11

Is there a 'proper' way to iterate over a two-dimensional sequence in Clojure? Suppose I had a list of lists of numbers, like this

 ((1 2 3)
  (4 5 6)
  (7 8 9))

and I wanted to generate a new list of lists with each number incremented by one. Is there an easy way to do this in Clojure without relying on nested maps or loop/recurs? I've been able to do it, but my solutions are ugly and I find them difficult to understand when I re-read them.

Thanks

14

You can always just use a list comprehension. I find myself using them quite often coming from an imperative background so I don't know how idiomatic it is. In your specific case, you can do:

(for [my-list my-matrix] (map inc my-list))
  • 1
    I'm going to accept this one, although the others are certainly valid responses. This just trikes me as the shortest and most readable. – Joel Nov 11 '11 at 13:29
  • 4
    It should be noted that for produces a lazy sequence, so it only "iterates" when the value is requested. – postfuturist Nov 14 '11 at 18:59
18

What you describe is precisely what clojure.walk is for:

(def matrix [[1 2 3]
             [4 5 6]
             [7 8 9]])
(use 'clojure.walk :only [prewalk])
(prewalk #(if (number? %) (inc %) %) matrix)
=> [[2 3 4] [5 6 7] [8 9 10]]

Note 1: it is idiomatic to use vectors instead of parentheses for literal sequential collections.

Note 2: walk preserves type.

  • Thanks for mentioning Note 1 - I'm still a little iffy on when to use one or the other. – Joel Nov 11 '11 at 13:26
  • This answer is referenced by the Clojure cheat sheet at clojure.org. – John Jul 13 '13 at 15:10
10

For the two-dimensional case, you could do something like:

(map #(map inc %) my-two-d-list)

That's not too bad to read: apply the function #(map inc %) to each element in a list.

For the higher-order case, you're basically talking about tree-traversal. You'd want a function that takes in a tree and a function, and applies that function to each node in the tree. You can find functions for this in clojure.walk.

5

The other answers by Sean and Matt both show concise and effective ways of getting the right result.

However there are some important extensions you can make to this:

  • It would be nice to handle the case of higher dimensions
  • It is good to wrap the functionality in a higher order function

Example code:

;; general higher order function
(defn map-dimensions [n f coll] 
  (if (= n 1)
    (map f coll)
    (map #(map-dimensions (dec n) f %) coll)))

;; use partial application to specialise to 2 dimensions
(def map-2d (partial map-dimensions 2))

(map-2d inc  
    '((1 2 3)
      (4 5 6)
      (7 8 9)))
=> ((2 3 4) (5 6 7) (8 9 10))
  • It's nevertheless valuable to see how it can be done from scratch. – Mars Feb 12 '14 at 17:17
  • Also, prewalk requires a function that distinguishes leaf nodes from branch nodes. You can't just give inc, for example. – Mars Feb 12 '14 at 17:31
5

Since the introduction of core.matrix in 2013, this is now a much better way of handling operations over multi-dimensional arrays:

(use 'clojure.core.matrix)

(def M  [[1 2 3]
         [4 5 6]
         [7 8 9]])

(emap inc M)

=> [[2 3 4 ]
    [5 6 7 ]
    [8 9 10]]

Advantages of using core.matrix:

  • Clean, idiomatic Clojure code
  • Lots of general purpose n-dimensional array manipulation functions - transpose, shape, reshape, slice, subarray etc.
  • Ability to plug in high performance array implementations (e.g. for big numerical arrays)
0

A belated answer, and maybe not exactly what is needed: you could try flatten. It will return a seq that you can iterate over:

(flatten  '((1 2 3)
            (4 5 6)
            (7 8 9)))

user=> (1 2 3 4 5 6 7 8 9)

And in order to increment matrix elements and reassemble the matrix:

(partition 3 (map inc (flatten  '((1 2 3)
                                  (4 5 6)
                                  (7 8 9)))))

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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