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I want to map over a sequence in order but want to carry an accumulator value forward, like in a reduce.

Example use case: Take a vector and return a running total, each value multiplied by two.

(defn map-with-accumulator
  "Map over input but with an accumulator. func accepts [value accumulator] and returns [new-value new-accumulator]."
  [func accumulator collection]
  (if (empty? collection)
    nil
    (let [[this-value new-accumulator] (func (first collection) accumulator)]
      (cons this-value (map-with-accumulator func new-accumulator (rest collection))))))

(defn double-running-sum
  [value accumulator]
  [(* 2 (+ value accumulator)) (+ value accumulator)])

Which gives

(prn (pr-str (map-with-accumulator double-running-sum 0 [1 2 3 4 5])))

>>> (2 6 12 20 30)

Another example to illustrate the generality, print running sum as stars and the original number. A slightly convoluted example, but demonstrates that I need to keep the running accumulator in the map function:

(defn stars [n] (apply str (take n (repeat \*))))

(defn stars-sum [value accumulator]
  [[(stars (+ value accumulator)) value] (+ value accumulator)])

(prn (pr-str (map-with-accumulator stars-sum 0 [1 2 3 4 5])))
>>> (["*" 1] ["***" 2] ["******" 3] ["**********" 4] ["***************" 5])

This works fine, but I would expect this to be a common pattern, and for some kind of map-with-accumulator to exist in core. Does it?

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4 Answers 4

up vote 3 down vote accepted

You should look into reductions. For this specific case:

(reductions #(+ % (* 2 %2)) 2 (range 2 6))

produces

(2 6 12 20 30)

share|improve this answer
    
Thanks. I'm not sure that captures the generality of my question though (I had to illustrate it but perhaps the illustration didn't exhibit the generality adequately). I've added another example. –  Joe May 24 '14 at 21:32
    
Sorry for the delay in accepting, I wanted to be sure that this covered my use case. It does, thank you. –  Joe Jun 2 '14 at 21:56

The general solution

The common pattern of a mapping that can depend on both an item and the accumulating sum of a sequence is captured by the function

(defn map-sigma [f s] (map f s (sigma s)))

where

(def sigma (partial reductions +))

... returns the sequence of accumulating sums of a sequence:

(sigma (repeat 12 1))
; (1 2 3 4 5 6 7 8 9 10 11 12)

(sigma [1 2 3 4 5])
; (1 3 6 10 15)

In the definition of map-sigma, f is a function of two arguments, the item followed by the accumulator.

The examples

In these terms, the first example can be expressed

(map-sigma (fn [_ x] (* 2 x)) [1 2 3 4 5])
; (2 6 12 20 30)

In this case, the mapping function ignores the item and depends only on the accumulator.

The second can be expressed

(map-sigma #(vector (stars %2) %1) [1 2 3 4 5])
; (["*" 1] ["***" 2] ["******" 3] ["**********" 4] ["***************" 5])

... where the mapping function depends on both the item and the accumulator.

There is no standard function like map-sigma.

General conclusions

  • Just because a pattern of computation is common does not imply that it merits or requires its own standard function.
  • Lazy sequences and the sequence library are powerful enough to tease apart many problems into clear function compositions.

Rewritten to be specific to the question posed.


Edited to accommodate the changed second example.

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Thanks for your answer, but I think this answers the examples but not the actual question (a map where the running accumulator is available). I've edited the stars to demonstrate this (note I haven't changed the question or the function I'm asking about!). –  Joe May 26 '14 at 13:07
    
@Joe - adapted to make the running accumulator available to any mapping. –  Thumbnail May 26 '14 at 14:40
    
Thanks very much for your answer + effort. I accepted the other because he was first, sorry. I'd double-upvote if I could! –  Joe Jun 2 '14 at 21:57
    
@Joe No problem. I had to get it right for myself. The insight is the parameterisation: obvious once seen, but harder to capture. The thing about functional programming is that the perfect expression of the question is the answer. –  Thumbnail Jun 2 '14 at 22:40

Reductions is the way to go as Diego mentioned however to your specific problem the following works

(map #(* % (inc %)) [1 2 3 4 5])
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Thanks. This solves the "how do I calculate this sequence of numbers" not "does this higher-order function exist?". I suppose that's my fault for providing an example. Anyway, I've added another one to illustrate. –  Joe May 24 '14 at 21:36

As mentioned you could use reductions:

(defn map-with-accumulator [f init-value collection]
  (map first (reductions (fn [[_ accumulator] next-elem]
                           (f next-elem accumulator))
                         (f (first collection) init-value)
                         (rest collection))))

=> (map-with-accumulator double-running-sum 0 [1 2 3 4 5])
(2 6 12 20 30)

=> (map-with-accumulator stars-sum 0 [1 2 3 4 5])
("*" "***" "******" "**********" "***************")

It's only in case you want to keep the original requirements. Otherwise I'd prefer to decompose f into two separate functions and use Thumbnail's approach.

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