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Add hotplug, rumble and fix 3rd party adapters for the GC adapter

This commit is contained in:
german 2020-10-12 18:11:22 -05:00
parent c20569ebdf
commit 5333db91c1
3 changed files with 440 additions and 310 deletions

View file

@ -21,26 +21,6 @@
namespace GCAdapter { namespace GCAdapter {
// Used to loop through and assign button in poller
constexpr std::array<PadButton, 12> PadButtonArray{
PadButton::PAD_BUTTON_LEFT, PadButton::PAD_BUTTON_RIGHT, PadButton::PAD_BUTTON_DOWN,
PadButton::PAD_BUTTON_UP, PadButton::PAD_TRIGGER_Z, PadButton::PAD_TRIGGER_R,
PadButton::PAD_TRIGGER_L, PadButton::PAD_BUTTON_A, PadButton::PAD_BUTTON_B,
PadButton::PAD_BUTTON_X, PadButton::PAD_BUTTON_Y, PadButton::PAD_BUTTON_START,
};
static void PadToState(const GCPadStatus& pad, GCState& out_state) {
for (const auto& button : PadButtonArray) {
const auto button_key = static_cast<u16>(button);
const auto button_value = (pad.button & button_key) != 0;
out_state.buttons.insert_or_assign(static_cast<s32>(button_key), button_value);
}
for (std::size_t i = 0; i < pad.axis_values.size(); ++i) {
out_state.axes.insert_or_assign(static_cast<u32>(i), pad.axis_values[i]);
}
}
Adapter::Adapter() { Adapter::Adapter() {
if (usb_adapter_handle != nullptr) { if (usb_adapter_handle != nullptr) {
return; return;
@ -49,168 +29,263 @@ Adapter::Adapter() {
const int init_res = libusb_init(&libusb_ctx); const int init_res = libusb_init(&libusb_ctx);
if (init_res == LIBUSB_SUCCESS) { if (init_res == LIBUSB_SUCCESS) {
Setup(); adapter_scan_thread = std::thread(&Adapter::AdapterScanThread, this);
} else { } else {
LOG_ERROR(Input, "libusb could not be initialized. failed with error = {}", init_res); LOG_ERROR(Input, "libusb could not be initialized. failed with error = {}", init_res);
} }
} }
GCPadStatus Adapter::GetPadStatus(std::size_t port, const std::array<u8, 37>& adapter_payload) { Adapter::~Adapter() {
GCPadStatus pad = {}; Reset();
const std::size_t offset = 1 + (9 * port); }
adapter_controllers_status[port] = static_cast<ControllerTypes>(adapter_payload[offset] >> 4); void Adapter::AdapterInputThread() {
LOG_DEBUG(Input, "GC Adapter input thread started");
s32 payload_size{};
AdapterPayload adapter_payload{};
if (adapter_scan_thread.joinable()) {
adapter_scan_thread.join();
}
while (adapter_input_thread_running) {
libusb_interrupt_transfer(usb_adapter_handle, input_endpoint, adapter_payload.data(),
static_cast<s32>(adapter_payload.size()), &payload_size, 16);
if (IsPayloadCorrect(adapter_payload, payload_size)) {
UpdateControllers(adapter_payload);
UpdateVibrations();
}
std::this_thread::yield();
}
if (restart_scan_thread) {
adapter_scan_thread = std::thread(&Adapter::AdapterScanThread, this);
restart_scan_thread = false;
}
}
bool Adapter::IsPayloadCorrect(const AdapterPayload& adapter_payload, s32 payload_size) {
if (payload_size != static_cast<s32>(adapter_payload.size()) ||
adapter_payload[0] != LIBUSB_DT_HID) {
LOG_DEBUG(Input, "Error reading payload (size: {}, type: {:02x})", payload_size,
adapter_payload[0]);
if (input_error_counter++ > 20) {
LOG_ERROR(Input, "GC adapter timeout, Is the adapter connected?");
adapter_input_thread_running = false;
restart_scan_thread = true;
}
return false;
}
input_error_counter = 0;
return true;
}
void Adapter::UpdateControllers(const AdapterPayload& adapter_payload) {
for (std::size_t port = 0; port < pads.size(); ++port) {
const std::size_t offset = 1 + (9 * port);
const auto type = static_cast<ControllerTypes>(adapter_payload[offset] >> 4);
UpdatePadType(port, type);
if (DeviceConnected(port)) {
const u8 b1 = adapter_payload[offset + 1];
const u8 b2 = adapter_payload[offset + 2];
UpdateStateButtons(port, b1, b2);
UpdateStateAxes(port, adapter_payload);
if (configuring) {
UpdateYuzuSettings(port);
}
}
}
}
void Adapter::UpdatePadType(std::size_t port, ControllerTypes pad_type) {
if (pads[port].type == pad_type) {
return;
}
// Device changed reset device and set new type
ResetDevice(port);
pads[port].type = pad_type;
}
void Adapter::UpdateStateButtons(std::size_t port, u8 b1, u8 b2) {
if (port >= pads.size()) {
return;
}
static constexpr std::array<PadButton, 8> b1_buttons{ static constexpr std::array<PadButton, 8> b1_buttons{
PadButton::PAD_BUTTON_A, PadButton::PAD_BUTTON_B, PadButton::PAD_BUTTON_X, PadButton::ButtonA, PadButton::ButtonB, PadButton::ButtonX, PadButton::ButtonY,
PadButton::PAD_BUTTON_Y, PadButton::PAD_BUTTON_LEFT, PadButton::PAD_BUTTON_RIGHT, PadButton::ButtonLeft, PadButton::ButtonRight, PadButton::ButtonDown, PadButton::ButtonUp,
PadButton::PAD_BUTTON_DOWN, PadButton::PAD_BUTTON_UP,
}; };
static constexpr std::array<PadButton, 4> b2_buttons{ static constexpr std::array<PadButton, 4> b2_buttons{
PadButton::PAD_BUTTON_START, PadButton::ButtonStart,
PadButton::PAD_TRIGGER_Z, PadButton::TriggerZ,
PadButton::PAD_TRIGGER_R, PadButton::TriggerR,
PadButton::PAD_TRIGGER_L, PadButton::TriggerL,
}; };
pads[port].buttons = 0;
for (std::size_t i = 0; i < b1_buttons.size(); ++i) {
if ((b1 & (1U << i)) != 0) {
pads[port].buttons =
static_cast<u16>(pads[port].buttons | static_cast<u16>(b1_buttons[i]));
pads[port].last_button = b1_buttons[i];
}
}
for (std::size_t j = 0; j < b2_buttons.size(); ++j) {
if ((b2 & (1U << j)) != 0) {
pads[port].buttons =
static_cast<u16>(pads[port].buttons | static_cast<u16>(b2_buttons[j]));
pads[port].last_button = b2_buttons[j];
}
}
}
void Adapter::UpdateStateAxes(std::size_t port, const AdapterPayload& adapter_payload) {
if (port >= pads.size()) {
return;
}
const std::size_t offset = 1 + (9 * port);
static constexpr std::array<PadAxes, 6> axes{ static constexpr std::array<PadAxes, 6> axes{
PadAxes::StickX, PadAxes::StickY, PadAxes::SubstickX, PadAxes::StickX, PadAxes::StickY, PadAxes::SubstickX,
PadAxes::SubstickY, PadAxes::TriggerLeft, PadAxes::TriggerRight, PadAxes::SubstickY, PadAxes::TriggerLeft, PadAxes::TriggerRight,
}; };
if (adapter_controllers_status[port] == ControllerTypes::None && !get_origin[port]) { for (const PadAxes axis : axes) {
// Controller may have been disconnected, recalibrate if reconnected. const auto index = static_cast<std::size_t>(axis);
get_origin[port] = true; const u8 axis_value = adapter_payload[offset + 3 + index];
if (pads[port].axis_origin[index] == 255) {
pads[port].axis_origin[index] = axis_value;
}
pads[port].axis_values[index] =
static_cast<s16>(axis_value - pads[port].axis_origin[index]);
} }
if (adapter_controllers_status[port] != ControllerTypes::None) {
const u8 b1 = adapter_payload[offset + 1];
const u8 b2 = adapter_payload[offset + 2];
for (std::size_t i = 0; i < b1_buttons.size(); ++i) {
if ((b1 & (1U << i)) != 0) {
pad.button = static_cast<u16>(pad.button | static_cast<u16>(b1_buttons[i]));
}
}
for (std::size_t j = 0; j < b2_buttons.size(); ++j) {
if ((b2 & (1U << j)) != 0) {
pad.button = static_cast<u16>(pad.button | static_cast<u16>(b2_buttons[j]));
}
}
for (PadAxes axis : axes) {
const auto index = static_cast<std::size_t>(axis);
pad.axis_values[index] = adapter_payload[offset + 3 + index];
}
if (get_origin[port]) {
origin_status[port].axis_values = pad.axis_values;
get_origin[port] = false;
}
}
return pad;
} }
void Adapter::Read() { void Adapter::UpdateYuzuSettings(std::size_t port) {
LOG_DEBUG(Input, "GC Adapter Read() thread started"); if (port >= pads.size()) {
return;
}
int payload_size; constexpr u8 axis_threshold = 50;
std::array<u8, 37> adapter_payload; GCPadStatus pad_status = {.port = port};
std::array<GCPadStatus, 4> pads;
while (adapter_thread_running) { if (pads[port].buttons != 0) {
libusb_interrupt_transfer(usb_adapter_handle, input_endpoint, adapter_payload.data(), pad_status.button = pads[port].last_button;
sizeof(adapter_payload), &payload_size, 16); pad_queue.Push(pad_status);
}
if (payload_size != sizeof(adapter_payload) || adapter_payload[0] != LIBUSB_DT_HID) { // Accounting for a threshold here to ensure an intentional press
LOG_ERROR(Input, for (std::size_t i = 0; i < pads[port].axis_values.size(); ++i) {
"Error reading payload (size: {}, type: {:02x}) Is the adapter connected?", const s16 value = pads[port].axis_values[i];
payload_size, adapter_payload[0]);
adapter_thread_running = false; // error reading from adapter, stop reading. if (value > axis_threshold || value < -axis_threshold) {
break; pad_status.axis = static_cast<PadAxes>(i);
pad_status.axis_value = value;
pad_status.axis_threshold = axis_threshold;
pad_queue.Push(pad_status);
} }
for (std::size_t port = 0; port < pads.size(); ++port) { }
pads[port] = GetPadStatus(port, adapter_payload); }
if (DeviceConnected(port) && configuring) {
if (pads[port].button != 0) {
pad_queue[port].Push(pads[port]);
}
// Accounting for a threshold here to ensure an intentional press void Adapter::UpdateVibrations() {
for (size_t i = 0; i < pads[port].axis_values.size(); ++i) { // Use 8 states to keep the switching between on/off fast enough for
const u8 value = pads[port].axis_values[i]; // a human to not notice the difference between switching from on/off
const u8 origin = origin_status[port].axis_values[i]; // More states = more rumble strengths = slower update time
constexpr u8 vibration_states = 8;
if (value > origin + pads[port].THRESHOLD || vibration_counter = (vibration_counter + 1) % vibration_states;
value < origin - pads[port].THRESHOLD) {
pads[port].axis = static_cast<PadAxes>(i); for (GCController& pad : pads) {
pads[port].axis_value = pads[port].axis_values[i]; const bool vibrate = pad.rumble_amplitude > vibration_counter;
pad_queue[port].Push(pads[port]); vibration_changed |= vibrate != pad.enable_vibration;
} pad.enable_vibration = vibrate;
} }
} SendVibrations();
PadToState(pads[port], state[port]); }
void Adapter::SendVibrations() {
if (!rumble_enabled || !vibration_changed) {
return;
}
s32 size{};
constexpr u8 rumble_command = 0x11;
const u8 p1 = pads[0].enable_vibration;
const u8 p2 = pads[1].enable_vibration;
const u8 p3 = pads[2].enable_vibration;
const u8 p4 = pads[3].enable_vibration;
std::array<u8, 5> payload = {rumble_command, p1, p2, p3, p4};
const int err = libusb_interrupt_transfer(usb_adapter_handle, output_endpoint, payload.data(),
static_cast<s32>(payload.size()), &size, 16);
if (err) {
LOG_DEBUG(Input, "Adapter libusb write failed: {}", libusb_error_name(err));
if (output_error_counter++ > 5) {
LOG_ERROR(Input, "GC adapter output timeout, Rumble disabled");
rumble_enabled = false;
} }
std::this_thread::yield(); return;
}
output_error_counter = 0;
vibration_changed = false;
}
bool Adapter::RumblePlay(std::size_t port, f32 amplitude) {
amplitude = std::clamp(amplitude, 0.0f, 1.0f);
const auto raw_amp = static_cast<u8>(amplitude * 0x8);
pads[port].rumble_amplitude = raw_amp;
return rumble_enabled;
}
void Adapter::AdapterScanThread() {
adapter_scan_thread_running = true;
adapter_input_thread_running = false;
if (adapter_input_thread.joinable()) {
adapter_input_thread.join();
}
ClearLibusbHandle();
ResetDevices();
while (adapter_scan_thread_running && !adapter_input_thread_running) {
Setup();
std::this_thread::sleep_for(std::chrono::seconds(1));
} }
} }
void Adapter::Setup() { void Adapter::Setup() {
// Initialize all controllers as unplugged usb_adapter_handle = libusb_open_device_with_vid_pid(libusb_ctx, 0x057e, 0x0337);
adapter_controllers_status.fill(ControllerTypes::None);
// Initialize all ports to store axis origin values
get_origin.fill(true);
// pointer to list of connected usb devices if (usb_adapter_handle == NULL) {
libusb_device** devices{}; return;
}
// populate the list of devices, get the count if (!CheckDeviceAccess()) {
const ssize_t device_count = libusb_get_device_list(libusb_ctx, &devices); ClearLibusbHandle();
if (device_count < 0) {
LOG_ERROR(Input, "libusb_get_device_list failed with error: {}", device_count);
return; return;
} }
if (devices != nullptr) { libusb_device* device = libusb_get_device(usb_adapter_handle);
for (std::size_t index = 0; index < static_cast<std::size_t>(device_count); ++index) {
if (CheckDeviceAccess(devices[index])) { LOG_INFO(Input, "GC adapter is now connected");
// GC Adapter found and accessible, registering it // GC Adapter found and accessible, registering it
GetGCEndpoint(devices[index]); if (GetGCEndpoint(device)) {
break; adapter_scan_thread_running = false;
} adapter_input_thread_running = true;
} rumble_enabled = true;
libusb_free_device_list(devices, 1); input_error_counter = 0;
output_error_counter = 0;
adapter_input_thread = std::thread(&Adapter::AdapterInputThread, this);
} }
} }
bool Adapter::CheckDeviceAccess(libusb_device* device) { bool Adapter::CheckDeviceAccess() {
libusb_device_descriptor desc; // This fixes payload problems from offbrand GCAdapters
const int get_descriptor_error = libusb_get_device_descriptor(device, &desc); const s32 control_transfer_error =
if (get_descriptor_error) { libusb_control_transfer(usb_adapter_handle, 0x21, 11, 0x0001, 0, nullptr, 0, 1000);
// could not acquire the descriptor, no point in trying to use it. if (control_transfer_error < 0) {
LOG_ERROR(Input, "libusb_get_device_descriptor failed with error: {}", LOG_ERROR(Input, "libusb_control_transfer failed with error= {}", control_transfer_error);
get_descriptor_error);
return false;
} }
if (desc.idVendor != 0x057e || desc.idProduct != 0x0337) { s32 kernel_driver_error = libusb_kernel_driver_active(usb_adapter_handle, 0);
// This isn't the device we are looking for.
return false;
}
const int open_error = libusb_open(device, &usb_adapter_handle);
if (open_error == LIBUSB_ERROR_ACCESS) {
LOG_ERROR(Input, "Yuzu can not gain access to this device: ID {:04X}:{:04X}.",
desc.idVendor, desc.idProduct);
return false;
}
if (open_error) {
LOG_ERROR(Input, "libusb_open failed to open device with error = {}", open_error);
return false;
}
int kernel_driver_error = libusb_kernel_driver_active(usb_adapter_handle, 0);
if (kernel_driver_error == 1) { if (kernel_driver_error == 1) {
kernel_driver_error = libusb_detach_kernel_driver(usb_adapter_handle, 0); kernel_driver_error = libusb_detach_kernel_driver(usb_adapter_handle, 0);
if (kernel_driver_error != 0 && kernel_driver_error != LIBUSB_ERROR_NOT_SUPPORTED) { if (kernel_driver_error != 0 && kernel_driver_error != LIBUSB_ERROR_NOT_SUPPORTED) {
@ -236,13 +311,13 @@ bool Adapter::CheckDeviceAccess(libusb_device* device) {
return true; return true;
} }
void Adapter::GetGCEndpoint(libusb_device* device) { bool Adapter::GetGCEndpoint(libusb_device* device) {
libusb_config_descriptor* config = nullptr; libusb_config_descriptor* config = nullptr;
const int config_descriptor_return = libusb_get_config_descriptor(device, 0, &config); const int config_descriptor_return = libusb_get_config_descriptor(device, 0, &config);
if (config_descriptor_return != LIBUSB_SUCCESS) { if (config_descriptor_return != LIBUSB_SUCCESS) {
LOG_ERROR(Input, "libusb_get_config_descriptor failed with error = {}", LOG_ERROR(Input, "libusb_get_config_descriptor failed with error = {}",
config_descriptor_return); config_descriptor_return);
return; return false;
} }
for (u8 ic = 0; ic < config->bNumInterfaces; ic++) { for (u8 ic = 0; ic < config->bNumInterfaces; ic++) {
@ -264,31 +339,51 @@ void Adapter::GetGCEndpoint(libusb_device* device) {
unsigned char clear_payload = 0x13; unsigned char clear_payload = 0x13;
libusb_interrupt_transfer(usb_adapter_handle, output_endpoint, &clear_payload, libusb_interrupt_transfer(usb_adapter_handle, output_endpoint, &clear_payload,
sizeof(clear_payload), nullptr, 16); sizeof(clear_payload), nullptr, 16);
return true;
adapter_thread_running = true;
adapter_input_thread = std::thread(&Adapter::Read, this);
} }
Adapter::~Adapter() { void Adapter::JoinThreads() {
Reset(); restart_scan_thread = false;
} adapter_input_thread_running = false;
adapter_scan_thread_running = false;
void Adapter::Reset() { if (adapter_scan_thread.joinable()) {
if (adapter_thread_running) { adapter_scan_thread.join();
adapter_thread_running = false;
} }
if (adapter_input_thread.joinable()) { if (adapter_input_thread.joinable()) {
adapter_input_thread.join(); adapter_input_thread.join();
} }
}
adapter_controllers_status.fill(ControllerTypes::None); void Adapter::ClearLibusbHandle() {
get_origin.fill(true);
if (usb_adapter_handle) { if (usb_adapter_handle) {
libusb_release_interface(usb_adapter_handle, 1); libusb_release_interface(usb_adapter_handle, 1);
libusb_close(usb_adapter_handle); libusb_close(usb_adapter_handle);
usb_adapter_handle = nullptr; usb_adapter_handle = nullptr;
} }
}
void Adapter::ResetDevices() {
for (std::size_t i = 0; i < pads.size(); ++i) {
ResetDevice(i);
}
}
void Adapter::ResetDevice(std::size_t port) {
pads[port].type = ControllerTypes::None;
pads[port].enable_vibration = false;
pads[port].rumble_amplitude = 0;
pads[port].buttons = 0;
pads[port].last_button = PadButton::Undefined;
pads[port].axis_values.fill(0);
pads[port].axis_origin.fill(255);
}
void Adapter::Reset() {
JoinThreads();
ClearLibusbHandle();
ResetDevices();
if (libusb_ctx) { if (libusb_ctx) {
libusb_exit(libusb_ctx); libusb_exit(libusb_ctx);
@ -297,11 +392,11 @@ void Adapter::Reset() {
std::vector<Common::ParamPackage> Adapter::GetInputDevices() const { std::vector<Common::ParamPackage> Adapter::GetInputDevices() const {
std::vector<Common::ParamPackage> devices; std::vector<Common::ParamPackage> devices;
for (std::size_t port = 0; port < state.size(); ++port) { for (std::size_t port = 0; port < pads.size(); ++port) {
if (!DeviceConnected(port)) { if (!DeviceConnected(port)) {
continue; continue;
} }
std::string name = fmt::format("Gamecube Controller {}", port); std::string name = fmt::format("Gamecube Controller {}", port + 1);
devices.emplace_back(Common::ParamPackage{ devices.emplace_back(Common::ParamPackage{
{"class", "gcpad"}, {"class", "gcpad"},
{"display", std::move(name)}, {"display", std::move(name)},
@ -318,18 +413,18 @@ InputCommon::ButtonMapping Adapter::GetButtonMappingForDevice(
// This list also excludes any button that can't be really mapped // This list also excludes any button that can't be really mapped
static constexpr std::array<std::pair<Settings::NativeButton::Values, PadButton>, 12> static constexpr std::array<std::pair<Settings::NativeButton::Values, PadButton>, 12>
switch_to_gcadapter_button = { switch_to_gcadapter_button = {
std::pair{Settings::NativeButton::A, PadButton::PAD_BUTTON_A}, std::pair{Settings::NativeButton::A, PadButton::ButtonA},
{Settings::NativeButton::B, PadButton::PAD_BUTTON_B}, {Settings::NativeButton::B, PadButton::ButtonB},
{Settings::NativeButton::X, PadButton::PAD_BUTTON_X}, {Settings::NativeButton::X, PadButton::ButtonX},
{Settings::NativeButton::Y, PadButton::PAD_BUTTON_Y}, {Settings::NativeButton::Y, PadButton::ButtonY},
{Settings::NativeButton::Plus, PadButton::PAD_BUTTON_START}, {Settings::NativeButton::Plus, PadButton::ButtonStart},
{Settings::NativeButton::DLeft, PadButton::PAD_BUTTON_LEFT}, {Settings::NativeButton::DLeft, PadButton::ButtonLeft},
{Settings::NativeButton::DUp, PadButton::PAD_BUTTON_UP}, {Settings::NativeButton::DUp, PadButton::ButtonUp},
{Settings::NativeButton::DRight, PadButton::PAD_BUTTON_RIGHT}, {Settings::NativeButton::DRight, PadButton::ButtonRight},
{Settings::NativeButton::DDown, PadButton::PAD_BUTTON_DOWN}, {Settings::NativeButton::DDown, PadButton::ButtonDown},
{Settings::NativeButton::SL, PadButton::PAD_TRIGGER_L}, {Settings::NativeButton::SL, PadButton::TriggerL},
{Settings::NativeButton::SR, PadButton::PAD_TRIGGER_R}, {Settings::NativeButton::SR, PadButton::TriggerR},
{Settings::NativeButton::R, PadButton::PAD_TRIGGER_Z}, {Settings::NativeButton::R, PadButton::TriggerZ},
}; };
if (!params.Has("port")) { if (!params.Has("port")) {
return {}; return {};
@ -352,8 +447,10 @@ InputCommon::ButtonMapping Adapter::GetButtonMappingForDevice(
for (const auto& [switch_button, gcadapter_axis] : switch_to_gcadapter_axis) { for (const auto& [switch_button, gcadapter_axis] : switch_to_gcadapter_axis) {
Common::ParamPackage button_params({{"engine", "gcpad"}}); Common::ParamPackage button_params({{"engine", "gcpad"}});
button_params.Set("port", params.Get("port", 0)); button_params.Set("port", params.Get("port", 0));
button_params.Set("button", static_cast<int>(PadButton::PAD_STICK)); button_params.Set("button", static_cast<s32>(PadButton::Stick));
button_params.Set("axis", static_cast<int>(gcadapter_axis)); button_params.Set("axis", static_cast<s32>(gcadapter_axis));
button_params.Set("threshold", 0.5f);
button_params.Set("direction", "+");
mapping.insert_or_assign(switch_button, std::move(button_params)); mapping.insert_or_assign(switch_button, std::move(button_params));
} }
return mapping; return mapping;
@ -382,46 +479,33 @@ InputCommon::AnalogMapping Adapter::GetAnalogMappingForDevice(
} }
bool Adapter::DeviceConnected(std::size_t port) const { bool Adapter::DeviceConnected(std::size_t port) const {
return adapter_controllers_status[port] != ControllerTypes::None; return pads[port].type != ControllerTypes::None;
}
void Adapter::ResetDeviceType(std::size_t port) {
adapter_controllers_status[port] = ControllerTypes::None;
} }
void Adapter::BeginConfiguration() { void Adapter::BeginConfiguration() {
get_origin.fill(true); pad_queue.Clear();
for (auto& pq : pad_queue) {
pq.Clear();
}
configuring = true; configuring = true;
} }
void Adapter::EndConfiguration() { void Adapter::EndConfiguration() {
for (auto& pq : pad_queue) { pad_queue.Clear();
pq.Clear();
}
configuring = false; configuring = false;
} }
std::array<Common::SPSCQueue<GCPadStatus>, 4>& Adapter::GetPadQueue() { Common::SPSCQueue<GCPadStatus>& Adapter::GetPadQueue() {
return pad_queue; return pad_queue;
} }
const std::array<Common::SPSCQueue<GCPadStatus>, 4>& Adapter::GetPadQueue() const { const Common::SPSCQueue<GCPadStatus>& Adapter::GetPadQueue() const {
return pad_queue; return pad_queue;
} }
std::array<GCState, 4>& Adapter::GetPadState() { GCController& Adapter::GetPadState(std::size_t port) {
return state; return pads.at(port);
} }
const std::array<GCState, 4>& Adapter::GetPadState() const { const GCController& Adapter::GetPadState(std::size_t port) const {
return state; return pads.at(port);
}
int Adapter::GetOriginValue(u32 port, u32 axis) const {
return origin_status[port].axis_values[axis];
} }
} // namespace GCAdapter } // namespace GCAdapter

View file

@ -19,24 +19,23 @@ struct libusb_device_handle;
namespace GCAdapter { namespace GCAdapter {
enum class PadButton { enum class PadButton {
PAD_BUTTON_LEFT = 0x0001, Undefined = 0x0000,
PAD_BUTTON_RIGHT = 0x0002, ButtonLeft = 0x0001,
PAD_BUTTON_DOWN = 0x0004, ButtonRight = 0x0002,
PAD_BUTTON_UP = 0x0008, ButtonDown = 0x0004,
PAD_TRIGGER_Z = 0x0010, ButtonUp = 0x0008,
PAD_TRIGGER_R = 0x0020, TriggerZ = 0x0010,
PAD_TRIGGER_L = 0x0040, TriggerR = 0x0020,
PAD_BUTTON_A = 0x0100, TriggerL = 0x0040,
PAD_BUTTON_B = 0x0200, ButtonA = 0x0100,
PAD_BUTTON_X = 0x0400, ButtonB = 0x0200,
PAD_BUTTON_Y = 0x0800, ButtonX = 0x0400,
PAD_BUTTON_START = 0x1000, ButtonY = 0x0800,
ButtonStart = 0x1000,
// Below is for compatibility with "AxisButton" type // Below is for compatibility with "AxisButton" type
PAD_STICK = 0x2000, Stick = 0x2000,
}; };
extern const std::array<PadButton, 12> PadButtonArray;
enum class PadAxes : u8 { enum class PadAxes : u8 {
StickX, StickX,
StickY, StickY,
@ -47,87 +46,122 @@ enum class PadAxes : u8 {
Undefined, Undefined,
}; };
enum class ControllerTypes {
None,
Wired,
Wireless,
};
struct GCPadStatus { struct GCPadStatus {
u16 button{}; // Or-ed PAD_BUTTON_* and PAD_TRIGGER_* bits std::size_t port{};
std::array<u8, 6> axis_values{}; // Triggers and sticks, following indices defined in PadAxes PadButton button{PadButton::Undefined}; // Or-ed PAD_BUTTON_* and PAD_TRIGGER_* bits
static constexpr u8 THRESHOLD = 50; // Threshold for axis press for polling
u8 port{};
PadAxes axis{PadAxes::Undefined}; PadAxes axis{PadAxes::Undefined};
u8 axis_value{255}; s16 axis_value{};
u8 axis_threshold{50};
}; };
struct GCState { struct GCController {
std::unordered_map<int, bool> buttons; ControllerTypes type{};
std::unordered_map<u32, u16> axes; bool enable_vibration{};
u8 rumble_amplitude{};
u16 buttons{};
PadButton last_button{};
std::array<s16, 6> axis_values{};
std::array<u8, 6> axis_origin{};
}; };
enum class ControllerTypes { None, Wired, Wireless };
class Adapter { class Adapter {
public: public:
/// Initialize the GC Adapter capture and read sequence
Adapter(); Adapter();
/// Close the adapter read thread and release the adapter
~Adapter(); ~Adapter();
/// Request a vibration for a controlelr
bool RumblePlay(std::size_t port, f32 amplitude);
/// Used for polling /// Used for polling
void BeginConfiguration(); void BeginConfiguration();
void EndConfiguration(); void EndConfiguration();
std::vector<Common::ParamPackage> GetInputDevices() const; Common::SPSCQueue<GCPadStatus>& GetPadQueue();
InputCommon::ButtonMapping GetButtonMappingForDevice(const Common::ParamPackage& params) const; const Common::SPSCQueue<GCPadStatus>& GetPadQueue() const;
InputCommon::AnalogMapping GetAnalogMappingForDevice(const Common::ParamPackage& params) const;
GCController& GetPadState(std::size_t port);
const GCController& GetPadState(std::size_t port) const;
/// Returns true if there is a device connected to port /// Returns true if there is a device connected to port
bool DeviceConnected(std::size_t port) const; bool DeviceConnected(std::size_t port) const;
std::array<Common::SPSCQueue<GCPadStatus>, 4>& GetPadQueue(); /// Used for automapping features
const std::array<Common::SPSCQueue<GCPadStatus>, 4>& GetPadQueue() const; std::vector<Common::ParamPackage> GetInputDevices() const;
InputCommon::ButtonMapping GetButtonMappingForDevice(const Common::ParamPackage& params) const;
std::array<GCState, 4>& GetPadState(); InputCommon::AnalogMapping GetAnalogMappingForDevice(const Common::ParamPackage& params) const;
const std::array<GCState, 4>& GetPadState() const;
int GetOriginValue(u32 port, u32 axis) const;
private: private:
GCPadStatus GetPadStatus(std::size_t port, const std::array<u8, 37>& adapter_payload); using AdapterPayload = std::array<u8, 37>;
void Read(); void UpdatePadType(std::size_t port, ControllerTypes pad_type);
void UpdateControllers(const AdapterPayload& adapter_payload);
void UpdateYuzuSettings(std::size_t port);
void UpdateStateButtons(std::size_t port, u8 b1, u8 b2);
void UpdateStateAxes(std::size_t port, const AdapterPayload& adapter_payload);
void UpdateVibrations();
/// Resets status of device connected to port void AdapterInputThread();
void ResetDeviceType(std::size_t port);
/// Returns true if we successfully gain access to GC Adapter void AdapterScanThread();
bool CheckDeviceAccess(libusb_device* device);
/// Captures GC Adapter endpoint address, bool IsPayloadCorrect(const AdapterPayload& adapter_payload, s32 payload_size);
void GetGCEndpoint(libusb_device* device);
/// For shutting down, clear all data, join all threads, release usb // Updates vibration state of all controllers
void Reset(); void SendVibrations();
/// For use in initialization, querying devices to find the adapter /// For use in initialization, querying devices to find the adapter
void Setup(); void Setup();
/// Resets status of all GC controller devices to a disconected state
void ResetDevices();
/// Resets status of device connected to a disconected state
void ResetDevice(std::size_t port);
/// Returns true if we successfully gain access to GC Adapter
bool CheckDeviceAccess();
/// Captures GC Adapter endpoint address
/// Returns true if the endpoind was set correctly
bool GetGCEndpoint(libusb_device* device);
/// For shutting down, clear all data, join all threads, release usb
void Reset();
// Join all threads
void JoinThreads();
// Release usb handles
void ClearLibusbHandle();
libusb_device_handle* usb_adapter_handle = nullptr; libusb_device_handle* usb_adapter_handle = nullptr;
std::array<GCController, 4> pads;
Common::SPSCQueue<GCPadStatus> pad_queue;
std::thread adapter_input_thread; std::thread adapter_input_thread;
bool adapter_thread_running; std::thread adapter_scan_thread;
bool adapter_input_thread_running;
bool adapter_scan_thread_running;
bool restart_scan_thread;
libusb_context* libusb_ctx; libusb_context* libusb_ctx;
u8 input_endpoint = 0; u8 input_endpoint{0};
u8 output_endpoint = 0; u8 output_endpoint{0};
u8 input_error_counter{0};
u8 output_error_counter{0};
int vibration_counter{0};
bool configuring = false; bool configuring{false};
bool rumble_enabled{true};
std::array<GCState, 4> state; bool vibration_changed{true};
std::array<bool, 4> get_origin;
std::array<GCPadStatus, 4> origin_status;
std::array<Common::SPSCQueue<GCPadStatus>, 4> pad_queue;
std::array<ControllerTypes, 4> adapter_controllers_status{};
}; };
} // namespace GCAdapter } // namespace GCAdapter

View file

@ -15,22 +15,30 @@ namespace InputCommon {
class GCButton final : public Input::ButtonDevice { class GCButton final : public Input::ButtonDevice {
public: public:
explicit GCButton(u32 port_, int button_, const GCAdapter::Adapter* adapter) explicit GCButton(u32 port_, s32 button_, GCAdapter::Adapter* adapter)
: port(port_), button(button_), gcadapter(adapter) {} : port(port_), button(button_), gcadapter(adapter) {}
~GCButton() override; ~GCButton() override;
bool GetStatus() const override { bool GetStatus() const override {
if (gcadapter->DeviceConnected(port)) { if (gcadapter->DeviceConnected(port)) {
return gcadapter->GetPadState()[port].buttons.at(button); return (gcadapter->GetPadState(port).buttons & button) != 0;
} }
return false; return false;
} }
bool SetRumblePlay(f32 amp_high, f32 amp_low, f32 freq_high, f32 freq_low) const override {
const float amplitude = amp_high + amp_low > 2.0f ? 1.0f : (amp_high + amp_low) * 0.5f;
const auto new_amp =
static_cast<f32>(pow(amplitude, 0.5f) * (3.0f - 2.0f * pow(amplitude, 0.15f)));
return gcadapter->RumblePlay(port, new_amp);
}
private: private:
const u32 port; const u32 port;
const int button; const s32 button;
const GCAdapter::Adapter* gcadapter; GCAdapter::Adapter* gcadapter;
}; };
class GCAxisButton final : public Input::ButtonDevice { class GCAxisButton final : public Input::ButtonDevice {
@ -38,13 +46,12 @@ public:
explicit GCAxisButton(u32 port_, u32 axis_, float threshold_, bool trigger_if_greater_, explicit GCAxisButton(u32 port_, u32 axis_, float threshold_, bool trigger_if_greater_,
const GCAdapter::Adapter* adapter) const GCAdapter::Adapter* adapter)
: port(port_), axis(axis_), threshold(threshold_), trigger_if_greater(trigger_if_greater_), : port(port_), axis(axis_), threshold(threshold_), trigger_if_greater(trigger_if_greater_),
gcadapter(adapter), gcadapter(adapter) {}
origin_value(static_cast<float>(adapter->GetOriginValue(port_, axis_))) {}
bool GetStatus() const override { bool GetStatus() const override {
if (gcadapter->DeviceConnected(port)) { if (gcadapter->DeviceConnected(port)) {
const float current_axis_value = gcadapter->GetPadState()[port].axes.at(axis); const float current_axis_value = gcadapter->GetPadState(port).axis_values.at(axis);
const float axis_value = (current_axis_value - origin_value) / 128.0f; const float axis_value = current_axis_value / 128.0f;
if (trigger_if_greater) { if (trigger_if_greater) {
// TODO: Might be worthwile to set a slider for the trigger threshold. It is // TODO: Might be worthwile to set a slider for the trigger threshold. It is
// currently always set to 0.5 in configure_input_player.cpp ZL/ZR HandleClick // currently always set to 0.5 in configure_input_player.cpp ZL/ZR HandleClick
@ -61,7 +68,6 @@ private:
float threshold; float threshold;
bool trigger_if_greater; bool trigger_if_greater;
const GCAdapter::Adapter* gcadapter; const GCAdapter::Adapter* gcadapter;
const float origin_value;
}; };
GCButtonFactory::GCButtonFactory(std::shared_ptr<GCAdapter::Adapter> adapter_) GCButtonFactory::GCButtonFactory(std::shared_ptr<GCAdapter::Adapter> adapter_)
@ -73,7 +79,7 @@ std::unique_ptr<Input::ButtonDevice> GCButtonFactory::Create(const Common::Param
const auto button_id = params.Get("button", 0); const auto button_id = params.Get("button", 0);
const auto port = static_cast<u32>(params.Get("port", 0)); const auto port = static_cast<u32>(params.Get("port", 0));
constexpr int PAD_STICK_ID = static_cast<u16>(GCAdapter::PadButton::PAD_STICK); constexpr s32 PAD_STICK_ID = static_cast<s32>(GCAdapter::PadButton::Stick);
// button is not an axis/stick button // button is not an axis/stick button
if (button_id != PAD_STICK_ID) { if (button_id != PAD_STICK_ID) {
@ -106,32 +112,25 @@ Common::ParamPackage GCButtonFactory::GetNextInput() const {
Common::ParamPackage params; Common::ParamPackage params;
GCAdapter::GCPadStatus pad; GCAdapter::GCPadStatus pad;
auto& queue = adapter->GetPadQueue(); auto& queue = adapter->GetPadQueue();
for (std::size_t port = 0; port < queue.size(); ++port) { while (queue.Pop(pad)) {
while (queue[port].Pop(pad)) { // This while loop will break on the earliest detected button
// This while loop will break on the earliest detected button params.Set("engine", "gcpad");
params.Set("engine", "gcpad"); params.Set("port", static_cast<s32>(pad.port));
params.Set("port", static_cast<int>(port)); if (pad.button != GCAdapter::PadButton::Undefined) {
for (const auto& button : GCAdapter::PadButtonArray) { params.Set("button", static_cast<u16>(pad.button));
const u16 button_value = static_cast<u16>(button); }
if (pad.button & button_value) {
params.Set("button", button_value);
break;
}
}
// For Axis button implementation // For Axis button implementation
if (pad.axis != GCAdapter::PadAxes::Undefined) { if (pad.axis != GCAdapter::PadAxes::Undefined) {
params.Set("axis", static_cast<u8>(pad.axis)); params.Set("axis", static_cast<u8>(pad.axis));
params.Set("button", static_cast<u16>(GCAdapter::PadButton::PAD_STICK)); params.Set("button", static_cast<u16>(GCAdapter::PadButton::Stick));
if (pad.axis_value > 128) { params.Set("threshold", "0.25");
params.Set("direction", "+"); if (pad.axis_value > 0) {
params.Set("threshold", "0.25"); params.Set("direction", "+");
} else { } else {
params.Set("direction", "-"); params.Set("direction", "-");
params.Set("threshold", "-0.25");
}
break;
} }
break;
} }
} }
return params; return params;
@ -152,17 +151,14 @@ public:
explicit GCAnalog(u32 port_, u32 axis_x_, u32 axis_y_, float deadzone_, explicit GCAnalog(u32 port_, u32 axis_x_, u32 axis_y_, float deadzone_,
const GCAdapter::Adapter* adapter, float range_) const GCAdapter::Adapter* adapter, float range_)
: port(port_), axis_x(axis_x_), axis_y(axis_y_), deadzone(deadzone_), gcadapter(adapter), : port(port_), axis_x(axis_x_), axis_y(axis_y_), deadzone(deadzone_), gcadapter(adapter),
origin_value_x(static_cast<float>(adapter->GetOriginValue(port_, axis_x_))),
origin_value_y(static_cast<float>(adapter->GetOriginValue(port_, axis_y_))),
range(range_) {} range(range_) {}
float GetAxis(u32 axis) const { float GetAxis(u32 axis) const {
if (gcadapter->DeviceConnected(port)) { if (gcadapter->DeviceConnected(port)) {
std::lock_guard lock{mutex}; std::lock_guard lock{mutex};
const auto origin_value = axis % 2 == 0 ? origin_value_x : origin_value_y;
const auto axis_value = const auto axis_value =
static_cast<float>(gcadapter->GetPadState()[port].axes.at(axis)); static_cast<float>(gcadapter->GetPadState(port).axis_values.at(axis));
return (axis_value - origin_value) / (100.0f * range); return (axis_value) / (100.0f * range);
} }
return 0.0f; return 0.0f;
} }
@ -215,8 +211,6 @@ private:
const u32 axis_y; const u32 axis_y;
const float deadzone; const float deadzone;
const GCAdapter::Adapter* gcadapter; const GCAdapter::Adapter* gcadapter;
const float origin_value_x;
const float origin_value_y;
const float range; const float range;
mutable std::mutex mutex; mutable std::mutex mutex;
}; };
@ -254,26 +248,44 @@ void GCAnalogFactory::EndConfiguration() {
Common::ParamPackage GCAnalogFactory::GetNextInput() { Common::ParamPackage GCAnalogFactory::GetNextInput() {
GCAdapter::GCPadStatus pad; GCAdapter::GCPadStatus pad;
Common::ParamPackage params;
auto& queue = adapter->GetPadQueue(); auto& queue = adapter->GetPadQueue();
for (std::size_t port = 0; port < queue.size(); ++port) { while (queue.Pop(pad)) {
while (queue[port].Pop(pad)) { if (pad.button != GCAdapter::PadButton::Undefined) {
if (pad.axis == GCAdapter::PadAxes::Undefined || params.Set("engine", "gcpad");
std::abs((static_cast<float>(pad.axis_value) - 128.0f) / 128.0f) < 0.1f) { params.Set("port", static_cast<s32>(pad.port));
continue; params.Set("button", static_cast<u16>(pad.button));
} return params;
// An analog device needs two axes, so we need to store the axis for later and wait for }
// a second input event. The axes also must be from the same joystick. if (pad.axis == GCAdapter::PadAxes::Undefined ||
const u8 axis = static_cast<u8>(pad.axis); std::abs(static_cast<float>(pad.axis_value) / 128.0f) < 0.1f) {
if (analog_x_axis == -1) { continue;
analog_x_axis = axis; }
controller_number = static_cast<int>(port); // An analog device needs two axes, so we need to store the axis for later and wait for
} else if (analog_y_axis == -1 && analog_x_axis != axis && // a second input event. The axes also must be from the same joystick.
controller_number == static_cast<int>(port)) { const u8 axis = static_cast<u8>(pad.axis);
analog_y_axis = axis; if (axis == 0 || axis == 1) {
} analog_x_axis = 0;
analog_y_axis = 1;
controller_number = static_cast<s32>(pad.port);
break;
}
if (axis == 2 || axis == 3) {
analog_x_axis = 2;
analog_y_axis = 3;
controller_number = static_cast<s32>(pad.port);
break;
}
if (analog_x_axis == -1) {
analog_x_axis = axis;
controller_number = static_cast<s32>(pad.port);
} else if (analog_y_axis == -1 && analog_x_axis != axis &&
controller_number == static_cast<s32>(pad.port)) {
analog_y_axis = axis;
break;
} }
} }
Common::ParamPackage params;
if (analog_x_axis != -1 && analog_y_axis != -1) { if (analog_x_axis != -1 && analog_y_axis != -1) {
params.Set("engine", "gcpad"); params.Set("engine", "gcpad");
params.Set("port", controller_number); params.Set("port", controller_number);