Internet-Draft | Observe Multicast Notifications | April 2023 |
Tiloca, et al. | Expires 28 October 2023 | [Page] |
The Constrained Application Protocol (CoAP) allows clients to "observe" resources at a server, and receive notifications as unicast responses upon changes of the resource state. In some use cases, such as based on publish-subscribe, it would be convenient for the server to send a single notification addressed to all the clients observing a same target resource. This document updates RFC7252 and RFC7641, and defines how a server sends observe notifications as response messages over multicast, synchronizing all the observers of a same resource on a same shared Token value. Besides, this document defines how Group OSCORE can be used to protect multicast notifications end-to-end between the server and the observer clients.¶
This note is to be removed before publishing as an RFC.¶
Discussion of this document takes place on the Constrained RESTful Environments Working Group mailing list (core@ietf.org), which is archived at https://mailarchive.ietf.org/arch/browse/core/.¶
Source for this draft and an issue tracker can be found at https://github.com/core-wg/observe-multicast-notifications.¶
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The Constrained Application Protocol (CoAP) [RFC7252] has been extended with a number of mechanisms, including resource Observation [RFC7641]. This enables CoAP clients to register at a CoAP server as "observers" of a resource, and hence being automatically notified with an unsolicited response upon changes of the resource state.¶
CoAP supports group communication over IP multicast [I-D.ietf-core-groupcomm-bis]. This includes support for Observe registration requests over multicast, in order for clients to efficiently register as observers of a resource hosted at multiple servers.¶
However, in a number of use cases, using multicast messages for responses would also be desirable. That is, it would be useful that a server sends observe notifications for a same target resource to multiple observers as responses over IP multicast.¶
For instance, in CoAP publish-subscribe [I-D.ietf-core-coap-pubsub], multiple clients can subscribe to a topic, by observing the related resource hosted at the responsible broker. When a new value is published on that topic, it would be convenient for the broker to send a single multicast notification at once, to all the subscriber clients observing that topic.¶
A different use case concerns clients observing a same registration resource at the CoRE Resource Directory [RFC9176]. For example, multiple clients can benefit of observation for discovering (to-be-created) OSCORE groups [I-D.ietf-core-oscore-groupcomm], by retrieving from the Resource Directory updated links and descriptions to join them through the respective Group Manager [I-D.tiloca-core-oscore-discovery].¶
More in general, multicast notifications would be beneficial whenever several CoAP clients observe a same target resource at a CoAP server, and can be all notified at once by means of a single response message. However, CoAP does not currently define response messages over IP multicast. This document fills this gap and provides the following twofold contribution.¶
First, it updates [RFC7252] and [RFC7641], by defining a method to deliver Observe notifications as CoAP responses addressed to multiple clients, e.g., over IP multicast. In the proposed method, the group of potential observers entrusts the server to manage the Token space for multicast notifications. By doing so, the server provides all the observers of a target resource with the same Token value to bind to their own observation. That Token value is then used in every multicast notification for the target resource. This is achieved by means of an unicast informative response sent by the server to each observer client.¶
Second, this document defines how to use Group OSCORE [I-D.ietf-core-oscore-groupcomm] to protect multicast notifications end-to-end between the server and the observer clients. This is also achieved by means of the unicast informative response mentioned above, which additionally includes parameter values used by the server to protect every multicast notification for the target resource by using Group OSCORE. This provides a secure binding between each of such notifications and the observation of each of the clients.¶
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 terms and concepts described in CoAP [RFC7252], group communication for CoAP [I-D.ietf-core-groupcomm-bis], Observe [RFC7641], CBOR [RFC8949], OSCORE [RFC8613], and Group OSCORE [I-D.ietf-core-oscore-groupcomm].¶
This document additionally defines the following terminology.¶
In order to use multicast notifications as defined in this document, the following prerequisites have to be fulfilled.¶
The server and the clients need to agree out of band that multicast notifications may be used.¶
This document does not describe a way for a client to influence the server's decision to start group observations and thus to use multicast notifications. This is done on purpose.¶
That is, the mechanism specified in this document is expected to be used in situations where sending individual notifications is not feasible, or is not preferred beyond a certain number of clients observing a target resource.¶
If applications arise where a negotiation between the clients and the server does make sense, those applications are welcome to specify additional means to opt in to multicast notifications.¶
The method defined in this document fundamentally enables a server to setup a group observation. This is associated with a phantom observation request started by the server, and to which the multicast notifications of the group observation are bound.¶
While the server can provide the phantom request in question to the interested clients as they reach out for registering to the group observation, the server may alternatively distribute the phantom request in advance by alternative means (e.g., see Appendix A). Clients that have already retrieved the phantom request can immediately starts listening to multicast notifications if able to directly do so, or rather instruct an assisting intermediary such as a proxy to do that on their behalf.¶
The following provides an overview of the available variants to enforce a group observation, depending on whether a proxy is deployed or not, and on whether exchanged messages are protected end-to-end between the observer clients and the server.¶
No proxy - This is simplest network configuration, where the clients participating to the group observation are capable to listen to multicast traffic. In such a setup, the clients directly receive multicast notifications from the server.¶
With end-to-end security - Messages pertaining to the group observation are protected end-to-end between the clients and the server, by using the Group OSCORE security protocol [I-D.ietf-core-oscore-groupcomm]. This case is defined in Section 9. An example is provided in Section 10.¶
If the participating endpoints using Group OSCORE also support the concept of Deterministic Client [I-D.amsuess-core-cachable-oscore], then the possible early distribution of the phantom request can specifically make available its smaller, plain version. Then, all the clients are able to compute the same protected phantom request to use (see Appendix D).¶
With proxy - This network configuration is expected in case the clients participating to the group observation are not capable to listen to multicast traffic. In such a setup, the proxy directly receives multicast notifications from the server, and relays them back to the clients.¶
With end-to-end security - Messages pertaining to the group observation are protected end-to-end between the clients and the server, by using the Group OSCORE security protocol [I-D.ietf-core-oscore-groupcomm]. In particular, the clients are required to separately provide the proxy with the obtained phantom request, thus enabling the proxy to receive the multicast notifications from the server. This case is defined in Section 12. An example is provided in Appendix F.¶
If the participating endpoints using Group OSCORE also support the concept of Deterministic Client [I-D.amsuess-core-cachable-oscore], the same advantages mentioned above for the case without a proxy applies (see Appendix D). In addition, this allows for a more efficient setup and enforcement of the group observation, by reducing the amount of message exchanges and allowing the proxy to effectively serve protected multicast notifications from its cache. An example is provided in Appendix G.2.¶
The server can, at any time, start a group observation on one of its resources. Practically, the server may want to do that under the following circumstances.¶
The server maintains an observer counter for each group observation to a target resource, as a rough estimation of the observers actively taking part in the group observation.¶
The server initializes the counter to 0 when starting the group observation, and increments it after a new client starts taking part in that group observation. Also, the server should keep the counter up-to-date over time, for instance by using the method described in Section 8. This allows the server to possibly terminate a group observation in case, at some point in time, not enough clients are estimated to be still active and interested.¶
Assuming it is reachable at the address SRV_ADDR and port number SRV_PORT, the server starts a group observation on one of its resources as defined below. The server intends to send multicast notifications for the target resource to the multicast IP address GRP_ADDR and port number GRP_PORT.¶
The server selects an available value T, from the Token space of a CoAP endpoint used for messages having:¶
This Token space is under exclusive control of the server.¶
After having started a group observation on a target resource, the server proceeds as follows.¶
For each traditional observation ongoing on the target resource, the server MAY cancel that observation. Then, the server considers the corresponding clients as now taking part in the group observation, for which it increases the corresponding observer counter accordingly.¶
The server sends to each of such clients an informative response message, encoded as a unicast response with response code 5.03 (Service Unavailable). As per [RFC7641], such a response does not include an Observe Option. The response MUST be Confirmable and MUST NOT encode link-local addresses.¶
The Content-Format of the informative response is set to application/informative-response+cbor, defined in Section 16.2. The payload of the informative response is a CBOR map including the following parameters, whose CBOR labels are defined in Section 13.¶
'ph_req', with value the byte serialization of the transport-independent information of the phantom observation request (see Section 4.1), encoded as a CBOR byte string. The value of the CBOR byte string is formatted as defined in Section 4.2.2.¶
This parameter MAY be omitted, in case the phantom request is, in terms of transport-independent information, identical to the registration request from the client. Otherwise, this parameter MUST be included.¶
Note that the registration request from the client may indeed differ from the phantom observation request in terms of transport-independent information, but still be acceptable for the server to register the client as taking part in the group observation.¶
'next_not_before', with value the amount of seconds that will minimally elapse before the server sends the next multicast notification for the group observation of the target resource, encoded as a CBOR unsigned integer. This parameter MAY be included.¶
This information can help a new client to align itself with the server's timeline, especially in scenarios where multicast notifications are regularly sent. Also, it can help synchronizing different clients when orchestrating a content distribution through multicast notifications.¶
The CDDL notation [RFC8610] provided below describes the payload of the informative response.¶
Upon receiving a registration request to observe the target resource, the server does not create a corresponding individual observation for the requesting client. Instead, the server considers that client as now taking part in the group observation of the target resource, of which it increments the observer counter by 1. Then, the server replies to the client with the same informative response message defined above, which MUST be Confirmable.¶
Note that this also applies when, with no ongoing traditional observations on the target resource, the server receives a registration request from a first client and decides to start a group observation on the target resource.¶
[ This encoding might be replaced by CRIs [I-D.ietf-core-href] in a later version of this document. ]¶
The CBOR array specified in the 'tp_info' parameter is formatted according to the following CDDL notation.¶
The 'srv_addr' element of 'tp_info' specifies the addressing information of the server, and includes at least one element 'tp_id' which is formatted as follows.¶
'tp_id' : this element is a CBOR integer, which specifies the transport protocol used to transport the CoAP response from the server, i.e., a multicast notification in this document.¶
This element takes value from the "Value" column of the "CoAP Transport Information" registry defined in Section 16.5 of this document. This element MUST be present. The value of this element determines:¶
This document registers the integer value 1 ("UDP") to be used as value for the 'tp_id' element, when CoAP responses are transported over UDP. In such a case, the full encoding of the 'tp_info' CBOR array is as defined in Section 4.2.1.1.¶
Future specifications that consider CoAP multicast notifications transported over different transport protocols MUST:¶
The 'req_info' element of 'tp_info' specifies transport-specific information related to a pertinent request message, i.e., the phantom observation request in this document. The exact format of 'req_info' depends on the value of 'tp_id'.¶
Given a specific value of 'tp_id', the complete set of elements composing 'srv_addr' and 'req_info' in the 'tp_info' CBOR array is indicated by the two columns "Srv Addr" and "Req Info" of the "CoAP Transport Information" registry defined in Section 16.5, respectively.¶
When CoAP multicast notifications are transported over UDP as per [RFC7252] and [I-D.ietf-core-groupcomm-bis], the server specifies the integer value 1 ("UDP") as value of 'tp_id' in the 'srv_addr' element of the 'tp_info' CBOR array in the informative response. Then, the rest of the 'tp_info' CBOR array is defined as follows.¶
'srv_addr' includes two more elements following 'tp_id':¶
'req_info' includes the following elements:¶
The CDDL notation provided below describes the full 'tp_info' CBOR array using the format above.¶
For both the parameters 'ph_req' and 'last_notif' in the informative response, the value of the byte string is the concatenation of the following components, in the order specified below.¶
When defining the value of each component, "CoAP message" refers to the phantom observation request for the 'ph_req' parameter, and to the corresponding latest multicast notification for the 'last_notif' parameter.¶
Upon a change in the status of the target resource under group observation, the server sends a multicast notification, intended to all the clients taking part in the group observation of that resource. In particular, each of such multicast notifications is formatted as follows.¶
It MUST have the same Token value T of the phantom registration request that started the group observation. This Token value is specified in the 'token' element of 'req_info' under the 'tp_info' parameter, in the informative response sent to all the observer clients.¶
That is, every multicast notification for a target resource is not bound to the observation requests from the different clients, but rather to the phantom registration request associated with the whole set of clients taking part in the group observation of that resource.¶
For each target resource with an active group observation, the server MUST store the latest multicast notification.¶
In order to not cause congestion, the server should conservatively control the sending of multicast notifications. In particular:¶
At any point in time, the server may want to cancel a group observation of a target resource. For instance, the server may realize that no clients or not enough clients are interested in taking part in the group observation anymore. A possible approach that the server can use to assess this is defined in Section 8.¶
In order to cancel the group observation, the server sends a multicast response with response code 5.03 (Service Unavailable), signaling that the group observation has been terminated. The response has the same Token value T of the phantom registration request, it has no payload, and it does not include an Observe Option.¶
The server sends the response to the same multicast IP address GRP_ADDR and port number GRP_PORT used to send the multicast notifications related to the target resource. Finally, the server releases the resources allocated for the group observation, and especially frees up the Token value T used at its CoAP endpoint.¶
A client sends an observation request to the server as described in [RFC7641], i.e., a GET request with an Observe Option set to 0 (register). The request MUST NOT encode link-local addresses. If the server is not configured to accept registrations on that target resource specifically for a group observation, this would still result in a positive notification response to the client as described in [RFC7641], in case the server is able and willing to add the client to the list of observers.¶
In a particular setup, the information typically specified in the 'tp_info' parameter of the informative response (see Section 4.2) can be pre-configured on the server and the clients. For example, the destination multicast address and port number where to send multicast notifications for a group observation, as well as the associated Token value to use, can be set aside for particular tasks (e.g., enforcing observations of a specific resource). Alternative mechanisms can rely on using some bytes from the hash of the observation request as the last bytes of the multicast address or as part of the Token value.¶
In such a particular setup, the client may also have an early knowledge of the phantom request, i.e., it will be possible for the server to safely omit the parameter 'ph_req' from the informative response to the observation request (see Section 4.2). In this case, the client can include a No-Response Option [RFC7967] with value 16 in its Observe registration request, which results in the server suppressing the informative response. As a consequence, the observation request only informs the server that there is one additional client interested to take part in the group observation.¶
While the considered client is able to simply set up its multicast address and start receiving multicast notifications for the group observation, sending an observation request as above allows the server to increment the observer counter. This helps the server to assess the current number of clients interested in the group observation over time (e.g., by using the method in Section 8), which in turn can play a role in deciding to cancel the group observation.¶
Upon receiving the informative response defined in Section 4.2, the client proceeds as follows.¶
The client configures an observation of the target resource. To this end, it relies on a CoAP endpoint used for messages having:¶
The client rebuilds the phantom registration request as follows.¶
If the informative response includes the parameter 'last_notif', the client rebuilds the latest multicast notification, by using:¶
If any of the expected fields in the informative response are not present or malformed, the client MAY try sending a new registration request to the server (see Section 5.1). Otherwise, the client SHOULD explicitly withdraw from the group observation.¶
Appendix A describes possible alternative ways for clients to retrieve the phantom registration request and other information related to a group observation.¶
After having successfully processed the informative response as defined in Section 5.2, the client will receive, accept and process multicast notifications about the state of the target resource from the server, as responses to the phantom registration request and with Token value T.¶
The client relies on the value of the Observe Option for notification reordering, as defined in Section 3.4 of [RFC7641].¶
At a certain point in time, a client may become not interested in receiving further multicast notifications about a target resource. When this happens, the client can simply "forget" about being part of the group observation for that target resource, as per Section 3.6 of [RFC7641].¶
When, later on, the server sends the next multicast notification, the client will not recognize the Token value T in the message. Since the multicast notification is Non-confirmable, it is OPTIONAL for the client to reject the multicast notification with a Reset message, as defined in Section 3.5 of [RFC7641].¶
In case the server has canceled a group observation as defined in Section 4.5, the client simply forgets about the group observation and frees up the used Token value T for that endpoint, upon receiving the multicast error response defined in Section 4.5.¶
The possible use of multicast notifications in a group observation may be indicated by a target attribute "gp-obs" in a web link [RFC8288] to a resource, e.g., using a link-format document [RFC6690].¶
The "gp-obs" attribute is a hint, indicating that the server might send multicast notifications for observations of the resource targeted by the link. Note that this is simply a hint, i.e., it does not include any information required to participate in a group observation, and to receive and process multicast notifications.¶
A value MUST NOT be given for the "gp-obs" attribute; any present value MUST be ignored by parsers. The "gp-obs" attribute MUST NOT appear more than once in a given link-value; occurrences after the first MUST be ignored by parsers.¶
The example in Figure 4 shows a use of the "gp-obs" attribute: the client does resource discovery on a server and gets back a list of resources, one of which includes the "gp-obs" attribute indicating that the server might send multicast notifications for observations of that resource. The link-format notation (see Section 5 of [RFC6690]) is used.¶
The following example refers to two clients C_1 and C_2 that register to observe a resource /r at a Server S, which has address SRV_ADDR and listens to the port number SRV_PORT. Before the following exchanges occur, no clients are observing the resource /r , which has value "1234".¶
The server S sends multicast notifications to the IP multicast address GRP_ADDR and port number GRP_PORT, and starts the group observation upon receiving a registration request from a first client that wishes to start a traditional observation on the resource /r.¶
The following notation is used for the payload of the informative responses:¶
This section specifies a method that the server can use to keep an estimate of still active and interested clients, without creating undue traffic on the network.¶
In order to enable the rough counting of still active and interested clients, a new CoAP option is introduced, which SHOULD be supported by clients that listen to multicast responses.¶
The option is called Multicast-Response-Feedback-Divider. As summarized in Figure 6, the option is not Critical, not Safe-to-Forward, and integer valued. Since the option is not Safe-to-Forward, the column "N" indicates a dash for "not applicable".¶
The Multicast-Response-Feedback-Divider Option is of class E for OSCORE [RFC8613][I-D.ietf-core-oscore-groupcomm].¶
Upon receiving a response with a Multicast-Response-Feedback-Divider Option, a client SHOULD acknowledge its interest in continuing receiving multicast notifications for the target resource, as described below.¶
The client picks an integer random number I, from 0 inclusive to the number Z = (2^Q) exclusive, where Q is the value specified in the option and "^" is the exponentiation operator. If I is different than 0, the client takes no further action. Otherwise, the client should wait a random fraction of the Leisure time (see Section 8.2 of [RFC7252]), and then registers a regular unicast observation on the same target resource.¶
To this end, the client essentially follows the steps that got it originally subscribed to group notifications for the target resource. In particular, the client sends an observation request to the server, i.e., a GET request with an Observe Option set to 0 (register). The request MUST be addressed to the same target resource, and MUST have the same destination IP address and port number used for the original registration request, regardless the source IP address and port number of the received multicast notification.¶
Since the Observe registration is only done for its side effect of showing as an attempted observation at the server, the client MUST send the unicast request in a non confirmable way, and with the maximum No-Response setting [RFC7967]. In the request, the client MUST include a Multicast-Response-Feedback-Divider Option, whose value MUST be empty (Option Length = 0). The client does not need to wait for responses, and can keep processing further notifications on the same Token.¶
The client MUST ignore the Multicast-Response-Feedback-Divider Option, if the multicast notification is retrieved from the 'last_notif' parameter of an informative response (see Section 4.2). A client includes the Multicast-Response-Feedback-Divider Option only in a re-registration request triggered by the server as described above, and MUST NOT include it in any other request.¶
Appendix B.1 and Appendix B.2 provide a description in pseudo-code of the operations above performed by the client.¶
Section 11 specifies how the approach presented in Section 4 and Section 5 works when a proxy is used between the clients and the server. In such a case, the following applies.¶
Upon receiving a multicast notification including the Multicast-Response-Feedback-Divider Option, the proxy MUST remove the option before forwarding the notification to (the previous hop towards) any of the origin clients.¶
The proxy would have to rely on separate means for asserting whether the origin clients are still interested in the observation, e.g., by regularly forwarding notifications to the clients as unicast, Confirmable response messages.¶
When no interested origin clients remain, the proxy can simply forget about being part of the group observation for the target resource at the server, like an origin client would do (see Section 5.4).¶
In order to avoid needless use of network resources, a server SHOULD keep a rough, updated count of the number of clients taking part in the group observation of a target resource. To this end, the server updates the value COUNT of the associated observer counter (see Section 4), for instance by using the method described below.¶
When it wants to obtain a new estimated count, the server considers a number M of confirmations it would like to receive from the clients. It is up to applications to define policies about how the server determines and possibly adjusts the value of M.¶
Then, the server computes the value Q = max(L, 0), where:¶
Finally, the server sets Q as the value of the Multicast-Response-Feedback-Divider Option, which is sent within a successful multicast notification.¶
If several multicast notifications are sent in a burst fashion, it is RECOMMENDED for the server to include the Multicast-Response-Feedback-Divider Option only in the first one of those notifications.¶
The server collects unicast observation requests from the clients, for an amount of time of MAX_CONFIRMATION_WAIT seconds. During this time, the server regularly increments the observer counter when adding a new client to the group observation (see Section 4.2).¶
It is up to applications to define the value of MAX_CONFIRMATION_WAIT, which has to take into account the transmission time of the multicast notification and of unicast observation requests, as well as the leisure time of the clients, which may be hard to know or estimate for the server.¶
If this information is not known to the server, it is recommended to define MAX_CONFIRMATION_WAIT as follows.¶
MAX_CONFIRMATION_WAIT = MAX_RTT + MAX_CLIENT_REQUEST_DELAY¶
where MAX_RTT is as defined in Section 4.8.2 of [RFC7252] and has default value 202 seconds, while MAX_CLIENT_REQUEST_DELAY is equivalent to MAX_SERVER_RESPONSE_DELAY defined in Section 3.1.5 of [I-D.ietf-core-groupcomm-bis] and has default value 250 seconds. In the absence of more specific information, the server can thus consider a conservative MAX_CONFIRMATION_WAIT of 452 seconds.¶
If more information is available in deployments, a much shorter MAX_CONFIRMATION_WAIT can be set. This can be based on a realistic round trip time (replacing MAX_RTT) and on the largest leisure time configured on the clients (replacing MAX_CLIENT_REQUEST_DELAY), e.g., DEFAULT_LEISURE = 5 seconds, thus shortening MAX_CONFIRMATION_WAIT to a few seconds.¶
Once MAX_CONFIRMATION_WAIT seconds have passed, the server counts the R confirmations arrived as unicast observation requests to the target resource, since the multicast notification with the Multicast-Response-Feedback-Divider Option has been sent. In particular, the server considers a unicast observation request as a confirmation from a client only if it includes a Multicast-Response-Feedback-Divider Option with an empty value (Option Length = 0).¶
Then, the server computes a feedback indicator as E = R * (2^Q), where "^" is the exponentiation operator. According to what defined by application policies, the server determines the next time when to ask clients for their confirmation, e.g., after a certain number of multicast notifications has been sent. For example, the decision can be influenced by the reception of no confirmations from the clients, i.e., R = 0, or by the value of the ratios (E/N) and (N/E).¶
Finally, the server computes a new estimated count of the observers. To this end, the server first consider COUNT' as the current value of the observer counter at this point in time. Note that COUNT' may be greater than the value COUNT used at the beginning of this process, if the server has incremented the observer counter upon adding new clients to the group observation (see Section 4.2).¶
In particular, the server computes the new estimated count value as COUNT' + ((E - N) / D), where D > 0 is an integer value used as dampener. This step has to be performed atomically. That is, until this step is completed, the server MUST hold the processing of an observation request for the same target resource from a new client. Finally, the server considers the result as the current observer counter, and assesses it for possibly canceling the group observation (see Section 4.5).¶
This estimate is skewed by packet loss, but it gives the server a sufficiently good estimation for further counts and for deciding when to cancel the group observation. It is up to applications to define policies about how the server takes the newly updated estimate into account and determines whether to cancel the group observation.¶
As an example, if the server currently estimates that N = COUNT = 32 observers are active and considers a constant M = 8, it sends out a notification with Multicast-Response-Feedback-Divider: 2. Then, out of 18 actually active clients, 5 send a re-registration request based on their random draw, of which one request gets lost, thus leaving 4 re-registration requests received by the server. Also, no new clients have been added to the group observation during this time, i.e., COUNT' is equal to COUNT. As a consequence, assuming that a dampener value D = 1 is used, the server computes the new estimated count value as 32 + (16 - 32) = 16, and keeps the group observation active.¶
To produce a most accurate updated counter, a server can include a Multicast-Response-Feedback-Divider Option with value Q = 0 in its multicast notifications, as if M is equal to N. This will trigger all the active clients to state their interest in continuing receiving notifications for the target resource. Thus, the amount R of arrived confirmations is affected only by possible packet loss.¶
Appendix B.3 provides a description in pseudo-code of the operations above performed by the server, including example behaviors for scheduling the next count update and deciding whether to cancel the group observation.¶
A server can protect multicast notifications by using Group OSCORE [I-D.ietf-core-oscore-groupcomm], thus ensuring they are protected end-to-end with the observer clients. This requires that both the server and the clients interested in receiving multicast notifications from that server are members of the same OSCORE group.¶
In some settings, the OSCORE group to refer to can be pre-configured on the clients and the server. In such a case, a server which is aware of such pre-configuration can simply assume a client to be already member of the correct OSCORE group.¶
In any other case, the server MAY communicate to clients what OSCORE group they are required to join, by providing additional guidance in the informative response as described in Section 9.1. Note that clients can already be members of the right OSCORE group, in case they have previously joined it to securely communicate with the same server and/or with other servers to access their resources.¶
Both the clients and the server MAY join the OSCORE group by using the approach described in [I-D.ietf-ace-key-groupcomm-oscore] and based on the ACE framework for Authentication and Authorization in constrained environments [RFC9200]. Further details on how to discover the OSCORE group and join it are out of the scope of this document.¶
If multicast notifications are protected using Group OSCORE, the original registration requests and related unicast (notification) responses MUST also be secured, including and especially the informative responses from the server.¶
To this end, alternative security protocols than Group OSCORE, such as OSCORE [RFC8613] and/or DTLS [RFC9147], can be used to protect other exchanges via unicast between the server and each client, including the original client registration (see Section 5).¶
This section describes a mechanism for the server to communicate to the client what OSCORE group to join in order to decrypt and verify the multicast notifications protected with Group OSCORE. The client MAY use the information provided by the server to start the ACE joining procedure described in [I-D.ietf-ace-key-groupcomm-oscore]. This mechanism is OPTIONAL to support for the client and server.¶
Additionally to what defined in Section 4, the CBOR map in the informative response payload contains the following fields, whose CBOR labels are defined in Section 13.¶
Optionally, 'cred_fmt', with value the format of the authentication credentials used in the OSCORE group, encoded as a CBOR integer. The value is taken from the 'Label' column of the "COSE Header Parameters" Registry [COSE.Header.Parameters]. Consistently with Section 2.3 of [I-D.ietf-core-oscore-groupcomm], acceptable values denote a format that MUST explicitly provide the comprehensive set of information related to the public key algorithm, including, e.g., the used elliptic curve (when applicable).¶
At the time of writing this specification, acceptable formats of authentication credentials are CBOR Web Tokens (CWTs) and CWT Claim Sets (CCSs) [RFC8392], X.509 certificates [RFC7925] and C509 certificates [I-D.ietf-cose-cbor-encoded-cert]. Further formats may be available in the future, and would be acceptable to use as long as they comply with the criteria defined above.¶
[ As to CWTs and unprotected CWT claim sets, there is a pending registration requested by draft-ietf-lake-edhoc. ]¶
[ As to C509 certificates, there is a pending registration requested by draft-ietf-cose-cbor-encoded-cert. ]¶
Optionally, 'sign_params', encoded as a CBOR array and including the following two elements:¶
The values of 'sign_alg', 'sign_params' and 'cred_fmt' provide an early knowledge of the format of authentication credentials as well as of the type of public keys used in the OSCORE group. Thus, the client does not need to ask the Group Manager for this information as a preliminary step before the (ACE) join process, or to perform a trial-and-error exchange with the Group Manager upon joining the group. Hence, the client is able to provide the Group Manager with its own authentication credential in the correct expected format and including a public key of the correct expected type, at the very first step of the (ACE) join process.¶
The values of 'hkdf', 'sign_enc_alg' and 'sign_alg' provide an early knowledge of the algorithms used in the OSCORE group. Thus, the client is able to decide whether to actually proceed with the (ACE) join process, depending on its support for the indicated algorithms.¶
As mentioned above, since this mechanism is OPTIONAL, all the fields are OPTIONAL in the informative response. However, the 'join_uri' and 'sec_gp' fields MUST be present if the mechanism is implemented and used. If any of the fields are present without the 'join_uri' and 'sec_gp' fields present, the client MUST ignore these fields, since they would not be sufficient to start the (ACE) join procedure. When this happens, the client MAY try sending a new registration request to the server (see Section 5.1). Otherwise, the client SHOULD explicitly withdraw from the group observation.¶
Appendix C describes a possible alternative approach, where the server self-manages the OSCORE group, and provides the observer clients with the necessary keying material in the informative response. The approach in Appendix C MUST NOT be used together with the mechanism defined in this section for indicating what OSCORE group to join.¶
When using Group OSCORE to protect multicast notifications, the server performs the operations described in Section 4, with the following differences.¶
The phantom registration request MUST be secured, by using Group OSCORE. In particular, the group mode of Group OSCORE defined in Section 8 of [I-D.ietf-core-oscore-groupcomm] MUST be used.¶
The server protects the phantom registration request as defined in Section 8.1 of [I-D.ietf-core-oscore-groupcomm], as if it was the actual sender, i.e., by using its Sender Context. As a consequence, the server consumes the current value of its Sender Sequence Number SN in the OSCORE group, and hence updates it to SN* = (SN + 1). Consistently, the OSCORE Option in the phantom registration request includes:¶
The value of the CBOR byte string in the 'ph_req' parameter encodes the phantom observation request as a message protected with Group OSCORE (see Section 9.2.1). As a consequence: the specified Code is always 0.05 (FETCH); the sequence of CoAP options will be limited to the outer, non encrypted options; a payload is always present, as the authenticated ciphertext followed by the signature. Note that, in terms of transport-independent information, the registration request from the client typically differs from the phantom request. Thus, the server has to include the 'ph_req' parameter in the informative response. An exception is the case discussed in Appendix D.¶
Similarly, the value of the CBOR byte string in the 'last_notif' parameter encodes the latest multicast notification as a message protected with Group OSCORE (see Section 9.2.3). This applies also to the initial multicast notification INIT_NOTIF built in step 6 of Section 4.1.¶
Optionally, the informative response includes information on the OSCORE group to join, as additional parameters (see Section 9.1).¶
The server MUST protect every multicast notification for the target resource with Group OSCORE. In particular, the group mode of Group OSCORE defined in Section 8 of [I-D.ietf-core-oscore-groupcomm] MUST be used.¶
The process described in Section 8.3 of [I-D.ietf-core-oscore-groupcomm] applies, with the following additions when building the two OSCORE 'external_aad' to encrypt and sign the multicast notification (see Section 4.3 of [I-D.ietf-core-oscore-groupcomm]).¶
Note that these same values are used to protect each and every multicast notification sent for the target resource under this group observation.¶
When canceling a group observation (see Section 4.5), the multicast response with error code 5.03 (Service Unavailable) is also protected with Group OSCORE, as per Section 8.3 of [I-D.ietf-core-oscore-groupcomm]. The server MUST use its own Sender Sequence Number as Partial IV to protect the error response, and include it as Partial IV in the OSCORE Option of the response.¶
When using Group OSCORE to protect multicast notifications, the client performs as described in Section 5, with the following differences.¶
Upon receiving the informative response from the server, the client performs as described in Section 5.2, with the following additions.¶
When performing step 2, the client expects the 'ph_req' parameter to be included in the informative response, which is otherwise considered malformed. An exception is the case discussed in Appendix D.¶
Once completed step 2, the client decrypts and verifies the rebuilt phantom registration request as defined in Section 8.2 of [I-D.ietf-core-oscore-groupcomm], with the following differences.¶
If decryption and verification of the phantom registration request succeed:¶
After successful decryption and verification, the client performs step 3 in Section 5.2, considering the decrypted phantom registration request.¶
If the informative response includes the parameter 'last_notif', the client also decrypts and verifies the latest multicast notification rebuilt at step 5 in Section 5.2, just like it would for the multicast notifications transmitted as CoAP messages on the wire (see Section 9.3.2). If decryption and verification succeed, the client proceeds with step 6, considering the decrypted latest multicast notification. Otherwise, the client proceeds to step 7.¶
After having successfully processed the informative response as defined in Section 9.3.1, the client will decrypt and verify every multicast notification for the target resource as defined in Section 8.4 of [I-D.ietf-core-oscore-groupcomm], with the following difference.¶
For both decryption and signature verification, the client MUST set the 'external_aad' defined in Section 4.3 of [I-D.ietf-core-oscore-groupcomm] as follows. The particular way to achieve this is implementation specific.¶
Note that these same values are used to decrypt and verify each and every multicast notification received for the target resource.¶
The replay protection and checking of multicast notifications is performed as specified in Section 4.1.3.5.2 of [RFC8613].¶
The following example refers to two clients C_1 and C_2 that register to observe a resource /r at a Server S, which has address SRV_ADDR and listens to the port number SRV_PORT. Before the following exchanges occur, no clients are observing the resource /r , which has value "1234".¶
The server S sends multicast notifications to the IP multicast address GRP_ADDR and port number GRP_PORT, and starts the group observation upon receiving a registration request from a first client that wishes to start a traditional observation on the resource /r.¶
Pairwise communication over unicast is protected with OSCORE, while S protects multicast notifications with Group OSCORE. Specifically:¶
The following notation is used for the payload of the informative responses:¶
The two external_aad used to encrypt and sign the multicast notification above have 'request_kid' = 5, 'request_piv' = 501 and 'request_kid_context' = 0x57ab2e. These values are specified in the 'kid', 'piv' and 'kid context' field of the OSCORE Option of the phantom observation request, which is encoded in the 'ph_req' parameter of the unicast informative response to the two clients. Thus, the two clients can build the two same external_aad for decrypting and verifying this multicast notification and the following ones.¶
This section specifies how the approach presented in Section 4 and Section 5 works when a proxy is used between the clients and the server. In addition to what specified in Section 5.7 of [RFC7252] and Section 5 of [RFC7641], the following applies.¶
A client sends its original observation request to the proxy. If the proxy is not already registered at the server for that target resource, the proxy forwards the observation request to the server, hence registering itself as an observer. If the server has an ongoing group observation for the target resource or decides to start one, the server considers the proxy as taking part in the group observation, and replies to the proxy with an informative response.¶
Upon receiving an informative response, the proxy performs as specified for the client in Section 5, with the peculiarity that "consuming" the last notification (if present) means populating its cache.¶
In particular, by using the information retrieved from the informative response, the proxy configures an observation of the target resource at the origin server, acting as a client directly taking part in the group observation.¶
As a consequence, the proxy will listen to the IP multicast address and port number indicated by the server in the informative response, as 'cli_host' and 'cli_port' element of 'req_info' under the 'tp_info' parameter, respectively (see Section 4.2.1.1). Furthermore, multicast notifications will match the phantom request stored at the proxy, based on the Token value specified in the 'token' element of 'req_info' under the 'tp_info' parameter in the informative response.¶
Then, the proxy performs the following actions.¶
When responding to an observation request from a client, the proxy also adds that client (and its Token) to the list of its registered observers for the target resource, next to the older observations.¶
Upon receiving a multicast notification from the server, the proxy forwards it back separately to each observer client over unicast. Note that the notification forwarded back to a certain client has the same Token value of the original observation request sent by that client to the proxy.¶
Note that the proxy configures the observation of the target resource at the server only once, when receiving the informative response associated with a (newly started) group observation for that target resource.¶
After that, when receiving an observation request from a following new client to be added to the same group observation, the proxy does not take any further action with the server. Instead, the proxy responds to the client either with the latest multicast notification if available from its cache, or with an Empty Acknowledgement otherwise, as defined above.¶
An example is provided in Appendix E.¶
In the general case with a chain of two or more proxies, every proxy in the chain takes the role of client with the (next hop towards the) origin server. Note that the proxy adjacent to the origin server is the only one in the chain that receives informative responses and listens to an IP multicast address to receive notifications for the group observation. Furthermore, every proxy in the chain takes the role of server with the (previous hop towards the) origin client.¶
As defined in Section 9, Group OSCORE can be used to protect multicast notifications end-to-end between the origin server and the clients. In such a case, additional actions are required when also the informative responses from the origin server are protected specifically end-to-end, by using OSCORE or Group OSCORE.¶
In fact, the proxy adjacent to the origin server is not able to access the encrypted payload of such informative responses. Hence, the proxy cannot retrieve the 'ph_req' and 'tp_info' parameters necessary to correctly receive multicast notifications and forward them back to the clients.¶
Then, differently from what defined in Section 11, each proxy receiving an informative response simply forwards it back to the client that has sent the corresponding observation request. Note that the proxy does not even realize the message to be an actual informative response, since the outer Code field is set to 2.05 (Content).¶
Upon receiving the informative response, the client does not configure an observation of the target resource. Instead, the client performs a new observe registration request, by transmitting the re-built phantom request as intended to reach the proxy adjacent to the origin server. In particular, the client includes the new Listen-To-Multicast-Responses CoAP option defined in Section 12.1, to provide that proxy with the transport-specific information required for receiving multicast notifications for the group observation.¶
Details on the additional message exchange and processing are defined in Section 12.2.¶
In order to allow the proxy to listen to the multicast notifications sent by the server, a new CoAP option is introduced. This option MUST be supported by clients interested to take part in group observations through intermediaries, and by proxies that collect multicast notifications and forward them back to the observer clients.¶
The option is called Listen-To-Multicast-Responses and is intended only for requests. As summarized in Figure 8, the option is critical and not Safe-to-Forward. Since the option is not Safe-to-Forward, the column "N" indicates a dash for "not applicable".¶
The Listen-To-Multicast-Responses Option includes the serialization of a CBOR array. This specifies transport-specific message information required for listening to the multicast notifications of a group observation, and intended to the proxy adjacent to the origin server sending those notifications. In particular, the serialized CBOR array has the same format specified in Section 4.2.1 for the 'tp_info' parameter of the informative response (see Section 4.2).¶
The Listen-To-Multicast-Responses Option is of class U for OSCORE [RFC8613][I-D.ietf-core-oscore-groupcomm].¶
Compared to Section 11, the following additions apply when informative responses are protected end-to-end between the origin server and the clients.¶
After the origin server sends an informative response, each proxy simply forwards it back to the (previous hop towards the) origin client that has sent the observation request.¶
Once received the informative response, the origin client proceeds in a different way than in Section 9.3.1:¶
The client builds a ticket request (see Appendix B of [I-D.amsuess-core-cachable-oscore]), as intended to reach the proxy adjacent to the origin server. The ticket request is formatted as follows.¶
The new option Listen-To-Multicast-Responses is included as an outer option. The value is set to the serialization of the CBOR array specified by the 'tp_info' parameter of the informative response.¶
Note that, except for transport-specific information such as the Token and Message ID values, every different client participating to the same group observation (hence rebuilding the same phantom request) will build the same ticket request.¶
Note also that, identically to the phantom request, the ticket request is still protected with Group OSCORE, i.e., it has the same OSCORE Option, encrypted payload and signature.¶
Then, the client sends the ticket request to the next hop towards the origin server. Every proxy in the chain forwards the ticket request to the next hop towards the origin server, until the last proxy in the chain is reached. This last proxy, adjacent to the origin server, proceeds as follows.¶
After that, the proxy will listen to the IP multicast address and port number indicated in the Listen-To-Multicast-Responses Option, as 'cli_host' and 'cli_port' element of the serialized CBOR array, respectively. Furthermore, multicast notifications will match the phantom request stored at the proxy, based on the Token value specified in the 'token' element of the serialized CBOR array in the Listen-To-Multicast-Responses Option.¶
An example is provided in Appendix F.¶
This document defines a number of fields used in the informative response defined in Section 4.2.¶
The table below summarizes them and specifies the CBOR key to use instead of the full descriptive name. Note that the media type application/informative-response+cbor MUST be used when these fields are transported.¶
Name | CBOR Key | CBOR Type | Reference |
---|---|---|---|
tp_info | 0 | array | Section 4.2 |
ph_req | 1 | bstr | Section 4.2 |
last_notif | 2 | bstr | Section 4.2 |
next_not_before | 3 | uint | Section 4.2 |
join_uri | 4 | tstr | Section 9.1 |
sec_gp | 5 | tstr | Section 9.1 |
as_uri | 6 | tstr | Section 9.1 |
hkdf | 7 | int / tstr | Section 9.1 |
cred_fmt | 8 | int | Section 9.1 |
sign_enc_alg | 9 | int / tstr | Section 9.1 |
sign_alg | 10 | int / tstr | Section 9.1 |
sign_params | 11 | array | Section 9.1 |
gp_material | 12 | map | Appendix C |
srv_cred | 13 | bstr | Appendix C |
srv_identifier | 14 | bstr | Appendix C |
exp | 15 | uint | Appendix C |
This document defines some values of transport protocol identifiers to use within the 'tp_info' parameter of the informative response defined in Section 4.2.¶
According to the encoding specified in Section 4.2.1, these values are used for the 'tp_id' element of 'srv_addr', under the 'tp_info' parameter.¶
The table below summarizes them, specifies the integer value to use instead of the full descriptive name, and provides the corresponding comprehensive set of information elements to include in the 'tp_info' parameter.¶
Note to RFC Editor: Please replace in the table below all occurrences of "[RFC-XXXX]" with the RFC number of this specification and delete this paragraph.¶
In addition to the security considerations from [RFC7252][RFC7641][I-D.ietf-core-groupcomm-bis][RFC8613][I-D.ietf-core-oscore-groupcomm], the following considerations hold for this document.¶
In case communications are not protected, the server might not be able to effectively authenticate a new client when it registers as an observer. Section 7 of [RFC7641] specifies how, in such a case, the server must strictly limit the number of notifications sent between receiving acknowledgements from the client, as confirming to be still interested in the observation; i.e., any notifications sent in Non-confirmable messages must be interspersed with confirmable messages.¶
This is not possible to achieve by the same means when using the communication model defined in this document, since multicast notifications are sent as Non-confirmable messages. Nonetheless, the server might obtain such acknowledgements by other means.¶
For instance, the method defined in Section 8 to perform the rough counting of still interested clients triggers (some of) them to explicitly send a new observation request to acknowledge their interest. Then, the server can decide to terminate the group observation altogether, in case not enough clients are estimated to be still active. If the method defined in Section 8 is used, the server SHOULD NOT send more than a strict number of multicast notifications for a given group observation, without having first performed a new rough counting of active clients.¶
If multicast notifications are protected using Group OSCORE as per Section 9, the following applies.¶
To this end, clients and servers SHOULD use OSCORE or Group OSCORE, so ensuring that the secure binding above is enforced end-to-end between the server and each observing client.¶
The CoAP option Listen-To-Multicast-Responses defined in Section 12.1 is of class U for OSCORE and Group OSCORE [RFC8613][I-D.ietf-core-oscore-groupcomm].¶
This allows the proxy adjacent to the origin server to access the option value conveyed in a ticket request (see Section 12.2), and to retrieve from it the transport-specific information about a phantom request. By doing so, the proxy becomes able to configure an observation of the target resource and to receive multicast notifications matching to the phantom request.¶
Any proxy in the chain, as well as further possible intermediaries or on-path active adversaries, are thus able to remove the option or alter its content, before the ticket request reaches the proxy adjacent to the origin server.¶
Removing the option would result in the proxy adjacent to the origin server to not configure the group observation, if that has not happened yet. In such a case, the proxy would not receive the corresponding multicast notifications to be forwarded back to the clients.¶
Altering the option content would result in the proxy adjacent to the origin server to incorrectly configure a group observation (e.g., by indicating a wrong multicast IP address) hence preventing the correct reception of multicast notifications and their forwarding to the clients; or to configure bogus group observations that are currently not active on the origin server.¶
In order to prevent what is described above, the ticket requests conveying the Listen-To-Multicast-Responses Option can be additionally protected hop-by-hop. This can be achieved by the client protecting the ticket request sent to the proxy using OSCORE (see [I-D.tiloca-core-oscore-capable-proxies]) and/or DTLS [RFC9147].¶
This document has the following actions for IANA.¶
Note to RFC Editor: Please replace all occurrences of "[RFC-XXXX]" with the RFC number of this specification and delete this paragraph.¶
This document registers the media type 'application/informative-response+cbor' for error messages as informative response defined in Section 4.2, when carrying parameters encoded in CBOR. This registration follows the procedures specified in [RFC6838].¶
IANA is asked to add the following entry to the "CoAP Content-Formats" registry within the "Constrained RESTful Environments (CoRE) Parameters" registry group.¶
Media Type: application/informative-response+cbor¶
Encoding: -¶
ID: TBD¶
Reference: [RFC-XXXX]¶
IANA is asked to enter the following option numbers to the "CoAP Option Numbers" registry within the "CoRE Parameters" registry group.¶
+--------+--------------------------------------+------------+ | Number | Name | Reference | +--------+--------------------------------------+------------+ | TBD | Multicast-Response-Feedback-Divider | [RFC-XXXX] | +--------+--------------------------------------+------------+ | TBD | Listen-To-Multicast-Responses | [RFC-XXXX] | +--------+--------------------------------------+------------+¶
This document establishes the "Informative Response Parameters" registry within the "Constrained RESTful Environments (CoRE) Parameters" registry group. The registry has been created to use the "Expert Review" registration procedure [RFC8126]. Expert review guidelines are provided in Section 16.7.¶
The columns of this registry are:¶
This registry has been initially populated by the values in Section 13. The "Reference" column for all of these entries refers to sections of this document.¶
This document establishes the "CoAP Transport Information" registry within the "CoRE Parameters" registry group. The registry has been created to use the "Expert Review" registration procedure [RFC8126]. Expert review guidelines are provided in Section 16.7. It should be noted that, in addition to the expert review, some portions of the Registry require a specification, potentially a Standards Track RFC, to be supplied as well.¶
The columns of this registry are:¶
This registry has been initially populated by the values in Section 14. The "Reference" column for all of these entries refers to sections of this document.¶
IANA is asked to register the following entry in the "Target Attributes" registry within the "CoRE Parameters" registry group.¶
Attribute Name: gp-obs Brief Description: Observable resource supporting group observation Change Controller: IESG Reference: Section 6 of [RFC-XXXX]¶
The IANA registries established in this document are defined as Expert Review. This section gives some general guidelines for what the experts should be looking for, but they are being designated as experts for a reason so they should be given substantial latitude.¶
Expert reviewers should take into consideration the following points:¶
While the clients usually receive the phantom registration request and other information related to the group observation through an informative response (see Section 4.2), the server can make the same data available through different means, such as the following ones.¶
In such a case, the server has to first start the group observation (see Section 4.1), before making the corresponding data available.¶
In a Publish-Subscribe scenario [I-D.ietf-core-coap-pubsub], a group observation can be discovered along with topic metadata.¶
To this end, together with topic metadata, the server has to publish the same information associated with the group observation that would be conveyed in the informative response returned to observer clients (see Section 4.2).¶
This information especially includes the phantom observation request associated with the group observation, as well as the addressing information of the server and the addressing information where multicast notifications are sent to.¶
Figure 10 provides an example where a group observation is discovered. The example assumes a CoRAL namespace [I-D.ietf-core-coral], that contains properties analogous to those in the content-format application/informative-response+cbor.¶
Note that the information about the transport protocol used for the group observation is not expressed through a dedicated element equivalent to 'tp_id' of the informative response (see Section 4.2.1). Rather, it is expressed through the scheme component of the two URIs specified as 'tp_info_srv' and 'tp_info_cli', where the former specifies the addressing information of the server (like 'srv_host' and 'srv_port' in Section 4.2.1.1), while the latter specifies the addressing information where multicast notifications are sent to (like 'cli_host' and 'cli_port' in Section 4.2.1.1).¶
With this information from the topic discovery step, the client can already set up its multicast address and start receiving multicast notifications for the group observation in question. Clients that are not directly able to listen to multicast notifications can instead rely on a proxy to do so on their behalf (see Section 11 and Section 12).¶
In heavily asymmetric networks like municipal notification services, discovery and notifications do not necessarily need to use the same network link. For example, a departure monitor could use its (costly and usually-off) cellular uplink to discover the topics it needs to update its display to, and then listen on a LoRA-WAN interface for receiving the actual multicast notifications.¶
For network debugging purposes, it can be useful to query a server that sends multicast responses as matching a phantom registration request.¶
Such an interface is left for other documents to specify on demand. As an example, a possible interface can be as follows, and rely on the already known Token value of intercepted multicast notifications, associated with a phantom registration request.¶
For example, a network sniffer could offer sending such a request when unknown multicast notifications are seen in a network. Consequently, it can associate those notifications with a URI, or decrypt them, if member of the correct OSCORE group.¶
This appendix provides a description in pseudo-code of the two algorithms used for the rough counting of active observers, as defined in Section 8.¶
In particular, Appendix B.1 describes the algorithm for the client side, while Appendix B.2 describes an optimized version for constrained clients. Finally, Appendix B.3 describes the algorithm for the server side.¶
input: int Q, // Value of the MRFD option int LEISURE_TIME, // DEFAULT_LEISURE from RFC 7252, // unless overridden output: None int RAND_MIN = 0; int RAND_MAX = (2^Q) - 1; int I = randomInteger(RAND_MIN, RAND_MAX); if (I == 0) { float fraction = randomFloat(0, 1); Timer t = new Timer(); t.setAndStart(fraction * LEISURE_TIME); while(!t.isExpired()); Request req = new Request(); // Initialize as NON and with maximum // No-Response settings, set options ... Option opt = new Option(OBSERVE); opt.set(0); req.setOption(opt); opt = new Option(MRFD); req.setOption(opt); req.send(SRV_ADDR, SRV_PORT); }¶
input: int Q, // Value of the MRFD option int LEISURE_TIME, // DEFAULT_LEISURE from RFC 7252, // unless overridden output: None const unsigned int UINT_BIT = CHAR_BIT * sizeof(unsigned int); if (respond_to(Q) == true) { float fraction = randomFloat(0, 1); Timer t = new Timer(); t.setAndStart(fraction * LEISURE_TIME); while(!t.isExpired()); Request req = new Request(); // Initialize as NON and with maximum // No-Response settings, set options ... Option opt = new Option(OBSERVE); opt.set(0); req.setOption(opt); opt = new Option(MRFD); req.setOption(opt); req.send(SRV_ADDR, SRV_PORT); } bool respond_to(int Q) { while (Q >= UINT_BIT) { if (rand() != 0) return false; Q -= UINT_BIT; } unsigned int mask = ~((~0u) << Q); unsigned int masked = mask & rand(); return masked == 0; }¶
input: int COUNT, // Current observer counter int M, // Desired number of confirmations int MAX_CONFIRMATION_WAIT, Response notification, // Multicast notification to send output: int NEW_COUNT // Updated observer counter int D = 4; // Dampener value int RETRY_NEXT_THRESHOLD = 4; float CANCEL_THRESHOLD = 0.2; int N = max(COUNT, 1); int Q = max(ceil(log2(N / M)), 0); Option opt = new Option(MRFD); opt.set(Q); notification.setOption(opt); <Finalize the notification message> notification.send(GRP_ADDR, GRP_PORT); Timer t = new Timer(); t.setAndStart(MAX_CONFIRMATION_WAIT); // Time t1 while(!t.isExpired()); // Time t2 int R = <number of requests to the target resource between t1 and t2, with the MRFD option>; int E = R * (2^Q); // Determine after how many multicast notifications // the next count update will be performed if ((R == 0) || (max(E/N, N/E) > RETRY_NEXT_THRESHOLD)) { <Next count update with the next multicast notification> } else { <Next count update after 10 multicast notifications> } // Compute the new count estimate int COUNT_PRIME = <current value of the observer counter>; int NEW_COUNT = COUNT_PRIME + ((E - N) / D); // Determine whether to cancel the group observation if (NEW_COUNT < CANCEL_THRESHOLD) { <Cancel the group observation>; return 0; } return NEW_COUNT;¶
For simple settings, where no pre-arranged group with suitable memberships is available, the server can be responsible to setup and manage the OSCORE group used to protect the group observation.¶
In such a case, a client would implicitly request to join the OSCORE group when sending the observe registration request to the server. When replying, the server includes the group keying material and related information in the informative response (see Section 4.2).¶
Additionally to what is defined in Section 4, the CBOR map in the informative response payload contains the following fields, whose CBOR labels are defined in Section 13.¶
'gp_material': this element is a CBOR map, which includes what the client needs in order to set up the Group OSCORE Security Context.¶
This parameter has as value a subset of the Group_OSCORE_Input_Material object, which is defined in Section 6.4 of [I-D.ietf-ace-key-groupcomm-oscore] and extends the OSCORE_Input_Material object encoded in CBOR as defined in Section 3.2.1 of [RFC9203].¶
In particular, the following elements of the Group_OSCORE_Input_Material object are included, using the same CBOR labels from the OSCORE Security Context Parameters Registry, as in Section 6.4 of [I-D.ietf-ace-key-groupcomm-oscore].¶
The 'group_senderId' element of the Group_OSCORE_Input_Material object MUST NOT be included.¶
Note that the informative response does not require to include an explicit proof-of-possession (PoP) of the server's private key. Although the server is also acting as Group Manager and a PoP evidence of the Group Manager's private key is included in a full-fledged Join Response (see Section 6.4 of [I-D.ietf-ace-key-groupcomm-oscore]), such proof-of-possession will be achieved through every multicast notification, that the server sends as protected with the group mode of Group OSCORE and including a signature computed with its private key.¶
A client receiving an informative response uses the information above to set up the Group OSCORE Security Context, as described in Section 2 of [I-D.ietf-core-oscore-groupcomm]. Note that the client does not obtain a Sender ID of its own, hence it installs a Security Context that a "silent server" would, i.e., without Sender Context. From then on, the client uses the received keying material to process the incoming multicast notifications from the server.¶
Since the server is also acting as Group Manager, the authentication credential of the server provided in the 'srv_cred' element of the informative response is also used in the 'gm_cred' element of the external_aad for encrypting and signing the phantom request and multicast notifications (see Section 4.3 of [I-D.ietf-core-oscore-groupcomm])¶
Furthermore, the server complies with the following points.¶
The server MUST NOT self-manage OSCORE groups and provide the related keying material in the informative response for any other purpose than the protection of group observations, as defined in this document.¶
The server MAY use the same self-managed OSCORE group to protect the phantom request and the multicast notifications of multiple group observations it hosts.¶
After the time indicated in the 'exp' field:¶
The server MUST stop using the keying material and MUST cancel the group observations for which that keying material is used (see Section 4.5 and Section 9.2.4). If the server creates a new group observation as a replacement or follow-up using the same OSCORE group:¶
Before the keying material has expired, the server can send a multicast response with response code 5.03 (Service Unavailable) to the observing clients, protected with the current keying material. In particular, this is an informative response (see Section 4.2), which: i) additionally contains the abovementioned parameters for the next group keying material to be used; and ii) MAY omit the 'tp_info' and 'ph_req' parameters, since the associated information is immutable throughout the observation lifetime. The response has the same Token value T of the phantom registration request and it does not include an Observe Option. The server MUST use its own Sender Sequence Number as Partial IV to protect the error response, and include it as Partial IV in the OSCORE Option of the response.¶
When some clients leave the OSCORE group and forget about the group observation, the server does not have to provide the remaining clients with any stale Sender IDs, as normally required for Group OSCORE (see Section 3.2 of [I-D.ietf-core-oscore-groupcomm]). In fact, only two entities in the group have a Sender ID, i.e., the server and possibly the Deterministic Client, if the optimization defined in this appendix is combined with the use of phantom requests as deterministic requests (see Appendix D). In particular, both of them never change their Sender ID during the group lifetime, while they both remain part of the group until the group ceases to exist.¶
As an alternative to renewing the keying material before it expires, the server can simply cancel the group observation (see Section 4.5 and Section 9.2.4), which results in the eventual re-registration of the clients that are still interested in the group observation.¶
Applications requiring backward security and forward security are REQUIRED to use an actual group joining process (usually through a dedicated Group Manager), e.g., the ACE joining procedure defined in [I-D.ietf-ace-key-groupcomm-oscore]. The server can facilitate the clients by providing them information about the OSCORE group to join, as described in Section 9.1.¶
In some settings, the server can assume that all the approaching clients already have the exact phantom observation request to use, together with the transport-specific information required to listen to corresponding multicast notifications.¶
For instance, the clients can be pre-configured with the phantom observation request, or they may be expected to retrieve it through dedicated means (see Appendix A). In either case, the server would already have started the group observation, before the associated phantom observation request was disseminated.¶
Then, the clients either set up their multicast address and group observation for listening to multicast notifications if directly able to, or rely on a proxy to do so on their behalf (see Section 11 and Section 12).¶
If Group OSCORE is used to protect the group observation (see Section 9), and the OSCORE group supports the concept of Deterministic Client [I-D.amsuess-core-cachable-oscore], then the server and each client in the OSCORE group can also independently compute the protected phantom observation request.¶
In such a case, the unprotected version of the phantom observation request can be made available to the clients as a smaller, plain CoAP message. As above, this can be pre-configured on the clients, or they can obtain it through dedicated means (see Appendix A). In either case, the clients and the server can independently protect the plain CoAP message by using the approach defined in Section 3 of [I-D.amsuess-core-cachable-oscore], thus all computing the same protected deterministic request. The latter is used as the actual phantom observation request, against which the protected multicast notifications will match for the group observation in question.¶
If relying on a proxy, each client sends the deterministic request to the proxy as a ticket request (see Section 12). However, differently from what is defined in Section 12 when the ticket request is not a deterministic request, the clients do not include a Listen-to-Multicast-Responses Option. This results in the proxy forwarding the ticket request (i.e., the phantom observation request) to the server and obtaining the information required to listen to multicast notifications, unless the proxy has already set itself to do so. Also, the proxy will be able to serve multicast notifications from its cache as per [I-D.amsuess-core-cachable-oscore]. An example considering such a setup is shown in Appendix G.¶
Note that the phantom registration request is, in terms of transport-independent information, identical to the same deterministic request possibly sent by each client (e.g., if a proxy is deployed). Thus, if the server receives such a phantom registration request, the informative response may omit the 'ph_req' parameter (see Section 4.2). If a client receives an informative response that includes the 'ph_req' parameter, and this specifies transport-independent information different from the one of the sent deterministic request, then the client considers the informative response malformed.¶
If the optimization defined in Appendix C is also used, the 'gp_material' element in the informative response from the server MUST also include the following elements from the Group_OSCORE_Input_Material object.¶
If a deterministic request is used as phantom observation request for a group observation, the server does not assist clients that are interested to take part to the group observation but do not support deterministic requests. This is consistent with the fact that the setup in question already relies on a lot of agreed pre-configuration.¶
Therefore, the following holds when a group observation relies on a deterministic request as phantom observation request.¶
When running such an observation request, the server does not simultaneously run a parallel group observation for the same target resource, as associated with a different phantom observation request and intended to clients that do not support deterministic requests.¶
Upon receiving an individual observation request for the same target resource, the server MUST reply with a generic 5.03 (Service Unavailable) response (i.e., not the informative response defined in Section 4.2), if the request differs from the specific deterministic request associated with the group observation.¶
This section provides an example when a proxy P is used between the clients and the server. The same assumptions and notation used in Section 7 are used for this example. In addition, the proxy has address PRX_ADDR and listens to the port number PRX_PORT.¶
Unless explicitly indicated, all messages transmitted on the wire are sent over unicast.¶
Note that the proxy has all the information to understand the observation request from C2, and can immediately start to serve the still fresh values.¶
This behavior is mandated by Section 5 of [RFC7641], i.e., the proxy registers itself only once with the next hop and fans out the notifications it receives to all registered clients.¶
This section provides an example when a proxy P is used between the clients and the server, and Group OSCORE is used to protect multicast notifications end-to-end between the server and the clients.¶
The same assumptions and notation used in Section 10 are used for this example. In addition, the proxy has address PRX_ADDR and listens to the port number PRX_PORT.¶
Unless explicitly indicated, all messages transmitted on the wire are sent over unicast and protected with OSCORE end-to-end between a client and the server.¶
Unlike in the unprotected example in Appendix E, the proxy does not have all the information to perform request deduplication, and can only recognize the identical request once the client sends the ticket request.¶
This section provides an example when a proxy P is used between the clients and the server, and Group OSCORE is used to protect multicast notifications end-to-end between the server and the clients.¶
In addition, the phantom request is especially a deterministic request (see Appendix D), which is protected with the pairwise mode of Group OSCORE as defined in [I-D.amsuess-core-cachable-oscore].¶
The example provided in this appendix as reflected by the message exchange shown in Appendix G.2 assumes the following.¶
The same assumptions and notation used in Section 10 are used for this example. As a recap of some specific value:¶
In addition:¶
Unless explicitly indicated, all messages transmitted on the wire are sent over unicast and protected with Group OSCORE end-to-end between a client and the server.¶
C1 C2 P S | | | | | | | | (The value of the resource /r is "1234") | | | | | | | | (S allocates the available | | | | Token value 0x7b .) | | | | | | | | (S sends to itself a phantom observation | | | | request PH_REQ as coming from the | | | | IP multicast address GRP_ADDR. | | | | The OSCORE processing occurs as | | | | specified for a deterministic request) | | | | | | | -------| | | | / | | | | \------>| Token: 0x7b | | | FETCH | Uri-Host: sensor.example | | | | Observe: 0 (Register) | | | | OSCORE: {kid: 0x09 ; piv: 0 ; | | | | kid context: 0x57ab2e ; ... } | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x01 (GET), | | | | Observe: 0 (Register), | | | | Uri-Path: r, | | | | <Other class E options> | | | | } | | | | | | | | (S creates a group observation of /r) | | | | | | | | (The server does not respond to PH_REQ. | | | | The server stores PH_REQ locally and | | | | makes it available at an external source) | | | | | | | | | | | | (C1 obtains PH_REQ and sends it to P) | | | | | | | | +-------------->| | Token: 0x4a | FETCH | | | Uri-Host: sensor.example | | | | Observe: 0 (Register) | | | | OSCORE: {kid: 0x09 ; piv: 0 ; | | | | kid context: 0x57ab2e ; ... } | | | | Proxy-Scheme: coap | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x01 (GET), | | | | Observe: 0 (Register), | | | | Uri-Path: r, | | | | <Other class E options> | | | | } | | | | | | +-------->| Token: 0x5e | | | FETCH | Uri-Host: sensor.example | | | | Observe: 0 (Register) | | | | OSCORE: {kid: 0x09 ; piv: 0 ; | | | | kid context: 0x57ab2e ; ... } | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x01 (GET), | | | | Observe: 0 (Register), | | | | Uri-Path: r, | | | | <Other class E options> | | | | } | | | | | | | | (S recognizes PH_REQ through byte-by-byte | | | | comparison against the stored one, and | | | | skips any OSCORE processing) | | | | | | | | (S prepares the "last notification" | | | | response defined below) | | | | | | | | 0x45 (2.05 Content) | | | | Observe: 10 | | | | OSCORE: {kid: 0x05 ; piv: 501 ; ...} | | | | Max-Age: 3000 | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x45 (2.05 Content), | | | | Observe: [empty], | | | | CBOR_Payload: "1234" | | | | } | | | | <Signature> | | | | | | | | (S responds to the proxy with an | | | | unprotected informative response) | | | | | | |<--------| Token: 0x5e | | | 5.03 | Content-Format: application/ | | | | informative-response+cbor | | | | Max-Age: 0 | | | | 0xff, | | | | CBOR_payload { | | | | tp_info : [1, bstr(SRV_ADDR), SRV_PORT, | | | | 0x7b, bstr(GRP_ADDR), | | | | GRP_PORT], | | | | last_notif : <the "last notification" | | | | response prepared above> | | | | } | | | | } | | | | | | | | (P extracts PH_REQ and starts listening | | | | to multicast notifications with Token | | | | 0x7b at GRP_ADDR:GRP_PORT) | | | | | | | | (P extracts the "last notification" | | | | response, caches it and forwards | | | | it back to C1) | | | | |<--------------+ | Token: 0x4a | 2.05 | | | Observe: 54120 | | | | OSCORE: {kid: 0x05 ; piv: 501 ; ...} | | | | Max-Age: 2995 | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x45 (2.05 Content), | | | | Observe: [empty], | | | | CBOR_Payload: "1234" | | | | } | | | | <Signature> | | | | : : : | : : : | : : : | | | | | | | | | (C2 obtains PH_REQ and sends it to P) | | | | | +------>| | Token: 0x01 | | FETCH | | Uri-Host: sensor.example | | | | Observe: 0 (Register) | | | | OSCORE: {kid: 0x09 ; piv: 0 ; | | | | kid context: 0x57ab2e; ...} | | | | Proxy-Scheme: coap | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x01 (GET), | | | | Observe: 0 (Register), | | | | Uri-Path: r, | | | | <Other class E options> | | | | } | | | | | | | | (P serves C2 from it cache) | | | | | |<------+ | Token: 0x01 | | 2.05 | | Observe: 54120 | | | | OSCORE: {kid: 0x05 ; piv: 501 ; ...} | | | | Max-Age: 1800 | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x45 (2.05 Content), | | | | Observe: [empty], | | | | CBOR_Payload: "1234" | | | | } | | | | <Signature> | | | | : : : | : : : | : : : | | | | | | | | | (The value of the resource | | | | /r changes to "5678".) | | | | | | | (*) | | | |<--------| Token: 0x7b | | | 2.05 | Observe: 11 | | | | OSCORE: {kid: 0x05; piv: 502 ; ...} | | | | <Other class U/I options> | | | | 0xff | | | | Encrypted_payload { | | | | 0x45 (2.05 Content), | | | | Observe: [empty], | | | | Content-Format: application/cbor, | | | | <Other class E options>, | | | | 0xff, | | | | CBOR_Payload: "5678" | | | | } | | | | <Signature> | | | | | | | | (P updates its cache entry | | | | with this notification) | | | | |<--------------+ | Token: 0x4a | 2.05 | | | Observe: 54123 | | | | OSCORE: {kid: 0x05; piv: 502 ; ...} | | | | <Other class U/I options> | | | | 0xff | | | | (Same Encrypted_payload and signature) | | | | | |<------+ | Token: 0x01 | | 2.05 | | Observe: 54123 | | | | OSCORE: {kid: 0x05; piv: 502 ; ...} | | | | <Other class U/I options> | | | | 0xff | | | | (Same Encrypted_payload and signature) | | | | (*) Sent over IP multicast to GROUP_ADDR:GROUP_PORT and protected with Group OSCORE end-to-end between the server and the clients.¶
RFC EDITOR: PLEASE REMOVE THIS SECTION.¶
The authors sincerely thank Carsten Bormann, Klaus Hartke, Jaime Jiménez, John Preuß Mattsson, Jim Schaad, Ludwig Seitz and Göran Selander for their comments and feedback.¶
The work on this document has been partly supported by VINNOVA and the Celtic-Next project CRITISEC; and by the H2020 project SIFIS-Home (Grant agreement 952652).¶