import os,sys,argparse,yaml,types,select,serial,logging,time from multiprocessing import Process, Pipe # Message header id's for messages passed between the application # process and the microcontroller and video processes QUIT_MSG = 0xffff DATA_MSG = 0xfffe ERROR_MSG = 0xfffd def _reset_port(port): port.reset_input_buffer() port.reset_output_buffer() port.send_break() #self.reportResetFl = True #self.reportStatusFl = True def _serial_process_func( serial_dev, baud, sensor_count, pipe ): reset_N = 0 drop_N = 0 noSync_N = 0 with serial.Serial(serial_dev, baud) as port: while True: # get the count of available bytes in the serial port buffer bytes_waiting_N = port.in_waiting # if no serial port bytes are available then sleep .... if bytes_waiting_N == 0: time.sleep(0.01) # ... for 10 ms else: # read the serial port ... v = port.read(bytes_waiting_N) pipe.send((DATA_MSG,v)) # ... and send it to the parent msg = None if pipe.poll(): # non-blocking check for parent process messages try: msg = pipe.recv() except EOFError: break # if an incoming message was received if msg != None: # this is a shutdown msg if msg[0] == QUIT_MSG: pipe.send(msg) # ... send quit msg back break # this is a data xmit msg elif msg[0] == DATA_MSG: port.write(msg[1]) class SessionProcess(Process): def __init__(self,target,name,args=()): self.parent_end, child_end = Pipe() super(SessionProcess, self).__init__(target=target,name=name,args=args + (child_end,)) self.doneFl = False def quit(self): # send quit msg to the child process self.parent_end.send((QUIT_MSG,0)) def send(self,msg_id,value): # send a msg to the child process self.parent_end.send((msg_id,value)) def recv(self): x = None if not self.doneFl and self.parent_end.poll(): x = self.parent_end.recv() if x[0] == QUIT_MSG: self.doneFl = True return x def isDone(self): return self.doneFl class SerialProcess(SessionProcess): def __init__(self,serial_device,baud,foo): super(SerialProcess, self).__init__(_serial_process_func,"Serial",args=(serial_device,baud,foo)) class App: def __init__( self, cfg ): self.cfg = cfg self.serialProc = SerialProcess(cfg.serial_dev,cfg.serial_baud,0) def _update( self, quittingFl=False ): if self.serialProc.isDone(): return False while True: msg = serialProc.recv() # no serial msg's were received if msg is None: break if msg[0] == DATA_MSG: print("in:",msg[1]) def _parse_error( self, msg, cmd_str=None ): if cmd_str: msg += " Command:{}".format(cmd_str) return (None,msg) def _parse_int( self, token, var_label, min_value, max_value ): # convert the i2c destination address to an integer try: int_value = int(token) except ValueError: return self._parse_error("Synax error: '{}' is not a legal integer.".format(token)) # validate the i2c address value if min_value > int_value or int_value > max_value: return self._parse_error("Syntax error: '{}' {} out of range 0 to {}.".format(token,int_value,max_value)) return (int_value,None) def parse_app_cmd( self, cmd_str ): """ Command syntax """ op_tok_idx = 0 i2c_tok_idx = 1 val_tok_idx = 2 cmdD = { 'p':{ 'reg':0, 'n':1, 'min':0, 'max':4 }, # timer pre-scalar: sets timer tick rate 't':{ 'reg':1, 'n':2, 'min':0, 'max':10e7 }, # microseconds 'd':{ 'reg':3, 'n':1, 'min':0, 'max':100 }, # pwm duty cylce (0-100%) 'f':{ 'reg':4, 'n':1, 'min':1, 'max':5 }, # pwm frequency divider 1=1,2=8,3=64,4=256,5=1024 } cmd_str = cmd_str.strip() tokenL = cmd_str.split(' ') # validate the counf of tokens if len(tokenL) != 3: return self._parse_error("Syntax error: Invalid token count.",cmd_str) opcode = tokenL[op_tok_idx] # validate the opcode if opcode not in cmdD: return self._parse_error("Syntax error: Invalid opcode.",cmd_str) # convert the i2c destination address to an integer i2c_addr, msg = self._parse_int( tokenL[i2c_tok_idx], "i2c address", 0,127 ) if i2c_addr is None: return (None,msg) d = cmdD[ opcode ] # get the value value, msg = self._parse_int( tokenL[val_tok_idx], "command value", d['min'], d['max'] ) if value is None: return (value,msg) dataL = [ value ] if opcode == 't': coarse = int(value/(32*254)) fine = int((value - coarse*32*254)/32) print(coarse,fine) dataL = [ coarse, fine ] elif opcode == 'd': dataL = [ int(value * 255 / 100.0) ] cmd_bV = bytearray( [ ord('w'), i2c_addr, d['reg'], len(dataL) ] + dataL ) if False: print('cmd_bV:') for x in cmd_bV: print(int(x)) return (cmd_bV,None) def parse_cmd( self, cmd_str ): op_tok_idx = 0 i2c_tok_idx = 1 reg_tok_idx = 2 rdn_tok_idx = 3 cmd_str = cmd_str.strip() # if this is a high level command if cmd_str[0] not in ['r','w']: return self.parse_app_cmd( cmd_str ) # convert the command string to tokens tokenL = cmd_str.split(' ') # no commands require fewer than 4 tokens if len(tokenL) < 4: return self._parse_error("Syntax error: Missing tokens.") # get the command opcode op_code = tokenL[ op_tok_idx ] # validate the opcode if op_code not in [ 'r','w']: return self._parse_error("Unrecognized opcode: {}".format( op_code )) # validate the token count given the opcode if op_code == 'r' and len(tokenL) != 4: return self._parse_error("Syntax error: Illegal read syntax.") if op_code == 'w' and len(tokenL) < 4: return self._parse_error("Syntax error: Illegal write command too short.") # convert the i2c destination address to an integer i2c_addr, msg = self._parse_int( tokenL[i2c_tok_idx], "i2c address", 0,127 ) if i2c_addr is None: return (None,msg) reg_addr, msg = self._parse_int( tokenL[reg_tok_idx], "reg address", 0, 255 ) if reg_addr is None: return (None,msg) dataL = [] # parse and validate the count of bytes to read if op_code == 'r': op_byteN, msg = self._parse_int( tokenL[ rdn_tok_idx ], "read byte count", 0, 255 ) if op_byteN is None: return (None,msg) # parse and validate the values to write elif op_code == 'w': for j,i in enumerate(range(reg_tok_idx+1,len(tokenL))): value, msg = self._parse_int( tokenL[i], "write value: %i" % (j), 0, 255 ) if value is None: return (None,msg) dataL.append(value) op_byteN = len(dataL) # form the command into a byte array cmd_bV = bytearray( [ ord(op_code), i2c_addr, reg_addr, op_byteN ] + dataL ) # s = "" # for i in range(len(cmd_bV)): # s += "%i " % (cmd_bV[i]) # print(s) return (cmd_bV,None) def run( self ): self.serialProc.start() print("'quit' to exit") time_out_secs = 1 while True: i, o, e = select.select( [sys.stdin], [], [], time_out_secs ) if (i): s = sys.stdin.readline().strip() if s == 'quit' or s == 'q': break cmd_bV,err_msg = self.parse_cmd(s) if cmd_bV is None: print(err_msg) else: self.serialProc.send( DATA_MSG, cmd_bV ) else: # wait timed out msg = self.serialProc.recv() # if a serial msg was received if msg is not None and msg[0] == DATA_MSG: str = "" for i in range(len(msg[1])): str += "{} ".format(int(msg[1][i])) print("ser:",str) self.serialProc.quit() def parse_args(): """Parse the command line arguments.""" descStr = """Picadae auto-calibrate.""" logL = ['debug','info','warning','error','critical'] ap = argparse.ArgumentParser(description=descStr) ap.add_argument("-s","--setup", default="picadae_cmd.yml", help="YAML configuration file.") ap.add_argument("-c","--cmd", nargs="*", help="Give a command as multiple tokens") ap.add_argument("-r","--run", help="Run a named command list from the setup file.") ap.add_argument("-l","--log_level",choices=logL, default="warning", help="Set logging level: debug,info,warning,error,critical. Default:warning") return ap.parse_args() def parse_yaml_cfg( fn ): """Parse the YAML configuration file.""" cfg = None with open(fn,"r") as f: cfgD = yaml.load(f, Loader=yaml.FullLoader) cfg = types.SimpleNamespace(**cfgD['picadae_cmd']) return cfg if __name__ == "__main__": args = parse_args() cfg = parse_yaml_cfg( args.setup ) app = App(cfg) app.run()