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memory35.py
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memory35.py
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# -*- coding: utf-8 -*-
#
# K9's Short Term Memory using Redis
#
# authored by Richard Hopkins February 2022
#
# Licensed under The Unlicense, so free for public domain use
#
# This program provides K9 with a short term memory that can recall
# all internal messages from sensors, motors, browser commands etc.
# for the last 10 seconds. It also enables this history of messages to
# be quickly retrieved on a per sensor basis
import json
import time
import redis
print("Short term memory loaded...")
class Memory():
'''
K9 short term memory
Arg:
record (bool): When true, all messages will be recorded and not forgotten after 10 seconds
Described in full in this post
https://k9-build.blogspot.com/2018/02/using-redis-to-create-robot-short-term.html?q=redis
'''
def __init__(self, record = False):
self.rec = record
print("Connecting to local redis host")
self.r = redis.Redis(host='127.0.0.1',port=6379, decode_responses=True, charset="utf-8")
if self.rec:
print("Recording data permanently") # let the user know they are in sim mode
self.storeState("left:speed",0.0)
self.storeState("right:speed",0.0)
def storeState(self, key:str, value) -> None:
'''Stores the value of a received key and the time it was stored as well as preserving the previous value
Args:
key (str): Name of the key
value (float): New value for the key
'''
#print("Key:", key,", new value:", value)
old_value = self.r.get(str(key) + ":now")
if not old_value:
old_value = 0.0
#print("Old value:", old_value)
self.r.set(str(key) + ":old", old_value )
old_value = self.r.get(str(key) + ":time:now")
if not old_value:
old_value = 0.0
elapsed_time = int(time.time() - float(old_value))
if elapsed_time >= 86400:
print("Old value of",str(key),"set",round(elapsed_time/86400),"days ago.")
elif elapsed_time >= 3600:
print("Old value of",str(key),"set",round(elapsed_time/3600),"hours ago.")
elif elapsed_time >= 60:
print("Old value of",str(key),"set",round(elapsed_time/60),"minutes ago.")
else:
pass
#print("Old value set", round(elapsed_time),"seconds ago.")
self.r.set(str(key) + ":time:old", old_value)
self.r.set(str(key) + ":now",str(value))
self.r.set(str(key) + ":time:now",str(time.time()))
def retrieveState(self, key:str):
'''Retrieves the last version of a desired key
Args:
key (str): Name of the key
'''
try:
state_value = self.r.get(str(key) + ":now")
except TypeError:
return None
return state_value
def retrieveStateMetadata(self, key:str) -> dict:
'''
Returns a dictionary for a state that includes
its current value, rate of change and age, will
return None if state is not known
Args:
key (str): Name of state
'''
try:
now = float(self.r.get(key + ":now"))
now_time = float(self.r.get(key + ":time:now"))
old = float(self.r.get(key + ":old"))
old_time = float(self.r.get(key + ":time:old"))
except TypeError:
return None
try:
delta_v = (now - old) / (now_time - old_time)
except ZeroDivisionError:
delta_v = None
age = time.time() - now_time
dict = {
"key": key,
"value": now,
"old_value": old,
"delta_v": delta_v,
"age": age
}
return dict
def getMsgKey(self):
'''Uses redis to create a unique message key by incrementing message_num
'''
msg_key = "message:"+str(self.r.incr("message_num",amount=1))
return msg_key
def storeSensorReading(self, name:str, reading:float, angle:float) -> None:
'''Stores a sensor reading as a JSON string, compatible with other sensor readings
Args:
name (str): Name of the sensor
reading (float): Distance measured by sensor
angle (float): Angle measured by sensor
'''
reading = {
"type":"sensor",
"sensor": str(name),
"distance": reading,
"angle": angle,
"time": time.time()
}
json_data = json.dumps(reading)
# json_data = '{"type":"sensor","sensor":"'+str(name)+'","distance":"'+str(reading)+'","angle":"'+str(angle)+'"}'
self.storeSensorMessage(json_data)
def storeSensorMessage(self, json_data:str):
'''Stores a JSON string formatted sensor reading message
Arg:
json_data (json): store a string that is in JSON format
'''
# Parse message into dictionary of name value pairs
message = {}
message = json.loads(json_data)
# print(message)
msg_key = self.getMsgKey()
# Create a transactional pipeline to store new message, this will be closed
# and committed by the pipe.execute() command
pipe = self.r.pipeline(transaction=True)
# Store the whole of the message as a hash value
pipe.hmset(msg_key,message)
# Expire all messages after 10 seconds unless in record mode
if not self.rec :
pipe.expire(msg_key,10)
# For each of the message generating devices e.g. sensors, create a list
# where the most recent element is at the left of the list
pipe.lpush("sensor:" + message["sensor"],msg_key)
# Ensure that the list for each device doesn't get any longer than 40 messages so
# stuff will fall of the right hand end of the list
if not self.rec :
pipe.ltrim("sensor:" + message["sensor"],0,40)
# Execute all of the above as part of a single transactional interaction with the
# Redis server
pipe.execute()
def getSensorKey(self,sensor:str) -> str:
'''Returns name of sensor key
Args:
sensor (str): Name of the sensor
'''
return "sensor:" + sensor
def floatDict(self, dict:dict, list:list=['distance','angle','time']) -> dict:
'''Returns a dictionary with floats rather than strings
Args:
dict (dict): Dictionary to modify
list (list): List of dictionary indices to modify
'''
for index in list:
try:
dict[index] = float(dict[index])
except KeyError:
# print("Key error detected in Redis")
pass
return dict
def retrieveSensorReading(self, sensor:str) -> dict:
'''Retrieves the last message stored for a sensor
as a dictionary, will return None if none found
Arg:
sensor (str): Name of the sensor
'''
dict_key=self.r.lrange(self.getSensorKey(sensor), 0, 0)
# msg = self.r.hmget(msg_key)
try:
dict = self.r.hgetall(dict_key[0])
except IndexError:
return None
dict = self.floatDict(dict)
return dict
def retrieveSensorReadings(self, sensor:str) -> list:
'''Retrieves all the values stored for a sensor
as a list of dictionaries, will return empty
list if none found
Arg:
sensor (str): Name of sensor
'''
dict_list = []
msg_key_list = self.r.lrange(self.getSensorKey(sensor), 0, -1)
for key in msg_key_list:
item = self.r.hgetall(key)
item = self.floatDict(item)
dict_list.append(item)
return dict_list
def retrieveLastSensorReading(self, sensor:str) -> dict:
'''Retrieves the last value stored for a sensor
as a dictionary, will return None if none
recorded
Arg:
sensor (str): Name of the sensor
'''
return self.retrieveSensorReading(sensor)
def storePerson(self, name:str, gender:str, bearing:float) -> None:
'''Saves the details of the person talking to the robot
Args:
name: first name of the person
gender: 'male' or 'female' as string
bearing: direction to person in degrees; zero is directly
forward whilst left is negative, right is positive
'''
self.storeState("name", name)
self.storeState("gender", gender)
self.storeState("bearing", str(bearing))
def retrievePerson(self) -> dict:
'''Retrieves the details of the last person talking to the robot
'''
name = str(self.retrieveState("name"))
if name :
gender = str(self.retrieveState("gender"))
bearing = float(self.retrieveState("bearing"))
else :
name = "richard"
gender = "male"
bearing = 0.0
self.storePerson(name, gender, bearing)
dict = {"name": name,
"gender": gender,
"bearing": bearing}
return dict