// // MFM.cpp // Clock Signal // // Created by Thomas Harte on 18/09/2016. // Copyright © 2016 Thomas Harte. All rights reserved. // #include "MFM.hpp" #include "../PCMTrack.hpp" #include "../../../NumberTheory/CRC.hpp" using namespace Storage::Encodings::MFM; class MFMEncoder: public Encoder { public: MFMEncoder(std::vector &target) : Encoder(target) {} void add_byte(uint8_t input) { crc_generator_.add(input); uint16_t spread_value = (uint16_t)( ((input & 0x01) << 0) | ((input & 0x02) << 1) | ((input & 0x04) << 2) | ((input & 0x08) << 3) | ((input & 0x10) << 4) | ((input & 0x20) << 5) | ((input & 0x40) << 6) | ((input & 0x80) << 7) ); uint16_t or_bits = (uint16_t)((spread_value << 1) | (spread_value >> 1) | (last_output_ << 15)); uint16_t output = spread_value | ((~or_bits) & 0xaaaa); output_short(output); } void add_index_address_mark() { for(int c = 0; c < 3; c++) output_short(MFMIndexSync); add_byte(IndexAddressByte); } void add_ID_address_mark() { output_sync(); add_byte(IDAddressByte); } void add_data_address_mark() { output_sync(); add_byte(DataAddressByte); } void add_deleted_data_address_mark() { output_sync(); add_byte(DeletedDataAddressByte); } private: uint16_t last_output_; void output_short(uint16_t value) { last_output_ = value; Encoder::output_short(value); } void output_sync() { for(int c = 0; c < 3; c++) output_short(MFMSync); crc_generator_.set_value(MFMPostSyncCRCValue); } }; class FMEncoder: public Encoder { // encodes each 16-bit part as clock, data, clock, data [...] public: FMEncoder(std::vector &target) : Encoder(target) {} void add_byte(uint8_t input) { crc_generator_.add(input); output_short( (uint16_t)( ((input & 0x01) << 0) | ((input & 0x02) << 1) | ((input & 0x04) << 2) | ((input & 0x08) << 3) | ((input & 0x10) << 4) | ((input & 0x20) << 5) | ((input & 0x40) << 6) | ((input & 0x80) << 7) | 0xaaaa )); } void add_index_address_mark() { crc_generator_.reset(); crc_generator_.add(IndexAddressByte); output_short(FMIndexAddressMark); } void add_ID_address_mark() { crc_generator_.reset(); crc_generator_.add(IDAddressByte); output_short(FMIDAddressMark); } void add_data_address_mark() { crc_generator_.reset(); crc_generator_.add(DataAddressByte); output_short(FMDataAddressMark); } void add_deleted_data_address_mark() { crc_generator_.reset(); crc_generator_.add(DeletedDataAddressByte); output_short(FMDeletedDataAddressMark); } }; static uint8_t logarithmic_size_for_size(size_t size) { switch(size) { default: return 0; case 256: return 1; case 512: return 2; case 1024: return 3; case 2048: return 4; case 4196: return 5; } } template std::shared_ptr GetTrackWithSectors( const std::vector §ors, size_t post_index_address_mark_bytes, uint8_t post_index_address_mark_value, size_t pre_address_mark_bytes, size_t post_address_mark_bytes, size_t pre_data_mark_bytes, size_t post_data_bytes, size_t inter_sector_gap, size_t expected_track_bytes) { Storage::Disk::PCMSegment segment; segment.data.reserve(expected_track_bytes); T shifter(segment.data); // output the index mark shifter.add_index_address_mark(); // add the post-index mark for(size_t c = 0; c < post_index_address_mark_bytes; c++) shifter.add_byte(post_index_address_mark_value); // add sectors for(const Sector §or : sectors) { // gap for(size_t c = 0; c < pre_address_mark_bytes; c++) shifter.add_byte(0x00); // sector header shifter.add_ID_address_mark(); shifter.add_byte(sector.track); shifter.add_byte(sector.side); shifter.add_byte(sector.sector); uint8_t size = logarithmic_size_for_size(sector.data.size()); shifter.add_byte(size); shifter.add_crc(); // gap for(size_t c = 0; c < post_address_mark_bytes; c++) shifter.add_byte(0x4e); for(size_t c = 0; c < pre_data_mark_bytes; c++) shifter.add_byte(0x00); // data shifter.add_data_address_mark(); for(size_t c = 0; c < sector.data.size(); c++) { shifter.add_byte(sector.data[c]); } shifter.add_crc(); // gap for(size_t c = 0; c < post_data_bytes; c++) shifter.add_byte(0x00); for(size_t c = 0; c < inter_sector_gap; c++) shifter.add_byte(0x4e); } while(segment.data.size() < expected_track_bytes) shifter.add_byte(0x00); segment.number_of_bits = (unsigned int)(segment.data.size() * 8); return std::shared_ptr(new Storage::Disk::PCMTrack(std::move(segment))); } Encoder::Encoder(std::vector &target) : crc_generator_(0x1021, 0xffff), target_(target) {} void Encoder::output_short(uint16_t value) { target_.push_back(value >> 8); target_.push_back(value & 0xff); } void Encoder::add_crc() { uint16_t crc_value = crc_generator_.get_value(); add_byte(crc_value >> 8); add_byte(crc_value & 0xff); } std::shared_ptr Storage::Encodings::MFM::GetFMTrackWithSectors(const std::vector §ors) { return GetTrackWithSectors( sectors, 16, 0x00, 6, 0, 17, 14, 0, 6250); // i.e. 250kbps (including clocks) * 60 = 15000kpm, at 300 rpm => 50 kbits/rotation => 6250 bytes/rotation } std::shared_ptr Storage::Encodings::MFM::GetMFMTrackWithSectors(const std::vector §ors) { return GetTrackWithSectors( sectors, 50, 0x4e, 12, 22, 12, 18, 32, 12500); // unintelligently: double the single-density bytes/rotation (or: 500kps @ 300 rpm) } std::unique_ptr Storage::Encodings::MFM::GetMFMEncoder(std::vector &target) { return std::unique_ptr(new MFMEncoder(target)); } std::unique_ptr Storage::Encodings::MFM::GetFMEncoder(std::vector &target) { return std::unique_ptr(new FMEncoder(target)); } #pragma mark - Parser Parser::Parser(bool is_mfm) : Storage::Disk::Controller(4000000, 1, 300), crc_generator_(0x1021, 0xffff), shift_register_(0), track_(0), is_mfm_(is_mfm) { Storage::Time bit_length; bit_length.length = 1; bit_length.clock_rate = is_mfm ? 500000 : 250000; // i.e. 250 kbps (including clocks) set_expected_bit_length(bit_length); drive.reset(new Storage::Disk::Drive); set_drive(drive); set_motor_on(true); } Parser::Parser(bool is_mfm, const std::shared_ptr &disk) : Parser(is_mfm) { drive->set_disk(disk); } Parser::Parser(bool is_mfm, const std::shared_ptr &track) : Parser(is_mfm) { drive->set_disk_with_track(track); } void Parser::seek_to_track(uint8_t track) { int difference = (int)track - (int)track_; track_ = track; if(difference) { int direction = difference < 0 ? -1 : 1; difference *= direction; for(int c = 0; c < difference; c++) step(direction); } } std::shared_ptr Parser::get_sector(uint8_t track, uint8_t sector) { seek_to_track(track); return get_sector(sector); } std::vector Parser::get_track(uint8_t track) { seek_to_track(track); return get_track(); } void Parser::process_input_bit(int value, unsigned int cycles_since_index_hole) { shift_register_ = ((shift_register_ << 1) | (unsigned int)value) & 0xffff; bit_count_++; } void Parser::process_index_hole() { index_count_++; } uint8_t Parser::get_byte_for_shift_value(uint16_t value) { return (uint8_t)( ((value&0x0001) >> 0) | ((value&0x0004) >> 1) | ((value&0x0010) >> 2) | ((value&0x0040) >> 3) | ((value&0x0100) >> 4) | ((value&0x0400) >> 5) | ((value&0x1000) >> 6) | ((value&0x4000) >> 7)); } uint8_t Parser::get_next_byte() { bit_count_ = 0; while(bit_count_ < 16) run_for_cycles(1); uint8_t byte = get_byte_for_shift_value((uint16_t)shift_register_); crc_generator_.add(byte); return byte; } std::vector Parser::get_track() { std::vector result; int distance_until_permissible_sync = 0; uint8_t last_id[6]; int last_id_pointer = 0; bool next_is_type = false; // align to the next index hole index_count_ = 0; while(!index_count_) run_for_cycles(1); // capture every other bit until the next index hole index_count_ = 0; while(1) { // wait until either another bit or the index hole arrives bit_count_ = 0; bool found_sync = false; while(!index_count_ && !found_sync && bit_count_ < 16) { int previous_bit_count = bit_count_; run_for_cycles(1); if(!distance_until_permissible_sync && bit_count_ != previous_bit_count) { uint16_t low_shift_register = (shift_register_&0xffff); if(is_mfm_) { found_sync = (low_shift_register == MFMIndexSync) || (low_shift_register == MFMSync); } else { found_sync = (low_shift_register == FMIndexAddressMark) || (low_shift_register == FMIDAddressMark) || (low_shift_register == FMDataAddressMark) || (low_shift_register == FMDeletedDataAddressMark); } } } // if that was the index hole then finish if(index_count_) { if(bit_count_) result.push_back(get_byte_for_shift_value((uint16_t)(shift_register_ << (16 - bit_count_)))); break; } // store whatever the current byte is uint8_t byte_value = get_byte_for_shift_value((uint16_t)shift_register_); result.push_back(byte_value); if(last_id_pointer < 6) last_id[last_id_pointer++] = byte_value; // if no syncs are permissible here, decrement the waiting period and perform no further contemplation bool found_id = false, found_data = false; if(distance_until_permissible_sync) { distance_until_permissible_sync--; } else { if(found_sync) { if(is_mfm_) { next_is_type = true; } else { switch(shift_register_&0xffff) { case FMIDAddressMark: found_id = true; break; case FMDataAddressMark: case FMDeletedDataAddressMark: found_data = true; break; } } } else if(next_is_type) { switch(byte_value) { case IDAddressByte: found_id = true; break; case DataAddressByte: case DeletedDataAddressByte: found_data = true; break; } } } if(found_id) { distance_until_permissible_sync = 6; last_id_pointer = 0; } if(found_data) { distance_until_permissible_sync = 128 << last_id[3]; } } return result; } std::shared_ptr Parser::get_next_sector() { std::shared_ptr sector(new Sector); index_count_ = 0; while(index_count_ < 2) { // look for an ID address mark bool id_found = false; while(!id_found) { run_for_cycles(1); if(is_mfm_) { while(shift_register_ == MFMSync) { uint8_t mark = get_next_byte(); if(mark == IDAddressByte) { crc_generator_.set_value(MFMPostSyncCRCValue); id_found = true; break; } } } else { if(shift_register_ == FMIDAddressMark) { crc_generator_.reset(); id_found = true; } } if(index_count_ >= 2) return nullptr; } crc_generator_.add(IDAddressByte); sector->track = get_next_byte(); sector->side = get_next_byte(); sector->sector = get_next_byte(); uint8_t size = get_next_byte(); uint16_t header_crc = crc_generator_.get_value(); if((header_crc >> 8) != get_next_byte()) continue; if((header_crc & 0xff) != get_next_byte()) continue; // look for data mark bool data_found = false; while(!data_found) { run_for_cycles(1); if(is_mfm_) { while(shift_register_ == MFMSync) { uint8_t mark = get_next_byte(); if(mark == DataAddressByte) { crc_generator_.set_value(MFMPostSyncCRCValue); data_found = true; break; } if(mark == IDAddressByte) return nullptr; } } else { if(shift_register_ == FMDataAddressMark) { crc_generator_.reset(); data_found = true; } if(shift_register_ == FMIDAddressMark) return nullptr; } if(index_count_ >= 2) return nullptr; } crc_generator_.add(DataAddressByte); size_t data_size = (size_t)(128 << size); sector->data.reserve(data_size); for(size_t c = 0; c < data_size; c++) { sector->data.push_back(get_next_byte()); } uint16_t data_crc = crc_generator_.get_value(); if((data_crc >> 8) != get_next_byte()) continue; if((data_crc & 0xff) != get_next_byte()) continue; return sector; } return nullptr; } std::shared_ptr Parser::get_sector(uint8_t sector) { std::shared_ptr first_sector; index_count_ = 0; while(!first_sector && index_count_ < 2) first_sector = get_next_sector(); if(!first_sector) return first_sector; if(first_sector->sector == sector) return first_sector; while(1) { std::shared_ptr next_sector = get_next_sector(); if(!next_sector) continue; if(next_sector->sector == first_sector->sector) return nullptr; if(next_sector->sector == sector) return next_sector; } }