def setUpClass(cls):
print("setUpClass()")
# Initialize airports
cls.Logan = Airport()
cls.JFK = Airport()
cls.Logan.set_name("Logan")
cls.JFK.set_name("JFK")
# Initialize passengers
cls.Ben = Passenger("Ben")
cls.Julia = Passenger("Julia")
cls.Jamie = Passenger("Jamie")
# Initialize flights
cls.flightLoganToJFK = Flight.airports_to_from(cls.Logan, cls.JFK)
# Flight 1
cls.flightLoganToJFK.set_flight_number("UA1161")
cls.flightLoganToJFK.set_flight_date("04-27-2020")
cls.flightLoganToJFK.set_flight_time("4:30pm")
cls.flightLoganToJFK.set_airline("United Airlines")
# Add flights to airport
cls.Logan.add_flight(cls.flightLoganToJFK)
cls.JFK.add_flight(cls.flightLoganToJFK)
def schedule(self):
count = 0
while True:
count += 1
destination = random.choice(destinations)
trip = Journey("A", destination)
passenger = Passenger(count, self.env, trip)
print("Sending passenger %d on the trip %s at %d" %
(count, trip, self.env.now))
self.env.process(passenger.wait_for_train(self.train_stop))
yield self.env.timeout(5)
def group_AssignSeat(airplane, df, group_list, offset_dict):
success = 0
# Filter from all groups to groups of this size
group_df = find_members_in_group(df[df['group_size'] == len(group_list)],
group_list)
sort_on = ['number_of_flags', 'age']
group_df = group_df.sort_values(by=sort_on, ascending=False)
group_df = group_df.reset_index(drop=True)
# iterate through each member in this group
for row in group_df.index:
# this_row = group_df[group_df.index == row]
pID = group_df.loc[row, 'pID']
this_psgr = Passenger(pID)
age = group_df.loc[row, 'age']
group = group_df.loc[row, 'group']
has_travelled = group_df.loc[row, 'has_travelled']
has_precon = group_df.loc[row, 'has_preexisting_condition']
this_psgr.fill_questionare(age, group, has_travelled, has_precon)
this_offset_detail = offset_selector(airplane, this_psgr, offset_dict)
this_offset = this_offset_detail['offset']
group_df.loc[row, 'offset_order'] = this_offset_detail['order']
group_df.loc[row, 'offset_x'] = this_offset['x']
group_df.loc[row, 'offset_y'] = this_offset['y']
group_df.loc[row, 'offset_method'] = this_offset['method']
#group passenger seating method
# Allowed Group Passenger Seat_State = 'G'
blocked_seat_list = SocialDistance(airplane,
this_offset,
occupied_state='G')
SeatPassenger(airplane, blocked_seat_list, occupied_state='G')
#if prev_assigned_seat is not None and success < len(group_list)-1:
# assert prev_assigned_seat != airplane.last_assigned_seat, "Unable to Seat"
group_df.loc[row, 'seat'] = airplane.last_assigned_seat
success += 1
group_find_next_seat(airplane)
airplane.update()
assert success == len(group_list), "NOT ALL PASSENGERS IN GROUP SEATED"
group_ToggleState(airplane, group_df)
group_find_next_seat(airplane)
return group_df
###################################################################################################
def login():
url = request.url
if "demo" not in url:
session["demo"] = False
passenger = Passenger({
"id_type": url.split("id_type=")[1].split("&")[0],
"data": url.split("data=")[1],
"demo": False
})
else:
session["demo"] = True
passenger = Passenger({"demo": True})
session["passenger"] = passenger.uid
with open("pickle/" + passenger.uid + ".pickle", "wb") as f:
pickle.dump(passenger, f)
return redirect(url_for("welcome"))
def init_synthethic_dataset(self):
self.database = {}
passengers = [Passenger(name) for name in ["john green", \
"louie anderson", \
"liza koshy"]]
bookings = [Booking(*booking) for booking in
[("AMS", "ZRH", "10-Dec-2018"), \
("LHR", "AMS", "01-Jan-2019"), \
("BER", "ARN", "02-Mar-2019")]]
flights = [Flight(*flight) for flight in \
[("KLM", "AMS", "BSL", "10-Dec-2018", 200), \
("SWISS", "BSL", "ZRH", "10-Dec-2018", 100), \
("KLM", "LHR", "AMS", "01-Jan-2019", 300), \
("Eurowings", "BER", "ARN", "02-Mar-2019", 300)]]
tickets = [Ticket(*ticket) for ticket in \
[(passengers[0], flights[0], "economy"),
(passengers[0], flights[1], "economy"),
(passengers[1], flights[2], "business"), \
(passengers[2], flights[3], "economy")]]
bookings[0].add_ticket(tickets[0])
bookings[0].add_ticket(tickets[1])
bookings[1].add_ticket(tickets[2])
bookings[2].add_ticket(tickets[3])
self.database["passengers"] = passengers
self.database["bookings"] = bookings
self.database["flights"] = flights
self.database["tickets"] = tickets
self.database["name_to_tickets"] = {
passenger.name: []
for passenger in passengers
}
for ticket in tickets:
self.database["name_to_tickets"][ticket.client.name] += [ticket]
def main():
num_passengers = int(input("How many passengers does the building have?"))
num_floors = int(input("How many floors does the building have?"))
strategy = int(input("Which strategy do you want to use? (1 for FIFO, 2 for move-to-max-min)"))
building = Building(num_passengers, num_floors)
elevator = Elevator(num_floors)
passengers = []
for i in range(num_passengers):
start_floor = random.choice(range(elevator.n_floors))
destination_floor = random.choice(range(elevator.n_floors))
while start_floor == destination_floor:
destination_floor = random.choice(range(elevator.n_floors))
passenger = Passenger(start_floor, destination_floor)
passengers.append(passenger)
elevator.add_call(passenger.start_floor, passenger.destination, passenger)
if strategy == 1:
for passenger in passengers:
elevator.FIFO()
else:
elevator.max_floor_strategy()
print "\n"
costs = []
for passenger in passengers:
costs.append(passenger.time_cost)
print "Average cost: ", np.mean(costs), " floors"
print "Average squared cost: ", np.mean([i**2 for i in costs]), " floors"
print "Median cost: ", np.median(costs), " floors"
print "Maximum cost: ", max(costs), " floors"
def load_bus(self, name, boarding, destination,):
if self.checkSeat():
passenger = Passenger(name, boarding, destination)
self.buss_passangers.append(passenger)
else:
return self.buss_passangers
return self.buss_passangers
def buildPassengers(count, result, lines):
for i in range(count):
p = Passenger(
i,
getRandomPath(result,
[node.id for line in lines for node in line.nodes]))
yield p
def main():
airport_names = ['JFK', 'LAX', 'ATL', 'DFW']
# string flight_num, string airline, string date, string time
flight_info = [["UA1215", "United Airlines", "3/20/2020", "3:30pm"],
["UA1438", "United Airlines", "3/20/2020", "3:45pm"],
["UA3455", "United Airlines", "3/20/2020", "4:00pm"],
["UA4234", "United Airlines", "3/20/2020", "4:15pm"]]
# read_csv of names
df = pd.read_csv('baby_names.csv')
# get name values
names = df['NAME'].values
# these will become Passenger()'s
# Initialize airports
airports = initialize_airports(airport_names)
# Initialize flights
initialize_flights(flight_info, airports)
# Display the airport data created thus far
print_data(airports)
for airport in airports:
for flight in airport.get_flights():
for i in range(25 + np.random.randint(0, 200)):
passenger = Passenger(names[np.random.choice(len(names), 1)])
flight.add_passenger(passenger)
def tick(self):
if (self.environment.get_clock() %
self.environment.TICKS_NEEDED_TO_GENERATE_PASSENGER) == 0:
for i in range(self.environment.PASSENGERS_TO_BE_GENERATED):
# GET ID FROM ENVIRONMENT PASSENGER LIST
i + 0 # HACK: fix unused variable warning
p = Passenger(self.environment)
self.environment.add_passenger(p)
def increment_time(self, request_json):
requests_to_process = self.get_requests_to_process(request_json)
new_pickups = [Passenger(person) for person in requests_to_process]
self.car.pickup_requests.extend(new_pickups)
next_destination = self.get_next_destination()
self.car.move(next_destination.location)
self.car.do_pickups()
self.car.do_dropoffs()
self.car.print_status()
def passengers(self):
list_pass = []
for i in range(self.pass_count):
flight = self.flights[random.randint(0, len(self.flights) - 1)]
list_pass.append(
Passenger(random.choice(self.first_names),
random.choice(self.last_names), flight,
random.randint(1, 100)))
return list_pass
def add_passengers(self, stages_list):
diff = self.max_num_of_passengers - len(self.passengers)
if diff > 0:
# Объекту пассажира передается объект его целевого этажа с использованием модуля random
nbuilding = stages_list[:]
nbuilding.remove(self) # Из списка исключается текущий этаж
for _ in range(diff):
self.passengers.append(Passenger(random.choice(nbuilding)))
# Переинициализация состояния кнопок этажа
self.initialize_floor_buttons()
def _handleArrival(self, curTime):
"""
Makes changes according to 1st rule.
"""
prob_number = random.random()
if prob_number <= self._arriveProb:
self._numPassengers += 1
passenger = Passenger(self._numPassengers, curTime)
self._passengerQ.enqueue(passenger)
print(f"Time {curTime}: Passenger {self._numPassengers} arrived.")
def generate_boarding(self, plane_length):
passengers = list()
seatList = set()
while len(seatList) is not 6 * plane_length:
seatList.add((randint(1, plane_length), chr(randint(65, 70))))
for seat in seatList:
passengers.append(Passenger(seat[0], seat[1], randint(0, 2)))
self.plane = Plane(plane_length)
passengers.reverse()
self.plane.add_passengers(passengers)
return passengers
def read_passengers(in_file):
passengers = {}
with open(in_file, 'r') as file:
reader = csv.reader(file)
for row in reader:
try:
tmp = Passenger(int(row[0]), int(row[1]), int(row[2]))
passengers[tmp.id] = tmp
except:
pass
return passengers
def _handleArrive(self, curTime):
"""
Rule 1: If a customer arrives, he is added to the queue.
At most, one customer can arrive during each time step.
"""
if random.random() <= self._arriveProb:
self._numPassengers += 1
thePassenger = Passenger(self._numPassengers, curTime)
print("Time {}: Passenger {} arrived.".format(
curTime, self._numPassengers))
self._passengerQ.add(thePassenger)
def _get_states(self):
states = {}
state_to_no = {}
no_to_state = {}
state_count = 0
no_of_dests = self.no_of_rows * self.no_of_cols
no_of_locs = no_of_dests + 1 #+ 1 for being in taxi
#What a mess - think of a way to eliminate the nestedness
for taxi_loc in range(no_of_dests):
for pass1_loc in range(no_of_locs):
for pass2_loc in range(no_of_locs):
for pass1_dest in range(no_of_dests):
for pass2_dest in range(no_of_dests):
#if pass1_loc == pass1_dest == pass2_loc == pass2_dest: continue
state = self.encode(taxi_loc, pass1_loc, pass2_loc,
pass1_dest, pass2_dest)
taxi = Taxi(taxi_loc, 0, self.taxi_max_capacity)
pass1 = Passenger(1, pass1_loc, pass1_dest)
pass2 = Passenger(2, pass2_loc, pass2_dest)
if pass1_loc == self.position_in_taxi:
taxi.pickup_passenger(pass1)
if pass2_loc == self.position_in_taxi:
taxi.pickup_passenger(pass2)
if pass1_loc == pass1_dest:
taxi.pickup_passenger(pass1)
taxi.drop_passenger(pass1)
if pass2_loc == pass2_dest:
taxi.pickup_passenger(pass2)
taxi.drop_passenger(pass2)
states[state] = [taxi, pass1, pass2]
state_to_no[state] = state_count
no_to_state[state_count] = state
state_count = state_count + 1
return states, state_to_no, no_to_state
def single_AssignSeat(airplane, df, offset_info):
sort_on = ['number_of_flags', 'age']
df = df.sort_values(by=sort_on, ascending=False)
for row in df.index:
pID = df.loc[row, 'pID']
this_psgr = Passenger(pID)
age = df.loc[row, 'age']
group = []
has_travelled = df.loc[row, 'has_travelled']
has_precon = df.loc[row, 'has_preexisting_condition']
this_psgr.fill_questionare(age, group, has_travelled, has_precon)
condition_count = len(df[df['has_preexisting_condition'] == True])
this_offset_detail = offset_selector(airplane,
this_psgr,
offset_info,
limiter=condition_count)
this_offset = this_offset_detail['offset']
df.loc[row, 'offset_order'] = this_offset_detail['order']
df.loc[row, 'offset_x'] = this_offset['x']
df.loc[row, 'offset_y'] = this_offset['y']
df.loc[row, 'offset_method'] = this_offset['method']
blocked_seat_list = SocialDistance(airplane,
this_offset,
occupied_state='P')
SeatPassenger(airplane, blocked_seat_list, occupied_state='P')
# assert prev_assigned_seat != airplane.last_assigned_seat, "Unsuccessful Seating!"
df.loc[row, 'seat'] = airplane.last_assigned_seat
single_find_next_seat(airplane)
airplane.update()
return df
def load_data():
with open("titanic/test.csv") as file:
data = csv.reader(file)
count = 0
for row in data:
if count > 0:
try:
PASSENGERS[int(row[0])] = Passenger(
int(row[0]), int(row[1]), float(row[8]))
except:
pass
count = count + 1
file.close()
def generate_boarding(self, plane_length):
passengers = list()
seatList = list()
for count in range(1, 4):
seats = set()
while len(seats) < plane_length * 2:
seats.add((randint(1, plane_length), chr(64 + count)))
seats.add((randint(1, plane_length), chr(71 - count)))
seatList.extend(list(seats))
for seat in seatList:
passengers.append(Passenger(seat[0], seat[1], randint(0, 2)))
self.plane = Plane(plane_length)
self.plane.add_passengers(passengers)
return passengers
def generate_boarding(self, plane_length):
passengers = list()
seatList = list()
for number in range(1, plane_length, plane_length // 4):
seats = set()
while len(seats) < plane_length * 6 / 4:
seats.add((randint(number, number + (plane_length // 4) - 1),
chr(randint(65, 70))))
seatList.extend(list(seats))
for seat in seatList:
passengers.append(Passenger(seat[0], seat[1], randint(0, 2)))
self.plane = Plane(plane_length)
self.plane.add_passengers(passengers)
return passengers
def reset(self):
"""
Initializes/resets the simulation to its initial state
"""
# Generate a list of passengers based on total number of passengers
self.passenger_list = [
Passenger(i, self.num_floors)
for i in range(1, self.total_passengers + 1)
]
self.elevator = ElevatorFactory.get_elevator(self.num_floors,
self.elevator_type,
self.passenger_list,
self.elevator_capacity)
self.building = Building(self.num_floors, self.passenger_list)
def generate_boarding(self, plane_length):
passengers = list()
seatList = list()
for count in range(0, 3):
for i in range(plane_length, 0, -2):
seatList.append((i, chr(65 + count)))
for i in range(plane_length, 0, -2):
seatList.append((i, chr(70 - count)))
for i in range(plane_length - 1, 0, -2):
seatList.append((i, chr(65 + count)))
for i in range(plane_length - 1, 0, -2):
seatList.append((i, chr(70 - count)))
for seat in seatList:
passengers.append(Passenger(seat[0], seat[1], randint(0, 2)))
self.plane = Plane(plane_length)
self.plane.add_passengers(passengers)
return passengers
def add_passenger(self, num_passengers):
assert num_passengers <= self.size[0] * self.size[
1], 'number of passengers is larger than number of grids'
passenger_set = set()
while True:
if len(passenger_set) == num_passengers:
break
p = (random.randint(0, self.size[0] - 1),
random.randint(0, self.size[1] - 1))
if p not in passenger_set:
passenger_set.add(p)
for s in passenger_set:
# generate destination point
while True:
d = (random.randint(0, self.size[0] - 1),
random.randint(0, self.size[1] - 1))
if d != s:
break
self.passengers.append(Passenger(s, d))
def getPassengers(self):
filename = self.testPath if self.useTest else self.trainPath
passengers = []
with open(filename, 'r', newline='\n') as file:
reader = csv.reader(file)
for row in reader:
cells = row
if len(cells) != 12:
raise Exception('Fields missing in dataset!')
passengerId, survived, pClass, name, sex, age, sibSp, parch, ticket, fare, cabin, embarked = cells
passenger = Passenger(passengerId, survived, pClass, name, sex,
age, sibSp, parch, ticket, fare, cabin,
embarked)
passengers.append(passenger)
return passengers
# Stats MISC
coachQueueSTATS = { 'duration': 0.0, 'maxSize': 0, 'maxWait': 0, 'nPass': 0 }
firstQueueSTATS = { 'duration': 0.0, 'maxSize': 0, 'maxWait': 0, 'nPass': 0 }
# Stats Service Stations
busyStation = {
'coach':{'001':0.0, '002':0.0, '003':0.0, },
'first':{'001':0.0, '002':0.0,}
}
duration = 0
while ongoingSimulation(duration, checkInDuration):
# Handle New Arrivals
# First Class
if newArrival(checkInDuration, fcAvgArrivalRate, duration):
psgr = Passenger('First', duration, fcAvgSvcRate)
firstClassQueue.enqueue(psgr)
firstQueueSTATS['nPass'] += 1 # Increments total number of passengers in queue
# Checks Queue Max size
if firstClassQueue.size() > firstQueueSTATS['maxSize']:
firstQueueSTATS['maxSize'] = firstClassQueue.size()
# Coach
if newArrival(checkInDuration, coachAvgArrivalRate, duration):
psgr = Passenger('Coach', duration, coachAvgSvcRate)
coachQueue.enqueue(psgr)
coachQueueSTATS['nPass'] += 1 # Increments total number of passengers in queue
# Checks Queue Max size
if coachQueue.size() > coachQueueSTATS['maxSize']:
coachQueueSTATS['maxSize'] = coachQueue.size()
# Handle BUSY Service Stations
class TestOneToManyRelationships(unittest.TestCase):
global driver_1
driver_1 = Driver("Daniel", "fast and furious")
global driver_2
driver_2 = Driver("Alice", "faster and furiouser")
global passenger_1
passenger_1 = Passenger("Michael Scott", 38)
global passenger_2
passenger_2 = Passenger("Anna", 25)
global passenger_3
passenger_3 = Passenger("Katie", 20)
global trip_1
trip_1 = Trip(driver_1, passenger_1)
global trip_2
trip_2 = Trip(driver_1, passenger_2)
global trip_3
trip_3 = Trip(driver_1, passenger_3)
global trip_4
trip_4 = Trip(driver_2, passenger_3)
global trip_5
trip_5 = Trip(driver_2, passenger_2)
def test_passenger_property_methods(self):
self.assertEqual(passenger_1._name, "Michael Scott")
self.assertEqual(passenger_1.name, "Michael Scott")
self.assertEqual(passenger_1._age, 38)
self.assertEqual(passenger_1.age, 38)
def test_driver_property_methods(self):
self.assertEqual(driver_1._name, "Daniel")
self.assertEqual(driver_1.name, "Daniel")
self.assertEqual(driver_1._driving_style, "fast and furious")
self.assertEqual(driver_1.driving_style, "fast and furious")
def test_trip_property_methods(self):
self.assertEqual(trip_1._driver, driver_1)
self.assertEqual(trip_1.driver, driver_1)
self.assertEqual(trip_1._passenger, passenger_1)
self.assertEqual(trip_1.passenger, passenger_1)
def test_trip_class_method(self):
self.assertItemsEqual(Trip._all,
[trip_1, trip_2, trip_3, trip_4, trip_5])
self.assertItemsEqual(Trip.all(),
[trip_1, trip_2, trip_3, trip_4, trip_5])
def test_driver_instance_methods(self):
self.assertItemsEqual(driver_1.trips(), [trip_1, trip_2, trip_3])
self.assertItemsEqual(driver_1.passengers(),
[passenger_1, passenger_2, passenger_3])
self.assertEqual(driver_1.trip_count(), 3)
def test_passenger_instance_methods(self):
self.assertItemsEqual(passenger_2.trips(), [trip_2, trip_5])
self.assertItemsEqual(passenger_2.drivers(), [driver_1, driver_2])
self.assertEqual(passenger_2.trip_count(), 2)
global artist_1
artist_1 = Artist("Lady Gaga")
global artist_2
artist_2 = Artist("Vulfpeck")
global genre_1
genre_1 = Genre("Pop")
global genre_2
genre_2 = Genre("Indie")
global genre_3
genre_3 = Genre("Alternative")
global song_1
song_1 = Song("Joanne", artist_1, genre_1)
global song_2
song_2 = Song("Conscious Club", artist_2, genre_2)
global song_3
song_3 = Song("Back Pocket", artist_2, genre_1)
global song_4
song_4 = Song("El Chepe", artist_2, genre_3)
global song_5
song_5 = Song("Sinner's Prayer", artist_1, genre_3)
def test_genre_property_methods(self):
self.assertEqual(genre_1._name, "Pop")
self.assertEqual(genre_1.name, "Pop")
def test_artist_property_methods(self):
self.assertEqual(artist_1._name, "Lady Gaga")
self.assertEqual(artist_1.name, "Lady Gaga")
def test_song_property_methods(self):
self.assertEqual(song_1._name, "Joanne")
self.assertEqual(song_1.name, "Joanne")
self.assertEqual(song_1._artist, artist_1)
self.assertEqual(song_1.artist, artist_1)
self.assertEqual(song_1._genre, genre_1)
self.assertEqual(song_1.genre, genre_1)
def test_song_class_method(self):
self.assertItemsEqual(Song._all,
[song_1, song_2, song_3, song_4, song_5])
self.assertItemsEqual(Song.all(),
[song_1, song_2, song_3, song_4, song_5])
def test_artist_instance_methods(self):
self.assertItemsEqual(artist_1.songs(), [song_1, song_5])
self.assertItemsEqual(artist_1.genres(), [genre_1, genre_3])
def test_genre_instance_methods(self):
self.assertItemsEqual(genre_3.songs(), [song_4, song_5])
self.assertItemsEqual(genre_3.artists(), [artist_1, artist_2])
from plane_class import Plane
from FlightTrip import FlightTrip
from passenger import Passenger
from people import People
plane = Plane("AirSparta",20,20,15,10)
seats = plane.get_seats()
flight = FlightTrip(1,"Peru","12/06/2020","2:00PM",20,20)
michael = Passenger("Michael", "111", 21, "21/12/1992")
samir = Passenger("Samir", "122", 23, "21/12/1999")
flight.add_passenger(michael)
flight.add_passenger(samir)
# print(flight.return_passenger_list())
flight = FlightTrip(1, 'Bora Bora', '01/01/2022', '10:00', 3, 3)
samir = Passenger("Samir", "15503", 122, "24/08/1999")
stefan = Passenger('Stefan', '123A', 100, '10/12/96')
ryan = Passenger('Ryan', '2468B', 555, '08/06/20', True)
mergim = Passenger('Mergim', '101010X', 777, '01/01/2077')
print(flight.add_passenger(samir))
print(flight.add_passenger(stefan))
print(flight.add_passenger(ryan))
print(flight.add_passenger(mergim))
flight.flight_attendee_report()
while True:
pass_or_staff = input("Passenger or Staff? ")
if pass_or_staff.lower() == 'staff':
break
elif pass_or_staff.lower() == 'passenger':
name = input("Enter name: ")
tax_no = input('Enter tax number: ')
passport_no = input("Enter passport number: ")
dob = input("Enter date of birth: ")
with_child = input("Are you travelling with infant? [True/False]")
if with_child == 'True':
with_child = True
elif with_child == 'False':
with_child = False
pass1 = Passenger(name, tax_no, passport_no, dob, with_child)
flight_options = input("Where do you want to go? ")
if flight_options.capitalize() == flight_cannes.destination:
print(flight_cannes.add_passenger(pass1))
else:
print('Invalid response')
break
flight_cannes.flight_attendee_report()
print(flight_cannes.ticket_revenue())
def menu():
texts = Texts()
passenger = Passenger()
dao = BusDao()
if os.path.exists(dao.path):
dao.set_passenger(passenger, texts)
choice = ""
while choice != "0":
views = Views(texts)
choice = multipy_input(texts.show_menutext())
if choice == "1":
passenger.set_bus_lines(multipy_input(texts.busline_input_text))
elif choice == "2":
views.show_near_lines(passenger, dao)
elif choice == "3":
views.show_bus_lines(passenger, dao)
elif choice == "4":
passenger.bus_lines_del(multipy_input(texts.busline_input_text))
elif choice == "5":
views.show_near(passenger, dao)
elif choice == "6":
passenger.show_bus_lines()
elif choice == "7":
views.open_map(passenger, dao, (multipy_input(texts.busid_input_text)))
elif choice == "8":
views.show_by_id(passenger, dao, (multipy_input(texts.busid_input_text)))
elif choice == "9":
views.show_fastests(passenger, dao)
elif choice == "10":
views.show_all(passenger, dao)
elif choice == "11":
views.open_map_manually(multipy_input(texts.latitude_input_text), multipy_input(texts.longitude_input_text))
elif choice == "12":
try:
passenger.set_latitude(multipy_input(texts.latitude_input_text))
passenger.set_longitude(multipy_input(texts.longitude_input_text))
except:
print("=(")
elif choice == "13":
try:
passenger.maxdistance = multipy_input(texts.max_distance_intext)
except:
print("=(")
elif choice == "14":
try:
passenger.minspeed = multipy_input(texts.min_speed_text)
except:
print("=(")
elif choice == "97":
print("%s %s" % (texts.language_text, texts.language))
passenger.show(texts.passenger_text)
elif choice == "98":
dao.write_user_config(passenger, texts)
elif choice == "99":
texts.language = multipy_input(texts.lang_chtext)
print(texts.language)
else:
if choice != "0":
print("\n=(\n")
else:
print("\n=)\n")
