// // AcornAnalyser.cpp // Clock Signal // // Created by Thomas Harte on 29/08/2016. // Copyright 2016 Thomas Harte. All rights reserved. // #include "StaticAnalyser.hpp" #include "Disk.hpp" #include "Tape.hpp" #include "Target.hpp" #include using namespace Analyser::Static::Acorn; static std::vector> AcornCartridgesFrom(const std::vector> &cartridges) { std::vector> acorn_cartridges; for(const auto &cartridge : cartridges) { const auto &segments = cartridge->get_segments(); // only one mapped item is allowed if(segments.size() != 1) continue; // which must be 8 or 16 kb in size const Storage::Cartridge::Cartridge::Segment &segment = segments.front(); if(segment.data.size() != 0x4000 && segment.data.size() != 0x2000) continue; // is a copyright string present? const uint8_t copyright_offset = segment.data[7]; if( segment.data[copyright_offset] != 0x00 || segment.data[copyright_offset+1] != 0x28 || segment.data[copyright_offset+2] != 0x43 || segment.data[copyright_offset+3] != 0x29 ) continue; // is the language entry point valid? if(!( (segment.data[0] == 0x00 && segment.data[1] == 0x00 && segment.data[2] == 0x00) || (segment.data[0] != 0x00 && segment.data[2] >= 0x80 && segment.data[2] < 0xc0) )) continue; // is the service entry point valid? if(!(segment.data[5] >= 0x80 && segment.data[5] < 0xc0)) continue; // probability of a random binary blob that isn't an Acorn ROM proceeding to here: // 1/(2^32) * // ( ((2^24)-1)/(2^24)*(1/4) + 1/(2^24) ) * // 1/4 // = something very improbable, around 1/16th of 1 in 2^32, but not exactly. acorn_cartridges.push_back(cartridge); } return acorn_cartridges; } Analyser::Static::TargetList Analyser::Static::Acorn::GetTargets(const Media &media, const std::string &, TargetPlatform::IntType) { auto target8bit = std::make_unique(); auto targetArchimedes = std::make_unique(Machine::Archimedes); // Copy appropriate cartridges to the 8-bit target. target8bit->media.cartridges = AcornCartridgesFrom(media.cartridges); // If there are any tapes, attempt to get data from the first. if(!media.tapes.empty()) { std::shared_ptr tape = media.tapes.front(); std::vector files = GetFiles(tape); tape->reset(); // continue if there are any files if(!files.empty()) { bool is_basic = true; // If a file is execute-only, that means *RUN. if(files.front().flags & File::Flags::ExecuteOnly) is_basic = false; // check also for a continuous threading of BASIC lines; if none then this probably isn't BASIC code, // so that's also justification to *RUN std::size_t pointer = 0; uint8_t *const data = &files.front().data[0]; const std::size_t data_size = files.front().data.size(); while(1) { if(pointer >= data_size-1 || data[pointer] != 13) { is_basic = false; break; } if((data[pointer+1]&0x7f) == 0x7f) break; pointer += data[pointer+3]; } // Inspect first file. If it's protected or doesn't look like BASIC // then the loading command is *RUN. Otherwise it's CHAIN"". target8bit->loading_command = is_basic ? "CHAIN\"\"\n" : "*RUN\n"; target8bit->media.tapes = media.tapes; } } if(!media.disks.empty()) { // TODO: below requires an [8-bit compatible] 'Hugo' ADFS catalogue, disallowing // [Archimedes-exclusive] 'Nick' catalogues. // // Would be better to form the appropriate target in the latter case. std::shared_ptr disk = media.disks.front(); std::unique_ptr dfs_catalogue, adfs_catalogue; dfs_catalogue = GetDFSCatalogue(disk); if(dfs_catalogue == nullptr) adfs_catalogue = GetADFSCatalogue(disk); if(dfs_catalogue || (adfs_catalogue && !adfs_catalogue->has_large_sectors && adfs_catalogue->is_hugo)) { // Accept the disk and determine whether DFS or ADFS ROMs are implied. // Use the Pres ADFS if using an ADFS, as it leaves Page at &EOO. target8bit->media.disks = media.disks; target8bit->has_dfs = bool(dfs_catalogue); target8bit->has_pres_adfs = bool(adfs_catalogue); // Check whether a simple shift+break will do for loading this disk. Catalogue::BootOption bootOption = (dfs_catalogue ?: adfs_catalogue)->bootOption; if(bootOption != Catalogue::BootOption::None) { target8bit->should_shift_restart = true; } else { target8bit->loading_command = "*CAT\n"; } // Check whether adding the AP6 ROM is justified. // For now this is an incredibly dense text search; // if any of the commands that aren't usually present // on a stock Electron are here, add the AP6 ROM and // some sideways RAM such that the SR commands are useful. for(const auto &file: dfs_catalogue ? dfs_catalogue->files : adfs_catalogue->files) { for(const auto &command: { "AQRPAGE", "BUILD", "DUMP", "FORMAT", "INSERT", "LANG", "LIST", "LOADROM", "LOCK", "LROMS", "RLOAD", "ROMS", "RSAVE", "SAVEROM", "SRLOAD", "SRPAGE", "SRUNLOCK", "SRWIPE", "TUBE", "TYPE", "UNLOCK", "UNPLUG", "UROMS", "VERIFY", "ZERO" }) { if(std::search(file.data.begin(), file.data.end(), command, command+strlen(command)) != file.data.end()) { target8bit->has_ap6_rom = true; target8bit->has_sideways_ram = true; } } } } else if(adfs_catalogue) { targetArchimedes->media.disks = media.disks; } } // Enable the Acorn ADFS if a mass-storage device is attached; // unlike the Pres ADFS it retains SCSI logic. if(!media.mass_storage_devices.empty()) { target8bit->has_pres_adfs = false; // To override a floppy selection, if one was made. target8bit->has_acorn_adfs = true; // Assume some sort of later-era Acorn work is likely to happen; // so ensure *TYPE, etc are present. target8bit->has_ap6_rom = true; target8bit->has_sideways_ram = true; target8bit->media.mass_storage_devices = media.mass_storage_devices; // Check for a boot option. const auto sector = target8bit->media.mass_storage_devices.front()->get_block(1); if(sector[0xfd]) { target8bit->should_shift_restart = true; } else { target8bit->loading_command = "*CAT\n"; } } TargetList targets; if(!target8bit->media.empty()) { targets.push_back(std::move(target8bit)); } if(!targetArchimedes->media.empty()) { targets.push_back(std::move(targetArchimedes)); } return targets; }