/* $Id: MachineImpl.cpp 13723 2008-10-31 16:05:55Z vboxsync $ */ /** @file * Implementation of IMachine in VBoxSVC. */ /* * Copyright (C) 2006-2007 Sun Microsystems, Inc. * * 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. * * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa * Clara, CA 95054 USA or visit http://www.sun.com if you need * additional information or have any questions. */ /* Make sure all the stdint.h macros are included - must come first! */ #ifndef __STDC_LIMIT_MACROS # define __STDC_LIMIT_MACROS #endif #ifndef __STDC_CONSTANT_MACROS # define __STDC_CONSTANT_MACROS #endif #if defined(RT_OS_WINDOWS) #elif defined(RT_OS_LINUX) #endif #ifdef VBOX_WITH_SYS_V_IPC_SESSION_WATCHER # include # include # include # include # include #endif #include "VirtualBoxImpl.h" #include "MachineImpl.h" #include "ProgressImpl.h" #include "HardDiskAttachmentImpl.h" #include "USBControllerImpl.h" #include "HostImpl.h" #include "SystemPropertiesImpl.h" #include "SharedFolderImpl.h" #include "GuestOSTypeImpl.h" #include "VirtualBoxErrorInfoImpl.h" #include "GuestImpl.h" #include "SATAControllerImpl.h" #ifdef VBOX_WITH_USB # include "USBProxyService.h" #endif #include "VirtualBoxXMLUtil.h" #include "Logging.h" #include #include #include #include #include #include #include #include #include #include #include #include #ifdef VBOX_WITH_GUEST_PROPS # include # include #endif #include #include #if defined(RT_OS_WINDOWS) || defined(RT_OS_OS2) #define HOSTSUFF_EXE ".exe" #else /* !RT_OS_WINDOWS */ #define HOSTSUFF_EXE "" #endif /* !RT_OS_WINDOWS */ // defines / prototypes ///////////////////////////////////////////////////////////////////////////// // globals ///////////////////////////////////////////////////////////////////////////// /** * @note The template is NOT completely valid according to VBOX_XML_SCHEMA * (when loading a newly created settings file, validation will be turned off) */ static const char DefaultMachineConfig[] = { "" RTFILE_LINEFEED "" RTFILE_LINEFEED "" RTFILE_LINEFEED "" RTFILE_LINEFEED }; /** * Progress callback handler for lengthy operations * (corresponds to the FNRTPROGRESS typedef). * * @param uPercentage Completetion precentage (0-100). * @param pvUser Pointer to the Progress instance. */ static DECLCALLBACK(int) progressCallback (unsigned uPercentage, void *pvUser) { Progress *progress = static_cast (pvUser); /* update the progress object */ if (progress) progress->notifyProgress (uPercentage); return VINF_SUCCESS; } ///////////////////////////////////////////////////////////////////////////// // Machine::Data structure ///////////////////////////////////////////////////////////////////////////// Machine::Data::Data() { mRegistered = FALSE; mAccessible = FALSE; /* mUuid is initialized in Machine::init() */ mMachineState = MachineState_PoweredOff; RTTimeNow (&mLastStateChange); mMachineStateDeps = 0; mMachineStateDepsSem = NIL_RTSEMEVENTMULTI; mMachineStateChangePending = 0; mCurrentStateModified = TRUE; mHandleCfgFile = NIL_RTFILE; mSession.mPid = NIL_RTPROCESS; mSession.mState = SessionState_Closed; } Machine::Data::~Data() { if (mMachineStateDepsSem != NIL_RTSEMEVENTMULTI) { RTSemEventMultiDestroy (mMachineStateDepsSem); mMachineStateDepsSem = NIL_RTSEMEVENTMULTI; } } ///////////////////////////////////////////////////////////////////////////// // Machine::UserData structure ///////////////////////////////////////////////////////////////////////////// Machine::UserData::UserData() { /* default values for a newly created machine */ mNameSync = TRUE; /* mName, mOSTypeId, mSnapshotFolder, mSnapshotFolderFull are initialized in * Machine::init() */ } Machine::UserData::~UserData() { } ///////////////////////////////////////////////////////////////////////////// // Machine::HWData structure ///////////////////////////////////////////////////////////////////////////// Machine::HWData::HWData() { /* default values for a newly created machine */ mMemorySize = 128; mCPUCount = 1; mMemoryBalloonSize = 0; mStatisticsUpdateInterval = 0; mVRAMSize = 8; mMonitorCount = 1; mHWVirtExEnabled = TSBool_False; mHWVirtExNestedPagingEnabled = false; mHWVirtExVPIDEnabled = false; mPAEEnabled = false; /* default boot order: floppy - DVD - HDD */ mBootOrder [0] = DeviceType_Floppy; mBootOrder [1] = DeviceType_DVD; mBootOrder [2] = DeviceType_HardDisk; for (size_t i = 3; i < ELEMENTS (mBootOrder); i++) mBootOrder [i] = DeviceType_Null; mClipboardMode = ClipboardMode_Bidirectional; mGuestPropertyNotificationPatterns = ""; } Machine::HWData::~HWData() { } bool Machine::HWData::operator== (const HWData &that) const { if (this == &that) return true; if (mMemorySize != that.mMemorySize || mMemoryBalloonSize != that.mMemoryBalloonSize || mStatisticsUpdateInterval != that.mStatisticsUpdateInterval || mVRAMSize != that.mVRAMSize || mMonitorCount != that.mMonitorCount || mHWVirtExEnabled != that.mHWVirtExEnabled || mHWVirtExNestedPagingEnabled != that.mHWVirtExNestedPagingEnabled || mHWVirtExVPIDEnabled != that.mHWVirtExVPIDEnabled || mPAEEnabled != that.mPAEEnabled || mCPUCount != that.mCPUCount || mClipboardMode != that.mClipboardMode) return false; for (size_t i = 0; i < ELEMENTS (mBootOrder); ++ i) if (mBootOrder [i] != that.mBootOrder [i]) return false; if (mSharedFolders.size() != that.mSharedFolders.size()) return false; if (mSharedFolders.size() == 0) return true; /* Make copies to speed up comparison */ SharedFolderList folders = mSharedFolders; SharedFolderList thatFolders = that.mSharedFolders; SharedFolderList::iterator it = folders.begin(); while (it != folders.end()) { bool found = false; SharedFolderList::iterator thatIt = thatFolders.begin(); while (thatIt != thatFolders.end()) { if ((*it)->name() == (*thatIt)->name() && RTPathCompare (Utf8Str ((*it)->hostPath()), Utf8Str ((*thatIt)->hostPath())) == 0) { thatFolders.erase (thatIt); found = true; break; } else ++ thatIt; } if (found) it = folders.erase (it); else return false; } Assert (folders.size() == 0 && thatFolders.size() == 0); return true; } ///////////////////////////////////////////////////////////////////////////// // Machine::HDData structure ///////////////////////////////////////////////////////////////////////////// Machine::HDData::HDData() { } Machine::HDData::~HDData() { } bool Machine::HDData::operator== (const HDData &that) const { if (this == &that) return true; if (mAttachments.size() != that.mAttachments.size()) return false; if (mAttachments.size() == 0) return true; /* Make copies to speed up comparison */ AttachmentList atts = mAttachments; AttachmentList thatAtts = that.mAttachments; AttachmentList::iterator it = atts.begin(); while (it != atts.end()) { bool found = false; AttachmentList::iterator thatIt = thatAtts.begin(); while (thatIt != thatAtts.end()) { if ((*it)->bus() == (*thatIt)->bus() && (*it)->channel() == (*thatIt)->channel() && (*it)->device() == (*thatIt)->device() && (*it)->hardDisk().equalsTo ((*thatIt)->hardDisk())) { thatAtts.erase (thatIt); found = true; break; } else ++ thatIt; } if (found) it = atts.erase (it); else return false; } Assert (atts.size() == 0 && thatAtts.size() == 0); return true; } ///////////////////////////////////////////////////////////////////////////// // Machine class ///////////////////////////////////////////////////////////////////////////// // constructor / destructor ///////////////////////////////////////////////////////////////////////////// Machine::Machine() : mType (IsMachine) {} Machine::~Machine() {} HRESULT Machine::FinalConstruct() { LogFlowThisFunc (("\n")); return S_OK; } void Machine::FinalRelease() { LogFlowThisFunc (("\n")); uninit(); } /** * Initializes the instance. * * @param aParent Associated parent object * @param aConfigFile Local file system path to the VM settings file (can * be relative to the VirtualBox config directory). * @param aMode Init_New, Init_Existing or Init_Registered * @param aName name for the machine when aMode is Init_New * (ignored otherwise) * @param aNameSync |TRUE| to automatically sync settings dir and file * name with the machine name. |FALSE| is used for legacy * machines where the file name is specified by the * user and should never change. Used only in Init_New * mode (ignored otherwise). * @param aId UUID of the machine. Required for aMode==Init_Registered * and optional for aMode==Init_New. Used for consistency * check when aMode is Init_Registered; must match UUID * stored in the settings file. Used for predefining the * UUID of a VM when aMode is Init_New. * * @return Success indicator. if not S_OK, the machine object is invalid */ HRESULT Machine::init (VirtualBox *aParent, const BSTR aConfigFile, InitMode aMode, const BSTR aName /* = NULL */, BOOL aNameSync /* = TRUE */, const Guid *aId /* = NULL */) { LogFlowThisFuncEnter(); LogFlowThisFunc (("aConfigFile='%ls', aMode=%d\n", aConfigFile, aMode)); AssertReturn (aParent, E_INVALIDARG); AssertReturn (aConfigFile, E_INVALIDARG); AssertReturn (aMode != Init_New || (aName != NULL && *aName != '\0'), E_INVALIDARG); AssertReturn (aMode != Init_Registered || aId != NULL, E_FAIL); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan (this); AssertReturn (autoInitSpan.isOk(), E_UNEXPECTED); HRESULT rc = S_OK; /* share the parent weakly */ unconst (mParent) = aParent; /* register with parent early, since uninit() will unconditionally * unregister on failure */ mParent->addDependentChild (this); /* allocate the essential machine data structure (the rest will be * allocated later by initDataAndChildObjects() */ mData.allocate(); /* memorize the config file name (as provided) */ mData->mConfigFile = aConfigFile; /* get the full file name */ Utf8Str configFileFull; int vrc = mParent->calculateFullPath (Utf8Str (aConfigFile), configFileFull); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("Invalid machine settings file name '%ls' (%Vrc)"), aConfigFile, vrc); mData->mConfigFileFull = configFileFull; if (aMode == Init_Registered) { mData->mRegistered = TRUE; /* store the supplied UUID (will be used to check for UUID consistency * in loadSettings() */ unconst (mData->mUuid) = *aId; rc = registeredInit(); } else { if (aMode == Init_Existing) { /* lock the settings file */ rc = lockConfig(); } else if (aMode == Init_New) { /* check for the file existence */ RTFILE f = NIL_RTFILE; int vrc = RTFileOpen (&f, configFileFull, RTFILE_O_READ); if (VBOX_SUCCESS (vrc) || vrc == VERR_SHARING_VIOLATION) { rc = setError (E_FAIL, tr ("Machine settings file '%s' already exists"), configFileFull.raw()); if (VBOX_SUCCESS (vrc)) RTFileClose (f); } else { if (vrc != VERR_FILE_NOT_FOUND && vrc != VERR_PATH_NOT_FOUND) rc = setError (E_FAIL, tr ("Invalid machine settings file name '%ls' (%Vrc)"), mData->mConfigFileFull.raw(), vrc); } } else AssertFailed(); if (SUCCEEDED (rc)) rc = initDataAndChildObjects(); if (SUCCEEDED (rc)) { /* set to true now to cause uninit() to call * uninitDataAndChildObjects() on failure */ mData->mAccessible = TRUE; if (aMode != Init_New) { rc = loadSettings (false /* aRegistered */); } else { /* create the machine UUID */ if (aId) unconst (mData->mUuid) = *aId; else unconst (mData->mUuid).create(); /* memorize the provided new machine's name */ mUserData->mName = aName; mUserData->mNameSync = aNameSync; /* initialize the default snapshots folder * (note: depends on the name value set above!) */ rc = COMSETTER(SnapshotFolder) (NULL); AssertComRC (rc); } /* commit all changes made during the initialization */ if (SUCCEEDED (rc)) commit(); } } /* Confirm a successful initialization when it's the case */ if (SUCCEEDED (rc)) { if (mData->mAccessible) autoInitSpan.setSucceeded(); else autoInitSpan.setLimited(); } LogFlowThisFunc (("mName='%ls', mRegistered=%RTbool, mAccessible=%RTbool " "rc=%08X\n", !!mUserData ? mUserData->mName.raw() : NULL, mData->mRegistered, mData->mAccessible, rc)); LogFlowThisFuncLeave(); return rc; } /** * Initializes the registered machine by loading the settings file. * This method is separated from #init() in order to make it possible to * retry the operation after VirtualBox startup instead of refusing to * startup the whole VirtualBox server in case if the settings file of some * registered VM is invalid or inaccessible. * * @note Must be always called from this object's write lock * (unless called from #init() that doesn't need any locking). * @note Locks the mUSBController method for writing. * @note Subclasses must not call this method. */ HRESULT Machine::registeredInit() { AssertReturn (mType == IsMachine, E_FAIL); AssertReturn (!mData->mUuid.isEmpty(), E_FAIL); AssertReturn (!mData->mAccessible, E_FAIL); HRESULT rc = lockConfig(); if (SUCCEEDED (rc)) rc = initDataAndChildObjects(); if (SUCCEEDED (rc)) { /* Temporarily reset the registered flag in order to let setters * potentially called from loadSettings() succeed (isMutable() used in * all setters will return FALSE for a Machine instance if mRegistered * is TRUE). */ mData->mRegistered = FALSE; rc = loadSettings (true /* aRegistered */); /* Restore the registered flag (even on failure) */ mData->mRegistered = TRUE; if (FAILED (rc)) unlockConfig(); } if (SUCCEEDED (rc)) { /* Set mAccessible to TRUE only if we successfully locked and loaded * the settings file */ mData->mAccessible = TRUE; /* commit all changes made during loading the settings file */ commit(); /* VirtualBox will not call trySetRegistered(), so * inform the USB proxy about all attached USB filters */ mUSBController->onMachineRegistered (TRUE); } else { /* If the machine is registered, then, instead of returning a * failure, we mark it as inaccessible and set the result to * success to give it a try later */ /* fetch the current error info */ mData->mAccessError = com::ErrorInfo(); LogWarning (("Machine {%Vuuid} is inaccessible! [%ls]\n", mData->mUuid.raw(), mData->mAccessError.getText().raw())); /* rollback all changes */ rollback (false /* aNotify */); /* uninitialize the common part to make sure all data is reset to * default (null) values */ uninitDataAndChildObjects(); rc = S_OK; } return rc; } /** * Uninitializes the instance. * Called either from FinalRelease() or by the parent when it gets destroyed. * * @note The caller of this method must make sure that this object * a) doesn't have active callers on the current thread and b) is not locked * by the current thread; otherwise uninit() will hang either a) due to * AutoUninitSpan waiting for a number of calls to drop to zero or b) due to * a dead-lock caused by this thread waiting for all callers on the other * threads are are done but preventing them from doing so by holding a lock. */ void Machine::uninit() { LogFlowThisFuncEnter(); Assert (!isWriteLockOnCurrentThread()); /* Enclose the state transition Ready->InUninit->NotReady */ AutoUninitSpan autoUninitSpan (this); if (autoUninitSpan.uninitDone()) return; Assert (mType == IsMachine); Assert (!!mData); LogFlowThisFunc (("initFailed()=%d\n", autoUninitSpan.initFailed())); LogFlowThisFunc (("mRegistered=%d\n", mData->mRegistered)); /* Enter this object lock because there may be a SessionMachine instance * somewhere around, that shares our data and lock but doesn't use our * addCaller()/removeCaller(), and it may be also accessing the same data * members. mParent lock is necessary as well because of * SessionMachine::uninit(), etc. */ AutoMultiWriteLock2 alock (mParent, this); if (!mData->mSession.mMachine.isNull()) { /* Theoretically, this can only happen if the VirtualBox server has been * terminated while there were clients running that owned open direct * sessions. Since in this case we are definitely called by * VirtualBox::uninit(), we may be sure that SessionMachine::uninit() * won't happen on the client watcher thread (because it does * VirtualBox::addCaller() for the duration of the * SessionMachine::checkForDeath() call, so that VirtualBox::uninit() * cannot happen until the VirtualBox caller is released). This is * important, because SessionMachine::uninit() cannot correctly operate * after we return from this method (it expects the Machine instance is * still valid). We'll call it ourselves below. */ LogWarningThisFunc (("Session machine is not NULL (%p), " "the direct session is still open!\n", (SessionMachine *) mData->mSession.mMachine)); if (mData->mMachineState >= MachineState_Running) { LogWarningThisFunc (("Setting state to Aborted!\n")); /* set machine state using SessionMachine reimplementation */ static_cast (mData->mSession.mMachine) ->setMachineState (MachineState_Aborted); } /* * Uninitialize SessionMachine using public uninit() to indicate * an unexpected uninitialization. */ mData->mSession.mMachine->uninit(); /* SessionMachine::uninit() must set mSession.mMachine to null */ Assert (mData->mSession.mMachine.isNull()); } /* the lock is no more necessary (SessionMachine is uninitialized) */ alock.leave(); /* make sure the configuration is unlocked */ unlockConfig(); if (isModified()) { LogWarningThisFunc (("Discarding unsaved settings changes!\n")); rollback (false /* aNotify */); } if (mData->mAccessible) uninitDataAndChildObjects(); /* free the essential data structure last */ mData.free(); mParent->removeDependentChild (this); LogFlowThisFuncLeave(); } // IMachine properties ///////////////////////////////////////////////////////////////////////////// STDMETHODIMP Machine::COMGETTER(Parent) (IVirtualBox **aParent) { if (!aParent) return E_POINTER; AutoLimitedCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mParent is constant during life time, no need to lock */ mParent.queryInterfaceTo (aParent); return S_OK; } STDMETHODIMP Machine::COMGETTER(Accessible) (BOOL *aAccessible) { if (!aAccessible) return E_POINTER; AutoLimitedCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = S_OK; if (!mData->mAccessible) { /* try to initialize the VM once more if not accessible */ AutoReinitSpan autoReinitSpan (this); AssertReturn (autoReinitSpan.isOk(), E_FAIL); rc = registeredInit(); if (SUCCEEDED (rc) && mData->mAccessible) { autoReinitSpan.setSucceeded(); /* make sure interesting parties will notice the accessibility * state change */ mParent->onMachineStateChange (mData->mUuid, mData->mMachineState); mParent->onMachineDataChange (mData->mUuid); } } if (SUCCEEDED (rc)) *aAccessible = mData->mAccessible; return rc; } STDMETHODIMP Machine::COMGETTER(AccessError) (IVirtualBoxErrorInfo **aAccessError) { if (!aAccessError) return E_POINTER; AutoLimitedCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); if (mData->mAccessible || !mData->mAccessError.isBasicAvailable()) { /* return shortly */ aAccessError = NULL; return S_OK; } HRESULT rc = S_OK; ComObjPtr errorInfo; rc = errorInfo.createObject(); if (SUCCEEDED (rc)) { errorInfo->init (mData->mAccessError.getResultCode(), mData->mAccessError.getInterfaceID(), mData->mAccessError.getComponent(), mData->mAccessError.getText()); rc = errorInfo.queryInterfaceTo (aAccessError); } return rc; } STDMETHODIMP Machine::COMGETTER(Name) (BSTR *aName) { if (!aName) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mUserData->mName.cloneTo (aName); return S_OK; } STDMETHODIMP Machine::COMSETTER(Name) (INPTR BSTR aName) { if (!aName) return E_INVALIDARG; if (!*aName) return setError (E_INVALIDARG, tr ("Machine name cannot be empty")); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mUserData.backup(); mUserData->mName = aName; return S_OK; } STDMETHODIMP Machine::COMGETTER(Description) (BSTR *aDescription) { if (!aDescription) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mUserData->mDescription.cloneTo (aDescription); return S_OK; } STDMETHODIMP Machine::COMSETTER(Description) (INPTR BSTR aDescription) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mUserData.backup(); mUserData->mDescription = aDescription; return S_OK; } STDMETHODIMP Machine::COMGETTER(Id) (GUIDPARAMOUT aId) { if (!aId) return E_POINTER; AutoLimitedCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mData->mUuid.cloneTo (aId); return S_OK; } STDMETHODIMP Machine::COMGETTER(OSTypeId) (BSTR *aOSTypeId) { if (!aOSTypeId) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mUserData->mOSTypeId.cloneTo (aOSTypeId); return S_OK; } STDMETHODIMP Machine::COMSETTER(OSTypeId) (INPTR BSTR aOSTypeId) { if (!aOSTypeId) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* look up the object by Id to check it is valid */ ComPtr guestOSType; HRESULT rc = mParent->GetGuestOSType (aOSTypeId, guestOSType.asOutParam()); CheckComRCReturnRC (rc); AutoWriteLock alock (this); rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mUserData.backup(); mUserData->mOSTypeId = aOSTypeId; return S_OK; } STDMETHODIMP Machine::COMGETTER(MemorySize) (ULONG *memorySize) { if (!memorySize) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *memorySize = mHWData->mMemorySize; return S_OK; } STDMETHODIMP Machine::COMSETTER(MemorySize) (ULONG memorySize) { /* check RAM limits */ if (memorySize < SchemaDefs::MinGuestRAM || memorySize > SchemaDefs::MaxGuestRAM) return setError (E_INVALIDARG, tr ("Invalid RAM size: %lu MB (must be in range [%lu, %lu] MB)"), memorySize, SchemaDefs::MinGuestRAM, SchemaDefs::MaxGuestRAM); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mMemorySize = memorySize; return S_OK; } STDMETHODIMP Machine::COMGETTER(CPUCount) (ULONG *CPUCount) { if (!CPUCount) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *CPUCount = mHWData->mCPUCount; return S_OK; } STDMETHODIMP Machine::COMSETTER(CPUCount) (ULONG CPUCount) { /* check RAM limits */ if (CPUCount < SchemaDefs::MinCPUCount || CPUCount > SchemaDefs::MaxCPUCount) return setError (E_INVALIDARG, tr ("Invalid virtual CPU count: %lu (must be in range [%lu, %lu])"), CPUCount, SchemaDefs::MinCPUCount, SchemaDefs::MaxCPUCount); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mCPUCount = CPUCount; return S_OK; } STDMETHODIMP Machine::COMGETTER(VRAMSize) (ULONG *memorySize) { if (!memorySize) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *memorySize = mHWData->mVRAMSize; return S_OK; } STDMETHODIMP Machine::COMSETTER(VRAMSize) (ULONG memorySize) { /* check VRAM limits */ if (memorySize < SchemaDefs::MinGuestVRAM || memorySize > SchemaDefs::MaxGuestVRAM) return setError (E_INVALIDARG, tr ("Invalid VRAM size: %lu MB (must be in range [%lu, %lu] MB)"), memorySize, SchemaDefs::MinGuestVRAM, SchemaDefs::MaxGuestVRAM); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mVRAMSize = memorySize; return S_OK; } /** @todo this method should not be public */ STDMETHODIMP Machine::COMGETTER(MemoryBalloonSize) (ULONG *memoryBalloonSize) { if (!memoryBalloonSize) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *memoryBalloonSize = mHWData->mMemoryBalloonSize; return S_OK; } /** @todo this method should not be public */ STDMETHODIMP Machine::COMSETTER(MemoryBalloonSize) (ULONG memoryBalloonSize) { /* check limits */ if (memoryBalloonSize >= VMMDEV_MAX_MEMORY_BALLOON(mHWData->mMemorySize)) return setError (E_INVALIDARG, tr ("Invalid memory balloon size: %lu MB (must be in range [%lu, %lu] MB)"), memoryBalloonSize, 0, VMMDEV_MAX_MEMORY_BALLOON(mHWData->mMemorySize)); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mMemoryBalloonSize = memoryBalloonSize; return S_OK; } /** @todo this method should not be public */ STDMETHODIMP Machine::COMGETTER(StatisticsUpdateInterval) (ULONG *statisticsUpdateInterval) { if (!statisticsUpdateInterval) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *statisticsUpdateInterval = mHWData->mStatisticsUpdateInterval; return S_OK; } /** @todo this method should not be public */ STDMETHODIMP Machine::COMSETTER(StatisticsUpdateInterval) (ULONG statisticsUpdateInterval) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mStatisticsUpdateInterval = statisticsUpdateInterval; return S_OK; } STDMETHODIMP Machine::COMGETTER(MonitorCount) (ULONG *monitorCount) { if (!monitorCount) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *monitorCount = mHWData->mMonitorCount; return S_OK; } STDMETHODIMP Machine::COMSETTER(MonitorCount) (ULONG monitorCount) { /* make sure monitor count is a sensible number */ if (monitorCount < 1 || monitorCount > SchemaDefs::MaxGuestMonitors) return setError (E_INVALIDARG, tr ("Invalid monitor count: %lu (must be in range [%lu, %lu])"), monitorCount, 1, SchemaDefs::MaxGuestMonitors); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mMonitorCount = monitorCount; return S_OK; } STDMETHODIMP Machine::COMGETTER(BIOSSettings)(IBIOSSettings **biosSettings) { if (!biosSettings) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mBIOSSettings is constant during life time, no need to lock */ mBIOSSettings.queryInterfaceTo (biosSettings); return S_OK; } STDMETHODIMP Machine::COMGETTER(HWVirtExEnabled)(TSBool_T *enabled) { if (!enabled) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *enabled = mHWData->mHWVirtExEnabled; return S_OK; } STDMETHODIMP Machine::COMSETTER(HWVirtExEnabled)(TSBool_T enable) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); /** @todo check validity! */ mHWData.backup(); mHWData->mHWVirtExEnabled = enable; return S_OK; } STDMETHODIMP Machine::COMGETTER(HWVirtExNestedPagingEnabled)(BOOL *enabled) { if (!enabled) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *enabled = mHWData->mHWVirtExNestedPagingEnabled; return S_OK; } STDMETHODIMP Machine::COMSETTER(HWVirtExNestedPagingEnabled)(BOOL enable) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); /** @todo check validity! */ mHWData.backup(); mHWData->mHWVirtExNestedPagingEnabled = enable; return S_OK; } STDMETHODIMP Machine::COMGETTER(HWVirtExVPIDEnabled)(BOOL *enabled) { if (!enabled) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *enabled = mHWData->mHWVirtExVPIDEnabled; return S_OK; } STDMETHODIMP Machine::COMSETTER(HWVirtExVPIDEnabled)(BOOL enable) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); /** @todo check validity! */ mHWData.backup(); mHWData->mHWVirtExVPIDEnabled = enable; return S_OK; } STDMETHODIMP Machine::COMGETTER(PAEEnabled)(BOOL *enabled) { if (!enabled) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *enabled = mHWData->mPAEEnabled; return S_OK; } STDMETHODIMP Machine::COMSETTER(PAEEnabled)(BOOL enable) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); /** @todo check validity! */ mHWData.backup(); mHWData->mPAEEnabled = enable; return S_OK; } STDMETHODIMP Machine::COMGETTER(SnapshotFolder) (BSTR *aSnapshotFolder) { if (!aSnapshotFolder) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mUserData->mSnapshotFolderFull.cloneTo (aSnapshotFolder); return S_OK; } STDMETHODIMP Machine::COMSETTER(SnapshotFolder) (INPTR BSTR aSnapshotFolder) { /* @todo (r=dmik): * 1. Allow to change the name of the snapshot folder containing snapshots * 2. Rename the folder on disk instead of just changing the property * value (to be smart and not to leave garbage). Note that it cannot be * done here because the change may be rolled back. Thus, the right * place is #saveSettings(). */ AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); if (!mData->mCurrentSnapshot.isNull()) return setError (E_FAIL, tr ("The snapshot folder of a machine with snapshots cannot " "be changed (please discard all snapshots first)")); Utf8Str snapshotFolder = aSnapshotFolder; if (snapshotFolder.isEmpty()) { if (isInOwnDir()) { /* the default snapshots folder is 'Snapshots' in the machine dir */ snapshotFolder = Utf8Str ("Snapshots"); } else { /* the default snapshots folder is {UUID}, for backwards * compatibility and to resolve conflicts */ snapshotFolder = Utf8StrFmt ("{%Vuuid}", mData->mUuid.raw()); } } int vrc = calculateFullPath (snapshotFolder, snapshotFolder); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("Invalid snapshot folder '%ls' (%Vrc)"), aSnapshotFolder, vrc); mUserData.backup(); mUserData->mSnapshotFolder = aSnapshotFolder; mUserData->mSnapshotFolderFull = snapshotFolder; return S_OK; } STDMETHODIMP Machine:: COMGETTER(HardDisk2Attachments) (ComSafeArrayOut (IHardDisk2Attachment *, aAttachments)) { if (ComSafeArrayOutIsNull (aAttachments)) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); SafeIfaceArray attachments (mHDData->mAttachments); attachments.detachTo (ComSafeArrayOutArg (aAttachments)); return S_OK; } STDMETHODIMP Machine::COMGETTER(VRDPServer)(IVRDPServer **vrdpServer) { #ifdef VBOX_WITH_VRDP if (!vrdpServer) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); Assert (!!mVRDPServer); mVRDPServer.queryInterfaceTo (vrdpServer); return S_OK; #else return E_NOTIMPL; #endif } STDMETHODIMP Machine::COMGETTER(DVDDrive) (IDVDDrive **dvdDrive) { if (!dvdDrive) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); Assert (!!mDVDDrive); mDVDDrive.queryInterfaceTo (dvdDrive); return S_OK; } STDMETHODIMP Machine::COMGETTER(FloppyDrive) (IFloppyDrive **floppyDrive) { if (!floppyDrive) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); Assert (!!mFloppyDrive); mFloppyDrive.queryInterfaceTo (floppyDrive); return S_OK; } STDMETHODIMP Machine::COMGETTER(AudioAdapter)(IAudioAdapter **audioAdapter) { if (!audioAdapter) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mAudioAdapter.queryInterfaceTo (audioAdapter); return S_OK; } STDMETHODIMP Machine::COMGETTER(USBController) (IUSBController **aUSBController) { #ifdef VBOX_WITH_USB if (!aUSBController) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); MultiResult rc = mParent->host()->checkUSBProxyService(); CheckComRCReturnRC (rc); AutoReadLock alock (this); return rc = mUSBController.queryInterfaceTo (aUSBController); #else /* Note: The GUI depends on this method returning E_NOTIMPL with no * extended error info to indicate that USB is simply not available * (w/o treting it as a failure), for example, as in OSE */ return E_NOTIMPL; #endif } STDMETHODIMP Machine::COMGETTER(SATAController) (ISATAController **aSATAController) { #ifdef VBOX_WITH_AHCI if (!aSATAController) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); return mSATAController.queryInterfaceTo (aSATAController); #else /* Note: The GUI depends on this method returning E_NOTIMPL with no * extended error info to indicate that SATA is simply not available * (w/o treting it as a failure), for example, as in OSE */ return E_NOTIMPL; #endif } STDMETHODIMP Machine::COMGETTER(SettingsFilePath) (BSTR *aFilePath) { if (!aFilePath) return E_POINTER; AutoLimitedCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mData->mConfigFileFull.cloneTo (aFilePath); return S_OK; } STDMETHODIMP Machine:: COMGETTER(SettingsFileVersion) (BSTR *aSettingsFileVersion) { if (!aSettingsFileVersion) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mData->mSettingsFileVersion.cloneTo (aSettingsFileVersion); return S_OK; } STDMETHODIMP Machine::COMGETTER(SettingsModified) (BOOL *aModified) { if (!aModified) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); if (!isConfigLocked()) { /* * if we're ready and isConfigLocked() is FALSE then it means * that no config file exists yet, so always return TRUE */ *aModified = TRUE; } else { *aModified = isModified(); } return S_OK; } STDMETHODIMP Machine::COMGETTER(SessionState) (SessionState_T *aSessionState) { if (!aSessionState) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *aSessionState = mData->mSession.mState; return S_OK; } STDMETHODIMP Machine::COMGETTER(SessionType) (BSTR *aSessionType) { if (!aSessionType) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mData->mSession.mType.cloneTo (aSessionType); return S_OK; } STDMETHODIMP Machine::COMGETTER(SessionPid) (ULONG *aSessionPid) { if (!aSessionPid) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *aSessionPid = mData->mSession.mPid; return S_OK; } STDMETHODIMP Machine::COMGETTER(State) (MachineState_T *machineState) { if (!machineState) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *machineState = mData->mMachineState; return S_OK; } STDMETHODIMP Machine::COMGETTER(LastStateChange) (LONG64 *aLastStateChange) { if (!aLastStateChange) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *aLastStateChange = RTTimeSpecGetMilli (&mData->mLastStateChange); return S_OK; } STDMETHODIMP Machine::COMGETTER(StateFilePath) (BSTR *aStateFilePath) { if (!aStateFilePath) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mSSData->mStateFilePath.cloneTo (aStateFilePath); return S_OK; } STDMETHODIMP Machine::COMGETTER(LogFolder) (BSTR *aLogFolder) { if (!aLogFolder) return E_POINTER; AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); Utf8Str logFolder; getLogFolder (logFolder); Bstr (logFolder).cloneTo (aLogFolder); return S_OK; } STDMETHODIMP Machine::COMGETTER(CurrentSnapshot) (ISnapshot **aCurrentSnapshot) { if (!aCurrentSnapshot) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mData->mCurrentSnapshot.queryInterfaceTo (aCurrentSnapshot); return S_OK; } STDMETHODIMP Machine::COMGETTER(SnapshotCount) (ULONG *aSnapshotCount) { if (!aSnapshotCount) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *aSnapshotCount = !mData->mFirstSnapshot ? 0 : mData->mFirstSnapshot->descendantCount() + 1 /* self */; return S_OK; } STDMETHODIMP Machine::COMGETTER(CurrentStateModified) (BOOL *aCurrentStateModified) { if (!aCurrentStateModified) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); /* Note: for machines with no snapshots, we always return FALSE * (mData->mCurrentStateModified will be TRUE in this case, for historical * reasons :) */ *aCurrentStateModified = !mData->mFirstSnapshot ? FALSE : mData->mCurrentStateModified; return S_OK; } STDMETHODIMP Machine::COMGETTER(SharedFolders) (ISharedFolderCollection **aSharedFolders) { if (!aSharedFolders) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); ComObjPtr coll; coll.createObject(); coll->init (mHWData->mSharedFolders); coll.queryInterfaceTo (aSharedFolders); return S_OK; } STDMETHODIMP Machine::COMGETTER(ClipboardMode) (ClipboardMode_T *aClipboardMode) { if (!aClipboardMode) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *aClipboardMode = mHWData->mClipboardMode; return S_OK; } STDMETHODIMP Machine::COMSETTER(ClipboardMode) (ClipboardMode_T aClipboardMode) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mClipboardMode = aClipboardMode; return S_OK; } STDMETHODIMP Machine::COMGETTER(GuestPropertyNotificationPatterns) (BSTR *aPatterns) { if (!aPatterns) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mHWData->mGuestPropertyNotificationPatterns.cloneTo (aPatterns); return RT_LIKELY(aPatterns != NULL) ? S_OK : E_OUTOFMEMORY; } STDMETHODIMP Machine::COMSETTER(GuestPropertyNotificationPatterns) (INPTR BSTR aPatterns) { AssertLogRelReturn (VALID_PTR(aPatterns), E_POINTER); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mGuestPropertyNotificationPatterns = aPatterns; return RT_LIKELY(!mHWData->mGuestPropertyNotificationPatterns.isNull()) ? S_OK : E_OUTOFMEMORY; } // IMachine methods ///////////////////////////////////////////////////////////////////////////// STDMETHODIMP Machine::SetBootOrder (ULONG aPosition, DeviceType_T aDevice) { if (aPosition < 1 || aPosition > SchemaDefs::MaxBootPosition) return setError (E_INVALIDARG, tr ("Invalid boot position: %lu (must be in range [1, %lu])"), aPosition, SchemaDefs::MaxBootPosition); if (aDevice == DeviceType_USB) return setError (E_FAIL, tr ("Booting from USB devices is not currently supported")); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mBootOrder [aPosition - 1] = aDevice; return S_OK; } STDMETHODIMP Machine::GetBootOrder (ULONG aPosition, DeviceType_T *aDevice) { if (aPosition < 1 || aPosition > SchemaDefs::MaxBootPosition) return setError (E_INVALIDARG, tr ("Invalid boot position: %lu (must be in range [1, %lu])"), aPosition, SchemaDefs::MaxBootPosition); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *aDevice = mHWData->mBootOrder [aPosition - 1]; return S_OK; } STDMETHODIMP Machine::AttachHardDisk2 (INPTR GUIDPARAM aId, StorageBus_T aBus, LONG aChannel, LONG aDevice) { if (aBus == StorageBus_SATA) { /* The device property is not used for SATA yet. Thus it is always zero. */ if (aDevice != 0) return setError (E_INVALIDARG, tr ("Invalid SATA device slot: %l (must be always 0)"), aDevice); /* We suport 30 ports, starting from 0 */ /// @todo: r=aeichner make max port count a system property if (aChannel < 0 || aChannel > 29) return setError (E_INVALIDARG, tr ("Invalid SATA channel number: %l (must be in range " "[0, 29])"), aChannel); } else if (aBus == StorageBus_IDE) { if (aChannel < 0 || aChannel > 1) return setError (E_FAIL, tr ("Invalid IDE channel: %l (must be in range [0, 1])"), aChannel); if (aChannel == 0) { if (aDevice < 0 || aDevice > 1) return setError (E_FAIL, tr ("Invalid IDE device slot: %l (must be in range " "[0, 1] for for channel 0)"), aDevice); } else if (aChannel == 1) { /* Device slot 0 is reserved for the CD/DVD drive. */ if (aDevice != 1) return setError (E_FAIL, tr ("Invalid IDE device slot: %l (must be " "1 for channel 1)"), aDevice); } } else return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* VirtualBox::findHardDisk2() need read lock; also we want to make sure the * hard disk object we pick up doesn't get unregistered before we finish. */ AutoReadLock vboxLock (mParent); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); /// @todo NEWMEDIA implicit machine registration if (!mData->mRegistered) return setError (E_FAIL, tr ("Cannot attach hard disks to an unregistered machine")); AssertReturn (mData->mMachineState != MachineState_Saved, E_FAIL); if (mData->mMachineState >= MachineState_Running) return setError (E_FAIL, tr ("Invalid machine state: %d"), mData->mMachineState); /* check if the device slot is already busy */ HDData::AttachmentList::const_iterator it = std::find_if (mHDData->mAttachments.begin(), mHDData->mAttachments.end(), HardDisk2Attachment::EqualsTo (aBus, aChannel, aDevice)); if (it != mHDData->mAttachments.end()) { ComObjPtr hd = (*it)->hardDisk(); AutoReadLock hdLock (hd); return setError (E_FAIL, tr ("Hard disk '%ls' is already attached to device slot %d on " "channel %d of bus %d of this virtual machine"), hd->locationFull().raw(), aDevice, aChannel, aBus); } Guid id = aId; /* find a hard disk by UUID */ ComObjPtr hd; rc = mParent->findHardDisk2 (&id, NULL, true /* aSetError */, &hd); CheckComRCReturnRC (rc); AutoCaller hdCaller (hd); CheckComRCReturnRC (hdCaller.rc()); AutoWriteLock hdLock (hd); if (std::find_if (mHDData->mAttachments.begin(), mHDData->mAttachments.end(), HardDisk2Attachment::RefersTo (hd)) != mHDData->mAttachments.end()) { return setError (E_FAIL, tr ("Hard disk '%ls' is already attached to this virtual machine"), hd->locationFull().raw()); } bool indirect = hd->isReadOnly(); bool associate = true; do { if (mHDData.isBackedUp()) { const HDData::AttachmentList &oldAtts = mHDData.backedUpData()->mAttachments; /* check if the hard disk was attached to the VM before we started * changing attachemnts in which case the attachment just needs to * be restored */ HDData::AttachmentList::const_iterator it = std::find_if (oldAtts.begin(), oldAtts.end(), HardDisk2Attachment::RefersTo (hd)); if (it != oldAtts.end()) { AssertReturn (!indirect, E_FAIL); /* see if it's the same bus/channel/device */ if ((*it)->device() == aDevice && (*it)->channel() == aChannel && (*it)->bus() == aBus) { /* the simplest case: restore the whole attachment * and return, nothing else to do */ mHDData->mAttachments.push_back (*it); return S_OK; } /* bus/channel/device differ; we need a new attachment object, * but don't try to associate it again */ associate = false; break; } } /* go further only if the attachment is to be indirect */ if (!indirect) break; /* perform the so called smart attachment logic for indirect * attachments. Note that smart attachment is only applicable to base * hard disks. */ if (hd->parent().isNull()) { /* first, investigate the backup copy of the current hard disk * attachments to make it possible to re-attach existing diffs to * another device slot w/o losing their contents */ if (mHDData.isBackedUp()) { const HDData::AttachmentList &oldAtts = mHDData.backedUpData()->mAttachments; HDData::AttachmentList::const_iterator foundIt = oldAtts.end(); uint32_t foundLevel = 0; for (HDData::AttachmentList::const_iterator it = oldAtts.begin(); it != oldAtts.end(); ++ it) { uint32_t level = 0; if ((*it)->hardDisk()->root (&level).equalsTo (hd)) { /* skip the hard disk if its currently attached (we * cannot attach the same hard disk twice) */ if (std::find_if (mHDData->mAttachments.begin(), mHDData->mAttachments.end(), HardDisk2Attachment::RefersTo ( (*it)->hardDisk())) != mHDData->mAttachments.end()) continue; /* matched device, channel and bus (i.e. attached to the * same place) will win and immediately stop the search; * otherwise the attachment that has the youngest * descendant of hd will be used */ if ((*it)->device() == aDevice && (*it)->channel() == aChannel && (*it)->bus() == aBus) { /* the simplest case: restore the whole attachment * and return, nothing else to do */ mHDData->mAttachments.push_back (*it); return S_OK; } else if (foundIt == oldAtts.end() || level > foundLevel /* prefer younger */) { foundIt = it; foundLevel = level; } } } if (foundIt != oldAtts.end()) { /* use the previously attached hard disk */ hd = (*foundIt)->hardDisk(); hdCaller.attach (hd); CheckComRCReturnRC (hdCaller.rc()); hdLock.attach (hd); /* not implicit, doesn't require association with this VM */ indirect = false; associate = false; /* go right to the HardDisk2Attachment creation */ break; } } /* then, search through snapshots for the best diff in the given * hard disk's chain to base the new diff on */ ComObjPtr base; ComObjPtr snap = mData->mCurrentSnapshot; while (snap) { AutoReadLock snapLock (snap); const HDData::AttachmentList &snapAtts = snap->data().mMachine->mHDData->mAttachments; HDData::AttachmentList::const_iterator foundIt = snapAtts.end(); uint32_t foundLevel = 0; for (HDData::AttachmentList::const_iterator it = snapAtts.begin(); it != snapAtts.end(); ++ it) { uint32_t level = 0; if ((*it)->hardDisk()->root (&level).equalsTo (hd)) { /* matched device, channel and bus (i.e. attached to the * same place) will win and immediately stop the search; * otherwise the attachment that has the youngest * descendant of hd will be used */ if ((*it)->device() == aDevice && (*it)->channel() == aChannel && (*it)->bus() == aBus) { foundIt = it; break; } else if (foundIt == snapAtts.end() || level > foundLevel /* prefer younger */) { foundIt = it; foundLevel = level; } } } if (foundIt != snapAtts.end()) { base = (*foundIt)->hardDisk(); break; } snap = snap->parent(); } /* found a suitable diff, use it as a base */ if (!base.isNull()) { hd = base; hdCaller.attach (hd); CheckComRCReturnRC (hdCaller.rc()); hdLock.attach (hd); } } /// @todo NEWMEDIA use the proper storage format (either the parent /// storage type or the ISystemProperties::defaultHardDiskFormat) ComObjPtr diff; diff.createObject(); rc = diff->init (mParent, Bstr ("VDI"), BstrFmt ("%ls"RTPATH_SLASH_STR, mUserData->mSnapshotFolderFull.raw())); CheckComRCReturnRC (rc); /* make sure the hard disk is not modified before createDiffStorage() */ rc = hd->LockRead (NULL); CheckComRCReturnRC (rc); /* will leave the lock before the potentially lengthy operation, so * protect with the special state */ MachineState_T oldState = mData->mMachineState; setMachineState (MachineState_SettingUp); hdLock.leave(); alock.leave(); vboxLock.unlock(); rc = hd->createDiffStorageAndWait (diff); alock.enter(); hdLock.enter(); setMachineState (oldState); hd->UnlockRead (NULL); CheckComRCReturnRC (rc); /* use the created diff for the actual attachment */ hd = diff; hdCaller.attach (hd); CheckComRCReturnRC (hdCaller.rc()); hdLock.attach (hd); } while (0); ComObjPtr attachment; attachment.createObject(); rc = attachment->init (hd, aBus, aChannel, aDevice, indirect); CheckComRCReturnRC (rc); if (associate) { /* as the last step, associate the hard disk to the VM */ rc = hd->attachTo (mData->mUuid); /* here we can fail because of Deleting, or being in process of * creating a Diff */ CheckComRCReturnRC (rc); } /* sucsess: finally remember the attachment */ mHDData.backup(); mHDData->mAttachments.push_back (attachment); return rc; } STDMETHODIMP Machine::GetHardDisk2 (StorageBus_T aBus, LONG aChannel, LONG aDevice, IHardDisk2 **aHardDisk) { if (aBus == StorageBus_Null) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); *aHardDisk = NULL; HDData::AttachmentList::const_iterator it = std::find_if (mHDData->mAttachments.begin(), mHDData->mAttachments.end(), HardDisk2Attachment::EqualsTo (aBus, aChannel, aDevice)); if (it == mHDData->mAttachments.end()) return setError (E_INVALIDARG, tr ("No hard disk attached to device slot %d on channel %d of bus %d"), aDevice, aChannel, aBus); (*it)->hardDisk().queryInterfaceTo (aHardDisk); return S_OK; } STDMETHODIMP Machine::DetachHardDisk2 (StorageBus_T aBus, LONG aChannel, LONG aDevice) { if (aBus == StorageBus_Null) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); AssertReturn (mData->mMachineState != MachineState_Saved, E_FAIL); if (mData->mMachineState >= MachineState_Running) return setError (E_FAIL, tr ("Invalid machine state: %d"), mData->mMachineState); HDData::AttachmentList::const_iterator it = std::find_if (mHDData->mAttachments.begin(), mHDData->mAttachments.end(), HardDisk2Attachment::EqualsTo (aBus, aChannel, aDevice)); if (it == mHDData->mAttachments.end()) return setError (E_INVALIDARG, tr ("No hard disk attached to device slot %d on channel %d of bus %d"), aDevice, aChannel, aBus); ComObjPtr hda = *it; ComObjPtr hd = hda->hardDisk(); if (hda->isImplicit()) { /* attempt to implicitly delete the implicitly created diff */ /// @todo move the implicit flag from HardDisk2Attachment to HardDisk2 /// and forbid any hard disk operation when it is implicit. Or maybe /// a special media state for it to make it even more simple. Assert (mHDData.isBackedUp()); /* will leave the lock before the potentially lengthy operation, so * protect with the special state */ MachineState_T oldState = mData->mMachineState; setMachineState (MachineState_SettingUp); alock.leave(); rc = hd->deleteStorageAndWait(); alock.enter(); setMachineState (oldState); CheckComRCReturnRC (rc); } mHDData.backup(); /* we cannot use erase (it) below because backup() above will create * a copy of the list and make this copy active, but the iterator * still refers to the original and is not valid for the copy */ mHDData->mAttachments.remove (hda); return S_OK; } STDMETHODIMP Machine::GetSerialPort (ULONG slot, ISerialPort **port) { if (!port) return E_POINTER; if (slot >= ELEMENTS (mSerialPorts)) return setError (E_INVALIDARG, tr ("Invalid slot number: %d"), slot); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mSerialPorts [slot].queryInterfaceTo (port); return S_OK; } STDMETHODIMP Machine::GetParallelPort (ULONG slot, IParallelPort **port) { if (!port) return E_POINTER; if (slot >= ELEMENTS (mParallelPorts)) return setError (E_INVALIDARG, tr ("Invalid slot number: %d"), slot); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mParallelPorts [slot].queryInterfaceTo (port); return S_OK; } STDMETHODIMP Machine::GetNetworkAdapter (ULONG slot, INetworkAdapter **adapter) { if (!adapter) return E_POINTER; if (slot >= ELEMENTS (mNetworkAdapters)) return setError (E_INVALIDARG, tr ("Invalid slot number: %d"), slot); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); mNetworkAdapters [slot].queryInterfaceTo (adapter); return S_OK; } /** * @note Locks this object for reading. */ STDMETHODIMP Machine::GetNextExtraDataKey (INPTR BSTR aKey, BSTR *aNextKey, BSTR *aNextValue) { if (!aNextKey) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* serialize file access (prevent writes) */ AutoReadLock alock (this); /* start with nothing found */ *aNextKey = NULL; if (aNextValue) *aNextValue = NULL; /* if we're ready and isConfigLocked() is FALSE then it means * that no config file exists yet, so return shortly */ if (!isConfigLocked()) return S_OK; HRESULT rc = S_OK; try { using namespace settings; /* load the settings file (we don't reuse the existing handle but * request a new one to allow for concurrent multithreaded reads) */ File file (File::Mode_Read, Utf8Str (mData->mConfigFileFull)); XmlTreeBackend tree; rc = VirtualBox::loadSettingsTree_Again (tree, file); CheckComRCReturnRC (rc); Key machineNode = tree.rootKey().key ("Machine"); Key extraDataNode = machineNode.findKey ("ExtraData"); if (!extraDataNode.isNull()) { Key::List items = extraDataNode.keys ("ExtraDataItem"); if (items.size()) { for (Key::List::const_iterator it = items.begin(); it != items.end(); ++ it) { Bstr key = (*it).stringValue ("name"); /* if we're supposed to return the first one */ if (aKey == NULL) { key.cloneTo (aNextKey); if (aNextValue) { Bstr val = (*it).stringValue ("value"); val.cloneTo (aNextValue); } return S_OK; } /* did we find the key we're looking for? */ if (key == aKey) { ++ it; /* is there another item? */ if (it != items.end()) { Bstr key = (*it).stringValue ("name"); key.cloneTo (aNextKey); if (aNextValue) { Bstr val = (*it).stringValue ("value"); val.cloneTo (aNextValue); } } /* else it's the last one, arguments are already NULL */ return S_OK; } } } } /* Here we are when a) there are no items at all or b) there are items * but none of them equals to the requested non-NULL key. b) is an * error as well as a) if the key is non-NULL. When the key is NULL * (which is the case only when there are no items), we just fall * through to return NULLs and S_OK. */ if (aKey != NULL) return setError (E_FAIL, tr ("Could not find the extra data key '%ls'"), aKey); } catch (...) { rc = VirtualBox::handleUnexpectedExceptions (RT_SRC_POS); } return rc; } /** * @note Locks this object for reading. */ STDMETHODIMP Machine::GetExtraData (INPTR BSTR aKey, BSTR *aValue) { if (!aKey) return E_INVALIDARG; if (!aValue) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* serialize file access (prevent writes) */ AutoReadLock alock (this); /* start with nothing found */ *aValue = NULL; /* if we're ready and isConfigLocked() is FALSE then it means * that no config file exists yet, so return shortly */ if (!isConfigLocked()) return S_OK; HRESULT rc = S_OK; try { using namespace settings; /* load the settings file (we don't reuse the existing handle but * request a new one to allow for concurrent multithreaded reads) */ File file (File::Mode_Read, Utf8Str (mData->mConfigFileFull)); XmlTreeBackend tree; rc = VirtualBox::loadSettingsTree_Again (tree, file); CheckComRCReturnRC (rc); const Utf8Str key = aKey; Key machineNode = tree.rootKey().key ("Machine"); Key extraDataNode = machineNode.findKey ("ExtraData"); if (!extraDataNode.isNull()) { /* check if the key exists */ Key::List items = extraDataNode.keys ("ExtraDataItem"); for (Key::List::const_iterator it = items.begin(); it != items.end(); ++ it) { if (key == (*it).stringValue ("name")) { Bstr val = (*it).stringValue ("value"); val.cloneTo (aValue); break; } } } } catch (...) { rc = VirtualBox::handleUnexpectedExceptions (RT_SRC_POS); } return rc; } /** * @note Locks mParent for writing + this object for writing. */ STDMETHODIMP Machine::SetExtraData (INPTR BSTR aKey, INPTR BSTR aValue) { if (!aKey) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* VirtualBox::onExtraDataCanChange() and saveSettings() need mParent * lock (saveSettings() needs a write one). This object's write lock is * also necessary to serialize file access (prevent concurrent reads and * writes). */ AutoMultiWriteLock2 alock (mParent, this); if (mType == IsSnapshotMachine) { HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); } bool changed = false; HRESULT rc = S_OK; /* If we're ready and isConfigLocked() is FALSE then it means that no * config file exists yet, so call saveSettings() to create one. */ if (!isConfigLocked()) { rc = saveSettings(); CheckComRCReturnRC (rc); } try { using namespace settings; /* load the settings file */ File file (mData->mHandleCfgFile, Utf8Str (mData->mConfigFileFull)); XmlTreeBackend tree; rc = VirtualBox::loadSettingsTree_ForUpdate (tree, file); CheckComRCReturnRC (rc); const Utf8Str key = aKey; Bstr oldVal; Key machineNode = tree.rootKey().key ("Machine"); Key extraDataNode = machineNode.createKey ("ExtraData"); Key extraDataItemNode; Key::List items = extraDataNode.keys ("ExtraDataItem"); for (Key::List::const_iterator it = items.begin(); it != items.end(); ++ it) { if (key == (*it).stringValue ("name")) { extraDataItemNode = *it; oldVal = (*it).stringValue ("value"); break; } } /* When no key is found, oldVal is null */ changed = oldVal != aValue; if (changed) { /* ask for permission from all listeners */ Bstr error; if (!mParent->onExtraDataCanChange (mData->mUuid, aKey, aValue, error)) { const char *sep = error.isEmpty() ? "" : ": "; const BSTR err = error.isNull() ? (const BSTR) L"" : error.raw(); LogWarningFunc (("Someone vetoed! Change refused%s%ls\n", sep, err)); return setError (E_ACCESSDENIED, tr ("Could not set extra data because someone refused " "the requested change of '%ls' to '%ls'%s%ls"), aKey, aValue, sep, err); } if (aValue != NULL) { if (extraDataItemNode.isNull()) { extraDataItemNode = extraDataNode.appendKey ("ExtraDataItem"); extraDataItemNode.setStringValue ("name", key); } extraDataItemNode.setStringValue ("value", Utf8Str (aValue)); } else { /* an old value does for sure exist here (XML schema * guarantees that "value" may not absent in the * element) */ Assert (!extraDataItemNode.isNull()); extraDataItemNode.zap(); } /* save settings on success */ rc = VirtualBox::saveSettingsTree (tree, file, mData->mSettingsFileVersion); CheckComRCReturnRC (rc); } } catch (...) { rc = VirtualBox::handleUnexpectedExceptions (RT_SRC_POS); } /* fire a notification */ if (SUCCEEDED (rc) && changed) mParent->onExtraDataChange (mData->mUuid, aKey, aValue); return rc; } STDMETHODIMP Machine::SaveSettings() { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* saveSettings() needs mParent lock */ AutoMultiWriteLock2 alock (mParent, this); /* when there was auto-conversion, we want to save the file even if * the VM is saved */ StateDependency dep = mData->mSettingsFileVersion != VBOX_XML_VERSION_FULL ? MutableOrSavedStateDep : MutableStateDep; HRESULT rc = checkStateDependency (dep); CheckComRCReturnRC (rc); /* the settings file path may never be null */ ComAssertRet (mData->mConfigFileFull, E_FAIL); /* save all VM data excluding snapshots */ return saveSettings(); } STDMETHODIMP Machine::SaveSettingsWithBackup (BSTR *aBakFileName) { if (!aBakFileName) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* saveSettings() needs mParent lock */ AutoMultiWriteLock2 alock (mParent, this); /* when there was auto-conversion, we want to save the file even if * the VM is saved */ StateDependency dep = mData->mSettingsFileVersion != VBOX_XML_VERSION_FULL ? MutableOrSavedStateDep : MutableStateDep; HRESULT rc = checkStateDependency (dep); CheckComRCReturnRC (rc); /* the settings file path may never be null */ ComAssertRet (mData->mConfigFileFull, E_FAIL); /* perform backup only when there was auto-conversion */ if (mData->mSettingsFileVersion != VBOX_XML_VERSION_FULL) { Bstr bakFileName; HRESULT rc = VirtualBox::backupSettingsFile (mData->mConfigFileFull, mData->mSettingsFileVersion, bakFileName); CheckComRCReturnRC (rc); bakFileName.cloneTo (aBakFileName); } /* save all VM data excluding snapshots */ return saveSettings(); } STDMETHODIMP Machine::DiscardSettings() { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); /* * during this rollback, the session will be notified if data has * been actually changed */ rollback (true /* aNotify */); return S_OK; } STDMETHODIMP Machine::DeleteSettings() { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); if (mData->mRegistered) return setError (E_FAIL, tr ("Cannot delete settings of a registered machine")); /* delete the settings only when the file actually exists */ if (isConfigLocked()) { unlockConfig(); int vrc = RTFileDelete (Utf8Str (mData->mConfigFileFull)); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("Could not delete the settings file '%ls' (%Vrc)"), mData->mConfigFileFull.raw(), vrc); /* delete the Logs folder, nothing important should be left * there (we don't check for errors because the user might have * some private files there that we don't want to delete) */ Utf8Str logFolder; getLogFolder (logFolder); Assert (!logFolder.isEmpty()); if (RTDirExists (logFolder)) { /* Delete all VBox.log[.N] files from the Logs folder * (this must be in sync with the rotation logic in * Console::powerUpThread()). Also, delete the VBox.png[.N] * files that may have been created by the GUI. */ Utf8Str log = Utf8StrFmt ("%s/VBox.log", logFolder.raw()); RTFileDelete (log); log = Utf8StrFmt ("%s/VBox.png", logFolder.raw()); RTFileDelete (log); for (int i = 3; i >= 0; i--) { log = Utf8StrFmt ("%s/VBox.log.%d", logFolder.raw(), i); RTFileDelete (log); log = Utf8StrFmt ("%s/VBox.png.%d", logFolder.raw(), i); RTFileDelete (log); } RTDirRemove (logFolder); } /* delete the Snapshots folder, nothing important should be left * there (we don't check for errors because the user might have * some private files there that we don't want to delete) */ Utf8Str snapshotFolder = mUserData->mSnapshotFolderFull; Assert (!snapshotFolder.isEmpty()); if (RTDirExists (snapshotFolder)) RTDirRemove (snapshotFolder); /* delete the directory that contains the settings file, but only * if it matches the VM name (i.e. a structure created by default in * prepareSaveSettings()) */ { Utf8Str settingsDir; if (isInOwnDir (&settingsDir)) RTDirRemove (settingsDir); } } return S_OK; } STDMETHODIMP Machine::GetSnapshot (INPTR GUIDPARAM aId, ISnapshot **aSnapshot) { if (!aSnapshot) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); Guid id = aId; ComObjPtr snapshot; HRESULT rc = findSnapshot (id, snapshot, true /* aSetError */); snapshot.queryInterfaceTo (aSnapshot); return rc; } STDMETHODIMP Machine::FindSnapshot (INPTR BSTR aName, ISnapshot **aSnapshot) { if (!aName) return E_INVALIDARG; if (!aSnapshot) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); ComObjPtr snapshot; HRESULT rc = findSnapshot (aName, snapshot, true /* aSetError */); snapshot.queryInterfaceTo (aSnapshot); return rc; } STDMETHODIMP Machine::SetCurrentSnapshot (INPTR GUIDPARAM aId) { /// @todo (dmik) don't forget to set // mData->mCurrentStateModified to FALSE return setError (E_NOTIMPL, "Not implemented"); } STDMETHODIMP Machine::CreateSharedFolder (INPTR BSTR aName, INPTR BSTR aHostPath, BOOL aWritable) { if (!aName || !aHostPath) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); ComObjPtr sharedFolder; rc = findSharedFolder (aName, sharedFolder, false /* aSetError */); if (SUCCEEDED (rc)) return setError (E_FAIL, tr ("Shared folder named '%ls' already exists"), aName); sharedFolder.createObject(); rc = sharedFolder->init (machine(), aName, aHostPath, aWritable); CheckComRCReturnRC (rc); BOOL accessible = FALSE; rc = sharedFolder->COMGETTER(Accessible) (&accessible); CheckComRCReturnRC (rc); if (!accessible) return setWarning (E_FAIL, tr ("Shared folder host path '%ls' is not accessible"), aHostPath); mHWData.backup(); mHWData->mSharedFolders.push_back (sharedFolder); /* inform the direct session if any */ alock.leave(); onSharedFolderChange(); return S_OK; } STDMETHODIMP Machine::RemoveSharedFolder (INPTR BSTR aName) { if (!aName) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); ComObjPtr sharedFolder; rc = findSharedFolder (aName, sharedFolder, true /* aSetError */); CheckComRCReturnRC (rc); mHWData.backup(); mHWData->mSharedFolders.remove (sharedFolder); /* inform the direct session if any */ alock.leave(); onSharedFolderChange(); return S_OK; } STDMETHODIMP Machine::CanShowConsoleWindow (BOOL *aCanShow) { if (!aCanShow) return E_POINTER; /* start with No */ *aCanShow = FALSE; AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); if (mData->mSession.mState != SessionState_Open) return setError (E_FAIL, tr ("Machine session is not open (session state: %d)"), mData->mSession.mState); directControl = mData->mSession.mDirectControl; } /* ignore calls made after #OnSessionEnd() is called */ if (!directControl) return S_OK; ULONG64 dummy; return directControl->OnShowWindow (TRUE /* aCheck */, aCanShow, &dummy); } STDMETHODIMP Machine::ShowConsoleWindow (ULONG64 *aWinId) { if (!aWinId) return E_POINTER; AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); if (mData->mSession.mState != SessionState_Open) return setError (E_FAIL, tr ("Machine session is not open (session state: %d)"), mData->mSession.mState); directControl = mData->mSession.mDirectControl; } /* ignore calls made after #OnSessionEnd() is called */ if (!directControl) return S_OK; BOOL dummy; return directControl->OnShowWindow (FALSE /* aCheck */, &dummy, aWinId); } STDMETHODIMP Machine::GetGuestProperty (INPTR BSTR aName, BSTR *aValue, ULONG64 *aTimestamp, BSTR *aFlags) { #if !defined (VBOX_WITH_GUEST_PROPS) return E_NOTIMPL; #else if (!VALID_PTR (aName)) return E_INVALIDARG; if (!VALID_PTR (aValue)) return E_POINTER; if (!VALID_PTR (aTimestamp)) return E_POINTER; if (!VALID_PTR (aFlags)) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); using namespace guestProp; HRESULT rc = E_FAIL; if (!mHWData->mPropertyServiceActive) { bool found = false; for (HWData::GuestPropertyList::const_iterator it = mHWData->mGuestProperties.begin(); (it != mHWData->mGuestProperties.end()) && !found; ++it) { if (it->mName == aName) { char szFlags[MAX_FLAGS_LEN + 1]; it->mValue.cloneTo(aValue); *aTimestamp = it->mTimestamp; writeFlags(it->mFlags, szFlags); Bstr(szFlags).cloneTo(aFlags); found = true; } } rc = S_OK; } else { ComPtr directControl = mData->mSession.mDirectControl; /* just be on the safe side when calling another process */ alock.unlock(); rc = directControl->AccessGuestProperty (aName, NULL, NULL, false /* isSetter */, aValue, aTimestamp, aFlags); } return rc; #endif /* else !defined (VBOX_WITH_GUEST_PROPS) */ } STDMETHODIMP Machine::GetGuestPropertyValue (INPTR BSTR aName, BSTR *aValue) { ULONG64 dummyTimestamp; BSTR dummyFlags; return GetGuestProperty(aName, aValue, &dummyTimestamp, &dummyFlags); } STDMETHODIMP Machine::GetGuestPropertyTimestamp (INPTR BSTR aName, ULONG64 *aTimestamp) { BSTR dummyValue; BSTR dummyFlags; return GetGuestProperty(aName, &dummyValue, aTimestamp, &dummyFlags); } STDMETHODIMP Machine::SetGuestProperty (INPTR BSTR aName, INPTR BSTR aValue, INPTR BSTR aFlags) { #if !defined (VBOX_WITH_GUEST_PROPS) return E_NOTIMPL; #else using namespace guestProp; if (!VALID_PTR (aName)) return E_INVALIDARG; if ((aValue != NULL) && !VALID_PTR (aValue)) return E_INVALIDARG; if ((aFlags != NULL) && !VALID_PTR (aFlags)) return E_INVALIDARG; Utf8Str utf8Name(aName); Utf8Str utf8Flags(aFlags); Utf8Str utf8Patterns(mHWData->mGuestPropertyNotificationPatterns); if ( utf8Name.isNull() || ((aFlags != NULL) && utf8Flags.isNull()) || utf8Patterns.isNull() ) return E_OUTOFMEMORY; bool matchAll = false; if (0 == utf8Patterns.length()) matchAll = true; uint32_t fFlags = NILFLAG; if ((aFlags != NULL) && RT_FAILURE (validateFlags (utf8Flags.raw(), &fFlags)) ) return setError (E_INVALIDARG, tr ("Invalid flag values: '%ls'"), aFlags); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); rc = S_OK; if (!mHWData->mPropertyServiceActive) { bool found = false; HWData::GuestProperty property; property.mFlags = NILFLAG; if (fFlags & TRANSIENT) rc = setError (E_INVALIDARG, tr ("Cannot set a transient property when the machine is not running")); if (SUCCEEDED (rc)) { for (HWData::GuestPropertyList::iterator it = mHWData->mGuestProperties.begin(); (it != mHWData->mGuestProperties.end()) && !found; ++it) if (it->mName == aName) { property = *it; if (it->mFlags & (RDONLYHOST)) rc = setError (E_ACCESSDENIED, tr ("The property '%ls' cannot be changed by the host"), aName); else { mHWData.backup(); /* The backup() operation invalidates our iterator, so get a * new one. */ for (it = mHWData->mGuestProperties.begin(); it->mName != aName; ++it) ; mHWData->mGuestProperties.erase(it); } found = true; } } if (found && SUCCEEDED (rc)) { if (aValue != NULL) { RTTIMESPEC time; property.mValue = aValue; property.mTimestamp = RTTimeSpecGetNano(RTTimeNow(&time)); if (aFlags != NULL) property.mFlags = fFlags; mHWData->mGuestProperties.push_back(property); } } else if (SUCCEEDED (rc) && (aValue != NULL)) { RTTIMESPEC time; mHWData.backup(); property.mName = aName; property.mValue = aValue; property.mTimestamp = RTTimeSpecGetNano(RTTimeNow(&time)); property.mFlags = fFlags; mHWData->mGuestProperties.push_back(property); } } else { ComPtr directControl = mData->mSession.mDirectControl; /* just be on the safe side when calling another process */ alock.leave(); BSTR dummy = NULL; ULONG64 dummy64; rc = directControl->AccessGuestProperty (aName, aValue, aFlags, true /* isSetter */, &dummy, &dummy64, &dummy); } if ( SUCCEEDED (rc) && ( matchAll || RTStrSimplePatternMultiMatch (utf8Patterns.raw(), RTSTR_MAX, utf8Name.raw(), RTSTR_MAX, NULL) ) ) mParent->onGuestPropertyChange (mData->mUuid, aName, aValue, aFlags); return rc; #endif /* else !defined (VBOX_WITH_GUEST_PROPS) */ } STDMETHODIMP Machine::SetGuestPropertyValue (INPTR BSTR aName, INPTR BSTR aValue) { return SetGuestProperty(aName, aValue, NULL); } STDMETHODIMP Machine::EnumerateGuestProperties (INPTR BSTR aPatterns, ComSafeArrayOut(BSTR, aNames), ComSafeArrayOut(BSTR, aValues), ComSafeArrayOut(ULONG64, aTimestamps), ComSafeArrayOut(BSTR, aFlags)) { #if !defined (VBOX_WITH_GUEST_PROPS) return E_NOTIMPL; #else if (!VALID_PTR (aPatterns) && (aPatterns != NULL)) return E_POINTER; if (ComSafeArrayOutIsNull (aNames)) return E_POINTER; if (ComSafeArrayOutIsNull (aValues)) return E_POINTER; if (ComSafeArrayOutIsNull (aTimestamps)) return E_POINTER; if (ComSafeArrayOutIsNull (aFlags)) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); using namespace guestProp; HRESULT rc = E_FAIL; bool matchAll = false; if ((NULL == aPatterns) || (0 == aPatterns[0])) matchAll = true; if (!mHWData->mPropertyServiceActive) { /* * Look for matching patterns and build up a list. */ HWData::GuestPropertyList propList; for (HWData::GuestPropertyList::iterator it = mHWData->mGuestProperties.begin(); it != mHWData->mGuestProperties.end(); ++it) if ( matchAll || RTStrSimplePatternMultiMatch (Utf8Str(aPatterns).raw(), RTSTR_MAX, Utf8Str(it->mName).raw(), RTSTR_MAX, NULL) ) propList.push_back(*it); /* * And build up the arrays for returning the property information. */ size_t cEntries = propList.size(); SafeArray names(cEntries); SafeArray values(cEntries); SafeArray timestamps(cEntries); SafeArray flags(cEntries); size_t iProp = 0; for (HWData::GuestPropertyList::iterator it = propList.begin(); it != propList.end(); ++it) { char szFlags[MAX_FLAGS_LEN + 1]; it->mName.cloneTo(&names[iProp]); it->mValue.cloneTo(&values[iProp]); timestamps[iProp] = it->mTimestamp; writeFlags(it->mFlags, szFlags); Bstr(szFlags).cloneTo(&flags[iProp]); ++iProp; } names.detachTo(ComSafeArrayOutArg (aNames)); values.detachTo(ComSafeArrayOutArg (aValues)); timestamps.detachTo(ComSafeArrayOutArg (aTimestamps)); flags.detachTo(ComSafeArrayOutArg (aFlags)); rc = S_OK; } else { ComPtr directControl = mData->mSession.mDirectControl; /* just be on the safe side when calling another process */ alock.unlock(); rc = directControl->EnumerateGuestProperties(aPatterns, ComSafeArrayOutArg(aNames), ComSafeArrayOutArg(aValues), ComSafeArrayOutArg(aTimestamps), ComSafeArrayOutArg(aFlags)); } return rc; #endif /* else !defined (VBOX_WITH_GUEST_PROPS) */ } // public methods for internal purposes ///////////////////////////////////////////////////////////////////////////// /** * Saves the registry entry of this machine to the given configuration node. * * @param aEntryNode Node to save the registry entry to. * * @note locks this object for reading. */ HRESULT Machine::saveRegistryEntry (settings::Key &aEntryNode) { AssertReturn (!aEntryNode.isNull(), E_FAIL); AutoLimitedCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoReadLock alock (this); /* UUID */ aEntryNode.setValue ("uuid", mData->mUuid); /* settings file name (possibly, relative) */ aEntryNode.setValue ("src", mData->mConfigFile); return S_OK; } /** * Calculates the absolute path of the given path taking the directory of the * machine settings file as the current directory. * * @param aPath Path to calculate the absolute path for. * @param aResult Where to put the result (used only on success, can be the * same Utf8Str instance as passed in @a aPath). * @return IPRT result. * * @note Locks this object for reading. */ int Machine::calculateFullPath (const char *aPath, Utf8Str &aResult) { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoReadLock alock (this); AssertReturn (!mData->mConfigFileFull.isNull(), VERR_GENERAL_FAILURE); Utf8Str settingsDir = mData->mConfigFileFull; RTPathStripFilename (settingsDir.mutableRaw()); char folder [RTPATH_MAX]; int vrc = RTPathAbsEx (settingsDir, aPath, folder, sizeof (folder)); if (VBOX_SUCCESS (vrc)) aResult = folder; return vrc; } /** * Tries to calculate the relative path of the given absolute path using the * directory of the machine settings file as the base directory. * * @param aPath Absolute path to calculate the relative path for. * @param aResult Where to put the result (used only when it's possible to * make a relative path from the given absolute path; otherwise * left untouched). * * @note Locks this object for reading. */ void Machine::calculateRelativePath (const char *aPath, Utf8Str &aResult) { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), (void) 0); AutoReadLock alock (this); AssertReturnVoid (!mData->mConfigFileFull.isNull()); Utf8Str settingsDir = mData->mConfigFileFull; RTPathStripFilename (settingsDir.mutableRaw()); if (RTPathStartsWith (aPath, settingsDir)) { /* when assigning, we create a separate Utf8Str instance because both * aPath and aResult can point to the same memory location when this * func is called (if we just do aResult = aPath, aResult will be freed * first, and since its the same as aPath, an attempt to copy garbage * will be made. */ aResult = Utf8Str (aPath + settingsDir.length() + 1); } } /** * Returns the full path to the machine's log folder in the * \a aLogFolder argument. */ void Machine::getLogFolder (Utf8Str &aLogFolder) { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoReadLock alock (this); Utf8Str settingsDir; if (isInOwnDir (&settingsDir)) { /* Log folder is //Logs */ aLogFolder = Utf8StrFmt ("%s%cLogs", settingsDir.raw(), RTPATH_DELIMITER); } else { /* Log folder is //Logs */ Assert (!mUserData->mSnapshotFolderFull.isEmpty()); aLogFolder = Utf8StrFmt ("%ls%cLogs", mUserData->mSnapshotFolderFull.raw(), RTPATH_DELIMITER); } } /** * @note Locks this object for writing, calls the client process (outside the * lock). */ HRESULT Machine::openSession (IInternalSessionControl *aControl) { LogFlowThisFuncEnter(); AssertReturn (aControl, E_FAIL); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); if (!mData->mRegistered) return setError (E_UNEXPECTED, tr ("The machine '%ls' is not registered"), mUserData->mName.raw()); LogFlowThisFunc (("mSession.mState=%d\n", mData->mSession.mState)); if (mData->mSession.mState == SessionState_Open || mData->mSession.mState == SessionState_Closing) return setError (E_ACCESSDENIED, tr ("A session for the machine '%ls' is currently open " "(or being closed)"), mUserData->mName.raw()); /* may not be Running */ AssertReturn (mData->mMachineState < MachineState_Running, E_FAIL); /* get the sesion PID */ RTPROCESS pid = NIL_RTPROCESS; AssertCompile (sizeof (ULONG) == sizeof (RTPROCESS)); aControl->GetPID ((ULONG *) &pid); Assert (pid != NIL_RTPROCESS); if (mData->mSession.mState == SessionState_Spawning) { /* This machine is awaiting for a spawning session to be opened, so * reject any other open attempts from processes other than one * started by #openRemoteSession(). */ LogFlowThisFunc (("mSession.mPid=%d(0x%x)\n", mData->mSession.mPid, mData->mSession.mPid)); LogFlowThisFunc (("session.pid=%d(0x%x)\n", pid, pid)); if (mData->mSession.mPid != pid) return setError (E_ACCESSDENIED, tr ("An unexpected process (PID=0x%08X) has tried to open a direct " "session with the machine named '%ls', while only a process " "started by OpenRemoteSession (PID=0x%08X) is allowed"), pid, mUserData->mName.raw(), mData->mSession.mPid); } /* create a SessionMachine object */ ComObjPtr sessionMachine; sessionMachine.createObject(); HRESULT rc = sessionMachine->init (this); AssertComRC (rc); if (SUCCEEDED (rc)) { #ifdef VBOX_WITH_RESOURCE_USAGE_API registerMetrics (mParent->performanceCollector(), this, pid); #endif /* VBOX_WITH_RESOURCE_USAGE_API */ /* * Set the session state to Spawning to protect against subsequent * attempts to open a session and to unregister the machine after * we leave the lock. */ SessionState_T origState = mData->mSession.mState; mData->mSession.mState = SessionState_Spawning; /* * Leave the lock before calling the client process -- it will call * Machine/SessionMachine methods. Leaving the lock here is quite safe * because the state is Spawning, so that openRemotesession() and * openExistingSession() calls will fail. This method, called before we * enter the lock again, will fail because of the wrong PID. * * Note that mData->mSession.mRemoteControls accessed outside * the lock may not be modified when state is Spawning, so it's safe. */ alock.leave(); LogFlowThisFunc (("Calling AssignMachine()...\n")); rc = aControl->AssignMachine (sessionMachine); LogFlowThisFunc (("AssignMachine() returned %08X\n", rc)); /* The failure may w/o any error info (from RPC), so provide one */ if (FAILED (rc)) setError (rc, tr ("Failed to assign the machine to the session")); if (SUCCEEDED (rc) && origState == SessionState_Spawning) { /* complete the remote session initialization */ /* get the console from the direct session */ ComPtr console; rc = aControl->GetRemoteConsole (console.asOutParam()); ComAssertComRC (rc); if (SUCCEEDED (rc) && !console) { ComAssert (!!console); rc = E_FAIL; } /* assign machine & console to the remote sesion */ if (SUCCEEDED (rc)) { /* * after openRemoteSession(), the first and the only * entry in remoteControls is that remote session */ LogFlowThisFunc (("Calling AssignRemoteMachine()...\n")); rc = mData->mSession.mRemoteControls.front()-> AssignRemoteMachine (sessionMachine, console); LogFlowThisFunc (("AssignRemoteMachine() returned %08X\n", rc)); /* The failure may w/o any error info (from RPC), so provide one */ if (FAILED (rc)) setError (rc, tr ("Failed to assign the machine to the remote session")); } if (FAILED (rc)) aControl->Uninitialize(); } /* enter the lock again */ alock.enter(); /* Restore the session state */ mData->mSession.mState = origState; } /* finalize spawning amyway (this is why we don't return on errors above) */ if (mData->mSession.mState == SessionState_Spawning) { /* Note that the progress object is finalized later */ /* We don't reset mSession.mPid here because it is necessary for * SessionMachine::uninit() to reap the child process later. */ if (FAILED (rc)) { /* Close the remote session, remove the remote control from the list * and reset session state to Closed (@note keep the code in sync * with the relevant part in openSession()). */ Assert (mData->mSession.mRemoteControls.size() == 1); if (mData->mSession.mRemoteControls.size() == 1) { ErrorInfoKeeper eik; mData->mSession.mRemoteControls.front()->Uninitialize(); } mData->mSession.mRemoteControls.clear(); mData->mSession.mState = SessionState_Closed; } } else { /* memorize PID of the directly opened session */ if (SUCCEEDED (rc)) mData->mSession.mPid = pid; } if (SUCCEEDED (rc)) { /* memorize the direct session control and cache IUnknown for it */ mData->mSession.mDirectControl = aControl; mData->mSession.mState = SessionState_Open; /* associate the SessionMachine with this Machine */ mData->mSession.mMachine = sessionMachine; /* request an IUnknown pointer early from the remote party for later * identity checks (it will be internally cached within mDirectControl * at least on XPCOM) */ ComPtr unk = mData->mSession.mDirectControl; NOREF (unk); } if (mData->mSession.mProgress) { /* finalize the progress after setting the state, for consistency */ mData->mSession.mProgress->notifyComplete (rc); mData->mSession.mProgress.setNull(); } /* uninitialize the created session machine on failure */ if (FAILED (rc)) sessionMachine->uninit(); LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } /** * @note Locks this object for writing, calls the client process * (inside the lock). */ HRESULT Machine::openRemoteSession (IInternalSessionControl *aControl, INPTR BSTR aType, INPTR BSTR aEnvironment, Progress *aProgress) { LogFlowThisFuncEnter(); AssertReturn (aControl, E_FAIL); AssertReturn (aProgress, E_FAIL); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); if (!mData->mRegistered) return setError (E_UNEXPECTED, tr ("The machine '%ls' is not registered"), mUserData->mName.raw()); LogFlowThisFunc (("mSession.mState=%d\n", mData->mSession.mState)); if (mData->mSession.mState == SessionState_Open || mData->mSession.mState == SessionState_Spawning || mData->mSession.mState == SessionState_Closing) return setError (E_ACCESSDENIED, tr ("A session for the machine '%ls' is currently open " "(or being opened or closed)"), mUserData->mName.raw()); /* may not be Running */ AssertReturn (mData->mMachineState < MachineState_Running, E_FAIL); /* get the path to the executable */ char path [RTPATH_MAX]; RTPathAppPrivateArch (path, RTPATH_MAX); size_t sz = strlen (path); path [sz++] = RTPATH_DELIMITER; path [sz] = 0; char *cmd = path + sz; sz = RTPATH_MAX - sz; int vrc = VINF_SUCCESS; RTPROCESS pid = NIL_RTPROCESS; RTENV env = RTENV_DEFAULT; if (aEnvironment) { char *newEnvStr = NULL; do { /* clone the current environment */ int vrc2 = RTEnvClone (&env, RTENV_DEFAULT); AssertRCBreakStmt (vrc2, vrc = vrc2); newEnvStr = RTStrDup(Utf8Str (aEnvironment)); AssertPtrBreakStmt (newEnvStr, vrc = vrc2); /* put new variables to the environment * (ignore empty variable names here since RTEnv API * intentionally doesn't do that) */ char *var = newEnvStr; for (char *p = newEnvStr; *p; ++ p) { if (*p == '\n' && (p == newEnvStr || *(p - 1) != '\\')) { *p = '\0'; if (*var) { char *val = strchr (var, '='); if (val) { *val++ = '\0'; vrc2 = RTEnvSetEx (env, var, val); } else vrc2 = RTEnvUnsetEx (env, var); if (VBOX_FAILURE (vrc2)) break; } var = p + 1; } } if (VBOX_SUCCESS (vrc2) && *var) vrc2 = RTEnvPutEx (env, var); AssertRCBreakStmt (vrc2, vrc = vrc2); } while (0); if (newEnvStr != NULL) RTStrFree(newEnvStr); } Bstr type (aType); /* Qt4 is default */ #ifdef VBOX_WITH_QT4GUI if (type == "gui" || type == "GUI/Qt4") { # ifdef RT_OS_DARWIN /* Avoid Lanuch Services confusing this with the selector by using a helper app. */ const char VirtualBox_exe[] = "../Resources/VirtualBoxVM.app/Contents/MacOS/VirtualBoxVM"; # else const char VirtualBox_exe[] = "VirtualBox" HOSTSUFF_EXE; # endif Assert (sz >= sizeof (VirtualBox_exe)); strcpy (cmd, VirtualBox_exe); Utf8Str idStr = mData->mUuid.toString(); # ifdef RT_OS_WINDOWS /** @todo drop this once the RTProcCreate bug has been fixed */ const char * args[] = {path, "-startvm", idStr, 0 }; # else Utf8Str name = mUserData->mName; const char * args[] = {path, "-comment", name, "-startvm", idStr, 0 }; # endif vrc = RTProcCreate (path, args, env, 0, &pid); } #else /* !VBOX_WITH_QT4GUI */ if (0) ; #endif /* VBOX_WITH_QT4GUI */ else /* Qt3 is used sometimes as well, OS/2 does not have Qt4 at all */ #ifdef VBOX_WITH_QTGUI if (type == "gui" || type == "GUI/Qt3") { # ifdef RT_OS_DARWIN /* Avoid Lanuch Services confusing this with the selector by using a helper app. */ const char VirtualBox_exe[] = "../Resources/VirtualBoxVM.app/Contents/MacOS/VirtualBoxVM3"; # else const char VirtualBox_exe[] = "VirtualBox3" HOSTSUFF_EXE; # endif Assert (sz >= sizeof (VirtualBox_exe)); strcpy (cmd, VirtualBox_exe); Utf8Str idStr = mData->mUuid.toString(); # ifdef RT_OS_WINDOWS /** @todo drop this once the RTProcCreate bug has been fixed */ const char * args[] = {path, "-startvm", idStr, 0 }; # else Utf8Str name = mUserData->mName; const char * args[] = {path, "-comment", name, "-startvm", idStr, 0 }; # endif vrc = RTProcCreate (path, args, env, 0, &pid); } #else /* !VBOX_WITH_QTGUI */ if (0) ; #endif /* !VBOX_WITH_QTGUI */ else #ifdef VBOX_WITH_VRDP if (type == "vrdp") { const char VBoxVRDP_exe[] = "VBoxHeadless" HOSTSUFF_EXE; Assert (sz >= sizeof (VBoxVRDP_exe)); strcpy (cmd, VBoxVRDP_exe); Utf8Str idStr = mData->mUuid.toString(); # ifdef RT_OS_WINDOWS const char * args[] = {path, "-startvm", idStr, 0 }; # else Utf8Str name = mUserData->mName; const char * args[] = {path, "-comment", name, "-startvm", idStr, 0 }; # endif vrc = RTProcCreate (path, args, env, 0, &pid); } #else /* !VBOX_WITH_VRDP */ if (0) ; #endif /* !VBOX_WITH_VRDP */ else #ifdef VBOX_WITH_HEADLESS if (type == "capture") { const char VBoxVRDP_exe[] = "VBoxHeadless" HOSTSUFF_EXE; Assert (sz >= sizeof (VBoxVRDP_exe)); strcpy (cmd, VBoxVRDP_exe); Utf8Str idStr = mData->mUuid.toString(); # ifdef RT_OS_WINDOWS const char * args[] = {path, "-startvm", idStr, "-capture", 0 }; # else Utf8Str name = mUserData->mName; const char * args[] = {path, "-comment", name, "-startvm", idStr, "-capture", 0 }; # endif vrc = RTProcCreate (path, args, env, 0, &pid); } #else /* !VBOX_WITH_HEADLESS */ if (0) ; #endif /* !VBOX_WITH_HEADLESS */ else { RTEnvDestroy (env); return setError (E_INVALIDARG, tr ("Invalid session type: '%ls'"), aType); } RTEnvDestroy (env); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("Could not launch a process for the machine '%ls' (%Vrc)"), mUserData->mName.raw(), vrc); LogFlowThisFunc (("launched.pid=%d(0x%x)\n", pid, pid)); /* * Note that we don't leave the lock here before calling the client, * because it doesn't need to call us back if called with a NULL argument. * Leaving the lock herer is dangerous because we didn't prepare the * launch data yet, but the client we've just started may happen to be * too fast and call openSession() that will fail (because of PID, etc.), * so that the Machine will never get out of the Spawning session state. */ /* inform the session that it will be a remote one */ LogFlowThisFunc (("Calling AssignMachine (NULL)...\n")); HRESULT rc = aControl->AssignMachine (NULL); LogFlowThisFunc (("AssignMachine (NULL) returned %08X\n", rc)); if (FAILED (rc)) { /* restore the session state */ mData->mSession.mState = SessionState_Closed; /* The failure may w/o any error info (from RPC), so provide one */ return setError (rc, tr ("Failed to assign the machine to the session")); } /* attach launch data to the machine */ Assert (mData->mSession.mPid == NIL_RTPROCESS); mData->mSession.mRemoteControls.push_back (aControl); mData->mSession.mProgress = aProgress; mData->mSession.mPid = pid; mData->mSession.mState = SessionState_Spawning; mData->mSession.mType = type; LogFlowThisFuncLeave(); return S_OK; } /** * @note Locks this object for writing, calls the client process * (outside the lock). */ HRESULT Machine::openExistingSession (IInternalSessionControl *aControl) { LogFlowThisFuncEnter(); AssertReturn (aControl, E_FAIL); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); if (!mData->mRegistered) return setError (E_UNEXPECTED, tr ("The machine '%ls' is not registered"), mUserData->mName.raw()); LogFlowThisFunc (("mSession.state=%d\n", mData->mSession.mState)); if (mData->mSession.mState != SessionState_Open) return setError (E_ACCESSDENIED, tr ("The machine '%ls' does not have an open session"), mUserData->mName.raw()); ComAssertRet (!mData->mSession.mDirectControl.isNull(), E_FAIL); /* * Get the console from the direct session (note that we don't leave the * lock here because GetRemoteConsole must not call us back). */ ComPtr console; HRESULT rc = mData->mSession.mDirectControl-> GetRemoteConsole (console.asOutParam()); if (FAILED (rc)) { /* The failure may w/o any error info (from RPC), so provide one */ return setError (rc, tr ("Failed to get a console object from the direct session")); } ComAssertRet (!console.isNull(), E_FAIL); ComObjPtr sessionMachine = mData->mSession.mMachine; AssertReturn (!sessionMachine.isNull(), E_FAIL); /* * Leave the lock before calling the client process. It's safe here * since the only thing to do after we get the lock again is to add * the remote control to the list (which doesn't directly influence * anything). */ alock.leave(); /* attach the remote session to the machine */ LogFlowThisFunc (("Calling AssignRemoteMachine()...\n")); rc = aControl->AssignRemoteMachine (sessionMachine, console); LogFlowThisFunc (("AssignRemoteMachine() returned %08X\n", rc)); /* The failure may w/o any error info (from RPC), so provide one */ if (FAILED (rc)) return setError (rc, tr ("Failed to assign the machine to the session")); alock.enter(); /* need to revalidate the state after entering the lock again */ if (mData->mSession.mState != SessionState_Open) { aControl->Uninitialize(); return setError (E_ACCESSDENIED, tr ("The machine '%ls' does not have an open session"), mUserData->mName.raw()); } /* store the control in the list */ mData->mSession.mRemoteControls.push_back (aControl); LogFlowThisFuncLeave(); return S_OK; } /** * Returns @c true if the given machine has an open direct session and returns * the session machine instance and additional session data (on some platforms) * if so. * * Note that when the method returns @c false, the arguments remain unchanged. * * @param aMachine Session machine object. * @param aControl Direct session control object (optional). * @param aIPCSem Mutex IPC semaphore handle for this machine (optional). * * @note locks this object for reading. */ #if defined (RT_OS_WINDOWS) bool Machine::isSessionOpen (ComObjPtr &aMachine, ComPtr *aControl /*= NULL*/, HANDLE *aIPCSem /*= NULL*/, bool aAllowClosing /*= false*/) #elif defined (RT_OS_OS2) bool Machine::isSessionOpen (ComObjPtr &aMachine, ComPtr *aControl /*= NULL*/, HMTX *aIPCSem /*= NULL*/, bool aAllowClosing /*= false*/); #else bool Machine::isSessionOpen (ComObjPtr &aMachine, ComPtr *aControl /*= NULL*/, bool aAllowClosing /*= false*/) #endif { AutoLimitedCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), false); /* just return false for inaccessible machines */ if (autoCaller.state() != Ready) return false; AutoReadLock alock (this); if (mData->mSession.mState == SessionState_Open || (aAllowClosing && mData->mSession.mState == SessionState_Closing)) { AssertReturn (!mData->mSession.mMachine.isNull(), false); aMachine = mData->mSession.mMachine; if (aControl != NULL) *aControl = mData->mSession.mDirectControl; #if defined (RT_OS_WINDOWS) || defined (RT_OS_OS2) /* Additional session data */ if (aIPCSem != NULL) *aIPCSem = aMachine->mIPCSem; #endif return true; } return false; } /** * Returns @c true if the given machine has an spawning direct session and * returns and additional session data (on some platforms) if so. * * Note that when the method returns @c false, the arguments remain unchanged. * * @param aPID PID of the spawned direct session process. * * @note locks this object for reading. */ #if defined (RT_OS_WINDOWS) || defined (RT_OS_OS2) bool Machine::isSessionSpawning (RTPROCESS *aPID /*= NULL*/) #else bool Machine::isSessionSpawning() #endif { AutoLimitedCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), false); /* just return false for inaccessible machines */ if (autoCaller.state() != Ready) return false; AutoReadLock alock (this); if (mData->mSession.mState == SessionState_Spawning) { #if defined (RT_OS_WINDOWS) || defined (RT_OS_OS2) /* Additional session data */ if (aPID != NULL) { AssertReturn (mData->mSession.mPid != NIL_RTPROCESS, false); *aPID = mData->mSession.mPid; } #endif return true; } return false; } /** * Called from the client watcher thread to check for unexpected client process * death during Session_Spawning state (e.g. before it successfully opened a * direct session). * * On Win32 and on OS/2, this method is called only when we've got the * direct client's process termination notification, so it always returns @c * true. * * On other platforms, this method returns @c true if the client process is * terminated and @c false if it's still alive. * * @note Locks this object for writing. */ bool Machine::checkForSpawnFailure() { AutoCaller autoCaller (this); if (!autoCaller.isOk()) { /* nothing to do */ LogFlowThisFunc (("Already uninitialized!")); return true; } /* VirtualBox::addProcessToReap() needs a write lock */ AutoMultiWriteLock2 alock (mParent, this); if (mData->mSession.mState != SessionState_Spawning) { /* nothing to do */ LogFlowThisFunc (("Not spawning any more!")); return true; } HRESULT rc = S_OK; #if defined (RT_OS_WINDOWS) || defined (RT_OS_OS2) /* the process was already unexpectedly terminated, we just need to set an * error and finalize session spawning */ rc = setError (E_FAIL, tr ("Virtual machine '%ls' has terminated unexpectedly " "during startup"), name().raw()); #else RTPROCSTATUS status; int vrc = ::RTProcWait (mData->mSession.mPid, RTPROCWAIT_FLAGS_NOBLOCK, &status); if (vrc != VERR_PROCESS_RUNNING) rc = setError (E_FAIL, tr ("Virtual machine '%ls' has terminated unexpectedly " "during startup"), name().raw()); #endif if (FAILED (rc)) { /* Close the remote session, remove the remote control from the list * and reset session state to Closed (@note keep the code in sync with * the relevant part in checkForSpawnFailure()). */ Assert (mData->mSession.mRemoteControls.size() == 1); if (mData->mSession.mRemoteControls.size() == 1) { ErrorInfoKeeper eik; mData->mSession.mRemoteControls.front()->Uninitialize(); } mData->mSession.mRemoteControls.clear(); mData->mSession.mState = SessionState_Closed; /* finalize the progress after setting the state, for consistency */ mData->mSession.mProgress->notifyComplete (rc); mData->mSession.mProgress.setNull(); mParent->addProcessToReap (mData->mSession.mPid); mData->mSession.mPid = NIL_RTPROCESS; mParent->onSessionStateChange (mData->mUuid, SessionState_Closed); return true; } return false; } /** * Checks that the registered flag of the machine can be set according to * the argument and sets it. On success, commits and saves all settings. * * @note When this machine is inaccessible, the only valid value for \a * aRegistered is FALSE (i.e. unregister the machine) because unregistered * inaccessible machines are not currently supported. Note that unregistering * an inaccessible machine will \b uninitialize this machine object. Therefore, * the caller must make sure there are no active Machine::addCaller() calls * on the current thread because this will block Machine::uninit(). * * @note Must be called from mParent's write lock. Locks this object and * children for writing. */ HRESULT Machine::trySetRegistered (BOOL aRegistered) { AssertReturn (mParent->isWriteLockOnCurrentThread(), E_FAIL); AutoLimitedCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); /* wait for state dependants to drop to zero */ ensureNoStateDependencies(); ComAssertRet (mData->mRegistered != aRegistered, E_FAIL); if (!mData->mAccessible) { /* A special case: the machine is not accessible. */ /* inaccessible machines can only be unregistered */ AssertReturn (!aRegistered, E_FAIL); /* Uninitialize ourselves here because currently there may be no * unregistered that are inaccessible (this state combination is not * supported). Note releasing the caller and leaving the lock before * calling uninit() */ alock.leave(); autoCaller.release(); uninit(); return S_OK; } AssertReturn (autoCaller.state() == Ready, E_FAIL); if (aRegistered) { if (mData->mRegistered) return setError (E_FAIL, tr ("The machine '%ls' with UUID {%s} is already registered"), mUserData->mName.raw(), mData->mUuid.toString().raw()); } else { if (mData->mMachineState == MachineState_Saved) return setError (E_FAIL, tr ("Cannot unregister the machine '%ls' because it " "is in the Saved state"), mUserData->mName.raw()); size_t snapshotCount = 0; if (mData->mFirstSnapshot) snapshotCount = mData->mFirstSnapshot->descendantCount() + 1; if (snapshotCount) return setError (E_FAIL, tr ("Cannot unregister the machine '%ls' because it " "has %d snapshots"), mUserData->mName.raw(), snapshotCount); if (mData->mSession.mState != SessionState_Closed) return setError (E_FAIL, tr ("Cannot unregister the machine '%ls' because it has an " "open session"), mUserData->mName.raw()); if (mHDData->mAttachments.size() != 0) return setError (E_FAIL, tr ("Cannot unregister the machine '%ls' because it " "has %d hard disks attached"), mUserData->mName.raw(), mHDData->mAttachments.size()); } /* Ensure the settings are saved. If we are going to be registered and * isConfigLocked() is FALSE then it means that no config file exists yet, * so create it. */ if (isModified() || (aRegistered && !isConfigLocked())) { HRESULT rc = saveSettings(); CheckComRCReturnRC (rc); } mData->mRegistered = aRegistered; /* inform the USB proxy about all attached/detached USB filters */ mUSBController->onMachineRegistered (aRegistered); return S_OK; } /** * Increases the number of objects dependent on the machine state or on the * registered state. Guarantees that these two states will not change at least * until #releaseStateDependency() is called. * * Depending on the @a aDepType value, additional state checks may be made. * These checks will set extended error info on failure. See * #checkStateDependency() for more info. * * If this method returns a failure, the dependency is not added and the caller * is not allowed to rely on any particular machine state or registration state * value and may return the failed result code to the upper level. * * @param aDepType Dependency type to add. * @param aState Current machine state (NULL if not interested). * @param aRegistered Current registered state (NULL if not interested). * * @note Locks this object for writing. */ HRESULT Machine::addStateDependency (StateDependency aDepType /* = AnyStateDep */, MachineState_T *aState /* = NULL */, BOOL *aRegistered /* = NULL */) { AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (aDepType); CheckComRCReturnRC (rc); { if (mData->mMachineStateChangePending != 0) { /* ensureNoStateDependencies() is waiting for state dependencies to * drop to zero so don't add more. It may make sense to wait a bit * and retry before reporting an error (since the pending state * transition should be really quick) but let's just assert for * now to see if it ever happens on practice. */ AssertFailed(); return setError (E_ACCESSDENIED, tr ("Machine state change is in progress. " "Please retry the operation later.")); } ++ mData->mMachineStateDeps; Assert (mData->mMachineStateDeps != 0 /* overflow */); } if (aState) *aState = mData->mMachineState; if (aRegistered) *aRegistered = mData->mRegistered; return S_OK; } /** * Decreases the number of objects dependent on the machine state. * Must always complete the #addStateDependency() call after the state * dependency is no more necessary. */ void Machine::releaseStateDependency() { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoWriteLock alock (this); AssertReturnVoid (mData->mMachineStateDeps != 0 /* releaseStateDependency() w/o addStateDependency()? */); -- mData->mMachineStateDeps; if (mData->mMachineStateDeps == 0) { /* inform ensureNoStateDependencies() that there are no more deps */ if (mData->mMachineStateChangePending != 0) { Assert (mData->mMachineStateDepsSem != NIL_RTSEMEVENTMULTI); RTSemEventMultiSignal (mData->mMachineStateDepsSem); } } } // protected methods ///////////////////////////////////////////////////////////////////////////// /** * Performs machine state checks based on the @a aDepType value. If a check * fails, this method will set extended error info, otherwise it will return * S_OK. It is supposed, that on failure, the caller will immedieately return * the return value of this method to the upper level. * * When @a aDepType is AnyStateDep, this method always returns S_OK. * * When @a aDepType is MutableStateDep, this method returns S_OK only if the * current state of this machine object allows to change settings of the * machine (i.e. the machine is not registered, or registered but not running * and not saved). It is useful to call this method from Machine setters * before performing any change. * * When @a aDepType is MutableOrSavedStateDep, this method behaves the same * as for MutableStateDep except that if the machine is saved, S_OK is also * returned. This is useful in setters which allow changing machine * properties when it is in the saved state. * * @param aDepType Dependency type to check. * * @note Non Machine based classes should use #addStateDependency() and * #releaseStateDependency() methods or the smart AutoStateDependency * template. * * @note This method must be called from under this object's read or write * lock. */ HRESULT Machine::checkStateDependency (StateDependency aDepType) { switch (aDepType) { case AnyStateDep: { break; } case MutableStateDep: { if (mData->mRegistered && (mType != IsSessionMachine || mData->mMachineState > MachineState_Paused || mData->mMachineState == MachineState_Saved)) return setError (E_ACCESSDENIED, tr ("The machine is not mutable (state is %d)"), mData->mMachineState); break; } case MutableOrSavedStateDep: { if (mData->mRegistered && (mType != IsSessionMachine || mData->mMachineState > MachineState_Paused)) return setError (E_ACCESSDENIED, tr ("The machine is not mutable (state is %d)"), mData->mMachineState); break; } } return S_OK; } /** * Helper to initialize all associated child objects and allocate data * structures. * * This method must be called as a part of the object's initialization procedure * (usually done in the #init() method). * * @note Must be called only from #init() or from #registeredInit(). */ HRESULT Machine::initDataAndChildObjects() { AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AssertComRCReturn (autoCaller.state() == InInit || autoCaller.state() == Limited, E_FAIL); AssertReturn (!mData->mAccessible, E_FAIL); /* allocate data structures */ mSSData.allocate(); mUserData.allocate(); mHWData.allocate(); mHDData.allocate(); /* initialize mOSTypeId */ mUserData->mOSTypeId = mParent->getUnknownOSType()->id(); /* create associated BIOS settings object */ unconst (mBIOSSettings).createObject(); mBIOSSettings->init (this); #ifdef VBOX_WITH_VRDP /* create an associated VRDPServer object (default is disabled) */ unconst (mVRDPServer).createObject(); mVRDPServer->init (this); #endif /* create an associated DVD drive object */ unconst (mDVDDrive).createObject(); mDVDDrive->init (this); /* create an associated floppy drive object */ unconst (mFloppyDrive).createObject(); mFloppyDrive->init (this); /* create associated serial port objects */ for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) { unconst (mSerialPorts [slot]).createObject(); mSerialPorts [slot]->init (this, slot); } /* create associated parallel port objects */ for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) { unconst (mParallelPorts [slot]).createObject(); mParallelPorts [slot]->init (this, slot); } /* create the audio adapter object (always present, default is disabled) */ unconst (mAudioAdapter).createObject(); mAudioAdapter->init (this); /* create the USB controller object (always present, default is disabled) */ unconst (mUSBController).createObject(); mUSBController->init (this); /* create the SATA controller object (always present, default is disabled) */ unconst (mSATAController).createObject(); mSATAController->init (this); /* create associated network adapter objects */ for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) { unconst (mNetworkAdapters [slot]).createObject(); mNetworkAdapters [slot]->init (this, slot); } return S_OK; } /** * Helper to uninitialize all associated child objects and to free all data * structures. * * This method must be called as a part of the object's uninitialization * procedure (usually done in the #uninit() method). * * @note Must be called only from #uninit() or from #registeredInit(). */ void Machine::uninitDataAndChildObjects() { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AssertComRCReturnVoid (autoCaller.state() == InUninit || autoCaller.state() == Limited); /* uninit all children using addDependentChild()/removeDependentChild() * in their init()/uninit() methods */ uninitDependentChildren(); /* tell all our other child objects we've been uninitialized */ for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) { if (mNetworkAdapters [slot]) { mNetworkAdapters [slot]->uninit(); unconst (mNetworkAdapters [slot]).setNull(); } } if (mUSBController) { mUSBController->uninit(); unconst (mUSBController).setNull(); } if (mSATAController) { mSATAController->uninit(); unconst (mSATAController).setNull(); } if (mAudioAdapter) { mAudioAdapter->uninit(); unconst (mAudioAdapter).setNull(); } for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) { if (mParallelPorts [slot]) { mParallelPorts [slot]->uninit(); unconst (mParallelPorts [slot]).setNull(); } } for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) { if (mSerialPorts [slot]) { mSerialPorts [slot]->uninit(); unconst (mSerialPorts [slot]).setNull(); } } if (mFloppyDrive) { mFloppyDrive->uninit(); unconst (mFloppyDrive).setNull(); } if (mDVDDrive) { mDVDDrive->uninit(); unconst (mDVDDrive).setNull(); } #ifdef VBOX_WITH_VRDP if (mVRDPServer) { mVRDPServer->uninit(); unconst (mVRDPServer).setNull(); } #endif if (mBIOSSettings) { mBIOSSettings->uninit(); unconst (mBIOSSettings).setNull(); } /* Deassociate hard disks (only when a real Machine or a SnapshotMachine * instance is uninitialized; SessionMachine instances refer to real * Machine hard disks). This is necessary for a clean re-initialization of * the VM after successfully re-checking the accessibility state. Note * that in case of normal Machine or SnapshotMachine uninitialization (as * a result of unregistering or discarding the snapshot), outdated hard * disk attachments will already be uninitialized and deleted, so this * code will not affect them. */ if (!!mHDData && (mType == IsMachine || mType == IsSnapshotMachine)) { for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { HRESULT rc = (*it)->hardDisk()->detachFrom (mData->mUuid, snapshotId()); AssertComRC (rc); } } if (mType == IsMachine) { /* reset some important fields of mData */ mData->mCurrentSnapshot.setNull(); mData->mFirstSnapshot.setNull(); } /* free data structures (the essential mData structure is not freed here * since it may be still in use) */ mHDData.free(); mHWData.free(); mUserData.free(); mSSData.free(); } /** * Makes sure that there are no machine state dependants. If necessary, waits * for the number of dependants to drop to zero. * * Make sure this method is called from under this object's write lock to * guarantee that no new dependants may be added when this method returns * control to the caller. * * @note Locks this object for writing. The lock will be released while waiting * (if necessary). * * @warning To be used only in methods that change the machine state! */ void Machine::ensureNoStateDependencies() { AssertReturnVoid (isWriteLockOnCurrentThread()); AutoWriteLock alock (this); /* Wait for all state dependants if necessary */ if (mData->mMachineStateDeps != 0) { /* lazy semaphore creation */ if (mData->mMachineStateDepsSem == NIL_RTSEMEVENTMULTI) RTSemEventMultiCreate (&mData->mMachineStateDepsSem); LogFlowThisFunc (("Waiting for state deps (%d) to drop to zero...\n", mData->mMachineStateDeps)); ++ mData->mMachineStateChangePending; /* reset the semaphore before waiting, the last dependant will signal * it */ RTSemEventMultiReset (mData->mMachineStateDepsSem); alock.leave(); RTSemEventMultiWait (mData->mMachineStateDepsSem, RT_INDEFINITE_WAIT); alock.enter(); -- mData->mMachineStateChangePending; } } /** * Changes the machine state and informs callbacks. * * This method is not intended to fail so it either returns S_OK or asserts (and * returns a failure). * * @note Locks this object for writing. */ HRESULT Machine::setMachineState (MachineState_T aMachineState) { LogFlowThisFuncEnter(); LogFlowThisFunc (("aMachineState=%d\n", aMachineState)); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); /* wait for state dependants to drop to zero */ ensureNoStateDependencies(); if (mData->mMachineState != aMachineState) { mData->mMachineState = aMachineState; RTTimeNow (&mData->mLastStateChange); mParent->onMachineStateChange (mData->mUuid, aMachineState); } LogFlowThisFuncLeave(); return S_OK; } /** * Searches for a shared folder with the given logical name * in the collection of shared folders. * * @param aName logical name of the shared folder * @param aSharedFolder where to return the found object * @param aSetError whether to set the error info if the folder is * not found * @return * S_OK when found or E_INVALIDARG when not found * * @note * must be called from under the object's lock! */ HRESULT Machine::findSharedFolder (const BSTR aName, ComObjPtr &aSharedFolder, bool aSetError /* = false */) { bool found = false; for (HWData::SharedFolderList::const_iterator it = mHWData->mSharedFolders.begin(); !found && it != mHWData->mSharedFolders.end(); ++ it) { AutoWriteLock alock (*it); found = (*it)->name() == aName; if (found) aSharedFolder = *it; } HRESULT rc = found ? S_OK : E_INVALIDARG; if (aSetError && !found) setError (rc, tr ("Could not find a shared folder named '%ls'"), aName); return rc; } /** * Loads all the VM settings by walking down the node. * * @param aRegistered true when the machine is being loaded on VirtualBox * startup * * @note This method is intended to be called only from init(), so it assumes * all machine data fields have appropriate default values when it is called. * * @note Doesn't lock any objects. */ HRESULT Machine::loadSettings (bool aRegistered) { LogFlowThisFuncEnter(); AssertReturn (mType == IsMachine, E_FAIL); AutoCaller autoCaller (this); AssertReturn (autoCaller.state() == InInit, E_FAIL); HRESULT rc = S_OK; try { using namespace settings; /* no concurrent file access is possible in init() so open by handle */ File file (mData->mHandleCfgFile, Utf8Str (mData->mConfigFileFull)); XmlTreeBackend tree; rc = VirtualBox::loadSettingsTree_FirstTime (tree, file, mData->mSettingsFileVersion); CheckComRCThrowRC (rc); Key machineNode = tree.rootKey().key ("Machine"); /* uuid (required) */ Guid id = machineNode.value ("uuid"); /* If the stored UUID is not empty, it means the registered machine * is being loaded. Compare the loaded UUID with the stored one taken * from the global registry. */ if (!mData->mUuid.isEmpty()) { if (mData->mUuid != id) { throw setError (E_FAIL, tr ("Machine UUID {%Vuuid} in '%ls' doesn't match its " "UUID {%s} in the registry file '%ls'"), id.raw(), mData->mConfigFileFull.raw(), mData->mUuid.toString().raw(), mParent->settingsFileName().raw()); } } else unconst (mData->mUuid) = id; /* name (required) */ mUserData->mName = machineNode.stringValue ("name"); /* nameSync (optional, default is true) */ mUserData->mNameSync = machineNode.value ("nameSync"); /* Description (optional, default is null) */ { Key descNode = machineNode.findKey ("Description"); if (!descNode.isNull()) mUserData->mDescription = descNode.keyStringValue(); else mUserData->mDescription.setNull(); } /* OSType (required) */ { mUserData->mOSTypeId = machineNode.stringValue ("OSType"); /* look up the object by Id to check it is valid */ ComPtr guestOSType; rc = mParent->GetGuestOSType (mUserData->mOSTypeId, guestOSType.asOutParam()); CheckComRCThrowRC (rc); } /* stateFile (optional) */ { Bstr stateFilePath = machineNode.stringValue ("stateFile"); if (stateFilePath) { Utf8Str stateFilePathFull = stateFilePath; int vrc = calculateFullPath (stateFilePathFull, stateFilePathFull); if (VBOX_FAILURE (vrc)) { throw setError (E_FAIL, tr ("Invalid saved state file path '%ls' (%Vrc)"), stateFilePath.raw(), vrc); } mSSData->mStateFilePath = stateFilePathFull; } else mSSData->mStateFilePath.setNull(); } /* * currentSnapshot ID (optional) * * Note that due to XML Schema constaraints, this attribute, when * present, will guaranteedly refer to an existing snapshot * definition in XML */ Guid currentSnapshotId = machineNode.valueOr ("currentSnapshot", Guid()); /* snapshotFolder (optional) */ { Bstr folder = machineNode.stringValue ("snapshotFolder"); rc = COMSETTER(SnapshotFolder) (folder); CheckComRCThrowRC (rc); } /* currentStateModified (optional, default is true) */ mData->mCurrentStateModified = machineNode.value ("currentStateModified"); /* lastStateChange (optional, defaults to now) */ { RTTIMESPEC now; RTTimeNow (&now); mData->mLastStateChange = machineNode.valueOr ("lastStateChange", now); } /* aborted (optional, default is false) */ bool aborted = machineNode.value ("aborted"); /* * note: all mUserData members must be assigned prior this point because * we need to commit changes in order to let mUserData be shared by all * snapshot machine instances. */ mUserData.commitCopy(); /* Snapshot node (optional) */ { Key snapshotNode = machineNode.findKey ("Snapshot"); if (!snapshotNode.isNull()) { /* read all snapshots recursively */ rc = loadSnapshot (snapshotNode, currentSnapshotId, NULL); CheckComRCThrowRC (rc); } } /* Hardware node (required) */ rc = loadHardware (machineNode.key ("Hardware")); CheckComRCThrowRC (rc); /* HardDiskAttachments node (required) */ rc = loadHardDisks (machineNode.key ("HardDiskAttachments"), aRegistered); CheckComRCThrowRC (rc); /* * NOTE: the assignment below must be the last thing to do, * otherwise it will be not possible to change the settings * somewehere in the code above because all setters will be * blocked by checkStateDependency (MutableStateDep). */ /* set the machine state to Aborted or Saved when appropriate */ if (aborted) { Assert (!mSSData->mStateFilePath); mSSData->mStateFilePath.setNull(); /* no need to use setMachineState() during init() */ mData->mMachineState = MachineState_Aborted; } else if (mSSData->mStateFilePath) { /* no need to use setMachineState() during init() */ mData->mMachineState = MachineState_Saved; } } catch (HRESULT err) { /* we assume that error info is set by the thrower */ rc = err; } catch (...) { rc = VirtualBox::handleUnexpectedExceptions (RT_SRC_POS); } LogFlowThisFuncLeave(); return rc; } /** * Recursively loads all snapshots starting from the given. * * @param aNode node. * @param aCurSnapshotId Current snapshot ID from the settings file. * @param aParentSnapshot Parent snapshot. */ HRESULT Machine::loadSnapshot (const settings::Key &aNode, const Guid &aCurSnapshotId, Snapshot *aParentSnapshot) { using namespace settings; AssertReturn (!aNode.isNull(), E_INVALIDARG); AssertReturn (mType == IsMachine, E_FAIL); /* create a snapshot machine object */ ComObjPtr snapshotMachine; snapshotMachine.createObject(); HRESULT rc = S_OK; /* required */ Guid uuid = aNode.value ("uuid"); { /* optional */ Bstr stateFilePath = aNode.stringValue ("stateFile"); if (stateFilePath) { Utf8Str stateFilePathFull = stateFilePath; int vrc = calculateFullPath (stateFilePathFull, stateFilePathFull); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("Invalid saved state file path '%ls' (%Vrc)"), stateFilePath.raw(), vrc); stateFilePath = stateFilePathFull; } /* Hardware node (required) */ Key hardwareNode = aNode.key ("Hardware"); /* HardDiskAttachments node (required) */ Key hdasNode = aNode.key ("HardDiskAttachments"); /* initialize the snapshot machine */ rc = snapshotMachine->init (this, hardwareNode, hdasNode, uuid, stateFilePath); CheckComRCReturnRC (rc); } /* create a snapshot object */ ComObjPtr snapshot; snapshot.createObject(); { /* required */ Bstr name = aNode.stringValue ("name"); /* required */ RTTIMESPEC timeStamp = aNode.value ("timeStamp"); /* optional */ Bstr description; { Key descNode = aNode.findKey ("Description"); if (!descNode.isNull()) description = descNode.keyStringValue(); } /* initialize the snapshot */ rc = snapshot->init (uuid, name, description, timeStamp, snapshotMachine, aParentSnapshot); CheckComRCReturnRC (rc); } /* memorize the first snapshot if necessary */ if (!mData->mFirstSnapshot) mData->mFirstSnapshot = snapshot; /* memorize the current snapshot when appropriate */ if (!mData->mCurrentSnapshot && snapshot->data().mId == aCurSnapshotId) mData->mCurrentSnapshot = snapshot; /* Snapshots node (optional) */ { Key snapshotsNode = aNode.findKey ("Snapshots"); if (!snapshotsNode.isNull()) { Key::List children = snapshotsNode.keys ("Snapshot"); for (Key::List::const_iterator it = children.begin(); it != children.end(); ++ it) { rc = loadSnapshot ((*it), aCurSnapshotId, snapshot); CheckComRCBreakRC (rc); } } } return rc; } /** * @param aNode node. */ HRESULT Machine::loadHardware (const settings::Key &aNode) { using namespace settings; AssertReturn (!aNode.isNull(), E_INVALIDARG); AssertReturn (mType == IsMachine || mType == IsSnapshotMachine, E_FAIL); HRESULT rc = S_OK; /* CPU node (currently not required) */ { /* default value in case the node is not there */ mHWData->mHWVirtExEnabled = TSBool_Default; mHWData->mHWVirtExNestedPagingEnabled = false; mHWData->mHWVirtExVPIDEnabled = false; mHWData->mPAEEnabled = false; Key cpuNode = aNode.findKey ("CPU"); if (!cpuNode.isNull()) { Key hwVirtExNode = cpuNode.key ("HardwareVirtEx"); if (!hwVirtExNode.isNull()) { const char *enabled = hwVirtExNode.stringValue ("enabled"); if (strcmp (enabled, "false") == 0) mHWData->mHWVirtExEnabled = TSBool_False; else if (strcmp (enabled, "true") == 0) mHWData->mHWVirtExEnabled = TSBool_True; else mHWData->mHWVirtExEnabled = TSBool_Default; } /* HardwareVirtExNestedPaging (optional, default is false) */ Key HWVirtExNestedPagingNode = cpuNode.findKey ("HardwareVirtExNestedPaging"); if (!HWVirtExNestedPagingNode.isNull()) { mHWData->mHWVirtExNestedPagingEnabled = HWVirtExNestedPagingNode.value ("enabled"); } /* HardwareVirtExVPID (optional, default is false) */ Key HWVirtExVPIDNode = cpuNode.findKey ("HardwareVirtExVPID"); if (!HWVirtExVPIDNode.isNull()) { mHWData->mHWVirtExVPIDEnabled = HWVirtExVPIDNode.value ("enabled"); } /* PAE (optional, default is false) */ Key PAENode = cpuNode.findKey ("PAE"); if (!PAENode.isNull()) { mHWData->mPAEEnabled = PAENode.value ("enabled"); } /* CPUCount(optional, default is 1) */ Key CPUCountNode = cpuNode.findKey ("CPUCount"); if (!CPUCountNode.isNull()) { mHWData->mCPUCount = CPUCountNode.value ("count"); } } } /* Memory node (required) */ { Key memoryNode = aNode.key ("Memory"); mHWData->mMemorySize = memoryNode.value ("RAMSize"); } /* Boot node (required) */ { /* reset all boot order positions to NoDevice */ for (size_t i = 0; i < ELEMENTS (mHWData->mBootOrder); i++) mHWData->mBootOrder [i] = DeviceType_Null; Key bootNode = aNode.key ("Boot"); Key::List orderNodes = bootNode.keys ("Order"); for (Key::List::const_iterator it = orderNodes.begin(); it != orderNodes.end(); ++ it) { /* position (required) */ /* position unicity is guaranteed by XML Schema */ uint32_t position = (*it).value ("position"); -- position; Assert (position < ELEMENTS (mHWData->mBootOrder)); /* device (required) */ const char *device = (*it).stringValue ("device"); if (strcmp (device, "None") == 0) mHWData->mBootOrder [position] = DeviceType_Null; else if (strcmp (device, "Floppy") == 0) mHWData->mBootOrder [position] = DeviceType_Floppy; else if (strcmp (device, "DVD") == 0) mHWData->mBootOrder [position] = DeviceType_DVD; else if (strcmp (device, "HardDisk") == 0) mHWData->mBootOrder [position] = DeviceType_HardDisk; else if (strcmp (device, "Network") == 0) mHWData->mBootOrder [position] = DeviceType_Network; else ComAssertMsgFailed (("Invalid device: %s\n", device)); } } /* Display node (required) */ { Key displayNode = aNode.key ("Display"); mHWData->mVRAMSize = displayNode.value ("VRAMSize"); mHWData->mMonitorCount = displayNode.value ("MonitorCount"); } #ifdef VBOX_WITH_VRDP /* RemoteDisplay */ rc = mVRDPServer->loadSettings (aNode); CheckComRCReturnRC (rc); #endif /* BIOS */ rc = mBIOSSettings->loadSettings (aNode); CheckComRCReturnRC (rc); /* DVD drive */ rc = mDVDDrive->loadSettings (aNode); CheckComRCReturnRC (rc); /* Floppy drive */ rc = mFloppyDrive->loadSettings (aNode); CheckComRCReturnRC (rc); /* USB Controller */ rc = mUSBController->loadSettings (aNode); CheckComRCReturnRC (rc); /* SATA Controller */ rc = mSATAController->loadSettings (aNode); CheckComRCReturnRC (rc); /* Network node (required) */ { /* we assume that all network adapters are initially disabled * and detached */ Key networkNode = aNode.key ("Network"); rc = S_OK; Key::List adapters = networkNode.keys ("Adapter"); for (Key::List::const_iterator it = adapters.begin(); it != adapters.end(); ++ it) { /* slot number (required) */ /* slot unicity is guaranteed by XML Schema */ uint32_t slot = (*it).value ("slot"); AssertBreak (slot < ELEMENTS (mNetworkAdapters)); rc = mNetworkAdapters [slot]->loadSettings (*it); CheckComRCReturnRC (rc); } } /* Serial node (required) */ { Key serialNode = aNode.key ("UART"); rc = S_OK; Key::List ports = serialNode.keys ("Port"); for (Key::List::const_iterator it = ports.begin(); it != ports.end(); ++ it) { /* slot number (required) */ /* slot unicity is guaranteed by XML Schema */ uint32_t slot = (*it).value ("slot"); AssertBreak (slot < ELEMENTS (mSerialPorts)); rc = mSerialPorts [slot]->loadSettings (*it); CheckComRCReturnRC (rc); } } /* Parallel node (optional) */ { Key parallelNode = aNode.key ("LPT"); rc = S_OK; Key::List ports = parallelNode.keys ("Port"); for (Key::List::const_iterator it = ports.begin(); it != ports.end(); ++ it) { /* slot number (required) */ /* slot unicity is guaranteed by XML Schema */ uint32_t slot = (*it).value ("slot"); AssertBreak (slot < ELEMENTS (mSerialPorts)); rc = mParallelPorts [slot]->loadSettings (*it); CheckComRCReturnRC (rc); } } /* AudioAdapter */ rc = mAudioAdapter->loadSettings (aNode); CheckComRCReturnRC (rc); /* Shared folders (required) */ { Key sharedFoldersNode = aNode.key ("SharedFolders"); rc = S_OK; Key::List folders = sharedFoldersNode.keys ("SharedFolder"); for (Key::List::const_iterator it = folders.begin(); it != folders.end(); ++ it) { /* folder logical name (required) */ Bstr name = (*it).stringValue ("name"); /* folder host path (required) */ Bstr hostPath = (*it).stringValue ("hostPath"); bool writable = (*it).value ("writable"); rc = CreateSharedFolder (name, hostPath, writable); CheckComRCReturnRC (rc); } } /* Clipboard node (required) */ { Key clipNode = aNode.key ("Clipboard"); const char *mode = clipNode.stringValue ("mode"); if (strcmp (mode, "Disabled") == 0) mHWData->mClipboardMode = ClipboardMode_Disabled; else if (strcmp (mode, "HostToGuest") == 0) mHWData->mClipboardMode = ClipboardMode_HostToGuest; else if (strcmp (mode, "GuestToHost") == 0) mHWData->mClipboardMode = ClipboardMode_GuestToHost; else if (strcmp (mode, "Bidirectional") == 0) mHWData->mClipboardMode = ClipboardMode_Bidirectional; else AssertMsgFailed (("Invalid clipboard mode '%s'\n", mode)); } /* Guest node (required) */ { Key guestNode = aNode.key ("Guest"); /* optional, defaults to 0 */ mHWData->mMemoryBalloonSize = guestNode.value ("memoryBalloonSize"); /* optional, defaults to 0 */ mHWData->mStatisticsUpdateInterval = guestNode.value ("statisticsUpdateInterval"); } #ifdef VBOX_WITH_GUEST_PROPS /* Guest properties (optional) */ { using namespace guestProp; Key guestPropertiesNode = aNode.findKey ("GuestProperties"); Bstr notificationPatterns (""); /* We catch allocation failure below. */ if (!guestPropertiesNode.isNull()) { Key::List properties = guestPropertiesNode.keys ("GuestProperty"); for (Key::List::const_iterator it = properties.begin(); it != properties.end(); ++ it) { uint32_t fFlags = NILFLAG; /* property name (required) */ Bstr name = (*it).stringValue ("name"); /* property value (required) */ Bstr value = (*it).stringValue ("value"); /* property timestamp (optional, defaults to 0) */ ULONG64 timestamp = (*it).value ("timestamp"); /* property flags (optional, defaults to empty) */ Bstr flags = (*it).stringValue ("flags"); Utf8Str utf8Flags (flags); if (utf8Flags.isNull ()) return E_OUTOFMEMORY; validateFlags (utf8Flags.raw(), &fFlags); HWData::GuestProperty property = { name, value, timestamp, fFlags }; mHWData->mGuestProperties.push_back(property); /* This is just sanity, as the push_back() will probably have thrown * an exception if we are out of memory. Note that if we run out * allocating the Bstrs above, this will be caught here as well. */ if ( mHWData->mGuestProperties.back().mName.isNull () || mHWData->mGuestProperties.back().mValue.isNull () ) return E_OUTOFMEMORY; } notificationPatterns = guestPropertiesNode.stringValue ("notificationPatterns"); } mHWData->mPropertyServiceActive = false; mHWData->mGuestPropertyNotificationPatterns = notificationPatterns; if (mHWData->mGuestPropertyNotificationPatterns.isNull ()) return E_OUTOFMEMORY; } #endif /* VBOX_WITH_GUEST_PROPS defined */ AssertComRC (rc); return rc; } /** * @param aNode node. * @param aRegistered true when the machine is being loaded on VirtualBox * startup, or when a snapshot is being loaded (wchich * currently can happen on startup only) * @param aSnapshotId pointer to the snapshot ID if this is a snapshot machine * * @note May lock mParent for reading and hard disks for writing. */ HRESULT Machine::loadHardDisks (const settings::Key &aNode, bool aRegistered, const Guid *aSnapshotId /* = NULL */) { using namespace settings; AssertReturn (!aNode.isNull(), E_INVALIDARG); AssertReturn ((mType == IsMachine && aSnapshotId == NULL) || (mType == IsSnapshotMachine && aSnapshotId != NULL), E_FAIL); HRESULT rc = S_OK; Key::List children = aNode.keys ("HardDiskAttachment"); if (!aRegistered && children.size() > 0) { /* when the machine is being loaded (opened) from a file, it cannot * have hard disks attached (this should not happen normally, * because we don't allow to attach hard disks to an unregistered * VM at all */ return setError (E_FAIL, tr ("Unregistered machine '%ls' cannot have hard disks attached " "(found %d hard disk attachments)"), mUserData->mName.raw(), children.size()); } /* Make sure the attached hard disks don't get unregistered until we * associate them with tis machine (important for VMs loaded (opened) after * VirtualBox startup) */ AutoReadLock vboxLock (mParent); for (Key::List::const_iterator it = children.begin(); it != children.end(); ++ it) { /* hard disk uuid (required) */ Guid uuid = (*it).value ("hardDisk"); /* bus (controller) type (required) */ const char *busStr = (*it).stringValue ("bus"); /* channel (required) */ LONG channel = (*it).value ("channel"); /* device (required) */ LONG device = (*it).value ("device"); /* find a hard disk by UUID */ ComObjPtr hd; rc = mParent->findHardDisk2 (&uuid, NULL, true /* aDoSetError */, &hd); CheckComRCReturnRC (rc); AutoWriteLock hdLock (hd); if (hd->type() == HardDiskType_Immutable) { if (mType == IsSnapshotMachine) return setError (E_FAIL, tr ("Immutable hard disk '%ls' with UUID {%Vuuid} cannot be " "directly attached to snapshot with UUID {%Vuuid} " "of the virtual machine '%ls' ('%ls')"), hd->locationFull().raw(), uuid.raw(), aSnapshotId->raw(), mUserData->mName.raw(), mData->mConfigFileFull.raw()); return setError (E_FAIL, tr ("Immutable hard disk '%ls' with UUID {%Vuuid} cannot be " "directly attached to the virtual machine '%ls' ('%ls')"), hd->locationFull().raw(), uuid.raw(), mUserData->mName.raw(), mData->mConfigFileFull.raw()); } if (mType != IsSnapshotMachine && hd->children().size() != 0) return setError (E_FAIL, tr ("Hard disk '%ls' with UUID {%Vuuid} cannot be directly " "attached to the virtual machine '%ls' ('%ls') " "because it has %d differencing child hard disks"), hd->locationFull().raw(), uuid.raw(), mUserData->mName.raw(), mData->mConfigFileFull.raw(), hd->children().size()); if (std::find_if (mHDData->mAttachments.begin(), mHDData->mAttachments.end(), HardDisk2Attachment::RefersTo (hd)) != mHDData->mAttachments.end()) { return setError (E_FAIL, tr ("Hard disk '%ls' with UUID {%Vuuid} is already attached " "to the virtual machine '%ls' ('%ls')"), hd->locationFull().raw(), uuid.raw(), mUserData->mName.raw(), mData->mConfigFileFull.raw()); } StorageBus_T bus = StorageBus_Null; if (strcmp (busStr, "IDE") == 0) bus = StorageBus_IDE; else if (strcmp (busStr, "SATA") == 0) bus = StorageBus_SATA; else AssertFailedReturn (E_FAIL); ComObjPtr attachment; attachment.createObject(); rc = attachment->init (hd, bus, channel, device); CheckComRCBreakRC (rc); /* associate the hard disk with this machine and snapshot */ if (mType == IsSnapshotMachine) rc = hd->attachTo (mData->mUuid, *aSnapshotId); else rc = hd->attachTo (mData->mUuid); AssertComRCBreakRC (rc); /* backup mHDData to let registeredInit() properly rollback on failure * (= limited accessibility) */ mHDData.backup(); mHDData->mAttachments.push_back (attachment); } return rc; } /** * Searches for a node for the given snapshot. * If the search is successful, \a aSnapshotNode will contain the found node. * In this case, \a aSnapshotsNode can be NULL meaning the found node is a * direct child of \a aMachineNode. * * If the search fails, a failure is returned and both \a aSnapshotsNode and * \a aSnapshotNode are set to 0. * * @param aSnapshot Snapshot to search for. * @param aMachineNode node to start from. * @param aSnapshotsNode node containing the found node * (may be NULL if the caller is not interested). * @param aSnapshotNode Found node. */ HRESULT Machine::findSnapshotNode (Snapshot *aSnapshot, settings::Key &aMachineNode, settings::Key *aSnapshotsNode, settings::Key *aSnapshotNode) { using namespace settings; AssertReturn (aSnapshot && !aMachineNode.isNull() && aSnapshotNode != NULL, E_FAIL); if (aSnapshotsNode) aSnapshotsNode->setNull(); aSnapshotNode->setNull(); // build the full uuid path (from the top parent to the given snapshot) std::list path; { ComObjPtr parent = aSnapshot; while (parent) { path.push_front (parent->data().mId); parent = parent->parent(); } } Key snapshotsNode = aMachineNode; Key snapshotNode; for (std::list ::const_iterator it = path.begin(); it != path.end(); ++ it) { if (!snapshotNode.isNull()) { /* proceed to the nested node */ snapshotsNode = snapshotNode.key ("Snapshots"); snapshotNode.setNull(); } AssertReturn (!snapshotsNode.isNull(), E_FAIL); Key::List children = snapshotsNode.keys ("Snapshot"); for (Key::List::const_iterator ch = children.begin(); ch != children.end(); ++ ch) { Guid id = (*ch).value ("uuid"); if (id == (*it)) { /* pass over to the outer loop */ snapshotNode = *ch; break; } } if (!snapshotNode.isNull()) continue; /* the next uuid is not found, no need to continue... */ AssertFailedBreak(); } // we must always succesfully find the node AssertReturn (!snapshotNode.isNull(), E_FAIL); AssertReturn (!snapshotsNode.isNull(), E_FAIL); if (aSnapshotsNode && (snapshotsNode != aMachineNode)) *aSnapshotsNode = snapshotsNode; *aSnapshotNode = snapshotNode; return S_OK; } /** * Returns the snapshot with the given UUID or fails of no such snapshot. * * @param aId snapshot UUID to find (empty UUID refers the first snapshot) * @param aSnapshot where to return the found snapshot * @param aSetError true to set extended error info on failure */ HRESULT Machine::findSnapshot (const Guid &aId, ComObjPtr &aSnapshot, bool aSetError /* = false */) { if (!mData->mFirstSnapshot) { if (aSetError) return setError (E_FAIL, tr ("This machine does not have any snapshots")); return E_FAIL; } if (aId.isEmpty()) aSnapshot = mData->mFirstSnapshot; else aSnapshot = mData->mFirstSnapshot->findChildOrSelf (aId); if (!aSnapshot) { if (aSetError) return setError (E_FAIL, tr ("Could not find a snapshot with UUID {%s}"), aId.toString().raw()); return E_FAIL; } return S_OK; } /** * Returns the snapshot with the given name or fails of no such snapshot. * * @param aName snapshot name to find * @param aSnapshot where to return the found snapshot * @param aSetError true to set extended error info on failure */ HRESULT Machine::findSnapshot (const BSTR aName, ComObjPtr &aSnapshot, bool aSetError /* = false */) { AssertReturn (aName, E_INVALIDARG); if (!mData->mFirstSnapshot) { if (aSetError) return setError (E_FAIL, tr ("This machine does not have any snapshots")); return E_FAIL; } aSnapshot = mData->mFirstSnapshot->findChildOrSelf (aName); if (!aSnapshot) { if (aSetError) return setError (E_FAIL, tr ("Could not find a snapshot named '%ls'"), aName); return E_FAIL; } return S_OK; } /** * Helper for #saveSettings. Cares about renaming the settings directory and * file if the machine name was changed and about creating a new settings file * if this is a new machine. * * @note Must be never called directly but only from #saveSettings(). * * @param aRenamed receives |true| if the name was changed and the settings * file was renamed as a result, or |false| otherwise. The * value makes sense only on success. * @param aNew receives |true| if a virgin settings file was created. */ HRESULT Machine::prepareSaveSettings (bool &aRenamed, bool &aNew) { /* Note: tecnhically, mParent needs to be locked only when the machine is * registered (see prepareSaveSettings() for details) but we don't * currently differentiate it in callers of saveSettings() so we don't * make difference here too. */ AssertReturn (mParent->isWriteLockOnCurrentThread(), E_FAIL); AssertReturn (isWriteLockOnCurrentThread(), E_FAIL); HRESULT rc = S_OK; aRenamed = false; /* if we're ready and isConfigLocked() is FALSE then it means * that no config file exists yet (we will create a virgin one) */ aNew = !isConfigLocked(); /* attempt to rename the settings file if machine name is changed */ if (mUserData->mNameSync && mUserData.isBackedUp() && mUserData.backedUpData()->mName != mUserData->mName) { aRenamed = true; if (!aNew) { /* unlock the old config file */ rc = unlockConfig(); CheckComRCReturnRC (rc); } bool dirRenamed = false; bool fileRenamed = false; Utf8Str configFile, newConfigFile; Utf8Str configDir, newConfigDir; do { int vrc = VINF_SUCCESS; Utf8Str name = mUserData.backedUpData()->mName; Utf8Str newName = mUserData->mName; configFile = mData->mConfigFileFull; /* first, rename the directory if it matches the machine name */ configDir = configFile; RTPathStripFilename (configDir.mutableRaw()); newConfigDir = configDir; if (RTPathFilename (configDir) == name) { RTPathStripFilename (newConfigDir.mutableRaw()); newConfigDir = Utf8StrFmt ("%s%c%s", newConfigDir.raw(), RTPATH_DELIMITER, newName.raw()); /* new dir and old dir cannot be equal here because of 'if' * above and because name != newName */ Assert (configDir != newConfigDir); if (!aNew) { /* perform real rename only if the machine is not new */ vrc = RTPathRename (configDir.raw(), newConfigDir.raw(), 0); if (VBOX_FAILURE (vrc)) { rc = setError (E_FAIL, tr ("Could not rename the directory '%s' to '%s' " "to save the settings file (%Vrc)"), configDir.raw(), newConfigDir.raw(), vrc); break; } dirRenamed = true; } } newConfigFile = Utf8StrFmt ("%s%c%s.xml", newConfigDir.raw(), RTPATH_DELIMITER, newName.raw()); /* then try to rename the settings file itself */ if (newConfigFile != configFile) { /* get the path to old settings file in renamed directory */ configFile = Utf8StrFmt ("%s%c%s", newConfigDir.raw(), RTPATH_DELIMITER, RTPathFilename (configFile)); if (!aNew) { /* perform real rename only if the machine is not new */ vrc = RTFileRename (configFile.raw(), newConfigFile.raw(), 0); if (VBOX_FAILURE (vrc)) { rc = setError (E_FAIL, tr ("Could not rename the settings file '%s' to '%s' " "(%Vrc)"), configFile.raw(), newConfigFile.raw(), vrc); break; } fileRenamed = true; } } /* update mConfigFileFull amd mConfigFile */ Bstr oldConfigFileFull = mData->mConfigFileFull; Bstr oldConfigFile = mData->mConfigFile; mData->mConfigFileFull = newConfigFile; /* try to get the relative path for mConfigFile */ Utf8Str path = newConfigFile; mParent->calculateRelativePath (path, path); mData->mConfigFile = path; /* last, try to update the global settings with the new path */ if (mData->mRegistered) { rc = mParent->updateSettings (configDir, newConfigDir); if (FAILED (rc)) { /* revert to old values */ mData->mConfigFileFull = oldConfigFileFull; mData->mConfigFile = oldConfigFile; break; } } /* update the snapshot folder */ path = mUserData->mSnapshotFolderFull; if (RTPathStartsWith (path, configDir)) { path = Utf8StrFmt ("%s%s", newConfigDir.raw(), path.raw() + configDir.length()); mUserData->mSnapshotFolderFull = path; calculateRelativePath (path, path); mUserData->mSnapshotFolder = path; } /* update the saved state file path */ path = mSSData->mStateFilePath; if (RTPathStartsWith (path, configDir)) { path = Utf8StrFmt ("%s%s", newConfigDir.raw(), path.raw() + configDir.length()); mSSData->mStateFilePath = path; } /* Update saved state file paths of all online snapshots. * Note that saveSettings() will recognize name change * and will save all snapshots in this case. */ if (mData->mFirstSnapshot) mData->mFirstSnapshot->updateSavedStatePaths (configDir, newConfigDir); } while (0); if (FAILED (rc)) { /* silently try to rename everything back */ if (fileRenamed) RTFileRename (newConfigFile.raw(), configFile.raw(), 0); if (dirRenamed) RTPathRename (newConfigDir.raw(), configDir.raw(), 0); } if (!aNew) { /* lock the config again */ HRESULT rc2 = lockConfig(); if (SUCCEEDED (rc)) rc = rc2; } CheckComRCReturnRC (rc); } if (aNew) { /* create a virgin config file */ int vrc = VINF_SUCCESS; /* ensure the settings directory exists */ Utf8Str path = mData->mConfigFileFull; RTPathStripFilename (path.mutableRaw()); if (!RTDirExists (path)) { vrc = RTDirCreateFullPath (path, 0777); if (VBOX_FAILURE (vrc)) { return setError (E_FAIL, tr ("Could not create a directory '%s' " "to save the settings file (%Vrc)"), path.raw(), vrc); } } /* Note: open flags must correlate with RTFileOpen() in lockConfig() */ path = Utf8Str (mData->mConfigFileFull); vrc = RTFileOpen (&mData->mHandleCfgFile, path, RTFILE_O_READWRITE | RTFILE_O_CREATE | RTFILE_O_DENY_WRITE); if (VBOX_SUCCESS (vrc)) { vrc = RTFileWrite (mData->mHandleCfgFile, (void *) DefaultMachineConfig, sizeof (DefaultMachineConfig), NULL); } if (VBOX_FAILURE (vrc)) { mData->mHandleCfgFile = NIL_RTFILE; return setError (E_FAIL, tr ("Could not create the settings file '%s' (%Vrc)"), path.raw(), vrc); } /* we do not close the file to simulate lockConfig() */ } return rc; } /** * Saves and commits machine data, user data and hardware data. * * Note that on failure, the data remains uncommitted. * * @a aFlags may combine the following flags: * * - SaveS_ResetCurStateModified: Resets mData->mCurrentStateModified to FALSE. * Used when saving settings after an operation that makes them 100% * correspond to the settings from the current snapshot. * - SaveS_InformCallbacksAnyway: Callbacks will be informed even if * #isReallyModified() returns false. This is necessary for cases when we * change machine data diectly, not through the backup()/commit() mechanism. * * @note Must be called from under mParent write lock (sometimes needed by * #prepareSaveSettings()) and this object's write lock. Locks children for * writing. There is one exception when mParent is unused and therefore may be * left unlocked: if this machine is an unregistered one. */ HRESULT Machine::saveSettings (int aFlags /*= 0*/) { LogFlowThisFuncEnter(); /* Note: tecnhically, mParent needs to be locked only when the machine is * registered (see prepareSaveSettings() for details) but we don't * currently differentiate it in callers of saveSettings() so we don't * make difference here too. */ AssertReturn (mParent->isWriteLockOnCurrentThread(), E_FAIL); AssertReturn (isWriteLockOnCurrentThread(), E_FAIL); /* make sure child objects are unable to modify the settings while we are * saving them */ ensureNoStateDependencies(); AssertReturn (mType == IsMachine || mType == IsSessionMachine, E_FAIL); BOOL currentStateModified = mData->mCurrentStateModified; bool settingsModified; if (!(aFlags & SaveS_ResetCurStateModified) && !currentStateModified) { /* We ignore changes to user data when setting mCurrentStateModified * because the current state will not differ from the current snapshot * if only user data has been changed (user data is shared by all * snapshots). */ currentStateModified = isReallyModified (true /* aIgnoreUserData */); settingsModified = mUserData.hasActualChanges() || currentStateModified; } else { if (aFlags & SaveS_ResetCurStateModified) currentStateModified = FALSE; settingsModified = isReallyModified(); } HRESULT rc = S_OK; /* First, prepare to save settings. It will will care about renaming the * settings directory and file if the machine name was changed and about * creating a new settings file if this is a new machine. */ bool isRenamed = false; bool isNew = false; rc = prepareSaveSettings (isRenamed, isNew); CheckComRCReturnRC (rc); try { using namespace settings; /* this object is locked for writing to prevent concurrent reads and writes */ File file (mData->mHandleCfgFile, Utf8Str (mData->mConfigFileFull)); XmlTreeBackend tree; /* The newly created settings file is incomplete therefore we turn off * validation. The rest is like in loadSettingsTree_ForUpdate().*/ rc = VirtualBox::loadSettingsTree (tree, file, !isNew /* aValidate */, false /* aCatchLoadErrors */, false /* aAddDefaults */); CheckComRCThrowRC (rc); Key machineNode = tree.rootKey().createKey ("Machine"); /* uuid (required) */ Assert (!mData->mUuid.isEmpty()); machineNode.setValue ("uuid", mData->mUuid); /* name (required) */ Assert (!mUserData->mName.isEmpty()); machineNode.setValue ("name", mUserData->mName); /* nameSync (optional, default is true) */ machineNode.setValueOr ("nameSync", !!mUserData->mNameSync, true); /* Description node (optional) */ if (!mUserData->mDescription.isNull()) { Key descNode = machineNode.createKey ("Description"); descNode.setKeyValue (mUserData->mDescription); } else { Key descNode = machineNode.findKey ("Description"); if (!descNode.isNull()) descNode.zap(); } /* OSType (required) */ machineNode.setValue ("OSType", mUserData->mOSTypeId); /* stateFile (optional) */ if (mData->mMachineState == MachineState_Saved) { Assert (!mSSData->mStateFilePath.isEmpty()); /* try to make the file name relative to the settings file dir */ Utf8Str stateFilePath = mSSData->mStateFilePath; calculateRelativePath (stateFilePath, stateFilePath); machineNode.setStringValue ("stateFile", stateFilePath); } else { Assert (mSSData->mStateFilePath.isNull()); machineNode.zapValue ("stateFile"); } /* currentSnapshot ID (optional) */ if (!mData->mCurrentSnapshot.isNull()) { Assert (!mData->mFirstSnapshot.isNull()); machineNode.setValue ("currentSnapshot", mData->mCurrentSnapshot->data().mId); } else { Assert (mData->mFirstSnapshot.isNull()); machineNode.zapValue ("currentSnapshot"); } /* snapshotFolder (optional) */ /// @todo use the Bstr::NullOrEmpty constant and setValueOr if (!mUserData->mSnapshotFolder.isEmpty()) machineNode.setValue ("snapshotFolder", mUserData->mSnapshotFolder); else machineNode.zapValue ("snapshotFolder"); /* currentStateModified (optional, default is true) */ machineNode.setValueOr ("currentStateModified", !!currentStateModified, true); /* lastStateChange */ machineNode.setValue ("lastStateChange", mData->mLastStateChange); /* set the aborted attribute when appropriate, defaults to false */ machineNode.setValueOr ("aborted", mData->mMachineState == MachineState_Aborted, false); /* Hardware node (required) */ { /* first, delete the entire node if exists */ Key hwNode = machineNode.findKey ("Hardware"); if (!hwNode.isNull()) hwNode.zap(); /* then recreate it */ hwNode = machineNode.createKey ("Hardware"); rc = saveHardware (hwNode); CheckComRCThrowRC (rc); } /* HardDiskAttachments node (required) */ { /* first, delete the entire node if exists */ Key hdaNode = machineNode.findKey ("HardDiskAttachments"); if (!hdaNode.isNull()) hdaNode.zap(); /* then recreate it */ hdaNode = machineNode.createKey ("HardDiskAttachments"); rc = saveHardDisks (hdaNode); CheckComRCThrowRC (rc); } /* ask to save all snapshots when the machine name was changed since * it may affect saved state file paths for online snapshots (see * #openConfigLoader() for details) */ if (isRenamed) { rc = saveSnapshotSettingsWorker (machineNode, NULL, SaveSS_UpdateAllOp); CheckComRCThrowRC (rc); } /* save the settings on success */ rc = VirtualBox::saveSettingsTree (tree, file, mData->mSettingsFileVersion); CheckComRCThrowRC (rc); } catch (HRESULT err) { /* we assume that error info is set by the thrower */ rc = err; } catch (...) { rc = VirtualBox::handleUnexpectedExceptions (RT_SRC_POS); } if (SUCCEEDED (rc)) { commit(); /* memorize the new modified state */ mData->mCurrentStateModified = currentStateModified; } if (settingsModified || (aFlags & SaveS_InformCallbacksAnyway)) { /* Fire the data change event, even on failure (since we've already * committed all data). This is done only for SessionMachines because * mutable Machine instances are always not registered (i.e. private * to the client process that creates them) and thus don't need to * inform callbacks. */ if (mType == IsSessionMachine) mParent->onMachineDataChange (mData->mUuid); } LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } /** * Wrapper for #saveSnapshotSettingsWorker() that opens the settings file * and locates the node in there. See #saveSnapshotSettingsWorker() * for more details. * * @param aSnapshot Snapshot to operate on * @param aOpFlags Operation to perform, one of SaveSS_NoOp, SaveSS_AddOp * or SaveSS_UpdateAttrsOp possibly combined with * SaveSS_UpdateCurrentId. * * @note Locks this object for writing + other child objects. */ HRESULT Machine::saveSnapshotSettings (Snapshot *aSnapshot, int aOpFlags) { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AssertReturn (mType == IsMachine || mType == IsSessionMachine, E_FAIL); /* This object's write lock is also necessary to serialize file access * (prevent concurrent reads and writes) */ AutoWriteLock alock (this); AssertReturn (isConfigLocked(), E_FAIL); HRESULT rc = S_OK; try { using namespace settings; /* load the settings file */ File file (mData->mHandleCfgFile, Utf8Str (mData->mConfigFileFull)); XmlTreeBackend tree; rc = VirtualBox::loadSettingsTree_ForUpdate (tree, file); CheckComRCReturnRC (rc); Key machineNode = tree.rootKey().key ("Machine"); rc = saveSnapshotSettingsWorker (machineNode, aSnapshot, aOpFlags); CheckComRCReturnRC (rc); /* save settings on success */ rc = VirtualBox::saveSettingsTree (tree, file, mData->mSettingsFileVersion); CheckComRCReturnRC (rc); } catch (...) { rc = VirtualBox::handleUnexpectedExceptions (RT_SRC_POS); } return rc; } /** * Performs the specified operation on the given snapshot * in the settings file represented by \a aMachineNode. * * If \a aOpFlags = SaveSS_UpdateAllOp, \a aSnapshot can be NULL to indicate * that the whole tree of the snapshots should be updated in . * One particular case is when the last (and the only) snapshot should be * removed (it is so when both mCurrentSnapshot and mFirstSnapshot are NULL). * * \a aOp may be just SaveSS_UpdateCurrentId if only the currentSnapshot * attribute of needs to be updated. * * @param aMachineNode node in the opened settings file. * @param aSnapshot Snapshot to operate on. * @param aOpFlags Operation to perform, one of SaveSS_NoOp, SaveSS_AddOp * or SaveSS_UpdateAttrsOp possibly combined with * SaveSS_UpdateCurrentId. * * @note Must be called with this object locked for writing. * Locks child objects. */ HRESULT Machine::saveSnapshotSettingsWorker (settings::Key &aMachineNode, Snapshot *aSnapshot, int aOpFlags) { using namespace settings; AssertReturn (!aMachineNode.isNull(), E_FAIL); AssertReturn (isWriteLockOnCurrentThread(), E_FAIL); int op = aOpFlags & SaveSS_OpMask; AssertReturn ( (aSnapshot && (op == SaveSS_AddOp || op == SaveSS_UpdateAttrsOp || op == SaveSS_UpdateAllOp)) || (!aSnapshot && ((op == SaveSS_NoOp && (aOpFlags & SaveSS_CurrentId)) || op == SaveSS_UpdateAllOp)), E_FAIL); HRESULT rc = S_OK; bool recreateWholeTree = false; do { if (op == SaveSS_NoOp) break; /* quick path: recreate the whole tree of the snapshots */ if (op == SaveSS_UpdateAllOp && !aSnapshot) { /* first, delete the entire root snapshot node if it exists */ Key snapshotNode = aMachineNode.findKey ("Snapshot"); if (!snapshotNode.isNull()) snapshotNode.zap(); /* second, if we have any snapshots left, substitute aSnapshot * with the first snapshot to recreate the whole tree, otherwise * break */ if (mData->mFirstSnapshot) { aSnapshot = mData->mFirstSnapshot; recreateWholeTree = true; } else break; } Assert (!!aSnapshot); ComObjPtr parent = aSnapshot->parent(); if (op == SaveSS_AddOp) { Key parentNode; if (parent) { rc = findSnapshotNode (parent, aMachineNode, NULL, &parentNode); CheckComRCBreakRC (rc); ComAssertBreak (!parentNode.isNull(), rc = E_FAIL); } do { Key snapshotsNode; if (!parentNode.isNull()) snapshotsNode = parentNode.createKey ("Snapshots"); else snapshotsNode = aMachineNode; do { Key snapshotNode = snapshotsNode.appendKey ("Snapshot"); rc = saveSnapshot (snapshotNode, aSnapshot, false /* aAttrsOnly */); CheckComRCBreakRC (rc); /* when a new snapshot is added, this means diffs were created * for every normal/immutable hard disk of the VM, so we need to * save the current hard disk attachments */ Key hdaNode = aMachineNode.findKey ("HardDiskAttachments"); if (!hdaNode.isNull()) hdaNode.zap(); hdaNode = aMachineNode.createKey ("HardDiskAttachments"); rc = saveHardDisks (hdaNode); CheckComRCBreakRC (rc); if (mHDData->mAttachments.size() != 0) { /* If we have one or more attachments then we definitely * created diffs for them and associated new diffs with * current settngs. So, since we don't use saveSettings(), * we need to inform callbacks manually. */ if (mType == IsSessionMachine) mParent->onMachineDataChange (mData->mUuid); } } while (0); } while (0); break; } Assert ((op == SaveSS_UpdateAttrsOp && !recreateWholeTree) || op == SaveSS_UpdateAllOp); Key snapshotsNode; Key snapshotNode; if (!recreateWholeTree) { rc = findSnapshotNode (aSnapshot, aMachineNode, &snapshotsNode, &snapshotNode); CheckComRCBreakRC (rc); } if (snapshotsNode.isNull()) snapshotsNode = aMachineNode; if (op == SaveSS_UpdateAttrsOp) rc = saveSnapshot (snapshotNode, aSnapshot, true /* aAttrsOnly */); else { if (!snapshotNode.isNull()) snapshotNode.zap(); snapshotNode = snapshotsNode.appendKey ("Snapshot"); rc = saveSnapshot (snapshotNode, aSnapshot, false /* aAttrsOnly */); CheckComRCBreakRC (rc); } } while (0); if (SUCCEEDED (rc)) { /* update currentSnapshot when appropriate */ if (aOpFlags & SaveSS_CurrentId) { if (!mData->mCurrentSnapshot.isNull()) aMachineNode.setValue ("currentSnapshot", mData->mCurrentSnapshot->data().mId); else aMachineNode.zapValue ("currentSnapshot"); } if (aOpFlags & SaveSS_CurStateModified) { /* defaults to true */ aMachineNode.setValueOr ("currentStateModified", !!mData->mCurrentStateModified, true); } } return rc; } /** * Saves the given snapshot and all its children (unless \a aAttrsOnly is true). * It is assumed that the given node is empty (unless \a aAttrsOnly is true). * * @param aNode node to save the snapshot to. * @param aSnapshot Snapshot to save. * @param aAttrsOnly If true, only updatge user-changeable attrs. */ HRESULT Machine::saveSnapshot (settings::Key &aNode, Snapshot *aSnapshot, bool aAttrsOnly) { using namespace settings; AssertReturn (!aNode.isNull() && aSnapshot, E_INVALIDARG); AssertReturn (mType == IsMachine || mType == IsSessionMachine, E_FAIL); /* uuid (required) */ if (!aAttrsOnly) aNode.setValue ("uuid", aSnapshot->data().mId); /* name (required) */ aNode.setValue ("name", aSnapshot->data().mName); /* timeStamp (required) */ aNode.setValue ("timeStamp", aSnapshot->data().mTimeStamp); /* Description node (optional) */ if (!aSnapshot->data().mDescription.isNull()) { Key descNode = aNode.createKey ("Description"); descNode.setKeyValue (aSnapshot->data().mDescription); } else { Key descNode = aNode.findKey ("Description"); if (!descNode.isNull()) descNode.zap(); } if (aAttrsOnly) return S_OK; /* stateFile (optional) */ if (aSnapshot->stateFilePath()) { /* try to make the file name relative to the settings file dir */ Utf8Str stateFilePath = aSnapshot->stateFilePath(); calculateRelativePath (stateFilePath, stateFilePath); aNode.setStringValue ("stateFile", stateFilePath); } { ComObjPtr snapshotMachine = aSnapshot->data().mMachine; ComAssertRet (!snapshotMachine.isNull(), E_FAIL); /* save hardware */ { Key hwNode = aNode.createKey ("Hardware"); HRESULT rc = snapshotMachine->saveHardware (hwNode); CheckComRCReturnRC (rc); } /* save hard disks */ { Key hdasNode = aNode.createKey ("HardDiskAttachments"); HRESULT rc = snapshotMachine->saveHardDisks (hdasNode); CheckComRCReturnRC (rc); } } /* save children */ { AutoWriteLock listLock (aSnapshot->childrenLock ()); if (aSnapshot->children().size()) { Key snapshotsNode = aNode.createKey ("Snapshots"); HRESULT rc = S_OK; for (Snapshot::SnapshotList::const_iterator it = aSnapshot->children().begin(); it != aSnapshot->children().end(); ++ it) { Key snapshotNode = snapshotsNode.createKey ("Snapshot"); rc = saveSnapshot (snapshotNode, (*it), aAttrsOnly); CheckComRCReturnRC (rc); } } } return S_OK; } /** * Saves the VM hardware configuration. It is assumed that the * given node is empty. * * @param aNode node to save the VM hardware confguration to. */ HRESULT Machine::saveHardware (settings::Key &aNode) { using namespace settings; AssertReturn (!aNode.isNull(), E_INVALIDARG); HRESULT rc = S_OK; /* CPU (optional, but always created atm) */ { Key cpuNode = aNode.createKey ("CPU"); Key hwVirtExNode = cpuNode.createKey ("HardwareVirtEx"); const char *value = NULL; switch (mHWData->mHWVirtExEnabled) { case TSBool_False: value = "false"; break; case TSBool_True: value = "true"; break; case TSBool_Default: value = "default"; break; } hwVirtExNode.setStringValue ("enabled", value); /* Nested paging (optional, default is false) */ if (mHWData->mHWVirtExNestedPagingEnabled) { Key HWVirtExNestedPagingNode = cpuNode.createKey ("HardwareVirtExNestedPaging"); HWVirtExNestedPagingNode.setValue ("enabled", true); } /* VPID (optional, default is false) */ if (mHWData->mHWVirtExVPIDEnabled) { Key HWVirtExVPIDNode = cpuNode.createKey ("HardwareVirtExVPID"); HWVirtExVPIDNode.setValue ("enabled", true); } /* PAE (optional, default is false) */ if (mHWData->mPAEEnabled) { Key PAENode = cpuNode.createKey ("PAE"); PAENode.setValue ("enabled", true); } /* CPU count */ Key CPUCountNode = cpuNode.createKey ("CPUCount"); CPUCountNode.setValue ("count", mHWData->mCPUCount); } /* memory (required) */ { Key memoryNode = aNode.createKey ("Memory"); memoryNode.setValue ("RAMSize", mHWData->mMemorySize); } /* boot (required) */ { Key bootNode = aNode.createKey ("Boot"); for (ULONG pos = 0; pos < ELEMENTS (mHWData->mBootOrder); ++ pos) { const char *device = NULL; switch (mHWData->mBootOrder [pos]) { case DeviceType_Null: /* skip, this is allowed for nodes * when loading, the default value NoDevice will remain */ continue; case DeviceType_Floppy: device = "Floppy"; break; case DeviceType_DVD: device = "DVD"; break; case DeviceType_HardDisk: device = "HardDisk"; break; case DeviceType_Network: device = "Network"; break; default: { ComAssertMsgFailedRet (("Invalid boot device: %d\n", mHWData->mBootOrder [pos]), E_FAIL); } } Key orderNode = bootNode.appendKey ("Order"); orderNode.setValue ("position", pos + 1); orderNode.setStringValue ("device", device); } } /* display (required) */ { Key displayNode = aNode.createKey ("Display"); displayNode.setValue ("VRAMSize", mHWData->mVRAMSize); displayNode.setValue ("MonitorCount", mHWData->mMonitorCount); } #ifdef VBOX_WITH_VRDP /* VRDP settings (optional) */ rc = mVRDPServer->saveSettings (aNode); CheckComRCReturnRC (rc); #endif /* BIOS (required) */ rc = mBIOSSettings->saveSettings (aNode); CheckComRCReturnRC (rc); /* DVD drive (required) */ rc = mDVDDrive->saveSettings (aNode); CheckComRCReturnRC (rc); /* Flooppy drive (required) */ rc = mFloppyDrive->saveSettings (aNode); CheckComRCReturnRC (rc); /* USB Controller (required) */ rc = mUSBController->saveSettings (aNode); CheckComRCReturnRC (rc); /* SATA Controller (required) */ rc = mSATAController->saveSettings (aNode); CheckComRCReturnRC (rc); /* Network adapters (required) */ { Key nwNode = aNode.createKey ("Network"); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); ++ slot) { Key adapterNode = nwNode.appendKey ("Adapter"); adapterNode.setValue ("slot", slot); rc = mNetworkAdapters [slot]->saveSettings (adapterNode); CheckComRCReturnRC (rc); } } /* Serial ports */ { Key serialNode = aNode.createKey ("UART"); for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); ++ slot) { Key portNode = serialNode.appendKey ("Port"); portNode.setValue ("slot", slot); rc = mSerialPorts [slot]->saveSettings (portNode); CheckComRCReturnRC (rc); } } /* Parallel ports */ { Key parallelNode = aNode.createKey ("LPT"); for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); ++ slot) { Key portNode = parallelNode.appendKey ("Port"); portNode.setValue ("slot", slot); rc = mParallelPorts [slot]->saveSettings (portNode); CheckComRCReturnRC (rc); } } /* Audio adapter */ rc = mAudioAdapter->saveSettings (aNode); CheckComRCReturnRC (rc); /* Shared folders */ { Key sharedFoldersNode = aNode.createKey ("SharedFolders"); for (HWData::SharedFolderList::const_iterator it = mHWData->mSharedFolders.begin(); it != mHWData->mSharedFolders.end(); ++ it) { ComObjPtr folder = *it; Key folderNode = sharedFoldersNode.appendKey ("SharedFolder"); /* all are mandatory */ folderNode.setValue ("name", folder->name()); folderNode.setValue ("hostPath", folder->hostPath()); folderNode.setValue ("writable", !!folder->writable()); } } /* Clipboard */ { Key clipNode = aNode.createKey ("Clipboard"); const char *modeStr = "Disabled"; switch (mHWData->mClipboardMode) { case ClipboardMode_Disabled: /* already assigned */ break; case ClipboardMode_HostToGuest: modeStr = "HostToGuest"; break; case ClipboardMode_GuestToHost: modeStr = "GuestToHost"; break; case ClipboardMode_Bidirectional: modeStr = "Bidirectional"; break; default: ComAssertMsgFailedRet (("Clipboard mode %d is invalid", mHWData->mClipboardMode), E_FAIL); } clipNode.setStringValue ("mode", modeStr); } /* Guest */ { Key guestNode = aNode.createKey ("Guest"); guestNode.setValue ("memoryBalloonSize", mHWData->mMemoryBalloonSize); guestNode.setValue ("statisticsUpdateInterval", mHWData->mStatisticsUpdateInterval); } #ifdef VBOX_WITH_GUEST_PROPS /* Guest properties */ try { using namespace guestProp; Key guestPropertiesNode = aNode.createKey ("GuestProperties"); for (HWData::GuestPropertyList::const_iterator it = mHWData->mGuestProperties.begin(); it != mHWData->mGuestProperties.end(); ++it) { HWData::GuestProperty property = *it; Key propertyNode = guestPropertiesNode.appendKey ("GuestProperty"); char szFlags[MAX_FLAGS_LEN + 1]; propertyNode.setValue ("name", property.mName); propertyNode.setValue ("value", property.mValue); propertyNode.setValue ("timestamp", property.mTimestamp); writeFlags(property.mFlags, szFlags); Bstr flags (szFlags); if (flags.isNull()) return E_OUTOFMEMORY; propertyNode.setValue ("flags", flags); } Bstr emptyStr (""); if (emptyStr.isNull()) return E_OUTOFMEMORY; guestPropertiesNode.setValueOr ("notificationPatterns", mHWData->mGuestPropertyNotificationPatterns, emptyStr); } catch (ENoMemory e) { return E_OUTOFMEMORY; } #endif /* VBOX_WITH_GUEST_PROPS defined */ AssertComRC (rc); return rc; } /** * Saves the hard disk confguration. * It is assumed that the given node is empty. * * @param aNode node to save the hard disk confguration to. */ HRESULT Machine::saveHardDisks (settings::Key &aNode) { using namespace settings; AssertReturn (!aNode.isNull(), E_INVALIDARG); for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { ComObjPtr att = *it; Key hdNode = aNode.appendKey ("HardDiskAttachment"); { const char *bus = NULL; switch (att->bus()) { case StorageBus_IDE: bus = "IDE"; break; case StorageBus_SATA: bus = "SATA"; break; default: ComAssertFailedRet (E_FAIL); } /* hard disk uuid (required) */ hdNode.setValue ("hardDisk", att->hardDisk()->id()); /* bus (controller) type (required) */ hdNode.setStringValue ("bus", bus); /* channel (required) */ hdNode.setValue ("channel", att->channel()); /* device (required) */ hdNode.setValue ("device", att->device()); } } return S_OK; } /** * Saves machine state settings as defined by aFlags * (SaveSTS_* values). * * @param aFlags Combination of SaveSTS_* flags. * * @note Locks objects for writing. */ HRESULT Machine::saveStateSettings (int aFlags) { if (aFlags == 0) return S_OK; AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); /* This object's write lock is also necessary to serialize file access * (prevent concurrent reads and writes) */ AutoWriteLock alock (this); AssertReturn (isConfigLocked(), E_FAIL); HRESULT rc = S_OK; try { using namespace settings; /* load the settings file */ File file (mData->mHandleCfgFile, Utf8Str (mData->mConfigFileFull)); XmlTreeBackend tree; rc = VirtualBox::loadSettingsTree_ForUpdate (tree, file); CheckComRCReturnRC (rc); Key machineNode = tree.rootKey().key ("Machine"); if (aFlags & SaveSTS_CurStateModified) { /* defaults to true */ machineNode.setValueOr ("currentStateModified", !!mData->mCurrentStateModified, true); } if (aFlags & SaveSTS_StateFilePath) { if (mSSData->mStateFilePath) { /* try to make the file name relative to the settings file dir */ Utf8Str stateFilePath = mSSData->mStateFilePath; calculateRelativePath (stateFilePath, stateFilePath); machineNode.setStringValue ("stateFile", stateFilePath); } else machineNode.zapValue ("stateFile"); } if (aFlags & SaveSTS_StateTimeStamp) { Assert (mData->mMachineState != MachineState_Aborted || mSSData->mStateFilePath.isNull()); machineNode.setValue ("lastStateChange", mData->mLastStateChange); /* set the aborted attribute when appropriate, defaults to false */ machineNode.setValueOr ("aborted", mData->mMachineState == MachineState_Aborted, false); } /* save settings on success */ rc = VirtualBox::saveSettingsTree (tree, file, mData->mSettingsFileVersion); CheckComRCReturnRC (rc); } catch (...) { rc = VirtualBox::handleUnexpectedExceptions (RT_SRC_POS); } return rc; } /** * Creates differencing hard disks for all normal hard disks attached to this * machine and a new set of attachments to refer to created disks. * * Used when taking a snapshot or when discarding the current state. * * This method assumes that mHDData contains the original hard disk attachments * it needs to create diffs for. On success, these attachments will be replaced * with the created diffs. On failure, #deleteImplicitDiffs() is implicitly * called to delete created diffs which will also rollback mHDData and restore * whatever was backed up before calling this method. * * Attachments with non-normal hard disks are left as is. * * If @a aOnline is @c false then the original hard disks that require implicit * diffs will be locked for reading. Otherwise it is assumed that they are * already locked for writing (when the VM was started). Note that in the latter * case it is responsibility of the caller to lock the newly created diffs for * writing if this method succeeds. * * @param aFolder Folder where to create diff hard disks. * @param aProgress Progress object to run (must contain at least as * many operations left as the number of hard disks * attached). * @param aOnline Whether the VM was online prior to this operation. * * @note The progress object is not marked as completed, neither on success nor * on failure. This is a responsibility of the caller. * * @note Locks this object for writing. */ HRESULT Machine::createImplicitDiffs (const Bstr &aFolder, ComObjPtr &aProgress, bool aOnline) { AssertReturn (!aFolder.isEmpty(), E_FAIL); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); /* must be in a protective state because we leave the lock below */ AssertReturn (mData->mMachineState == MachineState_Saving || mData->mMachineState == MachineState_Discarding, E_FAIL); HRESULT rc = S_OK; typedef std::list > LockedMedia; LockedMedia lockedMedia; try { if (!aOnline) { /* lock all attached hard disks early to to detect "in use" * situations before creating actual diffs */ for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { ComObjPtr hda = *it; ComObjPtr hd = hda->hardDisk(); rc = hd->LockRead (NULL); CheckComRCThrowRC (rc); lockedMedia.push_back (hd); } } /* remember the current list (note that we don't use backup() since * mHDData may be already backed up) */ HDData::AttachmentList atts = mHDData->mAttachments; /* start from scratch */ mHDData->mAttachments.clear(); /* go through remembered attachments and create diffs for normal hard * disks and attach them */ for (HDData::AttachmentList::const_iterator it = atts.begin(); it != atts.end(); ++ it) { ComObjPtr hda = *it; ComObjPtr hd = hda->hardDisk(); /* type cannot be changed while attached => no need to lock */ if (hd->type() != HardDiskType_Normal) { /* copy the attachment as is */ Assert (hd->type() == HardDiskType_Writethrough); rc = aProgress->advanceOperation ( BstrFmt (tr ("Skipping writethrough hard disk '%s'"), hd->root()->name().raw())); CheckComRCThrowRC (rc); mHDData->mAttachments.push_back (hda); continue; } /* need a diff */ rc = aProgress->advanceOperation ( BstrFmt (tr ("Creating differencing hard disk for '%s'"), hd->root()->name().raw())); CheckComRCThrowRC (rc); /// @todo NEWMEDIA use the proper storage format (either the parent /// storage type or the ISystemProperties::defaultHardDiskFormat) ComObjPtr diff; diff.createObject(); rc = diff->init (mParent, Bstr ("VDI"), BstrFmt ("%ls"RTPATH_SLASH_STR, mUserData->mSnapshotFolderFull.raw())); CheckComRCThrowRC (rc); /* leave the lock before the potentially lengthy operation */ alock.leave(); rc = hd->createDiffStorageAndWait (diff, &aProgress); alock.enter(); CheckComRCThrowRC (rc); rc = diff->attachTo (mData->mUuid); AssertComRCThrowRC (rc); /* add a new attachment */ ComObjPtr attachment; attachment.createObject(); rc = attachment->init (diff, hda->bus(), hda->channel(), hda->device(), true /* aImplicit */); CheckComRCThrowRC (rc); mHDData->mAttachments.push_back (attachment); } } catch (HRESULT aRC) { rc = aRC; } /* unlock all hard disks we locked */ if (!aOnline) { ErrorInfoKeeper eik; for (LockedMedia::const_iterator it = lockedMedia.begin(); it != lockedMedia.end(); ++ it) { HRESULT rc2 = (*it)->UnlockRead (NULL); AssertComRC (rc2); } } if (FAILED (rc)) { MultiResultRef mrc (rc); mrc = deleteImplicitDiffs(); } return rc; } /** * Deletes implicit differencing hard disks created either by * #createImplicitDiffs() or by #AttachHardDisk2() and rolls back mHDData. * * Note that to delete hard disks created by #AttachHardDisk2() this method is * called from #fixupHardDisks2() when the changes are rolled back. * * @note Locks this object for writing. */ HRESULT Machine::deleteImplicitDiffs() { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); AssertReturn (mHDData.isBackedUp(), E_FAIL); HRESULT rc = S_OK; HDData::AttachmentList implicitAtts; const HDData::AttachmentList &oldAtts = mHDData.backedUpData()->mAttachments; /* enumerate new attachments */ for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { ComObjPtr hd = (*it)->hardDisk(); if ((*it)->isImplicit()) { implicitAtts.push_back (*it); continue; } /* was this hard disk attached before? */ HDData::AttachmentList::const_iterator oldIt = std::find_if (oldAtts.begin(), oldAtts.end(), HardDisk2Attachment::RefersTo (hd)); if (oldIt == oldAtts.end()) { /* no: de-associate */ rc = hd->detachFrom (mData->mUuid); AssertComRC (rc); } } /* rollback hard disk changes */ mHDData.rollback(); /* delete unused implicit diffs */ if (implicitAtts.size() != 0) { /* will leave the lock before the potentially lengthy * operation, so protect with the special state (unless already * protected) */ MachineState_T oldState = mData->mMachineState; if (oldState != MachineState_Saving && oldState != MachineState_Discarding) { setMachineState (MachineState_SettingUp); } alock.leave(); for (HDData::AttachmentList::const_iterator it = implicitAtts.begin(); it != implicitAtts.end(); ++ it) { ComObjPtr hd = (*it)->hardDisk(); rc = hd->deleteStorageAndWait(); /// @todo NEWMEDIA report the error as a warning here. Note that /// we cannot simply abort the rollback because parts of machine /// data may have been already restored from backup and /// overwrote the recent changes. The best we can do is to /// deassociate the hard disk (to prevent the consistency) but /// leave it undeleted. if (FAILED (rc)) { rc = hd->detachFrom (mData->mUuid); AssertComRC (rc); } } alock.enter(); if (mData->mMachineState == MachineState_SettingUp) { setMachineState (oldState); } } return rc; } /** * Perform deferred hard disk detachments on success and deletion of implicitly * created diffs on failure. * * Does nothing if the hard disk attachment data (mHDData) is not changed (not * backed up). * * When the data is backed up, this method will commit mHDData if @a aCommit is * @c true and rollback it otherwise before returning. * * If @a aOnline is @c true then this method called with @a aCommit = @c true * will also unlock the old hard disks for which the new implicit diffs were * created and will lock these new diffs for writing. When @a aCommit is @c * false, this argument is ignored. * * @param aCommit @c true if called on success. * @param aOnline Whether the VM was online prior to this operation. * * @note Locks this object for writing! */ void Machine::fixupHardDisks2 (bool aCommit, bool aOnline /*= false*/) { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoWriteLock alock (this); /* no attach/detach operations -- nothing to do */ if (!mHDData.isBackedUp()) return; HRESULT rc = S_OK; if (aCommit) { HDData::AttachmentList &oldAtts = mHDData.backedUpData()->mAttachments; /* enumerate new attachments */ for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { ComObjPtr hd = (*it)->hardDisk(); if ((*it)->isImplicit()) { /* convert implicit attachment to normal */ (*it)->setImplicit (false); if (aOnline) { rc = hd->LockWrite (NULL); AssertComRC (rc); /* also, relock the old hard disk which is a base for the * new diff for reading if the VM is online */ ComObjPtr parent = hd->parent(); /* make the relock atomic */ AutoWriteLock parentLock (parent); rc = parent->UnlockWrite (NULL); AssertComRC (rc); rc = parent->LockRead (NULL); AssertComRC (rc); } continue; } /* was this hard disk attached before? */ HDData::AttachmentList::iterator oldIt = std::find_if (oldAtts.begin(), oldAtts.end(), HardDisk2Attachment::RefersTo (hd)); if (oldIt != oldAtts.end()) { /* yes: remove from old to avoid de-association */ oldAtts.erase (oldIt); } } /* enumerate remaining old attachments and de-associate from the * current machine state */ for (HDData::AttachmentList::const_iterator it = oldAtts.begin(); it != oldAtts.end(); ++ it) { ComObjPtr hd = (*it)->hardDisk(); /* now de-associate from the current machine state */ rc = hd->detachFrom (mData->mUuid); AssertComRC (rc); if (aOnline) { /* unlock since not used anymore */ MediaState_T state; rc = hd->UnlockWrite (&state); /* the disk may be alredy relocked for reading above */ Assert (SUCCEEDED (rc) || state == MediaState_LockedRead); } } /* commit the hard disk changes */ mHDData.commit(); if (mType == IsSessionMachine) { /* attach new data to the primary machine and reshare it */ mPeer->mHDData.attach (mHDData); } } else { deleteImplicitDiffs(); } return; } /** * Helper to lock the machine configuration for write access. * * @return S_OK or E_FAIL and sets error info on failure * * @note Doesn't lock anything (must be called from this object's lock) */ HRESULT Machine::lockConfig() { HRESULT rc = S_OK; if (!isConfigLocked()) { /* open the associated config file */ int vrc = RTFileOpen (&mData->mHandleCfgFile, Utf8Str (mData->mConfigFileFull), RTFILE_O_READWRITE | RTFILE_O_OPEN | RTFILE_O_DENY_WRITE); if (VBOX_FAILURE (vrc)) { mData->mHandleCfgFile = NIL_RTFILE; rc = setError (E_FAIL, tr ("Could not lock the settings file '%ls' (%Vrc)"), mData->mConfigFileFull.raw(), vrc); } } LogFlowThisFunc (("mConfigFile={%ls}, mHandleCfgFile=%d, rc=%08X\n", mData->mConfigFileFull.raw(), mData->mHandleCfgFile, rc)); return rc; } /** * Helper to unlock the machine configuration from write access * * @return S_OK * * @note Doesn't lock anything. * @note Not thread safe (must be called from this object's lock). */ HRESULT Machine::unlockConfig() { HRESULT rc = S_OK; if (isConfigLocked()) { RTFileFlush(mData->mHandleCfgFile); RTFileClose(mData->mHandleCfgFile); /** @todo flush the directory. */ mData->mHandleCfgFile = NIL_RTFILE; } LogFlowThisFunc (("\n")); return rc; } /** * Returns true if the settings file is located in the directory named exactly * as the machine. This will be true if the machine settings structure was * created by default in #openConfigLoader(). * * @param aSettingsDir if not NULL, the full machine settings file directory * name will be assigned there. * * @note Doesn't lock anything. * @note Not thread safe (must be called from this object's lock). */ bool Machine::isInOwnDir (Utf8Str *aSettingsDir /* = NULL */) { Utf8Str settingsDir = mData->mConfigFileFull; RTPathStripFilename (settingsDir.mutableRaw()); char *dirName = RTPathFilename (settingsDir); AssertReturn (dirName, false); /* if we don't rename anything on name change, return false shorlty */ if (!mUserData->mNameSync) return false; if (aSettingsDir) *aSettingsDir = settingsDir; return Bstr (dirName) == mUserData->mName; } /** * @note Locks objects for reading! */ bool Machine::isModified() { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), false); AutoReadLock alock (this); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) if (mNetworkAdapters [slot] && mNetworkAdapters [slot]->isModified()) return true; for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) if (mSerialPorts [slot] && mSerialPorts [slot]->isModified()) return true; for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) if (mParallelPorts [slot] && mParallelPorts [slot]->isModified()) return true; return mUserData.isBackedUp() || mHWData.isBackedUp() || mHDData.isBackedUp() || #ifdef VBOX_WITH_VRDP (mVRDPServer && mVRDPServer->isModified()) || #endif (mDVDDrive && mDVDDrive->isModified()) || (mFloppyDrive && mFloppyDrive->isModified()) || (mAudioAdapter && mAudioAdapter->isModified()) || (mUSBController && mUSBController->isModified()) || (mSATAController && mSATAController->isModified()) || (mBIOSSettings && mBIOSSettings->isModified()); } /** * Returns the logical OR of data.hasActualChanges() of this and all child * objects. * * @param aIgnoreUserData @c true to ignore changes to mUserData * * @note Locks objects for reading! */ bool Machine::isReallyModified (bool aIgnoreUserData /* = false */) { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), false); AutoReadLock alock (this); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) if (mNetworkAdapters [slot] && mNetworkAdapters [slot]->isReallyModified()) return true; for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) if (mSerialPorts [slot] && mSerialPorts [slot]->isReallyModified()) return true; for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) if (mParallelPorts [slot] && mParallelPorts [slot]->isReallyModified()) return true; return (!aIgnoreUserData && mUserData.hasActualChanges()) || mHWData.hasActualChanges() || mHDData.hasActualChanges() || #ifdef VBOX_WITH_VRDP (mVRDPServer && mVRDPServer->isReallyModified()) || #endif (mDVDDrive && mDVDDrive->isReallyModified()) || (mFloppyDrive && mFloppyDrive->isReallyModified()) || (mAudioAdapter && mAudioAdapter->isReallyModified()) || (mUSBController && mUSBController->isReallyModified()) || (mSATAController && mSATAController->isReallyModified()) || (mBIOSSettings && mBIOSSettings->isReallyModified()); } /** * Discards all changes to machine settings. * * @param aNotify whether to notify the direct session about changes or not * * @note Locks objects! */ void Machine::rollback (bool aNotify) { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), (void) 0); AutoWriteLock alock (this); /* check for changes in own data */ bool sharedFoldersChanged = false; if (aNotify && mHWData.isBackedUp()) { if (mHWData->mSharedFolders.size() != mHWData.backedUpData()->mSharedFolders.size()) sharedFoldersChanged = true; else { for (HWData::SharedFolderList::iterator rit = mHWData->mSharedFolders.begin(); rit != mHWData->mSharedFolders.end() && !sharedFoldersChanged; ++ rit) { for (HWData::SharedFolderList::iterator cit = mHWData.backedUpData()->mSharedFolders.begin(); cit != mHWData.backedUpData()->mSharedFolders.end(); ++ cit) { if ((*cit)->name() != (*rit)->name() || (*cit)->hostPath() != (*rit)->hostPath()) { sharedFoldersChanged = true; break; } } } } } mUserData.rollback(); mHWData.rollback(); if (mHDData.isBackedUp()) fixupHardDisks2 (false /* aCommit */); /* check for changes in child objects */ bool vrdpChanged = false, dvdChanged = false, floppyChanged = false, usbChanged = false, sataChanged = false; ComPtr networkAdapters [ELEMENTS (mNetworkAdapters)]; ComPtr serialPorts [ELEMENTS (mSerialPorts)]; ComPtr parallelPorts [ELEMENTS (mParallelPorts)]; if (mBIOSSettings) mBIOSSettings->rollback(); #ifdef VBOX_WITH_VRDP if (mVRDPServer) vrdpChanged = mVRDPServer->rollback(); #endif if (mDVDDrive) dvdChanged = mDVDDrive->rollback(); if (mFloppyDrive) floppyChanged = mFloppyDrive->rollback(); if (mAudioAdapter) mAudioAdapter->rollback(); if (mUSBController) usbChanged = mUSBController->rollback(); if (mSATAController) sataChanged = mSATAController->rollback(); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) if (mNetworkAdapters [slot]) if (mNetworkAdapters [slot]->rollback()) networkAdapters [slot] = mNetworkAdapters [slot]; for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) if (mSerialPorts [slot]) if (mSerialPorts [slot]->rollback()) serialPorts [slot] = mSerialPorts [slot]; for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) if (mParallelPorts [slot]) if (mParallelPorts [slot]->rollback()) parallelPorts [slot] = mParallelPorts [slot]; if (aNotify) { /* inform the direct session about changes */ ComObjPtr that = this; alock.leave(); if (sharedFoldersChanged) that->onSharedFolderChange(); if (vrdpChanged) that->onVRDPServerChange(); if (dvdChanged) that->onDVDDriveChange(); if (floppyChanged) that->onFloppyDriveChange(); if (usbChanged) that->onUSBControllerChange(); if (sataChanged) that->onSATAControllerChange(); for (ULONG slot = 0; slot < ELEMENTS (networkAdapters); slot ++) if (networkAdapters [slot]) that->onNetworkAdapterChange (networkAdapters [slot]); for (ULONG slot = 0; slot < ELEMENTS (serialPorts); slot ++) if (serialPorts [slot]) that->onSerialPortChange (serialPorts [slot]); for (ULONG slot = 0; slot < ELEMENTS (parallelPorts); slot ++) if (parallelPorts [slot]) that->onParallelPortChange (parallelPorts [slot]); } } /** * Commits all the changes to machine settings. * * Note that this operation is supposed to never fail. * * @note Locks this object and children for writing. */ void Machine::commit() { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoWriteLock alock (this); /* * use safe commit to ensure Snapshot machines (that share mUserData) * will still refer to a valid memory location */ mUserData.commitCopy(); mHWData.commit(); if (mHDData.isBackedUp()) fixupHardDisks2 (true /* aCommit */); mBIOSSettings->commit(); #ifdef VBOX_WITH_VRDP mVRDPServer->commit(); #endif mDVDDrive->commit(); mFloppyDrive->commit(); mAudioAdapter->commit(); mUSBController->commit(); mSATAController->commit(); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) mNetworkAdapters [slot]->commit(); for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) mSerialPorts [slot]->commit(); for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) mParallelPorts [slot]->commit(); if (mType == IsSessionMachine) { /* attach new data to the primary machine and reshare it */ mPeer->mUserData.attach (mUserData); mPeer->mHWData.attach (mHWData); /* mHDData is reshared by fixupHardDisks2 */ // mPeer->mHDData.attach (mHDData); Assert (mPeer->mHDData.data() == mHDData.data()); } } /** * Copies all the hardware data from the given machine. * * @note * This method must be called from under this object's lock. * @note * This method doesn't call #commit(), so all data remains backed up * and unsaved. */ void Machine::copyFrom (Machine *aThat) { AssertReturn (mType == IsMachine || mType == IsSessionMachine, (void) 0); AssertReturn (aThat->mType == IsSnapshotMachine, (void) 0); mHWData.assignCopy (aThat->mHWData); // create copies of all shared folders (mHWData after attiching a copy // contains just references to original objects) for (HWData::SharedFolderList::iterator it = mHWData->mSharedFolders.begin(); it != mHWData->mSharedFolders.end(); ++ it) { ComObjPtr folder; folder.createObject(); HRESULT rc = folder->initCopy (machine(), *it); AssertComRC (rc); *it = folder; } mBIOSSettings->copyFrom (aThat->mBIOSSettings); #ifdef VBOX_WITH_VRDP mVRDPServer->copyFrom (aThat->mVRDPServer); #endif mDVDDrive->copyFrom (aThat->mDVDDrive); mFloppyDrive->copyFrom (aThat->mFloppyDrive); mAudioAdapter->copyFrom (aThat->mAudioAdapter); mUSBController->copyFrom (aThat->mUSBController); mSATAController->copyFrom (aThat->mSATAController); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) mNetworkAdapters [slot]->copyFrom (aThat->mNetworkAdapters [slot]); for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) mSerialPorts [slot]->copyFrom (aThat->mSerialPorts [slot]); for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) mParallelPorts [slot]->copyFrom (aThat->mParallelPorts [slot]); } #ifdef VBOX_WITH_RESOURCE_USAGE_API void Machine::registerMetrics (PerformanceCollector *aCollector, Machine *aMachine, RTPROCESS pid) { pm::CollectorHAL *hal = aCollector->getHAL(); /* Create sub metrics */ pm::SubMetric *cpuLoadUser = new pm::SubMetric ("CPU/Load/User", "Percentage of processor time spent in user mode by VM process."); pm::SubMetric *cpuLoadKernel = new pm::SubMetric ("CPU/Load/Kernel", "Percentage of processor time spent in kernel mode by VM process."); pm::SubMetric *ramUsageUsed = new pm::SubMetric ("RAM/Usage/Used", "Size of resident portion of VM process in memory."); /* Create and register base metrics */ IUnknown *objptr; ComObjPtr tmp = aMachine; tmp.queryInterfaceTo (&objptr); pm::BaseMetric *cpuLoad = new pm::MachineCpuLoadRaw (hal, objptr, pid, cpuLoadUser, cpuLoadKernel); aCollector->registerBaseMetric (cpuLoad); pm::BaseMetric *ramUsage = new pm::MachineRamUsage (hal, objptr, pid, ramUsageUsed); aCollector->registerBaseMetric (ramUsage); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadUser, 0)); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadUser, new pm::AggregateAvg())); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadUser, new pm::AggregateMin())); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadUser, new pm::AggregateMax())); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadKernel, 0)); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadKernel, new pm::AggregateAvg())); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadKernel, new pm::AggregateMin())); aCollector->registerMetric (new pm::Metric(cpuLoad, cpuLoadKernel, new pm::AggregateMax())); aCollector->registerMetric (new pm::Metric(ramUsage, ramUsageUsed, 0)); aCollector->registerMetric (new pm::Metric(ramUsage, ramUsageUsed, new pm::AggregateAvg())); aCollector->registerMetric (new pm::Metric(ramUsage, ramUsageUsed, new pm::AggregateMin())); aCollector->registerMetric (new pm::Metric(ramUsage, ramUsageUsed, new pm::AggregateMax())); }; void Machine::unregisterMetrics (PerformanceCollector *aCollector, Machine *aMachine) { aCollector->unregisterMetricsFor (aMachine); aCollector->unregisterBaseMetricsFor (aMachine); }; #endif /* VBOX_WITH_RESOURCE_USAGE_API */ ///////////////////////////////////////////////////////////////////////////// // SessionMachine class ///////////////////////////////////////////////////////////////////////////// /** Task structure for asynchronous VM operations */ struct SessionMachine::Task { Task (SessionMachine *m, Progress *p) : machine (m), progress (p) , state (m->mData->mMachineState) // save the current machine state , subTask (false) {} void modifyLastState (MachineState_T s) { *const_cast (&state) = s; } virtual void handler() = 0; ComObjPtr machine; ComObjPtr progress; const MachineState_T state; bool subTask : 1; }; /** Take snapshot task */ struct SessionMachine::TakeSnapshotTask : public SessionMachine::Task { TakeSnapshotTask (SessionMachine *m) : Task (m, NULL) {} void handler() { machine->takeSnapshotHandler (*this); } }; /** Discard snapshot task */ struct SessionMachine::DiscardSnapshotTask : public SessionMachine::Task { DiscardSnapshotTask (SessionMachine *m, Progress *p, Snapshot *s) : Task (m, p) , snapshot (s) {} DiscardSnapshotTask (const Task &task, Snapshot *s) : Task (task) , snapshot (s) {} void handler() { machine->discardSnapshotHandler (*this); } ComObjPtr snapshot; }; /** Discard current state task */ struct SessionMachine::DiscardCurrentStateTask : public SessionMachine::Task { DiscardCurrentStateTask (SessionMachine *m, Progress *p, bool discardCurSnapshot) : Task (m, p), discardCurrentSnapshot (discardCurSnapshot) {} void handler() { machine->discardCurrentStateHandler (*this); } const bool discardCurrentSnapshot; }; //////////////////////////////////////////////////////////////////////////////// DEFINE_EMPTY_CTOR_DTOR (SessionMachine) HRESULT SessionMachine::FinalConstruct() { LogFlowThisFunc (("\n")); /* set the proper type to indicate we're the SessionMachine instance */ unconst (mType) = IsSessionMachine; #if defined(RT_OS_WINDOWS) mIPCSem = NULL; #elif defined(RT_OS_OS2) mIPCSem = NULLHANDLE; #elif defined(VBOX_WITH_SYS_V_IPC_SESSION_WATCHER) mIPCSem = -1; #else # error "Port me!" #endif return S_OK; } void SessionMachine::FinalRelease() { LogFlowThisFunc (("\n")); uninit (Uninit::Unexpected); } /** * @note Must be called only by Machine::openSession() from its own write lock. */ HRESULT SessionMachine::init (Machine *aMachine) { LogFlowThisFuncEnter(); LogFlowThisFunc (("mName={%ls}\n", aMachine->mUserData->mName.raw())); AssertReturn (aMachine, E_INVALIDARG); AssertReturn (aMachine->lockHandle()->isWriteLockOnCurrentThread(), E_FAIL); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan (this); AssertReturn (autoInitSpan.isOk(), E_UNEXPECTED); /* create the interprocess semaphore */ #if defined(RT_OS_WINDOWS) mIPCSemName = aMachine->mData->mConfigFileFull; for (size_t i = 0; i < mIPCSemName.length(); i++) if (mIPCSemName[i] == '\\') mIPCSemName[i] = '/'; mIPCSem = ::CreateMutex (NULL, FALSE, mIPCSemName); ComAssertMsgRet (mIPCSem, ("Cannot create IPC mutex '%ls', err=%d\n", mIPCSemName.raw(), ::GetLastError()), E_FAIL); #elif defined(RT_OS_OS2) Utf8Str ipcSem = Utf8StrFmt ("\\SEM32\\VBOX\\VM\\{%Vuuid}", aMachine->mData->mUuid.raw()); mIPCSemName = ipcSem; APIRET arc = ::DosCreateMutexSem ((PSZ) ipcSem.raw(), &mIPCSem, 0, FALSE); ComAssertMsgRet (arc == NO_ERROR, ("Cannot create IPC mutex '%s', arc=%ld\n", ipcSem.raw(), arc), E_FAIL); #elif defined(VBOX_WITH_SYS_V_IPC_SESSION_WATCHER) Utf8Str configFile = aMachine->mData->mConfigFileFull; char *configFileCP = NULL; int error; RTStrUtf8ToCurrentCP (&configFileCP, configFile); key_t key = ::ftok (configFileCP, 0); RTStrFree (configFileCP); mIPCSem = ::semget (key, 1, S_IRWXU | S_IRWXG | S_IRWXO | IPC_CREAT); error = errno; if (mIPCSem < 0 && error == ENOSYS) { setError(E_FAIL, tr ("Cannot create IPC semaphore. Most likely your host kernel lacks " "support for SysV IPC. Check the host kernel configuration for " "CONFIG_SYSVIPC=y")); return E_FAIL; } ComAssertMsgRet (mIPCSem >= 0, ("Cannot create IPC semaphore, errno=%d", error), E_FAIL); /* set the initial value to 1 */ int rv = ::semctl (mIPCSem, 0, SETVAL, 1); ComAssertMsgRet (rv == 0, ("Cannot init IPC semaphore, errno=%d", errno), E_FAIL); #else # error "Port me!" #endif /* memorize the peer Machine */ unconst (mPeer) = aMachine; /* share the parent pointer */ unconst (mParent) = aMachine->mParent; /* take the pointers to data to share */ mData.share (aMachine->mData); mSSData.share (aMachine->mSSData); mUserData.share (aMachine->mUserData); mHWData.share (aMachine->mHWData); mHDData.share (aMachine->mHDData); unconst (mBIOSSettings).createObject(); mBIOSSettings->init (this, aMachine->mBIOSSettings); #ifdef VBOX_WITH_VRDP /* create another VRDPServer object that will be mutable */ unconst (mVRDPServer).createObject(); mVRDPServer->init (this, aMachine->mVRDPServer); #endif /* create another DVD drive object that will be mutable */ unconst (mDVDDrive).createObject(); mDVDDrive->init (this, aMachine->mDVDDrive); /* create another floppy drive object that will be mutable */ unconst (mFloppyDrive).createObject(); mFloppyDrive->init (this, aMachine->mFloppyDrive); /* create another audio adapter object that will be mutable */ unconst (mAudioAdapter).createObject(); mAudioAdapter->init (this, aMachine->mAudioAdapter); /* create a list of serial ports that will be mutable */ for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) { unconst (mSerialPorts [slot]).createObject(); mSerialPorts [slot]->init (this, aMachine->mSerialPorts [slot]); } /* create a list of parallel ports that will be mutable */ for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) { unconst (mParallelPorts [slot]).createObject(); mParallelPorts [slot]->init (this, aMachine->mParallelPorts [slot]); } /* create another USB controller object that will be mutable */ unconst (mUSBController).createObject(); mUSBController->init (this, aMachine->mUSBController); /* create another SATA controller object that will be mutable */ unconst (mSATAController).createObject(); mSATAController->init (this, aMachine->mSATAController); /* create a list of network adapters that will be mutable */ for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) { unconst (mNetworkAdapters [slot]).createObject(); mNetworkAdapters [slot]->init (this, aMachine->mNetworkAdapters [slot]); } /* Confirm a successful initialization when it's the case */ autoInitSpan.setSucceeded(); LogFlowThisFuncLeave(); return S_OK; } /** * Uninitializes this session object. If the reason is other than * Uninit::Unexpected, then this method MUST be called from #checkForDeath(). * * @param aReason uninitialization reason * * @note Locks mParent + this object for writing. */ void SessionMachine::uninit (Uninit::Reason aReason) { LogFlowThisFuncEnter(); LogFlowThisFunc (("reason=%d\n", aReason)); /* * Strongly reference ourselves to prevent this object deletion after * mData->mSession.mMachine.setNull() below (which can release the last * reference and call the destructor). Important: this must be done before * accessing any members (and before AutoUninitSpan that does it as well). * This self reference will be released as the very last step on return. */ ComObjPtr selfRef = this; /* Enclose the state transition Ready->InUninit->NotReady */ AutoUninitSpan autoUninitSpan (this); if (autoUninitSpan.uninitDone()) { LogFlowThisFunc (("Already uninitialized\n")); LogFlowThisFuncLeave(); return; } if (autoUninitSpan.initFailed()) { /* We've been called by init() because it's failed. It's not really * necessary (nor it's safe) to perform the regular uninit sequense * below, the following is enough. */ LogFlowThisFunc (("Initialization failed.\n")); #if defined(RT_OS_WINDOWS) if (mIPCSem) ::CloseHandle (mIPCSem); mIPCSem = NULL; #elif defined(RT_OS_OS2) if (mIPCSem != NULLHANDLE) ::DosCloseMutexSem (mIPCSem); mIPCSem = NULLHANDLE; #elif defined(VBOX_WITH_SYS_V_IPC_SESSION_WATCHER) if (mIPCSem >= 0) ::semctl (mIPCSem, 0, IPC_RMID); mIPCSem = -1; #else # error "Port me!" #endif uninitDataAndChildObjects(); mData.free(); unconst (mParent).setNull(); unconst (mPeer).setNull(); LogFlowThisFuncLeave(); return; } /* We need to lock this object in uninit() because the lock is shared * with mPeer (as well as data we modify below). mParent->addProcessToReap() * and others need mParent lock. */ AutoMultiWriteLock2 alock (mParent, this); #ifdef VBOX_WITH_RESOURCE_USAGE_API unregisterMetrics (mParent->performanceCollector(), mPeer); #endif /* VBOX_WITH_RESOURCE_USAGE_API */ MachineState_T lastState = mData->mMachineState; if (aReason == Uninit::Abnormal) { LogWarningThisFunc (("ABNORMAL client termination! (wasRunning=%d)\n", lastState >= MachineState_Running)); /* reset the state to Aborted */ if (mData->mMachineState != MachineState_Aborted) setMachineState (MachineState_Aborted); } if (isModified()) { LogWarningThisFunc (("Discarding unsaved settings changes!\n")); rollback (false /* aNotify */); } Assert (!mSnapshotData.mStateFilePath || !mSnapshotData.mSnapshot); if (mSnapshotData.mStateFilePath) { LogWarningThisFunc (("canceling failed save state request!\n")); endSavingState (FALSE /* aSuccess */); } else if (!mSnapshotData.mSnapshot.isNull()) { LogWarningThisFunc (("canceling untaken snapshot!\n")); endTakingSnapshot (FALSE /* aSuccess */); } #ifdef VBOX_WITH_USB /* release all captured USB devices */ if (aReason == Uninit::Abnormal && lastState >= MachineState_Running) { /* Console::captureUSBDevices() is called in the VM process only after * setting the machine state to Starting or Restoring. * Console::detachAllUSBDevices() will be called upon successful * termination. So, we need to release USB devices only if there was * an abnormal termination of a running VM. * * This is identical to SessionMachine::DetachAllUSBDevices except * for the aAbnormal argument. */ HRESULT rc = mUSBController->notifyProxy (false /* aInsertFilters */); AssertComRC (rc); NOREF (rc); USBProxyService *service = mParent->host()->usbProxyService(); if (service) service->detachAllDevicesFromVM (this, true /* aDone */, true /* aAbnormal */); } #endif /* VBOX_WITH_USB */ if (!mData->mSession.mType.isNull()) { /* mType is not null when this machine's process has been started by * VirtualBox::OpenRemoteSession(), therefore it is our child. We * need to queue the PID to reap the process (and avoid zombies on * Linux). */ Assert (mData->mSession.mPid != NIL_RTPROCESS); mParent->addProcessToReap (mData->mSession.mPid); } mData->mSession.mPid = NIL_RTPROCESS; if (aReason == Uninit::Unexpected) { /* Uninitialization didn't come from #checkForDeath(), so tell the * client watcher thread to update the set of machines that have open * sessions. */ mParent->updateClientWatcher(); } /* uninitialize all remote controls */ if (mData->mSession.mRemoteControls.size()) { LogFlowThisFunc (("Closing remote sessions (%d):\n", mData->mSession.mRemoteControls.size())); Data::Session::RemoteControlList::iterator it = mData->mSession.mRemoteControls.begin(); while (it != mData->mSession.mRemoteControls.end()) { LogFlowThisFunc ((" Calling remoteControl->Uninitialize()...\n")); HRESULT rc = (*it)->Uninitialize(); LogFlowThisFunc ((" remoteControl->Uninitialize() returned %08X\n", rc)); if (FAILED (rc)) LogWarningThisFunc (("Forgot to close the remote session?\n")); ++ it; } mData->mSession.mRemoteControls.clear(); } /* * An expected uninitialization can come only from #checkForDeath(). * Otherwise it means that something's got really wrong (for examlple, * the Session implementation has released the VirtualBox reference * before it triggered #OnSessionEnd(), or before releasing IPC semaphore, * etc). However, it's also possible, that the client releases the IPC * semaphore correctly (i.e. before it releases the VirtualBox reference), * but but the VirtualBox release event comes first to the server process. * This case is practically possible, so we should not assert on an * unexpected uninit, just log a warning. */ if ((aReason == Uninit::Unexpected)) LogWarningThisFunc (("Unexpected SessionMachine uninitialization!\n")); if (aReason != Uninit::Normal) { mData->mSession.mDirectControl.setNull(); } else { /* this must be null here (see #OnSessionEnd()) */ Assert (mData->mSession.mDirectControl.isNull()); Assert (mData->mSession.mState == SessionState_Closing); Assert (!mData->mSession.mProgress.isNull()); mData->mSession.mProgress->notifyComplete (S_OK); mData->mSession.mProgress.setNull(); } /* remove the association between the peer machine and this session machine */ Assert (mData->mSession.mMachine == this || aReason == Uninit::Unexpected); /* reset the rest of session data */ mData->mSession.mMachine.setNull(); mData->mSession.mState = SessionState_Closed; mData->mSession.mType.setNull(); /* close the interprocess semaphore before leaving the shared lock */ #if defined(RT_OS_WINDOWS) if (mIPCSem) ::CloseHandle (mIPCSem); mIPCSem = NULL; #elif defined(RT_OS_OS2) if (mIPCSem != NULLHANDLE) ::DosCloseMutexSem (mIPCSem); mIPCSem = NULLHANDLE; #elif defined(VBOX_WITH_SYS_V_IPC_SESSION_WATCHER) if (mIPCSem >= 0) ::semctl (mIPCSem, 0, IPC_RMID); mIPCSem = -1; #else # error "Port me!" #endif /* fire an event */ mParent->onSessionStateChange (mData->mUuid, SessionState_Closed); uninitDataAndChildObjects(); /* free the essential data structure last */ mData.free(); /* leave the shared lock before setting the below two to NULL */ alock.leave(); unconst (mParent).setNull(); unconst (mPeer).setNull(); LogFlowThisFuncLeave(); } // util::Lockable interface //////////////////////////////////////////////////////////////////////////////// /** * Overrides VirtualBoxBase::lockHandle() in order to share the lock handle * with the primary Machine instance (mPeer). */ RWLockHandle *SessionMachine::lockHandle() const { AssertReturn (!mPeer.isNull(), NULL); return mPeer->lockHandle(); } // IInternalMachineControl methods //////////////////////////////////////////////////////////////////////////////// /** * @note Locks the same as #setMachineState() does. */ STDMETHODIMP SessionMachine::UpdateState (MachineState_T machineState) { return setMachineState (machineState); } /** * @note Locks this object for reading. */ STDMETHODIMP SessionMachine::GetIPCId (BSTR *id) { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoReadLock alock (this); #if defined(RT_OS_WINDOWS) || defined(RT_OS_OS2) mIPCSemName.cloneTo (id); return S_OK; #elif defined(VBOX_WITH_SYS_V_IPC_SESSION_WATCHER) mData->mConfigFileFull.cloneTo (id); return S_OK; #else # error "Port me!" #endif } /** * Goes through the USB filters of the given machine to see if the given * device matches any filter or not. * * @note Locks the same as USBController::hasMatchingFilter() does. */ STDMETHODIMP SessionMachine::RunUSBDeviceFilters (IUSBDevice *aUSBDevice, BOOL *aMatched, ULONG *aMaskedIfs) { LogFlowThisFunc (("\n")); if (!aUSBDevice) return E_INVALIDARG; if (!aMatched) return E_POINTER; AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); #ifdef VBOX_WITH_USB *aMatched = mUSBController->hasMatchingFilter (aUSBDevice, aMaskedIfs); #else *aMatched = FALSE; #endif return S_OK; } /** * @note Locks the same as Host::captureUSBDevice() does. */ STDMETHODIMP SessionMachine::CaptureUSBDevice (INPTR GUIDPARAM aId) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); #ifdef VBOX_WITH_USB /* if captureDeviceForVM() fails, it must have set extended error info */ MultiResult rc = mParent->host()->checkUSBProxyService(); CheckComRCReturnRC (rc); USBProxyService *service = mParent->host()->usbProxyService(); AssertReturn (service, E_FAIL); return service->captureDeviceForVM (this, aId); #else return E_FAIL; #endif } /** * @note Locks the same as Host::detachUSBDevice() does. */ STDMETHODIMP SessionMachine::DetachUSBDevice (INPTR GUIDPARAM aId, BOOL aDone) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); #ifdef VBOX_WITH_USB USBProxyService *service = mParent->host()->usbProxyService(); AssertReturn (service, E_FAIL); return service->detachDeviceFromVM (this, aId, !!aDone); #else return E_FAIL; #endif } /** * Inserts all machine filters to the USB proxy service and then calls * Host::autoCaptureUSBDevices(). * * Called by Console from the VM process upon VM startup. * * @note Locks what called methods lock. */ STDMETHODIMP SessionMachine::AutoCaptureUSBDevices() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); #ifdef VBOX_WITH_USB HRESULT rc = mUSBController->notifyProxy (true /* aInsertFilters */); AssertComRC (rc); NOREF (rc); USBProxyService *service = mParent->host()->usbProxyService(); AssertReturn (service, E_FAIL); return service->autoCaptureDevicesForVM (this); #else return S_OK; #endif } /** * Removes all machine filters from the USB proxy service and then calls * Host::detachAllUSBDevices(). * * Called by Console from the VM process upon normal VM termination or by * SessionMachine::uninit() upon abnormal VM termination (from under the * Machine/SessionMachine lock). * * @note Locks what called methods lock. */ STDMETHODIMP SessionMachine::DetachAllUSBDevices(BOOL aDone) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); #ifdef VBOX_WITH_USB HRESULT rc = mUSBController->notifyProxy (false /* aInsertFilters */); AssertComRC (rc); NOREF (rc); USBProxyService *service = mParent->host()->usbProxyService(); AssertReturn (service, E_FAIL); return service->detachAllDevicesFromVM (this, !!aDone, false /* aAbnormal */); #else return S_OK; #endif } /** * @note Locks this object for writing. */ STDMETHODIMP SessionMachine::OnSessionEnd (ISession *aSession, IProgress **aProgress) { LogFlowThisFuncEnter(); AssertReturn (aSession, E_INVALIDARG); AssertReturn (aProgress, E_INVALIDARG); AutoCaller autoCaller (this); LogFlowThisFunc (("state=%d\n", autoCaller.state())); /* * We don't assert below because it might happen that a non-direct session * informs us it is closed right after we've been uninitialized -- it's ok. */ CheckComRCReturnRC (autoCaller.rc()); /* get IInternalSessionControl interface */ ComPtr control (aSession); ComAssertRet (!control.isNull(), E_INVALIDARG); AutoWriteLock alock (this); if (control.equalsTo (mData->mSession.mDirectControl)) { ComAssertRet (aProgress, E_POINTER); /* The direct session is being normally closed by the client process * ----------------------------------------------------------------- */ /* go to the closing state (essential for all open*Session() calls and * for #checkForDeath()) */ Assert (mData->mSession.mState == SessionState_Open); mData->mSession.mState = SessionState_Closing; /* set direct control to NULL to release the remote instance */ mData->mSession.mDirectControl.setNull(); LogFlowThisFunc (("Direct control is set to NULL\n")); /* Create the progress object the client will use to wait until * #checkForDeath() is called to uninitialize this session object after * it releases the IPC semaphore. */ ComObjPtr progress; progress.createObject(); progress->init (mParent, static_cast (mPeer), Bstr (tr ("Closing session")), FALSE /* aCancelable */); progress.queryInterfaceTo (aProgress); mData->mSession.mProgress = progress; } else { /* the remote session is being normally closed */ Data::Session::RemoteControlList::iterator it = mData->mSession.mRemoteControls.begin(); while (it != mData->mSession.mRemoteControls.end()) { if (control.equalsTo (*it)) break; ++it; } BOOL found = it != mData->mSession.mRemoteControls.end(); ComAssertMsgRet (found, ("The session is not found in the session list!"), E_INVALIDARG); mData->mSession.mRemoteControls.remove (*it); } LogFlowThisFuncLeave(); return S_OK; } /** * @note Locks this object for writing. */ STDMETHODIMP SessionMachine::BeginSavingState (IProgress *aProgress, BSTR *aStateFilePath) { LogFlowThisFuncEnter(); AssertReturn (aProgress, E_INVALIDARG); AssertReturn (aStateFilePath, E_POINTER); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); AssertReturn (mData->mMachineState == MachineState_Paused && mSnapshotData.mLastState == MachineState_Null && mSnapshotData.mProgressId.isEmpty() && mSnapshotData.mStateFilePath.isNull(), E_FAIL); /* memorize the progress ID and add it to the global collection */ Guid progressId; HRESULT rc = aProgress->COMGETTER(Id) (progressId.asOutParam()); AssertComRCReturn (rc, rc); rc = mParent->addProgress (aProgress); AssertComRCReturn (rc, rc); Bstr stateFilePath; /* stateFilePath is null when the machine is not running */ if (mData->mMachineState == MachineState_Paused) { stateFilePath = Utf8StrFmt ("%ls%c{%Vuuid}.sav", mUserData->mSnapshotFolderFull.raw(), RTPATH_DELIMITER, mData->mUuid.raw()); } /* fill in the snapshot data */ mSnapshotData.mLastState = mData->mMachineState; mSnapshotData.mProgressId = progressId; mSnapshotData.mStateFilePath = stateFilePath; /* set the state to Saving (this is expected by Console::SaveState()) */ setMachineState (MachineState_Saving); stateFilePath.cloneTo (aStateFilePath); return S_OK; } /** * @note Locks mParent + this object for writing. */ STDMETHODIMP SessionMachine::EndSavingState (BOOL aSuccess) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); /* endSavingState() need mParent lock */ AutoMultiWriteLock2 alock (mParent, this); AssertReturn (mData->mMachineState == MachineState_Saving && mSnapshotData.mLastState != MachineState_Null && !mSnapshotData.mProgressId.isEmpty() && !mSnapshotData.mStateFilePath.isNull(), E_FAIL); /* * on success, set the state to Saved; * on failure, set the state to the state we had when BeginSavingState() was * called (this is expected by Console::SaveState() and * Console::saveStateThread()) */ if (aSuccess) setMachineState (MachineState_Saved); else setMachineState (mSnapshotData.mLastState); return endSavingState (aSuccess); } /** * @note Locks this object for writing. */ STDMETHODIMP SessionMachine::AdoptSavedState (INPTR BSTR aSavedStateFile) { LogFlowThisFunc (("\n")); AssertReturn (aSavedStateFile, E_INVALIDARG); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); AssertReturn (mData->mMachineState == MachineState_PoweredOff || mData->mMachineState == MachineState_Aborted, E_FAIL); Utf8Str stateFilePathFull = aSavedStateFile; int vrc = calculateFullPath (stateFilePathFull, stateFilePathFull); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("Invalid saved state file path '%ls' (%Vrc)"), aSavedStateFile, vrc); mSSData->mStateFilePath = stateFilePathFull; /* The below setMachineState() will detect the state transition and will * update the settings file */ return setMachineState (MachineState_Saved); } /** * @note Locks mParent + this object for writing. */ STDMETHODIMP SessionMachine::BeginTakingSnapshot ( IConsole *aInitiator, INPTR BSTR aName, INPTR BSTR aDescription, IProgress *aProgress, BSTR *aStateFilePath, IProgress **aServerProgress) { LogFlowThisFuncEnter(); AssertReturn (aInitiator && aName, E_INVALIDARG); AssertReturn (aStateFilePath && aServerProgress, E_POINTER); LogFlowThisFunc (("aName='%ls'\n", aName)); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); /* saveSettings() needs mParent lock */ AutoMultiWriteLock2 alock (mParent, this); AssertReturn ((mData->mMachineState < MachineState_Running || mData->mMachineState == MachineState_Paused) && mSnapshotData.mLastState == MachineState_Null && mSnapshotData.mSnapshot.isNull() && mSnapshotData.mServerProgress.isNull() && mSnapshotData.mCombinedProgress.isNull(), E_FAIL); bool takingSnapshotOnline = mData->mMachineState == MachineState_Paused; if (!takingSnapshotOnline && mData->mMachineState != MachineState_Saved) { /* save all current settings to ensure current changes are committed and * hard disks are fixed up */ HRESULT rc = saveSettings(); CheckComRCReturnRC (rc); } /// @todo NEWMEDIA so far, we decided to allow for Writhethrough hard disks /// when taking snapshots putting all the responsibility to the user... #if 0 /* check that there are no Writethrough hard disks attached */ for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { ComObjPtr hd = (*it)->hardDisk(); AutoReadLock hdLock (hd); if (hd->type() == HardDiskType_Writethrough) return setError (E_FAIL, tr ("Cannot take a snapshot because the Writethrough hard disk " "'%ls' is attached to this virtual machine"), hd->locationFull().raw()); } #endif AssertReturn (aProgress || !takingSnapshotOnline, E_FAIL); /* create an ID for the snapshot */ Guid snapshotId; snapshotId.create(); Bstr stateFilePath; /* stateFilePath is null when the machine is not online nor saved */ if (takingSnapshotOnline || mData->mMachineState == MachineState_Saved) stateFilePath = Utf8StrFmt ("%ls%c{%Vuuid}.sav", mUserData->mSnapshotFolderFull.raw(), RTPATH_DELIMITER, snapshotId.ptr()); /* ensure the directory for the saved state file exists */ if (stateFilePath) { HRESULT rc = VirtualBox::ensureFilePathExists (Utf8Str (stateFilePath)); CheckComRCReturnRC (rc); } /* create a snapshot machine object */ ComObjPtr snapshotMachine; snapshotMachine.createObject(); HRESULT rc = snapshotMachine->init (this, snapshotId, stateFilePath); AssertComRCReturn (rc, rc); Bstr progressDesc = BstrFmt (tr ("Taking snapshot of virtual machine '%ls'"), mUserData->mName.raw()); Bstr firstOpDesc = Bstr (tr ("Preparing to take snapshot")); /* create a server-side progress object (it will be descriptionless when we * need to combine it with the VM-side progress, i.e. when we're taking a * snapshot online). The number of operations is: 1 (preparing) + # of * hard disks + 1 (if the state is saved so we need to copy it) */ ComObjPtr serverProgress; serverProgress.createObject(); { ULONG opCount = 1 + mHDData->mAttachments.size(); if (mData->mMachineState == MachineState_Saved) opCount ++; if (takingSnapshotOnline) rc = serverProgress->init (FALSE, opCount, firstOpDesc); else rc = serverProgress->init (mParent, aInitiator, progressDesc, FALSE, opCount, firstOpDesc); AssertComRCReturn (rc, rc); } /* create a combined server-side progress object when necessary */ ComObjPtr combinedProgress; if (takingSnapshotOnline) { combinedProgress.createObject(); rc = combinedProgress->init (mParent, aInitiator, progressDesc, serverProgress, aProgress); AssertComRCReturn (rc, rc); } /* create a snapshot object */ RTTIMESPEC time; ComObjPtr snapshot; snapshot.createObject(); rc = snapshot->init (snapshotId, aName, aDescription, *RTTimeNow (&time), snapshotMachine, mData->mCurrentSnapshot); AssertComRCReturnRC (rc); /* create and start the task on a separate thread (note that it will not * start working until we release alock) */ TakeSnapshotTask *task = new TakeSnapshotTask (this); int vrc = RTThreadCreate (NULL, taskHandler, (void *) task, 0, RTTHREADTYPE_MAIN_WORKER, 0, "TakeSnapshot"); if (VBOX_FAILURE (vrc)) { snapshot->uninit(); delete task; ComAssertRCRet (vrc, E_FAIL); } /* fill in the snapshot data */ mSnapshotData.mLastState = mData->mMachineState; mSnapshotData.mSnapshot = snapshot; mSnapshotData.mServerProgress = serverProgress; mSnapshotData.mCombinedProgress = combinedProgress; /* set the state to Saving (this is expected by Console::TakeSnapshot()) */ setMachineState (MachineState_Saving); if (takingSnapshotOnline) stateFilePath.cloneTo (aStateFilePath); else *aStateFilePath = NULL; serverProgress.queryInterfaceTo (aServerProgress); LogFlowThisFuncLeave(); return S_OK; } /** * @note Locks this object for writing. */ STDMETHODIMP SessionMachine::EndTakingSnapshot (BOOL aSuccess) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); AssertReturn (!aSuccess || (mData->mMachineState == MachineState_Saving && mSnapshotData.mLastState != MachineState_Null && !mSnapshotData.mSnapshot.isNull() && !mSnapshotData.mServerProgress.isNull() && !mSnapshotData.mCombinedProgress.isNull()), E_FAIL); /* set the state to the state we had when BeginTakingSnapshot() was called * (this is expected by Console::TakeSnapshot() and * Console::saveStateThread()) */ setMachineState (mSnapshotData.mLastState); return endTakingSnapshot (aSuccess); } /** * @note Locks mParent + this + children objects for writing! */ STDMETHODIMP SessionMachine::DiscardSnapshot ( IConsole *aInitiator, INPTR GUIDPARAM aId, MachineState_T *aMachineState, IProgress **aProgress) { LogFlowThisFunc (("\n")); Guid id = aId; AssertReturn (aInitiator && !id.isEmpty(), E_INVALIDARG); AssertReturn (aMachineState && aProgress, E_POINTER); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); /* saveSettings() needs mParent lock */ AutoMultiWriteLock2 alock (mParent, this); ComAssertRet (mData->mMachineState < MachineState_Running, E_FAIL); ComObjPtr snapshot; HRESULT rc = findSnapshot (id, snapshot, true /* aSetError */); CheckComRCReturnRC (rc); AutoWriteLock snapshotLock (snapshot); { AutoWriteLock chLock (snapshot->childrenLock()); size_t childrenCount = snapshot->children().size(); if (childrenCount > 1) return setError (E_FAIL, tr ("Snapshot '%ls' of the machine '%ls' has more than one " "child snapshot (%d)"), snapshot->data().mName.raw(), mUserData->mName.raw(), childrenCount); } /* If the snapshot being discarded is the current one, ensure current * settings are committed and saved. */ if (snapshot == mData->mCurrentSnapshot) { if (isModified()) { rc = saveSettings(); CheckComRCReturnRC (rc); } } /* create a progress object. The number of operations is: * 1 (preparing) + # of hard disks + 1 if the snapshot is online */ ComObjPtr progress; progress.createObject(); rc = progress->init (mParent, aInitiator, Bstr (Utf8StrFmt (tr ("Discarding snapshot '%ls'"), snapshot->data().mName.raw())), FALSE /* aCancelable */, 1 + snapshot->data().mMachine->mHDData->mAttachments.size() + (snapshot->stateFilePath().isNull() ? 0 : 1), Bstr (tr ("Preparing to discard snapshot"))); AssertComRCReturn (rc, rc); /* create and start the task on a separate thread */ DiscardSnapshotTask *task = new DiscardSnapshotTask (this, progress, snapshot); int vrc = RTThreadCreate (NULL, taskHandler, (void *) task, 0, RTTHREADTYPE_MAIN_WORKER, 0, "DiscardSnapshot"); if (VBOX_FAILURE (vrc)) delete task; ComAssertRCRet (vrc, E_FAIL); /* set the proper machine state (note: after creating a Task instance) */ setMachineState (MachineState_Discarding); /* return the progress to the caller */ progress.queryInterfaceTo (aProgress); /* return the new state to the caller */ *aMachineState = mData->mMachineState; return S_OK; } /** * @note Locks this + children objects for writing! */ STDMETHODIMP SessionMachine::DiscardCurrentState ( IConsole *aInitiator, MachineState_T *aMachineState, IProgress **aProgress) { LogFlowThisFunc (("\n")); AssertReturn (aInitiator, E_INVALIDARG); AssertReturn (aMachineState && aProgress, E_POINTER); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); ComAssertRet (mData->mMachineState < MachineState_Running, E_FAIL); if (mData->mCurrentSnapshot.isNull()) return setError (E_FAIL, tr ("Could not discard the current state of the machine '%ls' " "because it doesn't have any snapshots"), mUserData->mName.raw()); /* create a progress object. The number of operations is: 1 (preparing) + # * of hard disks + 1 (if we need to copy the saved state file) */ ComObjPtr progress; progress.createObject(); { ULONG opCount = 1 + mData->mCurrentSnapshot->data() .mMachine->mHDData->mAttachments.size(); if (mData->mCurrentSnapshot->stateFilePath()) ++ opCount; progress->init (mParent, aInitiator, Bstr (tr ("Discarding current machine state")), FALSE /* aCancelable */, opCount, Bstr (tr ("Preparing to discard current state"))); } /* create and start the task on a separate thread (note that it will not * start working until we release alock) */ DiscardCurrentStateTask *task = new DiscardCurrentStateTask (this, progress, false /* discardCurSnapshot */); int vrc = RTThreadCreate (NULL, taskHandler, (void *) task, 0, RTTHREADTYPE_MAIN_WORKER, 0, "DiscardCurState"); if (VBOX_FAILURE (vrc)) { delete task; ComAssertRCRet (vrc, E_FAIL); } /* set the proper machine state (note: after creating a Task instance) */ setMachineState (MachineState_Discarding); /* return the progress to the caller */ progress.queryInterfaceTo (aProgress); /* return the new state to the caller */ *aMachineState = mData->mMachineState; return S_OK; } /** * @note Locks thos object for writing! */ STDMETHODIMP SessionMachine::DiscardCurrentSnapshotAndState ( IConsole *aInitiator, MachineState_T *aMachineState, IProgress **aProgress) { LogFlowThisFunc (("\n")); AssertReturn (aInitiator, E_INVALIDARG); AssertReturn (aMachineState && aProgress, E_POINTER); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); ComAssertRet (mData->mMachineState < MachineState_Running, E_FAIL); if (mData->mCurrentSnapshot.isNull()) return setError (E_FAIL, tr ("Could not discard the current state of the machine '%ls' " "because it doesn't have any snapshots"), mUserData->mName.raw()); /* create a progress object. The number of operations is: * 1 (preparing) + # of hard disks in the current snapshot + * # of hard disks in the previous snapshot + * 1 if we need to copy the saved state file of the previous snapshot + * 1 if the current snapshot is online * or (if there is no previous snapshot): * 1 (preparing) + # of hard disks in the current snapshot * 2 + * 1 if we need to copy the saved state file of the current snapshot * 2 */ ComObjPtr progress; progress.createObject(); { ComObjPtr curSnapshot = mData->mCurrentSnapshot; ComObjPtr prevSnapshot = mData->mCurrentSnapshot->parent(); ULONG opCount = 1; if (prevSnapshot) { opCount += curSnapshot->data().mMachine->mHDData->mAttachments.size(); opCount += prevSnapshot->data().mMachine->mHDData->mAttachments.size(); if (prevSnapshot->stateFilePath()) ++ opCount; if (curSnapshot->stateFilePath()) ++ opCount; } else { opCount += curSnapshot->data().mMachine->mHDData->mAttachments.size() * 2; if (curSnapshot->stateFilePath()) opCount += 2; } progress->init (mParent, aInitiator, Bstr (tr ("Discarding current machine snapshot and state")), FALSE /* aCancelable */, opCount, Bstr (tr ("Preparing to discard current snapshot and state"))); } /* create and start the task on a separate thread */ DiscardCurrentStateTask *task = new DiscardCurrentStateTask (this, progress, true /* discardCurSnapshot */); int vrc = RTThreadCreate (NULL, taskHandler, (void *) task, 0, RTTHREADTYPE_MAIN_WORKER, 0, "DiscardCurStSnp"); if (VBOX_FAILURE (vrc)) { delete task; ComAssertRCRet (vrc, E_FAIL); } /* set the proper machine state (note: after creating a Task instance) */ setMachineState (MachineState_Discarding); /* return the progress to the caller */ progress.queryInterfaceTo (aProgress); /* return the new state to the caller */ *aMachineState = mData->mMachineState; return S_OK; } STDMETHODIMP SessionMachine::PullGuestProperties (ComSafeArrayOut(BSTR, aNames), ComSafeArrayOut(BSTR, aValues), ComSafeArrayOut(ULONG64, aTimestamps), ComSafeArrayOut(BSTR, aFlags)) { LogFlowThisFunc (("\n")); #ifdef VBOX_WITH_GUEST_PROPS using namespace guestProp; AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoReadLock alock (this); AssertReturn(!ComSafeArrayOutIsNull (aNames), E_POINTER); AssertReturn(!ComSafeArrayOutIsNull (aValues), E_POINTER); AssertReturn(!ComSafeArrayOutIsNull (aTimestamps), E_POINTER); AssertReturn(!ComSafeArrayOutIsNull (aFlags), E_POINTER); size_t cEntries = mHWData->mGuestProperties.size(); com::SafeArray names(cEntries); com::SafeArray values(cEntries); com::SafeArray timestamps(cEntries); com::SafeArray flags(cEntries); unsigned i = 0; for (HWData::GuestPropertyList::iterator it = mHWData->mGuestProperties.begin(); it != mHWData->mGuestProperties.end(); ++it) { char szFlags[MAX_FLAGS_LEN + 1]; it->mName.cloneTo(&names[i]); it->mValue.cloneTo(&values[i]); timestamps[i] = it->mTimestamp; writeFlags(it->mFlags, szFlags); Bstr(szFlags).cloneTo(&flags[i]); ++i; } names.detachTo(ComSafeArrayOutArg (aNames)); values.detachTo(ComSafeArrayOutArg (aValues)); timestamps.detachTo(ComSafeArrayOutArg (aTimestamps)); flags.detachTo(ComSafeArrayOutArg (aFlags)); mHWData->mPropertyServiceActive = true; return S_OK; #else return E_NOTIMPL; #endif } STDMETHODIMP SessionMachine::PushGuestProperties (ComSafeArrayIn(INPTR BSTR, aNames), ComSafeArrayIn(INPTR BSTR, aValues), ComSafeArrayIn(ULONG64, aTimestamps), ComSafeArrayIn(INPTR BSTR, aFlags)) { LogFlowThisFunc (("\n")); #ifdef VBOX_WITH_GUEST_PROPS using namespace guestProp; AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); /* Temporarily reset the registered flag, so that our machine state * changes (i.e. mHWData.backup()) succeed. (isMutable() used in * all setters will return FALSE for a Machine instance if mRegistered * is TRUE). This is copied from registeredInit(), and may or may not be * the right way to handle this. */ mData->mRegistered = FALSE; HRESULT rc = checkStateDependency (MutableStateDep); LogRel(("checkStateDependency (MutableStateDep) returned 0x%x\n", rc)); CheckComRCReturnRC (rc); // ComAssertRet (mData->mMachineState < MachineState_Running, E_FAIL); AssertReturn(!ComSafeArrayInIsNull (aNames), E_POINTER); AssertReturn(!ComSafeArrayInIsNull (aValues), E_POINTER); AssertReturn(!ComSafeArrayInIsNull (aTimestamps), E_POINTER); AssertReturn(!ComSafeArrayInIsNull (aFlags), E_POINTER); com::SafeArray names(ComSafeArrayInArg(aNames)); com::SafeArray values(ComSafeArrayInArg(aValues)); com::SafeArray timestamps(ComSafeArrayInArg(aTimestamps)); com::SafeArray flags(ComSafeArrayInArg(aFlags)); DiscardSettings(); mHWData.backup(); mHWData->mGuestProperties.erase(mHWData->mGuestProperties.begin(), mHWData->mGuestProperties.end()); for (unsigned i = 0; i < names.size(); ++i) { uint32_t fFlags = NILFLAG; validateFlags (Utf8Str(flags[i]).raw(), &fFlags); HWData::GuestProperty property = { names[i], values[i], timestamps[i], fFlags }; mHWData->mGuestProperties.push_back(property); } mHWData->mPropertyServiceActive = false; alock.unlock(); SaveSettings(); /* Restore the mRegistered flag. */ mData->mRegistered = TRUE; return S_OK; #else return E_NOTIMPL; #endif } STDMETHODIMP SessionMachine::PushGuestProperty (INPTR BSTR aName, INPTR BSTR aValue, ULONG64 aTimestamp, INPTR BSTR aFlags) { LogFlowThisFunc (("\n")); #ifdef VBOX_WITH_GUEST_PROPS using namespace guestProp; if (!VALID_PTR(aName)) return E_POINTER; if ((aValue != NULL) && (!VALID_PTR(aValue) || !VALID_PTR(aFlags))) return E_POINTER; /* aValue can be NULL to indicate deletion */ Utf8Str utf8Name(aName); Utf8Str utf8Flags(aFlags); Utf8Str utf8Patterns(mHWData->mGuestPropertyNotificationPatterns); if ( utf8Name.isNull() || ((aFlags != NULL) && utf8Flags.isNull()) || utf8Patterns.isNull() ) return E_OUTOFMEMORY; uint32_t fFlags = NILFLAG; if ((aFlags != NULL) && RT_FAILURE (validateFlags (utf8Flags.raw(), &fFlags))) return E_INVALIDARG; bool matchAll = false; if (0 == utf8Patterns.length()) matchAll = true; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoWriteLock alock (this); HRESULT rc = checkStateDependency (MutableStateDep); CheckComRCReturnRC (rc); mHWData.backup(); for (HWData::GuestPropertyList::iterator iter = mHWData->mGuestProperties.begin(); iter != mHWData->mGuestProperties.end(); ++iter) if (aName == iter->mName) { mHWData->mGuestProperties.erase(iter); break; } if (aValue != NULL) { HWData::GuestProperty property = { aName, aValue, aTimestamp, fFlags }; mHWData->mGuestProperties.push_back(property); } /* send a callback notification if appropriate */ alock.leave(); if ( matchAll || RTStrSimplePatternMultiMatch (utf8Patterns.raw(), RTSTR_MAX, utf8Name.raw(), RTSTR_MAX, NULL) ) mParent->onGuestPropertyChange (mData->mUuid, aName, aValue, aFlags); return S_OK; #else return E_NOTIMPL; #endif } // public methods only for internal purposes ///////////////////////////////////////////////////////////////////////////// /** * Called from the client watcher thread to check for expected or unexpected * death of the client process that has a direct session to this machine. * * On Win32 and on OS/2, this method is called only when we've got the * mutex (i.e. the client has either died or terminated normally) so it always * returns @c true (the client is terminated, the session machine is * uninitialized). * * On other platforms, the method returns @c true if the client process has * terminated normally or abnormally and the session machine was uninitialized, * and @c false if the client process is still alive. * * @note Locks this object for writing. */ bool SessionMachine::checkForDeath() { Uninit::Reason reason; bool terminated = false; /* Enclose autoCaller with a block because calling uninit() from under it * will deadlock. */ { AutoCaller autoCaller (this); if (!autoCaller.isOk()) { /* return true if not ready, to cause the client watcher to exclude * the corresponding session from watching */ LogFlowThisFunc (("Already uninitialized!")); return true; } AutoWriteLock alock (this); /* Determine the reason of death: if the session state is Closing here, * everything is fine. Otherwise it means that the client did not call * OnSessionEnd() before it released the IPC semaphore. This may happen * either because the client process has abnormally terminated, or * because it simply forgot to call ISession::Close() before exiting. We * threat the latter also as an abnormal termination (see * Session::uninit() for details). */ reason = mData->mSession.mState == SessionState_Closing ? Uninit::Normal : Uninit::Abnormal; #if defined(RT_OS_WINDOWS) AssertMsg (mIPCSem, ("semaphore must be created")); /* release the IPC mutex */ ::ReleaseMutex (mIPCSem); terminated = true; #elif defined(RT_OS_OS2) AssertMsg (mIPCSem, ("semaphore must be created")); /* release the IPC mutex */ ::DosReleaseMutexSem (mIPCSem); terminated = true; #elif defined(VBOX_WITH_SYS_V_IPC_SESSION_WATCHER) AssertMsg (mIPCSem >= 0, ("semaphore must be created")); int val = ::semctl (mIPCSem, 0, GETVAL); if (val > 0) { /* the semaphore is signaled, meaning the session is terminated */ terminated = true; } #else # error "Port me!" #endif } /* AutoCaller block */ if (terminated) uninit (reason); return terminated; } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onDVDDriveChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnDVDDriveChange(); } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onFloppyDriveChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnFloppyDriveChange(); } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onNetworkAdapterChange(INetworkAdapter *networkAdapter) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnNetworkAdapterChange(networkAdapter); } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onSerialPortChange(ISerialPort *serialPort) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnSerialPortChange(serialPort); } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onParallelPortChange(IParallelPort *parallelPort) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnParallelPortChange(parallelPort); } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onVRDPServerChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnVRDPServerChange(); } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onUSBControllerChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnUSBControllerChange(); } /** * @note Locks this object for reading. */ HRESULT SessionMachine::onSharedFolderChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* ignore notifications sent after #OnSessionEnd() is called */ if (!directControl) return S_OK; return directControl->OnSharedFolderChange (FALSE /* aGlobal */); } /** * Returns @c true if this machine's USB controller reports it has a matching * filter for the given USB device and @c false otherwise. * * @note Locks this object for reading. */ bool SessionMachine::hasMatchingUSBFilter (const ComObjPtr &aDevice, ULONG *aMaskedIfs) { AutoCaller autoCaller (this); /* silently return if not ready -- this method may be called after the * direct machine session has been called */ if (!autoCaller.isOk()) return false; AutoReadLock alock (this); #ifdef VBOX_WITH_USB switch (mData->mMachineState) { case MachineState_Starting: case MachineState_Restoring: case MachineState_Paused: case MachineState_Running: return mUSBController->hasMatchingFilter (aDevice, aMaskedIfs); default: break; } #endif return false; } /** * @note The calls shall hold no locks. Will temporarily lock this object for reading. */ HRESULT SessionMachine::onUSBDeviceAttach (IUSBDevice *aDevice, IVirtualBoxErrorInfo *aError, ULONG aMaskedIfs) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); /* This notification may happen after the machine object has been * uninitialized (the session was closed), so don't assert. */ CheckComRCReturnRC (autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* fail on notifications sent after #OnSessionEnd() is called, it is * expected by the caller */ if (!directControl) return E_FAIL; /* No locks should be held at this point. */ AssertMsg (RTThreadGetWriteLockCount (RTThreadSelf()) == 0, ("%d\n", RTThreadGetWriteLockCount (RTThreadSelf()))); AssertMsg (RTThreadGetReadLockCount (RTThreadSelf()) == 0, ("%d\n", RTThreadGetReadLockCount (RTThreadSelf()))); return directControl->OnUSBDeviceAttach (aDevice, aError, aMaskedIfs); } /** * @note The calls shall hold no locks. Will temporarily lock this object for reading. */ HRESULT SessionMachine::onUSBDeviceDetach (INPTR GUIDPARAM aId, IVirtualBoxErrorInfo *aError) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); /* This notification may happen after the machine object has been * uninitialized (the session was closed), so don't assert. */ CheckComRCReturnRC (autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); directControl = mData->mSession.mDirectControl; } /* fail on notifications sent after #OnSessionEnd() is called, it is * expected by the caller */ if (!directControl) return E_FAIL; /* No locks should be held at this point. */ AssertMsg (RTThreadGetWriteLockCount (RTThreadSelf()) == 0, ("%d\n", RTThreadGetWriteLockCount (RTThreadSelf()))); AssertMsg (RTThreadGetReadLockCount (RTThreadSelf()) == 0, ("%d\n", RTThreadGetReadLockCount (RTThreadSelf()))); return directControl->OnUSBDeviceDetach (aId, aError); } // protected methods ///////////////////////////////////////////////////////////////////////////// /** * Helper method to finalize saving the state. * * @note Must be called from under this object's lock. * * @param aSuccess TRUE if the snapshot has been taken successfully * * @note Locks mParent + this objects for writing. */ HRESULT SessionMachine::endSavingState (BOOL aSuccess) { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); /* saveSettings() needs mParent lock */ AutoMultiWriteLock2 alock (mParent, this); HRESULT rc = S_OK; if (aSuccess) { mSSData->mStateFilePath = mSnapshotData.mStateFilePath; /* save all VM settings */ rc = saveSettings(); } else { /* delete the saved state file (it might have been already created) */ RTFileDelete (Utf8Str (mSnapshotData.mStateFilePath)); } /* remove the completed progress object */ mParent->removeProgress (mSnapshotData.mProgressId); /* clear out the temporary saved state data */ mSnapshotData.mLastState = MachineState_Null; mSnapshotData.mProgressId.clear(); mSnapshotData.mStateFilePath.setNull(); LogFlowThisFuncLeave(); return rc; } /** * Helper method to finalize taking a snapshot. Gets called to finalize the * "take snapshot" procedure. * * Expected to be called after completing *all* the tasks related to taking the * snapshot, either successfully or unsuccessfilly. * * @param aSuccess TRUE if the snapshot has been taken successfully. * * @note Locks this objects for writing. */ HRESULT SessionMachine::endTakingSnapshot (BOOL aSuccess) { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); AssertReturn (!mSnapshotData.mSnapshot.isNull(), E_FAIL); MultiResult rc (S_OK); if (aSuccess) { /* the server progress must be completed on success */ Assert (mSnapshotData.mServerProgress->completed()); mData->mCurrentSnapshot = mSnapshotData.mSnapshot; /* memorize the first snapshot if necessary */ if (!mData->mFirstSnapshot) mData->mFirstSnapshot = mData->mCurrentSnapshot; int opFlags = SaveSS_AddOp | SaveSS_CurrentId; if (mSnapshotData.mLastState < MachineState_Running) { /* the machine was powered off or saved when taking a snapshot, so * reset the mCurrentStateModified flag */ mData->mCurrentStateModified = FALSE; opFlags |= SaveSS_CurStateModified; } rc = saveSnapshotSettings (mSnapshotData.mSnapshot, opFlags); } if (aSuccess && SUCCEEDED (rc)) { bool online = mSnapshotData.mLastState >= MachineState_Running; /* associate old hard disks with the snapshot and do locking/unlocking*/ fixupHardDisks2 (true /* aCommit */, online); /* inform callbacks */ mParent->onSnapshotTaken (mData->mUuid, mSnapshotData.mSnapshot->data().mId); } else { /* wait for the completion of the server progress (diff VDI creation) */ /// @todo (dmik) later, we will definitely want to cancel it instead // (when the cancel function is implemented) mSnapshotData.mServerProgress->WaitForCompletion (-1); /* delete all differencing hard disks created (this will also attach * their parents back by rolling back mHDData) */ fixupHardDisks2 (false /* aCommit */); /* delete the saved state file (it might have been already created) */ if (mSnapshotData.mSnapshot->stateFilePath()) RTFileDelete (Utf8Str (mSnapshotData.mSnapshot->stateFilePath())); mSnapshotData.mSnapshot->uninit(); } /* clear out the snapshot data */ mSnapshotData.mLastState = MachineState_Null; mSnapshotData.mSnapshot.setNull(); mSnapshotData.mServerProgress.setNull(); /* uninitialize the combined progress (to remove it from the VBox collection) */ if (!mSnapshotData.mCombinedProgress.isNull()) { mSnapshotData.mCombinedProgress->uninit(); mSnapshotData.mCombinedProgress.setNull(); } LogFlowThisFuncLeave(); return rc; } /** * Take snapshot task handler. Must be called only by * TakeSnapshotTask::handler()! * * The sole purpose of this task is to asynchronously create differencing VDIs * and copy the saved state file (when necessary). The VM process will wait for * this task to complete using the mSnapshotData.mServerProgress returned to it. * * @note Locks this object for writing. */ void SessionMachine::takeSnapshotHandler (TakeSnapshotTask &aTask) { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); LogFlowThisFunc (("state=%d\n", autoCaller.state())); if (!autoCaller.isOk()) { /* we might have been uninitialized because the session was accidentally * closed by the client, so don't assert */ LogFlowThisFuncLeave(); return; } AutoWriteLock alock (this); HRESULT rc = S_OK; bool online = mSnapshotData.mLastState >= MachineState_Running; LogFlowThisFunc (("Creating differencing hard disks (online=%d)...\n", online)); mHDData.backup(); /* create new differencing hard disks and attach them to this machine */ rc = createImplicitDiffs (mUserData->mSnapshotFolderFull, mSnapshotData.mServerProgress, online); if (SUCCEEDED (rc) && mSnapshotData.mLastState == MachineState_Saved) { Utf8Str stateFrom = mSSData->mStateFilePath; Utf8Str stateTo = mSnapshotData.mSnapshot->stateFilePath(); LogFlowThisFunc (("Copying the execution state from '%s' to '%s'...\n", stateFrom.raw(), stateTo.raw())); mSnapshotData.mServerProgress->advanceOperation ( Bstr (tr ("Copying the execution state"))); /* Leave the lock before a lengthy operation (mMachineState is * MachineState_Saving here) */ alock.leave(); /* copy the state file */ int vrc = RTFileCopyEx (stateFrom, stateTo, 0, progressCallback, static_cast (mSnapshotData.mServerProgress)); alock.enter(); if (VBOX_FAILURE (vrc)) rc = setError (E_FAIL, tr ("Could not copy the state file '%ls' to '%ls' (%Vrc)"), stateFrom.raw(), stateTo.raw()); } /* we have to call endTakingSnapshot() ourselves if the snapshot was taken * offline because the VM process will not do it in this case */ if (!online) { LogFlowThisFunc (("Finalizing the taken snapshot (rc=%Rhrc)...\n", rc)); { ErrorInfoKeeper eik; setMachineState (mSnapshotData.mLastState); updateMachineStateOnClient(); } /* finalize the progress after setting the state, for consistency */ mSnapshotData.mServerProgress->notifyComplete (rc); endTakingSnapshot (SUCCEEDED (rc)); } else { mSnapshotData.mServerProgress->notifyComplete (rc); } LogFlowThisFuncLeave(); } /** * Discard snapshot task handler. Must be called only by * DiscardSnapshotTask::handler()! * * When aTask.subTask is true, the associated progress object is left * uncompleted on success. On failure, the progress is marked as completed * regardless of this parameter. * * @note Locks mParent + this + child objects for writing! */ void SessionMachine::discardSnapshotHandler (DiscardSnapshotTask &aTask) { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); LogFlowThisFunc (("state=%d\n", autoCaller.state())); if (!autoCaller.isOk()) { /* we might have been uninitialized because the session was accidentally * closed by the client, so don't assert */ aTask.progress->notifyComplete ( E_FAIL, COM_IIDOF (IMachine), getComponentName(), tr ("The session has been accidentally closed")); LogFlowThisFuncLeave(); return; } /* saveSettings() needs mParent lock */ AutoWriteLock vboxLock (mParent); /* @todo We don't need mParent lock so far so unlock() it. Better is to * provide an AutoWriteLock argument that lets create a non-locking * instance */ vboxLock.unlock(); /* Preseve the {parent, child} lock order for this and snapshot stuff */ AutoMultiWriteLock3 alock (this->lockHandle(), aTask.snapshot->lockHandle(), aTask.snapshot->childrenLock()); ComObjPtr sm = aTask.snapshot->data().mMachine; /* no need to lock the snapshot machine since it is const by definiton */ HRESULT rc = S_OK; /* save the snapshot ID (for callbacks) */ Guid snapshotId = aTask.snapshot->data().mId; typedef std::list , HardDisk2::MergeChain *> > ToDiscard; ToDiscard toDiscard; bool settingsChanged = false; try { /* first pass: */ LogFlowThisFunc (("1: Checking hard disk merge prerequisites...\n")); for (HDData::AttachmentList::const_iterator it = sm->mHDData->mAttachments.begin(); it != sm->mHDData->mAttachments.end(); ++ it) { ComObjPtr hda = *it; ComObjPtr hd = hda->hardDisk(); /* HardDisk2::prepareDiscard() reqiuires a write lock */ AutoWriteLock hdLock (hd); if (hd->type() != HardDiskType_Normal) { /* skip writethrough hard disks */ Assert (hd->type() == HardDiskType_Writethrough); rc = aTask.progress->advanceOperation ( BstrFmt (tr ("Skipping writethrough hard disk '%s'"), hd->root()->name().raw())); CheckComRCThrowRC (rc); continue; } HardDisk2::MergeChain *chain = NULL; /* needs to be discarded (merged with the child if any), check * prerequisites */ rc = hd->prepareDiscard (chain); CheckComRCThrowRC (rc); toDiscard.push_back (std::make_pair (hd, chain)); } /* Now we checked that we can successfully merge all normal hard disks * (unless a runtime error like end-of-disc happens). Prior to * performing the actual merge, we want to discard the snapshot itself * and remove it from the XML file to make sure that a possible merge * ruintime error will not make this snapshot inconsistent because of * the partially merged or corrupted hard disks */ /* second pass: */ LogFlowThisFunc (("2: Discarding snapshot...\n")); { /* for now, the snapshot must have only one child when discarded, * or no children at all */ ComAssertThrow (aTask.snapshot->children().size() <= 1, E_FAIL); ComObjPtr parentSnapshot = aTask.snapshot->parent(); /// @todo (dmik): // when we introduce clones later, discarding the snapshot // will affect the current and first snapshots of clones, if they are // direct children of this snapshot. So we will need to lock machines // associated with child snapshots as well and update mCurrentSnapshot // and/or mFirstSnapshot fields. if (aTask.snapshot == mData->mCurrentSnapshot) { /* currently, the parent snapshot must refer to the same machine */ /// @todo NEWMEDIA not really clear why ComAssertThrow ( !parentSnapshot || parentSnapshot->data().mMachine->mData->mUuid == mData->mUuid, E_FAIL); mData->mCurrentSnapshot = parentSnapshot; /* we've changed the base of the current state so mark it as * modified as it no longer guaranteed to be its copy */ mData->mCurrentStateModified = TRUE; } if (aTask.snapshot == mData->mFirstSnapshot) { if (aTask.snapshot->children().size() == 1) { ComObjPtr childSnapshot = aTask.snapshot->children().front(); ComAssertThrow ( childSnapshot->data().mMachine->mData->mUuid == mData->mUuid, E_FAIL); mData->mFirstSnapshot = childSnapshot; } else mData->mFirstSnapshot.setNull(); } Bstr stateFilePath = aTask.snapshot->stateFilePath(); /* Note that discarding the snapshot will deassociate it from the * hard disks which will allow the merge+delete operation for them*/ aTask.snapshot->discard(); rc = saveSnapshotSettings (parentSnapshot, SaveSS_UpdateAllOp | SaveSS_CurrentId | SaveSS_CurStateModified); CheckComRCThrowRC (rc); /// @todo (dmik) // if we implement some warning mechanism later, we'll have // to return a warning if the state file path cannot be deleted if (stateFilePath) { aTask.progress->advanceOperation ( Bstr (tr ("Discarding the execution state"))); RTFileDelete (Utf8Str (stateFilePath)); } /// @todo NEWMEDIA to provide a good level of fauilt tolerance, we /// should restore the shapshot in the snapshot tree if /// saveSnapshotSettings fails. Actually, we may call /// #saveSnapshotSettings() with a special flag that will tell it to /// skip the given snapshot as if it would have been discarded and /// only actually discard it if the save operation succeeds. } /* here we come when we've irrevesibly discarded the snapshot which * means that the VM settigns (our relevant changes to mData) need to be * saved too */ /// @todo NEWMEDIA maybe save everything in one operation in place of /// saveSnapshotSettings() above settingsChanged = true; /* third pass: */ LogFlowThisFunc (("3: Performing actual hard disk merging...\n")); /* leave the locks before the potentially lengthy operation */ alock.leave(); /// @todo NEWMEDIA turn the following errors into warnings because the /// snapshot itself has been already deleted (and interpret these /// warnings properly on the GUI side) for (ToDiscard::iterator it = toDiscard.begin(); it != toDiscard.end();) { ComObjPtr replaceHd; Guid snapshotId; if (it->first->parent().isNull() && it->second != NULL) { /* it's a base hard disk so it will be a backward merge of its * only child to it. We need then to update the attachment that * refers to the child so get it and detach the child * (otherwise mergeTo() called by discard() will assert because * it will be going to delete the child) */ Assert (it->first->children().size() == 1); replaceHd = it->first->children().front(); Assert (replaceHd->backRefs().front().machineId == mData->mUuid); Assert (replaceHd->backRefs().front().snapshotIds.size() <= 1); if (replaceHd->backRefs().front().snapshotIds.size() == 1) snapshotId = replaceHd->backRefs().front().snapshotIds.front(); HRESULT rc2 = replaceHd->detachFrom (mData->mUuid, snapshotId); AssertComRC (rc2); } rc = it->first->discard (aTask.progress, it->second); if (FAILED (rc)) { /* attach the detached child again */ if (!replaceHd.isNull()) replaceHd->attachTo (mData->mUuid, snapshotId); break; } if (SUCCEEDED (rc) && !replaceHd.isNull()) { /* replace the attachment on success */ alock.enter(); HDData::AttachmentList::iterator jt; if (snapshotId.isEmpty()) { /* in current state */ jt = std::find_if (mHDData->mAttachments.begin(), mHDData->mAttachments.end(), HardDisk2Attachment::RefersTo (replaceHd)); AssertBreakStmt (jt != mHDData->mAttachments.end(), rc = E_FAIL); } else { /* in snapshot */ ComObjPtr snapshot; findSnapshot (snapshotId, snapshot); AssertBreakStmt (!snapshot.isNull(), rc = E_FAIL); /* don't lock the snapshot; cannot be modified outside */ HDData::AttachmentList &snapAtts = snapshot->data().mMachine->mHDData->mAttachments; jt = std::find_if (snapAtts.begin(), snapAtts.end(), HardDisk2Attachment::RefersTo (replaceHd)); AssertBreakStmt (jt != snapAtts.end(), rc = E_FAIL); } { AutoWriteLock attLock (*jt); (*jt)->updateHardDisk (it->first, false /* aImplicit */); } HRESULT rc2 = it->first->attachTo (mData->mUuid, snapshotId); AssertComRC (rc2); alock.leave(); } /* prevent from calling cancelDiscard() */ it = toDiscard.erase (it); } alock.enter(); CheckComRCThrowRC (rc); } catch (HRESULT aRC) { rc = aRC; } if FAILED (rc) { /* un-prepare the remaining hard disks */ for (ToDiscard::const_iterator it = toDiscard.begin(); it != toDiscard.end(); ++ it) it->first->cancelDiscard (it->second); } if (!aTask.subTask || FAILED (rc)) { if (!aTask.subTask) { /* saveSettings() below needs a VirtualBox write lock and we need to * leave this object's lock to do this to follow the {parent-child} * locking rule. This is the last chance to do that while we are * still in a protective state which allows us to temporarily leave * the lock */ alock.unlock(); vboxLock.lock(); alock.lock(); /* preserve existing error info */ ErrorInfoKeeper eik; /* restore the machine state */ setMachineState (aTask.state); updateMachineStateOnClient(); if (settingsChanged) saveSettings (SaveS_InformCallbacksAnyway); } /* set the result (this will try to fetch current error info on failure) */ aTask.progress->notifyComplete (rc); } if (SUCCEEDED (rc)) mParent->onSnapshotDiscarded (mData->mUuid, snapshotId); LogFlowThisFunc (("Done discarding snapshot (rc=%08X)\n", rc)); LogFlowThisFuncLeave(); } /** * Discard current state task handler. Must be called only by * DiscardCurrentStateTask::handler()! * * @note Locks mParent + this object for writing. */ void SessionMachine::discardCurrentStateHandler (DiscardCurrentStateTask &aTask) { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); LogFlowThisFunc (("state=%d\n", autoCaller.state())); if (!autoCaller.isOk()) { /* we might have been uninitialized because the session was accidentally * closed by the client, so don't assert */ aTask.progress->notifyComplete ( E_FAIL, COM_IIDOF (IMachine), getComponentName(), tr ("The session has been accidentally closed")); LogFlowThisFuncLeave(); return; } /* saveSettings() needs mParent lock */ AutoWriteLock vboxLock (mParent); /* @todo We don't need mParent lock so far so unlock() it. Better is to * provide an AutoWriteLock argument that lets create a non-locking * instance */ vboxLock.unlock(); AutoWriteLock alock (this); /* discard all current changes to mUserData (name, OSType etc.) (note that * the machine is powered off, so there is no need to inform the direct * session) */ if (isModified()) rollback (false /* aNotify */); HRESULT rc = S_OK; bool errorInSubtask = false; bool stateRestored = false; const bool isLastSnapshot = mData->mCurrentSnapshot->parent().isNull(); try { /* discard the saved state file if the machine was Saved prior to this * operation */ if (aTask.state == MachineState_Saved) { Assert (!mSSData->mStateFilePath.isEmpty()); RTFileDelete (Utf8Str (mSSData->mStateFilePath)); mSSData->mStateFilePath.setNull(); aTask.modifyLastState (MachineState_PoweredOff); rc = saveStateSettings (SaveSTS_StateFilePath); CheckComRCThrowRC (rc); } if (aTask.discardCurrentSnapshot && !isLastSnapshot) { /* the "discard current snapshot and state" task is in action, the * current snapshot is not the last one. Discard the current * snapshot first */ DiscardSnapshotTask subTask (aTask, mData->mCurrentSnapshot); subTask.subTask = true; discardSnapshotHandler (subTask); AutoCaller progressCaller (aTask.progress); AutoReadLock progressLock (aTask.progress); if (aTask.progress->completed()) { /* the progress can be completed by a subtask only if there was * a failure */ rc = aTask.progress->resultCode(); Assert (FAILED (rc)); errorInSubtask = true; throw rc; } } RTTIMESPEC snapshotTimeStamp; RTTimeSpecSetMilli (&snapshotTimeStamp, 0); { ComObjPtr curSnapshot = mData->mCurrentSnapshot; AutoReadLock snapshotLock (curSnapshot); /* remember the timestamp of the snapshot we're restoring from */ snapshotTimeStamp = curSnapshot->data().mTimeStamp; /* copy all hardware data from the current snapshot */ copyFrom (curSnapshot->data().mMachine); LogFlowThisFunc (("Restoring hard disks from the snapshot...\n")); /* restore the attachmends from the snapshot */ mHDData.backup(); mHDData->mAttachments = curSnapshot->data().mMachine->mHDData->mAttachments; /* leave the locks before the potentially lengthy operation */ snapshotLock.unlock(); alock.leave(); rc = createImplicitDiffs (mUserData->mSnapshotFolderFull, aTask.progress, false /* aOnline */); alock.enter(); snapshotLock.lock(); CheckComRCThrowRC (rc); /* Note: on success, current (old) hard disks will be * deassociated/deleted on #commit() called from #saveSettings() at * the end. On failure, newly created implicit diffs will be * deleted by #rollback() at the end. */ /* should not have a saved state file associated at this point */ Assert (mSSData->mStateFilePath.isNull()); if (curSnapshot->stateFilePath()) { Utf8Str snapStateFilePath = curSnapshot->stateFilePath(); Utf8Str stateFilePath = Utf8StrFmt ("%ls%c{%Vuuid}.sav", mUserData->mSnapshotFolderFull.raw(), RTPATH_DELIMITER, mData->mUuid.raw()); LogFlowThisFunc (("Copying saved state file from '%s' to '%s'...\n", snapStateFilePath.raw(), stateFilePath.raw())); aTask.progress->advanceOperation ( Bstr (tr ("Restoring the execution state"))); /* leave the lock before the potentially lengthy operation */ snapshotLock.unlock(); alock.leave(); /* copy the state file */ int vrc = RTFileCopyEx (snapStateFilePath, stateFilePath, 0, progressCallback, aTask.progress); alock.enter(); snapshotLock.lock(); if (VBOX_SUCCESS (vrc)) { mSSData->mStateFilePath = stateFilePath; } else { throw setError (E_FAIL, tr ("Could not copy the state file '%s' to '%s' (%Vrc)"), snapStateFilePath.raw(), stateFilePath.raw(), vrc); } } } /* grab differencing hard disks from the old attachments that will * become unused and need to be auto-deleted */ std::list > diffs; for (HDData::AttachmentList::const_iterator it = mHDData.backedUpData()->mAttachments.begin(); it != mHDData.backedUpData()->mAttachments.end(); ++ it) { ComObjPtr hd = (*it)->hardDisk(); /* while the hard disk is attached, the number of children or the * parent cannot change, so no lock */ if (!hd->parent().isNull() && hd->children().size() == 0) diffs.push_back (hd); } int saveFlags = 0; if (aTask.discardCurrentSnapshot && isLastSnapshot) { /* commit changes to have unused diffs deassociated from this * machine before deletion (see below) */ commit(); /* delete the unused diffs now (and uninit them) because discard * may fail otherwise (too many children of the hard disk to be * discarded) */ for (std::list >::const_iterator it = diffs.begin(); it != diffs.end(); ++ it) { /// @todo for now, we ignore errors since we've already /// and therefore cannot fail. Later, we may want to report a /// warning through the Progress object HRESULT rc2 = (*it)->deleteStorageAndWait(); if (SUCCEEDED (rc2)) (*it)->uninit(); } /* prevent further deletion */ diffs.clear(); /* discard the current snapshot and state task is in action, the * current snapshot is the last one. Discard the current snapshot * after discarding the current state. */ DiscardSnapshotTask subTask (aTask, mData->mCurrentSnapshot); subTask.subTask = true; discardSnapshotHandler (subTask); AutoCaller progressCaller (aTask.progress); AutoReadLock progressLock (aTask.progress); if (aTask.progress->completed()) { /* the progress can be completed by a subtask only if there * was a failure */ rc = aTask.progress->resultCode(); Assert (FAILED (rc)); errorInSubtask = true; } /* we've committed already, so inform callbacks anyway to ensure * they don't miss some change */ /// @todo NEWMEDIA check if we need this informCallbacks at all /// after updating discardCurrentSnapshot functionality saveFlags |= SaveS_InformCallbacksAnyway; } /* @todo saveSettings() below needs a VirtualBox write lock and we need * to leave this object's lock to do this to follow the {parent-child} * locking rule. This is the last chance to do that while we are still * in a protective state which allows us to temporarily leave the lock*/ alock.unlock(); vboxLock.lock(); alock.lock(); /* we have already discarded the current state, so set the execution * state accordingly no matter of the discard snapshot result */ if (mSSData->mStateFilePath) setMachineState (MachineState_Saved); else setMachineState (MachineState_PoweredOff); updateMachineStateOnClient(); stateRestored = true; /* assign the timestamp from the snapshot */ Assert (RTTimeSpecGetMilli (&snapshotTimeStamp) != 0); mData->mLastStateChange = snapshotTimeStamp; /* save all settings, reset the modified flag and commit. Note that we * do so even if the subtask failed (errorInSubtask=true) because we've * already committed machine data and deleted old diffs before * discarding the current snapshot so there is no way to rollback */ HRESULT rc2 = saveSettings (SaveS_ResetCurStateModified | saveFlags); /// @todo NEWMEDIA return multiple errors if (errorInSubtask) throw rc; rc = rc2; if (SUCCEEDED (rc)) { /* now, delete the unused diffs (only on success!) and uninit them*/ for (std::list >::const_iterator it = diffs.begin(); it != diffs.end(); ++ it) { /// @todo for now, we ignore errors since we've already /// and therefore cannot fail. Later, we may want to report a /// warning through the Progress object HRESULT rc2 = (*it)->deleteStorageAndWait(); if (SUCCEEDED (rc2)) (*it)->uninit(); } } } catch (HRESULT aRC) { rc = aRC; } if (FAILED (rc)) { /* preserve existing error info */ ErrorInfoKeeper eik; if (!errorInSubtask) { /* undo all changes on failure unless the subtask has done so */ rollback (false /* aNotify */); } if (!stateRestored) { /* restore the machine state */ setMachineState (aTask.state); updateMachineStateOnClient(); } } if (!errorInSubtask) { /* set the result (this will try to fetch current error info on failure) */ aTask.progress->notifyComplete (rc); } if (SUCCEEDED (rc)) mParent->onSnapshotDiscarded (mData->mUuid, Guid()); LogFlowThisFunc (("Done discarding current state (rc=%08X)\n", rc)); LogFlowThisFuncLeave(); } /** * Helper to change the machine state (reimplementation). * * @note Locks this object for writing. */ HRESULT SessionMachine::setMachineState (MachineState_T aMachineState) { LogFlowThisFuncEnter(); LogFlowThisFunc (("aMachineState=%d\n", aMachineState)); AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); AutoWriteLock alock (this); MachineState_T oldMachineState = mData->mMachineState; AssertMsgReturn (oldMachineState != aMachineState, ("oldMachineState=%d, aMachineState=%d\n", oldMachineState, aMachineState), E_FAIL); HRESULT rc = S_OK; int stsFlags = 0; bool deleteSavedState = false; /* detect some state transitions */ if ((oldMachineState == MachineState_Saved && aMachineState == MachineState_Restoring) || (oldMachineState < MachineState_Running /* any other OFF state */ && aMachineState == MachineState_Starting)) { /* The EMT thread is about to start */ /* Nothing to do here for now... */ /// @todo NEWMEDIA don't let mDVDDrive and other children /// change anything when in the Starting/Restoring state } else if (oldMachineState >= MachineState_Running && oldMachineState != MachineState_Discarding && oldMachineState != MachineState_SettingUp && aMachineState < MachineState_Running && /* ignore PoweredOff->Saving->PoweredOff transition when taking a * snapshot */ (mSnapshotData.mSnapshot.isNull() || mSnapshotData.mLastState >= MachineState_Running)) { /* The EMT thread has just stopped, unlock attached media. Note that * opposed to locking, we do unlocking here because the VM process may * have just aborted before properly unlocking all media it locked. */ for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { ComObjPtr hd = (*it)->hardDisk(); bool first = true; while (!hd.isNull()) { if (first) { rc = hd->UnlockWrite (NULL); AssertComRC (rc); first = false; } else { rc = hd->UnlockRead (NULL); AssertComRC (rc); } /* no locks or callers here since there should be no way to * change the hard disk parent at this point (as it is still * attached to the machine) */ hd = hd->parent(); } } { AutoReadLock driveLock (mDVDDrive); if (mDVDDrive->data()->mState == DriveState_ImageMounted) { rc = mDVDDrive->data()->mImage->UnlockRead (NULL); AssertComRC (rc); } } { AutoReadLock driveLock (mFloppyDrive); if (mFloppyDrive->data()->mState == DriveState_ImageMounted) { rc = mFloppyDrive->data()->mImage->UnlockRead (NULL); AssertComRC (rc); } } } if (oldMachineState == MachineState_Restoring) { if (aMachineState != MachineState_Saved) { /* * delete the saved state file once the machine has finished * restoring from it (note that Console sets the state from * Restoring to Saved if the VM couldn't restore successfully, * to give the user an ability to fix an error and retry -- * we keep the saved state file in this case) */ deleteSavedState = true; } } else if (oldMachineState == MachineState_Saved && (aMachineState == MachineState_PoweredOff || aMachineState == MachineState_Aborted)) { /* * delete the saved state after Console::DiscardSavedState() is called * or if the VM process (owning a direct VM session) crashed while the * VM was Saved */ /// @todo (dmik) // Not sure that deleting the saved state file just because of the // client death before it attempted to restore the VM is a good // thing. But when it crashes we need to go to the Aborted state // which cannot have the saved state file associated... The only // way to fix this is to make the Aborted condition not a VM state // but a bool flag: i.e., when a crash occurs, set it to true and // change the state to PoweredOff or Saved depending on the // saved state presence. deleteSavedState = true; mData->mCurrentStateModified = TRUE; stsFlags |= SaveSTS_CurStateModified; } if (aMachineState == MachineState_Starting || aMachineState == MachineState_Restoring) { /* set the current state modified flag to indicate that the current * state is no more identical to the state in the * current snapshot */ if (!mData->mCurrentSnapshot.isNull()) { mData->mCurrentStateModified = TRUE; stsFlags |= SaveSTS_CurStateModified; } } if (deleteSavedState == true) { Assert (!mSSData->mStateFilePath.isEmpty()); RTFileDelete (Utf8Str (mSSData->mStateFilePath)); mSSData->mStateFilePath.setNull(); stsFlags |= SaveSTS_StateFilePath; } /* redirect to the underlying peer machine */ mPeer->setMachineState (aMachineState); if (aMachineState == MachineState_PoweredOff || aMachineState == MachineState_Aborted || aMachineState == MachineState_Saved) { /* the machine has stopped execution * (or the saved state file was adopted) */ stsFlags |= SaveSTS_StateTimeStamp; } if ((oldMachineState == MachineState_PoweredOff || oldMachineState == MachineState_Aborted) && aMachineState == MachineState_Saved) { /* the saved state file was adopted */ Assert (!mSSData->mStateFilePath.isNull()); stsFlags |= SaveSTS_StateFilePath; } rc = saveStateSettings (stsFlags); if ((oldMachineState != MachineState_PoweredOff && oldMachineState != MachineState_Aborted) && (aMachineState == MachineState_PoweredOff || aMachineState == MachineState_Aborted)) { /* we've been shut down for any reason */ /* no special action so far */ } LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } /** * Sends the current machine state value to the VM process. * * @note Locks this object for reading, then calls a client process. */ HRESULT SessionMachine::updateMachineStateOnClient() { AutoCaller autoCaller (this); AssertComRCReturn (autoCaller.rc(), autoCaller.rc()); ComPtr directControl; { AutoReadLock alock (this); AssertReturn (!!mData, E_FAIL); directControl = mData->mSession.mDirectControl; /* directControl may be already set to NULL here in #OnSessionEnd() * called too early by the direct session process while there is still * some operation (like discarding the snapshot) in progress. The client * process in this case is waiting inside Session::close() for the * "end session" process object to complete, while #uninit() called by * #checkForDeath() on the Watcher thread is waiting for the pending * operation to complete. For now, we accept this inconsitent behavior * and simply do nothing here. */ if (mData->mSession.mState == SessionState_Closing) return S_OK; AssertReturn (!directControl.isNull(), E_FAIL); } return directControl->UpdateMachineState (mData->mMachineState); } /* static */ DECLCALLBACK(int) SessionMachine::taskHandler (RTTHREAD thread, void *pvUser) { AssertReturn (pvUser, VERR_INVALID_POINTER); Task *task = static_cast (pvUser); task->handler(); // it's our responsibility to delete the task delete task; return 0; } ///////////////////////////////////////////////////////////////////////////// // SnapshotMachine class ///////////////////////////////////////////////////////////////////////////// DEFINE_EMPTY_CTOR_DTOR (SnapshotMachine) HRESULT SnapshotMachine::FinalConstruct() { LogFlowThisFunc (("\n")); /* set the proper type to indicate we're the SnapshotMachine instance */ unconst (mType) = IsSnapshotMachine; return S_OK; } void SnapshotMachine::FinalRelease() { LogFlowThisFunc (("\n")); uninit(); } /** * Initializes the SnapshotMachine object when taking a snapshot. * * @param aSessionMachine machine to take a snapshot from * @param aSnapshotId snapshot ID of this snapshot machine * @param aStateFilePath file where the execution state will be later saved * (or NULL for the offline snapshot) * * @note The aSessionMachine must be locked for writing. */ HRESULT SnapshotMachine::init (SessionMachine *aSessionMachine, INPTR GUIDPARAM aSnapshotId, INPTR BSTR aStateFilePath) { LogFlowThisFuncEnter(); LogFlowThisFunc (("mName={%ls}\n", aSessionMachine->mUserData->mName.raw())); AssertReturn (aSessionMachine && !Guid (aSnapshotId).isEmpty(), E_INVALIDARG); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan (this); AssertReturn (autoInitSpan.isOk(), E_UNEXPECTED); AssertReturn (aSessionMachine->isWriteLockOnCurrentThread(), E_FAIL); mSnapshotId = aSnapshotId; /* memorize the primary Machine instance (i.e. not SessionMachine!) */ unconst (mPeer) = aSessionMachine->mPeer; /* share the parent pointer */ unconst (mParent) = mPeer->mParent; /* take the pointer to Data to share */ mData.share (mPeer->mData); /* take the pointer to UserData to share (our UserData must always be the * same as Machine's data) */ mUserData.share (mPeer->mUserData); /* make a private copy of all other data (recent changes from SessionMachine) */ mHWData.attachCopy (aSessionMachine->mHWData); mHDData.attachCopy (aSessionMachine->mHDData); /* SSData is always unique for SnapshotMachine */ mSSData.allocate(); mSSData->mStateFilePath = aStateFilePath; HRESULT rc = S_OK; /* create copies of all shared folders (mHWData after attiching a copy * contains just references to original objects) */ for (HWData::SharedFolderList::iterator it = mHWData->mSharedFolders.begin(); it != mHWData->mSharedFolders.end(); ++ it) { ComObjPtr folder; folder.createObject(); rc = folder->initCopy (this, *it); CheckComRCReturnRC (rc); *it = folder; } /* associate hard disks with the snapshot * (Machine::uninitDataAndChildObjects() will deassociate at destruction) */ for (HDData::AttachmentList::const_iterator it = mHDData->mAttachments.begin(); it != mHDData->mAttachments.end(); ++ it) { rc = (*it)->hardDisk()->attachTo (mData->mUuid, mSnapshotId); AssertComRC (rc); } /* create all other child objects that will be immutable private copies */ unconst (mBIOSSettings).createObject(); mBIOSSettings->initCopy (this, mPeer->mBIOSSettings); #ifdef VBOX_WITH_VRDP unconst (mVRDPServer).createObject(); mVRDPServer->initCopy (this, mPeer->mVRDPServer); #endif unconst (mDVDDrive).createObject(); mDVDDrive->initCopy (this, mPeer->mDVDDrive); unconst (mFloppyDrive).createObject(); mFloppyDrive->initCopy (this, mPeer->mFloppyDrive); unconst (mAudioAdapter).createObject(); mAudioAdapter->initCopy (this, mPeer->mAudioAdapter); unconst (mUSBController).createObject(); mUSBController->initCopy (this, mPeer->mUSBController); unconst (mSATAController).createObject(); mSATAController->initCopy (this, mPeer->mSATAController); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) { unconst (mNetworkAdapters [slot]).createObject(); mNetworkAdapters [slot]->initCopy (this, mPeer->mNetworkAdapters [slot]); } for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) { unconst (mSerialPorts [slot]).createObject(); mSerialPorts [slot]->initCopy (this, mPeer->mSerialPorts [slot]); } for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) { unconst (mParallelPorts [slot]).createObject(); mParallelPorts [slot]->initCopy (this, mPeer->mParallelPorts [slot]); } /* Confirm a successful initialization when it's the case */ autoInitSpan.setSucceeded(); LogFlowThisFuncLeave(); return S_OK; } /** * Initializes the SnapshotMachine object when loading from the settings file. * * @param aMachine machine the snapshot belngs to * @param aHWNode node * @param aHDAsNode node * @param aSnapshotId snapshot ID of this snapshot machine * @param aStateFilePath file where the execution state is saved * (or NULL for the offline snapshot) * * @note Doesn't lock anything. */ HRESULT SnapshotMachine::init (Machine *aMachine, const settings::Key &aHWNode, const settings::Key &aHDAsNode, INPTR GUIDPARAM aSnapshotId, INPTR BSTR aStateFilePath) { LogFlowThisFuncEnter(); LogFlowThisFunc (("mName={%ls}\n", aMachine->mUserData->mName.raw())); AssertReturn (aMachine && !aHWNode.isNull() && !aHDAsNode.isNull() && !Guid (aSnapshotId).isEmpty(), E_INVALIDARG); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan (this); AssertReturn (autoInitSpan.isOk(), E_UNEXPECTED); /* Don't need to lock aMachine when VirtualBox is starting up */ mSnapshotId = aSnapshotId; /* memorize the primary Machine instance */ unconst (mPeer) = aMachine; /* share the parent pointer */ unconst (mParent) = mPeer->mParent; /* take the pointer to Data to share */ mData.share (mPeer->mData); /* * take the pointer to UserData to share * (our UserData must always be the same as Machine's data) */ mUserData.share (mPeer->mUserData); /* allocate private copies of all other data (will be loaded from settings) */ mHWData.allocate(); mHDData.allocate(); /* SSData is always unique for SnapshotMachine */ mSSData.allocate(); mSSData->mStateFilePath = aStateFilePath; /* create all other child objects that will be immutable private copies */ unconst (mBIOSSettings).createObject(); mBIOSSettings->init (this); #ifdef VBOX_WITH_VRDP unconst (mVRDPServer).createObject(); mVRDPServer->init (this); #endif unconst (mDVDDrive).createObject(); mDVDDrive->init (this); unconst (mFloppyDrive).createObject(); mFloppyDrive->init (this); unconst (mAudioAdapter).createObject(); mAudioAdapter->init (this); unconst (mUSBController).createObject(); mUSBController->init (this); unconst (mSATAController).createObject(); mSATAController->init (this); for (ULONG slot = 0; slot < ELEMENTS (mNetworkAdapters); slot ++) { unconst (mNetworkAdapters [slot]).createObject(); mNetworkAdapters [slot]->init (this, slot); } for (ULONG slot = 0; slot < ELEMENTS (mSerialPorts); slot ++) { unconst (mSerialPorts [slot]).createObject(); mSerialPorts [slot]->init (this, slot); } for (ULONG slot = 0; slot < ELEMENTS (mParallelPorts); slot ++) { unconst (mParallelPorts [slot]).createObject(); mParallelPorts [slot]->init (this, slot); } /* load hardware and harddisk settings */ HRESULT rc = loadHardware (aHWNode); if (SUCCEEDED (rc)) rc = loadHardDisks (aHDAsNode, true /* aRegistered */, &mSnapshotId); if (SUCCEEDED (rc)) { /* commit all changes made during the initialization */ commit(); } /* Confirm a successful initialization when it's the case */ if (SUCCEEDED (rc)) autoInitSpan.setSucceeded(); LogFlowThisFuncLeave(); return rc; } /** * Uninitializes this SnapshotMachine object. */ void SnapshotMachine::uninit() { LogFlowThisFuncEnter(); /* Enclose the state transition Ready->InUninit->NotReady */ AutoUninitSpan autoUninitSpan (this); if (autoUninitSpan.uninitDone()) return; uninitDataAndChildObjects(); /* free the essential data structure last */ mData.free(); unconst (mParent).setNull(); unconst (mPeer).setNull(); LogFlowThisFuncLeave(); } // util::Lockable interface //////////////////////////////////////////////////////////////////////////////// /** * Overrides VirtualBoxBase::lockHandle() in order to share the lock handle * with the primary Machine instance (mPeer). */ RWLockHandle *SnapshotMachine::lockHandle() const { AssertReturn (!mPeer.isNull(), NULL); return mPeer->lockHandle(); } // public methods only for internal purposes //////////////////////////////////////////////////////////////////////////////// /** * Called by the snapshot object associated with this SnapshotMachine when * snapshot data such as name or description is changed. * * @note Locks this object for writing. */ HRESULT SnapshotMachine::onSnapshotChange (Snapshot *aSnapshot) { AutoWriteLock alock (this); mPeer->saveSnapshotSettings (aSnapshot, SaveSS_UpdateAttrsOp); /* inform callbacks */ mParent->onSnapshotChange (mData->mUuid, aSnapshot->data().mId); return S_OK; }