/*global $, SERVO_DATA, PID_names, ADJUSTMENT_RANGES, RXFAIL_CONFIG, SERVO_CONFIG*/ 'use strict'; var mspHelper = (function (gui) { var self = {}; self.BAUD_RATES_post1_6_3 = [ 'AUTO', '1200', '2400', '4800', '9600', '19200', '38400', '57600', '115200', '230400', '250000', '460800', '921600' ]; self.BAUD_RATES_pre1_6_3 = [ 'AUTO', '9600', '19200', '38400', '57600', '115200', '230400', '250000' ]; self.SERIAL_PORT_FUNCTIONS = { 'MSP': 0, 'GPS': 1, 'TELEMETRY_FRSKY': 2, 'TELEMETRY_HOTT': 3, 'TELEMETRY_LTM': 4, // LTM replaced MSP 'TELEMETRY_SMARTPORT': 5, 'RX_SERIAL': 6, 'BLACKBOX': 7, 'TELEMETRY_MAVLINK': 8, 'TELEMETRY_IBUS': 9, 'RUNCAM_DEVICE_CONTROL': 10, 'TBS_SMARTAUDIO': 11, 'IRC_TRAMP': 12, 'OPFLOW': 14, 'LOG': 15, 'RANGEFINDER': 16, 'VTX_FFPV': 17, 'ESC': 18, 'GSM_SMS': 19, }; // Required for MSP_DEBUGMSG because console.log() doesn't allow omitting // the newline at the end, so we keep the pending message here until we find a // '\0', then print it. Messages sent by MSP_DEBUGMSG are guaranteed to // always finish with a '\0'. var debugMsgBuffer = ''; /** * * @param {MSP} dataHandler */ self.processData = function (dataHandler) { var data = new DataView(dataHandler.message_buffer, 0), // DataView (allowing us to view arrayBuffer as struct/union) offset = 0, needle = 0, i = 0, buff = [], identifier = '', flags, colorCount, color; if (!dataHandler.unsupported) switch (dataHandler.code) { case MSPCodes.MSP_IDENT: //FIXME remove this frame when proven not needed console.log('Using deprecated msp command: MSP_IDENT'); // Deprecated CONFIG.version = parseFloat((data.getUint8(0) / 100).toFixed(2)); CONFIG.multiType = data.getUint8(1); CONFIG.msp_version = data.getUint8(2); CONFIG.capability = data.getUint32(3, true); break; case MSPCodes.MSP_STATUS: console.log('Using deprecated msp command: MSP_STATUS'); CONFIG.cycleTime = data.getUint16(0, true); CONFIG.i2cError = data.getUint16(2, true); CONFIG.activeSensors = data.getUint16(4, true); CONFIG.mode = data.getUint32(6, true); CONFIG.profile = data.getUint8(10); gui.updateProfileChange(); gui.updateStatusBar(); break; case MSPCodes.MSP_STATUS_EX: CONFIG.cycleTime = data.getUint16(0, true); CONFIG.i2cError = data.getUint16(2, true); CONFIG.activeSensors = data.getUint16(4, true); CONFIG.profile = data.getUint8(10); CONFIG.cpuload = data.getUint16(11, true); CONFIG.armingFlags = data.getUint16(13, true); gui.updateStatusBar(); gui.updateProfileChange(); break; case MSPCodes.MSPV2_INAV_STATUS: CONFIG.cycleTime = data.getUint16(offset, true); offset += 2; CONFIG.i2cError = data.getUint16(offset, true); offset += 2; CONFIG.activeSensors = data.getUint16(offset, true); offset += 2; CONFIG.cpuload = data.getUint16(offset, true); offset += 2; profile_byte = data.getUint8(offset++) CONFIG.profile = profile_byte & 0x0F; CONFIG.battery_profile = (profile_byte & 0xF0) >> 4; CONFIG.armingFlags = data.getUint32(offset, true); offset += 4; gui.updateStatusBar(); gui.updateProfileChange(); break; case MSPCodes.MSP_ACTIVEBOXES: var words = dataHandler.message_length_expected / 4; CONFIG.mode = []; for (i = 0; i < words; ++i) CONFIG.mode.push(data.getUint32(i * 4, true)); break; case MSPCodes.MSP_SENSOR_STATUS: SENSOR_STATUS.isHardwareHealthy = data.getUint8(0); SENSOR_STATUS.gyroHwStatus = data.getUint8(1); SENSOR_STATUS.accHwStatus = data.getUint8(2); SENSOR_STATUS.magHwStatus = data.getUint8(3); SENSOR_STATUS.baroHwStatus = data.getUint8(4); SENSOR_STATUS.gpsHwStatus = data.getUint8(5); SENSOR_STATUS.rangeHwStatus = data.getUint8(6); SENSOR_STATUS.speedHwStatus = data.getUint8(7); SENSOR_STATUS.flowHwStatus = data.getUint8(8); sensor_status_ex(SENSOR_STATUS); break; case MSPCodes.MSP_RAW_IMU: // 512 for mpu6050, 256 for mma // currently we are unable to differentiate between the sensor types, so we are goign with 512 SENSOR_DATA.accelerometer[0] = data.getInt16(0, true) / 512; SENSOR_DATA.accelerometer[1] = data.getInt16(2, true) / 512; SENSOR_DATA.accelerometer[2] = data.getInt16(4, true) / 512; // properly scaled SENSOR_DATA.gyroscope[0] = data.getInt16(6, true) * (4 / 16.4); SENSOR_DATA.gyroscope[1] = data.getInt16(8, true) * (4 / 16.4); SENSOR_DATA.gyroscope[2] = data.getInt16(10, true) * (4 / 16.4); // no clue about scaling factor SENSOR_DATA.magnetometer[0] = data.getInt16(12, true) / 1090; SENSOR_DATA.magnetometer[1] = data.getInt16(14, true) / 1090; SENSOR_DATA.magnetometer[2] = data.getInt16(16, true) / 1090; break; case MSPCodes.MSP_SERVO: var servoCount = dataHandler.message_length_expected / 2; for (i = 0; i < servoCount; i++) { SERVO_DATA[i] = data.getUint16(needle, true); needle += 2; } break; case MSPCodes.MSP_MOTOR: var motorCount = dataHandler.message_length_expected / 2; for (i = 0; i < motorCount; i++) { MOTOR_DATA[i] = data.getUint16(needle, true); needle += 2; } break; case MSPCodes.MSP_RC: RC.active_channels = dataHandler.message_length_expected / 2; for (i = 0; i < RC.active_channels; i++) { RC.channels[i] = data.getUint16((i * 2), true); } break; case MSPCodes.MSP_RAW_GPS: GPS_DATA.fix = data.getUint8(0); GPS_DATA.numSat = data.getUint8(1); GPS_DATA.lat = data.getInt32(2, true); GPS_DATA.lon = data.getInt32(6, true); GPS_DATA.alt = data.getInt16(10, true); GPS_DATA.speed = data.getUint16(12, true); GPS_DATA.ground_course = data.getUint16(14, true); GPS_DATA.hdop = data.getUint16(16, true); break; case MSPCodes.MSP_COMP_GPS: GPS_DATA.distanceToHome = data.getUint16(0, 1); GPS_DATA.directionToHome = data.getUint16(2, 1); GPS_DATA.update = data.getUint8(4); break; case MSPCodes.MSP_GPSSTATISTICS: GPS_DATA.messageDt = data.getUint16(0, true); GPS_DATA.errors = data.getUint32(2, true); GPS_DATA.timeouts = data.getUint32(6, true); GPS_DATA.packetCount = data.getUint32(10, true); GPS_DATA.hdop = data.getUint16(14, true); GPS_DATA.eph = data.getUint16(16, true); GPS_DATA.epv = data.getUint16(18, true); break; case MSPCodes.MSP_ATTITUDE: SENSOR_DATA.kinematics[0] = data.getInt16(0, true) / 10.0; // x SENSOR_DATA.kinematics[1] = data.getInt16(2, true) / 10.0; // y SENSOR_DATA.kinematics[2] = data.getInt16(4, true); // z break; case MSPCodes.MSP_ALTITUDE: SENSOR_DATA.altitude = parseFloat((data.getInt32(0, true) / 100.0).toFixed(2)); // correct scale factor SENSOR_DATA.barometer = parseFloat((data.getInt32(6, true) / 100.0).toFixed(2)); // correct scale factor break; case MSPCodes.MSP_SONAR: SENSOR_DATA.sonar = data.getInt32(0, true); break; case MSPCodes.MSPV2_INAV_AIR_SPEED: SENSOR_DATA.air_speed = data.getInt32(0, true); break; case MSPCodes.MSP_ANALOG: ANALOG.voltage = data.getUint8(0) / 10.0; ANALOG.mAhdrawn = data.getUint16(1, true); ANALOG.rssi = data.getUint16(3, true); // 0-1023 ANALOG.amperage = data.getInt16(5, true) / 100; // A break; case MSPCodes.MSPV2_INAV_ANALOG: if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { var tmp = data.getUint8(offset++); ANALOG.battery_full_when_plugged_in = (tmp & 1 ? true : false); ANALOG.use_capacity_thresholds = ((tmp & 2) >> 1 ? true : false); ANALOG.battery_state = (tmp & 12) >> 2; ANALOG.cell_count = (tmp & 0xF0) >> 4; ANALOG.voltage = data.getUint16(offset, true) / 100.0; offset += 2; ANALOG.amperage = data.getInt16(offset, true) / 100; // A offset += 2; ANALOG.power = data.getInt32(offset, true) / 100.0; offset += 4; ANALOG.mAhdrawn = data.getInt32(offset, true); offset += 4; ANALOG.mWhdrawn = data.getInt32(offset, true); offset += 4; ANALOG.battery_remaining_capacity = data.getUint32(offset, true); offset += 4; ANALOG.battery_percentage = data.getUint8(offset++); ANALOG.rssi = data.getUint16(offset, true); // 0-1023 offset += 2; } else { ANALOG.voltage = data.getUint16(offset, true) / 100.0; offset += 2; ANALOG.cell_count = data.getUint8(offset++); ANALOG.battery_percentage = data.getUint8(offset++); ANALOG.power = data.getUint16(offset, true); offset += 2; ANALOG.mAhdrawn = data.getUint16(offset, true); offset += 2; ANALOG.mWhdrawn = data.getUint16(offset, true); offset += 2; ANALOG.rssi = data.getUint16(offset, true); // 0-1023 offset += 2; ANALOG.amperage = data.getInt16(offset, true) / 100; // A offset += 2; var battery_flags = data.getUint8(offset++); ANALOG.battery_full_when_plugged_in = (battery_flags & 1 ? true : false); ANALOG.use_capacity_thresholds = ((battery_flags & 2) >> 1 ? true : false); ANALOG.battery_state = (battery_flags & 12) >> 2; ANALOG.battery_remaining_capacity = data.getUint32(offset, true); offset += 4; } //noinspection JSValidateTypes dataHandler.analog_last_received_timestamp = Date.now(); break; case MSPCodes.MSP_RC_TUNING: RC_tuning.RC_RATE = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.RC_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.roll_pitch_rate = 0; RC_tuning.roll_rate = parseFloat((data.getUint8(offset++) * 10)); RC_tuning.pitch_rate = parseFloat((data.getUint8(offset++) * 10)); RC_tuning.yaw_rate = parseFloat((data.getUint8(offset++) * 10)); RC_tuning.dynamic_THR_PID = parseInt(data.getUint8(offset++)); RC_tuning.throttle_MID = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.throttle_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.dynamic_THR_breakpoint = data.getUint16(offset, true); offset += 2; RC_tuning.RC_YAW_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); break; case MSPCodes.MSPV2_INAV_RATE_PROFILE: // compat RC_tuning.RC_RATE = 100; RC_tuning.roll_pitch_rate = 0; // throttle RC_tuning.throttle_MID = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.throttle_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.dynamic_THR_PID = parseInt(data.getUint8(offset++)); RC_tuning.dynamic_THR_breakpoint = data.getUint16(offset, true); offset += 2; // stabilized RC_tuning.RC_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.RC_YAW_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.roll_rate = data.getUint8(offset++) * 10; RC_tuning.pitch_rate = data.getUint8(offset++) * 10; RC_tuning.yaw_rate = data.getUint8(offset++) * 10; // manual RC_tuning.manual_RC_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.manual_RC_YAW_EXPO = parseFloat((data.getUint8(offset++) / 100).toFixed(2)); RC_tuning.manual_roll_rate = data.getUint8(offset++); RC_tuning.manual_pitch_rate = data.getUint8(offset++); RC_tuning.manual_yaw_rate = data.getUint8(offset++); break; case MSPCodes.MSP_PID: // PID data arrived, we need to scale it and save to appropriate bank / array for (i = 0, needle = 0; i < (dataHandler.message_length_expected / 3); i++, needle += 3) { PIDs[i][0] = data.getUint8(needle); PIDs[i][1] = data.getUint8(needle + 1); PIDs[i][2] = data.getUint8(needle + 2); } break; case MSPCodes.MSP2_PID: // PID data arrived, we need to scale it and save to appropriate bank / array for (i = 0, needle = 0; i < (dataHandler.message_length_expected / 4); i++, needle += 4) { PIDs[i][0] = data.getUint8(needle); PIDs[i][1] = data.getUint8(needle + 1); PIDs[i][2] = data.getUint8(needle + 2); PIDs[i][3] = data.getUint8(needle + 3); } break; case MSPCodes.MSP_ARMING_CONFIG: ARMING_CONFIG.auto_disarm_delay = data.getUint8(0); ARMING_CONFIG.disarm_kill_switch = data.getUint8(1); break; case MSPCodes.MSP_LOOP_TIME: FC_CONFIG.loopTime = data.getInt16(0, true); break; case MSPCodes.MSP_MISC: // 22 bytes MISC.midrc = data.getInt16(offset, true); offset += 2; MISC.minthrottle = data.getUint16(offset, true); // 0-2000 offset += 2; MISC.maxthrottle = data.getUint16(offset, true); // 0-2000 offset += 2; MISC.mincommand = data.getUint16(offset, true); // 0-2000 offset += 2; MISC.failsafe_throttle = data.getUint16(offset, true); // 1000-2000 offset += 2; MISC.gps_type = data.getUint8(offset++); MISC.sensors_baudrate = data.getUint8(offset++); MISC.gps_ubx_sbas = data.getInt8(offset++); MISC.multiwiicurrentoutput = data.getUint8(offset++); MISC.rssi_channel = data.getUint8(offset++); MISC.placeholder2 = data.getUint8(offset++); MISC.mag_declination = data.getInt16(offset, 1) / 10; // -18000-18000 offset += 2; MISC.vbatscale = data.getUint8(offset++); // 10-200 MISC.vbatmincellvoltage = data.getUint8(offset++) / 10; // 10-50 MISC.vbatmaxcellvoltage = data.getUint8(offset++) / 10; // 10-50 MISC.vbatwarningcellvoltage = data.getUint8(offset++) / 10; // 10-50 break; case MSPCodes.MSPV2_INAV_MISC: MISC.midrc = data.getInt16(offset, true); offset += 2; MISC.minthrottle = data.getUint16(offset, true); // 0-2000 offset += 2; MISC.maxthrottle = data.getUint16(offset, true); // 0-2000 offset += 2; MISC.mincommand = data.getUint16(offset, true); // 0-2000 offset += 2; MISC.failsafe_throttle = data.getUint16(offset, true); // 1000-2000 offset += 2; MISC.gps_type = data.getUint8(offset++); MISC.sensors_baudrate = data.getUint8(offset++); MISC.gps_ubx_sbas = data.getInt8(offset++); MISC.rssi_channel = data.getUint8(offset++); MISC.mag_declination = data.getInt16(offset, 1) / 10; // -18000-18000 offset += 2; MISC.vbatscale = data.getUint16(offset, true); offset += 2; if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { MISC.voltage_source = data.getUint8(offset++); MISC.battery_cells = data.getUint8(offset++); MISC.vbatdetectcellvoltage = data.getUint16(offset, true) / 100; offset += 2; } MISC.vbatmincellvoltage = data.getUint16(offset, true) / 100; offset += 2; MISC.vbatmaxcellvoltage = data.getUint16(offset, true) / 100; offset += 2; MISC.vbatwarningcellvoltage = data.getUint16(offset, true) / 100; offset += 2; MISC.battery_capacity = data.getUint32(offset, true); offset += 4; MISC.battery_capacity_warning = data.getUint32(offset, true); offset += 4; MISC.battery_capacity_critical = data.getUint32(offset, true); offset += 4; MISC.battery_capacity_unit = (data.getUint8(offset++) ? 'mWh' : 'mAh'); break; case MSPCodes.MSPV2_INAV_SET_MISC: console.log('MISC INAV Configuration saved'); break; case MSPCodes.MSPV2_INAV_BATTERY_CONFIG: BATTERY_CONFIG.vbatscale = data.getUint16(offset, true); offset += 2; if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { BATTERY_CONFIG.voltage_source = data.getUint8(offset++); BATTERY_CONFIG.battery_cells = data.getUint8(offset++); BATTERY_CONFIG.vbatdetectcellvoltage = data.getUint16(offset, true) / 100; offset += 2; } BATTERY_CONFIG.vbatmincellvoltage = data.getUint16(offset, true) / 100; offset += 2; BATTERY_CONFIG.vbatmaxcellvoltage = data.getUint16(offset, true) / 100; offset += 2; BATTERY_CONFIG.vbatwarningcellvoltage = data.getUint16(offset, true) / 100; offset += 2; BATTERY_CONFIG.current_offset = data.getUint16(offset, true); offset += 2; BATTERY_CONFIG.current_scale = data.getUint16(offset, true); offset += 2; BATTERY_CONFIG.capacity = data.getUint32(offset, true); offset += 4; BATTERY_CONFIG.capacity_warning = data.getUint32(offset, true); offset += 4; BATTERY_CONFIG.capacity_critical = data.getUint32(offset, true); offset += 4; BATTERY_CONFIG.battery_capacity_unit = (data.getUint8(offset++) ? 'mWh' : 'mAh'); break; case MSPCodes.MSP_3D: _3D.deadband3d_low = data.getUint16(offset, true); offset += 2; _3D.deadband3d_high = data.getUint16(offset, true); offset += 2; _3D.neutral3d = data.getUint16(offset, true); if (semver.lt(CONFIG.apiVersion, "1.17.0")) { offset += 2; _3D.deadband3d_throttle = data.getUint16(offset, true); } break; case MSPCodes.MSP_MOTOR_PINS: console.log(data); break; case MSPCodes.MSP_BOXNAMES: //noinspection JSUndeclaredVariable AUX_CONFIG = []; // empty the array as new data is coming in buff = []; for (i = 0; i < data.byteLength; i++) { if (data.getUint8(i) == 0x3B) { // ; (delimeter char) AUX_CONFIG.push(String.fromCharCode.apply(null, buff)); // convert bytes into ASCII and save as strings // empty buffer buff = []; } else { buff.push(data.getUint8(i)); } } break; case MSPCodes.MSP_PIDNAMES: //noinspection JSUndeclaredVariable PID_names = []; // empty the array as new data is coming in buff = []; for (i = 0; i < data.byteLength; i++) { if (data.getUint8(i) == 0x3B) { // ; (delimiter char) PID_names.push(String.fromCharCode.apply(null, buff)); // convert bytes into ASCII and save as strings // empty buffer buff = []; } else { buff.push(data.getUint8(i)); } } break; case MSPCodes.MSP_WP: MISSION_PLANER.bufferPoint.number = data.getUint8(0); MISSION_PLANER.bufferPoint.action = data.getUint8(1); MISSION_PLANER.bufferPoint.lat = data.getInt32(2, true) / 10000000; MISSION_PLANER.bufferPoint.lon = data.getInt32(6, true) / 10000000; MISSION_PLANER.bufferPoint.alt = data.getInt32(10, true); MISSION_PLANER.bufferPoint.p1 = data.getInt16(14, true); break; case MSPCodes.MSP_BOXIDS: //noinspection JSUndeclaredVariable AUX_CONFIG_IDS = []; // empty the array as new data is coming in for (i = 0; i < data.byteLength; i++) { AUX_CONFIG_IDS.push(data.getUint8(i)); } break; case MSPCodes.MSP_SERVO_MIX_RULES: SERVO_RULES.flush(); if (semver.gte(CONFIG.flightControllerVersion, "2.1.0")) { if (data.byteLength % 8 === 0) { for (i = 0; i < data.byteLength; i += 8) { SERVO_RULES.put(new ServoMixRule( data.getInt8(i), data.getInt8(i + 1), data.getInt16(i + 2, true), data.getInt8(i + 4) )); } } } else { if (data.byteLength % 7 === 0) { for (i = 0; i < data.byteLength; i += 7) { SERVO_RULES.put(new ServoMixRule( data.getInt8(i), data.getInt8(i + 1), data.getInt8(i + 2), data.getInt8(i + 3) )); } } } SERVO_RULES.cleanup(); break; case MSPCodes.MSP2_INAV_SERVO_MIXER: SERVO_RULES.flush(); if (data.byteLength % 6 === 0) { for (i = 0; i < data.byteLength; i += 6) { SERVO_RULES.put(new ServoMixRule( data.getInt8(i), data.getInt8(i + 1), data.getInt16(i + 2, true), data.getInt8(i + 4), data.getInt8(i + 5) )); } } SERVO_RULES.cleanup(); break; case MSPCodes.MSP_SET_SERVO_MIX_RULE: console.log("Servo mix saved"); break; case MSPCodes.MSP2_INAV_SET_SERVO_MIXER: console.log("Servo mix saved"); break; case MSPCodes.MSP2_INAV_LOGIC_CONDITIONS: LOGIC_CONDITIONS.flush(); if (data.byteLength % 13 === 0) { for (i = 0; i < data.byteLength; i += 13) { LOGIC_CONDITIONS.put(new LogicCondition( data.getInt8(i), data.getInt8(i + 1), data.getInt8(i + 2), data.getInt32(i + 3, true), data.getInt8(i + 7), data.getInt32(i + 8, true), data.getInt8(i + 12) )); } } break; case MSPCodes.MSP2_INAV_LOGIC_CONDITIONS_STATUS: if (data.byteLength % 4 === 0) { let index = 0; for (i = 0; i < data.byteLength; i += 4) { LOGIC_CONDITIONS_STATUS.set(index, data.getInt32(i, true)); index++; } } break; case MSPCodes.MSP2_INAV_SET_LOGIC_CONDITIONS: console.log("Logic conditions saved"); break; case MSPCodes.MSP2_COMMON_MOTOR_MIXER: MOTOR_RULES.flush(); if (data.byteLength % 8 === 0) { for (i = 0; i < data.byteLength; i += 8) { var rule = new MotorMixRule(0, 0, 0, 0); rule.fromMsp( data.getUint16(i, true), data.getUint16(i + 2, true), data.getUint16(i + 4, true), data.getUint16(i + 6, true) ); MOTOR_RULES.put(rule); } } MOTOR_RULES.cleanup(); break; case MSPCodes.MSP2_COMMON_SET_MOTOR_MIXER: console.log("motor mixer saved"); break; case MSPCodes.MSP_SERVO_CONFIGURATIONS: //noinspection JSUndeclaredVariable SERVO_CONFIG = []; // empty the array as new data is coming in if (data.byteLength % 14 == 0) { for (i = 0; i < data.byteLength; i += 14) { var arr = { 'min': data.getInt16(i + 0, true), 'max': data.getInt16(i + 2, true), 'middle': data.getInt16(i + 4, true), 'rate': data.getInt8(i + 6), 'indexOfChannelToForward': data.getInt8(i + 9) }; data.getUint32(i + 10); // Skip 4 bytes that used to be reversed Sources SERVO_CONFIG.push(arr); } } break; case MSPCodes.MSP_RC_DEADBAND: RC_deadband.deadband = data.getUint8(offset++); RC_deadband.yaw_deadband = data.getUint8(offset++); RC_deadband.alt_hold_deadband = data.getUint8(offset++); if (semver.gte(CONFIG.apiVersion, "1.24.0")) { _3D.deadband3d_throttle = data.getUint16(offset, true); } break; case MSPCodes.MSP_SENSOR_ALIGNMENT: SENSOR_ALIGNMENT.align_gyro = data.getUint8(offset++); SENSOR_ALIGNMENT.align_acc = data.getUint8(offset++); SENSOR_ALIGNMENT.align_mag = data.getUint8(offset++); if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { SENSOR_ALIGNMENT.align_opflow = data.getUint8(offset++); } break; case MSPCodes.MSP_SET_RAW_RC: break; case MSPCodes.MSP_SET_RAW_GPS: break; case MSPCodes.MSP_SET_PID: console.log('PID settings saved'); break; case MSPCodes.MSP2_SET_PID: console.log('PID settings saved'); break; case MSPCodes.MSP_SET_RC_TUNING: console.log('RC Tuning saved'); break; case MSPCodes.MSP_ACC_CALIBRATION: console.log('Accelerometer calibration executed'); break; case MSPCodes.MSP_MAG_CALIBRATION: console.log('Mag calibration executed'); break; case MSPCodes.MSP2_INAV_OPFLOW_CALIBRATION: console.log('Optic flow calibration executed'); break; case MSPCodes.MSP_SET_MISC: console.log('MISC Configuration saved'); break; case MSPCodes.MSP_RESET_CONF: console.log('Settings Reset'); break; case MSPCodes.MSP_SELECT_SETTING: console.log('Profile selected'); break; case MSPCodes.MSP_SET_SERVO_CONFIGURATION: console.log('Servo Configuration saved'); break; case MSPCodes.MSP_RTC: if (data.length >= 6) { var seconds = data.getInt32(0, true); var millis = data.getUint16(4, true); console.log("RTC received: " + new Date(seconds * 1000 + millis)); } break; case MSPCodes.MSP_SET_RTC: console.log('RTC set'); break; case MSPCodes.MSP_EEPROM_WRITE: console.log('Settings Saved in EEPROM'); break; case MSPCodes.MSP_DEBUGMSG: for (var ii = 0; ii < data.byteLength; ii++) { var c = data.readU8(); if (c == 0) { // End of message if (debugMsgBuffer.length > 1) { console.log('[DEBUG] ' + debugMsgBuffer); DEBUG_TRACE = (DEBUG_TRACE || '') + debugMsgBuffer; } debugMsgBuffer = ''; continue; } debugMsgBuffer += String.fromCharCode(c); } break; case MSPCodes.MSP_DEBUG: for (i = 0; i < 4; i++) SENSOR_DATA.debug[i] = data.getInt16((2 * i), 1); break; case MSPCodes.MSP2_INAV_DEBUG: for (i = 0; i < 8; i++) SENSOR_DATA.debug[i] = data.getInt32((4 * i), 1); break; case MSPCodes.MSP_SET_MOTOR: console.log('Motor Speeds Updated'); break; // Additional baseflight commands that are not compatible with MultiWii case MSPCodes.MSP_UID: CONFIG.uid[0] = data.getUint32(0, true); CONFIG.uid[1] = data.getUint32(4, true); CONFIG.uid[2] = data.getUint32(8, true); break; case MSPCodes.MSP_ACC_TRIM: CONFIG.accelerometerTrims[0] = data.getInt16(0, true); // pitch CONFIG.accelerometerTrims[1] = data.getInt16(2, true); // roll break; case MSPCodes.MSP_SET_ACC_TRIM: console.log('Accelerometer trimms saved.'); break; // Additional private MSP for baseflight configurator case MSPCodes.MSP_RX_MAP: //noinspection JSUndeclaredVariable RC_MAP = []; // empty the array as new data is coming in for (i = 0; i < data.byteLength; i++) { RC_MAP.push(data.getUint8(i)); } break; case MSPCodes.MSP_SET_RX_MAP: console.log('RCMAP saved'); break; case MSPCodes.MSP_BF_CONFIG: BF_CONFIG.mixerConfiguration = data.getUint8(0); BF_CONFIG.features = data.getUint32(1, true); BF_CONFIG.serialrx_type = data.getUint8(5); BF_CONFIG.board_align_roll = data.getInt16(6, true); // -180 - 360 BF_CONFIG.board_align_pitch = data.getInt16(8, true); // -180 - 360 BF_CONFIG.board_align_yaw = data.getInt16(10, true); // -180 - 360 BF_CONFIG.currentscale = data.getInt16(12, true); BF_CONFIG.currentoffset = data.getInt16(14, true); break; case MSPCodes.MSP_SET_BF_CONFIG: console.log('BF_CONFIG saved'); break; case MSPCodes.MSP_SET_REBOOT: console.log('Reboot request accepted'); break; // // Cleanflight specific // case MSPCodes.MSP_API_VERSION: CONFIG.mspProtocolVersion = data.getUint8(offset++); CONFIG.apiVersion = data.getUint8(offset++) + '.' + data.getUint8(offset++) + '.0'; break; case MSPCodes.MSP_FC_VARIANT: for (offset = 0; offset < 4; offset++) { identifier += String.fromCharCode(data.getUint8(offset)); } CONFIG.flightControllerIdentifier = identifier; break; case MSPCodes.MSP_FC_VERSION: CONFIG.flightControllerVersion = data.getUint8(offset++) + '.' + data.getUint8(offset++) + '.' + data.getUint8(offset++); break; case MSPCodes.MSP_BUILD_INFO: var dateLength = 11; buff = []; for (i = 0; i < dateLength; i++) { buff.push(data.getUint8(offset++)); } buff.push(32); // ascii space var timeLength = 8; for (i = 0; i < timeLength; i++) { buff.push(data.getUint8(offset++)); } CONFIG.buildInfo = String.fromCharCode.apply(null, buff); break; case MSPCodes.MSP_BOARD_INFO: for (offset = 0; offset < 4; offset++) { identifier += String.fromCharCode(data.getUint8(offset)); } CONFIG.boardIdentifier = identifier; CONFIG.boardVersion = data.getUint16(offset, 1); offset += 2; break; case MSPCodes.MSP_SET_CHANNEL_FORWARDING: console.log('Channel forwarding saved'); break; case MSPCodes.MSP_CF_SERIAL_CONFIG: SERIAL_CONFIG.ports = []; var bytesPerPort = 1 + 2 + 4; var serialPortCount = data.byteLength / bytesPerPort; for (i = 0; i < serialPortCount; i++) { var BAUD_RATES = (semver.gte(CONFIG.flightControllerVersion, "1.6.3")) ? mspHelper.BAUD_RATES_post1_6_3 : mspHelper.BAUD_RATES_pre1_6_3; var serialPort = { identifier: data.getUint8(offset), functions: mspHelper.serialPortFunctionMaskToFunctions(data.getUint16(offset + 1, true)), msp_baudrate: BAUD_RATES[data.getUint8(offset + 3)], sensors_baudrate: BAUD_RATES[data.getUint8(offset + 4)], telemetry_baudrate: BAUD_RATES[data.getUint8(offset + 5)], blackbox_baudrate: BAUD_RATES[data.getUint8(offset + 6)] }; offset += bytesPerPort; SERIAL_CONFIG.ports.push(serialPort); } break; case MSPCodes.MSP2_CF_SERIAL_CONFIG: SERIAL_CONFIG.ports = []; var bytesPerPort = 1 + 4 + 4; var serialPortCount = data.byteLength / bytesPerPort; for (i = 0; i < serialPortCount; i++) { var BAUD_RATES = (semver.gte(CONFIG.flightControllerVersion, "1.6.3")) ? mspHelper.BAUD_RATES_post1_6_3 : mspHelper.BAUD_RATES_pre1_6_3; var serialPort = { identifier: data.getUint8(offset), functions: mspHelper.serialPortFunctionMaskToFunctions(data.getUint32(offset + 1, true)), msp_baudrate: BAUD_RATES[data.getUint8(offset + 5)], sensors_baudrate: BAUD_RATES[data.getUint8(offset + 6)], telemetry_baudrate: BAUD_RATES[data.getUint8(offset + 7)], blackbox_baudrate: BAUD_RATES[data.getUint8(offset + 8)] }; offset += bytesPerPort; SERIAL_CONFIG.ports.push(serialPort); } break; case MSPCodes.MSP_SET_CF_SERIAL_CONFIG: case MSPCodes.MSP2_SET_CF_SERIAL_CONFIG: console.log('Serial config saved'); break; case MSPCodes.MSP_MODE_RANGES: //noinspection JSUndeclaredVariable MODE_RANGES = []; // empty the array as new data is coming in var modeRangeCount = data.byteLength / 4; // 4 bytes per item. for (i = 0; offset < data.byteLength && i < modeRangeCount; i++) { var modeRange = { id: data.getUint8(offset++), auxChannelIndex: data.getUint8(offset++), range: { start: 900 + (data.getUint8(offset++) * 25), end: 900 + (data.getUint8(offset++) * 25) } }; MODE_RANGES.push(modeRange); } break; case MSPCodes.MSP_ADJUSTMENT_RANGES: //noinspection JSUndeclaredVariable ADJUSTMENT_RANGES = []; // empty the array as new data is coming in var adjustmentRangeCount = data.byteLength / 6; // 6 bytes per item. for (i = 0; offset < data.byteLength && i < adjustmentRangeCount; i++) { var adjustmentRange = { slotIndex: data.getUint8(offset++), auxChannelIndex: data.getUint8(offset++), range: { start: 900 + (data.getUint8(offset++) * 25), end: 900 + (data.getUint8(offset++) * 25) }, adjustmentFunction: data.getUint8(offset++), auxSwitchChannelIndex: data.getUint8(offset++) }; ADJUSTMENT_RANGES.push(adjustmentRange); } break; case MSPCodes.MSP_CHANNEL_FORWARDING: for (i = 0; i < data.byteLength && i < SERVO_CONFIG.length; i++) { var channelIndex = data.getUint8(i); if (channelIndex < 255) { SERVO_CONFIG[i].indexOfChannelToForward = channelIndex; } else { SERVO_CONFIG[i].indexOfChannelToForward = undefined; } } break; case MSPCodes.MSP_RX_CONFIG: RX_CONFIG.serialrx_provider = data.getUint8(offset); offset++; RX_CONFIG.maxcheck = data.getUint16(offset, true); offset += 2; RX_CONFIG.midrc = data.getUint16(offset, true); offset += 2; RX_CONFIG.mincheck = data.getUint16(offset, true); offset += 2; RX_CONFIG.spektrum_sat_bind = data.getUint8(offset); offset++; RX_CONFIG.rx_min_usec = data.getUint16(offset, true); offset += 2; RX_CONFIG.rx_max_usec = data.getUint16(offset, true); offset += 2; if (semver.gte(CONFIG.apiVersion, "1.21.0")) { offset += 4; // 4 null bytes for betaflight compatibility RX_CONFIG.spirx_protocol = data.getUint8(offset); offset++; RX_CONFIG.spirx_id = data.getUint32(offset, true); offset += 4; RX_CONFIG.spirx_channel_count = data.getUint8(offset); offset += 1; } // unused byte for fpvCamAngleDegrees, for compatiblity with betaflight offset += 1; RX_CONFIG.receiver_type = data.getUint8(offset); offset += 1; break; case MSPCodes.MSP_FAILSAFE_CONFIG: FAILSAFE_CONFIG.failsafe_delay = data.getUint8(offset); offset++; FAILSAFE_CONFIG.failsafe_off_delay = data.getUint8(offset); offset++; FAILSAFE_CONFIG.failsafe_throttle = data.getUint16(offset, true); offset += 2; FAILSAFE_CONFIG.failsafe_kill_switch = data.getUint8(offset); offset++; FAILSAFE_CONFIG.failsafe_throttle_low_delay = data.getUint16(offset, true); offset += 2; FAILSAFE_CONFIG.failsafe_procedure = data.getUint8(offset); offset++; FAILSAFE_CONFIG.failsafe_recovery_delay = data.getUint8(offset); offset++; FAILSAFE_CONFIG.failsafe_fw_roll_angle = data.getUint16(offset, true); offset += 2; FAILSAFE_CONFIG.failsafe_fw_pitch_angle = data.getUint16(offset, true); offset += 2; FAILSAFE_CONFIG.failsafe_fw_yaw_rate = data.getUint16(offset, true); offset += 2; FAILSAFE_CONFIG.failsafe_stick_motion_threshold = data.getUint16(offset, true); offset += 2; FAILSAFE_CONFIG.failsafe_min_distance = data.getUint16(offset, true); offset += 2; FAILSAFE_CONFIG.failsafe_min_distance_procedure = data.getUint8(offset); offset++; break; case MSPCodes.MSP_RXFAIL_CONFIG: //noinspection JSUndeclaredVariable RXFAIL_CONFIG = []; // empty the array as new data is coming in var channelCount = data.byteLength / 3; for (i = 0; offset < data.byteLength && i < channelCount; i++, offset++) { var rxfailChannel = { mode: data.getUint8(offset++), value: data.getUint16(offset++, true) }; RXFAIL_CONFIG.push(rxfailChannel); } break; case MSPCodes.MSP_LED_STRIP_CONFIG: //noinspection JSUndeclaredVariable LED_STRIP = []; var ledCount = data.byteLength / 7; // v1.4.0 and below incorrectly reported 4 bytes per led. if (semver.gte(CONFIG.apiVersion, "1.20.0")) ledCount = data.byteLength / 4; var directionMask, directions, directionLetterIndex, functions, led; for (i = 0; offset < data.byteLength && i < ledCount; i++) { if (semver.lt(CONFIG.apiVersion, "1.20.0")) { directionMask = data.getUint16(offset, true); offset += 2; directions = []; for (directionLetterIndex = 0; directionLetterIndex < MSP.ledDirectionLetters.length; directionLetterIndex++) { if (bit_check(directionMask, directionLetterIndex)) { directions.push(MSP.ledDirectionLetters[directionLetterIndex]); } } var functionMask = data.getUint16(offset, 1); offset += 2; functions = []; for (var functionLetterIndex = 0; functionLetterIndex < MSP.ledFunctionLetters.length; functionLetterIndex++) { if (bit_check(functionMask, functionLetterIndex)) { functions.push(MSP.ledFunctionLetters[functionLetterIndex]); } } led = { directions: directions, functions: functions, x: data.getUint8(offset++), y: data.getUint8(offset++), color: data.getUint8(offset++) }; LED_STRIP.push(led); } else { var mask = data.getUint32(offset, 1); offset += 4; var functionId = (mask >> 8) & 0xF; functions = []; for (var baseFunctionLetterIndex = 0; baseFunctionLetterIndex < MSP.ledBaseFunctionLetters.length; baseFunctionLetterIndex++) { if (functionId == baseFunctionLetterIndex) { functions.push(MSP.ledBaseFunctionLetters[baseFunctionLetterIndex]); break; } } var overlayMask = (mask >> 12) & 0x3F; for (var overlayLetterIndex = 0; overlayLetterIndex < MSP.ledOverlayLetters.length; overlayLetterIndex++) { if (bit_check(overlayMask, overlayLetterIndex)) { functions.push(MSP.ledOverlayLetters[overlayLetterIndex]); } } directionMask = (mask >> 22) & 0x3F; directions = []; for (directionLetterIndex = 0; directionLetterIndex < MSP.ledDirectionLetters.length; directionLetterIndex++) { if (bit_check(directionMask, directionLetterIndex)) { directions.push(MSP.ledDirectionLetters[directionLetterIndex]); } } led = { y: (mask) & 0xF, x: (mask >> 4) & 0xF, functions: functions, color: (mask >> 18) & 0xF, directions: directions, parameters: (mask >> 28) & 0xF }; LED_STRIP.push(led); } } break; case MSPCodes.MSP_SET_LED_STRIP_CONFIG: console.log('Led strip config saved'); break; case MSPCodes.MSP_LED_COLORS: //noinspection JSUndeclaredVariable LED_COLORS = []; colorCount = data.byteLength / 4; for (i = 0; offset < data.byteLength && i < colorCount; i++) { var h = data.getUint16(offset, true); var s = data.getUint8(offset + 2); var v = data.getUint8(offset + 3); offset += 4; color = { h: h, s: s, v: v }; LED_COLORS.push(color); } break; case MSPCodes.MSP_SET_LED_COLORS: console.log('Led strip colors saved'); break; case MSPCodes.MSP_LED_STRIP_MODECOLOR: if (semver.gte(CONFIG.apiVersion, "1.19.0")) { //noinspection JSUndeclaredVariable LED_MODE_COLORS = []; colorCount = data.byteLength / 3; for (i = 0; offset < data.byteLength && i < colorCount; i++) { var mode = data.getUint8(offset++); var direction = data.getUint8(offset++); color = data.getUint8(offset++); LED_MODE_COLORS.push({ mode: mode, direction: direction, color: color }); } } break; case MSPCodes.MSP_SET_LED_STRIP_MODECOLOR: console.log('Led strip mode colors saved'); break; case MSPCodes.MSP_DATAFLASH_SUMMARY: if (data.byteLength >= 13) { flags = data.getUint8(0); DATAFLASH.ready = (flags & 1) != 0; DATAFLASH.supported = (flags & 2) != 0 || DATAFLASH.ready; DATAFLASH.sectors = data.getUint32(1, 1); DATAFLASH.totalSize = data.getUint32(5, 1); DATAFLASH.usedSize = data.getUint32(9, 1); } else { // Firmware version too old to support MSP_DATAFLASH_SUMMARY DATAFLASH.ready = false; DATAFLASH.supported = false; DATAFLASH.sectors = 0; DATAFLASH.totalSize = 0; DATAFLASH.usedSize = 0; } update_dataflash_global(); break; case MSPCodes.MSP_DATAFLASH_READ: // No-op, let callback handle it break; case MSPCodes.MSP_DATAFLASH_ERASE: console.log("Data flash erase begun..."); break; case MSPCodes.MSP_SDCARD_SUMMARY: flags = data.getUint8(0); SDCARD.supported = (flags & 0x01) != 0; SDCARD.state = data.getUint8(1); SDCARD.filesystemLastError = data.getUint8(2); SDCARD.freeSizeKB = data.getUint32(3, true); SDCARD.totalSizeKB = data.getUint32(7, true); break; case MSPCodes.MSP_BLACKBOX_CONFIG: BLACKBOX.supported = (data.getUint8(0) & 1) != 0; BLACKBOX.blackboxDevice = data.getUint8(1); BLACKBOX.blackboxRateNum = data.getUint8(2); BLACKBOX.blackboxRateDenom = data.getUint8(3); break; case MSPCodes.MSP_SET_BLACKBOX_CONFIG: console.log("Blackbox config saved"); break; case MSPCodes.MSP_TRANSPONDER_CONFIG: TRANSPONDER.supported = (data.getUint8(offset++) & 1) != 0; TRANSPONDER.data = []; var bytesRemaining = data.byteLength - offset; for (i = 0; i < bytesRemaining; i++) { TRANSPONDER.data.push(data.getUint8(offset++)); } break; case MSPCodes.MSP_SET_TRANSPONDER_CONFIG: console.log("Transponder config saved"); break; case MSPCodes.MSP_VTX_CONFIG: VTX_CONFIG.device_type = data.getUint8(offset++); if (VTX_CONFIG.device_type != VTX.DEV_UNKNOWN) { VTX_CONFIG.band = data.getUint8(offset++); VTX_CONFIG.channel = data.getUint8(offset++); VTX_CONFIG.power = data.getUint8(offset++); VTX_CONFIG.pitmode = data.getUint8(offset++); // Ignore wether the VTX is ready for now offset++; VTX_CONFIG.low_power_disarm = data.getUint8(offset++); } break; case MSPCodes.MSP_ADVANCED_CONFIG: ADVANCED_CONFIG.gyroSyncDenominator = data.getUint8(offset); offset++; ADVANCED_CONFIG.pidProcessDenom = data.getUint8(offset); offset++; ADVANCED_CONFIG.useUnsyncedPwm = data.getUint8(offset); offset++; ADVANCED_CONFIG.motorPwmProtocol = data.getUint8(offset); offset++; ADVANCED_CONFIG.motorPwmRate = data.getUint16(offset, true); offset += 2; ADVANCED_CONFIG.servoPwmRate = data.getUint16(offset, true); offset += 2; ADVANCED_CONFIG.gyroSync = data.getUint8(offset); break; case MSPCodes.MSP_SET_VTX_CONFIG: console.log("VTX config saved"); break; case MSPCodes.MSP_SET_ADVANCED_CONFIG: console.log("Advanced config saved"); break; case MSPCodes.MSP_FILTER_CONFIG: FILTER_CONFIG.gyroSoftLpfHz = data.getUint8(0); FILTER_CONFIG.dtermLpfHz = data.getUint16(1, true); FILTER_CONFIG.yawLpfHz = data.getUint16(3, true); FILTER_CONFIG.gyroNotchHz1 = data.getUint16(5, true); FILTER_CONFIG.gyroNotchCutoff1 = data.getUint16(7, true); FILTER_CONFIG.dtermNotchHz = data.getUint16(9, true); FILTER_CONFIG.dtermNotchCutoff = data.getUint16(11, true); FILTER_CONFIG.gyroNotchHz2 = data.getUint16(13, true); FILTER_CONFIG.gyroNotchCutoff2 = data.getUint16(15, true); if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { FILTER_CONFIG.accNotchHz = data.getUint16(17, true); FILTER_CONFIG.accNotchCutoff = data.getUint16(19, true); FILTER_CONFIG.gyroStage2LowpassHz = data.getUint16(21, true); } break; case MSPCodes.MSP_SET_FILTER_CONFIG: console.log("Filter config saved"); break; case MSPCodes.MSP_PID_ADVANCED: PID_ADVANCED.rollPitchItermIgnoreRate = data.getUint16(0, true); PID_ADVANCED.yawItermIgnoreRate = data.getUint16(2, true); PID_ADVANCED.yawPLimit = data.getUint16(4, true); PID_ADVANCED.dtermSetpointWeight = data.getUint8(9); PID_ADVANCED.pidSumLimit = data.getUint16(10, true); PID_ADVANCED.axisAccelerationLimitRollPitch = data.getUint16(13, true); PID_ADVANCED.axisAccelerationLimitYaw = data.getUint16(15, true); break; case MSPCodes.MSP_SET_PID_ADVANCED: console.log("PID advanced saved"); break; case MSPCodes.MSP_SENSOR_CONFIG: SENSOR_CONFIG.accelerometer = data.getUint8(0, true); SENSOR_CONFIG.barometer = data.getUint8(1, true); SENSOR_CONFIG.magnetometer = data.getUint8(2, true); SENSOR_CONFIG.pitot = data.getUint8(3, true); SENSOR_CONFIG.rangefinder = data.getUint8(4, true); SENSOR_CONFIG.opflow = data.getUint8(5, true); break; case MSPCodes.MSP_SET_SENSOR_CONFIG: console.log("Sensor config saved"); break; case MSPCodes.MSP_INAV_PID: INAV_PID_CONFIG.asynchronousMode = data.getUint8(0); INAV_PID_CONFIG.accelerometerTaskFrequency = data.getUint16(1, true); INAV_PID_CONFIG.attitudeTaskFrequency = data.getUint16(3, true); INAV_PID_CONFIG.magHoldRateLimit = data.getUint8(5); INAV_PID_CONFIG.magHoldErrorLpfFrequency = data.getUint8(6); INAV_PID_CONFIG.yawJumpPreventionLimit = data.getUint16(7, true); INAV_PID_CONFIG.gyroscopeLpf = data.getUint8(9); INAV_PID_CONFIG.accSoftLpfHz = data.getUint8(10); break; case MSPCodes.MSP_SET_INAV_PID: console.log("MSP_INAV_PID saved"); break; case MSPCodes.MSP_NAV_POSHOLD: NAV_POSHOLD.userControlMode = data.getUint8(0); NAV_POSHOLD.maxSpeed = data.getUint16(1, true); NAV_POSHOLD.maxClimbRate = data.getUint16(3, true); NAV_POSHOLD.maxManualSpeed = data.getUint16(5, true); NAV_POSHOLD.maxManualClimbRate = data.getUint16(7, true); NAV_POSHOLD.maxBankAngle = data.getUint8(9); NAV_POSHOLD.useThrottleMidForAlthold = data.getUint8(10); NAV_POSHOLD.hoverThrottle = data.getUint16(11, true); break; case MSPCodes.MSP_SET_NAV_POSHOLD: console.log('NAV_POSHOLD saved'); break; case MSPCodes.MSP_CALIBRATION_DATA: var callibrations = data.getUint8(0); CALIBRATION_DATA.acc.Pos0 = (1 & (callibrations >> 0)); CALIBRATION_DATA.acc.Pos1 = (1 & (callibrations >> 1)); CALIBRATION_DATA.acc.Pos2 = (1 & (callibrations >> 2)); CALIBRATION_DATA.acc.Pos3 = (1 & (callibrations >> 3)); CALIBRATION_DATA.acc.Pos4 = (1 & (callibrations >> 4)); CALIBRATION_DATA.acc.Pos5 = (1 & (callibrations >> 5)); CALIBRATION_DATA.accZero.X = data.getInt16(1, true); CALIBRATION_DATA.accZero.Y = data.getInt16(3, true); CALIBRATION_DATA.accZero.Z = data.getInt16(5, true); CALIBRATION_DATA.accGain.X = data.getInt16(7, true); CALIBRATION_DATA.accGain.Y = data.getInt16(9, true); CALIBRATION_DATA.accGain.Z = data.getInt16(11, true); CALIBRATION_DATA.magZero.X = data.getInt16(13, true); CALIBRATION_DATA.magZero.Y = data.getInt16(15, true); CALIBRATION_DATA.magZero.Z = data.getInt16(17, true); if (semver.gte(CONFIG.flightControllerVersion, "2.2.0")) { CALIBRATION_DATA.opflow.Scale = (data.getInt16(19, true) / 256.0); } break; case MSPCodes.MSP_SET_CALIBRATION_DATA: console.log('Calibration data saved'); break; case MSPCodes.MSP_POSITION_ESTIMATION_CONFIG: POSITION_ESTIMATOR.w_z_baro_p = data.getUint16(0, true) / 100; POSITION_ESTIMATOR.w_z_gps_p = data.getUint16(2, true) / 100; POSITION_ESTIMATOR.w_z_gps_v = data.getUint16(4, true) / 100; POSITION_ESTIMATOR.w_xy_gps_p = data.getUint16(6, true) / 100; POSITION_ESTIMATOR.w_xy_gps_v = data.getUint16(8, true) / 100; POSITION_ESTIMATOR.gps_min_sats = data.getUint8(10); POSITION_ESTIMATOR.use_gps_velned = data.getUint8(11); break; case MSPCodes.MSP_SET_POSITION_ESTIMATION_CONFIG: console.log('POSITION_ESTIMATOR saved'); break; case MSPCodes.MSP_RTH_AND_LAND_CONFIG: RTH_AND_LAND_CONFIG.minRthDistance = data.getUint16(0, true); RTH_AND_LAND_CONFIG.rthClimbFirst = data.getUint8(2); RTH_AND_LAND_CONFIG.rthClimbIgnoreEmergency = data.getUint8(3); RTH_AND_LAND_CONFIG.rthTailFirst = data.getUint8(4); RTH_AND_LAND_CONFIG.rthAllowLanding = data.getUint8(5); RTH_AND_LAND_CONFIG.rthAltControlMode = data.getUint8(6); RTH_AND_LAND_CONFIG.rthAbortThreshold = data.getUint16(7, true); RTH_AND_LAND_CONFIG.rthAltitude = data.getUint16(9, true); RTH_AND_LAND_CONFIG.landDescentRate = data.getUint16(11, true); RTH_AND_LAND_CONFIG.landSlowdownMinAlt = data.getUint16(13, true); RTH_AND_LAND_CONFIG.landSlowdownMaxAlt = data.getUint16(15, true); RTH_AND_LAND_CONFIG.emergencyDescentRate = data.getUint16(17, true); break; case MSPCodes.MSP_SET_RTH_AND_LAND_CONFIG: console.log('RTH_AND_LAND_CONFIG saved'); break; case MSPCodes.MSP_FW_CONFIG: FW_CONFIG.cruiseThrottle = data.getUint16(0, true); FW_CONFIG.minThrottle = data.getUint16(2, true); FW_CONFIG.maxThrottle = data.getUint16(4, true); FW_CONFIG.maxBankAngle = data.getUint8(6); FW_CONFIG.maxClimbAngle = data.getUint8(7); FW_CONFIG.maxDiveAngle = data.getUint8(8); FW_CONFIG.pitchToThrottle = data.getUint8(9); FW_CONFIG.loiterRadius = data.getUint16(10, true); break; case MSPCodes.MSP_SET_FW_CONFIG: console.log('FW_CONFIG saved'); break; case MSPCodes.MSP_SET_MODE_RANGE: console.log('Mode range saved'); break; case MSPCodes.MSP_SET_ADJUSTMENT_RANGE: console.log('Adjustment range saved'); break; case MSPCodes.MSP_SET_LOOP_TIME: console.log('Looptime saved'); break; case MSPCodes.MSP_SET_ARMING_CONFIG: console.log('Arming config saved'); break; case MSPCodes.MSP_SET_RESET_CURR_PID: console.log('Current PID profile reset'); break; case MSPCodes.MSP_SET_3D: console.log('3D settings saved'); break; case MSPCodes.MSP_SET_RC_DEADBAND: console.log('Rc controls settings saved'); break; case MSPCodes.MSP_SET_SENSOR_ALIGNMENT: console.log('Sensor alignment saved'); break; case MSPCodes.MSP_SET_RX_CONFIG: console.log('Rx config saved'); break; case MSPCodes.MSP_SET_RXFAIL_CONFIG: console.log('Rxfail config saved'); break; case MSPCodes.MSP_SET_FAILSAFE_CONFIG: console.log('Failsafe config saved'); break; case MSPCodes.MSP_OSD_CONFIG: break; case MSPCodes.MSP_SET_OSD_CONFIG: console.log('OSD config set'); break; case MSPCodes.MSP_OSD_CHAR_READ: break; case MSPCodes.MSP_OSD_CHAR_WRITE: console.log('OSD char uploaded'); break; case MSPCodes.MSP_NAME: CONFIG.name = ''; var char; while ((char = data.readU8()) !== null) { CONFIG.name += String.fromCharCode(char); } break; case MSPCodes.MSP_SET_NAME: console.log("Craft name set"); break; case MSPCodes.MSPV2_SETTING: break; case MSPCodes.MSP2_COMMON_SETTING_INFO: break; case MSPCodes.MSPV2_SET_SETTING: console.log("Setting set"); break; case MSPCodes.MSP_WP_GETINFO: // Reserved for waypoint capabilities data.getUint8(0); MISSION_PLANER.maxWaypoints = data.getUint8(1); MISSION_PLANER.isValidMission = data.getUint8(2); MISSION_PLANER.countBusyPoints = data.getUint8(3); break; case MSPCodes.MSP_SET_WP: console.log('Point saved'); break; case MSPCodes.MSP_WP_MISSION_SAVE: // buffer.push(0); console.log(data); break; case MSPCodes.MSP_WP_MISSION_LOAD: console.log('Mission load'); break; case MSPCodes.MSP2_INAV_MIXER: MIXER_CONFIG.yawMotorDirection = data.getInt8(0); MIXER_CONFIG.yawJumpPreventionLimit = data.getUint16(1, true); MIXER_CONFIG.platformType = data.getInt8(3); MIXER_CONFIG.hasFlaps = data.getInt8(4); MIXER_CONFIG.appliedMixerPreset = data.getInt16(5, true); MIXER_CONFIG.numberOfMotors = data.getInt8(7); MIXER_CONFIG.numberOfServos = data.getInt8(8); MOTOR_RULES.setMotorCount(MIXER_CONFIG.numberOfMotors); SERVO_RULES.setServoCount(MIXER_CONFIG.numberOfServos); break; case MSPCodes.MSP2_INAV_SET_MIXER: console.log('Mixer config saved'); case MSPCodes.MSP2_INAV_OSD_LAYOUTS: break; case MSPCodes.MSP2_INAV_OSD_SET_LAYOUT_ITEM: console.log('OSD layout item saved'); break; case MSPCodes.MSP2_INAV_OSD_ALARMS: break; case MSPCodes.MSP2_INAV_OSD_SET_ALARMS: console.log('OSD alarms saved'); break; case MSPCodes.MSP2_INAV_OSD_PREFERENCES: break; case MSPCodes.MSP2_INAV_OSD_SET_PREFERENCES: console.log('OSD preferences saved'); break; case MSPCodes.MSPV2_INAV_OUTPUT_MAPPING: OUTPUT_MAPPING.flush(); for (i = 0; i < data.byteLength; ++i) OUTPUT_MAPPING.put(data.getUint8(i)); break; case MSPCodes.MSP2_INAV_MC_BRAKING: BRAKING_CONFIG.speedThreshold = data.getUint16(0, true); BRAKING_CONFIG.disengageSpeed = data.getUint16(2, true); BRAKING_CONFIG.timeout = data.getUint16(4, true); BRAKING_CONFIG.boostFactor = data.getInt8(6); BRAKING_CONFIG.boostTimeout = data.getUint16(7, true); BRAKING_CONFIG.boostSpeedThreshold = data.getUint16(9, true); BRAKING_CONFIG.boostDisengageSpeed = data.getUint16(11, true); BRAKING_CONFIG.bankAngle = data.getInt8(13); break; case MSPCodes.MSP2_INAV_SET_MC_BRAKING: console.log('Braking config saved'); break; case MSPCodes.MSP2_BLACKBOX_CONFIG: BLACKBOX.supported = (data.getUint8(0) & 1) != 0; BLACKBOX.blackboxDevice = data.getUint8(1); BLACKBOX.blackboxRateNum = data.getUint16(2); BLACKBOX.blackboxRateDenom = data.getUint16(4); break; case MSPCodes.MSP2_SET_BLACKBOX_CONFIG: console.log("Blackbox config saved"); break; case MSPCodes.MSP2_INAV_TEMPERATURES: for (i = 0; i < 8; ++i) { temp_decidegrees = data.getInt16(i * 2, true); SENSOR_DATA.temperature[i] = temp_decidegrees / 10; // °C } break; default: console.log('Unknown code detected: ' + dataHandler.code); } else { console.log('FC reports unsupported message error: ' + dataHandler.code); } // trigger callbacks, cleanup/remove callback after trigger for (i = dataHandler.callbacks.length - 1; i >= 0; i--) { // iterating in reverse because we use .splice which modifies array length if (i < dataHandler.callbacks.length) { if (dataHandler.callbacks[i].code == dataHandler.code) { // save callback reference var callback = dataHandler.callbacks[i].onFinish; // remove timeout clearTimeout(dataHandler.callbacks[i].timer); /* * Compute roundtrip */ if (dataHandler.callbacks[i]) { helper.mspQueue.putRoundtrip(new Date().getTime() - dataHandler.callbacks[i].createdOn); helper.mspQueue.putHardwareRoundtrip(new Date().getTime() - dataHandler.callbacks[i].sentOn); } // remove object from array dataHandler.callbacks.splice(i, 1); // fire callback if (callback) callback({'command': dataHandler.code, 'data': data, 'length': dataHandler.message_length_expected}); } } } }; self.crunch = function (code) { var buffer = [], i; switch (code) { case MSPCodes.MSP_SET_BF_CONFIG: buffer.push(BF_CONFIG.mixerConfiguration); buffer.push(specificByte(BF_CONFIG.features, 0)); buffer.push(specificByte(BF_CONFIG.features, 1)); buffer.push(specificByte(BF_CONFIG.features, 2)); buffer.push(specificByte(BF_CONFIG.features, 3)); buffer.push(BF_CONFIG.serialrx_type); buffer.push(specificByte(BF_CONFIG.board_align_roll, 0)); buffer.push(specificByte(BF_CONFIG.board_align_roll, 1)); buffer.push(specificByte(BF_CONFIG.board_align_pitch, 0)); buffer.push(specificByte(BF_CONFIG.board_align_pitch, 1)); buffer.push(specificByte(BF_CONFIG.board_align_yaw, 0)); buffer.push(specificByte(BF_CONFIG.board_align_yaw, 1)); buffer.push(lowByte(BF_CONFIG.currentscale)); buffer.push(highByte(BF_CONFIG.currentscale)); buffer.push(lowByte(BF_CONFIG.currentoffset)); buffer.push(highByte(BF_CONFIG.currentoffset)); break; case MSPCodes.MSP_SET_VTX_CONFIG: if (VTX_CONFIG.band > 0) { buffer.push16(((VTX_CONFIG.band - 1) * 8) + (VTX_CONFIG.channel - 1)); } else { // This tells the firmware to ignore this value. buffer.push16(VTX.MAX_FREQUENCY_MHZ + 1); } buffer.push(VTX_CONFIG.power); // Don't enable PIT mode buffer.push(0); buffer.push(VTX_CONFIG.low_power_disarm); break; case MSPCodes.MSP_SET_PID: for (i = 0; i < PIDs.length; i++) { buffer.push(parseInt(PIDs[i][0])); buffer.push(parseInt(PIDs[i][1])); buffer.push(parseInt(PIDs[i][2])); } break; case MSPCodes.MSP2_SET_PID: for (i = 0; i < PIDs.length; i++) { buffer.push(parseInt(PIDs[i][0])); buffer.push(parseInt(PIDs[i][1])); buffer.push(parseInt(PIDs[i][2])); buffer.push(parseInt(PIDs[i][3])); } break; case MSPCodes.MSP_SET_RC_TUNING: buffer.push(Math.round(RC_tuning.RC_RATE * 100)); buffer.push(Math.round(RC_tuning.RC_EXPO * 100)); buffer.push(Math.round(RC_tuning.roll_rate / 10)); buffer.push(Math.round(RC_tuning.pitch_rate / 10)); buffer.push(Math.round(RC_tuning.yaw_rate / 10)); buffer.push(RC_tuning.dynamic_THR_PID); buffer.push(Math.round(RC_tuning.throttle_MID * 100)); buffer.push(Math.round(RC_tuning.throttle_EXPO * 100)); buffer.push(lowByte(RC_tuning.dynamic_THR_breakpoint)); buffer.push(highByte(RC_tuning.dynamic_THR_breakpoint)); buffer.push(Math.round(RC_tuning.RC_YAW_EXPO * 100)); break; case MSPCodes.MSPV2_INAV_SET_RATE_PROFILE: // throttle buffer.push(Math.round(RC_tuning.throttle_MID * 100)); buffer.push(Math.round(RC_tuning.throttle_EXPO * 100)); buffer.push(RC_tuning.dynamic_THR_PID); buffer.push(lowByte(RC_tuning.dynamic_THR_breakpoint)); buffer.push(highByte(RC_tuning.dynamic_THR_breakpoint)); // stabilized buffer.push(Math.round(RC_tuning.RC_EXPO * 100)); buffer.push(Math.round(RC_tuning.RC_YAW_EXPO * 100)); buffer.push(Math.round(RC_tuning.roll_rate / 10)); buffer.push(Math.round(RC_tuning.pitch_rate / 10)); buffer.push(Math.round(RC_tuning.yaw_rate / 10)); // manual buffer.push(Math.round(RC_tuning.manual_RC_EXPO * 100)); buffer.push(Math.round(RC_tuning.manual_RC_YAW_EXPO * 100)); buffer.push(RC_tuning.manual_roll_rate); buffer.push(RC_tuning.manual_pitch_rate); buffer.push(RC_tuning.manual_yaw_rate); break; case MSPCodes.MSP_SET_RX_MAP: for (i = 0; i < RC_MAP.length; i++) { buffer.push(RC_MAP[i]); } break; case MSPCodes.MSP_SET_ACC_TRIM: buffer.push(lowByte(CONFIG.accelerometerTrims[0])); buffer.push(highByte(CONFIG.accelerometerTrims[0])); buffer.push(lowByte(CONFIG.accelerometerTrims[1])); buffer.push(highByte(CONFIG.accelerometerTrims[1])); break; case MSPCodes.MSP_SET_ARMING_CONFIG: buffer.push(ARMING_CONFIG.auto_disarm_delay); buffer.push(ARMING_CONFIG.disarm_kill_switch); break; case MSPCodes.MSP_SET_LOOP_TIME: buffer.push(lowByte(FC_CONFIG.loopTime)); buffer.push(highByte(FC_CONFIG.loopTime)); break; case MSPCodes.MSP_SET_MISC: buffer.push(lowByte(MISC.midrc)); buffer.push(highByte(MISC.midrc)); buffer.push(lowByte(MISC.minthrottle)); buffer.push(highByte(MISC.minthrottle)); buffer.push(lowByte(MISC.maxthrottle)); buffer.push(highByte(MISC.maxthrottle)); buffer.push(lowByte(MISC.mincommand)); buffer.push(highByte(MISC.mincommand)); buffer.push(lowByte(MISC.failsafe_throttle)); buffer.push(highByte(MISC.failsafe_throttle)); buffer.push(MISC.gps_type); buffer.push(MISC.sensors_baudrate); buffer.push(MISC.gps_ubx_sbas); buffer.push(MISC.multiwiicurrentoutput); buffer.push(MISC.rssi_channel); buffer.push(MISC.placeholder2); buffer.push(lowByte(Math.round(MISC.mag_declination * 10))); buffer.push(highByte(Math.round(MISC.mag_declination * 10))); buffer.push(MISC.vbatscale); buffer.push(Math.round(MISC.vbatmincellvoltage * 10)); buffer.push(Math.round(MISC.vbatmaxcellvoltage * 10)); buffer.push(Math.round(MISC.vbatwarningcellvoltage * 10)); break; case MSPCodes.MSPV2_INAV_SET_MISC: buffer.push(lowByte(MISC.midrc)); buffer.push(highByte(MISC.midrc)); buffer.push(lowByte(MISC.minthrottle)); buffer.push(highByte(MISC.minthrottle)); buffer.push(lowByte(MISC.maxthrottle)); buffer.push(highByte(MISC.maxthrottle)); buffer.push(lowByte(MISC.mincommand)); buffer.push(highByte(MISC.mincommand)); buffer.push(lowByte(MISC.failsafe_throttle)); buffer.push(highByte(MISC.failsafe_throttle)); buffer.push(MISC.gps_type); buffer.push(MISC.sensors_baudrate); buffer.push(MISC.gps_ubx_sbas); buffer.push(MISC.rssi_channel); buffer.push(lowByte(Math.round(MISC.mag_declination * 10))); buffer.push(highByte(Math.round(MISC.mag_declination * 10))); buffer.push(lowByte(MISC.vbatscale)); buffer.push(highByte(MISC.vbatscale)); if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { buffer.push(MISC.voltage_source); buffer.push(MISC.battery_cells); buffer.push(lowByte(Math.round(MISC.vbatdetectcellvoltage * 100))); buffer.push(highByte(Math.round(MISC.vbatdetectcellvoltage * 100))); } buffer.push(lowByte(Math.round(MISC.vbatmincellvoltage * 100))); buffer.push(highByte(Math.round(MISC.vbatmincellvoltage * 100))); buffer.push(lowByte(Math.round(MISC.vbatmaxcellvoltage * 100))); buffer.push(highByte(Math.round(MISC.vbatmaxcellvoltage * 100))); buffer.push(lowByte(Math.round(MISC.vbatwarningcellvoltage * 100))); buffer.push(highByte(Math.round(MISC.vbatwarningcellvoltage * 100))); for (byte_index = 0; byte_index < 4; ++byte_index) buffer.push(specificByte(MISC.battery_capacity, byte_index)); for (byte_index = 0; byte_index < 4; ++byte_index) buffer.push(specificByte(MISC.battery_capacity_warning, byte_index)); for (byte_index = 0; byte_index < 4; ++byte_index) buffer.push(specificByte(MISC.battery_capacity_critical, byte_index)); buffer.push((MISC.battery_capacity_unit == 'mAh') ? 0 : 1); break; case MSPCodes.MSPV2_INAV_SET_BATTERY_CONFIG: buffer.push(lowByte(BATTERY_CONFIG.vbatscale)); buffer.push(highByte(BATTERY_CONFIG.vbatscale)); if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { buffer.push(BATTERY_CONFIG.voltage_source); buffer.push(BATTERY_CONFIG.battery_cells); buffer.push(lowByte(Math.round(BATTERY_CONFIG.vbatdetectcellvoltage * 100))); buffer.push(highByte(Math.round(BATTERY_CONFIG.vbatdetectcellvoltage * 100))); } buffer.push(lowByte(Math.round(BATTERY_CONFIG.vbatmincellvoltage * 100))); buffer.push(highByte(Math.round(BATTERY_CONFIG.vbatmincellvoltage * 100))); buffer.push(lowByte(Math.round(BATTERY_CONFIG.vbatmaxcellvoltage * 100))); buffer.push(highByte(Math.round(BATTERY_CONFIG.vbatmaxcellvoltage * 100))); buffer.push(lowByte(Math.round(BATTERY_CONFIG.vbatwarningcellvoltage * 100))); buffer.push(highByte(Math.round(BATTERY_CONFIG.vbatwarningcellvoltage * 100))); buffer.push(lowByte(BATTERY_CONFIG.current_offset)); buffer.push(highByte(BATTERY_CONFIG.current_offset)); buffer.push(lowByte(BATTERY_CONFIG.current_scale)); buffer.push(highByte(BATTERY_CONFIG.current_scale)); for (byte_index = 0; byte_index < 4; ++byte_index) buffer.push(specificByte(BATTERY_CONFIG.capacity, byte_index)); for (byte_index = 0; byte_index < 4; ++byte_index) buffer.push(specificByte(BATTERY_CONFIG.capacity_warning, byte_index)); for (byte_index = 0; byte_index < 4; ++byte_index) buffer.push(specificByte(BATTERY_CONFIG.capacity_critical, byte_index)); buffer.push(BATTERY_CONFIG.capacity_unit); break; case MSPCodes.MSP_SET_RX_CONFIG: buffer.push(RX_CONFIG.serialrx_provider); buffer.push(lowByte(RX_CONFIG.maxcheck)); buffer.push(highByte(RX_CONFIG.maxcheck)); buffer.push(lowByte(RX_CONFIG.midrc)); buffer.push(highByte(RX_CONFIG.midrc)); buffer.push(lowByte(RX_CONFIG.mincheck)); buffer.push(highByte(RX_CONFIG.mincheck)); buffer.push(RX_CONFIG.spektrum_sat_bind); buffer.push(lowByte(RX_CONFIG.rx_min_usec)); buffer.push(highByte(RX_CONFIG.rx_min_usec)); buffer.push(lowByte(RX_CONFIG.rx_max_usec)); buffer.push(highByte(RX_CONFIG.rx_max_usec)); if (semver.gte(CONFIG.apiVersion, "1.21.0")) { buffer.push(0); // 4 null bytes for betaflight compatibility buffer.push(0); buffer.push(0); buffer.push(0); buffer.push(RX_CONFIG.spirx_protocol); // spirx_id - 4 bytes buffer.push32(RX_CONFIG.spirx_id); buffer.push(RX_CONFIG.spirx_channel_count); } // unused byte for fpvCamAngleDegrees, for compatiblity with betaflight buffer.push(0); // receiver type in RX_CONFIG rather than in BF_CONFIG.features buffer.push(RX_CONFIG.receiver_type); break; case MSPCodes.MSP_SET_FAILSAFE_CONFIG: buffer.push(FAILSAFE_CONFIG.failsafe_delay); buffer.push(FAILSAFE_CONFIG.failsafe_off_delay); buffer.push(lowByte(FAILSAFE_CONFIG.failsafe_throttle)); buffer.push(highByte(FAILSAFE_CONFIG.failsafe_throttle)); buffer.push(FAILSAFE_CONFIG.failsafe_kill_switch); buffer.push(lowByte(FAILSAFE_CONFIG.failsafe_throttle_low_delay)); buffer.push(highByte(FAILSAFE_CONFIG.failsafe_throttle_low_delay)); buffer.push(FAILSAFE_CONFIG.failsafe_procedure); buffer.push(FAILSAFE_CONFIG.failsafe_recovery_delay); buffer.push(lowByte(FAILSAFE_CONFIG.failsafe_fw_roll_angle)); buffer.push(highByte(FAILSAFE_CONFIG.failsafe_fw_roll_angle)); buffer.push(lowByte(FAILSAFE_CONFIG.failsafe_fw_pitch_angle)); buffer.push(highByte(FAILSAFE_CONFIG.failsafe_fw_pitch_angle)); buffer.push(lowByte(FAILSAFE_CONFIG.failsafe_fw_yaw_rate)); buffer.push(highByte(FAILSAFE_CONFIG.failsafe_fw_yaw_rate)); buffer.push(lowByte(FAILSAFE_CONFIG.failsafe_stick_motion_threshold)); buffer.push(highByte(FAILSAFE_CONFIG.failsafe_stick_motion_threshold)); buffer.push(lowByte(FAILSAFE_CONFIG.failsafe_min_distance)); buffer.push(highByte(FAILSAFE_CONFIG.failsafe_min_distance)); buffer.push(FAILSAFE_CONFIG.failsafe_min_distance_procedure); break; case MSPCodes.MSP_SET_TRANSPONDER_CONFIG: for (i = 0; i < TRANSPONDER.data.length; i++) { buffer.push(TRANSPONDER.data[i]); } break; case MSPCodes.MSP_SET_CHANNEL_FORWARDING: for (i = 0; i < SERVO_CONFIG.length; i++) { var out = SERVO_CONFIG[i].indexOfChannelToForward; if (out == undefined) { out = 255; // Cleanflight defines "CHANNEL_FORWARDING_DISABLED" as "(uint8_t)0xFF" } buffer.push(out); } break; case MSPCodes.MSP_SET_CF_SERIAL_CONFIG: for (i = 0; i < SERIAL_CONFIG.ports.length; i++) { var serialPort = SERIAL_CONFIG.ports[i]; buffer.push(serialPort.identifier); var functionMask = mspHelper.SERIAL_PORT_FUNCTIONSToMask(serialPort.functions); buffer.push(specificByte(functionMask, 0)); buffer.push(specificByte(functionMask, 1)); var BAUD_RATES = (semver.gte(CONFIG.flightControllerVersion, "1.6.3")) ? mspHelper.BAUD_RATES_post1_6_3 : mspHelper.BAUD_RATES_pre1_6_3; buffer.push(BAUD_RATES.indexOf(serialPort.msp_baudrate)); buffer.push(BAUD_RATES.indexOf(serialPort.sensors_baudrate)); buffer.push(BAUD_RATES.indexOf(serialPort.telemetry_baudrate)); buffer.push(BAUD_RATES.indexOf(serialPort.blackbox_baudrate)); } break; case MSPCodes.MSP2_SET_CF_SERIAL_CONFIG: for (i = 0; i < SERIAL_CONFIG.ports.length; i++) { var serialPort = SERIAL_CONFIG.ports[i]; buffer.push(serialPort.identifier); var functionMask = mspHelper.SERIAL_PORT_FUNCTIONSToMask(serialPort.functions); buffer.push(specificByte(functionMask, 0)); buffer.push(specificByte(functionMask, 1)); buffer.push(specificByte(functionMask, 2)); buffer.push(specificByte(functionMask, 3)); var BAUD_RATES = (semver.gte(CONFIG.flightControllerVersion, "1.6.3")) ? mspHelper.BAUD_RATES_post1_6_3 : mspHelper.BAUD_RATES_pre1_6_3; buffer.push(BAUD_RATES.indexOf(serialPort.msp_baudrate)); buffer.push(BAUD_RATES.indexOf(serialPort.sensors_baudrate)); buffer.push(BAUD_RATES.indexOf(serialPort.telemetry_baudrate)); buffer.push(BAUD_RATES.indexOf(serialPort.blackbox_baudrate)); } break; case MSPCodes.MSP_SET_3D: buffer.push(lowByte(_3D.deadband3d_low)); buffer.push(highByte(_3D.deadband3d_low)); buffer.push(lowByte(_3D.deadband3d_high)); buffer.push(highByte(_3D.deadband3d_high)); buffer.push(lowByte(_3D.neutral3d)); buffer.push(highByte(_3D.neutral3d)); if (semver.lt(CONFIG.apiVersion, "1.17.0")) { buffer.push(lowByte(_3D.deadband3d_throttle)); buffer.push(highByte(_3D.deadband3d_throttle)); } break; case MSPCodes.MSP_SET_RC_DEADBAND: buffer.push(RC_deadband.deadband); buffer.push(RC_deadband.yaw_deadband); buffer.push(RC_deadband.alt_hold_deadband); if (semver.gte(CONFIG.apiVersion, "1.24.0")) { buffer.push(lowByte(_3D.deadband3d_throttle)); buffer.push(highByte(_3D.deadband3d_throttle)); } break; case MSPCodes.MSP_SET_SENSOR_ALIGNMENT: buffer.push(SENSOR_ALIGNMENT.align_gyro); buffer.push(SENSOR_ALIGNMENT.align_acc); buffer.push(SENSOR_ALIGNMENT.align_mag); if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { buffer.push(SENSOR_ALIGNMENT.align_opflow); } break; case MSPCodes.MSP_SET_ADVANCED_CONFIG: buffer.push(ADVANCED_CONFIG.gyroSyncDenominator); buffer.push(ADVANCED_CONFIG.pidProcessDenom); buffer.push(ADVANCED_CONFIG.useUnsyncedPwm); buffer.push(ADVANCED_CONFIG.motorPwmProtocol); buffer.push(lowByte(ADVANCED_CONFIG.motorPwmRate)); buffer.push(highByte(ADVANCED_CONFIG.motorPwmRate)); buffer.push(lowByte(ADVANCED_CONFIG.servoPwmRate)); buffer.push(highByte(ADVANCED_CONFIG.servoPwmRate)); buffer.push(ADVANCED_CONFIG.gyroSync); break; case MSPCodes.MSP_SET_INAV_PID: buffer.push(INAV_PID_CONFIG.asynchronousMode); buffer.push(lowByte(INAV_PID_CONFIG.accelerometerTaskFrequency)); buffer.push(highByte(INAV_PID_CONFIG.accelerometerTaskFrequency)); buffer.push(lowByte(INAV_PID_CONFIG.attitudeTaskFrequency)); buffer.push(highByte(INAV_PID_CONFIG.attitudeTaskFrequency)); buffer.push(INAV_PID_CONFIG.magHoldRateLimit); buffer.push(INAV_PID_CONFIG.magHoldErrorLpfFrequency); buffer.push(lowByte(INAV_PID_CONFIG.yawJumpPreventionLimit)); buffer.push(highByte(INAV_PID_CONFIG.yawJumpPreventionLimit)); buffer.push(INAV_PID_CONFIG.gyroscopeLpf); buffer.push(INAV_PID_CONFIG.accSoftLpfHz); buffer.push(0); //reserved buffer.push(0); //reserved buffer.push(0); //reserved buffer.push(0); //reserved break; case MSPCodes.MSP_SET_NAV_POSHOLD: buffer.push(NAV_POSHOLD.userControlMode); buffer.push(lowByte(NAV_POSHOLD.maxSpeed)); buffer.push(highByte(NAV_POSHOLD.maxSpeed)); buffer.push(lowByte(NAV_POSHOLD.maxClimbRate)); buffer.push(highByte(NAV_POSHOLD.maxClimbRate)); buffer.push(lowByte(NAV_POSHOLD.maxManualSpeed)); buffer.push(highByte(NAV_POSHOLD.maxManualSpeed)); buffer.push(lowByte(NAV_POSHOLD.maxManualClimbRate)); buffer.push(highByte(NAV_POSHOLD.maxManualClimbRate)); buffer.push(NAV_POSHOLD.maxBankAngle); buffer.push(NAV_POSHOLD.useThrottleMidForAlthold); buffer.push(lowByte(NAV_POSHOLD.hoverThrottle)); buffer.push(highByte(NAV_POSHOLD.hoverThrottle)); break; case MSPCodes.MSP_SET_CALIBRATION_DATA: buffer.push(lowByte(CALIBRATION_DATA.accZero.X)); buffer.push(highByte(CALIBRATION_DATA.accZero.X)); buffer.push(lowByte(CALIBRATION_DATA.accZero.Y)); buffer.push(highByte(CALIBRATION_DATA.accZero.Y)); buffer.push(lowByte(CALIBRATION_DATA.accZero.Z)); buffer.push(highByte(CALIBRATION_DATA.accZero.Z)); buffer.push(lowByte(CALIBRATION_DATA.accGain.X)); buffer.push(highByte(CALIBRATION_DATA.accGain.X)); buffer.push(lowByte(CALIBRATION_DATA.accGain.Y)); buffer.push(highByte(CALIBRATION_DATA.accGain.Y)); buffer.push(lowByte(CALIBRATION_DATA.accGain.Z)); buffer.push(highByte(CALIBRATION_DATA.accGain.Z)); buffer.push(lowByte(CALIBRATION_DATA.magZero.X)); buffer.push(highByte(CALIBRATION_DATA.magZero.X)); buffer.push(lowByte(CALIBRATION_DATA.magZero.Y)); buffer.push(highByte(CALIBRATION_DATA.magZero.Y)); buffer.push(lowByte(CALIBRATION_DATA.magZero.Z)); buffer.push(highByte(CALIBRATION_DATA.magZero.Z)); if (semver.gte(CONFIG.flightControllerVersion, "2.2.0")) { buffer.push(lowByte(Math.round(CALIBRATION_DATA.opflow.Scale * 256))); buffer.push(highByte(Math.round(CALIBRATION_DATA.opflow.Scale * 256))); } break; case MSPCodes.MSP_SET_POSITION_ESTIMATION_CONFIG: buffer.push(lowByte(POSITION_ESTIMATOR.w_z_baro_p * 100)); buffer.push(highByte(POSITION_ESTIMATOR.w_z_baro_p * 100)); buffer.push(lowByte(POSITION_ESTIMATOR.w_z_gps_p * 100)); buffer.push(highByte(POSITION_ESTIMATOR.w_z_gps_p * 100)); buffer.push(lowByte(POSITION_ESTIMATOR.w_z_gps_v * 100)); buffer.push(highByte(POSITION_ESTIMATOR.w_z_gps_v * 100)); buffer.push(lowByte(POSITION_ESTIMATOR.w_xy_gps_p * 100)); buffer.push(highByte(POSITION_ESTIMATOR.w_xy_gps_p * 100)); buffer.push(lowByte(POSITION_ESTIMATOR.w_xy_gps_v * 100)); buffer.push(highByte(POSITION_ESTIMATOR.w_xy_gps_v * 100)); buffer.push(POSITION_ESTIMATOR.gps_min_sats); buffer.push(POSITION_ESTIMATOR.use_gps_velned); break; case MSPCodes.MSP_SET_RTH_AND_LAND_CONFIG: buffer.push(lowByte(RTH_AND_LAND_CONFIG.minRthDistance)); buffer.push(highByte(RTH_AND_LAND_CONFIG.minRthDistance)); buffer.push(RTH_AND_LAND_CONFIG.rthClimbFirst); buffer.push(RTH_AND_LAND_CONFIG.rthClimbIgnoreEmergency); buffer.push(RTH_AND_LAND_CONFIG.rthTailFirst); buffer.push(RTH_AND_LAND_CONFIG.rthAllowLanding); buffer.push(RTH_AND_LAND_CONFIG.rthAltControlMode); buffer.push(lowByte(RTH_AND_LAND_CONFIG.rthAbortThreshold)); buffer.push(highByte(RTH_AND_LAND_CONFIG.rthAbortThreshold)); buffer.push(lowByte(RTH_AND_LAND_CONFIG.rthAltitude)); buffer.push(highByte(RTH_AND_LAND_CONFIG.rthAltitude)); buffer.push(lowByte(RTH_AND_LAND_CONFIG.landDescentRate)); buffer.push(highByte(RTH_AND_LAND_CONFIG.landDescentRate)); buffer.push(lowByte(RTH_AND_LAND_CONFIG.landSlowdownMinAlt)); buffer.push(highByte(RTH_AND_LAND_CONFIG.landSlowdownMinAlt)); buffer.push(lowByte(RTH_AND_LAND_CONFIG.landSlowdownMaxAlt)); buffer.push(highByte(RTH_AND_LAND_CONFIG.landSlowdownMaxAlt)); buffer.push(lowByte(RTH_AND_LAND_CONFIG.emergencyDescentRate)); buffer.push(highByte(RTH_AND_LAND_CONFIG.emergencyDescentRate)); break; case MSPCodes.MSP_SET_FW_CONFIG: buffer.push(lowByte(FW_CONFIG.cruiseThrottle)); buffer.push(highByte(FW_CONFIG.cruiseThrottle)); buffer.push(lowByte(FW_CONFIG.minThrottle)); buffer.push(highByte(FW_CONFIG.minThrottle)); buffer.push(lowByte(FW_CONFIG.maxThrottle)); buffer.push(highByte(FW_CONFIG.maxThrottle)); buffer.push(FW_CONFIG.maxBankAngle); buffer.push(FW_CONFIG.maxClimbAngle); buffer.push(FW_CONFIG.maxDiveAngle); buffer.push(FW_CONFIG.pitchToThrottle); buffer.push(lowByte(FW_CONFIG.loiterRadius)); buffer.push(highByte(FW_CONFIG.loiterRadius)); break; case MSPCodes.MSP_SET_FILTER_CONFIG: buffer.push(FILTER_CONFIG.gyroSoftLpfHz); buffer.push(lowByte(FILTER_CONFIG.dtermLpfHz)); buffer.push(highByte(FILTER_CONFIG.dtermLpfHz)); buffer.push(lowByte(FILTER_CONFIG.yawLpfHz)); buffer.push(highByte(FILTER_CONFIG.yawLpfHz)); buffer.push(lowByte(FILTER_CONFIG.gyroNotchHz1)); buffer.push(highByte(FILTER_CONFIG.gyroNotchHz1)); buffer.push(lowByte(FILTER_CONFIG.gyroNotchCutoff1)); buffer.push(highByte(FILTER_CONFIG.gyroNotchCutoff1)); buffer.push(lowByte(FILTER_CONFIG.dtermNotchHz)); buffer.push(highByte(FILTER_CONFIG.dtermNotchHz)); buffer.push(lowByte(FILTER_CONFIG.dtermNotchCutoff)); buffer.push(highByte(FILTER_CONFIG.dtermNotchCutoff)); buffer.push(lowByte(FILTER_CONFIG.gyroNotchHz2)); buffer.push(highByte(FILTER_CONFIG.gyroNotchHz2)); buffer.push(lowByte(FILTER_CONFIG.gyroNotchCutoff2)); buffer.push(highByte(FILTER_CONFIG.gyroNotchCutoff2)); if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { buffer.push(lowByte(FILTER_CONFIG.accNotchHz)); buffer.push(highByte(FILTER_CONFIG.accNotchHz)); buffer.push(lowByte(FILTER_CONFIG.accNotchCutoff)); buffer.push(highByte(FILTER_CONFIG.accNotchCutoff)); buffer.push(lowByte(FILTER_CONFIG.gyroStage2LowpassHz)); buffer.push(highByte(FILTER_CONFIG.gyroStage2LowpassHz)); } break; case MSPCodes.MSP_SET_PID_ADVANCED: buffer.push(lowByte(PID_ADVANCED.rollPitchItermIgnoreRate)); buffer.push(highByte(PID_ADVANCED.rollPitchItermIgnoreRate)); buffer.push(lowByte(PID_ADVANCED.yawItermIgnoreRate)); buffer.push(highByte(PID_ADVANCED.yawItermIgnoreRate)); buffer.push(lowByte(PID_ADVANCED.yawPLimit)); buffer.push(highByte(PID_ADVANCED.yawPLimit)); buffer.push(0); //BF: currentProfile->pidProfile.deltaMethod buffer.push(0); //BF: currentProfile->pidProfile.vbatPidCompensation buffer.push(0); //BF: currentProfile->pidProfile.setpointRelaxRatio buffer.push(PID_ADVANCED.dtermSetpointWeight); buffer.push(lowByte(PID_ADVANCED.pidSumLimit)); buffer.push(highByte(PID_ADVANCED.pidSumLimit)); buffer.push(0); //BF: currentProfile->pidProfile.itermThrottleGain buffer.push(lowByte(PID_ADVANCED.axisAccelerationLimitRollPitch)); buffer.push(highByte(PID_ADVANCED.axisAccelerationLimitRollPitch)); buffer.push(lowByte(PID_ADVANCED.axisAccelerationLimitYaw)); buffer.push(highByte(PID_ADVANCED.axisAccelerationLimitYaw)); break; case MSPCodes.MSP_SET_SENSOR_CONFIG: buffer.push(SENSOR_CONFIG.accelerometer); buffer.push(SENSOR_CONFIG.barometer); buffer.push(SENSOR_CONFIG.magnetometer); buffer.push(SENSOR_CONFIG.pitot); buffer.push(SENSOR_CONFIG.rangefinder); buffer.push(SENSOR_CONFIG.opflow); break; case MSPCodes.MSP_SET_WP: buffer.push(MISSION_PLANER.bufferPoint.number); // sbufReadU8(src); // number buffer.push(MISSION_PLANER.bufferPoint.action); // sbufReadU8(src); // action buffer.push(specificByte(MISSION_PLANER.bufferPoint.lat, 0)); // sbufReadU32(src); // lat buffer.push(specificByte(MISSION_PLANER.bufferPoint.lat, 1)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.lat, 2)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.lat, 3)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.lon, 0)); // sbufReadU32(src); // lon buffer.push(specificByte(MISSION_PLANER.bufferPoint.lon, 1)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.lon, 2)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.lon, 3)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.alt, 0)); // sbufReadU32(src); // to set altitude (cm) buffer.push(specificByte(MISSION_PLANER.bufferPoint.alt, 1)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.alt, 2)); buffer.push(specificByte(MISSION_PLANER.bufferPoint.alt, 3)); buffer.push(lowByte(MISSION_PLANER.bufferPoint.p1)); //sbufReadU16(src); // P1 speed or landing buffer.push(highByte(MISSION_PLANER.bufferPoint.p1)); buffer.push(lowByte(0)); //sbufReadU16(src); // P2 buffer.push(highByte(0)); buffer.push(lowByte(0)); //sbufReadU16(src); // P3 buffer.push(highByte(0)); buffer.push(MISSION_PLANER.bufferPoint.endMission); //sbufReadU8(src); // future: to set nav flag break; case MSPCodes.MSP_WP: console.log(MISSION_PLANER.bufferPoint.number); buffer.push(MISSION_PLANER.bufferPoint.number+1); break; case MSPCodes.MSP_WP_MISSION_SAVE: // buffer.push(0); console.log(buffer); break; case MSPCodes.MSP_WP_MISSION_LOAD: // buffer.push(0); console.log(buffer); break; case MSPCodes.MSP2_INAV_SET_MIXER: buffer.push(MIXER_CONFIG.yawMotorDirection); buffer.push(lowByte(MIXER_CONFIG.yawJumpPreventionLimit)); buffer.push(highByte(MIXER_CONFIG.yawJumpPreventionLimit)); buffer.push(MIXER_CONFIG.platformType); buffer.push(MIXER_CONFIG.hasFlaps); buffer.push(lowByte(MIXER_CONFIG.appliedMixerPreset)); buffer.push(highByte(MIXER_CONFIG.appliedMixerPreset)); break; case MSPCodes.MSP2_INAV_SET_MC_BRAKING: buffer.push(lowByte(BRAKING_CONFIG.speedThreshold)); buffer.push(highByte(BRAKING_CONFIG.speedThreshold)); buffer.push(lowByte(BRAKING_CONFIG.disengageSpeed)); buffer.push(highByte(BRAKING_CONFIG.disengageSpeed)); buffer.push(lowByte(BRAKING_CONFIG.timeout)); buffer.push(highByte(BRAKING_CONFIG.timeout)); buffer.push(BRAKING_CONFIG.boostFactor); buffer.push(lowByte(BRAKING_CONFIG.boostTimeout)); buffer.push(highByte(BRAKING_CONFIG.boostTimeout)); buffer.push(lowByte(BRAKING_CONFIG.boostSpeedThreshold)); buffer.push(highByte(BRAKING_CONFIG.boostSpeedThreshold)); buffer.push(lowByte(BRAKING_CONFIG.boostDisengageSpeed)); buffer.push(highByte(BRAKING_CONFIG.boostDisengageSpeed)); buffer.push(BRAKING_CONFIG.bankAngle); break; default: return false; } return buffer; }; /** * Set raw Rx values over MSP protocol. * * Channels is an array of 16-bit unsigned integer channel values to be sent. 8 channels is probably the maximum. */ self.setRawRx = function (channels) { var buffer = []; for (var i = 0; i < channels.length; i++) { buffer.push(specificByte(channels[i], 0)); buffer.push(specificByte(channels[i], 1)); } MSP.send_message(MSPCodes.MSP_SET_RAW_RC, buffer, false); }; self.sendBlackboxConfiguration = function (onDataCallback) { var buffer = []; var messageId = MSPCodes.MSP_SET_BLACKBOX_CONFIG; buffer.push(BLACKBOX.blackboxDevice & 0xFF); if (semver.gte(CONFIG.apiVersion, "2.3.0")) { messageId = MSPCodes.MSP2_SET_BLACKBOX_CONFIG; buffer.push(lowByte(BLACKBOX.blackboxRateNum)); buffer.push(highByte(BLACKBOX.blackboxRateNum)); buffer.push(lowByte(BLACKBOX.blackboxRateDenom)); buffer.push(highByte(BLACKBOX.blackboxRateDenom)); } else { buffer.push(BLACKBOX.blackboxRateNum & 0xFF); buffer.push(BLACKBOX.blackboxRateDenom & 0xFF); } //noinspection JSUnusedLocalSymbols MSP.send_message(messageId, buffer, false, function (response) { onDataCallback(); }); }; self.sendServoConfigurations = function (onCompleteCallback) { var nextFunction = send_next_servo_configuration; var servoIndex = 0; if (SERVO_CONFIG.length == 0) { onCompleteCallback(); } else { nextFunction(); } function send_next_servo_configuration() { var buffer = []; // send one at a time, with index var servoConfiguration = SERVO_CONFIG[servoIndex]; buffer.push(servoIndex); buffer.push(lowByte(servoConfiguration.min)); buffer.push(highByte(servoConfiguration.min)); buffer.push(lowByte(servoConfiguration.max)); buffer.push(highByte(servoConfiguration.max)); buffer.push(lowByte(servoConfiguration.middle)); buffer.push(highByte(servoConfiguration.middle)); buffer.push(lowByte(servoConfiguration.rate)); buffer.push(0); buffer.push(0); var out = servoConfiguration.indexOfChannelToForward; if (out == undefined) { out = 255; // Cleanflight defines "CHANNEL_FORWARDING_DISABLED" as "(uint8_t)0xFF" } buffer.push(out); //Mock 4 bytes of servoConfiguration.reversedInputSources buffer.push(0); buffer.push(0); buffer.push(0); buffer.push(0); // prepare for next iteration servoIndex++; if (servoIndex == SERVO_CONFIG.length) { nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP_SET_SERVO_CONFIGURATION, buffer, false, nextFunction); } }; self.sendServoMixer = function (onCompleteCallback) { var nextFunction = sendMixer, servoIndex = 0; if (SERVO_RULES.length == 0) { onCompleteCallback(); } else { nextFunction(); } function sendMixer() { var buffer = []; // send one at a time, with index var servoRule = SERVO_RULES.get()[servoIndex]; if (semver.lt(CONFIG.flightControllerVersion, "2.2.0")) { buffer.push(servoIndex); buffer.push(servoRule.getTarget()); buffer.push(servoRule.getInput()); if (semver.gte(CONFIG.flightControllerVersion, "2.1.0")) { buffer.push(lowByte(servoRule.getRate())); buffer.push(highByte(servoRule.getRate())); } else { buffer.push(servoRule.getRate()); } buffer.push(servoRule.getSpeed()); buffer.push(0); buffer.push(0); buffer.push(0); // prepare for next iteration servoIndex++; if (servoIndex == SERVO_RULES.getServoRulesCount()) { //This is the last rule. Not pretty, but we have to send all rules nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP_SET_SERVO_MIX_RULE, buffer, false, nextFunction); } else { //INAV 2.2 uses different MSP frame buffer.push(servoIndex); buffer.push(servoRule.getTarget()); buffer.push(servoRule.getInput()); buffer.push(lowByte(servoRule.getRate())); buffer.push(highByte(servoRule.getRate())); buffer.push(servoRule.getSpeed()); buffer.push(servoRule.getConditionId()); // prepare for next iteration servoIndex++; if (servoIndex == SERVO_RULES.getServoRulesCount()) { //This is the last rule. Not pretty, but we have to send all rules nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP2_INAV_SET_SERVO_MIXER, buffer, false, nextFunction); } } }; self.sendMotorMixer = function (onCompleteCallback) { var nextFunction = sendMixer, servoIndex = 0; if (MOTOR_RULES.length === 0) { onCompleteCallback(); } else { nextFunction(); } function sendMixer() { var buffer = []; // send one at a time, with index var rule = MOTOR_RULES.get()[servoIndex]; if (rule) { buffer.push(servoIndex); buffer.push(lowByte(rule.getThrottleForMsp())); buffer.push(highByte(rule.getThrottleForMsp())); buffer.push(lowByte(rule.getRollForMsp())); buffer.push(highByte(rule.getRollForMsp())); buffer.push(lowByte(rule.getPitchForMsp())); buffer.push(highByte(rule.getPitchForMsp())); buffer.push(lowByte(rule.getYawForMsp())); buffer.push(highByte(rule.getYawForMsp())); // prepare for next iteration servoIndex++; if (servoIndex == MOTOR_RULES.getMotorCount()) { //This is the last rule. Not pretty, but we have to send all rules nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP2_COMMON_SET_MOTOR_MIXER, buffer, false, nextFunction); } else { onCompleteCallback(); } } }; self.loadLogicConditions = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.2.0")) { MSP.send_message(MSPCodes.MSP2_INAV_LOGIC_CONDITIONS, false, false, callback); } else { callback(); } } self.sendLogicConditions = function (onCompleteCallback) { let nextFunction = sendCondition, conditionIndex = 0; if (LOGIC_CONDITIONS.getCount() == 0 || semver.lt(CONFIG.flightControllerVersion, "2.2.0")) { onCompleteCallback(); } else { nextFunction(); } function sendCondition() { let buffer = []; // send one at a time, with index, 14 bytes per one condition let condition = LOGIC_CONDITIONS.get()[conditionIndex]; buffer.push(conditionIndex); buffer.push(condition.getEnabled()); buffer.push(condition.getOperation()); buffer.push(condition.getOperandAType()); buffer.push(specificByte(condition.getOperandAValue(), 0)); buffer.push(specificByte(condition.getOperandAValue(), 1)); buffer.push(specificByte(condition.getOperandAValue(), 2)); buffer.push(specificByte(condition.getOperandAValue(), 3)); buffer.push(condition.getOperandBType()); buffer.push(specificByte(condition.getOperandBValue(), 0)); buffer.push(specificByte(condition.getOperandBValue(), 1)); buffer.push(specificByte(condition.getOperandBValue(), 2)); buffer.push(specificByte(condition.getOperandBValue(), 3)); buffer.push(condition.getFlags()); // prepare for next iteration conditionIndex++; if (conditionIndex == LOGIC_CONDITIONS.getCount()) { //This is the last rule. Not pretty, but we have to send all rules nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP2_INAV_SET_LOGIC_CONDITIONS, buffer, false, nextFunction); } }; self.sendModeRanges = function (onCompleteCallback) { var nextFunction = send_next_mode_range; var modeRangeIndex = 0; if (MODE_RANGES.length == 0) { onCompleteCallback(); } else { send_next_mode_range(); } function send_next_mode_range() { var modeRange = MODE_RANGES[modeRangeIndex]; var buffer = []; buffer.push(modeRangeIndex); buffer.push(modeRange.id); buffer.push(modeRange.auxChannelIndex); buffer.push((modeRange.range.start - 900) / 25); buffer.push((modeRange.range.end - 900) / 25); // prepare for next iteration modeRangeIndex++; if (modeRangeIndex == MODE_RANGES.length) { nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP_SET_MODE_RANGE, buffer, false, nextFunction); } }; /** * Send a request to read a block of data from the dataflash at the given address and pass that address and a dataview * of the returned data to the given callback (or null for the data if an error occured). */ self.dataflashRead = function (address, onDataCallback) { var buffer = []; buffer.push(address & 0xFF); buffer.push((address >> 8) & 0xFF); buffer.push((address >> 16) & 0xFF); buffer.push((address >> 24) & 0xFF); // For API > 2.0.0 we support requesting payload size - request 4KiB and let firmware decide what actual size to send if (CONFIG.apiVersion && semver.gte(CONFIG.apiVersion, "2.0.0")) { buffer.push(lowByte(4096)); buffer.push(highByte(4096)); } MSP.send_message(MSPCodes.MSP_DATAFLASH_READ, buffer, false, function (response) { var chunkAddress = response.data.getUint32(0, 1); // Verify that the address of the memory returned matches what the caller asked for if (chunkAddress == address) { /* Strip that address off the front of the reply and deliver it separately so the caller doesn't have to * figure out the reply format: */ onDataCallback(address, new DataView(response.data.buffer, response.data.byteOffset + 4, response.data.buffer.byteLength - 4)); } else { // Report error onDataCallback(address, null); } }); }; self.sendRxFailConfig = function (onCompleteCallback) { var nextFunction = send_next_rxfail_config; var rxFailIndex = 0; if (RXFAIL_CONFIG.length == 0) { onCompleteCallback(); } else { send_next_rxfail_config(); } function send_next_rxfail_config() { var rxFail = RXFAIL_CONFIG[rxFailIndex]; var buffer = []; buffer.push(rxFailIndex); buffer.push(rxFail.mode); buffer.push(lowByte(rxFail.value)); buffer.push(highByte(rxFail.value)); // prepare for next iteration rxFailIndex++; if (rxFailIndex == RXFAIL_CONFIG.length) { nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP_SET_RXFAIL_CONFIG, buffer, false, nextFunction); } }; /** * @return {number} */ self.SERIAL_PORT_FUNCTIONSToMask = function (functions) { var mask = 0; for (var index = 0; index < functions.length; index++) { var key = functions[index]; var bitIndex = mspHelper.SERIAL_PORT_FUNCTIONS[key]; if (bitIndex >= 0) { mask = bit_set(mask, bitIndex); } } return mask; }; self.serialPortFunctionMaskToFunctions = function (functionMask) { var functions = []; var keys = Object.keys(mspHelper.SERIAL_PORT_FUNCTIONS); for (var index = 0; index < keys.length; index++) { var key = keys[index]; var bit = mspHelper.SERIAL_PORT_FUNCTIONS[key]; if (bit_check(functionMask, bit)) { functions.push(key); } } return functions; }; self.sendServoMixRules = function (onCompleteCallback) { // TODO implement onCompleteCallback(); }; self.sendAdjustmentRanges = function (onCompleteCallback) { var nextFunction = send_next_adjustment_range; var adjustmentRangeIndex = 0; if (ADJUSTMENT_RANGES.length == 0) { onCompleteCallback(); } else { send_next_adjustment_range(); } function send_next_adjustment_range() { var adjustmentRange = ADJUSTMENT_RANGES[adjustmentRangeIndex]; var buffer = []; buffer.push(adjustmentRangeIndex); buffer.push(adjustmentRange.slotIndex); buffer.push(adjustmentRange.auxChannelIndex); buffer.push((adjustmentRange.range.start - 900) / 25); buffer.push((adjustmentRange.range.end - 900) / 25); buffer.push(adjustmentRange.adjustmentFunction); buffer.push(adjustmentRange.auxSwitchChannelIndex); // prepare for next iteration adjustmentRangeIndex++; if (adjustmentRangeIndex == ADJUSTMENT_RANGES.length) { nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP_SET_ADJUSTMENT_RANGE, buffer, false, nextFunction); } }; self.sendLedStripColors = function (onCompleteCallback) { if (LED_COLORS.length == 0) { onCompleteCallback(); } else { var buffer = []; for (var colorIndex = 0; colorIndex < LED_COLORS.length; colorIndex++) { var color = LED_COLORS[colorIndex]; buffer.push(specificByte(color.h, 0)); buffer.push(specificByte(color.h, 1)); buffer.push(color.s); buffer.push(color.v); } MSP.send_message(MSPCodes.MSP_SET_LED_COLORS, buffer, false, onCompleteCallback); } }; self.sendLedStripConfig = function (onCompleteCallback) { var nextFunction = send_next_led_strip_config; var ledIndex = 0; if (LED_STRIP.length == 0) { onCompleteCallback(); } else { send_next_led_strip_config(); } function send_next_led_strip_config() { var led = LED_STRIP[ledIndex]; /* var led = { directions: directions, functions: functions, x: data.getUint8(offset++, 1), y: data.getUint8(offset++, 1), color: data.getUint8(offset++, 1) }; */ var buffer = [], directionLetterIndex, functionLetterIndex, bitIndex; buffer.push(ledIndex); if (semver.lt(CONFIG.apiVersion, "1.20.0")) { var directionMask = 0; for (directionLetterIndex = 0; directionLetterIndex < led.directions.length; directionLetterIndex++) { bitIndex = MSP.ledDirectionLetters.indexOf(led.directions[directionLetterIndex]); if (bitIndex >= 0) { directionMask = bit_set(directionMask, bitIndex); } } buffer.push(specificByte(directionMask, 0)); buffer.push(specificByte(directionMask, 1)); var functionMask = 0; for (functionLetterIndex = 0; functionLetterIndex < led.functions.length; functionLetterIndex++) { bitIndex = MSP.ledFunctionLetters.indexOf(led.functions[functionLetterIndex]); if (bitIndex >= 0) { functionMask = bit_set(functionMask, bitIndex); } } buffer.push(specificByte(functionMask, 0)); buffer.push(specificByte(functionMask, 1)); buffer.push(led.x); buffer.push(led.y); buffer.push(led.color); } else { var mask = 0; /* ledDirectionLetters: ['n', 'e', 's', 'w', 'u', 'd'], // in LSB bit order ledFunctionLetters: ['i', 'w', 'f', 'a', 't', 'r', 'c', 'g', 's', 'b', 'l'], // in LSB bit order ledBaseFunctionLetters: ['c', 'f', 'a', 'l', 's', 'g', 'r'], // in LSB bit ledOverlayLetters: ['t', 'o', 'b', 'n', 'i', 'w'], // in LSB bit */ mask |= (led.y << 0); mask |= (led.x << 4); for (functionLetterIndex = 0; functionLetterIndex < led.functions.length; functionLetterIndex++) { var fnIndex = MSP.ledBaseFunctionLetters.indexOf(led.functions[functionLetterIndex]); if (fnIndex >= 0) { mask |= (fnIndex << 8); break; } } for (var overlayLetterIndex = 0; overlayLetterIndex < led.functions.length; overlayLetterIndex++) { bitIndex = MSP.ledOverlayLetters.indexOf(led.functions[overlayLetterIndex]); if (bitIndex >= 0) { mask |= bit_set(mask, bitIndex + 12); } } mask |= (led.color << 18); for (directionLetterIndex = 0; directionLetterIndex < led.directions.length; directionLetterIndex++) { bitIndex = MSP.ledDirectionLetters.indexOf(led.directions[directionLetterIndex]); if (bitIndex >= 0) { mask |= bit_set(mask, bitIndex + 22); } } mask |= (0 << 28); // parameters buffer.push(specificByte(mask, 0)); buffer.push(specificByte(mask, 1)); buffer.push(specificByte(mask, 2)); buffer.push(specificByte(mask, 3)); } // prepare for next iteration ledIndex++; if (ledIndex == LED_STRIP.length) { nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP_SET_LED_STRIP_CONFIG, buffer, false, nextFunction); } }; self.sendLedStripModeColors = function (onCompleteCallback) { var nextFunction = send_next_led_strip_mode_color; var index = 0; if (LED_MODE_COLORS.length == 0) { onCompleteCallback(); } else { send_next_led_strip_mode_color(); } function send_next_led_strip_mode_color() { var buffer = []; var mode_color = LED_MODE_COLORS[index]; buffer.push(mode_color.mode); buffer.push(mode_color.direction); buffer.push(mode_color.color); // prepare for next iteration index++; if (index == LED_MODE_COLORS.length) { nextFunction = onCompleteCallback; } MSP.send_message(MSPCodes.MSP_SET_LED_STRIP_MODECOLOR, buffer, false, nextFunction); } }; /* * Basic sending methods used for chaining purposes */ /** * @deprecated * @param callback */ self.loadMspIdent = function (callback) { MSP.send_message(MSPCodes.MSP_IDENT, false, false, callback); }; self.loadINAVPidConfig = function (callback) { MSP.send_message(MSPCodes.MSP_INAV_PID, false, false, callback); }; self.loadLoopTime = function (callback) { MSP.send_message(MSPCodes.MSP_LOOP_TIME, false, false, callback); }; self.loadAdvancedConfig = function (callback) { MSP.send_message(MSPCodes.MSP_ADVANCED_CONFIG, false, false, callback); }; self.loadFilterConfig = function (callback) { MSP.send_message(MSPCodes.MSP_FILTER_CONFIG, false, false, callback); }; self.loadPidAdvanced = function (callback) { MSP.send_message(MSPCodes.MSP_PID_ADVANCED, false, false, callback); }; self.loadRcTuningData = function (callback) { MSP.send_message(MSPCodes.MSP_RC_TUNING, false, false, callback); }; self.loadRateProfileData = function (callback) { MSP.send_message(MSPCodes.MSPV2_INAV_RATE_PROFILE, false, false, callback); }; self.loadPidData = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, '2.2.0')) { MSP.send_message(MSPCodes.MSP2_PID, false, false, callback); } else { MSP.send_message(MSPCodes.MSP_PID, false, false, callback); } }; self.loadPidNames = function (callback) { MSP.send_message(MSPCodes.MSP_PIDNAMES, false, false, callback); }; self.loadStatus = function (callback) { MSP.send_message(MSPCodes.MSP_STATUS, false, false, callback); }; self.loadBfConfig = function (callback) { MSP.send_message(MSPCodes.MSP_BF_CONFIG, false, false, callback); }; self.queryFcStatus = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, '2.0.0')) MSP.send_message(MSPCodes.MSPV2_INAV_STATUS, false, false, callback); else MSP.send_message(MSPCodes.MSP_STATUS_EX, false, false, callback); }; self.loadMisc = function (callback) { MSP.send_message(MSPCodes.MSP_MISC, false, false, callback); }; self.loadMiscV2 = function (callback) { MSP.send_message(MSPCodes.MSPV2_INAV_MISC, false, false, callback); }; self.loadOutputMapping = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, '2.0.0')) MSP.send_message(MSPCodes.MSPV2_INAV_OUTPUT_MAPPING, false, false, callback); else { OUTPUT_MAPPING.flush(); callback(); } }; self.loadBatteryConfig = function (callback) { MSP.send_message(MSPCodes.MSPV2_BATTERY_CONFIG, false, false, callback); }; self.loadArmingConfig = function (callback) { MSP.send_message(MSPCodes.MSP_ARMING_CONFIG, false, false, callback); }; self.loadRxConfig = function (callback) { if (semver.gte(CONFIG.apiVersion, "1.21.0")) { MSP.send_message(MSPCodes.MSP_RX_CONFIG, false, false, callback); } else { callback(); } }; self.load3dConfig = function (callback) { MSP.send_message(MSPCodes.MSP_3D, false, false, callback); }; self.loadSensorAlignment = function (callback) { MSP.send_message(MSPCodes.MSP_SENSOR_ALIGNMENT, false, false, callback); }; self.loadSensorConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SENSOR_CONFIG, false, false, callback); }; self.loadSensorStatus = function (callback) { MSP.send_message(MSPCodes.MSP_SENSOR_STATUS, false, false, callback); }; self.loadRcDeadband = function (callback) { MSP.send_message(MSPCodes.MSP_RC_DEADBAND, false, false, callback); }; self.loadRcMap = function (callback) { MSP.send_message(MSPCodes.MSP_RX_MAP, false, false, callback); }; self.loadRcData = function (callback) { MSP.send_message(MSPCodes.MSP_RC, false, false, callback); }; self.loadAccTrim = function (callback) { MSP.send_message(MSPCodes.MSP_ACC_TRIM, false, false, callback); }; self.loadAnalog = function (callback) { MSP.send_message(MSPCodes.MSP_ANALOG, false, false, callback); }; self.saveToEeprom = function saveToEeprom(callback) { MSP.send_message(MSPCodes.MSP_EEPROM_WRITE, false, false, callback); }; self.saveINAVPidConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_INAV_PID, mspHelper.crunch(MSPCodes.MSP_SET_INAV_PID), false, callback); }; self.saveLooptimeConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_LOOP_TIME, mspHelper.crunch(MSPCodes.MSP_SET_LOOP_TIME), false, callback); }; self.saveAdvancedConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_ADVANCED_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_ADVANCED_CONFIG), false, callback); }; self.saveFilterConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_FILTER_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_FILTER_CONFIG), false, callback); }; self.savePidData = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, '2.2.0')) { MSP.send_message(MSPCodes.MSP2_SET_PID, mspHelper.crunch(MSPCodes.MSP2_SET_PID), false, callback); } else { MSP.send_message(MSPCodes.MSP_SET_PID, mspHelper.crunch(MSPCodes.MSP_SET_PID), false, callback); } }; self.saveRcTuningData = function (callback) { MSP.send_message(MSPCodes.MSP_SET_RC_TUNING, mspHelper.crunch(MSPCodes.MSP_SET_RC_TUNING), false, callback); }; self.saveRateProfileData = function (callback) { MSP.send_message(MSPCodes.MSPV2_INAV_SET_RATE_PROFILE, mspHelper.crunch(MSPCodes.MSPV2_INAV_SET_RATE_PROFILE), false, callback); }; self.savePidAdvanced = function (callback) { MSP.send_message(MSPCodes.MSP_SET_PID_ADVANCED, mspHelper.crunch(MSPCodes.MSP_SET_PID_ADVANCED), false, callback); }; self.saveBfConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_BF_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_BF_CONFIG), false, callback); }; self.saveMisc = function (callback) { MSP.send_message(MSPCodes.MSP_SET_MISC, mspHelper.crunch(MSPCodes.MSP_SET_MISC), false, callback); }; self.saveMiscV2 = function (callback) { MSP.send_message(MSPCodes.MSPV2_INAV_SET_MISC, mspHelper.crunch(MSPCodes.MSPV2_INAV_SET_MISC), false, callback); }; self.saveBatteryConfig = function (callback) { MSP.send_message(MSPCodes.MSPV2_SET_BATTERY_CONFIG, mspHelper.crunch(MSPCodes.MSPV2_SET_BATTERY_CONFIG), false, callback); }; self.save3dConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_3D, mspHelper.crunch(MSPCodes.MSP_SET_3D), false, callback); }; self.saveSensorAlignment = function (callback) { MSP.send_message(MSPCodes.MSP_SET_SENSOR_ALIGNMENT, mspHelper.crunch(MSPCodes.MSP_SET_SENSOR_ALIGNMENT), false, callback); }; self.saveAccTrim = function (callback) { MSP.send_message(MSPCodes.MSP_SET_ACC_TRIM, mspHelper.crunch(MSPCodes.MSP_SET_ACC_TRIM), false, callback); }; self.saveArmingConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_ARMING_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_ARMING_CONFIG), false, callback); }; self.saveRxConfig = function (callback) { if (semver.gte(CONFIG.apiVersion, "1.21.0")) { MSP.send_message(MSPCodes.MSP_SET_RX_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_RX_CONFIG), false, callback); } else { callback(); } }; self.saveSensorConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_SENSOR_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_SENSOR_CONFIG), false, callback); }; self.loadNavPosholdConfig = function (callback) { MSP.send_message(MSPCodes.MSP_NAV_POSHOLD, false, false, callback); }; self.saveNavPosholdConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_NAV_POSHOLD, mspHelper.crunch(MSPCodes.MSP_SET_NAV_POSHOLD), false, callback); }; self.loadPositionEstimationConfig = function (callback) { MSP.send_message(MSPCodes.MSP_POSITION_ESTIMATION_CONFIG, false, false, callback); }; self.savePositionEstimationConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_POSITION_ESTIMATION_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_POSITION_ESTIMATION_CONFIG), false, callback); }; self.loadCalibrationData = function (callback) { MSP.send_message(MSPCodes.MSP_CALIBRATION_DATA, false, false, callback); }; self.saveCalibrationData = function (callback) { MSP.send_message(MSPCodes.MSP_SET_CALIBRATION_DATA, mspHelper.crunch(MSPCodes.MSP_SET_CALIBRATION_DATA), false, callback); }; self.loadRthAndLandConfig = function (callback) { MSP.send_message(MSPCodes.MSP_RTH_AND_LAND_CONFIG, false, false, callback); }; self.saveRthAndLandConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_RTH_AND_LAND_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_RTH_AND_LAND_CONFIG), false, callback); }; self.loadFwConfig = function (callback) { MSP.send_message(MSPCodes.MSP_FW_CONFIG, false, false, callback); }; self.saveFwConfig = function (callback) { MSP.send_message(MSPCodes.MSP_SET_FW_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_FW_CONFIG), false, callback); }; self.getMissionInfo = function (callback) { MSP.send_message(MSPCodes.MSP_WP_GETINFO, false, false, callback); }; self._getSetting = function (name) { if (semver.lt(CONFIG.flightControllerVersion, '2.0.0')) { return self._getLegacySetting(name); } if (SETTINGS[name]) { return Promise.resolve(SETTINGS[name]); } var data = []; self._encodeSettingReference(name, null, data); return MSP.promise(MSPCodes.MSP2_COMMON_SETTING_INFO, data).then(function (result) { const MODE_LOOKUP = 1 << 6; var settingTypes = { 0: "uint8_t", 1: "int8_t", 2: "uint16_t", 3: "int16_t", 4: "uint32_t", 5: "float", 6: "string", }; var setting = {}; // Discard PG ID result.data.readU16(); var type = result.data.readU8(); setting.type = settingTypes[type]; if (!setting.type) { console.log("Unknown setting type " + type + " for setting '" + name + "'"); return null; } // Discard section result.data.readU8(); setting.mode = result.data.readU8(); setting.min = result.data.read32(); setting.max = result.data.readU32(); setting.index = result.data.readU16(); // Discard profile info result.data.readU8(); result.data.readU8(); if (setting.mode == MODE_LOOKUP) { var values = []; for (var ii = setting.min; ii <= setting.max; ii++) { values.push(result.data.readString()); } setting.table = {values: values}; } SETTINGS[name] = setting; return setting; }); } self._getLegacySetting = function (name) { var promise; if (SETTINGS) { promise = Promise.resolve(SETTINGS); } else { promise = new Promise(function (resolve, reject) { $.ajax({ url: chrome.runtime.getURL('/resources/settings.json'), dataType: 'json', error: function (jqXHR, text, error) { reject(error); }, success: function (data) { SETTINGS = data; resolve(data); } }); }); } return promise.then(function (data) { return data[name]; }); }; self._encodeSettingReference = function (name, index, data) { if (Number.isInteger(index)) { data.push8(0); data.push16(index); } else { for (var ii = 0; ii < name.length; ii++) { data.push(name.charCodeAt(ii)); } data.push(0); } }; self.getSetting = function (name) { var $this = this; return this._getSetting(name).then(function (setting) { if (!setting) { // Setting not available in the FC return null; } var data = []; $this._encodeSettingReference(name, setting.index, data); return MSP.promise(MSPCodes.MSPV2_SETTING, data).then(function (resp) { var value; switch (setting.type) { case "uint8_t": value = resp.data.getUint8(0); break; case "int8_t": value = resp.data.getInt8(0); break; case "uint16_t": value = resp.data.getUint16(0, true); break; case "int16_t": value = resp.data.getInt16(0, true); break; case "uint32_t": value = resp.data.getUint32(0, true); break; case "float": var fi32 = resp.data.getUint32(0, true); var buf = new ArrayBuffer(4); (new Uint32Array(buf))[0] = fi32; value = (new Float32Array(buf))[0]; break; default: throw "Unknown setting type " + setting.type; } return {setting: setting, value: value}; }); }); }; self.encodeSetting = function (name, value) { return this._getSetting(name).then(function (setting) { if (setting.table && !Number.isInteger(value)) { var found = false; for (var ii = 0; ii < setting.table.values.length; ii++) { if (setting.table.values[ii] == value) { value = ii; found = true; break; } } if (!found) { throw 'Invalid value "' + value + '" for setting ' + name; } } var data = []; self._encodeSettingReference(name, setting.index, data); switch (setting.type) { case "uint8_t": case "int8_t": data.push8(value); break; case "uint16_t": case "int16_t": data.push16(value); break; case "uint32_t": data.push32(value); break; case "float": var buf = new ArrayBuffer(4); (new Float32Array(buf))[0] = value; var if32 = (new Uint32Array(buf))[0]; data.push32(if32); break; default: throw "Unknown setting type " + setting.type; } return data; }); }; self.setSetting = function (name, value) { this.encodeSetting(name, value).then(function (data) { return MSP.promise(MSPCodes.MSPV2_SET_SETTING, data); }); }; self.getRTC = function (callback) { MSP.send_message(MSPCodes.MSP_RTC, false, false, function (resp) { var seconds = resp.data.read32(); var millis = resp.data.readU16(); if (callback) { callback(seconds, millis); } }); }; self.setRTC = function (callback) { var now = Date.now(); var secs = now / 1000; var millis = now % 1000; var data = []; data.push32(secs); data.push16(millis); MSP.send_message(MSPCodes.MSP_SET_RTC, data, false, callback); }; self.loadServoConfiguration = function (callback) { MSP.send_message(MSPCodes.MSP_SERVO_CONFIGURATIONS, false, false, callback); }; self.loadServoMixRules = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.2.0")) { MSP.send_message(MSPCodes.MSP2_INAV_SERVO_MIXER, false, false, callback); } else { MSP.send_message(MSPCodes.MSP_SERVO_MIX_RULES, false, false, callback); } }; self.loadMotorMixRules = function (callback) { MSP.send_message(MSPCodes.MSP2_COMMON_MOTOR_MIXER, false, false, callback); }; self.loadMotors = function (callback) { MSP.send_message(MSPCodes.MSP_MOTOR, false, false, callback); }; self.getCraftName = function(callback) { MSP.send_message(MSPCodes.MSP_NAME, false, false, function(resp) { var name = resp.data.readString(); if (callback) { callback(name); } }); }; self.setCraftName = function(name, callback) { var data = []; name = name || ""; for (var ii = 0; ii < name.length; ii++) { data.push(name.charCodeAt(ii)); } MSP.send_message(MSPCodes.MSP_SET_NAME, data, false, callback); }; self.loadMixerConfig = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, "1.9.1")) { MSP.send_message(MSPCodes.MSP2_INAV_MIXER, false, false, callback); } else { callback(); } }; self.saveMixerConfig = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, "1.9.1")) { MSP.send_message(MSPCodes.MSP2_INAV_SET_MIXER, mspHelper.crunch(MSPCodes.MSP2_INAV_SET_MIXER), false, callback); } else { callback(); } }; self.loadVTXConfig = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { MSP.send_message(MSPCodes.MSP_VTX_CONFIG, false, false, callback); } else { callback(); } }; self.saveVTXConfig = function(callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { MSP.send_message(MSPCodes.MSP_SET_VTX_CONFIG, mspHelper.crunch(MSPCodes.MSP_SET_VTX_CONFIG), false, callback); } else { callback(); } }; self.loadBrakingConfig = function(callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.1.0")) { MSP.send_message(MSPCodes.MSP2_INAV_MC_BRAKING, false, false, callback); } else { callback(); } } self.saveBrakingConfig = function(callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.1.0")) { MSP.send_message(MSPCodes.MSP2_INAV_SET_MC_BRAKING, mspHelper.crunch(MSPCodes.MSP2_INAV_SET_MC_BRAKING), false, callback); } else { callback(); } }; self.loadParameterGroups = function(callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.0.0")) { MSP.send_message(MSPCodes.MSP2_COMMON_PG_LIST, false, false, function (resp) { var groups = []; while (resp.data.offset < resp.data.byteLength) { var id = resp.data.readU16(); var start = resp.data.readU16(); var end = resp.data.readU16(); groups.push({id: id, start: start, end: end}); } if (callback) { callback(groups); } }); } else if (callback) { callback(); } }; self.loadBrakingConfig = function(callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.1.0")) { MSP.send_message(MSPCodes.MSP2_INAV_MC_BRAKING, false, false, callback); } else { callback(); } } self.loadSensorStatus = function (callback) { if (semver.gte(CONFIG.flightControllerVersion, "2.3.0")) { MSP.send_message(MSPCodes.MSP2_INAV_LOGIC_CONDITIONS_STATUS, false, false, callback); } else { callback(); } }; return self; })(GUI);