/** * @file llthreadwatchdog.cpp * @brief The LLThreadWatchdog class definitions * * $LicenseInfo:firstyear=2007&license=viewergpl$ * * Copyright (c) 2007-2009, Linden Research, Inc. * * Second Life Viewer Source Code * The source code in this file ("Source Code") is provided by Linden Lab * to you under the terms of the GNU General Public License, version 2.0 * ("GPL"), unless you have obtained a separate licensing agreement * ("Other License"), formally executed by you and Linden Lab. Terms of * the GPL can be found in doc/GPL-license.txt in this distribution, or * online at http://secondlifegrid.net/programs/open_source/licensing/gplv2 * * There are special exceptions to the terms and conditions of the GPL as * it is applied to this Source Code. View the full text of the exception * in the file doc/FLOSS-exception.txt in this software distribution, or * online at * http://secondlifegrid.net/programs/open_source/licensing/flossexception * * By copying, modifying or distributing this software, you acknowledge * that you have read and understood your obligations described above, * and agree to abide by those obligations. * * ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO * WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY, * COMPLETENESS OR PERFORMANCE. * $/LicenseInfo$ */ #include "llviewerprecompiledheaders.h" #include "llwatchdog.h" const U32 WATCHDOG_SLEEP_TIME_USEC = 1000000; void default_killer_callback() { #ifdef LL_WINDOWS RaiseException(0,0,0,0); #else raise(SIGQUIT); #endif } // This class runs the watchdog timing thread. class LLWatchdogTimerThread : public LLThread { public: LLWatchdogTimerThread() : LLThread("Watchdog"), mSleepMsecs(0), mStopping(false) { } ~LLWatchdogTimerThread() {} void setSleepTime(long ms) { mSleepMsecs = ms; } void stop() { mStopping = true; mSleepMsecs = 1; } /* virtual */ void run() { while(!mStopping) { LLWatchdog::getInstance()->run(); ms_sleep(mSleepMsecs); } } private: long mSleepMsecs; bool mStopping; }; // LLWatchdogEntry LLWatchdogEntry::LLWatchdogEntry() { } LLWatchdogEntry::~LLWatchdogEntry() { stop(); } void LLWatchdogEntry::start() { LLWatchdog::getInstance()->add(this); } void LLWatchdogEntry::stop() { LLWatchdog::getInstance()->remove(this); } // LLWatchdogTimeout const std::string UNINIT_STRING = "uninitialized"; LLWatchdogTimeout::LLWatchdogTimeout() : mTimeout(0.0f), mPingState(UNINIT_STRING) { } LLWatchdogTimeout::~LLWatchdogTimeout() { } bool LLWatchdogTimeout::isAlive() const { return (mTimer.getStarted() && !mTimer.hasExpired()); } void LLWatchdogTimeout::reset() { mTimer.setTimerExpirySec(mTimeout); } void LLWatchdogTimeout::setTimeout(F32 d) { mTimeout = d; } void LLWatchdogTimeout::start(const std::string& state) { // Order of operation is very impmortant here. // After LLWatchdogEntry::start() is called // LLWatchdogTimeout::isAlive() will be called asynchronously. mTimer.start(); ping(state); LLWatchdogEntry::start(); } void LLWatchdogTimeout::stop() { LLWatchdogEntry::stop(); mTimer.stop(); } void LLWatchdogTimeout::ping(const std::string& state) { if(!state.empty()) { mPingState = state; } reset(); } // LLWatchdog LLWatchdog::LLWatchdog() : mSuspectsAccessMutex(NULL), mTimer(NULL), mLastClockCount(0), mKillerCallback(&default_killer_callback) { } LLWatchdog::~LLWatchdog() { } void LLWatchdog::add(LLWatchdogEntry* e) { lockThread(); mSuspects.insert(e); unlockThread(); } void LLWatchdog::remove(LLWatchdogEntry* e) { lockThread(); mSuspects.erase(e); unlockThread(); } void LLWatchdog::init(killer_event_callback func) { mKillerCallback = func; if(!mSuspectsAccessMutex && !mTimer) { mSuspectsAccessMutex = new LLMutex; mTimer = new LLWatchdogTimerThread; mTimer->setSleepTime(WATCHDOG_SLEEP_TIME_USEC / 1000); mLastClockCount = LLTimer::getTotalTime(); // mTimer->start() kicks off the thread, any code after // start needs to use the mSuspectsAccessMutex mTimer->start(); } } void LLWatchdog::cleanup() { if(mTimer) { mTimer->stop(); delete mTimer; mTimer = NULL; } if(mSuspectsAccessMutex) { delete mSuspectsAccessMutex; mSuspectsAccessMutex = NULL; } mLastClockCount = 0; } void LLWatchdog::run() { lockThread(); // Check the time since the last call to run... // If the time elapsed is two times greater than the regualr sleep time // reset the active timeouts. const U32 TIME_ELAPSED_MULTIPLIER = 2; U64 current_time = LLTimer::getTotalTime(); U64 current_run_delta = current_time - mLastClockCount; mLastClockCount = current_time; if(current_run_delta > (WATCHDOG_SLEEP_TIME_USEC * TIME_ELAPSED_MULTIPLIER)) { llinfos << "Watchdog thread delayed: resetting entries." << llendl; std::for_each(mSuspects.begin(), mSuspects.end(), std::mem_fun(&LLWatchdogEntry::reset) ); } else { SuspectsRegistry::iterator result = std::find_if(mSuspects.begin(), mSuspects.end(), std::not1(std::mem_fun(&LLWatchdogEntry::isAlive)) ); if(result != mSuspects.end()) { // error!!! if(mTimer) { mTimer->stop(); } llinfos << "Watchdog detected error:" << llendl; mKillerCallback(); } } unlockThread(); } void LLWatchdog::lockThread() { if(mSuspectsAccessMutex != NULL) { mSuspectsAccessMutex->lock(); } } void LLWatchdog::unlockThread() { if(mSuspectsAccessMutex != NULL) { mSuspectsAccessMutex->unlock(); } }