It works best if you provide a mask. That way you specify how far to sign extend.

```
>>> bin(-27 & 0b1111111111111111)
'0b1111111111100101'
```

Or perhaps more generally:

```
def bindigits(n, bits):
s = bin(n & int("1"*bits, 2))[2:]
return ("{0:0>%s}" % (bits)).format(s)
>>> print bindigits(-31337, 24)
111111111000010110010111
```

In basic theory, the actual width of the number is a function of the size of the storage. If it's a 32-bit number, then a negative number has a 1 in the MSB of a set of 32. If it's a 64-bit value, then there are 64 bits to display.

But in Python, integer precision is limited only to the constraints of your hardware. On my computer, this *actually works*, but it consumes 9GB of RAM just to store the value of **x**. Anything higher and I get a MemoryError. If I had more RAM, I could store larger numbers.

```
>>> x = 1 << (1 << 36)
```

So with that in mind, what binary number represents `-1`

? Python is well-capable of interpreting literally millions (and even billions) of bits of precision, as the previous example shows. In 2's complement, the sign bit extends all the way to the left, but in Python there is no pre-defined number of bits; there are as many as you need.

But then you run into ambiguity: does binary `1`

represent `1`

, or `-1`

? Well, it could be either. Does `111`

represent `7`

or `-1`

? Again, it could be either. So does `111111111`

represent `511`

, or `-1`

... well, both, depending on your precision.

Python needs a way to represent these numbers in binary so that there's no ambiguity of their meaning. The `0b`

prefix just says "this number is in binary". Just like `0x`

means "this number is in hex". So if I say `0b1111`

, how do I know if the user wants -1 or 15? There are two options:

**Option A:** *The sign bit*

You could declare that all numbers are signed, and the left-most bit is the sign bit. That means `0b1`

is -1, while `0b01`

is 1. That also means that `0b111`

is also -1, while `0b0111`

is 7. In the end, this is probably more confusing than helpful particularly because **most binary arithmetic is going to be unsigned anyway,** and people are more likely to run into mistakes by accidentally marking a number as negative because they didn't include an explicit sign bit.

**Option B:** *The sign indication*

With this option, binary numbers are represented unsigned, and negative numbers have a "-" prefix, just like they do in decimal. This is (a) more consistent with decimal, (b) more compatible with the way binary values are most likely going to be used. You lose the ability to specify a negative number using its two's complement representation, but remember that two's complement is a *storage implementation* detail, not a proper indication of the underlying value itself. It shouldn't have to be something that the user has to understand.

In the end, Option B makes the most sense. There's less confusion and the user isn't required to understand the storage details.