/** * @file threadsafeschedule.h * @author Nat Goodspeed * @date 2021-10-02 * @brief ThreadSafeSchedule is an ordered queue in which every item has an * associated timestamp. * * $LicenseInfo:firstyear=2021&license=viewerlgpl$ * Copyright (c) 2021, Linden Research, Inc. * $/LicenseInfo$ */ #if ! defined(LL_THREADSAFESCHEDULE_H) #define LL_THREADSAFESCHEDULE_H #include "chrono.h" #include "llexception.h" #include "llthreadsafequeue.h" #include "tuple.h" #include #include namespace LL { namespace ThreadSafeSchedulePrivate { using TimePoint = std::chrono::steady_clock::time_point; // Bundle consumer's data with a TimePoint to order items by timestamp. template using TimestampedTuple = std::tuple; // comparison functor for TimedTuples -- see TimedQueue comments struct ReverseTupleOrder { template bool operator()(const Tuple& left, const Tuple& right) const { return std::get<0>(left) > std::get<0>(right); } }; template using TimedQueue = PriorityQueueAdapter< TimestampedTuple, // std::vector is the default storage for std::priority_queue, // have to restate to specify comparison template parameter std::vector>, // std::priority_queue uses a counterintuitive comparison // behavior: the default std::less comparator is used to present // the *highest* value as top(). So to sort by earliest timestamp, // we must invert by using >. ReverseTupleOrder>; } // namespace ThreadSafeSchedulePrivate /** * ThreadSafeSchedule is an ordered LLThreadSafeQueue in which every item * is given an associated timestamp. That is, TimePoint is implicitly * prepended to the std::tuple with the specified types. * * Items are popped in increasing chronological order. Moreover, any item * with a timestamp in the future is held back until * std::chrono::steady_clock reaches that timestamp. */ template class ThreadSafeSchedule: public LLThreadSafeQueue, ThreadSafeSchedulePrivate::TimedQueue> { public: using DataTuple = std::tuple; using TimeTuple = ThreadSafeSchedulePrivate::TimestampedTuple; private: using super = LLThreadSafeQueue>; using lock_t = typename super::lock_t; // VS 2017 needs this due to a bug: // https://developercommunity.visualstudio.com/t/cannot-access-protected-enumerator-of-enclosing-cl/203430 enum pop_result { EMPTY=super::EMPTY, DONE=super::DONE, WAITING=super::WAITING, POPPED=super::POPPED }; public: using Closed = LLThreadSafeQueueInterrupt; using TimePoint = ThreadSafeSchedulePrivate::TimePoint; using Clock = TimePoint::clock; ThreadSafeSchedule(U32 capacity=1024): super(capacity) {} /*----------------------------- push() -----------------------------*/ /// explicitly pass TimeTuple using super::push; /// pass DataTuple with implicit now // This could be ambiguous for Args with a single type. Unfortunately // we can't enable_if an individual method with a condition based on // the *class* template arguments, only on that method's template // arguments. We could specialize this class for the single-Args case; // we could minimize redundancy by breaking out a common base class... void push(const DataTuple& tuple) { push(tuple_cons(Clock::now(), tuple)); } /// individually pass each component of the TimeTuple void push(const TimePoint& time, Args&&... args) { push(TimeTuple(time, std::forward(args)...)); } /// individually pass every component except the TimePoint (implies now) // This could be ambiguous if the first specified template parameter // type is also TimePoint. We could try to disambiguate, but a simpler // approach would be for the caller to explicitly construct DataTuple // and call that overload. void push(Args&&... args) { push(Clock::now(), std::forward(args)...); } /*--------------------------- tryPush() ----------------------------*/ /// explicit TimeTuple using super::tryPush; /// DataTuple with implicit now bool tryPush(const DataTuple& tuple) { return tryPush(tuple_cons(Clock::now(), tuple)); } /// individually pass components bool tryPush(const TimePoint& time, Args&&... args) { return tryPush(TimeTuple(time, std::forward(args)...)); } /// individually pass components with implicit now bool tryPush(Args&&... args) { return tryPush(Clock::now(), std::forward(args)...); } /*-------------------------- tryPushFor() --------------------------*/ /// explicit TimeTuple using super::tryPushFor; /// DataTuple with implicit now template bool tryPushFor(const std::chrono::duration& timeout, const DataTuple& tuple) { return tryPushFor(timeout, tuple_cons(Clock::now(), tuple)); } /// individually pass components template bool tryPushFor(const std::chrono::duration& timeout, const TimePoint& time, Args&&... args) { return tryPushFor(TimeTuple(time, std::forward(args)...)); } /// individually pass components with implicit now template bool tryPushFor(const std::chrono::duration& timeout, Args&&... args) { return tryPushFor(Clock::now(), std::forward(args)...); } /*------------------------- tryPushUntil() -------------------------*/ /// explicit TimeTuple using super::tryPushUntil; /// DataTuple with implicit now template bool tryPushUntil(const std::chrono::time_point& until, const DataTuple& tuple) { return tryPushUntil(until, tuple_cons(Clock::now(), tuple)); } /// individually pass components template bool tryPushUntil(const std::chrono::time_point& until, const TimePoint& time, Args&&... args) { return tryPushUntil(until, TimeTuple(time, std::forward(args)...)); } /// individually pass components with implicit now template bool tryPushUntil(const std::chrono::time_point& until, Args&&... args) { return tryPushUntil(until, Clock::now(), std::forward(args)...); } /*----------------------------- pop() ------------------------------*/ // Our consumer may or may not care about the timestamp associated // with each popped item, so we allow retrieving either DataTuple or // TimeTuple. One potential use would be to observe, and possibly // adjust for, the time lag between the item time and the actual // current time. /// pop DataTuple by value // It would be great to notice when sizeof...(Args) == 1 and directly // return the first (only) value, instead of making pop()'s caller // call std::get<0>(value). See push(DataTuple) remarks for why we // haven't yet jumped through those hoops. DataTuple pop() { return tuple_cdr(popWithTime()); } /// pop TimeTuple by value TimeTuple popWithTime() { lock_t lock(super::mLock); // We can't just sit around waiting forever, given that there may // be items in the queue that are not yet ready but will *become* // ready in the near future. So in fact, with this class, every // pop() becomes a tryPopUntil(), constrained to the timestamp of // the head item. It almost doesn't matter what we specify for the // caller's time constraint -- all we really care about is the // head item's timestamp. Since pop() and popWithTime() are // defined to wait until either an item becomes available or the // queue is closed, loop until one of those things happens. The // constraint we pass just determines how often we'll loop while // waiting. TimeTuple tt; while (true) { // Pick a point suitably far into the future. TimePoint until = TimePoint::clock::now() + std::chrono::hours(24); pop_result popped = tryPopUntil_(lock, until, tt); if (popped == POPPED) return std::move(tt); // DONE: throw, just as super::pop() does if (popped == DONE) { LLTHROW(LLThreadSafeQueueInterrupt()); } // WAITING: we've still got items to drain. // EMPTY: not closed, so it's worth waiting for more items. // Either way, loop back to wait. } } // We can use tryPop(TimeTuple&) just as it stands; the only behavior // difference is in our canPop() override method. using super::tryPop; /// tryPop(DataTuple&) bool tryPop(DataTuple& tuple) { TimeTuple tt; if (! super::tryPop(tt)) return false; tuple = tuple_cdr(std::move(tt)); return true; } /// for when Args has exactly one type bool tryPop(typename std::tuple_element<1, TimeTuple>::type& value) { TimeTuple tt; if (! super::tryPop(tt)) return false; value = std::get<1>(std::move(tt)); return true; } /// tryPopFor() template bool tryPopFor(const std::chrono::duration& timeout, Tuple& tuple) { // It's important to use OUR tryPopUntil() implementation, rather // than delegating immediately to our base class. return tryPopUntil(Clock::now() + timeout, tuple); } /// tryPopUntil(TimeTuple&) template bool tryPopUntil(const std::chrono::time_point& until, TimeTuple& tuple) { // super::tryPopUntil() wakes up when an item becomes available or // we hit 'until', whichever comes first. Thing is, the current // head of the queue could become ready sooner than either of // those events, and we need to deliver it as soon as it does. // Don't wait past the TimePoint of the head item. // Naturally, lock the queue before peeking at mStorage. return super::tryLockUntil( until, [this, until, &tuple](lock_t& lock) { // Use our time_point_cast to allow for 'until' that's a // time_point type other than TimePoint. return POPPED == tryPopUntil_(lock, LL::time_point_cast(until), tuple); }); } pop_result tryPopUntil_(lock_t& lock, const TimePoint& until, TimeTuple& tuple) { TimePoint adjusted = until; if (! super::mStorage.empty()) { // use whichever is earlier: the head item's timestamp, or // the caller's limit adjusted = min(std::get<0>(super::mStorage.front()), adjusted); } // now delegate to base-class tryPopUntil_() pop_result popped; while ((popped = pop_result(super::tryPopUntil_(lock, adjusted, tuple))) == WAITING) { // If super::tryPopUntil_() returns WAITING, it means there's // a head item, but it's not yet time. But it's worth looping // back to recheck. } return popped; } /// tryPopUntil(DataTuple&) template bool tryPopUntil(const std::chrono::time_point& until, DataTuple& tuple) { TimeTuple tt; if (! tryPopUntil(until, tt)) return false; tuple = tuple_cdr(std::move(tt)); return true; } /// for when Args has exactly one type template bool tryPopUntil(const std::chrono::time_point& until, typename std::tuple_element<1, TimeTuple>::type& value) { TimeTuple tt; if (! tryPopUntil(until, tt)) return false; value = std::get<1>(std::move(tt)); return true; } /*------------------------------ etc. ------------------------------*/ // We can't hide items that aren't yet ready because we can't traverse // the underlying priority_queue: it has no iterators, only top(). So // a consumer could observe size() > 0 and yet tryPop() returns false. // Shrug, in a multi-consumer scenario that would be expected behavior. using super::size; // open/closed state using super::close; using super::isClosed; using super::done; private: // this method is called by base class pop_() every time we're // considering whether to deliver the current head element bool canPop(const TimeTuple& head) const override { // an item with a future timestamp isn't yet ready to pop // (should we add some slop for overhead?) return std::get<0>(head) <= Clock::now(); } }; } // namespace LL #endif /* ! defined(LL_THREADSAFESCHEDULE_H) */