I know of rolling hash functions that are similar to a hash on a bounded queue. Is there anything similar for stacks?
My use case is that I am doing a depth first search of possible program traces (with loop unrolling, so these stacks can get biiiiig) and I need to identify branching via these traces. Rather than store a bunch of stacks of depth 1000 I want to hash them so that I can index by int. However, if I have stacks of depth 10000+ this hash is going to be expensive, so I want to keep track of my last hash so that when I push/pop from my stack I can hash/unhash the new/old item respectively.
In particular, I am looking for a hash
h(Object, Hash) with an unhash
u(Object, Hash) with the property that for object
x to be hashed we have:
u(x, h(x, baseHash)) = baseHash
Additionally, this hash shouldn't be commutative, since order matters.
One thought I had was matrix multiplication over
GL(2, F(2^k)), maybe using a Cayley graph? For example, take two invertible matrices
A_1, with inverses
GL(2, F(2^k)), and compute the hash of an object
x by first computing some integer hash with bits
b31b30...b1b0, and then compute
H(x) = A_b31 . A_b30 . ... . A_b1 . A_b0
This has an inverse
U(x) = B_b0 . B_b1 . ... . B_b30 . B_31.
h(x, baseHash) = H(x) . baseHash and
u(x, baseHash) = U(x) . baseHash, so that
u(x, h(x, base)) = U(x) . H(x) . base = base,
This seems like it might be more expensive than is necessary, but for 2x2 matrices it shouldn't be too bad?