```
#define ISUNSIGNED(a) (a >= 0 && ~a >= 0)
```

For a signed value which is positive, `a >= 0`

will be true (obviously) and `~a >= 0`

will be false since we've flipped the bits so the sign bit is now set, resulting in a negative value. The entire expression is therefore false.

For a signed value which is negative, `a >= 0`

will be false (obviously) and the rest of the expression will not be evaluated; the overall result for the expression is false.

For an unsigned value, `a >= 0`

will **always** be true (obviously, since unsigned values can't be negative). If we flip the bits then `~a >= 0`

is also true, since even with the most significant bit (the sign bit) set to 1, it's still treated as a positive value.

So, the expression returns true if the original value and its bitwise inverse are both positive, i.e. it's an unsigned value.

```
#define ISUNSIGNED(type) ((type)0 - 1 > 0)
```

This is to be called with a type rather than a value: `ISUNSIGNED(int)`

or `ISUNSIGNED(unsigned int)`

, for example.

For an `int`

, the code expands to

```
((int)0 - 1 > 0)
```

which is false, since `-1`

is not greater than `0`

.

For an `unsigned int`

, the code expands to

```
((unsigned int)0 - 1 > 0)
```

The signed `1`

and `0`

literals in the expression are promoted to `unsigned`

to match the first `0`

, so the entire expression is evaluated as an unsigned comparison. `0 - 1`

in unsigned arithmetic will wrap around resulting in the largest possible unsigned value (all bits set to 1), which is greater than 0, so the result is true.

As to why it would work with K&R C, but not ANSI C, maybe this article can shed some light:

When an unsigned char or unsigned short is widened, the result type is
int if an int is large enough to represent all the values of the
smaller type. Otherwise, the result type is unsigned int. The value
preserving rule produces the least surprise arithmetic result for most
expressions.

I guess that means that when comparing an `unsigned short`

to `0`

, for example, the unsigned value is converted to a `signed int`

which breaks the behaviour of the macro.

You can probably work around this by having `(a-a)`

which evaluates to either signed or unsigned zero as appropriate, instead of the literal `0`

which is always signed.

`a >= 0`

only is not enough. – Felix Kling Sep 19 '11 at 11:06values, notrepresentations. The only exceptions areunsigned integral values, for which you can assume the specific binary representation to be what you always thought it was. Consequently, you should only use bitwise operations on unsigned integral types. Everything else will give you unpredictable (implementation-defined or undefined) results. – Kerrek SB Sep 19 '11 at 11:16`(1?-1:(a))<0`

. Also note that all of these methods will fail for smaller-than-int types due to integer promotion issues. – R.. Sep 19 '11 at 12:29