Cisco Nexus 9000 ACI-Mode Switches Release Notes, Release 12.1(1)
This document describes the features, bugs, and limitations for Cisco NX-OS software that runs on Cisco Nexus 9000 Series Application Centric Infrastructure (ACI) switches. Use this document in combination with the Cisco Application Policy Infrastructure Controller, Release Notes, Release 2.1(1), which you can view at the following location:
Additional product documentation is listed in the “Related Documentation” section.
Release notes are sometimes updated with new information about restrictions and bugs. See the following website for the most recent version of the Cisco NX-OS Release 12.1(1) Release Notes for Cisco Nexus 9000 Series ACI-Mode Switches:
Table 1 shows the online change history for this document.
Table 1. Online History Change
Date |
Description |
January 19, 2021 |
In the Known Behaviors section, changed the following sentence: The Cisco Nexus 9508 ACI-mode switch supports warm (stateless) standby where the state is not synched between the active and the standby supervisor modules. To: The modular chassis Cisco ACI spine nodes, such as the Cisco Nexus 9508, support warm (stateless) standby where the state is not synched between the active and the standby supervisor modules. |
March 13, 2020 |
12.1(1h): In the Resolved Bugs section, added bug CSCvr98827. |
September 20, 2019 |
In the Usage Guidelines section, added the following bullet: ■ A 25G link that is using the IEEE-RS-FEC mode can communicate with a link that is using the CL16-RS-FEC mode. There will not be a FEC mismatch and the link will not be impacted. |
August 14, 2019 |
12.1(1h): In the Open Bugs section, added bug CSCvp92269. |
July 31, 2019 |
In the Compatibility Information section, added the following bullet: ■ On Cisco ACI platforms, 25G copper optics do not honor auto-negotiation, and therefore auto-negotiation on the peer device (ESX or standalone) must be disabled to bring up the links. |
January 30, 2019 |
12.1(1h): In the Open Bugs section, added bug CSCvn69340. |
January 28, 2019 |
12.1(1h): In the Open Bugs section, added bug CSCvi76161. |
February 19, 2018 |
12.1(1h): In the Open Bugs section, added bug CSCvc18574. |
August 28, 2017 |
Added N9K-C9336PQ and N9K-X9736PQ switches, as they are supported. |
February 14, 2017 |
In the Compatibility Information section, changed: Break out the 40G FEX ports on the N2348UPQ to 4x10G ports and connect to the N9396PX, N9372PX, or N9372PX-E switches To: Break out the 40G FEX ports on the N2348UPQ to 4x10G ports and connect to the 10G ports on all other ACI leaf switches Note: A fabric uplink port cannot be used as a FEX fabric port. |
January 25, 2017 |
Removed mention of the N9K-C9336PQ and N9K-X9736PQ switches, as they are not supported. |
December 22, 2016 |
12.1(1i): Release 12.1(1i) became available. Added the resolved bugs for this release. |
December 6, 2016 |
In the “Usage Guidelines” section, removed the bullet that began with, “GARP flooding is enabled by default for the Cisco Nexus 93180YC-EX switch…” GARP flooding is now disabled by default for 93180YC-EX switches. |
October 27, 2016 |
In the Supported FEX Models section, added N2K-B22HP-P. 12.1(1h): Updated the resolved bugs table with an entirely new list. |
October 18, 2016 |
12.1(1h): Removed open bug CSCvb37009. |
October 2, 2016 |
12.1(1h): Release 12.1(1h) became available. |
This document includes the following sections:
■ Cisco Nexus 9000 Series ACI-Mode
■ Bugs
Cisco NX-OS Software for the Cisco Nexus 9000 Series is a data center, purpose-built, operating system designed with performance, resiliency, scalability, manageability, and programmability at its foundation. It provides a robust and comprehensive feature set that meets the requirements of virtualization and automation in data centers
Cisco NX-OS Release 12.1 works only on Cisco Nexus 9000 Series switches in ACI Mode.
See Table 2 for a list of modules that are supported on Cisco Nexus 9000 Series switches in ACI Mode.
Table 2 lists the hardware that the Cisco Nexus 9000 Series ACI Mode switches support.
Table 2. Cisco Nexus 9000 Series Hardware.
Hardware Type |
Product ID |
Description |
Chassis |
N9K-C9504 |
Cisco Nexus 9504 chassis with 4 I/O slots |
Chassis |
N9K-C9508 |
Cisco Nexus 9508 chassis with 8 I/O slots |
Chassis component |
N9K-C9508-FAN |
Fan tray |
Chassis component |
N9k-PAC-3000W-B |
Cisco Nexus 9500 3000W AC power supply, port side intake |
Pluggable module (GEM) |
N9K-M6PQ |
6-port |
Pluggable module (GEM) |
N9K-M6PQ-E |
6-port, 40 Gigabit Ethernet expansion module |
Pluggable module (GEM) |
N9K-M12PQ |
12-port or 8-port |
Spine switch |
N9K-C9336PQ |
Cisco Nexus 9336PQ switch, 36-port 40 Gigabit Ethernet QSFP |
Spine switch |
N9K-C9508-B1 |
Cisco Nexus 9508 chassis bundle with 1 supervisor module, 3 power supplies, 2 system controllers, 3 fan trays, and 3 fabric modules |
Spine switch |
N9K-C9508-B2 |
Cisco Nexus 9508 chassis bundle with 1 supervisor module, 3 power supplies, 2 system controllers, 3 fan trays, and 6 fabric modules |
Spine switch |
N9K-C9516 |
Cisco Nexus 9516 switch with 16 line card slots Note: This switch supports up to 10 line cards. |
Spine switch fan |
N9K-C9300-FAN3 |
Port side intake fan |
Spine switch fan |
N9K-C9300-FAN3-B |
Port side exhaust fan |
Spine switch module |
N9K-C9504-FM |
Cisco Nexus 9504 fabric module supporting 40 Gigabit line cards |
Spine switch module |
N9K-C9504-FM-E |
Cisco Nexus 9504 fabric module supporting 100 Gigabit line cards |
Spine switch module |
N9K-C9508-FM |
Cisco Nexus 9508 fabric module supporting 40 Gigabit line cards |
Spine switch module |
N9K-C9508-FM-E |
Cisco Nexus 9508 Fabric module supporting 100 Gigabit line cards |
Spine switch module |
N9K-X9732C-EX |
Cisco Nexus 9500 32-port, 40/100 Gigabit Ethernet QSFP28 aggregation module |
Spine switch module |
N9K-X9736PQ |
Cisco Nexus 9500 36-port, 40 Gigabit Ethernet QSFP aggregation module |
Switch module |
N9K-SC-A |
Cisco Nexus 9500 Series system controller |
Switch module |
N9K-SUP-A |
Cisco Nexus 9500 Series supervisor module |
Switch module |
N9K-SUP-B |
Cisco Nexus 9500 Series supervisor module |
Top-of-rack (ToR) leaf switch |
N9K-C93108TC-EX |
Cisco Nexus 9300 with 48-port 1/10 Gigabit-T and 6-port 100 Gigabit Ethernet QSFP28 switch |
Top-of-rack (ToR) leaf switch |
N9K-C93120TX |
Cisco Nexus 9300 with 96-port 1/10 Gigabit-T and 6-port 40 Gigabit Ethernet QSFP switch |
Top-of-rack (ToR) leaf switch |
N9K-C93128TX |
Cisco Nexus 9300 96-port, 1-/10-Gbps BASE-T and 6-port or 8-port, 40 Gigabit Ethernet QSFP switch |
Top-of-rack (ToR) leaf switch |
N9K-C93180YC-EX |
Cisco Nexus 9300 Fixed with 48-port 10/25 Gigabit and 6-port 40/100 Gigabit QSFP28 |
Top-of-rack (ToR) leaf switch |
N9K-C9332PQ |
Cisco Nexus 9332PQ 32-port 40 Gigabit Ethernet QSFP+ Top-of-rack (ToR) Layer 3 switch |
Top-of-rack (ToR) leaf switch |
N9K-C9372PX |
Cisco Nexus 9372PX 48-port, 10 Gigabit Ethernet SFP+ and 6-port 40 Gigabit Ethernet QSFP+ Top-of-rack (ToR) Layer 3 switch Note: Only the downlink ports 1-16 and 33-48 are capable of supporting SFP1-10G-ZR SFP+. |
Top-of-rack (ToR) leaf switch |
N9K-C9372PX-E |
Cisco Nexus 9372PX-E 48-port, 10 Gigabit Ethernet SFP+ and 6-port 40 Gigabit Ethernet QSFP+ Top-of-rack (ToR) Layer 3 switch Note: Only the downlink ports 1-16 and 33-48 are capable of supporting SFP1-10G-ZR SFP+. |
Top-of-rack (ToR) leaf switch |
N9K-C9372TX |
Cisco Nexus 9372TX 48-port, 1/10 Gbps Base-T and 6-port, 40 Gigabit Ethernet QSFP Top-of-rack (ToR) Layer 3 switch |
Top-of-rack (ToR) leaf switch |
N9K-C9372TX-E |
Cisco Nexus 9372TX-E 48-port 1/10 Gbps Base-T and 6-port 40 Gbps Ethernet QSFP+ Top-of-rack (ToR) Layer 3 switch |
Top-of-rack (ToR) leaf switch |
N9K-C9396PX |
Cisco Nexus 9300 48-port, 1/10 Gigabit Ethernet SFP+ and 6-port or 12-port, 40 Gigabit Ethernet QSFP switch |
Top-of-rack (ToR) leaf switch |
N9K-C9396TX |
Cisco Nexus 9300 48-port, 1/10 Gbps Base-T and 6-port or 12-port, 40 Gigabit Ethernet QSFP switch |
Top-of-rack (ToR) leaf switch power supply unit |
N9K-PAC-650W-B |
650W AC Power supply, port side exhaust pluggable |
Top-of-rack (ToR) leaf switch power supply unit |
N9K-PAC-650W |
650W AC Power supply, port side intake pluggable |
Top-of-rack (ToR) leaf switch power supply unit |
N9K-PAC-1200W-B |
1200W AC Power supply, port side exhaust pluggable Note: This power supply is supported only by the Cisco Nexus 93120TX, 93128TX, and 9336PQ ACI-mode switches |
Top-of-rack (ToR) leaf switch power supply unit |
N9K-PAC-1200W |
1200W AC Power supply, port side intake pluggable Note: This power supply is supported only by the Cisco Nexus 93120TX, 93128TX, and 9336PQ ACI-mode switches |
Top-of-rack (ToR) leaf switch power supply unit |
N9K-PUV-1200W |
1200W HVAC/HVDC dual-direction airflow power supply Note: This power supply is supported only by the Cisco Nexus 93120TX, 93128TX, and 9336PQ ACI-mode switches |
Top-of-rack (ToR) leaf switch power supply unit |
N9K-PUV-3000W-B |
3000W AC Power supply, port side exhaust pluggable |
Top-of-rack (ToR) leaf switch power supply unit |
NXA-PAC-1200W-PE |
1200W AC Power supply, port side exhaust pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only by the Cisco Nexus 93120TX, 93128TX, and 9336PQ ACI-mode switches. |
Top-of-rack (ToR) leaf switch power supply unit |
NXA-PAC-1200W-PI |
1200W AC Power supply, port side intake pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only by the Cisco Nexus 93120TX, 93128TX, and 9336PQ ACI-mode switches. |
Top-of-rack (ToR) leaf switch power supply unit |
UCS-PSU-6332-DC |
930W DC power supply, reversed airflow (port side exhaust) |
Top-of-rack (ToR) leaf switch power supply unit |
UCSC-PSU-930WDC V01 |
Port side exhaust DC power supply compatible with all ToR leaf switches |
Top-of-rack (ToR) leaf switch fan |
NXA-FAN-30CFM-F |
Port side exhaust fan |
Top-of-rack (ToR) leaf switch fan |
NXA-FAN-30CFM-B |
Port side intake fan |
Table 3 lists the FEX models that the Cisco Nexus 9000 Series ACI Mode switches support. For more information on the FEX models, see the Cisco Nexus 2000 Series Fabric Extenders Data Sheet at the following location:
Table 3. Supported FEX Models.
Product ID |
Description |
N2K-B22DELL-P |
B22 FEX for Dell |
N2K-B22HP-P |
B22 FEX for HP |
N2K-B22IBM-P |
B22 FEX for IBM |
N2K-C2248PQ-10GE |
Cisco Nexus 2248PQ 10GE Fabric Extender, 2PS, 4 Fan Module, 48x1/10GE (req SFP/SFP+) + 4x40G QSFP+(req QSFP+), choice of airflow and power supply |
N2K-C2248TP-1GE |
Cisco Nexus 2248TP Series 1GE Fabric Extender, 2 AC PS, 1 Fan Module (Standard Airflow/port side exhaust), 48x100/1000Base-T + 4x10GE (req SFP+), same as N2K-C2248TP |
N2K-C2248TP-E-1GE |
Cisco Nexus 2248TP-E Series 1GE Fabric Extender, 2PS, 1 Fan Module, 48x100/1000Base-T + 4x10GE (req SFP+), 32MB buffer, choice of airflow and power supply |
N2K-C2332TQ |
Cisco Nexus 2332TQ 10G BASE T Fabric Extender, 2PS, 3 Fan Module, 48x100M/1/10GE + 4x40G QSFP+(req QSFP+), choice of airflow and power supply |
N2K-C2348TQ |
Cisco Nexus 2348TQ 10G BASE T Fabric Extender, 2PS, 3 Fan Module, 48x100M/1/10GE + 6x40G QSFP+(req QSFP+), choice of airflow and power supply |
N2K-C2348UPQ |
48 100Mῖ/1/10 Gigabit Ethernet and Unified Port host interfaces (SFP+) and up to 6ῖ QSFP+ 10/40 Gigabit Ethernet fabric interfaces |
N2K-C2232PP-10GE |
Cisco Nexus 2232PP Series 10GE Fabric Extender, 2 AC PS, 1 Fan Module (Standard Airflow/port side exhaust), 32x1/10GE (req SFP/SFP+) + 8x10GE (req SFP+), same as N2K-C2232PP |
N2K-C2232TM-E-10GE |
Cisco Nexus 2232TM-E Series 10GBASE-T Fabric Extender, 2PS, 1 Fan Module, 32x1/10GBase-T + 8x10GE Module (req SFP+), choice of airflow and power supply |
This section lists the new and changed features in this release.
Cisco NX-OS release 12.1(1) supports the following new hardware features.
■ 40-Gigabit ports on the following devices support the use of 10-Gigabit SFP+ transceivers if you connect them using a QSFP-to-SFP adapter (part number CVR-QSFP-SFP10G):
o Cisco Nexus 9500 family line cards:
§ N9K-X9732C-EX
For new software features, see the Cisco APIC 2.1(1) Release Notes at the following location:
The following procedure installs a Gigabit Ethernet module (GEM) in a top-of-rack switch:
1. Clear the switch’s current configuration by using the setup-clean-config command.
2. Power off the switch by disconnecting the power.
3. Replace the current GEM card with the new GEM card.
4. Power on the switch.
For other installation instructions, see the Cisco ACI Fabric Hardware Installation Guide at the following location:
■ This release supports the hardware and software listed on the ACI Ecosystem Compatibility List and the Cisco AVS, Release 5.2(1)SV3(2.1).
■ Link level flow control is not supported on ACI-mode switches.
■ The breakout of 40G ports to 4x10G on the N9332PQ switch is not supported in ACI-Mode.
■ To connect the N2348UPQ to ACI leaf switches, the following options are available:
— Directly connect the 40G FEX ports on the N2348UPQ to the 40G switch ports on the ACI leaf switches
— Break out the 40G FEX ports on the N2348UPQ to 4x10G ports and connect to the 10G ports on all other ACI leaf switches
Note: A fabric uplink port cannot be used as a FEX fabric port.
■ To connect the APIC (the controller cluster) to the ACI fabric, it is required to have a 10G interface on the ACI leaf. You cannot connect the APIC directly to the N9332PQ ACI leaf switch.
■ We do not qualify third party optics in Cisco ACI. When using third party optics, the behavior across releases is not guaranteed, meaning that the optics might not work in some NX-OS releases. Use third party optics at your own risk. We recommend that you use Cisco SFPs, which have been fully tested in each release to ensure consistent behavior.
■ On Cisco ACI platforms, 25G copper optics do not honor auto-negotiation, and therefore auto-negotiation on the peer device (ESX or standalone) must be disabled to bring up the links.
■ The current list of protocols that are allowed (and cannot be blocked through contracts) include the following. Some of the protocols have SrcPort/DstPort distinction.
Note: See the APIC release notes for policy information: https://www.cisco.com/c/en/us/support/cloud-systems-management/application-policy-infrastructure-controller-apic/tsd-products-support-series-home.html
— UDP DestPort 161: SNMP. These cannot be blocked through contracts. Creating an SNMP ClientGroup with a list of Client-IP Addresses restricts SNMP access to only those configured Client-IP Addresses. If no Client-IP address is configured, SNMP packets are allowed from anywhere.
— TCP SrcPort 179: BGP
— TCP DstPort 179: BGP
— OSPF
— UDP DstPort 67: BOOTP/DHCP
— UDP DstPort 68: BOOTP/DHCP
— IGMP
— PIM
— UDP SrcPort 53: DNS replies
— TCP SrcPort 25: SMTP replies
— TCP DstPort 443: HTTPS
— UDP SrcPort 123: NTP
— UDP DstPort 123: NTP
■ Leafs and spines from two different fabrics cannot be connected regardless of whether the links are administratively kept down.
■ A 25G link that is using the IEEE-RS-FEC mode can communicate with a link that is using the CL16-RS-FEC mode. There will not be a FEC mismatch and the link will not be impacted.
This section contains lists of open and resolved bugs and known behaviors.
The following list describes IpEpg (IpCkt) known limitations in this release:
■ An IP/MAC Ckt endpoint configuration is not supported in combination with static endpoint configurations.
■ An IP/MAC Ckt endpoint configuration is not supported with Layer 2-only bridge domains. Such a configuration will not be blocked, but the configuration will not take effect as there is no Layer 3 learning in these bridge domains.
■ An IP/MAC Ckt endpoint configuration is not supported with external and Infra bridge domains because there is no Layer 3 learning in these bridge domains.
■ An IP/MAC Ckt endpoint configuration is not supported with a shared services provider configuration. The same or overlapping prefix cannot be used for a shared services provider and IP Ckt endpoint. However, this configuration can be applied in bridge domains having shared services consumer endpoint groups.
■ An IP/MAC Ckt endpoint configuration is not supported with dynamic endpoint groups. Only static endpoint groups are supported.
■ No fault will be raised if the IP/MAC Ckt endpoint prefix configured is outside of the bridge domain subnet range. This is because a user can configure bridge domain subnet and IP/MAC Ckt endpoint in any order and so this is not error condition. If the final configuration is such that a configured IP/MAC Ckt endpoint prefix is outside all bridge domain subnets, the configuration has no impact and is not an error condition.
■ Dynamic deployment of contracts based on instrImmedcy set to onDemand/lazy not supported; only immediate mode is supported.
The following list describes direct server return (DSR) known limitations in this release:
■ When a server and load balancer are on the same endpoint group, make sure that the Server does not generate ARP/GARP/ND request/response/solicits. This will lead to learning of LB virtual IP (VIP) towards the Server and defeat the purpose of DSR support
■ Load balancers and servers must be Layer 2 adjacent. Layer 3 direct server return is not supported. If a load balancer and servers are Layer 3 adjacent, then they have to be placed behind the Layer 3 out, which works without a specific direct server return virtual IP address configuration.
■ Direct server return is not supported for shared services. Direct server return endpoints cannot be spread around different virtual routing and forwarding (VRF) contexts.
■ Configurations for a virtual IP address can only be /32 or /128 prefix.
■ Client to virtual IP address (load balancer) traffic always will go through proxy-spine because fabric data-path learning of a virtual IP address does not occur.
■ GARP learning of a virtual IP address must be explicitly enabled. A load balancer can send GARP when it switches over from active-to-standby (MAC changes).
■ Learning through GARP will work only in ARP Flood Mode.
This section lists the open bugs. Click the bug ID to access the Bug Search tool and see additional information about the bug. The "Exists In" column of the table specifies the 12.1(1) releases in which the bug exists. A bug might also exist in releases other than the 12.1(1) releases.
Table 4 Open Bugs in This Release
Bug ID |
Description |
Exists In |
FEX logs are missing in the output of the show fex detail command. |
12.1(1h) and later |
|
The events and faults for interfaces are not updated under Ports in the GUI. |
12.1(1h) and later |
|
The output of some CLI commands display very slowly. This usually occurs in a scaled environment when the switches are heavily loaded with the configuration. |
12.1(1h) and later |
|
Because ibash is implemented on top of bash, when using ibash for the CLI, the bash behavior is inherited. For example, the sh mod command works in traditional Cisco switches. But when executed on N9K switches in ibash, because bash interprets sh differently, sh mod will not work. Similarly, if there is a clash in the next available options, the TAB key must be pressed twice to get the options rather than once as in other Cisco switches. In short, the CLI infra for ibash is not exactly the same as the CLI infra for the traditional Cisco switches because N9K ibash is built on top of bash. |
12.1(1h) and later |
|
FEX-related diagnostic results are missing. |
12.1(1h) and later |
|
Transit traffic is dropped during ingress or egress when configured under the same Layer 3 Out with 0.0.0.0/0 security import subnet. This behavior is true for dynamic or static routing. To prevent this behavior, you must define more specific subnets and set the policy control enforcement preference to unenforced when configuring the associated VRF. |
12.1(1h) and later |
|
The server virtual Fibre Channel interface state changes to “port reinit limit reached” when an NP link is shut down. |
12.1(1h) and later |
|
The virtual Fibre Channel (VFC) NP port enters the flogi-fail-retry state followed by the down state if there is a user-configured mismatch of the VSAN and VLAN mapping between the leaf switch and the Fibre Channel Forwarder (FCF). To recover the VFC NP port, delete the wrong VLAN-VSAN mapping on the leaf switch, delete and recreate the VLAN pool/encapsulation block if needed, and then create the correct VLAN-VSAN mapping. |
12.1(1h) and later |
|
With passive QSA, a GLC-SX-MMD transceiver is not detected by N9K-93108TC-EX and N9K-93180YC-EX switches. |
12.1(1h) and later |
|
With VRF scale and 2 spine switches, reloading a spine switch will take time for the switch to re-join the fabric. During that time, the traffic will flow through the other spine switch. |
12.1(1h) and later |
|
A port is put into the “learn disable” state when the MAC limit is reached. When an existing endpoint on a learn-disabled port is updated with a new IP address, for example, the endpoint might get deleted erroneously. As a result, the number of dynamic endpoints on a learn-disabled port might be less than the MAC limit. |
12.1(1h) and later |
|
In the case of endpoints in two different TOR pairs across a spine switch that are trying to communicate, an endpoint does not get relearned after being deleted on the local TOR pair. However, the endpoint still has its entries on the remote TOR pair. |
12.1(1h) and later |
|
The permit log and glean packets share the same policer, which can cause direct BGPs to take a while to establish when one of the VPC peers is reloaded. This can occur when permit log is enabled and traffic is forwarding. There is no traffic loss, as BGP is established with other VPC peers, and traffic continues through the other peers. |
12.1(1h) and later |
|
Local endpoints are installed without a "Bounce" flag and point to a remote tunnel instead of a local interface. |
12.1(1h) and later |
|
A version mismatch between Cisco ACI leaf switches causes the EPM process to crash and a HAP reset to occur. |
12.1(1h) and later |
|
The BFD session does not get instantiated under some circumstances in one of the VPC legs for static routes. |
12.1(1h) and later |
|
A leaf switch experiences an unexpected reload due to a HAP reset. |
12.1(1h) and later |
|
Running a Qualys security scan results in the following message: CWE - 693 Protection Mechanism Failure - "HTTP Security Header Not Detected" |
12.1(1h) and later |
|
Some of the control plane packets are incorrectly classified as the user class and are reported as dropped in single chip spine switches. The statistics are incorrect because the packets are not actually dropped. |
12.1(1h) and later |
|
A switch SSD fails in less than two years and needs replacement. The /mnt/pss/ssd_log_amp.log file shows daily P/E cycles increasing by 10 or more each day, and fault "F3525: High SSD usage" is observed. Check the switch activity and contact Cisco Technical Support if the "High SSD usage" fault is raised on the switch. |
12.1(1h) and later |
|
A switch SSD fails in less than two years and needs replacement. The /mnt/pss/ssd_log_amp.log file shows daily P/E cycles increasing by 10 or more each day, and fault "F3525: High SSD usage" is observed. ARP/ICMPv6 adjacency updates can also contribute to many SSD writes. |
12.1(1h) and later |
|
There are faults for failed contract rules and prefixes on switches prior to the -EX switches. Furthermore, traffic that is destined to an L3Out gets dropped because the compute leaf switches do not have the external prefix programmed in ns shim GST-TCAM. You might also see that leaf switches prior to the -EX switches do not have all contracts programmed correctly in the hardware. |
12.1(1h) and later |
This section lists the resolved bugs. Click the bug ID to access the Bug Search tool and see additional information about the bug.
Table 5 Resolved Bugs in This Release
Bug ID |
Description |
Fixed in |
IPv6 link-local unicast packets from an L3Out device destined to a border leaf switch fails. When running OSPFv3, adjacencies are built using the link-local addresses. If unicast traffic to the link-local address fails, the OSPF may see the adjacency never come up, stay in Exstart/Exchange status, or bounce. |
12.1(1h) |
|
There is a stale endpoint on a border leaf switch after changing the VRF from egress policy enforcement to ingress policy enforcement. |
12.1(1h) |
|
Extra FEX interfaces are being shown in the GUI, and the interface objects are present on the leaf switch. |
12.1(1h) |
|
In the APIC GUI under Fabric > Inventory > Pod X > Leaf X > Physical Interfaces > eth 1/x, the Cfg Access VLAN will show a VLAN even though the port is configured as tagged only. In the switch CLI, when issuing the "show interface ethernet 1/x switchport" command, the Access Mode VLAN will show a VLAN even though the port is configured as tagged only. |
12.1(1h) |
|
The data in the "Actual Output" column of the "show environment power" command for the N9K-PUV-3000W-B power supply on a N9504 chassis is incorrect and unstable. The values often change, and sometimes are zero. |
12.1(1h) |
|
Fault message F103824 displays intermittently. |
12.1(1h) |
|
In a multipod fabric, packets are not reaching a remote POD endpoint due to missing COOP entry in the spine switches. |
12.1(1h) |
|
A leaf switch continuously reboots upon being booted up due to an ELTM crash. |
12.1(1h) |
|
From the APIC GUI in the Visibility and Troubleshooting dialog, selecting "Drop/Stats" generates the following system messages: Aug 03 14:23:00 133.116.135.133 <154> Aug 03 14:22:17 CL-NY2-A0203-LEAFPX02 %LOG_LOCAL3-2-SYSTEM_MSG [E4204936][transition][critical][sys] Aug 03 14:22:17 LOG_LOCAL0-2-SYSTEM_MSG: can't dlsym ssnmgr_is_session_command: please link this binary with ssnmgr.so! This message is generated on only leaf nodes through which a selected packet has a flow path. |
12.1(1h) |
|
The “show platform internal alp counters asic-block all asic 0 detail” command pulls the wrong ASIC MAC block. |
12.1(1h) |
|
The /var/log directory on a leaf switch grows to 100% usage. The directory generates a full fault for the affected nodes that are reported on the APIC. |
12.1(1h) |
|
Traffic destined to the HSRP vIP (using the HSRP vMAC) is dropped on the ingress leaf switch due to the policy, even though the proper contracts are in place. |
12.1(1h) |
|
The data plane policer on an L3out becomes stale and does not remove the old policer if you apply a new policer or completely remove the policer from the configuration. |
12.1(1h) |
|
BGP asserts on a handshake failure from the system manager. |
12.1(1i) |
|
In a multimode multi spine setup, when the spine1 switch in POD 1 is powered off as part of negative testing with Bi-directional traffic running between POD 1 and POD 2, the remote MAC to POD2 previously learned on EX server leaf switches over the VXLAN tunnel in POD 1 disappeared, whereas the remote MAC to POD 1 learned on non-EX server leaf switches over the VLXAN tunnel in POD 2 was working correctly. The traffic from the POD 1 endpoint to the POD 2 endpoint becomes double the traffic rate that is actually being sent, which is nothing but flooding. |
12.1(1i) |
This section lists bugs that describe known behaviors. Click the Bug ID to access the Bug Search Tool and see additional information about the bug. The "Exists In" column of the table specifies the 12.1(1) releases in which the known behavior exists. A bug might also exist in releases other than the 12.1(1) releases.
Table 7 Known Behaviors in This Release
Bug ID |
Description |
Exists In |
When configuring the output span on a FEX Hif interface, all the layer 3 switched packets going out of that FEX Hif interface are not spanned. Only layer 2 switched packets going out of that FEX Hif are spanned. |
12.1(1h) and later |
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When output span is enabled on a port where the filter is VLAN, multicast traffic in the VLAN that goes out of that port is not spanned. |
12.1(1h) and later |
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The show interface command shows the tunnel's Rx/Tx counters as 0. |
12.1(1h) and later |
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The show vpc brief command displays the wire-encap VLAN Ids and the show interface .. trunk command displays the internal/hardware VLAN IDs. Both VLAN IDs are allocated and used differently, so there is no correlation between them. |
12.1(1h) and later |
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Continuous “threshold exceeded” messages are generated from the fabric. |
12.1(1h) and later |
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Switch rescue user ("admin") can log into fabric switches even when TACACS is selected as the default login realm. |
12.1(1h) and later |
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An extra 4 bytes is added to the untagged packet with Egress local and remote SPAN. |
12.1(1h) and later |
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When the command show ip ospf vrf <vrf_name> is run from bash on the border leaf, the checksum field in the output always shows a zero value. |
12.1(1h) and later |
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When an IP address moves from one MAC behind one ToR to another MAC behind another ToR, even though the VM sends a GARP packet, in ARP unicast mode, this GARP packet is not flooded. As a result, any other host with the original MAC to IP binding sending an L2 packet will send to the original ToR where the IP was in the beginning (based on MAC lookup), and the packet will be sent out on the old port (location). Without flooding the GARP packet in the network, all hosts will not update the MAC-to-IP binding. |
12.1(1h) and later |
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When modifying the L2Unknown Unicast parameter on a Bridge Domain (BD), interfaces on externally connected devices may bounce. Additionally, the endpoint cache for the BD is flushed and all endpoints will have to be re-learned. |
12.1(1h) and later |
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If an endpoint has multiple IPs, the endpoint will not be aged until all IPs go silent. If one of the IP addresses is reassigned to another server/host, the fabric detects it as an IP address move and forwarding will work as expected. |
12.1(1h) and later |
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The power supply will not be detected after performing a PSU online insertion and removal (OIR). |
12.1(1h) and later |
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The access-port operational status is always “trunk”. |
12.1(1h) and later |
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An MSTP topology change notification (TCN) on a flood domain (FD) VLAN may not flush endpoints learned as remote where the FD is not deployed. |
12.1(1h) and later |
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The transceiver type for some Cisco AOC (active optical) cables is displayed as ACU (active copper). |
12.1(1h) and later |
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Any TCAM that is full, or nearly full, will raise the usage threshold fault. Because the faults for all TCAMs on leaf switches are grouped together, the fault will appear even on those with low usage. Workaround: Review the leaf switch scale and reduce the TCAM usage. Contact TAC to isolate further which TCAM is full. |
12.1(1h) and later |
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The default route is not leaked by BGP when the scope is set to context. The scope should be set to Outside for default route leaking. |
12.1(1h) and later |
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If the TOR 1RU system is configured with the RED fan (the reverse airflow), the air will flow from front to back. The temperature sensor in the back will be defined as an inlet temperature sensor, and the temperature sensor in the front will be defined as an outlet temperature sensor. If the TOR 1RU system is configured with the BLUE fan (normal airflow), the air will flow from back to front. The temperature sensor in the front will be defined as an inlet temperature sensor, and the temperature sensor in the back will be defined as outlet temperature sensor. From the airflow perspective, the inlet sensor reading should always be less than the outlet sensor reading. However, in the TOR 1RU family, the front panel temperature sensor has some inaccurate readings due to the front panel utilization and configuration, which causes the inlet temperature sensor reading to be very close, equal, or even greater than the outlet temperature reading. |
12.1(1h) and later |
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If Backbone and NSSA areas are on the same leaf, and default route leak is enabled, Type-5 LSAs cannot be redistributed to the Backbone area. |
12.1(1h) and later |
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Traffic from the orphan port to the vPC pair is not recorded against the tunnel stats. Traffic from the vPC pair to the orphan port is recorded against the tunnel stats. |
12.1(1h) and later |
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Traffic from the orphan port to the vPC pair is only updated on the destination node, so the traffic count shows as excess. |
12.1(1h) and later |
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If a bridge domain "Multi Destination Flood" mode is configured as "Drop", the ISIS PDU from the tenant space will get dropped in the fabric. |
12.1(1h) and later |
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Atomic counters on the border leaf do not increment for traffic from an endpoint group going to the Layer 3 out interface. |
12.1(1h) and later |
|
Atomic counters on the border leaf do not increment for traffic from the Layer 3 out interface to an internal remote endpoint group. |
12.1(1h) and later |
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TEP counters from the border leaf to remote leaf nodes do not increment. |
12.1(1h) and later |
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For direct server return operations, if the client is behind the Layer 3 out, the server-to-client response will not be forwarded through the fabric. |
12.1(1h) and later |
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With the common pervasive gateway, only the packet destination to the virtual MAC is being properly Layer 3 forwarded. The packet destination to the bridge domain custom MAC fails to be forwarded. This is causing issues with certain appliances that rely on the incoming packets’ source MAC to set the return packet destination MAC. |
12.1(1h) and later |
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BCM does not have a stats option for yellow packets/bytes, and so BCM does not show in the switch or APIC GUI stats/observer. |
12.1(1h) and later |
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Bidirectional Forwarding Detection (BFD) echo mode is not supported on IPv6 BFD sessions carrying link-local as the source and destination IP address. BFD echo mode also is not supported on IPv4 BFD sessions over multihop or VPC peer links. |
12.1(1h) and later |
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Traffic is dropped between two isolated EPGs. |
12.1(1h) and later |
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The iping command’s replies get dropped by the QOS ingress policer. |
12.1(1h) and later |
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An overlapping or duplicate prefix/subnet could cause the valid prefixes not to be installed because of batching behavior on a switch. This can happen during an upgrade to the 1.2(2) release. |
12.1(1h) and later |
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EPG statistics only count total bytes and packets. The breakdown of statistics into multicast/unicast/broadcast is not available on new hardware. |
12.1(1h) and later |
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You must configure different router MACs for SVI on each border leaf if L3out is deployed over port-channels/ports with STP and OSPF/OSPFv3/eBGP protocols are used. There is no need to configure different router MACs if you use VPC. |
12.1(1h) and later |
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The default minimum bandwidth is used if the BW parameter is set to "0", and so traffic will still flow. |
12.1(1h) and later |
|
The debounce timer is not supported on 25G links. |
12.1(1h) and later |
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With the N9K-C93180YC-EX switch, drop packets, such as MTU or storm control drops, are not accounted for in the input rate calculation. |
12.1(1h) and later |
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For traffic coming out of an L3out to an internal EPG, stats for the actrlRule will not increment. |
12.1(1h) and later |
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When subnet check is enabled, a ToR does not learn IP addresses locally that are outside of the bridge domain subnets. However, the packet itself is not dropped and will be forwarded to the fabric. This will result in such IP addresses getting learned as remote endpoints on other ToRs. |
12.1(1h) and later |
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SAN boot over a virtual Port Channel or traditional Port Channel does not work. |
12.1(1h) and later |
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A policy-based redirect (PBR) policy to redirect IP traffic also redirects IPv6 neighbor solicitation and neighbor advertisement packets. |
12.1(1h) and later |
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When nodes in the pod are running with mixed releases of the 12.0(x) release and pre-11.2(2) release, this can lead ISIS to core on the pre-11.2(2) release nodes. |
12.1(1h) and later |
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The front port of the QSA and GLC-T 1G module has a 10 to 15-second delay as it comes up from the insertion process. |
12.1(1h) and later |
■ IPN should preserve the CoS and DSCP values of a packet that enters IPN from the ACI spine switches. If there is a default policy on these nodes that change the CoS value based on the DSCP value or by any other mechanism, you must apply a policy to prevent the CoS value from being changed. At the minimum, the remarked CoS value should not be 4, 5, 6 or 7. If CoS is changed in the IPN, you must configure a multipod QoS policy in the ACI for the multipod that translates queuing class information of the packet into the DSCP value in the outer header of the iVXLAN packet.
■ The following properties within a QoS class under “Global QoS Class policies,” should not be changed from its default value and is only used for debugging purposes:
— MTU (default – 9216 bytes)
— Queue Control Method (default – Dynamic)
— Queue Limit (default – 1522 bytes)
— Minimum Buffers (default – 0)
■ The modular chassis Cisco ACI spine nodes, such as the Cisco Nexus 9508, support warm (stateless) standby where the state is not synched between the active and the standby supervisor modules. For an online insertion and removal (OIR) or reload of the active supervisor module, the standby supervisor module becomes active, but all modules in the switch are reset because the switchover is stateless. In the output of the show system redundancy status command, warm standby indicates stateless mode.
■ When a recommissioned APIC controller rejoins the cluster, GUI and CLI commands can time out while the cluster expands to include the recommissioned APIC controller.
■ If connectivity to the APIC cluster is lost while a switch is being decommissioned, the decommissioned switch may not complete a clean reboot. In this case, the fabric administrator should manually complete a clean reboot of the decommissioned switch.
■ Before expanding the APIC cluster with a recommissioned controller, remove any decommissioned switches from the fabric by powering down and disconnecting them. Doing so will ensure that the recommissioned APIC controller will not attempt to discover and recommission the switch.
IGMP Snooping Known Behaviors:
■ Multicast router functionality is not supported when IGMP queries are received with VxLAN encapsulation.
■ IGMP Querier election across multiple Endpoint Groups (EPGs) or Layer 2 outsides (External Bridged Network) in a given bridge domain is not supported. Only one EPG or Layer 2 outside for a given bridge domain should be extended to multiple multicast routers if any.
■ The rate of the number of IGMP reports sent to a leaf switch should be limited to 1000 reports per second.
■ Unknown IP multicast packets are flooded on ingress leaf switches and border leaf switches, unless “unknown multicast flooding” is set to “Optimized Flood” in a bridge domain. This knob can be set to “Optimized Flood” only for a maximum of 50 bridge domains per leaf.
If “Optimized Flood” is enabled for more than the supported number of bridge domains on a leaf, follow these configuration steps to recover:
— Set “unknown multicast flooding” to “Flood” for all bridge domains mapped to a leaf.
— Set “unknown multicast flooding” to “Optimized Flood” on needed bridge domains.
The Cisco Application Policy Infrastructure Controller (APIC) documentation can be accessed from the following website:
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