griesmey/kmeans.py

## kmeans.py
from math import sqrt
import sys
from collections import defaultdict
from itertools import izip


class Point(object):
    def __init__(self, x, y, id=None):
        self.x = x
        self.y = y
        self.id = id

class KMeans(object):
    def __init__(self, centroids, points):
        self.centroids = centroids
        self.points = points
        self.assigned = defaultdict(list)
        self.delta = 0.0001

    def distance(self, p1, p2):
        dist = (p2.x - p1.x)**2 + (p2.y - p1.y)**2
        if dist < 0:
            return 0
        return sqrt(dist)

    def clear_assignments(self):
        self.assigned.clear()

    def assign_centroids(self):
        for point in self.points:
            closest_dist = sys.maxsize
            closest_cent = self.centroids[0]

            for centroid in self.centroids:
                cur_dist = self.distance(point, centroid)
                if cur_dist < closest_dist:
                    closest_dist = cur_dist
                    closest_cent = centroid
            self.assigned[closest_cent].append(point)
        for centroid in self.centroids:
            if centroid not in self.assigned:
                self.assigned[centroid] = []

    def avg_points(self, points):
        x_avg = 0
        y_avg = 0
        length = len(points)
        for point in points:
            x_avg += point.x
            y_avg += point.y
        return Point(x_avg / float(length), y_avg / float(length)

    def assign_new_centroids(self):
        for centroid, points in self.assigned.iteritems():
            if not points:
                avg = None
            else:
                avg = self.avg_points(points)
                the_delta = self.distance(avg, centroid)
                if the_delta < self.delta:
                    return True
                centroid.x = avg.x
                centroid.y = avg.y
        return False

    def run(self):
        while(True):
            self.assign_centroids()
            if(self.assign_new_centroids()):
                return
            self.clear_assignments()

    def plot_graph(self):
        from matplotlib import pyplot as plt
        colors = ['go', 'bo', 'yo']
        for color, (centroid, points) in izip(colors, self.assigned.iteritems()):
            x_axis = []
            y_axis = []
            for p in points:
                x_axis.append(p.x)
                y_axis.append(p.y)
            plt.plot(x_axis, y_axis, color)
            plt.plot([centroid.x], [centroid.y], 'ro')
        plt.show()

if __name__ == '__main__':
    import random

    points = []
    centroids = []

    MAXX = 100
    MAXY = 100
    for i in xrange(100):
        x = random.randint(0, MAXX)
        y = random.randint(0, MAXY)
        points.append(Point(x, y, i))
    for k in xrange(100, 103):
        new_p = Point(random.randint(0, 0), random.randint(0, 0), k)
        centroids.append(new_p)

    km = KMeans(centroids, points)
    km.run()
    km.plot_graph()
	from math import sqrt
	import sys
	from collections import defaultdict
	from itertools import izip


	class Point(object):
	def __init__(self, x, y, id=None):
	self.x = x
	self.y = y
	self.id = id

	class KMeans(object):
	def __init__(self, centroids, points):
	self.centroids = centroids
	self.points = points
	self.assigned = defaultdict(list)
	self.delta = 0.0001

	def distance(self, p1, p2):
	dist = (p2.x - p1.x)2 + (p2.y - p1.y)2
	if dist < 0:
	return 0
	return sqrt(dist)

	def clear_assignments(self):
	self.assigned.clear()

	def assign_centroids(self):
	for point in self.points:
	closest_dist = sys.maxsize
	closest_cent = self.centroids[0]

	for centroid in self.centroids:
	cur_dist = self.distance(point, centroid)
	if cur_dist < closest_dist:
	closest_dist = cur_dist
	closest_cent = centroid
	self.assigned[closest_cent].append(point)
	for centroid in self.centroids:
	if centroid not in self.assigned:
	self.assigned[centroid] = []

	def avg_points(self, points):
	x_avg = 0
	y_avg = 0
	length = len(points)
	for point in points:
	x_avg += point.x
	y_avg += point.y
	return Point(x_avg / float(length), y_avg / float(length)

	def assign_new_centroids(self):
	for centroid, points in self.assigned.iteritems():
	if not points:
	avg = None
	else:
	avg = self.avg_points(points)
	the_delta = self.distance(avg, centroid)
	if the_delta < self.delta:
	return True
	centroid.x = avg.x
	centroid.y = avg.y
	return False

	def run(self):
	while(True):
	self.assign_centroids()
	if(self.assign_new_centroids()):
	return
	self.clear_assignments()

	def plot_graph(self):
	from matplotlib import pyplot as plt
	colors = ['go', 'bo', 'yo']
	for color, (centroid, points) in izip(colors, self.assigned.iteritems()):
	x_axis = []
	y_axis = []
	for p in points:
	x_axis.append(p.x)
	y_axis.append(p.y)
	plt.plot(x_axis, y_axis, color)
	plt.plot([centroid.x], [centroid.y], 'ro')
	plt.show()

	if __name__ == '__main__':
	import random

	points = []
	centroids = []

	MAXX = 100
	MAXY = 100
	for i in xrange(100):
	x = random.randint(0, MAXX)
	y = random.randint(0, MAXY)
	points.append(Point(x, y, i))
	for k in xrange(100, 103):
	new_p = Point(random.randint(0, 0), random.randint(0, 0), k)
	centroids.append(new_p)

	km = KMeans(centroids, points)
	km.run()
	km.plot_graph()