// // Oric.cpp // Clock Signal // // Created by Thomas Harte on 11/10/2016. // Copyright 2016 Thomas Harte. All rights reserved. // #include "Oric.hpp" #include "BD500.hpp" #include "Jasmin.hpp" #include "Keyboard.hpp" #include "Microdisc.hpp" #include "Video.hpp" #include "../../Activity/Source.hpp" #include "../MachineTypes.hpp" #include "../Utility/MemoryFuzzer.hpp" #include "../Utility/StringSerialiser.hpp" #include "../../Processors/6502Esque/6502Selector.hpp" #include "../../Components/6522/6522.hpp" #include "../../Components/AY38910/AY38910.hpp" #include "../../Components/DiskII/DiskII.hpp" #include "../../Storage/Tape/Tape.hpp" #include "../../Storage/Tape/Parsers/Oric.hpp" #include "../../ClockReceiver/ForceInline.hpp" #include "../../Configurable/StandardOptions.hpp" #include "../../Outputs/Speaker/Implementation/LowpassSpeaker.hpp" #include "../../Analyser/Static/Oric/Target.hpp" #include "../../ClockReceiver/JustInTime.hpp" #include #include #include #include namespace { /*! Provides an Altai-style joystick. */ class Joystick: public Inputs::ConcreteJoystick { public: Joystick() : ConcreteJoystick({ Input(Input::Up), Input(Input::Down), Input(Input::Left), Input(Input::Right), Input(Input::Fire) }) {} void did_set_input(const Input &digital_input, bool is_active) final { const auto apply = [&](uint8_t bit) { if(is_active) state_ &= ~bit; else state_ |= bit; }; switch(digital_input.type) { default: return; case Input::Right: apply(0x02); break; case Input::Left: apply(0x01); break; case Input::Down: apply(0x08); break; case Input::Up: apply(0x10); break; case Input::Fire: apply(0x20); break; } } uint8_t get_state() { return state_; } private: uint8_t state_ = 0xff; }; } namespace Oric { using DiskInterface = Analyser::Static::Oric::Target::DiskInterface; using Processor = Analyser::Static::Oric::Target::Processor; using AY = GI::AY38910::AY38910; using Speaker = Outputs::Speaker::PullLowpass; enum ROM { BASIC10 = 0, BASIC11, Microdisc, Colour }; /*! Models the Oric's keyboard: eight key rows, containing a bitfield of keys set. Active line is selected through a port on the Oric's VIA, and a column mask is selected via a port on the AY, returning a single Boolean representation of the logical OR of every key selected by the column mask on the active row. */ class Keyboard { public: struct SpecialKeyHandler { virtual void perform_special_key(Oric::Key key) = 0; }; Keyboard(SpecialKeyHandler *handler) : special_key_handler_(handler) { clear_all_keys(); } /// Sets whether @c key is or is not pressed, per @c is_pressed. void set_key_state(uint16_t key, bool is_pressed) { switch(key) { default: { const uint8_t mask = key & 0xff; const int line = key >> 8; if(is_pressed) rows_[line] |= mask; else rows_[line] &= ~mask; } break; case KeyNMI: case KeyJasminReset: if(is_pressed) { special_key_handler_->perform_special_key(Oric::Key(key)); } break; } } /// Sets all keys as unpressed. void clear_all_keys() { memset(rows_, 0, sizeof(rows_)); } /// Selects the active row. void set_active_row(uint8_t row) { row_ = row & 7; } /// Queries the keys on the active row specified by @c mask. bool query_column(uint8_t column_mask) { return !!(rows_[row_] & column_mask); } private: uint8_t row_ = 0; uint8_t rows_[8]; SpecialKeyHandler *const special_key_handler_; }; /*! Provide's the Oric's tape player: a standard binary-sampled tape which also holds an instance of the Oric tape parser, to provide fast-tape loading. */ class TapePlayer: public Storage::Tape::BinaryTapePlayer { public: TapePlayer() : Storage::Tape::BinaryTapePlayer(1000000) {} /*! Parses the incoming tape event stream to obtain the next stored byte. @param use_fast_encoding If set to @c true , inspects the tape as though it is encoded in the Oric's fast-loading scheme. Otherwise looks for a slow-encoded byte. @returns The next byte from the tape. */ uint8_t get_next_byte(bool use_fast_encoding) { return uint8_t(parser_.get_next_byte(get_tape(), use_fast_encoding)); } private: Storage::Tape::Oric::Parser parser_; }; /*! Implements the Oric's VIA's port handler. On the Oric the VIA's ports connect to the AY, the tape's motor control signal and the keyboard. */ class VIAPortHandler: public MOS::MOS6522::IRQDelegatePortHandler { public: VIAPortHandler(Concurrency::AsyncTaskQueue &audio_queue, AY &ay8910, Speaker &speaker, TapePlayer &tape_player, Keyboard &keyboard) : audio_queue_(audio_queue), ay8910_(ay8910), speaker_(speaker), tape_player_(tape_player), keyboard_(keyboard) { // Attach a couple of joysticks. joysticks_.emplace_back(new Joystick); joysticks_.emplace_back(new Joystick); } /*! Reponds to the 6522's control line output change signal; on an Oric A2 is connected to the AY's BDIR, and B2 is connected to the AY's A2. */ void set_control_line_output(MOS::MOS6522::Port port, MOS::MOS6522::Line line, bool value) { if(line) { if(port) ay_bdir_ = value; else ay_bc1_ = value; update_ay(); ay8910_.set_control_lines( (GI::AY38910::ControlLines)((ay_bdir_ ? GI::AY38910::BDIR : 0) | (ay_bc1_ ? GI::AY38910::BC1 : 0) | GI::AY38910::BC2)); } } /*! Reponds to changes in the 6522's port output. On an Oric port B sets the tape motor control and the keyboard's active row. Port A is connected to the AY's data bus. */ void set_port_output(MOS::MOS6522::Port port, uint8_t value, uint8_t) { if(port) { keyboard_.set_active_row(value); tape_player_.set_motor_control(value & 0x40); } else { update_ay(); ay8910_.set_data_input(value); porta_output_ = value; } } /*! Provides input data for the 6522. Port B reads the keyboard, and port A reads from the AY. */ uint8_t get_port_input(MOS::MOS6522::Port port) { if(port) { uint8_t column = ay8910_.get_port_output(false) ^ 0xff; return keyboard_.query_column(column) ? 0x08 : 0x00; } else { uint8_t result = ay8910_.get_data_output(); if(porta_output_ & 0x40) result &= static_cast(joysticks_[0].get())->get_state(); if(porta_output_ & 0x80) result &= static_cast(joysticks_[1].get())->get_state(); return result; } } /*! Advances time. This class manages the AY's concept of time to permit updating-on-demand. */ inline void run_for(const HalfCycles cycles) { cycles_since_ay_update_ += cycles; } /// Flushes any queued behaviour (which, specifically, means on the AY). void flush() { update_ay(); audio_queue_.perform(); } const std::vector> &get_joysticks() { return joysticks_; } private: void update_ay() { speaker_.run_for(audio_queue_, cycles_since_ay_update_.flush()); } bool ay_bdir_ = false; bool ay_bc1_ = false; uint8_t porta_output_ = 0xff; HalfCycles cycles_since_ay_update_; Concurrency::AsyncTaskQueue &audio_queue_; AY &ay8910_; Speaker &speaker_; TapePlayer &tape_player_; Keyboard &keyboard_; std::vector> joysticks_; }; template class ConcreteMachine: public MachineTypes::TimedMachine, public MachineTypes::ScanProducer, public MachineTypes::AudioProducer, public MachineTypes::JoystickMachine, public MachineTypes::MediaTarget, public MachineTypes::MappedKeyboardMachine, public Configurable::Device, public CPU::MOS6502::BusHandler, public MOS::MOS6522::IRQDelegatePortHandler::Delegate, public Storage::Tape::BinaryTapePlayer::Delegate, public DiskController::Delegate, public Activity::Source, public Machine, public Keyboard::SpecialKeyHandler { public: ConcreteMachine(const Analyser::Static::Oric::Target &target, const ROMMachine::ROMFetcher &rom_fetcher) : m6502_(*this), video_(ram_.data()), ay8910_(GI::AY38910::Personality::AY38910, audio_queue_), speaker_(ay8910_), via_port_handler_(audio_queue_, ay8910_, speaker_, tape_player_, keyboard_), via_(via_port_handler_), keyboard_(this), diskii_(2000000) { set_clock_rate(1000000); speaker_.set_input_rate(1000000.0f); via_port_handler_.set_interrupt_delegate(this); tape_player_.set_delegate(this); // Slight hack here: I'm unclear what RAM should look like at startup. // Actually, I think completely random might be right since the Microdisc // sort of assumes it, but also the BD-500 never explicitly sets PAL mode // so I can't have any switch-to-NTSC bytes in the display area. Hence: // disallow all atributes. Memory::Fuzz(ram_); for(auto &c: ram_) { c |= 0x40; } ::ROM::Request request = ::ROM::Request(::ROM::Name::OricColourROM, true); ::ROM::Name basic; switch(target.rom) { case Analyser::Static::Oric::Target::ROM::BASIC10: basic = ::ROM::Name::OricBASIC10; break; default: case Analyser::Static::Oric::Target::ROM::BASIC11: basic = ::ROM::Name::OricBASIC11; break; case Analyser::Static::Oric::Target::ROM::Pravetz: basic = ::ROM::Name::OricPravetzBASIC; break; } request = request && ::ROM::Request(basic); switch(disk_interface) { default: break; case DiskInterface::BD500: request = request && ::ROM::Request(::ROM::Name::OricByteDrive500); break; case DiskInterface::Jasmin: request = request && ::ROM::Request(::ROM::Name::OricJasmin); break; case DiskInterface::Microdisc: request = request && ::ROM::Request(::ROM::Name::OricMicrodisc); break; case DiskInterface::Pravetz: request = request && ::ROM::Request(::ROM::Name::Oric8DOSBoot) && ::ROM::Request(::ROM::Name::DiskIIStateMachine16Sector); break; } auto roms = rom_fetcher(request); if(!request.validate(roms)) { throw ROMMachine::Error::MissingROMs; } // The colour ROM is optional; an alternative composite encoding can be used if // it is absent. const auto colour_rom = roms.find(::ROM::Name::OricColourROM); if(colour_rom != roms.end()) { video_->set_colour_rom(colour_rom->second); } rom_ = std::move(roms.find(basic)->second); switch(disk_interface) { default: break; case DiskInterface::BD500: disk_rom_ = std::move(roms.find(::ROM::Name::OricByteDrive500)->second); break; case DiskInterface::Jasmin: disk_rom_ = std::move(roms.find(::ROM::Name::OricJasmin)->second); break; case DiskInterface::Microdisc: disk_rom_ = std::move(roms.find(::ROM::Name::OricMicrodisc)->second); break; case DiskInterface::Pravetz: { pravetz_rom_ = std::move(roms.find(::ROM::Name::Oric8DOSBoot)->second); pravetz_rom_.resize(512); diskii_->set_state_machine(roms.find(::ROM::Name::DiskIIStateMachine16Sector)->second); } break; } paged_rom_ = rom_.data(); switch(target.disk_interface) { default: break; case DiskInterface::BD500: bd500_.set_delegate(this); break; case DiskInterface::Jasmin: jasmin_.set_delegate(this); break; case DiskInterface::Microdisc: microdisc_.set_delegate(this); break; } if(!target.loading_command.empty()) { type_string(target.loading_command); } if(target.should_start_jasmin) { // If Jasmin autostart is requested then plan to do so in 3 seconds; empirically long enough // for the Oric to boot normally, before the Jasmin intercedes. jasmin_reset_counter_ = 3000000; } switch(target.rom) { case Analyser::Static::Oric::Target::ROM::BASIC10: tape_get_byte_address_ = 0xe630; tape_speed_address_ = 0x67; break; case Analyser::Static::Oric::Target::ROM::BASIC11: case Analyser::Static::Oric::Target::ROM::Pravetz: tape_get_byte_address_ = 0xe6c9; tape_speed_address_ = 0x024d; break; } insert_media(target.media); } ~ConcreteMachine() { audio_queue_.flush(); } void set_key_state(uint16_t key, bool is_pressed) final { if(key == KeyNMI) { m6502_.set_nmi_line(is_pressed); } else { keyboard_.set_key_state(key, is_pressed); } } void clear_all_keys() final { keyboard_.clear_all_keys(); } void set_use_fast_tape_hack(bool activate) { use_fast_tape_hack_ = activate; } template bool insert_disks(const Analyser::Static::Media &media, DiskInterface &interface, int num_drives) { int drive_index = 0; for(auto &disk : media.disks) { interface.set_disk(disk, drive_index); ++drive_index; if(drive_index == num_drives) break; } return true; } bool insert_media(const Analyser::Static::Media &media) final { bool inserted = false; if(!media.tapes.empty()) { tape_player_.set_tape(media.tapes.front()); inserted = true; } if(!media.disks.empty()) { switch(disk_interface) { case DiskInterface::BD500: inserted |= insert_disks(media, bd500_, 4); break; case DiskInterface::Jasmin: inserted |= insert_disks(media, jasmin_, 4); break; case DiskInterface::Microdisc: inserted |= insert_disks(media, microdisc_, 4); break; case DiskInterface::Pravetz: inserted |= insert_disks(media, *diskii_.last_valid(), 2); break; default: break; } } return inserted; } // to satisfy CPU::MOS6502::BusHandler forceinline Cycles perform_bus_operation(CPU::MOS6502::BusOperation operation, uint16_t address, uint8_t *value) { if(address > ram_top_) { if(!isWriteOperation(operation)) *value = paged_rom_[address - ram_top_ - 1]; // 024D = 0 => fast; otherwise slow // E6C9 = read byte: return byte in A if( address == tape_get_byte_address_ && paged_rom_ == rom_.data() && use_fast_tape_hack_ && operation == CPU::MOS6502::BusOperation::ReadOpcode && tape_player_.has_tape() && !tape_player_.get_tape()->is_at_end()) { uint8_t next_byte = tape_player_.get_next_byte(!ram_[tape_speed_address_]); m6502_.set_value_of(CPU::MOS6502Esque::A, next_byte); m6502_.set_value_of(CPU::MOS6502Esque::Flags, next_byte ? 0 : CPU::MOS6502::Flag::Zero); *value = 0x60; // i.e. RTS } } else { if((address & 0xff00) == 0x0300) { if(address < 0x0310 || (disk_interface == DiskInterface::None)) { if(!isWriteOperation(operation)) *value = via_.read(address); else via_.write(address, *value); } else { switch(disk_interface) { default: break; case DiskInterface::BD500: if(!isWriteOperation(operation)) *value = bd500_.read(address); else bd500_.write(address, *value); break; case DiskInterface::Jasmin: if(address >= 0x3f4) { if(!isWriteOperation(operation)) *value = jasmin_.read(address); else jasmin_.write(address, *value); } break; case DiskInterface::Microdisc: switch(address) { case 0x0310: case 0x0311: case 0x0312: case 0x0313: if(!isWriteOperation(operation)) *value = microdisc_.read(address); else microdisc_.write(address, *value); break; case 0x314: case 0x315: case 0x316: case 0x317: if(!isWriteOperation(operation)) *value = microdisc_.get_interrupt_request_register(); else microdisc_.set_control_register(*value); break; case 0x318: case 0x319: case 0x31a: case 0x31b: if(!isWriteOperation(operation)) *value = microdisc_.get_data_request_register(); break; } break; case DiskInterface::Pravetz: if(address >= 0x0320) { if(!isWriteOperation(operation)) *value = pravetz_rom_[pravetz_rom_base_pointer_ + (address & 0xff)]; else { switch(address) { case 0x380: case 0x381: case 0x382: case 0x383: ram_top_ = (address&1) ? basic_invisible_ram_top_ : basic_visible_ram_top_; pravetz_rom_base_pointer_ = (address&2) ? 0x100 : 0x000; break; } } } else { const int disk_value = diskii_->read_address(address); if(!isWriteOperation(operation) && disk_value != Apple::DiskII::DidNotLoad) *value = uint8_t(disk_value); } break; } } } else { if(!isWriteOperation(operation)) *value = ram_[address]; else { if(address >= 0x9800 && address <= 0xc000) video_.flush(); ram_[address] = *value; } } } // $02df is where the Oric ROMs; all of them, including BASIC 1.0, 1.1 and the Pravetz; have the // IRQ routine store an incoming keystroke in order for reading to occur later. By capturing the // read rather than the decode and write: (i) nothing is lost while BASIC is parsing; and // (ii) keyboard input is much more rapid. if(string_serialiser_ && address == 0x02df && operation == CPU::MOS6502::BusOperation::Read) { *value = string_serialiser_->head() | 0x80; if(!string_serialiser_->advance()) string_serialiser_.reset(); } via_.run_for(Cycles(1)); tape_player_.run_for(Cycles(1)); switch(disk_interface) { default: break; case DiskInterface::BD500: bd500_.run_for(Cycles(9)); // i.e. effective clock rate of 9Mhz. break; case DiskInterface::Jasmin: jasmin_.run_for(Cycles(8)); // i.e. effective clock rate of 8Mhz. // Jasmin autostart hack: wait for a period, then trigger a reset, having forced // the Jasmin to page its ROM in first. I assume the latter being what the Jasmin's // hardware boot button did. if(jasmin_reset_counter_) { --jasmin_reset_counter_; if(!jasmin_reset_counter_) { perform_special_key(KeyJasminReset); } } break; case DiskInterface::Microdisc: microdisc_.run_for(Cycles(8)); // i.e. effective clock rate of 8Mhz. break; case DiskInterface::Pravetz: if(diskii_.clocking_preference() == ClockingHint::Preference::RealTime) { diskii_->set_data_input(*value); } diskii_ += Cycles(2); // i.e. effective clock rate of 2Mhz. break; } if(video_ += Cycles(1)) { set_via_port_b_input(); } return Cycles(1); } void flush_output(int outputs) final { if(outputs & Output::Video) { video_.flush(); } if(outputs & Output::Audio) { via_.flush(); } diskii_.flush(); } // to satisfy CRTMachine::Machine void set_scan_target(Outputs::Display::ScanTarget *scan_target) final { video_.last_valid()->set_scan_target(scan_target); } Outputs::Display::ScanStatus get_scaled_scan_status() const final { return video_.last_valid()->get_scaled_scan_status(); } void set_display_type(Outputs::Display::DisplayType display_type) final { video_.last_valid()->set_display_type(display_type); } Outputs::Display::DisplayType get_display_type() const final { return video_.last_valid()->get_display_type(); } Outputs::Speaker::Speaker *get_speaker() final { return &speaker_; } void run_for(const Cycles cycles) final { m6502_.run_for(cycles); } // to satisfy MOS::MOS6522IRQDelegate::Delegate void mos6522_did_change_interrupt_status(void *) final { set_interrupt_line(); } // to satisfy Storage::Tape::BinaryTapePlayer::Delegate void tape_did_change_input(Storage::Tape::BinaryTapePlayer *) final { set_via_port_b_input(); } void set_via_port_b_input() { // set CB1 via_.set_control_line_input( MOS::MOS6522::Port::B, MOS::MOS6522::Line::One, tape_player_.get_motor_control() ? !tape_player_.get_input() : !video_->vsync() ); } // for Utility::TypeRecipient::Delegate void type_string(const std::string &string) final { string_serialiser_ = std::make_unique(string, true); } bool can_type(char c) const final { // Make an effort to type the entire printable ASCII range. return c >= 32 && c < 127; } // DiskController::Delegate void disk_controller_did_change_paged_item(DiskController *controller) final { switch(controller->get_paged_item()) { default: ram_top_ = basic_visible_ram_top_; paged_rom_ = rom_.data(); break; case DiskController::PagedItem::RAM: ram_top_ = basic_invisible_ram_top_; break; case DiskController::PagedItem::DiskROM: ram_top_ = uint16_t(0xffff - disk_rom_.size()); paged_rom_ = disk_rom_.data(); break; } } // WD::WD1770::Delegate void wd1770_did_change_output(WD::WD1770 *) final { set_interrupt_line(); } KeyboardMapper *get_keyboard_mapper() final { return &keyboard_mapper_; } // MARK: - Configuration options. std::unique_ptr get_options() const final { auto options = std::make_unique(Configurable::OptionsType::UserFriendly); options->output = get_video_signal_configurable(); options->quickload = use_fast_tape_hack_; return options; } void set_options(const std::unique_ptr &str) final { const auto options = dynamic_cast(str.get()); set_video_signal_configurable(options->output); set_use_fast_tape_hack(options->quickload); } void set_activity_observer(Activity::Observer *observer) final { switch(disk_interface) { default: break; case DiskInterface::BD500: bd500_.set_activity_observer(observer); break; case DiskInterface::Jasmin: jasmin_.set_activity_observer(observer); break; case DiskInterface::Microdisc: microdisc_.set_activity_observer(observer); break; case DiskInterface::Pravetz: diskii_->set_activity_observer(observer); break; } } private: const uint16_t basic_invisible_ram_top_ = 0xffff; const uint16_t basic_visible_ram_top_ = 0xbfff; CPU::MOS6502Esque::Processor m6502_; // RAM and ROM std::vector rom_, disk_rom_; std::array ram_{}; // ROM bookkeeping uint16_t tape_get_byte_address_ = 0, tape_speed_address_ = 0; int keyboard_read_count_ = 0; // Outputs JustInTimeActor video_; Concurrency::AsyncTaskQueue audio_queue_; GI::AY38910::AY38910 ay8910_; Speaker speaker_; // Inputs Oric::KeyboardMapper keyboard_mapper_; // The tape TapePlayer tape_player_; bool use_fast_tape_hack_ = false; VIAPortHandler via_port_handler_; MOS::MOS6522::MOS6522 via_; Keyboard keyboard_; // the Microdisc, if in use. class Microdisc microdisc_; // the Jasmin, if in use. Jasmin jasmin_; int jasmin_reset_counter_ = 0; // the BD-500, if in use. BD500 bd500_; // the Pravetz/Disk II, if in use. JustInTimeActor diskii_; std::vector pravetz_rom_; std::size_t pravetz_rom_base_pointer_ = 0; // Overlay RAM uint16_t ram_top_ = basic_visible_ram_top_; uint8_t *paged_rom_ = nullptr; // Helper to discern current IRQ state inline void set_interrupt_line() { bool irq_line = via_.get_interrupt_line(); // The Microdisc directly provides an interrupt line. if constexpr (disk_interface == DiskInterface::Microdisc) { irq_line |= microdisc_.get_interrupt_request_line(); } // The Jasmin reroutes its data request line to the processor's interrupt line. if constexpr (disk_interface == DiskInterface::Jasmin) { irq_line |= jasmin_.get_data_request_line(); } m6502_.set_irq_line(irq_line); } // Keys that aren't read by polling. void perform_special_key(Oric::Key key) final { switch(key) { default: break; case KeyJasminReset: jasmin_.write(0x3fa, 0); jasmin_.write(0x3fb, 1); m6502_.set_power_on(true); break; case KeyNMI: // As luck would have it, the 6502's NMI line is edge triggered. // So just forcing through an edge will work here. m6502_.set_nmi_line(true); m6502_.set_nmi_line(false); break; } } // MARK: - typing std::unique_ptr string_serialiser_; // MARK: - Joysticks const std::vector> &get_joysticks() override { return via_port_handler_.get_joysticks(); } }; } using namespace Oric; namespace { template std::unique_ptr machine(const Analyser::Static::Oric::Target &target, const ROMMachine::ROMFetcher &rom_fetcher) { switch(target.disk_interface) { default: return std::make_unique>(target, rom_fetcher); case DiskInterface::Microdisc: return std::make_unique>(target, rom_fetcher); case DiskInterface::Pravetz: return std::make_unique>(target, rom_fetcher); case DiskInterface::Jasmin: return std::make_unique>(target, rom_fetcher); case DiskInterface::BD500: return std::make_unique>(target, rom_fetcher); } } } std::unique_ptr Machine::Oric(const Analyser::Static::Target *target_hint, const ROMMachine::ROMFetcher &rom_fetcher) { auto *const oric_target = dynamic_cast(target_hint); switch(oric_target->processor) { case Processor::WDC65816: return machine(*oric_target, rom_fetcher); case Processor::MOS6502: return machine(*oric_target, rom_fetcher); } return nullptr; }