## A seq "looking into the future"

An example of a funky seq looking into the future might look like this:

```
(def funky-seq
(let [substrate (atom ())]
(letfn [(funk [n] (delay (if (odd? n) n @(nth @substrate (inc n)))))]
(reset! substrate (map funk (range))))
(map deref @substrate)))
user> (take 10 funky-seq)
(1 1 3 3 5 5 7 7 9 9)
```

(A cookie to whoever makes this simpler without breaking it. :-))

Of course if determining the value of an element might involve looking at a "future" element which itself depends on a further element which calls for the computation of a still more distant element..., the catastrophe cannot be helped.

## Euler 14

The fundamental problem with the scheme of "looking into the future" the code from the question attempts to employ aside, this approach doesn't really solve the problem, because, if you decide to start from `1`

*and go upwards*, you need to take branching into account: a `10`

in a Collatz chain might be arrived at through the application of either rule (the `n / 2`

rule applied to `20`

or the `3n + 1`

rule starting from `3`

). Also, if you wish to build your chains upward, you should reverse the rules and either multiply by `2`

or subtract `1`

and divide by `3`

(applying, at each step, that rule which produces an integer -- or possibly both if both do).

Of course you could build a *tree*, rather than a lazy list, but that wouldn't look anything like the code sketch in the question and I'd expect you to end up ultimately memoizing the thing.

The above is to be qualified with the remark that you might have a conjecture as to which "chain building rule" is likely to generate the longest chain starting from `1`

while having the final entry stay below the given limit. If that is the case, you should probably *prove it correct* and then implement it directly (through `loop`

/ `recur`

starting at `1`

); without a proof, you can't really claim to have solved the problem.