Internet-Draft | HTTP Datagrams | October 2021 |
Schinazi & Pardue | Expires 10 April 2022 | [Page] |
The QUIC DATAGRAM extension provides application protocols running over QUIC with a mechanism to send unreliable data while leveraging the security and congestion-control properties of QUIC. However, QUIC DATAGRAM frames do not provide a means to demultiplex application contexts. This document describes how to use QUIC DATAGRAM frames when the application protocol running over QUIC is HTTP/3. It associates datagrams with client-initiated bidirectional streams and defines an optional additional demultiplexing layer. Additionally, this document defines how to convey datagrams over prior versions of HTTP.¶
This note is to be removed before publishing as an RFC.¶
Discussion of this document takes place on the MASQUE WG mailing list (masque@ietf.org), which is archived at https://mailarchive.ietf.org/arch/browse/masque/.¶
Source for this draft and an issue tracker can be found at https://github.com/ietf-wg-masque/draft-ietf-masque-h3-datagram.¶
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/.¶
Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."¶
This Internet-Draft will expire on 10 April 2022.¶
Copyright (c) 2021 IETF Trust and the persons identified as the document authors. All rights reserved.¶
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.¶
The QUIC DATAGRAM extension [DGRAM] provides application protocols running over QUIC [QUIC] with a mechanism to send unreliable data while leveraging the security and congestion-control properties of QUIC. However, QUIC DATAGRAM frames do not provide a means to demultiplex application contexts. This document describes how to use QUIC DATAGRAM frames when the application protocol running over QUIC is HTTP/3 [H3]. It associates datagrams with client-initiated bidirectional streams and defines an optional additional demultiplexing layer. Additionally, this document defines how to convey datagrams over prior versions of HTTP.¶
This document is structured as follows:¶
Section 2 presents core concepts for multiplexing across HTTP versions.¶
Section 4 introduces the Capsule Protocol and the "data stream" concept. Data streams are initiated using special-purpose HTTP requests, after which Capsules, an end-to-end message, can be sent.¶
The following Capsule types are defined, together with guidance for defining new types:¶
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.¶
When running over HTTP/3, multiple exchanges of datagrams need the ability to coexist on a given QUIC connection. To allow this, HTTP datagrams contain two layers of multiplexing. First, the QUIC DATAGRAM frame payload starts with an encoded stream identifier that associates the datagram with a given QUIC stream. Second, datagrams optionally carry a context identifier (see Section 2.1) that allows multiplexing multiple datagram contexts related to a given HTTP request. Conceptually, the first layer of multiplexing is per-hop, while the second is end-to-end.¶
When running over HTTP/2, the first level of demultiplexing is provided by the HTTP/2 framing layer. When running over HTTP/1, requests are strictly serialized in the connection, therefore the first layer of demultiplexing is not needed.¶
Within the scope of a given HTTP request, contexts provide an additional demultiplexing layer. Contexts determine the encoding of datagrams, and can be used to implicitly convey metadata. For example, contexts can be used for compression to elide some parts of the datagram: the context identifier then maps to a compression context that the receiver can use to reconstruct the elided data.¶
Contexts are optional, whether to use them or not is decided by the client on each request stream using registration capsules, see Section 4.4.1 and Section 4.4.2. When contexts are used, they are identified within the scope of a given request by a numeric value, referred to as the context ID. A context ID is a 62-bit integer (0 to 262-1).¶
While stream IDs are a per-hop concept, context IDs are an end-to-end concept. In other words, if a datagram travels through one or more intermediaries on its way from client to server, the stream ID will most likely change from hop to hop, but the context ID will remain the same. Context IDs are opaque to intermediaries.¶
When an endpoint registers a datagram context (or the lack of contexts), it communicates the format (i.e., the semantics and encoding) of datagrams sent using this context. This is acccomplished by sending a Datagram Format Type as part of the registration capsule, see Section 4.4.1 and Section 4.4.2. This type identifier is registered with IANA (see Section 8.3) and allows applications that use HTTP Datagrams to indicate what the content of datagrams are. Registration capsules carry a Datagram Format Additional Data field which allows sending some additional information that would impact the format of datagrams.¶
For example, a protocol which proxies IP packets can define a Datagram Format Type which represents an IP packet. The corresponding Datagram Format Additional Data field would be empty. An extension to such a protocol that wishes to compress IP addresses could define a distinct Datagram Format Type and exchange two IP addresses via the Datagram Format Additional Data field. Then any datagrams with that type would contain the IP packet with addresses elided.¶
Implementations of HTTP Datagrams MUST provide a context ID allocation service. That service will allow applications co-located with HTTP to request a unique context ID that they can subsequently use for their own purposes. The HTTP implementation will then parse the context ID of incoming HTTP Datagrams and use it to deliver the frame to the appropriate application context.¶
Even-numbered context IDs are client-initiated, while odd-numbered context IDs are server-initiated. This means that an HTTP client implementation of the context ID allocation service MUST only provide even-numbered IDs, while a server implementation MUST only provide odd-numbered IDs. Note that, once allocated, any context ID can be used by both client and server - only allocation carries separate namespaces to avoid requiring synchronization. Additionally, note that the context ID namespace is tied to a given HTTP request: it is possible for the same numeral context ID to be used simultaneously in distinct requests.¶
When used with HTTP/3, the Datagram Data field of QUIC DATAGRAM frames uses the following format (using the notation from the "Notational Conventions" section of [QUIC]):¶
A variable-length integer that contains the value of the client-initiated bidirectional stream that this datagram is associated with, divided by four (the division by four stems from the fact that HTTP requests are sent on client-initiated bidirectional streams, and those have stream IDs that are divisible by four). The largest legal QUIC stream ID value is 262-1, so the largest legal value of Quarter Stream ID is 262-1 / 4. Receipt of a frame that includes a larger value MUST be treated as a connection error of type FRAME_ENCODING_ERROR.¶
A variable-length integer indicating the context ID of the datagram (see Section 2.1). Whether or not this field is present depends on which registration capsules were exchanged on the associated stream: if a REGISTER_DATAGRAM_CONTEXT capsule (see Section 4.4.1) has been sent or received on this stream, then the field is present; if a REGISTER_DATAGRAM_NO_CONTEXT capsule (see Section 4.4.2) has been sent or received, then this field is absent; if neither has been sent or received, then it is not yet possible to parse this datagram and the receiver MUST either drop that datagram silently or buffer it temporarily while awaiting the registration capsule.¶
The payload of the datagram, whose semantics are defined by individual applications. Note that this field can be empty.¶
Intermediaries parse the Quarter Stream ID field in order to associate the QUIC DATAGRAM frame with a stream. If an intermediary receives a QUIC DATAGRAM frame whose payload is too short to allow parsing the Quarter Stream ID field, the intermediary MUST treat it as an HTTP/3 connection error of type H3_GENERAL_PROTOCOL_ERROR. The Context ID field is optional and whether it is present or not is decided end-to-end by the client, see Section 4.4.2. Therefore intermediaries cannot know whether the Context ID field is present or absent and they MUST ignore any HTTP/3 Datagram fields after the Quarter Stream ID.¶
Endpoints parse both the Quarter Stream ID field and the Context ID field in order to associate the QUIC DATAGRAM frame with a stream and context within that stream. If an endpoint receives a QUIC DATAGRAM frame whose payload is too short to allow parsing the Quarter Stream ID field, the endpoint MUST treat it as an HTTP/3 connection error of type H3_GENERAL_PROTOCOL_ERROR. If an endpoint receives a QUIC DATAGRAM frame whose payload is long enough to allow parsing the Quarter Stream ID field but too short to allow parsing the Context ID field, the endpoint MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
Endpoints MUST NOT send HTTP/3 datagrams unless the corresponding stream's send side is open. On a given endpoint, once the receive side of a stream is closed, incoming datagrams for this stream are no longer expected so the endpoint can release related state. Endpoints MAY keep state for a short time to account for reordering. Once the state is released, the endpoint MUST silently drop received associated datagrams.¶
If an HTTP/3 datagram is received and its Quarter Stream ID maps to a stream that has not yet been created, the receiver SHALL either drop that datagram silently or buffer it temporarily while awaiting the creation of the corresponding stream.¶
This specification introduces the Capsule Protocol. The Capsule Protocol is a sequence of type-length-value tuples that allows endpoints to reliably communicate request-related information end-to-end, even in the presence of HTTP intermediaries.¶
This specification defines the "data stream" of an HTTP request as the bidirectional stream of bytes that follow the headers in both directions. In HTTP/1.x, the data stream consists of all bytes on the connection that follow the blank line that concludes either the request header section, or the 2xx (Successful) response header section. In HTTP/2 and HTTP/3, the data stream of a given HTTP request consists of all bytes sent in DATA frames with the corresponding stream ID. The concept of a data stream is particularly relevant for methods such as CONNECT where there is no HTTP message content after the headers.¶
Definitions of new HTTP Methods or of new HTTP Upgrade Tokens can state that their data stream uses the Capsule Protocol. If they do so, that means that the contents of their data stream uses the following format (using the notation from the "Notational Conventions" section of [QUIC]):¶
A variable-length integer indicating the Type of the capsule. Endpoints that receive a capsule with an unknown Capsule Type MUST silently skip over that capsule.¶
The length of the Capsule Value field following this field, encoded as a variable-length integer. Note that this field can have a value of zero.¶
The payload of this capsule. Its semantics are determined by the value of the Capsule Type field.¶
If the definition of an HTTP Method or HTTP Upgrade Token states that it uses the capsule protocol, its implementations MUST follow the following requirements:¶
Intermediaries MUST operate in one of the two following modes:¶
In this mode, the intermediary forwards the data stream between two associated streams without any modification of the data stream.¶
In this mode, the intermediary terminates the data stream and parses all Capsule Type and Capsule Length fields it receives.¶
Each Capsule Type determines whether it is opaque or transparent to intermediaries in participant mode: opaque capsules are forwarded unmodified while transparent ones can be parsed, added, or removed by intermediaries. Intermediaries MAY modify the contents of the Capsule Data field of transparent capsule types.¶
Unless otherwise specified, all Capsule Types are defined as opaque to intermediaries. Intermediaries MUST forward all received opaque CAPSULE frames in their unmodified entirety. Intermediaries MUST NOT send any opaque CAPSULE frames other than the ones it is forwarding. All Capsule Types defined in this document are opaque, with the exception of the DATAGRAM Capsule, see Section 4.4.4. Definitions of new Capsule Types MAY specify that the newly introduced type is transparent. Intermediaries MUST treat unknown Capsule Types as opaque.¶
Intermediaries respect the order of opaque CAPSULE frames: if an intermediary receives two opaque CAPSULE frames in a given order, it MUST forward them in the same order.¶
Endpoints which receive a Capsule with an unknown Capsule Type MUST silently drop that Capsule.¶
The REGISTER_DATAGRAM_CONTEXT capsule (see Section 8.2 for the value of the capsule type) allows an endpoint to inform its peer of the encoding and semantics of datagrams associated with a given context ID.¶
The context ID to register.¶
A variable-length integer that defines the semantics and encoding of the HTTP Datagram Payload field of datagrams with this context ID, see Section 2.2.¶
This field carries additional information that impact the format of datagrams with this context ID, see Section 2.2.¶
Note that these registrations are unilateral and bidirectional: the sender of the frame unilaterally defines the semantics it will apply to the datagrams it sends and receives using this context ID. Once a context ID is registered, it can be used in both directions.¶
Endpoints MUST NOT send DATAGRAM frames using a Context ID until they have either sent or received a REGISTER_DATAGRAM_CONTEXT Capsule with the same Context ID. However, reordering can cause DATAGRAM frames to be received with an unknown Context ID. Receipt of such frames MUST NOT be treated as an error. Endpoints SHALL drop the DATAGRAM frame silently, or buffer it temporarily while awaiting the corresponding REGISTER_DATAGRAM_CONTEXT Capsule. Intermediaries SHALL drop the DATAGRAM frame silently, MAY buffer it, or forward it on immediately.¶
Endpoints MUST NOT register the same Context ID twice on the same stream. This also applies to Context IDs that have been closed using a CLOSE_DATAGRAM_CONTEXT capsule. Clients MUST NOT register server-initiated Context IDs and servers MUST NOT register client-initiated Context IDs. If an endpoint receives a REGISTER_DATAGRAM_CONTEXT capsule that violates one or more of these requirements, the endpoint MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
Servers MUST NOT send a REGISTER_DATAGRAM_CONTEXT capsule on a stream before they have received at least one REGISTER_DATAGRAM_CONTEXT capsule or one REGISTER_DATAGRAM_NO_CONTEXT capsule from the client on that stream. This ensures that clients control whether datagrams are allowed for a given request. If a client receives a REGISTER_DATAGRAM_CONTEXT capsule on a stream where the client has not yet sent a REGISTER_DATAGRAM_CONTEXT capsule, the client MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
Servers MUST NOT send a REGISTER_DATAGRAM_CONTEXT capsule on a stream where it has received a REGISTER_DATAGRAM_NO_CONTEXT capsule. If a client receives a REGISTER_DATAGRAM_CONTEXT capsule on a stream where the client has sent a REGISTER_DATAGRAM_NO_CONTEXT capsule, the client MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
The REGISTER_DATAGRAM_NO_CONTEXT capsule (see Section 8.2 for the value of the capsule type) allows a client to inform the server that datagram contexts will not be used with this stream. It also informs the server of the encoding and semantics of datagrams associated with this stream.¶
A variable-length integer that defines the semantics and encoding of the HTTP Datagram Payload field of datagrams, see Section 2.2.¶
This field carries additional information that impact the format of datagrams, see Section 2.2.¶
Note that this registration is unilateral and bidirectional: the client unilaterally defines the semantics it will apply to the datagrams it sends and receives with this stream.¶
Endpoints MUST NOT send DATAGRAM frames without a Context ID until they have either sent or received a REGISTER_DATAGRAM_NO_CONTEXT Capsule. However, due to reordering, an endpoint that receives a DATAGRAM frame before receiving either a REGISTER_DATAGRAM_CONTEXT capsule or a REGISTER_DATAGRAM_NO_CONTEXT capsule MUST NOT treat it as an error, it SHALL instead drop the DATAGRAM frame silently, or buffer it temporarily while awaiting a REGISTER_DATAGRAM_NO_CONTEXT capsule or the corresponding REGISTER_DATAGRAM_CONTEXT capsule.¶
Servers MUST NOT send the REGISTER_DATAGRAM_NO_CONTEXT capsule. If a client receives a REGISTER_DATAGRAM_NO_CONTEXT capsule, the client MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
Clients MUST NOT send more than one REGISTER_DATAGRAM_NO_CONTEXT capsule on a stream. If a server receives a second REGISTER_DATAGRAM_NO_CONTEXT capsule on the same stream, the server MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
Clients MUST NOT send both REGISTER_DATAGRAM_CONTEXT capsules and REGISTER_DATAGRAM_NO_CONTEXT capsules on the same stream. If a server receives both a REGISTER_DATAGRAM_CONTEXT capsule and a REGISTER_DATAGRAM_NO_CONTEXT capsule on the same stream, the server MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
Extensions MAY define a different mechanism to communicate whether contexts are in use, and they MAY do so in a way which is opaque to intermediaries.¶
The CLOSE_DATAGRAM_CONTEXT capsule (see Section 8.2 for the value of the capsule type) allows an endpoint to inform its peer that it will no longer send or parse received datagrams associated with a given context ID.¶
The context ID to close.¶
The close code allows an endpoint to provide additional information as to why a datagram context was closed. Section 4.4.3.1 defines a set of codes, the circumstances under which an implementation sends them, and how receivers react.¶
This is meant for debugging purposes. It consists of a human-readable string encoded in UTF-8.¶
Note that this close is unilateral and bidirectional: the sender of the frame unilaterally informs its peer of the closure. Endpoints can use CLOSE_DATAGRAM_CONTEXT capsules to close a context that was initially registered by either themselves, or by their peer. Endpoints MAY use the CLOSE_DATAGRAM_CONTEXT capsule to immediately reject a context that was just registered using a REGISTER_DATAGRAM_CONTEXT capsule if they find its Datagram Format Type field to be unacceptable.¶
After an endpoint has either sent or received a CLOSE_DATAGRAM_CONTEXT frame, it MUST NOT send any DATAGRAM frames with that Context ID. However, due to reordering, an endpoint that receives a DATAGRAM frame with a closed Context ID MUST NOT treat it as an error, it SHALL instead drop the DATAGRAM frame silently.¶
Endpoints MUST NOT close a Context ID that was not previously registered. Endpoints MUST NOT close a Context ID that has already been closed. If an endpoint receives a CLOSE_DATAGRAM_CONTEXT capsule that violates one or more of these requirements, the endpoint MUST abruptly terminate the corresponding stream with a stream error of type H3_GENERAL_PROTOCOL_ERROR.¶
Close codes are intended to allow implementations to react differently when they receive them - for example, some close codes require the receiver to not open another context under certain conditions.¶
This specification defines the close codes below. Their numeric values are in Section 8.4. Extensions to this mechanism MAY define new close codes and they SHOULD state how receivers react to them.¶
This indicates that a context was closed without any action specified for the receiver.¶
This indicates that the sender does not know how to interpret the datagram format type associated with this context. The endpoint that had originally registered this context MUST NOT try to register another context with the same datagram format type on this stream.¶
This indicates that the sender has rejected the context registration based on its local policy. The endpoint that had originally registered this context MUST NOT try to register another context with the same datagram format type and datagram format data on this stream.¶
This indicates that the context was closed to save resources. The recipient SHOULD limit its future registration of resource-intensive contexts.¶
Receipt of an unknown close code MUST be treated as if the NO_ERROR code was present. Close codes are registered with IANA, see Section 8.4.¶
The DATAGRAM capsule (see Section 8.2 for the value of the capsule type) allows an endpoint to send a datagram frame over an HTTP stream. This is particularly useful when using a version of HTTP that does not support QUIC DATAGRAM frames.¶
A variable-length integer indicating the context ID of the datagram (see Section 2.1). Whether or not this field is present depends on which registration capsules were exchanged on the associated stream: if a REGISTER_DATAGRAM_CONTEXT capsule (see Section 4.4.1) has been sent or received on this stream, then the field is present; if a REGISTER_DATAGRAM_NO_CONTEXT capsule (see Section 4.4.2) has been sent or received, then this field is absent; if neither has been sent or received, then it is not yet possible to parse this datagram and the receiver MUST either drop that datagram silently or buffer it temporarily while awaiting the registration capsule.¶
The payload of the datagram, whose semantics are defined by individual applications. Note that this field can be empty.¶
Datagrams sent using the DATAGRAM Capsule have the exact same semantics as datagrams sent in QUIC DATAGRAM frames. In particular, the restrictions on when it is allowed to send an HTTP Datagram and how to process them from Section 3 also apply to HTTP Datagrams sent and received using the DATAGRAM capsule.¶
The DATAGRAM Capsule is transparent to intermediaries, meaning that intermediaries MAY parse it and send DATAGRAM Capsules that they did not receive. This allows an intermediary to reencode HTTP Datagrams as it forwards them: in other words, an intermediary MAY send a DATAGRAM Capsule to forward an HTTP Datagram which was received in a QUIC DATAGRAM frame, and vice versa.¶
Note that while DATAGRAM capsules are sent on a stream, intermediaries can reencode HTTP Datagrams into QUIC DATAGRAM frames over the next hop, and those could be dropped. Because of this, applications have to always consider HTTP Datagrams to be unreliable, even if they were initially sent in a capsule.¶
If an intermediary receives an HTTP Datagram in a QUIC DATAGRAM frame and is forwarding it on a connection that supports QUIC DATAGRAM frames, the intermediary SHOULD NOT convert that HTTP Datagram to a DATAGRAM capsule. If the HTTP Datagram is too large to fit in a DATAGRAM frame (for example because the path MTU of that QUIC connection is too low or if the maximum UDP payload size advertised on that connection is too low), the intermediary SHOULD drop the HTTP Datagram instead of converting it to a DATAGRAM capsule. This preserves the end-to-end unreliability characteristic that methods such as Datagram Packetization Layer Path MTU Discovery (DPLPMTUD) depend on [RFC8899]. An intermediary that converts QUIC DATAGRAM frames to DATAGRAM capsules allows HTTP Datagrams to be arbitrarily large without suffering any loss; this can misrepresent the true path properties, defeating methods such a DPLPMTUD.¶
Implementations of HTTP/3 that support HTTP Datagrams can indicate that to their peer by sending the H3_DATAGRAM SETTINGS parameter with a value of 1. The value of the H3_DATAGRAM SETTINGS parameter MUST be either 0 or 1. A value of 0 indicates that HTTP Datagrams are not supported. An endpoint that receives the H3_DATAGRAM SETTINGS parameter with a value that is neither 0 or 1 MUST terminate the connection with error H3_SETTINGS_ERROR.¶
Endpoints MUST NOT send QUIC DATAGRAM frames until they have both sent and received the H3_DATAGRAM SETTINGS parameter with a value of 1.¶
When clients use 0-RTT, they MAY store the value of the server's H3_DATAGRAM SETTINGS parameter. Doing so allows the client to send QUIC DATAGRAM frames in 0-RTT packets. When servers decide to accept 0-RTT data, they MUST send a H3_DATAGRAM SETTINGS parameter greater than or equal to the value they sent to the client in the connection where they sent them the NewSessionTicket message. If a client stores the value of the H3_DATAGRAM SETTINGS parameter with their 0-RTT state, they MUST validate that the new value of the H3_DATAGRAM SETTINGS parameter sent by the server in the handshake is greater than or equal to the stored value; if not, the client MUST terminate the connection with error H3_SETTINGS_ERROR. In all cases, the maximum permitted value of the H3_DATAGRAM SETTINGS parameter is 1.¶
[[RFC editor: please remove this section before publication.]]¶
Some revisions of this draft specification use a different value (the Identifier field of a Setting in the HTTP/3 SETTINGS frame) for the H3_DATAGRAM Settings Parameter. This allows new draft revisions to make incompatible changes. Multiple draft versions MAY be supported by either endpoint in a connection. Such endpoints MUST send multiple values for H3_DATAGRAM. Once an endpoint has sent and received SETTINGS, it MUST compute the intersection of the values it has sent and received, and then it MUST select and use the most recent draft version from the intersection set. This ensures that both endpoints negotiate the same draft version.¶
Data streams (see Section 4.1) can be prioritized using any means suited to stream or request prioritization. For example, see Section 11 of [PRIORITY].¶
Prioritization of HTTP/3 datagrams is not defined in this document. Future extensions MAY define how to prioritize datagrams, and MAY define signaling to allow endpoints to communicate their prioritization preferences.¶
Since this feature requires sending an HTTP/3 Settings parameter, it "sticks out". In other words, probing clients can learn whether a server supports this feature. Implementations that support this feature SHOULD always send this Settings parameter to avoid leaking the fact that there are applications using HTTP/3 datagrams enabled on this endpoint.¶
This document will request IANA to register the following entry in the "HTTP/3 Settings" registry:¶
Setting Name | Value | Specification | Default |
---|---|---|---|
H3_DATAGRAM | 0xffd277 | This Document | 0 |
This document establishes a registry for HTTP capsule type codes. The "HTTP Capsule Types" registry governs a 62-bit space. Registrations in this registry MUST include the following fields:¶
A name or label for the capsule type.¶
The value of the Capsule Type field (see Section 4.1) is a 62-bit integer.¶
An optional reference to a specification for the type. This field MAY be empty.¶
Registrations follow the "First Come First Served" policy (see Section 4.4 of [IANA-POLICY]) where two registrations MUST NOT have the same Type.¶
This registry initially contains the following entries:¶
Capsule Type | Value | Specification |
---|---|---|
DATAGRAM | 0xff37a0 | This Document |
REGISTER_DATAGRAM_CONTEXT | 0xff37a1 | This Document |
REGISTER_DATAGRAM_NO_CONTEXT | 0xff37a2 | This Document |
CLOSE_DATAGRAM_CONTEXT | 0xff37a3 | This Document |
Capsule types with a value of the form 41 * N + 23 for integer values of N are reserved to exercise the requirement that unknown capsule types be ignored. These capsules have no semantics and can carry arbitrary values. These values MUST NOT be assigned by IANA and MUST NOT appear in the listing of assigned values.¶
This document establishes a registry for HTTP datagram format type codes. The "HTTP Datagram Format Types" registry governs a 62-bit space. Registrations in this registry MUST include the following fields:¶
A name or label for the datagram format type.¶
The value of the Datagram Format Type field (see Section 2.2) is a 62-bit integer.¶
An optional reference to a specification for the parameter. This field MAY be empty.¶
Registrations follow the "First Come First Served" policy (see Section 4.4 of [IANA-POLICY]) where two registrations MUST NOT have the same Type nor Value.¶
This registry is initially empty.¶
Datagram format types with a value of the form 41 * N + 17 for integer values of N are reserved to exercise the requirement that unknown datagram format types be ignored. These format types have no semantics and can carry arbitrary values. These values MUST NOT be assigned by IANA and MUST NOT appear in the listing of assigned values.¶
This document establishes a registry for HTTP context close codes. The "HTTP Context Close Codes" registry governs a 62-bit space. Registrations in this registry MUST include the following fields:¶
A name or label for the close code.¶
The value of the Close Code field (see Section 4.4.3) is a 62-bit integer.¶
An optional reference to a specification for the parameter. This field MAY be empty.¶
Registrations follow the "First Come First Served" policy (see Section 4.4 of [IANA-POLICY]) where two registrations MUST NOT have the same Type nor Value.¶
This registry initially contains the following entries:¶
Context Close Code | Value | Specification |
---|---|---|
NO_ERROR | 0xff78a0 | This Document |
UNKNOWN_FORMAT | 0xff78a1 | This Document |
DENIED | 0xff78a2 | This Document |
RESOURCE_LIMIT | 0xff78a3 | This Document |
Context close codes with a value of the form 41 * N + 19 for integer values of N are reserved to exercise the requirement that unknown context close codes be treated as NO_ERROR. These values MUST NOT be assigned by IANA and MUST NOT appear in the listing of assigned values.¶
Client Server STREAM(44): HEADERS --------> :method = CONNECT-UDP :scheme = https :path = / :authority = target.example.org:443 STREAM(44): DATA --------> Capsule Type = REGISTER_DATAGRAM_CONTEXT Context ID = 0 Datagram Format Type = UDP_PAYLOAD Datagram Format Additional Data = "" DATAGRAM --------> Quarter Stream ID = 11 Context ID = 0 Payload = Encapsulated UDP Payload <-------- STREAM(44): HEADERS :status = 200 /* Wait for target server to respond to UDP packet. */ <-------- DATAGRAM Quarter Stream ID = 11 Context ID = 0 Payload = Encapsulated UDP Payload¶
Client Server STREAM(44): HEADERS --------> :method = CONNECT-UDP :scheme = https :path = / :authority = target.example.org:443 STREAM(44): DATA --------> Capsule Type = REGISTER_DATAGRAM_CONTEXT Context ID = 0 Datagram Format Type = UDP_PAYLOAD Datagram Format Additional Data = "" DATAGRAM --------> Quarter Stream ID = 11 Context ID = 0 Payload = Encapsulated UDP Payload <-------- STREAM(44): HEADERS :status = 200 /* Wait for target server to respond to UDP packet. */ <-------- DATAGRAM Quarter Stream ID = 11 Context ID = 0 Payload = Encapsulated UDP Payload STREAM(44): DATA --------> Capsule Type = REGISTER_DATAGRAM_CONTEXT Context ID = 2 Datagram Format Type = UDP_PAYLOAD_WITH_TIMESTAMP Datagram Format Additional Data = "" DATAGRAM --------> Quarter Stream ID = 11 Context ID = 2 Payload = Encapsulated UDP Payload With Timestamp¶
Client Server STREAM(44): HEADERS --------> :method = CONNECT-IP :scheme = https :path = / :authority = proxy.example.org:443 <-------- STREAM(44): HEADERS :status = 200 /* Exchange CONNECT-IP configuration information. */ STREAM(44): DATA --------> Capsule Type = REGISTER_DATAGRAM_CONTEXT Context ID = 0 Datagram Format Type = IP_PACKET Datagram Format Additional Data = "" DATAGRAM --------> Quarter Stream ID = 11 Context ID = 0 Payload = Encapsulated IP Packet /* Endpoint happily exchange encapsulated IP packets */ /* using Quarter Stream ID 11 and Context ID 0. */ DATAGRAM --------> Quarter Stream ID = 11 Context ID = 0 Payload = Encapsulated IP Packet /* After performing some analysis on traffic patterns, */ /* the client decides it wants to compress a 2-tuple. */ STREAM(44): DATA --------> Capsule Type = REGISTER_DATAGRAM_CONTEXT Context ID = 2 Datagram Format Type = COMPRESSED_IP_PACKET Datagram Format Additional Data = "192.0.2.6,192.0.2.7" DATAGRAM --------> Quarter Stream ID = 11 Context ID = 2 Payload = Compressed IP Packet¶
Client Server STREAM(44): HEADERS --------> :method = CONNECT :scheme = https :method = webtransport :path = /hello :authority = webtransport.example.org:443 Origin = https://www.example.org:443 STREAM(44): DATA --------> Capsule Type = REGISTER_DATAGRAM_NO_CONTEXT Datagram Format Type = WEBTRANSPORT_DATAGRAM Datagram Format Additional Data = "" <-------- STREAM(44): HEADERS :status = 200 /* Both endpoints can now send WebTransport datagrams. */¶
The DATAGRAM context identifier was previously part of the DATAGRAM frame definition itself, the authors would like to acknowledge the authors of that document and the members of the IETF MASQUE working group for their suggestions. Additionally, the authors would like to thank Martin Thomson for suggesting the use of an HTTP/3 SETTINGS parameter. Furthermore, the authors would like to thank Ben Schwartz for writing the first proposal that used two layers of indirection.¶