3 research outputs found
Scalable Range Locks for Scalable Address Spaces and Beyond
Range locks are a synchronization construct designed to provide concurrent
access to multiple threads (or processes) to disjoint parts of a shared
resource. Originally conceived in the file system context, range locks are
gaining increasing interest in the Linux kernel community seeking to alleviate
bottlenecks in the virtual memory management subsystem. The existing
implementation of range locks in the kernel, however, uses an internal spin
lock to protect the underlying tree structure that keeps track of acquired and
requested ranges. This spin lock becomes a point of contention on its own when
the range lock is frequently acquired. Furthermore, where and exactly how
specific (refined) ranges can be locked remains an open question.
In this paper, we make two independent, but related contributions. First, we
propose an alternative approach for building range locks based on linked lists.
The lists are easy to maintain in a lock-less fashion, and in fact, our range
locks do not use any internal locks in the common case. Second, we show how the
range of the lock can be refined in the mprotect operation through a
speculative mechanism. This refinement, in turn, allows concurrent execution of
mprotect operations on non-overlapping memory regions. We implement our new
algorithms and demonstrate their effectiveness in user-space and kernel-space,
achieving up to 9 speedup compared to the stock version of the Linux
kernel. Beyond the virtual memory management subsystem, we discuss other
applications of range locks in parallel software. As a concrete example, we
show how range locks can be used to facilitate the design of scalable
concurrent data structures, such as skip lists.Comment: 17 pages, 9 figures, Eurosys 202