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CLI-based Configuration Guide - QoS

AR100-S, AR110-S, AR120-S, AR150-S, AR160-S, AR200-S, AR1200-S, AR2200-S, and AR3200-S V200R009

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Configuring MQC to Implement Traffic Shaping

Configuring MQC to Implement Traffic Shaping

Background

Modular QoS command-Line interface (MQC) can implement traffic shaping for a specific type of traffic using a traffic policy. A traffic policy can be applied to different interfaces. When the rate of packets matching the specified traffic classifier exceeds the rate limit, the device buffers the excess packets. When there are sufficient tokens in the token bucket, the device forwards the buffered packets at an even rate. When the buffer queue is full, the device discards the buffered packets. MQC-based traffic shaping enables the device to identify different service flows using traffic classifiers and provide differentiated services on a per flow basis.

A traffic policy containing a traffic shaping behavior can be applied to the outbound direction on a WAN interface and layer 2 VE interface.

Procedure

  1. Configure a traffic classifier.
    1. Run system-view

      The system view is displayed.

    2. Run traffic classifier classifier-name [ operator { and | or } ]

      A traffic classifier is created and the traffic classifier view is displayed.

      and indicates that rules are ANDed with each other.
      • If a traffic classifier contains ACL rules, packets match the traffic classifier only when they match one ACL rule and all the non-ACL rules.

      • If a traffic classifier does not contain ACL rules, packets match the traffic classifier only when the packets match all the non-ACL rules.

      or indicates that the relationship between rules is OR. Packets match a traffic classifier as long as packets match only one rule of the traffic classifier.

      By default, the relationship between rules in a traffic classifier is OR.

    3. Run the following commands as required.

      Matching Rule

      Command

      Outer VLAN ID

      if-match vlan-id start-vlan-id [ to end-vlan-id ]

      Inner VLAN IDs in QinQ packets

      if-match cvlan-id start-vlan-id [ to end-vlan-id ]

      802.1p priority in VLAN packets

      if-match 8021p 8021p-value &<1-8>

      Inner 802.1p priority in QinQ packets

      if-match cvlan-8021p 8021p-value &<1-8>

      EXP priority in MPLS packets (AR1200-S series, AR2200-S series and AR3200-S series)

      if-match mpls-exp exp-value &<1-8>

      Destination MAC address

      if-match destination-mac mac-address [ mac-address-mask mac-address-mask ]

      Source MAC address

      if-match source-mac mac-address [ mac-address-mask mac-address-mask ]

      DLCI value in FR packets

      if-match dlci start-dlci-number [ to end-dlci-number ]

      DE value in FR packets

      if-match fr-de

      Protocol type field encapsulated in the Ethernet frame header

      if-match l2-protocol { arp | ip | mpls | rarp | protocol-value }

      All packets

      if-match any

      DSCP priority in IP packets

      if-match [ ipv6 ] dscp dscp-value &<1-8>
      NOTE:

      If DSCP priority matching is configured in a traffic policy, the SAE220 (WSIC) and SAE550 (XSIC) cards do not support redirect ip-nexthop ip-address post-nat.

      IP precedence in IP packets

      if-match ip-precedence ip-precedence-value &<1-8>
      NOTE:

      if-match [ ipv6 ] dscp and if-match ip-precedence cannot be configured simultaneously in a traffic classifier where the relationship between rules is AND.

      Layer 3 protocol type

      if-match protocol { ip | ipv6 }

      QoS group index of packets

      if-match qos-group qos-group-value

      IPv4 packet length

      if-match packet-length min-length [ to max-length ]

      PVC information in ATM packets

      if-match pvc vpi-number/vci-number

      RTP port number

      if-match rtp start-port start-port-number end-port end-port-number

      SYN Flag in the TCP packet header

      if-match tcp syn-flag { ack | fin | psh | rst | syn | urg } *

      Inbound interface

      if-match inbound-interface interface-type interface-number

      Outbound interface

      if-match outbound-interface Cellular interface-number:channel

      ACL rule

      if-match acl { acl-number | acl-name }
      NOTE:
      • Before defining a matching rule for traffic classification based on an ACL, create the ACL.

      • To use an ACL in a traffic classifier to match the source IP address, run the qos pre-nat command on an interface to configure NAT pre-classification. NAT pre-classification enables the NAT-enabled device to carry the private IP address before translation on the outbound interface so that the NAT-enabled device can classify IP packets based on private IP addresses and provide differentiated services.

      ACL6 rule

      if-match ipv6 acl { acl-number | acl-name }
      NOTE:
      • Before defining a matching rule for traffic classification based on an ACL, create the ACL.

      • To use an ACL in a traffic classifier to match the source IP address, run the qos pre-nat command on an interface to configure NAT pre-classification. NAT pre-classification enables the NAT-enabled device to carry the private IP address before translation on the outbound interface so that the NAT-enabled device can classify IP packets based on private IP addresses and provide differentiated services.

      Application protocol

      if-match application application-name [ user-set user-set-name ] [ time-range time-name ]

      NOTE:

      Before defining a matching rule based on an application protocol, enable Smart Application Control (SA) and load the signature file.

      SA group

      if-match category category-name [ user-set user-set-name ] [ time-range time-name ]

      NOTE:
      • Before defining a matching rule based on an application protocol, enable Smart Application Control (SA) and load the signature file.

      User group

      if-match user-set user-set-name [ time-range time-range-name ]

    4. Run quit

      Exit from the traffic classifier view.

  2. Configure a traffic behavior.
    1. Run traffic behavior behavior-name

      A traffic behavior is created and its view is displayed.

    2. Run gts cir { cir-value [ cbs cbs-value ] | pct pct-value } [ queue-length queue-length ]

      Traffic shaping is configured.

    3. (Optional) Run statistic enable

      Traffic statistics collection is enabled.

    4. Run quit

      Exit from the traffic behavior view.

    5. (Optional) Run qos overhead layer { link | physics }

      A mode is specified for calculating packet lengths during traffic policing or traffic shaping.

      By default, the system counts the physical-layer and link-layer compensation information in packet lengths during traffic policing or traffic shaping.

    6. Run quit

      Exit from the system view.

  3. Configure a traffic policy.
    1. Run system-view

      The system view is displayed.

    2. Run traffic policy policy-name

      A traffic policy is created and the traffic policy view is displayed, or the view of an existing traffic policy is displayed.

      By default, no traffic policy is created in the system.

    3. Run classifier classifier-name behavior behavior-name [ precedence precedence-value ]

      A traffic behavior is bound to a traffic classifier in a traffic policy.

      By default, no traffic classifier or traffic behavior is bound to a traffic policy.

    4. Run quit

      Exit from the traffic policy view.

    5. Run quit

      Exit from the system view.

  4. Apply the traffic policy.
    • Apply the traffic policy to an interface.

      1. Run system-view

        The system view is displayed.

      2. Run interface interface-type interface-number[.subinterface-number ]

        The interface view is displayed.

      3. Run traffic-policy policy-name { inbound | outbound }

        The traffic policy is applied to the inbound or outbound direction on the interface.

        By default, no traffic policy is applied to an interface.

    • Apply the traffic policy to an interzone.

      Only the AR100-S&AR110-S&AR120-S&AR150-S&AR200-S series routers support this configuration.

      1. Run system-view

        The system view is displayed.

      2. Run firewall interzone zone-name1 zone-name2

        An interzone is created and the interzone view is displayed.

        By default, no interzone is created.

        You must specify two existing zones for the interzone.

      3. Run traffic-policy policy-name

        The traffic policy is bound to the interzone.

        By default, no traffic policy is bound to an interzone.

    • Apply the traffic policy to a BD.

      Only the AR100-S&AR110-S&AR120-S&AR150-S&AR200-S&AR1200-S series routers support this configuration.

      1. Run system-view

        The system view is displayed.

      2. Run bridge-domain bd-id

        A BD is created and the BD view is displayed.

        By default, no BD is created.

      3. Run traffic-policy policy-name { inbound | outbound }

        The traffic policy is applied to the BD.

        By default, no traffic policy is applied to a BD.

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Updated: 2019-12-27

Document ID: EDOC1000174115

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