def inversion_mutation(offspring: list) -> list: # aka IVM
mutated_offspring = []
for o in offspring:
route_len = len(o.route_stops)
cutoff_1 = random.randrange(route_len + 1)
cutoff_2 = random.randrange(route_len + 1)
cut_start = min(cutoff_1, cutoff_2)
cut_end = max(cutoff_1, cutoff_2)
cut_route = list(reversed(o.route_stops[cut_start:cut_end]))
leftovers = o.route_stops[:cut_start] + o.route_stops[cut_end:]
try:
insert_at = random.randrange(len(leftovers))
except:
insert_at = 0
mutated_o = Route(RouteManager.INSTANCE)
mutated_o.route_stops = leftovers[:insert_at] + cut_route + leftovers[insert_at:]
mutated_o.build_spf()
mutated_offspring.append(mutated_o)
return mutated_offspring
def test_Append_station_true( self ):
"""
Successful append should return True
"""
r = Route( self.rm, ['A', 'B'] )
self.assertTrue( r.append_station( 'C' ) )
def scramble_mutation(offspring: list) -> list: # aka IVM
mutated_offspring = []
for o in offspring:
route_len = len(o.route_stops)
cutoff_1 = random.randrange(route_len + 1)
cutoff_2 = random.randrange(route_len + 1)
cut_start = min(cutoff_1, cutoff_2)
cut_end = max(cutoff_1, cutoff_2)
cut_piece = o.route_stops[cut_start:cut_end]
random.shuffle(cut_piece)
mutated_o = Route(RouteManager.INSTANCE)
for i in range(cut_start):
mutated_o.route_stops.append(o.route_stops[i])
for s in cut_piece:
mutated_o.route_stops.append(s)
for i in range(cut_end, route_len):
mutated_o.route_stops.append(o.route_stops[i])
mutated_o.build_spf()
mutated_offspring.append(mutated_o)
return mutated_offspring
def add_line(self, name, code, stationList):
line = Line(name, code)
self.lineList.append(line)
prevStation = None
nextStation = None
stationObjectList = []
routeObjectList = []
for i, v in enumerate(stationList):
name = v['station']
if name in self.stationMap:
station = self.stationMap[name]
else:
station = Station(name, 0, 0)
self.stationMap[name] = station
route = Route(line, prevStation, nextStation)
prevStation = station
stationObjectList.append(station)
routeObjectList.append(route)
length = len(stationObjectList)
for i, route in enumerate(routeObjectList):
if i != length - 1:
route.nextStation = stationObjectList[i + 1]
stationObjectList[i].add_routes(route)
def crossover(self, route_1, route_2):
child = Route(self.cities)
start = np.random.randint(len(route_1))
if start < len(route_1) - 1:
end = np.random.randint(start + 1,len(route_2))
s = end - start
k = 0
while 0 < (end - start):
random_city = route_1.get_city(start)
child.assign_city(k,random_city)
start += 1
k += 1
for i in range(len(route_2)):
random_city = route_2.get_city(i)
if random_city not in child.route:
child.assign_city(s,random_city)
s += 1
else:
k = 1
random_city = route_1.get_city(start)
child.assign_city(0,random_city)
for i in range(len(route_2)):
random_city = route_2.get_city(i)
if random_city not in child.route:
child.assign_city(k, random_city)
k += 1
return child
def please(n, airport_thing):
if n < 0 or n > len(airport_thing["list_of_airports"]):
return 0
# if you're trying to access a bad index just return
if Route.calculate_distance(airport_thing["list_of_airports"][n - 1],
airport_thing["list_of_airports"]
[n - 2]) > airport_thing["plane"].getRange():
return 0
# likewise, if you're trying to go somewhere you can't just return
airport_thing["signature"] += list_of_airports[n].getName(
) + ":" + list_of_airports[n + 1].getName()
# but otherwise, update the airport thing signature
for name in airport_names:
if name not in signature or list_of_airports[n].getName() != home:
continue
else:
return airport_thing
original_airport_thing = dict(airport_thing)
# we need to keep a copy of the airport thing because in one of the calls we're going to update it, and in another we're not going to
airport_thing["score"] += Route.calculate_score(
airport_thing[list_of_airports[n]],
airport_thing[list_of_airports[n + 1]])
return min(please(n - 1, original_airport_thing),
please(n - 1, airport_thing))
def traverse(start_node, subset, flight_record):
# next time through, start_node is next in subset if not in visited
flight_record["previously_visited"].append(start_node.getName())
if flight_record["previous_airport"] == None:
flight_record["previous_airport"] = start_node
else:
flight_record["previous_airport"] = flight_record["current_airport"]
flight_record["current_airport"] = start_node
if len(subset) == 0:
start = flight_record["current_airport"]
previous = flight_record["previous_airport"]
score = Route.calculate_score(flight_record["previous_airport"],
flight_record["current_airport"])
flight_record[
"accumulated_score"] = flight_record["accumulated_score"] + score
return flight_record
for airport in subset:
start = flight_record["current_airport"]
previous = flight_record["previous_airport"]
flight_record = traverse(airport, [
x for x in stops[airport.getName()]
if x.getName() not in flight_record["previously_visited"]
], flight_record)
score = Route.calculate_score(previous, start)
flight_record[
"accumulated_score"] = flight_record["accumulated_score"] + score
return flight_record
def get_variable_length_route(self) -> Route:
# Generates a route between random stations, but keeps track of sations inbetween, so that we attempt
# to avoid duplicated stations. On avg gives wtt=1000, but the length of the route varies - no idea
# how to work with that
r = Route(self)
unused_stations = set(list(range(1, len(self.stations) + 1)))
def _take_one_from_unused(remove=True) -> int:
elem = random.choice(tuple(unused_stations))
if remove:
unused_stations.remove(elem)
return elem
stops = [self.stations[_take_one_from_unused() - 1]]
while len(unused_stations) != 0:
st_from = stops[-1]
st_to = self.stations[_take_one_from_unused(False) - 1]
info = get_path_info(self.graph, self.stations, st_from, st_to)
for s in info["stations"]:
unused_stations.discard(s.id)
stops.append(s)
r.route_stops = stops
r.build_spf()
return r
def get_route(self, destination):
destination = self.get_uid_from_map(destination)
current_pos = self.get_current();
dest_id = self.get_index_from_uid(destination)
curr_id = self.get_index_from_uid(current_pos)
print "dest id = ", dest_id
print "curr id = ", curr_id
from Route import Route
route = Route(curr_id, dest_id, [], [], [])
path = route.findRoute()
from Imu import IMU
imu = IMU()
print "imu reading = ", imu.get_heading()
from obstacle import Obstacle
o = Obstacle()
print "setting up motors..."
from Motor import Motor
motor = Motor(o)
motor.setup()
print "setting up navigation..."
from navigate import Navigate
navigator = Navigate(motor,imu)
navigator.set_direc(imu)
for x in range(0,len(path)-1):
#print (path[x],path[x+1])
#navigator.set_direc(imu)
navigator.navigate(path[x], path[x+1])
def simple_inversion_mutation(offspring: list) -> list: # aka SIM
mutated_offspring = []
for o in offspring:
route_len = len(o.route_stops)
cutoff_1 = random.randrange(route_len + 1)
cutoff_2 = random.randrange(route_len + 1)
cut_start = min(cutoff_1, cutoff_2)
cut_end = max(cutoff_1, cutoff_2)
mutated_o = Route(RouteManager.INSTANCE)
for i in range(cut_start):
mutated_o.route_stops.append(o.route_stops[i])
for i in range(cut_end - cut_start):
mutated_o.route_stops.append(o.route_stops[cut_end - i - 1])
for i in range(cut_end, route_len):
mutated_o.route_stops.append(o.route_stops[i])
mutated_o.build_spf()
mutated_offspring.append(mutated_o)
return mutated_offspring
def test_Append_off_map( self ):
"""
Attempt to append a Station that does not follow the Route Map
should return False.
"""
r = Route( self.rm, ['A', 'B'] )
self.assertFalse( r.append_station( 'B' ) )
def export_gtfs(cls, directory):
Agency.write_agencies(directory)
Calendar.write_calendars(directory)
Stop.write_stops(directory)
Route.write_routes(directory)
Trip.write_trips(directory)
Frequency.write_frequencies(directory)
Path.write_paths(directory)
def import_gtfs(cls, directory):
Agency.import_agencies(directory)
Calendar.import_calendars(directory)
Stop.import_stops(directory)
Path.import_paths(directory)
Route.import_routes(directory)
Trip.import_trips(directory)
Frequency.import_frequencies(directory)
def setUp(self): ''' Sets up the test suite by creating new Route objects before every test is ran ''' cityPair = ['CHI', 'TOR'] metroPair = ['SHA', 'NYC'] self.routeA = Route(cityPair, 1337) self.routeB = Route(metroPair, 9001)
def __init__(self, cities, population_size):
self.routes = list()
self.cities = cities
self.population_size = population_size
for _ in range(population_size):
route = Route(self.cities)
route.generate_route()
self.routes.append(route)
def test_Append_station( self ):
"""
Precondition: Route ['A', 'B']
Postcondition: Route ['A', 'B', 'C']
"""
r = Route( self.rm, ['A', 'B'] )
r.append_station( 'C' )
self.assertEqual( r.stations, ['A', 'B', 'C'] )
def calculate_distance(self):
distance = 0
previous_idx = 0
for detail_idx in sorted(self.details + [len(self.points)]):
temp_route = Route(self.routes[previous_idx:detail_idx])
distance += temp_route.calculate_distance()
previous_idx = detail_idx
return distance
def get_object_from_dict(values):
route = Route()
route.name = XmlParser.get_title(values)
route.tag = XmlParser.get_tag(values)
latitude_min = RouteXmlParser.get_latitude_min(values)
latitude_max = RouteXmlParser.get_latitude_max(values)
longitude_min = RouteXmlParser.get_longitude_min(values)
longtitude_max = RouteXmlParser.get_longitude_max(values)
route.bounding_box = [ [latitude_min, latitude_max], [longitude_min, longtitude_max] ]
return route
def get_fixed_length_route(self) -> Route:
# Always gets a route of fixed length of #total stations, but definitely has a lot of duplicate
# stations en-route. On avg gives wtt=3000, but it is the best option for crossover methods
r = Route(self)
mixed_stops = list(range(1, len(self.stations) + 1))
random.shuffle(mixed_stops)
r.route_stops = [self.stations[x - 1] for x in mixed_stops]
r.build_spf()
return r
def readNetworkView(self, filename):
target = None
access = []
routes = []
tempNodes = {}
gateway = ""
with open(filename) as file:
lines = file.readlines()
for line in lines:
line = line.replace("\n", "")
args = line.split(",")
if args[0] == "Target":
n = Node(args[1], args[2], args[3], args[4], args[4],
False, False, False, args[5], args[6])
target = n
access.append(n)
tempNodes[args[1]] = n
if args[0] == "Server":
n = Node(args[1], args[2], args[2], args[3], args[3],
False, False, True, args[4], args[5])
server = n
if args[0] == "Node":
n = Node(args[1], args[2], args[3], args[4], args[4],
False, False, False, args[5], args[6])
access.append(n)
tempNodes[args[1]] = n
if args[0] == "Honeypot":
hp = Node(args[1], args[2], args[3], args[4], args[5],
True, False, False, args[6])
access.append(hp)
tempNodes[args[1]] = hp
if args[0] == "Honeyrouter":
hr = Node(args[1], args[2], args[2], args[3], args[3],
False, True, False, args[4])
access.append(hr)
tempNodes[args[1]] = hr
if args[0] == "Route":
idxh = 0
r = Route(tempNodes[args[1]], tempNodes[args[2]])
for h in args:
if idxh > 2:
r.addHop(tempNodes[h])
idxh += 1
routes.append(r)
if args[0] == "Gateway":
gateway = tempNodes[args[1]]
nv = NetworkView(target, access, routes, gateway, server)
print("Generated network view for " + str(target.decepted_ip_addr) +
" on port " + str(target.switchPort))
return nv
def buildRouteCosts(list_of_airports, home):
costs = {}
for airport in list_of_airports:
costs[airport.getName()] = {}
get_costs_from = possibilities[airport.getName()]
for key in get_costs_from:
costs_key = airport.getName() + ":" + key
costs[airport.getName()][costs_key] = (Route.calculate_score(
airport, possibilities[airport.getName()][key]),
Route.calculate_distance(
airport, home))
return costs
def dijkstraAlg(self, startCity, endCity, adjList):
'''
Finds the shortest path between two cities
'''
pQueue = Queue.PriorityQueue()
for adj in adjList[startCity]:
adj.accumDist = adj.distance
pQueue.put((adj.accumDist, adj))
for iter in adjList:
for adjC in adjList[iter]:
if adjC.startCity == startCity:
adjC.accumDist = adj.distance
newAdj = Route(adjC.endCity, adjC.startCity, adjC.accumDist)
pQueue.put((adjC.accumDist, newAdj))
itEdge = pQueue.get()
adj = itEdge[1]
while adj.endCity != endCity:
itEdge[1].visited = True
for adj in adjList[itEdge[1].endCity]:
adj.parent = itEdge[1]
if adj.visited == False:
adj.accumDist = adj.parent.accumDist + adj.distance
if adj.endCity == endCity:
break
for iter in adjList[adj.endCity]:
if iter.accumDist < adj.accumDist and iter.visited == True:
adj.parent = iter
pQueue.put((adj.accumDist, adj))
for iter in adjList:
for adjC in adjList[iter]:
if adjC.endCity == itEdge[1].endCity:
newAdj = Route(adjC.endCity, adjC.startCity, adjC.distance)
newAdj.parent = itEdge[1]
if newAdj.visited == False:
newAdj.accumDist = newAdj.distance + newAdj.parent.accumDist
if newAdj.startCity == endCity:
adj = newAdj
break
for iter in adjList[newAdj.endCity]:
if iter.accumDist < newAdj.accumDist and iter.visited == True:
newAdj.parent = iter
pQueue.put((adjC.accumDist, newAdj))
itEdge = pQueue.get()
print 'Done! The path is:'
print adj.endCity
print adj.startCity
while adj.startCity != startCity:
adj = adj.parent
print adj.endCity
print adj.startCity
def close(self):
self._is_open = False
self._dbname = None
# clear everything
Agency.clear()
Calendar.clear()
Stop.clear()
Path.clear()
Route.clear()
TripRoute.clear()
Trip.clear()
Frequency.clear()
Picture.clear()
def get_best_route(self, from_station, to_station, lines):
route = Route()
route.from_stop = from_station
route.to_stop = to_station
route.stops = 9999
if len(lines) == 0:
route.stops = 9999
return route
else:
for each_line in lines:
line = self.lines[each_line]
start_index = 0
stop_index = 0
for i in range(0, len(line.stations)):
if line.stations[i] == from_station:
start_index = i
elif line.stations[i] == to_station:
stop_index = i
stops = abs(start_index - stop_index)
if stops < route.stops:
route.stops = stops
route.line_number = line.line_number
return route
def __init__(self, session, api_key, route_id):
route = Route(session, route_id)
self.__start_location = Location(session, route.get_start_location())
self.__end_location = Location(session, route.get_end_location())
maps_client = googlemaps.Client(key=api_key)
now = datetime.now()
self.__directions_result = maps_client.directions(
self.__start_location.get_full_address(),
self.__end_location.get_full_address(),
mode="driving",
departure_time=now)[0]
def two_opt_swap(route: Route, i, k):
route = route.route
part_1 = deepcopy(route[:i])
part_2 = deepcopy(route[i:k])
part_2.reverse()
part_3 = deepcopy(route[k:])
return Route(part_1 + part_2 + part_3)
def crossover(cls, route_1, route_2):
if random.random() <= cls.crossover_rate:
pivot_1 = random.randint(0, route_1.routes.get_length())
pivot_2 = random.randint(0, route_1.routes.get_length())
pivot_1, pivot_2 = sorted([pivot_1, pivot_2])
crossover_1 = deepcopy(route_1)
crossover_2 = deepcopy(route_2)
crossover_1.routes = Route(route_1.routes[:pivot_1] +
route_2.routes[pivot_1:pivot_2] +
route_1.routes[pivot_2:])
crossover_2.routes = Route(route_2.routes[:pivot_1] +
route_1.routes[pivot_1:pivot_2] +
route_2.routes[pivot_2:])
return crossover_1, crossover_2
else:
return route_1, route_2
def index():
context = {"key": api_key, "title": "Map Demo"}
startLocation = request.form['startLoc']
endLocation = request.form['endLoc']
mT = str(request.form.get('_mode'))
print(str(mT))
duration = _create_update_CSVFile(startLocation, endLocation)
rout = Route(filename)
maps = Map(rout.trackpoints)
if "fourWheel" in mT:
COEmmision = (((rout.trackpoints[0][6]) / 17) * 2.31)
elif "TwoWheel" in mT:
COEmmision = (((rout.trackpoints[0][6]) / 55) * 2.31)
else:
COEmmision = "Yiiykkss !! you made it to 0 "
#duration = get_duration
#route = Route()
result = {
'Start ': startLocation,
'Destination ': endLocation,
'Distace ': rout.trackpoints[0][6],
'Duration ': duration,
'Fuel ': "Petrol",
"Carbon Emmision ": COEmmision
}
return render_template("template.html",
map=maps,
context=context,
result=result)
def create_routes(self, debug=False):
if debug:
# start a timer because it's a long process!!
start_time, function_name = time.time(), "create_routes"
print("Starting", function_name)
# create the routes
routes = []
for route_index in range(self.number_of_routes):
route = np.random.choice(self.number_of_cities,
self.number_of_cities,
replace=False)
# generate a name
name = self.name + " number: " + str(route_index)
route = Route(self.cities, name)
# tell it where it came from
routes.append(route)
# and save them
self.routes = routes
# timer because it's a long process!!
if debug:
print("Leaving", function_name, "and the process took",
time.time() - start_time)
def read_graph_from_file(self, directory_files: str):
for filename in glob.glob(directory_files):
with open(filename, 'r', encoding='latin-1') as file:
lines = file.readlines()
for i in range(0, len(lines) - 1):
if lines[i].startswith('*Z'):
# riga con l'identificativo univoco della corsa
codice, linea = lines[i].split()[1:3]
corsa_uid = codice + " " + linea
if not (lines[i].startswith('*')
or lines[i + 1].startswith('*')):
# righe con informazioni sulla tratta della corsa
row = lines[i]
nextrow = lines[i + 1]
ora_partenza = row[39:44]
ora_arrivo = nextrow[32:37]
ora_prossima_partenza = nextrow[39:44]
stazione_partenza = row[0:9]
stazione_arrivo = nextrow[0:9]
# aggiunta dell'arco tra le due stazioni
self.add_edge(
stazione_partenza, stazione_arrivo,
Route(int(ora_partenza), int(ora_arrivo),
corsa_uid))
if ora_prossima_partenza.isspace() and not (
stazione_arrivo in self.graph.keys()):
# caso in cui una stazione finale di arrivo non sia presente come stazione di partenza per qualche tratta
self.add_node(stazione_arrivo)
def open_routes_file(self, file_name):
logging.info("Opening routes file: %s" % file_name)
with open(file_name, newline='') as csvfile:
reader = csv.DictReader(csvfile)
# Read all routes info
for row in reader:
route = Route(row, self.stops_list)
self.routes_list.append(route)
# Create buses for each route
for route in self.routes_list:
logging.info("Creating %d buses for route %s" %
(route.buses_total, route.name))
for i in range(route.buses_total):
bus = Bus(self.bus_count, route, self.stops_list)
self.bus_count += 1
bus.start_time = route.time_offset + route.bus_counter * route.frequency
route.bus_counter += 1
self.buses_list.append(bus)
logging.info("Total created buses %d" % len(self.buses_list))
globalConstants.results['Total_buses'] = len(self.buses_list)
globalConstants.results['Total_routes'] = len(self.routes_list)
def generate_random_routes_container(points):
# from klasteryzacja import klasteryzacja
# _, details = klasteryzacja()
# sam = Route(points)
# sam = Route(points)
sam = Route(sample(points, len(points)))
details = generate_random_details(points)
return RoutesContainer(sam, details)
def get_subroutes(self):
subroutes = []
copy_routes = deepcopy(self.routes)
for nodes in self.details:
to_add = copy_routes[:nodes]
del copy_routes[:nodes]
subroutes.append(Route(to_add))
return subroutes
def build_dict_as_dictionaries(list_of_airports, possibilities_lookup, plane):
for i in range(len(list_of_airports)):
possibilities_lookup[list_of_airports[i].getName()] = {}
for j in range(len(list_of_airports)):
if i != j and Route.calculate_distance(list_of_airports[i], list_of_airports[j]) <= plane.getRange():
possibilities_lookup[list_of_airports[i].getName()][list_of_airports[j].getName()] = list_of_airports[j]
return possibilities_lookup
def readNetworkView(self,filename):
target = None
access = []
routes = []
tempNodes = {}
gateway = ""
with open(filename) as file:
lines = file.readlines()
for line in lines:
line = line.replace("\n","")
args = line.split(",")
if args[0] == "Target":
n = Node(args[1],args[2],args[3],args[4],args[4],False,False,False,args[5],args[6])
target = n
access.append(n)
tempNodes[args[1]] = n
if args[0] == "Server":
n = Node(args[1],args[2],args[2],args[3],args[3],False,False,True,args[4],args[5])
server = n
if args[0] == "Node":
n = Node(args[1],args[2],args[3],args[4],args[4],False,False,False,args[5],args[6])
access.append(n)
tempNodes[args[1]] = n
if args[0] == "Honeypot":
hp = Node(args[1],args[2],args[3],args[4],args[5],True,False,False,args[6])
access.append(hp)
tempNodes[args[1]] = hp
if args[0] == "Honeyrouter":
hr = Node(args[1],args[2],args[2],args[3],args[3],False,True,False,args[4])
access.append(hr)
tempNodes[args[1]] = hr
if args[0] == "Route":
idxh=0
r = Route(tempNodes[args[1]],tempNodes[args[2]])
for h in args:
if idxh > 2:
r.addHop(tempNodes[h])
idxh+=1
routes.append(r)
if args[0] == "Gateway":
gateway = tempNodes[args[1]]
nv = NetworkView(target,access,routes,gateway,server)
print("Generated network view for " + str(target.decepted_ip_addr) + " on port " + str(target.switchPort))
return nv
def open_routes_file(self, file_name):
logging.info("Opening routes file: %s" % file_name)
with open(file_name, newline='') as csvfile:
reader = csv.DictReader(csvfile)
# Read all routes info
for row in reader:
route = Route(row, self.stops_list)
self.routes_list.append(route)
def swap_mutation(offspring: list) -> list: # aka EM
mutated_offspring = []
for o in offspring:
route_len = len(o.route_stops)
swap_pos_1 = random.randrange(route_len)
swap_pos_2 = random.randrange(route_len)
mutated_o = Route(RouteManager.INSTANCE)
mutated_o.route_stops = [ s for s in o.route_stops]
temp = mutated_o.route_stops[swap_pos_1]
mutated_o.route_stops[swap_pos_1] = mutated_o.route_stops[swap_pos_2]
mutated_o.route_stops[swap_pos_2] = temp
mutated_offspring.append(mutated_o)
return mutated_offspring
def setRouteInitialNode(self):
"""
Inicializar ruta con nodo de inicio.
"""
route = Route(
self.nodeStart.name,
self.calculateRouteValue(0, self.nodeStart.estimatedCost), 0,
self.iteration, self.nodeStart)
self.routeslist.append(route)
self.iterationList[self.iteration] = self.routeslist
def build_dict(list_of_airports, possibilities_lookup, plane):
for i in range(len(list_of_airports)):
possibilities_lookup[list_of_airports[i].getName()] = []
for j in range(len(list_of_airports)):
if i != j and Route.calculate_distance(
list_of_airports[i],
list_of_airports[j]) <= plane.getRange():
possibilities_lookup[list_of_airports[i].getName()].append(
list_of_airports[j])
return possibilities_lookup
def build_dp(n, fr):
dp[0] = 0
for i in range(1, n):
min_cost = uint(2 >> 63) + 1
min_candidate = None
for candidate in expand(fr.current, fr.visited, fr.input):
cost = Route.calculate(fr.current, candidate)
if min_cost > cost:
min_cost = cost
min_candidate = candidate
ret_cost = Route.calculate_return_path(candidate, fr.route)
clone_fr = clone(fr)
clone_fr.route = clone_fr.route.add(min_candidate)
clone_fr.visited.add(min_candidate)
clone_fr.current = min_candidate
last = fr.last
home = fr.input.first()
fr = clone_fr
dp[i] = min(dp[i - 1] + ret_cost,
dp[i - 1] + cost(candidate, last) + cost(last, home))
def generateRoutes(self, ammount=20000, alpha=0.2, maxLoops =300000 ):
'gera N rotas randomicas'
random.seed(42)
self.routes = []
randomRange = int((len(self.customers)-1) * alpha)
customers = self.customers[1::]
customersIgnored = []
route = Route(self.customers[0])
def sortFunc(c): return c.distanceOf(route.customers[-1])
customers.sort(key=sortFunc)
it = 0
while(len(self.routes) < ammount):
it += 1
if it == (maxLoops/2):
print "Atingindo numero maximo de execucoes. abrindo alpha"
randomRange = len(customers)-1
if it > maxLoops:
print "Maximo de execucoes sem resultados atingido.", len(self.routes), "rotas geradas"
break
i = random.randint(
0, randomRange)
nextCustomer = customers[i % len(customers)]
if(route.canAddCustomer(nextCustomer, self.capacity)):
route.addCustomer(nextCustomer)
customers.remove(nextCustomer)
customers.extend(customersIgnored)
customersIgnored = []
customers.sort(key=sortFunc)
else:
customersIgnored.append(nextCustomer)
customers.remove(nextCustomer)
if(len(customers) == 0):
route.closeRoute()
if(self.addRoute(route, it=it)):
it = 0
route = Route(self.customers[0])
customers.extend(customersIgnored)
customersIgnored = []
if(len(customers) == 0):
customers = self.customers[1::]
customers.sort(key=sortFunc)
def get_cheapest_route(self):
# calculates the cost of each possible route and returns the cheapest route (and its cost)
if self.__error is not None: # if there are no valid routes for this itinerary
return None, 10 ** 10
lowest_cost = 10 ** 10 # method will return this number if itinerary cannot be completed
self.route_list = self.build_route_list()
self.cheapest_route = None
for route in self.route_list:
total_cost_of_stopovers = self.__stopover_cost * (len(route) - len(self.__airport_list))
try:
current_route = Route(route,
self.__aircraft_range,
self.__airport_atlas,
self.__currency_table,
self.__empty_tank,
total_cost_of_stopovers)
except ImpossibleRouteError:
continue # this route has a leg that cannot be completed
else:
current_route_cost = current_route.get_cost_of_route()
if current_route_cost < lowest_cost:
self.cheapest_route = current_route
lowest_cost = current_route_cost
if lowest_cost == 10 ** 10: # if itinerary cannot be completed
print("Aircraft has insufficient range to complete this itinerary.")
print("Consider using a larger aircraft or adding a fuel stop to the list of hubs.")
self.__error = "Aircraft has insufficient range to complete this itinerary." \
"\nConsider using a larger aircraft or adding a fuel stop to the list of hubs."
self.cheapest_route = None
else:
print()
print(self.cheapest_route)
self.cheapest_route.print_costs()
print()
self.lowest_cost = lowest_cost
return self.cheapest_route, lowest_cost
def import_trips(cls, directory):
from Route import Route
from Calendar import Calendar
from TripRoute import TripRoute
from Path import Path
from Stop import Stop
try:
f = open(os.path.join(directory, 'trips.txt'), 'rb')
reader = csv.reader(f)
mappings = {'route_id': ('route', lambda x: Route.get_by_gtfs_id(x)),
'service_id': ('calendar', lambda x: Calendar.get_by_gtfs_id(x)),
'trip_id': ('name', lambda x: x),
'trip_headsign': ('headsign', lambda x: x),
'direction_id': ('direction', lambda x: int(x) if x else 0),
'shape_id': ('path', lambda x: Path.get_by_gtfs_id(x)),
}
# create a headers with an index
headers = reader.next()
r_headers = dict([(x, i) for i, x in enumerate(headers)])
for l2 in reader:
if len(l2) != len(headers):
print >> sys.stderr, 'Invalid line', l2, headers
continue
kw = {}
for i, a in enumerate(l2):
key = headers[i]
if key in mappings:
kw[mappings[key][0]] = mappings[key][1](BaseObject.unquote(a))
# create the trip route
trip_route = TripRoute(**kw)
# set the id
trip_route.gtfs_id = BaseObject.unquote(l2[r_headers['trip_id']])
# create a trip
trip = trip_route.add_trip()
trip.gtfs_id = BaseObject.unquote(l2[r_headers['trip_id']])
# go through the list again and set block ids
#!mwd - I'm not sure how to do this. We link
# blocks by trip ids, but block ids are
# random in gtfs, so we have no way to link
# them back
except IOError, e:
print >> sys.stderr, 'Unable to open trips.txt:', e
class TestRoute(unittest.TestCase):
'''
A unit test suite for the Route class.
'''
def setUp(self):
'''
Sets up the test suite by creating new Route objects before every test is ran
'''
cityPair = ['CHI', 'TOR']
metroPair = ['SHA', 'NYC']
self.routeA = Route(cityPair, 1337)
self.routeB = Route(metroPair, 9001)
def test_constructor(self):
'''
Tests the constructor of the Route class by checking if all the values passed into the constructor
match all of the object's instance variables
'''
self.assertEqual('CHI', self.routeA.ports[0])
self.assertEqual('TOR', self.routeA.ports[1])
self.assertEqual(1337, self.routeA.distance)
self.assertEqual('SHA', self.routeB.ports[0])
self.assertEqual('NYC', self.routeB.ports[1])
self.assertEqual(9001, self.routeB.distance)
def test_set_departure_city(self):
'''
Tests set_departure_city() by changing the departure city of one route and checking if the change
applied, then attempting to change the departure city to an invalid input (nothing should happen).
'''
self.assertEqual(self.routeA.set_departure_city('TES'), True)
self.assertEqual(self.routeB.set_departure_city({1:'adfhsdfhy'}), False)
self.assertEqual(self.routeA.ports[0], 'TES')
self.assertEqual(self.routeB.ports[0], 'SHA')
def test_set_arrival_city(self):
'''
Tests set_arrival_city() by changing the arrival city of one route and checking if the change
applied, then attempting to change the arrival city to an invalid input (nothing should happen).
'''
self.assertEqual(self.routeB.set_arrival_city('TIN'), True)
self.assertEqual(self.routeA.set_arrival_city(64386), False)
self.assertEqual(self.routeB.ports[1], 'TIN')
self.assertEqual(self.routeA.ports[1], 'TOR')
def test_set_distance(self):
'''
Tests set_distance() by changing the distance of one route and checking if the change
applied, then attempting to change the distance to an invalid input (nothing should happen).
'''
self.assertEqual(self.routeA.set_distance(50256), True)
self.assertEqual(self.routeB.set_distance([1234, 1235]), False)
self.assertEqual(self.routeA.distance, 50256)
self.assertEqual(self.routeB.distance, 9001)
def generatgeView(self,rHosts,subnetSpace,targetPort,NCDSPort,HoneyPort,numSubnets,minHP,maxHP,Strategy):
self.targetsubnet = numSubnets
self.lowerSubnet = numSubnets/2
self.upperSubnet = 0
#generate specified number of subnets
for s in range(1,numSubnets):
self.getAvaiSubnet(numSubnets)
hosts=[]
#assign hosts to subnets, and deceive their data
for k in rHosts.keys():
if k!=NCDSPort and k!=HoneyPort:
#create new host object
realip=rHosts[k].split("/")[0]
realmac=rHosts[k].split("/")[1]
if k==targetPort:
self.target=Host(self.getShortnameHost(),realip,realmac,k)
#get subnet address for target
self.target=self.setAvailableSubnetAddress(subnetSpace,numSubnets,self.target,targetPort)
#print(str(self.target.deceptiveIP))
else:
host=Host(self.getShortnameHost(),realip,realmac,k)
#get subnet address for host
host=self.setAvailableSubnetAddress(subnetSpace,numSubnets,host,targetPort)
#print(str(host.deceptiveIP))
#assign honeypots to subnets
realHoneyIP=rHosts[HoneyPort].split("/")[0]
realHoneyMac=rHosts[HoneyPort].split("/")[1]
for subKey in self.subnetList.keys():
numHoneypots=random.randint(minHP,maxHP)
for hp in range(1,numHoneypots):
subnet=self.subnetList[subKey]
hpAddr=self.getAvaiHoneypotforSubnet(subnet)
honeyAddr=str(subnetSpace[:-2]) + "." + str(subnet.number) + "." + str(hpAddr)
honeypot=Honeypot(self.getShortnameHoneypot(),realHoneyIP,realHoneyMac,honeyAddr,self.randMac(),HoneyPort)
self.subnetList[subnet.number].honeypots.append(honeypot)
#print("Honeypot " + honeyAddr)
#create honeyrouters
routerMac=self.randMac()
targetSubnet = int(self.target.deceptiveIP.split(".")[2])
subnet=self.subnetList[targetSubnet]
subnetAddr=str(subnetSpace[:-2]) + "." + str(subnet.number) + ".1"
hr=Honeyrouter(self.getShortnameHoneyrouter(),subnetAddr,routerMac,NCDSPort)
subnet.honeyrouter.append(hr)
gateway=hr.shortName
self.subnetList[subnet.number]=subnet
self.honeyrouterList.append(hr)
for subKey in self.subnetList.keys():
subnet=self.subnetList[subKey]
if subnet.number != targetSubnet:
subnetAddr=str(subnetSpace[:-2]) + "." + str(subnet.number) + ".1"
hr=Honeyrouter(self.getShortnameHoneyrouter(),subnetAddr,routerMac,NCDSPort)
subnet.honeyrouter.append(hr)
self.subnetList[subKey]=subnet
self.honeyrouterList.append(hr)
#generate routes
numhops=1
for subKey in self.subnetList.keys():
subnet=self.subnetList[subKey]
targetSubnet = int(self.target.deceptiveIP.split(".")[2])
if subnet.number != targetSubnet:
numhops+=1
#numhops=random.randint(2,networkDiameter)
hostIdx=0
for host in subnet.hosts:
r=Route(self.target,host)
hostSubnet = int(host.deceptiveIP.split(".")[2])
#hops = int(math.fabs(hostSubnet-targetSubnet))
#max sub dist min hop dist
if Strategy=="minhop_maxsub":
hops = numSubnets - hostSubnet
if Strategy=="maxhop_maxsub":
#max sub dist max hop dist
hops = hostSubnet
for hop in range(0,hops):
r.addHop(self.honeyrouterList[hop])
self.routeList.append(r)
host.distance=hops
#subnet.hosts.insert(hostIdx,host)
#hostIdx+=1
for honeypot in subnet.honeypots:
r=Route(self.target,honeypot)
for hop in range(0,numhops-1):
r.addHop(self.honeyrouterList[hop])
self.routeList.append(r)
else:
for host in subnet.hosts:
r=Route(self.target,host)
self.routeList.append(r)
for honeypot in subnet.honeypots:
r=Route(self.target,honeypot)
self.routeList.append(r)
#set gateway
printer = NetworkPrinter()
realhosts = printer.printView(self.target,self.subnetList,self.routeList,targetPort,gateway)
#for printhost in realhosts:
#print("realhosts.append(\"" + printhost + "\")")
return (realhosts, self.targetsubnet)
sequence = int(coord_node.get('sequence', -1))
lat = float(coord_node.get('lat', 0.0))
lon = float(coord_node.get('lon', 0.0))
coords.append((lat, lon))
except Exception, e:
print >> sys.stderr, 'Invalid coordinate path %s: %s' % (name, e)
try:
p = Path(name = name, coords = coords)
p.path_id = int(path_id)
p.gtfs_id = gtfs_id
except Exception, e:
print >> sys.stderr, 'Error loading path', name, e
for route_node in tree.getroot().findall('Route'):
route_id = route_node.get('id', Route.new_id())
gtfs_id = route_node.get('gtfs_id', None)
agency_id = route_node.findtext('agency_id')
short_name = route_node.findtext('short_name')
long_name = route_node.findtext('long_name')
description = route_node.findtext('description')
route_type = route_node.findtext('route_node')
url = route_node.findtext('url')
color = route_node.findtext('color')
text_color = route_node.findtext('text_color')
agency_id = int(agency_id)
r = Route(agency = Agency.get(agency_id),
short_name = short_name, long_name = long_name,
description = description, route_type = route_type,
url = url, color = color, text_color = text_color)
