// // Archimedes.cpp // Clock Signal // // Created by Thomas Harte on 04/03/2024. // Copyright © 2024 Thomas Harte. All rights reserved. // #include "Archimedes.hpp" #include "../../AudioProducer.hpp" #include "../../KeyboardMachine.hpp" #include "../../MediaTarget.hpp" #include "../../ScanProducer.hpp" #include "../../TimedMachine.hpp" #include "../../../InstructionSets/ARM/Executor.hpp" #include "../../../Outputs/Log.hpp" #include #include #include namespace { Log::Logger logger; enum class Zone { LogicallyMappedRAM, PhysicallyMappedRAM, IOControllers, LowROM, HighROM, VideoController, DMAAndMEMC, AddressTranslator, }; constexpr std::array zones(bool is_read) { std::array zones{}; for(size_t c = 0; c < zones.size(); c++) { const auto address = c << 21; if(address < 0x200'0000) { zones[c] = Zone::LogicallyMappedRAM; } else if(address < 0x300'0000) { zones[c] = Zone::PhysicallyMappedRAM; } else if(address < 0x340'0000) { zones[c] = Zone::IOControllers; } else if(address < 0x360'0000) { zones[c] = is_read ? Zone::LowROM : Zone::VideoController; } else if(address < 0x380'0000) { zones[c] = is_read ? Zone::LowROM : Zone::DMAAndMEMC; } else { zones[c] = is_read ? Zone::HighROM : Zone::AddressTranslator; } } return zones; } } namespace Archimedes { /// Primarily models the MEMC. struct Memory { void set_rom(const std::vector &rom) { std::copy( rom.begin(), rom.begin() + static_cast(std::min(rom.size(), rom_.size())), rom_.begin()); } template bool write(uint32_t address, IntT source, InstructionSet::ARM::Mode mode, bool trans) { (void)mode; (void)trans; switch (write_zones_[(address >> 21) & 31]) { case Zone::DMAAndMEMC: // if(mode != InstructionSet::ARM::Mode::Supervisor) return false; if((address & 0b1110'0000'0000'0000'0000) == 0b1110'0000'0000'0000'0000) { logger.error().append("TODO: MEMC Control: %08x", source); break; } else { logger.error().append("TODO: DMA/MEMC %08x to %08x", source, address); break; } case Zone::PhysicallyMappedRAM: // if(mode != InstructionSet::ARM::Mode::Supervisor) return false; physical_ram(address) = source; break; default: printf("TODO: write of %08x to %08x [%lu]\n", source, address, sizeof(IntT)); break; } return true; } template bool read(uint32_t address, IntT &source, InstructionSet::ARM::Mode mode, bool trans) { (void)mode; (void)trans; switch (read_zones_[(address >> 21) & 31]) { case Zone::PhysicallyMappedRAM: // if(mode != InstructionSet::ARM::Mode::Supervisor) return false; source = physical_ram(address); return true; case Zone::LogicallyMappedRAM: if(!has_moved_rom_) { source = high_rom(address); break; } logger.error().append("TODO: Logical RAM read from %08x", address); break; case Zone::HighROM: has_moved_rom_ = true; source = high_rom(address); break; default: logger.error().append("TODO: read from %08x", address); break; } source = 0; return true; } private: bool has_moved_rom_ = false; std::array ram_{}; std::array rom_; template IntT &physical_ram(uint32_t address) { return *reinterpret_cast(&ram_[address & (ram_.size() - 1)]); } template IntT &high_rom(uint32_t address) { return *reinterpret_cast(&rom_[address & (rom_.size() - 1)]); } static constexpr std::array read_zones_ = zones(true); static constexpr std::array write_zones_ = zones(false); }; class ConcreteMachine: public Machine, public MachineTypes::MediaTarget, public MachineTypes::TimedMachine, public MachineTypes::ScanProducer { public: ConcreteMachine( const Analyser::Static::Target &target, const ROMMachine::ROMFetcher &rom_fetcher ) { constexpr ROM::Name risc_os = ROM::Name::AcornRISCOS319; ROM::Request request(risc_os); auto roms = rom_fetcher(request); if(!request.validate(roms)) { throw ROMMachine::Error::MissingROMs; } executor_.bus.set_rom(roms.find(risc_os)->second); // TODO: pick a sensible clock rate; this is just code for '20 MIPS, please'. set_clock_rate(20'000'000); insert_media(target.media); } private: // MARK: - ScanProducer. void set_scan_target(Outputs::Display::ScanTarget *scan_target) override { (void)scan_target; } Outputs::Display::ScanStatus get_scaled_scan_status() const override { return Outputs::Display::ScanStatus(); } // MARK: - TimedMachine. void run_for(Cycles cycles) override { auto instructions = cycles.as(); while(instructions--) { uint32_t instruction; executor_.bus.read(executor_.pc(), instruction, executor_.registers().mode(), false); // TODO: what if abort? How about pipeline prefetch? InstructionSet::ARM::execute(instruction, executor_); } } // MARK: - MediaTarget bool insert_media(const Analyser::Static::Media &) override { // int c = 0; // for(auto &disk : media.disks) { // fdc_.set_disk(disk, c); // c++; // if(c == 4) break; // } // return true; return false; } // MARK: - ARM execution static constexpr auto arm_model = InstructionSet::ARM::Model::ARMv2; InstructionSet::ARM::Executor executor_; }; } using namespace Archimedes; std::unique_ptr Machine::Archimedes(const Analyser::Static::Target *target, const ROMMachine::ROMFetcher &rom_fetcher) { return std::make_unique(*target, rom_fetcher); }