Esempio n. 1
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    def test_save(self):
        g = Graph.Graph([
                (1,2),
                (1,3),
                (1,4),
                (2,4),
                (2,6),
                (2,7),
                (7,4),
                (6,1),
            ]
        )

        dot = Dot.Dot(g)
        dot.style(graph="foobar")
        dot.node_style(1, key='value')
        dot.node_style(2, key='another', key2='world')
        dot.edge_style(1,4, key1='value1', key2='value2')
        dot.edge_style(2,4, key1='valueA')

        fn = 'test_dot.dot'
        self.assertTrue(not os.path.exists(fn))

        try:
            dot.save_dot(fn)

            fp = open(fn, 'r')
            data = fp.read()
            fp.close()
            self.assertEqual(data, ''.join(dot))

        finally:
            if os.path.exists(fn):
                os.unlink(fn)
Esempio n. 2
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    def test_constructor(self):
        o = modulegraph.ModuleGraph()
        self.assertTrue(o.path is sys.path)
        self.assertEqual(o.lazynodes, {})
        self.assertEqual(o.replace_paths, ())
        self.assertEqual(o.debug, 0)

        # Stricter tests would be nice, but that requires
        # better control over what's on sys.path
        self.assertIsInstance(o.nspackages, dict)

        g = Graph.Graph()
        o = modulegraph.ModuleGraph(['a', 'b', 'c'], ['modA'], [
                ('fromA', 'toB'), ('fromC', 'toD')],
                {
                    'modA': ['modB', 'modC'],
                    'modC': ['modE', 'modF'],
                }, g, 1)
        self.assertEqual(o.path, ['a', 'b', 'c'])
        self.assertEqual(o.lazynodes, {
            'modA': None,
            'modC': ['modE', 'modF'],
        })
        self.assertEqual(o.replace_paths, [('fromA', 'toB'), ('fromC', 'toD')])
        self.assertEqual(o.nspackages, {})
        self.assertTrue(o.graph is g)
        self.assertEqual(o.debug, 1)
Esempio n. 3
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    def test_node_style(self):
        g = Graph.Graph([
                (1,2),
                (1,3),
                (1,4),
                (2,4),
                (2,6),
                (2,7),
                (7,4),
                (6,1),
            ]
        )

        dot = Dot.Dot(g)

        self.assertEqual(dot.nodes[1], {})

        dot.node_style(1, key='value')
        self.assertEqual(dot.nodes[1], {'key': 'value'})

        dot.node_style(1, key2='value2')
        self.assertEqual(dot.nodes[1], {'key2': 'value2'})
        self.assertEqual(dot.nodes[2], {})

        dot.all_node_style(key3='value3')
        for n in g:
            self.assertEqual(dot.nodes[n], {'key3': 'value3'})

        self.assertTrue(9 not in dot.nodes)
        dot.node_style(9, key='value')
        self.assertEqual(dot.nodes[9], {'key': 'value'})
Esempio n. 4
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    def test_edge_style(self):
        g = Graph.Graph([
                (1,2),
                (1,3),
                (1,4),
                (2,4),
                (2,6),
                (2,7),
                (7,4),
                (6,1),
            ]
        )

        dot = Dot.Dot(g)

        self.assertEqual(dot.edges[1][2], {})
        dot.edge_style(1,2, foo='bar')
        self.assertEqual(dot.edges[1][2], {'foo': 'bar'})

        dot.edge_style(1,2, foo2='2bar')
        self.assertEqual(dot.edges[1][2], {'foo2': '2bar'})

        self.assertEqual(dot.edges[1][3], {})

        self.assertFalse(6 in dot.edges[1])
        dot.edge_style(1,6, foo2='2bar')
        self.assertEqual(dot.edges[1][6], {'foo2': '2bar'})

        self.assertRaises(GraphError, dot.edge_style, 1, 9, a=1)
        self.assertRaises(GraphError, dot.edge_style, 9, 1, a=1)
Esempio n. 5
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    def test_simple(self):
        a = Graph.Graph()
        self.assertEqual(GraphStat.degree_dist(a), [])

        a.add_node(1)
        a.add_node(2)
        a.add_node(3)

        self.assertEqual(GraphStat.degree_dist(a),
                         GraphStat._binning([0, 0, 0]))

        for x in range(100):
            a.add_node(x)

        for x in range(1, 100):
            for y in range(1, 50):
                if x % y == 0:
                    a.add_edge(x, y)

        counts_inc = []
        counts_out = []
        for n in a:
            counts_inc.append(a.inc_degree(n))
            counts_out.append(a.out_degree(n))

        self.assertEqual(GraphStat.degree_dist(a),
                         GraphStat._binning(counts_out))
        self.assertEqual(GraphStat.degree_dist(a, mode='inc'),
                         GraphStat._binning(counts_inc))
Esempio n. 6
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    def test_style(self):
        g = Graph.Graph([])

        dot = Dot.Dot(g)

        self.assertEqual(dot.attr, {})

        dot.style(key='value')
        self.assertEqual(dot.attr, {'key': 'value'})

        dot.style(key2='value2')
        self.assertEqual(dot.attr, {'key2': 'value2'})
Esempio n. 7
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    def setUp(self):
        self.edges = [(1, 2), (2, 4), (1, 3), (2, 4), (3, 4), (4, 5), (6, 5),
                      (6, 14), (14, 15), (6, 15), (5, 7), (7, 8), (7, 13),
                      (12, 8), (8, 13), (11, 12), (11, 9), (13, 11), (9, 13),
                      (13, 10)]

        # these are the edges
        self.store = {}
        self.g = Graph.Graph()
        for head, tail in self.edges:
            self.store[head] = self.store[tail] = None
            self.g.add_edge(head, tail)
Esempio n. 8
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    def test_filter_stack(self):
        g = Graph.Graph()
        g.add_node("1", "N.1")
        g.add_node("1.1", "N.1.1")
        g.add_node("1.1.1", "N.1.1.1")
        g.add_node("1.1.2", "N.1.1.2")
        g.add_node("1.1.3", "N.1.1.3")
        g.add_node("1.1.1.1", "N.1.1.1.1")
        g.add_node("1.1.1.2", "N.1.1.1.2")
        g.add_node("1.1.2.1", "N.1.1.2.1")
        g.add_node("1.1.2.2", "N.1.1.2.2")
        g.add_node("1.1.2.3", "N.1.1.2.3")
        g.add_node("2", "N.2")

        g.add_edge("1", "1.1")
        g.add_edge("1.1", "1.1.1")
        g.add_edge("1.1", "1.1.2")
        g.add_edge("1.1", "1.1.3")
        g.add_edge("1.1.1", "1.1.1.1")
        g.add_edge("1.1.1", "1.1.1.2")
        g.add_edge("1.1.2", "1.1.2.1")
        g.add_edge("1.1.2", "1.1.2.2")
        g.add_edge("1.1.2", "1.1.2.3")

        v, r, o = GraphUtil.filter_stack(
            g, "1", [lambda n: n != "N.1.1.1", lambda n: n != "N.1.1.2.3"])

        self.assertEqual(
            v,
            set([
                "1", "1.1", "1.1.1", "1.1.2", "1.1.3", "1.1.1.1", "1.1.1.2",
                "1.1.2.1", "1.1.2.2", "1.1.2.3"
            ]))
        self.assertEqual(r, set(["1.1.1", "1.1.2.3"]))

        o.sort()
        self.assertEqual(o, [("1.1", "1.1.1.1"), ("1.1", "1.1.1.2")])

        v, r, o = GraphUtil.filter_stack(
            g, "1", [lambda n: n != "N.1.1.1", lambda n: n != "N.1.1.1.2"])

        self.assertEqual(
            v,
            set([
                "1", "1.1", "1.1.1", "1.1.2", "1.1.3", "1.1.1.1", "1.1.1.2",
                "1.1.2.1", "1.1.2.2", "1.1.2.3"
            ]))
        self.assertEqual(r, set(["1.1.1", "1.1.1.2"]))

        self.assertEqual(o, [
            ("1.1", "1.1.1.1"),
        ])
Esempio n. 9
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def generate_scale_free_graph(steps, growth_num, self_loops=False, multi_edges=False):
    '''
    Generates and returns a :py:class:`~altgraph.Graph.Graph` instance that will have *steps* \* *growth_num* nodes
    and a scale free (powerlaw) connectivity. Starting with a fully connected graph with *growth_num* nodes
    at every step *growth_num* nodes are added to the graph and are connected to existing nodes with
    a probability proportional to the degree of these existing nodes.
    '''
    # FIXME: The code doesn't seem to do what the documentation claims.
    graph = Graph.Graph()

    # initialize the graph
    store = []
    for i in range(growth_num):
        #store   += [ i ] * (growth_num - 1)
        for j in range(i + 1, growth_num):
            store.append(i)
            store.append(j)
            graph.add_edge(i,j)

    # generate
    for node in range(growth_num, steps * growth_num):
        graph.add_node(node)
        while ( graph.out_degree(node) < growth_num ):
            nbr = random.choice(store)

            # loop defense
            if node == nbr and not self_loops:
                continue

            # multi edge defense
            if graph.edge_by_node(node, nbr) and not multi_edges:
                continue

            graph.add_edge(node, nbr)


        for nbr in graph.out_nbrs(node):
            store.append(node)
            store.append(nbr)

    return graph
Esempio n. 10
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def generate_random_graph(node_num, edge_num, self_loops=False, multi_edges=False):
    '''
    Generates and returns a :py:class:`~altgraph.Graph.Graph` instance with *node_num* nodes
    randomly connected by *edge_num* edges.
    '''
    g = Graph.Graph()

    if not multi_edges:
        if self_loops:
            max_edges = node_num * node_num
        else:
            max_edges = node_num * (node_num-1)

        if edge_num > max_edges:
            raise GraphError("inconsistent arguments to 'generate_random_graph'")

    nodes = range(node_num)

    for node in nodes:
        g.add_node(node)

    while 1:
        head = random.choice(nodes)
        tail = random.choice(nodes)

        # loop defense
        if head == tail and not self_loops:
            continue

        # multiple edge defense
        if g.edge_by_node(head,tail) is not None and not multi_edges:
            continue

        # add the edge
        g.add_edge(head, tail)
        if g.number_of_edges() >= edge_num:
            break

    return g
Esempio n. 11
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    def test_img(self):
        g = Graph.Graph([
                (1,2),
                (1,3),
                (1,4),
                (2,4),
                (2,6),
                (2,7),
                (7,4),
                (6,1),
            ]
        )

        dot = Dot.Dot(g, dot='/usr/local/bin/!!dot', dotty='/usr/local/bin/!!dotty', neato='/usr/local/bin/!!neato')
        dot.style(size='10,10', rankdir='RL', page='5, 5' , ranksep=0.75)
        dot.node_style(1, label='BASE_NODE',shape='box', color='blue')
        dot.node_style(2, style='filled', fillcolor='red')
        dot.edge_style(1,4, style='dotted')
        dot.edge_style(2,4, arrowhead='dot', label='binds', labelangle='90')

        system_cmds = []
        def fake_system(cmd):
            system_cmds.append(cmd)
            return None

        try:
            real_system = os.system
            os.system = fake_system

            system_cmds = []
            dot.save_img('foo')
            self.assertEqual(system_cmds, ['/usr/local/bin/!!dot -Tgif tmp_dot.dot -o foo.gif'])

            system_cmds = []
            dot.save_img('foo', file_type='jpg')
            self.assertEqual(system_cmds, ['/usr/local/bin/!!dot -Tjpg tmp_dot.dot -o foo.jpg'])

            system_cmds = []
            dot.save_img('bar', file_type='jpg', mode='neato')
            self.assertEqual(system_cmds, [
                '/usr/local/bin/!!neato -o tmp_dot.dot tmp_neo.dot',
                '/usr/local/bin/!!dot -Tjpg tmp_dot.dot -o bar.jpg',
            ])

            system_cmds = []
            dot.display()
            self.assertEqual(system_cmds, [
                '/usr/local/bin/!!dotty tmp_dot.dot'
            ])

            system_cmds = []
            dot.display(mode='neato')
            self.assertEqual(system_cmds, [
                '/usr/local/bin/!!neato -o tmp_dot.dot tmp_neo.dot',
                '/usr/local/bin/!!dotty tmp_dot.dot'
            ])

        finally:
            if os.path.exists(dot.temp_dot):
                os.unlink(dot.temp_dot)
            if os.path.exists(dot.temp_neo):
                os.unlink(dot.temp_neo)
            os.system = real_system

        if os.path.exists('/usr/local/bin/dot') and os.path.exists('/usr/local/bin/neato'):
            try:
                dot.dot='/usr/local/bin/dot'
                dot.neato='/usr/local/bin/neato'
                self.assertFalse(os.path.exists('foo.gif'))
                dot.save_img('foo')
                self.assertTrue(os.path.exists('foo.gif'))
                os.unlink('foo.gif')

                self.assertFalse(os.path.exists('foo.gif'))
                dot.save_img('foo', mode='neato')
                self.assertTrue(os.path.exists('foo.gif'))
                os.unlink('foo.gif')

            finally:
                if os.path.exists(dot.temp_dot):
                    os.unlink(dot.temp_dot)
                if os.path.exists(dot.temp_neo):
                    os.unlink(dot.temp_neo)
Esempio n. 12
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    def test_iter(self):
        g = Graph.Graph([
                (1,2),
                (1,3),
                (1,4),
                (2,4),
                (2,6),
                (2,7),
                (7,4),
                (6,1),
            ]
        )

        dot = Dot.Dot(g)
        dot.style(graph="foobar")
        dot.node_style(1, key='value')
        dot.node_style(2, key='another', key2='world')
        dot.edge_style(1,4, key1='value1', key2='value2')
        dot.edge_style(2,4, key1='valueA')

        self.assertEqual(list(iter(dot)), list(dot.iterdot()))

        for item in dot.iterdot():
            self.assertTrue(isinstance(item, str))

        first = list(dot.iterdot())[0]
        self.assertEqual(first, "digraph %s {\n"%(dot.name,))

        dot.type = 'graph'
        first = list(dot.iterdot())[0]
        self.assertEqual(first, "graph %s {\n"%(dot.name,))

        dot.type = 'foo'
        self.assertRaises(GraphError, list, dot.iterdot())
        dot.type = 'digraph'

        self.assertEqual(list(dot), [
            'digraph G {\n',
              'graph="foobar";',
              '\n',

            '\t"1" [',
              'key="value",',
            '];\n',

            '\t"2" [',
              'key="another",',
              'key2="world",',
            '];\n',

            '\t"3" [',
            '];\n',

            '\t"4" [',
            '];\n',

            '\t"6" [',
            '];\n',

            '\t"7" [',
            '];\n',

            '\t"1" -> "2" [',
            '];\n',

            '\t"1" -> "3" [',
            '];\n',

            '\t"1" -> "4" [',
              'key1="value1",',
              'key2="value2",',
            '];\n',

             '\t"2" -> "4" [',
               'key1="valueA",',
             '];\n',

             '\t"2" -> "6" [',
             '];\n',

             '\t"2" -> "7" [',
             '];\n',

             '\t"6" -> "1" [',
             '];\n',

             '\t"7" -> "4" [',
             '];\n',
           '}\n'])
Esempio n. 13
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    def test_constructor(self):
        g = Graph.Graph([
                (1,2),
                (1,3),
                (1,4),
                (2,4),
                (2,6),
                (2,7),
                (7,4),
                (6,1),
            ]
        )

        dot = Dot.Dot(g)

        self.assertEqual(dot.name, 'G')
        self.assertEqual(dot.attr, {})
        self.assertEqual(dot.temp_dot, 'tmp_dot.dot')
        self.assertEqual(dot.temp_neo, 'tmp_neo.dot')
        self.assertEqual(dot.dot, 'dot')
        self.assertEqual(dot.dotty, 'dotty')
        self.assertEqual(dot.neato, 'neato')
        self.assertEqual(dot.type, 'digraph')

        self.assertEqual(dot.nodes, dict([(x, {}) for x in g]))

        edges = {}
        for head in g:
            edges[head] = {}
            for tail in g.out_nbrs(head):
                edges[head][tail] = {}

        self.assertEqual(dot.edges[1], edges[1])
        self.assertEqual(dot.edges, edges)


        dot = Dot.Dot(g, nodes=[1,2],
                edgefn=lambda node: list(sorted(g.out_nbrs(node)))[:-1],
                nodevisitor=lambda node: {'label': node},
                edgevisitor=lambda head, tail: {'label': (head, tail) },
                name="testgraph",
                dot='/usr/local/bin/dot',
                dotty='/usr/local/bin/dotty',
                neato='/usr/local/bin/neato',
                graphtype="graph")

        self.assertEqual(dot.name, 'testgraph')
        self.assertEqual(dot.attr, {})
        self.assertEqual(dot.temp_dot, 'tmp_dot.dot')
        self.assertEqual(dot.temp_neo, 'tmp_neo.dot')
        self.assertEqual(dot.dot, '/usr/local/bin/dot')
        self.assertEqual(dot.dotty, '/usr/local/bin/dotty')
        self.assertEqual(dot.neato, '/usr/local/bin/neato')
        self.assertEqual(dot.type, 'graph')

        self.assertEqual(dot.nodes, dict([(x, {'label': x}) for x in [1,2]]))

        edges = {}
        for head in [1,2]:
            edges[head] = {}
            for tail in list(sorted(g.out_nbrs(head)))[:-1]:
                if tail not in [1,2]: continue
                edges[head][tail] = {'label': (head, tail) }

        self.assertEqual(dot.edges[1], edges[1])
        self.assertEqual(dot.edges, edges)

        self.assertRaises(GraphError, Dot.Dot, g, nodes=[1,2, 9])