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CLK/OSBindings/Mac/Clock Signal/Machine/CSMachine.mm
Thomas Harte 645c29f853 Adds an intermediate buffer to correct inter-frame smoothing.
Also goes someway back to the old scan output scheduling, albeit presently with limited thread safety.
2020-08-15 21:24:10 -04:00

845 lines
29 KiB
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//
// CSMachine.m
// Clock Signal
//
// Created by Thomas Harte on 04/01/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#import "CSMachine.h"
#import "CSMachine+Target.h"
#import "CSHighPrecisionTimer.h"
#include "CSROMFetcher.hpp"
#import "CSScanTarget+CppScanTarget.h"
#include "MediaTarget.hpp"
#include "JoystickMachine.hpp"
#include "KeyboardMachine.hpp"
#include "KeyCodes.h"
#include "MachineForTarget.hpp"
#include "StandardOptions.hpp"
#include "Typer.hpp"
#include "../../../../Activity/Observer.hpp"
#include "../../../../ClockReceiver/TimeTypes.hpp"
#include "../../../../ClockReceiver/ScanSynchroniser.hpp"
#import "CSStaticAnalyser+TargetVector.h"
#import "NSBundle+DataResource.h"
#import "NSData+StdVector.h"
#include <atomic>
#include <bitset>
@interface CSMachine() <CSScanTargetViewDisplayLinkDelegate>
- (void)speaker:(Outputs::Speaker::Speaker *)speaker didCompleteSamples:(const int16_t *)samples length:(int)length;
- (void)speakerDidChangeInputClock:(Outputs::Speaker::Speaker *)speaker;
- (void)addLED:(NSString *)led;
@end
struct LockProtectedDelegate {
// Contractual promise is: machine, the pointer **and** the object **, may be accessed only
// in sections protected by the machineAccessLock;
NSLock *machineAccessLock;
__unsafe_unretained CSMachine *machine;
};
struct SpeakerDelegate: public Outputs::Speaker::Speaker::Delegate, public LockProtectedDelegate {
void speaker_did_complete_samples(Outputs::Speaker::Speaker *speaker, const std::vector<int16_t> &buffer) final {
[machineAccessLock lock];
[machine speaker:speaker didCompleteSamples:buffer.data() length:(int)buffer.size()];
[machineAccessLock unlock];
}
void speaker_did_change_input_clock(Outputs::Speaker::Speaker *speaker) final {
[machineAccessLock lock];
[machine speakerDidChangeInputClock:speaker];
[machineAccessLock unlock];
}
};
struct ActivityObserver: public Activity::Observer {
void register_led(const std::string &name) final {
[machine addLED:[NSString stringWithUTF8String:name.c_str()]];
}
void set_led_status(const std::string &name, bool lit) final {
[machine.delegate machine:machine led:[NSString stringWithUTF8String:name.c_str()] didChangeToLit:lit];
}
void announce_drive_event(const std::string &name, DriveEvent) final {
[machine.delegate machine:machine ledShouldBlink:[NSString stringWithUTF8String:name.c_str()]];
}
__unsafe_unretained CSMachine *machine;
};
@interface CSMissingROM (Mutability)
@property (nonatomic, nonnull, copy) NSString *machineName;
@property (nonatomic, nonnull, copy) NSString *fileName;
@property (nonatomic, nullable, copy) NSString *descriptiveName;
@property (nonatomic, readwrite) NSUInteger size;
@property (nonatomic, copy) NSArray<NSNumber *> *crc32s;
@end
@implementation CSMissingROM {
NSString *_machineName;
NSString *_fileName;
NSString *_descriptiveName;
NSUInteger _size;
NSArray<NSNumber *> *_crc32s;
}
- (NSString *)machineName {
return _machineName;
}
- (void)setMachineName:(NSString *)machineName {
_machineName = [machineName copy];
}
- (NSString *)fileName {
return _fileName;
}
- (void)setFileName:(NSString *)fileName {
_fileName = [fileName copy];
}
- (NSString *)descriptiveName {
return _descriptiveName;
}
- (void)setDescriptiveName:(NSString *)descriptiveName {
_descriptiveName = [descriptiveName copy];
}
- (NSUInteger)size {
return _size;
}
- (void)setSize:(NSUInteger)size {
_size = size;
}
- (NSArray<NSNumber *> *)crc32s {
return _crc32s;
}
- (void)setCrc32s:(NSArray<NSNumber *> *)crc32s {
_crc32s = [crc32s copy];
}
- (NSString *)description {
return [NSString stringWithFormat:@"%@/%@, %lu bytes, CRCs: %@", _fileName, _descriptiveName, (unsigned long)_size, _crc32s];
}
@end
@implementation CSMachine {
SpeakerDelegate _speakerDelegate;
ActivityObserver _activityObserver;
NSLock *_delegateMachineAccessLock;
CSStaticAnalyser *_analyser;
std::unique_ptr<Machine::DynamicMachine> _machine;
MachineTypes::JoystickMachine *_joystickMachine;
CSJoystickManager *_joystickManager;
NSMutableArray<NSString *> *_leds;
CSHighPrecisionTimer *_timer;
CGSize _pixelSize;
std::atomic_flag _isUpdating;
Time::Nanos _syncTime;
Time::Nanos _timeDiff;
double _refreshPeriod;
BOOL _isSyncLocking;
Time::ScanSynchroniser _scanSynchroniser;
NSTimer *_joystickTimer;
// This array exists to reduce blocking on the main queue; anything that would otherwise need
// to synchronise on self in order to post input to the machine can instead synchronise on
// _inputEvents and add a block to it. The main machine execution loop promises to synchronise
// on _inputEvents very briefly at the start of every tick and execute all enqueued blocks.
NSMutableArray<dispatch_block_t> *_inputEvents;
}
- (instancetype)initWithAnalyser:(CSStaticAnalyser *)result missingROMs:(inout NSMutableArray<CSMissingROM *> *)missingROMs {
self = [super init];
if(self) {
_analyser = result;
Machine::Error error;
std::vector<ROMMachine::ROM> missing_roms;
_machine.reset(Machine::MachineForTargets(_analyser.targets, CSROMFetcher(&missing_roms), error));
if(!_machine) {
for(const auto &missing_rom : missing_roms) {
CSMissingROM *rom = [[CSMissingROM alloc] init];
// Copy/convert the primitive fields.
rom.machineName = [NSString stringWithUTF8String:missing_rom.machine_name.c_str()];
rom.fileName = [NSString stringWithUTF8String:missing_rom.file_name.c_str()];
rom.descriptiveName = missing_rom.descriptive_name.empty() ? nil : [NSString stringWithUTF8String:missing_rom.descriptive_name.c_str()];
rom.size = missing_rom.size;
// Convert the CRC list.
NSMutableArray<NSNumber *> *crc32s = [[NSMutableArray alloc] init];
for(const auto &crc : missing_rom.crc32s) {
[crc32s addObject:@(crc)];
}
rom.crc32s = [crc32s copy];
// Add to the missing list.
[missingROMs addObject:rom];
}
return nil;
}
// Use the keyboard as a joystick if the machine has no keyboard, or if it has a 'non-exclusive' keyboard.
_inputMode =
(_machine->keyboard_machine() && _machine->keyboard_machine()->get_keyboard().is_exclusive())
? CSMachineKeyboardInputModeKeyboardPhysical : CSMachineKeyboardInputModeJoystick;
_leds = [[NSMutableArray alloc] init];
Activity::Source *const activity_source = _machine->activity_source();
if(activity_source) {
_activityObserver.machine = self;
activity_source->set_activity_observer(&_activityObserver);
}
_delegateMachineAccessLock = [[NSLock alloc] init];
_speakerDelegate.machine = self;
_speakerDelegate.machineAccessLock = _delegateMachineAccessLock;
_inputEvents = [[NSMutableArray alloc] init];
_joystickMachine = _machine->joystick_machine();
[self updateJoystickTimer];
_isUpdating.clear();
}
return self;
}
- (void)speaker:(Outputs::Speaker::Speaker *)speaker didCompleteSamples:(const int16_t *)samples length:(int)length {
[self.audioQueue enqueueAudioBuffer:samples numberOfSamples:(unsigned int)length];
}
- (void)speakerDidChangeInputClock:(Outputs::Speaker::Speaker *)speaker {
[self.delegate machineSpeakerDidChangeInputClock:self];
}
- (void)dealloc {
[_joystickTimer invalidate];
// The two delegate's references to this machine are nilled out here because close_output may result
// in a data flush, which might cause an audio callback, which could cause the audio queue to decide
// that it's out of data, resulting in an attempt further to run the machine while it is dealloc'ing.
//
// They are nilled inside an explicit lock because that allows the delegates to protect their entire
// call into the machine, not just the pointer access.
[_delegateMachineAccessLock lock];
_speakerDelegate.machine = nil;
[_delegateMachineAccessLock unlock];
// [_view performWithGLContext:^{
// @synchronized(self) {
// self->_scanTarget.reset();
// }
// }];
}
- (float)idealSamplingRateFromRange:(NSRange)range {
@synchronized(self) {
Outputs::Speaker::Speaker *speaker = _machine->audio_producer()->get_speaker();
if(speaker) {
return speaker->get_ideal_clock_rate_in_range((float)range.location, (float)(range.location + range.length));
}
return 0;
}
}
- (BOOL)isStereo {
@synchronized(self) {
Outputs::Speaker::Speaker *speaker = _machine->audio_producer()->get_speaker();
if(speaker) {
return speaker->get_is_stereo();
}
return NO;
}
}
- (void)setAudioSamplingRate:(float)samplingRate bufferSize:(NSUInteger)bufferSize stereo:(BOOL)stereo {
@synchronized(self) {
[self setSpeakerDelegate:&_speakerDelegate sampleRate:samplingRate bufferSize:bufferSize stereo:stereo];
}
}
- (BOOL)setSpeakerDelegate:(Outputs::Speaker::Speaker::Delegate *)delegate sampleRate:(float)sampleRate bufferSize:(NSUInteger)bufferSize stereo:(BOOL)stereo {
@synchronized(self) {
Outputs::Speaker::Speaker *speaker = _machine->audio_producer()->get_speaker();
if(speaker) {
speaker->set_output_rate(sampleRate, (int)bufferSize, stereo);
speaker->set_delegate(delegate);
return YES;
}
return NO;
}
}
- (void)updateJoystickTimer {
// Joysticks updates are scheduled for a nominal 200 polls/second, using a plain old NSTimer.
if(_joystickMachine && _joystickManager) {
_joystickTimer = [NSTimer scheduledTimerWithTimeInterval:1.0 / 200.0 target:self selector:@selector(updateJoysticks) userInfo:nil repeats:YES];
} else {
[_joystickTimer invalidate];
_joystickTimer = nil;
}
}
- (void)updateJoysticks {
[_joystickManager update];
// TODO: configurable mapping from physical joypad inputs to machine inputs.
// Until then, apply a default mapping.
@synchronized(self) {
size_t c = 0;
auto &machine_joysticks = _joystickMachine->get_joysticks();
for(CSJoystick *joystick in _joystickManager.joysticks) {
size_t target = c % machine_joysticks.size();
++c;
// 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(!joystick.hats.count || !joystick.hats[0].direction) {
if(joystick.axes.count > 0) {
const float x_axis = joystick.axes[0].position;
machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Horizontal), x_axis);
}
if(joystick.axes.count > 1) {
const float y_axis = joystick.axes[1].position;
machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Vertical), y_axis);
}
} else {
// Forward hats as directions; hats always override analogue inputs.
for(CSJoystickHat *hat in joystick.hats) {
machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Up), !!(hat.direction & CSJoystickHatDirectionUp));
machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Down), !!(hat.direction & CSJoystickHatDirectionDown));
machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Left), !!(hat.direction & CSJoystickHatDirectionLeft));
machine_joysticks[target]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Right), !!(hat.direction & CSJoystickHatDirectionRight));
}
}
// Forward all fire buttons, mapping as a function of index.
if(machine_joysticks[target]->get_number_of_fire_buttons()) {
std::vector<bool> button_states((size_t)machine_joysticks[target]->get_number_of_fire_buttons());
for(CSJoystickButton *button in joystick.buttons) {
if(button.isPressed) button_states[(size_t)(((int)button.index - 1) % machine_joysticks[target]->get_number_of_fire_buttons())] = true;
}
for(size_t index = 0; index < button_states.size(); ++index) {
machine_joysticks[target]->set_input(
Inputs::Joystick::Input(Inputs::Joystick::Input::Type::Fire, index),
button_states[index]);
}
}
}
}
}
- (void)setView:(CSScanTargetView *)view aspectRatio:(float)aspectRatio {
_view = view;
_view.displayLinkDelegate = self;
_machine->scan_producer()->set_scan_target(_view.scanTarget.scanTarget);
}
- (void)paste:(NSString *)paste {
auto keyboardMachine = _machine->keyboard_machine();
if(keyboardMachine)
keyboardMachine->type_string([paste UTF8String]);
}
- (NSBitmapImageRep *)imageRepresentation {
// Grab a screenshot.
/* Outputs::Display::OpenGL::Screenshot screenshot(4, 3);
// Generate an NSBitmapImageRep containing the screenshot's data.
NSBitmapImageRep *const result =
[[NSBitmapImageRep alloc]
initWithBitmapDataPlanes:NULL
pixelsWide:screenshot.width
pixelsHigh:screenshot.height
bitsPerSample:8
samplesPerPixel:4
hasAlpha:YES
isPlanar:NO
colorSpaceName:NSDeviceRGBColorSpace
bytesPerRow:4 * screenshot.width
bitsPerPixel:0];
memcpy(result.bitmapData, screenshot.pixel_data.data(), size_t(screenshot.width*screenshot.height*4));
return result;*/
return nil;
}
- (void)applyMedia:(const Analyser::Static::Media &)media {
@synchronized(self) {
const auto mediaTarget = _machine->media_target();
if(mediaTarget) mediaTarget->insert_media(media);
}
}
- (void)setJoystickManager:(CSJoystickManager *)joystickManager {
_joystickManager = joystickManager;
if(_joystickMachine) {
@synchronized(self) {
auto &machine_joysticks = _joystickMachine->get_joysticks();
for(const auto &joystick: machine_joysticks) {
joystick->reset_all_inputs();
}
}
}
[self updateJoystickTimer];
}
- (void)setKey:(uint16_t)key characters:(NSString *)characters isPressed:(BOOL)isPressed {
[self applyInputEvent:^{
auto keyboard_machine = self->_machine->keyboard_machine();
if(keyboard_machine && (self.inputMode != CSMachineKeyboardInputModeJoystick || !keyboard_machine->get_keyboard().is_exclusive())) {
Inputs::Keyboard::Key mapped_key = Inputs::Keyboard::Key::Help; // Make an innocuous default guess.
#define BIND(source, dest) case source: mapped_key = Inputs::Keyboard::Key::dest; break;
// Connect the Carbon-era Mac keyboard scancodes to Clock Signal's 'universal' enumeration in order
// to pass into the platform-neutral realm.
switch(key) {
BIND(VK_ANSI_0, k0); BIND(VK_ANSI_1, k1); BIND(VK_ANSI_2, k2); BIND(VK_ANSI_3, k3); BIND(VK_ANSI_4, k4);
BIND(VK_ANSI_5, k5); BIND(VK_ANSI_6, k6); BIND(VK_ANSI_7, k7); BIND(VK_ANSI_8, k8); BIND(VK_ANSI_9, k9);
BIND(VK_ANSI_Q, Q); BIND(VK_ANSI_W, W); BIND(VK_ANSI_E, E); BIND(VK_ANSI_R, R); BIND(VK_ANSI_T, T);
BIND(VK_ANSI_Y, Y); BIND(VK_ANSI_U, U); BIND(VK_ANSI_I, I); BIND(VK_ANSI_O, O); BIND(VK_ANSI_P, P);
BIND(VK_ANSI_A, A); BIND(VK_ANSI_S, S); BIND(VK_ANSI_D, D); BIND(VK_ANSI_F, F); BIND(VK_ANSI_G, G);
BIND(VK_ANSI_H, H); BIND(VK_ANSI_J, J); BIND(VK_ANSI_K, K); BIND(VK_ANSI_L, L);
BIND(VK_ANSI_Z, Z); BIND(VK_ANSI_X, X); BIND(VK_ANSI_C, C); BIND(VK_ANSI_V, V);
BIND(VK_ANSI_B, B); BIND(VK_ANSI_N, N); BIND(VK_ANSI_M, M);
BIND(VK_F1, F1); BIND(VK_F2, F2); BIND(VK_F3, F3); BIND(VK_F4, F4);
BIND(VK_F5, F5); BIND(VK_F6, F6); BIND(VK_F7, F7); BIND(VK_F8, F8);
BIND(VK_F9, F9); BIND(VK_F10, F10); BIND(VK_F11, F11); BIND(VK_F12, F12);
BIND(VK_ANSI_Keypad0, Keypad0); BIND(VK_ANSI_Keypad1, Keypad1); BIND(VK_ANSI_Keypad2, Keypad2);
BIND(VK_ANSI_Keypad3, Keypad3); BIND(VK_ANSI_Keypad4, Keypad4); BIND(VK_ANSI_Keypad5, Keypad5);
BIND(VK_ANSI_Keypad6, Keypad6); BIND(VK_ANSI_Keypad7, Keypad7); BIND(VK_ANSI_Keypad8, Keypad8);
BIND(VK_ANSI_Keypad9, Keypad9);
BIND(VK_ANSI_Equal, Equals); BIND(VK_ANSI_Minus, Hyphen);
BIND(VK_ANSI_RightBracket, CloseSquareBracket); BIND(VK_ANSI_LeftBracket, OpenSquareBracket);
BIND(VK_ANSI_Quote, Quote); BIND(VK_ANSI_Grave, BackTick);
BIND(VK_ANSI_Semicolon, Semicolon);
BIND(VK_ANSI_Backslash, Backslash); BIND(VK_ANSI_Slash, ForwardSlash);
BIND(VK_ANSI_Comma, Comma); BIND(VK_ANSI_Period, FullStop);
BIND(VK_ANSI_KeypadDecimal, KeypadDecimalPoint); BIND(VK_ANSI_KeypadEquals, KeypadEquals);
BIND(VK_ANSI_KeypadMultiply, KeypadAsterisk); BIND(VK_ANSI_KeypadDivide, KeypadSlash);
BIND(VK_ANSI_KeypadPlus, KeypadPlus); BIND(VK_ANSI_KeypadMinus, KeypadMinus);
BIND(VK_ANSI_KeypadClear, KeypadDelete); BIND(VK_ANSI_KeypadEnter, KeypadEnter);
BIND(VK_Return, Enter); BIND(VK_Tab, Tab);
BIND(VK_Space, Space); BIND(VK_Delete, Backspace);
BIND(VK_Control, LeftControl); BIND(VK_Option, LeftOption);
BIND(VK_Command, LeftMeta); BIND(VK_Shift, LeftShift);
BIND(VK_RightControl, RightControl); BIND(VK_RightOption, RightOption);
BIND(VK_Escape, Escape); BIND(VK_CapsLock, CapsLock);
BIND(VK_Home, Home); BIND(VK_End, End);
BIND(VK_PageUp, PageUp); BIND(VK_PageDown, PageDown);
BIND(VK_RightShift, RightShift);
BIND(VK_Help, Help);
BIND(VK_ForwardDelete, Delete);
BIND(VK_LeftArrow, Left); BIND(VK_RightArrow, Right);
BIND(VK_DownArrow, Down); BIND(VK_UpArrow, Up);
}
#undef BIND
// Pick an ASCII code, if any.
char pressedKey = '\0';
if(characters.length) {
unichar firstCharacter = [characters characterAtIndex:0];
if(firstCharacter < 128) {
pressedKey = (char)firstCharacter;
}
}
@synchronized(self) {
if(keyboard_machine->apply_key(mapped_key, pressedKey, isPressed, self.inputMode == CSMachineKeyboardInputModeKeyboardLogical)) {
return;
}
}
}
auto joystick_machine = self->_machine->joystick_machine();
if(self.inputMode == CSMachineKeyboardInputModeJoystick && joystick_machine) {
auto &joysticks = joystick_machine->get_joysticks();
if(!joysticks.empty()) {
// Convert to a C++ bool so that the following calls are resolved correctly even if overloaded.
bool is_pressed = !!isPressed;
switch(key) {
case VK_LeftArrow: joysticks[0]->set_input(Inputs::Joystick::Input::Left, is_pressed); break;
case VK_RightArrow: joysticks[0]->set_input(Inputs::Joystick::Input::Right, is_pressed); break;
case VK_UpArrow: joysticks[0]->set_input(Inputs::Joystick::Input::Up, is_pressed); break;
case VK_DownArrow: joysticks[0]->set_input(Inputs::Joystick::Input::Down, is_pressed); break;
case VK_Space: joysticks[0]->set_input(Inputs::Joystick::Input::Fire, is_pressed); break;
case VK_ANSI_A: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 0), is_pressed); break;
case VK_ANSI_S: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 1), is_pressed); break;
case VK_ANSI_D: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 2), is_pressed); break;
case VK_ANSI_F: joysticks[0]->set_input(Inputs::Joystick::Input(Inputs::Joystick::Input::Fire, 3), is_pressed); break;
default:
if(characters.length) {
joysticks[0]->set_input(Inputs::Joystick::Input([characters characterAtIndex:0]), is_pressed);
} else {
joysticks[0]->set_input(Inputs::Joystick::Input::Fire, is_pressed);
}
break;
}
}
}
}];
}
- (void)applyInputEvent:(dispatch_block_t)event {
@synchronized(_inputEvents) {
[_inputEvents addObject:event];
}
}
- (void)clearAllKeys {
const auto keyboard_machine = _machine->keyboard_machine();
if(keyboard_machine) {
[self applyInputEvent:^{
keyboard_machine->get_keyboard().reset_all_keys();
}];
}
const auto joystick_machine = _machine->joystick_machine();
if(joystick_machine) {
[self applyInputEvent:^{
for(auto &joystick : joystick_machine->get_joysticks()) {
joystick->reset_all_inputs();
}
}];
}
const auto mouse_machine = _machine->mouse_machine();
if(mouse_machine) {
[self applyInputEvent:^{
mouse_machine->get_mouse().reset_all_buttons();
}];
}
}
- (void)setMouseButton:(int)button isPressed:(BOOL)isPressed {
auto mouse_machine = _machine->mouse_machine();
if(mouse_machine) {
[self applyInputEvent:^{
mouse_machine->get_mouse().set_button_pressed(button % mouse_machine->get_mouse().get_number_of_buttons(), isPressed);
}];
}
}
- (void)addMouseMotionX:(CGFloat)deltaX y:(CGFloat)deltaY {
auto mouse_machine = _machine->mouse_machine();
if(mouse_machine) {
[self applyInputEvent:^{
mouse_machine->get_mouse().move(int(deltaX), int(deltaY));
}];
}
}
#pragma mark - Options
- (void)setUseFastLoadingHack:(BOOL)useFastLoadingHack {
Configurable::Device *configurable_device = _machine->configurable_device();
if(!configurable_device) return;
@synchronized(self) {
_useFastLoadingHack = useFastLoadingHack;
auto options = configurable_device->get_options();
Reflection::set(*options, "quickload", useFastLoadingHack ? true : false);
configurable_device->set_options(options);
}
}
- (void)setVideoSignal:(CSMachineVideoSignal)videoSignal {
Configurable::Device *configurable_device = _machine->configurable_device();
if(!configurable_device) return;
@synchronized(self) {
_videoSignal = videoSignal;
Configurable::Display display;
switch(videoSignal) {
case CSMachineVideoSignalRGB: display = Configurable::Display::RGB; break;
case CSMachineVideoSignalSVideo: display = Configurable::Display::SVideo; break;
case CSMachineVideoSignalComposite: display = Configurable::Display::CompositeColour; break;
case CSMachineVideoSignalMonochromeComposite: display = Configurable::Display::CompositeMonochrome; break;
}
auto options = configurable_device->get_options();
Reflection::set(*options, "output", int(display));
configurable_device->set_options(options);
}
}
- (BOOL)supportsVideoSignal:(CSMachineVideoSignal)videoSignal {
Configurable::Device *configurable_device = _machine->configurable_device();
if(!configurable_device) return NO;
// Get the options this machine provides.
@synchronized(self) {
auto options = configurable_device->get_options();
// Get the standard option for this video signal.
Configurable::Display option;
switch(videoSignal) {
case CSMachineVideoSignalRGB: option = Configurable::Display::RGB; break;
case CSMachineVideoSignalSVideo: option = Configurable::Display::SVideo; break;
case CSMachineVideoSignalComposite: option = Configurable::Display::CompositeColour; break;
case CSMachineVideoSignalMonochromeComposite: option = Configurable::Display::CompositeMonochrome; break;
}
// Map to a string and check against returned options for the 'output' field.
const auto string_option = Reflection::Enum::to_string<Configurable::Display>(option);
const auto all_values = options->values_for("output");
return std::find(all_values.begin(), all_values.end(), string_option) != all_values.end();
}
return NO;
}
- (void)setUseAutomaticTapeMotorControl:(BOOL)useAutomaticTapeMotorControl {
Configurable::Device *configurable_device = _machine->configurable_device();
if(!configurable_device) return;
@synchronized(self) {
_useAutomaticTapeMotorControl = useAutomaticTapeMotorControl;
auto options = configurable_device->get_options();
Reflection::set(*options, "automatic_tape_motor_control", useAutomaticTapeMotorControl ? true : false);
configurable_device->set_options(options);
}
}
- (void)setUseQuickBootingHack:(BOOL)useQuickBootingHack {
Configurable::Device *configurable_device = _machine->configurable_device();
if(!configurable_device) return;
@synchronized(self) {
_useQuickBootingHack = useQuickBootingHack;
auto options = configurable_device->get_options();
Reflection::set(*options, "quickboot", useQuickBootingHack ? true : false);
configurable_device->set_options(options);
}
}
- (NSString *)userDefaultsPrefix {
// Assumes that the first machine in the targets list is the source of user defaults.
std::string name = Machine::ShortNameForTargetMachine(_analyser.targets.front()->machine);
return [[NSString stringWithUTF8String:name.c_str()] lowercaseString];
}
- (BOOL)canInsertMedia {
return !!_machine->media_target();
}
#pragma mark - Special machines
- (CSAtari2600 *)atari2600 {
return [[CSAtari2600 alloc] initWithAtari2600:_machine->raw_pointer() owner:self];
}
- (CSZX8081 *)zx8081 {
return [[CSZX8081 alloc] initWithZX8081:_machine->raw_pointer() owner:self];
}
#pragma mark - Input device queries
- (BOOL)hasJoystick {
return !!_machine->joystick_machine();
}
- (BOOL)hasMouse {
return !!_machine->mouse_machine();
}
- (BOOL)hasExclusiveKeyboard {
return !!_machine->keyboard_machine() && _machine->keyboard_machine()->get_keyboard().is_exclusive();
}
- (BOOL)shouldUsurpCommand {
if(!_machine->keyboard_machine()) return NO;
const auto essential_modifiers = _machine->keyboard_machine()->get_keyboard().get_essential_modifiers();
return essential_modifiers.find(Inputs::Keyboard::Key::LeftMeta) != essential_modifiers.end() ||
essential_modifiers.find(Inputs::Keyboard::Key::RightMeta) != essential_modifiers.end();
}
#pragma mark - Volume control
- (void)setVolume:(float)volume {
@synchronized(self) {
Outputs::Speaker::Speaker *speaker = _machine->audio_producer()->get_speaker();
if(speaker) {
return speaker->set_output_volume(volume);
}
}
}
- (BOOL)hasAudioOutput {
@synchronized(self) {
Outputs::Speaker::Speaker *speaker = _machine->audio_producer()->get_speaker();
return speaker ? YES : NO;
}
}
#pragma mark - Activity observation
- (void)addLED:(NSString *)led {
[_leds addObject:led];
}
- (NSArray<NSString *> *)leds {
return _leds;
}
#pragma mark - Timer
- (void)openGLViewDisplayLinkDidFire:(CSScanTargetView *)view now:(const CVTimeStamp *)now outputTime:(const CVTimeStamp *)outputTime {
// First order of business: grab a timestamp.
const auto timeNow = Time::nanos_now();
CGSize pixelSize = view.backingSize;
BOOL isSyncLocking;
@synchronized(self) {
// Store a means to map from CVTimeStamp.hostTime to Time::Nanos;
// there is an extremely dodgy assumption here that the former is in ns.
if(!_timeDiff) {
_timeDiff = int64_t(now->hostTime) - int64_t(timeNow);
}
// Store the next end-of-frame time. TODO: and start of next and implied visible duration, if raster racing?
_syncTime = int64_t(now->hostTime) + _timeDiff;
// Also crib the current view pixel size.
_pixelSize = pixelSize;
// Set the current refresh period.
_refreshPeriod = double(now->videoRefreshPeriod) / double(now->videoTimeScale);
// Determine where responsibility lies for drawing.
isSyncLocking = _isSyncLocking;
}
// Draw the current output. (TODO: do this within the timer if either raster racing or, at least, sync matching).
if(!isSyncLocking) {
// [self.view performWithGLContext:^{
// self->_scanTarget->draw((int)pixelSize.width, (int)pixelSize.height);
// } flushDrawable:YES];
}
}
#define TICKS 600
- (void)start {
__block auto lastTime = Time::nanos_now();
_timer = [[CSHighPrecisionTimer alloc] initWithTask:^{
// Grab the time now and, therefore, the amount of time since the timer last fired
// (subject to a cap to avoid potential perpetual regression).
const auto timeNow = Time::nanos_now();
lastTime = std::max(timeNow - Time::Nanos(10'000'000'000 / TICKS), lastTime);
const auto duration = timeNow - lastTime;
CGSize pixelSize;
BOOL splitAndSync = NO;
@synchronized(self) {
// Post on input events.
@synchronized(self->_inputEvents) {
for(dispatch_block_t action: self->_inputEvents) {
action();
}
[self->_inputEvents removeAllObjects];
}
// If this tick includes vsync then inspect the machine.
if(timeNow >= self->_syncTime && lastTime < self->_syncTime) {
splitAndSync = self->_isSyncLocking = self->_scanSynchroniser.can_synchronise(self->_machine->scan_producer()->get_scan_status(), self->_refreshPeriod);
// If the time window is being split, run up to the split, then check out machine speed, possibly
// adjusting multiplier, then run after the split.
if(splitAndSync) {
self->_machine->timed_machine()->run_for((double)(self->_syncTime - lastTime) / 1e9);
self->_machine->timed_machine()->set_speed_multiplier(
self->_scanSynchroniser.next_speed_multiplier(self->_machine->scan_producer()->get_scan_status())
);
self->_machine->timed_machine()->run_for((double)(timeNow - self->_syncTime) / 1e9);
}
}
// If the time window is being split, run up to the split, then check out machine speed, possibly
// adjusting multiplier, then run after the split.
if(!splitAndSync) {
self->_machine->timed_machine()->run_for((double)duration / 1e9);
}
pixelSize = self->_pixelSize;
}
// If this was not a split-and-sync then dispatch the update request asynchronously, unless
// there is an earlier one not yet finished, in which case don't worry about it for now.
//
// If it was a split-and-sync then spin until it is safe to dispatch, and dispatch with
// a concluding draw. Implicit assumption here: whatever is left to be done in the final window
// can be done within the retrace period.
auto wasUpdating = self->_isUpdating.test_and_set();
if(wasUpdating && splitAndSync) {
while(self->_isUpdating.test_and_set());
wasUpdating = false;
}
if(!wasUpdating) {
dispatch_async(dispatch_get_global_queue(QOS_CLASS_USER_INTERACTIVE, 0), ^{
[self.view updateBacking];
// [self.view performWithGLContext:^{
// self->_scanTarget->update((int)pixelSize.width, (int)pixelSize.height);
// if(splitAndSync) {
// self->_scanTarget->draw((int)pixelSize.width, (int)pixelSize.height);
// }
// } flushDrawable:splitAndSync];
self->_isUpdating.clear();
});
}
lastTime = timeNow;
} interval:uint64_t(1000000000) / uint64_t(TICKS)];
}
#undef TICKS
- (void)stop {
[_timer invalidate];
_timer = nil;
}
@end