Internet-Draft | Group OSCORE | September 2023 |
Tiloca, et al. | Expires 5 March 2024 | [Page] |
This document defines the security protocol Group Object Security for Constrained RESTful Environments (Group OSCORE), providing end-to-end security of CoAP messages exchanged between members of a group, e.g., sent over IP multicast. In particular, the described protocol defines how OSCORE is used in a group communication setting to provide source authentication for CoAP group requests, sent by a client to multiple servers, and for protection of the corresponding CoAP responses. Group OSCORE also defines a pairwise mode where each member of the group can efficiently derive a symmetric pairwise key with any other member of the group for pairwise OSCORE communication. Group OSCORE can be used between endpoints communicating with CoAP or CoAP-mappable HTTP.¶
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The Constrained Application Protocol (CoAP) [RFC7252] is a web transfer protocol specifically designed for constrained devices and networks [RFC7228]. Group communication for CoAP [I-D.ietf-core-groupcomm-bis] addresses use cases where deployed devices benefit from a group communication model, for example to reduce latencies, improve performance, and reduce bandwidth utilization. Use cases include lighting control, integrated building control, software and firmware updates, parameter and configuration updates, commissioning of constrained networks, and emergency multicast (see Appendix B). Group communication for CoAP [I-D.ietf-core-groupcomm-bis] mainly uses UDP/IP multicast as the underlying data transport.¶
Object Security for Constrained RESTful Environments (OSCORE) [RFC8613] describes a security protocol based on the exchange of protected CoAP messages. OSCORE builds on CBOR Object Signing and Encryption (COSE) [RFC9052][RFC9053] and provides end-to-end encryption, integrity, replay protection, and binding of response to request between a sender and a recipient, independent of the transport layer also in the presence of intermediaries. To this end, a CoAP message is protected by including its payload (if any), certain options, and header fields into a COSE object, which is conveyed within the CoAP payload and the CoAP OSCORE option of the protected message, thereby replacing those message fields with an authenticated and encrypted object.¶
This document defines Group OSCORE, a security protocol for group communication with CoAP [I-D.ietf-core-groupcomm-bis] and for CoAP-mappable HTTP requests and responses, providing the same end-to-end security properties as OSCORE also in the case where requests have multiple recipients. In particular, the described protocol defines how OSCORE is used in a group communication setting to provide source authentication for group requests sent by a client to multiple servers, and for protection of the corresponding responses. Group OSCORE also defines a pairwise mode where each member of the group can efficiently derive a symmetric pairwise key with any other member of the group for pairwise-protected OSCORE communication. Just like OSCORE, Group OSCORE is independent of the transport layer and works wherever CoAP does.¶
As with OSCORE, it is possible to combine Group OSCORE with communication security on other layers. One example is the use of transport layer security, such as DTLS [RFC9147], between one client and one proxy (and vice versa), or between one proxy and one server (and vice versa). This prevents observers from accessing addressing information conveyed in CoAP options that would not be protected by Group OSCORE, but would be protected by DTLS. These options include Uri-Host, Uri-Port, and Proxy-Uri. Note that DTLS does not define how to secure messages sent over IP multicast. Group OSCORE is also intended to work with OSCORE-capable proxies [I-D.tiloca-core-oscore-capable-proxies] thereby enabling, for example, nested OSCORE operations with OSCORE-protected communication between a CoAP client and a proxy, carrying messages that are additionally protected with Group OSCORE between the CoAP client and the target CoAP servers.¶
Group OSCORE defines two modes of operation, that can be used independently or together:¶
Both modes provide source authentication of CoAP messages. The application decides what mode to use, potentially on a per-message basis. Such decisions can be based, for instance, on pre-configured policies or dynamic assessing of the target recipient and/or resource, among other things. One important case is when requests are protected in group mode, and responses in pairwise mode. Since such responses convey shorter integrity tags instead of bigger, full-fledged signatures, this significantly reduces the message overhead in case of many responses to one request.¶
A special deployment of Group OSCORE consists in using the pairwise mode only. For example, consider the case of a constrained-node network [RFC7228] with a large number of CoAP endpoints and the objective to establish secure communication between any pair of endpoints with a small provisioning effort and message overhead. Since the total number of security associations that needs to be established grows with the square of the number of endpoints, it is desirable to restrict the amount of secret keying material provided to each endpoint. Moreover, a key establishment protocol would need to be executed for each security association. One solution to this issue is to deploy Group OSCORE, with the endpoints being part of a group, and to use the pairwise mode. This solution has the benefit of providing a single shared secret, while distributing only the public keys of group members or a subset of those. After that, a CoAP endpoint can locally derive the OSCORE Security Context for the other endpoint in the group, and protect CoAP communications with very low overhead [I-D.ietf-iotops-security-protocol-comparison].¶
In some circumstances, Group OSCORE messages may be transported in HTTP, e.g., when they are protected with the pairwise mode and target a single recipient, or when they are protected with the group mode and target multiple CoAP recipients through cross-protocol translators such as HTTP-to-CoAP proxies [RFC8075][I-D.tiloca-core-groupcomm-proxy]. The use of Group OSCORE with HTTP is as defined for OSCORE in Section 11 of [RFC8613].¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
Readers are expected to be familiar with the terms and concepts described in CoAP [RFC7252], including "endpoint", "client", "server", "sender", and "recipient"; group communication for CoAP [I-D.ietf-core-groupcomm-bis]; Observe [RFC7641]; CBOR [RFC8949]; COSE [RFC9052][RFC9053] and related countersignatures [RFC9338].¶
Readers are also expected to be familiar with the terms and concepts for protection and processing of CoAP messages through OSCORE, such as "Security Context" and "Master Secret", defined in [RFC8613].¶
Terminology for constrained environments, such as "constrained device" and "constrained-node network", is defined in [RFC7228].¶
This document refers also to the following terminology.¶
Long exchange: an exchange of messages associated with a request that is a group request and/or an Observe request [RFC7641].¶
In either case, multiple responses can follow from the same server to the request associated with the long exchange. The client terminates a long exchange when freeing up the CoAP Token value used for the associated request, for which no further responses will be accepted afterwards.¶
This document refers to a group as a set of endpoints sharing keying material and security parameters for executing the Group OSCORE protocol, see Section 1.1. All members of a group maintain a Security Context as defined in this section.¶
How the Security Context is established by the group members is out of scope for this document, but if there is more than one Security Context applicable to a message, then the endpoints MUST be able to tell which Security Context was latest established. How to manage information about the group is described in terms of a Group Manager (see Section 3).¶
An endpoint of the group may use the group mode (see Section 8), the pairwise mode (see Section 9), or both, depending on the modes it supports and on the parameters of the Security Context. The Security Context of Group OSCORE extends the OSCORE Security Context defined in Section 3 of [RFC8613] as follows (see Figure 1).¶
One Common Context, shared by all the endpoints in the group and extended as defined below.¶
For the group mode, the Common Context is extended with the following new parameters.¶
One Sender Context, extended with the following new parameters.¶
If the endpoint is configured exclusively as silent server (see Section 1.1), then the Sender Context is omitted.¶
One Recipient Context for each other endpoint from which messages are received. It is not necessary to maintain Recipient Contexts associated with endpoints from which messages are not (expected to be) received.¶
The following sections specify how the Common Context is used and extended compared to [RFC8613]. All algorithms (AEAD, Group Encryption, Signature, Pairwise Key Agreement) are immutable once the Common Context is established. The Common Context may be acquired from the Group Manager (see Section 3).¶
The AEAD Algorithm (see Section 3.1 of [RFC8613]) SHALL identify the COSE AEAD algorithm to use for encryption and decryption when messages are protected using the pairwise mode (see Section 9). This algorithm MUST provide integrity protection. If this parameter is not set, the pairwise mode is not used in the group.¶
The ID Context parameter (see Sections 3.1 and 3.3 of [RFC8613]) SHALL contain the Group Identifier (Gid) of the group. The choice of the Gid format is application specific. An example of specific formatting of the Gid is given in Appendix C. The application needs to specify how to handle potential collisions between Gids (see Section 13.6).¶
The Common IV parameter (see Section 3.1 of [RFC8613]) SHALL identify the Common IV used in the group. Differently from OSCORE, the length of the Common IV is determined as follows.¶
The new parameter Authentication Credential Format specifies the format of authentication credentials used in the group. Further details on authentication credentials are compiled in Section 2.4.¶
The new parameter Group Manager Authentication Credential specifies the authentication credential of the Group Manager, including the Group Manager's public key. The endpoint MUST achieve proof-of-possession of the corresponding private key. Further details on the provisioning of the Group Manager's authentication credential to the group members are out of the scope of this document.¶
The new parameter Group Encryption Algorithm identifies the algorithm to use for encryption and decryption, when messages are protected in group mode (see Section 8). This algorithm MAY provide integrity protection. If this parameter is not set, the group mode is not used in the group.¶
The new parameter Signature Algorithm identifies the digital signature algorithm used for computing and verifying the countersignature on the COSE object (see Sections 3.2 and 3.3 of [RFC9338]), when messages are protected in group mode (see Section 8). If this parameter is not set, the group mode is not used in the group.¶
The new parameter Signature Encryption Key specifies the encryption key for deriving a keystream to encrypt/decrypt a countersignature, when a message is protected in group mode (see Section 8).¶
The Signature Encryption Key is derived as defined for Sender/Recipient Keys in Section 3.2.1 of [RFC8613], with the following differences.¶
The new parameter Pairwise Key Agreement Algorithm identifies the elliptic curve Diffie-Hellman algorithm used to derive a static-static Diffie-Hellman shared secret, from which pairwise keys are derived (see Section 2.5.1) to protect messages with the pairwise mode (see Section 9). If this parameter is not set, the pairwise mode is not used in the group.¶
If the HKDF Algorithm specified in the Common Context is "HKDF SHA-256" (identified as "HMAC 256/256", COSE algorithm encoding: 5), then the Pairwise Key Agreement Algorithm is "ECDH-SS + HKDF-256" (COSE algorithm encoding: -27).¶
If the HKDF Algorithm specified in the Common Context is "HKDF SHA-512" (identified as "HMAC 512/512", COSE algorithm encoding: 7), then the Pairwise Key Agreement Algorithm is "ECDH-SS + HKDF-512" (COSE algorithm encoding: -28).¶
Note that the HKDF Algorithm in the Common Context is denoted by the corresponding COSE HMAC Algorithm. For example, the HKDF Algorithm "HKDF SHA-256" is specified as the HMAC Algorithm "HMAC 256/256" (COSE algorithm encoding: 5).¶
More generally, if Pairwise Key Agreement Algorithm is set, it MUST identify a COSE algorithm such that: i) it performs a direct ECDH Static-Static key agreement; and ii) it indicates the use of the same HKDF Algorithm used in the group as specified in the Common Context.¶
The Sender ID SHALL be unique for each endpoint in a group with a certain triplet (Master Secret, Master Salt, Group Identifier), see Section 3.3 of [RFC8613].¶
The maximum length of a Sender ID in bytes equals L minus 6, where L is determined as follows.¶
With the exception of the authentication credential of the sender endpoint, a receiver endpoint can derive a complete Security Context from a received Group OSCORE message and the Common Context (see Section 2.3).¶
The authentication credentials in the Recipient Contexts can be retrieved from the Group Manager (see Section 3) upon joining the group. An authentication credential can alternatively be acquired from the Group Manager at a later time, for example the first time a message is received from a particular endpoint in the group (see Section 8.2 and Section 8.4).¶
For severely constrained devices, it may be infeasible to simultaneously handle the ongoing processing of a recently received message in parallel with the retrieval of the sender endpoint's authentication credential. Such devices can be configured to drop a received message for which there is no (complete) Recipient Context, and retrieve the sender endpoint's authentication credential in order to have it available to verify subsequent messages from that endpoint.¶
An endpoint may admit a maximum number of Recipient Contexts for a same Security Context, e.g., due to memory limitations. After reaching that limit, the endpoint has to delete a current Recipient Context to install a new one (see Section 2.6.1.2). It is up to the application to define policies for Recipient Contexts to delete.¶
OSCORE defines the derivation of Sender Context and Recipient Context (specifically, of Sender/Recipient Keys) and of the Common IV, from a set of input parameters (see Section 3.2 of [RFC8613]).¶
The derivation of Sender/Recipient Keys and of the Common IV defined in OSCORE applies also to Group OSCORE, with the following modifications compared to Section 3.2.1 of [RFC8613].¶
The authentication credentials of the endpoints in a group MUST be encoded according to the format used in the group, as indicated by the Authentication Credential Format parameter in the Common Context (see Section 2.1.4). The authentication credential of the Group Manager SHOULD be encoded according to that same format. The format of authentication credentials MUST provide the public key and a comprehensive set of information related to the public key algorithm, including, e.g., the used elliptic curve (when applicable).¶
If Group Encryption Algorithm in the Common Context is not set (see Section 2.1.6), then the public key algorithm is the Pairwise Key Agreement Algorithm used in the group (see Section 2.1.9), else the Signature Algorithm used in the group (see Section 2.1.7).¶
If the authentication credentials are X.509 certificates [RFC5280] or C509 certificates [I-D.ietf-cose-cbor-encoded-cert], the public key algorithm is fully described by the "algorithm" field of the "SubjectPublicKeyInfo" structure, and by the "subjectPublicKeyAlgorithm" element, respectively.¶
If authentication credentials are CBOR Web Tokens (CWTs) or CWT Claims Sets [RFC8392], the public key algorithm is fully described by a COSE key type and its "kty" and "crv" parameters.¶
Authentication credentials are used to derive pairwise keys (see Section 2.5.1) and are included in the external additional authenticated data when processing messages (see Section 4.4). In both these cases, an endpoint in a group MUST treat authentication credentials as opaque data, i.e., by considering the same binary representation made available to other endpoints in the group, possibly through a designated trusted source (e.g., the Group Manager).¶
For example, an X.509 certificate is provided as its direct binary serialization. If C509 certificates or CWTs are used as authentication credentials, each is provided as the binary serialization of a (possibly tagged) CBOR array. If CWT Claims Sets are used as authentication credentials, each is provided as the binary serialization of a CBOR map.¶
If authentication credentials are CWTs, then the untagged CWT associated with an entity is stored in the Security Context and used as authentication credential for that entity.¶
If authentication credentials are X.509 / C509 certificates or CWTs, and the authentication credential associated with an entity is provided within a chain or a bag, then only the end-entity certificate or end-entity untagged CWT is stored in the Security Context and used as authentication credential for that entity.¶
Storing whole authentication credentials rather than only a subset of those may result in a non-negligible storage overhead. On the other hand, it also ensures that authentication credentials are correctly used in a simple, flexible and non-error-prone way, also taking into account future credential formats as entirely new or extending existing ones. In particular, it is ensured that:¶
Depending on the particular deployment and the intended group size, limiting the storage overhead of endpoints in a group can be an incentive for system/network administrators to prefer using a compact format of authentication credentials in the first place.¶
Certain signature schemes, such as EdDSA and ECDSA, support a secure combined signature and encryption scheme. This section specifies the derivation of "pairwise keys", for use in the pairwise mode defined in Section 9.¶
Group OSCORE keys used for both signature and encryption MUST be used only for purposes related to Group OSCORE. These include the processing of messages with Group OSCORE, as well as performing proof-of-possession of private keys, e.g., upon joining a group through the Group Manager (see Section 3).¶
Using the Group OSCORE Security Context (see Section 2), a group member can derive AEAD keys, to protect point-to-point communication between itself and any other endpoint X in the group by means of the AEAD Algorithm from the Common Context (see Section 2.1.1). The key derivation of these so-called pairwise keys follows the same construction as in Section 3.2.1 of [RFC8613]:¶
Pairwise Sender Key = HKDF(Sender Key, IKM-Sender, info, L) Pairwise Recipient Key = HKDF(Recipient Key, IKM-Recipient, info, L) with IKM-Sender = Sender Auth Cred | Recipient Auth Cred | Shared Secret IKM-Recipient = Recipient Auth Cred | Sender Auth Cred | Shared Secret¶
where:¶
The Shared Secret is computed as a cofactor Diffie-Hellman shared secret, see Section 5.7.1.2 of [NIST-800-56A], using the Pairwise Key Agreement Algorithm. The endpoint uses its private key from the Sender Context and the other endpoint's public key included in Recipient Auth Cred. Note the requirement of validation of public keys in Section 13.16.¶
In case the other endpoint's public key has COSE Key Type "EC2" (e.g., for the curves P-256, P-384, and P-512), then the public key is used as is. In case the other endpoint's public key has COSE Key Type "OKP", the procedure is described in Section 5 of [RFC7748]. In particular, if the public key is for X25519 or X448, it is used as is. Otherwise, if the public key is for the curve Ed25519 or Ed448, it is first mapped to Montgomery coordinates (see Section 2.5.2).¶
info and L are as defined in Section 3.2.1 of [RFC8613]. That is:¶
If EdDSA asymmetric keys are used, the Edward coordinates are mapped to Montgomery coordinates using the maps defined in Sections 4.1 and 4.2 of [RFC7748], before using the X25519 or X448 function defined in Section 5 of [RFC7748]. For further details, see Section 2.5.2. ECC asymmetric keys in Montgomery or Weierstrass form are used directly in the key agreement algorithm, without coordinate mapping.¶
After establishing a partially or completely new Security Context (see Section 2.6 and Section 3.2), the old pairwise keys MUST be deleted. Since new Sender/Recipient Keys are derived from the new group keying material (see Section 2.2), every group member MUST use the new Sender/Recipient Keys when deriving new pairwise keys.¶
As long as any two group members preserve the same asymmetric keys, their Diffie-Hellman shared secret does not change across updates of the group keying material.¶
The y-coordinate of the other endpoint's Ed25519 public key is decoded as specified in Section 5.1.3 of [RFC8032]. The Curve25519 u-coordinate is recovered as u = (1 + y) / (1 - y) (mod p) following the map in Section 4.1 of [RFC7748]. Note that the mapping is not defined for y = 1, and that y = -1 maps to u = 0 which corresponds to the neutral group element and thus will result in a degenerate shared secret. Therefore, implementations MUST abort if the y-coordinate of the other endpoint's Ed25519 public key is 1 or -1 (mod p).¶
The private signing key byte strings (i.e., the lower 32 bytes used for generating the public key, see step 1 of Section 5.1.5 of [RFC8032]) are decoded the same way for signing in Ed25519 and scalar multiplication in X25519. Hence, in order to compute the shared secret, the endpoint applies the X25519 function to the Ed25519 private signing key byte string and the encoded u-coordinate byte string as specified in Section 5 of [RFC7748].¶
The y-coordinate of the other endpoint's Ed448 public key is decoded as specified in Section 5.2.3. of [RFC8032]. The Curve448 u-coordinate is recovered as u = y^2 * (d * y^2 - 1) / (y^2 - 1) (mod p) following the map from "edwards448" in Section 4.2 of [RFC7748], and also using the relation x^2 = (y^2 - 1)/(d * y^2 - 1) from the curve equation. Note that the mapping is not defined for y = 1 or -1. Therefore, implementations MUST abort if the y-coordinate of the peer endpoint's Ed448 public key is 1 or -1 (mod p).¶
The private signing key byte strings (i.e., the lower 57 bytes used for generating the public key, see step 1 of Section 5.2.5 of [RFC8032]) are decoded the same way for signing in Ed448 and scalar multiplication in X448. Hence, in order to compute the shared secret, the endpoint applies the X448 function to the Ed448 private signing key byte string and the encoded u-coordinate byte string as specified in Section 5 of [RFC7748].¶
When using any of its Pairwise Sender Keys, a sender endpoint including the 'Partial IV' parameter in the protected message MUST use the current fresh value of the Sender Sequence Number from its Sender Context (see Section 2.2). That is, the same Sender Sequence Number space is used for all outgoing messages protected with Group OSCORE, thus limiting both storage and complexity.¶
On the other hand, when combining communications with the group mode and the pairwise mode, this may result in the Partial IV values moving forward more often. This can happen when a client engages in frequent or long sequences of one-to-one exchanges with servers in the group, by sending requests over unicast. In turn, this contributes to a sooner exhaustion of the Sender Sequence Number space of the client, which would then require to take actions for deriving a new Sender Context before resuming communications in the group (see Section 2.6.2).¶
If the pairwise mode is supported, the Security Context additionally includes the Pairwise Key Agreement Algorithm and the pairwise keys, as described at the beginning of Section 2.¶
The pairwise keys as well as the shared secrets used in their derivation (see Section 2.5.1) may be stored in memory or recomputed every time they are needed. The shared secret changes only when a public/private key pair used for its derivation changes, which results in the pairwise keys also changing. Additionally, the pairwise keys change if the Sender ID changes or if a new Security Context is established for the group (see Section 2.6.3). In order to optimize protocol performance, an endpoint may store the derived pairwise keys for easy retrieval.¶
In the pairwise mode, the Sender Context includes the Pairwise Sender Keys to use with the other endpoints (see Figure 1). In order to identify the right key to use, the Pairwise Sender Key for endpoint X may be associated with the Recipient ID of endpoint X, as defined in the Recipient Context (i.e., the Sender ID from the point of view of endpoint X). In this way, the Recipient ID can be used to lookup for the right Pairwise Sender Key. This association may be implemented in different ways, e.g., by storing the pair (Recipient ID, Pairwise Sender Key) or linking a Pairwise Sender Key to a Recipient Context.¶
It is RECOMMENDED that the immutable part of the Security Context is stored in non-volatile memory, or that it can otherwise be reliably accessed throughout the operation of the group, e.g., after device reboots. However, also immutable parts of the Security Context may need to be updated, for example due to scheduled key renewal, new or re-joining members in the group, or the fact that the endpoint changes Sender ID (see Section 2.6.3).¶
The mutable parts of the Security Context are updated by the endpoint when executing the security protocol, but may be lost (see Section 2.6.1) or become outdated by exhaustion of Sender Sequence Numbers (see Section 2.6.2).¶
An endpoint may lose its mutable Security Context, e.g., due to a reboot occurred in an unprepared way (see Section 2.6.1.1) or due to a deleted Recipient Context (see Section 2.6.1.2).¶
If it is not feasible or practically possible to store and maintain up-to-date the mutable part in non-volatile memory (e.g., due to limited number of write operations), the endpoint MUST be able to detect a loss of the mutable Security Context, to prevent the re-use of a nonce with the same AEAD key, and to handle incoming replayed messages.¶
In case a loss of the Sender Context and/or of the Recipient Contexts is detected (e.g., following a reboot occurred in an unprepared way), the endpoint MUST NOT protect further messages using this Security Context, to avoid reusing an AEAD nonce with the same AEAD key.¶
Before resuming its operations in the group, the endpoint MUST retrieve new Security Context parameters from the Group Manager (see Section 2.6.3) and use them to derive a new Sender Context and Recipient Contexts (see Section 2.2). Since the new Sender Context includes newly derived encryption keys, an endpoint will not reuse the same pair (key, nonce), even when it is a server using the Partial IV of (old re-injected) requests to build the AEAD nonce for protecting the responses.¶
From then on, the endpoint MUST use the latest installed Sender Context to protect outgoing messages. Newly derived Recipient Contexts will have a Replay Window which is initialized as valid.¶
If an endpoint is not configured as silent server and is not able to establish an updated Sender Context, e.g., because of lack of connectivity with the Group Manager, then the endpoint MUST NOT protect further messages using the current Security Context and MUST NOT accept incoming messages from other group members, as currently unable to detect possible replays.¶
If an endpoint is configured as silent server and is not able to establish an updated Security Context, e.g., because of lack of connectivity with the Group Manager, then the endpoint MUST NOT accept incoming messages from other group members, as currently unable to detect possible replays.¶
An adversary may leverage the above to perform a Denial of Service attack and prevent some group members from communicating altogether. That is, the adversary can first block the communication path between the Group Manager and some individual group members. This can be achieved, for instance, by injecting fake responses to DNS queries for the Group Manager hostname, or by removing a network link used for routing traffic towards the Group Manager. Then, the adversary can induce an unprepared reboot for some endpoints in the group, e.g., by triggering a short power outage. After that, such endpoints that have lost their Sender Context and/or Recipient Contexts following the reboot would not be able to obtain new Security Context parameters from the Group Manager, as specified above. Thus, they would not be able to further communicate in the group until connectivity with the Group Manager is restored.¶
The Security Context may contain a large and variable number of Recipient Contexts. A Recipient Context may need to be deleted, because the maximum number of Recipient Contexts has been reached (see Section 2.2), or due to some other reason.¶
When a Recipient Context is deleted, information about previously received messages from the corresponding other endpoint is lost. Therefore, if the Recipient Context is derived again from the same Security Context, there is a risk that a replayed message is not detected. If one Recipient Context has been deleted from the current Security Context, then the Replay Window of any new Recipient Context in this Security Context MUST be initialized as invalid. Messages associated with a Recipient Context that has an invalid Replay Window MUST NOT be delivered to the application.¶
If the endpoint receives a request to process with the new Recipient Context and the endpoint supports the CoAP Echo Option [RFC9175], then it is RECOMMENDED to follow the procedure specified in Section 10 which establishes a valid Replay Window. In particular, the endpoint MUST use its Partial IV when generating the AEAD nonce and MUST include the Partial IV in the response message conveying the Echo Option.¶
Alternatively, the endpoint MAY retrieve or wait for new Security Context parameters from the Group Manager and derive new Sender and Recipient Contexts, as defined in Section 2.6.1.1. In this case the Replay Windows of all Recipient Contexts become valid if they are not already.¶
Since an endpoint increments its Sender Sequence Number for each new outgoing message including a Partial IV, an endpoint can eventually exhaust the Sender Sequence Number space.¶
Implementations MUST be able to detect an exhaustion of Sender Sequence Number space, after the endpoint has consumed the largest usable value. This may be influenced by additional limitations besides the mere 40-bit size limit of the Partial IV. If an implementation's integers support wrapping addition, the implementation MUST treat the Sender Sequence Number as exhausted when a wrap-around is detected.¶
Upon exhausting the Sender Sequence Number space, the endpoint MUST NOT use this Security Context to protect further messages including a Partial IV.¶
The endpoint SHOULD inform the Group Manager, retrieve new Security Context parameters from the Group Manager (see Section 2.6.3), and use them to derive a new Sender Context (see Section 2.2).¶
From then on, the endpoint MUST use its latest installed Sender Context to protect outgoing messages.¶
The Group Manager can assist an endpoint with an incomplete Sender Context to retrieve missing data of the Security Context and thereby become fully operational in the group again. The two main options for the Group Manager are described in this section: i) assignment of a new Sender ID to the endpoint (see Section 2.6.3.1); and ii) establishment of a new Security Context for the group (see Section 2.6.3.2). The update of the Replay Window in each of the Recipient Contexts is discussed in Section 2.6.1.¶
As group membership changes, or as group members get new Sender IDs (see Section 2.6.3.1), so do the relevant Recipient IDs that the other endpoints need to keep track of. As a consequence, group members may end up retaining stale Recipient Contexts, that are no longer useful to verify incoming secure messages.¶
The Recipient ID ('kid') SHOULD NOT be considered as a persistent and reliable identifier of a group member. Such an indication can be achieved only by using that member's public key, when verifying countersignatures of received messages (in group mode), or when verifying messages integrity-protected with pairwise keying material derived from authentication credentials and associated asymmetric keys (in pairwise mode).¶
Furthermore, applications MAY define policies to: i) delete (long-)unused Recipient Contexts and reduce the impact on storage space; as well as ii) check with the Group Manager that an authentication credential with the public key included therein is currently the one associated with a 'kid' value, after a number of consecutive failed verifications.¶
The Group Manager may assign a new Sender ID to an endpoint, while leaving the Gid, Master Secret and Master Salt unchanged in the group. In this case, the Group Manager MUST assign a Sender ID that has not been used in the group since the latest time when the current Gid value was assigned to the group (see Section 3.2).¶
Having retrieved the new Sender ID, and potentially other missing data of the immutable Security Context, the endpoint can derive a new Sender Context (see Section 2.2). When doing so, the endpoint resets the Sender Sequence Number in its Sender Context to 0, and derives a new Sender Key. This is in turn used to possibly derive new Pairwise Sender Keys.¶
From then on, the endpoint MUST use its latest installed Sender Context to protect outgoing messages.¶
The assignment of a new Sender ID may be the result of different processes. The endpoint may request a new Sender ID, e.g., because of the exhaustion of the Sender Sequence Number space (see Section 2.6.2). An endpoint may request to re-join the group, e.g., because of losing its mutable Security Context (see Section 2.6.1), and is provided with a new Sender ID together with the latest immutable Security Context.¶
For the other group members, the Recipient Context corresponding to the old Sender ID becomes stale (see Section 3.2).¶
The Group Manager may establish a new Security Context for the group (see Section 3.2). The Group Manager does not necessarily establish a new Security Context for the group if one member has an outdated Security Context (see Section 2.6.3.1), unless that was already planned or required for other reasons.¶
All the group members need to acquire new Security Context parameters from the Group Manager. Once having acquired new Security Context parameters, each group member performs the following actions.¶
It derives and installs a new Security Context. In particular:¶
From then on, it can resume processing new messages for the considered group. In particular:¶
The distribution of a new Gid and Master Secret may result in temporarily misaligned Security Contexts among group members. In particular, this may result in a group member not being able to process messages received right after a new Gid and Master Secret have been distributed. A discussion on practical consequences and possible ways to address them, as well as on how to handle the old Security Context, is provided in Section 13.5.¶
As with OSCORE, endpoints communicating with Group OSCORE need to establish the relevant Security Context. Group OSCORE endpoints need to acquire OSCORE input parameters, information about the group(s) and about other endpoints in the group(s). This document is based on the existence of an entity called Group Manager that is responsible for the group, but it does not mandate how the Group Manager interacts with the group members. The list of responsibilities of the Group Manager is compiled in Section 3.4.¶
The Group Manager assigns unique Group Identifiers (Gids) to the groups under its control. Within each of such groups, the Group Manager assigns unique Sender IDs (and thus Recipient IDs) to the respective group members. The maximum length of Sender IDs depends on the length of the AEAD nonce for the algorithms used in the group (see Section 2.2).¶
According to a hierarchical approach, the Gid value assigned to a group is associated with a dedicated space for the values of Sender ID and Recipient ID of the members of that group. When an endpoint (re-)joins a group, it is provided with the current Gid to use in the group. The Group Manager also assigns an integer Key Generation Number counter to each of its groups, identifying the current version of the keying material used in that group. Further details about identifiers and keys are provided in Section 3.2.¶
The Group Manager maintains records of the authentication credentials of endpoints in a group, and provides information about the group and its members to other group members (see Section 3.1), and to external entities with a specific role (see Section 3.3).¶
From the Group Manager, an endpoint acquires group data such as the Gid and OSCORE input parameters including its own Sender ID, with which it can derive the Sender Context.¶
When joining the group or later on as a group member, an endpoint can also retrieve from the Group Manager the authentication credential of the Group Manager as well as the authentication credential and other information associated with other members of the group, with which it can derive the corresponding Recipient Context. An application can configure a group member to asynchronously retrieve information about Recipient Contexts, e.g., by Observing [RFC7641] a resource at the Group Manager to get updates on the group membership.¶
Upon endpoints' joining, the Group Manager collects their authentication credentials and MUST verify proof-of-possession of the respective private key. Together with the requested authentication credentials of other group members, the Group Manager MUST provide the joining endpoints with the Sender ID of the associated group members and the current Key Generation Number in the group (see Section 3.2).¶
An endpoint may join a group, for example, by explicitly interacting with the responsible Group Manager, or by being configured with some tool performing the tasks of the Group Manager. When becoming members of a group, endpoints are not required to know how many and what endpoints are in the same group.¶
Communications that the Group Manager has with joining endpoints and group members MUST be secured. Specific details on how to secure such communications are out of the scope of this document.¶
The Group Manager MUST verify that the joining endpoint is authorized to join the group. To this end, the Group Manager can directly authorize the joining endpoint, or expect it to provide authorization evidence previously obtained from a trusted entity. Further details about the authorization of joining endpoints are out of the scope of this document.¶
In case of successful authorization check, the Group Manager provides the joining endpoint with the keying material to initialize the Security Context. The actual provisioning of keying material and parameters to the joining endpoint is out of the scope of this document.¶
One realization of a Group Manager is specified in [I-D.ietf-ace-key-groupcomm-oscore], where the join process is based on the ACE framework for authentication and authorization in constrained environments [RFC9200].¶
In order to establish a new Security Context for a group, the Group Manager MUST generate and assign to the group a new Group Identifier (Gid) and a new value for the Master Secret parameter. When doing so, a new value for the Master Salt parameter MAY also be generated and assigned to the group. When establishing the new Security Context, the Group Manager should preserve the current value of the Sender ID of each group member.¶
The specific group key management scheme used to distribute new keying material is out of the scope of this document. A simple group key management scheme is defined in [I-D.ietf-ace-key-groupcomm-oscore]. When possible, the delivery of rekeying messages should use a reliable transport, in order to reduce chances of group members missing a rekeying instance.¶
The set of group members should not be assumed as fixed, i.e., the group membership is subject to changes, possibly on a frequent basis.¶
The Group Manager MUST rekey the group without undue delay in case one or more endpoints leave the group. An endpoint may leave the group at own initiative, or may be evicted from the group by the Group Manager, e.g., in case an endpoint is compromised, or is suspected to be compromised. In either case, rekeying the group excludes such endpoints from future communications in the group, and thus preserves forward security. If a network node is compromised or suspected to be compromised, the Group Manager MUST evict from the group all the endpoints hosted by that node that are member of the group and rekey the group accordingly.¶
If required by the application, the Group Manager MUST rekey the group also before one or more new joining endpoints are added to the group, thus preserving backward security.¶
Separately for each group, the value of the Key Generation Number increases by one each time the Group Manager distributes new keying material to that group (see Section 3.2). The first Key Generation Number assigned to every group MUST be 0.¶
The establishment of the new Security Context for the group takes the following steps.¶
The Group Manager MUST build a set of stale Sender IDs including:¶
The Group Manager rekeys the group, by distributing:¶
Further information may be distributed, depending on the specific group key management scheme used in the group.¶
When receiving the new group keying material, a group member considers the received stale Sender IDs and performs the following actions.¶
After that, the group member installs the new keying material and derives the corresponding new Security Context.¶
A group member might miss one or more consecutive instances of group rekeying. As a result, the group member will retain old group keying material with Key Generation Number GEN_OLD. Eventually, the group member can notice the discrepancy, e.g., by repeatedly failing to verify incoming messages, or by explicitly querying the Group Manager for the current Key Generation Number. Once the group member gains knowledge of having missed a group rekeying, it MUST delete the old keying material it stores.¶
Then, the group member proceeds according to the following steps.¶
If no exact indication can be obtained from the Group Manager, the group member MUST remove all the authentication credentials from its list of group members' authentication credentials used in the group and MUST delete all its Recipient Contexts used in the group.¶
Otherwise, the group member MUST remove every authentication credential associated with a stale Sender ID from its list of group members' authentication credentials used in the group, and MUST delete each of its Recipient Contexts used in the group whose corresponding Recipient ID is a stale Sender ID.¶
Alternatively, the group member can re-join the group. In such a case, the group member MUST take one of the following two actions.¶
The group member re-joins the group with the same roles it currently has in the group, and, during the re-joining process, it asks the Group Manager for the authentication credentials of all the current group members.¶
Then, given Z, the set of authentication credentials received from the Group Manager, the group member removes every authentication credential which is not in Z from its list of group members' authentication credentials used in the group, and deletes each of its Recipient Contexts used in the group that does not include any of the authentication credentials in Z.¶
By removing authentication credentials and deleting Recipient Contexts associated with stale Sender IDs, it is ensured that a recipient endpoint storing the latest group keying material does not store the authentication credentials of sender endpoints that are not current group members. This in turn allows group members to rely on stored authentication credentials to confidently assert the group membership of sender endpoints, when receiving incoming messages protected in group mode (see Section 8).¶
Such a strictness in managing the authentication credentials and Recipient Contexts associated with other group members is required for two reasons. First, as further discussed in Section 13.1, it ensures that the group mode can be used securely, even in a group where the Group Encryption Algorithm does not provide integrity protection (see Section 2.1.6) and external signature checkers are used (see Section 8.5). Second, it ensures that the wrong (old) authentication credential associated with a group member A is never used with a sender ID that used to be associated with A and has been later issued to a different group member B (see Section 3.2.1.2), thus preventing the need to recover from an identity mix-up.¶
This section specifies how the Group Manager handles and possibly reassigns Gid values and Sender ID values in a group.¶
Since the Gid value changes every time a group is rekeyed, it can happen that, after several rekeying instances, the whole space of Gid values has been used for the group in question. When this happens, the Group Manager has no available Gid values to use that have never been assigned to the group during the group's lifetime.¶
The occurrence of such an event and how long it would take to occur depend on the format and encoding of Gid values used in the group (see, e.g., Appendix C), as well as on the frequency of rekeying instances yielding a change of Gid value. Independently for each group under its control, the Group Manager can take one of the two following approaches.¶
While the Gid value changes every time a group is rekeyed, the Group Manager can reassign Gid values previously used during a group's lifetime. By doing so, the group can continue to exist even once the whole space of Gid values has been used.¶
The Group Manager MAY support and use this approach. In such a case, the Group Manager MUST take additional actions when handling Gid values and rekeying the group, as specified below.¶
When a node (re-)joins the group and it is provided with the current Gid to use in the group, the Group Manager considers such a Gid as the Birth Gid of that endpoint for that group. For each group member, the Group Manager MUST store the latest corresponding Birth Gid until that member leaves the group. In case the endpoint has in fact re-joined the group, the newly determined Birth Gid overwrites the one currently stored.¶
When establishing a new Security Context for the group, the Group Manager takes the additional following step between steps 1 and 2 of Section 3.2.¶
A. The Group Manager MUST check if the new Gid to be distributed is equal to the Birth Gid of any of the current group members. If any of such "elder members" is found in the group, then:¶
The Group Manager MUST evict the elder members from the group. That is, the Group Manager MUST terminate their membership and, in the following steps, it MUST rekey the group in such a way that the new keying material is not provided to those evicted elder members.¶
This ensures that any response from the same server to the request of a long exchange can never successfully match against the request of two different long exchanges.¶
In fact, the excluded elder members could eventually re-join the group, thus terminating any of their ongoing long exchanges (see Section 6.1).¶
Therefore, it is ensured by construction that no client can have with the same server two ongoing long exchanges, such that the two respective requests were protected using the same Partial IV, Gid, and Sender ID.¶
From the moment when a Gid is assigned to a group until the moment a new Gid is assigned to that same group, the Group Manager MUST NOT reassign a Sender ID within the group. This prevents to reuse a Sender ID ('kid') with the same triple (Gid, Master Secret, Master Salt). Within this restriction, the Group Manager can assign a Sender ID used under an old Gid value (including under a same, recycled Gid value), thus avoiding Sender ID values to irrecoverably grow in size.¶
Even when an endpoint joining a group is recognized as a current member of that group, e.g., through the ongoing secure communication association, the Group Manager MUST assign a new Sender ID different than the one currently used by the endpoint in the group, unless the group is rekeyed first and a new Gid value is established.¶
Figure 2 overviews the different identifiers and keying material components, considering their relation and possible reuse across group rekeying.¶
The Group Manager may serve signature checkers, e.g., intermediary gateways, which verify countersignatures of messages protected in group mode (see Section 8.5). These entities do not join a group as members, but can retrieve authentication credentials of group members and other selected group data from the Group Manager.¶
In order to verify countersignatures of messages in a group, a signature checker needs to retrieve the following information about the group:¶
The authentication credentials of the group members and of the Group Manager.¶
If the signature checker is provided with a CWT for a given entity, then the authentication credential associated with that entity is the untagged CWT.¶
If the signature checker is provided with a chain or a bag of X.509 / C509 certificates or of CWTs for a given entity, then the authentication credential associated with that entity is the end-entity certificate or end-entity untagged CWT.¶
A signature checker MUST be authorized before it can retrieve such information, for example with the use of [I-D.ietf-ace-key-groupcomm-oscore].¶
The Group Manager is responsible for performing the following tasks:¶
Generating and managing Sender IDs within its OSCORE groups, as well as assigning and providing them to new endpoints during the join process, or to current group members upon request of renewal or re-joining. This includes ensuring that:¶
The Group Manager specified in [I-D.ietf-ace-key-groupcomm-oscore] provides this functionality.¶
Building on Section 5 of [RFC8613], this section defines how to use COSE [RFC9052] to wrap and protect data in the original message. Like OSCORE, Group OSCORE uses the untagged COSE_Encrypt0 structure with an Authenticated Encryption with Associated Data (AEAD) algorithm. Unless otherwise specified, the following modifications to what is defined for OSCORE apply, for both the group mode and the pairwise mode of Group OSCORE.¶
When protecting a message in group mode, the 'unprotected' field MUST additionally include the following parameter:¶
Countersignature0 version 2: its value is set to the countersignature of the COSE object.¶
The countersignature is computed by the sender as described in Sections 3.2 and 3.3 of [RFC9338], by using its private key and according to the Signature Algorithm in the Security Context.¶
In particular, the Countersign_structure contains the context text string "CounterSignature0", the external_aad as defined in Section 4.4 of this document, and the ciphertext of the COSE object as payload.¶
The literature commonly refers to a countersignature as a signature computed by an entity A over a document already protected by a different entity B.¶
However, the COSE_Countersignature0 structure belongs to the set of abbreviated countersignatures defined in Sections 3.2 and 3.3 of [RFC9338], which were designed primarily to deal with the problem of encrypted group messaging, but where it is required to know who originated the message.¶
Since the parameters for computing or verifying the abbreviated countersignature generated by A are provided by the same context used to describe the security processing performed by B and to be countersigned, these structures are applicable also when the two entities A and B are actually the same one, like the sender of a Group OSCORE message protected in group mode.¶
The value of the 'kid' parameter in the 'unprotected' field of response messages MUST be set to the Sender ID of the endpoint transmitting the message, if the request was protected in group mode. That is, unlike in [RFC8613], the 'kid' parameter is always present in responses to a request that was protected in group mode.¶
The value of the 'kid context' parameter in the 'unprotected' field of request messages MUST be set to the ID Context, i.e., the Group Identifier value (Gid) of the group. That is, unlike in [RFC8613], the 'kid context' parameter is always present in requests.¶
The AEAD nonce is constructed like in OSCORE, with the difference that step 4 in Section 5.2 of [RFC8613] is replaced with:¶
A. and then XOR with the X least significant bits of the Common IV, where X is the length in bits of the AEAD nonce.¶
The external_aad of the Additional Authenticated Data (AAD) is different compared to OSCORE [RFC8613], and is defined in this section.¶
The same external_aad structure is used in group mode and pairwise mode for encryption/decryption (see Section 5.3 of [RFC9052]), as well as in group mode for computing and verifying the countersignature (see Sections 3.2 and 3.3 of [RFC9338]).¶
In particular, the external_aad includes also the Signature Algorithm, the Group Encryption Algorithm, the Pairwise Key Agreement Algorithm, the value of the 'kid context' in the COSE object of the request, the OSCORE option of the protected message, the sender's authentication credential, and the Group Manager's authentication credential.¶
The external_aad SHALL be a CBOR array wrapped in a bstr object as defined below, following the notation of [RFC8610]:¶
Compared with Section 5.4 of [RFC8613], the aad_array has the following differences.¶
The 'algorithms' array is extended as follows.¶
The parameter 'alg_aead' MUST be set to the CBOR simple value "null" (0xf6) if the parameter AEAD Algorithm in the Security Context is not set (see Section 2). Otherwise, regardless of whether the endpoint supports the pairwise mode or not, this parameter MUST specify AEAD Algorithm from the Common Context (see Section 2.1.1) as per Section 5.4 of [RFC8613].¶
Furthermore, the 'algorithms' array additionally includes:¶
The new element 'request_kid_context' contains the value of the 'kid context' in the COSE object of the request (see Section 4.2).¶
This enables endpoints to safely keep a long exchange active beyond a possible change of Gid (i.e., of ID Context), following a group rekeying (see Section 3.2). In fact, it ensures that every response within a long exchange cryptographically matches with only one request (i.e., the request associated with that long exchange), rather than with multiple requests that were protected with different keying material but share the same 'request_kid' and 'request_piv' values.¶
The new element 'OSCORE_option', containing the value of the OSCORE Option present in the protected message, encoded as a binary string. This prevents the attack described in Section 13.7 when using the group mode, as further explained in Section 13.7.2.¶
Note for implementation: this construction requires the OSCORE option of the message to be generated and finalized before computing the ciphertext of the COSE_Encrypt0 object (when using the group mode or the pairwise mode) and before calculating the countersignature (when using the group mode). Also, the aad_array needs to be large enough to contain the largest possible OSCORE option.¶
The OSCORE header compression defined in Section 6 of [RFC8613] is used for compactly encoding the COSE_Encrypt0 object specified in Section 4 of this document, with the following differences.¶
When the Group OSCORE message is protected in group mode, the message payload SHALL encode the ciphertext of the COSE object, concatenated with the encrypted countersignature of the COSE object. That is:¶
The encrypted countersignature, namely ENC_SIGNATURE, is computed as¶
ENC_SIGNATURE = SIGNATURE XOR KEYSTREAM¶
where KEYSTREAM is derived as per Section 5.1.¶
The following defines how an endpoint derives the keystream KEYSTREAM, used to encrypt/decrypt the countersignature of an outgoing/incoming message M protected in group mode.¶
The keystream SHALL be derived as follows, by using the HKDF Algorithm from the Common Context (see Section 3.2 of [RFC8613]), which consists of composing the HKDF-Extract and HKDF-Expand steps [RFC5869].¶
KEYSTREAM = HKDF(salt, IKM, info, L)¶
The input parameters of HKDF are as follows.¶
info = [ id : bstr, id_context : bstr, type : bool, L : uint ]¶
where:¶
id_context is the ID Context (Gid) used when protecting M.¶
Note that, in case of group rekeying, a server might use a different Gid when protecting a response, compared to the Gid that it used to verify (that the client used to protect) the request, see Section 8.3.¶
This section covers a list of OSCORE Header Compression examples of Group OSCORE used in group mode (see Section 5.2.1) or in pairwise mode (see Section 5.2.2).¶
The examples assume that the COSE_Encrypt0 object is set (which means the CoAP message and cryptographic material is known). Note that the examples do not include the full CoAP unprotected message or the full Security Context, but only the input necessary to the compression mechanism, i.e., the COSE_Encrypt0 object. The output is the compressed COSE object as defined in Section 5 and divided into two parts, since the object is transported in two CoAP fields: OSCORE option and payload.¶
The examples assume that the plaintext (see Section 5.3 of [RFC8613]) is 6 bytes long, and that the AEAD tag is 8 bytes long, hence resulting in a ciphertext which is 14 bytes long. When using the group mode, the COSE_Countersignature0 byte string as described in Section 4 is assumed to be 64 bytes long.¶
Request with ciphertext = 0xaea0155667924dff8a24e4cb35b9, kid = 0x25, Partial IV = 5 and kid context = 0x44616c.¶
[ / protected / h'', / unprotected / { / kid / 4 : h'25', / Partial IV / 6 : h'05', / kid context / 10 : h'44616c', / Countersignature0 version 2 / 12 : h'66e6d9b0 db009f3e105a673f8855611726caed57f530f8cae9d0b168 513ab949fedc3e80a96ebe94ba08d3f8d3bf83487458e2ab 4c2f936ff78b50e33c885e35' }, / ciphertext / h'aea0155667924dff8a24e4cb35b9' ]¶
Flag byte: 0b00111001 = 0x39 (1 byte) Option Value: 0x39 05 03 44 61 6c 25 (7 bytes) Payload: 0xaea0155667924dff8a24e4cb35b9 de9e ... f1 (14 bytes + size of the encrypted countersignature)¶
Response with ciphertext = 0x60b035059d9ef5667c5a0710823b, kid = 0x52 and no Partial IV.¶
[ / protected / h'', / unprotected / { / kid / 4 : h'52', / Countersignature0 version 2 / 12 : h'f5b659b8 24487eb349c5c5c8a3fe401784cade2892725438e8be0fab daa2867ee6d29f68edb0818e50ebf98c28b923d0205f5162 e73662e27c1a3ec562a49b80' }, / ciphertext / h'60b035059d9ef5667c5a0710823b' ]¶
Flag byte: 0b00101000 = 0x28 (1 byte) Option Value: 0x28 52 (2 bytes) Payload: 0x60b035059d9ef5667c5a0710823b ca1e ... b3 (14 bytes + size of the encrypted countersignature)¶
Request with ciphertext = 0xaea0155667924dff8a24e4cb35b9, kid = 0x25, Partial IV = 5 and kid context = 0x44616c.¶
[ / protected / h'', / unprotected / { / kid / 4 : h'25', / Partial IV / 6 : h'05', / kid context / 10 : h'44616c' }, / ciphertext / h'aea0155667924dff8a24e4cb35b9' ]¶
Flag byte: 0b00011001 = 0x19 (1 byte) Option Value: 0x19 05 03 44 61 6c 25 (7 bytes) Payload: 0xaea0155667924dff8a24e4cb35b9 (14 bytes)¶
Response with ciphertext = 0x60b035059d9ef5667c5a0710823b and no Partial IV.¶
[ / protected / h'', / unprotected / {}, / ciphertext / h'60b035059d9ef5667c5a0710823b' ]¶
Flag byte: 0b00000000 = 0x00 (1 byte) Option Value: 0x (0 bytes) Payload: 0x60b035059d9ef5667c5a0710823b (14 bytes)¶
Like OSCORE, Group OSCORE provides message binding of responses to requests, as well as uniqueness of AEAD (key, nonce) pair (see Sections 7.1 and 7.2 of [RFC8613], respectively).¶
For each of its ongoing long exchange, a client maintains one Response Number for each different server. Then, separately for each server, the client uses the associated Response Number to perform ordering and replay protection of responses received from that server within that long exchange (see Section 6.3.1).¶
That is, the Response Number has the same purpose that the Notification Number has in OSCORE (see Section 4.1.3.5.2 of [RFC8613]), but a client uses it for handling any response from the associated server within a long exchange.¶
Group OSCORE allows to preserve a long exchange active indefinitely, even in case the group is rekeyed, with consequent change of ID Context, or in case the client obtains a new Sender ID.¶
As defined in Section 8, this is achieved by the client and server(s) storing the 'kid' and 'kid context' used in the original request, throughout the whole duration of the long exchange.¶
Upon leaving the group or before re-joining the group, a group member MUST terminate all the ongoing long exchanges that it has started in the group as a client, and hence frees up the CoAP Token associated with the corresponding request.¶
If the application requires freshness, e.g., according to time- or event-based policies (see Section 2.5.1 of [RFC9175]), a server can use the approach in Section 10 as a variant of the procedure in Appendix B.1.2 of [RFC8613], before delivering request messages from a client to the application. This also makes the server (re-)synchronize with the client's Sender Sequence Number.¶
Like in OSCORE [RFC8613], assuming an honest server, the message binding guarantees that a response is not older than the request it replies to. Therefore, building on Section 7.3 of [RFC8613], the following properties hold for Group OSCORE.¶
The freshness of a response can be assessed if it is received soon after the request.¶
For responses within a long exchange, this assessment gets weaker with time. If such responses are Observe notifications [RFC7641], it is RECOMMENDED that the client regularly re-register the observation.¶
If the request was neither a group request nor an Observe request, there is at most a single valid response and only from one, individually targeted server in the group. Thus, freshness can be assessed depending on when the request was sent.¶
Like in OSCORE [RFC8613], the replay protection relies on the Partial IV of incoming messages. A server updates the Replay Window of its Recipient Contexts based on the Partial IV values in received request messages, which correspond to the Sender Sequence Numbers of the clients. Note that there can be large jumps in these Sender Sequence Number values, for example when a client exchanges unicast messages with other servers. The operation of validating the Partial IV and performing replay protection MUST be atomic. The update of Replay Windows is described in Section 2.6.1.¶
The protection from replay of requests is performed as per Section 7.4 of [RFC8613], separately for each client and by leveraging the Replay Window in the corresponding Recipient Context. The protection from replay of responses in a long exchange is performed as defined in Section 6.3.1.¶
A client uses the method defined in this section in order to check whether a received response is a replay.¶
This especially applies to responses received within a long exchange, during which multiple such responses can be received from the same server to the corresponding request. These include Observe notifications [RFC7641]; and non-notification responses as a reply to a group request, which the client can receive until the CoAP Token value associated with the group request is freed up (see Section 3.1.6 of [I-D.ietf-core-groupcomm-bis]).¶
When sending a response (both successful and error), a server MUST include its Sender Sequence Number as Partial IV in the response, except when sending the first response to the corresponding request, in which case the Partial IV in the response MAY be omitted.¶
In order to protect against replay, the client SHALL maintain for each ongoing long exchange one Response Number for each different server. The Response Number is a non-negative integer containing the largest Partial IV of the responses received from that server during the long exchange, while using the same Security Context.¶
Then, separately for each server, the client uses the associated Response Number to perform ordering and replay protection of the responses from that server during the long exchange, by comparing their Partial IVs with one another and against the Response Number.¶
For every long exchange, the Response Number associated with a server is initialized to the Partial IV of the response from that server such that, within the long exchange, it is the first response from that server to include a Partial IV and to be successfully verified with the used Security Context. Note that, when a new Security Context is established in the group, the client sets the Response Number of each associated server as not initialized (see Section 2.6.3.2), hence later responses within the same long exchange and protected with the new Security Context will result in a new initialization of Response Numbers. Furthermore, for every long exchange, a client MUST only accept at most one response without Partial IV from each server, and treat it as the oldest response from that server within that long exchange.¶
During a long exchange, a client receiving a response containing a Partial IV SHALL compare the Partial IV with the Response Number associated with the replying server within that long exchange. The client MUST stop processing a response from a server, if that response has a Partial IV that has been previously received from that server during that long exchange, while using the same Security Context. Applications MAY decide that a client only processes responses within a long exchange if those have a greater Partial IV than the Response Number associated with the replying server within that long exchange.¶
If the verification of the response succeeds, and the received Partial IV (when included) was greater than the Response Number associated with the replying server, then the client SHALL overwrite that Response Number with the received Partial IV.¶
As long as a server uses the same Security Context to protect its responses to the same request, the client MUST consider the response with the highest Partial IV as the freshest response from that server among those protected with that Security Context, regardless of the order of arrival. Within a long exchange, implementations need to make sure that a response without Partial IV is considered the oldest response from the replying server within that long exchange.¶
The method defined in this section is not relevant for responses to requests that are neither group requests nor Observe requests. In fact, for each of such requests, there is at most one response and only from one, individually targeted server in the group.¶
Upon receiving a protected message, a recipient endpoint retrieves a Security Context as in [RFC8613]. An endpoint MUST be able to distinguish between a Security Context to process OSCORE messages as in [RFC8613] and a Group OSCORE Security Context to process Group OSCORE messages as defined in this document.¶
To this end, an endpoint can take into account the different structure of the Security Context defined in Section 2, for example based on the presence of Signature Algorithm and Pairwise Key Agreement Algorithm in the Common Context. Alternatively, implementations can use an additional parameter in the Security Context, to explicitly mark that it is intended for processing Group OSCORE messages.¶
If either of the following conditions holds, a recipient endpoint MUST discard the incoming protected message:¶
The Group Flag is set to 1 but there is no Security Context associated with an OSCORE group.¶
Future specifications may define how to process incoming messages protected with Security Contexts as in [RFC8613], when the Group Flag bit is set to 1.¶
Otherwise, if a Security Context associated with an OSCORE group is retrieved, the recipient endpoint processes the message with Group OSCORE, using the group mode (see Section 8) if the Group Flag is set to 1, or the pairwise mode (see Section 9) if the Group Flag is set to 0.¶
Note that, if the Group Flag is set to 0, and the recipient endpoint retrieves a Security Context which is valid to process the message but is not associated with an OSCORE group, then the message is processed according to [RFC8613].¶
When using the group mode, messages are protected and processed as specified in [RFC8613], with the modifications described in this section. The security objectives of the group mode are discussed in Appendix A.2.¶
The possible use of the group mode is indicated by the Group Manager as part of the group data provided to candidate group members when joining the group, according to which the parameters Group Encryption Algorithm and Signature Algorithm in the Security Context are set (see Section 2).¶
During all the steps of the message processing, an endpoint MUST use the same Security Context for the considered group. That is, an endpoint MUST NOT install a new Security Context for that group (see Section 2.6.3.2) until the message processing is completed.¶
The group mode SHOULD be used to protect group requests intended for multiple recipients or for the whole group. For an example where this is not fulfilled, see [I-D.amsuess-core-cachable-oscore]. This applies to both requests directly addressed to multiple recipients, e.g., sent by the client over multicast, as well as requests sent by the client over unicast to a proxy, that forwards them to the intended recipients over multicast [I-D.ietf-core-groupcomm-bis].¶
As per [RFC7252][I-D.ietf-core-groupcomm-bis], group requests sent over multicast MUST be Non-confirmable, and thus are not retransmitted by the CoAP messaging layer. Instead, applications should store such outgoing messages for a predefined, sufficient amount of time, in order to correctly perform potential retransmissions at the application layer. If performed, these retransmissions are repetitions of previous protected messages, which the sender endpoint does not protect again with Group OSCORE.¶
According to Section 5.2.3 of [RFC7252], responses to Non-confirmable group requests SHOULD also be Non-confirmable, but endpoints MUST be prepared to receive Confirmable responses in reply to a Non-confirmable group request. Confirmable group requests are acknowledged when sent over non-multicast transports, as specified in [RFC7252].¶
Furthermore, endpoints in the group locally perform error handling and processing of invalid messages according to the same principles adopted in [RFC8613]. In addition, a recipient MUST stop processing and reject any message that is malformed and that does not follow the format specified in Section 4 of this document, or that is not cryptographically validated in a successful way as per the processing defined in Section 8.2 and Section 8.4 of this document.¶
In either case, it is RECOMMENDED that a server does not send back any error message in reply to a received request, if any of the two following conditions holds:¶
This prevents servers from replying with multiple error messages to a client sending a group request, so avoiding the risk of flooding and possibly congesting the network.¶
When using the group mode to protect a request, a client SHALL proceed as described in Section 8.1 of [RFC8613], with the following modifications.¶
In addition, the following applies when sending a request that establishes a long exchange.¶
If the client intends to keep the long exchange active beyond a possible change of ID Context following a group rekeying (see Section 3.2), then the following applies.¶
The client MUST store an invariant identifier of the group, which is immutable even in case the Security Context of the group is re-established. For example, this invariant identifier can be the "group name" in [I-D.ietf-ace-key-groupcomm-oscore], where it is used for joining the group and retrieving the current group keying material from the Group Manager.¶
After a group rekeying, such an invariant information makes it simpler for the client to retrieve the current group keying material from the Group Manager, in case the client has missed both the rekeying messages and the first response protected with the new Security Context (see Section 8.3).¶
Upon receiving a protected request with the Group Flag set to 1, following the procedure in Section 7, a server SHALL proceed as described in Section 8.2 of [RFC8613], with the following modifications.¶
In step 2, the decoding of the compressed COSE object follows Section 5 of this document. In particular:¶
In step 6, the server also verifies the countersignature, by using the public key from the client's authentication credential stored in the associated Recipient Context. In particular:¶
The server retrieves the encrypted countersignature ENC_SIGNATURE from the message payload, and computes the original countersignature SIGNATURE as¶
SIGNATURE = ENC_SIGNATURE XOR KEYSTREAM¶
where KEYSTREAM is derived as per Section 5.1.¶
The server verifies the original countersignature SIGNATURE as described in Sections 3.2 and 3.3 of [RFC9338], by using the client's public key and according to the Signature Algorithm in the Security Context.¶
In particular, the Countersign_structure contains the context text string "CounterSignature0", the external_aad as defined in Section 4.4 of this document, and the ciphertext of the COSE object as payload.¶
A server SHOULD NOT process a request if the received Recipient ID ('kid') is equal to its own Sender ID in its own Sender Context. For an example where this is not fulfilled, see Section 9.2.1 of [I-D.ietf-core-observe-multicast-notifications].¶
In addition, the following applies if the request establishes a long exchange and the server intends to reply with multiple responses.¶
When using the group mode to protect a response, a server SHALL proceed as described in Section 8.3 of [RFC8613], with the following modifications.¶
Note that the server always protects a response with the Sender Context from its latest Security Context, and that establishing a new Security Context resets the Sender Sequence Number to 0 (see Section 3.2).¶
In step 2, the Additional Authenticated Data is modified as described in Section 4 of this document.¶
In addition, the following applies if the server intends to reply with multiple responses, within the long exchange established by the corresponding request.¶
In step 3, if any of the following two conditions holds, the server MUST include its Sender Sequence Number as Partial IV in the response and use it to build the AEAD nonce to protect the response. This prevents the server from reusing the AEAD nonce from the request together with the same encryption key.¶
In step 4, the encryption of the COSE object is modified as described in Section 4 of this document. The encoding of the compressed COSE object is modified as described in Section 5 of this document. In particular, the Group Flag MUST be set to 1. The Group Encryption Algorithm from the Common Context MUST be used.¶
In addition, the following applies.¶
The server may be replying to a request that was protected with an old Security Context. After completing the establishment of a new Security Context, the server MUST protect all the responses to that request with the Sender Context of the new Security Context.¶
For each ongoing long exchange, the server can help the client to synchronize, by including also the 'kid context' parameter in responses following a group rekeying, with value set to the ID Context (Gid) of the new Security Context.¶
If there is a known upper limit to the duration of a group rekeying, the server SHOULD include the 'kid context' parameter during that time. Otherwise, the server SHOULD include it until the Max-Age has expired for the last response sent before the installation of the new Security Context.¶
The server can obtain a new Sender ID from the Group Manager, when individually rekeyed (see Section 2.6.3.1) or when re-joining the group. In such a case, the server can help the client to synchronize, by including the 'kid' parameter in a response protected in group mode, even when the request was protected in pairwise mode (see Section 9.3).¶
That is, when responding to a request protected in pairwise mode, the server SHOULD include the 'kid' parameter in a response protected in group mode, if it is replying to that client for the first time since the assignment of its new Sender ID.¶
Upon receiving a protected response with the Group Flag set to 1, following the procedure in Section 7, a client SHALL proceed as described in Section 8.4 of [RFC8613], with the modifications described in this section.¶
Note that a client may receive a response protected with a Security Context different from the one used to protect the corresponding request, and that, upon the establishment of a new Security Context, the client re-initializes its Replay Windows in its Recipient Contexts (see Section 3.2).¶
In step 2, the decoding of the compressed COSE object is modified as described in Section 5 of this document. In particular, a 'kid' may not be present, if the response is a reply to a request protected in pairwise mode. In such a case, the client assumes the response 'kid' to be the Recipient ID for the server to which the request protected in pairwise mode was intended for.¶
If the response 'kid context' matches an existing ID Context (Gid) but the received/assumed 'kid' does not match any Recipient ID in this Security Context, then the client MAY create a new Recipient Context for this Recipient ID and initialize it according to Section 3 of [RFC8613], and also retrieve the authentication credential associated with the Recipient ID to be stored in the new Recipient Context. If the application does not specify dynamic derivation of new Recipient Contexts, then the client SHALL stop processing the response.¶
In step 3, the Additional Authenticated Data is modified as described in Section 4 of this document.¶
In addition, the following applies if the client processes a response to a request within a long exchange.¶
This ensures that, throughout a long exchange, the client can correctly verify the received responses, even in case the client is individually rekeyed and starts using a new Sender ID received from the Group Manager (see Section 2.6.3.1), as well as when it installs a new Security Context with a new ID Context (Gid) following a group rekeying (see Section 3.2).¶
In step 5, the client also verifies the countersignature, by using the public key from the server's authentication credential stored in the associated Recipient Context. In particular:¶
The client retrieves the encrypted countersignature ENC_SIGNATURE from the message payload, and computes the original countersignature SIGNATURE as¶
SIGNATURE = ENC_SIGNATURE XOR KEYSTREAM¶
where KEYSTREAM is derived as per Section 5.1.¶
The client verifies the original countersignature SIGNATURE.¶
After a successful verification of the countersignature, the client performs also the following actions in case the request was protected in pairwise mode (see Section 9.3).¶
In either case, if the client determines that the response has come from a different server than the expected one, then the client: i) SHALL discard the response and SHALL NOT deliver it to the application; ii) SHALL NOT update the Response Number associated with the server.¶
Otherwise, the client hereafter considers the received 'kid' as the current Recipient ID for the server.¶
In step 5, when decrypting the COSE object using the Recipient Key, the Group Encryption Algorithm from the Common Context MUST be used.¶
In addition, the client performs the following actions if the response is received within a long exchange.¶
When receiving another valid response to the same request from the same server - which can be identified and recognized through the same public key used to verify the countersignature and included in the server's authentication credential - the client determines the current kid "kid2" of the server as above for "kid1", and MUST check whether "kid2" is equal to the stored "kid1".¶
If "kid1" and "kid2" are different, the client SHOULD NOT accept the response as valid to be delivered to the application, and SHOULD NOT update the Response Number associated with the server. Exceptions can apply if the client has a means of preserving the order of responses in a more elaborate way out of the scope of this document, or the client application does not require response ordering altogether.¶
Note that, if "kid2" is different from "kid1" and the 'kid' field is omitted from the response - which is possible if the request was protected in pairwise mode - then the client will compute a wrong keystream to decrypt the countersignature (i.e., by using "kid1" rather than "kid2" in the 'id' field of the 'info' array in Section 5.1), thus subsequently failing to verify the countersignature and discarding the response.¶
This ensures that the client remains able to correctly perform the ordering and replay protection of responses within a long exchange, even in case the server legitimately starts using a new Sender ID, as received from the Group Manager when individually rekeyed (see Section 2.6.3.1) or when re-joining the group.¶
When receiving a message protected in group mode, a signature checker (see Section 3.3) proceeds as follows.¶
The signature checker retrieves the encrypted countersignature ENC_SIGNATURE from the message payload, and computes the original countersignature SIGNATURE as¶
SIGNATURE = ENC_SIGNATURE XOR KEYSTREAM¶
where KEYSTREAM is derived as per Section 5.1.¶
Note that the following applies when attempting to verify the countersignature of a response message.¶
The particular actions following a successful or unsuccessful verification of the countersignature are application specific and out of the scope of this document.¶
When using the pairwise mode of Group OSCORE, messages are protected and processed as in [RFC8613], with the modifications described in this section. The security objectives of the pairwise mode are discussed in Appendix A.2.¶
The possible use of the pairwise mode is indicated by the Group Manager as part of the group data provided to candidate group members when joining the group, according to which the parameters AEAD Algorithm and Pairwise Key Agreement Algorithm in the Security Context are set (see Section 2).¶
The pairwise mode takes advantage of an existing Security Context to establish keying material shared exclusively with any other member. For encryption and decryption operations in pairwise mode, the AEAD Algorithm from the Common Context is used (see Section 2.1.1).¶
In order to use the pairwise mode in a group where the group mode is also used (i.e., Group Encryption Algorithm and Signature Algorithm in the Security Context are set), the signature scheme of the group mode MUST support a combined signature and encryption scheme. For example, this can rely on signing operations using ECDSA, and encryption operations using AES-CCM with keying material derived through ECDH.¶
The pairwise mode does not support external verifiers of source authentication and message integrity like the group mode does (see Section 8.5).¶
An endpoint implementing only a silent server does not support the pairwise mode.¶
Endpoints using the CoAP Echo Option [RFC9175] and/or block-wise transfers [RFC7959] in a group where the AEAD Algorithm and Pairwise Key Agreement Algorithm are set MUST support the pairwise mode. This applies, for example, to block-wise exchanges after a first block-wise request which targets all servers in the group and includes the CoAP Block2 option (see Section 3.8 of [I-D.ietf-core-groupcomm-bis]). This prevents the attack described in Section 13.9, which leverages requests sent over unicast to a single group member and protected in group mode.¶
The pairwise mode cannot be used to protect messages intended for multiple recipients. In fact, the keying material used for the pairwise mode is shared only between two endpoints.¶
However, a sender can use the pairwise mode to protect a message sent to (but not intended for) multiple recipients, if interested in a response from only one of them. For instance, this is useful to support the address discovery service defined in Section 9.1, when a single 'kid' value is indicated in the payload of a request sent to multiple recipients, e.g., over multicast.¶
In order to protect an outgoing message in pairwise mode, the sender needs to know the authentication credential and the Recipient ID for the recipient endpoint, as stored in the Recipient Context associated with that endpoint (see Section 2.5.4).¶
Furthermore, the sender needs to know the individual address of the recipient endpoint. This information may not be known at any given point in time. For instance, right after having joined the group, a client may know the authentication credential and Recipient ID for a given server, but not the addressing information required to reach it with an individual, one-to-one request.¶
In order to make addressing information of individual endpoints available, servers in the group MAY expose a resource to which a client can send a request targeting a set of servers, identified by their 'kid' values specified in the request payload, or implicitly if the request is sent in pairwise mode. Further details of such an interface are out of scope for this document.¶
The pairwise mode protects messages between two members of a group, essentially following [RFC8613], but with the following notable differences.¶
When using the pairwise mode to protect a request, a client SHALL proceed as described in Section 8.1 of [RFC8613], with the differences summarized in Section 9.2 of this document.¶
Furthermore, when sending a request that establishes a long exchange, what is specified in Section 8.1 of this document holds, with respect to storing the value of the 'kid' and 'kid context' parameters, and to storing an invariant identifier of the group.¶
Upon receiving a protected request with the Group Flag set to 0, following the procedure in Section 7, a server SHALL proceed as described in Section 8.2 of [RFC8613], with the differences summarized in Section 9.2 of this document. The following differences also apply.¶
What is specified in Section 8.2 of this document holds with respect to the following points.¶
When using the pairwise mode to protect a response, a server SHALL proceed as described in Section 8.3 of [RFC8613], with the differences summarized in Section 9.2 of this document. The following differences also apply.¶
What is specified in Section 8.3 of this document holds with respect to the following points.¶
Upon receiving a protected response with the Group Flag set to 0, following the procedure in Section 7, a client SHALL proceed as described in Section 8.4 of [RFC8613], with the differences summarized in Section 9.2 of this document. The following differences also apply.¶
What is specified in Section 8.4 of this document holds with respect to the following points.¶
This section describes how a server endpoint can verify freshness of a request and synchronize with Sender Sequence Numbers of client endpoints in the group. Similarly to what is defined in Appendix B.1.2 of [RFC8613], the server performs a challenge-response exchange with a client, by using the Echo Option for CoAP specified in Section 2 of [RFC9175].¶
Upon receiving a request from a particular client for the first time, the server processes the message as described in this document, but, even if valid, does not deliver it to the application. Instead, the server replies to the client with a Group OSCORE protected 4.01 (Unauthorized) response message, including only the Echo Option and no diagnostic payload. The server MUST use its Partial IV when generating the AEAD nonce for protecting the response conveying the Echo Option, and MUST include the Partial IV in the response.¶
The Echo option value SHOULD NOT be reused; if it is reused, it MUST be highly unlikely to have been recently used with this client. Since this response is protected with the Security Context used in the group, the client will consider the response valid upon successfully decrypting and verifying it.¶
The server stores the Echo Option value included in the response together with the pair (gid,kid), where 'gid' is the Group Identifier of the OSCORE group and 'kid' is the Sender ID of the client in the group. These are specified in the 'kid context' and 'kid' fields of the OSCORE Option of the request, respectively. After a group rekeying has been completed and a new Security Context has been established in the group, which results also in a new Group Identifier (see Section 3.2), the server MUST delete all the stored Echo values associated with members of the group.¶
Upon receiving a 4.01 (Unauthorized) response that includes an Echo Option and originates from a verified group member, the subsequent client request echoing the Echo Option value MUST be sent as a unicast message to the same server.¶
If in the group the AEAD Algorithm and Pairwise Key Agreement Algorithm are set in the Security Context, the client MUST use the pairwise mode to protect the request, as per Section 9.3. Note that, as defined in Section 9, endpoints that are members of such a group and that use the Echo Option support the pairwise mode. In a group where the AEAD Algorithm and Pairwise Key Agreement Algorithm are not set, only the group mode can be used. Hence, requests including the Echo option can be protected only with the Group Mode, with the caveat due to the risk for those requests to be redirected to a different server than the intended one, as discussed in Section 13.9.¶
The client does not necessarily resend the same request, but can instead send a more recent one, if the application permits it. This allows the client to not retain previously sent requests for full retransmission, unless the application explicitly requires otherwise. In either case, the client uses a fresh Sender Sequence Number value from its own Sender Context. If the client stores requests for possible retransmission with the Echo Option, it should not store a given request for longer than a preconfigured time interval. Note that the unicast request echoing the Echo Option is correctly treated and processed, since the 'kid context' field including the Group Identifier of the OSCORE group is still present in the OSCORE Option as part of the COSE object (see Section 4).¶
Upon receiving the unicast request including the Echo Option, the server performs the following verifications.¶
If the verifications above fail, the server MUST NOT process the request further and MAY send a 4.01 (Unauthorized) response including an Echo Option, hence performing a new challenge-response exchange.¶
If the verifications above are successful, the server considers the Recipient Context associated with the sender client and proceeds as follows.¶
In case the Replay Window is invalid, the steps below occur.¶
A server should not deliver requests from a given client to the application until one valid request from that same client has been verified as fresh, as conveying an echoed Echo Option. A server may perform the challenge-response described above at any time, if synchronization with Sender Sequence Numbers of clients is lost, e.g., after a device reboot occurred in an unprepared way. A client has to be ready to perform the challenge-response based on the Echo Option if a server starts it.¶
Message freshness is further discussed in Section 13.14.¶
Like in [RFC8613], HKDF SHA-256 is the mandatory to implement HKDF.¶
An endpoint may support only the group mode, or only the pairwise mode, or both.¶
For endpoints that support the group mode, the following applies.¶
For many constrained IoT devices it is problematic to support more than one signature algorithm. Existing devices can be expected to support either EdDSA or ECDSA. In order to enable as much interoperability as we can reasonably achieve, the following applies with respect to the Signature Algorithm (see Section 2.1.7).¶
Less constrained endpoints SHOULD implement both: the EdDSA signature algorithm together with the elliptic curve Ed25519 [RFC8032]; and the ECDSA signature algorithm together with the elliptic curve P-256.¶
Constrained endpoints SHOULD implement: the EdDSA signature algorithm together with the elliptic curve Ed25519 [RFC8032]; or the ECDSA signature algorithm together with the elliptic curve P-256.¶
For endpoints that support the pairwise mode, the following applies.¶
In order to enable as much interoperability as we can reasonably achieve in the presence of constrained devices (see above), the following applies.¶
Less constrained endpoints SHOULD implement both the X25519 curve [RFC7748] and the P-256 curve as ECDH curves.¶
Constrained endpoints SHOULD implement the X25519 curve [RFC7748] or the P-256 curve as ECDH curve.¶
Constrained IoT devices may alternatively represent Montgomery curves and (twisted) Edwards curves [RFC7748] in the short-Weierstrass form Wei25519, with which the algorithms ECDSA25519 and ECDH25519 can be used for signature operations and Diffie-Hellman secret calculation, respectively [I-D.ietf-lwig-curve-representations].¶
The use of Group OSCORE or OSCORE [RFC8613] MAY be indicated by a target "gosc" attribute in a web link [RFC8288] to a resource, e.g., using a link-format document [RFC6690] if the resource is accessible over CoAP.¶
The "gosc" attribute is a hint indicating that the destination of that link is only accessible using Group OSCORE or OSCORE, and unprotected access to it is not supported. Note that this is simply a hint, it does not include any security context material or any other information required to run Group OSCORE or OSCORE.¶
A value MUST NOT be given for the "gosc" attribute; any present value MUST be ignored by parsers. The "gosc" attribute MUST NOT appear more than once in a given link-value; occurrences after the first MUST be ignored by parsers.¶
When a link-value includes the "gosc" attribute, the link-value MUST also include the "osc" attribute defined in Section 9 of [RFC8613]. If the endpoint parsing the link-value supports Group OSCORE and understands the "gosc" attribute, then the parser MUST ignore the "osc" attribute, which is overshadowed by the "gosc" attribute.¶
The example in Figure 4 shows a use of the "gosc" attribute: the client does resource discovery on a server and gets back a list of resources, one of which includes the "gosc" attribute indicating that the resource is protected with Group OSCORE or OSCORE. The link-format notation (see Section 5 of [RFC6690]) is used.¶
The same threat model discussed for OSCORE in Appendix D.1 of [RFC8613] holds for Group OSCORE.¶
For Group OSCORE, the Sender Context and Recipient Context additionally contain asymmetric keys, which are used to provide source authentication: in group mode, by means of countersignatures (see Section 13.1); in pairwise mode, by using Diffie-Hellman (see Section 13.2). The key pair can, for example, be generated by the endpoint or provisioned during manufacturing.¶
Note that, even if an endpoint is authorized to be a group member and to take part in group communications, there is a risk that it behaves inappropriately. For instance, it can forward the content of messages in the group to unauthorized entities. However, in many use cases, the devices in the group belong to a common authority and are configured by a commissioner (see Appendix B), which results in a practically limited risk and enables a prompt detection/reaction in case of misbehaving.¶
The same considerations on supporting Proxy operations discussed for OSCORE in Appendix D.2 of [RFC8613] hold for Group OSCORE.¶
The same considerations on protected message fields for OSCORE discussed in Appendix D.3 of [RFC8613] hold for Group OSCORE.¶
The same considerations on uniqueness of (key, nonce) pairs for OSCORE discussed in Appendix D.4 of [RFC8613] hold for Group OSCORE. This is further discussed in Section 13.3 of this document.¶
The same considerations on unprotected message fields for OSCORE discussed in Appendix D.5 of [RFC8613] hold for Group OSCORE, with the following differences. First, the 'kid context' of request messages is part of the Additional Authenticated Data, thus safely enabling to keep long exchanges active beyond a possible change of ID Context (Gid), following a group rekeying (see Section 4.4). Second, the countersignature included in a Group OSCORE message protected in group mode is computed also over the value of the OSCORE option, which is also part of the Additional Authenticated Data used in the signing process. This is further discussed in Section 13.7 of this document.¶
As discussed in Section 6.2.3 of [I-D.ietf-core-groupcomm-bis], Group OSCORE addresses security attacks against CoAP listed in Sections 11.2-11.6 of [RFC7252], especially when run over IP multicast.¶
The rest of this section first discusses security aspects to be taken into account when using Group OSCORE. Then it goes through aspects covered in the security considerations of OSCORE (see Section 12 of [RFC8613]), and discusses how they hold when Group OSCORE is used.¶
The group mode defined in Section 8 relies on commonly shared group keying material to protect communication within a group. Using the group mode has the implications discussed below. The following refers to group members as the endpoints in the group storing the latest version of the group keying material.¶
If the used Group Encryption Algorithm provides integrity protection, then it also ensures group authentication and proof of group membership, but not source authentication. That is, it ensures that a message sent to a group has been sent by a member of that group, but not necessarily by the alleged sender. In fact, any group member is able to derive the Sender Key used by the actual sender endpoint, and thus can compute a valid authentication tag. Therefore, the message content could originate from any of the current group members.¶
Furthermore, if the used Group Encryption Algorithm does not provide integrity protection, then it does not ensure any level of message authentication or proof of group membership.¶
On the other hand, proof of group membership is always ensured by construction through the strict management of the group keying material (see Section 3.2). That is, the group is rekeyed in case of members' leaving, and the current group members are informed of former group members. Thus, a current group member storing the latest group keying material does not store the authentication credential of any former group member.¶
This allows a recipient endpoint to rely on the stored authentication credentials and public keys included therein, in order to always confidently assert the group membership of a sender endpoint when processing an incoming message, i.e., to assert that the sender endpoint was a group member when it signed the message. In turn, this prevents a former group member to possibly re-sign and inject in the group a stored message that was protected with old keying material.¶
A case in point is a group where the Group Encryption Algorithm does not provide integrity protection; a group member leaves the group; and, after the group rekeying, associates with the group as external signature checker (see Section 8.5). When doing so, it obtains from the Group Manager the new Signature Encryption Key, from which it can derive keystreams for encrypting and decrypting the countersignatures of messages protected in group mode.¶
If, when participating in the group rekeying, the current group members had not deleted the Recipient Context and authentication credential of the former group member, then the signature checker would be able to successfully inject messages protected in group mode, as encrypted with the old group keying material, signed with its own private key, and with the countersignature encrypted by means of the latest Signature Encryption Key. Then, the group members, as still retaining the authentication credential of the signature checker, will verify and accept the message, even though the sender was not a group member when signing the message.¶
The security properties of the group mode are summarized below.¶
The group mode fulfills the security properties above while also displaying the following benefits. First, the use of a Group Encryption Algorithm that does not provide integrity protection results in a minimal communication overhead, by limiting the message payload to the ciphertext without integrity tag together with the encrypted countersignature. Second, it is possible to deploy semi-trusted entities such as signature checkers (see Section 3.3), which can break property 5, but cannot break properties 1, 2, 3, and 4.¶
The pairwise mode defined in Section 9 protects messages by using pairwise symmetric keys, derived from the static-static Diffie-Hellman shared secret computed from the asymmetric keys of the sender and recipient endpoint (see Section 2.5).¶
The used AEAD Algorithm MUST provide integrity protection. Therefore, the pairwise mode ensures both pairwise data-confidentiality and source authentication of messages, without using countersignatures. Furthermore, the recipient endpoint achieves proof of group membership for the sender endpoint, since only current group members have the required keying material to derive a valid Pairwise Sender/Recipient Key.¶
The long-term storing of the Diffie-Hellman shared secret is a potential security issue. In fact, if the shared secret of two group members is leaked, a third group member can exploit it to impersonate any of those two group members, by deriving and using their pairwise key. The possibility of such leakage should be contemplated, as more likely to happen than the leakage of a private key, which could be rather protected at a significantly higher level than generic memory, e.g., by using a Trusted Platform Module. Therefore, there is a trade-off between the maximum amount of time a same shared secret is stored and the frequency of its re-computing.¶
The proof for uniqueness of (key, nonce) pairs in Appendix D.4 of [RFC8613] is also valid in group communication scenarios. That is, given an OSCORE group:¶
As a consequence, each message encrypted/decrypted with the same Sender Key is processed by using a different (ID_PIV, PIV) pair. This means that nonces used by any fixed encrypting endpoint are unique. Thus, each message is processed with a different (key, nonce) pair.¶
The protocol described in this document should take into account the risk of compromise of group members. In particular, this document specifies that a key management scheme for secure revocation and renewal of Security Contexts and group keying material MUST be adopted.¶
[I-D.ietf-ace-key-groupcomm-oscore] specifies a simple rekeying scheme for renewing the Security Context in a group.¶
Alternative rekeying schemes that are more scalable with the group size may be needed in dynamic, large groups where endpoints can join and leave at any time, in order to limit the impact on performance due to the Security Context and keying material update.¶
A group member can receive a message shortly after the group has been rekeyed, and new security parameters and keying material have been distributed by the Group Manager.¶
This may result in a client using an old Security Context to protect a request, and a server using a different new Security Context to protect a corresponding response. As a consequence, clients may receive a response protected with a Security Context different from the one used to protect the corresponding request.¶
In particular, a server may first get a request protected with the old Security Context, then install the new Security Context, and only after that produce a response to send back to the client. In such a case, as specified in Section 8.3, the server MUST protect the potential response using the new Security Context. Specifically, the server MUST include its Sender Sequence Number as Partial IV in the response and use it to build the AEAD nonce to protect the response. This prevents the AEAD nonce from the request from being reused with the new Security Context.¶
The client will process that response using the new Security Context, provided that it has installed the new security parameters and keying material before the message processing.¶
In case block-wise transfer [RFC7959] is used, the same considerations from Section 10.3 of [I-D.ietf-ace-key-groupcomm] hold.¶
Furthermore, as described below, a group rekeying may temporarily result in misaligned Security Contexts between the sender and recipient of a same message.¶
In this case, the sender protects a message using the old Security Context, i.e., before having installed the new Security Context. However, the recipient receives the message after having installed the new Security Context, and is thus unable to correctly process it.¶
A possible way to ameliorate this issue is to preserve the old retained Security Context for a maximum amount of time defined by the application. By doing so, the recipient can still try to process the received message using the old retained Security Context.¶
This makes particular sense when the recipient is a client, that would hence be able to process incoming responses protected with the old retained Security Context used to protect the associated request. If, as typically expected, the old Gid is not included in the response, then the client will first fail to process the response using the latest Security Context, and then use the old retained Security Context as a second attempt.¶
Instead, a recipient server can immediately process an incoming request with the old retained Security Context, as signaled by the old Gid that is always included in requests. However, the server would better and more simply discard such an incoming request.¶
This tolerance preserves the processing of secure messages throughout a long-lasting key rotation, as group rekeying processes may likely take a long time to complete, especially in large groups. On the other hand, a former (compromised) group member can abusively take advantage of this, and send messages protected with the old retained Security Context. Therefore, a conservative application policy should not admit the retention of old Security Contexts.¶
In this case, the sender protects a message using the new Security Context, but the recipient receives that message before having installed the new Security Context. Therefore, the recipient would not be able to correctly process the message and hence discards it.¶
If the recipient installs the new Security Context shortly after that and the sender endpoint retransmits the message, the former will still be able to receive and correctly process the message.¶
In any case, the recipient should actively ask the Group Manager for an updated Security Context according to an application-defined policy, for instance after a given number of unsuccessfully decrypted incoming messages.¶
In case endpoints are deployed in multiple groups managed by different non-synchronized Group Managers, it is possible for Group Identifiers of different groups to coincide.¶
This does not impair the security of the AEAD algorithm. In fact, as long as the Master Secret is different for different groups and this condition holds over time, AEAD keys are different among different groups.¶
In case multiple groups use the same IP multicast address, the entity assigning that address may help limiting the chances to experience such collisions of Group Identifiers. In particular, it may allow the Group Managers of those groups using the same IP multicast address to share their respective list of assigned Group Identifiers currently in use.¶
A same endpoint is allowed to and would likely use the same pair (private key, authentication credential) in multiple OSCORE groups, possibly administered by different Group Managers.¶
When a sender endpoint sends a message protected in pairwise mode to a recipient endpoint in an OSCORE group, a malicious group member may attempt to inject the message to a different OSCORE group also including the same endpoints (see Section 13.7.1).¶
This practically relies on altering the content of the OSCORE option, and having the same MAC in the ciphertext still correctly validating, which has a success probability depending on the size of the MAC.¶
As discussed in Section 13.7.2, the attack is practically infeasible if the message is protected in group mode, thanks to the countersignature also bound to the OSCORE option through the Additional Authenticated Data used in the signing process (see Section 4.4).¶
Let us consider:¶
When X sends a message M1 addressed to Y in G1 and protected in pairwise mode, Z can intercept M1, and attempt to forge a valid message M2 to be injected in G2, making it appear as still sent by X to Y and valid to be accepted.¶
More in detail, Z intercepts and stops message M1, and forges a message M2 by changing the value of the OSCORE option from M1 as follows: the 'kid context' is set to G2 (rather than G1); and the 'kid' is set to Sid2 (rather than Sid1). Then, Z injects message M2 as addressed to Y in G2.¶
Upon receiving M2, there is a probability equal to 2^-64 that Y successfully verifies the same unchanged MAC by using the Pairwise Recipient Key associated with X in G2.¶
Note that Z does not know the pairwise keys of X and Y, since it does not know and is not able to compute their shared Diffie-Hellman secret. Therefore, Z is not able to check offline if a performed forgery is actually valid, before sending the forged message to G2.¶
When a Group OSCORE message is protected in group mode, the countersignature is computed also over the value of the OSCORE option, which is part of the Additional Authenticated Data used in the signing process (see Section 4.4).¶
That is, other than over the ciphertext, the countersignature is computed over: the ID Context (Gid) and the Partial IV, which are always present in requests; as well as the Sender ID of the message originator, which is always present in requests as well as in responses to requests protected in group mode.¶
Since the signing process takes as input also the ciphertext of the COSE_Encrypt0 object, the countersignature is bound not only to the intended OSCORE group, hence to the triplet (Master Secret, Master Salt, ID Context), but also to a specific Sender ID in that group and to its specific symmetric key used for AEAD encryption, hence to the quartet (Master Secret, Master Salt, ID Context, Sender ID).¶
This makes it practically infeasible to perform the attack described in Section 13.7.1, since it would require the adversary to additionally forge a valid countersignature that replaces the original one in the forged message M2.¶
If, hypothetically, the countersignature did not cover the OSCORE option:¶
A simplification would also be possible in performing the attack, since Z is able to derive the Sender/Recipient Keys of X and Y in G1 and G2. That is, Z can also set a convenient Partial IV in the response, until the same unchanged MAC is successfully verified by using G2 as 'request_kid_context', Sid2 as 'request_kid', and the symmetric key associated with X in G2.¶
Since the Partial IV is 5 bytes in size, this requires 2^40 operations to test all the Partial IVs, which can be done in real-time. The probability that a single given message M1 can be used to forge a response M2 for a given request would be equal to 2^-24, since there are more MAC values (8 bytes in size) than Partial IV values (5 bytes in size).¶
Note that, by changing the Partial IV as discussed above, any member of G1 would also be able to forge a valid signed response message M2 to be injected in the same group G1.¶
Both when using the group mode and the pairwise mode, the message protection covers also the Group Manager's authentication credential. This is included in the Additional Authenticated Data used in the signing process and/or in the integrity-protected encryption process (see Section 4.4).¶
By doing so, an endpoint X member of a group G1 cannot perform the following attack.¶
The attack above is effectively prevented, since message M is protected by including the authentication credential of G1's Group Manager in the Additional Authenticated Data. Therefore, members of G2 do not successfully verify and decrypt M, since they correctly use the authentication credential of X as Group Manager of G2 when attempting to.¶
If a request is intended to be sent over unicast as addressed to a single group member, it is NOT RECOMMENDED for the client to protect the request by using the group mode as defined in Section 8.1.¶
This does not include the case where the client sends a request over unicast to a proxy, to be forwarded to multiple intended recipients over multicast [I-D.ietf-core-groupcomm-bis]. In this case, the client typically protects the request with the group mode, even though it is sent to the proxy over unicast (see Section 8).¶
If the client uses the group mode with its own Sender Key to protect a unicast request to a group member, an on-path adversary can, right then or later on, redirect that request to one/many different group member(s) over unicast, or to the whole OSCORE group over multicast. By doing so, the adversary can induce the target group member(s) to perform actions intended for one group member only. Note that the adversary can be external, i.e., they do not need to also be a member of the OSCORE group.¶
This is due to the fact that the client is not able to indicate the single intended recipient in a way which is secure and possible to process for Group OSCORE on the server side. In particular, Group OSCORE does not protect network addressing information such as the IP address of the intended recipient server. It follows that the server(s) receiving the redirected request cannot assert whether that was the original intention of the client, and would thus simply assume so.¶
The impact of such an attack depends especially on the REST method of the request, i.e., the Inner CoAP Code of the OSCORE request message. In particular, safe methods such as GET and FETCH would trigger (several) unintended responses from the targeted server(s), while not resulting in destructive behavior. On the other hand, non safe methods such as PUT, POST, and PATCH/iPATCH would result in the target server(s) taking active actions on their resources and possible cyber-physical environment, with the risk of destructive consequences and possible implications for safety.¶
A client can instead use the pairwise mode as defined in Section 9.3, in order to protect a request sent to a single group member by using pairwise keying material (see Section 2.5). This prevents the attack discussed above by construction, as only the intended server is able to derive the pairwise keying material used by the client to protect the request. In a group where the AEAD Algorithm and Pairwise Key Agreement Algorithm are set in the Security Context, a client supporting the pairwise mode SHOULD use it to protect requests sent to a single group member over unicast. For an example where this is not fulfilled, see Section 9.2.1 of [I-D.ietf-core-observe-multicast-notifications].¶
The use of block-wise transfers [RFC7959] with group communication for CoAP is as discussed in Section 3.8 of [I-D.ietf-core-groupcomm-bis].¶
Additional considerations are discussed in Section 10, with respect to requests including a CoAP Echo Option [RFC9175] that have to be sent over unicast, as a challenge-response method for servers to achieve synchronization of clients' Sender Sequence Number.¶
The same considerations from Section 12.1 of [RFC8613] hold for Group OSCORE.¶
Additionally, (D)TLS and Group OSCORE can be combined for protecting message exchanges occurring over unicast. However, it is not possible to combine (D)TLS and Group OSCORE for protecting message exchanges where messages are sent over multicast.¶
Group OSCORE derives the Security Context using the same construction used by OSCORE, and by using the Group Identifier of a group as the related ID Context. Hence, the same required properties of the Security Context parameters discussed in Section 3.3 of [RFC8613] hold for this document.¶
With particular reference to the OSCORE Master Secret, it has to be kept secret among the members of the respective OSCORE group and the Group Manager responsible for that group. Also, the Master Secret must have a good amount of randomness, and the Group Manager can generate it offline using a good random number generator. This includes the case where the Group Manager rekeys the group by generating and distributing a new Master Secret. Randomness requirements for security are described in [RFC4086].¶
As in OSCORE [RFC8613], also Group OSCORE relies on Sender Sequence Numbers included in the COSE message field 'Partial IV' and used to build AEAD nonces.¶
Note that the Partial IV of an endpoint does not necessarily grow monotonically. For instance, upon exhaustion of the endpoint's Sender Sequence Number space, the endpoint's Partial IV space also gets exhausted. As discussed in Section 2.6.3, this results either in the endpoint being individually rekeyed and getting a new Sender ID, or in the establishment of a new Security Context in the group. Therefore, uniqueness of (key, nonce) pairs (see Section 13.3) is preserved also when a new Security Context is established.¶
Since one-to-many communication such as multicast usually involves unreliable transports, the simplification of the Replay Window to a size of 1 suggested in Section 7.4 of [RFC8613] is not viable with Group OSCORE, unless exchanges in the group rely only on unicast messages.¶
A server may not be synchronized with a client's Sender Sequence Number, or a Replay Window may be initialized as invalid (see Section 2.6.1). The server can either retrieve a new Group OSCORE Security Context, or synchronize with the clients' Sender Sequence Numbers before resuming to accept incoming messages from other group members.¶
Assuming that the other endpoint is honest, Group OSCORE provides relative ordering of received messages. For a given Group OSCORE Security Context, the received Partial IV (when included) allows the recipient endpoint to determine the order in which requests or responses were sent by the other endpoint.¶
In case the Partial IV was omitted in a response, this indicates that it was the oldest response from the sender endpoint to the corresponding request (like notification responses in OSCORE, see Section 7.4.1 of [RFC8613]). A received response is not older than the corresponding request.¶
As in OSCORE, Group OSCORE provides only the guarantee that the request is not older than the Group OSCORE Security Context used to protect it. Other aspects of freshness are discussed in Section 6.2.¶
The challenge-response approach described in Section 10 provides an assurance of freshness of the request without depending on the honesty of the client. However, it can result in an impact on performance which is undesirable or unbearable, especially in large groups where many endpoints at the same time might join as new members or lose synchronization.¶
Endpoints configured as silent servers are not able to perform the challenge-response described above, as they do not store a Sender Context to secure the 4.01 (Unauthorized) response to the client. Thus, silent servers should adopt alternative approaches to achieve and maintain synchronization with Sender Sequence Numbers of clients.¶
Since requests including the Echo Option are sent over unicast, a server can be victim of the attack discussed in Section 13.9, in case such requests are protected in group mode. Instead, protecting those requests with the pairwise mode prevents the attack above. In fact, only the very server involved in the challenge-response exchange is able to derive the pairwise key used by the client to protect the request including the Echo Option.¶
In either case, an internal on-path adversary would not be able to mix up the Echo Option value of two different unicast requests, sent by a same client to any two different servers in the group. In fact, even if the group mode was used, this would require the adversary to forge the countersignature of both requests. As a consequence, each of the two servers remains able to selectively accept a request with the Echo Option only if it is waiting for that exact integrity-protected Echo Option value, and is thus the intended recipient.¶
Like in OSCORE (see Section 12.5 of [RFC8613]), a server may verify the aliveness of the client by using the CoAP Echo Option [RFC9175] as described in Section 10.¶
In the interest of avoiding otherwise unnecessary uses of such an approach, the server can exploit the fact that the received request cannot be older than the Security Context used to protect it. This effectively allows the server to verify the client aliveness relative to the installation of the latest group keying material.¶
The same considerations from Section 12.6 of [RFC8613] about the maximum Sender Sequence Number hold for Group OSCORE.¶
As discussed in Section 2.6.2, an endpoint that experiences an exhaustion of its own Sender Sequence Number space MUST NOT protect further messages including a Partial IV, until it has derived a new Sender Context. This prevents the endpoint to reuse the same AEAD nonce with the same Sender Key.¶
In order to renew its own Sender Context, the endpoint SHOULD inform the Group Manager, which can either renew the whole Security Context by means of group rekeying, or provide only that endpoint with a new Sender ID value. In either case, the endpoint derives a new Sender Context, and in particular a new Sender Key.¶
Additionally, the same considerations from Section 12.6 of [RFC8613] hold for Group OSCORE, about building the AEAD nonce and the secrecy of the Security Context parameters.¶
The group mode uses the "encrypt-then-sign" construction, i.e., the countersignature is computed over the COSE_Encrypt0 object (see Section 4.1). This is motivated by enabling signature checkers (see Section 3.3), which do not join a group as members but are allowed to verify countersignatures of messages protected in group mode without being able to decrypt them (see Section 8.5).¶
If the Group Encryption Algorithm used in group mode provides integrity protection, countersignatures of COSE_Encrypt0 with short authentication tags do not provide the security properties associated with the same algorithm used in COSE_Sign (see Section 6 of [RFC9338]). To provide 128-bit security against collision attacks, the tag length MUST be at least 256-bits. A countersignature of a COSE_Encrypt0 with AES-CCM-16-64-128 provides at most 32 bits of integrity protection.¶
The derivation of pairwise keys defined in Section 2.5.1 is compatible with ECDSA and EdDSA asymmetric keys, but is not compatible with RSA asymmetric keys.¶
For the public key translation from Ed25519 (Ed448) to X25519 (X448) specified in Section 2.5.1, variable time methods can be used since the translation operates on public information. Any byte string of appropriate length is accepted as a public key for X25519 (X448) in [RFC7748]. It is therefore not necessary for security to validate the translated public key (assuming the translation was successful).¶
The security of using the same key pair for Diffie-Hellman and for signing (by considering the ECDH procedure in Section 2.5 as a Key Encapsulation Mechanism (KEM)) is demonstrated in [Degabriele] and [Thormarker].¶
Applications using ECDH (except X25519 and X448) based KEM in Section 2.5 are assumed to verify that a peer endpoint's public key is on the expected curve and that the shared secret is not the point at infinity. The KEM in [Degabriele] checks that the shared secret is different from the point at infinity, as does the procedure in Section 5.7.1.2 of [NIST-800-56A] which is referenced in Section 2.5.¶
By extending Theorem 2 of [Degabriele], [Thormarker] shows that the same key pair can be used with X25519 and Ed25519 (X448 and Ed448) for the KEM specified in Section 2.5. By symmetry in the KEM used in this document, both endpoints can consider themselves to have the recipient role in the KEM - as discussed in Section 7 of [Thormarker] - and rely on the mentioned proofs for the security of their key pairs.¶
Theorem 3 in [Degabriele] shows that the same key pair can be used for an ECDH based KEM and ECDSA. The KEM uses a different KDF than in Section 2.5, but the proof only depends on that the KDF has certain required properties, which are the typical assumptions about HKDF, e.g., that output keys are pseudorandom. In order to comply with the assumptions of Theorem 3, received public keys MUST be successfully validated, see Section 5.6.2.3.4 of [NIST-800-56A]. The validation MAY be performed by a trusted Group Manager. For [Degabriele] to apply as it is written, public keys need to be in the expected subgroup. For this, we rely on cofactor Diffie-Hellman as per Section 5.7.1.2 of [NIST-800-56A], which is referenced in Section 2.5.1.¶
HashEdDSA variants of Ed25519 and Ed448 are not used by COSE (see Section 2.2 of [RFC9053]), and are not covered by the analysis in [Thormarker]. Hence, they MUST NOT be used with the public keys used to derive pairwise keys as specified in this document.¶
The same considerations from Section 12.7 of [RFC8613] hold for Group OSCORE.¶
Group OSCORE ensures end-to-end integrity protection and encryption of the message payload and of all the options that are not used for proxy operations. In particular, options are processed according to the same class U/I/E that they have for OSCORE. Therefore, the same privacy considerations from Section 12.8 of [RFC8613] hold for Group OSCORE, with the following addition.¶
Furthermore, the following privacy considerations hold about the OSCORE option, which may reveal information on the communicating endpoints.¶
When receiving a group request, each of the recipient endpoints can reply with a response that includes its Sender ID as 'kid' parameter. All these responses will be matchable with the request through the CoAP Token. Thus, even if these responses do not include a 'kid context' parameter, it becomes possible to understand that the responder endpoints are in the same group of the requester endpoint.¶
Furthermore, using the approach described in Section 10 to achieve synchronization with a client's Sender Sequence Number may reveal when a server device goes through a reboot. This can be mitigated by the server device storing the precise state of the Replay Window of each known client on a clean shutdown.¶
Finally, the approach described in Section 13.6 to prevent collisions of Group Identifiers from different Group Managers may reveal information about events in the respective OSCORE groups. In particular, a Group Identifier changes when the corresponding group is rekeyed. Thus, Group Managers might use the shared list of Group Identifiers to infer the rate and patterns of group membership changes triggering a group rekeying, e.g., due to newly joined members or evicted (compromised) members. In order to alleviate this privacy concern, it should be hidden from the Group Managers which exact Group Manager has currently assigned which Group Identifiers in its OSCORE groups.¶
Note to RFC Editor: Please replace "[RFC-XXXX]" with the RFC number of this document and delete this paragraph.¶
This document has the following actions for IANA.¶
IANA is asked to add the following entry to the "OSCORE Flag Bits" registry within the "Constrained RESTful Environments (CoRE) Parameters" registry group.¶
+--------------+-------+-----------------------------+------------+ | Bit Position | Name | Description | Reference | +--------------+-------+-----------------------------+------------+ | 2 | Group | For using a Group OSCORE | [RFC-XXXX] | | | Flag | Security Context, set to 1 | | | | | if the message is protected | | | | | with the group mode | | +--------------+-------+-----------------------------+------------+¶
IANA is asked to add the following entry to the "Target Attributes" registry within the "CoRE Parameters" registry group.¶
Attribute Name: gosc Brief Description: Hint: resource only accessible using Group OSCORE or OSCORE Change Controller: IETF Reference: [RFC-XXXX]¶
This section presents a set of assumptions and security objectives for the protocol described in this document. The rest of this section refers to three types of groups:¶
The following points are assumed to be already addressed and are out of the scope of this document.¶
Multicast communication topology: this document considers both 1-to-N (one sender and multiple recipients) and M-to-N (multiple senders and multiple recipients) communication topologies. The 1-to-N communication topology is the simplest group communication scenario that would serve the needs of a typical Low-power and Lossy Network (LLN). Examples of use cases that benefit from secure group communication are provided in Appendix B.¶
In a 1-to-N communication model, only a single client transmits data to the CoAP group, in the form of request messages; in an M-to-N communication model (where M and N do not necessarily have the same value), M clients transmit data to the CoAP group. According to [I-D.ietf-core-groupcomm-bis], any possible proxy entity is supposed to know about the clients. Also, every client expects and is able to handle multiple response messages associated with a same request sent to the CoAP group.¶
The protocol described in this document aims at fulfilling the following security objectives:¶
Group Communication for CoAP [I-D.ietf-core-groupcomm-bis] provides the necessary background for multicast-based CoAP communication, with particular reference to low-power and lossy networks (LLNs) and resource constrained environments. The interested reader is encouraged to first read [I-D.ietf-core-groupcomm-bis] to understand the non-security related details. This section discusses a number of use cases that benefit from secure group communication, and refers to the three types of groups from Appendix A. Specific security requirements for these use cases are discussed in Appendix A.¶
This section provides an example of how the Group Identifier (Gid) can be specifically formatted. That is, the Gid can be composed of two parts, namely a Group Prefix and a Group Epoch.¶
For each group, the Group Prefix is constant over time and is uniquely defined in the set of all the groups associated with the same Group Manager. The choice of the Group Prefix for a given group's Security Context is application specific. The size of the Group Prefix directly impact on the maximum number of distinct groups under the same Group Manager.¶
The Group Epoch is set to 0 upon the group's initialization, and is incremented by 1 each time new keying material, together with a new Gid, is distributed to the group in order to establish a new Security Context (see Section 3.2).¶
As an example, a 3-byte Gid can be composed of: i) a 1-byte Group Prefix '0xb1' interpreted as a raw byte string; and ii) a 2-byte Group Epoch interpreted as an unsigned integer ranging from 0 to 65535. Then, after having established the Common Context 61532 times in the group, its Gid will assume value '0xb1f05c'.¶
Using an immutable Group Prefix for a group with a Group Manager that cannot reassign Gid values (see Section 3.2) limits the total number of rekeying instances. With a Group Manager that does reassign Gid values, it limits the maximum active number of rekeying instances that a CoAP observation [RFC7641] can persist through. In either case, the group epoch size needs to be chosen depending on the expected rate of rekeying instances.¶
As discussed in Section 13.6, if endpoints are deployed in multiple groups managed by different non-synchronized Group Managers, it is possible that Group Identifiers of different groups coincide at some point in time. In this case, a recipient has to handle coinciding Group Identifiers, and has to try using different Security Contexts to process an incoming message, until the right one is found and the message is correctly verified. Therefore, it is favorable that Group Identifiers from different Group Managers have a size that result in a small probability of collision. How small this probability should be is up to system designers.¶
RFC EDITOR: PLEASE REMOVE THIS SECTION.¶
Section 2 has been updated with:¶
Section 3 has been updated with:¶
The authors sincerely thank Christian Amsüss, Stefan Beck, Rolf Blom, Carsten Bormann, Esko Dijk, Martin Gunnarsson, Klaus Hartke, Richard Kelsey, Dave Robin, Jim Schaad, Ludwig Seitz, Peter van der Stok, and Erik Thormarker for their feedback and comments.¶
The work on this document has been partly supported by VINNOVA and the Celtic-Next project CRITISEC; the H2020 projects SIFIS-Home (Grant agreement 952652) and ARCADIAN-IoT (Grant agreement 101020259); the SSF project SEC4Factory under the grant RIT17-0032; and the EIT-Digital High Impact Initiative ACTIVE.¶