1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-12-25 18:30:21 +00:00
CLK/Storage/Disk/PCMPatchedTrack.cpp

243 lines
8.0 KiB
C++

//
// PCMPatchedTrack.cpp
// Clock Signal
//
// Created by Thomas Harte on 15/12/2016.
// Copyright © 2016 Thomas Harte. All rights reserved.
//
#include "PCMPatchedTrack.hpp"
using namespace Storage::Disk;
PCMPatchedTrack::PCMPatchedTrack(std::shared_ptr<Track> underlying_track) :
underlying_track_(underlying_track)
{
const Time zero(0);
const Time one(1);
periods_.emplace_back(zero, one, zero, nullptr);
active_period_ = periods_.begin();
underlying_track_->seek_to(zero);
}
PCMPatchedTrack::PCMPatchedTrack(const PCMPatchedTrack &original)
{
underlying_track_.reset(original.underlying_track_->clone());
periods_ = original.periods_;
active_period_ = periods_.begin();
}
Track *PCMPatchedTrack::clone()
{
return new PCMPatchedTrack(*this);
}
void PCMPatchedTrack::add_segment(const Time &start_time, const PCMSegment &segment)
{
std::shared_ptr<PCMSegmentEventSource> event_source(new PCMSegmentEventSource(segment));
Time zero(0);
Time end_time = start_time + event_source->get_length();
Period insertion_period(start_time, end_time, zero, event_source);
// the new segment may wrap around, so divide it up into track-length parts if required
Time one = Time(1);
while(insertion_period.end_time > one)
{
Time next_end_time = insertion_period.end_time - one;
insertion_period.end_time = one;
insert_period(insertion_period);
insertion_period.start_time = zero;
insertion_period.end_time = next_end_time;
}
insert_period(insertion_period);
// the vector may have been resized, potentially invalidating active_period_ even if
// the thing it pointed to is still the same thing. So work it out afresh.
insertion_error_ = current_time_ - seek_to(current_time_);
}
void PCMPatchedTrack::insert_period(const Period &period)
{
// find the existing period that the new period starts in
std::vector<Period>::iterator start_period = periods_.begin();
while(start_period->end_time <= period.start_time) start_period++;
// find the existing period that the new period end in
std::vector<Period>::iterator end_period = start_period;
while(end_period->end_time < period.end_time) end_period++;
// perform a division if called for
if(start_period == end_period)
{
if(start_period->start_time == period.start_time)
{
if(start_period->end_time == period.end_time)
{
// period has the same start and end time as start_period. So just replace it.
*start_period = period;
}
else
{
// period has the same start time as start_period but a different end time.
// So trim the left-hand side of start_period and insert the new period in front.
start_period->push_start_to_time(period.end_time);
periods_.insert(start_period, period);
}
}
else
{
if(start_period->end_time == period.end_time)
{
// period has the same end time as start_period but a different start time.
// So trim the right-hand side of start_period and insert the new period afterwards
start_period->trim_end_to_time(period.start_time);
periods_.insert(start_period + 1, period);
}
else
{
// start_period has an earlier start and a later end than period. So copy it,
// trim the right off the original and the left off the copy, then insert the
// new period and the copy after start_period
Period right_period = *start_period;
right_period.push_start_to_time(period.end_time);
start_period->trim_end_to_time(period.start_time);
// the iterator isn't guaranteed to survive the insert, e.g. if it causes a resize
std::vector<Period>::difference_type offset = start_period - periods_.begin();
periods_.insert(start_period + 1, period);
periods_.insert(periods_.begin() + offset + 2, right_period);
}
}
}
else
{
bool should_insert = false;
std::vector<Period>::difference_type insertion_offset = 0;
if(start_period->start_time == period.start_time)
{
// start_period starts at the same place as period. Period then
// ends after start_period. So replace.
*start_period = period;
should_insert = false;
}
else
{
// start_period starts before period. So trim and plan to insert afterwards.
start_period->trim_end_to_time(period.start_time);
should_insert = true;
insertion_offset = start_period + 1 - periods_.begin();
}
if(end_period->end_time == period.end_time)
{
// end_period ends exactly when period does. So include it from the list to delete
end_period++;
}
else
{
end_period->push_start_to_time(period.end_time);
}
// remove everything that is exiting in between
periods_.erase(start_period + 1, end_period);
// insert the new period if required
if(should_insert)
periods_.insert(periods_.begin()+insertion_offset, period);
}
}
Track::Event PCMPatchedTrack::get_next_event()
{
const Time one(1);
const Time zero(0);
Time extra_time(0);
Time period_error(0);
while(1)
{
// get the next event from the current active period
Track::Event event;
if(active_period_->event_source) event = active_period_->event_source->get_next_event();
else event = underlying_track_->get_next_event();
// see what time that gets us to. If it's still within the current period, return the found event
Time event_time = current_time_ + event.length - period_error - insertion_error_;
if(event_time < active_period_->end_time)
{
current_time_ = event_time;
// TODO: this is spelt out in three steps because times don't necessarily do the sensible
// thing when 'negative' if intermediate result get simplified in the meantime. So fix Time.
event.length += extra_time;
event.length -= period_error;
event.length -= insertion_error_;
return event;
}
insertion_error_.set_zero();
// otherwise move time back to the end of the outgoing period, accumulating the error into
// extra_time, and advance the extra period
extra_time += (active_period_->end_time - current_time_);
current_time_ = active_period_->end_time;
active_period_++;
// test for having reached the end of the track
if(active_period_ == periods_.end())
{
// if this is the end of the track then jump the active pointer back to the beginning
// of the list of periods and reset current_time_ to zero
active_period_ = periods_.begin();
if(active_period_->event_source) active_period_->event_source->reset();
else underlying_track_->seek_to(zero);
current_time_ = zero;
// then return an index hole that is the aggregation of accumulated extra_time away
event.type = Storage::Disk::Track::Event::IndexHole;
event.length = extra_time;
return event;
}
else
{
// if this is not the end of the track then move to the next period and note how much will need
// to be subtracted if an event is found here
if(active_period_->event_source) period_error = active_period_->segment_start_time - active_period_->event_source->seek_to(active_period_->segment_start_time);
else period_error = current_time_ - underlying_track_->seek_to(current_time_);
}
}
}
Storage::Time PCMPatchedTrack::seek_to(const Time &time_since_index_hole)
{
// start at the beginning and continue while segments end before reaching the time sought
active_period_ = periods_.begin();
while(active_period_->end_time < time_since_index_hole) active_period_++;
// allow whatever storage represents the period found to perform its seek
if(active_period_->event_source)
current_time_ = active_period_->event_source->seek_to(time_since_index_hole - active_period_->start_time) + active_period_->start_time;
else
current_time_ = underlying_track_->seek_to(time_since_index_hole);
return current_time_;
}
PCMPatchedTrack::Period::Period(const Period &original) :
start_time(original.start_time), end_time(original.end_time), segment_start_time(original.segment_start_time)
{
if(original.event_source) event_source.reset(new PCMSegmentEventSource(*original.event_source));
}
void PCMPatchedTrack::Period::push_start_to_time(const Storage::Time &new_start_time)
{
segment_start_time += new_start_time - start_time;
start_time = new_start_time;
}
void PCMPatchedTrack::Period::trim_end_to_time(const Storage::Time &new_end_time)
{
end_time = new_end_time;
}