uint8_t Gimbal::SBGC_cmd_angles_unpack(angulos &p, SerialCommand &cmd) { for (uint8_t i = 0; i < 3; i++) { switch (i) { case 0: p.roll = cmd.readWord(); p.roll = p.roll*ESCALA; break; case 1: p.pitch = cmd.readWord(); p.pitch = p.pitch*ESCALA; break; case 2: p.yaw = cmd.readWord(); p.yaw = p.yaw*ESCALA; break; } //Leemos dos veces, para consumir los datos rc_angle y rc_speed que no son necesarios. cmd.readWord(); cmd.readWord(); } if (cmd.checkLimit()) return 0; else return PARSER_ERROR_WRONG_DATA_SIZE; }
/* * Unpacks SerialCommand object to command structure. * Returns 0 on success, PARSER_ERROR_XX code on fail. */ uint8_t SBGC_cmd_realtime_data_unpack(SBGC_cmd_realtime_data_t &p, SerialCommand &cmd) { #ifdef SBGC_CMD_STRUCT_ALIGNED if(cmd.len <= sizeof(p)) { memcpy(&p, cmd.data, cmd.len); return 0; } else { return PARSER_ERROR_WRONG_DATA_SIZE; } #else for(uint8_t i=0; i<3; i++) { p.sensor_data[i].acc_data = cmd.readWord(); p.sensor_data[i].gyro_data = cmd.readWord(); } p.serial_error_cnt = cmd.readWord(); p.system_error = cmd.readWord(); cmd.skipBytes(4); // reserved cmd.readWordArr(p.rc_raw_data, SBGC_RC_NUM_CHANNELS); cmd.readWordArr(p.imu_angle, 3); cmd.readWordArr(p.frame_imu_angle, 3); cmd.readWordArr(p.target_angle, 3); p.cycle_time_us = cmd.readWord(); p.i2c_error_count = cmd.readWord(); cmd.readByte(); // reserved p.battery_voltage = cmd.readWord(); p.state_flags1 = cmd.readByte(); p.cur_imu = cmd.readByte(); p.cur_profile = cmd.readByte(); cmd.readBuf(p.motor_power, 3); if(cmd.id == SBGC_CMD_REALTIME_DATA_4) { cmd.readWordArr(p.rotor_angle, 3); cmd.readByte(); // reserved cmd.readWordArr(p.balance_error, 3); p.current = cmd.readWord(); cmd.readWordArr(p.magnetometer_data, 3); p.imu_temp_celcius = cmd.readByte(); p.frame_imu_temp_celcius = cmd.readByte(); cmd.skipBytes(38); } if(cmd.checkLimit()) return 0; else return PARSER_ERROR_WRONG_DATA_SIZE; #endif }