# How to output fraction instead of decimal number?

In C++, When I calculate 2/3, it will output decimal values, how can I just get the original format (i.e.g 2/3) instead of 0.66666667

Thanks

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It depends on what do you mean by "calculate 2/3" –  Itamar Katz Jan 27 '11 at 16:37
This question should come with a code example and the actual and expected output. –  Björn Pollex Jan 27 '11 at 16:39
There's an interesting demo, showing the working, of converting a decimal to a fraction here: webmath.com/dec2fract.html –  Tony Jan 27 '11 at 16:41
@Tony: Yes, it's interesting, but far from mathematically rigorous, and so I feel it is dangerously misleading for really understanding the subject. It's a start though :-). For a more thorough explanation, see e.g. en.wikipedia.org/wiki/Continued_fractions , in particular the section "Best rational within an interval". (Sorry, I'm a mathematician, couldn't resist...). –  sleske Jan 27 '11 at 17:02

You can't. You would need to write a class dedicated to holding rational numbers (i.e. fractions). Or maybe just use the Boost Rational Number library.

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+1: the obvious solution - just don't throw that information away, indeed! –  Eamon Nerbonne Jan 27 '11 at 16:38
There's a finite number of `int` values that produce `0.66666667`. Why not just write a function that picks one? The answer is not "you can't" –  Inverse Jan 31 '11 at 14:51
@Inverse: You can't with any reasonable approach. It sounds like you're suggesting the approach of multiplying the floating-point value by all possible denominators until you find a result that's somewhere near an integer value? Obviously, this is of essentially infinite algorithmic complexity (are there better methods?). And even this won't get back "the original format" as requested by the OP; it can't distinguish between 2/3 and 4/6. –  Oli Charlesworth Jan 31 '11 at 15:23
@Inverse: No, there is an infinite number of ints that produce `0.66666667`. It might be 1/3, or 1000000/3000001, or 1000001/3000000, etc. (assuming enought zeros to exhaust the FP precision). You can easily show that for any FP number, there is an infinite (though countably infinite) number of integer fractions. –  sleske Nov 16 '11 at 14:23
Of course, in practice you usually want the fraction with the smallest denominator that is reasonably close to your FP number. There is indeed only one such fraction, if you set a fixed limit for the maximum difference between the FP number and the fraction (or if you set an upper bound for the denominator). See my answer for details :-). –  sleske Nov 16 '11 at 14:27

If I understand correctly, you have a floating point number (a `float` or `double` type variable), and you'd like to output this value as a fraction.

If that is the case, you need to further specify your question:

• A FP number is a fraction, by definition: A FP number consists of two integers, a mantissa m and an expontent e (and a sign, but that's irrelevant here). So each FP number is really a pair (m,e), and the value f it represents is f=mb^e (where b is a fixed integral base, usually 2). So the natural representation as a fraction is simply m / b^(-e) with e<0 (if e>=0 , f is integral anyway).
• However, you probably want to get the fraction with the smallest reasonable divisor. This is a different question. To get is, you could e.g. use the bestappr function from the Pari/GP library. In your case, you'd probably use `bestappr(x, A)`, with x your input, and A the largest denominator you want to try. bestappr will give you the fraction closest to x whose denominator is still smaller than A.
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+1 Not only a library link, but a walk-through as well ;-) –  user166390 Jan 27 '11 at 18:43

how can I just get the original format (i.e.g 2/3) instead of 0.66666667

Only with great difficulty by wrapping something like the GMP library with custom output operators. Below is a bit more on GMP:

# What is GMP?

GMP is a free library for arbitrary precision arithmetic, operating on signed integers, rational numbers, and floating point numbers. There is no practical limit to the precision except the ones implied by the available memory in the machine GMP runs on. GMP has a rich set of functions, and the functions have a regular interface.

The main target applications for GMP are cryptography applications and research, Internet security applications, algebra systems, computational algebra research, etc.

GMP is carefully designed to be as fast as possible, both for small operands and for huge operands. The speed is achieved by using fullwords as the basic arithmetic type, by using fast algorithms, with highly optimised assembly code for the most common inner loops for a lot of CPUs, and by a general emphasis on speed.

GMP is faster than any other bignum library. The advantage for GMP increases with the operand sizes for many operations, since GMP uses asymptotically faster algorithms.

The first GMP release was made in 1991. It is continually developed and maintained, with a new release about once a year.

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This, or some facility like it is pretty much the only way. You still have to keep track from the start. If you just have 0.6666667, you have no way of knowing if that was 6666667/10000000 or 2/3. –  T.E.D. Jan 27 '11 at 17:22

You have to store them in some sort of Fraction class with two integer fields. Of course, you have to simplify the fraction before using it for output.

You can develop your own class or use some libraries, like this one for exact maths: CLN - Class Library for Numbers

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A class with two integer fields: nominator and denominator doesn't help with the conversion of `float` or `double` to a fraction. The conversion to a fraction can occur with a Fraction class. –  Thomas Matthews Jan 27 '11 at 18:31
Thomas, I don't get the difference. However, also `float` and `double` are fractions, in a way. As I understood it, the question was about how to manage the issue from the beginning, and the solution is to avoid the creation of `float` or `double` variables in the first place. –  Mauro Vanetti Feb 3 '11 at 10:27

This is impossible in general: floating point numbers are not precise and do not retain sufficient information to fully reconstruct a fraction.

You could, however, write a function that heuristically finds an "optimal" approximation, whereby fractions with small numerators and denominators are preferred, as are fractions that have almost the same value as the floating point number.

If you're in full control of the code, Oli's idea is better: don't throw away the information in the first place.

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That's not QUITE true. If you have a specific precision you're willing to live with (say, 0.00001), you could multiply by the inverse of that precision - which gives you a large numerator and denominator. It would be possible at that point to factorize both numerator and denominator, then start removing common factors until you're left with the smallest fraction that yields a floating-point value that is within the precision you specified of the original floating-point number. –  BobG Jan 27 '11 at 16:38
You mean: it's not always true, for all floating point numbers. To be more precise then: for any floating point number, there are a countable infinity of rational numbers at least as close to it as to other floating point numbers, although exactly one of those rational numbers is exactly equal to the floating point number. Is that better? –  Eamon Nerbonne Jan 27 '11 at 16:43
@BobG: that algorithm will generally not find the "optimal" fraction since the hand-picked initial denominator (1/0.00001 in your example) is not divisible by the optimal divisor (e.g. the "3" in Sean's example). Anyhow, this sounds like a different question... –  Eamon Nerbonne Jan 27 '11 at 16:47
At any rate, implementing an algorithm for finding the best rational approximation is not necessary; such implementations already exist, for example in Pari/GP (see my answer). –  sleske Jan 27 '11 at 16:58
Yeah: no point in reinventing the wheel. –  Eamon Nerbonne Jan 27 '11 at 18:54

write your own Rational class to calculate divisions

``````class Rational
{
public:
int numerator, denominator;

Rational(int num, int den=1){
numerator = num;
denominator=den;
}
Rational(Rational other){
numerator = other.numerator;
denominator = other.denominator;
}
double operator / (int divisor){
denominator *= divisor;
simplificate();
return getrealformat();
}
Rational& operator / (int divisor){
denominator *= divisor;
simplificate();
return this;
}
Rational& operator / (Rational &divisor){
numerator *= divisor.numerator;
denominator *= divisor.denominator;
simplificate();
return this;
}
double operator / (int divisor){
denominator *= divisor;
simplificate();
return getrealformat();
}
double getrealformat(){
return numerator/denominator;
}
simplificate(){
int commondivisor = 1;
for(int i=2;i<=min(abs(numerator), abs(denominator));i++)
if( numerator%i == 0 && denominator%i == 0 )
commondivisor = i;
numerator /= commondivisor;
denominator /= commondivisor;
}
};
``````

use

``````Rational r1(45), r2(90), r3=r1/r2;
cout<<r3.numerator<<'/'<<r3.denominator;
cout<<r3.getrealformat();
``````
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How does this handle converting from `float` or `double` to `Rational`? –  Thomas Matthews Jan 27 '11 at 18:29
Rational operator=(double number){ numerator = number*decimals;/*once specified before, for ex. 100 */ denominator = decimals; simplificate(); } –  Aak Jan 31 '12 at 18:06

You can store all your fraction's numerators and denominators as intergers. Integers have exact representations in binary.

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...until they don't. There is a max int, past which you'd have to use some kind of bignum library. Or floating-point, which gets him back to his original problem. –  T.E.D. Jan 27 '11 at 17:24
@T.E.D., overflowing ints was not OP's problem. –  ThomasMcLeod Jan 27 '11 at 17:37
i'd say 1/10^20 is sufficient precision for almost any application. –  flownt Jan 27 '11 at 17:39

To simplify efforts, I suggest you stick with known denominators if possible.

I'm working with an application where the fractions are restricted to denominators of powers of 2 or using 3 (for thirds).

I convert to these fractions using an approximation (rounding to the nearest 1.0/24.0).

Without some restrictions, finding the denominator can be quite a chore and take up a lot of the execution time.

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I am beginner and this way that I use may not be a proper way

``````#include <iostream>

using namespace std;
int main ()
{
double a;
double b;
double c;

cout << "first number: ";
cin >> a;
cout << "second number: ";
cin >> b;

c = a/b;
cout << "result is: " << c << endl;

if (b != 0) {
if (a > 0) {
if (c - (int)c > 0 && c - (int)c < 1)
cout << "fraction: " << a << "/" << b;
} else {
if (c - (int)c < 0 && c - (int)c < 1)
cout << "fraction: " << a << "/" << b;
}
}

return 0;
}
``````
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I think you answered a different question. Your answer is about separating the integer-part of a floating point number from the non-integer part (i.e. separate `1.25` into `1` and `.25`). But the question is about transforming the floating point number into a fraction-representation of a rational number, i.e. `1 1/4` or `5/4`. –  jogojapan Jun 10 '13 at 7:16
With this you can recognize floating result and print them in fraction way –  EmPlusPlus Jun 10 '13 at 7:22
For `1.25` your program outputs `1` and `.25`, correct? How does it transform `.25` into `1/4`? –  jogojapan Jun 10 '13 at 7:26
Ok guys I just edited it with that way I said :) check it out and leave comment :) –  EmPlusPlus Jun 10 '13 at 7:29
But now your program requires the user to entire `a` and `b` explicitly. Some of the other answers said this too; if a rational number is given as input, you could simply store it so you have it when you need it. But the real difficulty is in calculating `a` and `b` from the floating point number. –  jogojapan Jun 10 '13 at 7:34