Configuring Modular QoS Service Packet Classification

Packet classification identifies and marks traffic flows that require congestion management or congestion avoidance on a data path. The Modular Quality of Service (QoS) command-line interface (MQC) is used to define the traffic flows that should be classified, where each traffic flow is called a class of service, or class. Subsequently, a traffic policy is created and applied to a class. All traffic not identified by defined classes falls into the category of a default class.

This module provides the conceptual and configuration information for QoS packet classification.

Line Card, SIP, and SPA Support

Feature

ASR 9000 Ethernet Line Cards

SIP 700 for the ASR 9000

Classification Based on DEI

yes

no

Class-Based Unconditional Packet Marking

yes

yes

In-Place Policy Modification

yes

yes

IPv6 QoS

yes

yes

Packet Classification and Marking

yes

yes

Policy Inheritance

yes

yes

Port Shape Policies

yes

no

Shared Policy Instance

yes

no

Feature History for Configuring Modular QoS Packet Classification and Marking on Cisco ASR 9000 Series Routers

Release

Modification

Release 3.7.2

The Class-Based Unconditional Packet Marking feature was introduced on ASR 9000 Ethernet Line Cards.

The IPv6 QoS feature was introduced on ASR 9000 Ethernet Line Cards. (QoS matching on IPv6 ACLs is not supported.)

The Packet Classification and Marking feature was introduced on ASR 9000 Ethernet Line Cards.

Release 3.9.0

The Class-Based Unconditional Packet Marking feature was supported on the SIP 700 for the ASR 9000.

The Packet Classification and Marking feature was supported on the SIP 700 for the ASR 9000.

The Policy Inheritance feature was introduced on ASR 9000 Ethernet Line Cards and on the SIP 700 for the ASR 9000.

The Shared Policy Instance feature was introduced on ASR 9000 Ethernet Line Cards.

Release 4.0.0

The Classification Based on DEI feature was introduced on ASR 9000 Ethernet Line Cards.

The In-Place Policy Modification feature was introduced on ASR 9000 Ethernet Line Cards and on the SIP 700 for the ASR 9000.

The IPv6 QoS feature was supported on the SIP 700 for the ASR 9000.

Support for three stand-alone marking actions and three marking actions as part of a policer action in the same class was added on the SIP 700 for the ASR 9000. (ASR 9000 Ethernet Line Cards support two stand-alone marking actions and two marking actions as part of a policer action in the same class.)

Release 4.0.1

Support for the port shape policies feature was introduced on ASR 9000 Ethernet Line Cards.

Release 4.2.1 QoS on satellite feature was added.
Release 5.1.1

The QoS Offload on satellite feature was added.

The Inter Class Policer Bucket Sharing feature was added. This feature is applicable to all ASR 9000 Enhanced Ethernet line cards except the first generation and SIP 700 line cards.

Release 5.1.2

The QoS Offload on 901 feature was added.

Port Shaper Policy Support on L2 Fabric ICL Interface

Release 5.2.0

The QPPB on GRE Tunnel Interfaces feature was added.

Release 6.0

Classification Support for Ethernet-Services ACL was added.

Release 6.1.2

New Chapter, "Configuring QoS on the Satellite System" was created that contains information about QoS Offload.

Release 6.2.1

Support for Multiple QoS Policy feature was added.

Prerequisites for Configuring Modular QoS Packet Classification

These prerequisites are required for configuring modular QoS packet classification and marking on your network:

  • You must be in a user group associated with a task group that includes the proper task IDs. The command reference guides include the task IDs required for each command. If you suspect user group assignment is preventing you from using a command, contact your AAA administrator for assistance.

  • You must be familiar with Cisco IOS XR QoS configuration tasks and concepts.

Information About Configuring Modular QoS Packet Classification

Packet Classification Overview

Packet classification involves categorizing a packet within a specific group (or class) and assigning it a traffic descriptor to make it accessible for QoS handling on the network. The traffic descriptor contains information about the forwarding treatment (quality of service) that the packet should receive. Using packet classification, you can partition network traffic into multiple priority levels or classes of service. The source agrees to adhere to the contracted terms and the network promises a quality of service. Traffic policers and traffic shapers use the traffic descriptor of a packet to ensure adherence to the contract.

Traffic policers and traffic shapers rely on packet classification features, such as IP precedence, to select packets (or traffic flows) traversing a router or interface for different types of QoS service. For example, by using the three precedence bits in the type of service (ToS) field of the IP packet header, you can categorize packets into a limited set of up to eight traffic classes. After you classify packets, you can use other QoS features to assign the appropriate traffic handling policies including congestion management, bandwidth allocation, and delay bounds for each traffic class.


Note


IPv6-based classification is supported only on Layer 3 interfaces.


Traffic Class Elements

The purpose of a traffic class is to classify traffic on your router. Use the class-map command to define a traffic class.

A traffic class contains three major elements: a name, a series of match commands, and, if more than one match command exists in the traffic class, an instruction on how to evaluate these match commands. The traffic class is named in the class-map command. For example, if you use the word cisco with the class-map command, the traffic class would be named cisco.

The match commands are used to specify various criteria for classifying packets. Packets are checked to determine whether they match the criteria specified in the match commands. If a packet matches the specified criteria, that packet is considered a member of the class and is forwarded according to the QoS specifications set in the traffic policy. Packets that fail to meet any of the matching criteria are classified as members of the default traffic class. See the “Default Traffic Class” section on page 18.

The instruction on how to evaluate these match commands needs to be specified if more than one match criterion exists in the traffic class. The evaluation instruction is specified with the class-map [match-any] command. If the match-any option is specified as the evaluation instruction, the traffic being evaluated by the traffic class must match at least one of the specified criteria.

The function of these commands is described more thoroughly in the Cisco ASR 9000 Series Aggregation Services Routers Modular Quality of Service Command Reference. The traffic class configuration task is described in the “Creating a Traffic Class” section on page 32.


Note


Users can provide multiple values for a match type in a single line of configuration; that is, if the first value does not meet the match criteria, then the next value indicated in the match statement is considered for classification.


Traffic Policy Elements

The purpose of a traffic policy is to configure the QoS features that should be associated with the traffic that has been classified in a user-specified traffic class or classes. The policy-map command is used to create a traffic policy. A traffic policy contains three elements: a name, a traffic class (specified with the class command), and the QoS policies. The name of a traffic policy is specified in the policy map Modular Quality of Service (MQC) (for example, the policy-map policy1 command creates a traffic policy named policy1 ). The traffic class that is used to classify traffic to the specified traffic policy is defined in class map configuration mode. After choosing the traffic class that is used to classify traffic to the traffic policy, the user can enter the QoS features to apply to the classified traffic.

The MQC does not necessarily require that users associate only one traffic class to one traffic policy. When packets match to more than one match criterion, as many as 1024 traffic classes can be associated to a single traffic policy. The 1024 class maps include the default class and the classes of the child policies, if any.

The order in which classes are configured in a policy map is important. The match rules of the classes are programmed into the TCAM in the order in which the classes are specified in a policy map. Therefore, if a packet can possibly match multiple classes, only the first matching class is returned and the corresponding policy is applied.

The function of these commands is described more thoroughly in the Cisco ASR 9000 Series Aggregation Services Router Modular Quality of Service Command Reference.

The traffic policy configuration task is described in “Creating a Traffic Policy” section on page 38.

Limitation

Fragmented IPv4 packets are subjected to egress QoS policies only on the main interface and not on sub-interfaces. The fragmented IPv4 packets are subjected to the Local Packet Transport Services (LPTS) policer. IPv4 packets are fragmented when the egress interface MTU is smaller than the packet size.

Default Traffic Class

Unclassified traffic (traffic that does not meet the match criteria specified in the traffic classes) is treated as belonging to the default traffic class.

If the user does not configure a default class, packets are still treated as members of the default class. However, by default, the default class has no enabled features. Therefore, packets belonging to a default class with no configured features have no QoS functionality. These packets are then placed into a first in, first out (FIFO) queue and forwarded at a rate determined by the available underlying link bandwidth. This FIFO queue is managed by a congestion avoidance technique called tail drop.

For further information about congestion avoidance techniques, such as tail drop, see the “Configuring Modular QoS Congestion Avoidance on Cisco ASR 9000 Series Routers” module in this guide

Bundle Traffic Policies

When a policy is bound to a bundle, the same policy is programmed on every bundle member (port). For example, if there is a policer or shaper rate, the same rate is configured on every port. Traffic is scheduled to bundle members based on the load balancing algorithm.

A policy can be bound to:

  • Bundles

  • Bundle Layer 3 subinterfaces

  • Bundle Layer 2 subinterfaces (Layer 2 transport)

Both ingress and egress traffic is supported. Percentage-based policies and absolute rate-based policies are supported. However, for ease of use, it is recommended to use percentage-based policies.

Shared Policy Instance

After the traffic class and traffic policy have been created, Shared Policy Instance (SPI) can optionally be used to allow allocation of a single set of QoS resources and share them across a group of subinterfaces, multiple Ethernet flow points (EFPs), or bundle interfaces.

Using SPI, a single instance of qos policy can be shared across multiple subinterfaces, allowing for aggregate shaping of the subinterfaces to one rate. All of the subinterfaces that share the instance of a QoS policy must belong to the same physical interface. The number of subinterfaces sharing the QoS policy instance can range from 2 to the maximum number of subinterfaces on the port.

For bundle interfaces, hardware resources are replicated per bundle member. All subinterfaces that use a common shared policy instance and are configured on a Link Aggregation Control Protocol (LAG) bundle must be load-balanced to the same member link.

When a policy is configured on a bundle EFP, one instance of the policy is configured on each of the bundle member links. When using SPI across multiple bundle EFPs of the same bundle, one shared instance of the policy is configured on each of the bundle member links. By default, the bundle load balancing algorithm uses hashing to distribute the traffic (that needs to be sent out of the bundle EFPs) among its bundle members. The traffic for single or multiple EFPs can get distributed among multiple bundle members. If multiple EFPs have traffic that needs to be shaped or policed together usingSPI, the bundle load balancing has to be configured to select the same bundle member (hash-select) for traffic to all the EFPs that belong the same shared instance of the policy. This ensures that traffic going out on all the EFPs with same shared instance of the policy use the same policer/shaper Instance.

This is normally used when the same subscriber has many EFPs, for example, one EFP for each service type, and the provider requires shaping and queuing to be implemented together for all the subscriber EFPs.

Policy Inheritance

When a policy map is applied on a physical port, the policy is enforced for all Layer 2 and Layer 3 subinterfaces under that physical port.

Port Shape Policies

When a port shaping policy is applied to a main interface, individual regular service policies can also be applied on its subinterfaces. Port shaping policy maps have these restrictions:

  • class-default is the only allowed class map.

  • The shape class action is the only allowed class action.

  • They can only be configured in the egress direction.

  • They can only be applied to main interfaces, not to subinterfaces.

  • Two- and three- level policies are not supported. Only one level or flat policies are supported.

If any of the above restrictions are violated, the configured policy map is applied as a regular policy, not a port shaping policy.

Support for 16 Queues

The ASR 9000 traffic manager (TM) for the enhanced Ethernet line cards now supports up to 16 Queues. The extension is from 8 queues to 16 queues at leaf level called L4 in a QoS policy.

The capabilities of each mode are:

  • 8 Q-mode—8 L4 flows per L3 class. Up to 32000 L3 classes in TM.

  • 16 Q-mode—16 L4 flows per L3 class. Up to 16000 L3 classes in TM.

This table provides the different service profiles supported in different modes:

Mode Service Profile
8Q 1 priority-1 queue, 1 priority-2 queue, 6 normal priority queue
16Q 1 priority-1 queue, 1 priority-2 queue, 14 normal priority queue
8Q 1 priority-1 queue, 2 priority-2 queues, 5 normal priority queue (BNG Only)
16Q 1 priority-1 queue, 2 priority-2 queues, 13 normal priority queue (BNG Only)
8Q 1 priority-1 queue, 1 priority-2 queue, 1 priority- 3 queue, 5 normal priority queue
16Q 1 priority-1 queue, 1 priority-2 queue, 1 priority- 3 queue, 13 normal priority queue

The L3, L4 service profiles in 16 Q-mode are similar to that of the 8 Q-mode, with just an increase in the number of normal priority queues.

Restrictions

The support for 16 queues has these restrictions:

  • Supports only the enhanced Ethernet line cards.

  • When 16Q-mode policy is applied on all interfaces, the number of interface scale will be 4K interface.

Class-based Unconditional Packet Marking Feature and Benefits

The Class-based, Unconditional Packet Marking feature provides users with a means for efficient packet marking by which the users can differentiate packets based on the designated markings.

The Class-based, Unconditional Packet Marking feature allows users to perform these tasks:

  • Mark packets by setting the IP precedence bits or the IP differentiated services code point (DSCP) in the IP ToS byte.

  • Mark Multiprotocol Label Switching (MPLS) packets by setting the EXP bits within the imposed or topmost label.

  • Mark packets by setting the Layer 2 class-of-service (CoS) value.

  • Mark packets by setting inner and outer CoS tags for an IEEE 802.1Q tunneling (QinQ) configuration.

  • Mark packets by setting the value of the qos-group argument.

  • Mark packets by setting the value of the discard-class argument.


    Note


    qos-group and discard-class are variables internal to the router, and are not transmitted.



Note


When the router receives multicast traffic from a Multicast Label Distribution Protocol (MLDP) solution, the MPLS label from the received packet is not dispositioned at the ingress line-card. Instead, the label is removed at the egress line-card. As a result, you cannot mark the IP header for incoming multicast traffic in an MLDP scenario. This means that such packets will not be marked with a Differentiated Services Code Point (DSCP) or precedence value. This is expected behavior for the line cards listed below and is applicable for unconditional marking and for packet marking as policer action (also known as conditional marking):
  • ASR 9000 Ethernet Line Cards

  • Cisco ASR 9000 High Density 100GE Ethernet line cards

  • Cisco ASR 9000 fourth Generation family of QSFP-based dense 100GE line cards.


Unconditional packet marking allows you to partition your network into multiple priority levels or classes of service, as follows:

  • Use QoS unconditional packet marking to set the IP precedence or IP DSCP values for packets entering the network. Routers within your network can then use the newly marked IP precedence values to determine how the traffic should be treated.

    For example, weighted random early detection (WRED), a congestion avoidance technique, can be used to determine the probability that a packet is dropped. In addition, low-latency queuing (LLQ) can then be configured to put all packets of that mark into the priority queue.

  • Use QoS unconditional packet marking to assign packets to a QoS group. To set the QoS group identifier on MPLS packets, use the set qos-group command in policy map class configuration mode.


    Note


    Setting the QoS group identifier does not automatically prioritize the packets for transmission. You must first configure an egress policy that uses the QoS group.


  • Use CoS unconditional packet marking to assign packets to set the priority value of IEEE 802.1p/Inter-Switch Link (ISL) packets. The router uses the CoS value to determine how to prioritize packets for transmission and can use this marking to perform Layer 2-to-Layer 3 mapping. To set the Layer 2 CoS value of an outgoing packet, use the set cos command in policy map configuration mode.

The configuration task is described in the Configuring Class-based Unconditional Packet Marking, page 46.


Note


Unless otherwise indicated, the class-based unconditional packet marking for Layer 3 physical interfaces applies to bundle interfaces.


Specification of the CoS for a Packet with IP Precedence

Use of IP precedence allows you to specify the CoS for a packet. You use the three precedence bits in the ToS field of the IP version 4 (IPv4) header for this purpose. This figure shows the ToS field.

Figure 1. IPv4 Packet Type of Service Field

Using the ToS bits, you can define up to eight classes of service. Other features configured throughout the network can then use these bits to determine how to treat the packet in regard to the ToS to grant it. These other QoS features can assign appropriate traffic-handling policies, including congestion management strategy and bandwidth allocation. For example, queuing features such as LLQ can use the IP precedence setting of the packet to prioritize traffic.

By setting precedence levels on incoming traffic and using them in combination with the Cisco IOS XR QoS queuing features, you can create differentiated service.

So that each subsequent network element can provide service based on the determined policy, IP precedence is usually deployed as close to the edge of the network or administrative domain as possible. This allows the rest of the core or backbone to implement QoS based on precedence.

The configuration task is described in the “Configuring Class-based Unconditional Packet Marking” section on page 46.

IP Precedence Bits Used to Classify Packets

Use the three IP precedence bits in the ToS field of the IP header to specify the CoS assignment for each packet. As mentioned earlier, you can partition traffic into a maximum of eight classes and then use policy maps to define network policies in terms of congestion handling and bandwidth allocation for each class.

For historical reasons, each precedence corresponds to a name. These names are defined in RFC 791. This table lists the numbers and their corresponding names, from least to most important.

Table 1. IP Precedence Values

Number

Name

0

routine

1

priority

2

immediate

3

flash

4

flash-override

5

critical

6

internet

7

network


Note


IP precedence bit settings 6 and 7 are reserved for network control information, such as routing updates.


IP Precedence Value Settings

By default, Cisco IOS XR software leaves the IP precedence value untouched. This preserves the precedence value set in the header and allows all internal network devices to provide service based on the IP precedence setting. This policy follows the standard approach stipulating that network traffic should be sorted into various types of service at the edge of the network and that those types of service should be implemented in the core of the network. Routers in the core of the network can then use the precedence bits to determine the order of transmission, the likelihood of packet drop, and so on.

Because traffic coming into your network can have the precedence set by outside devices, we recommend that you reset the precedence for all traffic entering your network. By controlling IP precedence settings, you prohibit users that have already set the IP precedence from acquiring better service for their traffic simply by setting a high precedence for all of their packets.

The class-based unconditional packet marking, LLQ, and WRED features can use the IP precedence bits.

Classification Based on DEI

You can classify traffic based on the Drop Eligible Indicator (DEI ) bit that is present in 802.1ad frames and in 802.1ah frames. Default DEI marking is supported. The set DEI action in policy maps is supported on 802.1ad packets for:

  • Ingress and egress

  • Layer 2 subinterfaces

  • Layer 2 main interfaces

  • Layer 3 main interfaces


    Note


    The set DEI action is ignored for traffic on interfaces that are not configured for 802.1ad encapsulation.


Default DEI Marking

Incoming Packet

Default DEI on Imposed 802.1ad Headers

802.1q packet

None

0

802.1ad packet

None

DEI of top-most tag of the incoming packet

802.1q packet translated to 802.1ad packet

or

802.1ad packet

set dei {0 | 1}

0 or 1


Based on DEI value in the set action

TCP Establishment DSCP Marking/ Set IP Precedence/DSCP for NTP

The Differentiated Services Code Point (DSCP) field in an IP packet which helps enables different levels of service to be assigned to network traffic. Marking is a process, which helps to modify QOS fields incoming and outgoing packets. You can use marking commands in traffic classes, which are referenced in the policy map. You can configure the following marking features:
  • DSCP

  • IP Precedence

  • CoS

Each IP packet is marked with a DSCP code and assigned to corresponding level of service. DSCP is a combination of IP Precedence and Type of Service fields. The TCP Establishment DSCP Marking/Set IP Precedence feature sets Network Time Protocol (NTP) with the DSCP field. NTP packets can be based on either IPv4 and IPV6 based respectively. The NTP sets DSCP/TOS field under either v4 or v6 IP headers. The DSCP level can be configured through the NTP configuration. The configured level will be set across NTP packets throughout IP layer.

IP Precedence Compared to IP DSCP Marking

If you need to mark packets in your network and all your devices support IP DSCP marking, use the IP DSCP marking to mark your packets because the IP DSCP markings provide more unconditional packet marking options. If marking by IP DSCP is undesirable, however, or if you are unsure if the devices in your network support IP DSCP values, use the IP precedence value to mark your packets. The IP precedence value is likely to be supported by all devices in the network.

You can set up to 8 different IP precedence markings and 64 different IP DSCP markings.

Configuring DSCP for source IPv4 address for NTP Packets

To mark a packet by setting the IP DSCP value for NTP packets, use the following commands (given below) starting in global configuration mode. These commands permit configuring the DSCP for source addresses, to mark NTP packets, so that the marked NTP packets are treated as per the DSCP markings. There are different code point values available for different services:

SUMMARY STEPS

  1. configure
  2. ntp { ipv4} dscp
  3. end or commit
  4. show processes ntpd
  5. show ntp associations

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:

 

RP/0/0/CPU0:Router#configure
Mon Aug 10 14:35:04.826 IST
RP/0/0/CPU0:Router(config)#

Enters the global configuration mode.

Step 2

ntp { ipv4} dscp

Example:



RP/0/0/CPU0:Router(config)#ntp ipv4 dscp ?
  <0-63>   Differentiated services codepoint value
  af11     Match packets with AF11 dscp (001010)
  af12     Match packets with AF12 dscp (001100)
  af13     Match packets with AF13 dscp (001110)
  af21     Match packets with AF21 dscp (010010)
  af22     Match packets with AF22 dscp (010100)
  af23     Match packets with AF23 dscp (010110)
  af31     Match packets with AF31 dscp (011010)
  af32     Match packets with AF32 dscp (011100)
  af33     Match packets with AF33 dscp (011110)
  af41     Match packets with AF41 dscp (100010)
  af42     Match packets with AF42 dscp (100100)
  af43     Match packets with AF43 dscp (100110)
  cs1      Match packets with CS1(precedence 1) dscp (001000)
  cs2      Match packets with CS2(precedence 2) dscp (010000)
  cs3      Match packets with CS3(precedence 3) dscp (011000)
  cs4      Match packets with CS4(precedence 4) dscp (100000)
  cs5      Match packets with CS5(precedence 5) dscp (101000)
  cs6      Match packets with CS6(precedence 6) dscp (110000)
  cs7      Match packets with CS7(precedence 7) dscp (111000)
  default  Match packets with default dscp (000000)
  ef       Match packets with EF dscp (101110)

Specifies Differentiated services code point (dscp) value. The range is from 0 to 63. The default value is 0.

Step 3

end or commit

Example:

RP/0/RP0/CPU0:Router(config)#commit

Example:


RP/0/0/CPU0:Router#exit
(

Commit- saves the configuration changes and remains within the configuration session.

End- prompts the user to take one of these actions:
  • Yes- Saves configuration changes and exits the configuration session.

  • No-Exits the configuration session without committing the configuration changes.

  • Cancel-Remains in the configuration session, without committing the configuration changes.

Step 4

show processes ntpd

Example:



RP/0/RP0/CPU0:Router#show processes ntpd
Mon Jun 22 20:25:18.026 IST
                  Job Id: 208
                     PID: 2540
         Executable path: /pkg/bin/ntpd
              Instance #: 1
              Version ID: 00.00.0000
                 Respawn: ON
           Respawn count: 1
            Last started: Fri Jun 19 16:04:14 2015
           Process state: Run
           Package state: Normal
           Process group: dlrsc
                    core: MAINMEM 
               Max. core: 0
                   Level: 120
               Placement: None
            startup_path: /pkg/startup/ip_ntp.startup
                   Ready: 2.444s
        Process cpu time: 0.074s user, 0.031s kernel, 1.005s total
  PID   TID CPU Stack Pri State           Run Time  CPU use NAME
 2540  2978   1   92K  15 Sleeping     3:04:20:59s   0.000s ntpd
 2540  2975   4   92K  15 Sleeping     3:04:20:59s   0.001s ntpd
 2540  2947   5   92K  15 Sleeping     x3:04:20:59s   0.027s chkpt_evm
 2540  2943   1   92K  15 Sleeping     3:04:21:00s   0.000s ITAL Server Thr
 2540  2914   5   92K  15 Sleeping     3:04:21:00s   0.000s async
 2540  2810   3   92K  15 Sleeping     3:04:21:00s   0.000s EnXR internal:mmap_peer_threa
 2540  2760   2   92K  15 Sleeping     3:04:21:00s   0.011s ntpd
 2540  2540   1   92K  15 Sleeping     3:04:21:03s   0.064s ntpd

   

Displays the ntpd process

Step 5

show ntp associations

Example:



Router# show ntp associations
Sat Feb 14 13:53:18.468 UTC

      address         ref clock     st  when  poll reach  delay  offset    disp
*~223.255.254.254  171.68.38.65      2   121   128  377    2.44  -0.260   4.537
 * sys_peer, # selected, + candidate, - outlayer, x falseticker, ~ configured
   

Shows the status of NTP associations.

Configure DSCP CS7 (Precedence 7)

Before you begin

The IP DSCP value in the class map command using the following commands, starting with the global configuration mode.

SUMMARY STEPS

  1. configure
  2. ntp ipv4 dscp cs7
  3. end or commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:



RP/0/0/CPU0:Router#configure
Mon Aug 10 14:35:04.826 IST
RP/0/0/CPU0:Router(config)#

Enters the global configuration mode.

Step 2

ntp ipv4 dscp cs7

Configures options in DSCP for a particular source address in IPv4 packets.

Step 3

end or commit

Example:

RP/0/RP0/CPU0:Router(config)#commit
Commit Command saves the configuration changes and remains within the configuration session. End Command prompts the user to take one of these actions:
  • Yes- Saves configuration changes and exits the configuration session.

  • No-Exits the configuration session without committing the configuration changes.

  • Cancel-Remains in the configuration session, without committing the configuration changes.

Configure IPv4 DSCP Precedence

Before you begin

The following steps help you to configure DSCP precedence:

SUMMARY STEPS

  1. configure
  2. ntp { ipv4 } precedence codepoint_value
  3. ntp { ipv4} precedence
  4. end or commit
  5. show ntp status

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:

 

RP/0/0/CPU0:Router#configure
Mon Aug 10 14:35:04.826 IST
RP/0/0/CPU0:Router(config)#

Enters the global configuration mode.

Step 2

ntp { ipv4 } precedence codepoint_value

Example:



  RP/0/0/CPU0:Router(config)#ntp ipv4 precedence ?
  <0-7>           Precedence value
  critical        Match packets with critical precedence (5)
  flash           Match packets with flash precedence (3)
  flash-override  Match packets with flash override precedence (4)
  immediate       Match packets with immediate precedence (2)
  internet        Match packets with internetwork control precedence (6)
  network         Match packets with network control precedence (7)
  priority        Match packets with priority precedence (1)
  routine         Match packets with routine precedence (0)
 

Sets the ntp [IPv4] precedence. It ranges from 0 to 63.

Step 3

ntp { ipv4} precedence

Example:



   RP/0/RP0/CPU0:Router(config)#ntp ipv4 precedence internet

 

Sets precedence values.

Step 4

end or commit

Example:

RP/0/RP0/CPU0:Router(config)#commit

Example:


RP/0/0/CPU0:Router#exit
(

Commit- saves the configuration changes and remains within the configuration session.

End- prompts the user to take one of these actions:
  • Yes- Saves configuration changes and exits the configuration session.

  • No-Exits the configuration session without committing the configuration changes.

  • Cancel-Remains in the configuration session, without committing the configuration changes.

Step 5

show ntp status

Example:



RP/0/RP0/CPU0:Router#show ntp status
Mon Aug 10 14:35:04.826 IST

Clock is synchronized, stratum 3, reference is 223.255.254.254
nominal freq is 1000000000.0000 Hz, actual freq is 30440042.8893 Hz, precision is 2**22
reference time is D889D255.BF525356 (13:55:33.747 UTC Sat Feb 14 2015)
clock offset is -0.413 msec, root delay is 3.569 msec
root dispersion is 20.55 msec, peer dispersion is 4.04 msec
loopfilter state is 'CTRL' (Normal Controlled Loop), drift is 0.0000318515 s/s
system poll interval is 128, last update was 117 sec ago

Displays NTP status.

Configure IPv6 DSCP precedence

Before you begin

You can configure DSCP precedence:

SUMMARY STEPS

  1. configure
  2. ntp , source { ipv6 } dscp codepoint_value
  3. ntp { ipv6 } precedence codepoint_value
  4. end or commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:

 

RP/0/RP0/CPU0:Router(config)#

Enters the global configuration mode.

Step 2

ntp , source { ipv6 } dscp codepoint_value

Example:




RP/0/0/CPU0:Router(config)#ntp ipv6 dscp ?
  <0-63>   Differentiated services codepoint value
  af11     Match packets with AF11 dscp (001010)
  af12     Match packets with AF12 dscp (001100)
  af13     Match packets with AF13 dscp (001110)
  af21     Match packets with AF21 dscp (010010)
  af22     Match packets with AF22 dscp (010100)
  af23     Match packets with AF23 dscp (010110)
  af31     Match packets with AF31 dscp (011010)
  af32     Match packets with AF32 dscp (011100)
  af33     Match packets with AF33 dscp (011110)
  af41     Match packets with AF41 dscp (100010)
  af42     Match packets with AF42 dscp (100100)
  af43     Match packets with AF43 dscp (100110)
  cs1      Match packets with CS1(precedence 1) dscp (001000)
  cs2      Match packets with CS2(precedence 2) dscp (010000)
  cs3      Match packets with CS3(precedence 3) dscp (011000)
  cs4      Match packets with CS4(precedence 4) dscp (100000)
  cs5      Match packets with CS5(precedence 5) dscp (101000)
  cs6      Match packets with CS6(precedence 6) dscp (110000)
  cs7      Match packets with CS7(precedence 7) dscp (111000)
  default  Match packets with default dscp (000000)
  ef       Match packets with EF dscp (101110)


 

Configures options in DSCP for a particular source address in IPV6 packets. The value ranges between 0 - 63.

Step 3

ntp { ipv6 } precedence codepoint_value

Example:





  RP/0/0/CPU0:Router(config)#ntp ipv6 precedence ?
  <0-7>           Precedence value
  critical        Match packets with critical precedence (5)
  flash           Match packets with flash precedence (3)
  flash-override  Match packets with flash override precedence (4)
  immediate       Match packets with immediate precedence (2)
  internet        Match packets with internetwork control precedence (6)
  network         Match packets with network control precedence (7)
  priority        Match packets with priority precedence (1)
  routine         Match packets with routine precedence (0)

 

Sets ntp ipv6 precedence

Step 4

end or commit

Example:

RP/0/RP0/CPU0:Router(config)#commit

Example:


RP/0/0/CPU0:ios#exit
(

Commit- saves the configuration changes and remains within the configuration session.

End- prompts the user to take one of these actions:
  • Yes- Saves configuration changes and exits the configuration session.

  • No-Exits the configuration session without committing the configuration changes.

  • Cancel-Remains in the configuration session, without committing the configuration changes.

QoS Policy Propagation Using Border Gateway Protocol

Packet classification identifies and marks traffic flows that require congestion management or congestion avoidance on a data path. Quality-of-service Policy Propagation Using Border Gateway Protocol (QPPB) allows you to classify packets by Qos Group ID, based on access lists (ACLs), Border Gateway Protocol (BGP) community lists, BGP autonomous system (AS) paths, Source Prefix address, or Destination Prefix address. After a packet has been classified, you can use other QoS features such as policing and weighted random early detection (WRED) to specify and enforce policies to fit your business model.

QoS Policy Propagation Using BGP (QPPB) allows you to map BGP prefixes and attributes to Cisco Express Forwarding (CEF) parameters that can be used to enforce traffic policing. QPPB allows BGP policy set in one location of the network to be propagated using BGP to other parts of the network, where appropriate QoS policies can be created.

QPPB supports both the IPv4 and IPv6 address-families.

QPPB allows you to classify packets based on:

  • Access lists.

  • BGP community lists. You can use community lists to create groups of communities to use in a match clause of a route policy. As with access lists, you can create a series of community lists.

  • BGP autonomous system paths. You can filter routing updates by specifying an access list on both incoming and outbound updates, based on the BGP autonomous system path.

  • Source Prefix address. You can classify a set of prefixes coming from the address of a BGP neighbor(s).

  • Destination Prefix address. You can classify a set of BGP prefixes.

Classification can be based on the source or destination address of the traffic. BGP and CEF must be enabled for the QPPB feature to be supported.

QoS on PWHE

QoS on Pseudo-wire Head End (PWHE) enables enhanced L3VPN and L2VPN service on a service-provider-edge router. The available PWHE types are PW-Ether main interfaces, PW-Ether subinterfaces, and PW interworking (IW) interfaces.


Note


The PWHE-Ether subinterfaces and PW-IW interfaces are supported from Release 5.1.1 onwards.


Supported Features

Features of QoS on PWHE:

  • IPv4 and IPv6 address-families are supported.

  • Policy maps on both ingress and egress PWHE. Both ingress and egress support policing, marking, and queuing within hardware limitations.

  • Policies at the port for the transit traffic can be applied simultaneously with policies for PWHE interfaces.

  • Policy is replicated on all PWHE members. This means the rate specified in the PWHE policy-map is limited to the lowest rate of all the pin down members. For example, if the PWHE interface has both 1G and 10G pin down members, the rate is limited to 1G. if the 10G member has a shaper of 900 mbps, the rate of the PWHE interface policy is limited to 900 mbps.
  • Port shaping policy on the member interface will impact the PWHE traffic passing through that port.

  • Policy maps can be applied on PW-Ether subinterface.

  • PW-Ether subinterfaces inherit policy on its main PW-Ether interface.

  • PW-Ether subinterface can have policy configured as shared policy instance (SPI).

  • PW-Ether main and subinterface policies may co-exist.

  • L2 multicast and flood over PW-Ether interface are supported.

  • L3 multicast over PW-Ether interface are supported.

  • Independent of line card co-existence mode, percentage based rate at the lowest policy level in PW-Ether main and subinterface policies is supported.

    Note


    In the same policy, the grand parent level is lower than parent level, and parent level is lower than child level.

Limitations for QoS on PWHE

Supported Interfaces

You can configure PWHE in Layer 3 mode on PWHE-Ether main and subinterfaces.

QoS Accounting Scope

QoS accounting, which measures and records the packet length when performing QoS functions such as policing, shaping, and gathering statistics, doesn't include PW headers.

QoS Configuration Rules
  • match commands are optional when configuring QoS on PWHE. However, you must configure at least one match criterion for a class.

  • When using the match access-group command to configure the match criteria for a class map on the basis of the specified access control list (ACL), QoS classification based on the packet length or time to live (TTL) field in the IPv4 and IPv6 headers is not supported.

L2 Header Based Classification and Marking Scope

L2 header classification and marking are not supported on L3 PWHE interfaces.


Note


The classification and marking applied on PW-Ether main interface are inherited by its subinterfaces without policy.

Bandwidth Distribution

PWHE and non-PWHE traffic on the same pin down member share scheduling resources. It is recommended to configure bandwidth remaining in the parent class-default of PWHE policies to control the distribution of excess bandwidth between PWHE and non-PWHE traffic.

Bandwidth remaining command can be used in the parent default class of PWHE policies allowing user to control the distribution of excess bandwidth between various PWHE interfaces and physical interface.

QoS Accounting

  • The packet length when performing QoS functions (policing, shaping, statistics, etc.) will be based on the customer IP packet, customer L2 header and the configured additional overhead.

  • QoS statistics will include the customer IP packet, customer L2 header and configured additional overhead.


    Note


    For PW-IW interfaces, the packet length used for QoS accounting does not contain customer L2 header.
  • Outer MPLS headers (VC label, transport labels, etc.) and outer L2 header (Layer 2 encap of the underlying physical interface) will not be included in the packet length when performing QoS on the PWHE virtual interface.

Classification and Marking Support

Marking for PW-Ether in ingress and egress direction

  • Marking of customer IP header, qos-group and discard-class will be supported.

  • Marking of EXP bits for all imposed MPLS labels will be supported for PWHE main interface and PW-Ether subinterfaces.

  • EXP for imposed labels can be set in an ingress or an egress policy attached to a PWHE interface.

    Note


    For non-PWHE interfaces, EXP for imposed labels can only be set in an ingress policy. This is an exception made for PWHE interfaces because more labels are imposed on the customer IP packet after processing the egress QoS policy.
  • For unconditional markings in ingress direction, the following fields can be marked - DSCP/precedence, EXP for imposed labels, qos-group and discard-class.
  • For unconditional markings in egress direction, the following fields can be marked - DSCP/precedence, discard-class and EXP for imposed labels.
  • For conditional policer markings in ingress direction, at most two of the following fields can be marked - DSCP/precedence, EXP for imposed labels, qos-group and discard-class.
  • For conditional policer markings in egress direction, the following fields can be marked - DSCP/precedence, discard-class and EXP for imposed labels.

L2 header based classification and marking support

The Table-1, Table-2 and Table-3 summarizes the L2 header based classification and marking support on different PWHE interfaces.

Table 2. Supported L2 header based classification and marking for PW-Ether VC type 4 interface
PW-Ether VC type 4
Classification Ingress Egress

SRC MAC

Yes

No

DEST MAC

Yes

No

DEI

Yes

No

DEI Inner

No

No

COS

Yes

No

COS Inner

No

No

VLAN

Yes

No

VLAN Inner

No

No

Marking

DEI

No

No

COS

No

No

COS Inner

No

No

Table 3. Supported L2 header based classification and marking for PW-Ether VC type 5 interface
PW-Ether VC type 5
Classification Ingress Egress

SRC MAC

Yes

No

DEST MAC

Yes

No

DEI

Yes

Yes

DEI Inner

No

No

COS

Yes

Yes

COS Inner

Yes

Yes

VLAN

No

No

VLAN Inner

No

No

Marking

DEI

No

Yes

COS

No

Yes

COS Inner

No

Yes


Note


The classification and marking applied on PW-Ether main interface are inherited by its subinterfaces without policy.
Table 4. Supported L2 header based classification and marking for PW-Ether L3 subinterface VC type 5
PW-Ether L3 subinterface VC type 5
Classification Ingress Egress

SRC MAC

Yes

No

DEST MAC

Yes

No

DEI

Yes

Yes

DEI Inner

No

No

COS

Yes

Yes

COS Inner

Yes

Yes

VLAN

Yes

Yes

VLAN Inner

Yes

Yes

Marking

DEI

No

Yes

COS

No

Yes

COS Inner

No

Yes

For PW-Ether L2 subinterface VC type 5, all classification and marking are supported.

L2 classification and marking are not supported for PW-IW interface VC type 11.

Policing and Queuing support

All the policing features supported on normal L3 interfaces will be supported on PWHE main interface and subinterface too.

Queuing

Ingress and Egress Queues Ingress and Egress Policers
PWHE interface with no policy map

Each PWHE member has per port default queues. Both the ingress and egress traffic will use the members port default queue.

Not applicable
PWHE interface with a policy map

Any ingress and egress queues in the policymaps would be replicated on each PWHE member.

Any ingress and egress policer in the policymaps would be replicated per each PWHE member.


Note


If PWHE member is a bundle, policy maps will be replicated on bundle members.

Statistics

Show commands of a PWHE virtual interface and PWHE subinterface QoS policy will provide ingress / egress statistics;

  • per pin down member.

  • per bundle member if the bundle is a pin down member.

  • aggregated stats on the whole PWHE interface.

  • shared policy instance per pin down member.

  • aggregated stats on the whole bundle if the bundle is a pin down member.

  • PWHE aggregate shaper stats aggregates all queuing stats of all subinterfaces.

Co-existence of PWHE Main and Subinterface Policies

A line card (LC) can be configured to allow PWHE aggregate shaper policy to co-exist with subinterface policies. This mode is known as co-existence mode. The PWHE aggregate shaper policy will only have a class-default with shape and bandwidth remaining actions. If no PWHE subinterface policy exists, PWHE main interface can have up to 3 level-queuing hierarchical policy.

The co-existence mode with subinterface queuing policies is known as co-existence queuing mode. The co-existence mode with subinterface non-queuing policies is known as co-existence non-queuing mode.

As shown in below examples, PWHE aggregate shaper policy can have:
  • only shape action
  • only bandwidth remaining action
  • shape and bandwidth remaining actions.
Here is the example for PWHE aggregate shaper policy with only shape action:

policy-map pwhe-aggregate-shaper
class class-default
shape average 1 gbps 
!
end-policy-map
!
end
Here is the example for PWHE aggregate shaper policy with only bandwidth remaining action:

policy-map pwhe-aggregate-shaper
class class-default
bandwidth remaining ratio 20 
!
end-policy-map
!
end
Here is the example for PWHE aggregate shaper policy with shape and bandwidth remaining actions:

policy-map pwhe-aggregate-shaper
class class-default
shape average 1 gbps 
bandwidth remaining ratio 20 
!
end-policy-map
!
end

Note


It is recommended to configure shape and bandwidth remaining actions for PWHE aggregate shaper policy.

Restrictions

These restrictions apply while configuring co-existence mode:
  • If co-existence mode is configured for all LCs in ingress direction then co-existence mode configuration for specified LC in ingress will be rejected. But co-existence configuration for specified LC in egress will be accepted provided there is no co-existence mode configured for all LCs in egress direction.

  • If any PWHE main or subinterface has policy configured on a LC, configuring or not configuring co-existence mode will take effect after the LC reloads.

  • If no PWHE main or subinterface has policy configured on a LC, configuring or not configuring co-existence mode will take effect immediately on the LC. It is recommended to commit the co-existence mode change before adding QoS policies on the PWHE main or subinterfaces.

  • In the co-existence queuing mode, policy applied on PWHE subinterface will have up to 2-levels of queuing. Configuring a 3-level queuing policy on PWHE subinterface will be rejected.

  • In the co-existence non-queuing mode, only non-queuing policies on subinterfaces are allowed to co-exist with the PWHE aggregate shaper. If PWHE main interface does not have policy, then subinterface policy can have up to 2-level of queuing.

  • When a LC is not in co-existence mode, the PWHE main interface and subinterfaces cannot have policies at the same time. But each can have policy if the other does not.

  • The traffic for PWHE main interface and subinterfaces without queuing policy will use the pin down interface default queue. The behavior is consistent whether the LC is in co-existence mode or not.

  • In co-existence queuing, non-queuing mode or co-existence disabled (default) mode, applying a non-aggregate shaper policy on PWHE main interface is allowed if subinterface policy does not exists. The non-aggregate shaper policy can have up to 3-levels of queuing. If non-aggregate shaper policy applied on PWHE main interface is a queuing policy, it impacts traffic on the PWHE main interface and subinterfaces because the traffic is moving from the port default queues to the new queues created for the PWHE.

  • After PWHE subinterface policies are applied, in-place modification of the PWHE aggregate shaper is also allowed but after the modification the policy should still be a PWHE aggregate shaper.

  • PWHE subinterface policy co-existing with PWHE aggregate shaper is allowed to be configured as SPI.

PW-Ether Subinterface Policy

QoS policies can be applied on PW-Ether subinterfaces when there is no policy applied on the main PW-Ether interface.

Restrictions
  • When the LC is not in co-existence mode, policies supported on regular subinterface are supported on PW-Ether subinterface too.
  • Percentage based rate on the lowest level is supported on policy applied on PW-Ether subinterface.

    Note


    In the same policy, the grand parent level is lower than parent level, and parent level is lower than child level.
  • When LC is not in co-existence mode, service-policy on the PW-Ether main interface is rejected if there is a service-policy already applied on any of its PW-Ether subinterfaces .

PW-Ether Subinterface Shared Policy Instance

PW-Ether subinterface supports shared policy instance (SPI). SPI on PW-Ether subinterface functions similarly to SPI on bundle subinterfaces.

Restrictions

  • SPI is only supported on PW-Ether subinterfaces. Configuring SPI on PWHE main interface will be rejected.

  • When a policy is applied on PW-Ether subinterface with the SPI, a single instance of the same policy is created on each pin down member.
  • SPI name is unique across all PW-Ether main interfaces and bundle interfaces.

Scale Information

QoS on PWHE supports:

  • 8000 PWHE interface per system.

  • 1792 PWHE interface per line card (LC).
  • 8 physical or bundle interfaces per generic interface list.
  • 4096 sub-interfaces per PW-Ether interface.

  • 20,000 total subinterfaces per LC.


Note


The scale numbers are supported if configuration is applied properly so that queuing resource is not exhausted.

Policy Instantiation

The various scenarios of QoS on PWHE are discussed here:

  • If any member interface has policies applied to them, only non PWHE traffic will be subjected to those policies. An exception to this is a configured port shaper.

  • QoS policy applied on the PWHE main interface or PWHE subinterface is instantiated on pin-down member. If the pin-down member is a bundle, then the policy is instantiated on each bundle member .

  • The supported policy combinations on PWHE main and subinterfaces for line card (LC) in any mode are:
    • Non-queuing policy on PWHE main interface and no policy on subinterfaces.
    • No policy on PWHE main interface and no policy or non-queuing policy on subinterfaces.
    • No policy on PWHE main interface. 2-level queuing policies on subinterface with or without SPI.
    • 1, 2, or 3-level queuing policy on PWHE main interface. No policies on subinterface.
  • The supported policy combinations on PWHE main and subinterfaces for LC not in the co-existence mode are:
    • No policy on PWHE main interface. 3-level queuing policies on subinterfaces with or without SPI.

    Note


    In ingress direction, policies with priority but no queuing actions in the policy-map will use the member port default queues. In egress direction, priority is treated as queuing action so dedicated queue is created for it.
  • The supported policy combinations on PWHE main and subinterfaces for LC in the co-existence queuing mode are:
    • PWHE aggregate shaper policy on the PWHE main interface. Non-queuing policies on subinterfaces with or without SPI.
    • PWHE aggregate shaper policy on the PWHE main interface. Up to 2 level queuing policies on subinterfaces with or without SPI.

    Note


    In the ingress direction, the PWHE subinterface polices with priority but no queuing action in the policy-map will use the queues created for the PWHE main interface. In the egress direction, priority is treated as queuing action so dedicated queues will be created for the subinterface. If the PWHE main interface does not have queuing policy, its subinterface with non-queuing policies will use the pindown interface default queues.
  • The supported policy combination on PWHE main and subinterfaces for LC in the co-existence non-queuing mode is:
    • PWHE aggregate shaper on the PWHE main interface. Non-queuing policies on subinterfaces.

    Note


    In ingress and egress direction, the PWHE subinterface policies with priority but no queuing action in the policy-map will use the queues created for the PWHE main interface. If the PWHE main interface does not have queuing policy, its subinterface policies with priority but no queuing action will use the pin-down interface default queues.

Note


When PWHE interface is created, and no PWHE QoS policy is applied on it, PWHE traffic will pass through the member interface default queues.

 


PWHE without QoS policy

The following two cases represent the default behavior of the PWHE interfaces:

  • PWHE ingress to core facing egress (access to core) - DSCP/ precedence value from customer IP packet is copied to EXP of all imposed labels (VPN and transport)in the core-facing direction.

  • PWHE egress (core to access) - DSCP/precedence value from customer IP packet is copied to EXP of all imposed labels (VC and transport) in the access-facing direction.

Configuring QoS on PWHE: Example.

The example shows how to configure QoS on PWHE main interface or subinterfaces. The example configuration can not be applied on PWHE main and subinterfaces at the same time.

policy-map pw_child_in
class voip
 priority level 1
  police rate percent 1
  !
!
class video
  police rate percent 10
  !
  priority level 2
!
class data
  police rate percent 70 peak-rate percent 100
   exceed-action transmit
   violate-action drop
  !
!
class class-default
  police rate percent 19 peak-rate percent 100
   exceed-action transmit
   violate-action drop
  !
!
end-policy-map
!
policy-map pw_parent_in
class class-default
  service-policy pw_child_in
  police rate 100 mbps
   child-conform-aware
  !
!
end-policy-map
!

policy-map pw_child_out
class voip
  priority level 1
  police rate 1 mbps
  !
!
class data
  bandwidth remaining percent 70
  random-detect discard-class 3 40 ms 50 ms
!
class video
  priority level 2
  police rate 10 mbps
  !
!
class class-default
  random-detect discard-class 1 20 ms 30 ms
!
end-policy-map
!
policy-map pw_parent_out
class class-default
  service-policy pw_child_out
  shape average 100 mbps
!
end-policy-map
!

interface pw-ether 1
service-policy input pw_parent_in
service-policy output pw_parent_out
!
 
The example shows how to apply the PWHE aggregate shaper on PWHE main interface and another policy on its subinterface when the LC is in co-existence mode:

Note


  • Use the hw-module qos-mode pwhe-aggregate-shaper sub-interface { queuing | non-queuing } { ingress | egress } command to enable co-existence mode on the LC.

  • For the following example to work, the LC must be in co-existence queuing mode.

  • When LC is in co-existence mode, apply only PWHE aggregate shaper policy on PWHE main interface.



policy-map pwhe-aggregate-shaper
class class-default
shape average 1 gbps
bandwidth remaining ratio 20
!
end-policy-map
!
policy-map pw_parent_out
class class-default
service-policy pw_child_out
shape average 100 mbps
!
end-policy-map
!

interface pw-ether 1
service-policy output pwhe-aggregate-shaper
!

interface pw-ether 1.1
service-policy output pw_parent_out

For other PWHE related information, please refer the L2VPN and Ethernet Services Configuration Guide for Cisco ASR 9000 Series Routers

Port Shaper Policy Support on L2 Fabric ICL Interface

In L2 fabric mode, a port shaper policy can be applied on the inter-chassis link (ICL) sub-interface. The port shaper policy applied on the ICL sub-interface helps to control the traffic going out on all satellite access ports, and efficiently handles the oversubscribed backhaul ethernet virtual circuits (EVC). This port shaper policy applies to all the satellite interfaces hosted under the ICL sub-interface.

Restrictions

  • Support to add or remove the port shaper policy is implemented only when the nV satellite configuration is present on the ICL sub-interface.
  • Only the port shaper policy can be configured under the L2 Fabric ICL in egress direction.
  • Ability to shape all satellite ports under a single satellite in a simple ring mode is not supported.
  • When operating in L2 fabric and simple ring mode, only upto 2 levels of QoS policies are supported on the satellite access ports. The user-defined class configuration is not supported at parent level.
  • Pseudowire Headend (PW-HE) and Broadband Network Gateway (BNG) configurations are not supported under the satellite interfaces in L2 fabric or simple ring mode.

Configuring Port Shaper Policy on the ICL Interface in L2 Fabric Mode

Perform this task to apply the port shaper policy on the L2 fabric inter-chassis link (ICL) ethernet virtual circuits (EVC). This procedure applies the port shaper in the egress direction of the ICL EVC.

Before you begin

The nV satellite configuration must be applied on the inter-chassis link (ICL) interface.

SUMMARY STEPS

  1. configure
  2. policy-map [ type qos ] policy-name
  3. class class-name
  4. shape {shape [units] | average value}
  5. exit
  6. end-policy-map
  7. interface type interface-path-id
  8. service-policy output policy-map
  9. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:

RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

policy-map [ type qos ] policy-name

Example:

RP/0/RSP0/CPU0:router(config)# policy-map icl_ps

Creates or modifies a policy map that can be attached to one or more ICL interfaces to specify a service policy and enters the policy map configuration mode.

Step 3

class class-name

Example:

RP/0/RSP0/CPU0:router(config-pmap)# class class-default

Specifies the name of the class whose policy you want to create or change.

Step 4

shape {shape [units] | average value}

Example:

RP/0/RSP0/CPU0:router(config-pmap-c)# shape average 400 mbps

Specifies the port shape allocated for a class belonging to a policy map.

Step 5

exit

Example:

RP/0/RSP0/CPU0:router(config-pmap)# exit

Returns the router to policy map configuration mode.

Step 6

end-policy-map

Example:

RP/0/RSP0/CPU0:router(config-pmap)# end-policy-map

Ends the policy map configuration.

Step 7

interface type interface-path-id

Example:

RP/0/RSP0/CPU0:router(config)# interface TenGigabitEthernet 0/1/0/0.1

Configures an interface and enters the sub-interface configuration mode.

Step 8

service-policy output policy-map

Example:

RP/0/RSP0/CPU0:router(config-satellite-fabric-link)# service-policy output icl_ps

Attaches a policy map to an output interface to be used as the service policy for the ICL interface.

Step 9

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Functionality Differences Between ASR 9000 Series High Density Ethernet Line Card Generations

The table lists some fundamental differences in functionalities between the third, fourth, and fifth generations of the ASR 9000 Series High Density Ethernet line cards. See the data sheets for more information on these line cards.

Functionality

Third Generation of ASR 9000 Series High Density Ethernet Line Cards

Fourth and Fifth Generations of ASR 9000 Series High Density Ethernet Line Cards

Ingress queuing

Supported.

See Ingress Queuing support for details.

Not supported

Pre-configured profile values

Supported

Not supported

Default queue limit

100 ms

20 ms

Queue length measurement unit

packets or particles

KB

Queue length for Weighted Random Early Detection (WRED)

Instantaneous queue length. Run the show policy-map interface command to view the counter readings.

Average queue length. Run the show policy-map interface command to view the counter readings.

Shaper granularity

8 kbps for all scheduler hierarchies

  • 100 kbps for scheduler hierachies L2—L4

  • 400 kbps for scheduler hierachy L1

    In certain use cases, traffic shaper rates may be rounded down. For example, in a two or three-level Hierarchical QOS policy with only a shaper action in the parent or grandparent policy applied to the main interface, if the configured shaper rate is

    • Non-multiples of 4—shaper rate is rounded down to the nearest multiple of 4 due to L1 shaper granularity of 400 kbps.

    • Multiples of 4—configured shaper rate is honored.

    For values in non-multiples of 4, to ensure the configured shaper rate is honored, apply the policy to L2 or L3 sub-interfaces, or add a marking action to the parent or grandparent policy when applying it to the main interface.

Policer granularity

8 kbps

1 kbps

Default burst size for policer

100 ms

100 ms

Default burst size for shaper

100 ms

1 ms

Particle granularity

256 bytes

32 bytes

Combination for priority and normal queues

Support for two modes:

  • 3 priority queues and 5 normal queues

  • 2 priority queues and 6 normal queues

2 priority queues and 6 normal queues.

No support for priority level 3.

QoS classification format ID 5

Supported

Not supported

Traffic drop

Packet drops on account of a full egress queue, or drops by WRED are performed in the Traffic Manager after the packet has exited the NP pipeline. The following commands account for these drops:

Because of better integration of the NP pipeline with the Traffic Manager, the egress queue state is verified while the NP pipeline is still processing the packet. The following commands account for drops because of a full egress queue or drops by WRED:

Multi-rate interfaces

Supported

Not supported

Ingress Queuing Support

Ingress queuing is disabled for some line cards.

The tables below list out the ingress queuing support for fixed port and modular line cards.


Note


Ingress queuing is not supported on ASR9K-SIP-700 line cards.


Fixed port Line Card

LC type Ingress Queuing Support

A9K-24X10GE-TR/- SE

Yes

A9K-36X10GE-TR/ -SE

No

A9K-2X100GE-TR/ -SE

No

A9K-1X100GE-TR/ -SE

No

A9K-8X100G-LB-SE / -TR

No

A9K-8X100GE-SE / -TR

No

A99-8X100GE-SE / -TR

No

A9K-4X100GE-SE / -TR

Yes

A99-12X100GE

No

A9K-4X100GE

No

A9K-48X10GE-1G-SE/-TR

No

A9K-24X10GE-1G-SE/-TR

No

A99-48X10GE-1G-SE/-TR

No

Modular Line Card


Note


The A9K-MOD400-SE/TR line cards are supported from Cisco IOS XR Release 5.3.2, and the A9K-MOD200-SE/TR line cards are supported from Cisco IOS XR Release 6.0.1.

For minimum software release versions of the new MPAs that are supported on the Cisco ASR 9000 Series 400G (A9K-MOD400-SE/TR) and 200G Modular Line Cards (A9K-MOD200-SE/TR), see Table 5 and Table 6 respectively.


LC type EP type Ingress Queuing Support

A9K-MOD80-TR/ -SE

A9K-MPA-20X1GE

Yes

A9K-MOD80-TR/ -SE

A9K-MPA-4X10GE

No

Note

 

To enable ingress queueing on these line cards, run the command hw-module all qos-mode ingress-queue-enable.

A9K-MOD80-TR/ -SE

A9K-MPA-2X10GE

Yes

A9K-MOD80-TR/ -SE

A9K-MPA-1X40GE

No

A9K-MOD400-SE

A9K-MPA-8X10GE

Yes

A9K-MOD400-SE

A9K-MPA-20X10GE

No

Note

 

To enable ingress queueing on these line cards, run the command hw-module all qos-mode ingress-queue-enable.

A9K-MOD400-SE

A9K-MPA-2X100GE

No

A9K-MOD400-SE

A9K-MPA-1X100GE

Yes

A9K-MOD400-SE

A9K-MPA-2X100GE

Yes

A9K-MOD400-SE

A9K-MPA-32X1GE

Yes

A9K-MOD200-SE/ -TR

A9K-MPA-8X10GE

No

Note

 

To enable ingress queueing on these line cards, run the command hw-module all qos-mode ingress-queue-enable.

A9K-MOD200-SE

A9K-MPA-4X10GE

Yes

A9K-MOD200-SE

A9K-MPA-2X10GE

Yes

A9K-MOD200-SE

A9K-MPA-2X40GE

No

A9K-MOD200-SE

A9K-MPA-1X40GE

Yes

A9K-MOD200-SE

A9K-MPA-20X1GE

Yes

A9K-MOD200-SE

A9K-MPA-32X1GE

Yes

A9K-MOD200-SE

A9K-MPA-1X100GE

No

A9K-MOD200-SE

A9K-MPA-10X10GE

No

A9K-24X10GE-1G

4X1GE , 4X10GE

No

A9K-48X10GE-1G

4X1GE , 4X10GE

No

A99-12X100GE/A9K-4X100GE

QSFP-4X10G

No

A99-12X100GE/A9K-4X100GE

QSFP-1X40G

No

A99-12X100GE/A9K-4X100GE

QSFP-1x100G

No

ASR9901

All types

No

A9K-MOD160-TR/ -SE

A9K-MPA-20X1GE

Yes

A9K-MOD160-TR/ -SE

A9K-MPA-4X10GE

Yes

A9K-MOD160-TR/ -SE

A9K-MPA-2X10GE

Yes

A9K-MOD160-TR/ -SE

A9K-MPA-1X40GE

No

A9K-MOD160-TR/ -SE

A9K-MPA-2X40GE

No

A9K-MOD160-TR/ -SE

A9K-MPA-8X10GE

No

A9K-MOD200-TR/ -SE

A9K-MPA-20X1GE

Yes

A9K-MOD200-TR/ -SE

A9K-MPA-4X10GE

Yes

A9K-MOD200-TR/ -SE

A9K-MPA-2X10GE

Yes

A9K-MOD200-TR/ -SE

A9K-MPA-1X40GE

Yes

A9K-MOD200-TR/ -SE

A9K-MPA-2X40GE

No

A9K-MOD200-TR/ -SE

A9K-MPA-8X10GE

No

A9K-MOD400-TR/ -SE

A9K-MPA-20X1GE

Yes

A9K-MOD400-TR/ -SE

A9K-MPA-4X10GE

Yes

A9K-MOD400-TR/ -SE

A9K-MPA-2X10GE

Yes

A9K-MOD400-TR/ -SE

A9K-MPA-1X40GE

Yes

A9K-MOD400-TR/ -SE

A9K-MPA-2X40GE

No

A9K-MOD400-TR

A9K-MPA-8X10GE

Yes

A9K-MOD400-TR

A9K-MPA-20X10GE

No

A9K-MOD400-TR

A9K-MPA-2X100GE

No

A9K-MOD400-TR

A9K-MPA-1X100GE

Yes

ASR9001-LC

Chassis fixed 4X10GE

No

ASR9001-LC

A9K-MPA-4X10GE

No

ASR9001-LC

A9K-MPA-2X10GE

No

ASR9001-LC

A9K-MPA-1X40GE

No

ASR9001-LC

A9K-MPA-20X1GE

No

In-Place Policy Modification

The In-Place Policy Modification feature allows you to modify a QoS policy even when the QoS policy is attached to one or more interfaces. When you modify the QoS policy attached to one or more interfaces, the QoS policy is automatically modified on all the interfaces to which the QoS policy is attached. A modified policy is subject to the same checks that a new policy is subject to when it is bound to an interface.

If the policy-modification is successful, the modified policy takes effect on all the interfaces to which the policy is attached. The configuration session is blocked until the policy modification is complete.

However, if the policy modification fails on any one of the interfaces, an automatic rollback is initiated to ensure that the pre-modification policy is in effect on all the interfaces. The configuration session is blocked until the rollback is complete on all affected interfaces.

If unrecoverable errors occur during in-place policy modification, the policy is put into an inconsistent state on target interfaces. Use the show qos inconsistency command to view inconsistency in each location. (This command is supported only on ASR 9000 Ethernet Line Cards). The configuration session is blocked until the modified policy is effective on all interfaces that are using the policy. No new configuration is possible until the configuration session is unblocked.

When a QoS policy attached to an interface is modified, there might not be any policy in effect on the interfaces in which the modified policy is used for a short period of time.


Note


The QoS statistics for the policy that is attached to an interface are lost (reset to 0) when the policy is modified.


Recommendations for Using In-Place Policy Modification

For a short period of time while a QoS policy is being modified, there might not be any policy in effect on the interfaces in which the modified policy is used. For this reason, modify QoS policies that affect the fewest number of interfaces at a time. Use the show policy-map targets command to identify the number of interfaces that will be affected during policy map modification.

Dynamic Modification of Interface Bandwidth

This section describes the dynamic modification of interface bandwidth feature.

Policy States

  • Verification—This state indicates an incompatibility of the configured QoS policy with respect to the new interface bandwidth value. The system handles traffic on a best-efforts basis and some traffic drops can occur.

Inter-Class Policer Bucket Sharing

Based on different classification criteria, inter-class policer bucket sharing feature allows policer bucket sharing among different classes in a hierarchical QoS model, within the modular quality of service command line (MQC) construct, to achieve multirate policing of the same packet. In this feature, the classification of the incoming packet happens only once. However, the policer bucket is shared among classes; that is the same token bucket is used even though a match happens against different classes.

This feature includes following components:

Policer Bucket Shared

The policer bucket shared feature defines and shares a policer node entity. The defined policer bucket is shared among multiple classes.

Here is a sample configuration that defines and shares policer bucket instance sp1 :
policy-map parent 
        class long-distance
          police bucket shared sp1 rate 1 mbps

In this configuration, a policy-map for class long-distance traffic type is created to police at 1Mbps and the policer bucket is shared.

Policer Bucket Referred

The policer bucket referred feature refers a defined policer bucket instance. The reference to the policer bucket could be across policy level, a parent can refer a child policer, or vice versa, and one policer node can be referred by multiple classes across a policy map.

Here is a sample configuration that refers shared policer bucket instance sp1 :
policy-map voip-child
        class long-distance-voip
         police bucket referred sp1

In this configuration, a policy-map for class long-distance-voip traffic type is created and the shared policer bucket sp1 is referred.

Interface Support

Inter-class policer bucket sharing feature is supported in both the egress and ingress directions. This section describes supported and non-supported interfaces for inter-class policer bucket sharing feature.

Table 5. Supported and non-supported interfaces

Supported Interfaces

1G/10G/100GE Physical interfaces

L2 and L3 sub-interfaces

Bundle ports

Bundle sub-interfaces

Non-supported Interfaces

Bridge Virtual Interface (BVI)

Satellite interfaces

Pseudowire Headend (PWHE) interfaces


Note


Inter-class policer bucket sharing feature is supported only on the ASR 9000 Enhanced Ethernet Line Card.

Classification Support for Ethernet-Services ACL

You can configure class of service (QoS) classification based on a match for partial MAC address (such as Organizationally Unique Identifier (OUI)) using the match access-group ethernet-service command. This command creates a match criteria for a class map based on the specified ethernet-service access control list (ACL) containing MAC addresses.

For example, you can create an ethernet-service ACL such as the following:

ethernet-services access-list acl1
 20 permit 2222.3300.0000 0000.00ff.ffff any
 30 permit 1111.2200.0000 0000.00ff.ffff any
 40 permit 1212.2300.0000 0000.00ff.ffff any
!

The ethernet-service ACL can be used in the class map to match the MAC addresses as follows:

class-map NID-123
  match access-group ethernet-service acl1
end-class-map

Note


  • You can provide multiple values for the ethernet-service match type in a configuration; only the first value is considered for the match criteria. Subsequent values indicated in the match statement are ignored for classification.

  • The capture statements in an ethernet-service ACL are ignored.

  • An ethernet-service ACL should have only permit statements. If there are any deny statements, the policy is rejected.

  • If you specify a value for the Ether-Type keyword using the match access-group ethernet-service command, the value is ignored.


ICMP, ICMPv6 Fragment Packet and Message Type QoS Classification Enhancement

Table 6. Feature History Table

Feature Name

Release Information

Feature Description

ICMP, ICMPv6 Fragment Packet and Message Type QoS Classification Enhancement

Release 24.3.1

In this release, we have enhanced network congestion management and security against distributed denial-of-service (DDoS) fragment attacks by enabling more granular classification and policing of ICMP and ICMPv6 traffic.

This is made possible by enabling support for QoS policies that can classify and police ICMP and ICMPv6 fragments and message types in both flat QoS and hierarchical QoS (HQoS).

Prior to release 24.3.1, this capability was limited to classifying ICMP and ICMPv6 fragments in HQoS and message types in flat QoS only.

This feature enables accurate identification of ICMP and ICMPv6 fragment packets in flat QoS scenarios, utilizing Access Control Lists (ACLs) for effective Modular QoS Command-Line Interface (MQC) policing. This ensures that fragmented packets are now classified into a separate class, allowing for distinct policy rules and better congestion control. As a result, it improves network security by mitigating ICMP and ICMP6 fragment attacks.

This feature also supports classification of ICMP and ICMPv6 message types, specifically echo and echo-reply, in the HQoS scenarios. By leveraging ACLs for MQC policing within child-queues, this feature improves the granularity of traffic management, enabling the deployment of differentiated policy rules for these message types and enhancing overall network performance.

ICMP and ICMPv6 Fragments and Message Types: QoS Classification Enhancements

Internet Control Message Protocol (ICMP) and its IPv6 variant, ICMPv6, are routing protocols integral to network diagnostics and error reporting. They facilitate communication between network devices to relay error messages and operational information.

There are two types of classification for ICMP and ICMPv6 packets:

  • Fragmentation Classification: ICMP/ICMPv6 Fragments—Fragmentation occurs when packets are too large to be transmitted in a single frame and must be divided into smaller fragments. Proper classification of these fragments is crucial for effective congestion management and security, as it allows for the application of specific policy rules to mitigate potential fragment-based distributed denial-of-service (DDoS) attacks.

  • Message Type Classification: Echo and Echo-Reply—These message types are used primarily for diagnostic purposes, such as the ping command, which tests the reachability of a host on an IP network. Differentiating these message types in hierarchical QoS scenarios allows for more granular traffic management and the application of tailored policy rules, enhancing network performance and reliability.

Configure ICMP, ICMPv6 Fragment Packets for Flat QoS

Procedure


Step 1

Create IPv4 and IPv6 ACLs with fragment match.

  • For ICMP (IPv4) ACLs, use the ipv4 access-list command.
    Example:
    router (config)#ipv4 access-list ICMP-fragment-rate-limit
    router(config-ipv4-acl)#permit icmp any any fragments
    router(config-ipv4-acl)#exit
  • For ICMPv6 (IPv6) ACLs, use the ipv6 access-list command.
    Example:
    router (config)#ipv6 access-list ICMP-fragment-rate-limit-IPv6
    router(config-ipv6-acl)#permit icmpv6 any any fragments
    router(config-ipv6-acl)#exit

Step 2

Create two class maps, one for IPv4 and IPv6, and attach the respective ACLs to the class maps.

  • For ICMP (IPv4) class maps:
    Example:
    router (config)#class-map match-any ICMP-fragment-rate-limit
    router(config-cmap)#match access-group ipv4 ICMP-fragment-rate-limit
    router(config-cmap)#end-class-map
    router(config-cmap)#exit
  • For ICMPv6 (IPv6) class maps:
    Example:
    router (config)#class-map match-any ICMP-fragment-rate-limit
    router(config-cmap)#match access-group ipv6 ICMP-fragment-rate-limit-IPv6
    router(config-cmap)#end-class-map
    router(config-cmap)#exit

Step 3

Create a flat QoS policy map to attach to an interface.

Example:

router(config)#policy-map ICMP-fragment
router(config-pmap)#class ICMP-fragment-rate-limit
router(config-pmap-c)#police rate 10 mbps burst 1875000 bytes peak-burst 3750000 bytes
router(config-pmap-c-police)#exit
router(config-pmap-c)#exit
router(config-pmap)#exit

Within the policy map, specify the class type and apply traffic policing and shaping to it.

Step 4

Attach the policy map to an input interface.

Example:

router (config)#interface TenGigE0/4/0/10
router(config-if)#service-policy output ICMP-fragment
router(config-if)#commit

Step 5

Verify ICMP, ICMPv6 fragment packets in a flat QoS scenario.

Example:

router#show policy-map interface tenGigE 0/4/0/10 output

TenGigE0/4/0/10 output: ICMP-fragment
Class ICMP-fragment-rate-limit
    Classification statistics          (packets/bytes)     (rate - kbps)
      Matched             :             1374137/714551240            41596
      Transmitted         :              332712/173010240            9998 => 10 Mbps policing
      Total Dropped       :             1041425/541541000            31598
    Policing statistics                (packets/bytes)     (rate - kbps) 
      Policed(conform)    :              332712/173010240            9998
      Policed(exceed)     :             1041425/541541000            31598
      Policed(violate)    :                   0/0                    0
      Policed and dropped :             1041425/541541000          
      Policed and dropped(parent policer)  : N/A
Class class-default
  Classification statistics          (packets/bytes)     (rate - kbps)
    Matched             :             1374137/714551240            41596
    Transmitted         :              332712/173010240            9998
    Total Dropped       :             1041425/541541000            31598

In the configuration examples, the configured policy rate is 10 Mbps.


Configure ICMP, ICMPv6 Message Types for Hierarchical QoS

Procedure


Step 1

Create IPv4 and IPv6 ACLs with message type match.

  • For ICMP (IPv4) ACLs, use the ipv4 access-list command.
    Example:
    router (config)#ipv4 access-list ICMP-fragment-rate-limit
    router(config-ipv4-acl)#permit icmp any any echo
    router(config-ipv4-acl)#permit icmp any any echo-reply
    router(config-ipv4-acl)#exit
  • For ICMPv6 (IPv6) ACLs, use the ipv6 access-list command.
    Example:
    router (config)#ipv6 access-list ICMP-fragment-rate-limit-IPv6
    router(config-ipv6-acl)#permit icmpv6 any any echo
    router(config-ipv4-acl)#permit icmpv6 any any echo-reply
    router(config-ipv6-acl)#exit

Step 2

Create two class maps, one for IPv4 and IPv6, and attach the respective ACLs to the class maps.

  • For ICMP (IPv4) class maps:
    Example:
    router (config)#class-map match-any ICMP-fragment-rate-limit
    router(config-cmap)#match access-group ipv4 ICMP-fragment-rate-limit
    router(config-cmap)#end-class-map
    router(config-cmap)#exit
  • For ICMPv6 (IPv6) class maps:
    Example:
    router (config)#class-map match-any ICMP-fragment-rate-limit
    router(config-cmap)#match access-group ipv6 ICMP-fragment-rate-limit-IPv6
    router(config-cmap)#end-class-map
    router(config-cmap)#exit

Step 3

Create a hierarchical QoS (HQoS) policy map to attach to an interface.

  • For ICMP (IPv4) policy maps:
    Example:
    router(config)#policy-map ICMP-rate-limit
    router(config-pmap)#class ICMP-rate-limit
    router(config-pmap-c)#police rate 3 gbps burst 16777215 bytes peak-burst 16777215 bytes
    router(config-pmap-c-police)#exit
    router(config-pmap-c)#exit
    router(config-pmap)#exit
    router(config)#policy-map HQOS-ICMP-rate-limit
    router(config-pmap)#class class-default
    router(config-pmap-c)#service-policy ICMP-rate-limit
    router(config-pmap-c-police)#exit
  • For ICMPv6 (IPv6) policy maps:
    Example:
    router(config)#policy-map ICMP-rate-limit
    router(config-pmap)#class ICMP-rate-limit-IPv6
    router(config-pmap-c)#police rate 3 gbps burst 16777215 bytes peak-burst 16777215 bytes
    router(config-pmap-c-police)#exit
    router(config-pmap-c)#exit
    router(config-pmap)#exit
    router(config)#policy-map HQOS-ICMP-rate-limit
    router(config-pmap)#class class-default
    router(config-pmap-c)#service-policy ICMP-rate-limit-IPv6
    router(config-pmap-c-police)#exit

In both examples, the child policy map ICMP-rate-limit is referenced within the class-default of the parent policy map HQOS-ICMP-rate-limit.

Step 4

Attach the policy map to an input interface.

Example:

router (config)#interface TenGigE0/2/0/39
router(config-if)#service-policy output HQOS-ICMP-rate-limit
router(config-if)#commit

Step 5

Verify ICMP, ICMPv6 message types transmission rate in the HQoS policing.

Example:

router#show policy-map interface ten0/2/0/39 output

Fri Nov  3 14:29:59.768 KST
 
TenGigE0/2/0/39 output: ICMP-rate-limit
 
Class class-default
  Classification statistics          (packets/bytes)     (rate - kbps)
    Matched             :                   0/0                    0
    Transmitted         :                   0/0                    0
    Total Dropped       :                   0/0                    0
 
  Policy ICMP-type Class ICMP-rate-limit
  Classification statistics          (packets/bytes)     (rate - kbps)
    Matched             :            47704736/12212412416          3710115
    Transmitted         :            38639920/9891819520           3000260
    Total Dropped       :             9064816/2320592896           709855
  Policing statistics                (packets/bytes)     (rate - kbps) 
    Policed(conform)    :            38639920/9891819520           3000260
    Policed(exceed)     :             9064816/2320592896           709855
    Policed(violate)    :                   0/0                    0
    Policed and dropped :             9064816/2320592896         
  Queueing statistics
    Queue ID                             : 36970 
    High watermark                       : N/A 
    Inst-queue-len  (kbytes)             : 0
    Avg-queue-len   (kbytes)             : 0
    Taildropped(packets/bytes)           : 0/0
    Queue(conform)      :            38639920/9891819520           3000260
    RED random drops(packets/bytes)      : 0/0
 
 
  Policy ICMP-type Class class-default
    Classification statistics          (packets/bytes)     (rate - kbps)
      Matched             :                   0/0                    0
      Transmitted         :                   0/0                    0
      Total Dropped       :                   0/0                    0
    Queueing statistics
      Queue ID                             : 36970 
      High watermark                       : N/A 
      Inst-queue-len  (kbytes)             : 0
      Avg-queue-len   (kbytes)             : 0
      Taildropped(packets/bytes)           : 0/0
      Queue(conform)      :                   0/0                    0
      RED random drops(packets/bytes)      : 0/0

In the configuration examples, the configured policy rate is 3 Gbps.


How to Configure Modular QoS Packet Classification

Creating a Traffic Class

To create a traffic class containing match criteria, use the class-map command to specify the traffic class name, and then use the following match commands in class-map configuration mode, as needed.

Note


Users can provide multiple values for a match type in a single line of configuration; that is, if the first value does not meet the match criteria, then the next value indicated in the match statement is considered for classification.


For conceptual information, see the Traffic Class Elements, page 16.

Restrictions

  • All match commands specified in this configuration task are considered optional, but you must configure at least one match criterion for a class.
  • For the match access-group command, QoS classification based on the packet length or TTL (time to live) field in the IPv4 and IPv6 headers is not supported.

  • For the match access-group command, when an ACL list is used within a class-map, the deny action of the ACL is ignored and the traffic is classified based on the specified ACL match parameters.

    An empty ACL (contains no rules, only remarks) within a QoS policy-map permits all traffic by default, and the implicit deny condition doesn’t work with an empty ACL. Within a QoS policy map, the corresponding class-map matches all traffic not yet matched by the preceding traffic classes. In such a case, any explicit deny rule in the ACL leads to configuration commit failure.

  • The match discard-class command is not supported on the Asynchronous Transfer Mode (ATM) interfaces.

  • When QoS policy-maps use ACLs to classify traffic, ACEs of ACLs consume some amount of TCAM memory of the line card. Each QoS policy-map for ASR9000 supports up to a maximum of 3072 TCAM IPv4 entries. If you cross the limit, IOS XR fails to apply this policy-map with the insufficient memory available error. If you encounter this error, decrease the number of ACEs in ACLs for the policy-map. This error typically appears when using nested policy-maps, where ACEs in ACLs on different levels are multiplied.

SUMMARY STEPS

  1. configure
  2. class-map [ type qos] [ match-any] [ match-all] class-map-name
  3. match [not] access-group [ipv4| ipv6| ethernet-service ] access-group-name
  4. match [not] cos [cos-value] [cos-value0 ... cos-value7]
  5. match [not] cos inner [inner-cos-value] [inner-cos-value0 ...inner-cos-value7]
  6. match destination-address mac destination-mac-address
  7. match source-address mac source-mac-address
  8. match [not] discard-class discard-class-value [discard-class-value1 ... discard-class-value6]
  9. match [not] dscp [ipv4 | ipv6] dscp-value [dscp-value ... dscp-value]
  10. match [not] mpls experimental topmost exp-value [exp-value1 ... exp-value7]
  11. match [not] precedence [ipv4 | ipv6] precedence-value [precedence-value1 ... precedence-value6]
  12. match [not] protocol protocol-value
[protocol-value1 ... protocol-value7]
  13. match [not] qos-group [qos-group-value1 ... qos-group-value8]
  14. match vlan [inner] vlanid [ vlanid1 ... vlanid7]
  15. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

class-map [ type qos] [ match-any] [ match-all] class-map-name

Example:


RP/0/RSP0/CPU0:router(config)# class-map class201

Creates a class map to be used for matching packets to the class whose name you specify and enters the class map configuration mode.

If you specify match-any , one of the match criteria must be met for traffic entering the traffic class to be classified as part of the traffic class. This is the default. If you specify match-all , the traffic must match all the match criteria.

Step 3

match [not] access-group [ipv4| ipv6| ethernet-service ] access-group-name

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match access-group ipv4 map1

(Optional) Configures the match criteria for a class map based on the specified access control list (ACL) name.

Note

 

You can provide multiple values in a configuration; only the first value is considered for the match criteria. The subsequent values indicated in the match statement are ignored for classification.

Step 4

match [not] cos [cos-value] [cos-value0 ... cos-value7]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match cos 5

(Optional) Specifies a cos-value in a class map to match packets. The cos-value arguments are specified as an integer from 0 to 7.

Step 5

match [not] cos inner [inner-cos-value] [inner-cos-value0 ...inner-cos-value7]

Example:


RP/0/RSP0/CPU0:router match cos inner 7

(Optional) Specifies an inner-cos-value in a class map to match packets. The inner-cos-value arguments are specified as an integer from 0 to 7.

Step 6

match destination-address mac destination-mac-address

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match destination-address mac 00.00.00

(Optional) Configures the match criteria for a class map based on the specified destination MAC address.

Step 7

match source-address mac source-mac-address

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match source-address mac 00.00.00

(Optional) Configures the match criteria for a class map based on the specified source MAC address.

Step 8

match [not] discard-class discard-class-value [discard-class-value1 ... discard-class-value6]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match discard-class 5

(Optional) Specifies a discard-class-value in a class map to match packets. The discard-class-value argument is specified as an integer from 0 to 7.

The match discard-class command is supported only for an egress policy. The match discard-class command is not supported on the Asynchronous Transfer Mode (ATM) interfaces.

Step 9

match [not] dscp [ipv4 | ipv6] dscp-value [dscp-value ... dscp-value]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match dscp ipv4 15

(Optional) Identifies a specific DSCP value as a match criterion.

  • Value range is from 0 to 63.

  • Reserved keywords can be specified instead of numeric values.

  • Up to eight values or ranges con be used per match statement.

Step 10

match [not] mpls experimental topmost exp-value [exp-value1 ... exp-value7]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match mpls experimental topmost 3

(Optional) Configures a class map so that the three-bit experimental field in the topmost Multiprotocol Label Switching (MPLS) labels are examined for experimental (EXP) field values. The value range is from 0 to 7.

Step 11

match [not] precedence [ipv4 | ipv6] precedence-value [precedence-value1 ... precedence-value6]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match precedence ipv4 5

(Optional) Identifies IP precedence values as match criteria.

  • Value range is from 0 to 7.

  • Reserved keywords can be specified instead of numeric values.

Step 12

match [not] protocol protocol-value
[protocol-value1 ... protocol-value7]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match protocol igmp

(Optional) Configures the match criteria for a class map on the basis of the specified protocol.

Step 13

match [not] qos-group [qos-group-value1 ... qos-group-value8]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match qos-group 1 2 3 4 5 6 7 8

(Optional) Specifies service (QoS) group values in a class map to match packets.

  • qos-group-value identifier argument is specified as the exact value or range of values from 0 to 63.

  • Up to eight values (separated by spaces) can be entered in one match statement.

  • match qos-group command is supported only for an egress policy.

Step 14

match vlan [inner] vlanid [ vlanid1 ... vlanid7]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match vlan vlanid vlanid1

(Optional) Specifies a VLAN ID or range of VLAN IDs in a class map to match packets.

  • vlanid is specified as an exact value or range of values from 1 to 4094.

  • Total number of supported VLAN values or ranges is 8.

Step 15

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Creating a Traffic Policy

To create a traffic policy, use the policy-map command to specify the traffic policy name.

The traffic class is associated with the traffic policy when the class command is used. The class command must be issued after you enter the policy map configuration mode. After entering the class command, the router is automatically in policy map class configuration mode, which is where the QoS policies for the traffic policy are defined.

These class-actions are supported:

  • bandwidth—Configures the bandwidth for the class. See the “Configuring Modular Quality of Service Congestion Management on Cisco ASR 9000 Series Routers” module in this guide.

  • police—Police traffic. See the “Configuring Modular Quality of Service Congestion Management on Cisco ASR 9000 Series Routers” module in this guide.

  • priority—Assigns priority to the class. See the “Configuring Modular Quality of Service Congestion Management on Cisco ASR 9000 Series Routers” module in this guide.

  • queue-limit—Configures queue-limit (tail drop threshold) for the class. See the “Configuring Modular QoS Congestion Avoidance on Cisco ASR 9000 Series Routers” module in this guide.

  • random-detect—Enables Random Early Detection. See the “Configuring Modular QoS Congestion Avoidance on Cisco ASR 9000 Series Routers” module in this guide.

  • service-policy—Configures a child service policy.

  • set—Configures marking for this class. See the “Class-based Unconditional Packet Marking Feature and Benefits” section on page 20.

  • shape—Configures shaping for the class. See the “Configuring Modular Quality of Service Congestion Management on Cisco ASR 9000 Series Routers” module in this guide.

For additional commands that can be entered as match criteria, see the Cisco ASR 9000 Series  Aggregation Services Router Modular Quality of Service Command Reference.

For conceptual information, see “Traffic Policy Elements” section on page 17.

SUMMARY STEPS

  1. configure
  2. policy-map [ type qos ] policy-name
  3. class class-name
  4. set precedence [ tunnel ] precedence-value
  5. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

policy-map [ type qos ] policy-name

Example:


RP/0/RSP0/CPU0:router(config)# policy-map policy1

Creates or modifies a policy map that can be attached to one or more interfaces to specify a service policy and enters the policy map configuration mode.

Step 3

class class-name

Example:


RP/0/RSP0/CPU0:router(config-pmap)# class class1

Specifies the name of the class whose policy you want to create or change.

Step 4

set precedence [ tunnel ] precedence-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set precedence 3

Sets the precedence value in the IP header.

Step 5

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Attaching a Traffic Policy to an Interface

After the traffic class and traffic policy are created, you must use the service-policy interface configuration command to attach a traffic policy to an interface, and to specify the direction in which the policy should be applied (either on packets coming into the interface or packets leaving the interface).

For additional commands that can be entered in policy map class configuration mode, see the Cisco ASR 9000 Series Aggregation Services RoutersModular Quality of Service Command Reference..

Prerequisites

A traffic class and traffic policy must be created before attaching a traffic policy to an interface.

SUMMARY STEPS

  1. configure
  2. interface type interface-path-id
  3. service-policy {input | output} policy-map
  4. Use the commit or end command.
  5. show policy-map interface type interface-path-id [input | output]

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

interface type interface-path-id

Example:


RP/0/RSP0/CPU0:router(config)# interface gigabitethernet 0/1/0/9

Configures an interface and enters the interface configuration mode.

Step 3

service-policy {input | output} policy-map

Example:


RP/0/RSP0/CPU0:router(config-if)# service-policy output policy1

Attaches a policy map to an input or output interface to be used as the service policy for that interface. In this example, the traffic policy evaluates all traffic leaving that interface.

Step 4

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Step 5

show policy-map interface type interface-path-id [input | output]

Example:


RP/0/RSP0/CPU0:router# show policy-map interface gigabitethernet 0/1/0/9

(Optional) Displays statistics for the policy on the specified interface.

Attaching a Shared Policy Instance to Multiple Subinterfaces

After the traffic class and traffic policy are created, you can optionally use the service-policy (interface) configuration command to attach a shared policy instance to multiple subinterfaces, and to specify the direction in which the policy should be applied (either on packets coming into or leaving the subinterface).


Note


A shared policy can include a combination of Layer 2 and Layer 3 subinterfaces.


For additional commands that can be entered in policy map class configuration mode, see the Cisco ASR 9000 Series Aggregation Services Routers Modular Quality of Service Command Reference.

Prerequisites

A traffic class and traffic policy must be created before attaching a shared policy instance to a subinterface.

Restrictions

Shared policy instance across multiple physical interfaces is not supported.

SUMMARY STEPS

  1. configure
  2. interface type interface-path-id
  3. service-policy {input | output} policy-map [ shared-policy-instance instance-name]
  4. Use the commit or end command.
  5. show policy-map shared-policy-instance instance-name [input | output] location rack/slot/module

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:

RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

interface type interface-path-id

Example:

RP/0/RSP0/CPU0:router(config)# interface gigabitethernet 0/1/0/0.1

Enters interface configuration mode and configures a subinterface.

Step 3

service-policy {input | output} policy-map [ shared-policy-instance instance-name]

Example:

RP/0/RSP0/CPU0:router(config-if)# service-policy output policy1 shared-policy-instance Customer1

Attaches a policy map to an input or output subinterface to be used as the service policy for that subinterface.

  • In this example, the traffic policy evaluates all traffic leaving that interface.

Step 4

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Step 5

show policy-map shared-policy-instance instance-name [input | output] location rack/slot/module

Example:

RP/0/RSP0/CPU0:router# show policy-map shared-policy-instance Customer1 location 0/1/0/7.1

(Optional) Displays statistics for the policy on the specified shared policy instance subinterface.

Attaching a Shared Policy Instance to Bundle Interfaces or EFP Bundles

After the traffic class and traffic policy are created, you can optionally use the service-policy (interface) configuration command to attach a shared policy instance to bundle interfaces and to bundle EFPs, and to specify the direction in which the policy should be applied (either on packets coming into or leaving the subinterface).

For additional commands that can be entered in policy map class configuration mode, see the Cisco ASR 9000 Series Aggregation Services Router Modular Quality of Service Command Reference.

Prerequisites

A traffic class and traffic policy must be created before attaching a shared policy instance to bundle interfaces or EFP bundles.

Restrictions

Shared policy instance across multiple physical interfaces is not supported.

SUMMARY STEPS

  1. configure
  2. interface Bundle-Ether bundle-id
  3. service-policy {input | output} policy-map [ shared-policy-instance instance-name]
  4. Use the commit or end command.
  5. show policy-map shared-policy-instance instance-name [input | output] location location-id

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:

RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

interface Bundle-Ether bundle-id

Example:

RP/0/RP1/CPU0:router(config)# interface Bundle-Ether 100.1 l2transport

Enters interface configuration mode and configures a bundle interface.

Step 3

service-policy {input | output} policy-map [ shared-policy-instance instance-name]

Example:

RP/0/RSP0/CPU0:router(config-if)# service-policy output policy1 shared-policy-instance Customer1

Attaches a policy map to an input or output bundle interface to be used as the service policy for that subinterface.

  • In this example, the traffic policy evaluates all traffic leaving that interface.

Step 4

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Step 5

show policy-map shared-policy-instance instance-name [input | output] location location-id

Example:

RP/0/RSP0/CPU0:router# show policy-map shared-policy-instance Customer1 location 0/rsp0/cpu0

(Optional) Displays statistics for the policy at the specified shared policy instance location.

Configuring Class-based Unconditional Packet Marking

Table 7. Feature History Table

Feature Name

Release Information

Feature Description

Set IP Marking for SRv6 Encapsulation

Release 24.2.1

With this feature support for IP marking for SRv6 packets that are encapsulated, there are some important updates to the QoS behavior.

This is an explicit packet marking feature that applies only to ingress QoS policies.

CLI: This feature introduces the set ip encapsulation command.

This configuration task explains how to configure the following class-based unconditional packet marking features on your router:

  • IP precedence value

  • IP DSCP value

  • IP Encapsulation value

  • QoS group value (ingress only)

  • CoS value ( egress only on Layer 3 subinterfaces)

  • MPLS experimental value

  • Discard class


Note


IPv4 and IPv6 QoS actions applied to MPLS tagged packets are not supported. The configuration is accepted, but no action is taken.



Note


Choose only two set commands per class.


Procedure


Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

policy-map policy-name

Example:


RP/0/RSP0/CPU0:router(config)# policy-map policy1

Creates or modifies a policy map that can be attached to one or more interfaces to specify a service policy and enters the policy map configuration mode.

Step 3

class class-name

Example:


RP/0/RSP0/CPU0:router(config-pmap)# class class1

Specifies the name of the class whose policy you want to create or change and enters the policy class map configuration mode.

Step 4

set precedence

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set precedence 1

Sets the precedence value in the IP header.

Step 5

set dscp

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set dscp 5

Marks a packet by setting the DSCP in the ToS byte.

Step 6

set ip encapsulation class-of-service cos-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set ip encapsulation class-of-service 55

Sets the traffic class imposition for SRv6 encapsulation.

Step 7

set qos-group qos-group-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set qos-group 31

Sets the QoS group identifiers on IPv4 or MPLS packets.

The set qos-group command is supported only on an ingress policy.

Step 8

set cos cos-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set cos 7

Sets the specific IEEE 802.1Q Layer 2 CoS value of an outgoing packet. Values are from 0 to7.

Sets the Layer 2 CoS value of an outgoing packet.

  • This command should be used by a router if a user wants to mark a packet that is being sent to a switch. Switches can leverage Layer 2 header information, including a CoS value marking.

  • Packets entering an interface cannot be set with a CoS value.

Step 9

set cos [ inner] cos-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set cos 7

Sets the specific IEEE 802.1Q Layer 2 CoS value of an outgoing packet. Values are from 0 to7.

Sets the Layer 2 CoS value of an outgoing packet.

  • This command should be used by a router if a user wants to mark a packet that is being sent to a switch. Switches can leverage Layer 2 header information, including a CoS value marking.

  • For Layer 2 interfaces, the set cos command:

    Is rejected on ingress or egress policies on a main interface.

    Is accepted but ignored on ingress policies on a subinterface.

    Is supported on egress policies on a subinterface.

  • For Layer 3 interfaces, the set cos command:

    Is ignored on ingress policies on a main interface.

    Is rejected on ingress policies on a subinterface.

    Is supported on egress policies on main interfaces and subinterfaces.

Step 10

set mpls experimental {imposition | topmost} exp-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set mpls experimental imposition 3

Sets the experimental value of the MPLS packet top-most or imposition labels.

Note

 
The imposition keyword can be used only in service policies that are attached in the ingress policy.

Step 11

set srp-priority priority-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set srp-priority 3

Sets the spatial reuse protocol (SRP) priority value of an outgoing packet.

Note

 
This command can be used only in service policies that are attached in the output direction of an interface.

Step 12

set discard-class discard-class-value

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set discard-class 3

Sets the discard class on IP Version 4 (IPv4) or Multiprotocol Label Switching (MPLS) packets.

Note

 
This command can be used only in service policies that are attached in the ingress policy.

Step 13

set atm-clp

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# set atm-clp

Sets the cell loss priority (CLP) bit.

Step 14

exit

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# exit

Returns the router to policy map configuration mode.

Step 15

exit

Example:


RP/0/RSP0/CPU0:router(config-pmap)# exit

Returns the router to global configuration mode.

Step 16

interface type interface-path-id

Example:


RP/0/RSP0/CPU0:router(config)# interface pos 0/2/0/0

Configures an interface and enters the interface configuration mode.

Step 17

service-policy {input | output]} policy-map

Example:


RP/0/RSP0/CPU0:router(config-if)# service-policy output policy1

Attaches a policy map to an input or output interface to be used as the service policy for that interface. In this example, the traffic policy evaluates all traffic leaving that interface.

Step 18

Use the commit or end command.

commit —Saves the configuration changes, and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration mode, without committing the configuration changes.

Step 19

show policy-map interface type interface-path-id [input | output]

Example:


RP/0/RSP0/CPU0:router# show policy-map interface pos 0/2/0/0

(Optional) Displays policy configuration information for all classes configured for all service policies on the specified interface.


Configuring QoS Policy Propagation Using Border Gateway Protocol

This section explains how to configure Policy Propagation Using Border Gateway Protocol (BGP) on a router based on BGP community lists, BGP autonomous system paths, access lists, source prefix address, or destination prefix address.

Policy Propagation Using BGP Configuration Task List

Policy propagation using BGP allows you to classify packets by IP precedence and/or QoS group ID, based on BGP community lists, BGP autonomous system paths, access lists, source prefix address and destination prefix address. After a packet has been classified, you can use other quality-of-service features such as weighted random early detection (WRED) to specify and enforce policies to fit your business model.

Overview of Tasks

To configure Policy Propagation Using BGP, perform these basic tasks:

  • Configure BGP and Cisco Express Forwarding (CEF). To configure BGP, see Cisco IOS XR Routing Configuration Guide . To configure CEF, see Cisco IOS XR IP Address and Services Configuration Guide .

  • Configure a BGP community list or access list.

  • Define the route policy. Set the IP precedence and/or QoS group ID, based on the BGP community list, BGP autonomous system path, access list, source prefix address or destination prefix address.

  • Apply the route policy to BGP.

  • Configure QPPB on the desired interfaces or configure QPPB on the GRE Tunnel interfaces.

  • Configure and enable a QoS Policy to use the above classification (IP precedence or QoS group ID). To configure committed access rate (CAR), WRED and tail drop, see the Configuring Modular QoS Congestion Avoidance on Cisco IOS XR Software module.

Defining the Route Policy

This task defines the route policy used to classify BGP prefixes with IP precedence or QoS group ID.

Prerequisites

Configure the BGP community list, or access list, for use in the route policy.

Restrictions
  • IPv4 and IPv6 QPPB with egress QoS policy is supported on all Ethernet and SIP-700 line cards.

  • IPv4 and IPv6 QPPB with ingress QoS policy is supported on the first generation ASR9000 Ethernet line cards.

SUMMARY STEPS

  1. configure
  2. route-policy name
  3. set qos-group qos-group-value
  4. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

route-policy name

Example:


RP/0/RSP0/CPU0:router(config)# route-policy r1

Enters route policy configuration mode and specifies the name of the route policy to be configured.

Step 3

set qos-group qos-group-value

Example:

RP/0/RSP0/CPU0:router(config-pmap-c)# set qos-group 30

Sets the QoS group identifiers. The set qos-group command is supported only on an ingress policy.

Step 4

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Applying the Route Policy to BGP

This task applies the route policy to BGP.

Prerequisites

Configure BGP and CEF.

SUMMARY STEPS

  1. configure
  2. router bgp as-number
  3. address-family { ipv4 | ipv6 } address-family-modifier
  4. table-policy policy-name
  5. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

router bgp as-number

Example:

RP/0/RSP0/CPU0:router(config)# router bgp 120

Enters BGP configuration mode.

Step 3

address-family { ipv4 | ipv6 } address-family-modifier

Example:

RP/0/RSP0/CPU0:router(config-bgp)# address-family ipv4 unicast

Enters address-family configuration mode, allowing you to configure an address family.

Step 4

table-policy policy-name

Example:

RP/0/RSP0/CPU0:router(config-bgp-af) # table-policy qppb a1

Configures the routing policy for installation of routes to RIB.

Step 5

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Configuring QPPB on the Desired Interfaces

This task applies QPPB to a specified interface. The traffic begins to be classified, based on matching prefixes in the route policy. The source or destination IP address of the traffic can be used to match the route policy.

SUMMARY STEPS

  1. configure
  2. interface type interface-path-id
  3. ipv4 | ipv6 bgp policy propagation input{ip-precedence|qos-group} {destination[ip-precedence {destination|source}] {source[ip-precedence {destination|source}]
  4. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

interface type interface-path-id

Example:


RP/0/RSP0/CPU0:router(config)# interface pos 0/2/0/0

Enters interface configuration mode and associates one or more interfaces to the VRF.

Step 3

ipv4 | ipv6 bgp policy propagation input{ip-precedence|qos-group} {destination[ip-precedence {destination|source}] {source[ip-precedence {destination|source}]

Example:


RP/0/RSP0/CPU0:router(config-if)# ipv4 bgp policy propagation input qos-group destination

Enables QPPB on an interface

Step 4

Use the commit or end command.

commit —Saves the configuration changes, and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration mode, without committing the configuration changes.

Configuring QPPB on the GRE Tunnel Interfaces

This task applies QPPB to a GRE tunnel interface. The traffic begins to be classified, based on matching prefixes in the route policy. The source or destination IP address of the traffic can be used to match the route policy.

SUMMARY STEPS

  1. configure
  2. interface tunnel-ipnumber
  3. ipv4 address ipv4-address subnet-mask
  4. ipv6 address ipv6-prefix/prefix-length
  5. ipv4 | ipv6 bgp policy propagation input{ip-precedence|qos-group} {destination[ip-precedence {destination|source}] {source[ip-precedence {destination|source}]
  6. tunnel source type path-id
  7. tunnel destination ip-address
  8. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

interface tunnel-ipnumber

Example:


RP/0/RSP0/CPU0:router(config)# interface tunnel-ip 4000

Enters interface configuration mode and associates one or more interfaces to the VRF.

Step 3

ipv4 address ipv4-address subnet-mask

Example:


RP/0/RSP0/CPU0:router(config-if)# ipv4 address 10.1.1.1 255.255.255.0

Assigns an IP address and subnet mask to the tunnel interface.

Step 4

ipv6 address ipv6-prefix/prefix-length

Example:


RP/0/RSP0/CPU0:router(config-if)# ipv6 address 100:1:1:1::1/64

Specifies an IPv6 network assigned to the interface.

Step 5

ipv4 | ipv6 bgp policy propagation input{ip-precedence|qos-group} {destination[ip-precedence {destination|source}] {source[ip-precedence {destination|source}]

Example:


RP/0/RSP0/CPU0:router(config-if)# ipv4 bgp policy propagation input qos-group destination

Enables QPPB on the GRE tunnel interface

Step 6

tunnel source type path-id

Example:


RP/0/RSP0/CPU0:router(config-if)# tunnel source TenGigE0/2/0/1

Specifies the source of the tunnel interface.

Step 7

tunnel destination ip-address

Example:


RP/0/RSP0/CPU0:router(config-if)# tunnel destination 100.100.100.20

Defines the tunnel destination.

Step 8

Use the commit or end command.

commit —Saves the configuration changes, and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration mode, without committing the configuration changes.

QPPB Scenario

Consider a scenario where in traffic is moving from Network1 to Network2 through (a single) router port1 and port2. If QPPB is enabled on port1, then

  • for qos on ingress: attach an ingress policy on the interface port1.

  • for qos on egress: attach an egress policy on interface port2.

Configuring Hierarchical Ingress Policing

SUMMARY STEPS

  1. configure
  2. policy-map policy-name
  3. class class-name
  4. service-policy policy-name
  5. police rate percent percentage
  6. conform-action action
  7. exceed-action action
  8. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

policy-map policy-name

Example:


RP/0/RSP0/CPU0:router(config)# policy-map parent

Creates or modifies a policy map that can be attached to one or more interfaces to specify a service policy and enters the policy map configuration mode.

Step 3

class class-name

Example:


RP/0/RSP0/CPU0:router(config-pmap)# class class-default

Specifies the name of the class whose policy you want to create or change and enters the policy map class configuration mode.

Step 4

service-policy policy-name

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# service-policy child

Specifies the service-policy as a QoS policy within a policy map.

Step 5

police rate percent percentage

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# police rate percent 50 	

Configures traffic policing and enters policy map police configuration mode.

Step 6

conform-action action

Example:


RP/0/RSP0/CPU0:router(config-pmap-c-police)# conform-action transmit

Configures the action to take on packets that conform to the rate limit. The allowed action is transmit that transmits the packets.

Step 7

exceed-action action

Example:


RP/0/RSP0/CPU0:router(config-pmap-c-police)# exceed-action drop

Configures the action to take on packets that exceed the rate limit. The allowed action is drop that drops the packet.

Step 8

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Configuring Policer Bucket Sharing

Perform these tasks to enable policer bucket sharing in both the egress and ingress directions.

SUMMARY STEPS

  1. configure
  2. class-map [ type qos] [ match-any] [ match-all] class-map-name
  3. match precedence[ number | name ]
  4. end-class-map
  5. class-map [ type qos] [ match-any] [ match-all] class-map-name
  6. match precedence[ number | name ]
  7. end-class-map
  8. policy-map [ type qos ] policy-name
  9. class class-name
  10. police bucket shared policer instance nameratevalue
  11. exit
  12. class class-name
  13. police bucket referred policer instance name
  14. exit
  15. end-policy-map
  16. interface type interface-path-id
  17. service-policy input policy-map
  18. service-policy output policy-map
  19. Use the commit or end command.

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Example:


RP/0/RSP0/CPU0:router# configure

Enters global configuration mode.

Step 2

class-map [ type qos] [ match-any] [ match-all] class-map-name

Example:


RP/0/RSP0/CPU0:router(config)# class-map class1

Creates a class map to be used for matching packets to the class specified and enters the class map configuration mode.

If you specify match-any , any one match criteria must be met for traffic entering the traffic class to be classified as part of the traffic class. This is the default. If you specify match-all , the traffic must match all match criteria.

Step 3

match precedence[ number | name ]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match precedence 5

Identifies IP precedence values as match criteria. The range is from 0 to 7. Reserved keywords can be specified, instead of numeric values.

Step 4

end-class-map

Example:


RP/0/RSP0/CPU0:router(config-cmap)# end-class-map

Ends the class map configuration.

Step 5

class-map [ type qos] [ match-any] [ match-all] class-map-name

Example:


RP/0/RSP0/CPU0:router(config)# class-map class2

Creates a class map to be used for matching packets to the class specified and enters the class map configuration mode.

If you specify match-any , any one match criteria must be met, for traffic entering the traffic class to be classified as part of the traffic class. This is the default. If you specify match-all , the traffic must match all match criteria.

Step 6

match precedence[ number | name ]

Example:


RP/0/RSP0/CPU0:router(config-cmap)# match precedence 1

Identifies IP precedence values as match criteria. The range is from 0 to 7. Reserved keywords can be specified, instead of numeric values.

Step 7

end-class-map

Example:


RP/0/RSP0/CPU0:router(config-cmap)# end-class-map

Ends the class map configuration.

Step 8

policy-map [ type qos ] policy-name

Example:


RP/0/RSP0/CPU0:router(config)# policy-map policy1

Creates or modifies a policy map that can be attached to one or more interfaces to specify a service policy and enters the policy map configuration mode.

Step 9

class class-name

Example:


RP/0/RSP0/CPU0:router(config-pmap)# class class1

Specifies the name of the class whose policy you want to create or change.

Step 10

police bucket shared policer instance nameratevalue

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# policer bucket shared policy1 rate 2Mbps

Defines and shares a policer bucket.

In this example, shared policer bucket policy1 is created to rate limit traffic at 2Mbps.

Step 11

exit

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# exit

Returns the router to policy map configuration mode.

Step 12

class class-name

Example:


RP/0/RSP0/CPU0:router(config-pmap)# class class2

Specifies the name of the class whose policy you want to create or change.

Step 13

police bucket referred policer instance name

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# policer bucket referred policy1

Refers a shared policer bucket.

In this example, policer bucket policy1 is referred.

Step 14

exit

Example:


RP/0/RSP0/CPU0:router(config-pmap-c)# exit

Returns the router to policy map configuration mode.

Step 15

end-policy-map

Example:


RP/0/RSP0/CPU0:router(config-pmap)# end-policy-map

Ends the policy map configuration.

Step 16

interface type interface-path-id

Example:


RP/0/RSP0/CPU0:router(config)# interface gigabitethernet 100/0/0/0

Configures an interface and enters the interface configuration mode.

Step 17

service-policy input policy-map

Example:


RP/0/RSP0/CPU0:router(config-if)# service-policy input policy1

Attaches a policy map to an input interface to be used as the service policy for that interface.

Step 18

service-policy output policy-map

Example:


RP/0/RSP0/CPU0:router(config-if)# service-policy output policy1

Attaches a policy map to an output interface to be used as the service policy for that interface.

Step 19

Use the commit or end command.

commit —Saves the configuration changes and remains within the configuration session.

end —Prompts user to take one of these actions:
  • Yes — Saves configuration changes and exits the configuration session.

  • No —Exits the configuration session without committing the configuration changes.

  • Cancel —Remains in the configuration session, without committing the configuration changes.

Overview of Multiple QoS Policy Support

In Cisco Common Classification Policy Language (C3PL), the order of precedence of a class in a policy is based on the position of the class in the policy, that is, the class-map configuration which appears first in a policy-map has higher precedence. Also, the actions to be performed by the classified traffic are defined inline rather than using action templates. As a result of these two characteristics, aggregated actions cannot be applied to traffic that matches different classes.

In order to overcome this limitation, the “Multiple QoS Policy Support” feature is introduced. This feature enables the users to apply aggregated actions to various classes of traffic and apply multiple QoS policies on an interface.

Use Case — Multiple QoS Policy Support

Consider a scenario where:

  • The classification rules must be applied at different precedence levels.

  • Each classification rule must be associated with non-queueing actions (that is, policing/marking).

  • Multiple classification rules at different precedence levels must be mapped to a traffic-class.

  • Each traffic-class or a group of traffic-classes must be associated with a single queue.

The figure below provides a detailed explanation of the above explained scenario—

In this example, if the traffic packet matches 2.2.2.10 or 1.1.1.0/24, then the traffic packet is forwarded to the queue that is associated with traffic-class 1. And if the traffic packet matches 1.1.1.10 or 2.2.2.0/24, then the traffic packet is forwarded to the queue that is associated with traffic class 2.

With the existing Modular Quality of Service, we have the following limitations in order to achieve the above mentioned requirement—

  1. Packets are matched in the order of precedence that is defined based on the position of the class-maps. There is no way to explicitly specify precedence for a class-map.

  2. A queuing action under a class-map in a policy-map, creates a queue for that class.

  3. Queues cannot be shared across class-maps.

These limitations can be overcome by separating classification from queuing. By doing this, it is possible to reorder the class-map from higher precedence to lower precedence and also share queues with multiple class-maps.

The example below depicts the implementation—

In this example, 4 classes A1, A2, B1, and B2 are created. Later, classification policies and queueing policies for these classes (A1, A2, B1, and B2) are created. After this, both the classification and queuing policies are applied to the interface. The detailed configuration steps are explained in the following section.

Configuring Multiple QoS Policy Support

In brief, configuring Multiple QoS policy support involves the following steps—

  1. Configure Class Map—In this procedure, the traffic classes are defined.
    /*Defining ACLs for Traffic Filtering*/
    ipv4 access-list acl-a1
     10 permit ipv4 host 2.2.2.10 any
    ipv4 access-list acl-b1
     10 permit ipv4 host 1.1.1.10 any
    ipv4 access-list acl-a2
     10 permit ipv4 1.1.1.0/24 any
    ipv4 access-list acl-b2
     10 permit ipv4 2.2.2.0/24 any
    !
    /*Creating Class Maps*/
    class-map match-any A1
     match access-group ipv4 acl-a1 
    class-map match-any B1
     match access-group ipv4 acl-b1 
    class-map match-any A2
     match access-group ipv4 acl-a2 
    class-map match-any B2
     match access-group ipv4 acl-b2 
    
    class-map match-any traffic-class-1
     match traffic-class 1
    class-map match-any traffic-class-2
     match traffic-class 2
    
  2. Configure Policy—In this procedure, the classification and the queuing policies are created.
    /*Creating Classification Policy*/
    policy-map classification-policy
    class A1
      set traffic-class 1  
     class B1
      set traffic-class 2 
    class A2
      set traffic-class 1
     class B2
      set traffic-class 2 
    class class-default
      
    !
    /*Creating Queuing Policy*/ 
    policy-map queue-parent
     class class-default
      service-policy queue-child
      shape average 50 mbps 
    policy-map queue-child
     class traffic-class-1
      bandwidth remaining percent 10  
     class traffic-class-2
      bandwidth remaining percent 20 
     ! 
     class class-default
     ! 
     end-policy-map
    
  3. Apply Multiple Services on an Interface—In this procedure, the classification and queuing policies are applied on the interface.
    /*Applying Policies on an Interface*/
    Interface TenGigE0/0/0/3/0
    service-policy output classification-policy
    service-policy output queue-parent
    

To summarize, two policies (classification and queuing policies) are applied in the Egress direction. The classification policy executes first and classifies traffic at different precedence levels and marks the traffic-class field. The queuing policy executes second, matches on the traffic-class field to select the queue. For traffic matching in different classification precedence to share the same queue, mark the traffic-class field with the same value.

Verification

The show qos interface interface-name output command displays:

  • per class per output policy QoS configuration values

  • queuing policy followed by the classification policy

  • traffic-classes matched by each class in queuing-policy

Router#show qos interface TenGigE 0/0/0/3/0 output
Interface: TenGigE0/0/0/3/0 output 
Bandwidth configured: 50000 kbps Bandwidth programed: 50000 kbps
ANCP user configured: 0 kbps ANCP programed in HW: 0 kbps
Port Shaper programed in HW: 50000 kbps 
Policy: queue-parent Total number of classes: 4
----------------------------------------------------------------------
Level: 0 Policy: queue-parent Class: class-default
Matches: traffic-classes : { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63,} and no traffic-class
QueueID: N/A
Shape CIR : NONE
Shape PIR Profile : 8 (Grid) Scale: 134 PIR: 49920 kbps  PBS: 624000 bytes
WFQ Profile: 3/9 Committed Weight: 10 Excess Weight: 10
Bandwidth: 0 kbps, BW sum for Level 0: 0 kbps, Excess Ratio: 1
----------------------------------------------------------------------
Level: 1 Policy: queue-child Class: traffic-class-1
Matches: traffic-classes : { 1}
Parent Policy: queue-parent Class: class-default
QueueID: 1040402 (Priority Normal)
Queue Limit: 66 kbytes Abs-Index: 19 Template: 0 Curve: 0
Shape CIR Profile: INVALID
WFQ Profile: 3/19 Committed Weight: 20 Excess Weight: 20
Bandwidth: 0 kbps, BW sum for Level 1: 0 kbps, Excess Ratio: 10
----------------------------------------------------------------------
Level: 1 Policy: queue-child Class: traffic-class-2
Matches: traffic-classes : {2}
Parent Policy: queue-parent Class: class-default
QueueID: 1040403 (Priority Normal)
Queue Limit: 126 kbytes Abs-Index: 29 Template: 0 Curve: 0
Shape CIR Profile: INVALID
WFQ Profile: 3/39 Committed Weight: 40 Excess Weight: 40
Bandwidth: 0 kbps, BW sum for Level 1: 0 kbps, Excess Ratio: 20
----------------------------------------------------------------------
Level: 1 Policy: queue-child Class: class-default
Matches: traffic-classes : { 0, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63,} and no traffic-class
Parent Policy: queue-parent Class: class-default
QueueID: 1040404 (Priority Normal)
Queue Limit: 446 kbytes Abs-Index: 52 Template: 0 Curve: 0
Shape CIR Profile: INVALID
WFQ Profile: 3/98 Committed Weight: 139 Excess Weight: 139
Bandwidth: 0 kbps, BW sum for Level 1: 0 kbps, Excess Ratio: 70
----------------------------------------------------------------------
Interface: TenGigE0/0/0/3/0 output 
Bandwidth configured: 10000000 kbps Bandwidth programed: 10000000 kbps
ANCP user configured: 0 kbps ANCP programed in HW: 0 kbps
Port Shaper programed in HW: 0 kbps 
Policy: classification-policy Total number of classes: 5
----------------------------------------------------------------------
Level: 0 Policy: classification-policy Class: A1
Set traffic-class : 1
QueueID: 0 (Port Default)
Policer Profile: 59 (Single)
Conform: 100000 kbps (100 mbps) Burst: 1250000 bytes (0 Default)
Child Policer Conform: TX
Child Policer Exceed: DROP
Child Policer Violate: DROP
----------------------------------------------------------------------
Level: 0 Policy: classification-policy Class: B1
Set traffic-class : 2
QueueID: 0 (Port Default)
Policer Profile: 60 (Single)
Conform: 200000 kbps (200 mbps) Burst: 2500000 bytes (0 Default)
Child Policer Conform: TX
Child Policer Exceed: DROP
Child Policer Violate: DROP
----------------------------------------------------------------------
Level: 0 Policy: classification-policy Class: A2
Set traffic-class : 1
QueueID: 0 (Port Default)
Policer Profile: 61 (Single)
Conform: 300000 kbps (300 mbps) Burst: 3750000 bytes (0 Default)
Child Policer Conform: TX
Child Policer Exceed: DROP
Child Policer Violate: DROP
----------------------------------------------------------------------
Level: 0 Policy: classification-policy Class: B2
Set traffic-class : 2
QueueID: 0 (Port Default)
Policer Profile: 62 (Single)
Conform: 400000 kbps (400 mbps) Burst: 5000000 bytes (0 Default)
Child Policer Conform: TX
Child Policer Exceed: DROP
Child Policer Violate: DROP
----------------------------------------------------------------------
Level: 0 Policy: classification-policy Class: class-default
QueueID: 0 (Port Default)
----------------------------------------------------------------------

Restrictions for Multiple QoS Policy Support

Policy Classification Restrictions

  • Classification policy must always be executed before the queuing policy. Also, queuing actions are not supported within a classification policy.

  • Classification policy supports unconditional set traffic-class actions. The valid values for set traffic-class are 0 – 63.

  • In a conditional policer action, set traffic-class action is not supported.

  • At least one set traffic-class action must be present for a policy to be considered a classification policy in the multi policy context.

  • Only two additional packet fields can be unconditionally set along with set traffic-class.

  • Class-maps in a classification policy cannot be used to match on traffic-class.

  • Only one set traffic-class action is permitted in a hierarchy (either parent or child).

  • Flow aware and shared policers are not supported.

  • In a three-level policy, set traffic-class action is permitted only at the lowest two-levels.

  • In a policer action, conditional set traffic-class is not supported.

Queuing Policy Restrictions

  • Queuing policy can only classify on traffic-class field.

    • Valid values for match traffic-class are 0-63.

    • Class-maps can match up to 8 discreet traffic-class values or traffic-class ranges.

  • At least one class-map with match traffic-class must be present for a policy to be considered a queuing policy in the multiple qos policy support feature.

  • Class-map with match not traffic-class is not supported.

  • Non-queuing actions like policer and set are not supported.

  • Since policer is not supported in queuing policy, when priority level 1 queue is used, the service rate computed for lower priority queues is very low (with priority 1 utilizing all the bandwidth, the bandwidth remaining for lower priority queues is very low). Due to the same reason, minimum bandwidth is also not be supported with priority level 1. However, bandwidth remaining ratio may be used instead of minimum bandwidth. Since the default queue-limit and time based queue-limit configurations use service-rate to calculate queue-limit in bytes, it is recommended to explicitly configure queue-limit in bytes when using priority 1 queue.

Applying Multiple Services on an Interface Restrictions

  • Applying multiple polices is supported only when one policy is a classification policy and the other policy is a queuing policy.

  • Applying multiple polices (not more than 2 policies) is supported only in the egress direction. Applying more than 1 policy in the ingress direction is not supported.

  • Applying multiple policies is supported only on the following interfaces:

    • Main-interface

    • Sub-interface

    • Bundle interface

    • Bundle sub-interface

  • Applying Multi policies is not supported on the following interfaces:

    • PWHE

    • GRE

    • BVI

    • Satellite interfaces

  • Multi policies are only supported on Cisco ASR 9000 High Density 100GE Ethernet line cards, Cisco ASR 9000 Enhanced Ethernet line cards, and Cisco ASR 9000 Ethernet line cards.

  • The same classification policy cannot be applied with different queuing policies on a different interface of the same line card.

  • Classification policy and queuing policy cannot be applied with any of the following feature options

    • account

    • service-fragment-parent

    • shared-policy-instance

    • subscriber-parent

Policy Combinations

The different policy combinations are displayed in the below table:

Policies Already Applied on the Interface

Policies that are yet to be Applied on the Interface

Accepted

Regular Policy (no set/match traffic-class)

Classification Policy

Queuing Policy

Regular Policy (no set/match traffic-class)

Classification Policy

Queuing Policy

Yes

No

No

Any combination

No

No

Yes

No

No

No

No

No

No

No

No

No

Yes

No

No

No

No

No

Yes

Yes

No

Yes

Yes

No

No

Yes

Yes

No

No

No

Yes

No

Yes

No

Yes

Yes

Yes

No

No

No

No

Yes

No

No

Yes

Yes

No

No

Yes

Yes

No

No

Yes

Yes

Any combination

No


Note


To change a policy to a different policy of the same type you must first remove the existing policy and then apply the new policy.


Multi Policy and Interface Hierarchy

Multi Policy and Interface Hierarchy is displayed in the below table:

Main/Bundle Interface Sub/Bundle Sub Interface Comments

Regular Policy (no set/match traffic-class)

Classification Policy

Queuing Policy

Regular Policy

Classification Policy

Queuing Policy

Non Port Shaper Policy

No

No

No policy allowed on child interfaces

The policy is enabled and is inherited by all the child interfaces. The same policy executes on the main interface and all its child interface traffic.

No

Yes

No

No policy allowed on child interfaces

Policy is disabled

No

Yes

No

No policy allowed on child interfaces

Policy is disabled

No

Yes

Yes

No policy allowed on child interfaces

Both policies are enabled and are inherited by all the child interfaces. The classification policy is executed first, followed by the queuing policy on the main interface and all its child interface traffic.

Port Shaper Policy

No

No

Yes

No

No

Main interface policy enabled.

Sub interface policy is enabled and uses the port shaper rate as the reference bandwidth.

If port shaper is applied after sub interface policy, then the applied sub interface policy will be updated with the new reference bandwidth. If the port shaper rate is lower than any sub interface policy rate, then the port shaper policy is rejected.

No

Yes

No

Main interface policy enabled. Sub interface policy is disabled

No

No

Yes

Main interface policy enabled. Sub interface policy is disabled

No

Yes

Yes

Main interface policy enabled.

Both the sub interface policies are enabled and both the policies use the port shaper rate as the reference bandwidth.

If port shaper is applied after sub interface policies, then both the applied sub interface policies will be updated with the new reference bandwidth. If the port shaper rate is lower than any sub interface policy rate, then the port shaper policy is rejected.

Non port shaper policy not allowed on main interface

Yes