# how to access two adjoining elems in a seq while iterating through it

I have a seq `(2 3 1 4)`.

I want to iterate through it, and whereever the next element is smaller then the prev element replace both the elems another seq. '(- 4 1).

So f('(2 3 1 4)) => (2 (- 3 1) 4). How do I write it?

Basically -

1) I want to access two adjoining elements in a seq at the same time. 2) Edit and return a new seq at that point. 3) Continue processing the new returned seq.

What is the mechanism to achieve the above 3 generically. (map, reduce both give me access to only one elem at a time.)

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According to your description, shouldn't `f('(2 3 1 4)) => (2 3 (- 4 1))` evaluate to `('(- 3 2) '(- 4 1))`. Is this the desired output? Or would it be this:`('(- 3 2) 1 '(- 4 1))` ? –  leonardoborges Apr 24 '13 at 3:01
sorry for the wrong wording and ex. I have done the edits. Its where the next el is smaller than the prev. Have also changed the ex to reflect it. –  murtaza52 Apr 24 '13 at 3:15
That still seems odd to do in a generic way. In your example, the pairs are `([2 3] [3 1] [1 4])` and according to your requested output, on the first pair you want to keep the `2`, but on the last pair you want to keep the `4` which indicates a special case in the algorithm: namely that if we're on the last pair, we want to keep the second element if it's not smaller than the first. Is this correct? –  leonardoborges Apr 24 '13 at 4:58
Please check my answer, I added an UPDATE at the end. Is that what you're looking for? –  leonardoborges Apr 24 '13 at 5:12
The issue is that the next pair to check depends on whether the previous pair was replaced, so the pairs are not `([2 3] [3 1] [1 4])` but rather `([2 3] [3 1] [4])`. –  Francis Avila Apr 24 '13 at 5:15

This isn't really an issue of pairwise consumption because how you partition your sequence depends on what you do with the current pair. Notice that sometimes you consume one item from the sequence (`2 3`), but sometimes you consume two items (`3 1`).

Because of this, you can't use any of the usual methods of creating a sliding window in clojure (`(partition 2 1 coll)`, `(map fn coll (rest coll))`, etc). You need to use something that is explicitly recursive.

1. if empty seq emit nil
2. if only one item emit item
3. if two items, test for size:
1. if first > second, replace both with `(- first second)`; recurse with remaining items
2. otherwise, emit first; recurse with second and remaining items.

Here is a lazy implementation of this algorithm. You can also do this with `recur` and an accumulator--it won't be lazy but it will still work.

``````(defn combine-if-gt-next
[[f s & r]]
(cond
(nil? f) nil
(nil? s) (cons f nil)
(> f s)  (cons (list '- f s) (lazy-seq (combine-if-gt-next r)))
true (cons f (lazy-seq (combine-if-gt-next (cons s r))))))
``````

Examples:

``````(combine-if-gt-next '(2 3 1 4)) ; your example
;; (2 (- 3 1) 4)
(combine-if-gt-next [])
;; nil
(combine-if-gt-next [1 2 3])
;; (1 2 3)
(combine-if-gt-next [2 3 4 1])
;; (2 3 (- 4 1))
(combine-if-gt-next [2 3 4 1 4])
;; (2 3 (- 4 1) 4)
(combine-if-gt-next [2 1 4 1 4 5 1])
;; ((- 2 1) (- 4 1) 4 (- 5 1))
(combine-if-gt-next [5 4 3 2 1])
;; ((- 5 4) (- 3 2) 1)
``````
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Francis thanks for the answer and the explanation on how to generally create the sliding window. I was getting tripped on how to access the f and s elements during recursion. The destructuring does that in a clever manner. Thanks! –  murtaza52 Apr 25 '13 at 4:39
Without destructuring you can accomplish the same with `first`, `second`, and `nnext` (note two "n"s). E.g., `(fn combine-if-gt-next [seq-arg] (let [f (first seq-arg) s (second seq-arg) r (nnext seq-arg)] FUNC-BODY))`. –  Francis Avila Apr 25 '13 at 13:45
thats cool thanks! –  murtaza52 Apr 26 '13 at 4:42

partition and partition-all let you convert a sequence into batches of elements, using `(partition 2 1 data)` lets you iterate over a sliding window of pairs.

``````(def data '(2 3 1 4))

(loop [res [] pairs (partition-all 2 1 data)]
(if-let [[l r] (first pairs)]
(if (and r (< r l))
(recur (conj res ['- l r]) (drop 2 pairs))
(recur (conj res l) (rest pairs)))
res))

;; returns [2 [- 3 1] 4]
``````
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I'm not sure I understood your problem fully but I'll take a stab at it.

First we declare a var to hold your seq:

``````(def myseq '(2 3 1 4))
``````

Then, we can zip the same sequence together, but at different starting points. That way we easily gain access to the previous element. This would return a seq of seqs, which is why we use `mapcat` to concatenate the results in the one list:

``````(mapcat
(fn [prev curr]
(if (< prev curr)
[`(~'- ~curr ~prev)]
[curr]))
myseq (drop 1 myseq))

;; evaluates to((- 3 2) 1 (- 4 1))
``````

Or if you're after my second proposed output:

``````(mapcat
(fn [prev curr]
(if (< prev curr)
[`(~'- ~curr ~prev)]
[]))
myseq (drop 1 myseq))

;; evaluates to ((- 3 2) (- 4 1))
``````

Hope this helps.

UPDATE:

Ok, this gives you the output you want:

``````(mapcat
(fn [prev curr idx]
(cond
(< curr prev) [`(~'- ~prev ~curr)]
(= (+ idx 2) (count myseq)) [curr]
:else [prev]))
myseq (drop 1 myseq) (range (count myseq)))

;; evaluates to (2 (- 3 1) 4)
``````

Hope this is what you're after.

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+1 for the answer. Yours is a very clever answer, and thanks for it. I used the one from Francis as it was near what I already had. –  murtaza52 Apr 25 '13 at 4:42
also +1 for all your comments as I really liked ur ans. Thanks ! –  murtaza52 Apr 25 '13 at 4:45
no problems. Glad it got the solutions flowing. –  leonardoborges Apr 25 '13 at 6:51

Does this solve what you need:

``````(defn my-fun [[f s & r]]
(let [[flip next] (cond (and (nil? f) (nil? s)) ['() r]
(nil? f) [(list s) r]
(nil? s) [(list f) r]
(< s f) [(list (list (- f) s)) r]
:else [(list f) (cons s r)])]
(if (nil? r)
(concat flip next)
(concat flip (my-fun next)))))

(my-fun '(2 3 1 4))
=> (2 (-3 1) 4)
(my-fun '(6 3 5 4))
=> ((-6 3) (-5 4))
``````
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