406 lines
11 KiB
C++
406 lines
11 KiB
C++
// Copyright 2009-2021 Intel Corporation
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// SPDX-License-Identifier: Apache-2.0
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#include "taskschedulerinternal.h"
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#include "../math/emath.h"
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#include "../sys/sysinfo.h"
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#include <algorithm>
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namespace embree
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{
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RTC_NAMESPACE_BEGIN
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static MutexSys g_mutex;
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size_t TaskScheduler::g_numThreads = 0;
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__thread TaskScheduler* TaskScheduler::g_instance = nullptr;
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std::vector<Ref<TaskScheduler>> g_instance_vector;
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__thread TaskScheduler::Thread* TaskScheduler::thread_local_thread = nullptr;
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TaskScheduler::ThreadPool* TaskScheduler::threadPool = nullptr;
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template<typename Predicate, typename Body>
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__forceinline void TaskScheduler::steal_loop(Thread& thread, const Predicate& pred, const Body& body)
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{
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while (true)
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{
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/*! some rounds that yield */
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for (size_t i=0; i<32; i++)
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{
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/*! some spinning rounds */
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const size_t threadCount = thread.threadCount();
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for (size_t j=0; j<1024; j+=threadCount)
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{
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if (!pred()) return;
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if (thread.scheduler->steal_from_other_threads(thread)) {
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i=j=0;
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body();
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}
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}
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yield();
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}
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}
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}
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/*! run this task */
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void TaskScheduler::Task::run_internal (Thread& thread) // FIXME: avoid as many dll_exports as possible
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{
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/* try to run if not already stolen */
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if (try_switch_state(INITIALIZED,DONE))
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{
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Task* prevTask = thread.task;
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thread.task = this;
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// -- GODOT start --
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// try {
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// if (context->cancellingException == nullptr)
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closure->execute();
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// } catch (...) {
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// if (context->cancellingException == nullptr)
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// context->cancellingException = std::current_exception();
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// }
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// -- GODOT end --
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thread.task = prevTask;
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add_dependencies(-1);
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}
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/* steal until all dependencies have completed */
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steal_loop(thread,
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[&] () { return dependencies>0; },
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[&] () { while (thread.tasks.execute_local_internal(thread,this)); });
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/* now signal our parent task that we are finished */
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if (parent)
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parent->add_dependencies(-1);
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}
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/*! run this task */
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dll_export void TaskScheduler::Task::run (Thread& thread) {
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run_internal(thread);
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}
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bool TaskScheduler::TaskQueue::execute_local_internal(Thread& thread, Task* parent)
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{
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/* stop if we run out of local tasks or reach the waiting task */
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if (right == 0 || &tasks[right-1] == parent)
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return false;
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/* execute task */
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size_t oldRight = right;
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tasks[right-1].run_internal(thread);
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if (right != oldRight) {
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THROW_RUNTIME_ERROR("you have to wait for spawned subtasks");
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}
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/* pop task and closure from stack */
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right--;
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if (tasks[right].stackPtr != size_t(-1))
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stackPtr = tasks[right].stackPtr;
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/* also move left pointer */
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if (left >= right) left.store(right.load());
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return right != 0;
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}
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dll_export bool TaskScheduler::TaskQueue::execute_local(Thread& thread, Task* parent) {
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return execute_local_internal(thread,parent);
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}
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bool TaskScheduler::TaskQueue::steal(Thread& thread)
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{
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size_t l = left;
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size_t r = right;
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if (l < r)
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{
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l = left++;
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if (l >= r)
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return false;
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}
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else
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return false;
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if (!tasks[l].try_steal(thread.tasks.tasks[thread.tasks.right]))
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return false;
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thread.tasks.right++;
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return true;
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}
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/* we steal from the left */
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size_t TaskScheduler::TaskQueue::getTaskSizeAtLeft()
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{
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if (left >= right) return 0;
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return tasks[left].N;
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}
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void threadPoolFunction(std::pair<TaskScheduler::ThreadPool*,size_t>* pair)
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{
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TaskScheduler::ThreadPool* pool = pair->first;
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size_t threadIndex = pair->second;
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delete pair;
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pool->thread_loop(threadIndex);
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}
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TaskScheduler::ThreadPool::ThreadPool(bool set_affinity)
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: numThreads(0), numThreadsRunning(0), set_affinity(set_affinity), running(false) {}
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dll_export void TaskScheduler::ThreadPool::startThreads()
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{
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if (running) return;
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setNumThreads(numThreads,true);
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}
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void TaskScheduler::ThreadPool::setNumThreads(size_t newNumThreads, bool startThreads)
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{
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Lock<MutexSys> lock(g_mutex);
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assert(newNumThreads);
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if (newNumThreads == std::numeric_limits<size_t>::max())
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newNumThreads = (size_t) getNumberOfLogicalThreads();
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numThreads = newNumThreads;
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if (!startThreads && !running) return;
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running = true;
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size_t numThreadsActive = numThreadsRunning;
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mutex.lock();
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numThreadsRunning = newNumThreads;
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mutex.unlock();
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condition.notify_all();
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/* start new threads */
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for (size_t t=numThreadsActive; t<numThreads; t++)
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{
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if (t == 0) continue;
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auto pair = new std::pair<TaskScheduler::ThreadPool*,size_t>(this,t);
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threads.push_back(createThread((thread_func)threadPoolFunction,pair,4*1024*1024,set_affinity ? t : -1));
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}
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/* stop some threads if we reduce the number of threads */
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for (ssize_t t=numThreadsActive-1; t>=ssize_t(numThreadsRunning); t--) {
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if (t == 0) continue;
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embree::join(threads.back());
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threads.pop_back();
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}
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}
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TaskScheduler::ThreadPool::~ThreadPool()
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{
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/* leave all taskschedulers */
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mutex.lock();
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numThreadsRunning = 0;
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mutex.unlock();
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condition.notify_all();
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/* wait for threads to terminate */
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for (size_t i=0; i<threads.size(); i++)
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embree::join(threads[i]);
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}
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dll_export void TaskScheduler::ThreadPool::add(const Ref<TaskScheduler>& scheduler)
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{
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mutex.lock();
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schedulers.push_back(scheduler);
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mutex.unlock();
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condition.notify_all();
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}
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dll_export void TaskScheduler::ThreadPool::remove(const Ref<TaskScheduler>& scheduler)
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{
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Lock<MutexSys> lock(mutex);
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for (std::list<Ref<TaskScheduler> >::iterator it = schedulers.begin(); it != schedulers.end(); it++) {
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if (scheduler == *it) {
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schedulers.erase(it);
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return;
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}
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}
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}
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void TaskScheduler::ThreadPool::thread_loop(size_t globalThreadIndex)
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{
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while (globalThreadIndex < numThreadsRunning)
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{
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Ref<TaskScheduler> scheduler = NULL;
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ssize_t threadIndex = -1;
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{
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Lock<MutexSys> lock(mutex);
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condition.wait(mutex, [&] () { return globalThreadIndex >= numThreadsRunning || !schedulers.empty(); });
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if (globalThreadIndex >= numThreadsRunning) break;
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scheduler = schedulers.front();
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threadIndex = scheduler->allocThreadIndex();
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}
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scheduler->thread_loop(threadIndex);
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}
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}
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TaskScheduler::TaskScheduler()
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: threadCounter(0), anyTasksRunning(0), hasRootTask(false)
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{
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assert(threadPool);
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threadLocal.resize(2 * TaskScheduler::threadCount()); // FIXME: this has to be 2x as in the compatibility join mode with rtcCommitScene the worker threads also join. When disallowing rtcCommitScene to join a build we can remove the 2x.
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for (size_t i=0; i<threadLocal.size(); i++)
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threadLocal[i].store(nullptr);
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}
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TaskScheduler::~TaskScheduler()
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{
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assert(threadCounter == 0);
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}
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dll_export size_t TaskScheduler::threadID()
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{
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Thread* thread = TaskScheduler::thread();
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if (thread) return thread->threadIndex;
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else return 0;
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}
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dll_export size_t TaskScheduler::threadIndex()
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{
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Thread* thread = TaskScheduler::thread();
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if (thread) return thread->threadIndex;
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else return 0;
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}
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dll_export size_t TaskScheduler::threadCount() {
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return threadPool->size();
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}
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dll_export TaskScheduler* TaskScheduler::instance()
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{
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if (g_instance == NULL) {
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Lock<MutexSys> lock(g_mutex);
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g_instance = new TaskScheduler;
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g_instance_vector.push_back(g_instance);
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}
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return g_instance;
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}
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void TaskScheduler::create(size_t numThreads, bool set_affinity, bool start_threads)
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{
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if (!threadPool) threadPool = new TaskScheduler::ThreadPool(set_affinity);
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threadPool->setNumThreads(numThreads,start_threads);
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}
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void TaskScheduler::destroy() {
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delete threadPool; threadPool = nullptr;
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}
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dll_export ssize_t TaskScheduler::allocThreadIndex()
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{
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size_t threadIndex = threadCounter++;
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assert(threadIndex < threadLocal.size());
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return threadIndex;
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}
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void TaskScheduler::join()
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{
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mutex.lock();
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size_t threadIndex = allocThreadIndex();
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condition.wait(mutex, [&] () { return hasRootTask.load(); });
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mutex.unlock();
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thread_loop(threadIndex);
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}
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void TaskScheduler::reset() {
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hasRootTask = false;
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}
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void TaskScheduler::wait_for_threads(size_t threadCount)
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{
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while (threadCounter < threadCount-1)
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pause_cpu();
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}
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dll_export TaskScheduler::Thread* TaskScheduler::thread() {
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return thread_local_thread;
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}
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dll_export TaskScheduler::Thread* TaskScheduler::swapThread(Thread* thread)
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{
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Thread* old = thread_local_thread;
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thread_local_thread = thread;
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return old;
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}
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dll_export void TaskScheduler::wait()
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{
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Thread* thread = TaskScheduler::thread();
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if (thread == nullptr)
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return;
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while (thread->tasks.execute_local_internal(*thread,thread->task)) {};
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}
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void TaskScheduler::thread_loop(size_t threadIndex)
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{
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/* allocate thread structure */
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std::unique_ptr<Thread> mthread(new Thread(threadIndex,this)); // too large for stack allocation
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Thread& thread = *mthread;
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threadLocal[threadIndex].store(&thread);
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Thread* oldThread = swapThread(&thread);
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/* main thread loop */
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while (anyTasksRunning)
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{
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steal_loop(thread,
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[&] () { return anyTasksRunning > 0; },
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[&] () {
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anyTasksRunning++;
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while (thread.tasks.execute_local_internal(thread,nullptr));
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anyTasksRunning--;
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});
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}
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threadLocal[threadIndex].store(nullptr);
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swapThread(oldThread);
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/* wait for all threads to terminate */
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threadCounter--;
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#if defined(__WIN32__)
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size_t loopIndex = 1;
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#endif
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#define LOOP_YIELD_THRESHOLD (4096)
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while (threadCounter > 0) {
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#if defined(__WIN32__)
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if ((loopIndex % LOOP_YIELD_THRESHOLD) == 0)
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yield();
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else
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_mm_pause();
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loopIndex++;
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#else
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yield();
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#endif
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}
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}
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bool TaskScheduler::steal_from_other_threads(Thread& thread)
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{
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const size_t threadIndex = thread.threadIndex;
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const size_t threadCount = this->threadCounter;
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for (size_t i=1; i<threadCount; i++)
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{
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pause_cpu(32);
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size_t otherThreadIndex = threadIndex+i;
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if (otherThreadIndex >= threadCount) otherThreadIndex -= threadCount;
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Thread* othread = threadLocal[otherThreadIndex].load();
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if (!othread)
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continue;
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if (othread->tasks.steal(thread))
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return true;
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}
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return false;
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}
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dll_export void TaskScheduler::startThreads() {
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threadPool->startThreads();
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}
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dll_export void TaskScheduler::addScheduler(const Ref<TaskScheduler>& scheduler) {
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threadPool->add(scheduler);
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}
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dll_export void TaskScheduler::removeScheduler(const Ref<TaskScheduler>& scheduler) {
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threadPool->remove(scheduler);
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}
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RTC_NAMESPACE_END
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}
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