Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

sorry if dumb but could not find an answer.

#include <iostream>

using namespace std;

int main()
double a(0);
double b(0.001);
cout << a - 0.0 << endl;
for (;a<1.0;a+=b);
cout << a - 1.0 << endl;
for (;a<10.0;a+=b);
cout << a - 10.0 << endl;
cout << a - 10.0-b << endl;
return 0;


Tried compiling it with MSVC9, MSVC10, Borland C++ 2010. All of them arrive in the end to the error of about 1e-13. Is it normal to have such a significant error accumulation over only a 1000, 10000 increments?

share|improve this question
home.comcast.net/~tom_forsyth/… (not me, heh) –  dash-tom-bang May 7 '10 at 1:51

4 Answers 4

up vote 12 down vote accepted

Yes, this is normal numeric representation floating point error. It has to do with the fact that the hardware must approximate most floating point numbers, rather than storing them exactly. Thus, the compiler you use should not matter.

What Every Computer Scientist Should Know About Floating-Point Arithmetic

share|improve this answer
Thanks, I do understand truncation error and all the other crap. Done a lot of theoretical work on numerical methods but I just never checked it myself and was very surprised to find out how large it is... –  Andrew May 7 '10 at 1:35
Well, a double gives you roughly 16 decimal digits of precision, that that's about right. When you loop 1000 times, you're down to 13 or so digits of precision. –  WhirlWind May 7 '10 at 1:39
Mind that it's particularly painful only with irrational (in base 2) numbers. If you use powers of two you'll be fine. E.g. if your adder was 0.5, 0.25, 0.125, 0.0625, etc., they will eventually add up exactly to 1.0, as these values in base 2 are 0.1, 0.01, 0.001, and 0.0001. –  dash-tom-bang May 7 '10 at 1:55
@dash-tom-bang Good point, though I'd argue if you're doing that sort of thing, you might be better off fitting into integer arithmetic. –  WhirlWind May 7 '10 at 2:00
@ WhirlWind: somewhere deep in my heart I was expecting it to accumulate slower than linearly due to randomness of the error nature but now I realize that was just a fantasy :) –  Andrew May 7 '10 at 2:21

This is why when using a floating point error you should never do:

if( foo == 0.0 ){
    //code here

and instead do

bool checkFloat(float _input, float _compare, float _epsilon){
    return ( _input + _epsilon > _compare ) && ( _input - _epsilon < _compare );
share|improve this answer
Checking against zero is fine in many circumstances as it can be exactly represented in the hardware, but of course it depends on what you're doing with it... Starting at 1 and subtracting .1 ten times will not lead to 0, of course. –  dash-tom-bang May 7 '10 at 1:53
That's very true but in most cases it's just not good practice. I like erring on the side of caution. –  wheaties May 7 '10 at 1:55
erring on the side of caution... funny ;) Or perhaps erring under the size of epsilon. –  WhirlWind May 7 '10 at 1:59

think about this. every operation introduces slight error, but next operation uses slightly faulty result. given enough iterations, you will deviate from true result. if you like, write your expressions in the form t0 = (t + y + e), t1 = (t0 + y +e) and figure out terms with epsilon. from their terms you can estimate approximate error.

there is also second source of error: at some point you are combining relatively small and relatively large numbers, towards the end. if you recall definition of machine precision, 1 + e = 1, at some point operations will be losing significant bits.

Hopefully this helps to clarify in laymen terms

share|improve this answer

This is the issue with floating point numbers—they're approximate, and weird things happen at zero (that is, weird representations appear). Because of this, some of the operations on numbers you take for granted have to be handled more delicately.

When comparing two numbers, you can't simply say a == b because one might be 0 and the other -1.03583e-13 due to the loss of precision along the floating point operations applied to get to a and b. You have to choose an arbitrary tolerance, like this: fabs(a,b) < 1e-8.

When printing a number, you often need to limit the number of digits printed. If you use printf, you can say printf("%g\n", a);, which won't print things like -1.03583e-13 . I don't know if there's an iostream analog to %g; is there?

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.