Other than zero, the double precision value that comes closest to an exact multiple of π/2 is 6381956970095103 * 2^797, which is equal to:

```
(an odd integer) * π/2 + 2.983942503748063...e−19
```

Thus, for all double-precision values x, we have the bound:

```
|cos(x)| >= cos(2.983942503748063...e−19)
```

Note that this is a bound on the mathematically exact value, not on the value returned by the library function `cos`

. On a platform with a good-quality math library, this bound is sufficiently good that we can say that `cos(x)`

is not zero for any double-precision `x`

. In fact, it turns out that this is not unique to double; this property holds for all IEEE-754 basic types, if `cos`

is faithfully rounded.

However, that's not to say that this could never occur on a platform that had a spectacularly poor implementation of trigonometric argument reduction.

Even more importantly, it's critical to note that in your example `y`

can be infinite *without* `cos(a)`

being zero:

```
#include <math.h>
#include <stdio.h>
int main(int argc, char *argv[]) {
double a = 0x1.6ac5b262ca1ffp+849;
double h = 0x1.0p1022;
printf("cos(a) = %g\n", cos(a));
printf("h/cos(a) = %g\n", h/cos(a));
return 0;
}
```

compile and run:

```
scanon$ clang example.c && ./a.out
cos(a) = -4.68717e-19
h/cos(a) = -inf
```

`a`

is aprox. equal to`pi/2`

. – ja72 Jul 31 '11 at 11:06