## Software Prefetching for Mark-Sweep Garbage Collection: Hardware Analysis and Software Redesign

#### Abstract

Tracing garbage collectors traverse references from live program variables, transitively tracing out the closure of live objects. Memory accesses incurred during tracing are essentially random: a given object may contain references to any other object. Since application heaps are typically much larger than hardware caches, tracing results in many cache misses. Technology trends will make cache misses more important, so tracing is a prime target for prefetching.

Simulation of Java benchmarks running with the Boehm-Demers-Weiser mark-sweep garbage collector for a projected hardware platform reveal high tracing overhead (up to 65% of elapsed time), and that cache misses are a problem. Applying Boehm’s default prefetching strategy yields improvements in execution time (16% on average with incremental/generational collection for GC-intensive benchmarks), but analysis shows that his strategy suffers from significant timing problems: prefetches that occur too early or too late relative to their matching loads. This analysis drives development of a new prefetching strategy that yields up to three times the performance improvement of Boehm’s strategy for GC-intensive benchmarks (27% average speedup), and achieves performance close to that of perfect timing (ie, few misses for tracing accesses) on some benchmarks. Validating these simulation results with live runs on current hardware produces average speedup of 6% for the new strategy on GC-intensive benchmarks with a GC configuration that tightly controls heap growth. In contrast, Boehm’s default prefetching strategy is ineffective on this platform.

@inproceedings{Cher+2004ASPLOS,
author = {Cher, Chen-Yong and Hosking, Antony L. and Vijaykumar, T. N.},
title = {Software Prefetching for Mark-Sweep Garbage Collection:
Hardware Analysis and Software Redesign},
booktitle = {ACM International Conference on Architectural Support for
Programming Languages and Operating Systemes},
series = {ASPLOS},
year = {2004},
pages = {199--210},
month = {October},
doi = {10.1145/1024393.1024417},
acm = {http://dl.acm.org/authorize?N93678},
gscholar = {27}
}