/* $Id: server.cpp 13837 2008-11-05 02:54:02Z vboxsync $ */ /** @file * XPCOM server process (VBoxSVC) start point. */ /* * Copyright (C) 2006-2007 Sun Microsystems, Inc. * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa * Clara, CA 95054 USA or visit http://www.sun.com if you need * additional information or have any questions. */ /* Make sure all the stdint.h macros are included - must come first! */ #ifndef __STDC_LIMIT_MACROS # define __STDC_LIMIT_MACROS #endif #ifndef __STDC_CONSTANT_MACROS # define __STDC_CONSTANT_MACROS #endif #include #include #include #if defined(XPCOM_GLUE) #include #endif #include #include #include "xpcom/server.h" #include "Logging.h" #include #include #include #include #include #include #include #include // for the signal handler #include #include #include #include #include // for the backtrace signal handler #if defined(DEBUG) && defined(RT_OS_LINUX) # define USE_BACKTRACE #endif #if defined(USE_BACKTRACE) # include // get REG_EIP/RIP from ucontext.h # ifndef __USE_GNU # define __USE_GNU # endif # include # ifdef RT_ARCH_AMD64 # define REG_PC REG_RIP # else # define REG_PC REG_EIP # endif #endif ///////////////////////////////////////////////////////////////////////////// // VirtualBox component instantiation ///////////////////////////////////////////////////////////////////////////// #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef VBOX_WITH_USB # include # include #endif #include #include #include #include /* implement nsISupports parts of our objects with support for nsIClassInfo */ NS_DECL_CLASSINFO(VirtualBox) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(VirtualBox, IVirtualBox) NS_DECL_CLASSINFO(Machine) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(Machine, IMachine) NS_DECL_CLASSINFO(SessionMachine) NS_IMPL_THREADSAFE_ISUPPORTS2_CI(SessionMachine, IMachine, IInternalMachineControl) NS_DECL_CLASSINFO(SnapshotMachine) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(SnapshotMachine, IMachine) NS_DECL_CLASSINFO(Snapshot) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(Snapshot, ISnapshot) NS_DECL_CLASSINFO(DVDImage2) NS_IMPL_THREADSAFE_ISUPPORTS2_AMBIGUOUS_CI(DVDImage2, IMedium, ImageMediumBase, IDVDImage2, DVDImage2) NS_DECL_CLASSINFO(FloppyImage2) NS_IMPL_THREADSAFE_ISUPPORTS2_AMBIGUOUS_CI(FloppyImage2, IMedium, ImageMediumBase, IFloppyImage2, FloppyImage2) NS_DECL_CLASSINFO(HardDisk2) NS_IMPL_THREADSAFE_ISUPPORTS2_AMBIGUOUS_CI(HardDisk2, IMedium, MediumBase, IHardDisk2, HardDisk2) NS_DECL_CLASSINFO(HardDiskFormat) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(HardDiskFormat, IHardDiskFormat) NS_DECL_CLASSINFO(HardDisk2Attachment) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(HardDisk2Attachment, IHardDisk2Attachment) NS_DECL_CLASSINFO(Progress) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(Progress, IProgress) NS_DECL_CLASSINFO(CombinedProgress) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(CombinedProgress, IProgress) NS_DECL_CLASSINFO(DVDDrive) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(DVDDrive, IDVDDrive) NS_DECL_CLASSINFO(FloppyDrive) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(FloppyDrive, IFloppyDrive) NS_DECL_CLASSINFO(SharedFolder) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(SharedFolder, ISharedFolder) #ifdef VBOX_WITH_VRDP NS_DECL_CLASSINFO(VRDPServer) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(VRDPServer, IVRDPServer) #endif NS_DECL_CLASSINFO(Host) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(Host, IHost) NS_DECL_CLASSINFO(HostDVDDrive) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(HostDVDDrive, IHostDVDDrive) NS_DECL_CLASSINFO(HostFloppyDrive) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(HostFloppyDrive, IHostFloppyDrive) NS_DECL_CLASSINFO(HostNetworkInterface) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(HostNetworkInterface, IHostNetworkInterface) NS_DECL_CLASSINFO(GuestOSType) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(GuestOSType, IGuestOSType) NS_DECL_CLASSINFO(NetworkAdapter) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(NetworkAdapter, INetworkAdapter) NS_DECL_CLASSINFO(SerialPort) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(SerialPort, ISerialPort) NS_DECL_CLASSINFO(ParallelPort) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(ParallelPort, IParallelPort) NS_DECL_CLASSINFO(USBController) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(USBController, IUSBController) NS_DECL_CLASSINFO(SATAController) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(SATAController, ISATAController) #ifdef VBOX_WITH_USB NS_DECL_CLASSINFO(USBDeviceFilter) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(USBDeviceFilter, IUSBDeviceFilter) NS_DECL_CLASSINFO(HostUSBDevice) NS_IMPL_THREADSAFE_ISUPPORTS2_CI(HostUSBDevice, IUSBDevice, IHostUSBDevice) NS_DECL_CLASSINFO(HostUSBDeviceFilter) NS_IMPL_THREADSAFE_ISUPPORTS2_CI(HostUSBDeviceFilter, IUSBDeviceFilter, IHostUSBDeviceFilter) #endif NS_DECL_CLASSINFO(AudioAdapter) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(AudioAdapter, IAudioAdapter) NS_DECL_CLASSINFO(SystemProperties) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(SystemProperties, ISystemProperties) #ifdef VBOX_WITH_RESOURCE_USAGE_API NS_DECL_CLASSINFO(PerformanceCollector) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(PerformanceCollector, IPerformanceCollector) NS_DECL_CLASSINFO(PerformanceMetric) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(PerformanceMetric, IPerformanceMetric) #endif /* VBOX_WITH_RESOURCE_USAGE_API */ NS_DECL_CLASSINFO(BIOSSettings) NS_IMPL_THREADSAFE_ISUPPORTS1_CI(BIOSSettings, IBIOSSettings) /* collections and enumerators */ COM_IMPL_READONLY_ENUM_AND_COLLECTION(Snapshot) COM_IMPL_READONLY_ENUM_AND_COLLECTION(GuestOSType) COM_IMPL_READONLY_ENUM_AND_COLLECTION(HostDVDDrive) COM_IMPL_READONLY_ENUM_AND_COLLECTION(HostFloppyDrive) COM_IMPL_READONLY_ENUM_AND_COLLECTION(HostNetworkInterface) COM_IMPL_READONLY_ENUM_AND_COLLECTION(SharedFolder) #ifdef VBOX_WITH_USB COM_IMPL_READONLY_ENUM_AND_COLLECTION(HostUSBDevice) COM_IMPL_READONLY_ENUM_AND_COLLECTION(HostUSBDeviceFilter) COM_IMPL_READONLY_ENUM_AND_COLLECTION(USBDeviceFilter) #endif COM_IMPL_READONLY_ENUM_AND_COLLECTION_AS(Progress, IProgress) #ifdef VBOX_WITH_USB COM_IMPL_READONLY_ENUM_AND_COLLECTION_AS(IfaceUSBDevice, IUSBDevice) #endif //////////////////////////////////////////////////////////////////////////////// enum { /* Delay before shutting down the VirtualBox server after the last * VirtualBox instance is released, in ms */ VBoxSVC_ShutdownDelay = 5000, }; static bool gAutoShutdown = false; static nsIEventQueue* gEventQ = nsnull; static PRBool volatile gKeepRunning = PR_TRUE; ///////////////////////////////////////////////////////////////////////////// /** * Simple but smart PLEvent wrapper. * * @note Instances must be always created with operator new! */ class MyEvent { public: MyEvent() { mEv.that = NULL; }; /** * Posts this event to the given message queue. This method may only be * called once. @note On success, the event will be deleted automatically * after it is delivered and handled. On failure, the event will delete * itself before this method returns! The caller must not delete it in * either case. */ nsresult postTo (nsIEventQueue *aEventQ) { AssertReturn (mEv.that == NULL, NS_ERROR_FAILURE); AssertReturn (aEventQ, NS_ERROR_FAILURE); nsresult rv = aEventQ->InitEvent (&mEv.e, NULL, eventHandler, eventDestructor); if (NS_SUCCEEDED (rv)) { mEv.that = this; rv = aEventQ->PostEvent (&mEv.e); if (NS_SUCCEEDED (rv)) return rv; } delete this; return rv; } virtual void *handler() = 0; private: struct Ev { PLEvent e; MyEvent *that; } mEv; static void *PR_CALLBACK eventHandler (PLEvent *self) { return reinterpret_cast (self)->that->handler(); } static void PR_CALLBACK eventDestructor (PLEvent *self) { delete reinterpret_cast (self)->that; } }; //////////////////////////////////////////////////////////////////////////////// /** * VirtualBox class factory that destroys the created instance right after * the last reference to it is released by the client, and recreates it again * when necessary (so VirtualBox acts like a singleton object). */ class VirtualBoxClassFactory : public VirtualBox { public: virtual ~VirtualBoxClassFactory() { LogFlowFunc (("Deleting VirtualBox...\n")); FinalRelease(); sInstance = 0; LogFlowFunc (("VirtualBox object deleted.\n")); printf ("Informational: VirtualBox object deleted.\n"); } NS_IMETHOD_(nsrefcnt) Release() { /* we overload Release() to guarantee the VirtualBox destructor is * always called on the main thread */ nsrefcnt count = VirtualBox::Release(); if (count == 1) { /* the last reference held by clients is being released * (see GetInstance()) */ PRBool onMainThread = PR_TRUE; if (gEventQ) gEventQ->IsOnCurrentThread (&onMainThread); PRBool timerStarted = PR_FALSE; /* sTimes is null if this call originates from * FactoryDestructor() */ if (sTimer != NULL) { LogFlowFunc (("Last VirtualBox instance was released.\n")); LogFlowFunc (("Scheduling server shutdown in %d ms...\n", VBoxSVC_ShutdownDelay)); /* make sure the previous timer (if any) is stopped; * otherwise RTTimerStart() will definitely fail. */ RTTimerLRStop (sTimer); int vrc = RTTimerLRStart (sTimer, uint64_t (VBoxSVC_ShutdownDelay) * 1000000); AssertRC (vrc); timerStarted = SUCCEEDED (vrc); } else { LogFlowFunc (("Last VirtualBox instance was released " "on XPCOM shutdown.\n")); Assert (onMainThread); } if (!timerStarted) { if (!onMainThread) { /* Failed to start the timer, post the shutdown event * manually if not on the main thread alreay. */ ShutdownTimer (NULL, NULL, 0); } else { /* Here we come if: * * a) gEventQ is 0 which means either FactoryDestructor() is called * or the IPC/DCONNECT shutdown sequence is initiated by the * XPCOM shutdown routine (NS_ShutdownXPCOM()), which always * happens on the main thread. * * b) gEventQ has reported we're on the main thread. This means * that DestructEventHandler() has been called, but another * client was faster and requested VirtualBox again. * * In either case, there is nothing to do. * * Note: case b) is actually no more valid since we don't * call Release() from DestructEventHandler() in this case * any more. Thus, we assert below. */ Assert (gEventQ == NULL); } } } return count; } class MaybeQuitEvent : public MyEvent { /* called on the main thread */ void *handler() { LogFlowFunc (("\n")); Assert (RTCritSectIsInitialized (&sLock)); /* stop accepting GetInstance() requests on other threads during * possible destruction */ RTCritSectEnter (&sLock); nsrefcnt count = 0; /* sInstance is NULL here if it was deleted immediately after * creation due to initialization error. See GetInstance(). */ if (sInstance != NULL) { /* Release the guard reference added in GetInstance() */ count = sInstance->Release(); } if (count == 0) { if (gAutoShutdown) { Assert (sInstance == NULL); LogFlowFunc (("Terminating the server process...\n")); /* make it leave the event loop */ gKeepRunning = PR_FALSE; } } else { /* This condition is quite rare: a new client will have to * connect after this event has been posted to the main queue * but before it started to process it. */ LogFlowFunc (("Destruction is canceled (refcnt=%d).\n", count)); } RTCritSectLeave (&sLock); return NULL; } }; static void ShutdownTimer (RTTIMERLR hTimerLR, void *pvUser, uint64_t /*iTick*/) { NOREF (hTimerLR); NOREF (pvUser); /* A "too late" event is theoretically possible if somebody * manually ended the server after a destruction has been scheduled * and this method was so lucky that it got a chance to run before * the timer was killed. */ AssertReturnVoid (gEventQ); /* post a quit event to the main queue */ MaybeQuitEvent *ev = new MaybeQuitEvent(); nsresult rv = ev->postTo (gEventQ); NOREF (rv); /* A failure above means we've been already stopped (for example * by Ctrl-C). FactoryDestructor() (NS_ShutdownXPCOM()) * will do the job. Nothing to do. */ } static NS_IMETHODIMP FactoryConstructor() { LogFlowFunc (("\n")); /* create a critsect to protect object construction */ if (RT_FAILURE (RTCritSectInit (&sLock))) return NS_ERROR_OUT_OF_MEMORY; int vrc = RTTimerLRCreateEx (&sTimer, 0, 0, ShutdownTimer, NULL); if (RT_FAILURE (vrc)) { LogFlowFunc (("Failed to create a timer! (vrc=%Rrc)\n", vrc)); return NS_ERROR_FAILURE; } return NS_OK; } static NS_IMETHODIMP FactoryDestructor() { LogFlowFunc (("\n")); RTTimerLRDestroy (sTimer); sTimer = NULL; RTCritSectDelete (&sLock); if (sInstance) { /* Either posting a destruction event falied for some reason (most * likely, the quit event has been received before the last release), * or the client has terminated abnormally w/o releasing its * VirtualBox instance (so NS_ShutdownXPCOM() is doing a cleanup). * Release the guard reference we added in GetInstance(). */ sInstance->Release(); } return NS_OK; } static nsresult GetInstance (VirtualBox **inst) { LogFlowFunc (("Getting VirtualBox object...\n")); RTCritSectEnter (&sLock); int rv = NS_OK; if (sInstance == 0) { LogFlowFunc (("Creating new VirtualBox object...\n")); sInstance = new VirtualBoxClassFactory(); if (sInstance) { /* make an extra AddRef to take the full control * on the VirtualBox destruction (see FinalRelease()) */ sInstance->AddRef(); sInstance->AddRef(); /* protect FinalConstruct() */ rv = sInstance->FinalConstruct(); printf ("Informational: VirtualBox object created (rc=%08X).\n", rv); if (NS_FAILED (rv)) { /* On failure diring VirtualBox initialization, delete it * immediately on the current thread by releasing all * references in order to properly schedule the server * shutdown. Since the object is fully deleted here, there * is a chance to fix the error and request a new * instantiation before the server terminates. However, * the main reason to maintain the shoutdown delay on * failure is to let the front-end completely fetch error * info from a server-side IVirtualBoxErrorInfo object. */ sInstance->Release(); sInstance->Release(); Assert (sInstance == 0); } else { /* On success, make sure the previous timer is stopped to * cancel a scheduled server termination (if any). */ RTTimerLRStop (sTimer); } } else { rv = NS_ERROR_OUT_OF_MEMORY; } } else { LogFlowFunc (("Using existing VirtualBox object...\n")); nsrefcnt count = sInstance->AddRef(); Assert (count > 1); if (count == 2) { LogFlowFunc (("Another client has requested a reference to VirtualBox, " "canceling detruction...\n")); /* make sure the previous timer is stopped */ RTTimerLRStop (sTimer); } } *inst = sInstance; RTCritSectLeave (&sLock); return rv; } private: /* Don't be confused that sInstance is of the *ClassFactory type. This is * actually a singleton instance (*ClassFactory inherits the singleton * class; we combined them just for "simplicity" and used "static" for * factory methods. *ClassFactory here is necessary for a couple of extra * methods. */ static VirtualBoxClassFactory *sInstance; static RTCRITSECT sLock; static RTTIMERLR sTimer; }; VirtualBoxClassFactory *VirtualBoxClassFactory::sInstance = 0; RTCRITSECT VirtualBoxClassFactory::sLock = {0}; RTTIMERLR VirtualBoxClassFactory::sTimer = NIL_RTTIMERLR; NS_GENERIC_FACTORY_SINGLETON_CONSTRUCTOR_WITH_RC (VirtualBox, VirtualBoxClassFactory::GetInstance) //////////////////////////////////////////////////////////////////////////////// typedef NSFactoryDestructorProcPtr NSFactoryConsructorProcPtr; /** * Enhanced module component information structure. * * nsModuleComponentInfo lacks the factory construction callback, here we add * it. This callback is called by NS_NewGenericFactoryEx() after a * nsGenericFactory instance is successfully created. */ struct nsModuleComponentInfoEx : nsModuleComponentInfo { nsModuleComponentInfoEx () {} nsModuleComponentInfoEx (int) {} nsModuleComponentInfoEx ( const char* aDescription, const nsCID& aCID, const char* aContractID, NSConstructorProcPtr aConstructor, NSRegisterSelfProcPtr aRegisterSelfProc, NSUnregisterSelfProcPtr aUnregisterSelfProc, NSFactoryDestructorProcPtr aFactoryDestructor, NSGetInterfacesProcPtr aGetInterfacesProc, NSGetLanguageHelperProcPtr aGetLanguageHelperProc, nsIClassInfo ** aClassInfoGlobal, PRUint32 aFlags, NSFactoryConsructorProcPtr aFactoryConstructor) { mDescription = aDescription; mCID = aCID; mContractID = aContractID; mConstructor = aConstructor; mRegisterSelfProc = aRegisterSelfProc; mUnregisterSelfProc = aUnregisterSelfProc; mFactoryDestructor = aFactoryDestructor; mGetInterfacesProc = aGetInterfacesProc; mGetLanguageHelperProc = aGetLanguageHelperProc; mClassInfoGlobal = aClassInfoGlobal; mFlags = aFlags; mFactoryConstructor = aFactoryConstructor; } /** (optional) Factory Construction Callback */ NSFactoryConsructorProcPtr mFactoryConstructor; }; //////////////////////////////////////////////////////////////////////////////// static const nsModuleComponentInfoEx components[] = { nsModuleComponentInfoEx ( "VirtualBox component", (nsCID) NS_VIRTUALBOX_CID, NS_VIRTUALBOX_CONTRACTID, VirtualBoxConstructor, // constructor funcion NULL, // registration function NULL, // deregistration function VirtualBoxClassFactory::FactoryDestructor, // factory destructor function NS_CI_INTERFACE_GETTER_NAME(VirtualBox), NULL, // language helper &NS_CLASSINFO_NAME(VirtualBox), 0, // flags VirtualBoxClassFactory::FactoryConstructor // factory constructor function ) }; ///////////////////////////////////////////////////////////////////////////// /** * Extends NS_NewGenericFactory() by immediately calling * nsModuleComponentInfoEx::mFactoryConstructor before returning to the * caller. */ nsresult NS_NewGenericFactoryEx (nsIGenericFactory **result, const nsModuleComponentInfoEx *info) { AssertReturn (result, NS_ERROR_INVALID_POINTER); nsresult rv = NS_NewGenericFactory (result, info); if (NS_SUCCEEDED (rv) && info && info->mFactoryConstructor) { rv = info->mFactoryConstructor(); if (NS_FAILED (rv)) NS_RELEASE (*result); } return rv; } ///////////////////////////////////////////////////////////////////////////// /** * Hhelper function to register self components upon start-up * of the out-of-proc server. */ static nsresult RegisterSelfComponents (nsIComponentRegistrar *registrar, const nsModuleComponentInfoEx *components, PRUint32 count) { nsresult rc = NS_OK; const nsModuleComponentInfoEx *info = components; for (PRUint32 i = 0; i < count && NS_SUCCEEDED (rc); i++, info++) { /* skip components w/o a constructor */ if (!info->mConstructor) continue; /* create a new generic factory for a component and register it */ nsIGenericFactory *factory; rc = NS_NewGenericFactoryEx (&factory, info); if (NS_SUCCEEDED (rc)) { rc = registrar->RegisterFactory (info->mCID, info->mDescription, info->mContractID, factory); factory->Release(); } } return rc; } ///////////////////////////////////////////////////////////////////////////// static ipcIService *gIpcServ = nsnull; static char *pszPidFile = NULL; class ForceQuitEvent : public MyEvent { void *handler() { LogFlowFunc (("\n")); gKeepRunning = PR_FALSE; if (pszPidFile) RTFileDelete(pszPidFile); return NULL; } }; static void signal_handler (int sig) { if (gEventQ && gKeepRunning) { /* post a quit event to the queue */ ForceQuitEvent *ev = new ForceQuitEvent(); ev->postTo (gEventQ); } } #if defined(USE_BACKTRACE) /** * the signal handler that prints out a backtrace of the call stack. * the code is taken from http://www.linuxjournal.com/article/6391. */ static void bt_sighandler (int sig, siginfo_t *info, void *secret) { void *trace[16]; char **messages = (char **)NULL; int i, trace_size = 0; ucontext_t *uc = (ucontext_t *)secret; // Do something useful with siginfo_t if (sig == SIGSEGV) Log (("Got signal %d, faulty address is %p, from %p\n", sig, info->si_addr, uc->uc_mcontext.gregs[REG_PC])); else Log (("Got signal %d\n", sig)); trace_size = backtrace (trace, 16); // overwrite sigaction with caller's address trace[1] = (void *) uc->uc_mcontext.gregs [REG_PC]; messages = backtrace_symbols (trace, trace_size); // skip first stack frame (points here) Log (("[bt] Execution path:\n")); for (i = 1; i < trace_size; ++i) Log (("[bt] %s\n", messages[i])); exit (0); } #endif int main (int argc, char **argv) { const struct option options[] = { { "automate", no_argument, NULL, 'a' }, #ifdef RT_OS_DARWIN { "auto-shutdown", no_argument, NULL, 'A' }, #endif { "daemonize", no_argument, NULL, 'd' }, { "pidfile", required_argument, NULL, 'p' }, #ifdef RT_OS_DARWIN { "pipe", required_argument, NULL, 'P' }, #endif { NULL, 0, NULL, 0 } }; int c; bool fDaemonize = false; #ifndef RT_OS_OS2 static int daemon_pipe_fds[2] = {-1, -1}; #endif for (;;) { c = getopt_long(argc, argv, "", options, NULL); if (c == -1) break; switch (c) { case 'a': { /* --automate mode means we are started by XPCOM on * demand. Daemonize ourselves and activate * auto-shutdown. */ gAutoShutdown = true; fDaemonize = true; break; } #ifdef RT_OS_DARWIN /* Used together with '-P', see below. Internal use only. */ case 'A': { gAutoShutdown = true; break; } #endif case 'd': { fDaemonize = true; break; } case 'p': { pszPidFile = optarg; break; } #ifdef RT_OS_DARWIN /* we need to exec on darwin, this is just an internal * hack for passing the pipe fd along to the final child. */ case 'P': { daemon_pipe_fds[1] = atoi(optarg); break; } #endif default: { /* exit on invalid options */ return 1; } } } static RTFILE pidFile = NIL_RTFILE; #ifdef RT_OS_OS2 /* nothing to do here, the process is supposed to be already * started daemonized when it is necessary */ NOREF(fDaemonize); #else // ifdef RT_OS_OS2 if (fDaemonize) { /* create a pipe for communication between child and parent */ if (pipe(daemon_pipe_fds) < 0) { printf("ERROR: pipe() failed (errno = %d)\n", errno); return 1; } pid_t childpid = fork(); if (childpid == -1) { printf("ERROR: fork() failed (errno = %d)\n", errno); return 1; } if (childpid != 0) { /* we're the parent process */ bool fSuccess = false; /* close the writing end of the pipe */ close(daemon_pipe_fds[1]); /* try to read a message from the pipe */ char msg[10] = {0}; /* initialize so it's NULL terminated */ if (read(daemon_pipe_fds[0], msg, sizeof(msg)) > 0) { if (strcmp(msg, "READY") == 0) fSuccess = true; else printf ("ERROR: Unknown message from child " "process (%s)\n", msg); } else printf ("ERROR: 0 bytes read from child process\n"); /* close the reading end of the pipe as well and exit */ close(daemon_pipe_fds[0]); return fSuccess ? 0 : 1; } /* we're the child process */ /* Create a new SID for the child process */ pid_t sid = setsid(); if (sid < 0) { printf("ERROR: setsid() failed (errno = %d)\n", errno); return 1; } /* Need to do another for to get rid of the session leader status. * Otherwise any accidentally opened tty will automatically become a * controlling tty for the daemon process. */ childpid = fork(); if (childpid == -1) { printf("ERROR: second fork() failed (errno = %d)\n", errno); return 1; } if (childpid != 0) { /* we're the parent process, just a dummy so terminate now */ exit(0); } /* Redirect standard i/o streams to /dev/null */ if (daemon_pipe_fds[0] > 2) { freopen ("/dev/null", "r", stdin); freopen ("/dev/null", "w", stdout); freopen ("/dev/null", "w", stderr); } /* close the reading end of the pipe */ close(daemon_pipe_fds[0]); # ifdef RT_OS_DARWIN /* * On leopard we're no longer allowed to use some of the core API's * after forking - this will cause us to hit an int3. * So, we'll have to execv VBoxSVC once again and hand it the pipe * and all other relevant options. */ const char *apszArgs[7]; unsigned i = 0; apszArgs[i++] = argv[0]; apszArgs[i++] = "--pipe"; char szPipeArg[32]; RTStrPrintf (szPipeArg, sizeof (szPipeArg), "%d", daemon_pipe_fds[1]); apszArgs[i++] = szPipeArg; if (pszPidFile) { apszArgs[i++] = "--pidfile"; apszArgs[i++] = pszPidFile; } if (gAutoShutdown) apszArgs[i++] = "--auto-shutdown"; apszArgs[i++] = NULL; Assert(i <= RT_ELEMENTS(apszArgs)); execv (apszArgs[0], (char * const *)apszArgs); exit (0); # endif } #endif // ifdef RT_OS_OS2 #if defined(USE_BACKTRACE) { /* install our signal handler to backtrace the call stack */ struct sigaction sa; sa.sa_sigaction = bt_sighandler; sigemptyset (&sa.sa_mask); sa.sa_flags = SA_RESTART | SA_SIGINFO; sigaction (SIGSEGV, &sa, NULL); sigaction (SIGBUS, &sa, NULL); sigaction (SIGUSR1, &sa, NULL); } #endif /* * Initialize the VBox runtime without loading * the support driver */ RTR3Init(); nsresult rc; do { rc = com::Initialize(); if (NS_FAILED (rc)) { printf ("ERROR: Failed to initialize XPCOM! (rc=%08X)\n", rc); break; } nsCOMPtr registrar; rc = NS_GetComponentRegistrar (getter_AddRefs (registrar)); if (NS_FAILED (rc)) { printf ("ERROR: Failed to get component registrar! (rc=%08X)\n", rc); break; } registrar->AutoRegister (nsnull); rc = RegisterSelfComponents (registrar, components, NS_ARRAY_LENGTH (components)); if (NS_FAILED (rc)) { printf ("ERROR: Failed to register server components! (rc=%08X)\n", rc); break; } /* get the main thread's event queue (afaik, the dconnect service always * gets created upon XPCOM startup, so it will use the main (this) * thread's event queue to receive IPC events) */ rc = NS_GetMainEventQ (&gEventQ); if (NS_FAILED (rc)) { printf ("ERROR: Failed to get the main event queue! (rc=%08X)\n", rc); break; } nsCOMPtr ipcServ (do_GetService(IPC_SERVICE_CONTRACTID, &rc)); if (NS_FAILED (rc)) { printf ("ERROR: Failed to get IPC service! (rc=%08X)\n", rc); break; } NS_ADDREF (gIpcServ = ipcServ); LogFlowFunc (("Will use \"%s\" as server name.\n", VBOXSVC_IPC_NAME)); rc = gIpcServ->AddName (VBOXSVC_IPC_NAME); if (NS_FAILED (rc)) { LogFlowFunc (("Failed to register the server name (rc=%08X)!\n" "Is another server already running?\n", rc)); printf ("ERROR: Failed to register the server name \"%s\" (rc=%08X)!\n" "Is another server already running?\n", VBOXSVC_IPC_NAME, rc); NS_RELEASE (gIpcServ); break; } { /* setup signal handling to convert some signals to a quit event */ struct sigaction sa; sa.sa_handler = signal_handler; sigemptyset (&sa.sa_mask); sa.sa_flags = 0; sigaction (SIGINT, &sa, NULL); sigaction (SIGQUIT, &sa, NULL); sigaction (SIGTERM, &sa, NULL); sigaction (SIGTRAP, &sa, NULL); } { char szBuf[80]; int iSize; iSize = snprintf (szBuf, sizeof(szBuf), "Sun xVM VirtualBox XPCOM Server Version " VBOX_VERSION_STRING); for (int i=iSize; i>0; i--) putchar('*'); printf ("\n%s\n", szBuf); printf ("(C) 2008 Sun Microsystems, Inc.\n" "All rights reserved.\n"); #ifdef DEBUG printf ("Debug version.\n"); #endif #if 0 /* in my opinion two lines enclosing the text look better */ for (int i=iSize; i>0; i--) putchar('*'); putchar('\n'); #endif } #ifndef RT_OS_OS2 if (daemon_pipe_fds[1] >= 0) { printf ("\nStarting event loop....\n[send TERM signal to quit]\n"); /* now we're ready, signal the parent process */ write(daemon_pipe_fds[1], "READY", strlen("READY")); } else #endif { printf ("\nStarting event loop....\n[press Ctrl-C to quit]\n"); } if (pszPidFile) { char szBuf[32]; const char *lf = "\n"; RTFileOpen(&pidFile, pszPidFile, RTFILE_O_WRITE | RTFILE_O_CREATE_REPLACE); RTStrFormatNumber(szBuf, getpid(), 10, 0, 0, 0); RTFileWrite(pidFile, szBuf, strlen(szBuf), NULL); RTFileWrite(pidFile, lf, strlen(lf), NULL); RTFileClose(pidFile); } PLEvent *ev; while (gKeepRunning) { gEventQ->WaitForEvent (&ev); gEventQ->HandleEvent (ev); } gIpcServ->RemoveName (VBOXSVC_IPC_NAME); /* stop accepting new events */ gEventQ->StopAcceptingEvents(); /* process any remaining events */ gEventQ->ProcessPendingEvents(); printf ("Terminated event loop.\n"); } while (0); // this scopes the nsCOMPtrs NS_IF_RELEASE (gIpcServ); NS_IF_RELEASE (gEventQ); /* no nsCOMPtrs are allowed to be alive when you call com::Shutdown(). */ LogFlowFunc (("Calling com::Shutdown()...\n")); rc = com::Shutdown(); LogFlowFunc (("Finished com::Shutdown() (rc=%08X)\n", rc)); if (NS_FAILED (rc)) printf ("ERROR: Failed to shutdown XPCOM! (rc=%08X)\n", rc); printf ("XPCOM server has shutdown.\n"); if (pszPidFile) { RTFileDelete(pszPidFile); } #ifndef RT_OS_OS2 if (daemon_pipe_fds[1] >= 0) { /* close writing end of the pipe as well */ close(daemon_pipe_fds[1]); } #endif return 0; }