def test_is_route(self):
     G = Graph(6, [(1, 2), (2, 3), (1, 4), (5, 6), (6, 5)])
     for u in [1, 2, 3, 4]:
         for v in [5, 6]:
             with self.subTest(u=u, v=v):
                 self.assertFalse(is_route(G, u, v))
                 self.assertFalse(is_route(G, v, u))
     for (u, v) in [(1, 2), (2, 3), (1, 4)]:
         with self.subTest(u=u, v=v):
             self.assertTrue(is_route(G, u, v))
             self.assertFalse(is_route(G, v, u))
     self.assertTrue(is_route(G, 5, 6))
     self.assertTrue(is_route(G, 6, 5))
Esempio n. 2
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def main(domain, path_set):
    """Read domain and graph files to generate the problem, call general_search function
    """

    G = Graph()
    read_graph(G, path_set["GRAPH_FILE"])
    coords = get_coords(path_set["COORDS_FILE"])

    if domain not in ["route", "tsp"]:
        # print "Wrong Domain!"
        return 0

    if domain == "route":
        # Q2: Get domain and search method from route.txt
        route_info = []
        for line in open(path_set["DOMAIN_ROUTE_FILE"]):
            route_info.append(line.strip('\n'))
        start, goal, method = route_info[:3]
        problem = {
            'domain': domain,
            'method': method,
            'graph': G,
            'coords': coords,
            'start': start,
            'goal': goal}

    elif domain == "tsp":
        # Q3: Get domain and search method from tsp.txt
        tsp_info = []
        for line in open(path_set["DOMAIN_TSP_FILE"]):
            tsp_info.append(line.strip('\n'))
        start, method = tsp_info[:2]
        problem = {
            'domain': domain,
            'method': method,
            'graph': G,
            'coords': coords,
            'start': start}

    result = general_search(problem)  # my search algorithm
    if result:
        path, cost, count = result

        print("------------------------------")
        print("domain: \t %s" % domain)
        print("method: \t %s" % method)
        print("node expanded: \t %s" % count)
        print("solution path: \t %s" % " -> ".join(path))
        print("total cost: \t %s" % cost)
    else:
        print("no path!")
Esempio n. 3
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def make_graph_from_maze(coordinate, maze, graph=Graph()):
    x, y = coordinate
    path = maze[y][x]
    cur_vertex = Vertex(coordinate)

    if path == '+':
        return (None, graph)

    if coordinate in graph.data:
        return graph.get_vertex(coordinate), graph

    if x < 0 or y < 0 or x > len(maze[0]) or y > len(maze):
        return Vertex('GOAAAAAAL'), graph

    graph.add_vertex(cur_vertex)

    for x_offset, y_offset in DIRECTION:

        other_vertex, _ = make_graph_from_maze((x + x_offset, y + y_offset),
                                               maze, graph)
        if other_vertex is not None:
            graph.add_edge(cur_vertex, other_vertex, 1)

    return cur_vertex, graph
Esempio n. 4
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 def test_topological_sort(self):
     G = Graph(6, [(1, 4), (6, 2), (2, 4), (6, 1), (4, 3)])
     print(topological_sort(G))
     G = Graph(8, [(1, 3), (1, 4), (2, 4), (3, 4), (3, 5), (5, 8), (6, 5),
                   (6, 7), (7, 8)])
     print(topological_sort(G))
Esempio n. 5
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from mygraph import Graph
from myalgorithm import prims_algorithm

with open('graph_10.txt') as f:
    l = f.readline()
    m = []
    for line in f:
        m.append([int(x) for x in line.split()])
cnt = 0
g = Graph()

weight = []
for i in range(len(m)):
    weight.append(m[i][len(m[i]) - 1])

for i in range(len(m[0]) - 1):
    g.add_vertex(i)

for j in range(len(m)):
    x = None
    y = None
    cnt = 0
    for i in range(len(m[0]) - 1):
        if cnt == 0 and m[j][i] == 1:
            x = i
            cnt = 1
            continue
        if m[j][i] == 1 and cnt == 1:
            y = i
            cnt = 2
        if cnt == 2:
Esempio n. 6
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from mygraph import Node
from mygraph import Graph

g = Graph()

g.add_node('a')
g.add_node('b')
g.add_node('c')
g.add_node('d')
g.add_node('e')
g.add_node('f')

g.add_edge('a', 'b', 7)
g.add_edge('a', 'c', 9)
g.add_edge('a', 'f', 14)
g.add_edge('b', 'c', 10)
g.add_edge('b', 'd', 15)
g.add_edge('c', 'd', 11)
g.add_edge('c', 'f', 2)
g.add_edge('d', 'e', 6)
g.add_edge('e', 'f', 9)

print("Nodes")
for n in g:
    print(g.nodes_dict[n.name])

print("Connections")
for n in g:
    for w in n.get_connections():
        print('( %s , %s, %3d)' % (n.id, w.id, n.get_weight(w)))
Esempio n. 7
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from mygraph import Graph

f=open('graph_18.txt','r')
line = f.readline()
mymatrix = []
weights = []
graph = Graph()
new_graph = {}
count=0
for line in f:
  mymatrix.append([int(x) for x in line.split()])
  graph.add_vertex(count)
  new_graph[count] = {}
  count += 1

for i in range(len(mymatrix)):
  weights.append(mymatrix[i][len(mymatrix[i]) - 1])



for j in range(len(mymatrix)):
  col = 0
  row = 0
  counter = 0
  for i in range(len(mymatrix[0]) - 1):
    if counter == 0 and mymatrix[j][i] == 1:
      col = i
      counter = 1
      continue
    if mymatrix[j][i] == 1 and counter == 1:
      row = i
Esempio n. 8
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from mygraph import Graph
from myalgorithm import dijkstra

with open('graph_36.txt') as file:
    line1 = file.readline()
    incidence_matrix = []
    for line in file:
        incidence_matrix.append([int(x) for x in line.split()])
counter = 0
graph = Graph()
new_graph = {}

weight = []
for i in range(len(incidence_matrix)):
    weight.append(incidence_matrix[i][len(incidence_matrix[i]) - 1])

for i in range(len(incidence_matrix[0]) - 1):
    graph.add_vertex(i)
    new_graph[i] = {}

for j in range(len(incidence_matrix)):
    first_one = None
    second_one = None
    counter = 0
    for i in range(len(incidence_matrix[0]) - 1):
        if counter == 0 and incidence_matrix[j][i] == 1:
            first_one = i
            counter = 1
            continue
        if incidence_matrix[j][i] == 1 and counter == 1:
            second_one = i
Esempio n. 9
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from mygraph import Graph
from myalgorithm import kruskalsalg

with open('graph_17.txt') as f:
    s = f.readline()
    t = []
    for line in f:
        t.append([int(i) for i in line.split()])

cnt = 0
g = Graph()

weight = []
for i in range(len(t)):
    weight.append(t[i][len(t[i]) - 1])

for i in range(len(t[0]) - 1):
    g.add_vertex(i)

for j in range(len(t)):
    x = None
    y = None
    cnt = 0
    for i in range(len(t[0]) - 1):
        if cnt == 0 and t[j][i] == 1:
            x = i
            cnt = 1
            continue
        if t[j][i] == 1 and cnt == 1:
            y = i
            cnt = 2