Network Working Group M. Richardson
Internet-Draft SSW
Intended status: Informational April 28, 2014
Expires: October 30, 2014

security architecture for 6top: requirements and structure
draft-richardson-6tisch-security-architecture-02

Abstract

This document details security requirements for 6tisch nodes that use 6top in an industrial settings. Layer-2 and a layer-4 authentication and authorization requirements and assumptions are identified. Two approaches to accomplishing these requirements are outlined, with the goal of eventually picking one. This internet-draft is intended for later inclusion into the 6tisch architecture document.

Status of This Memo

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

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This Internet-Draft will expire on October 30, 2014.

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Table of Contents

1. Introduction: secure bootstrap requirements

There are five security problems that must be solved in the 6tisch environment in order to permit the nodes to come together and function as a network. They are:

layer 2 join: new nodes must be recognized by the network, and provided with layer-2 symmetric credentials
zero-touch join: new nodes must recognize the network without explicit provisioning, and attempt to join
new nodes must become a part of the RPL DODAG, and make contact with parent and child nodes
in networks with a PCE, new nodes must authorize the PCE to update the nodes' schedule using 6top
in networks without a PCE, and some situations where a PCE delegates details of a bundle to the nodes, the nodes must be authorized to allocate time slots in their DODAG children

This document, presently a stand-alone document, but later to be a section of [I-D.ietf-6tisch-architecture], explains the assumptions of how the node is expected to be provisioned in the factory, and how it will react to networks that it encounters. As is explained in every Internet of Things document, the nodes are constrainted, have no end-user interfaces, and therefore it is desired that they function in a "zero-touch" manner. [I-D.irtf-nmrg-autonomic-network-definitions] introduces the term "autonomic", and it is exactly the properties described there that are desired for 6tisch networks.

A 802.1AR [IEEE.802.1AR] certificate provisioned in each node at the factory, combined with a certificate chain provided to the network service provider, permits the node to be recognized by the network, and also for the network to assert it's authority to own and control the node. The authentication part of a security protocol (TLS, DTLS, EAP-TLS, details TBD) will establish identities, and then, said security protocol will be used to provide integrity protection for a control protocol (YANG/6top, as discussed in [I-D.wang-6tisch-6top-sublayer]) to configure the TSCH cells.

1.1. Requirements Language

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119 [RFC2119].

1.2. layer-2 join

As outlined in [I-D.ietf-roll-security-threats] there are a number of threats in LLNs, and in RPL which are solved if there is layer-2 security. The requirement is therefore to provide keying for the layer-2 security features: encryption and integrity protection.

In addition to serving to protect the routing traffic against attacks, use of the layer-2 access control serves as adminission control to the network. It is therefore part of the layer-2 join process to authenticate the new node, as well as authorize it to join the network. The admission control SHOULD be controlled by autonomic certificates, as described below.

1.3. Terminology

Plant Installation:
the (6tisch) network installed for control purposes.
>Service Provider:
the operator of the network. The service provider may a department internal to the plant, or may be an external contractor. It is a role.
Authorization server:
a centralized entity that makes both layer-2 admission control decisions, and acting as a super-user for all nodes, delegates 6top authorization to a PCE, or to parent nodes for PCE-less operation.
New Entity:
a new 6LN that wishes to join the network.

[I-D.pritikin-bootstrapping-keyinfrastructures] explains the architecture for use of 802.1AR certificates in a bootstrap process. In that document a number of terms of introduced, and in this section those terms are mapped to 6tisch entities and processes. Section 2 of [I-D.pritikin-bootstrapping-keyinfrastructures] defines:

Domain:
this refers to the entire 6tisch installation
Domain CA:
this is a CA operated by the service provider. It is a role: physically, it may be co-located with an Authorization Server and/or with a PCE and have private interfaces with those entities, or may be elsewhere with interfaces to be determined, but out of scope for this document.
Orchestrator:
the role of the orchestrator is provided by Authorization Server (a term used by both ACE and PANA [RFC5191]), or the EAP Server (see [RFC5247]).
Factory:
this is the vendor of the mote. It may consist of a supplier chain of value-added resellers.
Factory CA:
this is the root CA that is placed into the mote. Each device also has an 802.1AR identity issued from that CA.
Registrar:
the role of registrar is performed by the Authorization Server.
MASA Cloud Service:
A Manufacturer Authorized Signing Authority. These will typically be co-located in the Authorization Server.

1.4. Use of 802.1AR certificates

This section explains how the process detailed in [I-D.pritikin-bootstrapping-keyinfrastructures] is to be implemented in the 6tisch case. To recap, the process looks like:

(1)
Proxy Discovery
(2)
Receiving and accepting the Domain Identity
(3)
Enrollment
(4)
After Enrollment
(5)
Behavior of a proxy
(6)
Behavior of the Registrar
(7)
Authenticating the Device
(8)
Accepting the Entity
(9)
Claiming the new entity
(10)
Behavior of the MASA Cloud Service
(11)
Issue Authorization Token and Log the event

1.4.1. Proxy Discovery

The Proxy Discovery step may occur via one of two mechanisms, which are further described in section Section 3. One method involves using an EAP-TLS (or rather, EAP-EST, as imagined by [I-D.pritikin-bootstrapping-keyinfrastructures]), over either 1X or PANA. A nearby node provides a PANA Authentication Agent (PAA) ([RFC5191]), or 802.1X Authenticator. A well-known L2-JOIN key is used during bootstrap. A second method involves using leveraging the ARO ND messages that 6LOWPAN mandates be exchanged.

In either case, a (D)TLS channel is created from the New Entity/6LN to the Registrar/Authorization Server

1.4.1.1. Certificate Chains

In forming the TLS channel, two certificate chains are validated. The Registrar validates a certificate (possibly chain) presented by the New Entity. This certificate chain would be communicated using the TLS Client Certificate message. The Registrar sends a certificate chain in the TLS Server Certificate message which the New Entity must be able to validate.

As the Registar will in general perform enrollment for all 6LN on a network, it will have multiple identities, and should send only the certificate chain relevant to each New Entity.

The New Entity must also send some TBD extension to the server to indicate who it is. This has to be done before the server sends it's Server Certificate message. This is a variation of the problem the TLS 1.2 SNI extension was designed to solve.

1.4.2. Registrar/Authorization server access to certificate chain

The certificate chain that the Registrar returns may not exist until the New Entity attempts to join. It may be retrieved/created through a number of different mechanisms which are out of scope of this document, but may include:

(1)
loaded from a diskette/USB/QR code that was included in the packaging
(2)
downloaded via some interactive web interface provided by the manufacturer and/or logistics company
(3)
acquired via an online enrollment protocol, such as EST protocol. This could be secured using a one-time password provided in the packaging.
(4)
out of band, by having a human talk to another human.

An important aspect to note is that it may be some minutes to days between the time the New Entity initiates the join operation, and when the Registrar is able to respond properly: some kind of error code and back-off process may be appropriate.

1.4.3. Receiving and accepting the Domain Identity

The two certificate chains described in the previous section are critical for permitting the zero-touch operation of the 6LN New Entity. This section describes the contents of the Server Certificate that the 6LN expects to verify. For the purposes of this explanation, assume the 6LN has a deviceID of 3145191, and is manufactured by Example Corp, that it was distributed by Example Logistics, and it is being installed at ACME Widgets.

The certificate chain will be rooted with the 6LN's manufacturer certificate: Example Corp.

(a)
An 802.1AR certificate signed by Example Corp. delegates deviceID 3145191 to Example Logistics.
(b)
An 802.1AR certificate signed by Example Logistics delegates deviceID 3145191 to ACME Widgets

This chain permits the 6LN to verify that ACME Widgets is in fact it's rightful owner. The certificate chain MAY have a validity permit, or MAY be valid indefinitely. Given that it is unlikely that the 6LN will have a reliable real-time clock, or access to a secure network time source, validation of validity permits may be useless.

The certificate chain that the New Entity presents to the Registrar would look like:

(a)
An 802.1AR certificate signed by Example Corp. binds deviceID 3145191 to the public key of the New Entity.

1While a longer certificate chain could be embedded in the device, it is not advised. Any part of the manufacturing chain that can do such a thing should simply put it's own identity there, and provide a new certificate chain path to the Registrar.

1.4.4. Enrollment

1.5. 6top/PCE security requirements

In addition to authorization a node to join the network, the node agree to provide authorization to a PCE in order for the 6top protocol to run. This protocol, described in section X of 6tisch architecture (this) document and in [6top], permits the PCE to program a timeslot schedule into the node.

So, the second part of the 6tisch security requirements is to establish the identities of the the node and the PCE, and to establish an authorization that permits the new node to be programmed by the PCE.

1.5.1. no-PCE and 6LR to 6LR 6top authorization

2. leveraging layer-2 identities for layer-4 security

As explained in [I-D.behringer-autonomic-network-framework] the layer-2 identity of the node will be given by a certificate signed by the vendor of the node. The vendor's certificate authority is loaded into the (PANA) Authorization Server, and permits the AS to authenticate the node.

The vendor provides a certificate (chain) to the (PANA) Authorization Server (PAS) attesting to that the PAS is the rightful owner/controller of the node. This permits the node to validate that the network it is joining is the correct network. This process permits the bootstrap of one of the layer-2 security mechanism(s) describe in sections below.

The same set of trust relationships can then permit the PAS to act as an Authorization Server (now, in the context of [I-D.gerdes-core-dcaf-authorize]). The PCE and it's Authorization Manager (AM, again from [I-D.gerdes-core-dcaf-authorize]) can now get a ticket to permit it to write the timeslot schedule. In option 2, below, it also permits updates to the security parameters.

3. Layer-2 Join

3.1. option 1: The ZigBeeIP/PANA way

This is an adaptation of the process described in [ZigBeeIP], section and expounded upon in section 6.3: "Network Discovery", 6.4: "Network Selection", and 6.5, "Node Joining". The process is abridged below.

3.1.1. Network Discovery

The MAC beacon facility is used. A critical difference in 6tisch from ZigBee IP is that because nodes transmit and receive according to their own schedule, every node is in essence a coordinator. While nodes may sleep a lot, they will not in general be sleep Hosts, from a ZigBee IP point of view, and MLE is not necessary.

Each response to the Beacon is a potential network-joining-parent.

As an option, it may be desireable for this document to define a well known NetworkID.

3.1.2. PANA protocol

The PANA payloads MUST be relayed by the chosen network-joining-parent. It is assumed that the PANA Authentication Agent is co-located with the PCE, if there is a PCE.

As per section 8.3.4 of [ZigBeeIP], the PANA process runs over UDP using link-layer addressing. The process is first the PANA initialization (PCI, PAR:S, PAN:S), followed by EAP initialization (EAP-Request, EAP-Response), which negotiates the identity, and then EAP-TLS starts, consisting of (TLS(Start), TLS(ClientHello), TLS(ServerHello), TLS(ServerKeyExchange), TLS(ClientKeyExchange), and TLS(ChangeCipherSpec)).

When the TLS is done, the EAP derives new network security material, and sends it encrypted using the Encr-Encap AVP described in [RFC6786].

3.1.3. Authorization

QUESTION: can we find a way for the authorization protocol, such as described in draft-gerdes-core-dcaf-authorize-01, to run simultaenously with the authentication system if we assume that the dcaf AS is also the PANA Authentication Server/Agent

In the context of draft-selander-core-access-control, the new node that is joining is the resource server, and the origin client is the PCE.

3.1.4. Advantages of the EAP-TLS based methods

3.1.5. Bandwidth considerations for joins

Calculations show that with a contention-based medium, using slotted Aloha style, there will be only 1-3 cells available per slotframe, at most 36% of bandwidth. Typical slotframes repeat 10 times/second. Calculations show that it take about 10-15s for each node to join, or about 30 minutes for 10-hop deep, 100-node network. This assumes 300 bytes for a certificate.

JS: in WHART, all frames sent to centralized manager to set up tyransport session. Primary different is tha the number fo frame is very small (1 frame up, 1 frame down) to get transport session started.

JS: limitation is that you cannot cleanly separate joining flows from steady-state flws in the netowkr. You can take device from box, which will disrupt data traffic. In a typical HART network, amount of BW for joining is really low. Limitation, no external validation of the manager's ID, other than it posesses the right key.

3.1.6. Challenges with this method

number of messages
size of certificate exchanges
EAP and TLS code not used for anything else
ability to support non-PCE case

3.2. option 2: The WirelessHart/ISA100 way

This is an adaptation of the process described in [HART], section 6.6.3.

In this process, the new node joins using a well-known layer-2 "JOIN" key. It brings up the layer-3, using 6loWPAN Neighbour Discovery to learn of the 6lowpan contexts, and then uses RPL to join a well-known DODAG as a leaf node.

Nodes which have capacity for new joining nodes will respond to the RPL DIS messages. Once connected, the new node uses regular unicasted IP datagrams to contact an Authorization Manager (in the context of [I-D.gerdes-core-dcaf-authorize]). The negotiation with the Authorization Manager (AM) uses the autonomic certificates as described above to establish the trust relationship.

Once the relationship is up, the AM needs to signal the PCE that it has a new authorized node, and the PCE can now (acting as a [I-D.gerdes-core-dcaf-authorize] Client), get a Ticket to update the node.

The PCE then writes both a new timeslot schedule, and also writes new security parameters that permit the node to fully join the network. Appropriate layer-2 keys are updated, as well as any appropriate layer-3 RPL credentials. MLE may be used to establish pair-wise keying, as appropriate to the timeslot schedule.

3.2.1. Advantages of this method

3.2.2. Challenges with the CoAP method

new protocol to initiate layer-2
potentially weaker resistance to layer-2 DoS

4. Security Considerations

5. Other Related Protocols

6. IANA Considerations

7. Acknowledgements

8. References

8.1. Normative references

[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[ZigBeeIP] ZigBee Public Document 15-002r00, "ZigBee IP Specification", 2013.
[RFC6786] Yegin, A. and R. Cragie, "Encrypting the Protocol for Carrying Authentication for Network Access (PANA) Attribute-Value Pairs", RFC 6786, November 2012.
[I-D.ietf-6tisch-architecture] Thubert, P., Watteyne, T. and R. Assimiti, "An Architecture for IPv6 over the TSCH mode of IEEE 802.15.4e", Internet-Draft draft-ietf-6tisch-architecture-00, November 2013.
[I-D.wang-6tisch-6top-sublayer] Wang, Q., Vilajosana, X. and T. Watteyne, "6TiSCH Operation Sublayer (6top)", Internet-Draft draft-wang-6tisch-6top-sublayer-00, February 2014.
[I-D.ietf-roll-security-threats] Tsao, T., Alexander, R., Dohler, M., Daza, V., Lozano, A. and M. Richardson, "A Security Threat Analysis for Routing Protocol for Low-power and lossy networks (RPL)", Internet-Draft draft-ietf-roll-security-threats-06, December 2013.
[I-D.gerdes-core-dcaf-authorize] Gerdes, S., Bergmann, O. and C. Bormann, "Delegated CoAP Authentication and Authorization Framework (DCAF)", Internet-Draft draft-gerdes-core-dcaf-authorize-02, February 2014.
[I-D.pritikin-bootstrapping-keyinfrastructures] Pritikin, M., Behringer, M. and S. Bjarnason, "Bootstrapping Key Infrastructures", Internet-Draft draft-pritikin-bootstrapping-keyinfrastructures-00, January 2014.
[I-D.irtf-nmrg-autonomic-network-definitions] Behringer, M., Pritikin, M., Bjarnason, S., Clemm, A., Carpenter, B., Jiang, S. and L. Ciavaglia, "Autonomic Networking - Definitions and Design Goals", Internet-Draft draft-irtf-nmrg-autonomic-network-definitions-00, December 2013.
[HART] www.hartcomm.org, "Highway Addressable Remote Transducer, a group of specifications for industrial process and control devices administered by the HART Foundation", .
[ISA100.11a] ISA, "ISA100, Wireless Systems for Automation", May 2008.
[IEEE.802.1AR] Institute of Electrical and Electronics Engineers, "Secure Device Identity", IEEE 802.1AR, 2009.

8.2. Informative references

[I-D.behringer-autonomic-network-framework] Behringer, M., Pritikin, M., Bjarnason, S. and A. Clemm, "A Framework for Autonomic Networking", Internet-Draft draft-behringer-autonomic-network-framework-01, October 2013.
[RFC5191] Forsberg, D., Ohba, Y., Patil, B., Tschofenig, H. and A. Yegin, "Protocol for Carrying Authentication for Network Access (PANA)", RFC 5191, May 2008.
[RFC5247] Aboba, B., Simon, D. and P. Eronen, "Extensible Authentication Protocol (EAP) Key Management Framework", RFC 5247, August 2008.
[RFC6869] Salgueiro, G., Clarke, J. and P. Saint-Andre, "vCard KIND:device", RFC 6869, February 2013.

Author's Address

Michael C. Richardson Sandelman Software Works 470 Dawson Avenue Ottawa, ON K1Z 5V7 CA EMail: mcr+ietf@sandelman.ca URI: http://www.sandelman.ca/