grignaak/Ability.java

## Ability.java
package gaming.online.java;

public class Ability {
    private final double mean;
    private final double variance;

    private Ability(final double mean, final double variance) {
        this.mean = mean;
        this.variance = variance;
    }

    public static Ability zero() {
        return withStddev(0, 0);
    }

    /**
     * A numerical representation of the ability, representing 95% confidence that the actual
     * ability is above the returned number
     */
    public double skill() {
        return mean - 3 * stddev();
    }

    public Ability plus(final Ability other) {
        return withVariance(
                mean + other.mean,
                variance + other.variance);
    }

    public double stddev() {
        return Math.sqrt(variance);
    }

    public static Ability withVariance(final double mean, final double variance) {
        return new Ability(mean, variance);
    }

    public static Ability withStddev(final double mean, final double stddev) {
        return new Ability(mean, stddev * stddev);
    }

    public double variance() {
        return variance;
    }

    public double mean() {
        return mean;
    }
}

## BradleyTerryFullUpdater.java
package gaming.online.java;

import java.util.ArrayList;
import java.util.Collections;
import java.util.Comparator;
import java.util.List;
import java.util.ListIterator;

public class BradleyTerryFullUpdater {
    private final double betaSquared; {
        final double init_mu = 25;
        final double init_sigma = init_mu / 3;
        final double beta = init_sigma * 0.5;
        betaSquared = beta * beta;
    }

    private final Comparator<Team> byScoreAndAbility = ByScoreAndSkillComparator.forCalculation();
    private final double rankAllowance;

    public BradleyTerryFullUpdater(final int rankAllowance) {
        this.rankAllowance = rankAllowance;
    }


    public List<Player> updatePlayerRankings(final List<Team> teams_) {
        final List<Team> teams = sortedByScoreAndAbility(teams_);
        calculateRanks(teams);
        final double gamma = 1.0 / teams.size();

        final List<Player> updatedPlayers = new ArrayList<Player>();
        for (final Team team : teams) {
            double Omega = 0;
            double Delta = 0;
            final Ability teamAbility = team.ability();

            for (final Team opponent : teams) {
                if (opponent == team) continue;
                final Ability opAbility = opponent.ability();

                final double c = Math.sqrt(teamAbility.variance() + opAbility.variance() + 2 * betaSquared);
                final double p = 1 / (1 + Math.exp((opAbility.mean() - teamAbility.mean()) / c));
                final double varianceToC = teamAbility.variance() / c;

                final double s = s(team, opponent);

                Omega += varianceToC * (s - p);
                Delta += gamma * varianceToC / c * p * (1 - p);
            }

            updatedPlayers.addAll(resultingAbilities(team, Delta, Omega));
        }

        return updatedPlayers;
    }


    public List<Player> resultingAbilities(final Team players, final double Delta, final double Omega) {
        final List<Player> resultingAbilities = new ArrayList<Player>();
        final Ability teamAbility = players.ability();
        for (final Player player : players) {
            final Ability ability = player.priorAbility();
            final double mean = ability.mean() + ability.variance() / teamAbility.variance() * Omega;
            final double stddev = ability.stddev() *
                    Math.sqrt(Math.max(1 - ability.variance() / teamAbility.variance() * Delta, 0.0001));
            resultingAbilities.add(new Player(player.id(), Ability.withStddev(mean, stddev)));
        }
        return resultingAbilities;
    }

    private List<Team> sortedByScoreAndAbility(final List<Team> unsorted) {
        final List<Team> teams = new ArrayList<Team>(unsorted);
        Collections.sort(teams, byScoreAndAbility);
        return teams;
    }

    private void calculateRanks(final List<Team> teams) {
        final ListIterator<Team> iter = teams.listIterator();
        while (iter.hasNext()) {
            final Team topOfRank = iter.next();
            final int currentRank = iter.previousIndex();
            topOfRank.setRank(currentRank);
            while (iter.hasNext()) {
                final Team team = iter.next();
                if (!isSameRank(topOfRank, team))
                    break;
                team.setRank(currentRank);
            }
        }
    }

    private double s(final Team team_i, final Team team_q) {
        final int cmp = Double.compare(team_q.rank(), team_i.rank());

        if (cmp > 0)
            return 1;
        else if (cmp == 0)
            return 0.5;
        else
            return 0.0;
    }

    private boolean isSameRank(final Team topOfRank, final Team team) {
        return topOfRank.score() - rankAllowance <= team.score();
    }
}

## ByScoreAndSkillComparator.java
package gaming.online.java;

import java.util.Comparator;

/**
 * Comparators which sorts a team by score and ability.
 * <p>
 * These comparators will produce the same sorted results no matter the initial
 * order of the teams. This is important when using a partial-pair updater
 * instead of a full-pair updater.
 * </p>
 */
public final class ByScoreAndSkillComparator {
    private ByScoreAndSkillComparator() {}

    /**
     * A comparator which gives preference to teams with
     * <ol>
     * <li>Higher score;</li>
     * <li>More players;</li>
     * <li>Higher skill;</li>
     * <li>Lower id</li>
     * </ol>
     *
     * <p>
     * <b>Rationale for tie-breakers</b> A partial-pair updater only updates
     * players' abilities based on how it compared to the surrounding teams by
     * rank. When two teams tie, one team will be compared with a better team
     * while the other is compared with a worse team, in terms of score. In
     * other words, of these two teams the team this comparator puts first will
     * get attributed a loss while the other team is attributed a win. (Both
     * teams will also be attributed a draw.)
     * </p>
     * <p>
     * The team with less players and equal score likely had better individual
     * ability, and are accordingly attributed the "win."
     * </p>
     * <p>
     * Accounting for number of players, it is assumed a team with higher skill
     * should have beaten a team with lower skill. Thus, this comparator
     * positions the underdog to gain the win.
     * </p>
     * <p>
     * <b>Note:</b> The tie-breaking doesn't matter when using a full-pair
     * updater because a team is always compared to every other team.
     * </p>
     */
    public static Comparator<Team> forCalculation() {
        return new Comparator<Team>() {
            @Override
            public int compare(Team a, Team b) {
                final int scoreCmp = -Double.compare(a.score(), b.score());
                if (scoreCmp != 0)
                    return scoreCmp;

                final int countCmp = -Double.compare(a.size(), b.size());
                if (countCmp != 0)
                    return countCmp;

                final int abilityCmp = -Double.compare(a.skill(), b.skill());
                if (abilityCmp != 0)
                    return abilityCmp;

                return Double.compare(a.id(), b.id());
            }
        };
    }

    /**
     * A comparator which gives preference to teams with
     * <ol>
     * <li>Higher score;</li>
     * <li>Less players;</li>
     * <li>Lower skill;</li>
     * <li>Higher id</li>
     * </ol>
     *
     * See the documentation of {@link #forCalculation()} for rationale of the
     * tie-breakers which are flipped in this method to provide better user
     * experience.
     */
    public static Comparator<Team> forDisplay() {
        return new Comparator<Team>() {
            @Override
            public int compare(Team a, Team b) {
                final int scoreCmp = -Double.compare(a.score(), b.score());
                if (scoreCmp != 0)
                    return scoreCmp;

                final int countCmp = Double.compare(a.size(), b.size());
                if (countCmp != 0)
                    return countCmp;

                final int abilityCmp = Double.compare(a.skill(), b.skill());
                if (abilityCmp != 0)
                    return abilityCmp;

                return -Double.compare(a.id(), b.id());
            }
        };
    }
}

## Go.java
package gaming.online.java;

import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.Comparator;
import java.util.List;

public class Go {
    public static void main(final String[] args) {
        final Team team1 = new Team(1, 500,
                Arrays.asList(new Player(1, Ability.withStddev(25, 8)),
                        new Player(2, Ability.withStddev(27, 5)),
                        new Player(3, Ability.withStddev(22, 3))));

        final Team team2 = new Team(2, 400,
                Arrays.asList(new Player(4, Ability.withStddev(25, 8)),
                        new Player(5, Ability.withStddev(27, 5)),
                        new Player(6, Ability.withStddev(22, 3))));

        final Team team3 = new Team(3, 395,
                Arrays.asList(new Player(7, Ability.withStddev(25, 8)),
                        new Player(8, Ability.withStddev(27, 5)),
                        new Player(9, Ability.withStddev(22, 3))));

        final List<Team> teams = Arrays.asList(team1, team2, team3);
        Collections.shuffle(teams);

        System.out.println("Game outcome:");
        System.out.println(split(sort(teams, ByScoreAndSkillComparator.forDisplay())));

        final List<Player> updatedPlayers = new BradleyTerryFullUpdater(10).updatePlayerRankings(teams);

        System.out.println();
        System.out.println("Updated abilities:");
        System.out.println(split(sort(updatedPlayers, byId())));
    }

    private static Comparator<Player> byId() {
        return new Comparator<Player>() {
            public int compare(Player a, Player b) {
                return Double.compare(a.id(), b.id());
            }
        };
    }

    private static <T> String split(final List<T> list) {
        final StringBuilder builder = new StringBuilder();
        for (final T item : list) {
            builder.append(item).append("\n");
        }
        builder.setLength(builder.length() - 1);
        return builder.toString();
    }

    private static <T> List<T> sort(final List<T> list, final Comparator<? super T> cmp) {
        final ArrayList<T> sorted = new ArrayList<T>(list);
        Collections.sort(sorted, cmp);
        return sorted;
    }

}

## Player.java
package gaming.online.java;

public final class Player {
    private final long id;
    private final Ability priorAbility;

    public Player(final long id, final Ability ability) {
        this.id = id;
        this.priorAbility = ability;
    }

    public long id() {
        return id;
    }

    public Ability priorAbility() {
        return priorAbility;
    }
}

## Team.java
package gaming.online.java;

import java.util.Iterator;
import java.util.List;

public final class Team implements Iterable<Player> {
    private final long id;
    private final double score;
    private final List<Player> players;
    private final Ability ability;
    private int rank = -1;

    public Team(final long id, final double score, final List<Player> players) {
        this.id = id;
        this.score = score;
        this.players = players;

        this.ability = calculateAbility(players);
    }

    private static Ability calculateAbility(final List<Player> players) {
        Ability aggregate = Ability.zero();
        for (final Player player : players) {
            aggregate = aggregate.plus(player.priorAbility());
        }
        return aggregate;
    }

    public double score() {
        return score;
    }

    public int rank() {
        if (rank < 0)
            throw new IllegalArgumentException("Rank not calculated yet");
        return rank;
    }

    public void setRank(final int rank) {
        this.rank = rank;
    }

    public double skill() {
        return ability.skill();
    }

    public Ability ability() {
        return ability;
    }

    public long id() {
        return id;
    }

    public int size() {
        return players.size();
    }

    @Override
    public String toString() {
        return Long.toString(id);
    }

    @Override
    public Iterator<Player> iterator() {
        return players.iterator();
    }
}
	package gaming.online.java;

	public class Ability {
	private final double mean;
	private final double variance;

	private Ability(final double mean, final double variance) {
	this.mean = mean;
	this.variance = variance;
	}

	public static Ability zero() {
	return withStddev(0, 0);
	}

	/**
	* A numerical representation of the ability, representing 95% confidence that the actual
	* ability is above the returned number
	*/
	public double skill() {
	return mean - 3 * stddev();
	}

	public Ability plus(final Ability other) {
	return withVariance(
	mean + other.mean,
	variance + other.variance);
	}

	public double stddev() {
	return Math.sqrt(variance);
	}

	public static Ability withVariance(final double mean, final double variance) {
	return new Ability(mean, variance);
	}

	public static Ability withStddev(final double mean, final double stddev) {
	return new Ability(mean, stddev * stddev);
	}

	public double variance() {
	return variance;
	}

	public double mean() {
	return mean;
	}
	}
	package gaming.online.java;

	import java.util.ArrayList;
	import java.util.Collections;
	import java.util.Comparator;
	import java.util.List;
	import java.util.ListIterator;

	public class BradleyTerryFullUpdater {
	private final double betaSquared; {
	final double init_mu = 25;
	final double init_sigma = init_mu / 3;
	final double beta = init_sigma * 0.5;
	betaSquared = beta * beta;
	}

	private final Comparator<Team> byScoreAndAbility = ByScoreAndSkillComparator.forCalculation();
	private final double rankAllowance;

	public BradleyTerryFullUpdater(final int rankAllowance) {
	this.rankAllowance = rankAllowance;
	}


	public List<Player> updatePlayerRankings(final List<Team> teams_) {
	final List<Team> teams = sortedByScoreAndAbility(teams_);
	calculateRanks(teams);
	final double gamma = 1.0 / teams.size();

	final List<Player> updatedPlayers = new ArrayList<Player>();
	for (final Team team : teams) {
	double Omega = 0;
	double Delta = 0;
	final Ability teamAbility = team.ability();

	for (final Team opponent : teams) {
	if (opponent == team) continue;
	final Ability opAbility = opponent.ability();

	final double c = Math.sqrt(teamAbility.variance() + opAbility.variance() + 2 * betaSquared);
	final double p = 1 / (1 + Math.exp((opAbility.mean() - teamAbility.mean()) / c));
	final double varianceToC = teamAbility.variance() / c;

	final double s = s(team, opponent);

	Omega += varianceToC * (s - p);
	Delta += gamma * varianceToC / c * p * (1 - p);
	}

	updatedPlayers.addAll(resultingAbilities(team, Delta, Omega));
	}

	return updatedPlayers;
	}


	public List<Player> resultingAbilities(final Team players, final double Delta, final double Omega) {
	final List<Player> resultingAbilities = new ArrayList<Player>();
	final Ability teamAbility = players.ability();
	for (final Player player : players) {
	final Ability ability = player.priorAbility();
	final double mean = ability.mean() + ability.variance() / teamAbility.variance() * Omega;
	final double stddev = ability.stddev() *
	Math.sqrt(Math.max(1 - ability.variance() / teamAbility.variance() * Delta, 0.0001));
	resultingAbilities.add(new Player(player.id(), Ability.withStddev(mean, stddev)));
	}
	return resultingAbilities;
	}

	private List<Team> sortedByScoreAndAbility(final List<Team> unsorted) {
	final List<Team> teams = new ArrayList<Team>(unsorted);
	Collections.sort(teams, byScoreAndAbility);
	return teams;
	}

	private void calculateRanks(final List<Team> teams) {
	final ListIterator<Team> iter = teams.listIterator();
	while (iter.hasNext()) {
	final Team topOfRank = iter.next();
	final int currentRank = iter.previousIndex();
	topOfRank.setRank(currentRank);
	while (iter.hasNext()) {
	final Team team = iter.next();
	if (!isSameRank(topOfRank, team))
	break;
	team.setRank(currentRank);
	}
	}
	}

	private double s(final Team team_i, final Team team_q) {
	final int cmp = Double.compare(team_q.rank(), team_i.rank());

	if (cmp > 0)
	return 1;
	else if (cmp == 0)
	return 0.5;
	else
	return 0.0;
	}

	private boolean isSameRank(final Team topOfRank, final Team team) {
	return topOfRank.score() - rankAllowance <= team.score();
	}
	}
	package gaming.online.java;

	import java.util.Comparator;

	/**
	* Comparators which sorts a team by score and ability.
	* <p>
	* These comparators will produce the same sorted results no matter the initial
	* order of the teams. This is important when using a partial-pair updater
	* instead of a full-pair updater.
	* </p>
	*/
	public final class ByScoreAndSkillComparator {
	private ByScoreAndSkillComparator() {}

	/**
	* A comparator which gives preference to teams with
	* <ol>
	* <li>Higher score;</li>
	* <li>More players;</li>
	* <li>Higher skill;</li>
	* <li>Lower id</li>
	* </ol>
	*
	* <p>
	* <b>Rationale for tie-breakers</b> A partial-pair updater only updates
	* players' abilities based on how it compared to the surrounding teams by
	* rank. When two teams tie, one team will be compared with a better team
	* while the other is compared with a worse team, in terms of score. In
	* other words, of these two teams the team this comparator puts first will
	* get attributed a loss while the other team is attributed a win. (Both
	* teams will also be attributed a draw.)
	* </p>
	* <p>
	* The team with less players and equal score likely had better individual
	* ability, and are accordingly attributed the "win."
	* </p>
	* <p>
	* Accounting for number of players, it is assumed a team with higher skill
	* should have beaten a team with lower skill. Thus, this comparator
	* positions the underdog to gain the win.
	* </p>
	* <p>
	* <b>Note:</b> The tie-breaking doesn't matter when using a full-pair
	* updater because a team is always compared to every other team.
	* </p>
	*/
	public static Comparator<Team> forCalculation() {
	return new Comparator<Team>() {
	@Override
	public int compare(Team a, Team b) {
	final int scoreCmp = -Double.compare(a.score(), b.score());
	if (scoreCmp != 0)
	return scoreCmp;

	final int countCmp = -Double.compare(a.size(), b.size());
	if (countCmp != 0)
	return countCmp;

	final int abilityCmp = -Double.compare(a.skill(), b.skill());
	if (abilityCmp != 0)
	return abilityCmp;

	return Double.compare(a.id(), b.id());
	}
	};
	}

	/**
	* A comparator which gives preference to teams with
	* <ol>
	* <li>Higher score;</li>
	* <li>Less players;</li>
	* <li>Lower skill;</li>
	* <li>Higher id</li>
	* </ol>
	*
	* See the documentation of {@link #forCalculation()} for rationale of the
	* tie-breakers which are flipped in this method to provide better user
	* experience.
	*/
	public static Comparator<Team> forDisplay() {
	return new Comparator<Team>() {
	@Override
	public int compare(Team a, Team b) {
	final int scoreCmp = -Double.compare(a.score(), b.score());
	if (scoreCmp != 0)
	return scoreCmp;

	final int countCmp = Double.compare(a.size(), b.size());
	if (countCmp != 0)
	return countCmp;

	final int abilityCmp = Double.compare(a.skill(), b.skill());
	if (abilityCmp != 0)
	return abilityCmp;

	return -Double.compare(a.id(), b.id());
	}
	};
	}
	}
	package gaming.online.java;

	import java.util.ArrayList;
	import java.util.Arrays;
	import java.util.Collections;
	import java.util.Comparator;
	import java.util.List;

	public class Go {
	public static void main(final String[] args) {
	final Team team1 = new Team(1, 500,
	Arrays.asList(new Player(1, Ability.withStddev(25, 8)),
	new Player(2, Ability.withStddev(27, 5)),
	new Player(3, Ability.withStddev(22, 3))));

	final Team team2 = new Team(2, 400,
	Arrays.asList(new Player(4, Ability.withStddev(25, 8)),
	new Player(5, Ability.withStddev(27, 5)),
	new Player(6, Ability.withStddev(22, 3))));

	final Team team3 = new Team(3, 395,
	Arrays.asList(new Player(7, Ability.withStddev(25, 8)),
	new Player(8, Ability.withStddev(27, 5)),
	new Player(9, Ability.withStddev(22, 3))));

	final List<Team> teams = Arrays.asList(team1, team2, team3);
	Collections.shuffle(teams);

	System.out.println("Game outcome:");
	System.out.println(split(sort(teams, ByScoreAndSkillComparator.forDisplay())));

	final List<Player> updatedPlayers = new BradleyTerryFullUpdater(10).updatePlayerRankings(teams);

	System.out.println();
	System.out.println("Updated abilities:");
	System.out.println(split(sort(updatedPlayers, byId())));
	}

	private static Comparator<Player> byId() {
	return new Comparator<Player>() {
	public int compare(Player a, Player b) {
	return Double.compare(a.id(), b.id());
	}
	};
	}

	private static <T> String split(final List<T> list) {
	final StringBuilder builder = new StringBuilder();
	for (final T item : list) {
	builder.append(item).append("\n");
	}
	builder.setLength(builder.length() - 1);
	return builder.toString();
	}

	private static <T> List<T> sort(final List<T> list, final Comparator<? super T> cmp) {
	final ArrayList<T> sorted = new ArrayList<T>(list);
	Collections.sort(sorted, cmp);
	return sorted;
	}

	}
	package gaming.online.java;

	public final class Player {
	private final long id;
	private final Ability priorAbility;

	public Player(final long id, final Ability ability) {
	this.id = id;
	this.priorAbility = ability;
	}

	public long id() {
	return id;
	}

	public Ability priorAbility() {
	return priorAbility;
	}
	}
	package gaming.online.java;

	import java.util.Iterator;
	import java.util.List;

	public final class Team implements Iterable<Player> {
	private final long id;
	private final double score;
	private final List<Player> players;
	private final Ability ability;
	private int rank = -1;

	public Team(final long id, final double score, final List<Player> players) {
	this.id = id;
	this.score = score;
	this.players = players;

	this.ability = calculateAbility(players);
	}

	private static Ability calculateAbility(final List<Player> players) {
	Ability aggregate = Ability.zero();
	for (final Player player : players) {
	aggregate = aggregate.plus(player.priorAbility());
	}
	return aggregate;
	}

	public double score() {
	return score;
	}

	public int rank() {
	if (rank < 0)
	throw new IllegalArgumentException("Rank not calculated yet");
	return rank;
	}

	public void setRank(final int rank) {
	this.rank = rank;
	}

	public double skill() {
	return ability.skill();
	}

	public Ability ability() {
	return ability;
	}

	public long id() {
	return id;
	}

	public int size() {
	return players.size();
	}

	@Override
	public String toString() {
	return Long.toString(id);
	}

	@Override
	public Iterator<Player> iterator() {
	return players.iterator();
	}
	}