OpenSSI

OpenSSI
Developer(s) OpenSSI Team[1]
Stable release 1.9.3 [1] / 1 September 2007
Preview release 1.9.6 [1] / 18 February 2010
Operating system Linux
Type Cluster software
License GPL
Website openssi.org

OpenSSI is an open source single-system image clustering system. It allows a collection of computers to be treated as one large system, allowing applications running on any one machine access to the resources of all the machines in the cluster. [2] [3]

OpenSSI is based on the Linux operating system and was released as an open source project by Compaq in 2001. [4] It is the final stage of a long process of development, stretching back to LOCUS, developed in the early 1980s.

Description

OpenSSI allows a cluster of individual computers (nodes) to be treated as one large system. Processes run on any node have full access to the resources of all nodes. Processes can be migrated from node to node automatically to balance system utilization. Inbound network connections can be directed to the least loaded node available.

OpenSSI is designed to be used for both high performance and high availability clusters. It is possible to create an OpenSSI cluster with no single point of failure, for example the file system can be mirrored between two nodes, so if one node crashes the process accessing the file will fail over to the other node. Alternatively the cluster can be designed in such a manner that every node has direct access to the file system.

Features

Single Process space

OpenSSI provides a single process space - every process is visible from every node, and can be managed from any node using the normal Linux commands (ps, kill, renice and so on). The Linux /proc virtual filesystem shows all running processes on all nodes.

The implementation of the single process space is accomplished using the VPROC abstraction invented by Locus for the OSF/1 AD operating system.

Migration

OpenSSI allows migration of running processes between nodes. When running processes are migrated they continue to have access to any open files, IPC objects or network connections.

Processes can be manually migrated, either by the process calling the special OpenSSI migrate(2) system call, or by writing a node number to a special file in the processes /proc directory.

Processes may also, if the user wants, be automatically migrated in order to balance load across the cluster. OpenSSI uses an algorithm developed by the MOSIX project for determining the load on each node.

Single root

OpenSSI provides a single root for the cluster - from any node the same files and directories are available. OpenSSI uses several mechanisms to provide the single root - CFS (the OpenSSI Cluster File System), SAN cluster filesystems and parallel mounts of network file systems.

OpenSSI uses the context dependent symbolic link (CDSL) feature, inspired by HP's TruCluster system, to allow access to node-specific files in a manner transparent to non cluster-aware applications. A CDSL may point to different files on each node in the cluster.

CFS

CFS, the OpenSSI Cluster File System provides transparent inter-node access to an underlying real file system on one node.

CFS is stacked on top of the real file system and co-ordinates accesses from different nodes using a token mechanism. One node has physical access to the underlying file system and performs all read and write operations. At any one time one node owns a token, representing a part of the underlying file, this implies that that part of the file is in the cache of the owning node. If another node tries to access that part of the file the token is stolen and the cache contents are copied to the stealing node. The OpenSSI CFS implementation is remarkably similar to that used by HP TruCluster.[5]

CFS is also used to co-ordinate access to shared memory segments.

CFS can be used in a fault tolerant system by using shared disk subsystems (dual ported SCSI or SAN), or by using DRBD. If the node that is currently directly accessing the file system crashes then the CFS mount fails over to the other node that is directly connected to the disk and the cluster now accesses the file system via that node.

SAN clustered file systems

OpenSSI can use SAN based clustered file systems for its root provided they provide a POSIX compatible file system interface. Currently Lustre and GFS have been tested.

With a clustered file system, each node mounts the file system in parallel and access to the files goes directly from the node to the file system.

NFS

OpenSSI mounts NFS files systems in parallel on each node. Every node accesses the NFS server directly.

Single I/O space

OpenSSI provides cluster-wide access to all I/O devices on the system, with some limitations - it is not possible for a node to mount a block device from another node.

The udev device manager is used to manage the /dev directory. Each node runs its own copy of udev to create the appropriate device nodes in a subdirectory of /dev, /dev/1 for node 1, /dev/2 for node 2 and so on.

Single IPC space

OpenSSI provides internode access to all the standard Linux inter-process communication mechanisms, shared memory, semaphores, SYSV message queues, pipes and Unix domain sockets.

In order to implement cluster wide shared memory - distributed shared memory - OpenSSI uses the CFS token system. At any one time a memory segment may be readable by one or more nodes, or writable by one node. If a node without write access to a segment tries to write then the segment is marked unreadable on all other nodes and writable on the current node. If a node without read access tries to read a segment then the current value is copied from a node where it was valid and if it was writable it is marked readable.

Cluster IP address

OpenSSI uses LVS to provide fault-tolerant load balanced IP services. Inbound network connections are received by a director node which redirects them to the least loaded server node. (A node may be both a director and server). In the event of director node failure another director node takes over and the system continues to accept inbound connections.

Distributions

The OpenSSI software is available for various Linux distributions. The OpenSSI kernel is distribution independent but various distribution specific Linux user level systems need to be modified, for example the init process and the system startup scripts.

Currently the supported distributions are:

  1. Fedora Core 3
  2. Debian Sarge

Work is in progress to port OpenSSI to Debian Etch and Lenny.[6]

History

The origins of OpenSSI date back to the early 1980s when the LOCUS distributed operating system was developed at UCLA. The team that developed LOCUS went on to form the Locus Computing Corporation and produced various versions of the LOCUS technology under several names, culminating in the development of the UnixWare NonStop Clusters product at Tandem Computers, which had by that time acquired the LOCUS team and rights to the technology. NonStop Clusters for Unixware was commercialized by SCO as an add-on for UnixWare. When SCO stopped selling NonStop Clusters, the former Locus team, now working for Compaq (which had acquired Tandem in the interim), ported the NonStop Clusters code to Linux and released it as open source. The team at Compaq continued to develop the system, now called OpenSSI, for some time after HP acquired Compaq. OpenSSI is currently developed by an independent team.

See also

References

  1. 1.0 1.1 1.2 "OpenSSI (Single System Image) Clusters for Linux". Retrieved 2008-07-07.
  2. Ferri, Richard; Watson, Brian J. (2003-08-01), Sys Admin Magazine > Server Management > Introducing the OpenSSI Project, retrieved 2008-07-06
  3. Pfister, Gregory F. (1998), In search of clusters, Upper Saddle River, NJ: Prentice Hall PTR, ISBN 978-0-13-899709-0, OCLC 38300954
  4. Orlowski, Andrew (2001-11-14), "Compaq cavalry rescues Linux clusters", The Register, retrieved 2008-10-06
  5. Fafrak, Scott; Lola, Jim A.; Nichols, Brad; Yates, Gregory (2003), TruCluster Server Handbook, Digital Press, pp. 342–345, ISBN 1-55558-259-1
  6. OpenSSI on Debian Etch, prerelease, retrieved 2008-10-07

External links