Funny enough, but you don't actually need to add any suffix to your hex constant in order for it to be treated correctly. Section 6.4.4.1 of the C standard and section 2.14.3 of the C++ standard contain the following table:

```
Suffix | Decimal Constant | Octal or Hexadecimal Constant
-------------+------------------------+------------------------------
none | int | int
| long int | unsigned int
| long long int | long int
| | unsigned long int
| | long long int
| | unsigned long long int
-------------+------------------------+------------------------------
u or U | unsigned int | unsigned int
| unsigned long int | unsigned long int
| unsigned long long int | unsigned long long int
-------------+------------------------+------------------------------
l or L | long int | long int
| long long int | unsigned long int
| | long long int
| | unsigned long long int
-------------+------------------------+------------------------------
Both u or U | unsigned long int | unsigned long int
and l or L | unsigned long long int | unsigned long long int
-------------+------------------------+------------------------------
ll or LL | long long int | long long int
| | unsigned long long int
-------------+------------------------+------------------------------
Both u or U | unsigned long long int | unsigned long long int
and ll or LL | |
```

This table tells us what type an integer constant will have. The integer constant's type will be the first type in which it the value fits.

This means that the compiler will iterate through the following types for the hexadecimal constant `0x800000000000000`

(it has no suffix, so it uses the "none" row, and it's a hex constant, so it uses the "Hexadecimal Constant" column), and it will use the first type which can store that value*:

`int`

: No, a 32-bit signed integer can't store this value.
`unsigned int`

: No, a 32-bit unsigned integer can't store this value.
`long int`

: No, a 32-bit signed integer can't store this value.
`unsigned long int`

: No, a 32-bit unsigned integer can't store this value.
`long long int`

: No, a 64-bit signed integer can't store this value.
`unsigned long long int`

: *Yes*, a 64-bit unsigned integer *can* store this value. Since this is the first type that can fully store the value, this is the type that the integer constant will have.

So, to answer your question of "How can I write and use the value `0x800000000000000`

and make sure the compiler won't treat the high bit as a sign bit?": Simply just write `unsigned long long value = 0x800000000000000`

.

If you want to do some bitwise arithmetic with the value, you can just go ahead and do that (i.e. just write `0x800000000000000 >> myval`

). You're guaranteed that it will not be treated as an overflowed signed integer, and your right shift won't do any sign extension because it's a positive value.

_{*I'm assuming that int is 32-bits, long is 32-bits, and long long is 64-bits. Note that your compiler might use different bit sizes for these types, which may change the end result (though the process will still be the same).}

`limits.h`

has the syntax`0xffffffffffffffffui64`

, so`0x800000000000000ui64`

should work. However, it's a newer version, so maybe it didn't work in Visual Studio 2008. – anatolyg Jul 21 '15 at 10:19`U`

can be`unsigned int`

,`unsigned long int`

, or`unsigned long long int`

for a hex integer constant.`UL`

can be either`unsigned long int`

or`unsigned long long int`

. See 6.4.4.1 of the C standard (or 2.14.3 of the C++ standard). Given that, I don't think the OP's example is incorrect or needs modification. – Cornstalks Mar 23 at 0:01