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# Can a Fibonacci function be written to execute in O(1) time?

So, we see a lot of fibonacci questions. I, personally, hate them. A lot. More than a lot. I thought it'd be neat if maybe we could make it impossible for anyone to ever use it as an interview question again. Let's see how close to O(1) we can get fibonacci.

Here's my kick off, pretty much crib'd from Wikipedia, with of course plenty of headroom. Importantly, this solution will detonate for any particularly large fib, and it contains a relatively naive use of the power function, which places it at O(log(n)) at worst, if your libraries aren't good. I suspect we can get rid of the power function, or at least specialize it. Anyone up for helping? Is there a true O(1) solution, other than the finite* solution of using a look-up table?

#include <iostream>
#include <math.h>
using namespace std; // would never normally do this.

int main()
{
int target = 10;
cin >> target;
// should be close enough for anything that won't make us explode anyway.
float mangle = 2.23607610;

float manglemore = mangle;
++manglemore; manglemore = manglemore / 2;
manglemore = pow(manglemore, target);
manglemore = manglemore/mangle;
manglemore += .5;
cout << floor(manglemore);

}

*I know, I know, it's enough for any of the zero practical uses fibonacci has.

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That relies on the power function, which is not O(c). My example is actually that algorithm. Which is mentioned. In my question. – Jake Kurzer May 17 '11 at 21:41
Seems like the biggest problem is the pow function as it is imprecise. perhaps one could split it in such a way that any error would be less than 1/2 and then round? then repeat? (using the one line of math way to get the nth fibonacci) – soandos May 17 '11 at 21:42
Sure - just use a lookup table - there's aren't that many Fibonacci numbers between 1 and FLT_MAX. ;-) – Paul R May 17 '11 at 21:46
I'll make it O(1)... O(c) is constant time, used to indicate that it may not be a single op. Doesn't look to be standard though, so... – Jake Kurzer May 17 '11 at 22:28
If you want a simple check, the last digits of the fibbonacci sequence form a pattern (base 16 repeats every 24, base 32 repeats every 48, base 64 repeats every 96 etc) you can use that to do a more accurate rounding. – soandos May 17 '11 at 22:42

Given arbitrary large inputs, simply reading in n takes O(log n), so in that sense no constant time algorithm is possible. So, use the closed form solution, or precompute the values you care about, to get reasonable performance.

Edit: In comments it was pointed out that it is actually worse, because fibonacci is O(phi^n) printing the result of Fibonacci is O(log (phi^n)) which is O(n)!

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It'll do for now, I guess. Feels a bit limp to just fob it off though. – Jake Kurzer May 19 '11 at 5:04
Actually it is even worse than this... True, reading the input is O(log n). But printing (or even storing) the output is O(n), no matter what number base you use. (The output value is O(phi^n), which requires O(n) digits to represent.) – Nemo Aug 2 '11 at 15:17

Here is a near O(1) solution for a Fibonacci sequence term. Admittedly, O(log n) depending on the system Math.pow() implementation, but it is Fibonacci w/o a visible loop, if your interviewer is looking for that. The ceil() was due to rounding precision on larger values returning .9 repeating.

Example in JS:

function fib (n) {
var A=(1+Math.sqrt(5))/2,
B=(1-Math.sqrt(5))/2,
fib = (Math.pow(A,n) - Math.pow(B,n)) / Math.sqrt(5);
return Math.ceil(fib);
}
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Nice. Works for n <= 1474. Above that result becomes infinity. – user31389 Dec 18 '15 at 11:11
Thanks for this; I was looking for code for this algorithm to add to a demonstration for a course. However, we use Java (1.8) and a direct translation of this made sample values such as 10, 20, 40, 45, 50 come out 1 too large. Removing that .ceil() call fixed it. – David Brown Mar 20 at 0:11

The following answer executes in O(1), though I am not sure whether it is qualified for you question. It is called Template Meta-Programming.

#include <iostream>
using namespace std;

template <int N>
class Fibonacci
{
public:
enum {
value = Fibonacci<N - 1>::value + Fibonacci<N - 2>::value
};
};

template <>
class Fibonacci<0>
{
public:
enum {
value = 0
};
};

template <>
class Fibonacci<1>
{
public:
enum {
value = 1
};
};

int main()
{
cout << Fibonacci<50>::value << endl;
return 0;
}
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To nitpick, this executes at compile time, where it does not take constant time. – hammar May 18 '11 at 2:46
@hammar, you cannot deny that it executes at O(1). It does not compile at O(1) is another story. – Dante is not a Geek May 18 '11 at 2:53
My point is that this is a meta-program, and meta-programs execute at compile-time. At run-time this just displays a constant, which is indeed O(1). – hammar May 18 '11 at 2:55
It's still very clever, even if it's not perfect for our purposes. – Jake Kurzer May 18 '11 at 3:15
I would say nice creativity :-D – NirmalGeo May 18 '11 at 9:49

In Programming: The Derivation of Algorithms, Anne Kaldewaij expands out the linear algebra solution to get (translated and refactored from the programming language used in that book):

template <typename Int_t> Int_t fib(Int_t n)
{
Int_t a(0), b(1), x(0), y(1), t0, t1;
while (n != 0) {
switch(n % Int_t(2)) {
case Int_t(1):
t0 = a * x + b * y;
t1 = b * x + a * y + b * y;
x = t0;
y = t1;
--n;
continue;
default:
t0 = a * a + b * b;
t1 = 2 * a * b + b * b;
a = t0;
b = t1;
n /= 2;
continue;
}
}
return x;
}

This has O(log n) complexity. That's not constant, of course, but I think it's worth adding to the discussion, especially given that it only uses relatively fast integer operations and has no possibility of rounding error.

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Yes. Precalculate the values, and store in an array, then use N to do a lookup.

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I did mention a look-up table. – Jake Kurzer May 17 '11 at 22:32

Pick some largest value to handle. For any larger value, raise an error. For any smaller value than that, just store the answer at that smaller value, and keep running the calculation for the "largest" value, and return the stored value.

After all, O(1) specifically means "constant", not "fast". With this method, all calculations will take the same amount of time.

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