Here's one way of doing it that gives you a bit of exposure to lazy sequences, although it's certainly not really an optimal way of computing the Fibonacci sequence.

Given the definition of the Fibonacci sequence, we can see that it's built up by repeatedly applying the same rule to the base case of `'(1 1)`

. The Clojure function `iterate`

sounds like it would be good for this:

```
user> (doc iterate)
-------------------------
clojure.core/iterate
([f x])
Returns a lazy sequence of x, (f x), (f (f x)) etc. f must be free of side-effects
```

So for our function we'd want something that takes the values we've computed so far, sums the two most recent, and returns a list of the new value and all the old values.

```
(fn [[x y & _ :as all]] (cons (+ x y) all))
```

The argument list here just means that `x`

and `y`

will be bound to the first two values from the list passed as the function's argument, a list containing all arguments after the first two will be bound to `_`

, and the original list passed as an argument to the function can be referred to via `all`

.

Now, `iterate`

will return an infinite sequence of intermediate values, so for our case we'll want to wrap it in something that'll just return the value we're interested in; lazy evaluation will stop the entire infinite sequence being evaluated.

```
(defn fib [n]
(nth (iterate (fn [[x y & _ :as all]] (cons (+ x y) all)) '(1 1)) (- n 2)))
```

Note also that this returns the result in the opposite order to your implementation; it's a simple matter to fix this with `reverse`

of course.

Edit: or indeed, as amalloy says, by using vectors:

```
(defn fib [n]
(nth (iterate (fn [all]
(conj all (->> all (take-last 2) (apply +)))) [1 1])
(- n 2)))
```