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204 lines
7.7 KiB
C++
204 lines
7.7 KiB
C++
//
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// PCMTrack.cpp
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// Clock Signal
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//
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// Created by Thomas Harte on 10/07/2016.
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// Copyright 2016 Thomas Harte. All rights reserved.
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//
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#include "PCMTrack.hpp"
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#include "../../../Outputs/Log.hpp"
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using namespace Storage::Disk;
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PCMTrack::PCMTrack() : segment_pointer_(0) {}
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PCMTrack::PCMTrack(const std::vector<PCMSegment> &segments) : PCMTrack() {
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// sum total length of all segments
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Time total_length;
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for(const auto &segment : segments) {
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total_length += segment.length_of_a_bit * unsigned(segment.data.size());
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}
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total_length.simplify();
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// each segment is then some proportion of the total; for them all to sum to 1 they'll
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// need to be adjusted to be
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for(const auto &segment : segments) {
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Time original_length_of_segment = segment.length_of_a_bit * unsigned(segment.data.size());
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Time proportion_of_whole = original_length_of_segment / total_length;
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proportion_of_whole.simplify();
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PCMSegment length_adjusted_segment = segment;
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length_adjusted_segment.length_of_a_bit = proportion_of_whole / unsigned(segment.data.size());
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length_adjusted_segment.length_of_a_bit.simplify();
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segment_event_sources_.emplace_back(length_adjusted_segment);
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}
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}
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PCMTrack::PCMTrack(const PCMSegment &segment) : PCMTrack() {
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// a single segment necessarily fills the track
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PCMSegment length_adjusted_segment = segment;
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length_adjusted_segment.length_of_a_bit.length = 1;
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length_adjusted_segment.length_of_a_bit.clock_rate = unsigned(segment.data.size());
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segment_event_sources_.emplace_back(std::move(length_adjusted_segment));
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}
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PCMTrack::PCMTrack(const PCMTrack &original) : PCMTrack() {
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segment_event_sources_ = original.segment_event_sources_;
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}
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PCMTrack::PCMTrack(unsigned int bits_per_track) : PCMTrack() {
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PCMSegment segment;
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segment.length_of_a_bit.length = 1;
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segment.length_of_a_bit.clock_rate = bits_per_track;
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segment.data.resize(bits_per_track);
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segment_event_sources_.emplace_back(segment);
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}
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PCMTrack *PCMTrack::resampled_clone(Track *original, size_t bits_per_track) {
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PCMTrack *pcm_original = dynamic_cast<PCMTrack *>(original);
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if(pcm_original) {
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return pcm_original->resampled_clone(bits_per_track);
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}
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ERROR("NOT IMPLEMENTED: resampling non-PCMTracks");
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return nullptr;
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}
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bool PCMTrack::is_resampled_clone() {
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return is_resampled_clone_;
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}
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Track *PCMTrack::clone() const {
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return new PCMTrack(*this);
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}
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PCMTrack *PCMTrack::resampled_clone(size_t bits_per_track) {
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// Create an empty track.
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PCMTrack *const new_track = new PCMTrack(unsigned(bits_per_track));
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// Plot all segments from this track onto the destination.
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Time start_time;
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for(const auto &event_source: segment_event_sources_) {
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const PCMSegment &source = event_source.segment();
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new_track->add_segment(start_time, source, true);
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start_time += source.length();
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}
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new_track->is_resampled_clone_ = true;
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return new_track;
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}
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Track::Event PCMTrack::get_next_event() {
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// ask the current segment for a new event
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Track::Event event = segment_event_sources_[segment_pointer_].get_next_event();
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// if it was a flux transition, that's code for end-of-segment, so dig deeper
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if(event.type == Track::Event::IndexHole) {
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// multiple segments may be crossed, so start summing lengths in case the net
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// effect is an index hole
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Time total_length = event.length;
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// continue until somewhere not returning an index hole
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while(event.type == Track::Event::IndexHole) {
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// advance to [the start of] the next segment
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segment_pointer_ = (segment_pointer_ + 1) % segment_event_sources_.size();
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segment_event_sources_[segment_pointer_].reset();
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// if this is all the way back to the start, that's a genuine index hole,
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// so set the summed length and return
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if(!segment_pointer_) {
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return event;
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}
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// otherwise get the next event (if it's not another index hole, the loop will end momentarily),
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// summing in any prior accumulated time
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event = segment_event_sources_[segment_pointer_].get_next_event();
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total_length += event.length;
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event.length = total_length;
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}
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}
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return event;
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}
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float PCMTrack::seek_to(float time_since_index_hole) {
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// initial condition: no time yet accumulated, the whole thing requested yet to navigate
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float accumulated_time = 0.0f;
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float time_left_to_seek = time_since_index_hole;
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// search from the first segment
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segment_pointer_ = 0;
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do {
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// if this segment extends beyond the amount of time left to seek, trust it to complete
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// the seek
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const float segment_time = segment_event_sources_[segment_pointer_].get_length().get<float>();
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if(segment_time > time_left_to_seek) {
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return accumulated_time + segment_event_sources_[segment_pointer_].seek_to(time_left_to_seek);
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}
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// otherwise swallow this segment, updating the time left to seek and time so far accumulated
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time_left_to_seek -= segment_time;
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accumulated_time += segment_time;
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segment_pointer_ = (segment_pointer_ + 1) % segment_event_sources_.size();
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} while(segment_pointer_);
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// if all segments have now been swallowed, the closest we can get is the very end of
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// the list of segments
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return accumulated_time;
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}
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void PCMTrack::add_segment(const Time &start_time, const PCMSegment &segment, bool clamp_to_index_hole) {
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// Get a reference to the destination.
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PCMSegment &destination = segment_event_sources_.front().segment();
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// Determine the range to fill on the target segment.
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const Time end_time = start_time + segment.length();
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const size_t start_bit = start_time.length * destination.data.size() / start_time.clock_rate;
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const size_t end_bit = end_time.length * destination.data.size() / end_time.clock_rate;
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const size_t target_width = end_bit - start_bit;
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const size_t half_offset = target_width / (2 * segment.data.size());
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if(clamp_to_index_hole || end_bit <= destination.data.size()) {
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// If clamping is applied, just write a single segment, from the start_bit to whichever is
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// closer of the end of track and the end_bit.
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const size_t selected_end_bit = std::min(end_bit, destination.data.size());
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// Reset the destination.
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std::fill(destination.data.begin() + ptrdiff_t(start_bit), destination.data.begin() + ptrdiff_t(selected_end_bit), false);
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// Step through the source data from start to finish, stopping early if it goes out of bounds.
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for(size_t bit = 0; bit < segment.data.size(); ++bit) {
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if(segment.data[bit]) {
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const size_t output_bit = start_bit + half_offset + (bit * target_width) / segment.data.size();
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if(output_bit >= destination.data.size()) return;
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destination.data[output_bit] = true;
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}
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}
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} else {
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// Clamping is not enabled, so the supplied segment loops over the index hole, arbitrarily many times.
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// So work backwards unless or until the original start position is reached, then stop.
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// This definitely runs over the index hole; check whether the whole track needs clearing, or whether
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// a centre segment is untouched.
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if(target_width >= destination.data.size()) {
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std::fill(destination.data.begin(), destination.data.end(), false);
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} else {
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std::fill(destination.data.begin(), destination.data.begin() + ptrdiff_t(end_bit % destination.data.size()), false);
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std::fill(destination.data.begin() + ptrdiff_t(start_bit), destination.data.end(), false);
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}
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// Run backwards from final bit back to first, stopping early if overlapping the beginning.
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for(auto bit = ptrdiff_t(segment.data.size()-1); bit >= 0; --bit) {
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// Store flux transitions only; non-transitions can be ignored.
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if(segment.data[size_t(bit)]) {
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// Map to the proper output destination; stop if now potentially overwriting where we began.
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const size_t output_bit = start_bit + half_offset + (size_t(bit) * target_width) / segment.data.size();
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if(output_bit < end_bit - destination.data.size()) return;
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// Store.
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destination.data[output_bit % destination.data.size()] = true;
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}
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}
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}
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}
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