Operating systems use lock managers to organise and serialise the access to resources. A distributed lock manager (DLM) runs in every machine in a cluster, with an identical copy of a cluster-wide lock database. In this way a DLM provides software applications which are distributed across a cluster on multiple machines with a means to synchronize their accesses to shared resources.

DLMs have been used as the foundation for several successful clustered file systems, in which the machines in a cluster can use each other's storage via a unified file system, with significant advantages for performance and availability. The main performance benefit comes from solving the problem of disk cache coherency between participating computers. The DLM is used not only for file locking but also for coordination of all disk access. VMScluster, the first clustering system to come into widespread use, relied on the OpenVMS DLM in just this way.

Resources

The DLM uses a generalized concept of a resource, which is some entity to which shared access must be controlled. This can relate to a file, a record, an area of shared memory, or anything else that the application designer chooses. A hierarchy of resources may be defined, so that a number of levels of locking can be implemented. For instance, a hypothetical database might define a resource hierarchy as follows:

  • Database
  • Table
  • Record
  • Field

A process can then acquire locks on the database as a whole, and then on particular parts of the database. A lock must be obtained on a parent resource before a subordinate resource can be locked.

Lock modes

A process running within a VMSCluster may obtain a lock on a resource. There are six lock modes that can be granted, and these determine the level of exclusivity being granted, it is possible to convert the lock to a higher or lower level of lock mode. When all processes have unlocked a resource, the system's information about the resource is destroyed.

  • Null (NL). Indicates interest in the resource, but does not prevent other processes from locking it. It has the advantage that the resource and its lock value block are preserved, even when no processes are locking it.
  • Concurrent Read (CR). Indicates a desire to read (but not update) the resource. It allows other processes to read or update the resource, but prevents others from having exclusive access to it. This is usually employed on high-level resources, in order that more restrictive locks can be obtained on subordinate resources.
  • Concurrent Write (CW). Indicates a desire to read and update the resource. It also allows other processes to read or update the resource, but prevents others from having exclusive access to it. This is also usually employed on high-level resources, in order that more restrictive locks can be obtained on subordinate resources.
  • Protected Read (PR). This is the traditional share lock, which indicates a desire to read the resource but prevents other from updating it. Others can however also read the resource.
  • Protected Write (PW). This is the traditional update lock, which indicates a desire to read and update the resource and prevents others from updating it. Others with Concurrent Read access can however read the resource.
  • Exclusive (EX). This is the traditional exclusive lock which allows read and update access to the resource, and prevents others from having any access to it.

The following truth table shows the compatibility of each lock mode with the others:

ModeNLCRCWPRPWEX
NL YesYesYesYesYesYes
CR YesYesYesYesYesNo
CW YesYesYesNoNoNo
PR YesYesNoYesNoNo
PW YesYesNoNoNoNo
EX YesNoNoNoNoNo

Obtaining a lock

A process can obtain a lock on a resource by enqueueing a lock request. This is similar to the QIO technique that is used to perform I/O. The enqueue lock request can either complete synchronously, in which case the process waits until the lock is granted, or asynchronously, in which case an AST occurs when the lock has been obtained.

It is also possible to establish a blocking AST, which is triggered when a process has obtained a lock that is preventing access to the resource by another process. The original process can then optionally take action to allow the other access (e.g. by demoting or releasing the lock).

Lock value block

A lock value block is associated with each resource. This can be read by any process that has obtained a lock on the resource (other than a null lock) and can be updated by a process that has obtained a protected update or exclusive lock on it.

It can be used to hold any information about the resource that the application designer chooses. A typical use is to hold a version number of the resource. Each time the associated entity (e.g. a database record) is updated, the holder of the lock increments the lock value block. When another process wishes to read the resource, it obtains the appropriate lock and compares the current lock value with the value it had last time the process locked the resource. If the value is the same, the process knows that the associated entity has not been updated since last time it read it, and therefore it is unnecessary to read it again. Hence, this technique can be used to implement various types of cache in a database or similar application.

Deadlock detection

When one or more processes have obtained locks on resources, it is possible to produce a situation where each is preventing another from obtaining a lock, and none of them can proceed. This is known as a deadlock (E. W. Dijkstra originally called it a deadly embrace).[1]

A simple example is when Process 1 has obtained an exclusive lock on Resource A, and Process 2 has obtained an exclusive lock on Resource B. If Process 1 then tries to lock Resource B, it will have to wait for Process 2 to release it. But if Process 2 then tries to lock Resource A, both processes will wait forever for each other.

The OpenVMS DLM periodically checks for deadlock situations. In the example above, the second lock enqueue request of one of the processes would return with a deadlock status. It would then be up to this process to take action to resolve the deadlock—in this case by releasing the first lock it obtained.

Linux clustering

Both Red Hat and Oracle have developed clustering software for Linux.

OCFS2, the Oracle Cluster File System was added[2] to the official Linux kernel with version 2.6.16, in January 2006. The alpha-quality code warning on OCFS2 was removed in 2.6.19.

Red Hat's cluster software, including their DLM and GFS2 was officially added to the Linux kernel [3] with version 2.6.19, in November 2006.

Both systems use a DLM modeled on the venerable VMS DLM.[4] Oracle's DLM has a simpler API. (the core function, dlmlock(), has eight parameters, whereas the VMS SYS$ENQ service and Red Hat's dlm_lock both have 11.)

Other implementations

Other DLM implementations include the following:

  • Google has developed Chubby, a lock service for loosely coupled distributed systems.[5] It is designed for coarse-grained locking and also provides a limited but reliable distributed file system. Key parts of Google's infrastructure, including Google File System, Bigtable, and MapReduce, use Chubby to synchronize accesses to shared resources. Though Chubby was designed as a lock service, it is now heavily used inside Google as a name server, supplanting DNS.[5]
  • Apache ZooKeeper, which was created at Yahoo, is open-source software and can be used to perform distributed locks[6] as well.
  • Etcd is open-source software, developed at CoreOS under the Apache License.[7] It can be used to perform distributed locks as well.[8]
  • Redis is an open source, BSD licensed, advanced key-value cache and store.[9] Redis can be used to implement the Redlock Algorithm for distributed lock management.[10]
  • HashiCorp's Consul,[11] which was created by HashiCorp, is open-source software and can be used to perform distributed locks as well.
  • Taooka distributed lock manager[12] uses the "try lock" methods to avoid deadlocks. It can also specify a TTL for each lock with nanosecond precision.
  • A DLM is also a key component of more ambitious single system image (SSI) projects such as OpenSSI.

References

  1. Gehani, Narain (1991). Ada: Concurrent Programming. Silicon Press. p. 105. ISBN 9780929306087.
  2. kernel/git/torvalds/linux.git - Linux kernel source tree. Kernel.org. Retrieved on 2013-09-18.
  3. kernel/git/torvalds/linux.git - Linux kernel source tree Archived 2012-07-18 at archive.today. Git.kernel.org (2006-12-07). Retrieved on 2013-09-18.
  4. The OCFS2 filesystem. Lwn.net (2005-05-24). Retrieved on 2013-09-18.
  5. 1 2 Google Research Publication: Chubby Distributed Lock Service. Research.google.com. Retrieved on 2013-09-18.
  6. . Zookeeper.apache.org. Retrieved on 2013-09-18.
  7. "CoreOS". coreos.com.
  8. etcd: Distributed reliable key-value store for the most critical data of a distributed system, CoreOS, 2018-01-16, retrieved 2016-09-20
  9. redis.io http://redis.io/. Retrieved 2015-04-14. {{cite web}}: Missing or empty |title= (help)
  10. "Distributed locks with Redis – Redis". redis.io. Retrieved 2015-04-14.
  11. Consul Overview. Retrieved on 2015-02-19.
  12. Taooka Description Retrieved on 2017-05-04.
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