There is an implicit even if there is no explicit relationship forced between immutable and hashable due the interplay between
- Hashable objects which compare equal must have the same hash value
- An object is hashable if it has a hash value which never changes during its lifetime.
There is no problem here unless you redefine
__eq__ so the the objects class defines equivalence on value.
Once you've done that you need to find a stable hash function which always returns the same value for objects which represent the same value (eg, where
__eq__) returns True, and never changes during the lifetime of an object.
It hard to see an application where this is possible, consider a possible class A which meets these requirements. Although there is the obvious degenerate case where
__hash__ returns a constant.
>>> a = A(1)
>>> b = A(1)
>>> c = A(2)
>>> a == b
>>> a == c
>>> hash(a) == hash(b)
>>> a == c
>>> assert(hash(a) == hash(c)) # Because a == c => hash(a) == hash(c)
>>> assert(hash(a) == hash(b)) # Because hash(a) and hash(b) have compared equal
before and the result must stay static over the objects lifetime.
In fact this means at creation hash(b) == hash(c), despite the fact there are never compared equal. I struggle to see anyway to usefully define
__hash__() for a mutable object which defines compare by value.
__ge__ comparsions aren't affected so you can still define an ordering of hashable objects, mutable or otherwise based on their value.