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A continued fraction is a series of divisions of this kind:

depth   1    1+1/s

depth   2    1+1/(1+1/s)

depth   3    1+1/(1+1/(1+1/s))
  .     .      .           
  .     .      .      
  .     .      . 

The depth is an integer, but s is a floating point number.

What would be an optimal algorithm (performance-wise) to calculate the result for such a fraction with large depth?

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this is not homework because my school is closed last july ,now I am sitting in my home and I am just trying to solve some problem – user319824 Jul 24 '10 at 19:00
Since you will most likely want to solve this yourself, for best learning effect, I think it is good to treat this question as if it were homework. – Svante Jul 24 '10 at 19:10
up vote 5 down vote accepted

Hint: unroll each of these formulas using basic algebra. You will see a pattern emerge.

I'll show you the first steps so it becomes obvious:

f(2,s) = 1+1/s = (s+1)/s
f(3,s) = 1+1/f(2,s) = 1+(s/(s+1)) = (1*(s+1) + s)/(s+1) = (2*s + 1) / (s + 1)
         /* You multiply the first "1" by denominator */
f(4,s) = 1+1/f(3,s) = 1+(s+1)/(2s+1) = (1*(2*s+1) + (s+1))/(2*s+1) = (3*s + 2) / (2*s + 1)
f(5,s) = 1+1/f(4,s) = 1+(2s+1)/(3s+2) = (1*(3*s+2) + (2s+1))/(3*s+2) = (5*s + 3) / (3*s + 2)


Hint2: if you don't see the obvious pattern emerging form the above, the most optimal algorithm would involve calculating Fibonacci numbers (so you'd need to google for optimal Fibonacci # generator).

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NOTE: not having learn basic algebra in English, I hope I didn't mix up "denominator" and "nominator" in the comment above - hope the formulas are obvious enough for themselves even if I did mix up the terminology. – DVK Jul 24 '10 at 19:16
No, I believe you have it correct. The Numerator is the number on "top" of the division, and the denominator is on the "bottom". IE, 2/3 -> Numerator = 2; Denominator = 3 – Daenyth Jul 25 '10 at 19:50
@Daenyth - Thx! – DVK Jul 25 '10 at 21:03

Smells like tail recursion(recursion(recursion(...))).

(In other words - loop it!)

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Generally C doesn't support tail recursion. – James Black Jul 24 '10 at 18:48
@James Black But any recursive algorithm can be unrolled :-) It doesn't change the run-time complexity. (I'm not arguing for this to be a good answer for "optimal" algorithm.) – user166390 Jul 24 '10 at 18:50
@James Black: As @pst mentions, I'm advocating transforming the tail recursive problem (at the conceptual level) into a loop (at the code level) which is provably a rather trivial process. That's where my "loop it" comment comes in, although I suppose it could have been clearer. – Chris Tonkinson Jul 24 '10 at 18:56
@Chris - I just didn't want him to start looking at tail-recursion as a possible solution, given the language he is using. But looping it is probably the best option. – James Black Jul 24 '10 at 18:58
@James Black: Most modern C compilers can do tail-recursion optimizations just fine, and will even transform your non-tail-recursive code into a tail-recursive form in some circumstances. – Stephen Canon Jul 25 '10 at 16:58

I would start with calculating 1/s, which we will call a.

Then use a for-loop, as, if you use recursion, in C, you may experience a stack overflow.

Since this is homework I won't give much code, but, if you start with a simple loop, of 1, then keep increasing it, until you get to 4, then you can just go to n times.

Since you are always going to be dividing 1/s and division is expensive, just doing it one time will help with performance.

I expect that if you work it out that you can actually find a pattern that will help you to further optimize.

You may find an article such as this:, to be helpful.

I am assuming by performance-wise you mean that you want it to be fast, regardless of memory used, btw.

You may find that if you cache the values that you calculated, at each step, that you can reuse them, rather than redoing an expensive calculation.

I personally would do 4-5 steps by hand, writing out the equations and results of each step, and see if any pattern emerges.


GCC has added tail recursion, and I never noticed it, since I try to limit recursion heavily in C, from habit. But this answer has a nice quick explanation of different optimizations gcc did based on the optimization level.

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your algorithms is decidedly NOT the most optimal, though it is the most optimal implementation of that particular algorithm. – DVK Jul 24 '10 at 19:09
@DVK - I am not trying to give the most optimal algorithm, as it was listed as being homework, but to point to a way to perhaps find a better algorithm, which is why I suggested doing several steps by hand to find a pattern, so that a solution that is better than what I suggested could be found. – James Black Jul 24 '10 at 19:16

I'd like to elaborate a bit on DVK's excellent answer. I'll stick with his notation f(d,s) to denote the sought value for depth d.

If you calculate the value f(d,s) for large d, you'll notice that the values converge as d increases.

Let φ=f(∞,s). That is, φ is the limit as d approaches infinity, and is the continued fraction fully expanded. Note that φ contains a copy of itself, so that we can write φ=1+1/φ. Multiplying both sides by φ and rearranging, we get the quadratic equation

φ2 - φ - 1 = 0

which can be solved to get

φ = (1 + √5)/2.

This is the famous golden ratio.

You'll find that f(d,s) is very close to φ as d gets large.

But wait. There's more!

As DVK pointed out, the formula for f(d,s) involves terms from the Fibonacci sequence. In particular, it involves ratios of successive terms of the Fibonacci sequence. There is a closed form expression for the nth term of the sequence, namely


Since 1-φ is less than one, (1-φ)n gets small as n gets large, so a good approximation for the nth Fibonacci term is φn/√5. And getting back to DVK's formula, the ratio of successive terms in the Fibonacci sequence will tend to φn+1n = φ.

So that's a second way of getting to the fact that the continued fraction in this question evaluates to φ.

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