input_common: joycon: Remove magic numbers from calibration protocol

This commit is contained in:
Narr the Reg 2023-01-27 13:12:54 -06:00
parent e54d08fc1f
commit 8647c72778
6 changed files with 203 additions and 108 deletions

View File

@ -13,34 +13,34 @@ CalibrationProtocol::CalibrationProtocol(std::shared_ptr<JoyconHandle> handle)
DriverResult CalibrationProtocol::GetLeftJoyStickCalibration(JoyStickCalibration& calibration) { DriverResult CalibrationProtocol::GetLeftJoyStickCalibration(JoyStickCalibration& calibration) {
ScopedSetBlocking sb(this); ScopedSetBlocking sb(this);
std::vector<u8> buffer;
DriverResult result{DriverResult::Success}; DriverResult result{DriverResult::Success};
JoystickLeftSpiCalibration spi_calibration{};
bool has_user_calibration = false;
calibration = {}; calibration = {};
result = ReadSPI(CalAddr::USER_LEFT_MAGIC, sizeof(u16), buffer);
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
const bool has_user_calibration = buffer[0] == 0xB2 && buffer[1] == 0xA1; result = HasUserCalibration(SpiAddress::USER_LEFT_MAGIC, has_user_calibration);
if (has_user_calibration) {
result = ReadSPI(CalAddr::USER_LEFT_DATA, 9, buffer);
} else {
result = ReadSPI(CalAddr::FACT_LEFT_DATA, 9, buffer);
} }
// Read User defined calibration
if (result == DriverResult::Success && has_user_calibration) {
result = ReadSPI(SpiAddress::USER_LEFT_DATA, spi_calibration);
}
// Read Factory calibration
if (result == DriverResult::Success && !has_user_calibration) {
result = ReadSPI(SpiAddress::FACT_LEFT_DATA, spi_calibration);
} }
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
calibration.x.max = static_cast<u16>(((buffer[1] & 0x0F) << 8) | buffer[0]); calibration.x.center = GetXAxisCalibrationValue(spi_calibration.center);
calibration.y.max = static_cast<u16>((buffer[2] << 4) | (buffer[1] >> 4)); calibration.y.center = GetYAxisCalibrationValue(spi_calibration.center);
calibration.x.center = static_cast<u16>(((buffer[4] & 0x0F) << 8) | buffer[3]); calibration.x.min = GetXAxisCalibrationValue(spi_calibration.min);
calibration.y.center = static_cast<u16>((buffer[5] << 4) | (buffer[4] >> 4)); calibration.y.min = GetYAxisCalibrationValue(spi_calibration.min);
calibration.x.min = static_cast<u16>(((buffer[7] & 0x0F) << 8) | buffer[6]); calibration.x.max = GetXAxisCalibrationValue(spi_calibration.max);
calibration.y.min = static_cast<u16>((buffer[8] << 4) | (buffer[7] >> 4)); calibration.y.max = GetYAxisCalibrationValue(spi_calibration.max);
} }
// Nintendo fix for drifting stick
// result = ReadSPI(0x60, 0x86 ,buffer, 16);
// calibration.deadzone = (u16)((buffer[4] << 8) & 0xF00 | buffer[3]);
// Set a valid default calibration if data is missing // Set a valid default calibration if data is missing
ValidateCalibration(calibration); ValidateCalibration(calibration);
@ -49,34 +49,34 @@ DriverResult CalibrationProtocol::GetLeftJoyStickCalibration(JoyStickCalibration
DriverResult CalibrationProtocol::GetRightJoyStickCalibration(JoyStickCalibration& calibration) { DriverResult CalibrationProtocol::GetRightJoyStickCalibration(JoyStickCalibration& calibration) {
ScopedSetBlocking sb(this); ScopedSetBlocking sb(this);
std::vector<u8> buffer;
DriverResult result{DriverResult::Success}; DriverResult result{DriverResult::Success};
JoystickRightSpiCalibration spi_calibration{};
bool has_user_calibration = false;
calibration = {}; calibration = {};
result = ReadSPI(CalAddr::USER_RIGHT_MAGIC, sizeof(u16), buffer);
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
const bool has_user_calibration = buffer[0] == 0xB2 && buffer[1] == 0xA1; result = HasUserCalibration(SpiAddress::USER_RIGHT_MAGIC, has_user_calibration);
if (has_user_calibration) {
result = ReadSPI(CalAddr::USER_RIGHT_DATA, 9, buffer);
} else {
result = ReadSPI(CalAddr::FACT_RIGHT_DATA, 9, buffer);
} }
// Read User defined calibration
if (result == DriverResult::Success && has_user_calibration) {
result = ReadSPI(SpiAddress::USER_RIGHT_DATA, spi_calibration);
}
// Read Factory calibration
if (result == DriverResult::Success && !has_user_calibration) {
result = ReadSPI(SpiAddress::FACT_RIGHT_DATA, spi_calibration);
} }
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
calibration.x.center = static_cast<u16>(((buffer[1] & 0x0F) << 8) | buffer[0]); calibration.x.center = GetXAxisCalibrationValue(spi_calibration.center);
calibration.y.center = static_cast<u16>((buffer[2] << 4) | (buffer[1] >> 4)); calibration.y.center = GetYAxisCalibrationValue(spi_calibration.center);
calibration.x.min = static_cast<u16>(((buffer[4] & 0x0F) << 8) | buffer[3]); calibration.x.min = GetXAxisCalibrationValue(spi_calibration.min);
calibration.y.min = static_cast<u16>((buffer[5] << 4) | (buffer[4] >> 4)); calibration.y.min = GetYAxisCalibrationValue(spi_calibration.min);
calibration.x.max = static_cast<u16>(((buffer[7] & 0x0F) << 8) | buffer[6]); calibration.x.max = GetXAxisCalibrationValue(spi_calibration.max);
calibration.y.max = static_cast<u16>((buffer[8] << 4) | (buffer[7] >> 4)); calibration.y.max = GetYAxisCalibrationValue(spi_calibration.max);
} }
// Nintendo fix for drifting stick
// buffer = ReadSPI(0x60, 0x98 , 16);
// joystick.deadzone = (u16)((buffer[4] << 8) & 0xF00 | buffer[3]);
// Set a valid default calibration if data is missing // Set a valid default calibration if data is missing
ValidateCalibration(calibration); ValidateCalibration(calibration);
@ -85,39 +85,41 @@ DriverResult CalibrationProtocol::GetRightJoyStickCalibration(JoyStickCalibratio
DriverResult CalibrationProtocol::GetImuCalibration(MotionCalibration& calibration) { DriverResult CalibrationProtocol::GetImuCalibration(MotionCalibration& calibration) {
ScopedSetBlocking sb(this); ScopedSetBlocking sb(this);
std::vector<u8> buffer;
DriverResult result{DriverResult::Success}; DriverResult result{DriverResult::Success};
ImuSpiCalibration spi_calibration{};
bool has_user_calibration = false;
calibration = {}; calibration = {};
result = ReadSPI(CalAddr::USER_IMU_MAGIC, sizeof(u16), buffer);
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
const bool has_user_calibration = buffer[0] == 0xB2 && buffer[1] == 0xA1; result = HasUserCalibration(SpiAddress::USER_IMU_MAGIC, has_user_calibration);
if (has_user_calibration) {
result = ReadSPI(CalAddr::USER_IMU_DATA, sizeof(IMUCalibration), buffer);
} else {
result = ReadSPI(CalAddr::FACT_IMU_DATA, sizeof(IMUCalibration), buffer);
} }
// Read User defined calibration
if (result == DriverResult::Success && has_user_calibration) {
result = ReadSPI(SpiAddress::USER_IMU_DATA, spi_calibration);
}
// Read Factory calibration
if (result == DriverResult::Success && !has_user_calibration) {
result = ReadSPI(SpiAddress::FACT_IMU_DATA, spi_calibration);
} }
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
IMUCalibration device_calibration{}; calibration.accelerometer[0].offset = spi_calibration.accelerometer_offset[0];
memcpy(&device_calibration, buffer.data(), sizeof(IMUCalibration)); calibration.accelerometer[1].offset = spi_calibration.accelerometer_offset[1];
calibration.accelerometer[0].offset = device_calibration.accelerometer_offset[0]; calibration.accelerometer[2].offset = spi_calibration.accelerometer_offset[2];
calibration.accelerometer[1].offset = device_calibration.accelerometer_offset[1];
calibration.accelerometer[2].offset = device_calibration.accelerometer_offset[2];
calibration.accelerometer[0].scale = device_calibration.accelerometer_scale[0]; calibration.accelerometer[0].scale = spi_calibration.accelerometer_scale[0];
calibration.accelerometer[1].scale = device_calibration.accelerometer_scale[1]; calibration.accelerometer[1].scale = spi_calibration.accelerometer_scale[1];
calibration.accelerometer[2].scale = device_calibration.accelerometer_scale[2]; calibration.accelerometer[2].scale = spi_calibration.accelerometer_scale[2];
calibration.gyro[0].offset = device_calibration.gyroscope_offset[0]; calibration.gyro[0].offset = spi_calibration.gyroscope_offset[0];
calibration.gyro[1].offset = device_calibration.gyroscope_offset[1]; calibration.gyro[1].offset = spi_calibration.gyroscope_offset[1];
calibration.gyro[2].offset = device_calibration.gyroscope_offset[2]; calibration.gyro[2].offset = spi_calibration.gyroscope_offset[2];
calibration.gyro[0].scale = device_calibration.gyroscope_scale[0]; calibration.gyro[0].scale = spi_calibration.gyroscope_scale[0];
calibration.gyro[1].scale = device_calibration.gyroscope_scale[1]; calibration.gyro[1].scale = spi_calibration.gyroscope_scale[1];
calibration.gyro[2].scale = device_calibration.gyroscope_scale[2]; calibration.gyro[2].scale = spi_calibration.gyroscope_scale[2];
} }
ValidateCalibration(calibration); ValidateCalibration(calibration);
@ -127,10 +129,12 @@ DriverResult CalibrationProtocol::GetImuCalibration(MotionCalibration& calibrati
DriverResult CalibrationProtocol::GetRingCalibration(RingCalibration& calibration, DriverResult CalibrationProtocol::GetRingCalibration(RingCalibration& calibration,
s16 current_value) { s16 current_value) {
constexpr s16 DefaultRingRange{800};
// TODO: Get default calibration form ring itself // TODO: Get default calibration form ring itself
if (ring_data_max == 0 && ring_data_min == 0) { if (ring_data_max == 0 && ring_data_min == 0) {
ring_data_max = current_value + 800; ring_data_max = current_value + DefaultRingRange;
ring_data_min = current_value - 800; ring_data_min = current_value - DefaultRingRange;
ring_data_default = current_value; ring_data_default = current_value;
} }
ring_data_max = std::max(ring_data_max, current_value); ring_data_max = std::max(ring_data_max, current_value);
@ -143,42 +147,72 @@ DriverResult CalibrationProtocol::GetRingCalibration(RingCalibration& calibratio
return DriverResult::Success; return DriverResult::Success;
} }
DriverResult CalibrationProtocol::HasUserCalibration(SpiAddress address,
bool& has_user_calibration) {
MagicSpiCalibration spi_magic{};
const DriverResult result{ReadSPI(address, spi_magic)};
has_user_calibration = false;
if (result == DriverResult::Success) {
has_user_calibration = spi_magic.first == CalibrationMagic::USR_MAGIC_0 &&
spi_magic.second == CalibrationMagic::USR_MAGIC_1;
}
return result;
}
u16 CalibrationProtocol::GetXAxisCalibrationValue(std::span<u8> block) const {
return static_cast<u16>(((block[1] & 0x0F) << 8) | block[0]);
}
u16 CalibrationProtocol::GetYAxisCalibrationValue(std::span<u8> block) const {
return static_cast<u16>((block[2] << 4) | (block[1] >> 4));
}
void CalibrationProtocol::ValidateCalibration(JoyStickCalibration& calibration) { void CalibrationProtocol::ValidateCalibration(JoyStickCalibration& calibration) {
constexpr u16 DefaultStickCenter{2048}; constexpr u16 DefaultStickCenter{0x800};
constexpr u16 DefaultStickRange{1740}; constexpr u16 DefaultStickRange{0x6cc};
if (calibration.x.center == 0xFFF || calibration.x.center == 0) { calibration.x.center = ValidateValue(calibration.x.center, DefaultStickCenter);
calibration.x.center = DefaultStickCenter; calibration.x.max = ValidateValue(calibration.x.max, DefaultStickRange);
} calibration.x.min = ValidateValue(calibration.x.min, DefaultStickRange);
if (calibration.x.max == 0xFFF || calibration.x.max == 0) {
calibration.x.max = DefaultStickRange;
}
if (calibration.x.min == 0xFFF || calibration.x.min == 0) {
calibration.x.min = DefaultStickRange;
}
if (calibration.y.center == 0xFFF || calibration.y.center == 0) { calibration.y.center = ValidateValue(calibration.y.center, DefaultStickCenter);
calibration.y.center = DefaultStickCenter; calibration.y.max = ValidateValue(calibration.y.max, DefaultStickRange);
} calibration.y.min = ValidateValue(calibration.y.min, DefaultStickRange);
if (calibration.y.max == 0xFFF || calibration.y.max == 0) {
calibration.y.max = DefaultStickRange;
}
if (calibration.y.min == 0xFFF || calibration.y.min == 0) {
calibration.y.min = DefaultStickRange;
}
} }
void CalibrationProtocol::ValidateCalibration(MotionCalibration& calibration) { void CalibrationProtocol::ValidateCalibration(MotionCalibration& calibration) {
constexpr s16 DefaultAccelerometerScale{0x4000};
constexpr s16 DefaultGyroScale{0x3be7};
constexpr s16 DefaultOffset{0};
for (auto& sensor : calibration.accelerometer) { for (auto& sensor : calibration.accelerometer) {
if (sensor.scale == 0) { sensor.scale = ValidateValue(sensor.scale, DefaultAccelerometerScale);
sensor.scale = 0x4000; sensor.offset = ValidateValue(sensor.offset, DefaultOffset);
}
} }
for (auto& sensor : calibration.gyro) { for (auto& sensor : calibration.gyro) {
if (sensor.scale == 0) { sensor.scale = ValidateValue(sensor.scale, DefaultGyroScale);
sensor.scale = 0x3be7; sensor.offset = ValidateValue(sensor.offset, DefaultOffset);
}
} }
} }
u16 CalibrationProtocol::ValidateValue(u16 value, u16 default_value) const {
if (value == 0) {
return default_value;
}
if (value == 0xFFF) {
return default_value;
}
return value;
}
s16 CalibrationProtocol::ValidateValue(s16 value, s16 default_value) const {
if (value == 0) {
return default_value;
}
if (value == 0xFFF) {
return default_value;
}
return value;
}
} // namespace InputCommon::Joycon } // namespace InputCommon::Joycon

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@ -53,9 +53,27 @@ public:
DriverResult GetRingCalibration(RingCalibration& calibration, s16 current_value); DriverResult GetRingCalibration(RingCalibration& calibration, s16 current_value);
private: private:
/// Returns true if the specified address corresponds to the magic value of user calibration
DriverResult HasUserCalibration(SpiAddress address, bool& has_user_calibration);
/// Converts a raw calibration block to an u16 value containing the x axis value
u16 GetXAxisCalibrationValue(std::span<u8> block) const;
/// Converts a raw calibration block to an u16 value containing the y axis value
u16 GetYAxisCalibrationValue(std::span<u8> block) const;
/// Ensures that all joystick calibration values are set
void ValidateCalibration(JoyStickCalibration& calibration); void ValidateCalibration(JoyStickCalibration& calibration);
/// Ensures that all motion calibration values are set
void ValidateCalibration(MotionCalibration& calibration); void ValidateCalibration(MotionCalibration& calibration);
/// Returns the default value if the value is either zero or 0xFFF
u16 ValidateValue(u16 value, u16 default_value) const;
/// Returns the default value if the value is either zero or 0xFFF
s16 ValidateValue(s16 value, s16 default_value) const;
s16 ring_data_max = 0; s16 ring_data_max = 0;
s16 ring_data_default = 0; s16 ring_data_default = 0;
s16 ring_data_min = 0; s16 ring_data_min = 0;

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@ -23,7 +23,7 @@ void JoyconCommonProtocol::SetNonBlocking() {
DriverResult JoyconCommonProtocol::GetDeviceType(ControllerType& controller_type) { DriverResult JoyconCommonProtocol::GetDeviceType(ControllerType& controller_type) {
std::vector<u8> buffer; std::vector<u8> buffer;
const auto result = ReadSPI(CalAddr::DEVICE_TYPE, 1, buffer); const auto result = ReadSPI(SpiAddress::DEVICE_TYPE, 1, buffer);
controller_type = ControllerType::None; controller_type = ControllerType::None;
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
@ -148,7 +148,7 @@ DriverResult JoyconCommonProtocol::SendVibrationReport(std::span<const u8> buffe
return SendData(local_buffer); return SendData(local_buffer);
} }
DriverResult JoyconCommonProtocol::ReadSPI(CalAddr addr, u8 size, std::vector<u8>& output) { DriverResult JoyconCommonProtocol::ReadSPI(SpiAddress addr, u8 size, std::vector<u8>& output) {
constexpr std::size_t MaxTries = 10; constexpr std::size_t MaxTries = 10;
std::size_t tries = 0; std::size_t tries = 0;
std::array<u8, 5> buffer = {0x00, 0x00, 0x00, 0x00, size}; std::array<u8, 5> buffer = {0x00, 0x00, 0x00, 0x00, size};

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@ -100,7 +100,26 @@ public:
* @param size in bytes to be read * @param size in bytes to be read
* @returns output buffer containing the responce * @returns output buffer containing the responce
*/ */
DriverResult ReadSPI(CalAddr addr, u8 size, std::vector<u8>& output); DriverResult ReadSPI(SpiAddress addr, u8 size, std::vector<u8>& output);
template <typename Output>
requires(std::is_trivially_copyable_v<Output>)
DriverResult ReadSPI(SpiAddress addr, Output& output) {
std::vector<u8> buffer;
output = {};
const auto result = ReadSPI(addr, sizeof(Output), buffer);
if (result != DriverResult::Success) {
return result;
}
if (buffer.size() != sizeof(Output)) {
return DriverResult::WrongReply;
}
std::memcpy(&output, buffer.data(), sizeof(Output));
return DriverResult::Success;
}
/** /**
* Enables MCU chip on the joycon * Enables MCU chip on the joycon

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@ -72,7 +72,7 @@ DriverResult GenericProtocol::GetBattery(u32& battery_level) {
DriverResult GenericProtocol::GetColor(Color& color) { DriverResult GenericProtocol::GetColor(Color& color) {
ScopedSetBlocking sb(this); ScopedSetBlocking sb(this);
std::vector<u8> buffer; std::vector<u8> buffer;
const auto result = ReadSPI(CalAddr::COLOR_DATA, 12, buffer); const auto result = ReadSPI(SpiAddress::COLOR_DATA, 12, buffer);
color = {}; color = {};
if (result == DriverResult::Success) { if (result == DriverResult::Success) {
@ -88,7 +88,7 @@ DriverResult GenericProtocol::GetColor(Color& color) {
DriverResult GenericProtocol::GetSerialNumber(SerialNumber& serial_number) { DriverResult GenericProtocol::GetSerialNumber(SerialNumber& serial_number) {
ScopedSetBlocking sb(this); ScopedSetBlocking sb(this);
std::vector<u8> buffer; std::vector<u8> buffer;
const auto result = ReadSPI(CalAddr::SERIAL_NUMBER, 16, buffer); const auto result = ReadSPI(SpiAddress::SERIAL_NUMBER, 16, buffer);
serial_number = {}; serial_number = {};
if (result == DriverResult::Success) { if (result == DriverResult::Success) {

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@ -159,13 +159,12 @@ enum class UsbSubCommand : u8 {
SEND_UART = 0x92, SEND_UART = 0x92,
}; };
enum class CalMagic : u8 { enum class CalibrationMagic : u8 {
USR_MAGIC_0 = 0xB2, USR_MAGIC_0 = 0xB2,
USR_MAGIC_1 = 0xA1, USR_MAGIC_1 = 0xA1,
USRR_MAGI_SIZE = 2,
}; };
enum class CalAddr { enum class SpiAddress {
SERIAL_NUMBER = 0X6000, SERIAL_NUMBER = 0X6000,
DEVICE_TYPE = 0X6012, DEVICE_TYPE = 0X6012,
COLOR_EXIST = 0X601B, COLOR_EXIST = 0X601B,
@ -396,10 +395,35 @@ struct MotionData {
u64 delta_timestamp{}; u64 delta_timestamp{};
}; };
// Output from SPI read command containing user calibration magic
struct MagicSpiCalibration {
CalibrationMagic first;
CalibrationMagic second;
};
static_assert(sizeof(MagicSpiCalibration) == 0x2, "MagicSpiCalibration is an invalid size");
// Output from SPI read command containing left joystick calibration
struct JoystickLeftSpiCalibration {
std::array<u8, 3> max;
std::array<u8, 3> center;
std::array<u8, 3> min;
};
static_assert(sizeof(JoystickLeftSpiCalibration) == 0x9,
"JoystickLeftSpiCalibration is an invalid size");
// Output from SPI read command containing right joystick calibration
struct JoystickRightSpiCalibration {
std::array<u8, 3> center;
std::array<u8, 3> min;
std::array<u8, 3> max;
};
static_assert(sizeof(JoystickRightSpiCalibration) == 0x9,
"JoystickRightSpiCalibration is an invalid size");
struct JoyStickAxisCalibration { struct JoyStickAxisCalibration {
u16 max{1}; u16 max;
u16 min{1}; u16 min;
u16 center{0}; u16 center;
}; };
struct JoyStickCalibration { struct JoyStickCalibration {
@ -407,6 +431,14 @@ struct JoyStickCalibration {
JoyStickAxisCalibration y; JoyStickAxisCalibration y;
}; };
struct ImuSpiCalibration {
std::array<s16, 3> accelerometer_offset;
std::array<s16, 3> accelerometer_scale;
std::array<s16, 3> gyroscope_offset;
std::array<s16, 3> gyroscope_scale;
};
static_assert(sizeof(ImuSpiCalibration) == 0x18, "ImuSpiCalibration is an invalid size");
struct RingCalibration { struct RingCalibration {
s16 default_value; s16 default_value;
s16 max_value; s16 max_value;
@ -488,14 +520,6 @@ struct InputReportNfcIr {
static_assert(sizeof(InputReportNfcIr) == 0x29, "InputReportNfcIr is an invalid size"); static_assert(sizeof(InputReportNfcIr) == 0x29, "InputReportNfcIr is an invalid size");
#pragma pack(pop) #pragma pack(pop)
struct IMUCalibration {
std::array<s16, 3> accelerometer_offset;
std::array<s16, 3> accelerometer_scale;
std::array<s16, 3> gyroscope_offset;
std::array<s16, 3> gyroscope_scale;
};
static_assert(sizeof(IMUCalibration) == 0x18, "IMUCalibration is an invalid size");
struct NFCReadBlock { struct NFCReadBlock {
u8 start; u8 start;
u8 end; u8 end;