# Tennis tournament algorithm

After a tennis tournament each player was asked how many matches he had. An athlete can't play more than one match with another athlete. As an input the only thing you have is the number of athletes and the matches each athlete had. As an output you will have 1 if the tournament was possible to be done according to the athletes answers or 0 if not. For example:

``````Input: 4 3 3 3 3      Output: 1
Input: 6 2 4 5 5 2 1  Output: 0
Input: 2 1 1          Output: 1
Input: 1 0            Output: 0
Input: 3 1 1 1        Output: 0
Input: 3 2 2 0        Output: 0
Input: 3 4 3 2        Output: 0
``````

the first number of the input is not part of the athletes answer it's the number of athletes that took part in the tournament for example in 6 2 4 5 5 2 1 we have 6 athletes that took part and their answers were 2 4 5 5 2 1.

So far this is what we wrote but didn't work that great:

``````import java.util.Scanner;
import java.util.Arrays;

public class Tennis {

public static void main(String[] args) {
Scanner input = new Scanner(System.in);

String N;
int count;
int sum = 0;
int max;
int activeAthletes;
int flag;

System.out.printf("Give: ");
N = input.nextLine();

String[] arr = N.split(" ");
int[] array = new int[arr.length];

for (count = 0; count < arr.length; count++) {
array[count] = Integer.parseInt(arr[count]);
//System.out.print(arr[count] + " ");
}

for (count = 1; count < arr.length; count++) {
sum += array[count];
}
//System.out.println("\n" + sum);

activeAthletes = array[0];

for (count = 1; count < array.length; count++) {
if (array[count] == 0) {
activeAthletes--;
}
}

max = array[1];
for (count = 2; count < array.length; count++) {
if (array[count] > max) {
max = array[count];
}
}
// System.out.println(max);

if ((sum % 2 == 0) && (max < activeAthletes)) {
flag = 1;
} else{
flag = 0;
}

System.out.println(flag);
}
}
``````

I do not want a straight solution just maybe some tips and hints because we really have no idea what else to do and I repeat even though I'll tag it as a homework (because I feel the moderators will close it again) it is not, it's just something my brother found and we are trying to solve.

Well many of you have answered and I'm really grateful but as I have work tomorrow I need to go to sleep, so I'll probably read the rest of the answers tomorrow and see what works

• The first thing you should do after you get the number of athletes and the total number of matches is decide whether or not that there is any way for that to be valid. (If there are more matches the total number of possible matches than it's not valid) the total number of possible matches is (I think) `n choose 2 * 2` (accounted for the fact that each match is counted twice once for each person) Commented Apr 25, 2012 at 20:46
• Is this problem for a Round-robin tournament or Single-elimination tournament? Commented Apr 25, 2012 at 20:52
• Why is the answer for `1 0` `0`? You say each athlete can't play more than one match with another. That implies they can play `0` matches. So can they or can't they play 0 matches? Commented Apr 25, 2012 at 21:24
• That is unfortunately not given and as a matter of fact it is quite confusing but the Input: 1 0 Output: 0 is deffinitely correct so I guess they can play 0 matches because another valid point would be that 1 0 is 0 because it only has 1 player, so it is not a valid tournament Commented Apr 25, 2012 at 21:36
• @emory - you got it wrong. The `1` in `1 0` represents the number of players, not the matches of one of the players. There is only one player who played `0` matches. Commented Apr 26, 2012 at 8:05

Not sure if it works 100%, i would go like:

1. Sort input
2. for each element going from right to left in array (bigger to smaller)

• based on value n of element at index i decrease n left elements by 1
• return fail if cant decrease because you reached end of list or value 0
3. return success.

This logic (if correct) can lead whit some modifications to O(N*log(N)) solution, but I currently think that that would be just too much for novice programmer.

EDIT:

This does not work correct on input
2 2 1 1

All steps are then (whitout sorting):

1. while any element in list L not 0:

• find largest element N in list L
• decrease N other values in list L by 1 if value >= 1 (do not decrease this largest element)
• return fail if failure at this step
• set this element N on 0
2. return OK

• This fails for 3 2 2 0 I think
– dfb
Commented Apr 25, 2012 at 21:42
• @spinning_plate - `0 2 2` would cause it to return `0` immediately if I understand correctly. Commented Apr 25, 2012 at 21:44
• that is actually what I had initially planned to do but I didn't like it, I wanted something more mathematical and elegant Commented Apr 25, 2012 at 21:59
• +1, I think this solution is correct, but I'd love to see a proof
– dfb
Commented Apr 25, 2012 at 22:01
• I was thinking about the same solution and I think it works (The array needs to be resorted after step 2). Anybody can think of an exception? Commented Apr 25, 2012 at 22:07

Here's a hint. Answer these questions

1. Given N athletes, what is the maximum number of matches?
2. Given athlete X, what is the maximum number of matches he could do?
3. Is this sufficient to check just these? If you're not sure, try writing a program to generate every possible matching of players and check if at least one satisfies the input. This will only work for small #s of atheletes, but it's a good exercise. Or just do it by hand

Another way of asking this question, can we create a symmetric matrix of 1s and 0s whose rows are equal the values. This would be the table of 'who played who'. Think of this like an N by N grid where grid[i][j] = grid[j][i] (if you play someone they play you) and grid[i][i] = 0 (no one plays themselves)

For example

``````Input: 4 3 3 3 3 Output: 1
``````

Looks like

`````` 0 1 1 1
1 0 1 1
1 1 0 1
1 1 1 0
``````

We can't do this with this one, though: Input: 3 2 2 0 Output: 0

EDIT

This is equivalent to this (from Degree (graph theory))

Hakimi (1962) proved that (d1, d2, ..., dn) is a degree sequence of a simple graph if and only if (d2 − 1, d3 − 1, ..., dd1+1 − 1, dd1+2, dd1+3, ..., dn) is. This fact leads to a simple algorithm for finding a simple graph that has a given realizable degree sequence:

1. Begin with a graph with no edges.
2. Maintain a list of vertices whose degree requirement has not yet been met in non-increasing order of residual degree requirement.
3. Connect the first vertex to the next d1 vertices in this list, and then remove it from the list. Re-sort the list and repeat until all degree requirements are met.

The problem of finding or estimating the number of graphs with a given degree sequence is a problem from the field of graph enumeration.

• I like (1) and (2), but (3) checking by brute force doesn't sit right with me ;) I really do like how you suggest thinking about the problem in terms of a symmetric matrix, but given the OP's level of computer science (grade school) it might be appropriate to explain further what a "symmetric matrix" is, and possibly give an example. (Remember the diagonal must be zeroes.) Commented Apr 25, 2012 at 21:07
• @Li-aungYip - re: (3) this is what I do when I get stuck :) Not as a solution, just to check my intuitions
– dfb
Commented Apr 25, 2012 at 21:10
• I'm actually into college and I know what a symmetric matrix is actually Commented Apr 25, 2012 at 21:14
• I am really sorry, it's just that English is not my native language. I will try to improve this in the future Commented Apr 25, 2012 at 21:24
• Link to the original paper by Hakimi for those interested: compalg.inf.elte.hu/~tony/Oktatas/Algoritmusok-hatekonysaga/… Commented Apr 26, 2012 at 0:50

Maybe you can take the array of athletes' match qties, and determine the largest number in there.

Then see if you can split that number into 1's and subtract those 1's from a few other members of the array.

Zero out that largest number array member, and remove it from the array, and update the other members with reduced values.

Now, repeat the process - determine the new largest number, and subtract it from other members of the array.

If at any point there are not enough array members to subtract the 1's from, then have the app return 0. otherwise continue doing it until there are no more members in the array, at which point you can have the app return 1.

Also, remember to remove array members that were reduced down to zero.

• that is exactly what I have been doing by hand to determine if the match quantity was valid or not but I didn't want to implement this in an algorithm because it seemed the easiest way as of thinking and hardest way as of implementing into a programming language that's why I wanted a "smarter" solution Commented Apr 25, 2012 at 21:06

Your examples can all trivially be solved by counting the matches and looking whether they divide by 2.

A problem not covered by your examples would be a player, who has more games than the sum of the other players:

• Input: 4 5 1 1 1 Output: 0

This can be complicated if we add more players:

• Input: 6 5 5 5 1 1 1 Output: 0

How to solve this question? Well, remove one game pairwise from the maximum and the minimum player, and see what happens:

• Input: 6 5 5 5 1 1 1
• Input: 5 5 5 4 1 1 -
• Input: 4 5 4 4 1 - -
• Input: 3 4 4 4 - - -

It violates the rule:

An athlete can't play more than one match with another athlete.

If 3 players are left, they can't have had more than 2 games each.

Edit: Below solution passes some invalid inputs as valid. It's a fast way to check for definite negatives, but it allows false positives.

Here's what a mathematician would suggest:

1. The sum of the number of matches must be even. `3 3 4 2 1` sums to `13`, which would imply someone played a match against themselves.
2. For `n` players, if every match eliminates one player at least `n-1` distinct matches must be played. (A knockout tournament.) To see this, draw a tree of matches for 2, 4, 8, 16, 32... players, requiring 1, 3, 7, 31... matches to decide a winner.
3. For `n` players, the maximum number of matches if everyone plays everyone once, assuming no repeat matches, is `n choose 2`, or `(n!)/(2!)(n-2)!` (Round robin tournament). `n!` is the factorial function, `n! = n * n-1 * n-2 * ... * 3 * 2 * 1.`.

So the criteria are:

1. Sum of the number of matches must be even.
2. Sum of the number of matches must be at least `2n-2`. (Note the multiplication by 2 - each match results in both players increasing their count by one.)
3. Sum of the number of matches must be at most `2 * n choose 2`.
4.  Each player must participate in at least one match.

If your tournament is a cross between a knockout tournament and a round robin tournament, you could have somewhere between `n-1` and `n choose 2` matches.

Edit:

If any player plays more than `n-1` matches, they played someone at least twice.

If your tournament is a knockout tournament ordered so that each player participates in as few matches as possible, then each player can participate in at most `log_2(n)` matches or so (Take `log` base 2 and round up.) In a tournament with 16 players, at most 4 matches. In a tournament of 1024 players, at most 10 matches.

• I believe that is exactly it. We had tracked down the first 2 criteria but we couldn't find the third one and I was sure it was something along those lines. I will test it today or tomorrow and let you know if it worked Commented Apr 25, 2012 at 21:07
• no the only limitation is that a player can't have more than one match with another player Commented Apr 25, 2012 at 21:19
• I don't see how you arrive at the second condition. From the way he stated the problem, I assume 2 0 0 would be valid input. Commented Apr 25, 2012 at 21:23
• @G.Bach : That input reads as : "Player A played in two matches, player B played in no matches, and player C played in no matches". (Who did player A play against? ;) ) Commented Apr 25, 2012 at 21:25
• @JasonBraucht: Because I had my mathematician hat on and I was thinking about it combinatorically (`n choose k`), not in terms of 'number of edges in complete undirected graph'. In this case, `n choose 2 == n!/2!(n-2!)` which simplifies to `(n^2 -n)/2` which is the same thing. Commented Apr 25, 2012 at 22:04