This will provide all six logic gate functions (including `nand`

) in a dictionary:

```
from operator import and_, or_, xor
gates = {g.__name__.rstrip('_'): g for g in (and_, or_, xor)}
gates = {**gates, **{f'n{k}': lambda a, b, _f=v: _f(a, b) ^ True for k, v in gates.items()}}
```

`x ^ y`

means `xor(x, y)`

. `x ^ True`

means `xor(x, True)`

which means `not x`

.

##### Usage

```
>>> gates
{'and': <function _operator.and_(a, b, /)>,
'or': <function _operator.or_(a, b, /)>,
'xor': <function _operator.xor(a, b, /)>,
'nand': <function __main__.<dictcomp>.<lambda>(a, b, _f=<built-in function and_>)>,
'nor': <function __main__.<dictcomp>.<lambda>(a, b, _f=<built-in function or_>)>,
'nxor': <function __main__.<dictcomp>.<lambda>(a, b, _f=<built-in function xor>)>}
>>> gates['and'](True, True)
True
>>> gates['and'](1, 1)
1
>>> gates['nand'](True, True)
False
>>> gates['nand'](1, 1)
0
```

`def nand(a, b): return not (a and b)`

?"Tree 2's x and y both are not the same as Tree 1's x and y"is an incorrect (and meaningless) placement of "both"