Implemented the (not yet fully working) communication class. Added error handling to move.py and fixed the node list in planettest.py.

This commit is contained in:
d3rped 2018-03-22 02:14:44 +01:00
parent 7cff115075
commit f023393113
5 changed files with 161 additions and 31 deletions

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@ -1,27 +1,153 @@
#!/usr/bin/env python3
# Suggestion: Do not import the ev3dev.ev3 module in this file
from planet import Planet, Direction
from enum import Enum
"""
Class to hold the MQTT client
Documentation:
On start do the following (make part of __init__):
(1) subscribe to explorer/<N>
(2) publish to explorer/<N>: SYN ready
Next receive the planet name and starting coordinates
(1) receive from explorer/<N>: ACK <Name> <X>,<Y>
(2) subscribe to planet/<Name>
on_message:
Called when a message has been received on a topic that the client subscribes to and the message does not match an existing topic filter callback. Use message_callback_add() to define a callback that will be called for specific topic filters. on_message will serve as fallback when none matched.
client
the client instance for this callback
userdata
the private user data as set in Client() or user_data_set()
message
an instance of MQTTMessage. This is a class with members topic, payload, qos, retain.
mqtt message Documentation:
| Members:
|
| topic : String. topic that the message was published on.
| payload : String/bytes the message payload.
| qos : Integer. The message Quality of Service 0, 1 or 2.
| retain : Boolean. If true, the message is a retained message and not fresh.
| mid : Integer. The message id.
"""
def str2dir(string):
return {
'N': Direction.NORTH,
'E': Direction.EAST,
'S': Direction.SOUTH,
'W': Direction.WEST
}.get(string)
def dir2str(direction):
return {
Direction.NORTH: 'N',
Direction.EAST: 'E',
Direction.SOUTH: 'S',
Direction.WEST: 'W'
}.get(direction)
def str2tuple(string_a, string_b):
return (eval(string_a), eval(string_b))
def tupel2str(int_a, int_b):
return str(int_a) + ',' + str(int_b)
class Command(str, Enum):
SEND = "SYN " # SYN is short for synchronize
RECEIVE = "ACK " # ACK is short for acknowledge
READY = "ready"
PATH = "path "
TARGET = "target "
COMPLETE = "exploration completed!"
NOTICE = "notice"
class Communication:
"""
Class to hold the MQTT client
Feel free to add functions, change the constructor and the example send_message() to satisfy your requirements and thereby solve the task according to the specifications
"""
def __init__(self, mqtt_client, planet):
""" Initializes communication module, connect to server, subscribe, etc. """
def __init__(self, mqtt_client):
# THESE TWO VARIABLES MUST NOT BE CHANGED
self.msg_queue = []
self.planetname = None
self.planet = Planet()
self.client = mqtt_client
self.client.on_message = self.on_message
# ADD YOUR VARIABLES HERE
self.uid = '122'
passwd = '7KMuWPT2UE'
self.client.username_pw_set(self.uid, password=passwd)
try:
self.client.connect('robolab.inf.tu-dresden.de', port=8883)
except OSError:
print("ERROR: check your network connection.")
self.subscribetochannel("explorer/" + self.uid)
self.encode_message(Command.READY, None)
self.client.loop_start()
# THIS FUNCTIONS SIGNATURE MUST NOT BE CHANGED
def on_message(self, client, data, message):
""" Handles the callback if any message arrived """
pass
def on_message(self, client, data, message):
self.msg_queue.append(message)
# Example
def send_message(self, topic, message):
""" Sends given message to specified channel """
pass
def subscribetochannel(self, channelname):
self.client.subscribe(channelname, qos=1)
def encode_message(self, msgtype, msgdata):
if(msgtype == Command.READY):
print("ENC: Case 1")
self.msg_queue.append(("explorer/" + self.uid, Command.SEND + Command.READY))
if(msgtype == Command.TARGET):
print("ENC: Case 2")
self.msg_queue.append("explorer/" + self.uid, Command.SEND + Command.TARGET + "reached!")
if(msgtype == Command.COMPLETE):
print("ENC: Case 3")
self.msg_queue.append("explorer/" + self.uid, Command.SEND + Command.COMPLETE)
if(msgtype == Command.PATH):
print("ENC: Case 4")
self.msg_queue.append(("planet/" + self.planetname, Command.SEND + Command.PATH + self.pathtostring(msgdata[0], msgdata[1], msgdata[2])))
def process_messages(self):
for messages in self.msg_queue:
if(type(messages) == tuple):
print("Sending Message:", messages)
self.client.publish(messages[0], payload=messages[1], qos=1)
elif(messages.payload.decode('utf-8').startswith(Command.RECEIVE)):
print("Received Message:", messages.payload.decode('utf-8'))
self.comexec(messages.payload.decode('utf-8')[4:])
self.msg_queue.pop(0)
def comexec(self, message):
if not any([message.startswith(instruction) for instruction in Command]): # is planet name and starting position
print("EXEC: Case 1")
[self.planetname, startnode] = message.rsplit(' ')
self.subscribetochannel(self.planetname)
self.planet.setcurnode(str2tuple(*startnode.rsplit(',')))
elif message.startswith(Command.PATH):
print("EXEC: Case 2")
self.stringtopath(*message[5:].rsplit(' '))
elif message.startswith(Command.TARGET):
print("EXEC: Case 3")
self.navto = self.planet.shortest_path(self.planet.getcurnode(), str2tuple(*message[7:].rsplit(',')))
elif message.startswith(Command.NOTICE):
print("EXEC: Case 4")
print(message)
def stringtopath(self, start, target, block, weight):
snode = (str2tuple(*start[:-2].rsplit(',')), str2dir(start[-1:]))
tnode = (str2tuple(*target[:-2].rsplit(',')), str2dir(target[-1:]))
self.planet.add_path(snode, tnode, int(weight))
def pathtostring(self, start, target, blocked):
if(blocked):
path = "blocked"
else:
path = "free"
return tupel2str(*start[0]) + ',' + dir2str(start[1]) + ' ' + tupel2str(*target[0]) + ',' + dir2str(target[1]) + ' ' + path

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@ -19,10 +19,6 @@ def run():
clean_session=False,
protocol=mqtt.MQTTv31)
# the execution of all code shall be started from within this function
# ADD YOUR OWN IMPLEMENTATION HEREAFTER
print("Hello World!")
# DO NOT EDIT
if __name__ == '__main__':

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@ -7,10 +7,13 @@ from sensor import Sensor
class Move:
def __init__(self, planet):
try:
self._wheel_l = Wheel('outB')
self._wheel_r = Wheel('outC')
self._sensor = Sensor()
self._bumper = ev3.TouchSensor()
except:
print("ERROR: Cannot find Motor/Sensor")
'''
determine maximum and minimum brightness of lines/white space
@ -42,11 +45,8 @@ class Move:
self._wheel_l.run()
self._wheel_r.run()
while(self._bumper.value() == False):
# this does not work... why?
# self._wheel_l.speed_set(ne)
# self._wheel_r.speed_set(newspeed)
self._wheel_l._motor.duty_cycle_sp = 48 - self._sensor.getbrightness()
self._wheel_r._motor.duty_cycle_sp = self._sensor.getbrightness()
self._wheel_l.speed_set(48 - self._sensor.getbrightness())
self._wheel_r.speed_set(self._sensor.getbrightness())
if(isknownstation == False):
pass #run odometry stuff here
self._wheel_l.stop()

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@ -45,11 +45,12 @@ formatting example of bidirectional map:
}
'''
#Contains the representation of the map and provides certain functions to manipulate it according to the specifications
# Contains the representation of the map and provides certain functions to manipulate it according to the specifications
class Planet:
def __init__(self):
""" Initializes the data structure """
self._planetmap = {}
self._curnode = None
self.target = None
# Adds a bidirectional path defined between the start and end coordinates to the map and assigns the weight to it.
@ -66,6 +67,12 @@ class Planet:
def get_paths(self) -> Dict[Tuple[int, int], Dict[Direction, Tuple[Tuple[int, int], Direction, Weight]]]:
return self._planetmap
def setcurnode(self, node):
self._curnode = node
def getcurnode(self):
return self._curnode
'''
Returns a shortest path between two nodes.
Used Algorithm: Dijkstra's Algorithm

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@ -71,6 +71,7 @@ class YourFirstTestPlanet(unittest.TestCase):
self.planet.add_path(((1, 0), Direction.NORTH), ((2, 2), Direction.SOUTH), 2)
self.planet.add_path(((1, 0), Direction.EAST), ((3, 0), Direction.WEST), 1)
self.planet.add_path(((2, 2), Direction.NORTH), ((2, 3), Direction.SOUTH), 3)
self.planet.add_path(((2, 2), Direction.NORTH), ((3, 2), Direction.SOUTH), 1)
self.planet.add_path(((3, 0), Direction.EAST), ((4, 0), Direction.WEST), -1)
self.planet.add_path(((3, 2), Direction.NORTH), ((3, 2), Direction.SOUTH), 1)