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nintendo_controller.cc
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nintendo_controller.cc
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// Copyright 2019 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "device/gamepad/nintendo_controller.h"
#include <algorithm>
#include <utility>
#include "base/bind.h"
#include "base/numerics/ranges.h"
#include "base/strings/stringprintf.h"
#include "device/gamepad/gamepad_data_fetcher.h"
#include "device/gamepad/gamepad_id_list.h"
namespace device {
namespace {
// Device IDs for the Switch Charging Grip, also used for composite devices.
const uint16_t kVendorNintendo = 0x057e;
const uint16_t kProductSwitchChargingGrip = 0x200e;
// Maximum output report sizes, used to distinguish USB and Bluetooth.
const size_t kSwitchProMaxOutputReportSizeBytesUsb = 63;
const size_t kSwitchProMaxOutputReportSizeBytesBluetooth = 48;
// Input report size.
const size_t kMaxInputReportSizeBytes = 64;
// Device name for a composite Joy-Con device.
const char kProductNameSwitchCompositeDevice[] = "Joy-Con L+R";
// Report IDs.
const uint8_t kReportIdOutput01 = 0x01;
const uint8_t kReportIdOutput10 = 0x10;
const uint8_t kReportIdInput21 = 0x21;
const uint8_t kReportIdInput30 = 0x30;
const uint8_t kUsbReportIdOutput80 = 0x80;
const uint8_t kUsbReportIdInput81 = 0x81;
// Sub-types of the 0x80 output report, used for initialization.
const uint8_t kSubTypeRequestMac = 0x01;
const uint8_t kSubTypeHandshake = 0x02;
const uint8_t kSubTypeBaudRate = 0x03;
const uint8_t kSubTypeDisableUsbTimeout = 0x04;
const uint8_t kSubTypeEnableUsbTimeout = 0x05;
// UART subcommands.
const uint8_t kSubCommandSetInputReportMode = 0x03;
const uint8_t kSubCommandReadSpi = 0x10;
const uint8_t kSubCommandSetPlayerLights = 0x30;
const uint8_t kSubCommand33 = 0x33;
const uint8_t kSubCommandSetHomeLight = 0x38;
const uint8_t kSubCommandEnableImu = 0x40;
const uint8_t kSubCommandSetImuSensitivity = 0x41;
const uint8_t kSubCommandEnableVibration = 0x48;
// SPI memory regions.
const uint16_t kSpiImuCalibrationAddress = 0x6020;
const size_t kSpiImuCalibrationSize = 24;
const uint16_t kSpiAnalogStickCalibrationAddress = 0x603d;
const size_t kSpiAnalogStickCalibrationSize = 18;
const uint16_t kSpiImuHorizontalOffsetsAddress = 0x6080;
const size_t kSpiImuHorizontalOffsetsSize = 6;
const uint16_t kSpiAnalogStickParametersAddress = 0x6086;
const size_t kSpiAnalogStickParametersSize = 18;
// Byte index for the first byte of subcommand data in 0x80 output reports.
const size_t kSubCommandDataOffset = 11;
// Byte index for the first byte of SPI data in SPI read responses.
const size_t kSpiDataOffset = 20;
// Values for the |device_type| field reported in the MAC reply.
const uint8_t kUsbDeviceTypeChargingGripNoDevice = 0x00;
const uint8_t kUsbDeviceTypeChargingGripJoyConL = 0x01;
const uint8_t kUsbDeviceTypeChargingGripJoyConR = 0x02;
const uint8_t kUsbDeviceTypeProController = 0x03;
// During initialization, the current initialization step will be retried if
// the client does not respond within |kTimeoutDuration|. After |kMaxRetryCount|
// retries, initialization is restarted from the first step.
//
// The timeout duration was chosen through experimentation. A shorter duration
// (~1 second) works for Pro controllers, but Joy-Cons sometimes fail to
// initialize correctly.
const base::TimeDelta kTimeoutDuration =
base::TimeDelta::FromMilliseconds(3000);
const size_t kMaxRetryCount = 3;
const size_t kMaxVibrationEffectDurationMillis = 100;
// Initialization parameters.
const uint8_t kGyroSensitivity2000Dps = 0x03;
const uint8_t kAccelerometerSensitivity8G = 0x00;
const uint8_t kGyroPerformance208Hz = 0x01;
const uint8_t kAccelerometerFilterBandwidth100Hz = 0x01;
const uint8_t kPlayerLightPattern1 = 0x01;
// Parameters for the "strong" and "weak" components of the dual-rumble effect.
const double kVibrationFrequencyStrongRumble = 141.0;
const double kVibrationFrequencyWeakRumble = 182.0;
const double kVibrationAmplitudeStrongRumbleMax = 0.9;
const double kVibrationAmplitudeWeakRumbleMax = 0.1;
const int kVibrationFrequencyHzMin = 41;
const int kVibrationFrequencyHzMax = 1253;
const int kVibrationAmplitudeMax = 1000;
// https://github.com/dekuNukem/Nintendo_Switch_Reverse_Engineering/blob/master/rumble_data_table.md
struct VibrationFrequency {
uint16_t hf;
uint8_t lf;
int freq_hz; // rounded
} kVibrationFrequency[] = {
// The linear resonant actuators (LRAs) on Switch devices are capable of
// producing vibration effects at a wide range of frequencies, but the
// Gamepad API assumes "dual-rumble" style vibration which is typically
// implemented by a pair of eccentric rotating mass (ERM) actuators. To
// simulate "dual-rumble" with Switch LRAs, the strong and weak vibration
// magnitudes are translated into low and high frequency vibration effects.
// Only the frequencies used for this translation are included; unused
// frequencies have been removed.
//
// This list must be kept sorted.
{0x0068, 0x3a, 141},
{0x0098, 0x46, 182}};
const size_t kVibrationFrequencySize = base::size(kVibrationFrequency);
// https://github.com/dekuNukem/Nintendo_Switch_Reverse_Engineering/blob/master/rumble_data_table.md
struct VibrationAmplitude {
uint8_t hfa;
uint16_t lfa;
int amp; // rounded, max 1000 (kVibrationAmplitudeMax)
} kVibrationAmplitude[]{
// Only include safe amplitudes.
{0x00, 0x0040, 0}, {0x02, 0x8040, 10}, {0x04, 0x0041, 12},
{0x06, 0x8041, 14}, {0x08, 0x0042, 17}, {0x0a, 0x8042, 20},
{0x0c, 0x0043, 24}, {0x0e, 0x8043, 28}, {0x10, 0x0044, 33},
{0x12, 0x8044, 40}, {0x14, 0x0045, 47}, {0x16, 0x8045, 56},
{0x18, 0x0046, 67}, {0x1a, 0x8046, 80}, {0x1c, 0x0047, 95},
{0x1e, 0x8047, 112}, {0x20, 0x0048, 117}, {0x22, 0x8048, 123},
{0x24, 0x0049, 128}, {0x26, 0x8049, 134}, {0x28, 0x004a, 140},
{0x2a, 0x804a, 146}, {0x2c, 0x004b, 152}, {0x2e, 0x804b, 159},
{0x30, 0x004c, 166}, {0x32, 0x804c, 173}, {0x34, 0x004d, 181},
{0x36, 0x804d, 189}, {0x38, 0x004e, 198}, {0x3a, 0x804e, 206},
{0x3c, 0x004f, 215}, {0x3e, 0x804f, 225}, {0x40, 0x0050, 230},
{0x42, 0x8050, 235}, {0x44, 0x0051, 240}, {0x46, 0x8051, 245},
{0x48, 0x0052, 251}, {0x4a, 0x8052, 256}, {0x4c, 0x0053, 262},
{0x4e, 0x8053, 268}, {0x50, 0x0054, 273}, {0x52, 0x8054, 279},
{0x54, 0x0055, 286}, {0x56, 0x8055, 292}, {0x58, 0x0056, 298},
{0x5a, 0x8056, 305}, {0x5c, 0x0057, 311}, {0x5e, 0x8057, 318},
{0x60, 0x0058, 325}, {0x62, 0x8058, 332}, {0x64, 0x0059, 340},
{0x66, 0x8059, 347}, {0x68, 0x005a, 355}, {0x6a, 0x805a, 362},
{0x6c, 0x005b, 370}, {0x6e, 0x805b, 378}, {0x70, 0x005c, 387},
{0x72, 0x805c, 395}, {0x74, 0x005d, 404}, {0x76, 0x805d, 413},
{0x78, 0x005e, 422}, {0x7a, 0x805e, 431}, {0x7c, 0x005f, 440},
{0x7e, 0x805f, 450}, {0x80, 0x0060, 460}, {0x82, 0x8060, 470},
{0x84, 0x0061, 480}, {0x86, 0x8061, 491}, {0x88, 0x0062, 501},
{0x8a, 0x8062, 512}, {0x8c, 0x0063, 524}, {0x8e, 0x8063, 535},
{0x90, 0x0064, 547}, {0x92, 0x8064, 559}, {0x94, 0x0065, 571},
{0x96, 0x8065, 584}, {0x98, 0x0066, 596}, {0x9a, 0x8066, 609},
{0x9c, 0x0067, 623}, {0x9e, 0x8067, 636}, {0xa0, 0x0068, 650},
{0xa2, 0x8068, 665}, {0xa4, 0x0069, 679}, {0xa6, 0x8069, 694},
{0xa8, 0x006a, 709}, {0xaa, 0x806a, 725}, {0xac, 0x006b, 741},
{0xae, 0x806b, 757}, {0xb0, 0x006c, 773}, {0xb2, 0x806c, 790},
{0xb4, 0x006d, 808}, {0xb6, 0x806d, 825}, {0xb8, 0x006e, 843},
{0xba, 0x806e, 862}, {0xbc, 0x006f, 881}, {0xbe, 0x806f, 900},
{0xc0, 0x0070, 920}, {0xc2, 0x8070, 940}, {0xc4, 0x0071, 960},
{0xc6, 0x8071, 981}, {0xc8, 0x0072, 1000},
};
const size_t kVibrationAmplitudeSize = base::size(kVibrationAmplitude);
// Define indices for the additional buttons on Switch controllers.
enum SWITCH_BUTTON_INDICES {
SWITCH_BUTTON_INDEX_CAPTURE = BUTTON_INDEX_META + 1,
SWITCH_BUTTON_INDEX_LEFT_SL,
SWITCH_BUTTON_INDEX_LEFT_SR,
SWITCH_BUTTON_INDEX_RIGHT_SL,
SWITCH_BUTTON_INDEX_RIGHT_SR,
SWITCH_BUTTON_INDEX_COUNT
};
// Input reports with ID 0x81 are replies to commands sent during the
// initialization sequence.
#pragma pack(push, 1)
struct UsbInputReport81 {
uint8_t subtype;
uint8_t data[kMaxInputReportSizeBytes - 2];
};
#pragma pack(pop)
static_assert(sizeof(UsbInputReport81) == kMaxInputReportSizeBytes - 1,
"UsbInputReport81 has incorrect size");
// When connected over USB, the initialization sequence includes a step to
// request the MAC address. The MAC is returned in an input report with ID 0x81
// and subtype 0x01.
#pragma pack(push, 1)
struct MacAddressReport {
uint8_t subtype; // 0x01
uint8_t padding;
uint8_t device_type;
uint8_t mac_data[6];
uint8_t padding2[kMaxInputReportSizeBytes - 10];
};
#pragma pack(pop)
static_assert(sizeof(MacAddressReport) == kMaxInputReportSizeBytes - 1,
"MacAddressReport has incorrect size");
// When configured for standard full input report mode, controller data is
// reported at regular intervals. The data format is the same for all Switch
// devices, although some buttons are not present on all devices.
#pragma pack(push, 1)
struct ControllerData {
uint8_t timestamp;
uint8_t battery_level : 4;
uint8_t connection_info : 4;
bool button_y : 1;
bool button_x : 1;
bool button_b : 1;
bool button_a : 1;
bool button_right_sr : 1;
bool button_right_sl : 1;
bool button_r : 1;
bool button_zr : 1;
bool button_minus : 1;
bool button_plus : 1;
bool button_thumb_r : 1;
bool button_thumb_l : 1;
bool button_home : 1;
bool button_capture : 1;
uint8_t dummy : 1;
bool charging_grip : 1;
bool dpad_down : 1;
bool dpad_up : 1;
bool dpad_right : 1;
bool dpad_left : 1;
bool button_left_sr : 1;
bool button_left_sl : 1;
bool button_l : 1;
bool button_zl : 1;
uint8_t analog[6];
uint8_t vibrator_input_report;
};
#pragma pack(pop)
static_assert(sizeof(ControllerData) == 12,
"ControllerData has incorrect size");
// In standard full input report mode, controller data is reported with IMU data
// in reports with ID 0x30.
#pragma pack(push, 1)
struct ControllerDataReport {
ControllerData controller_data; // 12 bytes
uint8_t imu_data[36];
uint8_t padding[kMaxInputReportSizeBytes - 49];
};
#pragma pack(pop)
static_assert(sizeof(ControllerDataReport) == kMaxInputReportSizeBytes - 1,
"ControllerDataReport has incorrect size");
// Responses to SPI read requests are sent in reports with ID 0x21. These
// reports also include controller data.
#pragma pack(push, 1)
struct SpiReadReport {
ControllerData controller_data; // 12 bytes
uint8_t subcommand_ack; // 0x90
uint8_t subcommand; // 0x10
uint8_t addrl;
uint8_t addrh;
uint8_t padding[2]; // 0x00 0x00
uint8_t length;
uint8_t spi_data[kMaxInputReportSizeBytes - kSpiDataOffset];
};
#pragma pack(pop)
static_assert(sizeof(SpiReadReport) == kMaxInputReportSizeBytes - 1,
"SpiReadReport has incorrect size");
// Unpack two packed 12-bit values.
void UnpackShorts(uint8_t byte0,
uint8_t byte1,
uint8_t byte2,
uint16_t* short1,
uint16_t* short2) {
DCHECK(short1);
DCHECK(short2);
*short1 = ((byte1 << 8) & 0x0f00) | byte0;
*short2 = (byte2 << 4) | (byte1 >> 4);
}
// Unpack a 6-byte MAC address.
uint64_t UnpackSwitchMacAddress(const uint8_t* data) {
DCHECK(data);
uint64_t acc = data[5];
acc = (acc << 8) | data[4];
acc = (acc << 8) | data[3];
acc = (acc << 8) | data[2];
acc = (acc << 8) | data[1];
acc = (acc << 8) | data[0];
return acc;
}
// Unpack the analog stick parameters into |cal|.
void UnpackSwitchAnalogStickParameters(
const uint8_t* data,
NintendoController::SwitchCalibrationData& cal) {
DCHECK(data);
// Only fetch the dead zone and range ratio. The other parameters are unknown.
UnpackShorts(data[3], data[4], data[5], &cal.dead_zone, &cal.range_ratio);
}
// Unpack the IMU calibration data into |cal|
void UnpackSwitchImuCalibration(
const uint8_t* data,
NintendoController::SwitchCalibrationData& cal) {
DCHECK(data);
// 24 bytes, as 4 groups of 3 16-bit little-endian values.
cal.accelerometer_origin_x = (data[1] << 8) | data[0];
cal.accelerometer_origin_y = (data[3] << 8) | data[2];
cal.accelerometer_origin_z = (data[5] << 8) | data[4];
cal.accelerometer_sensitivity_x = (data[7] << 8) | data[6];
cal.accelerometer_sensitivity_y = (data[9] << 8) | data[8];
cal.accelerometer_sensitivity_z = (data[11] << 8) | data[10];
cal.gyro_origin_x = (data[13] << 8) | data[12];
cal.gyro_origin_y = (data[15] << 8) | data[14];
cal.gyro_origin_z = (data[17] << 8) | data[16];
cal.gyro_sensitivity_x = (data[19] << 8) | data[18];
cal.gyro_sensitivity_y = (data[21] << 8) | data[20];
cal.gyro_sensitivity_z = (data[23] << 8) | data[22];
}
// Unpack the IMU horizontal offsets into |cal|.
void UnpackSwitchImuHorizontalOffsets(
const uint8_t* data,
NintendoController::SwitchCalibrationData& cal) {
DCHECK(data);
// 6 bytes, as 3 16-bit little-endian values.
cal.horizontal_offset_x = (data[1] << 8) | data[0];
cal.horizontal_offset_y = (data[3] << 8) | data[2];
cal.horizontal_offset_z = (data[5] << 8) | data[4];
}
// Unpack the analog stick calibration data into |cal|.
void UnpackSwitchAnalogStickCalibration(
const uint8_t* data,
NintendoController::SwitchCalibrationData& cal) {
DCHECK(data);
// 18 bytes, as 2 groups of 6 packed 12-bit values.
UnpackShorts(data[0], data[1], data[2], &cal.lx_max, &cal.ly_max);
UnpackShorts(data[3], data[4], data[5], &cal.lx_center, &cal.ly_center);
UnpackShorts(data[6], data[7], data[8], &cal.lx_min, &cal.ly_min);
UnpackShorts(data[9], data[10], data[11], &cal.rx_center, &cal.ry_center);
UnpackShorts(data[12], data[13], data[14], &cal.rx_min, &cal.ry_min);
UnpackShorts(data[15], data[16], data[17], &cal.rx_max, &cal.ry_max);
cal.lx_min = cal.lx_center - cal.lx_min;
cal.lx_max = cal.lx_center + cal.lx_max;
cal.ly_min = cal.ly_center - cal.ly_min;
cal.ly_max = cal.ly_center + cal.ly_max;
cal.rx_min = cal.rx_center - cal.rx_min;
cal.rx_max = cal.rx_center + cal.rx_max;
cal.ry_min = cal.ry_center - cal.ry_min;
cal.ry_max = cal.ry_center + cal.ry_max;
}
// Unpack one frame of IMU data into |imu_data|.
void UnpackSwitchImuData(const uint8_t* data,
NintendoController::SwitchImuData* imu_data) {
DCHECK(data);
DCHECK(imu_data);
// 12 bytes of IMU data containing 6 16-bit little-endian values.
imu_data->accelerometer_x = (data[1] << 8) | data[0];
imu_data->accelerometer_y = (data[3] << 8) | data[2];
imu_data->accelerometer_z = (data[5] << 8) | data[4];
imu_data->gyro_x = (data[7] << 8) | data[6];
imu_data->gyro_y = (data[9] << 8) | data[8];
imu_data->gyro_z = (data[11] << 8) | data[10];
}
// Given joystick input |x|,|y|, apply a radial deadzone with radius
// |dead_zone| centered at |x_center|,|y_center|. If the input is within the
// dead zone region, the value is snapped to the center of the dead zone.
bool ApplyDeadZone(uint16_t& x,
uint16_t& y,
uint16_t x_center,
uint16_t y_center,
uint16_t dead_zone) {
int dx = x - x_center;
int dy = y - y_center;
if (dx * dx + dy * dy < dead_zone * dead_zone) {
x = x_center;
y = y_center;
return true;
}
return false;
}
// Normalize |value| to the range [|min|,|max|]. If |value| is outside this
// range, clamp it.
double NormalizeAndClampAxis(int value, int min, int max) {
if (value <= min)
return -1.0;
if (value >= max)
return 1.0;
return (2.0 * (value - min) / static_cast<double>(max - min)) - 1.0;
}
// Update the button and axis state in |pad| with the new controller data in
// |data|, using the calibration data |cal|. Returns true if the new data
// differs from the previous data.
bool UpdateGamepadFromControllerData(
const ControllerData& data,
const NintendoController::SwitchCalibrationData& cal,
Gamepad& pad) {
bool buttons_changed =
pad.buttons_length != SWITCH_BUTTON_INDEX_COUNT ||
pad.buttons[BUTTON_INDEX_PRIMARY].pressed != data.button_b ||
pad.buttons[BUTTON_INDEX_SECONDARY].pressed != data.button_a ||
pad.buttons[BUTTON_INDEX_TERTIARY].pressed != data.button_y ||
pad.buttons[BUTTON_INDEX_QUATERNARY].pressed != data.button_x ||
pad.buttons[BUTTON_INDEX_LEFT_SHOULDER].pressed != data.button_l ||
pad.buttons[BUTTON_INDEX_RIGHT_SHOULDER].pressed != data.button_r ||
pad.buttons[BUTTON_INDEX_LEFT_TRIGGER].pressed != data.button_zl ||
pad.buttons[BUTTON_INDEX_RIGHT_TRIGGER].pressed != data.button_zr ||
pad.buttons[BUTTON_INDEX_BACK_SELECT].pressed != data.button_minus ||
pad.buttons[BUTTON_INDEX_START].pressed != data.button_plus ||
pad.buttons[BUTTON_INDEX_LEFT_THUMBSTICK].pressed !=
data.button_thumb_l ||
pad.buttons[BUTTON_INDEX_RIGHT_THUMBSTICK].pressed !=
data.button_thumb_r ||
pad.buttons[BUTTON_INDEX_DPAD_UP].pressed != data.dpad_up ||
pad.buttons[BUTTON_INDEX_DPAD_DOWN].pressed != data.dpad_down ||
pad.buttons[BUTTON_INDEX_DPAD_LEFT].pressed != data.dpad_left ||
pad.buttons[BUTTON_INDEX_DPAD_RIGHT].pressed != data.dpad_right ||
pad.buttons[BUTTON_INDEX_META].pressed != data.button_home ||
pad.buttons[SWITCH_BUTTON_INDEX_CAPTURE].pressed != data.button_capture ||
pad.buttons[SWITCH_BUTTON_INDEX_LEFT_SL].pressed != data.button_left_sl ||
pad.buttons[SWITCH_BUTTON_INDEX_LEFT_SR].pressed != data.button_left_sr ||
pad.buttons[SWITCH_BUTTON_INDEX_RIGHT_SL].pressed !=
data.button_right_sl ||
pad.buttons[SWITCH_BUTTON_INDEX_RIGHT_SR].pressed != data.button_right_sr;
if (buttons_changed) {
pad.buttons_length = SWITCH_BUTTON_INDEX_COUNT;
pad.buttons[BUTTON_INDEX_PRIMARY].pressed = data.button_b;
pad.buttons[BUTTON_INDEX_PRIMARY].value = data.button_b ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_SECONDARY].pressed = data.button_a;
pad.buttons[BUTTON_INDEX_SECONDARY].value = data.button_a ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_TERTIARY].pressed = data.button_y;
pad.buttons[BUTTON_INDEX_TERTIARY].value = data.button_y ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_QUATERNARY].pressed = data.button_x;
pad.buttons[BUTTON_INDEX_QUATERNARY].value = data.button_x ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_LEFT_SHOULDER].pressed = data.button_l;
pad.buttons[BUTTON_INDEX_LEFT_SHOULDER].value = data.button_l ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_RIGHT_SHOULDER].pressed = data.button_r;
pad.buttons[BUTTON_INDEX_RIGHT_SHOULDER].value = data.button_r ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_LEFT_TRIGGER].pressed = data.button_zl;
pad.buttons[BUTTON_INDEX_LEFT_TRIGGER].value = data.button_zl ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_RIGHT_TRIGGER].pressed = data.button_zr;
pad.buttons[BUTTON_INDEX_RIGHT_TRIGGER].value = data.button_zr ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_BACK_SELECT].pressed = data.button_minus;
pad.buttons[BUTTON_INDEX_BACK_SELECT].value = data.button_minus ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_START].pressed = data.button_plus;
pad.buttons[BUTTON_INDEX_START].value = data.button_plus ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_LEFT_THUMBSTICK].pressed = data.button_thumb_l;
pad.buttons[BUTTON_INDEX_LEFT_THUMBSTICK].value =
data.button_thumb_l ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_RIGHT_THUMBSTICK].pressed = data.button_thumb_r;
pad.buttons[BUTTON_INDEX_RIGHT_THUMBSTICK].value =
data.button_thumb_r ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_DPAD_UP].pressed = data.dpad_up;
pad.buttons[BUTTON_INDEX_DPAD_UP].value = data.dpad_up ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_DPAD_DOWN].pressed = data.dpad_down;
pad.buttons[BUTTON_INDEX_DPAD_DOWN].value = data.dpad_down ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_DPAD_LEFT].pressed = data.dpad_left;
pad.buttons[BUTTON_INDEX_DPAD_LEFT].value = data.dpad_left ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_DPAD_RIGHT].pressed = data.dpad_right;
pad.buttons[BUTTON_INDEX_DPAD_RIGHT].value = data.dpad_right ? 1.0 : 0.0;
pad.buttons[BUTTON_INDEX_META].pressed = data.button_home;
pad.buttons[BUTTON_INDEX_META].value = data.button_home ? 1.0 : 0.0;
pad.buttons[SWITCH_BUTTON_INDEX_CAPTURE].pressed = data.button_capture;
pad.buttons[SWITCH_BUTTON_INDEX_CAPTURE].value =
data.button_capture ? 1.0 : 0.0;
pad.buttons[SWITCH_BUTTON_INDEX_LEFT_SL].pressed = data.button_left_sl;
pad.buttons[SWITCH_BUTTON_INDEX_LEFT_SL].value =
data.button_left_sl ? 1.0 : 0.0;
pad.buttons[SWITCH_BUTTON_INDEX_LEFT_SR].pressed = data.button_left_sr;
pad.buttons[SWITCH_BUTTON_INDEX_LEFT_SR].value =
data.button_left_sr ? 1.0 : 0.0;
pad.buttons[SWITCH_BUTTON_INDEX_RIGHT_SL].pressed = data.button_right_sl;
pad.buttons[SWITCH_BUTTON_INDEX_RIGHT_SL].value =
data.button_right_sl ? 1.0 : 0.0;
pad.buttons[SWITCH_BUTTON_INDEX_RIGHT_SR].pressed = data.button_right_sr;
pad.buttons[SWITCH_BUTTON_INDEX_RIGHT_SR].value =
data.button_right_sr ? 1.0 : 0.0;
}
uint16_t axis_lx;
uint16_t axis_ly;
uint16_t axis_rx;
uint16_t axis_ry;
UnpackShorts(data.analog[0], data.analog[1], data.analog[2], &axis_lx,
&axis_ly);
UnpackShorts(data.analog[3], data.analog[4], data.analog[5], &axis_rx,
&axis_ry);
// Apply a radial dead zone to both sticks.
bool ldead = ApplyDeadZone(axis_lx, axis_ly, cal.lx_center, cal.ly_center,
cal.dead_zone);
bool rdead = ApplyDeadZone(axis_rx, axis_ry, cal.rx_center, cal.ry_center,
cal.dead_zone);
// Normalize using calibration data.
double lx =
ldead ? 0.0 : NormalizeAndClampAxis(axis_lx, cal.lx_min, cal.lx_max);
double ly =
ldead ? 0.0 : -NormalizeAndClampAxis(axis_ly, cal.ly_min, cal.ly_max);
double rx =
rdead ? 0.0 : NormalizeAndClampAxis(axis_rx, cal.rx_min, cal.rx_max);
double ry =
rdead ? 0.0 : -NormalizeAndClampAxis(axis_ry, cal.ry_min, cal.ry_max);
bool axes_changed = pad.axes_length != AXIS_INDEX_COUNT ||
pad.axes[device::AXIS_INDEX_LEFT_STICK_X] != lx ||
pad.axes[device::AXIS_INDEX_LEFT_STICK_Y] != ly ||
pad.axes[device::AXIS_INDEX_RIGHT_STICK_X] != rx ||
pad.axes[device::AXIS_INDEX_RIGHT_STICK_Y] != ry;
if (axes_changed) {
pad.axes_length = AXIS_INDEX_COUNT;
pad.axes[device::AXIS_INDEX_LEFT_STICK_X] = lx;
pad.axes[device::AXIS_INDEX_LEFT_STICK_Y] = ly;
pad.axes[device::AXIS_INDEX_RIGHT_STICK_X] = rx;
pad.axes[device::AXIS_INDEX_RIGHT_STICK_Y] = ry;
}
return buttons_changed || axes_changed;
}
// Update the state for a single button. The button state is taken from
// the button at index |button_index| in |src_pad|. If this is a composite
// device, |src_pad| holds the state for the left component. If |horizontal| is
// true, the button index is remapped for horizontal orientation before updating
// the state in |dst_pad|.
void UpdateButtonForLeftSide(const Gamepad& src_pad,
Gamepad& dst_pad,
size_t button_index,
bool horizontal) {
size_t remapped_index = button_index;
// The internal button mapping assumes a docked orientation for Joy-Cons. If
// a Joy-Con is used by itself, remap the buttons so they match the Standard
// Gamepad spec when held horizontally.
if (horizontal) {
switch (button_index) {
// Map the D-pad buttons to action buttons.
case BUTTON_INDEX_DPAD_LEFT:
remapped_index = BUTTON_INDEX_PRIMARY;
break;
case BUTTON_INDEX_DPAD_DOWN:
remapped_index = BUTTON_INDEX_SECONDARY;
break;
case BUTTON_INDEX_DPAD_UP:
remapped_index = BUTTON_INDEX_TERTIARY;
break;
case BUTTON_INDEX_DPAD_RIGHT:
remapped_index = BUTTON_INDEX_QUATERNARY;
break;
// Map L to Select.
case BUTTON_INDEX_LEFT_SHOULDER:
remapped_index = BUTTON_INDEX_BACK_SELECT;
break;
// Map Minus to Start.
case BUTTON_INDEX_BACK_SELECT:
remapped_index = BUTTON_INDEX_START;
break;
// Map Capture to Meta.
case SWITCH_BUTTON_INDEX_CAPTURE:
remapped_index = BUTTON_INDEX_META;
break;
// Map SL and SR to the left and right shoulders.
case SWITCH_BUTTON_INDEX_LEFT_SL:
remapped_index = BUTTON_INDEX_LEFT_SHOULDER;
break;
case SWITCH_BUTTON_INDEX_LEFT_SR:
remapped_index = BUTTON_INDEX_RIGHT_SHOULDER;
break;
// ZL and the left thumbstick are unmodified.
case BUTTON_INDEX_LEFT_TRIGGER:
case BUTTON_INDEX_LEFT_THUMBSTICK:
break;
default:
NOTREACHED();
break;
}
}
dst_pad.buttons[remapped_index] = src_pad.buttons[button_index];
}
// Update the state for a single button. The button state is taken from
// the button at index |button_index| in |src_pad|. If this is a composite
// device, |src_pad| holds the state for the right component. If |horizontal| is
// true, the button index is remapped for horizontal orientation before updating
// the state in |dst_pad|.
void UpdateButtonForRightSide(const Gamepad& src_pad,
Gamepad& dst_pad,
size_t button_index,
bool horizontal) {
size_t remapped_index = button_index;
// The internal button mapping assumes a docked orientation for Joy-Cons. If
// a Joy-Con is used by itself, remap the buttons so they match the Standard
// Gamepad spec when held horizontally.
if (horizontal) {
switch (button_index) {
// Re-map the action buttons to rotate them.
case BUTTON_INDEX_PRIMARY:
remapped_index = BUTTON_INDEX_TERTIARY;
break;
case BUTTON_INDEX_TERTIARY:
remapped_index = BUTTON_INDEX_QUATERNARY;
break;
case BUTTON_INDEX_QUATERNARY:
remapped_index = BUTTON_INDEX_SECONDARY;
break;
case BUTTON_INDEX_SECONDARY:
remapped_index = BUTTON_INDEX_PRIMARY;
break;
// Map R to Select.
case BUTTON_INDEX_RIGHT_SHOULDER:
remapped_index = BUTTON_INDEX_BACK_SELECT;
break;
// Map SL and SR to the left and right shoulders.
case SWITCH_BUTTON_INDEX_RIGHT_SL:
remapped_index = BUTTON_INDEX_LEFT_SHOULDER;
break;
case SWITCH_BUTTON_INDEX_RIGHT_SR:
remapped_index = BUTTON_INDEX_RIGHT_SHOULDER;
break;
// Map right thumbstick button to left thumbstick button.
case BUTTON_INDEX_RIGHT_THUMBSTICK:
remapped_index = BUTTON_INDEX_LEFT_THUMBSTICK;
break;
// The Plus, Home, and ZR buttons are unmodified.
case BUTTON_INDEX_START:
case BUTTON_INDEX_META:
case BUTTON_INDEX_RIGHT_TRIGGER:
break;
default:
NOTREACHED();
break;
}
}
dst_pad.buttons[remapped_index] = src_pad.buttons[button_index];
}
// Update the state for a single axis. The axis state is taken from the axis at
// index |axis_index| in |src_pad|. If this is a composite device, |src_pad|
// holds the state for the left component. If |horizontal| is true, the axis
// index and value are remapped for horizontal orientation before updating the
// state in |dst_pad|.
void UpdateAxisForLeftSide(const Gamepad& src_pad,
Gamepad& dst_pad,
size_t axis_index,
bool horizontal) {
size_t remapped_index = axis_index;
double axis_value = src_pad.axes[axis_index];
// The internal axis values assume a docked orientation for Joy-Cons. If a
// Joy-Con is used by itself, remap the axis indices and adjust the sign on
// the axis value for a horizontal orientation.
if (horizontal) {
switch (axis_index) {
case AXIS_INDEX_LEFT_STICK_X:
// Map +X to -Y.
axis_value = -axis_value;
remapped_index = AXIS_INDEX_LEFT_STICK_Y;
break;
case AXIS_INDEX_LEFT_STICK_Y:
// Map +Y to +X.
remapped_index = AXIS_INDEX_LEFT_STICK_X;
break;
default:
NOTREACHED();
break;
}
}
dst_pad.axes[remapped_index] = axis_value;
}
// Update the state for a single axis. The axis state is taken from the axis at
// index |axis_index| in |src_pad|. If this is a composite device, |src_pad|
// holds the state for the right component. If |horizontal| is true, the axis
// index and value are remapped for horizontal orientation before updating the
// state in |dst_pad|.
void UpdateAxisForRightSide(const Gamepad& src_pad,
Gamepad& dst_pad,
size_t axis_index,
bool horizontal) {
size_t remapped_index = axis_index;
double axis_value = src_pad.axes[axis_index];
// The internal axis values assume a docked orientation for Joy-Cons. If a
// Joy-Con is used by itself, remap the axis indices and adjust the sign on
// the axis value for a horizontal orientation.
if (horizontal) {
switch (axis_index) {
case AXIS_INDEX_RIGHT_STICK_X:
// Map +X to +Y.
remapped_index = AXIS_INDEX_LEFT_STICK_Y;
break;
case AXIS_INDEX_RIGHT_STICK_Y:
// Map +Y to -X.
axis_value = -axis_value;
remapped_index = AXIS_INDEX_LEFT_STICK_X;
break;
default:
NOTREACHED();
break;
}
}
dst_pad.axes[remapped_index] = axis_value;
}
// Convert the vibration parameters |frequency| and |amplitude| into a set of
// parameters that can be sent to the vibration actuator.
void FrequencyToHex(float frequency,
float amplitude,
uint16_t* hf,
uint8_t* lf,
uint8_t* hf_amp,
uint16_t* lf_amp) {
int freq = static_cast<int>(frequency);
int amp = static_cast<int>(amplitude * kVibrationAmplitudeMax);
// Clamp the target frequency and amplitude to a safe range.
freq = base::ClampToRange(freq, kVibrationFrequencyHzMin,
kVibrationFrequencyHzMax);
amp = base::ClampToRange(amp, 0, kVibrationAmplitudeMax);
const auto* best_vf = &kVibrationFrequency[0];
for (size_t i = 1; i < kVibrationFrequencySize; ++i) {
const auto* vf = &kVibrationFrequency[i];
if (vf->freq_hz < freq) {
best_vf = vf;
} else {
// The candidate frequency is higher than the target frequency. Check if
// it is closer than the current best.
int vf_error_above = vf->freq_hz - freq;
int best_vf_error_below = freq - best_vf->freq_hz;
if (vf_error_above < best_vf_error_below)
best_vf = vf;
break;
}
}
const auto* best_va = &kVibrationAmplitude[0];
for (size_t i = 0; i < kVibrationAmplitudeSize; ++i) {
const auto* va = &kVibrationAmplitude[i];
if (va->amp < amp) {
best_va = va;
} else {
// The candidate amplitude is higher than the target amplitude. Check if
// it is closer than the current best.
int va_error_above = va->amp - amp;
int best_va_error_below = amp - best_va->amp;
if (va_error_above < best_va_error_below)
best_va = va;
break;
}
}
DCHECK(best_vf);
DCHECK(best_va);
*hf = best_vf->hf;
*lf = best_vf->lf;
*hf_amp = best_va->hfa;
*lf_amp = best_va->lfa;
}
// Return the bus type of the Switch device described by |device_info|. This is
// needed for Windows which does not report the bus type in the HID API.
GamepadBusType BusTypeFromDeviceInfo(const mojom::HidDeviceInfo* device_info) {
DCHECK(device_info);
// If the |device_info| indicates the device is connected over Bluetooth, it's
// probably right. On some platforms the bus type is reported as USB
// regardless of the actual connection.
if (device_info->bus_type == mojom::HidBusType::kHIDBusTypeBluetooth)
return GAMEPAD_BUS_BLUETOOTH;
auto gamepad_id = GamepadIdList::Get().GetGamepadId(device_info->vendor_id,
device_info->product_id);
switch (gamepad_id) {
case GamepadId::kNintendoProduct2009:
// The Switch Pro Controller may be connected over USB or Bluetooth.
// Determine which connection is in use by comparing the max output report
// size against known values.
switch (device_info->max_output_report_size) {
case kSwitchProMaxOutputReportSizeBytesUsb:
return GAMEPAD_BUS_USB;
case kSwitchProMaxOutputReportSizeBytesBluetooth:
return GAMEPAD_BUS_BLUETOOTH;
default:
break;
}
break;
case GamepadId::kNintendoProduct200e:
// The Charging Grip can only be connected over USB.
return GAMEPAD_BUS_USB;
case GamepadId::kNintendoProduct2006:
case GamepadId::kNintendoProduct2007:
// Joy Cons can only be connected over Bluetooth. When connected through
// a Charging Grip, the grip's ID is reported instead.
return GAMEPAD_BUS_BLUETOOTH;
default:
break;
}
NOTREACHED();
return GAMEPAD_BUS_UNKNOWN;
}
} // namespace
NintendoController::SwitchCalibrationData::SwitchCalibrationData() = default;
NintendoController::SwitchCalibrationData::~SwitchCalibrationData() = default;
NintendoController::SwitchImuData::SwitchImuData() = default;
NintendoController::SwitchImuData::~SwitchImuData() = default;
NintendoController::NintendoController(int source_id,
mojom::HidDeviceInfoPtr device_info,
mojom::HidManager* hid_manager)
: source_id_(source_id),
is_composite_(false),
bus_type_(GAMEPAD_BUS_UNKNOWN),
output_report_size_bytes_(0),
device_info_(std::move(device_info)),
hid_manager_(hid_manager) {
if (device_info_) {
bus_type_ = BusTypeFromDeviceInfo(device_info_.get());
output_report_size_bytes_ = device_info_->max_output_report_size;
gamepad_id_ = GamepadIdList::Get().GetGamepadId(device_info_->vendor_id,
device_info_->product_id);
} else {
gamepad_id_ = GamepadId::kUnknownGamepad;
}
}
NintendoController::NintendoController(
int source_id,
std::unique_ptr<NintendoController> composite1,
std::unique_ptr<NintendoController> composite2,
mojom::HidManager* hid_manager)
: source_id_(source_id), is_composite_(true), hid_manager_(hid_manager) {
// Require exactly one left component and one right component, but allow them
// to be provided in either order.
DCHECK(composite1);
DCHECK(composite2);
composite_left_ = std::move(composite1);
composite_right_ = std::move(composite2);
if (composite_left_->GetGamepadHand() != GamepadHand::kLeft)
composite_left_.swap(composite_right_);
DCHECK_EQ(composite_left_->GetGamepadHand(), GamepadHand::kLeft);
DCHECK_EQ(composite_right_->GetGamepadHand(), GamepadHand::kRight);
DCHECK_EQ(composite_left_->GetBusType(), composite_right_->GetBusType());
bus_type_ = composite_left_->GetBusType();
}
NintendoController::~NintendoController() = default;
// static
std::unique_ptr<NintendoController> NintendoController::Create(
int source_id,
mojom::HidDeviceInfoPtr device_info,
mojom::HidManager* hid_manager) {
return std::make_unique<NintendoController>(source_id, std::move(device_info),
hid_manager);
}
// static
std::unique_ptr<NintendoController> NintendoController::CreateComposite(
int source_id,
std::unique_ptr<NintendoController> composite1,
std::unique_ptr<NintendoController> composite2,
mojom::HidManager* hid_manager) {
return std::make_unique<NintendoController>(
source_id, std::move(composite1), std::move(composite2), hid_manager);
}
// static
bool NintendoController::IsNintendoController(uint16_t vendor_id,
uint16_t product_id) {
auto gamepad_id = GamepadIdList::Get().GetGamepadId(vendor_id, product_id);
switch (gamepad_id) {
case GamepadId::kNintendoProduct2006:
case GamepadId::kNintendoProduct2007:
case GamepadId::kNintendoProduct2009:
case GamepadId::kNintendoProduct200e:
return true;
default:
break;
}
return false;
}
std::vector<std::unique_ptr<NintendoController>>
NintendoController::Decompose() {
// Stop any ongoing vibration effects before decomposing the device.
SetZeroVibration();
std::vector<std::unique_ptr<NintendoController>> decomposed_devices;
if (composite_left_)
decomposed_devices.push_back(std::move(composite_left_));
if (composite_right_)
decomposed_devices.push_back(std::move(composite_right_));
return decomposed_devices;
}
void NintendoController::Open(base::OnceClosure device_ready_closure) {
device_ready_closure_ = std::move(device_ready_closure);
if (is_composite_) {
StartInitSequence();
} else {
uint16_t vendor_id = device_info_->vendor_id;
uint16_t product_id = device_info_->product_id;
if (IsNintendoController(vendor_id, product_id)) {
Connect(base::BindOnce(&NintendoController::OnConnect,
weak_factory_.GetWeakPtr()));
}
}
}
GamepadHand NintendoController::GetGamepadHand() const {
if (is_composite_)
return GamepadHand::kNone;
switch (gamepad_id_) {
case GamepadId::kNintendoProduct2009:
// Switch Pro is held in both hands.
return GamepadHand::kNone;
case GamepadId::kNintendoProduct2006:
// Joy-Con L is held in the left hand.
return GamepadHand::kLeft;
case GamepadId::kNintendoProduct2007:
// Joy-Con R is held in the right hand.
return GamepadHand::kRight;
case GamepadId::kNintendoProduct200e:
// Refer to |usb_device_type_| to determine the handedness of Joy-Cons
// connected to a Charging Grip.
if (state_ == kInitialized) {
switch (usb_device_type_) {
case kUsbDeviceTypeChargingGripJoyConL:
return GamepadHand::kLeft;
case kUsbDeviceTypeChargingGripJoyConR:
return GamepadHand::kRight;
case kUsbDeviceTypeChargingGripNoDevice:
case kUsbDeviceTypeProController:
return GamepadHand::kNone;
default:
break;
}
} else {
return GamepadHand::kNone;
}
break;
default:
break;
}
NOTREACHED();
return GamepadHand::kNone;
}
bool NintendoController::IsUsable() const {
if (state_ != kInitialized)
return false;
if (is_composite_)
return composite_left_ && composite_right_;
switch (gamepad_id_) {
case GamepadId::kNintendoProduct2009:
case GamepadId::kNintendoProduct2006:
case GamepadId::kNintendoProduct2007:
return true;
case GamepadId::kNintendoProduct200e:
// Only usable as a composite device.
return false;
default:
break;
}
NOTREACHED();
return false;
}
bool NintendoController::HasGuid(const std::string& guid) const {
if (is_composite_) {
DCHECK(composite_left_);
DCHECK(composite_right_);
return composite_left_->HasGuid(guid) || composite_right_->HasGuid(guid);
}
return device_info_->guid == guid;
}
GamepadStandardMappingFunction NintendoController::GetMappingFunction() const {
if (is_composite_) {
// In composite mode, we use the same mapping as the Charging Grip.
return GetGamepadStandardMappingFunction(
kVendorNintendo, kProductSwitchChargingGrip,
/*hid_specification_version=*/0, /*version_number=*/0, bus_type_);
} else {
return GetGamepadStandardMappingFunction(
device_info_->vendor_id, device_info_->product_id,
/*hid_specification_version=*/0, /*version_number=*/0, bus_type_);
}
}
void NintendoController::InitializeGamepadState(bool has_standard_mapping,
Gamepad& pad) const {
pad.buttons_length = SWITCH_BUTTON_INDEX_COUNT;
pad.axes_length = device::AXIS_INDEX_COUNT;
pad.vibration_actuator.type = GamepadHapticActuatorType::kDualRumble;