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1 # -*- coding: utf-8 -*-
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2 """Chapter 5.5, exercise 6 in Allen Downey's Think Complexity book.
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3
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4 1. Read Barabási and Albert’s paper and implement their algorithm for generating
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5 graphs. See if you can replicate their Figure 2(A), which shows P(k) versus
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6 k for a graph with 150 000 vertices.
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7
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8 """
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9 import random
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10 import sys
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11
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12 from matplotlib import pyplot
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13
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14 from Graph import Graph, Vertex, Edge
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15
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16
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17 class BAGraph(Graph):
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18 """BAGraph implements the algorithm described in the Barabási and
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19 Albert paper "Emergence of Scaling in Random Networks" from Science
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20 Magazine Vol. 286, 15 October 1999.
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21
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22 """
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23 def __init__(self, m0, m):
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24 """Create a graph with m0 vertices and m connecting edges.
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25
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26 """
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27 self.m0 = m0
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28 self.m = m
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29 self.histogram = []
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30
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31 initial_vertices = [Vertex() for i in xrange(m0)]
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32
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33 super(BAGraph, self).__init__(vs=initial_vertices)
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34
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35 # Add initial edges between nodes randomly
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36 n = 0
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37 while n != m:
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38 # pick two vertices at random
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39 v = random.choice(initial_vertices)
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40 w = random.choice(initial_vertices)
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41
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42 # if they aren't the same and don't already have an edge, add one
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43 if v is not w and not self.get_edge(v, w):
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44 self.add_edge(Edge(v, w))
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45 n += 1
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46
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47 def add_edge(self, edge):
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48 """Our version of add_edge() adds the two vertices on either end of the
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49 edge to a histogram. This allows us to more easily pick popular vertices
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50 when adding edges as part of the step() method.
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51
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52 """
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53 super(BAGraph, self).add_edge(edge) # invoke base class version
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54
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55 v, w = edge
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56 self.histogram.append(v)
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57 self.histogram.append(w)
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58
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59 def step(self):
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60 """This method adds a new vertex to the graph, then adds m edges that
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61 link the new vertex to m different vertices already present in the
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62 graph. Preferential treatment is given towards vertices that already
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63 have high connectivity.
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64
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65 The paper describes this preferential choosing as creating a probability
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66 P that a new vertex will be connected to vertex i depends on the
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67 connectivity ki of that vertex, so that P(ki) = ki / sum(kj).
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68
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69 We implement that by keeping a list of vertices (histogram), where we
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70 insert a vertex into this list whenever it gets an edge added to it. We
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71 then randomly choose a vertex from this list. Thus the vertices with
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72 more edges will be more likely chosen.
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73
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74 """
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75 # pick m unique vertices to attach to the new vertex
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76 vs = set()
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77 while len(vs) < self.m:
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78 w = random.choice(self.histogram)
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79 if w not in vs:
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80 vs.add(w)
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81
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82 # Add the new vertex to the graph and create edges
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83 v = Vertex()
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84 self.add_vertex(v)
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85 for w in vs:
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86 self.add_edge(Edge(v, w))
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87
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88
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89 def main(script, m0, m, n):
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90
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91 # create a BAGraph with parameters m0 & m:
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92 m0, m, n = int(m0), int(m), int(n)
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93 g = BAGraph(m0, m)
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94
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95 # step the graph n times:
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96 for i in xrange(n):
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97 g.step()
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98
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99 # retrieve probabilities
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100 p = g.get_p()
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101
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102 # plot P(k) versus k on a log-log scale
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103
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104 vals = p.items()
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105 vals.sort(key=lambda t: t[0])
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106 x, y = zip(*vals)
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107
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108 assert abs(sum(y) - 1.0) < 1e-6
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109
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110 pyplot.clf()
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111 pyplot.xscale('log')
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112 pyplot.yscale('log')
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113 pyplot.title('P(k) versus k')
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114 pyplot.xlabel('k')
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115 pyplot.ylabel('P(k)')
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116 pyplot.plot(x, y, label='P(k) vs. k', color='green', linewidth=3)
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117 pyplot.legend(loc='upper right')
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118 pyplot.show()
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119
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120
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121 if __name__ == '__main__':
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122 main(*sys.argv)
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