/* $Id: HGCMThread.cpp 47117 2013-07-12 12:48:17Z vboxsync $ */ /** @file * HGCMThread - Host-Guest Communication Manager Threads */ /* * Copyright (C) 2006-2011 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ #define LOG_GROUP_MAIN_OVERRIDE LOG_GROUP_HGCM #include "Logging.h" #include "HGCMThread.h" #include #include #include #include /* HGCM uses worker threads, which process messages from other threads. * A message consists of the message header and message specific data. * Message header is opaque for callers, but message data is defined * and used by them. * * Messages are distinguished by message identifier and worker thread * they are allocated for. * * Messages are allocated for a worker thread and belong to * the thread. A worker thread holds the queue of messages. * * The calling thread creates a message, specifying which worker thread * the message is created for, then, optionally, initializes message * specific data and, also optionally, references the message. * * Message then is posted or sent to worker thread by inserting * it to the worker thread message queue and referencing the message. * Worker thread then again may fetch next message. * * Upon processing the message the worker thread dereferences it. * Dereferencing also automatically deletes message from the thread * queue and frees memory allocated for the message, if no more * references left. If there are references, the message remains * in the queue. * */ /* Version of HGCM message header */ #define HGCMMSG_VERSION (1) /* Thread is initializing. */ #define HGCMMSG_TF_INITIALIZING (0x00000001) /* Thread must be terminated. */ #define HGCMMSG_TF_TERMINATE (0x00000002) /* Thread has been terminated. */ #define HGCMMSG_TF_TERMINATED (0x00000004) /** @todo consider use of RTReq */ static DECLCALLBACK(int) hgcmWorkerThreadFunc (RTTHREAD ThreadSelf, void *pvUser); class HGCMThread: public HGCMObject { private: friend DECLCALLBACK(int) hgcmWorkerThreadFunc (RTTHREAD ThreadSelf, void *pvUser); /* Worker thread function. */ PFNHGCMTHREAD m_pfnThread; /* A user supplied thread parameter. */ void *m_pvUser; /* The thread runtime handle. */ RTTHREAD m_thread; /* Event the thread waits for, signalled when a message * to process is posted to the thread. */ RTSEMEVENTMULTI m_eventThread; /* A caller thread waits for completion of a SENT message on this event. */ RTSEMEVENTMULTI m_eventSend; int32_t volatile m_i32MessagesProcessed; /* Critical section for accessing the thread data, mostly for message queues. */ RTCRITSECT m_critsect; /* thread state/operation flags */ uint32_t m_fu32ThreadFlags; /* Message queue variables. Messages are inserted at tail of message * queue. They are consumed by worker thread sequentially. If a message was * consumed, it is removed from message queue. */ /* Head of message queue. */ HGCMMsgCore *m_pMsgInputQueueHead; /* Message which another message will be inserted after. */ HGCMMsgCore *m_pMsgInputQueueTail; /* Head of messages being processed queue. */ HGCMMsgCore *m_pMsgInProcessHead; /* Message which another message will be inserted after. */ HGCMMsgCore *m_pMsgInProcessTail; /* Head of free message structures list. */ HGCMMsgCore *m_pFreeHead; /* Tail of free message structures list. */ HGCMMsgCore *m_pFreeTail; HGCMTHREADHANDLE m_handle; inline int Enter (void); inline void Leave (void); HGCMMsgCore *FetchFreeListHead (void); protected: virtual ~HGCMThread (void); public: HGCMThread (); int WaitForTermination (void); int Initialize (HGCMTHREADHANDLE handle, const char *pszThreadName, PFNHGCMTHREAD pfnThread, void *pvUser); int MsgAlloc (HGCMMSGHANDLE *pHandle, uint32_t u32MsgId, PFNHGCMNEWMSGALLOC pfnNewMessage); int MsgGet (HGCMMsgCore **ppMsg); int MsgPost (HGCMMsgCore *pMsg, PHGCMMSGCALLBACK pfnCallback, bool bWait); void MsgComplete (HGCMMsgCore *pMsg, int32_t result); }; /* * HGCMMsgCore implementation. */ #define HGCM_MSG_F_PROCESSED (0x00000001) #define HGCM_MSG_F_WAIT (0x00000002) #define HGCM_MSG_F_IN_PROCESS (0x00000004) void HGCMMsgCore::InitializeCore (uint32_t u32MsgId, HGCMTHREADHANDLE hThread) { m_u32Version = HGCMMSG_VERSION; m_u32Msg = u32MsgId; m_pfnCallback = NULL; m_pNext = NULL; m_pPrev = NULL; m_fu32Flags = 0; m_rcSend = VINF_SUCCESS; m_pThread = (HGCMThread *)hgcmObjReference (hThread, HGCMOBJ_THREAD); AssertRelease (m_pThread); } /* virtual */ HGCMMsgCore::~HGCMMsgCore () { if (m_pThread) { hgcmObjDereference (m_pThread); m_pThread = NULL; } } /* * HGCMThread implementation. */ static DECLCALLBACK(int) hgcmWorkerThreadFunc (RTTHREAD ThreadSelf, void *pvUser) { int rc = VINF_SUCCESS; HGCMThread *pThread = (HGCMThread *)pvUser; LogFlow(("MAIN::hgcmWorkerThreadFunc: starting HGCM thread %p\n", pThread)); AssertRelease(pThread); pThread->m_thread = ThreadSelf; pThread->m_fu32ThreadFlags &= ~HGCMMSG_TF_INITIALIZING; rc = RTThreadUserSignal (ThreadSelf); AssertRC(rc); pThread->m_pfnThread (pThread->Handle (), pThread->m_pvUser); pThread->m_fu32ThreadFlags |= HGCMMSG_TF_TERMINATED; pThread->m_thread = NIL_RTTHREAD; LogFlow(("MAIN::hgcmWorkerThreadFunc: completed HGCM thread %p\n", pThread)); return rc; } HGCMThread::HGCMThread () : HGCMObject(HGCMOBJ_THREAD), m_pfnThread (NULL), m_pvUser (NULL), m_thread (NIL_RTTHREAD), m_eventThread (0), m_eventSend (0), m_i32MessagesProcessed (0), m_fu32ThreadFlags (0), m_pMsgInputQueueHead (NULL), m_pMsgInputQueueTail (NULL), m_pMsgInProcessHead (NULL), m_pMsgInProcessTail (NULL), m_pFreeHead (NULL), m_pFreeTail (NULL), m_handle (0) { RT_ZERO(m_critsect); } HGCMThread::~HGCMThread () { /* * Free resources allocated for the thread. */ Assert(m_fu32ThreadFlags & HGCMMSG_TF_TERMINATED); if (RTCritSectIsInitialized (&m_critsect)) { RTCritSectDelete (&m_critsect); } if (m_eventSend) { RTSemEventMultiDestroy (m_eventSend); } if (m_eventThread) { RTSemEventMultiDestroy (m_eventThread); } return; } int HGCMThread::WaitForTermination (void) { int rc = VINF_SUCCESS; LogFlowFunc(("\n")); if (m_thread != NIL_RTTHREAD) { rc = RTThreadWait (m_thread, 5000, NULL); } LogFlowFunc(("rc = %Rrc\n", rc)); return rc; } int HGCMThread::Initialize (HGCMTHREADHANDLE handle, const char *pszThreadName, PFNHGCMTHREAD pfnThread, void *pvUser) { int rc = VINF_SUCCESS; rc = RTSemEventMultiCreate (&m_eventThread); if (RT_SUCCESS(rc)) { rc = RTSemEventMultiCreate (&m_eventSend); if (RT_SUCCESS(rc)) { rc = RTCritSectInit (&m_critsect); if (RT_SUCCESS(rc)) { m_pfnThread = pfnThread; m_pvUser = pvUser; m_handle = handle; m_fu32ThreadFlags = HGCMMSG_TF_INITIALIZING; RTTHREAD thread; rc = RTThreadCreate (&thread, hgcmWorkerThreadFunc, this, 0, /* default stack size; some service may need quite a bit */ RTTHREADTYPE_IO, RTTHREADFLAGS_WAITABLE, pszThreadName); if (RT_SUCCESS(rc)) { /* Wait until the thread is ready. */ rc = RTThreadUserWait (thread, 30000); AssertRC(rc); Assert(!(m_fu32ThreadFlags & HGCMMSG_TF_INITIALIZING) || RT_FAILURE(rc)); } else { m_thread = NIL_RTTHREAD; Log(("hgcmThreadCreate: FAILURE: Can't start worker thread.\n")); } } else { Log(("hgcmThreadCreate: FAILURE: Can't init a critical section for a hgcm worker thread.\n")); RT_ZERO(m_critsect); } } else { Log(("hgcmThreadCreate: FAILURE: Can't create an event semaphore for a sent messages.\n")); m_eventSend = 0; } } else { Log(("hgcmThreadCreate: FAILURE: Can't create an event semaphore for a hgcm worker thread.\n")); m_eventThread = 0; } return rc; } inline int HGCMThread::Enter (void) { int rc = RTCritSectEnter (&m_critsect); #ifdef LOG_ENABLED if (RT_FAILURE(rc)) { Log(("HGCMThread::MsgPost: FAILURE: could not obtain worker thread mutex, rc = %Rrc!!!\n", rc)); } #endif /* LOG_ENABLED */ return rc; } inline void HGCMThread::Leave (void) { RTCritSectLeave (&m_critsect); } int HGCMThread::MsgAlloc (HGCMMSGHANDLE *pHandle, uint32_t u32MsgId, PFNHGCMNEWMSGALLOC pfnNewMessage) { int rc = VINF_SUCCESS; HGCMMsgCore *pmsg = NULL; bool fFromFreeList = false; if (!pmsg && RT_SUCCESS(rc)) { /* We have to allocate a new memory block. */ pmsg = pfnNewMessage (u32MsgId); if (pmsg == NULL) { rc = VERR_NO_MEMORY; } } if (RT_SUCCESS(rc)) { /* Initialize just allocated message core */ pmsg->InitializeCore (u32MsgId, m_handle); /* and the message specific data. */ pmsg->Initialize (); LogFlow(("MAIN::hgcmMsgAlloc: allocated message %p\n", pmsg)); /** Get handle of the message. The message will be also referenced * until the handle is deleted. */ *pHandle = hgcmObjGenerateHandle (pmsg); if (fFromFreeList) { /* Message was referenced in the free list, now dereference it. */ pmsg->Dereference (); } } return rc; } int HGCMThread::MsgPost (HGCMMsgCore *pMsg, PHGCMMSGCALLBACK pfnCallback, bool fWait) { int rc = VINF_SUCCESS; LogFlow(("HGCMThread::MsgPost: thread = %p, pMsg = %p, pfnCallback = %p\n", this, pMsg, pfnCallback)); rc = Enter (); if (RT_SUCCESS(rc)) { pMsg->m_pfnCallback = pfnCallback; if (fWait) { pMsg->m_fu32Flags |= HGCM_MSG_F_WAIT; } /* Insert the message to the queue tail. */ pMsg->m_pNext = NULL; pMsg->m_pPrev = m_pMsgInputQueueTail; if (m_pMsgInputQueueTail) { m_pMsgInputQueueTail->m_pNext = pMsg; } else { m_pMsgInputQueueHead = pMsg; } m_pMsgInputQueueTail = pMsg; Leave (); LogFlow(("HGCMThread::MsgPost: going to inform the thread %p about message, fWait = %d\n", this, fWait)); /* Inform the worker thread that there is a message. */ RTSemEventMultiSignal (m_eventThread); LogFlow(("HGCMThread::MsgPost: event signalled\n")); if (fWait) { /* Immediately check if the message has been processed. */ while ((pMsg->m_fu32Flags & HGCM_MSG_F_PROCESSED) == 0) { /* Poll infrequently to make sure no completed message has been missed. */ RTSemEventMultiWait (m_eventSend, 1000); LogFlow(("HGCMThread::MsgPost: wait completed flags = %08X\n", pMsg->m_fu32Flags)); if ((pMsg->m_fu32Flags & HGCM_MSG_F_PROCESSED) == 0) { RTThreadYield(); } } /* 'Our' message has been processed, so should reset the semaphore. * There is still possible that another message has been processed * and the semaphore has been signalled again. * Reset only if there are no other messages completed. */ int32_t c = ASMAtomicDecS32(&m_i32MessagesProcessed); Assert(c >= 0); if (c == 0) { RTSemEventMultiReset (m_eventSend); } rc = pMsg->m_rcSend; } } LogFlow(("HGCMThread::MsgPost: rc = %Rrc\n", rc)); return rc; } int HGCMThread::MsgGet (HGCMMsgCore **ppMsg) { int rc = VINF_SUCCESS; LogFlow(("HGCMThread::MsgGet: thread = %p, ppMsg = %p\n", this, ppMsg)); for (;;) { if (m_fu32ThreadFlags & HGCMMSG_TF_TERMINATE) { rc = VERR_INTERRUPTED; break; } LogFlow(("MAIN::hgcmMsgGet: m_pMsgInputQueueHead = %p\n", m_pMsgInputQueueHead)); if (m_pMsgInputQueueHead) { /* Move the message to the m_pMsgInProcessHead list */ rc = Enter (); if (RT_FAILURE(rc)) { break; } HGCMMsgCore *pMsg = m_pMsgInputQueueHead; /* Remove the message from the head of Queue list. */ Assert(m_pMsgInputQueueHead->m_pPrev == NULL); if (m_pMsgInputQueueHead->m_pNext) { m_pMsgInputQueueHead = m_pMsgInputQueueHead->m_pNext; m_pMsgInputQueueHead->m_pPrev = NULL; } else { Assert(m_pMsgInputQueueHead == m_pMsgInputQueueTail); m_pMsgInputQueueHead = NULL; m_pMsgInputQueueTail = NULL; } /* Insert the message to the tail of the m_pMsgInProcessHead list. */ pMsg->m_pNext = NULL; pMsg->m_pPrev = m_pMsgInProcessTail; if (m_pMsgInProcessTail) { m_pMsgInProcessTail->m_pNext = pMsg; } else { m_pMsgInProcessHead = pMsg; } m_pMsgInProcessTail = pMsg; pMsg->m_fu32Flags |= HGCM_MSG_F_IN_PROCESS; Leave (); /* Return the message to the caller. */ *ppMsg = pMsg; LogFlow(("MAIN::hgcmMsgGet: got message %p\n", *ppMsg)); break; } /* Wait for an event. */ RTSemEventMultiWait (m_eventThread, RT_INDEFINITE_WAIT); RTSemEventMultiReset (m_eventThread); } LogFlow(("HGCMThread::MsgGet: *ppMsg = %p, return rc = %Rrc\n", *ppMsg, rc)); return rc; } void HGCMThread::MsgComplete (HGCMMsgCore *pMsg, int32_t result) { LogFlow(("HGCMThread::MsgComplete: thread = %p, pMsg = %p\n", this, pMsg)); int rc = VINF_SUCCESS; AssertRelease(pMsg->m_pThread == this); AssertReleaseMsg((pMsg->m_fu32Flags & HGCM_MSG_F_IN_PROCESS) != 0, ("%p %x\n", pMsg, pMsg->m_fu32Flags)); if (pMsg->m_pfnCallback) { /** @todo call callback with error code in MsgPost in case of errors */ pMsg->m_pfnCallback (result, pMsg); LogFlow(("HGCMThread::MsgComplete: callback executed. pMsg = %p, thread = %p\n", pMsg, this)); } /* Message processing has been completed. */ rc = Enter (); if (RT_SUCCESS(rc)) { /* Remove the message from the InProcess queue. */ if (pMsg->m_pNext) { pMsg->m_pNext->m_pPrev = pMsg->m_pPrev; } else { m_pMsgInProcessTail = pMsg->m_pPrev; } if (pMsg->m_pPrev) { pMsg->m_pPrev->m_pNext = pMsg->m_pNext; } else { m_pMsgInProcessHead = pMsg->m_pNext; } pMsg->m_pNext = NULL; pMsg->m_pPrev = NULL; bool fWaited = ((pMsg->m_fu32Flags & HGCM_MSG_F_WAIT) != 0); if (fWaited) { ASMAtomicIncS32(&m_i32MessagesProcessed); /* This should be done before setting the HGCM_MSG_F_PROCESSED flag. */ pMsg->m_rcSend = result; } /* The message is now completed. */ pMsg->m_fu32Flags &= ~HGCM_MSG_F_IN_PROCESS; pMsg->m_fu32Flags &= ~HGCM_MSG_F_WAIT; pMsg->m_fu32Flags |= HGCM_MSG_F_PROCESSED; hgcmObjDeleteHandle (pMsg->Handle ()); Leave (); if (fWaited) { /* Wake up all waiters. so they can decide if their message has been processed. */ RTSemEventMultiSignal (m_eventSend); } } return; } /* * Thread API. Public interface. */ int hgcmThreadCreate (HGCMTHREADHANDLE *pHandle, const char *pszThreadName, PFNHGCMTHREAD pfnThread, void *pvUser) { int rc = VINF_SUCCESS; LogFlow(("MAIN::hgcmThreadCreate\n")); HGCMTHREADHANDLE handle = 0; /* Allocate memory for a new thread object. */ HGCMThread *pThread = new HGCMThread (); if (pThread) { /* Put just created object to pool and obtain handle for it. */ handle = hgcmObjGenerateHandle (pThread); /* Initialize the object. */ rc = pThread->Initialize (handle, pszThreadName, pfnThread, pvUser); } else { Log(("hgcmThreadCreate: FAILURE: Can't allocate memory for a hgcm worker thread.\n")); rc = VERR_NO_MEMORY; } if (RT_SUCCESS(rc)) { *pHandle = handle; } else { Log(("hgcmThreadCreate: FAILURE: rc = %Rrc.\n", rc)); if (handle != 0) { /* Delete allocated handle, this will also free the object memory. */ hgcmObjDeleteHandle (handle); } } LogFlow(("MAIN::hgcmThreadCreate: rc = %Rrc\n", rc)); return rc; } int hgcmThreadWait (HGCMTHREADHANDLE hThread) { int rc = VERR_INVALID_HANDLE; LogFlowFunc(("0x%08X\n", hThread)); HGCMThread *pThread = (HGCMThread *)hgcmObjReference (hThread, HGCMOBJ_THREAD); if (pThread) { rc = pThread->WaitForTermination (); hgcmObjDereference (pThread); } hgcmObjDeleteHandle (hThread); LogFlowFunc(("rc = %Rrc\n", rc)); return rc; } int hgcmMsgAlloc (HGCMTHREADHANDLE hThread, HGCMMSGHANDLE *pHandle, uint32_t u32MsgId, PFNHGCMNEWMSGALLOC pfnNewMessage) { LogFlow(("hgcmMsgAlloc: thread handle = 0x%08X, pHandle = %p, sizeof (HGCMMsgCore) = %d\n", hThread, pHandle, sizeof (HGCMMsgCore))); if (!pHandle) { return VERR_INVALID_PARAMETER; } int rc = VINF_SUCCESS; HGCMThread *pThread = (HGCMThread *)hgcmObjReference (hThread, HGCMOBJ_THREAD); if (!pThread) { rc = VERR_INVALID_HANDLE; } else { rc = pThread->MsgAlloc (pHandle, u32MsgId, pfnNewMessage); hgcmObjDereference (pThread); } LogFlow(("MAIN::hgcmMsgAlloc: handle 0x%08X, rc = %Rrc\n", *pHandle, rc)); return rc; } static int hgcmMsgPostInternal (HGCMMSGHANDLE hMsg, PHGCMMSGCALLBACK pfnCallback, bool fWait) { LogFlow(("MAIN::hgcmMsgPostInternal: hMsg = 0x%08X, pfnCallback = %p, fWait = %d\n", hMsg, pfnCallback, fWait)); int rc = VINF_SUCCESS; HGCMMsgCore *pMsg = (HGCMMsgCore *)hgcmObjReference (hMsg, HGCMOBJ_MSG); if (!pMsg) { rc = VERR_INVALID_HANDLE; } else { rc = pMsg->Thread()->MsgPost (pMsg, pfnCallback, fWait); hgcmObjDereference (pMsg); } LogFlow(("MAIN::hgcmMsgPostInternal: hMsg 0x%08X, rc = %Rrc\n", hMsg, rc)); return rc; } /* Post message to worker thread with a flag indication if this is a Send or Post. * * @thread any */ int hgcmMsgPost (HGCMMSGHANDLE hMsg, PHGCMMSGCALLBACK pfnCallback) { int rc = hgcmMsgPostInternal (hMsg, pfnCallback, false); if (RT_SUCCESS(rc)) { rc = VINF_HGCM_ASYNC_EXECUTE; } return rc; } /* Send message to worker thread. Sending thread will block until message is processed. * * @thread any */ int hgcmMsgSend (HGCMMSGHANDLE hMsg) { return hgcmMsgPostInternal (hMsg, NULL, true); } int hgcmMsgGet (HGCMTHREADHANDLE hThread, HGCMMsgCore **ppMsg) { LogFlow(("MAIN::hgcmMsgGet: hThread = 0x%08X, ppMsg = %p\n", hThread, ppMsg)); if (!hThread || !ppMsg) { return VERR_INVALID_PARAMETER; } int rc = VINF_SUCCESS; HGCMThread *pThread = (HGCMThread *)hgcmObjReference (hThread, HGCMOBJ_THREAD); if (!pThread) { rc = VERR_INVALID_HANDLE; } else { rc = pThread->MsgGet (ppMsg); hgcmObjDereference (pThread); } LogFlow(("MAIN::hgcmMsgGet: *ppMsg = %p, rc = %Rrc\n", *ppMsg, rc)); return rc; } void hgcmMsgComplete (HGCMMsgCore *pMsg, int32_t u32Result) { LogFlow(("MAIN::hgcmMsgComplete: pMsg = %p\n", pMsg)); if (!pMsg) { return; } pMsg->Thread()->MsgComplete (pMsg, u32Result); LogFlow(("MAIN::hgcmMsgComplete: pMsg = %p, rc = void\n", pMsg)); return; } int hgcmThreadInit (void) { int rc = VINF_SUCCESS; LogFlow(("MAIN::hgcmThreadInit\n")); /** @todo error processing. */ rc = hgcmObjInit (); LogFlow(("MAIN::hgcmThreadInit: rc = %Rrc\n", rc)); return rc; } void hgcmThreadUninit (void) { hgcmObjUninit (); }