Basically, you can't.

The range of representable values for `int64_t`

is -2^{63} to +2^{63}-1. (And the standard requires `int64_t`

to have a pure 2's-complement representation; if that's not supported, an implementation just won't define `int64_t`

.)

That extra negative value has no corresponding representable positive value.

So unless your system has an integer type bigger than 64 bits, you're just not going to be able to represent the absolute value of `0x8000000000000000`

as an integer.

In fact, your program's behavior is undefined according to the ISO C standard. Quoting section 7.22.6.1 of the N1570 draft of the 2011 ISO C standard:

The **abs**, **labs**, and **llabs** functions compute the absolute
value of an integer **j**. If the result cannot be represented, the
behavior is undefined.

For that matter, the result of

```
int64_t a = 0x8000000000000000;
```

is implementation-defined. Assuming `long long`

is 64 bits, that constant is of type `unsigned long long`

. It's implicitly converted to `int64_t`

. It's very likely, but not guaranteed, that the stored value will be -2^{63}, or `-9223372036854775808`

. (It's even permitted for the conversion to raise an implementation-defined signal, but that's not likely.)

(It's also theoretically possible for your program's behavior to be merely implementation-defined rather than undefined. If `long long`

is wider than 64 bits, then the evaluation of `llabs(a)`

is not undefined, but the conversion of the result back to `int64_t`

is implementation-defined. In practice, I've never seen a C compiler with `long long`

wider than 64 bits.)

If you really need to represent integer values that large, you might consider a multi-precision arithmetic package such as GNU GMP.