def main():
graph_file = os.path.dirname(__file__) + "/sf_graph.pickle"
gragh_pickle_in = open(graph_file, "rb")
graph = pickle.load(gragh_pickle_in)
cnns = graph.get_nodes()
if len(sys.argv) == 3:
if sys.argv[1] in cnns and sys.argv[2] in cnns:
start = sys.argv[1]
end = sys.argv[2]
else:
print("invalid start or end node")
assert False
else:
start = random.choice(list(cnns))
end = random.choice(list(cnns))
while end == start:
end = random.choice(list(cnns))
cnnList = list(cnns)
start_ind = cnnList.index(start)
end_ind = cnnList.index(end)
start_node = cnnList[start_ind]
end_node = cnnList[end_ind]
path = dijkstra_search(graph, start_node, end_node)
path = makePathFromDijk(graph, path)
print(path.PHPstring())
def main(start = None, end = None):
#list of strings containing every street with an
#intersection in the grid
exp_node_num = 31
exp_edge_num = 47
streets_in_grid = ["SACRAMENTO ST", "BAKER ST", "SUTTER ST", "STEINER ST", "PERINE PL", "WILMOT ST", "BRODERICK ST", "DIVISADERO ST", "SCOTT ST", "PIERCE ST", "CALIFORNIA ST", "PINE ST", "BUSH ST"]
int_dic = loadIntersections(toPrint=False)
ints_in_grid = {}
#if both streets for intersection are in grid, add the intersection to ints_in_grid
for key in int_dic.keys():
if int_dic[key].get_streets()[0] in streets_in_grid and int_dic[key].get_streets()[1] in streets_in_grid:
ints_in_grid[key] = int_dic[key]
# for key in ints_in_grid.keys():
# print(ints_in_grid[key].get_streets())
# print(len(ints_in_grid))
#get every street where start int and end int are in test Grid
all_streets = load_streets(toPrint=False)
streets_in_grid = {}
for key in all_streets.keys():
if all_streets[key].get_start() in ints_in_grid.keys() and all_streets[key].get_end() in ints_in_grid.keys():
streets_in_grid[key] = all_streets[key]
# for key in streets_in_grid.keys():
# sne = streets_in_grid[key].get_start_name_end()
# print("{}->{}->{}".format(ints_in_grid[sne[0]].get_streets(), sne[1], ints_in_grid[sne[2]].get_streets()))
# print(len(streets_in_grid))
digraph = build_graph(ints_in_grid, streets_in_grid)
# print("Args: {}".format(sys.argv))
# print("Arg length: {}".format(len(sys.argv)))
if len(sys.argv) == 3:
if sys.argv[1] in ints_in_grid.keys() and sys.argv[2] in ints_in_grid.keys():
start = sys.argv[1]
end = sys.argv[2]
else:
print("invalid start or end node")
assert False
else:
start = random.choice(list(ints_in_grid.keys()))
end = random.choice(list(ints_in_grid.keys()))
while end == start:
end = random.choice(list(ints_in_grid.keys()))
start_int = ints_in_grid[start]
end_int = ints_in_grid[end]
start_node= SF_intersection(start_int.get_cnn(), start_int.get_streets(), start_int.get_loc(), start_int.get_elev())
end_node= SF_intersection(end_int.get_cnn(), end_int.get_streets(), end_int.get_loc(), end_int.get_elev())
bf_path = search(digraph, start_node, end_node)
print("start:{} - {}".format(start_int.get_streets(), start_int.get_cnn()))
print("end:{} - {}".format(end_int.get_streets(), end_int.get_cnn()))
print("brute force: " + str(bf_path))
print(bf_path.get_weight())
print()
dp_path = dsearch(digraph, start_node, end_node)
print()
print("dynamic p: " + str(dp_path))
print(dp_path.get_node_list())
print(dp_path.get_weight())
print("\nDystra:")
dpath = dijkstra_search(digraph, start_node, end_node, toPrint=False)
dyspath = makePathFromDijk(digraph, dpath)
print(dyspath)
print(dpath)
print(dyspath.get_weight())
