Cisco Nexus 9000 ACI-Mode Switches Release Notes, Release 15.2(1)
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Introduction
The Cisco NX-OS software for the Cisco Nexus 9000 series switches 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.
This release works only on Cisco Nexus 9000 Series switches in ACI mode.
This document describes the features, issues, and limitations for the Cisco NX-OS software. For the features, issues, and limitations for the Cisco Application Policy Infrastructure Controller (APIC), see the Cisco Application Policy Infrastructure Controller Release Notes, Release 5.2(1).
For more information about this product, see "Related Content."
| Date |
Description |
| April 27, 2023 |
Added the N9K-M12PQ, N9K-M6PQ, and N9K-M6PQ-E expansion modules to the No Longer Supported section. |
| July 28, 2022 |
In the Open Issues section, added bug CSCvz31425. |
| May 16, 2022 |
In the Open Issues section, added bug CSCwa47686. |
| April 4, 2022 |
In the Open Issues section, added bug CSCwa92634. |
| March 16, 2022 |
In the Open Issues section, added bugs CSCwa95241, CSCwb12482, and CSCwb14844. |
| February 8, 2022 |
In the Open Issues section, added bug CSCwa86674. |
| December 16, 2021 |
In the Open Issues section, added bug CSCvz95984. |
| December 7, 2021 |
In the Compatibility Information section, for the N9K-C9364C-GX switch, added: All 4 fans must be operational, otherwise the switch will power down due to a fan policy trigger. |
| November 29, 2021 |
In the Supported Hardware section, updated Modular Spine Switch Line Cards table to indicate that the N9K-X9716D-GX switch is not supported with the Cisco Nexus 9516 fabric cards. In the Compatibility Information section, updated the Modular Spine Switch Fabric Module Compatibility Information table to indicate that the N9K-X9716D-GX switch is not supported with any of the FM-E nor FM-E2 fabric modules. |
| November 16, 2021 |
In the Open Issues section, added bugs CSCvx31008 and CSCvz49846. |
| August 18, 2021 |
In the Compatibility Information section, for the N9K-C9316D-GX, N9K-C93600CD-GX, and N9K-C9364C-GX switches, added: 1G and 100MB speeds are not supported. |
| July 6, 2021 |
In the Supported Hardware section, added the NXA-PAC-500W-PI and NXA-PAC-500W-PE PSUs. |
| June 24, 2021 |
In the Open Issues section, added bug CSCvy75247. |
| June 21, 2021 |
In the Known Issues section, added bug CSCvu42069. |
| June 15, 2021 |
In the Open Issues section, added bug CSCvy43640. |
| June 10, 2021 |
In the Compatibility Information section, removed the MACsec support information. This information is in the Cisco APIC Layer 2 Networking Configuration Guide, Release 5.2(x). See the MACsec chapter. |
| June 7, 2021 |
Release 15.2(1g) became available. |
Table 1. Modular Spine Switches
| Product ID |
Description |
| N9K-C9504 |
Cisco Nexus 9504 switch chassis |
| N9K-C9508 |
Cisco Nexus 9508 switch chassis |
| 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 |
| 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 |
| N9K-C9516 |
Cisco Nexus 9516 switch chassis |
Table 2. Modular Spine Switch Line Cards
| Product ID |
Description |
Maximum Quantity |
||
| Cisco Nexus 9504 |
Cisco Nexus 9508 |
Cisco Nexus 9516 |
||
| N9K-X9716D-GX |
Cisco Nexus 9500 16-port 400 Gigabit Ethernet QSFP line card |
4 |
8 |
N/A |
| N9K-X9736C-FX |
Cisco Nexus 9500 36-port 40/100 Gigabit Ethernet Cloud Scale line card |
4 |
8 |
16 |
| N9K-X9736Q-FX |
Cisco Nexus 9500 36-port 40 Gigabit Ethernet Cloud Scale line card |
4 |
8 |
16 |
| N9K-X9732C-EX |
Cisco Nexus 9500 32-port, 40/100 Gigabit Ethernet Cloud Scale line card Note: The N9K-X9732C-EX line card cannot be used when a fabric module is installed in FM slot 25. |
4 |
8 |
16 |
Table 3. Modular Spine Switch Fabric Modules
| Product ID |
Description |
Minimum |
Maximum |
| N9K-C9504-FM-G |
Cisco Nexus 9508 cloud scale fabric module (400G capable) |
4 |
5 |
| N9K-C9508-FM-G |
Cisco Nexus 9508 cloud scale fabric module (400G capable) |
4 |
5 |
| N9K-C9504-FM-E |
Cisco Nexus 9504 cloud scale fabric module |
4 |
5 |
| N9K-C9508-FM-E |
Cisco Nexus 9508 cloud scale fabric module |
4 |
5 |
| N9K-C9508-FM-E2 |
Cisco Nexus 9508 cloud scale fabric module |
4 |
5 |
| N9K-C9516-FM-E2 |
Cisco Nexus 9516 cloud scale fabric module |
4 |
5 |
Table 4. Modular Spine Switch Fans
| Product ID |
Description |
| N9K-C9504-FAN2 |
Nexus 9500 4-slot Fan Tray (Gen 2) |
| N9K-C9504-FAN-PWR |
Nexus 9500 4-slot Fan Tray Power Card Blank |
| N9K-C9504-FAN |
Fan tray for Cisco Nexus 9504 chassis |
| N9K-C9508-FAN2 |
Nexus 9500 8-slot Fan Tray (Gen 2) |
| N9K-C9508-FAN-PWR |
Nexus 9500 8-slot Fan Tray Power Card Blank |
| N9K-C9508-FAN |
Fan tray for Cisco Nexus 9508 chassis |
| N9K-C9516-FAN |
Fan tray for Cisco Nexus 9516 chassis |
Table 5. Modular Spine Switch Supervisor and System Controller Modules
| Product ID |
Description |
| N9K-SUP-A+ |
Cisco Nexus 9500 Series supervisor module |
| N9K-SUP-B+ |
Cisco Nexus 9500 Series supervisor module |
| N9K-SUP-A |
Cisco Nexus 9500 Series supervisor module |
| N9K-SUP-B |
Cisco Nexus 9500 Series supervisor module |
| N9K-SC-A |
Cisco Nexus 9500 Series system controller |
Table 6. Fixed Spine Switches
| Product ID |
Description |
| N9K-C93600CD-GX |
Cisco Nexus 9300 platform switch with 28 10/40/100-Gigabit Ethernet QSFP28 ports (ports 1-28) and 8 10/40/100/400-Gigabit QSFP-DD ports (ports 29-36). |
| N9K-C9316D-GX |
Cisco Nexus 9300 platform switch with 16 10/40/100/400-Gigabit QSFP-DD ports (ports 1-16). |
| N9K-C9332C |
Cisco Nexus 9300 platform switch with 32 40/100-Gigabit QSFP28 ports and 2 SFP ports. Ports 25-32 offer hardware support for MACsec encryption. |
| N9K-C9364C-GX |
Cisco Nexus 9300 platform switch with 64 100-Gigabit Ethernet QSFP28 ports, two management ports (one RJ-45 port and one SFP port), one console port (RS-232), and one USB port. |
| N9K-C9364C |
Cisco Nexus 9300 platform switch with 64 40/100-Gigabit QSFP28 ports and two 1/10-Gigabit SFP+ ports. The last 16 of the QSFP28 ports are colored green to indicate that they support wire-rate MACsec encryption. |
Table 7. Fixed Spine Switch Power Supply Units
| Product ID |
Description |
| N9K-PAC-1200W |
1200W AC power supply, port side intake pluggable Note: This power supply is supported only by the Cisco Nexus 93120TX and 9336PQ ACI-mode switches |
| N9K-PAC-1200W-B |
1200W AC power supply, port side exhaust pluggable Note: This power supply is supported only by the Cisco Nexus 93120TX and 9336PQ ACI-mode switches |
| NXA-PAC-1200W-PE |
1200W AC power supply, port side exhaust pluggable, with higher fan speeds for NEBS compliance |
| NXA-PAC-1200W-PI |
1200W AC power supply, port side intake pluggable, with higher fan speeds for NEBS compliance |
| NXA-PAC-1100W-PE2 |
1100W AC power supply, port side exhaust pluggable |
| NXA-PAC-1100W-PI2 |
1100W AC power supply, port side intake pluggable |
| NXA-PAC-750W-PE |
750W AC power supply, port side exhaust pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only on release 14.2(1) and later. |
| NXA-PAC-750W-PI |
750W AC power supply, port side intake pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only on release 14.2(1) and later. |
| NXA-PDC-1100W-PE |
1100W AC power supply, port side exhaust pluggable |
| NXA-PDC-1100W-PI |
1100W AC power supply, port side intake pluggable |
| NXA-PDC-930W-PE |
930W AC power supply, port side exhaust pluggable |
| NXA-PDC-930W-PI |
930W AC power supply, port side intake pluggable |
| NXA-PHV-1100W-PE |
1100W HVAC/HVDC power supply, port-side exhaust |
| NXA-PHV-1100W-PI |
1100W HVAC/HVDC power supply, port-side intake |
| N9K-PUV-1200W |
1200W HVAC/HVDC dual-direction airflow power supply |
Table 8. Fixed Spine Switch Fans
| Product ID |
Description |
| N9K-C9300-FAN3 |
Burgundy port side intake fan |
| N9K-C9300-FAN3-B |
Blue port side exhaust fan |
| NXA-FAN-160CFM-PE |
Blue port side exhaust fan |
| NXA-FAN-160CFM-PI |
Burgundy port side intake fan |
| NXA-FAN-35CFM-PE |
Blue port side exhaust fan |
| NXA-FAN-35CFM-PI |
Burgundy port side intake fan |
Table 9. Fixed Leaf Switches
| Product ID |
Description |
| N9K-C9316D-GX |
Cisco Nexus 9300 platform switch with 16 10/40/100/400-Gigabit QSFP-DD ports (ports 1-16). |
| N9K-C9364C-GX |
Cisco Nexus 9300 platform switch with 64 100-Gigabit Ethernet QSFP28 ports, two management ports (one RJ-45 port and one SFP port), one console port (RS-232), and one USB port. |
| N9K-C93600CD-GX |
Cisco Nexus 9300 platform switch with 28 10/40/100-Gigabit Ethernet QSFP28 ports (ports 1-28) and 8 10/40/100/400-Gigabit QSFP-DD ports (ports 29-36). |
| N9K-C93180YC-FX3 |
Cisco Nexus 9300 platform switch with 48 100M/1/10/25-Gigabit Ethernet SFP28 ports, 6 40/100-Gigabit QSFP28 ports, two management ports (one 10/100/1000BASE-T and one SFP+), one console port (RS-232), and one USB port. |
| N9K-C93108TC-FX3P |
Cisco Nexus 9300 platform switch with 48 100M/1/10-GBASE-T (copper) ports, 6 40/100-Gigabit QSFP28 ports, two management ports (one 10/100/1000BASE-T port and one SFP port), one console port (RS-232), and one USB port. |
| N9K-C93240YC-FX2 |
Cisco Nexus 9300 platform switch with 48 1/10/25-Gigabit Ethernet SFP28 ports and 12 40/100-Gigabit Ethernet QSFP28 ports. The N9K-C93240YC-FX2 is a 1.2-RU switch. Note: 10/25G-LR-S with QSA is not supported. |
| N9K-C93216TC-FX2 |
Cisco Nexus 9300 platform switch with 96 1/10GBASE-T (copper) front panel ports and 12 40 /100-Gigabit Ethernet QSFP28 spine-facing ports |
| N9K-C93360YC-FX2 |
Cisco Nexus 9300 platform switch with 96 1/10/25-Gigabit front panel ports and 12 40 /100-Gigabit Ethernet QSFP spine-facing ports. Note: The supported total number of fabric ports and port profile converted fabric links is 64. |
| N9K-C9336C-FX2 |
Cisco Nexus C9336C-FX2 Top-of-rack (ToR) switch with 36 fixed 40/100-Gigabit Ethernet QSFP28 spine-facing ports. Note: 1-Gigabit QSA is not supported on ports 1/1-6 and 1/33-36. The port profile feature supports downlink conversion of ports 31 through 34. Ports 35 and 36 can only be used as uplinks. |
| N9K-C93108TC-FX |
Cisco Nexus 9300 platform switch with 48 1/10GBASE-T (copper) front panel ports and 6 fixed 40/100-Gigabit Ethernet QSFP28 spine-facing ports. Note: Incoming FCOE packets are redirected by the supervisor module. The data plane-forwarded packets are dropped and are counted as forward drops instead of as supervisor module drops. |
| N9K-C93108TC-FX-24 |
Cisco Nexus 9300 platform switch with 24 1/10GBASE-T (copper) front panel ports and 6 fixed 40/100-Gigabit Ethernet QSFP28 spine-facing ports. Note: Incoming FCOE packets are redirected by the supervisor module. The data plane-forwarded packets are dropped and are counted as forward drops instead of as supervisor module drops. |
| N9K-C93180YC-FX |
Cisco Nexus 9300 platform switch with 48 1/10/25-Gigabit Ethernet SFP28 front panel ports and 6 fixed 40/100-Gigabit Ethernet QSFP28 spine-facing ports. The SFP28 ports support 1-, 10-, and 25-Gigabit Ethernet connections and 8-, 16-, and 32-Gigabit Fibre Channel connections. Note: Incoming FCOE packets are redirected by the supervisor module. The data plane-forwarded packets are dropped and are counted as forward drops instead of as supervisor module drops. |
| N9K-C93180YC-FX-24 |
Cisco Nexus 9300 platform switch with 24 1/10/25-Gigabit Ethernet SFP28 front panel ports and 6 fixed 40/100-Gigabit Ethernet QSFP28 spine-facing ports. The SFP28 ports support 1-, 10-, and 25-Gigabit Ethernet connections and 8-, 16-, and 32-Gigabit Fibre Channel connections. Note: Incoming FCOE packets are redirected by the supervisor module. The data plane-forwarded packets are dropped and are counted as forward drops instead of as supervisor module drops. |
| N9K-C9348GC-FXP |
Cisco Nexus 9348GC-FXP switch with 48 100/1000-Megabit 1GBASE-T downlink ports, 4 10-/25-Gigabit SFP28 downlink ports, and 2 40-/100-Gigabit QSFP28 uplink ports. |
| N9K-C93108TC-EX |
Cisco Nexus 9300 platform switch with 48 1/10GBASE-T (copper) front panel ports and 6 40/100-Gigabit QSFP28 spine facing ports. |
| N9K-C93108TC-EX-24 |
Cisco Nexus 9300 platform switch with 24 1/10GBASE-T (copper) front panel ports and 6 40/100-Gigabit QSFP28 spine facing ports. |
| N9K-C93180LC-EX |
Cisco Nexus 9300 platform switch with 24 40-Gigabit front panel ports and 6 40/100-Gigabit QSFP28 spine-facing ports. The switch can be used as either a 24 40G port switch or a 12 100G port switch. If 100G is connected the Port1, Port 2 will be HW disabled. |
| N9K-C93180YC-EX |
Cisco Nexus 9300 platform switch with 48 1/10/25-Gigabit front panel ports and 6-port 40/100 Gigabit QSFP28 spine-facing ports. |
| N9K-C93180YC-EX-24 |
Cisco Nexus 9300 platform switch with 24 1/10/25-Gigabit front panel ports and 6-port 40/100 Gigabit QSFP28 spine-facing ports. |
| N9K-C93120TX |
Cisco Nexus 9300 platform switch with 96 1/10GBASE-T (copper) front panel ports and 6-port 40-Gigabit Ethernet QSFP spine-facing ports. |
Table 10. Fixed Leaf Switch Power Supply Units
| Product ID |
Description |
| NXA-PAC-2KW-PE |
Nexus 9000 2KW AC power supply, port-side exhaust Note: This power supply is supported only by the Cisco Nexus 9364C-GX ACI-mode switch. |
| NXA-PAC-2KW-PI |
Nexus 9000 2KW AC power supply, port-side intake Note: This power supply is supported only by the Cisco Nexus 9364C-GX ACI-mode switch. |
| N9K-PAC-1200W |
1200W AC power supply, port side intake pluggable Note: This power supply is supported only by the Cisco Nexus 93120TX and 9336PQ ACI-mode switches |
| N9K-PAC-1200W-B |
1200W AC power supply, port side exhaust pluggable Note: This power supply is supported only by the Cisco Nexus 93120TX and 9336PQ ACI-mode switches |
| N9k-PAC-3000W-B |
3000W AC power supply, port side intake |
| N9K-PAC-650W |
650W AC power supply, port side intake pluggable |
| N9K-PAC-650W-B |
650W AC power supply, port side exhaust pluggable |
| NXA-PAC-1200W-PE |
1200W AC power supply, port side exhaust pluggable, with higher fan speeds for NEBS compliance |
| NXA-PAC-1200W-PI |
1200W AC power supply, port side intake pluggable, with higher fan speeds for NEBS compliance |
| NXA-PAC-1100W-PE2 |
1100W AC power supply, port side exhaust pluggable |
| NXA-PAC-1100W-PI2 |
1100W AC power supply, port side intake pluggable |
| NXA-PAC-750W-PE |
750W AC power supply, port side exhaust pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only on release 14.2(1) and later. |
| NXA-PAC-750W-PI |
750W AC power supply, port side intake pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only on release 14.2(1) and later. |
| NXA-PAC-650W-PE |
650W AC power supply, port side exhaust pluggable |
| NXA-PAC-650W-PI |
650W AC power supply, port side intake pluggable |
| NXA-PAC-500W-PE |
500W AC Power supply, port side exhaust pluggable |
| NXA-PAC-500W-PI |
500W AC Power supply, port side intake pluggable |
| NXA-PAC-350W-PE |
350W AC power supply, port side exhaust pluggable |
| NXA-PAC-350W-PI |
350W AC power supply, port side intake pluggable |
| NXA-PDC-2KW-PE |
Nexus 9000 2KW DC power supply, port-side exhaust Note: This power supply is supported only by the Cisco Nexus 9364C-GX ACI-mode switch. |
| NXA-PDC-2KW-PI |
Nexus 9000 2KW DC power supply, port-side intake Note: This power supply is supported only by the Cisco Nexus 9364C-GX ACI-mode switch. |
| NXA-PDC-1100W-PE |
1100W AC power supply, port side exhaust pluggable |
| NXA-PDC-1100W-PI |
1100W AC power supply, port side intake pluggable |
| NXA-PDC-930W-PE |
930W AC power supply, port side exhaust pluggable |
| NXA-PDC-930W-PI |
930W AC power supply, port side intake pluggable |
| NXA-PDC-440W-PE |
440W DC power supply, port side exhaust pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only by the Cisco Nexus 9348GC-FXP ACI-mode switch. |
| NXA-PDC-440W-PI |
440W DC power supply, port side intake pluggable, with higher fan speeds for NEBS compliance Note: This power supply is supported only by the Cisco Nexus 9348GC-FXP ACI-mode switch. |
| NXA-PHV-2KW-PE |
Nexus 9000 2KW AC power supply, port-side exhaust Note: This power supply is supported only by the Cisco Nexus 9364C-GX ACI-mode switch. |
| NXA-PHV-2KW-PI |
Nexus 9000 2KW AC power supply, port-side intake Note: This power supply is supported only by the Cisco Nexus 9364C-GX ACI-mode switch. |
| NXA-PHV-1100W-PE |
1100W HVAC/HVDC power supply, port-side exhaust |
| NXA-PHV-1100W-PI |
1100W HVAC/HVDC power supply, port-side intake |
| NXA-PHV-350W-PE |
350W HVAC/HVDC power supply, port-side exhaust |
| NXA-PHV-350W-PI |
350W HVAC/HVDC power supply, port-side intake |
| N9K-PUV-1200W |
1200W HVAC/HVDC dual-direction airflow power supply |
| N9K-PUV-3000W-B |
3000W AC power supply, port side exhaust pluggable |
| UCSC-PSU-930WDC V01 |
Port side exhaust DC power supply compatible with all ToR leaf switches |
| UCS-PSU-6332-DC |
930W DC power supply, reversed airflow (port side exhaust) |
Table 11. Fixed Leaf Switch Fans
| Product ID |
Description |
| N9K-C9300-FAN2 |
Burgundy port side intake fan |
| N9K-C9300-FAN2-B |
Blue port side exhaust fan |
| N9K-C9300-FAN3 |
Burgundy port side intake fan |
| N9K-C9300-FAN3-B |
Blue port side exhaust fan |
| NXA-FAN-160CFM2-PE |
Blue port side exhaust fan |
| NXA-FAN-160CFM2-PI |
Burgundy port side intake fan |
| NXA-FAN-160CFM-PE |
Blue port side exhaust fan |
| NXA-FAN-160CFM-PI |
Burgundy port side intake fan |
| NXA-FAN-30CFM-B |
Burgundy port side intake fan |
| NXA-FAN-30CFM-F |
Blue port side exhaust fan |
| NXA-FAN-35CFM-PE |
Blue port side exhaust fan |
| NXA-FAN-35CFM-PI |
Burgundy port side intake fan |
| NXA-FAN-65CFM-PE |
Blue port side exhaust fan |
| NXA-SFAN-65CFM-PE |
Blue port side exhaust fan |
| NXA-FAN-65CFM-PI |
Burgundy port side intake fan |
| NXA-SFAN-65CFM-PI |
Burgundy port side intake fan |
No Longer Supported Hardware
Starting in the 15.0(1) release, the following hardware is no longer supported:
| Product Type |
Product ID |
| Spine switch |
N9K-C9336PQ |
| Modular spine switch line card |
N9K-X9736PQ |
| Modular spine switch fabric module |
N9K-C9504-FM N9K-C9508-FM N9K-C9516-FM |
| Leaf Switch |
N9K-C9372PX-E N9K-C9372TX-E N9K-C9332PQ N9K-C9372PX N9K-C9372TX N9K-C9396PX N9K-C9396TX N9K-C93128TX |
| Expansion Modules |
N9K-M12PQ N9K-M6PQ N9K-M6PQ-E |
Prior to upgrading your fabric to release 15.0(1) or later, replace these hardware elements in your fabric with other supported hardware. For modular spine switches, replace all unsupported modular line cards and fabric modules because these old generation line cards and fabric modules cannot be operated with newer line cards and fabric modules in the same chassis.
If you attempt to upgrade one of the unsupported hardware to the 15.0(1) release or later, the hardware will unsuccessfully attempt to boot three times, after which the switch will be reverted to the release that was previously installed on it. Therefore, the unsupported hardware will not upgrade to release 15.0(1) or later and the Cisco ACI fabric will operate with inconsistent firmware releases in each switch, which is why we recommend that you replace the unsupported hardware prior to performing the upgrade.
Supported FEX Models
For tables of the FEX models that the Cisco Nexus 9000 Series ACI Mode switches support, see the following webpage:
For more information on the FEX models, see the Cisco Nexus 2000 Series Fabric Extenders Data Sheet at the following location:
· The Cisco N9K-C93600CD-GX switch can now be used as a spine switch.
New Software Features
For new software features, see the Cisco Application Policy Infrastructure Controller Release Notes, Release 5.2(1).
Changes in Behavior
For the changes in behavior, see the Cisco ACI Releases Changes in Behavior document.
Open Issues
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 15.2(1) releases in which the bug exists. A bug might also exist in releases other than the 15.2(1) releases.
| Bug ID |
Description |
Exists in |
| When an ARP request is generated from one endpoint to another endpoint in an isolated EPG, an ARP glean request is generated for the first endpoint. |
15.2(1g) and later |
|
| Applications are slow when deployed in servers that are connected to a Tier-1 leaf switch. |
15.2(1g) and later |
|
| Traffic originating from a vPC TEP is dropped for Layer 2 multicast and unknown unicast traffic when pod redundancy is triggered. |
15.2(1g) and later |
|
| This issue is only observed with Cisco ACI Multi-Pod Infra OSPF B2B links. When B2B OSPF link goes down, the faults for the multiPodDirect instance will not be raised. Also, the Oper for the multiPodDirect instance will not be updated in the DME DB. |
15.2(1g) and later |
|
| Traffic is dropped for PBR redirected traffic from a remote leaf switch to the service device in the main pod, after the bridge domain used for service device hosting is completely undeployed from all of the remote leaf switches. |
15.2(1g) and later |
|
| If PBR is configured with an L3Out, the fault "tracked-as-down" may be incorrectly raised on the destGrp object in the switch. There is no impact to traffic. |
15.2(1g) and later |
|
| The PBR destination group for bypass action is not properly programmed with PBR service graph for service devices behind l3out and with "bypass" action enabled to redirect to another service node in the graph.Now on bypass switchover, the traffic doesn't get redirected to the next service node in the chain. |
15.2(1g) and later |
|
| In the ipmgr process, for the primary subnet, an overlapping address is ignored and is not pushed to EPM. But, this is not enforced for secondary subnets. |
15.2(1g) and later |
|
| The static source-specific multicast exact configuration of the quality level for EEC2/eEEC has a lower preference than the internal OSC. The same is not true if the user considers the quality level coming on wire. There, the EEC2/eEEC are treated equally, and so there is no problem. On Tx, the switch always considers and transmits the quality level as locked. We do not recommend that you configure the exact Tx in the field. |
15.2(1g) and later |
|
| This condition occurs when the RX quality level is hardcoded to eEEC. In this case, eEEC will be treated lower than ST3. The issue will not be seen if a user considers the incoming quality level on wire, which is the recommended configuration. On wire, it is treated similar to ST3. |
15.2(1g) and later |
|
| A leaf node crashes when PFC or LLFC is enabled on a stretched fabric or a Multi-tier fabric. PFC and LLFC is mainly used for FCoE and RoCE. For a stretched fabric, when a transit leaf node that has connectivity to spine nodes in both locations receives the traffic that matches the QoS class with No-Drop-Cos and PFC enabled, the transit leaf node crashes. For a Multi-tier fabric, when a tier-2 leaf node receives the traffic that matches the QoS class with No-Drop-Cos and PFC enabled, the tier-2 leaf node crashes. |
15.2(1g) and later |
|
| The PTP feature will not work if Cisco N9K-C93600CD-GX and N9K-C9364C-GX switches are used as spines. |
15.2(1g) and later |
|
| A Nexus Insights app sees some extra flows sent from the spine switch when a subnet is added in a VRF instance for flow telemetry and then the subnet is deleted. |
15.2(1g) and later |
|
| In summary, a remote leaf switch endpoint is sending multicast traffic, and after a spine switch fabric card reload, traffic is hashed on this fabric card, which causes the endpoint to be marked as rogue and penalize that endpoint for 30 minutes. |
15.2(1g) and later |
|
| The value of "Use count" in the "show flow monitor" command output is incorrect. |
15.2(1g) and later |
|
| External route import for a VRF instance fails on a leaf switch after removing a shared services contract between two EPGs. |
15.2(1g) and later |
|
| For a Cisco ACI fabric with more than 128 leaf switches in a given pod, such as 210 leaf switches in a single pod deployment, after enabling PTP globally, only 128 leaf switches are able to enable PTP. The remaining 82 leaf switches fail to enable PTP due to the error F2728 latency-enable-failed. |
15.2(1g) and later |
|
| A switch reloads due to a kernel panic that is triggered by oom-killer. The dmesg log gets filled with messages similar to the following example: [1056.987558] Shared skb 0xffff880828f7f9c0 users -1519686805 dma vaddr 0xffff880828f94018 dma paddr 0x0000000828f94018 len 1802201963 vrf 1802201963 protocol 27499 |
15.2(1g) and later |
|
| The power supply status flaps between failed and OK. |
15.2(1g) and later |
|
| An endpoint may fail to resolve an ARP request of another endpoint. |
15.2(1g) and later |
|
| A route profile that matches on community list and sets the local pref and community is not working post upgrade to 5.2.x release. route-map imp-l3out-L3OUT_WAN-peer-2359297, permit, sequence 4201 Match clauses: community (community-list filter): peer16389-2359297-exc-ext-in-L3OUT_WAN_COMMUNITY-rgcom Set clauses: local-preference 200 community xxxxx:101 xxxxx:500 xxxxx:601 xxxxy:4 additive The match clause works as expected, but the set clause is ignored. |
15.2(1g) and later |
|
| A 40G link takes an extended amount of time for link bring up to occur. |
15.2(1g) and later |
|
| There is a long delay when connecting a Cisco N9K-C9336C-FX2 switch to a Mellanox NIC/40G using QSFP-40G-SR4. The status of the port is down, not connected. |
15.2(1g) and later |
|
| An ACI switch's console may continuously output messages similar to: svc_ifc_eventmg (*****) Ran 7911 msecs in last 7924 msecs |
15.2(1g) and later |
|
| The BFD process crashes in Cisco ACI switches and the BFD process is listed in the output of the "show cores" command. |
15.2(1g) and later |
|
| Fiber interfaces (QSA) show up as "Fcot Copper" in the USD port information. When a 10G Fiber optics with Copper QSA is inserted, the fcot gets updated as Copper only instead of Fiber. |
15.2(1g) and later |
|
| A leaf switch may the bring front panel ports up before programming all policies, which causes traffic to get dropped. The issue is specific to a stateless reload or upgrade. The root cause is related to pushing the configuration from the Cisco APIC to the leaf switch, resolving all objects and programming hardware tables. In some corner cases, the bootstrap may be falsely claimed as completed and ports go up while the actual hardware tables are not fully ready. Another symptom may be a significant amount of time needed for bootstrap (possibly over an hour). |
15.2(1g) and later |
|
| The parser drops IP-in-IP packets that are associated with IP traffic on ingress leaf switches. |
15.2(1g) and later |
|
| After reloading a leaf switch, HAL becomes unresponsive, other processes generate a core, and HAL continuously runs with ZMQ processing. |
15.2(1g) and later |
|
| 100Mb links that use GLC-T/GLC-TE transceivers do not come up. |
15.2(1g) and later |
|
| There are actrl.Rule programming failures followed by a policy-mgr HAP reset. |
15.2(1g) and later |
|
| The 30 second input rate and 30 second output rate show values beyond 30 seconds for an interface that is disabled |
15.2(1g) and later |
|
| When one of the vPC peers reloads and comes up, the non-reloaded peer is seen to be suspending the vPC interfaces. |
15.2(1g) and later |
|
| The EPM process crashed when there was no disk space was available at /var/sysmgr/tmp_logs/. |
15.2(1g) and later |
|
| Traffic that is forwarded by a spine switch toward a leaf switch is dropped by one of the spine switch's fabric modules.On this fabric module where packets are dropped, the TEP of the destination leaf switch is not programmed in FIB and HAL. |
15.2(1g) and later |
|
| Breakout ports configured as port channel members are no longer part of the port channel post clean reload. |
15.2(1g) and later |
Resolved Issues
Click the bug ID to access the Bug Search tool and see additional information about the bug. The "Fixed In" column of the table specifies whether the bug was resolved in the base release or a patch release.
| Bug ID |
Description |
Fixed in |
| Copy service traffic will fail to reach the TEP where the copy devices are connected. Traffic will not be seen on the spine switches. |
15.2(1g) |
|
| On a remote leaf switch, the sclass of a shared service endpoint can be incorrect due to overwriting of the sclass by the new share service prefix on a different EPG.Example:On the remote leaf switch, XR IP <IP1> is learned with sclass <S1>, which corresponds to the EPG sclass <sclass1> that is based on LPM (<prefix1>/24).If a more specific route leak subnet <prefix1/>29 is configured, then the XR endpoint is still learned with the EPG <sclass1> instead of the sclass coming from the <prefix1/>29 configuration. |
15.2(1g) |
|
| Remote leaf switch discovery does not happen, causing the remote leaf switch to not join the fabric. |
15.2(1g) |
|
| A severity 2 fault may be seen on a Cisco APIC, which indicates that a tunnel is down with a destination IP address of 0.0.0.0 after a policy upgrade. |
15.2(1g) |
|
| Consumer routes are not leaked into provider VRFs. |
15.2(1g) |
|
| Consumer routes are not leaked into provider VRFs. |
15.2(1g) |
|
| The prefix is not advertised out of the permit route-map if configured with deny rule in an MPLS export route-map, and the prefix is permitted in another MPLS export route-map belonging to same VRF and same border leaf switch. |
15.2(1g) |
|
| When using a 100G auto-negotiation link with a cable length of 3 meters or longer, the link up time-up could be as long as 300 seconds. |
15.2(1g) |
|
| When DPP is enabled, the ping response is sent with a CoS value of 0 for a request whose CoS value is 1 or 2. |
15.2(1g) |
Known Issues
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 15.2(1) releases in which the bug exists. A bug might also exist in releases other than the 15.2(1) releases.
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| The show interface command shows the tunnel's Rx/Tx counters as 0. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| Continuous "threshold exceeded" messages are generated from the fabric. |
15.2(1g) and later |
|
| Switch rescue user ("admin") can log into fabric switches even when TACACS is selected as the default login realm. |
15.2(1g) and later |
|
| An extra 4 bytes is added to the untagged packet with Egress local and remote SPAN. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| The power supply will not be detected after performing a PSU online insertion and removal (OIR). |
15.2(1g) and later |
|
| The access-port operational status is always "trunk". |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| The transceiver type for some Cisco AOC (active optical) cables is displayed as ACU (active copper). |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| Traffic from the orphan port to the vPC pair is only updated on the destination node, so the traffic count shows as excess. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| Atomic counters on the border leaf do not increment for traffic from an endpoint group going to the Layer 3 out interface. |
15.2(1g) 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. |
15.2(1g) and later |
|
| TEP counters from the border leaf to remote leaf nodes do not increment. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| Traffic is dropped between two isolated EPGs. |
15.2(1g) and later |
|
| The iping command’s replies get dropped by the QOS ingress policer. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| EPG statistics only count total bytes and packets. The breakdown of statistics into multicast/unicast/broadcast is not available on new hardware. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| The default minimum bandwidth is used if the BW parameter is set to "0", and so traffic will still flow. |
15.2(1g) and later |
|
| The debounce timer is not supported on 25G links. |
15.2(1g) and later |
|
| With the N9K-C93180YC-EX switch, drop packets, such as MTU or storm control drops, are not accounted for in the input rate calculation. |
15.2(1g) and later |
|
| For traffic coming out of an L3out to an internal EPG, stats for the actrlRule will not increment. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| SAN boot over a virtual Port Channel or traditional Port Channel does not work. |
15.2(1g) and later |
|
| A policy-based redirect (PBR) policy to redirect IP traffic also redirects IPv6 neighbor solicitation and neighbor advertisement packets. |
15.2(1g) and later |
|
| 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. |
15.2(1g) and later |
|
| If you have only one spine switch that is part of the infra WAN and you reload that switch, there can be drops in traffic. You should deploy the infra WAN on more than one spine switch to avoid this issue. |
15.2(1g) and later |
|
| Slow drain is not supported on FEX Host Interface (HIF) ports. |
15.2(1g) 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. |
15.2(1g) and later |
|
| Bridge domain subnet routes advertised out of the Cisco ACI fabric through an OSPF L3Out can be relearned in another node belonging to another OSPF L3Out on a different area. |
15.2(1g) and later |
|
| After upgrading a switch, Layer 2 multicast traffic flowing across PODs gets affected for some of the bridge domain Global IP Outsides. |
15.2(1g) and later |
|
| If Cisco ACI Virtual Edge or AVS is operating in VxLAN non-switching mode behind a FEX, the traffic between endpoints in the same EPG will fail when the bridge domain has ARP flooding enabled. |
15.2(1g) and later |
|
| There is a traffic blackhole that lasts anywhere from a few seconds to a few mins after a border leaf switch is restored. |
15.2(1g) and later |
|
| During an upgrade on a dual-SUP system, the standby SUP may go into a failed state. |
15.2(1g) and later |
|
| There is a policy drop that occurs with L3Out transit cases. |
15.2(1g) and later |
|
| A switch reloads due to a sysmgr heartbeat failure and sysmgr HAP reset. |
15.2(1g) and later |
|
| In a port group that has ports of mixed speeds, the first port in the port group that has valid optics present and is not in the admin down state is processed. The ports that come up later are brought up if they are using the same speed; otherwise, they are put in the hw-disabled state. For example, if ports 14 and 15 are up and are using the 100G speed, then if ports 13 and 16 are using the 40G speed, these ports will be put in the hw-disabled state. After reloading or upgrading, you might not have the same interfaces in the port group in the UP state and in the hw-disabled state as you did before the reload or upgrade. |
15.2(1g) and later |
|
| A link flap policy can be configured on Cisco switches that were released prior to the -EX switches. However, this feature does not work with such switches and no fault is raised in the Cisco APIC. |
15.2(1g) and later |
|
| When MPLS VRF stats (egress) is compared with Layer 2 interface egress stats, we can find that the packet count matches for both while there could be a discrepancy with the bytes count. |
15.2(1g) and later |
|
| The DEI value in a Layer 2 header of spanned Tx packets from an MPLS interface might not have the same value as the actual data path packet. |
15.2(1g) and later |
|
| The event log shows VTEP tunnel down and up events. The down time and up time are the same, and there is no fault message. |
15.2(1g) and later |
|
| When a service device is connected behind an L3Out in 2-arm mode with both legs on the same leaf switch, tracking packets get dropped. |
15.2(1g) and later |
|
| Redirected traffic to a service device behind an L3Out is dropped by the service device due to the lack of proper routing information. |
15.2(1g) and later |
|
| Redirected traffic coming back from a service device behind an L3Out is dropped on the second leg. |
15.2(1g) and later |
|
| The leaf switch techsupport with a specified time range fails when the space "/mnt/ifc/log" gets filled up by more than 80%. |
15.2(1g) and later |
|
| N/A |
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. |
15.2(1g) and later |
| N/A |
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 DSCP-CoS translation policy in the APIC for the pod that translates queuing class information of the packet into the DSCP value in the outer header of the iVXLAN packet. You can also embed CoS by enabling CoS preservation. For more information, see the Cisco APIC and QoS KB article. |
15.2(1g) and later |
| N/A |
The following properties within a QoS class under "Global QoS Class policies" should not be changed from their 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) |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
Multicast router functionality is not supported when IGMP queries are received with VxLAN encapsulation. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
The rate of the number of IGMP reports sent to a leaf switch should be limited to 1000 reports per second. |
15.2(1g) and later |
| N/A |
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 switch. 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 switch. Set "unknown multicast flooding" to "Optimized Flood" on needed bridge domains. |
15.2(1g) and later |
| N/A |
Traffic destined to Static Route EP VIPs sourced from N9000 switches (switches with names that end in -EX) might not function properly because proxy route is not programmed. |
15.2(1g) and later |
| N/A |
An iVXLAN header of 50 bytes is added for traffic ingressing into the fabric. A bandwidth allowance of (50/50 + ingress_packet_size) needs to be made to prevent oversubscription from happening. If the allowance is not made, oversubscription might happen resulting in buffer drops. |
15.2(1g) and later |
| N/A |
An IP/MAC Ckt endpoint configuration is not supported in combination with static endpoint configurations. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
An IP/MAC Ckt endpoint configuration is not supported with dynamic endpoint groups. Only static endpoint groups are supported. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
Dynamic deployment of contracts based on instrImmedcy set to onDemand/lazy not supported; only immediate mode is supported. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
Direct server return is not supported for shared services. Direct server return endpoints cannot be spread around different virtual routing and forwarding (VRF) contexts. |
15.2(1g) and later |
| N/A |
Configurations for a virtual IP address can only be /32 or /128 prefix. |
15.2(1g) and later |
| N/A |
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. |
15.2(1g) and later |
| N/A |
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). |
15.2(1g) and later |
| N/A |
Learning through GARP will work only in ARP Flood Mode. |
15.2(1g) and later |
Compatibility Information
● For the supported optics per device, see the Cisco Optics-to-Device Compatibility Matrix.
● 100mb optics, such as the GLC-TE, are supported in 100mb speed only on -EX, -FX, -FX2, and -FX3 switches, such as the N9K-C93180YC-EX and N9K-C93180YC-FX, and only on front panel ports 1/1-48. 100mb optics are not supported any other switches. 100mb optics cannot be used on EX or FX leaf switches on port profile converted downlink ports (1/49-52) using QSA.
● This release supports the hardware and software listed on the ACI Ecosystem Compatibility List, and supports the Cisco AVS, release 5.2(2)SV3(3.10).
● 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 Cisco APIC (the controller cluster) to the Cisco ACI fabric, it is required to have a 10G interface on the ACI leaf.
● 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.
● 10G GLC-T transceivers cannot be used for the initial bring up between the Cisco APIC and a leaf switch. The fabric discovery process cannot occur because the transceiver needs the SFP media type to be pushed from the Cisco APIC to bring up the link.
● You cannot use the 100 megabit speed of a switch's QSFP28 ports.
● If you are using 10G copper cables, when you configure a link level policy, you must set the Physical Media Type to "SFP 10G TX."
Table 12. Modular Spine Switch Fabric Module Compatibility Information
| Product ID |
N9K-C9504-FM-G |
N9K-C9508-FM-G |
N9K-C9504-FM-E |
N9K-C9508-FM-E |
N9K-C9508-FM-E2 |
N9K-C9516-FM-E2 |
| N9K-X9716D-GX |
4 |
4 |
No |
No |
No |
No |
| N9K-X9736C-FX |
5 |
5 |
5 |
5 |
5 |
5 |
| N9K-X9736Q-FX |
5 |
5 |
5 |
5 |
5 |
5 |
| N9K-X9732C-EX |
No |
No |
4 |
4 |
4 |
4 |
Table 13. Modular Spine Switch Line Card Compatibility Information
| Product ID |
Compatibility Information |
| N9K-X9716D-GX |
If you connect a Cisco N9K-X9716D-GX breakout port to a non-Cisco ACI peer, such as a standalone switch capable of 100G, the link comes up and LLDP is detected. However, this is an unsupported scenario, but no fault is generated. |
Table 14. Fixed Spine Switches Compatibility Information
| Product ID |
Compatibility Information |
| N9K-C9364C |
You can deploy multipod or Cisco ACI Multi-Site separately (but not together) on the Cisco N9K-9364C switch starting in the 3.1 release. You can deploy multipod and Cisco ACI Multi-Site together on the Cisco N9K-9364C switch starting in the 3.2 release. A 930W-DC PSU (NXA-PDC-930W-PE or NXA-PDC-930W-PI) is supported in redundancy mode if 3.5W QSFP+ modules or passive QSFP cables are used and the system is used in 40C ambient temperature or less; for other optics or a higher ambient temperature, a 930W-DC PSU is supported only with 2 PSUs in non-redundancy mode. 1-Gigabit QSA is not supported on ports 1/49-64. This switch supports the following PSUs:
● NXA-PAC-1200W-PE
● NXA-PAC-1200W-PI
● N9K-PUV-1200W
● NXA-PDC-930W-PE
● NXA-PDC-930W-PI
|
| N9K-C9316D-GX |
1G and 100MB speeds are not supported. |
Table 15. Fixed Leaf Switches Compatibility Information
| Product ID |
Compatibility Information |
| This switch has the following limitations:
● The switch will power down in 2 minutes after the first fan failure. The switch can be powered up only after replacing the failed fan.
● For ports 1-64, every 4 ports 1-4,5-8...60-64 is referred as a quad. Each quad can be operated only with a fixed speed. For example: Ports 1-4 can operate only on 10G or 40/100G. Similarly, ports 60-64 can operate only on 10G or 40/100G.
● You cannot use mixed speeds of 10G and 40G, 10G and 100G, or 40G and 100G in a quad (1-4,5-8...21-24). Based on the port bring up sequence, the port in the quad where a speed mismatch is detected will be HW disabled.
● If there is a speed mismatch in a quad even when the ports are configured in the disabled state, the working links in that quad might get into the HW disabled state upon upgrading and reloading because the mixed speed is brought up first before the admin down configuration is pushed. As a result, you must manually perform the shut and no shut commands on the ports to bring up the links.
● There is a lane selector button on the hardware. The button is used for the breakout port LED status. Because breakout is not supported, this button does nothing.
● The maximum number of downlinks is 30 x 4 ports 10/25G (breakout) + 2 ports (1/61-62) = 122 ports. Ports 1/63 and 1/64 are reserved for fabric links and even numbers from 1/1 to 1/60 are error-disabled.
● 1G and 100MB speeds are not supported.
● All 4 fans must be operational, otherwise the switch will power down due to a fan policy trigger.
|
|
|
|
This switch has the following limitations:
● Auto-negotiation is not supported with 10G speed on ports 1 through 24.
● For ports 1 through 24, every 4 ports (1-4, 5-8, 9-12, and so on, referred to as a "quad") will operate at a fixed speed. That is, all 4 ports will operate in 10G or 40/100G; you cannot mix the speeds.
● Mixed speeds of 10G and 40G or 10G and 100G in a quad is not supported. Based on the port bring up sequence, the port in the quad where the speed mismatch is detected will be HW disabled.
● If there is a speed mismatch in a quad even though the ports are configured in the disabled state, the working links in that quad might get into the HW disabled state upon upgrading or reloading, as the mixed speed is brought up first before admin down config is pushed. To avoid this issue, you must manually use the shut and no shut commands on the working ports to bring up the links. For more information, see bug
CSCvr61096.
● Ports 25-26 and ports 27-28 (port groups of 2 ports each) will operate in a fixed speed within the respective group, and you cannot mismatch the speed.
● Uplink ports 29 to 36 do not have a mixed speed restriction; you can toggle the speed for the bidirectional ports.
● For ports 1 to 28, even if you convert any ports to uplink with bidirectional optics, you cannot toggle the speed, as it will introduce mixed speeds and will disturb the neighboring ports.
● For ports 1 to 28, if any of the ports are converted to uplink with bidirectional optics, the ports will stay in the not connected state if the peer is a 40G link.
● 4x10 and 4x25 breakout is supported on ports 25-28 and 29-34 (port profile converted downlinks).
● Ports 25-26 and 27-28 form respective port pairs, and each pair can operate with 4x10, 10G, or 4x25G speed.
● This switch does not support 4x100 breakout in this release.
● The Hardware Abstraction Layer (HAL) will spike and the console can hang if a port channel or vPC exists when overlying breakout ports are deleted. To avoid this issue, delete the PC or vPC before deleting the overlying breakout policy.
● The maximum number of downlinks is 12 x 4 ports 10/25G (breakout) + 10 x 4 ports 10/25G (breakout) = 88 ports. Ports 35 and 36 are reserved for fabric links and 12 ports are error-disabled.
● 1G and 100MB speeds are not supported.
|
| N9K-C9316D-GX |
Auto-negotiation and forward error correction are not supported when you use this switch is as a leaf switch. |
| N9K-C93180YC-FX3 |
The following information applies to this switch:
● The following ports are not supported:
◦ Antenna
◦ GNSS
◦ GPS
◦ PPS
◦ PTP GM
● When using the SFP-10G-T-X optic on a port, the you must either leave the physically adjacent ports empty or only deploy direct attach cables (DACs) to those ports.
● If you insert a non-DAC optic in a port that is physically adjacent to a port that is capable of supporting a 10G GLC-T optic, and later you insert a GLC-T optic into the GLC-T-capable port, the GLC-T optic will be hw-disabled. To bring up the GLC-T port, you must shut down the non-DAC port, then run the shut and no shut commands on the GLC-T port.
|
| N9K-C9336C-FX2 |
The following information applies to this switch:
● On older N9K-C9336C-FX2 switches, auto-negotiation does not work on port eth1/4. You can check whether your switch is older by using the following command:
ifav124-leaf5# cat /sys/kernel/cisco_board_info/hw_change_bits
0x0
The output of "0x0" indicates an older switch that has this limitation.
● You can apply a breakout configuration on ports 1 through 34, which can give up to 136 (34*4) server or downlink ports.
● Port profiles and breakouts are not supported on the same port. However, you can apply a port profile to convert a fabric port to a downlink, and then apply a breakout configuration.
● If you apply a breakout configuration on 34 ports, you must configure a port profile on the ports first, which requires you to reboot the leaf switch.
● If you apply a breakout configuration to a leaf switch for multiple ports at the same time, it can take up to 10 minutes for the hardware of 34 ports to be programmed. The ports remain down until the programming completes. The delay can occur for a new configuration, after a clean reboot, or during switch discovery.
● Ports 7 through 32 have a link bring up time of less than 2 seconds with QSFP-100G-LR4 and QSFP-40/100G-SRBD optics. For all other ports, the link up time for these optics is between 5 to 14 seconds. In the following situations, the link bring up time will also be greater than 2 seconds:
◦ After reloading the Top-of-Rack (ToR) switch
◦ When using port optical insertion and removal (OIR)
◦ When performing bulk flaps of ports on the ToR switch
|
| N9K-C93240YC-FX2 |
The following information applies when this switch is configured with port-side intake airflow:
● Ports 2, 6, 8, 12, 14, 18, 20, 24, 26, 30, 32, 36, 38, 42, 44, and 48 are capable of supporting the 10G GLC-T optic. After you configure these ports to use 10G GLC-T, these ports will be the only ports on the switch that can support 10G GLC-T. Without being configured for 10G GLC-T, these ports behave as normal switch ports.
● If you configure port 12 for 10G GLC-T, then ports 9 and 15 must either be left empty or must deploy only DACs.
● Ports 49 through 60 can be configured to use 10G GLC-T or can be normal ports, regardless of the configuration of the other ports.
The following information applies when this switch is configured with port-side exhaust airflow:
● Ports 6, 12, 18, 24, 30, 36, 42, and 48 are capable of supporting the 10G GLC-T optic. After you configure these ports to use 10G GLC-T, these ports will be the only ports on the switch that can support 10G GLC-T. Without being configured for 10G GLC-T, these ports behave as normal switch ports.
● If you configure port 12 for 10G GLC-T, then ports 9, 11, and 15 must either be left empty or must deploy only DACs.
● Ports 49 through 60 can be configured to use 10G GLC-T or can be normal ports, regardless of the configuration of the other ports.
The following information applies regardless of the airflow direction:
● When using the SFP-10G-T-X optic on a port, the you must either leave the physically adjacent ports empty or only deploy direct attach cables (DACs) to those ports.
● If you insert a non-DAC optic in a port that is physically adjacent to a port that is capable of supporting a 10G GLC-T optic, and later you insert a GLC-T optic into the GLC-T-capable port, the GLC-T optic will be hw-disabled. To bring up the GLC-T port, you must shut down the non-DAC port, then run the shut and no shut commands on the GLC-T port.
|
| N9K-C93360YC-FX2 |
The following information applies to this switch:
● Ports 1, 4, 5, 8, 41, 44, 45, 48, 49, 52, 53, 56, 57, 60, 61, 64, 65, 68, 69, 72, 73, 76, 77, 80, 81, 84, 85, 88, 89, 92, 93, and 96 are capable of supporting the 10G GLC-T optic. After you configure these ports to use 10G GLC-T, these ports will be the only ports on the switch that can support 10G GLC-T. Without being configured for 10G GLC-T, these ports behave as normal switch ports.
● If you configure port 60 for 10G GLC-T, then ports 58, 59, and 62 must either be left empty or must deploy only DACs.
● Ports 97 through 108 can be configured to use 10G GLC-T or can be normal ports, regardless of the configuration of the other ports.
● When using the SFP-10G-T-X optic on a port, the you must either leave the physically adjacent ports empty or only deploy direct attach cables (DACs) to those ports.
● If you insert a non-DAC optic in a port that is physically adjacent to a port that is capable of supporting a 10G GLC-T optic, and later you insert a GLC-T optic into the GLC-T-capable port, the GLC-T optic will be hw-disabled. To bring up the GLC-T port, you must shut down the non-DAC port, then run the shut and no shut commands on the GLC-T port.
|
| N9K-C9348GC-FXP |
This switch supports the following PSUs:
● NXA-PAC-350W-PI
● NXA-PAC-350W-PE
● NXA-PAC-1100W-PI
● NXA-PAC-1100W-PE
● Incoming FCOE packets are redirected by the supervisor module. The data plane-forwarded packets are dropped and are counted as forward drops instead of as supervisor module drops.
● This switch does not support the 10G GLC-T optic.
● The PSU SPROM is not readable when the PSU is not connected. The model displays as "UNKNOWN" and status of the module displays as "shutdown."
|
| N9K-C93180YC-FX-24 |
This switch does not support the 10G GLC-T optic. |
| N9K-C93180YC-FX |
The following information applies to this switch:
● Auto-negotiation is not supported if you convert port 51 or 52 to a downlink and you have 40/100G copper cables connected.
● Ports 1, 4, 5, 8, 9, 12, 13, 16, 37, 40, 41, 44, 45, and 48 are capable of supporting the 10G GLC-T optic. After you configure these ports to use 10G GLC-T, these ports will be the only ports on the switch that can support 10G GLC-T. Without being configured for 10G GLC-T, these ports behave as normal switch ports.
● If you configure port 12 for 10G GLC-T, then ports 10, 11, and 14 must either be left empty or must deploy only DACs.
● Ports 49 through 54 can be configured to use 10G GLC-T or can be normal ports, regardless of the configuration of the other ports.
● When using the SFP-10G-T-X optic on a port, the you must either leave the physically adjacent ports empty or only deploy direct attach cables (DACs) to those ports.
● If you insert a non-DAC optic in a port that is physically adjacent to a port that is capable of supporting a 10G GLC-T optic, and later you insert a GLC-T optic into the GLC-T-capable port, the GLC-T optic will be hw-disabled. To bring up the GLC-T port, you must shut down the non-DAC port, then run the shut and no shut commands on the GLC-T port.
|
| N9K-C93180YC-EX-24 |
This switch does not support the 10G GLC-T optic. |
| N9K-C93180YC-EX |
The following information applies to this switch:
● The following FEC modes are not supported on N9K-C93180YC-EX ports 1 through 48 when running in 25G speed:
◦ cl91-rs-fec
◦ cons16-rs-fec
◦ ieee-rs-fec
● Auto-negotiation is not supported if you convert port 51 or 52 to a downlink and you have 40/100G copper cables connected.
● Ports 1, 4, 5, 8, 9, 12, 13, 16, 37, 40, 41, 44, 45, and 48 are capable of supporting the 10G GLC-T optic. After you configure these ports to use 10G GLC-T, these ports will be the only ports on the switch that can support 10G GLC-T. Without being configured for 10G GLC-T, these ports behave as normal switch ports.
● If you configure port 12 for 10G GLC-T, then ports 10, 11, and 14 must either be left empty or must deploy only DACs.
● Ports 49 through 54 can be configured to use 10G GLC-T or can be normal ports, regardless of the configuration of the other ports.
● When using the SFP-10G-T-X optic on a port, the you must either leave the physically adjacent ports empty or only deploy direct attach cables (DACs) to those ports.
● If you insert a non-DAC optic in a port that is physically adjacent to a port that is capable of supporting a 10G GLC-T optic, and later you insert a GLC-T optic into the GLC-T-capable port, the GLC-T optic will be hw-disabled. To bring up the GLC-T port, you must shut down the non-DAC port, then run the shut and no shut commands on the GLC-T port.
|
| N9K-C93180LC-EX |
This switch has the following limitations:
● The top and bottom ports must use the same speed. If there is a speed mismatch, the top port takes precedence and bottom port will be error disabled. Both ports both must be used in either the 40 Gbps or 10 Gbps mode.
● Ports 26 and 28 are hardware disabled.
● This release supports 40 and 100 Gbps for the front panel ports. The uplink ports can be used at the 100 Gbps speed.
● Port profiles and breakout ports are not supported on the same port.
|
| Hardware Type |
CloudSec Support |
|
| N9K-C9332C |
Switch |
Yes, only on the last 8 ports |
| N9K-C9364C |
Switch |
Yes, only on the last 16 ports |
| N9K-X9736C-FX |
Line Card |
Yes, only on the last 8 ports |
● The following additional CloudSec compatibility restrictions apply:
◦ CloudSec only works with spine switches in Cisco ACI and only works between sites managed by Cisco ACI Multi-Site.
◦ For CloudSec to work properly, all of the spine switch links that participate in Cisco ACI Multi-Site must have MACsec/CloudSec support.
Usage Guidelines
● 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 Cisco Application Policy Infrastructure Controller Release Notes, Release 5.2(1) for policy information.
◦ 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
● Leaf switches and spine switches typically have memory utilization of approximately 70% to 75%, even in a new deployment where no configuration has been pushed. This amount of memory utilization is due to the Cisco ACI-specific processes, which take up more memory compared to a standalone Nexus deployment. The memory utilization is not a problem unless it exceeds 90%. You can open a Cisco TAC case to troubleshoot proactively when memory utilization is more than 85%.
● Leaf and spine switches from two different fabrics cannot be connected regardless of whether the links are administratively kept down.
● If you replace a switch where a Cisco APIC is connected, make sure that the Cisco APIC has two connections: one active/backup to the replaced switch and another to a different switch. Otherwise, the Cisco APIC will not join the cluster after you replace the switch.
● Only one instance of OSPF (or any multi-instance process using the managed object hierarchy for configurations) can have the write access to operate the database. Due to this, the operational database is limited to the default OSPF process alone and the multipodInternal instance does not store any operational data. To debug an OSPF instance ospf-multipodInternal, use the command in VSH prompt. Do not use ibash because some ibash commands depend on Operational data stored in the database.
● When you enable or disable Federal Information Processing Standards (FIPS) on a Cisco ACI fabric, you must reload each of the switches in the fabric for the change to take effect. The configured scale profile setting is lost when you issue the first reload after changing the FIPS configuration. The switch remains operational, but it uses the default port scale profile. This issue does not happen on subsequent reloads if the FIPS configuration has not changed.
◦ FIPS is supported on Cisco NX-OS release 15.2(1) or later. If you must downgrade the firmware from a release that supports FIPS to a release that does not support FIPS, you must first disable FIPS on the Cisco ACI fabric and reload all of the switches in the fabric.
● You cannot use the breakout feature on a port that has a port profile configured on a Cisco N9K-C93180LC-EX switch. With a port profile on an access port, the port is converted to an uplink, and breakout is not supported on an uplink. With a port profile on a fabric port, the port is converted to a downlink. Breakout is currently supported only on ports 1 through 24.
● On Cisco 93180LC-EX Switches, ports 25 and 27 are the native uplink ports. Using a port profile, if you convert ports 25 and 27 to downlink ports, ports 29, 30, 31, and 32 are still available as four native uplink ports. Because of the threshold on the number of ports (which is maximum of 12 ports) that can be converted, you can convert 8 more downlink ports to uplink ports. For example, ports 1, 3, 5, 7, 9, 13, 15, 17 are converted to uplink ports and ports 29, 30, 31 and 32 are the 4 native uplink ports, which is the maximum uplink port limit on Cisco 93180LC-EX switches.
◦ When the switch is in this state and if the port profile configuration is deleted on ports 25 and 27, ports 25 and 27 are converted back to uplink ports, but there are already 12 uplink ports on the switch in the example. To accommodate ports 25 and 27 as uplink ports, 2 random ports from the port range 1, 3, 5, 7, 9, 13, 15, 17 are denied the uplink conversion; the chosen ports cannot be controlled by the user. Therefore, it is mandatory to clear all the faults before reloading the leaf node to avoid any unexpected behavior regarding the port type. If a node is reloaded without clearing the port profile faults, especially when there is a fault related to limit-exceed, the ports might be in an unexpected mode.
● When using a 25G Mellanox cable that is connected to a Mellanox NIC, you can set the ACI leaf switch port to run at a speed of 25G or 10G.
● You cannot enable auto-negotiation on the spine switch or leaf switch side with 40G or 100G CR4 optics. For 40G copper transceivers, you must disable auto-negotiation and set the speed to 40G. For 100G copper transceivers, you must disable auto-negotiation on the remote end and set the speed to 100G.
● You cannot enable auto-negotiation on an active QSFP to SFP/SFP+ Adapter (QSA) module. You can enable auto-negotiation only on a passive QSA module. The following example CLI command shows an active QSA module:
module-1# show platform internal usd port info | grep -A 10 "Eth1/42"
Port 107.0 (Eth1/42) : Admin UP Link DOWN Cfg_Fec Disabled Fec Disabled Fcot Copper retimer 0x116c0100
AN_cfg Yes AN_operSt No In_debounce 0, Debounce-Time 100000 usecs SM sm qsa: Yes
The following example CLI command shows a passive QSA module:
module-1# show platform internal usd port info | grep -A 10 "Eth1/43"
Port 109.0 (Eth1/43) : Admin UP Link UP Cfg_Fec Disabled Fec Disabled Fcot Copper retimer 0x116c0100
AN_cfg Yes AN_operSt No In_debounce 0, Debounce-Time 100000 usecs SM sm qsa: Passive
● You can enable auto-negotiation for 10G, 25G, 40G, or 100G on downlink ports on a Cisco ACI leaf switch. However, you cannot enable auto-negotiation on spine ports and uplink ports on a Cisco ACI leaf switch. Therefore, if the Inter-Pod Network (IPN) is connected to the spine ports using copper cables, you should disable auto-negotiation on the peer node that is the IPN port. Similarly, if a remote leaf switch is connected to the IPN using copper cables on the uplink port, you should disable auto-negotiation on the peer node that is the IPN port.
● 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.
● When the provider edge router is an IOS XR device, the router does not support route re-origination from one EVPN stitching site to another EVPN stitching site.
Related Content
See the Cisco Application Policy Infrastructure Controller (APIC) page for the documentation.
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