/** @file * * VBox Console COM Class implementation */ /* * Copyright (C) 2006 InnoTek Systemberatung GmbH * * 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 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. * * If you received this file as part of a commercial VirtualBox * distribution, then only the terms of your commercial VirtualBox * license agreement apply instead of the previous paragraph. */ #if defined(__WIN__) #elif defined(__LINUX__) # include # include # include # include # include # include #endif #include "ConsoleImpl.h" #include "GuestImpl.h" #include "KeyboardImpl.h" #include "MouseImpl.h" #include "DisplayImpl.h" #include "MachineDebuggerImpl.h" #include "USBDeviceImpl.h" #include "RemoteUSBDeviceImpl.h" #include "SharedFolderImpl.h" #include "AudioSnifferInterface.h" #include "ConsoleVRDPServer.h" #include "VMMDev.h" // generated header #include "SchemaDefs.h" #include "Logging.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // for auto_ptr // VMTask and friends //////////////////////////////////////////////////////////////////////////////// /** * Task structure for asynchronous VM operations. * * Once created, the task structure adds itself as a Console caller. * This means: * * 1. The user must check for #rc() before using the created structure * (e.g. passing it as a thread function argument). If #rc() returns a * failure, the Console object may not be used by the task (see Console::addCaller() for more details). * 2. On successful initialization, the structure keeps the Console caller * until destruction (to ensure Console remains in the Ready state and won't * be accidentially uninitialized). Forgetting to delete the created task * will lead to Console::uninit() stuck waiting for releasing all added * callers. * * If \a aUsesVMPtr parameter is true, the task structure will also add itself * as a Console::mpVM caller with the same meaning as above. See * Console::addVMCaller() for more info. */ struct VMTask { VMTask (Console *aConsole, bool aUsesVMPtr) : mConsole (aConsole), mCallerAdded (false), mVMCallerAdded (false) { AssertReturnVoid (aConsole); mRC = aConsole->addCaller(); if (SUCCEEDED (mRC)) { mCallerAdded = true; if (aUsesVMPtr) { mRC = aConsole->addVMCaller(); if (SUCCEEDED (mRC)) mVMCallerAdded = true; } } } ~VMTask() { if (mVMCallerAdded) mConsole->releaseVMCaller(); if (mCallerAdded) mConsole->releaseCaller(); } HRESULT rc() const { return mRC; } bool isOk() const { return SUCCEEDED (rc()); } /** Releases the Console caller before destruction. Not normally necessary. */ void releaseCaller() { AssertReturnVoid (mCallerAdded); mConsole->releaseCaller(); mCallerAdded = false; } /** Releases the VM caller before destruction. Not normally necessary. */ void releaseVMCaller() { AssertReturnVoid (mVMCallerAdded); mConsole->releaseVMCaller(); mVMCallerAdded = false; } const ComObjPtr mConsole; private: HRESULT mRC; bool mCallerAdded : 1; bool mVMCallerAdded : 1; }; struct VMProgressTask : public VMTask { VMProgressTask (Console *aConsole, Progress *aProgress, bool aUsesVMPtr) : VMTask (aConsole, aUsesVMPtr), mProgress (aProgress) {} const ComObjPtr mProgress; }; struct VMPowerUpTask : public VMProgressTask { VMPowerUpTask (Console *aConsole, Progress *aProgress) : VMProgressTask (aConsole, aProgress, false /* aUsesVMPtr */) , mSetVMErrorCallback (NULL), mConfigConstructor (NULL) {} PFNVMATERROR mSetVMErrorCallback; PFNCFGMCONSTRUCTOR mConfigConstructor; Utf8Str mSavedStateFile; std::map > mSharedFolders; }; struct VMSaveTask : public VMProgressTask { VMSaveTask (Console *aConsole, Progress *aProgress) : VMProgressTask (aConsole, aProgress, true /* aUsesVMPtr */) , mIsSnapshot (false) , mLastMachineState (MachineState_InvalidMachineState) {} bool mIsSnapshot; Utf8Str mSavedStateFile; MachineState_T mLastMachineState; ComPtr mServerProgress; }; // constructor / desctructor ///////////////////////////////////////////////////////////////////////////// Console::Console() : mSavedStateDataLoaded (false) , mConsoleVRDPServer (NULL) , mpVM (NULL) , mVMCallers (0) , mVMZeroCallersSem (NIL_RTSEMEVENT) , mVMDestroying (false) , meDVDState (DriveState_NotMounted) , meFloppyState (DriveState_NotMounted) , mVMMDev (NULL) , mAudioSniffer (NULL) , mVMStateChangeCallbackDisabled (false) , mMachineState (MachineState_PoweredOff) {} Console::~Console() {} HRESULT Console::FinalConstruct() { LogFlowThisFunc (("\n")); memset(mapFDLeds, 0, sizeof(mapFDLeds)); memset(mapIDELeds, 0, sizeof(mapIDELeds)); memset(mapNetworkLeds, 0, sizeof(mapNetworkLeds)); #ifdef VBOX_WITH_UNIXY_TAP_NETWORKING Assert(ELEMENTS(maTapFD) == ELEMENTS(maTAPDeviceName)); Assert(ELEMENTS(maTapFD) >= SchemaDefs::NetworkAdapterCount); for (unsigned i = 0; i < ELEMENTS(maTapFD); i++) { maTapFD[i] = NIL_RTFILE; maTAPDeviceName[i] = ""; } #endif return S_OK; } void Console::FinalRelease() { LogFlowThisFunc (("\n")); uninit(); } // public initializer/uninitializer for internal purposes only ///////////////////////////////////////////////////////////////////////////// HRESULT Console::init (IMachine *aMachine, IInternalMachineControl *aControl) { AssertReturn (aMachine && aControl, E_INVALIDARG); /* Enclose the state transition NotReady->InInit->Ready */ AutoInitSpan autoInitSpan (this); AssertReturn (autoInitSpan.isOk(), E_UNEXPECTED); LogFlowThisFuncEnter(); LogFlowThisFunc(("aMachine=%p, aControl=%p\n", aMachine, aControl)); HRESULT rc = E_FAIL; unconst (mMachine) = aMachine; unconst (mControl) = aControl; /* Cache essential properties and objects */ rc = mMachine->COMGETTER(State) (&mMachineState); AssertComRCReturn (rc, rc); #ifdef VBOX_VRDP rc = mMachine->COMGETTER(VRDPServer) (unconst (mVRDPServer).asOutParam()); AssertComRCReturn (rc, rc); #endif rc = mMachine->COMGETTER(DVDDrive) (unconst (mDVDDrive).asOutParam()); AssertComRCReturn (rc, rc); rc = mMachine->COMGETTER(FloppyDrive) (unconst (mFloppyDrive).asOutParam()); AssertComRCReturn (rc, rc); /* Create associated child COM objects */ unconst (mGuest).createObject(); rc = mGuest->init (this); AssertComRCReturn (rc, rc); unconst (mKeyboard).createObject(); rc = mKeyboard->init (this); AssertComRCReturn (rc, rc); unconst (mMouse).createObject(); rc = mMouse->init (this); AssertComRCReturn (rc, rc); unconst (mDisplay).createObject(); rc = mDisplay->init (this); AssertComRCReturn (rc, rc); unconst (mRemoteDisplayInfo).createObject(); rc = mRemoteDisplayInfo->init (this); AssertComRCReturn (rc, rc); /* Create other child objects */ unconst (mConsoleVRDPServer) = new ConsoleVRDPServer (this); AssertReturn (mConsoleVRDPServer, E_FAIL); #ifdef VRDP_MC m_cAudioRefs = 0; #endif /* VRDP_MC */ unconst (mVMMDev) = new VMMDev(this); AssertReturn (mVMMDev, E_FAIL); unconst (mAudioSniffer) = new AudioSniffer(this); AssertReturn (mAudioSniffer, E_FAIL); /* Confirm a successful initialization when it's the case */ autoInitSpan.setSucceeded(); LogFlowThisFuncLeave(); return S_OK; } /** * Uninitializes the Console object. */ void Console::uninit() { LogFlowThisFuncEnter(); /* Enclose the state transition Ready->InUninit->NotReady */ AutoUninitSpan autoUninitSpan (this); if (autoUninitSpan.uninitDone()) { LogFlowThisFunc (("Already uninitialized.\n")); LogFlowThisFuncLeave(); return; } LogFlowThisFunc (("initFailed()=%d\n", autoUninitSpan.initFailed())); /* * Uninit all children that ise addDependentChild()/removeDependentChild() * in their init()/uninit() methods. */ uninitDependentChildren(); /* This should be the first, since this may cause detaching remote USB devices. */ if (mConsoleVRDPServer) { delete mConsoleVRDPServer; unconst (mConsoleVRDPServer) = NULL; } /* power down the VM if necessary */ if (mpVM) { powerDown(); Assert (mpVM == NULL); } if (mVMZeroCallersSem != NIL_RTSEMEVENT) { RTSemEventDestroy (mVMZeroCallersSem); mVMZeroCallersSem = NIL_RTSEMEVENT; } if (mAudioSniffer) { delete mAudioSniffer; unconst (mAudioSniffer) = NULL; } if (mVMMDev) { delete mVMMDev; unconst (mVMMDev) = NULL; } mSharedFolders.clear(); mRemoteUSBDevices.clear(); mUSBDevices.clear(); if (mRemoteDisplayInfo) { mRemoteDisplayInfo->uninit(); unconst (mRemoteDisplayInfo).setNull();; } if (mDebugger) { mDebugger->uninit(); unconst (mDebugger).setNull(); } if (mDisplay) { mDisplay->uninit(); unconst (mDisplay).setNull(); } if (mMouse) { mMouse->uninit(); unconst (mMouse).setNull(); } if (mKeyboard) { mKeyboard->uninit(); unconst (mKeyboard).setNull();; } if (mGuest) { mGuest->uninit(); unconst (mGuest).setNull();; } unconst (mFloppyDrive).setNull(); unconst (mDVDDrive).setNull(); #ifdef VBOX_VRDP unconst (mVRDPServer).setNull(); #endif unconst (mControl).setNull(); unconst (mMachine).setNull(); // Release all callbacks. Do this after uninitializing the components, // as some of them are well-behaved and unregister their callbacks. // These would trigger error messages complaining about trying to // unregister a non-registered callback. mCallbacks.clear(); LogFlowThisFuncLeave(); } #ifdef VRDP_MC DECLCALLBACK(int) Console::vrdp_ClientLogon (void *pvUser, uint32_t u32ClientId, const char *pszUser, const char *pszPassword, const char *pszDomain) #else DECLCALLBACK(int) Console::vrdp_ClientLogon (void *pvUser, const char *pszUser, const char *pszPassword, const char *pszDomain) #endif /* VRDP_MC */ { LogFlowFuncEnter(); #ifdef VRDP_MC LogFlowFunc (("%d, %s, %s, %s\n", u32ClientId, pszUser, pszPassword, pszDomain)); #else LogFlowFunc (("%s, %s, %s\n", pszUser, pszPassword, pszDomain)); #endif /* VRDP_MC */ Console *console = static_cast (pvUser); AssertReturn (console, VERR_INVALID_POINTER); AutoCaller autoCaller (console); if (!autoCaller.isOk()) { /* Console has been already uninitialized, deny request */ LogRel(("VRDPAUTH: Access denied (Console uninitialized).\n")); LogFlowFuncLeave(); return VERR_ACCESS_DENIED; } Guid uuid; HRESULT hrc = console->mMachine->COMGETTER (Id) (uuid.asOutParam()); AssertComRCReturn (hrc, VERR_ACCESS_DENIED); VRDPAuthType_T authType = VRDPAuthType_VRDPAuthNull; hrc = console->mVRDPServer->COMGETTER(AuthType) (&authType); AssertComRCReturn (hrc, VERR_ACCESS_DENIED); ULONG authTimeout = 0; hrc = console->mVRDPServer->COMGETTER(AuthTimeout) (&authTimeout); AssertComRCReturn (hrc, VERR_ACCESS_DENIED); VRDPAuthResult result = VRDPAuthAccessDenied; VRDPAuthGuestJudgement guestJudgement = VRDPAuthGuestNotAsked; LogFlowFunc(("Auth type %d\n", authType)); LogRel (("VRDPAUTH: User: [%s]. Domain: [%s]. Authentication type: [%s]\n", pszUser, pszDomain, authType == VRDPAuthType_VRDPAuthNull? "null": (authType == VRDPAuthType_VRDPAuthExternal? "external": (authType == VRDPAuthType_VRDPAuthGuest? "guest": "INVALID" ) ) )); switch (authType) { case VRDPAuthType_VRDPAuthNull: { result = VRDPAuthAccessGranted; break; } case VRDPAuthType_VRDPAuthExternal: { /* Call the external library. */ result = console->mConsoleVRDPServer->Authenticate (uuid, guestJudgement, pszUser, pszPassword, pszDomain); if (result != VRDPAuthDelegateToGuest) { break; } LogRel(("VRDPAUTH: Delegated to guest.\n")); LogFlowFunc (("External auth asked for guest judgement\n")); } /* pass through */ case VRDPAuthType_VRDPAuthGuest: { guestJudgement = VRDPAuthGuestNotReacted; if (console->mVMMDev) { /* Issue the request to guest. Assume that the call does not require EMT. It should not. */ /* Ask the guest to judge these credentials. */ uint32_t u32GuestFlags = VMMDEV_SETCREDENTIALS_JUDGE; int rc = console->mVMMDev->getVMMDevPort()->pfnSetCredentials (console->mVMMDev->getVMMDevPort(), pszUser, pszPassword, pszDomain, u32GuestFlags); if (VBOX_SUCCESS (rc)) { /* Wait for guest. */ rc = console->mVMMDev->WaitCredentialsJudgement (authTimeout, &u32GuestFlags); if (VBOX_SUCCESS (rc)) { switch (u32GuestFlags & (VMMDEV_CREDENTIALS_JUDGE_OK | VMMDEV_CREDENTIALS_JUDGE_DENY | VMMDEV_CREDENTIALS_JUDGE_NOJUDGEMENT)) { case VMMDEV_CREDENTIALS_JUDGE_DENY: guestJudgement = VRDPAuthGuestAccessDenied; break; case VMMDEV_CREDENTIALS_JUDGE_NOJUDGEMENT: guestJudgement = VRDPAuthGuestNoJudgement; break; case VMMDEV_CREDENTIALS_JUDGE_OK: guestJudgement = VRDPAuthGuestAccessGranted; break; default: LogFlowFunc (("Invalid guest flags %08X!!!\n", u32GuestFlags)); break; } } else { LogFlowFunc (("Wait for credentials judgement rc = %Vrc!!!\n", rc)); } LogFlowFunc (("Guest judgement %d\n", guestJudgement)); } else { LogFlowFunc (("Could not set credentials rc = %Vrc!!!\n", rc)); } } if (authType == VRDPAuthType_VRDPAuthExternal) { LogRel(("VRDPAUTH: Guest judgement %d.\n", guestJudgement)); LogFlowFunc (("External auth called again with guest judgement = %d\n", guestJudgement)); result = console->mConsoleVRDPServer->Authenticate (uuid, guestJudgement, pszUser, pszPassword, pszDomain); } else { switch (guestJudgement) { case VRDPAuthGuestAccessGranted: result = VRDPAuthAccessGranted; break; default: result = VRDPAuthAccessDenied; break; } } } break; default: AssertFailed(); } LogFlowFunc (("Result = %d\n", result)); LogFlowFuncLeave(); if (result == VRDPAuthAccessGranted) { LogRel(("VRDPAUTH: Access granted.\n")); return VINF_SUCCESS; } /* Reject. */ LogRel(("VRDPAUTH: Access denied.\n")); return VERR_ACCESS_DENIED; } #ifdef VRDP_MC DECLCALLBACK(void) Console::vrdp_ClientConnect (void *pvUser, uint32_t u32ClientId) #else DECLCALLBACK(void) Console::vrdp_ClientConnect (void *pvUser, uint32_t fu32SupportedOrders) #endif /* VRDP_MC */ { LogFlowFuncEnter(); Console *console = static_cast (pvUser); AssertReturnVoid (console); AutoCaller autoCaller (console); AssertComRCReturnVoid (autoCaller.rc()); #ifdef VBOX_VRDP #ifdef VRDP_MC NOREF(u32ClientId); console->mDisplay->VideoAccelVRDP (true); #else console->mDisplay->VideoAccelVRDP (true, fu32SupportedOrders); #endif /* VRDP_MC */ #endif /* VBOX_VRDP */ LogFlowFuncLeave(); return; } #ifdef VRDP_MC DECLCALLBACK(void) Console::vrdp_ClientDisconnect (void *pvUser, uint32_t u32ClientId, uint32_t fu32Intercepted) #else DECLCALLBACK(void) Console::vrdp_ClientDisconnect (void *pvUser) #endif /* VRDP_MC */ { LogFlowFuncEnter(); Console *console = static_cast (pvUser); AssertReturnVoid (console); AutoCaller autoCaller (console); AssertComRCReturnVoid (autoCaller.rc()); AssertReturnVoid (console->mConsoleVRDPServer); #ifdef VBOX_VRDP #ifdef VRDP_MC console->mDisplay->VideoAccelVRDP (false); #else console->mDisplay->VideoAccelVRDP (false, 0); #endif /* VRDP_MC */ #endif /* VBOX_VRDP */ #ifdef VRDP_MC if (fu32Intercepted & VRDP_CLIENT_INTERCEPT_USB) { console->mConsoleVRDPServer->USBBackendDelete (u32ClientId); } #else console->mConsoleVRDPServer->DeleteUSBBackend (); #endif /* VRDP_MC */ #ifdef VBOX_VRDP #ifdef VRDP_MC if (fu32Intercepted & VRDP_CLIENT_INTERCEPT_AUDIO) { console->m_cAudioRefs--; if (console->m_cAudioRefs <= 0) { if (console->mAudioSniffer) { PPDMIAUDIOSNIFFERPORT port = console->mAudioSniffer->getAudioSnifferPort(); if (port) { port->pfnSetup (port, false, false); } } } } #else if (console->mAudioSniffer) { PPDMIAUDIOSNIFFERPORT port = console->mAudioSniffer->getAudioSnifferPort(); if (port) { port->pfnSetup (port, false, false); } } #endif /* VRDP_MC */ #endif /* VBOX_VRDP */ LogFlowFuncLeave(); return; } #ifdef VRDP_MC DECLCALLBACK(void) Console::vrdp_InterceptAudio (void *pvUser, uint32_t u32ClientId) #else DECLCALLBACK(void) Console::vrdp_InterceptAudio (void *pvUser, bool fKeepHostAudio) #endif /* VRDP_MC */ { LogFlowFuncEnter(); Console *console = static_cast (pvUser); AssertReturnVoid (console); AutoCaller autoCaller (console); AssertComRCReturnVoid (autoCaller.rc()); #ifdef VRDP_MC LogFlowFunc (("mAudioSniffer %p, u32ClientId %d.\n", console->mAudioSniffer, u32ClientId)); NOREF(u32ClientId); #else LogFlowFunc (("mAudioSniffer %p, keepHostAudio %d.\n", console->mAudioSniffer, fKeepHostAudio)); #endif /* VRDP_MC */ #ifdef VBOX_VRDP #ifdef VRDP_MC console->m_cAudioRefs++; if (console->m_cAudioRefs == 1) { if (console->mAudioSniffer) { PPDMIAUDIOSNIFFERPORT port = console->mAudioSniffer->getAudioSnifferPort(); if (port) { port->pfnSetup (port, true, true); } } } #else if (console->mAudioSniffer) { PPDMIAUDIOSNIFFERPORT port = console->mAudioSniffer->getAudioSnifferPort(); if (port) { port->pfnSetup (port, true, !!fKeepHostAudio); } } #endif /* VRDP_MC */ #endif LogFlowFuncLeave(); return; } #ifdef VRDP_MC DECLCALLBACK(void) Console::vrdp_InterceptUSB (void *pvUser, uint32_t u32ClientId, PFNVRDPUSBCALLBACK *ppfn, void **ppv) #else DECLCALLBACK(void) Console::vrdp_InterceptUSB (void *pvUser, PFNVRDPUSBCALLBACK *ppfn, void **ppv) #endif /* VRDP_MC */ { LogFlowFuncEnter(); Console *console = static_cast (pvUser); AssertReturnVoid (console); AutoCaller autoCaller (console); AssertComRCReturnVoid (autoCaller.rc()); AssertReturnVoid (console->mConsoleVRDPServer); #ifdef VRDP_MC console->mConsoleVRDPServer->USBBackendCreate (u32ClientId, ppfn, ppv); #else console->mConsoleVRDPServer->CreateUSBBackend (ppfn, ppv); #endif /* VRDP_MC */ LogFlowFuncLeave(); return; } // static VRDPSERVERCALLBACK Console::sVrdpServerCallback = { vrdp_ClientLogon, vrdp_ClientConnect, vrdp_ClientDisconnect, vrdp_InterceptAudio, vrdp_InterceptUSB }; //static char *Console::sSSMConsoleUnit = "ConsoleData"; //static uint32_t Console::sSSMConsoleVer = 0x00010000; /** * Loads various console data stored in the saved state file. * This method does validation of the state file and returns an error info * when appropriate. * * The method does nothing if the machine is not in the Saved file or if * console data from it has already been loaded. * * @note The caller must lock this object for writing. */ HRESULT Console::loadDataFromSavedState() { if (mMachineState != MachineState_Saved || mSavedStateDataLoaded) return S_OK; Bstr savedStateFile; HRESULT rc = mMachine->COMGETTER(StateFilePath) (savedStateFile.asOutParam()); if (FAILED (rc)) return rc; PSSMHANDLE ssm; int vrc = SSMR3Open (Utf8Str(savedStateFile), 0, &ssm); if (VBOX_SUCCESS (vrc)) { uint32_t version = 0; vrc = SSMR3Seek (ssm, sSSMConsoleUnit, 0 /* iInstance */, &version); if (version == sSSMConsoleVer) { if (VBOX_SUCCESS (vrc)) vrc = loadStateFileExec (ssm, this, 0); else if (vrc == VERR_SSM_UNIT_NOT_FOUND) vrc = VINF_SUCCESS; } else vrc = VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION; SSMR3Close (ssm); } if (VBOX_FAILURE (vrc)) rc = setError (E_FAIL, tr ("The saved state file '%ls' is invalid (%Vrc). " "Discard the saved state and try again"), savedStateFile.raw(), vrc); mSavedStateDataLoaded = true; return rc; } /** * Callback handler to save various console data to the state file, * called when the user saves the VM state. * * @param pvUser pointer to Console * * @note Locks the Console object for reading. */ //static DECLCALLBACK(void) Console::saveStateFileExec (PSSMHANDLE pSSM, void *pvUser) { LogFlowFunc (("\n")); Console *that = static_cast (pvUser); AssertReturnVoid (that); AutoCaller autoCaller (that); AssertComRCReturnVoid (autoCaller.rc()); AutoReaderLock alock (that); int vrc = SSMR3PutU32 (pSSM, that->mSharedFolders.size()); AssertRC (vrc); for (SharedFolderList::const_iterator it = that->mSharedFolders.begin(); it != that->mSharedFolders.end(); ++ it) { ComObjPtr folder = (*it); AutoLock folderLock (folder); Utf8Str name = folder->name(); vrc = SSMR3PutU32 (pSSM, name.length() + 1 /* term. 0 */); AssertRC (vrc); vrc = SSMR3PutStrZ (pSSM, name); AssertRC (vrc); Utf8Str hostPath = folder->hostPath(); vrc = SSMR3PutU32 (pSSM, hostPath.length() + 1 /* term. 0 */); AssertRC (vrc); vrc = SSMR3PutStrZ (pSSM, hostPath); AssertRC (vrc); } return; } /** * Callback handler to load various console data from the state file. * When \a u32Version is 0, this method is called from #loadDataFromSavedState, * otherwise it is called when the VM is being restored from the saved state. * * @param pvUser pointer to Console * @param u32Version Console unit version. * When not 0, should match sSSMConsoleVer. * * @note Locks the Console object for writing. */ //static DECLCALLBACK(int) Console::loadStateFileExec (PSSMHANDLE pSSM, void *pvUser, uint32_t u32Version) { LogFlowFunc (("\n")); if (u32Version != 0 && u32Version != sSSMConsoleVer) return VERR_VERSION_MISMATCH; if (u32Version != 0) { /* currently, nothing to do when we've been called from VMR3Load */ return VINF_SUCCESS; } Console *that = static_cast (pvUser); AssertReturn (that, VERR_INVALID_PARAMETER); AutoCaller autoCaller (that); AssertComRCReturn (autoCaller.rc(), VERR_ACCESS_DENIED); AutoLock alock (that); AssertReturn (that->mSharedFolders.size() == 0, VERR_INTERNAL_ERROR); uint32_t size = 0; int vrc = SSMR3GetU32 (pSSM, &size); AssertRCReturn (vrc, vrc); for (uint32_t i = 0; i < size; ++ i) { Bstr name; Bstr hostPath; uint32_t szBuf = 0; char *buf = NULL; vrc = SSMR3GetU32 (pSSM, &szBuf); AssertRCReturn (vrc, vrc); buf = new char [szBuf]; vrc = SSMR3GetStrZ (pSSM, buf, szBuf); AssertRC (vrc); name = buf; delete[] buf; vrc = SSMR3GetU32 (pSSM, &szBuf); AssertRCReturn (vrc, vrc); buf = new char [szBuf]; vrc = SSMR3GetStrZ (pSSM, buf, szBuf); AssertRC (vrc); hostPath = buf; delete[] buf; ComObjPtr sharedFolder; sharedFolder.createObject(); HRESULT rc = sharedFolder->init (that, name, hostPath); AssertComRCReturn (rc, VERR_INTERNAL_ERROR); if (FAILED (rc)) return rc; that->mSharedFolders.push_back (sharedFolder); } return VINF_SUCCESS; } // IConsole properties ///////////////////////////////////////////////////////////////////////////// STDMETHODIMP Console::COMGETTER(Machine) (IMachine **aMachine) { if (!aMachine) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mMachine is constant during life time, no need to lock */ mMachine.queryInterfaceTo (aMachine); return S_OK; } STDMETHODIMP Console::COMGETTER(State) (MachineState_T *aMachineState) { if (!aMachineState) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReaderLock alock (this); /* we return our local state (since it's always the same as on the server) */ *aMachineState = mMachineState; return S_OK; } STDMETHODIMP Console::COMGETTER(Guest) (IGuest **aGuest) { if (!aGuest) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mGuest is constant during life time, no need to lock */ mGuest.queryInterfaceTo (aGuest); return S_OK; } STDMETHODIMP Console::COMGETTER(Keyboard) (IKeyboard **aKeyboard) { if (!aKeyboard) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mKeyboard is constant during life time, no need to lock */ mKeyboard.queryInterfaceTo (aKeyboard); return S_OK; } STDMETHODIMP Console::COMGETTER(Mouse) (IMouse **aMouse) { if (!aMouse) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mMouse is constant during life time, no need to lock */ mMouse.queryInterfaceTo (aMouse); return S_OK; } STDMETHODIMP Console::COMGETTER(Display) (IDisplay **aDisplay) { if (!aDisplay) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mDisplay is constant during life time, no need to lock */ mDisplay.queryInterfaceTo (aDisplay); return S_OK; } STDMETHODIMP Console::COMGETTER(Debugger) (IMachineDebugger **aDebugger) { if (!aDebugger) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* we need a write lock because of the lazy mDebugger initialization*/ AutoLock alock (this); /* check if we have to create the debugger object */ if (!mDebugger) { unconst (mDebugger).createObject(); mDebugger->init (this); } mDebugger.queryInterfaceTo (aDebugger); return S_OK; } STDMETHODIMP Console::COMGETTER(USBDevices) (IUSBDeviceCollection **aUSBDevices) { if (!aUSBDevices) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReaderLock alock (this); ComObjPtr collection; collection.createObject(); collection->init (mUSBDevices); collection.queryInterfaceTo (aUSBDevices); return S_OK; } STDMETHODIMP Console::COMGETTER(RemoteUSBDevices) (IHostUSBDeviceCollection **aRemoteUSBDevices) { if (!aRemoteUSBDevices) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoReaderLock alock (this); ComObjPtr collection; collection.createObject(); collection->init (mRemoteUSBDevices); collection.queryInterfaceTo (aRemoteUSBDevices); return S_OK; } STDMETHODIMP Console::COMGETTER(RemoteDisplayInfo) (IRemoteDisplayInfo **aRemoteDisplayInfo) { if (!aRemoteDisplayInfo) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* mDisplay is constant during life time, no need to lock */ mRemoteDisplayInfo.queryInterfaceTo (aRemoteDisplayInfo); return S_OK; } STDMETHODIMP Console::COMGETTER(SharedFolders) (ISharedFolderCollection **aSharedFolders) { if (!aSharedFolders) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* loadDataFromSavedState() needs a write lock */ AutoLock alock (this); /* Read console data stored in the saved state file (if not yet done) */ HRESULT rc = loadDataFromSavedState(); CheckComRCReturnRC (rc); ComObjPtr coll; coll.createObject(); coll->init (mSharedFolders); coll.queryInterfaceTo (aSharedFolders); return S_OK; } // IConsole methods ///////////////////////////////////////////////////////////////////////////// STDMETHODIMP Console::PowerUp (IProgress **aProgress) { LogFlowThisFuncEnter(); LogFlowThisFunc (("mMachineState=%d\n", mMachineState)); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState >= MachineState_Running) return setError(E_FAIL, tr ("Cannot power up the machine as it is already running. (Machine state: %d)"), mMachineState); /* * First check whether all disks are accessible. This is not a 100% * bulletproof approach (race condition, it might become inaccessible * right after the check) but it's convenient as it will cover 99.9% * of the cases and here, we're able to provide meaningful error * information. */ ComPtr coll; mMachine->COMGETTER(HardDiskAttachments)(coll.asOutParam()); ComPtr enumerator; coll->Enumerate(enumerator.asOutParam()); BOOL fHasMore; while (SUCCEEDED(enumerator->HasMore(&fHasMore)) && fHasMore) { ComPtr attach; enumerator->GetNext(attach.asOutParam()); ComPtr hdd; attach->COMGETTER(HardDisk)(hdd.asOutParam()); Assert(hdd); BOOL fAccessible; HRESULT rc = hdd->COMGETTER(AllAccessible)(&fAccessible); CheckComRCReturnRC (rc); if (!fAccessible) { Bstr loc; hdd->COMGETTER(Location) (loc.asOutParam()); Bstr errMsg; hdd->COMGETTER(LastAccessError) (errMsg.asOutParam()); return setError (E_FAIL, tr ("VM cannot start because the hard disk '%ls' is not accessible " "(%ls)"), loc.raw(), errMsg.raw()); } } /* now perform the same check if a ISO is mounted */ ComPtr dvdDrive; mMachine->COMGETTER(DVDDrive)(dvdDrive.asOutParam()); ComPtr dvdImage; dvdDrive->GetImage(dvdImage.asOutParam()); if (dvdImage) { BOOL fAccessible; HRESULT rc = dvdImage->COMGETTER(Accessible)(&fAccessible); CheckComRCReturnRC (rc); if (!fAccessible) { Bstr filePath; dvdImage->COMGETTER(FilePath)(filePath.asOutParam()); /// @todo (r=dmik) grab the last access error once // IDVDImage::lastAccessError is there return setError (E_FAIL, tr ("VM cannot start because the DVD image '%ls' is not accessible"), filePath.raw()); } } /* now perform the same check if a floppy is mounted */ ComPtr floppyDrive; mMachine->COMGETTER(FloppyDrive)(floppyDrive.asOutParam()); ComPtr floppyImage; floppyDrive->GetImage(floppyImage.asOutParam()); if (floppyImage) { BOOL fAccessible; HRESULT rc = floppyImage->COMGETTER(Accessible)(&fAccessible); CheckComRCReturnRC (rc); if (!fAccessible) { Bstr filePath; floppyImage->COMGETTER(FilePath)(filePath.asOutParam()); /// @todo (r=dmik) grab the last access error once // IDVDImage::lastAccessError is there return setError (E_FAIL, tr ("VM cannot start because the floppy image '%ls' is not accessible"), filePath.raw()); } } /* now the network cards will undergo a quick consistency check */ for (ULONG slot = 0; slot < SchemaDefs::NetworkAdapterCount; slot ++) { ComPtr adapter; mMachine->GetNetworkAdapter (slot, adapter.asOutParam()); BOOL enabled = FALSE; adapter->COMGETTER(Enabled) (&enabled); if (!enabled) continue; NetworkAttachmentType_T netattach; adapter->COMGETTER(AttachmentType)(&netattach); switch (netattach) { case NetworkAttachmentType_HostInterfaceNetworkAttachment: { #ifdef __WIN__ /* a valid host interface must have been set */ Bstr hostif; adapter->COMGETTER(HostInterface)(hostif.asOutParam()); if (!hostif) { return setError (E_FAIL, tr ("VM cannot start because host interface networking " "requires a host interface name to be set")); } ComPtr virtualBox; mMachine->COMGETTER(Parent)(virtualBox.asOutParam()); ComPtr host; virtualBox->COMGETTER(Host)(host.asOutParam()); ComPtr coll; host->COMGETTER(NetworkInterfaces)(coll.asOutParam()); ComPtr hostInterface; if (!SUCCEEDED(coll->FindByName(hostif, hostInterface.asOutParam()))) { return setError (E_FAIL, tr ("VM cannot start because the host interface '%ls' " "does not exist"), hostif.raw()); } #endif /* __WIN__ */ break; } default: break; } } /* Read console data stored in the saved state file (if not yet done) */ { HRESULT rc = loadDataFromSavedState(); CheckComRCReturnRC (rc); } /* Check all types of shared folders and compose a single list */ std::map > sharedFolders; { /// @todo (dmik) check and add globally shared folders when they are // done ComPtr coll; HRESULT rc = mMachine->COMGETTER(SharedFolders) (coll.asOutParam()); CheckComRCReturnRC (rc); ComPtr en; rc = coll->Enumerate (en.asOutParam()); CheckComRCReturnRC (rc); BOOL hasMore = FALSE; while (SUCCEEDED (en->HasMore (&hasMore)) && hasMore) { ComPtr folder; en->GetNext (folder.asOutParam()); Bstr name; rc = folder->COMGETTER(Name) (name.asOutParam()); CheckComRCReturnRC (rc); BOOL accessible = FALSE; rc = folder->COMGETTER(Accessible) (&accessible); CheckComRCReturnRC (rc); if (!accessible) { Bstr hostPath; folder->COMGETTER(HostPath) (hostPath.asOutParam()); return setError (E_FAIL, tr ("Host path '%ls' of the shared folder '%ls' is not accessible"), hostPath.raw(), name.raw()); } sharedFolders.insert (std::make_pair (name, folder)); /// @todo (dmik) later, do this: // if (!sharedFolders.insert (std::pair ).second) // return setError (E_FAIL, // tr ("Could not accept a permanently shared folder named '%ls' " // "because a globally shared folder with the same name " // "already exists"), // name.raw()); } for (SharedFolderList::const_iterator it = mSharedFolders.begin(); it != mSharedFolders.end(); ++ it) { ComPtr folder = static_cast (*it); if (!sharedFolders.insert (std::make_pair ((*it)->name(), folder)).second) return setError (E_FAIL, tr ("Could not create a transient shared folder named '%ls' " "because a global or a permanent shared folder with " "the same name already exists"), (*it)->name().raw()); } } Bstr savedStateFile; /* * Saved VMs will have to prove that their saved states are kosher. */ if (mMachineState == MachineState_Saved) { HRESULT rc = mMachine->COMGETTER(StateFilePath) (savedStateFile.asOutParam()); CheckComRCReturnRC (rc); ComAssertRet (!!savedStateFile, E_FAIL); int vrc = SSMR3ValidateFile (Utf8Str (savedStateFile)); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("VM cannot start because the saved state file '%ls' is invalid (%Vrc). " "Discard the saved state prior to starting the VM"), savedStateFile.raw(), vrc); } /* create an IProgress object to track progress of this operation */ ComObjPtr progress; progress.createObject(); Bstr progressDesc; if (mMachineState == MachineState_Saved) progressDesc = tr ("Restoring the virtual machine"); else progressDesc = tr ("Starting the virtual machine"); progress->init ((IConsole *) this, progressDesc, FALSE /* aCancelable */); /* pass reference to caller if requested */ if (aProgress) progress.queryInterfaceTo (aProgress); /* setup task object and thread to carry out the operation asynchronously */ std::auto_ptr task (new VMPowerUpTask (this, progress)); ComAssertComRCRetRC (task->rc()); task->mSetVMErrorCallback = setVMErrorCallback; task->mConfigConstructor = configConstructor; task->mSharedFolders = sharedFolders; if (mMachineState == MachineState_Saved) task->mSavedStateFile = savedStateFile; int vrc = RTThreadCreate (NULL, Console::powerUpThread, (void *) task.get(), 0, RTTHREADTYPE_MAIN_WORKER, 0, "VMPowerUp"); ComAssertMsgRCRet (vrc, ("Could not create VMPowerUp thread (%Vrc)\n", vrc), E_FAIL); /* task is now owned by powerUpThread(), so release it */ task.release(); if (mMachineState == MachineState_Saved) setMachineState (MachineState_Restoring); else setMachineState (MachineState_Starting); LogFlowThisFunc (("mMachineState=%d\n", mMachineState)); LogFlowThisFuncLeave(); return S_OK; } STDMETHODIMP Console::PowerDown() { LogFlowThisFuncEnter(); LogFlowThisFunc (("mMachineState=%d\n", mMachineState)); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState != MachineState_Running && mMachineState != MachineState_Paused) { /* extra nice error message for a common case */ if (mMachineState == MachineState_Saved) return setError(E_FAIL, tr ("Cannot power off a saved machine")); else return setError(E_FAIL, tr ("Cannot power off the machine as it is not running or paused. (Machine state: %d)"), mMachineState); } LogFlowThisFunc (("Sending SHUTDOWN request...\n")); HRESULT rc = powerDown(); LogFlowThisFunc (("mMachineState=%d, rc=%08X\n", mMachineState, rc)); LogFlowThisFuncLeave(); return rc; } STDMETHODIMP Console::Reset() { LogFlowThisFuncEnter(); LogFlowThisFunc (("mMachineState=%d\n", mMachineState)); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState != MachineState_Running) return setError(E_FAIL, tr ("Cannot reset the machine as it is not running. (Machine state: %d)"), mMachineState); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); /* leave the lock before a VMR3* call (EMT will call us back)! */ alock.leave(); int vrc = VMR3Reset (mpVM); HRESULT rc = VBOX_SUCCESS (vrc) ? S_OK : setError (E_FAIL, tr ("Could not reset the machine. (Error: %Vrc)"), vrc); LogFlowThisFunc (("mMachineState=%d, rc=%08X\n", mMachineState, rc)); LogFlowThisFuncLeave(); return rc; } STDMETHODIMP Console::Pause() { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState != MachineState_Running) return setError (E_FAIL, tr ("Cannot pause the machine as it is not running. (Machine state: %d)"), mMachineState); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); LogFlowThisFunc (("Sending PAUSE request...\n")); /* leave the lock before a VMR3* call (EMT will call us back)! */ alock.leave(); int vrc = VMR3Suspend (mpVM); HRESULT rc = VBOX_SUCCESS (vrc) ? S_OK : setError (E_FAIL, tr ("Could not suspend the machine execution. (Error: %Vrc)"), vrc); LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } STDMETHODIMP Console::Resume() { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState != MachineState_Paused) return setError (E_FAIL, tr ("Cannot resume the machine as it is not paused. (Machine state: %d)"), mMachineState); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); LogFlowThisFunc (("Sending RESUME request...\n")); /* leave the lock before a VMR3* call (EMT will call us back)! */ alock.leave(); int vrc = VMR3Resume (mpVM); HRESULT rc = VBOX_SUCCESS (vrc) ? S_OK : setError (E_FAIL, tr ("Could not resume the machine execution. (Error: %Vrc)"), vrc); LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } STDMETHODIMP Console::PowerButton() { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock lock (this); if (mMachineState != MachineState_Running) return setError (E_FAIL, tr ("Cannot power off the machine as it is not running. (Machine state: %d)"), mMachineState); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); PPDMIBASE pBase; int vrc = PDMR3QueryDeviceLun (mpVM, "acpi", 0, 0, &pBase); if (VBOX_SUCCESS (vrc)) { Assert (pBase); PPDMIACPIPORT pPort = (PPDMIACPIPORT) pBase->pfnQueryInterface(pBase, PDMINTERFACE_ACPI_PORT); vrc = pPort ? pPort->pfnPowerButtonPress(pPort) : VERR_INVALID_POINTER; } HRESULT rc = VBOX_SUCCESS (vrc) ? S_OK : setError (E_FAIL, tr ("Controlled power off failed. (Error: %Vrc)"), vrc); LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } STDMETHODIMP Console::SaveState (IProgress **aProgress) { LogFlowThisFuncEnter(); LogFlowThisFunc (("mMachineState=%d\n", mMachineState)); if (!aProgress) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState != MachineState_Running && mMachineState != MachineState_Paused) { return setError (E_FAIL, tr ("Cannot save the machine state as the machine is not running or paused. (Machine state: %d)"), mMachineState); } /* memorize the current machine state */ MachineState_T lastMachineState = mMachineState; if (mMachineState == MachineState_Running) { HRESULT rc = Pause(); CheckComRCReturnRC (rc); } HRESULT rc = S_OK; /* create a progress object to track operation completion */ ComObjPtr progress; progress.createObject(); progress->init ((IConsole *) this, Bstr (tr ("Saving the execution state of the virtual machine")), FALSE /* aCancelable */); bool beganSavingState = false; bool taskCreationFailed = false; do { /* create a task object early to ensure mpVM protection is successful */ std::auto_ptr task (new VMSaveTask (this, progress)); rc = task->rc(); /* * If we fail here it means a PowerDown() call happened on another * thread while we were doing Pause() (which leaves the Console lock). * We assign PowerDown() a higher precendence than SaveState(), * therefore just return the error to the caller. */ if (FAILED (rc)) { taskCreationFailed = true; break; } Bstr stateFilePath; /* * request a saved state file path from the server * (this will set the machine state to Saving on the server to block * others from accessing this machine) */ rc = mControl->BeginSavingState (progress, stateFilePath.asOutParam()); CheckComRCBreakRC (rc); beganSavingState = true; /* sync the state with the server */ setMachineStateLocally (MachineState_Saving); /* ensure the directory for the saved state file exists */ { Utf8Str dir = stateFilePath; RTPathStripFilename (dir.mutableRaw()); if (!RTDirExists (dir)) { int vrc = RTDirCreateFullPath (dir, 0777); if (VBOX_FAILURE (vrc)) { rc = setError (E_FAIL, tr ("Could not create a directory '%s' to save the state to. (Error: %Vrc)"), dir.raw(), vrc); break; } } } /* setup task object and thread to carry out the operation asynchronously */ task->mIsSnapshot = false; task->mSavedStateFile = stateFilePath; /* set the state the operation thread will restore when it is finished */ task->mLastMachineState = lastMachineState; /* create a thread to wait until the VM state is saved */ int vrc = RTThreadCreate (NULL, Console::saveStateThread, (void *) task.get(), 0, RTTHREADTYPE_MAIN_WORKER, 0, "VMSave"); ComAssertMsgRCBreak (vrc, ("Could not create VMSave thread (%Vrc)\n", vrc), rc = E_FAIL); /* task is now owned by saveStateThread(), so release it */ task.release(); /* return the progress to the caller */ progress.queryInterfaceTo (aProgress); } while (0); if (FAILED (rc) && !taskCreationFailed) { /* fetch any existing error info */ ErrorInfo ei; if (beganSavingState) { /* * cancel the requested save state procedure. * This will reset the machine state to the state it had right * before calling mControl->BeginSavingState(). */ mControl->EndSavingState (FALSE); } if (lastMachineState == MachineState_Running) { /* restore the paused state if appropriate */ setMachineStateLocally (MachineState_Paused); /* restore the running state if appropriate */ Resume(); } else setMachineStateLocally (lastMachineState); /* restore fetched error info */ setError (ei); } LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } STDMETHODIMP Console::DiscardSavedState() { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState != MachineState_Saved) return setError (E_FAIL, tr ("Cannot discard the machine state as the machine is not in the saved state. (Machine state: %d"), mMachineState); /* * Saved -> PoweredOff transition will be detected in the SessionMachine * and properly handled. */ setMachineState (MachineState_PoweredOff); return S_OK; } /** read the value of a LEd. */ inline uint32_t readAndClearLed(PPDMLED pLed) { if (!pLed) return 0; uint32_t u32 = pLed->Actual.u32 | pLed->Asserted.u32; pLed->Asserted.u32 = 0; return u32; } STDMETHODIMP Console::GetDeviceActivity (DeviceType_T aDeviceType, DeviceActivity_T *aDeviceActivity) { if (!aDeviceActivity) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); /* * Note: we don't lock the console object here because * readAndClearLed() should be thread safe. */ /* Get LED array to read */ PDMLEDCORE SumLed = {0}; switch (aDeviceType) { case DeviceType_FloppyDevice: { for (unsigned i = 0; i < ELEMENTS(mapFDLeds); i++) SumLed.u32 |= readAndClearLed(mapFDLeds[i]); break; } case DeviceType_DVDDevice: { SumLed.u32 |= readAndClearLed(mapIDELeds[2]); break; } case DeviceType_HardDiskDevice: { SumLed.u32 |= readAndClearLed(mapIDELeds[0]); SumLed.u32 |= readAndClearLed(mapIDELeds[1]); SumLed.u32 |= readAndClearLed(mapIDELeds[3]); break; } case DeviceType_NetworkDevice: { for (unsigned i = 0; i < ELEMENTS(mapNetworkLeds); i++) SumLed.u32 |= readAndClearLed(mapNetworkLeds[i]); break; } case DeviceType_USBDevice: { /// @todo (r=dmik) // USB_DEVICE_ACTIVITY break; } default: return setError (E_INVALIDARG, tr ("Invalid device type: %d"), aDeviceType); } /* Compose the result */ switch (SumLed.u32 & (PDMLED_READING | PDMLED_WRITING)) { case 0: *aDeviceActivity = DeviceActivity_DeviceIdle; break; case PDMLED_READING: *aDeviceActivity = DeviceActivity_DeviceReading; break; case PDMLED_WRITING: case PDMLED_READING | PDMLED_WRITING: *aDeviceActivity = DeviceActivity_DeviceWriting; break; } return S_OK; } STDMETHODIMP Console::AttachUSBDevice (INPTR GUIDPARAM aId) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); /// @todo (r=dmik) is it legal to attach USB devices when the machine is // Paused, Starting, Saving, Stopping, etc? if not, we should make a // stricter check (mMachineState != MachineState_Running). if (mMachineState < MachineState_Running) return setError (E_FAIL, tr ("Cannot attach a USB device to a machine which is not running. (Machine state: %d)"), mMachineState); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); /* Don't proceed unless we've found the usb controller. */ PPDMIBASE pBase = NULL; int vrc = PDMR3QueryLun (mpVM, "usb-ohci", 0, 0, &pBase); if (VBOX_FAILURE (vrc)) return setError (E_FAIL, tr ("The virtual machine does not have a USB controller.")); PVUSBIRHCONFIG pRhConfig = (PVUSBIRHCONFIG) pBase-> pfnQueryInterface (pBase, PDMINTERFACE_VUSB_RH_CONFIG); ComAssertRet (pRhConfig, E_FAIL); /// @todo (dmik) REMOTE_USB // when remote USB devices are ready, first search for a device with the // given UUID in mRemoteUSBDevices. If found, request a capture from // a remote client. If not found, search it on the local host as done below /* * Try attach the given host USB device (a proper errror message should * be returned in case of error). */ ComPtr hostDevice; HRESULT hrc = mControl->CaptureUSBDevice (aId, hostDevice.asOutParam()); CheckComRCReturnRC (hrc); return attachUSBDevice (hostDevice, true /* aManual */, pRhConfig); } STDMETHODIMP Console::DetachUSBDevice (INPTR GUIDPARAM aId, IUSBDevice **aDevice) { if (!aDevice) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); /* Find it. */ ComObjPtr device; USBDeviceList::iterator it = mUSBDevices.begin(); while (it != mUSBDevices.end()) { if ((*it)->id() == aId) { device = *it; break; } ++ it; } if (!device) return setError (E_INVALIDARG, tr ("Cannot detach the USB device (UUID: %s) as it is not attached here."), Guid (aId).toString().raw()); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); PPDMIBASE pBase = NULL; int vrc = PDMR3QueryLun (mpVM, "usb-ohci", 0, 0, &pBase); /* if the device is attached, then there must be a USB controller */ ComAssertRCRet (vrc, E_FAIL); PVUSBIRHCONFIG pRhConfig = (PVUSBIRHCONFIG) pBase-> pfnQueryInterface (pBase, PDMINTERFACE_VUSB_RH_CONFIG); ComAssertRet (pRhConfig, E_FAIL); Guid Uuid(aId); LogFlowThisFunc (("Detaching USB proxy device {%Vuuid}...\n", Uuid.raw())); /* leave the lock before a VMR3* call (EMT will call us back)! */ alock.leave(); PVMREQ pReq = NULL; vrc = VMR3ReqCall (mpVM, &pReq, RT_INDEFINITE_WAIT, (PFNRT) usbDetachCallback, 5, this, &it, true /* aManual */, pRhConfig, Uuid.raw()); if (VBOX_SUCCESS (vrc)) vrc = pReq->iStatus; VMR3ReqFree (pReq); HRESULT hrc = S_OK; if (VBOX_SUCCESS (vrc)) device.queryInterfaceTo (aDevice); else hrc = setError (E_FAIL, tr ("Error detaching the USB device. (Failed to destroy the USB proxy device: %Vrc)"), vrc); return hrc; } STDMETHODIMP Console::CreateSharedFolder (INPTR BSTR aName, INPTR BSTR aHostPath) { if (!aName || !aHostPath) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState == MachineState_Saved) return setError (E_FAIL, tr ("Cannot create a transient shared folder on a " "machine in the saved state.")); /// @todo (dmik) check globally shared folders when they are done /* check machine's shared folders */ { ComPtr coll; HRESULT rc = mMachine->COMGETTER(SharedFolders) (coll.asOutParam()); if (FAILED (rc)) return rc; ComPtr machineSharedFolder; rc = coll->FindByName (aName, machineSharedFolder.asOutParam()); if (SUCCEEDED (rc)) return setError (E_FAIL, tr ("A permanent shared folder named '%ls' already " "exists."), aName); } ComObjPtr sharedFolder; HRESULT rc = findSharedFolder (aName, sharedFolder, false /* aSetError */); if (SUCCEEDED (rc)) return setError (E_FAIL, tr ("A shared folder named '%ls' already exists."), aName); sharedFolder.createObject(); rc = sharedFolder->init (this, aName, aHostPath); CheckComRCReturnRC (rc); BOOL accessible = FALSE; rc = sharedFolder->COMGETTER(Accessible) (&accessible); CheckComRCReturnRC (rc); if (!accessible) return setError (E_FAIL, tr ("The shared folder path '%ls' on the host is not accessible."), aHostPath); /// @todo (r=sander?) should move this into the shared folder class */ if (mpVM && mVMMDev->getShFlClientId()) { /* * if the VM is online and supports shared folders, share this folder * under the specified name. On error, return it to the caller. */ /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); VBOXHGCMSVCPARM parms[2]; SHFLSTRING *pFolderName, *pMapName; int cbString; Log(("Add shared folder %ls -> %ls\n", aName, aHostPath)); cbString = (RTStrUcs2Len(aHostPath) + 1) * sizeof(RTUCS2); pFolderName = (SHFLSTRING *)RTMemAllocZ(sizeof(SHFLSTRING) + cbString); Assert(pFolderName); memcpy(pFolderName->String.ucs2, aHostPath, cbString); pFolderName->u16Size = cbString; pFolderName->u16Length = cbString - sizeof(RTUCS2); parms[0].type = VBOX_HGCM_SVC_PARM_PTR; parms[0].u.pointer.addr = pFolderName; parms[0].u.pointer.size = sizeof(SHFLSTRING) + cbString; cbString = (RTStrUcs2Len(aName) + 1) * sizeof(RTUCS2); pMapName = (SHFLSTRING *)RTMemAllocZ(sizeof(SHFLSTRING) + cbString); Assert(pMapName); memcpy(pMapName->String.ucs2, aName, cbString); pMapName->u16Size = cbString; pMapName->u16Length = cbString - sizeof(RTUCS2); parms[1].type = VBOX_HGCM_SVC_PARM_PTR; parms[1].u.pointer.addr = pMapName; parms[1].u.pointer.size = sizeof(SHFLSTRING) + cbString; rc = mVMMDev->hgcmHostCall("VBoxSharedFolders", SHFL_FN_ADD_MAPPING, 2, &parms[0]); RTMemFree(pFolderName); RTMemFree(pMapName); if (rc != VINF_SUCCESS) return setError (E_FAIL, tr ("Unable to add mapping %ls to %ls."), aHostPath, aName); } mSharedFolders.push_back (sharedFolder); return S_OK; } STDMETHODIMP Console::RemoveSharedFolder (INPTR BSTR aName) { if (!aName) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState == MachineState_Saved) return setError (E_FAIL, tr ("Cannot remove a transient shared folder when the " "machine is in the saved state.")); ComObjPtr sharedFolder; HRESULT rc = findSharedFolder (aName, sharedFolder, true /* aSetError */); CheckComRCReturnRC (rc); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); if (mpVM && mVMMDev->getShFlClientId()) { /* * if the VM is online and supports shared folders, UNshare this folder. * On error, return it to the caller. */ VBOXHGCMSVCPARM parms; SHFLSTRING *pMapName; int cbString; cbString = (RTStrUcs2Len(aName) + 1) * sizeof(RTUCS2); pMapName = (SHFLSTRING *)RTMemAllocZ(sizeof(SHFLSTRING) + cbString); Assert(pMapName); memcpy(pMapName->String.ucs2, aName, cbString); pMapName->u16Size = cbString; pMapName->u16Length = cbString - sizeof(RTUCS2); parms.type = VBOX_HGCM_SVC_PARM_PTR; parms.u.pointer.addr = pMapName; parms.u.pointer.size = sizeof(SHFLSTRING) + cbString; rc = mVMMDev->hgcmHostCall("VBoxSharedFolders", SHFL_FN_REMOVE_MAPPING, 1, &parms); RTMemFree(pMapName); if (rc != VINF_SUCCESS) rc = setError (E_FAIL, tr ("Unable to remove the mapping %ls."), aName); } mSharedFolders.remove (sharedFolder); return rc; } STDMETHODIMP Console::TakeSnapshot (INPTR BSTR aName, INPTR BSTR aDescription, IProgress **aProgress) { LogFlowThisFuncEnter(); LogFlowThisFunc (("aName='%ls' mMachineState=%08X\n", aName, mMachineState)); if (!aName) return E_INVALIDARG; if (!aProgress) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState > MachineState_Running && mMachineState != MachineState_Paused) { return setError (E_FAIL, tr ("Cannot take a snapshot of a machine while it is changing state. (Machine state: %d)"), mMachineState); } /* memorize the current machine state */ MachineState_T lastMachineState = mMachineState; if (mMachineState == MachineState_Running) { HRESULT rc = Pause(); CheckComRCReturnRC (rc); } HRESULT rc = S_OK; bool takingSnapshotOnline = mMachineState == MachineState_Paused; /* * create a descriptionless VM-side progress object * (only when creating a snapshot online) */ ComObjPtr saveProgress; if (takingSnapshotOnline) { saveProgress.createObject(); rc = saveProgress->init (FALSE, 1, Bstr (tr ("Saving the execution state"))); AssertComRCReturn (rc, rc); } bool beganTakingSnapshot = false; bool taskCreationFailed = false; do { /* create a task object early to ensure mpVM protection is successful */ std::auto_ptr task; if (takingSnapshotOnline) { task.reset (new VMSaveTask (this, saveProgress)); rc = task->rc(); /* * If we fail here it means a PowerDown() call happened on another * thread while we were doing Pause() (which leaves the Console lock). * We assign PowerDown() a higher precendence than TakeSnapshot(), * therefore just return the error to the caller. */ if (FAILED (rc)) { taskCreationFailed = true; break; } } Bstr stateFilePath; ComPtr serverProgress; /* * request taking a new snapshot object on the server * (this will set the machine state to Saving on the server to block * others from accessing this machine) */ rc = mControl->BeginTakingSnapshot (this, aName, aDescription, saveProgress, stateFilePath.asOutParam(), serverProgress.asOutParam()); if (FAILED (rc)) break; /* * state file is non-null only when the VM is paused * (i.e. createing a snapshot online) */ ComAssertBreak ( (!stateFilePath.isNull() && takingSnapshotOnline) || (stateFilePath.isNull() && !takingSnapshotOnline), rc = E_FAIL); beganTakingSnapshot = true; /* sync the state with the server */ setMachineStateLocally (MachineState_Saving); /* * create a combined VM-side progress object and start the save task * (only when creating a snapshot online) */ ComObjPtr combinedProgress; if (takingSnapshotOnline) { combinedProgress.createObject(); rc = combinedProgress->init ((IConsole *) this, Bstr (tr ("Taking snapshot of virtual machine")), serverProgress, saveProgress); AssertComRCBreakRC (rc); /* setup task object and thread to carry out the operation asynchronously */ task->mIsSnapshot = true; task->mSavedStateFile = stateFilePath; task->mServerProgress = serverProgress; /* set the state the operation thread will restore when it is finished */ task->mLastMachineState = lastMachineState; /* create a thread to wait until the VM state is saved */ int vrc = RTThreadCreate (NULL, Console::saveStateThread, (void *) task.get(), 0, RTTHREADTYPE_MAIN_WORKER, 0, "VMTakeSnap"); ComAssertMsgRCBreak (vrc, ("Could not create VMTakeSnap thread (%Vrc)\n", vrc), rc = E_FAIL); /* task is now owned by saveStateThread(), so release it */ task.release(); } if (SUCCEEDED (rc)) { /* return the correct progress to the caller */ if (combinedProgress) combinedProgress.queryInterfaceTo (aProgress); else serverProgress.queryInterfaceTo (aProgress); } } while (0); if (FAILED (rc) && !taskCreationFailed) { /* fetch any existing error info */ ErrorInfo ei; if (beganTakingSnapshot && takingSnapshotOnline) { /* * cancel the requested snapshot (only when creating a snapshot * online, otherwise the server will cancel the snapshot itself). * This will reset the machine state to the state it had right * before calling mControl->BeginTakingSnapshot(). */ mControl->EndTakingSnapshot (FALSE); } if (lastMachineState == MachineState_Running) { /* restore the paused state if appropriate */ setMachineStateLocally (MachineState_Paused); /* restore the running state if appropriate */ Resume(); } else setMachineStateLocally (lastMachineState); /* restore fetched error info */ setError (ei); } LogFlowThisFunc (("rc=%08X\n", rc)); LogFlowThisFuncLeave(); return rc; } STDMETHODIMP Console::DiscardSnapshot (INPTR GUIDPARAM aId, IProgress **aProgress) { if (Guid (aId).isEmpty()) return E_INVALIDARG; if (!aProgress) return E_POINTER; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState >= MachineState_Running) return setError (E_FAIL, tr ("Cannot discard a snapshot on a running machine (Machine state: %d)"), mMachineState); MachineState_T machineState = MachineState_InvalidMachineState; HRESULT rc = mControl->DiscardSnapshot (this, aId, &machineState, aProgress); CheckComRCReturnRC (rc); setMachineStateLocally (machineState); return S_OK; } STDMETHODIMP Console::DiscardCurrentState (IProgress **aProgress) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState >= MachineState_Running) return setError (E_FAIL, tr ("Cannot discard the current state of a running machine. (Machine state: %d)"), mMachineState); MachineState_T machineState = MachineState_InvalidMachineState; HRESULT rc = mControl->DiscardCurrentState (this, &machineState, aProgress); CheckComRCReturnRC (rc); setMachineStateLocally (machineState); return S_OK; } STDMETHODIMP Console::DiscardCurrentSnapshotAndState (IProgress **aProgress) { AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mMachineState >= MachineState_Running) return setError (E_FAIL, tr ("Cannot discard the current snapshot and state on a running machine. (Machine state: %d)"), mMachineState); MachineState_T machineState = MachineState_InvalidMachineState; HRESULT rc = mControl->DiscardCurrentSnapshotAndState (this, &machineState, aProgress); CheckComRCReturnRC (rc); setMachineStateLocally (machineState); return S_OK; } STDMETHODIMP Console::RegisterCallback (IConsoleCallback *aCallback) { if (!aCallback) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); mCallbacks.push_back (CallbackList::value_type (aCallback)); return S_OK; } STDMETHODIMP Console::UnregisterCallback (IConsoleCallback *aCallback) { if (!aCallback) return E_INVALIDARG; AutoCaller autoCaller (this); CheckComRCReturnRC (autoCaller.rc()); AutoLock alock (this); CallbackList::iterator it; it = std::find (mCallbacks.begin(), mCallbacks.end(), CallbackList::value_type (aCallback)); if (it == mCallbacks.end()) return setError (E_INVALIDARG, tr ("The given callback handler is not registered")); mCallbacks.erase (it); return S_OK; } // Non-interface public methods ///////////////////////////////////////////////////////////////////////////// /** * Called by IInternalSessionControl::OnDVDDriveChange(). * * @note Locks this object for reading. */ HRESULT Console::onDVDDriveChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoReaderLock alock (this); /* Ignore callbacks when there's no VM around */ if (!mpVM) return S_OK; /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); /* Get the current DVD state */ HRESULT rc; DriveState_T eState; rc = mDVDDrive->COMGETTER (State) (&eState); ComAssertComRCRetRC (rc); /* Paranoia */ if ( eState == DriveState_NotMounted && meDVDState == DriveState_NotMounted) { LogFlowThisFunc (("Returns (NotMounted -> NotMounted)\n")); return S_OK; } /* Get the path string and other relevant properties */ Bstr Path; bool fPassthrough = false; switch (eState) { case DriveState_ImageMounted: { ComPtr ImagePtr; rc = mDVDDrive->GetImage (ImagePtr.asOutParam()); if (SUCCEEDED (rc)) rc = ImagePtr->COMGETTER(FilePath) (Path.asOutParam()); break; } case DriveState_HostDriveCaptured: { ComPtr DrivePtr; BOOL enabled; rc = mDVDDrive->GetHostDrive (DrivePtr.asOutParam()); if (SUCCEEDED (rc)) rc = DrivePtr->COMGETTER (Name) (Path.asOutParam()); if (SUCCEEDED (rc)) rc = mDVDDrive->COMGETTER (Passthrough) (&enabled); if (SUCCEEDED (rc)) fPassthrough = !!enabled; break; } case DriveState_NotMounted: break; default: AssertMsgFailed (("Invalid DriveState: %d\n", eState)); rc = E_FAIL; break; } AssertComRC (rc); if (FAILED (rc)) { LogFlowThisFunc (("Returns %#x\n", rc)); return rc; } return doDriveChange ("piix3ide", 0, 2, eState, &meDVDState, Utf8Str (Path).raw(), fPassthrough); } /** * Called by IInternalSessionControl::OnFloppyDriveChange(). * * @note Locks this object for reading. */ HRESULT Console::onFloppyDriveChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoReaderLock alock (this); /* Ignore callbacks when there's no VM around */ if (!mpVM) return S_OK; /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); /* Get the current floppy state */ HRESULT rc; DriveState_T eState; /* If the floppy drive is disabled, we're not interested */ BOOL fEnabled; rc = mFloppyDrive->COMGETTER (Enabled) (&fEnabled); ComAssertComRCRetRC (rc); if (!fEnabled) return S_OK; rc = mFloppyDrive->COMGETTER (State) (&eState); ComAssertComRCRetRC (rc); Log2 (("onFloppyDriveChange: eState=%d meFloppyState=%d\n", eState, meFloppyState)); /* Paranoia */ if ( eState == DriveState_NotMounted && meFloppyState == DriveState_NotMounted) { LogFlowThisFunc (("Returns (NotMounted -> NotMounted)\n")); return S_OK; } /* Get the path string and other relevant properties */ Bstr Path; switch (eState) { case DriveState_ImageMounted: { ComPtr ImagePtr; rc = mFloppyDrive->GetImage (ImagePtr.asOutParam()); if (SUCCEEDED (rc)) rc = ImagePtr->COMGETTER(FilePath) (Path.asOutParam()); break; } case DriveState_HostDriveCaptured: { ComPtr DrivePtr; rc = mFloppyDrive->GetHostDrive (DrivePtr.asOutParam()); if (SUCCEEDED (rc)) rc = DrivePtr->COMGETTER (Name) (Path.asOutParam()); break; } case DriveState_NotMounted: break; default: AssertMsgFailed (("Invalid DriveState: %d\n", eState)); rc = E_FAIL; break; } AssertComRC (rc); if (FAILED (rc)) { LogFlowThisFunc (("Returns %#x\n", rc)); return rc; } return doDriveChange ("i82078", 0, 0, eState, &meFloppyState, Utf8Str (Path).raw(), false); } /** * Process a floppy or dvd change. * * @returns COM status code. * * @param pszDevice The PDM device name. * @param uInstance The PDM device instance. * @param uLun The PDM LUN number of the drive. * @param eState The new state. * @param peState Pointer to the variable keeping the actual state of the drive. * This will be both read and updated to eState or other appropriate state. * @param pszPath The path to the media / drive which is now being mounted / captured. * If NULL no media or drive is attached and the lun will be configured with * the default block driver with no media. This will also be the state if * mounting / capturing the specified media / drive fails. * @param fPassthrough Enables using passthrough mode of the host DVD drive if applicable. * * @note Locks this object for reading. */ HRESULT Console::doDriveChange (const char *pszDevice, unsigned uInstance, unsigned uLun, DriveState_T eState, DriveState_T *peState, const char *pszPath, bool fPassthrough) { LogFlowThisFunc (("pszDevice=%p:{%s} uInstance=%u uLun=%u eState=%d " "peState=%p:{%d} pszPath=%p:{%s} fPassthrough=%d\n", pszDevice, pszDevice, uInstance, uLun, eState, peState, *peState, pszPath, pszPath, fPassthrough)); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoReaderLock alock (this); /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); /* * Call worker in EMT, that's faster and safer than doing everything * using VM3ReqCall. Note that we separate VMR3ReqCall from VMR3ReqWait * here to make requests from under the lock in order to serialize them. */ PVMREQ pReq; int vrc = VMR3ReqCall (mpVM, &pReq, 0 /* no wait! */, (PFNRT) Console::changeDrive, 8, this, pszDevice, uInstance, uLun, eState, peState, pszPath, fPassthrough); /// @todo (r=dmik) bird, it would be nice to have a special VMR3Req method // for that purpose, that doesn't return useless VERR_TIMEOUT if (vrc == VERR_TIMEOUT) vrc = VINF_SUCCESS; /* leave the lock before waiting for a result (EMT will call us back!) */ alock.leave(); if (VBOX_SUCCESS (vrc)) { vrc = VMR3ReqWait (pReq, RT_INDEFINITE_WAIT); AssertRC (vrc); if (VBOX_SUCCESS (vrc)) vrc = pReq->iStatus; } VMR3ReqFree (pReq); if (VBOX_SUCCESS (vrc)) { LogFlowThisFunc (("Returns S_OK\n")); return S_OK; } if (pszPath) return setError (E_FAIL, tr ("Could not mount the media/drive '%s' (%Vrc)"), pszPath, vrc); return setError (E_FAIL, tr ("Could not unmount the currently mounted media/drive (%Vrc)"), vrc); } /** * Performs the Floppy/DVD change in EMT. * * @returns VBox status code. * * @param pThis Pointer to the Console object. * @param pszDevice The PDM device name. * @param uInstance The PDM device instance. * @param uLun The PDM LUN number of the drive. * @param eState The new state. * @param peState Pointer to the variable keeping the actual state of the drive. * This will be both read and updated to eState or other appropriate state. * @param pszPath The path to the media / drive which is now being mounted / captured. * If NULL no media or drive is attached and the lun will be configured with * the default block driver with no media. This will also be the state if * mounting / capturing the specified media / drive fails. * @param fPassthrough Enables using passthrough mode of the host DVD drive if applicable. * * @thread EMT * @note Locks the Console object for writing */ DECLCALLBACK(int) Console::changeDrive (Console *pThis, const char *pszDevice, unsigned uInstance, unsigned uLun, DriveState_T eState, DriveState_T *peState, const char *pszPath, bool fPassthrough) { LogFlowFunc (("pThis=%p pszDevice=%p:{%s} uInstance=%u uLun=%u eState=%d " "peState=%p:{%d} pszPath=%p:{%s} fPassthrough=%d\n", pThis, pszDevice, pszDevice, uInstance, uLun, eState, peState, *peState, pszPath, pszPath, fPassthrough)); AssertReturn (pThis, VERR_INVALID_PARAMETER); AssertMsg ( (!strcmp (pszDevice, "i82078") && uLun == 0 && uInstance == 0) || (!strcmp (pszDevice, "piix3ide") && uLun == 2 && uInstance == 0), ("pszDevice=%s uLun=%d uInstance=%d\n", pszDevice, uLun, uInstance)); AutoCaller autoCaller (pThis); AssertComRCReturn (autoCaller.rc(), VERR_ACCESS_DENIED); /* * Locking the object before doing VMR3* calls is quite safe here, * since we're on EMT. Write lock is necessary because we're indirectly * modify the meDVDState/meFloppyState members (pointed to by peState). */ AutoLock alock (pThis); /* protect mpVM */ AutoVMCaller autoVMCaller (pThis); CheckComRCReturnRC (autoVMCaller.rc()); PVM pVM = pThis->mpVM; /* * Suspend the VM first. * * The VM must not be running since it might have pending I/O to * the drive which is being changed. */ bool fResume; VMSTATE enmVMState = VMR3GetState (pVM); switch (enmVMState) { case VMSTATE_RESETTING: case VMSTATE_RUNNING: { LogFlowFunc (("Suspending the VM...\n")); /* disable the callback to prevent Console-level state change */ pThis->mVMStateChangeCallbackDisabled = true; int rc = VMR3Suspend (pVM); pThis->mVMStateChangeCallbackDisabled = false; AssertRCReturn (rc, rc); fResume = true; break; } case VMSTATE_SUSPENDED: case VMSTATE_CREATED: case VMSTATE_OFF: fResume = false; break; default: AssertMsgFailedReturn (("enmVMState=%d\n", enmVMState), VERR_ACCESS_DENIED); } int rc = VINF_SUCCESS; int rcRet = VINF_SUCCESS; do { /* * Unmount existing media / detach host drive. */ PPDMIMOUNT pIMount = NULL; switch (*peState) { case DriveState_ImageMounted: { /* * Resolve the interface. */ PPDMIBASE pBase; rc = PDMR3QueryLun (pVM, pszDevice, uInstance, uLun, &pBase); if (VBOX_FAILURE (rc)) { if (rc == VERR_PDM_LUN_NOT_FOUND) rc = VINF_SUCCESS; AssertRC (rc); break; } pIMount = (PPDMIMOUNT) pBase->pfnQueryInterface (pBase, PDMINTERFACE_MOUNT); AssertBreak (pIMount, rc = VERR_INVALID_POINTER); /* * Unmount the media. */ rc = pIMount->pfnUnmount (pIMount); if (rc == VERR_PDM_MEDIA_NOT_MOUNTED) rc = VINF_SUCCESS; break; } case DriveState_HostDriveCaptured: { rc = PDMR3DeviceDetach (pVM, pszDevice, uInstance, uLun); if (rc == VINF_PDM_NO_DRIVER_ATTACHED_TO_LUN) rc = VINF_SUCCESS; AssertRC (rc); break; } case DriveState_NotMounted: break; default: AssertMsgFailed (("Invalid *peState: %d\n", peState)); break; } if (VBOX_FAILURE (rc)) { rcRet = rc; break; } /* * Nothing is currently mounted. */ *peState = DriveState_NotMounted; /* * Process the HostDriveCaptured state first, as the fallback path * means mounting the normal block driver without media. */ if (eState == DriveState_HostDriveCaptured) { /* * Detach existing driver chain (block). */ int rc = PDMR3DeviceDetach (pVM, pszDevice, uInstance, uLun); if (VBOX_FAILURE (rc)) { if (rc == VERR_PDM_LUN_NOT_FOUND) rc = VINF_SUCCESS; AssertReleaseRC (rc); break; /* we're toast */ } pIMount = NULL; /* * Construct a new driver configuration. */ PCFGMNODE pInst = CFGMR3GetChildF (CFGMR3GetRoot (pVM), "Devices/%s/%d/", pszDevice, uInstance); AssertRelease (pInst); /* nuke anything which might have been left behind. */ CFGMR3RemoveNode (CFGMR3GetChildF (pInst, "LUN#%d", uLun)); /* create a new block driver config */ PCFGMNODE pLunL0; PCFGMNODE pCfg; if ( VBOX_SUCCESS (rc = CFGMR3InsertNodeF (pInst, &pLunL0, "LUN#%u", uLun)) && VBOX_SUCCESS (rc = CFGMR3InsertString (pLunL0, "Driver", !strcmp (pszDevice, "i82078") ? "HostFloppy" : "HostDVD")) && VBOX_SUCCESS (rc = CFGMR3InsertNode (pLunL0, "Config", &pCfg)) && VBOX_SUCCESS (rc = CFGMR3InsertString (pCfg, "Path", pszPath)) && VBOX_SUCCESS (rc = !strcmp (pszDevice, "i82078") ? VINF_SUCCESS : CFGMR3InsertInteger(pCfg, "Passthrough", fPassthrough))) { /* * Attempt to attach the driver. */ rc = PDMR3DeviceAttach (pVM, pszDevice, uInstance, uLun, NULL); AssertRC (rc); } if (VBOX_FAILURE (rc)) rcRet = rc; } /* * Process the ImageMounted, NotMounted and failed HostDriveCapture cases. */ rc = VINF_SUCCESS; switch (eState) { #define RC_CHECK() do { if (VBOX_FAILURE (rc)) { AssertReleaseRC (rc); break; } } while (0) case DriveState_HostDriveCaptured: if (VBOX_SUCCESS (rcRet)) break; /* fallback: umounted block driver. */ pszPath = NULL; eState = DriveState_NotMounted; /* fallthru */ case DriveState_ImageMounted: case DriveState_NotMounted: { /* * Resolve the drive interface / create the driver. */ if (!pIMount) { PPDMIBASE pBase; rc = PDMR3QueryLun (pVM, pszDevice, uInstance, uLun, &pBase); if (rc == VERR_PDM_NO_DRIVER_ATTACHED_TO_LUN) { /* * We have to create it, so we'll do the full config setup and everything. */ PCFGMNODE pIdeInst = CFGMR3GetChildF (CFGMR3GetRoot (pVM), "Devices/%s/%d/", pszDevice, uInstance); AssertRelease (pIdeInst); /* nuke anything which might have been left behind. */ CFGMR3RemoveNode (CFGMR3GetChildF (pIdeInst, "LUN#%d", uLun)); /* create a new block driver config */ PCFGMNODE pLunL0; rc = CFGMR3InsertNodeF (pIdeInst, &pLunL0, "LUN#%d", uLun); RC_CHECK(); rc = CFGMR3InsertString (pLunL0, "Driver", "Block"); RC_CHECK(); PCFGMNODE pCfg; rc = CFGMR3InsertNode (pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString (pCfg, "Type", !strcmp (pszDevice, "i82078") ? "Floppy 1.44" : "DVD"); RC_CHECK(); rc = CFGMR3InsertInteger (pCfg, "Mountable", 1); RC_CHECK(); /* * Attach the driver. */ rc = PDMR3DeviceAttach (pVM, pszDevice, uInstance, uLun, &pBase); RC_CHECK(); } else if (VBOX_FAILURE(rc)) { AssertRC (rc); return rc; } pIMount = (PPDMIMOUNT) pBase->pfnQueryInterface (pBase, PDMINTERFACE_MOUNT); if (!pIMount) { AssertFailed(); return rc; } } /* * If we've got an image, let's mount it. */ if (pszPath && *pszPath) { rc = pIMount->pfnMount (pIMount, pszPath, strcmp (pszDevice, "i82078") ? "MediaISO" : "RawImage"); if (VBOX_FAILURE (rc)) eState = DriveState_NotMounted; } break; } default: AssertMsgFailed (("Invalid eState: %d\n", eState)); break; #undef RC_CHECK } if (VBOX_FAILURE (rc) && VBOX_SUCCESS (rcRet)) rcRet = rc; *peState = eState; } while (0); /* * Resume the VM if necessary. */ if (fResume) { LogFlowFunc (("Resuming the VM...\n")); /* disable the callback to prevent Console-level state change */ pThis->mVMStateChangeCallbackDisabled = true; rc = VMR3Resume (pVM); pThis->mVMStateChangeCallbackDisabled = false; AssertRC (rc); if (VBOX_FAILURE (rc)) { /* too bad, we failed. try to sync the console state with the VMM state */ vmstateChangeCallback (pVM, VMSTATE_SUSPENDED, enmVMState, pThis); } /// @todo (r=dmik) if we failed with drive mount, then the VMR3Resume // error (if any) will be hidden from the caller. For proper reporting // of such multiple errors to the caller we need to enhance the // IVurtualBoxError interface. For now, give the first error the higher // priority. if (VBOX_SUCCESS (rcRet)) rcRet = rc; } LogFlowFunc (("Returning %Vrc\n", rcRet)); return rcRet; } /** * Called by IInternalSessionControl::OnNetworkAdapterChange(). * * @note Locks this object for writing. */ HRESULT Console::onNetworkAdapterChange(INetworkAdapter *networkAdapter) { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); /* Don't do anything if the VM isn't running */ if (!mpVM) return S_OK; /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); /* Get the properties we need from the adapter */ BOOL fCableConnected; HRESULT rc = networkAdapter->COMGETTER(CableConnected)(&fCableConnected); AssertComRC(rc); if (SUCCEEDED(rc)) { ULONG ulInstance; rc = networkAdapter->COMGETTER(Slot)(&ulInstance); AssertComRC(rc); if (SUCCEEDED(rc)) { /* * Find the pcnet instance, get the config interface and update the link state. */ PPDMIBASE pBase; int rcVBox = PDMR3QueryDeviceLun(mpVM, "pcnet", (unsigned)ulInstance, 0, &pBase); ComAssertRC(rcVBox); if (VBOX_SUCCESS(rcVBox)) { Assert(pBase); PPDMINETWORKCONFIG pINetCfg = (PPDMINETWORKCONFIG)pBase->pfnQueryInterface(pBase, PDMINTERFACE_NETWORK_CONFIG); if (pINetCfg) { Log(("Console::onNetworkAdapterChange: setting link state to %d\n", fCableConnected)); rcVBox = pINetCfg->pfnSetLinkState(pINetCfg, fCableConnected ? PDMNETWORKLINKSTATE_UP : PDMNETWORKLINKSTATE_DOWN); ComAssertRC(rcVBox); } } } } LogFlowThisFunc (("Leaving rc=%#x\n", rc)); return rc; } /** * Called by IInternalSessionControl::OnVRDPServerChange(). * * @note Locks this object for writing. */ HRESULT Console::onVRDPServerChange() { AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); HRESULT rc = S_OK; if (mVRDPServer && mMachineState == MachineState_Running) { BOOL vrdpEnabled = FALSE; rc = mVRDPServer->COMGETTER(Enabled) (&vrdpEnabled); ComAssertComRCRetRC (rc); if (vrdpEnabled) { // If there was no VRDP server started the 'stop' will do nothing. // However if a server was started and this notification was called, // we have to restart the server. mConsoleVRDPServer->Stop (); if (VBOX_FAILURE(mConsoleVRDPServer->Launch ())) { rc = E_FAIL; } else { mConsoleVRDPServer->SetCallback (); } } else { mConsoleVRDPServer->Stop (); } } return rc; } /** * Called by IInternalSessionControl::OnUSBControllerChange(). * * @note Locks this object for writing. */ HRESULT Console::onUSBControllerChange() { LogFlowThisFunc (("\n")); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); /* Ignore if no VM is running yet. */ if (!mpVM) return S_OK; /// @todo (dmik) // check for the Enabled state and disable virtual USB controller?? // Anyway, if we want to query the machine's USB Controller we need to cache // it to to mUSBController in #init() (as it is done with mDVDDrive). // // bird: While the VM supports hot-plugging, I doubt any guest can handle it at this time... :-) // // /* protect mpVM */ // AutoVMCaller autoVMCaller (this); // CheckComRCReturnRC (autoVMCaller.rc()); return S_OK; } /** * Called by IInternalSessionControl::OnUSBDeviceAttach() or locally by * processRemoteUSBDevices() after IInternalMachineControl::RunUSBDeviceFilters() * returns TRUE for a given remote USB device. * * @return S_OK if the device was attached to the VM. * @return failure if not attached. * * @param aDevice * The device in question. * * @note Locks this object for writing. */ HRESULT Console::onUSBDeviceAttach (IUSBDevice *aDevice) { LogFlowThisFunc (("aDevice=%p\n", aDevice)); AutoCaller autoCaller (this); ComAssertComRCRetRC (autoCaller.rc()); AutoLock alock (this); /* VM might have been stopped when this message arrives */ if (mMachineState < MachineState_Running) { LogFlowThisFunc (("Attach request ignored (mMachineState=%d).\n", mMachineState)); return E_FAIL; } /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); /* Don't proceed unless we've found the usb controller. */ PPDMIBASE pBase = NULL; int vrc = PDMR3QueryLun (mpVM, "usb-ohci", 0, 0, &pBase); if (VBOX_FAILURE (vrc)) { LogFlowThisFunc (("Attach request ignored (no USB controller).\n")); return E_FAIL; } PVUSBIRHCONFIG pRhConfig = (PVUSBIRHCONFIG) pBase-> pfnQueryInterface (pBase, PDMINTERFACE_VUSB_RH_CONFIG); ComAssertRet (pRhConfig, E_FAIL); return attachUSBDevice (aDevice, false /* aManual */, pRhConfig); } /** * Called by IInternalSessionControl::OnUSBDeviceDetach() and locally by * processRemoteUSBDevices(). * * @note Locks this object for writing. */ HRESULT Console::onUSBDeviceDetach (INPTR GUIDPARAM aId) { Guid Uuid (aId); LogFlowThisFunc (("aId={%Vuuid}\n", Uuid.raw())); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); /* Find the device. */ ComObjPtr device; USBDeviceList::iterator it = mUSBDevices.begin(); while (it != mUSBDevices.end()) { LogFlowThisFunc (("it={%Vuuid}\n", (*it)->id().raw())); if ((*it)->id() == Uuid) { device = *it; break; } ++ it; } /* VM might have been stopped when this message arrives */ if (device.isNull()) { LogFlowThisFunc (("Device not found.\n")); if (mMachineState < MachineState_Running) { LogFlowThisFunc (("Detach request ignored (mMachineState=%d).\n", mMachineState)); return E_FAIL; } /* the device must be in the list */ AssertFailedReturn (E_FAIL); } /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); PPDMIBASE pBase = NULL; int vrc = PDMR3QueryLun (mpVM, "usb-ohci", 0, 0, &pBase); /* if the device is attached, then there must be a USB controller */ AssertRCReturn (vrc, E_FAIL); PVUSBIRHCONFIG pRhConfig = (PVUSBIRHCONFIG) pBase-> pfnQueryInterface (pBase, PDMINTERFACE_VUSB_RH_CONFIG); AssertReturn (pRhConfig, E_FAIL); LogFlowThisFunc (("Detaching USB proxy device {%Vuuid}...\n", Uuid.raw())); /* leave the lock before a VMR3* call (EMT will call us back)! */ alock.leave(); PVMREQ pReq; vrc = VMR3ReqCall (mpVM, &pReq, RT_INDEFINITE_WAIT, (PFNRT) usbDetachCallback, 5, this, &it, false /* aManual */, pRhConfig, Uuid.raw()); if (VBOX_SUCCESS (vrc)) vrc = pReq->iStatus; VMR3ReqFree (pReq); AssertRC (vrc); return VBOX_SUCCESS (vrc) ? S_OK : E_FAIL; } /** * Gets called by Session::UpdateMachineState() * (IInternalSessionControl::updateMachineState()). * * Must be called only in certain cases (see the implementation). * * @note Locks this object for writing. */ HRESULT Console::updateMachineState (MachineState_T aMachineState) { AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); AssertReturn (mMachineState == MachineState_Saving || mMachineState == MachineState_Discarding, E_FAIL); return setMachineStateLocally (aMachineState); } /** * @note Locks this object for reading. */ void Console::onMousePointerShapeChange(bool fVisible, bool fAlpha, uint32_t xHot, uint32_t yHot, uint32_t width, uint32_t height, void *pShape) { LogFlowThisFunc (("fVisible=%d, fAlpha=%d, xHot = %d, yHot = %d, width=%d, " "height=%d, shape=%p\n", fVisible, fAlpha, xHot, yHot, width, height, pShape)); AutoReaderLock alock (this); CallbackList::iterator it = mCallbacks.begin(); while (it != mCallbacks.end()) (*it++)->OnMousePointerShapeChange (fVisible, fAlpha, xHot, yHot, width, height, (BYTE *) pShape); } /** * @note Locks this object for reading. */ void Console::onMouseCapabilityChange (BOOL supportsAbsolute, BOOL needsHostCursor) { LogFlowThisFunc (("supportsAbsolute=%d needsHostCursor=%d\n", supportsAbsolute, needsHostCursor)); AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoReaderLock alock (this); CallbackList::iterator it = mCallbacks.begin(); while (it != mCallbacks.end()) { Log2(("Console::onMouseCapabilityChange: calling %p\n", (void*)*it)); (*it++)->OnMouseCapabilityChange (supportsAbsolute, needsHostCursor); } } /** * @note Locks this object for reading. */ void Console::onStateChange (MachineState_T machineState) { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoReaderLock alock (this); CallbackList::iterator it = mCallbacks.begin(); while (it != mCallbacks.end()) (*it++)->OnStateChange (machineState); } /** * @note Locks this object for reading. */ void Console::onAdditionsStateChange() { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoReaderLock alock (this); CallbackList::iterator it = mCallbacks.begin(); while (it != mCallbacks.end()) (*it++)->OnAdditionsStateChange(); } /** * @note Locks this object for reading. */ void Console::onAdditionsOutdated() { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoReaderLock alock (this); /** @todo Use the On-Screen Display feature to report the fact. * The user should be told to install additions that are * provided with the current VBox build: * VBOX_VERSION_MAJOR.VBOX_VERSION_MINOR.VBOX_VERSION_BUILD */ } /** * @note Locks this object for reading. */ void Console::onKeyboardLedsChange(bool fNumLock, bool fCapsLock, bool fScrollLock) { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoReaderLock alock (this); CallbackList::iterator it = mCallbacks.begin(); while (it != mCallbacks.end()) (*it++)->OnKeyboardLedsChange(fNumLock, fCapsLock, fScrollLock); } /** * @note Locks this object for reading. */ void Console::onRuntimeError (BOOL aFatal, INPTR BSTR aErrorID, INPTR BSTR aMessage) { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoReaderLock alock (this); CallbackList::iterator it = mCallbacks.begin(); while (it != mCallbacks.end()) (*it++)->OnRuntimeError (aFatal, aErrorID, aMessage); } // private mehtods //////////////////////////////////////////////////////////////////////////////// /** * Increases the usage counter of the mpVM pointer. Guarantees that * VMR3Destroy() will not be called on it at least until releaseVMCaller() * is called. * * If this method returns a failure, the caller is not allowed to use mpVM * and may return the failed result code to the upper level. This method sets * the extended error info on failure if \a aQuiet is false. * * Setting \a aQuiet to true is useful for methods that don't want to return * the failed result code to the caller when this method fails (e.g. need to * silently check for the mpVM avaliability). * * When mpVM is NULL but \a aAllowNullVM is true, a corresponding error will be * returned instead of asserting. Having it false is intended as a sanity check * for methods that have checked mMachineState and expect mpVM *NOT* to be NULL. * * @param aQuiet true to suppress setting error info * @param aAllowNullVM true to accept mpVM being NULL and return a failure * (otherwise this method will assert if mpVM is NULL) * * @note Locks this object for writing. */ HRESULT Console::addVMCaller (bool aQuiet /* = false */, bool aAllowNullVM /* = false */) { AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); if (mVMDestroying) { /* powerDown() is waiting for all callers to finish */ return aQuiet ? E_ACCESSDENIED : setError (E_ACCESSDENIED, tr ("Virtual machine is being powered down")); } if (mpVM == NULL) { Assert (aAllowNullVM == true); /* The machine is not powered up */ return aQuiet ? E_ACCESSDENIED : setError (E_ACCESSDENIED, tr ("Virtual machine is not powered up")); } ++ mVMCallers; return S_OK; } /** * Decreases the usage counter of the mpVM pointer. Must always complete * the addVMCaller() call after the mpVM pointer is no more necessary. * * @note Locks this object for writing. */ void Console::releaseVMCaller() { AutoCaller autoCaller (this); AssertComRCReturnVoid (autoCaller.rc()); AutoLock alock (this); AssertReturnVoid (mpVM != NULL); Assert (mVMCallers > 0); -- mVMCallers; if (mVMCallers == 0 && mVMDestroying) { /* inform powerDown() there are no more callers */ RTSemEventSignal (mVMZeroCallersSem); } } /** * Internal power off worker routine. * * This method may be called only at certain places with the folliwing meaning * as shown below: * * - if the machine state is either Running or Paused, a normal * Console-initiated powerdown takes place (e.g. PowerDown()); * - if the machine state is Saving, saveStateThread() has successfully * done its job; * - if the machine state is Starting or Restoring, powerUpThread() has * failed to start/load the VM; * - if the machine state is Stopping, the VM has powered itself off * (i.e. not as a result of the powerDown() call). * * Calling it in situations other than the above will cause unexpected * behavior. * * Note that this method should be the only one that destroys mpVM and sets * it to NULL. * * @note Locks this object for writing. * * @note Never call this method from a thread that called addVMCaller() or * instantiated an AutoVMCaller object; first call releaseVMCaller() or * release(). Otherwise it will deadlock. */ HRESULT Console::powerDown() { LogFlowThisFuncEnter(); AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); /* sanity */ AssertReturn (mVMDestroying == false, E_FAIL); LogRel (("Console::powerDown(): a request to power off the VM has been issued " "(mMachineState=%d, InUninit=%d)\n", mMachineState, autoCaller.state() == InUninit)); /* First, wait for all mpVM callers to finish their work if necessary */ if (mVMCallers > 0) { /* go to the destroying state to prevent from adding new callers */ mVMDestroying = true; /* lazy creation */ if (mVMZeroCallersSem == NIL_RTSEMEVENT) RTSemEventCreate (&mVMZeroCallersSem); LogFlowThisFunc (("Waiting for mpVM callers (%d) to drop to zero...\n", mVMCallers)); alock.leave(); RTSemEventWait (mVMZeroCallersSem, RT_INDEFINITE_WAIT); alock.enter(); } AssertReturn (mpVM, E_FAIL); AssertMsg (mMachineState == MachineState_Running || mMachineState == MachineState_Paused || mMachineState == MachineState_Saving || mMachineState == MachineState_Starting || mMachineState == MachineState_Restoring || mMachineState == MachineState_Stopping, ("Invalid machine state: %d\n", mMachineState)); HRESULT rc = S_OK; int vrc = VINF_SUCCESS; /* * Power off the VM if not already done that. In case of Stopping, the VM * has powered itself off and notified Console in vmstateChangeCallback(). * In case of Starting or Restoring, powerUpThread() is calling us on * failure, so the VM is already off at that point. */ if (mMachineState != MachineState_Stopping && mMachineState != MachineState_Starting && mMachineState != MachineState_Restoring) { /* * don't go from Saving to Stopping, vmstateChangeCallback needs it * to set the state to Saved on VMSTATE_TERMINATED. */ if (mMachineState != MachineState_Saving) setMachineState (MachineState_Stopping); LogFlowThisFunc (("Powering off the VM...\n")); /* Leave the lock since EMT will call us back on VMR3PowerOff() */ alock.leave(); vrc = VMR3PowerOff (mpVM); /* * Note that VMR3PowerOff() may fail here (invalid VMSTATE) if the * VM-(guest-)initiated power off happened in parallel a ms before * this call. So far, we let this error pop up on the user's side. */ alock.enter(); } LogFlowThisFunc (("Ready for VM destruction\n")); /* * If we are called from Console::uninit(), then try to destroy the VM * even on failure (this will most likely fail too, but what to do?..) */ if (VBOX_SUCCESS (vrc) || autoCaller.state() == InUninit) { /* * Stop the VRDP server and release all USB device. * (When called from uninit mConsoleVRDPServer is already destroyed.) */ if (mConsoleVRDPServer) { LogFlowThisFunc (("Stopping VRDP server...\n")); mConsoleVRDPServer->Stop(); } releaseAllUSBDevices(); /* * Now we've got to destroy the VM as well. (mpVM is not valid * beyond this point). We leave the lock before calling VMR3Destroy() * because it will result into calling destructors of drivers * associated with Console children which may in turn try to lock * Console (e.g. by instantiating SafeVMPtr to access mpVM). It's safe * here because mVMDestroying is set which should prevent any activity. */ /* * Set mpVM to NULL early just in case if some old code is not using * addVMCaller()/releaseVMCaller(). */ PVM pVM = mpVM; mpVM = NULL; LogFlowThisFunc (("Destroying the VM...\n")); alock.leave(); vrc = VMR3Destroy (pVM); /* take the lock again */ alock.enter(); if (VBOX_SUCCESS (vrc)) { LogFlowThisFunc (("Machine has been destroyed (mMachineState=%d)\n", mMachineState)); /* * Note: the Console-level machine state change happens on the * VMSTATE_TERMINATE state change in vmstateChangeCallback(). If * powerDown() is called from EMT (i.e. from vmstateChangeCallback() * on receiving VM-initiated VMSTATE_OFF), VMSTATE_TERMINATE hasn't * occured yet. This is okay, because mMachineState is already * Stopping in this case, so any other attempt to call PowerDown() * will be rejected. */ } else { /* bad bad bad, but what to do? */ mpVM = pVM; rc = setError (E_FAIL, tr ("Could not destroy the machine. (Error: %Vrc)"), vrc); } } else { rc = setError (E_FAIL, tr ("Could not power off the machine. (Error: %Vrc)"), vrc); } /* * Finished with destruction. Note that if something impossible happened * and we've failed to destroy the VM, mVMDestroying will remain false and * mMachineState will be something like Stopping, so most Console methods * will return an error to the caller. */ if (mpVM == NULL) mVMDestroying = false; LogFlowThisFuncLeave(); return rc; } /** * @note Locks this object for writing. */ HRESULT Console::setMachineState (MachineState_T aMachineState, bool aUpdateServer /* = true */) { AutoCaller autoCaller (this); AssertComRCReturnRC (autoCaller.rc()); AutoLock alock (this); HRESULT rc = S_OK; if (mMachineState != aMachineState) { LogFlowThisFunc (("machineState=%d\n", aMachineState)); mMachineState = aMachineState; /// @todo (dmik) // possibly, we need to redo onStateChange() using the dedicated // Event thread, like it is done in VirtualBox. This will make it // much safer (no deadlocks possible if someone tries to use the // console from the callback), however, listeners will lose the // ability to synchronously react to state changes (is it really // necessary??) LogFlowThisFunc (("Doing onStateChange()...\n")); onStateChange (aMachineState); LogFlowThisFunc (("Done onStateChange()\n")); if (aUpdateServer) { /* * Server notification MUST be done from under the lock; otherwise * the machine state here and on the server might go out of sync, that * can lead to various unexpected results (like the machine state being * >= MachineState_Running on the server, while the session state is * already SessionState_SessionClosed at the same time there). * * Cross-lock conditions should be carefully watched out: calling * UpdateState we will require Machine and SessionMachine locks * (remember that here we're holding the Console lock here, and * also all locks that have been entered by the thread before calling * this method). */ LogFlowThisFunc (("Doing mControl->UpdateState()...\n")); rc = mControl->UpdateState (aMachineState); LogFlowThisFunc (("mControl->UpdateState()=%08X\n", rc)); } } return rc; } /** * 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 The caller must lock this object for writing. */ HRESULT Console::findSharedFolder (const BSTR aName, ComObjPtr &aSharedFolder, bool aSetError /* = false */) { /* sanity check */ AssertReturn (isLockedOnCurrentThread(), E_FAIL); bool found = false; for (SharedFolderList::const_iterator it = mSharedFolders.begin(); !found && it != mSharedFolders.end(); ++ it) { AutoLock 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; } /** * VM state callback function. Called by the VMM * using its state machine states. * * Primarily used to handle VM initiated power off, suspend and state saving, * but also for doing termination completed work (VMSTATE_TERMINATE). * * In general this function is called in the context of the EMT. * * @param aVM The VM handle. * @param aState The new state. * @param aOldState The old state. * @param aUser The user argument (pointer to the Console object). * * @note Locks the Console object for writing. */ DECLCALLBACK(void) Console::vmstateChangeCallback (PVM aVM, VMSTATE aState, VMSTATE aOldState, void *aUser) { LogFlowFunc (("Changing state from %d to %d (aVM=%p)\n", aOldState, aState, aVM)); Console *that = static_cast (aUser); AssertReturnVoid (that); AutoCaller autoCaller (that); /* * Note that we must let this method proceed even if Console::uninit() has * been already called. In such case this VMSTATE change is a result of: * 1) powerDown() called from uninit() itself, or * 2) VM-(guest-)initiated power off. */ AssertReturnVoid (autoCaller.isOk() || autoCaller.state() == InUninit); switch (aState) { /* * The VM has terminated */ case VMSTATE_OFF: { AutoLock alock (that); if (that->mVMStateChangeCallbackDisabled) break; /* * Do we still think that it is running? It may happen if this is * a VM-(guest-)initiated shutdown/poweroff. */ if (that->mMachineState != MachineState_Stopping && that->mMachineState != MachineState_Saving && that->mMachineState != MachineState_Restoring) { LogFlowFunc (("VM has powered itself off but Console still " "thinks it is running. Notifying.\n")); /* prevent powerDown() from calling VMR3PowerOff() again */ that->setMachineState (MachineState_Stopping); /* * Setup task object and thread to carry out the operation * asynchronously (if we call powerDown() right here but there * is one or more mpVM callers (added with addVMCaller()) we'll * deadlock. */ std::auto_ptr task (new VMTask (that, true /* aUsesVMPtr */)); /* * If creating a task is falied, this can currently mean one * of two: either Console::uninit() has been called just a ms * before (so a powerDown() call is already on the way), or * powerDown() itself is being already executed. Just do * nothing . */ if (!task->isOk()) { LogFlowFunc (("Console is already being uninitialized.\n")); break; } int vrc = RTThreadCreate (NULL, Console::powerDownThread, (void *) task.get(), 0, RTTHREADTYPE_MAIN_WORKER, 0, "VMPowerDowm"); AssertMsgRC (vrc, ("Could not create VMPowerUp thread (%Vrc)\n", vrc)); if (VBOX_FAILURE (vrc)) break; /* task is now owned by powerDownThread(), so release it */ task.release(); } break; } /* * The VM has been completely destroyed. * * Note: This state change can happen at two points: * 1) At the end of VMR3Destroy() if it was not called from EMT. * 2) At the end of vmR3EmulationThread if VMR3Destroy() was * called by EMT. */ case VMSTATE_TERMINATED: { AutoLock alock (that); if (that->mVMStateChangeCallbackDisabled) break; /* * Terminate host interface networking. If aVM is NULL, we've been * manually called from powerUpThread() either before calling * VMR3Create() or after VMR3Create() failed, so no need to touch * networking. */ if (aVM) that->powerDownHostInterfaces(); /* * From now on the machine is officially powered down or * remains in the Saved state. */ switch (that->mMachineState) { default: AssertFailed(); /* fall through */ case MachineState_Stopping: /* successfully powered down */ that->setMachineState (MachineState_PoweredOff); break; case MachineState_Saving: /* * successfully saved (note that the machine is already * in the Saved state on the server due to EndSavingState() * called from saveStateThread(), so only change the local * state) */ that->setMachineStateLocally (MachineState_Saved); break; case MachineState_Starting: /* * failed to start, but be patient: set back to PoweredOff * (for similarity with the below) */ that->setMachineState (MachineState_PoweredOff); break; case MachineState_Restoring: /* * failed to load the saved state file, but be patient: * set back to Saved (to preserve the saved state file) */ that->setMachineState (MachineState_Saved); break; } break; } case VMSTATE_SUSPENDED: { if (aOldState == VMSTATE_RUNNING) { AutoLock alock (that); if (that->mVMStateChangeCallbackDisabled) break; /* Change the machine state from Running to Paused */ Assert (that->mMachineState == MachineState_Running); that->setMachineState (MachineState_Paused); } } case VMSTATE_RUNNING: { if (aOldState == VMSTATE_CREATED || aOldState == VMSTATE_SUSPENDED) { AutoLock alock (that); if (that->mVMStateChangeCallbackDisabled) break; /* * Change the machine state from Starting, Restoring or Paused * to Running */ Assert ((that->mMachineState == MachineState_Starting && aOldState == VMSTATE_CREATED) || ((that->mMachineState == MachineState_Restoring || that->mMachineState == MachineState_Paused) && aOldState == VMSTATE_SUSPENDED)); that->setMachineState (MachineState_Running); } } default: /* shut up gcc */ break; } } /** * Sends a request to VMM to attach the given host device. * After this method succeeds, the attached device will appear in the * mUSBDevices collection. * * If \a aManual is true and a failure occures, the given device * will be returned back to the USB proxy manager. * * @param aHostDevice device to attach * @param aManual true if device is being manually attached * * @note Locks this object for writing. * @note Synchronously calls EMT. */ HRESULT Console::attachUSBDevice (IUSBDevice *aHostDevice, bool aManual, PVUSBIRHCONFIG aConfig) { AssertReturn (aHostDevice && aConfig, E_FAIL); AutoLock alock (this); HRESULT hrc; /* * Get the address and the Uuid, and call the pfnCreateProxyDevice roothub * method in EMT (using usbAttachCallback()). */ Bstr BstrAddress; hrc = aHostDevice->COMGETTER (Address) (BstrAddress.asOutParam()); ComAssertComRCRetRC (hrc); Utf8Str Address (BstrAddress); Guid Uuid; hrc = aHostDevice->COMGETTER (Id) (Uuid.asOutParam()); ComAssertComRCRetRC (hrc); BOOL fRemote = FALSE; void *pvRemote = NULL; hrc = aHostDevice->COMGETTER (Remote) (&fRemote); ComAssertComRCRetRC (hrc); #ifndef VRDP_MC if (fRemote) { pvRemote = mConsoleVRDPServer->GetUSBBackendPointer (); ComAssertRet (pvRemote, E_FAIL); } #endif /* !VRDP_MC */ /* protect mpVM */ AutoVMCaller autoVMCaller (this); CheckComRCReturnRC (autoVMCaller.rc()); LogFlowThisFunc (("Proxying USB device '%s' {%Vuuid}...\n", Address.raw(), Uuid.ptr())); /* leave the lock before a VMR3* call (EMT will call us back)! */ alock.leave(); PVMREQ pReq = NULL; int vrc = VMR3ReqCall (mpVM, &pReq, RT_INDEFINITE_WAIT, (PFNRT) usbAttachCallback, 7, this, aHostDevice, aConfig, Uuid.ptr(), fRemote, Address.raw(), pvRemote); if (VBOX_SUCCESS (vrc)) vrc = pReq->iStatus; VMR3ReqFree (pReq); /* restore the lock */ alock.enter(); /* hrc is S_OK here */ if (VBOX_FAILURE (vrc)) { LogWarningThisFunc (("Failed to create proxy device for '%s' {%Vuuid} (%Vrc)\n", Address.raw(), Uuid.ptr(), vrc)); if (aManual) { /* * Neither SessionMachine::ReleaseUSBDevice() nor Host::releaseUSBDevice() * should call the Console back, so keep the lock to provide atomicity * (to protect Host reapplying USB filters) */ hrc = mControl->ReleaseUSBDevice (Uuid); AssertComRC (hrc); } switch (vrc) { case VERR_VUSB_NO_PORTS: hrc = setError (E_FAIL, tr ("Failed to attach the USB device. (No available ports on the USB controller).")); break; case VERR_VUSB_USBFS_PERMISSION: hrc = setError (E_FAIL, tr ("Not permitted to open the USB device, check usbfs options")); break; default: hrc = setError (E_FAIL, tr ("Failed to create a proxy device for the USB device. (Error: %Vrc)"), vrc); break; } } return hrc; } /** * USB device attack callback used by AttachUSBDevice(). * Note that AttachUSBDevice() doesn't return until this callback is executed, * so we don't use AutoCaller and don't care about reference counters of * interface pointers passed in. * * @thread EMT * @note Locks the console object for writing. */ //static DECLCALLBACK(int) Console::usbAttachCallback (Console *that, IUSBDevice *aHostDevice, PVUSBIRHCONFIG aConfig, PCRTUUID aUuid, bool aRemote, const char *aAddress, void *aRemoteBackend) { LogFlowFuncEnter(); LogFlowFunc (("that={%p}\n", that)); AssertReturn (that && aConfig && aUuid, VERR_INVALID_PARAMETER); #ifdef VRDP_MC if (aRemote) { /* @todo aRemoteBackend input parameter is not needed. */ Assert (aRemoteBackend == NULL); RemoteUSBDevice *pRemoteUSBDevice = static_cast (aHostDevice); Guid guid (*aUuid); aRemoteBackend = that->consoleVRDPServer ()->USBBackendRequestPointer (pRemoteUSBDevice->clientId (), &guid); if (aRemoteBackend == NULL) { /* The clientId is invalid then. */ return VERR_INVALID_PARAMETER; } } #endif /* VRDP_MC */ int vrc = aConfig->pfnCreateProxyDevice (aConfig, aUuid, aRemote, aAddress, aRemoteBackend); if (VBOX_SUCCESS (vrc)) { /* Create a OUSBDevice and add it to the device list */ ComObjPtr device; device.createObject(); HRESULT hrc = device->init (aHostDevice); AssertComRC (hrc); AutoLock alock (that); that->mUSBDevices.push_back (device); LogFlowFunc (("Attached device {%Vuuid}\n", device->id().raw())); } LogFlowFunc (("vrc=%Vrc\n", vrc)); LogFlowFuncLeave(); return vrc; } /** * USB device attack callback used by AttachUSBDevice(). * Note that AttachUSBDevice() doesn't return until this callback is executed, * so we don't use AutoCaller and don't care about reference counters of * interface pointers passed in. * * @thread EMT * @note Locks the console object for writing. */ //static DECLCALLBACK(int) Console::usbDetachCallback (Console *that, USBDeviceList::iterator *aIt, bool aManual, PVUSBIRHCONFIG aConfig, PCRTUUID aUuid) { LogFlowFuncEnter(); LogFlowFunc (("that={%p}\n", that)); AssertReturn (that && aConfig && aUuid, VERR_INVALID_PARAMETER); #ifdef VRDP_MC /* * If that was a remote device, release the backend pointer. * The pointer was requested in usbAttachCallback. */ BOOL fRemote = FALSE; HRESULT hrc2 = (**aIt)->COMGETTER (Remote) (&fRemote); ComAssertComRC (hrc2); if (fRemote) { Guid guid (*aUuid); that->consoleVRDPServer ()->USBBackendReleasePointer (&guid); } #endif /* VRDP_MC */ int vrc = aConfig->pfnDestroyProxyDevice (aConfig, aUuid); if (VBOX_SUCCESS (vrc)) { AutoLock alock (that); /* Remove the device from the collection */ that->mUSBDevices.erase (*aIt); LogFlowFunc (("Detached device {%Vuuid}\n", (**aIt)->id().raw())); /// @todo (dmik) REMOTE_USB // if the device is remote, notify a remote client that we have // detached the device /* If it's a manual detach, give it back to the USB Proxy */ if (aManual) { /* * Neither SessionMachine::ReleaseUSBDevice() nor Host::releaseUSBDevice() * should call the Console back, so keep the lock to provide atomicity * (to protect Host reapplying USB filters) */ LogFlowFunc (("Giving it back it to USB proxy...\n")); HRESULT hrc = that->mControl->ReleaseUSBDevice (Guid (*aUuid)); AssertComRC (hrc); vrc = SUCCEEDED (hrc) ? VINF_SUCCESS : VERR_GENERAL_FAILURE; } } LogFlowFunc (("vrc=%Vrc\n", vrc)); LogFlowFuncLeave(); return vrc; } /** * Construct the VM configuration tree (CFGM). * * This is a callback for VMR3Create() call. It is called from CFGMR3Init() * in the emulation thread (EMT). Any per thread COM/XPCOM initialization * is done here. * * @param pVM VM handle. * @param pvTask Pointer to the VMPowerUpTask object. * @return VBox status code. * * @note Locks the Console object for writing. */ DECLCALLBACK(int) Console::configConstructor(PVM pVM, void *pvTask) { LogFlowFuncEnter(); /* Note: the task pointer is owned by powerUpThread() */ VMPowerUpTask *task = static_cast (pvTask); AssertReturn (task, VERR_GENERAL_FAILURE); #if defined(__WIN__) { /* initialize COM */ HRESULT hrc = CoInitializeEx(NULL, COINIT_MULTITHREADED | COINIT_DISABLE_OLE1DDE | COINIT_SPEED_OVER_MEMORY); LogFlow (("Console::configConstructor(): CoInitializeEx()=%08X\n", hrc)); AssertComRCReturn (hrc, VERR_GENERAL_FAILURE); } #endif ComObjPtr pConsole = task->mConsole; AutoCaller autoCaller (pConsole); AssertComRCReturn (autoCaller.rc(), VERR_ACCESS_DENIED); /* lock the console because we widely use internal fields and methods */ AutoLock alock (pConsole); ComPtr pMachine = pConsole->machine(); int rc; HRESULT hrc; char *psz = NULL; BSTR str = NULL; ULONG cRamMBs; unsigned i; #define STR_CONV() do { rc = RTStrUcs2ToUtf8(&psz, str); RC_CHECK(); } while (0) #define STR_FREE() do { if (str) { SysFreeString(str); str = NULL; } if (psz) { RTStrFree(psz); psz = NULL; } } while (0) #define RC_CHECK() do { if (VBOX_FAILURE(rc)) { AssertMsgFailed(("rc=%Vrc\n", rc)); STR_FREE(); return rc; } } while (0) #define H() do { if (FAILED(hrc)) { AssertMsgFailed(("hrc=%#x\n", hrc)); STR_FREE(); return VERR_GENERAL_FAILURE; } } while (0) /* Get necessary objects */ ComPtr virtualBox; hrc = pMachine->COMGETTER(Parent)(virtualBox.asOutParam()); H(); ComPtr host; hrc = virtualBox->COMGETTER(Host)(host.asOutParam()); H(); ComPtr systemProperties; hrc = virtualBox->COMGETTER(SystemProperties)(systemProperties.asOutParam()); H(); ComPtr biosSettings; hrc = pMachine->COMGETTER(BIOSSettings)(biosSettings.asOutParam()); H(); /* * Get root node first. * This is the only node in the tree. */ PCFGMNODE pRoot = CFGMR3GetRoot(pVM); Assert(pRoot); /* * Set the root level values. */ hrc = pMachine->COMGETTER(Name)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pRoot, "Name", psz); RC_CHECK(); STR_FREE(); hrc = pMachine->COMGETTER(MemorySize)(&cRamMBs); H(); rc = CFGMR3InsertInteger(pRoot, "RamSize", cRamMBs * _1M); RC_CHECK(); rc = CFGMR3InsertInteger(pRoot, "TimerMillies", 10); RC_CHECK(); rc = CFGMR3InsertInteger(pRoot, "RawR3Enabled", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertInteger(pRoot, "RawR0Enabled", 1); /* boolean */ RC_CHECK(); /** @todo Config: RawR0, PATMEnabled and CASMEnabled needs attention later. */ rc = CFGMR3InsertInteger(pRoot, "PATMEnabled", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertInteger(pRoot, "CSAMEnabled", 1); /* boolean */ RC_CHECK(); /* hardware virtualization extensions */ TriStateBool_T hwVirtExEnabled; BOOL fHWVirtExEnabled; hrc = pMachine->COMGETTER(HWVirtExEnabled)(&hwVirtExEnabled); H(); if (hwVirtExEnabled == TriStateBool_Default) { /* check the default value */ hrc = systemProperties->COMGETTER(HWVirtExEnabled)(&fHWVirtExEnabled); H(); } else fHWVirtExEnabled = (hwVirtExEnabled == TriStateBool_True); if (fHWVirtExEnabled) { PCFGMNODE pHWVirtExt; rc = CFGMR3InsertNode(pRoot, "HWVirtExt", &pHWVirtExt); RC_CHECK(); rc = CFGMR3InsertInteger(pHWVirtExt, "Enabled", 1); RC_CHECK(); } BOOL fIOAPIC; hrc = biosSettings->COMGETTER(IOAPICEnabled)(&fIOAPIC); H(); /* * PDM config. * Load drivers in VBoxC.[so|dll] */ PCFGMNODE pPDM; PCFGMNODE pDrivers; PCFGMNODE pMod; rc = CFGMR3InsertNode(pRoot, "PDM", &pPDM); RC_CHECK(); rc = CFGMR3InsertNode(pPDM, "Drivers", &pDrivers); RC_CHECK(); rc = CFGMR3InsertNode(pDrivers, "VBoxC", &pMod); RC_CHECK(); #ifdef VBOX_WITH_XPCOM // VBoxC is located in the components subdirectory char szPathProgram[RTPATH_MAX + sizeof("/components/VBoxC")]; rc = RTPathProgram(szPathProgram, RTPATH_MAX); AssertRC(rc); strcat(szPathProgram, "/components/VBoxC"); rc = CFGMR3InsertString(pMod, "Path", szPathProgram); RC_CHECK(); #else rc = CFGMR3InsertString(pMod, "Path", "VBoxC"); RC_CHECK(); #endif /* * Devices */ PCFGMNODE pDevices = NULL; /* /Devices */ PCFGMNODE pDev = NULL; /* /Devices/Dev/ */ PCFGMNODE pInst = NULL; /* /Devices/Dev/0/ */ PCFGMNODE pCfg = NULL; /* /Devices/Dev/.../Config/ */ PCFGMNODE pLunL0 = NULL; /* /Devices/Dev/0/LUN#0/ */ PCFGMNODE pLunL1 = NULL; /* /Devices/Dev/0/LUN#0/AttachedDriver/ */ rc = CFGMR3InsertNode(pRoot, "Devices", &pDevices); RC_CHECK(); /* * PC Arch. */ rc = CFGMR3InsertNode(pDevices, "pcarch", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); /* * PC Bios. */ rc = CFGMR3InsertNode(pDevices, "pcbios", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "RamSize", cRamMBs * _1M); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "HardDiskDevice", "piix3ide"); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "FloppyDevice", "i82078"); RC_CHECK(); DeviceType_T bootDevice; if (SchemaDefs::MaxBootPosition > 9) { AssertMsgFailed (("Too many boot devices %d\n", SchemaDefs::MaxBootPosition)); return VERR_INVALID_PARAMETER; } for (ULONG pos = 1; pos <= SchemaDefs::MaxBootPosition; pos ++) { hrc = pMachine->GetBootOrder(pos, &bootDevice); H(); char szParamName[] = "BootDeviceX"; szParamName[sizeof (szParamName) - 2] = ((char (pos - 1)) + '0'); const char *pszBootDevice; switch (bootDevice) { case DeviceType_NoDevice: pszBootDevice = "NONE"; break; case DeviceType_HardDiskDevice: pszBootDevice = "IDE"; break; case DeviceType_DVDDevice: pszBootDevice = "DVD"; break; case DeviceType_FloppyDevice: pszBootDevice = "FLOPPY"; break; case DeviceType_NetworkDevice: pszBootDevice = "LAN"; break; default: AssertMsgFailed(("Invalid bootDevice=%d\n", bootDevice)); return VERR_INVALID_PARAMETER; } rc = CFGMR3InsertString(pCfg, szParamName, pszBootDevice); RC_CHECK(); } /* * BIOS logo */ BOOL fFadeIn; hrc = biosSettings->COMGETTER(LogoFadeIn)(&fFadeIn); H(); rc = CFGMR3InsertInteger(pCfg, "FadeIn", fFadeIn ? 1 : 0); RC_CHECK(); BOOL fFadeOut; hrc = biosSettings->COMGETTER(LogoFadeOut)(&fFadeOut); H(); rc = CFGMR3InsertInteger(pCfg, "FadeOut", fFadeOut ? 1: 0); RC_CHECK(); ULONG logoDisplayTime; hrc = biosSettings->COMGETTER(LogoDisplayTime)(&logoDisplayTime); H(); rc = CFGMR3InsertInteger(pCfg, "LogoTime", logoDisplayTime); RC_CHECK(); Bstr logoImagePath; hrc = biosSettings->COMGETTER(LogoImagePath)(logoImagePath.asOutParam()); H(); rc = CFGMR3InsertString(pCfg, "LogoFile", logoImagePath ? Utf8Str(logoImagePath) : ""); RC_CHECK(); /* * Boot menu */ BIOSBootMenuMode_T bootMenuMode; int value; biosSettings->COMGETTER(BootMenuMode)(&bootMenuMode); switch (bootMenuMode) { case BIOSBootMenuMode_Disabled: value = 0; break; case BIOSBootMenuMode_MenuOnly: value = 1; break; default: value = 2; } rc = CFGMR3InsertInteger(pCfg, "ShowBootMenu", value); RC_CHECK(); /* * ACPI */ BOOL fACPI; hrc = biosSettings->COMGETTER(ACPIEnabled)(&fACPI); H(); if (fACPI) { rc = CFGMR3InsertNode(pDevices, "acpi", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "RamSize", cRamMBs * _1M); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IOAPIC", fIOAPIC); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIDeviceNo", 7); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIFunctionNo", 0); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "ACPIHost"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); } /* * DMA */ rc = CFGMR3InsertNode(pDevices, "8237A", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); /* * PCI bus. */ rc = CFGMR3InsertNode(pDevices, "pci", &pDev); /* piix3 */ RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IOAPIC", fIOAPIC); RC_CHECK(); /* * PS/2 keyboard & mouse. */ rc = CFGMR3InsertNode(pDevices, "pckbd", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "KeyboardQueue"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "QueueSize", 64); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL1); RC_CHECK(); rc = CFGMR3InsertString(pLunL1, "Driver", "MainKeyboard"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); Keyboard *pKeyboard = pConsole->mKeyboard; rc = CFGMR3InsertInteger(pCfg, "Object", (uintptr_t)pKeyboard); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "LUN#1", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "MouseQueue"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "QueueSize", 128); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL1); RC_CHECK(); rc = CFGMR3InsertString(pLunL1, "Driver", "MainMouse"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); Mouse *pMouse = pConsole->mMouse; rc = CFGMR3InsertInteger(pCfg, "Object", (uintptr_t)pMouse); RC_CHECK(); /* * i82078 Floppy drive controller */ ComPtr floppyDrive; hrc = pMachine->COMGETTER(FloppyDrive)(floppyDrive.asOutParam()); H(); BOOL fFloppyEnabled; hrc = floppyDrive->COMGETTER(Enabled)(&fFloppyEnabled); H(); if (fFloppyEnabled) { rc = CFGMR3InsertNode(pDevices, "i82078", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IRQ", 6); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "DMA", 2); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "MemMapped", 0 ); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IOBase", 0x3f0); RC_CHECK(); /* Attach the status driver */ rc = CFGMR3InsertNode(pInst, "LUN#999", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "MainStatus"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "papLeds", (uintptr_t)&pConsole->mapFDLeds[0]); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "First", 0); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "Last", 0); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); ComPtr floppyImage; hrc = floppyDrive->GetImage(floppyImage.asOutParam()); H(); if (floppyImage) { pConsole->meFloppyState = DriveState_ImageMounted; rc = CFGMR3InsertString(pLunL0, "Driver", "Block"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "Type", "Floppy 1.44"); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "Mountable", 1); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL1); RC_CHECK(); rc = CFGMR3InsertString(pLunL1, "Driver", "RawImage"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); hrc = floppyImage->COMGETTER(FilePath)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCfg, "Path", psz); RC_CHECK(); STR_FREE(); } else { ComPtr hostFloppyDrive; hrc = floppyDrive->GetHostDrive(hostFloppyDrive.asOutParam()); H(); if (hostFloppyDrive) { pConsole->meFloppyState = DriveState_HostDriveCaptured; rc = CFGMR3InsertString(pLunL0, "Driver", "HostFloppy"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); hrc = hostFloppyDrive->COMGETTER(Name)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCfg, "Path", psz); RC_CHECK(); STR_FREE(); } else { pConsole->meFloppyState = DriveState_NotMounted; rc = CFGMR3InsertString(pLunL0, "Driver", "Block"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "Type", "Floppy 1.44"); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "Mountable", 1); RC_CHECK(); } } } /* * i8254 Programmable Interval Timer And Dummy Speaker */ rc = CFGMR3InsertNode(pDevices, "i8254", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); #ifdef DEBUG rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); #endif /* * i8259 Programmable Interrupt Controller. */ rc = CFGMR3InsertNode(pDevices, "i8259", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); /* * Advanced Programmable Interrupt Controller. */ rc = CFGMR3InsertNode(pDevices, "apic", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); if (fIOAPIC) { /* * I/O Advanced Programmable Interrupt Controller. */ rc = CFGMR3InsertNode(pDevices, "ioapic", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); } /* * RTC MC146818. */ rc = CFGMR3InsertNode(pDevices, "mc146818", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); #if 0 /* * Serial ports */ rc = CFGMR3InsertNode(pDevices, "serial", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IRQ", 4); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IOBase", 0x3f8); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "1", &pInst); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IRQ", 3); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "IOBase", 0x2f8); RC_CHECK(); #endif /* * VGA. */ rc = CFGMR3InsertNode(pDevices, "vga", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIDeviceNo", 2); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIFunctionNo", 0); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); hrc = pMachine->COMGETTER(VRAMSize)(&cRamMBs); H(); rc = CFGMR3InsertInteger(pCfg, "VRamSize", cRamMBs * _1M); RC_CHECK(); /* Custom VESA mode list */ unsigned cModes = 0; for (unsigned iMode = 1; iMode <= 16; iMode++) { char szExtraDataKey[sizeof("CustomVideoModeXX")]; RTStrPrintf(szExtraDataKey, sizeof(szExtraDataKey), "CustomVideoMode%d", iMode); hrc = pMachine->GetExtraData(Bstr(szExtraDataKey), &str); H(); if (!str || !*str) break; STR_CONV(); rc = CFGMR3InsertString(pCfg, szExtraDataKey, psz); STR_FREE(); cModes++; } rc = CFGMR3InsertInteger(pCfg, "CustomVideoModes", cModes); /* VESA height reduction */ ULONG ulHeightReduction; IFramebuffer *pFramebuffer = pConsole->getDisplay()->getFramebuffer(); hrc = pFramebuffer->COMGETTER(HeightReduction)(&ulHeightReduction); H(); rc = CFGMR3InsertInteger(pCfg, "HeightReduction", ulHeightReduction); RC_CHECK(); /* Attach the display. */ rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "MainDisplay"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); Display *pDisplay = pConsole->mDisplay; rc = CFGMR3InsertInteger(pCfg, "Object", (uintptr_t)pDisplay); RC_CHECK(); /* * IDE (update this when the main interface changes) */ rc = CFGMR3InsertNode(pDevices, "piix3ide", &pDev); /* piix3 */ RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIDeviceNo", 1); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIFunctionNo", 1); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); /* Attach the status driver */ rc = CFGMR3InsertNode(pInst, "LUN#999", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "MainStatus"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "papLeds", (uintptr_t)&pConsole->mapIDELeds[0]);RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "First", 0); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "Last", 3); RC_CHECK(); /* Attach the harddisks */ ComPtr hdaColl; hrc = pMachine->COMGETTER(HardDiskAttachments)(hdaColl.asOutParam()); H(); ComPtr hdaEnum; hrc = hdaColl->Enumerate(hdaEnum.asOutParam()); H(); BOOL fMore = FALSE; while ( SUCCEEDED(hrc = hdaEnum->HasMore(&fMore)) && fMore) { ComPtr hda; hrc = hdaEnum->GetNext(hda.asOutParam()); H(); ComPtr hardDisk; hrc = hda->COMGETTER(HardDisk)(hardDisk.asOutParam()); H(); DiskControllerType_T enmCtl; hrc = hda->COMGETTER(Controller)(&enmCtl); H(); LONG lDev; hrc = hda->COMGETTER(DeviceNumber)(&lDev); H(); switch (enmCtl) { case DiskControllerType_IDE0Controller: i = 0; break; case DiskControllerType_IDE1Controller: i = 2; break; default: AssertMsgFailed(("invalid disk controller type: %d\n", enmCtl)); return VERR_GENERAL_FAILURE; } if (lDev < 0 || lDev >= 2) { AssertMsgFailed(("invalid controller device number: %d\n", lDev)); return VERR_GENERAL_FAILURE; } i = i + lDev; char szLUN[16]; RTStrPrintf(szLUN, sizeof(szLUN), "LUN#%d", i); rc = CFGMR3InsertNode(pInst, szLUN, &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "Block"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "Type", "HardDisk"); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "Mountable", 0); RC_CHECK(); HardDiskStorageType_T hddType; hardDisk->COMGETTER(StorageType)(&hddType); if (hddType == HardDiskStorageType_VirtualDiskImage) { rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL1); RC_CHECK(); rc = CFGMR3InsertString(pLunL1, "Driver", "VBoxHDD"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); /// @todo (dmik) we temporarily use the location property to // determine the image file name. This is subject to change // when iSCSI disks are here (we should either query a // storage-specific interface from IHardDisk, or "standardize" // the location property) hrc = hardDisk->COMGETTER(Location)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCfg, "Path", psz); RC_CHECK(); STR_FREE(); /* Create an inversed tree of parents. */ ComPtr parentHardDisk = hardDisk; for (PCFGMNODE pParent = pCfg;;) { ComPtr curHardDisk; hrc = parentHardDisk->COMGETTER(Parent)(curHardDisk.asOutParam()); H(); if (!curHardDisk) break; PCFGMNODE pCur; rc = CFGMR3InsertNode(pParent, "Parent", &pCur); RC_CHECK(); /// @todo (dmik) we temporarily use the location property to // determine the image file name. This is subject to change // when iSCSI disks are here (we should either query a // storage-specific interface from IHardDisk, or "standardize" // the location property) hrc = curHardDisk->COMGETTER(Location)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCur, "Path", psz); RC_CHECK(); STR_FREE(); /* next */ pParent = pCur; parentHardDisk = curHardDisk; } } else if (hddType == HardDiskStorageType_ISCSIHardDisk) { ComPtr iSCSIDisk = hardDisk; rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL1); RC_CHECK(); rc = CFGMR3InsertString(pLunL1, "Driver", "iSCSI"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); /* Set up the iSCSI initiator driver configuration. */ hrc = iSCSIDisk->COMGETTER(Target)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCfg, "TargetName", psz); RC_CHECK(); STR_FREE(); // @todo currently there is no Initiator name config. rc = CFGMR3InsertString(pCfg, "InitiatorName", "iqn.2006-02.de.innotek.initiator"); RC_CHECK(); ULONG64 lun; hrc = iSCSIDisk->COMGETTER(Lun)(&lun); H(); rc = CFGMR3InsertInteger(pCfg, "LUN", lun); RC_CHECK(); hrc = iSCSIDisk->COMGETTER(Server)(&str); H(); STR_CONV(); USHORT port; hrc = iSCSIDisk->COMGETTER(Port)(&port); H(); if (port != 0) { char *pszTN; RTStrAPrintf(&pszTN, "%s:%u", psz, port); rc = CFGMR3InsertString(pCfg, "TargetAddress", pszTN); RC_CHECK(); RTStrFree(pszTN); } else { rc = CFGMR3InsertString(pCfg, "TargetAddress", psz); RC_CHECK(); } STR_FREE(); hrc = iSCSIDisk->COMGETTER(UserName)(&str); H(); if (str) { STR_CONV(); rc = CFGMR3InsertString(pCfg, "InitiatorUsername", psz); RC_CHECK(); STR_FREE(); } hrc = iSCSIDisk->COMGETTER(Password)(&str); H(); if (str) { STR_CONV(); rc = CFGMR3InsertString(pCfg, "InitiatorSecret", psz); RC_CHECK(); STR_FREE(); } // @todo currently there is no target username config. //rc = CFGMR3InsertString(pCfg, "TargetUsername", ""); RC_CHECK(); // @todo currently there is no target password config. //rc = CFGMR3InsertString(pCfg, "TargetSecret", ""); RC_CHECK(); /* The iSCSI initiator needs an attached iSCSI transport driver. */ PCFGMNODE pLunL2 = NULL; /* /Devices/Dev/0/LUN#0/AttachedDriver/AttachedDriver */ rc = CFGMR3InsertNode(pLunL1, "AttachedDriver", &pLunL2); RC_CHECK(); rc = CFGMR3InsertString(pLunL2, "Driver", "iSCSITCP"); RC_CHECK(); /* Currently the transport driver has no config options. */ } else AssertFailed(); } H(); ComPtr dvdDrive; hrc = pMachine->COMGETTER(DVDDrive)(dvdDrive.asOutParam()); H(); if (dvdDrive) { // ASSUME: DVD drive is always attached to LUN#2 (i.e. secondary IDE master) rc = CFGMR3InsertNode(pInst, "LUN#2", &pLunL0); RC_CHECK(); ComPtr hostDvdDrive; hrc = dvdDrive->GetHostDrive(hostDvdDrive.asOutParam()); H(); if (hostDvdDrive) { pConsole->meDVDState = DriveState_HostDriveCaptured; rc = CFGMR3InsertString(pLunL0, "Driver", "HostDVD"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); hrc = hostDvdDrive->COMGETTER(Name)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCfg, "Path", psz); RC_CHECK(); STR_FREE(); BOOL fPassthrough; hrc = dvdDrive->COMGETTER(Passthrough)(&fPassthrough); H(); rc = CFGMR3InsertInteger(pCfg, "Passthrough", !!fPassthrough); RC_CHECK(); } else { pConsole->meDVDState = DriveState_NotMounted; rc = CFGMR3InsertString(pLunL0, "Driver", "Block"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "Type", "DVD"); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "Mountable", 1); RC_CHECK(); ComPtr dvdImage; hrc = dvdDrive->GetImage(dvdImage.asOutParam()); H(); if (dvdImage) { pConsole->meDVDState = DriveState_ImageMounted; rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL1); RC_CHECK(); rc = CFGMR3InsertString(pLunL1, "Driver", "MediaISO"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); hrc = dvdImage->COMGETTER(FilePath)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCfg, "Path", psz); RC_CHECK(); STR_FREE(); } } } /* * Network adapters */ rc = CFGMR3InsertNode(pDevices, "pcnet", &pDev); RC_CHECK(); //rc = CFGMR3InsertNode(pDevices, "ne2000", &pDev); RC_CHECK(); for (ULONG ulInstance = 0; ulInstance < SchemaDefs::NetworkAdapterCount; ulInstance++) { ComPtr networkAdapter; hrc = pMachine->GetNetworkAdapter(ulInstance, networkAdapter.asOutParam()); H(); BOOL fEnabled = FALSE; hrc = networkAdapter->COMGETTER(Enabled)(&fEnabled); H(); if (!fEnabled) continue; char szInstance[4]; Assert(ulInstance <= 999); RTStrPrintf(szInstance, sizeof(szInstance), "%lu", ulInstance); rc = CFGMR3InsertNode(pDev, szInstance, &pInst); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); /* the first network card gets the PCI ID 3, the followings starting from 8 */ rc = CFGMR3InsertInteger(pInst, "PCIDeviceNo", !ulInstance ? 3 : ulInstance - 1 + 8); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIFunctionNo", 0); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); /* * The virtual hardware type. */ NetworkAdapterType_T adapterType; hrc = networkAdapter->COMGETTER(AdapterType)(&adapterType); H(); switch (adapterType) { case NetworkAdapterType_NetworkAdapterAm79C970A: rc = CFGMR3InsertInteger(pCfg, "Am79C973", 0); RC_CHECK(); break; case NetworkAdapterType_NetworkAdapterAm79C973: rc = CFGMR3InsertInteger(pCfg, "Am79C973", 1); RC_CHECK(); break; default: AssertMsgFailed(("Invalid network adapter type '%d' for slot '%d'", adapterType, ulInstance)); return VERR_GENERAL_FAILURE; } /* * Get the MAC address and convert it to binary representation */ Bstr macAddr; hrc = networkAdapter->COMGETTER(MACAddress)(macAddr.asOutParam()); H(); Assert(macAddr); Utf8Str macAddrUtf8 = macAddr; char *macStr = (char*)macAddrUtf8.raw(); Assert(strlen(macStr) == 12); PDMMAC Mac; memset(&Mac, 0, sizeof(Mac)); char *pMac = (char*)&Mac; for (uint32_t i = 0; i < 6; i++) { char c1 = *macStr++ - '0'; if (c1 > 9) c1 -= 7; char c2 = *macStr++ - '0'; if (c2 > 9) c2 -= 7; *pMac++ = ((c1 & 0x0f) << 4) | (c2 & 0x0f); } rc = CFGMR3InsertBytes(pCfg, "MAC", &Mac, sizeof(Mac)); RC_CHECK(); /* * Check if the cable is supposed to be unplugged */ BOOL fCableConnected; hrc = networkAdapter->COMGETTER(CableConnected)(&fCableConnected); H(); rc = CFGMR3InsertInteger(pCfg, "CableConnected", fCableConnected ? 1 : 0); RC_CHECK(); /* * Attach the status driver. */ rc = CFGMR3InsertNode(pInst, "LUN#999", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "MainStatus"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "papLeds", (uintptr_t)&pConsole->mapNetworkLeds[ulInstance]); RC_CHECK(); /* * Enable the packet sniffer if requested. */ BOOL fSniffer; hrc = networkAdapter->COMGETTER(TraceEnabled)(&fSniffer); H(); if (fSniffer) { /* insert the sniffer filter driver. */ rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "NetSniffer"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); hrc = networkAdapter->COMGETTER(TraceFile)(&str); H(); if (str) /* check convention for indicating default file. */ { STR_CONV(); rc = CFGMR3InsertString(pCfg, "File", psz); RC_CHECK(); STR_FREE(); } } NetworkAttachmentType_T networkAttachment; hrc = networkAdapter->COMGETTER(AttachmentType)(&networkAttachment); H(); switch (networkAttachment) { case NetworkAttachmentType_NoNetworkAttachment: break; case NetworkAttachmentType_NATNetworkAttachment: { if (fSniffer) { rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL0); RC_CHECK(); } else { rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); } rc = CFGMR3InsertString(pLunL0, "Driver", "NAT"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); /* (Port forwarding goes here.) */ break; } case NetworkAttachmentType_HostInterfaceNetworkAttachment: { /* * Perform the attachment if required (don't return on error!) */ hrc = pConsole->attachToHostInterface(networkAdapter); if (SUCCEEDED(hrc)) { #ifdef VBOX_WITH_UNIXY_TAP_NETWORKING Assert (pConsole->maTapFD[ulInstance] >= 0); if (pConsole->maTapFD[ulInstance] >= 0) { if (fSniffer) { rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL0); RC_CHECK(); } else { rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); } rc = CFGMR3InsertString(pLunL0, "Driver", "HostInterface"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "FileHandle", pConsole->maTapFD[ulInstance]); RC_CHECK(); } #elif defined(__WIN__) if (fSniffer) { rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL0); RC_CHECK(); } else { rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); } Bstr hostInterfaceName; hrc = networkAdapter->COMGETTER(HostInterface)(hostInterfaceName.asOutParam()); H(); ComPtr coll; hrc = host->COMGETTER(NetworkInterfaces)(coll.asOutParam()); H(); ComPtr hostInterface; rc = coll->FindByName(hostInterfaceName, hostInterface.asOutParam()); if (!SUCCEEDED(rc)) { AssertMsgFailed(("Cannot get GUID for host interface '%ls'\n", hostInterfaceName)); hrc = networkAdapter->Detach(); H(); } else { rc = CFGMR3InsertString(pLunL0, "Driver", "HostInterface"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "HostInterfaceName", Utf8Str(hostInterfaceName)); RC_CHECK(); Guid hostIFGuid; hrc = hostInterface->COMGETTER(Id)(hostIFGuid.asOutParam()); H(); char szDriverGUID[256] = {0}; /* add curly brackets */ szDriverGUID[0] = '{'; strcpy(szDriverGUID + 1, hostIFGuid.toString().raw()); strcat(szDriverGUID, "}"); rc = CFGMR3InsertBytes(pCfg, "GUID", szDriverGUID, sizeof(szDriverGUID)); RC_CHECK(); } #else # error "Port me" #endif } else { switch (hrc) { #ifdef __LINUX__ case VERR_ACCESS_DENIED: return VMSetError(pVM, VERR_HOSTIF_INIT_FAILED, RT_SRC_POS, N_( "Failed to open '/dev/net/tun' for read/write access. Please check the " "permissions of that node. Either do 'chmod 0666 /dev/net/tun' or " "change the group of that node and get member of that group. Make " "sure that these changes are permanently in particular if you are " "using udev")); #endif /* __LINUX__ */ default: AssertMsgFailed(("Could not attach to host interface! Bad!\n")); return VMSetError(pVM, VERR_HOSTIF_INIT_FAILED, RT_SRC_POS, N_( "Failed to initialize Host Interface Networking")); } } break; } case NetworkAttachmentType_InternalNetworkAttachment: { hrc = networkAdapter->COMGETTER(InternalNetwork)(&str); H(); STR_CONV(); if (psz && *psz) { if (fSniffer) { rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL0); RC_CHECK(); } else { rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); } rc = CFGMR3InsertString(pLunL0, "Driver", "IntNet"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "Network", psz); RC_CHECK(); } STR_FREE(); break; } default: AssertMsgFailed(("should not get here!\n")); break; } } /* * VMM Device */ rc = CFGMR3InsertNode(pDevices, "VMMDev", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIDeviceNo", 4); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIFunctionNo", 0); RC_CHECK(); /* the VMM device's Main driver */ rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "MainVMMDev"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); VMMDev *pVMMDev = pConsole->mVMMDev; rc = CFGMR3InsertInteger(pCfg, "Object", (uintptr_t)pVMMDev); RC_CHECK(); /* * Audio Sniffer Device */ rc = CFGMR3InsertNode(pDevices, "AudioSniffer", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); /* the Audio Sniffer device's Main driver */ rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "MainAudioSniffer"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); AudioSniffer *pAudioSniffer = pConsole->mAudioSniffer; rc = CFGMR3InsertInteger(pCfg, "Object", (uintptr_t)pAudioSniffer); RC_CHECK(); /* * AC'97 ICH audio */ ComPtr audioAdapter; hrc = pMachine->COMGETTER(AudioAdapter)(audioAdapter.asOutParam()); H(); BOOL enabled = FALSE; if (audioAdapter) { hrc = audioAdapter->COMGETTER(Enabled)(&enabled); H(); } if (enabled) { rc = CFGMR3InsertNode(pDevices, "ichac97", &pDev); /* ichac97 */ rc = CFGMR3InsertNode(pDev, "0", &pInst); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIDeviceNo", 5); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIFunctionNo", 0); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); /* the Audio driver */ rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "AUDIO"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); AudioDriverType_T audioDriver; hrc = audioAdapter->COMGETTER(AudioDriver)(&audioDriver); H(); switch (audioDriver) { case AudioDriverType_NullAudioDriver: { rc = CFGMR3InsertString(pCfg, "AudioDriver", "null"); RC_CHECK(); break; } #ifdef __WIN__ case AudioDriverType_WINMMAudioDriver: { rc = CFGMR3InsertString(pCfg, "AudioDriver", "winmm"); RC_CHECK(); break; } case AudioDriverType_DSOUNDAudioDriver: { rc = CFGMR3InsertString(pCfg, "AudioDriver", "dsound"); RC_CHECK(); break; } #endif /* !__LINUX__ */ #ifdef __LINUX__ case AudioDriverType_OSSAudioDriver: { rc = CFGMR3InsertString(pCfg, "AudioDriver", "oss"); RC_CHECK(); break; } #ifdef VBOX_WITH_ALSA case AudioDriverType_ALSAAudioDriver: { rc = CFGMR3InsertString(pCfg, "AudioDriver", "alsa"); RC_CHECK(); break; } #endif #endif /* __LINUX__ */ } } /* * The USB Controller. */ ComPtr USBCtlPtr; hrc = pMachine->COMGETTER(USBController)(USBCtlPtr.asOutParam()); if (USBCtlPtr) { BOOL fEnabled; hrc = USBCtlPtr->COMGETTER(Enabled)(&fEnabled); H(); if (fEnabled) { rc = CFGMR3InsertNode(pDevices, "usb-ohci", &pDev); RC_CHECK(); rc = CFGMR3InsertNode(pDev, "0", &pInst); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "Trusted", 1); /* boolean */ RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIDeviceNo", 6); RC_CHECK(); rc = CFGMR3InsertInteger(pInst, "PCIFunctionNo", 0); RC_CHECK(); rc = CFGMR3InsertNode(pInst, "LUN#0", &pLunL0); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "VUSBRootHub"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); } } /* * Clipboard */ { ClipboardMode_T mode = ClipboardMode_ClipDisabled; hrc = pMachine->COMGETTER(ClipboardMode) (&mode); H(); if (mode != ClipboardMode_ClipDisabled) { /* Load the service */ rc = pConsole->mVMMDev->hgcmLoadService ("VBoxSharedClipboard", "VBoxSharedClipboard"); if (VBOX_FAILURE (rc)) { LogRel(("VBoxSharedClipboard is not available. rc = %Vrc\n", rc)); /* That is not a fatal failure. */ rc = VINF_SUCCESS; } else { /* Setup the service. */ VBOXHGCMSVCPARM parm; parm.type = VBOX_HGCM_SVC_PARM_32BIT; switch (mode) { default: case ClipboardMode_ClipDisabled: { LogRel(("VBoxSharedClipboard mode: Off\n")); parm.u.uint32 = VBOX_SHARED_CLIPBOARD_MODE_OFF; break; } case ClipboardMode_ClipGuestToHost: { LogRel(("VBoxSharedClipboard mode: Guest to Host\n")); parm.u.uint32 = VBOX_SHARED_CLIPBOARD_MODE_GUEST_TO_HOST; break; } case ClipboardMode_ClipHostToGuest: { LogRel(("VBoxSharedClipboard mode: Host to Guest\n")); parm.u.uint32 = VBOX_SHARED_CLIPBOARD_MODE_HOST_TO_GUEST; break; } case ClipboardMode_ClipBidirectional: { LogRel(("VBoxSharedClipboard mode: Bidirectional\n")); parm.u.uint32 = VBOX_SHARED_CLIPBOARD_MODE_BIDIRECTIONAL; break; } } pConsole->mVMMDev->hgcmHostCall ("VBoxSharedClipboard", VBOX_SHARED_CLIPBOARD_HOST_FN_SET_MODE, 1, &parm); Log(("Set VBoxSharedClipboard mode\n")); } } } /* * CFGM overlay handling. * * Here we check the extra data entries for CFGM values * and create the nodes and insert the values on the fly. Existing * values will be removed and reinserted. If a value is a valid number, * it will be inserted as a number, otherwise as a string. * * We first perform a run on global extra data, then on the machine * extra data to support global settings with local overrides. * */ Bstr strExtraDataKey; bool fGlobalExtraData = true; for (;;) { Bstr strNextExtraDataKey; Bstr strExtraDataValue; /* get the next key */ if (fGlobalExtraData) hrc = virtualBox->GetNextExtraDataKey(strExtraDataKey, strNextExtraDataKey.asOutParam(), strExtraDataValue.asOutParam()); else hrc = pMachine->GetNextExtraDataKey(strExtraDataKey, strNextExtraDataKey.asOutParam(), strExtraDataValue.asOutParam()); /* stop if for some reason there's nothing more to request */ if (FAILED(hrc) || !strNextExtraDataKey) { /* if we're out of global keys, continue with machine, otherwise we're done */ if (fGlobalExtraData) { fGlobalExtraData = false; strExtraDataKey.setNull(); continue; } break; } strExtraDataKey = strNextExtraDataKey; Utf8Str strExtraDataKeyUtf8 = Utf8Str(strExtraDataKey); /* we only care about keys starting with "VBoxInternal/" */ if (strncmp(strExtraDataKeyUtf8.raw(), "VBoxInternal/", 13) != 0) continue; char *pszExtraDataKey = (char*)strExtraDataKeyUtf8.raw() + 13; /* the key will be in the format "Node1/Node2/Value" or simply "Value". */ PCFGMNODE pNode; char *pszCFGMValueName = strrchr(pszExtraDataKey, '/'); if (pszCFGMValueName) { /* terminate the node and advance to the value */ *pszCFGMValueName = '\0'; pszCFGMValueName++; /* does the node already exist? */ pNode = CFGMR3GetChild(pRoot, pszExtraDataKey); if (pNode) { /* the value might already exist, remove it to be safe */ CFGMR3RemoveValue(pNode, pszCFGMValueName); } else { /* create the node */ rc = CFGMR3InsertNode(pRoot, pszExtraDataKey, &pNode); AssertMsgRC(rc, ("failed to insert node '%s'\n", pszExtraDataKey)); if (VBOX_FAILURE(rc) || !pNode) continue; } } else { pNode = pRoot; pszCFGMValueName = pszExtraDataKey; pszExtraDataKey--; /* the value might already exist, remove it to be safe */ CFGMR3RemoveValue(pNode, pszCFGMValueName); } /* now let's have a look at the value */ Utf8Str strCFGMValueUtf8 = Utf8Str(strExtraDataValue); const char *pszCFGMValue = strCFGMValueUtf8.raw(); /* empty value means remove value which we've already done */ if (pszCFGMValue && *pszCFGMValue) { /* if it's a valid number, we'll insert it as such, otherwise string */ uint64_t u64Value; if (RTStrToUInt64Ex(pszCFGMValue, NULL, 0, &u64Value) == VINF_SUCCESS) { rc = CFGMR3InsertInteger(pNode, pszCFGMValueName, u64Value); } else { rc = CFGMR3InsertString(pNode, pszCFGMValueName, pszCFGMValue); } AssertMsgRC(rc, ("failed to insert CFGM value '%s' to key '%s'\n", pszCFGMValue, pszExtraDataKey)); } } #undef H #undef RC_CHECK #undef STR_FREE #undef STR_CONV /* Register VM state change handler */ int rc2 = VMR3AtStateRegister (pVM, Console::vmstateChangeCallback, pConsole); AssertRC (rc2); if (VBOX_SUCCESS (rc)) rc = rc2; /* Register VM runtime error handler */ rc2 = VMR3AtRuntimeErrorRegister (pVM, Console::setVMRuntimeErrorCallback, pConsole); AssertRC (rc2); if (VBOX_SUCCESS (rc)) rc = rc2; /* Save the VM pointer in the machine object */ pConsole->mpVM = pVM; LogFlowFunc (("vrc = %Vrc\n", rc)); LogFlowFuncLeave(); return rc; } /** * Helper function to handle host interface device creation and attachment. * * @param networkAdapter the network adapter which attachment should be reset * @return COM status code * * @note The caller must lock this object for writing. */ HRESULT Console::attachToHostInterface(INetworkAdapter *networkAdapter) { /* sanity check */ AssertReturn (isLockedOnCurrentThread(), E_FAIL); #ifdef DEBUG /* paranoia */ NetworkAttachmentType_T attachment; networkAdapter->COMGETTER(AttachmentType)(&attachment); Assert(attachment == NetworkAttachmentType_HostInterfaceNetworkAttachment); #endif /* DEBUG */ HRESULT rc = S_OK; #ifdef VBOX_WITH_UNIXY_TAP_NETWORKING ULONG slot = 0; rc = networkAdapter->COMGETTER(Slot)(&slot); AssertComRC(rc); /* * Try get the FD. */ LONG ltapFD; rc = networkAdapter->COMGETTER(TAPFileDescriptor)(<apFD); if (SUCCEEDED(rc)) maTapFD[slot] = (RTFILE)ltapFD; else maTapFD[slot] = NIL_RTFILE; /* * Are we supposed to use an existing TAP interface? */ if (maTapFD[slot] != NIL_RTFILE) { /* nothing to do */ Assert(ltapFD >= 0); Assert((LONG)maTapFD[slot] == ltapFD); rc = S_OK; } else #endif /* VBOX_WITH_UNIXY_TAP_NETWORKING */ { /* * Allocate a host interface device */ #ifdef __WIN__ /* nothing to do */ int rcVBox = VINF_SUCCESS; #elif defined(__LINUX__) int rcVBox = RTFileOpen(&maTapFD[slot], "/dev/net/tun", RTFILE_O_READWRITE | RTFILE_O_OPEN | RTFILE_O_DENY_NONE | RTFILE_O_INHERIT); if (VBOX_SUCCESS(rcVBox)) { /* * Set/obtain the tap interface. */ struct ifreq IfReq; memset(&IfReq, 0, sizeof(IfReq)); Bstr tapDeviceName; rc = networkAdapter->COMGETTER(HostInterface)(tapDeviceName.asOutParam()); if (FAILED(rc) || tapDeviceName.isEmpty()) strcpy(IfReq.ifr_name, "tap%d"); else { Utf8Str str(tapDeviceName); if (str.length() <= sizeof(IfReq.ifr_name)) strcpy(IfReq.ifr_name, str.raw()); else memcpy(IfReq.ifr_name, str.raw(), sizeof(IfReq.ifr_name) - 1); /** @todo bitch about names which are too long... */ } IfReq.ifr_flags = IFF_TAP | IFF_NO_PI; rcVBox = ioctl(maTapFD[slot], TUNSETIFF, &IfReq); if (!rcVBox) { /* * Make it pollable. */ if (fcntl(maTapFD[slot], F_SETFL, O_NONBLOCK) != -1) { tapDeviceName = IfReq.ifr_name; if (tapDeviceName) { Log(("attachToHostInterface: %RTfile %ls\n", maTapFD[slot], tapDeviceName.raw())); /* * Here is the right place to communicate the TAP file descriptor and * the host interface name to the server if/when it becomes really * necessary. */ maTAPDeviceName[slot] = tapDeviceName; rcVBox = VINF_SUCCESS; rc = S_OK; } else rcVBox = VERR_NO_MEMORY; } else { AssertMsgFailed(("Configuration error: Failed to configure /dev/net/tun non blocking. errno=%d\n", errno)); rcVBox = VERR_HOSTIF_BLOCKING; rc = setError(E_FAIL, "Failed to set /dev/net/tun to non blocking. errno=%d\n", errno); } } else { AssertMsgFailed(("Configuration error: Failed to configure /dev/net/tun. errno=%d\n", errno)); rcVBox = VERR_HOSTIF_IOCTL; rc = setError(E_FAIL, "Failed to configure /dev/net/tun. errno = %d\n", errno); } } else { AssertMsgFailed(("Configuration error: Failed to open /dev/net/tun rc=%Vrc\n", rcVBox)); switch (rcVBox) { case VERR_ACCESS_DENIED: /* will be handled by our caller */ LogRel(("HERE\n")); rc = rcVBox; break; default: rc = setError(E_FAIL, "Failed to open /dev/net/tun rc = %Vrc\n", rcVBox); break; } } #elif defined(__DARWIN__) /** @todo Implement tap networking for Darwin. */ int rcVBox = VERR_NOT_IMPLEMENTED; #elif defined(VBOX_WITH_UNIXY_TAP_NETWORKING) # error "PORTME: Implement OS specific TAP interface open/creation." #else # error "Unknown host OS" #endif /* in case of failure, cleanup. */ if (VBOX_FAILURE(rcVBox) && SUCCEEDED(rc)) { rc = setError(E_FAIL, tr ("General failure attaching to host interface")); } } #ifdef VBOX_WITH_UNIXY_TAP_NETWORKING if (SUCCEEDED(rc)) { /* * Call the initialization program. * * The initialization program is passed the device name as the first param. * The second parameter is the decimal value of the file handle of the device * which it inherits. */ Bstr tapSetupApplication; networkAdapter->COMGETTER(TAPSetupApplication)(tapSetupApplication.asOutParam()); if (tapSetupApplication) { /* * Create the argument list. */ const char *apszArgs[4]; /* 0. The program name. */ Utf8Str tapSetupApp(tapSetupApplication); apszArgs[0] = tapSetupApp.raw(); /* 1. The file descriptor. */ char szFD[32]; RTStrPrintf(szFD, sizeof(szFD), "%RTfile", maTapFD[slot]); apszArgs[1] = szFD; /* 2. The device name (optional). */ apszArgs[2] = maTAPDeviceName[slot].isEmpty() ? NULL : maTAPDeviceName[slot].raw(); /* 3. The end. */ apszArgs[3] = NULL; /* * Create the process and wait for it to complete. */ RTPROCESS Process; int rcVBox = RTProcCreate(apszArgs[0], &apszArgs[0], NULL, 0, &Process); if (VBOX_SUCCESS(rcVBox)) { /* wait for the process to exit */ RTPROCSTATUS ProcStatus; rcVBox = RTProcWait(Process, RTPROCWAIT_FLAGS_BLOCK, &ProcStatus); AssertRC(rcVBox); if (VBOX_SUCCESS(rcVBox)) { if ( ProcStatus.enmReason == RTPROCEXITREASON_NORMAL && ProcStatus.iStatus == 0) rcVBox = VINF_SUCCESS; else rcVBox = VMSetError(mpVM, VERR_HOSTIF_INIT_FAILED, RT_SRC_POS, N_("Failed to initialize Host Interface Networking")); } } else { AssertMsgFailed(("Configuration error: Failed to start init program \"%s\", rc=%Vra\n", tapSetupApp.raw(), rcVBox)); rc = setError(E_FAIL, "Failed to start init program \"%s\", rc = %Vra\n", tapSetupApp.raw(), rcVBox); } /* in case of failure, cleanup. */ if (VBOX_FAILURE(rcVBox) && SUCCEEDED(rc)) { rc = setError(E_FAIL, tr ("General failure configuring Host Interface Networking")); } } } #endif /* VBOX_WITH_UNIXY_TAP_NETWORKING */ return rc; } /** * Helper function to handle detachment from a host interface * * @param networkAdapter the network adapter which attachment should be reset * @return COM status code * * @note The caller must lock this object for writing. */ HRESULT Console::detachFromHostInterface(INetworkAdapter *networkAdapter) { /* sanity check */ AssertReturn (isLockedOnCurrentThread(), E_FAIL); HRESULT rc = S_OK; #ifdef DEBUG /* paranoia */ NetworkAttachmentType_T attachment; networkAdapter->COMGETTER(AttachmentType)(&attachment); Assert(attachment == NetworkAttachmentType_HostInterfaceNetworkAttachment); #endif /* DEBUG */ #ifdef VBOX_WITH_UNIXY_TAP_NETWORKING ULONG slot = 0; rc = networkAdapter->COMGETTER(Slot)(&slot); AssertComRC(rc); /* is there an open TAP device? */ if (maTapFD[slot] != NIL_RTFILE) { /* * Execute term command and close the file handle. */ Bstr tapTerminateApplication; networkAdapter->COMGETTER(TAPTerminateApplication)(tapTerminateApplication.asOutParam()); if (tapTerminateApplication) { /* * Create the argument list */ const char *apszArgs[4]; /* 0. The program name. */ Utf8Str tapTermAppUtf8(tapTerminateApplication); apszArgs[0] = tapTermAppUtf8.raw(); /* 1. The file descriptor. */ char szFD[32]; RTStrPrintf(szFD, sizeof(szFD), "%RTfile", maTapFD[slot]); apszArgs[1] = szFD; /* 2. Device name (optional). */ apszArgs[2] = maTAPDeviceName[slot].isEmpty() ? NULL : maTAPDeviceName[slot].raw(); /* 3. The end. */ apszArgs[3] = NULL; /* * Create the process and wait for it to complete. */ RTPROCESS Process; int rcVBox = RTProcCreate(apszArgs[0], &apszArgs[0], NULL, 0, &Process); if (VBOX_SUCCESS(rcVBox)) { /* wait for the process to exit */ RTPROCSTATUS ProcStatus; rcVBox = RTProcWait(Process, RTPROCWAIT_FLAGS_BLOCK, &ProcStatus); AssertRC(rcVBox); /* ignore return code? */ } else AssertMsgFailed(("Configuration error: Failed to start terminate program \"%s\", rc=%Vra\n", apszArgs[0], rcVBox)); /** @todo last error candidate. */ if (VBOX_FAILURE(rcVBox)) rc = E_FAIL; } /* * Now we can close the file handle. */ int rcVBox = RTFileClose(maTapFD[slot]); AssertRC(rcVBox); /* the TAP device name and handle are no longer valid */ maTapFD[slot] = NIL_RTFILE; maTAPDeviceName[slot] = ""; } #endif return rc; } /** * Called at power down to terminate host interface networking. * * @note The caller must lock this object for writing. */ HRESULT Console::powerDownHostInterfaces() { LogFlowThisFunc (("\n")); /* sanity check */ AssertReturn (isLockedOnCurrentThread(), E_FAIL); /* * host interface termination handling */ HRESULT rc; for (ULONG slot = 0; slot < SchemaDefs::NetworkAdapterCount; slot ++) { ComPtr networkAdapter; rc = mMachine->GetNetworkAdapter(slot, networkAdapter.asOutParam()); CheckComRCBreakRC (rc); BOOL enabled = FALSE; networkAdapter->COMGETTER(Enabled) (&enabled); if (!enabled) continue; NetworkAttachmentType_T attachment; networkAdapter->COMGETTER(AttachmentType)(&attachment); if (attachment == NetworkAttachmentType_HostInterfaceNetworkAttachment) { HRESULT rc2 = detachFromHostInterface(networkAdapter); if (FAILED(rc2) && SUCCEEDED(rc)) rc = rc2; } } return rc; } /** * Process callback handler for VMR3Load and VMR3Save. * * @param pVM The VM handle. * @param uPercent Completetion precentage (0-100). * @param pvUser Pointer to the VMProgressTask structure. * @return VINF_SUCCESS. */ /*static*/ DECLCALLBACK (int) Console::stateProgressCallback (PVM pVM, unsigned uPercent, void *pvUser) { VMProgressTask *task = static_cast (pvUser); AssertReturn (task, VERR_INVALID_PARAMETER); /* update the progress object */ if (task->mProgress) task->mProgress->notifyProgress (uPercent); return VINF_SUCCESS; } /** * VM error callback function. Called by the various VM components. * * @param pVM The VM handle. Can be NULL if an error occurred before * successfully creating a VM. * @param pvUser Pointer to the VMProgressTask structure. * @param rc VBox status code. * @param pszFormat The error message. * @thread EMT. */ /* static */ DECLCALLBACK (void) Console::setVMErrorCallback (PVM pVM, void *pvUser, int rc, RT_SRC_POS_DECL, const char *pszFormat, va_list args) { VMProgressTask *task = static_cast (pvUser); AssertReturnVoid (task); /* we ignore RT_SRC_POS_DECL arguments to avoid confusion of end-users */ HRESULT hrc = setError (E_FAIL, tr ("%N.\n" "VBox status code: %d (%Vrc)"), tr (pszFormat), &args, rc, rc); task->mProgress->notifyComplete (hrc); } /** * VM runtime error callback function. * See VMSetRuntimeError for the detailed description of parameters. * * @param pVM The VM handle. * @param pvUser The user argument. * @param fFatal Whether it is a fatal error or not. * @param pszErrorID Error ID string. * @param pszFormat Error message format string. * @param args Error message arguments. * @thread EMT. */ /* static */ DECLCALLBACK(void) Console::setVMRuntimeErrorCallback (PVM pVM, void *pvUser, bool fFatal, const char *pszErrorID, const char *pszFormat, va_list args) { LogFlowFuncEnter(); Console *that = static_cast (pvUser); AssertReturnVoid (that); Utf8Str message = Utf8StrFmt (pszFormat, args); LogRel (("Console: VM runtime error: fatal=%RTbool, " "errorID=%s message=\"%s\"\n", fFatal, pszErrorID, message.raw())); that->onRuntimeError (BOOL (fFatal), Bstr (pszErrorID), Bstr (message)); LogFlowFuncLeave(); } /** * Captures and attaches USB devices to a newly created VM. * * @param pVM The VM handle. * * @note The caller must lock this object for writing. */ HRESULT Console::captureUSBDevices (PVM pVM) { LogFlowThisFunc (("\n")); /* sanity check */ ComAssertRet (isLockedOnCurrentThread(), E_FAIL); /* * If the machine has an USB controller, capture devices and attach * them to it. */ PPDMIBASE pBase; int vrc = PDMR3QueryLun (pVM, "usb-ohci", 0, 0, &pBase); if (VBOX_SUCCESS (vrc)) { PVUSBIRHCONFIG pRhConfig = (PVUSBIRHCONFIG) pBase-> pfnQueryInterface (pBase, PDMINTERFACE_VUSB_RH_CONFIG); ComAssertRet (pRhConfig, E_FAIL); /* * Get the list of USB devices that should be captured and attached to * the newly created machine. */ ComPtr coll; HRESULT hrc = mControl->AutoCaptureUSBDevices (coll.asOutParam()); ComAssertComRCRetRC (hrc); /* * Enumerate the devices and attach them. * Failing to attach an device is currently ignored and the device * released. */ ComPtr en; hrc = coll->Enumerate (en.asOutParam()); ComAssertComRCRetRC (hrc); BOOL hasMore = FALSE; while (SUCCEEDED (en->HasMore (&hasMore)) && hasMore) { ComPtr hostDevice; hrc = en->GetNext (hostDevice.asOutParam()); ComAssertComRCRetRC (hrc); ComAssertRet (!hostDevice.isNull(), E_FAIL); hrc = attachUSBDevice (hostDevice, true /* aManual */, pRhConfig); /// @todo (r=dmik) warning reporting subsystem } } else if ( vrc == VERR_PDM_DEVICE_NOT_FOUND || vrc == VERR_PDM_DEVICE_INSTANCE_NOT_FOUND) vrc = VINF_SUCCESS; else AssertRC (vrc); return VBOX_SUCCESS (vrc) ? S_OK : E_FAIL; } /** * Releases all USB device which is attached to the VM for the * purpose of clean up and such like. * * @note The caller must lock this object for writing. */ void Console::releaseAllUSBDevices (void) { LogFlowThisFunc (("\n")); /* sanity check */ AssertReturnVoid (isLockedOnCurrentThread()); mControl->ReleaseAllUSBDevices(); mUSBDevices.clear(); } /** * @note Locks this object for writing. */ #ifdef VRDP_MC void Console::processRemoteUSBDevices (uint32_t u32ClientId, VRDPUSBDEVICEDESC *pDevList, uint32_t cbDevList) #else void Console::processRemoteUSBDevices (VRDPUSBDEVICEDESC *pDevList, uint32_t cbDevList) #endif /* VRDP_MC */ { LogFlowThisFuncEnter(); #ifdef VRDP_MC LogFlowThisFunc (("u32ClientId = %d, pDevList=%p, cbDevList = %d\n", u32ClientId, pDevList, cbDevList)); #else LogFlowThisFunc (("pDevList=%p, cbDevList = %d\n", pDevList, cbDevList)); #endif /* VRDP_MC */ AutoCaller autoCaller (this); if (!autoCaller.isOk()) { /* Console has been already uninitialized, deny request */ AssertMsgFailed (("Temporary assertion to prove that it happens, " "please report to dmik\n")); LogFlowThisFunc (("Console is already uninitialized\n")); LogFlowThisFuncLeave(); return; } AutoLock alock (this); /* * Mark all existing remote USB devices as dirty. */ RemoteUSBDeviceList::iterator it = mRemoteUSBDevices.begin(); while (it != mRemoteUSBDevices.end()) { (*it)->dirty (true); ++ it; } /* * Process the pDevList and add devices those are not already in the mRemoteUSBDevices list. */ /** @todo (sunlover) REMOTE_USB Strict validation of the pDevList. */ VRDPUSBDEVICEDESC *e = pDevList; /* The cbDevList condition must be checked first, because the function can * receive pDevList = NULL and cbDevList = 0 on client disconnect. */ while (cbDevList >= 2 && e->oNext) { LogFlowThisFunc (("vendor %04X, product %04X, name = %s\n", e->idVendor, e->idProduct, e->oProduct? (char *)e + e->oProduct: "")); bool fNewDevice = true; it = mRemoteUSBDevices.begin(); while (it != mRemoteUSBDevices.end()) { #ifdef VRDP_MC if ((*it)->devId () == e->id && (*it)->clientId () == u32ClientId) #else if ((*it)->devId () == e->id) #endif /* VRDP_MC */ { /* The device is already in the list. */ (*it)->dirty (false); fNewDevice = false; break; } ++ it; } if (fNewDevice) { LogRel(("Remote USB: ++++ Vendor %04X. Product %04X. Name = [%s].\n", e->idVendor, e->idProduct, e->oProduct? (char *)e + e->oProduct: "" )); /* Create the device object and add the new device to list. */ ComObjPtr device; device.createObject(); #ifdef VRDP_MC device->init (u32ClientId, e); #else device->init (e); #endif /* VRDP_MC */ mRemoteUSBDevices.push_back (device); /* Check if the device is ok for current USB filters. */ BOOL fMatched = FALSE; HRESULT hrc = mControl->RunUSBDeviceFilters(device, &fMatched); AssertComRC (hrc); LogFlowThisFunc (("USB filters return %d\n", fMatched)); if (fMatched) { hrc = onUSBDeviceAttach(device); /// @todo (r=dmik) warning reporting subsystem if (hrc == S_OK) { LogFlowThisFunc (("Device attached\n")); device->captured (true); } } } if (cbDevList < e->oNext) { LogWarningThisFunc (("cbDevList %d > oNext %d\n", cbDevList, e->oNext)); break; } cbDevList -= e->oNext; e = (VRDPUSBDEVICEDESC *)((uint8_t *)e + e->oNext); } /* * Remove dirty devices, that is those which are not reported by the server anymore. */ for (;;) { ComObjPtr device; RemoteUSBDeviceList::iterator it = mRemoteUSBDevices.begin(); while (it != mRemoteUSBDevices.end()) { if ((*it)->dirty ()) { device = *it; break; } ++ it; } if (!device) { break; } USHORT vendorId = 0; device->COMGETTER(VendorId) (&vendorId); USHORT productId = 0; device->COMGETTER(ProductId) (&productId); Bstr product; device->COMGETTER(Product) (product.asOutParam()); LogRel(("Remote USB: ---- Vendor %04X. Product %04X. Name = [%ls].\n", vendorId, productId, product.raw () )); /* Detach the device from VM. */ if (device->captured ()) { Guid uuid; device->COMGETTER (Id) (uuid.asOutParam()); onUSBDeviceDetach (uuid); } /* And remove it from the list. */ mRemoteUSBDevices.erase (it); } LogFlowThisFuncLeave(); } /** * Thread function which starts the VM (also from saved state) and * track progress. * * @param Thread The thread id. * @param pvUser Pointer to a VMPowerUpTask structure. * @return VINF_SUCCESS (ignored). * * @note Locks the Console object for writing. */ /*static*/ DECLCALLBACK (int) Console::powerUpThread (RTTHREAD Thread, void *pvUser) { LogFlowFuncEnter(); std::auto_ptr task (static_cast (pvUser)); AssertReturn (task.get(), VERR_INVALID_PARAMETER); AssertReturn (!task->mConsole.isNull(), VERR_INVALID_PARAMETER); AssertReturn (!task->mProgress.isNull(), VERR_INVALID_PARAMETER); #if defined(__WIN__) { /* initialize COM */ HRESULT hrc = CoInitializeEx (NULL, COINIT_MULTITHREADED | COINIT_DISABLE_OLE1DDE | COINIT_SPEED_OVER_MEMORY); LogFlowFunc (("CoInitializeEx()=%08X\n", hrc)); } #endif HRESULT hrc = S_OK; int vrc = VINF_SUCCESS; ComObjPtr console = task->mConsole; /* Note: no need to use addCaller() because VMPowerUpTask does that */ AutoLock alock (console); /* sanity */ Assert (console->mpVM == NULL); do { /* * Initialize the release logging facility. In case something * goes wrong, there will be no release logging. Maybe in the future * we can add some logic to use different file names in this case. * Note that the logic must be in sync with Machine::DeleteSettings(). */ Bstr logFolder; hrc = console->mControl->GetLogFolder (logFolder.asOutParam()); CheckComRCBreakRC (hrc); Utf8Str logDir = logFolder; /* make sure the Logs folder exists */ Assert (!logDir.isEmpty()); if (!RTDirExists (logDir)) RTDirCreateFullPath (logDir, 0777); Utf8Str logFile = Utf8StrFmt ("%s%cVBox.log", logDir.raw(), RTPATH_DELIMITER); /* * Age the old log files * Rename .2 to .3, .1 to .2 and the last log file to .1 * Overwrite target files in case they exist; */ for (int i = 2; i >= 0; i--) { Utf8Str oldName; if (i > 0) oldName = Utf8StrFmt ("%s.%d", logFile.raw(), i); else oldName = logFile; Utf8Str newName = Utf8StrFmt ("%s.%d", logFile.raw(), i + 1); RTFileRename(oldName.raw(), newName.raw(), RTFILEMOVE_FLAGS_REPLACE); } PRTLOGGER loggerRelease; static const char * const s_apszGroups[] = VBOX_LOGGROUP_NAMES; RTUINT fFlags = RTLOGFLAGS_PREFIX_TIME_PROG; #ifdef __WIN__ fFlags |= RTLOGFLAGS_USECRLF; #endif /* __WIN__ */ vrc = RTLogCreate(&loggerRelease, fFlags, "all", "VBOX_RELEASE_LOG", ELEMENTS(s_apszGroups), s_apszGroups, RTLOGDEST_FILE, logFile.raw()); if (VBOX_SUCCESS(vrc)) { /* some introductory information */ RTTIMESPEC timeSpec; char nowUct[64]; RTTimeSpecToString(RTTimeNow(&timeSpec), nowUct, sizeof(nowUct)); RTLogRelLogger(loggerRelease, 0, ~0U, "VirtualBox %d.%d.%d (%s %s) release log\n" "Log opened %s\n", VBOX_VERSION_MAJOR, VBOX_VERSION_MINOR, VBOX_VERSION_BUILD, __DATE__, __TIME__, nowUct); /* register this logger as the release logger */ RTLogRelSetDefaultInstance(loggerRelease); } else { hrc = setError (E_FAIL, tr ("Failed to open release log file '%s' (%Vrc)"), logFile.raw(), vrc); break; } #ifdef VBOX_VRDP if (VBOX_SUCCESS (vrc)) { /* Create the VRDP server. In case of headless operation, this will * also create the framebuffer, required at VM creation. */ ConsoleVRDPServer *server = console->consoleVRDPServer(); Assert (server); /// @todo (dmik) // does VRDP server call Console from the other thread? // Not sure, so leave the lock just in case alock.leave(); vrc = server->Launch(); alock.enter(); if (VBOX_FAILURE (vrc)) { Utf8Str errMsg; switch (vrc) { case VERR_NET_ADDRESS_IN_USE: { ULONG port = 0; console->mVRDPServer->COMGETTER(Port) (&port); errMsg = Utf8StrFmt (tr ("VRDP server port %d is already in use"), port); break; } default: errMsg = Utf8StrFmt (tr ("Failed to launch VRDP server (%Vrc)"), vrc); } LogRel (("Failed to launch VRDP server (%Vrc), error message: '%s'\n", vrc, errMsg.raw())); hrc = setError (E_FAIL, errMsg); break; } } #endif /* VBOX_VRDP */ /* * Create the VM */ PVM pVM; /* * leave the lock since EMT will call Console. It's safe because * mMachineState is either Starting or Restoring state here. */ alock.leave(); vrc = VMR3Create (task->mSetVMErrorCallback, task.get(), task->mConfigConstructor, task.get(), &pVM); alock.enter(); #ifdef VBOX_VRDP { /* Enable client connections to the server. */ ConsoleVRDPServer *server = console->consoleVRDPServer(); server->SetCallback (); } #endif /* VBOX_VRDP */ if (VBOX_SUCCESS (vrc)) { do { /* * Register our load/save state file handlers */ vrc = SSMR3RegisterExternal (pVM, sSSMConsoleUnit, 0 /* iInstance */, sSSMConsoleVer, 0 /* cbGuess */, NULL, saveStateFileExec, NULL, NULL, loadStateFileExec, NULL, static_cast (console)); AssertRC (vrc); if (VBOX_FAILURE (vrc)) break; /* * Synchronize debugger settings */ MachineDebugger *machineDebugger = console->getMachineDebugger(); if (machineDebugger) { machineDebugger->flushQueuedSettings(); } if (console->getVMMDev()->getShFlClientId()) { /// @todo (dmik) // does the code below call Console from the other thread? // Not sure, so leave the lock just in case alock.leave(); /* * Shared Folders */ for (std::map >::const_iterator it = task->mSharedFolders.begin(); it != task->mSharedFolders.end(); ++ it) { Bstr name = (*it).first; ComPtr folder = (*it).second; Bstr hostPath; hrc = folder->COMGETTER(HostPath) (hostPath.asOutParam()); CheckComRCBreakRC (hrc); LogFlowFunc (("Adding shared folder '%ls' -> '%ls'\n", name.raw(), hostPath.raw())); ComAssertBreak (!name.isEmpty() && !hostPath.isEmpty(), hrc = E_FAIL); /** @todo should move this into the shared folder class */ VBOXHGCMSVCPARM parms[2]; SHFLSTRING *pFolderName, *pMapName; int cbString; cbString = (hostPath.length() + 1) * sizeof(RTUCS2); pFolderName = (SHFLSTRING *)RTMemAllocZ(sizeof(SHFLSTRING) + cbString); Assert(pFolderName); memcpy(pFolderName->String.ucs2, hostPath.raw(), cbString); pFolderName->u16Size = cbString; pFolderName->u16Length = cbString - sizeof(RTUCS2); parms[0].type = VBOX_HGCM_SVC_PARM_PTR; parms[0].u.pointer.addr = pFolderName; parms[0].u.pointer.size = sizeof(SHFLSTRING) + cbString; cbString = (name.length() + 1) * sizeof(RTUCS2); pMapName = (SHFLSTRING *)RTMemAllocZ(sizeof(SHFLSTRING) + cbString); Assert(pMapName); memcpy(pMapName->String.ucs2, name.raw(), cbString); pMapName->u16Size = cbString; pMapName->u16Length = cbString - sizeof(RTUCS2); parms[1].type = VBOX_HGCM_SVC_PARM_PTR; parms[1].u.pointer.addr = pMapName; parms[1].u.pointer.size = sizeof(SHFLSTRING) + cbString; vrc = console->getVMMDev()->hgcmHostCall("VBoxSharedFolders", SHFL_FN_ADD_MAPPING, 2, &parms[0]); RTMemFree(pFolderName); RTMemFree(pMapName); if (VBOX_FAILURE (vrc)) { hrc = setError (E_FAIL, tr ("Unable to add mapping '%ls' to '%ls' (%Vrc)"), hostPath.raw(), name.raw(), vrc); break; } } /* enter the lock again */ alock.enter(); CheckComRCBreakRC (hrc); } /* * Capture USB devices. */ hrc = console->captureUSBDevices (pVM); CheckComRCBreakRC (hrc); /* leave the lock before a lengthy operation */ alock.leave(); /* Load saved state? */ if (!!task->mSavedStateFile) { LogFlowFunc (("Restoring saved state from '%s'...\n", task->mSavedStateFile.raw())); vrc = VMR3Load (pVM, task->mSavedStateFile, Console::stateProgressCallback, static_cast (task.get())); /* Start/Resume the VM execution */ if (VBOX_SUCCESS (vrc)) { vrc = VMR3Resume (pVM); AssertRC (vrc); } /* Power off in case we failed loading or resuming the VM */ if (VBOX_FAILURE (vrc)) { int vrc2 = VMR3PowerOff (pVM); AssertRC (vrc2); } } else { /* Power on the VM (i.e. start executing) */ vrc = VMR3PowerOn(pVM); AssertRC (vrc); } /* enter the lock again */ alock.enter(); } while (0); /* On failure, destroy the VM */ if (FAILED (hrc) || VBOX_FAILURE (vrc)) { /* preserve the current error info */ ErrorInfo ei; /* * powerDown() will call VMR3Destroy() and do all necessary * cleanup (VRDP, USB devices) */ HRESULT hrc2 = console->powerDown(); AssertComRC (hrc2); setError (ei); } } else { /* * If VMR3Create() failed it has released the VM memory. */ console->mpVM = NULL; } if (SUCCEEDED (hrc) && VBOX_FAILURE (vrc)) { /* * If VMR3Create() or one of the other calls in this function fail, * an appropriate error message has been already set. However since * that happens via a callback, the status code in this function is * not updated. */ if (!task->mProgress->completed()) { /* * If the COM error info is not yet set but we've got a * failure, convert the VBox status code into a meaningful * error message. This becomes unused once all the sources of * errors set the appropriate error message themselves. * Note that we don't use VMSetError() below because pVM is * either invalid or NULL here. */ AssertMsgFailed (("Missing error message during powerup for " "status code %Vrc\n", vrc)); hrc = setError (E_FAIL, tr ("Failed to start VM execution (%Vrc)"), vrc); } else hrc = task->mProgress->resultCode(); Assert (FAILED (hrc)); break; } } while (0); if (console->mMachineState == MachineState_Starting || console->mMachineState == MachineState_Restoring) { /* * We are still in the Starting/Restoring state. This means one of: * 1) we failed before VMR3Create() was called; * 2) VMR3Create() failed. * In both cases, there is no need to call powerDown(), but we still * need to go back to the PoweredOff/Saved state. Reuse * vmstateChangeCallback() for that purpose. */ /* preserve the current error info */ ErrorInfo ei; Assert (console->mpVM == NULL); vmstateChangeCallback (NULL, VMSTATE_TERMINATED, VMSTATE_CREATING, console); setError (ei); } /* * Evaluate the final result. * Note that the appropriate mMachineState value is already set by * vmstateChangeCallback() in all cases. */ /* leave the lock, don't need it any more */ alock.leave(); if (SUCCEEDED (hrc)) { /* Notify the progress object of the success */ task->mProgress->notifyComplete (S_OK); } else { if (!task->mProgress->completed()) { /* The progress object will fetch the current error info. This * gets the errors signalled by using setError(). The ones * signalled via VMSetError() immediately notify the progress * object that the operation is completed. */ task->mProgress->notifyComplete (hrc); } LogRel (("Power up failed (vrc=%Vrc, hrc=0x%08X)\n", vrc, hrc)); } #if defined(__WIN__) /* uninitialize COM */ CoUninitialize(); #endif LogFlowFuncLeave(); return VINF_SUCCESS; } /** * Reconfigures a VDI. * * @param pVM The VM handle. * @param hda The harddisk attachment. * @param phrc Where to store com error - only valid if we return VERR_GENERAL_FAILURE. * @return VBox status code. */ static DECLCALLBACK(int) reconfigureVDI(PVM pVM, IHardDiskAttachment *hda, HRESULT *phrc) { LogFlowFunc (("pVM=%p hda=%p phrc=%p\n", pVM, hda, phrc)); int rc; HRESULT hrc; char *psz = NULL; BSTR str = NULL; *phrc = S_OK; #define STR_CONV() do { rc = RTStrUcs2ToUtf8(&psz, str); RC_CHECK(); } while (0) #define STR_FREE() do { if (str) { SysFreeString(str); str = NULL; } if (psz) { RTStrFree(psz); psz = NULL; } } while (0) #define RC_CHECK() do { if (VBOX_FAILURE(rc)) { AssertMsgFailed(("rc=%Vrc\n", rc)); STR_FREE(); return rc; } } while (0) #define H() do { if (FAILED(hrc)) { AssertMsgFailed(("hrc=%#x\n", hrc)); STR_FREE(); *phrc = hrc; return VERR_GENERAL_FAILURE; } } while (0) /* * Figure out which IDE device this is. */ ComPtr hardDisk; hrc = hda->COMGETTER(HardDisk)(hardDisk.asOutParam()); H(); DiskControllerType_T enmCtl; hrc = hda->COMGETTER(Controller)(&enmCtl); H(); LONG lDev; hrc = hda->COMGETTER(DeviceNumber)(&lDev); H(); int i; switch (enmCtl) { case DiskControllerType_IDE0Controller: i = 0; break; case DiskControllerType_IDE1Controller: i = 2; break; default: AssertMsgFailed(("invalid disk controller type: %d\n", enmCtl)); return VERR_GENERAL_FAILURE; } if (lDev < 0 || lDev >= 2) { AssertMsgFailed(("invalid controller device number: %d\n", lDev)); return VERR_GENERAL_FAILURE; } i = i + lDev; /* * Is there an existing LUN? If not create it. * We ASSUME that this will NEVER collide with the DVD. */ PCFGMNODE pCfg; PCFGMNODE pLunL1 = CFGMR3GetChildF(CFGMR3GetRoot(pVM), "Devices/piix3ide/0/LUN#%d/AttachedDriver/", i); if (!pLunL1) { PCFGMNODE pInst = CFGMR3GetChild(CFGMR3GetRoot(pVM), "Devices/piix3ide/0/"); AssertReturn(pInst, VERR_INTERNAL_ERROR); PCFGMNODE pLunL0; rc = CFGMR3InsertNodeF(pInst, &pLunL0, "LUN#%d", i); RC_CHECK(); rc = CFGMR3InsertString(pLunL0, "Driver", "Block"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "Config", &pCfg); RC_CHECK(); rc = CFGMR3InsertString(pCfg, "Type", "HardDisk"); RC_CHECK(); rc = CFGMR3InsertInteger(pCfg, "Mountable", 0); RC_CHECK(); rc = CFGMR3InsertNode(pLunL0, "AttachedDriver", &pLunL1); RC_CHECK(); rc = CFGMR3InsertString(pLunL1, "Driver", "VBoxHDD"); RC_CHECK(); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); } else { #ifdef VBOX_STRICT char *pszDriver; rc = CFGMR3QueryStringAlloc(pLunL1, "Driver", &pszDriver); RC_CHECK(); Assert(!strcmp(pszDriver, "VBoxHDD")); MMR3HeapFree(pszDriver); #endif /* * Check if things has changed. */ pCfg = CFGMR3GetChild(pLunL1, "Config"); AssertReturn(pCfg, VERR_INTERNAL_ERROR); /* the image */ /// @todo (dmik) we temporarily use the location property to // determine the image file name. This is subject to change // when iSCSI disks are here (we should either query a // storage-specific interface from IHardDisk, or "standardize" // the location property) hrc = hardDisk->COMGETTER(Location)(&str); H(); STR_CONV(); char *pszPath; rc = CFGMR3QueryStringAlloc(pCfg, "Path", &pszPath); RC_CHECK(); if (!strcmp(psz, pszPath)) { /* parent images. */ ComPtr parentHardDisk = hardDisk; for (PCFGMNODE pParent = pCfg;;) { MMR3HeapFree(pszPath); pszPath = NULL; STR_FREE(); /* get parent */ ComPtr curHardDisk; hrc = parentHardDisk->COMGETTER(Parent)(curHardDisk.asOutParam()); H(); PCFGMNODE pCur; pCur = CFGMR3GetChild(pParent, "Parent"); if (!pCur && !curHardDisk) { /* no change */ LogFlowFunc (("No change!\n")); return VINF_SUCCESS; } if (!pCur || !curHardDisk) break; /* compare paths. */ /// @todo (dmik) we temporarily use the location property to // determine the image file name. This is subject to change // when iSCSI disks are here (we should either query a // storage-specific interface from IHardDisk, or "standardize" // the location property) hrc = curHardDisk->COMGETTER(Location)(&str); H(); STR_CONV(); rc = CFGMR3QueryStringAlloc(pCfg, "Path", &pszPath); RC_CHECK(); if (strcmp(psz, pszPath)) break; /* next */ pParent = pCur; parentHardDisk = curHardDisk; } } else LogFlowFunc (("LUN#%d: old leaf image '%s'\n", i, pszPath)); MMR3HeapFree(pszPath); STR_FREE(); /* * Detach the driver and replace the config node. */ rc = PDMR3DeviceDetach(pVM, "piix3ide", 0, i); RC_CHECK(); CFGMR3RemoveNode(pCfg); rc = CFGMR3InsertNode(pLunL1, "Config", &pCfg); RC_CHECK(); } /* * Create the driver configuration. */ /// @todo (dmik) we temporarily use the location property to // determine the image file name. This is subject to change // when iSCSI disks are here (we should either query a // storage-specific interface from IHardDisk, or "standardize" // the location property) hrc = hardDisk->COMGETTER(Location)(&str); H(); STR_CONV(); LogFlowFunc (("LUN#%d: leaf image '%s'\n", i, psz)); rc = CFGMR3InsertString(pCfg, "Path", psz); RC_CHECK(); STR_FREE(); /* Create an inversed tree of parents. */ ComPtr parentHardDisk = hardDisk; for (PCFGMNODE pParent = pCfg;;) { ComPtr curHardDisk; hrc = parentHardDisk->COMGETTER(Parent)(curHardDisk.asOutParam()); H(); if (!curHardDisk) break; PCFGMNODE pCur; rc = CFGMR3InsertNode(pParent, "Parent", &pCur); RC_CHECK(); /// @todo (dmik) we temporarily use the location property to // determine the image file name. This is subject to change // when iSCSI disks are here (we should either query a // storage-specific interface from IHardDisk, or "standardize" // the location property) hrc = curHardDisk->COMGETTER(Location)(&str); H(); STR_CONV(); rc = CFGMR3InsertString(pCur, "Path", psz); RC_CHECK(); STR_FREE(); /* next */ pParent = pCur; parentHardDisk = curHardDisk; } /* * Attach the new driver. */ rc = PDMR3DeviceAttach(pVM, "piix3ide", 0, i, NULL); RC_CHECK(); LogFlowFunc (("Returns success\n")); return rc; } /** * Thread for executing the saved state operation. * * @param Thread The thread handle. * @param pvUser Pointer to a VMSaveTask structure. * @return VINF_SUCCESS (ignored). * * @note Locks the Console object for writing. */ /*static*/ DECLCALLBACK (int) Console::saveStateThread (RTTHREAD Thread, void *pvUser) { LogFlowFuncEnter(); std::auto_ptr task (static_cast (pvUser)); AssertReturn (task.get(), VERR_INVALID_PARAMETER); Assert (!task->mSavedStateFile.isNull()); Assert (!task->mProgress.isNull()); const ComObjPtr &that = task->mConsole; /* * Note: no need to use addCaller() to protect Console or addVMCaller() to * protect mpVM because VMSaveTask does that */ Utf8Str errMsg; HRESULT rc = S_OK; if (task->mIsSnapshot) { Assert (!task->mServerProgress.isNull()); LogFlowFunc (("Waiting until the server creates differencing VDIs...\n")); rc = task->mServerProgress->WaitForCompletion (-1); if (SUCCEEDED (rc)) { HRESULT result = S_OK; rc = task->mServerProgress->COMGETTER(ResultCode) (&result); if (SUCCEEDED (rc)) rc = result; } } if (SUCCEEDED (rc)) { LogFlowFunc (("Saving the state to '%s'...\n", task->mSavedStateFile.raw())); int vrc = VMR3Save (that->mpVM, task->mSavedStateFile, Console::stateProgressCallback, static_cast (task.get())); if (VBOX_FAILURE (vrc)) { errMsg = Utf8StrFmt ( Console::tr ("Failed to save the machine state to '%s' (%Vrc)"), task->mSavedStateFile.raw(), vrc); rc = E_FAIL; } } /* lock the console sonce we're going to access it */ AutoLock thatLock (that); if (SUCCEEDED (rc)) { if (task->mIsSnapshot) do { LogFlowFunc (("Reattaching new differencing VDIs...\n")); ComPtr hdaColl; rc = that->mMachine->COMGETTER(HardDiskAttachments) (hdaColl.asOutParam()); if (FAILED (rc)) break; ComPtr hdaEn; rc = hdaColl->Enumerate (hdaEn.asOutParam()); if (FAILED (rc)) break; BOOL more = FALSE; while (SUCCEEDED (rc = hdaEn->HasMore (&more)) && more) { ComPtr hda; rc = hdaEn->GetNext (hda.asOutParam()); if (FAILED (rc)) break; PVMREQ pReq; IHardDiskAttachment *pHda = hda; /* * don't leave the lock since reconfigureVDI isn't going to * access Console. */ int vrc = VMR3ReqCall (that->mpVM, &pReq, RT_INDEFINITE_WAIT, (PFNRT)reconfigureVDI, 3, that->mpVM, pHda, &rc); if (VBOX_SUCCESS (rc)) rc = pReq->iStatus; VMR3ReqFree (pReq); if (FAILED (rc)) break; if (VBOX_FAILURE (vrc)) { errMsg = Utf8StrFmt (Console::tr ("%Vrc"), vrc); rc = E_FAIL; break; } } } while (0); } /* finalize the procedure regardless of the result */ if (task->mIsSnapshot) { /* * finalize the requested snapshot object. * This will reset the machine state to the state it had right * before calling mControl->BeginTakingSnapshot(). */ that->mControl->EndTakingSnapshot (SUCCEEDED (rc)); } else { /* * finalize the requested save state procedure. * In case of success, the server will set the machine state to Saved; * in case of failure it will reset the it to the state it had right * before calling mControl->BeginSavingState(). */ that->mControl->EndSavingState (SUCCEEDED (rc)); } /* synchronize the state with the server */ if (task->mIsSnapshot || FAILED (rc)) { if (task->mLastMachineState == MachineState_Running) { /* restore the paused state if appropriate */ that->setMachineStateLocally (MachineState_Paused); /* restore the running state if appropriate */ that->Resume(); } else that->setMachineStateLocally (task->mLastMachineState); } else { /* * The machine has been successfully saved, so power it down * (vmstateChangeCallback() will set state to Saved on success). * Note: we release the task's VM caller, otherwise it will * deadlock. */ task->releaseVMCaller(); rc = that->powerDown(); } /* notify the progress object about operation completion */ if (SUCCEEDED (rc)) task->mProgress->notifyComplete (S_OK); else { if (!errMsg.isNull()) task->mProgress->notifyComplete (rc, COM_IIDOF(IConsole), Console::getComponentName(), errMsg); else task->mProgress->notifyComplete (rc); } LogFlowFuncLeave(); return VINF_SUCCESS; } /** * Thread for powering down the Console. * * @param Thread The thread handle. * @param pvUser Pointer to the VMTask structure. * @return VINF_SUCCESS (ignored). * * @note Locks the Console object for writing. */ /*static*/ DECLCALLBACK (int) Console::powerDownThread (RTTHREAD Thread, void *pvUser) { LogFlowFuncEnter(); std::auto_ptr task (static_cast (pvUser)); AssertReturn (task.get(), VERR_INVALID_PARAMETER); AssertReturn (task->isOk(), VERR_GENERAL_FAILURE); const ComObjPtr &that = task->mConsole; /* * Note: no need to use addCaller() to protect Console * because VMTask does that */ /* release VM caller to let powerDown() proceed */ task->releaseVMCaller(); HRESULT rc = that->powerDown(); AssertComRC (rc); LogFlowFuncLeave(); return VINF_SUCCESS; } /** * The Main status driver instance data. */ typedef struct DRVMAINSTATUS { /** The LED connectors. */ PDMILEDCONNECTORS ILedConnectors; /** Pointer to the LED ports interface above us. */ PPDMILEDPORTS pLedPorts; /** Pointer to the array of LED pointers. */ PPDMLED *papLeds; /** The unit number corresponding to the first entry in the LED array. */ RTUINT iFirstLUN; /** The unit number corresponding to the last entry in the LED array. * (The size of the LED array is iLastLUN - iFirstLUN + 1.) */ RTUINT iLastLUN; } DRVMAINSTATUS, *PDRVMAINSTATUS; /** * Notification about a unit which have been changed. * * The driver must discard any pointers to data owned by * the unit and requery it. * * @param pInterface Pointer to the interface structure containing the called function pointer. * @param iLUN The unit number. */ DECLCALLBACK(void) Console::drvStatus_UnitChanged(PPDMILEDCONNECTORS pInterface, unsigned iLUN) { PDRVMAINSTATUS pData = (PDRVMAINSTATUS)(void *)pInterface; if (iLUN >= pData->iFirstLUN && iLUN <= pData->iLastLUN) { PPDMLED pLed; int rc = pData->pLedPorts->pfnQueryStatusLed(pData->pLedPorts, iLUN, &pLed); if (VBOX_FAILURE(rc)) pLed = NULL; ASMAtomicXchgPtr((void * volatile *)&pData->papLeds[iLUN - pData->iFirstLUN], pLed); Log(("drvStatus_UnitChanged: iLUN=%d pLed=%p\n", iLUN, pLed)); } } /** * Queries an interface to the driver. * * @returns Pointer to interface. * @returns NULL if the interface was not supported by the driver. * @param pInterface Pointer to this interface structure. * @param enmInterface The requested interface identification. */ DECLCALLBACK(void *) Console::drvStatus_QueryInterface(PPDMIBASE pInterface, PDMINTERFACE enmInterface) { PPDMDRVINS pDrvIns = PDMIBASE_2_PDMDRV(pInterface); PDRVMAINSTATUS pDrv = PDMINS2DATA(pDrvIns, PDRVMAINSTATUS); switch (enmInterface) { case PDMINTERFACE_BASE: return &pDrvIns->IBase; case PDMINTERFACE_LED_CONNECTORS: return &pDrv->ILedConnectors; default: return NULL; } } /** * Destruct a status driver instance. * * @returns VBox status. * @param pDrvIns The driver instance data. */ DECLCALLBACK(void) Console::drvStatus_Destruct(PPDMDRVINS pDrvIns) { PDRVMAINSTATUS pData = PDMINS2DATA(pDrvIns, PDRVMAINSTATUS); LogFlowFunc(("iInstance=%d\n", pDrvIns->iInstance)); if (pData->papLeds) { unsigned iLed = pData->iLastLUN - pData->iFirstLUN + 1; while (iLed-- > 0) ASMAtomicXchgPtr((void * volatile *)&pData->papLeds[iLed], NULL); } } /** * Construct a status driver instance. * * @returns VBox status. * @param pDrvIns The driver instance data. * If the registration structure is needed, pDrvIns->pDrvReg points to it. * @param pCfgHandle Configuration node handle for the driver. Use this to obtain the configuration * of the driver instance. It's also found in pDrvIns->pCfgHandle, but like * iInstance it's expected to be used a bit in this function. */ DECLCALLBACK(int) Console::drvStatus_Construct(PPDMDRVINS pDrvIns, PCFGMNODE pCfgHandle) { PDRVMAINSTATUS pData = PDMINS2DATA(pDrvIns, PDRVMAINSTATUS); LogFlowFunc(("iInstance=%d\n", pDrvIns->iInstance)); /* * Validate configuration. */ if (!CFGMR3AreValuesValid(pCfgHandle, "papLeds\0First\0Last\0")) return VERR_PDM_DRVINS_UNKNOWN_CFG_VALUES; PPDMIBASE pBaseIgnore; int rc = pDrvIns->pDrvHlp->pfnAttach(pDrvIns, &pBaseIgnore); if (rc != VERR_PDM_NO_ATTACHED_DRIVER) { AssertMsgFailed(("Configuration error: Not possible to attach anything to this driver!\n")); return VERR_PDM_DRVINS_NO_ATTACH; } /* * Data. */ pDrvIns->IBase.pfnQueryInterface = Console::drvStatus_QueryInterface; pData->ILedConnectors.pfnUnitChanged = Console::drvStatus_UnitChanged; /* * Read config. */ rc = CFGMR3QueryPtr(pCfgHandle, "papLeds", (void **)&pData->papLeds); if (VBOX_FAILURE(rc)) { AssertMsgFailed(("Configuration error: Failed to query the \"papLeds\" value! rc=%Vrc\n", rc)); return rc; } rc = CFGMR3QueryU32(pCfgHandle, "First", &pData->iFirstLUN); if (rc == VERR_CFGM_VALUE_NOT_FOUND) pData->iFirstLUN = 0; else if (VBOX_FAILURE(rc)) { AssertMsgFailed(("Configuration error: Failed to query the \"First\" value! rc=%Vrc\n", rc)); return rc; } rc = CFGMR3QueryU32(pCfgHandle, "Last", &pData->iLastLUN); if (rc == VERR_CFGM_VALUE_NOT_FOUND) pData->iLastLUN = 0; else if (VBOX_FAILURE(rc)) { AssertMsgFailed(("Configuration error: Failed to query the \"Last\" value! rc=%Vrc\n", rc)); return rc; } if (pData->iFirstLUN > pData->iLastLUN) { AssertMsgFailed(("Configuration error: Invalid unit range %u-%u\n", pData->iFirstLUN, pData->iLastLUN)); return VERR_GENERAL_FAILURE; } /* * Get the ILedPorts interface of the above driver/device and * query the LEDs we want. */ pData->pLedPorts = (PPDMILEDPORTS)pDrvIns->pUpBase->pfnQueryInterface(pDrvIns->pUpBase, PDMINTERFACE_LED_PORTS); if (!pData->pLedPorts) { AssertMsgFailed(("Configuration error: No led ports interface above!\n")); return VERR_PDM_MISSING_INTERFACE_ABOVE; } for (unsigned i = pData->iFirstLUN; i <= pData->iLastLUN; i++) Console::drvStatus_UnitChanged(&pData->ILedConnectors, i); return VINF_SUCCESS; } /** * Keyboard driver registration record. */ const PDMDRVREG Console::DrvStatusReg = { /* u32Version */ PDM_DRVREG_VERSION, /* szDriverName */ "MainStatus", /* pszDescription */ "Main status driver (Main as in the API).", /* fFlags */ PDM_DRVREG_FLAGS_HOST_BITS_DEFAULT, /* fClass. */ PDM_DRVREG_CLASS_STATUS, /* cMaxInstances */ ~0, /* cbInstance */ sizeof(DRVMAINSTATUS), /* pfnConstruct */ Console::drvStatus_Construct, /* pfnDestruct */ Console::drvStatus_Destruct, /* pfnIOCtl */ NULL, /* pfnPowerOn */ NULL, /* pfnReset */ NULL, /* pfnSuspend */ NULL, /* pfnResume */ NULL, /* pfnDetach */ NULL };