HTTPbis Working GroupR. Peon
Internet-DraftGoogle, Inc
Intended status: InformationalH. Ruellan
Expires: February 22, 2014Canon CRF
August 21, 2013

HPACK

Abstract

This document describes HPACK, a format adapted to efficiently represent HTTP headers in the context of HTTP/2.0.

Status of This Memo

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This Internet-Draft will expire on February 22, 2014.

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1. Introduction

This document describes HPACK, a format adapted to efficiently represent HTTP headers in the context of HTTP/2.0.

2. Overview

In HTTP/1.X, HTTP headers, which are necessary for the functioning of the protocol, are transmitted with no transformations. Unfortunately, the amount of redundancy in both the keys and the values of these headers is high, and is the cause of increased latency on lower bandwidth links. This indicates that an alternate more compact encoding for headers would be beneficial to latency, and that is what is proposed here.

As shown by SPDY [SPDY], Deflate compresses HTTP very effectively. However, the use of a compression scheme which allows for arbitrary matches against the previously encoded data (such as Deflate) exposes users to security issues. In particular, the compression of sensitive data, together with other data controlled by an attacker, may lead to leakage of that sensitive data, even when the resultant bytes are transmitted over an encrypted channel.

Another consideration is that processing and memory costs of a compressor such as Deflate may also be too high for some classes of devices, for example when doing forward or reverse proxying.

2.1. Outline

The HTTP header encoding described in this document is based on a header table that map (name, value) pairs to index values. This scheme is believed to be safe for all known attacks against the compression context today. Header tables are incrementally updated during the HTTP/2.0 session.

The encoder is responsible for deciding which headers to insert as new entries in the header table. The decoder then does exactly what the encoder prescribes, ending in a state that exactly matches the encoder's state. This enables decoders to remain simple and understand a wide variety of encoders.

As two consecutive sets of headers often have headers in common, each set of headers is coded as a difference from the previous set of headers. The goal is to only encode the changes (headers present in one of the set and not in the other) between the two sets of headers.

An example illustrating the use of these different mechanisms to represent headers is available in Appendix C.

3. Header Encoding

3.1. Encoding Concepts

The encoding and decoding of headers relies on some components and concepts. The set of components used form an encoding context.

Header Table:
The header table (see Section 3.1.2) is a component used to associate headers to index values.
Reference Set:
The reference set (see Section 3.1.3) is a component containing a group of headers used as a reference for the differential encoding of a new set of headers.
Header Set:
A header set (see Section 3.1.4) is a group of headers that are encoded jointly. A complete set of key-value pairs as encoded in an HTTP request or response is a header set.
Header Representation:
A header can be represented in encoded form either as a literal or as an index (see Section 3.1.5). The indexed representation is based on the header table.
Header Emission:
When decoding a set of headers, some operations emit a header (see Section 3.1.6). An emitted header is added to the set of headers. Once emitted, a header can't be removed from the set of headers.

3.1.1. Encoding Context

The set of components used to encode or decode a header set form an encoding context: an encoding context contains a header table and a reference set.

Using HTTP, messages are exchanged between a client and a server in both direction. To keep the encoding of headers in each direction independent from the other direction, there is one encoding context for each direction.

The headers contained in a PUSH_PROMISE frame sent by a server to a client are encoded within the same context as the headers contained in the HEADERS frame corresponding to a response sent from the server to the client.

3.1.2. Header Table

A header table consists of an ordered list of (name, value) pairs. The first entry of a header table is assigned the index 0.

A header can be represented by an entry of the header table if they match. A header and an entry match if both their name and their value match. A header name and an entry name match if they are equal using a character-based, case insensitive comparison (the case insensitive comparison is used because HTTP header names are defined in a case insensitive way). A header value and an entry value match if they are equal using a character-based, case sensitive comparison.

Generally, the header table will not contain duplicate entries. However, implementations MUST be prepared to accept duplicates without signalling an error.

Initially, a header table contains a list of common headers. Two initial lists of header are provided in Appendix B. One list is for headers transmitted from a client to a server, the other for the reverse direction.

A header table is modified by either adding a new entry at the end of the table, or by replacing an existing entry.

The encoder decides how to update the header table and as such can control how much memory is used by the header table. To limit the memory requirements on the decoder side, the header table size is bounded (see the SETTINGS_MAX_BUFFER_SIZE in Section 5).

The size of an entry is the sum of its name's length in bytes (as defined in Section 4.1.2), of its value's length in bytes (Section 4.1.3) and of 32 bytes. The 32 bytes are an accounting for the entry structure overhead. For example, an entry structure using two 64-bits pointers to reference the name and the value and the entry, and two 64-bits integer for counting the number of references to these name and value would use 32 bytes.

The size of a header table is the sum of the size of its entries.

3.1.3. Reference Set

A reference set is defined as an unordered set of references to entries of the header table.

The initial reference set is the empty set.

The reference set is updated during the processing of a set of headers.

Using the differential encoding, a header that is not present in the reference set can be encoded either with an indexed representation (if the header is present in the header table), or with a literal representation (if the header is not present in the header table).

A header that is to be removed from the reference set is encoded with an indexed representation.

3.1.4. Header set

A header set is a group of header fields that are encoded as a whole. Each header field is a (name, value) pair.

A header set is encoded using an ordered list of zero or more header representations. All the header representations describing a header set a grouped into a header block.

3.1.5. Header Representation

A header can be represented either as a literal or as an index.

Literal Representation:
A literal representation defines a new header. The header name is represented either literally or as a reference to an entry of the header table. The header value is represented literally.
Three different literal representations are provided:
  • A literal representation that does not add the header to the header table (see Section 4.3.1).
  • A literal representation that adds the header at the end of the header table (see Section 4.3.2).
  • A literal representation that uses the header to replace an existing entry of the header table (see Section 4.3.3).
Indexed Representation:
The indexed representation defines a header as a reference in the header table (see Section 4.2).

3.1.6. Header Emission

The emission of header is the process of adding a header to the current set of headers. Once an header is emitted, it can't be removed from the current set of headers.

The concept of header emission allows a decoder to know when it can pass a header safely to a higher level on the receiver side. This allows a decoder to be implemented in a streaming way, and as such to only keep in memory the header table and the reference set. With such an implementation, the amount of memory used by the decoder is bounded, even in presence of a very large set of headers. The management of memory for handling very large sets of headers can therefore be deferred to the application, which may be able to emit the header to the wire and thus free up memory quickly.

3.2. Header Set Processing

The processing of an encoded header set to obtain a list of headers is defined in this section. To ensure a correct decoding of a header set, a decoder MUST obey the following rules.

3.2.1. Header Representation Processing

All the header representations contained in a header block are processed in the order in which they are presented, as specified below.

An indexed representation corresponding to an entry not present in the reference set entails the following actions:

  • The header corresponding to the entry is emitted.
  • The entry is added to the reference set.

An indexed representation corresponding to an entry present in the reference set entails the following actions:

  • The entry is removed from the reference set.

A literal representation that is not added to the header table entails the following action:

  • The header is emitted.

A literal representation that is added to the header table entails the following actions:

  • The header is emitted.
  • The header is added to the header table, at the location defined by the representation.
  • The new entry is added to the reference set.

3.2.2. Reference Set Emission

Once all the representations contained in a header block have been processed, the headers that are in common with the previous header set are emitted, during the reference set emission.

For the reference set emission, each header contained in the reference set that has not been emitted during the processing of the header block is emitted.

3.2.3. Header Set Completion

Once all of the header representations have been processed, and the remaining items in the reference set have been emitted, the header set is complete.

3.2.4. Header Table Management

The header table can be modified by either adding a new entry to it or by replacing an existing one. Before doing such a modification, it has to be ensured that the header table size will stay lower than or equal to the SETTINGS_MAX_BUFFER_SIZE limit (see Section 5). To achieve this, repeatedly, the first entry of the header table is removed, until enough space is available for the modification.

A consequence of removing one or more entries at the beginning of the header table is that the remaining entries are renumbered. The first entry of the header table is always associated to the index 0.

When the modification of the header table is the replacement of an existing entry, the replaced entry is the one indicated in the literal representation before any entry is removed from the header table. If the entry to be replaced is removed from the header table when performing the size adjustment, the replacement entry is inserted at the beginning of the header table.

The addition of a new entry with a size greater than the SETTINGS_MAX_BUFFER_SIZE limit causes all the entries from the header table to be dropped and the new entry not to be added to the header table. The replacement of an existing entry with a new entry with a size greater than the SETTINGS_MAX_BUFFER_SIZE has the same consequences.

3.2.5. Specific Use Cases

Three occurrences of the same indexed representation, corresponding to an entry not present in the reference set, emit the associated header twice:

  • The first occurrence emits the header a first time and adds the corresponding entry to the reference set.
  • The second occurrence removes the header's entry from the reference set.
  • The third occurrence emits the header a second time and adds again its entry to the reference set.

This allows for headers sets which include duplicate header entries to be encoded efficiently and faithfully.

The first occurrence of the indexed representation can be replaced by a literal representation creating an entry for the header.

4. Detailed Format

4.1. Low-level representations

4.1.1. Integer representation

Integers are used to represent name indexes, pair indexes or string lengths. To allow for optimized processing, an integer representation always finishes at the end of a byte.

An integer is represented in two parts: a prefix that fills the current byte and an optional list of bytes that are used if the integer value does not fit in the prefix. The number of bits of the prefix (called N) is a parameter of the integer representation.

The N-bit prefix allows filling the current byte. If the value is small enough (strictly less than 2^N-1), it is encoded within the N-bit prefix. Otherwise all the bits of the prefix are set to 1 and the value is encoded using an unsigned variable length integer representation.

The algorithm to represent an integer I is as follows:

If I < 2^N - 1, encode I on N bits
Else
    encode 2^N - 1 on N bits
    While I >= 128
         Encode (I % 128 + 128) on 8 bits
         I = I / 128
    encode (I) on 8 bits
                        
4.1.1.1. Example 1: Encoding 10 using a 5-bit prefix

The value 10 is to be encoded with a 5-bit prefix.

  • 10 is less than 31 (= 2^5 - 1) and is represented using the 5-bit prefix.
  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| X | X | X | 0 | 1 | 0 | 1 | 0 |   10 stored on 5 bits
+---+---+---+---+---+---+---+---+
4.1.1.2. Example 2: Encoding 1337 using a 5-bit prefix

The value I=1337 is to be encoded with a 5-bit prefix.

  • 1337 is greater than 31 (= 2^5 - 1).
    • The 5-bit prefix is filled with its max value (31).
  • I = 1337 - (2^5 - 1) = 1306.
    • I (1306) is greater than or equal to 128, the while loop body executes:
      • I % 128 == 26
      • 26 + 128 == 154
      • 154 is encoded in 8 bits as: 10011010
      • I is set to 10 (1306 / 128 == 10)
      • I is no longer greater than or equal to 128, the while loop terminates.
    • I, now 10, is encoded on 8 bits as: 00001010
  • The process ends.
  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| X | X | X | 1 | 1 | 1 | 1 | 1 |   Prefix = 31, I = 1306
| 1 | 0 | 0 | 1 | 1 | 0 | 1 | 0 |   1306>=128, encode(154), I = 1306/128
| 0 | 0 | 0 | 0 | 1 | 0 | 1 | 0 |   10<128, encode(10), done
+---+---+---+---+---+---+---+---+

4.1.2. Header Name Representation

Header names are sequences of ASCII characters that MUST conform to the following header-name ABNF construction:

  LOWERALPHA = %x61-7A
  header-char = "!" / "#" / "$" / "%" / "&" / "'" /
                "*" / "+" / "-" / "." / "^" / "_" /
                "`" / "|" / "~" / DIGIT / LOWERALPHA
  header-name = [":"] 1*header-char
                  

They are encoded in two parts:

  1. The length of the text, defined as the number of octets of storage required to store the text, represented as a variable-length-quantity (Section 4.1.1).
  2. The specific sequence of ASCII octets

4.1.3. Header Value Representation

Header values are encoded as sequences of UTF-8 encoded text. They are encoded in two parts:

  1. The length of the text, defined as the number of octets of storage required to store the text, represented as a variable-length-quantity (Section 4.1.1).
  2. The specific sequence of octets representing the UTF-8 text.

Invalid UTF-8 octet sequences, "over-long" UTF-8 encodings, and UTF-8 octets that represent invalid Unicode Codepoints MUST NOT be used.

4.2. Indexed Header Representation

  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 1 |        Index (7+)         |
+---+---------------------------+

Figure 1: Indexed Header

This representation starts with the '1' 1-bit pattern, followed by the index of the matching pair, represented as an integer with a 7-bit prefix.

4.3. Literal Header Representation

4.3.1. Literal Header without Indexing

  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 0 | 1 | 1 |    Index (5+)     |
+---+---+---+-------------------+
|       Value Length (8+)       |
+-------------------------------+
| Value String (Length octets)  |
+-------------------------------+

Figure 2: Literal Header without Indexing - Indexed Name

  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 0 | 1 | 1 |         0         |
+---+---+---+-------------------+
|       Name Length (8+)        |
+-------------------------------+
|  Name String (Length octets)  |
+-------------------------------+
|       Value Length (8+)       |
+-------------------------------+
| Value String (Length octets)  |
+-------------------------------+

Figure 3: Literal Header without Indexing - New Name

This representation, which does not involve updating the header table, starts with the '011' 3-bit pattern.

If the header name matches the header name of a (name, value) pair stored in the Header Table, the index of the pair increased by one (index + 1) is represented as an integer with a 5-bit prefix. Note that if the index is strictly below 31, one byte is used.

If the header name does not match a header name entry, the value 0 is represented on 5 bits followed by the header name (Section 4.1.2).

Header name representation is followed by the header value represented as a literal string as described in Section 4.1.3.

4.3.2. Literal Header with Incremental Indexing

  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 0 | 1 | 0 |    Index (5+)     |
+---+---+---+-------------------+
|       Value Length (8+)       |
+-------------------------------+
| Value String (Length octets)  |
+-------------------------------+

Figure 4: Literal Header with Incremental Indexing - Indexed Name

  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 0 | 1 | 0 |         0         |
+---+---+---+-------------------+
|       Name Length (8+)        |
+-------------------------------+
|  Name String (Length octets)  |
+-------------------------------+
|       Value Length (8+)       |
+-------------------------------+
| Value String (Length octets)  |
+-------------------------------+

Figure 5: Literal Header with Incremental Indexing - New Name

This representation starts with the '010' 3-bit pattern.

If the header name matches the header name of a (name, value) pair stored in the Header Table, the index of the pair increased by one (index + 1) is represented as an integer with a 5-bit prefix. Note that if the index is strictly below 31, one byte is used.

If the header name does not match a header name entry, the value 0 is represented on 5 bits followed by the header name (Section 4.1.2).

Header name representation is followed by the header value represented as a literal string as described in Section 4.1.3.

4.3.3. Literal Header with Substitution Indexing

  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 0 | 0 |      Index (6+)       |
+---+---+-----------------------+
|    Substituted Index (8+)     |
+-------------------------------+
|       Value Length (8+)       |
+-------------------------------+
| Value String (Length octets)  |
+-------------------------------+

Figure 6: Literal Header with Substitution Indexing - Indexed Name

  0   1   2   3   4   5   6   7
+---+---+---+---+---+---+---+---+
| 0 | 0 |           0           |
+---+---+-----------------------+
|       Name Length (8+)        |
+-------------------------------+
|  Name String (Length octets)  |
+-------------------------------+
|    Substituted Index (8+)     |
+-------------------------------+
|       Value Length (8+)       |
+-------------------------------+
| Value String (Length octets)  |
+-------------------------------+

Figure 7: Literal Header with Substitution Indexing - New Name

This representation starts with the '00' 2-bit pattern.

If the header name matches the header name of a (name, value) pair stored in the Header Table, the index of the pair increased by one (index + 1) is represented as an integer with a 6-bit prefix. Note that if the index is strictly below 62, one byte is used.

If the header name does not match a header name entry, the value 0 is represented on 6 bits followed by the header name (Section 4.1.2).

The index of the substituted (name, value) pair is inserted after the header name representation as a 0-bit prefix integer.

The index of the substituted pair MUST correspond to a position in the header table containing a non-void entry. An index for the substituted pair that corresponds to empty position in the header table MUST be treated as an error.

This index is followed by the header value represented as a literal string as described in Section 4.1.3.

5. Parameter Negotiation

A few parameters can be used to accommodate client and server processing and memory requirements. [rfc.comment.1: These settings are currently not supported as they have not been integrated in the main specification. Therefore, the maximum buffer size for the header table is fixed at 4096 bytes.]

SETTINGS_MAX_BUFFER_SIZE:
Allows the sender to inform the remote endpoint of the maximum size it accepts for the header table.
The default value is 4096 bytes.
[rfc.comment.2: Is this default value OK? Do we need a maximum size? Do we want to allow infinite buffer?]
When the remote endpoint receives a SETTINGS frame containing a SETTINGS_MAX_BUFFER_SIZE setting with a value smaller than the one currently in use, it MUST send as soon as possible a HEADER frame with a stream identifier of 0x0 containing a value smaller than or equal to the received setting value.
[rfc.comment.3: This changes slightly the behaviour of the HEADERS frame, which should be updated as follows:]
A HEADER frame with a stream identifier of 0x0 indicates that the sender has reduced the maximum size of the header table. The new maximum size of the header table is encoded on 32-bit. The decoder MUST reduce its own header table by dropping entries from it until the size of the header table is lower than or equal to the transmitted maximum size.

6. Security Considerations

This compressor exists to solve security issues present in stream compressors such as DEFLATE whereby the compression context can be efficiently probed to reveal secrets. A conformant implementation of this specification should be fairly safe against that kind of attack, as the reaping of any information from the compression context requires more work than guessing and verifying the plaintext data directly with the server. As with any secret, however, the longer the length of the secret, the more difficult the secret is to guess. It is inadvisable to have short cookies that are relied upon to remain secret for any duration of time.

A proper security-conscious implementation will also need to prevent timing attacks by ensuring that the amount of time it takes to do string comparisons is always a function of the total length of the strings, and not a function of the number of matched characters.

Another common security problem is when the remote endpoint successfully causes the local endpoint to exhaust its memory. This compressor attempts to deal with the most obvious ways that this could occur by limiting both the peak and the steady-state amount of memory consumed in the compressor state, by providing ways for the application to consume/flush the emitted headers in small chunks, and by considering overhead in the state size calculation. Implementors must still be careful in the creation of APIs to an implementation of this compressor by ensuring that header keys and values are either emitted as a stream, or that the compression implementation have a limit on the maximum size of a key or value. Failure to implement these kinds of safeguards may still result in a scenario where the local endpoint exhausts its memory.

7. IANA Considerations

This memo includes no request to IANA.

8. Informative References

[SPDY]
Belshe, M. and R. Peon, “SPDY Protocol”, February 2012, <http://tools.ietf.org/html/draft-mbelshe-httpbis-spdy>.

Appendix A. Change Log (to be removed by RFC Editor before publication

A.1. Since draft-ietf-httpbis-header-compression-01

  • Refactored of Header Encoding Section: split definitions and processing rule.
  • Backward incompatible change: Updated reference set management as per issue #214. This changes how the interaction between the reference set and eviction works. This also changes the working of the reference set in some specific cases.
  • Backward incompatible change: modified initial header list, as per issue #188.
  • Added example of 32 bytes entry structure (issue #191).
  • Added Header Set Completion section. Reflowed some text. Clarified some writing which was akward. Added text about duplicate header entry encoding. Clarified some language w.r.t Header Set. Changed x-my-header to mynewheader. Added text in the HeaderEmission section indicating that the application may also be able to free up memory more quickly. Added information in Security Considerations section.

Appendix B. Initial Header Tables

[rfc.comment.4: The tables in this section should be updated based on statistical analysis of header names frequency and specific HTTP 2.0 header rules (like removal of some headers).]
[rfc.comment.5: These tables are not adapted for headers contained in PUSH_PROMISE frames. Either the tables can be merged, or the table for responses can be updated.]

B.1. Requests

The following table lists the pre-defined headers that make-up the initial header table user to represent requests sent from a client to a server.

Table 1: Initial Header Table for Requests
IndexHeader NameHeader Value
0:schemehttp
1:schemehttps
2:host
3:path/
4:methodGET
5accept
6accept-charset
7accept-encoding
8accept-language
9cookie
10if-modified-since
11user-agent
12referer
13authorization
14allow
15cache-control
16connection
17content-length
18content-type
19date
20expect
21from
22if-match
23if-none-match
24if-range
25if-unmodified-since
26max-forwards
27proxy-authorization
28range
29via

B.2. Responses

The following table lists the pre-defined headers that make-up the initial header table used to represent responses sent from a server to a client. The same header table is also used to represent request headers sent from a server to a client in a PUSH_PROMISE frame.

Table 2: Initial Header Table for Responses
IndexHeader NameHeader Value
0:status200
1age
2cache-control
3content-length
4content-type
5date
6etag
7expires
8last-modified
9server
10set-cookie
11vary
12via
13access-control-allow-origin
14accept-ranges
15allow
16connection
17content-disposition
18content-encoding
19content-language
20content-location
21content-range
22link
23location
24proxy-authenticate
25refresh
26retry-after
27strict-transport-security
28transfer-encoding
29www-authenticate

Appendix C. Example

Here is an example that illustrates different representations and how tables are updated. [rfc.comment.6: This section needs to be updated to better reflect the new processing of header fields, and include more examples.]

C.1. First header set

The first header set to represent is the following:

:path: /my-example/index.html
user-agent: my-user-agent
mynewheader: first

The header table is empty, all headers are represented as literal headers with indexing. The 'mynewheader' header name is not in the header name table and is encoded literally. This gives the following representation:

0x44      (literal header with incremental indexing, name index = 3)
0x16      (header value string length = 22)
/my-example/index.html
0x4D      (literal header with incremental indexing, name index = 12)
0x0D      (header value string length = 13)
my-user-agent
0x40      (literal header with incremental indexing, new name)
0x0B      (header name string length = 11)
mynewheader
0x05      (header value string length = 5)
first

The header table is as follows after the processing of these headers:

Header table
+---------+----------------+---------------------------+
|  Index  | Header Name    | Header Value              |
+---------+----------------+---------------------------+
|    0    | :scheme        | http                      |
+---------+----------------+---------------------------+
|    1    | :scheme        | https                     |
+---------+----------------+---------------------------+
|   ...   | ...            | ...                       |
+---------+----------------+---------------------------+
|   37    | warning        |                           |
+---------+----------------+---------------------------+
|   38    | :path          | /my-example/index.html    | added header
+---------+----------------+---------------------------+
|   39    | user-agent     | my-user-agent             | added header
+---------+----------------+---------------------------+
|   40    | mynewheader    | first                     | added header
+---------+----------------+---------------------------+

As all the headers in the first header set are indexed in the header table, all are kept in the reference set of headers, which is:

Reference Set:
:path, /my-example/index.html
user-agent, my-user-agent
mynewheader, first

C.2. Second header set

The second header set to represent is the following:

:path: /my-example/resources/script.js
user-agent: my-user-agent
mynewheader: second

Comparing this second header set to the reference set, the first and third headers are from the reference set are not present in this second header set and must be removed. In addition, in this new set, the first and third headers have to be encoded. The path header is represented as a literal header with substitution indexing. The mynewheader will be represented as a literal header with incremental indexing.

0xa6       (indexed header, index = 38: removal from reference set)
0xa8       (indexed header, index = 40: removal from reference set)
0x04       (literal header, substitution indexing, name index = 3)
0x26       (replaced entry index = 38)
0x1f       (header value string length = 31)
/my-example/resources/script.js
0x5f 0x0a  (literal header, incremental indexing, name index = 40)
0x06       (header value string length = 6)
second

The header table is updated as follow:

Header table
+---------+----------------+---------------------------+
|  Index  | Header Name    | Header Value              |
+---------+----------------+---------------------------+
|    0    | :scheme        | http                      |
+---------+----------------+---------------------------+
|    1    | :scheme        | https                     |
+---------+----------------+---------------------------+
|   ...   | ...            | ...                       |
+---------+----------------+---------------------------+
|   37    | warning        |                           |
+---------+----------------+---------------------------+
|   38    | :path          | /my-example/resources/    | replaced
|         |                |     script.js             | header
+---------+----------------+---------------------------+
|   39    | user-agent     | my-user-agent             |
+---------+----------------+---------------------------+
|   40    | mynewheader    | first                     |
+---------+----------------+---------------------------+
|   41    | mynewheader    | second                    | added header
+---------+----------------+---------------------------+

All the headers in this second header set are indexed in the header table, therefore, all are kept in the reference set of headers, which becomes:

Reference Set:
:path, /my-example/resources/script.js
user-agent, my-user-agent
mynewheader, second

Authors' Addresses

Roberto Peon
Google, Inc
Email: fenix@google.com
Hervé Ruellan
Canon CRF
Email: herve.ruellan@crf.canon.fr