# Fibonacci's Closed-form expression in Haskell

How would the Fibonacci's closed form code look like in haskell?

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Choose a language already; you really expect one answer to give code for all of those? –  ildjarn May 17 '11 at 22:07
Just write it yourself. The expression's given right there... do you really need other people to work for you? –  erjiang May 17 '11 at 22:08
The formula involves exponentiation, subtraction, and division. Can you please be more specific about which part of that you are having trouble with? –  Rob Kennedy May 17 '11 at 22:08
Seeing as you now narrowed this down to a specific language, I can live with that. –  Jeff Mercado May 17 '11 at 22:16
I've just verified, and a direct implementation using doubles gives correct (exact) answers to n=70. I'm voting to re-open hoping to see a discussion around whether Binet's formula can be used to get exact answers for n>70. –  NPE May 17 '11 at 22:19

Trivially, Binet's formula, from the Haskell wiki page is given in Haskell as:

``````fib n = round \$ phi ^ n / sq5
where
sq5 = sqrt 5
phi = (1 + sq5) / 2
``````

Which includes sharing of the result of the square root. For example:

``````*Main> fib 1000
4346655768693891486263750038675
5014010958388901725051132915256
4761122929200525397202952340604
5745805780073202508613097599871
6977051839168242483814062805283
3118210513272735180508820756626
59534523370463746326528
``````

For arbitrary integers, you'll need to be a bit more careful about the conversion to floating point values. Note that Binet's value differs from the recursive formula by quite a bit at this point:

``````*Main> let fibs = 0 : 1 : zipWith (+) fibs (tail fibs)
*Main> fibs !!   1000
4346655768693745643568852767504
0625802564660517371780402481729
0895365554179490518904038798400
7925516929592259308032263477520
9689623239873322471161642996440
9065331879382989696499285160037
04476137795166849228875
``````

You may need more precision :-)

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Here's a straightforward translation of the formula to Haskell:

``````fib n = round \$ (phi^n - (1 - phi)^n) / sqrt 5
where phi = (1 + sqrt 5) / 2
``````

This gives correct values only up to `n = 75`, because it uses `Double` precision floating-point arithmetic.

However, we can avoid floating-point arithmetic by working with numbers of the form `a + b * sqrt 5`! Let's make a data type for them:

``````data Ext = Ext !Integer !Integer
deriving (Eq, Show)

instance Num Ext where
fromInteger a = Ext a 0
negate (Ext a b) = Ext (-a) (-b)
(Ext a b) + (Ext c d) = Ext (a+c) (b+d)
(Ext a b) * (Ext c d) = Ext (a*c + 5*b*d) (a*d + b*c) -- easy to work out on paper
-- remaining instance methods are not needed
``````

We get exponentiation for free since it is implemented in terms of the `Num` methods. Now, we have to rearrange the formula slightly to use this.

``````fib n = divide \$ twoPhi^n - (2-twoPhi)^n
where twoPhi = Ext 1 1
divide (Ext 0 b) = b `div` 2^n -- effectively divides by 2^n * sqrt 5
``````

Daniel Fischer points out that we can use the formula `phi^n = fib(n-1) + fib(n)*phi` and work with numbers of the form `a + b * phi` (i.e. ℤ[φ]). This avoids the clumsy division step, and uses only one exponentiation. This gives a much nicer implementation:

``````data ZPhi = ZPhi !Integer !Integer
deriving (Eq, Show)

instance Num ZPhi where
fromInteger n = ZPhi n 0
negate (ZPhi a b) = ZPhi (-a) (-b)
(ZPhi a b) + (ZPhi c d) = ZPhi (a+c) (b+d)
(ZPhi a b) * (ZPhi c d) = ZPhi (a*c+b*d) (a*d+b*c+b*d)

fib n = let ZPhi _ x = phi^n in x
where phi = ZPhi 0 1
``````
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+1 for the algebraic number field idea –  Thies Heidecke May 18 '11 at 0:27
Yes, hurray for ℤ[√5] :) –  ephemient May 18 '11 at 1:04
As a side note: this comes pre-defined in Math.Algebra.Field.Extension (most of which I don't understand, but I used it successfully for this problem) –  sleepyMonad May 18 '11 at 18:46
Wow, this is so good! –  Charles Durham Jun 13 '11 at 3:13
What you need for this is `Z[(1+sqrt 5)/2]`, the ring of algebraic integers in `Q[sqrt 5]`. Nice is, with `phi = (1+sqrt 5)/2`, we have `phi^n = fib(n-1) + fib(n)*phi`. –  Daniel Fischer Nov 20 '11 at 1:24