# Tail recursive Clojure function for computing combinations

I have a function that, given a vector, returns all unordered combinations:

``````(defn combination [ps]
(loop [acc []
ps ps]
(if (= 2 (count ps))
(conj acc (apply vector ps))
(recur (apply conj acc (map #(vector (first ps) %) (rest ps)))
(rest ps)))))
``````

This works just fine, but seems a bit convoluted to me.

Is there a more straight-forward, idiomatic way to accomplish this in Clojure? I'm happy to use a Clojure core or library function, as this is certainly part of my definition of "idiomatic". :)

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You can replace `(apply vector ps)` with `(vec ps)` –  Thumbnail Mar 17 at 13:48
... crashes for `(count ps)` less than 2. `(case (count ps), (0 1) (), 2 (conj ... ), (recur ... ))` perhaps. –  Thumbnail Mar 17 at 14:18
Good point. I was just looking at the code and thinking that `(= 2 ...)` was a bit of a code smell. You'll be happy to know that I replaced my function with yours in the program that caused me to ask this question. :) –  Josh Glover Mar 17 at 14:24

Your code returns all selections of two elements taken in order. Another way to do this is ...

``````(defn combination [s]
(let [tails (take-while next (iterate rest s))]
(mapcat (fn [[f & rs]] (map #(vector f %) rs)) tails)))
``````

This is shorter than yours and is lazy too. But it's likely to be slower.

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Speed is not an issue for me, so this works just fine. –  Josh Glover Mar 17 at 13:42
When I look at this again, the algorithm is virtually the same as yours. I've used destructuring for brevity in the inner loop. And the expression for `tails` replaces both your `loop`/`recur` and your termination test. And, since I deal in lazy sequences throughout, I don't need to accumulate the solutions in a vector or anything else. –  Thumbnail Mar 17 at 13:45
Yes, your code is really nice and concise. Clojure's destructuring is great stuff! –  Josh Glover Mar 17 at 13:50

Clojure has clojure.math.combinatorics which contains many convenient functions. So arguably the "idiomatic" way to do what you did in Clojure would be to import/require clojure.math.combinatorics and then simply call combinations with n = 2.

``````...>  (comb/combinations [1 2 3 4] 2)
((1 2) (1 3) (1 4) (2 3) (2 4) (3 4))
``````

For this to work you'll need to first add the correct dependency.

As I write this the latest version is: `[org.clojure/math.combinatorics "0.0.7"]`

I did then require it "`:as comb`":

``````(:require [clojure.math.combinatorics :as comb]
``````

In case you don't want to use math.combinatorics, you can edit your question to precise it and I'll delete my answer.

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Somewhat facetiously ...

``````(defn combination [ps]
(clojure.math.combinatorics/combinations ps 2))
``````

... which is lazy, but the source code is two or three times as long as yours.

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Thumbnail, are you sure that's not what my code does? It certainly returns the same value as `clojure.math.combinatorics/combinations`. –  Josh Glover Mar 17 at 13:38
No. I'll delete my misleading - ok, downright wrong - comment. I misunderstood the library function without trying it or reading the given example. Tut tut! –  Thumbnail Mar 17 at 14:00