I am going to implement a Farey fraction approximation for converting limited-precision user input into possibly-repeating rationals.

http://mathworld.wolfram.com/FareySequence.html

I can easily locate the closest Farey fraction in a sequence, and I can find Fn by recursively searching for mediant fractions by building the Stern-Brocot tree.

http://mathworld.wolfram.com/Stern-BrocotTree.html

However, the method I've come up with for finding the fractions in the sequence Fn seems very inefficient:

(pseudo)

```
For int i = 0 to fractions.count -2
{
if fractions[i].denominator + fractions[i+1].denominator < n
{
insert new fraction(
numerator = fractions[i].numerator + fractions[i+1].numerator
,denominator = fractions[i].denominator + fractions[i+1].denominator)
//note that fraction will reduce itself
addedAnElement = true
}
}
if addedAnElement
repeat
```

I will almost always be defining the sequence Fn where n = 10^m where m >1

So perhaps it might be best to build the sequence one time and cache it... but it still seems like there should be a better way to derive it.

**EDIT:**

This paper has a promising algorithm:

http://www.math.harvard.edu/~corina/publications/farey.pdf

I will try to implement.

The trouble is that their "most efficient" algorithm requires knowing the prior two elements. I know element one of any sequence is 1/n but finding the second element seems a challenge...

**EDIT2:**

I'm not sure how I overlooked this:

Given F0 = 1/n

If x > 2 then

F1 = 1/(n-1)

Therefore for all n > 2, the first two fractions will always be

1/n, 1/(n-1) and I can implement the solution from Patrascu.

So now, we the answer to this question should prove that this solution is or isn't optimal using benchmarks..