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Consider the following:

#include <iostream>
#include <cmath>
int main()
  using std::cout;
  using std::endl;

  const long double be2 = std::log(2);
  cout << std::log(8.0) / be2 << ", " << std::floor(std::log(8.0) / be2)
      << endl;

  cout << std::log(8.0L) / be2 << ", " << std::floor(std::log(8.0L) / be2)
      << endl;


  3, 2
  3, 3

Why does the output differ? What am I missing here?

Also here is the link to codepad: http://codepad.org/baLtYrmy

And I'm using gcc 4.5 on linux, if that's important.

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FYI, Visual C++ 2010 gives: 3, 3 and 3, 3. BTW, I needed to do "std::log(2.0)" instead of "std::log(2)" to avoid ambiguity. –  Branko Dimitrijevic Aug 11 '11 at 19:39
@Branko : VC++ treats long double as a synonym for double. –  ildjarn Aug 11 '11 at 19:40

3 Answers 3

up vote 4 down vote accepted

When I add this:


I get this output:

2.999999999999999839754918906642444653698, 2
3.00000000000000010039712117215771058909, 3

You're printing two values that are very close to, but not exactly equal to, 3.0. It's the nature of std::floor that its results can differ for values that are very close together (mathematically, it's a discontinuous function).

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#include <iostream>
#include <cmath>
#include <iomanip>

int main()
  using std::cout;
  using std::endl;

  const long double be2 = std::log(2);

  cout << setprecision (50)<<std::log(8.0)<<"\n";
  cout << setprecision (50)<<std::log(8.0L)<<"\n";
  cout << setprecision (50)<<std::log(8.0) / be2 << ", " << std::floor(std::log(8.0) / be2)
       << endl;
  cout << setprecision (50)<< std::log(8.0L) / be2 << ", " << std::floor(std::log(8.0L) / be2)
       << endl;

  return 0;

The output is:

2.9999999999999998397549189066424446536984760314226, 2
3.0000000000000001003971211721577105890901293605566, 3

If you check the output here, you will notice that there is a slight difference in the precision of the two outputs. These roundoff errors usually kick in on operations on float & double here while performing floor() and the results that appear are not what one feels they should be.

It is important to remember two attributes Precision & Rounding when you are working with float or double numbers.

You might want to read more about it in my answer here, the same reasoning applies here as well.

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I see no difference in the output –  BЈовић Aug 11 '11 at 19:34
@Vjo: I updated the answer with link. –  Alok Save Aug 11 '11 at 19:39

To expand on what Als is saying-

In the first case you are dividing an 8-byte double precision value by a 16-byte long double. In the second case you are dividing a 16-byte long double by a 16-byte long double. This results in a very small roundoff error which can be seen here:

cout << std::setprecision(20) << (std::log(8.0) / be2) << std::endl;
cout << std::setprecision(20) << (std::log(8.0L) / be2) << std::endl;

which yields:


Edit to say: in this case, sizeof is your friend (To see the difference in precision):

sizeof(std::log(8.0));  // 8
sizeof(std::log(8.0L)); // 16
sizeof(be2);            // 16
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8-bit doubles? Is that a typo, perhaps? –  molbdnilo Aug 11 '11 at 19:55
aye, it was, DOH! Thanks for pointing it out molbdnilo –  MarkD Aug 11 '11 at 20:08

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