1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-30 04:50:08 +00:00
CLK/Outputs/CRT/Internals/Flywheel.hpp
2020-05-09 21:23:52 -04:00

266 lines
8.4 KiB
C++

//
// Flywheel.hpp
// Clock Signal
//
// Created by Thomas Harte on 11/02/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#ifndef Flywheel_hpp
#define Flywheel_hpp
#include <cassert>
#include <cstdlib>
#include <cstdint>
namespace Outputs {
namespace CRT {
/*!
Provides timing for a two-phase signal consisting of a retrace phase followed by a scan phase,
announcing the start and end of retrace and providing the abiliy to read the current
scanning position.
The @c Flywheel will attempt to converge with timing implied by synchronisation pulses.
*/
struct Flywheel {
/*!
Constructs an instance of @c Flywheel.
@param standard_period The expected amount of time between one synchronisation and the next.
@param retrace_time The amount of time it takes to complete a retrace.
@param sync_error_window The permitted deviation of sync timings from the norm.
*/
Flywheel(int standard_period, int retrace_time, int sync_error_window) :
standard_period_(standard_period),
retrace_time_(retrace_time),
sync_error_window_(sync_error_window),
counter_before_retrace_(standard_period - retrace_time),
expected_next_sync_(standard_period) {}
enum SyncEvent {
/// Indicates that no synchronisation events will occur in the queried window.
None,
/// Indicates that the next synchronisation event will be a transition into retrce.
StartRetrace,
/// Indicates that the next synchronisation event will be a transition out of retrace.
EndRetrace
};
/*!
Asks the flywheel for the first synchronisation event that will occur in a given time period,
indicating whether a synchronisation request occurred at the start of the query window.
@param sync_is_requested @c true indicates that the flywheel should act as though having
received a synchronisation request now; @c false indicates no such event was detected.
@param cycles_to_run_for The number of cycles to look ahead.
@param cycles_advanced After this method has completed, contains the amount of time until
the returned synchronisation event.
@returns The next synchronisation event.
*/
inline SyncEvent get_next_event_in_period(bool sync_is_requested, int cycles_to_run_for, int *cycles_advanced) {
// If sync is signalled _now_, consider adjusting expected_next_sync_.
if(sync_is_requested) {
const auto last_sync = expected_next_sync_;
if(counter_ < sync_error_window_ || counter_ > expected_next_sync_ - sync_error_window_) {
const int time_now = (counter_ < sync_error_window_) ? expected_next_sync_ + counter_ : counter_;
expected_next_sync_ = (3*expected_next_sync_ + time_now) >> 2;
} else {
++number_of_surprises_;
if(counter_ < retrace_time_ + (expected_next_sync_ >> 1)) {
expected_next_sync_ = (3*expected_next_sync_ + standard_period_ + sync_error_window_) >> 2;
} else {
expected_next_sync_ = (3*expected_next_sync_ + standard_period_ - sync_error_window_) >> 2;
}
}
last_adjustment_ = expected_next_sync_ - last_sync;
}
SyncEvent proposed_event = SyncEvent::None;
int proposed_sync_time = cycles_to_run_for;
// End an ongoing retrace?
if(counter_ < retrace_time_ && counter_ + proposed_sync_time >= retrace_time_) {
proposed_sync_time = retrace_time_ - counter_;
proposed_event = SyncEvent::EndRetrace;
}
// Start a retrace?
if(counter_ + proposed_sync_time >= expected_next_sync_) {
proposed_sync_time = expected_next_sync_ - counter_;
proposed_event = SyncEvent::StartRetrace;
}
*cycles_advanced = proposed_sync_time;
return proposed_event;
}
/*!
Advances a nominated amount of time, applying a previously returned synchronisation event
at the end of that period.
@param cycles_advanced The amount of time to run for.
@param event The synchronisation event to apply after that period.
*/
inline void apply_event(int cycles_advanced, SyncEvent event) {
// In debug builds, perform a sanity check for counter overflow.
#ifndef NDEBUG
const int old_counter = counter_;
#endif
counter_ += cycles_advanced;
assert(old_counter <= counter_);
switch(event) {
default: return;
case StartRetrace:
counter_before_retrace_ = counter_ - retrace_time_;
counter_ = 0;
return;
}
}
/*!
Returns the current output position; while in retrace this will go down towards 0, while in scan
it will go upward.
@returns The current output position.
*/
inline int get_current_output_position() const {
if(counter_ < retrace_time_) {
const int retrace_distance = int((int64_t(counter_) * int64_t(standard_period_)) / int64_t(retrace_time_));
if(retrace_distance > counter_before_retrace_) return 0;
return counter_before_retrace_ - retrace_distance;
}
return counter_ - retrace_time_;
}
/*!
Returns the current 'phase' — 0 is the start of the display; a count up to 0 from a negative number represents
the retrace period and it will then count up to get_locked_scan_period().
@returns The current output position.
*/
inline int get_current_phase() const {
return counter_ - retrace_time_;
}
/*!
@returns the amount of time since retrace last began. Time then counts monotonically up from zero.
*/
inline int get_current_time() const {
return counter_;
}
/*!
@returns whether the output is currently retracing.
*/
inline bool is_in_retrace() const {
return counter_ < retrace_time_;
}
/*!
@returns the expected length of the scan period (excluding retrace).
*/
inline int get_scan_period() const {
return standard_period_ - retrace_time_;
}
/*!
@returns the actual length of the scan period (excluding retrace).
*/
inline int get_locked_scan_period() const {
return expected_next_sync_ - retrace_time_;
}
/*!
@returns the expected length of a complete scan and retrace cycle.
*/
inline int get_standard_period() const {
return standard_period_;
}
/*!
@returns the actual current period for a complete scan (including retrace).
*/
inline int get_locked_period() const {
return expected_next_sync_;
}
/*!
@returns the amount by which the @c locked_period was adjusted, the last time that an adjustment was applied.
*/
inline int get_last_period_adjustment() const {
return last_adjustment_;
}
/*!
@returns the number of synchronisation events that have seemed surprising since the last time this method was called;
a low number indicates good synchronisation.
*/
inline int get_and_reset_number_of_surprises() {
const int result = number_of_surprises_;
number_of_surprises_ = 0;
return result;
}
/*!
@returns A count of the number of retraces so far performed.
*/
inline int get_number_of_retraces() const {
return number_of_retraces_;
}
/*!
@returns The amount of time this flywheel spends in retrace, as supplied at construction.
*/
inline int get_retrace_period() const {
return retrace_time_;
}
/*!
@returns `true` if a sync is expected soon or if the time at which it was expected (or received) was recent.
*/
inline bool is_near_expected_sync() const {
return
(counter_ < (standard_period_ / 100)) ||
(counter_ >= expected_next_sync_ - (standard_period_ / 100));
}
private:
const int standard_period_; // The idealised length of time between syncs.
const int retrace_time_; // A constant indicating the amount of time it takes to perform a retrace.
const int sync_error_window_; // A constant indicating the window either side of the next expected sync in which we'll accept other syncs.
int counter_ = 0; // Time since the _start_ of the last sync.
int counter_before_retrace_; // The value of _counter immediately before retrace began.
int expected_next_sync_; // Our current expection of when the next sync will be encountered (which implies velocity).
int number_of_surprises_ = 0; // A count of the surprising syncs.
int number_of_retraces_ = 0; // A count of the number of retraces to date.
int last_adjustment_ = 0; // The amount by which expected_next_sync_ was adjusted at the last sync.
/*
Implementation notes:
Retrace takes a fixed amount of time and runs during [0, _retrace_time).
For the current line, scan then occurs from [_retrace_time, _expected_next_sync), at which point
retrace begins and the internal counter is reset.
All synchronisation events that occur within (-_sync_error_window, _sync_error_window) of the
expected synchronisation time will cause a proportional adjustment in the expected time for the next
synchronisation. Other synchronisation events are clamped as though they occurred in that range.
*/
};
}
}
#endif /* Flywheel_hpp */