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Possible Duplicate:
Floating point inaccuracy examples

double a = 0.3;
std::cout << a << std::endl;

result: 0.2999999999999999889

double a, b;
a = 0.3;
b = 0;
for (char i = 1; i <= 50; i++) {
  b = b + a;
std::cout << b << std::endl;

result: 15.000000000000014211

So.. 'a' is smaller than it should be. But if we take 'a' 50 times - result will be bigger than it should be.

Why is this? And how to get correct result in this case?

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marked as duplicate by Greg Hewgill, James McNellis, Jim Lewis, Paul R, Matthew Flaschen May 26 '10 at 8:30

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

Go and read about it. Floating-point issues need careful study so that you don't make dangerous mistakes. – Artelius May 26 '10 at 0:26
to have exact values use integers instead (or some bignum lib) const int acc=100; int tmp, a=30/acc, b=0; for (char i=1;i<=50;i++) b=b+a; std::cout << int(b/acc) << "."; tmp=b%acc; if (tmp<10) std::cout << "0"; std::cout << int (tmp); to speed things up you can use a power of 2 for acc so *,/,% converts to <<,>>,& – Spektre Aug 20 '13 at 13:07
up vote 13 down vote accepted

To get the correct results, don't set precision greater than available for this numeric type:

#include <iostream>
#include <limits>
int main()
        double a = 0.3;
        std::cout << a << std::endl;
        double b = 0;
        for (char i = 1; i <= 50; i++) {
                  b = b + a;
        std::cout << b << std::endl;

Although if that loop runs for 5000 iterations instead of 50, the accumulated error will show up even with this approach -- it's just how floating-point numbers work.

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+1 for numeric_limits are definitively not enough known as they should be. – Kornel Kisielewicz May 26 '10 at 0:47

Why is this?

Because floating-point numbers are stored in binary, in which 0.3 is 0.01001100110011001... repeating just like 1/3 is 0.333333... is repeating in decimal. When you write 0.3, you actually get 0.299999999999999988897769753748434595763683319091796875.

Keep in mind that for the applications for which floating-point is designed, it's not a problem that you can't represent 0.3 exactly. Floating-point was designed to be used with:

  • Physical measurements, which are often measured to only 4 sig figs and never to more than 15.
  • Transcendental functions like logarithms and the trig functions, which are only approximated anyway.

For which binary-decimal conversions are pretty much irrelevant compared to other sources of error.

Now, if you're writing financial software, for which $0.30 means exactly $0.30, it's different. There are decimal arithmetic classes designed for this situation.

And how to get correct result in this case?

Limiting the precision to 15 significant digits is usually enough to hide the "noise" digits. Unless you actually need an exact answer, this is usually the best approach.

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Computers store floating point numbers in binary, not decimal.

Many numbers that look ordinary in decimal, such as 0.3, have no exact representation of finite length in binary.
Therefore, the compiler picks the closest number that has an exact binary representation, just like you write 0.33333 for 1⁄3.

If you add many floating-point numbers, these tiny difference add up, and you get unexpected results.

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I think the key answer for the OP is, "you can't get the correct result using floating point." :) – dash-tom-bang May 26 '10 at 1:20
You get the correct result. Admittably, not the result you were expecting. – MSalters May 26 '10 at 7:15

It's not that it's bigger or smaller, it's just that it's physically impossible to store "0.3" as an exact value inside a binary floating point number.

The way to get the "correct" result is to not display 20 decimal places.

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To get the "correct" result, try

List of Arbitrary-precision arithmetic Libraries from Wikipedia:


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Decimal and arbitrary-precision arithmetic is most likely unnecessary for the OP's purposes. – dan04 May 26 '10 at 5:09

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