Created
February 21, 2011 17:39
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Plot the network of the first 1000 #cn220 tweets with igraph and cairo.
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''' | |
@author Michael J Bommarito II | |
@contact [email protected] | |
@date Feb 21, 2011 | |
@license Simplified BSD, (C) 2011. | |
Plot the network of the first 1000 #cn220 tweets with igraph and cairo. | |
''' | |
import cairo | |
import codecs | |
import dateutil.parser | |
import igraph | |
import numpy | |
import re | |
def readTweets(fileName): | |
''' | |
Read in tweet data from the tab-delimited tweet format. | |
''' | |
rows = [[field.strip() for field in line.split("\t")] for line in codecs.open(fileName, 'r', 'utf-8')] | |
return [(int(row[0]), dateutil.parser.parse(row[1]), row[2], row[3]) for row in rows] | |
def getNetwork(tweets): | |
''' | |
Parse the list of tweets and find "edges" embedded in the tweets. | |
Edges are just mentions in the tweet text, e.g., @mjbommar. | |
Then process the network from the edges. | |
''' | |
reMention = re.compile('\@([\w]+)') | |
# Calculate the list of mentions | |
mentions = [] | |
for tweet in tweets: | |
mentions.extend([(tweet[1], tweet[2], name) for name in reMention.findall(tweet[3])]) | |
# Sort by date | |
mentions = sorted(mentions) | |
# Now convert the dates/mention to edges and weights | |
dates, nodeA, nodeB = zip(*mentions) | |
nodes = set(nodeA) | set(nodeB) | |
nodes = sorted(list(nodes)) | |
nodeMap = dict([(v,i) for i,v in enumerate(nodes)]) | |
edges = [(nodeMap[e[1]], nodeMap[e[2]]) for e in mentions] | |
edges, weights = map(list, zip(*[[e, edges.count(e)] for e in set(edges)])) | |
# Now create the graph | |
graph = igraph.Graph(edges) | |
graph.es['weight'] = weights | |
graph.vs['label'] = nodes | |
return graph | |
def project2D(layout, alpha, beta): | |
''' | |
This method will project a set of points in 3D to 2D based on the given | |
angles alpha and beta. | |
''' | |
# Calculate the rotation matrices based on the given angles. | |
c = numpy.matrix([[1, 0, 0], [0, numpy.cos(alpha), numpy.sin(alpha)], [0, -numpy.sin(alpha), numpy.cos(alpha)]]) | |
c = c * numpy.matrix([[numpy.cos(beta), 0, -numpy.sin(beta)], [0, 1, 0], [numpy.sin(beta), 0, numpy.cos(beta)]]) | |
b = numpy.matrix([[1, 0, 0], [0, 1, 0], [0, 0, 1]]) | |
# Hit the layout, rotate, and kill a dimension | |
layout = numpy.matrix(layout) | |
X = (b * (c * layout.transpose())).transpose() | |
return [[X[i,0],X[i,1],X[i,2]] for i in range(X.shape[0])] | |
def drawGraph3D(graph, layout, angle, fileName): | |
''' | |
Draw a graph in 3D with the given layout, angle, and filename. | |
''' | |
# Setup some vertex attributes and calculate the projection | |
graph.vs['degree'] = graph.degree() | |
vertexRadius = 0.1 * (0.9 * 0.9) / numpy.sqrt(graph.vcount()) | |
graph.vs['x3'], graph.vs['y3'], graph.vs['z3'] = zip(*layout) | |
layout2D = project2D(layout, angle[0], angle[1]) | |
graph.vs['x2'], graph.vs['y2'], graph.vs['z2'] = zip(*layout2D) | |
minX, maxX = min(graph.vs['x2']), max(graph.vs['x2']) | |
minY, maxY = min(graph.vs['y2']), max(graph.vs['y2']) | |
minZ, maxZ = min(graph.vs['z2']), max(graph.vs['z2']) | |
# Calculate the draw order. This is important if we want this to look | |
# realistically 3D. | |
zVal, zOrder = zip(*sorted(zip(graph.vs['z3'], range(graph.vcount())))) | |
# Setup the cairo surface | |
surf = cairo.ImageSurface(cairo.FORMAT_ARGB32, 1280, 800) | |
con = cairo.Context(surf) | |
con.scale(1280.0, 800.0) | |
# Draw the background | |
con.set_source_rgba(0.0, 0.0, 0.0, 1.0) | |
con.rectangle(0.0, 0.0, 1.0, 1.0) | |
con.fill() | |
# Draw the edges without respect to z-order but set their alpha along | |
# a linear gradient to represent depth. | |
for e in graph.get_edgelist(): | |
# Get the first vertex info | |
v0 = graph.vs[e[0]] | |
x0 = (v0['x2'] - minX) / (maxX - minX) | |
y0 = (v0['y2'] - minY) / (maxY - minY) | |
alpha0 = (v0['z2'] - minZ) / (maxZ - minZ) | |
alpha0 = max(0.1, alpha0) | |
# Get the second vertex info | |
v1 = graph.vs[e[1]] | |
x1 = (v1['x2'] - minX) / (maxX - minX) | |
y1 = (v1['y2'] - minY) / (maxY - minY) | |
alpha1 = (v1['z2'] - minZ) / (maxZ - minZ) | |
alpha1 = max(0.1, alpha1) | |
# Setup the pattern info | |
pat = cairo.LinearGradient(x0, y0, x1, y1) | |
pat.add_color_stop_rgba(0, 1, 1.0, 1.0, alpha0 / 6.0) | |
pat.add_color_stop_rgba(1, 1, 1.0, 1.0, alpha1 / 6.0) | |
con.set_source(pat) | |
# Draw the line | |
con.set_line_width(vertexRadius / 4.0) | |
con.move_to(x0, y0) | |
con.line_to(x1, y1) | |
con.stroke() | |
# Draw vertices in z-order | |
for i in zOrder: | |
v = graph.vs[i] | |
alpha = (v['z2'] - minZ) / (maxZ - minZ) | |
alpha = max(0.1, alpha) | |
radius = vertexRadius | |
x = (v['x2'] - minX) / (maxX - minX) | |
y = (v['y2'] - minY) / (maxY - minY) | |
# Setup the radial pattern for 3D lighting effect | |
pat = cairo.RadialGradient(x, y, radius / 4.0, x, y, radius) | |
pat.add_color_stop_rgba(0, alpha, 0, 0, 1) | |
pat.add_color_stop_rgba(1, 0, 0, 0, 1) | |
con.set_source(pat) | |
# Draw the vertex sphere | |
con.move_to(x, y) | |
con.arc(x, y, radius, 0, 2 * numpy.pi) | |
con.fill() | |
# Output the surface | |
surf.write_to_png(fileName) | |
if __name__ == "__main__": | |
# Load the tweets | |
tweets = readTweets("data/tweets_cn220.csv") | |
# Determine how many tweets we'll use to construct the network. | |
numTweets = 1000 | |
# Load the graph, isolate the giant component, and calculate the layout. | |
graph = getNetwork(tweets[0:numTweets]) | |
graph = graph.components(mode=igraph.WEAK).giant() | |
layout = graph.layout_kamada_kawai_3d() | |
# Now draw the frames while rotating. | |
for frame in range(400): | |
alpha = frame * numpy.pi / 200. | |
beta = frame * numpy.pi / 150. | |
print frame, alpha, beta | |
drawGraph3D(graph, layout, (alpha, beta), "frames/%08d.png" % (frame)) |
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Hi, i merged this code with a previous forked animation code, hope you dont get troubled by this. Many thanks again.