ASA Cluster for the Secure Firewall 3100

Clustering lets you group multiple ASAs together as a single logical device. A cluster provides all the convenience of a single device (management, integration into a network) while achieving the increased throughput and redundancy of multiple devices.


Note


Some features are not supported when using clustering. See Unsupported Features with Clustering.


About ASA Clustering

This section describes the clustering architecture and how it works.

How the Cluster Fits into Your Network

The cluster consists of multiple firewalls acting as a single unit. To act as a cluster, the firewalls need the following infrastructure:

  • Isolated, high-speed backplane network for intra-cluster communication, known as the cluster control link.

  • Management access to each firewall for configuration and monitoring.

When you place the cluster in your network, the upstream and downstream routers need to be able to load-balance the data coming to and from the cluster using Spanned EtherChannels. Interfaces on multiple members of the cluster are grouped into a single EtherChannel; the EtherChannel performs load balancing between units.

Cluster Members

Cluster members work together to accomplish the sharing of the security policy and traffic flows. This section describes the nature of each member role.

Bootstrap Configuration

On each device, you configure a minimal bootstrap configuration including the cluster name, cluster control link interface, and other cluster settings. The first node on which you enable clustering typically becomes the control node. When you enable clustering on subsequent nodes, they join the cluster as data nodes.

Control and Data Node Roles

One member of the cluster is the control node. If multiple cluster nodes come online at the same time, the control node is determined by the priority setting in the bootstrap configuration; the priority is set between 1 and 100, where 1 is the highest priority. All other members are data nodes. Typically, when you first create a cluster, the first node you add becomes the control node simply because it is the only node in the cluster so far.

You must perform all configuration (aside from the bootstrap configuration) on the control node only; the configuration is then replicated to the data nodes. In the case of physical assets, such as interfaces, the configuration of the control node is mirrored on all data nodes. For example, if you configure Ethernet 1/2 as the inside interface and Ethernet 1/1 as the outside interface, then these interfaces are also used on the data nodes as inside and outside interfaces.

Some features do not scale in a cluster, and the control node handles all traffic for those features.

Cluster Interfaces

You can configure data interfaces as Spanned EtherChannels. See About Cluster Interfaces for more information.


Note


Individual interfaces are not supported, with the exception of a management interface.


Cluster Control Link

Each unit must dedicate at least one hardware interface as the cluster control link. See Cluster Control Link for more information.

Configuration Replication

All nodes in the cluster share a single configuration. You can only make configuration changes on the control node (with the exception of the bootstrap configuration), and changes are automatically synced to all other nodes in the cluster.

ASA Cluster Management

One of the benefits of using ASA clustering is the ease of management. This section describes how to manage the cluster.

Management Network

We recommend connecting all units to a single management network. This network is separate from the cluster control link.

Management Interface

For the management interface, we recommend using one of the dedicated management interfaces. You can configure the management interfaces as Individual interfaces (for both routed and transparent modes) or as a Spanned EtherChannel interface.

We recommend using Individual interfaces for management, even if you use Spanned EtherChannels for your data interfaces. Individual interfaces let you connect directly to each unit if necessary, while a Spanned EtherChannel interface only allows remote connection to the current control unit.


Note


You cannot enable dynamic routing for the management interface. You must use a static route.


For an Individual interface, the Main cluster IP address is a fixed address for the cluster that always belongs to the current control unit. For each interface, you also configure a range of addresses so that each unit, including the current control unit, can use a Local address from the range. The Main cluster IP address provides consistent management access to an address; when a control unit changes, the Main cluster IP address moves to the new control unit, so management of the cluster continues seamlessly. The Local IP address is used for routing, and is also useful for troubleshooting.

For example, you can manage the cluster by connecting to the Main cluster IP address, which is always attached to the current control unit. To manage an individual member, you can connect to the Local IP address.


Note


To-the-box traffic needs to be directed to the node's management IP address; to-the-box traffic is not forwarded over the cluster control link to any other node.


For outbound management traffic such as TFTP or syslog, each unit, including the control unit, uses the Local IP address to connect to the server.

For a Spanned EtherChannel interface, you can only configure one IP address, and that IP address is always attached to the control unit. You cannot connect directly to a data unit using the EtherChannel interface; we recommend configuring the management interface as an Individual interface so that you can connect to each unit. Note that you can use a device-local EtherChannel for management.

Control Unit Management Vs. Data Unit Management

All management and monitoring can take place on the control node. From the control node, you can check runtime statistics, resource usage, or other monitoring information of all nodes. You can also issue a command to all nodes in the cluster, and replicate the console messages from data nodes to the control node.

You can monitor data nodes directly if desired. Although also available from the control node, you can perform file management on data nodes (including backing up the configuration and updating images). The following functions are not available from the control node:

  • Monitoring per-node cluster-specific statistics.

  • Syslog monitoring per node (except for syslogs sent to the console when console replication is enabled).

  • SNMP

  • NetFlow

Crypto Key Replication

When you create a crypto key on the control node, the key is replicated to all data nodes. If you have an SSH session to the Main cluster IP address, you will be disconnected if the control node fails. The new control node uses the same key for SSH connections, so that you do not need to update the cached SSH host key when you reconnect to the new control node.

ASDM Connection Certificate IP Address Mismatch

By default, a self-signed certificate is used for the ASDM connection based on the Local IP address. If you connect to the Main cluster IP address using ASDM, then a warning message about a mismatched IP address might appear because the certificate uses the Local IP address, and not the Main cluster IP address. You can ignore the message and establish the ASDM connection. However, to avoid this type of warning, you can enroll a certificate that contains the Main cluster IP address and all the Local IP addresses from the IP address pool. You can then use this certificate for each cluster member. See https://www.cisco.com/c/en/us/td/docs/security/asdm/identity-cert/cert-install.html for more information.

Inter-Site Clustering

For inter-site installations, you can take advantage of ASA clustering as long as you follow the recommended guidelines.

You can configure each cluster chassis to belong to a separate site ID.

Site IDs work with site-specific MAC addresses and IP addresses. Packets egressing the cluster use a site-specific MAC address and IP address, while packets received by the cluster use a global MAC address and IP address. This feature prevents the switches from learning the same global MAC address from both sites on two different ports, which causes MAC flapping; instead, they only learn the site MAC address. Site-specific MAC addresses and IP address are supported for routed mode using Spanned EtherChannels only.

Site IDs are also used to enable flow mobility using LISP inspection, director localization to improve performance and reduce round-trip time latency for inter-site clustering for data centers, and site redundancy for connections where a backup owner of a traffic flow is always at a different site from the owner.

See the following sections for more information about inter-site clustering:

Licenses for ASA Clustering

Smart Software Manager Regular and On-Prem

Each unit requires the Standard license (enabled by default) and the same encryption license. We recommend licensing each unit with the licensing server before you enable clustering to avoid licensing mismatch issues, and when using the Strong Encryption license, issues with cluster control link encryption.

The clustering feature itself does not require any licenses. There is no extra cost for the Context license on data units.

The Strong Encryption license is automatically enabled for qualified customers when you apply the registration token. For the optional Strong Encryption (3DES/AES) feature license enabled in the ASA configuration, see below.

In the ASA license configuration, the Standard license is always enabled by default on all units. You can only configure smart licensing on the control unit. The configuration is replicated to the data units, but for some licenses, they do not use the configuration; it remains in a cached state, and only the control unit requests the license. The licenses are aggregated into a single cluster license that is shared by the cluster units, and this aggregated license is also cached on the data units to be used if one of them becomes the control unit in the future. Each license type is managed as follows:

  • Standard—Each unit requests a Standard license from the server.

  • Context—Only the control unit requests the Context license from the server. The Standard license includes 2 contexts by default and is present on all cluster members. The value from each unit’s Standard license plus the value of the Context license on the control unit are combined up to the platform limit in an aggregated cluster license. For example:

    • You have 6 Secure Firewall 3100s in the cluster. The Standard license includes 2 contexts; for 6 units, these licenses add up to 12 contexts. You configure an additional 20-Context license on the control unit. Therefore, the aggregated cluster license includes 32 contexts. Because the platform limit for one chassis is 100, the combined license allows a maximum of 100 contexts; the 32 contexts are within the limit. Therefore, you can configure up to 32 contexts on the control unit; each data unit will also have 32 contexts through configuration replication.

    • You have 3 Secure Firewall 3100s in the cluster. The Standard license includes 2 contexts; for 3 units, these licenses add up to 6 contexts. You configure an additional 100-Context license on the control unit. Therefore, the aggregated cluster license includes 106 contexts. Because the platform limit for one unit is 100, the combined license allows a maximum of 100 contexts; the 106 contexts are over the limit. Therefore, you can only configure up to 100 contexts on the control unit; each data unit will also have 100 contexts through configuration replication. In this case, you should only configure the control unit Context license to be 94 contexts.

  • Strong Encryption (3DES)—If your Smart Account is not authorized for strong encryption, but Cisco has determined that you are allowed to use strong encryption, you can manually add a strong encryption license to your account. Only the control unit requests this license, and all units can use it due to license aggregation.

If a new control unit is elected, the new control unit continues to use the aggregated license. It also uses the cached license configuration to re-request the control unit license. When the old control unit rejoins the cluster as a data unit, it releases the control unit license entitlement. Before the data unit releases the license, the control unit's license might be in a non-compliant state if there are no available licenses in the account. The retained license is valid for 30 days, but if it is still non-compliant after the grace period, you will not be able to make configuration changes to features requiring special licenses; operation is otherwise unaffected. The new active unit sends an entitlement authorization renewal request every 35 seconds until the license is compliant. You should refrain from making configuration changes until the license requests are completely processed. If a unit leaves the cluster, the cached control configuration is removed, while the per-unit entitlements are retained. In particular, you would need to re-request the Context license on non-cluster units.

Permanent License Reservation

For permanent license reservation, you must purchase separate licenses for each chassis and enable the licenses before you configure clustering.

Requirements and Prerequisites for ASA Clustering

Model Requirements

  • Secure Firewall 3100—Maximum 8 units

ASA Hardware and Software Requirements

All units in a cluster:

  • Must be the same model with the same DRAM. You do not have to have the same amount of flash memory.

  • Must run the identical software except at the time of an image upgrade. Hitless upgrade is supported. Mismatched software versions can lead to poor performance, so be sure to upgrade all nodes in the same maintenance window.

  • Must be in the same security context mode, single or multiple.

  • (Single context mode) Must be in the same firewall mode, routed or transparent.

  • New cluster members must use the same SSL encryption setting (the ssl encryption command) as the control unit for initial cluster control link communication before configuration replication.

Switch Requirements

  • Be sure to complete the switch configuration before you configure clustering on the ASAs.

  • For a list of supported switches, see Cisco ASA Compatibility.

ASA Requirements

  • Provide each unit with a unique IP address before you join them to the management network.

    • See the Getting Started chapter for more information about connecting to the ASA and setting the management IP address.

    • Except for the IP address used by the control unit (typically the first unit you add to the cluster), these management IP addresses are for temporary use only.

    • After a data unit joins the cluster, its management interface configuration is replaced by the one replicated from the control unit.

Sizing the Data Center Interconnect for Inter-Site Clustering

You should reserve bandwidth on the data center interconnect (DCI) for cluster control link traffic equivalent to the following calculation:

If the number of members differs at each site, use the larger number for your calculation. The minimum bandwidth for the DCI should not be less than the size of the cluster control link for one member.

For example:

  • For 4 members at 2 sites:

    • 4 cluster members total

    • 2 members at each site

    • 5 Gbps cluster control link per member

    Reserved DCI bandwidth = 5 Gbps (2/2 x 5 Gbps).

  • For 6 members at 3 sites, the size increases:

    • 6 cluster members total

    • 3 members at site 1, 2 members at site 2, and 1 member at site 3

    • 10 Gbps cluster control link per member

    Reserved DCI bandwidth = 15 Gbps (3/2 x 10 Gbps).

  • For 2 members at 2 sites:

    • 2 cluster members total

    • 1 member at each site

    • 10 Gbps cluster control link per member

    Reserved DCI bandwidth = 10 Gbps (1/2 x 10 Gbps = 5 Gbps; but the minimum bandwidth should not be less than the size of the cluster control link (10 Gbps)).

Other Requirements

We recommend using a terminal server to access all cluster member unit console ports. For initial setup, and ongoing management (for example, when a unit goes down), a terminal server is useful for remote management.

Guidelines for ASA Clustering

Context Mode

The mode must match on each member unit.

Firewall Mode

For single mode, the firewall mode must match on all units.

Failover

Failover is not supported with clustering.

IPv6

The cluster control link is only supported using IPv4.

Switches

  • Make sure connected switches match the MTU for both cluster data interfaces and the cluster control link interface. You should configure the cluster control link interface MTU to be at least 100 bytes higher than the data interface MTU, so make sure to configure the cluster control link connecting switch appropriately. Because the cluster control link traffic includes data packet forwarding, the cluster control link needs to accommodate the entire size of a data packet plus cluster traffic overhead. In addition, we do not recommend setting the cluster control link MTU between 2561 and 8362; due to block pool handling, this MTU size is not optimal for system operation.

  • For Cisco IOS XR systems, if you want to set a non-default MTU, set the IOS XR interface MTU to be 14 bytes higher than the cluster device MTU. Otherwise, OSPF adjacency peering attempts may fail unless the mtu-ignore option is used. Note that the cluster device MTU should match the IOS XR IPv4 MTU. This adjustment is not required for Cisco Catalyst and Cisco Nexus switches.

  • On the switch(es) for the cluster control link interfaces, you can optionally enable Spanning Tree PortFast on the switch ports connected to the cluster unit to speed up the join process for new units.

  • On the switch, we recommend that you use one of the following EtherChannel load-balancing algorithms: source-dest-ip or source-dest-ip-port (see the Cisco Nexus OS and Cisco IOS-XE port-channel load-balance command). Do not use a vlan keyword in the load-balance algorithm because it can cause unevenly distributed traffic to the devices in a cluster. Do not change the load-balancing algorithm from the default on the cluster device.

  • If you change the load-balancing algorithm of the EtherChannel on the switch, the EtherChannel interface on the switch temporarily stops forwarding traffic, and the Spanning Tree Protocol restarts. There will be a delay before traffic starts flowing again.

  • Switches on the cluster control link path should not verify the L4 checksum. Redirected traffic over the cluster control link does not have a correct L4 checksum. Switches that verify the L4 checksum could cause traffic to be dropped.

  • Port-channel bundling downtime should not exceed the configured keepalive interval.

  • On Supervisor 2T EtherChannels, the default hash distribution algorithm is adaptive. To avoid asymmetric traffic in a VSS design, change the hash algorithm on the port-channel connected to the cluster device to fixed:

    router(config)# port-channel id hash-distribution fixed

    Do not change the algorithm globally; you may want to take advantage of the adaptive algorithm for the VSS peer link.

  • You should disable the LACP Graceful Convergence feature on all cluster-facing EtherChannel interfaces for Cisco Nexus switches.

EtherChannels

  • In Catalyst 3750-X Cisco IOS software versions earlier than 15.1(1)S2, the cluster unit did not support connecting an EtherChannel to a switch stack. With default switch settings, if the cluster unit EtherChannel is connected cross stack, and if the control unit switch is powered down, then the EtherChannel connected to the remaining switch will not come up. To improve compatibility, set the stack-mac persistent timer command to a large enough value to account for reload time; for example, 8 minutes or 0 for indefinite. Or, you can upgrade to more a more stable switch software version, such as 15.1(1)S2.

  • Spanned vs. Device-Local EtherChannel Configuration—Be sure to configure the switch appropriately for Spanned EtherChannels vs. Device-local EtherChannels.

    • Spanned EtherChannels—For cluster unit Spanned EtherChannels, which span across all members of the cluster, the interfaces are combined into a single EtherChannel on the switch. Make sure each interface is in the same channel group on the switch.

    • Device-local EtherChannels—For cluster unit Device-local EtherChannels including any EtherChannels configured for the cluster control link, be sure to configure discrete EtherChannels on the switch; do not combine multiple cluster unit EtherChannels into one EtherChannel on the switch.

Inter-Site Guidelines

See the following guidelines for inter-site clustering:

  • The cluster control link latency must be less than 20 ms round-trip time (RTT).

  • The cluster control link must be reliable, with no out-of-order or dropped packets; for example, you should use a dedicated link.

  • Do not configure connection rebalancing; you do not want connections rebalanced to cluster members at a different site.

  • The ASA does not encrypt forwarded data traffic on the cluster control link because it is a dedicated link, even when used on a Data Center Interconnect (DCI). If you use Overlay Transport Virtualization (OTV), or are otherwise extending the cluster control link outside of the local administrative domain, you can configure encryption on your border routers such as 802.1AE MacSec over OTV.

  • The cluster implementation does not differentiate between members at multiple sites for incoming connections; therefore, connection roles for a given connection may span across sites. This is expected behavior. However, if you enable director localization, the local director role is always chosen from the same site as the connection owner (according to site ID). Also, the local director chooses a new owner at the same site if the original owner fails (Note: if the traffic is asymmetric across sites, and there is continuous traffic from the remote site after the original owner fails, then a node from the remote site might become the new owner if it receives a data packet within the re-hosting window.).

  • For director localization, the following traffic types do not support localization: NAT or PAT traffic; SCTP-inspected traffic; Fragmentation owner query.

  • For transparent mode, if the cluster is placed between a pair of inside and outside routers (AKA North-South insertion), you must ensure that both inside routers share a MAC address, and also that both outside routers share a MAC address. When a cluster member at site 1 forwards a connection to a member at site 2, the destination MAC address is preserved. The packet will only reach the router at site 2 if the MAC address is the same as the router at site 1.

  • For transparent mode, if the cluster is placed between data networks and the gateway router at each site for firewalling between internal networks (AKA East-West insertion), then each gateway router should use a First Hop Redundancy Protocol (FHRP) such as HSRP to provide identical virtual IP and MAC address destinations at each site. The data VLANs are extended across the sites using Overlay Transport Virtualization (OTV), or something similar. You need to create filters to prevent traffic that is destined to the local gateway router from being sent over the DCI to the other site. If the gateway router becomes unreachable at one site, you need to remove any filters so traffic can successfully reach the other site’s gateway.

  • For transparent mode, if the cluster is connected to an HSRP router, you must add the router HSRP MAC address as a static MAC address table entry on the ASA (see Add a Static MAC Address for Bridge Groups). When adjacent routers use HSRP, traffic destined to the HSRP IP address will be sent to the HSRP MAC Address, but return traffic will be sourced from the MAC address of a particular router's interface in the HSRP pair. Therefore, the ASA MAC address table is typically only updated when the ASA ARP table entry for the HSRP IP address expires, and the ASA sends an ARP request and receives a reply. Because the ASA’s ARP table entries expire after 14400 seconds by default, but the MAC address table entry expires after 300 seconds by default, a static MAC address entry is required to avoid MAC address table expiration traffic drops.

  • For routed mode using Spanned EtherChannel, configure site-specific MAC addresses. Extend the data VLANs across the sites using OTV, or something similar. You need to create filters to prevent traffic that is destined to the global MAC address from being sent over the DCI to the other site. If the cluster becomes unreachable at one site, you need to remove any filters so traffic can successfully reach the other site’s cluster nodes. Dynamic routing is not supported when an inter-site cluster acts as the first hop router for an extended segment.

Additional Guidelines

  • When significant topology changes occur (such as adding or removing an EtherChannel interface, enabling or disabling an interface on the ASA or the switch, adding an additional switch to form a VSS, vPC, StackWise, or StackWise Virtual) you should disable the health check feature and also disable interface monitoring for the disabled interfaces. When the topology change is complete, and the configuration change is synced to all units, you can re-enable the interface health check feature.

  • When adding a unit to an existing cluster, or when reloading a unit, there will be a temporary, limited packet/connection drop; this is expected behavior. In some cases, the dropped packets can hang your connection; for example, dropping a FIN/ACK packet for an FTP connection will make the FTP client hang. In this case, you need to reestablish the FTP connection.

  • If you use a Windows 2003 server connected to a Spanned EtherChannel, when the syslog server port is down and the server does not throttle ICMP error messages, then large numbers of ICMP messages are sent back to the ASA cluster. These messages can result in some units of the ASA cluster experiencing high CPU, which can affect performance. We recommend that you throttle ICMP error messages.

  • It takes time to replicate changes to all the units in a cluster. If you make a large change, for example, adding an access control rule that uses object groups (which, when deployed, are broken out into multiple rules), the time needed to complete the change can exceed the timeout for the cluster units to respond with a success message. If this happens, you might see a "failed to replicate command" message. You can ignore the message.

Defaults for ASA Clustering

  • When using Spanned EtherChannels, the cLACP system ID is auto-generated and the system priority is 1 by default.

  • The cluster health check feature is enabled by default with the holdtime of 3 seconds. Interface health monitoring is enabled on all interfaces by default.

  • The cluster auto-rejoin feature for a failed cluster control link is unlimited attempts every 5 minutes.

  • The cluster auto-rejoin feature for a failed data interface is 3 attempts every 5 minutes, with the increasing interval set to 2.

  • Connection rebalancing is disabled by default. If you enable connection rebalancing, the default time between load information exchanges is 5 seconds.

  • Connection replication delay of 5 seconds is enabled by default for HTTP traffic.

Configure ASA Clustering

To configure clustering, perform the following tasks.


Note


To enable or disable clustering, you must use a console connection (for CLI) or an ASDM connection.


Cable the Units and Configure Interfaces

Before configuring clustering, cable the cluster control link network, management network, and data networks. Then configure your interfaces.

About Cluster Interfaces

You can configure data interfaces as Spanned EtherChannels.

Each unit must also dedicate at least one hardware interface as the cluster control link.

Cluster Control Link

Each unit must dedicate at least one hardware interface as the cluster control link. We recommend using an EtherChannel for the cluster control link if available.

Cluster Control Link Traffic Overview

Cluster control link traffic includes both control and data traffic.

Control traffic includes:

  • Control node election.

  • Configuration replication.

  • Health monitoring.

Data traffic includes:

  • State replication.

  • Connection ownership queries and data packet forwarding.

Cluster Control Link Interfaces and Network

You can use any data interface(s) for the cluster control link, with the following exceptions:

  • You cannot use a VLAN subinterface as the cluster control link.

  • You cannot use a Management x/x interface as the cluster control link, either alone or as an EtherChannel.

You can use an EtherChannel.

Each cluster control link has an IP address on the same subnet. This subnet should be isolated from all other traffic, and should include only the ASA cluster control link interfaces.

For a 2-member cluster, do not directly-connect the cluster control link from one ASA to the other ASA. If you directly connect the interfaces, then when one unit fails, the cluster control link fails, and thus the remaining healthy unit fails. If you connect the cluster control link through a switch, then the cluster control link remains up for the healthy unit.

Size the Cluster Control Link

If possible, you should size the cluster control link to match the expected throughput of each chassis so the cluster control link can handle the worst-case scenarios.

Cluster control link traffic is comprised mainly of state update and forwarded packets. The amount of traffic at any given time on the cluster control link varies. The amount of forwarded traffic depends on the load-balancing efficacy or whether there is a lot of traffic for centralized features. For example:

  • NAT results in poor load balancing of connections, and the need to rebalance all returning traffic to the correct units.

  • AAA for network access is a centralized feature, so all traffic is forwarded to the control unit.

  • When membership changes, the cluster needs to rebalance a large number of connections, thus temporarily using a large amount of cluster control link bandwidth.

A higher-bandwidth cluster control link helps the cluster to converge faster when there are membership changes and prevents throughput bottlenecks.


Note


If your cluster has large amounts of asymmetric (rebalanced) traffic, then you should increase the cluster control link size.


Cluster Control Link Redundancy

We recommend using an EtherChannel for the cluster control link, so that you can pass traffic on multiple links in the EtherChannel while still achieving redundancy.

The following diagram shows how to use an EtherChannel as a cluster control link in a Virtual Switching System (VSS), Virtual Port Channel (vPC), StackWise, or StackWise Virtual environment. All links in the EtherChannel are active. When the switch is part of a redundant system, then you can connect firewall interfaces within the same EtherChannel to separate switches in the redundant system. The switch interfaces are members of the same EtherChannel port-channel interface, because the separate switches act like a single switch. Note that this EtherChannel is device-local, not a Spanned EtherChannel.

Cluster Control Link Reliability

To ensure cluster control link functionality, be sure the round-trip time (RTT) between units is less than 20 ms. This maximum latency enhances compatibility with cluster members installed at different geographical sites. To check your latency, perform a ping on the cluster control link between units.

The cluster control link must be reliable, with no out-of-order or dropped packets; for example, for inter-site deployment, you should use a dedicated link.

Cluster Control Link Failure

If the cluster control link line protocol goes down for a unit, then clustering is disabled; data interfaces are shut down. After you fix the cluster control link, you must manually rejoin the cluster by re-enabling clustering.


Note


When the ASA becomes inactive, all data interfaces are shut down; only the management-only interface can send and receive traffic. The management interface remains up using the IP address the unit received from the cluster IP pool. However if you reload, and the unit is still inactive in the cluster, the management interface is not accessible (because it then uses the Main IP address, which is the same as the control unit). You must use the console port for any further configuration.


Spanned EtherChannels

You can group one or more interfaces per chassis into an EtherChannel that spans all chassis in the cluster. The EtherChannel aggregates the traffic across all the available active interfaces in the channel.

A Spanned EtherChannel can be configured in both routed and transparent firewall modes. In routed mode, the EtherChannel is configured as a routed interface with a single IP address. In transparent mode, the IP address is assigned to the BVI, not to the bridge group member interface.

The EtherChannel inherently provides load balancing as part of basic operation.

Guidelines for Maximum Throughput

To achieve maximum throughput, we recommend the following:

  • Use a load-balancing hash algorithm that is “symmetric,” meaning that packets from both directions will have the same hash and will be sent to the same ASA in the Spanned EtherChannel. We recommend using the source and destination IP address (the default) or the source and destination port as the hashing algorithm.

  • Use the same type of line cards when connecting the ASAs to the switch so that hashing algorithms applied to all packets are the same.

Load Balancing

The EtherChannel link is selected using a proprietary hash algorithm, based on source or destination IP addresses and TCP and UDP port numbers.


Note


On the switch, we recommend that you use one of the following algorithms: source-dest-ip or source-dest-ip-port (see the Cisco Nexus OS or Cisco IOS port-channel load-balance command). Do not use a vlan keyword in the load-balance algorithm because it can cause unevenly distributed traffic to the ASAs in a cluster.


The number of links in the EtherChannel affects load balancing.

Symmetric load balancing is not always possible. If you configure NAT, then forward and return packets will have different IP addresses and/or ports. Return traffic will be sent to a different unit based on the hash, and the cluster will have to redirect most returning traffic to the correct unit.

EtherChannel Redundancy

The EtherChannel has built-in redundancy. It monitors the line protocol status of all links. If one link fails, traffic is re-balanced between remaining links. If all links in the EtherChannel fail on a particular unit, but other units are still active, then the unit is removed from the cluster.

Connecting to a Redundant Switch System

You can include multiple interfaces per ASA in the Spanned EtherChannel. Multiple interfaces per ASA are especially useful for connecting to both switches in a VSS, vPC, StackWise, or StackWise Virtual system.

Depending on your switches, you can configure up to 32 active links in the spanned EtherChannel. This feature requires both switches in the vPC to support EtherChannels with 16 active links each (for example the Cisco Nexus 7000 with F2-Series 10 Gigabit Ethernet Module).

For switches that support 8 active links in the EtherChannel, you can configure up to 16 active links in the spanned EtherChannel when connecting to two switches in a redundant system.

The following figure shows a 16-active-link spanned EtherChannel in a 4-node cluster and an 8-node cluster.

Cable the Cluster Units and Configure Upstream and Downstream Equipment

Before configuring clustering, cable the cluster control link network, management network, and data networks.

Procedure

Step 1

Cable the cluster control link network, management network, and data networks.

Note

 

At a minimum, an active cluster control link network is required before you configure the nodes to join the cluster.

Step 2

You should also configure the upstream and downstream equipment. For example, if you use EtherChannels, then you should configure the upstream and downstream equipment for the EtherChannels.


Configure the Cluster Interface Mode on Each Unit

Before you enable clustering, you need to convert the firewall to use Spanned EtherChannels. Because clustering limits the types of interfaces you can use, this process lets you check your existing configuration for incompatible interfaces and then prevents you from configuring any unsupported interfaces.

Before you begin
  • You must set the mode separately on each ASA that you want to add to the cluster.

  • You can always configure the management-only interface as an Individual interface (recommended). The management interface can be an Individual interface even in transparent firewall mode.

  • If you configure the management interface as an Individual interface, you cannot enable dynamic routing for the management interface. You must use a static route.

Procedure

Step 1

Show any incompatible configuration so that you can force the interface mode and fix your configuration later; the mode is not changed with this command:

cluster interface-mode spanned check-details

Example:

ciscoasa(config)# cluster interface-mode spanned check-details

Step 2

Set the interface mode for clustering:

cluster interface-mode spanned force

Example:

ciscoasa(config)# cluster interface-mode spanned force

There is no default setting; you must explicitly choose the mode. If you have not set the mode, you cannot enable clustering.

The force option changes the mode without checking your configuration for incompatible settings. You need to manually fix any configuration issues after you change the mode. Because any interface configuration can only be fixed after you set the mode, we recommend using the force option so that you can at least start from the existing configuration. You can re-run the check-details option after you set the mode for more guidance.

Without the force option, if there is any incompatible configuration, you are prompted to clear your configuration and reload, thus requiring you to connect to the console port to reconfigure your management access. If your configuration is compatible (rare), the mode is changed and the configuration is preserved. If you do not want to clear your configuration, you can exit the command by typing n.

To remove the interface mode, enter the no cluster interface-mode command.


Configure Interfaces on the Control Node

You must modify any interface that is currently configured with an IP address to be cluster-ready before you enable clustering. For other interfaces, you can configure them before or after you enable clustering; we recommend pre-configuring all of your interfaces so that the complete configuration is synced to new cluster members.

This section describes how to configure interfaces to be compatible with clustering.

Configure the Management Interface as an Individual Interface

Individual interfaces are normal routed interfaces, each with their own IP address taken from a pool of IP addresses. The Main cluster IP address is a fixed address for the cluster that always belongs to the control node.

We recommend configuring the management interface as an Individual interface. Individual management interfaces let you connect directly to each unit if necessary, while a Spanned EtherChannel interface only allows connection to the control node.

Before you begin
  • For multiple context mode, perform this procedure in each context. If you are not already in the context configuration mode, enter the changeto context name command.

  • (Optional) Configure the interface as a device-local EtherChannel interface, and/or configure subinterfaces.

    • For an EtherChannel, this EtherChannel is local to the unit, and is not a Spanned EtherChannel.

Procedure

Step 1

Configure a pool of Local IP addresses (IPv4 and/or IPv6), one of which will be assigned to each cluster unit for the interface:

(IPv4)

ip local pool poolname first-address last-address [mask mask]

(IPv6)

ipv6 local pool poolname ipv6-address/prefix-length number_of_addresses

Example:

ciscoasa(config)# ip local pool ins 192.168.1.2-192.168.1.9
ciscoasa(config-if)# ipv6 local pool insipv6 2001:DB8:45:1002/64 8

Include at least as many addresses as there are units in the cluster. If you plan to expand the cluster, include additional addresses. The Main cluster IP address that belongs to the current primary unit is not a part of this pool; be sure to reserve an IP address on the same network for the Main cluster IP address.

You cannot determine the exact Local address assigned to each unit in advance; to see the address used on each unit, enter the show ip[v6] local pool poolname command. Each cluster member is assigned a member ID when it joins the cluster. The ID determines the Local IP used from the pool.

Step 2

Enter interface configuration mode:

interface interface_id

Example:

ciscoasa(config)# interface management 1/1

Step 3

Set the interface to management-only mode so that it does not pass through traffic:

management-only

By default, Management type interfaces are configured as management-only. In transparent mode, this command is always enabled for a Management type interface.

Step 4

Name the interface:

nameif name

Example:

ciscoasa(config-if)# nameif management

The name is a text string up to 48 characters, and is not case-sensitive. You can change the name by reentering this command with a new value.

Step 5

Set the Main cluster IP address and identify the cluster pool:

(IPv4)

ip address ip_address [mask] cluster-pool poolname

(IPv6)

ipv6 address ipv6-address/prefix-length cluster-pool poolname

Example:

ciscoasa(config-if)# ip address 192.168.1.1 255.255.255.0 cluster-pool ins
ciscoasa(config-if)# ipv6 address 2001:DB8:45:1002::99/64 cluster-pool insipv6

This IP address must be on the same network as the cluster pool addresses, but not be part of the pool. You can configure an IPv4 and/or an IPv6 address.

DHCP, PPPoE, and IPv6 autoconfiguration are not supported; you must manually configure the IP addresses. Manually configuring the link-local address is also not supported.

Step 6

Set the security level, where number is an integer between 0 (lowest) and 100 (highest):

security-level number

Example:

ciscoasa(config-if)# security-level 100

Step 7

Enable the interface:

no shutdown


Examples

The following example configures the Ethernet 1/3 and Ethernet 1/4 interfaces as a device-local EtherChannel, and then configures the EtherChannel as an Individual interface:


ip local pool mgmt 10.1.1.2-10.1.1.9
ipv6 local pool mgmtipv6 2001:DB8:45:1002/64 8

interface ethernet 1/3
channel-group 1 mode active
no shutdown

interface ethernet 1/4
channel-group 1 mode active
no shutdown

interface port-channel 1
nameif management
ip address 10.1.1.1 255.255.255.0 cluster-pool mgmt
ipv6 address 2001:DB8:45:1002::99/64 cluster-pool mgmtipv6
security-level 100
management-only

Configure Spanned EtherChannels

A Spanned EtherChannel spans all ASAs in the cluster, and provides load balancing as part of the EtherChannel operation.

Before you begin
  • You must be in Spanned EtherChannel interface mode.

  • For multiple context mode, start this procedure in the system execution space. If you are not already in the System configuration mode, enter the changeto system command.

  • For transparent mode, configure the bridge group. See Configure the Bridge Virtual Interface (BVI).

  • When using Spanned EtherChannels, the port-channel interface will not come up until clustering is fully enabled. This requirement prevents traffic from being forwarded to a unit that is not an active unit in the cluster.

Procedure

Step 1

Specify the interface you want to add to the channel group:

interface physical_interface

Example:

ciscoasa(config)# interface ethernet 1/1

The physical_interface ID includes the type, slot, and port number as type slot/ port. This first interface in the channel group determines the type and speed for all other interfaces in the group.

Step 2

Assign this interface to an EtherChannel:

channel-group channel_id mode active

Example:

ciscoasa(config-if)# channel-group 1 mode active

The channel_id is between 1 and 48. If the port-channel interface for this channel ID does not yet exist in the configuration, one will be added automatically:

interface port-channel channel_id

Only active mode is supported for Spanned EtherChannels.

Step 3

Enable the interface:

no shutdown

Step 4

(Optional) Add additional interfaces to the EtherChannel by repeating the process.

Example:

ciscoasa(config)# interface ethernet 1/2
ciscoasa(config-if)# channel-group 1 mode active
ciscoasa(config-if)# no shutdown

Multiple interfaces in the EtherChannel per unit are useful for connecting to switches in a VSS, vPC, StackWise, or StackWise Virtual.

Step 5

Specify the port-channel interface:

interface port-channel channel_id

Example:

ciscoasa(config)# interface port-channel 1

This interface was created automatically when you added an interface to the channel group.

Step 6

(Optional) If you are creating VLAN subinterfaces on this EtherChannel, do so now.

Example:

ciscoasa(config)# interface port-channel 1.10
ciscoasa(config-if)# vlan 10

The rest of this procedure applies to the subinterfaces.

Step 7

(Multiple Context Mode) Allocate the interface to a context. Then enter:

changeto context name
interface port-channel channel_id

Example:

ciscoasa(config)# context admin
ciscoasa(config)# allocate-interface port-channel1
ciscoasa(config)# changeto context admin
ciscoasa(config-if)# interface port-channel 1

For multiple context mode, the rest of the interface configuration occurs within each context.

Step 8

Name the interface:

nameif name

Example:

ciscoasa(config-if)# nameif inside

The name is a text string up to 48 characters, and is not case-sensitive. You can change the name by reentering this command with a new value.

Step 9

Perform one of the following, depending on the firewall mode.

  • Routed Mode—Set the IPv4 and/or IPv6 address:

    (IPv4)

    ip address ip_address [mask]

    (IPv6)

    ipv6 address ipv6-prefix/prefix-length

    Example:

    
    ciscoasa(config-if)# ip address 10.1.1.1 255.255.255.0
    ciscoasa(config-if)# ipv6 address 2001:DB8::1001/32
    
    

    DHCP, PPPoE, and IPv6 autoconfig are not supported. For point-to-point connections, you can specify a 31-bit subnet mask (255.255.255.254). In this case, no IP addresses are reserved for the network or broadcast addresses. Manually configuring the link-local address is also not supported.

  • Transparent Mode—Assign the interface to a bridge group:

    bridge-group number

    Example:

    
    ciscoasa(config-if)# bridge-group 1
    
    

    Where number is an integer between 1 and 100. You can assign up to 64 interfaces to a bridge group. You cannot assign the same interface to more than one bridge group. Note that the BVI configuration includes the IP address.

Step 10

Set the security level:

security-level number

Example:

ciscoasa(config-if)# security-level 50

Where number is an integer between 0 (lowest) and 100 (highest).

Step 11

Configure a global MAC address for a Spanned EtherChannel to avoid potential network connectivity problems:

mac-address mac_address

Example:

ciscoasa(config-if)# mac-address 000C.F142.4CDE

With a manually-configured MAC address, the MAC address stays with the current control unit. If you do not configure a MAC address, then if the control unit changes, the new control unit uses a new MAC address for the interface, which can cause a temporary network outage.

In multiple context mode, if you share an interface between contexts, you should instead enable auto-generation of MAC addresses so you do not need to set the MAC address manually. Note that you must manually configure the MAC address using this command for non-shared interfaces.

The mac_address is in H.H.H format, where H is a 16-bit hexadecimal digit. For example, the MAC address 00-0C-F1-42-4C-DE is entered as 000C.F142.4CDE.

The first two bytes of a manual MAC address cannot be A2 if you also want to use auto-generated MAC addresses.

Step 12

(Routed mode) For inter-site clustering, configure a site-specific MAC address and IP address for each site:

mac-address mac_address site-id number site-ip ip_address
Example:

ciscoasa(config-if)# mac-address aaaa.1111.1234
ciscoasa(config-if)# mac-address aaaa.1111.aaaa site-id 1 site-ip 10.9.9.1
ciscoasa(config-if)# mac-address aaaa.1111.bbbb site-id 2 site-ip 10.9.9.2
ciscoasa(config-if)# mac-address aaaa.1111.cccc site-id 3 site-ip 10.9.9.3
ciscoasa(config-if)# mac-address aaaa.1111.dddd site-id 4 site-ip 10.9.9.4

The site-specific IP addresses must be on the same subnet as the global IP address. The site-specific MAC address and IP address used by a unit depends on the site ID you specify in each unit’s bootstrap configuration.


Create the Bootstrap Configuration

Each node in the cluster requires a bootstrap configuration to join the cluster.

Configure the Control Node Bootstrap Settings

Each node in the cluster requires a bootstrap configuration to join the cluster. Typically, the first node you configure to join the cluster will be the control node. After you enable clustering, after an election period, the cluster elects a control node. With only one node in the cluster initially, that node will become the control node. Subsequent nodes that you add to the cluster will be data nodes.

Before you begin
  • Back up your configurations in case you later want to leave the cluster, and need to restore your configuration.

  • For multiple context mode, complete these procedures in the system execution space. To change from the context to the system execution space, enter the changeto system command.

  • You must use the console port to enable or disable clustering. You cannot use Telnet or SSH.

  • When you add a node to a running cluster, you may see temporary, limited packet/connection drops; this is expected behavior.

  • Pre-determine the size of the cluster control link. See Size the Cluster Control Link.

Procedure

Step 1

Enable the cluster control link interface before you join the cluster.

You will later identify this interface as the cluster control link when you enable clustering.

We recommend that you combine multiple cluster control link interfaces into an EtherChannel if you have enough interfaces. The EtherChannel is local to the ASA, and is not a Spanned EtherChannel.

The cluster control link interface configuration is not replicated from the control node to data nodes; however, you must use the same configuration on each node. Because this configuration is not replicated, you must configure the cluster control link interfaces separately on each node.

  • You cannot use a VLAN subinterface as the cluster control link.

  • You cannot use a Management x/x interface as the cluster control link, either alone or as an EtherChannel.

  1. Enter interface configuration mode:

    interface interface_id

    Example:
    
    ciscoasa(config)# interface ethernet 1/6
    
    
  2. (Optional, for an EtherChannel) Assign this physical interface to an EtherChannel:

    channel-group channel_id mode on

    Example:
    
    ciscoasa(config-if)# channel-group 1 mode on
    
    

    The channel_id is between 1 and 48. If the port-channel interface for this channel ID does not yet exist in the configuration, one will be added automatically:

    interface port-channel channel_id

    We recommend using the On mode for cluster control link member interfaces to reduce unnecessary traffic on the cluster control link. The cluster control link does not need the overhead of LACP traffic because it is an isolated, stable network. Note: We recommend setting data EtherChannels to Active mode.

  3. Enable the interface:

    no shutdown

    You only need to enable the interface; do not configure a name for the interface, or any other parameters.

  4. (For an EtherChannel) Repeat for each additional interface you want to add to the EtherChannel:

    Example:
    
    ciscoasa(config)# interface ethernet 1/7
    ciscoasa(config-if)# channel-group 1 mode on
    ciscoasa(config-if)# no shutdown
    
    

Step 2

Specify the maximum transmission node for the cluster control link interface to be at least 100 bytes higher than the highest MTU of the data interfaces.

mtu cluster bytes

Example:

ciscoasa(config)# mtu cluster 9198

Set the MTU between 1400 and 9198 bytes, but not between 2561 and 8362. Due to block pool handling, this MTU size is not optimal for system operation. The default MTU is 1500 bytes. We suggest setting the cluster control link MTU to the maximum. Because the cluster control link traffic includes data packet forwarding, the cluster control link needs to accommodate the entire size of a data packet plus cluster traffic overhead.

For example, because the maximum MTU is 9198 bytes, then the highest data interface MTU can be 9098, while the cluster control link can be set to 9198.

This command is a global configuration command, but is also part of the bootstrap configuration that is not replicated between nodes.

Step 3

Name the cluster and enter cluster configuration mode:

cluster group name

Example:

ciscoasa(config)# cluster group pod1

The name must be an ASCII string from 1 to 38 characters. You can only configure one cluster group per node. All members of the cluster must use the same name.

Step 4

Name this member of the cluster:

local-unit unit_name

Use a unique ASCII string from 1 to 38 characters. Each node must have a unique name. A node with a duplicated name will be not be allowed in the cluster.

Example:

ciscoasa(cfg-cluster)# local-unit node1

Step 5

Specify the cluster control link interface, preferably an EtherChannel:

cluster-interface interface_id ip ip_address mask

Example:

ciscoasa(cfg-cluster)# cluster-interface port-channel2 ip 192.168.1.1 255.255.255.0
INFO: Non-cluster interface config is cleared on Port-Channel2

Subinterfaces and Management interfaces are not allowed.

Specify an IPv4 address for the IP address; IPv6 is not supported for this interface. This interface cannot have a nameif configured.

For each node, specify a different IP address on the same network.

Step 6

If you use inter-site clustering, set the site ID for this node so it uses a site-specific MAC address:

site-id number

Example:

ciscoasa(cfg-cluster)# site-id 1

The number is between 1 and 8.

Step 7

Set the priority of this node for control node elections:

priority priority_number

Example:

ciscoasa(cfg-cluster)# priority 1

The priority is between 1 and 100, where 1 is the highest priority.

Step 8

(Optional) Set an authentication key for control traffic on the cluster control link:

key shared_secret

Example:

ciscoasa(cfg-cluster)# key chuntheunavoidable

The shared secret is an ASCII string from 1 to 63 characters. The shared secret is used to generate the key. This command does not affect datapath traffic, including connection state update and forwarded packets, which are always sent in the clear.

Step 9

(Optional) Manually specify the cLACP system ID and system priority:

clacp system-mac {mac_address | auto} [system-priority number]

Example:

ciscoasa(cfg-cluster)# clacp system-mac 000a.0000.aaaa

When using Spanned EtherChannels, the ASA uses cLACP to negotiate the EtherChannel with the neighbor switch. ASAs in a cluster collaborate in cLACP negotiation so that they appear as a single (virtual) device to the switch. One parameter in cLACP negotiation is a system ID, which is in the format of a MAC address. All ASAs in the cluster use the same system ID: auto-generated by the control node (the default) and replicated to all secondaries; or manually specified in this command in the form H.H.H, where H is a 16-bit hexadecimal digit. (For example, the MAC address 00-0A-00-00-AA-AA is entered as 000A.0000.AAAA.) You might want to manually configure the MAC address for troubleshooting purposes, for example, so that you can use an easily identified MAC address. Typically, you would use the auto-generated MAC address.

The system priority, between 1 and 65535, is used to decide which node is in charge of making a bundling decision. By default, the ASA uses priority 1, which is the highest priority. The priority needs to be higher than the priority on the switch.

This command is not part of the bootstrap configuration, and is replicated from the control node to the data nodes. However, you cannot change this value after you enable clustering.

Step 10

Enable clustering:

enable [noconfirm]

Example:

ciscoasa(cfg-cluster)# enable
INFO: Clustering is not compatible with following commands:
policy-map global_policy
 class inspection_default
 inspect skinny
policy-map global_policy
 class inspection_default
  inspect sip
 Would you like to remove these commands? [Y]es/[N]o:Y

INFO: Removing incompatible commands from running configuration...
Cryptochecksum (changed): f16b7fc2 a742727e e40bc0b0 cd169999
INFO: Done

When you enter the enable command, the ASA scans the running configuration for incompatible commands for features that are not supported with clustering, including commands that may be present in the default configuration. You are prompted to delete the incompatible commands. If you respond No, then clustering is not enabled. Use the noconfirm keyword to bypass the confirmation and delete incompatible commands automatically.

For the first node enabled, a control node election occurs. Because the first node should be the only member of the cluster so far, it will become the control node. Do not perform any configuration changes during this period.

To disable clustering, enter the no enable command.

Note

 

If you disable clustering, all data interfaces are shut down, and only the management-only interface is active.


Examples

The following example configures a management interface, configures a device-local EtherChannel for the cluster control link, and then enables clustering for the ASA called “node1,” which will become the control node because it is added to the cluster first:


ip local pool mgmt 10.1.1.2-10.1.1.9
ipv6 local pool mgmtipv6 2001:DB8::1002/32 8
interface management 1/1
   nameif management
   ip address 10.1.1.1 255.255.255.0 cluster-pool mgmt
   ipv6 address 2001:DB8::1001/32 cluster-pool mgmtipv6
   security-level 100
   management-only
   no shutdown

interface ethernet 1/6
   channel-group 1 mode on
   no shutdown

interface ethernet 1/7
   channel-group 1 mode on
   no shutdown

cluster group pod1
   local-unit node1
   cluster-interface port-channel1 ip 192.168.1.1 255.255.255.0
   priority 1
   key chuntheunavoidable
   enable noconfirm

Configure Data Node Bootstrap Settings

Perform the following procedure to configure the data nodes.

Before you begin
  • You must use the console port to enable or disable clustering. You cannot use Telnet or SSH.

  • Back up your configurations in case you later want to leave the cluster, and need to restore your configuration.

  • For multiple context mode, complete this procedure in the system execution space. To change from the context to the system execution space, enter the changeto system command.

  • If you have any interfaces in your configuration that have not been configured for clustering (for example, the default configuration Management 1/1 interface), you can join the cluster as a data node (with no possibility of becoming the control node in a current election).

  • When you add a node to a running cluster, you may see temporary, limited packet/connection drops; this is expected behavior.

Procedure

Step 1

Configure the same cluster control link interface as you configured for the control node.

Example:

ciscoasa(config)# interface ethernet 1/6
ciscoasa(config-if)# channel-group 1 mode on
ciscoasa(config-if)# no shutdown
ciscoasa(config)# interface ethernet 1/7
ciscoasa(config-if)# channel-group 1 mode on
ciscoasa(config-if)# no shutdown

Step 2

Specify the same MTU that you configured for the control node:

Example:

ciscoasa(config)# mtu cluster 9198

Step 3

Identify the same cluster name that you configured for the control node:

Example:

ciscoasa(config)# cluster group pod1

Step 4

Name this member of the cluster with a unique string:

local-unit unit_name

Example:

ciscoasa(cfg-cluster)# local-unit node2

Specify an ASCII string from 1 to 38 characters.

Each node must have a unique name. A node with a duplicated name will be not be allowed in the cluster.

Step 5

Specify the same cluster control link interface that you configured for the control node, but specify a different IP address on the same network for each node:

cluster-interface interface_id ip ip_address mask

Example:

ciscoasa(cfg-cluster)# cluster-interface port-channel2 ip 192.168.1.2 255.255.255.0
INFO: Non-cluster interface config is cleared on Port-Channel2

Specify an IPv4 address for the IP address; IPv6 is not supported for this interface. This interface cannot have a nameif configured.

Step 6

If you use inter-site clustering, set the site ID for this node so it uses a site-specific MAC address:

site-id number

Example:

ciscoasa(cfg-cluster)# site-id 1

The number is between 1 and 8.

Step 7

Set the priority of this node for control node elections, typically to a higher value than the control node:

priority priority_number

Example:

ciscoasa(cfg-cluster)# priority 2

Set the priority between 1 and 100, where 1 is the highest priority.

Step 8

Set the same authentication key that you set for the control node:

Example:

ciscoasa(cfg-cluster)# key chuntheunavoidable

Step 9

Enable clustering:

enable as-slave

You can avoid any configuration incompatibilities (primarily the existence of any interfaces not yet configured for clustering) by using the enable as-slave command. This command ensures the data node joins the cluster with no possibility of becoming the control node in any current election. Its configuration is overwritten with the one synced from the control node.

To disable clustering, enter the no enable command.

Note

 

If you disable clustering, all data interfaces are shut down, and only the management interface is active.


Examples

The following example includes the configuration for a data node, node2:


interface ethernet 1/6

channel-group 1 mode on
no shutdown

interface ethernet 1/7

channel-group 1 mode on
no shutdown

cluster group pod1

local-unit node2
cluster-interface port-channel1 ip 192.168.1.2 255.255.255.0
priority 2
key chuntheunavoidable
enable as-slave

Customize the Clustering Operation

You can customize clustering health monitoring, TCP connection replication delay, flow mobility and other optimizations.

Perform these procedures on the control node.

Configure Basic ASA Cluster Parameters

You can customize cluster settings on the control node.

Before you begin
  • For multiple context mode, complete this procedure in the system execution space on the control node. To change from the context to the system execution space, enter the changeto system command.

Procedure

Step 1

Enter cluster configuration mode:

cluster group name

Step 2

(Optional) Enable console replication from data nodes to the control node:

console-replicate

This feature is disabled by default. The ASA prints out some messages directly to the console for certain critical events. If you enable console replication, data nodes send the console messages to the control node so that you only need to monitor one console port for the cluster.

Step 3

Set the minimum trace level for clustering events:

trace-level level

Set the minimum level as desired:

  • critical —Critical events (severity=1)

  • warning —Warnings (severity=2)

  • informational —Informational events (severity=3)

  • debug —Debugging events (severity=4)


Configure Health Monitoring and Auto-Rejoin Settings

This procedure configures node and interface health monitoring.

You might want to disable health monitoring of non-essential interfaces, for example, the management interface. You can monitor any port-channel ID, redundant ID, or single physical interface ID. Health monitoring is not performed on VLAN subinterfaces or virtual interfaces such as VNIs or BVIs. You cannot configure monitoring for the cluster control link; it is always monitored.

Procedure

Step 1

Enter cluster configuration mode.

cluster group name

Example:

ciscoasa(config)# cluster group test
ciscoasa(cfg-cluster)#

Step 2

Customize the cluster node health check feature.

health-check [holdtime timeout] [vss-enabled]

To determine node health, the ASA cluster nodes send heartbeat messages on the cluster control link to other nodes. If a node does not receive any heartbeat messages from a peer node within the holdtime period, the peer node is considered unresponsive or dead.

  • holdtime timeout —Determines the amount of time between node heartbeat status messages, between .3 and 45 seconds; The default is 3 seconds.

  • vss-enabled —Floods the heartbeat messages on all EtherChannel interfaces in the cluster control link to ensure that at least one of the switches can receive them. If you configure the cluster control link as an EtherChannel (recommended), and it is connected to a VSS, vPC, StackWise, or StackWise Virtual pair, then you might need to enable the vss-enabled option. For some switches, when one node in the redundant system is shutting down or booting up, EtherChannel member interfaces connected to that switch may appear to be Up to the ASA, but they are not passing traffic on the switch side. The ASA can be erroneously removed from the cluster if you set the ASA holdtime timeout to a low value (such as .8 seconds), and the ASA sends keepalive messages on one of these EtherChannel interfaces.

When any topology changes occur (such as adding or removing a data interface, enabling or disabling an interface on the ASA or the switch, or adding an additional switch to form a VSS, vPC, StackWise, or StackWise Virtual) you should disable the health check feature and also disable interface monitoring for the disabled interfaces (no health-check monitor-interface ). When the topology change is complete, and the configuration change is synced to all nodes, you can re-enable the health check feature.

Example:

ciscoasa(cfg-cluster)# health-check holdtime 5

Step 3

Disable the interface health check on an interface.

no health-check monitor-interface interface_id

The interface health check monitors for link failures. If all physical ports for a given logical interface fail on a particular node, but there are active ports under the same logical interface on other nodes, then the node is removed from the cluster. The amount of time before the ASA removes a member from the cluster depends on the type of interface and whether the node is an established member or is joining the cluster. Health check is enabled by default for all interfaces. You can disable it per interface using the no form of this command. You might want to disable health monitoring of non-essential interfaces, for example, the management interface.

  • interface_id —Disables monitoring of any port-channel ID, redundant ID, or single physical interface ID. Health monitoring is not performed on VLAN subinterfaces or virtual interfaces such as VNIs or BVIs. You cannot configure monitoring for the cluster control link; it is always monitored.

When any topology changes occur (such as adding or removing a data interface, enabling or disabling an interface on the ASA or the switch, or adding an additional switch to form a VSS, vPC, StackWise, or StackWise Virtual) you should disable the health check feature (no health-check ) and also disable interface monitoring for the disabled interfaces. When the topology change is complete, and the configuration change is synced to all nodes, you can re-enable the health check feature.

Example:

ciscoasa(cfg-cluster)# no health-check monitor-interface management1/1

Step 4

Customize the auto-rejoin cluster settings after a health check failure.

health-check {data-interface | cluster-interface | system} auto-rejoin [unlimited | auto_rejoin_max] auto_rejoin_interval auto_rejoin_interval_variation

  • system —Specifies the auto-rejoin settings for internal errors. Internal failures include: application sync timeout; inconsistent application statuses; and so on.

  • unlimited —(Default for the cluster-interface ) Does not limit the number of rejoin attempts.

  • auto-rejoin-max —Sets the number of rejoin attempts, between 0 and 65535. 0 disables auto-rejoining. The default for the data-interface and system is 3.

  • auto_rejoin_interval —Defines the interval duration in minutes between rejoin attempts, between 2 and 60. The default value is 5 minutes. The maximum total time that the node attempts to rejoin the cluster is limited to 14400 minutes (10 days) from the time of last failure.

  • auto_rejoin_interval_variation —Defines if the interval duration increases. Set the value between 1 and 3: 1 (no change); 2 (2 x the previous duration), or 3 (3 x the previous duration). For example, if you set the interval duration to 5 minutes, and set the variation to 2, then the first attempt is after 5 minutes; the 2nd attempt is 10 minutes (2 x 5); the 3rd attempt 20 minutes (2 x 10), and so on. The default value is 1 for the cluster-interface and 2 for the data-interface and system.

Example:

ciscoasa(cfg-cluster)# health-check data-interface auto-rejoin 10 3 3

Step 5

Configure the debounce time before the ASA considers an interface to be failed and the node is removed from the cluster.

health-check monitor-interface debounce-time ms

Example:

ciscoasa(cfg-cluster)# health-check monitor-interface debounce-time 300

Set the debounce time between 300 and 9000 ms. The default is 500 ms. Lower values allow for faster detection of interface failures. Note that configuring a lower debounce time increases the chances of false-positives. When an interface status update occurs, the ASA waits the number of milliseconds specified before marking the interface as failed and the node is removed from the cluster. In the case of an EtherChannel that transitions from a down state to an up state (for example, the switch reloaded, or the switch enabled an EtherChannel), a longer debounce time can prevent the interface from appearing to be failed on a cluster node just because another cluster node was faster at bundling the ports.

Step 6

(Optional) Configure traffic load monitoring.

load-monitor [frequency seconds] [intervals intervals]

  • frequency seconds —Sets the time in seconds between monitoring messages, between 10 and 360 seconds. The default is 20 seconds.

  • intervals intervals —Sets the number of intervals for which the ASA maintains data, between 1 and 60. The default is 30.

You can monitor the traffic load for cluster members, including total connection count, CPU and memory usage, and buffer drops. If the load is too high, you can choose to manually disable clustering on the node if the remaining nodes can handle the load, or adjust the load balancing on the external switch. This feature is enabled by default. For example, for inter-chassis clustering on the Firepower 9300 with 3 security modules in each chassis, if 2 security modules in a chassis leave the cluster, then the same amount of traffic to the chassis will be sent to the remaining module and potentially overwhelm it. You can periodically monitor the traffic load. If the load is too high, you can choose to manually disable clustering on the node.

Use the show cluster info load-monitor command to view the traffic load.

Example:

ciscoasa(cfg-cluster)# load-monitor frequency 50 intervals 25
ciscoasa(cfg-cluster)# show cluster info load-monitor
ID  Unit Name
0  B
1  A_1
Information from all units with 50 second interval:
Unit     Connections    Buffer Drops   Memory Used   CPU Used
Average from last 1 interval:
   0           0            0            14              25
   1           0            0            16              20
Average from last 25 interval:
   0           0            0            12              28
   1           0            0            13              27


Example

The following example configures the health-check holdtime to .3 seconds; enables VSS; disables monitoring on the Ethernet 1/2 interface, which is used for management; sets the auto-rejoin for data interfaces to 4 attempts starting at 2 minutes, increasing the duration by 3 x the previous interval; and sets the auto-rejoin for the cluster control link to 6 attempts every 2 minutes.


ciscoasa(config)# cluster group test
ciscoasa(cfg-cluster)# health-check holdtime .3 vss-enabled
ciscoasa(cfg-cluster)# no health-check monitor-interface ethernet1/2
ciscoasa(cfg-cluster)# health-check data-interface auto-rejoin 4 2 3
ciscoasa(cfg-cluster)# health-check cluster-interface auto-rejoin 6 2 1

Configure Connection Rebalancing and the Cluster TCP Replication Delay

You can configure connection rebalancing. For more information, see Rebalancing New TCP Connections Across the Cluster

Enable the cluster replication delay for TCP connections to help eliminate the “unnecessary work” related to short-lived flows by delaying the director/backup flow creation. Note that if a node fails before the director/backup flow is created, then those flows cannot be recovered. Similarly, if traffic is rebalanced to a different node before the flow is created, then the flow cannot be recovered. You should not enable the TCP replication delay for traffic on which you disable TCP randomization.

Procedure

Step 1

Enable the cluster replication delay for TCP connections:

cluster replication delay seconds {http | match tcp {host ip_address | ip_address mask | any | any4 | any6} [{eq | lt | gt} port] {host ip_address | ip_address mask | any | any4 | any6} [{eq | lt | gt} port]}

Example:

ciscoasa(config)# cluster replication delay 15 match tcp any any eq ftp
ciscoasa(config)# cluster replication delay 15 http

Set the seconds between 1 and 15. The http delay is enabled by default for 5 seconds.

In multiple context mode, configure this setting within the context.

Step 2

Enter cluster configuration mode:

cluster group name

Step 3

(Optional) Enable connection rebalancing for TCP traffic:

conn-rebalance [frequency seconds]

Example:

ciscoasa(cfg-cluster)# conn-rebalance frequency 60

This command is disabled by default. If enabled, ASAs exchange information about the connections per second periodically, and offload new connections from devices with more connections per second to less loaded devices. Existing connections are never moved. Moreover, because this command only rebalances based on connections per second, the total number of established connections on each node is not considered, and the total number of connections may not be equal. The frequency, between 1 and 360 seconds, specifies how often the load information is exchanged. The default is 5 seconds.

Once a connection is offloaded to a different node, it becomes an asymmetric connection.

Do not configure connection rebalancing for inter-site topologies; you do not want connections rebalanced to cluster members at a different site.


Configure Inter-Site Features

For inter-site clustering, you can customize your configuration to enhance redundancy and stability.

Enable Director Localization

To improve performance and reduce round-trip time latency for inter-site clustering for data centers, you can enable director localization. New connections are typically load-balanced and owned by cluster members within a given site. However, the ASA assigns the director role to a member at any site. Director localization enables additional director roles: a local director at the same site as the owner, and a global director that can be at any site. Keeping the owner and director at the same site improves performance. Also, if the original owner fails, the local director chooses a new connection owner at the same site. The global director is used if a cluster member receives packets for a connection that is owned on a different site.

Before you begin
  • Set the site ID for the cluster member in the bootstrap configuration.

  • The following traffic types do not support localization: NAT or PAT traffic; SCTP-inspected traffic; Fragmentation owner query.

Procedure

Step 1

Enter cluster configuration mode.

cluster group name

Example:

ciscoasa(config)# cluster group cluster1
ciscoasa(cfg-cluster)# 

Step 2

Enable director localization.

director-localization


Enable Site Redundancy

To protect flows from a site failure, you can enable site redundancy. If the connection backup owner is at the same site as the owner, then an additional backup owner will be chosen from another site to protect flows from a site failure.

Before you begin
  • Set the site ID for the cluster member in the bootstrap configuration.

Procedure

Step 1

Enter cluster configuration mode.

cluster group name

Example:

ciscoasa(config)# cluster group cluster1
ciscoasa(cfg-cluster)# 

Step 2

Enable site redundancy.

site-redundancy


Configure Per-Site Gratuitous ARP

The ASA now generates gratuitous ARP (GARP) packets to keep the switching infrastructure up to date: the highest priority member at each site periodically generates GARP traffic for the global MAC/IP addresses.

When using per-site MAC and IP addresses, packets sourced from the cluster use a site-specific MAC address and IP address, while packets received by the cluster use a global MAC address and IP address. If traffic is not generated from the global MAC address periodically, you could experience a MAC address timeout on your switches for the global MAC address. After a timeout, traffic destined for the global MAC address will be flooded across the entire switching infrastructure, which can cause performance and security concerns.

GARP is enabled by default when you set the site ID for each unit and the site MAC address for each Spanned EtherChannel. You can customize the GARP interval, or you can disable GARP.

Before you begin
  • Set the site ID for the cluster member in the bootstrap configuration.

  • Set the per-site MAC address for the Spanned EtherChannel in the control unit configuration.

Procedure

Step 1

Enter cluster configuration mode.

cluster group name

Example:

ciscoasa(config)# cluster group cluster1
ciscoasa(cfg-cluster)# 

Step 2

Customize the GARP interval.

site-periodic-garp interval seconds

  • secondsSets the time in seconds between GARP generation, between 1 and 1000000 seconds. The default is 290 seconds.

To disable GARP, enter no site-periodic-garp interval .


Configure Cluster Flow Mobility

You can inspect LISP traffic to enable flow mobility when a server moves between sites.

About LISP Inspection

You can inspect LISP traffic to enable flow mobility between sites.

About LISP

Data center virtual machine mobility such as VMware VMotion enables servers to migrate between data centers while maintaining connections to clients. To support such data center server mobility, routers need to be able to update the ingress route towards the server when it moves. Cisco Locator/ID Separation Protocol (LISP) architecture separates the device identity, or endpoint identifier (EID), from its location, or routing locator (RLOC), into two different numbering spaces, making server migration transparent to clients. For example, when a server moves to a new site and a client sends traffic to the server, the router redirects traffic to the new location.

LISP requires routers and servers in certain roles, such as the LISP egress tunnel router (ETR), ingress tunnel router (ITR), first hop routers, map resolver (MR), and map server (MS). When the first hop router for the server senses that the server is connected to a different router, it updates all of the other routers and databases so that the ITR connected to the client can intercept, encapsulate, and send traffic to the new server location.

ASA LISP Support

The ASA does not run LISP itself; it can, however, inspect LISP traffic for location changes and then use this information for seamless clustering operation. Without LISP integration, when a server moves to a new site, traffic comes to an ASA cluster member at the new site instead of to the original flow owner. The new ASA forwards traffic to the ASA at the old site, and then the old ASA has to send traffic back to the new site to reach the server. This traffic flow is sub-optimal and is known as “tromboning” or “hair-pinning.”

With LISP integration, the ASA cluster members can inspect LISP traffic passing between the first hop router and the ETR or ITR, and can then change the flow owner to be at the new site.

LISP Guidelines
  • The ASA cluster members must reside between the first hop router and the ITR or ETR for the site. The ASA cluster itself cannot be the first hop router for an extended segment.

  • Only fully-distributed flows are supported; centralized flows, semi-distributed flows, or flows belonging to individual nodes are not moved to new owners. Semi-distributed flows include applications, such as SIP, where all child flows are owned by the same ASA that owns the parent flow.

  • The cluster only moves Layer 3 and 4 flow states; some application data might be lost.

  • For short-lived flows or non-business-critical flows, moving the owner may not be worthwhile. You can control the types of traffic that are supported with this feature when you configure the inspection policy, and should limit flow mobility to essential traffic.

ASA LISP Implementation

This feature includes several inter-related configurations (all of which are described in this chapter):

  1. (Optional) Limit inspected EIDs based on the host or server IP address—The first hop router might send EID-notify messages for hosts or networks the ASA cluster is not involved with, so you can limit the EIDs to only those servers or networks relevant to your cluster. For example, if the cluster is only involved with 2 sites, but LISP is running on 3 sites, you should only include EIDs for the 2 sites involved with the cluster.

  2. LISP traffic inspection—The ASA inspects LISP traffic on UDP port 4342 for the EID-notify message sent between the first hop router and the ITR or ETR. The ASA maintains an EID table that correlates the EID and the site ID. For example, you should inspect LISP traffic with a source IP address of the first hop router and a destination address of the ITR or ETR. Note that LISP traffic is not assigned a director, and LISP traffic itself does not participate in cluster state sharing.

  3. Service Policy to enable flow mobility on specified traffic—You should enable flow mobility on business-critical traffic. For example, you can limit flow mobility to only HTTPS traffic, and/or to traffic to specific servers.

  4. Site IDs—The ASA uses the site ID for each cluster node to determine the new owner.

  5. Cluster-level configuration to enable flow mobility—You must also enable flow mobility at the cluster level. This on/off toggle lets you easily enable or disable flow mobility for a particular class of traffic or applications.

Configure LISP Inspection

You can inspect LISP traffic to enable flow mobility when a server moves between sites.

Before you begin
Procedure

Step 1

(Optional) Configure a LISP inspection map to limit inspected EIDs based on IP address, and to configure the LISP pre-shared key:

  1. Create an extended ACL; only the destination IP address is matched to the EID embedded address:

    access list eid_acl_name extended permit ip source_address mask destination_address mask

    Both IPv4 and IPv6 ACLs are accepted. See the command reference for exact access-list extended syntax.

  2. Create the LISP inspection map, and enter parameters mode:

    policy-map type inspect lisp inspect_map_name

    parameters

  3. Define the allowed EIDs by identifying the ACL you created:

    allowed-eid access-list eid_acl_name

    The first hop router or ITR/ETR might send EID-notify messages for hosts or networks that the ASA cluster is not involved with, so you can limit the EIDs to only those servers or networks relevant to your cluster. For example, if the cluster is only involved with 2 sites, but LISP is running on 3 sites, you should only include EIDs for the 2 sites involved with the cluster.

  4. If necessary, enter the pre-shared key:

    validate-key key

Example:

ciscoasa(config)# access-list TRACKED_EID_LISP extended permit ip any 10.10.10.0 255.255.255.0
ciscoasa(config)# policy-map type inspect lisp LISP_EID_INSPECT
ciscoasa(config-pmap)# parameters 
ciscoasa(config-pmap-p)# allowed-eid access-list TRACKED_EID_LISP
ciscoasa(config-pmap-p)# validate-key MadMaxShinyandChrome

Step 2

Configure LISP inspection for UDP traffic between the first hop router and the ITR or ETR on port 4342:

  1. Configure the extended ACL to identify LISP traffic:

    access list inspect_acl_name extended permit udp source_address mask destination_address mask eq 4342

    You must specify UDP port 4342. Both IPv4 and IPv6 ACLs are accepted. See the command reference for exact access-list extended syntax.

  2. Create a class map for the ACL:

    class-map inspect_class_name

    match access-list inspect_acl_name

  3. Specify the policy map, the class map, enable inspection using the optional LISP inspection map, and apply the service policy to an interface (if new):

    policy-map policy_map_name

    class inspect_class_name

    inspect lisp [inspect_map_name]

    service-policy policy_map_name {global | interface ifc_name}

    If you have an existing service policy, specify the existing policy map name. By default, the ASA includes a global policy called global_policy, so for a global policy, specify that name. You can also create one service policy per interface if you do not want to apply the policy globally. LISP inspection is applied to traffic bidirectionally so you do not need to apply the service policy on both the source and destination interfaces; all traffic that enters or exits the interface to which you apply the policy map is affected if the traffic matches the class map for both directions.

Example:

ciscoasa(config)# access-list LISP_ACL extended permit udp host 192.168.50.89 host 192.168.10.8 eq 4342
ciscoasa(config)# class-map LISP_CLASS
ciscoasa(config-cmap)# match access-list LISP_ACL
ciscoasa(config-cmap)# policy-map INSIDE_POLICY
ciscoasa(config-pmap)# class LISP_CLASS
ciscoasa(config-pmap-c)# inspect lisp LISP_EID_INSPECT
ciscoasa(config)# service-policy INSIDE_POLICY interface inside

The ASA inspects LISP traffic for the EID-notify message sent between the first hop router and the ITR or ETR. The ASA maintains an EID table that correlates the EID and the site ID.

Step 3

Enable Flow Mobility for a traffic class:

  1. Configure the extended ACL to identify business critical traffic that you want to re-assign to the most optimal site when servers change sites:

    access list flow_acl_name extended permit udp source_address mask destination_address mask eq port

    Both IPv4 and IPv6 ACLs are accepted. See the command reference for exact access-list extended syntax. You should enable flow mobility on business-critical traffic. For example, you can limit flow mobility to only HTTPS traffic, and/or to traffic to specific servers.

  2. Create a class map for the ACL:

    class-map flow_map_name

    match access-list flow_acl_name

  3. Specify the same policy map on which you enabled LISP inspection, the flow class map, and enable flow mobility:

    policy-map policy_map_name

    class flow_map_name

    cluster flow-mobility lisp

Example:

ciscoasa(config)# access-list IMPORTANT-FLOWS extended permit tcp any 10.10.10.0 255.255.255.0 eq https
ciscoasa(config)# class-map IMPORTANT-FLOWS-MAP
ciscoasa(config)# match access-list IMPORTANT-FLOWS
ciscoasa(config-cmap)# policy-map INSIDE_POLICY
ciscoasa(config-pmap)# class IMPORTANT-FLOWS-MAP
ciscoasa(config-pmap-c)# cluster flow-mobility lisp

Step 4

Enter cluster group configuration mode, and enable flow mobility for the cluster:

cluster group name

flow-mobility lisp

This on/off toggle lets you easily enable or disable flow mobility.


Examples

The following example:

  • Limits EIDs to those on the 10.10.10.0/24 network

  • Inspects LISP traffic (UDP 4342) between a LISP router at 192.168.50.89 (on inside) and an ITR or ETR router (on another ASA interface) at 192.168.10.8

  • Enables flow mobility for all inside traffic going to a server on 10.10.10.0/24 using HTTPS.

  • Enables flow mobility for the cluster.


access-list TRACKED_EID_LISP extended permit ip any 10.10.10.0 255.255.255.0
policy-map type inspect lisp LISP_EID_INSPECT
   parameters 
      allowed-eid access-list TRACKED_EID_LISP
      validate-key MadMaxShinyandChrome
!
access-list LISP_ACL extended permit udp host 192.168.50.89 host 192.168.10.8 eq 4342
class-map LISP_CLASS
   match access-list LISP_ACL
policy-map INSIDE_POLICY
   class LISP_CLASS
      inspect lisp LISP_EID_INSPECT
service-policy INSIDE_POLICY interface inside
!
access-list IMPORTANT-FLOWS extended permit tcp any 10.10.10.0 255.255.255.0 eq https
class-map IMPORTANT-FLOWS-MAP
   match access-list IMPORTANT-FLOWS
policy-map INSIDE_POLICY
   class IMPORTANT-FLOWS-MAP
      cluster flow-mobility lisp
!
cluster group cluster1
   flow-mobility lisp

Manage Cluster Nodes

After you deploy the cluster, you can change the configuration and manage cluster nodes.

Become an Inactive Node

To become an inactive member of the cluster, disable clustering on the node while leaving the clustering configuration intact.


Note


When an ASA becomes inactive (either manually or through a health check failure), all data interfaces are shut down; only the management-only interface can send and receive traffic. To resume traffic flow, re-enable clustering; or you can remove the node altogether from the cluster. The management interface remains up using the IP address the node received from the cluster IP pool. However if you reload, and the node is still inactive in the cluster (for example, you saved the configuration with clustering disabled), then the management interface is disabled. You must use the console port for any further configuration.


Before you begin

  • You must use the console port; you cannot enable or disable clustering from a remote CLI connection.

  • For multiple context mode, perform this procedure in the system execution space. If you are not already in the System configuration mode, enter the changeto system command.

Procedure


Step 1

Enter cluster configuration mode:

cluster group name

Example:


ciscoasa(config)# cluster group pod1

Step 2

Disable clustering:

no enable

If this node was the control node, a new control election takes place, and a different member becomes the control node.

The cluster configuration is maintained, so that you can enable clustering again later.


Deactivate a Node

To deactivate a member other than the node you are logged into, perform the following steps.


Note


When an ASA becomes inactive, all data interfaces are shut down; only the management-only interface can send and receive traffic. To resume traffic flow, re-enable clustering. The management interface remains up using the IP address the node received from the cluster IP pool. However if you reload, and the node is still inactive in the cluster (for example, if you saved the configuration with clustering disabled), the management interface is disabled. You must use the console port for any further configuration.


Before you begin

For multiple context mode, perform this procedure in the system execution space. If you are not already in the System configuration mode, enter the changeto system command.

Procedure


Remove the node from the cluster.

cluster remove unit node_name

The bootstrap configuration remains intact, as well as the last configuration synched from the control node, so that you can later re-add the node without losing your configuration. If you enter this command on a data node to remove the control node, a new control node is elected.

To view member names, enter cluster remove unit ?, or enter the show cluster info command.

Example:


ciscoasa(config)# cluster remove unit ?

Current active units in the cluster:
asa2

ciscoasa(config)# cluster remove unit asa2
WARNING: Clustering will be disabled on unit asa2. To bring it back
to the cluster please logon to that unit and re-enable clustering


Rejoin the Cluster

If a node was removed from the cluster, for example for a failed interface or if you manually deactivated a member, you must manually rejoin the cluster.

Before you begin

  • You must use the console port to reenable clustering. Other interfaces are shut down.

  • For multiple context mode, perform this procedure in the system execution space. If you are not already in the System configuration mode, enter the changeto system command.

  • Make sure the failure is resolved before you try to rejoin the cluster.

Procedure


Step 1

At the console, enter cluster configuration mode:

cluster group name

Example:


ciscoasa(config)# cluster group pod1

Step 2

Enable clustering.

enable


Leave the Cluster

If you want to leave the cluster altogether, you need to remove the entire cluster bootstrap configuration. Because the current configuration on each node is the same (synced from the active unit), leaving the cluster also means either restoring a pre-clustering configuration from backup, or clearing your configuration and starting over to avoid IP address conflicts.

Before you begin

You must use the console port; when you remove the cluster configuration, all interfaces are shut down, including the management interface and cluster control link. Moreover, you cannot enable or disable clustering from a remote CLI connection.

Procedure


Step 1

For a data node, disable clustering:


cluster group cluster_name
  no enable

Example:


ciscoasa(config)# cluster group cluster1
ciscoasa(cfg-cluster)# no enable

You cannot make configuration changes while clustering is enabled on a data node.

Step 2

Clear the cluster configuration:

clear configure cluster

The ASA shuts down all interfaces including the management interface and cluster control link.

Step 3

Disable cluster interface mode:

no cluster interface-mode

The mode is not stored in the configuration and must be reset manually.

Step 4

If you have a backup configuration, copy the backup configuration to the running configuration:

copy backup_cfg running-config

Example:


ciscoasa(config)# copy backup_cluster.cfg running-config

Source filename [backup_cluster.cfg]?

Destination filename [running-config]?
ciscoasa(config)#

Step 5

Save the configuration to startup:

write memory

Step 6

If you do not have a backup configuration, reconfigure management access. Be sure to change the interface IP addresses, and restore the correct hostname, for example.


Change the Control Node


Caution


The best method to change the control node is to disable clustering on the control node, wait for a new control election, and then re-enable clustering. If you must specify the exact node you want to become the control node, use the procedure in this section. Note, however, that for centralized features, if you force a control node change using this procedure, then all connections are dropped, and you have to re-establish the connections on the new control node.


To change the control node, perform the following steps.

Before you begin

For multiple context mode, perform this procedure in the system execution space. If you are not already in the System configuration mode, enter the changeto system command.

Procedure


Set a new node as the control node:

cluster master unitnode_name

Example:


ciscoasa(config)# cluster master unit asa2

You will need to reconnect to the Main cluster IP address.

To view member names, enter cluster master unit ? (to see all names except the current node), or enter the show cluster info command.


Execute a Command Cluster-Wide

To send a command to all nodes in the cluster, or to a specific node, perform the following steps. Sending a show command to all nodes collects all output and displays it on the console of the current node. Other commands, such as capture and copy, can also take advantage of cluster-wide execution.

Procedure


Send a command to all nodes, or if you specify the node name, a specific node:

cluster exec [unit node_name] command

Example:


ciscoasa# cluster exec show xlate

To view node names, enter cluster exec unit ? (to see all names except the current node), or enter the show cluster info command.


Examples

To copy the same capture file from all nodes in the cluster at the same time to a TFTP server, enter the following command on the control node:


ciscoasa# cluster exec copy /pcap capture: tftp://10.1.1.56/capture1.pcap

Multiple PCAP files, one from each node, are copied to the TFTP server. The destination capture file name is automatically attached with the node name, such as capture1_asa1.pcap, capture1_asa2.pcap, and so on. In this example, asa1 and asa2 are cluster node names.

The following sample output for the cluster exec show port-channel summary command shows EtherChannel information for each node in the cluster:


ciscoasa# cluster exec show port-channel summary
master(LOCAL):***********************************************************
 Number of channel-groups in use: 2
Group  Port-channel  Protocol  Span-cluster  Ports
------+-------------+-----------+-----------------------------------------------
1         Po1              LACP      	Yes  Gi0/0(P)
2         Po2              LACP      	Yes  Gi0/1(P)
 slave:******************************************************************
 Number of channel-groups in use: 2
Group  Port-channel  Protocol  Span-cluster   Ports
------+-------------+-----------+-----------------------------------------------
1         Po1              LACP      	Yes   Gi0/0(P)
2         Po2              LACP      	Yes   Gi0/1(P)

Monitoring the ASA Cluster

You can monitor and troubleshoot cluster status and connections.

Monitoring Cluster Status

See the following commands for monitoring cluster status:

  • show cluster info [health [details]]

    With no keywords, the show cluster info command shows the status of all members of the cluster.

    The show cluster info health command shows the current health of interfaces, nodes, and the cluster overall. The details keyword shows the number heartbeat message failures.

    See the following output for the show cluster info command:

    
    ciscoasa# show cluster info
    Cluster stbu: On
      This is "C" in state SLAVE
          ID        : 0
          Site ID   : 1
                Version   : 9.4(1)
          Serial No.: P3000000025
          CCL IP    : 10.0.0.3
          CCL MAC   : 000b.fcf8.c192
          Last join : 17:08:59 UTC Sep 26 2011
          Last leave: N/A
    Other members in the cluster:
      Unit "D" in state SLAVE
          ID        : 1
          Site ID   : 1
                Version   : 9.4(1)
          Serial No.: P3000000001
          CCL IP    : 10.0.0.4
          CCL MAC   : 000b.fcf8.c162
          Last join : 19:13:11 UTC Sep 23 2011
          Last leave: N/A
      Unit "A" in state MASTER
          ID        : 2
          Site ID   : 2
                Version   : 9.4(1)
          Serial No.: JAB0815R0JY
          CCL IP    : 10.0.0.1
          CCL MAC   : 000f.f775.541e
          Last join : 19:13:20 UTC Sep 23 2011
          Last leave: N/A
      Unit "B" in state SLAVE
          ID        : 3
          Site ID   : 2
                Version   : 9.4(1)
          Serial No.: P3000000191
          CCL IP    : 10.0.0.2
          CCL MAC   : 000b.fcf8.c61e
          Last join : 19:13:50 UTC Sep 23 2011
          Last leave: 19:13:36 UTC Sep 23 2011
    
    
  • show cluster info auto-join

    Shows whether the cluster node will automatically rejoin the cluster after a time delay and if the failure conditions (such as waiting for the license, chassis health check failure, and so on) are cleared. If the node is permanently disabled, or if the node is already in the cluster, then this command will not show any output.

    See the following outputs for the show cluster info auto-join command:

    
    ciscoasa(cfg-cluster)# show cluster info auto-join
    Unit will try to join cluster in 253 seconds.
    Quit reason: Received control message DISABLE
     
    ciscoasa(cfg-cluster)# show cluster info auto-join       
    Unit will try to join cluster when quit reason is cleared.
    Quit reason: Master has application down that slave has up.
     
    ciscoasa(cfg-cluster)# show cluster info auto-join        
    Unit will try to join cluster when quit reason is cleared.
    Quit reason: Chassis-blade health check failed.
     
    ciscoasa(cfg-cluster)# show cluster info auto-join        
    Unit will try to join cluster when quit reason is cleared.
    Quit reason: Service chain application became down.
     
    ciscoasa(cfg-cluster)# show cluster info auto-join
    Unit will try to join cluster when quit reason is cleared.
    Quit reason: Unit is kicked out from cluster because of Application health check failure.
     
    ciscoasa(cfg-cluster)# show cluster info auto-join
    Unit join is pending (waiting for the smart license entitlement: ent1)
     
    ciscoasa(cfg-cluster)# show cluster info auto-join
    Unit join is pending (waiting for the smart license export control flag)
    
    
  • show cluster info transport {asp | cp [detail]}

    Shows transport related statistics for the following:

    • asp —Data plane transport statistics.

    • cp —Control plane transport statistics.

      If you enter the detail keyword, you can view cluster reliable transport protocol usage so you can identify packet drop issues when the buffer is full in the control plane. See the following output for the show cluster info transport cp detail command:

      
      ciscoasa# show cluster info transport cp detail
      Member ID to name mapping: 
        0 - unit-1-1   2 - unit-4-1   3 - unit-2-1 
      
      Legend:
        U    - unreliable messages
        UE   - unreliable messages error
        SN   - sequence number
        ESN  - expecting sequence number
        R    - reliable messages
        RE   - reliable messages error
        RDC  - reliable message deliveries confirmed
        RA   - reliable ack packets received
        RFR  - reliable fast retransmits
        RTR  - reliable timer-based retransmits
        RDP  - reliable message dropped
        RDPR - reliable message drops reported
        RI   - reliable message with old sequence number
        RO   - reliable message with out of order sequence number
        ROW  - reliable message with out of window sequence number
        ROB  - out of order reliable messages buffered
        RAS  - reliable ack packets sent
      
      This unit as a sender
      --------------------------
              all       0         2         3         
        U     123301    3867966   3230662   3850381   
        UE    0         0         0         0         
        SN    1656a4ce  acb26fe   5f839f76  7b680831  
        R     733840    1042168   852285    867311    
        RE    0         0         0         0         
        RDC   699789    934969    740874    756490    
        RA    385525    281198    204021    205384    
        RFR   27626     56397     0         0         
        RTR   34051     107199    111411    110821    
        RDP   0         0         0         0         
        RDPR  0         0         0         0         
      
      This unit as a receiver of broadcast messages
      ---------------------------------------------
              0         2         3         
        U     111847    121862    120029    
        R     7503      665700    749288    
        ESN   5d75b4b3  6d81d23   365ddd50  
        RI    630       34278     40291     
        RO    0         582       850       
        ROW   0         566       850       
        ROB   0         16        0         
        RAS   1571      123289    142256    
      
      This unit as a receiver of unicast messages
      ---------------------------------------------
              0         2         3         
        U     1         3308122   4370233   
        R     513846    879979    1009492   
        ESN   4458903a  6d841a84  7b4e7fa7  
        RI    66024     108924    102114    
        RO    0         0         0         
        ROW   0         0         0         
        ROB   0         0         0         
        RAS   130258    218924    228303    
      
      Gated Tx Buffered Message Statistics
      -------------------------------------
          current sequence number: 0
      
          total:                   0
          current:                 0
          high watermark:          0
      
          delivered:               0
          deliver failures:        0
      
          buffer full drops:       0
          message truncate drops:  0
      
          gate close ref count:    0
      
          num of supported clients:45
      
      MRT Tx of broadcast messages
      =============================
      Message high watermark: 3%
        Total messages buffered at high watermark: 5677
        [Per-client message usage at high watermark]
        ---------------------------------------------------------------
        Client name                          Total messages  Percentage  
        Cluster Redirect Client                        4153         73% 
        Route Cluster Client                            419          7% 
        RRI Cluster Client                             1105         19% 
      
      Current MRT buffer usage: 0%
        Total messages buffered in real-time: 1
        [Per-client message usage in real-time]
        Legend:
              F - MRT messages sending when buffer is full
              L - MRT messages sending when cluster node leave
              R - MRT messages sending in Rx thread
        ----------------------------------------------------------------------------
        Client name                          Total messages  Percentage    F   L   R
        VPN Clustering HA Client                          1        100%    0   0   0
      
      MRT Tx of unitcast messages(to member_id:0)
      ============================================
      Message high watermark: 31%
        Total messages buffered at high watermark: 4059
        [Per-client message usage at high watermark]
        ---------------------------------------------------------------
        Client name                          Total messages  Percentage  
        Cluster Redirect Client                        3731         91% 
        RRI Cluster Client                              328          8% 
      
      Current MRT buffer usage: 29%
        Total messages buffered in real-time: 3924
        [Per-client message usage in real-time]
        Legend:
              F - MRT messages sending when buffer is full
              L - MRT messages sending when cluster node leave
              R - MRT messages sending in Rx thread
        ----------------------------------------------------------------------------
        Client name                          Total messages  Percentage    F   L   R
        Cluster Redirect Client                        3607         91%    0   0   0
        RRI Cluster Client                              317          8%    0   0   0
      
      MRT Tx of unitcast messages(to member_id:2)
      ============================================
      Message high watermark: 14%
        Total messages buffered at high watermark: 578
        [Per-client message usage at high watermark]
        ---------------------------------------------------------------
        Client name                          Total messages  Percentage  
        VPN Clustering HA Client                        578        100% 
      
      Current MRT buffer usage: 0%
        Total messages buffered in real-time: 0
      
      MRT Tx of unitcast messages(to member_id:3)
      ============================================
      Message high watermark: 12%
        Total messages buffered at high watermark: 573
        [Per-client message usage at high watermark]
        ---------------------------------------------------------------
        Client name                          Total messages  Percentage  
        VPN Clustering HA Client                        572         99% 
        Cluster VPN Unique ID Client                      1          0% 
                    
      Current MRT buffer usage: 0%
        Total messages buffered in real-time: 0
      
      
  • show cluster history

    Shows the cluster history, as well as error messages about why a cluster node failed to join or why a node left the cluster.

Capturing Packets Cluster-Wide

See the following command for capturing packets in a cluster:

cluster exec capture

To support cluster-wide troubleshooting, you can enable capture of cluster-specific traffic on the control node using the cluster exec capture command, which is then automatically enabled on all of the data nodes in the cluster.

Monitoring Cluster Resources

See the following command for monitoring cluster resources:

show cluster {cpu | memory | resource} [options]

Displays aggregated data for the entire cluster. The options available depends on the data type.

Monitoring Cluster Traffic

See the following commands for monitoring cluster traffic:

  • show conn [detail], cluster exec show conn

    The show conn command shows whether a flow is a director, backup, or forwarder flow. Use the cluster exec show conn command on any node to view all connections. This command can show how traffic for a single flow arrives at different ASAs in the cluster. The throughput of the cluster is dependent on the efficiency and configuration of load balancing. This command provides an easy way to view how traffic for a connection is flowing through the cluster, and can help you understand how a load balancer might affect the performance of a flow.

    The show conn detail command also shows which flows are subject to flow mobility.

    The following is sample output for the show conn detail command:

    
    ciscoasa/ASA2/slave# show conn detail
    12 in use, 13 most used
    Cluster stub connections: 0 in use, 46 most used
    Flags: A - awaiting inside ACK to SYN, a - awaiting outside ACK to SYN,
           B - initial SYN from outside, b - TCP state-bypass or nailed,
           C - CTIQBE media, c - cluster centralized,
           D - DNS, d - dump, E - outside back connection, e - semi-distributed,
           F - outside FIN, f - inside FIN,
           G - group, g - MGCP, H - H.323, h - H.225.0, I - inbound data,
           i - incomplete, J - GTP, j - GTP data, K - GTP t3-response
           k - Skinny media, L - LISP triggered flow owner mobility,
           M - SMTP data, m - SIP media, n - GUP
           O - outbound data, o - offloaded,
           P - inside back connection,
           Q - Diameter, q - SQL*Net data,
           R - outside acknowledged FIN,
           R - UDP SUNRPC, r - inside acknowledged FIN, S - awaiting inside SYN,
           s - awaiting outside SYN, T - SIP, t - SIP transient, U - up,
           V - VPN orphan, W - WAAS,
           w - secondary domain backup,
           X - inspected by service module,
           x - per session, Y - director stub flow, y - backup stub flow,
           Z - Scansafe redirection, z - forwarding stub flow
    ESP outside: 10.1.227.1/53744 NP Identity Ifc: 10.1.226.1/30604, , flags c, idle 0s, uptime
    1m21s, timeout 30s, bytes 7544, cluster sent/rcvd bytes 0/0, owners (0,255) Traffic received
    at interface outside Locally received: 7544 (93 byte/s) Traffic received at interface NP
    Identity Ifc Locally received: 0 (0 byte/s) UDP outside: 10.1.227.1/500 NP Identity Ifc:
    10.1.226.1/500, flags -c, idle 1m22s, uptime 1m22s, timeout 2m0s, bytes 1580, cluster
    sent/rcvd bytes 0/0, cluster sent/rcvd total bytes 0/0, owners (0,255) Traffic received at
    interface outside Locally received: 864 (10 byte/s) Traffic received at interface NP Identity
    Ifc Locally received: 716 (8 byte/s)
    
    

    To troubleshoot the connection flow, first see connections on all nodes by entering the cluster exec show conn command on any node. Look for flows that have the following flags: director (Y), backup (y), and forwarder (z). The following example shows an SSH connection from 172.18.124.187:22 to 192.168.103.131:44727 on all three ASAs; ASA 1 has the z flag showing it is a forwarder for the connection, ASA3 has the Y flag showing it is the director for the connection, and ASA2 has no special flags showing it is the owner. In the outbound direction, the packets for this connection enter the inside interface on ASA2 and exit the outside interface. In the inbound direction, the packets for this connection enter the outside interface on ASA 1 and ASA3, are forwarded over the cluster control link to ASA2, and then exit the inside interface on ASA2.

    
    ciscoasa/ASA1/master# cluster exec show conn
    ASA1(LOCAL):**********************************************************
    18 in use, 22 most used
    Cluster stub connections: 0 in use, 5 most used
    TCP outside  172.18.124.187:22 inside  192.168.103.131:44727, idle 0:00:00, bytes 37240828, flags z
    
    
    ASA2:*****************************************************************
    12 in use, 13 most used
    Cluster stub connections: 0 in use, 46 most used
    TCP outside  172.18.124.187:22 inside  192.168.103.131:44727, idle 0:00:00, bytes 37240828, flags UIO
    
    
    ASA3:*****************************************************************
    10 in use, 12 most used
    Cluster stub connections: 2 in use, 29 most used
    TCP outside  172.18.124.187:22 inside  192.168.103.131:44727, idle 0:00:03, bytes 0, flags  Y
    
  • show cluster info [conn-distribution | packet-distribution | loadbalance | flow-mobility counters]

    The show cluster info conn-distribution and show cluster info packet-distribution commands show traffic distribution across all cluster nodes. These commands can help you to evaluate and adjust the external load balancer.

    The show cluster info loadbalance command shows connection rebalance statistics.

    The show cluster info flow-mobility counters command shows EID movement and flow owner movement information. See the following output for show cluster info flow-mobility counters:

    
    ciscoasa# show cluster info flow-mobility counters
    EID movement notification received  : 4
    EID movement notification processed : 4
    Flow owner moving requested         : 2
    
    
  • show cluster info load-monitor [details]

    The show cluster info load-monitor command shows the traffic load for cluster members for the last interval and also the average over total number of intervals configured (30 by default). Use the details keyword to view the value for each measure at each interval.

    
    ciscoasa(cfg-cluster)# show cluster info load-monitor
    ID  Unit Name
    0  B
    1  A_1
    Information from all units with 20 second interval:
    Unit     Connections    Buffer Drops   Memory Used   CPU Used
    Average from last 1 interval:
       0           0            0            14              25
       1           0            0            16              20
    Average from last 30 interval:
       0           0            0            12              28
       1           0            0            13              27
    
    
    ciscoasa(cfg-cluster)# show cluster info load-monitor details              
                                                                                               
    ID  Unit Name                                                                              
     0  B                                                                                      
     1  A_1                                                                                    
    Information from all units with 20 second interval                                         
                                                                                               
    Connection count captured over 30 intervals:                                               
    Unit ID  0                                                                                 
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
    Unit ID  1                                                                                 
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
                                                                                               
    Buffer drops captured over 30 intervals:                                                   
    Unit ID  0                                                                                 
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
    Unit ID  1                                                                                 
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
             0          0          0          0          0          0                          
                                                                                               
    Memory usage(%) captured over 30 intervals:                                                   
    Unit ID  0                                                                                 
            25         25         30         30         30         35                          
            25         25         35         30         30         30                          
            25         25         30         25         25         35                          
            30         30         30         25         25         25                          
            25         20         30         30         30         30                          
    Unit ID  1                                                                                 
            30         25         35         25         30         30                          
            25         25         35         25         30         35                          
            30         30         35         30         30         30                          
            25         20         30         25         25         30                          
            20         30         35         30         30         35                            
                                                                                               
    CPU usage(%) captured over 30 intervals:                                                      
    Unit ID  0                                                                                 
            25         25         30         30         30         35                          
            25         25         35         30         30         30                          
            25         25         30         25         25         35                          
            30         30         30         25         25         25                          
            25         20         30         30         30         30                          
    Unit ID  1                                                                                 
            30         25         35         25         30         30                          
            25         25         35         25         30         35                          
            30         30         35         30         30         30                          
            25         20         30         25         25         30                          
            20         30         35         30         30         35       
    
    
  • show cluster {access-list | conn | traffic | user-identity | xlate} [options]

    Displays aggregated data for the entire cluster. The options available depends on the data type.

    See the following output for the show cluster access-list command:

    
    ciscoasa# show cluster access-list
    hitcnt display order: cluster-wide aggregated result, unit-A, unit-B,  unit-C, unit-D
    access-list cached ACL log flows: total 0, denied 0 (deny-flow-max 4096) alert-interval 300
    access-list 101; 122 elements; name hash: 0xe7d586b5
    access-list 101 line 1 extended permit tcp 192.168.143.0 255.255.255.0 any eq www (hitcnt=0, 0, 0, 0, 0) 0x207a2b7d
    access-list 101 line 2 extended permit tcp any 192.168.143.0 255.255.255.0 (hitcnt=0, 0, 0, 0, 0) 0xfe4f4947
    access-list  101 line 3 extended permit tcp host 192.168.1.183 host 192.168.43.238 (hitcnt=1, 0, 0, 0, 1) 0x7b521307
    access-list 101 line 4 extended permit tcp host 192.168.1.116 host 192.168.43.238 (hitcnt=0, 0, 0, 0, 0) 0x5795c069
    access-list 101 line 5 extended permit tcp host 192.168.1.177 host 192.168.43.238 (hitcnt=1, 0, 0, 1, 0) 0x51bde7ee
    access list 101 line 6 extended permit tcp host 192.168.1.177 host 192.168.43.13 (hitcnt=0, 0, 0, 0, 0) 0x1e68697c
    access-list 101 line 7 extended permit tcp host 192.168.1.177 host 192.168.43.132 (hitcnt=2, 0, 0, 1, 1) 0xc1ce5c49
    access-list 101 line 8 extended permit tcp host 192.168.1.177 host 192.168.43.192 (hitcnt=3, 0, 1, 1, 1) 0xb6f59512
    access-list 101 line 9 extended permit tcp host 192.168.1.177 host 192.168.43.44 (hitcnt=0, 0, 0, 0, 0) 0xdc104200
    access-list 101 line 10 extended permit tcp host 192.168.1.112 host 192.168.43.44 (hitcnt=429, 109, 107, 109, 104)
    0xce4f281d
    access-list 101 line 11 extended permit tcp host 192.168.1.170 host 192.168.43.238 (hitcnt=3, 1, 0, 0, 2) 0x4143a818
    access-list 101 line 12 extended permit tcp host 192.168.1.170 host 192.168.43.169 (hitcnt=2, 0, 1, 0, 1) 0xb18dfea4
    access-list 101 line 13 extended permit tcp host 192.168.1.170 host 192.168.43.229 (hitcnt=1, 1, 0, 0, 0) 0x21557d71
    access-list 101 line 14 extended permit tcp host 192.168.1.170 host 192.168.43.106 (hitcnt=0, 0, 0, 0, 0) 0x7316e016
    access-list 101 line 15 extended permit tcp host 192.168.1.170 host 192.168.43.196 (hitcnt=0, 0, 0, 0, 0) 0x013fd5b8
    access-list 101 line 16 extended permit tcp host 192.168.1.170 host 192.168.43.75 (hitcnt=0, 0, 0, 0, 0) 0x2c7dba0d
    
    

    To display the aggregated count of in-use connections for all nodes, enter:

    
    ciscoasa# show cluster conn count
    Usage Summary In Cluster:*********************************************
      200 in use (cluster-wide aggregated)
         cl2(LOCAL):***********************************************************
      100 in use, 100 most used
    
      cl1:******************************************************************
      100 in use, 100 most used
    
    
  • show asp cluster counter

    This command is useful for datapath troubleshooting.

Monitoring Cluster Routing

See the following commands for cluster routing:

  • show route cluster

  • debug route cluster

    Shows cluster information for routing.

  • show lisp eid

    Shows the ASA EID table showing EIDs and site IDs.

    See the following output from the cluster exec show lisp eid command.

    
    ciscoasa# cluster exec show lisp eid
    L1(LOCAL):************************************************************
         LISP EID       Site ID
        33.44.33.105        2
        33.44.33.201        2
        11.22.11.1             4
        11.22.11.2             4
    L2:*******************************************************************
         LISP EID       Site ID
        33.44.33.105        2
        33.44.33.201        2
        11.22.11.1 	 4
        11.22.11.2	 4
    
    
  • show asp table classify domain inspect-lisp

    This command is useful for troubleshooting.

Configuring Logging for Clustering

See the following command for configuring logging for clustering:

logging device-id

Each node in the cluster generates syslog messages independently. You can use the logging device-id command to generate syslog messages with identical or different device IDs to make messages appear to come from the same or different nodes in the cluster.

Monitoring Cluster Interfaces

See the following commands for monitoring cluster interfaces:

  • show cluster interface-mode

    Shows the cluster interface mode.

  • show port-channel

    Includes information about whether a port-channel is spanned.

  • show lacp cluster {system-mac | system-id}

    Shows the cLACP system ID and priority.

  • debug lacp cluster [all | ccp | misc | protocol]

    Shows debug messages for cLACP.

  • show interface

    Shows the use of the site MAC address when in use:

    
    ciscoasa# show interface port-channel1.3151
    Interface Port-channel1.3151 "inside", is up, line protocol is up
    Hardware is EtherChannel/LACP, BW 1000 Mbps, DLY 10 usec
    VLAN identifier 3151
    MAC address aaaa.1111.1234, MTU 1500
    Site Specific MAC address aaaa.1111.aaaa
    IP address 10.3.1.1, subnet mask 255.255.255.0
    Traffic Statistics for "inside":
    132269 packets input, 6483425 bytes
    1062 packets output, 110448 bytes
    98530 packets dropped
    
    

Debugging Clustering

See the following commands for debugging clustering:

  • debug cluster [ccp | datapath | fsm | general | hc | license | rpc | transport]

    Shows debug messages for clustering.

  • debug cluster flow-mobility

    Shows events related to clustering flow mobility.

  • debug lisp eid-notify-intercept

    Shows events when the eid-notify message is intercepted.

  • show cluster info trace

    The show cluster info trace command shows the debug information for further troubleshooting.

    See the following output for the show cluster info trace command:

    
    ciscoasa# show cluster info trace
     Feb 02 14:19:47.456 [DBUG]Receive CCP message: CCP_MSG_LOAD_BALANCE
     Feb 02 14:19:47.456 [DBUG]Receive CCP message: CCP_MSG_LOAD_BALANCE
     Feb 02 14:19:47.456 [DBUG]Send CCP message to all: CCP_MSG_KEEPALIVE from 80-1 at MASTER
    
    

    For example, if you see the following messages showing that two nodes with the same local-unit name are acting as the control node, it could mean that either two nodes have the same local-unit name (check your configuration), or a node is receiving its own broadcast messages (check your network).

    
    ciscoasa# show cluster info trace
     May 23 07:27:23.113 [CRIT]Received datapath event 'multi masters' with parameter 1.
     May 23 07:27:23.113 [CRIT]Found both unit-9-1 and unit-9-1 as master units. Master role retained by unit-9-1, unit-9-1 will leave then join as a Slave
     May 23 07:27:23.113 [DBUG]Send event (DISABLE, RESTART | INTERNAL-EVENT, 5000 msecs, Detected another Master, leave and re-join as Slave) to FSM. Current state MASTER
     May 23 07:27:23.113 [INFO]State machine changed from state MASTER to DISABLED
    
    

Examples for ASA Clustering

These examples include all cluster-related ASA configuration for typical deployments.

Sample ASA and Switch Configuration

The following sample configurations connect the following interfaces between the ASA and the switch:

ASA Interface

Switch Interface

Ethernet 1/2

GigabitEthernet 1/0/15

Ethernet 1/3

GigabitEthernet 1/0/16

Ethernet 1/4

GigabitEthernet 1/0/17

Ethernet 1/5

GigabitEthernet 1/0/18

ASA Configuration

Interface Mode on Each Unit

cluster interface-mode spanned force

ASA1 Control Unit Bootstrap Configuration

interface Ethernet1/6
 channel-group 1 mode on
 no shutdown
!
interface Ethernet1/7
 channel-group 1 mode on
 no shutdown
!
interface Port-channel1
 description Clustering Interface
!
cluster group Moya
 local-unit A
 cluster-interface Port-channel1 ip 10.0.0.1 255.255.255.0
 priority 10
 key emphyri0
 enable noconfirm

ASA2 Data Unit Bootstrap Configuration

interface Ethernet1/6
 channel-group 1 mode on
 no shutdown
!
interface Ethernet1/7
 channel-group 1 mode on
 no shutdown
!
interface Port-channel1
 description Clustering Interface
!
cluster group Moya
 local-unit B
 cluster-interface Port-channel1 ip 10.0.0.2 255.255.255.0
 priority 11
 key emphyri0
 enable as-slave

Control Unit Interface Configuration

ip local pool mgmt-pool 10.53.195.231-10.53.195.232

interface Ethernet1/2
 channel-group 10 mode active
 no shutdown
!
interface Ethernet1/3
 channel-group 10 mode active
 no shutdown
!
interface Ethernet1/4
 channel-group 11 mode active
 no shutdown
!
interface Ethernet1/5
 channel-group 11 mode active
 no shutdown
!
interface Management1/1
 management-only
 nameif management
 ip address 10.53.195.230 cluster-pool mgmt-pool
 security-level 100
 no shutdown
!
interface Port-channel10
 mac-address aaaa.bbbb.cccc
 nameif inside
 security-level 100
 ip address 209.165.200.225 255.255.255.224
!
interface Port-channel11
 mac-address aaaa.dddd.cccc
 nameif outside
 security-level 0
 ip address 209.165.201.1 255.255.255.224

Cisco IOS Switch Configuration


interface GigabitEthernet1/0/15
 switchport access vlan 201
 switchport mode access
 spanning-tree portfast
 channel-group 10 mode active
!
interface GigabitEthernet1/0/16
 switchport access vlan 201
 switchport mode access
 spanning-tree portfast
 channel-group 10 mode active
!
interface GigabitEthernet1/0/17
 switchport access vlan 401
 switchport mode access
 spanning-tree portfast
 channel-group 11 mode active
!
interface GigabitEthernet1/0/18
 switchport access vlan 401
 switchport mode access
 spanning-tree portfast
 channel-group 11 mode active

interface Port-channel10
 switchport access vlan 201
 switchport mode access

interface Port-channel11
 switchport access vlan 401
 switchport mode access

Firewall on a Stick

Data traffic from different security domains are associated with different VLANs, for example, VLAN 10 for the inside network and VLAN 20 for the outside network. Each ASA has a single physical port connected to the external switch or router. Trunking is enabled so that all packets on the physical link are 802.1q encapsulated. The ASA is the firewall between VLAN 10 and VLAN 20.

When using Spanned EtherChannels, all data links are grouped into one EtherChannel on the switch side. If the ASA becomes unavailable, the switch will rebalance traffic between the remaining units.

Interface Mode on Each Unit


cluster interface-mode spanned force

Unit 1 Control Unit Bootstrap Configuration


interface ethernet1/8
no shutdown
description CCL

cluster group cluster1
local-unit asa1
cluster-interface ethernet1/8 ip 192.168.1.1 255.255.255.0
priority 1
key chuntheunavoidable
enable noconfirm

Unit 2 Data Unit Bootstrap Configuration


interface ethernet1/8
no shutdown
description CCL

cluster group cluster1
local-unit asa2
cluster-interface ethernet1/8 ip 192.168.1.2 255.255.255.0
priority 2
key chuntheunavoidable
enable as-slave

Unit 3 Data Unit Bootstrap Configuration


interface ethernet1/8
no shutdown
description CCL

cluster group cluster1
local-unit asa3
cluster-interface ethernet1/8 ip 192.168.1.3 255.255.255.0
priority 3
key chuntheunavoidable
enable as-slave

Control Unit Interface Configuration


ip local pool mgmt 10.1.1.2-10.1.1.9
ipv6 local pool mgmtipv6 2001:DB8::1002/64 8

interface management 1/1
nameif management
ip address 10.1.1.1 255.255.255.0 cluster-pool mgmt
ipv6 address 2001:DB8::1001/32 cluster-pool mgmtipv6
security-level 100
management-only
no shutdown

interface ethernet1/1
channel-group 1 mode active
no shutdown

interface port-channel 1

interface port-channel 1.10
vlan 10
nameif inside
ip address 10.10.10.5 255.255.255.0
ipv6 address 2001:DB8:1::5/64
mac-address 000C.F142.4CDE

interface port-channel 1.20
vlan 20
nameif outside
ip address 209.165.201.1 255.255.255.224
ipv6 address 2001:DB8:2::8/64
mac-address 000C.F142.5CDE

Traffic Segregation

You may prefer physical separation of traffic between the inside and outside network.

As shown in the diagram above, there is one Spanned EtherChannel on the left side that connects to the inside switch, and the other on the right side to outside switch. You can also create VLAN subinterfaces on each EtherChannel if desired.

Interface Mode on Each Unit


cluster interface-mode spanned force

Unit 1 Control Unit Bootstrap Configuration


interface ethernet 1/6
 channel-group 1 mode on
 no shutdown

interface ethernet 1/7
 channel-group 1 mode on
 no shutdown

interface port-channel 1
 description CCL

cluster group cluster1
 local-unit asa1
 cluster-interface port-channel1 ip 192.168.1.1 255.255.255.0
 priority 1
 key chuntheunavoidable
 enable noconfirm

Unit 2 Data Unit Bootstrap Configuration


interface ethernet 1/6
 channel-group 1 mode on
 no shutdown

interface ethernet 1/7
 channel-group 1 mode on
 no shutdown

interface port-channel 1
 description CCL

cluster group cluster1
 local-unit asa2
 cluster-interface port-channel1 ip 192.168.1.2 255.255.255.0
 priority 2
 key chuntheunavoidable
 enable as-slave

Unit 3 Data Unit Bootstrap Configuration


interface ethernet 1/6
 channel-group 1 mode on
 no shutdown

interface ethernet 1/7
 channel-group 1 mode on
 no shutdown

interface port-channel 1
 description CCL

cluster group cluster1
 local-unit asa3
 cluster-interface port-channel1 ip 192.168.1.3 255.255.255.0
 priority 3
 key chuntheunavoidable
 enable as-slave

Control Unit Interface Configuration


ip local pool mgmt 10.1.1.2-10.1.1.9
ipv6 local pool mgmtipv6 2001:DB8::1002/64 8

interface management 1/1
 nameif management
 ip address 10.1.1.1 255.255.255.0 cluster-pool mgmt
 ipv6 address 2001:DB8::1001/32 cluster-pool mgmtipv6
 security-level 100
 management-only
 no shutdown

interface ethernet 1/8
 channel-group 2 mode active
 no shutdown

interface port-channel 2
 nameif inside
 ip address 10.10.10.5 255.255.255.0
 ipv6 address 2001:DB8:1::5/64
 mac-address 000C.F142.4CDE

interface ethernet 2/1
 channel-group 3 mode active
 no shutdown

interface port-channel 3 
 nameif outside
 ip address 209.165.201.1 255.255.255.224
 ipv6 address 2001:DB8:2::8/64
 mac-address 000C.F142.5CDE

OTV Configuration for Routed Mode Inter-Site Clustering

The success of inter-site clustering for routed mode with Spanned EtherChannels depends on the proper configuration and monitoring of OTV. OTV plays a major role by forwarding the packets across the DCI. OTV forwards unicast packets across the DCI only when it learns the MAC address in its forwarding table. If the MAC address is not learned in the OTV forwarding table, it will drop the unicast packets.

Sample OTV Configuration


//Sample OTV config:
//3151 – Inside VLAN, 3152 – Outside VLAN, 202 – CCL VLAN
//aaaa.1111.1234 – ASA inside interface global vMAC
//0050.56A8.3D22 – Server MAC

feature ospf
feature otv

mac access-list ALL_MACs
  10 permit any any
mac access-list HSRP_VMAC
  10 permit aaaa.1111.1234 0000.0000.0000 any
  20 permit aaaa.2222.1234 0000.0000.0000 any
  30 permit any aaaa.1111.1234 0000.0000.0000
  40 permit any aaaa.2222.1234 0000.0000.0000
vlan access-map Local 10
  match mac address HSRP_VMAC
  action drop
vlan access-map Local 20
  match mac address ALL_MACs
  action forward
vlan filter Local vlan-list 3151-3152


//To block global MAC with ARP inspection:
arp access-list HSRP_VMAC_ARP    
  10 deny aaaa.1111.1234 0000.0000.0000 any
  20 deny aaaa.2222.1234 0000.0000.0000 any
  30 deny any aaaa.1111.1234 0000.0000.0000
  40 deny any aaaa.2222.1234 0000.0000.0000
  50 permit ip any mac
ip arp inspection filter HSRP_VMAC_ARP 3151-3152

no ip igmp snooping optimise-multicast-flood
vlan 1,202,1111,2222,3151-3152

otv site-vlan 2222
mac-list GMAC_DENY seq 10 deny aaaa.aaaa.aaaa ffff.ffff.ffff
mac-list GMAC_DENY seq 20 deny aaaa.bbbb.bbbb ffff.ffff.ffff
mac-list GMAC_DENY seq 30 permit 0000.0000.0000 0000.0000.0000
route-map stop-GMAC permit 10
  match mac-list GMAC_DENY

interface Overlay1
  otv join-interface Ethernet8/1
  otv control-group 239.1.1.1
  otv data-group 232.1.1.0/28
  otv extend-vlan 202, 3151
  otv arp-nd timeout 60
  no shutdown

interface Ethernet8/1
  description uplink_to_OTV_cloud
  mtu 9198
  ip address 10.4.0.18/24
  ip igmp version 3
  no shutdown

interface Ethernet8/2

interface Ethernet8/3
  description back_to_default_vdc_e6/39
  switchport
    switchport mode trunk
    switchport trunk allowed vlan 202,2222,3151-3152
  mac packet-classify
  no shutdown

otv-isis default
  vpn Overlay1
    redistribute filter route-map stop-GMAC
otv site-identifier 0x2
//OTV flood not required for ARP inspection:
otv flood mac 0050.56A8.3D22 vlan 3151

OTV Filter Modifications Required Because of Site Failure

If a site goes down, the filters need to be removed from OTV because you do not want to block the global MAC address anymore. There are some additional configurations required.

You need to add a static entry for the ASA global MAC address on the OTV switch in the site that is functional. This entry will let the OTV at the other end add these entries on the overlay interface. This step is required because if the server and client already have the ARP entry for the ASA, which is the case for existing connections, then they will not send the ARP again. Therefore, OTV will not get a chance to learn the ASA global MAC address in its forwarding table. Because OTV does not have the global MAC address in its forwarding table, and per OTV design it will not flood unicast packets over the overlay interface, then it will drop the unicast packets to the global MAC address from the server, and the existing connections will break.


//OTV filter configs when one of the sites is down

mac-list GMAC_A seq 10 permit 0000.0000.0000 0000.0000.0000
route-map a-GMAC permit 10
  match mac-list GMAC_A

otv-isis default
  vpn Overlay1
    redistribute filter route-map a-GMAC

no vlan filter Local vlan-list 3151

//For ARP inspection, allow global MAC:
arp access-list HSRP_VMAC_ARP_Allow    
  50 permit ip any mac
ip arp inspection filter HSRP_VMAC_ARP_Allow 3151-3152

mac address-table static aaaa.1111.1234 vlan 3151 interface Ethernet8/3
//Static entry required only in the OTV in the functioning Site


When the other site is restored, you need to add the filters back again and remove this static entry on the OTV. It is very important to clear the dynamic MAC address table on both the OTVs to clear the overlay entry for the global MAC address.

MAC Address Table Clearing

When a site goes down, and a static entry for the global MAC address is added to OTV, you need to let the other OTV learn the global MAC address on the overlay interface. After the other site comes up, these entries should be cleared. Make sure to clear the mac address table to make sure OTV does not have these entries in its forwarding table.


cluster-N7k6-OTV# show mac address-table
Legend:
* - primary entry, G - Gateway MAC, (R) - Routed MAC, O - Overlay MAC
age - seconds since last seen,+ - primary entry using vPC Peer-Link,
(T) - True, (F) - False
VLAN MAC Address Type age Secure NTFY Ports/SWID.SSID.LID
---------+-----------------+--------+---------+------+----+------------------
G -    d867.d900.2e42 static  -  F F sup-eth1(R)
O 202  885a.92f6.44a5 dynamic -  F F Overlay1
* 202  885a.92f6.4b8f dynamic 5  F F Eth8/3
O 3151 0050.5660.9412 dynamic -  F F Overlay1
* 3151 aaaa.1111.1234 dynamic 50 F F Eth8/3

OTV ARP Cache Monitoring

OTV maintains an ARP cache to proxy ARP for IP addresses that it learned across the OTV interface.


cluster-N7k6-OTV# show otv arp-nd-cache
OTV ARP/ND L3->L2 Address Mapping Cache

Overlay Interface Overlay1
VLAN MAC Address Layer-3 Address Age Expires In
3151 0050.5660.9412 10.0.0.2 1w0d 00:00:31
cluster-N7k6-OTV# 

Examples for Inter-Site Clustering

The following examples show supported cluster deployments.

Spanned EtherChannel Routed Mode Example with Site-Specific MAC and IP Addresses

The following example shows 2 cluster members at each of 2 data centers placed between the gateway router and an inside network at each site (East-West insertion). The cluster members are connected by the cluster control link over the DCI. The cluster members at each site connect to the local switches using spanned EtherChannels for both the inside and outside networks. Each EtherChannel is spanned across all chassis in the cluster.

The data VLANs are extended between the sites using Overlay Transport Virtualization (OTV) (or something similar). You must add filters blocking the global MAC address to prevent traffic from traversing the DCI to the other site when the traffic is destined for the cluster. If the cluster nodes at one site become unreachable, you must remove the filters so traffic can be sent to the other site’s cluster nodes. You should use VACLs to filter the global MAC address.For some switches, such as Nexus with the F3-series line card, you must also use ARP inspection to block ARP packets from the global MAC address. ARP inspection requires you to set both the site MAC address and the site IP address on the ASA. If you only configure the site MAC address be sure to disable ARP inspection.

The cluster acts as the gateway for the inside networks. The global virtual MAC, which is shared across all cluster nodes, is used only to receive packets. Outgoing packets use a site-specific MAC address from each DC cluster. This feature prevents the switches from learning the same global MAC address from both sites on two different ports, which causes MAC flapping; instead, they only learn the site MAC address.

In this scenario:

  • All egress packets sent from the cluster use the site MAC address and are localized at the data center.

  • All ingress packets to the cluster are sent using the global MAC address, so they can be received by any of the nodes at both sites; filters at the OTV localize the traffic within the data center.



Spanned EtherChannel Transparent Mode North-South Inter-Site Example

The following example shows 2 cluster members at each of 2 data centers placed between inside and outside routers (North-South insertion). The cluster members are connected by the cluster control link over the DCI. The cluster members at each site connect to the local switches using spanned EtherChannels for the inside and outside. Each EtherChannel is spanned across all chassis in the cluster.

The inside and outside routers at each data center use OSPF, which is passed through the transparent ASAs. Unlike MACs, router IPs are unique on all routers. By assigning a higher cost route across the DCI, traffic stays within each data center unless all cluster members at a given site go down. The lower cost route through the ASAs must traverse the same bridge group at each site for the cluster to maintain asymmetric connections. In the event of a failure of all cluster members at one site, traffic goes from each router over the DCI to the cluster members at the other site.

The implementation of the switches at each site can include:

  • Inter-site VSS, vPC, StackWise, or StackWise Virtual—In this scenario, you install one switch at Data Center 1, and the other at Data Center 2. One option is for the cluster nodes at each Data Center to only connect to the local switch, while the redundant switch traffic goes across the DCI. In this case, connections are for the most part kept local to each datacenter. You can optionally connect each node to both switches across the DCI if the DCI can handle the extra traffic. In this case, traffic is distributed across the data centers, so it is essential for the DCI to be very robust.

  • Local VSS, vPC, StackWise, or StackWise Virtual at each site—For better switch redundancy, you can install 2 separate redundant switch pairs at each site. In this case, although the cluster nodes still have a spanned EtherChannel with Data Center 1 chassis connected only to both local switches, and Data Center 2 chassis connected to those local switches, the spanned EtherChannel is essentially “split.” Each local redundant switch system sees the spanned EtherChannel as a site-local EtherChannel.

Spanned EtherChannel Transparent Mode East-West Inter-Site Example

The following example shows 2 cluster members at each of 2 data centers placed between the gateway router and two inside networks at each site, the App network and the DB network (East-West insertion). The cluster members are connected by the cluster control link over the DCI. The cluster members at each site connect to the local switches using spanned EtherChannels for both the App and DB networks on the inside and outside. Each EtherChannel is spanned across all chassis in the cluster.

The gateway router at each site uses an FHRP such as HSRP to provide the same destination virtual MAC and IP addresses at each site. A good practice to avoid unintended MAC address flapping is to statically add the gateway routers real MAC addresses to the ASA MAC address table using the mac-address-table static outside_interface mac_address command. Without these entries, if the gateway at site 1 communicates with the gateway at site 2, that traffic might pass through the ASA and attempt to reach site 2 from the inside interface and cause problems. The data VLANs are extended between the sites using Overlay Transport Virtualization (OTV) (or something similar). You must add filters to prevent traffic from traversing the DCI to the other site when the traffic is destined for the gateway router. If the gateway router at one site becomes unreachable, you must remove the filters so traffic can be sent to the other site’s gateway router.



Reference for Clustering

This section includes more information about how clustering operates.

ASA Features and Clustering

Some ASA features are not supported with ASA clustering, and some are only supported on the control node. Other features might have caveats for proper usage.

Unsupported Features with Clustering

These features cannot be configured with clustering enabled, and the commands will be rejected.

  • Unified Communication features that rely on TLS Proxy

  • Remote access VPN (SSL VPN and IPsec VPN)

  • Virtual Tunnel Interfaces (VTIs)

  • The following application inspections:

    • CTIQBE

    • H323, H225, and RAS

    • IPsec passthrough

    • MGCP

    • MMP

    • RTSP

    • SCCP (Skinny)

    • WAAS

    • WCCP

  • Botnet Traffic Filter

  • Auto Update Server

  • DHCP client, server, and proxy. DHCP relay is supported.

  • VPN load balancing

  • Failover

  • Integrated Routing and Bridging

  • FIPS mode

Centralized Features for Clustering

The following features are only supported on the control node, and are not scaled for the cluster.


Note


Traffic for centralized features is forwarded from member nodes to the control node over the cluster control link.

If you use the rebalancing feature, traffic for centralized features may be rebalanced to non-control nodes before the traffic is classified as a centralized feature; if this occurs, the traffic is then sent back to the control node.

For centralized features, if the control node fails, all connections are dropped, and you have to re-establish the connections on the new control node.


  • The following application inspections:

    • DCERPC

    • ESMTP

    • IM

    • NetBIOS

    • PPTP

    • RADIUS

    • RSH

    • SNMP

    • SQLNET

    • SUNRPC

    • TFTP

    • XDMCP

  • Static route monitoring

  • Authentication and Authorization for network access. Accounting is decentralized.

  • Filtering Services

  • Site-to-site VPN

  • IGMP multicast control plane protocol processing (data plane forwarding is distributed across the cluster)

  • PIM multicast control plane protocol processing (data plane forwarding is distributed across the cluster)

  • Dynamic routing

Features Applied to Individual Nodes

These features are applied to each ASA node, instead of the cluster as a whole or to the control node.

  • QoS—The QoS policy is synced across the cluster as part of configuration replication. However, the policy is enforced on each node independently. For example, if you configure policing on output, then the conform rate and conform burst values are enforced on traffic exiting a particular ASA. In a cluster with 3 nodes and with traffic evenly distributed, the conform rate actually becomes 3 times the rate for the cluster.

  • Threat detection—Threat detection works on each node independently; for example, the top statistics is node-specific. Port scanning detection, for example, does not work because scanning traffic will be load-balanced between all nodes, and one node will not see all traffic.

  • Resource management—Resource management in multiple context mode is enforced separately on each node based on local usage.

  • LISP traffic—LISP traffic on UDP port 4342 is inspected by each receiving node, but is not assigned a director. Each node adds to the EID table that is shared across the cluster, but the LISP traffic itself does not participate in cluster state sharing.

AAA for Network Access and Clustering

AAA for network access consists of three components: authentication, authorization, and accounting. Authentication and authorization are implemented as centralized features on the clustering control node with replication of the data structures to the cluster data nodes. If a control node is elected, the new control node will have all the information it needs to continue uninterrupted operation of the established authenticated users and their associated authorizations. Idle and absolute timeouts for user authentications are preserved when a control node change occurs.

Accounting is implemented as a distributed feature in a cluster. Accounting is done on a per-flow basis, so the cluster node owning a flow will send accounting start and stop messages to the AAA server when accounting is configured for a flow.

Connection Settings and Clustering

Connection limits are enforced cluster-wide (see the set connection conn-max , set connection embryonic-conn-max , set connection per-client-embryonic-max , and set connection per-client-max commands). Each node has an estimate of the cluster-wide counter values based on broadcast messages. Due to efficiency considerations, the configured connection limit across the cluster might not be enforced exactly at the limit number. Each node may overestimate or underestimate the cluster-wide counter value at any given time. However, the information will get updated over time in a load-balanced cluster.

FTP and Clustering

  • If FTP data channel and control channel flows are owned by different cluster members, then the data channel owner will periodically send idle timeout updates to the control channel owner and update the idle timeout value. However, if the control flow owner is reloaded, and the control flow is re-hosted, the parent/child flow relationship will not longer be maintained; the control flow idle timeout will not be updated.

  • If you use AAA for FTP access, then the control channel flow is centralized on the control node.

ICMP Inspection and Clustering

The flow of ICMP and ICMP error packets through the cluster varies depending on whether ICMP/ICMP error inspection is enabled. Without ICMP inspection, ICMP is a one-direction flow, and there is no director flow support. With ICMP inspection, the ICMP flow becomes two-directional and is backed up by a director/backup flow. One difference for an inspected ICMP flow is in the director handling of a forwarded packet: the director will forward the ICMP echo reply packet to the flow owner instead of returning the packet to the forwarder.

Multicast Routing and Clustering

Multicast Routing in Spanned EtherChannel Mode

In Spanned EtherChannel mode: The control unit handles all multicast routing packets and data packets until fast-path forwarding is established. After the connection is established, each data unit can forward multicast data packets.

NAT and Clustering

NAT can affect the overall throughput of the cluster. Inbound and outbound NAT packets can be sent to different ASAs in the cluster, because the load balancing algorithm relies on IP addresses and ports, and NAT causes inbound and outbound packets to have different IP addresses and/or ports. When a packet arrives at the ASA that is not the NAT owner, it is forwarded over the cluster control link to the owner, causing large amounts of traffic on the cluster control link. Note that the receiving node does not create a forwarding flow to the owner, because the NAT owner may not end up creating a connection for the packet depending on the results of security and policy checks.

If you still want to use NAT in clustering, then consider the following guidelines:

  • PAT with Port Block Allocation—See the following guidelines for this feature:

    • Maximum-per-host limit is not a cluster-wide limit, and is enforced on each node individually. Thus, in a 3-node cluster with the maximum-per-host limit configured as 1, if the traffic from a host is load-balanced across all 3 nodes, then it can get allocated 3 blocks with 1 in each node.

    • Port blocks created on the backup node from the backup pools are not accounted for when enforcing the maximum-per-host limit.

    • On-the-fly PAT rule modifications, where the PAT pool is modified with a completely new range of IP addresses, will result in xlate backup creation failures for the xlate backup requests that were still in transit while the new pool became effective. This behavior is not specific to the port block allocation feature, and is a transient PAT pool issue seen only in cluster deployments where the pool is distributed and traffic is load-balanced across the cluster nodes.

    • When operating in a cluster, you cannot simply change the block allocation size. The new size is effective only after you reload each device in the cluster. To avoid having to reload each device, we recommend that you delete all block allocation rules and clear all xlates related to those rules. You can then change the block size and recreate the block allocation rules.

  • NAT pool address distribution for dynamic PAT—When you configure a PAT pool, the cluster divides each IP address in the pool into port blocks. By default, each block is 512 ports, but if you configure port block allocation rules, your block setting is used instead. These blocks are distributed evenly among the nodes in the cluster, so that each node has one or more blocks for each IP address in the PAT pool. Thus, you could have as few as one IP address in a PAT pool for a cluster, if that is sufficient for the number of PAT’ed connections you expect. Port blocks cover the 1024-65535 port range, unless you configure the option to include the reserved ports, 1-1023, on the PAT pool NAT rule.

  • Reusing a PAT pool in multiple rules—To use the same PAT pool in multiple rules, you must be careful about the interface selection in the rules. You must either use specific interfaces in all rules, or "any" in all rules. You cannot mix specific interfaces and "any" across the rules, or the system might not be able to match return traffic to the right node in the cluster. Using unique PAT pools per rule is the most reliable option.

  • No round-robin—Round-robin for a PAT pool is not supported with clustering.

  • No extended PAT—Extended PAT is not supported with clustering.

  • Dynamic NAT xlates managed by the control node—The control node maintains and replicates the xlate table to data nodes. When a data node receives a connection that requires dynamic NAT, and the xlate is not in the table, it requests the xlate from the control node. The data node owns the connection.

  • Stale xlates—The xlate idle time on the connection owner does not get updated. Thus, the idle time might exceed the idle timeout. An idle timer value higher than the configured timeout with a refcnt of 0 is an indication of a stale xlate.

  • Per-session PAT feature—Although not exclusive to clustering, the per-session PAT feature improves the scalability of PAT and, for clustering, allows each data node to own PAT connections; by contrast, multi-session PAT connections have to be forwarded to and owned by the control node. By default, all TCP traffic and UDP DNS traffic use a per-session PAT xlate, whereas ICMP and all other UDP traffic uses multi-session. You can configure per-session NAT rules to change these defaults for TCP and UDP, but you cannot configure per-session PAT for ICMP. For traffic that benefits from multi-session PAT, such as H.323, SIP, or Skinny, you can disable per-session PAT for the associated TCP ports (the UDP ports for those H.323 and SIP are already multi-session by default). For more information about per-session PAT, see the firewall configuration guide.

  • No static PAT for the following inspections—

    • FTP

    • PPTP

    • RSH

    • SQLNET

    • TFTP

    • XDMCP

    • SIP

  • If you have an extremely large number of NAT rules, over ten thousand, you should enable the transactional commit model using the asp rule-engine transactional-commit nat command in the device CLI. Otherwise, the node might not be able to join the cluster.

Dynamic Routing and Clustering

This section describes how to use dynamic routing with clustering.

Dynamic Routing in Spanned EtherChannel Mode

Note


IS-IS is not supported in Spanned EtherChannel mode.


The routing process only runs on the control node, and routes are learned through the control node and replicated to data nodes. If a routing packet arrives at a data node, it is redirected to the control node.

Figure 1. Dynamic Routing in Spanned EtherChannel Mode

After the data node learn the routes from the control node, each node makes forwarding decisions independently.

The OSPF LSA database is not synchronized from the control node to data nodes. If there is a control node switchover, the neighboring router will detect a restart; the switchover is not transparent. The OSPF process picks an IP address as its router ID. Although not required, you can assign a static router ID to ensure a consistent router ID is used across the cluster. See the OSPF Non-Stop Forwarding feature to address the interruption.

SCTP and Clustering

An SCTP association can be created on any node (due to load balancing); its multi-homing connections must reside on the same node.

SIP Inspection and Clustering

A control flow can be created on any node (due to load balancing); its child data flows must reside on the same node.

TLS Proxy configuration is not supported.

SNMP and Clustering

An SNMP agent polls each individual ASA by its Local IP address. You cannot poll consolidated data for the cluster.

You should always use the Local address, and not the Main cluster IP address for SNMP polling. If the SNMP agent polls the Main cluster IP address, if a new control node is elected, the poll to the new control node will fail.

When using SNMPv3 with clustering, if you add a new cluster node after the initial cluster formation, then SNMPv3 users are not replicated to the new node.You must re-add them on the control node to force the users to replicate to the new node, or directly on the data node.

STUN and Clustering

STUN inspection is supported in failover and cluster modes, as pinholes are replicated. However, the transaction ID is not replicated among nodes. In the case where a node fails after receiving a STUN Request and another node received the STUN Response, the STUN Response will be dropped.

Syslog and NetFlow and Clustering

  • Syslog—Each node in the cluster generates its own syslog messages. You can configure logging so that each node uses either the same or a different device ID in the syslog message header field. For example, the hostname configuration is replicated and shared by all nodes in the cluster. If you configure logging to use the hostname as the device ID, syslog messages generated by all nodes look as if they come from a single node. If you configure logging to use the local-node name that is assigned in the cluster bootstrap configuration as the device ID, syslog messages look as if they come from different nodes.

  • NetFlow—Each node in the cluster generates its own NetFlow stream. The NetFlow collector can only treat each ASA as a separate NetFlow exporter.

Cisco TrustSec and Clustering

Only the control node learns security group tag (SGT) information. The control node then populates the SGT to data nodes, and data nodes can make a match decision for SGT based on the security policy.

VPN and Clustering

Site-to-site VPN is a centralized feature; only the control node supports VPN connections.


Note


Remote access VPN is not supported with clustering.


VPN functionality is limited to the control node and does not take advantage of the cluster high availability capabilities. If the control node fails, all existing VPN connections are lost, and VPN users will see a disruption in service. When a new control node is elected, you must reestablish the VPN connections.

When you connect a VPN tunnel to a Spanned EtherChannel address, connections are automatically forwarded to the control node.

VPN-related keys and certificates are replicated to all nodes.

Performance Scaling Factor

When you combine multiple units into a cluster, you can expect the total cluster performance to be approximately 80% of the maximum combined throughput.

For example, if your model can handle approximately 10 Gbps of traffic when running alone, then for a cluster of 8 units, the maximum combined throughput will be approximately 80% of 80 Gbps (8 units x 10 Gbps): 64 Gbps.

Control Node Election

Nodes of the cluster communicate over the cluster control link to elect a control node as follows:

  1. When you enable clustering for a node (or when it first starts up with clustering already enabled), it broadcasts an election request every 3 seconds.

  2. Any other nodes with a higher priority respond to the election request; the priority is set between 1 and 100, where 1 is the highest priority.

  3. If after 45 seconds, a node does not receive a response from another node with a higher priority, then it becomes the control node.


    Note


    If multiple nodes tie for the highest priority, the cluster node name and then the serial number is used to determine the control node.


  4. If a node later joins the cluster with a higher priority, it does not automatically become the control node; the existing control node always remains as the control node unless it stops responding, at which point a new control node is elected.

  5. In a "split brain" scenario when there are temporarily multiple control nodes, then the node with highest priority retains the role while the other nodes return to data node roles.


Note


You can manually force a node to become the control node. For centralized features, if you force a control node change, then all connections are dropped, and you have to re-establish the connections on the new control node.


High Availability Within the Cluster

Clustering provides high availability by monitoring node and interface health and by replicating connection states between nodes.

Node Health Monitoring

Each node periodically sends a broadcast heartbeat packet over the cluster control link. If the control node does not receive any heartbeat packets or other packets from a data node within the configurable timeout period, then the control node removes the data node from the cluster. If the data nodes do not receive packets from the control node, then a new control node is elected from the remaining nodes.

If nodes cannot reach each other over the cluster control link because of a network failure and not because a node has actually failed, then the cluster may go into a "split brain" scenario where isolated data nodes will elect their own control nodes. For example, if a router fails between two cluster locations, then the original control node at location 1 will remove the location 2 data nodes from the cluster. Meanwhile, the nodes at location 2 will elect their own control node and form their own cluster. Note that asymmetric traffic may fail in this scenario. After the cluster control link is restored, then the control node that has the higher priority will keep the control node’s role.

See Control Node Election for more information.

Interface Monitoring

Each node monitors the link status of all named hardware interfaces in use, and reports status changes to the control node.

  • Spanned EtherChannel—Uses cluster Link Aggregation Control Protocol (cLACP). Each node monitors the link status and the cLACP protocol messages to determine if the port is still active in the EtherChannel. The status is reported to the control node.

When you enable health monitoring, all physical interfaces (including the main EtherChannel) are monitored by default; you can optionally disable monitoring per interface. Only named interfaces can be monitored. For example, the named EtherChannel must fail to be considered failed, which means all member ports of an EtherChannel must fail to trigger cluster removal (depending on your minimum port bundling setting).

A node is removed from the cluster if its monitored interfaces fail. The amount of time before the ASA removes a member from the cluster depends on whether the node is an established member or is joining the cluster. If the interface is down on an established member, then the ASA removes the member after 9 seconds. The ASA does not monitor interfaces for the first 90 seconds that a node joins the cluster. Interface status changes during this time will not cause the ASA to be removed from the cluster. For non-EtherChannels, the node is removed after 500 ms, regardless of the member state.

Status After Failure

When a node in the cluster fails, the connections hosted by that node are seamlessly transferred to other nodes; state information for traffic flows is shared over the control node's cluster control link.

If the control node fails, then another member of the cluster with the highest priority (lowest number) becomes the control node.

The ASA automatically tries to rejoin the cluster, depending on the failure event.


Note


When the ASA becomes inactive and fails to automatically rejoin the cluster, all data interfaces are shut down; only the management-only interface can send and receive traffic. The management interface remains up using the IP address the node received from the cluster IP pool. However if you reload, and the node is still inactive in the cluster, the management interface is disabled. You must use the console port for any further configuration.


Rejoining the Cluster

After a cluster node is removed from the cluster, how it can rejoin the cluster depends on why it was removed:

  • Failed cluster control link when initially joining—After you resolve the problem with the cluster control link, you must manually rejoin the cluster by re-enabling clustering at the console port by entering cluster group name , and then enable.

  • Failed cluster control link after joining the cluster—The ASA automatically tries to rejoin every 5 minutes, indefinitely. This behavior is configurable.

  • Failed data interface—The ASA automatically tries to rejoin at 5 minutes, then at 10 minutes, and finally at 20 minutes. If the join is not successful after 20 minutes, then the ASA disables clustering. After you resolve the problem with the data interface, you have to manually enable clustering at the console port by entering cluster group name , and then enable. This behavior is configurable.

  • Failed node—If the node was removed from the cluster because of a node health check failure, then rejoining the cluster depends on the source of the failure. For example, a temporary power failure means the node will rejoin the cluster when it starts up again as long as the cluster control link is up and clustering is still enabled with the enable command. The ASA attempts to rejoin the cluster every 5 seconds.

  • Internal error—Internal failures include: application sync timeout; inconsistent application statuses; and so on. A node will attempt to rejoin the cluster automatically at the following intervals: 5 minutes, 10 minutes, and then 20 minutes. This behavior is configurable.

See Configure the Control Node Bootstrap Settings.

Data Path Connection State Replication

Every connection has one owner and at least one backup owner in the cluster. The backup owner does not take over the connection in the event of a failure; instead, it stores TCP/UDP state information, so that the connection can be seamlessly transferred to a new owner in case of a failure. The backup owner is usually also the director.

Some traffic requires state information above the TCP or UDP layer. See the following table for clustering support or lack of support for this kind of traffic.

Table 1. Features Replicated Across the Cluster

Traffic

State Support

Notes

Up time

Yes

Keeps track of the system up time.

ARP Table

Yes

MAC address table

Yes

User Identity

Yes

Includes AAA rules (uauth).

IPv6 Neighbor database

Yes

Dynamic routing

Yes

SNMP Engine ID

No

Distributed VPN (Site-to-Site) for Firepower 4100/9300

Yes

Backup session becomes the active session, then a new backup session is created.

How the Cluster Manages Connections

Connections can be load-balanced to multiple nodes of the cluster. Connection roles determine how connections are handled in both normal operation and in a high availability situation.

Connection Roles

See the following roles defined for each connection:

  • Owner—Usually, the node that initially receives the connection. The owner maintains the TCP state and processes packets. A connection has only one owner. If the original owner fails, then when new nodes receive packets from the connection, the director chooses a new owner from those nodes.

  • Backup owner—The node that stores TCP/UDP state information received from the owner, so that the connection can be seamlessly transferred to a new owner in case of a failure. The backup owner does not take over the connection in the event of a failure. If the owner becomes unavailable, then the first node to receive packets from the connection (based on load balancing) contacts the backup owner for the relevant state information so it can become the new owner.

    As long as the director (see below) is not the same node as the owner, then the director is also the backup owner. If the owner chooses itself as the director, then a separate backup owner is chosen.

    For clustering on the Firepower 9300, which can include up to 3 cluster nodes in one chassis, if the backup owner is on the same chassis as the owner, then an additional backup owner will be chosen from another chassis to protect flows from a chassis failure.

    If you enable director localization for inter-site clustering, then there are two backup owner roles: the local backup and the global backup. The owner always chooses a local backup at the same site as itself (based on site ID). The global backup can be at any site, and might even be the same node as the local backup. The owner sends connection state information to both backups.

    If you enable site redundancy, and the backup owner is at the same site as the owner, then an additional backup owner will be chosen from another site to protect flows from a site failure. Chassis backup and site backup are independent, so in some cases a flow will have both a chassis backup and a site backup.

  • Director—The node that handles owner lookup requests from forwarders. When the owner receives a new connection, it chooses a director based on a hash of the source/destination IP address and ports (see below for ICMP hash details), and sends a message to the director to register the new connection. If packets arrive at any node other than the owner, the node queries the director about which node is the owner so it can forward the packets. A connection has only one director. If a director fails, the owner chooses a new director.

    As long as the director is not the same node as the owner, then the director is also the backup owner (see above). If the owner chooses itself as the director, then a separate backup owner is chosen.

    If you enable director localization for inter-site clustering, then there are two director roles: the local director and the global director. The owner always chooses a local director at the same site as itself (based on site ID). The global director can be at any site, and might even be the same node as the local director. If the original owner fails, then the local director chooses a new connection owner at the same site.

    ICMP/ICMPv6 hash details:

    • For Echo packets, the source port is the ICMP identifier, and the destination port is 0.

    • For Reply packets, the source port is 0, and the destination port is the ICMP identifier.

    • For other packets, both source and destination ports are 0.

  • Forwarder—A node that forwards packets to the owner. If a forwarder receives a packet for a connection it does not own, it queries the director for the owner, and then establishes a flow to the owner for any other packets it receives for this connection. The director can also be a forwarder. If you enable director localization, then the forwarder always queries the local director. The forwarder only queries the global director if the local director does not know the owner, for example, if a cluster member receives packets for a connection that is owned on a different site. Note that if a forwarder receives the SYN-ACK packet, it can derive the owner directly from a SYN cookie in the packet, so it does not need to query the director. (If you disable TCP sequence randomization, the SYN cookie is not used; a query to the director is required.) For short-lived flows such as DNS and ICMP, instead of querying, the forwarder immediately sends the packet to the director, which then sends them to the owner. A connection can have multiple forwarders; the most efficient throughput is achieved by a good load-balancing method where there are no forwarders and all packets of a connection are received by the owner.


    Note


    We do not recommend disabling TCP sequence randomization when using clustering. There is a small chance that some TCP sessions won't be established, because the SYN/ACK packet might be dropped.


  • Fragment Owner—For fragmented packets, cluster nodes that receive a fragment determine a fragment owner using a hash of the fragment source IP address, destination IP address, and the packet ID. All fragments are then forwarded to the fragment owner over the cluster control link. Fragments may be load-balanced to different cluster nodes, because only the first fragment includes the 5-tuple used in the switch load balance hash. Other fragments do not contain the source and destination ports and may be load-balanced to other cluster nodes. The fragment owner temporarily reassembles the packet so it can determine the director based on a hash of the source/destination IP address and ports. If it is a new connection, the fragment owner will register to be the connection owner. If it is an existing connection, the fragment owner forwards all fragments to the provided connection owner over the cluster control link. The connection owner will then reassemble all fragments.

When a connection uses Port Address Translation (PAT), then the PAT type (per-session or multi-session) influences which member of the cluster becomes the owner of a new connection:

  • Per-session PAT—The owner is the node that receives the initial packet in the connection.

    By default, TCP and DNS UDP traffic use per-session PAT.

  • Multi-session PAT—The owner is always the control node. If a multi-session PAT connection is initially received by a data node, then the data node forwards the connection to the control node.

    By default, UDP (except for DNS UDP) and ICMP traffic use multi-session PAT, so these connections are always owned by the control node.

You can change the per-session PAT defaults for TCP and UDP so connections for these protocols are handled per-session or multi-session depending on the configuration. For ICMP, you cannot change from the default multi-session PAT. For more information about per-session PAT, see the firewall configuration guide.

New Connection Ownership

When a new connection is directed to a node of the cluster via load balancing, that node owns both directions of the connection. If any connection packets arrive at a different node, they are forwarded to the owner node over the cluster control link. For best performance, proper external load balancing is required for both directions of a flow to arrive at the same node, and for flows to be distributed evenly between nodes. If a reverse flow arrives at a different node, it is redirected back to the original node.

Sample Data Flow for TCP

The following example shows the establishment of a new connection.

  1. The SYN packet originates from the client and is delivered to one ASA (based on the load balancing method), which becomes the owner. The owner creates a flow, encodes owner information into a SYN cookie, and forwards the packet to the server.

  2. The SYN-ACK packet originates from the server and is delivered to a different ASA (based on the load balancing method). This ASA is the forwarder.

  3. Because the forwarder does not own the connection, it decodes owner information from the SYN cookie, creates a forwarding flow to the owner, and forwards the SYN-ACK to the owner.

  4. The owner sends a state update to the director, and forwards the SYN-ACK to the client.

  5. The director receives the state update from the owner, creates a flow to the owner, and records the TCP state information as well as the owner. The director acts as the backup owner for the connection.

  6. Any subsequent packets delivered to the forwarder will be forwarded to the owner.

  7. If packets are delivered to any additional nodes, it will query the director for the owner and establish a flow.

  8. Any state change for the flow results in a state update from the owner to the director.

Sample Data Flow for ICMP and UDP

The following example shows the establishment of a new connection.

  1. Figure 2. ICMP and UDP Data Flow
    ICMP and UDP Data Flow
    The first UDP packet originates from the client and is delivered to one ASA (based on the load balancing method).
  2. The node that received the first packet queries the director node that is chosen based on a hash of the source/destination IP address and ports.

  3. The director finds no existing flow, creates a director flow and forwards the packet back to the previous node. In other words, the director has elected an owner for this flow.

  4. The owner creates the flow, sends a state update to the director, and forwards the packet to the server.

  5. The second UDP packet originates from the server and is delivered to the forwarder.

  6. The forwarder queries the director for ownership information. For short-lived flows such as DNS, instead of querying, the forwarder immediately sends the packet to the director, which then sends it to the owner.

  7. The director replies to the forwarder with ownership information.

  8. The forwarder creates a forwarding flow to record owner information and forwards the packet to the owner.

  9. The owner forwards the packet to the client.

Rebalancing New TCP Connections Across the Cluster

If the load balancing capabilities of the upstream or downstream routers result in unbalanced flow distribution, you can configure new connection rebalancing so nodes with higher new connections per second will redirect new TCP flows to other nodes. No existing flows will be moved to other nodes.

Because this command only rebalances based on connections per second, the total number of established connections on each node is not considered, and the total number of connections may not be equal.

Once a connection is offloaded to a different node, it becomes an asymmetric connection.

Do not configure connection rebalancing for inter-site topologies; you do not want new connections rebalanced to cluster members at a different site.

History for ASA Clustering for the Secure Firewall 3100

Feature Name

Version

Feature Information

Support for clustering on the Secure Firewall 3100 was introduced

9.17(1)

You can cluster up to 8 Secure Firewall 3100 nodes in Spanned EtherChannel mode.