Cisco IOS Release 12.0(23)SX2

These release notes provide information about Cisco IOS software Release 12.0(23)SX2 for the Cisco 10000 Series Edge Services Router (ESR). These release notes describe new features, memory requirements, hardware support, software platform deferrals, and changes to the microcode and related documents.

Cisco IOS Release 12.0(23)SX2 includes the new features and updates provided in Release 12.0(23)SX and Release 12.0(23)SX1. Cisco IOS Release 12.0(23)SX includes all of the new features introduced in Cisco IOS Release 12.0(23)S. To review the release notes for Cisco IOS Release 12.0(23)S, go to www.cisco.com and click Technical Documents > Aggregation > Cisco 10000 Series Edge Services Routers > Cisco 10000 Series ESR Release Notes > Release Notes for the Cisco 10000 Series ESR for Cisco IOS Release 12.0(23)S.

You can also view the release notes for Cisco IOS Release 12.0(23)S at the following URL:

Upgrading to a New Software Release

For specific information about upgrading your Cisco 10000 series ESR to a new software release, see the Cisco 10000 Series ESR Software Configuration Guide at the following URL:

For general information about how to upgrade to a new software release, see the product bulletin Cisco IOS Upgrade Ordering Instructions located at:

For information about how to order Cisco IOS software, refer to the Cisco IOS Software Releases URL:

Upgrading Software from Earlier Cisco IOS Releases

Upgrading from Cisco IOS Release 12.0(21)SX or Release 12.0(21)SX1

If you are upgrading your software from Cisco IOS Release 12.0(21)SX or Release 12.0(21)SX1 to Cisco IOS Release 12.0(23)SX2, you must upgrade the eboot image on the Cisco 10000 series edge services router (ESR). If you fail to upgrade the eboot image, the ESR configuration may not load properly, and a checksum error appears on the console. If you are upgrading the software from an earlier Cisco IOS release, you do not need to upgrade the eboot image.

Upgrading from Cisco IOS Release 12.(14)SL or from Earlier 12.0(x)SL-based Releases

If you are upgrading your software from Cisco IOS Release 12.0(14)SL or from earlier 12.0(x)SL-based releases to Cisco IOS Release 12.0(23)SX2, save your current configuration file. If you decide to reinstall Release 12.0(14)SL or an earlier release, you must also reinstall the configuration file associated with that release. This is because some Border Gateway Protocol (BGP) configuration-file entries in Release 12.0(23)SX2 are not compatible with Release 12.0(14)SL or earlier releases.

Upgrading Software on Redundant PREs

When you upgrade software on redundant Cisco 10000 series Performance Routing Engines (PREs), be sure to download the software to both the active PRE and the standby PRE before you reload both PREs. For more information, refer to the "Upgrading Software on Redundant PREs" section in the "System Startup and Basic Configuration Tasks" of the Cisco 10000 Series ESR Software Configuration Guide at the following URL:

System Requirements

This release requires that you have the PRE1 version (part number ESR-PRE1) of the Performance Routing Engine (PRE) installed in the Cisco 10000 series ESR chassis. To verify which PRE is installed in the ESR, use the show version command.

Memory Requirements

Feature Set by Router	Image Name	Flash Memory	DRAM Memory	Runs From
Edge Services Router	c10k-p10-mz	40 MB	512 MB	RAM
Service Provider/ Secured Shell 3DES	c10k-k4p10-mz	40 MB	512 MB	RAM

New Features in Cisco IOS Release 12.0(23)SX2 and 12.0(23)SX1

New Features in Cisco IOS Release 12.0(23)SX

The following sections describe the new features and improvements introduced in Cisco IOS Release 12.0(23)SX:

Multirouter-Automatic Protection Switching

The multirouter-automatic protection switching (MR-APS) feature allows switchover of SONET connections in the event of circuit failure. MR-APS is often required when connecting SONET equipment to telco equipment. APS refers to the mechanism of using a "protect" SONET interface in the SONET network as the backup for a working SONET interface. When the working interface fails, the protect interface quickly assumes its traffic load.

The protection mechanism provided by MR-APS has a linear 1+1 architecture, as described in the Bellcore publication TR-TSY-000253, SONET Transport Systems; Common Generic Criteria, Section 5.3. The connection may be bidirectional or unidirectional, and revertive or non-revertive.

MR-APS provides a protection mechanism in which the "working" and "protect" SONET interfaces are on separate routers. MR-APS also allows both interfaces to be on the same router. However, in this case, we recommend you use single router-APS instead.

Single router-APS (SR-APS) provides a protection mechanism in which the working and protect interfaces are both on the same router. This protection mechanism provides a linear 1+1 unidirectional, non-revertive architecture. Note that the ESR supports bridging in the SR-APS implementation.

For more information on this feature, see the following URL. Note that the documentation includes aps commands for POS interfaces. However, the same commands also apply for ATM interfaces.

Recommendation for MR-APS Configurations with Limited Static Routes

If your MR-APS configuration has a limited number of static routes (for example, less than 10), we recommend that you use the following command for gigabit Ethernet, ATM, and POS interfaces that have static routes configured for them.

The command adds static routes to the routing table immediately when an interface becomes active, rather than after a route dampening period ends.

Restrictions

Multicast for MPLS/VPN

The Multicast for Multiprotocol Label-Switching (MPLS)/Virtual Private Network (VPN) feature allows service providers to offer multicast services over their MPLS core network. Multicast for MPLS/VPN allows end-user customers to improve productivity and communication flow for applications such as corporate communication, e-learning, data warehousing, content synchronization, trading stocks and commodities (stock quotes and ticker information), and emergency messaging services.

Live video and Video-on-Demand applications also require a multicast solution that offers scalability, efficiency, and performance. As demand grows for multicast and VPN, enterprises will require service providers to enable multicast across VPNs. Multicast for MPLS/VPN provides that solution.

MPLS Traffic Engineering Fast Reroute

The Fast Reroute (FRR) link protection feature of MPLS traffic engineering provides link protection to label-switched paths (LSPs). MPLS traffic engineering automatically establishes and maintains LSPs across the backbone using Resource ReSerVation Protocol (RSVP). Paths for LSPs are calculated at the headend, based on the LSP resource requirements and available network resources such as bandwidth. Under failure conditions, the headend determines a new route for the LSP. This provides for the optimal use of resources. However, due to messaging delays, recovery at the headend is not as quick as recovery at the point of failure.

FRR link protection enables the router to reroute traffic around a failed link without involving the headend in the rerouting decision. This provides quicker recovery time and prevents any further packet loss caused by the failed link. The headend of the tunnel is also notified of the link failure through the IGP or RSVP; the headend then attempts to establish a new LSP that bypasses the failure.

Restrictions

DiffServe Aware Traffic Engineering for MPLS

The DiffServer Aware Traffic Engineering feature extends DiffServe quality of service (QoS) over an MPLS backbone that uses traffic engineering. Bandwidth pools assigned to tunnel interfaces ensure that critical data is associated with a tunnel that has enough bandwidth to transport data over the MPLS network. For information about this feature, see the following URL:

eiBGP Multipath Load Sharing

This section describes the Border Gateway Protocol (BGP) Multipath Load Sharing for external BGP (eBGP) and internal BGP (iBGP) in a Multiprotocol Label Switching (MPLS) Virtual Private Network (VPN) feature. This feature allows you to configure multihomed autonomous systems and provider edge (PE) routers to:

BGP installs up to the maximum number of paths allowed (configured by the maximum-paths command). BGP uses the best path algorithm to select one multipath as the best path, insert the best path into the routing information base (RIB), and advertise the best path to BGP peers. Other multipaths may be inserted into the RIB, but only one path will be selected as the best path.

The multipaths are used by Cisco Express Forwarding (CEF) to perform load balancing on a per-packet or per-source or destination pair basis. The eiBGP Multipath Load Sharing feature performs unequal cost load balancing by default by selecting BGP paths that do not have an equal cost of the Interior Gateway Protocol (IGP). To enable this feature, configure the router with MPLS VPNs that contain VPN routing and forwarding instances (VRFs) that import both eBGP and iBGP paths. The number of multipaths can be configured separately for each VRF.

Restrictions

Route Reflector Limitation—With multiple iBGP paths installed in a routing table, a route reflector will advertise only one of the paths (one next hop). If a router is behind a route reflector, all routers that are connected to multihomed sites will not be advertised unless separate VRFs with different RDs are configured for each VRF.

Memory Consumption Restriction—Each IP routing table entry for a BGP prefix that has multiple iBGP paths uses additional memory. We recommend not using this feature on a router with a low amount of available memory and especially when the router is carrying a full Internet routing table.

Link Fragmentation and Interleaving

Interactive traffic (Telnet, voice on IP, and the like) is susceptible to increased latency and jitter when the network processes large packets, (LAN-to-LAN FTP transfers traversing a WAN link, for example), especially as they are queued on slower links. The Link Fragmentation and Interleaving (LFI) feature reduces delay and jitter on slower-speed links by breaking up large datagrams and interleaving low-delay traffic packets (such as voice) with the smaller packets resulting from the fragmented datagram. LFI was designed especially for lower-speed links where serialization delay is significant.

The Cisco 10000 series ESR implementation of LFI provides the following benefits:

Cisco 10000 Series ESR LFI Limitations and Restrictions

The following limitations and restrictions apply to the Cisco 10000 series ESR implementation of LFI

fragments received (in_frag)
fragments dropped (drop_frag)
fragments transmitted (out_frag)

in fragmented pkts
in fragmented bytes
in dropped reassembling packets
in timeouts
out interleaved packets
out fragmented pkts
out fragmented bytes
out dropped fragmenting pkts

Cisco 10000 Series ESR LFI Implementation Notes

The following sections provide information about the LFI implementation on the Cisco 10000 series ESR:

MLPPP LFI Packet Counts

On an MLPPP interface that has LFI enabled, each packet fragment is counted as a separate packet in the interface's input and output statistics. For example, if a single packet is fragmented into three packets, the the show interface stats command and the show interfaces commands show a count of 3 for Packets In and Packets Out, rather than a count of 1.

Configuring LFI on a Frame Relay Interface—Method 1

One way to configure LFI on a Frame Relay data-link connection identifier (DLCI) is to:

The following is a sample configuration showing this method of configuring LFI. (In this example, fragment size is 384 bytes and the bandwidth for the priority queue is 307 kbps.)

Configuring LFI on a Frame Relay Interface—Method 2

You can also use a nested policy and access lists to configure LFI on a Frame Relay DLCI as follows:

The following is a sample configuration showing this method of configuring LFI. (In the example, fragmentation size is 768 bytes and bandwidth for the priority queue is 10 percent of the link bandwidth.)

Configuring LFI on a Multilink PPP Interface

Command	Purpose
ppp multilink	Enables multilink operation on the interface.
ppp multilink fragmentation	Enables multilink fragmentation on the interface.
ppp multilink fragment-delay milliseconds	(Optional) Specifies the maximum delay (in milliseconds) for fragmentation (for example, you can specify that voice traffic has a maximum fragmentation delay of 20 milliseconds). MLP uses this value to choose a fragment size.
ppp multilink interleave	Enables real-time packet interleaving on the bundle.

The following commands show an example of how to configure LFI on an MLPPP interface:

Single Rate 3-Color Marker for Traffic Policing

The single rate 3-Color Marker feature meters an IP packet stream and marks its packets different colors, based on the Committed Information Rate (CIR) and two associated burst sizes: Committed Burst Size (CBS) and Excess Burst Size (EBS). CIR is measured in bytes of IP packets per second (and it includes the IP header, but not link specific headers). CBS and EBS are measured in bytes.

Previously, the ESR supported a single rate, 2-color marker. The single rate, 3-color marker allows the ESR to classify packets that violate the EBS. This feature is useful, for example, for ingress policing of a service, where service eligibility is determined only by the burst's length, and not its peak rate.

The marker starts with a surplus equal to Be or EBS, and replenishes the surplus by the amount of unused CIR allowance until the surplus reaches Be or EBS.

Configuring the Single Rate Three-Color Marker Feature

For conform, exceed, and violate action, you can specify one of the following actions: transmit, set-dscp-transmit, set-prec-transmit, set-mpls-exp-transmit, or set-qos-transmit.

Using the Feature

The 3-color marker can be used to mark a packet stream in a service, where different, decreasing levels of assurances (either absolute or relative) are given to packets which are green, yellow, or red. For example, a service might:

Cisco 10000 ESR MIB Enhancements

For more information about the ESR MIB capabilities for this release, see the Cisco 10000 Series ESR Leased Line MIB Specifications Guide (version 3) at the following URL. (Table 3-1 in the "MIB Specifications" section of the guide lists the MIBs supported in this release.)

SNMP Trap Filtering

Use the SNMP trap filtering feature to filter linkDown traps so that SNMP only sends a linkDown trap if the main interface goes Down. If a Cisco 10000 series ESR interfaces goes Down, all of its subinterfaces go Down, which results in numerous linkDown traps for each subinterface. This feature filters out those subinterface traps. This feature is turned off by default.

To enable the SNMP trap filtering feature, issue the following CLI command. Use the no form of the command to disable the feature.

Limitations and Restrictions

PRE Network Management Ethernet Port

Ensure that the Fast Ethernet NME port on the PRE is configured for auto-negotiation mode, which is the system default. Duplex mode can cause problems, such as flapping. If the port is experiencing such problems and has been configured for duplex mode, use the no half-duplex or no full-duplex command to disable duplex mode.

Controlling the Rate of Logging Messages

It is important that you limit the rate that system messages are logged by the Cisco 10000 series ESR. This helps to avoid a situation in which the router becomes unstable and the CPU is overloaded. To control the output of messages from the system, use the logging rate-limit command.

We recommend that you configure the logging rate-limit command as follows. This rate-limits all messages to the console to 10 per second, except for messages with critical priority (level 3) or greater.

For more information on the logging rate-limit command, see the Cisco IOS Configuration Fundamentals Command Reference.

Frame Relay

The following limitations apply to the Cisco 10000 series ESR implementation of Frame Relay:

Nested Policy Feature

The following limitations and restrictions apply to the Cisco 10000 series ESR nested policy feature:

Testing Performance of High-Speed Interfaces

Cisco IOS software running on the Cisco 10000 series ESR has multiple queues for all classes of traffic over high-speed interfaces. The software selects a queue based on the source and destination address for the packet. This ensures that a traffic flow always uses the same queue and the packets are transmitted in proper order.

When the Cisco 10000 series ESR is installed in a real network, the high-speed interfaces work efficiently to spread traffic flow equally over the queues. However, using single traffic streams in a laboratory environment may result in less-than-expected performance.

To ensure accurate test results, you should test the throughput of the gigabit Ethernet, POS, or ATM uplink with multiple source or destination addresses.

Important Notes

Cisco Discovery Protocol

Unlike other Cisco routers, on the Cisco 10000 series ESR the Cisco Discovery Protocol (CDP) is disabled by default. You can enable CDP on an interface using the cdp enable command.

Frame Relay and PPP Sessions

You can run up to 4000 Frame Relay sessions or 4000 PPP sessions, and you can configure up to 800 Border Gateway Protocol (BGP) peers on the Cisco 10000 series ESR. The ESR also supports up to 512 Multilink Point-to-Point (MLP) protocol sessions and up to 1024 MLP bundles.

Performance Routing Engine 1 (PRE1) on the Cisco 10000 Series Edge Services Router

In order for Cisco IOS Release 12.0(22)S and later releases to run on the Cisco 10000 series ESR, the Performance Routing Engine (PRE) installed in the chassis must be the PRE1 version (part number ESR-PRE1). You can verify which PRE is installed in the chassis by using the show version command.

VLAN Session Support

Inserting a New Line Card

Unlike other Cisco routers, if you insert a new or different line card into a Cisco 10000 series ESR chassis slot that previously had a line card installed, the line card initially reports that it is administratively Up.

RBE Subinterfaces

To ensure that the Performance Routing Engine (PRE) microcode has adequate IP address space, use IP addresses in a contiguous address space. Also, use the ip unnumbered command on the RBE subinterface.

Resolved Caveats in Cisco IOS Release 12.0(23)SX2

CSCdx87500

The mstat and mtrace commands now work correctly over a multicast distribution tree (MDT) tunnel.

CSCdy50036

The show ip pim mdt history command now displays the correct reuse value for MDT data groups. Previously, in cases where one MDT data group was being reused and another group was being used only one time, the command incorrectly showed that both groups were being reused.

CSCdz28485

When the default MDT group is removed on the remote provider edge (PE), the Cisco 10000 series ESR no longer stops responding or experiences spurious access.

CSCdz28491

The router no longer loses tunnel information when an MDT default group is removed from a remote PE.

CSCdz30254

The router no longer displays a card provisioning conflict message when the configuration is downloaded after a Cisco IOS software reload. Previously, this message appeared even though the cards were never removed from the chassis and the configuration was not changed.

CSCdz32805

The router now forms data MDTs consistently when configured for use in a multicast Virtual Private Network (VPN) environment.

CSCdz55717

The Open Shortest Path First (OSPF) router process no longer experiences a memory leak when OSPF sham links are configured in a Multiprotocol Label Switching (MPLS) VPN environment.

CSCea18595

When configured for multicast VPN, the router now correctly triggers an assertion when it receives data on a tunnel interface.

CSCea27138

When configured for multicast VPN, the router now handles MDT data mappings correctly. Previously, when the router was configured as a receiving PE router, the router deleted MDT mappings too quickly, or did not delete them at all.

CSCea27231

When you use the priority command to assign link bandwidth to priority-queue traffic, the traffic is dequeued and scheduled at the specified bandwidth. Previously, the traffic was dequeued and scheduled at the full link bandwidth, which was incorrect.

CSCea33501

Setting the MAC rewrite index to zero no longer causes the parallel express forwarding (PXF) network processor to reload.

CSCea54257

Link Fragmentation and Interleaving (LFI) now correctly handles 1-part dequeuing with two buffers.

CSCea61833

The Parallel eXpress Forwarder (PXF) no longer generates a T1 SW Exception error when multicast traffic with an IP precedence of 5 is sent over the priority queue.

CSCea70433

CSCea71781

When multicast VPN and Multicast Source Discovery Protocol (MSDP), the router no longer generates a LINK-2-LINEST message when it receives a broadcast IP packet on a multicast VPN tunnel.

Resolved Caveats in Cisco IOS Release 12.0(23)SX1

CSCdy01660

MIB walks on the sonetVTIntervalTable and sonetFarEndVTIntervalTable (SONET-MIB) now work correctly. Previously, information in the tables was deleted after 24 hours, which caused MIB walks to loop.

CSCdz00466

SNMP now provides correct values for the MIB objects atmTrafficDescrType and atmTrafficQoSClass for all types of PVCs. Note that this problem was a duplicate of CSCdp53356, which has been fixed.

CSCdz29005

On Cisco channelized OC-12 and channelized STM line cards, the SNMP MIB object ifOperStatus now correctly shows T1 layers as Down when all other layers are Down.

CSCdz30172

A traceback message no longer appears during stateful switchover (SSO) testing of PPP.

CSCdz30287

The Cisco 10000 series ESR now shapes traffic correctly when LFI is enabled on an MLP bundle running over a T1 channel.

CSCdz36334

Previously, when a priority queue (PQ) was underloaded and fragmentation queues (FQs) were overloaded, the PQ Max latency and Avg latency values were higher than they should have been. The latency values are now correct. Note that this problem was a duplicate of CSCdz70148, which has been fixed.

CSCdz40022

The show interface command now shows correct input and output byte counts for MLP interfaces with LFI enabled. The clear counters command also clears the output packet and byte counters as it should.

CSCdz49398

A traceback message no longer appears while using the 3-color policer to police 1000 VLANs.

CSCdz50858

A stateful switchover (SSO) no longer causes a Cisco 10000 series ESR with redundant PRE-1 cards and channelized OC-12 or channelized STM line cards to experience a traceback or %CEF fibidb error.

CSCdz51638

The show frame-relay fragment command increments the "out-frag" and "out fragmented" counts as it should. Previously, the counts did not increment.

CSCdz56052

Cisco channelized T3 (CT3) line cards no longer stop responding when 1000 Frame Relay or MLP interfaces (with LFI enabled) are configured over two CT3 line cards. Note that CSCdz49702 is a duplicate of this.

CSCdz58839

A PXF failure no longer occurs when a fast reroute (FRR) is performed after a primary link fails. This problem was observed when the Cisco 10000 series ESR was configured as an MPLS traffic engineering (TE) tunnel head and FRR break point, and the primary link had 500 tunnels.

CSCdz70148

The Cisco 10000 series ESR now processes priority traffic correctly. Previously, when priority traffic arrived in a burst or exceeded the configured rate, the traffic experienced a longer-than-expected delay.

CSCdz77838

A PXF microcode reload no longer breaks MPLS/VPN multicast traffic forwarding. Previously, a reload could cause Protocol Independent Multicast (PIM) VPN routing/forwarding (VRF) neighbor relationships to be lost. When this happened, the Cisco 10000 series ESR stopped forwarding VRF multicast traffic.

CSCea13379

Previously, when the Cisco 10000 series ESR received PIM (*,G) joins with (S,G)R prune, the router incorrectly forwarded only the (*,G) joins to the rendezvous point (RP). Now, the router correctly forwards the (*,G) joins with (S,G)R prune.

CSCea15963

When two redundant provider edge (PE) Cisco 10000 series ESRs are connected to a single Virtual Private Network (VPN), both routers might send different multicast distributed tunnel-Join (MDT-Join) updates to the VPN source. This can cause the receivers to toggle between different MDT data groups, which results in intermediate data loss for the receivers.

CSCea18756

Previously, the Netflow aggregation test failed to match the correct prefix, mask, and AS values for source, destination, prefix, and AS types of aggregation schemes. Now, the values match as expected.

Open Caveats

Table 1 Open Caveats

Caveat	Description
General
CSCdz02942	After a stateful switchover (SSO) in a redundant PRE system, the MIB objects ifLastChange (IF-MIB) and atmVclLastChange (ATM-MIB) might not match sysUpTime.0 (MIB-2), but they should. This problem can occur: After a second switchover When the standby PRE is reset, followed by a switchover When the standby PRE is inserted in the chassis later, after insertion of the primary PRE Workaround: None.
CSCdz26218	The Parallel eXpress Forwarder (PXF) diversion statistics do not clear when you issue the microcode reload all command, although they should. Workaround: Reload the Cisco IOS software.
CSCdz29077	After you issue the commands shutdown and no shutdown on a Cisco channelized OC-12 line card, the show controller t3 command incorrectly displays the T3 controller as Down. The controller is really Up. Workaround: Issue the shutdown command, wait several seconds, and then issue the no shutdown command on the SONET interface. Doing so sets the T3 interface to Up in the show controller t3 command.
CSCdz32795	A routing policy does not count packets of 65 bytes or larger. The packets are transported, but not counted. Workaround: None.
CSCdz35018	A traceback occurred during testing of IP multicast. Workaround: None.
CSCdz54597	The Cisco 4-port channelized OC-3 line card experiences low through put and packet loss when configured with 252 SONET interfaces (VT E1 unframed). Workaround: None.
CSCdz56101	On a Cisco channelized 4-port STM-1 line card with 756 interfaces, each at 512 Kbps with SDH framing and AU-4-TUG-3 controllers, the line protocol failed to initialize for several interfaces. Workaround: None.
CSCea66250	When an ICMP echo request (ping) packet is received on an interface that has access control list (ACL) logging enabled, the PXF can fail and a Local Bus Exception error message appears. Workaround: Disable ACL logging on the interface.
CSCea74742	When the traffic policing max burst size is set to a small value, the policing exceed function does not work correctly. Workaround: None.
SNMP and MIBs (see also General)
CSCdz50531	The SONET-MIB does not update the intervals in the sonetVTIntervalTable or sonetVTFarEndIntervalTable for channelized STM and channelized OC-12 AU-3 TU controllers. Workaround: None.
CSCdz65705	When SNMP trap filtering is enabled (snmp ifmib trap throttle), SNMP does not generate a notification when a subinterface is shut down, although it should. Workaround: None.
CSCea08828	When SNMP trap filtering is enabled on a Cisco 1-port channelized OC-12 line card, the T3 layer generates a linkDown trap when the SONET layer is shut down. When trap filtering is enabled (snmp ifmib trap throttle), no trap should be generated. Workaround: None.
Stateful Switchover
CSCdy66774	After a stateful switchover (SSO), the first packet sent through UDP is lost. Workaround: Issue the following CLI command to configure the ESR to check before sending the first IP packet to make sure that an ARP entry exists for the destination (which must be connected through a fast Ethernet interface). In the command, A.B.C.D is the destination IP address and H.H.H is the 48-bit hardware address. conf t arp A.B.C.D H.H.H
eiBGP Multipath Load Sharing
CSCdy88837	If eiBGP multipath is configured in an MPLS network and one of the links is configured as eBGP, traffic may not be distributed through all links. This problem occurs when MAX Paths EIBGP is enabled under the address family. In this case, the IP BGP table displays multiple routes to a destination network (eBGP and iBGP paths), but the IP Route VPN table only shows iBGP paths. Workaround: Disable eiBGP and use the weight command to forward traffic through eBGP or iBGP paths.
CSCdz10264	When the ESR is configured as a provider edge (PE) router with 100 VPNs, the number of packets reported at an ingress port might not reflect the actual number of packets forwarded by the ESR. This problem occurs on gigabit Ethernet (gigE) line cards when a gigE port is configured as a subinterface on a VLAN and traffic is sent to each VLAN ID from another router. Workaround: None.
CSCdz26257	Traffic might not be load balanced through iBGP paths when MPLS eiBGP or iBGP max-paths is configured. For example, two iBGP paths might exist to the next hop but the PXF only forwards traffic through one of them. This means one of the links is not being used. Workaround: If traffic is being forwarded through the slower links, you can shut down the slower link to allow the faster link to forward traffic.
Link Fragmentation and Interleaving
CSCdy75500	The show frame-relay fragment command truncates the Frame Relay interface name for Channelized 4-port STM-1 line cards. Workaround: None.
CSCdz27628	When class-based weighted fair queuing (CBWFQ) is used with LFI enabled and multiple queues are configured for a link, packets are dropped from underloaded queues rather than overloaded (congested) queues. This problem occurs when traffic with different packet sizes is sent to different queues, which causes fragmentation on some queues but not others. Workaround: Be sure to use a priority queue when you enable LFI.
CSCdz42829	When LFI is enabled, the show frame pvc command sometimes shows invalid counts for input and output packets and bytes. Workaround: None.

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Table of Contents

Release Notes for the Cisco 10000 Series ESRfor Cisco IOS Release 12.0(23)SX2

Contents

Upgrading to a New Software Release

Upgrading Software from Earlier Cisco IOS Releases

Upgrading from Cisco IOS Release 12.0(21)SX or Release 12.0(21)SX1

Upgrading from Cisco IOS Release 12.(14)SL or from Earlier 12.0(x)SL-based Releases

Upgrading Software on Redundant PREs

System Requirements

Memory Requirements

New Features in Cisco IOS Release 12.0(23)SX2 and 12.0(23)SX1

New Features in Cisco IOS Release 12.0(23)SX

Multirouter-Automatic Protection Switching

Recommendation for MR-APS Configurations with Limited Static Routes

Restrictions

Multicast for MPLS/VPN

MPLS Traffic Engineering Fast Reroute

Restrictions

DiffServe Aware Traffic Engineering for MPLS

eiBGP Multipath Load Sharing

Restrictions

Link Fragmentation and Interleaving

Cisco 10000 Series ESR LFI Limitations and Restrictions

Cisco 10000 Series ESR LFI Implementation Notes

MLPPP LFI Packet Counts

Configuring LFI on a Frame Relay Interface—Method 1

Configuring LFI on a Frame Relay Interface—Method 2

Configuring LFI on a Multilink PPP Interface

Single Rate 3-Color Marker for Traffic Policing

Configuring the Single Rate Three-Color Marker Feature

Using the Feature

Cisco 10000 ESR MIB Enhancements

SNMP Trap Filtering

Limitations and Restrictions

PRE Network Management Ethernet Port

Controlling the Rate of Logging Messages

Frame Relay

Nested Policy Feature

Testing Performance of High-Speed Interfaces

Important Notes

Cisco Discovery Protocol

Frame Relay and PPP Sessions

Performance Routing Engine 1 (PRE1) on the Cisco 10000 Series Edge Services Router

VLAN Session Support

Inserting a New Line Card

RBE Subinterfaces

Resolved Caveats in Cisco IOS Release 12.0(23)SX2

CSCdx87500

CSCdy50036

CSCdz28485

CSCdz28491

CSCdz30254

CSCdz32805

CSCdz55717

CSCea18595

CSCea27138

CSCea27231

CSCea33501

CSCea54257

CSCea61833

CSCea70433

CSCea71781

Resolved Caveats in Cisco IOS Release 12.0(23)SX1

CSCdy01660

CSCdz00466

CSCdz29005

CSCdz30172

CSCdz30287

CSCdz36334

CSCdz40022

CSCdz49398

CSCdz50858

CSCdz51638

CSCdz56052

CSCdz58839

CSCdz70148

CSCdz77838

CSCea13379

CSCea15963

CSCea18756

Release Notes for the Cisco 10000 Series ESR
for Cisco IOS Release 12.0(23)SX2