When an `unsigned int`

value is compared to `int`

value, the `int`

value is implicitly converted to `unsigned int`

type. The result of that conversion is congruent to the original value modulo 2^{N}, where `N`

is the number of value-forming bits in `unsigned int`

. This modulo equals to `UINT_MAX + 1`

.

For this reason initialization

```
unsigned int x = -1;
```

initializes `x`

with some unsigned value congruent to `-1`

modulo `UINT_MAX + 1`

. Incidentally, this is nothing else than `UINT_MAX`

. This value has `1`

in each value-forming bit of `unsigned int`

object. It works that way with any unsigned type.

Expression `~0`

is evaluated in the domain of `signed int`

type, and then `y`

is implicitly converted to `unsigned int`

in `x == y`

comparison. Apparently, on your platform the conversion produces the same `unsigned int`

value with all value-forming bits set to `1`

. Hence the equality.

Initialization

```
unsigned int x = -4;
```

initializes `x`

with some unsigned value congruent to `-4`

modulo `UINT_MAX + 1`

. In comparison `x == -4`

the right-hand side is converted to unsigned type by the very same rules. Hence the equality.

`(unsigned)(-1)`

to produce`UNIT_MAX`

on all platforms, regardless of whether they use 2's coimplement or not. – AnT Sep 30 '14 at 18:14