Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am currently implementing a Fraction class for training my OOP skills, and I have got to a problem... In my class, you are able to do math operations between:

  • Fraction & Fraction
  • Integer & Fraction
  • Fraction & Integer

And I want to add both:

  • Fraction & Float
  • Float & Fraction

Since when I work with integers, what I do is to make them a Fraction with denominator 1, I want to, when operating with float, creating a Fraction that represents that given float. And that is where I have my problem.

Firstly, the minimum code required to understand my Fraction class:

class Fraction(object):
    def __init__(self,num,den=1,reduce=True):
        # only accept integers or convertable strings
        if not(type(num) == int and type(den) == int):
            if type(num) == str:
                    num = int(num)
                except ValueError:
                    raise RuntimeError("You can only pass to the numerator and \
denominator integers or integer convertable strings!")
                raise RuntimeError("You can only pass to the numerator and \
denominator integers or integer convertable strings!")
            if type(den) == str:
                    den = int(den)
                except ValueError:
                    raise RuntimeError("You can only pass to the numerator and \
denominator integers or integer convertable strings!")
                raise RuntimeError("You can only pass to the numerator and \
denominator integers or integer convertable strings!")
        # don't accept fractions with denominator 0
        if den == 0:
            raise ZeroDivisionError("The denominator must not be 0")
        # if both num and den are negative, flip both
        if num < 0 and den < 0:
            num = abs(num)
            den = abs(num)
        # if only the den is negative, change the "-" to the numerator
        elif den < 0:
            num *= -1
            den = abs(den)
        self.num = num
        self.den = den
        # the self.auto is a variable that will tell us if we are supposed to
        #automatically reduce the Fraction to its lower terms. when doing some
        #maths, if either one of the fractions has self.auto==False, the result
        #will also have self.auto==False
        self.auto = reduce
        if self.auto:

    def float_to_fraction(f):
        '''should not be called by an instance of a Fraction, since it does not\
accept, purposedly, the "self" argument. Instead, call it as\
Fraction.float_to_fraction to create a new Fraction with a given float'''
        # Start by making the number a string
        f = str(f)
        exp = ""
        # If the number has an exponent (is multiplied by 10 to the power of sth
        #store it for later.
        if "e" in f:
            # Get the "e+N" or "e-N"
            exp = f[f.index("e"):]
            # Slice the exponent from the string
            f = f[:f.index("e")]
        # Start the numerator and the denominator
        num = "0"
        den = "1"
        # Variable to check if we passed a ".", marking the decimal part of a
        decimal = False
        for char in f:
            if char != ".":
                # Add the current char to the numerator
                num += char
                if decimal:
                    # If we are to the right of the ".", also add a 0 to the
                    #denominator to keep proportion
                    den += "0"
                # Slice parsed character
                f = f[1:]
            if char == ".":
                # Tell the function we are now going to the decimal part of the
                decimal = True
                # Slice the "."
                f = f[1:]
        # Parse the exponent, if there is one
        if exp != "":
            # If it is a negative exponent, we should make the denominator bigger
            if exp[1] == "-":
                # Add as many 0s to the den as the absolute value of what is to
                #the right of the "-" sign. e.g.: if exp = "e-12", add 12 zeros
                den += "0"*int(exp[2:])
            # Same stuff as above, but in the numerator
            if exp[1] == "+":
                num += "0"*int(exp[2:])
        # Last, return the Fraction object with the parsed num and den!
        return Fraction(int(num),int(den))

My float_to_fraction() function converts, 100% accurately, a given float to a Fraction. But as I remember from my math classes a cyclic decimal with a n-digit long cycle, like 0.123123123123... or 0.(123) can be written in the form of a fraction with numerator = cycle and denominator = (as many 9s as the length of the cycle):

123/999 = 0.(123) 3/9 (=1/3) = 0.(3); 142857/999999 (=1/7) = 0.(142857) etc, etc...

But with this implementation, if I pass to the float_to_fraction() an argument like 1/3, it will parse "0.3333333333333333" which is finite, returning this Fraction: 3333333333333333/10000000000000000. It IS accurate, since I passed to the function a finite number! How can I implement, in this function, a way of recognizing cyclic decimals, so I can return, instead of a Fraction with a denominator = 10^n, a denominator with loads of 9s.

share|improve this question
You might want to look at this: find rational approximation to given real number. Although the code is C, it should help you get started. –  devnull Mar 9 at 13:08
Take a look at fractions.Fraction.limit_denominator and its source code. It's not a simple job. –  user2357112 Mar 9 at 13:12
Your float_to_fraction() function does not convert 100% accurately. Floats have a binary exponent, but you’re relying on the base-10 representation. The correct way to convert a float to an accurate fraction is to examine its binary representation; you'll see that you need to divide (or multiply) the mantissa by 2**exponent. –  alastair Mar 9 at 13:25
This is not going to work out. Don't put the number in a binary float in the first place. –  David Heffernan Mar 9 at 14:01

1 Answer 1

The best way to convert a decimal expression into an approximating rational is via the continued fraction expansion.

For x=0.123123123123 this results in

a[0]=floor(r)=0, r=r-a[0], r=1/r=8.121951219520,
a[1]=floor(r)=8, r=r-a[1], r=1/r=8.199999999453,
a[2]=floor(r)=8, r=r-a[2], r=1/r=5.000000013653,
a[3]=floor(r)=5, r=r-a[3], r=1/r=73243975.48780,

And at this point r-a[3]<1e-5 the iteration stops. The rational approximation found is

x=1/(8+1/(8+1/5))=1/(8+5/41)=41/333 (=123/999)

The intermediate convergents are

1/8=0.125,      x- 1/8   = -0.001876876877,
1/(8+1/8)=8/65, x- 8/65  =  0.0000462000460,
41/333,         x-41/333 = -1.231231231231e-13.
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.