# Bitwise xor 0xFFFFFFFF?

I couldn't wrap my head around this:

def expr(a):
return ~(a ^ 0xFFFFFFFF), a ^ 0xFFFFFFFF, ~a, a

print(expr(0xFFFFFFFF))
print(expr(1))
print(expr(0))
print(expr(-1))


I understand ~a means two's complement of a, but a ^ 0xFFFFFFFF also flips all the bits, but python will interpret it as a large number. I know Python3 is using unbound integer size, how does that work? Can someone ELI5 (Explain Like I'm Five)?

Results:

(         -1,           0, -4294967296, 4294967295)
(-4294967295,  4294967294,          -2,          1)
(-4294967296,  4294967295,          -1,          0)
( 4294967295, -4294967296,           0,         -1)


UPDATE: I guess my question can be reduced to this: in C, 111...1 can represent -1, I got this, because it's 32 bits. In Python, the integer size is unlimited, how do you represent -1 in binary? 111...1 is a large positive integer, no?

Python extends this concept to negative numbers by saying that they have an infinite number of leading ones. So if you need to represent -37, that would be ...111011011, with as many ones as you need in front. Similarly, -1 is just ...1111. So if you XOR -1 with another Python integer, it will flip all of that number's bits, including its leading zeros or ones (as if you had used the tilde operator). Unfortunately, Python does not have a convenient binary notation for "infinite leading ones," so you cannot write (for instance) 0b...111 as an integer literal; you must use -1 instead, or invert it and write ~0b0.
0xFFFFFFFF is a large number; it's the hexadecimal representation of 232-1. Python's ints are represented internally as a linked list of C longs, allowing theoretically unbounded size. Bitwise XOR (^) in Python uses zero values for the bits more significant than those you've given, so the net result is that only the lower 32 bits are flipped, resulting in behavior that diverges from what you get in C, where there are only 32 bits and the net result is that 'all' the bits are flipped.