QPACK: Header Compression for HTTP over QUICNetflixckrasic@netflix.comAkamai Technologiesmbishop@evequefou.beFacebookafrind@fb.com
Transport
QUICThis specification defines QPACK, a compression format for efficiently
representing HTTP header fields, to be used in HTTP/QUIC. This is a variation of
HPACK header compression that seeks to reduce head-of-line blocking.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/-qpack.The QUIC transport protocol was designed from the outset to support HTTP
semantics, and its design subsumes many of the features of HTTP/2. HTTP/2 uses
HPACK () for header compression, but QUIC’s stream multiplexing
comes into some conflict with HPACK. A key goal of the design of QUIC is to
improve stream multiplexing relative to HTTP/2 by reducing head-of-line
blocking. If HPACK were used for HTTP/QUIC, it would induce head-of-line
blocking due to built-in assumptions of a total ordering across frames on all
streams.QUIC is described in . The HTTP/QUIC mapping is described in
. For a full description of HTTP/2, see . The
description of HPACK is .QPACK reuses core concepts from HPACK, but is redesigned to allow correctness in
the presence of out-of-order delivery, with flexibility for implementations to
balance between resilience against head-of-line blocking and optimal compression
ratio. The design goals are to closely approach the compression ratio of HPACK
with substantially less head-of-line blocking under the same loss conditions.QPACK preserves the ordering of header fields within each header list. An
encoder MUST emit header field representations in the order they appear in the
input header list. A decoder MUST must emit header fields in the order their
representations appear in the input header block.Like HPACK, QPACK uses two tables for associating header fields to indices. The
static table (see ) is predefined and contains common header
fields (some of them with an empty value). The dynamic table (see
) is built up over the course of the connection and can be used
by the encoder to index header fields repeated in the encoded header lists.Unlike in HPACK, entries in the QPACK static and dynamic tables are addressed
separately. The following sections describe how entries in each table are
addressed.The static table consists of a predefined static list of header fields, each of
which has a fixed index over time. Its entries are defined in .A decoder that encounters an invalid static table index on a request stream or
push stream MUST treat this as a stream error of type
HTTP_QPACK_DECOMPRESSION_FAILED. If this index is received on the encoder
stream, this MUST be treated as a connection error of type
HTTP_QPACK_ENCODER_STREAM_ERROR.The dynamic table consists of a list of header fields maintained in first-in,
first-out order. The dynamic table is initially empty. Entries are added by
instructions on the encoder stream (see ).The maximum size of the dynamic table can be modified by the encoder, subject to
a decoder-controlled limit (see and ). The
initial maximum size is determined by the corresponding setting when HTTP
requests or responses are first permitted to be sent. For clients using 0-RTT
data in HTTP/QUIC, the table size is the remembered value of the setting, even
if the server later specifies a larger maximum in its SETTINGS frame. For
HTTP/QUIC servers and HTTP/QUIC clients when 0-RTT is not attempted or is
rejected, the initial maximum table size is the value of the setting in the
peer’s SETTINGS frame.Before a new entry is added to the dynamic table, entries are evicted from the
end of the dynamic table until the size of the dynamic table is less than or
equal to (maximum size - new entry size) or until the table is empty. The
encoder MUST NOT evict a dynamic table entry unless it has first been
acknowledged by the decoder.If the size of the new entry is less than or equal to the maximum size, that
entry is added to the table. It is an error to attempt to add an entry that is
larger than the maximum size; this MUST be treated as a connection error of type
HTTP_QPACK_ENCODER_STREAM_ERROR.A new entry can reference an entry in the dynamic table that will be evicted
when adding this new entry into the dynamic table. Implementations are
cautioned to avoid deleting the referenced name if the referenced entry is
evicted from the dynamic table prior to inserting the new entry.The dynamic table can contain duplicate entries (i.e., entries with the same
name and same value). Therefore, duplicate entries MUST NOT be treated as an
error by a decoder.The encoder decides how to update the dynamic table and as such can control how
much memory is used by the dynamic table. To limit the memory requirements of
the decoder, the dynamic table size is strictly bounded.The decoder determines the maximum size that the encoder is permitted to use for
the dynamic table. In HTTP/QUIC, this value is determined by the
SETTINGS_HEADER_TABLE_SIZE setting (see ).An encoder can choose to use less capacity than this maximum size (see
), but the chosen size MUST stay lower than or equal to the
maximum set by the decoder. Whenever the maximum size for the dynamic table is
reduced, entries are evicted from the end of the dynamic table until the size of
the dynamic table is less than or equal to the maximum size.This mechanism can be used to completely clear entries from the dynamic table by
setting a maximum size of 0, which can subsequently be restored.The size of the dynamic table is the sum of the size of its entries.The size of an entry is the sum of its name’s length in octets (as defined in
), its value’s length in octets, and 32.The size of an entry is calculated using the length of its name and value
without any Huffman encoding applied.MaxEntries is the maximum number of entries that the dynamic table can have.
The smallest entry has empty name and value strings and has the size of 32.
The MaxEntries is calculated asMaxTableSize is the maximum size of the dynamic table as specified by the
decoder (see ).Each entry possesses both an absolute index which is fixed for the lifetime of
that entry and a relative index which changes over time based on the context of
the reference. The first entry inserted has an absolute index of “1”; indices
increase sequentially with each insertion.The relative index begins at zero and increases in the opposite direction from
the absolute index. Determining which entry has a relative index of “0” depends
on the context of the reference.On the encoder stream, a relative index of “0” always refers to the most
recently inserted value in the dynamic table. Note that this means the entry
referenced by a given relative index will change while interpreting instructions
on the encoder stream.Because frames from request streams can be delivered out of order with
instructions on the encoder stream, relative indices are relative to the Base
Index at the beginning of the header block (see ). The Base
Index is an absolute index. When interpreting the rest of the frame, the entry
identified by Base Index has a relative index of zero. The relative indices of
entries do not change while interpreting headers on a request or push stream.A header block on the request stream can reference entries added after the entry
identified by the Base Index. This allows an encoder to process a header block
in a single pass and include references to entries added while processing this
(or other) header blocks. Newly added entries are referenced using Post-Base
instructions. Indices for Post-Base instructions increase in the same direction
as absolute indices, but the zero value is one higher than the Base Index.If the decoder encounters a reference on a request or push stream to a dynamic
table entry which has already been dropped or which has an absolute index
greater than the declared Largest Reference (see ), it MUST
treat this as a stream error of type HTTP_QPACK_DECOMPRESSION_FAILED.If the decoder encounters a reference on the encoder stream to a dynamic table
entry which has already been dropped, it MUST treat this as a connection error
of type HTTP_QPACK_ENCODER_STREAM_ERROR.Because QUIC does not guarantee order between data on different streams, a
header block might reference an entry in the dynamic table that has not yet been
received.Each header block contains a Largest Reference which identifies the table state
necessary for decoding. If the greatest absolute index in the dynamic table is
less than the value of the Largest Reference, the stream is considered
“blocked.” While blocked, header field data should remain in the blocked
stream’s flow control window. When the Largest Reference is zero, the frame
contains no references to the dynamic table and can always be processed
immediately. A stream becomes unblocked when the greatest absolute index in the
dynamic table becomes greater than or equal to the Largest Reference for all
header blocks the decoder has started reading from the stream. If a decoder
encounters a header block where the actual largest reference is not equal to the
Largest Reference declared in the prefix, it MAY treat this as a stream error of
type HTTP_QPACK_DECOMPRESSION_FAILED.A decoder can permit the possibility of blocked streams by setting
SETTINGS_QPACK_BLOCKED_STREAMS to a non-zero value (see ).
This setting specifies an upper bound on the number of streams which can be
blocked.An encoder can decide whether to risk having a stream become blocked. If
permitted by the value of SETTINGS_QPACK_BLOCKED_STREAMS, compression efficiency
can be improved by referencing dynamic table entries that are still in transit,
but if there is loss or reordering the stream can become blocked at the decoder.
An encoder avoids the risk of blocking by only referencing dynamic table entries
which have been acknowledged, but this means using literals. Since literals make
the header block larger, this can result in the encoder becoming blocked on
congestion or flow control limits.An encoder MUST limit the number of streams which could become blocked to the
value of SETTINGS_QPACK_BLOCKED_STREAMS at all times. Note that the decoder
might not actually become blocked on every stream which risks becoming blocked.
If the decoder encounters more blocked streams than it promised to support, it
MUST treat this as a stream error of type HTTP_QPACK_DECOMPRESSION_FAILED.The decoder stream () signals key events at the
decoder that permit the encoder to track the decoder’s state. These events are:Complete processing of a header blockAbandonment of a stream which might have remaining header blocksReceipt of new dynamic table entriesRegardless of whether a header block contained blocking references, the
knowledge that it has been processed permits the encoder to evict
entries to which no unacknowledged references remain; see .
When a stream is reset or abandoned, the indication that these header blocks
will never be processed serves a similar function; see .For the encoder to identify which dynamic table entries can be safely used
without a stream becoming blocked, the encoder tracks the absolute index of the
decoder’s Largest Known Received entry.When blocking references are permitted, the encoder uses acknowledgement of
header blocks to identify the Largest Known Received index, as described in
.To acknowledge dynamic table entries which are not referenced by header blocks,
for example because the encoder or the decoder have chosen not to risk blocked
streams, the decoder sends a Table State Synchronize instruction (see
).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
when, and only when, they appear in all capitals, as shown here.Definitions of terms that are used in this document:
A name-value pair sent as part of an HTTP message.
The ordered collection of header fields associated with an HTTP message. A
header list can contain multiple header fields with the same name. It can
also contain duplicate header fields.
The compressed representation of a header list.
An implementation which transforms a header list into a header block.
An implementation which transforms a header block into a header list.QPACK is a name, not an acronym.Diagrams use the format described in Section 3.1 of , with the
following additional conventions:
Indicates that x is A bits long
Indicates that x uses the prefixed integer encoding defined in Section 5.1 of
, beginning with an A-bit prefix.
Indicates that x is variable-length and extends to the end of the region.QPACK defines two settings which are included in the HTTP/QUIC SETTINGS frame.
An integer with a maximum value of 2^30 - 1. The default value is 4,096
bytes. See for usage.
An integer with a maximum value of 2^16 - 1. The default value is 100. See
.QPACK instructions occur in three locations, each of which uses a separate
instruction space:The encoder stream is a unidirectional stream of type 0x48 (ASCII ‘H’)
which carries table updates from encoder to decoder. Instructions on this
stream modify the dynamic table state without generating output to any
particular request.The decoder stream is a unidirectional stream of type 0x68 (ASCII ‘h’)
which carries acknowledgements of table modifications and header processing
from decoder to encoder.Finally, the contents of HEADERS and PUSH_PROMISE frames on request streams
and push streams reference the QPACK table state.There MUST be exactly one of each unidirectional stream type in each direction.
Receipt of a second instance of either stream type MUST be treated as a
connection error of HTTP_WRONG_STREAM_COUNT. Closure of either unidirectional
stream MUST be treated as a connection error of type
HTTP_CLOSED_CRITICAL_STREAM.This section describes the instructions which are possible on each stream type.All table updates occur on the encoder stream. Request streams and push streams
only carry header blocks that do not modify the state of the table.The prefixed integer from Section 5.1 of is used heavily throughout
this document. The format from is used unmodified. QPACK
implementations MUST be able to decode integers up to 62 bits long.The string literal defined by Section 5.2 of is also used throughout.
This string format includes optional Huffman encoding.HPACK defines string literals to begin on a byte boundary. They begin with a
single flag (indicating whether the string is Huffman-coded), followed by the
Length encoded as a 7-bit prefix integer, and finally Length octets of data.
When Huffman encoding is enabled, the Huffman table from Appendix B of
is used without modification.This document expands the definition of string literals and permits them to
begin other than on a byte boundary. An “N-bit prefix string literal” begins
with the same Huffman flag, followed by the length encoded as an (N-1)-bit
prefix integer. The remainder of the string literal is unmodified.A string literal without a prefix length noted is an 8-bit prefix string literal
and follows the definitions in without modification.Table updates can add a table entry, possibly using existing entries to avoid
transmitting redundant information. The name can be transmitted as a reference
to an existing entry in the static or the dynamic table or as a string literal.
For entries which already exist in the dynamic table, the full entry can also be
used by reference, creating a duplicate entry.The contents of the encoder stream are an unframed sequence of the following
instructions.An addition to the header table where the header field name matches the header
field name of an entry stored in the static table or the dynamic table starts
with the ‘1’ one-bit pattern. The S bit indicates whether the reference is to
the static (S=1) or dynamic (S=0) table. The 6-bit prefix integer (see Section
5.1 of ) that follows is used to locate the table entry for the header
name. When S=1, the number represents the static table index; when S=0, the
number is the relative index of the entry in the dynamic table.The header name reference is followed by the header field value represented as a
string literal (see Section 5.2 of ).An addition to the header table where both the header field name and the header
field value are represented as string literals (see ) starts with
the ‘01’ two-bit pattern.The name is represented as a 6-bit prefix string literal, while the value is
represented as an 8-bit prefix string literal.Duplication of an existing entry in the dynamic table starts with the ‘000’
three-bit pattern. The relative index of the existing entry is represented as
an integer with a 5-bit prefix.The existing entry is re-inserted into the dynamic table without resending
either the name or the value. This is useful to mitigate the eviction of older
entries which are frequently referenced, both to avoid the need to resend the
header and to avoid the entry in the table blocking the ability to insert new
headers.An encoder informs the decoder of a change to the size of the dynamic table
using an instruction which begins with the ‘001’ three-bit pattern. The new
maximum table size is represented as an integer with a 5-bit prefix (see Section
5.1 of ).The new maximum size MUST be lower than or equal to the limit determined by the
protocol using QPACK. A value that exceeds this limit MUST be treated as a
connection error of type HTTP_QPACK_ENCODER_STREAM_ERROR. In HTTP/QUIC, this
limit is the value of the SETTINGS_HEADER_TABLE_SIZE parameter (see
) received from the decoder.Reducing the maximum size of the dynamic table can cause entries to be evicted
(see Section 4.3 of ). This MUST NOT cause the eviction of entries
with outstanding references (see ). Changing the size of
the dynamic table is not acknowledged as this instruction does not insert an
entry.The decoder stream carries information used to ensure consistency of the dynamic
table. Information is sent from the QPACK decoder to the QPACK encoder; that is,
the server informs the client about the processing of the client’s header blocks
and table updates, and the client informs the server about the processing of the
server’s header blocks and table updates.The contents of the decoder stream are an unframed sequence of the following
instructions.The Table State Synchronize instruction begins with the ‘00’ two-bit pattern.
The instruction specifies the total number of dynamic table inserts and
duplications since the last Table State Synchronize or Header Acknowledgement
that increased the Largest Known Received dynamic table entry. This is encoded
as a 6-bit prefix integer. The encoder uses this value to determine which table
entries might cause a stream to become blocked, as described in
.An encoder that receives an Insert Count equal to zero or one that increases
Largest Known Received beyond what the encoder has sent MUST treat this as a
connection error of type HTTP_QPACK_DECODER_STREAM_ERROR.A decoder chooses when to emit Table State Synchronize instructions. Emitting a
Table State Synchronize after adding each new dynamic table entry will provide
the most timely feedback to the encoder, but could be redundant with other
decoder feedback. By delaying a Table State Synchronize, a decoder might be able
to coalesce multiple Table State Synchronize instructions, or replace them
entirely with Header Acknowledgements. However, delaying too long may lead to
compression inefficiencies if the encoder waits for an entry to be acknowledged
before using it.After processing a header block whose declared Largest Reference is not zero,
the decoder emits a Header Acknowledgement instruction on the decoder stream.
The instruction begins with the ‘1’ one-bit pattern and includes the request
stream’s stream ID, encoded as a 7-bit prefix integer. It is used by the
peer’s QPACK encoder to know when it is safe to evict an entry.The same Stream ID can be identified multiple times, as multiple header blocks
can be sent on a single stream in the case of intermediate responses, trailers,
and pushed requests. Since header frames on each stream are received and
processed in order, this gives the encoder precise feedback on which header
blocks within a stream have been fully processed.If an encoder receives a Header Acknowledgement instruction referring to a
stream on which every header block with a non-zero Largest Reference has already
been acknowledged, that MUST be treated as a connection error of type
HTTP_QPACK_DECODER_STREAM_ERROR.When blocking references are permitted, the encoder uses acknowledgement of
header blocks to update the Largest Known Received index. If a header block was
potentially blocking, the acknowledgement implies that the decoder has received
all dynamic table state necessary to process the header block. If the Largest
Reference of an acknowledged header block was greater than the encoder’s current
Largest Known Received index, the block’s Largest Reference becomes the new
Largest Known Received.A stream that is reset might have multiple outstanding header blocks with
dynamic table references. A decoder that receives a stream reset before the end
of a stream generates a Stream Cancellation instruction on the decoder stream.
Similarly, a decoder that abandons reading of a stream needs to signal this
using the Stream Cancellation instruction. This signals to the encoder that all
references to the dynamic table on that stream are no longer outstanding. A
decoder with a maximum dynamic table size equal to zero MAY omit sending Stream
Cancellations, because the encoder cannot have any dynamic table references.An encoder cannot infer from this instruction that any updates to the dynamic
table have been received.The instruction begins with the ‘01’ two-bit pattern. The instruction includes
the stream ID of the affected stream - a request or push stream - encoded as a
6-bit prefix integer.HEADERS and PUSH_PROMISE frames on request and push streams reference the
dynamic table in a particular state without modifying it. Frames on these
streams emit the headers for an HTTP request or response.Header data is prefixed with two integers, Largest Reference and Base Index.Largest Reference identifies the largest absolute dynamic index referenced in
the block. Blocking decoders use the Largest Reference to determine when it is
safe to process the rest of the block. If Largest Reference is greater than
zero, the encoder transforms it as follows before encoding:The decoder reconstructs the Largest Reference using the following algorithm:TableLargestAbsoluteIndex is the Absolute Index of the most recently inserted
item in the decoder’s dynamic table. This encoding limits the length of the
prefix on long-lived connections.Base Index is used to resolve references in the dynamic table as described in
.To save space, Base Index is encoded relative to Largest Reference using a
one-bit sign and the Delta Base Index value. A sign bit of 0 indicates that
the Base Index has an absolute index that is greater than or equal to the
Largest Reference; the value of Delta Base Index is added to the Largest
Reference to determine the absolute value of the Base Index. A sign bit of 1
indicates that the Base Index is less than the Largest Reference. That is:A single-pass encoder is expected to determine the absolute value of Base Index
before encoding a header block. If the encoder inserted entries in the dynamic
table while encoding the header block, Largest Reference will be greater than
Base Index, so the encoded difference is negative and the sign bit is set to 1.
If the header block did not reference the most recent entry in the table and did
not insert any new entries, Base Index will be greater than the Largest
Reference, so the delta will be positive and the sign bit is set to 0.An encoder that produces table updates before encoding a header block might set
Largest Reference and Base Index to the same value. When Largest Reference and
Base Index are equal, the Delta Base Index is encoded with a zero sign bit. A
sign bit set to 1 when the Delta Base Index is 0 MUST be treated as a decoder
error.A header block that does not reference the dynamic table can use any value for
Base Index; setting both Largest Reference and Base Index to zero is the most
efficient encoding.An indexed header field representation identifies an entry in either the static
table or the dynamic table and causes that header field to be added to the
decoded header list, as described in Section 3.2 of .If the entry is in the static table, or in the dynamic table with an absolute
index less than or equal to Base Index, this representation starts with the ‘1’
1-bit pattern, followed by the S bit indicating whether the reference is into
the static (S=1) or dynamic (S=0) table. Finally, the relative index of the
matching header field is represented as an integer with a 6-bit prefix (see
Section 5.1 of ).If the entry is in the dynamic table with an absolute index greater than Base
Index, the representation starts with the ‘0001’ 4-bit pattern, followed by the
post-base index (see ) of the matching header field,
represented as an integer with a 4-bit prefix (see Section 5.1 of ).A literal header field with a name reference represents a header where the
header field name matches the header field name of an entry stored in the static
table or the dynamic table.If the entry is in the static table, or in the dynamic table with an absolute
index less than or equal to Base Index, this representation starts with the ‘01’
two-bit pattern. If the entry is in the dynamic table with an absolute index
greater than Base Index, the representation starts with the ‘0000’ four-bit
pattern.The following bit, ‘N’, indicates whether an intermediary is permitted to add
this header to the dynamic header table on subsequent hops. When the ‘N’ bit is
set, the encoded header MUST always be encoded with a literal representation. In
particular, when a peer sends a header field that it received represented as a
literal header field with the ‘N’ bit set, it MUST use a literal representation
to forward this header field. This bit is intended for protecting header field
values that are not to be put at risk by compressing them (see Section 7.1 of
for more details).For entries in the static table or in the dynamic table with an absolute index
less than or equal to Base Index, the header field name is represented using the
relative index of that entry, which is represented as an integer with a 4-bit
prefix (see Section 5.1 of ). The S bit indicates whether the
reference is to the static (S=1) or dynamic (S=0) table.For entries in the dynamic table with an absolute index greater than Base Index,
the header field name is represented using the post-base index of that entry
(see ) encoded as an integer with a 3-bit prefix.An addition to the header table where both the header field name and the header
field value are represented as string literals (see ) starts with
the ‘001’ three-bit pattern.The fourth bit, ‘N’, indicates whether an intermediary is permitted to add this
header to the dynamic header table on subsequent hops. When the ‘N’ bit is set,
the encoded header MUST always be encoded with a literal representation. In
particular, when a peer sends a header field that it received represented as a
literal header field with the ‘N’ bit set, it MUST use a literal representation
to forward this header field. This bit is intended for protecting header field
values that are not to be put at risk by compressing them (see Section 7.1 of
for more details).The name is represented as a 4-bit prefix string literal, while the value is
represented as an 8-bit prefix string literal.The following error codes are defined for HTTP/QUIC to indicate failures of
QPACK which prevent the stream or connection from continuing:
The decoder failed to interpret an instruction on a request or push stream and
is not able to continue decoding that header block.
HTTP_QPACK_ENCODER_STREAM_ERROR (TBD):The decoder failed to interpret an instruction on the encoder stream.
HTTP_QPACK_DECODER_STREAM_ERROR (TBD):The encoder failed to interpret an instruction on the decoder stream.Upon encountering an error, an implementation MAY elect to treat it as a
connection error even if this document prescribes that it MUST be treated as a
stream error.An encoder making a single pass over a list of headers must choose Base Index
before knowing Largest Reference. When trying to reference a header inserted to
the table after encoding has begun, the entry is encoded with different
instructions that tell the decoder to use an absolute index greater than the
Base Index.Due to out-of-order arrival, QPACK’s eviction algorithm requires changes
(relative to HPACK) to avoid the possibility that an indexed representation is
decoded after the referenced entry has already been evicted. QPACK employs a
two-phase eviction algorithm, in which the encoder will not evict entries that
have outstanding (unacknowledged) references.An encoder MUST ensure that a header block which references a dynamic table
entry is not received by the decoder after the referenced entry has already been
evicted. An encoder also respects the limit set by the decoder on the number of
streams that are allowed to become blocked. Even if the decoder is willing to
tolerate blocked streams, the encoder might choose to avoid them in certain
cases.In order to enable this, the encoder will need to track outstanding
(unacknowledged) header blocks and table updates using feedback received from
the decoder.An encoder MUST NOT insert an entry into the dynamic table (or duplicate an
existing entry) if doing so would evict an entry with unacknowledged references.
For header blocks that might rely on the newly added entry, the encoder can use
a literal representation and maybe insert the entry later.To ensure that the encoder is not prevented from adding new entries, the encoder
can avoid referencing entries that will be evicted soonest. Rather than
reference such an entry, the encoder SHOULD emit a Duplicate instruction (see
), and reference the duplicate instead.Determining which entries are too close to eviction to reference is an encoder
preference. One heuristic is to target a fixed amount of available space in the
dynamic table: either unused space or space that can be reclaimed by evicting
unreferenced entries. To achieve this, the encoder can maintain a draining
index, which is the smallest absolute index in the dynamic table that it will
emit a reference for. As new entries are inserted, the encoder increases the
draining index to maintain the section of the table that it will not
reference. Draining entries - entries with an absolute index lower than the
draining index - will not accumulate new references. The number of
unacknowledged references to draining entries will eventually become zero,
making the entry available for eviction.For header blocks encoded in non-blocking mode, the encoder needs to forego
indexed representations that refer to table updates which have not yet been
acknowledged (see ). Since all table updates are
processed in sequence on the control stream, an index into the dynamic
table is sufficient to track which entries have been acknowledged.To track blocked streams, the necessary Base Index value for each stream can be
used. Whenever the decoder processes a table update, it can begin decoding any
blocked streams that now have their dependencies satisfied.Implementations can speculatively send instructions on the encoder stream
which are not needed for any current HTTP request or response. Such headers
could be used strategically to improve performance. For instance, the encoder
might decide to refresh by sending Duplicate representations for popular
header fields (), ensuring they have small indices and hence
minimal size on the wire.Pseudo-code for single pass encoding, excluding handling of duplicates,
non-blocking mode, and reference tracking.TBD.This document creates two new settings in the “HTTP/QUIC Settings” registry
established in .The entries in the following table are registered by this document.Setting NameCodeSpecificationHEADER_TABLE_SIZE0x1QPACK_BLOCKED_STREAMS0x7This document creates two new settings in the “HTTP/QUIC Stream Type” registry
established in .The entries in the following table are registered by this document.Stream TypeCodeSpecificationSenderQPACK Encoder Stream0x48BothQPACK Decoder Stream0x68BothThis document establishes the following new error codes in the “HTTP/QUIC Error
Code” registry established in .NameCodeDescriptionSpecificationHTTP_QPACK_DECOMPRESSION_FAILEDTBDDecompression of a header block failedHTTP_QPACK_ENCODER_STREAM_ERRORTBDError on the encoder streamHTTP_QPACK_DECODER_STREAM_ERRORTBDError on the decoder streamHypertext Transfer Protocol (HTTP) over QUICAkamai TechnologiesQUIC: A UDP-Based Multiplexed and Secure TransportFastlyMozillaHPACK: Header Compression for HTTP/2This specification defines HPACK, a compression format for efficiently representing HTTP header fields, to be used in HTTP/2.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.Ambiguity of Uppercase vs Lowercase in RFC 2119 Key WordsRFC 2119 specifies common key words that may be used in protocol specifications. This document aims to reduce the ambiguity by clarifying that only UPPERCASE usage of the key words have the defined special meanings.Hypertext 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.Guide for Internet Standards WritersThis document is a guide for Internet standard writers. It defines those characteristics that make standards coherent, unambiguous, and easy to interpret. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements.IndexNameValue0:authority1:path/2age03content-disposition4content-length05cookie6date7etag8if-modified-since9if-none-match10last-modified11link12location13referer14set-cookie15:methodCONNECT16:methodDELETE17:methodGET18:methodHEAD19:methodOPTIONS20:methodPOST21:methodPUT22:schemehttp23:schemehttps24:status10325:status20026:status30427:status40428:status50329accept*/*30acceptapplication/dns-message31accept-encodinggzip, deflate, br32accept-rangesbytes33access-control-allow-headerscache-control34access-control-allow-headerscontent-type35access-control-allow-origin*36cache-controlmax-age=037cache-controlmax-age=259200038cache-controlmax-age=60480039cache-controlno-cache40cache-controlno-store41cache-controlpublic, max-age=3153600042content-encodingbr43content-encodinggzip44content-typeapplication/dns-message45content-typeapplication/javascript46content-typeapplication/json47content-typeapplication/x-www-form-urlencoded48content-typeimage/gif49content-typeimage/jpeg50content-typeimage/png51content-typetext/css52content-typetext/html; charset=utf-853content-typetext/plain54content-typetext/plain;charset=utf-855rangebytes=0-56strict-transport-securitymax-age=3153600057strict-transport-securitymax-age=31536000; includesubdomains58strict-transport-securitymax-age=31536000; includesubdomains; preload59varyaccept-encoding60varyorigin61x-content-type-optionsnosniff62x-xss-protection1; mode=block63:status10064:status20465:status20666:status30267:status40068:status40369:status42170:status42571:status50072accept-language73access-control-allow-credentialsFALSE74access-control-allow-credentialsTRUE75access-control-allow-headers*76access-control-allow-methodsget77access-control-allow-methodsget, post, options78access-control-allow-methodsoptions79access-control-expose-headerscontent-length80access-control-request-headerscontent-type81access-control-request-methodget82access-control-request-methodpost83alt-svcclear84authorization85content-security-policyscript-src ‘none’; object-src ‘none’; base-uri ‘none’86early-data187expect-ct88forwarded89if-range90origin91purposeprefetch92server93timing-allow-origin*94upgrade-insecure-requests195user-agent96x-forwarded-for97x-frame-optionsdeny98x-frame-optionssameoriginRFC Editor’s Note: Please remove this section prior to publication of a
final version of this document.Largest Reference encoded modulo MaxEntries (#1763)New Static Table (#1355)Table Size Update with Insert Count=0 is a connection error (#1762)Stream Cancellations are optional when SETTINGS_HEADER_TABLE_SIZE=0 (#1761)Implementations must handle 62 bit integers (#1760)Different error types for each QPACK stream, other changes to error
handling (#1726)Preserve header field order (#1725)Initial table size is the maximum permitted when table is first usable (#1642)Only header blocks that reference the dynamic table are acknowledged (#1603,
#1605)Renumbered instructions for consistency (#1471, #1472)Decoder is allowed to validate largest reference (#1404, #1469)Header block acknowledgments also acknowledge the associated largest reference
(#1370, #1400)Added an acknowledgment for unread streams (#1371, #1400)Removed framing from encoder stream (#1361,#1467)Control streams use typed unidirectional streams rather than fixed stream IDs
(#910,#1359)Separate instruction sets for table updates and header blocks (#1235, #1142,
#1141)Reworked indexing scheme (#1176, #1145, #1136, #1130, #1125, #1314)Added mechanisms that support one-pass encoding (#1138, #1320)Added a setting to control the number of blocked decoders (#238, #1140, #1143)Moved table updates and acknowledgments to dedicated streams (#1121, #1122,
#1238)This draft draws heavily on the text of . The indirect input of
those authors is gratefully acknowledged, as well as ideas from:Ryan HamiltonPatrick McManusKazuho OkuBiren RoyIan SwettDmitri TikhonovBuck’s contribution was supported by Google during his employment there.A substantial portion of Mike’s contribution was supported by Microsoft during
his employment there.