(Name.wc_str(), &Guid, NULL);
DBG("NVRAM : %s,%ls = '%s'\n", GuidLEToXString8(Guid).c_str(), Name.wc_str(), s.c_str());
}else if ( Status != EFI_NOT_FOUND ) {
DBG("GetNextVariableName returns '%s'\n", efiStrError(Status));
break;
}
} while( Status != EFI_NOT_FOUND );
return Status;
}
#endif
// Reset Native NVRAM by vit9696, reworked and implemented by Sherlocks
EFI_STATUS
ResetNativeNvram ()
{
EFI_STATUS Status = EFI_NOT_FOUND;
EFI_GUID Guid;
CHAR16 *Name;
UINTN NameSize;
UINTN NewNameSize;
BOOLEAN Restart = TRUE;
UINTN VolumeIndex;
REFIT_VOLUME *Volume;
EFI_FILE* FileHandle;
//DbgHeader("ResetNativeNvram: cleanup NVRAM variables");
NameSize = sizeof (CHAR16);
Name = (__typeof__(Name))AllocateZeroPool(NameSize);
if (Name == NULL) {
return Status;
}
while (TRUE) {
if (Restart) {
ZeroMem (&Guid, sizeof(Guid));
ZeroMem (Name, sizeof(Name));
Restart = FALSE;
}
NewNameSize = NameSize;
Status = gRT->GetNextVariableName (&NewNameSize, Name, &Guid);
if (Status == EFI_BUFFER_TOO_SMALL) {
Name = (__typeof__(Name))ReallocatePool (NameSize, NewNameSize, Name);
if (Name == NULL) {
return Status;
}
Status = gRT->GetNextVariableName (&NewNameSize, Name, &Guid);
NameSize = NewNameSize;
}
if (EFI_ERROR(Status)) {
break;
}
if (!EFI_ERROR(Status)) {
if (IsDeletableVariable (Name, &Guid)) {
//DBG("Deleting %s:%ls...", strguid(&Guid), Name);
Status = DeleteNvramVariable(Name, &Guid);
if (!EFI_ERROR(Status)) {
//DBG("OK\n");
Restart = TRUE;
} else {
//DBG("FAIL (%s)\n", efiStrError(Status));
break;
}
}
}
}
if (Name) {
FreePool(Name);
}
if (gFirmwareClover || gDriversFlags.EmuVariableLoaded) {
//DBG("Searching volumes for nvram.plist\n");
for (VolumeIndex = 0; VolumeIndex < Volumes.size(); ++VolumeIndex) {
Volume = &Volumes[VolumeIndex];
if (!Volume->RootDir) {
continue;
}
Status = Volume->RootDir->Open (Volume->RootDir, &FileHandle, L"nvram.plist", EFI_FILE_MODE_READ, 0);
if (EFI_ERROR(Status)) {
//DBG("- [%02d]: '%ls' - no nvram.plist - skipping!\n", VolumeIndex, Volume->VolName);
continue;
}
// find the partition where nvram.plist can be deleted and delete it
if (Volume != NULL) {
if (StriStr(Volume->VolName.wc_str(), L"EFI") != NULL) {
//DBG("- [%02d]: '%ls' - found nvram.plist and deleted it\n", VolumeIndex, Volume->VolName);
Status = DeleteFile (Volume->RootDir, L"nvram.plist");
} else {
//DBG("- [%02d]: '%ls' - found nvram.plist but can't delete it\n", VolumeIndex, Volume->VolName);
}
}
}
}
return Status;
}
///
// Print all fakesmc variables, i.e. SMC keys
///
UINT32 KeyFromName(CHAR16 *Name)
{
//fakesmc-key-CLKT-ui32: Size = 4, Data: 00 00 8C BE
UINT32 Key;
Key = ((Name[12] & 0xFF) << 24) + ((Name[13] & 0xFF) << 16) +
((Name[14] & 0xFF) << 8) + ((Name[15] & 0xFF) << 0);
return Key;
}
UINT32 TypeFromName(CHAR16 *Name)
{
//fakesmc-key-CLKT-ui32: Size = 4, Data: 00 00 8C BE
UINT32 Key;
Key = ((Name[17] & 0xFF) << 24) + ((Name[18] & 0xFF) << 16) +
((Name[19] & 0xFF) << 8) + ((Name[20] & 0xFF) << 0);
if (Name[20] == L'\0') {
Key += 0x20; //' '
}
return Key;
}
UINT32 FourCharKey(CONST CHAR8 *Name)
{
return (Name[0] << 24) + (Name[1] << 16) + (Name[2] << 8) + Name[3]; //Big Endian
}
INT8 NKey[4] = {0, 0, 0, 0};
INT8 SAdr[4] = {0, 0, 3, 0};
INT8 SNum[1] = {1};
void
GetSmcKeys (BOOLEAN WriteToSMC)
{
EFI_STATUS Status;
CHAR16 *Name;
EFI_GUID Guid;
UINTN NameSize;
UINTN NewNameSize;
UINT8 *Data;
UINTN DataSize;
INTN NumKey = 0;
STATIC UINTN Once = 0;
if (Once++) {
return;
}
NameSize = sizeof (CHAR16);
Name = (__typeof__(Name))AllocateZeroPool(NameSize);
if (Name == NULL) {
return;
}
DbgHeader("Dump SMC keys from NVRAM");
Status = gBS->LocateProtocol(&gAppleSMCProtocolGuid, NULL, (void**)&gAppleSmc);
if (!EFI_ERROR(Status)) {
DBG("found AppleSMC protocol\n");
} else {
DBG("no AppleSMC protocol\n");
gAppleSmc = NULL;
}
while (TRUE) {
NewNameSize = NameSize;
Status = gRT->GetNextVariableName (&NewNameSize, Name, &Guid);
if (Status == EFI_BUFFER_TOO_SMALL) {
Name = (__typeof__(Name))ReallocatePool (NameSize, NewNameSize, Name);
if (Name == NULL) {
return; //if something wrong then just do nothing
}
Status = gRT->GetNextVariableName (&NewNameSize, Name, &Guid);
NameSize = NewNameSize;
}
if (EFI_ERROR(Status)) {
break; //no more variables
}
if (!StrStr(Name, L"fakesmc-key")) {
continue; //the variable is not interesting for us
}
Data = (__typeof__(Data))GetNvramVariable(Name, &Guid, NULL, &DataSize);
if (Data) {
UINTN Index;
DBG(" %ls:", Name);
for (Index = 0; Index < DataSize; Index++) {
DBG("%02hhX ", *((UINT8*)Data + Index));
}
DBG("\n");
if (gAppleSmc && WriteToSMC) {
Status = gAppleSmc->SmcAddKey(gAppleSmc, KeyFromName(Name), (SMC_DATA_SIZE)DataSize, TypeFromName(Name), 0xC0);
if (!EFI_ERROR(Status)) {
Status = gAppleSmc->SmcWriteValue(gAppleSmc, KeyFromName(Name), (SMC_DATA_SIZE)DataSize, Data);
// DBG("Write to AppleSMC status=%s\n", efiStrError(Status));
}
NumKey++;
}
FreePool(Data);
}
}
if (WriteToSMC && gAppleSmc && (gAppleSmc->Signature == NON_APPLE_SMC_SIGNATURE)) {
CHAR8 Mode = SMC_MODE_APPCODE;
NKey[3] = NumKey & 0xFF;
NKey[2] = (NumKey >> 8) & 0xFF; //key, size, type, attr
DBG("Registered %lld SMC keys\n", NumKey);
Status = gAppleSmc->SmcAddKey(gAppleSmc, FourCharKey("#KEY"), 4, SmcKeyTypeUint32, 0xC0);
if (!EFI_ERROR(Status)) {
Status = gAppleSmc->SmcWriteValue(gAppleSmc, FourCharKey("#KEY"), 4, (SMC_DATA *)&NKey);
}
Status = gAppleSmc->SmcAddKey(gAppleSmc, FourCharKey("$Adr"), 4, SmcKeyTypeUint32, 0x08);
if (!EFI_ERROR(Status)) {
Status = gAppleSmc->SmcWriteValue(gAppleSmc, FourCharKey("$Adr"), 4, (SMC_DATA *)&SAdr);
}
Status = gAppleSmc->SmcAddKey(gAppleSmc, FourCharKey("$Num"), 1, SmcKeyTypeUint8, 0x08);
if (!EFI_ERROR(Status)) {
Status = gAppleSmc->SmcWriteValue(gAppleSmc, FourCharKey("$Num"), 1, (SMC_DATA *)&SNum);
}
Status = gAppleSmc->SmcAddKey(gAppleSmc, FourCharKey("RMde"), 1, SmcKeyTypeChar, 0xC0);
if (!EFI_ERROR(Status)) {
Status = gAppleSmc->SmcWriteValue(gAppleSmc, FourCharKey("RMde"), 1, (SMC_DATA *)&Mode);
}
}
FreePool(Name);
}
#if CHECK_SMC
void DumpSmcKeys()
{
if (!gAppleSmc || !gAppleSmc->DumpData) {
return;
}
gAppleSmc->DumpData(gAppleSmc);
}
#endif
/** Searches for GPT HDD dev path node and return pointer to partition GUID or NULL. */
EFI_GUID
*FindGPTPartitionGuidInDevicePath (
const EFI_DEVICE_PATH_PROTOCOL *DevicePath
)
{
HARDDRIVE_DEVICE_PATH *HDDDevPath;
EFI_GUID *Guid = NULL;
if (DevicePath == NULL) {
return NULL;
}
while (!IsDevicePathEndType(DevicePath) &&
!(DevicePathType(DevicePath) == MEDIA_DEVICE_PATH && DevicePathSubType (DevicePath) == MEDIA_HARDDRIVE_DP)) {
DevicePath = NextDevicePathNode(DevicePath);
}
if (DevicePathType(DevicePath) == MEDIA_DEVICE_PATH && DevicePathSubType (DevicePath) == MEDIA_HARDDRIVE_DP) {
HDDDevPath = (HARDDRIVE_DEVICE_PATH*)DevicePath;
if (HDDDevPath->SignatureType == SIGNATURE_TYPE_GUID) {
Guid = (EFI_GUID*)HDDDevPath->Signature;
}
}
return Guid;
}
/** detailed debug for BootVolumeDevicePathEqual */
#define DBG_DP(...)
//#define DBG_DP(...) DBG(__VA_ARGS__)
/** Returns TRUE if dev paths are equal. Ignores some differences. */
BOOLEAN
BootVolumeDevicePathEqual (
IN EFI_DEVICE_PATH_PROTOCOL *DevicePath1,
IN EFI_DEVICE_PATH_PROTOCOL *DevicePath2
)
{
BOOLEAN Equal;
UINT8 Type1;
UINT8 SubType1;
UINT8 Type2;
UINTN Len1;
UINT8 SubType2;
UINTN Len2;
SATA_DEVICE_PATH *SataNode1;
SATA_DEVICE_PATH *SataNode2;
BOOLEAN ForceEqualNodes;
// DBG_DP (" BootVolumeDevicePathEqual:\n %ls\n %ls\n", FileDevicePathToStr (DevicePath1), FileDevicePathToStr (DevicePath2));
// DBG_DP (" N1: (Type, Subtype, Len) N2: (Type, Subtype, Len)\n");
Equal = FALSE;
while (TRUE) {
Type1 = DevicePathType (DevicePath1);
SubType1 = DevicePathSubType (DevicePath1);
Len1 = DevicePathNodeLength (DevicePath1);
Type2 = DevicePathType (DevicePath2);
SubType2 = DevicePathSubType (DevicePath2);
Len2 = DevicePathNodeLength (DevicePath2);
ForceEqualNodes = FALSE;
// DBG_DP (" N1: (%d, %d, %lld)", Type1, SubType1, Len1);
// DBG_DP (" N2: (%d, %d, %lld)", Type2, SubType2, Len2);
// DBG_DP ("%ls\n", DevicePathToStr (DevicePath1));
// DBG_DP ("%ls\n", DevicePathToStr (DevicePath2));
//
// Some eSata device can have path:
// PciRoot(0x0)/Pci(0x1C,0x5)/Pci(0x0,0x0)/VenHw(CF31FAC5-C24E-11D2-85F3-00A0C93EC93B,80)
// while macOS can set it as
// PciRoot(0x0)/Pci(0x1C,0x5)/Pci(0x0,0x0)/Sata(0x0,0x0,0x0)
// we'll assume VenHw and Sata nodes to be equal to cover that
// as well add NVME to this comparison
//
if (Type1 == MESSAGING_DEVICE_PATH && SubType1 == MSG_SATA_DP) {
if ((Type2 == HARDWARE_DEVICE_PATH && SubType2 == HW_VENDOR_DP)
|| (Type2 == MESSAGING_DEVICE_PATH && SubType2 == MSG_NVME_NAMESPACE_DP)) {
ForceEqualNodes = TRUE;
}
} else if (Type2 == MESSAGING_DEVICE_PATH && SubType2 == MSG_SATA_DP &&
((Type1 == HARDWARE_DEVICE_PATH && SubType1 == HW_VENDOR_DP)
|| (Type1 == MESSAGING_DEVICE_PATH && SubType1 == MSG_NVME_NAMESPACE_DP))) {
ForceEqualNodes = TRUE;
}
//
// UEFI can see it as PcieRoot, while macOS could generate PciRoot
// we'll assume Acpi dev path nodes to be equal to cover that
//
if (Type1 == ACPI_DEVICE_PATH && Type2 == ACPI_DEVICE_PATH) {
ForceEqualNodes = TRUE;
}
if (ForceEqualNodes) {
// assume equal nodes
// DBG_DP (" - forcing equal nodes\n");
DevicePath1 = NextDevicePathNode (DevicePath1);
DevicePath2 = NextDevicePathNode (DevicePath2);
continue;
}
if (Type1 != Type2 || SubType1 != SubType2 || Len1 != Len2) {
// Not equal
// DBG_DP (" - not equal\n");
break;
}
//
// Same type/subtype/len ...
//
if (IsDevicePathEnd (DevicePath1)) {
// END node - they are the same
Equal = TRUE;
// DBG_DP (" - END = equal\n");
break;
}
//
// Do mem compare of nodes or special compare for selected types/subtypes
//
if (Type1 == MESSAGING_DEVICE_PATH && SubType1 == MSG_SATA_DP) {
//
// Ignore
//
SataNode1 = (SATA_DEVICE_PATH *)DevicePath1;
SataNode2 = (SATA_DEVICE_PATH *)DevicePath2;
if (SataNode1->HBAPortNumber != SataNode2->HBAPortNumber) {
// not equal
// DBG_DP (" - not equal SataNode.HBAPortNumber\n");
break;
}
if (SataNode1->Lun != SataNode2->Lun) {
// not equal
// DBG_DP (" - not equal SataNode.Lun\n");
break;
}
// DBG_DP (" - forcing equal nodes");
} else if (CompareMem (DevicePath1, DevicePath2, DevicePathNodeLength (DevicePath1)) != 0) {
// Not equal
// DBG_DP (" - not equal\n");
break;
}
// DBG_DP ("\n");
//
// Advance to next node
//
DevicePath1 = NextDevicePathNode (DevicePath1);
DevicePath2 = NextDevicePathNode (DevicePath2);
}
return Equal;
}
/** Returns TRUE if dev paths contain the same MEDIA_DEVICE_PATH. */
BOOLEAN
BootVolumeMediaDevicePathNodesEqual (
IN EFI_DEVICE_PATH_PROTOCOL *DevicePath1,
IN EFI_DEVICE_PATH_PROTOCOL *DevicePath2
)
{
DevicePath1 = Clover_FindDevicePathNodeWithType (DevicePath1, MEDIA_DEVICE_PATH, 0);
if (DevicePath1 == NULL) {
return FALSE;
}
DevicePath2 = Clover_FindDevicePathNodeWithType (DevicePath2, MEDIA_DEVICE_PATH, 0);
if (DevicePath2 == NULL) {
return FALSE;
}
return (DevicePathNodeLength (DevicePath1) == DevicePathNodeLength (DevicePath1))
&& (CompareMem (DevicePath1, DevicePath2, DevicePathNodeLength (DevicePath1)) == 0);
}
/** Reads gEfiAppleBootGuid:efi-boot-device-data and BootCampHD NVRAM variables and parses them
* into gEfiBootVolume, gEfiBootLoaderPath and gEfiBootDeviceGuid.
* Vars after this call:
* gEfiBootDeviceData - original efi-boot-device-data
* gBootCampHD - if gEfiBootDeviceData starts with MemoryMapped node, then BootCampHD variable (device path), NULL otherwise
* gEfiBootVolume - volume device path (from efi-boot-device-data or BootCampHD)
* gEfiBootLoaderPath - file path (from efi-boot-device-data or BootCampHD) or NULL
* gEfiBootDeviceGuid - GPT volume GUID if gEfiBootVolume or NULL
*/
EFI_STATUS
GetEfiBootDeviceFromNvram ()
{
UINTN Size = 0;
EFI_GUID *Guid;
FILEPATH_DEVICE_PATH *FileDevPath;
DbgHeader("GetEfiBootDeviceFromNvram");
// DBG("GetEfiBootDeviceFromNvram:");
if (gEfiBootDeviceData != NULL) {
// DBG(" - [!] already parsed\n");
return EFI_SUCCESS;
}
gEfiBootDeviceData = (__typeof__(gEfiBootDeviceData))GetNvramVariable(L"efi-boot-next-data", &gEfiAppleBootGuid, NULL, &Size);
if (gEfiBootDeviceData != NULL) {
DBG("Got efi-boot-next-data size=%lld\n", Size);
if (IsDevicePathValid(gEfiBootDeviceData, Size)) {
// DBG(" - efi-boot-next-data: %ls\n", FileDevicePathToStr (gEfiBootDeviceData));
} else {
DBG(" - device path for efi-boot-next-data is invalid\n");
FreePool(gEfiBootDeviceData);
gEfiBootDeviceData = NULL;
}
}
if (gEfiBootDeviceData == NULL) {
void *Value;
UINTN Size2=0;
EFI_STATUS Status;
Status = GetVariable2 (L"aptiofixflag", &gEfiAppleBootGuid, &Value, &Size2);
if (EFI_ERROR(Status)) {
gEfiBootDeviceData = (__typeof__(gEfiBootDeviceData))GetNvramVariable(L"efi-boot-device-data", &gEfiAppleBootGuid, NULL, &Size);
} else {
gEfiBootDeviceData = (__typeof__(gEfiBootDeviceData))GetNvramVariable(L"specialbootdevice", &gEfiAppleBootGuid, NULL, &Size);
}
if (gEfiBootDeviceData != NULL) {
DBG("Got efi-boot-device-data size=%lld\n", Size);
if (!IsDevicePathValid(gEfiBootDeviceData, Size)) {
DBG(" - device path for efi-boot-device-data is invalid\n");
FreePool(gEfiBootDeviceData);
gEfiBootDeviceData = NULL;
}
}
}
if (gEfiBootDeviceData == NULL) {
DBG(" - [!] efi-boot-device-data not found\n");
return EFI_NOT_FOUND;
}
// DBG("\n");
DBG(" - efi-boot-device-data: %ls\n", FileDevicePathToXStringW(gEfiBootDeviceData).wc_str());
gEfiBootVolume = gEfiBootDeviceData;
//
// if gEfiBootDeviceData starts with MemoryMapped node,
// then Startup Disk sets BootCampHD to Win disk dev path.
//
if (DevicePathType(gEfiBootDeviceData) == HARDWARE_DEVICE_PATH && DevicePathSubType (gEfiBootDeviceData) == HW_MEMMAP_DP) {
gBootCampHD = (__typeof__(gBootCampHD))GetNvramVariable(L"BootCampHD", &gEfiAppleBootGuid, NULL, &Size);
gEfiBootVolume = gBootCampHD;
if (gBootCampHD == NULL) {
// DBG(" - [!] Error: BootCampHD not found\n");
return EFI_NOT_FOUND;
}
if (!IsDevicePathValid(gBootCampHD, Size)) {
// DBG(" Error: BootCampHD device path is invalid\n");
FreePool(gBootCampHD);
gEfiBootVolume = gBootCampHD = NULL;
return EFI_NOT_FOUND;
}
DBG(" - BootCampHD: %ls\n", FileDevicePathToXStringW(gBootCampHD).wc_str());
}
//
// if gEfiBootVolume contains FilePathNode, then split them into gEfiBootVolume dev path and gEfiBootLoaderPath
//
gEfiBootLoaderPath = NULL;
FileDevPath = (FILEPATH_DEVICE_PATH *)Clover_FindDevicePathNodeWithType (gEfiBootVolume, MEDIA_DEVICE_PATH, MEDIA_FILEPATH_DP);
if (FileDevPath != NULL) {
gEfiBootLoaderPath = (__typeof__(gEfiBootLoaderPath))AllocateCopyPool(StrSize(FileDevPath->PathName), FileDevPath->PathName);
// copy DevPath and write end of path node after in place of file path node
gEfiBootVolume = DuplicateDevicePath (gEfiBootVolume);
FileDevPath = (FILEPATH_DEVICE_PATH *)Clover_FindDevicePathNodeWithType (gEfiBootVolume, MEDIA_DEVICE_PATH, MEDIA_FILEPATH_DP);
SetDevicePathEndNode (FileDevPath);
// gEfiBootVolume now contains only Volume path
}
DBG(" - Volume: '%ls'\n", FileDevicePathToXStringW(gEfiBootVolume).wc_str());
DBG(" - LoaderPath: '%ls'\n", gEfiBootLoaderPath);
//
// if this is GPT disk, extract GUID
// gEfiBootDeviceGuid can be used as a flag for GPT disk then
//
Guid = FindGPTPartitionGuidInDevicePath (gEfiBootVolume);
if (Guid != NULL) {
gEfiBootDeviceGuid = (__typeof__(gEfiBootDeviceGuid))AllocatePool (sizeof(EFI_GUID));
if (gEfiBootDeviceGuid != NULL) {
CopyMem(gEfiBootDeviceGuid, Guid, sizeof(EFI_GUID));
DBG(" - Guid = %s\n", strguid(gEfiBootDeviceGuid));
}
}
return EFI_SUCCESS;
}
/** Loads and parses nvram.plist into gNvramDict. */
EFI_STATUS
LoadNvramPlist(
IN EFI_FILE *RootDir,
IN CONST CHAR16* NVRAMPlistPath
)
{
EFI_STATUS Status;
CHAR8 *NvramPtr = NULL;
UINTN Size = 0;
DBG(" begin load gNvramDict=0x%llX\n", (uintptr_t)gNvramDict);
//
// skip loading if already loaded
//
if (gNvramDict != NULL) {
return EFI_SUCCESS;
}
//
// load nvram.plist
//
Status = egLoadFile(RootDir, NVRAMPlistPath, (UINT8**)&NvramPtr, &Size);
if(EFI_ERROR(Status)) {
DBG(" not present\n");
return Status;
}
DBG(" loaded, size=%llu\n", Size);
//
// parse it into gNvramDict
//
Status = ParseXML((const CHAR8*)NvramPtr, &gNvramDict, Size);
if(Status != EFI_SUCCESS) {
DBG(" parsing error\n");
}
FreePool(NvramPtr);
// we will leave nvram.plist loaded and parsed for later processing
//FreeTag(gNvramDict);
return Status;
}
#define SEARCH_ONLY_EFI 1
/** Searches all volumes for the most recent nvram.plist and loads it into gNvramDict. */
EFI_STATUS
LoadLatestNvramPlist()
{
EFI_STATUS Status;
EFI_FILE* FileHandle = NULL;
EFI_FILE_INFO *FileInfo = NULL;
UINT64 LastModifTimeMs;
UINT64 ModifTimeMs;
#if !SEARCH_ONLY_EFI
REFIT_VOLUME *Volume;
REFIT_VOLUME *VolumeWithLatestNvramPlist = NULL;
#endif
//there are debug messages not needed for users
DBG("Searching volumes for latest nvram.plist ...");
//
// skip loading if already loaded
//
if (gNvramDict != NULL) {
DBG(" already loaded\n");
return EFI_SUCCESS;
}
DBG("\n");
//
// find latest nvram.plist
//
LastModifTimeMs = 0;
#if SEARCH_ONLY_EFI
UINTN HandleCount = 0;
EFI_HANDLE *Handles = NULL;
EFI_FILE* RootDir;
EFI_FILE* NewestRootDir = NULL;
UINTN indexSuccess = 0;
Status = gBS->LocateHandleBuffer(ByProtocol, &gEfiPartTypeSystemPartGuid, NULL, &HandleCount, &Handles);
if (!EFI_ERROR(Status) && HandleCount > 0) {
for (UINTN indexHandle = 0; indexHandle < HandleCount; indexHandle++) {
RootDir = EfiLibOpenRoot(Handles[indexHandle]);
if ( RootDir == NULL ) {
DBG(" - [%lld] cannot open - skipping!\n", indexHandle);
continue;
}
Status = RootDir->Open(RootDir, &FileHandle, L"nvram.plist", EFI_FILE_MODE_READ, 0);
if (EFI_ERROR(Status)) {
if ( Status == EFI_NOT_FOUND ) {
DBG(" - [%lld] no nvram.plist\n", indexHandle);
}else{
DBG(" - [%lld] Cannot open nvram.plist - %s\n", indexHandle, efiStrError(Status));
}
continue;
}
FileInfo = EfiLibFileInfo(FileHandle);
// DBG("got FileInfo=0x%X\n", FileInfo);
if (FileInfo == NULL) {
DBG(" - no nvram.plist file info - skipping!\n");
FileHandle->Close(FileHandle);
continue;
}
DBG(" Modified = ");
ModifTimeMs = GetEfiTimeInMs (&(FileInfo->ModificationTime));
DBG("%d-%d-%d %d:%d:%d (%lld ms)\n",
FileInfo->ModificationTime.Year, FileInfo->ModificationTime.Month, FileInfo->ModificationTime.Day,
FileInfo->ModificationTime.Hour, FileInfo->ModificationTime.Minute, FileInfo->ModificationTime.Second,
ModifTimeMs);
FreePool(FileInfo);
FileHandle->Close(FileHandle);
// check if newer
if (LastModifTimeMs < ModifTimeMs) {
DBG(" - newer - will use this one\n");
NewestRootDir = RootDir;
LastModifTimeMs = ModifTimeMs;
indexSuccess = indexHandle;
}
}
if (NewestRootDir == NULL) {
Status = EFI_NOT_FOUND;
} else {
//
// if we have nvram.plist - load it
//
DBG("Loading nvram.plist from EFI index %lld", indexSuccess);
Status = LoadNvramPlist(NewestRootDir, L"nvram.plist");
}
FreePool(Handles);
}
#else
// search all volumes
for (UINTN Index = 0; Index < Volumes.size(); ++Index) {
Volume = &Volumes[Index];
if (!Volume->RootDir) {
continue;
}
/* Guid = FindGPTPartitionGuidInDevicePath (Volume->DevicePath);
DBG(" %2d. Volume '%ls', GUID = %s", Index, Volume->VolName, strguid(Guid));
if (Guid == NULL) {
// not a GUID partition
DBG(" - not GPT");
} */
DBG("Volume[%lld]\n", Index);
// check if nvram.plist exists
Status = Volume->RootDir->Open (Volume->RootDir, &FileHandle, L"nvram.plist", EFI_FILE_MODE_READ, 0);
if (EFI_ERROR(Status)) {
DBG(" - no nvram.plist - skipping!\n");
continue;
}
DBG(" Status=%s\n", efiStrError(Status));
if (GlobalConfig.isFastBoot()) {
VolumeWithLatestNvramPlist = Volume;
break;
}
// get nvram.plist modification date
FileInfo = EfiLibFileInfo(FileHandle);
// DBG("got FileInfo=0x%X\n", FileInfo);
if (FileInfo == NULL) {
DBG(" - no nvram.plist file info - skipping!\n");
FileHandle->Close(FileHandle);
continue;
}
DBG(" Modified = ");
ModifTimeMs = GetEfiTimeInMs (&(FileInfo->ModificationTime));
DBG("%d-%d-%d %d:%d:%d (%lld ms)\n",
FileInfo->ModificationTime.Year, FileInfo->ModificationTime.Month, FileInfo->ModificationTime.Day,
FileInfo->ModificationTime.Hour, FileInfo->ModificationTime.Minute, FileInfo->ModificationTime.Second,
ModifTimeMs);
FreePool(FileInfo);
FileHandle->Close(FileHandle);
// check if newer
if (LastModifTimeMs < ModifTimeMs) {
DBG(" - newer - will use this one\n");
VolumeWithLatestNvramPlist = Volume;
LastModifTimeMs = ModifTimeMs;
}
// else {
// DBG(" - older - skipping!\n");
// }
}
Status = EFI_NOT_FOUND;
//
// if we have nvram.plist - load it
//
if (VolumeWithLatestNvramPlist != NULL) {
DBG("Loading nvram.plist from Vol '%ls' -", VolumeWithLatestNvramPlist->VolName.wc_str());
Status = LoadNvramPlist(VolumeWithLatestNvramPlist->RootDir, L"nvram.plist");
}
// else {
// DBG(" nvram.plist not found!\n");
// }
#endif
DBG("LoadLatestNvramPlist loaded Status=%s\n", efiStrError(Status));
return Status;
}
/** Puts all vars from nvram.plist to RT vars. Should be used in CloverEFI only
* or if some UEFI boot uses EmuRuntimeDxe driver.
*/
void
PutNvramPlistToRtVars ()
{
// EFI_STATUS Status;
// const TagStruct* ValTag;
INTN Size;
const VOID *Value;
if (gNvramDict == NULL) {
/*Status = */LoadLatestNvramPlist();
if (gNvramDict == NULL) {
DBG("PutNvramPlistToRtVars: no nvram.plist\n");
return;
}
}
DbgHeader("PutNvramPlistToRtVars");
// iterate over dict elements
size_t count = gNvramDict->dictKeyCount(); // ok
for (size_t tagIdx = 0 ; tagIdx < count ; tagIdx++ )
{
const TagKey* keyTag;
const TagStruct* valueTag;
if ( EFI_ERROR(gNvramDict->getKeyAndValueAtIndex(tagIdx, &keyTag, &valueTag)) ) { //If GetKeyValueAtIndex return success, key and value != NULL
MsgLog("MALFORMED PLIST nvram.plist. A key is expected at pos : %zu\n", tagIdx);
continue;
}
EFI_GUID *VendorGuid = &gEfiAppleBootGuid;
// process only valid <key> tags
if ( valueTag == NULL ) {
// DBG(" ERROR: ValTag is not NULL\n");
continue;
}
// skip OsxAptioFixDrv-RelocBase - appears and causes trouble
// in kernel and kext patcher when mixing UEFI and CloverEFI boot
if ( keyTag->keyStringValue() == "OsxAptioFixDrv-RelocBase"_XS8 ) {
DBG(" Skipping OsxAptioFixDrv-RelocBase\n");
continue;
} else if ( keyTag->keyStringValue() == "OsxAptioFixDrv-ErrorExitingBootServices"_XS8 ) {
DBG(" Skipping OsxAptioFixDrv-ErrorExitingBootServices\n");
continue;
} else if ( keyTag->keyStringValue() == "EmuVariableUefiPresent"_XS8 ) {
DBG(" Skipping EmuVariableUefiPresent\n");
continue;
} else if ( keyTag->keyStringValue() == "aapl,panic-info"_XS8 ) {
DBG(" Skipping aapl,panic-info\n");
continue;
}
if (keyTag->keyStringValue() == "Boot0082"_XS8 ||
keyTag->keyStringValue() == "BootNext"_XS8 ) {
VendorGuid = &gEfiGlobalVariableGuid;
// it may happen only in this case
gSettings.Boot.HibernationFixup = TRUE;
}
// AsciiStrToUnicodeStrS(Tag.stringValue(), KeyBuf, 128);
XStringW KeyBuf = keyTag->keyStringValue();
// if (!gSettings.Boot.DebugLog) {
DBG(" Adding Key: %ls: ", KeyBuf.wc_str());
// }
// process value tag
if (valueTag->isString()) {
// <string> element
Value = (void*)valueTag->getString()->stringValue().c_str();
Size = valueTag->getString()->stringValue().length();
// if (!gSettings.Boot.DebugLog) {
DBG("String: Size = %llu, Val = '%s'\n", Size, valueTag->getString()->stringValue().c_str());
// }
} else if (valueTag->isData()) {
// <data> element
Size = valueTag->getData()->dataLenValue();
Value = valueTag->getData()->dataValue();
// if (gSettings.Boot.DebugLog) {
DBG("Size = %llu, Data: ", Size);
for (INTN i = 0; i < Size; i++) {
DBG("%02hhX ", *(((UINT8*)Value) + i));
}
// }
// if (!gSettings.Boot.DebugLog) {
DBG("\n");
//
} else {
DBG("ERROR: Unsupported tag type: %s\n", valueTag->getTypeAsXString8().c_str());
continue;
}
if (Size == 0 || !Value) {
continue;
}
// set RT var: all vars visible in nvram.plist are gEfiAppleBootGuid
SetNvramVariable (
KeyBuf.wc_str(),
VendorGuid,
EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS,
Size,
Value
);
}
}
/** Performs detailed search for Startup Disk or last Clover boot volume
* by looking for gEfiAppleBootGuid:efi-boot-device-data and BootCampHD RT vars.
* Returns MainMenu entry index or -1 if not found.
*/
INTN
FindStartupDiskVolume (
REFIT_MENU_SCREEN *MainMenu
)
{
INTN Index;
// LEGACY_ENTRY *LegacyEntry;
// LOADER_ENTRY *LoaderEntry;
// REFIT_VOLUME *Volume;
REFIT_VOLUME *DiskVolume;
BOOLEAN IsPartitionVolume;
XStringW LoaderPath;
XStringW EfiBootVolumeStr;
//
// search RT vars for efi-boot-device-data
// and try to find that volume
//
GetEfiBootDeviceFromNvram ();
if (gEfiBootVolume == NULL) {
// DBG(" - [!] EfiBootVolume not found\n");
return -1;
}
DbgHeader("FindStartupDiskVolume");
//
// Check if gEfiBootVolume is disk or partition volume
//
EfiBootVolumeStr = FileDevicePathToXStringW(gEfiBootVolume);
IsPartitionVolume = NULL != Clover_FindDevicePathNodeWithType (gEfiBootVolume, MEDIA_DEVICE_PATH, 0);
DBG(" - Volume: %ls = %ls\n", IsPartitionVolume ? L"partition" : L"disk", EfiBootVolumeStr.wc_str());
//
// 1. gEfiBootVolume + gEfiBootLoaderPath
// PciRoot(0x0)/.../Sata(...)/HD(...)/\EFI\BOOT\XXX.EFI - set by Clover
//
if (gEfiBootLoaderPath != NULL) {
DBG(" - searching for that partition and loader '%ls'\n", gEfiBootLoaderPath);
for (Index = 0; ((Index < (INTN)MainMenu->Entries.size()) && (MainMenu->Entries[Index].Row == 0)); ++Index) {
if (MainMenu->Entries[Index].getLOADER_ENTRY()) {
LOADER_ENTRY& LoaderEntry = *MainMenu->Entries[Index].getLOADER_ENTRY();
REFIT_VOLUME* Volume = LoaderEntry.Volume;
LoaderPath = LoaderEntry.LoaderPath;
if (Volume != NULL && BootVolumeDevicePathEqual(gEfiBootVolume, Volume->DevicePath)) {
DBG(" checking '%ls'\n", DevicePathToXStringW(Volume->DevicePath).wc_str());
DBG(" '%ls'\n", LoaderPath.wc_str());
// case insensitive cmp
if ( LoaderPath.isEqualIC(gEfiBootLoaderPath) ) {
// that's the one
DBG(" - found entry %lld. '%ls', Volume '%ls', '%ls'\n", Index, LoaderEntry.Title.s(), Volume->VolName.wc_str(), LoaderPath.wc_str());
return Index;
}
}
}
}
DBG(" - [!] not found\n");
//
// search again, but compare only Media dev path nodes
// (in case of some dev path differences we do not cover)
//
DBG(" - searching again, but comparing Media dev path nodes\n");
for (Index = 0; ((Index < (INTN)MainMenu->Entries.size()) && (MainMenu->Entries[Index].Row == 0)); ++Index) {
if (MainMenu->Entries[Index].getLOADER_ENTRY()) {
LOADER_ENTRY& LoaderEntry = *MainMenu->Entries[Index].getLOADER_ENTRY();
REFIT_VOLUME* Volume = LoaderEntry.Volume;
EFI_DEVICE_PATH *DevicePath = LoaderEntry.DevicePath;
EFI_DEVICE_PATH *MediaPath = Clover_FindDevicePathNodeWithType(DevicePath, MEDIA_DEVICE_PATH, MEDIA_VENDOR_DP);
if (MediaPath) {
EFI_GUID *MediaPathGuid = (EFI_GUID *)&((VENDOR_DEVICE_PATH_WITH_DATA*)MediaPath)->VendorDefinedData;
XStringW MediaPathGuidStr = GuidLEToXStringW(*MediaPathGuid);
DBG(" checking '%ls'\n", MediaPathGuidStr.wc_str());
if (StrStr(gEfiBootLoaderPath, MediaPathGuidStr.wc_str())) {
DBG(" - found entry %lld. '%ls', Volume '%ls', '%ls'\n", Index, LoaderEntry.Title.s(), Volume->VolName.wc_str(), LoaderPath.wc_str());
return Index;
}
}
}
}
DBG(" - [!] not found\n");
}
//Slice - why all further? For legacy boot which is not working???
//
// 2. gEfiBootVolume - partition volume
// PciRoot(0x0)/.../Sata(...)/HD(...) - set by Clover or macOS
//
if (IsPartitionVolume) {
DBG(" - searching for that partition\n");
for (Index = 0; ((Index < (INTN)MainMenu->Entries.size()) && (MainMenu->Entries[Index].Row == 0)); ++Index) {
REFIT_VOLUME* Volume = NULL;
if (MainMenu->Entries[Index].getLEGACY_ENTRY()) {
Volume = MainMenu->Entries[Index].getLEGACY_ENTRY()->Volume;
} else if (MainMenu->Entries[Index].getLOADER_ENTRY()) {
Volume = MainMenu->Entries[Index].getLOADER_ENTRY()->Volume;
}
if (Volume != NULL && BootVolumeDevicePathEqual (gEfiBootVolume, Volume->DevicePath)) {
DBG(" - found entry %lld. '%ls', Volume '%ls'\n", Index, MainMenu->Entries[Index].Title.s(), Volume->VolName.wc_str());
return Index;
}
}
DBG(" - [!] not found\n");
//
// search again, but compare only Media dev path nodes
//
DBG(" - searching again, but comparing Media dev path nodes\n");
for (Index = 0; ((Index < (INTN)MainMenu->Entries.size()) && (MainMenu->Entries[Index].Row == 0)); ++Index) {
REFIT_VOLUME* Volume = NULL;
if (MainMenu->Entries[Index].getLEGACY_ENTRY()) {
Volume = MainMenu->Entries[Index].getLEGACY_ENTRY()->Volume;
} else if (MainMenu->Entries[Index].getLOADER_ENTRY()) {
Volume = MainMenu->Entries[Index].getLOADER_ENTRY()->Volume;
}
if (Volume != NULL && BootVolumeMediaDevicePathNodesEqual (gEfiBootVolume, Volume->DevicePath)) {
DBG(" - found entry %lld. '%ls', Volume '%ls'\n", Index, MainMenu->Entries[Index].Title.s(), Volume->VolName.wc_str());
return Index;
}
}
DBG(" - [!] not found\n");
return -1;
}
//
// 3. gEfiBootVolume - disk volume
// PciRoot(0x0)/.../Sata(...) - set by macOS for Win boot
//
// 3.1 First find disk volume in Volumes[]
//
DiskVolume = NULL;
DBG(" - searching for that disk\n");
for (Index = 0; Index < (INTN)Volumes.size(); ++Index) {
REFIT_VOLUME* Volume = &Volumes[Index];
if (BootVolumeDevicePathEqual (gEfiBootVolume, Volume->DevicePath)) {
// that's the one
DiskVolume = Volume;
DBG(" - found disk as volume %lld. '%ls'\n", Index, Volume->VolName.wc_str());
break;
}
}
if (DiskVolume == NULL) {
DBG(" - [!] not found\n");
return -1;
}
//
// 3.2 DiskVolume
// search for first entry with win loader or win partition on that disk
//
DBG(" - searching for first entry with win loader or win partition on that disk\n");
for (Index = 0; ((Index < (INTN)MainMenu->Entries.size()) && (MainMenu->Entries[Index].Row == 0)); ++Index) {
if (MainMenu->Entries[Index].getLEGACY_ENTRY()) {
LEGACY_ENTRY& LegacyEntry = (LEGACY_ENTRY&)MainMenu->Entries[Index];
REFIT_VOLUME* Volume = LegacyEntry.Volume;
if (Volume != NULL && Volume->WholeDiskBlockIO == DiskVolume->BlockIO) {
// check for Win
//DBG(" checking legacy entry %d. %ls\n", Index, LegacyEntry.Title);
//DBG(" %ls\n", DevicePathToStr (Volume->DevicePath));
//DBG(" OSType = %d\n", Volume->OSType);
if (Volume->LegacyOS->Type == OSTYPE_WIN) {
// that's the one - legacy win partition
DBG(" - found legacy entry %lld. '%ls', Volume '%ls'\n", Index, LegacyEntry.Title.s(), Volume->VolName.wc_str());
return Index;
}
}
} else if (MainMenu->Entries[Index].getLOADER_ENTRY()) {
LOADER_ENTRY& LoaderEntry = *MainMenu->Entries[Index].getLOADER_ENTRY();
REFIT_VOLUME* Volume = LoaderEntry.Volume;
if (Volume != NULL && Volume->WholeDiskBlockIO == DiskVolume->BlockIO) {
// check for Win
//DBG(" checking loader entry %d. %ls\n", Index, LoaderEntry.Title);
//DBG(" %ls\n", DevicePathToStr (Volume->DevicePath));
//DBG(" LoaderPath = %ls\n", LoaderEntry.LoaderPath);
//DBG(" LoaderType = %d\n", LoaderEntry.LoaderType);
if (LoaderEntry.LoaderType == OSTYPE_WINEFI) {
// that's the one - win loader entry
DBG(" - found loader entry %lld. '%ls', Volume '%ls', '%ls'\n", Index, LoaderEntry.Title.s(), Volume->VolName.wc_str(), LoaderEntry.LoaderPath.wc_str());
return Index;
}
}
}
}
DBG(" - [!] not found\n");
//
// 3.3 DiskVolume, but no Win entry
// PciRoot(0x0)/.../Sata(...)
// just find first menu entry on that disk?
//
DBG(" - searching for any entry from disk '%ls'\n", DiskVolume->VolName.wc_str());
for (Index = 0; ((Index < (INTN)MainMenu->Entries.size()) && (MainMenu->Entries[Index].Row == 0)); ++Index) {
if (MainMenu->Entries[Index].getLEGACY_ENTRY()) {
LEGACY_ENTRY& LegacyEntry = (LEGACY_ENTRY&)MainMenu->Entries[Index];
REFIT_VOLUME* Volume = LegacyEntry.Volume;
if (Volume != NULL && Volume->WholeDiskBlockIO == DiskVolume->BlockIO) {
// that's the one
DBG(" - found legacy entry %lld. '%ls', Volume '%ls'\n", Index, LegacyEntry.Title.s(), Volume->VolName.wc_str());
return Index;
}
} else if (MainMenu->Entries[Index].getLOADER_ENTRY()) {
LOADER_ENTRY& LoaderEntry = *MainMenu->Entries[Index].getLOADER_ENTRY();
REFIT_VOLUME* Volume = LoaderEntry.Volume;
if (Volume != NULL && Volume->WholeDiskBlockIO == DiskVolume->BlockIO) {
// that's the one
DBG(" - found loader entry %lld. '%ls', Volume '%ls', '%ls'\n", Index, LoaderEntry.Title.s(), Volume->VolName.wc_str(), LoaderEntry.LoaderPath.wc_str());
return Index;
}
}
}
DBG(" - [!] not found\n");
return -1;
}
/** Sets efi-boot-device-data RT var to currently selected Volume and LoadePath. */
EFI_STATUS SetStartupDiskVolume (
IN REFIT_VOLUME *Volume,
IN CONST XStringW& LoaderPath
)
{
EFI_STATUS Status;
EFI_DEVICE_PATH_PROTOCOL *DevPath;
EFI_DEVICE_PATH_PROTOCOL *FileDevPath;
EFI_GUID *Guid;
// CHAR8 *EfiBootDevice;
// CONST CHAR8 *EfiBootDeviceTmpl;
// UINTN Size;
UINT32 Attributes;
DBG("SetStartupDiskVolume:\n");
DBG(" * Volume: '%ls'\n", Volume->VolName.wc_str());
DBG(" * LoaderPath: '%ls'\n", LoaderPath.wc_str());
//
// construct dev path for Volume/LoaderPath
//
DevPath = Volume->DevicePath;
if (LoaderPath.notEmpty()) {
FileDevPath = FileDevicePath (NULL, LoaderPath);
DevPath = AppendDevicePathNode (DevPath, FileDevPath);
}
DBG(" * DevPath: %ls\n", Volume->VolName.wc_str()/*, FileDevicePathToStr (DevPath)*/);
Guid = FindGPTPartitionGuidInDevicePath (Volume->DevicePath);
DBG(" * GUID = %s\n", strguid(Guid));
//
// let's save it without EFI_VARIABLE_NON_VOLATILE in CloverEFI like other vars so far
//
if (!gFirmwareClover && !gDriversFlags.EmuVariableLoaded) {
Attributes = EFI_VARIABLE_NON_VOLATILE | EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS;
} else {
Attributes = EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS;
}
//
// set efi-boot-device-data to volume dev path
//
Status = SetNvramVariable (L"efi-boot-device-data", &gEfiAppleBootGuid, Attributes, GetDevicePathSize(DevPath), DevPath);
if (EFI_ERROR(Status)) {
return Status;
}
//
// set efi-boot-device to XML string
// (probably not needed at all)
//
if (Guid != NULL) {
XString8 EfiBootDevice;
EfiBootDevice.S8Printf(
"<array><dict>"
"<key>IOMatch</key>"
"<dict>"
"<key>IOProviderClass</key><string>IOMedia</string>"
"<key>IOPropertyMatch</key>"
"<dict><key>UUID</key><string>%s</string></dict>"
"</dict>"
"</dict></array>", strguid(Guid));
DBG (" * efi-boot-device: %s\n", EfiBootDevice.c_str());
Status = SetNvramXString8(L"efi-boot-device", &gEfiAppleBootGuid, Attributes, EfiBootDevice);
}
return Status;
}
/** Deletes Startup disk vars: efi-boot-device, efi-boot-device-data, BootCampHD. */
void
RemoveStartupDiskVolume ()
{
// EFI_STATUS Status;
// DBG("RemoveStartupDiskVolume:\n");
/*Status =*/ DeleteNvramVariable (L"efi-boot-device", &gEfiAppleBootGuid);
// DBG(" * efi-boot-device = %s\n", efiStrError(Status));
/*Status =*/ DeleteNvramVariable (L"efi-boot-device-data", &gEfiAppleBootGuid);
// DBG(" * efi-boot-device-data = %s\n", efiStrError(Status));
/*Status =*/ DeleteNvramVariable (L"BootCampHD", &gEfiAppleBootGuid);
// DBG(" * BootCampHD = %s\n", efiStrError(Status));
// DBG("Removed efi-boot-device-data variable: %s\n", efiStrError(Status));
}
void ResetNvram ()
{
if (gFirmwareClover || gDriversFlags.EmuVariableLoaded) {
if (gEmuVariableControl != NULL) {
gEmuVariableControl->InstallEmulation(gEmuVariableControl);
}
}
ResetNativeNvram ();
if (gFirmwareClover || gDriversFlags.EmuVariableLoaded) {
if (gEmuVariableControl != NULL) {
gEmuVariableControl->UninstallEmulation(gEmuVariableControl);
}
}
// Attempt warm reboot
// gRT->ResetSystem(EfiResetWarm, EFI_SUCCESS, 0, NULL);
// Warm reboot may not be supported attempt cold reboot
// gRT->ResetSystem(EfiResetCold, EFI_SUCCESS, 0, NULL);
// Terminate the screen and just exit
// TerminateScreen();
}
Reference in New Issue View Git Blame Copy Permalink