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CLK/Storage/Disk/Parsers/CPM.cpp

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//
// CPM.cpp
// Clock Signal
//
// Created by Thomas Harte on 10/08/2017.
// Copyright 2017 Thomas Harte. All rights reserved.
//
#include "CPM.hpp"
#include <algorithm>
#include <cstring>
#include "../Encodings/MFM/Parser.hpp"
using namespace Storage::Disk::CPM;
std::unique_ptr<Storage::Disk::CPM::Catalogue> Storage::Disk::CPM::GetCatalogue(const std::shared_ptr<Storage::Disk::Disk> &disk, const ParameterBlock &parameters) {
Storage::Encodings::MFM::Parser parser(true, disk);
// Assemble the actual bytes of the catalogue.
std::vector<uint8_t> catalogue;
std::size_t sector_size = 1;
uint16_t catalogue_allocation_bitmap = parameters.catalogue_allocation_bitmap;
if(!catalogue_allocation_bitmap) return nullptr;
int sector = 0;
int track = parameters.reserved_tracks;
while(catalogue_allocation_bitmap) {
if(catalogue_allocation_bitmap & 0x8000) {
std::size_t size_read = 0;
do {
Storage::Encodings::MFM::Sector *sector_contents = parser.get_sector(0, uint8_t(track), uint8_t(parameters.first_sector + sector));
if(!sector_contents || sector_contents->samples.empty()) {
return nullptr;
}
catalogue.insert(catalogue.end(), sector_contents->samples[0].begin(), sector_contents->samples[0].end());
sector_size = sector_contents->samples[0].size();
size_read += sector_size;
sector++;
if(sector == parameters.sectors_per_track) {
sector = 0;
track++;
}
} while(size_read < size_t(parameters.block_size));
}
catalogue_allocation_bitmap <<= 1;
}
struct CatalogueEntry {
uint8_t user_number;
std::string name;
std::string type;
bool read_only;
bool system;
std::size_t extent;
uint8_t number_of_records;
std::size_t catalogue_index;
bool operator < (const CatalogueEntry &rhs) const {
return std::tie(user_number, name, type, extent) < std::tie(rhs.user_number, rhs.name, rhs.type, rhs.extent);
}
bool is_same_file(const CatalogueEntry &rhs) const {
return std::tie(user_number, name, type) == std::tie(rhs.user_number, rhs.name, rhs.type);
}
};
// From the catalogue, get catalogue entries.
std::vector<CatalogueEntry> catalogue_entries;
for(std::size_t c = 0; c < catalogue.size(); c += 32) {
// Skip this file if it's deleted; this is marked by it having 0xe5 as its user number
if(catalogue[c] == 0xe5) continue;
catalogue_entries.emplace_back();
CatalogueEntry &entry = catalogue_entries.back();
entry.user_number = catalogue[c];
entry.name.insert(entry.name.begin(), &catalogue[c+1], &catalogue[c+9]);
for(std::size_t s = 0; s < 3; s++) entry.type.push_back(char(catalogue[c + s + 9]) & 0x7f);
entry.read_only = catalogue[c + 9] & 0x80;
entry.system = catalogue[c + 10] & 0x80;
entry.extent = size_t(catalogue[c + 12] + (catalogue[c + 14] << 5));
entry.number_of_records = catalogue[c + 15];
entry.catalogue_index = c;
}
// Sort the catalogue entries and then map to files.
std::sort(catalogue_entries.begin(), catalogue_entries.end());
std::unique_ptr<Catalogue> result(new Catalogue);
bool has_long_allocation_units = (parameters.tracks * parameters.sectors_per_track * int(sector_size) / parameters.block_size) >= 256;
std::size_t bytes_per_catalogue_entry = (has_long_allocation_units ? 8 : 16) * size_t(parameters.block_size);
int sectors_per_block = parameters.block_size / int(sector_size);
int records_per_sector = int(sector_size) / 128;
auto entry = catalogue_entries.begin();
while(entry != catalogue_entries.end()) {
// Find final catalogue entry that relates to the same file.
auto final_entry = entry + 1;
while(final_entry != catalogue_entries.end() && final_entry->is_same_file(*entry)) {
final_entry++;
}
final_entry--;
// Create file.
result->files.emplace_back();
File &new_file = result->files.back();
new_file.user_number = entry->user_number;
new_file.name = std::move(entry->name);
new_file.type = std::move(entry->type);
new_file.read_only = entry->read_only;
new_file.system = entry->system;
// Create storage for data.
std::size_t required_size = final_entry->extent * bytes_per_catalogue_entry + size_t(final_entry->number_of_records) * 128;
new_file.data.resize(required_size);
// Accumulate all data.
while(entry <= final_entry) {
int record = 0;
int number_of_records = (entry->number_of_records != 0x80) ? entry->number_of_records : (has_long_allocation_units ? 8 : 16);
for(std::size_t block = 0; block < (has_long_allocation_units ? 8 : 16) && record < number_of_records; block++) {
int block_number;
if(has_long_allocation_units) {
block_number = catalogue[entry->catalogue_index + 16 + (block << 1)] + (catalogue[entry->catalogue_index + 16 + (block << 1) + 1] << 8);
} else {
block_number = catalogue[entry->catalogue_index + 16 + block];
}
if(!block_number) {
record += parameters.block_size / 128;
continue;
}
int first_sector = block_number * sectors_per_block;
sector = first_sector % parameters.sectors_per_track;
track = first_sector / parameters.sectors_per_track;
for(int s = 0; s < sectors_per_block && record < number_of_records; s++) {
Storage::Encodings::MFM::Sector *sector_contents = parser.get_sector(0, uint8_t(track), uint8_t(parameters.first_sector + sector));
if(!sector_contents || sector_contents->samples.empty()) break;
sector++;
if(sector == parameters.sectors_per_track) {
sector = 0;
track++;
}
int records_to_copy = std::min(entry->number_of_records - record, records_per_sector);
std::memcpy(&new_file.data[entry->extent * bytes_per_catalogue_entry + size_t(record) * 128], sector_contents->samples[0].data(), size_t(records_to_copy) * 128);
record += records_to_copy;
}
}
entry++;
}
}
return result;
}