Network Working Group L. Dunbar
Internet Draft A. Malis
Intended status: Informational Futurewei
Expires: December 19, 2019 C. Jacquenet
Orange
June 19, 2019
Gap Analysis of Dynamic Networks to Hybrid Cloud DCs
draft-ietf-rtgwg-net2cloud-gap-analysis-02
Abstract
This document analyzes the technological gaps when using SD-WAN to
dynamically interconnect workloads and applications hosted in
rd various 3 party cloud data centers.
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This Internet-Draft will expire on December 19, 2019.
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Table of Contents
1. Introduction...................................................2
2. Conventions used in this document..............................3
3. Gap Analysis of C-PEs WAN Port Registration....................4
4. Aggregating VPN paths and Internet paths.......................5
4.1. Key Control Plane Components of SD-WAN....................6
4.2. Using BGP Tunnel-Encap....................................7
4.3. SECURE-L3VPN/EVPN.........................................9
4.4. Preventing attacks from Internet-facing ports............10
5. CPEs not directly connected to VPN PEs........................10
5.1. Floating PEs to connect to Remote CPEs...................13
5.2. NAT Traversal............................................13
5.3. Complexity of using BGP between PEs and remote CPEs via
Internet......................................................13
5.4. Designated Forwarder to the remote edges.................14
5.5. Traffic Path Management..................................15
6. Manageability Considerations..................................15
7. Security Considerations.......................................15
8. IANA Considerations...........................................16
9. References....................................................16
9.1. Normative References.....................................16
9.2. Informative References...................................16
10. Acknowledgments..............................................17
1. Introduction
[Net2Cloud-Problem] describes the problems that enterprises face
today in transitioning their IT infrastructure to support digital
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economy, such as connecting enterprises' branch offices to dynamic
workloads in different Cloud DCs.
This document analyzes the technological gaps to interconnect
dynamic workloads & apps hosted in cloud data centers that the
enterprise's VPN service provider may not own/operate or may be
unable to provide the enterprise with the required connectivity to
access such locations. When VPN service providers have insufficient
bandwidth to reach a location, SD-WAN techniques can be used to
aggregate bandwidth of multiple networks, such as MPLS VPNs or the
Public Internet to achieve better performance. This document
primarily focuses on the technological gaps raised by using SD-WAN
techniques to connect enterprise premises to cloud data centers
operated by third parties.
For the sake of readability, a SD-WAN edge, a SD-WAN endpoint, C-PE,
or CPE are used interchangeably throughout this document. However,
each term has some minor emphasis, especially when used in other
related documents:
. SD-WAN Edge: could include multiple devices (virtual or
physical);
. SD-WAN endpoint: to refer to a WAN port of SD-WAN devices or a
single SD-WAN device;
. C-PE: more for provider owned SD-WAN edge, e.g. for SECURE-
EVPN's PE based VPN, when PE is the edge node of SD-WAN;
. CPE: more for enterprise owned SD-WAN edge.
2. Conventions used in this document
Cloud DC: Third party Data Centers that usually host applications
and workload owned by different organizations or
tenants.
Controller: Used interchangeably with SD-WAN controller to manage
SD-WAN overlay path creation/deletion and monitor the
path conditions between sites.
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CPE-Based VPN: Virtual Private Network designed and deployed from
CPEs. This is to differentiate from most commonly used
PE-based VPNs a la RFC 4364.
OnPrem: On Premises data centers and branch offices
SD-WAN: Software Defined Wide Area Network, "SD-WAN" refers to
the solutions of pooling WAN bandwidth from multiple
underlay networks to get better WAN bandwidth
management, visibility & control. When the underlay is a
private network, traffic may be forwarded without any
additional encryption; when the underlay networks are
public, such as the Internet, some traffic needs to be
encrypted when passing through (depending on user-
provided policies).
3. Gap Analysis of C-PEs WAN Port Registration
SD-WAN technology has emerged as means to dynamically and securely
interconnect the OnPrem branches with the workloads instantiated in
Cloud DCs that do not have direct connectivity to BGP/MPLS VPN PEs
or have very limited bandwidth.
Some SD-WAN networks use the NHRP protocol [RFC2332] to register WAN
ports of SD-WAN edges with a "Controller" (or NHRP server), which
then has the ability to map a private VPN address to a public IP
address of the destination node. DSVPN [DSVPN] or DMVPN [DMVPN] are
used to establish tunnels between WAN ports of SD-WAN edge nodes.
NHRP was originally intended for ATM address resolution, and as a
result, it misses many attributes that are necessary for dynamic
endpoint C-PE registration to the controller, such as:
- Interworking with the MPLS VPN control plane. A SD-WAN edge can
have some ports facing the MPLS VPN network over which packets can
be forwarded without any encryption and some ports facing the
public Internet over which sensitive traffic needs to be encrypted
before being sent.
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- Scalability: NHRP/DSVPN/DMVPN works fine with small numbers of
edge nodes. When a network has more than 100 nodes, these
protocols do not scale well.
- NHRP does not have the IPsec attributes, which are needed for
peers to build Security Associations over the public internet.
- NHRP messages do not have any field to encode the C-PE supported
encapsulation types, such as IPsec-GRE or IPsec-VxLAN.
- NHRP messages do not have any field to encode C-PE Location
identifiers, such as Site Identifier, System ID, and/or Port ID.
- NHRP messages do not have any field to describe the gateway(s) to
which the C-PE is attached. When a C-PE is instantiated in a Cloud
DC, it is desirable for C-PE's owner to be informed of how/where
the C-PE is attached.
- NHRP messages do not have any field to describe C-PE's NAT
properties if the C-PE is using private addresses, such as the NAT
type, Private address, Public address, Private port, Public port,
etc.
[BGP-SDWAN-PORT] describes how SD-WAN edge nodes use BGP to register
their WAN ports properties to the SD-WAN controller, which then
propagates the information to other SD-WAN edge nodes that are
authenticated and authorized to communicate with them.
4. Aggregating VPN paths and Internet paths
Most likely, enterprises (especially the largest ones) already have
their CPEs interconnected by providers' VPNs, based upon VPN
techniques such as EVPN, L2VPN, or L3VPN. The VPN can be PE-based or
CPE-based. The commonly used PE-based VPNs have CPE directly
attached to PEs, therefore the communication between CPEs and PEs is
considered as secure. MP-BGP is used to learn & distribute routes
among CPEs, even though sometimes routes among CPEs are statically
configured on the CPEs.
To aggregate paths over the Internet and paths over the VPN, the C-
PEs need to have some WAN ports connected to the PEs of the VPNs and
other WAN ports connected to the Internet. It is necessary for the
CPEs to use a protocol so that they can register the WAN port
properties with their SD-WAN Controller(s): this information
conditions the establishment and the maintenance of IPsec SA
associations among relevant C-PEs.
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When using NHRP for registration purposes, C-PEs need to run two
separate control planes: EVPN&BGP for CPE-based VPNs, and NHRP &
DSVPN/DMVPN for ports connected to the Internet. Two separate
control planes not only add complexity to C-PEs, but also increase
operational cost.
+---+
+--------------|RR |----------+
/ Untrusted +-+-+ \
/ \
/ \
+----+ +---------+ packets encrypted over +------+ +----+
| TN3|--| A1-----+ Untrusted +------ B1 |--| TN1|
+----+ | C-PE A2-\ | C-PE | +----+
+----+ | A A3--+--+ +---+---B2 B | +----+
| TN2|--| | |PE+--------------+PE |---B3 |--| TN3|
+----+ +---------+ +--+ trusted +---+ +------+ +----+
| WAN |
+----+ +---------+ +--+ packets +---+ +------+ +----+
| TN1|--| C1--|PE| go natively |PE |-- D1 |--| TN1|
+----+ | C-PE C2--+--+ without encry+---+ | C-PE | +----+
| C | +--------------+ | D |
| | | |
+----+ | C3--| without encrypt over | | +----+
| TN2|--| C4--+---- Untrusted --+------D2 |--| TN2|
+----+ +---------+ +------+ +----+
Figure 1: CPEs interconnected by VPN paths and Internet Paths
4.1. Key Control Plane Components of SD-WAN
As described in [BGP-SDWAN-Usage], the SD-WAN Overlay Control Plane
has three distinct properties:
- SD-WAN node's WAN Port Property registration to the SD-WAN
Controller.
o To inform the SD-WAN controller and authorized peers of
the WAN port properties of the C-PE [SDWAN-Port]. When the
WAN ports are assigned private addresses, this step can
register the type of NAT that translates private addresses
into public ones.
- Controller facilitated IPsec SA management and NAT information
distribution
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o It is for SD-WAN controller to facilitate or manage the
IPsec configuration and peer authentication for all IPsec
tunnels terminated at the SD-WAN nodes.
- Establishing and Managing the topology and reachability for
services attached to the client ports of SD-WAN nodes.
o This is for the overlay layer's route distribution, so
that a C-PE can populate its overlay routing table with
entries that identify the next hop for reaching a specific
route/service attached to remote nodes. [SECURE-EVPN]
describes EVPN and other options.
4.2. Using BGP Tunnel-Encap
RFC5512 and [Tunnel-Encap] describe methods to construct BGP UPDATE
messages that advertise endpoints' tunnel encapsulation capability
and the respective attached client routes, so that the peers that
receive of the BGP UPDATE can establish appropriate tunnels with the
endpoints for the aforementioined routes. RFC5512 uses the Endpoint
Address subTLV, whereas [Tunnel-Encap] uses Remote Endpoint Address
subTLV to indicates address of the tunnel endpoint which can be an
IPv4 or an IPv6 address. There are Tunnel Encapsulation attribute
subTLVs to indicate the supported encapsulation types, such as
L2TPv3, GRE, VxLAN, IP-in-IP, etc.
[Tunnel-Encap] removed SAFI =7 (which was specified by RFC5512) for
distributing encapsulation tunnel information. [Tunnel-Encap]
requires that tunnels need to be associated with routes.
There is also the Color sub-TLV to describe customer-specified
information about the tunnels (which can be creatively used for SD-
WAN).
Here are some of the gaps using [Tunnel-Encap] to control SD-WAN
Tunnels:
- [Tunnel-Encap] doesn't have the functionality that would help the
C-PE to register its WAN Port properties.
- A SD-WAN tunnel, e.g. IPsec-based, requires a negotiation between
the tunnel's end points for supported encryption algorithms and
tunnel types before it can be properly established, whereas
[Tunnel-Encap] only allow the announcement of one endpoint's
supported encapsulation capabilities for specific attached routes
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and no negotiation between tunnel end points is needed. The
establishment of a SD-WAN tunnel can fail, e.g., in case the two
endpoints support different encryption algorithms. That is why a
SD-WAN tunnel needs to be established and maintained independently
from advertising client routes attached to the edge node.
- [Tunnel-Encap] requires all tunnels updates are associated with
routes. There can be many client routes associated with the SD-WAN
IPsec tunnel between two C-PEs' WAN ports; the corresponding
destination prefixes (as announced by the aforementioned routes)
may also be reached through the VPN underlay without any
encryption. A more realistic approach to separate SD-WAN tunnel
management from client routes association with the SD-WAN tunnels.
- When SD-WAN tunnel and clients routes are separate, the SD-WAN
Tunnel establishment may not have routes associated.
There is a suggestion on using a "Fake Route" for a SD-WAN node to
use [Tunnel-Encap] to advertise its SD-WAN tunnel end-points
properties. However, using "Fake Route" can raise some design
complexity for large SD-WAN networks with many tunnels. For
example, for a SD-WAN network with hundreds of nodes, with each
node having many ports & many endpoints to establish SD-WAN
tunnels with their corresponding peers, the node would need as
many "fake addresses". For large SD-WAN networks (such as those
comprised of more than 10000 nodes), each node might need 10's
thousands of "fake addresses", which is very difficult to manage
and requires lots of configuration tasks to get the nodes properly
set up.
- [Tunnel-Encap] does not have any field to carry detailed
information about the remote C-PE, such as Site-ID, System-ID,
Port-ID
- [Tunnel-Encap] Does not have any field to carry IPsec attributes
for the SD-WAN edge nodes to establish IPsec Security Associations
with others. It does not have any proper way for two peer CPEs to
negotiate IPsec keys either, based on the configuration sent by
the Controller.
- [Tunnel-Encap] does not have any field to indicate the UDP NAT
private address <-> public address mapping
- C-PEs tend to communicate with a subset of the other C-PEs, not
all the C-PEs need to be connected through a mesh topology.
Without any BGP extension, many nodes can get dumped with too much
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information coming from other nodes that they never need to
communicate with.
4.3. SECURE-L3VPN/EVPN
[SECURE-L3VPN] describes how to extend the BGP/MPLS VPN [RFC4364]
capabilities to allow some PEs to connect to other PEs via public
networks. [SECURE-L3VPN] introduces the concept of Red Interface &
Black Interface used by PEs, where the RED interfaces are used to
forward traffic into the VPN, and the Black Interfaces are used
between WAN ports through which only IPsec-protected packets are
forwarded to the Internet or to other backbone network thereby
eliminating the need for MPLS transport in the backbone.
[SECURE-L3VPN] assumes PEs using MPLS over IPsec when sending
traffic through the Black Interfaces.
[SECURE-EVPN] describes a solution where point-to-multipoint BGP
signaling is used in the control plane for SDWAN Scenario #1. It
relies upon a BGP cluster design to facilitate the key and policy
exchange among PE devices to create private pair-wise IPsec Security
Associations without IKEv2 point-to-point signaling or any other
direct peer-to-peer session establishment messages.
Both [SECURE-L3VPN] and [SECURE-EVPN] are useful, however, they both
miss the aspects of aggregating VPN and Internet underlays. In
summary:
- These documents do not address the scenario of C-PE having some
ports facing VPN PEs and other ports facing the Internet.
- The [SECURE-L3VPN] assumes that a CPE "registers" with the RR.
However, it does not say how. It assumes that the remote CPEs are
pre-configured with the IPsec SA manually. In SD-WAN, Zero Touch
Provisioning is expected. Manual configuration is not an option,
as it contradicts the objectives of SD-WAN to automate
configuration tasks.
- For RR communication with C-PEs, this draft only mentions IPsec.
Missing TLS/DTLS.
- The draft assumes that C-PEs and RR are connected with an IPsec
tunnel. With zero touch provisioning, we need an automatic way to
synchronize the IPsec SAs between C-PEs and RR. The draft assumes:
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A CPE must also be provisioned with whatever additional
information is needed in order to set up an IPsec SA with
each of the red RRs
- IPsec requires periodic refreshment of the keys. The draft does
not provide any information about how to synchronize the
refreshment among multiple nodes.
- IPsec usually sends configuration parameters to two endpoints only
and lets these endpoints negotiate the key. Let us assume that the
RR is responsible for creating the key for all endpoints: When one
endpoint is compromised, all other connections will be impacted.
4.4. Preventing attacks from Internet-facing ports
When C-PEs have Internet-facing ports, additional security risks are
raised.
To mitigate security risks, in addition to requiring Anti-DDoS
features on C-PEs, it is necessary for CPEs to support means to
determine whether traffic sent by remote peers is legitimate to
prevent spoofing attacks.
5. CPEs not directly connected to VPN PEs
Because of the ephemeral property of the selected Cloud DCs, an
enterprise or its network service provider may not have direct
connections to the Cloud DCs that are used for hosting the
enterprise's specific workloads/Apps. Under those circumstances, SD-
WAN is a very flexible choice to interconnect the enterprise on-
premises data centers & branch offices to its desired Cloud DCs.
However, SD-WAN paths established over the public Internet can have
unpredictable performance, especially over long distances and across
operators' domains. Therefore, it is highly desirable to steer as
much as possible the portion of SD-WAN paths over service provider
VPN (e.g., enterprise's existing VPN) that have guaranteed SLA to
minimize the distance or the number of segments over the public
Internet.
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MEF Cloud Service Architecture [MEF-Cloud] also describes a use case
of network operators that uses SD-WAN over LTE or the public
Internet for last mile access where the VPN service providers cannot
necessarily provide the required physical infrastructure.
Under those scenarios, one or two of the SD-WAN endpoints may not be
directly attached to the PEs of a VPN Domain.
When using SD-WAN to connect the enterprise's existing sites with
the workloads hosted in Cloud DCs, the corresponding CPEs have to be
upgraded to support SD-WAN. If the workloads hosted in Cloud DCs
need to be connected to many sites, the upgrade process can be very
expensive.
[Net2Cloud-Problem] describes a hybrid network approach that
integrates SD-WAN with traditional MPLS-based VPNs, to extend the
existing MPLS-based VPNs to the Cloud DC Workloads over the access
paths that are not under the VPN provider's control. To make it work
properly, a small number of the PEs of the MPLS VPN can be
designated to connect to the remote workloads via SD-WAN secure
IPsec tunnels. Those designated PEs are shown as fPE (floating PE
or smart PE) in Figure 3. Once the secure IPsec tunnels are
established, the workloads hosted in Cloud DCs can be reached by the
enterprise's VPN without upgrading all of the enterprise's existing
CPEs. The only CPE that needs to support SD-WAN would be a
virtualized CPE instantiated within the cloud DC.
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+--------+ +--------+
| Host-a +--+ +----| Host-b |
| | | (') | |
+--------+ | +-----------+ ( ) +--------+
| +-+--+ ++-+ ++-+ +--+-+ (_)
| | CPE|--|PE| |PE+--+ CPE| |
+--| | | | | | | |---+
+-+--+ ++-+ ++-+ +----+
/ | |
/ | MPLS +-+---+ +--+-++--------+
+------+-+ | Network |fPE-1| |CPE || Host |
| Host | | | |- --| || d |
| c | +-----+ +-+---+ +--+-++--------+
+--------+ |fPE-2|-----+
+---+-+ (|)
(|) (|) SD-WAN
(|) (|) over any access
+=\======+=========+
// \ | Cloud DC \\
// \ ++-----+ \\
+Remote|
| CPE |
+-+----+
----+-------+-------+-----
| |
+---+----+ +---+----+
| Remote | | Remote |
| App-1 | | App-2 |
+--------+ +--------+
Figure 3: VPN Extension to Cloud DC
In Figure 3, the optimal Cloud DC to host the workloads (as a
function of the proximity, capacity, pricing, or other criteria
chosen by the enterprises) does not have a direct connection to the
PEs of the MPLS VPN that interconnects the enterprise's existing
sites.
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5.1. Floating PEs to connect to Remote CPEs
To extend MPLS VPNs to remote CPEs, it is necessary to establish
secure tunnels (such as IPsec tunnels) between the Floating PEs and
the remote CPEs.
Even though a set of PEs can be manually selected to act as the
floating PEs for a specific cloud data center, there are no standard
protocols for those PEs to interact with the remote CPEs (most
likely virtualized) instantiated in the third party cloud data
centers (such as exchanging performance or route information).
When there is more than one fPE available for use (as there should
be for resiliency purposes or the ability to support multiple cloud
DCs geographically scattered), it is not straightforward to
designate an egress fPE to remote CPEs based on applications. There
is too much applications' traffic traversing PEs, and it is not
feasible for PEs to recognize applications from the payload of
packets.
5.2. NAT Traversal
Cloud DCs that only assign private IPv4 addresses to the
instantiated workloads assume that traffic to/from the workload
usually needs to traverse NATs.
A SD-WAN edge node can solicit a STUN (Session Traversal of UDP
Through Network Address Translation RFC 3489) Server to get the NAT
property, the public IP address and the Public Port number so that
such information can be communicated to the relevant peers.
5.3. Complexity of using BGP between PEs and remote CPEs via Internet
Even though an EBGP (external BGP) Multi-hop design can be used to
connect peers that are not directly connected to each other, there
are still some complications in extending BGP from MPLS VPN PEs to
remote CPEs via any access path (e.g., Internet).
The path between the remote CPEs and VPN PEs that maintain VPN
routes may very well traverse untrusted nodes.
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EBGP Multi-hop design requires static configuration on both peers.
To use EBGP between a PE and remote CPEs, the PE has to be manually
configured with the "next-hop" set to the IP address of the CPEs.
When remote CPEs, especially remote virtualized CPEs are dynamically
instantiated or removed, the configuration of Multi-Hop EBGP on the
PE has to be changed accordingly.
Egress peering engineering (EPE) is not sufficient. Running BGP on
virtualized CPEs in Cloud DCs requires GRE tunnels to be
established first, which requires the remote CPEs to support
address and key management capabilities. RFC 7024 (Virtual Hub &
Spoke) and Hierarchical VPN do not support the required
properties.
Also, there is a need for a mechanism to automatically trigger
configuration changes on PEs when remote CPEs' are instantiated or
moved (leading to an IP address change) or deleted.
EBGP Multi-hop design does not include a security mechanism by
default. The PE and remote CPEs need secure communication channels
when connecting via the public Internet.
Remote CPEs, if instantiated in Cloud DCs, might have to traverse
NATs to reach PEs. It is not clear how BGP can be used between
devices located beyond the NAT and the devices located behind the
NAT. It is not clear how to configure the Next Hop on the PEs to
reach private IPv4 addresses.
5.4. Designated Forwarder to the remote edges
Among the multiple floating PEs that are reachable from a remote
CPE, multicast traffic sent by the remote CPE towards the MPLS VPN
can be forwarded back to the remote CPE due to the PE receiving the
multicast packets forwarding the multicast/broadcast frame to other
PEs that in turn send to all attached CPEs. This process may cause
traffic loops.
Therefore, it is necessary to designate one floating PE as the CPE's
Designated Forwarder, similar to TRILL's Appointed Forwarders
[RFC6325].
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MPLS VPNs do not have features like TRILL's Appointed Forwarders.
5.5. Traffic Path Management
When there are multiple floating PEs that have established IPsec
tunnels with the remote CPE, the remote CPE can forward outbound
traffic to the Designated Forwarder PE, which in turn forwards
traffic to egress PEs and then to the final destinations. However,
it is not straightforward for the egress PE to send back the return
traffic to the Designated Forwarder PE.
Example of Return Path management using Figure 3 above.
- fPE-1 is DF for communication between App-1 <-> Host-a due to
latency, pricing or other criteria.
- fPE-2 is DF for communication between App-1 <-> Host-b.
6. Manageability Considerations
Zero touch provisioning of SD-WAN edge nodes should be a major
feature of SD-WAN deployments. It is necessary for a newly powered
up SD-WAN edge node to establish a secure connection (by means of
TLS, DTLS, etc.) with its controller.
7. Security Considerations
The intention of this draft is to identify the gaps in current and
proposed SD-WAN approaches that can address requirements
identified in [Net2Cloud-problem].
Several of these approaches have gaps in meeting enterprise
security requirements when tunneling their traffic over the
Internet, since this is the purpose of SD-WAN. See the individual
sections above for further discussion of these security gaps.
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8. IANA Considerations
This document requires no IANA actions. RFC Editor: Please remove
this section before publication.
9. References
9.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
9.2. Informative References
[RFC8192] S. Hares, et al, "Interface to Network Security Functions
(I2NSF) Problem Statement and Use Cases", July 2017
[RFC5521] P. Mohapatra, E. Rosen, "The BGP Encapsulation Subsequent
Address Family Identifier (SAFI) and the BGP Tunnel
Encapsulation Attribute", April 2009.
[BGP-SDWAN-PORT]L. Dunbar, et al, "Subsequent Address Family
Indicator for SDWAN Ports", draft-dunbar-idr-sdwan-port-
safi-00, Work-in-progress, March 2019.
[BGP-SDWAN-Usage] L. Dunbar, et al, "Framework of Using BGP for
SDWAN Overlay Networks", draft-dunbar-idr-sdwan-framework-
00, work-in-progress, Feb 2019.
[Tunnel-Encap]E. Rosen, et al, "The BGP Tunnel Encapsulation
Attribute", draft-ietf-idr-tunnel-encaps-10, July 2018.
[SECURE-EVPN A. Sajassi, et al, draft-sajassi-bess-secure-evpn-01,
work in progress, March 2019.
[SECURE-L3VPN] E. Rosen, "Provide Secure Layer L3VPNs over Public
Infrastructure", draft-rosen-bess-secure-l3vpn-00, work-
in-progress, July 2018
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[DMVPN] Dynamic Multi-point VPN:
https://www.cisco.com/c/en/us/products/security/dynamic-
multipoint-vpn-dmvpn/index.html
[DSVPN] Dynamic Smart VPN:
http://forum.huawei.com/enterprise/en/thread-390771-1-
1.html
[ITU-T-X1036] ITU-T Recommendation X.1036, "Framework for creation,
storage, distribution and enforcement of policies for
network security", Nov 2007.
[Net2Cloud-Problem] L. Dunbar and A. Malis, "Seamless Interconnect
Underlay to Cloud Overlay Problem Statement", draft-dm-
net2cloud-problem-statement-02, June 2018
10. Acknowledgments
Acknowledgements to xxx for his review and contributions.
This document was prepared using 2-Word-v2.0.template.dot.
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Internet-Draft Net2Cloud Gap Analysis June 2019
Authors' Addresses
Linda Dunbar
Futurewei
Email: ldunbar@futurewei.com
Andrew G. Malis
Futurewei
Email: agmalis@gmail.com
Christian Jacquenet
Orange
Rennes, 35000
France
Email: Christian.jacquenet@orange.com
Dunbar, et al. Expires December 19, 2019 [Page 18]