An IEEE double has 53 significant bits (that's the value of `DBL_MANT_DIG`

in `<cfloat>`

). That's approximately 15.95 decimal digits (log10(2^{53})); the implementation sets `DBL_DIG`

to 15, not 16, because it has to round down. So you have nearly an extra decimal digit of precision (beyond what's implied by `DBL_DIG==15`

) because of that.

The `nextafter()`

function computes the nearest representable number to a given number; it can be used to show just how precise a given number is.

This program:

```
#include <cstdio>
#include <cfloat>
#include <cmath>
int main() {
double x = 1.0/7.0;
printf("FLT_RADIX = %d\n", FLT_RADIX);
printf("DBL_DIG = %d\n", DBL_DIG);
printf("DBL_MANT_DIG = %d\n", DBL_MANT_DIG);
printf("%.17g\n%.17g\n%.17g\n", nextafter(x, 0.0), x, nextafter(x, 1.0));
}
```

gives me this output on my system:

```
FLT_RADIX = 2
DBL_DIG = 15
DBL_MANT_DIG = 53
0.14285714285714282
0.14285714285714285
0.14285714285714288
```

(You can replace `%.17g`

by, say, `%.64g`

to see more digits, none of which are significant.)

As you can see, the last displayed decimal digit changes by 3 with each consecutive value. The fact that the last displayed digit of `1.0/7.0`

(`5`

) happens to match the mathematical value is largely coincidental; it was a lucky guess. And the correct *rounded* digit is `6`

, not `5`

. Replacing `1.0/7.0`

by `1.0/3.0`

gives this output:

```
FLT_RADIX = 2
DBL_DIG = 15
DBL_MANT_DIG = 53
0.33333333333333326
0.33333333333333331
0.33333333333333337
```

which shows about 16 decimal digits of precision, as you'd expect.

`1/7`

is a rational number, but one whose denominator is not a power of 2. – Keith Thompson Apr 30 '13 at 23:28