def walkPath():
# Read in Arguments
start = request.args.get('origin')
end = request.args.get('dest')
if start is None:
start = '633 Bay St, Toronto ON'
if end is None:
end = '633 Bay St, Toronto ON'
return jsonify ( directions(start, end, 'walking') );
def walkPath():
# Read in Arguments
start = request.args.get('origin')
end = request.args.get('dest')
if start is None:
start = '633 Bay St, Toronto ON'
if end is None:
end = '633 Bay St, Toronto ON'
return jsonify(directions(start, end, 'walking'))
def init(datas):
source = conversionData[datas[0]]
dest = conversionData[datas[1]]
robo1 = conversionData[datas[2]]
robo2 = conversionData[datas[3]]
robo = [robo1, robo2]
src_dest = tracer(source, dest)
source_to_dest = (gen for gen in src_dest)
pre = next(source_to_dest)
nex = next(source_to_dest)
diff = tuple(numpy.subtract(pre, nex))
path = [[pre, nex]]
i = 0
pre = nex
while (True):
try:
nex = next(source_to_dest)
except:
break
if diff == tuple(numpy.subtract(pre, nex)):
path[i].append(nex)
else:
i += 1
diff = tuple(numpy.subtract(pre, nex))
path.append([pre])
path[i].append(nex)
pre = nex
for i in range(len(path)):
prevNode = tuple(
numpy.add(numpy.subtract(path[i][0], path[i][1]), path[i][0]))
toChange = []
toChange.append(path[i][0])
for r in robo:
if r != robo[i]:
toChange.append(r)
MAP = updateMap(toChange)
temp = tracer(robo[i], prevNode)
if temp == []:
print("Not Possible")
break
temp += path[i]
# print("Path for Robo" + str(i))
# print(temp)
robo[i] = temp[-2]
source = temp[-1]
swarmPaths.append(temp)
swarmDirecs.append(' '.join(directions(temp)))
swarmPaths.append(src_dest)
return swarmPaths, swarmDirecs
import requests, json
from directions import directions
obj = directions("633 Bay St, Toronto ON", "45 Ulster, Toronto ON", 'walking')
print(obj)
import requests, json
from directions import directions
obj = directions("633 Bay St, Toronto ON", "45 Ulster, Toronto ON",'walking');
print(obj)
def move(self, turn, moves, ai = True, plots = False, plot_every = True):
if not ai:
x = int(raw_input("row:"))
y = int(raw_input("col:"))
else:
x = random.randint(0,18)
y = random.randint(0,18)
print "turn # = " + str(turn)
id = 19 * x + y
while self.board[id] != -1: # while not placing on empty
if not ai:
x = int(raw_input("row:"))
y = int(raw_input("col:"))
else:
x = random.randint(0,18)
y = random.randint(0,18)
id = 19 * x + y
#ko, 1 member set
for piece in self.ko_piece:
self.board[piece] = -1
self.ko_piece.clear()
#creates a new group for each new move
self.board_groups[id] = power_group(id, turn, self.board, self.board_groups, \
self.master_set, self.ko_piece, self.black_caps, self.white_caps)
self.board[id] = turn
self.master_set.add(self.board_groups[id])
directions.directions(id, self.board_groups[id].verify_enemy_dead)
self.value_update(x,y,turn, moves, plot_every)
if plot_every or turn == moves:
#prints board
for j in xrange(self.size):
for i in xrange(self.size):
print str(self.board[j * 19 + i]),
print " "
print " "
for j in xrange(self.size):
for i in xrange(self.size):
print str(self.board_groups[j * 19 + i]),
print " "
print " "
#prints liberties using heat graph
colors = [0 for x in xrange(self.size*self.size)]
for member in self.board_groups:
if isinstance(member, power_group):
for liberty in member.liberties:
if member.turn % 2 ==0:
colors[liberty] = -2
else:
colors[liberty] = -1
self.heat_graph(colors, 'alexnoob2.png', 1, 's', 300)
# check if it is in open list
# if it is in open list compare and replace if it is better
# if it is not in open list, add it and details
if ((cellDetails[parent[1] + neighbours[i][0]][parent[2] + neighbours[i][1]]['f'] == float('inf')) or (cellDetails[parent[1] + neighbours[i][0]][parent[2] + neighbours[i][1]]['f'] > newF)):
openList.append([newF, parent[1] + neighbours[i][0], parent[2] + neighbours[i][1]])
cellDetails[parent[1] + neighbours[i][0]][parent[2] + neighbours[i][1]]['f'] = newF
cellDetails[parent[1] + neighbours[i][0]][parent[2] + neighbours[i][1]]['g'] = newG
cellDetails[parent[1] + neighbours[i][0]][parent[2] + neighbours[i][1]]['h'] = newH
cellDetails[parent[1] + neighbours[i][0]][parent[2] + neighbours[i][1]]['PX'] = parent[1]
cellDetails[parent[1] + neighbours[i][0]][parent[2] + neighbours[i][1]]['PY'] = parent[2]
# Tracing the path
tracedPath = [(SX, SY), (DX, DY)]
if not destinationFound:
print("Sorry, couldnot find the destination")
else:
print("\nThe path is\n")
row = cellDetails[DX][DY]['PX']
col = cellDetails[DX][DY]['PY']
while(not (row == SX and col == SY)):
tracedPath.insert(1, (row, col))
x = cellDetails[row][col]['PX']
y = cellDetails[row][col]['PY']
row, col = x, y
# print(*tracedPath)
from directions import directions
print(directions(tracedPath))
#!/usr/bin/python
import readline
import json
import goog_shell
import directions
import os
instructions = directions.directions()
shell = goog_shell.goog_shell()
print " 'h' for available options "
print " 'see' for examples "
print " 'exit' to quit"
while True:
try:
readline.parse_and_bind("tab: complete")
readline.set_completer(shell.complete)
user_command = raw_input('>> ')
tokenized = user_command.split()
token_one = user_command.split()[0]
if token_one == 'h':
instructions.help_goog()
if token_one == "see":
instructions.see()
if token_one == "ls":
shell.list_directory()
if token_one == "clear":
os.system('clear')
if token_one == "cd":
if len(user_command.split()) < 2:
shell.change_directory('root')
if __name__ == "__main__":
# Parse settings file
api_key, origin, dest = load_settings("../settings.json")
# Create client object
client = Client(key=api_key)
# Get response
rsp = directions(client,
origin,
dest,
mode="transit",
waypoints=None,
alternatives=False,
avoid=None,
language=None,
units="metric",
region=None,
departure_time=None,
arrival_time=None,
optimize_waypoints=False,
transit_mode=None,
transit_routing_preference=None,
traffic_model=None)
parsed = json.loads(json.dumps(rsp, sort_keys=False, indent=4))[0]
print(json.dumps(parsed, sort_keys=False, indent=4))
# Run server
from sys import argv
if len(argv) == 2:
# export FLASK_APP=app.py && python3 -m flask run
from directions import directions as directions
from locations_selectable import selectable_locations_dict as locations_dict
from locations_selectable import selectable_locations_list as locations_list
from flask import Flask
# # Users need to see locations_dict.values() i.e. locations_list, but locations_dict.keys() has to be inputted to the algorithm
# locations_dict = locations_dict()
# locations_list = locations_list()
# print(locations_dict)
# print(f"\n\n")
# print(locations_list)
# Testing algorithm
print(directions("becc", "coleman"))
print(f"\n")
print(directions("woodland_10", "trim"))
print(f"\n")
print(directions("forest", "tomasso"))
app = Flask(__name__)
