The now deleted answer by Pavan Manjunath had the correct answer for one case, assuming that `int`

is as usual a 32-bit type. The integer constant

```
0xffffffff
```

has the value `2^32 - 1`

and that isn't representable by an `int`

, but it is representable as an `unsigned int`

. So its type is `unsigned int`

(6.4.4.1). Hence `x`

is converted to `unsigned int`

for the addition, and

```
((~(x+0xffffffff))>>n)
```

evaluates as

```
((~(0x80000000u + 0xffffffffu)) >> n)
((~0x7fffffffu) >> n)
(0x80000000u >> n)
```

with the value `2^(31-n)`

if `0 <= n < 32`

(it's undefined behaviour if `n`

is outside that range).

For the other case, ouah's answer is correct, when `x = 0x80000000`

is an `int`

, `~0x8000000 = 0x7fffffff = INT_MAX`

and `INT_MAX + 1`

is undefined behaviour as signed integer overflow.

Nevertheless, a common behaviour is wrap-around, and then the result of the addition is the signed integer `0x80000000`

and right-shifting of negative integers is implementation-defined behaviour (6.5.7). Common is shifting with sign-extension, which would yield the result `-2^(31-n)`

, which then is interpreted as the `unsigned int`

with the value `2^32 - 2^(31-n)`

by the `printf`

conversion specifier `%x`

.

`(uint16_t)-1`

isguaranteed by the standard to produce`0xFFFF`

if the implementation provides that type in`stdint.h`

. (Of course, nothing is guaranteed if it's your own typedef.) There's no ambiguity, the fixed-width types are required to have no padding bits, so it isn't even restricted to the value bits (well, it is, since there are only value bits in`uintN_t`

). – Daniel Fischer Jun 4 '12 at 18:39