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)))
(defn yadda-lazy
[len]
(letfn [(inner [v1 v2 v3]
(cons (yadda-iter 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)))))
(defn yadda-loop
[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))))))
(prn (take 11 (yadda-lazy 4)))
(prn (yadda-loop 4 11))
```

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.

`inner`

will return before the next call occurs, so the stack stays at a constant depth. – Chuck Feb 11 '14 at 20:42`OutOfMemoryError`

if you hang onto the head (you'll overflow the memory, not the stack). – omiel Feb 11 '14 at 22:55