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198 lines
6.0 KiB
C++
198 lines
6.0 KiB
C++
//
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// NIB.cpp
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// Clock Signal
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//
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// Created by Thomas Harte on 21/04/2018.
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// Copyright 2018 Thomas Harte. All rights reserved.
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//
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#include "NIB.hpp"
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#include "../../Track/PCMTrack.hpp"
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#include "../../Track/TrackSerialiser.hpp"
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#include "../../Encodings/AppleGCR/Encoder.hpp"
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#include "../../Encodings/AppleGCR/Encoder.hpp"
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#include "../../Encodings/AppleGCR/SegmentParser.hpp"
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#include <vector>
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using namespace Storage::Disk;
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namespace {
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const long track_length = 6656;
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const std::size_t number_of_tracks = 35;
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}
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NIB::NIB(const std::string &file_name) :
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file_(file_name) {
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// A NIB should be 35 tracks, each 6656 bytes long.
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if(file_.stats().st_size != track_length*number_of_tracks) {
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throw Error::InvalidFormat;
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}
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// A real NIB should have every single top bit set. Yes, 1/8th of the
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// file size is a complete waste. But it provides a hook for validation.
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while(true) {
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uint8_t next = file_.get8();
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if(file_.eof()) break;
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if(!(next & 0x80)) throw Error::InvalidFormat;
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}
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}
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HeadPosition NIB::get_maximum_head_position() {
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return HeadPosition(number_of_tracks);
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}
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bool NIB::get_is_read_only() {
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return file_.get_is_known_read_only();
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}
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long NIB::file_offset(Track::Address address) {
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return long(address.position.as_int()) * track_length;
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}
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std::shared_ptr<::Storage::Disk::Track> NIB::get_track_at_position(::Storage::Disk::Track::Address address) {
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// NIBs contain data for even-numbered tracks underneath a single head only.
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if(address.head) return nullptr;
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long offset = file_offset(address);
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std::vector<uint8_t> track_data;
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{
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std::lock_guard lock_guard(file_.get_file_access_mutex());
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file_.seek(offset, SEEK_SET);
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track_data = file_.read(track_length);
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}
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// NIB files leave sync bytes implicit and make no guarantees
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// about overall track positioning. My current best-guess attempt
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// is to seek sector prologues then work backwards, inserting sync
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// bits into [at most 5] preceding FFs. This is intended to put the
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// Disk II into synchronisation just before each sector.
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std::size_t start_index = 0;
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std::set<size_t> sync_starts;
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// Establish where syncs start by finding instances of 0xd5 0xaa and then regressing
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// from each along all preceding FFs.
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for(size_t index = 0; index < track_data.size(); ++index) {
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// This is a D5 AA...
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if(track_data[index] == 0xd5 && track_data[(index+1)%track_data.size()] == 0xaa) {
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// ... count backwards to find out where the preceding FFs started.
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size_t start = index - 1;
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size_t length = 0;
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while(track_data[start] == 0xff && length < 5) {
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start = (start + track_data.size() - 1) % track_data.size();
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++length;
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}
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// Record a sync position only if there were at least five FFs, and
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// sync only in the final five. One of the many crazy fictions of NIBs
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// is the fixed track length in bytes, which is quite long. So the aim
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// is to be as conservative as possible with sync placement.
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if(length == 5) {
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sync_starts.insert((start + 1) % track_data.size());
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// If the apparent start of this sync area is 'after' the start, then
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// this sync period overlaps position zero. So this track will start
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// in a sync block.
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if(start > index)
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start_index = start;
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}
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}
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}
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PCMSegment segment;
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// If the track started in a sync block, write sync first.
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if(start_index) {
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segment += Encodings::AppleGCR::six_and_two_sync(int(start_index));
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}
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std::size_t index = start_index;
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for(const auto location: sync_starts) {
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// Write data from index to sync_start.
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if(location > index) {
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// This is the usual case; the only occasion on which it won't be true is
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// when the initial sync was detected to carry over the index hole,
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// in which case there's nothing to copy.
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std::vector<uint8_t> data_segment(
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track_data.begin() + off_t(index),
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track_data.begin() + off_t(location));
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segment += PCMSegment(data_segment);
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}
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// Add a sync from sync_start to end of 0xffs, if there are
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// any before the end of data.
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index = location;
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while(index < track_length && track_data[index] == 0xff)
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++index;
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if(index - location)
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segment += Encodings::AppleGCR::six_and_two_sync(int(index - location));
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}
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// If there's still data remaining on the track, write it out. If a sync ran over
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// the notional index hole, the loop above will already have completed the track
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// with sync, so no need to deal with that case here.
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if(index < track_length) {
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std::vector<uint8_t> data_segment(
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track_data.begin() + off_t(index),
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track_data.end());
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segment += PCMSegment(data_segment);
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}
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return std::make_shared<PCMTrack>(segment);
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}
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void NIB::set_tracks(const std::map<Track::Address, std::shared_ptr<Track>> &tracks) {
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std::map<Track::Address, std::vector<uint8_t>> tracks_by_address;
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// Convert to a map from address to a vector of data that contains the NIB representation
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// of the track.
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for(const auto &pair: tracks) {
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// Grab the track bit stream.
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auto segment = Storage::Disk::track_serialisation(*pair.second, Storage::Time(1, 50000));
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// Process to eliminate all sync bits.
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std::vector<uint8_t> track;
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track.reserve(track_length);
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uint8_t shifter = 0;
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int bit_count = 0;
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size_t sync_location = 0, location = 0;
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for(const auto bit: segment.data) {
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shifter = uint8_t((shifter << 1) | (bit ? 1 : 0));
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++bit_count;
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++location;
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if(shifter & 0x80) {
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track.push_back(shifter);
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if(bit_count == 10) {
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sync_location = location;
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}
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shifter = 0;
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bit_count = 0;
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}
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}
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// Trim or pad out to track_length.
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if(track.size() > track_length) {
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track.resize(track_length);
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} else {
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while(track.size() < track_length) {
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std::vector<uint8_t> extra_data(size_t(track_length) - track.size(), 0xff);
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track.insert(track.begin() + off_t(sync_location), extra_data.begin(), extra_data.end());
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}
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}
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tracks_by_address[pair.first] = std::move(track);
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}
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// Lock the file and spool out.
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std::lock_guard lock_guard(file_.get_file_access_mutex());
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for(const auto &track: tracks_by_address) {
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file_.seek(file_offset(track.first), SEEK_SET);
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file_.write(track.second);
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}
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}
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