Refer to the 7705 SAR OAM and Diagnostics Guide for information about CLI commands and syntax for OAM and diagnostics commands.
This command administratively disables an entity. When disabled, an entity does not change, reset, or remove any configuration settings or statistics.
The operational state of the entity is disabled as well as the operational state of any entities contained within. Many objects must be shut down before they can be deleted.
Services are created in the administratively down (shutdown) state. When a no shutdown command is entered, the service becomes administratively up and then tries to enter the operationally up state. Default administrative states for services and service entities are described below in Special Cases.
The no form of this command places the entity into an administratively enabled state.
This command creates a text description stored in the configuration file for a configuration context.
The description command associates a text string with a configuration context to help identify the content in the configuration file.
The no form of this command removes the string from the configuration.
n/a
This command creates or edits a Virtual Private LAN Services (VPLS) instance. If the service-id does not exist, a context for the service is created. If the service-id exists, the context for editing the service is entered.
A VPLS service connects multiple customer sites together acting like a zero-hop, Layer 2 switched domain. A VPLS is always a logical full mesh.
When a service is created, the create keyword and the customer keyword and customer-id must be specified in order to associate the service with a customer. The customer-id must already exist (created using the customer command in the service context). Once a service has been created with a customer association, it is not possible to edit the customer association. To edit the customer association, the service must be deleted and recreated with a new customer association.
To create a management VPLS, include the m-vpls keyword when creating the VPLS. Associate a range of VLANs with the mVPLS by using the managed-vlan-list command.
Once a service is created, the use of the customer customer-id is optional for navigating into the service configuration context. Attempting to edit a service with the incorrect customer-id specified will result in an error.
More than one VPLS service may be created for a single customer ID.
By default, no VPLS instances exist until they are explicitly created.
The no form of this command deletes the VPLS service instance with the specified service-id. The service cannot be deleted until all SAPs and SDPs defined within the service ID have been shut down and deleted, and the service has been shut down.
This command enables blocking (brings the entity to an operationally down state) after all configured SDPs or endpoints are in operationally down state. This event is signaled to a corresponding T-LDP peer by withdrawing the service label (status-bit-signaling non-capable peer) or by setting the “PW not forwarding” status bit in the T-LDP message (status-bit-signaling capable peer).
disabled
This command disables MAC address aging across a VPLS service or on a VPLS service SAP or spoke SDP.
As is the case for a Layer 2 switch, learned MACs can be aged out if no packets are sourced from the MAC address for a period of time (the aging time). In each VPLS service instance, there are independent aging timers for local learned MAC and remote learned MAC entries in the VPLS forwarding database (FDB). The disable-aging command turns off aging for local and remote learned MAC addresses.
When no disable-aging is specified for a VPLS, it is possible to disable aging for specific SAPs and/ or spoke SDPs by entering the disable-aging command at the appropriate level.
When the disable-aging command is entered at the VPLS level, the disable-aging state of individual SAPs or SDPs will be ignored.
The no form of this command enables aging on the VPLS service.
no disable-aging
This command disables learning of new MAC addresses in the VPLS forwarding database (FDB) for the service instance, SAP instance, or spoke SDP instance.
When disable-learning is enabled, new source MAC addresses will not be entered in the VPLS service forwarding database. This is true for both local and remote MAC addresses.
When disable-learning is disabled, new source MAC addresses will be learned and entered into the VPLS forwarding database.
This parameter is mainly used in conjunction with the discard-unknown command.
The no form of this command enables learning of MAC addresses.
no disable-learning (Normal MAC learning is enabled)
By default, packets with unknown destination MAC addresses are flooded. If discard-unknown is enabled at the VPLS level, packets with an unknown destination MAC address will be dropped instead of being flooded (even when configured FDB size limits for VPLS or SAPs are not yet reached).
The no form of this command allows flooding of packets with unknown destination MAC addresses in the VPLS.
no discard-unknown—packets with unknown destination MAC addresses are flooded
This command configures a service endpoint.
When this command is enabled, the node will ignores the standby bit received from T-LDP peers for the given spoke SDP and performs internal tasks without taking the standby bit into account—traffic can egress out to the spoke SDP.
This command is present at the endpoint level as well as at the spoke SDP level. If the spoke SDP is part of the explicit endpoint, it is not possible to change this setting at the spoke SDP level. The existing spoke SDP will become part of the explicit endpoint only if the setting is not conflicting. The newly created spoke SDP that is a part of the given explicit endpoint will inherit this setting from the endpoint configuration.
enabled
This command configures the time to wait before reverting to the primary spoke SDP.
For a regular endpoint, the revert-time setting affects only the pseudowire defined as “primary” (precedence 0). If the primary pseudowire fails and is then restored, the revert timer is started. After the revert timer expires, the primary pseudowire takes the active role in the endpoint. This behavior does not apply if both pseudowires are defined as “secondary”. For example, if the active secondary pseudowire fails and is restored, it will stay in standby until a configuration change or a force command occurs.
This command assigns a static MAC address to the endpoint. In the FDB, the static MAC address is then associated with the active spoke SDP.
n/a
When this command is enabled, the pseudowire standby bit (value 0x00000020) will not be sent to the T-LDP peer when the given spoke SDP is selected as a standby. This allows faster switchover because the traffic will be sent over this SDP and discarded at the blocking side of the connection. This is particularly applicable to multicast traffic.
enabled
This command enables PIM snooping for the VPLS service. When enabled, it is enabled for all SAPs except default SAPs. A default SAP is a SAP that has a wildcard VLAN ID, such as sap 1/1/1:*.
The no form of the command disables PIM snooping and removes the PIM snooping configuration.
This command identifies one or more route policies for multicast groups applied to this VPLS entity. The sources of the multicast traffic must be members of the VPLS.
Routing policies are configured in the config>router>policy-options context. The router policy must be defined before it can be imported. The grp-policy-name variable is the same as the name variable in the policy-options>policy-statement name command.
For details on route policies, refer to the “Route Policies” section in the 7705 SAR Router Configuration Guide.
The no form of the command removes the policy association from the VPLS configuration.
n/a
This command configures the length of time during which the PIM snooping switch snoops all the PIM states in the VPLS. During the hold-time, multicast traffic is flooded in the VPLS. At the end of the hold-time, multicast traffic is forwarded using the snooped states. The snooped state consists of the forwarding state for the (S,G) and (*,G) groups, the incoming interface, and the outgoing interfaces.
When PIM snooping is enabled in VPLS, there is a period of time when the PIM snooping switch may not have built the complete snooping state. The switch cannot build states until the routers connected to the VPLS refresh their PIM messages.
This parameter is applicable only when PIM snooping is enabled.
This command disables PIM snooping for IPv4 multicast traffic within a VPLS service. By default, IPv4 multicast traffic is enabled.
The no form of the command enables PIM snooping for IPv4 multicast traffic within a VPLS service. To fully remove PIM snooping from a VPLS service, the no pim-snooping command must be used.
enabled (no ipv4-multicast-disable)
This command disables PIM snooping for IPv6 multicast traffic within a VPLS service. By default, IPv6 multicast traffic is disabled.
The no form of the command enables PIM snooping for IPv6 multicast traffic within a VPLS service. To fully remove PIM snooping from a VPLS service, the no pim-snooping command must be used.
disabled (ipv6-multicast-disable)
This command sets the PIM snooping mode to proxy or plain snooping.
When enabled, this command appends Agent-Circuit-Id information to PADI and PADR packets received from an ATM SAP (the subscriber) that is bound to a VPLS instance. The Agent-Circuit-Id information is compliant with RFC 4679 section-3.3.1; Agent-Circuit-Id. The ATM SAP must be configured for bridged llc-snap encapsulation.
The pppoe-circuit-id command can be enabled or disabled for a VPLS instance or an individual ATM SAP. When applied to a VPLS instance, pppoe-circuit-id appends the Agent-Circuit-Id to all ATM SAPs bound to that VPLS instance. Furthermore, pppoe-circuit-id can be applied to individual SAPs bound to that VPLS instance in order to override the VPLS setting. If there is a mix of enabled and disabled SAPs bound to the VPLS instance, applying the command to the VPLS will override the mix, enabling (or disabling) pppoe-circuit-id on all the SAPs.
In addition, any newly created SAPs bound to the VPLS will default to match the VPLS setting.
As per the DSL Forum TR-101 April'06 specification, section 3.9.2, any PPPoE vendor-specific tag that may already be present in the received frame is replaced by the 7705 SAR client-id tag.
The no version of this command disables appending the Agent-Circuit-Id information.
disabled
This command enables the propagation of mac-flush messages received from the given T-LDP on all spoke and mesh SDPs within the context of the VPLS service. The propagation conforms to split-horizon principles and any datapath blocking in order to avoid looping of these messages.
disabled
This command specifies the upper threshold value for FDB entries. The high-water-mark is configured as a percentage of the FDB. When the number of FDB entries exceeds the high-water-mark, the system raises a log event.
This command specifies the lower threshold value for FDB entries. The low-water-mark is configured as a percentage of the FDB. When the number of FDB entries drops below the low-water-mark, the system raises a log event.
This command specifies the maximum number of MAC entries in the FDB for the VPLS instance on this node.
The fdb-table-size specifies the maximum number of FDB entries for both learned and static MAC addresses for the VPLS instance.
The no form of this command returns the maximum FDB table size to the default.
250
This command accesses the context to configure load balancing.
This command enables or disables Layer 4 load balancing for the VPLS instance. When enabled, Layer 4 source and destination port fields of incoming TCP/UDP packets are included in the hashing calculation to randomly determine the distribution of packets.
Adding the Layer 4 source and destination port fields to the hashing algorithm generates a higher degree of randomness and a more even distribution of packets across the available LAG ports.
You can add additional fields to generate more randomness and more equal distribution of packets with the teid-load-balancing command.
Hashing based on the l4-load-balancing and teid-load-balancing commands and hashing based on the per-service-hashing command are mutually exclusive.
The no form of the command disables Layer 4 load balancing.
no l4-load-balancing
This command enables or disables hashing based on the service ID. The result of the hashing calculation is used to determine the distribution of packets.
Hashing based on the per-service-hashing command and hashing based on the l4-load-balancing and teid-load-balancing commands are mutually exclusive.
Note: Starting with Release 8.0.R4, unless per-service-hashing is enabled, a 4-byte hash value will be appended to internal overhead for VPLS multicast traffic at ingress. The egress internal hash value is discarded at egress before scheduling. Therefore, shaping rates at access and network ingress and for fabric policies may need to be adjusted accordingly. In addition, the 4-byte internal hash value may be included in any affected statistics counters. |
The no form of the command disables per-service hashing.
no per-service-hashing
This command enables or disables TEID load balancing for the VPLS instance. The TEID attribute is included in the header of GTP (general packet radio system tunneling protocol) packets. When TEID load balancing is enabled, the TEID field of incoming TCP/UDP packets is included in the hashing calculation to randomly determine the distribution of packets.
You can add additional fields to generate more randomness and more equal distribution of packets with the l4-load-balancing command.
Hashing based on the teid-load-balancing and l4-load-balancing commands and hashing based on the per-service-hashing command are mutually exclusive.
The no form of the command disables TEID load balancing.
no teid-load-balancing
This command specifies the aging time for locally learned MAC addresses in the FDB for the VPLS instance. In a VPLS service, MAC addresses are associated with a SAP or SDP. MACs associated with a SAP are classified as local MACs, and MACs associated with an SDP are remote MACs.
As is the case for a Layer 2 switch, learned MACs can be aged out if no packets are sourced from the MAC address for a period of time (the aging time). In each VPLS service instance, there are independent aging timers for locally learned MAC and remotely learned MAC entries in the FDB. The local-age timer specifies the aging time for locally learned MAC addresses.
The no form of this command returns the local aging timer to the default value.
300
This command enables the context to configure MAC move attributes. A sustained, high relearn rate can be a sign of a loop somewhere in the VPLS topology. Typically, the spanning tree protocol (STP) detects loops in the topology, but for those networks that do not run STP, the mac-move feature is an alternative way to protect the network against loops.
When enabled in a VPLS, mac-move monitors the relearn rate of each MAC. If the rate exceeds the configured maximum allowed limit, it disables the SAP where the source MAC was last seen. The SAP can be disabled permanently (until a shutdown/no shutdown command is executed) or for a length of time that increases linearly with the number of times the given SAP was disabled. A SAP can be configures as non-blockable with the limit-mac-move command. This means that when the relearn rate has exceeded the limit, another (blockable) SAP will be disabled instead. By default, all SAPs and spoke SDPs are configured as blockable when MAC-move is enabled.
When MAC-move is enabled and the relearn rate exceeds the maximum limit, the 7705 SAR sends a “Mac move rate for MAC ... exceeded” alarm. This alarm is raised for both blockable and non-blockable SAPs and spoke SDPs. The alarm frequency for non-blockable SAPs and spoke SDPs decreases if the MAC-move condition persists.
The mac-move command enables the feature at the service level for SAPs and spoke SDPs, as only those objects can be blocked by this feature. Mesh SDPs are never blocked, but their relearn rates (SAP-to-mesh/spoke-to-mesh or vice versa) are still measured.
The operation of this feature is the same on the SAP and spoke SDP. For example, if a MAC address moves from SAP to SAP, from SAP to spoke SDP, or between spoke SDPs, one will be blocked to prevent thrashing. If the MAC address moves between a SAP and mesh SDP or spoke SDP and mesh SDP combinations, the respective SAP or spoke SDP will be blocked.
The mac-move command will disable a VPLS port when the number of relearns detected has reached the number of relearns needed to reach the move frequency in the 5-s interval. For example, when the move frequency is configured to 1 (1 relearn per second), mac-move will disable one of the VPLS ports when 5 relearns were detected during the 5-s interval because the average move frequency of 1 relearn per second has been reached. This can also occur in the first second if the relearn rate is 5 relearns per second or higher.
The no form of this command disables MAC move.
This command specifies the number of bits to be considered when performing MAC learning (MAC source) and MAC switching (MAC destination). Specifically, this value identifies how many bits are used, starting from the beginning of the MAC address. For example, if the mask value of 28 is used, MAC learning will only do a lookup for the first 28 bits of the source MAC address when comparing it with existing FDB entries. Then, it will install the first 28 bits in the FDB while zeroing out the last 20 bits of the MAC address. When performing switching in the reverse direction, only the first 28 bits of the destination MAC address will be used to perform an FDB lookup to determine the next hop.
The no form of this command switches back to full MAC lookup.
This command indicates the maximum rate at which MACs can be relearned in the VPLS service before the SAP where the moving MAC was last seen is automatically disabled in order to protect the system against undetected loops or duplicate MACs.
The no form of the command reverts to the default value
2 (when mac-move is enabled); for example, 10 relearns in a 5-s period.
This command configures the number of times that retries are performed for re-enabling the SAP or SDP bindings.
This command enables the context to define primary VPLS ports. VPLS ports that were declared as secondary prior to the execution of this command will be moved from secondary port level to primary port level. Changing a port to the tertiary level (default) can only be done by first removing it from the secondary port level.
This command configures a factor for the primary or secondary ports that defines how many MAC relearn periods should be used to measure the MAC relearn rate. The rate must be exceeded during consecutive periods before the corresponding ports (SAP and/or spoke SDP) are blocked by the mac-move feature.
This command configures the specified SAP to be a primary or secondary VPLS port.
This command configures the specified spoke SDP to be a primary or secondary VPLS port.
This command enables the context to define secondary VPLS ports. VPLS ports that were declared as primary prior to the execution of this command will be moved from the primary port level to the secondary port level. Changing a port to the tertiary level (default) can only be done by first removing it from the primary port level.
This command indicates the time, in seconds, to wait before a SAP that has been disabled after exceeding the maximum relearn rate is re-enabled.
It is recommended that the timeout value be equal to or larger than 5 s × cumulative factor of the highest-priority port so that the sequential order of port blocking will not be disturbed by reinitializing lower-priority ports.
A zero value indicates that the SAP will not automatically be re-enabled after being disabled. If, after the SAP is re-enabled it is disabled again, the effective retry timeout is doubled in order to avoid thrashing.
The no form of the command reverts to the default value.
10 (when mac-move is enabled)
This command specifies the aging time for remotely learned MAC addresses in the FDB for the VPLS instance. In a VPLS service, MAC addresses are associated with a SAP or an SDP. MACs associated with a SAP are classified as local MACs, and MACs associated with an SDP are remote MACs.
As is the case for a Layer 2 switch, learned MACs can be aged out if no packets are sourced from the MAC address for a period of time (the aging time). In each VPLS service instance, there are independent aging timers for locally learned MAC and remotely learned MAC entries in the FDB. The remote-age timer specifies the aging time for remotely learned MAC addresses. To reduce the amount of signaling required between switches, configure this timer to be larger than the local-age timer.
The no form of this command returns the remote aging timer to the default value.
900
This command enables sending out “flush-all-from-ME” messages to all LDP peers included in the affected VPLS, in the event of physical port failures or “oper-down” events of individual SAPs. This feature provides an LDP-based mechanism for recovering a physical link failure in a dual-homed connection to a VPLS service. This method provides an alternative to Rapid Spanning Tree Protocol (RSTP) solutions where dual homing redundancy and recovery, in the case of link failure, is resolved by RSTP running between a PE router and CE devices. If the endpoint is configured within the VPLS and send-flush-on-failure is enabled, “flush-all-from-ME” messages will be sent out only when all spoke SDPs associated with the endpoint go down.
no send-flush-on-failure
This command configures the service payload Maximum Transmission Unit (MTU), in bytes, for the service. This MTU value overrides the service-type default MTU. The service-mtu defines the payload capabilities of the service. It is used by the system to validate the SAP and SDP bindings’ operational state within the service.
The service MTU and a SAP’s service delineation encapsulation overhead (that is, 4 bytes for a dot1q tag or 8 bytes for a qinq tag) are used to derive the required MTU of the physical port or channel on which the SAP was created. If the required payload is larger than the port or channel MTU, the SAP will be placed in an inoperative state. If the required MTU is equal to or less than the port or channel MTU, the SAP will be able to transition to the operative state.
When binding an SDP to a service, the service MTU is compared to the path MTU associated with the SDP. The path MTU can be administratively defined in the context of the SDP. The default or administrative path MTU can be dynamically reduced due to the MTU capabilities discovered by the tunneling mechanism of the SDP or the egress interface MTU capabilities based on the next hop in the tunnel path. If the service MTU is larger than the path MTU, the SDP binding for the service will be placed in an inoperative state. If the service MTU is equal to or less than the path MTU, then the SDP binding will be placed in an operational state.
If a service MTU, port or channel MTU, or path MTU is dynamically or administratively modified, then all associated SAP and SDP binding operational states are automatically re-evaluated.
The no form of this command returns the default service-mtu for the indicated service type to the default value.
VPLS: 1514
Table 59 shows MTU values for specific VC types.
VC-Type Example | Service MTU | Advertised MTU |
Ethernet | 1514 | 1500 |
Ethernet (with preserved dot1q) | 1518 | 1504 |
Ethernet (with preserved qinq) | 1522 | 1508 |
VPLS | 1514 | 1500 |
VPLS (with preserved dot1q) | 1518 | 1504 |
VPLS (with preserved qinq) | 1522 | 1508 |
VLAN (dot1p transparent to MTU value) | 1514 | 1500 |
This command configures a service name that can be used in other configuration commands and show commands that reference the service.
This command creates a new split horizon group (SHG) for the VPLS instance. Traffic arriving on a SAP or spoke SDP within this split horizon group will not be copied to other SAPs or spoke SDPs in the same split horizon group. If the residential-group keyword is included, the split horizon group is a residential SHG.
A split horizon group must be created before SAPs and spoke SDPs can be assigned to the group. The split horizon group is defined within the context of a single VPLS. The same group-name can be reused in different VPLS instances.
An ATM SAP must be in a residential SHGs. If an Ethernet SAP is in a SHG, then that SHG cannot be a residential SHG.
Up to 30 split horizon groups can be defined per VPLS instance.
The no form of the command removes the group name from the configuration.
This command creates a Service Access Point (SAP) within a service. A SAP is a combination of port and encapsulation parameters that identify the service access point on the interface and within the 7705 SAR. Each SAP must be unique. All SAPs must be explicitly created. If no SAPs are created within a service or on an IP interface, a SAP will not exist on that object.
Enter an existing SAP without the create keyword to edit SAP parameters. The SAP is owned by the service in which it was created.
A SAP can only be associated with a single service. A SAP can only be defined on a port that has been configured as an access port using the config interface port-type port-id mode access command. Channelized TDM ports are always access ports.
If a port is shut down, all SAPs on that port become operationally down. When a service is shut down, SAPs for the service are not displayed as operationally down although all traffic traversing the service will be discarded. The operational state of a SAP is relative to the operational state of the port on which the SAP is defined.
The no form of this command deletes the SAP with the specified port. When a SAP is deleted, all configuration parameters for the SAP will also be deleted. For Internet Enhanced Service (IES), the IP interface must be shut down before the SAP on that interface may be removed.
n/a
This command specifies that packets received on a SAP or a spoke SDP with an unknown source MAC address will be dropped only if the maximum number of MAC addresses for that SAP or spoke SDP (see max-nbr-mac-addr) has been reached. If max-nbr-mac-addr has not been set for the SAP or spoke SDP, enabling discard-unknown-source has no effect.
When disabled, the packets are forwarded based on the destination MAC addresses.
The no form of this command causes packets with an unknown source MAC addresses to be forwarded by destination MAC addresses in VPLS.
no discard-unknown-source
This command indicates whether the MAC move agent, when enabled using mac-move, will limit the MAC relearn (move) rate on this SAP.
blockable
This command disables relearning of MAC addresses on other SAPs or SDPs within the VPLS. The MAC address will remain attached to a given SAP or SDP for the duration of its age timer.
The age of the MAC address entry in the FDB is set by the age timer. If mac-aging is disabled on a given VPLS service, any MAC address learned on a SAP or SDP with mac-pinning enabled will remain in the FDB on this SAP or SDP forever. Every event that would otherwise result in relearning will be logged (MAC address; original SAP; new SAP).
MAC addresses learned during DHCP address assignment (DHCP snooping enabled) are not impacted by this command. MAC pinning for such addresses is implicit.
disabled, except enabled at the creation of the SAP or spoke SDP that is part of a residential split horizon group (RSHG)
This command specifies the maximum number of FDB entries for both learned and static MAC addresses for this SAP, spoke SDP, or endpoint.
When the configured limit has been reached, and discard-unknown-source has been enabled for this SAP or spoke SDP (see discard-unknown-source), packets with unknown source MAC addresses will be discarded.
The no form of the command restores the global MAC learning limitations for the SAP or spoke SDP.
no max-nbr-mac-addr
This command creates a local static MAC entry in the VPLS FDB associated with the SAP.
In a VPLS service, MAC addresses are associated with a SAP or an SDP. MACs associated with a SAP are classified as local MACs, and MACs associated with an SDP are remote MACs.
Local static MAC entries create a permanent MAC address-to-SAP association in the FDB for the VPLS instance so that the MAC address will not be learned on the edge device.
Static MAC definitions on one edge device are not propagated to other edge devices participating in the VPLS instance; that is, each edge device has an independent FDB for the VPLS.
Only one static MAC entry (local or remote) can be defined per MAC address per VPLS instance.
By default, no static MAC address entries are defined for the SAP.
The no form of this command deletes the static MAC entry with the specified MAC address associated with the SAP from the VPLS FDB.
This command enables access to the context to configure ATM-related attributes. This command can only be used when a given context (for example, a channel or SAP) supports ATM functionality such as:
If ATM functionality is not supported for a given context, the command returns an error.
This command enables the context to configure egress ATM attributes for the SAP.
This command assigns an ATM traffic descriptor profile to a given context (for example, a SAP).
When configured under the egress context, the specified traffic descriptor profile defines the traffic contract in the backwards direction.
The no form of the command reverts to the default traffic descriptor profile.
The default traffic descriptor (trafficDescProfileId. = 1) is associated with newly created PVCC-delimited SAPs
This command specifies the data encapsulation for an ATM PVCC-delimited SAP. The definition references RFC 2684, Multiprotocol Encapsulation over ATM AAL5, and the ATM Forum LAN Emulation specification.
Ingress traffic that does not match the configured encapsulation will be dropped.
The encapsulation is driven by the service for which the SAP is configured.
For VPLS SAPs, the default and only option is aal5snap-bridged.
This command enables the context to configure OAM functionality for a PVCC delimiting a SAP. The ATM-capable adapter cards support the following F5 end-to-end OAM functionality (AIS, RDI, loopback):
This command configures AIS/RDI fault management on a PVCC. Fault management allows PVCC termination to monitor and report the status of its connection by propagating fault information through the network and by driving a PVCC operational status.
When alarm-cells functionality is enabled, a PVCC operational status is affected when a PVCC goes into an AIS or RDI state because of AIS/RDI processing. This assumes that nothing else affects the PVCC operational status; for example, the PVCC goes down, or enters a fault state and comes back up, or exits that fault state. RDI cells are generated when a PVCC is operationally down. No OAM-specific SNMP trap is raised whenever an endpoint enters or exits an AIS or RDI state; however, if an OAM state change results in a change to the operational status of the PVCC, then a trap is expected from an entity that the PVCC is associated with (for example, a SAP).
The no form of the command disables alarm-cells functionality for a PVCC. When alarm-cells functionality is disabled, the PVCC operational status is no longer affected by the PVCC OAM state changes due to AIS/RDI processing. When alarm-cells is disabled, a PVCC will change operational status to up from down due to alarm-cell processing. RDI cells are not generated as result of PVCC going into an AIS or RDI state; however, the PVCC OAM status will record OAM faults as described above.
enabled for PVCCs delimiting VPLS SAPs
This command enables the push operation of a configured VLAN at ingress and a pop operation at egress on a per-ATM SAP basis. After AAL5 termination at ATM access ingress as per the configured encapsulation type, the configured VLAN tag is pushed to the received subscriber frame. The type of Ethernet frame is set to 0x8100 in order to designate the existence of the VLAN header, and the original Ethertype is shifted by 4 bytes (dot1q) or 8 bytes (qinq), enlarging the resulting subscriber frame by 4 or 8 bytes.
Using the subscriber-vlan command necessitates the use of the tagged (dot1q or qinq) uplink. In the uplink ingress direction (from the network to the 7705 SAR), the 7705 SAR is programmed to pop the VLAN tags. The first pop operation is mandatory, but if the frame is a single-tagged frame and there are no other VLAN tags, then the resulting untagged frame is forwarded to the subscriber interface without any errors.
no subscriber-vlan
This command enables the Internet Group Management Protocol (IGMP) snooping context.
This command enables the Multicast Listener Discovery (MLD) snooping context.
This command enables or disables router alert checking for IGMP or MLD messages received on this interface. The router alert field in the IP header is used to inform the router to extract the packet. By default, router alert checks are enabled for IGMP and MLD packets (that is, no disable).
The no form of the command enables the router alert check.
no disable-router-alert-check
This command enables fast leave. When IGMP or MLD fast-leave processing is enabled, the 7705 SAR immediately removes a SAP or SDP from the multicast group when it detects an IGMP or MLD leave message on that SAP or SDP. Fast-leave processing allows the 7705 SAR to remove from the forwarding table a SAP or SDP that has sent a leave message without first sending group-specific queries to the SAP or SDP. This speeds up the process of changing channels (called zapping).
Fast leave should only be enabled when there is a single receiver present on the SAP or SDP. When fast leave is enabled, the configured last-member-query-interval value is ignored.
no fast-leave
This command specifies the import routing policy used to filter IGMP or MLD packets on this SAP or SDP. Only a single policy can be imported on a single SAP or SDP at any time.
The no form of the command removes the policy association from the SAP or SDP.
no import
This command configures the maximum response time used in group-specific queries that are sent by the router acting as the querier in response to leave messages, and is also the amount of time between two consecutive group-specific queries. This value may be tuned to modify the leave latency of the network. A reduced value results in reduced time to detect the loss of the last member of a group. The configured last-member-query-interval is ignored when fast-leave is enabled on the SAP or SDP.
10
This command defines the maximum number of multicast groups that can be joined on this SAP or SDP. If the node receives an IGMP, MLD, or PIM join message that would exceed the configured number of groups, the request is ignored. The max-num-groups command does not apply to mesh SDPs.
The no form of this command disables the check.
no max-num-groups
This command defines the maximum number of multicast (S,G)s that can be joined on this SAP or SDP. If the node receives an IGMP join message that would exceed the configured number of (S,G)s, the request is ignored.
The no form of this command disables the check.
no max-num-grp-sources
This command defines the maximum number of multicast sources that can be joined on this SAP or SDP. If the node receives an IGMP join message that would exceed the configured number of sources, the request is ignored.
The no form of this command disables the check.
no max-num-sources
This command specifies whether a multicast router is attached behind this SAP or SDP.
Configuring a SAP as an mrouter-port has two effects. First, all multicast traffic received on another SAP or SDP is copied to this SAP or SDP. Second, IGMP or MLD reports generated by the system as a result of a host joining or leaving a multicast group are sent to this SAP or SDP.
If two multicast routers exist in the network, one of them becomes the active querier and the other one (the non-querier) stops sending IGMP queries. The non-querier router continues to receive reports in order to keep its multicast trees up to date. To support this, enable mrouter-port on all SAPs or SDPs connected to a multicast router.
The version used for the reports (IGMPv1, v2, or v3, or MLDv1 or v2) can only be determined after an initial query has been received. Until the version is determined, no reports are sent on the SAP or spoke SDP, even if mrouter-port is enabled.
If the send-queries command is enabled on this SAP or spoke SDP, the mrouter-port command cannot be enabled. The mrouter-port and send-queries commands are mutually exclusive.
no mrouter-port
This command configures the IGMP or MLD query interval. If the send-queries command is enabled, this command specifies the interval between two consecutive general queries sent by the router acting as the querier on this SAP or SDP. The configured query-interval must be greater than the configured query-response-interval.
If send-queries is not enabled on this SAP or SDP, the configured query-interval value is ignored.
125
1 to 65535 | (at the VPLS level) |
2 to 1024 | (at the VPLS SAP or SDP level) |
This command configures the IGMP or MLD query response interval. If the send-queries command is enabled, this command specifies how long the router acting as the querier waits to receive a response from the host. The configured query-response-interval must be smaller than the configured query-interval. If send-queries is not enabled on this SAP or SDP, the configured query-response-interval value is ignored.
10
This command configures the IP source address used in IGMP or MLD queries.
This command specifies the source IP address used when generating IGMP or MLD reports. According to the IGMPv3 standard, a zero source address is allowed when sending IGMP reports. However, for interoperability with some multicast routers, the source IP address of IGMP group reports can be configured using this command.
0.0.0.0
This command allows tuning for the expected packet loss on a SAP or an SDP, and is comparable to a retry count. For a SAP or SDP, this command is functional when the send-queries command is enabled. If the send-queries command is not enabled, robust-count is ignored. If the SAP or SDP is expected to experience packet loss, the robust-count parameter may be increased. IGMP or MLD snooping on this SAP or SDP is robust up to the robust-count minus 1 packet.
2
For VPLS: | 1 to 255 |
For SAP or SDP: | 2 to 7 |
This command specifies whether to send IGMP or MLD general query messages on the SAP or SDP.
When send-queries is configured, all query reports generated locally are of the type belonging to the configured version. If a report from a version higher than the configured version is received, the report is dropped and a “wrong version” counter is incremented. If send-queries is not configured, the version command has no effect and the version used is the version of the querier. This implies that, for example, when there is a version 2 querier, a specific version 3 group or group-source query is never sent when a host wants to leave a group.
no send-queries
This command enables access to the context to configure static group addresses. Static group addresses can be configured on a SAP or SDP. When present as either a (*,G) or a (S,G) entry, multicast packets matching the configuration are forwarded even if no join message was registered for the specific group.
n/a
This command adds a static multicast group either as a (*,G) or as one or more (S,G) records. When a static IGMP or MLD group is added, multicast data for that (*,G) or (S,G) is forwarded to the specific SAP or SDP without receiving any membership report from a host.
The group is not created until the source or starg is specified.
n/a
This command adds a static (S,G) entry, to allow multicast traffic for a multicast group from a specified source. For a multicast group, more than one source address can be specified. Static (S,G) entries cannot be added if a starg has been created previously.
The no form of the command removes the source from the configuration.
n/a
This command adds a static (*,G) entry to allow multicast traffic for the corresponding multicast group from any source. This command can only be enabled if there are no existing source addresses for this group.
The no form of the command removes the starg entry from the configuration.
no starg
This command specifies the version of IGMP or MLD that is running on this SAP or SDP. This command can be used to configure a router capable of running IGMP version 1, 2, or 3, or MLD version 1 or 2. For IGMP or MLD to function correctly, all routers on a LAN must be configured to run the same version of IGMP or MLD on that LAN.
When the send-queries command is configured, all query reports generated locally are of the type belonging to the configured version. If a report from a version higher than the configured version is received, the report gets dropped and a “wrong version” counter is incremented.
If the send-queries command is not configured, the version command has no effect. The version used on that SAP or SDP is the version of the querier. This implies that, for example, when there is an IGMP version 2 querier, a specific version 3 group or group-source query is never sent when a host wants to leave a group.
The no form of the command returns the version to the default value.
3 (IGMP) 2 (MLD)
This command enables the context to configure the Spanning Tree Protocol (STP) parameters. The 7705 SAR runs the RSTP version of STP. The Nokia implementation of STP is simply the Spanning Tree Protocol (STP) with a few modifications to better suit the operational characteristics of VPLS services. The most evident change is to the root bridge election. Since the core network operating between Nokia service routers should not be blocked, the root path is calculated from the core perspective.
This command configures the Spanning Tree Protocol (STP) hello time for the Virtual Private LAN Service (VPLS) STP instance.
The hello-time command defines the default timer value that controls the sending interval between BPDU configuration messages by this bridge, on ports where this bridge assumes the designated role.
Since VPLS on the 7705 SAR runs in RSTP mode, the hello time is always taken from the locally configured parameter, unless RSTP fails and the SAP falls back to legacy STP operation, in which case the hello time for the spanning tree is determined by the root bridge.
The no form of this command returns the hello time to the default value.
2 s
This command configures the peak number of BPDUs that can be transmitted in a period of 1 s.
The no form of this command returns the hold count to the default value.
6
This command specifies the version of Spanning Tree Protocol the bridge is currently running. VPLS on the 7705 SAR runs only in RSTP mode.
The no form of this command returns the STP variant to the default mode.
rstp
The priority command is used to populate the priority portion of the bridge ID field within outbound BPDUs (the most significant 4 bits of the bridge ID). It is also used as part of the decision process when determining the best BPDU between messages received and sent. All values will be truncated to multiples of 4096, conforming with IEEE 802.1t and 802.1D-2004.
The no form of this command returns the bridge priority to the default value.
By default, the bridge priority is configured to 4096, which is the highest priority
This command enables the context to configure VLAN ranges to be managed by a management VPLS. The list indicates, for each SAP, the ranges of associated VLANs that will be affected when the SAP changes state.
This command is only valid when the VPLS in which it is entered was created as a management VPLS.
This command configures a range of VLANs on an access port that are to be managed by an existing management VPLS.
This command is only valid when the VPLS in which it is entered was created as a management VPLS, and when the SAP in which it was entered was created on an Ethernet port with encapsulation type of dot1q or qinq.
To modify the range of VLANs, first the new range should be entered and then the old range removed. See Modifying VPLS Service Parameters.
n/a
This command configures automatic detection of the edge port characteristics of the SAP or spoke SDP.
If auto-edge is enabled and STP concludes there is no bridge behind the SAP or spoke SDP, the OPER_EDGE variable will dynamically be set to true. If auto-edge is enabled and a BPDU is received, the OPER_EDGE variable will dynamically be set to false (see edge-port).
The no form of this command removes automatic edge detection.
auto-edge
This command configures the SAP or spoke SDP as an edge or non-edge port. If auto-edge is enabled for the SAP or spoke SDP, this value of the edge/non-edge setting will be used only as the initial value.
The function of the edge-port command is to tell STP that it is on the edge of the network (for example, there are no other bridges connected to that port), and, as a consequence, it can immediately transition to a forwarding state if the port becomes available.
STP, however, can detect that the actual situation is different from what edge-port may indicate.
Initially, the value of the SAP or spoke SDP parameter is set to edge-port. This value will change if:
The no form of this command returns the edge port setting to the default value.
no edge-port
This command instructs STP on the maximum number of bridges behind the SAP or spoke SDP. If there is only a single bridge, transitioning to the forwarding state will be based on handshaking (fast transitions). If two or more bridges are connected via a shared media, their SAPs or spoke SDPs should be configured as shared, and timer-based transitions are used.
The no form of this command returns the link type to the default value.
pt-pt
This command configures the STP path cost for the SAP or spoke SDP.
The path cost is used by STP to calculate the path cost to the root bridge. The path cost in BPDUs received on the root port is incremented with the configured path cost for that SAP or spoke SDP. When BPDUs are sent out other egress SAP or spoke SDP, the newly calculated root path cost is used.
STP suggests that the path cost is defined as a function of the link bandwidth. Since SAPs and spoke SDPs are controlled by complex queuing dynamics, in the 7705 SAR the STP path cost is a purely static configuration.
The no form of this command returns the path cost to the default value.
10
This command configures the virtual port number that uniquely identifies a SAP or spoke SDP within configuration BPDUs. The internal representation of a SAP or spoke SDP is unique to a system and has a reference space much larger than the 12 bits definable in a configuration BPDU. STP takes the internal representation value of a SAP or spoke SDP and identifies it with its own virtual port number, which is unique to any other SAP or spoke SDP defined on the VPLS. The virtual port number is assigned at the time that the SAP or spoke SDP is added to the VPLS. Since the order in which SAPs or spoke SDPs are added to the VPLS is not preserved between reboots of the system, the virtual port number may change between restarts of the STP instance.
This command configures the STP priority for the SAP or spoke SDP.
When configuration BPDUs are received, the STP priority is used in some circumstances as a tie-breaking mechanism to determine whether the SAP or spoke SDP will be designated or blocked. In traditional STP implementations (802.1D-1998), this field is called the port priority and has a value of 0 to 255. This field is coupled with the port number (0 to 255) to create a 16-bit value. In the latest STP standard (802.1D-2004), only the upper 4 bits of the port priority field are used to encode the SAP or spoke SDP priority. The remaining 4 bits are used to extend the port ID field into a 12-bit virtual port number field. The virtual port number uniquely references a SAP or spoke SDP within the STP instance.
STP computes the actual priority by taking the input value and masking out the lower 4 bits.The result is the value that is stored in the SAP or spoke SDP priority parameter. For instance, if a value of 0 is entered, masking out the lower 4 bits results in a parameter value of 0. If a value of 255 is entered, the result is 240.
The no form of this command returns the STP priority to the default value.
128
This command specifies whether this port is allowed to become an STP root port. It corresponds to the restrictedRole parameter in 802.1Q. If set, it can cause lack of spanning tree connectivity.
no root-guard
This command enables the context to configure egress SAP QoS policies and filter policies.
If no sap-egress QoS policy is defined, the system default sap-egress QoS policy is used for egress processing. If no egress filter is defined, no filtering is performed.
This command enables the context to configure ingress SAP QoS policies and filter policies.
If no sap-ingress QoS policy is defined, the system default sap-ingress QoS policy is used for ingress processing. If no ingress filter is defined, no filtering is performed.
This command sets the aggregate rate limits (PIR and CIR) for the SAP. The agg-rate sets the PIR value. The cir-rate sets the CIR value. When aggregate rate limits are configured on a second-generation (Gen-2) Ethernet adapter card, the scheduler mode must be set to 16-priority. On a third-generation (Gen-3) Ethernet adapter card, the scheduler mode is always 4-priority. For information on adapter card generations, refer to the “Evolution of Ethernet Adapter Cards, Modules, and Platforms” section in the 7705 SAR Interface Configuration Guide.
Configuring the cir-rate is optional. If a cir-rate is not entered, then the cir-rate is set to its default value (0 kb/s). If a cir-rate has been set and the agg-rate is changed without re-entering the cir-rate, the cir-rate automatically resets to 0 kb/s. For example, to change the agg-rate from 2000 to 1500 while maintaining a cir-rate of 500, use the command agg-rate-limit 1500 cir 500.
If the specified SAP is a LAG SAP, then agg-rate and cir-rate can be configured regardless of the scheduler mode setting on Gen-2 or Gen-3 hardware—it is not configurable if one of the ports configured in the LAG SAP is on Gen-1 hardware. If the active port is on a Gen-3 card or platform, then agg-rate and cir-rate are applicable. If the active port is on a Gen-2 card or platform, then agg-rate and cir-rate apply when the scheduler mode is set to 16-priority. If the active port is on a Gen-1 card, then agg-rate and cir-rate are not applicable. For details on the behavior of a mix-and-match LAG SAP, refer to the “LAG Support on Third-Generation Ethernet Adapter Cards, Ports, and Platforms” and “Network LAG Traffic Management” sections in the 7705 SAR Interface Configuration Guide.
Note: From Release 7.0.R6, schedulers on Gen-3 adapter cards and platforms have been updated to better align with the scheduling behavior supported on the other 7705 SAR adapter cards and platforms. The updated scheduler mode is called “4-priority” scheduler-mode throughout the CLI. Prior to Release 7.0.R6, the CLI designation was “4-priority-hqos”. In the updated mode of operation, arbitration among different flows at the second-tier aggregate (per-SAP or per-VLAN) and third-tier aggregate (per-customer (MSS)) levels are carried out in a round-robin manner, scheduling cir-rate first from the shapers, followed by the pir-rate. |
Caution: Any Gen-3 adapter card or platform running Release 7.0.R6 or later software uses 4-priority scheduling instead of 4-priority-hqos scheduling, which was supported previously. The migration of scheduler mode is automatic with an upgrade and there is no operator action required. As part of the migration, all CIR values at second-tier (per-SAP and per-VLAN) and third-tier (per-customer (MSS)) aggregate shaper levels are set to zero. Operators must exercise caution when performing an upgrade to Release 7.0.R6 or later from a previous Release 7.0 version, and must adjust the affected CIR values in accordance with the needs of their applications as soon as possible. |
The no form of the command sets the agg-rate to the maximum and the cir-rate to 0 kb/s.
no agg-rate-limit
This command associates a filter policy with a SAP or SDP (mesh or spoke). Filters can be applied to VPLS and routed VPLS SAPs and SDPs.
The filter mac command applies only to the ingress SAP and SDP contexts.
Filter policies control the forwarding and dropping of packets based on IP or MAC matching criteria. There are two types of filter policies: IP and MAC. Only one type may be applied at a time. The filter ID must be defined before the filter command is executed. If the filter policy does not exist, the operation will fail and an error message will be returned.
Only one filter ID can be assigned to an interface unless the interface is dual-stack (supports both IPv4 and IPv6). A dual-stack interface can have one IPv4 and one IPv6 filter ID assigned to it.
In general, filters applied to SAPs or SDPs apply to all packets on the SAP or SDP. One exception is that non-IP packets are not applied to IP match criteria, so the default action in the filter policy applies to these packets.
If an IP interface is attached to a VPLS service context (routed VPLS), the VPLS SAP or SDP configured IP or MAC filter for ingress routed packets can be optionally overridden in order to provide special ingress filtering for routed packets. This allows different filtering for routed packets and non-routed packets. The filter override is defined on the IP interface bound to the VPLS service name. A separate override filter can be specified for IPv4 and IPv6 packet types, using the v4-routed-override-filter or v6-routed-override-filter command in the IES or VPRN service contexts.
If filter override is configured, the IP or MAC filter configured on the SAP or SDP applies to non-routed packets. If filter override is not configured, the IP or MAC filter configured on the SAP or SDP applies to both routed and non-routed packets.
The no form of this command removes any configured filter ID association with the SAP or SDP. The filter ID itself is not removed from the system unless the scope of the created filter is set to exclusive. To avoid deletion of the filter ID and only break the association with the service object, use the scope command within the filter definition to set the scope to template. The default scope of a filter is exclusive.
This command specifies which dot1q tag position (top or bottom) in a qinq-encapsulated packet should be used when QoS evaluates dot1p classification.
The no form of the command restores the default dot1p evaluation behavior for the SAP, which means that the inner (bottom) tag (second tag) dot1p bits are used for classification.
By default, the dot1p bits from the inner tag service-delineating dot1q tag are used.
Table 60 shows which set of dot1p bits are used for QoS purposes when match-qinq-dot1p is configured. To use the table, find the row that represents the settings for Port/SAP Type and Match-QinQ-Dot1q Setting. Use the Existing Packet Tags column to identify which dot1q tags are available in the packet. Then use the P-bits Used for Match column to identify which dot1q tag contains the dot1p bits that are used for QoS dot1p classification.
no match-qinq-dot1p
Port/ SAP Type | Match-QinQ-Dot1p Setting 1 | Existing Packet Tags | P-bits Used for Match |
Null | n/a | None | None |
Null | n/a | Dot1p (VLAN ID 0) | None 2 |
Null | n/a | Dot1q | None 2 |
Null | n/a | TopQ BottomQ | None 2 |
Dot1Q | n/a | None | None |
Dot1Q | n/a | Dot1p (default SAP VLAN ID 0) | Dot1p P-bits |
Dot1Q | n/a | Dot1q | Dot1q P-bits |
QinQ/ X.Y | Top | TopQ BottomQ | TopQ P-bits |
QinQ/ X.Y | Default or Bottom | TopQ BottomQ | BottomQ P-bits |
QinQ/ X.0 | Top | TopQ | TopQ P-bits |
QinQ/ X.0 | Default or Bottom | TopQ | TopQ P-bits |
QinQ/ X.0 | Top | TopQ BottomQ | TopQ P-bits |
QinQ/ X.0 | Default or Bottom | TopQ BottomQ | BottomQ P-bits |
QinQ/ X.* | Top | TopQ | TopQ P-bits |
QinQ/ X.* | Default or Bottom | TopQ | TopQ P-bits |
QinQ/ X.* | Top | TopQ BottomQ | TopQ P-bits |
QinQ/ X.* | Default or Bottom | TopQ BottomQ | BottomQ P-bits |
QinQ/ 0.* | Top | None | None |
QinQ/ 0.* | Default or Bottom | None | None |
QinQ/ 0.* | Top | TopQ | TopQ P-bits |
QinQ/ 0.* | Default or Bottom | TopQ | TopQ P-bits |
QinQ/ 0.* | Top | TopQ BottomQ | TopQ P-bits |
QinQ/ 0.* | Default or Bottom | TopQ BottomQ | BottomQ P-bits |
QinQ/ *.* | Top | None | None |
QinQ/ *.* | Default or Bottom | None | None |
QinQ/ *.* | Top | TopQ | TopQ P-bits |
QinQ/ *.* | Default or Bottom | TopQ | TopQ P-bits |
QinQ/ *.* | Top | TopQ BottomQ | TopQ P-bits |
QinQ/ *.* | Default or Bottom | TopQ BottomQ | BottomQ P-bits |
Notes:
When enabled, the qinq-mark-top-only command specifies which P-bits to mark during packet egress. When disabled, both sets of P-bits are marked. When enabled, only the P-bits in the top Q-tag are marked. The no form of the command is the default state (disabled).
Table 61 shows the dot1p remarking behavior for different egress port type/SAP type combinations and qinq-mark-top-only state, where “False” represents the default (disabled) state.
If a new tag is pushed, the dot1p bits of the new tag will be zero (unless the new tag is re-marked by the egress policy. The dot1p bits are configured using the dot1p parameter under the config>qos context.
Egress Port Type/SAP Type | QinQ-mark-top-only State | Egress P-Bits Marked or Re-marked |
Null 1 | n/a | None |
Dot1q/ X 1 | n/a | Outer tag |
Dot1q/ * 2 | n/a | None |
Dot1q/ 0 2 | n/a | Outer tag |
QinQ/ X.Y 1 | False | Two outer tags 3 |
True | Outer tag 3 | |
QinQ/ X.* 1 | True or False | Outer tag |
QinQ/ X.0 1 | True or False | Outer tag |
QinQ/ 0.* 1 | True or False | None |
QinQ/ *.* 2 | True or False | None |
Notes:
no qinq-mark-top-only (disabled)
This command associates a QoS policy with an ingress or egress SAP.
QoS ingress and egress policies are important for the enforcement of SLA agreements. The policy ID must be defined prior to associating the policy with a SAP. If the policy-id does not exist, an error will be returned.
The qos command is used to associate both ingress and egress QoS policies. The qos command only allows ingress policies to be associated with ingress SAP, and egress policies with egress SAP. Attempts to associate a QoS policy of the wrong type returns an error.
Only one ingress and one egress QoS policy can be associated with a SAP at one time.
By default, if no specific QoS policy is associated with the SAP for ingress or egress, then the default QoS policy is used.
The no form of this command removes the QoS policy association from the SAP, and the QoS policy for the SAP reverts to the default.
This command sets the scheduler mode for the SAP and is part of the hierarchical QoS (H-QoS) feature on the 7705 SAR.
If the mode is 4-priority, then the SAP is considered an unshaped 4-priority SAP and the agg-rate-limit cannot be changed from its default values.
If the mode is 16-priority and the agg-rate limit parameters are configured to be non-default values, then the SAP is considered a shaped SAP. If the agg-rate limit parameters are left in their default settings, the SAP is considered an unshaped, 16-priority SAP.
This command is blocked on third-generation (Gen-3) Ethernet adapter cards and platforms, such as the 6-port Ethernet 10Gbps Adapter card and the 7705 SAR-X, which only support 4-priority scheduling mode.
If the specified SAP is a LAG SAP, scheduler-mode can be configured but is not applied to Gen-3 adapter cards and platforms. If one of the ports in the LAG is on a Gen-1 adapter card, then scheduler-mode cannot be configured.
4-priority
This command applies a shaper group to a SAP. The shaper group must already be created and must be within the shaper policy assigned to the Ethernet MDA (for ingress) or port (for egress). A shaper group is a dual-rate aggregate shaper used to shape aggregate access ingress or egress SAPs at a shaper group rate. Multiple aggregate shaper groups ensure fair sharing of available bandwidth among different aggregate shapers.
The default shaper group cannot be deleted.
The no form of this command removes the configured shaper-group.
shaper-group “default”
This command preserves the VLAN tag at the ingress SAP. The default (disabled) behavior is to strip off the VLAN tag at the ingress SAP and push a new VLAN tag at the egress SAP.
The force-c-vlan-forwarding command is only available on VPLS dot1q and qinq SAPs.
When the ingress and egress port encap-type are both dot1q, force-c-vlan-forwarding has the following behavior:
When the ingress and egress port encap-type are both qinq, force-c-vlan-forwarding has the following behavior:
The no version of this command sets the default behavior.
disabled
This command creates the accounting policy context that can be applied to a SAP.
An accounting policy must be defined before it can be associated with a SAP. If the acct-policy-id does not exist, an error message is generated.
A maximum of one accounting policy can be associated with a SAP at one time. Accounting policies are configured in the config>log context.
The no form of this command removes the accounting policy association from the SAP, and the accounting policy reverts to the default.
accounting-policy
This command enables accounting and statistical data collection for a SAP, a network port, or an IP interface. When applying accounting policies, the data (by default) is collected in the appropriate records and written to the designated billing file.
When the no collect-stats command is issued, the statistics are still accumulated by the CSM. However, the CPU will not obtain the results and write them to the billing file. If a subsequent collect-stats command is issued, then the counters written to the billing file include all the traffic while the no collect-stats command was in effect.
collect-stats
This command enables the context to configure DHCP parameters.
This command enables DHCP Option 82 (Relay Agent Information Option) parameters processing and enters the context for configuring Option 82 suboptions.
The no form of this command returns the system to the default.
no option
This command configures the Relay Agent Information Option (Option 82) processing.
The no form of this command returns the system to the default value.
keep
The behavior is slightly different in the case of Vendor Specific Options (VSOs). When the keep parameter is specified, the router will insert its own VSO into the Option 82 field (as per RFC 4243). This will only be done when the incoming message already has an Option 82 field. However, if adding the VSO causes the Option 82 field to exceed the maximum allowable length (255 octets), the packet is dropped.
If no Option 82 field is present, the router will not create the Option 82 field. In this in that case, no VSO will be added to the message.
This command causes the router to send an ASCII-encoded “tuple” in the circuit-id suboption of the DHCP packet. This ASCII-tuple consists of the access-node-identifier, service-id, and SAP-ID, separated by “|”. If no keyword is configured, then the circuit-id suboption will not be part of the information option (Option 82).
If disabled, the circuit-id suboption of the DHCP packet will be left empty.
no circuit-id
This command specifies what information goes into the remote-id suboption in the DHCP Relay packet.
If disabled, the remote-id suboption of the DHCP packet will be left empty.
The no form of this command returns the system to the default.
no remote-id
This command configures the vendor-specific suboption within the Option 82 field of the DHCP relay packet.
This command enables the sending of the MAC address in the vendor-specific suboption of the DHCP relay packet.
The no form of the command disables the sending of the MAC address in the vendor-specific suboption of the DHCP relay packet.
This command enables the sending of the SAP ID in the vendor-specific suboption of the DHCP relay packet.
The no form of the command disables the sending of the SAP ID in the vendor-specific suboption of the DHCP relay packet.
This command enables the sending of the service ID in the vendor specific suboption of the DHCP relay packet.
The no form of the command disables the sending of the service ID in the vendor specific suboption of the DHCP relay packet.
This command specifies the string in the vendor specific suboption of the DHCP relay packet.
The no form of the command returns the default value.
no string
This command specifies whether the system ID is encoded in the vendor specific suboption of Option 82.
This command enables DHCP snooping of DHCP messages on the SAP. Enabling DHCP snooping on VPLS interfaces (SAPs) is required where vendor-specific information (as per RFC 4243) is to be inserted into the Option 82 field of the DHCP messages.
Use the no form of the command to disable DHCP snooping on the specified VPLS SAP binding.
no snoop
This command binds a VPLS service to an existing Service Distribution Point (SDP). Mesh SDPs bound to a service are logically treated like a single bridge “port” for flooded traffic, where flooded traffic received on any mesh SDP on the service is replicated to other “ports” (spoke SDPs and SAPs) and not transmitted on any mesh SDPs.
This command creates a binding between a service and an SDP. The SDP has an operational state that determines the operational state of the SDP within the service. For example, if the SDP is administratively or operationally down, the SDP for the service will be down.
The SDP must already be defined in the config>service>sdp context in order to associate the SDP with a valid service. If the sdp sdp-id is not already configured, an error message is generated. If the sdp-id does exist, a binding between that sdp-id and the service is created.
SDPs must be explicitly associated and bound to a service. If an SDP is not bound to a service, no far-end 7705 SAR devices can participate in the service.
The no form of this command removes the SDP binding from the service. The SDP configuration is not affected; only the binding of the SDP to a service. Once removed, no packets are forwarded to the far-end router.
No sdp-id is bound to a service
This command binds a service to an existing SDP. A spoke SDP is treated like the equivalent of a traditional bridge “port”, where flooded traffic received on the spoke SDP is replicated on all other “ports” (other spoke and mesh SDPs or SAPs) and not transmitted on the port it was received.
The SDP has an operational state that determines the operational state of the SDP within the service. For example, if the SDP is administratively or operationally down, the SDP for the service will be down.
The SDP must already be defined in the config>service>sdp context in order to associate an SDP with a VPLS service. If the sdp sdp-id is not already configured, an error message is generated. If the sdp-id does exist, a binding between that sdp-id and the service is created. SDPs must be explicitly associated and bound to a service. If an SDP is not bound to a service, no far-end devices can participate in the service.
The no form of this command removes the SDP binding from the service. The SDP configuration is not affected; only the binding of the SDP to a service. Once removed, no packets are forwarded to the far-end router.
No sdp-id is bound to a service
Split horizon groups can only be created in the scope of a VPLS service.
This command enables the use of the control word on pseudowire packets in VPLS and enables the use of the control word individually on each mesh SDP or spoke SDP. By default, the control word is disabled.
When the control word is enabled, all VPLS packets are encapsulated with the control word when sent over the pseudowire. The T-LDP control plane behavior is the same as in the implementation of control word for VLL services. The configuration for the two directions of the Ethernet pseudowire should match.
The no form of the command resets the mesh SDP or spoke SDP to the default behavior of not using the control word.
no control-word
This command configures the egress SDP context.
This command configures the ingress SDP context.
This command configures the egress VC label.
This command configures the ingress VC label.
This command enables or disables the use of entropy labels for mesh or spoke SDPs.
If entropy-label is enabled, the entropy label and entropy label indicator (ELI) are inserted in packets for which at least one LSP in the stack for the far end of the tunnel used by the service has advertised entropy label capability.
If the tunnel is an RSVP-TE type, entropy-label can also be controlled by disabling entropy-label-capability under the config>router>rsvp context at the far-end LER.
When the entropy-label and entropy-label-capability commands are both enabled, the entropy label value inserted at the iLER is always based on the service ID.
no entropy-label
This command configures the precedence of this SDP binding when there are multiple SDP bindings attached to one service endpoint. When an SDP binding goes down, the next highest precedence SDP binding begins forwarding traffic.
no precedence
This command enables pseudowire status signaling for spoke SDPs. The no form of this command disables pseudowire status signaling. When pseudowire status signaling is disabled, a 7705 SAR does not include the PW status TLV in the initial label mapping message of the pseudowire that is used for a spoke SDP. This forces both 7705 SAR PEs to use the pseudowire label withdrawal method for signaling pseudowire status. If the remote endpoint has standby-signaling-master enabled and it determines that a particular PW should be standby, based on the precedence of the PWs, it will withdraw the PW label. If the label is withdrawn for all PWs on a VPLS, the VPLS will go operationally down.
If pseudowire status signaling is enabled, the 7705 SAR includes the pseudowire status TLV in the initial label mapping message for the pseudowire.
pw-status-signaling
This command creates a remote static MAC entry in the VPLS FDB associated with the SDP.
In a VPLS service, MAC addresses are associated with a SAP or an SDP. MACs associated with a SAP are classified as local MACs, and MACs associated with an SDP are remote MACs.
Remote static MAC entries create a permanent MAC address to SDP association in the FDB for the VPLS instance so that the MAC address will not be learned on the edge device.
Static MAC definitions on one edge device are not propagated to other edge devices participating in the VPLS instance; that is, each edge device has an independent FDB for the VPLS.
Only one static MAC entry (local or remote) can be defined per MAC address per VPLS instance.
The no form of this command deletes the static MAC entry with the specified MAC address associated with the SDP from the VPLS FDB.
n/a
This command specifies an explicit dot1q value that is used when encapsulating to the SDP far end. When signaling is enabled between the near and far end, the configured dot1q tag can be overridden by a received TLV specifying the dot1q value expected by the far end. This signaled value must be stored as the remote signaled dot1q value for the binding. The provisioned local dot1q tag must be stored as the administrative dot1q value for the binding.
When the dot1q tag is not defined, the default value of 0 is stored as the administrative dot1q value. Setting the value to 0 is equivalent to not specifying the value.
The no form of this command disables the command.
no vlan-vc-tag
This command sets a flag on the VPLS service that allows an IES or VPRN IP interface to be attached to the VPLS service in order to make the VPLS service routable. If the allow-ip-int-binding command is not enabled, the VPLS service cannot be attached to an IP interface.
When attempting to set the allow-ip-int-binding VPLS flag, the system first checks to see if the correct configuration constraints exist for the VPLS service and the network ports. The following features are disabled when the allow-ip-int-binding flag is set under VPLS:
Note: The DHCP relay functionality under config>service>ies>if>dhcp or config>service>ies>if>ipv6>dhcp6-relay can be used to dynamically assign IP addresses to the clients connected to routed VPLS SAPs. |
If a service name is applied to a VPLS service and that service name is also bound to an IP interface but the allow-ip-int-binding flag has not been set on the VPLS service context, the system attempt to resolve the service name between the VPLS service and the IP interface fails. As soon as the allow-ip-int-binding flag is enabled on the VPLS, the corresponding IP interface will be attached and become operationally up. There is no need to toggle the shutdown/no shutdown command.
The no form of the command resets the allow-ip-int-binding flag on the VPLS service. If the VPLS service currently has an IP interface from an IES or VPRN service attached, the no allow-ip-int-binding command fails. Once the allow-ip-int-binding flag is reset on the VPLS service, the configuration restrictions associated with setting the flag are removed.
This command configures a service name, up to 64 characters in length, which adds a name identifier to a given service to use as display in show commands throughout the system.
All services are required to assign a service ID to initially create a service. However, either the service ID or the service name can be used to identify and reference a given service once it is initially created.
Note: The following command outputs are examples only; actual displays may differ depending on supported functionality and user configuration. |
This command displays service information using the range of egress labels. If only the mandatory start-label parameter is specified, only services using the specified label are displayed. If both start-label and end-label parameters are specified, the services using the range of labels are displayed.
Use the show router ldp bindings command to display dynamic labels.
The following output is an example of service egress-label information, and Table 62 describes the fields.
Label | Description |
Svc Id | The ID that identifies a service |
Sdp Binding | The binding that identifies an SDP |
Type | Indicates whether the SDP binding is a spoke or a mesh |
I. Lbl | The VC label used by the far-end device to send packets to this device in this service by the SDP |
E. Lbl | The VC label used by this device to send packets to the far-end device in this service by the SDP |
Number of Bindings Found | The total number of SDP bindings that exist within the specified egress label range |
This command displays global forwarding database (FDB) usage information.
The following output is an example of global FDB usage information, and Table 63 describes the fields.
Label | Description |
Service Id | The value that identifies a service |
Mac Move | Indicates the administrative state of the MAC movement feature associated with the service |
Mac Move Rate | The maximum rate at which MACs can be relearned in this TLS service, before the SAP where the moving MAC was last seen is automatically disabled in order to protect the system against undetected loops or duplicate MACs. The rate is computed as the maximum number of relearns allowed in a 5-s interval. The default rate of 10 relearns per second corresponds to 50 relearns in a 5-s period. |
Mac Move Timeout | Indicates the time, in seconds, to wait before a SAP that has been disabled after exceeding the maximum relearn rate is re-enabled. A value of 0 indicates that the SAP will not be automatically re-enabled after being disabled. If after the SAP is re-enabled it is disabled again, the effective retry timeout is doubled in order to avoid thrashing. |
Table Size | The maximum number of learned and static entries allowed in the FDB |
Total Count | The current number of entries (both learned and static) in the FDB of this service |
Learned Count | The current number of learned entries in the FDB of this service |
Static Count | The current number of static entries in the FDB of this service |
OAM-learned Count | The current number of OAM-learned entries in the FDB of this service |
DHCP-learned Count | The current number of DHCP-learned entries in the FDB of this service |
Host-learned Count | The current number of host-learned entries in the FDB of this service |
Remote Age | The number of seconds used to age out FDB entries learned on an SDP; these entries correspond to MAC addresses learned on remote SAPs |
Local Age | The seconds used to age out FDB entries learned on local SAPs |
High Watermark | The usage of the FDB table of this service at which a “table full” alarm is raised by the agent |
Low Watermark | The usage of the FDB table of this service at which a “table full” alarm is cleared by the agent |
Mac Learning | Specifies whether the MAC learning process is enabled in this service |
Discard Unknown | Specifies whether frames received with an unknown destination MAC are discarded in this service |
MAC Aging | Specifies whether MAC aging is enabled |
MAC Pinning | Specifies whether MAC pinning is enabled |
Relearn Only | When enabled, indicates that either the FDB table of this service is full or that the maximum system-wide number of MACs supported by the agent has been reached, and thus MAC learning is temporarily disabled, and only MAC relearns can take place |
Total Service FDB | The current number of service FDBs configured on this node |
Total FDB Configured Size | The sum of configured FDBs |
Total FDB Entries In Use | The total number of entries (both learned and static) in use |
PBB MAC Address Indices in Use | Not applicable |
This command displays the FDB entry for a given MAC address.
The following output is an example of FDB information for a specific MAC address, and Table 64 describes the fields.
Label | Description |
ServId | The service ID number |
MAC | The specified MAC address |
Source-Identifier | The location where the MAC is defined |
Type/Age | Static: FDB entries created by management |
Learned: dynamic entries created by the learning process | |
OAM: entries created by the OAM process | |
H: host, the entry added by the system for a static configured subscriber host | |
D or DHCP: DHCP-installed MAC Learned addresses can be temporarily frozen by the DHCP snooping application for the duration of a DHCP lease | |
P: indicates the MAC is protected by the MAC protection feature | |
Last Change | The date and time of the last change |
This command enables the context to display information for a specific service-id. The output display can be filtered by using one of the command filters in the Parameters list.
This command displays detailed information for all aspects of a service.
The following output is an example of detailed information about a service, and Table 65 describes the fields.
Label | Description |
Service Id | The service identifier |
Service Type | The type of service |
Name | The service name |
Description | Generic information about the service |
Customer Id | The customer identifier |
Last Status Change | The date and time of the most recent status change to this customer |
Last Mgmt Change | The date and time of the most recent management-initiated change to this customer |
Admin State | The administrative state of the service |
Oper State | The operational state of the service |
MTU | The largest frame size (in octets) that the service can handle |
Def. Mesh VC Id | This object is only valid in services that accept mesh SDP bindings. It is used to validate the VC ID portion of each mesh SDP binding defined in the service. |
SAP Count | The number of SAPs defined on the service |
SDP Bind Count | The number of SDPs bound to the service |
Snd Flush on Fail | Specifies the state of sending a MAC flush on failure (enabled or disabled) |
Host Conn Verify | Specifies the state of verifying host connectivity (enabled or disabled) |
Propagate MacFlush | Specifies the state of propagating a MAC flush (enabled or disabled) |
Def. Gateway IP | Specifies the defined gateway IP address for the service |
Def. Gateway MAC | Specifies the defined gateway MAC address for the service |
Split Horizon Group | |
Description | Description of the split horizon group |
Last Changed | The date and time of the most recent management-initiated change to this split horizon group |
Instance Id | The identifier for this split horizon group instance |
Service Distribution Points (SDPs) (see Table 81) | |
Service Access Points (see Table 80) | |
IGMP Snooping Base info (see Table 72) | |
MLD Snooping Base info (see Table 72) | |
VPLS Spanning Tree Information (see Table 83) | |
DHCP Summary (see Table 68) | |
ARP host Summary | |
Sap | The SAP identifier |
Used | The number of lease-states that are currently in use on a specific interface; that is, the number of clients on that interface who received an IP address via ARP. This value is always less than or equal to the “Provided” field. |
Provided | The lease-populate value that is configured for a specific interface |
Admin State | The administrative state of the service |
Service Endpoints (see Table 69) |
This command displays basic information about the service ID, including service type, description, SAPs, and SDPs.
The following output is an example of basic information about a service, and Table 66 describes the fields.
Label | Description |
Service Id | The service identifier |
Service Type | The type of service |
Name | The service name |
Description | Generic information about the service |
Customer Id | The customer identifier |
Last Status Change | The date and time of the most recent status change to this customer |
Last Mgmt Change | The date and time of the most recent management-initiated change to this customer |
Admin State | The administrative state of the service |
Oper State | The operational state of the service |
MTU | The largest frame size (in octets) that the service can handle |
Def. Mesh VC Id | This object is only valid in services that accept mesh SDP bindings. It is used to validate the VC ID portion of each mesh SDP binding defined in the service. |
SAP Count | The number of SAPs defined on the service |
SDP Bind Count | The number of SDPs bound to the service |
Snd Flush on Fail | Specifies the state of sending a MAC flush on failure (enabled or disabled) |
Host Conn Verify | Specifies the state of verifying host connectivity (enabled or disabled) |
Propagate MacFlush | Specifies the state of propagating a MAC flush (enabled or disabled) |
Def. Gateway IP | Specifies the defined gateway IP address for the service |
Def. Gateway MAC | Specifies the defined gateway MAC address for the service |
Service Access and Destination Points | |
Identifier | Specifies the service access (SAP) and destination (SDP) points |
Type | Specifies the signaling protocol used to obtain the ingress and egress labels used in frames transmitted and received on the SDP |
AdmMTU | Specifies the largest service frame size (in octets) that can be transmitted through this SDP to the far-end router, without requiring the packet to be fragmented |
OprMTU | Specifies the actual largest service frame size (in octets) that can be transmitted through this service to the far-end router, without requiring the packet to be fragmented |
Adm | The administrative state of the service |
Opr | The operational state of the service |
This command enables the context to display DHCP information for the specified service.
This command displays DHCP statistics information.
The following output is an example of DHCP statistics information for a SAP, an SDP, and an interface, and Table 67 describes the fields.
Label | Description |
Client Packets Snooped | The number of client packets snooped |
Client Packets Forwarded | The number of client packets forwarded |
Client Packets Dropped | The number of client packets dropped |
Client Packets Proxied (RADIUS) | The number of client packets proxied (RADIUS) |
Client Packets Proxied (Lease-Split) | The number of client packets proxied (lease-split) |
Server Packets Snooped | The number of server packets snooped |
Server Packets Forwarded | The number of server packets forwarded |
Server Packets Dropped | The number of server packets dropped |
DHCP RELEASEs Spoofed | The number of DHCP releases spoofed |
DHCP FORCERENEWs Spoofed | The number of DHCP forced renewals spoofed |
This command displays DHCP configuration summary information.
The following output is an example of DHCP summary information, and Table 68 describes the fields.
Label | Description |
Sap/Sdp | The SAP or SDP identifier of the router interface |
Snoop | Specifies whether DHCP snooping is enabled |
Used/Provided | Used: the number of lease-states that are currently in use on a specific interface; that is, the number of clients on that interface who received an IP address via DHCP. This value is always less than or equal to the “Provided” field. Provided: the lease-populate value that is configured for a specific interface |
Arp Reply Agent | Specifies whether the ARP reply agent is enabled |
Info Option | Indicates whether Option 82 processing is enabled on the interface |
Admin State | Indicates the administrative state |
This command displays service endpoint information.
The following output is an example of endpoint information, and Table 69 describes the fields.
Label | Description |
Endpoint name | The name of the endpoint |
Description | A description of the endpoint |
Revert time | The programmable time delay to switch back to the primary spoke SDP |
Act Hold Delay | Not applicable |
Ignore Standby Signaling | Specifies whether ignore standby signaling is configured True: standby signaling is ignored False: standby signaling is not ignored |
Suppress Standby Signaling | Specifies whether suppress standby signaling is configured True: standby signaling is suppressed False: standby signaling is not suppressed |
Block On Mesh Fail | Specifies whether to take down the spoke SDP when the mesh SDP is down True: the spoke SDP is not taken down False: the spoke SDP is taken down |
Tx Active | The identifier of the active spoke SDP |
Tx Active Up Time | The total amount of time that a spoke SDP remains the active spoke SDP |
Revert Time Count Down | The amount of time remaining before active transmission reverts to the primary spoke SDP |
Tx Active Change Count | The number of times that the active spoke SDP has changed |
Last Tx Active Change | The timestamp of the last active spoke SDP change |
Members | |
Spoke-sdp | Identifies the spoke SDP |
Prec | Specifies the precedence of this SDP binding when there are multiple SDP bindings attached to one service endpoint |
Oper Status | Indicates the operational status of the endpoint |
This command displays FDB entries for a specified entity associated with the service.
The following output is an example of FDB entries for a specific MAC address, and Table 70 describes the fields.
Label | Description |
ServID | The service ID |
Mac Move | The administrative state of the MAC movement feature associated with this service |
Primary Factor | A factor for the primary ports defining how many MAC relearn periods should be used to measure the MAC relearn rate |
Secondary Factor | A factor for the secondary ports defining how many MAC relearn periods should be used to measure the MAC relearn rate |
Mac Move Rate | The maximum rate at which MACs can be relearned in this service, before the SAP where the moving MAC was last seen is automatically disabled in order to protect the system against undetected loops or duplicate MACs The rate is computed as the maximum number of relearns allowed in a 5-s interval: for example, the default rate of 2 relearns per second corresponds to 10 relearns in a 5-s period |
Mac Move Timeout | The time, in seconds, to wait before a SAP that has been disabled after exceeding the maximum relearn rate is re-enabled. A value of 0 indicates that the SAP will not be automatically re-enabled after being disabled. If after the SAP is re-enabled it is disabled again, the effective retry timeout is doubled in order to avoid thrashing. |
Mac Move Retries | The number of times retries are performed for re-enabling the SAP/SDP |
Table Size | The maximum number of learned and static entries allowed in the FDB of this service |
Total Count | The total number of learned entries in the FDB of this service |
Learned Count | The current number of learned entries in the FDB of this service |
Static Count | The current number of static entries in the FDB of this service |
OAM-learned Count | The current number of OAM entries in the FDB of this service |
DHCP-learned Count | The current number of DHCP-learned entries in the FDB of this service |
Host-learned Count | The current number of host-learned entries in the FDB of this service |
Remote Age | The number of seconds used to age out FDB entries learned on an SDP. These entries correspond to MAC addresses learned on remote SAPs. |
Local Age | The number of seconds used to age out FDB entries learned on local SAPs |
High Watermark | The usage of the FDB table of this service at which a table full alarm will be raised by the agent |
Low Watermark | The usage of the FDB table of this service at which a table full alarm will be cleared by the agent |
Mac Learning | Specifies whether MAC learning is enabled |
Discard Unknown | Specifies whether frames received with an unknown destination MAC are discarded |
Mac Aging | Specifies whether MAC aging is enabled |
Relearn Only | When enabled, displays that either the FDB table of this service is full or the maximum system-wide number of MACs supported by the agent has been reached, and thus MAC learning is temporarily disabled and only MAC relearns can take place |
Mac Subnet Len | The number of bits to be considered when performing MAC-learning or MAC-switching |
Source-Identifier | The location where the MAC is defined |
Type/Age | Type: the number of seconds used to age out TLS FDB entries learned on local SAPs |
Age: the number of seconds used to age out TLS FDB entries learned on an SDP. These entries correspond to MAC addresses learned on remote SAPs. | |
L: learned - dynamic entries created by the learning process OAM: entries created by the OAM process | |
H: host, the entry added by the system for a static configured subscriber host | |
D or DHCP: DHCP-installed MAC. Learned addresses can be temporarily frozen by the DHCP snooping application for the duration of a DHCP lease. | |
P: indicates the MAC is protected by the MAC protection feature | |
Static: statically configured | |
Last Change | Indicates the time of the most recent state changes |
This command enables the context to display IGMP snooping information.
This command enables the context to display MLD snooping information.
This command displays detailed information for all aspects of IGMP or MLD snooping on the VPLS service.
The following outputs are examples of IGMP snooping and MLD snooping displays for the specified VPLS service, and Table 71 describes the fields.
Label | Description |
IGMP Snooping info for service id MLD Snooping info for service id | Shows the service id for which snooping applies |
IGMP Snooping Base info MLD Snooping Base info | |
Admin State | The administrative state of the IGMP or MLD instance |
Querier | The address of the IGMP or MLD querier on the IP subnet to which the interface is attached |
Sap/Sdp Id | The SAP IDs and SDP IDs for the service ID |
Oper Stat | The operational state of the SAP IDs and SDP IDs of the service ID |
MRtr Port | Specifies whether the port is a multicast router port |
Pim Port | (IGMP only) Specifies whether the port is a PIM port |
Send Qrys Send Queries | Specifies whether the send-queries command is enabled or disabled |
Max Grps | (IGMP only) The maximum number of multicast groups for the entry |
Max Srcs | (IGMP only) The maximum number of multicast sources for the entry |
Max Grp Srcs | (IGMP only) The maximum number of multicast group sources for the entry |
Max Num Groups | (MLD only) The maximum number of multicast groups that can be joined on this SAP or SDP |
MVR From-VPLS | Specifies multicast VPLS registration (MVR) from VPLS |
Num Grps Num Groups | The actual number of multicast groups that can be joined on this SAP or SDP |
IGMP Snooping Querier info MLD Snooping Querier info | |
Sap Id | The SAP ID of the service |
IP Address | The IP address of the querier |
Expires | The length of time remaining before this query ages out, in seconds |
Up Time | The length of time that the query has been enabled |
Version | The configured version of IGMP or MLD |
General Query Interval | The frequency at which host-query packets are transmitted |
Query Response Interval | The time to wait to receive a response to the host-query message from the host |
Robust Count | The number of IGMP or MLD message intervals that are used when there is expected packet loss on the SAP or SDP. Robust count is similar to a retry counter, where the number of retries is robust count minus 1. |
IGMP Snooping Multicast Routers MLD Snooping Multicast Routers | |
MRouter | The IP address of the multicast router |
Sap/Sdp Id | The SAP ID or SDP ID connected to the multicast router |
Up Time | The time since the multicast router was created |
Expires | The length of time remaining before this entry ages out, in seconds |
Version | The version of IGMP or MLD used by the multicast router |
Number of mrouters | The number of multicast routers connected to this VPLS |
IGMP Snooping Proxy-reporting DB MLD Snooping Proxy-reporting DB | |
Group Address | The IP multicast group address for which this entry contains information |
Mode | The type of membership reports received on the interface for the group: include or exclude Include — reception of packets sent to the specified multicast address is requested only from those IP source addresses listed in the source-list parameter of the IGMP or MLD membership report Exclude — reception of packets sent to the given multicast address is requested from all IP source addresses except those listed in the source-list parameter of the IGMP or MLD membership report |
Up Time | The total operational time in seconds |
Num Sources | The number of IGMP or MLD group-specific and source-specific queries received on this interface |
Number of groups | The number of IGMP groups |
IGMP Snooping SAP id Port-DB MLD Snooping SAP id Port-DB | |
Group Address | The IP multicast group address for which this entry contains information |
Mode | The type of membership reports received on the interface for the group: include or exclude Include — reception of packets sent to the specified multicast address is requested only from those IP source addresses listed in the source-list parameter of the IGMP or MLD membership report Exclude — reception of packets sent to the given multicast address is requested from all IP source addresses except those listed in the source-list parameter of the IGMP or MLD membership report |
Type | Indicates how this group entry was learned: dynamic or static Dynamic — this group entry was learned by IGMP or MLD Static — this group entry was statically configured |
From-VPLS | The VPLS from which the multicast streams corresponding to the groups learned via this SAP or SDP are copied. If “local”, stream comes from its own VPLS. |
Up Time | The time since the source group entry was created |
Expires | The length of time remaining before this entry ages out, in seconds |
Num Src | The number of IGMP or MLD group-specific and source-specific queries received on this SAP |
MC Stdby | The multicast standby state |
Number of groups | The number of groups configured for this SAP |
IGMP Snooping SDP id Port-DB MLD Snooping SDP id Port-DB | |
Group Address | The IP multicast group address for which this entry contains information |
Mode | The type of membership reports received on the interface for the group: include or exclude Include — reception of packets sent to the specified multicast address is requested only from those IP source addresses listed in the source-list parameter of the IGMP or MLD membership report Exclude — reception of packets sent to the given multicast address is requested from all IP source addresses except those listed in the source-list parameter of the IGMP or MLD membership report |
Type | Indicates how this group entry was learned: dynamic or static Dynamic — this group entry was learned by IGMP or MLD Static — this group entry was statically configured |
From-VPLS | The VPLS from which the multicast streams corresponding to the groups learned via this SAP or SDP are copied. If “local”, stream comes from its own VPLS. |
Up Time | The time since the source group entry was created |
Expires | The length of time remaining before this entry ages out, in seconds |
Num Src | The number of IGMP or MLD group-specific and source-specific queries received on this SDP |
Number of groups | The number of groups configured for this SDP |
IGMP Snooping Static Source Groups MLD Snooping Static Source Groups | |
IGMP Snooping Static Source Groups for SAP id IGMP Snooping Static Source Groups for SDP id MLD Snooping Static Source Groups for SAP id MLD Snooping Static Source Groups for SDP id | |
Source | The source IP address of the static group |
Group | The group IP address of the static (S,G) or (*,G) |
Static (*,G)/(S,G) entries | The number of static (S,G) or (*, G) entries |
IGMP Snooping Statistics MLD Snooping Statistics | |
Message Type | The column heading for IGMP or MLD snooping messages |
General Queries | The number of general query messages received, transmitted, and forwarded |
Group Queries | The number of group query messages received, transmitted, and forwarded |
Group-Source Queries | The number of group-source query messages received, transmitted, and forwarded |
V1 Reports | The number of IGMPv1 or MLDv1 report messages received, transmitted, and forwarded |
V2 Reports | The number of IGMPv2 or MLDv2 report messages received, transmitted, and forwarded |
V3 Reports | (IGMP only) The number of IGMPv3 report messages received, transmitted, and forwarded |
V2 Leaves | (IGMP only) The number of IGMPv2 leave messages received, transmitted, and forwarded |
V1 Done | (MLD only) The number of MLDv1 done messages received, transmitted, and forwarded |
Unknown Type | The number of unknown type messages received, transmitted, and forwarded |
Drop Statistics | |
Bad Length | The number of packets dropped due to bad length |
Bad IP Checksum | (IGMP only) The number of packets dropped due to a bad IP checksum |
Bad IGMP Checksum Bad MLD Checksum | The number of packets dropped due to a bad IGMP or MLD checksum |
Bad Encoding | The number of packets dropped due to bad encoding |
No Router Alert | The number of packets dropped because there was no router alert |
Zero Source IP | The number of packets dropped due to a source IP address of 0.0.0.0 or 00:00:00:00:00:00:00:00 |
Wrong Version | The number of packets dropped due to a wrong version of IGMP or MLD |
Lcl-Scope Packets | The number of local scope packets dropped |
Rsvd-Scope Packets | The number of reserved scope packets dropped |
Send Query Cfg Drops | The number of messages dropped because of send query configuration errors |
Import Policy Drops | The number of messages dropped because of import policy |
Exceeded Max Num Groups | The number of packets dropped because the maximum number of groups has been exceeded |
Exceeded Max Num Sources | (IGMP only) The number of packets dropped because the maximum number of sources has been exceeded |
Exceeded Max Num Grp Srcs | (IGMP only) The number of packets dropped because the maximum number of group sources has been exceeded |
MCAC Policy Drops | The number of packets dropped due to multicast CAC |
MCS Failures | The number of packets dropped due to multicast server (MCS) failures |
MVR From VPLS Cfg Drops | The number of packets dropped due to VPLS configuration multicast VPLS registration (MVR) |
MVR To SAP Cfg Drops | The number of packets dropped due to SAP configuration |
IGMP Snooping Multicast VPLS Registration info MLD Snooping Multicast VPLS Registration info | |
IGMP Snooping Admin State MLD Snooping Admin State | The administrative state of IGMP or MLD snooping |
MVR Admin State | The administrative state of received MVR |
MVR Policy | The MVR policy |
Local SAPs/SDPs | |
Svc Id | The service identifier for this SAP or SDP entry |
Sap/Sdp Id | The local SAP or SDP identifier |
Oper State | The operational state of this SAP or SDP |
From VPLS | The VPLS from which the multicast streams corresponding to the groups learned via this SAP or SDP are copied. If “local”, stream comes from its own VPLS. |
Num Local Groups | The number of local groups associated with this SAP or SDP |
MVR SAPs (from-vpls=id) | |
Svc Id | The service identifier for this SAP or SDP entry |
Sap/Sdp Id | The MVR SAP or SDP identifier |
Oper State | The operational state of this SAP or SDP |
From VPLS | The VPLS from which the multicast streams corresponding to the groups learned via this SAP or SDP are copied. If “local”, stream comes from its own VPLS. |
Num MVR Groups | The number of MVR groups associated with this SAP |
This command displays basic information about IGMP snooping or MLD snooping for the VPLS service.
The following outputs are examples of basic IGMP snooping and MLD snooping displays for the specified VPLS service, and Table 72 describes the fields.
Label | Description |
Admin State | The administrative state of the IGMP or MLD instance |
Querier | The address of the IGMP or MLD querier on the IP subnet to which the interface is attached |
Sap/Sdp Id | The SAP IDs and SDP IDs for the service ID |
Oper Stat | The operational state of the SAP IDs and SDP IDs of the service ID |
MRtr Port | Specifies whether the port is a multicast router port |
Pim Port | (IGMP only) Specifies whether the port is a PIM port |
Send Qrys Send Queries | Specifies whether the send-queries command is enabled or disabled |
Max Grps | (IGMP only) The maximum number of multicast groups for the entry |
Max Srcs | (IGMP only) The maximum number of multicast sources for the entry |
Max Grp Srcs | (IGMP only) The maximum number of multicast group sources for the entry |
Max Num Groups | (MLD only) The maximum number of multicast groups that can be joined on this SAP or SDP |
MVR From-VPLS | Specifies MVR from VPLS |
Num Grps Num Groups | The actual number of multicast groups that can be joined on this SAP or SDP |
This command displays information on the IGMP or MLD snooping port database for the VPLS service.
The following outputs are examples of port database information for IGMP snooping and MLD snooping displays for the specified VPLS service, and Table 73 describes the fields.
Label | Description |
Group Address | The IP multicast group address for which this entry contains information |
Mode | The type of membership reports received on the interface for the group: include or exclude Include — reception of packets sent to the specified multicast address is requested only from those IP source addresses listed in the source-list parameter of the IGMP or MLD membership report Exclude — reception of packets sent to the given multicast address is requested from all IP source addresses except those listed in the source-list parameter |
Type | Indicates how this group entry was learned: dynamic or static Dynamic — this group entry was learned by IGMP or MLD Static — this group entry was statically configured |
From-VPLS | The VPLS from which the multicast streams corresponding to the groups learned via this SAP or SDP are copied. If “local”, stream comes from its own VPLS. |
Up Time | The time since the source group entry was created |
Expires | The length of time remaining before this entry ages out, in seconds |
Num Src | Indicates the number of IGMP or MLD group and source specific queries received on this SAP |
MC Stdby | (SAP only) Indicates the multicast standby state |
Number of groups | Indicates the number of groups configured for this SAP or SDP |
IGMP Group MLD Group | The IPv4 or IPv6 multicast group address for which this entry contains information |
Compat Mode | The IGMP or MLD compatibility mode. This is used in order for routers to be compatible with older version routers. IGMPv3 hosts must operate in version 1 and version 2 compatibility modes; MLD must operate in version 1 mode. IGMPv3 and MLDv2 hosts must track the compatibility mode of each attached network on a per-local-interface basis. A host's compatibility mode is determined from the host compatibility mode variable, which can be in one of three states for IGMP (IGMPv1, IGMPv2, or IGMPv3) or one of two states for MLD (MLDv1 or MLDv2). The compatibility mode variable is kept on a per-interface basis and is dependent on the version of general queries heard on that interface and the older version querier present timers for the interface. |
V1 Host Expires | The time remaining until the local router assumes that there are no longer any IGMPv1 members on the IP subnet attached to this interface. Upon receiving an IGMPv1 membership report, this value is reset to the setting of the group membership timer. While the time remaining on the timer is non-zero, the local router ignores any IGMPv3 leave messages for this group that are received on this interface. |
V2 Host Expires | The time remaining until the local router assumes that there are no longer any IGMPv2 members on the IP subnet attached to this interface. Upon receiving an IGMPv2 membership report, this value is reset to the setting of the group membership timer. While the time remaining on the timer is non-zero, the local router ignores any IGMPv3 leave messages for this group that are received on this interface. |
MVR From-VPLS | The VPLS from which the multicast VPLS registration (MVR) streams corresponding to the groups learned via this SAP or SDP are copied. If “local”, it is from its own VPLS. |
MVR To-SAP | The SAP to which the multicast VPLS registration (MVR) streams corresponding to the groups learned via this SAP or SDP are copied. If “local”, it is from its own VPLS. |
Source Address | The source address for which this entry contains information |
Fwd/Blk | Indicates whether the corresponding multicast stream will be blocked or forwarded |
This command displays information on the IGMP or MLD snooping proxy reporting database for the VPLS service.
The following outputs are examples of proxy reporting database information for IGMP snooping and MLD snooping displays for the specified VPLS service, and Table 74 describes the fields.
Label | Description |
IGMP Group Address | The IP multicast group address for which this entry contains information |
Up Time | The time since the source group entry was created |
Mode | The type of membership reports received on the interface for the group: include or exclude Include — reception of packets sent to the specified multicast address is requested only from those IP source addresses listed in the source-list parameter of the IGMP or MLD membership report Exclude — reception of packets sent to the given multicast address is requested from all IP source addresses except those listed in the source-list parameter |
Source Address | The source address for which this entry contains information |
Num Sources | Indicates the number of IGMP or MLD group and source specific queries received on this SAP |
Number of groups | Indicates the number of groups configured for this SAP or SDP |
This command displays information on the current IGMP or MLD snooping querier for the VPLS service.
The following outputs are examples of querier information for IGMP snooping and MLD snooping displays for the specified VPLS service, and Table 75 describes the fields.
Label | Description |
SAP Id | The SAP ID of the service |
IP Address | The IP address of the querier |
Expires | The length of time remaining before this query ages out, in seconds |
Up Time | The length of time that the query has been enabled |
Version | The configured version of IGMP or MLD |
General Query Interval | The frequency at which host-query packets are transmitted |
Query Response Interval | The time to wait to receive a response to the host-query message from the host |
Robust Count | The number of IGMP or MLD message intervals that are used when there is expected packet loss on the SAP or SDP. Robust count is similar to a retry counter, where the number of retries is robust count minus one packet. |
This command displays information on static IGMP or MLD snooping source group membership for the VPLS service.
The following outputs are examples of static SAP or SDP multicast source and group information for IGMP snooping and MLD snooping displays for the specified VPLS service, and Table 76 describes the fields.
Label | Description |
Source | The source IP address of the static group |
Group | The group IP address of the static (S,G) or (*/G) |
Static (*,G)/(S,G) entries | The number of static (S,G) or (*, G) entries |
This command displays IGMP or MLD snooping statistics information for the specified VPLS SAP or SDP.
The following outputs are examples of multicast statistics for SAPs and SDPs for IGMP snooping and MLD snooping displays for the specified VPLS service, and Table 77 describes the fields.
Label | Description |
Message Type | The column heading for IGMP or MLD snooping messages |
General Queries | The number of general query messages received, transmitted, and forwarded |
Group Queries | The number of group query messages received, transmitted, and forwarded |
Group-Source Queries | The number of group-source query messages received, transmitted, and forwarded |
V1 Reports | The number of IGMPv1 or MLDv1 report messages received, transmitted, and forwarded |
V2 Reports | The number of IGMPv2 or MLDv2 report messages received, transmitted, and forwarded |
V3 Reports | (IGMP only) The number of IGMPv3 report messages received, transmitted, and forwarded |
V2 Leaves | (IGMP only) The number of IGMP leave messages received, transmitted, and forwarded |
V1 Done | (MLD only) The number of MLD done messages received, transmitted, and forwarded |
Unknown Type | The number of unknown type messages received, transmitted, and forwarded |
Drop Statistics | |
Bad Length | The number of packets dropped due to bad length |
Bad IP Checksum | (IGMP only) The number of packets dropped due to a bad IP checksum |
Bad IGMP Checksum Bad MLD Checksum | The number of packets dropped due to a bad IGMP or MLD checksum |
Bad Encoding | The number of packets dropped due to bad encoding |
No Router Alert | The number of packets dropped because there was no router alert |
Zero Source IP | The number of packets dropped due to a source IP address of 0.0.0.0 or 00:00:00:00:00:00:00:00 |
Wrong Version | The number of packets dropped due to a wrong version of IGMP or MLD |
Lcl-Scope Packets | The number of local scope packets dropped |
Rsvd-Scope Packets | The number of reserved scope packets dropped |
Send Query Cfg Drops | The number of messages dropped because of send query configuration errors |
Import Policy Drops | The number of messages dropped because of import policy |
Exceeded Max Num Groups | The number of packets dropped because the maximum number of groups has been exceeded |
Exceeded Max Num Sources | The number of packets dropped because the maximum number of sources has been exceeded |
Exceeded Max Num Grp Srcs | The number of packets dropped because the maximum number of group sources has been exceeded |
MCAC Policy Drops | The number of packets dropped due to multicast CAC |
MCS Failures | The number of packets dropped due to multicast server (MCS) failures |
MVR From VPLS Cfg Drops | The number of packets dropped due to VPLS configuration multicast VPLS registration (MVR) |
MVR To SAP Cfg Drops | The number of packets dropped due to SAP configuration |
This command displays information about ingress and egress labels for the specified service.
The following output is an example of service label information, and Table 78 describes the fields.
Label | Description |
Svc Id | The service identifier |
Sdp Binding | The SDP binding identifier |
Type | Indicates whether the SDP is spoke or mesh |
I.Lbl | The ingress label used by the far-end device to send packets to this device in this service by the SDP |
E.Lbl | The egress label used by this device to send packets to the far-end device in this service by the SDP |
Number of Bound SDPs | The number of SDP bindings |
This command displays information related to the mac-move feature for the specified service.
The following output is an example of service MAC move information, and Table 79 describes the fields.
Label | Description |
Service Id | The service identifier |
Mac Move | The administrative state of the MAC movement feature associated with this service |
Primary Factor | A factor for the primary ports defining how many MAC relearn periods should be used to measure the MAC relearn rate |
Secondary Factor | A factor for the secondary ports defining how many MAC relearn periods should be used to measure the MAC relearn rate |
Mac Move Rate | The maximum rate at which MACs can be relearned in this service, before the SAP where the moving MAC was last seen is automatically disabled in order to protect the system against undetected loops or duplicate MACs. The rate is computed as the maximum number of relearns allowed in a 5-s interval: for example, the default rate of 2 relearns per second corresponds to 10 relearns in a 5-s period. |
Mac Move Timeout | The time, in seconds, to wait before a SAP that has been disabled after exceeding the maximum relearn rate is re-enabled. A value of 0 indicates that the SAP will not be automatically re-enabled after being disabled. If after the SAP is re-enabled it is disabled again, the effective retry timeout is doubled in order to avoid thrashing. |
Mac Move Retries | The number of times retries are performed for re-enabling the SAP or SDP |
SAP Mac Move Information: | |
Admin State | The administrative state of the SAP |
Oper State | The operational state of the SAP |
Flags | Specifies the conditions that affect the operating status of this SAP. Display output includes: ServiceAdminDown, PortOperDown, L2OperDown. |
Time to RetryReset | The time, in seconds, to wait before a SAP that has been disabled after exceeding the maximum relearn rate is re-enabled. A value of 0 indicates that the SAP will not be automatically re-enabled after being disabled. If after the SAP is re-enabled it is disabled again, the effective retry timeout is doubled in order to avoid thrashing. |
Retries Left | The number of remaining attempts to re-enable the SAP |
Mac Move | Specifies whether MAC move is configured as blockable or not blockable on the SAP |
Blockable Level | Specifies the level at which MAC move is blockable on the SAP (primary, secondary, or tertiary) |
SDP Mac Move Information: | |
Admin State | The administrative state of the SDP |
Oper State | The operational state of the SDP |
Flags | Specifies the conditions that affect the operating status of this SDP. Display output includes: SvcAdminDown, SdpOperDown, NoIngVCLabel, NoEgrVCLabel, PathMTUTooSmall. |
Time to RetryReset | The time, in seconds, to wait before a SDP that has been disabled after exceeding the maximum relearn rate is re-enabled. A value of 0 indicates that the SDP will not be automatically re-enabled after being disabled. If after the SDP is re-enabled it is disabled again, the effective retry timeout is doubled in order to avoid thrashing. |
Retries Left | The number of remaining attempts to re-enable the SDP |
Mac Move | Specifies whether MAC move is configured as blockable or not blockable on the SDP |
Blockable Level | Specifies the level at which MAC move is blockable on the SDP (primary, secondary, or tertiary) |
This command displays information about SAPs. When the sap command is used without specifying a sap-id, the display shows all the information for all SAPs in the service. Including the sap-id and a filtering keyword with the sap command displays information pertaining to the keyword.
The following output is an example of service SAP information, and Table 80 describes the fields.
Label | Description |
Service Id | The service identifier |
SAP | The SAP identifier |
Encap | The encapsulation type of the SAP |
Admin State | The administrative state of the SAP |
Oper State | The operating state of the SAP |
Flags | Specifies the conditions that affect the operating status of this SAP. Display output includes: ServiceAdminDown, SapAdminDown, InterfaceAdminDown, PortOperDown, PortMTUTooSmall, L2OperDown, SapIngressQoSMismatch, SapEgressQoSMismatch, RelearnLimitExceeded, RxProtSrcMac, ParentIfAdminDown, NoSapIpipeCeIpAddr, TodResourceUnavail, TodMssResourceUnavail, SapParamMismatch, CemSapNoEcidOrMacAddr, StandByForMcRing, ServiceMTUTooSmall, SapIngressNamedPoolMismatch, SapEgressNamedPoolMismatch, NoSapEpipeRingNode. |
Last Status Change | The time of the most recent operating status change to this SAP |
Last Mgmt Change | The time of the most recent management-initiated change to this SAP |
Sub Type | The supported sub type: regular |
Split Horizon Group | Indicates the split horizon group that this SAP is a member of |
Admin MTU | The desired largest service frame size (in octets) that can be transmitted through the SAP to the far-end router, without requiring the packet to be fragmented |
Oper MTU | The actual largest service frame size (in octets) that can be transmitted through the SAP to the far-end router, without requiring the packet to be fragmented |
Ingr IP Fltr-Id | The IPv4 ingress filter policy ID assigned to the SAP |
Egr IP Fltr-Id | The IPv4 egress filter policy ID assigned to the SAP |
Ingr Mac Fltr-Id | Not applicable |
Egr Mac Fltr-Id | Not applicable |
Ingr IPv6 Fltr-Id | The IPv6 ingress filter policy ID assigned to the SAP |
Egr IPv6 Fltr-Id | The IPv6 egress filter policy ID assigned to the SAP |
tod-suite | Indicates whether a time-based policy is applied to a multiservice site |
qinq-pbit-marking | Indicates the qinq P-bit marking for the service: both or top |
Ing Scheduler Mode | The scheduler mode for the SAP in the access ingress direction: 4-priority or 16-priority |
Egr Scheduler Mode | The scheduler mode for the SAP in the access egress direction: 4-priority or 16-priority |
Ing Agg Rate Limit | The PIR rate limit in the access ingress direction for the aggregate of the SAP queues |
Egr Agg Rate Limit | The PIR rate limit in the access egress direction for the aggregate of the SAP queues |
Ing Agg cir | The CIR rate limit in the access ingress direction for the aggregate of the SAP queues |
Egr Agg cir | The CIR rate limit in the access egress direction for the aggregate of the SAP queues |
Ing Shaper Group | The ingress shaper group for the SAP |
Egr Shaper Group | The egress shaper group for the SAP |
ARP Reply Agent | Specifies whether the ARP reply agent is enabled |
Host Conn Verify | Specifies the state of verifying host connectivity (enabled or disabled) |
Mac Learning | Specifies whether MAC learning is enabled |
Discard Unkwn Srce | Specifies whether frames received with an unknown destination MAC are discarded |
Mac Aging | Specifies whether MAC aging is enabled |
Mac Pinning | Specifies whether MAC pinning is enabled |
Acct. Pol | The accounting policy ID applied to the SAP |
Collect Stats | Specifies whether accounting statistics are collected on the SAP |
Time to RetryReset | The time, in seconds, to wait before a SAP that has been disabled after exceeding the maximum relearn rate is re-enabled A value of 0 indicates that the SAP will not be automatically re-enabled after being disabled. If after the SAP is re-enabled it is disabled again, the effective retry timeout is doubled in order to avoid thrashing. |
Retries Left | The number of remaining attempts to re-enable the SAP |
Mac Move | Indicates the administrative state of the MAC movement feature associated with the SAP |
Blockable Level | Specifies the level at which MAC move is blockable on the SAP (primary, secondary, or tertiary) |
PPPoE Circuit-Id | Specifies the agent-circuit-id, as specified in RFC 4679 (applies to ATM VPLS instances only) |
Stp Service Access Point specifics | |
The fields under STP SAP specifics do not apply to VPLS services on the 7705 SAR. | |
QOS | |
Ingress qos-policy | The ingress QoS policy ID assigned to the SAP |
Egress qos-policy | The egress QoS policy ID assigned to the SAP |
Shared Q plcy | Not applicable |
Multipoint shared | Not applicable |
DHCP | |
Admin State | Specifies whether DHCP Relay is enabled on this SAP |
DHCP Snooping | The status of the DHCP snooping function (up or down) |
Action | The DHCP action to be used for the Relay Agent Information Option (Option 82) processing (forward, drop, or keep) |
Subscriber Management | |
The fields under subscriber management do not apply to VPLS services on the 7705 SAR. | |
Sap Statistics | |
Last Cleared Time | The date and time that a clear command was issued on statistics |
Forwarding Engine Stats | |
Dropped | The number of packets or octets dropped by the forwarding engine |
Off. HiPrio | The number of high-priority packets or octets offered to the forwarding engine |
Off. LowPrio | The number of low-priority packets offered to the forwarding engine |
Queueing Stats (Ingress QoS Policy) | |
Dro. HiPrio | The number of high-priority packets or octets discarded, as determined by the SAP ingress QoS policy |
Dro. LowPrio | The number of low-priority packets discarded, as determined by the SAP ingress QoS policy |
For. InProf | The number of in-profile packets or octets (rate below CIR) forwarded, as determined by the SAP ingress QoS policy |
For. OutProf | The number of out-of-profile packets or octets (rate above CIR) forwarded, as determined by the SAP ingress QoS policy |
Queueing Stats (Egress QoS Policy) | |
Dro. InProf | The number of in-profile packets or octets discarded, as determined by the SAP egress QoS policy |
Dro. OutProf | The number of out-of-profile packets or octets discarded, as determined by the SAP egress QoS policy |
For. InProf | The number of in-profile packets or octets (rate below CIR) forwarded, as determined by the SAP egress QoS policy |
For. OutProf | The number of out-of-profile packets or octets (rate above CIR) forwarded, as determined by the SAP egress QoS policy |
Sap per Queue stats | |
Ingress Queue n | The index of the ingress QoS queue of this SAP, where n is the index number |
Off. HiPrio | The number of packets or octets of high-priority traffic for the SAP (offered) |
Off. LoPrio | The number of packets or octets of low-priority traffic for the SAP (offered) |
Dro. HiPrio | The number of high-priority traffic packets or octets dropped |
Dro. LoPrio | The number of low-priority traffic packets or octets dropped |
For. InProf | The number of in-profile packets or octets (rate below CIR) forwarded |
For. OutProf | The number of out-of-profile packets or octets (rate above CIR) forwarded |
Egress Queue n | The index of the egress QoS queue of the SAP, where n is the index number |
For. InProf | The number of in-profile packets or octets (rate below CIR) forwarded |
For. OutProf | The number of out-of-profile packets or octets (rate above CIR) forwarded |
Dro. InProf | The number of in-profile packets or octets dropped for the SAP |
Dro. OutProf | The number of out-of-profile packets or octets discarded |
ATM SAP Configuration Information | |
Ingress TD Profile | The profile ID of the traffic descriptor applied to the ingress SAP |
Egress TD Profile | The profile ID of the traffic descriptor applied to the egress SAP |
Alarm Cell Handling | Indicates that OAM cells are being processed |
OAM Termination | Indicates whether this SAP is an OAM termination point |
AAL-5 Encap | Indicates the type of AAL5 encapsulation for this ATM SAP |
OAM Termination | Indicates the state of the OAM termination for this ATM SAP (enabled or disabled) |
Periodic Loopback | Indicates the state of the periodic loopback for this ATM SAP (enabled or disabled) |
This command displays information about SDPs. When the sdp command is used without specifying a sdp-id, the display shows all the information for all SDPs in the service. Including the sdp-id and a filtering keyword with the sdp command displays information pertaining to the keyword.]
The following output is an example of service SDP information, and Table 81 describes the fields.
Label | Description |
SDP Id | The SDP identifier |
Type | Indicates whether this service SDP binding is a spoke or a mesh |
Split Horizon Group | The name of the split horizon group |
VC Type | The VC type: ether or vlan |
VC Tag | The explicit dot1q value used when encapsulating to the SDP far end |
Admin Path MTU | The desired largest service frame size (in octets) that can be transmitted through this SDP to the far-end router, without requiring the packet to be fragmented |
Oper Path MTU | The actual largest service frame size (in octets) that can be transmitted through this SDP to the far-end router, without requiring the packet to be fragmented |
Far End | Specifies the IP address of the remote end of the GRE, MPLS, or IP tunnel defined by this SDP |
Delivery | Specifies the type of delivery used by the SDP: GRE, MPLS, or IP |
Admin State | The administrative state of this SDP |
Oper State | The operational state of this SDP |
Acct. Pol | The accounting policy applied to the SDP |
Collect Stats | Specifies whether accounting statistics are collected on the SDP |
Ingress Label | The label used by the far-end device to send packets to this device in this service by this SDP |
Egress Label | The label used by this device to send packets to the far-end device in this service by this SDP |
Ing mac Fltr | Not applicable |
Egr mac Fltr | Not applicable |
Ing ip Fltr | The SDP ingress filter policy ID for IPv4 |
Egr ip Fltr | The SDP egress filter policy ID for IPv4 |
Ing ipv6 Fltr | Not applicable |
Egr ipv6 Fltr | Not applicable |
Admin ControlWord | The administrative state of the control word: Preferred (control word enabled) or Not Preferred (control word disabled) |
Oper ControlWord | The operational state of the control word: True (control word enabled) or False (control word disabled) |
Last Status Change | The date and time of the most recent status change to this SDP |
Signaling | The signaling protocol used to obtain the ingress and egress labels used in frames transmitted and received on this SDP |
Last Mgmt Change | The date and time of the most recent management-initiated change to this SDP |
Endpoint | The name of the service endpoint |
Precedence | Specifies the precedence of this SDP binding when there are multiple SDP bindings attached to one service endpoint |
PW Status Sig | Specifies whether pseudowire status signaling for spoke SDPs is enabled or disabled |
Flags | Specifies the conditions that affect the operating status of this SAP. Display output includes: ServiceAdminDown, SvcAdminDown, SdpOperDown, NoIngVCLabel NoEgrVCLabel, PathMTUTooSmall. |
Retries Left | The number of remaining attempts to re-enable the SDP |
Mac Move | The administrative state of the MAC movement feature associated with the SDP |
Blockable Level | Specifies the level at which MAC move is blockable on the SAP (primary, secondary, or tertiary) |
MAC Learning | Specifies whether MAC learning is enabled |
MAC Pinning | Specifies whether MAC pinning is enabled in this SDP |
Ignore Standby Sig | Specifies whether ignore standby signaling is configured True: standby signaling is ignored False: standby signaling is not ignored |
Block On Mesh Fail | Specifies whether to take down the spoke SDP when the mesh SDP is down True: the spoke SDP is not taken down False: the spoke SDP is taken down |
KeepAlive Information | |
Admin State | The operating status of the keepalive protocol |
Oper State | The current status of the keepalive protocol |
Hello Time | Specifies how often the SDP echo request messages are transmitted on this SDP |
Hello Msg Len | The length of the SDP echo request messages transmitted on this SDP |
Max Drop Count | The maximum number of consecutive SDP Echo Request messages that can be unacknowledged before the keepalive protocol reports a fault |
Hold Down Time | The time to wait before the keepalive operating status is eligible to enter the alive state |
Statistics | |
I. Fwd. Pkts. | The number of forwarded ingress packets |
I. Dro. Pkts. | The number of dropped ingress packets |
I. Fwd. Octs. | The number of forwarded ingress octets |
I. Dro. Octs. | The number of dropped ingress octets |
E. Fwd. Pkts. | The number of forwarded egress packets |
E. Fwd. Octets | The number of forwarded egress octets |
E. Dro. Pkts. | The number of dropped egress octets |
Grp Enc Stats | |
I. Fwd. Pkts. | The number of forwarded ingress packets |
I. Fwd. Octs. | The number of forwarded ingress octets |
I. Dro. Inv. Spi. | The number of ingress packets dropped due to an invalid SPI |
I. Dro. OthEncPkt* | The number of ingress packets dropped due to a packet encapsulation other than that configured |
E. Fwd. Pkts. | The number of forwarded egress packets |
E. Fwd. Octs. | The number of forwarded egress octets |
E. Dro. Enc. Pkts | The number of dropped egress packets |
Associated LSP LIST | If the SDP type is MPLS, a list of LSPs used to reach the far-end router displays. All the LSPs in the list must terminate at the IP address specified in the far-end field. If the SDP type is GRE, the following message displays: SDP delivery mechanism is not MPLS |
Number of SDPs | The total number of SDPs applied to this service ID |
This command displays information related to all split horizon groups in the service or the specified service split horizon group.
The following output is an example of service split horizon group information, and Table 82 describes the fields.
Label | Description |
Name | The name of the split horizon group. When preceded by “R”, the group is a residential split horizon group. |
Description | A description of the split horizon group as configured by the user |
Associations | A list of SAPs and SDPs associated with the split horizon group |
This command displays information for the spanning tree protocol instance for the service.
The following output is an example of information about service-id STP, and Table 83 describes the fields.
Label | Description |
Stp info, Service # | |
Bridge Id | The MAC address used to identify this bridge in the network |
Top Change Count | The total number of topology changes detected by the Spanning Tree Protocol instance associated with this service since the management entity was last reset or initialized |
Root Bridge | The bridge identifier of the root of the spanning tree as determined by the Spanning Tree Protocol instance associated with this service. This value is used as the Root Identifier parameter in all Configuration BPDUs originated by this node. |
Topology Change | Specifies whether a topology change is currently in progress |
Mode | Always RSTP |
Last Top. Change | The time (in hundredths of a second) since the last time a topology change was detected by the Spanning Tree Protocol instance associated with this service |
Root Port | The port number of the port that offers the lowest cost path from this bridge to the root bridge |
Stp port info | |
Sap/Sdp/PIP Id | The ID of the access port where the SAP or spoke SDP is defined |
Oper-State | Indicates the operational state of the Rapid Spanning Tree Protocol instance associated with this service. This field is applicable only when STP is enabled on the router. |
Port-State | The port identifier of the port on the designated bridge for this port's segment |
Port-Num | The value of the port number field that is contained in the least significant 12 bits of the 16-bit port ID associated with the SAP or spoke SDP |
Oper-Edge | The state of the oper-edge variable: true or false |
Link-Type | The link type (number of bridges that can exist behind the SAP or spoke SDP): pt-pt or shared |
VPLS Spanning Tree Information | |
VPLS oper state | The operational state of the Rapid Spanning Tree Protocol instance associated with this service. This field is applicable only when STP is enabled on the router. |
Core Connectivity | The connectivity status to the core |
Stp Admin State | The administrative state of the Rapid Spanning Tree Protocol instance associated with this service |
Stp Oper State | The operational state of the Rapid Spanning Tree Protocol instance associated with this service. This field is applicable only when STP is enabled on the router. |
Mode | Always RSTP |
Bridge Id | The MAC address used to identify this bridge in the network |
Bridge Priority | The priority of the Spanning Tree Protocol instance associated with this service |
Tx Hold Count | The interval length during which no more than two Configuration BPDUs shall be transmitted by this bridge |
Topology Change | Specifies whether a topology change is currently in progress |
Bridge Hello Time | The amount of time between the transmission of Configuration BPDUs |
Last Top. Change | The time (in hundredths of a second) since the last time a topology change was detected by the Spanning Tree Protocol instance associated with this service |
Bridge Max Age | The maximum age of Spanning Tree Protocol information learned from the network on any port before it is discarded. This is the actual value that this bridge is currently using. |
Top. Change Count | The total number of topology changes detected by the Spanning Tree Protocol instance associated with this service since the management entity was last reset or initialized |
Bridge Fwd Delay | Specifies how fast a bridge changes its state when moving toward the forwarding state |
MST region revision | Not applicable |
MST region name | Not applicable |
Root Bridge | The bridge identifier of the root of the spanning tree as determined by the Spanning Tree Protocol instance associated with this service. This value is used as the Root Identifier parameter in all Configuration BPDUs originated by this node. |
Root Path Cost | The cost of the path to the root bridge as seen from this bridge |
Root Forward Delay | Specifies how fast the root changes its state when moving toward the forwarding state |
Rcvd Hello Time | The amount of time between the transmission of configuration BPDUs |
Root Max Age | The maximum age of Spanning Tree Protocol information learned from the network on any port before it is discarded |
Root Priority | The priority of the bridge that is currently selected as root-bridge for the network |
Root Port | The port number of the port that offers the lowest cost path from this bridge to the root bridge |
Spanning Tree Sap/Spoke SDP Specifics | |
SAP Identifier | The ID of the access port where this SAP is defined |
SDP Identifier | The ID of the SDP and VC |
Stp Admin State | The administrative state of the Rapid Spanning Tree Protocol instance associated with this service |
Port State | The port identifier of the port on the designated bridge for this port's segment |
Port number | The value of the port number field that is contained in the least significant 12 bits of the 16-bit port ID associated with the SAP or spoke SDP |
Port Priority | The value of the port priority field that is contained in the most significant 4 bits of the 16-bit port ID associated with the SAP or spoke SDP |
Port Path Cost | The contribution of this port to the path cost of paths towards the spanning tree root which include this port |
Auto Edge | Specifies whether auto edge is enabled or disabled |
Oper Edge | The state of the oper-edge variable: true or false |
Link Type | The link type (number of bridges that can exist behind the SAP or spoke SDP): pt-pt or shared |
BPDU Encap | The type of encapsulation used on BPDUs sent out and received on this SAP or spoke SDP |
Root Guard | Specifies whether the port is allowed to become an STP root port |
CIST Desig Bridge | The bridge identifier of the bridge which this port considers to be the designated bridge for this port's segment |
Designated Port | The port identifier of the port on the designated bridge for this port's segment |
This command displays services using a range of ingress labels.
If only the mandatory start-label parameter is specified, only services using the specified label are displayed.
If both start-label and end-label parameters are specified, the services using the range of labels are displayed.
Use the show router ldp bindings command to display dynamic labels.
The following output is an example of information about services using the specified range of ingress labels, and Table 84 describes the fields.
Label | Description |
Svc ID | The service identifier |
SDP Binding | The SDP binding identifier |
Type | Indicates whether the SDP is spoke or mesh |
I.Lbl | The ingress label used by the far-end device to send packets to this device in this service by the SDP |
E.Lbl | The egress label used by this device to send packets to the far-end device in this service by the SDP |
Number of Bindings Found | The number of SDP bindings within the label range specified |
This command enables the context to display PIM snooping information.
This command displays the multicast group information.
The following output is an example of PIM snooping multicast group information, and Table 85 describes the fields.
Label | Description |
PIM Snooping Groups | |
Group Address | The IP address of the multicast group |
Source Address | The IP address of the multicast source |
Type | The type of source-group pair: (S,G) or (*,G) |
Incoming Intf | The interface identifier for the incoming multicast stream |
Num Oifs | The number of outgoing interfaces |
Groups | The number of groups displayed |
This command displays PIM neighbor information.
The following output is an example of PIM snooping neighbor information, and Table 86 describes the fields.
Label | Description |
PIM Snooping Neighbors | |
Sap/Sdp Id Nbr Address | The SAP or SDP identifier and the IP address of the neighbor |
Nbr DR Prty | The neighbor designated router parity |
Up Time | The length of time that the multicast connection has been up |
Expiry Time | The length of time remaining before the multicast connection goes down |
Hold Time | The length of time that PIM snooping checks for the PIM state |
Neighbors | The number of neighbors for the specified instance of PIM snooping |
This command displays PIM port information.
The following output is an example of PIM snooping port information, and Table 87 describes the fields.
Label | Description |
PIM Snooping Ports | |
Sap/Sdp Id | The SAP or SDP identifier for the port |
Opr | The operational state of the port: Up or Down |
This command displays PIM statistics information.
The following output is an example of PIM snooping statistics information, and Table 88 describes the fields.
Label | Description |
Message Type | |
Hello | The number of hello messages received, transmitted, and received with errors |
Join Prune | The number of join-prune messages transmitted, received, and received with errors |
Total Packets | The total number of hello and join-prune messages transmitted, received, and received with errors |
General Statistics | |
Rx Neighbor Unknown | The number of packets received from an unkown neighbor |
Rx Bad Checkum Discard | The number of packets received and discarded because of a bad checksum |
Rx Bad Encoding | The number of packets received with bad encoding |
Rx Bad Version Discard | The number of packets received and discarded because of a bad version |
Join Policy Drops | The number of join messages dropped due to the join policy actions |
Source Group Statistics | |
(S,G) | The number of (S,G)s in the multicast |
(*,G) | The number of (*,G)s in the multicast |
This command displays PIM status information.
The following output is an example of PIM snooping status information, and Table 89 describes the fields.
Label | Description |
Admin State | The administrative state of PIM snooping for the specified service |
Oper State | The operational state of PIM snooping for the specified service |
Mode Admin | The administrative mode: snoop or proxy |
Mode Oper | The operational mode: snoop or proxy |
Hold Time | The length of time that PIM snooping checks for the PIM state |
Designated Router | The IP address of the designated router |
J/P Tracking | The join-prune status |
Up Time | The length of time that the multicast connection has been up |
Group Policy | The group policy name |
This command displays SAP information.
If no optional parameters are specified, the command displays a summary of all defined SAPs.
The optional parameters restrict output to only SAPs matching the specified properties.
The following output is an example of information about SAPs matching the specified properties, and Table 90 describes the fields.
Label | Description |
Port ID | The ID of the access port where the SAP is defined |
SvcID | The service identifier |
Ing.QoS | The SAP ingress QoS policy number specified on the ingress SAP |
Ing. Fltr | The filter policy ID applied to the ingress SAP |
Egr.QoS | The SAP egress QoS policy number specified on the egress SAP |
Egr. Fltr | The filter policy ID applied to the egress SAP |
Scheduler Mode | The scheduler mode of the SAP: 4-priority or 16-priority |
Shaper Policy | Identifies the shaper policy that the shaper group belongs to |
Adm | The administrative state of the SAP |
Opr | The actual state of the SAP |
Description | The description of the SAP |
Number of SAPs | The total number of SAPs listed in the output |
GroupName | The group name of any aggregation groups |
This command clears commands for a specific service.
This command clears DHCP statistics for this service.
This command clears FDB entries for the service.
This command enables the context to clear IGMP snooping-related data.
This command enables the context to clear MLD snooping-related data.
This command clears the information on the IGMP or MLD snooping port database for the VPLS service.
This command clears the information on the IGMP or MLD snooping queriers for the VPLS service.
This command clears IGMP or MLD snooping statistics.
This command clears and resets the mesh SDP bindings for the service.
This command enables the context to clear PIM snooping information.
This command clears PIM snooping source group database information.
This command clears PIM snooping neighbor information.
This command clears PIM snooping statistics for the specified SAP or SDP.
This command clears and resets the SAP statistics for the service.
This command clears and resets the spoke SDP bindings for the service.
This command clears CEM statistics for this service.
This command clears all traffic queue counters associated with the service ID.
This command clears statistics for the spoke SDP bound to the service.
This command clears all spanning tree statistics for the service ID.
This command clears statistics for the SAP bound to the service.
This command clears keepalive statistics associated with the SDP ID.
This command enables the context to clear and reset DHCP entities.
This command clears DHCP statistics.
This command debugs commands for a specific service.
This command enables IGMP snooping debugging.
The no form of the command disables IGMP snooping debugging.
This command enables MLD snooping debugging.
The no form of the command disables MLD snooping debugging.
This command enables debugging for the IGMP or MLD tracing detail level.
The no form of the command disables debugging for the IGMP or MLD tracing detail level.
This command debugs IGMP or MLD packets for the specified MAC address.
The no form of the command disables the MAC debugging.
This command enables debugging for the IGMP or MLD tracing mode.
The no form of the command disables debugging for the IGMP or MLD tracing mode.
This command enables debugging for IGMP or MLD packets for a specific SAP.
The no form of the command disables debugging for the SAP.
This command enables debugging for a specific SDP.
The no form of the command disables debugging for the SDP.
This command enables a particular debugging event type.
The no form of the command disables the event type debugging.
This command enables PIM-snooping debugging.
This command enables or disables debugging for PIM snooping adjacencies.
This command enables or disables debugging for all the PIM snooping modules for the specified multicast address.
This command enables or disables debugging for the PIM snooping database for the specified multicast address.
This command enables or disables debugging for the PIM snooping join-prune mechanism for the specified multicast address.
This command enables or disables debugging for PIM snooping packets.
This command enables or disables debugging for PIM snooping ports.
This command enables or disables debugging for PIM snooping messages sent to the standby (redundant) CSM.
This command enables debugging for a particular SAP.
This command enables the context for debugging STP.
This command enables STP debugging for all events.
This command enables STP debugging for received and transmitted BPDUs.
This command enables STP debugging for core connectivity.
This command enables STP debugging for exceptions.
This command enables STP debugging for FSM state changes.
This command enables STP debugging for FSM timer changes.
This command enables STP debugging for changes in port roles.
This command enables STP debugging for port states.
This command enables STP debugging for a specific SAP.