import threading import time import serial import serial.tools.list_ports import logHandler class SerialConnection: def __init__(self): self._ser = None self.port = None self.log_handler = logHandler.get_log_handler() # try connecting to an available port def open(self, port = None, baudrate = 1000000): if port != None: self.port = port if self.port: try: self._ser = serial.Serial(self.port, baudrate) self.log_handler.log_and_print("SERIAL: connected to " + self.port) except serial.SerialException as e: self.log_handler.log_and_print("SERIAL:", e) else: for port, name, _ in serial.tools.list_ports.comports(): try: self._ser = serial.Serial(port, baudrate) self.log_handler.log_and_print("SERIAL: connected to " + port + ", name: " + name) self.port = port break except serial.SerialException as e: self.log_handler.log_and_print("SERIAL:", e) if not self._ser: self.log_handler.log_and_print("SERIAL: no device available") def send(self, bytes): if self._ser: try: return self._ser.write(bytes) except serial.SerialException: self._ser = None else: time.sleep(10) self.open() return None def read(self, n=64): if self._ser: try: return self._ser.read(n) except AttributeError as e: self.log_handler.log_and_print("SERIAL:", e) return None except serial.SerialException as e: self.log_handler.log_and_print("SERIAL:", e) if self._ser.isOpen(): self._ser.close() self._ser = None return None else: time.sleep(10) self.open() return None def readline(self): if self._ser: try: return self._ser.readline() except AttributeError as e: self.log_handler.log_and_print("SERIAL:", e) return None except serial.SerialException as e: self.log_handler.log_and_print("SERIAL:", e) if self._ser.isOpen(): self._ser.close() self._ser = None return None else: time.sleep(10) self.open() return None def isConnected(self): return self._ser != None def close(self): if self._ser: self._ser.close() self._ser = None class ArduinoSlave(SerialConnection): def __init__(self): super().__init__() self.sensorData = [0] * 13 self._recvCbs = [] self._t = threading.Thread(target=self._readSensors, args=()) self._t.daemon = True # thread dies when main thread (only non-daemon thread) exits. def open(self, port = None, baudrate = 1000000): super().open(port, baudrate) if not self._t.is_alive(): self._t.start() def close(self): super().close() def getAcousticRTTs(self): # in microseconds return ( int(self.sensorData[0]) / 16, int(self.sensorData[1]) / 16 ) def getMagneticField(self): # in mT return ( int(self.sensorData[2]) / 1000, int(self.sensorData[3]) / 1000, int(self.sensorData[4]) / 1000 ) def getMagneticOffsets(self): return ( int(self.sensorData[5]) / 1000, int(self.sensorData[6]) / 1000, int(self.sensorData[7]) / 1000, ) def getAccelValues(self): return ( int(self.sensorData[8]) / 1000, int(self.sensorData[9]) / 1000, int(self.sensorData[10]) / 1000, ) def getGyroValues(self): return ( int(self.sensorData[11]) / 1000, # int(self.sensorData[12]) / 1000, # int(self.sensorData[13]) / 1000 # ) def getTemperature(self): # in °C return int(self.sensorData[14]) / 1000 def addRecvCallback(self, cb): self._recvCbs.append(cb) def _readSensors(self): while True: data = super().readline() if data and len(data) > 2: data = str(data, encoding="ASCII", errors="ignore") vals = data[:-2].split('\t') if vals[0] == "DATA:" and len(vals) >= 13: self.sensorData = vals[1:] for cb in self._recvCbs: cb(self.sensorData) elif data.startswith("I2C ERROR"): pass else: self.log_handler.log_and_print("SERIAL: ", data[:-2]) # this allows the usage of a single instance of ArduinoSlave _conn = None def globalArduinoSlave(): global _conn if not _conn: _conn = ArduinoSlave() return _conn if __name__ == "__main__": arduino = ArduinoSlave() def cb(x): print(arduino.getAcousticRTTs(), arduino.getMagneticField(), arduino.getTemperature()) arduino.addRecvCallback(cb) arduino.open() while True: time.sleep(1)