Contents

Frame Relay Queueing and Fragmentation at the Interface

The Frame Relay Queueing and Fragmentation at the Interface feature introduces support for low-latency queueing (LLQ) and FRF.12 end-to-end fragmentation on a Frame Relay interface.

Finding Feature Information

Your software release may not support all the features documented in this module. For the latest caveats and feature information, see Bug Search Tool and the release notes for your platform and software release. To find information about the features documented in this module, and to see a list of the releases in which each feature is supported, see the feature information table at the end of this module.

Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/​go/​cfn. An account on Cisco.com is not required.

Prerequisites for Frame Relay Queueing and Fragmentation at the Interface

The tasks in this document assume that you know how to configure low-latency queueing and shaping service policies.

The following prerequisites are specific to the Cisco 7500 series:

  • The Frame Relay Queueing and Fragmentation at the Interface feature is supported on VIP-based interfaces with VIP2-50 or higher.

  • Distributed Cisco Express Forwarding (dCEF) must be enabled both globally and on the Frame Relay interface.

Restrictions for Frame Relay Queueing and Fragmentation at the Interface

  • Interface fragmentation and Frame Relay traffic shaping cannot be configured at the same time.

  • Interface fragmentation and class-based fragmentation cannot be configured at the same time.

  • Frame Relay switched virtual circuits (SVCs) are not supported.

  • Hierarchical shaping and multiple shapers are not supported.

Information About Frame Relay Queueing and Fragmentation at the Interface

The Frame Relay Queueing and Fragmentation at the Interface feature simplifies the configuration of low-latency, low-jitter quality of service (QoS) by enabling the queueing policy and fragmentation configured on the main interface to apply to all permanent virtual circuits (PVCs) and subinterfaces under that interface. Before the introduction of this feature, queueing and fragmentation had to be configured on each individual PVC. Subrate shaping can also be configured on the interface.

How Frame Relay Queueing and Fragmentation at the Interface Works

When FRF.12 end-to-end fragmentation is enabled on an interface, all PVCs on the main interface and its subinterfaces will have fragmentation enabled with the same configured fragment size. To maintain low latency and low jitter for high-priority traffic, the configured fragment size must be greater than the largest high-priority frames. This configuration will prevent high-priority traffic from being fragmented and queued behind lower-priority fragmented frames. If the size of a high-priority frame is larger than the configured fragment size, the high-priority frame will be fragmented. Local Management Interface (LMI) traffic will not be fragmented and is guaranteed its required bandwidth.

When a low-latency queueing policy map is applied to the interface, traffic through the interface is identified using class maps and is directed to the appropriate queue. Time-sensitive traffic such as voice should be classified as high priority and will be queued on the priority queue. Traffic that does not fall into one of the defined classes will be queued on the class-default queue. Frames from the priority queue and class queues are subject to fragmentation and interleaving. As long as the configured fragment size is larger than the high-priority frames, the priority queue traffic will not be fragmented and will be interleaved with fragmented frames from other class queues. This approach provides the highest QoS transmission for priority queue traffic. The figure below illustrates the interface queueing and fragmentation process.

Figure 1. Frame Relay Queueing and Fragmentation at the Interface

Subrate shaping can also be applied to the interface, but interleaving of high-priority frames will not work when shaping is configured. If shaping is not configured, each PVC will be allowed to send bursts of traffic up to the physical line rate.

When shaping is configured and traffic exceeds the rate at which the shaper can send frames, the traffic is queued at the shaping layer using fair queueing. After a frame passes through the shaper, the frame is queued at the interface using whatever queueing method is configured. If shaping is not configured, then queueing occurs only at the interface.


Note


For interleaving to work, both fragmentation and the low-latency queueing policy must be configured with shaping disabled.


The Frame Relay Queueing and Fragmentation at the Interface feature supports the following functionality:

  • Voice over Frame Relay

  • Weighted Random Early Detection

  • Frame Relay payload compression


Note


When payload compression and Frame Relay fragmentation are used at the same time, payload compression is always performed before fragmentation.


  • IP header compression

Benefits of Frame Relay Queueing and Fragmentation at the Interface

Simple Configuration

The Frame Relay Queueing and Fragmentation at the Interface feature allows fragmentation, low-latency queueing, and subrate shaping to be configured on a Frame Relay interface queue. The fragmentation and queueing and shaping policy will apply to all PVCs and subinterfaces under the main interface, eliminating the need to configure QoS on each PVC individually.

Flexible Bandwidth

This feature allows PVCs to preserve the logical separation of traffic from different services while reducing bandwidth partitioning between PVCs. Each PVC can send bursts of traffic up to the interface shaping rate or, if shaping is not configured, the physical interface line rate.

How to Configure Frame Relay Queueing and Fragmentation at the Interface

Configuring Class Policy for the Priority Queue

To configure a policy map for the priority class, use the following commands beginning in global configuration mode:

SUMMARY STEPS

    1.    enable

    2.    configure terminal

    3.    policy-map policy-map

    4.    class class-name

    5.    Router(config-pmap-c)# priority bandwidth-kbps

    6.    exit


DETAILED STEPS
     Command or ActionPurpose
    Step 1 enable


    Example:
    Router> enable
     

    Enables privileged EXEC mode.

    • Enter your password if prompted.

     
    Step 2 configure terminal


    Example:
    Router# configure terminal
     

    Enters global configuration mode.

     
    Step 3 policy-map policy-map


    Example:
    Router(config) policy-map policy1
     

    Specifies the name of the policy map to be created or modified.

    • Use this command to define the queueing policy for the priority queue.

     
    Step 4 class class-name


    Example:
    Router(config-pmap)# class c1
     

    Specifies the name of a class to be created and included in the service policy.

    • The class name that you specify in the policy map defines the characteristics for that class and its match criteria as configured using the class-map command.

     
    Step 5 Router(config-pmap-c)# priority bandwidth-kbps

    Example:
    Router(config-pmap-c)# priority 30
     

    Creates a strict priority class and specifies the amount of bandwidth, in kbps, to be assigned to the class.

     
    Step 6 exit


    Example:
    Router(config-pmap-c)# exit
     

    Exits the current configuration mode.

     

    Configuring Class Policy for the Bandwidth Queues

    To configure a policy map and create class policies that make up the service policy, use the following commands beginning in global configuration mode:

    SUMMARY STEPS

      1.    enable

      2.    configure terminal

      3.    policy-map policy-map

      4.    class class-name

      5.    Router(config-pmap-c)# bandwidth bandwidth-kbps

      6.    exit


    DETAILED STEPS
       Command or ActionPurpose
      Step 1 enable


      Example:
      Router> enable
       

      Enables privileged EXEC mode.

      • Enter your password if prompted.

       
      Step 2 configure terminal


      Example:
      Router# configure terminal
       

      Enters global configuration mode.

       
      Step 3 policy-map policy-map


      Example:
      Router(config)# policy-map policy1
       

      Specifies the name of the policy map to be created or modified.

      • Use this command to define the queueing policy for the priority queue.

      • The bandwidth queues and the priority queue use the same policy map.

       
      Step 4 class class-name


      Example:
      Router(config-pmap)# class c1
       

      Specifies the name of a class to be created and included in the service policy.

      • The class name that you specify in the policy map defines the characteristics for that class and its match criteria as configured using the class-mapcommand.

       
      Step 5 Router(config-pmap-c)# bandwidth bandwidth-kbps

      Example:
      Router(config-pmap-c)# bandwidth 10
       

      Specifies the amount of bandwidth to be assigned to the class, in kbps, or as a percentage of the available bandwidth. Bandwidth must be specified in kbps or as a percentage consistently across classes. (Bandwidth of the priority queue must be specified in kbps.)

      • The sum of all bandwidth allocation on an interface cannot exceed 75 percent of the total available interface bandwidth. However, if you need to configure more than 75 percent of the interface bandwidth to classes, you can override the 75 percent maximum by using the max-reserved-bandwidth command.

       
      Step 6 exit


      Example:
      Router(config-pmap-c)# exit
       

      Exits the current configuration mode.

       

      Configuring the Shaping Policy Using the Class-Default Class

      In general, the class-default class is used to classify traffic that does not fall into one of the defined classes. Even though the class-default class is predefined when you create the policy map, you still have to configure it. If a default class is not configured, traffic that does not match any of the configured classes is given best-effort treatment, which means that the network will deliver the traffic if it can, without any assurance of reliability, delay prevention, or throughput.

      If you configure shaping in addition to queueing on the interface, use the class-default class to configure the shaping policy. The shaping policy will serve as the parent in a hierarchical traffic policy. The queueing policy will serve as the child policy. The class-default class is used for the shaping policy so that all traffic for the entire interface is shaped and a bandwidth-limited stream can be created.

      To configure the shaping policy in the class-default class, use the following commands beginning in global configuration mode:

      SUMMARY STEPS

        1.    enable

        2.    configure terminal

        3.    policy-map policy-map

        4.    class class-default

        5.    shape [average | peak] mean-rate [[burst-size] [excess-burst-size]]

        6.    service-policy policy-map-name

        7.    exit


      DETAILED STEPS
         Command or ActionPurpose
        Step 1 enable


        Example:
        Router> enable
         

        Enables privileged EXEC mode.

        • Enter your password if prompted.

         
        Step 2 configure terminal


        Example:
        Router# configure terminal
         

        Enters global configuration mode.

         
        Step 3 policy-map policy-map


        Example:
        Router(config)# policy-map policy1
         

        Specifies the name of the policy map to be created or modified.

        • Use this command to define the shaping policy.

         
        Step 4 class class-default


        Example:
        Router(config-pmap)# class class-default
         

        Specifies the default class so that you can configure or modify its policy.

         
        Step 5 shape [average | peak] mean-rate [[burst-size] [excess-burst-size]]


        Example:
        Router(config-pmap-c)# shape peak 10
         

        (Optional) Shapes traffic to the indicated bit rate according to the algorithm specified.

         
        Step 6 service-policy policy-map-name


        Example:
        Router(config-pmap-c)# service-policy policy1
         

        Specifies the name of a policy map to be used as a matching criterion (for nesting traffic policies [hierarchical traffic policies] within one another).

        • Use this command to attach the policy map for the priority queue (the child policy) to the shaping policy (the parent policy).

         
        Step 7 exit


        Example:
        Router(config-pmap-c)# exit
         

        Exits the current configuration mode.

         

        Configuring Queueing and Fragmentation on the Frame Relay Interface

        To configure low-latency queueing and FRF.12 end-to-end fragmentation on a Frame Relay interface, use the following commands beginning in global configuration mode:

        SUMMARY STEPS

          1.    enable

          2.    configure terminal

          3.    interface type / number

          4.    encapsulation frame-relay

          5.    service-policy output policy-map-name

          6.    frame-relay fragment fragment-size end-to-end

          7.    exit


        DETAILED STEPS
           Command or ActionPurpose
          Step 1 enable


          Example:
          Router> enable
           

          Enables privileged EXEC mode.

          • Enter your password if prompted.

           
          Step 2 configure terminal


          Example:
          Router# configure terminal
           

          Enters global configuration mode.

           
          Step 3 interface type / number


          Example:
          Router(config)# interface fe 0/0
           

          Configures an interface type and enters interface configuration mode.

           
          Step 4 encapsulation frame-relay


          Example:
          Router(config-if)# encapsulation frame-relay
           

          Enables Frame Relay encapsulation.

           
          Step 5 service-policy output policy-map-name


          Example:
          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.

          • If shaping is being used, use this command to attach the shaping policy (which includes the nested queueing policy) to the interface.

          • Interleaving of high-priority frames will not work if shaping is configured on the interface.

          • If shaping is not being used, use this command to attach the queueing policy to the interface.

           
          Step 6 frame-relay fragment fragment-size end-to-end


          Example:
          Router(config-if)# frame-relay fragment 100 end-to-end
           

          Enables fragmentation of Frame Relay frames.

          • To maintain low latency and low jitter for priority queue traffic, configure the fragment size to be greater than the largest high-priority frame that would be expected.

           
          Step 7 exit


          Example:
          Router(config-if)#
           
          exit
           

          Exits the current configuration mode.

           

          Verifying Frame Relay Queueing and Fragmentation at the Interface

          To verify the configuration and performance of Frame Relay queueing and fragmentation at the interface, perform the following steps:

          SUMMARY STEPS

            1.    Enter the show running-config command to verify the configuration.

            2.    Enter the show policy-map interface command to display low-latency queueing information, packet counters, and statistics for the policy map applied to the interface. Compare the values in the "packets" and the "pkts matched" counters; under normal circumstances, the "packets" counter is much larger than the "pkts matched" counter. If the values of the two counters are nearly equal, then the interface is receiving a large number of process-switched packets or is heavily congested.

            3.    Enter the show interfaces serialcommand to display information about the queueing strategy, priority queue interleaving, and type of fragmentation configured on the interface. You can determine whether the interface has reached a congestion condition and packets have been queued by looking at the "Conversations" fields. A nonzero value for "max active" counter shows whether any queues have been active. If the "active" counter is a nonzero value, you can use the show queue command to view the contents of the queues.


          DETAILED STEPS
            Step 1   Enter the show running-config command to verify the configuration.

            Example:
            Router# show running-config
            Building configuration...
            .
            .
            .
            class-map match-all voice
              match ip precedence 5
            !       
            !policy-map llq
              class voice
                priority 64
            policy-map shaper
              class class-default
               shape peak 96000
               service-policy llq
            !
            !interface Serial1/1
             ip address 16.0.0.1 255.255.255.0
             encapsulation frame-relay
             service-policy output shaper
             frame-relay fragment 80 end-to-end
            !
            
            Step 2   Enter the show policy-map interface command to display low-latency queueing information, packet counters, and statistics for the policy map applied to the interface. Compare the values in the "packets" and the "pkts matched" counters; under normal circumstances, the "packets" counter is much larger than the "pkts matched" counter. If the values of the two counters are nearly equal, then the interface is receiving a large number of process-switched packets or is heavily congested.

            The following sample output for the show policy-map interface command is based on the configuration in Step 1:



            Example:
            Router# show policy-map interface serial 1/1
             Serial1/1 
              Service-policy output:shaper
                Class-map:class-default (match-any)
                  12617 packets, 1321846 bytes
                  5 minute offered rate 33000 bps, drop rate 0 bps
                  Match:any 
                  Traffic Shaping
                       Target/Average   Byte   Sustain   Excess    Interval  Increment
                         Rate           Limit  bits/int  bits/int  (ms)      (bytes)  
                       192000/96000     1992   7968      7968      83        1992     
                    Adapt  Queue     Packets   Bytes     Packets   Bytes     Shaping
                    Active Depth                         Delayed   Delayed   Active
                    -      0         12586     1321540   0         0         no
                  Service-policy :llq
                    Class-map:voice (match-all)
                      3146 packets, 283140 bytes
                      5 minute offered rate 7000 bps, drop rate 0 bps
                      Match:ip precedence 1 
                      Weighted Fair Queueing
                        Strict Priority
                        Output Queue:Conversation 24 
                        Bandwidth 64 (kbps) Burst 1600 (Bytes)
                        (pkts matched/bytes matched) 0/0
                        (total drops/bytes drops) 0/0
                    Class-map:class-default (match-any)
                      9471 packets, 1038706 bytes
                      5 minute offered rate 26000 bps
                      Match:any 
            
            Step 3   Enter the show interfaces serialcommand to display information about the queueing strategy, priority queue interleaving, and type of fragmentation configured on the interface. You can determine whether the interface has reached a congestion condition and packets have been queued by looking at the "Conversations" fields. A nonzero value for "max active" counter shows whether any queues have been active. If the "active" counter is a nonzero value, you can use the show queue command to view the contents of the queues.

            The following sample output for the show interfaces serialcommand is based on the configuration in Step 1:



            Example:
            Router# show interfaces serial 1/1
            Serial1/1 is up, line protocol is up 
              Hardware is M4T
              Internet address is 16.0.0.1/24
              MTU 1500 bytes, BW 1544 Kbit, DLY 20000 usec, 
                 reliability 255/255, txload 5/255, rxload 1/255
              Encapsulation FRAME-RELAY, crc 16, loopback not set
              Keepalive set (10 sec)
              Restart-Delay is 0 secs
              LMI enq sent  40, LMI stat recvd 40, LMI upd recvd 0, DTE LMI up
              LMI enq recvd 0, LMI stat sent  0, LMI upd sent  0
              LMI DLCI 1023  LMI type is CISCO  frame relay DTE
              Fragmentation type:end-to-end, size 80, PQ interleaves 0
              Broadcast queue 0/64, broadcasts sent/dropped 0/0, interface broadcasts 0
              Last input 00:00:03, output 00:00:00, output hang never
              Last clearing of "show interface" counters 00:06:34
              Input queue:0/75/0/0 (size/max/drops/flushes); Total output drops:0
              Queueing strategy:weighted fair
              Output queue:0/1000/64/0 (size/max total/threshold/drops) 
                 Conversations  0/1/256 (active/max active/max total)
                 Reserved Conversations 0/0 (allocated/max allocated)
                 Available Bandwidth 1158 kilobits/sec
              5 minute input rate 0 bits/sec, 0 packets/sec
              5 minute output rate 33000 bits/sec, 40 packets/sec
                 40 packets input, 576 bytes, 0 no buffer
                 Received 0 broadcasts, 0 runts, 0 giants, 0 throttles
                 0 input errors, 0 CRC, 0 frame, 0 overrun, 0 ignored, 0 abort
                 15929 packets output, 1668870 bytes, 0 underruns
                 0 output errors, 0 collisions, 0 interface resets
                 0 output buffer failures, 0 output buffers swapped out
                 0 carrier transitions     DCD=up  DSR=up  DTR=up  RTS=up  CTS=up

            Monitoring and Maintaining Frame Relay Queueing and Fragmentation at the Interface

            To monitor and maintain Frame Relay queueing and fragmentation at the interface, use the following commands in privileged EXEC mode:

            SUMMARY STEPS

              1.    debug frame-relay fragment [event | interface type / number dlci]

              2.    show frame-relay fragment [interface type / number [dlci]]

              3.    show interfaces serial number

              4.    show queue interface-type interface-number

              5.    show policy-map interface number [input | output]


            DETAILED STEPS
              Step 1   debug frame-relay fragment [event | interface type / number dlci]

              Displays information related to Frame Relay fragmentation on a PVC.

              Step 2   show frame-relay fragment [interface type / number [dlci]]

              Displays information about Frame Relay fragmentation.

              Step 3   show interfaces serial number

              Displays information about a serial interface.

              Step 4   show queue interface-type interface-number

              Displays the contents of packets inside a queue for a particular interface.

              Step 5   show policy-map interface number [input | output]

              Displays the packet statistics of all classes that are configured for all service policies on the specified interface.


              Configuration Examples for Frame Relay Queueing and Fragmentation at the Interface

              Example Frame Relay Queueing Shaping and Fragmentation at the Interface

              The following example shows the configuration of a hierarchical policy for low-latency queueing, FRF.12 fragmentation, and shaping on serial interface 3/2. Note that traffic from the priority queue will not be interleaved with fragments from the class-default queue because shaping is configured.

              class-map voice
               match access-group 101
                   
              policy-map llq
               class voice
                priority 64
                 
              policy-map shaper
               class class-default 
                shape average 96000
                service-policy llq
              interface serial 3/2
               ip address 10.0.0.1 255.0.0.0
               encapsulation frame-relay
               bandwidth 128
               clock rate 128000
               service-policy output shaper
               frame-relay fragment 80 end-to-end
                 
               access-list 101 match ip any host 10.0.0.2

              Example Frame Relay Queueing and Fragmentation at the Interface

              The following example shows the configuration of low-latency queueing and FRF.12 fragmentation on serial interface 3/2. Because shaping is not being used, a hierarchical traffic policy is not needed and traffic from the priority queue will be interleaved with fragments from the other queues. Without shaping, the output rate of the interface is equal to the line rate or configured clock rate. In this example, the clock rate is 128,000 bps.

              class-map voice
               match access-group 101
                   
              policy-map llq
               class voice
                priority 64
               class video
                bandwidth 32
              interface serial 3/2
               ip address 10.0.0.1 255.0.0.0
               encapsulation frame-relay
               bandwidth 128
               clock rate 128000
               service-policy output llq
               frame-relay fragment 80 end-to-end
               access-list 101 match ip any host 10.0.0.2

              Additional References

              Related Documents

              Related Topic

              Document Title

              Cisco IOS commands

              Cisco IOS Master Commands List, All Releases

              WAN commands

              Cisco IOS Wide-Area Networking Command Reference

              Configuring Frame Relay

              Configuring Frame Relay

              Standards

              Standard

              Title

              FRF.12

              Frame Relay Fragmentation Implementation Agreement , December 1997

              MIBs

              MIB

              MIBs Link

              None

              To locate and download MIBs for selected platforms, Cisco software releases, and feature sets, use Cisco MIB Locator found at the following URL:

              http:/​/​www.cisco.com/​go/​mibs

              RFCs

              RFC

              Title

              None

              --

              Technical Assistance

              Description

              Link

              The Cisco Support website provides extensive online resources, including documentation and tools for troubleshooting and resolving technical issues with Cisco products and technologies.

              To receive security and technical information about your products, you can subscribe to various services, such as the Product Alert Tool (accessed from Field Notices), the Cisco Technical Services Newsletter, and Really Simple Syndication (RSS) Feeds.

              Access to most tools on the Cisco Support website requires a Cisco.com user ID and password.

              http:/​/​www.cisco.com/​cisco/​web/​support/​index.html

              Feature Information for Frame Relay Queueing and Fragmentation at the Interface

              The following table provides release information about the feature or features described in this module. This table lists only the software release that introduced support for a given feature in a given software release train. Unless noted otherwise, subsequent releases of that software release train also support that feature.

              Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/​go/​cfn. An account on Cisco.com is not required.

              Table 1 Feature Information for Frame Relay Queueing and Fragmentation at the Interface

              Feature Name

              Releases

              Feature Information

              Frame Relay Queuing and Fragmentation at the Interface

              12.2(11)S 12.2(13)T 15.0(1)S

              The Frame Relay Queueing and Fragmentation at the Interface feature introduces support for low-latency queueing (LLQ) and FRF.12 end-to-end fragmentation on a Frame Relay interface.

              The following commands were introduced or modified: frame-relay fragment end-to-end, show interfaces serial.


              Frame Relay Queueing and Fragmentation at the Interface

              Contents

              Frame Relay Queueing and Fragmentation at the Interface

              The Frame Relay Queueing and Fragmentation at the Interface feature introduces support for low-latency queueing (LLQ) and FRF.12 end-to-end fragmentation on a Frame Relay interface.

              Finding Feature Information

              Your software release may not support all the features documented in this module. For the latest caveats and feature information, see Bug Search Tool and the release notes for your platform and software release. To find information about the features documented in this module, and to see a list of the releases in which each feature is supported, see the feature information table at the end of this module.

              Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/​go/​cfn. An account on Cisco.com is not required.

              Prerequisites for Frame Relay Queueing and Fragmentation at the Interface

              The tasks in this document assume that you know how to configure low-latency queueing and shaping service policies.

              The following prerequisites are specific to the Cisco 7500 series:

              • The Frame Relay Queueing and Fragmentation at the Interface feature is supported on VIP-based interfaces with VIP2-50 or higher.

              • Distributed Cisco Express Forwarding (dCEF) must be enabled both globally and on the Frame Relay interface.

              Restrictions for Frame Relay Queueing and Fragmentation at the Interface

              • Interface fragmentation and Frame Relay traffic shaping cannot be configured at the same time.

              • Interface fragmentation and class-based fragmentation cannot be configured at the same time.

              • Frame Relay switched virtual circuits (SVCs) are not supported.

              • Hierarchical shaping and multiple shapers are not supported.

              Information About Frame Relay Queueing and Fragmentation at the Interface

              The Frame Relay Queueing and Fragmentation at the Interface feature simplifies the configuration of low-latency, low-jitter quality of service (QoS) by enabling the queueing policy and fragmentation configured on the main interface to apply to all permanent virtual circuits (PVCs) and subinterfaces under that interface. Before the introduction of this feature, queueing and fragmentation had to be configured on each individual PVC. Subrate shaping can also be configured on the interface.

              How Frame Relay Queueing and Fragmentation at the Interface Works

              When FRF.12 end-to-end fragmentation is enabled on an interface, all PVCs on the main interface and its subinterfaces will have fragmentation enabled with the same configured fragment size. To maintain low latency and low jitter for high-priority traffic, the configured fragment size must be greater than the largest high-priority frames. This configuration will prevent high-priority traffic from being fragmented and queued behind lower-priority fragmented frames. If the size of a high-priority frame is larger than the configured fragment size, the high-priority frame will be fragmented. Local Management Interface (LMI) traffic will not be fragmented and is guaranteed its required bandwidth.

              When a low-latency queueing policy map is applied to the interface, traffic through the interface is identified using class maps and is directed to the appropriate queue. Time-sensitive traffic such as voice should be classified as high priority and will be queued on the priority queue. Traffic that does not fall into one of the defined classes will be queued on the class-default queue. Frames from the priority queue and class queues are subject to fragmentation and interleaving. As long as the configured fragment size is larger than the high-priority frames, the priority queue traffic will not be fragmented and will be interleaved with fragmented frames from other class queues. This approach provides the highest QoS transmission for priority queue traffic. The figure below illustrates the interface queueing and fragmentation process.

              Figure 1. Frame Relay Queueing and Fragmentation at the Interface

              Subrate shaping can also be applied to the interface, but interleaving of high-priority frames will not work when shaping is configured. If shaping is not configured, each PVC will be allowed to send bursts of traffic up to the physical line rate.

              When shaping is configured and traffic exceeds the rate at which the shaper can send frames, the traffic is queued at the shaping layer using fair queueing. After a frame passes through the shaper, the frame is queued at the interface using whatever queueing method is configured. If shaping is not configured, then queueing occurs only at the interface.


              Note


              For interleaving to work, both fragmentation and the low-latency queueing policy must be configured with shaping disabled.


              The Frame Relay Queueing and Fragmentation at the Interface feature supports the following functionality:

              • Voice over Frame Relay

              • Weighted Random Early Detection

              • Frame Relay payload compression


              Note


              When payload compression and Frame Relay fragmentation are used at the same time, payload compression is always performed before fragmentation.


              • IP header compression

              Benefits of Frame Relay Queueing and Fragmentation at the Interface

              Simple Configuration

              The Frame Relay Queueing and Fragmentation at the Interface feature allows fragmentation, low-latency queueing, and subrate shaping to be configured on a Frame Relay interface queue. The fragmentation and queueing and shaping policy will apply to all PVCs and subinterfaces under the main interface, eliminating the need to configure QoS on each PVC individually.

              Flexible Bandwidth

              This feature allows PVCs to preserve the logical separation of traffic from different services while reducing bandwidth partitioning between PVCs. Each PVC can send bursts of traffic up to the interface shaping rate or, if shaping is not configured, the physical interface line rate.

              How to Configure Frame Relay Queueing and Fragmentation at the Interface

              Configuring Class Policy for the Priority Queue

              To configure a policy map for the priority class, use the following commands beginning in global configuration mode:

              SUMMARY STEPS

                1.    enable

                2.    configure terminal

                3.    policy-map policy-map

                4.    class class-name

                5.    Router(config-pmap-c)# priority bandwidth-kbps

                6.    exit


              DETAILED STEPS
                 Command or ActionPurpose
                Step 1 enable


                Example:
                Router> enable
                 

                Enables privileged EXEC mode.

                • Enter your password if prompted.

                 
                Step 2 configure terminal


                Example:
                Router# configure terminal
                 

                Enters global configuration mode.

                 
                Step 3 policy-map policy-map


                Example:
                Router(config) policy-map policy1
                 

                Specifies the name of the policy map to be created or modified.

                • Use this command to define the queueing policy for the priority queue.

                 
                Step 4 class class-name


                Example:
                Router(config-pmap)# class c1
                 

                Specifies the name of a class to be created and included in the service policy.

                • The class name that you specify in the policy map defines the characteristics for that class and its match criteria as configured using the class-map command.

                 
                Step 5 Router(config-pmap-c)# priority bandwidth-kbps

                Example:
                Router(config-pmap-c)# priority 30
                 

                Creates a strict priority class and specifies the amount of bandwidth, in kbps, to be assigned to the class.

                 
                Step 6 exit


                Example:
                Router(config-pmap-c)# exit
                 

                Exits the current configuration mode.

                 

                Configuring Class Policy for the Bandwidth Queues

                To configure a policy map and create class policies that make up the service policy, use the following commands beginning in global configuration mode:

                SUMMARY STEPS

                  1.    enable

                  2.    configure terminal

                  3.    policy-map policy-map

                  4.    class class-name

                  5.    Router(config-pmap-c)# bandwidth bandwidth-kbps

                  6.    exit


                DETAILED STEPS
                   Command or ActionPurpose
                  Step 1 enable


                  Example:
                  Router> enable
                   

                  Enables privileged EXEC mode.

                  • Enter your password if prompted.

                   
                  Step 2 configure terminal


                  Example:
                  Router# configure terminal
                   

                  Enters global configuration mode.

                   
                  Step 3 policy-map policy-map


                  Example:
                  Router(config)# policy-map policy1
                   

                  Specifies the name of the policy map to be created or modified.

                  • Use this command to define the queueing policy for the priority queue.

                  • The bandwidth queues and the priority queue use the same policy map.

                   
                  Step 4 class class-name


                  Example:
                  Router(config-pmap)# class c1
                   

                  Specifies the name of a class to be created and included in the service policy.

                  • The class name that you specify in the policy map defines the characteristics for that class and its match criteria as configured using the class-mapcommand.

                   
                  Step 5 Router(config-pmap-c)# bandwidth bandwidth-kbps

                  Example:
                  Router(config-pmap-c)# bandwidth 10
                   

                  Specifies the amount of bandwidth to be assigned to the class, in kbps, or as a percentage of the available bandwidth. Bandwidth must be specified in kbps or as a percentage consistently across classes. (Bandwidth of the priority queue must be specified in kbps.)

                  • The sum of all bandwidth allocation on an interface cannot exceed 75 percent of the total available interface bandwidth. However, if you need to configure more than 75 percent of the interface bandwidth to classes, you can override the 75 percent maximum by using the max-reserved-bandwidth command.

                   
                  Step 6 exit


                  Example:
                  Router(config-pmap-c)# exit
                   

                  Exits the current configuration mode.

                   

                  Configuring the Shaping Policy Using the Class-Default Class

                  In general, the class-default class is used to classify traffic that does not fall into one of the defined classes. Even though the class-default class is predefined when you create the policy map, you still have to configure it. If a default class is not configured, traffic that does not match any of the configured classes is given best-effort treatment, which means that the network will deliver the traffic if it can, without any assurance of reliability, delay prevention, or throughput.

                  If you configure shaping in addition to queueing on the interface, use the class-default class to configure the shaping policy. The shaping policy will serve as the parent in a hierarchical traffic policy. The queueing policy will serve as the child policy. The class-default class is used for the shaping policy so that all traffic for the entire interface is shaped and a bandwidth-limited stream can be created.

                  To configure the shaping policy in the class-default class, use the following commands beginning in global configuration mode:

                  SUMMARY STEPS

                    1.    enable

                    2.    configure terminal

                    3.    policy-map policy-map

                    4.    class class-default

                    5.    shape [average | peak] mean-rate [[burst-size] [excess-burst-size]]

                    6.    service-policy policy-map-name

                    7.    exit


                  DETAILED STEPS
                     Command or ActionPurpose
                    Step 1 enable


                    Example:
                    Router> enable
                     

                    Enables privileged EXEC mode.

                    • Enter your password if prompted.

                     
                    Step 2 configure terminal


                    Example:
                    Router# configure terminal
                     

                    Enters global configuration mode.

                     
                    Step 3 policy-map policy-map


                    Example:
                    Router(config)# policy-map policy1
                     

                    Specifies the name of the policy map to be created or modified.

                    • Use this command to define the shaping policy.

                     
                    Step 4 class class-default


                    Example:
                    Router(config-pmap)# class class-default
                     

                    Specifies the default class so that you can configure or modify its policy.

                     
                    Step 5 shape [average | peak] mean-rate [[burst-size] [excess-burst-size]]


                    Example:
                    Router(config-pmap-c)# shape peak 10
                     

                    (Optional) Shapes traffic to the indicated bit rate according to the algorithm specified.

                     
                    Step 6 service-policy policy-map-name


                    Example:
                    Router(config-pmap-c)# service-policy policy1
                     

                    Specifies the name of a policy map to be used as a matching criterion (for nesting traffic policies [hierarchical traffic policies] within one another).

                    • Use this command to attach the policy map for the priority queue (the child policy) to the shaping policy (the parent policy).

                     
                    Step 7 exit


                    Example:
                    Router(config-pmap-c)# exit
                     

                    Exits the current configuration mode.

                     

                    Configuring Queueing and Fragmentation on the Frame Relay Interface

                    To configure low-latency queueing and FRF.12 end-to-end fragmentation on a Frame Relay interface, use the following commands beginning in global configuration mode:

                    SUMMARY STEPS

                      1.    enable

                      2.    configure terminal

                      3.    interface type / number

                      4.    encapsulation frame-relay

                      5.    service-policy output policy-map-name

                      6.    frame-relay fragment fragment-size end-to-end

                      7.    exit


                    DETAILED STEPS
                       Command or ActionPurpose
                      Step 1 enable


                      Example:
                      Router> enable
                       

                      Enables privileged EXEC mode.

                      • Enter your password if prompted.

                       
                      Step 2 configure terminal


                      Example:
                      Router# configure terminal
                       

                      Enters global configuration mode.

                       
                      Step 3 interface type / number


                      Example:
                      Router(config)# interface fe 0/0
                       

                      Configures an interface type and enters interface configuration mode.

                       
                      Step 4 encapsulation frame-relay


                      Example:
                      Router(config-if)# encapsulation frame-relay
                       

                      Enables Frame Relay encapsulation.

                       
                      Step 5 service-policy output policy-map-name


                      Example:
                      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.

                      • If shaping is being used, use this command to attach the shaping policy (which includes the nested queueing policy) to the interface.

                      • Interleaving of high-priority frames will not work if shaping is configured on the interface.

                      • If shaping is not being used, use this command to attach the queueing policy to the interface.

                       
                      Step 6 frame-relay fragment fragment-size end-to-end


                      Example:
                      Router(config-if)# frame-relay fragment 100 end-to-end
                       

                      Enables fragmentation of Frame Relay frames.

                      • To maintain low latency and low jitter for priority queue traffic, configure the fragment size to be greater than the largest high-priority frame that would be expected.

                       
                      Step 7 exit


                      Example:
                      Router(config-if)#
                       
                      exit
                       

                      Exits the current configuration mode.

                       

                      Verifying Frame Relay Queueing and Fragmentation at the Interface

                      To verify the configuration and performance of Frame Relay queueing and fragmentation at the interface, perform the following steps:

                      SUMMARY STEPS

                        1.    Enter the show running-config command to verify the configuration.

                        2.    Enter the show policy-map interface command to display low-latency queueing information, packet counters, and statistics for the policy map applied to the interface. Compare the values in the "packets" and the "pkts matched" counters; under normal circumstances, the "packets" counter is much larger than the "pkts matched" counter. If the values of the two counters are nearly equal, then the interface is receiving a large number of process-switched packets or is heavily congested.

                        3.    Enter the show interfaces serialcommand to display information about the queueing strategy, priority queue interleaving, and type of fragmentation configured on the interface. You can determine whether the interface has reached a congestion condition and packets have been queued by looking at the "Conversations" fields. A nonzero value for "max active" counter shows whether any queues have been active. If the "active" counter is a nonzero value, you can use the show queue command to view the contents of the queues.


                      DETAILED STEPS
                        Step 1   Enter the show running-config command to verify the configuration.

                        Example:
                        Router# show running-config
                        Building configuration...
                        .
                        .
                        .
                        class-map match-all voice
                          match ip precedence 5
                        !       
                        !policy-map llq
                          class voice
                            priority 64
                        policy-map shaper
                          class class-default
                           shape peak 96000
                           service-policy llq
                        !
                        !interface Serial1/1
                         ip address 16.0.0.1 255.255.255.0
                         encapsulation frame-relay
                         service-policy output shaper
                         frame-relay fragment 80 end-to-end
                        !
                        
                        Step 2   Enter the show policy-map interface command to display low-latency queueing information, packet counters, and statistics for the policy map applied to the interface. Compare the values in the "packets" and the "pkts matched" counters; under normal circumstances, the "packets" counter is much larger than the "pkts matched" counter. If the values of the two counters are nearly equal, then the interface is receiving a large number of process-switched packets or is heavily congested.

                        The following sample output for the show policy-map interface command is based on the configuration in Step 1:



                        Example:
                        Router# show policy-map interface serial 1/1
                         Serial1/1 
                          Service-policy output:shaper
                            Class-map:class-default (match-any)
                              12617 packets, 1321846 bytes
                              5 minute offered rate 33000 bps, drop rate 0 bps
                              Match:any 
                              Traffic Shaping
                                   Target/Average   Byte   Sustain   Excess    Interval  Increment
                                     Rate           Limit  bits/int  bits/int  (ms)      (bytes)  
                                   192000/96000     1992   7968      7968      83        1992     
                                Adapt  Queue     Packets   Bytes     Packets   Bytes     Shaping
                                Active Depth                         Delayed   Delayed   Active
                                -      0         12586     1321540   0         0         no
                              Service-policy :llq
                                Class-map:voice (match-all)
                                  3146 packets, 283140 bytes
                                  5 minute offered rate 7000 bps, drop rate 0 bps
                                  Match:ip precedence 1 
                                  Weighted Fair Queueing
                                    Strict Priority
                                    Output Queue:Conversation 24 
                                    Bandwidth 64 (kbps) Burst 1600 (Bytes)
                                    (pkts matched/bytes matched) 0/0
                                    (total drops/bytes drops) 0/0
                                Class-map:class-default (match-any)
                                  9471 packets, 1038706 bytes
                                  5 minute offered rate 26000 bps
                                  Match:any 
                        
                        Step 3   Enter the show interfaces serialcommand to display information about the queueing strategy, priority queue interleaving, and type of fragmentation configured on the interface. You can determine whether the interface has reached a congestion condition and packets have been queued by looking at the "Conversations" fields. A nonzero value for "max active" counter shows whether any queues have been active. If the "active" counter is a nonzero value, you can use the show queue command to view the contents of the queues.

                        The following sample output for the show interfaces serialcommand is based on the configuration in Step 1:



                        Example:
                        Router# show interfaces serial 1/1
                        Serial1/1 is up, line protocol is up 
                          Hardware is M4T
                          Internet address is 16.0.0.1/24
                          MTU 1500 bytes, BW 1544 Kbit, DLY 20000 usec, 
                             reliability 255/255, txload 5/255, rxload 1/255
                          Encapsulation FRAME-RELAY, crc 16, loopback not set
                          Keepalive set (10 sec)
                          Restart-Delay is 0 secs
                          LMI enq sent  40, LMI stat recvd 40, LMI upd recvd 0, DTE LMI up
                          LMI enq recvd 0, LMI stat sent  0, LMI upd sent  0
                          LMI DLCI 1023  LMI type is CISCO  frame relay DTE
                          Fragmentation type:end-to-end, size 80, PQ interleaves 0
                          Broadcast queue 0/64, broadcasts sent/dropped 0/0, interface broadcasts 0
                          Last input 00:00:03, output 00:00:00, output hang never
                          Last clearing of "show interface" counters 00:06:34
                          Input queue:0/75/0/0 (size/max/drops/flushes); Total output drops:0
                          Queueing strategy:weighted fair
                          Output queue:0/1000/64/0 (size/max total/threshold/drops) 
                             Conversations  0/1/256 (active/max active/max total)
                             Reserved Conversations 0/0 (allocated/max allocated)
                             Available Bandwidth 1158 kilobits/sec
                          5 minute input rate 0 bits/sec, 0 packets/sec
                          5 minute output rate 33000 bits/sec, 40 packets/sec
                             40 packets input, 576 bytes, 0 no buffer
                             Received 0 broadcasts, 0 runts, 0 giants, 0 throttles
                             0 input errors, 0 CRC, 0 frame, 0 overrun, 0 ignored, 0 abort
                             15929 packets output, 1668870 bytes, 0 underruns
                             0 output errors, 0 collisions, 0 interface resets
                             0 output buffer failures, 0 output buffers swapped out
                             0 carrier transitions     DCD=up  DSR=up  DTR=up  RTS=up  CTS=up

                        Monitoring and Maintaining Frame Relay Queueing and Fragmentation at the Interface

                        To monitor and maintain Frame Relay queueing and fragmentation at the interface, use the following commands in privileged EXEC mode:

                        SUMMARY STEPS

                          1.    debug frame-relay fragment [event | interface type / number dlci]

                          2.    show frame-relay fragment [interface type / number [dlci]]

                          3.    show interfaces serial number

                          4.    show queue interface-type interface-number

                          5.    show policy-map interface number [input | output]


                        DETAILED STEPS
                          Step 1   debug frame-relay fragment [event | interface type / number dlci]

                          Displays information related to Frame Relay fragmentation on a PVC.

                          Step 2   show frame-relay fragment [interface type / number [dlci]]

                          Displays information about Frame Relay fragmentation.

                          Step 3   show interfaces serial number

                          Displays information about a serial interface.

                          Step 4   show queue interface-type interface-number

                          Displays the contents of packets inside a queue for a particular interface.

                          Step 5   show policy-map interface number [input | output]

                          Displays the packet statistics of all classes that are configured for all service policies on the specified interface.


                          Configuration Examples for Frame Relay Queueing and Fragmentation at the Interface

                          Example Frame Relay Queueing Shaping and Fragmentation at the Interface

                          The following example shows the configuration of a hierarchical policy for low-latency queueing, FRF.12 fragmentation, and shaping on serial interface 3/2. Note that traffic from the priority queue will not be interleaved with fragments from the class-default queue because shaping is configured.

                          class-map voice
                           match access-group 101
                               
                          policy-map llq
                           class voice
                            priority 64
                             
                          policy-map shaper
                           class class-default 
                            shape average 96000
                            service-policy llq
                          interface serial 3/2
                           ip address 10.0.0.1 255.0.0.0
                           encapsulation frame-relay
                           bandwidth 128
                           clock rate 128000
                           service-policy output shaper
                           frame-relay fragment 80 end-to-end
                             
                           access-list 101 match ip any host 10.0.0.2

                          Example Frame Relay Queueing and Fragmentation at the Interface

                          The following example shows the configuration of low-latency queueing and FRF.12 fragmentation on serial interface 3/2. Because shaping is not being used, a hierarchical traffic policy is not needed and traffic from the priority queue will be interleaved with fragments from the other queues. Without shaping, the output rate of the interface is equal to the line rate or configured clock rate. In this example, the clock rate is 128,000 bps.

                          class-map voice
                           match access-group 101
                               
                          policy-map llq
                           class voice
                            priority 64
                           class video
                            bandwidth 32
                          interface serial 3/2
                           ip address 10.0.0.1 255.0.0.0
                           encapsulation frame-relay
                           bandwidth 128
                           clock rate 128000
                           service-policy output llq
                           frame-relay fragment 80 end-to-end
                           access-list 101 match ip any host 10.0.0.2

                          Additional References

                          Related Documents

                          Related Topic

                          Document Title

                          Cisco IOS commands

                          Cisco IOS Master Commands List, All Releases

                          WAN commands

                          Cisco IOS Wide-Area Networking Command Reference

                          Configuring Frame Relay

                          Configuring Frame Relay

                          Standards

                          Standard

                          Title

                          FRF.12

                          Frame Relay Fragmentation Implementation Agreement , December 1997

                          MIBs

                          MIB

                          MIBs Link

                          None

                          To locate and download MIBs for selected platforms, Cisco software releases, and feature sets, use Cisco MIB Locator found at the following URL:

                          http:/​/​www.cisco.com/​go/​mibs

                          RFCs

                          RFC

                          Title

                          None

                          --

                          Technical Assistance

                          Description

                          Link

                          The Cisco Support website provides extensive online resources, including documentation and tools for troubleshooting and resolving technical issues with Cisco products and technologies.

                          To receive security and technical information about your products, you can subscribe to various services, such as the Product Alert Tool (accessed from Field Notices), the Cisco Technical Services Newsletter, and Really Simple Syndication (RSS) Feeds.

                          Access to most tools on the Cisco Support website requires a Cisco.com user ID and password.

                          http:/​/​www.cisco.com/​cisco/​web/​support/​index.html

                          Feature Information for Frame Relay Queueing and Fragmentation at the Interface

                          The following table provides release information about the feature or features described in this module. This table lists only the software release that introduced support for a given feature in a given software release train. Unless noted otherwise, subsequent releases of that software release train also support that feature.

                          Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/​go/​cfn. An account on Cisco.com is not required.

                          Table 1 Feature Information for Frame Relay Queueing and Fragmentation at the Interface

                          Feature Name

                          Releases

                          Feature Information

                          Frame Relay Queuing and Fragmentation at the Interface

                          12.2(11)S 12.2(13)T 15.0(1)S

                          The Frame Relay Queueing and Fragmentation at the Interface feature introduces support for low-latency queueing (LLQ) and FRF.12 end-to-end fragmentation on a Frame Relay interface.

                          The following commands were introduced or modified: frame-relay fragment end-to-end, show interfaces serial.