# In clojure how to lazilly calculate several sub sequences out of a big lazy sequence?

In clojure, I would like to calculate several subvectors out of a big lazy sequence (maybe an infinite one). The naive way would be to transform the lazy sequence into a vector and then to calculate the subvectors. But when doing that, I am losing the laziness.

I have a big sequence `big-sequence` and `positions`, a list of start and end positions. I would like to do the following calculation but lazilly:

``````(let [positions '((5 7) (8 12) (18 27) (28 37) (44 47))
big-sequence-in-vec (vec big-sequence)]
(map #(subvec big-sequence-in-vec (first %) (second %)) positions))
; ([5 6] [8 9 10 11] [18 19 20 21 22 23 24 25 26] [28 29 30 31 32 33 34 35 36] [44 45 46])
``````

Is it feasible?

Remark: If `big-sequence` is infinite, `vec` will never return!

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Is `positions` a fixed list as in your code fragment? If so, you can just use `(vec (take n big-sequence))`, where n = 47 in this case, in your subvec calls. –  Randy Hudson Jun 15 '14 at 13:45
@RandyHudson It will solve the issue with the infinite sequence, but it won't keep the laziness. –  viebel Jun 15 '14 at 13:47
`map` is itself lazy, so if you would like just some of the results, the big sequence would only be realized up to the position that are needed. Also, `take`ing some elements doesn't enforce the realization of the entire sequence. –  schaueho Jun 15 '14 at 14:34
Are the sub-vectors always sorted? They are in the example. I have assumed so in my solution, as @omiel points out. –  Thumbnail Jun 17 '14 at 0:17

## 5 Answers

You are asking for a lazy sequence of sub-vectors of a lazy sequence. We can develop it layer by layer as follows.

``````(defn sub-vectors [spans c]
(let [starts (map first spans)                 ; the start sequence of the spans
finishes (map second spans)              ; the finish sequence of the spans

drops (map - starts (cons 0 starts))                    ; the incremental numbers to drop
takes (map - finishes starts)                           ; the numbers to take

tails (next (reductions (fn [s n] (drop n s)) c drops)) ; the sub-sequences from which the sub-vectors will be taken from the front of
slices (map (comp vec take) takes tails)]               ; the sub-vectors
slices))
``````

For example, given

``````(def positions '((5 7) (8 12) (18 27) (28 37) (44 47)))
``````

we have

``````(sub-vectors positions (range))
; ([5 6] [8 9 10 11] [18 19 20 21 22 23 24 25 26] [28 29 30 31 32 33 34 35 36] [44 45 46])
``````

Both the spans and the basic sequence are treated lazily. Both can be infinite.

For example,

``````(take 10 (sub-vectors (partition 2 (range)) (range)))
; ([0] [2] [4] [6] [8] [10] [12] [14] [16] [18])
``````
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Nice! Note: this assumes that the positions are sorted and (though it is the case in the provided example) I see nothing in the question that implies that. –  omiel Jun 16 '14 at 15:48
@omiel Good point. I have asked the questioner. –  Thumbnail Jun 17 '14 at 0:18
@omiel Judging by OP's solution, the positions need not be sorted, and this solution is invalid. –  Thumbnail Jun 21 '14 at 3:13
Well that's too bad. If the positions are not sorted, you have to keep a reference to the sequence's head. With a big (potentially infinite) sequence and big positions, it's a potential OutOfMemoryError staring you in the face. –  omiel Jun 21 '14 at 20:17
@omiel Too true. Nor does OP's answer or my other attempt help: Even if the big sequence is lazy, more and more of it gets realized (or, in my case, moved to the vector) as bigger positions come along. –  Thumbnail Jun 22 '14 at 6:03

This works out @schauho's suggestion in a form that is faster than @alfredx's solution, even as improved by OP. Unlike my previous solution, it does not assume that the required sub-vectors are sorted.

The basic tool is an eager analogue of split-at:

``````(defn splitv-at [n v tail]
(if (and (pos? n) (seq tail))
(recur (dec n) (conj v (first tail)) (rest tail))
[v tail]))
``````

This removes the first `n` items from `tail`, appending them to vector `v`, returning the new `v` and `tail` as a vector. We use this to capture just as much more of the big sequence in the vector as is necessary to supply each sub-vector as it comes along.

``````(defn sub-spans [spans coll]
(letfn [(sss [spans [v tail]]
(lazy-seq
(when-let [[[from to] & spans-] (seq spans)]
(let [[v- tail- :as pair] (splitv-at (- to (count v)) v tail)]
(cons (subvec v- from to) (sss spans- pair))))))]
(sss spans [[] coll])))
``````

For example

``````(def positions '((8 12) (5 7) (18 27) (28 37) (44 47)))

(sub-spans positions (range))
; ([8 9 10 11] [5 6] [18 19 20 21 22 23 24 25 26] [28 29 30 31 32 33 34 35 36] [44 45 46])
``````
• Since `subvec` works in short constant time, it takes linear time in the amount of the big sequence consumed.
• Unlike my previous solution, it does not forget its head: it keeps all of the observed big sequence in memory.
-
``````(defn pos-pair-to-vec [[start end] big-sequence]
(vec (for [idx (range start end)]
(nth big-sequence idx))))

(let [positions '((5 7) (8 12) (18 27) (28 37) (44 47))
big-seq (range)]
(map #(pos-pair-to-vec % big-seq) positions))
``````
-

You could use `take` on the big sequence with the maximum of the positions. You need to compute the values up to this point anyway to compute the subvectors, so you don't really "lose" anything.

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I am losing something: I have to realize the big lazy sequence upfront and not only when I need it. –  viebel Jun 15 '14 at 14:20

The trick is to write a lazy version of `subvec` using `take` and `drop`:

``````(defn subsequence [coll start end]
(->> (drop start coll)
(take (- end start))))

(let [positions '((5 7) (8 12) (18 27) (28 37) (44 47))
big-sequence (range)]
(map (fn [[start end]]  (subsequence big-sequence start end)) positions))
;((5 6) (8 9 10 11) (18 19 20 21 22 23 24 25 26) (28 29 30 31 32 33 34 35 36) (44 45 46))
``````
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You had better put a `vec` at the end of `sub-sequence`, since your question asks for subvectors. –  Thumbnail Jun 21 '14 at 4:12