Configuring Priority Flow Control

About Priority Flow Control

Priority flow control (PFC; IEEE 802.1Qbb), which is also referred to as Class-based Flow Control (CBFC) or Per Priority Pause (PPP), is a mechanism that prevents frame loss that is due to congestion. PFC is similar to 802.3x Flow Control (pause frames) or link-level flow control (LFC). However, PFC functions on a per class-of-service (CoS) basis.

When a buffer threshold is exceeded due to congestion, LFC sends a pause frame to its peer to pause all data transmission on the link for a specified period of time. When the congestion is mitigated (traffic comes under the configured threshold), a resume frame is generated to restart data transmission on the link.

In contrast, during congestion, PFC sends a pause frame that indicates which CoS value needs to be paused. A PFC pause frame contains a 2-octet timer value for each CoS that indicates the length of time that the traffic needs to be paused. The unit of time for the timer is specified in pause quanta. A quanta is the time that is required for transmitting 512 bits at the speed of the port. The range is from 0 to 65535. A pause frame with a pause quanta of 0 indicates a resume frame to restart the paused traffic.


Note

Only certain classes of service of traffic can be flow controlled while other classes are allowed to operate normally.

PFC asks the peer to stop sending frames of a particular CoS value by sending a pause frame to a well-known multicast address. This pause frame is a one-hop frame that is not forwarded when received by the peer. When the congestion is mitigated, PFC can request the peer to restart transmitting frames.


Note

RDMA over Converged Ethernet (RoCE) v1 and v2 protocols are supported on Cisco Nexus 9000 Series switches.

Licensing Requirements for Priority Flow Control

The following table shows the licensing requirements for this feature:

Product

License Requirement

Cisco NX-OS

The PFC feature does not a require license. Any feature not included in a license package is bundled with the NX-OS image and is provided at no extra charge to you. For a complete explanation of the Cisco NX-OS licensing scheme, see the Cisco NX-OS Licensing Guide.

Prerequisites for Priority Flow Control

PFC has the following prerequisites:

  • You must be familiar with using modular QoS CLI.

  • You are logged on to the device.

Guidelines and Limitations for Priority Flow Control

PFC has the following configuration guidelines and limitations:

  • PFC is not supported on the Cisco Nexus 9508 switch.

  • The show commands with the internal keyword are not supported.

  • Adding the "pause buffer size threshold" configuration is optional for cable lengths that are less than 100 meters and it does need not to be configured.

  • For cable lengths greater than 100m, the "pause buffer size threshold" configuration is mandatory and it is required as part of the QoS policy configuration.

  • If PFC is enabled on a port or a port channel, it does not cause a port flap.

  • PFC configuration enables PFC in both the send (Tx) and receive (Rx) direction.

  • Configuration time quanta of the pause frames is not supported.

  • You can configure a PFC watchdog interval to detect whether packets in a no-drop queue are being drained within a specified time period. When the time period is exceeded, all outgoing packets are dropped on interfaces that match the PFC queue that is not being drained. This feature is supported only for Cisco Nexus 9200 Series switches, Cisco Nexus 93108TC-EX, and 93180YC-EX switches, and Cisco Nexus 9508 switches with the X9732C-EX line cards.

    This feature is supported on Cisco Nexus 9508 switches with N9K-X9636PQ line cards and Cisco Nexus 3164Q switches.

  • The configuration does not support pausing selected streams that are mapped to a particular traffic-class queue. All flows that are mapped to the class are treated as no-drop. It blocks out scheduling for the entire queue, which pauses traffic for all the streams in the queue. To achieve lossless service for a no-drop class, we recommend that you have only the no-drop class traffic on the queue.

  • When a no-drop class is classified based on 802.1p CoS x and assigned an internal priority value (qos-group) of y, we recommend that you use the internal priority value x to classify traffic on 802.1p CoS only, and not on any other field. The packet priority that is assigned is x if the classification is not based on CoS, which results in packets of internal priority x and y to map to the same priority x.

  • The PFC feature supports up to three no-drop classes of any maximum transmission unit (MTU) size. However, there is a limit on the number of PFC-enabled interfaces, based on the following factors:

    • MTU size of the no-drop class

    • Number of 10G and 40G ports

  • You can define the upper limit of any MTU in the system using the systemjumbomtu command. The MTU range is from 1500 to 9216 bytes, and the default is 9216 bytes.

  • The interface QoS policy takes precedence over the system policy. PFC priority derivation also happens in the same order.

  • Ensure that you apply the same interface-level QoS policy on all PFC-enabled interfaces for both ingress and egress.


    Caution

    Irrespective of the PFC configuration, we recommend that you stop traffic before applying or removing a queuing policy that has strict-priority levels at the interface level or the system level.

  • To achieve end-to-end lossless service over the network, we recommend that you enable PFC on each interface through which the no-drop class traffic flows (Tx/Rx).

  • We recommend that you change the PFC configuration when there is no traffic. Otherwise, packets already in the Memory Management Unit (MMU) of the system may not get the expected treatment.

  • We recommend that you use default buffer sizes for no-drop classes or configure different input queuing policies suitable to 10G and 40G interfaces and the no-drop class MTU size. If the buffer size is specified through the CLI, it allocates the same buffer size for all ports irrespective of the link speed and MTU size. Applying the same pause buffer-size on 10G and 40G interfaces is not supported.

  • Do not enable WRED on a no-drop class because it results in drops in the egress queue.

  • Dynamic load balancing cannot be enabled for internal links with PFC. Disable DLB and enable RTAG7 load-balancing for internal links with the port-channel load-balance internal rtag7 command.

  • The dynamic load balancing (DLB) based hashing scheme is enabled by default on all internal links of a linecard. When DLB is enabled, no-drop traffic may experience an out-of-order packet delivery when congestion on internal links occurs and PFC is applied. If applications on the system are sensitive to out-of-order delivery, you can adjust for this event by disabling DLB at the qos-group level. Disable DLB by using the set dlb-disable action in the QoS policy-maps and the set qos-group action for no-drop classes.

    In the following example, assume that qos-group 1 is a no-drop class. DLB is disabled for this no-drop class by adding the set dlb-disable action and the set qos-group action. 

    switch(config)# policy-map p1
switch(config-pmap-qos)# class c1
switch(config-pmap-c-qos)# set qos-group 1
switch(config-pmap-c-qos)# set dlb-disable
switch(config-pmap-c-qos)# end
switch# show policy-map p1


  Type qos policy-maps
  ====================

  policy-map type qos p1
    class  c1
      set qos-group 1
      set dlb-disable

  • For VLAN-tagged packets, priority is assigned based on the 802.1p field in the VLAN tag and takes precedence over the assigned internal priority (qos-group). DSCP or IP access-list classification cannot be performed on VLAN-tagged frames.

  • For non VLAN-tagged frames, priority is assigned based on the set qos-group action provided by the ingress QoS policy. Classification is based on a QoS policy-allowed match condition such as precedence, DSCP, or access-list. Ensure that the pfc-cos value that is provided in the network-qos policy for this class is the same as the qos-group value in this case.

  • PFC is not supported for the N9K-X9408PC-CFP2 line card on Cisco Nexus 9500 Series switches.

  • Link level flow control and PFC are supported on Cisco Nexus 9300 Series switches and line cards that contain the ALE (Application Leaf Engine).

  • PFC on mode is used to support the hosts that support PFC but do not support the Data Center Bridging Capability Exchange Protocol (DCBXP).

  • Only an exact match of the no-drop CoS is considered as a successful negotiation of PFC by the DCBXP.

  • Beginning with Cisco NX-OS Release 7.0(3)I3(1), DCBXP is supported on the following Cisco Nexus switches:

    • Nexus 9332PQ switch

    • Nexus 9372PX switch

    • Nexus 9372PX-E switch

    • Nexus C9396PX switch

    • Nexus 9500 Series switches with the following line cards:

      • X9432PQ

      • X9464PX

      • X9464TX

      • X9536PQ

      • X9564PX

      • X9564TX

      • X9636PQ

  • DCBXP is supported on Cisco Nexus 9200 and 9300-EX Series switches.

  • The no lldp tlv-select dcbxp command is enhanced so that PFC is disabled for interfaces on both sides of back-to-back switches.

Default Settings for Priority Flow Control

Table 1. Default PFC Setting

Parameter

Default

PFC

Auto

Configuring Priority Flow Control

You can configure PFC on a per-port basis to enable the no-drop behavior for the CoS as defined by the active network QoS policy. PFC can be configured in one of these modes:

  • auto—Enables the no-drop CoS values to be advertised by the DCBXP and negotiated with the peer. A successful negotiation enables PFC on the no-drop CoS. Any failures because of a mismatch in the capability of peers causes the PFC not to be enabled. (7.0(3)I3(1) and later)

  • on—Enables PFC on the local port regardless of the capability of the peers.

  • off—Disables PFC on the local port.


Note

You can use the priority-flow-control override-interface mode off command to globally disable PFC on all interfaces regardless of the current interface configuration. This command, which is meant to be used during troubleshooting, allows you to quickly disable PFC without having to disable PFC on each interface. It is supported beginning with Cisco NX-OS Release 7.0(3)I4(2) and only for Cisco Nexus 9200 Series switches, Cisco Nexus 93108TC-EX and 93180YC-EX switches, and Cisco Nexus 9508 switches with the X9732C-EX line card.

Beginning with Cisco NX-OS Release 7.0(3)I4(5), this feature is supported on Cisco Nexus 9508 switches with N9K-X9636PQ line cards and Cisco Nexus 3164Q switches.

SUMMARY STEPS

  1. configure terminal
  2. interface type slot/port
  3. priority-flow-control mode [ auto | off |on]
  4. show interface priority-flow-control

DETAILED STEPS

  Command or Action Purpose
Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface type slot/port

Example:

switch(config)# interface ethernet 2/5
switch(config-if)#

Enters interface mode on the interface specified.

Step 3

priority-flow-control mode [ auto | off |on]

Example:

switch(config-if)# priority-flow-control mode on
switch(config-if)#

Sets PFC to the on mode.

Step 4

show interface priority-flow-control

Example:

switch# show interface priority-flow-control

(Optional) Displays the status of PFC on all interfaces.

Enabling Priority Flow Control on a Traffic Class

You can enable PFC on a particular traffic class.

SUMMARY STEPS

  1. configure terminal
  2. class-map type qos class-name
  3. match cos cos-value
  4. exit
  5. policy-map type qos policy-name
  6. class type qos class-name
  7. set qos-group qos-group-value
  8. exit
  9. exit
  10. class-map type network-qos match-any class-name
  11. match qos-group qos-group-value
  12. exit
  13. class-map type network-qos class-name
  14. match qos-group qos-group-value
  15. exit
  16. policy-map type network-qos policy-name
  17. class type network-qos class-name
  18. pause pfc-cos value
  19. exit
  20. exit
  21. system qos
  22. service-policy type network-qos policy-name
  23. exit
  24. interface ethernet slot / number
  25. priority-flow-control mode on slot / number
  26. exit

DETAILED STEPS

  Command or Action Purpose
Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

class-map type qos class-name

Example:

switch(config)# class-map type qos c1
switch(config-cmap-qos)#

Creates a named object that represents a class of traffic. Class-map names can contain alphabetic, hyphen, or underscore characters, are case sensitive, and can be up to 40 characters.

Step 3

match cos cos-value

Example:

switch(config-cmap-qos)# match cos 2

Specifies the CoS value to match for classifying packets into this class. You can configure a CoS value in the range of 0 to 7.

Step 4

exit

Example:

switch(config-cmap-qos)# exit
switch(config)#

Exits class-map mode and enters global configuration mode.

Step 5

policy-map type qos policy-name

Example:

switch(config)# policy-map type qos p1
switch(config-pmap-qos)#

Creates a named object that represents a set of policies that are to be applied to a set of traffic classes. Policy-map names can contain alphabetic, hyphen, or underscore characters, are case sensitive, and can be up to 40 characters.

Step 6

class type qos class-name

Example:

switch(config-pmap-qos)# class type qos c1
switch(config-pmap-c-qos)#

Associates a class map with the policy map and enters the configuration mode for the specified system class.

Note 

The associated class map must be the same type as the policy map type.

Step 7

set qos-group qos-group-value

Example:

switch(config-pmap-c-qos)# set qos-group 2

Configures one or more qos-group values to match on for classification of traffic into this class map. There is no default value.

Step 8

exit

Example:

switch(config-pmap-c-qos)# exit
switch(config-pmap-qos)#

Exits the system class configuration mode and enters policy-map mode.

Step 9

exit

Example:

switch(config-pmap-qos)# exit
switch(config)#

Exits policy-map mode and enters global configuration mode.

Step 10

class-map type network-qos match-any class-name

Example:

switch(config)# class-map type network-qos match-any c1
switch(config-cmap-nqos)#

Creates a named object that represents a class of traffic. Class-map names can contain alphabetic, hyphen, or underscore characters, are case sensitive, and can be up to 40 characters.

Step 11

match qos-group qos-group-value

Example:

switch(config-cmap-nqos)# match qos-group 3

Configures the traffic class by matching packets based on a list of QoS group values. Values can range from 0 to 7. QoS group 0 is equivalent to class-default.

Note 

The qos-group-value should match the pause pfc-cos value . See the pause pfc-cos command below in this procedure.

Step 12

exit

Example:

switch(config-cmap-nqos)# exit
switch(config)#

Exits class-map mode and enters global configuration mode.

Step 13

class-map type network-qos class-name

Example:

switch(config)# class-map type network-qos nw-qos3
switch(config-cmap-nqos)#

Creates a named object that represents a class of traffic. Class-map names can contain alphabetic, hyphen, or underscore characters, are case sensitive, and can be up to 40 characters.

Step 14

match qos-group qos-group-value

Example:

switch(config-cmap-nqos)# match qos-group 3

Configures the traffic class by matching packets based on a list of QoS group values. Values can range from 0 to 7. QoS group 0 is equivalent to class-default.

Step 15

exit

Example:

switch(config-cmap-nqos)# exit
switch(config)#

Exits class-map mode and enters global configuration mode.

Step 16

policy-map type network-qos policy-name

Example:

switch(config)# policy-map type network-qos pfc-qos
switch(config-pmap-nqos)#

Creates a named object that represents a set of policies that are to be applied to a set of traffic classes. Policy-map names can contain alphabetic, hyphen, or underscore characters, are case sensitive, and can be up to 40 characters.

Step 17

class type network-qos class-name

Example:

switch(config-pmap-nqos)# class type network-qos nw-qos3
switch(config-pmap-nqos-c)#

Associates a class map with the policy map, and enters the configuration mode for the specified system class.

Note 

The associated class map must be the same type as the policy map type.

Step 18

pause pfc-cos value

Example:

switch(config-pmap-nqos-c)# pause pfc-cos 3
switch(config-pmap-nqos)#

PFC sends a pause frame that indicates which CoS value needs to be paused.

Note 

The pause pfc-cos value should match the qos-group-value in the match qos-group command. See the match qos-group step above in this procedure.

Step 19

exit

Example:

switch(config-pmap-nqos-c)# exit
switch(config-pmap-nqos)#

Exits configuration mode and enters policy-map mode.

Step 20

exit

Example:

switch(config-pmap-nqos)# exit
switch(config)#

Exits policy-map mode and enters global configuration mode.

Step 21

system qos

Example:

switch(config)# system qos
switch(config-sys-qos)#

Enters system class configuration mode.

Step 22

service-policy type network-qos policy-name

Example:

switch(config-sys-qos)# service-policy type network-qos pfc-qos

Applies the policy map of type network-qos at the system level or to the specific interface.

Step 23

exit

Example:

switch(config-sys-qos)# exit
switch(config)#

Exits policy-map mode and enters global configuration mode.

Step 24

interface ethernet slot / number

Example:

switch(config)# interface ethernet 1/1
switch(config-if)#

Enters the ethernet interface configuration mode for the selected slot and chassis number.
Step 25

priority-flow-control mode on slot / number

Example:

switch(config-if)# priority-flow-control mode on
switch(config-if)#

Enables the priority flow control policy for the interface.
Step 26

exit

Example:

switch(config-if)# exit
switch(config)#

Exits the ethernet interface mode and enters the global configuration mode.

Configuring a Priority Flow Control Watchdog Interval

You can configure a PFC watchdog interval to detect whether packets in a no-drop queue are being drained within a specified time period. When the time period is exceeded, all outgoing packets are dropped on interfaces that match the PFC queue that is not being drained. This feature is supported beginning with Cisco NX-OS Release 7.0(3)I4(2) and only for Cisco Nexus 9200 Series switches, Cisco Nexus 93108TC-EX and 93180YC-EX switches, and Cisco Nexus 9508 switches with the X9732C-EX line cards.

Beginning with Cisco NX-OS Release 7.0(3)I4(5), this feature is supported on Cisco Nexus 9508 switches with N9K-X9636PQ line cards and Cisco Nexus 3164Q switches.

Beginning with Cisco NX-OS Release 7.0(3)I6(1), Cisco Nexus 9200, 9300, 9300-EX, and 9500 Series switches, incoming packets are dropped when the queue is shut.


Note

Ingress drops are supported only on the front-panel ports of Cisco Nexus 9200, 9300, 9300-EX , 9500, Series switches. This feature is not supported on HiGig™ interfaces.

SUMMARY STEPS

  1. configure terminal
  2. priority-flow-control auto-restore multiplier value
  3. priority-flow-control fixed-restore multiplier value
  4. priority-flow-control watch-dog-interval {on | off}
  5. priority-flow-control watch-dog interval value
  6. priority-flow-control watch-dog shutdown-multiplier multiplier
  7. (Optional) priority-flow-control watch-dog internal-interface-multiplier value
  8. (Optional) sh queuing pfc-queue [interface] [ethernet|ii] [detail]
  9. (Optional) clear queuing pfc-queue [interface] [ethernet|ii] [intf-name]
  10. (Optional) priority-flow-control recover interface [ethernet|ii] [intf-name] [qos-group <0-7>]

DETAILED STEPS

  Command or Action Purpose
Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

priority-flow-control auto-restore multiplier value

Configures a value for the PFC auto-restore multiplier.
Step 3

priority-flow-control fixed-restore multiplier value

Configures a value for the PFC fixed-restore multiplier.
Step 4

priority-flow-control watch-dog-interval {on | off}

Example:

switch(config)# priority-flow-control watch-dog-interval on

Globally enables or disables the PFC watchdog interval for all interfaces. This command should be configured at global and also at an interface.

See the following example of the command configured at global:

switch(config)# priority-flow-control watch-dog-interval on

See the following example of the command configured at an interface:

switch(config)# interface ethernet 7/5
switch(config-if)# priority-flow-control watch-dog-interval on
Note 

You can use this same command in interface configuration mode to enable or disable the PFC watchdog interval for a specific interface.

Step 5

priority-flow-control watch-dog interval value

Example:

switch(config)# priority-flow-control watch-dog interval 200

Specifies the watchdog interval value. The range is from 100 to 1000 milliseconds.

Step 6

priority-flow-control watch-dog shutdown-multiplier multiplier

Example:

switch(config)# priority-flow-control watch-dog shutdown-multiplier 5

Specifies when to declare the PFC queue as stuck. The range is from 1 to 10, and the default value is 1.

Step 7

(Optional) priority-flow-control watch-dog internal-interface-multiplier value

Example:

switch(config)# priority-flow-control watch-dog internal-interface-multiplier 5
 (Optional)

Configures a PFC watchdog poll-interval multiplier for HiGig™ interfaces. The range is from 0 to 10, and the default value is 2. A value of 0 disables this feature on HiGig™ interfaces.

Step 8

(Optional) sh queuing pfc-queue [interface] [ethernet|ii] [detail]

Example:

switch(config)# sh queuing pfc-queue interface ethernet 1/1 detail
 (Optional)

Displays the PFCWD statistics.

Beginning with Cisco NX-OS Release 7.0(3)I6(1), Cisco Nexus 9200, 9300, 9300-EX, and 9500 series switches, using the detail option, you can account for Ingress drops. 

| QOS GROUP 1 [Active] PFC [YES] PFC-COS [1]                               
+----------------------------------------------------+
|                               |  Stats             |
+----------------------------------------------------+
|                       Shutdown|                   0|
|                       Restored|                   0|
|             Total pkts drained|                   0|
|             Total pkts dropped|                   0|
|   Total pkts drained + dropped|                   0|
|         Aggregate pkts dropped|                   0|
|     Total Ingress pkts dropped|                   0| ===>>>>>Ingress
| Aggregate Ingress pkts dropped|                   0|===>>>>Ingress
+——————————————————————————+
Step 9

(Optional) clear queuing pfc-queue [interface] [ethernet|ii] [intf-name]

Example:

switch(config)# clear queuing pfc-queue interface ethernet 1/1
 (Optional)

Clears the environment variable PFCWD statistics.
Step 10

(Optional) priority-flow-control recover interface [ethernet|ii] [intf-name] [qos-group <0-7>]

Example:

switch# priority-flow-control recover interface ethernet 1/1 qos-group 3
 (Optional)

Recovers the interface manually.

Configuring Pause Buffer Thresholds and Queue Limit Using Ingress Queuing Policy

The pause buffer thresholds specified in the network-qos policy are shared by all the ports in the system. However, there are situations where a few ports may need different thresholds (such as long distance connections). An ingress queuing policy can be used for this purpose.

An ingress queuing policy also allows the configuration of the queue-limit to restrict the amount of shared buffer that can be used in addition to the reserved pause buffer by the no-drop class.

Each no-drop class is mapped internally to one of the port's priority-group in the ingress direction. The configured pause buffer thresholds and queue-limit are applied to the priority-group associated with the class.


Note

Adding pause buffer size threshold configuration is optional for cable lengths that are less than 100 meters and it need not be configured.

For cable lengths that are greater than 100m, the pause buffer size threshold configuration is mandatory and it is required as part of the QoS policy configuration.


Note

About queue limits for 100G enabled devices (such as the Cisco Nexus 9300 Series switch with the N9K-M4PC-CFP2 GEM):

  • The maximum dynamic queue-limit alpha value supported by the device might be greater that 8. However 8 is the maximum alpha value supported. Configuring the alpha value to a value greater than 8 is overridden by the maximum alpha value of 8.

    No message is issued when the alpha value is overridden.

  • The static queue-limit has a maximum of 20,000 cells. Any value specified greater than the maximum 20,000 cell limit is overridden by the 20,000 cell limit.

    No message is issued when the cell limit is overridden.

SUMMARY STEPS

  1. configure terminal
  2. policy-map type queuing policy-map-name
  3. class type queuing c-in-q1
  4. pause buffer-size buffer-size pause threshold xoff-size resume threshold xon-size
  5. no pause buffer-size buffer-size pause threshold xoff-size resume threshold xon-size
  6. queue-limit queue size [dynamic dynamic threshold]

DETAILED STEPS

  Command or Action Purpose
Step 1

configure terminal

Enters global configuration mode.

Step 2

policy-map type queuing policy-map-name

Enters policy-map queuing class mode and identifies the policy map assigned to the type queuing policy map.

Step 3

class type queuing c-in-q1

Attaches the class map of type queuing and then enters policy-map class queuing mode. Class queuing names are listed in the System-Defined Type queuing Class Maps table.

Note 

The qos-group associated with the class must be defined as a no-drop class in the network-qos policy applied in the system qos.

Note 

Up to eight ingress queues are supported for the X9636C-R and X9636Q-R line cards and the C9508-FM-R fabric module (in a Cisco Nexus 9508 switch). The range is from c-in-8q-q-default to c-in-8q-q1 through 7.

Step 4

pause buffer-size buffer-size pause threshold xoff-size resume threshold xon-size

Specifies the buffer threshold settings for pause and resume.

Step 5

no pause buffer-size buffer-size pause threshold xoff-size resume threshold xon-size

Removes the buffer threshold settings for pause and resume.

Step 6

queue-limit queue size [dynamic dynamic threshold]

(Optional) Specifies either the static or dynamic shared limit available to the ingress priority-group. The static queue limit defines the fixed size to which the priority-group can grow. The dynamic queue limit allows the priority-group's threshold size to be decided depending on the number of free cells available, in terms of the alpha value.

Note 

Cisco Nexus 9200 Series switches only support a class level dynamic threshold configuration with respect to the alpha value. This means that all ports in a class share the same alpha value.

Note 

The queue limit for the X9636C-R and X9636Q-R line cards and the C9508-FM-R fabric module (in a Cisco Nexus 9508 switch) can be entered as a percent or in bytes/kbytes/mbytes/gbytes. For example, queue-limit percent 1 or queue-limit bytes 100.

Verifying the Priority Flow Control Configuration

To display the PFC configuration, perform the following task:

Command

Purpose

show interface priority-flow-control [module number]

Displays the status of PFC on all interfaces or on specific modules.

Configuration Examples for Priority Flow Control

The following example shows how to configure PFC: 

configure terminal
interface ethernet 5/5
priority-flow-control mode on

The following example shows how to enable PFC on a traffic class: 

switch(config)# class-map type qos c1
switch(config-cmap-qos)# match cos 3
switch(config-cmap-qos)# exit
switch(config)# policy-map type qos p1
switch(config-pmap-qos)# class type qos c1
switch(config-pmap-c-qos)# set qos-group 3
switch(config-pmap-c-qos)# exit
switch(config-pmap-qos)# exit
switch(config)# class-map type network-qos match-any c1
switch(config-cmap-nqos)# match qos-group 3
switch(config-cmap-nqos)# exit
switch(config)# policy-map type network-qos p1
switch(config-pmap-nqos)# class type network-qos c-nq1
switch(config-pmap-nqos-c)# pause pfc-cos 3
switch(config-pmap-nqos-c)# exit
switch(config-pmap-nqos)# exit
switch(config)# system qos
switch(config-sys-qos)# service-policy type network-qos p1