/* $Id: GuestProcessImpl.cpp 65120 2017-01-04 17:10:35Z vboxsync $ */ /** @file * VirtualBox Main - Guest process handling. */ /* * Copyright (C) 2012-2016 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. */ /** * Locking rules: * - When the main dispatcher (callbackDispatcher) is called it takes the * WriteLock while dispatching to the various on* methods. * - All other outer functions (accessible by Main) must not own a lock * while waiting for a callback or for an event. * - Only keep Read/WriteLocks as short as possible and only when necessary. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #ifndef VBOX_WITH_GUEST_CONTROL # error "VBOX_WITH_GUEST_CONTROL must defined in this file" #endif #include "GuestProcessImpl.h" #include "GuestSessionImpl.h" #include "GuestCtrlImplPrivate.h" #include "ConsoleImpl.h" #include "VirtualBoxErrorInfoImpl.h" #include "Global.h" #include "AutoCaller.h" #include "VBoxEvents.h" #include "ThreadTask.h" #include /* For auto_ptr. */ #include #include /* For unconst(). */ #include #include #include #ifdef LOG_GROUP #undef LOG_GROUP #endif #define LOG_GROUP LOG_GROUP_GUEST_CONTROL #include class GuestProcessTask : public ThreadTask { public: GuestProcessTask(GuestProcess *pProcess) : ThreadTask("GenericGuestProcessTask") , mProcess(pProcess) , mRC(VINF_SUCCESS) { } virtual ~GuestProcessTask(void) { } int i_rc(void) const { return mRC; } bool i_isOk(void) const { return RT_SUCCESS(mRC); } const ComObjPtr &i_process(void) const { return mProcess; } protected: const ComObjPtr mProcess; int mRC; }; class GuestProcessStartTask : public GuestProcessTask { public: GuestProcessStartTask(GuestProcess *pProcess) : GuestProcessTask(pProcess) { m_strTaskName = "gctlPrcStart"; } void handler() { GuestProcess::i_startProcessThreadTask(this); } }; /** * Internal listener class to serve events in an * active manner, e.g. without polling delays. */ class GuestProcessListener { public: GuestProcessListener(void) { } virtual ~GuestProcessListener(void) { } HRESULT init(GuestProcess *pProcess) { AssertPtrReturn(pProcess, E_POINTER); mProcess = pProcess; return S_OK; } void uninit(void) { mProcess = NULL; } STDMETHOD(HandleEvent)(VBoxEventType_T aType, IEvent *aEvent) { switch (aType) { case VBoxEventType_OnGuestProcessStateChanged: case VBoxEventType_OnGuestProcessInputNotify: case VBoxEventType_OnGuestProcessOutput: { AssertPtrReturn(mProcess, E_POINTER); int rc2 = mProcess->signalWaitEvent(aType, aEvent); RT_NOREF(rc2); #ifdef LOG_ENABLED LogFlowThisFunc(("Signalling events of type=%RU32, pProcess=%p resulted in rc=%Rrc\n", aType, &mProcess, rc2)); #endif break; } default: AssertMsgFailed(("Unhandled event %RU32\n", aType)); break; } return S_OK; } private: GuestProcess *mProcess; }; typedef ListenerImpl GuestProcessListenerImpl; VBOX_LISTENER_DECLARE(GuestProcessListenerImpl) // constructor / destructor ///////////////////////////////////////////////////////////////////////////// DEFINE_EMPTY_CTOR_DTOR(GuestProcess) HRESULT GuestProcess::FinalConstruct(void) { LogFlowThisFuncEnter(); return BaseFinalConstruct(); } void GuestProcess::FinalRelease(void) { LogFlowThisFuncEnter(); uninit(); BaseFinalRelease(); LogFlowThisFuncLeave(); } // public initializer/uninitializer for internal purposes only ///////////////////////////////////////////////////////////////////////////// int GuestProcess::init(Console *aConsole, GuestSession *aSession, ULONG aProcessID, const GuestProcessStartupInfo &aProcInfo, const GuestEnvironment *pBaseEnv) { LogFlowThisFunc(("aConsole=%p, aSession=%p, aProcessID=%RU32 pBaseEnv=%p\n", aConsole, aSession, aProcessID, pBaseEnv)); AssertPtrReturn(aConsole, VERR_INVALID_POINTER); AssertPtrReturn(aSession, VERR_INVALID_POINTER); /* Enclose the state transition NotReady->InInit->Ready. */ AutoInitSpan autoInitSpan(this); AssertReturn(autoInitSpan.isOk(), VERR_OBJECT_DESTROYED); HRESULT hr; int vrc = bindToSession(aConsole, aSession, aProcessID /* Object ID */); if (RT_SUCCESS(vrc)) { hr = unconst(mEventSource).createObject(); if (FAILED(hr)) vrc = VERR_NO_MEMORY; else { hr = mEventSource->init(); if (FAILED(hr)) vrc = VERR_COM_UNEXPECTED; } } if (RT_SUCCESS(vrc)) { try { GuestProcessListener *pListener = new GuestProcessListener(); ComObjPtr thisListener; hr = thisListener.createObject(); if (SUCCEEDED(hr)) hr = thisListener->init(pListener, this); if (SUCCEEDED(hr)) { com::SafeArray eventTypes; eventTypes.push_back(VBoxEventType_OnGuestProcessStateChanged); eventTypes.push_back(VBoxEventType_OnGuestProcessInputNotify); eventTypes.push_back(VBoxEventType_OnGuestProcessOutput); hr = mEventSource->RegisterListener(thisListener, ComSafeArrayAsInParam(eventTypes), TRUE /* Active listener */); if (SUCCEEDED(hr)) { vrc = baseInit(); if (RT_SUCCESS(vrc)) { mLocalListener = thisListener; } } else vrc = VERR_COM_UNEXPECTED; } else vrc = VERR_COM_UNEXPECTED; } catch(std::bad_alloc &) { vrc = VERR_NO_MEMORY; } } if (RT_SUCCESS(vrc)) { mData.mProcess = aProcInfo; mData.mpSessionBaseEnv = pBaseEnv; if (pBaseEnv) pBaseEnv->retainConst(); mData.mExitCode = 0; mData.mPID = 0; mData.mLastError = VINF_SUCCESS; mData.mStatus = ProcessStatus_Undefined; /* Everything else will be set by the actual starting routine. */ /* Confirm a successful initialization when it's the case. */ autoInitSpan.setSucceeded(); return vrc; } autoInitSpan.setFailed(); return vrc; } /** * Uninitializes the instance. * Called from FinalRelease() or IGuestSession::uninit(). */ void GuestProcess::uninit(void) { /* Enclose the state transition Ready->InUninit->NotReady. */ AutoUninitSpan autoUninitSpan(this); if (autoUninitSpan.uninitDone()) return; LogFlowThisFunc(("mExe=%s, PID=%RU32\n", mData.mProcess.mExecutable.c_str(), mData.mPID)); /* Terminate process if not already done yet. */ int guestRc = VINF_SUCCESS; int vrc = i_terminateProcess(30 * 1000, &guestRc); /** @todo Make timeouts configurable. */ /* Note: Don't return here yet; first uninit all other stuff in * case of failure. */ if (mData.mpSessionBaseEnv) { mData.mpSessionBaseEnv->releaseConst(); mData.mpSessionBaseEnv = NULL; } baseUninit(); LogFlowThisFunc(("Returning rc=%Rrc, guestRc=%Rrc\n", vrc, guestRc)); RT_NOREF_PV(vrc); } // implementation of public getters/setters for attributes ///////////////////////////////////////////////////////////////////////////// HRESULT GuestProcess::getArguments(std::vector &aArguments) { LogFlowThisFuncEnter(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aArguments = mData.mProcess.mArguments; return S_OK; } HRESULT GuestProcess::getEnvironment(std::vector &aEnvironment) { #ifndef VBOX_WITH_GUEST_CONTROL ReturnComNotImplemented(); #else AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); /* (Paranoia since both environment objects are immutable.) */ HRESULT hrc; if (mData.mpSessionBaseEnv) { int vrc; if (mData.mProcess.mEnvironmentChanges.count() == 0) vrc = mData.mpSessionBaseEnv->queryPutEnvArray(&aEnvironment); else { GuestEnvironment TmpEnv; vrc = TmpEnv.copy(*mData.mpSessionBaseEnv); if (RT_SUCCESS(vrc)) { vrc = TmpEnv.applyChanges(mData.mProcess.mEnvironmentChanges); if (RT_SUCCESS(vrc)) vrc = TmpEnv.queryPutEnvArray(&aEnvironment); } } hrc = Global::vboxStatusCodeToCOM(vrc); } else hrc = setError(VBOX_E_NOT_SUPPORTED, tr("The base environment feature is not supported by the guest additions")); LogFlowThisFuncLeave(); return hrc; #endif } HRESULT GuestProcess::getEventSource(ComPtr &aEventSource) { LogFlowThisFuncEnter(); // no need to lock - lifetime constant mEventSource.queryInterfaceTo(aEventSource.asOutParam()); LogFlowThisFuncLeave(); return S_OK; } HRESULT GuestProcess::getExecutablePath(com::Utf8Str &aExecutablePath) { LogFlowThisFuncEnter(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aExecutablePath = mData.mProcess.mExecutable; return S_OK; } HRESULT GuestProcess::getExitCode(LONG *aExitCode) { LogFlowThisFuncEnter(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aExitCode = mData.mExitCode; return S_OK; } HRESULT GuestProcess::getName(com::Utf8Str &aName) { LogFlowThisFuncEnter(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); aName = mData.mProcess.mName; return S_OK; } HRESULT GuestProcess::getPID(ULONG *aPID) { LogFlowThisFuncEnter(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aPID = mData.mPID; return S_OK; } HRESULT GuestProcess::getStatus(ProcessStatus_T *aStatus) { LogFlowThisFuncEnter(); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); *aStatus = mData.mStatus; return S_OK; } // private methods ///////////////////////////////////////////////////////////////////////////// int GuestProcess::i_callbackDispatcher(PVBOXGUESTCTRLHOSTCBCTX pCbCtx, PVBOXGUESTCTRLHOSTCALLBACK pSvcCb) { AssertPtrReturn(pCbCtx, VERR_INVALID_POINTER); AssertPtrReturn(pSvcCb, VERR_INVALID_POINTER); #ifdef DEBUG LogFlowThisFunc(("uPID=%RU32, uContextID=%RU32, uFunction=%RU32, pSvcCb=%p\n", mData.mPID, pCbCtx->uContextID, pCbCtx->uFunction, pSvcCb)); #endif int vrc; switch (pCbCtx->uFunction) { case GUEST_DISCONNECTED: { vrc = i_onGuestDisconnected(pCbCtx, pSvcCb); break; } case GUEST_EXEC_STATUS: { vrc = i_onProcessStatusChange(pCbCtx, pSvcCb); break; } case GUEST_EXEC_OUTPUT: { vrc = i_onProcessOutput(pCbCtx, pSvcCb); break; } case GUEST_EXEC_INPUT_STATUS: { vrc = i_onProcessInputStatus(pCbCtx, pSvcCb); break; } default: /* Silently ignore not implemented functions. */ vrc = VERR_NOT_SUPPORTED; break; } #ifdef DEBUG LogFlowFuncLeaveRC(vrc); #endif return vrc; } /** * Checks if the current assigned PID matches another PID (from a callback). * * In protocol v1 we don't have the possibility to terminate/kill * processes so it can happen that a formerly started process A * (which has the context ID 0 (session=0, process=0, count=0) will * send a delayed message to the host if this process has already * been discarded there and the same context ID was reused by * a process B. Process B in turn then has a different guest PID. * * Note: This also can happen when restoring from a saved state which * had a guest process running. * * @return IPRT status code. * @param uPID PID to check. */ inline int GuestProcess::i_checkPID(uint32_t uPID) { int rc = VINF_SUCCESS; /* Was there a PID assigned yet? */ if (mData.mPID) { if (RT_UNLIKELY(mData.mPID != uPID)) { LogFlowFunc(("Stale guest process (PID=%RU32) sent data to a newly started process (pProcesS=%p, PID=%RU32, status=%RU32)\n", uPID, this, mData.mPID, mData.mStatus)); rc = VERR_NOT_FOUND; } } return rc; } /* static */ Utf8Str GuestProcess::i_guestErrorToString(int guestRc) { Utf8Str strError; /** @todo pData->u32Flags: int vs. uint32 -- IPRT errors are *negative* !!! */ switch (guestRc) { case VERR_FILE_NOT_FOUND: /* This is the most likely error. */ strError += Utf8StrFmt(tr("The specified file was not found on guest")); break; case VERR_INVALID_VM_HANDLE: strError += Utf8StrFmt(tr("VMM device is not available (is the VM running?)")); break; case VERR_HGCM_SERVICE_NOT_FOUND: strError += Utf8StrFmt(tr("The guest execution service is not available")); break; case VERR_PATH_NOT_FOUND: strError += Utf8StrFmt(tr("Could not resolve path to specified file was not found on guest")); break; case VERR_BAD_EXE_FORMAT: strError += Utf8StrFmt(tr("The specified file is not an executable format on guest")); break; case VERR_AUTHENTICATION_FAILURE: strError += Utf8StrFmt(tr("The specified user was not able to logon on guest")); break; case VERR_INVALID_NAME: strError += Utf8StrFmt(tr("The specified file is an invalid name")); break; case VERR_TIMEOUT: strError += Utf8StrFmt(tr("The guest did not respond within time")); break; case VERR_CANCELLED: strError += Utf8StrFmt(tr("The execution operation was canceled")); break; case VERR_PERMISSION_DENIED: /** @todo r=bird: This is probably completely and utterly misleading. VERR_AUTHENTICATION_FAILURE could have this message. */ strError += Utf8StrFmt(tr("Invalid user/password credentials")); break; case VERR_MAX_PROCS_REACHED: strError += Utf8StrFmt(tr("Maximum number of concurrent guest processes has been reached")); break; case VERR_NOT_FOUND: strError += Utf8StrFmt(tr("The guest execution service is not ready (yet)")); break; default: strError += Utf8StrFmt("%Rrc", guestRc); break; } return strError; } /** * Returns @c true if the passed in error code indicates an error which came * from the guest side, or @c false if not. * * @return bool @c true if the passed in error code indicates an error which came * from the guest side, or @c false if not. * @param rc Error code to check. */ /* static */ bool GuestProcess::i_isGuestError(int rc) { return ( rc == VERR_GSTCTL_GUEST_ERROR || rc == VWRN_GSTCTL_PROCESS_EXIT_CODE); } inline bool GuestProcess::i_isAlive(void) { return ( mData.mStatus == ProcessStatus_Started || mData.mStatus == ProcessStatus_Paused || mData.mStatus == ProcessStatus_Terminating); } inline bool GuestProcess::i_hasEnded(void) { return ( mData.mStatus == ProcessStatus_TerminatedNormally || mData.mStatus == ProcessStatus_TerminatedSignal || mData.mStatus == ProcessStatus_TerminatedAbnormally || mData.mStatus == ProcessStatus_TimedOutKilled || mData.mStatus == ProcessStatus_TimedOutAbnormally || mData.mStatus == ProcessStatus_Down || mData.mStatus == ProcessStatus_Error); } int GuestProcess::i_onGuestDisconnected(PVBOXGUESTCTRLHOSTCBCTX pCbCtx, PVBOXGUESTCTRLHOSTCALLBACK pSvcCbData) { AssertPtrReturn(pCbCtx, VERR_INVALID_POINTER); AssertPtrReturn(pSvcCbData, VERR_INVALID_POINTER); int vrc = i_setProcessStatus(ProcessStatus_Down, VINF_SUCCESS); LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcess::i_onProcessInputStatus(PVBOXGUESTCTRLHOSTCBCTX pCbCtx, PVBOXGUESTCTRLHOSTCALLBACK pSvcCbData) { AssertPtrReturn(pCbCtx, VERR_INVALID_POINTER); AssertPtrReturn(pSvcCbData, VERR_INVALID_POINTER); /* pCallback is optional. */ if (pSvcCbData->mParms < 5) return VERR_INVALID_PARAMETER; CALLBACKDATA_PROC_INPUT dataCb; /* pSvcCb->mpaParms[0] always contains the context ID. */ int vrc = pSvcCbData->mpaParms[1].getUInt32(&dataCb.uPID); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[2].getUInt32(&dataCb.uStatus); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[3].getUInt32(&dataCb.uFlags); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[4].getUInt32(&dataCb.uProcessed); AssertRCReturn(vrc, vrc); LogFlowThisFunc(("uPID=%RU32, uStatus=%RU32, uFlags=%RI32, cbProcessed=%RU32\n", dataCb.uPID, dataCb.uStatus, dataCb.uFlags, dataCb.uProcessed)); vrc = i_checkPID(dataCb.uPID); if (RT_SUCCESS(vrc)) { ProcessInputStatus_T inputStatus = ProcessInputStatus_Undefined; switch (dataCb.uStatus) { case INPUT_STS_WRITTEN: inputStatus = ProcessInputStatus_Written; break; case INPUT_STS_ERROR: inputStatus = ProcessInputStatus_Broken; break; case INPUT_STS_TERMINATED: inputStatus = ProcessInputStatus_Broken; break; case INPUT_STS_OVERFLOW: inputStatus = ProcessInputStatus_Overflow; break; case INPUT_STS_UNDEFINED: /* Fall through is intentional. */ default: AssertMsg(!dataCb.uProcessed, ("Processed data is not 0 in undefined input state\n")); break; } if (inputStatus != ProcessInputStatus_Undefined) { AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); /* Copy over necessary data before releasing lock again. */ uint32_t uPID = mData.mPID; /** @todo Also handle mSession? */ alock.release(); /* Release lock before firing off event. */ fireGuestProcessInputNotifyEvent(mEventSource, mSession, this, uPID, 0 /* StdIn */, dataCb.uProcessed, inputStatus); } } LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcess::i_onProcessNotifyIO(PVBOXGUESTCTRLHOSTCBCTX pCbCtx, PVBOXGUESTCTRLHOSTCALLBACK pSvcCbData) { AssertPtrReturn(pCbCtx, VERR_INVALID_POINTER); AssertPtrReturn(pSvcCbData, VERR_INVALID_POINTER); return VERR_NOT_IMPLEMENTED; } int GuestProcess::i_onProcessStatusChange(PVBOXGUESTCTRLHOSTCBCTX pCbCtx, PVBOXGUESTCTRLHOSTCALLBACK pSvcCbData) { AssertPtrReturn(pCbCtx, VERR_INVALID_POINTER); AssertPtrReturn(pSvcCbData, VERR_INVALID_POINTER); if (pSvcCbData->mParms < 5) return VERR_INVALID_PARAMETER; CALLBACKDATA_PROC_STATUS dataCb; /* pSvcCb->mpaParms[0] always contains the context ID. */ int vrc = pSvcCbData->mpaParms[1].getUInt32(&dataCb.uPID); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[2].getUInt32(&dataCb.uStatus); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[3].getUInt32(&dataCb.uFlags); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[4].getPointer(&dataCb.pvData, &dataCb.cbData); AssertRCReturn(vrc, vrc); LogFlowThisFunc(("uPID=%RU32, uStatus=%RU32, uFlags=%RU32\n", dataCb.uPID, dataCb.uStatus, dataCb.uFlags)); vrc = i_checkPID(dataCb.uPID); if (RT_SUCCESS(vrc)) { ProcessStatus_T procStatus = ProcessStatus_Undefined; int procRc = VINF_SUCCESS; switch (dataCb.uStatus) { case PROC_STS_STARTED: { procStatus = ProcessStatus_Started; AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); mData.mPID = dataCb.uPID; /* Set the process PID. */ break; } case PROC_STS_TEN: { procStatus = ProcessStatus_TerminatedNormally; AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); mData.mExitCode = dataCb.uFlags; /* Contains the exit code. */ break; } case PROC_STS_TES: { procStatus = ProcessStatus_TerminatedSignal; AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); mData.mExitCode = dataCb.uFlags; /* Contains the signal. */ break; } case PROC_STS_TEA: { procStatus = ProcessStatus_TerminatedAbnormally; break; } case PROC_STS_TOK: { procStatus = ProcessStatus_TimedOutKilled; break; } case PROC_STS_TOA: { procStatus = ProcessStatus_TimedOutAbnormally; break; } case PROC_STS_DWN: { procStatus = ProcessStatus_Down; break; } case PROC_STS_ERROR: { procRc = dataCb.uFlags; /* mFlags contains the IPRT error sent from the guest. */ procStatus = ProcessStatus_Error; break; } case PROC_STS_UNDEFINED: default: { /* Silently skip this request. */ procStatus = ProcessStatus_Undefined; break; } } LogFlowThisFunc(("Got rc=%Rrc, procSts=%RU32, procRc=%Rrc\n", vrc, procStatus, procRc)); /* Set the process status. */ int rc2 = i_setProcessStatus(procStatus, procRc); if (RT_SUCCESS(vrc)) vrc = rc2; } LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcess::i_onProcessOutput(PVBOXGUESTCTRLHOSTCBCTX pCbCtx, PVBOXGUESTCTRLHOSTCALLBACK pSvcCbData) { RT_NOREF(pCbCtx); AssertPtrReturn(pSvcCbData, VERR_INVALID_POINTER); if (pSvcCbData->mParms < 5) return VERR_INVALID_PARAMETER; CALLBACKDATA_PROC_OUTPUT dataCb; /* pSvcCb->mpaParms[0] always contains the context ID. */ int vrc = pSvcCbData->mpaParms[1].getUInt32(&dataCb.uPID); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[2].getUInt32(&dataCb.uHandle); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[3].getUInt32(&dataCb.uFlags); AssertRCReturn(vrc, vrc); vrc = pSvcCbData->mpaParms[4].getPointer(&dataCb.pvData, &dataCb.cbData); AssertRCReturn(vrc, vrc); LogFlowThisFunc(("uPID=%RU32, uHandle=%RU32, uFlags=%RI32, pvData=%p, cbData=%RU32\n", dataCb.uPID, dataCb.uHandle, dataCb.uFlags, dataCb.pvData, dataCb.cbData)); vrc = i_checkPID(dataCb.uPID); if (RT_SUCCESS(vrc)) { com::SafeArray data((size_t)dataCb.cbData); if (dataCb.cbData) data.initFrom((BYTE*)dataCb.pvData, dataCb.cbData); fireGuestProcessOutputEvent(mEventSource, mSession, this, mData.mPID, dataCb.uHandle, dataCb.cbData, ComSafeArrayAsInParam(data)); } LogFlowFuncLeaveRC(vrc); return vrc; } /** * Called by IGuestSession right before this process gets * removed from the public process list. */ int GuestProcess::i_onRemove(void) { LogFlowThisFuncEnter(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); int vrc = VINF_SUCCESS; /* * Note: The event source stuff holds references to this object, * so make sure that this is cleaned up *before* calling uninit(). */ if (!mEventSource.isNull()) { mEventSource->UnregisterListener(mLocalListener); mLocalListener.setNull(); unconst(mEventSource).setNull(); } LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcess::i_readData(uint32_t uHandle, uint32_t uSize, uint32_t uTimeoutMS, void *pvData, size_t cbData, uint32_t *pcbRead, int *pGuestRc) { LogFlowThisFunc(("uPID=%RU32, uHandle=%RU32, uSize=%RU32, uTimeoutMS=%RU32, pvData=%p, cbData=%RU32, pGuestRc=%p\n", mData.mPID, uHandle, uSize, uTimeoutMS, pvData, cbData, pGuestRc)); AssertReturn(uSize, VERR_INVALID_PARAMETER); AssertPtrReturn(pvData, VERR_INVALID_POINTER); AssertReturn(cbData >= uSize, VERR_INVALID_PARAMETER); /* pcbRead is optional. */ AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); if ( mData.mStatus != ProcessStatus_Started /* Skip reading if the process wasn't started with the appropriate * flags. */ || ( ( uHandle == OUTPUT_HANDLE_ID_STDOUT || uHandle == OUTPUT_HANDLE_ID_STDOUT_DEPRECATED) && !(mData.mProcess.mFlags & ProcessCreateFlag_WaitForStdOut)) || ( uHandle == OUTPUT_HANDLE_ID_STDERR && !(mData.mProcess.mFlags & ProcessCreateFlag_WaitForStdErr)) ) { if (pcbRead) *pcbRead = 0; if (pGuestRc) *pGuestRc = VINF_SUCCESS; return VINF_SUCCESS; /* Nothing to read anymore. */ } int vrc; GuestWaitEvent *pEvent = NULL; GuestEventTypes eventTypes; try { /* * On Guest Additions < 4.3 there is no guarantee that the process status * change arrives *after* the output event, e.g. if this was the last output * block being read and the process will report status "terminate". * So just skip checking for process status change and only wait for the * output event. */ if (mSession->i_getProtocolVersion() >= 2) eventTypes.push_back(VBoxEventType_OnGuestProcessStateChanged); eventTypes.push_back(VBoxEventType_OnGuestProcessOutput); vrc = registerWaitEvent(eventTypes, &pEvent); } catch (std::bad_alloc) { vrc = VERR_NO_MEMORY; } if (RT_FAILURE(vrc)) return vrc; if (RT_SUCCESS(vrc)) { VBOXHGCMSVCPARM paParms[8]; int i = 0; paParms[i++].setUInt32(pEvent->ContextID()); paParms[i++].setUInt32(mData.mPID); paParms[i++].setUInt32(uHandle); paParms[i++].setUInt32(0 /* Flags, none set yet. */); alock.release(); /* Drop the write lock before sending. */ vrc = sendCommand(HOST_EXEC_GET_OUTPUT, i, paParms); } if (RT_SUCCESS(vrc)) vrc = i_waitForOutput(pEvent, uHandle, uTimeoutMS, pvData, cbData, pcbRead); unregisterWaitEvent(pEvent); LogFlowFuncLeaveRC(vrc); return vrc; } /* Does not do locking; caller is responsible for that! */ int GuestProcess::i_setProcessStatus(ProcessStatus_T procStatus, int procRc) { LogFlowThisFuncEnter(); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); LogFlowThisFunc(("oldStatus=%RU32, newStatus=%RU32, procRc=%Rrc\n", mData.mStatus, procStatus, procRc)); if (procStatus == ProcessStatus_Error) { AssertMsg(RT_FAILURE(procRc), ("Guest rc must be an error (%Rrc)\n", procRc)); /* Do not allow overwriting an already set error. If this happens * this means we forgot some error checking/locking somewhere. */ AssertMsg(RT_SUCCESS(mData.mLastError), ("Guest rc already set (to %Rrc)\n", mData.mLastError)); } else AssertMsg(RT_SUCCESS(procRc), ("Guest rc must not be an error (%Rrc)\n", procRc)); int rc = VINF_SUCCESS; if (mData.mStatus != procStatus) /* Was there a process status change? */ { mData.mStatus = procStatus; mData.mLastError = procRc; ComObjPtr errorInfo; HRESULT hr = errorInfo.createObject(); ComAssertComRC(hr); if (RT_FAILURE(mData.mLastError)) { hr = errorInfo->initEx(VBOX_E_IPRT_ERROR, mData.mLastError, COM_IIDOF(IGuestProcess), getComponentName(), i_guestErrorToString(mData.mLastError)); ComAssertComRC(hr); } /* Copy over necessary data before releasing lock again. */ uint32_t uPID = mData.mPID; /** @todo Also handle mSession? */ alock.release(); /* Release lock before firing off event. */ fireGuestProcessStateChangedEvent(mEventSource, mSession, this, uPID, procStatus, errorInfo); #if 0 /* * On Guest Additions < 4.3 there is no guarantee that outstanding * requests will be delivered to the host after the process has ended, * so just cancel all waiting events here to not let clients run * into timeouts. */ if ( mSession->getProtocolVersion() < 2 && hasEnded()) { LogFlowThisFunc(("Process ended, canceling outstanding wait events ...\n")); rc = cancelWaitEvents(); } #endif } return rc; } /* static */ HRESULT GuestProcess::i_setErrorExternal(VirtualBoxBase *pInterface, int guestRc) { AssertPtr(pInterface); AssertMsg(RT_FAILURE(guestRc), ("Guest rc does not indicate a failure when setting error\n")); return pInterface->setError(VBOX_E_IPRT_ERROR, GuestProcess::i_guestErrorToString(guestRc).c_str()); } int GuestProcess::i_startProcess(uint32_t cMsTimeout, int *pGuestRc) { LogFlowThisFunc(("cMsTimeout=%RU32, procExe=%s, procTimeoutMS=%RU32, procFlags=%x, sessionID=%RU32\n", cMsTimeout, mData.mProcess.mExecutable.c_str(), mData.mProcess.mTimeoutMS, mData.mProcess.mFlags, mSession->i_getId())); /* Wait until the caller function (if kicked off by a thread) * has returned and continue operation. */ AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); mData.mStatus = ProcessStatus_Starting; int vrc; GuestWaitEvent *pEvent = NULL; GuestEventTypes eventTypes; try { eventTypes.push_back(VBoxEventType_OnGuestProcessStateChanged); vrc = registerWaitEvent(eventTypes, &pEvent); } catch (std::bad_alloc) { vrc = VERR_NO_MEMORY; } if (RT_FAILURE(vrc)) return vrc; vrc = i_startProcessInner(cMsTimeout, alock, pEvent, pGuestRc); unregisterWaitEvent(pEvent); LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcess::i_startProcessInner(uint32_t cMsTimeout, AutoWriteLock &rLock, GuestWaitEvent *pEvent, int *pGuestRc) { GuestSession *pSession = mSession; AssertPtr(pSession); uint32_t const uProtocol = pSession->i_getProtocolVersion(); const GuestCredentials &sessionCreds = pSession->i_getCredentials(); /* Prepare arguments. */ size_t cArgs = mData.mProcess.mArguments.size(); if (cArgs >= 128*1024) return VERR_BUFFER_OVERFLOW; char *pszArgs = NULL; int vrc = VINF_SUCCESS; if (cArgs) { char const **papszArgv = (char const **)RTMemAlloc((cArgs + 1) * sizeof(papszArgv[0])); AssertReturn(papszArgv, VERR_NO_MEMORY); for (size_t i = 0; i < cArgs; i++) { papszArgv[i] = mData.mProcess.mArguments[i].c_str(); AssertPtr(papszArgv[i]); } papszArgv[cArgs] = NULL; if (uProtocol < UINT32_C(0xdeadbeef) ) /** @todo implement a way of sending argv[0], best idea is a new command. */ vrc = RTGetOptArgvToString(&pszArgs, papszArgv + 1, RTGETOPTARGV_CNV_QUOTE_BOURNE_SH); else vrc = RTGetOptArgvToString(&pszArgs, papszArgv, RTGETOPTARGV_CNV_QUOTE_BOURNE_SH); RTMemFree(papszArgv); if (RT_FAILURE(vrc)) return vrc; /* Note! No returns after this. */ } /* Calculate arguments size (in bytes). */ size_t cbArgs = pszArgs ? strlen(pszArgs) + 1 : 0; /* Include terminating zero. */ /* Prepare environment. The guest service dislikes the empty string at the end, so drop it. */ size_t cbEnvBlock; char *pszzEnvBlock; vrc = mData.mProcess.mEnvironmentChanges.queryUtf8Block(&pszzEnvBlock, &cbEnvBlock); if (RT_SUCCESS(vrc)) { Assert(cbEnvBlock > 0); cbEnvBlock--; /* Prepare HGCM call. */ VBOXHGCMSVCPARM paParms[16]; int i = 0; paParms[i++].setUInt32(pEvent->ContextID()); paParms[i++].setCppString(mData.mProcess.mExecutable); paParms[i++].setUInt32(mData.mProcess.mFlags); paParms[i++].setUInt32((uint32_t)mData.mProcess.mArguments.size()); paParms[i++].setPointer(pszArgs, (uint32_t)cbArgs); paParms[i++].setUInt32(mData.mProcess.mEnvironmentChanges.count()); paParms[i++].setUInt32((uint32_t)cbEnvBlock); paParms[i++].setPointer(pszzEnvBlock, (uint32_t)cbEnvBlock); if (uProtocol < 2) { /* In protocol v1 (VBox < 4.3) the credentials were part of the execution * call. In newer protocols these credentials are part of the opened guest * session, so not needed anymore here. */ paParms[i++].setCppString(sessionCreds.mUser); paParms[i++].setCppString(sessionCreds.mPassword); } /* * If the WaitForProcessStartOnly flag is set, we only want to define and wait for a timeout * until the process was started - the process itself then gets an infinite timeout for execution. * This is handy when we want to start a process inside a worker thread within a certain timeout * but let the started process perform lengthly operations then. */ if (mData.mProcess.mFlags & ProcessCreateFlag_WaitForProcessStartOnly) paParms[i++].setUInt32(UINT32_MAX /* Infinite timeout */); else paParms[i++].setUInt32(mData.mProcess.mTimeoutMS); if (uProtocol >= 2) { paParms[i++].setUInt32(mData.mProcess.mPriority); /* CPU affinity: We only support one CPU affinity block at the moment, * so that makes up to 64 CPUs total. This can be more in the future. */ paParms[i++].setUInt32(1); /* The actual CPU affinity blocks. */ paParms[i++].setPointer((void *)&mData.mProcess.mAffinity, sizeof(mData.mProcess.mAffinity)); } rLock.release(); /* Drop the write lock before sending. */ vrc = sendCommand(HOST_EXEC_CMD, i, paParms); if (RT_FAILURE(vrc)) { int rc2 = i_setProcessStatus(ProcessStatus_Error, vrc); AssertRC(rc2); } mData.mProcess.mEnvironmentChanges.freeUtf8Block(pszzEnvBlock); } RTStrFree(pszArgs); if (RT_SUCCESS(vrc)) vrc = i_waitForStatusChange(pEvent, cMsTimeout, NULL /* Process status */, pGuestRc); return vrc; } int GuestProcess::i_startProcessAsync(void) { LogFlowThisFuncEnter(); int vrc = VINF_SUCCESS; HRESULT hr = S_OK; GuestProcessStartTask* pTask = NULL; try { pTask = new GuestProcessStartTask(this); if (!pTask->i_isOk()) { delete pTask; LogFlow(("GuestProcess: Could not create GuestProcessStartTask object \n")); throw VERR_MEMOBJ_INIT_FAILED; } LogFlow(("GuestProcess: Successfully created GuestProcessStartTask object \n")); //this function delete pTask in case of exceptions, so there is no need in the call of delete operator hr = pTask->createThread(); } catch(std::bad_alloc &) { vrc = VERR_NO_MEMORY; } catch(int eVRC) { vrc = eVRC; LogFlow(("GuestSession: Could not create thread for GuestProcessStartTask task %Rrc\n", vrc)); } LogFlowFuncLeaveRC(vrc); return vrc; } /* static */ void GuestProcess::i_startProcessThreadTask(GuestProcessStartTask *pTask) { LogFlowFunc(("pTask=%p\n", pTask)); const ComObjPtr pProcess(pTask->i_process()); Assert(!pProcess.isNull()); AutoCaller autoCaller(pProcess); if (FAILED(autoCaller.rc())) return; int vrc = pProcess->i_startProcess(30 * 1000 /* 30s timeout */, NULL /* Guest rc, ignored */); /** @todo * * r=bird: what's up with vrc here? Safe to ignore it? * */ /* Nothing to do here anymore. */ LogFlowFunc(("pProcess=%p vrc=%Rrc (ignored)\n", (GuestProcess *)pProcess, vrc)); NOREF(vrc); } int GuestProcess::i_terminateProcess(uint32_t uTimeoutMS, int *pGuestRc) { /* pGuestRc is optional. */ LogFlowThisFunc(("uTimeoutMS=%RU32\n", uTimeoutMS)); AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); int vrc = VINF_SUCCESS; if (mData.mStatus != ProcessStatus_Started) { LogFlowThisFunc(("Process not in started state (state is %RU32), skipping termination\n", mData.mStatus)); } else { AssertPtr(mSession); /* Note: VBox < 4.3 (aka protocol version 1) does not * support this, so just skip. */ if (mSession->i_getProtocolVersion() < 2) vrc = VERR_NOT_SUPPORTED; if (RT_SUCCESS(vrc)) { GuestWaitEvent *pEvent = NULL; GuestEventTypes eventTypes; try { eventTypes.push_back(VBoxEventType_OnGuestProcessStateChanged); vrc = registerWaitEvent(eventTypes, &pEvent); } catch (std::bad_alloc) { vrc = VERR_NO_MEMORY; } if (RT_FAILURE(vrc)) return vrc; VBOXHGCMSVCPARM paParms[4]; int i = 0; paParms[i++].setUInt32(pEvent->ContextID()); paParms[i++].setUInt32(mData.mPID); alock.release(); /* Drop the write lock before sending. */ vrc = sendCommand(HOST_EXEC_TERMINATE, i, paParms); if (RT_SUCCESS(vrc)) vrc = i_waitForStatusChange(pEvent, uTimeoutMS, NULL /* ProcessStatus */, pGuestRc); unregisterWaitEvent(pEvent); } } LogFlowFuncLeaveRC(vrc); return vrc; } /* static */ ProcessWaitResult_T GuestProcess::i_waitFlagsToResultEx(uint32_t fWaitFlags, ProcessStatus_T oldStatus, ProcessStatus_T newStatus, uint32_t uProcFlags, uint32_t uProtocol) { ProcessWaitResult_T waitResult = ProcessWaitResult_None; switch (newStatus) { case ProcessStatus_TerminatedNormally: case ProcessStatus_TerminatedSignal: case ProcessStatus_TerminatedAbnormally: case ProcessStatus_Down: /* Nothing to wait for anymore. */ waitResult = ProcessWaitResult_Terminate; break; case ProcessStatus_TimedOutKilled: case ProcessStatus_TimedOutAbnormally: /* Dito. */ waitResult = ProcessWaitResult_Timeout; break; case ProcessStatus_Started: switch (oldStatus) { case ProcessStatus_Undefined: case ProcessStatus_Starting: /* Also wait for process start. */ if (fWaitFlags & ProcessWaitForFlag_Start) waitResult = ProcessWaitResult_Start; else { /* * If ProcessCreateFlag_WaitForProcessStartOnly was specified on process creation the * caller is not interested in getting further process statuses -- so just don't notify * anything here anymore and return. */ if (uProcFlags & ProcessCreateFlag_WaitForProcessStartOnly) waitResult = ProcessWaitResult_Start; } break; case ProcessStatus_Started: /* Only wait for process start. */ if (fWaitFlags == ProcessWaitForFlag_Start) waitResult = ProcessWaitResult_Start; break; default: AssertMsgFailed(("Unhandled old status %RU32 before new status 'started'\n", oldStatus)); waitResult = ProcessWaitResult_Start; break; } break; case ProcessStatus_Error: /* Nothing to wait for anymore. */ waitResult = ProcessWaitResult_Error; break; case ProcessStatus_Undefined: case ProcessStatus_Starting: case ProcessStatus_Terminating: case ProcessStatus_Paused: /* No result available yet, leave wait * flags untouched. */ break; } if (newStatus == ProcessStatus_Started) { /** * Filter out waits which are *not* supported using * older guest control Guest Additions. * ** @todo ProcessWaitForFlag_Std* flags are not implemented yet. */ if (uProtocol < 99) /* See @todo above. */ { if ( waitResult == ProcessWaitResult_None /* We don't support waiting for stdin, out + err, * just skip waiting then. */ && ( (fWaitFlags & ProcessWaitForFlag_StdIn) || (fWaitFlags & ProcessWaitForFlag_StdOut) || (fWaitFlags & ProcessWaitForFlag_StdErr) ) ) { /* Use _WaitFlagNotSupported because we don't know what to tell the caller. */ waitResult = ProcessWaitResult_WaitFlagNotSupported; } } } #ifdef DEBUG LogFlowFunc(("oldStatus=%RU32, newStatus=%RU32, fWaitFlags=0x%x, waitResult=%RU32\n", oldStatus, newStatus, fWaitFlags, waitResult)); #endif return waitResult; } ProcessWaitResult_T GuestProcess::i_waitFlagsToResult(uint32_t fWaitFlags) { AssertPtr(mSession); return GuestProcess::i_waitFlagsToResultEx(fWaitFlags, mData.mStatus /* curStatus */, mData.mStatus /* newStatus */, mData.mProcess.mFlags, mSession->i_getProtocolVersion()); } int GuestProcess::i_waitFor(uint32_t fWaitFlags, ULONG uTimeoutMS, ProcessWaitResult_T &waitResult, int *pGuestRc) { AssertReturn(fWaitFlags, VERR_INVALID_PARAMETER); AutoReadLock alock(this COMMA_LOCKVAL_SRC_POS); LogFlowThisFunc(("fWaitFlags=0x%x, uTimeoutMS=%RU32, procStatus=%RU32, procRc=%Rrc, pGuestRc=%p\n", fWaitFlags, uTimeoutMS, mData.mStatus, mData.mLastError, pGuestRc)); /* Did some error occur before? Then skip waiting and return. */ ProcessStatus_T curStatus = mData.mStatus; if (curStatus == ProcessStatus_Error) { waitResult = ProcessWaitResult_Error; AssertMsg(RT_FAILURE(mData.mLastError), ("No error rc (%Rrc) set when guest process indicated an error\n", mData.mLastError)); if (pGuestRc) *pGuestRc = mData.mLastError; /* Return last set error. */ LogFlowThisFunc(("Process is in error state (guestRc=%Rrc)\n", mData.mLastError)); return VERR_GSTCTL_GUEST_ERROR; } waitResult = i_waitFlagsToResult(fWaitFlags); /* No waiting needed? Return immediately using the last set error. */ if (waitResult != ProcessWaitResult_None) { if (pGuestRc) *pGuestRc = mData.mLastError; /* Return last set error (if any). */ LogFlowThisFunc(("Nothing to wait for (guestRc=%Rrc)\n", mData.mLastError)); return RT_SUCCESS(mData.mLastError) ? VINF_SUCCESS : VERR_GSTCTL_GUEST_ERROR; } /* Adjust timeout. Passing 0 means RT_INDEFINITE_WAIT. */ if (!uTimeoutMS) uTimeoutMS = RT_INDEFINITE_WAIT; int vrc; GuestWaitEvent *pEvent = NULL; GuestEventTypes eventTypes; try { eventTypes.push_back(VBoxEventType_OnGuestProcessStateChanged); vrc = registerWaitEvent(eventTypes, &pEvent); } catch (std::bad_alloc) { vrc = VERR_NO_MEMORY; } if (RT_FAILURE(vrc)) return vrc; alock.release(); /* Release lock before waiting. */ /* * Do the actual waiting. */ ProcessStatus_T newStatus = ProcessStatus_Undefined; uint64_t u64StartMS = RTTimeMilliTS(); for (;;) { uint64_t u64ElapsedMS = RTTimeMilliTS() - u64StartMS; if ( uTimeoutMS != RT_INDEFINITE_WAIT && u64ElapsedMS >= uTimeoutMS) { vrc = VERR_TIMEOUT; break; } vrc = i_waitForStatusChange(pEvent, uTimeoutMS == RT_INDEFINITE_WAIT ? RT_INDEFINITE_WAIT : uTimeoutMS - (uint32_t)u64ElapsedMS, &newStatus, pGuestRc); if (RT_SUCCESS(vrc)) { alock.acquire(); waitResult = i_waitFlagsToResultEx(fWaitFlags, curStatus, newStatus, mData.mProcess.mFlags, mSession->i_getProtocolVersion()); #ifdef DEBUG LogFlowThisFunc(("Got new status change: fWaitFlags=0x%x, newStatus=%RU32, waitResult=%RU32\n", fWaitFlags, newStatus, waitResult)); #endif if (ProcessWaitResult_None != waitResult) /* We got a waiting result. */ break; } else /* Waiting failed, bail out. */ break; alock.release(); /* Don't hold lock in next waiting round. */ } unregisterWaitEvent(pEvent); LogFlowThisFunc(("Returned waitResult=%RU32, newStatus=%RU32, rc=%Rrc\n", waitResult, newStatus, vrc)); return vrc; } int GuestProcess::i_waitForInputNotify(GuestWaitEvent *pEvent, uint32_t uHandle, uint32_t uTimeoutMS, ProcessInputStatus_T *pInputStatus, uint32_t *pcbProcessed) { RT_NOREF(uHandle); AssertPtrReturn(pEvent, VERR_INVALID_POINTER); VBoxEventType_T evtType; ComPtr pIEvent; int vrc = waitForEvent(pEvent, uTimeoutMS, &evtType, pIEvent.asOutParam()); if (RT_SUCCESS(vrc)) { if (evtType == VBoxEventType_OnGuestProcessInputNotify) { ComPtr pProcessEvent = pIEvent; Assert(!pProcessEvent.isNull()); if (pInputStatus) { HRESULT hr2 = pProcessEvent->COMGETTER(Status)(pInputStatus); ComAssertComRC(hr2); } if (pcbProcessed) { HRESULT hr2 = pProcessEvent->COMGETTER(Processed)((ULONG*)pcbProcessed); ComAssertComRC(hr2); } } else vrc = VWRN_GSTCTL_OBJECTSTATE_CHANGED; } LogFlowThisFunc(("Returning pEvent=%p, uHandle=%RU32, rc=%Rrc\n", pEvent, uHandle, vrc)); return vrc; } int GuestProcess::i_waitForOutput(GuestWaitEvent *pEvent, uint32_t uHandle, uint32_t uTimeoutMS, void *pvData, size_t cbData, uint32_t *pcbRead) { AssertPtrReturn(pEvent, VERR_INVALID_POINTER); /* pvData is optional. */ /* cbData is optional. */ /* pcbRead is optional. */ LogFlowThisFunc(("cEventTypes=%zu, pEvent=%p, uHandle=%RU32, uTimeoutMS=%RU32, pvData=%p, cbData=%zu, pcbRead=%p\n", pEvent->TypeCount(), pEvent, uHandle, uTimeoutMS, pvData, cbData, pcbRead)); int vrc; VBoxEventType_T evtType; ComPtr pIEvent; do { vrc = waitForEvent(pEvent, uTimeoutMS, &evtType, pIEvent.asOutParam()); if (RT_SUCCESS(vrc)) { if (evtType == VBoxEventType_OnGuestProcessOutput) { ComPtr pProcessEvent = pIEvent; Assert(!pProcessEvent.isNull()); ULONG uHandleEvent; HRESULT hr = pProcessEvent->COMGETTER(Handle)(&uHandleEvent); if ( SUCCEEDED(hr) && uHandleEvent == uHandle) { if (pvData) { com::SafeArray data; hr = pProcessEvent->COMGETTER(Data)(ComSafeArrayAsOutParam(data)); ComAssertComRC(hr); size_t cbRead = data.size(); if (cbRead) { if (cbRead <= cbData) { /* Copy data from event into our buffer. */ memcpy(pvData, data.raw(), data.size()); } else vrc = VERR_BUFFER_OVERFLOW; LogFlowThisFunc(("Read %zu bytes (uHandle=%RU32), rc=%Rrc\n", cbRead, uHandleEvent, vrc)); } } if ( RT_SUCCESS(vrc) && pcbRead) { ULONG cbRead; hr = pProcessEvent->COMGETTER(Processed)(&cbRead); ComAssertComRC(hr); *pcbRead = (uint32_t)cbRead; } break; } else if (FAILED(hr)) vrc = VERR_COM_UNEXPECTED; } else vrc = VWRN_GSTCTL_OBJECTSTATE_CHANGED; } } while (vrc == VINF_SUCCESS); if ( vrc != VINF_SUCCESS && pcbRead) { *pcbRead = 0; } LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcess::i_waitForStatusChange(GuestWaitEvent *pEvent, uint32_t uTimeoutMS, ProcessStatus_T *pProcessStatus, int *pGuestRc) { AssertPtrReturn(pEvent, VERR_INVALID_POINTER); /* pProcessStatus is optional. */ /* pGuestRc is optional. */ VBoxEventType_T evtType; ComPtr pIEvent; int vrc = waitForEvent(pEvent, uTimeoutMS, &evtType, pIEvent.asOutParam()); if (RT_SUCCESS(vrc)) { Assert(evtType == VBoxEventType_OnGuestProcessStateChanged); ComPtr pProcessEvent = pIEvent; Assert(!pProcessEvent.isNull()); ProcessStatus_T procStatus; HRESULT hr = pProcessEvent->COMGETTER(Status)(&procStatus); ComAssertComRC(hr); if (pProcessStatus) *pProcessStatus = procStatus; ComPtr errorInfo; hr = pProcessEvent->COMGETTER(Error)(errorInfo.asOutParam()); ComAssertComRC(hr); LONG lGuestRc; hr = errorInfo->COMGETTER(ResultDetail)(&lGuestRc); ComAssertComRC(hr); LogFlowThisFunc(("Got procStatus=%RU32, guestRc=%RI32 (%Rrc)\n", procStatus, lGuestRc, lGuestRc)); if (RT_FAILURE((int)lGuestRc)) vrc = VERR_GSTCTL_GUEST_ERROR; if (pGuestRc) *pGuestRc = (int)lGuestRc; } LogFlowFuncLeaveRC(vrc); return vrc; } /* static */ bool GuestProcess::i_waitResultImpliesEx(ProcessWaitResult_T waitResult, ProcessStatus_T procStatus, uint32_t uProcFlags, uint32_t uProtocol) { /** @todo r=bird: If you subscribe to HN, which the 'u' in 'uProcFlags' * indicates, you should actually be using 'fProc'! */ RT_NOREF(uProtocol, uProcFlags); bool fImplies; switch (waitResult) { case ProcessWaitResult_Start: fImplies = procStatus == ProcessStatus_Started; break; case ProcessWaitResult_Terminate: fImplies = ( procStatus == ProcessStatus_TerminatedNormally || procStatus == ProcessStatus_TerminatedSignal || procStatus == ProcessStatus_TerminatedAbnormally || procStatus == ProcessStatus_TimedOutKilled || procStatus == ProcessStatus_TimedOutAbnormally || procStatus == ProcessStatus_Down || procStatus == ProcessStatus_Error); break; default: fImplies = false; break; } return fImplies; } int GuestProcess::i_writeData(uint32_t uHandle, uint32_t uFlags, void *pvData, size_t cbData, uint32_t uTimeoutMS, uint32_t *puWritten, int *pGuestRc) { LogFlowThisFunc(("uPID=%RU32, uHandle=%RU32, uFlags=%RU32, pvData=%p, cbData=%RU32, uTimeoutMS=%RU32, puWritten=%p, pGuestRc=%p\n", mData.mPID, uHandle, uFlags, pvData, cbData, uTimeoutMS, puWritten, pGuestRc)); /* All is optional. There can be 0 byte writes. */ AutoWriteLock alock(this COMMA_LOCKVAL_SRC_POS); if (mData.mStatus != ProcessStatus_Started) { if (puWritten) *puWritten = 0; if (pGuestRc) *pGuestRc = VINF_SUCCESS; return VINF_SUCCESS; /* Not available for writing (anymore). */ } int vrc; GuestWaitEvent *pEvent = NULL; GuestEventTypes eventTypes; try { /* * On Guest Additions < 4.3 there is no guarantee that the process status * change arrives *after* the input event, e.g. if this was the last input * block being written and the process will report status "terminate". * So just skip checking for process status change and only wait for the * input event. */ if (mSession->i_getProtocolVersion() >= 2) eventTypes.push_back(VBoxEventType_OnGuestProcessStateChanged); eventTypes.push_back(VBoxEventType_OnGuestProcessInputNotify); vrc = registerWaitEvent(eventTypes, &pEvent); } catch (std::bad_alloc) { vrc = VERR_NO_MEMORY; } if (RT_FAILURE(vrc)) return vrc; VBOXHGCMSVCPARM paParms[5]; int i = 0; paParms[i++].setUInt32(pEvent->ContextID()); paParms[i++].setUInt32(mData.mPID); paParms[i++].setUInt32(uFlags); paParms[i++].setPointer(pvData, (uint32_t)cbData); paParms[i++].setUInt32((uint32_t)cbData); alock.release(); /* Drop the write lock before sending. */ uint32_t cbProcessed = 0; vrc = sendCommand(HOST_EXEC_SET_INPUT, i, paParms); if (RT_SUCCESS(vrc)) { ProcessInputStatus_T inputStatus; vrc = i_waitForInputNotify(pEvent, uHandle, uTimeoutMS, &inputStatus, &cbProcessed); if (RT_SUCCESS(vrc)) { /** @todo Set guestRc. */ if (puWritten) *puWritten = cbProcessed; } /** @todo Error handling. */ } unregisterWaitEvent(pEvent); LogFlowThisFunc(("Returning cbProcessed=%RU32, rc=%Rrc\n", cbProcessed, vrc)); return vrc; } // implementation of public methods ///////////////////////////////////////////////////////////////////////////// HRESULT GuestProcess::read(ULONG aHandle, ULONG aToRead, ULONG aTimeoutMS, std::vector &aData) { LogFlowThisFuncEnter(); if (aToRead == 0) return setError(E_INVALIDARG, tr("The size to read is zero")); aData.resize(aToRead); HRESULT hr = S_OK; uint32_t cbRead; int guestRc; int vrc = i_readData(aHandle, aToRead, aTimeoutMS, &aData.front(), aToRead, &cbRead, &guestRc); if (RT_SUCCESS(vrc)) { if (aData.size() != cbRead) aData.resize(cbRead); } else { aData.resize(0); switch (vrc) { case VERR_GSTCTL_GUEST_ERROR: hr = GuestProcess::i_setErrorExternal(this, guestRc); break; default: hr = setError(VBOX_E_IPRT_ERROR, tr("Reading from process \"%s\" (PID %RU32) failed: %Rrc"), mData.mProcess.mExecutable.c_str(), mData.mPID, vrc); break; } } LogFlowThisFunc(("rc=%Rrc, cbRead=%RU32\n", vrc, cbRead)); LogFlowFuncLeaveRC(vrc); return hr; } HRESULT GuestProcess::terminate() { HRESULT hr = S_OK; int guestRc; int vrc = i_terminateProcess(30 * 1000 /* Timeout in ms */, &guestRc); if (RT_FAILURE(vrc)) { switch (vrc) { case VERR_GSTCTL_GUEST_ERROR: hr = GuestProcess::i_setErrorExternal(this, guestRc); break; case VERR_NOT_SUPPORTED: hr = setError(VBOX_E_IPRT_ERROR, tr("Terminating process \"%s\" (PID %RU32) not supported by installed Guest Additions"), mData.mProcess.mExecutable.c_str(), mData.mPID); break; default: hr = setError(VBOX_E_IPRT_ERROR, tr("Terminating process \"%s\" (PID %RU32) failed: %Rrc"), mData.mProcess.mExecutable.c_str(), mData.mPID, vrc); break; } } /* Remove process from guest session list. Now only API clients * still can hold references to it. */ AssertPtr(mSession); int rc2 = mSession->i_processRemoveFromList(this); if (RT_SUCCESS(vrc)) vrc = rc2; LogFlowFuncLeaveRC(vrc); return hr; } HRESULT GuestProcess::waitFor(ULONG aWaitFor, ULONG aTimeoutMS, ProcessWaitResult_T *aReason) { /* * Note: Do not hold any locks here while waiting! */ HRESULT hr = S_OK; int guestRc; ProcessWaitResult_T waitResult; int vrc = i_waitFor(aWaitFor, aTimeoutMS, waitResult, &guestRc); if (RT_SUCCESS(vrc)) { *aReason = waitResult; } else { switch (vrc) { case VERR_GSTCTL_GUEST_ERROR: hr = GuestProcess::i_setErrorExternal(this, guestRc); break; case VERR_TIMEOUT: *aReason = ProcessWaitResult_Timeout; break; default: hr = setError(VBOX_E_IPRT_ERROR, tr("Waiting for process \"%s\" (PID %RU32) failed: %Rrc"), mData.mProcess.mExecutable.c_str(), mData.mPID, vrc); break; } } LogFlowFuncLeaveRC(vrc); return hr; } HRESULT GuestProcess::waitForArray(const std::vector &aWaitFor, ULONG aTimeoutMS, ProcessWaitResult_T *aReason) { /* * Note: Do not hold any locks here while waiting! */ uint32_t fWaitFor = ProcessWaitForFlag_None; for (size_t i = 0; i < aWaitFor.size(); i++) fWaitFor |= aWaitFor[i]; return WaitFor(fWaitFor, aTimeoutMS, aReason); } HRESULT GuestProcess::write(ULONG aHandle, ULONG aFlags, const std::vector &aData, ULONG aTimeoutMS, ULONG *aWritten) { LogFlowThisFuncEnter(); HRESULT hr = S_OK; uint32_t cbWritten; int guestRc; uint32_t cbData = (uint32_t)aData.size(); void *pvData = cbData > 0? (void *)&aData.front(): NULL; int vrc = i_writeData(aHandle, aFlags, pvData, cbData, aTimeoutMS, &cbWritten, &guestRc); if (RT_FAILURE(vrc)) { switch (vrc) { case VERR_GSTCTL_GUEST_ERROR: hr = GuestProcess::i_setErrorExternal(this, guestRc); break; default: hr = setError(VBOX_E_IPRT_ERROR, tr("Writing to process \"%s\" (PID %RU32) failed: %Rrc"), mData.mProcess.mExecutable.c_str(), mData.mPID, vrc); break; } } LogFlowThisFunc(("rc=%Rrc, aWritten=%RU32\n", vrc, cbWritten)); *aWritten = (ULONG)cbWritten; LogFlowFuncLeaveRC(vrc); return hr; } HRESULT GuestProcess::writeArray(ULONG aHandle, const std::vector &aFlags, const std::vector &aData, ULONG aTimeoutMS, ULONG *aWritten) { LogFlowThisFuncEnter(); /* * Note: Do not hold any locks here while writing! */ ULONG fWrite = ProcessInputFlag_None; for (size_t i = 0; i < aFlags.size(); i++) fWrite |= aFlags[i]; return write(aHandle, fWrite, aData, aTimeoutMS, aWritten); } /////////////////////////////////////////////////////////////////////////////// GuestProcessTool::GuestProcessTool(void) : pSession(NULL), pProcess(NULL) { } GuestProcessTool::~GuestProcessTool(void) { i_terminate(30 * 1000, NULL /* pGuestRc */); } int GuestProcessTool::Init(GuestSession *pGuestSession, const GuestProcessStartupInfo &startupInfo, bool fAsync, int *pGuestRc) { LogFlowThisFunc(("pGuestSession=%p, exe=%s, fAsync=%RTbool\n", pGuestSession, startupInfo.mExecutable.c_str(), fAsync)); AssertPtrReturn(pGuestSession, VERR_INVALID_POINTER); Assert(startupInfo.mArguments[0] == startupInfo.mExecutable); pSession = pGuestSession; mStartupInfo = startupInfo; /* Make sure the process is hidden. */ mStartupInfo.mFlags |= ProcessCreateFlag_Hidden; int vrc = pSession->i_processCreateExInternal(mStartupInfo, pProcess); if (RT_SUCCESS(vrc)) { int vrcGuest = VINF_SUCCESS; vrc = fAsync ? pProcess->i_startProcessAsync() : pProcess->i_startProcess(30 * 1000 /* 30s timeout */, &vrcGuest); if ( RT_SUCCESS(vrc) && !fAsync && RT_FAILURE(vrcGuest) ) { if (pGuestRc) *pGuestRc = vrcGuest; vrc = VERR_GSTCTL_GUEST_ERROR; } } LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcessTool::i_getCurrentBlock(uint32_t uHandle, GuestProcessStreamBlock &strmBlock) { const GuestProcessStream *pStream = NULL; if (uHandle == OUTPUT_HANDLE_ID_STDOUT) pStream = &mStdOut; else if (uHandle == OUTPUT_HANDLE_ID_STDERR) pStream = &mStdErr; if (!pStream) return VERR_INVALID_PARAMETER; int vrc; do { /* Try parsing the data to see if the current block is complete. */ vrc = mStdOut.ParseBlock(strmBlock); if (strmBlock.GetCount()) break; } while (RT_SUCCESS(vrc)); LogFlowThisFunc(("rc=%Rrc, %RU64 pairs\n", vrc, strmBlock.GetCount())); return vrc; } int GuestProcessTool::i_getRc(void) const { LONG exitCode = -1; HRESULT hr = pProcess->COMGETTER(ExitCode(&exitCode)); AssertComRC(hr); return GuestProcessTool::i_exitCodeToRc(mStartupInfo, exitCode); } bool GuestProcessTool::i_isRunning(void) { AssertReturn(!pProcess.isNull(), false); ProcessStatus_T procStatus = ProcessStatus_Undefined; HRESULT hr = pProcess->COMGETTER(Status(&procStatus)); AssertComRC(hr); if ( procStatus == ProcessStatus_Started || procStatus == ProcessStatus_Paused || procStatus == ProcessStatus_Terminating) { return true; } return false; } /* static */ int GuestProcessTool::i_run( GuestSession *pGuestSession, const GuestProcessStartupInfo &startupInfo, int *pGuestRc /* = NULL */) { int guestRc; GuestProcessToolErrorInfo errorInfo; int vrc = i_runErrorInfo(pGuestSession, startupInfo, errorInfo); if (RT_SUCCESS(vrc)) { if (errorInfo.guestRc == VWRN_GSTCTL_PROCESS_EXIT_CODE) { guestRc = GuestProcessTool::i_exitCodeToRc(startupInfo, errorInfo.lExitCode); } else guestRc = errorInfo.guestRc; if (pGuestRc) *pGuestRc = guestRc; } return vrc; } /** * Static helper function to start and wait for a certain toolbox tool. * * @return IPRT status code. * @param pGuestSession Guest control session to use for starting the toolbox tool in. * @param startupInfo Startup information about the toolbox tool. * @param errorInfo Error information returned for error handling. */ /* static */ int GuestProcessTool::i_runErrorInfo( GuestSession *pGuestSession, const GuestProcessStartupInfo &startupInfo, GuestProcessToolErrorInfo &errorInfo) { return i_runExErrorInfo(pGuestSession, startupInfo, NULL /* paStrmOutObjects */, 0 /* cStrmOutObjects */, errorInfo); } /** * Static helper function to start and wait for output of a certain toolbox tool. * * @return IPRT status code. * @param pGuestSession Guest control session to use for starting the toolbox tool in. * @param startupInfo Startup information about the toolbox tool. * @param paStrmOutObjects Pointer to stream objects array to use for retrieving the output of the toolbox tool. * Optional. * @param cStrmOutObjects Number of stream objects passed in. Optional. * @param pGuestRc Error code returned from the guest side if VERR_GSTCTL_GUEST_ERROR is returned. Optional. */ /* static */ int GuestProcessTool::i_runEx( GuestSession *pGuestSession, const GuestProcessStartupInfo &startupInfo, GuestCtrlStreamObjects *paStrmOutObjects, uint32_t cStrmOutObjects, int *pGuestRc /* = NULL */) { int guestRc; GuestProcessToolErrorInfo errorInfo; int vrc = GuestProcessTool::i_runExErrorInfo(pGuestSession, startupInfo, paStrmOutObjects, cStrmOutObjects, errorInfo); if (RT_SUCCESS(vrc)) { if (errorInfo.guestRc == VWRN_GSTCTL_PROCESS_EXIT_CODE) { guestRc = GuestProcessTool::i_exitCodeToRc(startupInfo, errorInfo.lExitCode); } else guestRc = errorInfo.guestRc; /* Return VERR_GSTCTL_GUEST_ERROR if we retrieved a guest return code. */ if (RT_FAILURE(guestRc)) vrc = VERR_GSTCTL_GUEST_ERROR; if (pGuestRc) *pGuestRc = guestRc; } return vrc; } /** * Static helper function to start and wait for output of a certain toolbox tool. * * This is the extended version, which addds the possibility of retrieving parsable so-called guest stream * objects. Those objects are issued on the guest side as part of VBoxService's toolbox tools (think of a BusyBox-like approach) * on stdout and can be used on the host side to retrieve more information about the actual command issued on the guest side. * * @return IPRT status code. * @param pGuestSession Guest control session to use for starting the toolbox tool in. * @param startupInfo Startup information about the toolbox tool. * @param paStrmOutObjects Pointer to stream objects array to use for retrieving the output of the toolbox tool. * Optional. * @param cStrmOutObjects Number of stream objects passed in. Optional. * @param errorInfo Error information returned for error handling. */ /* static */ int GuestProcessTool::i_runExErrorInfo( GuestSession *pGuestSession, const GuestProcessStartupInfo &startupInfo, GuestCtrlStreamObjects *paStrmOutObjects, uint32_t cStrmOutObjects, GuestProcessToolErrorInfo &errorInfo) { AssertPtrReturn(pGuestSession, VERR_INVALID_POINTER); /* paStrmOutObjects is optional. */ /** @todo Check if this is a valid toolbox. */ GuestProcessTool procTool; int vrc = procTool.Init(pGuestSession, startupInfo, false /* Async */, &errorInfo.guestRc); if (RT_SUCCESS(vrc)) { while (cStrmOutObjects--) { try { GuestProcessStreamBlock strmBlk; vrc = procTool.i_waitEx( paStrmOutObjects ? GUESTPROCESSTOOL_FLAG_STDOUT_BLOCK : GUESTPROCESSTOOL_FLAG_NONE, &strmBlk, &errorInfo.guestRc); if (paStrmOutObjects) paStrmOutObjects->push_back(strmBlk); } catch (std::bad_alloc) { vrc = VERR_NO_MEMORY; } } } if (RT_SUCCESS(vrc)) { /* Make sure the process runs until completion. */ vrc = procTool.i_wait(GUESTPROCESSTOOL_FLAG_NONE, &errorInfo.guestRc); if (RT_SUCCESS(vrc)) errorInfo.guestRc = procTool.i_terminatedOk(&errorInfo.lExitCode); } LogFlowFunc(("Returned rc=%Rrc, guestRc=%Rrc, exitCode=%ld\n", vrc, errorInfo.guestRc, errorInfo.lExitCode)); return vrc; } /** * Reports if the tool has been run correctly. * * @return Will return VWRN_GSTCTL_PROCESS_EXIT_CODE if the tool process returned an exit code <> 0, * VERR_GSTCTL_PROCESS_WRONG_STATE if the tool process is in a wrong state (e.g. still running), * or VINF_SUCCESS otherwise. * * @param plExitCode Exit code of the tool. Optional. */ int GuestProcessTool::i_terminatedOk(LONG *plExitCode /* = NULL */) { Assert(!pProcess.isNull()); /* pExitCode is optional. */ int vrc; if (!i_isRunning()) { LONG lExitCode = -1; HRESULT hr = pProcess->COMGETTER(ExitCode(&lExitCode)); AssertComRC(hr); if (plExitCode) *plExitCode = lExitCode; vrc = (lExitCode != 0) ? VWRN_GSTCTL_PROCESS_EXIT_CODE : VINF_SUCCESS; } else vrc = VERR_GSTCTL_PROCESS_WRONG_STATE; LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcessTool::i_wait(uint32_t fFlags, int *pGuestRc) { return i_waitEx(fFlags, NULL /* pStrmBlkOut */, pGuestRc); } int GuestProcessTool::i_waitEx(uint32_t fFlags, GuestProcessStreamBlock *pStrmBlkOut, int *pGuestRc) { LogFlowThisFunc(("fFlags=0x%x, pStreamBlock=%p, pGuestRc=%p\n", fFlags, pStrmBlkOut, pGuestRc)); /* Can we parse the next block without waiting? */ int vrc; if (fFlags & GUESTPROCESSTOOL_FLAG_STDOUT_BLOCK) { AssertPtr(pStrmBlkOut); vrc = i_getCurrentBlock(OUTPUT_HANDLE_ID_STDOUT, *pStrmBlkOut); if (RT_SUCCESS(vrc)) return vrc; /* else do the waiting below. */ } /* Do the waiting. */ uint32_t fWaitFlags = ProcessWaitForFlag_Terminate; if (mStartupInfo.mFlags & ProcessCreateFlag_WaitForStdOut) fWaitFlags |= ProcessWaitForFlag_StdOut; if (mStartupInfo.mFlags & ProcessCreateFlag_WaitForStdErr) fWaitFlags |= ProcessWaitForFlag_StdErr; /** @todo Decrease timeout while running. */ uint64_t u64StartMS = RTTimeMilliTS(); uint32_t uTimeoutMS = mStartupInfo.mTimeoutMS; int vrcGuest = VINF_SUCCESS; bool fDone = false; BYTE byBuf[_64K]; uint32_t cbRead; bool fHandleStdOut = false; bool fHandleStdErr = false; /** * Updates the elapsed time and checks if a * timeout happened, then breaking out of the loop. */ #define UPDATE_AND_CHECK_ELAPSED_TIME() \ u64ElapsedMS = RTTimeMilliTS() - u64StartMS; \ if ( uTimeoutMS != RT_INDEFINITE_WAIT \ && u64ElapsedMS >= uTimeoutMS) \ { \ vrc = VERR_TIMEOUT; \ break; \ } /** * Returns the remaining time (in ms). */ #define GET_REMAINING_TIME \ uTimeoutMS == RT_INDEFINITE_WAIT \ ? RT_INDEFINITE_WAIT : uTimeoutMS - (uint32_t)u64ElapsedMS \ ProcessWaitResult_T waitRes = ProcessWaitResult_None; do { uint64_t u64ElapsedMS; UPDATE_AND_CHECK_ELAPSED_TIME(); vrc = pProcess->i_waitFor(fWaitFlags, GET_REMAINING_TIME, waitRes, &vrcGuest); if (RT_FAILURE(vrc)) break; switch (waitRes) { case ProcessWaitResult_StdIn: vrc = VERR_NOT_IMPLEMENTED; break; case ProcessWaitResult_StdOut: fHandleStdOut = true; break; case ProcessWaitResult_StdErr: fHandleStdErr = true; break; case ProcessWaitResult_WaitFlagNotSupported: if (fWaitFlags & ProcessWaitForFlag_StdOut) fHandleStdOut = true; if (fWaitFlags & ProcessWaitForFlag_StdErr) fHandleStdErr = true; /* Since waiting for stdout / stderr is not supported by the guest, * wait a bit to not hog the CPU too much when polling for data. */ RTThreadSleep(1); /* Optional, don't check rc. */ break; case ProcessWaitResult_Error: vrc = VERR_GSTCTL_GUEST_ERROR; break; case ProcessWaitResult_Terminate: fDone = true; break; case ProcessWaitResult_Timeout: vrc = VERR_TIMEOUT; break; case ProcessWaitResult_Start: case ProcessWaitResult_Status: /* Not used here, just skip. */ break; default: AssertMsgFailed(("Unhandled process wait result %RU32\n", waitRes)); break; } if (RT_FAILURE(vrc)) break; if (fHandleStdOut) { UPDATE_AND_CHECK_ELAPSED_TIME(); cbRead = 0; vrc = pProcess->i_readData(OUTPUT_HANDLE_ID_STDOUT, sizeof(byBuf), GET_REMAINING_TIME, byBuf, sizeof(byBuf), &cbRead, &vrcGuest); if ( RT_FAILURE(vrc) || vrc == VWRN_GSTCTL_OBJECTSTATE_CHANGED) break; if (cbRead) { LogFlowThisFunc(("Received %RU32 bytes from stdout\n", cbRead)); vrc = mStdOut.AddData(byBuf, cbRead); if ( RT_SUCCESS(vrc) && (fFlags & GUESTPROCESSTOOL_FLAG_STDOUT_BLOCK)) { AssertPtr(pStrmBlkOut); vrc = i_getCurrentBlock(OUTPUT_HANDLE_ID_STDOUT, *pStrmBlkOut); /* When successful, break out of the loop because we're done * with reading the first stream block. */ if (RT_SUCCESS(vrc)) fDone = true; } } fHandleStdOut = false; } if (fHandleStdErr) { UPDATE_AND_CHECK_ELAPSED_TIME(); cbRead = 0; vrc = pProcess->i_readData(OUTPUT_HANDLE_ID_STDERR, sizeof(byBuf), GET_REMAINING_TIME, byBuf, sizeof(byBuf), &cbRead, &vrcGuest); if ( RT_FAILURE(vrc) || vrc == VWRN_GSTCTL_OBJECTSTATE_CHANGED) break; if (cbRead) { LogFlowThisFunc(("Received %RU32 bytes from stderr\n", cbRead)); vrc = mStdErr.AddData(byBuf, cbRead); } fHandleStdErr = false; } } while (!fDone && RT_SUCCESS(vrc)); #undef UPDATE_AND_CHECK_ELAPSED_TIME #undef GET_REMAINING_TIME if (RT_FAILURE(vrcGuest)) vrc = VERR_GSTCTL_GUEST_ERROR; LogFlowThisFunc(("Loop ended with rc=%Rrc, vrcGuest=%Rrc, waitRes=%RU32\n", vrc, vrcGuest, waitRes)); if (pGuestRc) *pGuestRc = vrcGuest; LogFlowFuncLeaveRC(vrc); return vrc; } int GuestProcessTool::i_terminate(uint32_t uTimeoutMS, int *pGuestRc) { LogFlowThisFuncEnter(); int rc = VINF_SUCCESS; if (!pProcess.isNull()) { rc = pProcess->i_terminateProcess(uTimeoutMS, pGuestRc); pProcess.setNull(); } else rc = VERR_NOT_FOUND; LogFlowFuncLeaveRC(rc); return rc; } /** * Converts a toolbox tool's exit code to an IPRT error code. * * @return int Returned IPRT error for the particular tool. * @param startupInfo Startup info of the toolbox tool to lookup error code for. * @param lExitCode The toolbox tool's exit code to lookup IPRT error for. */ /* static */ int GuestProcessTool::i_exitCodeToRc(const GuestProcessStartupInfo &startupInfo, LONG lExitCode) { if (startupInfo.mArguments.size() == 0) { AssertFailed(); return VERR_GENERAL_FAILURE; /* Should not happen. */ } return i_exitCodeToRc(startupInfo.mArguments[0].c_str(), lExitCode); } /** * Converts a toolbox tool's exit code to an IPRT error code. * * @return Returned IPRT error for the particular tool. * @param pszTool Name of toolbox tool to lookup error code for. * @param lExitCode The toolbox tool's exit code to lookup IPRT error for. */ /* static */ int GuestProcessTool::i_exitCodeToRc(const char *pszTool, LONG lExitCode) { AssertPtrReturn(pszTool, VERR_INVALID_POINTER); LogFlowFunc(("%s: %ld\n", pszTool, lExitCode)); if (lExitCode == 0) /* No error? Bail out early. */ return VINF_SUCCESS; if (!RTStrICmp(pszTool, VBOXSERVICE_TOOL_CAT)) { switch (lExitCode) { case VBOXSERVICETOOLBOX_CAT_EXITCODE_ACCESS_DENIED: return VERR_ACCESS_DENIED; case VBOXSERVICETOOLBOX_CAT_EXITCODE_FILE_NOT_FOUND: return VERR_FILE_NOT_FOUND; case VBOXSERVICETOOLBOX_CAT_EXITCODE_PATH_NOT_FOUND: return VERR_PATH_NOT_FOUND; case VBOXSERVICETOOLBOX_CAT_EXITCODE_SHARING_VIOLATION: return VERR_SHARING_VIOLATION; default: break; } } else if (!RTStrICmp(pszTool, VBOXSERVICE_TOOL_STAT)) { switch (lExitCode) { case VBOXSERVICETOOLBOX_STAT_EXITCODE_ACCESS_DENIED: return VERR_ACCESS_DENIED; case VBOXSERVICETOOLBOX_STAT_EXITCODE_FILE_NOT_FOUND: return VERR_FILE_NOT_FOUND; case VBOXSERVICETOOLBOX_STAT_EXITCODE_PATH_NOT_FOUND: return VERR_PATH_NOT_FOUND; default: break; } } AssertMsgFailed(("Error code %ld for tool '%s' not handled\n", lExitCode, pszTool)); return VERR_GENERAL_FAILURE; }