Network Working Group P. Marques
Internet-Draft Juniper Networks
Intended status: Standards Track L. Fang
Expires: March 22, 2015 Microsoft
N. Sheth
Juniper Networks
M. Napierala
AT&T Labs
N. Bitar
Verizon
September 18, 2014

BGP-signaled end-system IP/VPNs.
draft-ietf-l3vpn-end-system-03

Abstract

This document describes a solution in which the control plane protocol specified in BGP/MPLS IP VPNs [RFC4364] is used to provide a Virtual Network service to end-systems. These end-systems may be used to provide network services or may directly host end-to-end applications.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at http://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."

This Internet-Draft will expire on March 22, 2015.

Copyright Notice

Copyright (c) 2014 IETF Trust and the persons identified as the document authors. All rights reserved.

This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.


Table of Contents

1. Introduction

This document describes the requirements for a network virtualization solution that provides an IP service to end-system virtual interfaces. It then discusses how the BGP IP VPNs [RFC4364] control plane can be used to provide a solution that meets these requirements. Subsequent sections provide a detailed discussion of the control and forwarding plane components.

In BGP IP VPNs, Customer Edge (CE) interfaces connect to a Provider Edge (PE) device which provides both the control plane and VPN encapsulation functions required to implement a Virtual Network service. This document decouples the control plane and forwarding functionality of the PE device in order to enable the forwarding functionality to be implemented in multiple devices. For instance, the forwarding function can be implemented directly on the operating system of application servers or network appliances.

1.1. Terminology

This document makes use of the following terms:

End-System:
A compute node which primary function is to run applications. It is assumed that end-systems support multiple application instances (e.g. virtual-machines), each with its independent network configuration.
End-System Route Server:
A software application that implements the control plane functionality of a BGP IP VPN PE device and a XMPP server that interacts with VPN Forwarders.
Virtual Interface:
An interface in an end-system that is used by a virtual machine or by applications. It performs the role of a CE interface in a BGP IP VPN network.
VPN Forwarder:
The forwarding component of a BGP IP VPN PE device. This functionality may be co-located with the virtual interface or implemented by an external device.

2. Requirements

Network Virtualization is used in both service provider as well as enterprise networks to support multi-tenancy and network-based access control. It may also be used to facilitate application instance mobility.

Multi-tenancy allows a physical network to provide services to multiple "customers" or "tenants", whether these are external entities in the case of a Service Provider providing managed VPN services or internal departments sharing an IT facility. Multi-tenancy requires isolation of traffic and routing information between tenants.

Within a tenant, it is often required to create multiple distinct virtual networks, in order to be able to provide network-based access control. In this service model, each virtual network behaves as a "Closed User Group" (CUG) of virtual interfaces that are allowed to exchange traffic freely, while traffic between virtual networks is subject to access controls. This scenario can be found in both enterprise campus networks, branch offices and data-centers.

It is often the case when network access control is used, that the traffic patterns are such that there is significantly more traffic crossing a CUG boundary than staying within such boundary. As an example, in campus networks it is common to segregate users into CUGs based on some classification such as the user's department. Campus networks often see traffic patterns in which almost all the traffic flows northbound to the data-center or internet boundaries. Similar traffic patterns can be found in multi-tier applications in IT data-centers.

Virtual interfaces are often configured to expect the concept of IP subnet to match its closed user group. A network virtualization solution should be able to provide this concept of IP subnet regardless of whether the underlying implementation uses a multi-access network or not.

Virtual interfaces should be able to directly access multiple closed user groups without needing to traverse a gateway. Network access policy should allow this access whether the source and destination CUGs for a particular traffic flow belong to the same tenant or different tenants. It is often the case that infrastructure services are provided to multiple tenants. One such example is voice-over-IP gateway services for branch offices.

Independently, but often associated with the previous two functions, IP mobility is another network function that can be implemented using network virtualization. By abstracting the externally visible network address from the underlying infrastructure address, mobility can be implemented without having to recur to home agents or large L2 broadcast domains.

IP Mobility requires the ability to "move" a virtual interface without disrupting its TCP (or UDP) transport sessions. This requires a mechanism that can efficiently communicate the mappings between logical and physical addressing.

IP Mobility can be a result of devices physically moving (e.g., a WiFi enabled laptop) or workload being diverted between physical systems such as network appliances or application servers.

3. Applicability of BGP IP VPNs

BGP IP VPNs [RFC4364] is the industry de-facto standard for providing "closed user group" functionality in WAN environments. It is used by service providers in environments where several millions of routes are present. It supports both isolated VPNs as well as overlapping VPNs (often referred to as "extranets").

The BGP IP VPN control plane has been designed to be able to distribute the mapping between virtual address and location (next-hop) to the subset of network nodes for which this information is relevant, whenever that mapping changes. This provides an efficient mechanism to address IP mobility requirements as compared to methods that depend on a (cached) mapping request from the end-systems.

In its traditional usage in Service Provider networks, BGP IP VPN functionality is implemented in a Provider Edge (PE) device that combines both BGP signaling as well as VRF-based forwarding functions. In practice, most PE devices in current use are multi-component systems with the signaling and forwarding functionality actually implemented in different processors attached to an internal network.

This document assumes a similar separation of functionality in which software appliances, the End-System Route Servers, implement the control plane functionality of a PE device and a VPN Forwarder implements the forwarding function usually found in a PE device "line-card". The VPN Forwarder functionality may be co-located with the end-system (e.g., implemented in the hypervisor switch or host OS network drivers) or it may be external. For instance, residing in a data-center switch or specialized appliance.

Operationally, BGP IP VPN technology has several important characteristics:

The last point is particularly relevant to the convergence characteristics required for large scale deployments. BGP's hierarchical route distribution capabilities allow a deployment to divide the workload by increasing the number of End-System Route Servers.

As an example consider a topology in which 100 End-System Route Servers are deployed in a network each serving a subset of the VPN forwarding elements. The Route Servers inter-connect to two top-level BGP Route Reflectors [RFC4456].

If an event (i.e. a VPN route change) needs to be propagated from a specific end-system to 10,000 clients randomly distributed across the network, each of the End-System Route Servers must generate 100 updates to its respective downstream clients.

By modifying this topology such that another 100 End-System Route Servers are added, then each Route Server is now responsible to generate 50 client updates. This example illustrates the linear scaling properties of BGP: doubling the number of Route Servers (i.e. the processing capacity) reduces in half the number of updates generated by each (i.e. load at each processing node).

The same horizontal scaling techniques can be applied to the Route Reflector layer in the example above by subsetting the VPN Route space according to some pre-defined criteria (for instance VPN route target) and using a pair of Route Reflectors per subset.

In the previous example we assumed a dense membership in which all Route Servers have local clients that are interested in a particular event. BGP also optimizes the route distribution for sparse events. The Route Target Constraint [RFC4684] extension, builds an optimal distribution tree for message propagation based on VPN membership. It ensures that only the PEs with local receivers for a particular event do receive it also decreasing the total load on the upstream BGP speaker.

In the WAN environment, BGP IP VPN control plane scaling is focused not primarily on route convergence times but on memory footprint of embedded devices. While memory footprint does not have a similar linear scaling behavior, memory technology available to software appliances is often at 10x the scale of what is commonly found in WAN environments.

The functionality present in the BGP IP VPN control plane addresses the requirements specified in the previous section. Specifically, it supports multiple potentially overlapping "groups", regular or "hub and spoke" topologies and the scaling characteristics necessary.

The BGP IP VPN control plane supports not only the definition of "closed user-groups" (VPNs in its terminology) but also the propagation of inter-VPN traffic policies [RFC5575].

Note that the signaling protocol itself is rather agnostic of the encapsulation used on the wire as long as this encapsulation has the ability to carry a 20 bit label.

Several network environments use a network infrastructure that is only capable of providing an IP unicast service. In order to support them, implementations of this document should support the MPLS in GRE [RFC4023] encapsulation. Other encapsulations are possible, including UDP based encapsulations [I-D.ietf-mpls-in-udp].

4. Virtual network end-points

This document assumes that end-systems support one or more virtual network interfaces in addition to a physical interface that is associated with the underlying network infrastructure. Virtual network interfaces can be associated with a restricted list of applications via OS-dependent mechanisms, a Virtual Machine (VM), or they can be used to provide network connectivity to all user applications in the same way that a "VPN tunnel" interface is used to provide access between an end-system (e.g., a laptop) and a remote corporate network.

From an IP address assignment point of view, a virtual network interface is addressed out of the virtual IP topology and associated with a "closed user group" or VPN, while the physical interface of the machine is addressed in the network infrastructure topology.

A virtual network interface is connected to a VPN Forwarder. This VPN Forwarder MAY be co-located in the end-system or external.

Both static and dynamic IP address allocation can be supported. The later assumes that the VPN Forwarder implements a DHCP relay or DHCP proxy functionality.

Traffic that ingresses or egresses through a virtual network interface is routed at the VPN Forwarder which acts as the first-hop router (in the virtual topology). The IP configuration on the client side of this virtual network interface (e.g., in the guest OS) can follow one of two models:

In a point-to-point interface model, the VPN client routing table (e.g., on the guest OS) contains the following routing entires: a host route to the local IP address, a host route to the first-hop router via the virtual interface and a default route to the first-hop router. This is the model typically used in "VPN tunnel" configurations or other access technologies such as cable deployments or DSL. When this model is used, the first-hop router IP address is a link-local address that is the same on all first-hop routers across a specific deployment. This first-hop IP address should not change when a virtual interface moves between different machines.

In a multi-point interface model, the VPN client routing table (e.g., on the guest OS) contains the following routing entires: a host route to the local IP address, a subnet route to the local interface and optionally a default route to a specific router address within that subnet. In this model, the VPN client IP stack will issue address resolution requests for any IP addresses it considers to be directly attached to the subnet. The VPN Forwarder shall answer all address resolution requests with a virtual MAC address which SHOULD be the same across all VPN Forwarders in a specific deployment. This virtual MAC address SHALL default to the VRRP [RFC5798] virtual router MAC address for Virtual Router Identifier (VRID) 1.

When the virtual topology first-hop router resides on the same physical machine, the host OS is responsible to map the virtual interface with a VPN specific routing table (without taking L2 addresses into consideration). In this case the mac-addresses known to the guest OS are not used on the wire.

When the virtual topology first-hop router resides in an external system (e.g., the first hop-switch) the virtual interface shall be identified by the combination of the mac-address assigned to physical interface of the end-system and a 802.1Q VLAN tag. The first-hop switch should use a virtual router MAC address to answer any address resolution queries.

Whenever an external VPN Forwarder is used and resiliency is desired, the external VPN Forwarder should be redundant. It is desirable to use VRRP as a mechanism to control the flow of traffic between the end-system and the external VPN Forwarder. VRRP already defines the necessary procedures to elect a single forwarder for a LAN.

This specification uses the VRRP virtual router MAC address as the default L2 address for the VPN Forwarder as a client virtual interface may move between locations where redundancy may not be present.

While the VRRP Virtual Router MAC will be used to answer any address resolution request made by the virtual interface client (e.g., the guest VM) this does not imply that a single default router is elected per virtual IP subnet. The ingress VPN Forwarder will perform an IP forwarding decision based on the destination IP address of the (payload) traffic.

VRRP router election is only relevant in selecting the VPN Forwarder associated with a specific machine, when external forwarders are in use.

5. VPN Forwarder

In this solution, the Host OS/Hypervisor in the end-system must participate in the virtual network service. Given an end-system with multiple virtual interfaces, these virtual interfaces must be mapped onto the network by the guest OS such that applications on one virtual interface are not send traffic to networks they are not authorized to communicate with or using source addresses not assigned to the virtual interface.

When VPN forwarder functionality is implemented by the Host OS/Hypervisor, intermediate systems in the network do not require any knowledge of the virtual network topology. This can simplify the design and operation of the physical network.

When it is not possible or desirable to add the VPN forwarding functionality to the end-system, it may be implemented by an external system, typically located as close as possible to the end-system itself.

Both models, co-located and external VPN Forwarder can co-exist in a deployment.

In order to implement the BGP IP VPN Forwarder functionality a device MUST implement the following functionality:

The VPN Forwarder MAY support the ability to associate multiple virtual interfaces with the same VRF. When that is the case, locally originated routes, that is IP routes to the local virtual interfaces SHALL NOT be used to forward outbound traffic (from the virtual interfaces to the outside) unless a route advertisement has been received that matches that specific IP prefix and next-hop information.

As an example, if a given VRF contains two virtual interfaces, "veth0" and "veth1", with the addresses 10.0.1.1/32 and 10.0.1.2/32 respectively, the initial forwarding state must be initialized such that traffic from either of these interfaces does not match the other's routing table entry. It may for instance match a default route advertised by a remote system. Traffic received from other VPN Forwarders, however, must be delivered to the correct local interface. If at a subsequent stage a route is received from the Route Server such that 10.0.1.2/32 has a next-hop with the IP address of the local host and the correct label, the system may subsequently install a local routing table entry that delivers traffic directly to the "veth1" interface. This means that forwarding table entries apply to downstream only by default. This capability can be used to implement a hub-and-spoke topology, if required.

The 20-bit label which is associated with a virtual-interface is of local significance only and SHOULD be allocated by the VPN Forwarder.

When an external VPN Forwarder is used the end-system MUST associate each virtual interface with a VLAN [IEEE.802-1Q] that is unique on the end-system. The switching infrastructure MUST be configured such that multi-destination frames sourced from an end-system are only delivered to VPN Forwarders used by this end-system and not to other end-systems.

6. XMPP signaling protocol

End-System Route Servers must be aware of VPN membership on each Forwarder as well as what IP addresses are currently associated with each virtual interface.

VPN Forwarders must receive VPN route information from which to populate their forwarding tables. External VPN Forwarders also need to receive the virtual interface and IP address events from the end-system for which they are VPN forwarders. In this case the end-system assigns an 802.1Q VLAN tag to each virtual interface and communicates that information to the Forwarder.

In order to exchange this information this specification uses the XMPP [RFC6120] protocol along with the Publish-Subscribe [pubsub] extension.

VPN forwarders (both co-located and external) establish XMPP sessions with End-System Route Servers, acting as XMPP clients. When an external VPN Forwarder is used, end-systems establish XMPP sessions with VPN Forwarders. External VPN Forwarders act as XMPP servers for end-systems which are associated with them.

A VPN Forwarder MAY connect to multiple End-System Route Servers for reliability. In this case it SHOULD publish its information to each of the Route Servers. It MAY choose to subscribe to VPN routing information once only from one of the available gateways.

The information advertised by an XMPP client SHOULD be deleted after a configurable timeout, when the session closes. This timeout should default to 60 seconds.

                +---------+             +--------+
                |    RS   | ----------- |  BGP   |
                +---------+             +--------+
                //          \          /
              XMPP           \        /
              //              \      /
+------------+                 \    /
| end-system |                  \  /
+------------+                   \/
              \\                 /\
              XMPP              /  \
                \\             /    \
                +---------+   /      \  +--------+
                |    RS   | ----------- |  BGP   |
                +---------+             +--------+

The figure above represents a typical configuration in which an end-system with a co-located VPN Forwarder is directly connected to two End-System Routes Servers, which are in turn connected to multiple BGP speakers which may be other L3VPN PEs or BGP route reflectors.

In deployment the number of End-System Route Servers used will depend on the desired Route Server to VPN Forwarder ratio which affects the convergence time of event propagation.

The XMPP "jid" used by the client shall be a string that uniquely identifies it in its administrative domain. This specification recommends the use of the hostname (when unique) or an IP address in its string representation.

Each VPN shall be identified by a 128 octet ASCII character string.

When external Forwarders are used, its control software operates as a XMPP server processing requests from end-systems and as a client of one or more End-System Route Servers. The control software relays to the End-System Route Server(s) VPN membership messages it receives from the end-system. VPN routing information received from the Route Server(s) SHOULD NOT be propagated to the end-system.

When a virtual interface is created on a end-system, the host operating-system software shall generate an XMPP Subscribe message to its server (the End-System Route Server or external VPN Forwarder).

Subscription request from co-located VPN Forwarder to Route Server:

<iq type='set'
    from='hostname.domain.org'
    to='network-control@domain.org'
    id='sub1'>
  <pubsub xmlns='http://jabber.org/protocol/pubsub'>
    <subscribe node='vpn-customer-name'/>
    <options>
      <instance-id>1</instance-id>
    </options>
  </pubsub>
</iq>

The request above, instructs the End-System Route Server to start populating the client's VRF table with any routing information that is available for this VPN. The XMPP node 'vpn-customer-name' is assumed to be implicitly created by the End-System Route Server. Creation of a virtual interface may precede any IP address becoming active on the interface, as it is the case with VM instantiation.

The optional "instance-id" element allows the VPN Forwarder to specific an unique 16 bit index that can be used by the Route Server to automatically assign a Route Distinguisher (RD) to any route subsequently advertised by the VPN Forwarder. In a scenario where the VPN Forwarder is advertising reachability information to multiple Route Servers it is desirable for reachability information to have an RD composed of the VPN Forwarder identifier (e.g. IPv4 address) and the "instance-id".

Subscription request from end-system to external VPN Forwarder:

<iq type='set'
    from='hostname.domain.org'
    to='network-control@domain.org'
    id='sub1'>
  <pubsub xmlns='http://jabber.org/protocol/pubsub'>
    <subscribe node='vpn-customer-name'/>
    <options>
      <x xmlns='jabber:x:data' type='submit'>
        <field var='vpn#vlan_id'><value>vlan-id</value></field>
      </x>
    </options>
  </pubsub>
</iq>

When an external VPN Forwarder is used the end-system should include the VLAN identifier it assigned to the virtual interface as a subscription option.

When a IP address is added to a virtual interface, the end-system will generate an XMPP Publish request.

Publish request from VPN Forwarder to End-System Route Server:

<iq type='set'
    from='hostname.domain.org'	<!-- end-system jid -->
    to='network-control@domain.org'
    id='request1'>
  <pubsub xmlns='http://jabber.org/protocol/pubsub'>
    <publish node='vpn-customer-name'>
      <item id='x.x.x.x:y:vpn-ip-address/32'>
        <entry xmlns='http://ietf.org/protocol/bgpvpn'>
          <nlri>
	    <af>1</af>
	    <address>'vpn-ip-address/32'</address>
	  </nlri>
	  <next-hops>
	    <next-hop>
	      <af>1</af>
	      <address>'infrastructure-ip-address'</address>
	      <label>10000</label>	<!-- 20 bit number -->
	    </next-hop>
	  </next-hops>
          <sequence-number>1</sequence-number>
        </entry>
       </item>
    </publish>
  </pubsub>
</iq>

The End-System Route Server will convert the information received in a the 'publish' request into the corresponding BGP route information such that:.

Conversely, when an interface operational status is determined to be down or an IP address is unconfigured the VPN forwarder generates an XMPP retract message to withdraw the route advertisement.

Retract request from VPN Forwarder to End-System Route Server:

<iq type='set'
    from='hostname.domain.org'
    to='network-control@domain.org'
    id='retract1'>
  <pubsub xmlns='http://jabber.org/protocol/pubsub'>
    <retract node='vpn-customer-name'>
      <item id='x.x.x.x:y:vpn-ip-address/32'>
    </retract>
  </pubsub>
</iq>

Update notification from Route Server to VPN Forwarder:

<message to='hostname.domain.org' from='network-control@domain.org'>
  <event xmlns='http://jabber.org/protocol/pubsub#event'>
    <items node='vpn-customer-name'>
      <item id='x.x.x.x:y:vpn-ip-address/32'>
        <entry xmlns='http://ietf.org/protocol/bgpvpn'>
          <nlri>
            <af>1</af>
            <address>'vpn-ip-address>/32'</address>
          </nlri>
          <next-hops>
            <next-hop>
              <af>1</af>
              <address>'infrastructure-ip-address'</address>
              <label>10000</label>      <!-- 20 bit number -->
            </next-hop>
          </next-hops>
          <sequence-number>1</sequence-number>
        </entry>
       </item>
      <item >
        ...
      </item>
    </items>
  </event>
</message>

Notifications should be generated whenever a VPN route is added, modified or deleted.

Note that the Update from the Route Server to the VPN Forwarder does not contain the "jid" of the destination end-system. The "from" attribute in the 'message' element contains a "jid" associated with the Route Servers in the domain. The XMPP messages are point-to-point in nature, between a Forwarder and Route Server. Even in the case when one XMPP publish request from a Forwarder may cause the Route Server to generate one or more event notifications.

When multiple possible routes exist for a given VPN IP address within a VRF it is the responsibility of the Route Server to select the best path to advertise to the Forwarder.

When routes are withdrawn, the End-System Route Server generates an item "retract" request.

Route advertisements can have an optional sequence-number which help the route server determine the most recent route advertisement. The sequence number is detemined by an mechanism external to this document. One example is to use time synchronization between compute nodes to have a globally coordinated timestamp. This timestamp can be used to identify the time of interface creation on the compute node.

Routes can also be associated with a "local-preference" attribute. This attribute mapps to the BGP attribute of the same name for the purposes of route selection.

7. End-System Route Server behavior

End-System Route Servers SHALL support the BGP address families: VPN-IPv4 (1, 128), VPN-IPv6 (2, 128) and RT-Constraint (1, 132) [RFC4684].

When an End-System Route Server receives a request to create or modify a VPN route it SHALL generate a BGP VPN route advertisement with the corresponding information.

It is assumed that the End-System Route Servers have information regarding the mapping between the tuple ('end-system', 'vpn-customer-names') and BGP Route Targets used to import and export information from the associated VRFs. This mapping is known via an out-of-band mechanism not specified in this document.

Whenever the End-System Route Server receives an XMPP subscription request, it SHALL consult its RT-Constraint Routing Information Base (RIB). If the Route Server does not have a locally originated RT-Contraint route that corresponds to the vpn-name present in the request, it SHALL create one and generate the corresponding BGP route advertisement. This route advertisement should only be withdrawn when there are no more downstream XMPP clients subscribed to the VPN.

End-System Route Servers SHOULD automatically assign a BGP route distinguisher per VPN routing table.

8. Operational Model

In the simplest case, a VPN is a collection of systems that are allowed to exchange traffic with each other and only with each other. Since all the forwarding tables in this VPN have the same routing entries they are often referred to as symmetrical VPNs.

In order to better illustrate the operation of the protocol we consider a simple example in which "host 1" and "host 2" both contain a virtual interface that is a member of the same VPN.

Each of these hosts has an XMPP session with an End-System Route Server, RS1 and RS2 our example, and these Route Servers are part of the same BGP mesh.

When a virtual interface is created on "host 1", the local XMPP client generates a XMPP subscription message to its respective Route Server. This message contains a VPN identifier that has been assigned by the provisioning system. The Route Server maps that identifier to a BGP IP VPN configuration which contains the list of import and export route targets to be used for that particular VRF.

Once the interface is operational, "host 1" will publish any IP addresses that are configured on the respective virtual interface. This will in turn cause the End-System Route Server to advertise these (directly or indirectly) to any other BGP speaker on the network which is connected to an attachment point of that VPN.

+--------+       +------------+       +----------+
| host 1 | <===> | End-System | <===> | BGP mesh |
+--------+       |Route Server|       +----------+
                 +------------+

Figure 1

VPN IP address NEXT-HOP label Known via
10.1.1.1/32 192.168.1.1 10000 XMPP
10.1.1.2/32 192.168.2.1 20000 BGP

VPN Routing table on Route Server

The figure above represents the contents of the VRF routing table on RS1 after the IPv4 address 10.1.1.1 has been added to the virtual interface on host 1. It assumes that there is another attachement point for this VPN with the IPv4 address of 10.1.1.2. Host 1 has an infrastructure IP address of 192.168.1.1 configured on its physical interface while host 2 has IP address 192.168.2.1.

The contents of the VRF routing table in the End-System Route Servers are advertised via XMPP Update notifications sent to host 1. This information is the used by the host to populate the forwarding table associated with that VPN.

               +--------+                 +--------+
app -- veth0 --| host 1 |=== [network] ===| host 2 |-- veth0 -- app
               +--------+                 +--------+

 IP pkt  ===> GRE encap  ===> [IP net] ===> GRE decap ===> IP pkt
           [192.168.2.1, 20]               map 20 to veth0

Figure 2

VPN IP address Host address label
10.1.1.1/32 localhost 10000
10.1.1.2/32 192.168.2.1 20000

VRF table on host1

When an application that uses the virtual interface on host 1 generates packets with a destination IP address of 10.1.1.2 these are routed by the VPN Forwarder implemented in the Host OS. The packets are encapsulated with a header that contains a 20-bit label assigned by host 2.

In the case the virtual interface on host is associated with a guest OS, this guest OS has had its address resolution queries answered with the Virtual Router MAC address. As a result, that is the address it uses as the destination MAC address in packets it originates. This MAC address is not present on the encapsulated packet.

End-System Route Servers are software applications that implement both the BGP IP VPN PE control plane as well as XMPP server functionality. These applications are not in the forwarding plane and do not need to be co-located with a network device.

Network devices MAY have direct BGP sessions to the End-System Route Servers. For instance, a router or security appliance that supports BGP/MPLS IP VPNs over GRE may use its existing functionality to inter-operate directly with a collection of Virtual Machines or other network appliances that support this specification.

End-System Route Servers implement the VRF import policy and export policy functionality that is associated with PE routers in standard BGP IP/VPN deployments. VPN Forwarders receive forwarding information after policy and route selection is applied. These are unqualified routes in a specific VRF rather than VPN routing information qualified by a Route Distinguisher and with a set of Route Targets.

A symmetrical VPN uses a vrf import and vrf export polices that contain a single route target, where the route target used for both import and export is the same.

Different VPN topologies can be created by manipulating the vrf import and export configuration including "hub-and-spoke" topologies or overlapping VPNs.

An example of a hub-and-spoke VPN configuration is one where all the traffic from the VPN clients must be redirected though a middle-box for inspection. Assuming that the virtual interfaces of a particular user are configured to be in the VPN "tenant1". At an initial stage this "tenant1" VPN is symmetrical and uses a single Route Target in both its import and export policies. The middle-box functionality can be incrementally deployed by defining a new VPN, "tenant1-hub", and an associated Route Target. Accompanied with a change in the End-System Route Server configuration such that VPN "tenant1" only imports routes with the Route Target associated with the hub. The "hub" VPN is assumed to advertise a prefix that covers all the VPN clients IP addresses. The "hub" VPN imports the VPN routes in order for it to be able to generate the XMPP updates to the "hub" end-system. This information is required for the return traffic from the hub to the spokes (the VPN clients). In such a scenario a single physical interface can connect the middle-box to the clients in a given VPN which appear logically as downstream from it. Such a middle-box would often require connectivity to multiple VPNs, such as for instance an "outside" VPN which provides external connectivity to one or more "inside" VPNs.

The functionality defined in this document in which the BGP IP VPN PE functionality is split into its control (End-System Route Servers) and forwarding (VPN Forwarder) components is fully interoperable with existing BGP IP VPN PEs.

This makes it possible to reuse existing systems. For example, at the edge of a data-center facility it may be desirable to use an existing router or appliance that aggregates IP VPN routing information and/or provides IP based services such as stateful packet inspection.

Such a system can be configured, based on existing functionality, to suppress more specific routes than a specified aggregate while advertising the aggregate with a BGP NEXT_HOP containing the PE's IP address and a locally assigned label corresponding to a VRF where the more specific routes are present.

9. Security Considerations

The signaling protocol defines the access control policies for each virtual interface and any guest application associated with it. It is important to secure the end-system access to End-System Route Servers and the BGP infrastructure itself.

The XMPP session between end-systems and the Route Servers MUST use mutual authentication. One possible strategy is to distribute pre-signed certificates to end-systems which are presented as proof of authorization to the Route Server.

BGP sessions MUST be authenticated. This document recommends that BGP speaking systems filter traffic on port 179 such that only IP addresses which are known to participate in the BGP signaling protocol are allowed.

As a security measure, it is recommended that virtual and infrastructure topologies never be allowed to exchange traffic directly. The infrastructure network containing the end-systems is typically isolated from the outside world.

10. XML schema

The following schema defines the XML elements that are used to communicate unicast reachability information between the Route Server and VPN Forwarder:

<xsd:schema xmlns:xsd="http://www.w3.org/2001/XMLSchema"
    xsd:targetNamespace=
        "http://www.ietf.org/bgp-l3vpn-unicast.xsd">

<xsd:simpleType name="TunnelEncapsulationType">
    <xsd:restriction base="xsd:string">
        <xsd:enumeration value="gre"/>
        <xsd:enumeration value="udp"/>
        <xsd:enumeration value="vxlan"/>
    </xsd:restriction>
</xsd:simpleType>

<xsd:complexType name="TunnelEncapsulationListType">
    <xsd:element name="tunnel-encapsulation"
        type="TunnelEncapsulationType"
        maxOccurs="unbounded"/>
</xsd:complexType> 

<xsd:complexType name="NextHopType">
    <xsd:element name="af" type="xsd:integer"/>
    <xsd:element name="address" type="xsd:string"/>
    <xsd:element name="label" type="xsd:integer"/>
    <xsd:element name="tunnel-encapsulation-list"
        type="TunnelEncapsulationListType"/>
</xsd:complexType>

<xsd:complexType name="NextHopListType">
    <xsd:element name="next-hop" type="NextHopType"
        maxOccurs="unbounded"/>
</xsd:complexType>

<xsd:complexType name="IPAddressType">
    <xsd:element name="af" type="xsd:integer"/>
    <xsd:element name="safi" type="xsd:integer"/>
    <xsd:element name="address" type="xsd:string"/>
</xsd:complexType>

<xsd:complexType name="EntryType">
    <xsd:all>
        <xsd:element name="nlri" type="IPAddressType"/>
        <xsd:element name="next-hops" type="NextHopListType"/>
        <xsd:element name="sequence-number" type="xsd:integer"/>
	<xsd:element name="local-preference" type="xsd:integer"/>
    </xsd:all>
</xsd:complexType>

<xsd:complexType name="ItemType">
    <xsd:element name="entry" type="EntryType"/>
</xsd:complexType>

<xsd:complexType name="ItemsType">
    <xsd:all>
        <xsd:element name="item" type="ItemType"
            maxOccurs="unbounded"/>
    </xsd:all>
</xsd:complexType>

<xsd:element name="items" type="ItemsType"/>

</xsd:schema>

11. Acknowledgements

Yakov Rekhter has contributed to this document by providing detailed feedback and suggestions. The authors would also like to thank Thomas Morin for his comments.

Amit Shukla and Ping Pan contributed to earlier versions of this document.

12. References

12.1. Normative References

[RFC4023] Worster, T., Rekhter, Y. and E. Rosen, "Encapsulating MPLS in IP or Generic Routing Encapsulation (GRE)", RFC 4023, March 2005.
[RFC4271] Rekhter, Y., Li, T. and S. Hares, "A Border Gateway Protocol 4 (BGP-4)", RFC 4271, January 2006.
[RFC4364] Rosen, E. and Y. Rekhter, "BGP/MPLS IP Virtual Private Networks (VPNs)", RFC 4364, February 2006.
[RFC4456] Bates, T., Chen, E. and R. Chandra, "BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP)", RFC 4456, April 2006.
[RFC4684] Marques, P., Bonica, R., Fang, L., Martini, L., Raszuk, R., Patel, K. and J. Guichard, "Constrained Route Distribution for Border Gateway Protocol/MultiProtocol Label Switching (BGP/MPLS) Internet Protocol (IP) Virtual Private Networks (VPNs)", RFC 4684, November 2006.
[RFC5798] Nadas, S., "Virtual Router Redundancy Protocol (VRRP) Version 3 for IPv4 and IPv6", RFC 5798, March 2010.
[RFC6120] Saint-Andre, P., "Extensible Messaging and Presence Protocol (XMPP): Core", RFC 6120, March 2011.
[pubsub] Millard, P., Saint-Andre, P. and R. Meijer, "Publish-Subscribe", XEP 0060, July 2010.

12.2. Informational References

[RFC5575] Marques, P., Sheth, N., Raszuk, R., Greene, B., Mauch, J. and D. McPherson, "Dissemination of Flow Specification Rules", RFC 5575, August 2009.
[I-D.ietf-mpls-in-udp] Xu, X., Sheth, N., Yong, L., Pignataro, C. and F. Yongbing, "Encapsulating MPLS in UDP", Internet-Draft draft-ietf-mpls-in-udp-05, January 2014.
[IEEE.802-1Q] Institute of Electrical and Electronics Engineers, "Local and Metropolitan Area Networks: Virtual Bridged Local Area Networks", IEEE Std 802.1Q-2005, May 2006.

Authors' Addresses

Pedro Marques Juniper Networks 1133 Innovation Way Sunnyvale, CA 94089 EMail: roque@juniper.net
Luyuan Fang Microsoft 5600 148th Ave NE Redmond, WA 98052 EMail: lufang@microsoft.com
Nischal Sheth Juniper Networks 1133 Innovation Way Sunnyvale, CA 94089 EMail: nsheth@juniper.net
Maria Napierala AT&T Labs 200 Laurel Avenue Middletown, NJ 07748 EMail: mnapierala@att.com
Nabil Bitar Verizon 40 Sylvan Rd. Waltham, MA 02145 EMail: nabil.bitar@verizon.com