/* $Id: ConsoleImpl2.cpp 48528 2013-09-18 20:39:01Z vboxsync $ */ /** @file * VBox Console COM Class implementation - VM Configuration Bits. * * @remark We've split out the code that the 64-bit VC++ v8 compiler finds * problematic to optimize so we can disable optimizations and later, * perhaps, find a real solution for it (like rewriting the code and * to stop resemble a tonne of spaghetti). */ /* * Copyright (C) 2006-2013 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ /******************************************************************************* * Header Files * *******************************************************************************/ // for some reason Windows burns in sdk\...\winsock.h if this isn't included first #include "VBox/com/ptr.h" #include "ConsoleImpl.h" #include "DisplayImpl.h" #ifdef VBOX_WITH_GUEST_CONTROL # include "GuestImpl.h" #endif #ifdef VBOX_WITH_DRAG_AND_DROP # include "GuestDnDImpl.h" #endif #include "VMMDev.h" #include "Global.h" #ifdef VBOX_WITH_PCI_PASSTHROUGH # include "PCIRawDevImpl.h" #endif // generated header #include "SchemaDefs.h" #include "AutoCaller.h" #include "Logging.h" #include #include #include #include #include #include #include #include #include #include #if 0 /* enable to play with lots of memory. */ # include #endif #include #include #include #include #include /* For PDMR3DriverAttach/PDMR3DriverDetach */ #include #include #ifdef VBOX_WITH_CROGL # include #include #endif #ifdef VBOX_WITH_GUEST_PROPS # include # include # include # include "HGCM.h" /** @todo it should be possible to register a service * extension using a VMMDev callback. */ # include #endif /* VBOX_WITH_GUEST_PROPS */ #include #include #include #include #ifdef VBOX_WITH_NETFLT # if defined(RT_OS_SOLARIS) # include # elif defined(RT_OS_LINUX) # include # include # include # include # include # include # elif defined(RT_OS_FREEBSD) # include # include # include # include # include # include # endif # if defined(RT_OS_WINDOWS) # include # include # include # else # include # include # include # endif #endif /* VBOX_WITH_NETFLT */ #include "NetworkServiceRunner.h" #include "BusAssignmentManager.h" #ifdef VBOX_WITH_EXTPACK # include "ExtPackManagerImpl.h" #endif #if defined(RT_OS_DARWIN) # include "IOKit/IOKitLib.h" static int DarwinSmcKey(char *pabKey, uint32_t cbKey) { /* * Method as described in Amit Singh's article: * http://osxbook.com/book/bonus/chapter7/tpmdrmmyth/ */ typedef struct { uint32_t key; uint8_t pad0[22]; uint32_t datasize; uint8_t pad1[10]; uint8_t cmd; uint32_t pad2; uint8_t data[32]; } AppleSMCBuffer; AssertReturn(cbKey >= 65, VERR_INTERNAL_ERROR); io_service_t service = IOServiceGetMatchingService(kIOMasterPortDefault, IOServiceMatching("AppleSMC")); if (!service) return VERR_NOT_FOUND; io_connect_t port = (io_connect_t)0; kern_return_t kr = IOServiceOpen(service, mach_task_self(), 0, &port); IOObjectRelease(service); if (kr != kIOReturnSuccess) return RTErrConvertFromDarwin(kr); AppleSMCBuffer inputStruct = { 0, {0}, 32, {0}, 5, }; AppleSMCBuffer outputStruct; size_t cbOutputStruct = sizeof(outputStruct); for (int i = 0; i < 2; i++) { inputStruct.key = (uint32_t)(i == 0 ? 'OSK0' : 'OSK1'); kr = IOConnectCallStructMethod((mach_port_t)port, (uint32_t)2, (const void *)&inputStruct, sizeof(inputStruct), (void *)&outputStruct, &cbOutputStruct); if (kr != kIOReturnSuccess) { IOServiceClose(port); return RTErrConvertFromDarwin(kr); } for (int j = 0; j < 32; j++) pabKey[j + i*32] = outputStruct.data[j]; } IOServiceClose(port); pabKey[64] = 0; return VINF_SUCCESS; } #endif /* RT_OS_DARWIN */ /* Darwin compile kludge */ #undef PVM /* Comment out the following line to remove VMWare compatibility hack. */ #define VMWARE_NET_IN_SLOT_11 /** * Translate IDE StorageControllerType_T to string representation. */ const char* controllerString(StorageControllerType_T enmType) { switch (enmType) { case StorageControllerType_PIIX3: return "PIIX3"; case StorageControllerType_PIIX4: return "PIIX4"; case StorageControllerType_ICH6: return "ICH6"; default: return "Unknown"; } } /** * Simple class for storing network boot information. */ struct BootNic { ULONG mInstance; PCIBusAddress mPCIAddress; ULONG mBootPrio; bool operator < (const BootNic &rhs) const { ULONG lval = mBootPrio - 1; /* 0 will wrap around and get the lowest priority. */ ULONG rval = rhs.mBootPrio - 1; return lval < rval; /* Zero compares as highest number (lowest prio). */ } }; static int findEfiRom(IVirtualBox* vbox, FirmwareType_T aFirmwareType, Utf8Str *pEfiRomFile) { Bstr aFilePath, empty; BOOL fPresent = FALSE; HRESULT hrc = vbox->CheckFirmwarePresent(aFirmwareType, empty.raw(), empty.asOutParam(), aFilePath.asOutParam(), &fPresent); AssertComRCReturn(hrc, Global::vboxStatusCodeFromCOM(hrc)); if (!fPresent) { LogRel(("Failed to find an EFI ROM file.\n")); return VERR_FILE_NOT_FOUND; } *pEfiRomFile = Utf8Str(aFilePath); return VINF_SUCCESS; } static int getSmcDeviceKey(IMachine *pMachine, BSTR *aKey, bool *pfGetKeyFromRealSMC) { *pfGetKeyFromRealSMC = false; /* * The extra data takes precedence (if non-zero). */ HRESULT hrc = pMachine->GetExtraData(Bstr("VBoxInternal2/SmcDeviceKey").raw(), aKey); if (FAILED(hrc)) return Global::vboxStatusCodeFromCOM(hrc); if ( SUCCEEDED(hrc) && *aKey && **aKey) return VINF_SUCCESS; #ifdef RT_OS_DARWIN /* * Query it here and now. */ char abKeyBuf[65]; int rc = DarwinSmcKey(abKeyBuf, sizeof(abKeyBuf)); if (SUCCEEDED(rc)) { Bstr(abKeyBuf).detachTo(aKey); return rc; } LogRel(("Warning: DarwinSmcKey failed with rc=%Rrc!\n", rc)); #else /* * Is it apple hardware in bootcamp? */ /** @todo implement + test RTSYSDMISTR_MANUFACTURER on all hosts. * Currently falling back on the product name. */ char szManufacturer[256]; szManufacturer[0] = '\0'; RTSystemQueryDmiString(RTSYSDMISTR_MANUFACTURER, szManufacturer, sizeof(szManufacturer)); if (szManufacturer[0] != '\0') { if ( !strcmp(szManufacturer, "Apple Computer, Inc.") || !strcmp(szManufacturer, "Apple Inc.") ) *pfGetKeyFromRealSMC = true; } else { char szProdName[256]; szProdName[0] = '\0'; RTSystemQueryDmiString(RTSYSDMISTR_PRODUCT_NAME, szProdName, sizeof(szProdName)); if ( ( !strncmp(szProdName, RT_STR_TUPLE("Mac")) || !strncmp(szProdName, RT_STR_TUPLE("iMac")) || !strncmp(szProdName, RT_STR_TUPLE("iMac")) || !strncmp(szProdName, RT_STR_TUPLE("Xserve")) ) && !strchr(szProdName, ' ') /* no spaces */ && RT_C_IS_DIGIT(szProdName[strlen(szProdName) - 1]) /* version number */ ) *pfGetKeyFromRealSMC = true; } int rc = VINF_SUCCESS; #endif return rc; } /* * VC++ 8 / amd64 has some serious trouble with the next functions. * As a temporary measure, we'll drop global optimizations. */ #if defined(_MSC_VER) && defined(RT_ARCH_AMD64) # pragma optimize("g", off) #endif static const char *const g_apszIDEDrives[4] = { "PrimaryMaster", "PrimarySlave", "SecondaryMaster", "SecondarySlave" }; class ConfigError : public RTCError { public: ConfigError(const char *pcszFunction, int vrc, const char *pcszName) : RTCError(Utf8StrFmt("%s failed: rc=%Rrc, pcszName=%s", pcszFunction, vrc, pcszName)), m_vrc(vrc) { AssertMsgFailed(("%s\n", what())); // in strict mode, hit a breakpoint here } int m_vrc; }; /** * Helper that calls CFGMR3InsertString and throws an RTCError if that * fails (C-string variant). * @param pParent See CFGMR3InsertStringN. * @param pcszNodeName See CFGMR3InsertStringN. * @param pcszValue The string value. */ static void InsertConfigString(PCFGMNODE pNode, const char *pcszName, const char *pcszValue) { int vrc = CFGMR3InsertString(pNode, pcszName, pcszValue); if (RT_FAILURE(vrc)) throw ConfigError("CFGMR3InsertString", vrc, pcszName); } /** * Helper that calls CFGMR3InsertString and throws an RTCError if that * fails (Utf8Str variant). * @param pParent See CFGMR3InsertStringN. * @param pcszNodeName See CFGMR3InsertStringN. * @param rStrValue The string value. */ static void InsertConfigString(PCFGMNODE pNode, const char *pcszName, const Utf8Str &rStrValue) { int vrc = CFGMR3InsertStringN(pNode, pcszName, rStrValue.c_str(), rStrValue.length()); if (RT_FAILURE(vrc)) throw ConfigError("CFGMR3InsertStringLengthKnown", vrc, pcszName); } /** * Helper that calls CFGMR3InsertString and throws an RTCError if that * fails (Bstr variant). * * @param pParent See CFGMR3InsertStringN. * @param pcszNodeName See CFGMR3InsertStringN. * @param rBstrValue The string value. */ static void InsertConfigString(PCFGMNODE pNode, const char *pcszName, const Bstr &rBstrValue) { InsertConfigString(pNode, pcszName, Utf8Str(rBstrValue)); } /** * Helper that calls CFGMR3InsertBytes and throws an RTCError if that fails. * * @param pNode See CFGMR3InsertBytes. * @param pcszName See CFGMR3InsertBytes. * @param pvBytes See CFGMR3InsertBytes. * @param cbBytes See CFGMR3InsertBytes. */ static void InsertConfigBytes(PCFGMNODE pNode, const char *pcszName, const void *pvBytes, size_t cbBytes) { int vrc = CFGMR3InsertBytes(pNode, pcszName, pvBytes, cbBytes); if (RT_FAILURE(vrc)) throw ConfigError("CFGMR3InsertBytes", vrc, pcszName); } /** * Helper that calls CFGMR3InsertInteger and throws an RTCError if that * fails. * * @param pNode See CFGMR3InsertInteger. * @param pcszName See CFGMR3InsertInteger. * @param u64Integer See CFGMR3InsertInteger. */ static void InsertConfigInteger(PCFGMNODE pNode, const char *pcszName, uint64_t u64Integer) { int vrc = CFGMR3InsertInteger(pNode, pcszName, u64Integer); if (RT_FAILURE(vrc)) throw ConfigError("CFGMR3InsertInteger", vrc, pcszName); } /** * Helper that calls CFGMR3InsertNode and throws an RTCError if that fails. * * @param pNode See CFGMR3InsertNode. * @param pcszName See CFGMR3InsertNode. * @param ppChild See CFGMR3InsertNode. */ static void InsertConfigNode(PCFGMNODE pNode, const char *pcszName, PCFGMNODE *ppChild) { int vrc = CFGMR3InsertNode(pNode, pcszName, ppChild); if (RT_FAILURE(vrc)) throw ConfigError("CFGMR3InsertNode", vrc, pcszName); } /** * Helper that calls CFGMR3RemoveValue and throws an RTCError if that fails. * * @param pNode See CFGMR3RemoveValue. * @param pcszName See CFGMR3RemoveValue. */ static void RemoveConfigValue(PCFGMNODE pNode, const char *pcszName) { int vrc = CFGMR3RemoveValue(pNode, pcszName); if (RT_FAILURE(vrc)) throw ConfigError("CFGMR3RemoveValue", vrc, pcszName); } /** Helper that finds out the next SATA port used */ static LONG GetNextUsedSataPort(LONG aSataPortUsed[30], LONG lBaseVal, uint32_t u32Size) { LONG lNextPortUsed = 30; for (size_t j = 0; j < u32Size; ++j) { if ( aSataPortUsed[j] > lBaseVal && aSataPortUsed[j] <= lNextPortUsed) lNextPortUsed = aSataPortUsed[j]; } return lNextPortUsed; } #ifdef VBOX_WITH_PCI_PASSTHROUGH HRESULT Console::attachRawPCIDevices(PUVM pUVM, BusAssignmentManager *pBusMgr, PCFGMNODE pDevices) { HRESULT hrc = S_OK; PCFGMNODE pInst, pCfg, pLunL0, pLunL1; SafeIfaceArray assignments; ComPtr aMachine = machine(); hrc = aMachine->COMGETTER(PCIDeviceAssignments)(ComSafeArrayAsOutParam(assignments)); if ( hrc != S_OK || assignments.size() < 1) return hrc; /* * PCI passthrough is only available if the proper ExtPack is installed. * * Note. Configuring PCI passthrough here and providing messages about * the missing extpack isn't exactly clean, but it is a necessary evil * to patch over legacy compatability issues introduced by the new * distribution model. */ # ifdef VBOX_WITH_EXTPACK static const char *s_pszPCIRawExtPackName = "Oracle VM VirtualBox Extension Pack"; if (!mptrExtPackManager->isExtPackUsable(s_pszPCIRawExtPackName)) /* Always fatal! */ return VMR3SetError(pUVM, VERR_NOT_FOUND, RT_SRC_POS, N_("Implementation of the PCI passthrough framework not found!\n" "The VM cannot be started. To fix this problem, either " "install the '%s' or disable PCI passthrough via VBoxManage"), s_pszPCIRawExtPackName); # endif PCFGMNODE pBridges = CFGMR3GetChild(pDevices, "ich9pcibridge"); Assert(pBridges); /* Find required bridges, and add missing ones */ for (size_t iDev = 0; iDev < assignments.size(); iDev++) { ComPtr assignment = assignments[iDev]; LONG guest = 0; PCIBusAddress GuestPCIAddress; assignment->COMGETTER(GuestAddress)(&guest); GuestPCIAddress.fromLong(guest); Assert(GuestPCIAddress.valid()); if (GuestPCIAddress.miBus > 0) { int iBridgesMissed = 0; int iBase = GuestPCIAddress.miBus - 1; while (!pBusMgr->hasPCIDevice("ich9pcibridge", iBase) && iBase > 0) { iBridgesMissed++; iBase--; } iBase++; for (int iBridge = 0; iBridge < iBridgesMissed; iBridge++) { InsertConfigNode(pBridges, Utf8StrFmt("%d", iBase + iBridge).c_str(), &pInst); InsertConfigInteger(pInst, "Trusted", 1); hrc = pBusMgr->assignPCIDevice("ich9pcibridge", pInst); } } } /* Now actually add devices */ PCFGMNODE pPCIDevs = NULL; if (assignments.size() > 0) { InsertConfigNode(pDevices, "pciraw", &pPCIDevs); PCFGMNODE pRoot = CFGMR3GetParent(pDevices); Assert(pRoot); /* Tell PGM to tell GPCIRaw about guest mappings. */ CFGMR3InsertNode(pRoot, "PGM", NULL); InsertConfigInteger(CFGMR3GetChild(pRoot, "PGM"), "PciPassThrough", 1); /* * Currently, using IOMMU needed for PCI passthrough * requires RAM preallocation. */ /** @todo: check if we can lift this requirement */ CFGMR3RemoveValue(pRoot, "RamPreAlloc"); InsertConfigInteger(pRoot, "RamPreAlloc", 1); } for (size_t iDev = 0; iDev < assignments.size(); iDev++) { PCIBusAddress HostPCIAddress, GuestPCIAddress; ComPtr assignment = assignments[iDev]; LONG host, guest; Bstr aDevName; assignment->COMGETTER(HostAddress)(&host); assignment->COMGETTER(GuestAddress)(&guest); assignment->COMGETTER(Name)(aDevName.asOutParam()); InsertConfigNode(pPCIDevs, Utf8StrFmt("%d", iDev).c_str(), &pInst); InsertConfigInteger(pInst, "Trusted", 1); HostPCIAddress.fromLong(host); Assert(HostPCIAddress.valid()); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigString(pCfg, "DeviceName", aDevName); InsertConfigInteger(pCfg, "DetachHostDriver", 1); InsertConfigInteger(pCfg, "HostPCIBusNo", HostPCIAddress.miBus); InsertConfigInteger(pCfg, "HostPCIDeviceNo", HostPCIAddress.miDevice); InsertConfigInteger(pCfg, "HostPCIFunctionNo", HostPCIAddress.miFn); GuestPCIAddress.fromLong(guest); Assert(GuestPCIAddress.valid()); hrc = pBusMgr->assignHostPCIDevice("pciraw", pInst, HostPCIAddress, GuestPCIAddress, true); if (hrc != S_OK) return hrc; InsertConfigInteger(pCfg, "GuestPCIBusNo", GuestPCIAddress.miBus); InsertConfigInteger(pCfg, "GuestPCIDeviceNo", GuestPCIAddress.miDevice); InsertConfigInteger(pCfg, "GuestPCIFunctionNo", GuestPCIAddress.miFn); /* the driver */ InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "pciraw"); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); /* the Main driver */ InsertConfigString(pLunL1, "Driver", "MainPciRaw"); InsertConfigNode(pLunL1, "Config", &pCfg); PCIRawDev* pMainDev = new PCIRawDev(this); InsertConfigInteger(pCfg, "Object", (uintptr_t)pMainDev); } return hrc; } #endif void Console::attachStatusDriver(PCFGMNODE pCtlInst, PPDMLED *papLeds, uint64_t uFirst, uint64_t uLast, Console::MediumAttachmentMap *pmapMediumAttachments, const char *pcszDevice, unsigned uInstance) { PCFGMNODE pLunL0, pCfg; InsertConfigNode(pCtlInst, "LUN#999", &pLunL0); InsertConfigString(pLunL0, "Driver", "MainStatus"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "papLeds", (uintptr_t)papLeds); if (pmapMediumAttachments) { InsertConfigInteger(pCfg, "pmapMediumAttachments", (uintptr_t)pmapMediumAttachments); InsertConfigInteger(pCfg, "pConsole", (uintptr_t)this); AssertPtr(pcszDevice); Utf8Str deviceInstance = Utf8StrFmt("%s/%u", pcszDevice, uInstance); InsertConfigString(pCfg, "DeviceInstance", deviceInstance.c_str()); } InsertConfigInteger(pCfg, "First", uFirst); InsertConfigInteger(pCfg, "Last", uLast); } /** * Construct the VM configuration tree (CFGM). * * This is a callback for VMR3Create() call. It is called from CFGMR3Init() * in the emulation thread (EMT). Any per thread COM/XPCOM initialization * is done here. * * @param pUVM The user mode VM handle. * @param pVM The cross context VM handle. * @param pvConsole Pointer to the VMPowerUpTask object. * @return VBox status code. * * @note Locks the Console object for writing. */ DECLCALLBACK(int) Console::configConstructor(PUVM pUVM, PVM pVM, void *pvConsole) { LogFlowFuncEnter(); AssertReturn(pvConsole, VERR_GENERAL_FAILURE); ComObjPtr pConsole = static_cast(pvConsole); AutoCaller autoCaller(pConsole); AssertComRCReturn(autoCaller.rc(), VERR_ACCESS_DENIED); /* lock the console because we widely use internal fields and methods */ AutoWriteLock alock(pConsole COMMA_LOCKVAL_SRC_POS); /* * Set the VM handle and do the rest of the job in an worker method so we * can easily reset the VM handle on failure. */ pConsole->mpUVM = pUVM; VMR3RetainUVM(pUVM); int vrc; try { vrc = pConsole->configConstructorInner(pUVM, pVM, &alock); } catch (...) { vrc = VERR_UNEXPECTED_EXCEPTION; } if (RT_FAILURE(vrc)) { pConsole->mpUVM = NULL; VMR3ReleaseUVM(pUVM); } return vrc; } /** * Worker for configConstructor. * * @return VBox status code. * @param pUVM The user mode VM handle. * @param pVM The cross context VM handle. * @param pAlock The automatic lock instance. This is for when we have * to leave it in order to avoid deadlocks (ext packs and * more). */ int Console::configConstructorInner(PUVM pUVM, PVM pVM, AutoWriteLock *pAlock) { VMMDev *pVMMDev = m_pVMMDev; Assert(pVMMDev); ComPtr pMachine = machine(); int rc; HRESULT hrc; Bstr bstr; #define H() AssertMsgReturn(!FAILED(hrc), ("hrc=%Rhrc\n", hrc), VERR_GENERAL_FAILURE) /* * Get necessary objects and frequently used parameters. */ ComPtr virtualBox; hrc = pMachine->COMGETTER(Parent)(virtualBox.asOutParam()); H(); ComPtr host; hrc = virtualBox->COMGETTER(Host)(host.asOutParam()); H(); ComPtr systemProperties; hrc = virtualBox->COMGETTER(SystemProperties)(systemProperties.asOutParam()); H(); ComPtr biosSettings; hrc = pMachine->COMGETTER(BIOSSettings)(biosSettings.asOutParam()); H(); hrc = pMachine->COMGETTER(HardwareUUID)(bstr.asOutParam()); H(); RTUUID HardwareUuid; rc = RTUuidFromUtf16(&HardwareUuid, bstr.raw()); AssertRCReturn(rc, rc); ULONG cRamMBs; hrc = pMachine->COMGETTER(MemorySize)(&cRamMBs); H(); #if 0 /* enable to play with lots of memory. */ if (RTEnvExist("VBOX_RAM_SIZE")) cRamMBs = RTStrToUInt64(RTEnvGet("VBOX_RAM_SIZE")); #endif uint64_t const cbRam = cRamMBs * (uint64_t)_1M; uint32_t cbRamHole = MM_RAM_HOLE_SIZE_DEFAULT; uint64_t uMcfgBase = 0; uint32_t cbMcfgLength = 0; ChipsetType_T chipsetType; hrc = pMachine->COMGETTER(ChipsetType)(&chipsetType); H(); if (chipsetType == ChipsetType_ICH9) { /* We'd better have 0x10000000 region, to cover 256 buses but this put too much load on hypervisor heap */ cbMcfgLength = 0x4000000; //0x10000000; cbRamHole += cbMcfgLength; uMcfgBase = _4G - cbRamHole; } BusAssignmentManager *pBusMgr = mBusMgr = BusAssignmentManager::createInstance(chipsetType); ULONG cCpus = 1; hrc = pMachine->COMGETTER(CPUCount)(&cCpus); H(); ULONG ulCpuExecutionCap = 100; hrc = pMachine->COMGETTER(CPUExecutionCap)(&ulCpuExecutionCap); H(); Bstr osTypeId; hrc = pMachine->COMGETTER(OSTypeId)(osTypeId.asOutParam()); H(); LogRel(("OS type: '%s'\n", Utf8Str(osTypeId).c_str())); BOOL fIOAPIC; hrc = biosSettings->COMGETTER(IOAPICEnabled)(&fIOAPIC); H(); ComPtr guestOSType; hrc = virtualBox->GetGuestOSType(osTypeId.raw(), guestOSType.asOutParam()); H(); Bstr guestTypeFamilyId; hrc = guestOSType->COMGETTER(FamilyId)(guestTypeFamilyId.asOutParam()); H(); BOOL fOsXGuest = guestTypeFamilyId == Bstr("MacOS"); ULONG maxNetworkAdapters; hrc = systemProperties->GetMaxNetworkAdapters(chipsetType, &maxNetworkAdapters); H(); /* * Get root node first. * This is the only node in the tree. */ PCFGMNODE pRoot = CFGMR3GetRootU(pUVM); Assert(pRoot); // InsertConfigString throws try { /* * Set the root (and VMM) level values. */ hrc = pMachine->COMGETTER(Name)(bstr.asOutParam()); H(); InsertConfigString(pRoot, "Name", bstr); InsertConfigBytes(pRoot, "UUID", &HardwareUuid, sizeof(HardwareUuid)); InsertConfigInteger(pRoot, "RamSize", cbRam); InsertConfigInteger(pRoot, "RamHoleSize", cbRamHole); InsertConfigInteger(pRoot, "NumCPUs", cCpus); InsertConfigInteger(pRoot, "CpuExecutionCap", ulCpuExecutionCap); InsertConfigInteger(pRoot, "TimerMillies", 10); #ifdef VBOX_WITH_RAW_MODE InsertConfigInteger(pRoot, "RawR3Enabled", 1); /* boolean */ InsertConfigInteger(pRoot, "RawR0Enabled", 1); /* boolean */ /** @todo Config: RawR0, PATMEnabled and CSAMEnabled needs attention later. */ InsertConfigInteger(pRoot, "PATMEnabled", 1); /* boolean */ InsertConfigInteger(pRoot, "CSAMEnabled", 1); /* boolean */ #endif #ifdef VBOX_WITH_RAW_RING1 if (osTypeId == "QNX") { /* QNX needs special treatment in raw mode due to its use of ring-1. */ InsertConfigInteger(pRoot, "RawR1Enabled", 1); /* boolean */ } #endif /* Not necessary, but to make sure these two settings end up in the release log. */ BOOL fPageFusion = FALSE; hrc = pMachine->COMGETTER(PageFusionEnabled)(&fPageFusion); H(); InsertConfigInteger(pRoot, "PageFusion", fPageFusion); /* boolean */ ULONG ulBalloonSize = 0; hrc = pMachine->COMGETTER(MemoryBalloonSize)(&ulBalloonSize); H(); InsertConfigInteger(pRoot, "MemBalloonSize", ulBalloonSize); /* * CPUM values. */ PCFGMNODE pCPUM; InsertConfigNode(pRoot, "CPUM", &pCPUM); /* cpuid leaf overrides. */ static uint32_t const s_auCpuIdRanges[] = { UINT32_C(0x00000000), UINT32_C(0x0000000a), UINT32_C(0x80000000), UINT32_C(0x8000000a) }; for (unsigned i = 0; i < RT_ELEMENTS(s_auCpuIdRanges); i += 2) for (uint32_t uLeaf = s_auCpuIdRanges[i]; uLeaf < s_auCpuIdRanges[i + 1]; uLeaf++) { ULONG ulEax, ulEbx, ulEcx, ulEdx; hrc = pMachine->GetCPUIDLeaf(uLeaf, &ulEax, &ulEbx, &ulEcx, &ulEdx); if (SUCCEEDED(hrc)) { PCFGMNODE pLeaf; InsertConfigNode(pCPUM, Utf8StrFmt("HostCPUID/%RX32", uLeaf).c_str(), &pLeaf); InsertConfigInteger(pLeaf, "eax", ulEax); InsertConfigInteger(pLeaf, "ebx", ulEbx); InsertConfigInteger(pLeaf, "ecx", ulEcx); InsertConfigInteger(pLeaf, "edx", ulEdx); } else if (hrc != E_INVALIDARG) H(); } /* We must limit CPUID count for Windows NT 4, as otherwise it stops with error 0x3e (MULTIPROCESSOR_CONFIGURATION_NOT_SUPPORTED). */ if (osTypeId == "WindowsNT4") { LogRel(("Limiting CPUID leaf count for NT4 guests\n")); InsertConfigInteger(pCPUM, "NT4LeafLimit", true); } /* Expose CMPXCHG16B. Currently a hack. */ if ( osTypeId == "Windows81_64" || osTypeId == "Windows2012_64") { LogRel(("Enabling CMPXCHG16B for Windows 8.1 / 2k12 guests\n")); InsertConfigInteger(pCPUM, "CMPXCHG16B", true); } /* Expose extended MWAIT features to Mac OS X guests. */ if (fOsXGuest) { LogRel(("Using MWAIT extensions\n")); InsertConfigInteger(pCPUM, "MWaitExtensions", true); } if (fOsXGuest) InsertConfigInteger(pCPUM, "EnableHVP", 1); /* Synthetic CPU */ BOOL fSyntheticCpu = false; hrc = pMachine->GetCPUProperty(CPUPropertyType_Synthetic, &fSyntheticCpu); H(); InsertConfigInteger(pCPUM, "SyntheticCpu", fSyntheticCpu); /* Physical Address Extension (PAE) */ BOOL fEnablePAE = false; hrc = pMachine->GetCPUProperty(CPUPropertyType_PAE, &fEnablePAE); H(); InsertConfigInteger(pRoot, "EnablePAE", fEnablePAE); /* * Hardware virtualization extensions. */ BOOL fIsGuest64Bit; hrc = pMachine->GetCPUProperty(CPUPropertyType_LongMode, &fIsGuest64Bit); H(); BOOL fSupportsLongMode; hrc = host->GetProcessorFeature(ProcessorFeature_LongMode, &fSupportsLongMode); H(); if (!fSupportsLongMode && fIsGuest64Bit) { LogRel(("WARNING! 64-bit guest type selected but the host CPU does NOT support 64-bit.\n")); fIsGuest64Bit = FALSE; } BOOL fHMEnabled; hrc = pMachine->GetHWVirtExProperty(HWVirtExPropertyType_Enabled, &fHMEnabled); H(); if (cCpus > 1 && !fHMEnabled) { LogRel(("Forced fHMEnabled to TRUE by SMP guest.\n")); fHMEnabled = TRUE; } if (!fHMEnabled && fIsGuest64Bit) { LogRel(("WARNING! 64-bit guest type selected on host without hardware virtualization (VT-x or AMD-V).\n")); fIsGuest64Bit = FALSE; } BOOL fHMForced; #ifdef VBOX_WITH_RAW_MODE /* - With more than 4GB PGM will use different RAMRANGE sizes for raw mode and hv mode to optimize lookup times. - With more than one virtual CPU, raw-mode isn't a fallback option. - With a 64-bit guest, raw-mode isn't a fallback option either. */ fHMForced = fHMEnabled && ( cbRam + cbRamHole > _4G || cCpus > 1 || fIsGuest64Bit); # ifdef RT_OS_DARWIN fHMForced = fHMEnabled; # endif if (fHMForced) { if (cbRam + cbRamHole > _4G) LogRel(("fHMForced=TRUE - Lots of RAM\n")); if (cCpus > 1) LogRel(("fHMForced=TRUE - SMP\n")); if (fIsGuest64Bit) LogRel(("fHMForced=TRUE - 64-bit guest\n")); # ifdef RT_OS_DARWIN LogRel(("fHMForced=TRUE - Darwin host\n")); # endif } #else /* !VBOX_WITH_RAW_MODE */ fHMEnabled = fHMForced = TRUE; LogRel(("fHMForced=TRUE - No raw-mode support in this build!\n")); #endif /* !VBOX_WITH_RAW_MODE */ if (!fHMForced) /* No need to query if already forced above. */ { hrc = pMachine->GetHWVirtExProperty(HWVirtExPropertyType_Force, &fHMForced); H(); if (fHMForced) LogRel(("fHMForced=TRUE - HWVirtExPropertyType_Force\n")); } InsertConfigInteger(pRoot, "HMEnabled", fHMEnabled); /* /HM/xzy */ PCFGMNODE pHM; InsertConfigNode(pRoot, "HM", &pHM); InsertConfigInteger(pRoot, "HMForced", fHMForced); if (fHMEnabled) { /* Indicate whether 64-bit guests are supported or not. */ InsertConfigInteger(pHM, "64bitEnabled", fIsGuest64Bit); #if ARCH_BITS == 32 /* The recompiler must use VBoxREM64 (32-bit host only). */ PCFGMNODE pREM; InsertConfigNode(pRoot, "REM", &pREM); InsertConfigInteger(pREM, "64bitEnabled", 1); #endif /** @todo Not exactly pretty to check strings; VBOXOSTYPE would be better, but that requires quite a bit of API change in Main. */ if ( !fIsGuest64Bit && fIOAPIC && ( osTypeId == "WindowsNT4" || osTypeId == "Windows2000" || osTypeId == "WindowsXP" || osTypeId == "Windows2003")) { /* Only allow TPR patching for NT, Win2k, XP and Windows Server 2003. (32 bits mode) * We may want to consider adding more guest OSes (Solaris) later on. */ InsertConfigInteger(pHM, "TPRPatchingEnabled", 1); } } /* HWVirtEx exclusive mode */ BOOL fHMExclusive = true; hrc = systemProperties->COMGETTER(ExclusiveHwVirt)(&fHMExclusive); H(); InsertConfigInteger(pHM, "Exclusive", fHMExclusive); /* Nested paging (VT-x/AMD-V) */ BOOL fEnableNestedPaging = false; hrc = pMachine->GetHWVirtExProperty(HWVirtExPropertyType_NestedPaging, &fEnableNestedPaging); H(); InsertConfigInteger(pHM, "EnableNestedPaging", fEnableNestedPaging); /* Large pages; requires nested paging */ BOOL fEnableLargePages = false; hrc = pMachine->GetHWVirtExProperty(HWVirtExPropertyType_LargePages, &fEnableLargePages); H(); InsertConfigInteger(pHM, "EnableLargePages", fEnableLargePages); /* VPID (VT-x) */ BOOL fEnableVPID = false; hrc = pMachine->GetHWVirtExProperty(HWVirtExPropertyType_VPID, &fEnableVPID); H(); InsertConfigInteger(pHM, "EnableVPID", fEnableVPID); /* Unrestricted execution aka UX (VT-x) */ BOOL fEnableUX = false; hrc = pMachine->GetHWVirtExProperty(HWVirtExPropertyType_UnrestrictedExecution, &fEnableUX); H(); InsertConfigInteger(pHM, "EnableUX", fEnableUX); /* Reset overwrite. */ if (isResetTurnedIntoPowerOff()) InsertConfigInteger(pRoot, "PowerOffInsteadOfReset", 1); /* * MM values. */ PCFGMNODE pMM; InsertConfigNode(pRoot, "MM", &pMM); InsertConfigInteger(pMM, "CanUseLargerHeap", chipsetType == ChipsetType_ICH9); /* * PDM config. * Load drivers in VBoxC.[so|dll] */ PCFGMNODE pPDM; PCFGMNODE pNode; PCFGMNODE pMod; InsertConfigNode(pRoot, "PDM", &pPDM); InsertConfigNode(pPDM, "Devices", &pNode); InsertConfigNode(pPDM, "Drivers", &pNode); InsertConfigNode(pNode, "VBoxC", &pMod); #ifdef VBOX_WITH_XPCOM // VBoxC is located in the components subdirectory char szPathVBoxC[RTPATH_MAX]; rc = RTPathAppPrivateArch(szPathVBoxC, RTPATH_MAX - sizeof("/components/VBoxC")); AssertRC(rc); strcat(szPathVBoxC, "/components/VBoxC"); InsertConfigString(pMod, "Path", szPathVBoxC); #else InsertConfigString(pMod, "Path", "VBoxC"); #endif /* * Block cache settings. */ PCFGMNODE pPDMBlkCache; InsertConfigNode(pPDM, "BlkCache", &pPDMBlkCache); /* I/O cache size */ ULONG ioCacheSize = 5; hrc = pMachine->COMGETTER(IOCacheSize)(&ioCacheSize); H(); InsertConfigInteger(pPDMBlkCache, "CacheSize", ioCacheSize * _1M); /* * Bandwidth groups. */ PCFGMNODE pAc; PCFGMNODE pAcFile; PCFGMNODE pAcFileBwGroups; ComPtr bwCtrl; com::SafeIfaceArray bwGroups; hrc = pMachine->COMGETTER(BandwidthControl)(bwCtrl.asOutParam()); H(); hrc = bwCtrl->GetAllBandwidthGroups(ComSafeArrayAsOutParam(bwGroups)); H(); InsertConfigNode(pPDM, "AsyncCompletion", &pAc); InsertConfigNode(pAc, "File", &pAcFile); InsertConfigNode(pAcFile, "BwGroups", &pAcFileBwGroups); #ifdef VBOX_WITH_NETSHAPER PCFGMNODE pNetworkShaper; PCFGMNODE pNetworkBwGroups; InsertConfigNode(pPDM, "NetworkShaper", &pNetworkShaper); InsertConfigNode(pNetworkShaper, "BwGroups", &pNetworkBwGroups); #endif /* VBOX_WITH_NETSHAPER */ for (size_t i = 0; i < bwGroups.size(); i++) { Bstr strName; LONG64 cMaxBytesPerSec; BandwidthGroupType_T enmType; hrc = bwGroups[i]->COMGETTER(Name)(strName.asOutParam()); H(); hrc = bwGroups[i]->COMGETTER(Type)(&enmType); H(); hrc = bwGroups[i]->COMGETTER(MaxBytesPerSec)(&cMaxBytesPerSec); H(); if (enmType == BandwidthGroupType_Disk) { PCFGMNODE pBwGroup; InsertConfigNode(pAcFileBwGroups, Utf8Str(strName).c_str(), &pBwGroup); InsertConfigInteger(pBwGroup, "Max", cMaxBytesPerSec); InsertConfigInteger(pBwGroup, "Start", cMaxBytesPerSec); InsertConfigInteger(pBwGroup, "Step", 0); } #ifdef VBOX_WITH_NETSHAPER else if (enmType == BandwidthGroupType_Network) { /* Network bandwidth groups. */ PCFGMNODE pBwGroup; InsertConfigNode(pNetworkBwGroups, Utf8Str(strName).c_str(), &pBwGroup); InsertConfigInteger(pBwGroup, "Max", cMaxBytesPerSec); } #endif /* VBOX_WITH_NETSHAPER */ } /* * Devices */ PCFGMNODE pDevices = NULL; /* /Devices */ PCFGMNODE pDev = NULL; /* /Devices/Dev/ */ PCFGMNODE pInst = NULL; /* /Devices/Dev/0/ */ PCFGMNODE pCfg = NULL; /* /Devices/Dev/.../Config/ */ PCFGMNODE pLunL0 = NULL; /* /Devices/Dev/0/LUN#0/ */ PCFGMNODE pLunL1 = NULL; /* /Devices/Dev/0/LUN#0/AttachedDriver/ */ PCFGMNODE pLunL2 = NULL; /* /Devices/Dev/0/LUN#0/AttachedDriver/Config/ */ PCFGMNODE pBiosCfg = NULL; /* /Devices/pcbios/0/Config/ */ PCFGMNODE pNetBootCfg = NULL; /* /Devices/pcbios/0/Config/NetBoot/ */ InsertConfigNode(pRoot, "Devices", &pDevices); /* * PC Arch. */ InsertConfigNode(pDevices, "pcarch", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); /* * The time offset */ LONG64 timeOffset; hrc = biosSettings->COMGETTER(TimeOffset)(&timeOffset); H(); PCFGMNODE pTMNode; InsertConfigNode(pRoot, "TM", &pTMNode); InsertConfigInteger(pTMNode, "UTCOffset", timeOffset * 1000000); /* * DMA */ InsertConfigNode(pDevices, "8237A", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ /* * PCI buses. */ uint32_t uIocPCIAddress, uHbcPCIAddress; switch (chipsetType) { default: Assert(false); case ChipsetType_PIIX3: InsertConfigNode(pDevices, "pci", &pDev); uHbcPCIAddress = (0x0 << 16) | 0; uIocPCIAddress = (0x1 << 16) | 0; // ISA controller break; case ChipsetType_ICH9: InsertConfigNode(pDevices, "ich9pci", &pDev); uHbcPCIAddress = (0x1e << 16) | 0; uIocPCIAddress = (0x1f << 16) | 0; // LPC controller break; } InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pCfg, "IOAPIC", fIOAPIC); if (chipsetType == ChipsetType_ICH9) { /* Provide MCFG info */ InsertConfigInteger(pCfg, "McfgBase", uMcfgBase); InsertConfigInteger(pCfg, "McfgLength", cbMcfgLength); /* And register 2 bridges */ InsertConfigNode(pDevices, "ich9pcibridge", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice("ich9pcibridge", pInst); H(); InsertConfigNode(pDev, "1", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice("ich9pcibridge", pInst); H(); #ifdef VBOX_WITH_PCI_PASSTHROUGH /* Add PCI passthrough devices */ hrc = attachRawPCIDevices(pUVM, pBusMgr, pDevices); H(); #endif } /* * Enable the following devices: HPET, SMC and LPC on MacOS X guests or on ICH9 chipset */ /* * High Precision Event Timer (HPET) */ BOOL fHPETEnabled; /* Other guests may wish to use HPET too, but MacOS X not functional without it */ hrc = pMachine->COMGETTER(HPETEnabled)(&fHPETEnabled); H(); /* so always enable HPET in extended profile */ fHPETEnabled |= fOsXGuest; /* HPET is always present on ICH9 */ fHPETEnabled |= (chipsetType == ChipsetType_ICH9); if (fHPETEnabled) { InsertConfigNode(pDevices, "hpet", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pCfg, "ICH9", (chipsetType == ChipsetType_ICH9) ? 1 : 0); /* boolean */ } /* * System Management Controller (SMC) */ BOOL fSmcEnabled; fSmcEnabled = fOsXGuest; if (fSmcEnabled) { InsertConfigNode(pDevices, "smc", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); bool fGetKeyFromRealSMC; Bstr bstrKey; rc = getSmcDeviceKey(pMachine, bstrKey.asOutParam(), &fGetKeyFromRealSMC); AssertRCReturn(rc, rc); InsertConfigString(pCfg, "DeviceKey", bstrKey); InsertConfigInteger(pCfg, "GetKeyFromRealSMC", fGetKeyFromRealSMC); } /* * Low Pin Count (LPC) bus */ BOOL fLpcEnabled; /** @todo: implement appropriate getter */ fLpcEnabled = fOsXGuest || (chipsetType == ChipsetType_ICH9); if (fLpcEnabled) { InsertConfigNode(pDevices, "lpc", &pDev); InsertConfigNode(pDev, "0", &pInst); hrc = pBusMgr->assignPCIDevice("lpc", pInst); H(); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ } BOOL fShowRtc; fShowRtc = fOsXGuest || (chipsetType == ChipsetType_ICH9); /* * PS/2 keyboard & mouse. */ InsertConfigNode(pDevices, "pckbd", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "KeyboardQueue"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "QueueSize", 64); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "MainKeyboard"); InsertConfigNode(pLunL1, "Config", &pCfg); Keyboard *pKeyboard = mKeyboard; InsertConfigInteger(pCfg, "Object", (uintptr_t)pKeyboard); Mouse *pMouse = mMouse; PointingHIDType_T aPointingHID; hrc = pMachine->COMGETTER(PointingHIDType)(&aPointingHID); H(); InsertConfigNode(pInst, "LUN#1", &pLunL0); InsertConfigString(pLunL0, "Driver", "MouseQueue"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "QueueSize", 128); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "MainMouse"); InsertConfigNode(pLunL1, "Config", &pCfg); InsertConfigInteger(pCfg, "Object", (uintptr_t)pMouse); /* * i8254 Programmable Interval Timer And Dummy Speaker */ InsertConfigNode(pDevices, "i8254", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); #ifdef DEBUG InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ #endif /* * i8259 Programmable Interrupt Controller. */ InsertConfigNode(pDevices, "i8259", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); /* * Advanced Programmable Interrupt Controller. * SMP: Each CPU has a LAPIC, but we have a single device representing all LAPICs states, * thus only single insert */ InsertConfigNode(pDevices, "apic", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pCfg, "IOAPIC", fIOAPIC); InsertConfigInteger(pCfg, "NumCPUs", cCpus); if (fIOAPIC) { /* * I/O Advanced Programmable Interrupt Controller. */ InsertConfigNode(pDevices, "ioapic", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pCfg, "NumCPUs", cCpus); } /* * RTC MC146818. */ InsertConfigNode(pDevices, "mc146818", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); BOOL fRTCUseUTC; hrc = pMachine->COMGETTER(RTCUseUTC)(&fRTCUseUTC); H(); InsertConfigInteger(pCfg, "UseUTC", fRTCUseUTC ? 1 : 0); /* * VGA. */ GraphicsControllerType_T graphicsController; hrc = pMachine->COMGETTER(GraphicsControllerType)(&graphicsController); H(); switch (graphicsController) { case GraphicsControllerType_Null: break; case GraphicsControllerType_VBoxVGA: rc = configGraphicsController(pDevices, "vga", pBusMgr, pMachine, biosSettings, RT_BOOL(fHMEnabled)); if (FAILED(rc)) return rc; break; default: AssertMsgFailed(("Invalid graphicsController=%d\n", graphicsController)); return VMR3SetError(pUVM, VERR_INVALID_PARAMETER, RT_SRC_POS, N_("Invalid graphics controller type '%d'"), graphicsController); } /* * Firmware. */ FirmwareType_T eFwType = FirmwareType_BIOS; hrc = pMachine->COMGETTER(FirmwareType)(&eFwType); H(); #ifdef VBOX_WITH_EFI BOOL fEfiEnabled = (eFwType >= FirmwareType_EFI) && (eFwType <= FirmwareType_EFIDUAL); #else BOOL fEfiEnabled = false; #endif if (!fEfiEnabled) { /* * PC Bios. */ InsertConfigNode(pDevices, "pcbios", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pBiosCfg); InsertConfigInteger(pBiosCfg, "RamSize", cbRam); InsertConfigInteger(pBiosCfg, "RamHoleSize", cbRamHole); InsertConfigInteger(pBiosCfg, "NumCPUs", cCpus); InsertConfigString(pBiosCfg, "HardDiskDevice", "piix3ide"); InsertConfigString(pBiosCfg, "FloppyDevice", "i82078"); InsertConfigInteger(pBiosCfg, "IOAPIC", fIOAPIC); BOOL fPXEDebug; hrc = biosSettings->COMGETTER(PXEDebugEnabled)(&fPXEDebug); H(); InsertConfigInteger(pBiosCfg, "PXEDebug", fPXEDebug); InsertConfigBytes(pBiosCfg, "UUID", &HardwareUuid,sizeof(HardwareUuid)); InsertConfigNode(pBiosCfg, "NetBoot", &pNetBootCfg); InsertConfigInteger(pBiosCfg, "McfgBase", uMcfgBase); InsertConfigInteger(pBiosCfg, "McfgLength", cbMcfgLength); DeviceType_T bootDevice; AssertMsgReturn(SchemaDefs::MaxBootPosition <= 9, ("Too many boot devices %d\n", SchemaDefs::MaxBootPosition), VERR_INVALID_PARAMETER); for (ULONG pos = 1; pos <= SchemaDefs::MaxBootPosition; ++pos) { hrc = pMachine->GetBootOrder(pos, &bootDevice); H(); char szParamName[] = "BootDeviceX"; szParamName[sizeof(szParamName) - 2] = ((char (pos - 1)) + '0'); const char *pszBootDevice; switch (bootDevice) { case DeviceType_Null: pszBootDevice = "NONE"; break; case DeviceType_HardDisk: pszBootDevice = "IDE"; break; case DeviceType_DVD: pszBootDevice = "DVD"; break; case DeviceType_Floppy: pszBootDevice = "FLOPPY"; break; case DeviceType_Network: pszBootDevice = "LAN"; break; default: AssertMsgFailed(("Invalid bootDevice=%d\n", bootDevice)); return VMR3SetError(pUVM, VERR_INVALID_PARAMETER, RT_SRC_POS, N_("Invalid boot device '%d'"), bootDevice); } InsertConfigString(pBiosCfg, szParamName, pszBootDevice); } } else { /* Autodetect firmware type, basing on guest type */ if (eFwType == FirmwareType_EFI) { eFwType = fIsGuest64Bit ? (FirmwareType_T)FirmwareType_EFI64 : (FirmwareType_T)FirmwareType_EFI32; } bool const f64BitEntry = eFwType == FirmwareType_EFI64; Utf8Str efiRomFile; rc = findEfiRom(virtualBox, eFwType, &efiRomFile); AssertRCReturn(rc, rc); /* Get boot args */ Bstr bootArgs; hrc = pMachine->GetExtraData(Bstr("VBoxInternal2/EfiBootArgs").raw(), bootArgs.asOutParam()); H(); /* Get device props */ Bstr deviceProps; hrc = pMachine->GetExtraData(Bstr("VBoxInternal2/EfiDeviceProps").raw(), deviceProps.asOutParam()); H(); /* Get GOP mode settings */ uint32_t u32GopMode = UINT32_MAX; hrc = pMachine->GetExtraData(Bstr("VBoxInternal2/EfiGopMode").raw(), bstr.asOutParam()); H(); if (!bstr.isEmpty()) u32GopMode = Utf8Str(bstr).toUInt32(); /* UGA mode settings */ uint32_t u32UgaHorisontal = 0; hrc = pMachine->GetExtraData(Bstr("VBoxInternal2/EfiUgaHorizontalResolution").raw(), bstr.asOutParam()); H(); if (!bstr.isEmpty()) u32UgaHorisontal = Utf8Str(bstr).toUInt32(); uint32_t u32UgaVertical = 0; hrc = pMachine->GetExtraData(Bstr("VBoxInternal2/EfiUgaVerticalResolution").raw(), bstr.asOutParam()); H(); if (!bstr.isEmpty()) u32UgaVertical = Utf8Str(bstr).toUInt32(); /* * EFI subtree. */ InsertConfigNode(pDevices, "efi", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pCfg, "RamSize", cbRam); InsertConfigInteger(pCfg, "RamHoleSize", cbRamHole); InsertConfigInteger(pCfg, "NumCPUs", cCpus); InsertConfigString(pCfg, "EfiRom", efiRomFile); InsertConfigString(pCfg, "BootArgs", bootArgs); InsertConfigString(pCfg, "DeviceProps", deviceProps); InsertConfigInteger(pCfg, "IOAPIC", fIOAPIC); InsertConfigBytes(pCfg, "UUID", &HardwareUuid,sizeof(HardwareUuid)); InsertConfigInteger(pCfg, "64BitEntry", f64BitEntry); /* boolean */ InsertConfigInteger(pCfg, "GopMode", u32GopMode); InsertConfigInteger(pCfg, "UgaHorizontalResolution", u32UgaHorisontal); InsertConfigInteger(pCfg, "UgaVerticalResolution", u32UgaVertical); /* For OS X guests we'll force passing host's DMI info to the guest */ if (fOsXGuest) { InsertConfigInteger(pCfg, "DmiUseHostInfo", 1); InsertConfigInteger(pCfg, "DmiExposeMemoryTable", 1); } InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "NvramStorage"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "Object", (uintptr_t)mNvram); #ifdef DEBUG_vvl InsertConfigInteger(pCfg, "PermanentSave", 1); #endif } /* * Storage controllers. */ com::SafeIfaceArray ctrls; PCFGMNODE aCtrlNodes[StorageControllerType_LsiLogicSas + 1] = {}; hrc = pMachine->COMGETTER(StorageControllers)(ComSafeArrayAsOutParam(ctrls)); H(); bool fFdcEnabled = false; for (size_t i = 0; i < ctrls.size(); ++i) { DeviceType_T *paLedDevType = NULL; StorageControllerType_T enmCtrlType; rc = ctrls[i]->COMGETTER(ControllerType)(&enmCtrlType); H(); AssertRelease((unsigned)enmCtrlType < RT_ELEMENTS(aCtrlNodes)); StorageBus_T enmBus; rc = ctrls[i]->COMGETTER(Bus)(&enmBus); H(); Bstr controllerName; rc = ctrls[i]->COMGETTER(Name)(controllerName.asOutParam()); H(); ULONG ulInstance = 999; rc = ctrls[i]->COMGETTER(Instance)(&ulInstance); H(); BOOL fUseHostIOCache; rc = ctrls[i]->COMGETTER(UseHostIOCache)(&fUseHostIOCache); H(); BOOL fBootable; rc = ctrls[i]->COMGETTER(Bootable)(&fBootable); H(); /* /Devices// */ const char *pszCtrlDev = convertControllerTypeToDev(enmCtrlType); pDev = aCtrlNodes[enmCtrlType]; if (!pDev) { InsertConfigNode(pDevices, pszCtrlDev, &pDev); aCtrlNodes[enmCtrlType] = pDev; /* IDE variants are handled in the switch */ } /* /Devices/// */ PCFGMNODE pCtlInst = NULL; InsertConfigNode(pDev, Utf8StrFmt("%u", ulInstance).c_str(), &pCtlInst); /* Device config: /Devices/// & /ditto/Config/ */ InsertConfigInteger(pCtlInst, "Trusted", 1); InsertConfigNode(pCtlInst, "Config", &pCfg); switch (enmCtrlType) { case StorageControllerType_LsiLogic: { hrc = pBusMgr->assignPCIDevice("lsilogic", pCtlInst); H(); InsertConfigInteger(pCfg, "Bootable", fBootable); /* Attach the status driver */ Assert(cLedScsi >= 16); attachStatusDriver(pCtlInst, &mapStorageLeds[iLedScsi], 0, 15, &mapMediumAttachments, pszCtrlDev, ulInstance); paLedDevType = &maStorageDevType[iLedScsi]; break; } case StorageControllerType_BusLogic: { hrc = pBusMgr->assignPCIDevice("buslogic", pCtlInst); H(); InsertConfigInteger(pCfg, "Bootable", fBootable); /* Attach the status driver */ Assert(cLedScsi >= 16); attachStatusDriver(pCtlInst, &mapStorageLeds[iLedScsi], 0, 15, &mapMediumAttachments, pszCtrlDev, ulInstance); paLedDevType = &maStorageDevType[iLedScsi]; break; } case StorageControllerType_IntelAhci: { hrc = pBusMgr->assignPCIDevice("ahci", pCtlInst); H(); ULONG cPorts = 0; hrc = ctrls[i]->COMGETTER(PortCount)(&cPorts); H(); InsertConfigInteger(pCfg, "PortCount", cPorts); InsertConfigInteger(pCfg, "Bootable", fBootable); /* Needed configuration values for the bios, only first controller. */ if (!pBusMgr->hasPCIDevice("ahci", 1)) { #define MAX_SATA_LUN_COUNT 4 #define MAX_SATA_PORTS 30 static const char * const s_apszBiosConfig[4] = { "SataLUN1", "SataLUN2", "SataLUN3", "SataLUN4" }; LONG lPortLUN[MAX_SATA_LUN_COUNT]; LONG lPortUsed[MAX_SATA_PORTS]; uint32_t u32HDSataPortCount = 0; /* init to max value */ lPortLUN[0] = MAX_SATA_PORTS; if (pBiosCfg) { InsertConfigString(pBiosCfg, "SataHardDiskDevice", "ahci"); } com::SafeIfaceArray atts; hrc = pMachine->GetMediumAttachmentsOfController(controllerName.raw(), ComSafeArrayAsOutParam(atts)); H(); size_t uNumAttachments = atts.size(); if (uNumAttachments > MAX_SATA_PORTS) { LogRel(("Number of Sata Port Attachments > Max=%d.\n", uNumAttachments)); uNumAttachments = MAX_SATA_PORTS; } /* find the relavant ports i.e Sata ports to which * HD is attached. */ for (size_t j = 0; j < uNumAttachments; ++j) { IMediumAttachment *pMediumAtt = atts[j]; LONG lPortNum = 0; hrc = pMediumAtt->COMGETTER(Port)(&lPortNum); H(); if (SUCCEEDED(hrc)) { DeviceType_T lType; hrc = pMediumAtt->COMGETTER(Type)(&lType); H(); if (SUCCEEDED(hrc) && lType == DeviceType_HardDisk) { /* find min port number used for HD */ if (lPortNum < lPortLUN[0]) lPortLUN[0] = lPortNum; lPortUsed[u32HDSataPortCount++] = lPortNum; LogFlowFunc(("HD Sata port Count=%d\n", u32HDSataPortCount)); } } } /* Pick only the top 4 used HD Sata Ports as CMOS doesn't have space * to save details for every 30 ports */ uint32_t u32MaxPortCount = MAX_SATA_LUN_COUNT; if (u32HDSataPortCount < MAX_SATA_LUN_COUNT) u32MaxPortCount = u32HDSataPortCount; for (size_t j = 1; j < u32MaxPortCount; j++) lPortLUN[j] = GetNextUsedSataPort(lPortUsed, lPortLUN[j-1], u32HDSataPortCount); if (pBiosCfg) { for (size_t j = 0; j < u32MaxPortCount; j++) { InsertConfigInteger(pBiosCfg, s_apszBiosConfig[j], lPortLUN[j]); LogFlowFunc(("Top %d ports = %s, %d\n", j, s_apszBiosConfig[j], lPortLUN[j])); } } } /* Attach the status driver */ AssertRelease(cPorts <= cLedSata); attachStatusDriver(pCtlInst, &mapStorageLeds[iLedSata], 0, cPorts - 1, &mapMediumAttachments, pszCtrlDev, ulInstance); paLedDevType = &maStorageDevType[iLedSata]; break; } case StorageControllerType_PIIX3: case StorageControllerType_PIIX4: case StorageControllerType_ICH6: { /* * IDE (update this when the main interface changes) */ hrc = pBusMgr->assignPCIDevice("piix3ide", pCtlInst); H(); InsertConfigString(pCfg, "Type", controllerString(enmCtrlType)); /* Attach the status driver */ Assert(cLedIde >= 4); attachStatusDriver(pCtlInst, &mapStorageLeds[iLedIde], 0, 3, &mapMediumAttachments, pszCtrlDev, ulInstance); paLedDevType = &maStorageDevType[iLedIde]; /* IDE flavors */ aCtrlNodes[StorageControllerType_PIIX3] = pDev; aCtrlNodes[StorageControllerType_PIIX4] = pDev; aCtrlNodes[StorageControllerType_ICH6] = pDev; break; } case StorageControllerType_I82078: { /* * i82078 Floppy drive controller */ fFdcEnabled = true; InsertConfigInteger(pCfg, "IRQ", 6); InsertConfigInteger(pCfg, "DMA", 2); InsertConfigInteger(pCfg, "MemMapped", 0 ); InsertConfigInteger(pCfg, "IOBase", 0x3f0); /* Attach the status driver */ Assert(cLedFloppy >= 2); attachStatusDriver(pCtlInst, &mapStorageLeds[iLedFloppy], 0, 1, &mapMediumAttachments, pszCtrlDev, ulInstance); paLedDevType = &maStorageDevType[iLedFloppy]; break; } case StorageControllerType_LsiLogicSas: { hrc = pBusMgr->assignPCIDevice("lsilogicsas", pCtlInst); H(); InsertConfigString(pCfg, "ControllerType", "SAS1068"); InsertConfigInteger(pCfg, "Bootable", fBootable); /* Attach the status driver */ Assert(cLedSas >= 8); attachStatusDriver(pCtlInst, &mapStorageLeds[iLedSas], 0, 7, &mapMediumAttachments, pszCtrlDev, ulInstance); paLedDevType = &maStorageDevType[iLedSas]; break; } default: AssertMsgFailedReturn(("invalid storage controller type: %d\n", enmCtrlType), VERR_GENERAL_FAILURE); } /* Attach the media to the storage controllers. */ com::SafeIfaceArray atts; hrc = pMachine->GetMediumAttachmentsOfController(controllerName.raw(), ComSafeArrayAsOutParam(atts)); H(); /* Builtin I/O cache - per device setting. */ BOOL fBuiltinIOCache = true; hrc = pMachine->COMGETTER(IOCacheEnabled)(&fBuiltinIOCache); H(); for (size_t j = 0; j < atts.size(); ++j) { IMediumAttachment *pMediumAtt = atts[j]; rc = configMediumAttachment(pCtlInst, pszCtrlDev, ulInstance, enmBus, !!fUseHostIOCache, !!fBuiltinIOCache, false /* fSetupMerge */, 0 /* uMergeSource */, 0 /* uMergeTarget */, pMediumAtt, mMachineState, NULL /* phrc */, false /* fAttachDetach */, false /* fForceUnmount */, false /* fHotplug */, pUVM, paLedDevType); if (RT_FAILURE(rc)) return rc; } H(); } H(); /* * Network adapters */ #ifdef VMWARE_NET_IN_SLOT_11 bool fSwapSlots3and11 = false; #endif PCFGMNODE pDevPCNet = NULL; /* PCNet-type devices */ InsertConfigNode(pDevices, "pcnet", &pDevPCNet); #ifdef VBOX_WITH_E1000 PCFGMNODE pDevE1000 = NULL; /* E1000-type devices */ InsertConfigNode(pDevices, "e1000", &pDevE1000); #endif #ifdef VBOX_WITH_VIRTIO PCFGMNODE pDevVirtioNet = NULL; /* Virtio network devices */ InsertConfigNode(pDevices, "virtio-net", &pDevVirtioNet); #endif /* VBOX_WITH_VIRTIO */ std::list llBootNics; for (ULONG ulInstance = 0; ulInstance < maxNetworkAdapters; ++ulInstance) { ComPtr networkAdapter; hrc = pMachine->GetNetworkAdapter(ulInstance, networkAdapter.asOutParam()); H(); BOOL fEnabledNetAdapter = FALSE; hrc = networkAdapter->COMGETTER(Enabled)(&fEnabledNetAdapter); H(); if (!fEnabledNetAdapter) continue; /* * The virtual hardware type. Create appropriate device first. */ const char *pszAdapterName = "pcnet"; NetworkAdapterType_T adapterType; hrc = networkAdapter->COMGETTER(AdapterType)(&adapterType); H(); switch (adapterType) { case NetworkAdapterType_Am79C970A: case NetworkAdapterType_Am79C973: pDev = pDevPCNet; break; #ifdef VBOX_WITH_E1000 case NetworkAdapterType_I82540EM: case NetworkAdapterType_I82543GC: case NetworkAdapterType_I82545EM: pDev = pDevE1000; pszAdapterName = "e1000"; break; #endif #ifdef VBOX_WITH_VIRTIO case NetworkAdapterType_Virtio: pDev = pDevVirtioNet; pszAdapterName = "virtio-net"; break; #endif /* VBOX_WITH_VIRTIO */ default: AssertMsgFailed(("Invalid network adapter type '%d' for slot '%d'", adapterType, ulInstance)); return VMR3SetError(pUVM, VERR_INVALID_PARAMETER, RT_SRC_POS, N_("Invalid network adapter type '%d' for slot '%d'"), adapterType, ulInstance); } InsertConfigNode(pDev, Utf8StrFmt("%u", ulInstance).c_str(), &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ /* the first network card gets the PCI ID 3, the next 3 gets 8..10, * next 4 get 16..19. */ int iPCIDeviceNo; switch (ulInstance) { case 0: iPCIDeviceNo = 3; break; case 1: case 2: case 3: iPCIDeviceNo = ulInstance - 1 + 8; break; case 4: case 5: case 6: case 7: iPCIDeviceNo = ulInstance - 4 + 16; break; default: /* auto assignment */ iPCIDeviceNo = -1; break; } #ifdef VMWARE_NET_IN_SLOT_11 /* * Dirty hack for PCI slot compatibility with VMWare, * it assigns slot 0x11 to the first network controller. */ if (iPCIDeviceNo == 3 && adapterType == NetworkAdapterType_I82545EM) { iPCIDeviceNo = 0x11; fSwapSlots3and11 = true; } else if (iPCIDeviceNo == 0x11 && fSwapSlots3and11) iPCIDeviceNo = 3; #endif PCIBusAddress PCIAddr = PCIBusAddress(0, iPCIDeviceNo, 0); hrc = pBusMgr->assignPCIDevice(pszAdapterName, pInst, PCIAddr); H(); InsertConfigNode(pInst, "Config", &pCfg); #ifdef VBOX_WITH_2X_4GB_ADDR_SPACE /* not safe here yet. */ /** @todo Make PCNet ring-0 safe on 32-bit mac kernels! */ if (pDev == pDevPCNet) { InsertConfigInteger(pCfg, "R0Enabled", false); } #endif /* * Collect information needed for network booting and add it to the list. */ BootNic nic; nic.mInstance = ulInstance; /* Could be updated by reference, if auto assigned */ nic.mPCIAddress = PCIAddr; hrc = networkAdapter->COMGETTER(BootPriority)(&nic.mBootPrio); H(); llBootNics.push_back(nic); /* * The virtual hardware type. PCNet supports two types. */ switch (adapterType) { case NetworkAdapterType_Am79C970A: InsertConfigInteger(pCfg, "Am79C973", 0); break; case NetworkAdapterType_Am79C973: InsertConfigInteger(pCfg, "Am79C973", 1); break; case NetworkAdapterType_I82540EM: InsertConfigInteger(pCfg, "AdapterType", 0); break; case NetworkAdapterType_I82543GC: InsertConfigInteger(pCfg, "AdapterType", 1); break; case NetworkAdapterType_I82545EM: InsertConfigInteger(pCfg, "AdapterType", 2); break; } /* * Get the MAC address and convert it to binary representation */ Bstr macAddr; hrc = networkAdapter->COMGETTER(MACAddress)(macAddr.asOutParam()); H(); Assert(!macAddr.isEmpty()); Utf8Str macAddrUtf8 = macAddr; char *macStr = (char*)macAddrUtf8.c_str(); Assert(strlen(macStr) == 12); RTMAC Mac; RT_ZERO(Mac); char *pMac = (char*)&Mac; for (uint32_t i = 0; i < 6; ++i) { char c1 = *macStr++ - '0'; if (c1 > 9) c1 -= 7; char c2 = *macStr++ - '0'; if (c2 > 9) c2 -= 7; *pMac++ = ((c1 & 0x0f) << 4) | (c2 & 0x0f); } InsertConfigBytes(pCfg, "MAC", &Mac, sizeof(Mac)); /* * Check if the cable is supposed to be unplugged */ BOOL fCableConnected; hrc = networkAdapter->COMGETTER(CableConnected)(&fCableConnected); H(); InsertConfigInteger(pCfg, "CableConnected", fCableConnected ? 1 : 0); /* * Line speed to report from custom drivers */ ULONG ulLineSpeed; hrc = networkAdapter->COMGETTER(LineSpeed)(&ulLineSpeed); H(); InsertConfigInteger(pCfg, "LineSpeed", ulLineSpeed); /* * Attach the status driver. */ attachStatusDriver(pInst, &mapNetworkLeds[ulInstance], 0, 0, NULL, NULL, 0); /* * Configure the network card now */ bool fIgnoreConnectFailure = mMachineState == MachineState_Restoring; rc = configNetwork(pszAdapterName, ulInstance, 0, networkAdapter, pCfg, pLunL0, pInst, false /*fAttachDetach*/, fIgnoreConnectFailure); if (RT_FAILURE(rc)) return rc; } /* * Build network boot information and transfer it to the BIOS. */ if (pNetBootCfg && !llBootNics.empty()) /* NetBoot node doesn't exist for EFI! */ { llBootNics.sort(); /* Sort the list by boot priority. */ char achBootIdx[] = "0"; unsigned uBootIdx = 0; for (std::list::iterator it = llBootNics.begin(); it != llBootNics.end(); ++it) { /* A NIC with priority 0 is only used if it's first in the list. */ if (it->mBootPrio == 0 && uBootIdx != 0) break; PCFGMNODE pNetBtDevCfg; achBootIdx[0] = '0' + uBootIdx++; /* Boot device order. */ InsertConfigNode(pNetBootCfg, achBootIdx, &pNetBtDevCfg); InsertConfigInteger(pNetBtDevCfg, "NIC", it->mInstance); InsertConfigInteger(pNetBtDevCfg, "PCIBusNo", it->mPCIAddress.miBus); InsertConfigInteger(pNetBtDevCfg, "PCIDeviceNo", it->mPCIAddress.miDevice); InsertConfigInteger(pNetBtDevCfg, "PCIFunctionNo", it->mPCIAddress.miFn); } } /* * Serial (UART) Ports */ /* serial enabled mask to be passed to dev ACPI */ uint16_t auSerialIoPortBase[SchemaDefs::SerialPortCount] = {0}; uint8_t auSerialIrq[SchemaDefs::SerialPortCount] = {0}; InsertConfigNode(pDevices, "serial", &pDev); for (ULONG ulInstance = 0; ulInstance < SchemaDefs::SerialPortCount; ++ulInstance) { ComPtr serialPort; hrc = pMachine->GetSerialPort(ulInstance, serialPort.asOutParam()); H(); BOOL fEnabledSerPort = FALSE; if (serialPort) hrc = serialPort->COMGETTER(Enabled)(&fEnabledSerPort); H(); if (!fEnabledSerPort) continue; InsertConfigNode(pDev, Utf8StrFmt("%u", ulInstance).c_str(), &pInst); InsertConfigNode(pInst, "Config", &pCfg); ULONG ulIRQ; hrc = serialPort->COMGETTER(IRQ)(&ulIRQ); H(); InsertConfigInteger(pCfg, "IRQ", ulIRQ); auSerialIrq[ulInstance] = (uint8_t)ulIRQ; ULONG ulIOBase; hrc = serialPort->COMGETTER(IOBase)(&ulIOBase); H(); InsertConfigInteger(pCfg, "IOBase", ulIOBase); auSerialIoPortBase[ulInstance] = (uint16_t)ulIOBase; BOOL fServer; hrc = serialPort->COMGETTER(Server)(&fServer); H(); hrc = serialPort->COMGETTER(Path)(bstr.asOutParam()); H(); PortMode_T eHostMode; hrc = serialPort->COMGETTER(HostMode)(&eHostMode); H(); if (eHostMode != PortMode_Disconnected) { InsertConfigNode(pInst, "LUN#0", &pLunL0); if (eHostMode == PortMode_HostPipe) { InsertConfigString(pLunL0, "Driver", "Char"); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "NamedPipe"); InsertConfigNode(pLunL1, "Config", &pLunL2); InsertConfigString(pLunL2, "Location", bstr); InsertConfigInteger(pLunL2, "IsServer", fServer); } else if (eHostMode == PortMode_HostDevice) { InsertConfigString(pLunL0, "Driver", "Host Serial"); InsertConfigNode(pLunL0, "Config", &pLunL1); InsertConfigString(pLunL1, "DevicePath", bstr); } else if (eHostMode == PortMode_RawFile) { InsertConfigString(pLunL0, "Driver", "Char"); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "RawFile"); InsertConfigNode(pLunL1, "Config", &pLunL2); InsertConfigString(pLunL2, "Location", bstr); } } } /* * Parallel (LPT) Ports */ InsertConfigNode(pDevices, "parallel", &pDev); for (ULONG ulInstance = 0; ulInstance < SchemaDefs::ParallelPortCount; ++ulInstance) { ComPtr parallelPort; hrc = pMachine->GetParallelPort(ulInstance, parallelPort.asOutParam()); H(); BOOL fEnabledParPort = FALSE; if (parallelPort) { hrc = parallelPort->COMGETTER(Enabled)(&fEnabledParPort); H(); } if (!fEnabledParPort) continue; InsertConfigNode(pDev, Utf8StrFmt("%u", ulInstance).c_str(), &pInst); InsertConfigNode(pInst, "Config", &pCfg); ULONG ulIRQ; hrc = parallelPort->COMGETTER(IRQ)(&ulIRQ); H(); InsertConfigInteger(pCfg, "IRQ", ulIRQ); ULONG ulIOBase; hrc = parallelPort->COMGETTER(IOBase)(&ulIOBase); H(); InsertConfigInteger(pCfg, "IOBase", ulIOBase); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "HostParallel"); InsertConfigNode(pLunL0, "Config", &pLunL1); hrc = parallelPort->COMGETTER(Path)(bstr.asOutParam()); H(); InsertConfigString(pLunL1, "DevicePath", bstr); } /* * VMM Device */ InsertConfigNode(pDevices, "VMMDev", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice("VMMDev", pInst); H(); Bstr hwVersion; hrc = pMachine->COMGETTER(HardwareVersion)(hwVersion.asOutParam()); H(); InsertConfigInteger(pCfg, "RamSize", cbRam); if (hwVersion.compare(Bstr("1").raw()) == 0) /* <= 2.0.x */ InsertConfigInteger(pCfg, "HeapEnabled", 0); Bstr snapshotFolder; hrc = pMachine->COMGETTER(SnapshotFolder)(snapshotFolder.asOutParam()); H(); InsertConfigString(pCfg, "GuestCoreDumpDir", snapshotFolder); /* the VMM device's Main driver */ InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "HGCM"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "Object", (uintptr_t)pVMMDev); /* * Attach the status driver. */ attachStatusDriver(pInst, &mapSharedFolderLed, 0, 0, NULL, NULL, 0); /* * Audio Sniffer Device */ InsertConfigNode(pDevices, "AudioSniffer", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); /* the Audio Sniffer device's Main driver */ InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "MainAudioSniffer"); InsertConfigNode(pLunL0, "Config", &pCfg); AudioSniffer *pAudioSniffer = mAudioSniffer; InsertConfigInteger(pCfg, "Object", (uintptr_t)pAudioSniffer); /* * AC'97 ICH / SoundBlaster16 audio / Intel HD Audio */ BOOL fAudioEnabled = FALSE; ComPtr audioAdapter; hrc = pMachine->COMGETTER(AudioAdapter)(audioAdapter.asOutParam()); H(); if (audioAdapter) hrc = audioAdapter->COMGETTER(Enabled)(&fAudioEnabled); H(); if (fAudioEnabled) { AudioControllerType_T audioController; hrc = audioAdapter->COMGETTER(AudioController)(&audioController); H(); switch (audioController) { case AudioControllerType_AC97: { /* default: ICH AC97 */ InsertConfigNode(pDevices, "ichac97", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice("ichac97", pInst); H(); InsertConfigNode(pInst, "Config", &pCfg); break; } case AudioControllerType_SB16: { /* legacy SoundBlaster16 */ InsertConfigNode(pDevices, "sb16", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pCfg, "IRQ", 5); InsertConfigInteger(pCfg, "DMA", 1); InsertConfigInteger(pCfg, "DMA16", 5); InsertConfigInteger(pCfg, "Port", 0x220); InsertConfigInteger(pCfg, "Version", 0x0405); break; } case AudioControllerType_HDA: { /* Intel HD Audio */ InsertConfigNode(pDevices, "hda", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice("hda", pInst); H(); InsertConfigNode(pInst, "Config", &pCfg); } } /* the Audio driver */ InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "AUDIO"); InsertConfigNode(pLunL0, "Config", &pCfg); AudioDriverType_T audioDriver; hrc = audioAdapter->COMGETTER(AudioDriver)(&audioDriver); H(); switch (audioDriver) { case AudioDriverType_Null: { InsertConfigString(pCfg, "AudioDriver", "null"); break; } #ifdef RT_OS_WINDOWS #ifdef VBOX_WITH_WINMM case AudioDriverType_WinMM: { InsertConfigString(pCfg, "AudioDriver", "winmm"); break; } #endif case AudioDriverType_DirectSound: { InsertConfigString(pCfg, "AudioDriver", "dsound"); break; } #endif /* RT_OS_WINDOWS */ #ifdef RT_OS_SOLARIS case AudioDriverType_SolAudio: { InsertConfigString(pCfg, "AudioDriver", "solaudio"); break; } #endif #ifdef RT_OS_LINUX # ifdef VBOX_WITH_ALSA case AudioDriverType_ALSA: { InsertConfigString(pCfg, "AudioDriver", "alsa"); break; } # endif # ifdef VBOX_WITH_PULSE case AudioDriverType_Pulse: { InsertConfigString(pCfg, "AudioDriver", "pulse"); break; } # endif #endif /* RT_OS_LINUX */ #if defined(RT_OS_LINUX) || defined(RT_OS_FREEBSD) || defined(VBOX_WITH_SOLARIS_OSS) case AudioDriverType_OSS: { InsertConfigString(pCfg, "AudioDriver", "oss"); break; } #endif #ifdef RT_OS_FREEBSD # ifdef VBOX_WITH_PULSE case AudioDriverType_Pulse: { InsertConfigString(pCfg, "AudioDriver", "pulse"); break; } # endif #endif #ifdef RT_OS_DARWIN case AudioDriverType_CoreAudio: { InsertConfigString(pCfg, "AudioDriver", "coreaudio"); break; } #endif } hrc = pMachine->COMGETTER(Name)(bstr.asOutParam()); H(); InsertConfigString(pCfg, "StreamName", bstr); } /* * The USB Controllers. */ com::SafeIfaceArray usbCtrls; hrc = pMachine->COMGETTER(USBControllers)(ComSafeArrayAsOutParam(usbCtrls)); H(); bool fOhciPresent = false; /**< Flag whether at least one OHCI controller is presnet. */ for (size_t i = 0; i < usbCtrls.size(); ++i) { USBControllerType_T enmCtrlType; rc = usbCtrls[i]->COMGETTER(Type)(&enmCtrlType); H(); if (enmCtrlType == USBControllerType_OHCI) { fOhciPresent = true; break; } } /* * Currently EHCI is only enabled when a OHCI controller is present too. * This might change when XHCI is supported. */ if (fOhciPresent) mfVMHasUsbController = true; if (mfVMHasUsbController) { for (size_t i = 0; i < usbCtrls.size(); ++i) { USBControllerType_T enmCtrlType; rc = usbCtrls[i]->COMGETTER(Type)(&enmCtrlType); H(); if (enmCtrlType == USBControllerType_OHCI) { InsertConfigNode(pDevices, "usb-ohci", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice("usb-ohci", pInst); H(); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "VUSBRootHub"); InsertConfigNode(pLunL0, "Config", &pCfg); /* * Attach the status driver. */ attachStatusDriver(pInst, &mapUSBLed[0], 0, 0, NULL, NULL, 0); } #ifdef VBOX_WITH_EHCI else if (enmCtrlType == USBControllerType_EHCI) { /* * USB 2.0 is only available if the proper ExtPack is installed. * * Note. Configuring EHCI here and providing messages about * the missing extpack isn't exactly clean, but it is a * necessary evil to patch over legacy compatability issues * introduced by the new distribution model. */ static const char *s_pszUsbExtPackName = "Oracle VM VirtualBox Extension Pack"; # ifdef VBOX_WITH_EXTPACK if (mptrExtPackManager->isExtPackUsable(s_pszUsbExtPackName)) # endif { InsertConfigNode(pDevices, "usb-ehci", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice("usb-ehci", pInst); H(); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "VUSBRootHub"); InsertConfigNode(pLunL0, "Config", &pCfg); /* * Attach the status driver. */ attachStatusDriver(pInst, &mapUSBLed[1], 0, 0, NULL, NULL, 0); } # ifdef VBOX_WITH_EXTPACK else { /* Always fatal! Up to VBox 4.0.4 we allowed to start the VM anyway * but this induced problems when the user saved + restored the VM! */ return VMR3SetError(pUVM, VERR_NOT_FOUND, RT_SRC_POS, N_("Implementation of the USB 2.0 controller not found!\n" "Because the USB 2.0 controller state is part of the saved " "VM state, the VM cannot be started. To fix " "this problem, either install the '%s' or disable USB 2.0 " "support in the VM settings"), s_pszUsbExtPackName); } # endif } #endif } /* for every USB controller. */ /* * Virtual USB Devices. */ PCFGMNODE pUsbDevices = NULL; InsertConfigNode(pRoot, "USB", &pUsbDevices); #ifdef VBOX_WITH_USB { /* * Global USB options, currently unused as we'll apply the 2.0 -> 1.1 morphing * on a per device level now. */ InsertConfigNode(pUsbDevices, "USBProxy", &pCfg); InsertConfigNode(pCfg, "GlobalConfig", &pCfg); // This globally enables the 2.0 -> 1.1 device morphing of proxied devices to keep windows quiet. //InsertConfigInteger(pCfg, "Force11Device", true); // The following breaks stuff, but it makes MSDs work in vista. (I include it here so // that it's documented somewhere.) Users needing it can use: // VBoxManage setextradata "myvm" "VBoxInternal/USB/USBProxy/GlobalConfig/Force11PacketSize" 1 //InsertConfigInteger(pCfg, "Force11PacketSize", true); } #endif #ifdef VBOX_WITH_USB_CARDREADER BOOL aEmulatedUSBCardReaderEnabled = FALSE; hrc = pMachine->COMGETTER(EmulatedUSBCardReaderEnabled)(&aEmulatedUSBCardReaderEnabled); H(); if (aEmulatedUSBCardReaderEnabled) { InsertConfigNode(pUsbDevices, "CardReader", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigNode(pInst, "LUN#0", &pLunL0); # ifdef VBOX_WITH_USB_CARDREADER_TEST InsertConfigString(pLunL0, "Driver", "DrvDirectCardReader"); InsertConfigNode(pLunL0, "Config", &pCfg); # else InsertConfigString(pLunL0, "Driver", "UsbCardReader"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "Object", (uintptr_t)mUsbCardReader); # endif } #endif # if 0 /* Virtual MSD*/ InsertConfigNode(pUsbDevices, "Msd", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "SCSI"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "Block"); InsertConfigNode(pLunL1, "Config", &pCfg); InsertConfigString(pCfg, "Type", "HardDisk"); InsertConfigInteger(pCfg, "Mountable", 0); InsertConfigNode(pLunL1, "AttachedDriver", &pLunL2); InsertConfigString(pLunL2, "Driver", "VD"); InsertConfigNode(pLunL2, "Config", &pCfg); InsertConfigString(pCfg, "Path", "/Volumes/DataHFS/bird/VDIs/linux.vdi"); InsertConfigString(pCfg, "Format", "VDI"); # endif /* Virtual USB Mouse/Tablet */ if ( aPointingHID == PointingHIDType_USBMouse || aPointingHID == PointingHIDType_ComboMouse || aPointingHID == PointingHIDType_USBTablet || aPointingHID == PointingHIDType_USBMultiTouch) InsertConfigNode(pUsbDevices, "HidMouse", &pDev); if (aPointingHID == PointingHIDType_USBMouse) { InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigString(pCfg, "Mode", "relative"); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "MouseQueue"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "QueueSize", 128); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "MainMouse"); InsertConfigNode(pLunL1, "Config", &pCfg); InsertConfigInteger(pCfg, "Object", (uintptr_t)pMouse); } if ( aPointingHID == PointingHIDType_USBTablet || aPointingHID == PointingHIDType_USBMultiTouch) { InsertConfigNode(pDev, "1", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigString(pCfg, "Mode", "absolute"); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "MouseQueue"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "QueueSize", 128); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "MainMouse"); InsertConfigNode(pLunL1, "Config", &pCfg); InsertConfigInteger(pCfg, "Object", (uintptr_t)pMouse); } if (aPointingHID == PointingHIDType_USBMultiTouch) { InsertConfigNode(pDev, "2", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigString(pCfg, "Mode", "multitouch"); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "MouseQueue"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "QueueSize", 128); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "MainMouse"); InsertConfigNode(pLunL1, "Config", &pCfg); InsertConfigInteger(pCfg, "Object", (uintptr_t)pMouse); } /* Virtual USB Keyboard */ KeyboardHIDType_T aKbdHID; hrc = pMachine->COMGETTER(KeyboardHIDType)(&aKbdHID); H(); if (aKbdHID == KeyboardHIDType_USBKeyboard) { InsertConfigNode(pUsbDevices, "HidKeyboard", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigNode(pInst, "Config", &pCfg); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "KeyboardQueue"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "QueueSize", 64); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "MainKeyboard"); InsertConfigNode(pLunL1, "Config", &pCfg); pKeyboard = mKeyboard; InsertConfigInteger(pCfg, "Object", (uintptr_t)pKeyboard); } } /* * Clipboard */ { ClipboardMode_T mode = ClipboardMode_Disabled; hrc = pMachine->COMGETTER(ClipboardMode)(&mode); H(); if (/* mode != ClipboardMode_Disabled */ true) { /* Load the service */ rc = pVMMDev->hgcmLoadService("VBoxSharedClipboard", "VBoxSharedClipboard"); if (RT_FAILURE(rc)) { LogRel(("VBoxSharedClipboard is not available. rc = %Rrc\n", rc)); /* That is not a fatal failure. */ rc = VINF_SUCCESS; } else { changeClipboardMode(mode); /* Setup the service. */ VBOXHGCMSVCPARM parm; parm.type = VBOX_HGCM_SVC_PARM_32BIT; parm.setUInt32(!useHostClipboard()); pVMMDev->hgcmHostCall("VBoxSharedClipboard", VBOX_SHARED_CLIPBOARD_HOST_FN_SET_HEADLESS, 1, &parm); Log(("Set VBoxSharedClipboard mode\n")); } } } /* * HGCM HostChannel */ { Bstr value; hrc = pMachine->GetExtraData(Bstr("HGCM/HostChannel").raw(), value.asOutParam()); if ( hrc == S_OK && value == "1") { rc = pVMMDev->hgcmLoadService("VBoxHostChannel", "VBoxHostChannel"); if (RT_FAILURE(rc)) { LogRel(("VBoxHostChannel is not available. rc = %Rrc\n", rc)); /* That is not a fatal failure. */ rc = VINF_SUCCESS; } } } #ifdef VBOX_WITH_DRAG_AND_DROP /* * Drag & Drop */ { DragAndDropMode_T mode = DragAndDropMode_Disabled; hrc = pMachine->COMGETTER(DragAndDropMode)(&mode); H(); /* Load the service */ rc = pVMMDev->hgcmLoadService("VBoxDragAndDropSvc", "VBoxDragAndDropSvc"); if (RT_FAILURE(rc)) { LogRel(("VBoxDragAndDropService is not available. rc = %Rrc\n", rc)); /* That is not a fatal failure. */ rc = VINF_SUCCESS; } else { HGCMSVCEXTHANDLE hDummy; rc = HGCMHostRegisterServiceExtension(&hDummy, "VBoxDragAndDropSvc", &GuestDnD::notifyGuestDragAndDropEvent, getGuest()); if (RT_FAILURE(rc)) Log(("Cannot register VBoxDragAndDropSvc extension!\n")); else { changeDragAndDropMode(mode); Log(("VBoxDragAndDropSvc loaded\n")); } } } #endif /* VBOX_WITH_DRAG_AND_DROP */ #ifdef VBOX_WITH_CROGL /* * crOpenGL */ { BOOL fEnabled3D = false; hrc = pMachine->COMGETTER(Accelerate3DEnabled)(&fEnabled3D); H(); if (fEnabled3D) { BOOL fSupports3D = VBoxOglIs3DAccelerationSupported(); if (!fSupports3D) return VMR3SetError(pUVM, VERR_NOT_AVAILABLE, RT_SRC_POS, N_("This VM was configured to use 3D acceleration. However, the " "3D support of the host is not working properly and the " "VM cannot be started. To fix this problem, either " "fix the host 3D support (update the host graphics driver?) " "or disable 3D acceleration in the VM settings")); /* Load the service */ rc = pVMMDev->hgcmLoadService("VBoxSharedCrOpenGL", "VBoxSharedCrOpenGL"); if (RT_FAILURE(rc)) { LogRel(("Failed to load Shared OpenGL service %Rrc\n", rc)); /* That is not a fatal failure. */ rc = VINF_SUCCESS; } else { LogRel(("Shared crOpenGL service loaded.\n")); /* Setup the service. */ VBOXHGCMSVCPARM parm; parm.type = VBOX_HGCM_SVC_PARM_PTR; parm.u.pointer.addr = (IConsole *)(Console *)this; parm.u.pointer.size = sizeof(IConsole *); rc = pVMMDev->hgcmHostCall("VBoxSharedCrOpenGL", SHCRGL_HOST_FN_SET_CONSOLE, SHCRGL_CPARMS_SET_CONSOLE, &parm); if (!RT_SUCCESS(rc)) AssertMsgFailed(("SHCRGL_HOST_FN_SET_CONSOLE failed with %Rrc\n", rc)); parm.u.pointer.addr = pVM; parm.u.pointer.size = sizeof(pVM); rc = pVMMDev->hgcmHostCall("VBoxSharedCrOpenGL", SHCRGL_HOST_FN_SET_VM, SHCRGL_CPARMS_SET_VM, &parm); if (!RT_SUCCESS(rc)) AssertMsgFailed(("SHCRGL_HOST_FN_SET_VM failed with %Rrc\n", rc)); } } } #endif #ifdef VBOX_WITH_GUEST_PROPS /* * Guest property service */ rc = configGuestProperties(this, pUVM); #endif /* VBOX_WITH_GUEST_PROPS defined */ #ifdef VBOX_WITH_GUEST_CONTROL /* * Guest control service */ rc = configGuestControl(this); #endif /* VBOX_WITH_GUEST_CONTROL defined */ /* * ACPI */ BOOL fACPI; hrc = biosSettings->COMGETTER(ACPIEnabled)(&fACPI); H(); if (fACPI) { BOOL fCpuHotPlug = false; BOOL fShowCpu = fOsXGuest; /* Always show the CPU leafs when we have multiple VCPUs or when the IO-APIC is enabled. * The Windows SMP kernel needs a CPU leaf or else its idle loop will burn cpu cycles; the * intelppm driver refuses to register an idle state handler. */ if ((cCpus > 1) || fIOAPIC) fShowCpu = true; hrc = pMachine->COMGETTER(CPUHotPlugEnabled)(&fCpuHotPlug); H(); InsertConfigNode(pDevices, "acpi", &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ InsertConfigNode(pInst, "Config", &pCfg); hrc = pBusMgr->assignPCIDevice("acpi", pInst); H(); InsertConfigInteger(pCfg, "RamSize", cbRam); InsertConfigInteger(pCfg, "RamHoleSize", cbRamHole); InsertConfigInteger(pCfg, "NumCPUs", cCpus); InsertConfigInteger(pCfg, "IOAPIC", fIOAPIC); InsertConfigInteger(pCfg, "FdcEnabled", fFdcEnabled); InsertConfigInteger(pCfg, "HpetEnabled", fHPETEnabled); InsertConfigInteger(pCfg, "SmcEnabled", fSmcEnabled); InsertConfigInteger(pCfg, "ShowRtc", fShowRtc); if (fOsXGuest && !llBootNics.empty()) { BootNic aNic = llBootNics.front(); uint32_t u32NicPCIAddr = (aNic.mPCIAddress.miDevice << 16) | aNic.mPCIAddress.miFn; InsertConfigInteger(pCfg, "NicPciAddress", u32NicPCIAddr); } if (fOsXGuest && fAudioEnabled) { PCIBusAddress Address; if (pBusMgr->findPCIAddress("hda", 0, Address)) { uint32_t u32AudioPCIAddr = (Address.miDevice << 16) | Address.miFn; InsertConfigInteger(pCfg, "AudioPciAddress", u32AudioPCIAddr); } } InsertConfigInteger(pCfg, "IocPciAddress", uIocPCIAddress); if (chipsetType == ChipsetType_ICH9) { InsertConfigInteger(pCfg, "McfgBase", uMcfgBase); InsertConfigInteger(pCfg, "McfgLength", cbMcfgLength); } InsertConfigInteger(pCfg, "HostBusPciAddress", uHbcPCIAddress); InsertConfigInteger(pCfg, "ShowCpu", fShowCpu); InsertConfigInteger(pCfg, "CpuHotPlug", fCpuHotPlug); InsertConfigInteger(pCfg, "Serial0IoPortBase", auSerialIoPortBase[0]); InsertConfigInteger(pCfg, "Serial0Irq", auSerialIrq[0]); InsertConfigInteger(pCfg, "Serial1IoPortBase", auSerialIoPortBase[1]); InsertConfigInteger(pCfg, "Serial1Irq", auSerialIrq[1]); InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "ACPIHost"); InsertConfigNode(pLunL0, "Config", &pCfg); /* Attach the dummy CPU drivers */ for (ULONG iCpuCurr = 1; iCpuCurr < cCpus; iCpuCurr++) { BOOL fCpuAttached = true; if (fCpuHotPlug) { hrc = pMachine->GetCPUStatus(iCpuCurr, &fCpuAttached); H(); } if (fCpuAttached) { InsertConfigNode(pInst, Utf8StrFmt("LUN#%u", iCpuCurr).c_str(), &pLunL0); InsertConfigString(pLunL0, "Driver", "ACPICpu"); InsertConfigNode(pLunL0, "Config", &pCfg); } } } /* * Configure DBGF (Debug(ger) Facility). */ { PCFGMNODE pDbgf; InsertConfigNode(pRoot, "DBGF", &pDbgf); /* Paths to search for debug info and such things. */ hrc = pMachine->COMGETTER(SettingsFilePath)(bstr.asOutParam()); H(); Utf8Str strSettingsPath(bstr); bstr.setNull(); strSettingsPath.stripFilename(); char szHomeDir[RTPATH_MAX]; rc = RTPathUserHome(szHomeDir, sizeof(szHomeDir)); if (RT_FAILURE(rc)) szHomeDir[0] = '\0'; Utf8Str strPath; strPath.append(strSettingsPath).append("/debug/;"); strPath.append(strSettingsPath).append("/;"); strPath.append(szHomeDir).append("/"); InsertConfigString(pDbgf, "Path", strPath.c_str()); /* Tracing configuration. */ BOOL fTracingEnabled; hrc = pMachine->COMGETTER(TracingEnabled)(&fTracingEnabled); H(); if (fTracingEnabled) InsertConfigInteger(pDbgf, "TracingEnabled", 1); hrc = pMachine->COMGETTER(TracingConfig)(bstr.asOutParam()); H(); if (fTracingEnabled) InsertConfigString(pDbgf, "TracingConfig", bstr); BOOL fAllowTracingToAccessVM; hrc = pMachine->COMGETTER(AllowTracingToAccessVM)(&fAllowTracingToAccessVM); H(); if (fAllowTracingToAccessVM) InsertConfigInteger(pPDM, "AllowTracingToAccessVM", 1); } } catch (ConfigError &x) { // InsertConfig threw something: return x.m_vrc; } #ifdef VBOX_WITH_EXTPACK /* * Call the extension pack hooks if everything went well thus far. */ if (RT_SUCCESS(rc)) { pAlock->release(); rc = mptrExtPackManager->callAllVmConfigureVmmHooks(this, pVM); pAlock->acquire(); } #endif /* * Apply the CFGM overlay. */ if (RT_SUCCESS(rc)) rc = configCfgmOverlay(pRoot, virtualBox, pMachine); /* * Dump all extradata API settings tweaks, both global and per VM. */ if (RT_SUCCESS(rc)) rc = configDumpAPISettingsTweaks(virtualBox, pMachine); #undef H pAlock->release(); /* Avoid triggering the lock order inversion check. */ /* * Register VM state change handler. */ int rc2 = VMR3AtStateRegister(pUVM, Console::vmstateChangeCallback, this); AssertRC(rc2); if (RT_SUCCESS(rc)) rc = rc2; /* * Register VM runtime error handler. */ rc2 = VMR3AtRuntimeErrorRegister(pUVM, Console::setVMRuntimeErrorCallback, this); AssertRC(rc2); if (RT_SUCCESS(rc)) rc = rc2; pAlock->acquire(); LogFlowFunc(("vrc = %Rrc\n", rc)); LogFlowFuncLeave(); return rc; } /** * Applies the CFGM overlay as specified by VBoxInternal/XXX extra data * values. * * @returns VBox status code. * @param pRoot The root of the configuration tree. * @param pVirtualBox Pointer to the IVirtualBox interface. * @param pMachine Pointer to the IMachine interface. */ /* static */ int Console::configCfgmOverlay(PCFGMNODE pRoot, IVirtualBox *pVirtualBox, IMachine *pMachine) { /* * CFGM overlay handling. * * Here we check the extra data entries for CFGM values * and create the nodes and insert the values on the fly. Existing * values will be removed and reinserted. CFGM is typed, so by default * we will guess whether it's a string or an integer (byte arrays are * not currently supported). It's possible to override this autodetection * by adding "string:", "integer:" or "bytes:" (future). * * We first perform a run on global extra data, then on the machine * extra data to support global settings with local overrides. */ int rc = VINF_SUCCESS; try { /** @todo add support for removing nodes and byte blobs. */ /* * Get the next key */ SafeArray aGlobalExtraDataKeys; SafeArray aMachineExtraDataKeys; HRESULT hrc = pVirtualBox->GetExtraDataKeys(ComSafeArrayAsOutParam(aGlobalExtraDataKeys)); AssertMsg(SUCCEEDED(hrc), ("VirtualBox::GetExtraDataKeys failed with %Rhrc\n", hrc)); // remember the no. of global values so we can call the correct method below size_t cGlobalValues = aGlobalExtraDataKeys.size(); hrc = pMachine->GetExtraDataKeys(ComSafeArrayAsOutParam(aMachineExtraDataKeys)); AssertMsg(SUCCEEDED(hrc), ("Machine::GetExtraDataKeys failed with %Rhrc\n", hrc)); // build a combined list from global keys... std::list llExtraDataKeys; for (size_t i = 0; i < aGlobalExtraDataKeys.size(); ++i) llExtraDataKeys.push_back(Utf8Str(aGlobalExtraDataKeys[i])); // ... and machine keys for (size_t i = 0; i < aMachineExtraDataKeys.size(); ++i) llExtraDataKeys.push_back(Utf8Str(aMachineExtraDataKeys[i])); size_t i2 = 0; for (std::list::const_iterator it = llExtraDataKeys.begin(); it != llExtraDataKeys.end(); ++it, ++i2) { const Utf8Str &strKey = *it; /* * We only care about keys starting with "VBoxInternal/" (skip "G:" or "M:") */ if (!strKey.startsWith("VBoxInternal/")) continue; const char *pszExtraDataKey = strKey.c_str() + sizeof("VBoxInternal/") - 1; // get the value Bstr bstrExtraDataValue; if (i2 < cGlobalValues) // this is still one of the global values: hrc = pVirtualBox->GetExtraData(Bstr(strKey).raw(), bstrExtraDataValue.asOutParam()); else hrc = pMachine->GetExtraData(Bstr(strKey).raw(), bstrExtraDataValue.asOutParam()); if (FAILED(hrc)) LogRel(("Warning: Cannot get extra data key %s, rc = %Rhrc\n", strKey.c_str(), hrc)); /* * The key will be in the format "Node1/Node2/Value" or simply "Value". * Split the two and get the node, delete the value and create the node * if necessary. */ PCFGMNODE pNode; const char *pszCFGMValueName = strrchr(pszExtraDataKey, '/'); if (pszCFGMValueName) { /* terminate the node and advance to the value (Utf8Str might not offically like this but wtf) */ *(char*)pszCFGMValueName = '\0'; ++pszCFGMValueName; /* does the node already exist? */ pNode = CFGMR3GetChild(pRoot, pszExtraDataKey); if (pNode) CFGMR3RemoveValue(pNode, pszCFGMValueName); else { /* create the node */ rc = CFGMR3InsertNode(pRoot, pszExtraDataKey, &pNode); if (RT_FAILURE(rc)) { AssertLogRelMsgRC(rc, ("failed to insert node '%s'\n", pszExtraDataKey)); continue; } Assert(pNode); } } else { /* root value (no node path). */ pNode = pRoot; pszCFGMValueName = pszExtraDataKey; pszExtraDataKey--; CFGMR3RemoveValue(pNode, pszCFGMValueName); } /* * Now let's have a look at the value. * Empty strings means that we should remove the value, which we've * already done above. */ Utf8Str strCFGMValueUtf8(bstrExtraDataValue); if (!strCFGMValueUtf8.isEmpty()) { uint64_t u64Value; /* check for type prefix first. */ if (!strncmp(strCFGMValueUtf8.c_str(), RT_STR_TUPLE("string:"))) InsertConfigString(pNode, pszCFGMValueName, strCFGMValueUtf8.c_str() + sizeof("string:") - 1); else if (!strncmp(strCFGMValueUtf8.c_str(), RT_STR_TUPLE("integer:"))) { rc = RTStrToUInt64Full(strCFGMValueUtf8.c_str() + sizeof("integer:") - 1, 0, &u64Value); if (RT_SUCCESS(rc)) rc = CFGMR3InsertInteger(pNode, pszCFGMValueName, u64Value); } else if (!strncmp(strCFGMValueUtf8.c_str(), RT_STR_TUPLE("bytes:"))) { char const *pszBase64 = strCFGMValueUtf8.c_str() + sizeof("bytes:") - 1; ssize_t cbValue = RTBase64DecodedSize(pszBase64, NULL); if (cbValue > 0) { void *pvBytes = RTMemTmpAlloc(cbValue); if (pvBytes) { rc = RTBase64Decode(pszBase64, pvBytes, cbValue, NULL, NULL); if (RT_SUCCESS(rc)) rc = CFGMR3InsertBytes(pNode, pszCFGMValueName, pvBytes, cbValue); RTMemTmpFree(pvBytes); } else rc = VERR_NO_TMP_MEMORY; } else if (cbValue == 0) rc = CFGMR3InsertBytes(pNode, pszCFGMValueName, NULL, 0); else rc = VERR_INVALID_BASE64_ENCODING; } /* auto detect type. */ else if (RT_SUCCESS(RTStrToUInt64Full(strCFGMValueUtf8.c_str(), 0, &u64Value))) rc = CFGMR3InsertInteger(pNode, pszCFGMValueName, u64Value); else InsertConfigString(pNode, pszCFGMValueName, strCFGMValueUtf8); AssertLogRelMsgRCBreak(rc, ("failed to insert CFGM value '%s' to key '%s'\n", strCFGMValueUtf8.c_str(), pszExtraDataKey)); } } } catch (ConfigError &x) { // InsertConfig threw something: return x.m_vrc; } return rc; } /** * Dumps the API settings tweaks as specified by VBoxInternal2/XXX extra data * values. * * @returns VBox status code. * @param pVirtualBox Pointer to the IVirtualBox interface. * @param pMachine Pointer to the IMachine interface. */ /* static */ int Console::configDumpAPISettingsTweaks(IVirtualBox *pVirtualBox, IMachine *pMachine) { { SafeArray aGlobalExtraDataKeys; HRESULT hrc = pVirtualBox->GetExtraDataKeys(ComSafeArrayAsOutParam(aGlobalExtraDataKeys)); AssertMsg(SUCCEEDED(hrc), ("VirtualBox::GetExtraDataKeys failed with %Rhrc\n", hrc)); bool hasKey = false; for (size_t i = 0; i < aGlobalExtraDataKeys.size(); i++) { Utf8Str strKey(aGlobalExtraDataKeys[i]); if (!strKey.startsWith("VBoxInternal2/")) continue; Bstr bstrValue; hrc = pVirtualBox->GetExtraData(Bstr(strKey).raw(), bstrValue.asOutParam()); if (FAILED(hrc)) continue; if (!hasKey) LogRel(("Global extradata API settings:\n")); LogRel((" %s=\"%ls\"\n", strKey.c_str(), bstrValue.raw())); hasKey = true; } } { SafeArray aMachineExtraDataKeys; HRESULT hrc = pMachine->GetExtraDataKeys(ComSafeArrayAsOutParam(aMachineExtraDataKeys)); AssertMsg(SUCCEEDED(hrc), ("Machine::GetExtraDataKeys failed with %Rhrc\n", hrc)); bool hasKey = false; for (size_t i = 0; i < aMachineExtraDataKeys.size(); i++) { Utf8Str strKey(aMachineExtraDataKeys[i]); if (!strKey.startsWith("VBoxInternal2/")) continue; Bstr bstrValue; hrc = pMachine->GetExtraData(Bstr(strKey).raw(), bstrValue.asOutParam()); if (FAILED(hrc)) continue; if (!hasKey) LogRel(("Per-VM extradata API settings:\n")); LogRel((" %s=\"%ls\"\n", strKey.c_str(), bstrValue.raw())); hasKey = true; } } return VINF_SUCCESS; } int Console::configGraphicsController(PCFGMNODE pDevices, const char *pcszDevice, BusAssignmentManager *pBusMgr, const ComPtr &pMachine, const ComPtr &biosSettings, bool fHMEnabled) { // InsertConfig* throws try { PCFGMNODE pDev, pInst, pCfg, pLunL0; HRESULT hrc; Bstr bstr; #define H() AssertMsgReturn(!FAILED(hrc), ("hrc=%Rhrc\n", hrc), VERR_GENERAL_FAILURE) InsertConfigNode(pDevices, pcszDevice, &pDev); InsertConfigNode(pDev, "0", &pInst); InsertConfigInteger(pInst, "Trusted", 1); /* boolean */ hrc = pBusMgr->assignPCIDevice(pcszDevice, pInst); H(); InsertConfigNode(pInst, "Config", &pCfg); ULONG cVRamMBs; hrc = pMachine->COMGETTER(VRAMSize)(&cVRamMBs); H(); InsertConfigInteger(pCfg, "VRamSize", cVRamMBs * _1M); ULONG cMonitorCount; hrc = pMachine->COMGETTER(MonitorCount)(&cMonitorCount); H(); InsertConfigInteger(pCfg, "MonitorCount", cMonitorCount); #ifdef VBOX_WITH_2X_4GB_ADDR_SPACE InsertConfigInteger(pCfg, "R0Enabled", fHMEnabled); #else NOREF(fHMEnabled); #endif /* Custom VESA mode list */ unsigned cModes = 0; for (unsigned iMode = 1; iMode <= 16; ++iMode) { char szExtraDataKey[sizeof("CustomVideoModeXX")]; RTStrPrintf(szExtraDataKey, sizeof(szExtraDataKey), "CustomVideoMode%u", iMode); hrc = pMachine->GetExtraData(Bstr(szExtraDataKey).raw(), bstr.asOutParam()); H(); if (bstr.isEmpty()) break; InsertConfigString(pCfg, szExtraDataKey, bstr); ++cModes; } InsertConfigInteger(pCfg, "CustomVideoModes", cModes); /* VESA height reduction */ ULONG ulHeightReduction; IFramebuffer *pFramebuffer = getDisplay()->getFramebuffer(); if (pFramebuffer) { hrc = pFramebuffer->COMGETTER(HeightReduction)(&ulHeightReduction); H(); } else { /* If framebuffer is not available, there is no height reduction. */ ulHeightReduction = 0; } InsertConfigInteger(pCfg, "HeightReduction", ulHeightReduction); /* * BIOS logo */ BOOL fFadeIn; hrc = biosSettings->COMGETTER(LogoFadeIn)(&fFadeIn); H(); InsertConfigInteger(pCfg, "FadeIn", fFadeIn ? 1 : 0); BOOL fFadeOut; hrc = biosSettings->COMGETTER(LogoFadeOut)(&fFadeOut); H(); InsertConfigInteger(pCfg, "FadeOut", fFadeOut ? 1: 0); ULONG logoDisplayTime; hrc = biosSettings->COMGETTER(LogoDisplayTime)(&logoDisplayTime); H(); InsertConfigInteger(pCfg, "LogoTime", logoDisplayTime); Bstr logoImagePath; hrc = biosSettings->COMGETTER(LogoImagePath)(logoImagePath.asOutParam()); H(); InsertConfigString(pCfg, "LogoFile", Utf8Str(!logoImagePath.isEmpty() ? logoImagePath : "") ); /* * Boot menu */ BIOSBootMenuMode_T eBootMenuMode; int iShowBootMenu; biosSettings->COMGETTER(BootMenuMode)(&eBootMenuMode); switch (eBootMenuMode) { case BIOSBootMenuMode_Disabled: iShowBootMenu = 0; break; case BIOSBootMenuMode_MenuOnly: iShowBootMenu = 1; break; default: iShowBootMenu = 2; break; } InsertConfigInteger(pCfg, "ShowBootMenu", iShowBootMenu); /* Attach the display. */ InsertConfigNode(pInst, "LUN#0", &pLunL0); InsertConfigString(pLunL0, "Driver", "MainDisplay"); InsertConfigNode(pLunL0, "Config", &pCfg); Display *pDisplay = mDisplay; InsertConfigInteger(pCfg, "Object", (uintptr_t)pDisplay); } catch (ConfigError &x) { // InsertConfig threw something: return x.m_vrc; } #undef H return VINF_SUCCESS; } /** * Ellipsis to va_list wrapper for calling setVMRuntimeErrorCallback. */ void Console::setVMRuntimeErrorCallbackF(uint32_t fFlags, const char *pszErrorId, const char *pszFormat, ...) { va_list va; va_start(va, pszFormat); setVMRuntimeErrorCallback(NULL, this, fFlags, pszErrorId, pszFormat, va); va_end(va); } /* XXX introduce RT format specifier */ static uint64_t formatDiskSize(uint64_t u64Size, const char **pszUnit) { if (u64Size > INT64_C(5000)*_1G) { *pszUnit = "TB"; return u64Size / _1T; } else if (u64Size > INT64_C(5000)*_1M) { *pszUnit = "GB"; return u64Size / _1G; } else { *pszUnit = "MB"; return u64Size / _1M; } } int Console::configMediumAttachment(PCFGMNODE pCtlInst, const char *pcszDevice, unsigned uInstance, StorageBus_T enmBus, bool fUseHostIOCache, bool fBuiltinIOCache, bool fSetupMerge, unsigned uMergeSource, unsigned uMergeTarget, IMediumAttachment *pMediumAtt, MachineState_T aMachineState, HRESULT *phrc, bool fAttachDetach, bool fForceUnmount, bool fHotplug, PUVM pUVM, DeviceType_T *paLedDevType) { // InsertConfig* throws try { int rc = VINF_SUCCESS; HRESULT hrc; Bstr bstr; // #define RC_CHECK() AssertMsgReturn(RT_SUCCESS(rc), ("rc=%Rrc\n", rc), rc) #define H() AssertMsgReturn(!FAILED(hrc), ("hrc=%Rhrc\n", hrc), VERR_GENERAL_FAILURE) LONG lDev; hrc = pMediumAtt->COMGETTER(Device)(&lDev); H(); LONG lPort; hrc = pMediumAtt->COMGETTER(Port)(&lPort); H(); DeviceType_T lType; hrc = pMediumAtt->COMGETTER(Type)(&lType); H(); BOOL fNonRotational; hrc = pMediumAtt->COMGETTER(NonRotational)(&fNonRotational); H(); BOOL fDiscard; hrc = pMediumAtt->COMGETTER(Discard)(&fDiscard); H(); unsigned uLUN; PCFGMNODE pLunL0 = NULL; hrc = Console::convertBusPortDeviceToLun(enmBus, lPort, lDev, uLUN); H(); /* First check if the LUN already exists. */ pLunL0 = CFGMR3GetChildF(pCtlInst, "LUN#%u", uLUN); if (pLunL0) { if (fAttachDetach) { if (lType != DeviceType_HardDisk) { /* Unmount existing media only for floppy and DVD drives. */ PPDMIBASE pBase; rc = PDMR3QueryLun(pUVM, pcszDevice, uInstance, uLUN, &pBase); if (RT_FAILURE(rc)) { if (rc == VERR_PDM_LUN_NOT_FOUND || rc == VERR_PDM_NO_DRIVER_ATTACHED_TO_LUN) rc = VINF_SUCCESS; AssertRC(rc); } else { PPDMIMOUNT pIMount = PDMIBASE_QUERY_INTERFACE(pBase, PDMIMOUNT); AssertReturn(pIMount, VERR_INVALID_POINTER); /* Unmount the media (but do not eject the medium!) */ rc = pIMount->pfnUnmount(pIMount, fForceUnmount, false /*=fEject*/); if (rc == VERR_PDM_MEDIA_NOT_MOUNTED) rc = VINF_SUCCESS; /* for example if the medium is locked */ else if (RT_FAILURE(rc)) return rc; } } rc = PDMR3DeviceDetach(pUVM, pcszDevice, uInstance, uLUN, fHotplug ? 0 : PDM_TACH_FLAGS_NOT_HOT_PLUG); if (rc == VERR_PDM_NO_DRIVER_ATTACHED_TO_LUN) rc = VINF_SUCCESS; AssertRCReturn(rc, rc); CFGMR3RemoveNode(pLunL0); } else AssertFailedReturn(VERR_INTERNAL_ERROR); } InsertConfigNode(pCtlInst, Utf8StrFmt("LUN#%u", uLUN).c_str(), &pLunL0); PCFGMNODE pCfg = CFGMR3GetChild(pCtlInst, "Config"); if (pCfg) { if (!strcmp(pcszDevice, "piix3ide")) { PCFGMNODE pDrive = CFGMR3GetChild(pCfg, g_apszIDEDrives[uLUN]); if (!pDrive) InsertConfigNode(pCfg, g_apszIDEDrives[uLUN], &pDrive); /* Don't use the RemoveConfigValue wrapper above, as we don't * know if the leaf is present or not. */ CFGMR3RemoveValue(pDrive, "NonRotationalMedium"); InsertConfigInteger(pDrive, "NonRotationalMedium", !!fNonRotational); } else if (!strcmp(pcszDevice, "ahci")) { Utf8Str strPort = Utf8StrFmt("Port%u", uLUN); PCFGMNODE pDrive = CFGMR3GetChild(pCfg, strPort.c_str()); if (!pDrive) InsertConfigNode(pCfg, strPort.c_str(), &pDrive); /* Don't use the RemoveConfigValue wrapper above, as we don't * know if the leaf is present or not. */ CFGMR3RemoveValue(pDrive, "NonRotationalMedium"); InsertConfigInteger(pDrive, "NonRotationalMedium", !!fNonRotational); } } Utf8Str devicePath = Utf8StrFmt("%s/%u/LUN#%u", pcszDevice, uInstance, uLUN); mapMediumAttachments[devicePath] = pMediumAtt; /* SCSI has a another driver between device and block. */ if (enmBus == StorageBus_SCSI || enmBus == StorageBus_SAS) { InsertConfigString(pLunL0, "Driver", "SCSI"); PCFGMNODE pL1Cfg = NULL; InsertConfigNode(pLunL0, "Config", &pL1Cfg); InsertConfigInteger(pL1Cfg, "NonRotationalMedium", !!fNonRotational); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL0); } ComPtr pMedium; hrc = pMediumAtt->COMGETTER(Medium)(pMedium.asOutParam()); H(); /* * 1. Only check this for hard disk images. * 2. Only check during VM creation and not later, especially not during * taking an online snapshot! */ if ( lType == DeviceType_HardDisk && ( aMachineState == MachineState_Starting || aMachineState == MachineState_Restoring)) { /* * Some sanity checks. */ ComPtr pMediumFormat; hrc = pMedium->COMGETTER(MediumFormat)(pMediumFormat.asOutParam()); H(); ULONG uCaps = 0; com::SafeArray mediumFormatCap; hrc = pMediumFormat->COMGETTER(Capabilities)(ComSafeArrayAsOutParam(mediumFormatCap)); H(); for (ULONG j = 0; j < mediumFormatCap.size(); j++) uCaps |= mediumFormatCap[j]; if (uCaps & MediumFormatCapabilities_File) { Bstr strFile; hrc = pMedium->COMGETTER(Location)(strFile.asOutParam()); H(); Utf8Str utfFile = Utf8Str(strFile); Bstr strSnap; ComPtr pMachine = machine(); hrc = pMachine->COMGETTER(SnapshotFolder)(strSnap.asOutParam()); H(); Utf8Str utfSnap = Utf8Str(strSnap); RTFSTYPE enmFsTypeFile = RTFSTYPE_UNKNOWN; RTFSTYPE enmFsTypeSnap = RTFSTYPE_UNKNOWN; int rc2 = RTFsQueryType(utfFile.c_str(), &enmFsTypeFile); AssertMsgRCReturn(rc2, ("Querying the file type of '%s' failed!\n", utfFile.c_str()), rc2); /* Ignore the error code. On error, the file system type is still 'unknown' so * none of the following paths are taken. This can happen for new VMs which * still don't have a snapshot folder. */ (void)RTFsQueryType(utfSnap.c_str(), &enmFsTypeSnap); if (!mfSnapshotFolderDiskTypeShown) { LogRel(("File system of '%s' (snapshots) is %s\n", utfSnap.c_str(), RTFsTypeName(enmFsTypeSnap))); mfSnapshotFolderDiskTypeShown = true; } LogRel(("File system of '%s' is %s\n", utfFile.c_str(), RTFsTypeName(enmFsTypeFile))); LONG64 i64Size; hrc = pMedium->COMGETTER(LogicalSize)(&i64Size); H(); #ifdef RT_OS_WINDOWS if ( enmFsTypeFile == RTFSTYPE_FAT && i64Size >= _4G) { const char *pszUnit; uint64_t u64Print = formatDiskSize((uint64_t)i64Size, &pszUnit); setVMRuntimeErrorCallbackF(0, "FatPartitionDetected", N_("The medium '%ls' has a logical size of %RU64%s " "but the file system the medium is located on seems " "to be FAT(32) which cannot handle files bigger than 4GB.\n" "We strongly recommend to put all your virtual disk images and " "the snapshot folder onto an NTFS partition"), strFile.raw(), u64Print, pszUnit); } #else /* !RT_OS_WINDOWS */ if ( enmFsTypeFile == RTFSTYPE_FAT || enmFsTypeFile == RTFSTYPE_EXT || enmFsTypeFile == RTFSTYPE_EXT2 || enmFsTypeFile == RTFSTYPE_EXT3 || enmFsTypeFile == RTFSTYPE_EXT4) { RTFILE file; rc = RTFileOpen(&file, utfFile.c_str(), RTFILE_O_READ | RTFILE_O_OPEN | RTFILE_O_DENY_NONE); if (RT_SUCCESS(rc)) { RTFOFF maxSize; /* Careful: This function will work only on selected local file systems! */ rc = RTFileGetMaxSizeEx(file, &maxSize); RTFileClose(file); if ( RT_SUCCESS(rc) && maxSize > 0 && i64Size > (LONG64)maxSize) { const char *pszUnitSiz; const char *pszUnitMax; uint64_t u64PrintSiz = formatDiskSize((LONG64)i64Size, &pszUnitSiz); uint64_t u64PrintMax = formatDiskSize(maxSize, &pszUnitMax); setVMRuntimeErrorCallbackF(0, "FatPartitionDetected", /* <= not exact but ... */ N_("The medium '%ls' has a logical size of %RU64%s " "but the file system the medium is located on can " "only handle files up to %RU64%s in theory.\n" "We strongly recommend to put all your virtual disk " "images and the snapshot folder onto a proper " "file system (e.g. ext3) with a sufficient size"), strFile.raw(), u64PrintSiz, pszUnitSiz, u64PrintMax, pszUnitMax); } } } #endif /* !RT_OS_WINDOWS */ /* * Snapshot folder: * Here we test only for a FAT partition as we had to create a dummy file otherwise */ if ( enmFsTypeSnap == RTFSTYPE_FAT && i64Size >= _4G && !mfSnapshotFolderSizeWarningShown) { const char *pszUnit; uint64_t u64Print = formatDiskSize(i64Size, &pszUnit); setVMRuntimeErrorCallbackF(0, "FatPartitionDetected", #ifdef RT_OS_WINDOWS N_("The snapshot folder of this VM '%ls' seems to be located on " "a FAT(32) file system. The logical size of the medium '%ls' " "(%RU64%s) is bigger than the maximum file size this file " "system can handle (4GB).\n" "We strongly recommend to put all your virtual disk images and " "the snapshot folder onto an NTFS partition"), #else N_("The snapshot folder of this VM '%ls' seems to be located on " "a FAT(32) file system. The logical size of the medium '%ls' " "(%RU64%s) is bigger than the maximum file size this file " "system can handle (4GB).\n" "We strongly recommend to put all your virtual disk images and " "the snapshot folder onto a proper file system (e.g. ext3)"), #endif strSnap.raw(), strFile.raw(), u64Print, pszUnit); /* Show this particular warning only once */ mfSnapshotFolderSizeWarningShown = true; } #ifdef RT_OS_LINUX /* * Ext4 bug: Check if the host I/O cache is disabled and the disk image is located * on an ext4 partition. Later we have to check the Linux kernel version! * This bug apparently applies to the XFS file system as well. * Linux 2.6.36 is known to be fixed (tested with 2.6.36-rc4). */ char szOsRelease[128]; rc = RTSystemQueryOSInfo(RTSYSOSINFO_RELEASE, szOsRelease, sizeof(szOsRelease)); bool fKernelHasODirectBug = RT_FAILURE(rc) || (RTStrVersionCompare(szOsRelease, "2.6.36-rc4") < 0); if ( (uCaps & MediumFormatCapabilities_Asynchronous) && !fUseHostIOCache && fKernelHasODirectBug) { if ( enmFsTypeFile == RTFSTYPE_EXT4 || enmFsTypeFile == RTFSTYPE_XFS) { setVMRuntimeErrorCallbackF(0, "Ext4PartitionDetected", N_("The host I/O cache for at least one controller is disabled " "and the medium '%ls' for this VM " "is located on an %s partition. There is a known Linux " "kernel bug which can lead to the corruption of the virtual " "disk image under these conditions.\n" "Either enable the host I/O cache permanently in the VM " "settings or put the disk image and the snapshot folder " "onto a different file system.\n" "The host I/O cache will now be enabled for this medium"), strFile.raw(), enmFsTypeFile == RTFSTYPE_EXT4 ? "ext4" : "xfs"); fUseHostIOCache = true; } else if ( ( enmFsTypeSnap == RTFSTYPE_EXT4 || enmFsTypeSnap == RTFSTYPE_XFS) && !mfSnapshotFolderExt4WarningShown) { setVMRuntimeErrorCallbackF(0, "Ext4PartitionDetected", N_("The host I/O cache for at least one controller is disabled " "and the snapshot folder for this VM " "is located on an %s partition. There is a known Linux " "kernel bug which can lead to the corruption of the virtual " "disk image under these conditions.\n" "Either enable the host I/O cache permanently in the VM " "settings or put the disk image and the snapshot folder " "onto a different file system.\n" "The host I/O cache will now be enabled for this medium"), enmFsTypeSnap == RTFSTYPE_EXT4 ? "ext4" : "xfs"); fUseHostIOCache = true; mfSnapshotFolderExt4WarningShown = true; } } #endif } } if (pMedium) { BOOL fHostDrive; hrc = pMedium->COMGETTER(HostDrive)(&fHostDrive); H(); if ( ( lType == DeviceType_DVD || lType == DeviceType_Floppy) && !fHostDrive) { /* * Informative logging. */ Bstr strFile; hrc = pMedium->COMGETTER(Location)(strFile.asOutParam()); H(); Utf8Str utfFile = Utf8Str(strFile); RTFSTYPE enmFsTypeFile = RTFSTYPE_UNKNOWN; (void)RTFsQueryType(utfFile.c_str(), &enmFsTypeFile); LogRel(("File system of '%s' (%s) is %s\n", utfFile.c_str(), lType == DeviceType_DVD ? "DVD" : "Floppy", RTFsTypeName(enmFsTypeFile))); } } BOOL fPassthrough; hrc = pMediumAtt->COMGETTER(Passthrough)(&fPassthrough); H(); ComObjPtr pBwGroup; Bstr strBwGroup; hrc = pMediumAtt->COMGETTER(BandwidthGroup)(pBwGroup.asOutParam()); H(); if (!pBwGroup.isNull()) { hrc = pBwGroup->COMGETTER(Name)(strBwGroup.asOutParam()); H(); } rc = configMedium(pLunL0, !!fPassthrough, lType, fUseHostIOCache, fBuiltinIOCache, fSetupMerge, uMergeSource, uMergeTarget, strBwGroup.isEmpty() ? NULL : Utf8Str(strBwGroup).c_str(), !!fDiscard, pMedium, aMachineState, phrc); if (RT_FAILURE(rc)) return rc; if (fAttachDetach) { /* Attach the new driver. */ rc = PDMR3DeviceAttach(pUVM, pcszDevice, uInstance, uLUN, fHotplug ? 0 : PDM_TACH_FLAGS_NOT_HOT_PLUG, NULL /*ppBase*/); AssertRCReturn(rc, rc); /* There is no need to handle removable medium mounting, as we * unconditionally replace everthing including the block driver level. * This means the new medium will be picked up automatically. */ } if (paLedDevType) paLedDevType[uLUN] = lType; } catch (ConfigError &x) { // InsertConfig threw something: return x.m_vrc; } #undef H return VINF_SUCCESS; } int Console::configMedium(PCFGMNODE pLunL0, bool fPassthrough, DeviceType_T enmType, bool fUseHostIOCache, bool fBuiltinIOCache, bool fSetupMerge, unsigned uMergeSource, unsigned uMergeTarget, const char *pcszBwGroup, bool fDiscard, IMedium *pMedium, MachineState_T aMachineState, HRESULT *phrc) { // InsertConfig* throws try { int rc = VINF_SUCCESS; HRESULT hrc; Bstr bstr; PCFGMNODE pLunL1 = NULL; PCFGMNODE pCfg = NULL; #define H() \ AssertMsgReturnStmt(SUCCEEDED(hrc), ("hrc=%Rhrc\n", hrc), if (phrc) *phrc = hrc, Global::vboxStatusCodeFromCOM(hrc)) BOOL fHostDrive = FALSE; MediumType_T mediumType = MediumType_Normal; if (pMedium) { hrc = pMedium->COMGETTER(HostDrive)(&fHostDrive); H(); hrc = pMedium->COMGETTER(Type)(&mediumType); H(); } if (fHostDrive) { Assert(pMedium); if (enmType == DeviceType_DVD) { InsertConfigString(pLunL0, "Driver", "HostDVD"); InsertConfigNode(pLunL0, "Config", &pCfg); hrc = pMedium->COMGETTER(Location)(bstr.asOutParam()); H(); InsertConfigString(pCfg, "Path", bstr); InsertConfigInteger(pCfg, "Passthrough", fPassthrough); } else if (enmType == DeviceType_Floppy) { InsertConfigString(pLunL0, "Driver", "HostFloppy"); InsertConfigNode(pLunL0, "Config", &pCfg); hrc = pMedium->COMGETTER(Location)(bstr.asOutParam()); H(); InsertConfigString(pCfg, "Path", bstr); } } else { InsertConfigString(pLunL0, "Driver", "Block"); InsertConfigNode(pLunL0, "Config", &pCfg); switch (enmType) { case DeviceType_DVD: InsertConfigString(pCfg, "Type", "DVD"); InsertConfigInteger(pCfg, "Mountable", 1); break; case DeviceType_Floppy: InsertConfigString(pCfg, "Type", "Floppy 1.44"); InsertConfigInteger(pCfg, "Mountable", 1); break; case DeviceType_HardDisk: default: InsertConfigString(pCfg, "Type", "HardDisk"); InsertConfigInteger(pCfg, "Mountable", 0); } if ( pMedium && ( enmType == DeviceType_DVD || enmType == DeviceType_Floppy) ) { // if this medium represents an ISO image and this image is inaccessible, // the ignore it instead of causing a failure; this can happen when we // restore a VM state and the ISO has disappeared, e.g. because the Guest // Additions were mounted and the user upgraded VirtualBox. Previously // we failed on startup, but that's not good because the only way out then // would be to discard the VM state... MediumState_T mediumState; hrc = pMedium->RefreshState(&mediumState); H(); if (mediumState == MediumState_Inaccessible) { Bstr loc; hrc = pMedium->COMGETTER(Location)(loc.asOutParam()); H(); setVMRuntimeErrorCallbackF(0, "DvdOrFloppyImageInaccessible", "The image file '%ls' is inaccessible and is being ignored. Please select a different image file for the virtual %s drive.", loc.raw(), enmType == DeviceType_DVD ? "DVD" : "floppy"); pMedium = NULL; } } if (pMedium) { /* Start with length of parent chain, as the list is reversed */ unsigned uImage = 0; IMedium *pTmp = pMedium; while (pTmp) { uImage++; hrc = pTmp->COMGETTER(Parent)(&pTmp); H(); } /* Index of last image */ uImage--; #if 0 /* Enable for I/O debugging */ InsertConfigNode(pLunL0, "AttachedDriver", &pLunL0); InsertConfigString(pLunL0, "Driver", "DiskIntegrity"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "CheckConsistency", 0); InsertConfigInteger(pCfg, "CheckDoubleCompletions", 1); #endif InsertConfigNode(pLunL0, "AttachedDriver", &pLunL1); InsertConfigString(pLunL1, "Driver", "VD"); InsertConfigNode(pLunL1, "Config", &pCfg); hrc = pMedium->COMGETTER(Location)(bstr.asOutParam()); H(); InsertConfigString(pCfg, "Path", bstr); hrc = pMedium->COMGETTER(Format)(bstr.asOutParam()); H(); InsertConfigString(pCfg, "Format", bstr); if (mediumType == MediumType_Readonly) InsertConfigInteger(pCfg, "ReadOnly", 1); else if (enmType == DeviceType_Floppy) InsertConfigInteger(pCfg, "MaybeReadOnly", 1); /* Start without exclusive write access to the images. */ /** @todo Live Migration: I don't quite like this, we risk screwing up when * we're resuming the VM if some 3rd dude have any of the VDIs open * with write sharing denied. However, if the two VMs are sharing a * image it really is necessary.... * * So, on the "lock-media" command, the target teleporter should also * make DrvVD undo TempReadOnly. It gets interesting if we fail after * that. Grumble. */ if ( enmType == DeviceType_HardDisk && ( aMachineState == MachineState_TeleportingIn || aMachineState == MachineState_FaultTolerantSyncing)) InsertConfigInteger(pCfg, "TempReadOnly", 1); /* Flag for opening the medium for sharing between VMs. This * is done at the moment only for the first (and only) medium * in the chain, as shared media can have no diffs. */ if (mediumType == MediumType_Shareable) InsertConfigInteger(pCfg, "Shareable", 1); if (!fUseHostIOCache) { InsertConfigInteger(pCfg, "UseNewIo", 1); /* * Activate the builtin I/O cache for harddisks only. * It caches writes only which doesn't make sense for DVD drives * and just increases the overhead. */ if ( fBuiltinIOCache && (enmType == DeviceType_HardDisk)) InsertConfigInteger(pCfg, "BlockCache", 1); } if (fSetupMerge) { InsertConfigInteger(pCfg, "SetupMerge", 1); if (uImage == uMergeSource) InsertConfigInteger(pCfg, "MergeSource", 1); else if (uImage == uMergeTarget) InsertConfigInteger(pCfg, "MergeTarget", 1); } switch (enmType) { case DeviceType_DVD: InsertConfigString(pCfg, "Type", "DVD"); break; case DeviceType_Floppy: InsertConfigString(pCfg, "Type", "Floppy"); break; case DeviceType_HardDisk: default: InsertConfigString(pCfg, "Type", "HardDisk"); } if (pcszBwGroup) InsertConfigString(pCfg, "BwGroup", pcszBwGroup); if (fDiscard) InsertConfigInteger(pCfg, "Discard", 1); /* Pass all custom parameters. */ bool fHostIP = true; SafeArray names; SafeArray values; hrc = pMedium->GetProperties(Bstr().raw(), ComSafeArrayAsOutParam(names), ComSafeArrayAsOutParam(values)); H(); if (names.size() != 0) { PCFGMNODE pVDC; InsertConfigNode(pCfg, "VDConfig", &pVDC); for (size_t ii = 0; ii < names.size(); ++ii) { if (values[ii] && *values[ii]) { Utf8Str name = names[ii]; Utf8Str value = values[ii]; InsertConfigString(pVDC, name.c_str(), value); if ( name.compare("HostIPStack") == 0 && value.compare("0") == 0) fHostIP = false; } } } /* Create an inverted list of parents. */ uImage--; IMedium *pParentMedium = pMedium; for (PCFGMNODE pParent = pCfg;; uImage--) { hrc = pParentMedium->COMGETTER(Parent)(&pMedium); H(); if (!pMedium) break; PCFGMNODE pCur; InsertConfigNode(pParent, "Parent", &pCur); hrc = pMedium->COMGETTER(Location)(bstr.asOutParam()); H(); InsertConfigString(pCur, "Path", bstr); hrc = pMedium->COMGETTER(Format)(bstr.asOutParam()); H(); InsertConfigString(pCur, "Format", bstr); if (fSetupMerge) { if (uImage == uMergeSource) InsertConfigInteger(pCur, "MergeSource", 1); else if (uImage == uMergeTarget) InsertConfigInteger(pCur, "MergeTarget", 1); } /* Pass all custom parameters. */ SafeArray aNames; SafeArray aValues; hrc = pMedium->GetProperties(NULL, ComSafeArrayAsOutParam(aNames), ComSafeArrayAsOutParam(aValues)); H(); if (aNames.size() != 0) { PCFGMNODE pVDC; InsertConfigNode(pCur, "VDConfig", &pVDC); for (size_t ii = 0; ii < aNames.size(); ++ii) { if (aValues[ii] && *aValues[ii]) { Utf8Str name = aNames[ii]; Utf8Str value = aValues[ii]; InsertConfigString(pVDC, name.c_str(), value); if ( name.compare("HostIPStack") == 0 && value.compare("0") == 0) fHostIP = false; } } } /* next */ pParent = pCur; pParentMedium = pMedium; } /* Custom code: put marker to not use host IP stack to driver * configuration node. Simplifies life of DrvVD a bit. */ if (!fHostIP) InsertConfigInteger(pCfg, "HostIPStack", 0); } } #undef H } catch (ConfigError &x) { // InsertConfig threw something: return x.m_vrc; } return VINF_SUCCESS; } /** * Construct the Network configuration tree * * @returns VBox status code. * * @param pszDevice The PDM device name. * @param uInstance The PDM device instance. * @param uLun The PDM LUN number of the drive. * @param aNetworkAdapter The network adapter whose attachment needs to be changed * @param pCfg Configuration node for the device * @param pLunL0 To store the pointer to the LUN#0. * @param pInst The instance CFGM node * @param fAttachDetach To determine if the network attachment should * be attached/detached after/before * configuration. * @param fIgnoreConnectFailure * True if connection failures should be ignored * (makes only sense for bridged/host-only networks). * * @note Locks this object for writing. * @thread EMT */ int Console::configNetwork(const char *pszDevice, unsigned uInstance, unsigned uLun, INetworkAdapter *aNetworkAdapter, PCFGMNODE pCfg, PCFGMNODE pLunL0, PCFGMNODE pInst, bool fAttachDetach, bool fIgnoreConnectFailure) { AutoCaller autoCaller(this); AssertComRCReturn(autoCaller.rc(), VERR_ACCESS_DENIED); // InsertConfig* throws try { int rc = VINF_SUCCESS; HRESULT hrc; Bstr bstr; #define H() AssertMsgReturn(!FAILED(hrc), ("hrc=%Rhrc\n", hrc), VERR_GENERAL_FAILURE) /* * Locking the object before doing VMR3* calls is quite safe here, since * we're on EMT. Write lock is necessary because we indirectly modify the * meAttachmentType member. */ AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); ComPtr pMachine = machine(); ComPtr virtualBox; hrc = pMachine->COMGETTER(Parent)(virtualBox.asOutParam()); H(); ComPtr host; hrc = virtualBox->COMGETTER(Host)(host.asOutParam()); H(); BOOL fSniffer; hrc = aNetworkAdapter->COMGETTER(TraceEnabled)(&fSniffer); H(); NetworkAdapterPromiscModePolicy_T enmPromiscModePolicy; hrc = aNetworkAdapter->COMGETTER(PromiscModePolicy)(&enmPromiscModePolicy); H(); const char *pszPromiscuousGuestPolicy; switch (enmPromiscModePolicy) { case NetworkAdapterPromiscModePolicy_Deny: pszPromiscuousGuestPolicy = "deny"; break; case NetworkAdapterPromiscModePolicy_AllowNetwork: pszPromiscuousGuestPolicy = "allow-network"; break; case NetworkAdapterPromiscModePolicy_AllowAll: pszPromiscuousGuestPolicy = "allow-all"; break; default: AssertFailedReturn(VERR_INTERNAL_ERROR_4); } if (fAttachDetach) { rc = PDMR3DeviceDetach(mpUVM, pszDevice, uInstance, uLun, 0 /*fFlags*/); if (rc == VINF_PDM_NO_DRIVER_ATTACHED_TO_LUN) rc = VINF_SUCCESS; AssertLogRelRCReturn(rc, rc); /* nuke anything which might have been left behind. */ CFGMR3RemoveNode(CFGMR3GetChildF(pInst, "LUN#%u", uLun)); } #ifdef VBOX_WITH_NETSHAPER ComObjPtr pBwGroup; Bstr strBwGroup; hrc = aNetworkAdapter->COMGETTER(BandwidthGroup)(pBwGroup.asOutParam()); H(); if (!pBwGroup.isNull()) { hrc = pBwGroup->COMGETTER(Name)(strBwGroup.asOutParam()); H(); } #endif /* VBOX_WITH_NETSHAPER */ Utf8Str strNetDriver; InsertConfigNode(pInst, "LUN#0", &pLunL0); #ifdef VBOX_WITH_NETSHAPER if (!strBwGroup.isEmpty()) { InsertConfigString(pLunL0, "Driver", "NetShaper"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigString(pCfg, "BwGroup", strBwGroup); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL0); } #endif /* VBOX_WITH_NETSHAPER */ if (fSniffer) { InsertConfigString(pLunL0, "Driver", "NetSniffer"); InsertConfigNode(pLunL0, "Config", &pCfg); hrc = aNetworkAdapter->COMGETTER(TraceFile)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) /* check convention for indicating default file. */ InsertConfigString(pCfg, "File", bstr); InsertConfigNode(pLunL0, "AttachedDriver", &pLunL0); } Bstr networkName, trunkName, trunkType; NetworkAttachmentType_T eAttachmentType; hrc = aNetworkAdapter->COMGETTER(AttachmentType)(&eAttachmentType); H(); switch (eAttachmentType) { case NetworkAttachmentType_Null: break; case NetworkAttachmentType_NAT: { ComPtr natEngine; hrc = aNetworkAdapter->COMGETTER(NATEngine)(natEngine.asOutParam()); H(); InsertConfigString(pLunL0, "Driver", "NAT"); InsertConfigNode(pLunL0, "Config", &pCfg); /* Configure TFTP prefix and boot filename. */ hrc = virtualBox->COMGETTER(HomeFolder)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) InsertConfigString(pCfg, "TFTPPrefix", Utf8StrFmt("%ls%c%s", bstr.raw(), RTPATH_DELIMITER, "TFTP")); hrc = pMachine->COMGETTER(Name)(bstr.asOutParam()); H(); InsertConfigString(pCfg, "BootFile", Utf8StrFmt("%ls.pxe", bstr.raw())); hrc = natEngine->COMGETTER(Network)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) InsertConfigString(pCfg, "Network", bstr); else { ULONG uSlot; hrc = aNetworkAdapter->COMGETTER(Slot)(&uSlot); H(); InsertConfigString(pCfg, "Network", Utf8StrFmt("10.0.%d.0/24", uSlot+2)); } hrc = natEngine->COMGETTER(HostIP)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) InsertConfigString(pCfg, "BindIP", bstr); ULONG mtu = 0; ULONG sockSnd = 0; ULONG sockRcv = 0; ULONG tcpSnd = 0; ULONG tcpRcv = 0; hrc = natEngine->GetNetworkSettings(&mtu, &sockSnd, &sockRcv, &tcpSnd, &tcpRcv); H(); if (mtu) InsertConfigInteger(pCfg, "SlirpMTU", mtu); if (sockRcv) InsertConfigInteger(pCfg, "SockRcv", sockRcv); if (sockSnd) InsertConfigInteger(pCfg, "SockSnd", sockSnd); if (tcpRcv) InsertConfigInteger(pCfg, "TcpRcv", tcpRcv); if (tcpSnd) InsertConfigInteger(pCfg, "TcpSnd", tcpSnd); hrc = natEngine->COMGETTER(TFTPPrefix)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) { RemoveConfigValue(pCfg, "TFTPPrefix"); InsertConfigString(pCfg, "TFTPPrefix", bstr); } hrc = natEngine->COMGETTER(TFTPBootFile)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) { RemoveConfigValue(pCfg, "BootFile"); InsertConfigString(pCfg, "BootFile", bstr); } hrc = natEngine->COMGETTER(TFTPNextServer)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) InsertConfigString(pCfg, "NextServer", bstr); BOOL fDNSFlag; hrc = natEngine->COMGETTER(DNSPassDomain)(&fDNSFlag); H(); InsertConfigInteger(pCfg, "PassDomain", fDNSFlag); hrc = natEngine->COMGETTER(DNSProxy)(&fDNSFlag); H(); InsertConfigInteger(pCfg, "DNSProxy", fDNSFlag); hrc = natEngine->COMGETTER(DNSUseHostResolver)(&fDNSFlag); H(); InsertConfigInteger(pCfg, "UseHostResolver", fDNSFlag); ULONG aliasMode; hrc = natEngine->COMGETTER(AliasMode)(&aliasMode); H(); InsertConfigInteger(pCfg, "AliasMode", aliasMode); /* port-forwarding */ SafeArray pfs; hrc = natEngine->COMGETTER(Redirects)(ComSafeArrayAsOutParam(pfs)); H(); PCFGMNODE pPF = NULL; /* /Devices/Dev/.../Config/PF#0/ */ for (unsigned int i = 0; i < pfs.size(); ++i) { uint16_t port = 0; BSTR r = pfs[i]; Utf8Str utf = Utf8Str(r); Utf8Str strName; Utf8Str strProto; Utf8Str strHostPort; Utf8Str strHostIP; Utf8Str strGuestPort; Utf8Str strGuestIP; size_t pos, ppos; pos = ppos = 0; #define ITERATE_TO_NEXT_TERM(res, str, pos, ppos) \ do { \ pos = str.find(",", ppos); \ if (pos == Utf8Str::npos) \ { \ Log(( #res " extracting from %s is failed\n", str.c_str())); \ continue; \ } \ res = str.substr(ppos, pos - ppos); \ Log2((#res " %s pos:%d, ppos:%d\n", res.c_str(), pos, ppos)); \ ppos = pos + 1; \ } while (0) ITERATE_TO_NEXT_TERM(strName, utf, pos, ppos); ITERATE_TO_NEXT_TERM(strProto, utf, pos, ppos); ITERATE_TO_NEXT_TERM(strHostIP, utf, pos, ppos); ITERATE_TO_NEXT_TERM(strHostPort, utf, pos, ppos); ITERATE_TO_NEXT_TERM(strGuestIP, utf, pos, ppos); strGuestPort = utf.substr(ppos, utf.length() - ppos); #undef ITERATE_TO_NEXT_TERM uint32_t proto = strProto.toUInt32(); bool fValid = true; switch (proto) { case NATProtocol_UDP: strProto = "UDP"; break; case NATProtocol_TCP: strProto = "TCP"; break; default: fValid = false; } /* continue with next rule if no valid proto was passed */ if (!fValid) continue; InsertConfigNode(pCfg, strName.c_str(), &pPF); InsertConfigString(pPF, "Protocol", strProto); if (!strHostIP.isEmpty()) InsertConfigString(pPF, "BindIP", strHostIP); if (!strGuestIP.isEmpty()) InsertConfigString(pPF, "GuestIP", strGuestIP); port = RTStrToUInt16(strHostPort.c_str()); if (port) InsertConfigInteger(pPF, "HostPort", port); port = RTStrToUInt16(strGuestPort.c_str()); if (port) InsertConfigInteger(pPF, "GuestPort", port); } break; } case NetworkAttachmentType_Bridged: { #if (defined(RT_OS_LINUX) || defined(RT_OS_FREEBSD)) && !defined(VBOX_WITH_NETFLT) hrc = attachToTapInterface(aNetworkAdapter); if (FAILED(hrc)) { switch (hrc) { case VERR_ACCESS_DENIED: return VMSetError(VMR3GetVM(mpUVM), VERR_HOSTIF_INIT_FAILED, RT_SRC_POS, N_( "Failed to open '/dev/net/tun' for read/write access. Please check the " "permissions of that node. Either run 'chmod 0666 /dev/net/tun' or " "change the group of that node and make yourself a member of that group. Make " "sure that these changes are permanent, especially if you are " "using udev")); default: AssertMsgFailed(("Could not attach to host interface! Bad!\n")); return VMSetError(VMR3GetVM(mpUVM), VERR_HOSTIF_INIT_FAILED, RT_SRC_POS, N_( "Failed to initialize Host Interface Networking")); } } Assert((int)maTapFD[uInstance] >= 0); if ((int)maTapFD[uInstance] >= 0) { InsertConfigString(pLunL0, "Driver", "HostInterface"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "FileHandle", maTapFD[uInstance]); } #elif defined(VBOX_WITH_NETFLT) /* * This is the new VBoxNetFlt+IntNet stuff. */ Bstr BridgedIfName; hrc = aNetworkAdapter->COMGETTER(BridgedInterface)(BridgedIfName.asOutParam()); if (FAILED(hrc)) { LogRel(("NetworkAttachmentType_Bridged: COMGETTER(BridgedInterface) failed, hrc (0x%x)\n", hrc)); H(); } Utf8Str BridgedIfNameUtf8(BridgedIfName); const char *pszBridgedIfName = BridgedIfNameUtf8.c_str(); # if defined(RT_OS_DARWIN) /* The name is on the form 'ifX: long name', chop it off at the colon. */ char szTrunk[8]; RTStrCopy(szTrunk, sizeof(szTrunk), pszBridgedIfName); char *pszColon = (char *)memchr(szTrunk, ':', sizeof(szTrunk)); // Quick fix for @bugref{5633} // if (!pszColon) // { // /* // * Dynamic changing of attachment causes an attempt to configure // * network with invalid host adapter (as it is must be changed before // * the attachment), calling Detach here will cause a deadlock. // * See @bugref{4750}. // * hrc = aNetworkAdapter->Detach(); H(); // */ // return VMSetError(VMR3GetVM(mpUVM), VERR_INTERNAL_ERROR, RT_SRC_POS, // N_("Malformed host interface networking name '%ls'"), // BridgedIfName.raw()); // } if (pszColon) *pszColon = '\0'; const char *pszTrunk = szTrunk; # elif defined(RT_OS_SOLARIS) /* The name is on the form format 'ifX[:1] - long name, chop it off at space. */ char szTrunk[256]; strlcpy(szTrunk, pszBridgedIfName, sizeof(szTrunk)); char *pszSpace = (char *)memchr(szTrunk, ' ', sizeof(szTrunk)); /* * Currently don't bother about malformed names here for the sake of people using * VBoxManage and setting only the NIC name from there. If there is a space we * chop it off and proceed, otherwise just use whatever we've got. */ if (pszSpace) *pszSpace = '\0'; /* Chop it off at the colon (zone naming eg: e1000g:1 we need only the e1000g) */ char *pszColon = (char *)memchr(szTrunk, ':', sizeof(szTrunk)); if (pszColon) *pszColon = '\0'; const char *pszTrunk = szTrunk; # elif defined(RT_OS_WINDOWS) ComPtr hostInterface; hrc = host->FindHostNetworkInterfaceByName(BridgedIfName.raw(), hostInterface.asOutParam()); if (!SUCCEEDED(hrc)) { AssertLogRelMsgFailed(("NetworkAttachmentType_Bridged: FindByName failed, rc=%Rhrc (0x%x)", hrc, hrc)); return VMSetError(VMR3GetVM(mpUVM), VERR_INTERNAL_ERROR, RT_SRC_POS, N_("Nonexistent host networking interface, name '%ls'"), BridgedIfName.raw()); } HostNetworkInterfaceType_T eIfType; hrc = hostInterface->COMGETTER(InterfaceType)(&eIfType); if (FAILED(hrc)) { LogRel(("NetworkAttachmentType_Bridged: COMGETTER(InterfaceType) failed, hrc (0x%x)\n", hrc)); H(); } if (eIfType != HostNetworkInterfaceType_Bridged) { return VMSetError(VMR3GetVM(mpUVM), VERR_INTERNAL_ERROR, RT_SRC_POS, N_("Interface ('%ls') is not a Bridged Adapter interface"), BridgedIfName.raw()); } hrc = hostInterface->COMGETTER(Id)(bstr.asOutParam()); if (FAILED(hrc)) { LogRel(("NetworkAttachmentType_Bridged: COMGETTER(Id) failed, hrc (0x%x)\n", hrc)); H(); } Guid hostIFGuid(bstr); INetCfg *pNc; ComPtr pAdaptorComponent; LPWSTR pszApp; hrc = VBoxNetCfgWinQueryINetCfg(&pNc, FALSE, L"VirtualBox", 10, &pszApp); Assert(hrc == S_OK); if (hrc != S_OK) { LogRel(("NetworkAttachmentType_Bridged: Failed to get NetCfg, hrc=%Rhrc (0x%x)\n", hrc, hrc)); H(); } /* get the adapter's INetCfgComponent*/ hrc = VBoxNetCfgWinGetComponentByGuid(pNc, &GUID_DEVCLASS_NET, (GUID*)hostIFGuid.raw(), pAdaptorComponent.asOutParam()); if (hrc != S_OK) { VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); LogRel(("NetworkAttachmentType_Bridged: VBoxNetCfgWinGetComponentByGuid failed, hrc (0x%x)\n", hrc)); H(); } #define VBOX_WIN_BINDNAME_PREFIX "\\DEVICE\\" char szTrunkName[INTNET_MAX_TRUNK_NAME]; char *pszTrunkName = szTrunkName; wchar_t * pswzBindName; hrc = pAdaptorComponent->GetBindName(&pswzBindName); Assert(hrc == S_OK); if (hrc == S_OK) { int cwBindName = (int)wcslen(pswzBindName) + 1; int cbFullBindNamePrefix = sizeof(VBOX_WIN_BINDNAME_PREFIX); if (sizeof(szTrunkName) > cbFullBindNamePrefix + cwBindName) { strcpy(szTrunkName, VBOX_WIN_BINDNAME_PREFIX); pszTrunkName += cbFullBindNamePrefix-1; if (!WideCharToMultiByte(CP_ACP, 0, pswzBindName, cwBindName, pszTrunkName, sizeof(szTrunkName) - cbFullBindNamePrefix + 1, NULL, NULL)) { DWORD err = GetLastError(); hrc = HRESULT_FROM_WIN32(err); AssertMsgFailed(("%hrc=%Rhrc %#x\n", hrc, hrc)); AssertLogRelMsgFailed(("NetworkAttachmentType_Bridged: WideCharToMultiByte failed, hr=%Rhrc (0x%x) err=%u\n", hrc, hrc, err)); } } else { AssertLogRelMsgFailed(("NetworkAttachmentType_Bridged: insufficient szTrunkName buffer space\n")); /** @todo set appropriate error code */ hrc = E_FAIL; } if (hrc != S_OK) { AssertFailed(); CoTaskMemFree(pswzBindName); VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); H(); } /* we're not freeing the bind name since we'll use it later for detecting wireless*/ } else { VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); AssertLogRelMsgFailed(("NetworkAttachmentType_Bridged: VBoxNetCfgWinGetComponentByGuid failed, hrc (0x%x)", hrc)); H(); } const char *pszTrunk = szTrunkName; /* we're not releasing the INetCfg stuff here since we use it later to figure out whether it is wireless */ # elif defined(RT_OS_LINUX) || defined(RT_OS_FREEBSD) # if defined(RT_OS_FREEBSD) /* * If we bridge to a tap interface open it the `old' direct way. * This works and performs better than bridging a physical * interface via the current FreeBSD vboxnetflt implementation. */ if (!strncmp(pszBridgedIfName, RT_STR_TUPLE("tap"))) { hrc = attachToTapInterface(aNetworkAdapter); if (FAILED(hrc)) { switch (hrc) { case VERR_ACCESS_DENIED: return VMSetError(VMR3GetVM(mpUVM), VERR_HOSTIF_INIT_FAILED, RT_SRC_POS, N_( "Failed to open '/dev/%s' for read/write access. Please check the " "permissions of that node, and that the net.link.tap.user_open " "sysctl is set. Either run 'chmod 0666 /dev/%s' or " "change the group of that node to vboxusers and make yourself " "a member of that group. Make sure that these changes are permanent."), pszBridgedIfName, pszBridgedIfName); default: AssertMsgFailed(("Could not attach to tap interface! Bad!\n")); return VMSetError(VMR3GetVM(mpUVM), VERR_HOSTIF_INIT_FAILED, RT_SRC_POS, N_( "Failed to initialize Host Interface Networking")); } } Assert((int)maTapFD[uInstance] >= 0); if ((int)maTapFD[uInstance] >= 0) { InsertConfigString(pLunL0, "Driver", "HostInterface"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigInteger(pCfg, "FileHandle", maTapFD[uInstance]); } break; } # endif /** @todo Check for malformed names. */ const char *pszTrunk = pszBridgedIfName; /* Issue a warning if the interface is down */ { int iSock = socket(AF_INET, SOCK_DGRAM, 0); if (iSock >= 0) { struct ifreq Req; RT_ZERO(Req); RTStrCopy(Req.ifr_name, sizeof(Req.ifr_name), pszBridgedIfName); if (ioctl(iSock, SIOCGIFFLAGS, &Req) >= 0) if ((Req.ifr_flags & IFF_UP) == 0) setVMRuntimeErrorCallbackF(0, "BridgedInterfaceDown", N_("Bridged interface %s is down. Guest will not be able to use this interface"), pszBridgedIfName); close(iSock); } } # else # error "PORTME (VBOX_WITH_NETFLT)" # endif InsertConfigString(pLunL0, "Driver", "IntNet"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigString(pCfg, "Trunk", pszTrunk); InsertConfigInteger(pCfg, "TrunkType", kIntNetTrunkType_NetFlt); InsertConfigInteger(pCfg, "IgnoreConnectFailure", (uint64_t)fIgnoreConnectFailure); InsertConfigString(pCfg, "IfPolicyPromisc", pszPromiscuousGuestPolicy); char szNetwork[INTNET_MAX_NETWORK_NAME]; #if defined(RT_OS_SOLARIS) || defined(RT_OS_DARWIN) /* * 'pszTrunk' contains just the interface name required in ring-0, while 'pszBridgedIfName' contains * interface name + optional description. We must not pass any description to the VM as it can differ * for the same interface name, eg: "nge0 - ethernet" (GUI) vs "nge0" (VBoxManage). */ RTStrPrintf(szNetwork, sizeof(szNetwork), "HostInterfaceNetworking-%s", pszTrunk); #else RTStrPrintf(szNetwork, sizeof(szNetwork), "HostInterfaceNetworking-%s", pszBridgedIfName); #endif InsertConfigString(pCfg, "Network", szNetwork); networkName = Bstr(szNetwork); trunkName = Bstr(pszTrunk); trunkType = Bstr(TRUNKTYPE_NETFLT); # if defined(RT_OS_DARWIN) /** @todo Come up with a better deal here. Problem is that IHostNetworkInterface is completely useless here. */ if ( strstr(pszBridgedIfName, "Wireless") || strstr(pszBridgedIfName, "AirPort" )) InsertConfigInteger(pCfg, "SharedMacOnWire", true); # elif defined(RT_OS_LINUX) int iSock = socket(AF_INET, SOCK_DGRAM, 0); if (iSock >= 0) { struct iwreq WRq; RT_ZERO(WRq); strncpy(WRq.ifr_name, pszBridgedIfName, IFNAMSIZ); bool fSharedMacOnWire = ioctl(iSock, SIOCGIWNAME, &WRq) >= 0; close(iSock); if (fSharedMacOnWire) { InsertConfigInteger(pCfg, "SharedMacOnWire", true); Log(("Set SharedMacOnWire\n")); } else Log(("Failed to get wireless name\n")); } else Log(("Failed to open wireless socket\n")); # elif defined(RT_OS_FREEBSD) int iSock = socket(AF_INET, SOCK_DGRAM, 0); if (iSock >= 0) { struct ieee80211req WReq; uint8_t abData[32]; RT_ZERO(WReq); strncpy(WReq.i_name, pszBridgedIfName, sizeof(WReq.i_name)); WReq.i_type = IEEE80211_IOC_SSID; WReq.i_val = -1; WReq.i_data = abData; WReq.i_len = sizeof(abData); bool fSharedMacOnWire = ioctl(iSock, SIOCG80211, &WReq) >= 0; close(iSock); if (fSharedMacOnWire) { InsertConfigInteger(pCfg, "SharedMacOnWire", true); Log(("Set SharedMacOnWire\n")); } else Log(("Failed to get wireless name\n")); } else Log(("Failed to open wireless socket\n")); # elif defined(RT_OS_WINDOWS) # define DEVNAME_PREFIX L"\\\\.\\" /* we are getting the medium type via IOCTL_NDIS_QUERY_GLOBAL_STATS Io Control * there is a pretty long way till there though since we need to obtain the symbolic link name * for the adapter device we are going to query given the device Guid */ /* prepend the "\\\\.\\" to the bind name to obtain the link name */ wchar_t FileName[MAX_PATH]; wcscpy(FileName, DEVNAME_PREFIX); wcscpy((wchar_t*)(((char*)FileName) + sizeof(DEVNAME_PREFIX) - sizeof(FileName[0])), pswzBindName); /* open the device */ HANDLE hDevice = CreateFile(FileName, GENERIC_READ | GENERIC_WRITE, FILE_SHARE_READ | FILE_SHARE_WRITE, NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL); if (hDevice != INVALID_HANDLE_VALUE) { bool fSharedMacOnWire = false; /* now issue the OID_GEN_PHYSICAL_MEDIUM query */ DWORD Oid = OID_GEN_PHYSICAL_MEDIUM; NDIS_PHYSICAL_MEDIUM PhMedium; DWORD cbResult; if (DeviceIoControl(hDevice, IOCTL_NDIS_QUERY_GLOBAL_STATS, &Oid, sizeof(Oid), &PhMedium, sizeof(PhMedium), &cbResult, NULL)) { /* that was simple, now examine PhMedium */ if ( PhMedium == NdisPhysicalMediumWirelessWan || PhMedium == NdisPhysicalMediumWirelessLan || PhMedium == NdisPhysicalMediumNative802_11 || PhMedium == NdisPhysicalMediumBluetooth) fSharedMacOnWire = true; } else { int winEr = GetLastError(); LogRel(("Console::configNetwork: DeviceIoControl failed, err (0x%x), ignoring\n", winEr)); Assert(winEr == ERROR_INVALID_PARAMETER || winEr == ERROR_NOT_SUPPORTED || winEr == ERROR_BAD_COMMAND); } CloseHandle(hDevice); if (fSharedMacOnWire) { Log(("this is a wireless adapter")); InsertConfigInteger(pCfg, "SharedMacOnWire", true); Log(("Set SharedMacOnWire\n")); } else Log(("this is NOT a wireless adapter")); } else { int winEr = GetLastError(); AssertLogRelMsgFailed(("Console::configNetwork: CreateFile failed, err (0x%x), ignoring\n", winEr)); } CoTaskMemFree(pswzBindName); pAdaptorComponent.setNull(); /* release the pNc finally */ VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); # else /** @todo PORTME: wireless detection */ # endif # if defined(RT_OS_SOLARIS) # if 0 /* bird: this is a bit questionable and might cause more trouble than its worth. */ /* Zone access restriction, don't allow snooping the global zone. */ zoneid_t ZoneId = getzoneid(); if (ZoneId != GLOBAL_ZONEID) { InsertConfigInteger(pCfg, "IgnoreAllPromisc", true); } # endif # endif #elif defined(RT_OS_WINDOWS) /* not defined NetFlt */ /* NOTHING TO DO HERE */ #elif defined(RT_OS_LINUX) /// @todo aleksey: is there anything to be done here? #elif defined(RT_OS_FREEBSD) /** @todo FreeBSD: Check out this later (HIF networking). */ #else # error "Port me" #endif break; } case NetworkAttachmentType_Internal: { hrc = aNetworkAdapter->COMGETTER(InternalNetwork)(bstr.asOutParam()); H(); if (!bstr.isEmpty()) { InsertConfigString(pLunL0, "Driver", "IntNet"); InsertConfigNode(pLunL0, "Config", &pCfg); InsertConfigString(pCfg, "Network", bstr); InsertConfigInteger(pCfg, "TrunkType", kIntNetTrunkType_WhateverNone); InsertConfigString(pCfg, "IfPolicyPromisc", pszPromiscuousGuestPolicy); networkName = bstr; trunkType = Bstr(TRUNKTYPE_WHATEVER); } break; } case NetworkAttachmentType_HostOnly: { InsertConfigString(pLunL0, "Driver", "IntNet"); InsertConfigNode(pLunL0, "Config", &pCfg); Bstr HostOnlyName; hrc = aNetworkAdapter->COMGETTER(HostOnlyInterface)(HostOnlyName.asOutParam()); if (FAILED(hrc)) { LogRel(("NetworkAttachmentType_HostOnly: COMGETTER(HostOnlyInterface) failed, hrc (0x%x)\n", hrc)); H(); } Utf8Str HostOnlyNameUtf8(HostOnlyName); const char *pszHostOnlyName = HostOnlyNameUtf8.c_str(); ComPtr hostInterface; rc = host->FindHostNetworkInterfaceByName(HostOnlyName.raw(), hostInterface.asOutParam()); if (!SUCCEEDED(rc)) { LogRel(("NetworkAttachmentType_HostOnly: FindByName failed, rc (0x%x)\n", rc)); return VMSetError(VMR3GetVM(mpUVM), VERR_INTERNAL_ERROR, RT_SRC_POS, N_("Nonexistent host networking interface, name '%ls'"), HostOnlyName.raw()); } char szNetwork[INTNET_MAX_NETWORK_NAME]; RTStrPrintf(szNetwork, sizeof(szNetwork), "HostInterfaceNetworking-%s", pszHostOnlyName); #if defined(RT_OS_WINDOWS) # ifndef VBOX_WITH_NETFLT hrc = E_NOTIMPL; LogRel(("NetworkAttachmentType_HostOnly: Not Implemented\n")); H(); # else /* defined VBOX_WITH_NETFLT*/ /** @todo r=bird: Put this in a function. */ HostNetworkInterfaceType_T eIfType; hrc = hostInterface->COMGETTER(InterfaceType)(&eIfType); if (FAILED(hrc)) { LogRel(("NetworkAttachmentType_HostOnly: COMGETTER(InterfaceType) failed, hrc (0x%x)\n", hrc)); H(); } if (eIfType != HostNetworkInterfaceType_HostOnly) return VMSetError(VMR3GetVM(mpUVM), VERR_INTERNAL_ERROR, RT_SRC_POS, N_("Interface ('%ls') is not a Host-Only Adapter interface"), HostOnlyName.raw()); hrc = hostInterface->COMGETTER(Id)(bstr.asOutParam()); if (FAILED(hrc)) { LogRel(("NetworkAttachmentType_HostOnly: COMGETTER(Id) failed, hrc (0x%x)\n", hrc)); H(); } Guid hostIFGuid(bstr); INetCfg *pNc; ComPtr pAdaptorComponent; LPWSTR pszApp; hrc = VBoxNetCfgWinQueryINetCfg(&pNc, FALSE, L"VirtualBox", 10, &pszApp); Assert(hrc == S_OK); if (hrc != S_OK) { LogRel(("NetworkAttachmentType_HostOnly: Failed to get NetCfg, hrc=%Rhrc (0x%x)\n", hrc, hrc)); H(); } /* get the adapter's INetCfgComponent*/ hrc = VBoxNetCfgWinGetComponentByGuid(pNc, &GUID_DEVCLASS_NET, (GUID*)hostIFGuid.raw(), pAdaptorComponent.asOutParam()); if (hrc != S_OK) { VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); LogRel(("NetworkAttachmentType_HostOnly: VBoxNetCfgWinGetComponentByGuid failed, hrc=%Rhrc (0x%x)\n", hrc, hrc)); H(); } # define VBOX_WIN_BINDNAME_PREFIX "\\DEVICE\\" char szTrunkName[INTNET_MAX_TRUNK_NAME]; char *pszTrunkName = szTrunkName; wchar_t * pswzBindName; hrc = pAdaptorComponent->GetBindName(&pswzBindName); Assert(hrc == S_OK); if (hrc == S_OK) { int cwBindName = (int)wcslen(pswzBindName) + 1; int cbFullBindNamePrefix = sizeof(VBOX_WIN_BINDNAME_PREFIX); if (sizeof(szTrunkName) > cbFullBindNamePrefix + cwBindName) { strcpy(szTrunkName, VBOX_WIN_BINDNAME_PREFIX); pszTrunkName += cbFullBindNamePrefix-1; if (!WideCharToMultiByte(CP_ACP, 0, pswzBindName, cwBindName, pszTrunkName, sizeof(szTrunkName) - cbFullBindNamePrefix + 1, NULL, NULL)) { DWORD err = GetLastError(); hrc = HRESULT_FROM_WIN32(err); AssertLogRelMsgFailed(("NetworkAttachmentType_HostOnly: WideCharToMultiByte failed, hr=%Rhrc (0x%x) err=%u\n", hrc, hrc, err)); } } else { AssertLogRelMsgFailed(("NetworkAttachmentType_HostOnly: insufficient szTrunkName buffer space\n")); /** @todo set appropriate error code */ hrc = E_FAIL; } if (hrc != S_OK) { AssertFailed(); CoTaskMemFree(pswzBindName); VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); H(); } } else { VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); AssertLogRelMsgFailed(("NetworkAttachmentType_HostOnly: VBoxNetCfgWinGetComponentByGuid failed, hrc=%Rhrc (0x%x)\n", hrc, hrc)); H(); } CoTaskMemFree(pswzBindName); pAdaptorComponent.setNull(); /* release the pNc finally */ VBoxNetCfgWinReleaseINetCfg(pNc, FALSE /*fHasWriteLock*/); const char *pszTrunk = szTrunkName; InsertConfigInteger(pCfg, "TrunkType", kIntNetTrunkType_NetAdp); InsertConfigString(pCfg, "Trunk", pszTrunk); InsertConfigString(pCfg, "Network", szNetwork); InsertConfigInteger(pCfg, "IgnoreConnectFailure", (uint64_t)fIgnoreConnectFailure); /** @todo why is this windows only?? */ networkName = Bstr(szNetwork); trunkName = Bstr(pszTrunk); trunkType = TRUNKTYPE_NETADP; # endif /* defined VBOX_WITH_NETFLT*/ #elif defined(RT_OS_DARWIN) InsertConfigString(pCfg, "Trunk", pszHostOnlyName); InsertConfigString(pCfg, "Network", szNetwork); InsertConfigInteger(pCfg, "TrunkType", kIntNetTrunkType_NetAdp); networkName = Bstr(szNetwork); trunkName = Bstr(pszHostOnlyName); trunkType = TRUNKTYPE_NETADP; #else InsertConfigString(pCfg, "Trunk", pszHostOnlyName); InsertConfigString(pCfg, "Network", szNetwork); InsertConfigInteger(pCfg, "TrunkType", kIntNetTrunkType_NetFlt); networkName = Bstr(szNetwork); trunkName = Bstr(pszHostOnlyName); trunkType = TRUNKTYPE_NETFLT; #endif InsertConfigString(pCfg, "IfPolicyPromisc", pszPromiscuousGuestPolicy); #if !defined(RT_OS_WINDOWS) && defined(VBOX_WITH_NETFLT) Bstr tmpAddr, tmpMask; hrc = virtualBox->GetExtraData(BstrFmt("HostOnly/%s/IPAddress", pszHostOnlyName).raw(), tmpAddr.asOutParam()); if (SUCCEEDED(hrc) && !tmpAddr.isEmpty()) { hrc = virtualBox->GetExtraData(BstrFmt("HostOnly/%s/IPNetMask", pszHostOnlyName).raw(), tmpMask.asOutParam()); if (SUCCEEDED(hrc) && !tmpMask.isEmpty()) hrc = hostInterface->EnableStaticIPConfig(tmpAddr.raw(), tmpMask.raw()); else hrc = hostInterface->EnableStaticIPConfig(tmpAddr.raw(), Bstr(VBOXNET_IPV4MASK_DEFAULT).raw()); } else { /* Grab the IP number from the 'vboxnetX' instance number (see netif.h) */ hrc = hostInterface->EnableStaticIPConfig(getDefaultIPv4Address(Bstr(pszHostOnlyName)).raw(), Bstr(VBOXNET_IPV4MASK_DEFAULT).raw()); } ComAssertComRC(hrc); /** @todo r=bird: Why this isn't fatal? (H()) */ hrc = virtualBox->GetExtraData(BstrFmt("HostOnly/%s/IPV6Address", pszHostOnlyName).raw(), tmpAddr.asOutParam()); if (SUCCEEDED(hrc)) hrc = virtualBox->GetExtraData(BstrFmt("HostOnly/%s/IPV6NetMask", pszHostOnlyName).raw(), tmpMask.asOutParam()); if (SUCCEEDED(hrc) && !tmpAddr.isEmpty() && !tmpMask.isEmpty()) { hrc = hostInterface->EnableStaticIPConfigV6(tmpAddr.raw(), Utf8Str(tmpMask).toUInt32()); ComAssertComRC(hrc); /** @todo r=bird: Why this isn't fatal? (H()) */ } #endif break; } case NetworkAttachmentType_Generic: { hrc = aNetworkAdapter->COMGETTER(GenericDriver)(bstr.asOutParam()); H(); SafeArray names; SafeArray values; hrc = aNetworkAdapter->GetProperties(Bstr().raw(), ComSafeArrayAsOutParam(names), ComSafeArrayAsOutParam(values)); H(); InsertConfigString(pLunL0, "Driver", bstr); InsertConfigNode(pLunL0, "Config", &pCfg); for (size_t ii = 0; ii < names.size(); ++ii) { if (values[ii] && *values[ii]) { Utf8Str name = names[ii]; Utf8Str value = values[ii]; InsertConfigString(pCfg, name.c_str(), value); } } break; } default: AssertMsgFailed(("should not get here!\n")); break; } /* * Attempt to attach the driver. */ switch (eAttachmentType) { case NetworkAttachmentType_Null: break; case NetworkAttachmentType_Bridged: case NetworkAttachmentType_Internal: case NetworkAttachmentType_HostOnly: case NetworkAttachmentType_NAT: case NetworkAttachmentType_Generic: { if (SUCCEEDED(hrc) && SUCCEEDED(rc)) { if (fAttachDetach) { rc = PDMR3DriverAttach(mpUVM, pszDevice, uInstance, uLun, 0 /*fFlags*/, NULL /* ppBase */); //AssertRC(rc); } { /** @todo pritesh: get the dhcp server name from the * previous network configuration and then stop the server * else it may conflict with the dhcp server running with * the current attachment type */ /* Stop the hostonly DHCP Server */ } if (!networkName.isEmpty()) { /* * Until we implement service reference counters DHCP Server will be stopped * by DHCPServerRunner destructor. */ ComPtr dhcpServer; hrc = virtualBox->FindDHCPServerByNetworkName(networkName.raw(), dhcpServer.asOutParam()); if (SUCCEEDED(hrc)) { /* there is a DHCP server available for this network */ BOOL fEnabledDhcp; hrc = dhcpServer->COMGETTER(Enabled)(&fEnabledDhcp); if (FAILED(hrc)) { LogRel(("DHCP svr: COMGETTER(Enabled) failed, hrc (%Rhrc)\n", hrc)); H(); } if (fEnabledDhcp) hrc = dhcpServer->Start(networkName.raw(), trunkName.raw(), trunkType.raw()); } else hrc = S_OK; } } break; } default: AssertMsgFailed(("should not get here!\n")); break; } meAttachmentType[uInstance] = eAttachmentType; } catch (ConfigError &x) { // InsertConfig threw something: return x.m_vrc; } #undef H return VINF_SUCCESS; } #ifdef VBOX_WITH_GUEST_PROPS /** * Set an array of guest properties */ static void configSetProperties(VMMDev * const pVMMDev, void *names, void *values, void *timestamps, void *flags) { VBOXHGCMSVCPARM parms[4]; parms[0].type = VBOX_HGCM_SVC_PARM_PTR; parms[0].u.pointer.addr = names; parms[0].u.pointer.size = 0; /* We don't actually care. */ parms[1].type = VBOX_HGCM_SVC_PARM_PTR; parms[1].u.pointer.addr = values; parms[1].u.pointer.size = 0; /* We don't actually care. */ parms[2].type = VBOX_HGCM_SVC_PARM_PTR; parms[2].u.pointer.addr = timestamps; parms[2].u.pointer.size = 0; /* We don't actually care. */ parms[3].type = VBOX_HGCM_SVC_PARM_PTR; parms[3].u.pointer.addr = flags; parms[3].u.pointer.size = 0; /* We don't actually care. */ pVMMDev->hgcmHostCall("VBoxGuestPropSvc", guestProp::SET_PROPS_HOST, 4, &parms[0]); } /** * Set a single guest property */ static void configSetProperty(VMMDev * const pVMMDev, const char *pszName, const char *pszValue, const char *pszFlags) { VBOXHGCMSVCPARM parms[4]; AssertPtrReturnVoid(pszName); AssertPtrReturnVoid(pszValue); AssertPtrReturnVoid(pszFlags); parms[0].type = VBOX_HGCM_SVC_PARM_PTR; parms[0].u.pointer.addr = (void *)pszName; parms[0].u.pointer.size = (uint32_t)strlen(pszName) + 1; parms[1].type = VBOX_HGCM_SVC_PARM_PTR; parms[1].u.pointer.addr = (void *)pszValue; parms[1].u.pointer.size = (uint32_t)strlen(pszValue) + 1; parms[2].type = VBOX_HGCM_SVC_PARM_PTR; parms[2].u.pointer.addr = (void *)pszFlags; parms[2].u.pointer.size = (uint32_t)strlen(pszFlags) + 1; pVMMDev->hgcmHostCall("VBoxGuestPropSvc", guestProp::SET_PROP_HOST, 3, &parms[0]); } /** * Set the global flags value by calling the service * @returns the status returned by the call to the service * * @param pTable the service instance handle * @param eFlags the flags to set */ int configSetGlobalPropertyFlags(VMMDev * const pVMMDev, guestProp::ePropFlags eFlags) { VBOXHGCMSVCPARM paParm; paParm.setUInt32(eFlags); int rc = pVMMDev->hgcmHostCall("VBoxGuestPropSvc", guestProp::SET_GLOBAL_FLAGS_HOST, 1, &paParm); if (RT_FAILURE(rc)) { char szFlags[guestProp::MAX_FLAGS_LEN]; if (RT_FAILURE(writeFlags(eFlags, szFlags))) Log(("Failed to set the global flags.\n")); else Log(("Failed to set the global flags \"%s\".\n", szFlags)); } return rc; } #endif /* VBOX_WITH_GUEST_PROPS */ /** * Set up the Guest Property service, populate it with properties read from * the machine XML and set a couple of initial properties. */ /* static */ int Console::configGuestProperties(void *pvConsole, PUVM pUVM) { #ifdef VBOX_WITH_GUEST_PROPS AssertReturn(pvConsole, VERR_GENERAL_FAILURE); ComObjPtr pConsole = static_cast(pvConsole); AssertReturn(pConsole->m_pVMMDev, VERR_GENERAL_FAILURE); /* Load the service */ int rc = pConsole->m_pVMMDev->hgcmLoadService("VBoxGuestPropSvc", "VBoxGuestPropSvc"); if (RT_FAILURE(rc)) { LogRel(("VBoxGuestPropSvc is not available. rc = %Rrc\n", rc)); /* That is not a fatal failure. */ rc = VINF_SUCCESS; } else { /* * Initialize built-in properties that can be changed and saved. * * These are typically transient properties that the guest cannot * change. */ { VBOXHGCMSVCPARM Params[2]; int rc2 = pConsole->m_pVMMDev->hgcmHostCall("VBoxGuestPropSvc", guestProp::GET_DBGF_INFO_FN, 2, &Params[0]); if (RT_SUCCESS(rc2)) { PFNDBGFHANDLEREXT pfnHandler = (PFNDBGFHANDLEREXT)(uintptr_t)Params[0].u.pointer.addr; void *pService = (void*)Params[1].u.pointer.addr; DBGFR3InfoRegisterExternal(pUVM, "guestprops", "Display the guest properties", pfnHandler, pService); } } /* Sysprep execution by VBoxService. */ configSetProperty(pConsole->m_pVMMDev, "/VirtualBox/HostGuest/SysprepExec", "", "TRANSIENT, RDONLYGUEST"); configSetProperty(pConsole->m_pVMMDev, "/VirtualBox/HostGuest/SysprepArgs", "", "TRANSIENT, RDONLYGUEST"); /* * Pull over the properties from the server. */ SafeArray namesOut; SafeArray valuesOut; SafeArray timestampsOut; SafeArray flagsOut; HRESULT hrc; hrc = pConsole->mControl->PullGuestProperties(ComSafeArrayAsOutParam(namesOut), ComSafeArrayAsOutParam(valuesOut), ComSafeArrayAsOutParam(timestampsOut), ComSafeArrayAsOutParam(flagsOut)); AssertMsgReturn(SUCCEEDED(hrc), ("hrc=%Rhrc\n", hrc), VERR_GENERAL_FAILURE); size_t cProps = namesOut.size(); size_t cAlloc = cProps + 1; if ( valuesOut.size() != cProps || timestampsOut.size() != cProps || flagsOut.size() != cProps ) AssertFailedReturn(VERR_INVALID_PARAMETER); char **papszNames, **papszValues, **papszFlags; char szEmpty[] = ""; LONG64 *pai64Timestamps; papszNames = (char **)RTMemTmpAllocZ(sizeof(void *) * cAlloc); papszValues = (char **)RTMemTmpAllocZ(sizeof(void *) * cAlloc); pai64Timestamps = (LONG64 *)RTMemTmpAllocZ(sizeof(LONG64) * cAlloc); papszFlags = (char **)RTMemTmpAllocZ(sizeof(void *) * cAlloc); if (papszNames && papszValues && pai64Timestamps && papszFlags) { for (unsigned i = 0; RT_SUCCESS(rc) && i < cProps; ++i) { AssertPtrReturn(namesOut[i], VERR_INVALID_PARAMETER); rc = RTUtf16ToUtf8(namesOut[i], &papszNames[i]); if (RT_FAILURE(rc)) break; if (valuesOut[i]) rc = RTUtf16ToUtf8(valuesOut[i], &papszValues[i]); else papszValues[i] = szEmpty; if (RT_FAILURE(rc)) break; pai64Timestamps[i] = timestampsOut[i]; if (flagsOut[i]) rc = RTUtf16ToUtf8(flagsOut[i], &papszFlags[i]); else papszFlags[i] = szEmpty; } if (RT_SUCCESS(rc)) configSetProperties(pConsole->m_pVMMDev, (void *)papszNames, (void *)papszValues, (void *)pai64Timestamps, (void *)papszFlags); for (unsigned i = 0; i < cProps; ++i) { RTStrFree(papszNames[i]); if (valuesOut[i]) RTStrFree(papszValues[i]); if (flagsOut[i]) RTStrFree(papszFlags[i]); } } else rc = VERR_NO_MEMORY; RTMemTmpFree(papszNames); RTMemTmpFree(papszValues); RTMemTmpFree(pai64Timestamps); RTMemTmpFree(papszFlags); AssertRCReturn(rc, rc); /* * These properties have to be set before pulling over the properties * from the machine XML, to ensure that properties saved in the XML * will override them. */ /* Set the raw VBox version string as a guest property. Used for host/guest * version comparison. */ configSetProperty(pConsole->m_pVMMDev, "/VirtualBox/HostInfo/VBoxVer", VBOX_VERSION_STRING_RAW, "TRANSIENT, RDONLYGUEST"); /* Set the full VBox version string as a guest property. Can contain vendor-specific * information/branding and/or pre-release tags. */ configSetProperty(pConsole->m_pVMMDev, "/VirtualBox/HostInfo/VBoxVerExt", VBOX_VERSION_STRING, "TRANSIENT, RDONLYGUEST"); /* Set the VBox SVN revision as a guest property */ configSetProperty(pConsole->m_pVMMDev, "/VirtualBox/HostInfo/VBoxRev", RTBldCfgRevisionStr(), "TRANSIENT, RDONLYGUEST"); /* * Register the host notification callback */ HGCMSVCEXTHANDLE hDummy; HGCMHostRegisterServiceExtension(&hDummy, "VBoxGuestPropSvc", Console::doGuestPropNotification, pvConsole); #ifdef VBOX_WITH_GUEST_PROPS_RDONLY_GUEST rc = configSetGlobalPropertyFlags(pConsole->m_pVMMDev, guestProp::RDONLYGUEST); AssertRCReturn(rc, rc); #endif Log(("Set VBoxGuestPropSvc property store\n")); } return VINF_SUCCESS; #else /* !VBOX_WITH_GUEST_PROPS */ return VERR_NOT_SUPPORTED; #endif /* !VBOX_WITH_GUEST_PROPS */ } /** * Set up the Guest Control service. */ /* static */ int Console::configGuestControl(void *pvConsole) { #ifdef VBOX_WITH_GUEST_CONTROL AssertReturn(pvConsole, VERR_GENERAL_FAILURE); ComObjPtr pConsole = static_cast(pvConsole); /* Load the service */ int rc = pConsole->m_pVMMDev->hgcmLoadService("VBoxGuestControlSvc", "VBoxGuestControlSvc"); if (RT_FAILURE(rc)) { LogRel(("VBoxGuestControlSvc is not available. rc = %Rrc\n", rc)); /* That is not a fatal failure. */ rc = VINF_SUCCESS; } else { HGCMSVCEXTHANDLE hDummy; rc = HGCMHostRegisterServiceExtension(&hDummy, "VBoxGuestControlSvc", &Guest::notifyCtrlDispatcher, pConsole->getGuest()); if (RT_FAILURE(rc)) Log(("Cannot register VBoxGuestControlSvc extension!\n")); else Log(("VBoxGuestControlSvc loaded\n")); } return rc; #else /* !VBOX_WITH_GUEST_CONTROL */ return VERR_NOT_SUPPORTED; #endif /* !VBOX_WITH_GUEST_CONTROL */ }