Hypertext Transfer Protocol (HTTP) over QUICMicrosoftMichael.Bishop@microsoft.com
Transport
QUICThe QUIC transport protocol has several features that are desirable in a
transport for HTTP, such as stream multiplexing, per-stream flow control, and
low-latency connection establishment. This document describes a mapping of HTTP
semantics over QUIC. This document also identifies HTTP/2 features that are
subsumed by QUIC, and describes how HTTP/2 extensions can be ported to QUIC.Discussion of this draft takes place on the QUIC working group mailing list
(quic@ietf.org), which is archived at
https://mailarchive.ietf.org/arch/search/?email_list=quic.Working Group information can be found at https://github.com/quicwg; source
code and issues list for this draft can be found at
https://github.com/quicwg/base-drafts/labels/http.The QUIC transport protocol has several features that are desirable in a
transport for HTTP, such as stream multiplexing, per-stream flow control, and
low-latency connection establishment. This document describes a mapping of HTTP
semantics over QUIC, drawing heavily on the existing TCP mapping, HTTP/2.
Specifically, this document identifies HTTP/2 features that are subsumed by
QUIC, and describes how the other features can be implemented atop QUIC.QUIC is described in . For a full description of HTTP/2, see
.The words “MUST”, “MUST NOT”, “SHOULD”, and “MAY” are used in this document.
It’s not shouting; when they are capitalized, they have the special meaning
defined in .An HTTP origin advertises the availability of an equivalent HTTP/QUIC endpoint
via the Alt-Svc HTTP response header or the HTTP/2 ALTSVC frame (),
using the ALPN token defined in .For example, an origin could indicate in an HTTP/1.1 or HTTP/2 response that
HTTP/QUIC was available on UDP port 443 at the same hostname by including the
following header in any response:On receipt of an Alt-Svc header indicating HTTP/QUIC support, a client MAY
attempt to establish a QUIC connection to the indicated host and port and, if
successful, send HTTP requests using the mapping described in this document.Connectivity problems (e.g. firewall blocking UDP) can result in QUIC connection
establishment failure, in which case the client SHOULD continue using the
existing connection or try another alternative endpoint offered by the origin.This document defines the “quic” parameter for Alt-Svc, which MAY be used to
provide version-negotiation hints to HTTP/QUIC clients. QUIC versions are
four-octet sequences with no additional constraints on format. Syntax:Leading zeros SHOULD be omitted for brevity. When multiple versions are
supported, the “quic” parameter MAY be repeated multiple times in a single
Alt-Svc entry. For example, if a server supported both version 0x00000001 and
the version rendered in ASCII as “Q034”, it could specify the following header:Where multiple versions are listed, the order of the values reflects the
server’s preference (with the first value being the most preferred version).
Origins SHOULD list only versions which are supported by the alternative, but
MAY omit supported versions for any reason.HTTP/QUIC connections are established as described in . During
connection establishment, HTTP/QUIC support is indicated by selecting the ALPN
token “hq” in the crypto handshake.While connection-level options pertaining to the core QUIC protocol are set in
the initial crypto handshake, HTTP-specific settings are conveyed
in the SETTINGS frame. After the QUIC connection is established, a SETTINGS
frame () MUST be sent as the initial frame of the HTTP control
stream (StreamID 3, see ). The server MUST NOT send data on
any other stream until the client’s SETTINGS frame has been received.RFC Editor’s Note: Please remove this section prior to publication of a
final version of this document.Only implementations of the final, published RFC can identify themselves as
“hq”. Until such an RFC exists, implementations MUST NOT identify themselves
using this string.Implementations of draft versions of the protocol MUST add the string “-“ and
the corresponding draft number to the identifier. For example,
draft-ietf-quic-http-01 is identified using the string “hq-01”.Non-compatible experiments that are based on these draft versions MUST append
the string “-“ and an experiment name to the identifier. For example, an
experimental implementation based on draft-ietf-quic-http-09 which reserves an
extra stream for unsolicited transmission of 1980s pop music might identify
itself as “hq-09-rickroll”. Note that any label MUST conform to the “token”
syntax defined in Section 3.2.6 of . Experimenters are encouraged to
coordinate their experiments on the quic@ietf.org mailing list.A QUIC stream provides reliable in-order delivery of bytes, but makes no
guarantees about order of delivery with regard to bytes on other streams. On the
wire, data is framed into QUIC STREAM frames, but this framing is invisible to
the HTTP framing layer. A QUIC receiver buffers and orders received STREAM
frames, exposing the data contained within as a reliable byte stream to the
application.QUIC reserves Stream 1 for crypto operations (the handshake, crypto config
updates). Stream 3 is reserved for sending and receiving HTTP control frames,
and is analogous to HTTP/2’s Stream 0. This connection control stream is
considered critical to the HTTP connection. If the connection control stream is
closed for any reason, this MUST be treated as a connection error of type
QUIC_CLOSED_CRITICAL_STREAM.When HTTP headers and data are sent over QUIC, the QUIC layer handles most of
the stream management. An HTTP request/response consumes a pair of streams: This
means that the client’s first request occurs on QUIC streams 5 and 7, the second
on stream 9 and 11, and so on. The server’s first push consumes streams 2 and 4.
This amounts to the second least-significant bit differentiating the two streams
in a request.The lower-numbered stream is called the message control stream and carries
frames related to the request/response, including HEADERS. The higher-numbered
stream is the data stream and carries the request/response body with no
additional framing. Note that a request or response without a body will cause
this stream to be half-closed in the corresponding direction without
transferring data.Because the message control stream contains HPACK data which manipulates
connection-level state, the message control stream MUST NOT be closed with a
stream-level error. If an implementation chooses to reject a request with a
QUIC error code, it MUST trigger a QUIC RST_STREAM on the data stream only. An
implementation MAY close (FIN) a message control stream without completing a
full HTTP message if the data stream has been abruptly closed. Data on message
control streams MUST be fully consumed, or the connection terminated.All message control streams are considered critical to the HTTP connection. If
a message control stream is terminated abruptly for any reason, this MUST be
treated as a connection error of type HTTP_RST_CONTROL_STREAM. When a message
control stream terminates cleanly, if the last frame on the stream was
truncated, this MUST be treated as a connection error (see HTTP_MALFORMED_* in
).Pairs of streams must be utilized sequentially, with no gaps. The data stream
is opened at the same time as the message control stream is opened and is closed
after transferring the body. The data stream is closed immediately after
sending the request headers if there is no body.HTTP does not need to do any separate multiplexing when using QUIC - data sent
over a QUIC stream always maps to a particular HTTP transaction. Requests and
responses are considered complete when the corresponding QUIC streams are closed
in the appropriate direction.Since most connection-level concerns will be managed by QUIC, the primary use of
Stream 3 will be for the SETTINGS frame when the connection opens and for
PRIORITY frames subsequently.A client sends an HTTP request on a new pair of QUIC streams. A server sends an
HTTP response on the same streams as the request.An HTTP message (request or response) consists of:one header block (see ) on the control stream containing the
message headers (see , Section 3.2),the payload body (see , Section 3.3), sent on the data stream,optionally, one header block on the control stream containing the
trailer-part, if present (see , Section 4.1.2).In addition, prior to sending the message header block indicated above, a
response may contain zero or more header blocks on the control stream containing
the message headers of informational (1xx) HTTP responses (see ,
Section 3.2 and , Section 6.2).The data stream MUST be half-closed immediately after the transfer of the body.
If the message does not contain a body, the corresponding data stream MUST still
be half-closed without transferring any data. The “chunked” transfer encoding
defined in Section 4.1 of MUST NOT be used.Trailing header fields are carried in an additional header block on the message
control stream. Such a header block is a sequence of HEADERS frames with End
Header Block set on the last frame. Senders MUST send only one header block in
the trailers section; receivers MUST decode any subsequent header blocks in
order to maintain HPACK decoder state, but the resulting output MUST be
discarded.An HTTP request/response exchange fully consumes a pair of streams. After
sending a request, a client closes the streams for sending; after sending a
response, the server closes its streams for sending and the QUIC streams are
fully closed.A server can send a complete response prior to the client sending an entire
request if the response does not depend on any portion of the request that has
not been sent and received. When this is true, a server MAY request that the
client abort transmission of a request without error by sending a RST_STREAM
with an error code of NO_ERROR after sending a complete response and closing its
stream. Clients MUST NOT discard responses as a result of receiving such a
RST_STREAM, though clients can always discard responses at their discretion for
other reasons.HTTP/QUIC uses HPACK header compression as described in . HPACK was
designed for HTTP/2 with the assumption of in-order delivery such as that
provided by TCP. A sequence of encoded header blocks must arrive (and be
decoded) at an endpoint in the same order in which they were encoded. This
ensures that the dynamic state at the two endpoints remains in sync.QUIC streams provide in-order delivery of data sent on those streams, but there
are no guarantees about order of delivery between streams. To achieve in-order
delivery of HEADERS frames in QUIC, the HPACK-bearing frames contain a counter
which can be used to ensure in-order processing. Data (request/response bodies)
which arrive out of order are buffered until the corresponding HEADERS arrive.This does introduce head-of-line blocking: if the packet containing HEADERS for
stream N is lost or reordered then the HEADERS for stream N+4 cannot be
processed until it has been retransmitted successfully, even though the HEADERS
for stream N+4 may have arrived.
Keep HPACK with HOLB? Redesign HPACK to be order-invariant? How much
do we need to retain compatibility with HTTP/2’s HPACK?The pseudo-method CONNECT (, Section 4.3.6) is primarily used with
HTTP proxies to establish a TLS session with an origin server for the purposes
of interacting with “https” resources. In HTTP/1.x, CONNECT is used to convert
an entire HTTP connection into a tunnel to a remote host. In HTTP/2, the CONNECT
method is used to establish a tunnel over a single HTTP/2 stream to a remote
host for similar purposes.A CONNECT request in HTTP/QUIC functions in the same manner as in HTTP/2. The
request MUST be formatted as described in , Section 8.3. A CONNECT
request that does not conform to these restrictions is malformed. The message
data stream MUST NOT be closed at the end of the request.A proxy that supports CONNECT establishes a TCP connection () to the
server identified in the “:authority” pseudo-header field. Once this connection
is successfully established, the proxy sends a HEADERS frame containing a 2xx
series status code to the client, as defined in , Section 4.3.6, on
the message control stream.All QUIC STREAM frames on the message data stream correspond to data sent on the
TCP connection. Any QUIC STREAM frame sent by the client is transmitted by the
proxy to the TCP server; data received from the TCP server is written to the
data stream by the proxy. Note that the size and number of TCP segments is not
guaranteed to map predictably to the size and number of QUIC STREAM frames.The TCP connection can be closed by either peer. When the client half-closes the
data stream, the proxy will set the FIN bit on its connection to the TCP server.
When the proxy receives a packet with the FIN bit set, it will half-close the
corresponding data stream. TCP connections which remain half-closed in a single
direction are not invalid, but are often handled poorly by servers, so clients
SHOULD NOT half-close connections on which they are still expecting data.A TCP connection error is signaled with RST_STREAM. A proxy treats any error in
the TCP connection, which includes receiving a TCP segment with the RST bit set,
as a stream error of type HTTP_CONNECT_ERROR ().
Correspondingly, a proxy MUST send a TCP segment with the RST bit set if it
detects an error with the stream or the QUIC connection.HTTP/QUIC uses the priority scheme described in Section 5.3. In
this priority scheme, a given stream can be designated as dependent upon another
stream, which expresses the preference that the latter stream (the “parent”
stream) be allocated resources before the former stream (the “dependent”
stream). Taken together, the dependencies across all streams in a connection
form a dependency tree. The structure of the dependency tree changes as PRIORITY
frames add, remove, or change the dependency links between streams.For consistency’s sake, all PRIORITY frames MUST refer to the message control
stream of the dependent request, not the data stream.HTTP/QUIC supports server push as described in . During connection
establishment, the client indicates whether it is willing to receive server
pushes via the SETTINGS_DISABLE_PUSH setting in the SETTINGS frame (see
), which defaults to 1 (true).As with server push for HTTP/2, the server initiates a server push by sending a
PUSH_PROMISE frame containing the StreamID of the stream to be pushed, as well
as request header fields attributed to the request. The PUSH_PROMISE frame is
sent on the control stream of the associated (client-initiated) request, while
the Promised Stream ID field specifies the Stream ID of the control stream for
the server-initiated request.The server push response is conveyed in the same way as a non-server-push
response, with response headers and (if present) trailers carried by HEADERS
frames sent on the control stream, and response body (if any) sent via the
corresponding data stream.Frames are used only on the connection (stream 3) and message (streams 5, 9,
etc.) control streams. Other streams carry data payload and are not framed at
the HTTP layer.This section describes HTTP framing in QUIC and highlights some differences from
HTTP/2 framing. For more detail on differences from HTTP/2, see .All frames have the following format:The HEADERS frame (type=0x1) is used to carry part of a header set, compressed
using HPACK .One flag is defined:
This frame concludes a header block.A HEADERS frame with any other flags set MUST be treated as a connection error
of type HTTP_MALFORMED_HEADERS.The HEADERS frame payload has the following fields:
Present only on the first frame of a header block sequence. This MUST
be set to zero on the first header block sequence, and incremented on
each header block.The next frame on the same stream after a HEADERS frame without the EHB flag set
MUST be another HEADERS frame. A receiver MUST treat the receipt of any other
type of frame as a stream error of type HTTP_INTERRUPTED_HEADERS. (Note that
QUIC can intersperse data from other streams between frames, or even during
transmission of frames, so multiplexing is not blocked by this requirement.)A full header block is contained in a sequence of zero or more HEADERS frames
without EHB set, followed by a HEADERS frame with EHB set.On receipt, header blocks (HEADERS, PUSH_PROMISE) MUST be processed by the HPACK
decoder in sequence. If a block is missing, all subsequent HPACK frames MUST be
held until it arrives, or the connection terminated.When the Sequence counter reaches its maximum value (0xFFFF), the next increment
returns it to zero. An endpoint MUST NOT wrap the Sequence counter to zero
until the previous zero-value header block has been confirmed received.The PRIORITY (type=0x02) frame specifies the sender-advised priority of a stream
and is substantially different from . In order to support ordering,
it MUST be sent only on the connection control stream. The format has been
modified to accommodate not being sent on-stream and the larger stream ID space
of QUIC.The semantics of the Stream Dependency, Weight, and E flag are the same as in
HTTP/2.The flags defined are:
Indicates that the stream dependency is exclusive (see Section
5.3).The HEADERS frame payload has the following fields:
A 32-bit stream identifier for the message control stream whose priority is
being updated.
A 32-bit stream identifier for the stream that this stream depends on (see
and {!RFC7540}} Section 5.3).
An unsigned 8-bit integer representing a priority weight for the stream (see
Section 5.3). Add one to the value to obtain a weight between 1
and 256.A PRIORITY frame MUST have a payload length of nine octets. A PRIORITY frame
of any other length MUST be treated as a connection error of type
HTTP_MALFORMED_PRIORITY.The SETTINGS frame (type=0x4) conveys configuration parameters that affect how
endpoints communicate, such as preferences and constraints on peer behavior, and
is substantially different from . Individually, a SETTINGS parameter
can also be referred to as a “setting”.SETTINGS parameters are not negotiated; they describe characteristics of the
sending peer, which can be used by the receiving peer. However, a negotiation
can be implied by the use of SETTINGS – a peer uses SETTINGS to advertise a set
of supported values. The recipient can then choose which entries from this list
are also acceptable and proceed with the value it has chosen. (This choice could
be announced in a field of an extension frame, or in its own value in SETTINGS.)Different values for the same parameter can be advertised by each peer. For
example, a client might permit a very large HPACK state table while a server
chooses to use a small one to conserve memory.Parameters MUST NOT occur more than once. A receiver MAY treat the presence of
the same parameter more than once as a connection error of type
HTTP_MALFORMED_SETTINGS.The SETTINGS frame defines no flags.The payload of a SETTINGS frame consists of zero or more parameters, each
consisting of an unsigned 16-bit setting identifier and a length-prefixed binary
value.A zero-length content indicates that the setting value is a Boolean and true.
False is indicated by the absence of the setting.Non-zero-length values MUST be compared against the remaining length of the
SETTINGS frame. Any value which purports to cross the end of the frame MUST
cause the SETTINGS frame to be considered malformed and trigger a connection
error of type HTTP_MALFORMED_SETTINGS.An implementation MUST ignore the contents for any SETTINGS identifier it does
not understand.SETTINGS frames always apply to a connection, never a single stream. A SETTINGS
frame MUST be sent as the first frame of the connection control stream (see
) by each peer, and MUST NOT be sent subsequently or on any
other stream. If an endpoint receives an SETTINGS frame on a different stream,
the endpoint MUST respond with a connection error of type
HTTP_SETTINGS_ON_WRONG_STREAM. If an endpoint receives a second SETTINGS frame,
the endpoint MUST respond with a connection error of type
HTTP_MULTIPLE_SETTINGS.The SETTINGS frame affects connection state. A badly formed or incomplete
SETTINGS frame MUST be treated as a connection error (Section 5.4.1) of type
HTTP_MALFORMED_SETTINGS.Settings which are integers are transmitted in network byte order. Leading
zero octets are permitted, but implementations SHOULD use only as many bytes as
are needed to represent the value. An integer MUST NOT be represented in more
bytes than would be used to transfer the maximum permitted value.The following settings are defined in HTTP/QUIC:
An integer with a maximum value of 2^32 - 1.
Transmitted as a Boolean; replaces SETTINGS_ENABLE_PUSH
An integer with a maximum value of 2^32 - 1.When a 0-RTT QUIC connection is being used, the client’s initial requests will
be sent before the arrival of the server’s SETTINGS frame. Clients SHOULD
cache at least the following settings about servers:SETTINGS_HEADER_TABLE_SIZESETTINGS_MAX_HEADER_LIST_SIZEClients MUST comply with cached settings until the server’s current settings are
received. If a client does not have cached values, it SHOULD assume the
following values:SETTINGS_HEADER_TABLE_SIZE: 0 octetsSETTINGS_MAX_HEADER_LIST_SIZE: 16,384 octetsServers MAY continue processing data from clients which exceed its current
configuration during the initial flight. In this case, the client MUST apply
the new settings immediately upon receipt.If the connection is closed because these or other constraints were violated
during the 0-RTT flight (e.g. with HTTP_HPACK_DECOMPRESSION_FAILED), clients MAY
establish a new connection and retry any 0-RTT requests using the settings sent
by the server on the closed connection. (This assumes that only requests that
are safe to retry are sent in 0-RTT.) If the connection was closed before the
SETTINGS frame was received, clients SHOULD discard any cached values and use
the defaults above on the next connection.The PUSH_PROMISE frame (type=0x05) is used to carry a request header set from
server to client, as in HTTP/2. It defines no flags.The payload consists of:
A 32-bit Stream ID indicating the QUIC stream on which the response headers
will be sent. (The response body stream is implied by the headers stream,
as defined in .)
A sixteen-bit counter, equivalent to the Sequence field in HEADERS
HPACK-compressed request headers for the promised response.QUIC allows the application to abruptly terminate individual streams or the
entire connection when an error is encountered. These are referred to as
“stream errors” or “connection errors” and are described in more detail in
.HTTP/QUIC requires that only data streams be terminated abruptly. Terminating a
message control stream will result in an error of type HTTP_RST_CONTROL_STREAM.This section describes HTTP-specific error codes which can be used to express
the cause of a connection or stream error.QUIC allocates error codes 0x0000-0x3FFF to application protocol definition.
The following error codes are defined by HTTP for use in QUIC RST_STREAM,
GOAWAY, and CONNECTION_CLOSE frames.
The server has attempted to push content which the client will not accept
on this connection.
An internal error has occurred in the HTTP stack.
The server has attempted to push content which the client has cached.
The client no longer needs the requested data.
HPACK failed to decompress a frame and cannot continue.
The connection established in response to a CONNECT request was reset or
abnormally closed.
The endpoint detected that its peer is exhibiting a behavior that might be
generating excessive load.
The requested operation cannot be served over HTTP/QUIC. The peer should
retry over HTTP/2.
A HEADERS frame has been received with an invalid format.
A PRIORITY frame has been received with an invalid format.
A SETTINGS frame has been received with an invalid format.
A PUSH_PROMISE frame has been received with an invalid format.
A HEADERS frame without the End Header Block flag was followed by a frame
other than HEADERS.
A SETTINGS frame was received on a request control stream.
More than one SETTINGS frame was received.
A message control stream closed abruptly.HTTP/QUIC is strongly informed by HTTP/2, and bears many similarities. This
section points out important differences from HTTP/2 and describes how to map
HTTP/2 extensions into HTTP/QUIC.Many framing concepts from HTTP/2 can be elided away on QUIC, because the
transport deals with them. Because frames are already on a stream, they can omit
the stream number. Because frames do not block multiplexing (QUIC’s multiplexing
occurs below this layer), the support for variable-maximum-length packets can be
removed. Because stream termination is handled by QUIC, an END_STREAM flag is
not required.Frame payloads are largely drawn from . However, QUIC includes many
features (e.g. flow control) which are also present in HTTP/2. In these cases,
the HTTP mapping does not re-implement them. As a result, several HTTP/2 frame
types are not required in HTTP/QUIC. Where an HTTP/2-defined frame is no longer
used, the frame ID has been reserved in order to maximize portability between
HTTP/2 and HTTP/QUIC implementations. However, even equivalent frames between
the two mappings are not identical.Many of the differences arise from the fact that HTTP/2 provides an absolute
ordering between frames across all streams, while QUIC provides this guarantee
on each stream only. As a result, if a frame type makes assumptions that frames
from different streams will still be received in the order sent, HTTP/QUIC will
break them.For example, implicit in the HTTP/2 prioritization scheme is the notion of
in-order delivery of priority changes (i.e., dependency tree mutations): since
operations on the dependency tree such as reparenting a subtree are not
commutative, both sender and receiver must apply them in the same order to
ensure that both sides have a consistent view of the stream dependency tree.
HTTP/2 specifies priority assignments in PRIORITY frames and (optionally) in
HEADERS frames. To achieve in-order delivery of priority changes in HTTP/QUIC,
PRIORITY frames are sent on the connection control stream and the PRIORITY
section is removed from the HEADERS frame.Other than this issue, frame type HTTP/2 extensions are typically portable to
QUIC simply by replacing Stream 0 in HTTP/2 with Stream 3 in HTTP/QUIC.Below is a listing of how each HTTP/2 frame type is mapped:
Instead of DATA frames, HTTP/QUIC uses a separate data stream. See
.
As described above, the PRIORITY region of HEADERS is not supported. A
separate PRIORITY frame MUST be used. Padding is not defined in HTTP/QUIC
frames. See .
As described above, the PRIORITY frame is sent on the connection control
stream. See .
RST_STREAM frames do not exist, since QUIC provides stream lifecycle
management.
SETTINGS frames are sent only at the beginning of the connection. See
and .
See .
PING frames do not exist, since QUIC provides equivalent functionality.
GOAWAY frames do not exist, since QUIC provides equivalent functionality.
WINDOW_UPDATE frames do not exist, since QUIC provides flow control.
CONTINUATION frames do not exist; instead, larger HEADERS/PUSH_PROMISE
frames than HTTP/2 are permitted, and HEADERS frames can be used in series.The IANA registry of frame types has been updated in to include
references to the definition for each frame type in HTTP/2 and in HTTP/QUIC.
Frames not defined as available in HTTP/QUIC SHOULD NOT be sent and SHOULD be
ignored as unknown on receipt.An important difference from HTTP/2 is that settings are sent once, at the
beginning of the connection, and thereafter cannot change. This eliminates
many corner cases around synchronization of changes.Some transport-level options that HTTP/2 specifies via the SETTINGS frame are
superseded by QUIC transport parameters in HTTP/QUIC. The HTTP-level options
that are retained in HTTP/QUIC have the same value as in HTTP/2.Below is a listing of how each HTTP/2 SETTINGS parameter is mapped:
See .
See SETTINGS_DISABLE_PUSH in .
QUIC requires the maximum number of incoming streams per connection to be
specified in the initial transport handshake. Specifying
SETTINGS_MAX_CONCURRENT_STREAMS in the SETTINGS frame is an error.
QUIC requires both stream and connection flow control window sizes to be
specified in the initial transport handshake. Specifying
SETTINGS_INITIAL_WINDOW_SIZE in the SETTINGS frame is an error.
This setting has no equivalent in HTTP/QUIC. Specifying it in the SETTINGS
frame is an error.
See .Settings defined by extensions to HTTP/2 MAY be expressed as integers with a
maximum value of 2^32-1, if they are applicable to HTTP/QUIC, but SHOULD have a
specification describing their usage. Fields for this purpose have been added
to the IANA registry in .QUIC has the same concepts of “stream” and “connection” errors that HTTP/2
provides. However, because the error code space is shared between multiple
components, there is no direct portability of HTTP/2 error codes.The HTTP/2 error codes defined in Section 7 of map to QUIC error
codes as follows:
QUIC_NO_ERROR
No single mapping. See new HTTP_MALFORMED_* error codes defined in
.
HTTP_INTERNAL_ERROR in .
Not applicable, since QUIC handles flow control. Would provoke a
QUIC_FLOW_CONTROL_RECEIVED_TOO_MUCH_DATA from the QUIC layer.
Not applicable, since no acknowledgement of SETTINGS is defined.
Not applicable, since QUIC handles stream management. Would provoke a
QUIC_STREAM_DATA_AFTER_TERMINATION from the QUIC layer.
No single mapping. See new error codes defined in .
Not applicable, since QUIC handles stream management. Would provoke a
QUIC_TOO_MANY_OPEN_STREAMS from the QUIC layer.
HTTP_REQUEST_CANCELLED in .
HTTP_HPACK_DECOMPRESSION_FAILED in .
HTTP_CONNECT_ERROR in .
HTTP_EXCESSIVE_LOAD in .
Not applicable, since QUIC is assumed to provide sufficient security on all
connections.
HTTP_VERSION_FALLBACK in .Error codes defined by HTTP/2 extensions need to be re-registered for HTTP/QUIC
if still applicable. See .The security considerations of HTTP over QUIC should be comparable to those of
HTTP/2.The modified SETTINGS format contains nested length elements, which could pose
a security risk to an uncautious implementer. A SETTINGS frame parser MUST
ensure that the length of the frame exactly matches the length of the settings
it contains.This document creates a new registration for the identification of HTTP/QUIC in
the “Application Layer Protocol Negotiation (ALPN) Protocol IDs” registry
established in .The “hq” string identifies HTTP/QUIC:
HTTP over QUIC
0x68 0x71 (“hq”)
This documentThis document creates a new registration for version-negotiation hints in the
“Hypertext Transfer Protocol (HTTP) Alt-Svc Parameter” registry established in
.
“quic”
This document, This document adds two new columns to the “HTTP/2 Frame Type” registry defined
in :
Indicates which associated protocols use the frame type. Values MUST be one
of:
“HTTP/2 only”“HTTP/QUIC only”“Both”
Indicates where this frame’s behavior over QUIC is defined; required
if the frame is supported over QUIC.Values for existing registrations are assigned by this document:Frame TypeSupported ProtocolsHTTP/QUIC SpecificationDATAHTTP/2 onlyN/AHEADERSBothPRIORITYBothRST_STREAMHTTP/2 onlyN/ASETTINGSBothPUSH_PROMISEBothPINGHTTP/2 onlyN/AGOAWAYHTTP/2 onlyN/AWINDOW_UPDATEHTTP/2 onlyN/ACONTINUATIONHTTP/2 onlyN/AThe “Specification” column is renamed to “HTTP/2 specification” and is only
required if the frame is supported over HTTP/2.This document adds two new columns to the “HTTP/2 Settings” registry defined
in :
Indicates which associated protocols use the setting. Values MUST be one
of:
“HTTP/2 only”“HTTP/QUIC only”“Both”
Indicates where this setting’s behavior over QUIC is defined; required
if the frame is supported over QUIC.Values for existing registrations are assigned by this document:Setting NameSupported ProtocolsHTTP/QUIC SpecificationHEADER_TABLE_SIZEBothENABLE_PUSH / DISABLE_PUSHBothMAX_CONCURRENT_STREAMSHTTP/2 OnlyN/AINITIAL_WINDOW_SIZEHTTP/2 OnlyN/AMAX_FRAME_SIZEHTTP/2 OnlyN/AMAX_HEADER_LIST_SIZEBothThe “Specification” column is renamed to “HTTP/2 Specification” and is only
required if the setting is supported over HTTP/2.This document establishes a registry for HTTP/QUIC error codes. The
“HTTP/QUIC Error Code” registry manages a 30-bit space. The “HTTP/QUIC
Error Code” registry operates under the “Expert Review” policy
.Registrations for error codes are required to include a description
of the error code. An expert reviewer is advised to examine new
registrations for possible duplication with existing error codes.
Use of existing registrations is to be encouraged, but not mandated.New registrations are advised to provide the following information:
A name for the error code. Specifying an error code name is optional.
The 30-bit error code value.
A brief description of the error code semantics, longer if no detailed
specification is provided.
An optional reference for a specification that defines the error code.The entries in the following table are registered by this document.NameCodeDescriptionSpecificationHTTP_PUSH_REFUSED0x01Client refused pushed contentHTTP_INTERNAL_ERROR0x02Internal errorHTTP_PUSH_ALREADY_IN_CACHE0x03Pushed content already cachedHTTP_REQUEST_CANCELLED0x04Data no longer neededHTTP_HPACK_DECOMPRESSION_FAILED0x05HPACK cannot continueHTTP_CONNECT_ERROR0x06TCP reset or error on CONNECT requestHTTP_EXCESSIVE_LOAD0x07Peer generating excessive loadHTTP_VERSION_FALLBACK0x08Retry over HTTP/2HTTP_MALFORMED_HEADERS0x09Invalid HEADERS frameHTTP_MALFORMED_PRIORITY0x0AInvalid PRIORITY frameHTTP_MALFORMED_SETTINGS0x0BInvalid SETTINGS frameHTTP_MALFORMED_PUSH_PROMISE0x0CInvalid PUSH_PROMISE frameHTTP_INTERRUPTED_HEADERS0x0EIncomplete HEADERS blockHTTP_SETTINGS_ON_WRONG_STREAM0x0FSETTINGS frame on a request control streamHTTP_MULTIPLE_SETTINGS0x10Multiple SETTINGS framesHTTP_RST_CONTROL_STREAM0x11Message control stream was RSTQUIC: A UDP-Based Multiplexed and Secure TransportGoogleMozillaHypertext Transfer Protocol Version 2 (HTTP/2)This specification describes an optimized expression of the semantics of the Hypertext Transfer Protocol (HTTP), referred to as HTTP version 2 (HTTP/2). HTTP/2 enables a more efficient use of network resources and a reduced perception of latency by introducing header field compression and allowing multiple concurrent exchanges on the same connection. It also introduces unsolicited push of representations from servers to clients.This specification is an alternative to, but does not obsolete, the HTTP/1.1 message syntax. HTTP's existing semantics remain unchanged.Key words for use in RFCs to Indicate Requirement LevelsIn many standards track documents several words are used to signify the requirements in the specification. These words are often capitalized. This document defines these words as they should be interpreted in IETF documents. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements.HTTP Alternative ServicesThis document specifies "Alternative Services" for HTTP, which allow an origin's resources to be authoritatively available at a separate network location, possibly accessed with a different protocol configuration.Hypertext Transfer Protocol (HTTP/1.1): Message Syntax and RoutingThe Hypertext Transfer Protocol (HTTP) is a stateless application-level protocol for distributed, collaborative, hypertext information systems. This document provides an overview of HTTP architecture and its associated terminology, defines the "http" and "https" Uniform Resource Identifier (URI) schemes, defines the HTTP/1.1 message syntax and parsing requirements, and describes related security concerns for implementations.Hypertext Transfer Protocol (HTTP/1.1): Semantics and ContentThe Hypertext Transfer Protocol (HTTP) is a stateless \%application- level protocol for distributed, collaborative, hypertext information systems. This document defines the semantics of HTTP/1.1 messages, as expressed by request methods, request header fields, response status codes, and response header fields, along with the payload of messages (metadata and body content) and mechanisms for content negotiation.HPACK: Header Compression for HTTP/2This specification defines HPACK, a compression format for efficiently representing HTTP header fields, to be used in HTTP/2.Transmission Control ProtocolTransport Layer Security (TLS) Application-Layer Protocol Negotiation ExtensionThis document describes a Transport Layer Security (TLS) extension for application-layer protocol negotiation within the TLS handshake. For instances in which multiple application protocols are supported on the same TCP or UDP port, this extension allows the application layer to negotiate which protocol will be used within the TLS connection.Guidelines for Writing an IANA Considerations Section in RFCsMany protocols make use of identifiers consisting of constants and other well-known values. Even after a protocol has been defined and deployment has begun, new values may need to be assigned (e.g., for a new option type in DHCP, or a new encryption or authentication transform for IPsec). To ensure that such quantities have consistent values and interpretations across all implementations, their assignment must be administered by a central authority. For IETF protocols, that role is provided by the Internet Assigned Numbers Authority (IANA).In order for IANA to manage a given namespace prudently, it needs guidelines describing the conditions under which new values can be assigned or when modifications to existing values can be made. If IANA is expected to play a role in the management of a namespace, IANA must be given clear and concise instructions describing that role. This document discusses issues that should be considered in formulating a policy for assigning values to a namespace and provides guidelines for authors on the specific text that must be included in documents that place demands on IANA.This document obsoletes RFC 2434. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements.The original authors of this specification were Robbie Shade and Mike Warres.RFC Editor’s Note: Please remove this section prior to publication of a
final version of this document.SETTINGS changes (#181): SETTINGS can be sent only once at the start of a connection;
no changes thereafterSETTINGS_ACK removedSettings can only occur in the SETTINGS frame a single timeBoolean format updatedAlt-Svc parameter changed from “v” to “quic”; format updated (#229)Closing the connection control stream or any message control stream is a
fatal error (#176)HPACK Sequence counter can wrap (#173)0-RTT guidance addedGuide to differences from HTTP/2 and porting HTTP/2 extensions added
(#127,#242)Changed “HTTP/2-over-QUIC” to “HTTP/QUIC” throughout (#11,#29)Changed from using HTTP/2 framing within Stream 3 to new framing format and
two-stream-per-request model (#71,#72,#73)Adopted SETTINGS format from draft-bishop-httpbis-extended-settings-01Reworked SETTINGS_ACK to account for indeterminate inter-stream order (#75)Described CONNECT pseudo-method (#95)Updated ALPN token and Alt-Svc guidance (#13,#87)Application-layer-defined error codes (#19,#74)Adopted as base for draft-ietf-quic-http.Updated authors/editors list.