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CLK/Storage/Disk/DiskImage/Formats/STX.cpp
2020-01-19 21:08:49 -05:00

596 lines
20 KiB
C++

//
// STX.cpp
// Clock Signal
//
// Created by Thomas Harte on 13/11/2019.
// Copyright © 2019 Thomas Harte. All rights reserved.
//
#include "STX.hpp"
#include "../../Encodings/MFM/Constants.hpp"
#include "../../Encodings/MFM/Shifter.hpp"
#include "../../Encodings/MFM/Encoder.hpp"
#include "../../Track/PCMTrack.hpp"
#include "Utility/ImplicitSectors.hpp"
#include <array>
#include <cstdlib>
#include <cstring>
using namespace Storage::Disk;
namespace {
class TrackConstructor {
public:
constexpr static uint16_t NoFirstOffset = std::numeric_limits<uint16_t>::max();
struct Sector {
// Records explicitly present in the sector table.
uint32_t data_offset = 0;
size_t bit_position = 0;
uint16_t data_duration = 0;
std::array<uint8_t, 6> address = {0, 0, 0, 0, 0, 0};
uint8_t status = 0;
// Other facts that will either be supplied by the STX or which
// will be empty.
std::vector<uint8_t> fuzzy_mask;
std::vector<uint8_t> contents;
std::vector<uint16_t> timing;
// Accessors.
/// @returns The byte size of this sector, according to its address mark.
uint32_t data_size() const {
return uint32_t(128 << (address[3]&3));
}
struct Fragment {
int prior_syncs = 1;
std::vector<uint8_t> contents;
};
/// @returns The byte stream this sector address would produce if a WD read track command were to observe it.
std::vector<Fragment> get_track_address_fragments() const {
return track_fragments(address.begin(), address.begin() + 4, {0xa1, 0xa1, 0xfe});
}
/// @returns The byte stream this sector data would produce if a WD read track command were to observe it.
std::vector<Fragment> get_track_data_fragments() const {
return track_fragments(contents.begin(), contents.end(), {0xa1, 0xa1, 0xfb});
}
/*!
Acts like std::search except that it tries to find a start location from which all of the members of @c fragments
can be found in successive order with no more than a 'permissible' amount of gap between them.
Where 'permissible' is derived empirically from trial and error; in practice it's a measure of the number of bytes
a WD may produce when it has encountered a false sync, and I don't have documentation on that. So it's
derived from in-practice testing of STXs (which, hopefully, contain an accurate copy of what a WD would do,
so are themselves possibly a way to research that).
*/
template <typename Iterator> static Iterator find_fragments(Iterator begin, Iterator end, const std::vector<Fragment> &fragments) {
while(true) {
// To match the fragments, they must all be found, in order, with at most two bytes of gap.
auto this_begin = begin;
std::vector<uint8_t>::const_iterator first_location = end;
bool is_found = true;
bool is_first = true;
for(auto fragment: fragments) {
auto location = std::search(this_begin, end, fragment.contents.begin(), fragment.contents.end());
// If fragment wasn't found at all, it's never going to be found. So game over.
if(location == end) {
return location;
}
// Otherwise, either mark
if(is_first) {
first_location = location;
} else if(location > this_begin + 5*fragment.prior_syncs) {
is_found = false;
break;
}
is_first = false;
this_begin = location + ssize_t(fragment.contents.size());
}
if(is_found) {
return first_location;
}
// TODO: can I assume more than this?
++begin;
}
return end;
}
private:
/// @returns The effect of encoding @c prefix followed by the bytes from @c begin to @c end as MFM data and then decoding them as if
/// observed by a WD read track command, split into fragments separated by any instances of false sync — since it's still unclear to me exactly what
/// a WD should put out in those instances.
template <typename T> static std::vector<Fragment> track_fragments(T begin, T end, std::initializer_list<uint8_t> prefix) {
std::vector<Fragment> result;
result.reserve(size_t(end - begin) + prefix.size());
PCMSegment segment;
std::unique_ptr<Storage::Encodings::MFM::Encoder> encoder = Storage::Encodings::MFM::GetMFMEncoder(segment.data);
// Encode prefix.
for(auto c: prefix) {
encoder->add_byte(c);
}
// Encode body.
while(begin != end) {
encoder->add_byte(*begin);
++begin;
}
// Decode, starting a new segment upon any false sync since I don't have good documentation
// presently on exactly how a WD should react to those.
using Shifter = Storage::Encodings::MFM::Shifter;
Shifter shifter;
shifter.set_should_obey_syncs(true);
shifter.set_is_double_density(true);
result.emplace_back();
// Add whatever comes from the track.
int ignore_count = 0;
for(auto bit: segment.data) {
shifter.add_input_bit(int(bit));
const auto token = shifter.get_token();
if(token != Shifter::None) {
if(ignore_count) {
--ignore_count;
continue;
}
// If anything other than a byte is encountered,
// skip it and the next thing to be reported,
// beginning a new fragment.
if(token != Shifter::Token::Byte) {
ignore_count = 1;
if(!result.back().contents.empty()) {
result.emplace_back();
} else {
++result.back().prior_syncs;
}
continue;
}
// This was an ordinary byte, retain it.
result.back().contents.push_back(shifter.get_byte());
}
}
return result;
}
};
TrackConstructor(const std::vector<uint8_t> &track_data, const std::vector<Sector> &sectors, size_t track_size, uint16_t first_sync) :
track_data_(track_data), sectors_(sectors), track_size_(track_size), first_sync_(first_sync) {
}
std::shared_ptr<PCMTrack> get_track() {
// If no contents are supplied, return an unformatted track.
if(sectors_.empty() && track_data_.empty()) {
return nullptr;
}
// If no sectors are on this track, just encode the track data. STX allows speed
// changes and fuzzy bits in sectors only.
if(sectors_.empty()) {
PCMSegment segment;
std::unique_ptr<Storage::Encodings::MFM::Encoder> encoder = Storage::Encodings::MFM::GetMFMEncoder(segment.data);
for(auto c: track_data_) {
encoder->add_byte(c);
}
return std::make_shared<PCMTrack>(segment);
}
// Otherwise, seek to encode the sectors, using the track data to
// fill in the gaps (if provided).
std::unique_ptr<Storage::Encodings::MFM::Encoder> encoder;
std::vector<PCMSegment> segments;
// To reconcile the list of sectors with the WD get track-style track image,
// use sector bodies as definitive and refer to the track image for in-fill.
auto track_position = track_data_.begin();
const auto sync_mark = {0xa1, 0xa1};
struct Location {
enum Type {
Address, Data
} type;
std::vector<uint8_t>::const_iterator position;
const Sector &sector;
Location(Type type, std::vector<uint8_t>::const_iterator position, const Sector &sector) : type(type), position(position), sector(sector) {}
};
std::vector<Location> locations;
for(const auto &sector: sectors_) {
{
// Find out what the address would look like, if found in a read track.
const auto address_fragments = sector.get_track_address_fragments();
// Try to locate the header within the track image; if it can't be found then settle for
// the next thing that looks like a header of any sort.
auto address_position = TrackConstructor::Sector::find_fragments(track_position, track_data_.end(), address_fragments);
if(address_position == track_data_.end()) {
address_position = std::search(track_position, track_data_.end(), sync_mark.begin(), sync_mark.end());
}
// Place this address only if somewhere to put it was found.
if(address_position != track_data_.end()) {
locations.emplace_back(Location::Address, address_position, sector);
// Advance the track position.
track_position = address_position + 6;
}
}
// Do much the same thing for the data, if it exists.
if(!(sector.status & 0x10)) {
const auto data_fragments = sector.get_track_data_fragments();
auto data_position = TrackConstructor::Sector::find_fragments(track_position, track_data_.end(), data_fragments);
if(data_position == track_data_.end()) {
data_position = std::search(track_position, track_data_.end(), sync_mark.begin(), sync_mark.end());
}
if(data_position == track_data_.end()) {
// Desperation: guess from the given offset.
data_position = track_data_.begin() + (sector.bit_position / 16);
}
locations.emplace_back(Location::Data, data_position, sector);
track_position = data_position + sector.data_size();
}
}
const auto encoder_at_rate = [&encoder, &segments](unsigned int rate) -> Storage::Encodings::MFM::Encoder* {
if(!encoder) {
segments.emplace_back();
segments.back().length_of_a_bit = Storage::Time(int(rate + 1), 1);
encoder = Storage::Encodings::MFM::GetMFMEncoder(segments.back().data, &segments.back().fuzzy_mask);
} else if(segments.back().length_of_a_bit.length != rate) {
segments.emplace_back();
segments.back().length_of_a_bit = Storage::Time(int(rate + 1), 1);
encoder->reset_target(segments.back().data, &segments.back().fuzzy_mask);
}
return encoder.get();
};
// Write out, being wary of potential overlapping sectors, and copying from track_data_ to fill in gaps.
auto location = locations.begin();
track_position = track_data_.begin();
while(location != locations.end()) {
// assert(location->position >= track_position && location->position < track_data_.end());
// Advance to location.position.
auto default_rate_encoder = encoder_at_rate(127);
while(track_position < location->position) {
default_rate_encoder->add_byte(*track_position);
++track_position;
}
// Write the relevant mark and fill in a default number of bytes to write.
size_t bytes_to_write;
switch(location->type) {
default:
case Location::Address:
default_rate_encoder->add_ID_address_mark();
bytes_to_write = 6;
break;
case Location::Data:
if(location->sector.status & 0x20)
default_rate_encoder->add_deleted_data_address_mark();
else
default_rate_encoder->add_data_address_mark();
bytes_to_write = location->sector.data_size() + 2;
break;
}
track_position += 3;
// Decide how much data to write for real; this [partially] allows for overlapping sectors.
auto next_location = location + 1;
if(next_location != locations.end()) {
bytes_to_write = std::min(bytes_to_write, size_t(next_location->position - track_position));
}
// Skip that many bytes from the underlying track image.
track_position += ssize_t(bytes_to_write);
// Write bytes.
switch(location->type) {
default:
case Location::Address:
for(size_t c = 0; c < bytes_to_write; ++c)
default_rate_encoder->add_byte(location->sector.address[c]);
break;
case Location::Data: {
const auto body_bytes = std::min(bytes_to_write, size_t(location->sector.data_size()));
// If timing information is attached to this sector, write each byte at the proper speed.
// (TODO: is there any benefit to optiming number of calls to encoder_at_rate?)
if(!location->sector.timing.empty()) {
for(size_t c = 0; c < body_bytes; ++c) {
encoder_at_rate(location->sector.timing[c >> 4])->add_byte(
location->sector.contents[c],
location->sector.fuzzy_mask.empty() ? 0x00 : location->sector.fuzzy_mask[c]
);
}
} else {
for(size_t c = 0; c < body_bytes; ++c) {
default_rate_encoder->add_byte(
location->sector.contents[c],
location->sector.fuzzy_mask.empty() ? 0x00 : location->sector.fuzzy_mask[c]
);
}
}
// Add a CRC only if it fits (TODO: crop if necessary?).
if(bytes_to_write & 127) {
default_rate_encoder = encoder_at_rate(127);
default_rate_encoder->add_crc((location->sector.status & 0x18) == 0x10);
}
} break;
}
// Advance location.
++location;
}
// Write anything remaining from the track image.
while(track_position < track_data_.end()) {
encoder->add_byte(*track_position);
++track_position;
}
// Count total size of track.
size_t track_size = 0;
for(auto &segment: segments) {
track_size += segment.data.size();
}
// Write generic padding up until the specified track size.
while(track_size < track_size_ * 16) {
encoder->add_byte(0x4e);
track_size += 16;
}
// Pad out to the minimum size a WD can actually make sense of.
// I've no idea why it's valid for tracks to be shorter than this,
// so likely I'm suffering a comprehansion deficiency.
// TODO: determine why this isn't correct (or, possibly, is).
while(track_size < 5750 * 16) {
encoder->add_byte(0x4e);
track_size += 16;
}
return std::make_shared<PCMTrack>(segments);
}
private:
const std::vector<uint8_t> &track_data_;
const std::vector<Sector> &sectors_;
const size_t track_size_;
const uint16_t first_sync_;
};
}
STX::STX(const std::string &file_name) : file_(file_name) {
// Require that this be a version 3 Pasti.
if(!file_.check_signature("RSY", 4)) throw Error::InvalidFormat;
if(file_.get16le() != 3) throw Error::InvalidFormat;
// Skip: tool used, 2 reserved bytes.
file_.seek(4, SEEK_CUR);
// Skip the track count, test for a new-style encoding, skip a reserved area.
file_.seek(1, SEEK_CUR);
is_new_format_ = file_.get8() == 2;
file_.seek(4, SEEK_CUR);
// Set all tracks absent.
memset(offset_by_track_, 0, sizeof(offset_by_track_));
// Parse the tracks table to fill in offset_by_track_. The only available documentation
// for STX is unofficial and makes no promise about track order. Hence the bucket sort,
// effectively putting them into track order.
//
// Track descriptor layout:
//
// 0 4 Record size.
// 4 4 Number of bytes in fuzzy mask record.
// 8 2 Number of sectors on track.
// 10 2 Track flags.
// 12 2 Total number of bytes on track.
// 14 1 Track number (b7 = side, b0-b6 = track).
// 15 1 Track type.
track_count_ = 0;
head_count_ = 1;
while(true) {
const long offset = file_.tell();
const uint32_t size = file_.get32le();
if(file_.eof()) break;
// Skip fields other than track position, then fill in table position and advance.
file_.seek(10, SEEK_CUR);
const uint8_t track_position = file_.get8();
offset_by_track_[track_position] = offset;
// Update the maximum surface dimensions.
track_count_ = std::max(track_count_, track_position & 0x7f);
head_count_ = std::max(head_count_, ((track_position & 0x80) >> 6));
// Seek next track start.
file_.seek(offset + size, SEEK_SET);
}
}
HeadPosition STX::get_maximum_head_position() {
return HeadPosition(track_count_ + 1); // Same issue as MSA; must fix!
}
int STX::get_head_count() {
return head_count_;
}
std::shared_ptr<::Storage::Disk::Track> STX::get_track_at_position(::Storage::Disk::Track::Address address) {
// These images have two sides, at most.
if(address.head > 1) return nullptr;
// If no track was found, there's nothing to do here.
const int track_index = (address.head * 0x80) + address.position.as_int();
if(!offset_by_track_[track_index]) return nullptr;
// Seek to the track (skipping the record size field).
file_.seek(offset_by_track_[track_index] + 4, SEEK_SET);
// Grab the track description.
const uint32_t fuzzy_size = file_.get32le();
const uint16_t sector_count = file_.get16le();
const uint16_t flags = file_.get16le();
const size_t track_length = file_.get16le();
file_.seek(2, SEEK_CUR); // Skip track type; despite being named, it's apparently unused.
// If this is a trivial .ST-style sector dump, life is easy.
if(!(flags & 1)) {
const auto sector_contents = file_.read(sector_count * 512);
return track_for_sectors(sector_contents.data(), sector_count, uint8_t(address.position.as_int()), uint8_t(address.head), 1, 2, true);
}
// Grab sector records, if provided.
std::vector<TrackConstructor::Sector> sectors;
std::vector<uint8_t> track_data;
uint16_t first_sync = TrackConstructor::NoFirstOffset;
// Sector records come first.
for(uint16_t c = 0; c < sector_count; ++c) {
sectors.emplace_back();
sectors.back().data_offset = file_.get32le();
sectors.back().bit_position = file_.get16le();
sectors.back().data_duration = file_.get16le();
file_.read(sectors.back().address);
sectors.back().status = file_.get8();
file_.seek(1, SEEK_CUR);
}
// If fuzzy masks are specified, attach them to their corresponding sectors.
if(fuzzy_size) {
uint32_t fuzzy_bytes_read = 0;
for(auto &sector: sectors) {
// Check for the fuzzy bit mask; if it's not set then
// there's nothing for this sector.
if(!(sector.status & 0x80)) continue;
// Make sure there are enough bytes left.
const uint32_t expected_bytes = sector.data_size();
if(fuzzy_bytes_read + expected_bytes > fuzzy_size) break;
// Okay, there are, so read them.
sector.fuzzy_mask = file_.read(expected_bytes);
fuzzy_bytes_read += expected_bytes;
}
// It should be true that the number of fuzzy masks caused
// exactly the correct number of fuzzy bytes to be read.
// But, just in case, check and possibly skip some.
file_.seek(long(fuzzy_size) - fuzzy_bytes_read, SEEK_CUR);
}
// There may or may not be a track image. Grab it if so.
// Grab the read-track-esque track contents, if available.
long sector_start = file_.tell();
if(flags & 0x40) {
// Bit 6 => there is a track to read;
// bit
if(flags & 0x80) {
first_sync = file_.get16le();
const uint16_t image_size = file_.get16le();
track_data = file_.read(image_size);
} else {
const uint16_t image_size = file_.get16le();
track_data = file_.read(image_size);
}
}
// Grab sector contents.
long end_of_data = file_.tell();
for(auto &sector: sectors) {
// If the FDC record-not-found flag is set, there's no sector body to find.
// Otherwise there's a sector body in the file somewhere.
if(!(sector.status & 0x10)) {
file_.seek(sector.data_offset + sector_start, SEEK_SET);
sector.contents = file_.read(sector.data_size());
end_of_data = std::max(end_of_data, file_.tell());
}
}
file_.seek(end_of_data, SEEK_SET);
// Grab timing info if available.
file_.seek(4, SEEK_CUR); // Skip the timing descriptor, as it includes no new information.
for(auto &sector: sectors) {
// Skip any sector with no intra-sector bit width variation.
if(!(sector.status&1)) continue;
const auto timing_record_size = sector.data_size() >> 4; // Use one entry per 16 bytes.
sector.timing.resize(timing_record_size);
if(!is_new_format_) {
// Generate timing records for Macrodos/Speedlock.
// Timing is specified in quarters. Which might or might not be
// quantities of 128 bytes, who knows?
for(size_t c = 0; c < timing_record_size; ++c) {
if(c < (timing_record_size >> 2)) {
sector.timing[c] = 127;
} else if(c < ((timing_record_size*2) >> 2)) {
sector.timing[c] = 133;
} else if(c < ((timing_record_size*3) >> 2)) {
sector.timing[c] = 121;
} else {
sector.timing[c] = 127;
}
}
continue;
}
// This is going to be a new-format record.
for(size_t c = 0; c < timing_record_size; ++c) {
sector.timing[c] = file_.get16be(); // These values are big endian, unlike the rest of the file.
}
}
// Sort the sectors by starting position. It's perfectly possible that they're always
// sorted in STX but, again, the reverse-engineered documentation doesn't make the
// promise, so that's that.
std::sort(sectors.begin(), sectors.end(),
[] (TrackConstructor::Sector &lhs, TrackConstructor::Sector &rhs) {
return lhs.bit_position < rhs.bit_position;
});
/*
Having reached here, the actual stuff of parsing the file structure should be done.
So hand off to the TrackConstructor.
*/
TrackConstructor constructor(track_data, sectors, track_length, first_sync);
return constructor.get_track();
}