HTTP Working GroupP. Meenan, Editor
Internet-DraftY. Weiss, Editor
Intended status: Standards TrackGoogle LLC
Expires: July 30, 2024January 27, 2024

Compression Dictionary Transport

Abstract

This specification defines a mechanism for using designated HTTP responses as an external dictionary for future HTTP responses for compression schemes that support using external dictionaries (e.g., Brotli (RFC 7932) and Zstandard (RFC 8878)).

About This Document

This note is to be removed before publishing as an RFC.

Status information for this document may be found at <https://datatracker.ietf.org/doc/draft-ietf-httpbis-compression-dictionary/>.

Discussion of this document takes place on the HTTP Working Group mailing list (<mailto:ietf-http-wg@w3.org>), which is archived at <https://lists.w3.org/Archives/Public/ietf-http-wg/>. Working Group information can be found at <https://httpwg.org/>.

Source for this draft and an issue tracker can be found at <https://github.com/httpwg/http-extensions/labels/compression-dictionary>.

Status of this Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as “work in progress”.

This Internet-Draft will expire on July 30, 2024.

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1. Introduction

This specification defines a mechanism for using designated [HTTP] responses as an external dictionary for future HTTP responses for compression schemes that support using external dictionaries (e.g., Brotli [RFC7932] and Zstandard [RFC8878]).

This document describes the HTTP headers used for negotiating dictionary usage and registers media types for content encoding Brotli and Zstandard using a negotiated dictionary.

This document uses the line folding strategies described in [FOLDING].


2. Dictionary Negotiation

2.1. Use-As-Dictionary

When responding to a HTTP Request, a server can advertise that the response can be used as a dictionary for future requests for URLs that match the rules specified in the Use-As-Dictionary response header.

The Use-As-Dictionary response header is a Structured Field [STRUCTURED-FIELDS] with values for "match", "match-dest", "id", and "type".

2.1.1. match

The "match" value of the Use-As-Dictionary header is a sf-string value that provides the URLPattern to use for request matching (https://urlpattern.spec.whatwg.org/).

The URLPattern used for matching does not support using Regular expressions.

The following algorithm will return TRUE for a valid match pattern and FALSE for an invalid pattern that MUST NOT be used:

  1. Let MATCH be the value of "match" for the given dictionary.
  2. Let URL be the URL of the dictionary request.
  3. Let PATTERN be a URLPattern constructed by setting input=MATCH, and baseURL=URL (https://urlpattern.spec.whatwg.org/).
  4. If PATTERN has regexp groups then return FALSE (https://urlpattern.spec.whatwg.org/#urlpattern-has-regexp-groups).
  5. Return True.

The "match" value is required and MUST be included in the Use-As-Dictionary sf-dictionary for the dictionary to be considered valid.

2.1.2. match-dest

The "match-dest" value of the Use-As-Dictionary header is a sf-string value that provides a request destination (https://fetch.spec.whatwg.org/#concept-request-destination).

An empty string for "match-dest" MUST match all destinations.

For clients that do not support request destinations or if the value of "match-dest" is a value that is not supported by the client then the client MUST treat it as an empty string and match all destinations.

The "match-dest" value is optional and defaults to the empty string.

2.1.3. id

The "id" value of the Use-As-Dictionary header is a sf-string value that specifies a server identifier for the dictionary. If an "id" value is present then it MUST be sent to the server in a "Dictionary-ID" request header when the dictionary is advertised as being available.

The server identifier MUST be treated as an opaque string by the client.

The server identifier MUST NOT be relied upon by the server to guarantee the contents of the dictionary. The dictionary hash MUST be validated before use.

The "id" value string length (after any decoding) supports up to 1024 characters.

The "id" value is optional.

2.1.4. type

The "type" value of the Use-As-Dictionary header is a sf-string value that describes the file format of the supplied dictionary.

"raw" is the only defined dictionary format which represents an unformatted blob of bytes suitable for any compression scheme to use.

If a client receives a dictionary with a type that it does not understand, it MUST NOT use the dictionary.

The "type" value is optional and defaults to "raw".

2.1.5. Examples

2.1.5.1. Path Prefix

A response that contained a response header:

NOTE: '\' line wrapping per RFC 8792
Use-As-Dictionary: \
  match="/product/*", match-dest="document"

Would specify matching any document request for a URL with a path prefix of /product/ on the same [Origin] as the original request.

2.1.5.2. Versioned Directories

A response that contained a response header:

Use-As-Dictionary: match="/app/*/main.js"

Would match main.js in any directory under /app/ and expiring as a dictionary in one year.

2.2. Available-Dictionary

When a HTTP client makes a request for a resource for which it has an appropriate dictionary, it can add a "Available-Dictionary" request header to the request to indicate to the server that it has a dictionary available to use for compression.

The "Available-Dictionary" request header is a Structured Field [STRUCTURED-FIELDS] sf-binary [SHA-256] hash of the contents of a single available dictionary.

The client MUST only send a single "Available-Dictionary" request header with a single hash value for the best available match that it has available.

For example:

Available-Dictionary: :pZGm1Av0IEBKARczz7exkNYsZb8LzaMrV7J32a2fFG4=:

2.2.1. Dictionary freshness requirement

To be considered as a match, the dictionary resource MUST be either fresh [HTTP-CACHING] or allowed to be served stale (see eg [RFC5861]).

2.2.2. Dictionary URL matching

When a dictionary is stored as a result of a "Use-As-Dictionary" directive, it includes "match" and "match-dest" strings that are used to match an outgoing request from a client to the available dictionaries.

Dictionaries MUST have been served from the same {Origin} as the outgoing request to match.

To see if an outbound request matches a given dictionary, the following algorithm will return TRUE for a successful match and FALSE for no-match:

  1. If the current client supports request destinations:
    • Let DEST be the value of "match-dest" for the given dictionary.
    • Let REQUEST_DEST be the value of the destination for the current request.
    • If DEST is not an empty string and If DEST and REQUEST_DEST are not the same value, return FALSE
  2. Let BASEURL be the URL of the dictionary request.
  3. Let URL represent the URL of the outbound request being checked.
  4. If the {Origin} of BASEURL and the {Origin} of URL are not the same, return FALSE.
  5. Let MATCH be the value of "match" for the given dictionary.
  6. Let PATTERN be a URLPattern constructed by setting input=MATCH, and baseURL=BASEURL (https://urlpattern.spec.whatwg.org/).
  7. Return the result of running the "test" method of PATTERN with input=URL (https://urlpattern.spec.whatwg.org/#ref-for-dom-urlpattern-test)

2.2.3. Multiple matching dictionaries

When there are multiple dictionaries that match a given request URL, the client MUST pick a single dictionary using the following rules: 1. For clients that support request destinations, a dictionary that specifies and matches a "match-dest" takes precedence over a match that does not use a destination. 1. Given equivalent destination precedence, the dictionary with the longest "match" takes precedence. 1. Given equivalent destination and match length precedence, the most recently fetched dictionary takes precedence.

2.3. Dictionary-ID

When a HTTP client makes a request for a resource for which it has an appropriate dictionary and the dictionary was stored with a server-provided "id" in the Use-As-Dictionary response then the client MUST echo the stored "id" in a "Dictionary-ID" request header.

The "Dictionary-ID" request header is a Structured Field [STRUCTURED-FIELDS] sf-string of up to 1024 characters (after any decoding) and MUST be identical to the server-provided "id".

For example:

Available-Dictionary: :pZGm1Av0IEBKARczz7exkNYsZb8LzaMrV7J32a2fFG4=:
Dictionary-ID: "/v1/main.js 33a64df551425fcc55e4d42a148795d9f25f89d4"

2.4. Content-Dictionary

When a HTTP server responds with a resource that is encoded with a dictionary the server MUST send the hash of the dictionary that was used in the "Content-Dictionary" response header.

The "Content-Dictionary" response header is a Structured Field [STRUCTURED-FIELDS] sf-dictionary [SHA-256] hash of the contents of the dictionary that was used to encode the response.

If the HTTP response contains a "Content-Dictionary" response header with the hash of a dictionary that the client does not have available then the client cannot decode or use the HTTP response.

For example:

Content-Dictionary: :pZGm1Av0IEBKARczz7exkNYsZb8LzaMrV7J32a2fFG4=:

3. Negotiating the compression algorithm

When a compression dictionary is available for use for a given request, the algorithm to be used is negotiated through the regular mechanism for negotiating content encoding in HTTP.

This document introduces two new content encoding algorithms:

Content-EncodingDescription
br-dBrotli using an external compression dictionary
zstd-dZstandard using an external compression dictionary

The dictionary to use is negotiated separately and advertised in the "Available-Dictionary" request header.

3.1. Accept-Encoding

The client adds the algorithms that it supports to the "Accept-Encoding" request header. e.g.:

Accept-Encoding: gzip, deflate, br, zstd, br-d, zstd-d

3.2. Content-Encoding

If a server supports one of the dictionary algorithms advertised by the client and chooses to compress the content of the response using the dictionary that the client has advertised then it sets the "Content-Encoding" response header to the appropriate value for the algorithm selected. e.g.:

Content-Encoding: br-d

If the response is cacheable, it MUST include a "Vary" header to prevent caches serving dictionary-compressed resources to clients that don't support them or serving the response compressed with the wrong dictionary:

Vary: accept-encoding, available-dictionary

4. IANA Considerations

4.1. Content Encoding

IANA is asked to update the "HTTP Content Coding Registry" registry ([HTTP]) according to the table below:

NameDescriptionReference
br-dA stream of bytes compressed using the Brotli protocol with an external dictionary[RFC7932]
zstd-dA stream of bytes compressed using the Zstandard protocol with an external dictionary[RFC8878]

4.2. Header Field Registration

IANA is asked to update the "Hypertext Transfer Protocol (HTTP) Field Name Registry" registry ([HTTP]) according to the table below:

Field NameStatusReference
Use-As-DictionarypermanentSection 2.1 of this document
Available-DictionarypermanentSection 2.2 of this document
Dictionary-IDpermanentSection 2.3 of this document
Content-DictionarypermanentSection 2.4 of this document

5. Compatibility Considerations

To minimize the risk of middle-boxes incorrectly processing dictionary-compressed responses, compression dictionary transport MUST only be used in secure contexts (HTTPS).


6. Security Considerations

The security considerations for Brotli [RFC7932] and Zstandard [RFC8878] apply to the dictionary-based versions of the respective algorithms.

6.1. Changing content

The dictionary must be treated with the same security precautions as the content, because a change to the dictionary can result in a change to the decompressed content.

The dictionary is validated using a SHA-256 hash of the content to make sure that the client and server are both using the same dictionary. The strength of the SHA-256 hash algorithm isn't explicitly needed to counter attacks since the dictionary is being served from the same origin as the content. That said, if a weakness is discovered in SHA-256 and it is determined that the dictionary negotiation should use a different hash algorithm, the "Use-As-Dictionary" response header can be extended to specify a different algorithm and the server would just ignore any "Available-Dictionary" requests that do not use the updated hash.

6.2. Reading content

The CRIME attack shows that it's a bad idea to compress data from mixed (e.g. public and private) sources -- the data sources include not only the compressed data but also the dictionaries. For example, if you compress secret cookies using a public-data-only dictionary, you still leak information about the cookies.

Not only can the dictionary reveal information about the compressed data, but vice versa, data compressed with the dictionary can reveal the contents of the dictionary when an adversary can control parts of data to compress and see the compressed size. On the other hand, if the adversary can control the dictionary, the adversary can learn information about the compressed data.

6.3. Security Mitigations

If any of the mitigations do not pass, the client MUST drop the response and return an error.

6.3.1. Cross-origin protection

To make sure that a dictionary can only impact content from the same origin where the dictionary was served, the URLPattern used for matching a dictionary to requests is guaranteed to be for the same origin that the dictionary is served from.

6.3.2. Response readability

For clients, like web browsers, that provide additional protection against the readability of the payload of a response and against user tracking, additional protections MUST be taken to make sure that the use of dictionary-based compression does not reveal information that would not otherwise be available.

In these cases, dictionary compression MUST only be used when both the dictionary and the compressed response are fully readable by the client.

In browser terms, that means that both are either same-origin to the context they are being fetched from or that the response is cross-origin and passes the CORS check (https://fetch.spec.whatwg.org/#cors-check).

6.3.2.1. Same-Origin

On the client-side, same-origin determination is defined in the fetch spec (https://html.spec.whatwg.org/multipage/browsers.html#origin).

On the server-side, a request with a "Sec-Fetch-Site:" request header with a value of "same-origin" is to be considered a same-origin request.

  • For any request that is same-origin:
    • Response MAY be used as a dictionary.
    • Response MAY be compressed by an available dictionary.
6.3.2.2. Cross-Origin

For requests that are not same-origin (Section 6.3.2.1), the "mode" of the request can be used to determine the readability of the response.

For clients that conform to the fetch spec, the mode of the request is stored in the RequestMode attribute of the request (https://fetch.spec.whatwg.org/#requestmode).

For servers responding to clients that expose the request mode information, the value of the mode is sent in the "Sec-Fetch-Mode" request header.

If a "Sec-Fetch-Mode" request header is not present, the server SHOULD allow for the dictionary compression to be used.

  1. If the mode is "navigate" or "same-origin":
    • Response MAY be used as a dictionary.
    • Response MAY be compressed by an available dictionary.
  2. If the mode is "cors":
    • For clients, apply the CORS check from the fetch spec (https://fetch.spec.whatwg.org/#cors-check) which includes credentials checking restrictions that may not be possible to check on the server.
      • If the CORS check passes:
        • Response MAY be used as a dictionary.
        • Response MAY be compressed by an available dictionary.
      • Else:
        • Response MUST NOT be used as a dictionary.
        • Response MUST NOT be compressed by an available dictionary.
    • For servers:
      • If the response does not include an "Access-Control-Allow-Origin" response header:
        • Response MUST NOT be used as a dictionary.
        • Response MUST NOT be compressed by an available dictionary.
      • If the request does not include an "Origin" request header:
        • Response MUST NOT be used as a dictionary.
        • Response MUST NOT be compressed by an available dictionary.
      • If the value of the "Access-Control-Allow-Origin" response header is "*":
        • Response MAY be used as a dictionary.
        • Response MAY be compressed by an available dictionary.
      • If the value of the "Access-Control-Allow-Origin" response header matches the value of the "Origin" request header:
        • Response MAY be used as a dictionary.
        • Response MAY be compressed by an available dictionary.
  3. If the mode is any other value (including "no-cors"):
    • Response MUST NOT be used as a dictionary.
    • Response MUST NOT be compressed by an available dictionary.

7. Privacy Considerations

Since dictionaries are advertised in future requests using the hash of the content of the dictionary, it is possible to abuse the dictionary to turn it into a tracking cookie.

To mitigate any additional tracking concerns, clients MUST treat dictionaries in the same way that they treat cookies. This includes partitioning the storage as cookies are partitioned as well as clearing the dictionaries whenever cookies are cleared.


8. References

8.1. Normative References

[FOLDING]
Watsen, K., Auerswald, E., Farrel, A., and Q. Wu, “Handling Long Lines in Content of Internet-Drafts and RFCs”, RFC 8792, DOI 10.17487/RFC8792, June 2020, <https://www.rfc-editor.org/info/rfc8792>.
[HTTP]
Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, Ed., “HTTP Semantics”, STD 97, RFC 9110, DOI 10.17487/RFC9110, June 2022, <https://www.rfc-editor.org/info/rfc9110>.
[HTTP-CACHING]
Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, Ed., “HTTP Caching”, STD 98, RFC 9111, DOI 10.17487/RFC9111, June 2022, <https://www.rfc-editor.org/info/rfc9111>.
[RFC5861]
Nottingham, M., “HTTP Cache-Control Extensions for Stale Content”, RFC 5861, DOI 10.17487/RFC5861, May 2010, <https://www.rfc-editor.org/info/rfc5861>.

Authors' Addresses

Patrick Meenan (editor)
Google LLC
EMail: pmeenan@google.com
Yoav Weiss (editor)
Google LLC
EMail: yoavweiss@google.com