C Sharp Programming/K-Means++
using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Drawing;
using System.Security.Cryptography;
class KMeansPP
{
//Output object
public class PointClusters
{
private Dictionary<Point, List<Point>> _pc = new Dictionary<Point, List<Point>>();
public Dictionary<Point, List<Point>> PC
{
get { return _pc; } set { _pc = value; }
}
}
//Intermediate calculation object
public struct PointDetails
{
private Point _seedpoint;
private double[] _Weights;
private double _Sum;
private double _minD;
public Point SeedPoint
{
get { return _seedpoint; } set { _seedpoint = value; }
}
public double[] Weights
{
get { return _Weights; } set { _Weights = value; }
}
public double Sum
{
get { return _Sum; } set { _Sum = value; }
}
public double MinD
{
get { return _minD; } set { _minD = value; }
}
}
/// <summary>
/// Basic (non kd-tree) implementation of kmeans++ algorithm.
/// cf. http://en.wikipedia.org/wiki/K-means%2B%2B
/// Excellent for financial diversification cf.
/// Clustering Techniques for Financial Diversification, March 2009
/// cf http://www.cse.ohio-state.edu/~johansek/clustering.pdf
/// Zach Howard & Keith Johansen
/// Note1: If unsure what value of k to use, try: k ~ (n/2)^0.5
/// cf. http://en.wikipedia.org/wiki/Determining_the_number_of_clusters_in_a_data_set
/// </summary>
/// <param name="allPoints">All points in ensemble</param>
/// <param name="k">Number of clusters</param>
/// <returns></returns>
public PointClusters GetKMeansPP(List<Point> allPoints, int k)
{
//1. Preprocess KMeans (obtain optimized seed points)
List<Point> seedPoints = GetSeedPoints(allPoints, k);
//2. Regular KMeans algorithm
PointClusters resultado = GetKMeans(allPoints, seedPoints, k);
return resultado;
}
//Bog standard k-means.
private PointClusters GetKMeans(List<Point> allPoints, List<Point> seedPoints, int k)
{
PointClusters cluster = new PointClusters();
double[] Distances = new double[k];
double minD = double.MaxValue;
List<Point> sameDPoint = new List<Point>();
bool exit = true;
//Cycle thru all points in ensemble and assign to nearest centre
foreach (Point p in allPoints)
{
foreach (Point sPoint in seedPoints)
{
double dist = GetEuclideanD(p, sPoint);
if (dist < minD)
{
sameDPoint.Clear();
minD = dist;
sameDPoint.Add(sPoint);
}
if (dist == minD)
{
if (!sameDPoint.Contains(sPoint))
sameDPoint.Add(sPoint);
}
}
//Extract nearest central point.
Point keyPoint;
if (sameDPoint.Count > 1)
{
int index = GetRandNumCrypto(0, sameDPoint.Count);
keyPoint = sameDPoint[index];
}
else
keyPoint = sameDPoint[0];
//Assign ensemble point to correct central point cluster
if (!cluster.PC.ContainsKey(keyPoint)) //New
{
List<Point> newCluster = new List<Point>();
newCluster.Add(p);
cluster.PC.Add(keyPoint, newCluster);
}
else
{ //Existing cluster centre
cluster.PC[keyPoint].Add(p);
}
//Reset
sameDPoint.Clear();
minD = double.MaxValue;
}
//Bulletproof check - it it come out of the wash incorrect then re-seed.
if (cluster.PC.Count != k)
{
cluster.PC.Clear();
seedPoints = GetSeedPoints(allPoints, k);
}
List<Point> newSeeds = GetCentroid(cluster);
//Determine exit
foreach (Point newSeed in newSeeds)
{
if (!cluster.PC.ContainsKey(newSeed))
exit = false;
}
if (exit)
return cluster;
else
return GetKMeans(allPoints, newSeeds, k);
}
/// <summary>
/// Get the centroid of a set of points
/// cf. http://en.wikipedia.org/wiki/Centroid
/// Consider also: Metoid cf. http://en.wikipedia.org/wiki/Medoids
/// </summary>
/// <param name="pcs"></param>
/// <returns></returns>
private List<Point> GetCentroid(PointClusters pcs)
{
List<Point> newSeeds = new List<Point>(pcs.PC.Count);
Point newSeed;
int sumX = 0; int sumY = 0;
foreach (List<Point> cluster in pcs.PC.Values)
{
foreach (Point p in cluster)
{
sumX += p.X;
sumY += p.Y;
}
newSeed = new Point(sumX / cluster.Count, sumY / cluster.Count);
newSeeds.Add(newSeed);
sumX = sumY = 0;
}
return newSeeds;
}
private List<Point> GetSeedPoints(List<Point> allPoints, int k)
{
List<Point> seedPoints = new List<Point>(k);
PointDetails pd;
List<PointDetails> pds = new List<PointDetails>();
int index = 0;
//1. Choose 1 random point as first seed
int firstIndex = GetRandNorm(0, allPoints.Count);
Point FirstPoint = allPoints[firstIndex];
seedPoints.Add(FirstPoint);
for (int i = 0; i < k - 1; i++)
{
if (seedPoints.Count >= 2)
{
//Get point with min distance
PointDetails minpd = GetMinDPD(pds);
index = GetWeightedProbDist(minpd.Weights, minpd.Sum);
Point SubsequentPoint = allPoints[index];
seedPoints.Add(SubsequentPoint);
pd = new PointDetails();
pd = GetAllDetails(allPoints, SubsequentPoint, pd);
pds.Add(pd);
}
else
{
pd = new PointDetails();
pd = GetAllDetails(allPoints, FirstPoint, pd);
pds.Add(pd);
index = GetWeightedProbDist(pd.Weights, pd.Sum);
Point SecondPoint = allPoints[index];
seedPoints.Add(SecondPoint);
pd = new PointDetails();
pd = GetAllDetails(allPoints, SecondPoint, pd);
pds.Add(pd);
}
}
return seedPoints;
}
/// <summary>
/// Very simple weighted probability distribution. NB: No ranking involved.
/// Returns a random index proportional to to D(x)^2
/// </summary>
/// <param name="w">Weights</param>
/// <param name="s">Sum total of weights</param>
/// <returns>Index</returns>
private int GetWeightedProbDist(double[] w, double s)
{
double p = GetRandNumCrypto();
double q = 0d;
int i = -1;
while (q < p)
{
i++;
q += (w[i] / s);
}
return i;
}
//Gets a pseudo random number (of normal quality) in range: [0, 1)
private double GetRandNorm()
{
Random seed = new Random();
return seed.NextDouble();
}
//Gets a pseudo random number (of normal quality) in range: [min, max)
private int GetRandNorm(int min, int max)
{
Random seed = new Random();
return seed.Next(min, max);
}
//Pseudorandom number (of crypto strength) in range: [min,max)
private int GetRandNumCrypto(int min, int max)
{
byte[] salt = new byte[8];
RNGCryptoServiceProvider rng = new RNGCryptoServiceProvider();
rng.GetBytes(salt);
return (int)((double)BitConverter.ToUInt64(salt, 0) / UInt64.MaxValue * (max - min)) + min;
}
//Pseudorandom number (of crypto strength) in range: [0.0,1.0)
private double GetRandNumCrypto()
{
byte[] salt = new byte[8];
RNGCryptoServiceProvider rng = new RNGCryptoServiceProvider();
rng.GetBytes(salt);
return (double)BitConverter.ToUInt64(salt, 0) / UInt64.MaxValue;
}
//Gets the weight, sum, & min distance. Loop consolidation essentially.
private PointDetails GetAllDetails(List<Point> allPoints, Point seedPoint, PointDetails pd)
{
double[] Weights = new double[allPoints.Count];
double minD = double.MaxValue;
double Sum = 0d;
int i = 0;
foreach (Point p in allPoints)
{
if (p == seedPoint) //Delta is 0
continue;
Weights[i] = GetEuclideanD(p, seedPoint);
Sum += Weights[i];
if (Weights[i] < minD)
minD = Weights[i];
i++;
}
pd.SeedPoint = seedPoint;
pd.Weights = Weights;
pd.Sum = Sum;
pd.MinD = minD;
return pd;
}
/// <summary>
/// Simple Euclidean distance
/// cf. http://en.wikipedia.org/wiki/Euclidean_distance
/// Consider also: Manhattan, Chebyshev & Minkowski distances
/// </summary>
/// <param name="P1"></param>
/// <param name="P2"></param>
/// <returns></returns>
private double GetEuclideanD(Point P1, Point P2)
{
double dx = (P1.X - P2.X);
double dy = (P1.Y - P2.Y);
return ((dx * dx) + (dy * dy));
}
//Gets min distance from set of PointDistance objects. If similar then chooses random item.
private PointDetails GetMinDPD(List<PointDetails> pds)
{
double minValue = double.MaxValue;
List<PointDetails> sameDistValues = new List<PointDetails>();
foreach (PointDetails pd in pds)
{
if (pd.MinD < minValue)
{
sameDistValues.Clear();
minValue = pd.MinD;
sameDistValues.Add(pd);
}
if (pd.MinD == minValue)
{
if (!sameDistValues.Contains(pd))
sameDistValues.Add(pd);
}
}
if (sameDistValues.Count > 1)
return sameDistValues[GetRandNumCrypto(0, sameDistValues.Count)];
else
return sameDistValues[0];
}
}