The Mark & Compact algorithm, when using an in-heap break table for relocation, is said to require only constant space overhead. This seems quite obvious: It uses free space to store the break table, and by re-allocating the break table as objects are copied, it doesn't need
O(survivors) continuous words from the get-go. I also found mentions of a requirement that each object is at least as large as a single entry for the break table, which kinda makes sense too (though I quite can't put a finger on it, so if it's related to the core question, feel invited to elaborate!).
But it appears to me that it can't compact arbitrarily full heaps, and I haven't read anything confirming or denying this. Consider, as an extreme example, a heap with space for three objects (two words each) containing two live objects at in second and third two-word-block:
[0: empty] [2: object A] [4: object B]
I don't see how we could possibly compact this heap using the same algorithm. There are two objects, both slide left by one block, which necessitates a break table with two entries. But there's only space for one break table entry.
Of course, these situations only occur when the heap is mostly full, and in those cases, fragmentation is not a problem, so it doesn't diminish the usefulness of the algorithm. But I'd like to know how full exactly the heap can be for the break table to fit into the heap. I didn't find any mention of this in any of the presentations, articles, and course materials I've read. In fact, I didn't even find any requirement that the heap be at least x% empty, so I feel I must be missing something.