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194 lines
5.5 KiB
C++
194 lines
5.5 KiB
C++
//
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// AsyncTaskQueue.hpp
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// Clock Signal
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//
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// Created by Thomas Harte on 07/10/2016.
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// Copyright 2016 Thomas Harte. All rights reserved.
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//
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#ifndef AsyncTaskQueue_hpp
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#define AsyncTaskQueue_hpp
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#include <atomic>
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#include <condition_variable>
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#include <functional>
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#include <thread>
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#include <vector>
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#include "../ClockReceiver/TimeTypes.hpp"
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namespace Concurrency {
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/// An implementation detail; provides the time-centric part of a TaskQueue with a real Performer.
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template <typename Performer> struct TaskQueueStorage {
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template <typename... Args> TaskQueueStorage(Args&&... args) :
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performer(std::forward<Args>(args)...),
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last_fired_(Time::nanos_now()) {}
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Performer performer;
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protected:
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void update() {
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auto time_now = Time::nanos_now();
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performer.perform(time_now - last_fired_);
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last_fired_ = time_now;
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}
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private:
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Time::Nanos last_fired_;
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};
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/// An implementation detail; provides a no-op implementation of time advances for TaskQueues without a Performer.
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template <> struct TaskQueueStorage<void> {
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TaskQueueStorage() {}
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protected:
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void update() {}
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};
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/*!
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A task queue allows a caller to enqueue @c void(void) functions. Those functions are guaranteed
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to be performed serially and asynchronously from the caller.
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If @c perform_automatically is true, functions will be performed as soon as is possible,
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at the cost of thread synchronisation.
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If @c perform_automatically is false, functions will be queued up but not dispatched
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until a call to perform().
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If a @c Performer type is supplied then a public member, @c performer will be constructed
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with the arguments supplied to TaskQueue's constructor. That instance will receive calls of the
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form @c .perform(nanos) before every batch of new actions, indicating how much time has
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passed since the previous @c perform.
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@note Even if @c perform_automatically is true, actions may be batched, when a long-running
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action occupies the asynchronous thread for long enough. So it is not true that @c perform will be
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called once per action.
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*/
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template <bool perform_automatically, bool start_immediately = true, typename Performer = void> class AsyncTaskQueue: public TaskQueueStorage<Performer> {
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public:
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template <typename... Args> AsyncTaskQueue(Args&&... args) :
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TaskQueueStorage<Performer>(std::forward<Args>(args)...) {
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if constexpr (start_immediately) {
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start();
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}
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}
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/// Enqueus @c post_action to be performed asynchronously at some point
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/// in the future. If @c perform_automatically is @c true then the action
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/// will be performed as soon as possible. Otherwise it will sit unsheculed until
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/// a call to @c perform().
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///
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/// Actions may be elided.
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///
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/// If this TaskQueue has a @c Performer then the action will be performed
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/// on the same thread as the performer, after the performer has been updated
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/// to 'now'.
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void enqueue(const std::function<void(void)> &post_action) {
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std::lock_guard guard(condition_mutex_);
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actions_.push_back(post_action);
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if constexpr (perform_automatically) {
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condition_.notify_all();
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}
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}
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/// Causes any enqueued actions that are not yet scheduled to be scheduled.
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void perform() {
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if(actions_.empty()) {
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return;
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}
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condition_.notify_all();
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}
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/// Permanently stops this task queue, blocking until that has happened.
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/// All pending actions will be performed first.
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///
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/// The queue cannot be restarted; this is a destructive action.
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void stop() {
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if(thread_.joinable()) {
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should_quit_ = true;
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enqueue([] {});
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if constexpr (!perform_automatically) {
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perform();
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}
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thread_.join();
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}
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}
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/// Starts the queue if it has never been started before.
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///
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/// This is not guaranteed safely to restart a stopped queue.
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void start() {
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thread_ = std::move(std::thread{
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[this] {
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ActionVector actions;
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// Continue until told to quit.
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while(!should_quit_) {
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// Wait for new actions to be signalled, and grab them.
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std::unique_lock lock(condition_mutex_);
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while(actions_.empty()) {
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condition_.wait(lock);
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}
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std::swap(actions, actions_);
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lock.unlock();
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// Update to now (which is possibly a no-op).
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TaskQueueStorage<Performer>::update();
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// Perform the actions and destroy them.
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for(const auto &action: actions) {
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action();
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}
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actions.clear();
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}
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}
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});
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}
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/// Schedules any remaining unscheduled work, then blocks synchronously
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/// until all scheduled work has been performed.
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void flush() {
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std::mutex flush_mutex;
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std::condition_variable flush_condition;
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bool has_run = false;
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std::unique_lock lock(flush_mutex);
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enqueue([&flush_mutex, &flush_condition, &has_run] () {
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std::unique_lock inner_lock(flush_mutex);
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has_run = true;
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flush_condition.notify_all();
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});
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if constexpr (!perform_automatically) {
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perform();
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}
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flush_condition.wait(lock, [&has_run] { return has_run; });
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}
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~AsyncTaskQueue() {
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stop();
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}
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private:
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// The list of actions waiting be performed. These will be elided,
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// increasing their latency, if the emulation thread falls behind.
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using ActionVector = std::vector<std::function<void(void)>>;
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ActionVector actions_;
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// Necessary synchronisation parts.
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std::atomic<bool> should_quit_ = false;
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std::mutex condition_mutex_;
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std::condition_variable condition_;
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// Ensure the thread isn't constructed until after the mutex
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// and condition variable.
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std::thread thread_;
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};
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}
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#endif /* AsyncTaskQueue_hpp */
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