I'd like to write a recursively memoizing Scheme interpreter. At any point during evaluation, the interpreter should be able to detect when it receives as arguments a pair of expression and environment that it has previously seen.
Plain memoization of
apply is inefficient. It would require looking up the arguments in a hash table on every call of
apply, which would require walking the entire (possibly big) arguments on hash table matches.
For example, assume that the interpreter evaluates the program
(car (list A))
where A evaluates to a big object. When the interpreter evaluates the application
(list A), it first evaluates
A individually. Before it applies
A, it looks up in its hash table whether it has seen this application before, walking the entire
A object to compute a hash. Later on, when the memoizing interpreter applies
car to the list containing A, it computes a hash for this list which again involves walking the entire A object.
Instead, I want to build an interpreter that incrementally builds up approximately unique hashes, avoiding recomputation where possible and providing a guarantee that collisions are unlikely.
For example, one could recursively extend each object that the interpreter operates on with the MD5 of its value, or, if it is a compound object, with the MD5 of its component hashes. An environment might store the hash for each of its variable/value entries, and the hash of the environment might be computed as a function of the individual hashes. Then, if an entry in the environment changes, it is not necessary to rewalk the entire environment to compute the new hash of the environment. Instead, only the hash of the changed variable/value pair needs to be recomputed and the global hash of the set of entry hashes needs to be updated.
Does there exist related work on incrementally building up approximately unique hashes, in particular in the context of recursive memoization and/or program evaluation?