# Lazy sequence using loop/recur?

I'd like to write an implementation to an algorithm that produces an infinite sequence of results, where each element represents the calculation of a single iteration of the algorithm. Using a lazy sequence is convenient, as it decouples the logic of the number of iterations (by using `take`) and burn-in iterations (by using `drop`) from the implementation.

Here's an example of two algorithm implementations, one that produces a lazy sequence (`yadda-lazy`), and one that does not (`yadda-loop`).

``````(defn yadda-iter
[v1 v2 v3]

(+ (first v1)
(first v2)
(first v3)))

[len]

(letfn [(inner [v1 v2 v3]
(lazy-seq (inner (rest v1)
(rest v2)
(rest v3)))))]
(let [base (cycle (range len))]
(inner base
(map #(* %1 %1) base)
(map #(* %1 %1 %1) base)))))

[len iters]

(let [base (cycle (range len))]
(loop [result nil
i 0
v1 base
v2 (map #(* %1 %1) base)
v3 (map #(* %1 %1 %1) base)]
(if (= i iters)
result
(recur (cons (yadda-iter v1 v2 v3) result)
(inc i)
(rest v1)
(rest v2)
(rest v3))))))

``````

Is there a way to create a lazy sequence using the same style as `loop`/`recur`? I like `yadda-loop` better, because:

• It's more obvious what the initial conditions are and how the algorithm progresses to the next iteration.
• It won't suffer from a stack overflow due to tail optimization.
• Lazy sequences won't overflow the stack anyway. In order to overflow the stack, you need to keep building up stack frames, whereas a lazy sequence just returns a sequence with the current item in the head and a thunk for the tail. In other words, the first call to `inner` will return before the next call occurs, so the stack stays at a constant depth. – Chuck Feb 11 '14 at 20:42
• You won't get a stack overflow error, but you can get an `OutOfMemoryError` if you hang onto the head (you'll overflow the memory, not the stack). – omiel Feb 11 '14 at 22:55

Your loop version would be better written to (1) pull the addition out of the loop so you don't have to recur on so many sequences, and (2) use `conj` on a vector accumulator so your results are in the same order as your `yadda-lazy`.

``````(defn yadda-loop-2 [len iters]
(let [v1 (cycle (range len))
v2 (map * v1 v1)
v3 (map * v1 v2)
s (map + v1 v2 v3)]
(loop [result [], s s, i 0]
(if (= i iters)
result
(recur (conj result (first s)), (rest s), (inc i))))))
``````

However, at this point it becomes clear that the loop is pointless as this is just

``````(defn yadda-loop-3 [len iters]
(let [v1 (cycle (range len))
v2 (map * v1 v1)
v3 (map * v1 v2)
s (map + v1 v2 v3)]
(into [] (take iters s))))
``````

and we might as well pull out the `iters` parameter, return simply `s` and `take` from it.

``````(defn yadda-yadda [len]
(let [v1 (cycle (range len))
v2 (map * v1 v1)
v3 (map * v1 v2)]
(map + v1 v2 v3)))
``````

This produces the same results as your `yadda-lazy`, is also lazy, and is quite clear

``````(take 11 (yadda-yadda 4)) ;=> (0 3 14 39 0 3 14 39 0 3 14)
``````

You could also, equivalently

``````(defn yadda-yadda [len]
(as-> (range len) s
(cycle s)
(take 3 (iterate (partial map * s) s))
(apply map + s)))
``````

If you are looking for a pattern for converting an eager loop like yours to a lazy-sequence

1. `(loop [acc [] args args] ...)` -> `((fn step [args] ...) args)`
2. `(if condition (recur ...) acc)` -> `(when condition (lazy-seq ...)`
3. `(recur (conj acc (f ...)) ...)` -> `(lazy-seq (cons (f ...) (step ...)))`

Applying this to your `yadda-lazy`

``````(defn yadda-lazy-2 [len iters]
(let [base (cycle (range len))]
((fn step [i, v1, v2, v3]
(when (< i iters)
(lazy-seq
(step (inc i), (rest v1), (rest v2), (rest v3))))))
0, base, (map #(* %1 %1) base), (map #(* %1 %1 %1) base))))
``````

And at this point you'd probably want to pull out the `iters`

``````(defn yadda-lazy-3 [len]
(let [base (cycle (range len))]
((fn step [v1, v2, v3]
(lazy-seq
(step (rest v1), (rest v2), (rest v3)))))
base, (map #(* %1 %1) base), (map #(* %1 %1 %1) base))))
``````

So you can

``````(take 11 (yadda-lazy-3 4)) ;=> (0 3 14 39 0 3 14 39 0 3 14)
``````

And then you might say, hey, my `yadda-iter` is just applying `+` on the first and `step` is applied on the rest, so why not combine my `v1, v2, v3` and make this a bit clearer?

``````(defn yadda-lazy-4 [len]
(let [base (cycle (range len))]
((fn step [vs]
(lazy-seq
(cons (apply + (map first vs))
(step (map rest vs)))))
[base, (map #(* %1 %1) base), (map #(* %1 %1 %1) base)])))
``````

And lo and behold, you have just re-implemented variadic map

``````(defn yadda-lazy-5 [len]
(let [base (cycle (range len))]
(map + base, (map #(* %1 %1) base), (map #(* %1 %1 %1) base))))
``````
• This doesn't really answer my question. But your code inspired me to re-code the implementation using `iterate` and `map` instead of using `lazy-seq` and `cons`. Part of the problem was that I was co-recurring over several items (`v1`, `v2`, `v3`), and it wasn't immediately obvious how to do so with `iterate`, since `iterate` only allows one element. That was solved by wrapping all co-recurring elements in a vector and deconstructing it to get the individual co-recurring elements back from the vector. – Samad Lotia Feb 12 '14 at 22:24
• @SamadLotia I'm not sure I understood your question then, but see the addendum I just edited in. – A. Webb Feb 13 '14 at 2:38

@A.Webb's answer is perfect, but if your love for `loop`/`recur` overcomes his arguments, know that you can still combine both styles of recursion.

For example, take a look at the implementation of `range`:

``````(defn range
(...)
([start end step]
(lazy-seq
(let [b (chunk-buffer 32)
comp (cond (or (zero? step) (= start end)) not=
(pos? step) <
(neg? step) >)]
(loop [i start]                        ;; chunk building through loop/recur
(if (and (< (count b) 32)
(comp i end))
(do
(chunk-append b i)
(recur (+ i step)))
(chunk-cons (chunk b)
(when (comp i end)
(range i end step))))))))) ;; lazy recursive call
``````

Here's another example, an alternate implementation of `filter`:

``````(defn filter [pred coll]
(letfn [(step [pred coll]
(when-let [[x & more] (seq coll)]
(if (pred x)
(cons x (lazy-seq (step pred more))) ;; lazy recursive call
(recur pred more))))]                ;; eager recursive call
(lazy-seq (step pred coll))))
``````
• I did look at the code for `range` and `filter`. Indeed, my solution for a lazy sequence (`yadda-lazy`) follows the form of `filter`, which is precisely what I was trying to avoid. `range` just looks way too complicated to replicate. – Samad Lotia Feb 12 '14 at 22:25
• I agree, `range` is a mouthful. But I don't understand why you prefer the `loop`/`recur` style. From the issues you mentioned, the stack overflow risk has been addressed ; and I don't see how the initial conditions are more obvious - is it that they are introduced first ? – omiel Feb 13 '14 at 4:19

The Tupelo library has a new `lazy-gen`/`yield` feature that mimics `generator functions` in Python. It can generate a lazy sequence from any point in a looping structure. Here is version of `yadda-loop` that shows `lazy-gen` & `yield` in action:

``````(ns tst.xyz
(:use clojure.test tupelo.test)
(:require [tupelo.core :as t] ))

[len iters]
(t/lazy-gen
(let [base (cycle (range len))]
(loop [i      0
v1     base
v2     (map #(* %1 %1) base)
v3     (map #(* %1 %1 %1) base)]
(when (< i iters)
(recur
(inc i)
(rest v1)
(rest v2)
(rest v3)))))))

Testing tst.clj.core
(take 11 (yadda-lazy 4))  => (0 3 14 39 0 3 14 39 0 3 14)
(yadda-loop 4 11)         => (0 3 14 39 0 3 14 39 0 3 14)
(yadda-lazy-gen 4 11)     => (0 3 14 39 0 3 14 39 0 3 14)

Ran 1 tests containing 1 assertions.
0 failures, 0 errors.
``````