Yes. In a C implementation where `double`

is IEEE-754 basic 64-bit binary floating-point (with 53-bit significands) and `long double`

has 64-bit significands, the output of:

```
#include <stdio.h>
int main(void)
{
long double x = 0x1p154L - 0x1p101L + 0x1p100L;
long double y = 0x1p153L + 0x1p101L - 0x1p100L;
long double z = x / y;
double X = x;
double Y = y;
double Z = X/Y;
printf("x = %La.\n", x);
printf("y = %La.\n", y);
printf("z = %La.\n", z);
printf("X = %a.\n", X);
printf("Y = %a.\n", Y);
printf("Z = %a.\n", Z);
printf("(double) z = %a.\n", (double) z);
}
```

is:

x = 0xf.ffffffffffffcp+150.
y = 0x8.0000000000004p+150.
z = 0xf.ffffffffffff4p-3.
X = 0x1p+154.
Y = 0x1p+153.
Z = 0x1p+1.
(double) z = 0x1.ffffffffffffep+0.

`x / y`

is performed with `long double`

precision, of course, rather than infinite precision, but it captures sufficient information to show the result with infinite precision would have the same end result—inserting `#include <math.h>`

and `z = nexttowardl(z, INFINITY);`

changes `(double) z`

to be `0x1.fffffffffffffp+0`

, but this is still not equal to `Z`

.