Internet-Draft | PBB-EVPN ISID-based CMAC-flush | July 2023 |
Rabadan, et al. | Expires 6 January 2024 | [Page] |
Provider Backbone Bridging (PBB) can be combined with Ethernet Virtual Private Networks (EVPN) to deploy Ethernet Local Area Network (ELAN) services in large Multi-Protocol Label Switching (MPLS) networks (PBB-EVPN). Single-Active Multi-homing and per-I-SID (per Service Instance Identifier) Load-Balancing can be provided to access devices and aggregation networks. In order to speed up the network convergence in case of failures on Single-Active Multi-Homed Ethernet Segments, PBB-EVPN defines a flush mechanism for Customer MACs (C-MAC-flush) that works for different Ethernet Segment Backbone MAC (B-MAC) address allocation models. This document complements those C-MAC-flush procedures for cases in which no PBB-EVPN Ethernet Segments are defined (the attachment circuit is associated to a zero Ethernet Segment Identifier) and a Service Instance Identifier based (I-SID-based) C-MAC-flush granularity is required.¶
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[RFC7623] defines how Provider Backbone Bridging (PBB) can be combined with Ethernet Virtual Private Networks (EVPN) to deploy ELAN services in very large MPLS networks. [RFC7623] also describes how Single-Active Multi-homing and per-I-SID Load-Balancing can be provided to access devices and aggregation networks. When Access Ethernet/MPLS Networks exists, [I-D.ietf-bess-evpn-virtual-eth-segment] describes how virtual Ethernet Segments can be associated to a group of Ethernet Virtual Circuits (EVCs) or even Pseudowires (PWs). In order to speed up the network convergence in case of failures on Single-Active Multi-Homed Ethernet Segments, [RFC7623] defines a Customer MAC flush mechanism that works for different Ethernet Segment B-MAC address allocation models.¶
In some cases, the administrative entities that manage the access devices or aggregation networks do not demand Multi-Homing Ethernet Segments (ES) from the PBB-EVPN provider, but simply multiple single-homed ES. If that is the case, the PBB-EVPN network is no longer aware of the redundancy offered by the access administrative entity. Figure 1 shows an example where the PBB-EVPN network provides four different Attachment Circuits for I-SID1, with those Attachment Circuits not being part of any Ethernet Segment or virtual Ethernet Segment (therefore they are referred to as null virtual Ethernet Segment).¶
In the example in Figure 1, CE1, CE2 and CE3 are attached to the same service, identified by I-SID1, in the PBB-EVPN PEs. CE1 and CE2 are connected to the PEs via G.8032 Ethernet Ring Protection Switching, and their Attachment Circuits to PE1 and PE2 are represented by a port and VLAN identifier. CE3 is dual-homed to PE3 and PE4 through an active-standby PW, and its Attachment Circuit to the PEs is represented by a PW. Each of the four PEs uses a dedicated Backbone MAC address as source MAC address (B-MAC1, B-MAC2, B-MAC3 and B-MAC4, respectively) when encapsulating customer frames in PBB packets and forwarding those PBB packets to the remote PEs as per [RFC7623]. There are no multi-homed Ethernet Segments defined in the PBB-EVPN network of the example, that is why the four Attachment Circuits in Figure 1 show the text "ESI null", which means the Ethernet Segment Identifier on those Attachment Circuits is zero. Since there are no multi-homed ES defined, the PEs keep their Attachment Circuits active as long as the physical connectivity is established and the CEs are responsible for managing the redundancy, avoiding loops and providing per-I-SID load balancing to the PBB-EVPN network.¶
For instance, CE2 will block its link to CE1 and CE3 will block its forwarding path to PE4. In this situation, a failure in one of the redundant Attachment Circuits will trigger the CEs to start using their redundant paths, however those failures will not trigger any Customer MAC flush procedures in the PEs that implement [RFC7623], since the PEs are not using the PBB-EVPN multi-homing procedures. For example, if the active PW from CE3 (to PE3) fails, PE3 will not issue any Customer MAC flush message and therefore the remote PEs will continue pointing at PE3's Backbone MAC to reach CE3's Customer MACs, until the Customer MACs age out in the I-SID1 forwarding tables.¶
[RFC7623] provides a Customer MAC flush solution based on a shared Backbone MAC update along with the MAC Mobility extended community where the sequence number is incremented. However, the procedure is only used along with multi-homed Ethernet Segments. Even if that procedure could be used for null Ethernet Segments, as in the example of Figure 1, the [RFC7623] Customer MAC flush procedure would result in unnecessary flushing of unaffected I-SIDs on the remote PEs, and subsequent flooding of unknown unicast traffic in the network.¶
This document describes an extension of the [RFC7623] Customer MAC flush procedures, so that in the above failure example, PE3 can trigger a Customer MAC flush notification that makes PE1, PE2 and PE4 flush all the Customer MACs associated to PE3's B-MAC3 and (only) I-SID1. This new Customer MAC flush procedure explained in this document will be referred to as "PBB-EVPN I-SID-based C-MAC-flush" and can be used in PBB-EVPN networks with null or non-null (virtual) Ethernet Segments.¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
AC: Attachment Circuit.¶
B-Component: Backbone Component, as in [RFC7623].¶
B-MAC: Backbone MAC address.¶
B-MAC/0 route: an EVPN MAC/IP Advertisement route that uses a B-MAC in the MAC address field and a zero Ethernet Tag ID.¶
B-MAC/I-SID route: an EVPN MAC/IP Advertisement route that uses a B-MAC in the MAC address field and an I-SID in the Ethernet Tag field, and it is used to notify remote PEs about the required C-MAC-flush procedure for the C-MACs associated with the advertised B-MAC and I-SID.¶
CE: Customer Edge router.¶
C-MAC: Customer MAC address.¶
ES, vES and ESI: Ethernet Segment, virtual Ethernet Segment and Ethernet Segment Identifier.¶
EVI: EVPN Instance.¶
EVPN: Ethernet Virtual Private Networks, as in [RFC7432].¶
G.8032: Ethernet Ring Protection.¶
I-Component: Service Instance Component, as in [RFC7623].¶
I-SID: Service Instance Identifier.¶
MAC-VRF: A Virtual Routing and Forwarding table for MAC addresses.¶
PBB-EVPN: Provider-Backbone-Bridging and EVPN, as in [RFC7623].¶
PE: Provider Edge router.¶
RD: Route Distinguisher.¶
RT: Route Target.¶
The following requirements are followed by the C-MAC-flush solution described in this document:¶
The solution does not use any new BGP attributes but reuses the MAC Mobility extended community as an indication of C-MAC-flush (as in [RFC7623]) and encodes the I-SID in the Ethernet Tag field of the EVPN MAC/IP advertisement route. As a reference, Figure 2 shows the MAC Mobility extended community and the EVPN MAC/IP advertisement route that are used specified in [RFC7432] and used in this document as a C-MAC-flush notification message.¶
Where:¶
All the other fields are set and used as defined in [RFC7623]. This document will refer to this route as the B-MAC/I-SID route, as opposed to the EVPN MAC/IP Advertisement route used in [RFC7623] that contains a B-MAC and the Ethernet Tag ID set to zero. This document uses the term B-MAC/0 route to represent a B-MAC route advertised with Ethernet Tag ID = 0.¶
Note that this B-MAC/I-SID route will be accepted and reflected by any [RFC7432] RR, since no new attributes or values are used. A PE receiving the route will process the received B-MAC/I-SID update only in case of supporting the procedures described in this document.¶
Figure 1 will be used in the description of the solution. CE1, CE2 and CE3 are connected to ACs associated to I-SID1, where no (Multi-Homed) Ethernet Segments have been enabled, and the ACs and PWs are in active or standby state as per Figure 1.¶
Enabling or disabling I-SID-based C-MAC-flush SHOULD be an administrative choice on the system that MAY be configured per I-SID (I-Component). When enabled on a PE:¶
When I-SID-based C-MAC-flush is disabled, the PE will follow the [RFC7623] procedures for C-MAC-flush.¶
This C-MAC-flush specification is described in three sets of procedures:¶
The following behavior MUST be followed by the PBB-EVPN PEs following this specification. Figure 1 is used as a reference.¶
If, for instance, there is a failure on PE1's AC, PE1 will generate an update including B-MAC1/1 along with the MAC Mobility extended community where the Sequence Number has been incremented. The reception of the B-MAC1/1 with a delta in the sequence number will trigger the C-MAC-flush procedures on the receiving PEs.¶
A PE receiving a C-MAC-flush notification will follow these procedures:¶
Note that the C-MAC-flush procedures described in [RFC7623] for B-MAC/0 routes are still valid and a PE receiving [RFC7623] C-MAC-flush notification messages MUST observe the behavior specified in [RFC7623].¶
The I-SID-based C-MAC-flush solution described in this document has the following benefits:¶
Security considerations described in [RFC7623] apply to this document.¶
In addition, this document suggests additional procedures, that can be activated on a per I-SID basis, and generate additional EVPN MAC/IP Advertisement routes in the network. The format of these additional EVPN MAC/IP Advertisement routes is backwards compatible with [RFC7623] procedures and should not create any issues on receiving PEs not following this specification, however, the additional routes may consume extra memory and processing resources on the receiving PEs. Because of that, it is RECOMMENDED to activate this feature only when necessary (when multi-homed networks or devices are attached to the PBB-EVPN PEs), and not by default in any PBB-EVPN PE.¶
This document requests no actions from IANA.¶
The authors want to thank Vinod Prabhu, Sriram Venkateswaran, Laxmi Padakanti, Ranganathan Boovaraghavan for their review and contributions.¶