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I know this is a bit hypothetical but I am wondering why no language I know does it.

For example, you want to store 1/3. Give the programmer an option to specify it as 1/3, and store 1 and 3. Something like

struct float {
    int numerator;
    int denominator;
};

Rational number arithmetic becomes really easy and considerably more accurate!

This would solve so many problems related to the precision and storage limitations of floating point numbers, and I dont see it introducing any new problems as well!

Hence my question: Why aren't rational numbers implemented and stored as fractions with zero loss of information?


As Joe asked, and others might also point out, I do not mean this to replace existing system, but to complement it.

Q: How do you store pi?

A: So many times, I am just storing 1/3 and not pi. pi can be stored the old way, and 1/3 in the new way.

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closed as not constructive by Robᵩ, Corbin, Seth Carnegie, Bo Persson, stijn May 27 '12 at 7:29

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5  
See Boost.Rational. –  Robᵩ May 27 '12 at 3:27
2  
The nice thing about OOP is that you can do this. –  chris May 27 '12 at 3:27
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This would not solve any problems related to storing precision and storage limitations of floating point numbers. Because ints are a fixed number of bits, only certain fractions would be possible. How would you represent 3.45x10^30? How would you represent 1.23x10^-20? All you are doing is changing what the limitations are. –  Steven Burnap May 27 '12 at 3:28
2  
This is not really a (stackoverflow) question, in my opinion. I mean, there's no "absolute true" answer (unless Bjarne Stroustrup replies). If you ask me, it's something that you can implement if you want, but would bloat the language and would be confusing if it was there straight out of the box. –  Claudiu May 27 '12 at 3:33
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@joe No computer can store pi precisely. This is true both with standard C++ floats and what is being proposed here. Irrational numbers cannot be precisely stored, period. –  Steven Burnap May 27 '12 at 3:54

8 Answers 8

up vote 10 down vote accepted

The reason they are not stored this way by default is that the range of valid values that can fit in a fixed set of bits is smaller. Your float class can store numbers between 1/MAXINT and MAXINT (plus or minus). A C/C++ float can represent numbers between 1E+37 and 1E-37 (plus or minus). In other words, a standard float can represent values 26 orders of magnitude bigger and 26 orders of magnitude smaller then yours despite taking half the number of bits. In general, it's more convenient to be able to represent very large and very small values than to be perfectly precise. This is especially true since rounding tends to give us the right answers with small fractions like 1/3. In g++, the following gives 1:

std::cout << ((1.0/3.0) * 3.0) << std::endl; 

Remember that types in C++ have a fixed size in bits. Thus a datatype in 32 bits has at most MAX_UINT values. If you change the way it is represented, you're just changing which values can be precisely represented, not increasing them. You can't cram more in, and thus can't be "more precise". You trade being able to represent 1/3 precisely for not being able to represent other values precisely, like 5.4235E+25.

It is true that your float can represent values more precisely between 1E-9 and 1E+9 (assuming 32 bit ints) but at a cost of being completely unable to represent values outside of this range. Worse, while the standard float always has 6 digits of precision, your float would have precision that varied depending on how close to zero the values were. (And note that you are using twice the bits that float does.)

(I'm assuming 32 bit ints. Same argument applies for 64 bit ints.)

Edit: Also note that most data people use floats for is not precise anyway. If you are reading data off of a sensor, you've already got imprecision, so being about to "perfectly" represent the value is pointless. If you are using a float in any sort of computing context, it's not going to matter. There is no point in perfectly describing '1/3' if your purpose is to display a bit of text 1/3rd of the way across the screen.

The only people who really need perfect precision are mathematicians, and they generally have software that gives them this. Very few others need precision beyond what double gives.

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3  
You mention mathematicians as the only counter example, an important field that should never touch floating point numbers are financial applications (AFAIK they have their own rules for rounding that do not work with floating point). –  josefx May 28 '12 at 7:39
    
Yes, but they only ever use integers. –  Steven Burnap May 28 '12 at 16:08

Real number arithmetic becomes really easy and considerably more accurate!

No, it doesn't. The struct you describe only handles rational numbers, i.e. those that can be expressed as fractions. The set of real numbers includes both rational and irrational numbers. Most real-world calculations are done using real numbers, so you can't just limit yourself to the rationals and expect everything to be fine.

I am wondering why no language I know does it.

Most of the languages that I can think of make it possible to do exactly what you describe. In C, you can create a struct that contains numerator and denominator, and you can define a bunch of functions that operate on such structs. C++ makes things a LOT easier by letting you define a class and operations on that class -- same idea, much nicer syntax, etc. In fact, different sets of numbers are often used as examples in OO languages: you might start by defining a Rational class, and then extend that to include Imaginary numbers, and so on.

I'd guess that the reason that there aren't more languages with built-in support for exact types probably has to do with the fact that processors don't directly support such operations. Modern processors include instructions that implement arithmetic operations for floating point types, so it's easy to include those in any language. Supporting exact types would mean building a math library into the language, and it's probably better on several levels to leave the math library out of the language and let those who need it build it into their software.

If you're going to go to all the trouble to produce exact results, you probably don't want to limit yourself just to rationals, so the struct you give as an example isn't going to cut it. Being able to do exact calculations on rationals isn't very helpful if you fall back to inexact results the first time an irrational number shows up. Fortunately, there are sophisticated math systems out there. Mathematica is one well-known example.

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I'd say this should be a comment and not an answer as with a minor, one-word modification to the OP it becomes a valid question again (that is: real number -> rational number). –  Mahmoud Al-Qudsi May 27 '12 at 3:29
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@MahmoudAl-Qudsi Expanded the answer. "Fixing" the question leads directly to the answer -- support for rationals isn't built in because rational numbers by themselves aren't all that useful in real-world calculation. –  Caleb May 27 '12 at 4:02
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While the set of real numbers includes both rational and irrational numbers, standard datatypes can only handle rational numbers. A float is internally two values, an integar numerator and a denominator that is a power of ten. Thus it is always a rational. –  Steven Burnap May 27 '12 at 4:14
    
@StevenBurnap That's certainly true, but we think of floats as limited-precision representations of reals. The representation is rational but the number being represented may not be. –  Caleb May 27 '12 at 4:23
    
Same could be said for the proposal, though. 355/113 is a rational approximation of pi as is 31415926/10000000. Both are "limited-precision representations of reals". –  Steven Burnap May 27 '12 at 5:26

Strap on your helmets, because we're about to get theoretical up in here.

Any math undergrad could give you an elevator explanation of Cantor's proof of the uncountable cardinality of the real numbers. For a longer explanation, go here.

But as Caleb pointed out, the real number field contains both rational and irrational numbers. This means that some subset of the real number field will never be representable as a numerator/denominator pair. How big is this subset? As it turns out, most real numbers are irrational, because the set of rationals is countable.

Here's the punchline: Storing numbers in this way would be very silly because most outputs of real-valued functions cannot be stored as a numerator and a denominator.

This may seem hard to believe, but think about common transcendental functions, e.g. sin, cos, log. Most outputs of these functions aren't rational, and the guys who wrote IEEE 754 and other early FP stuff knew this. They figured that dealing with a small amount of error in exchange for the possibility of representing (with some truncation) a much larger portion of the real number field was a good design tradeoff.

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1  
The question is about rational number. While I agree on the argument about real number, your answer is a bit off-topic. –  nhahtdh May 27 '12 at 4:00
    
Addendum: Also consider that many commonly-used transcendental functions are implemented using interpolation on lookup tables or using a finite sequence approximation, which means that error exists in the outputs anyway. –  pg1989 May 27 '12 at 4:01
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Since irrational numbers can't be represented using a finite decimal (or binary) representation (see Wikipedia), actually a (IEEE 754) float can represent no irrational number. –  Florian Sowade May 27 '12 at 4:01
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Partially, yeah. As I said before, some very basic theoretical arguments show that it's a classic example of a very poor engineering decision, namely because it is a large investment of time and energy for a minute gain in narrow use cases. –  pg1989 May 27 '12 at 4:13
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Your punchline can be modified to apply to IEEE 754 values. "Storing numbers in this way would be very silly because most outputs of real-valued functions cannot be stored as an exponent and a finite precision fraction." I believe this shows that your conclusion does not follow from the proposition. Using a numerator/denominator pair may be silly, but not for this reason. –  bames53 May 31 '12 at 19:37

C++ at least includes a compile time rational arithmetic library. Here's an example:

#include <ratio>
#include <iostream>

int main() {
    using a = std::ratio<3,5>;
    using b = std::ratio<7,6>;

    using c = std::ratio_multiply<a,b>::type;

    std::cout << c::num << '/' << c::den << '\n'; // prints 7/10
}

Here we multiply 3/5 by 7/6 and get 7/10.

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Many CPUs have special treatment for floating points (see Wikipedia) and the float data type in the language ensures programs can utilize the FPU in an easy way. On the other hand I don't know of any CPU which can handle Fractions with special assembler instructions so fractions can easily and efficiently be implemented inside a library and don't have to be a language feature. If you want to use fractions in C++, you can use Boost.Rational.

The Reason why modern CPUs implement floating point arithmetic instead of handling fractions is that floating points can be implemented much more easily. To implement the basic float operations you basically need to be able to add, subtract multiply and divide integers and do some bit shifting. To compare to fractions on the other hand you need to find the greatest common divisor of two ints, which is much harder to implement in hardware.

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Isn't this argument circular? I think the OP was asking about the original design decisions related to FP. Modern CPUs have FP instructions because of the prevalence of floating point numbers. –  pg1989 May 27 '12 at 3:40
    
Lack of hardware support is definitely a major reason, but I'd say it likely goes much farther than that. vector's aren't supported by hardware, yet C++ includes those. There's a relatively low demand for a 'fraction' class, and a basic one is extremely easy to make. I would imagine that definitely factors in as well. –  Corbin May 27 '12 at 3:41
    
On the other hand I think there are better ways to store floats than link, but since it has been used since many years and is implemented in most modern CPUs it is hard to replace it with a different standard. –  Florian Sowade May 27 '12 at 3:41
    
@Corbin I think the reason not to include it in the standard is because there was no proposal yet. Classes like std::enable_if are really easy to implement, too, but are in the standard anyway. –  Florian Sowade May 27 '12 at 3:43
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There is a proposal: open-std.org/jtc1/sc22/wg21/docs/papers/2012/n3363.html –  Benjamin Lindley May 27 '12 at 4:12

Contrary to many of the answers you've gotten, your idea is good for many kinds of problems. Especially problems like this one in which you know that there will be a lot of cancelling, and want an exact answer. For this reason, Python has the fractions module, and as @bames53 points out, C++ has <ratio>.

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“Hence my question: Why aren't rational numbers implemented and stored as fractions with zero loss of information?”

The C++ standard library lacks many practically necessary types that other languages and libraries offer. The Boost library already offers a rational number implementation. And it appears that it may shortly also offer the proposed decimal types, e.g. for handling currency amounts.

As to why those types are lacking, the C++ standard library generally just provides bare bones general building blocks, not the more practically useful things that one would build with those blocks. I.e. it's minimalistic. The Boost library is just a tad less minimalistic, and then e.g. the Poco library is more like other languages’ more functionally rich standard libraries.

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There are a few reasons:
- No support from common architecture. This is understandable, since fraction must always comes with simplification. This is not trivial to be implemented at hardware level, or rather, it will be an instruction without much application.
- Cannot handle very big or very small numbers. Or BigInteger must involve. And for very big or very small numbers, we usually don't need most of the precision provided.
- If this is a type supported at the language level, it must support conversion with other numeric types. It must decide when to return floating type if the internal representation has fixed precision (in case of multiplication).

In a language, the decision to support something is usually decided by its application (or the rationale of the language). If the application is small, it has less chance to be supported.

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