# Randomly pairing elements of a vector in R to count unique arrangements

Background:

On this combinatorics question, the issue is how to determine the sample space: the ways 8 different soccer teams can be paired up for the next round of competition. Two different answers have been advanced for that part of the problem: 28 (see comments OP) and 105 (see edit within OP and answer).

I'd like to do this manually to try to hone down on the mistake in whichever answer is incorrect.

What I have tried:

``````teams = 1:8
names(teams) = c("RM", "BCN", "SEV", "JUV", "ROM", "MC", "LIV", "BYN")
split(sample(teams), rep(1:(length(teams)/2), each=2))
``````

Unfortunately, the output is a list, and I wanted a vector to be able to run something like:

``````unique(...,MARGIN=2)
``````

Is there a way of doing this in an elegant manner?

After a now erased answer (thank you), I would go with

`a <- replicate(1e5, unlist(split(sample(teams), rep(1:(length(teams)/2), each=2))))`

to simulate 100,000 random samples, and later run

`unique(a, MARGIN = 2)`.

But how can I account for the fact that the order of the 4 pairings of opponents doesn't matter, and that `LIV-BYN` and `BYN-LIV`, for example, is the same pairing (field advantage notwithstanding)?

• Will 'unlist' work for your question? Commented Mar 17, 2018 at 16:02

``````> u = ncol(unique(replicate(1e6, unlist(split(sample(teams), rep(1:(length(teams)/2), each=2)))), MARGIN = 2))
> u / (factorial(4) * 2^4)
[1] 105
``````

The idea of `unlist` is from @Song Zhengyi, and if his answer is un-deleted, I'll accept it. The complete answer is in the lines above.

`u` needs to be divided by 4! because

``````BCN-RM, BYN-SEV, JUV-ROM, LIV-MC
``````

is exactly the same as

``````LIV-MC, BCN-RM, BYN-SEV, JUV-ROM
``````

or

``````BCN-RM, LIV-MC, BYN-SEV, JUV-ROM
``````

etc.

The term `2^4` is to avoid over-counting since for every possible unique draw, each one of the pairings can be flipped without loss (discarding field advantage): `BCN-RM` is the same as `RM-BCN`, and there are 4 pairs in each draw.

If field advantage is a consideration (real life)...

``````> u/factorial(4)
[1] 1680
``````

we end up with 1,680 possible draws.