// // ZXSpectrum.cpp // Clock Signal // // Created by Thomas Harte on 17/03/2021. // Copyright © 2021 Thomas Harte. All rights reserved. // #include "ZXSpectrum.hpp" #include "Video.hpp" #define LOG_PREFIX "[Spectrum] " #include "../../MachineTypes.hpp" #include "../../../Processors/Z80/Z80.hpp" #include "../../../Components/AudioToggle/AudioToggle.hpp" #include "../../../Components/AY38910/AY38910.hpp" #include "../../../Outputs/Log.hpp" #include "../../../Outputs/Speaker/Implementation/CompoundSource.hpp" #include "../../../Outputs/Speaker/Implementation/LowpassSpeaker.hpp" #include "../../../Outputs/Speaker/Implementation/SampleSource.hpp" #include "../../../Storage/Tape/Tape.hpp" #include "../../../Storage/Tape/Parsers/Spectrum.hpp" #include "../../../Analyser/Static/ZXSpectrum/Target.hpp" #include "../../Utility/MemoryFuzzer.hpp" #include "../../../ClockReceiver/JustInTime.hpp" #include "../Keyboard/Keyboard.hpp" #include namespace Sinclair { namespace ZXSpectrum { using Model = Analyser::Static::ZXSpectrum::Target::Model; template class ConcreteMachine: public Configurable::Device, public Machine, public MachineTypes::AudioProducer, public MachineTypes::MappedKeyboardMachine, public MachineTypes::MediaTarget, public MachineTypes::ScanProducer, public MachineTypes::TimedMachine, public CPU::Z80::BusHandler { public: ConcreteMachine(const Analyser::Static::ZXSpectrum::Target &target, const ROMMachine::ROMFetcher &rom_fetcher) : z80_(*this), ay_(GI::AY38910::Personality::AY38910, audio_queue_), audio_toggle_(audio_queue_), mixer_(ay_, audio_toggle_), speaker_(mixer_), keyboard_(Sinclair::ZX::Keyboard::Machine::ZXSpectrum), keyboard_mapper_(Sinclair::ZX::Keyboard::Machine::ZXSpectrum), tape_player_(clock_rate() * 2) { set_clock_rate(clock_rate()); speaker_.set_input_rate(float(clock_rate()) / 2.0f); // With only the +2a and +3 currently supported, the +3 ROM is always // the one required. const auto roms = rom_fetcher({ {"ZXSpectrum", "the +2a/+3 ROM", "plus3.rom", 64 * 1024, 0x96e3c17a} }); if(!roms[0]) throw ROMMachine::Error::MissingROMs; memcpy(rom_.data(), roms[0]->data(), std::min(rom_.size(), roms[0]->size())); // Set up initial memory map. update_memory_map(); set_video_address(); Memory::Fuzz(ram_); // Insert media. insert_media(target.media); } ~ConcreteMachine() { audio_queue_.flush(); } static constexpr unsigned int clock_rate() { // constexpr unsigned int ClockRate = 3'500'000; constexpr unsigned int Plus3ClockRate = 3'546'875; // See notes below; this is a guess. // Notes on timing for the +2a and +3: // // Standard PAL produces 283.7516 colour cycles per line, each line being 64µs. // The oft-quoted 3.5469 Mhz would seem to imply 227.0016 clock cycles per line. // Since those Spectrums actually produce 228 cycles per line, but software like // Chromatrons seems to assume a fixed phase relationship, I guess that the real // clock speed is whatever gives: // // 228 / [cycles per line] * 283.7516 = [an integer]. // // i.e. 228 * 283.7516 = [an integer] * [cycles per line], such that cycles per line ~= 227 // ... which would imply that 'an integer' is probably 285, i.e. // // 228 / [cycles per line] * 283.7516 = 285 // => 227.00128 = [cycles per line] // => clock rate = 3.546895 Mhz? // // That is... unless I'm mistaken about the PAL colour subcarrier and it's actually 283.75, // which would give exactly 227 cycles/line and therefore 3.546875 Mhz. // // A real TV would be likely to accept either, I guess. But it does seem like // the Spectrum is a PAL machine with a fixed colour phase relationship. For // this emulator's world, that's a first! return Plus3ClockRate; } // MARK: - TimedMachine void run_for(const Cycles cycles) override { z80_.run_for(cycles); } void flush() { video_.flush(); update_audio(); audio_queue_.perform(); } // MARK: - ScanProducer void set_scan_target(Outputs::Display::ScanTarget *scan_target) override { video_->set_scan_target(scan_target); } Outputs::Display::ScanStatus get_scaled_scan_status() const override { return video_->get_scaled_scan_status(); } void set_display_type(Outputs::Display::DisplayType display_type) override { video_->set_display_type(display_type); } // MARK: - BusHandler forceinline HalfCycles perform_machine_cycle(const CPU::Z80::PartialMachineCycle &cycle) { using PartialMachineCycle = CPU::Z80::PartialMachineCycle; HalfCycles delay(0); const uint16_t address = cycle.address ? *cycle.address : 0x0000; switch(cycle.operation) { default: break; case PartialMachineCycle::ReadOpcodeStart: case PartialMachineCycle::ReadStart: case PartialMachineCycle::WriteStart: // Apply contention if necessary. // // Assumption here: the trigger for the ULA inserting a delay is the falling edge // of MREQ, which is always half a cycle into a read or write. // // TODO: somehow provide that information in the PartialMachineCycle? if(is_contended_[address >> 14]) { delay = video_.last_valid()->access_delay(video_.time_since_flush() + HalfCycles(1)); } break; case PartialMachineCycle::ReadOpcode: // Fast loading: ROM version. // // The below patches over the 'LD-BYTES' routine from the 48kb ROM. if(use_fast_tape_hack_ && address == 0x0556 && read_pointers_[0] == &rom_[0xc000]) { if(perform_rom_ld_bytes()) { *cycle.value = 0xc9; // i.e. RET. break; } } case PartialMachineCycle::Read: *cycle.value = read_pointers_[address >> 14][address]; break; case PartialMachineCycle::Write: // Flush video if this access modifies screen contents. if(is_video_[address >> 14] && (address & 0x3fff) < 6912) { video_.flush(); } write_pointers_[address >> 14][address] = *cycle.value; break; case PartialMachineCycle::Output: // Test for port FE. if(!(address&1)) { update_audio(); audio_toggle_.set_output(*cycle.value & 0x10); video_->set_border_colour(*cycle.value & 7); // b0–b2: border colour // b3: enable tape input (?) // b4: tape and speaker output } // Test for classic 128kb paging register. if((address & 0xc002) == 0x4000) { port7ffd_ = *cycle.value; update_memory_map(); // Set the proper video base pointer. set_video_address(); // Potentially lock paging, _after_ the current // port values have taken effect. disable_paging_ |= *cycle.value & 0x20; } // Test for +2a/+3 paging. if((address & 0xf002) == 0x1000) { port1ffd_ = *cycle.value; update_memory_map(); update_video_base(); } if((address & 0xc002) == 0xc000) { // Select AY register. update_audio(); GI::AY38910::Utility::select_register(ay_, *cycle.value); } if((address & 0xc002) == 0x8000) { // Write to AY register. update_audio(); GI::AY38910::Utility::write_data(ay_, *cycle.value); } if constexpr (model == Model::Plus3) { switch(address) { default: break; case 0x3ffd: // TODO: floppy data register. break; case 0x2ffd: // TODO: floppy status register. break; } } break; case PartialMachineCycle::Input: *cycle.value = 0xff; if(!(address&1)) { // Port FE: // // address b8+: mask of keyboard lines to select // result: b0–b4: mask of keys pressed // b6: tape input *cycle.value &= keyboard_.read(address); *cycle.value &= tape_player_.get_input() ? 0xbf : 0xff; // If this read is within 200 cycles of the previous, // count it as an adjacent hit; if 20 of those have // occurred then start the tape motor. if(use_automatic_tape_motor_control_) { if(cycles_since_tape_input_read_ < HalfCycles(400)) { ++recent_tape_hits_; if(recent_tape_hits_ == 20) { tape_player_.set_motor_control(true); } } else { recent_tape_hits_ = 0; } cycles_since_tape_input_read_ = HalfCycles(0); } } if((address & 0xc002) == 0xc000) { // Read from AY register. update_audio(); *cycle.value &= GI::AY38910::Utility::read_data(ay_); } break; } advance(cycle.length + delay); return delay; } private: void advance(HalfCycles duration) { time_since_audio_update_ += duration; video_ += duration; if(video_.did_flush()) { z80_.set_interrupt_line(video_.last_valid()->get_interrupt_line()); } // TODO: sleeping support here. tape_player_.run_for(duration.as_integral()); // Update automatic tape motor control, if enabled; if it's been // 3 seconds since software last possibly polled the tape, stop it. if(use_automatic_tape_motor_control_ && cycles_since_tape_input_read_ < HalfCycles(clock_rate() * 6)) { cycles_since_tape_input_read_ += duration; if(cycles_since_tape_input_read_ >= HalfCycles(clock_rate() * 6)) { tape_player_.set_motor_control(false); recent_tape_hits_ = 0; } } } public: // MARK: - Typer // HalfCycles get_typer_delay(const std::string &) const final { // return z80_.get_is_resetting() ? Cycles(7'000'000) : Cycles(0); // } // // HalfCycles get_typer_frequency() const final { // return Cycles(146'250); // } KeyboardMapper *get_keyboard_mapper() override { return &keyboard_mapper_; } // MARK: - Keyboard void set_key_state(uint16_t key, bool is_pressed) override { keyboard_.set_key_state(key, is_pressed); } void clear_all_keys() override { keyboard_.clear_all_keys(); } // MARK: - MediaTarget. bool insert_media(const Analyser::Static::Media &media) override { // If there are any tapes supplied, use the first of them. if(!media.tapes.empty()) { tape_player_.set_tape(media.tapes.front()); } return !media.tapes.empty(); } // MARK: - Tape control void set_use_automatic_tape_motor_control(bool enabled) { use_automatic_tape_motor_control_ = enabled; if(!enabled) { tape_player_.set_motor_control(false); } } void set_tape_is_playing(bool is_playing) final { tape_player_.set_motor_control(is_playing); } bool get_tape_is_playing() final { return tape_player_.get_motor_control(); } // MARK: - Configuration options. std::unique_ptr get_options() override { auto options = std::make_unique(Configurable::OptionsType::UserFriendly); // OptionsType is arbitrary, but not optional. options->automatic_tape_motor_control = use_automatic_tape_motor_control_; options->quickload = allow_fast_tape_hack_; return options; } void set_options(const std::unique_ptr &str) override { const auto options = dynamic_cast(str.get()); set_video_signal_configurable(options->output); set_use_automatic_tape_motor_control(options->automatic_tape_motor_control); allow_fast_tape_hack_ = options->quickload; set_use_fast_tape(); } // MARK: - AudioProducer. Outputs::Speaker::Speaker *get_speaker() override { return &speaker_; } private: CPU::Z80::Processor z80_; // MARK: - Memory. std::array rom_; std::array ram_; std::array scratch_; const uint8_t *read_pointers_[4]; uint8_t *write_pointers_[4]; uint8_t pages_[4]; bool is_contended_[4]; bool is_video_[4]; uint8_t port1ffd_ = 0; uint8_t port7ffd_ = 0; bool disable_paging_ = false; void update_memory_map() { // If paging is permanently disabled, don't react. if(disable_paging_) { return; } if(port1ffd_ & 0x01) { // "Special paging mode", i.e. one of four fixed // RAM configurations, port 7ffd doesn't matter. switch(port1ffd_ & 0x06) { default: case 0x00: set_memory(0, 0); set_memory(1, 1); set_memory(2, 2); set_memory(3, 3); break; case 0x02: set_memory(0, 4); set_memory(1, 5); set_memory(2, 6); set_memory(3, 7); break; case 0x04: set_memory(0, 4); set_memory(1, 5); set_memory(2, 6); set_memory(3, 3); break; case 0x06: set_memory(0, 4); set_memory(1, 7); set_memory(2, 6); set_memory(3, 3); break; } } else { // Apply standard 128kb-esque mapping (albeit with extra ROM to pick from). set_memory(0, 0x80 | ((port1ffd_ >> 1) & 2) | ((port7ffd_ >> 4) & 1)); set_memory(1, 5); set_memory(2, 2); set_memory(3, port7ffd_ & 7); } } void set_memory(int bank, uint8_t source) { is_contended_[bank] = (source >= 4 && source < 8); pages_[bank] = source; uint8_t *read = (source < 0x80) ? &ram_[source * 16384] : &rom_[(source & 0x7f) * 16384]; const auto offset = bank*16384; read_pointers_[bank] = read - offset; write_pointers_[bank] = ((source < 0x80) ? read : scratch_.data()) - offset; } void set_video_address() { video_->set_video_source(&ram_[((port7ffd_ & 0x08) ? 7 : 5) * 16384]); update_video_base(); } void update_video_base() { const uint8_t video_page = (port7ffd_ & 0x08) ? 7 : 5; is_video_[0] = pages_[0] == video_page; is_video_[1] = pages_[1] == video_page; is_video_[2] = pages_[2] == video_page; is_video_[3] = pages_[3] == video_page; } // MARK: - Audio. Concurrency::DeferringAsyncTaskQueue audio_queue_; GI::AY38910::AY38910 ay_; Audio::Toggle audio_toggle_; Outputs::Speaker::CompoundSource, Audio::Toggle> mixer_; Outputs::Speaker::LowpassSpeaker, Audio::Toggle>> speaker_; HalfCycles time_since_audio_update_; void update_audio() { speaker_.run_for(audio_queue_, time_since_audio_update_.divide_cycles(Cycles(2))); } // MARK: - Video. static constexpr VideoTiming video_timing = VideoTiming::Plus3; JustInTimeActor> video_; // MARK: - Keyboard. Sinclair::ZX::Keyboard::Keyboard keyboard_; Sinclair::ZX::Keyboard::KeyboardMapper keyboard_mapper_; // MARK: - Tape and disc. Storage::Tape::BinaryTapePlayer tape_player_; bool use_automatic_tape_motor_control_ = true; HalfCycles cycles_since_tape_input_read_; int recent_tape_hits_ = 0; bool allow_fast_tape_hack_ = false; bool use_fast_tape_hack_ = false; void set_use_fast_tape() { use_fast_tape_hack_ = allow_fast_tape_hack_ && tape_player_.has_tape(); } // Reimplements the 'LD-BYTES' routine, as documented at // https://skoolkid.github.io/rom/asm/0556.html i.e. // // In: // A: 0x00 or 0xff for block type; // F: carry set if loading, clear if verifying; // DE: block length; // IX: start address. // // Out: // F: carry set for success, clear for error. bool perform_rom_ld_bytes() { using Parser = Storage::Tape::ZXSpectrum::Parser; Parser parser(Parser::MachineType::ZXSpectrum); using Register = CPU::Z80::Register; uint8_t flags = uint8_t(z80_.get_value_of_register(Register::Flags)); if(!(flags & 1)) return false; const uint8_t block_type = uint8_t(z80_.get_value_of_register(Register::A)); const auto block = parser.find_block(tape_player_.get_tape()); if(!block || block_type != (*block).type) return false; uint16_t length = z80_.get_value_of_register(Register::DE); uint16_t target = z80_.get_value_of_register(Register::IX); while(length--) { auto next = parser.get_byte(tape_player_.get_tape()); if(!next) { flags &= ~1; break; } write_pointers_[target >> 14][target] = *next; ++target; } z80_.set_value_of_register(Register::Flags, flags); return true; } }; } } using namespace Sinclair::ZXSpectrum; Machine *Machine::ZXSpectrum(const Analyser::Static::Target *target, const ROMMachine::ROMFetcher &rom_fetcher) { const auto zx_target = dynamic_cast(target); switch(zx_target->model) { case Model::Plus2a: return new ConcreteMachine(*zx_target, rom_fetcher); case Model::Plus3: return new ConcreteMachine(*zx_target, rom_fetcher); } return nullptr; } Machine::~Machine() {}