Goal: **Convert "15605632.68128593" to a double without losing accuracy**.

`atof()`

accomplished that to best the program could do. But since `15605632.68128593`

(a 16-digit number) is not *exactly* representable as a `double`

in your `C`

, it was approximated to `1.560563268128593080...e+07`

. Thus accuracy was lost, albeit a small loss.

The grief comes when attempting to print, thinking that what printed was the *exact* value of `x`

. Instead a rounded value was printed. Using the `%f`

specifier defaults to 6 places to the right of the '.' giving the reported `15605632.681286`

, a 14 digit number.

A better way to see all the significant digits for all `double`

is to use the `%e`

format with `DBL_DIG`

. DBL_DIG is the most number of digits to the right of the '.', in *decimal exponential notation* `%e`

, to show all the digits needed to "round-trip" a `double`

(string to double to string without a string difference). Since `%e`

always shows 1 digit to the left of '.', the print below shows 1 + DBL_DIG significant digits. DBL_DIG is 15 on my mine and many `C`

environments, but it vary.

If you wish to show *all* the significant digits, you need to qualify what is *significant*. The `nextafter()`

function shows the next representable `double`

. So we might want to show at least enough digits to distinguish x and the next x. I recommend `DBL_DIG + 3`

. although `DBL_DIG + 1`

may be sufficient.

The *exact* value the program use for your 1.560563268128593e+07` is about a 53 decimal digit number. There are few situations where you need to see all those digits. Even is you request lots of digits, at some point, printf() just gives you zeros.

```
#include <stdio.h>
#include <float.h>
#include <tgmath.h>
int main(int argc, char *argv[]) {
double x;
d=atof("15605632.68128593");
printf("%.*le\n",DBL_DIG, x); // All the digits that "round-trip" string-to-double-string w/o loss
printf("%.*le\n",DBL_DIG + 1, x); // All the significant digit "one-way" double-string
printf("%.*le\n",DBL_DIG + 1, nextafter(x, 2*x)); // The next representable double
printf("%.*le\n",DBL_DIG + 3, x); // What happens with a few more
printf("%.*le\n",DBL_DIG + 30, x); // What happens if you are a bit loony
return 0;
}
```

```
1.560563268128593e+07
1.5605632681285931e+07
1.5605632681285933e+07
1.560563268128593080e+07
1.560563268128593079745769500732421875000000000e+07
```