I think the following works, but I will state my assumptions first:

- floating-point numbers are stored in IEEE-754 format on your implementation,
- No overflow,
- You have
`nextafterf()`

available (it's specified in C99).

Also, most likely, this method is not very efficient.

```
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
int main(int argc, char *argv[])
{
/* Change to non-zero for superior, otherwise inferior */
int superior = 0;
/* double value to convert */
double d = 0.1;
float f;
double tmp = d;
if (argc > 1)
d = strtod(argv[1], NULL);
/* First, get an approximation of the double value */
f = d;
/* Now, convert that back to double */
tmp = f;
/* Print the numbers. %a is C99 */
printf("Double: %.20f (%a)\n", d, d);
printf("Float: %.20f (%a)\n", f, f);
printf("tmp: %.20f (%a)\n", tmp, tmp);
if (superior) {
/* If we wanted superior, and got a smaller value,
get the next value */
if (tmp < d)
f = nextafterf(f, INFINITY);
} else {
if (tmp > d)
f = nextafterf(f, -INFINITY);
}
printf("converted: %.20f (%a)\n", f, f);
return 0;
}
```

On my machine, it prints:

```
Double: 0.10000000000000000555 (0x1.999999999999ap-4)
Float: 0.10000000149011611938 (0x1.99999ap-4)
tmp: 0.10000000149011611938 (0x1.99999ap-4)
converted: 0.09999999403953552246 (0x1.999998p-4)
```

The idea is that I am converting the `double`

value to a `float`

value—this could be less than or greater than the double value depending upon the rounding mode. When converted back to `double`

, we can check if it is smaller or greater than the original value. Then, if the value of the `float`

is not in the right direction, we look at the next `float`

number from the converted number in the original number's direction.