Internet-Draft | CDEP | August 2023 |
Rundgren | Expires 23 February 2024 | [Page] |
This document describes CDEP, a deterministic encoding profile for CBOR, intended for usage in high-end computing platforms like mobile phones, Web browsers, and Web servers. In addition to enhancing interoperability, deterministic encoding also enables performing cryptographic operations like signing "raw" CBOR data items, something which otherwise would require wrapping such data in byte strings, or introduce dependencies on non-standard canonicalization procedures.¶
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 23 February 2024.¶
Copyright (c) 2023 IETF Trust and the persons identified as the document authors. All rights reserved.¶
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document.¶
This specification introduces a deterministic encoding profile for data expressed in the CBOR [RFC8949] format. This profile is subsequently referred to as CDEP.¶
Note that this document is not on the IETF standards track. However, a conformant implementation is supposed to adhere to the specified behavior for security and interoperability reasons.¶
[RFC8949] supports a number of deterministic encoding options. Some of these options are not necessarily interoperable, like Rule 1‑3 in Section 4.2.2. This could potentially hamper large scale rollout of applications depending on deterministically encoded CBOR.¶
The main objective of CDEP is providing an interoperable CBOR encoding profile, primarily targeting high-end computing platforms like mobile phones, Web browsers, and Web servers. In addition, due to the underpinning deterministic representation of data, CDEP also enables performing cryptographic operations like signatures over "raw" (unwrapped) CBOR data items since signatures depend on a unified representation of the data to be signed. Furthermore, building on the same foundation, CDEP also permits decoded CBOR data to be subjected to simple and secure transformation and reencoding operations.¶
The deterministic encoding profile described in this document is characterized by being bidirectional also when CBOR is provided in diagnostic notation (Section 8 of [RFC8949]), making CDEP comparatively easy to understand, debug, and implement.¶
Although CDEP is a deterministic encoding profile, the intent is that the encoding scheme should be equally useful for applications that do not depend on this particular feature. See also Appendix C.¶
In spite of the enhanced functionality, this specification retains full compatibility with [RFC8949].¶
See also [I-D.mcnally-deterministic-cbor] which represents an alternative approach to deterministic encoding.¶
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.¶
The CDEP deterministic encoding profile builds on Section 4.2 of [RFC8949].¶
The following sections contain some additional clarifications and explicit choices, in order to facilitate an interoperable encoding scheme.¶
Occurrences of unknown or malformed CBOR data items MUST be rejected.¶
Map keys MUST only be compared and sorted based on their
bytewise lexicographic order of their deterministic encoding.
In practical terms this means that if the integer number
0
and the floating point numbers
0.0
, and -0.0
were used as map keys, they would represent the
proper sort order for the distinct keys 00
, f90000
, and f98000
, respectively.
Duplicate map keys MUST be rejected.¶
For applications that depend on deterministic reencoding of CBOR data items,
compliant decoder implementations MUST be able to recreate such data
in its original form. This means for example that the string component
of date items (tag 0
) MUST be preserved "as is" in order
to maintain consistency.¶
The optional numerical extensions described in Section 3.4.4 of [RFC8949] MUST be treated as distinct data items as well as not be subjected to any transformations at the encoding level.¶
Compliant CDEP implementations SHOULD as a minimum support the following CBOR data items:¶
Data Item | Encoding |
---|---|
integer
|
Major type 0 and 1
|
bignum
|
0xc2 and 0xc3
|
floating point
|
0xf9 , 0xfa and 0xfb
|
byte string
|
Major type 2
|
text string
|
Major type 3
|
false
|
0xf4
|
true
|
0xf5
|
null
|
0xf6
|
array
|
Major type 4
|
map
|
Major type 5
|
tag
|
Major type 6
|
See also Appendix B.¶
The following sub sections hold examples of numeric values expressed in diagnostic notation (Section 8 of [RFC8949]) and their CDEP encoded counterpart (expressed in hexadecimal). See also Appendix A.¶
To achieve a fixed and bidirectional representation of numbers, Rule 2 in
Section 4.2.2 of [RFC8949]
MUST be adhered to.
In addition, integer
and floating point
data items MUST
use preferred serialization as described in
Section 4.2.1.¶
Note that the values and encodings are supposed to work in both directions.¶
The following table holds a set of integer
/bignum
values.
Note that bignum
data items MUST
use preferred serialization as described in
Section 3.4.3 of [RFC8949].¶
Value | Encoding |
---|---|
0
|
00
|
-1
|
20
|
23
|
17
|
24
|
1818
|
-24
|
37
|
-25
|
3818
|
255
|
18ff
|
256
|
190100
|
-256
|
38ff
|
-257
|
390100
|
65535
|
19ffff
|
65536
|
1a00010000
|
1099511627775
|
1b000000ffffffffff
|
18446744073709551615
|
1bffffffffffffffff
|
18446744073709551616
|
c249010000000000000000
|
-18446744073709551616
|
3bffffffffffffffff
|
-18446744073709551617
|
c349010000000000000000
|
The following table holds the set of special IEEE 754
[IEEE754] values.
Note that "signaling" NaN
values MUST NOT be present.¶
Value | Encoding |
---|---|
0.0
|
f90000
|
-0.0
|
f98000
|
Infinity
|
f97c00
|
-Infinity
|
f9fc00
|
NaN
|
f97e00
|
The following table holds a set of "ordinary" IEEE 754 [IEEE754] values including some edge cases. Note that subnormal floating point values MUST be supported.¶
Value | Encoding |
---|---|
-5.960464477539062e-8
|
fbbe6fffffffffffff
|
-5.960464477539063e-8
|
f98001
|
-5.960464477539064e-8
|
fbbe70000000000001
|
-5.960465188081798e-8
|
fab3800001
|
0.00006097555160522461
|
f903ff
|
65504.0
|
f97bff
|
65504.00390625
|
fa477fe001
|
65536.0
|
fa47800000
|
10.559998512268066
|
fa4128f5c1
|
10.559998512268068
|
fb40251eb820000001
|
3.4028234663852886e+38
|
fa7f7fffff
|
3.402823466385289e+38
|
fb47efffffe0000001
|
1.401298464324817e-45
|
fa00000001
|
1.1754942106924411e-38
|
fa007fffff
|
5.0e-324
|
fb0000000000000001
|
-1.7976931348623157e+308
|
fbffefffffffffffff
|
This document has no IANA actions.¶
This specification inherits all the security considerations of CBOR [RFC8949].¶
Applications that exploit the uniqueness of deterministic encoding should verify that the used decoder actually rejects incorrectly formatted CBOR data items.¶
The following table holds a few examples of numeric CBOR data items that MUST be rejected because their respective encoding does not conform to CDEP. "PS" in the table is a short form for "Preferred Serialization".¶
Encoded | Error Description |
---|---|
f97e01
|
NaN "signaling"
|
f97c01
|
Invalid NaN
|
fb7ff8000000000000
|
PS: f97e00
|
fb8000000000000000
|
PS: f98000
|
faff800000
|
PS: f9fc00
|
fa477fe000
|
PS: f97bff
|
fab3800000
|
PS: f98001
|
fbbe70000000000000
|
PS: f98001
|
fa00000000
|
PS: f90000
|
fb36a0000000000000
|
PS: fa00000001
|
fb380fffffc0000000
|
PS: fa007fffff
|
1800
|
PS: 00
|
1817
|
PS: 17
|
1900ff
|
PS: 18ff
|
1a000000ff
|
PS: 18ff
|
1a0000ffff
|
PS: 19ffff
|
1b00000000ffffffff
|
PS: 1affffffff
|
3b00000000ffffffff
|
PS: 3affffffff
|
c2488000000000000000
|
PS: 1b8000000000000000
|
c348ffffffffffffffff
|
PS: 3bffffffffffffffff
|
c24a00800000000000000000
|
PS: c249800000000000000000
|
This section is non-normative.¶
Note that even if an application does not support (or need)
bignum
or floating point
data items,
CDEP is still applicable, since a strict subset is upwardly
compatible with full-blown implementations.
Low-end platforms typically also restrict CBOR map
keys to
integer
and text string
data items.
Since these issues are application specific, they are out of scope
for this specification.¶
This section is non-normative.¶
To not unnecessarily create incompatibilities with the existing CBOR ecosystem, CDEP decoders may benefit from supporting a non-deterministic mode, where the map key ordering and preferred serialization checks are disabled.¶
This section is non-normative.¶
Reference implementations that conform to this specification include:¶
This section is non-normative.¶
The following online tools enable testing CDEP without installing any software:¶
This document incorporates much appreciated suggestions and feedback by Eliot Lear, Wolf McNally, Laurence Lundblade, Joe Hildebrand, and Carsten Bormann.¶
[[ This section to be removed by the RFC Editor before publication as an RFC ]]¶
Version 00:¶
Version 01:¶
Version 02:¶
Version 03:¶
Version 04-00:¶
Version 01:¶
Version 02:¶
Version 03:¶
Version 04:¶
Version 05:¶
Version 06:¶
Version 07:¶
Version 08:¶
Version 09:¶
Version 10:¶
Version 11:¶
Version 12:¶
Version 13:¶
Version 14:¶
Version 15:¶
Version 16:¶
Version 17:¶
Version 18:¶
Version 19:¶
Version 20:¶
Version 21:¶
Version 22:¶
Version 23:¶