# Infinite fibonacci series, take only n from the list, without using mutation?

I'm trying to solve this problem in a pure-functional way, without using `set!`.

I've written a function that calls a given lambda for each number in the fibonacci series, forever.

``````(define (each-fib fn)
(letrec
((next (lambda (a b)
(fn a)
(next b (+ a b)))))
(next 0 1)))
``````

I think this is as succinct as it can be, but if I can shorten this, please enlighten me :)

With a definition like the above, is it possible to write another function that takes the first `n` numbers from the fibonacci series and gives me a list back, but without using variable mutation to track the state (which I understand is not really functional).

The function signature doesn't need to be the same as the following... any approach that will utilize `each-fib` without using `set!` is fine.

``````(take-n-fibs 7) ; (0 1 1 2 3 5 8)
``````

I'm guessing there's some sort of continuations + currying trick I can use, but I keep coming back to wanting to use `set!`, which is what I'm trying to avoid (purely for learning purposes/shifting my thinking to purely functional).

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The more I think about this, the more I'm starting to realize it's impossible, without changing the definition of `each-fib` to take the count. –  d11wtq Jun 24 '12 at 14:25
Indeed `each-fib` has to be changed somehow, but `set!` can be avoided (meaning: no explicit mutation is required) –  Óscar López Jun 24 '12 at 17:50

Try this, implemented using lazy code by means of delayed evaluation:

``````(define (each-fib fn)
(letrec
((next (lambda (a b)
(fn a)
(delay (next b (+ a b))))))
(next 0 1)))

(define (take-n-fibs n fn)
(let loop ((i n)
(promise (each-fib fn)))
(when (positive? i)
(loop (sub1 i) (force promise)))))
``````

As has been mentioned, `each-fib` can be further simplified by using a named `let`:

``````(define (each-fib fn)
(let next ((a 0) (b 1))
(fn a)
(delay (next b (+ a b)))))
``````

Either way, it was necessary to modify `each-fib` a little for using the `delay` primitive, which creates a promise:

A promise encapsulates an expression to be evaluated on demand via `force`. After a promise has been `force`d, every later force of the promise produces the same result.

I can't think of a way to stop the original (unmodified) procedure from iterating indefinitely. But with the above change in place, `take-n-fibs` can keep forcing the lazy evaluation of as many values as needed, and no more.

Also, `take-n-fibs` now receives a function for printing or processing each value in turn, use it like this:

``````(take-n-fibs 10 (lambda (n) (printf "~a " n)))
> 0 1 1 2 3 5 8 13 21 34 55
``````
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I like this solution. –  soegaard Jun 24 '12 at 18:22
This looks great, thanks! –  d11wtq Jun 25 '12 at 10:58

You provide an iteration function over fibonacci elements. If you want, instead of iterating over each element, to accumulate a result, you should use a different primitive that would be a `fold` (or `reduce`) rather than an `iter`.
(It might be possible to use continuations to turn an `iter` into a `fold`, but that will probably be less readable and less efficient that a direct solution using either a `fold` or mutation.)

Note however that using an accumulator updated by mutation is also fine, as long as you understand what you are doing: you are using mutable state locally for convenience, but the function `take-n-fibs` is, seen from the outside, observationally pure, so you do not "contaminate" your program as a whole with side effects.

A quick prototype for `fold-fib`, adapted from your own code. I made an arbitrary choice as to "when stop folding": if the function returns `null`, we return the current accumulator instead of continuing folding.

``````(define (fold-fib init fn) (letrec ([next (lambda (acc a b)
(let ([acc2 (fn acc a)])
(if (null? acc2) acc
(next acc2 b (+ a b)))))])
(next init 0 1)))

(reverse (fold-fib '() (lambda (acc n) (if (> n 10) null (cons n acc)))))
``````

It would be better to have a more robust convention to end folding.

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I have written few variants. First you ask if

``````(define (each-fib fn)
(letrec
((next (lambda (a b)
(fn a)
(next b (+ a b)))))
(next 0 1)))
``````

can be written any shorter. The pattern is used so often that special syntax called `named let` has been introduced. Your function looks like this using a named let:

``````(define (each-fib fn)
(let next ([a 0] [b 1])
(fn a)
(next b (+ a b))))
``````

In order to get the control flowing from one function to another, one can in languages with supports TCO use continuation passing style. Each function gets an extra argument often called k (for continuation). The function k represents what-to-do-next.

Using this style, one can write your program as follows:

``````(define (generate-fibs k)
(let next ([a 0] [b 1] [k k])
(k a (lambda (k1)
(next b (+ a b) k1)))))

(define (count-down n k)
(let loop ([n n] [fibs '()] [next generate-fibs])
(if (zero? n)
(k fibs)
(next (λ (a next)
(loop (- n 1) (cons a fibs) next))))))

(count-down 5 values)
``````

Now it is a bit annoying to write in style manually, so it could be convenient to introduce the co-routines. Breaking your rule of not using `set!` I have chosen to use a shared variable `fibs` in which `generate-fibs` repeatedly conses new fibonacci numbers onto. The `count-down` routine merely read the values, when the count down is over.

``````(define (make-coroutine co-body)
(letrec ([state (lambda () (co-body resume))]
[resume (lambda (other)
(call/cc (lambda (here)
(set! state here)
(other))))])
(lambda ()
(state))))

(define fibs '())

(define generate-fib
(make-coroutine
(lambda (resume)
(let next ([a 0] [b 1])
(set! fibs (cons a fibs))
(resume count-down)
(next b (+ a b))))))

(define count-down
(make-coroutine
(lambda (resume)
(let loop ([n 10])
(if (zero? n)
fibs
(begin
(resume generate-fib)
(loop (- n 1))))))))

(count-down)
``````

And a bonus you get a version with communicating threads:

``````#lang racket
(letrec ([result #f]
[count-down
(λ ()
(let loop ([n 10] [fibs '()])
(if (zero? n)
(set! result fibs)

[produce-fibs
(λ ()
(let next ([a 0] [b 1])
(next b (+ a b))))))])
result)
``````

The thread version is Racket specific, the others ought to run anywhere.

-

Building a list would be hard. But displaying the results can still be done (in a very bad fashion)

``````#lang racket

(define (each-fib fn)
(letrec
((next (lambda (a b)
(fn a)
(next b (+ a b)))))
(next 0 1)))

(define (take-n-fibs n fn)
(let/cc k
(begin
(each-fib (lambda (x)
(if (= x (fib (+ n 1)))
(k (void))
(begin
(display (fn x))
(newline))))))))

(define fib
(lambda (n)
(letrec ((f
(lambda (i a b)
(if (<= n i)
a
(f (+ i 1) b (+ a b))))))
(f 1 0 1))))
``````

Notice that i am using the regular fibonacci function as an escape (like i said, in a very bad fashion). I guess nobody will recommend programming like this.

Anyway

``````(take-n-fibs 7 (lambda (x) (* x x)))
0
1
1
4
9
25
64
``````
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