/** * @file llqueuedthread.cpp * * Copyright (c) 2004-2007, 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://secondlife.com/developers/opensource/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://secondlife.com/developers/opensource/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. */ #include "linden_common.h" #include "llqueuedthread.h" #include "llstl.h" //============================================================================ // MAIN THREAD LLQueuedThread::LLQueuedThread(const std::string& name, bool threaded) : LLThread(name), mThreaded(threaded), mIdleThread(TRUE), mNextHandle(0) { if (mThreaded) { start(); } } // MAIN THREAD LLQueuedThread::~LLQueuedThread() { shutdown(); // ~LLThread() will be called here } void LLQueuedThread::shutdown() { setQuitting(); unpause(); // MAIN THREAD if (mThreaded) { S32 timeout = 100; for ( ; timeout>0; timeout--) { if (isStopped()) { break; } ms_sleep(100); LLThread::yield(); } if (timeout == 0) { llwarns << "~LLQueuedThread (" << mName << ") timed out!" << llendl; } } else { mStatus = STOPPED; } QueuedRequest* req; S32 active_count = 0; while ( (req = (QueuedRequest*)mRequestHash.pop_element()) ) { if (req->getStatus() == STATUS_QUEUED || req->getStatus() == STATUS_INPROGRESS) { ++active_count; } req->deleteRequest(); } if (active_count) { llwarns << "~LLQueuedThread() called with active requests: " << active_count << llendl; } } //---------------------------------------------------------------------------- // MAIN THREAD // virtual S32 LLQueuedThread::update(U32 max_time_ms) { return updateQueue(max_time_ms); } S32 LLQueuedThread::updateQueue(U32 max_time_ms) { F64 max_time = (F64)max_time_ms * .001; LLTimer timer; S32 pending = 1; // Frame Update if (mThreaded) { pending = getPending(); unpause(); } else { while (pending > 0) { pending = processNextRequest(); if (max_time && timer.getElapsedTimeF64() > max_time) break; } } return pending; } void LLQueuedThread::incQueue() { // Something has been added to the queue if (!isPaused()) { if (mThreaded) { wake(); // Wake the thread up if necessary. } } } //virtual // May be called from any thread S32 LLQueuedThread::getPending() { S32 res; lockData(); res = mRequestQueue.size(); unlockData(); return res; } // MAIN thread void LLQueuedThread::waitOnPending() { while(1) { update(0); if (mIdleThread) { break; } if (mThreaded) { yield(); } } return; } // MAIN thread void LLQueuedThread::printQueueStats() { lockData(); if (!mRequestQueue.empty()) { QueuedRequest *req = *mRequestQueue.begin(); llinfos << llformat("Pending Requests:%d Current status:%d", mRequestQueue.size(), req->getStatus()) << llendl; } else { llinfos << "Queued Thread Idle" << llendl; } unlockData(); } // MAIN thread LLQueuedThread::handle_t LLQueuedThread::generateHandle() { lockData(); while ((mNextHandle == nullHandle()) || (mRequestHash.find(mNextHandle))) { mNextHandle++; } unlockData(); return mNextHandle++; } // MAIN thread bool LLQueuedThread::addRequest(QueuedRequest* req) { if (mStatus == QUITTING) { return false; } lockData(); req->setStatus(STATUS_QUEUED); mRequestQueue.insert(req); mRequestHash.insert(req); #if _DEBUG // llinfos << llformat("LLQueuedThread::Added req [%08d]",handle) << llendl; #endif unlockData(); incQueue(); return true; } // MAIN thread bool LLQueuedThread::waitForResult(LLQueuedThread::handle_t handle, bool auto_complete) { llassert (handle != nullHandle()) bool res = false; bool waspaused = isPaused(); bool done = false; while(!done) { update(0); // unpauses lockData(); QueuedRequest* req = (QueuedRequest*)mRequestHash.find(handle); if (!req) { done = true; // request does not exist } else if (req->getStatus() == STATUS_COMPLETE) { res = true; if (auto_complete) { mRequestHash.erase(handle); req->deleteRequest(); // check(); } done = true; } unlockData(); if (!done && mThreaded) { yield(); } } if (waspaused) { pause(); } return res; } // MAIN thread LLQueuedThread::QueuedRequest* LLQueuedThread::getRequest(handle_t handle) { if (handle == nullHandle()) { return 0; } lockData(); QueuedRequest* res = (QueuedRequest*)mRequestHash.find(handle); unlockData(); return res; } LLQueuedThread::status_t LLQueuedThread::getRequestStatus(handle_t handle) { status_t res = STATUS_EXPIRED; lockData(); QueuedRequest* req = (QueuedRequest*)mRequestHash.find(handle); if (req) { res = req->getStatus(); } unlockData(); return res; } void LLQueuedThread::abortRequest(handle_t handle, bool autocomplete) { lockData(); QueuedRequest* req = (QueuedRequest*)mRequestHash.find(handle); if (req) { req->setFlags(FLAG_ABORT | (autocomplete ? FLAG_AUTO_COMPLETE : 0)); } unlockData(); } // MAIN thread void LLQueuedThread::setFlags(handle_t handle, U32 flags) { lockData(); QueuedRequest* req = (QueuedRequest*)mRequestHash.find(handle); if (req) { req->setFlags(flags); } unlockData(); } void LLQueuedThread::setPriority(handle_t handle, U32 priority) { lockData(); QueuedRequest* req = (QueuedRequest*)mRequestHash.find(handle); if (req) { if(req->getStatus() == STATUS_INPROGRESS) { // not in list req->setPriority(priority); } else if(req->getStatus() == STATUS_QUEUED) { // remove from list then re-insert llverify(mRequestQueue.erase(req) == 1); req->setPriority(priority); mRequestQueue.insert(req); } } unlockData(); } bool LLQueuedThread::completeRequest(handle_t handle) { bool res = false; lockData(); QueuedRequest* req = (QueuedRequest*)mRequestHash.find(handle); if (req) { llassert_always(req->getStatus() != STATUS_QUEUED); llassert_always(req->getStatus() != STATUS_INPROGRESS); #if _DEBUG // llinfos << llformat("LLQueuedThread::Completed req [%08d]",handle) << llendl; #endif mRequestHash.erase(handle); req->deleteRequest(); // check(); res = true; } unlockData(); return res; } bool LLQueuedThread::check() { #if 0 // not a reliable check once mNextHandle wraps, just for quick and dirty debugging for (int i=0; i* entry = mRequestHash.get_element_at_index(i); while (entry) { if (entry->getHashKey() > mNextHandle) { llerrs << "Hash Error" << llendl; return false; } entry = entry->getNextEntry(); } } #endif return true; } //============================================================================ // Runs on its OWN thread S32 LLQueuedThread::processNextRequest() { QueuedRequest *req; // Get next request from pool lockData(); while(1) { req = NULL; if (mRequestQueue.empty()) { break; } req = *mRequestQueue.begin(); mRequestQueue.erase(mRequestQueue.begin()); if ((req->getFlags() & FLAG_ABORT) || (mStatus == QUITTING)) { req->setStatus(STATUS_ABORTED); req->finishRequest(false); if (req->getFlags() & FLAG_AUTO_COMPLETE) { mRequestHash.erase(req); req->deleteRequest(); // check(); } continue; } llassert_always(req->getStatus() == STATUS_QUEUED); break; } if (req) { req->setStatus(STATUS_INPROGRESS); } unlockData(); // This is the only place we will call req->setStatus() after // it has initially been seet to STATUS_QUEUED, so it is // safe to access req. if (req) { // process request bool complete = req->processRequest(); if (complete) { lockData(); req->setStatus(STATUS_COMPLETE); req->finishRequest(true); if (req->getFlags() & FLAG_AUTO_COMPLETE) { mRequestHash.erase(req); req->deleteRequest(); // check(); } unlockData(); } else { lockData(); req->setStatus(STATUS_QUEUED); mRequestQueue.insert(req); U32 priority = req->getPriority(); unlockData(); if (priority < PRIORITY_NORMAL) { ms_sleep(1); // sleep the thread a little } } } S32 res; S32 pending = getPending(); if (pending == 0) { if (isQuitting()) { res = -1; // exit thread } else { res = 0; } } else { res = pending; } return res; } bool LLQueuedThread::runCondition() { // mRunCondition must be locked here if (mRequestQueue.empty() && mIdleThread) return false; else return true; } void LLQueuedThread::run() { while (1) { // this will block on the condition until runCondition() returns true, the thread is unpaused, or the thread leaves the RUNNING state. checkPause(); if(isQuitting()) break; //llinfos << "QUEUED THREAD RUNNING, queue size = " << mRequestQueue.size() << llendl; mIdleThread = FALSE; int res = processNextRequest(); if (res == 0) { mIdleThread = TRUE; } if (res < 0) // finished working and want to exit { break; } //LLThread::yield(); // thread should yield after each request } llinfos << "QUEUED THREAD " << mName << " EXITING." << llendl; } //============================================================================ LLQueuedThread::QueuedRequest::QueuedRequest(LLQueuedThread::handle_t handle, U32 priority, U32 flags) : LLSimpleHashEntry(handle), mStatus(STATUS_UNKNOWN), mPriority(priority), mFlags(flags) { } LLQueuedThread::QueuedRequest::~QueuedRequest() { llassert_always(mStatus == STATUS_DELETE); } //virtual void LLQueuedThread::QueuedRequest::finishRequest(bool completed) { } //virtual void LLQueuedThread::QueuedRequest::deleteRequest() { llassert_always(mStatus != STATUS_INPROGRESS); setStatus(STATUS_DELETE); delete this; }