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

I wonder how calculators work with precision. For example the value of sin(M_PI) is not exactly zero when computed in double precision:

#include <math.h>
#include <stdio.h>

int main() {
    double x = sin(M_PI);
    printf("%.20f\n", x); // 0.00000000000000012246
    return 0;

Now I would certainly want to print zero when user enters sin(π). I can easily round somewhere on 1e–15 to make this particular case work, but that’s a hack, not a solution. When I start to round like this and the user enters something like 1e–20, they get a zero back (because of the rounding). The same thing happens when the user enters 1/10 and hits the = key repeatedly — when he reaches the rounding treshold, he gets zero.

And yet some calculators return plain zero for sin(π) and at the same time they can work with expressions such as (1e–20)/10 comfortably. Where’s the trick?

share|improve this question
Which calculators are you talking about? –  David Thornley Apr 26 '10 at 13:54
For example the calculator that ships with iPods and iPhones. –  zoul Apr 26 '10 at 14:01

4 Answers 4

up vote 3 down vote accepted

Desktop Calculators use arbitrary precision math libraries. Those can be configured to have much higher precision that double. Handheld calculators (tradition dedicated and mobile phones) use fixed precision math libraries.

If you want to print exactly zero, use width specifier

printf (%12.4d, number);
share|improve this answer
Can @~buratinas provide supporting evidence for the claim that calculators use arbitrary precision math libraries ? I think this is just plain wrong but I'm open to evidence that I am wrong. –  High Performance Mark Apr 26 '10 at 13:41
Depends on the calculator. For instance, Mathematica calculates in arbitrary precision (as stated by its documentation e.g. the Numeric Precision tutorial). I'm sure there are other calculators that do the same, as well as some that use high-precision (but not arbitrary precision) libraries and perhaps some that just do regular floating-point math. –  David Z Apr 26 '10 at 13:58
@David: Depends on the definition of 'calculator' then. I think calling Mathematica (or Maple or GMP etc) a calculator is very odd, I call my HP48SX a calculator. –  High Performance Mark Apr 26 '10 at 14:03
@Mark: Well, the question is asking about software calculators, and Mathematica is just a generalization of the same concept. Regardless of how you define "calculator," though, it's likely that different ones will use different precisions. –  David Z Apr 26 '10 at 15:35
@High Performance Mark: Default calculator on ubuntu uses arbitrary precision math library thus I chose to generalize the idea. –  user283145 Apr 28 '10 at 14:07

They may be using a lookup table to speed up their trig formulas. In that case the special numbers that work out nicely would probably just be in the table.

share|improve this answer

The trick is probably, as already said, that calculators will use arbitrary precision math libraries or lookup tables.

I'd also add that your code snippet works that way due to using floating point arithmetics, which as you probably know is not true math in the sense it's not precise - 1.0 + 0.1 != 1.1 (it's actually 1.1000000000000001) :)

share|improve this answer

Some answers can be found on this Calculator Precision page.

Among solutions are:

  • work in BCD
  • use lookup tables
  • use hidden digits, so that displayed digits are accurate
share|improve this answer
BCD is not really more accurate than binary; the advantage is that it mimics pencil-and-paper calculations, and therefore you get the exact same accuracy or inaccuracy. –  David Thornley Apr 26 '10 at 14:22
With binary, there is one source of inaccurracy more than BCD: this is the conversion of the result from base-2 to base-10. –  mouviciel Apr 27 '10 at 5:04
The relative precision indicated by a decimal number that's shown with e.g. six significant figures may vary from about one part per million (if the mantissa is 9.99999) to ten parts per million (if 1.00000), a nearly-tenfold variation. The relative precision of binary floating point numbers only varies by a factor of two. Thus, for the binary representation to be as accurate as the decimal in all cases, it must be ten (if not twenty) times as accurate in some cases. Using BCD doesn't really help, though; to ensure a certain level of relative precision in all intermediate calculations... –  supercat Aug 14 '13 at 17:15
...will in many cases end up requiring an "extra" digit; even then, the large variance in precision can often cause problems of its own. –  supercat Aug 14 '13 at 17:18

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.