# Calculate Biggest Rational Fraction Within Some Bounds

I am trying to place currency trades that match an exact rate on a market that only accepts integral bid/offer amounts. I want to make the largest trade possible at a specific rate. This is a toy program, not a real trading bot, so I am using C#.

I need an algorithm that returns an answer in a reasonable amount of time even when the numerator and denominator can be large (100000+).

``````static bool CalcBiggestRationalFraction(float target_real, float epsilon, int numerator_max, int denominator_max, out int numerator, out int denominator)
{
// target_real is the ratio we are tryig to achieve in our output fraction (numerator / denominator)
// epsilon is the largest difference abs(target_real - (numerator / denominator)) we are willing to tolerate in the answer
// numerator_max, denominator_max are the upper bounds on the numerator and the denominator in the answer
//
// in the case where there are multiple answers, we want to return the largest one
//
// in the case where an answer is found that is within epsilon, we return true and the answer.
// in the case where an answer is not found that is within epsilon, we return false and the closest answer that we have found.
//
// ex: CalcBiggestRationalFraction(.5, .001, 4, 4, num, denom) returns (2/4) instead of (1/2).

}
``````

I asked a previous question that is similar (http://stackoverflow.com/questions/4385580/finding-the-closest-integer-fraction-to-a-given-random-real) before I thought about what I was actually trying to accomplish and it turns out that I am trying to solve a different, but related problem.

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Why not decompose the floating point number and reconstruct a fraction from there? –  leppie Dec 8 '10 at 19:45
Fun question, let me see if I can whip something up. –  Keith Dec 8 '10 at 19:58
This does sound like fun. –  KeithS Dec 8 '10 at 20:10
I think it's duplicate of your other question stackoverflow.com/questions/4385580/… I can't see any difference, just some tags and text changed, but the thing you want is duplicate. –  Saeed Amiri Dec 8 '10 at 20:19
Can you give an example? –  phkahler Dec 8 '10 at 20:20

If you want the unreduced fraction, then here's one optimization you can do: Since you'll never be interested in n/2, because you want 2n/4, 4n/8, or 1024n/2048, we only need to check some of the numbers. As soon as we check any multiple of 2, we never need to check 2. Therefore, I believe you can try denominators `denominator_max` through `denominator_max/2`, and you'll have implicitly checked all of the factors of those numbers, which would be everything `2` through `denominator_max/2`.

I'm not at a compiler at the moment, so I haven't checked this code for correctness, or even that it compiles, but it should be close.

``````static bool CalcBiggestRationalFraction(float target_real, float epsilon,
int numerator_max, int denominator_max,
out int numerator, out int denominator)
{
if((int)Math.Round(target_real * denominator_max) > numerator_max)
{
// We were given values that don't match up.
// For example, target real = 0.5, but max_num / max_den = 0.3
denominator_max = (int)(numerator_max / target_real);
}

float bestEpsilon = float.MAX_VALUE;
for(int den = denominator_max; den >= denominator_max/2, den--)
{
int num = (int)Math.Round(target_real * den);
float thisEpsilon = Math.abs(((float)num / den) - target_real);
if(thisEpsilon < bestEpsilon)
{
numerator = num;
denominator = den;
bestEpsilon = thisEpsilon;
}
}

return bestEpsilon < epsilon;
}
``````
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This works great, thanks! –  John Shedletsky Dec 20 '10 at 5:31

The canonical way to solve your problem is with continued fraction expansion. In particular, see this section.

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I want an answer in the form: n / d. Not a nest continued fraction. –  John Shedletsky Dec 13 '10 at 23:29
You stop the expansion when the resulting (reduced) fraction meets your precision requirements. There is an algorithm to produce reduced N/D for successive levels of the continued fraction expansion - sorry I don't have a link. –  phkahler Dec 20 '10 at 18:55

Let's try this:

First, we need to turn the float into a fraction. Easiest way I can think to do this is to find the order of magnitude of the epsilon, multiply the float by that order, and truncate to get the numerator.

``````long orderOfMagnitude = 1
while(epsilon * orderOfMagnitude <1)
orderOfMagnitude *= 10;

numerator = (int)(target_real*orderOfMagnitude);
denominator = orderOfMagnitude;

//sanity check; if the initial fraction isn't within the epsilon, then add sig figs until it is
while(target_real - (float)numerator / denominator > epsilon)
{
orderOfMagnitude *= 10;
numerator = (int)(target_real*orderOfMagnitude);
denominator = orderOfMagnitude;
}
``````

Now, we can break the fraction down into least terms. The most efficient way I know of is to attempt to divide by all prime numbers less than or equal to the square root of the smaller of the numerator and denominator.

``````var primes = new List<int>{2,3,5,7,11,13,17,19,23}; //to start us off

var i = 0;
while (true)
{
if(Math.Sqrt(numerator) < primes[i] || Math.Sqrt(denominator) < primes[i]) break;

if(numerator % primes[i] == 0 && denominator % primes[i] == 0)
{
numerator /= primes[i];
denominator /= primes[i];
i=0;
}
else
{
i++;
if(i > primes.Count)
{
//Find the next prime number by looking for the first number not divisible
//by any prime < sqrt(number).
//We are actually unlikely to have to use this, because the denominator
//is a power of 10, so its prime factorization will be 2^x*5^x
var next = primes.Last() + 2;
do
{
for(var x=0; primes[x] <= Math.Sqrt(next); x++)
if(next % primes[x] == 0)
{
break;
}

You are correct, "highest terms" is a misnomer, but only taken on its own. He's passing in `max_denominator`, and gave the specific example that calculating the fraction of 0.5 with a max_denominator of 4 should give the result 2/4, not 1/2. You don't need to assume that the number is rational: For example, calculating Pi within 0.01 would give 314/100, which reduces to 157/50. However, 355/113 is much closer, accurate within 0.000001. –  David Yaw Dec 10 '10 at 0:18