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For example, if my function was called getlowestfraction(), this is what I expect it to do:

getlowestfraction(0.5) // returns 1, 2 or something along the lines of that

Another example:

getlowestfraction(0.125) // returns 1, 8 or something along the lines of that
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up vote 6 down vote accepted

Using Continued Fractions one can efficiently create a (finite or infinite) sequence of fractions hn/kn that are arbitrary good approximations to a given real number x.

If x is a rational number, the process stops at some point with hn/kn == x. If x is not a rational number, the sequence hn/kn, n = 0, 1, 2, ... converges to x very quickly.

The continued fraction algorithm produces only reduced fractions (nominator and denominator are relatively prime), and the fractions are in some sense the "best rational approximations" to a given real number.

I am not a JavaScript person (programming in C normally), but I have tried to implement the algorithm with the following JavaScript function. Please forgive me if there are stupid errors. But I have checked the function and it seems to work correctly.

function getlowestfraction(x0) {
    var eps = 1.0E-15;
    var h, h1, h2, k, k1, k2, a, x;

    x = x0;
    a = Math.floor(x);
    h1 = 1;
    k1 = 0;
    h = a;
    k = 1;

    while (x-a > eps*k*k) {
        x = 1/(x-a);
        a = Math.floor(x);
        h2 = h1; h1 = h;
        k2 = k1; k1 = k;
        h = h2 + a*h1;
        k = k2 + a*k1;

    return h + "/" + k;

The loop stops when the rational approximation is exact or has the given precision eps = 1.0E-15. Of course, you can adjust the precision to your needs. (The while condition is derived from the theory of continued fractions.)

Examples (with the number of iterations of the while-loop):

getlowestfraction(0.5)     = 1/2               (1 iteration)
getlowestfraction(0.125)   = 1/8               (1 iteration)
getlowestfraction(0.1+0.2) = 3/10              (2 iterations)
getlowestfraction(1.0/3.0) = 1/3               (1 iteration)
getlowestfraction(Math.PI) = 80143857/25510582 (12 iterations)

Note that this algorithm gives 1/3 as approximation for x = 1.0/3.0. Repeated multiplication of x by powers of 10 and canceling common factors would give something like 3333333333/10000000000.

Here is an example of different precisions:

  • With eps = 1.0E-15 you get getlowestfraction(0.142857) = 142857/1000000.
  • With eps = 1.0E-6 you get getlowestfraction(0.142857) = 1/7.
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This is a good answer. A good choice of eps can be determined from the length of the period of repetition - e.g. if the period is k digits, a good choice of eps is base^(-k) (since an upper bound for the denominator is -1 + base^k). Anything larger and the algorithm might overcompensate (after all, the number is inherently stored as a not-quite-correct rational number, which for all the machine knows could be a "perfect" representation). Your 1/7 example illustrates this perfectly. If eps is too big it'll accept an incorrect answer (e.g. if eps = 1 the nearest integer will be accepted). – amomin Dec 23 '12 at 21:07
@amomin: Thank you! But one advantage of this method is that is does not assume any period of repetition. For example, what would the period length be for (the machine approximation of) Pi? I think it is better to think of "precision". If have chosen eps=1E-15 as example because that (roughly) corresponds to the number of significant digits of a double precision number. But if the number is some user input with e.g. 6 digits after the decimal point, then eps=1E-6 would be appropriate. Anyway, thanks for the feedback. – Martin R Dec 23 '12 at 21:26
Great point! This also points out an ambiguity in the problem (at least I think so). If you really want the "right" rational representation whenever possible (and to gather evidence for/against the number being rational), you shouldn't fix epsilon. But if you concern is about getting some answer, even if the number is irrational, then this is the definitely way to go. I was thinking more along the former lines. – amomin Dec 23 '12 at 21:58

You could keep multiplying by ten until you have integer values for your numerator and denominator, then use the answers from this question to reduce the fraction to its simplest terms.

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You should probably multiply by 2 instead, knowing that JavaScript numbers are binary double-precision floating-point numbers. – Aadit M Shah Dec 23 '12 at 2:17
what about 0.3333...? (or for a binary example .010101010...) - actually, i'm confused, i thought the whole point was that you don't know the num/denum beforehand. – amomin Dec 23 '12 at 7:09
@AaditMShah Good point. Multiplying by 2 would be better. – Matthew Strawbridge Dec 23 '12 at 8:33
@amomin The original numerator is the floating-point number and the original denominator is 1. Then you multiply both the numerator and denominator repeatedly until the numerator is an integer. – Matthew Strawbridge Dec 23 '12 at 8:35
For numbers that are not exactly representable as a binary float, you will end up with a close but different fraction. – Matthew Strawbridge Dec 23 '12 at 8:38

Try this program instead:

function toFrac(number) {
    var fractional = number % 1;

    if (fractional) {
        var real = number - fractional;
        var exponent = String(fractional).length - 2;
        var denominator = Math.pow(10, exponent);
        var mantissa = fractional * denominator;
        var numerator = real * denominator + mantissa;
        var gcd = GCD(numerator, denominator);
        denominator /= gcd;
        numerator /= gcd;
        return [numerator, denominator];
    } else return [number, 1];

function gcd(numerator, denominator) {
    do {
        var modulus = numerator % denominator;
        numerator = denominator;
        denominator = modulus;
    } while (modulus);

    return numerator;

Then you may use it as follows:

var start = new Date;
var PI = toFrac(Math.PI);
var end = new Date;

alert(PI[0] / PI[1]);
alert(end - start + " ms");

You can see the demo here:

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Was just fiddling around with code, and got the answer myself:

function getlowestfraction (num) {
  var i = 1;
  var mynum = num;
  var retnum = 0;
  while (true) {
    if (mynum * i % 1 == 0) {
      retnum = mynum * i;
    // For exceptions, tuned down MAX value a bit
    if (i > 9000000000000000) {
      return false;
  return retnum + ", " + i;

In case anybody needed it.

P.S: I'm not trying to display my expertise or range of knowledge. I actually did spend a long time in JSFiddle trying to figure this out (well not a really long time anyway).

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Won't you get an infinite loop if num is not exactly 1/n for some integer n? For example, what happens with getlowestfraction(0.6)? – Matthew Strawbridge Dec 22 '12 at 10:59
@MatthewStrawbridge - In that case you get 3, 5: – Aadit M Shah Dec 22 '12 at 11:00
This is clever! +1 for both the question and the answer. – user529758 Dec 22 '12 at 11:03
Just wanted to let you know that this function is really slow: There must be a better way to do it. Give me some time and I'll figure it out. – Aadit M Shah Dec 22 '12 at 11:04
You may already be, but I hope you're conscious of the dangers of using floating point numbers in this kind of context. getlowestfraction(0.3) correctly returns 3, 10. getlowestfraction(0.1+0.2) hangs my browser. – Mark Amery Dec 22 '12 at 11:10

Suppose the number is x = 0 . ( a_1 a_2 ... a_k ) ( a_1 a_2 ... a_k ) .... for simplicity (keep in mind that the first few digits may not fit the repeating pattern, and that we need a way to figure out what k is). If b is the base, then

b ^ k * x - x = ( b ^ k - 1 ) * x

on one hand, but

b ^ k * x - x = ( a_1 a_2 ... a_k )

(exact, ie this is an integer) on the other hand.


x = ( a_1 ... a_k ) / ( b ^ k - 1 )

Now you can use Euclid's algorithm to get the gcd and divide it out to get the reduced fraction.

You would still have to figure out how to determine the repeating sequence. There should be an answer to that question. EDIT - one answer: it's the length of \1 if there's a match to the pattern /([0-9]+)\1+$/ (you might want to throw out the last digit before matching bc of rounding). If there's no match, then there's no better "answer" than the "trivial" representation" (x*base^precision/base^precision).

N.B. This answer makes some assumptions on what you expect of an answer, maybe not right for your needs. But it's the "textbook" way of getting reproducing the fraction from a repeating decimal representation - see e.g. here

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