- Table of Contents
-
- 03-Layer 2-LAN Switching Configuration Guide
- 00-Preface
- 01-Ethernet interface configuration
- 02-Loopback, null, and inloopback interface configuration
- 03-Bulk interface configuration
- 04-MAC address table configuration
- 05-Ethernet link aggregation configuration
- 06-Port isolation configuration
- 07-Spanning tree configuration
- 08-Loop detection configuration
- 09-VLAN configuration
- 10-MVRP configuration
- 11-QinQ configuration
- 12-VLAN mapping configuration
- 13-LLDP configuration
- 14-L2PT configuration
- 15-PPP configuration
- Related Documents
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Title | Size | Download |
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05-Ethernet link aggregation configuration | 316.04 KB |
Contents
Configuring Ethernet link aggregation
About Ethernet link aggregation
Ethernet link aggregation application scenario
Aggregate interface, aggregation group, and member port
How static link aggregation works
How dynamic link aggregation works
Load sharing modes for link aggregation groups
Restrictions and guidelines: Mixed use of manual and automatic link aggregation configuration
Ethernet link aggregation tasks at a glance
Configuring a manual link aggregation
Restrictions and guidelines for aggregation group configuration
Configuring a Layer 2 aggregation group
Configuring an aggregate interface
Configuring the description of an aggregate interface
Configuring jumbo frame support
Setting the expected bandwidth for an aggregate interface
Configuring an edge aggregate interface
Configuring physical state change suppression on an aggregate interface
Shutting down an aggregate interface
Restoring the default settings for an aggregate interface
Setting the minimum and maximum numbers of Selected ports for an aggregation group
Configuring load sharing for link aggregation groups
Setting load sharing modes for link aggregation groups
Enabling local-first load sharing for link aggregation
Enabling link-aggregation traffic redirection
About link-aggregation traffic redirection
Restrictions and guidelines for link-aggregation traffic redirection
Enabling link-aggregation traffic redirection globally
Enabling link-aggregation traffic redirection for an aggregation group
Enabling BFD for an aggregation group
Display and maintenance commands for Ethernet link aggregation
Ethernet link aggregation configuration examples
Example: Configuring a Layer 2 static aggregation group
Example: Configuring a Layer 2 dynamic aggregation group
Configuring Ethernet link aggregation
About Ethernet link aggregation
Ethernet link aggregation bundles multiple physical Ethernet links into one logical link (called an aggregate link). Link aggregation provides the following benefits:
· Increased bandwidth beyond the limits of a single individual link. In an aggregate link, traffic is distributed across the member ports.
· Improved link reliability. The member ports dynamically back up one another. When a member port fails, its traffic is automatically switched to other member ports.
Ethernet link aggregation application scenario
As shown in Figure 1, Device A and Device B are connected by three physical Ethernet links. These physical Ethernet links are combined into an aggregate link called link aggregation 1. The bandwidth of this aggregate link can reach up to the total bandwidth of the three physical Ethernet links. At the same time, the three Ethernet links back up one another. When a physical Ethernet link fails, the traffic transmitted on the failed link is switched to the other two links.
Figure 1 Ethernet link aggregation diagram
Aggregate interface, aggregation group, and member port
Each link aggregation is represented by a logical aggregate interface. Each aggregate interface has an automatically created aggregation group, which contains member ports to be used for aggregation. The type and number of an aggregation group are the same as its aggregate interface.
Supported aggregate interface types
An aggregate interface can be one of the following types:
· Layer 2—A Layer 2 aggregate interface is created manually. The member ports in a Layer 2 aggregation group can only be Layer 2 Ethernet interfaces.
The port rate of an aggregate interface equals the total rate of its Selected member ports. Its duplex mode is the same as that of the Selected member ports. For more information about Selected member ports, see "Aggregation states of member ports in an aggregation group."
Aggregation states of member ports in an aggregation group
A member port in an aggregation group can be in any of the following aggregation states:
· Selected—A Selected port can forward traffic.
· Unselected—An Unselected port cannot forward traffic.
· Individual—An Individual port can forward traffic as a normal physical port. This state is peculiar to the member ports of edge aggregate interfaces. A Selected or Unselected member port of an edge aggregate interface is placed in Individual state if the following events occur in sequence:
a. The member port goes down and then comes up.
b. The LACP timeout timer expires because it has not received LACPDUs.
For more information about edge aggregate interfaces, see "Edge aggregate interface."
Operational key
When aggregating ports, the system automatically assigns each port an operational key based on port information, such as port rate and duplex mode. Any change to this information triggers a recalculation of the operational key.
In an aggregation group, all Selected ports have the same operational key.
Configuration types
Port configuration includes the attribute configuration and protocol configuration. Attribute configuration affects the aggregation state of the port but the protocol configuration does not.
Attribute configuration
To become a Selected port, a member port must have the same attribute configuration as the aggregate interface. Table 1 describes the attribute configuration.
Table 1 Attribute configuration
Feature |
Attribute configuration |
Port isolation |
Membership of the port in an isolation group. Isolation group number. |
QinQ |
QinQ status (enabled/disabled), TPID for VLAN tags, and VLAN transparent transmission. For information about QinQ, see "Configuring QinQ." |
VLAN mapping |
VLAN mapping configured on the port. For more information about VLAN mapping, see "Configuring VLAN mapping." |
VLAN |
VLAN attribute settings: · Permitted VLAN IDs. · PVID. · Link type (trunk, hybrid, or access). · PVLAN port type (promiscuous, trunk promiscuous, host, or trunk secondary). · IP subnet-based VLAN configuration. · Protocol-based VLAN configuration. · VLAN tagging mode. For information about VLANs, see "Configuring VLANs." |
Protocol configuration
Protocol configuration of a member port does not affect the aggregation state of the member port. MAC address learning and spanning tree settings are examples of the protocol configuration.
Link aggregation modes
An aggregation group operates in one of the following modes:
· Static—Static aggregation is stable. An aggregation group in static mode is called a static aggregation group. The aggregation states of the member ports in a static aggregation group are not affected by the peer ports.
· Dynamic—An aggregation group in dynamic mode is called a dynamic aggregation group. Dynamic aggregation is implemented through IEEE 802.3ad Link Aggregation Control Protocol (LACP). The local system and the peer system automatically maintain the aggregation states of the member ports. Dynamic link aggregation reduces the administrators' workload.
How static link aggregation works
Reference port selection process
When setting the aggregation states of the ports in an aggregation group, the system automatically chooses a member port as the reference port. A Selected port must have the same operational key and attribute configurations as the reference port.
The system chooses a reference port from the member ports in up state.
The candidate reference ports are organized into different priority levels following these rules:
1. In descending order of port priority.
2. Full duplex.
3. In descending order of speed.
4. Half duplex.
5. In descending order of speed.
From the candidate ports with the same attribute configurations as the aggregate interface, the one with the highest priority level is chosen as the reference port.
· If multiple ports have the same priority level, the port that has been Selected (if any) is chosen. If multiple ports with the same priority level have been Selected, the one with the smallest port number is chosen.
· If multiple ports have the same priority level and none of them has been Selected, the port with the smallest port number is chosen.
Setting the aggregation state of each member port
After the reference port is chosen, the system sets the aggregation state of each member port in the static aggregation group.
Figure 2 Setting the aggregation state of a member port in a static aggregation group
After the limit on Selected ports is reached, the aggregation state of a new member port varies by following conditions:
· The port is placed in Unselected state if the port and the Selected ports have the same port priority. This mechanism prevents traffic interruption on the existing Selected ports. A device reboot can cause the device to recalculate the aggregation states of member ports.
· The port is placed in Selected state when the following conditions are met:
¡ The port and the Selected ports have different port priorities, and the port has a higher port priority than a minimum of one Selected port.
¡ The port has the same attribute configurations as the aggregate interface.
Any operational key or attribute configuration change might affect the aggregation states of link aggregation member ports.
Dynamic link aggregation
About LACP
Dynamic aggregation is implemented through IEEE 802.3ad Link Aggregation Control Protocol (LACP).
LACP uses LACPDUs to exchange aggregation information between LACP-enabled devices. Each member port in a dynamic aggregation group can exchange information with its peer. When a member port receives an LACPDU, it compares the received information with information received on the other member ports. In this way, the two systems reach an agreement on which ports are placed in Selected state.
LACP functions
LACP offers basic LACP functions and extended LACP functions, as described in Table 2.
Table 2 Basic and extended LACP functions
Category |
Description |
Basic LACP functions |
Implemented through the basic LACPDU fields, including the LACP system priority, system MAC address, port priority, port number, and operational key. |
Extended LACP functions |
Implemented by extending the LACPDU with new TLV fields. Extended LACP can implement LACP MAD for the IRF feature. The device can participate in LACP MAD as either an IRF member device or an intermediate device. For more information about IRF and the LACP MAD mechanism, see Virtual Technologies Configuration Guide. |
LACP operating modes
LACP can operate in active or passive mode.
When LACP is operating in passive mode on a local member port and its peer port, both ports cannot send LACPDUs. When LACP is operating in active mode on either end of a link, both ports can send LACPDUs.
LACP priorities
LACP priorities include LACP system priority and port priority, as described in Table 3. The smaller the priority value, the higher the priority.
Type |
Description |
LACP system priority |
Used by two peer devices (or systems) to determine which one is superior in link aggregation. In dynamic link aggregation, the system that has higher LACP system priority sets the Selected state of member ports on its side. The system that has lower priority sets the aggregation state of local member ports the same as their respective peer ports. |
Port priority |
Determines the likelihood of a member port to be a Selected port on a system. A port with a higher port priority is more likely to become Selected. |
LACP timeout interval
The LACP timeout interval specifies how long a member port waits to receive LACPDUs from the peer port. If a local member port has not received LACPDUs from the peer within the LACP timeout interval plus 3 seconds, the member port considers the peer as failed.
The LACP timeout interval also determines the LACPDU sending rate of the peer. LACP timeout intervals include the following types:
· Short timeout interval—3 seconds. If you use the short timeout interval, the peer sends one LACPDU per second.
· Long timeout interval—90 seconds. If you use the long timeout interval, the peer sends one LACPDU every 30 seconds.
Methods to assign interfaces to a dynamic link aggregation group
You can use one of the following methods to assign interfaces to a dynamic link aggregation group:
· Manual assignment—Manually assign interfaces to the dynamic link aggregation group.
· Automatic assignment—Enable automatic assignment on interfaces to have them automatically join a dynamic link aggregation group depending on the peer information in the received LACPDUs.
|
NOTE: When you use automatic assignment on one end, you must use manual assignment on the other end. |
Alternatively, you can use automatic link aggregation for two devices to automatically create a dynamic link aggregation between them by using LLDP.
Automatic member port assignment
This feature automates the assignment of aggregation member ports to an aggregation group. You can use this feature when setting up an aggregate link to a server.
As shown in Figure 3, an interface enabled with automatic assignment joins a dynamic aggregation group based on the peer information in the LACPDUs received from the aggregation peer. If none of the existing dynamic aggregation groups is qualified, the device automatically creates a new dynamic aggregation group, Then, the device assigns the interface to that group and synchronizes the interface's attribute configurations to the aggregate interface.
A dynamic aggregation group that contains automatically assigned member ports selects a reference port and Selected ports as described in "How dynamic link aggregation works." The assignment methods of member ports do not change the processes of reference port selection and Selected port selection.
Figure 3 Automatic member port assignment process
Automatic link aggregation
Automatic link aggregation enables two devices to automatically create a dynamic link aggregation between them by using LLDP.
After you enable automatic link aggregation and LLDP on two connected devices, they automatically establish a dynamic link aggregation based on the information in incoming LLDP frames. The devices each automatically create a dynamic aggregate interface and assign the redundant ports connected to the peer to the aggregation group of that interface. When assigning the first member port to the aggregate group, the device synchronizes the member port's attribute configuration to the aggregate interface.
An automatically created dynamic aggregation group selects a reference port and Selected ports as described in "How dynamic link aggregation works." The aggregation group creation methods do not change the processes of reference port selection and Selected port selection.
IMPORTANT: As a best practice to ensure correct operation of dynamic aggregation groups, do not use automatic link aggregation and automatic member port assignment together. |
How dynamic link aggregation works
Choosing a reference port
The system chooses a reference port from the member ports in up state. A Selected port must have the same operational key and attribute configurations as the reference port.
The local system (the actor) and the peer system (the partner) negotiate a reference port by using the following workflow:
1. The two systems determine the system with the smaller system ID.
A system ID contains the LACP system priority and the system MAC address.
a. The two systems compare their LACP priority values.
The lower the LACP priority, the smaller the system ID. If the LACP priority values are the same, the two systems proceed to step b.
b. The two systems compare their MAC addresses.
The lower the MAC address, the smaller the system ID.
2. The system with the smaller system ID chooses the port with the smallest port ID as the reference port.
A port ID contains a port priority and a port number. The lower the port priority, the smaller the port ID.
a. The system chooses the port with the lowest priority value as the reference port.
If the ports have the same priority, the system proceeds to step b.
b. The system compares their port numbers.
The smaller the port number, the smaller the port ID.
The port with the smallest port number and the same attribute configurations as the aggregate interface is chosen as the reference port.
|
NOTE: To identify the port numbers of aggregation member ports, execute the display link-aggregation verbose command and examine the Index field in the command output. |
Setting the aggregation state of each member port
After the reference port is chosen, the system with the smaller system ID sets the state of each member port on its side.
Figure 4 Setting the state of a member port in a dynamic aggregation group
The system with the greater system ID can detect the aggregation state changes on the peer system. The system with the greater system ID sets the aggregation state of local member ports the same as their peer ports.
When you aggregate interfaces in dynamic mode, follow these guidelines:
· A dynamic link aggregation group chooses only full-duplex ports as the Selected ports.
· For stable aggregation and service continuity, do not change the operational key or attribute configurations on any member port.
· When a member port changes to the Selected or Unselected state, its peer port changes to the same aggregation state.
· After the Selected port limit is reached, a newly joining port becomes a Selected port if it is more eligible than a current Selected port.
Edge aggregate interface
Dynamic link aggregation fails on a server-facing aggregate interface if dynamic link aggregation is configured only on the device. The device forwards traffic by using only one of the physical ports that are connected to the server.
To improve link reliability, configure the aggregate interface as an edge aggregate interface. This feature enables all member ports of the aggregation group to forward traffic. When a member port fails, its traffic is automatically switched to other member ports.
After dynamic link aggregation is configured on the server, the device can receive LACPDUs from the server. Then, link aggregation between the device and the server operates correctly.
An edge aggregate interface takes effect only when it is configured on an aggregate interface corresponding to a dynamic aggregation group.
Load sharing modes for link aggregation groups
In a link aggregation group, traffic can be load shared across the Selected ports based on any of the following modes:
· Per-flow load sharing—Distributes traffic on a per-flow basis. The load sharing mode classifies packets into flows and forwards packets of the same flow on the same link. This mode can be one of or a combination of the following traffic classification criteria:
¡ Ingress port.
¡ Source or destination IP.
¡ Source or destination MAC.
¡ Source or destination port number.
· Packet type-based load sharing—Distributes traffic automatically based on packet types.
S-MLAG
Simple multichassis link aggregation (S-MLAG) enhances dynamic link aggregation to establish an aggregation that spans multiple devices to a remote device.
An S-MLAG multichassis aggregation connects one dynamic Layer 2 aggregate interface on each S-MLAG device to the remote device, as shown in Figure 5.
S-MLAG uses an S-MLAG group to manage the aggregate interfaces for each aggregation, and it runs LACP to maintain each aggregation as does dynamic link aggregation. To the remote device, the S-MLAG devices appear as one peer aggregation system.
Figure 5 S-MLAG application scenario
Restrictions and guidelines: Mixed use of manual and automatic link aggregation configuration
To avoid unexpected aggregation issues, do not use manual assignment, automatic assignment, and automatic link aggregation in any combination. If you use any two of these features in combination, an automatically assigned member port might move between aggregation groups or undesirably change from Selected to Unselected in some situations.
Ethernet link aggregation tasks at a glance
To configure Ethernet link aggregation, perform the following tasks:
1. Configuring link aggregation
¡ Configuring a manual link aggregation
2. (Optional.) Configuring an aggregate interface
¡ Configuring the description of an aggregate interface
¡ Configuring jumbo frame support
¡ Setting the expected bandwidth for an aggregate interface
¡ Configuring an edge aggregate interface
An edge aggregate interface uses all member ports to forward traffic when the aggregation peer is not enabled with dynamic link aggregation.
¡ Configuring physical state change suppression on an aggregate interface
¡ Shutting down an aggregate interface
¡ Restoring the default settings for an aggregate interface
3. (Optional.) Adjusting aggregation states of link aggregation member ports
¡ Setting the minimum and maximum numbers of Selected ports for an aggregation group
4. (Optional.) Configuring load sharing for link aggregation groups
¡ Setting load sharing modes for link aggregation groups
¡ Enabling local-first load sharing for link aggregation
5. (Optional.) Enabling link-aggregation traffic redirection
This feature redirects traffic on an unavailable Selected port to the remaining available Selected ports of an aggregation group to avoid traffic interruption.
6. (Optional.) Enabling BFD for an aggregation group
Configuring a manual link aggregation
Restrictions and guidelines for aggregation group configuration
Layer 2 aggregation group restrictions
You cannot assign an interface to a Layer 2 aggregation group if any features in Table 4 are configured on that interface.
Table 4 Features incompatible with Layer 2 aggregation member ports
Feature on the interface |
Reference |
MAC authentication |
MAC authentication in Security Configuration Guide |
Port security |
Port security in Security Configuration Guide |
802.1X |
802.1X in Security Configuration Guide |
Aggregation member port restrictions
Deleting an aggregate interface also deletes its aggregation group and causes all member ports to leave the aggregation group.
An interface cannot join an aggregation group if it has different attribute configurations from the aggregate interface. After joining an aggregation group, an interface inherits the attribute configurations on the aggregate interface. You can modify the attribute configurations only on the aggregate interface.
Do not assign a reflector port for port mirroring to an aggregation group. For more information about reflector ports, see Network Management and Monitoring Configuration Guide.
Attribute and protocol configuration restrictions
For a link aggregation group, attribute configurations are configurable only on the aggregate interface and are automatically synchronized to all member ports. You cannot configure attribute configurations on a member port until it is removed from the link aggregation group. The configurations that have been synchronized from the aggregate interface are retained on the member ports even after the aggregate interface is deleted.
If an attribute setting on the aggregate interface fails to be synchronized to a Selected member port, the port might change to the Unselected state.
The protocol configurations for an aggregate interface take effect only on the current aggregate interface. The protocol configurations for a member port take effect only when the port leaves its aggregation group.
Configuration consistency requirements
You must configure the same aggregation mode at the two ends of an aggregate link.
· For a successful static aggregation, make sure the ports at both ends of each link are in the same aggregation state.
· For a successful dynamic aggregation:
¡ Make sure the ports at both ends of a link are assigned to the correct aggregation group. The two ends can automatically negotiate the aggregation state of each member port.
¡ If you use automatic interface assignment on one end, you must use manual assignment on the other end.
Configuring a Layer 2 aggregation group
Configuring a Layer 2 static aggregation group
1. Enter system view.
system-view
2. Create a Layer 2 aggregate interface and enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
When you create a Layer 2 aggregate interface, the system automatically creates a Layer 2 static aggregation group numbered the same as that interface.
3. Return to system view.
quit
4. Assign an interface to the Layer 2 aggregation group:
a. Enter Layer 2 Ethernet interface view.
interface interface-type interface-number
b. Assign the interface to the Layer 2 aggregation group.
port link-aggregation group group-id [ force ]
Repeat the substeps to assign more interfaces to the aggregation group.
To synchronize the attribute configurations from the aggregate interface when the current interface joins the aggregation group, specify the force keyword.
5. (Optional.) Set the port priority of the interface.
link-aggregation port-priority priority
The default port priority of an interface is 32768.
Configuring a Layer 2 dynamic aggregation group
1. Enter system view.
system-view
2. Set the LACP system priority.
lacp system-priority priority
By default, the LACP system priority is 32768.
Changing the LACP system priority might affect the aggregation states of the ports in a dynamic aggregation group.
3. Create a Layer 2 aggregate interface and enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
When you create a Layer 2 aggregate interface, the system automatically creates a Layer 2 static aggregation group numbered the same as that interface.
4. Configure the aggregation group to operate in dynamic mode.
link-aggregation mode dynamic
By default, an aggregation group operates in static mode.
5. Return to system view.
quit
6. Assign an interface to the Layer 2 aggregation group:
a. Enter Layer 2 Ethernet interface view.
interface interface-type interface-number
b. Assign the interface to the Layer 2 aggregation group or enable automatic assignment on that interface.
port link-aggregation group { group-id [ force ] | auto [ group-id ] }
Repeat these two substeps to assign more Layer 2 Ethernet interfaces to the aggregation group.
To synchronize the attribute configurations from the aggregate interface when the current interface joins the aggregation group, specify the force keyword.
To enable automatic assignment, specify the auto keyword. As a best practice, do not modify the configuration on an automatically created aggregate interface or its member ports.
7. Set the LACP operating mode for the interface.
¡ Set the LACP operating mode to passive.
lacp mode passive
¡ Set the LACP operating mode to active.
undo lacp mode
By default, LACP is operating in active mode.
8. (Optional.) Set the port priority for the interface.
link-aggregation port-priority priority
The default setting is 32768.
9. (Optional.) Set the short LACP timeout interval (3 seconds) for the interface.
lacp period short
By default, the long LACP timeout interval (90 seconds) is used by the interface.
Configuring S-MLAG
Restrictions and guidelines
Use S-MLAG to set up link aggregations only with servers.
S-MLAG is intended for a non-IRF environment. Do not configure it on an IRF fabric. For more formation about IRF, see Virtual Technologies Configuration Guide.
Each S-MLAG group can contain only one aggregate interface on each device.
Do not configure the following settings on S-MLAG devices:
· LACP MAD.
· Link-aggregation traffic redirection.
· Maximum or minimum number of Selected ports.
· Automatic member port assignment.
As a best practice, maintain consistency across S-MLAG devices in service feature configuration.
Prerequisites
Configure the link aggregation settings other than S-MLAG settings on each S-MLAG device. Make sure the settings are consistent across the S-MLAG devices.
Procedure
1. Enter system view.
system-view
2. Set the LACP system MAC address.
lacp system-mac mac-address
By default, the LACP system MAC address is the bridge MAC address of the device.
All S-MLAG devices must use the same LACP system MAC address.
3. Set the LACP system priority.
lacp system-priority priority
By default, the LACP system priority is 32768.
All S-MLAG devices must use the same LACP system priority.
4. Set the LACP system number.
lacp system-number number
By default, the LACP system number is not set.
You must assign a unique LACP system number to each S-MLAG device.
5. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
6. Set the link aggregation mode to dynamic.
link-aggregation mode dynamic
By default, an aggregation group operates in static mode.
7. Assign the aggregate interface to an S-MLAG group.
port s-mlag group group-id
By default, an aggregate interface is not assigned to any S-MLAG group.
Configuring an aggregate interface
Most settings that can be made on Layer 2 Ethernet interfaces can also be made on Layer 2 aggregate interfaces.
Configuring the description of an aggregate interface
About the aggregate interface description
You can configure the description of an aggregate interface for administration purposes, for example, describing the purpose of the interface.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Configure the interface description.
description text
By default, the description of an interface is interface-name Interface.
Configuring jumbo frame support
About jumbo frames
An aggregate interface might receive frames larger than 1522 bytes during high-throughput data exchanges, such as file transfers. These frames are called jumbo frames.
How an aggregate interface processes jumbo frames depends on whether jumbo frame support is enabled on the interface.
· If configured to deny jumbo frames, the aggregate interface discards jumbo frames.
· If enabled with jumbo frame support, the aggregate interface performs the following operations:
¡ Processes jumbo frames that are within the allowed length.
¡ Discards jumbo frames that exceed the allowed length.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Allow jumbo frames.
jumboframe enable [ size ]
By default, an aggregate interface allows jumbo frames with a maximum length of 10240 bytes to pass through.
If you execute this command multiple times, the most recent configuration takes effect.
Setting the expected bandwidth for an aggregate interface
About expected bandwidth
Expected bandwidth is an informational parameter used only by higher-layer protocols for calculation. You cannot adjust the actual bandwidth of an interface by performing this task.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Set the expected bandwidth for the interface.
bandwidth bandwidth-value
By default, the expected bandwidth (in kbps) is the interface baud rate divided by 1000.
Configuring an edge aggregate interface
Restrictions and guidelines
You can only configure an aggregate interface in dynamic mode as an edge interface.
Configure only aggregate interfaces connected to endpoints such as servers as edge aggregate interfaces. Do not connect edge aggregate interfaces to network devices.
Link-aggregation traffic redirection cannot operate correctly on an edge aggregate interface. For more information about link-aggregation traffic redirection, see "Enabling link-aggregation traffic redirection."
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Configure the aggregate interface as an edge aggregate interface.
lacp edge-port
By default, an aggregate interface does not operate as an edge aggregate interface.
Configuring physical state change suppression on an aggregate interface
About physical state change suppression
The physical link state of an aggregate interface is either up or down. Each time the physical link of an interface comes up or goes down, the system immediately reports the change to the CPU. The CPU then performs the following operations:
· Notifies the upper-layer protocol modules (such as routing and forwarding modules) of the change for guiding packet forwarding.
· Automatically generates traps and logs to inform users to take the correct actions.
To prevent frequent physical link flapping from affecting system performance, configure physical state change suppression. You can configure this feature to suppress link-down events, link-up events, or both. If an event of the specified type still exists when the suppression interval expires, the system reports the event to the CPU.
Restrictions and guidelines
Do not use this feature in combination with S-MLAG.
When you use this feature on an aggregate interface, make sure its peer is also an aggregate interface. In addition, you must set the physical state change suppression interval to the same value on those aggregate interfaces.
On an interface, you can configure different suppression intervals for link-up and link-down events. If you execute the link-delay command multiple times for an event type, the most recent configuration takes effect on that event type.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Configure physical state change suppression.
link-delay { down | up } [ msec ] delay-time
By default, each time the physical link of an aggregate interface goes up or comes down, the system immediately reports the change to the CPU.
Shutting down an aggregate interface
Restrictions and guidelines
CAUTION: The shutdown command will disconnect all links established on an interface. Make sure you are fully aware of the impacts of this command when you use it on a live network. |
Shutting down or bringing up an aggregate interface affects the aggregation states and link states of member ports in the corresponding aggregation group as follows:
· When an aggregate interface is shut down, all its Selected ports become Unselected and all member ports go down.
· When an aggregate interface is brought up, the aggregation states of all its member ports are recalculated.
When you shut down or bring up a Layer 3 aggregate interface, all its aggregate subinterfaces are also shut down or brought up. Shutting down or bringing up a Layer 3 aggregate subinterface does not affect the state of the main aggregate interface.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Shut down the interface.
Shutdown
Restoring the default settings for an aggregate interface
Restrictions and guidelines
CAUTION: The default command might interrupt ongoing network services. Make sure you are fully aware of the impacts of this command when you execute it on a live network. |
The default command might fail to restore the default settings for some commands for reasons such as command dependencies and system restrictions.
To resolve this issue:
1. Use the display this command in interface view to identify these commands.
2. Use their undo forms or follow the command reference to restore their default settings.
3. If the restoration attempt still fails, follow the error message instructions to resolve the issue.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Restore the default settings for the aggregate interface.
Default
Setting the minimum and maximum numbers of Selected ports for an aggregation group
About the minimum and maximum numbers of Selected ports for an aggregation group
The bandwidth of an aggregate link increases as the number of Selected member ports increases. To avoid congestion, you can set the minimum number of Selected ports required for bringing up an aggregate interface.
This minimum threshold setting affects the aggregation states of aggregation member ports and the state of the aggregate interface.
· When the number of member ports eligible to be Selected ports is smaller than the minimum threshold, the following events occur:
¡ The eligible member ports are placed in Unselected state.
¡ The link layer state of the aggregate interface becomes down.
· When the number of member ports eligible to be Selected ports reaches or exceeds the minimum threshold, the following events occur:
¡ The eligible member ports are placed in Selected state.
¡ The link layer state of the aggregate interface becomes up.
The maximum number of Selected ports allowed in an aggregation group is limited by either manual configuration or hardware limitation, whichever value is smaller.
You can implement backup between two ports by performing the following tasks:
· Assigning two ports to an aggregation group.
· Setting the maximum number of Selected ports to 1 for the aggregation group.
Then, only one Selected port is allowed in the aggregation group, and the Unselected port acts as a backup port.
Restrictions and guidelines
IMPORTANT: After you set the minimum percentage of Selected ports for an aggregation group, aggregate interface flapping might occur when ports join or leave an aggregation group. Make sure you are fully aware of the impacts of this setting when you configure it on a live network. |
You can set either the minimum number or the minimum percentage of Selected ports for an aggregation group. If you configure both settings on an aggregate interface, the higher Selected port number limit takes effect.
The minimum and maximum numbers of Selected ports must be the same between the two ends of an aggregate link.
The minimum percentage of Selected ports must be the same between the two ends of an aggregate link.
For an aggregation group, the maximum number of Selected ports must be equal to or higher than the minimum number of Selected ports.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Set the minimum number of Selected ports for the aggregation group. Choose one of the following methods:
¡ Set the minimum number of Selected ports.
link-aggregation selected-port minimum min-number
¡ Set the minimum percentage of Selected ports.
link-aggregation selected-port minimum percentage number
By default, the minimum number of Selected ports is not specified for an aggregation group.
4. Set the maximum number of Selected ports for the aggregation group.
link-aggregation selected-port maximum max-number
By default, an aggregation group can have a maximum of 8 Selected ports.
Disabling the default action of selecting a Selected port for dynamic aggregation groups that have not received LACPDUs
About the default port selection action
The default port selection action applies to dynamic aggregation groups.
This action automatically chooses the port with the lowest ID from among all up member ports as a Selected port if none of them has received LACPDUs before the LACP timeout interval expires.
After this action is disabled, a dynamic aggregation group will not have any Selected ports to forward traffic if it has not received LACPDUs before the LACP timeout interval expires.
Procedure
1. Enter system view.
system-view
2. Disable the default port selection action.
lacp default-selected-port disable
By default, the default port selection action is enabled for dynamic aggregation groups.
Configuring a dynamic aggregation group to use port speed as the prioritized criterion for reference port selection
About prioritizing port speed in reference port selection
Perform this task to ensure that a dynamic aggregation group selects a high-speed member port as the reference port. After you perform this task, the reference port will be selected based on the criteria in order of device ID, port speed, and port ID.
Restrictions and guidelines
Changing reference port selection criteria might cause transient traffic interruption. Make sure you understand the impact of this task on your network.
You must perform this task at both ends of the aggregate link so the peer aggregation systems use the same criteria for reference port selection.
As a best practice, shut down the peer aggregate interfaces before you execute this command and bring up the interfaces after this command is executed on both of them.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Specify port speed as the prioritized criterion for reference port selection.
lacp select speed
By default, port ID is the prioritized criterion for reference port selection of a dynamic aggregation group.
Configuring load sharing for link aggregation groups
Setting load sharing modes for link aggregation groups
About load sharing modes
You can set a global load sharing mode for all link aggregation groups.
The load sharing mode set for link aggregation groups might cause unbalanced traffic distribution across ECMP routes. Make sure you are fully aware of the impacts of this feature when you configure it on a live network.
Restrictions and guidelines
The following are global load sharing modes supported on the device:
· Load sharing mode automatically determined based on the packet type.
· Source IP.
· Destination IP.
· Source MAC.
· Destination MAC.
· Source port.
· Destination port.
· Ingress port.
· Any combinations of ingress port, source IP, source port, destination IP, and destination port.
· Any combinations of ingress port, source port, source MAC, destination port, and destination MAC.
Procedure
1. Enter system view.
system-view
2. Set the global link-aggregation load sharing mode.
link-aggregation global load-sharing mode { destination-ip | destination-mac | destination-port | ingress-port | source-ip | source-mac | source-port } *
By default, packets are load shared based on the following information:
¡ Source and destination IP addresses.
¡ Source and destination MAC addresses.
Enabling local-first load sharing for link aggregation
About local-first load sharing for link aggregation
Use local-first load sharing in a multidevice link aggregation scenario to distribute traffic preferentially across member ports on the ingress slot.
When you aggregate ports on different member devices in an IRF fabric, you can use local-first load sharing to reduce traffic on IRF links, as shown in Figure 6. For more information about IRF, see Virtual Technologies Configuration Guide.
Figure 6 Load sharing for multidevice link aggregation in an IRF fabric
Enabling local-first load sharing for link aggregation globally
1. Enter system view.
system-view
2. Enable local-first load sharing for link aggregation globally.
link-aggregation load-sharing mode local-first
By default, local-first load sharing is enabled globally.
Enabling link-aggregation traffic redirection
About link-aggregation traffic redirection
This feature operates on dynamic link aggregation groups. It redirects traffic on a Selected port to the remaining available Selected ports of an aggregation group if one of the following events occurs:
· The port is shut down by using the shutdown command.
· The slot that hosts the port reboots, and the aggregation group spans multiple slots.
|
NOTE: The device does not redirect traffic to member ports that become Selected during the traffic redirection process. |
This feature ensures zero packet loss for known unicast traffic, but does not protect unknown unicast traffic.
You can enable link-aggregation traffic redirection globally or for an aggregation group. Global link-aggregation traffic redirection settings take effect on all aggregation groups. A link aggregation group preferentially uses the group-specific link-aggregation traffic redirection settings. If group-specific link-aggregation traffic redirection is not configured, the group uses the global link-aggregation traffic redirection settings.
Restrictions and guidelines for link-aggregation traffic redirection
Link-aggregation traffic redirection applies only to dynamic link aggregation groups.
As a best practice, enable link-aggregation traffic redirection on a per-interface basis. If you enable this feature globally, communication with a third-party peer device might be affected if the peer is not compatible with this feature.
To prevent traffic interruption, enable link-aggregation traffic redirection at both ends of the aggregate link.
To prevent packet loss that might occur at a slot reboot, do not enable the spanning tree feature together with link-aggregation traffic redirection.
Link-aggregation traffic redirection does not operate correctly on an edge aggregate interface.
Enabling link-aggregation traffic redirection globally
1. Enter system view.
system-view
2. Enable link-aggregation traffic redirection globally.
link-aggregation lacp traffic-redirect-notification enable
By default, link-aggregation traffic redirection is disabled globally.
Enabling link-aggregation traffic redirection for an aggregation group
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Enable link-aggregation traffic redirection for the aggregation group.
link-aggregation lacp traffic-redirect-notification enable
By default, link-aggregation traffic redirection is disabled for an aggregation group.
Enabling BFD for an aggregation group
About BFD for Ethernet link aggregation
You can use BFD to monitor member link status in an aggregation group. After you enable BFD on an aggregate interface, each Selected port in the aggregation group establishes a BFD session with its peer port. BFD operates differently depending on the aggregation mode.
· BFD on a static aggregation—When BFD detects a link failure, BFD notifies the Ethernet link aggregation module that the peer port is unreachable. The local port is then placed in Unselected state. However, the BFD session between the local and peer ports remains, and the local port keeps sending BFD packets. When BFD on the local port receives packets from the peer port upon link recovery, BFD notifies the Ethernet link aggregation module that the peer port is reachable. Then, the local port is placed in Selected state again. This mechanism ensures that the local and peer ports of a static aggregate link have the same aggregation state.
· BFD on a dynamic aggregation—When BFD detects a link failure, BFD notifies the Ethernet link aggregation module that the peer port is unreachable. At the same time, BFD clears the session and stops sending BFD packets. When the local port is placed in Selected state again upon link recovery, the local port establishes a new session with the peer port and BFD notifies the Ethernet link aggregation module that the peer port is reachable. Because BFD provides fast failure detection, the local and peer systems of a dynamic aggregate link can negotiate the aggregation state of their member ports faster.
For more information about BFD, see High Availability Configuration Guide.
Restrictions and guidelines
When you enable BFD for an aggregation group, follow these restrictions and guidelines:
· Make sure the source and destination IP addresses are reversed between the two ends of an aggregate link. For example, if you execute link-aggregation bfd ipv4 source 1.1.1.1 destination 2.2.2.2 at the local end, execute link-aggregation bfd ipv4 source 2.2.2.2 destination 1.1.1.1 at the peer end. The source and destination IP addresses cannot be the same.
· The BFD parameters configured on an aggregate interface take effect on all BFD sessions established by the member ports in its aggregation group. BFD on an aggregate link supports only control packet mode for session establishment and maintenance. The two ends of an established BFD session can only operate in Asynchronous mode.
· As a best practice, do not configure BFD for any protocols on a BFD-enabled aggregate interface.
· Make sure the number of member ports in a BFD-enabled aggregation group is less than or identical to the number of BFD sessions supported by the device. If the aggregation group contains more member ports than the supported sessions, some Selected ports might change to the Unselected state.
· If the number of BFD sessions differs between the two ends of an aggregate link, check their settings for inconsistency in the maximum number of Selected ports. You must make sure the two ends have the same setting for the maximum number of Selected ports.
Procedure
1. Enter system view.
system-view
2. Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Enable BFD for the aggregation group.
link-aggregation bfd ipv4 source ip-address destination ip-address
By default, BFD is disabled for an aggregation group.
Display and maintenance commands for Ethernet link aggregation
Execute display commands in any view and reset commands in user view.
Task |
Command |
Display information about aggregate interfaces. |
display interface [ bridge-aggregation [ interface-number ] ] [ brief [ description | down ] ] |
Display the local system ID. |
display lacp system-id |
Display the global or group-specific link-aggregation load sharing modes. |
display link-aggregation load-sharing mode [ interface [ bridge-aggregation interface-number ] ] |
Display detailed link aggregation information about link aggregation member ports. |
display link-aggregation member-port [ interface-list | auto ] |
Display summary information about all aggregation groups. |
display link-aggregation summary |
Display detailed information about the specified aggregation groups. |
display link-aggregation verbose [ bridge-aggregation [ interface-number ] ] |
Clear statistics for the specified aggregate interfaces. |
reset counters interface [ bridge-aggregation [ interface-number ] ] |
Clear LACP statistics for the specified link aggregation member ports. |
reset lacp statistics [ interface interface-list ] |
Ethernet link aggregation configuration examples
Example: Configuring a Layer 2 static aggregation group
Network configuration
On the network shown in Figure 7, perform the following tasks:
· Configure a Layer 2 static aggregation group on both Device A and Device B.
· Enable VLAN 10 at one end of the aggregate link to communicate with VLAN 10 at the other end.
· Enable VLAN 20 at one end of the aggregate link to communicate with VLAN 20 at the other end.
Procedure
1. Configure Device A:
# Create VLAN 10, and assign port GigabitEthernet 1/0/4 to VLAN 10.
<DeviceA> system-view
[DeviceA] vlan 10
[DeviceA-vlan10] port gigabitethernet 1/0/4
[DeviceA-vlan10] quit
# Create VLAN 20, and assign port GigabitEthernet 1/0/5 to VLAN 20.
[DeviceA] vlan 20
[DeviceA-vlan20] port gigabitethernet 1/0/5
[DeviceA-vlan20] quit
# Create Layer 2 aggregate interface Bridge-Aggregation 1.
[DeviceA] interface bridge-aggregation 1
[DeviceA-Bridge-Aggregation1] quit
# Assign ports GigabitEthernet 1/0/1 through GigabitEthernet 1/0/3 to link aggregation group 1.
[DeviceA] interface gigabitethernet 1/0/1
[DeviceA-GigabitEthernet1/0/1] port link-aggregation group 1
[DeviceA-GigabitEthernet1/0/1] quit
[DeviceA] interface gigabitethernet 1/0/2
[DeviceA-GigabitEthernet1/0/2] port link-aggregation group 1
[DeviceA-GigabitEthernet1/0/2] quit
[DeviceA] interface gigabitethernet 1/0/3
[DeviceA-GigabitEthernet1/0/3] port link-aggregation group 1
[DeviceA-GigabitEthernet1/0/3] quit
# Configure Layer 2 aggregate interface Bridge-Aggregation 1 as a trunk port and assign it to VLANs 10 and 20.
[DeviceA] interface bridge-aggregation 1
[DeviceA-Bridge-Aggregation1] port link-type trunk
[DeviceA-Bridge-Aggregation1] port trunk permit vlan 10 20
[DeviceA-Bridge-Aggregation1] quit
2. Configure Device B in the same way Device A is configured. (Details not shown.)
Verifying the configuration
# Display detailed information about all aggregation groups on Device A.
[DeviceA] display link-aggregation verbose
Loadsharing Type: Shar -- Loadsharing, NonS -- Non-Loadsharing
Port Status: S -- Selected, U -- Unselected, I -- Individual
Port: A -- Auto port, M -- Management port, R -- Reference port
Flags: A -- LACP_Activity, B -- LACP_Timeout, C -- Aggregation,
D -- Synchronization, E -- Collecting, F -- Distributing,
G -- Defaulted, H -- Expired
Aggregate Interface: Bridge-Aggregation1
Aggregation Mode: Static
Loadsharing Type: Shar
Management VLANs: None
Port Status Priority Oper-Key
GE1/0/1(R) S 32768 1
GE1/0/2 S 32768 1
GE1/0/3 S 32768 1
The output shows that link aggregation group 1 is a Layer 2 static aggregation group that contains three Selected ports.
Example: Configuring a Layer 2 dynamic aggregation group
Network configuration
On the network shown in Figure 8, perform the following tasks:
· Configure a Layer 2 dynamic aggregation group on both Device A and Device B.
· Enable VLAN 10 at one end of the aggregate link to communicate with VLAN 10 at the other end.
· Enable VLAN 20 at one end of the aggregate link to communicate with VLAN 20 at the other end.
Procedure
1. Configure Device A:
# Create VLAN 10, and assign the port GigabitEthernet 1/0/4 to VLAN 10.
<DeviceA> system-view
[DeviceA] vlan 10
[DeviceA-vlan10] port gigabitethernet 1/0/4
[DeviceA-vlan10] quit
# Create VLAN 20, and assign the port GigabitEthernet 1/0/5 to VLAN 20.
[DeviceA] vlan 20
[DeviceA-vlan20] port gigabitethernet 1/0/5
[DeviceA-vlan20] quit
# Create Layer 2 aggregate interface Bridge-Aggregation 1, and set the link aggregation mode to dynamic.
[DeviceA] interface bridge-aggregation 1
[DeviceA-Bridge-Aggregation1] link-aggregation mode dynamic
[DeviceA-Bridge-Aggregation1] quit
# Assign ports GigabitEthernet 1/0/1 through GigabitEthernet 1/0/3 to link aggregation group 1.
[DeviceA] interface gigabitethernet 1/0/1
[DeviceA-GigabitEthernet1/0/1] port link-aggregation group 1
[DeviceA-GigabitEthernet1/0/1] quit
[DeviceA] interface gigabitethernet 1/0/2
[DeviceA-GigabitEthernet1/0/2] port link-aggregation group 1
[DeviceA-GigabitEthernet1/0/2] quit
[DeviceA] interface gigabitethernet 1/0/3
[DeviceA-GigabitEthernet1/0/3] port link-aggregation group 1
[DeviceA-GigabitEthernet1/0/3] quit
# Configure Layer 2 aggregate interface Bridge-Aggregation 1 as a trunk port and assign it to VLANs 10 and 20.
[DeviceA] interface bridge-aggregation 1
[DeviceA-Bridge-Aggregation1] port link-type trunk
[DeviceA-Bridge-Aggregation1] port trunk permit vlan 10 20
[DeviceA-Bridge-Aggregation1] quit
2. Configure Device B in the same way Device A is configured. (Details not shown.)
Verifying the configuration
# Display detailed information about all aggregation groups on Device A.
[DeviceA] display link-aggregation verbose
Loadsharing Type: Shar -- Loadsharing, NonS -- Non-Loadsharing
Port Status: S -- Selected, U -- Unselected, I -- Individual
Port: A -- Auto port, M -- Management port, R -- Reference port
Flags: A -- LACP_Activity, B -- LACP_Timeout, C -- Aggregation,
D -- Synchronization, E -- Collecting, F -- Distributing,
G -- Defaulted, H -- Expired
Aggregate Interface: Bridge-Aggregation1
Creation Mode: Manual
Aggregation Mode: Dynamic
Loadsharing Type: Shar
Management VLANs: None
System ID: 0x8000, 000f-e267-6c6a
Local:
Port Status Priority Index Oper-Key Flag
GE1/0/1(R) S 32768 11 1 {ACDEF}
GE1/0/2 S 32768 12 1 {ACDEF}
GE1/0/3 S 32768 13 1 {ACDEF}
Remote:
Actor Priority Index Oper-Key SystemID Flag
GE1/0/1 32768 81 1 0x8000, 000f-e267-57ad {ACDEF}
GE1/0/2 32768 82 1 0x8000, 000f-e267-57ad {ACDEF}
GE1/0/3 32768 83 1 0x8000, 000f-e267-57ad {ACDEF}
The output shows that link aggregation group 1 is a Layer 2 dynamic aggregation group that contains three Selected ports.
Example: Configuring a Layer 2 edge aggregate interface
Network configuration
As shown in Figure 9, a Layer 2 dynamic aggregation group is configured on the device. The server is not configured with dynamic link aggregation.
Configure an edge aggregate interface so that both GigabitEthernet 1/0/1 and GigabitEthernet 1/0/2 can forward traffic to improve link reliability.
Procedure
# Create Layer 2 aggregate interface Bridge-Aggregation 1, and set the link aggregation mode to dynamic.
<Device> system-view
[Device] interface bridge-aggregation 1
[Device-Bridge-Aggregation1] link-aggregation mode dynamic
# Configure Layer 2 aggregate interface Bridge-Aggregation 1 as an edge aggregate interface.
[Device-Bridge-Aggregation1] lacp edge-port
[Device-Bridge-Aggregation1] quit
# Assign ports GigabitEthernet 1/0/1 and GigabitEthernet 1/0/2 to link aggregation group 1.
[Device] interface gigabitethernet 1/0/1
[Device-GigabitEthernet1/0/1] port link-aggregation group 1
[Device-GigabitEthernet1/0/1] quit
[Device] interface gigabitethernet 1/0/2
[Device-GigabitEthernet1/0/2] port link-aggregation group 1
[Device-GigabitEthernet1/0/2] quit
Verifying the configuration
# Display detailed information about all aggregation groups on the device when the server is not configured with dynamic link aggregation.
[Device] display link-aggregation verbose
Loadsharing Type: Shar -- Loadsharing, NonS -- Non-Loadsharing
Port Status: S -- Selected, U -- Unselected, I -- Individual
Port: A -- Auto port, M -- Management port, R -- Reference port
Flags: A -- LACP_Activity, B -- LACP_Timeout, C -- Aggregation,
D -- Synchronization, E -- Collecting, F -- Distributing,
G -- Defaulted, H -- Expired
Aggregate Interface: Bridge-Aggregation1
Creation Mode: Manual
Aggregation Mode: Dynamic
Loadsharing Type: Shar
Management VLANs: None
System ID: 0x8000, 000f-e267-6c6a
Local:
Port Status Priority Index Oper-Key Flag
GE1/0/1 I 32768 11 1 {AG}
GE1/0/2 I 32768 12 1 {AG}
Remote:
Actor Priority Index Oper-Key SystemID Flag
GE1/0/1 32768 81 0 0x8000, 0000-0000-0000 {DEF}
GE1/0/2 32768 82 0 0x8000, 0000-0000-0000 {DEF}
The output shows that GigabitEthernet 1/0/1 and GigabitEthernet 1/0/2 are in Individual state when they do not receive LACPDUs from the server. Both GigabitEthernet 1/0/1 and GigabitEthernet 1/0/2 can forward traffic. When one port fails, its traffic is automatically switched to the other port.
Example: Configuring S-MLAG
Network configuration
As shown in Figure 10, configure Device B, Device C, and Device D as S-MLAG devices to establish a multidevice aggregate link with Device A.
Procedure
1. Configure Device A:
# Create Layer 2 aggregate interface Bridge-Aggregation 10, and set the link aggregation mode to dynamic.
<DeviceA> system-view
[DeviceA] interface bridge-aggregation 10
[DeviceA-Bridge-Aggregation10] link-aggregation mode dynamic
[DeviceA-Bridge-Aggregation10] quit
# Assign GigabitEthernet 1/0/1 through GigabitEthernet 1/0/3 to aggregation group 10.
[DeviceA] interface gigabitethernet 1/0/1
[DeviceA-GigabitEthernet1/0/1] port link-aggregation group 10
[DeviceA-GigabitEthernet1/0/1] quit
[DeviceA] interface gigabitethernet 1/0/2
[DeviceA-GigabitEthernet1/0/2] port link-aggregation group 10
[DeviceA-GigabitEthernet1/0/2] quit
[DeviceA] interface gigabitethernet 1/0/3
[DeviceA-GigabitEthernet1/0/3] port link-aggregation group 10
[DeviceA-GigabitEthernet1/0/3] quit
2. Configure Device B:
# Set the LACP system MAC address to 0001-0001-0001.
<DeviceB> system-view
[DeviceB] lacp system-mac 1-1-1
# Set the LACP system priority to 123.
[DeviceB] lacp system-priority 123
# Set the LACP system number to 1.
[DeviceB] lacp system-number 1
# Create Layer 2 aggregate interface Bridge-Aggregation 2, and set the link aggregation mode to dynamic.
[DeviceB] interface bridge-aggregation 2
[DeviceB-Bridge-Aggregation2] link-aggregation mode dynamic
# Assign Bridge-Aggregation 2 to S-MLAG group 100.
[DeviceB-Bridge-Aggregation2] port s-mlag group 100
# Assign GigabitEthernet 1/0/1 to aggregation group 2.
[DeviceB] interface gigabitethernet 1/0/1
[DeviceB-GigabitEthernet1/0/1] port link-aggregation group 2
[DeviceB-GigabitEthernet1/0/1] quit
3. Configure Device C:
# Set the LACP system MAC address to 0001-0001-0001.
<DeviceC> system-view
[DeviceC] lacp system-mac 1-1-1
# Set the LACP system priority to 123.
[DeviceC] lacp system-priority 123
# Set the LACP system number to 2.
[DeviceC] lacp system-number 2
# Create Layer 2 aggregate interface Bridge-Aggregation 3, and set the link aggregation mode to dynamic.
[DeviceC] interface bridge-aggregation 3
[DeviceC-Bridge-Aggregation3] link-aggregation mode dynamic
# Assign Bridge-Aggregation 3 to S-MLAG group 100.
[DeviceC-Bridge-Aggregation3] port s-mlag group 100
# Assign GigabitEthernet 1/0/1 to aggregation group 3.
[DeviceC] interface gigabitethernet 1/0/1
[DeviceC-GigabitEthernet1/0/1] port link-aggregation group 3
[DeviceC-GigabitEthernet1/0/1] quit
4. Configure Device D:
# Set the LACP system MAC address to 0001-0001-0001.
<DeviceD> system-view
[DeviceD] lacp system-mac 1-1-1
# Set the LACP system priority to 123.
[DeviceD] lacp system-priority 123
# Set the LACP system number to 3.
[DeviceD] lacp system-number 3
# Create Layer 2 aggregate interface Bridge-Aggregation 4, and set the link aggregation mode to dynamic.
[DeviceD] interface bridge-aggregation 4
[DeviceD-Bridge-Aggregation4] link-aggregation mode dynamic
# Assign Bridge-Aggregation 4 to S-MLAG group 100.
[DeviceD-Bridge-Aggregation4] port s-mlag group 100
# Assign GigabitEthernet 1/0/1 to aggregation group 4.
[DeviceD] interface gigabitethernet 1/0/1
[DeviceD-GigabitEthernet1/0/1] port link-aggregation group 4
[DeviceD-GigabitEthernet1/0/1] quit
Verifying the configuration
# Verify that GigabitEthernet 1/0/1 through GigabitEthernet 1/0/3 on Device A are Selected ports.
[DeviceA] display link-aggregation verbose
Loadsharing Type: Shar -- Loadsharing, NonS -- Non-Loadsharing
Port Status: S -- Selected, U -- Unselected, I -- Individual
Port: A -- Auto port, M -- Management port, R -- Reference port
Flags: A -- LACP_Activity, B -- LACP_Timeout, C -- Aggregation,
D -- Synchronization, E -- Collecting, F -- Distributing,
G -- Defaulted, H -- Expired
Aggregate Interface: Bridge-Aggregation10
Creation Mode: Manual
Aggregation Mode: Dynamic
Loadsharing Type: Shar
Management VLANs: None
System ID: 0x8000, 40fa-264f-0100
Local:
Port Status Priority Index Oper-Key Flag
GE1/0/1(R) S 32768 1 1 {ACDEF}
GE1/0/2 S 32768 2 1 {ACDEF}
GE1/0/3 S 32768 3 1 {ACDEF}
Remote:
Actor Priority Index Oper-Key SystemID Flag
GE1/0/1 32768 16385 50100 0x7b , 0001-0001-0001 {ACDEF}
GE1/0/2 32768 32769 50100 0x7b , 0001-0001-0001 {ACDEF}
GE1/0/3 32768 49153 50100 0x7b , 0001-0001-0001 {ACDEF}