// // JustInTime.hpp // Clock Signal // // Created by Thomas Harte on 28/07/2019. // Copyright © 2019 Thomas Harte. All rights reserved. // #pragma once #include "ClockReceiver.hpp" #include "../Concurrency/AsyncTaskQueue.hpp" #include "ClockingHintSource.hpp" #include "ForceInline.hpp" #include /*! A JustInTimeActor holds (i) an embedded object with a run_for method; and (ii) an amount of time since run_for was last called. Time can be added using the += operator. The -> operator can be used to access the embedded object. All time accumulated will be pushed to object before the pointer is returned. Machines that accumulate HalfCycle time but supply to a Cycle-counted device may supply a separate @c TargetTimeScale at template declaration. If the held object implements @c next_sequence_point() then it'll be used to flush implicitly as and when sequence points are hit. Callers can use will_flush() to predict these. If the held object is a subclass of ClockingHint::Source, this template will register as an observer and potentially stop clocking or stop delaying clocking until just-in-time references as directed. TODO: incorporate and codify AsyncJustInTimeActor. */ template class JustInTimeActor: public ClockingHint::Observer { private: /*! A std::unique_ptr deleter which causes an update_sequence_point to occur on the actor supplied to it at construction if it implements @c next_sequence_point(). Otherwise destruction is a no-op. **Does not delete the object.** This is used by the -> operators below, which provide a unique pointer to the enclosed object and update their sequence points upon its destruction — i.e. after the caller has made whatever call or calls as were relevant to the enclosed object. */ class SequencePointAwareDeleter { public: explicit SequencePointAwareDeleter( JustInTimeActor *const actor) noexcept : actor_(actor) {} forceinline void operator ()(const T *const) const { if constexpr (has_sequence_points::value) { actor_->update_sequence_point(); } } private: JustInTimeActor *const actor_; }; // This block of SFINAE determines whether objects of type T accepts Cycles or HalfCycles. using HalfRunFor = void (T::*const)(HalfCycles); static uint8_t half_sig(...); static uint16_t half_sig(HalfRunFor); using TargetTimeScale = std::conditional_t< sizeof(half_sig(&T::run_for)) == sizeof(uint16_t), HalfCycles, Cycles>; public: /// Constructs a new JustInTimeActor using the same construction arguments as the included object. template JustInTimeActor(Args&&... args) : object_(std::forward(args)...) { if constexpr (std::is_base_of::value) { object_.set_clocking_hint_observer(this); } } /// Adds time to the actor. /// /// @returns @c true if adding time caused a flush; @c false otherwise. forceinline bool operator += (LocalTimeScale rhs) { if constexpr (std::is_base_of::value) { if(clocking_preference_ == ClockingHint::Preference::None) { return false; } } if constexpr (multiplier != 1) { time_since_update_ += rhs * multiplier; } else { time_since_update_ += rhs; } is_flushed_ = false; if constexpr (std::is_base_of::value) { if (clocking_preference_ == ClockingHint::Preference::RealTime) { flush(); return true; } } if constexpr (has_sequence_points::value) { time_until_event_ -= rhs * multiplier; if(time_until_event_ <= LocalTimeScale(0)) { time_overrun_ = time_until_event_ / divider; flush(); update_sequence_point(); return true; } } return false; } /// Flushes all accumulated time and returns a pointer to the included object. /// /// If this object provides sequence points, checks for changes to the next /// sequence point upon deletion of the pointer. [[nodiscard]] forceinline auto operator->() { #ifndef NDEBUG assert(!flush_concurrency_check_.test_and_set()); #endif flush(); #ifndef NDEBUG flush_concurrency_check_.clear(); #endif return std::unique_ptr(&object_, SequencePointAwareDeleter(this)); } /// Acts exactly as per the standard ->, but preserves constness. /// /// Despite being const, this will flush the object and, if relevant, update the next sequence point. [[nodiscard]] forceinline auto operator -> () const { auto non_const_this = const_cast *>(this); #ifndef NDEBUG assert(!non_const_this->flush_concurrency_check_.test_and_set()); #endif non_const_this->flush(); #ifndef NDEBUG non_const_this->flush_concurrency_check_.clear(); #endif return std::unique_ptr(&object_, SequencePointAwareDeleter(non_const_this)); } /// @returns a pointer to the included object, without flushing time. [[nodiscard]] forceinline T *last_valid() { return &object_; } /// @returns a const pointer to the included object, without flushing time. [[nodiscard]] forceinline const T *last_valid() const { return &object_; } /// @returns the amount of time since the object was last flushed, in the target time scale. [[nodiscard]] forceinline TargetTimeScale time_since_flush() const { if constexpr (divider == 1) { return time_since_update_; } return TargetTimeScale(time_since_update_.as_integral() / divider); } /// @returns the amount of time since the object was last flushed, plus the local time scale @c offset, /// converted to the target time scale. [[nodiscard]] forceinline TargetTimeScale time_since_flush(LocalTimeScale offset) const { if constexpr (divider == 1) { return time_since_update_ + offset; } return TargetTimeScale((time_since_update_ + offset).as_integral() / divider); } /// Flushes all accumulated time. /// /// This does not affect this actor's record of when the next sequence point will occur. forceinline void flush() { if(!is_flushed_) { did_flush_ = is_flushed_ = true; if constexpr (divider == 1) { const auto duration = time_since_update_.template flush(); object_.run_for(duration); } else { const auto duration = time_since_update_.template divide(LocalTimeScale(divider)); if(duration > TargetTimeScale(0)) object_.run_for(duration); } } } /// Indicates whether a flush has occurred since the last call to did_flush(). [[nodiscard]] forceinline bool did_flush() { const bool did_flush = did_flush_; did_flush_ = false; return did_flush; } /// @returns a number in the range [-max, 0] indicating the offset of the most recent sequence /// point from the final time at the end of the += that triggered the sequence point. [[nodiscard]] forceinline LocalTimeScale last_sequence_point_overrun() { return time_overrun_; } /// @returns the number of cycles until the next sequence-point-based flush, if the embedded object /// supports sequence points; @c LocalTimeScale() otherwise. [[nodiscard]] LocalTimeScale cycles_until_implicit_flush() const { return time_until_event_ / divider; } /// Indicates whether a sequence-point-caused flush will occur if the specified period is added. [[nodiscard]] forceinline bool will_flush(LocalTimeScale rhs) const { if constexpr (!has_sequence_points::value) { return false; } return rhs >= time_until_event_; } /// Indicates the amount of time, in the local time scale, until the first local slot that falls wholly /// after @c duration, if that delay were to occur in @c offset units of time from now. [[nodiscard]] forceinline LocalTimeScale back_map(TargetTimeScale duration, TargetTimeScale offset) const { // A 1:1 mapping is easy. if constexpr (multiplier == 1 && divider == 1) { return duration; } // Work out when this query is placed, and the time to which it relates const auto base = time_since_update_ + offset * divider; const auto target = base + duration * divider; // Figure out the number of whole input steps that is required to get // past target, and subtract the number of whole input steps necessary // to get to base. const auto steps_to_base = base.as_integral() / multiplier; const auto steps_to_target = (target.as_integral() + divider - 1) / multiplier; return LocalTimeScale(steps_to_target - steps_to_base); } /// Updates this template's record of the next sequence point. void update_sequence_point() { if constexpr (has_sequence_points::value) { // Keep a fast path where no conversions will be applied; if conversions are // going to be applied then do a direct max -> max translation rather than // allowing the arithmetic to overflow. if constexpr (divider == 1 && std::is_same_v) { time_until_event_ = object_.next_sequence_point(); } else { const auto time = object_.next_sequence_point(); if(time == TargetTimeScale::max()) { time_until_event_ = LocalTimeScale::max(); } else { time_until_event_ = time * divider; } } assert(time_until_event_ > LocalTimeScale(0)); } } /// @returns A cached copy of the object's clocking preference. ClockingHint::Preference clocking_preference() const { return clocking_preference_; } private: T object_; LocalTimeScale time_since_update_, time_until_event_, time_overrun_; bool is_flushed_ = true; bool did_flush_ = false; template struct has_sequence_points : std::false_type {}; template struct has_sequence_points().next_sequence_point()))> : std::true_type {}; ClockingHint::Preference clocking_preference_ = ClockingHint::Preference::JustInTime; void set_component_prefers_clocking(ClockingHint::Source *, ClockingHint::Preference clocking) { clocking_preference_ = clocking; } #ifndef NDEBUG std::atomic_flag flush_concurrency_check_{}; #endif }; /*! An AsyncJustInTimeActor acts like a JustInTimeActor but additionally contains an AsyncTaskQueue. Any time the amount of accumulated time crosses a threshold provided at construction time, the object will be updated on the AsyncTaskQueue. */ template class AsyncJustInTimeActor { public: /// Constructs a new AsyncJustInTimeActor using the same construction arguments as the included object. template AsyncJustInTimeActor(TargetTimeScale threshold, Args&&... args) : object_(std::forward(args)...), threshold_(threshold) {} /// Adds time to the actor. inline void operator += (const LocalTimeScale &rhs) { time_since_update_ += rhs; if(time_since_update_ >= threshold_) { time_since_update_ -= threshold_; task_queue_.enqueue([this] () { object_.run_for(threshold_); }); } is_flushed_ = false; } /// Flushes all accumulated time and returns a pointer to the included object. inline T *operator->() { flush(); return &object_; } /// Returns a pointer to the included object without flushing time. inline T *last_valid() { return &object_; } /// Flushes all accumulated time. inline void flush() { if(!is_flushed_) { task_queue_.flush(); object_.run_for(time_since_update_.template flush()); is_flushed_ = true; } } private: T object_; LocalTimeScale time_since_update_; TargetTimeScale threshold_; bool is_flushed_ = true; Concurrency::AsyncTaskQueue task_queue_; };