Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I've been working on Project euler Problem 57 (Love the site!). For this problem a conversion is required between a finite continued fraction and a normal fraction. I devised an algorithm that basically takes the inverse of the last number in a list, add it to the next-to-last and continues until the final fraction remains. For problem 67 it worked maverlously, but this time it stops working after the second iteration (I have to perform the algorithm on multiple continued fractions).

This is the piece of code (I used an external module, namely sympy):

import time
from sympy import *
from sympy import fraction, Rational, Symbol

def cont_fract_to_fraction(cont_frac_list):
    new_reduced=Rational(b,1)+ Rational(1,a)
    del cont_frac_list[-1]
    if len(cont_frac_list)==1:
        print cont_frac_list #To check
        return cont_frac_list

def numerator_higher_denominator(fraction):
    if len(num)>len(den):
        return 1
        return 0



for k in xrange (1, 101):
    for x in xrange (1, k+2):
    print sqrt_eval ##To double check
    #fraction_result=fraction(soln[0]) To introduce later
    #tally+=numerator_higher_denominator(fraction_result) To introduce later


print "Solution: ", tally, "Solved in: ", elapsed

I basically test just to see if it gets all the final fraction and the print from the function, before the return, gives the answer, but the print after I assigned the value to sqrt_eval prints None. Here is a test run:

###Test run####
[3/2] #--> function print
[3/2] #--> sqrt_eval print

I've been searching thouroughly for an answer and can't quite find one. Help me debug this, if you can, without altering the code much.

share|improve this question
You're not returning a value on the last branch of your recursive function, else: cont_fract_to_fraction(cont_frac_list), hence the Nones. [Originally I made this an answer, but I'm not entirely sure I know what the code's supposed to be producing, so it might not be the whole problem you're looking to solve.] – DSM Jan 24 '13 at 4:25
Actually, that was the whole problem. Took you word, and in a second it spit out the answer. X_X sorry for such a trivial problem. edit: Go look at Project Euler, I highly recommend it :) – Sebastian Garrido Jan 24 '13 at 4:29

The fractions module makes short work of this problem:

>>> from fractions import Fraction
>>> def normal_fraction(continued_fraction):
         n = Fraction(0)
         for d in continued_fraction[:0:-1]:
             n = 1 / (d + n)
         return continued_fraction[0] + n

>>> cf = [3,7,15,1,292,1,1,1,2,1,3,1]
>>> normal_fraction(cf)
Fraction(5419351, 1725033)
>>> float(_)

If you like functional programming and concise code, the above logic can be expressed in a one-liner using reduce():

>>> cf[0] + reduce(lambda d, n: 1 / (d + n), cf[:0:-1], Fraction(0))
Fraction(5419351, 1725033)

And here is a version that doesn't use Fraction. It will work even on very old versions of Python:

def normal_fraction(continued_fraction):
    n, d = 0, 1
    for a in continued_fraction[:0:-1]:
        n, d = d, a*d + n
    return continued_fraction[0]*d + n, d
share|improve this answer

This doesn't answer your question, but there are some formulas on Wikipedia that might let you compute this more efficiently.

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.