| 6TiSCH Working Group | M. Richardson |
| Internet-Draft | Sandelman Software Works |
| Intended status: Standards Track | August 28, 2017 |
| Expires: March 1, 2018 |
Minimal Security rekeying mechanism for 6TiSCH
draft-richardson-6tisch-minimal-rekey-02
This draft describes a mechanism to rekey the networks used by 6TISCH nodes. It leverages the security association created during an enrollment protocol. The rekey mechanism permits incremental deployment of new sets of keys, followed by a rollover to a new key.
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6TiSCH networks of nodes often use a pair of keys, K1/K2 to authenticate beacons (K1), encrypt broadcast traffic (K1) and encrypt unicast traffic (K2). These keys need to occasionally be refreshed for a number of reasons:
This protocol uses the CoMI [I-D.ietf-core-comi] to present the set of 127 key pairs.
In addition to providing for rekey, this protocol includes access to the allocated short-address.
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 [RFC2119]. These words may also appear in this document in lowercase, absent their normative meanings.
The reader is expected to be familiar with the terms and concepts defined in [I-D.ietf-6tisch-terminology], [RFC7252], [I-D.ietf-core-object-security], and [I-D.ietf-anima-bootstrapping-keyinfra].
A simplified graphical representation of the data models is used in this document. The meaning of the symbols in these diagrams is as follows:
Rekeying of the network requires that all nodes be updated with the new keys. This can take time as the network is constrained, and this management traffic is not highest priority.
The JRC must reach out to all nodes that it is aware of. As the JRC has originally provided the keys via either zero-touch [I-D.ietf-6tisch-dtsecurity-secure-join] or [I-D.ietf-6tisch-minimal-security] protocol, and in each case, the JRC assigned the short-address to the node, so it knows about all the nodes.
The data model presented in this document provides for up to 127 K1/K2 keys, as each key requires a secKeyId, which is allocated from a 255-element palette provides by [IEEE8021542015]. Keys are to be updated in pairs, and the pairs are associated in the following way: the K1 key is always the odd numbered key (1,3,5), and the K2 key is the even numbered key that follows (2,4,6). A secKeyId value of 0 is invalid, and the secKeyId value of 255 is unused in this process.
Nodes MAY support up to all 127 key pair slots, but MUST support a minimum of 6 keys (3 slot-pairs). When fewer than 127 are supported, the node MUST support secKeyId values from 1 to 254 in a sparse array fashion.
A particular key slot-pair is considered active, and this model provides a mechanism to query and also to explicitely set the active pair.
Nodes decrypt any packets for which they have keys, but MUST continue to send using only the keypair which is considered active. Receipt of a packet which is encrypted (or authenticated in the case of a broadcast) with a secKeyId larger (taking consideration that secKeyId wraps at 254) than the active slot-pair causes the node to change active slot pairs.
This mechanism permits the JRC to provision new keys into all the nodes while the network continues to use the existing keys. When the JRC is certain that all (or enough) nodes have been provisioned with the new keys, then the JRC causes a packet to be sent using the new key. This can be the JRC sending the next Enhanced Beacon or unicast traffic using the new key if the JRC is also a regular member of the LLN. In the likely case that the JRC has no direct connection to the LLN, then the JRC updates the active key to the new key pair using a CoMI message.
The frame goes out with the new keys, and upon receipt (and decryption) of the new frame all receiving nodes will switch to the new active key. Beacons or unicast traffic leaving those nodes will then update additional peers, and the network will switch over in a flood-fill fashion.
((EDNOTE: do we need an example?))
A diagram of the two YANG modules looks like:
1700 module: ietf-6tisch-symmetric-keying
1701 +--rw ietf6tischkeypairs* [counter]
1702 | +--rw counter uint16
1703 | +--rw ietf6tischkey1
1704 | | +--rw secKeyDescriptor
1705 | | | +--rw secKey? binary
1706 | | +--rw secKeyIndex? uint8
1707 | +--rw ietf6tischkey2
1708 | +--rw secKeyDescriptor
1709 | | +--rw secKey? binary
1710 | +--rw secKeyIndex? uint8
1711 +--ro secKeyUsage
1712 | +--ro txPacketsSent? uint32
1713 | +--ro rxPacketsSuccess? uint32
1714 | +--ro rxPacketsReceived? uint32
1715 +--rw newKey? binary
rpcs:
1716 +---x installNextKey
1717 module: ietf-6tisch-short-address
1718 +--ro ietf6shortaddresses
1719 +--ro shortaddress binary
1720 +--ro validuntil uint32
1721 +--ro effectiveat? uint32
Figure 1: Tree diagrams of two rekey modules
module ietf-6tisch-symmetric-keying {
yang-version 1.1;
namespace
"urn:ietf:params:xml:ns:yang:ietf-6tisch-symmetric-keying";
prefix "ietf6keys";
//import ietf-yang-types { prefix yang; }
//import ietf-inet-types { prefix inet; }
organization
"IETF 6tisch Working Group";
contact
"WG Web: <http://tools.ietf.org/wg/6tisch/>
WG List: <mailto:6tisch@ietf.org>
Author: Michael Richardson
<mailto:mcr+ietf@sandelman.ca>";
description
"This module defines the format for a set of network-wide 802.15.4
keys used in 6tisch networks. There are 128 sets of key pairs,
with one keypair (K1) used to authenticate (and sometimes encrypt)
multicast traffic, and another keypair (K2) used to encrypt unicast
traffic. The 128 key pairs are numbered by the (lower) odd
keyindex, which otherwise is a 0-255 value. Keyindex 0 is
not valid. This module is a partial expression of the tables in
https://mentor.ieee.org/802.15/dcn/15/15-15-0106-07-0mag-security-section-pictures.pdf.
To read and write the key pairs, a monotonically increasing counter is added. A new key pair must be added with current_counter = last_counter+1. The current specification allows overwriting of earlier key pairs. It is up to the server to remove old key pairs, such that only the last three (two) pairs are stored and visible to the client.";
revision "2017-03-01" {
description
"Initial version";
reference
"RFC XXXX: 6tisch minimal security";
}
// list of key pairs
list ietf6tischkeypairs {
key counter;
description
"a list of key pairs with unique index: counter.";
leaf counter {
type uint16{
range "0..256"; // for the moment 256 items
}
mandatory "true";
description
"unique reference to the key pair for client access.";
} // counter
// key descriptor for FIRST part of pair
container ietf6tischkey1 {
description
"A voucher that can be used to assign one or more
devices to an owner.";
// this container is pretty empty, a leaf would do the job.
container secKeyDescriptor {
// I assume this needs to be extended, why else a container?
description
"This container describes the details of a
specific cipher key";
leaf secKey {
type binary;
description "The actual encryption key.
This value is write only, and is not returned in a
read, or returns all zeroes.";
} // secKey
} // secKeyDescriptor
// leaf secKeyIdMode is always 1, not described here.
leaf secKeyIndex {
type uint8;
description
"The keyIndex for this keySet.
A number between 1 and 255.";
reference
"IEEE802.15.4";
} // secKeyIndex
} // ietf6tischkey1
// key descriptor for SECOND part of pair
container ietf6tischkey2 {
description
"A voucher that can be used to assign one or more
devices to an owner.";
container secKeyDescriptor {
// I assume this needs to be extended, why else a container?
description
"This container describes the details of a
specific cipher key";
leaf secKey {
type binary;
description "The actual encryption key.
This value is write only, and is not returned in a
read, or returns all zeroes.";
} // secKey
} // secKeyDescriptor
// leaf secKeyIdMode is always 1, not described here.
leaf secKeyIndex {
type uint8;
description
"The keyIndex for this keySet.
A number between 1 and 255.";
reference
"IEEE802.15.4";
} // secKeyIndex
} // ietf6tischkey2
} //ietf6tischkeypairs
// the usage is over all pairs
container secKeyUsage {
config false; // cannot be set by client
description
"statistics of sent and received packets.";
leaf txPacketsSent {
type uint32;
description "Number of packets sent with this key.";
} // txPacketsSent
leaf rxPacketsSuccess {
type uint32;
description "Number of packets received with this key that were
successfully decrypted and authenticated.";
}// rxPacketsSuccess
leaf rxPacketsReceived {
type uint32;
description "Number of packets received with this key, both
successfully received, and unsuccessfully.";
} // rxPacketsReceived
} // secKeyUsage
// setting new key, and validation of new key
leaf newKey{
type binary;
description
"new key value to be set by client.";
} // newKey
rpc installNextKey{
description
"Client informs server that newKey is to be
used as current key.";
} // installNextKey
} // module ietf-6tisch-symmetric-keying
module ietf-6tisch-short-address {
yang-version 1.1;
namespace
"urn:ietf:params:xml:ns:yang:ietf-6tisch-short-address";
prefix "ietf6shortaddr";
//import ietf-yang-types { prefix yang; }
//import ietf-inet-types { prefix inet; }
organization
"IETF 6tisch Working Group";
contact
"WG Web: <http://tools.ietf.org/wg/6tisch/>
WG List: <mailto:6tisch@ietf.org>
Author: Michael Richardson
<mailto:mcr+ietf@sandelman.ca>";
description
"This module defines an interface to set and interrogate
the short (16-bit) layer-2 address used in 802.15.4
TSCH mode networks. The short addresses are used
in L2 frames to save space. A lifetime is included
in terms of TSCH Absolute Slot Number, which acts
as a monotonically increasing clock. ";
revision "2017-03-01" {
description
"Initial version";
reference
"RFC XXXX: 6tisch minimal security";
}
// top-level container
container ietf6shortaddresses {
config false;
description
"A 16-bit short address for use by the node.";
leaf shortaddress {
type binary{
length 1..2;}
mandatory true;
description
"The two byte short address to be set.";
}
leaf validuntil {
type uint32;
mandatory true;
description "The Absolute Slot Number/256 at which
the address ceases to be valid.";
}
leaf effectiveat {
type uint32;
description "The Absolute Slot Number/256 at which
time the address was originally set.
This is a read-only attribute that
records the ASN when the shortaddress
element was last written or updated.";
}
}
}
The CoMI resources presented here are protected by OSCOAP ([I-D.ietf-core-object-security]), secured using the EDHOC connection used for joining. A unique application key is generated using an additional key generation process with the unique label "6tisch-rekey".
Should the OSCOAP connection need to be rekeyed, a new EDHOC process will be necessary. This will need access to trusted authentication keys, either the PSK used from a one-touch process, or the locally significant domain certificates installed during a zero-touch process.
The rekey protocol itself runs over a network encrypted with the K2 key. The end to end protocol from JRC to node is also encrypted using OSCOAP, so the keys are not visible, nor is the keying traffic distinguished in anyway to an observer.
As the secKeyId is not confidential in the underlying 802.15.4 frames, an observer can determine what sets of keys are in use, and when a rekey is activated by observing the change in the secKeyId.
The absolute value of the monitonically increasing secKeyId could provide some information as to the age of the network.
This protocol permits the underlying network keys to be set. Access to all of the portions of this interface MUST be restricted to an ultimately trusted peer, such as the JRC.
An implementation SHOULD not permit reading the network keys. Those fields should be write-only.
The OSCOAP security for this interface is initialized by a join mechanism, and so depends upon the initial credentials provided to the node. The initial network keys would have been provided during the join process; this protocol permits them to be updated.
This document allocates a SID number for the YANG model. There is no IANA action required for this document.
| [I-D.ietf-core-comi] | Veillette, M., Stok, P., Pelov, A. and A. Bierman, "CoAP Management Interface", Internet-Draft draft-ietf-core-comi-01, July 2017. |
| [I-D.ietf-core-object-security] | Selander, G., Mattsson, J., Palombini, F. and L. Seitz, "Object Security of CoAP (OSCOAP)", Internet-Draft draft-ietf-core-object-security-04, July 2017. |
| [I-D.ietf-cose-msg] | Schaad, J., "CBOR Object Signing and Encryption (COSE)", Internet-Draft draft-ietf-cose-msg-24, November 2016. |
| [RFC2119] | Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997. |
| [RFC7049] | Bormann, C. and P. Hoffman, "Concise Binary Object Representation (CBOR)", RFC 7049, DOI 10.17487/RFC7049, October 2013. |
| [RFC7252] | Shelby, Z., Hartke, K. and C. Bormann, "The Constrained Application Protocol (CoAP)", RFC 7252, DOI 10.17487/RFC7252, June 2014. |
| [I-D.ietf-6tisch-6top-protocol] | Wang, Q., Vilajosana, X. and T. Watteyne, "6top Protocol (6P)", Internet-Draft draft-ietf-6tisch-6top-protocol-07, June 2017. |
| [I-D.ietf-6tisch-dtsecurity-secure-join] | Richardson, M., "6tisch Secure Join protocol", Internet-Draft draft-ietf-6tisch-dtsecurity-secure-join-01, February 2017. |
| [I-D.ietf-6tisch-minimal-security] | Vucinic, M., Simon, J., Pister, K. and M. Richardson, "Minimal Security Framework for 6TiSCH", Internet-Draft draft-ietf-6tisch-minimal-security-03, June 2017. |
| [I-D.ietf-6tisch-terminology] | Palattella, M., Thubert, P., Watteyne, T. and Q. Wang, "Terminology in IPv6 over the TSCH mode of IEEE 802.15.4e", Internet-Draft draft-ietf-6tisch-terminology-09, June 2017. |
| [I-D.ietf-anima-bootstrapping-keyinfra] | Pritikin, M., Richardson, M., Behringer, M., Bjarnason, S. and K. Watsen, "Bootstrapping Remote Secure Key Infrastructures (BRSKI)", Internet-Draft draft-ietf-anima-bootstrapping-keyinfra-07, July 2017. |
| [IEEE8021542015] | IEEE standard for Information Technology, ., "IEEE Std 802.15.4-2015 Standard for Low-Rate Wireless Personal Area Networks (WPANs)", 2015. |
In the examples below, a new key value is set in the server example.com; followed by the setting of the new key value as the current key value. The SID values of new Key and installNextKey are 1715 and 1716 respectively. The corresponding base64 values are: ez and e0 respectively.
The setting of the new key value is done with the PUT request with the binary value 1234567890.
PUT coap://example.com/c/ez (Content-Format :application/yang-value+cbor) h'1234567890' RES: 2.01 Created Payload in CBOR: 45 # bytes(5) 1234567890 # "\x124Vx\x90"
Consecutively, the RPC is invoked with a POST method to validate the new key value.
POST coap://example.com/c/e0 (Content-Format :application/yang-value+cbor) RES: 2.05 Content
The client can query how many TX packets have been received. The SID of secKeyUsage/txPacketsSent is 1712, corresponding with base64 ew.
GET coap://example.com/c/ew RES: 2.05 Content (Content-Format :application/yang-value+cbor) 3 Payload in CBOR: 03 # unsigned(3)