# a recursive Fibonacci function in Clojure

I'm a newcomer to clojure who wanted to see what all the fuss is about. Figuring the best way to get a feel for it is to write some simple code, I thought I'd start with a Fibonacci function.

My first effort was:

``````(defn fib [x, n]
(if (< (count x) n)
(fib (conj x (+ (last x) (nth x (- (count x) 2)))) n)
x))
``````

To use this I need to seed x with [0 1] when calling the function. My question is, without wrapping it in a separate function, is it possible to write a single function that only takes the number of elements to return?

Doing some reading around led me to some better ways of achieving the same funcionality:

``````(defn fib2 [n]
(loop [ x [0 1]]
(if (< (count x) n)
(recur (conj x (+ (last x) (nth x (- (count x) 2)))))
x)))
``````

and

``````(defn fib3 [n]
(take n
(map first (iterate (fn [[a b]] [b (+ a b)]) [0 1]))))
``````

Anyway, more for the sake of the exercise than anything else, can anyone help me with a better version of a purely recursive Fibonacci function? Or perhaps share a better/different function?

• fib3 is the most Clojure'ish of these – Arthur Ulfeldt Jan 20 '12 at 19:09

``````(defn fib
([n]
(fib [0 1] n))
([x, n]
(if (< (count x) n)
(fib (conj x (+ (last x) (nth x (- (count x) 2)))) n)
x)))
``````

This type of function definition is called multi-arity function definition. You can learn more about it here: http://clojure.org/functional_programming

As for a better Fib function, I think your fib3 function is quite awesome and shows off a lot of functional programming concepts.

• If I've understood correctly, looks like a fancy name for an overloaded function. Works great, thanks. – richc Jan 20 '12 at 13:01
• "Multi-arity" is more specific than "overloaded." "Multi-arity" means "distinguished by the number of arguments," whereas "overloaded" typically means "distinguished by the number or type of the arguments." So multi-arity is a subset of overloading methods. – Craig Stuntz Jan 20 '12 at 13:58
• How can we write an immutable version without recursion? – Dinesh Sep 15 '14 at 4:10

This is fast and cool:

``````(def fib (lazy-cat [0 1] (map + fib (rest fib))))
``````
• Thanks nickik, difficult to understand but very interesting. – richc Jan 21 '12 at 0:08
• (def fib (lazy-cat [0 1] (map + fib (rest fib)))) and (take 5 fib) will return the first 5 terms. Again I'm struggling to write this as one function: (defn fib ([n] (take n fib)) ([] (lazy-cat [0 1] (map + fib (rest fib))))) doesn't work. – richc Jan 21 '12 at 0:18
• If the difficulty of understanding those 5 lines of code (I'm talking about the tree algorithm) doesn't raise any red flags about this language to you.... also, can you count the number of allocations in that code? It's pretty damn high. Just because run time scales linearly it doesn't mean it's fast. – U Mad Jan 22 '12 at 15:36
• @richc It's originally defined as a var, but you changed it to a function. So you have to change all your uses of `fib` to `(fib)` in your implementations. – Dax Fohl Oct 15 '15 at 18:36

In Clojure it's actually advisable to avoid recursion and instead use the `loop` and `recur` special forms. This turns what looks like a recursive process into an iterative one, avoiding stack overflows and improving performance.

Here's an example of how you'd implement a Fibonacci sequence with this technique:

``````(defn fib [n]
(loop [fib-nums [0 1]]
(if (>= (count fib-nums) n)
(subvec fib-nums 0 n)
(let [[n1 n2] (reverse fib-nums)]
(recur (conj fib-nums (+ n1 n2)))))))
``````

The `loop` construct takes a series of bindings, which provide initial values, and one or more body forms. In any of these body forms, a call to `recur` will cause the loop to be called recursively with the provided arguments.

You can use the thrush operator to clean up #3 a bit (depending on who you ask; some people love this style, some hate it; I'm just pointing out it's an option):

``````(defn fib [n]
(->> [0 1]
(iterate (fn [[a b]] [b (+ a b)]))
(map first)
(take n)))
``````

That said, I'd probably extract the `(take n)` and just have the `fib` function be a lazy infinite sequence.

``````(def fib
(->> [0 1]
(iterate (fn [[a b]] [b (+ a b)]))
(map first)))

;;usage
(take 10 fib)
;;output (0 1 1 2 3 5 8 13 21 34)
(nth fib 9)
;; output  34
``````

A good recursive definition is:

``````(def fib
(memoize
(fn [x]
(if (< x 2) 1
(+ (fib (dec (dec x))) (fib (dec x)))))))
``````

This will return a specific term. Expanding this to return first n terms is trivial:

``````(take n (map fib (iterate inc 0)))
``````

For latecomers. Accepted answer is a slightly complicated expression of this:

``````(defn fib
([n]
(fib [0 1] n))
([x, n]
(if (< (count x) n)
(recur (conj x (apply + (take-last 2 x))) n)
x)))
``````

For what it's worth, lo these years hence, here's my solution to 4Closure Problem #26: Fibonacci Sequence

``````(fn [x]
(loop [i '(1 1)]
(if (= x (count i))
(reverse i)
(recur
(conj i (apply + (take 2 i)))))))
``````

I don't, by any means, think this is the optimal or most idiomatic approach. The whole reason I'm going through the exercises at 4Clojure ... and mulling over code examples from Rosetta Code is to learn .

Incidentally I'm well aware that the Fibonacci sequence formally includes 0 ... that this example should `loop [i '(1 0)]` ... but that wouldn't match their spec. nor pass their unit tests despite how they've labelled this exercise. It is written as an anonymous recursive function in order to conform to the requirements for the 4Clojure exercises ... where you have to "fill in the blank" within a given expression. (I'm finding the whole notion of anonymous recursion to be a bit of a mind bender; I get that the `(loop ... (recur ...` special form is constrained to ... but it's still a weird syntax to me).

I'll take @[Arthur Ulfeldt]'s comment, regarding fib3 in the original posting, under consideration as well. I've only used Clojure's `iterate` once, so far.

• FWIW: (fn [n] (take n (map first (iterate (fn [[a b]] [b (+ a b)]) '(1 1))))) ... works for the 4Clojure form of this problem as well. – Jim Dennis Jul 11 '15 at 23:15

Here is the shortest recursive function I've come up with for computing the nth Fibonacci number:

``````(defn fib-nth [n] (if (< n 2)
n
(+ (fib-nth (- n 1)) (fib-nth (- n 2)))))
``````

However, the solution with loop/recursion should be faster for all but the first few values of 'n' since Clojure does tail-end optimization on loop/recur.