コード例 #1
0
ファイル: processingMain.py プロジェクト: MIBbrandon/Athena
def coreExecution(inputG_swaps, inputG_interactions, soddi):
    # Check that the data types of the contents are valid
    checkExtractedContents(inputG_swaps, inputG_interactions, soddi)
    # Map each node to a number (index in list) which will be used to identify it afterwards
    ids = idNodes(inputG_swaps)
    adaptedG_swapsEdges, adaptedG_interactionsEdges, adaptedSODDI = adaptNodeNamesToIDs(
        ids, inputG_interactions, inputG_swaps, soddi)
    # Create the actual graphs and check them
    G_swaps = nx.Graph()
    G_swaps.add_nodes_from(range(len(ids)))
    G_swaps.add_edges_from(adaptedG_swapsEdges)
    checkingG_swaps(G_swaps)
    G_interactions = nx.DiGraph()
    G_interactions.add_nodes_from(range(len(ids)))
    G_interactions.add_edges_from(adaptedG_interactionsEdges)
    checkingG_interactions(G_interactions)
    # Check SODDI
    checkingSODDI(adaptedSODDI, len(ids))
    # From this point on, we are ready to manipulate the graphs as we wish
    newG_swaps, newG_interactions, allSwapSteps = swapsRequired(
        G_swaps, G_interactions, adaptedSODDI)
    # Rename every node in allSwapSteps to the original names
    renamedAllSwapSteps = revertAllSwapStepsNames(allSwapSteps, ids)
    totalSwaps = len([x for x in renamedAllSwapSteps if type(x) is tuple])
    print("SODDI: " + str(soddi))
    print("Swap steps: " + str(renamedAllSwapSteps))
    print("Total number of swaps required: " + str(totalSwaps))
    return totalSwaps, renamedAllSwapSteps, ids
コード例 #2
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    def test_SODDIInvalidSelfInteractions(self):
        # Test that an exception is thrown when there is a desired interaction in SODDI of a node with itself
        G_interactions = nx.DiGraph()
        G_interactions.add_nodes_from([0, 1, 2, 3])

        # There is no node 4, since there are only 4 nodes going from 0 to 3
        soddi = [(1, 1)]
        with self.assertRaises(Exception,
                               msg=CONST_SODDIInvalidSelfInteractions):
            checkingSODDI(soddi, len(list(G_interactions.nodes)))
コード例 #3
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    def test_SODDIIntegersWithinRange(self):
        # Test that an exception is thrown when the ints in SODDI are not within range

        G_interactions = nx.DiGraph()
        G_interactions.add_nodes_from([0, 1, 2, 3])

        # There is no node 4, since there are only 4 nodes going from 0 to 3
        soddi = [(2, 4)]
        with self.assertRaises(Exception, msg=CONST_SODDINodesOutOfRange):
            checkingSODDI(soddi, len(list(G_interactions.nodes)))

        # There is no node -1, since there are labelled from 0 to the number of nodes - 1
        soddi = [(2, -1)]
        with self.assertRaises(Exception, msg=CONST_SODDINodesOutOfRange):
            checkingSODDI(soddi, len(list(G_interactions.nodes)))
コード例 #4
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    def test_SODDIInputType(self):
        # Test that an exception is thrown when SODDI is not a list of tuples of ints

        G_interactions = nx.DiGraph()
        G_interactions.add_nodes_from([0, 1, 2, 3])

        # Checking for soddi not being a list
        soddi = "#"
        with self.assertRaises(Exception, msg=CONST_SODDIbadFormat):
            checkingSODDI(soddi, len(list(G_interactions.nodes)))

        # Checking for soddi not being a list of tuples
        soddi = [42]
        with self.assertRaises(Exception, msg=CONST_SODDIbadFormat):
            checkingSODDI(soddi, len(list(G_interactions.nodes)))

        # Checking for soddi not being a list of tuples of ints
        soddi = [("#", 2.5)]
        with self.assertRaises(Exception, msg=CONST_SODDIbadFormat):
            checkingSODDI(soddi, len(list(G_interactions.nodes)))
コード例 #5
0
ファイル: processingMain.py プロジェクト: MIBbrandon/Athena
def randomInput():
    for i in range(rounds):
        ####################################################
        # INPUT 1: Graph representing real swappable nodes #
        ####################################################
        G_swaps = G_preSwaps = None
        connected = False
        planar = False
        print("Searching for connected graph...")
        while not (connected and planar):
            G_swaps = G_preSwaps = nx.erdos_renyi_graph(
                numberOfNodes, edgeCreationProbabilitySwaps, directed=False)
            connected = nx.is_connected(G_preSwaps)
            planar = nx.check_planarity(G_preSwaps)
        print("\nConnected graph found!")

        drawOriginalGSwap(G_preSwaps)

        ################################################################
        # INPUT 2: Graph representing direct interaction possibilities #
        ################################################################

        G_interactions = nx.DiGraph()
        G_interactions.add_nodes_from(range(
            numberOfNodes))  # G_interactions has the same nodes as G_swaps

        def createRandomGInteractions(G_interactions):
            if randomInteractionGraph:
                hasOneEdge = False
                while not hasOneEdge:
                    for x in range(random.randint(0,
                                                  round(numberOfNodes * 2))):
                        if random.uniform(0, 1) < 0.5:
                            firstNode = random.randint(0, numberOfNodes - 1)
                            secondNode = random.randint(0, numberOfNodes - 1)
                            while firstNode == secondNode:  # Avoid edges from node to itself
                                firstNode = random.randint(
                                    0, numberOfNodes - 1)
                                secondNode = random.randint(
                                    0, numberOfNodes - 1)
                            if not G_interactions.has_edge(
                                    firstNode, secondNode):
                                G_interactions.add_edge(firstNode, secondNode)
                        else:
                            firstNode = random.randint(0, numberOfNodes - 1)
                            secondNode = random.randint(0, numberOfNodes - 1)
                            while firstNode == secondNode:  # Avoid edges from node to itself
                                firstNode = random.randint(
                                    0, numberOfNodes - 1)
                                secondNode = random.randint(
                                    0, numberOfNodes - 1)
                            if G_interactions.has_edge(firstNode, secondNode):
                                G_interactions.remove_edge(
                                    firstNode, secondNode)
                    hasOneEdge = G_interactions.edges

        createRandomGInteractions(G_interactions)

        print("Edges in G_swaps:")
        print([e for e in G_swaps.edges])
        print()
        print("Edges in G_interactions:")
        print([e for e in G_interactions.edges])
        print()
        print("G_interactions isolates: " +
              str(list(nx.isolates(G_interactions))) + "\n")

        drawGInteractions(G_interactions)

        ############################################################
        # INPUT 3: Sequence of desired direct interactions (SODDI) #
        ############################################################

        # Just a simple tuple of tuples which represents which nodes we want interaction between and in what order
        soddi = [
            valid_interaction for valid_interaction in (
                (random.randrange(numberOfNodes),
                 random.randrange(numberOfNodes))
                for i in range(random.randint(*nInteractions)))
            if valid_interaction[0] != valid_interaction[1]
        ]

        print("SODDI: ")
        print(soddi)

        #############################################################################################
        #										END OF INPUTS 										#
        #############################################################################################
        """
		We must check that the inputs are valid. Here are the requirements:
			1) G_swaps must be an undirected connected graph of nodes labelled 0 to (nodes-1)
			2) G_interactions must have the same nodes as G_swaps, it must have at least one edge somewhere and no node may have
			   an edge pointing to itself
			3) SODDI must be a list of tuples, with each tuple containing a pair of numbers, and each number must correspond to
			   one node. No tuple may have both numbers be the same
		"""
        # Checking requirement 1
        checkingG_swaps(G_swaps)

        # Checking requirement 2
        checkingG_interactions(G_interactions)

        # Checking requirement 3
        checkingSODDI(soddi, len(list(G_swaps.nodes)))

        # Now that we have checked the inputs, we want to evaluate what is the minimum number of swaps required to achieve
        # all of the desired interactions

        # First, we want to measure how many swaps are necessary with the initial configuration
        newG_swaps, newG_interactions, swaps = swapsRequired(
            G_swaps, G_interactions, soddi)

        drawNewGSwaps(newG_swaps)