(The following code is written and tested in Racket.)

Start with the naive version:

```
;; fib : nat -> nat
(define (fib n)
(cond [(= n 0) 0]
[(= n 1) 1]
[else (+ (fib (- n 1)) (fib (- n 2)))]))
```

As we develop new versions, we can use `test`

to see if they agree with the initial `fib`

(at least on the numbers 0 through 9).

```
;; test : (nat -> nat) -> boolean
;; Check that the given function agrees with fib on 0 through 9
(define (test f)
(for/and ([i (in-range 10)])
(= (f i) (fib i))))
```

First, the crucial observation that enables everything else is that when we compute `(fib N)`

, we have computed `(fib (- N 1))`

... but we discard it, and so we have to recompute it again later. That's why naive `fib`

is exponential-time! We can do better by keeping it around, say with an auxiliary function that returns a list:

```
;; fib2list : nat -> (list nat nat)
;; (fib2list N) = (list (fib (- N 1)) (fib N))
(define (fib2list n)
(cond [(= n 1) (list 0 1)]
[else (let ([resultN-1 (fib2list (- n 1))])
(let ([fibN-2 (first resultN-1)]
[fibN-1 (second resultN-1)])
(list fibN-1
(+ fibN-2 fibN-1))))]))
;; fib2 : nat -> nat
(define (fib2 n)
(cond [(= n 0) 0]
[else (second (fib2list n))]))
(test fib2) ;; => #t
```

The `fib2list`

function stops at 1, so `fib2`

handles 0 as a special (but uninteresting) case.

We can rewrite this in continuation-passing style (CPS) to make it tail recursive:

```
;; fib3k : nat ((list nat nat) -> nat) -> nat
(define (fib3k n k)
(cond [(= n 1) (k (list 0 1))]
[else (fib3k (- n 1)
(lambda (resultN-1)
(let ([fibN-2 (first resultN-1)]
[fibN-1 (second resultN-1)])
(k (list fibN-1
(+ fibN-2 fibN-1))))))]))
;; fib3 : nat -> nat
(define (fib3 n)
(cond [(= n 0) 0]
[else (fib3k n (lambda (resultN)
(let ([fibN-1 (first resultN)]
[fibN (second resultN)])
fibN)))]))
(test fib3) ;; => #t
```

Now instead of making a non-tail recursive call, `fib3k`

calls itself with an extended continuation that takes a list result. The continuation `k`

of `(fib3k N k)`

is called with a list equivalent to `(list (fib (- N 1)) (fib N))`

. (Thus if the first argument is `(- n 1)`

, the continuation argument is named `resultN-1`

, etc.)

To start everything off, we provide an initial continuation that takes the result `resultN`

; the second element is equal to `(fib N)`

, so we return that.

Of course, there's no reason to keep packaging things up as a list; we can just make the continuation take two arguments:

```
;; fib4k : nat (nat nat -> nat) -> nat
(define (fib4k n k)
(cond [(= n 1) (k 0 1)]
[else (fib4k (- n 1)
(lambda (fibN-2 fibN-1)
(k fibN-1
(+ fibN-2 fibN-1))))]))
;; fib4 : nat -> nat
(define (fib4 n)
(cond [(= n 0) 0]
[else (fib4k n (lambda (fibN-1 fibN) fibN))]))
(test fib4) ;; => #t
```

Notice that there are only two *variants* of continuation in the program---they correspond to the two occurrences of `lambda`

in the code. There's the initial continuation, and there's a single way of extending an existing continuation. Using this observation, we can transform the *continuation functions* into a *context data structure*:

```
;; A context5 is either
;; - (initial-context)
;; - (extend-context context5)
(struct initial-context ())
(struct extend-context (inner))
```

Now we replace the expressions that created *continuation functions* (ie, the `lambda`

s) with uses of the *context constructors*, and we replace the (single) site that applied a continuation function with a new explicit `apply-context5`

function that does the work previously done by the two `lambda`

expressions:

```
;; fib5ctx : nat context5 -> nat
(define (fib5ctx n ctx)
(cond [(= n 1) (apply-context5 ctx 0 1)]
[else (fib5ctx (- n 1)
(extend-context ctx))]))
;; apply-context5 : context5 nat nat -> nat
(define (apply-context5 ctx a b)
(match ctx
[(initial-context)
b]
[(extend-context inner-ctx)
(apply-context5 inner-ctx b (+ a b))]))
;; fib5 : nat -> nat
(define (fib5 n)
(cond [(= n 0) 0]
[else (fib5ctx n (initial-context))]))
(test fib5) ;; => #t
```

(When compilers do this, they call it defunctionalization or closure conversion, and they do it to turn indirect jumps into direct jumps.)

At this point, it's really obvious that the `context`

data type is totally boring. In fact, it's algebraically equivalent to the natural numbers! (A natural number is either zero or the successor of a natural number.) So let's just change the context data type to use natural numbers rather than some heap-allocated structure.

```
;; A context6 is just a natural number.
;; fib6ctx : nat context6 -> nat
(define (fib6ctx n ctx)
(cond [(= n 1) (apply-context6 ctx 0 1)]
[else (fib6ctx (- n 1)
(+ ctx 1))]))
;; apply-context6 : context6 nat nat -> nat
(define (apply-context6 ctx a b)
(cond [(= ctx 0)
b]
[else
(apply-context6 (- ctx 1) b (+ a b))]))
;; fib6 : nat -> nat
(define (fib6 n)
(cond [(= n 0) 0]
[else (fib6ctx n 0)]))
(test fib6) ;; => #t
```

But now it's obvious that `fib6ctx`

just counts `ctx`

up as it counts `n`

down to 1. In particular:

```
(fib6ctx N M) = (fib6ctx 1 (+ N M -1))
= (apply-context6 (+ N M -1) 0 1)
```

and so

```
(fib6ctx N 0) = (apply-context6 (+ N -1) 0 1)
```

So we can get rid of `fib6ctx`

entirely.

```
;; apply-context7 : nat nat nat -> nat
(define (apply-context7 ctx a b)
(cond [(= ctx 0)
b]
[else
(apply-context7 (- ctx 1) b (+ a b))]))
;; fib7 : nat -> nat
(define (fib7 n)
(cond [(= n 0) 0]
[else (apply-context7 (- n 1) 0 1)]))
(test fib7) ;; => #t
```

And that's the traditional iterative version of Fibonacci, except that `apply-context7`

is usually called `fib-iter`

or something like that, and most versions count up instead of down and hope they get the comparison right so they don't get an off-by-one error.