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56 lines
4.7 KiB
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56 lines
4.7 KiB
Markdown
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SPDX-FileCopyrightText: 2023 The "Notes on OpenPGP" project
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SPDX-License-Identifier: CC-BY-SA-4.0
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# Advanced material: Signatures
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(notation-signature-subpackets)=
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## Notation signature subpackets
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[Notation signature subpackets](https://www.ietf.org/archive/id/draft-ietf-openpgp-crypto-refresh-12.html#notation-data) can be used to effectively extend the otherwise limited set of {term}`signature subpacket types<OpenPGP Signature Subpacket Type>` in OpenPGP with user-defined {term}`notations<Notation>`. {term}`Issuers<Issuer>` can use these {term}`notations<Notation>` to add name-value pairs to an {term}`OpenPGP signature<OpenPGP Signature Packet>`.
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{term}`Notation` names - strings encoded in UTF-8 - may reside in the "user namespace." This namespace is characterized by a {term}`notation tag`, followed by a DNS domain name, both in UTF-8 format.
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{term}`Notations<Notation>`, as described earlier, allow for user-defined extensions to the {term}`OpenPGP signature subpacket types<OpenPGP Signature Subpacket Type>`. A practical and popular application of this functionality is seen in Keyoxide, a decentralized {term}`identity verification` service. Keyoxide uses {term}`notations<Notation>` in the `ariadne.id` namespace. For the details of this {term}`implementation<OpenPGP Implementation>`, refer to the [Keyoxide documentation](https://docs.keyoxide.org/wiki/ariadne-identity/).
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## Choosing the hash algorithm for a signature
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A central element of signature packets is the hash digest of the input data. Most OpenPGP software supports a set of different hash mechanisms, of which one is chosen for each signature packet (this is one aspect of OpenPGP's *cryptographic agility*), and used to calculate the hash digest.
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Different hash mechanisms offer different trade-offs:
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- *Hash digest size*: Larger hash size tends to correspond with greater strength against cryptanalysis, and hash digests are relatively small: at the time of this writing, typical sizes are 32 to 64 bytes. However, for some use cases - especially where small messages are sent over a bandwidth-limited transport - larger hash sizes may unacceptably increase message size.
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- *Computational cost*: Different hash algorithms may have different computational costs. Some OpenPGP users may prefer to limit this cost, for example on constrained computing environments.
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The following sections discuss how the hash algorithm is chosen, based on preferences that are associated with the involved OpenPGP certificates.
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### Typically: Local determination
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Often, signature creation isn't targeted at a specific receiver. Many signatures are issued for an indeterminate set of "anyone who receives the signature."
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For example, self-signatures that form a certificate are aimed at everyone who interacts with that certificate. Similarly, when creating a data signature for a software package, this signature is aimed at "anyone who will check the signature," often over a long period of time, easily spanning years.
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In such cases, the issuer of that signature chooses the hash algorithm locally, without following preferences of a third party.
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### With a specific recipient: "Negotiation" based on recipient's preferences
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In contrast, when a message is created for a specific recipient, the sender can - and should - choose the hash algorithm for the signature packet [based on the recipient's hash algorithm preference](https://www.ietf.org/archive/id/draft-ietf-openpgp-crypto-refresh-12.html#name-hash-algorithm-preferences).
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The recipient's hash algorithm preference is defined in metadata of their certificate, see {ref}`preferences-features` for more details.
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In this workflow, the signed hash digest is created with a hash algorithm that follows the recipient's preferences, and its intersection with the sender's capabilities and preferences.
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## Signature versions
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As described in the [RFC](https://www.ietf.org/archive/id/draft-ietf-openpgp-crypto-refresh-12.html#name-signature-packet-type-id-2), the version of a generated signature packet must conform to the version of the key that issues the signature.
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That is:
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- OpenPGP version 6 keys must generate version 6 signature packets
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- OpenPGP version 4 keys must generate version 4 signature packets
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Note that some historical version 3 signature packets may still be relevant for applications that handle old OpenPGP data[^sig-v3]. These version 3 signature packets will have been generated by version 4 keys.
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[sig-v3]Version 4 signature packets were introduced in [RFC 2440](https://datatracker.ietf.org/doc/html/rfc2440#section-5.2) in 1998, which specifies that applications SHOULD generate v4 signature, however generation of v3 signature packets has remained allowed through [RFC 4880](https://www.rfc-editor.org/rfc/rfc4880.html#section-5.2).
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