This section lists general restrictions that apply to L2VPN Interworking. Other restrictions that are platform-specific or device-specific are listed in the following sections.

• The interworking type on one provider edge (PE) router must match the interworking type on the peer PE router.
• The following quality of service (QoS) features are supported with L2VPN Interworking:
  • Static IP type of service (ToS) or Multiprotocol Label Switching (MPLS) experimental bit (EXP) setting in tunnel header
  • IP ToS reflection in tunnel header (Layer 2 Tunnel Protocol Version 3 (L2TPv3) only)
  • Frame Relay policing
  • Frame Relay data-link connection identifier (DLCI)-based congestion management (Cisco 7500/Versatile Interface Processor (VIP))
  • One-to-one mapping of VLAN priority bits to MPLS EXP bits
• Only ATM AAL5 VC mode is supported; ATM VP and port mode are not supported.
• In Cisco IOS Release 12.2(52)SE and Cisco IOS Release 12.2(33)SRE, the encapsulation command supports only the mpls keyword. The l2tpv3 keyword is not supported. The interworking command supports only the ethernet and vlan keywords. The ip keyword is not supported.

The following line cards are supported on the Cisco 7600 series router. The table below shows the line cards that are supported on the WAN (ATM, Frame Relay, or PPP) side of the interworking link. The second table below shows the line cards that are supported on the Ethernet side of the interworking link. For more details on the Cisco 7600 routers supported shared port adapters and line cards, see the Release Notes for Cisco IOS Release 12.2SR for the Cisco 7600 Series Routers.

The following restrictions apply to the Cisco 7600 series routers and L2VPN Interworking:

• OAM Emulation is not required with L2VPN Interworking on the SIP-200, SIP-400, and Flexwan2 line cards.
• Cisco 7600 series routers support the L2VPN Interworking: VLAN Enable/Disable Option for AToM feature starting in Cisco IOS Release 12.2(33)SRE. This feature has the following restrictions:
  • PFC-based EoMPLS is not supported.
  • Scalable and SVI-based EoMPLS are supported with the SIP-400 line card.
• The Cisco 7600 series routers do not support L2VPN Interworking over L2TPv3.
• Cisco 7600 series routers support only the following interworking types:
  • Ethernet/VLAN to Frame Relay (IP and Ethernet modes)
  • Ethernet/VLAN to ATM AAL5SNAP (IP and Ethernet modes)
  • Ethernet/VLAN to PPP (IP only)
  • Ethernet to VLAN Interworking
• Cisco 7600 series routers do not support the following interworking types:
  • Ethernet/VLAN to ATM AAL5MUX
  • Frame Relay to PPP Interworking
  • Frame Relay to ATM AAL5 Interworking
• Both ends of the interworking link must be configured with the same encapsulation and interworking type:
  • If you use Ethernet encapsulation, you must use the Ethernet (bridged) interworking type. If you are not using Ethernet encapsulation, you can use a bridging mechanism, such as routed bridge encapsulation (RBE).
  • If you use an IP encapsulation (such as ATM or Frame Relay), you must use the IP (routed) interworking type. The PE routers negotiate the process for learning and resolving addresses.
  • You must use the same MTU size on the attachment circuits at each end of the pseudowire.
• PFC-based EoMPLS is not supported on ES40 line cards. SVI and EVC/scalable EoMPLS are the alternative options.
• PFC-based EoMPLS is not supported for Routed/IP interworking in Cisco IOS Release 12.2(33)SRD and later releases. The alternative Routed/IP interworking options are SVI and EVC or scalable EoMPLS. However, PFC-based EoMPLS is supported for Ethernet/Bridged interworking and for like-to-like over AToM.

For more information about hardware requirements on the Cisco12000 series routers, see the Cross-Platform Release Notes for Cisco IOS Release 12.0S.

For QOS support on the Cisco 12000 series routers, see Any Transport over MPLS (AToM): Layer 2 QoS (Quality of Service) for the Cisco 12000 Series Router

The following restrictions apply to ATM AAL5 Interworking:

• Switched virtual circuits (SVCs) are not supported.
• Inverse Address Resolution Protocol (ARP) is not supported with IP interworking.
• Customer edge (CE) routers must use point-to-point subinterfaces or static maps.
• Both AAL5MUX and AAL5SNAP encapsulation are supported. In the case of AAL5MUX, no translation is needed.
• In the Ethernet end-to-end over ATM scenario, the following translations are supported:
  • Ethernet without LAN frame check sequence (FCS) (AAAA030080C200070000)
  • Spanning tree (AAAA030080c2000E)

Everything else is dropped.

• In the IP over ATM scenario, the IPv4 (AAAA030000000800) translation is supported. Everything else is dropped.
• Operation, Administration, and Management (OAM) emulation for L2VPN Interworking is the same as like-to-like. The end-to-end F5 loopback cells are looped back on the PE router. When the pseudowire is down, an F5 end-to-end segment Alarm Indication Signal (AIS)/Remote Defect Identification (RDI) is sent from the PE router to the CE router.
• Interim Local Management Interface (ILMI) can manage virtual circuits (VCs) and permanent virtual circuits (PVCs).
• To enable ILMI management, configure ILMI PVC 0/16 on the PE router's ATM interface. If a PVC is provisioned or deleted, an ilmiVCCChange trap is sent to the CE router.
• Only the user side of the User-Network Interface (UNI) is supported; the network side of the UNI is not supported.

The following restrictions apply to Ethernet/VLAN interworking:

• When you configure VLAN to Ethernet interworking, VLAN to Frame Relay (routed), or ATM using Ethernet (bridged) interworking, the PE router on the Ethernet side that receives a VLAN tagged frame from the CE router removes the VLAN tag. In the reverse direction, the PE router adds the VLAN tag to the frame before sending the frame to the CE router.

(If you enable the L2VPN Interworking: VLAN Enable/Disable Option for AToM feature with the interworking vlan command, VLAN ID is included as part of the Ethernet frame. See the VLAN Interworking for more information. )

• In bridged interworking from VLAN to Frame Relay, the Frame Relay PE router does not strip off VLAN tags from the Ethernet traffic it receives.
• The Cisco 10720 Internet router supports Ethernet to VLAN Interworking Ethernet only over L2TPv3.
• Ethernet interworking for a raw Ethernet port or a VLAN trunk is not supported. Traffic streams are not kept separate when traffic is sent between transport types.
• In routed mode, only one CE router can be attached to an Ethernet PE router.
• There must be a one-to-one relationship between an attachment circuit and the pseudowire. Point-to-multipoint or multipoint-to-point configurations are not supported.
• Configure routing protocols for point-to-point operation on the CE routers when configuring an Ethernet to non-Ethernet setup.
• In the IP interworking mode, the IPv4 (0800) translation is supported. The PE router captures ARP (0806) packets and responds with its own MAC address (proxy ARP). Everything else is dropped.
• The Ethernet or VLAN must contain only two IP devices: PE router and CE router. The PE router performs proxy ARP and responds to all ARP requests it receives. Therefore, only one CE and one PE router should be on the Ethernet or VLAN segment.
• If the CE routers are doing static routing, you can perform the following tasks:
  • The PE router needs to learn the MAC address of the CE router to correctly forward traffic to it. The Ethernet PE router sends an Internet Control Message Protocol (ICMP) Router discovery protocol (RDP) solicitation message with the source IP address as zero. The Ethernet CE router responds to this solicitation message. To configure the Cisco CE router's Ethernet or VLAN interface to respond to the ICMP RDP solicitation message, issue the ip irdpcommand in interface configuration mode. If you do not configure the CE router, traffic is dropped until the CE router sends traffic toward the PE router.
  • To disable the CE routers from running the router discovery protocol, issue the ip irdp maxadvertinterval 0 command in interface mode.
• This restriction applies if you configure interworking between Ethernet and VLAN with Catalyst switches as the CE routers. The spanning tree protocol is supported for Ethernet interworking. Ethernet interworking between an Ethernet port and a VLAN supports spanning tree protocol only on VLAN 1. Configure VLAN 1 as a nonnative VLAN.
• When you change the interworking configuration on an Ethernet PE router, clear the ARP entry on the adjacent CE router so that it can learn the new MAC address. Otherwise, you might experience traffic drops.

The following restrictions apply to the L2VPN Interworking: VLAN Enable/Disable Option for AToM feature, which allows the VLAN ID to be included as part of the Ethernet frame:

• The L2VPN Interworking: VLAN Enable/Disable Option for AToM feature is supported on the following releases:
  • Cisco IOS release 12.2(52)SE for the Cisco Catalyst 3750 Metro switches
  • Cisco IOS Release 12.2(33)SRE for the Cisco 7600 series routers
• L2VPN Interworking: VLAN Enable/Disable Option for AToM is not supported with L2TPv3. You can configure the featue only with AToM.
• If the interface on the PE router is a VLAN interface, it is not necessary to specify the interworking vlan command on that PE router.
• The L2VPN Interworking: VLAN Enable/Disable Option for AToM feature works only with the following attachment circuit combinations:
  • Ethernet to Ethernet
  • Ethernet to VLAN
  • VLAN to VLAN
• If you specify an interworking type on a PE router, that interworking type must be enforced. The interworking type must match on both PE routers. Otherwise, the VC may be in an incompatible state and remain in the down state. If the attachment circuit (AC) is VLAN, the PE router can negotiate (autosense) the VC type using Label Distribution Protocol (LDP).

For example, both PE1 and PE2 use Ethernet interfaces, and VLAN interworking is specified on PE1 only. PE2 is not configured with an interworking type and cannot autosense the interworking type. The result is an incompatible state where the VC remains in the down state.

On the other hand, if PE1 uses an Ethernet interface and VLAN interworking is enabled (which will enforce VLAN as the VC type), and PE2 uses a VLAN interface and interworking is not enabled (which causes PE2 to use Ethernet as its default VC type), PE2 can autosense and negotiate the interworking type and select VLAN as the VC type.

The table below shows the AC types, interworking options, and VC types after negotiation.

The following restrictions apply to Frame Relay interworking:

• The attachment circuit maximum transmission unit (MTU) sizes must match when you connect them over MPLS. By default, the MTU size associated with a Frame Relay DLCI is the interface MTU. This may cause problems, for example, when connecting some DLCIs on a PoS interface (with a default MTU of 4470 bytes) to Ethernet or VLAN (with a default MTU of 1500 bytes) and other DLCIs on the same PoS interface to ATM (with a default MTU of 4470 bytes). To avoid reducing all the interface MTUs to the lowest common denominator (1500 bytes in this case), you can specify the MTU for individual DLCIs using the mtu command.
• Only DLCI mode is supported. Port mode is not supported.
• Configure Frame Relay switching to use DCE or Network-to-Network Interface (NNI). DTE mode does not report status in the Local Management Interface (LMI) process. If a Frame Relay over MPLS circuit goes down and the PE router is in DTE mode, the CE router is never informed of the disabled circuit. You must configure the frame-relay switching command in global configuration mode in order to configure DCE or NNI.
• Frame Relay policing is non-distributed on the Cisco 7500 series routers. If you enable Frame Relay policing, traffic is sent to the route switch processor for processing.
• Inverse ARP is not supported with IP interworking. CE routers must use point-to-point subinterfaces or static maps.
• The PE router automatically supports translation of both the Cisco encapsulations and the Internet Engineering Task Force (IETF) encapsulations that come from the CE, but translates only to IETF when sending to the CE router. This is not a problem for the Cisco CE router, because it can handle IETF encapsulation on receipt even if it is configured to send Cisco encapsulation.
• With Ethernet interworking, the following translations are supported:
  • Ethernet without LAN FCS (0300800080C20007 or 6558)
  • Spanning tree (0300800080C2000E or 4242)

All other translations are dropped.

• With IP interworking, the IPv4 (03CC or 0800) translation is supported. All other translations are dropped.
• PVC status signaling works the same way as in like-to-like case. The PE router reports the PVC status to the CE router, based on the availability of the pseudowire. PVC status detected by the PE router will also be reflected into the pseudowire. LMI to OAM interworking is supported when you connect Frame Relay to ATM.

The following restrictions apply to PPP interworking:

• There must be a one-to-one relationship between a PPP session and the pseudowire. Multiplexing of multiple PPP sessions over the pseudowire is not supported.
• There must be a one-to-one relationship between a PPP session and a Frame Relay DLCI. Each Frame Relay PVC must have only one PPP session.
• Only IP (IPv4 (0021) interworking is supported. Link Control Protocol (LCP) packets and Internet Protocol Control Protocol (IPCP) packets are terminated at the PE router. Everything else is dropped.
• Proxy IPCP is automatically enabled on the PE router when IP interworking is configured on the pseudowire.
• By default, the PE router assumes that the CE router knows the remote CE router's IP address.
• Password Authentication Protocol (PAP) and Challenge-Handshake Authentication Protocol (CHAP) authentication are supported.

Layer 2 transport over MPLS and IP already exists for like-to-like attachment circuits, such as Ethernet-to-Ethernet or PPP-to-PPP. L2VPN Interworking builds on this functionality by allowing disparate attachment circuits to be connected. An interworking function facilitates the translation between the different Layer 2 encapsulations. The figure below is an example of Layer 2 interworking, where ATM and Frame Relay packets travel over the MPLS cloud.

Figure 1

ATM to Frame Relay Interworking Example

The L2VPN Interworking feature supports Ethernet, 802.1Q (VLAN), Frame Relay, ATM AAL5, and PPP attachment circuits over MPLS and L2TPv3. The features and restrictions for like-to-like functionality also apply to L2VPN Interworking.

L2VPN Interworking works in either Ethernet ("bridged") mode, IP ("routed"), or Ethernet VLAN mode. You specify the mode by issuing the interworking {ethernet | ip |vlan} command in pseudowire-class configuration mode.

• Ethernet Interworking
  
• IP Interworking
  
• VLAN Interworking
  

The supported L2VPN Interworking features are listed in the table below.

If the PE router needs to perform address resolution with the local CE router for PPP, you can configure the remote CE router's IP address on the PE router. Issue the ppp ipcp address proxy command with the remote CE router's IP address on the PE router's xconnect PPP interface. The following example shows a sample configuration:

pseudowire-class ip-interworking
 encapsulation mpls
 interworking ip
interface Serial2/0
 encapsulation ppp
 xconnect 10.0.0.2 200 pw-class ip-interworking
 ppp ipcp address proxy 10.65.32.14 

You can also configure the remote CE router's IP address on the local CE router with the peer default ip address command if the local CE router performs address resolution.

1.    enable

2.    configure terminal

3.    hw-module slot slot-number np mode feature

4.    pseudowire-class name

5.    encapsulation {mpls | l2tpv3}

6.    interworking {ethernet | ip} | vlan}

1.    enable

2.    show l2tun session all (L2TPv3 only)

3.    show arp

4.    ping

5.    show l2tun session interworking (L2TPv3 only)

6.    show mpls l2transport vc detail (AToM only)

Router# show l2tun session all

 Session Information Total tunnels 1 sessions 1

Session id 15736 is up, tunnel id 35411

Call serial number is 4035100045

Remote tunnel name is PE2

   Internet address is 10.9.9.9

   Session is L2TP signalled

   Session state is established, time since change 1d22h

   16 Packets sent, 16 received

   1518 Bytes sent, 1230 received

   Receive packets dropped:

     out-of-order:             0

     total:                    0

   Send packets dropped:

     exceeded session MTU:     0

     total:                    0

   Session vcid is 123

   Session Layer 2 circuit, type is Ethernet, name is FastEthernet1/1/0

   Circuit state is UP 

     Remote session id is 26570, remote tunnel id 46882

   DF bit off, ToS reflect disabled, ToS value 0, TTL value 255

   No session cookie information available

   FS cached header information:

     encap size = 24 bytes

       00000000 00000000 00000000 00000000

       00000000 00000000 

   Sequencing is off

Router# show l2tun session all

 Session Information Total tunnels 1 sessions 1

Session id 26570 is up, tunnel id 46882

Call serial number is 4035100045

Remote tunnel name is PE1

   Internet address is 10.8.8.8

   Session is L2TP signalled

   Session state is established, time since change 1d22h

   16 Packets sent, 16 received

   1230 Bytes sent, 1230 received

   Receive packets dropped:

     out-of-order:              0

     total:                     0

   Send packets dropped:

     exceeded session MTU:      0

     total:                     0

   Session vcid is 123

   Session Layer 2 circuit, type is Ethernet Vlan, name is FastEthernet2/0.1:10

   Circuit state is UP, interworking type is Ethernet

    Remote session id is 15736, remote tunnel id 35411

    DF bit off, ToS reflect disabled, ToS value 0, TTL value 255

   No session cookie information available

   FS cached header information:

     encap size = 24 bytes

     00000000 00000000 00000000 00000000

     00000000 00000000 

   Sequencing is off

Router# show arp
Protocol   Address       Age (min)   Hardware Addr    Type    Interface
Internet   10.1.1.5           134    0005.0032.0854   ARPA    FastEthernet0/0
Internet   10.1.1.7             -    0005.0032.0000   ARPA    FastEthernet0/0

Router# ping 10.1.1.5
Type escape sequence to abort.
Sending 5, 100-byte ICMP Echos to 10.1.1.5, timeout is 2 seconds:
!!!!!
Success rate is 100 percent (5/5), round-trip min/avg/max = 1/2/4 ms

Router# show l2tun session interworking
Session Information Total tunnels 1 sessions 1
LocID      TunID      Peer-address    Type IWrk Username, Intf/Vcid, Circuit                   
15736      35411      10.9.9.9         ETH   -   123,      Fa1/1/0 

Router# show l2tun session interworking
Session Information Total tunnels 1 sessions 1
LocID      TunID      Peer-address    Type IWrk Username, Intf/Vcid, Circuit                   
26570      46882      10.8.8.8         VLAN ETH  123,      Fa2/0.1:10 

Router# show mpls l2transport vc detail

Local interface: Fa1/1/0 up, line protocol up, Ethernet up

  Destination address: 10.9.9.9, VC ID: 123, VC status: up

    Preferred path: not configured  

    Default path: active

    Tunnel label: 17, next hop 10.1.1.3

    Output interface: Fa4/0/0, imposed label stack {17 20}

  Create time: 01:43:50, last status change time: 01:43:33

  Signaling protocol: LDP, peer 10.9.9.9:0 up

    MPLS VC labels: local 16, remote 20

    Group ID: local 0, remote 0

    MTU: local 1500, remote 1500

    Remote interface description: 

  Sequencing: receive disabled, send disabled

  VC statistics:

    packet totals: receive 15, send 4184

    byte totals:   receive 1830, send 309248

    packet drops:  receive 0, send 0

Router# show mpls l2transport vc detail

Local interface: Fa2/0.3 up, line protocol up, Eth VLAN 10 up

  MPLS VC type is Ethernet, interworking type is Ethernet

  Destination address: 10.8.8.8, VC ID: 123, VC status: up

    Preferred path: not configured  

    Default path: active

    Tunnel label: 16, next hop 10.1.1.3

    Output interface: Fa6/0, imposed label stack {16 16}

  Create time: 00:00:26, last status change time: 00:00:06

  Signaling protocol: LDP, peer 10.8.8.8:0 up

    MPLS VC labels: local 20, remote 16

    Group ID: local 0, remote 0

    MTU: local 1500, remote 1500

    Remote interface description: 

  Sequencing: receive disabled, send disabled

  VC statistics:

    packet totals: receive 5, send 0

    byte totals:   receive 340, send 0

    packet drops:  receive 0, send 0

1.    enable

2.    configure terminal

3.    pseudowire-class name

4.    encapsulation {mpls | l2tpv3}

5.    interworking {ethernet | ip| vlan}

6.    end

7.    show mpls l2transport vc [vcid vc-id | vcid vc-id-min vc-id-max] [interface type number [local-circuit-id]] [destination ip-address | name] [detail]

PE1# show mpls l2 vc 34 detail
Local interface: Et0/1 up, line protocol up, Ethernet up
  MPLS VC type is Ethernet, interworking type is Eth VLAN
  Destination address: 10.1.1.2, VC ID: 34, VC status: down
    Output interface: if-?(0), imposed label stack {}
    Preferred path: not configured  
    Default path: no route
    No adjacency
  Create time: 00:00:13, last status change time: 00:00:13
  Signaling protocol: LDP, peer unknown 
    Targeted Hello: 10.1.1.1(LDP Id) -> 10.1.1.2
    Status TLV support (local/remote)   : enabled/None (no remote binding)
      LDP route watch                   : enabled
      Label/status state machine        : local standby, AC-ready, LnuRnd
      Last local dataplane   status rcvd: No fault
      Last local SSS circuit status rcvd: No fault
      Last local SSS circuit status sent: Not sent
      Last local  LDP TLV    status sent: None
      Last remote LDP TLV    status rcvd: None (no remote binding)
      Last remote LDP ADJ    status rcvd: None (no remote binding)
    MPLS VC labels: local 2003, remote unassigned 
    Group ID: local 0, remote unknown
    MTU: local 1500, remote unknown
    Remote interface description: 
  Sequencing: receive disabled, send disabled
  VC statistics:
    packet totals: receive 0, send 0
    byte totals:   receive 0, send 0
    packet drops:  receive 0, seq error 0, send 0

The following example shows the configuration of Ethernet to VLAN over L2TPv3:

ip cef 

!

l2tp-class interworking-class 

authentication

hostname PE1

password 0 lab

!

pseudowire-class inter-ether-vlan 

encapsulation l2tpv3

interworking ethernet

protocol l2tpv3 interworking-class

ip local interface Loopback0

!

interface Loopback0

ip address 10.8.8.8 255.255.255.255

!

interface FastEthernet1/0

xconnect 10.9.9.9 1 pw-class inter-ether-vlan

ip cef 

!

l2tp-class interworking-class

authentication

hostname PE2

password 0 lab

!

pseudowire-class inter-ether-vlan

encapsulation l2tpv3

interworking ethernet

protocol l2tpv3 interworking-class

ip local interface Loopback0

!

interface Loopback0

ip address 10.9.9.9 255.255.255.255

!

interface FastEthernet0/0

no ip address

!

interface FastEthernet0/0.3

encapsulation dot1Q 10

xconnect 10.8.8.8 1 pw-class inter-ether-vlan

The following example shows the configuration of Ethernet to VLAN over AToM:

ip cef 

!

mpls label protocol ldp

mpls ldp router-id Loopback0 force

!

pseudowire-class atom-eth-iw

 encapsulation mpls

 interworking ethernet

!

interface Loopback0

ip address 10.8.8.8 255.255.255.255

!

interface FastEthernet1/0.1

 encapsulation dot1q 100

 xconnect 10.9.9.9 123 pw-class atom-eth-iw

ip cef 

!

mpls label protocol ldp

mpls ldp router-id Loopback0 force

!

pseudowire-class atom

 encapsulation mpls

!

interface Loopback0

 ip address 10.9.9.9 255.255.255.255

!

interface FastEthernet0/0

 no ip address

!

interface FastEthernet1/0

 xconnect 10.9.9.9 123 pw-class atom

The following example shows the configuration of Frame Relay to VLAN over L2TPv3:

configure terminal

ip cef

frame-relay switching

!

!

interface loopback 0

ip address 10.8.8.8 255.255.255.255

no shutdown

!

pseudowire-class ip

 encapsulation l2tpv3

 interworking ip

 ip local interface loopback0

!

interface POS1/0

encapsulation frame-relay

clock source internal

logging event dlci-status-change

no shutdown

no fair-queue

!

connect fr-vlan POS1/0 206 l2transport

 xconnect 10.9.9.9 6 pw-class ip

!

router ospf 10

 network 10.0.0.2 0.0.0.0 area 0

 network 10.8.8.8 0.0.0.0 area 0

configure terminal

ip routing

ip cef

frame-relay switching

!

interface loopback 0

ip address 10.9.9.9 255.255.255.255

no shutdown

!

pseudowire-class ip

 encapsulation l2tpv3

 interworking ip

 ip local interface loopback0

!

interface FastEthernet1/0/1

  speed 10

  no shutdown

!

interface FastEthernet1/0/1.6

encapsulation dot1Q 6

xconnect 10.8.8.8 6 pw-class ip

no shutdown

!

router ospf 10

 network 10.0.0.2 0.0.0.0 area 0

 network 10.9.9.9 0.0.0.0 area 0

The following example shows the configuration of Frame Relay to VLAN over AToM:

configure terminal

ip cef

frame-relay switching

!

mpls label protocol ldp

mpls ldp router-id loopback0

mpls ip

!

pseudowire-class atom

 encapsulation mpls

 interworking ip

!

interface loopback 0

 ip address 10.8.8.8 255.255.255.255

 no shutdown

!

connect fr-vlan POS1/0 206 l2transport

 xconnect 10.9.9.9 6 pw-class atom

configure terminal

ip routing

ip cef

frame-relay switching

!

mpls label protocol ldp

mpls ldp router-id loopback0

mpls ip

!

pseudowire-class atom

 encapsulation mpls

 interworking ip

!

interface loopback 0

 ip address 10.9.9.9 255.255.255.255

 no shutdown

!

interface FastEthernet1/0/1.6

 encapsulation dot1Q 6

 xconnect 10.8.8.8 6 pw-class atom

 no shutdown

Note	Frame Relay to ATM AAL5 is available only with AToM in IP mode.

The following example shows the configuration of Frame Relay to ATM AAL5 over AToM:

ip cef

frame-relay switching

mpls ip

mpls label protocol ldp

mpls ldp router-id loopback0 force

pseudowire-class fratmip

encapsulation mpls

interworking ip

interface Loopback0

ip address 10.33.33.33 255.255.255.255

interface serial 2/0

encapsulation frame-relay ietf

frame-relay intf-type dce

connect fr-eth serial 2/0 100 l2transport

xconnect 10.22.22.22 333 pw-class fratmip

interface POS1/0

ip address 10.1.7.3 255.255.255.0

crc 32

clock source internal

mpls ip

mpls label protocol ldp

router ospf 10

passive-interface Loopback0

network 10.33.33.33 0.0.0.0 area 10

network 10.1.7.0 0.0.0.255 area 10

ip cef

mpls ip

mpls label protocol ldp

mpls ldp router-id loopback0 force

pseudowire-class fratmip

encapsulation mpls

interworking ip

interface Loopback0

ip address 10.22.22.22 255.255.255.255

interface ATM 2/0

pvc 0/203 l2transport

encapsulation aa5snap

xconnect 10.33.33.33 333 pw-class fratmip

interface POS1/0

ip address 10.1.1.2 255.255.255.0

crc 32 

clock source internal

mpls ip

mpls label protocol ldp

router ospf 10

passive-interface Loopback0

network 10.22.22.22 0.0.0.0 area 10

network 10.1.1.0 0.0.0.255 area 10

The following example shows the configuration of VLAN to ATM AAL5 over AToM:

ip cef

!

mpls ip

mpls label protocol ldp

mpls ldp router-id Loopback0

!

pseudowire-class inter-ether

encapsulation mpls

interworking ethernet

!

interface Loopback0

 ip address 10.8.8.8 255.255.255.255

!

interface ATM1/0.1 point-to-point

pvc 0/100 l2transport

encapsulation aal5snap

xconnect 10.9.9.9 123 pw-class inter-ether

!

interface FastEthernet1/0

xconnect 10.9.9.9 1 pw-class inter-ether

!

router ospf 10

 log-adjacency-changes

 network 10.8.8.8 0.0.0.0 area 0

 network 10.1.1.1 0.0.0.0 area 0

ip cef

!

mpls ip

mpls label protocol ldp

mpls ldp router-id Loopback0

!

pseudowire-class inter-ether

 encapsulation mpls

 interworking ethernet

!

interface Loopback0

 ip address 10.9.9.9 255.255.255.255

!

interface FastEthernet0/0

 no ip address

!

interface FastEthernet0/0.1

encapsulation dot1Q 10

xconnect 10.8.8.8 123 pw-class inter-ether

!

router ospf 10

 log-adjacency-changes

 network 10.9.9.9 0.0.0.0 area 0

 network 10.1.1.2 0.0.0.0 area 0

The following example shows the configuration of Frame Relay to PPP over L2TPv3:

ip cef

ip routing

!

!

!

pseudowire-class ppp-fr

encapsulation l2tpv3

interworking ip

ip local interface Loopback0

!

interface Loopback0

 ip address 10.1.1.1 255.255.255.255

!

interface FastEthernet1/0/0

 ip address 10.16.1.1 255.255.255.0

!

interface Serial3/0/0

no ip address

encapsulation ppp

ppp authentication chap

!

ip route 10.0.0.0 255.0.0.0 10.16.1.2

!

xconnect 10.2.2.2 1 pw-class ppp-fr

ppp ipcp address proxy 10.65.32.14

ip cef 

ip routing

!

frame-relay switching

!

pseudowire-class ppp-fr

encapsulation l2tpv3

interworking ip

ip local interface Loopback0

!

interface Loopback0

 ip address 10.2.2.2 255.255.255.255

!

interface FastEthernet1/0/0

ip address 10.16.2.1 255.255.255.0

!

interface Serial3/0/0

no ip address

encapsulation frame-relay

frame-relay intf-type dce

!

ip route 10.0.0.0 255.0.0.0 10.16.2.2

!

connect ppp-fr Serial3/0/0 100 l2transport

 xconnect 10.1.1.1 100 pw-class ppp-fr

The following example shows the configuration of Frame Relay to PPP over AToM:

ip cef

ip routing

mpls label protocol ldp

mpls ldp router-id loopback0 force

!

!

!

pseudowire-class ppp-fr

encapsulation mpls

interworking ip

ip local interface Loopback0

!

interface Loopback0

 ip address 10.1.1.1 255.255.255.255

!

interface FastEthernet1/0/0

ip address 10.16.1.1 255.255.255.0

mpls ip

label protocol ldp

!

interface Serial3/0/0

 no ip address

 encapsulation ppp

 ppp authentication chap

 xconnect 10.2.2.2 1 pw-class ppp-fr

ppp ipcp address proxy 10.65.32.14 

!

ip route 10.0.0.0 255.0.0.0 10.16.1.2

ip cef 

ip routing

mpls label protocol ldp

mpls ldp router-id loopback0 force

!

frame-relay switching

!

pseudowire-class ppp-fr

encapsulation mpls

interworking ip

ip local interface Loopback0

!

interface Loopback0

 ip address 10.2.2.2 255.255.255.255

!

interface FastEthernet1/0/0

ip address 10.16.2.1 255.255.255.0

mpls ip

mpls label protocol ldp

!

interface Serial3/0/0

no ip address

encapsulation frame-relay

frame-relay intf-type dce

!

ip route 10.0.0.0 255.0.0.0 10.16.2.2

!

connect ppp-fr Serial3/0/0 100 l2transport

 xconnect 10.1.1.1 100 pw-class ppp-fr

The following example shows the configuration of Ethernet VLAN to PPP over AToM:

configure terminal

mpls label protocol ldp

mpls ldp router-id Loopback0

mpls ip

!

pseudowire-class ppp-ether

 encapsulation mpls

 interworking ip

!

interface Loopback0

 ip address 10.8.8.8 255.255.255.255

 no shutdown

!

interface POS2/0/1

 no ip address

 encapsulation ppp

 no peer default ip address

 ppp ipcp address proxy 10.10.10.1

 xconnect 10.9.9.9 300 pw-class ppp-ether  

 no shutdown

configure terminal

mpls label protocol ldp

mpls ldp router-id Loopback0

mpls ip

!

pseudowire-class ppp-ether

 encapsulation mpls

 interworking ip

!

interface Loopback0

 ip address 10.9.9.9 255.255.255.255

 no shutdown

!

interface vlan300

 mtu 4470

 no ip address

 xconnect 10.8.8.8 300 pw-class ppp-ether  

 no shutdown 

!

interface GigabitEthernet6/2

 switchport

 switchport trunk encapsulation dot1q

 switchport trunk allowed vlan 300

 switchport mode trunk

 no shutdown