Internet-Draft | Digest Fields | May 2022 |
Polli & Pardue | Expires 26 November 2022 | [Page] |
This document defines HTTP fields that support integrity digests. The Content-Digest field can be used for the integrity of HTTP message content. The Repr-Digest field can be used for the integrity of HTTP representations. Want-Content-Digest and Want-Repr-Digest can be used to indicate a sender's interest and preferences for receiving the respective Integrity fields.¶
This document obsoletes RFC 3230 and the Digest and Want-Digest HTTP fields.¶
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-digest-headers/.¶
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/digest-headers.¶
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/.¶
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This Internet-Draft will expire on 26 November 2022.¶
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HTTP does not define the means to protect the data integrity of content or representations. When HTTP messages are transferred between endpoints, lower layer features or properties such as TCP checksums or TLS records [RFC2818] can provide some integrity protection. However, transport-oriented integrity provides a limited utility because it is opaque to the application layer and only covers the extent of a single connection. HTTP messages often travel over a chain of separate connections, in between connections there is a possibility for unintended or malicious data corruption. An HTTP integrity mechanism can provide the means for endpoints, or applications using HTTP, to detect data corruption and make a choice about how to act on it. An example use case is to aid fault detection and diagnosis across system boundaries.¶
This document defines two digest integrity mechanisms for HTTP. First, content integrity, which acts on conveyed content (Section 6.4 of [SEMANTICS]). Second, representation data integrity, which acts on representation data (Section 3.2 of [SEMANTICS]). This supports advanced use cases such as validating the integrity of a resource that was reconstructed from parts retrieved using multiple requests or connections.¶
This document obsoletes RFC 3230 and therefore the Digest and Want-Digest HTTP fields; see Section 1.3.¶
This document is structured as follows:¶
The HTTP fields defined in this document can be used for HTTP integrity. Senders choose a hashing algorithm and calculate a digest from an input related to the HTTP message, the algorithm identifier and digest are transmitted in an HTTP field. Receivers can validate the digest for integrity purposes. Hashing algorithms are registered in the "Hash Algorithms for HTTP Digest Fields" (see Section 5).¶
Selecting the data on which digests are calculated depends on the use case of HTTP messages. This document provides different headers for HTTP representation data and HTTP content.¶
There are use-cases where a simple digest of the HTTP content bytes is
required. The Content-Digest
request and response header and trailer field is
defined to support digests of content (Section 3.2 of [SEMANTICS]); see
Section 2.¶
For more advanced use-cases, the Repr-Digest
request and response header
and trailer field (Section 3) is defined. It contains a digest value
computed by applying a hashing algorithm to selected representation data
(Section 3.2 of [SEMANTICS]). Basing Repr-Digest
on the selected
representation makes it straightforward to apply it to use-cases where the
transferred data requires some sort of manipulation to be considered a
representation or conveys a partial representation of a resource, such as Range
Requests (see Section 14.2 of [SEMANTICS]).¶
Content-Digest
and Repr-Digest
support hashing algorithm agility.
The Want-Content-Digest
and Want-Repr-Digest
fields allow
endpoints to express interest in Content-Digest
and Repr-Digest
respectively, and preference of algorithms in either.¶
Content-Digest
and Repr-Digest
are collectively termed
Integrity fields.
Want-Content-Digest
and Want-Repr-Digest
are
collectively termed Integrity preference fields.¶
Integrity fields are tied to the Content-Encoding
and Content-Type
header fields. Therefore, a given resource may have multiple
different digest values when transferred with HTTP.¶
Integrity fields do not provide integrity for HTTP messages or fields. However, they can be combined with other mechanisms that protect metadata, such as digital signatures, in order to protect the phases of an HTTP exchange in whole or in part. For example, HTTP Message Signatures [SIGNATURES] could be used to sign Integrity fields, thus providing coverage for HTTP content or representation data.¶
This specification does not define means for authentication, authorization or privacy.¶
[RFC3230] defined the Digest
and Want-Digest
HTTP fields for HTTP integrity.
It also coined the term "instance" and "instance manipulation" in order to
explain concepts that are now more universally defined, and implemented, as HTTP
semantics such as selected representation data (Section 3.2 of [SEMANTICS]).¶
Experience has shown that implementations of [RFC3230] have interpreted the meaning of "instance" inconsistently, leading to interoperability issues. The most common mistake being the calculation of the digest using (what we now call) message content, rather than using (what we now call) representation data as was originally intended. Interestingly, time has also shown that a digest of message content can be beneficial for some use cases. So it is difficult to detect if non-conformance to [RFC3230] is intentional or unintentional.¶
In order to address potential inconsistencies and ambiguity across
implementations of Digest
and Want-Digest
, this document obsoletes
[RFC3230]. The Integrity fields (Section 3 and
Section 2) and Integrity preference fields (Section 4)
defined in this document are better aligned with current HTTP semantics and
have names that more clearly articulate the intended usages.¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
This document uses the Augmented BNF defined in [RFC5234] and updated by [RFC7405].¶
This document uses the following terminology from Section 3 of [STRUCTURED-FIELDS] to specify syntax and parsing: Boolean, Byte Sequence, Dictionary, Integer, and List.¶
The definitions "representation", "selected representation", "representation data", "representation metadata", "user agent" and "content" in this document are to be interpreted as described in [SEMANTICS].¶
Hashing algorithm names respect the casing used in their definition document (e.g. SHA-1, CRC32c) whereas hashing algorithm keys are quoted (e.g. "sha", "crc32c").¶
The term "checksum" describes the output of the application of an algorithm to a sequence of bytes, whereas "digest" is only used in relation to the value contained in the fields.¶
Integrity fields: collective term for Content-Digest
and Repr-Digest
¶
Integrity preference fields: collective term for Want-Repr-Digest
and Want-Content-Digest
¶
The Content-Digest
HTTP field can be used in requests and responses to
communicate digests that are calculated using a hashing algorithm applied to
the actual message content (see Section 6.4 of [SEMANTICS]). It is a
Dictionary
(see Section 3.2 of [STRUCTURED-FIELDS])
where each:¶
Byte Sequence
(Section 3.3.5 of [STRUCTURED-FIELDS]),
that contains the output of the digest calculation.¶
For example:¶
The Dictionary
type can be used, for example, to attach multiple digests
calculated using different hashing algorithms in order to support a population
of endpoints with different or evolving capabilities. Such an approach could
support transitions away from weaker algorithms (see Section 6.6).¶
A recipient MAY ignore any or all digests. This allows the recipient to choose which hashing algorithm(s) to use for validation instead of verifying every digest.¶
A sender MAY send a digest without knowing whether the recipient supports a given hashing algorithm, or even knowing that the recipient will ignore it.¶
Content-Digest
can be sent in a trailer section.
In this case,
Content-Digest
MAY be merged into the header section; see Section 6.5.1 of [SEMANTICS].¶
The Repr-Digest
HTTP field can be used in requests and responses to
communicate digests that are calculated using a hashing algorithm applied to
the entire selected representation data (see Section 8.1 of [SEMANTICS]).¶
Representations take into account the effect of the HTTP semantics on messages. For example, the content can be affected by Range Requests or methods such as HEAD, while the way the content is transferred "on the wire" is dependent on other transformations (e.g. transfer codings for HTTP/1.1 - see Section 6.1 of [HTTP11]). To help illustrate HTTP representation concepts, several examples are provided in Appendix A.¶
When a message has no representation data it is still possible to assert that no representation data was sent by computing the digest on an empty string (see Section 6.3).¶
Repr-Digest
is a Dictionary
(see Section 3.2 of [STRUCTURED-FIELDS]) where each:¶
Byte Sequence
that
contains the output of the digest calculation.¶
For example:¶
The Dictionary
type can be used, for example, to attach multiple digests
calculated using different hashing algorithms in order to support a population
of endpoints with different or evolving capabilities. Such an approach could
support transitions away from weaker algorithms (see Section 6.6).¶
A recipient MAY ignore any or all digests. This allows the recipient to choose which hashing algorithm(s) to use for validation instead of verifying every digest.¶
A sender MAY send a digest without knowing whether the recipient supports a given hashing algorithm, or even knowing that the recipient will ignore it.¶
Repr-Digest
can be sent in a trailer section.
In this case,
Repr-Digest
MAY be merged into the header section; see Section 6.5.1 of [SEMANTICS].¶
When the representation enclosed in a state-changing request does not describe the target resource, the representation digest MUST be computed on the representation data. This is the only possible choice because representation digest requires complete representation metadata (see Section 3).¶
In responses,¶
Repr-Digest
MUST be computed on the enclosed representation
(see Appendix B.8 );¶
Repr-Digest
MUST be computed on the selected representation of the referenced resource
even if that is different from the target resource.
That might or might not result in computing Repr-Digest
on the enclosed representation.¶
The latter case is done according to the HTTP semantics of the given
method, for example using the Content-Location
header field (see Section 8.7 of [SEMANTICS]).
In contrast, the Location
header field does not affect Repr-Digest
because
it is not representation metadata.¶
For example, in PATCH
requests, the representation digest
will be computed on the patch document
because the representation metadata refers to the patch document and not
to the target resource (see Section 2 of [PATCH]).
In responses, instead, the representation digest will be computed on the selected
representation of the patched resource.¶
When a state-changing method returns the Content-Location
header field, the
enclosed representation refers to the resource identified by its value and
Repr-Digest
is computed accordingly.
An example is given in Appendix B.7.¶
Senders can indicate their interest in Integrity fields and hashing algorithm
preferences using the
Want-Content-Digest
or Want-Repr-Digest
fields. These can be used in both
requests and responses.¶
Want-Content-Digest
indicates that the sender would like to receive a content digest
on messages associated with the request URI and representation metadata, using
the Content-Digest
field.¶
Want-Repr-Digest
indicates that the sender would like to receive a representation digest
on messages associated with the request URI and representation metadata, using
the Repr-Digest
field.¶
If Want-Content-Digest
or Want-Repr-Digest
are used in a response, it
indicates that the server would like the client to provide the respective
Integrity field on future requests.¶
Want-Content-Digest
and Want-Repr-Digest
are of type Dictionary
where each:¶
Integer
(Section 3.3.1 of [STRUCTURED-FIELDS])
that conveys an ascending, relative, weighted preference.
It must be in the range 0 to 10 inclusive.
1 is the least preferred, 10 is the most preferred,
and a value of 0 means "not acceptable".¶
Examples:¶
The "Hash Algorithms for HTTP Digest Fields", maintained by IANA at https://www.iana.org/assignments/http-dig-alg/, registers algorithms for use with the Integrity and Integrity preference fields defined in this document.¶
This registry uses the Specification Required policy (Section 4.6 of [RFC8126]).¶
Registrations MUST include the following fields:¶
Content-Digest
, Repr-Digest
, Want-Content-Digest
, or Want-Repr-Digest
field Dictionary member keys¶
Status: the status of the algorithm. Use "standard" for standardized algorithms without known problems; "experimental" or some other appropriate value¶
Insecure hashing algorithms MAY be used to preserve integrity against corruption, but MUST NOT be used in a potentially adversarial setting; for example, when signing Integrity fields' values for authenticity.¶
The entries in Table 1 are registered by this document.¶
Algorithm Key | Status | Description | Reference(s) |
---|---|---|---|
sha-512 | standard | The SHA-512 algorithm. | [RFC6234], [RFC4648], this document. |
sha-256 | standard | The SHA-256 algorithm. | [RFC6234], [RFC4648], this document. |
md5 | insecure | The MD5 algorithm. It is vulnerable to collision attacks; see [NO-MD5] and [CMU-836068] | [RFC1321], [RFC4648], this document. |
sha | insecure | The SHA-1 algorithm. It is vulnerable to collision attacks; see [NO-SHA] and [IACR-2020-014] | [RFC3174], [RFC4648], [RFC6234] this document. |
unixsum | insecure | The algorithm used by the UNIX "sum" command. | [RFC4648], [RFC6234], [UNIX], this document. |
unixcksum | insecure | The algorithm used by the UNIX "cksum" command. | [RFC4648], [RFC6234], [UNIX], this document. |
adler | insecure | The ADLER32 algorithm. | [RFC1950], this document. |
crc32c | insecure | The CRC32c algorithm. | [RFC4960] appendix B, this document. |
This document specifies a data integrity mechanism that protects HTTP representation data or content, but not HTTP header and trailer fields, from certain kinds of corruption.¶
Integrity fields are not intended to be a general protection against malicious tampering with HTTP messages. This can be achieved by combining it with other approaches such as transport-layer security or digital signatures (for example, HTTP Message Signatures [SIGNATURES]).¶
Integrity fields can help detect representation data or content modification due to implementation errors, undesired "transforming proxies" (see Section 7.7 of [SEMANTICS]) or other actions as the data passes across multiple hops or system boundaries. Even a simple mechanism for end-to-end representation data integrity is valuable because a user agent can validate that resource retrieval succeeded before handing off to a HTML parser, video player etc. for parsing.¶
Note that using these mechanisms alone does not provide end-to-end integrity of HTTP messages over multiple hops, since metadata could be manipulated at any stage. Methods to protect metadata are discussed in Section 6.3.¶
Digital signatures are widely used together with checksums to provide the certain identification of the origin of a message [NIST800-32]. Such signatures can protect one or more HTTP fields and there are additional considerations when Integrity fields are included in this set.¶
There are no restrictions placed on the type or format of digitial signature that Integrity fields can be used with. One possible approach is to combine them with HTTP Message Signatures [SIGNATURES].¶
Digests explicitly
depend on the "representation metadata" (e.g. the values of Content-Type
,
Content-Encoding
etc). A signature that protects Integrity fields but not other
"representation metadata" can expose the communication to tampering. For
example, an actor could manipulate the Content-Type
field-value and cause a
digest validation failure at the recipient, preventing the application from
accessing the representation. Such an attack consumes the resources of both
endpoints. See also Section 3.2.¶
Signatures are likely to be deemed an adversarial setting when applying Integrity fields; see Section 5. Using signatures to protect the checksum of an empty representation allows receiving endpoints to detect if an eventual payload has been stripped or added.¶
Any mangling of Integrity fields, including digests' de-duplication or combining different field values (see Section 5.2 of [SEMANTICS]) might affect signature validation.¶
Before sending Integrity fields in a trailer section, the sender should consider that intermediaries are explicitly allowed to drop any trailer (see Section 6.5.2 of [SEMANTICS]).¶
When Integrity fields are used in a trailer section, the field-values are received after the content. Eager processing of content before the trailer section prevents digest validation, possibly leading to processing of invalid data.¶
Not every hashing algorithm is suitable for use in the trailer section, some may require to pre-process the whole payload before sending a message (e.g. see [I-D.thomson-http-mice]).¶
The checksum of an encrypted payload can change between different messages depending on the encryption algorithm used; in those cases its value could not be used to provide a proof of integrity "at rest" unless the whole (e.g. encoded) content is persisted.¶
The security properties of hashing algorithms are not fixed. Algorithm Agility (see [RFC7696]) is achieved by providing implementations with flexibility to choose hashing algorithms from the IANA Hash Algorithms for HTTP Digest Fields registry; see Section 7.2.¶
The "standard" algorithms listed in this document are suitable for many purposes, including adversarial situations where hash functions might need to provide resistance to collision, first-preimage and second-preimage attacks. Algorithms listed as "insecure" either provide none of these properties, or are known to be weak (see [NO-MD5] and [NO-SHA]).¶
For adversarial situations, which of the "standard" algorithms are acceptable will depend on the level of protection the circumstances demand. As there is no negotiation, endpoints that depend on a digest for security will be vulnerable to attacks on the weakest algorithm they are willing to accept.¶
Transition from weak algorithms is supported
by negotiation of hashing algorithm using Want-Content-Digest
or Want-Repr-Digest
(see Section 4)
or by sending multiple digests from which the receiver chooses.
Endpoints are advised that sending multiple values consumes resources,
which may be wasted if the receiver ignores them (see Section 3).¶
While algorithm agility allows the migration to stronger algorithms it does not prevent the use of weaker algorithms. Integrity fields do not provide any mitigiations for downgrade or substitution attacks (see Section 1 of [RFC6211]) of the hashing algorithm. To protect against such attacks, endpoints could restrict their set of supported algorithms to stronger ones and protect the fields value by using TLS and/or digital signatures.¶
Integrity fields validation consumes computational resources. In order to avoid resource exhaustion, implementations can restrict validation of the algorithm types, number of validations, or the size of content.¶
IANA is asked to update the "Hypertext Transfer Protocol (HTTP) Field Name Registry" registry ([SEMANTICS]) according to the table below:¶
Field Name | Status | Reference |
---|---|---|
Content-Digest | permanent | Section 2 of this document |
Repr-Digest | permanent | Section 3 of this document |
Want-Content-Digest | permanent | Section 4 of this document |
Want-Repr-Digest | permanent | Section 4 of this document |
Digest | obsoleted | [RFC3230], Section 1.3 of this document |
Want-Digest | obsoleted | [RFC3230], Section 1.3 of this document |
This memo sets this specification to be the establishing document for the Hash Algorithms for HTTP Digest Fields registry defined in Section 5.¶
IANA is asked to initialize the registry with the entries in Table 1.¶
The following examples show how representation metadata, payload transformations and method impacts on the message and content. When the content contains non-printable characters (e.g. when it is compressed) it is shown as a Base64-encoded string.¶
Now the same content conveys a malformed JSON object, because the request does not indicate a content coding.¶
A Range-Request alters the content, conveying a partial representation.¶
The method can also alter the content. For example, the response to a HEAD request does not carry content.¶
Finally, the semantics of an HTTP response might decouple the effective request URI
from the enclosed representation. In the example response below, the
Content-Location
header field indicates that the enclosed representation
refers to the resource available at /authors/123
, even though the request is
directed to /authors/
.¶
The following examples demonstrate interactions where a server responds with a
Content-Digest
or Repr-Digest
fields even though the client did not solicit one using
Want-Content-Digest
or Want-Repr-Digest
.¶
Some examples include JSON objects in the content. For presentation purposes, objects that fit completely within the line-length limits are presented on a single line using compact notation with no leading space. Objects that would exceed line-length limits are presented across multiple lines (one line per key-value pair) with 2 spaced of leading indentation.¶
Checksum mechanisms defined in this document are media-type agnostic
and do not provide canonicalization algorithms for specific formats.
Examples are calculated inclusive of any space.
While examples can include both fields,
Content-Digest
and Repr-Digest
can be returned independently.¶
In this example, the message content conveys complete representation data.
This means that in the response, Content-Digest
and Repr-Digest
are both computed over the JSON object {"hello": "world"}
, and thus have the same value.¶
In this example, a HEAD request is used to retrieve the checksum of a resource.¶
The response Content-Digest
field-value is computed on empty content.
Repr-Digest
is calculated over the JSON object
{"hello": "world"}
, which is not shown because there is no payload
data.¶
In this example, the client makes a range request and the server responds with partial content.¶
In the response message above, note that the
Repr-Digest
and Content-Digests
are different.
The Repr-Digest
field-value is calculated across the entire JSON object
{"hello": "world"}
, and the field is¶
However, since the message content is constrained to bytes 1-7,
the Content-Digest
field-value is calculated over the
byte sequence "hello"
, thus resulting in¶
The request contains a Repr-Digest
field-value calculated on the enclosed
representation. It also includes an Accept-Encoding: br
header field that advertises the
client supports Brotli encoding.¶
The response includes a Content-Encoding: br
that indicates the selected
representation is Brotli-encoded. The Repr-Digest
field-value is therefore
different compared to the request.¶
For presentation purposes, the response body is displayed as a Base64-encoded string because it contains non-printable characters.¶
The request Repr-Digest
field-value is calculated on the enclosed payload.¶
The response Repr-Digest
field-value
depends on the representation metadata header fields, including
Content-Encoding: br
even when the response does not contain content.¶
The response contains two digest values using different algorithms.¶
As the response body contains non-printable characters, it is displayed as a base64-encoded string.¶
The request Repr-Digest
field-value is computed on the enclosed representation (see
Section 3.1).¶
The representation enclosed in the response refers to the resource identified by
Content-Location
(see Section 6.4.2 of [SEMANTICS]). Repr-Digest
is thus computed on the enclosed representation.¶
Note that a 204 No Content
response without content but with the same
Repr-Digest
field-value would have been legitimate too.
In that case, Content-Digest
would have been computed on an empty content.¶
The request Repr-Digest
field-value is computed on the enclosed representation (see
Section 3.1).¶
The representation enclosed in the response describes the status of the request,
so Repr-Digest
is computed on that enclosed representation.¶
Response Repr-Digest
has no explicit relation with the resource referenced by
Location
.¶
This case is analogous to a POST request where the target resource reflects the effective request URI.¶
The PATCH request uses the application/merge-patch+json
media type defined in
[RFC7396].¶
Repr-Digest
is calculated on the enclosed payload, which corresponds to the patch
document.¶
The response Repr-Digest
field-value is computed on the complete representation of the patched
resource.¶
Note that a 204 No Content
response without content but with the same
Repr-Digest
field-value would have been legitimate too.¶
In error responses, the representation data does not necessarily refer to the target resource. Instead, it refers to the representation of the error.¶
In the following example, a client sends the same request from Figure 25 to patch the resource located at /books/123. However, the resource does not exist and the server generates a 404 response with a body that describes the error in accordance with [RFC7807].¶
The response Repr-Digest
field-value is computed on this enclosed representation.¶
An origin server sends Repr-Digest
as trailer field, so it can calculate digest-value
while streaming content and thus mitigate resource consumption.
The Repr-Digest
field-value is the same as in Appendix B.1 because Repr-Digest
is designed to
be independent from the use of one or more transfer codings (see Section 3).¶
The following examples demonstrate interactions where a client solicits a
Repr-Digest
using Want-Repr-Digest
.
The behavior of Content-Digest
and Want-Content-Digest
is identical.¶
Some examples include JSON objects in the content. For presentation purposes, objects that fit completely within the line-length limits are presented on a single line using compact notation with no leading space. Objects that would exceed line-length limits are presented across multiple lines (one line per key-value pair) with 2 spaced of leading indentation.¶
Checksum mechanisms described in this document are media-type agnostic and do not provide canonicalization algorithms for specific formats. Examples are calculated inclusive of any space.¶
The client requests a digest, preferring "sha". The server is free to reply with "sha-256" anyway.¶
The client requests a "sha" digest because that is the only algorithm it supports. The server is not obliged to produce a response containing a "sha" digest, it instead uses a different algorithm.¶
Appendix C.2 is an example where a server ignores the client's preferred digest algorithm. Alternatively a server can also reject the request and return an error.¶
In this example, the client requests a "sha" Repr-Digest
, and the server returns an
error with problem details [RFC7807] contained in the content. The problem
details contain a list of the hashing algorithms that the server supports. This
is purely an example, this specification does not define any format or
requirements for such content.¶
HTTP digests are computed by applying a hashing algorithm to input data. RFC 3230 defined the input data as an "instance", a term it also defined. The concept of instance has since been superseded by the HTTP semantic term "representation". It is understood that some implementations of RFC 3230 mistook "instance" to mean HTTP content. Using content for the Digest field is an error that leads to interoperability problems between peers that implement RFC 3230.¶
For the uncertainty of doubt, RFC 3230 was only ever intended to use what HTTP now defines as selected representation data. The semantic concept of digest and representation are explained alongside the definition of Representation-Digest Section 3.¶
While the syntax of Digest and Repr-Digest are different, the considerations and examples this document gives to Repr-Digest apply equally to Digest because they operate on the same input data. See Section 3.1, Section 6 and Section 6.3.¶
RFC 3230 could never communicate the digest of HTTP message content in the Digest field; Content-Digest now provides that capability.¶
This document is based on ideas from [RFC3230], so thanks to J. Mogul and A. Van Hoff for their great work. The original idea of refreshing RFC3230 arose from an interesting discussion with M. Nottingham, J. Yasskin and M. Thomson when reviewing the MICE content coding.¶
Thanks to Julian Reschke for his valuable contributions to this document, and to the following contributors that have helped improve this specification by reporting bugs, asking smart questions, drafting or reviewing text, and evaluating open issues: Mike Bishop, Brian Campbell, Matthew Kerwin, James Manger, Tommy Pauly, Sean Turner, Justin Richer, and Erik Wilde.¶
RFC Editor: Please remove this section before publication.¶
How can I generate and validate the Repr-Digest
values shown in the examples
throughout this document?¶
The following python3 code can be used to generate digests for JSON objects using SHA algorithms for a range of encodings. Note that these are formatted as base64. This function could be adapted to other algorithms and should take into account their specific formatting rules.¶
import base64, json, hashlib, brotli, logging log = logging.getLogger() def encode_item(item, encoding=lambda x: x): indent = 2 if isinstance(item, dict) and len(item) > 1 else None json_bytes = json.dumps(item, indent=indent).encode() return encoding(json_bytes) def digest_bytes(bytes_, algorithm=hashlib.sha256): checksum_bytes = algorithm(bytes_).digest() log.warning("Log bytes: \n[%r]", bytes_) return base64.encodebytes(checksum_bytes).strip() def digest(item, encoding=lambda x: x, algorithm=hashlib.sha256): content_encoded = encode_item(item, encoding) return digest_bytes(content_encoded, algorithm) item = {"hello": "world"} print("Encoding | hashing algorithm | digest-value") print("Identity | sha256 |", digest(item)) # Encoding | hashing algorithm | digest-value # Identity | sha256 | X48E9qOokqqrvdts8nOJRJN3OWDUoyWxBf7kbu9DBPE= print("Encoding | hashing algorithm | digest-value") print("Brotli | sha256 |", digest(item, encoding=brotli.compress)) # Encoding | hashing algorithm | digest-value # Brotli | sha256 | 4REjxQ4yrqUVicfSKYNO/cF9zNj5ANbzgDZt3/h3Qxo= print("Encoding | hashing algorithm | digest-value") print("Identity | sha512 |", digest(item, algorithm=hashlib.sha512)) print("Brotli | sha512 |", digest(item, algorithm=hashlib.sha512, encoding=brotli.compress)) # Encoding | hashing algorithm | digest-value # Identity | sha512 |b'WZDPaVn/7XgHaAy8pmojAkGWoRx2UFChF41A2svX+TaPm' # '+AbwAgBWnrIiYllu7BNNyealdVLvRwEmTHWXvJwew==' # Brotli | sha512 | b'pxo7aYzcGI88pnDnoSmAnaOEVys0MABhgvHY9+VI+ElE6' # '0jBCwnMPyA/s3NF3ZO5oIWA7lf8ukk+5KJzm3p5og=='¶
RFC Editor: Please remove this section before publication.¶
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