/* * ConfigManager.cpp * * Created on: Apr 21, 2021 * Author: jief */ #include #include "../cpp_lib/MemoryTracker.h" #include "ConfigManager.h" #include "../Settings/SelfOem.h" #include "../refit/lib.h" #include "../Platform/Settings.h" #include "../Platform/platformdata.h" #include "../Platform/VersionString.h" #include "../Platform/Nvram.h" #include "../Platform/smbios.h" #include "../Platform/gma.h" #include "../Platform/ati.h" #include "../Platform/ati_reg.h" #include "../Platform/nvidia.h" #include "../Platform/hda.h" #include "../include/Net.h" #include "../entry_scan/secureboot.h" #ifndef DEBUG_ALL #define DEBUG_CONFIGMANAGER 1 #else #define DEBUG_CONFIGMANAGER DEBUG_ALL #endif #if DEBUG_CONFIGMANAGER == 0 #define DBG(...) #else #define DBG(...) DebugLog (DEBUG_CONFIGMANAGER, __VA_ARGS__) #endif void ConfigManager::DiscoverDevices() { EFI_STATUS Status; UINT16 PreviousVendor = 0; XStringW GopDevicePathStr; DbgHeader("GetDevices"); { // Get GOP handle, in order to check to which GPU the monitor is currently connected UINTN HandleCount = 0; EFI_HANDLE *HandleArray = NULL; Status = gBS->LocateHandleBuffer(ByProtocol, &gEfiGraphicsOutputProtocolGuid, NULL, &HandleCount, &HandleArray); if (!EFI_ERROR(Status)) { if ( HandleCount == 0 ) { log_technical_bug("HandleCount == 0"); }else{ if ( HandleCount > 1 ) { MsgLog("Found more than one GOP protocol ??? Using the first one\n"); } GopDevicePathStr = DevicePathToXStringW(DevicePathFromHandle(HandleArray[0])); DBG("GOP found at: %ls\n", GopDevicePathStr.wc_str()); } } } // Scan PCI handles UINTN HandleCount = 0; EFI_HANDLE *HandleArray = NULL; Status = gBS->LocateHandleBuffer ( ByProtocol, &gEfiPciIoProtocolGuid, NULL, &HandleCount, &HandleArray ); if (!EFI_ERROR(Status)) { for (UINTN Index = 0; Index < HandleCount; ++Index) { EFI_PCI_IO_PROTOCOL *PciIo; Status = gBS->HandleProtocol(HandleArray[Index], &gEfiPciIoProtocolGuid, (void **)&PciIo); if (!EFI_ERROR(Status)) { // Read PCI BUS UINTN Segment = 0; UINTN Bus = 0; UINTN Device = 0; UINTN Function = 0; PciIo->GetLocation (PciIo, &Segment, &Bus, &Device, &Function); PCI_TYPE00 Pci; Status = PciIo->Pci.Read ( PciIo, EfiPciIoWidthUint32, 0, sizeof (Pci) / sizeof (UINT32), &Pci ); DBG("PCI (%02llX|%02llX:%02llX.%02llX) : %04hX %04hX class=%02hhX%02hhX%02hhX\n", Segment, Bus, Device, Function, Pci.Hdr.VendorId, Pci.Hdr.DeviceId, Pci.Hdr.ClassCode[2], Pci.Hdr.ClassCode[1], Pci.Hdr.ClassCode[0] ); // GFX //if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_DISPLAY) && // (Pci.Hdr.ClassCode[1] == PCI_CLASS_DISPLAY_VGA) && // (NGFX < 4)) { if ( Pci.Hdr.ClassCode[2] == PCI_CLASS_DISPLAY && ( Pci.Hdr.ClassCode[1] == PCI_CLASS_DISPLAY_VGA || Pci.Hdr.ClassCode[1] == PCI_CLASS_DISPLAY_OTHER ) ) { CONST CHAR8 *CardFamily = ""; UINT16 UFamily; DiscoveredGfx *gfx = new DiscoveredGfx; gfx->DeviceID = Pci.Hdr.DeviceId; gfx->Segment = Segment; gfx->Bus = Bus; gfx->Device = Device; gfx->Function = Function; gfx->Handle = HandleArray[Index]; switch (Pci.Hdr.VendorId) { case 0x1002: { const radeon_card_info_t *info = NULL; gfx->Vendor = Ati; size_t i = 0; do { info = &radeon_cards[i]; if (info->device_id == Pci.Hdr.DeviceId) { break; } } while (radeon_cards[i++].device_id != 0); gfx->Model.takeValueFrom(info->model_name); gfx->Config.takeValueFrom(card_configs[info->cfg_name].name); gfx->Ports = card_configs[info->cfg_name].ports; DBG(" - GFX: Model=%s (ATI/AMD)\n", gfx->Model.c_str()); //get mmio if (info->chip_family < CHIP_FAMILY_HAINAN) { gfx->Mmio = (UINT8 *)(UINTN)(Pci.Device.Bar[2] & ~0x0f); } else { gfx->Mmio = (UINT8 *)(UINTN)(Pci.Device.Bar[5] & ~0x0f); } gfx->Connectors = *(UINT32*)(gfx->Mmio + RADEON_BIOS_0_SCRATCH); // DBG(" - RADEON_BIOS_0_SCRATCH = 0x%08X\n", gfx->Connectors); gfx->ConnChanged = false; DiscoveredSlotDeviceClass* SlotDevice = new DiscoveredSlotDeviceClass; SlotDeviceArrayNonConst.AddReference(SlotDevice, true); SlotDevice->Index = 0; SlotDevice->SegmentGroupNum = (UINT16)Segment; SlotDevice->BusNum = (UINT8)Bus; SlotDevice->DevFuncNum = (UINT8)((Device << 3) | (Function & 0x07)); //SlotDevice->Valid = true; SlotDevice->SlotName = "PCI Slot 0"_XS8; SlotDevice->SlotID = 1; SlotDevice->SlotType = SlotTypePciExpressX16; break; } case 0x8086:{ gfx->Vendor = Intel; gfx->Model.takeValueFrom(get_gma_model (Pci.Hdr.DeviceId)); DBG(" - GFX: Model=%s (Intel)\n", gfx->Model.c_str()); gfx->Ports = 1; gfx->Connectors = (1 << GfxPropertiesArrayNonConst.size()); gfx->ConnChanged = false; break; } case 0x10de: { gfx->Vendor = Nvidia; UINT32 Bar0 = Pci.Device.Bar[0]; gfx->Mmio = (UINT8*)(UINTN)(Bar0 & ~0x0f); //DBG("BAR: 0x%p\n", Mmio); // get card type gfx->Family = (REG32(gfx->Mmio, 0) >> 20) & 0x1ff; UFamily = gfx->Family & 0x1F0; if ((UFamily == NV_ARCH_KEPLER1) || (UFamily == NV_ARCH_KEPLER2) || (UFamily == NV_ARCH_KEPLER3)) { CardFamily = "Kepler"; } else if ((UFamily == NV_ARCH_FERMI1) || (UFamily == NV_ARCH_FERMI2)) { CardFamily = "Fermi"; } else if ((UFamily == NV_ARCH_MAXWELL1) || (UFamily == NV_ARCH_MAXWELL2)) { CardFamily = "Maxwell"; } else if (UFamily == NV_ARCH_PASCAL) { CardFamily = "Pascal"; } else if (UFamily == NV_ARCH_VOLTA) { CardFamily = "Volta"; } else if (UFamily == NV_ARCH_TURING) { CardFamily = "Turing"; } else if ((UFamily >= NV_ARCH_TESLA) && (UFamily < 0xB0)) { //not sure if 0xB0 is Tesla or Fermi CardFamily = "Tesla"; } else { CardFamily = "NVidia unknown"; } gfx->Model.takeValueFrom( get_nvidia_model (((Pci.Hdr.VendorId << 16) | Pci.Hdr.DeviceId), ((Pci.Device.SubsystemVendorID << 16) | Pci.Device.SubsystemID) ) ); DBG(" - GFX: Model=%s family %hX (%s)\n", gfx->Model.c_str(), gfx->Family, CardFamily); gfx->Ports = 0; DiscoveredSlotDeviceClass* SlotDevice = new DiscoveredSlotDeviceClass; SlotDeviceArrayNonConst.AddReference(SlotDevice, true); SlotDevice->Index = 1; SlotDevice->SegmentGroupNum = (UINT16)Segment; SlotDevice->BusNum = (UINT8)Bus; SlotDevice->DevFuncNum = (UINT8)((Device << 3) | (Function & 0x07)); //SlotDevice->Valid = true; SlotDevice->SlotName = "PCI Slot 0"_XS8; SlotDevice->SlotID = 1; SlotDevice->SlotType = SlotTypePciExpressX16; break; } default: { gfx->Vendor = Unknown; gfx->Model.S8Printf("pci%hx,%hx", Pci.Hdr.VendorId, Pci.Hdr.DeviceId); gfx->Ports = 1; gfx->Connectors = (1 << GfxPropertiesArrayNonConst.size()); gfx->ConnChanged = false; break; } } // GOP device path should contain the device path of the GPU to which the monitor is connected XStringW DevicePathStr = DevicePathToXStringW(DevicePathFromHandle(HandleArray[Index])); if (StrStr(GopDevicePathStr.wc_str(), DevicePathStr.wc_str())) { DBG(" - GOP: Provided by device\n"); if ( GfxPropertiesArrayNonConst.size() != 0 ) { // we found GOP on a GPU scanned later, make space for this GPU at first position GfxPropertiesArrayNonConst.InsertRef(gfx, 0, true); }else{ GfxPropertiesArrayNonConst.AddReference(gfx, true); } } else { GfxPropertiesArrayNonConst.AddReference(gfx, true); } } //if gfx else if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_NETWORK) && (Pci.Hdr.ClassCode[1] == PCI_CLASS_NETWORK_OTHER)) { DiscoveredSlotDeviceClass* SlotDevice = new DiscoveredSlotDeviceClass; SlotDeviceArrayNonConst.AddReference(SlotDevice, true); SlotDevice->Index = 6; SlotDevice->SegmentGroupNum = (UINT16)Segment; SlotDevice->BusNum = (UINT8)Bus; SlotDevice->DevFuncNum = (UINT8)((Device << 3) | (Function & 0x07)); //SlotDevice->Valid = true; SlotDevice->SlotName = "AirPort"_XS8; SlotDevice->SlotID = 0; SlotDevice->SlotType = SlotTypePciExpressX1; DBG(" - WIFI: Vendor= "); switch (Pci.Hdr.VendorId) { case 0x11ab: DBG("Marvell\n"); break; case 0x10ec: DBG("Realtek\n"); break; case 0x14e4: DBG("Broadcom\n"); break; case 0x1969: case 0x168C: DBG("Atheros\n"); break; case 0x1814: DBG("Ralink\n"); break; case 0x8086: DBG("Intel\n"); break; default: DBG(" 0x%04X\n", Pci.Hdr.VendorId); break; } } else if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_NETWORK) && (Pci.Hdr.ClassCode[1] == PCI_CLASS_NETWORK_ETHERNET)) { DiscoveredSlotDeviceClass* SlotDevice = new DiscoveredSlotDeviceClass; SlotDeviceArrayNonConst.AddReference(SlotDevice, true); SlotDevice->Index = 5; SlotDevice->SegmentGroupNum = (UINT16)Segment; SlotDevice->BusNum = (UINT8)Bus; SlotDevice->DevFuncNum = (UINT8)((Device << 3) | (Function & 0x07)); //SlotDevice->Valid = true; SlotDevice->SlotName = "Ethernet"_XS8; SlotDevice->SlotID = 2; SlotDevice->SlotType = SlotTypePciExpressX1; LanCardClass* lanCard = new LanCardClass; LanCardArrayNonConst.AddReference(lanCard, true); UINT16 Vendor = Pci.Hdr.VendorId; UINT32 Bar0 = Pci.Device.Bar[0]; UINT8* Mmio = (UINT8*)(UINTN)(Bar0 & ~0x0f); DBG(" - LAN: %zu Vendor=", LanCardArrayNonConst.size()); switch (Pci.Hdr.VendorId) { case 0x11ab: DBG("Marvell\n"); break; case 0x10ec: DBG("Realtek\n"); break; case 0x14e4: DBG("Broadcom\n"); break; case 0x1969: case 0x168C: DBG("Atheros\n"); break; case 0x8086: DBG("Intel\n"); break; case 0x10de: DBG("Nforce\n"); break; default: DBG("Unknown\n"); break; } // // Get MAC-address from hardware directly // if ( Mmio != NULL ) { UINTN Offset = 0; XBool Swab = false; UINT32 Mac0, Mac4; switch ( Vendor ) { case 0x11ab: //Marvell Yukon if (PreviousVendor == Vendor) { Offset = B2_MAC_2; } else { Offset = B2_MAC_1; } CopyMem(&lanCard->MacAddress[0], Mmio + Offset, 6); goto done; case 0x10ec: //Realtek Mac0 = IoRead32((UINTN)Mmio); Mac4 = IoRead32((UINTN)Mmio + 4); goto copy; case 0x14e4: //Broadcom if (PreviousVendor == Vendor) { Offset = EMAC_MACADDR1_HI; } else { Offset = EMAC_MACADDR0_HI; } break; case 0x1969: //Atheros Offset = L1C_STAD0; Swab = true; break; case 0x8086: //Intel if (PreviousVendor == Vendor) { Offset = INTEL_MAC_2; } else { Offset = INTEL_MAC_1; } break; default: break; } if (!Offset) { continue; } Mac0 = *(UINT32*)(Mmio + Offset); Mac4 = *(UINT32*)(Mmio + Offset + 4); if (Swab) { lanCard->MacAddress[0] = (UINT8)((Mac4 & 0xFF00) >> 8); lanCard->MacAddress[1] = (UINT8)(Mac4 & 0xFF); lanCard->MacAddress[2] = (UINT8)((Mac0 & 0xFF000000) >> 24); lanCard->MacAddress[3] = (UINT8)((Mac0 & 0x00FF0000) >> 16); lanCard->MacAddress[4] = (UINT8)((Mac0 & 0x0000FF00) >> 8); lanCard->MacAddress[5] = (UINT8)(Mac0 & 0x000000FF); goto done; } copy: CopyMem(&lanCard->MacAddress[0], &Mac0, 4); CopyMem(&lanCard->MacAddress[4], &Mac4, 2); done: PreviousVendor = Vendor; DBG("Legacy MAC address of LAN #%zu= ", LanCardArrayNonConst.size()-1); // size() can't be 0 here. for (size_t Index2 = 0; Index2 < sizeof(lanCard->MacAddress); Index2++) { DBG("%02hhX:", lanCard->MacAddress[Index2]); } DBG("\n"); } } else if ((Pci.Hdr.ClassCode[2] == PCI_CLASS_SERIAL) && (Pci.Hdr.ClassCode[1] == PCI_CLASS_SERIAL_FIREWIRE)) { DiscoveredSlotDeviceClass* SlotDevice = new DiscoveredSlotDeviceClass; SlotDeviceArrayNonConst.AddReference(SlotDevice, true); SlotDevice->Index = 12; SlotDevice->SegmentGroupNum = (UINT16)Segment; SlotDevice->BusNum = (UINT8)Bus; SlotDevice->DevFuncNum = (UINT8)((Device << 3) | (Function & 0x07)); //SlotDevice->Valid = true; SlotDevice->SlotName = "FireWire"_XS8; SlotDevice->SlotID = 3; SlotDevice->SlotType = SlotTypePciExpressX4; } else if ( Pci.Hdr.ClassCode[2] == PCI_CLASS_MEDIA && ( Pci.Hdr.ClassCode[1] == PCI_CLASS_MEDIA_HDA || Pci.Hdr.ClassCode[1] == PCI_CLASS_MEDIA_AUDIO ) ) { DiscoveredHdaProperties *hda = new DiscoveredHdaProperties; // Populate Controllers IDs hda->controller_vendor_id = Pci.Hdr.VendorId; hda->controller_device_id = Pci.Hdr.DeviceId; // HDA Controller Info CHAR16* name; HdaControllerGetName(((hda->controller_device_id << 16) | hda->controller_vendor_id), &name); hda->controller_name.stealValueFrom(name, wcslen(name) + 1); // we "steal" the value of name, so we sace one memory allocation, and we don't have de free. if (IsHDMIAudio(HandleArray[Index])) { DBG(" - HDMI Audio: \n"); DiscoveredSlotDeviceClass* SlotDevice = new DiscoveredSlotDeviceClass; SlotDeviceArrayNonConst.AddReference(SlotDevice, true); SlotDevice->Index = 4; SlotDevice->SegmentGroupNum = (UINT16)Segment; SlotDevice->BusNum = (UINT8)Bus; SlotDevice->DevFuncNum = (UINT8)((Device << 3) | (Function & 0x07)); //SlotDevice->Valid = true; SlotDevice->SlotName = "HDMI port"_XS8; SlotDevice->SlotID = 5; SlotDevice->SlotType = SlotTypePciExpressX4; } // TODO not done here anymore! Here, we discover devices. No more. No other action. // if (gSettings.Devices.Audio.ResetHDA) { // //Slice method from VoodooHDA // //PCI_HDA_TCSEL_OFFSET = 0x44 // UINT8 Value = 0; // Status = PciIo->Pci.Read (PciIo, EfiPciIoWidthUint8, 0x44, 1, &Value); // // if (EFI_ERROR(Status)) { // continue; // } // // Value &= 0xf8; // PciIo->Pci.Write (PciIo, EfiPciIoWidthUint8, 0x44, 1, &Value); // //ResetControllerHDA(); // } HdaPropertiesArrayNonConst.AddReference(hda, true); } // if Audio device } } } } template EFI_STATUS LoadPlist(const XStringW& ConfName, C* plist) { EFI_STATUS Status = EFI_NOT_FOUND; UINTN Size = 0; UINT8* ConfigPtr = NULL; // not needed. but avoids warning apd apdConfigPtr; // XStringW ConfigPlistPath; // XStringW ConfigOemPath; DbgHeader("LoadUserSettings"); // load config if ( ConfName.isEmpty() /*|| Dict == NULL*/ ) { return EFI_NOT_FOUND; } // ConfigOemPath = SWPrintf("%ls\\%ls.plist", selfOem.getOOEMPath.wc_str(), ConfName.wc_str()); Status = EFI_NOT_FOUND; XStringW configFilename = SWPrintf("%ls.plist", ConfName.wc_str()); XStringW configPlistPath; if ( selfOem.oemDirExists() ) { configPlistPath = SWPrintf("%ls\\%ls.plist", selfOem.getOemFullPath().wc_str(), ConfName.wc_str()); if (FileExists (&selfOem.getOemDir(), configFilename)) { Status = egLoadFile(&selfOem.getOemDir(), configFilename.wc_str(), &ConfigPtr, &Size); apdConfigPtr = ConfigPtr; // This will automatically destruct ConfigPtr when the method exit. if (EFI_ERROR(Status)) { DBG("Cannot find %ls at path (%s): '%ls', trying '%ls'\n", configFilename.wc_str(), efiStrError(Status), selfOem.getOemFullPath().wc_str(), self.getCloverDirFullPath().wc_str()); }else{ DBG("Using %ls at path: %ls\n", configFilename.wc_str(), selfOem.getOemFullPath().wc_str()); } } } if ( !selfOem.oemDirExists() || EFI_ERROR(Status)) { configPlistPath = SWPrintf("%ls\\%ls.plist", self.getCloverDirFullPath().wc_str(), ConfName.wc_str()); if ( FileExists(&self.getCloverDir(), configFilename.wc_str())) { Status = egLoadFile(&self.getCloverDir(), configFilename.wc_str(), &ConfigPtr, &Size); apdConfigPtr = ConfigPtr; // This will automatically destruct ConfigPtr when the method exit. } if (EFI_ERROR(Status)) { DBG("Cannot find %ls at path '%ls' : %s\n", configFilename.wc_str(), self.getCloverDirFullPath().wc_str(), efiStrError(Status)); } else { DBG("Using %ls at path: %ls\n", configFilename.wc_str(), self.getCloverDirFullPath().wc_str()); } } if ( EFI_ERROR(Status) ) { MsgLog("'%ls' not loaded. Efi error %s\n", configPlistPath.wc_str(), efiStrError(Status)); return Status; } XmlLiteParser xmlLiteParser; XBool parsingOk = plist->parse((const CHAR8*)ConfigPtr, Size, ""_XS8, &xmlLiteParser); if ( xmlLiteParser.getXmlParserMessageArray().size() - xmlLiteParser.getXmlParserInfoMessageCount() > 0 ) { if ( xmlLiteParser.getXmlParserMessageArray().size() - xmlLiteParser.getXmlParserInfoMessageCount() > 1 ) { DebugLog(1, "There are problems in plist '%ls'\n", configPlistPath.wc_str()); }else{ DebugLog(1, "There is a problem in plist '%ls'\n", configPlistPath.wc_str()); } for ( size_t idx = 0 ; idx < xmlLiteParser.getXmlParserMessageArray().size() ; idx++ ) { const XmlParserMessage& xmlMsg = xmlLiteParser.getXmlParserMessageArray()[idx]; if ( xmlMsg.type != XmlParserMessageType::info ) { DebugLog(1, "%s\n", xmlMsg.getFormattedMsg().c_str()); } } DebugLog(1, "Use CloverConfigPlistValidator"); if ( plist->getSMBIOS().dgetModel() < MaxMacModel ) { if ( xmlLiteParser.productNameNeeded ) DebugLog(1, " (with --productname=%s)", MachineModelName[plist->getSMBIOS().dgetModel()].c_str()); } else { // This is NOT supposed to happen, since CLover set a default mac model // If a default mac model is not set, a crash would probably happen earlier, but who knows if ( xmlLiteParser.productNameNeeded ) DebugLog(1, "(with --productname=?)"); } DebugLog(1, " or look in the log\n"); } if ( !parsingOk ) { DebugLog(1, "Parsing error while parsing '%ls'.\n", configPlistPath.wc_str()); Status = EFI_LOAD_ERROR; } else { } #ifndef JIEF_DEBUG if ( !parsingOk || xmlLiteParser.getXmlParserMessageArray().size() - xmlLiteParser.getXmlParserInfoMessageCount() > 0 ) gBS->Stall(3000000); // 3 seconds delay #endif return Status; } /* * Load a plist into configPlist global object * ConfName : name of the file, without .plist extension. File will be searched in OEM or main folder */ EFI_STATUS ConfigManager::LoadConfigPlist(const XStringW& ConfName) { configPlist.reset(); configPlist.SMBIOS.defaultMacModel = GetDefaultModel(); EFI_STATUS Status = LoadPlist(ConfName, &configPlist); return Status; } /* * Load a plist into smbiosPlist global object * ConfName : name of the file, without .plist extension. File will be searched in OEM or main folder */ EFI_STATUS ConfigManager::LoadSMBIOSPlist(const XStringW& ConfName) { smbiosPlist.reset(); smbiosPlist.SMBIOS.defaultMacModel = GetDefaultModel(); EFI_STATUS Status = LoadPlist(ConfName, &smbiosPlist); if ( EFI_ERROR(Status) ) { smbiosPlist.reset(); } return Status; } void ConfigManager::ReloadSmbios(XStringW& str) { size_t N = SmbiosList.size(); if (OldChosenSmbios == 0) { for (size_t i=1; i 0 && gConf.GfxPropertiesArray[0].Vendor == Intel) || (gConf.GfxPropertiesArray.size() > 1 && gConf.GfxPropertiesArray[1].Vendor == Intel); } if ( !configPlist.Graphics.Inject.isInjectATIDefined() ) { gSettings.Graphics.InjectAsDict.InjectATI = (gConf.GfxPropertiesArray.size() > 0 && gConf.GfxPropertiesArray[0].Vendor == Ati && (gConf.GfxPropertiesArray[0].DeviceID & 0xF000) != 0x6000 ) || (gConf.GfxPropertiesArray.size() > 1 && gConf.GfxPropertiesArray[1].Vendor == Ati && (gConf.GfxPropertiesArray[1].DeviceID & 0xF000) != 0x6000 ); } if ( !configPlist.Graphics.Inject.isInjectNVidiaDefined() ) { gSettings.Graphics.InjectAsDict.InjectNVidia = ( gConf.GfxPropertiesArray.isCardAtPosNvidia(0) && gConf.GfxPropertiesArray[0].Family < 0xE0) || ( gConf.GfxPropertiesArray.isCardAtPosNvidia(1) && gConf.GfxPropertiesArray[1].Family < 0xE0); } if ( configPlist.RtVariables.dgetBooterCfgStr().isEmpty() ) { CHAR8* OldCfgStr = (CHAR8*)GetNvramVariable(L"bootercfg", gEfiAppleBootGuid, NULL, NULL); if ( OldCfgStr ) { gSettings.RtVariables.BooterCfgStr.takeValueFrom(OldCfgStr); FreePool(OldCfgStr); } } } // comes from GetDefaultCpuSettings(SETTINGS_DATA& gSettings) { if ( gCPUStructure.Model >= CPU_MODEL_IVY_BRIDGE ) { if ( !configPlist.ACPI.SSDT.Generate.getGeneratePStates().isDefined() ) gSettings.ACPI.SSDT.Generate.GeneratePStates = true; if ( !configPlist.ACPI.SSDT.Generate.getGenerateCStates().isDefined() ) gSettings.ACPI.SSDT.Generate.GenerateCStates = true; // backward compatibility, APFS, APLF, PluginType follow PStates if ( !configPlist.ACPI.SSDT.Generate.getGenerateAPSN().isDefined() ) gSettings.ACPI.SSDT.Generate.GenerateAPSN = gSettings.ACPI.SSDT.Generate.GeneratePStates; if ( !configPlist.ACPI.SSDT.Generate.getGenerateAPLF().isDefined() ) gSettings.ACPI.SSDT.Generate.GenerateAPLF = gSettings.ACPI.SSDT.Generate.GeneratePStates; if ( !configPlist.ACPI.SSDT.Generate.getGeneratePluginType().isDefined() ) gSettings.ACPI.SSDT.Generate.GeneratePluginType = gSettings.ACPI.SSDT.Generate.GeneratePStates; if ( !configPlist.ACPI.SSDT.getEnableC6().isDefined() ) gSettings.ACPI.SSDT._EnableC6 = true; if ( !configPlist.ACPI.SSDT.getPluginType().isDefined() ) gSettings.ACPI.SSDT.PluginType = 1; if ( gCPUStructure.Model == CPU_MODEL_IVY_BRIDGE ) { if ( !configPlist.ACPI.SSDT.getMinMultiplier().isDefined() ) gSettings.ACPI.SSDT.MinMultiplier = 7; } if ( !configPlist.ACPI.SSDT.getC3Latency().isDefined() ) gSettings.ACPI.SSDT._C3Latency = 0x00FA; } //gSettings.CPU.Turbo = gCPUStructure.Turbo; if ( gCPUStructure.Model >= CPU_MODEL_SKYLAKE_D ) { if ( !configPlist.CPU.getUseARTFreq().isDefined() ) gSettings.CPU.UseARTFreq = true; } } if ( gSettings.Smbios.SmUUID.isNull() ) { gSettings.Smbios.SmUUID = getSmUUIDFromSmbios(); } // comes from main.cpp { DBG("Calibrated TSC Frequency = %llu = %lluMHz\n", gCPUStructure.TSCCalibr, DivU64x32(gCPUStructure.TSCCalibr, Mega)); if (gCPUStructure.TSCCalibr > 200000000ULL) { //200MHz gCPUStructure.TSCFrequency = gCPUStructure.TSCCalibr; } // DBG("print error level mask = %x\n", GetDebugPrintErrorLevel() ); gCPUStructure.CPUFrequency = gCPUStructure.TSCFrequency; gCPUStructure.FSBFrequency = DivU64x32(MultU64x32(gCPUStructure.CPUFrequency, 10), (gCPUStructure.MaxRatio == 0) ? 1 : gCPUStructure.MaxRatio); gCPUStructure.MaxSpeed = (UINT32)DivU64x32(gCPUStructure.TSCFrequency + (Mega >> 1), Mega); switch (gCPUStructure.Model) { case CPU_MODEL_PENTIUM_M: case CPU_MODEL_ATOM:// Atom case CPU_MODEL_DOTHAN:// Pentium M, Dothan, 90nm case CPU_MODEL_YONAH:// Core Duo/Solo, Pentium M DC case CPU_MODEL_MEROM:// Core Xeon, Core 2 Duo, 65nm, Mobile //case CPU_MODEL_CONROE:// Core Xeon, Core 2 Duo, 65nm, Desktop like Merom but not mobile case CPU_MODEL_CELERON: case CPU_MODEL_PENRYN:// Core 2 Duo/Extreme, Xeon, 45nm , Mobile case CPU_MODEL_NEHALEM:// Core i7 LGA1366, Xeon 5500, "Bloomfield", "Gainstown", 45nm case CPU_MODEL_FIELDS:// Core i7, i5 LGA1156, "Clarksfield", "Lynnfield", "Jasper", 45nm case CPU_MODEL_DALES:// Core i7, i5, Nehalem case CPU_MODEL_CLARKDALE:// Core i7, i5, i3 LGA1156, "Westmere", "Clarkdale", , 32nm case CPU_MODEL_WESTMERE:// Core i7 LGA1366, Six-core, "Westmere", "Gulftown", 32nm case CPU_MODEL_NEHALEM_EX:// Core i7, Nehalem-Ex Xeon, "Beckton" case CPU_MODEL_WESTMERE_EX:// Core i7, Nehalem-Ex Xeon, "Eagleton" gCPUStructure.ExternalClock = (UINT32)DivU64x32(gCPUStructure.FSBFrequency + Kilo - 1, Kilo); //DBG(" Read TSC ExternalClock: %d MHz\n", (INT32)(DivU64x32(gCPUStructure.ExternalClock, Kilo))); break; default: //DBG(" Read TSC ExternalClock: %d MHz\n", (INT32)(DivU64x32(gCPUStructure.FSBFrequency, Mega))); // for sandy bridge or newer // to match ExternalClock 25 MHz like real mac, divide FSBFrequency by 4 gCPUStructure.ExternalClock = ((UINT32)DivU64x32(gCPUStructure.FSBFrequency + Kilo - 1, Kilo) + 3) / 4; //DBG(" Corrected TSC ExternalClock: %d MHz\n", (INT32)(DivU64x32(gCPUStructure.ExternalClock, Kilo))); break; } if (gSettings.CPU.QEMU) { // UINT64 Msrflex = 0ULL; if (!gSettings.CPU.UserChange) { gSettings.CPU.BusSpeed = 200000; } gCPUStructure.MaxRatio = (UINT32)DivU64x32(gCPUStructure.TSCCalibr, gSettings.CPU.BusSpeed * Kilo); DBG("Set MaxRatio for QEMU: %d\n", gCPUStructure.MaxRatio); gCPUStructure.MaxRatio *= 10; gCPUStructure.MinRatio = 60; gCPUStructure.FSBFrequency = DivU64x32(MultU64x32(gCPUStructure.CPUFrequency, 10), (gCPUStructure.MaxRatio == 0) ? 1 : gCPUStructure.MaxRatio); gCPUStructure.ExternalClock = (UINT32)DivU64x32(gCPUStructure.FSBFrequency + Kilo - 1, Kilo); } } // comes from SaveSettings() { gMobile = gSettings.Smbios.Mobile; if ( (gSettings.CPU.BusSpeed != 0) && (gSettings.CPU.BusSpeed > 10 * Kilo) && (gSettings.CPU.BusSpeed < 500 * Kilo) ) { switch ( gCPUStructure.Model ) { case CPU_MODEL_PENTIUM_M: case CPU_MODEL_ATOM: // Atom case CPU_MODEL_DOTHAN: // Pentium M, Dothan, 90nm case CPU_MODEL_YONAH: // Core Duo/Solo, Pentium M DC case CPU_MODEL_MEROM: // Core Xeon, Core 2 Duo, 65nm, Mobile //case CPU_MODEL_CONROE:// Core Xeon, Core 2 Duo, 65nm, Desktop like Merom but not mobile case CPU_MODEL_CELERON: case CPU_MODEL_PENRYN: // Core 2 Duo/Extreme, Xeon, 45nm , Mobile case CPU_MODEL_NEHALEM: // Core i7 LGA1366, Xeon 5500, "Bloomfield", "Gainstown", 45nm case CPU_MODEL_FIELDS: // Core i7, i5 LGA1156, "Clarksfield", "Lynnfield", "Jasper", 45nm case CPU_MODEL_DALES: // Core i7, i5, Nehalem case CPU_MODEL_CLARKDALE: // Core i7, i5, i3 LGA1156, "Westmere", "Clarkdale", , 32nm case CPU_MODEL_WESTMERE: // Core i7 LGA1366, Six-core, "Westmere", "Gulftown", 32nm case CPU_MODEL_NEHALEM_EX: // Core i7, Nehalem-Ex Xeon, "Beckton" case CPU_MODEL_WESTMERE_EX: // Core i7, Nehalem-Ex Xeon, "Eagleton" gCPUStructure.ExternalClock = gSettings.CPU.BusSpeed; //DBG("Read ExternalClock: %d MHz\n", (INT32)(DivU64x32(gCPUStructure.ExternalClock, Kilo))); break; default: //DBG("Read ExternalClock: %d MHz\n", (INT32)(DivU64x32(gSettings.BusSpeed, Kilo))); // for sandy bridge or newer // to match ExternalClock 25 MHz like real mac, divide BusSpeed by 4 gCPUStructure.ExternalClock = (gSettings.CPU.BusSpeed + 3) / 4; //DBG("Corrected ExternalClock: %d MHz\n", (INT32)(DivU64x32(gCPUStructure.ExternalClock, Kilo))); break; } gCPUStructure.FSBFrequency = MultU64x64(gSettings.CPU.BusSpeed, Kilo); //kHz -> Hz gCPUStructure.MaxSpeed = (UINT32) ((DivU64x32((UINT64) (gSettings.CPU.BusSpeed) * gCPUStructure.MaxRatio, 10000))); //kHz->MHz } if ( (gSettings.CPU.CpuFreqMHz > 100) && (gSettings.CPU.CpuFreqMHz < 20000) ) { gCPUStructure.MaxSpeed = gSettings.CPU.CpuFreqMHz; } // to determine the use of Table 132 if ( gSettings.CPU.QPI ) { GlobalConfig.SetTable132 = true; //DBG("QPI: use Table 132\n"); } else { switch ( gCPUStructure.Model ) { case CPU_MODEL_NEHALEM: // Core i7 LGA1366, Xeon 5500, "Bloomfield", "Gainstown", 45nm case CPU_MODEL_WESTMERE: // Core i7 LGA1366, Six-core, "Westmere", "Gulftown", 32nm case CPU_MODEL_NEHALEM_EX: // Core i7, Nehalem-Ex Xeon, "Beckton" case CPU_MODEL_WESTMERE_EX: // Core i7, Nehalem-Ex Xeon, "Eagleton" GlobalConfig.SetTable132 = true; DBG("QPI: use Table 132\n"); break; default: //DBG("QPI: disable Table 132\n"); break; } } gCPUStructure.CPUFrequency = MultU64x64(gCPUStructure.MaxSpeed, Mega); } } EFI_STATUS ConfigManager::LoadConfig(const XStringW& ConfName) { DbgHeader("GetUserSettings"); DBG("GetDefaultModel()=%s\n", MachineModelName[GetDefaultModel()].c_str()); // GetDefaultModel do NOT return MaxMacModel, so MachineModelName[GetDefaultModel()] is always valid if ( !selfOem.isInitialized() ) { log_technical_bug("%s : !selfOem.isInitialized()", __PRETTY_FUNCTION__); } EFI_STATUS Status = LoadConfigPlist(ConfName); if ( EFI_ERROR(Status) ) { DBG("LoadConfigPlist return %s. Config not loaded\n", efiStrError(Status)); } LoadSMBIOSPlist(L"smbios"_XSW); // we don't need Status. If not loaded correctly, smbiosPlist is !defined and will be ignored by AssignOldNewSettings() // get list of smbioses XStringW h = L"auto"_XSW; SmbiosList.AddReference(h.forgetDataWithoutFreeing(), true); size_t N = sizeof(configPlist.m_fields)/sizeof(configPlist.m_fields[0]); DBG("create SMBIOS list, found %lu dicts\n", N); for (size_t i=0; iLocateHandleBuffer ( ByProtocol, &gEfiDevicePathProtocolGuid, NULL, &NumberOfHandles, &HandleBuffer ); if (EFI_ERROR(Status)) { return; } DbgHeader("GetUEFIMacAddress"); for (size_t Index = 0; Index < NumberOfHandles; Index++) { EFI_DEVICE_PATH_PROTOCOL* Node = NULL; Status = gBS->HandleProtocol ( HandleBuffer[Index], &gEfiDevicePathProtocolGuid, (void **) &Node ); if (EFI_ERROR(Status)) { continue; } EFI_DEVICE_PATH_PROTOCOL* DevicePath = (EFI_DEVICE_PATH_PROTOCOL *) Node; while (!IsDevicePathEnd (DevicePath)) { if ((DevicePathType (DevicePath) == MESSAGING_DEVICE_PATH) && (DevicePathSubType (DevicePath) == MSG_MAC_ADDR_DP)) { // // Get MAC address. // MAC_ADDR_DEVICE_PATH* MacAddressNode = (MAC_ADDR_DEVICE_PATH*)DevicePath; if ( !LanCardArrayNonConst.containsMacAddress(&MacAddressNode->MacAddress.Addr[0]) ) { LanCardClass* lanPath = new LanCardClass; CopyMem(&lanPath->MacAddress, &MacAddressNode->MacAddress.Addr[0], sizeof(lanPath->MacAddress)); DBG("UEFI MAC address of %ls LAN #%zu= ", DevicePathToXStringW(DevicePath).wc_str(), LanCardArrayNonConst.size()); for (size_t Index2 = 0; Index2 < sizeof(lanPath->MacAddress); Index2++) { DBG("%02hhX:", lanPath->MacAddress[Index2]); } DBG("\n"); LanCardArrayNonConst.AddReference(lanPath, true); } } DevicePath = NextDevicePathNode (DevicePath); } } if (HandleBuffer != NULL) { FreePool(HandleBuffer); } } //EFI_STATUS ConfigManager::ReLoadSmbios(XStringW& tmpStr) //TODO //{ // DBG("SMBIOS reloaded from %ls\n", tmpStr.wc_str()); // return EFI_SUCCESS; //} EFI_STATUS ConfigManager::ReLoadConfig(const XStringW& ConfName) { /* I'm pretty sure, one day, there will be other things to do than just LoadConfig */ return LoadConfig(ConfName); } EFI_STATUS ConfigManager::InitialisePlatform() { EFI_STATUS Status; PrepatchSmbios(&g_SmbiosDiscoveredSettings); GlobalConfig.OEMBoardFromSmbios = g_SmbiosDiscoveredSettings.OEMBoardFromSmbios; GlobalConfig.OEMProductFromSmbios = g_SmbiosDiscoveredSettings.OEMProductFromSmbios; GlobalConfig.OEMVendorFromSmbios = g_SmbiosDiscoveredSettings.OEMVendorFromSmbios; //replace / with _ GlobalConfig.OEMProductFromSmbios.replaceAll(U'/', U'_'); GlobalConfig.OEMBoardFromSmbios.replaceAll(U'/', U'_'); DBG("Running on: '%s' with board '%s'\n", GlobalConfig.OEMProductFromSmbios.c_str(), GlobalConfig.OEMBoardFromSmbios.c_str()); gCPUStructure.ExternalClock = g_SmbiosDiscoveredSettings.ExternalClock; gCPUStructure.CurrentSpeed = g_SmbiosDiscoveredSettings.CurrentSpeed; gCPUStructure.MaxSpeed = g_SmbiosDiscoveredSettings.MaxSpeed; GetCPUProperties(); DiscoverDevices(); //SavingMode if ( g_SmbiosDiscoveredSettings.EnabledCores ) { GlobalConfig.EnabledCores = g_SmbiosDiscoveredSettings.EnabledCores; }else{ GlobalConfig.EnabledCores = gCPUStructure.Cores; } selfOem.initialize("config"_XS8, gFirmwareClover, GlobalConfig.OEMBoardFromSmbios, GlobalConfig.OEMProductFromSmbios, (INT32)(DivU64x32(gCPUStructure.CPUFrequency, Mega)), gConf.LanCardArray); Status = gConf.LoadConfig(L"config"_XSW); GlobalConfig.C3Latency = gSettings.ACPI.SSDT._C3Latency; GlobalConfig.KPKernelPm = gSettings.KernelAndKextPatches._KPKernelPm; for ( size_t idx = 0 ; idx < GfxPropertiesArrayNonConst.size() ; ++idx ) { GfxPropertiesArrayNonConst[idx].LoadVBios = gSettings.Graphics.LoadVBios; } if (gSettings.Devices.Audio.ResetHDA) ResetHDA(); #ifdef ENABLE_SECURE_BOOT InitializeSecureBoot(); #endif // ENABLE_SECURE_BOOT return Status; } ConfigManager gConf;