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CLK/Storage/Disk/Track/PCMSegment.cpp
2024-04-17 22:15:05 -04:00

156 lines
5.5 KiB
C++

//
// PCMSegment.cpp
// Clock Signal
//
// Created by Thomas Harte on 17/12/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#include "PCMSegment.hpp"
#include <cassert>
#include <cstdlib>
using namespace Storage::Disk;
PCMSegmentEventSource::PCMSegmentEventSource(const PCMSegment &segment) :
segment_(new PCMSegment(segment)) {
// add an extra bit of storage at the bottom if one is going to be needed;
// events returned are going to be in integral multiples of the length of a bit
// other than the very first and very last which will include a half bit length
if(segment_->length_of_a_bit.length&1) {
segment_->length_of_a_bit.length <<= 1;
segment_->length_of_a_bit.clock_rate <<= 1;
}
// load up the clock rate once only
next_event_.length.clock_rate = segment_->length_of_a_bit.clock_rate;
// set initial conditions
reset();
}
PCMSegmentEventSource::PCMSegmentEventSource(const PCMSegmentEventSource &original) {
*this = original;
}
PCMSegmentEventSource &PCMSegmentEventSource::operator =(const PCMSegmentEventSource &original) {
// share underlying data with the original
segment_ = original.segment_;
// load up the clock rate and set initial conditions
next_event_.length.clock_rate = segment_->length_of_a_bit.clock_rate;
reset();
return *this;
}
void PCMSegmentEventSource::reset() {
// start with the first bit to be considered the zeroth, and assume that it'll be
// flux transitions for the foreseeable
bit_pointer_ = 0;
next_event_.type = Track::Event::FluxTransition;
}
PCMSegment &PCMSegment::operator +=(const PCMSegment &rhs) {
data.insert(data.end(), rhs.data.begin(), rhs.data.end());
return *this;
}
void PCMSegment::rotate_right(size_t length) {
length %= data.size();
if(!length) return;
// To rotate to the right, front-insert the proper number
// of bits from the end and then resize. To rotate to
// the left, do the opposite.
std::vector<uint8_t> data_copy;
if(length > 0) {
data_copy.insert(data_copy.end(), data.end() - ptrdiff_t(length), data.end());
data.erase(data.end() - ptrdiff_t(length), data.end());
data.insert(data.begin(), data_copy.begin(), data_copy.end());
} else {
data_copy.insert(data_copy.end(), data.begin(), data.begin() - ptrdiff_t(length));
data.erase(data.begin(), data.begin() - ptrdiff_t(length));
data.insert(data.end(), data_copy.begin(), data_copy.end());
}
}
Storage::Disk::Track::Event PCMSegmentEventSource::get_next_event() {
// Track the initial bit pointer for potentially considering whether this was an
// initial index hole or a subsequent one later on.
const std::size_t initial_bit_pointer = bit_pointer_;
// If starting from the beginning, pull half a bit backward, as if the initial bit
// is set, it should be in the centre of its window.
next_event_.length.length = bit_pointer_ ? 0 : -(segment_->length_of_a_bit.length >> 1);
// search for the next bit that is set, if any
while(bit_pointer_ < segment_->data.size()) {
bool bit = segment_->data[bit_pointer_];
++bit_pointer_; // so this always points one beyond the most recent bit returned
next_event_.length.length += segment_->length_of_a_bit.length;
// if this bit is set, or is fuzzy and a random bit of 1 is selected, return the event.
if(bit ||
(!segment_->fuzzy_mask.empty() && segment_->fuzzy_mask[bit_pointer_] && lfsr_.next())
) return next_event_;
}
// If the end is reached without a bit being set, it'll be index holes from now on.
next_event_.type = Track::Event::IndexHole;
// Test whether this is the very first time that bits have been exhausted. If so then
// allow an extra half bit's length to run from the position of the potential final transition
// event to the end of the segment. Otherwise don't allow any extra time, as it's already
// been consumed.
if(initial_bit_pointer <= segment_->data.size()) {
next_event_.length.length += (segment_->length_of_a_bit.length >> 1);
bit_pointer_++;
}
return next_event_;
}
Storage::Time PCMSegmentEventSource::get_length() {
return segment_->length_of_a_bit * unsigned(segment_->data.size());
}
float PCMSegmentEventSource::seek_to(float time_from_start) {
// test for requested time being beyond the end
const float length = get_length().get<float>();
if(time_from_start >= length) {
next_event_.type = Track::Event::IndexHole;
bit_pointer_ = segment_->data.size()+1;
return length;
}
// if not beyond the end then make an initial assumption that the next thing encountered will be a flux transition
next_event_.type = Track::Event::FluxTransition;
// test for requested time being before the first bit
const float bit_length = segment_->length_of_a_bit.get<float>();
const float half_bit_length = bit_length / 2.0f;
if(time_from_start < half_bit_length) {
bit_pointer_ = 0;
return 0.0f;
}
// adjust for time to get to bit zero and determine number of bits in;
// bit_pointer_ always records _the next bit_ that might trigger an event,
// so should be one beyond the one reached by a seek.
const float relative_time = time_from_start + half_bit_length; // the period [0, 0.5) should map to window 0, ending with bit 0; [0.5, 1.5) should map to window 1; etc.
bit_pointer_ = size_t(relative_time / bit_length);
// Map up to the correct amount of time; this should be the start of the window that ends upon the bit at bit_pointer_.
return bit_length * float(bit_pointer_) - half_bit_length;
}
const PCMSegment &PCMSegmentEventSource::segment() const {
return *segment_;
}
PCMSegment &PCMSegmentEventSource::segment() {
return *segment_;
}