def test_nested_while(self):
        # weights = [AdaptType(1), AdaptType(1), AdaptType("k"), AdaptType("k"), AdaptType("k"), AdaptType("k * k"), AdaptType("k * k")]
        query = [0, 1, 0, 0, 1, 0, 1]
        edges = [(0, 2), (1, 4), (1, 6), (2, 2), (2, 3), (3, 5), (5, 5), (6, 4), (6, 6)]
        weights = [AdaptType("INF")]*len(query)

        ctl_edges = [(0, 1), (1, 2), (2, 3), (3, 4), (4, 5), (5, 6), (6, 7), (6, 2), (7, 8), (8, 6)]
        transitions = [
            (0, [DifferenceConstraint("i", None, "k", DifferenceConstraint.DCType.RESET)], 1, [0]),
            (1, [DifferenceConstraint("x", None, "Q", DifferenceConstraint.DCType.RESET)], 2, [1]),
            (1, [], 1, []),
            (1, [DifferenceConstraint("i", None, "1", DifferenceConstraint.DCType.DEC)], 1, [2]),
            (1, [DifferenceConstraint("j", None, "k", DifferenceConstraint.DCType.RESET)], 1, [3]),
            (1, [DifferenceConstraint("y", "x", "Q", DifferenceConstraint.DCType.RESET)], 1, [4]),
            (1, [], 1, []),
            (1, [], 1, []),
            (1, [DifferenceConstraint("j", None, "1", DifferenceConstraint.DCType.DEC)], 2, [5]),
            (1, [DifferenceConstraint("x", None, "Q", DifferenceConstraint.DCType.RESET)], 2, [6])
            ] 


        bound_infer = self.ALG(Graph(edges, weights, query), TransitionGraph(ctl_edges, transitions))
        bound_infer.attach_weights()
        print("The Reachability Bounds Expected for  Vertices in the Simple Nested While Graph are: [1, 1, k, k, k, k^2, k^2] ")
        print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())

        adapt_search = AdaptSearchAlgRefined(bound_infer.graph)
        adapt_search.search_adapt()
        print("The Adaptivity Expected for Simple Nested While Algorithm is: 2 + k * k ")
        print("The Adaptivity From This Graph is: ", adapt_search.get_adapt())
    def seq_multivar(self):
        query = [1, 1, 1, 1]
        edges = [(0, 1), (0, 2), (1, 2), (1, 3), (2, 3)]
        weights = [AdaptType("INF")] * len(query)

        # adapt_search = self.ALG(Graph(edges, weights, query))

        ctl_edges = [(2, 3), (1, 2), (0, 1), (3, 4)]
        transitions = [
            (2, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 3, [2]),
            (1, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [1]),
            (0, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]),
            (3, [
                DifferenceConstraint("w", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], -1, [3])
        ]
        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))
        print(
            "The Reachability Bounds Expected for  Vertices in Pure Sequence Graph are: [1,1,1,1] "
        )
        print("The Adaptivity Expected for Simple Seq Algorithm is: 4 ")
    def test_multiple_constriants(self):
        query = [0, 0, 0, 1, 0, 1]
        edges = [(0, 2), (1, 2), (1,4), (2,2), (2, 3), (3, 4), (4, 4), (4, 5)]
        weights = [AdaptType("INF")]*len(query)

        ctl_edges = [(0, 1), (1, 1), (1, 2)]
        transitions = [(0, 
        [DifferenceConstraint("i", None, "k", DifferenceConstraint.DCType.RESET),
        DifferenceConstraint("l", None, "Q", DifferenceConstraint.DCType.RESET)
        ], 1, [0, 1]),
        (1, [DifferenceConstraint("i", None, "1", DifferenceConstraint.DCType.DEC),
        DifferenceConstraint("a", None, "Q", DifferenceConstraint.DCType.RESET),
        DifferenceConstraint("l", "a", "0", DifferenceConstraint.DCType.INC)], 1, [2, 3, 4]),
        (1, [DifferenceConstraint("b", "l", "Q", DifferenceConstraint.DCType.RESET)], 2, [5])]


        bound_infer = self.ALG(Graph(edges, weights, query), TransitionGraph(ctl_edges, transitions))
        bound_infer.attach_weights()
        print("The Reachability Bounds Expected for  Vertices in the Two Round Graph are: [1, 1, k, k, k, 1] ")
        print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())
       
        adapt_search = AdaptSearchAlgRefined(bound_infer.graph)
        adapt_search.search_adapt()
        print("The Adaptivity Expected for Two Round Algorithm is: 2 ")
        print("The Adaptivity From This Graph is: ", adapt_search.get_adapt())
    def test_simple_nested_approximated(self):
        # weights = [AdaptType(1), AdaptType("k"), AdaptType("k"), AdaptType(1)]
        query = [0, 0, 0, 1, 0, 1]
        edges = [(0, 4), (1, 2), (1, 3), (2, 3), (3, 2), (3, 3)]
        weights = [AdaptType("INF")]*len(query)

        ctl_edges = [(0, 1), (1, 2), (2, 1), (2, 2)]
        transitions = [
            (0, [DifferenceConstraint("i", None, "k", DifferenceConstraint.DCType.RESET)], 1, [0]),
            (1, [DifferenceConstraint("i", None, "1", DifferenceConstraint.DCType.DEC),
            DifferenceConstraint("j", "i", "0", DifferenceConstraint.DCType.RESET)], 2, [1, 2]),
            (2, [DifferenceConstraint("j", None, "1", DifferenceConstraint.DCType.DEC)], 2, [3]),
            (2, [], 1, [])
            ]


        bound_infer = self.ALG(Graph(edges, weights, query), TransitionGraph(ctl_edges, transitions))
        bound_infer.attach_weights()
        print("The Reachability Bounds Expected for  Vertices in the Simple Nested While Graph are: [1, k, k, k!] ")
        print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())

        adapt_search = AdaptSearchAlgRefined(bound_infer.graph)
        adapt_search.search_adapt()
        print("The Adaptivity Expected for Simple Nested While Algorithm is: 2 + k! ")
        print("The Adaptivity From This Graph is: ", adapt_search.get_adapt())
 def test_if_val(self):
     weights = [AdaptType(1), AdaptType(1), AdaptType(1), AdaptType(1)]
     query = [1, 1, 1, 0]
     edges = [(0, 2), (1, 2), (1, 3)]
     adapt_search = self.ALG(Graph(edges, weights, query))
     adapt_search.search_adapt()
     print("The Adaptivity Expected for This Graph is: 2 ")
     print("The Adaptivity From This Graph is: ", adapt_search.get_adapt())
    def nested_while_multivaldep(self):
        # weights = [AdaptType(1), AdaptType(1), AdaptType("k"), AdaptType("k"), AdaptType("k"), AdaptType("k * k"), AdaptType("k * k")]
        query = [0, 1, 1, 0, 1, 0, 0, 1]
        edges = [(0, 3), (1, 4), (1, 7), (2, 4), (4, 4), (4, 7), (7, 4),
                 (7, 7)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(8, 9), (7, 8), (9, 7), (6, 7), (5, 6), (4, 5), (3, 4),
                     (7, 3), (2, 3), (1, 2), (0, 1), (3, 10)]
        transitions = [
            (7, [
                DifferenceConstraint("j", None, " 1 ",
                                     DifferenceConstraint.DCType.DEC)
            ], 8, [6]), (6, [], 7, []),
            (9, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 7, [7]),
            (6, [
                DifferenceConstraint("j", None, "k",
                                     DifferenceConstraint.DCType.RESET)
            ], 7, [5]),
            (5, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 6, [4]),
            (4, [
                DifferenceConstraint("i", None, " 1 ",
                                     DifferenceConstraint.DCType.DEC)
            ], 5, [3]), (2, [], 3, []), (6, [], 2, []),
            (2, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 3, [2]),
            (1, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [1]),
            (0, [
                DifferenceConstraint("i", None, "k",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]), (2, [], -1, [])
        ]

        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))

        # bound_infer = self.ALG(Graph(edges, weights, query), TransitionGraph(ctl_edges, transitions))
        # bound_infer.attach_weights()
        print(
            "The Reachability Bounds Expected for  Vertices in the Simple Nested While Graph are: [1, 1, k, k, k, k^2, k^2] "
        )
        print(
            "The Adaptivity Expected for Simple Nested While Algorithm is: 1 + k + k * k "
        )
Ejemplo n.º 7
0
    def dcfg_parse(self):
        with open(self.args.dcfg, "r") as graphdata:
            n = int(graphdata.readline())
            query = [
                int(q) for q in graphdata.readline().strip("\n").split(",")
            ]
            edges = [([int(v) for v in e.split(",")])
                     for e in graphdata.readline().split(";")]

            print(n, query, edges)
            return Graph(edges, [AdaptType(0)] * n, query)
    def while_multivaldep(self):
        query = [0, 1, 1, 0, 1, 1, 1]
        edges = [(0, 3), (0, 4), (1, 4), (2, 4), (4, 6), (6, 4), (4, 5),
                 (5, 4)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(6, 7), (5, 6), (4, 5), (3, 4), (7, 3), (2, 3), (1, 2),
                     (0, 1), (3, 8)]
        transitions = [
            (6, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 7, [5]),
            (5, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 6, [4]),
            (4, [
                DifferenceConstraint("i", None, "1",
                                     DifferenceConstraint.DCType.DEC)
            ], 5, [3]), (3, [], 4, []),
            (7, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 3, [6]),
            (2, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 3, [2]),
            (1, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [1]),
            (0, [
                DifferenceConstraint("i", None, "k",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]), (3, [], -1, [])
        ]

        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))
        print(
            "The Reachability Bounds Expected for Vertices in while Multi Variable Dependency: [1, 1, 1, k, k, k, k] "
        )

        print(
            "The Adaptivity Expected for while with (Multi Variable Dependency) Algorithm is: 1 + 2 * k"
        )
    def while_multipath_ctldep(self):
        query = [1, 0, 1, 1, 0, 1]
        edges = [(0, 2), (0, 3), (0, 4), (1, 2), (1, 3), (2, 2), (2, 5),
                 (3, 3), (3, 5), (4, 4)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(3, 4), (3, 5), (4, 6), (5, 6), (2, 3), (6, 2), (2, 7),
                     (1, 2), (0, 1), (7, 8)]
        transitions = [
            (3, [], 4, []), (3, [], 5, []),
            (4, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 6, [2]),
            (5, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 6, [3]), (2, [], 3, []),
            (6, [
                DifferenceConstraint("x", None, " 1 ",
                                     DifferenceConstraint.DCType.DEC)
            ], 2, [4]), (2, [], 7, []),
            (1, [
                DifferenceConstraint("y", None, " 0 ",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [1]),
            (0, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]),
            (7, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], -1, [5])
        ]

        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))
        print(
            "The Reachability Bounds Expected for  Vertices in while with If Banch inside are: [1, 1, Q, Q, Q, 1] "
        )

        print(
            "The Adaptivity Expected for while with If Banch (Multi-Path While Loop) Algorithm is: 2 + Q"
        )
    def two_round(self):
        query = [0, 0, 0, 1, 0, 1]
        edges = [(0, 2), (1, 4), (2, 2), (2, 3), (2, 4), (3, 4), (4, 4),
                 (4, 5)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(4, 5), (3, 4), (2, 3), (5, 2), (2, 6), (1, 2), (0, 1),
                     (6, 7)]
        transitions = [
            (4, [
                DifferenceConstraint("a", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 5, [3]),
            (3, [
                DifferenceConstraint("i", None, " 1 ",
                                     DifferenceConstraint.DCType.DEC)
            ], 4, [2]), (2, [], 3, []),
            (5, [
                DifferenceConstraint("l", None, "INF",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [4]), (2, [], 6, []),
            (1, [
                DifferenceConstraint("l", None, " 0 ",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [1]),
            (0, [
                DifferenceConstraint("i", None, " k ",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]),
            (6, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 7, [5])
        ]

        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))
        print(
            "The Reachability Bounds Expected for  Vertices in the Two Round Graph are: [1, 1, k, k, k, 1] "
        )
        # print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())

        # adapt_search = AdaptSearchAlgRefined(bound_infer.graph)
        # adapt_search.search_adapt()
        print("The Adaptivity Expected for Two Round Algorithm is: 2 ")
    def test_seq(self):
        weights = [AdaptType(0), AdaptType(0), AdaptType(0), AdaptType(0)]
        query = [1, 1, 1, 1]
        edges = [(0, 1), (1, 2), (1, 3), (2, 3)]
        # adapt_search = self.ALG(Graph(edges, weights, query))

        ctl_edges = [(0, 1)]
        transitions = [(0, [DifferenceConstraint("x", None, "k", DifferenceConstraint.DCType.RESET)], 1, [0, 1, 2 ,3])]


        bound_infer = self.ALG(Graph(edges, weights, query), TransitionGraph(ctl_edges, transitions))
        bound_infer.attach_weights()
        print("The Reachability Bounds Expected for  Vertices in Pure Sequence Graph are: [1,1,1,1] ")
        print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())
        adapt_search = AdaptSearchAlgRefined(bound_infer.graph)

        adapt_search.search_adapt()
        print("The Adaptivity Expected for Simple Seq Algorithm is: 4 ")
        print("The Adaptivity From This Graph is: ", adapt_search.get_adapt())
    def while_valdep(self):
        query = [0, 0, 1, 0, 0]
        edges = [(0, 2), (0, 3), (0, 4), (1, 2), (1, 3), (2, 3), (3, 2),
                 (3, 3), (4, 4)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(4, 5), (3, 4), (2, 3), (5, 2), (1, 2), (0, 1), (2, 7)]

        transitions = [
            (4, [
                DifferenceConstraint("l", None, "INF",
                                     DifferenceConstraint.DCType.RESET)
            ], 5, [3]),
            (3, [
                DifferenceConstraint("a", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 4, [2]), (2, [], 3, []),
            (5, [
                DifferenceConstraint("i", None, " 1 ",
                                     DifferenceConstraint.DCType.DEC)
            ], 2, [4]),
            (1, [
                DifferenceConstraint("l", None, " 0 ",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [1]),
            (0, [
                DifferenceConstraint("i", None, " 100 ",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]), (2, [], -1, [])
        ]
        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))
        print(
            "The Reachability Bounds Expected for  Vertices in Simple while are: [1, 1, 100, 100, 100] "
        )
        # print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())

        # adapt_search = AdaptSearchAlgRefined(bound_infer.graph)
        # adapt_search.search_adapt()
        print("The Adaptivity Expected for Simple While Algorithm is: 100 ")
    def if_ctldep(self):
        query = [1, 1, 1, 1]
        edges = [(0, 1), (1, 2), (1, 3)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(0, 1), (1, 2), (2, 3), (2, 4), (3, 5), (4, 5)]
        transitions = [
            (0, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]),
            (0, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [1]),
            (0, [], 1, []),
            (0, [], 1, []),
            (0, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [2]),
            (0, [
                DifferenceConstraint("w", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [3]),
        ]

        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))

        # bound_infer = self.ALG(Graph(edges, weights, query), TransitionGraph(ctl_edges, transitions))
        # bound_infer.attach_weights()
        print(
            "The Reachability Bounds Expected for  Vertices in If Branch with Control Dependency Graph are: [1, 1, 1, 1] "
        )
        print(
            "The Adaptivity Expected for Mutli-path Dependency in If branch Algorithm is: 3 "
        )
    def if_valdep(self):
        query = [1, 0, 1, 1]
        edges = [(0, 2), (1, 2), (1, 3)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(0, 1), (1, 2), (2, 3), (2, 4), (3, 5), (4, 5)]
        transitions = [
            (0, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]),
            (0, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [1]),
            (0, [], 1, []),
            (0, [], 1, []),
            (0, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [2]),
            (0, [
                DifferenceConstraint("y", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [3]),
        ]

        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))
        print(
            "The Reachability Bounds Expected for Mutli-path Dependency in If branch Algorithm are: [1,1,1,1] "
        )

        # adapt_search = AdaptSearchAlgRefined(bound_infer.graph)
        # adapt_search.search_adapt()
        print(
            "The Adaptivity Expected for Mutli-path Dependency in If branch Algorithm is: 2 "
        )
    def while_valctldep(self):
        query = [1, 1, 1, 1]
        edges = [(0, 2), (0, 3), (1, 2), (2, 3), (3, 2)]
        weights = [AdaptType("INF")] * len(query)

        ctl_edges = [(3, 4), (2, 3), (4, 2), (1, 2), (0, 1), (2, 5)]

        transitions = [
            (3, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 4, [2]), (2, [], 3, []),
            (4, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [3]),
            (1, [
                DifferenceConstraint("z", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 2, [1]),
            (0, [
                DifferenceConstraint("x", None, "Q",
                                     DifferenceConstraint.DCType.RESET)
            ], 1, [0]), (2, [], -1, [])
        ]
        AdaptEstimate.adapt_estimate(Graph(edges, weights, query),
                                     TransitionGraph(ctl_edges, transitions))
        print(
            "The Reachability Bounds Expected for  Vertices in While with Control and Value Dependency Overlapped are: [1, 1, INF, INF] "
        )
        # print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())

        # adapt_search = AdaptSearchAlgRefined(bound_infer.graph)
        # adapt_search.search_adapt()
        print(
            "The Adaptivity Expected for While with Control and Value Dependency Overlapped Algorithm is: INF "
        )
    def test_while_multipath_if(self):
        query = [0, 1, 0, 1, 1, 1]
        edges = [(0, 4), (1, 2), (1, 3), (2, 3), (3, 2), (3, 3)]
        weights = [AdaptType("INF")]*len(query)



        ctl_vertices_num = 4
        ctl_edges = [(0, 1), (1, 2), (2, 3), (2, 3), (3, 1)]
        transitions = [
            (0, [DifferenceConstraint("i", None, "k", DifferenceConstraint.DCType.RESET),
            DifferenceConstraint("x", None, "Q", DifferenceConstraint.DCType.RESET)], 1, [0, 1]),
            (1, [DifferenceConstraint("i", None, "1", DifferenceConstraint.DCType.DEC)], 2, [2]),
            (2, [DifferenceConstraint("y", None, "Q", DifferenceConstraint.DCType.RESET)], 3, [3]),
            (2, [DifferenceConstraint("y", None, "Q", DifferenceConstraint.DCType.RESET)], 3, [4]),
            (3, [DifferenceConstraint("x", None, "Q", DifferenceConstraint.DCType.RESET)], 2, [5])
            ]
        is_scc = [False, True, True, True, True]


        bound_infer = self.ALG(Graph(edges, weights, query), TransitionGraph(ctl_edges, transitions))
        bound_infer.attach_weights()
        print("The Reachability Bounds Expected for  Vertices in the Multiple Path Simple While Graph are: [1, 1, k, k/2, k/2, k] ")
        print("The Reachability Bounds Calculated for Vertices in This Graph are: ", bound_infer.get_weights())
Ejemplo n.º 17
0
 def __init__(
     self, graph=Graph(), transition_graph=TransitionGraph()) -> None:
     self.graph = graph
     self.transition_graph = transition_graph