1 research outputs found
CRAM: Efficient Hardware-Based Memory Compression for Bandwidth Enhancement
This paper investigates hardware-based memory compression designs to increase
the memory bandwidth. When lines are compressible, the hardware can store
multiple lines in a single memory location, and retrieve all these lines in a
single access, thereby increasing the effective memory bandwidth. However,
relocating and packing multiple lines together depending on the compressibility
causes a line to have multiple possible locations. Therefore, memory
compression designs typically require metadata to specify the compressibility
of the line. Unfortunately, even in the presence of dedicated metadata caches,
maintaining and accessing this metadata incurs significant bandwidth overheads
and can degrade performance by as much as 40%. Ideally, we want to implement
memory compression while eliminating the bandwidth overheads of metadata
accesses.
This paper proposes CRAM, a bandwidth-efficient design for memory compression
that is entirely hardware based and does not require any OS support or changes
to the memory modules or interfaces. CRAM uses a novel implicit-metadata
mechanism, whereby the compressibility of the line can be determined by
scanning the line for a special marker word, eliminating the overheads of
metadata access. CRAM is equipped with a low-cost Line Location Predictor (LLP)
that can determine the location of the line with 98% accuracy. Furthermore, we
also develop a scheme that can dynamically enable or disable compression based
on the bandwidth cost of storing compressed lines and the bandwidth benefits of
obtaining compressed lines, ensuring no degradation for workloads that do not
benefit from compression. Our evaluations, over a diverse set of 27 workloads,
show that CRAM provides a speedup of up to 73% (average 6%) without causing
slowdown for any of the workloads, and consuming a storage overhead of less
than 300 bytes at the memory controller