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I got the following question for an interview:

Program to change a decimal to the nearest fraction.

Example: 0.12345 => 2649/20000

0.34 => 17/50

What is the best approach to solve this?

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closed as not a real question by Gabe, L.B, Alexey Frunze, StanislavL, Graviton Feb 22 '12 at 6:34

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

5  
What makes this a programming question? –  Gabe Feb 21 '12 at 22:38
    
Which aspect of fractions don't you understand? –  Kerrek SB Feb 21 '12 at 22:39
5  
It's an algorithm question, which seems valid to me. Still I would have liked to see a basic solution, with the question being "how can I optimize this." –  Eric J. Feb 21 '12 at 22:39
    
See [this][1] [1]: stackoverflow.com/questions/4676481/… –  charlieg Feb 21 '12 at 22:43
    
@EricJ.: It may be valid, but it's not clear what the programming aspect is. It could be "How do I determine how many decimal places my floating point number has?", "How do I reduce a fraction?", or maybe "How do I compute the GCD of two numbers?". –  Gabe Feb 21 '12 at 22:45

8 Answers 8

up vote 2 down vote accepted

A decimal number is a fraction whose denominator is a power of ten (and similarly for any number base). So 0.34 is 34/100. Now just cancel the common factor, i.e. divide both numerator and denominator by their greatest common divisor.

You can find the GCD with a standard algorithm, which I leave to you to find.

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An approach I would come up with this late is get rid of the decimals:

0.12345 = 0.12345/1 = 12345/100000

Then find the Greatest common divisor and divide both by it.

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2  
You beat me by a few seconds :-) This solution only works for a terminating decimal value (e.g. not 1/3 = 0.3333..), which seems implied by the question but not conclusively stated. –  Eric J. Feb 21 '12 at 22:42
    
@Eric, all decimal values are terminating in IEEE754 :-) –  paxdiablo Feb 21 '12 at 22:46
1  
@paxdiablo: The OP used the term "decimal", never once referring to "floating point" or "IEEE 754". –  Gabe Feb 21 '12 at 22:47
    
Unless you're applying for a job as a mathematician rather than a programmer, that will matter :-) –  paxdiablo Feb 21 '12 at 22:51

Naive solution..

  1. 0.12345 = 12345 / 100000
  2. find greatest common divisor
  3. divide both of the parts of fraction with the GCD
  4. profit
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First, make the numerator and denominator integral by multiplying continuously by ten.

So, 0.34/1 becomes 34/100, and 0.12345/1 becomes 12345/100000

Then use a GCD calculation to get the greatest common divisor of those two numbers, and divide them both by that.

The GCD of 34 and 100 is 2, which gives you 17/50. The GCD of 12345 and 1000000 is 5, which gives you 2469/20000.

A recursive GCD function in C is:

int gcd (int a, int b) {
    return (b == 0) ? a : gcd (b, a%b);
}
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The answer by Kerrek SB is correct, but using continued fractions it is easy to find the best rational approximation of any real number (represented as a float or not), for any given maximal denominator. The optimal property of the method is described here: http://en.wikipedia.org/wiki/Continued_fraction#Some_useful_theorems, theorem 4 and 5.

Example results: approximate sqrt(2) with a denominator less or equal to 23:

findapprox(math.sqrt(2),23)
          (3, 2)  new error frac: 6.0660e-02 
          (7, 5)  new error frac: 1.0051e-02 
        (17, 12)  new error frac: 1.7346e-03 
        (41, 29)  new error frac: 2.9731e-04 
result: (17, 12)

Example: approximate 23.1234 with denominator <=20000:

findapprox(23.1234,20000)
            (185, 8)  new error frac: 6.9194e-05 
          (1688, 73)  new error frac: 4.8578e-06 
          (1873, 81)  new error frac: 2.4560e-06 
         (3561, 154)  new error frac: 1.0110e-06 
         (5434, 235)  new error frac: 1.8403e-07 
        (19863, 859)  new error frac: 3.0207e-08 
       (25297, 1094)  new error frac: 1.5812e-08 
       (45160, 1953)  new error frac: 4.4287e-09 
       (70457, 3047)  new error frac: 2.8386e-09 
      (115617, 5000)  new error frac: 0.0000e+00 
result: (115617, 5000) (exact)

Continued fractions have some funky characteristics. For example sqrt(2) can be written as 1,2,2,,... meaning 1+1/(2+1/(2+1/...). So we can find optimal rational approximations for sqrt(2):

rewrap([1]+[2]*30) gives 367296043199 / 259717522849, 
all correct: 1.4142135623730951

Here's the code (python).

# make a+1/(b+1/(c+1/...)) cont fraction of a float
# no special care taken to accumulation of float truncation errors.
def contfrac(v):
    nums=None
    while nums==None or len(nums)<20:
        if not nums:
            nums=[]
        vi=int(v)
        v=v-vi
        nums.append(vi)
        if v<=0 : 
            return nums
        v=1.0/v
    return nums


# make tuple representing a rational number based on a cont f list 
# this is exact
def rewrap(v):
    rat=(0,1)
    first=1
    for k in reversed(v):
        if first:
            first=0
            rat=(k,1)
        else:            
            rat=(k*rat[0]+rat[1],rat[0])        
    return rat

# float evaluate a ratio
def makefloat(v):
    return v[0]*1.0/v[1]

# find the best rational approximation with denominator <=maxdenom
def findapprox(flt,maxdenom):
    flt=1.0*flt
    cf=contfrac(flt)
    best=(cf[0],1)
    errfrac=1e9
    for i in range(2,len(cf)):
        new=rewrap(cf[:i])        
        newerrfrac=abs((flt-makefloat(new))/flt)
        print "%20s"%(str(new)),
        print(" new error frac: %5.4e " %(newerrfrac))
        if new[1]>maxdenom or newerrfrac>errfrac:
            return best
        best=new
        errfrac=newerrfrac
        if newerrfrac ==0: 
            return best
    return best
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First, convert your numbers to an obvious fraction

0.34 => 34/100

and

0.12345 => 12345/100000

Now reduce the fractions. You will need to find the GCD of the numerator and the denominator. The GDC of 34 and 100 is 2. Divide both numbers by 2 and you get 17/50.

See Greatest common divisor on Wikipedia. You will also find a brief description of an algorithm for GCD there.

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  1. get rid of dot : (0.a1..an * 10n) / (1*10n)
  2. x = GCD( a1..an , 10n)
  3. (a1..an/x) / (10n/x)
foo(double a) {
    int digits = (int)log(a, 10);
    int x = GCD((int)(a * 10^digits) , 10^digits);
    return ((int)(a * 10^digits) / x) + " / " + (10^digits / x);    
}
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Note that in c# ^ is the bitwise XOR operator, not the power function. Just in case you are using c#. –  Olivier Jacot-Descombes Feb 21 '12 at 23:04
    
@OlivierJacot-Descombes thanks, it is actually pseudo code. but thanks for clarifying for avoiding confusion –  james Feb 21 '12 at 23:11

http://homepage.smc.edu/kennedy_john/DEC2FRAC.PDF

In short:

Let X be our decimal value. Z1 == X, D0 == 0 and D1 == 1.

Zi+1 == 1 / (Zi - IntPart(Zi))

Di+1 == Di * IntPart(Zi+1) + Di-1

Ni+1 == Round(X * Di+1)

When you have found, by iterating through these Z, D and N series from the fixed-point Z1, an index i of the series producing an Ni and Di such that Ni / Di == X to the desired precision, you're done.

Understand that the decimal value is best stored as a decimal type, and the calculation of N/D should also result in a decimal type, to avoid floating point rounding error.

The solution:

public struct Fraction
{
    public int Numerator { get; private set; }
    public int Denominator { get; private set; }
    public decimal DecimalValue { get { return ((decimal)Numerator) / Denominator; } }
    public override string ToString()
    {
        return Numerator.ToString() + "/" + Denominator.ToString();
    }

    public static Fraction FromDecimal(decimal x)
    {
        decimal z = x;
        decimal dPrev = 0;
        decimal dCur = 1;
        decimal dTemp = dCur;
        decimal n = 0;

        while (n / dCur != x)
        {
            z = 1 / (z - (int)z);
            dTemp = dCur;
            dCur = (dCur * (int)z) + dPrev;
            dPrev = dTemp;
            n = Math.Round(x * dCur);
        }

        return new Fraction {Numerator = (int) n, Denominator = (int) dCur};
    }
}

This algorithm is capable of finding the "true" fractional values of rational numbers that are artificially terminated due to precision limitations (i.e. .3333333 would be 1/3, not 3333333/10000000); it does this by evaluating each candidate fraction to produce a value that would be subject to the same precision limitations. It actually depends upon that; feeding this algorithm the true value of pi (if you could) would cause an infinite loop.

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