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One Identity Safeguard for Privileged Sessions 8.0 LTS - Administration Guide

Preface Introduction The concepts of One Identity Safeguard for Privileged Sessions (SPS)
The philosophy of One Identity Safeguard for Privileged Sessions (SPS) Policies Credential Stores Plugin framework Indexing Supported protocols and client applications Modes of operation Connecting to a server through One Identity Safeguard for Privileged Sessions (SPS) Archive and backup concepts Maximizing the scope of auditing IPv6 in One Identity Safeguard for Privileged Sessions (SPS) SSH host keys Authenticating clients using public-key authentication in SSH The gateway authentication process Four-eyes authorization Network interfaces High Availability support in One Identity Safeguard for Privileged Sessions (SPS) Versions and releases of One Identity Safeguard for Privileged Sessions (SPS) Accessing and configuring One Identity Safeguard for Privileged Sessions (SPS)
Cloud deployment considerations The Welcome Wizard and the first login Basic settings
Supported web browsers The structure of the web interface Network settings Configuring date and time System logging, SNMP and e-mail alerts Configuring system monitoring on SPS Data and configuration backups Archiving Cleaning up audit data Using plugins Forwarding data to third-party systems Starling integration
User management and access control
Login settings Managing One Identity Safeguard for Privileged Sessions (SPS) users locally Setting password policies for local users Managing local user groups Managing One Identity Safeguard for Privileged Sessions (SPS) users from an LDAP database Handling user names in User Principal Name (UPN) format Authenticating users to a RADIUS server Authenticating users with X.509 certificates Authenticating users with SAML2 Managing user rights and user groups Creating rules for restricting access to search audit data Displaying the privileges of users and user groups Listing and searching configuration changes
Managing One Identity Safeguard for Privileged Sessions (SPS)
Controlling One Identity Safeguard for Privileged Sessions (SPS): reboot, shutdown Managing One Identity Safeguard for Privileged Sessions (SPS) clusters Managing a High Availability One Identity Safeguard for Privileged Sessions (SPS) cluster Upgrading One Identity Safeguard for Privileged Sessions (SPS) Managing the One Identity Safeguard for Privileged Sessions (SPS) license Accessing the One Identity Safeguard for Privileged Sessions (SPS) console Sealed mode Out-of-band management of One Identity Safeguard for Privileged Sessions (SPS) Managing the certificates used on One Identity Safeguard for Privileged Sessions (SPS)
General connection settings HTTP-specific settings ICA-specific settings MSSQL-specific settings RDP-specific settings SSH-specific settings Using Sudo with SPS Telnet-specific settings VMware Horizon View connections VNC-specific settings Indexing audit trails Using the Sessions interface Advanced authentication and authorization techniques Reports The One Identity Safeguard for Privileged Sessions (SPS) REST API One Identity Safeguard for Privileged Sessions (SPS) scenarios Troubleshooting One Identity Safeguard for Privileged Sessions (SPS)
Network troubleshooting Gathering data about system problems Viewing logs on One Identity Safeguard for Privileged Sessions (SPS) Changing log verbosity level of One Identity Safeguard for Privileged Sessions (SPS) Collecting logs and system information for error reporting Collecting logs and system information of the boot process for error reporting Support hotfixes Status history and statistics Troubleshooting a One Identity Safeguard for Privileged Sessions (SPS) cluster Understanding One Identity Safeguard for Privileged Sessions (SPS) RAID status Restoring One Identity Safeguard for Privileged Sessions (SPS) configuration and data VNC is not working with TLS Configuring the IPMI from the BIOS after losing IPMI password Incomplete TSA response received
Using SPS with SPP Configuring external devices Using SCP with agent-forwarding Security checklist for configuring One Identity Safeguard for Privileged Sessions (SPS) Jumplists for in-product help Configuring SPS to use an LDAP backend Glossary

Managing a High Availability One Identity Safeguard for Privileged Sessions (SPS) cluster

The goal of HA clusters is to support enterprise business continuity by providing failover.

In High Availability (HA) mode, two One Identity Safeguard for Privileged Sessions (SPS) units with identical configurations are operating simultaneously. These two units are the primary node and the secondary node (previously also referred to as the master node and the slave node). The primary node shares all data with the secondary node, and if the primary node stops functioning, the secondary node becomes active.

CAUTION: Depending on your environment, the shift between the two HA nodes might take 5 - 10 minutes. During this period, SPS connections are lost and they are not automatically restored. You might also encounter data loss during the shift.

NOTE: To ensure the stability of the connection, One Identity recommends a direct physical connection between the nodes in the HA cluster. Gratuitous ARP requests are sent to inform hosts on the local network that the MAC addresses behind these IP addresses have changed.

The primary node shares all data with the secondary node using the HA network interface (labeled as 4 or HA on the SPS appliance). The disks of the primary and the secondary node must be synchronized for the HA support to operate correctly. Interrupting the connection between running nodes (unplugging the Ethernet cables, rebooting a switch or a router between the nodes, or disabling the HA interface) disables data synchronization and forces the secondary node to become active. This might result in data loss. You can find instructions to resolve such problems and recover a SPS cluster in Troubleshooting a One Identity Safeguard for Privileged Sessions (SPS) cluster.

NOTE: HA functionality was designed for physical SPS units. If SPS is used in a virtual environment, use the fallback functionalities provided by the virtualization service instead.

The Basic Settings > High Availability page provides information about the status of the HA cluster and its nodes.

Figure 125: Basic Settings > High Availability — Managing a High Availability cluster

The following information is available about the cluster:

The active (that is, primary) SPS node is labeled as This node. This unit inspects the SSH traffic and provides the web interface. The SPS unit labeled as Other node is the secondary node that is activated if the primary node becomes unavailable.

The following information is available about each node:

  • Node ID: The MAC address of the HA interface of the node. This address is also printed on a label on the top cover of the SPS unit.

    For SPS clusters, the IDs of both nodes are included in the internal log messages of SPS. Note that if the central log server is a syslog-ng server, the keep-hostname option should be enabled on the syslog-ng server.

  • Node HA state: Indicates whether the SPS nodes recognize each other properly and whether those are configured to operate in High Availability mode. For details, see Understanding One Identity Safeguard for Privileged Sessions (SPS) cluster statuses.

  • Node HA UUID: A unique identifier of the cluster. Only available in High Availability mode.

  • DRBD status: The status of data synchronization between the nodes. For details, see Understanding One Identity Safeguard for Privileged Sessions (SPS) cluster statuses.

  • RAID status: The status of the RAID device of the node. If it is not Optimal, there is a problem with the RAID device. For details, see Understanding One Identity Safeguard for Privileged Sessions (SPS) RAID status.

  • Firmware version: Version number of the firmware.

  • HA link speed: The maximum allowed speed between the primary node and the secondary node. The HA link's speed must exceed the DRBD sync rate limit, else the web UI might become unresponsive and data loss can occur.

  • Interfaces for Heartbeat: Virtual interface used only to detect that the other node is still available. This interface is not used to synchronize data between the nodes (only heartbeat messages are transferred).

    You can find more information about configuring redundant heartbeat interfaces in Redundant heartbeat interfaces.

  • Next hop monitoring: IP addresses (usually next hop routers) to continuously monitor both the primary node and the secondary node by using ICMP echo (ping) messages. If any of the monitored addresses becomes unreachable from the primary node while being reachable from the secondary node (in other words, more monitored addresses are accessible from the secondary node), then it is assumed that the primary node is unreachable and a forced takeover occurs – even if the primary node is otherwise functional. For details, see Next-hop router monitoring.

HA cluster configuration and management options

This section is about the available configuration and management options for HA clusters.

Detailed information about this topic
Setting up a High Availability cluster

For detailed instructions about setting up a HA cluster, see Installing two SPS units in HA mode in the Installation Guide.

Adjust the DRBD (primary-secondary) synchronization speed

You can change the limit of the DRBD synchronization rate. Note that this does not change the speed of normal data replication. For details, see Adjusting the synchronization speed.

Configure redundant heartbeat interfaces

You can configure virtual interfaces for each HA node to monitor the availability of the other node. For details, see Redundant heartbeat interfaces.

Configure next-hop monitoring

You can provide IP addresses (usually next hop routers) to continuously monitor both the primary node and the secondary node by using ICMP echo (ping) messages. If any of the monitored addresses becomes unreachable from the primary node while being reachable from the secondary node (in other words, more monitored addresses are accessible from the secondary node), then it is assumed that the primary node is unreachable and a forced takeover occurs – even if the primary node is otherwise functional. For details, see Next-hop router monitoring.

Reboot the HA cluster

To reboot both nodes, click Reboot Cluster. To prevent takeover, a token is placed on the secondary node. While this token persists, the secondary node halts its boot process to make sure that the primary node boots first. Following reboot, the primary node removes this token from the secondary node, allowing it to continue with the boot process.

If the token still persists on the secondary node following reboot, the Unblock Slave Node button is displayed. Clicking the button removes the token, and reboots the secondary node.

Reboot a node

This option reboots the selected node.

When rebooting the nodes of a cluster, reboot the other node (that is, the secondary node) first to avoid unnecessary takeovers.

Shutdown a node

This option forces the selected node to shut down.

When shutting down the nodes of a cluster, shut down the other node (that is, the secondary node) first. When powering on the nodes, start the primary node first to avoid unnecessary takeovers.

Manual takeover

To activate the other node (that is, the secondary node) and disable the currently active node, click Activate slave.

Activating the secondary node terminates all connections of One Identity Safeguard for Privileged Sessions (SPS) and might result in data loss. The secondary node becomes active after about 60 seconds, during which the protected servers cannot be accessed.

Adjusting the synchronization speed

One Identity Safeguard for Privileged Sessions (SPS) synchronizes the content of the hard disk of the primary node (previously also referred to as master node) and the secondary node (previously also referred to as slave node) in the following cases.

  • When you configure two SPS units to operate in High Availability mode (converting a single node to a High Availability cluster),

  • when you replace a node from a cluster, or

  • when recovering from a split-brain situation.

  • Normal data replication (copying incoming data, for example, audit trails from the primary node to the secondary node is not synchronization.

Since this synchronization can take up significant system-resources, the maximal speed of the synchronization is limited, by default, to 10 Mbps. However, this means that synchronizing large amount of data can take very long time, so it is useful to increase the synchronization speed in certain situations —.

To change the limit of the DRBD synchronization rate, navigate to Basic Settings > High Availability > DRBD sync rate limit, and select the desired value. Note the following points before changing the DRBD sync rate limit option.

  • The Basic Settings > High Availability > DRBD sync rate limit option is visible only when synchronization is in progress, or when you have clicked Convert to Cluster but have not rebooted the cluster yet.

  • Changing this option does not change the limit of the data replication speed.

  • Set the sync rate carefully. A high value is not recommended if the load of SPS is very high, as increasing the resources used by the synchronization process may degrade the general performance of SPS. On the other hand, the HA link's speed must exceed the speed of the incoming data, else the web UI might become unresponsive and data loss can occur.

The Basic Settings > High Availability > DRBD status field indicates whether the latest data (including SPS configuration, audit trails, log files, and so on) is available on both SPS nodes. For a description of each possible status, see Understanding One Identity Safeguard for Privileged Sessions (SPS) cluster statuses.

Redundant heartbeat interfaces

To avoid unnecessary takeovers and to minimize the chance of split-brain situations, you can configure additional heartbeat interfaces in One Identity Safeguard for Privileged Sessions (SPS). These interfaces are used only to detect that the other node is still available, they are not used to synchronize data between the nodes (only heartbeat messages are transferred). For example, if the main HA interface breaks down, or is accidentally unplugged and the nodes can still access each other on the redundant HA interface, no takeover occurs, but no data is synchronized to the secondary node until the main HA link is restored. Similarly, if connection on the redundant heartbeat interface is lost, but the main HA connection is available, no takeover occurs.

If a redundant heartbeat interface is configured, its status is displayed in the Basic Settings > High Availability > Redundant Heartbeat status field, and also in the HA > Redundant field of the System monitor. For a description of each possible status, see Understanding One Identity Safeguard for Privileged Sessions (SPS) cluster statuses.

The redundant heartbeat interface is a virtual interface with a virtual MAC address that uses an existing interface of SPS. The MAC address of the virtual redundant heartbeat interface is displayed as HA MAC. The MAC address of the redundant heartbeat interface is generated in a way that it cannot interfere with the MAC addresses of physical interfaces. Similarly, the HA traffic on the redundant heartbeat interface cannot interfere with any other traffic on the interface used.

If the nodes lose connection on the main HA interface, and after a time the connection is lost on the redundant heartbeat interfaces as well, the secondary node becomes active. However, as the primary node was active for a time when no data synchronization was possible between the nodes, this results in a split-brain situation, which must be resolved before the HA functionality can be restored. For details, see Recovering from a split brain situation.

NOTE: Even if redundant HA links are configured, if the dedicated HA link fails, the secondary node will not be visible on the High Availability page anymore.

SPS nodes use UDP port 694 to send each other heartbeat signals.

To configure a redundant heartbeat interface

  1. Navigate to Basic Settings > High Availability > Interfaces for Heartbeat.

  2. Select the interface you want to use as redundant heartbeat interface (for example Physical interface 1). Using an interface as a redundant heartbeat interface does not affect the original traffic of the interface.

    Figure 126: Basic Settings > High Availability — Configuring redundant heartbeat interfaces

  3. Enter an IP address into the This node > Interface IP field of the selected interface. Note the following:

    • The two nodes must have different Interface IP.

    • If you do not use next hop monitoring on the redundant interface, you can use any Interface IP (even if otherwise it does not exist on that network).

    • If you use next hop monitoring on the redundant interface, the Interface IP address must be a real IP address that is visible from the other node.

    • If you use next hop monitoring on the redundant interface, the Interface IP must be accessible from the next-hop address, and vice-versa. For details on next hop monitoring, see Next-hop router monitoring.

    Use an IPv4 address.

  4. If the two nodes are in a different subnetwork, enter the IP address of the local gateway into the This node > Gateway IP field. The Interface IP address of the node must be accessible from the Gateway IP address.

    Use an IPv4 address.

  5. Enter an IP address into the Other node > Interface IP field of the selected interface. Note the following:

    • The two nodes must have different Interface IP.

    • If you do not use next hop monitoring on the redundant interface, you can use any Interface IP (even if otherwise it does not exist on that network).

    • If you use next hop monitoring on the redundant interface, the Interface IP address must be a real IP address that is visible from the other node.

    • If you use next hop monitoring on the redundant interface, the Interface IP must be accessible from the next-hop address, and vice-versa. For details on next hop monitoring, see Next-hop router monitoring.

    Use an IPv4 address.

  6. If the two nodes are in a different subnetwork, enter the IP address of the local gateway into the Other node > Gateway IP field. The Interface IP address of the node must be accessible from the Gateway IP address.

    Use an IPv4 address.

  7. Repeat the previous steps to add additional redundant heartbeat interfaces if needed.

  8. Click .

  9. Restart the nodes for the changes to take effect: click Reboot Cluster.

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