That's what `~`

does already. The tricky part is that Python has unlimited length integers, so when you invert a number it is sign extended with--at least conceptually speaking--an infinite number of 1's. Meaning you get negative numbers.

```
>>> bin(~0b101)
'-0b110'
>>> bin(~0b10101)
'-0b10110'
```

To convert these to unsigned numbers, you need to decide how many bits you care about. Maybe you are working with 8-bit bytes. Then you could AND them with a byte's worth of 1 bits:

```
>>> bin(~0b101 & 0xFF)
'0b11111010'
>>> bin(~0b10101 & 0xFF)
'0b11101010'
```

Or if you want to match the exact bit length of the input numbers, your solution is reasonable. For efficiency you could switch the exponent for a left shift. And it might be clearer to use `~`

and `&`

instead of `^`

.

```
>>> bin(~a & ((1 << a.bit_length()) - 1))
'0b10'
>>> bin(~b & ((1 << b.bit_length()) - 1))
'0b1010'
```

(I suspect a hardcoded mask like `& 0xFFFF`

will be the right solution in practice. I can't think of a good real world use case for the `bit_length()`

-based answer.)

`bin`

representation is confusing you.`~`

does invert the bits; it just inverts aninfinite numberof bits, making it impossible to represent textually.`bin`

thus does some messing around with`-`

to make it work, but it ends up hiding the fact all the bits are inversed. – Veedrac Sep 10 '14 at 2:59`a ^ 0xFFFF`

. – Bill Lynch Sep 10 '14 at 3:03`(1 << b.bit_length() - 1)`

is going to be faster than`(2 ** b.bit_length() - 1)`

- and yes, hardcode a mask if you can instead of calling`bit_length`

. – roippi Sep 10 '14 at 3:07