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yuzu-mainline/src/common/input.h

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chore: make yuzu REUSE compliant [REUSE] is a specification that aims at making file copyright information consistent, so that it can be both human and machine readable. It basically requires that all files have a header containing copyright and licensing information. When this isn't possible, like when dealing with binary assets, generated files or embedded third-party dependencies, it is permitted to insert copyright information in the `.reuse/dep5` file. Oh, and it also requires that all the licenses used in the project are present in the `LICENSES` folder, that's why the diff is so huge. This can be done automatically with `reuse download --all`. The `reuse` tool also contains a handy subcommand that analyzes the project and tells whether or not the project is (still) compliant, `reuse lint`. Following REUSE has a few advantages over the current approach: - Copyright information is easy to access for users / downstream - Files like `dist/license.md` do not need to exist anymore, as `.reuse/dep5` is used instead - `reuse lint` makes it easy to ensure that copyright information of files like binary assets / images is always accurate and up to date To add copyright information of files that didn't have it I looked up who committed what and when, for each file. As yuzu contributors do not have to sign a CLA or similar I couldn't assume that copyright ownership was of the "yuzu Emulator Project", so I used the name and/or email of the commit author instead. [REUSE]: https://reuse.software Follow-up to 01cf05bc75b1e47beb08937439f3ed9339e7b254
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// SPDX-FileCopyrightText: 2017 Citra Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#pragma once
#include <functional>
#include <memory>
#include <string>
#include <unordered_map>
#include <utility>
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#include <vector>
#include "common/logging/log.h"
#include "common/param_package.h"
#include "common/uuid.h"
namespace Common::Input {
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// Type of data that is expected to receive or send
enum class InputType {
None,
Battery,
Button,
Stick,
Analog,
Trigger,
Motion,
Touch,
Color,
Vibration,
Nfc,
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IrSensor,
};
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// Internal battery charge level
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enum class BatteryLevel : u32 {
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None,
Empty,
Critical,
Low,
Medium,
Full,
Charging,
};
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enum class PollingMode {
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// Constant polling of buttons, analogs and motion data
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Active,
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// Only update on button change, digital analogs
Passive,
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// Enable near field communication polling
NFC,
// Enable infrared camera polling
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IR,
// Enable ring controller polling
Ring,
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};
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enum class CameraFormat {
Size320x240,
Size160x120,
Size80x60,
Size40x30,
Size20x15,
None,
};
// Different results that can happen from a device request
enum class DriverResult {
Success,
WrongReply,
Timeout,
UnsupportedControllerType,
HandleInUse,
ErrorReadingData,
ErrorWritingData,
NoDeviceDetected,
InvalidHandle,
InvalidParameters,
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NotSupported,
Disabled,
Delayed,
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Unknown,
};
// Nfc reply from the controller
enum class NfcState {
Success,
NewAmiibo,
WaitingForAmiibo,
AmiiboRemoved,
InvalidTagType,
NotSupported,
WrongDeviceState,
WriteFailed,
Unknown,
};
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// Hint for amplification curve to be used
enum class VibrationAmplificationType {
Linear,
Exponential,
};
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// Analog properties for calibration
struct AnalogProperties {
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// Anything below this value will be detected as zero
float deadzone{};
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// Anything above this values will be detected as one
float range{1.0f};
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// Minimum value to be detected as active
float threshold{0.5f};
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// Drift correction applied to the raw data
float offset{};
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// Invert direction of the sensor data
bool inverted{};
// Invert the state if it's converted to a button
bool inverted_button{};
// Press once to activate, press again to release
bool toggle{};
};
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// Single analog sensor data
struct AnalogStatus {
float value{};
float raw_value{};
AnalogProperties properties{};
};
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// Button data
struct ButtonStatus {
Common::UUID uuid{};
bool value{};
// Invert value of the button
bool inverted{};
// Press once to activate, press again to release
bool toggle{};
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// Spams the button when active
bool turbo{};
// Internal lock for the toggle status
bool locked{};
};
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// Internal battery data
using BatteryStatus = BatteryLevel;
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// Analog and digital joystick data
struct StickStatus {
Common::UUID uuid{};
AnalogStatus x{};
AnalogStatus y{};
bool left{};
bool right{};
bool up{};
bool down{};
};
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// Analog and digital trigger data
struct TriggerStatus {
Common::UUID uuid{};
AnalogStatus analog{};
ButtonStatus pressed{};
};
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// 3D vector representing motion input
struct MotionSensor {
AnalogStatus x{};
AnalogStatus y{};
AnalogStatus z{};
};
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// Motion data used to calculate controller orientation
struct MotionStatus {
// Gyroscope vector measurement in radians/s.
MotionSensor gyro{};
// Acceleration vector measurement in G force
MotionSensor accel{};
// Time since last measurement in microseconds
u64 delta_timestamp{};
// Request to update after reading the value
bool force_update{};
};
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// Data of a single point on a touch screen
struct TouchStatus {
ButtonStatus pressed{};
AnalogStatus x{};
AnalogStatus y{};
int id{};
};
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// Physical controller color in RGB format
struct BodyColorStatus {
u32 body{};
u32 buttons{};
u32 left_grip{};
u32 right_grip{};
};
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// HD rumble data
struct VibrationStatus {
f32 low_amplitude{};
f32 low_frequency{};
f32 high_amplitude{};
f32 high_frequency{};
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VibrationAmplificationType type;
};
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// Physical controller LED pattern
struct LedStatus {
bool led_1{};
bool led_2{};
bool led_3{};
bool led_4{};
};
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// Raw data from camera
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struct CameraStatus {
CameraFormat format{CameraFormat::None};
std::vector<u8> data{};
};
struct NfcStatus {
NfcState state{NfcState::Unknown};
u8 uuid_length;
u8 protocol;
u8 tag_type;
std::array<u8, 10> uuid;
};
struct MifareData {
u8 command;
u8 sector;
std::array<u8, 0x6> key;
std::array<u8, 0x10> data;
};
struct MifareRequest {
std::array<MifareData, 0x10> data;
};
// List of buttons to be passed to Qt that can be translated
enum class ButtonNames {
Undefined,
Invalid,
// This will display the engine name instead of the button name
Engine,
// This will display the button by value instead of the button name
Value,
// Joycon button names
ButtonLeft,
ButtonRight,
ButtonDown,
ButtonUp,
ButtonA,
ButtonB,
ButtonX,
ButtonY,
ButtonPlus,
ButtonMinus,
ButtonHome,
ButtonCapture,
ButtonStickL,
ButtonStickR,
TriggerL,
TriggerZL,
TriggerSL,
TriggerR,
TriggerZR,
TriggerSR,
// GC button names
TriggerZ,
ButtonStart,
// DS4 button names
L1,
L2,
L3,
R1,
R2,
R3,
Circle,
Cross,
Square,
Triangle,
Share,
Options,
Home,
Touch,
// Mouse buttons
ButtonMouseWheel,
ButtonBackward,
ButtonForward,
ButtonTask,
ButtonExtra,
};
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// Callback data consisting of an input type and the equivalent data status
struct CallbackStatus {
InputType type{InputType::None};
ButtonStatus button_status{};
StickStatus stick_status{};
AnalogStatus analog_status{};
TriggerStatus trigger_status{};
MotionStatus motion_status{};
TouchStatus touch_status{};
BodyColorStatus color_status{};
BatteryStatus battery_status{};
VibrationStatus vibration_status{};
CameraFormat camera_status{CameraFormat::None};
NfcStatus nfc_status{};
std::vector<u8> raw_data{};
};
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// Triggered once every input change
struct InputCallback {
std::function<void(const CallbackStatus&)> on_change;
};
/// An abstract class template for an input device (a button, an analog input, etc.).
class InputDevice {
public:
virtual ~InputDevice() = default;
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// Force input device to update data regardless of the current state
virtual void ForceUpdate() {}
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// Sets the function to be triggered when input changes
void SetCallback(InputCallback callback_) {
callback = std::move(callback_);
}
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// Triggers the function set in the callback
void TriggerOnChange(const CallbackStatus& status) {
if (callback.on_change) {
callback.on_change(status);
}
}
private:
InputCallback callback;
};
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/// An abstract class template for an output device (rumble, LED pattern, polling mode).
class OutputDevice {
public:
virtual ~OutputDevice() = default;
virtual DriverResult SetLED([[maybe_unused]] const LedStatus& led_status) {
return DriverResult::NotSupported;
}
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virtual DriverResult SetVibration([[maybe_unused]] const VibrationStatus& vibration_status) {
return DriverResult::NotSupported;
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}
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virtual bool IsVibrationEnabled() {
return false;
}
virtual DriverResult SetPollingMode([[maybe_unused]] PollingMode polling_mode) {
return DriverResult::NotSupported;
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}
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virtual DriverResult SetCameraFormat([[maybe_unused]] CameraFormat camera_format) {
return DriverResult::NotSupported;
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}
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virtual NfcState SupportsNfc() const {
return NfcState::NotSupported;
}
virtual NfcState StartNfcPolling() {
return NfcState::NotSupported;
}
virtual NfcState StopNfcPolling() {
return NfcState::NotSupported;
}
virtual NfcState ReadAmiiboData([[maybe_unused]] std::vector<u8>& out_data) {
return NfcState::NotSupported;
}
virtual NfcState WriteNfcData([[maybe_unused]] const std::vector<u8>& data) {
return NfcState::NotSupported;
}
virtual NfcState ReadMifareData([[maybe_unused]] const MifareRequest& request,
[[maybe_unused]] MifareRequest& out_data) {
return NfcState::NotSupported;
}
virtual NfcState WriteMifareData([[maybe_unused]] const MifareRequest& request) {
return NfcState::NotSupported;
}
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};
/// An abstract class template for a factory that can create input devices.
template <typename InputDeviceType>
class Factory {
public:
virtual ~Factory() = default;
virtual std::unique_ptr<InputDeviceType> Create(const Common::ParamPackage&) = 0;
};
namespace Impl {
template <typename InputDeviceType>
using FactoryListType = std::unordered_map<std::string, std::shared_ptr<Factory<InputDeviceType>>>;
template <typename InputDeviceType>
struct FactoryList {
static FactoryListType<InputDeviceType> list;
};
template <typename InputDeviceType>
FactoryListType<InputDeviceType> FactoryList<InputDeviceType>::list;
} // namespace Impl
/**
* Registers an input device factory.
* @tparam InputDeviceType the type of input devices the factory can create
* @param name the name of the factory. Will be used to match the "engine" parameter when creating
* a device
* @param factory the factory object to register
*/
template <typename InputDeviceType>
void RegisterFactory(const std::string& name, std::shared_ptr<Factory<InputDeviceType>> factory) {
auto pair = std::make_pair(name, std::move(factory));
if (!Impl::FactoryList<InputDeviceType>::list.insert(std::move(pair)).second) {
LOG_ERROR(Input, "Factory '{}' already registered", name);
}
}
inline void RegisterInputFactory(const std::string& name,
std::shared_ptr<Factory<InputDevice>> factory) {
RegisterFactory<InputDevice>(name, std::move(factory));
}
inline void RegisterOutputFactory(const std::string& name,
std::shared_ptr<Factory<OutputDevice>> factory) {
RegisterFactory<OutputDevice>(name, std::move(factory));
}
/**
* Unregisters an input device factory.
* @tparam InputDeviceType the type of input devices the factory can create
* @param name the name of the factory to unregister
*/
template <typename InputDeviceType>
void UnregisterFactory(const std::string& name) {
if (Impl::FactoryList<InputDeviceType>::list.erase(name) == 0) {
LOG_ERROR(Input, "Factory '{}' not registered", name);
}
}
inline void UnregisterInputFactory(const std::string& name) {
UnregisterFactory<InputDevice>(name);
}
inline void UnregisterOutputFactory(const std::string& name) {
UnregisterFactory<OutputDevice>(name);
}
/**
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* Create an input device from given parameters.
* @tparam InputDeviceType the type of input devices to create
* @param params a serialized ParamPackage string that contains all parameters for creating the
* device
*/
template <typename InputDeviceType>
std::unique_ptr<InputDeviceType> CreateDeviceFromString(const std::string& params) {
const Common::ParamPackage package(params);
const std::string engine = package.Get("engine", "null");
const auto& factory_list = Impl::FactoryList<InputDeviceType>::list;
const auto pair = factory_list.find(engine);
if (pair == factory_list.end()) {
if (engine != "null") {
LOG_ERROR(Input, "Unknown engine name: {}", engine);
}
return std::make_unique<InputDeviceType>();
}
return pair->second->Create(package);
}
inline std::unique_ptr<InputDevice> CreateInputDeviceFromString(const std::string& params) {
return CreateDeviceFromString<InputDevice>(params);
}
inline std::unique_ptr<OutputDevice> CreateOutputDeviceFromString(const std::string& params) {
return CreateDeviceFromString<OutputDevice>(params);
}
/**
* Create an input device from given parameters.
* @tparam InputDeviceType the type of input devices to create
* @param package A ParamPackage that contains all parameters for creating the device
*/
template <typename InputDeviceType>
std::unique_ptr<InputDeviceType> CreateDevice(const ParamPackage& package) {
const std::string engine = package.Get("engine", "null");
const auto& factory_list = Impl::FactoryList<InputDeviceType>::list;
const auto pair = factory_list.find(engine);
if (pair == factory_list.end()) {
if (engine != "null") {
LOG_ERROR(Input, "Unknown engine name: {}", engine);
}
return std::make_unique<InputDeviceType>();
}
return pair->second->Create(package);
}
inline std::unique_ptr<InputDevice> CreateInputDevice(const ParamPackage& package) {
return CreateDevice<InputDevice>(package);
}
inline std::unique_ptr<OutputDevice> CreateOutputDevice(const ParamPackage& package) {
return CreateDevice<OutputDevice>(package);
}
} // namespace Common::Input