// // AmstradCPC.cpp // Clock Signal // // Created by Thomas Harte on 30/07/2017. // Copyright 2017 Thomas Harte. All rights reserved. // #include "StaticAnalyser.hpp" #include #include #include "../../../Storage/Disk/Parsers/CPM.hpp" #include "../../../Storage/Disk/Encodings/MFM/Parser.hpp" #include "../../../Storage/Tape/Parsers/Spectrum.hpp" #include "Target.hpp" namespace { bool strcmp_insensitive(const char *a, const char *b) { if(std::strlen(a) != std::strlen(b)) return false; while(*a) { if(std::tolower(*a) != std::tolower(*b)) return false; a++; b++; } return true; } bool is_implied_extension(const std::string &extension) { return extension == " " || strcmp_insensitive(extension.c_str(), "BAS") || strcmp_insensitive(extension.c_str(), "BIN"); } void right_trim(std::string &string) { string.erase(std::find_if(string.rbegin(), string.rend(), [](int ch) { return !std::isspace(ch); }).base(), string.end()); } std::string RunCommandFor(const Storage::Disk::CPM::File &file) { // Trim spaces from the name. std::string name = file.name; right_trim(name); // Form the basic command. std::string command = "run\"" + name; // Consider whether the extension is required. if(!is_implied_extension(file.type)) { std::string type = file.type; right_trim(type); command += "." + type; } // Add a newline and return. return command + "\n"; } void InspectCatalogue( const Storage::Disk::CPM::Catalogue &catalogue, const std::unique_ptr &target) { std::vector candidate_files; candidate_files.reserve(catalogue.files.size()); for(const auto &file : catalogue.files) { candidate_files.push_back(&file); } // Remove all files with untypable characters. candidate_files.erase( std::remove_if(candidate_files.begin(), candidate_files.end(), [](const Storage::Disk::CPM::File *file) { for(const auto c : file->name + file->type) { if(c < 32) return true; } return false; }), candidate_files.end()); // If that leaves a mix of 'system' (i.e. hidden) and non-system files, remove the system files. bool are_all_system = true; for(const auto &file : candidate_files) { if(!file->system) { are_all_system = false; break; } } if(!are_all_system) { candidate_files.erase( std::remove_if(candidate_files.begin(), candidate_files.end(), [](const Storage::Disk::CPM::File *file) { return file->system; }), candidate_files.end()); } // If there's just one file, run that. if(candidate_files.size() == 1) { target->loading_command = RunCommandFor(*candidate_files[0]); return; } // If only one file is [potentially] BASIC, run that one; otherwise if only one has a suffix // that AMSDOS allows to be omitted, pick that one. int basic_files = 0; int implicit_suffixed_files = 0; std::size_t last_basic_file = 0; std::size_t last_implicit_suffixed_file = 0; for(std::size_t c = 0; c < candidate_files.size(); c++) { // Files with nothing but spaces in their name can't be loaded by the user, so disregard them. if(candidate_files[c]->type == " " && candidate_files[c]->name == " ") continue; // Check for whether this is [potentially] BASIC. if(candidate_files[c]->data.size() >= 128 && !((candidate_files[c]->data[18] >> 1) & 7)) { basic_files++; last_basic_file = c; } // Check suffix for emptiness. if(is_implied_extension(candidate_files[c]->type)) { implicit_suffixed_files++; last_implicit_suffixed_file = c; } } if(basic_files == 1 || implicit_suffixed_files == 1) { std::size_t selected_file = (basic_files == 1) ? last_basic_file : last_implicit_suffixed_file; target->loading_command = RunCommandFor(*candidate_files[selected_file]); return; } // One more guess: if only one remaining candidate file has a different name than the others, // assume it is intended to stand out. std::map name_counts; std::map indices_by_name; std::size_t index = 0; for(const auto &file : candidate_files) { name_counts[file->name]++; indices_by_name[file->name] = index; index++; } if(name_counts.size() == 2) { for(const auto &pair : name_counts) { if(pair.second == 1) { target->loading_command = RunCommandFor(*candidate_files[indices_by_name[pair.first]]); return; } } } // Desperation. target->loading_command = "cat\n"; } bool CheckBootSector(const std::shared_ptr &disk, const std::unique_ptr &target) { Storage::Encodings::MFM::Parser parser(Storage::Encodings::MFM::Density::Double, disk); const Storage::Encodings::MFM::Sector *boot_sector = parser.sector(0, 0, 0x41); if(boot_sector != nullptr && !boot_sector->samples.empty() && boot_sector->samples[0].size() == 512) { // Check that the first 64 bytes of the sector aren't identical; if they are then probably // this disk was formatted and the filler byte never replaced. bool matched = true; for(std::size_t c = 1; c < 64; c++) { if(boot_sector->samples[0][c] != boot_sector->samples[0][0]) { matched = false; break; } } // This is a system disk, then launch it as though it were CP/M. if(!matched) { target->loading_command = "|cpm\n"; return true; } } return false; } bool IsAmstradTape(const std::shared_ptr &tape) { // Limited sophistication here; look for a CPC-style file header, that is // any Spectrum-esque block with a synchronisation character of 0x2c. // // More could be done here: parse the header, look for 0x16 data records. using Parser = Storage::Tape::ZXSpectrum::Parser; Parser parser(Parser::MachineType::AmstradCPC); while(true) { const auto block = parser.find_block(tape); if(!block) break; if(block->type == 0x2c) { return true; } } return false; } } // namespace Analyser::Static::TargetList Analyser::Static::AmstradCPC::GetTargets(const Media &media, const std::string &, TargetPlatform::IntType) { TargetList destination; auto target = std::make_unique(); target->confidence = 0.5; target->model = Target::Model::CPC6128; if(!media.tapes.empty()) { bool has_cpc_tape = false; for(auto &tape: media.tapes) { has_cpc_tape |= IsAmstradTape(tape); } if(has_cpc_tape) { target->media.tapes = media.tapes; // Ugliness flows here: assume the CPC isn't smart enough to pause between pressing // enter and responding to the follow-on prompt to press a key, so just type for // a while. Yuck! target->loading_command = "|tape\nrun\"\n123"; } } if(!media.disks.empty()) { Storage::Disk::CPM::ParameterBlock data_format; data_format.sectors_per_track = 9; data_format.tracks = 40; data_format.block_size = 1024; data_format.first_sector = 0xc1; data_format.catalogue_allocation_bitmap = 0xc000; data_format.reserved_tracks = 0; Storage::Disk::CPM::ParameterBlock system_format; system_format.sectors_per_track = 9; system_format.tracks = 40; system_format.block_size = 1024; system_format.first_sector = 0x41; system_format.catalogue_allocation_bitmap = 0xc000; system_format.reserved_tracks = 2; for(auto &disk: media.disks) { // Check for an ordinary catalogue. std::unique_ptr data_catalogue = Storage::Disk::CPM::GetCatalogue(disk, data_format); if(data_catalogue) { InspectCatalogue(*data_catalogue, target); target->media.disks.push_back(disk); continue; } // Failing that check for a boot sector. if(CheckBootSector(disk, target)) { target->media.disks.push_back(disk); continue; } // Failing that check for a system catalogue. std::unique_ptr system_catalogue = Storage::Disk::CPM::GetCatalogue(disk, system_format); if(system_catalogue) { InspectCatalogue(*system_catalogue, target); target->media.disks.push_back(disk); continue; } } } // If any media survived, add the target. if(!target->media.empty()) destination.push_back(std::move(target)); return destination; }