// // Enterprise.cpp // Clock Signal // // Created by Thomas Harte on 10/06/2021. // Copyright © 2021 Thomas Harte. All rights reserved. // #include "Enterprise.hpp" #include "Dave.hpp" #include "EXDos.hpp" #include "Keyboard.hpp" #include "Nick.hpp" #include "../MachineTypes.hpp" #include "../Utility/Typer.hpp" #include "../../Analyser/Static/Enterprise/Target.hpp" #include "../../ClockReceiver/JustInTime.hpp" #include "../../Outputs/Log.hpp" #include "../../Outputs/Speaker/Implementation/LowpassSpeaker.hpp" #include "../../Processors/Z80/Z80.hpp" namespace { Log::Logger logger; } namespace Enterprise { /* Notes to self on timing: Nick divides each line into 57 windows; each window lasts 16 cycles and dedicates the first 10 of those to VRAM accesses, leaving the final six for a Z80 video RAM access if one has been requested. The Z80 has a separate, asynchronous 4Mhz clock. That's that. The documentation is also very forward in emphasising that Nick generates phaselocked (i.e. in-phase) PAL video. So: 57*16 = 912 cycles/line. A standard PAL line lasts 64µs and during that time outputs 283.7516 colour cycles. I shall _guess_ that the Enterprise stretches each line to 284 colour cycles rather than reducing it to 283. Therefore 912 cycles occurs in 284/283.7516 * 64 µs. So one line = 181760000 / 2837516 µs = 45440000 / 709379 µs => one cycle = 45440000 / 709379*912 = 45440000 / 646953648 = 2840000 / 40434603 µs => clock rate of 40434603 / 2840000 Mhz And, therefore, the ratio to a 4Mhz Z80 clock is: 40434603 / (2840000 * 4) = 40434603 / 11360000 i.e. roughly 3.55 Nick cycles per Z80 cycle. If that's true then the 6-cycle window is around 1.69 Z80 cycles long. Given that the Z80 clock in an Enterprise can be stopped in half-cycle increments only, the Z80 can only be guaranteed to have around a 1.19 cycle minimum for its actual access. I'm therefore further postulating that the clock stoppage takes place so as to align the final cycle of a relevant access over the available window. */ template class ConcreteMachine: public Activity::Source, public Configurable::Device, public CPU::Z80::BusHandler, public Machine, public MachineTypes::AudioProducer, public MachineTypes::MappedKeyboardMachine, public MachineTypes::MediaTarget, public MachineTypes::ScanProducer, public MachineTypes::TimedMachine, public Utility::TypeRecipient { private: constexpr uint8_t min_ram_slot(const Analyser::Static::Enterprise::Target &target) { size_t ram_size = 128*1024; switch(target.model) { case Analyser::Static::Enterprise::Target::Model::Enterprise64: ram_size = 64*1024; break; case Analyser::Static::Enterprise::Target::Model::Enterprise128: ram_size = 128*1024; break; case Analyser::Static::Enterprise::Target::Model::Enterprise256: ram_size = 256*1024; break; } return uint8_t(0x100 - ram_size / 0x4000); } static constexpr double clock_rate = is_6mhz ? 6'000'000.0 : 4'000'000.0; using NickType = std::conditional_t, JustInTimeActor>; public: ConcreteMachine(const Analyser::Static::Enterprise::Target &target, const ROMMachine::ROMFetcher &rom_fetcher) : min_ram_slot_(min_ram_slot(target)), z80_(*this), nick_(ram_.end() - 65536), dave_audio_(audio_queue_), speaker_(dave_audio_) { // Request a clock of 4Mhz; this'll be mapped upwards for Nick and downwards for Dave elsewhere. set_clock_rate(clock_rate); speaker_.set_input_rate(float(clock_rate) / float(dave_divider)); ROM::Request request; using Target = Analyser::Static::Enterprise::Target; // Pick one or more EXOS ROMs. switch(target.exos_version) { case Target::EXOSVersion::v10: request = request && ROM::Request(ROM::Name::EnterpriseEXOS10); break; case Target::EXOSVersion::v20: request = request && ROM::Request(ROM::Name::EnterpriseEXOS20); break; case Target::EXOSVersion::v21: request = request && ROM::Request(ROM::Name::EnterpriseEXOS21); break; case Target::EXOSVersion::v23: request = request && ROM::Request(ROM::Name::EnterpriseEXOS23); break; case Target::EXOSVersion::Any: request = request && ( ROM::Request(ROM::Name::EnterpriseEXOS10) || ROM::Request(ROM::Name::EnterpriseEXOS20) || ROM::Request(ROM::Name::EnterpriseEXOS21) || ROM::Request(ROM::Name::EnterpriseEXOS23) ); break; default: break; } // Similarly pick one or more BASIC ROMs. switch(target.basic_version) { case Target::BASICVersion::v10: request = request && ( ROM::Request(ROM::Name::EnterpriseBASIC10) || (ROM::Request(ROM::Name::EnterpriseBASIC10Part1) && ROM::Request(ROM::Name::EnterpriseBASIC10Part2)) ); break; case Target::BASICVersion::v11: request = request && ( ROM::Request(ROM::Name::EnterpriseBASIC11) || ROM::Request(ROM::Name::EnterpriseBASIC11Suffixed) ); break; case Target::BASICVersion::v21: request = request && ROM::Request(ROM::Name::EnterpriseBASIC21); break; case Target::BASICVersion::Any: request = request && ( ROM::Request(ROM::Name::EnterpriseBASIC10) || (ROM::Request(ROM::Name::EnterpriseBASIC10Part1) && ROM::Request(ROM::Name::EnterpriseBASIC10Part2)) || ROM::Request(ROM::Name::EnterpriseBASIC11) || ROM::Request(ROM::Name::EnterpriseBASIC21) ); break; default: break; } // Possibly add in a DOS. switch(target.dos) { case Target::DOS::EXDOS: request = request && ROM::Request(ROM::Name::EnterpriseEXDOS); break; default: break; } // Get and validate ROMs. auto roms = rom_fetcher(request); if(!request.validate(roms)) { throw ROMMachine::Error::MissingROMs; } // Extract the appropriate EXOS ROM. exos_.fill(0xff); for(const auto rom_name: { ROM::Name::EnterpriseEXOS10, ROM::Name::EnterpriseEXOS20, ROM::Name::EnterpriseEXOS21, ROM::Name::EnterpriseEXOS23 }) { const auto exos = roms.find(rom_name); if(exos != roms.end()) { memcpy(exos_.data(), exos->second.data(), std::min(exos_.size(), exos->second.size())); break; } } // Extract the appropriate BASIC ROM[s] (if any). basic_.fill(0xff); bool has_basic = false; for(const auto rom_name: { ROM::Name::EnterpriseBASIC10, ROM::Name::EnterpriseBASIC11, ROM::Name::EnterpriseBASIC11Suffixed, ROM::Name::EnterpriseBASIC21 }) { const auto basic = roms.find(rom_name); if(basic != roms.end()) { memcpy(basic_.data(), basic->second.data(), std::min(basic_.size(), basic->second.size())); has_basic = true; break; } } if(!has_basic) { const auto basic1 = roms.find(ROM::Name::EnterpriseBASIC10Part1); const auto basic2 = roms.find(ROM::Name::EnterpriseBASIC10Part2); if(basic1 != roms.end() && basic2 != roms.end()) { memcpy(&basic_[0x0000], basic1->second.data(), std::min(size_t(8192), basic1->second.size())); memcpy(&basic_[0x2000], basic2->second.data(), std::min(size_t(8192), basic2->second.size())); } } // Extract the appropriate DOS ROMs. epdos_rom_.fill(0xff); const auto epdos = roms.find(ROM::Name::EnterpriseEPDOS); if(epdos != roms.end()) { memcpy(epdos_rom_.data(), epdos->second.data(), std::min(epdos_rom_.size(), epdos->second.size())); } exdos_rom_.fill(0xff); const auto exdos = roms.find(ROM::Name::EnterpriseEXDOS); if(exdos != roms.end()) { memcpy(exdos_rom_.data(), exdos->second.data(), std::min(exdos_rom_.size(), exdos->second.size())); } // Seed key state. clear_all_keys(); // Take a reasonable guess at the initial memory configuration: // put EXOS into the first bank since this is a Z80 and therefore // starts from address 0; the third instruction in EXOS is a jump // to $c02e so it's reasonable to assume EXOS is in the highest bank // too, and it appears to act correctly if it's the first 16kb that's // in the highest bank. From there I guess: all banks are initialised // to 0. page<0>(0x00); page<1>(0x00); page<2>(0x00); page<3>(0x00); // Pass on any media. insert_media(target.media); if(!target.loading_command.empty()) { type_string(target.loading_command); } // Ensure the splash screen is automatically skipped if any media has been provided. if(!target.media.empty()) { should_skip_splash_screen_ = !target.media.empty(); typer_delay_ = 2; } } ~ConcreteMachine() { audio_queue_.flush(); } // MARK: - Z80::BusHandler. forceinline void advance_nick(HalfCycles duration) { if(nick_ += duration) { const auto nick = nick_.last_valid(); const bool nick_interrupt_line = nick->get_interrupt_line(); if(nick_interrupt_line && !previous_nick_interrupt_line_) { set_interrupts(uint8_t(Dave::Interrupt::Nick), nick_.last_sequence_point_overrun()); } previous_nick_interrupt_line_ = nick_interrupt_line; } } forceinline HalfCycles perform_machine_cycle(const CPU::Z80::PartialMachineCycle &cycle) { using PartialMachineCycle = CPU::Z80::PartialMachineCycle; const uint16_t address = cycle.address ? *cycle.address : 0x0000; // Calculate an access penalty, if applicable. // // Rule applied here, which is slightly inferred: // // Non-video reads and writes are delayed by exactly a cycle or not delayed at all, // depending on the programmer's configuration of Dave. // // Video reads and writes, and Nick port accesses, are delayed so that the last // clock cycle of the machine cycle falls wholly inside the designated Z80 access // window, per Nick. // // The switch statement below just attempts to implement that logic. // HalfCycles penalty; switch(cycle.operation) { default: break; // For non-video pauses, insert during the initial part of the bus cycle. case PartialMachineCycle::ReadStart: case PartialMachineCycle::WriteStart: if(!is_video_[address >> 14] && wait_mode_ == WaitMode::OnAllAccesses) { penalty = dave_delay_; } break; case PartialMachineCycle::ReadOpcodeStart: { if(is_video_[address >> 14]) { // Query Nick for the amount of delay that would occur with one cycle left // in this read opcode. const auto delay_time = nick_.time_since_flush(HalfCycles(2)); const auto delay = nick_.last_valid()->get_time_until_z80_slot(delay_time); penalty = nick_.back_map(delay, delay_time); } else if(wait_mode_ != WaitMode::None) { penalty = dave_delay_; } } break; // Video pauses: insert right at the end of the bus cycle. case PartialMachineCycle::Write: // Ensure all video that should have been collected prior to // this write has been. if(is_video_[address >> 14]) { nick_.flush(); } [[fallthrough]]; case PartialMachineCycle::Read: if(is_video_[address >> 14]) { // Get delay, in Nick cycles, for a Z80 access that occurs in 0.5 // cycles from now (i.e. with one cycle left to run). const auto delay_time = nick_.time_since_flush(HalfCycles(1)); const auto delay = nick_.last_valid()->get_time_until_z80_slot(delay_time); penalty = nick_.back_map(delay, delay_time); } break; case PartialMachineCycle::Input: case PartialMachineCycle::Output: { if((address & 0xf0) == 0x80) { // Get delay, in Nick cycles, for a Z80 access that occurs in 0.5 // cycles from now (i.e. with one cycle left to run). const auto delay_time = nick_.time_since_flush(HalfCycles(1)); const auto delay = nick_.last_valid()->get_time_until_z80_slot(delay_time); penalty = nick_.back_map(delay, delay_time); } } } const HalfCycles full_length = cycle.length + penalty; time_since_audio_update_ += full_length; advance_nick(full_length); if(dave_timer_ += full_length) { set_interrupts(dave_timer_.last_valid()->get_new_interrupts(), dave_timer_.last_sequence_point_overrun()); } // The WD/etc runs at a nominal 8Mhz. if constexpr (has_disk_controller) { exdos_.run_for(Cycles(full_length.as_integral())); } switch(cycle.operation) { default: break; case PartialMachineCycle::Interrupt: *cycle.value = 0xff; break; case PartialMachineCycle::Input: switch(address & 0xff) { default: logger.error().append("Unhandled input from %02x", address & 0xff); *cycle.value = 0xff; break; case 0x10: case 0x11: case 0x12: case 0x13: case 0x14: case 0x15: case 0x16: case 0x17: if constexpr (has_disk_controller) { *cycle.value = exdos_.read(address); } else { *cycle.value = 0xff; } break; case 0x18: case 0x19: case 0x1a: case 0x1b: case 0x1c: case 0x1d: case 0x1e: case 0x1f: if constexpr (has_disk_controller) { *cycle.value = exdos_.get_control_register(); } else { *cycle.value = 0xff; } break; case 0x80: case 0x81: case 0x82: case 0x83: case 0x84: case 0x85: case 0x86: case 0x87: case 0x88: case 0x89: case 0x8a: case 0x8b: case 0x8c: case 0x8d: case 0x8e: case 0x8f: *cycle.value = nick_->read(); break; case 0xb0: *cycle.value = pages_[0]; break; case 0xb1: *cycle.value = pages_[1]; break; case 0xb2: *cycle.value = pages_[2]; break; case 0xb3: *cycle.value = pages_[3]; break; case 0xb4: *cycle.value = (nick_->get_interrupt_line() ? 0x10 : 0x00) | dave_timer_->get_divider_state() | interrupt_state_; break; case 0xb5: if(active_key_line_ < key_lines_.size()) { *cycle.value = key_lines_[active_key_line_]; } else { *cycle.value = 0xff; } break; case 0xb6: { // TODO: selected keyboard row, 0 to 9, should return one bit of joystick // input. That being the case: // // b0: joystick input // b1, b2: unused (in theory read from control port, but not used by any hardware) // b3: 0 = printer ready; 1 = not ready // b4: serial, data in // b5: serial, status in // b6: tape input volume level, 0 = high, 1 = low // b7: tape data input *cycle.value = 0xff; } break; } break; case PartialMachineCycle::Output: switch(address & 0xff) { default: logger.error().append("Unhandled output: %02x to %02x", *cycle.value, address & 0xff); break; case 0x10: case 0x11: case 0x12: case 0x13: case 0x14: case 0x15: case 0x16: case 0x17: if constexpr(has_disk_controller) { exdos_.write(address, *cycle.value); } break; case 0x18: case 0x19: case 0x1a: case 0x1b: case 0x1c: case 0x1d: case 0x1e: case 0x1f: if constexpr(has_disk_controller) { exdos_.set_control_register(*cycle.value); } break; case 0x80: case 0x81: case 0x82: case 0x83: case 0x84: case 0x85: case 0x86: case 0x87: case 0x88: case 0x89: case 0x8a: case 0x8b: case 0x8c: case 0x8d: case 0x8e: case 0x8f: nick_->write(address, *cycle.value); break; case 0xb0: page<0>(*cycle.value); break; case 0xb1: page<1>(*cycle.value); break; case 0xb2: page<2>(*cycle.value); break; case 0xb3: page<3>(*cycle.value); break; case 0xbf: switch((*cycle.value >> 2)&3) { default: wait_mode_ = WaitMode::None; break; case 0: wait_mode_ = WaitMode::OnAllAccesses; break; case 1: wait_mode_ = WaitMode::OnM1; break; } // Dave delays (i.e. those affecting memory areas not associated with Nick) // are one cycle in 8Mhz mode, two cycles in 12Mhz mode. dave_delay_ = HalfCycles(2 + ((*cycle.value)&2)); [[fallthrough]]; case 0xa0: case 0xa1: case 0xa2: case 0xa3: case 0xa4: case 0xa5: case 0xa6: case 0xa7: case 0xa8: case 0xa9: case 0xaa: case 0xab: case 0xac: case 0xad: case 0xae: case 0xaf: update_audio(); dave_audio_.write(address, *cycle.value); dave_timer_->write(address, *cycle.value); break; case 0xb4: interrupt_mask_ = *cycle.value & 0x55; interrupt_state_ &= ~*cycle.value; update_interrupts(); break; case 0xb5: // Logic here: the ROM scans the keyboard by checking ascending // lines. It also seems to provide a line of 0 when using port B5 // for non-keyboard uses. // // So: use the rollover from line 9 back to line 0 as a trigger to // spot that a scan of the keyboard just finished. Which makes it // time to enqueue the next keypress. // // Re: should_skip_splash_screen_ and typer_delay_, assume that a // single keypress is necessary to get past the Enterprise splash // screen, then a pause in keypressing while BASIC or whatever // starts up, then presses can resume. if(active_key_line_ == 9 && !(*cycle.value & 0xf) && (should_skip_splash_screen_ || typer_)) { if(should_skip_splash_screen_) { set_key_state(uint16_t(Key::Space), typer_delay_); if(typer_delay_) { --typer_delay_; } else { typer_delay_ = 60; should_skip_splash_screen_ = false; } } else { if(!typer_delay_) { if(!typer_->type_next_character()) { clear_all_keys(); typer_ = nullptr; } } else { --typer_delay_; } } } active_key_line_ = *cycle.value & 0xf; // TODO: // // b4: strobe output for printer // b5: tape sound control (?) // b6: tape motor control 1, 1 = on // b7: tape motor control 2, 1 = on break; case 0xb6: // Just 8 bits of printer data. logger.info().append("TODO: printer output: %02x", *cycle.value); break; case 0xb7: // b0 = serial data out // b1 = serial status out logger.info().append("TODO: serial output: %02x", *cycle.value); break; } break; case PartialMachineCycle::Read: case PartialMachineCycle::ReadOpcode: if(read_pointers_[address >> 14]) { *cycle.value = read_pointers_[address >> 14][address]; } else { *cycle.value = 0xff; } break; case PartialMachineCycle::Write: if(write_pointers_[address >> 14]) { write_pointers_[address >> 14][address] = *cycle.value; } break; } return penalty; } void flush_output(int outputs) final { if(outputs & Output::Video) { nick_.flush(); } if(outputs & Output::Audio) { update_audio(); audio_queue_.perform(); } } private: // MARK: - Memory layout std::array ram_{}; std::array exos_; std::array basic_; std::array exdos_rom_; std::array epdos_rom_; const uint8_t min_ram_slot_; const uint8_t *read_pointers_[4] = {nullptr, nullptr, nullptr, nullptr}; uint8_t *write_pointers_[4] = {nullptr, nullptr, nullptr, nullptr}; uint8_t pages_[4] = {0x80, 0x80, 0x80, 0x80}; template void page(uint8_t offset) { pages_[slot] = offset; #define Map(location, source) \ if(offset >= location && offset < location + source.size() / 0x4000) { \ page(&source[(offset - location) * 0x4000], nullptr); \ is_video_[slot] = false; \ return; \ } Map(0, exos_); Map(16, basic_); Map(32, exdos_rom_); Map(48, epdos_rom_); #undef Map // Of whatever size of RAM I've declared above, use only the final portion. // This correlated with Nick always having been handed the final 64kb and, // at least while the RAM is the first thing declared above, does a little // to benefit data locality. Albeit not in a useful sense. if(offset >= min_ram_slot_) { const auto ram_floor = 4194304 - ram_.size(); const size_t address = offset * 0x4000 - ram_floor; is_video_[slot] = offset >= 0xfc; // TODO: this hard-codes a 64kb video assumption. page(&ram_[address], &ram_[address]); return; } page(nullptr, nullptr); } template void page(const uint8_t *read, uint8_t *write) { read_pointers_[slot] = read ? read - (slot * 0x4000) : nullptr; write_pointers_[slot] = write ? write - (slot * 0x4000) : nullptr; } // MARK: - Memory Timing // The wait mode affects all memory accesses _outside of the video area_. enum class WaitMode { None, OnM1, OnAllAccesses } wait_mode_ = WaitMode::OnAllAccesses; bool is_video_[4]{}; // MARK: - ScanProducer void set_scan_target(Outputs::Display::ScanTarget *scan_target) override { nick_.last_valid()->set_scan_target(scan_target); } Outputs::Display::ScanStatus get_scaled_scan_status() const override { return nick_.last_valid()->get_scaled_scan_status(); } void set_display_type(Outputs::Display::DisplayType display_type) final { nick_.last_valid()->set_display_type(display_type); } Outputs::Display::DisplayType get_display_type() const final { return nick_.last_valid()->get_display_type(); } // MARK: - AudioProducer Outputs::Speaker::Speaker *get_speaker() final { return &speaker_; } // MARK: - TimedMachine void run_for(const Cycles cycles) override { z80_.run_for(cycles); } // MARK: - KeyboardMachine Enterprise::KeyboardMapper keyboard_mapper_; KeyboardMapper *get_keyboard_mapper() final { return &keyboard_mapper_; } uint8_t active_key_line_ = 0; std::array key_lines_; void set_key_state(uint16_t key, bool is_pressed) final { if(is_pressed) { key_lines_[key >> 8] &= ~uint8_t(key); } else { key_lines_[key >> 8] |= uint8_t(key); } } void clear_all_keys() final { key_lines_.fill(0xff); } // MARK: - Utility::TypeRecipient void type_string(const std::string &string) final { Utility::TypeRecipient::add_typer(string); if(z80_.get_is_resetting()) { should_skip_splash_screen_ = true; typer_delay_ = 1; } else { should_skip_splash_screen_ = false; typer_delay_ = 0; } } bool can_type(char c) const final { return Utility::TypeRecipient::can_type(c); } bool should_skip_splash_screen_ = false; int typer_delay_ = 30; // MARK: - MediaTarget bool insert_media(const Analyser::Static::Media &media) final { if constexpr (has_disk_controller) { if(!media.disks.empty()) { exdos_.set_disk(media.disks.front(), 0); } } return true; } // MARK: - Interrupts uint8_t interrupt_mask_ = 0x00, interrupt_state_ = 0x00; void set_interrupts(uint8_t mask, HalfCycles offset = HalfCycles(0)) { interrupt_state_ |= uint8_t(mask); update_interrupts(offset); } void update_interrupts(HalfCycles offset = HalfCycles(0)) { z80_.set_interrupt_line((interrupt_state_ >> 1) & interrupt_mask_, offset); } // MARK: - Chips. CPU::Z80::Processor z80_; NickType nick_; bool previous_nick_interrupt_line_ = false; // Cf. timing guesses above. Concurrency::AsyncTaskQueue audio_queue_; Dave::Audio dave_audio_; Outputs::Speaker::PullLowpass speaker_; HalfCycles time_since_audio_update_; HalfCycles dave_delay_ = HalfCycles(2); // The divider supplied to the JustInTimeActor and the manual divider used in // update_audio() should match. static constexpr int dave_divider = 8; JustInTimeActor dave_timer_; inline void update_audio() { speaker_.run_for(audio_queue_, time_since_audio_update_.divide_cycles(Cycles(dave_divider))); } // MARK: - EXDos card. EXDos exdos_; // MARK: - Activity Source void set_activity_observer([[maybe_unused]] Activity::Observer *observer) final { if constexpr (has_disk_controller) { exdos_.set_activity_observer(observer); } } // MARK: - Configuration options. std::unique_ptr get_options() const final { auto options = std::make_unique(Configurable::OptionsType::UserFriendly); options->output = get_video_signal_configurable(); return options; } void set_options(const std::unique_ptr &str) final { const auto options = dynamic_cast(str.get()); set_video_signal_configurable(options->output); } }; } using namespace Enterprise; std::unique_ptr Machine::Enterprise(const Analyser::Static::Target *target, const ROMMachine::ROMFetcher &rom_fetcher) { using Target = Analyser::Static::Enterprise::Target; const Target *const enterprise_target = dynamic_cast(target); #define BuildMachine(exdos, sixmhz) \ if((enterprise_target->dos == Target::DOS::None) != exdos && (enterprise_target->speed == Target::Speed::SixMHz) == sixmhz) { \ return std::make_unique>(*enterprise_target, rom_fetcher); \ } BuildMachine(false, false); BuildMachine(false, true); BuildMachine(true, false); BuildMachine(true, true); #undef BuildMachine return nullptr; }