// // main.cpp // Clock Signal // // Created by Thomas Harte on 04/11/2017. // Copyright 2017 Thomas Harte. All rights reserved. // #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../../Analyser/Static/StaticAnalyser.hpp" #include "../../Machines/Utility/MachineForTarget.hpp" #include "../../ClockReceiver/TimeTypes.hpp" #include "../../ClockReceiver/ScanSynchroniser.hpp" #include "../../Machines/MachineTypes.hpp" #include "../../Activity/Observer.hpp" #include "../../Outputs/OpenGL/Primitives/Rectangle.hpp" #include "../../Outputs/OpenGL/ScanTarget.hpp" #include "../../Outputs/OpenGL/Screenshot.hpp" #include "../../Reflection/Enum.hpp" #include "../../Reflection/Struct.hpp" namespace { struct MachineRunner { MachineRunner() { frame_lock_.clear(); } ~MachineRunner() { stop(); } void start() { last_time_ = Time::nanos_now(); timer_ = SDL_AddTimer(timer_period, &sdl_callback, reinterpret_cast(this)); } void stop() { if(timer_) { // SDL doesn't define whether SDL_RemoveTimer will block until any pending calls // have been completed, or will return instantly. So: do an ordered shutdown, // then remove the timer. state_ = State::Stopping; while(state_ == State::Stopping) { frame_lock_.clear(); } SDL_RemoveTimer(timer_); timer_ = 0; } } void signal_vsync() { const auto now = Time::nanos_now(); const auto previous_vsync_time = vsync_time_.load(); vsync_time_.store(now); // Update estimate of current frame time. frame_time_average_ -= frame_times_[frame_time_pointer_]; frame_times_[frame_time_pointer_] = now - previous_vsync_time; frame_time_average_ += frame_times_[frame_time_pointer_]; frame_time_pointer_ = (frame_time_pointer_ + 1) & (frame_times_.size() - 1); _frame_period.store((1e9 * 32.0) / double(frame_time_average_)); } void signal_did_draw() { frame_lock_.clear(); } void set_speed_multiplier(double multiplier) { scan_synchroniser_.set_base_speed_multiplier(multiplier); } std::mutex *machine_mutex; Machine::DynamicMachine *machine; private: SDL_TimerID timer_ = 0; Time::Nanos last_time_ = 0; std::atomic vsync_time_; std::atomic_flag frame_lock_; enum class State { Running, Stopping, Stopped }; std::atomic state_{State::Running}; Time::ScanSynchroniser scan_synchroniser_; // A slightly clumsy means of trying to derive frame rate from calls to // signal_vsync(); SDL_DisplayMode provides only an integral quantity // whereas, empirically, it's fairly common for monitors to run at the // NTSC-esque frame rates of 59.94Hz. std::array frame_times_; Time::Nanos frame_time_average_ = 0; size_t frame_time_pointer_ = 0; std::atomic _frame_period; static constexpr Uint32 timer_period = 4; static Uint32 sdl_callback(Uint32, void *param) { reinterpret_cast(param)->update(); return timer_period; } void update() { // If a shutdown is in progress, signal stoppage and do nothing. if(state_ != State::Running) { state_ = State::Stopped; return; } // Get time now and determine how long it has been since the last time this // function was called. If it's more than half a second then forego any activity // now, as there's obviously been some sort of substantial time glitch. const auto time_now = Time::nanos_now(); if(time_now - last_time_ > Time::Nanos(500'000'000)) { last_time_ = time_now - Time::Nanos(500'000'000); } const auto vsync_time = vsync_time_.load(); std::unique_lock lock_guard(*machine_mutex); const auto scan_producer = machine->scan_producer(); const auto timed_machine = machine->timed_machine(); bool split_and_sync = false; if(last_time_ < vsync_time && time_now >= vsync_time) { split_and_sync = scan_synchroniser_.can_synchronise(scan_producer->get_scan_status(), _frame_period); } if(split_and_sync) { timed_machine->run_for(double(vsync_time - last_time_) / 1e9); timed_machine->set_speed_multiplier( scan_synchroniser_.next_speed_multiplier(scan_producer->get_scan_status()) ); // This is a bit of an SDL ugliness; wait here until the next frame is drawn. // That is, unless and until I can think of a good way of running background // updates via a share group — possibly an extra intermediate buffer is needed? lock_guard.unlock(); while(frame_lock_.test_and_set()); lock_guard.lock(); timed_machine->run_for(double(time_now - vsync_time) / 1e9); } else { timed_machine->set_speed_multiplier(scan_synchroniser_.get_base_speed_multiplier()); timed_machine->run_for(double(time_now - last_time_) / 1e9); } last_time_ = time_now; } }; struct SpeakerDelegate: public Outputs::Speaker::Speaker::Delegate { // This is empirically the best that I can seem to do with SDL's timer precision. static constexpr size_t buffered_samples = 1024; bool is_stereo = false; void speaker_did_complete_samples(Outputs::Speaker::Speaker *, const std::vector &buffer) final { std::lock_guard lock_guard(audio_buffer_mutex_); const size_t buffer_size = buffered_samples * (is_stereo ? 2 : 1); if(audio_buffer_.size() > buffer_size) { audio_buffer_.erase(audio_buffer_.begin(), audio_buffer_.end() - buffer_size); } audio_buffer_.insert(audio_buffer_.end(), buffer.begin(), buffer.end()); } void audio_callback(Uint8 *stream, int len) { std::lock_guard lock_guard(audio_buffer_mutex_); // SDL buffer length is in bytes, so there's no need to adjust for stereo/mono in here. const std::size_t sample_length = size_t(len) / sizeof(int16_t); const std::size_t copy_length = std::min(sample_length, audio_buffer_.size()); int16_t *const target = static_cast(static_cast(stream)); std::memcpy(stream, audio_buffer_.data(), copy_length * sizeof(int16_t)); if(copy_length < sample_length) { std::memset(&target[copy_length], 0, (sample_length - copy_length) * sizeof(int16_t)); } audio_buffer_.erase(audio_buffer_.begin(), audio_buffer_.begin() + copy_length); } static void SDL_audio_callback(void *userdata, Uint8 *stream, int len) { reinterpret_cast(userdata)->audio_callback(stream, len); } SDL_AudioDeviceID audio_device; std::mutex audio_buffer_mutex_; std::vector audio_buffer_; }; class ActivityObserver: public Activity::Observer { public: ActivityObserver(Activity::Source *source, float aspect_ratio) { // Get the suorce to supply all LEDs and drives. source->set_activity_observer(this); // The objective is to display drives on one side of the screen, other LEDs on the other. Drives // may or may not have LEDs and this code intends to display only those which do; so a quick // comparative processing of the two lists is called for. // Strip the list of drives to only those which have LEDs. Thwy're the ones that'll be displayed. drives_.resize(std::remove_if(drives_.begin(), drives_.end(), [this](const std::string &string) { return std::find(leds_.begin(), leds_.end(), string) == leds_.end(); }) - drives_.begin()); // Remove from the list of LEDs any which are drives. Those will be represented separately. leds_.resize(std::remove_if(leds_.begin(), leds_.end(), [this](const std::string &string) { return std::find(drives_.begin(), drives_.end(), string) != drives_.end(); }) - leds_.begin()); set_aspect_ratio(aspect_ratio); } void set_aspect_ratio(float aspect_ratio) { std::lock_guard lock_guard(mutex); lights_.clear(); // Generate a bunch of LEDs for connected drives. constexpr float height = 0.05f; const float width = height / aspect_ratio; const float right_x = 1.0f - 2.0f * width; float y = 1.0f - 2.0f * height; for(const auto &drive: drives_) { lights_.emplace(std::make_pair(drive, std::make_unique(right_x, y, width, height))); y -= height * 2.0f; } /* This would generate LEDs for things other than drives; I'm declining for now due to the inexpressiveness of just painting a rectangle. const float left_x = -1.0f + 2.0f * width; y = 1.0f - 2.0f * height; for(const auto &led: leds_) { lights_.emplace(std::make_pair(led, std::make_unique(left_x, y, width, height))); y -= height * 2.0f; } */ } void draw() { std::lock_guard lock_guard(mutex); for(const auto &lit_led: lit_leds_) { if(blinking_leds_.find(lit_led) == blinking_leds_.end() && lights_.find(lit_led) != lights_.end()) lights_[lit_led]->draw(0.0, 0.8, 0.0); } blinking_leds_.clear(); } private: std::vector leds_; void register_led(const std::string &name) final { std::lock_guard lock_guard(mutex); leds_.push_back(name); } std::vector drives_; void register_drive(const std::string &name) final { std::lock_guard lock_guard(mutex); drives_.push_back(name); } void set_led_status(const std::string &name, bool lit) final { std::lock_guard lock_guard(mutex); if(lit) lit_leds_.insert(name); else lit_leds_.erase(name); } void announce_drive_event(const std::string &name, DriveEvent) final { std::lock_guard lock_guard(mutex); blinking_leds_.insert(name); } std::map> lights_; std::set lit_leds_; std::set blinking_leds_; std::mutex mutex; }; bool KeyboardKeyForSDLScancode(SDL_Scancode scancode, Inputs::Keyboard::Key &key) { #define BIND(x, y) case SDL_SCANCODE_##x: key = Inputs::Keyboard::Key::y; break; switch(scancode) { default: return false; BIND(F1, F1) BIND(F2, F2) BIND(F3, F3) BIND(F4, F4) BIND(F5, F5) BIND(F6, F6) BIND(F7, F7) BIND(F8, F8) BIND(F9, F9) BIND(F10, F10) BIND(F11, F11) BIND(F12, F12) BIND(1, k1) BIND(2, k2) BIND(3, k3) BIND(4, k4) BIND(5, k5) BIND(6, k6) BIND(7, k7) BIND(8, k8) BIND(9, k9) BIND(0, k0) BIND(Q, Q) BIND(W, W) BIND(E, E) BIND(R, R) BIND(T, T) BIND(Y, Y) BIND(U, U) BIND(I, I) BIND(O, O) BIND(P, P) BIND(A, A) BIND(S, S) BIND(D, D) BIND(F, F) BIND(G, G) BIND(H, H) BIND(J, J) BIND(K, K) BIND(L, L) BIND(Z, Z) BIND(X, X) BIND(C, C) BIND(V, V) BIND(B, B) BIND(N, N) BIND(M, M) BIND(KP_7, Keypad7) BIND(KP_8, Keypad8) BIND(KP_9, Keypad9) BIND(KP_4, Keypad4) BIND(KP_5, Keypad5) BIND(KP_6, Keypad6) BIND(KP_1, Keypad1) BIND(KP_2, Keypad2) BIND(KP_3, Keypad3) BIND(KP_0, Keypad0) BIND(ESCAPE, Escape) BIND(PRINTSCREEN, PrintScreen) BIND(SCROLLLOCK, ScrollLock) BIND(PAUSE, Pause) BIND(GRAVE, BackTick) BIND(MINUS, Hyphen) BIND(EQUALS, Equals) BIND(BACKSPACE, Backspace) BIND(TAB, Tab) BIND(LEFTBRACKET, OpenSquareBracket) BIND(RIGHTBRACKET, CloseSquareBracket) BIND(BACKSLASH, Backslash) BIND(CAPSLOCK, CapsLock) BIND(SEMICOLON, Semicolon) BIND(APOSTROPHE, Quote) BIND(RETURN, Enter) BIND(LSHIFT, LeftShift) BIND(COMMA, Comma) BIND(PERIOD, FullStop) BIND(SLASH, ForwardSlash) BIND(RSHIFT, RightShift) BIND(LCTRL, LeftControl) BIND(LALT, LeftOption) BIND(LGUI, LeftMeta) BIND(SPACE, Space) BIND(RCTRL, RightControl) BIND(RALT, RightOption) BIND(RGUI, RightMeta) BIND(LEFT, Left) BIND(RIGHT, Right) BIND(UP, Up) BIND(DOWN, Down) BIND(INSERT, Insert) BIND(HOME, Home) BIND(PAGEUP, PageUp) BIND(DELETE, Delete) BIND(END, End) BIND(PAGEDOWN, PageDown) BIND(NUMLOCKCLEAR, NumLock) BIND(KP_DIVIDE, KeypadSlash) BIND(KP_MULTIPLY, KeypadAsterisk) BIND(KP_PLUS, KeypadPlus) BIND(KP_MINUS, KeypadMinus) BIND(KP_ENTER, KeypadEnter) BIND(KP_DECIMAL, KeypadDecimalPoint) BIND(KP_EQUALS, KeypadEquals) BIND(HELP, Help) // SDL doesn't seem to have scancodes for hash or keypad delete? } #undef BIND return true; } struct ParsedArguments { std::vector file_names; std::map selections; // The empty string will be inserted for arguments without an = suffix. void apply(Reflection::Struct *reflectable) const { for(const auto &argument: selections) { // Replace any dashes with underscores in the argument name. std::string property; std::transform(argument.first.begin(), argument.first.end(), std::back_inserter(property), [](char c) { return c == '-' ? '_' : c; }); if(argument.second.empty()) { Reflection::set(*reflectable, property, true); } else { Reflection::fuzzy_set(*reflectable, property, argument.second); } } } }; /*! Parses an argc/argv pair to discern program arguments. */ ParsedArguments parse_arguments(int argc, char *argv[]) { ParsedArguments arguments; for(int index = 1; index < argc; ++index) { char *arg = argv[index]; // Accepted format is: // // --flag sets a Boolean option to true. // --flag=value sets the value for a list option. // name sets the file name to load. // Anything starting with a dash always makes a selection; otherwise it's a file name. if(arg[0] == '-') { while(*arg == '-') arg++; // Check for an equals sign, to discern a Boolean selection from a list selection. std::string argument = arg; std::size_t split_index = argument.find("="); if(split_index == std::string::npos) { arguments.selections[argument]; // To create an entry with the default empty string. } else { const std::string name = argument.substr(0, split_index); std::string value = argument.substr(split_index+1, std::string::npos); arguments.selections[name] = value; } } else { arguments.file_names.push_back(arg); } } return arguments; } std::string final_path_component(const std::string &path) { // An empty path has no final component. if(path.empty()) { return ""; } // Find the last slash... auto final_slash = path.find_last_of("/\\"); // If no slash was found at all, return the whole path. if(final_slash == std::string::npos) { return path; } // If a slash was found in the final position, remove it and recurse. if(final_slash == path.size() - 1) { return final_path_component(path.substr(0, path.size() - 1)); } // Otherwise return everything from just after the slash to the end of the path. return path.substr(final_slash+1, path.size() - final_slash - 1); } /*! Executes @c command and returns its STDOUT. */ std::string system_get(const char *command) { std::unique_ptr pipe(popen(command, "r"), pclose); if(!pipe) return ""; std::string result; while(!feof(pipe.get())) { std::array buffer; if(fgets(buffer.data(), buffer.size(), pipe.get()) != nullptr) result += buffer.data(); } return result; } /*! Maintains a communicative window title. */ class DynamicWindowTitler { public: DynamicWindowTitler(SDL_Window *window) : window_(window), file_name_(SDL_GetWindowTitle(window)) {} std::string window_title() { if(!mouse_is_captured_) return file_name_; return file_name_ + " (press control+escape to release mouse)"; } void set_mouse_is_captured(bool is_captured) { mouse_is_captured_ = is_captured; update_window_title(); } void set_file_name(const std::string &name) { file_name_ = name; update_window_title(); } private: void update_window_title() { SDL_SetWindowTitle(window_, window_title().c_str()); } bool mouse_is_captured_ = false; SDL_Window *window_ = nullptr; std::string file_name_; }; /*! Provides a wrapper for SDL_Joystick pointers that can keep track of historic hat values. */ class SDLJoystick { public: SDLJoystick(SDL_Joystick *joystick) : joystick_(joystick) { hat_values_.resize(SDL_JoystickNumHats(joystick)); } ~SDLJoystick() { SDL_JoystickClose(joystick_); } /// @returns The underlying SDL_Joystick. SDL_Joystick *get() { return joystick_; } /// @returns A reference to the storage for the previous state of hat @c c. Uint8 &last_hat_value(int c) { return hat_values_[c]; } /// @returns The logic OR of all stored hat states. Uint8 hat_values() { Uint8 value = 0; for(const auto hat_value: hat_values_) { value |= hat_value; } return value; } private: SDL_Joystick *joystick_; std::vector hat_values_; }; } int main(int argc, char *argv[]) { SDL_Window *window = nullptr; // Attempt to parse arguments. const ParsedArguments arguments = parse_arguments(argc, argv); // This may be printed either as const std::string usage_suffix = " [file or --new={machine}] [OPTIONS] [--rompath={path to ROMs}] [--speed={speed multiplier, e.g. 1.5}] [--logical-keyboard] [--volume={0.0 to 1.0}]"; // Print a help message if requested. if(arguments.selections.find("help") != arguments.selections.end() || arguments.selections.find("h") != arguments.selections.end()) { const auto all_machines = Machine::AllMachines(Machine::Type::DoesntRequireMedia, false); std::cout << "Usage: " << final_path_component(argv[0]) << usage_suffix << std::endl; std::cout << "Use alt+enter to toggle full screen display. Use control+shift+V to paste text." << std::endl; std::cout << "Required machine type **and all options** are determined from the file if specified; otherwise use:" << std::endl << std::endl; std::cout << "\t--new={"; bool is_first = true; for(const auto &name: all_machines) { if(!is_first) std::cout << "|"; std::cout << name; is_first = false; } std::cout << "}" << std::endl << std::endl; std::cout << "Media is required to start the: "; const auto other_machines = Machine::AllMachines(Machine::Type::RequiresMedia, true); is_first = true; for(const auto &name: other_machines) { if(!is_first) std::cout << ", "; std::cout << name; is_first = false; } std::cout << "." << std::endl << std::endl; std::cout << "Further machine options:" << std::endl << std::endl;; const auto targets = Machine::TargetsByMachineName(false); const auto runtime_options = Machine::AllOptionsByMachineName(); const auto machine_names = Machine::AllMachines(Machine::Type::Any, true); for(const auto &machine: machine_names) { const auto target = targets.find(machine); const auto options = runtime_options.find(machine); const auto target_reflectable = dynamic_cast(target != targets.end() ? target->second.get() : nullptr); const auto options_reflectable = dynamic_cast(options != runtime_options.end() ? options->second.get() : nullptr); // Don't print a section for this machine if it has no construction and no runtime options objects. if(!target_reflectable && !options_reflectable) continue; const auto target_keys = target_reflectable ? target_reflectable->all_keys() : std::vector(); const auto options_keys = options_reflectable ? options_reflectable->all_keys() : std::vector(); // Don't print a section for this machine if it doesn't actually have any options. if(target_keys.empty() && options_keys.empty()) { continue; } std::cout << machine << ":" << std::endl; // Join the two lists of properties and sort the result. std::vector all_options = options_keys; all_options.insert(all_options.end(), target_keys.begin(), target_keys.end()); std::sort(all_options.begin(), all_options.end()); for(const auto &option: all_options) { // Replace any underscores with hyphens, better to conform to command-line norms. std::string mapped_option; std::transform(option.begin(), option.end(), std::back_inserter(mapped_option), [](char c) { return c == '_' ? '-' : c; }); std::cout << '\t' << "--" << mapped_option; auto source = target_reflectable; auto type = target_reflectable ? target_reflectable->type_of(option) : nullptr; if(!type) { source = options_reflectable; type = options_reflectable->type_of(option); } // Is this a registered enum? If so, list options. if(!Reflection::Enum::name(*type).empty()) { std::cout << "={"; bool is_first = true; for(const auto &value: source->values_for(option)) { if(!is_first) std::cout << '|'; is_first = false; std::cout << value; } std::cout << "}"; } // The above effectively assumes that every field is either a // Boolean or an enum. This may need to be revisted. It also // assumes no name collisions, but that's kind of unavoidable. std::cout << std::endl; } std::cout << std::endl; } return EXIT_SUCCESS; } // Determine the machine for the supplied file, if any, or from --new. Analyser::Static::TargetList targets; const auto new_argument = arguments.selections.find("new"); std::string long_machine_name; if(new_argument != arguments.selections.end() && !new_argument->second.empty()) { // Perform for a case-insensitive search against short names. const auto short_names = Machine::AllMachines(Machine::Type::DoesntRequireMedia, false); auto short_name = short_names.begin(); while(short_name != short_names.end()) { if(std::equal( short_name->begin(), short_name->end(), new_argument->second.begin(), new_argument->second.end(), [](char a, char b) { return tolower(b) == tolower(a); })) { break; } ++short_name; } // If a match was found, use the corresponding long name to look up a suitable // Analyser::Statuc::Target and move that to the targets list. if(short_name != short_names.end()) { long_machine_name = Machine::AllMachines(Machine::Type::DoesntRequireMedia, true)[short_name - short_names.begin()]; auto targets_by_machine = Machine::TargetsByMachineName(false); std::unique_ptr tgt = std::move(targets_by_machine[long_machine_name]); targets.push_back(std::move(tgt)); } } else if(!arguments.file_names.empty()) { // Take the first file name that actually implies a machine. auto file_name = arguments.file_names.begin(); while(file_name != arguments.file_names.end() && targets.empty()) { targets = Analyser::Static::GetTargets(*file_name); ++file_name; } } if(targets.empty()) { if(!arguments.file_names.empty()) { std::cerr << "Cannot open "; bool is_first = true; for(const auto &name: arguments.file_names) { if(!is_first) std::cerr << ", "; is_first = false; std::cerr << name; } std::cerr << "; no target machine found" << std::endl; return EXIT_FAILURE; } if(!new_argument->second.empty()) { std::cerr << "Unknown machine: " << new_argument->second << std::endl; return EXIT_FAILURE; } std::cerr << "Usage: " << final_path_component(argv[0]) << usage_suffix << std::endl; std::cerr << "Use --help to learn more about available options." << std::endl; return EXIT_FAILURE; } MachineRunner machine_runner; SpeakerDelegate speaker_delegate; // For vanilla SDL purposes, assume system ROMs can be found in one of: // // /usr/local/share/CLK/[system]; // /usr/share/CLK/[system]; or // [user-supplied path]/[system] ROM::Request requested_roms; std::vector checked_paths; ROMMachine::ROMFetcher rom_fetcher = [&requested_roms, &arguments, &checked_paths] (const ROM::Request &roms) -> ROM::Map { requested_roms = roms; std::vector paths = { "/usr/local/share/CLK/", "/usr/share/CLK/" }; const auto rompath = arguments.selections.find("rompath"); if(rompath != arguments.selections.end()) { if(rompath->second.back() != '/') { paths.push_back(rompath->second + "/"); } else { paths.push_back(rompath->second); } } ROM::Map results; for(const auto &description: roms.all_descriptions()) { for(const auto &file_name: description.file_names) { FILE *file = nullptr; std::vector rom_checked_paths; for(const auto &path: paths) { std::string local_path = path + description.machine_name + "/" + file_name; file = std::fopen(local_path.c_str(), "rb"); rom_checked_paths.push_back(local_path); if(file) break; } if(!file) { std::copy(rom_checked_paths.begin(), rom_checked_paths.end(), std::back_inserter(checked_paths)); continue; } std::vector data; std::fseek(file, 0, SEEK_END); data.resize(std::ftell(file)); std::fseek(file, 0, SEEK_SET); std::size_t read = fread(data.data(), 1, data.size(), file); std::fclose(file); if(read == data.size()) { results[description.name] = std::move(data); } else { std::copy(rom_checked_paths.begin(), rom_checked_paths.end(), std::back_inserter(checked_paths)); } } } return results; }; // Apply all command-line options to the targets. for(auto &target: targets) { auto reflectable_target = dynamic_cast(target.get()); if(!reflectable_target) continue; arguments.apply(reflectable_target); } // Create and configure a machine. ::Machine::Error error; std::mutex machine_mutex; std::unique_ptr<::Machine::DynamicMachine> machine(::Machine::MachineForTargets(targets, rom_fetcher, error)); if(!machine) { switch(error) { default: break; case ::Machine::Error::MissingROM: /* std::cerr << "Could not find system ROMs; please install to /usr/local/share/CLK/ or /usr/share/CLK/, or provide a --rompath." << std::endl; std::cerr << "One or more of the following was needed but not found:" << std::endl; for(const auto &rom: requested_roms) { std::cerr << rom.machine_name << '/' << rom.file_name << " ("; if(!rom.descriptive_name.empty()) { std::cerr << rom.descriptive_name << "; "; } std::cerr << ((rom.crc32s.size() > 1) ? "usual crc32s: " : "usual crc32: "); bool is_first = true; for(const auto crc32: rom.crc32s) { if(!is_first) std::cerr << ", "; is_first = false; std::cerr << std::hex << std::setfill('0') << std::setw(8) << crc32; } std::cerr << ")" << std::endl; } std::cerr << std::endl << "Tried specifically: "; bool is_first = true; for(const auto &path: checked_paths) { if(!is_first) std::cerr << "; "; std::cerr << path; is_first = false; } std::cerr << std::endl;*/ break; } return EXIT_FAILURE; } // Apply all command-line options to the machines. auto configurable = machine->configurable_device(); if(configurable) { const auto options = configurable->get_options(); arguments.apply(options.get()); configurable->set_options(options); } // Apply the speed multiplier, if one was requested. { const auto speed_argument = arguments.selections.find("speed"); if(speed_argument != arguments.selections.end()) { const char *speed_string = speed_argument->second.c_str(); char *end; const double speed = strtod(speed_string, &end); if(size_t(end - speed_string) != strlen(speed_string)) { std::cerr << "Unable to parse speed: " << speed_string << std::endl; } else if(speed <= 0.0) { std::cerr << "Cannot run at speed " << speed_string << "; speeds must be positive." << std::endl; } else { machine_runner.set_speed_multiplier(speed); } } } // Apply the desired output volume, if requested. { const auto volume_argument = arguments.selections.find("volume"); if(volume_argument != arguments.selections.end()) { const char *volume_string = volume_argument->second.c_str(); char *end; const double volume = strtod(volume_string, &end); if(size_t(end - volume_string) != strlen(volume_string)) { std::cerr << "Unable to parse volume: " << volume_string << std::endl; } else if(volume < 0.0 || volume > 1.0) { std::cerr << "Cannot run with volume " << volume_string << "; volumes must be between 0.0 and 1.0." << std::endl; } else { const auto speaker = machine->audio_producer()->get_speaker(); if(speaker) speaker->set_output_volume(volume); } } } // Check whether a 'logical' keyboard has been requested, or the machine would prefer one anyway. const bool logical_keyboard = (arguments.selections.find("logical-keyboard") != arguments.selections.end()) || (machine->keyboard_machine() && machine->keyboard_machine()->prefers_logical_input()); if(logical_keyboard) { SDL_StartTextInput(); } // Ensure all media is inserted, if this machine accepts it. { auto media_target = machine->media_target(); if(media_target) { Analyser::Static::Media media; for(const auto &file_name: arguments.file_names) { media += Analyser::Static::GetMedia(file_name); } media_target->insert_media(media); } } // Attempt to set up video and audio. if(SDL_Init(SDL_INIT_VIDEO | SDL_INIT_AUDIO) < 0) { std::cerr << "SDL could not initialize! SDL_Error: " << SDL_GetError() << std::endl; return EXIT_FAILURE; } // Ask for no depth buffer, a core profile and vsync-aligned rendering. SDL_GL_SetAttribute(SDL_GL_DEPTH_SIZE, 0); SDL_GL_SetAttribute(SDL_GL_CONTEXT_PROFILE_MASK, SDL_GL_CONTEXT_PROFILE_CORE); SDL_GL_SetAttribute(SDL_GL_CONTEXT_MAJOR_VERSION, 3); SDL_GL_SetAttribute(SDL_GL_CONTEXT_MINOR_VERSION, 2); SDL_GL_SetSwapInterval(1); window = SDL_CreateWindow( long_machine_name.empty() ? final_path_component(arguments.file_names.front()).c_str() : long_machine_name.c_str(), SDL_WINDOWPOS_UNDEFINED, SDL_WINDOWPOS_UNDEFINED, 400, 300, SDL_WINDOW_OPENGL | SDL_WINDOW_RESIZABLE); DynamicWindowTitler window_titler(window); SDL_GLContext gl_context = nullptr; if(window) { gl_context = SDL_GL_CreateContext(window); } if(!window || !gl_context) { std::cerr << "Could not create " << (window ? "OpenGL context" : "window"); std::cerr << "; reported error: \"" << SDL_GetError() << "\"" << std::endl; return EXIT_FAILURE; } SDL_GL_MakeCurrent(window, gl_context); GLint target_framebuffer = 0; glGetIntegerv(GL_FRAMEBUFFER_BINDING, &target_framebuffer); // Setup output, assuming a CRT machine for now, and prepare a best-effort updater. Outputs::Display::OpenGL::ScanTarget scan_target(target_framebuffer); std::unique_ptr activity_observer; bool uses_mouse; std::vector joysticks; machine_runner.machine_mutex = &machine_mutex; const auto setup_machine_input_output = [&scan_target, &machine, &speaker_delegate, &activity_observer, &joysticks, &uses_mouse, &machine_runner] { // Wire up the best-effort updater, its delegate, and the speaker delegate. machine_runner.machine = machine.get(); machine->scan_producer()->set_scan_target(&scan_target); // For now, lie about audio output intentions. auto speaker = machine->audio_producer()->get_speaker(); if(speaker) { // Create an audio pipe. SDL_AudioSpec desired_audio_spec; SDL_AudioSpec obtained_audio_spec; SDL_zero(desired_audio_spec); desired_audio_spec.freq = 48000; // TODO: how can I get SDL to reveal the output rate of this machine? desired_audio_spec.format = AUDIO_S16; desired_audio_spec.channels = 1 + int(speaker->get_is_stereo()); desired_audio_spec.samples = Uint16(SpeakerDelegate::buffered_samples); desired_audio_spec.callback = SpeakerDelegate::SDL_audio_callback; desired_audio_spec.userdata = &speaker_delegate; speaker_delegate.audio_device = SDL_OpenAudioDevice(nullptr, 0, &desired_audio_spec, &obtained_audio_spec, SDL_AUDIO_ALLOW_FREQUENCY_CHANGE); speaker->set_output_rate(obtained_audio_spec.freq, desired_audio_spec.samples, obtained_audio_spec.channels == 2); speaker_delegate.is_stereo = obtained_audio_spec.channels == 2; speaker->set_delegate(&speaker_delegate); SDL_PauseAudioDevice(speaker_delegate.audio_device, 0); } /* If the machine offers anything for activity observation, create and register an activity observer. */ Activity::Source *const activity_source = machine->activity_source(); if(activity_source) { activity_observer = std::make_unique(activity_source, 4.0f / 3.0f); } else { activity_observer = nullptr; } // If this is a joystick machine, check for and open attached joysticks. const auto joystick_machine = machine->joystick_machine(); if(joystick_machine) { SDL_InitSubSystem(SDL_INIT_JOYSTICK); for(int c = 0; c < SDL_NumJoysticks(); ++c) { joysticks.emplace_back(SDL_JoystickOpen(c)); } } else { joysticks.clear(); } // Keep a record of whether mouse events can be forwarded. uses_mouse = !!machine->mouse_machine(); }; setup_machine_input_output(); int window_width, window_height; SDL_GetWindowSize(window, &window_width, &window_height); // SDL 2.x delivers key up/down events and text inputs separately even when they're correlated; // this struct and map is used to correlate them by time. struct KeyPress { uint32_t timestamp = 0; std::string input; SDL_Scancode scancode = SDL_SCANCODE_UNKNOWN; SDL_Keycode keycode = SDLK_UNKNOWN; bool is_down = true; KeyPress(uint32_t timestamp, const char *text) : timestamp(timestamp), input(text) {} KeyPress(uint32_t timestamp, SDL_Scancode scancode, SDL_Keycode keycode, bool is_down) : timestamp(timestamp), scancode(scancode), keycode(keycode), is_down(is_down) {} KeyPress() {} }; std::vector keypresses; // Run the main event loop until the OS tells us to quit. bool should_quit = false; Uint32 fullscreen_mode = 0; machine_runner.start(); while(!should_quit) { // Draw a new frame, indicating completion of the draw to the machine runner. scan_target.update(int(window_width), int(window_height)); scan_target.draw(int(window_width), int(window_height)); if(activity_observer) activity_observer->draw(); machine_runner.signal_did_draw(); // Wait for presentation of that frame, posting a vsync. SDL_GL_SwapWindow(window); machine_runner.signal_vsync(); // NB: machine_mutex is *not* currently locked, therefore it shouldn't // be 'most' of the time — assuming most of the time is spent waiting // on vsync, anyway. // Grab the machine lock and process all pending events. std::lock_guard lock_guard(machine_mutex); const auto keyboard_machine = machine->keyboard_machine(); SDL_Event event; while(SDL_PollEvent(&event)) { switch(event.type) { case SDL_QUIT: should_quit = true; break; case SDL_WINDOWEVENT: switch (event.window.event) { case SDL_WINDOWEVENT_RESIZED: { GLint target_framebuffer = 0; glGetIntegerv(GL_FRAMEBUFFER_BINDING, &target_framebuffer); scan_target.set_target_framebuffer(target_framebuffer); SDL_GetWindowSize(window, &window_width, &window_height); if(activity_observer) activity_observer->set_aspect_ratio(float(window_width) / float(window_height)); } break; default: break; } break; case SDL_DROPFILE: { const Analyser::Static::Media media = Analyser::Static::GetMedia(event.drop.file); // If the new file is only media, insert it; if it is a state snapshot then // tear down the entire machine and replace it. if(!media.empty()) { machine->media_target()->insert_media(media); break; } targets = Analyser::Static::GetTargets(event.drop.file); if(targets.empty()) break; ::Machine::Error error; std::unique_ptr<::Machine::DynamicMachine> new_machine(::Machine::MachineForTargets(targets, rom_fetcher, error)); if(error != Machine::Error::None) break; machine = std::move(new_machine); static_cast(&scan_target)->will_change_owner(); setup_machine_input_output(); window_titler.set_file_name(final_path_component(event.drop.file)); } break; case SDL_TEXTINPUT: keypresses.emplace_back(event.text.timestamp, event.text.text); break; case SDL_KEYDOWN: case SDL_KEYUP: { if(event.type == SDL_KEYDOWN) { // Syphon off the key-press if it's control+shift+V (paste). if(event.key.keysym.sym == SDLK_v && (SDL_GetModState()&KMOD_CTRL) && (SDL_GetModState()&KMOD_SHIFT)) { if(keyboard_machine) { keyboard_machine->type_string(SDL_GetClipboardText()); break; } } // Use ctrl+escape to release the mouse (if captured). if(event.key.keysym.sym == SDLK_ESCAPE && (SDL_GetModState()&KMOD_CTRL)) { SDL_SetRelativeMouseMode(SDL_FALSE); window_titler.set_mouse_is_captured(false); } // Capture ctrl+shift+d as a take-a-screenshot command. if(event.key.keysym.sym == SDLK_d && (SDL_GetModState()&KMOD_CTRL) && (SDL_GetModState()&KMOD_SHIFT)) { // Grab the screen buffer. Outputs::Display::OpenGL::Screenshot screenshot(4, 3); // Pick the directory for images. Try `xdg-user-dir PICTURES` first. std::string target_directory = system_get("xdg-user-dir PICTURES"); // Make sure there are no newlines. target_directory.erase(std::remove(target_directory.begin(), target_directory.end(), '\n'), target_directory.end()); target_directory.erase(std::remove(target_directory.begin(), target_directory.end(), '\r'), target_directory.end()); // Fall back on the HOME directory if necessary. if(target_directory.empty()) target_directory = getenv("HOME"); // Find the first available name of the form ~/clk-screenshot-.bmp. size_t index = 0; std::string target; while(true) { target = target_directory + "/clk-screenshot-" + std::to_string(index) + ".bmp"; struct stat file_stats; if(stat(target.c_str(), &file_stats)) break; ++index; } // Create a suitable SDL surface and save the thing. const bool is_big_endian = SDL_BYTEORDER == SDL_BIG_ENDIAN; SDL_Surface *const surface = SDL_CreateRGBSurfaceFrom( screenshot.pixel_data.data(), screenshot.width, screenshot.height, 8*4, screenshot.width*4, is_big_endian ? 0xff000000 : 0x000000ff, is_big_endian ? 0x00ff0000 : 0x0000ff00, is_big_endian ? 0x0000ff00 : 0x00ff0000, 0); SDL_SaveBMP(surface, target.c_str()); SDL_FreeSurface(surface); break; } } // Syphon off alt+enter (toggle full-screen) upon key up only; this was previously a key down action, // but the SDL_KEYDOWN announcement was found to be reposted after changing graphics mode on some // systems, causing a loop of changes, so key up is safer. if(event.type == SDL_KEYUP && event.key.keysym.sym == SDLK_RETURN && (SDL_GetModState()&KMOD_ALT)) { fullscreen_mode ^= SDL_WINDOW_FULLSCREEN_DESKTOP; SDL_SetWindowFullscreen(window, fullscreen_mode); SDL_ShowCursor((fullscreen_mode&SDL_WINDOW_FULLSCREEN_DESKTOP) ? SDL_DISABLE : SDL_ENABLE); // Announce a potential discontinuity in keyboard input. const auto keyboard_machine = machine->keyboard_machine(); if(keyboard_machine) { keyboard_machine->get_keyboard().reset_all_keys(); } break; } keypresses.emplace_back(event.text.timestamp, event.key.keysym.scancode, event.key.keysym.sym, event.type == SDL_KEYDOWN); } break; case SDL_MOUSEBUTTONDOWN: case SDL_MOUSEBUTTONUP: { if(uses_mouse && event.type == SDL_MOUSEBUTTONDOWN && !SDL_GetRelativeMouseMode()) { SDL_SetRelativeMouseMode(SDL_TRUE); window_titler.set_mouse_is_captured(true); break; } const auto mouse_machine = machine->mouse_machine(); if(mouse_machine) { mouse_machine->get_mouse().set_button_pressed( event.button.button % mouse_machine->get_mouse().get_number_of_buttons(), event.type == SDL_MOUSEBUTTONDOWN); } } break; case SDL_MOUSEMOTION: { if(SDL_GetRelativeMouseMode()) { const auto mouse_machine = machine->mouse_machine(); if(mouse_machine) { mouse_machine->get_mouse().move(event.motion.xrel, event.motion.yrel); } } } break; default: break; } } std::vector matched_keypresses; if(logical_keyboard) { // Look for potential keypress merges; SDL doesn't in any capacity guarantee that keypresses that produce // symbols will be delivered with the same timestamp. So look for any pairs of recorded kepresses that are // close together temporally and otherwise seem to match. if(keypresses.size()) { auto next_keypress = keypresses.begin(); while(next_keypress != keypresses.end()) { auto keypress = next_keypress; ++next_keypress; // If the two appear to pair off, push a combination and advance twice. // Otherwise, keep just the first and advance once. if( next_keypress != keypresses.end() && keypress->timestamp >= next_keypress->timestamp - 5 && keypress->is_down && next_keypress->is_down && !keypress->input.size() != !next_keypress->input.size() && (keypress->scancode != SDL_SCANCODE_UNKNOWN) != (next_keypress->scancode != SDL_SCANCODE_UNKNOWN)) { KeyPress combined_keypress; if(keypress->scancode != SDL_SCANCODE_UNKNOWN) { combined_keypress.scancode = keypress->scancode; combined_keypress.keycode = keypress->keycode; combined_keypress.input = std::move(next_keypress->input); } else { combined_keypress.scancode = next_keypress->scancode; combined_keypress.keycode = next_keypress->keycode; combined_keypress.input = std::move(keypress->input); }; ++next_keypress; matched_keypresses.push_back(combined_keypress); } else { matched_keypresses.push_back(*keypress); } } } } // Handle accumulated key states. const auto joystick_machine = machine->joystick_machine(); for (const auto &keypress: logical_keyboard ? matched_keypresses : keypresses) { // Try to set this key on the keyboard first, if there is one. if(keyboard_machine) { Inputs::Keyboard::Key key = Inputs::Keyboard::Key::Space; if(KeyboardKeyForSDLScancode(keypress.scancode, key)) { // In principle there's no need for a conditional here; in practice logical_keyboard mode // is sufficiently untested on SDL, and somewhat too reliant on empirical timestamp behaviour, // for it to be trustworthy enough otherwise to expose. if(logical_keyboard) { if(keyboard_machine->apply_key(key, keypress.input.size() ? keypress.input[0] : 0, keypress.is_down, logical_keyboard)) { continue; } } else { // This is a slightly terrible way of obtaining a symbol for the key, e.g. for letters it will always return // the capital letter version, at least empirically. But it'll have to do for now. const char *key_name = SDL_GetKeyName(keypress.keycode); if(keyboard_machine->get_keyboard().set_key_pressed(key, (strlen(key_name) == 1) ? key_name[0] : 0, keypress.is_down)) { continue; } } } } // Having failed that, try converting it into a joystick action. if(joystick_machine) { auto &joysticks = joystick_machine->get_joysticks(); if(!joysticks.empty()) { const bool is_pressed = keypress.is_down; switch(keypress.scancode) { case SDL_SCANCODE_LEFT: joysticks[0]->set_input(Inputs::Joystick::Input::Left, is_pressed); break; case SDL_SCANCODE_RIGHT: joysticks[0]->set_input(Inputs::Joystick::Input::Right, is_pressed); break; case SDL_SCANCODE_UP: joysticks[0]->set_input(Inputs::Joystick::Input::Up, is_pressed); break; case SDL_SCANCODE_DOWN: joysticks[0]->set_input(Inputs::Joystick::Input::Down, is_pressed); break; case SDL_SCANCODE_SPACE: joysticks[0]->set_input(Inputs::Joystick::Input::Fire, is_pressed); break; case SDL_SCANCODE_A: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 0), is_pressed); break; case SDL_SCANCODE_S: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 1), is_pressed); break; case SDL_SCANCODE_D: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 2), is_pressed); break; case SDL_SCANCODE_F: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 3), is_pressed); break; default: { if(keypress.input.size()) { joysticks[0]->set_input(Inputs::Joystick::Input(keypress.input[0]), is_pressed); } } break; } } } } keypresses.clear(); // Push new joystick state, if any. if(joystick_machine) { auto &machine_joysticks = joystick_machine->get_joysticks(); for(size_t c = 0; c < joysticks.size(); ++c) { size_t target = c % machine_joysticks.size(); // Post the first two analogue axes presented by the controller as horizontal and vertical inputs, // unless the user seems to be using a hat. // SDL will return a value in the range [-32768, 32767], so map from that to [0, 1.0] if(!joysticks[c].hat_values()) { const float x_axis = float(SDL_JoystickGetAxis(joysticks[c].get(), 0) + 32768) / 65535.0f; const float y_axis = float(SDL_JoystickGetAxis(joysticks[c].get(), 1) + 32768) / 65535.0f; machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Horizontal), x_axis); machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Vertical), y_axis); } // Forward hats as directions; hats always override analogue inputs. const int number_of_hats = SDL_JoystickNumHats(joysticks[c].get()); for(int hat = 0; hat < number_of_hats; ++hat) { const Uint8 hat_value = SDL_JoystickGetHat(joysticks[c].get(), hat); const Uint8 changes = hat_value ^ joysticks[c].last_hat_value(hat); joysticks[c].last_hat_value(hat) = hat_value; if(changes & SDL_HAT_UP) { machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Up), !!(hat_value & SDL_HAT_UP)); } if(changes & SDL_HAT_DOWN) { machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Down), !!(hat_value & SDL_HAT_DOWN)); } if(changes & SDL_HAT_LEFT) { machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Left), !!(hat_value & SDL_HAT_LEFT)); } if(changes & SDL_HAT_RIGHT) { machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Right), !!(hat_value & SDL_HAT_RIGHT)); } } // Forward all fire buttons, retaining their original indices. const int number_of_buttons = SDL_JoystickNumButtons(joysticks[c].get()); for(int button = 0; button < number_of_buttons; ++button) { machine_joysticks[target]->set_input( Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Fire, button), SDL_JoystickGetButton(joysticks[c].get(), button) ? true : false); } } } } // Clean up. machine_runner.stop(); // Ensure no further updates will occur. joysticks.clear(); SDL_DestroyWindow( window ); SDL_Quit(); return EXIT_SUCCESS; }