While dabbling in Clojure I completed a small example program to pick a random choice from a list of choices.

The basic idea is to iterate over the choices (which are assigned a weight) and turn their weights into a range, then pick a random number within the total range to select one. It might not be the most elegant design, but let's take it for granted.

What would wo do differently compared to my example below?

I'm not interested in overall program structure suggestions, name-spacing, etc, mostly in your approach to each function.

I'm especially interested in how a seasoned Clojurer would tackle the "augment" function, in which I had to use the external "cur" variable to refer to the previous end of the range.

  (def colors
            :white 1,
            :red 10,
            :blue 20,
            :green 1,
            :yellow 1

    (def color-list (vec colors))

    (def cur 0)

    (defn augment [x] 
      (def name (nth x 0))
      (def val (nth x 1))
      (def newval (+ cur val))
      (def left cur)
      (def right newval)
      (def cur (+ cur val))
      [name left right]

    (def color-list-augmented (map augment color-list))

    (defn within-bounds [bound]
      (def min-bound (nth bound 1))
      (def max-bound (nth bound 2))
      (and (> choice min-bound) (< choice max-bound))

    (def choice (rand-nth (range cur)))

    (def answer 
      (first (filter within-bounds color-list-augmented))

    (println "Random choice:" (nth answer 0))
  • 1
    Never use (def ...) inside a function, even if you do want to modify global state. Jan 22, 2013 at 17:25
  • Thanks, just picking up the syntax as I go along. I guess there's something else for local function scope? "let" maybe?
    – Hejazzman
    Jan 22, 2013 at 18:01

4 Answers 4


I suggest doing some problems at http://www.4clojure.com/ while learning Clojure. You can "follow" the top users and see how they solve problems.

Here's a solution. It is again not the most efficient as I was aiming to keep it simple and not use more advanced ideas and constructs that you'll learn later.

user=> (def colors {:white 1  :red 10  :blue 20  :green 1  :yellow 1})
user=> (keys colors)
(:white :red :blue :green :yellow)   
user=> (vals colors)
(1 10 20 1 1)

To turning the weights into intervals, we just do a cumulative sum:

user=> (reductions #(+ % %2) (vals colors))
(1 11 31 32 33)

Finding the random interval:

user=> (rand-int (last *1))
user=> (count (take-while #(<= % *1 ) *2 ))

Note *1 in the REPL refers to the most recent value printed, *2 to the next most recent, etc. So we asked for a random integer between 0 (inclusive) and 33 (exclusive). These 33 possible choices correspond to the total of the weights. Next we counted the number of intervals we would need to pass through to find that number. Here the random number was 13.

(1 11 31 32 33) 
     ^ 13 belongs here, 2 numbers in

We find our random number 2 in. Note that in order to land here we had to have at least 11 but less than 31, so 20 possibilities, which is precisely the weight of...

user=> (nth (keys colors) *1)

So, putting this all together into a function:

(defn weighted-rand-choice [m]
    (let [w (reductions #(+ % %2) (vals m))
          r (rand-int (last w))]
         (nth (keys m) (count (take-while #( <= % r ) w)))))

Let's test it:

user=> (->> #(weighted-rand-choice colors) repeatedly (take 10000) frequencies)
{:red 3008, :blue 6131, :white 280, :yellow 282, :green 299}

Rich Hickey's somewhat dated (2008) solution from ants.clj:

(defn wrand 
  "given a vector of slice sizes, returns the index of a slice given a
  random spin of a roulette wheel with compartments proportional to
  (let [total (reduce + slices)
        r (rand total)]
    (loop [i 0 sum 0]
      (if (< r (+ (slices i) sum))
        (recur (inc i) (+ (slices i) sum))))))

Stuart Halloway's more recent (2012) solution from data.generators:

(defn weighted
  "Given a map of generators and weights, return a value from one of
  the generators, selecting generator based on weights."
  (let [weights   (reductions + (vals m))
        total   (last weights)
        choices (map vector (keys m) weights)]
    (let [choice (uniform 0 total)]
      (loop [[[c w] & more] choices]
        (when w
          (if (< choice w)
            (call-through c)
            (recur more)))))))
  • There is a similar algorithm discussed in braveclojure.com (chapter on hitting hobbits), pretty much follows Rich Hickey's solution above. I couldn't wrap my head around it though, until I read Rich's comment on the roulette metaphor - thanks for sharing! Mar 18, 2020 at 8:36

It often helps to break the problem into layers that can be solved independently. Augment does this nicely in assigning ranges, though the result is harder to consume with the normal sequence functions while choosing one at random. If you change the goal of augment to have it produce a normal seq then the augmentation problem is more cleanly separated from choosing one randomly. Provided the weights are integers you can build a list containing weight number of each item, and then choose one at random:

user> (map (fn [[item weight]] (repeat weight item)) colors)
 (:red :red :red :red :red :red :red :red :red :red) 
 (:blue :blue :blue :blue :blue :blue :blue :blue :blue :blue
  :blue :blue :blue :blue :blue :blue :blue :blue :blue :blue) 
 (:green) (:yellow)) 

then flatten it down to a single list:

user> (flatten (map (fn [[item weight]] 
                       (repeat weight item)) 
(:white :red :red :red :red :red :red :red :red :red :red 
 :blue :blue :blue :blue :blue :blue :blue :blue :blue :blue 
 :blue :blue :blue :blue :blue :blue :blue :blue :blue :blue 
 :green :yellow)

and pick one with rand-nth:

user> (rand-nth (flatten (map (fn [[item weight]] (repeat weight item)) colors)))

ps: map literals make things look better: the reader page describes these nicely

(def colors {:white 1,
             :red 10,
             :blue 20,
             :green 1,
             :yellow 1})

use let to give things names within functions:

(defn augment [x]
  (let [name (nth x 0)
        val (nth x 1)
        newval (+ cur val)
        left cur
        right newval
        cur (+ cur val)]
    [name left right])) 
  • (->> {:a 10 :b 1} (map #(->> % reverse (apply repeat))) flatten rand-nth) is elegant, but slow(er) with ridiculous weights, like {:a 10000000 :b 100000} Oct 20, 2016 at 23:02

The open source bigml sampling library is another option. I've used it with some success. It's much better documented and has a nice API.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

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