Guidelines for OpenVMS Cluster Configurations


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9.5.6 Managing "Hot" Files

A "hot" file is a file in your system on which the most activity occurs. Hot files exist because, in many environments, approximately 80% of all I/O goes to 20% of data. This means that, of equal regions on a disk drive, 80% of the data being transferred goes to one place on a disk, as shown in Figure 9-12.

Figure 9-12 Hot-File Distribution


To increase the scalability of I/Os, focus on hot files, which can become a bottleneck if you do not manage them well. The activity in this area is expressed in I/Os, megabytes transferred, and queue depth.

RAID level 0 balances hot-file activity by spreading a single file over multiple disks. This reduces the performance impact of hot files.

Use the following DCL commands to analyze hot-file activity:

The MONITOR IO and the MONITOR MSCP commands enable you to find out which disk and which server are hot.

9.5.7 Volume Shadowing

The Volume Shadowing for OpenVMS product ensures that data is available to applications and end users by duplicating data on multiple disks. Although volume shadowing provides data redundancy and high availability, it can affect OpenVMS Cluster I/O on two levels:
Factor Effect
Geographic distance Host-based volume shadowing enables shadowing of any devices in an OpenVMS Cluster system, including those served by MSCP servers. This ability can allow great distances along with MSCP overhead. For example, OpenVMS Cluster systems using IP can be located up to 500 miles apart. Using Fibre Channel, they can be located up to 62 miles (100 kilometers) apart. Both the distance and the MSCP involvement can slow I/O throughput.
Read/write ratio Because shadowing writes data to multiple volumes, applications that are write intensive may experience reduced throughput. In contrast, read-intensive applications may experience increased throughput because the shadowing software selects one disk member from which it can retrieve the data most efficiently.


Chapter 10
OpenVMS Cluster System Management Strategies

This chapter suggests some key system management strategies that you can use to get the most out of your OpenVMS Cluster. It is not intended to be a comprehensive discussion of the most common OpenVMS Cluster system management practices; see HP OpenVMS Cluster Systems for that information.

This chapter also assumes that the reader has some familiarity with basic system management concepts, such as system disks, quorum disks, and OpenVMS Cluster transitions.

The following information is contained in this chapter:

10.1 Simple and Complex Configurations

OpenVMS Cluster software makes a system manager's job easier because many system management tasks need to be done only once. This is especially true if business requirements call for a simple configuration rather than for every feature that an OpenVMS Cluster can provide. The simple configuration is appealing to both new and experienced system managers and is applicable to small OpenVMS Clusters---those with 3 to 7 nodes, 20 to 30 users, and 100 GB of storage.

Complex OpenVMS Cluster configurations may require a more sophisticated system management strategy to deliver more availability, scalability, and performance.

Reference: See Figure 10-2 for an example of a complex OpenVMS Cluster configuration.

Choose system management strategies that balance simplicity of system management with the additional management tasks required by more complex OpenVMS Clusters.

10.2 System Disk Strategies

System disks contain system files and environment files.

System files are primarily read-only images and command procedures, such as run-time libraries, and are accessed clusterwide.

Environment files create specific working environments for users. You can create a common environment by making all environment files accessible clusterwide, or you can create multiple environments by making specific environment files accessible to only certain users or systems.

10.2.1 Single System Disk

System management is easiest for a simple configuration that has a single system disk and a common environment. Most procedures need to be performed only once, and both system files and environment files are located on the same disk. Page and swap files are also located on the system disk.

Figure 10-1 shows another variation of a simple OpenVMS Cluster with a common environment.

Figure 10-1 Simple LAN OpenVMS Cluster with a Single System Disk


In Figure 10-1, six satellites and one boot server are connected by Ethernet. Each satellite has its own page and swap disk, which saves system disk space and removes the I/O activity of page and swap files from the Ethernet. Removing page and swap files from the system disk improves performance for the OpenVMS Cluster.

Although the single-system-disk configuration works well for many OpenVMS Cluster requirements, multiple system disks can offer several advantages.

10.2.2 Multiple System Disks

OpenVMS Clusters that include both Integrity servers and Alpha systems require multiple system disks: an Integrity server system disk and an Alpha system disk. Table 10-1 gives some additional reasons (not related to architecture) why a system manager might want more than one system disk in a OpenVMS Cluster.

Table 10-1 Advantages of Multiple System Disks
Advantage Description
Decreased boot times A single system disk can be a bottleneck when booting three or more systems simultaneously.

Boot times are highly dependent on:

  • LAN utilization
  • Speed of the system disk
  • Number of disks mounted
  • Number of applications installed
  • Proximity of boot node to satellites
  • Boot node's processing power
  • Whether environment files are on the system disk
  • Whether the system disk is shadowed
Volume Shadowing for OpenVMS software can help disk read performance, assuming that environment files that experience high write activity (such as SYSUAF.DAT) are not on the system disk.
Increased system and application performance If your OpenVMS Cluster has many different applications that are in constant use, it may be advantageous to have either a local system disk for every node or a system disk that serves fewer systems. The benefits are shorter image-activation times and fewer files being served over the LAN.

Alpha workstations benefit from a local system disk because the powerful Alpha processor does not have to wait as long for system disk access.

Reference: See Section 9.3.5 for more information.

Reduced LAN utilization More system disks reduce LAN utilization because fewer files are served over the LAN. Isolating LAN segments and their boot servers from unnecessary traffic outside the segments decreases LAN path contention.

Reference: See Section 10.2.4 for more information.

Increased OpenVMS Cluster availability A single system disk can become a single point of failure. Increasing the number of boot servers and system disks increases availability by reducing the OpenVMS Cluster's dependency on a single resource.

10.2.3 Multiple System-Disk OpenVMS Cluster

Arranging system disks as shown in Figure 10-2 can reduce booting time and LAN utilization.

Figure 10-2 Multiple System Disks in a Common Environment


Figure 10-2 is an OpenVMS Cluster with multiple system disks:

The use of multiple system disks in this configuration and the way that the LAN segments are divided enable the booting sequence to be efficient and timely.

10.2.4 Dividing an OpenVMS Cluster System

In the workstation server examples shown in Section 9.3, OpenVMS Cluster reboots after a failure are relatively simple because of the small number of satellites per server. However, reboots in the larger, OpenVMS Cluster configuration shown in Figure 10-2 require careful planning. Dividing this OpenVMS Cluster and arranging the system disks as described in this section can reduce booting time significantly. Dividing the OpenVMS Cluster can also reduce the satellite utilization of the LAN segment and increase satellite performance.

The disks in this OpenVMS Cluster have specific functions, as described in Table 10-2.

Table 10-2 How Multiple System Disks Are Used
Disk Contents Purpose
Common disk All environment files for the entire OpenVMS Cluster Environment files such as SYSUAF.DAT, NETPROXY.DAT, QMAN$MASTER.DAT are accessible to all nodes---including satellites---during booting. This frees the satellite boot servers to serve only system files and root information to the satellites.

To create a common environment and increase performance for all system disks, see Section 10.3.

System disk System roots for Alpha 1, Alpha 2, and Alpha 3 High performance for server systems. Make this disk as read-only as possible by taking environment files that have write activity off the system disk. The disk can be mounted clusterwide in SYLOGICALS.COM during startup.
Satellite boot servers' system disks System files or roots for the satellites Frees the system disk attached to Alpha 1, Alpha 2, and Alpha 3 from having to serve satellites, and divide total LAN traffic over individual Ethernet segments.
Page and swap disks Page and swap files for one or more systems Reduce I/O activity on the system disks, and free system disk space for applications and system roots.

In a booting sequence for the configuration in Figure 10-2, make sure that nodes Alpha 1, Alpha 2, and Alpha 3 are entirely booted before booting the LAN Ethernet segments so that the files on the common disk are available to the satellites. For FDDI configuration, enable filtering of the Maintenance Operations Protocol (MOP) on the Ethernet-to-FDDI (10/100) bridges so that the satellites do not try to boot from the system disks for Alpha 1, Alpha 2, and Alpha 3. The order in which to boot this OpenVMS Cluster is:

  1. Boot Alpha 1, Alpha 2, and Alpha 3.
  2. Boot the satellite boot servers.
  3. Boot all satellites.

Reference: See Section 9.3.7 for information about extended LANs.

10.2.5 Summary: Single Versus Multiple System Disks

Use the information in Table 10-3 to determine whether you need a system disk for the entire OpenVMS Cluster or multiple system disks.

Table 10-3 Comparison of Single and Multiple System Disks
Single System Disk Multiple System Disks
Node may have to wait longer for access to a file on the system disk. Node does not have to wait for access to the system disk and has faster processor performance.
Contention for a single resource increases. Contention for a single resource decreases.
Boot time for satellites increases. Boot time for satellites decreases.
Only one system disk to manage. More than one system disk to manage.
Less complex system management. More complex system management, such as coordinating system parameters and files clusterwide.
Lower hardware and software costs. Higher hardware and software costs, especially if disks are shadowed.
Lower cost of system management because less time and experience required to manage a single system disk. Higher cost of system management because more time and experience required to manage multiple system disks.

10.3 OpenVMS Cluster Environment Strategies

Depending on your processing needs, you can prepare either a common environment, in which all environment files are shared clusterwide, or a multiple environment, in which some files are shared clusterwide and others are accessible only by certain OpenVMS Cluster members.

The following are the most frequently used and manipulated OpenVMS Cluster environment files:

SYS$SYSTEM:SYSUAF.DAT
SYS$SYSTEM:NETPROXY.DAT
SYS$SYSTEM:VMSMAIL_PROFILE.DATA
SYS$SYSTEM:NETNODE_REMOTE.DAT
SYS$MANAGER:NETNODE_UPDATE.COM
SYS$SYSTEM:RIGHTSLIST.DAT
SYS$SYSTEM:QMAN$MASTER.DAT

Reference: For more information about managing these files, see HP OpenVMS Cluster Systems.

10.3.1 Common Environment

A common OpenVMS Cluster environment is an operating environment that is identical on all nodes in the OpenVMS Cluster. A common environment is easier to manage than multiple environments because you use a common version of each system file. The environment is set up so that:

The simplest and most inexpensive environment strategy is to have one system disk for the OpenVMS Cluster with all environment files on the same disk. The benefits of this strategy are:

10.3.2 Putting Environment Files on a Separate, Common Disk

For an OpenVMS Cluster in which every node share the same system disk and environment, most common environment files are located in the SYS$SYSTEM directory.

However, you may want to move environment files to a separate disk so that you can improve OpenVMS Cluster performance. Because the environment files typically experience 80% of the system-disk activity, putting them on a separate disk decreases activity on the system disk. Figure 10-2 shows an example of a separate, common disk.

If you move environment files such as SYSUAF.DAT to a separate, common disk, SYSUAF.DAT will not be located in its default location of SYS$SYSTEM:SYSUAF.DAT.

Reference: See HP OpenVMS Cluster Systems for procedures to ensure that every node in the OpenVMS Cluster can access SYSUAF.DAT in its new location.

10.3.3 Multiple Environments

Multiple environments can vary from node to node. You can set up an individual node or a subset of nodes to:

Figure 10-3 shows an example of a multiple environment.

Figure 10-3 Multiple-Environment OpenVMS Cluster


In Figure 10-3, the multiple-environment OpenVMS Cluster consists of two system disks: one for Integrity server nodes and one for Alpha nodes. The common disk contains environment files for each node or group of nodes. Although many OpenVMS Cluster system managers prefer the simplicity of a single (common) environment, duplicating environment files is necessary for creating multiple environments that do not share resources across every node. Each environment can be tailored to the types of tasks users perform and the resources they use, and the configuration can have many different applications installed.

Each of the four Fibre Channel nodes has its own page and swap disk, offloading the Alpha and Integrity server system disks on the FC interconnect from page and swap activity. All of the disks are shadowed across the FC interconnects, which protects the disks if a failure occurs.

10.4 Additional Multiple-Environment Strategies

This section describes additional multiple-environment strategies, such as using multiple SYSUAF.DAT files and multiple queue managers.

10.4.1 Using Multiple SYSUAF.DAT Files

Most OpenVMS Clusters are managed with one user authorization (SYSUAF.DAT) file, but you can use multiple user authorization files to limit access for some users to certain systems. In this scenario, users who need access to all systems also need multiple passwords.

Be careful about security with multiple SYSUAF.DAT files. The OpenVMS Integrity servers and OpenVMS Alpha operating systems do not support multiple security domains.

Reference: See HP OpenVMS Cluster Systems for the list of fields that need to be the same for a single security domain, including SYSUAF.DAT entries.

Because Alpha systems require higher process quotas, system managers often respond by creating multiple SYSUAF.DAT files. This is not an optimal solution. Multiple SYSUAF.DAT files are intended only to vary environments from node to node, not to increase process quotas. To increase process quotas, HP recommends that you have one SYSUAF.DAT file and that you use system parameters to override process quotas in the SYSUAF.DAT file with system parameters to control resources for your Alpha systems.

10.4.2 Using Multiple Queue Managers

If the number of batch and print transactions on your OpenVMS Cluster is causing congestion, you can implement multiple queue managers to distribute the batch and print loads between nodes.

Every OpenVMS Cluster has only one QMAN$MASTER.DAT file. Multiple queue managers are defined through multiple *.QMAN$QUEUES and *.QMAN$JOURNAL files. Place each pair of queue manager files on different disks. If the QMAN$MASTER.DAT file has contention problems, place it on a solid-state disk to increase the number of batch and print transactions your OpenVMS Cluster can process. For example, you can create separate queue managers for batch queues and print queues.

Reference: See OpenVMS System Manager's Manual, Volume 1: Essentials for examples and commands to implement multiple queue managers.

10.5 Quorum Strategies

OpenVMS Cluster systems use a quorum algorithm to ensure synchronized access to storage. The quorum algorithm is a mathematical method for determining whether a majority of OpenVMS Cluster members exists so that they can "vote" on how resources can be shared across an OpenVMS Cluster system. The connection manager, which calculates quorum as a dynamic value, allows processing to occur only if a majority of the OpenVMS Cluster members are functioning.

Quorum votes are contributed by:

Each OpenVMS Cluster system can include only one quorum disk. The disk cannot be a member of a shadow set, but it can be the system disk.

The connection manager knows about the quorum disk from "quorum disk watchers," which are any systems that have a direct, active connection to the quorum disk.

10.5.1 Quorum Strategy Options

At least two systems should have a direct connection to the quorum disk. This ensures that the quorum disk votes are accessible if one of the systems fails.

When you consider quorum strategies, you must decide under what failure circumstances you want the OpenVMS Cluster to continue. Table 10-4 describes four options from which to choose.

Table 10-4 Quorum Strategies
Strategy Option1 Description
Continue if the majority of the maximum "expected" nodes still remain. Give every node a vote and do not use a quorum disk. This strategy requires three or more nodes.
Continue with only one node remaining (of three or more nodes). This strategy requires a quorum disk.

By increasing the quorum disk's votes to one less than the total votes from all systems (and by increasing the value of the EXPECTED_VOTES system parameter by the same amount), you can boot and run the cluster with only one node as a quorum disk watcher. This prevents having to wait until more than half the voting systems are operational before you can start using the OpenVMS Cluster system.

Continue with only one node remaining (two-node OpenVMS Cluster). Give each node and the quorum disk a vote.

The two-node OpenVMS Cluster is a special case of this alternative. By establishing a quorum disk, you can increase the availability of a two-node OpenVMS Cluster. Such configurations can maintain quorum and continue to operate in the event of failure of either the quorum disk or one node. This requires that both nodes be directly connected to storage (by CI, DSSI, SCSI, or Fibre Channel) for both to be quorum disk watchers.

Continue with only critical nodes in the OpenVMS Cluster. Generally, this strategy gives servers votes and gives satellites none. This assumes three or more servers and no quorum disk.


1These strategies are mutually exclusive; choose only one.

Reference: For more information about quorum disk management, see HP OpenVMS Cluster Systems.


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