Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have been searching everywhere, including the Stack Overflow archives, for an answer of how to do this, I tried rolling my own, but have come up short, so I decided I would post my request here.

I need to take an arbitrary (even) number of items in an array and return with item paired with another item in the array. I need the output of the code to be the same as the output example I have included below.




[[['A','H'], ['B','G'], ['C','F'], ['D','E']],
 [['A','G'], ['B','F'], ['C','E'], ['D','H']],
 [['A','F'], ['B','E'], ['C','D'], ['G','H']],
 [['A','E'], ['B','D'], ['C','H'], ['F','G']],
 [['A','D'], ['B','C'], ['E','G'], ['F','H']],
 [['A','C'], ['B','H'], ['D','G'], ['E','F']],
 [['A','B'], ['C','G'], ['D','F'], ['E','H']]]

Any ideas?

Here's what I have done so far. It's a bit dirty, and it's not returning in the order I need.

items = ('A'..'H').to_a
combinations = []

1.upto(7) do |index|
  curitems = items.dup
  combination = []
  1.upto(items.size / 2) do |i|
    team1 = curitems.delete_at(0)
    team2 = curitems.delete_at(curitems.size - index) || curitems.delete_at(curitems.size - 1)
    combination << [team1, team2]
  combinations << combination

pp combinations

The output is close, but not in the right order:

[[["A", "H"], ["B", "G"], ["C", "F"], ["D", "E"]],
 [["A", "G"], ["B", "F"], ["C", "E"], ["D", "H"]],
 [["A", "F"], ["B", "E"], ["C", "D"], ["G", "H"]],
 [["A", "E"], ["B", "D"], ["C", "H"], ["F", "G"]],
 [["A", "D"], ["B", "C"], ["E", "G"], ["F", "H"]],
 [["A", "C"], ["B", "H"], ["D", "E"], ["F", "G"]],
 [["A", "B"], ["C", "G"], ["D", "H"], ["E", "F"]]]

You'll notice that my code gets me two D<->H combinations (last line and second line) and that won't work.

My understanding of the OP's requirements [FM]:

  • Given N teams (for example, 8 teams: A..H).
  • Create a tournament schedule, consisting of R rounds of play (7 in our example) and G games (28 in our example).
  • Where every team plays every other team exactly once.
  • Where every team plays once in each round.
  • And (the hard part) where the ordering of games within a round works like this:
  • The top-ranked team (A) plays the low-ranked team (H) first.
  • If a candidate matchup is rejected for violating the no-repeat rule, put the low-ranked team on the "back-burner" and form the other matchups first. Then matchup the back-burner teams using the same rules. (For example: in Round 2, the first candidate matchup, A-H, is rejected as a repeat, so Game 1 will be A-G, and H will sit on the back burner, to be paired with D as the last game in the round).
  • When adding teams to the back-burner, add them to the front of that list (i.e., preserve rank ordering on the back-burner as well).
  • Note: Round 5 is the tricky one. The first 2 games are straightforward. The 3rd game would then be E-H; however, that creates a scenario where the 4th game would be a repeat (F-G). So the algorithm needs to backtrack, reject the E-H pairing and instead go for E-G in the 3rd game.
share|improve this question
Are there any performance constraints? What size arrays? When you say it needs to be the same, does this include the order? –  Mark Byers Dec 15 '09 at 23:21
Yes, it needs to be in that order. (It needs to replace an existing process that is currently manually done and the customer is set in their ways.) –  rwl4 Dec 15 '09 at 23:27
Could you explain what the order is? I'm not sure I can guess the pattern. –  Mark Byers Dec 15 '09 at 23:30
I apologize, I realized I missed a dimension. I constructed that array by hand from a sheet and didn't notice that I missed that. Take another look and it shoud be more clear. Thanks!!! –  rwl4 Dec 15 '09 at 23:34
@rwl4 Could you explain how it is done manually? There must be a way to capture the manual logic in code. –  Ben Marini Dec 16 '09 at 3:31

10 Answers 10

up vote 5 down vote accepted

Well, I can get your 8-team example right, but I don't know how to generalize the tweak. But maybe this'll get you thinking...

games = (1...teams.size).map do |r|
  t = teams.dup
  (0...(teams.size/2)).map do |_|
    [t.shift,t.delete_at(-(r % t.size + (r >= t.size * 2 ? 1 : 0)))]
share|improve this answer
Was anyone able to make this snippet work for any quantity of teams? –  Yuyo Dec 31 '12 at 19:33
It works for even number of teams, but not odd. –  Tiago Fernandez Dec 5 '13 at 22:52
See my answer stackoverflow.com/a/26323225/197944 for a gem working on odd and even number of teams. –  Sébastien Saunier Nov 11 '14 at 11:18

You seem want a round-robin schedule. The principle is easy:

If you start with this setup (teams in the upper row playing against the corresponding lower team):


you set one team as fixed (e.g., A) and rotate the rest (e.g., clockwise):

A H B C     A G H B     A F G H     A E F G    A D E F    A C D E  
G F E D     F E D C     E D C B     D C B H    C B H G    B H G F

Voilà, 7 rounds, and every team plays each other team.

Edit: I changed the enumeration order in this example to reflect your example output, but this only gets the opponents of A right.

share|improve this answer

I apologize for the Python-ness of this code. With any luck, someone will translate.

def tourney(teams):
    N = len(teams)
    R = N-1 # rounds
    M = N/2 # matches per round
    sched = [[None] * M for i in range(R)]
    played = set()

    def fill(i, t):
        # Replenish t at the start of each round.
        if i % M == 0:
            t = teams[:]

        # Pick out the highest-seeded team left in t.
        topseed = t.pop(min(range(len(t)), key=lambda i: teams.index(t[i])))

        # Try opponents in reverse order until we find a schedule that works.
        for j, opp in reversed(list(enumerate(t))):
            match = topseed, opp
            if match not in played:
                # OK, this is match we haven't played yet. Schedule it.
                sched[i // M][i % M] = match

                # Recurse, if there are any more matches to schedule.
                if i + 1 == R * M or fill(i + 1, t[j+1:]+t[:j]):
                    return True  # Success!

                # If we get here, we're backtracking. Unschedule this match.
        return False

    if not fill(0, []):
        raise ValueError("no schedule exists")
    return sched
share|improve this answer
Nice job. The funky ordering (assuming that I described it correctly) made this a tough one. –  FMc Dec 16 '09 at 23:33
FM: You did an amazing job reverse-engineering that, and I wouldn't have bothered with this without your explanation. –  Jason Orendorff Dec 17 '09 at 0:13
Apparently it works up to 4 teams (or maybe for even numbers only), then at least one team does not get all matchups properly scheduled. –  Tiago Fernandez Dec 5 '13 at 22:13
In my defense, the question does say "arbitrary (even) number". –  Jason Orendorff Dec 7 '13 at 1:42
If you have an odd number of teams then you can adjust this so in the first round only there is an extra team named "BYE" that is the lowest seeded team. –  Bill Rawlinson Jul 27 at 17:55

Here is an implementation in ruby 1.8.6 according to FM's specification giving the correct output for 8 teams (Many thanks to FM for the great work!):

#!/usr/bin/env ruby

require 'pp'
require 'enumerator'

class Array
  # special round robin scheduling
  def schedule
    res, scheduled = [], []
    (length-1).times { dup.distribute(scheduled, []) }
    # convert list of games to list of rounds
    scheduled.each_slice(length/2) {|x| res.push x}
    aux = res.inject {|a, b| a+b}
    raise if aux.uniq.length != aux.length
  # pair the teams in self and backburner and add games to scheduled
  def distribute(scheduled, backburner)
    # we are done if list is empty and back burners can be scheduled
    return true if empty? && backburner.empty?
    return backburner.distribute(scheduled, []) if empty?
    # take best team and remember if back burner list offered alternatives
    best, alternatives = shift, !backburner.empty?
    # try each team starting from the last
    while other = pop do
      # add team to the back burner list if best played it already
      if scheduled.include? [best, other]
      # schedule the game
      scheduled.push [best, other]
      # try if rest can be scheduled
      return true if dup.distribute(scheduled, backburner.dup)
      # if not unschedule game and add other to back burner list
    # no possible opponent was found, so try alternatives from back burners list
    return alternatives && backburner.unshift(best).distribute(scheduled, [])

pp %w{ A B C D E F G H }.schedule


[[["A", "H"], ["B", "G"], ["C", "F"], ["D", "E"]],
 [["A", "G"], ["B", "F"], ["C", "E"], ["D", "H"]],
 [["A", "F"], ["B", "E"], ["C", "D"], ["G", "H"]],
 [["A", "E"], ["B", "D"], ["C", "H"], ["F", "G"]],
 [["A", "D"], ["B", "C"], ["E", "G"], ["F", "H"]],
 [["A", "C"], ["B", "H"], ["D", "G"], ["E", "F"]],
 [["A", "B"], ["C", "G"], ["D", "F"], ["E", "H"]]]
share|improve this answer

How about

 => [["A", "B"], ["A", "C"], ["A", "D"], ["A", "E"], ["A", "F"], ["A", "G"], ["A", "H"], ["B", "A"], ["B", "C"], ["B", "D"], ["B", "E"], ["B", "F"], ["B", "G"],....

Edit: Just noticed the output is not in your desired format, but maybe it's still useful for somebody else.

share|improve this answer

I finally had time to look at this again. This is a Ruby version of Jason's answer, with a few simplifications and a couple of good ideas from jug's answer.

require 'pp'

def tournament (teams)

    # Hash of hashes to keep track of matchups already used.
    played = Hash[ * teams.map { |t| [t, {}] }.flatten ]

    # Initially generate the tournament as a list of games.
    games = []
    return [] unless set_game(0, games, played, teams, nil)

    # Convert the list into tournament rounds.
    rounds = []
    rounds.push games.slice!(0, teams.size / 2) while games.size > 0

def set_game (i, games, played, teams, rem)
    # Convenience vars: N of teams and total N of games.
    nt  = teams.size
    ng  = (nt - 1) * nt / 2

    # If we are working on the first game of a round,
    # reset rem (the teams remaining to be scheduled in
    # the round) to the full list of teams.
    rem = Array.new(teams) if i % (nt / 2) == 0

    # Remove the top-seeded team from rem.
    top = rem.sort_by { |tt| teams.index(tt) }.pop

    # Find the opponent for the top-seeded team.
    rem.each_with_index do |opp, j|
        # If top and opp haven't already been paired, schedule the matchup.
        next if played[top][opp]
        games[i] = [ top, opp ]
        played[top][opp] = true

        # Create a new list of remaining teams, removing opp
        # and putting rejected opponents at the end of the list.
        rem_new = [ rem[j + 1 .. rem.size - 1], rem[0, j] ].compact.flatten

        # Method has succeeded if we have scheduled the last game
        # or if all subsequent calls succeed.
        return true if i + 1 == ng
        return true if set_game(i + 1, games, played, teams, rem_new)

        # The matchup leads down a bad path. Unschedule the game
        # and proceed to the next opponent.
        played[top][opp] = false

    return false

pp tournament(ARGV)
share|improve this answer

I wrote a gem recently that help in the process of generating round-robin schedules. You might give it a try.

share|improve this answer

I created a gem, round_robin_tournament which you might find useful.

Just run

students = %w(John Paul Ringo George)
teams = RoundRobinTournament.schedule(students)

And teams will be an array of each day, each day being an array of couples.

share|improve this answer

The selected answer here gave me trouble. Seems related to the delete_at approach where you are moving backwards on the array of teams. Inevitbaly two teams play each other more than once before they should. I only noticed it when I went to 16 teams, but I think it happens at 8 teams as well...

so I coded Svante's algo which is clever and works with any number of teams. Also I'm rotating counter-clockwise, not clockwise

assuming teams is a model object here, and num_teams is the number of teams

  @tms = teams.all    
  matchups_play_each_team_once = (0...num_teams-1).map do |r|
    t = @tms.dup
    first_team = t.shift
    r.times do |i|
      t << t.shift
    t = t.unshift(first_team)  
    tms_away = t[0...num_teams/2]
    tms_home = t[num_teams/2...num_teams].reverse
    (0...(num_teams/2)).map do |i|
share|improve this answer

Based on this information in this link the following Ruby code is what I use to generate round-robin scheduling:

def round_robin(teams)
  raise "Only works for even number of teams" unless teams.length.even?
  first = teams.shift                               # Put one team in the middle, not part of the n-gon
  size  = teams.length                              # The size of the n-gon without one team
  pairs = (1..(size/2)).map{ |i| [i,size-i].sort }  # The 'lines' that connect vertices in the n-gon
    teams.unshift( teams.pop )                      # Rotate the n-gon
    # Combine the special case with the vertices joined by the lines
    [ [ first, teams[0] ], *pairs.map{ |a,b| [ teams[a], teams[b] ] } ]

teams    = ('A'..'H').to_a
schedule = round_robin(teams)
puts schedule.map{ |round| round.map{ |teams| teams.join }.join(' ') }
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.