From the paper, Hoard allocates memory internally in superblocks as required by the per-processor heaps. When these heaps need a superblock they ask the global heap for an empty one. As superblocks are freed entirely by a per-processor heap, they are released to the global heap for reuse elsewhere, thus putting a bound on the memory allocated.
In terms of thread contention, the superblocks are only actively used in one per-processor heap at a time. Hoard then works to only serve memory from one superblock to one thread. Using this strategy Hoard is able to avoid most active false sharing:
When multiple threads make simultaneous requests for memory, the requests will always be satisﬁed from different superblocks, avoiding actively induced false sharing.
There exists the possibility that when a superblock becomes relatively empty (determined by an internal factor) it will be made available to another heap, which could result in passive false sharing as another thread may still retain references into the superblock. However, given the size of the superblocks, they've not found this to be common in practice:
Further, we have observed that in practice, superblocks released to the global heap are often completely empty, eliminating the possibility of false sharing.
Hoard handles fragmentation by a fairly common allocator strategy of pooling common allocation sizes and coalescing freed space.