Imagine you have a data type that's only 3 bits wide. This allows you to represent 8 distinct values, from 0 through 7. If you add 1 to 7, you will "wrap around" back to 0, because you don't have enough bits to represent the value 8 (1000).

This behavior is well-defined for unsigned types. It is *not* well-defined for signed types, because there are multiple methods for representing signed values, and the result of an overflow will be interpreted differently based on that method.

Sign-magnitude: the uppermost bit represents the sign; 0 for positive, 1 for negative. If my type is three bits wide again, then I can represent signed values as follows:

```
000 = 0
001 = 1
010 = 2
011 = 3
100 = -0
101 = -1
110 = -2
111 = -3
```

Since one bit is taken up for the sign, I only have two bits to encode a value from 0 to 3. If I add 1 to 3, I'll overflow with -0 as the result. Yes, there are two representations for 0, one positive and one negative. You won't encounter sign-magnitude representation all that often.

One's-complement: the negative value is the bitwise-inverse of the positive value. Again, using the three-bit type:

```
000 = 0
001 = 1
010 = 2
011 = 3
100 = -3
101 = -2
110 = -1
111 = -0
```

I have three bits to encode my values, but the range is [-3, 3]. If I add 1 to 3, I'll overflow with -3 as the result. This is different from the sign-magnitude result above. Again, there are two encodings for 0 using this method.

Two's-complement: the negative value is the bitwise inverse of the positive value, plus 1. In the three-bit system:

```
000 = 0
001 = 1
010 = 2
011 = 3
100 = -4
101 = -3
110 = -2
111 = -1
```

If I add 1 to 3, I'll overflow with -4 as a result, which is different from the previous two methods. Note that we have a slightly larger range of values [-4, 3] and only one representation for 0.

Two's complement is probably the most common method of representing signed values, but it's not the only one, hence the C standard can't make any guarantees of what will happen when you overflow a signed integer type. So it leaves the behavior *undefined* so the compiler doesn't have to deal with interpreting multiple representations.

`-fSomething`

switch is used when compiling, then the result is wrapped in two’s complement.” Or, if GCC does not state this, then Fred Doe can check out the GCC sources, modify them as desired, and issue a new Fred-specific version of GCC that behaves in a particular way.