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440 lines
14 KiB
C++
440 lines
14 KiB
C++
//
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// IPF.cpp
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// Clock Signal
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//
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// Created by Thomas Harte on 25/12/2021.
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// Copyright © 2021 Thomas Harte. All rights reserved.
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//
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#include "IPF.hpp"
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#include "../../Encodings/MFM/Encoder.hpp"
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#include <cassert>
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using namespace Storage::Disk;
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namespace {
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constexpr uint32_t block(const char (& src)[5]) {
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return uint32_t(
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(uint32_t(src[0]) << 24) |
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(uint32_t(src[1]) << 16) |
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(uint32_t(src[2]) << 8) |
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uint32_t(src[3])
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);
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}
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size_t block_size(Storage::FileHolder &file, uint8_t header) {
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uint8_t size_width = header >> 5;
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size_t length = 0;
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while(size_width--) {
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length = (length << 8) | file.get8();
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}
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return length;
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}
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}
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IPF::IPF(const std::string &file_name) : file_(file_name) {
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std::map<uint32_t, Track::Address> tracks_by_data_key;
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// For now, just build up a list of tracks that exist, noting the file position at which their data begins
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// plus the other fields that'll be necessary to convert them into flux on demand later.
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while(true) {
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const auto start_of_block = file_.tell();
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const uint32_t type = file_.get32be();
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uint32_t length = file_.get32be(); // Can't be const because of the dumb encoding of DATA blocks.
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[[maybe_unused]] const uint32_t crc = file_.get32be();
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if(file_.eof()) break;
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// Sanity check: the first thing in a file should be the CAPS record.
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if(!start_of_block && type != block("CAPS")) {
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throw Error::InvalidFormat;
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}
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switch(type) {
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default:
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printf("Ignoring %c%c%c%c, starting at %ld of length %d\n", (type >> 24), (type >> 16) & 0xff, (type >> 8) & 0xff, type & 0xff, start_of_block, length);
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break;
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case block("CAPS"):
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// Analogously to the sanity check above, if a CAPS block is anywhere other
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// than first then something is amiss.
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if(start_of_block) {
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throw Error::InvalidFormat;
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}
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break;
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case block("INFO"): {
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// There are a lot of useful archival fields in the info chunk, which for emulation
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// aren't that interesting.
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// Make sure this is a floppy disk.
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const uint32_t media_type = file_.get32be();
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if(media_type != 1) {
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throw Error::InvalidFormat;
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}
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// Determine whether this is a newer SPS-style file.
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is_sps_format_ = file_.get32be() > 1;
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// Skip: revision, file key and revision, CRC of the original .ctr, and minimum track.
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file_.seek(20, SEEK_CUR);
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track_count_ = int(1 + file_.get32be());
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// Skip: min side.
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file_.seek(4, SEEK_CUR);
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head_count_ = int(1 + file_.get32be());
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// Skip: creation date, time.
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file_.seek(8, SEEK_CUR);
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platform_type_ = 0;
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for(int c = 0; c < 4; c++) {
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const uint8_t platform = file_.get8();
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switch(platform) {
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default: break;
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case 1: platform_type_ |= TargetPlatform::Amiga; break;
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case 2: platform_type_ |= TargetPlatform::AtariST; break;
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/* Omitted: 3 -> IBM PC */
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case 4: platform_type_ |= TargetPlatform::AmstradCPC; break;
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case 5: platform_type_ |= TargetPlatform::ZXSpectrum; break;
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/* Omitted: 6 -> Sam Coupé */
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/* Omitted: 7 -> Archimedes */
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/* Omitted: 8 -> C64 */
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/* Omitted: 9 -> Atari 8-bit */
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}
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}
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// If the file didn't declare anything, default to supporting everything.
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if(!platform_type_) {
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platform_type_ = ~0;
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}
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// Ignore: disk number, creator ID, reserved area.
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} break;
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case block("IMGE"): {
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// Get track location.
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const uint32_t track = file_.get32be();
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const uint32_t side = file_.get32be();
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const Track::Address address{int(side), HeadPosition(int(track))};
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// Hence generate a TrackDescription.
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auto pair = tracks_.emplace(address, TrackDescription());
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TrackDescription &description = pair.first->second;
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// Read those fields of interest...
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// Bit density. I've no idea why the density can't just be given as a measurement.
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description.density = TrackDescription::Density(file_.get32be());
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if(description.density > TrackDescription::Density::Max) {
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description.density = TrackDescription::Density::Unknown;
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}
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file_.seek(12, SEEK_CUR); // Skipped: signal type, track bytes, start byte position.
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description.start_bit_pos = file_.get32be();
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description.data_bits = file_.get32be();
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description.gap_bits = file_.get32be();
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file_.seek(4, SEEK_CUR); // Skipped: track bits, which is entirely redundant.
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description.block_count = file_.get32be();
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file_.seek(4, SEEK_CUR); // Skipped: encoder process.
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description.has_fuzzy_bits = file_.get32be() & 1;
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// For some reason the authors decided to introduce another primary key,
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// in addition to that which naturally exists of (track, side). So set up
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// a mapping from the one to the other.
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const uint32_t data_key = file_.get32be();
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tracks_by_data_key.emplace(data_key, address);
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} break;
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case block("DATA"): {
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length += file_.get32be();
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file_.seek(8, SEEK_CUR); // Skipped: bit size, CRC.
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// Grab the data key and use that to establish the file starting
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// position for this track.
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//
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// Assumed here: DATA records will come after corresponding IMGE records.
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const uint32_t data_key = file_.get32be();
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const auto pair = tracks_by_data_key.find(data_key);
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if(pair == tracks_by_data_key.end()) {
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break;
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}
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auto description = tracks_.find(pair->second);
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if(description == tracks_.end()) {
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break;
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}
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description->second.file_offset = file_.tell();
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} break;
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}
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file_.seek(start_of_block + length, SEEK_SET);
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}
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}
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HeadPosition IPF::get_maximum_head_position() {
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return HeadPosition(track_count_);
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}
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int IPF::get_head_count() {
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return head_count_;
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}
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std::shared_ptr<Track> IPF::get_track_at_position([[maybe_unused]] Track::Address address) {
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// Get the track description, if it exists, and check either that the file has contents for the track.
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auto pair = tracks_.find(address);
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if(pair == tracks_.end()) {
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return nullptr;
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}
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const TrackDescription &description = pair->second;
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if(!description.file_offset) {
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return nullptr;
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}
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// Seek to track content.
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file_.seek(description.file_offset, SEEK_SET);
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// Read the block descriptions up front.
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//
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// This is less efficient than just seeking for each block in turn,
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// but is a useful crutch to comprehension of the file format on a
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// first run through.
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struct BlockDescriptor {
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uint32_t data_bits = 0;
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uint32_t gap_bits = 0;
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uint32_t gap_offset = 0;
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bool is_mfm = false;
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bool has_forward_gap = false;
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bool has_backwards_gap = false;
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bool data_unit_is_bits = false;
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uint32_t default_gap_value = 0;
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uint32_t data_offset = 0;
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};
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std::vector<BlockDescriptor> blocks;
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blocks.reserve(description.block_count);
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for(uint32_t c = 0; c < description.block_count; c++) {
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auto &block = blocks.emplace_back();
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block.data_bits = file_.get32be();
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block.gap_bits = file_.get32be();
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if(is_sps_format_) {
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block.gap_offset = file_.get32be();
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file_.seek(4, SEEK_CUR); // Skip 'cell type' which appears to provide no content.
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} else {
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// Skip potlower-resolution copies of data_bits and gap_bits.
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file_.seek(8, SEEK_CUR);
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}
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block.is_mfm = file_.get32be() == 1;
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const uint32_t flags = file_.get32be();
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block.has_forward_gap = flags & 1;
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block.has_backwards_gap = flags & 2;
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block.data_unit_is_bits = flags & 4;
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block.default_gap_value = file_.get32be();
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block.data_offset = file_.get32be();
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}
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std::vector<Storage::Disk::PCMSegment> segments;
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int block_count = 0;
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for(auto &block: blocks) {
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const auto length_of_a_bit = bit_length(description.density, block_count);
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if(block.gap_offset) {
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file_.seek(description.file_offset + block.gap_offset, SEEK_SET);
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while(true) {
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const uint8_t gap_header = file_.get8();
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if(!gap_header) break;
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// Decompose the header and read the length.
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enum class Type {
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None, GapLength, SampleLength
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} type = Type(gap_header & 0x1f);
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const size_t length = block_size(file_, gap_header);
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switch(type) {
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case Type::GapLength:
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printf("Adding gap length %zu bits\n", length);
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add_gap(segments, length_of_a_bit, length, block.default_gap_value);
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break;
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default:
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case Type::SampleLength:
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printf("Adding sampled gap length %zu bits\n", length);
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add_raw_data(segments, length_of_a_bit, length);
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// file_.seek(long(length >> 3), SEEK_CUR);
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break;
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}
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}
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} else if(block.gap_bits) {
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add_gap(segments, length_of_a_bit, block.gap_bits, block.default_gap_value);
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}
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if(block.data_offset) {
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file_.seek(description.file_offset + block.data_offset, SEEK_SET);
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while(true) {
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const uint8_t data_header = file_.get8();
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if(!data_header) break;
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// Decompose the header and read the length.
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enum class Type {
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None, Sync, Data, Gap, Raw, Fuzzy
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} type = Type(data_header & 0x1f);
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const size_t length = block_size(file_, data_header) * (block.data_unit_is_bits ? 1 : 8);
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#ifndef NDEBUG
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const auto next_chunk = file_.tell() + long(length >> 3);
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#endif
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switch(type) {
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case Type::Gap:
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case Type::Data:
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add_unencoded_data(segments, length_of_a_bit, length);
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break;
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case Type::Sync:
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case Type::Raw:
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add_raw_data(segments, length_of_a_bit, length);
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break;
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default:
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printf("Unhandled data type %d, length %zu bits\n", int(type), length);
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break;
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}
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assert(file_.tell() == next_chunk);
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}
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}
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++block_count;
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}
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return std::make_shared<Storage::Disk::PCMTrack>(segments);
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}
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/// @returns The correct bit length for @c block on a track of @c density.
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///
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/// @discussion At least to me, this is the least well-designed part] of the IPF specification; rather than just dictating cell
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/// densities (or, equivalently, lengths) in the file, densities are named according to their protection scheme and the decoder
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/// is required to know all named protection schemes. Which makes IPF unable to handle arbitrary disks (or, indeed, disks
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/// with multiple protection schemes on a single track).
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Storage::Time IPF::bit_length(TrackDescription::Density density, int block) {
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constexpr unsigned int us = 100'000'000;
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static constexpr auto us170 = Storage::Time::simplified(170, us);
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static constexpr auto us180 = Storage::Time::simplified(180, us);
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static constexpr auto us189 = Storage::Time::simplified(189, us);
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static constexpr auto us190 = Storage::Time::simplified(190, us);
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static constexpr auto us199 = Storage::Time::simplified(199, us);
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static constexpr auto us200 = Storage::Time::simplified(200, us);
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static constexpr auto us209 = Storage::Time::simplified(209, us);
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static constexpr auto us210 = Storage::Time::simplified(210, us);
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static constexpr auto us220 = Storage::Time::simplified(220, us);
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switch(density) {
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default:
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break;
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case TrackDescription::Density::CopylockAmiga:
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if(block == 4) return us189;
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if(block == 5) return us199;
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if(block == 6) return us209;
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break;
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case TrackDescription::Density::CopylockAmigaNew:
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if(block == 0) return us189;
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if(block == 1) return us199;
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if(block == 2) return us209;
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break;
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case TrackDescription::Density::CopylockST:
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if(block == 5) return us210;
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break;
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case TrackDescription::Density::SpeedlockAmiga:
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if(block == 1) return us220;
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if(block == 2) return us180;
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break;
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case TrackDescription::Density::OldSpeedlockAmiga:
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if(block == 1) return us210;
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break;
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case TrackDescription::Density::AdamBrierleyAmiga:
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if(block == 1) return us220;
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if(block == 2) return us210;
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if(block == 3) return us200;
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if(block == 4) return us190;
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if(block == 5) return us180;
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if(block == 6) return us170;
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break;
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// TODO: AdamBrierleyDensityKeyAmiga.
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}
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return us200; // i.e. default to 2µs.
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}
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void IPF::add_gap(std::vector<Storage::Disk::PCMSegment> &track, Time bit_length, size_t num_bits, uint32_t value) {
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auto &segment = track.emplace_back();
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segment.length_of_a_bit = bit_length;
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// Empirically, I think gaps require MFM encoding.
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const auto byte_length = (num_bits + 7) >> 3;
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segment.data.reserve(byte_length * 16);
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auto encoder = Storage::Encodings::MFM::GetMFMEncoder(segment.data);
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while(segment.data.size() < num_bits) {
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encoder->add_byte(uint8_t(value >> 24));
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value = (value << 8) | (value >> 24);
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}
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assert(segment.data.size() <= (byte_length * 16));
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segment.data.resize(num_bits);
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}
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void IPF::add_unencoded_data(std::vector<Storage::Disk::PCMSegment> &track, Time bit_length, size_t num_bits) {
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auto &segment = track.emplace_back();
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segment.length_of_a_bit = bit_length;
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// Length appears to be in pre-encoded bits; double that to get encoded bits.
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#ifndef NDEBUG
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const auto byte_length = (num_bits + 7) >> 3;
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#endif
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segment.data.reserve(num_bits * 16);
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auto encoder = Storage::Encodings::MFM::GetMFMEncoder(segment.data);
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for(size_t c = 0; c < num_bits; c += 8) {
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encoder->add_byte(file_.get8());
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}
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assert(segment.data.size() <= (byte_length * 16));
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segment.data.resize(num_bits * 2);
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}
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void IPF::add_raw_data(std::vector<Storage::Disk::PCMSegment> &track, Time bit_length, size_t num_bits) {
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auto &segment = track.emplace_back();
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segment.length_of_a_bit = bit_length;
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const auto num_bits_ceiling = size_t(num_bits + 7) & size_t(~7);
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segment.data.reserve(num_bits_ceiling);
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for(size_t bit = 0; bit < num_bits; bit += 8) {
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const uint8_t next = file_.get8();
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segment.data.push_back(next & 0x80);
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segment.data.push_back(next & 0x40);
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segment.data.push_back(next & 0x20);
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segment.data.push_back(next & 0x10);
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segment.data.push_back(next & 0x08);
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segment.data.push_back(next & 0x04);
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segment.data.push_back(next & 0x02);
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segment.data.push_back(next & 0x01);
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}
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assert(segment.data.size() <= num_bits_ceiling);
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segment.data.resize(num_bits);
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}
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