Internet-Draft | pushpull | September 2024 |
Tulshibagwale | Expires 9 March 2025 | [Page] |
In situations where a transmitter of Security Event Tokens (SETs) to a network peer is also a receiver of SETs from the same peer, it is helpful to have an efficient way of sending and receiving SETs in one HTTP transaction. Using current mechanisms such as "Push-Based Delivery of Security Event Tokens (SETs) Using HTTP" or "Poll-Based Delivery of Security Event Tokens (SETs) Using HTTP" both require two or more HTTP connections to exchange SETs between peers. In many cases, such as when using the OpenID Shared Signals Framework (SSF), the situation where each entity is both a transmitter and receiver is getting increasingly common. In addition, this specification enables the transmission and reception of multiple SETs in one HTTP connection.¶
This note is to be removed before publishing as an RFC.¶
The latest revision of this draft can be found at https://sgnl-ai.github.io/pushpull/. Status information for this document may be found at https://datatracker.ietf.org/doc/draft-tulshibagwale-saag-pushpull-delivery/.¶
Source for this draft and an issue tracker can be found at https://github.com/SGNL-ai/pushpull.¶
This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.¶
Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.¶
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This Internet-Draft will expire on 9 March 2025.¶
Copyright (c) 2024 IETF Trust and the persons identified as the document authors. All rights reserved.¶
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Workloads that exchange SETs [RFC8417] with each other ("Transceivers") can do so efficiently using the protocol defined in this specification. Although this specification works along the lines of the DeliveryPush [RFC8935] and DeliveryPoll [RFC8936] specifications, it makes a few important additions:¶
A Transceiver initiating a communication can send multiple SETs in one HTTP connection to a Peer¶
The Transceiver initiating communication can acknowledge previously received SETs in the same HTTP connection to the Peer¶
The Peer responding to the communication can send multiple SETs in its response to a connection from the Transceiver¶
The Peer responding to the communication can acknowledge previously received SETs in its response to the Transceiver¶
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.¶
A networked workload that can act both as a transmitter of SETs and a receiver of SETs. It communicates with other trusted Transceivers to transmit and receive SETs using the protocol defined herein.¶
Another name for a Transceiver, used to signify the other end of the communication from a Transceiver.¶
A Transceiver initiating communication with a Peer.¶
A Transceiver responding to communication from a Peer.¶
The IETF RFC titled "Push-Based Delivery of Security Event Tokens (SETs) Using HTTP" [RFC8935].¶
The IETF RFC titled "Poll-Based Delivery of Security Event Tokens (SETs) Using HTTP" [RFC8936].¶
Each Transceiver that supports this specification MUST support a "Pushpull" endpoint. This endpoint MUST be capable of serving HTTP [RFC9110] requests. This endpoint MUST be TLS [RFC8446] enabled and MUST reject any communication not using TLS.¶
A Communication Object is a JSON object [RFC8259], and is a unit of communication used in this specification used both in requests and responses. When used in a request, the Initiator MAY have additional fields defined the later sections below. The common fields of this object are:¶
OPTIONAL. A JSON object containing key-value pairs in which the key of a field is a string that contains the jti
value of the SET that is specified in the value of the field. This field MAY be omitted to indicate that no SETs are being delivered by the initiator in this communication.¶
OPTIONAL. An array of strings, in which each string is the jti
value of a previously received SET that is acknowledged in this object. This array MAY be empty or this field MAY be omitted to indicate that no previously received SETs are being acknowledged in this communication.¶
OPTIONAL. A JSON object containing key-value pairs in which the key of a field is a string that contains the jti
value of a previously received SET that the sender of the communication object was unable to process. The value of the field is a JSON object that has the following fields:¶
This section describes how Transceivers can use HTTP Requests and Responses to exchange Communication Objects described in Section 5.¶
A Transceiver can initiate communication with a Peer in order to:¶
Acknowledge previously received SETs from the Peer.¶
Send SETs to the Peer.¶
Both acknowledge previously received SETs from the Peer and send SETs to the Peer.¶
To initiate communication, the Initiator makes a HTTP POST request to the Responder's Pushpull Endpoint Section 4. The body of this request is of the content type "application/json". It contains a Communication Object Section 5, and the following additional field MAY be present:¶
OPTIONAL. A number which specifies the maximum number of events the Responder can include in its response to the Initiator. If this field is absent in the request, the Responder MAY include any number of events in the response. If this field is present, then the Responder MUST NOT include more events than the value of "maxResponseEvents" in its response to the specific request.¶
A Responder MUST respond to a communication from an Initiator by sending an HTTP Response.¶
If the Responder is successful in processing the request, it MUST return the HTTP status code 200 (OK). The response MUST have the content-type "application/json" and the response MUST include a Communication Object Section 5.¶
The Responder MUST respond with an error response if it is unable to process the request. The error response MUST include the appropriate error code as described in Section 2.4 of DeliveryPush [RFC8935].¶
A Communication Object in a Response may contain jti
values in its ack
or setErrs
that do not correspond to the SETs received in the same Request to which the Response is being sent. They MAY consist of values received in previous Requests.¶
Transceivers MAY use WebSockets [RFC6455] to send and receive Communication Objects described in Section 5. Since WebSockets are a symmetric protocol, a Transceiver MAY send a Communication Object at any time to its Peer. In such communication, a Transceiver sends a Communication Object as Payload data over the WebSocket protocol to a Peer. Similarly, a Transceiver MAY receive a Communication Object from a Peer over a WebSocket connection, wherein the Communication Object is the Payload data. In all such WebSocket communication, the Payload data does not have any Extension data in it.¶
During any communication initiated by a Transceiver, the Transceiver MAY request the Peer to use WebSockets [RFC6455] by requesting that the connection be upgraded to a WebSocket connection. If the Transceiver and its Peer can successfully perform the WebSocket handshake for the Pushpull Subprotocol described in Section 7.1.1, then the Transceiver and Peer MUST use WebSockets until the connection is closed. If the handshake fails, the Transceiver and Peer MAY use the HTTP Request Response Binding as described in Section 6¶
The Pushpull subprotocol is used to transport Communication Objects Section 5 over a WebSocket connection. The Transceiver and its Peer agree to this subprotocol during the WebSocket handshake (see Section 1.3 of [RFC6455]).¶
During the Websocket handshake, the Initiator MUST include the value pushpull
in the list of protocols for the Sec-WebSocket-Protocol
header. The reply from the Responder MUST also include the value pushpull
in the list of values in its own Sec-WebSocket-Protocol
header, in order for the Initiator and Responder to use WebSockets.¶
The Initiator MUST verify the identity of the Responder by validating the TLS certification presented by the Responder, and verifying that it is the intended recipient of the request, before sending the Communication Object Section 5.¶
The Initiator MUST attempt to obtain the OAuth Protected Resource Metadata [OPRM] for the Responder endpoint. If such metadata is found, the Initiator MUST obtain an access token using the metadata. If no such metadata is found, then the Initiator MAY use any means to authorize itself to the Responder.¶
The Responder MUST verify the identity and authorization of the Initiator. The Responder MAY use OAuth Protected Resource Metadata [OPRM] for this purpose, but the Responder MAY use other means to authorize the Initiator, which are beyond the scope of this specification.¶
A Transceiver MUST attempt to deliver any SETs it has previously attempted to deliver to a Peer until:
* It receives an acknowledgement through the ack
value for that SET in a subsequent communication with the Peer
* It receives a setErrs
object for that SET in a subsequent communication with the Peer
* It has attempted to deliver the SET a maximum number of times and has failed to communicate either due to communication errors or lack of inclusion in ack
or setErrs
in subsequent communications that were conducted for the maximum number of times. The maximum number of attempts MAY be set by the Transceiver for itself and SHOULD be communicated offline to the Peers.¶
If a Transceiver previously attempted to deliver a SET in a response to a Peer's request, the Transceiver MAY Initiate a request to the Peer in order to retry delivery of the SET. A Peer MUST be able to either provide ack
s or setErrs
for the same SETs either through requests or responses.¶
A Transceiver MUST ensure that it includes the jti
value of each SET it receives, either in an ack
or a setErrs
value, to the Transceiver from which it received the SETs. A Transceiver SHOULD retry sending the same SET again if it was never responded to either in an ack
value or in a setErrs
value by a receiving Transceiver in a reasonable time period. A Transceiver MAY limit the number of times it retries sending a SET. A Transceiver MAY publish the retry time period and maximum number of retries to its peers, but such publication is outside the scope of this specification.¶
A Transceiver MUST NOT send two SETs with the same jti
value if the SET has been either acknowledged through ack
value or produced an error indicated by a setErrs
value. If a Transceiver wishes to re-send an event after it has received a error response through a setErrs
value, then it MUST generate a new SET that has a new (and unique) jti
value.¶
Transceivers MUST use TLS [RFC8446] to communicate with Peers and is subject to the security considerations of HTTP [RFC9110] Section 17.¶
A Responder may be vulnerable to denial of service attacks wherein a large number of spurious requests need to be processed. Having efficient authorization mechanisms such as OAuth 2.0 [RFC6749] can mitigate such attacks by leveraging standard infrastructure that is designed to handle such attacks.¶
Transceivers must make sure they respond to each SET received in a timely manner as described in the "All SETs Accounted For" section Section 10. This ensures that if there was a temporary disconnection between two Transceivers, say when a Responding Transceiver sent a Communication Object in the HTTP Response, that such disconnection is detected and the missing SETs can be retried.¶
SETs may contain confidential information, and Transceivers receiving SETs must be careful not to log such content or ensure that sensitive information from the SET is redacted before logging.¶
The following WebSocket subprotocol will be added to the "WebSocket Subprotocol Name Registry" [IANA.WebSocket.Subprotocol]¶
Subprotocol Identifier: puhspull
¶
Subprotocol Common Name: WebSocket transport for Pushpull delivery of SETs
¶
Subprotocol Definition: Section Section 7.1.1 of this document.¶