The generic problem
Suppose you are coding a system that consists of a graph, plus graph rewrite rules that can be activated depending on the configuration of neighboring nodes. That is, you have a dynamic graph that grows/shrinks unpredictably during runtime. If you naively use
malloc, new nodes are going to be allocated in random positions in memory; after enough time, your heap will be a pointer spaghetti, giving you terrible cache efficiency. Is there any lightweight, incremental technique to make nodes that wire together stay close together in memory?
What I tried
The only thing I could think of is embedding the nodes in a cartesian space with some physical elastic simulation that repulsed/attracted nodes. That'd keep wired nodes together, but looks silly and I guess the overhead of the simulation would be bigger than the cache efficiency speedup.
The solid example
This is the system I'm trying to implement. This is a brief snippet of the code I'm trying to optimize in C. This repo is a prototypal, working implementation in JS, with terrible cache efficiency (and of the language itself). This video shows the system in action graphically.