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draft-ietf-openpgp-crypto-refresh-08

The information below is for an old version of the document.
Document Type
This is an older version of an Internet-Draft that was ultimately published as RFC 9580.
Authors Paul Wouters , Daniel Huigens , Justus Winter , Niibe Yutaka
Last updated 2023-03-13
Replaces draft-ietf-openpgp-rfc4880bis
RFC stream Internet Engineering Task Force (IETF)
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Reviews
Additional resources Mailing list discussion
Stream WG state In WG Last Call
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IESG IESG state Became RFC 9580 (Proposed Standard)
Consensus boilerplate Yes
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draft-ietf-openpgp-crypto-refresh-08
Network Working Group                                    P. Wouters, Ed.
Internet-Draft                                                     Aiven
Obsoletes: 4880, 5581, 6637 (if approved)                     D. Huigens
Intended status: Standards Track                               Proton AG
Expires: 14 September 2023                                     J. Winter
                                                             Sequoia-PGP
                                                                Y. Niibe
                                                                    FSIJ
                                                           13 March 2023

                                OpenPGP
                  draft-ietf-openpgp-crypto-refresh-08

Abstract

   This document specifies the message formats used in OpenPGP.  OpenPGP
   provides encryption with public-key or symmetric cryptographic
   algorithms, digital signatures, compression and key management.

   This document is maintained in order to publish all necessary
   information needed to develop interoperable applications based on the
   OpenPGP format.  It is not a step-by-step cookbook for writing an
   application.  It describes only the format and methods needed to
   read, check, generate, and write conforming packets crossing any
   network.  It does not deal with storage and implementation questions.
   It does, however, discuss implementation issues necessary to avoid
   security flaws.

   This document obsoletes: RFC 4880 (OpenPGP), RFC 5581 (Camellia in
   OpenPGP) and RFC 6637 (Elliptic Curves in OpenPGP).

About This Document

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

   The latest revision of this draft can be found at https://openpgp-
   wg.gitlab.io/rfc4880bis/.  Status information for this document may
   be found at https://datatracker.ietf.org/doc/draft-ietf-openpgp-
   crypto-refresh/.

   Discussion of this document takes place on the OpenPGP Working Group
   mailing list (mailto:openpgp@ietf.org), which is archived at
   https://mailarchive.ietf.org/arch/browse/openpgp/.  Subscribe at
   https://www.ietf.org/mailman/listinfo/openpgp/.

   Source for this draft and an issue tracker can be found at
   https://gitlab.com/openpgp-wg/rfc4880bis.

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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 14 September 2023.

Copyright Notice

   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.  Code Components
   extracted from this document must include Revised BSD License text as
   described in Section 4.e of the Trust Legal Provisions and are
   provided without warranty as described in the Revised BSD License.

Table of Contents

   1.  Introduction  . . . . . . . . . . . . . . . . . . . . . . . .   8
     1.1.  Terms . . . . . . . . . . . . . . . . . . . . . . . . . .   8
   2.  General functions . . . . . . . . . . . . . . . . . . . . . .   9
     2.1.  Confidentiality via Encryption  . . . . . . . . . . . . .   9
     2.2.  Authentication via Digital Signature  . . . . . . . . . .  10
     2.3.  Compression . . . . . . . . . . . . . . . . . . . . . . .  11
     2.4.  Conversion to Radix-64  . . . . . . . . . . . . . . . . .  11
     2.5.  Signature-Only Applications . . . . . . . . . . . . . . .  11
   3.  Data Element Formats  . . . . . . . . . . . . . . . . . . . .  11
     3.1.  Scalar Numbers  . . . . . . . . . . . . . . . . . . . . .  11
     3.2.  Multiprecision Integers . . . . . . . . . . . . . . . . .  11
       3.2.1.  Using MPIs to encode other data . . . . . . . . . . .  12
     3.3.  Key IDs . . . . . . . . . . . . . . . . . . . . . . . . .  12
     3.4.  Text  . . . . . . . . . . . . . . . . . . . . . . . . . .  13
     3.5.  Time Fields . . . . . . . . . . . . . . . . . . . . . . .  13

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     3.6.  Keyrings  . . . . . . . . . . . . . . . . . . . . . . . .  13
     3.7.  String-to-Key (S2K) Specifiers  . . . . . . . . . . . . .  13
       3.7.1.  String-to-Key (S2K) Specifier Types . . . . . . . . .  13
         3.7.1.1.  Simple S2K  . . . . . . . . . . . . . . . . . . .  14
         3.7.1.2.  Salted S2K  . . . . . . . . . . . . . . . . . . .  15
         3.7.1.3.  Iterated and Salted S2K . . . . . . . . . . . . .  15
         3.7.1.4.  Argon2  . . . . . . . . . . . . . . . . . . . . .  16
       3.7.2.  String-to-Key Usage . . . . . . . . . . . . . . . . .  17
         3.7.2.1.  Secret-Key Encryption . . . . . . . . . . . . . .  17
         3.7.2.2.  Symmetric-Key Message Encryption  . . . . . . . .  19
   4.  Packet Syntax . . . . . . . . . . . . . . . . . . . . . . . .  19
     4.1.  Overview  . . . . . . . . . . . . . . . . . . . . . . . .  19
     4.2.  Packet Headers  . . . . . . . . . . . . . . . . . . . . .  20
       4.2.1.  OpenPGP Format Packet Lengths . . . . . . . . . . . .  21
         4.2.1.1.  One-Octet Lengths . . . . . . . . . . . . . . . .  21
         4.2.1.2.  Two-Octet Lengths . . . . . . . . . . . . . . . .  21
         4.2.1.3.  Five-Octet Lengths  . . . . . . . . . . . . . . .  22
         4.2.1.4.  Partial Body Lengths  . . . . . . . . . . . . . .  22
       4.2.2.  Legacy Format Packet Lengths  . . . . . . . . . . . .  22
       4.2.3.  Packet Length Examples  . . . . . . . . . . . . . . .  23
     4.3.  Packet Tags . . . . . . . . . . . . . . . . . . . . . . .  23
       4.3.1.  Packet Criticality  . . . . . . . . . . . . . . . . .  25
   5.  Packet Types  . . . . . . . . . . . . . . . . . . . . . . . .  25
     5.1.  Public-Key Encrypted Session Key Packets (Tag 1)  . . . .  25
       5.1.1.  v3 PKESK  . . . . . . . . . . . . . . . . . . . . . .  26
       5.1.2.  v6 PKESK  . . . . . . . . . . . . . . . . . . . . . .  26
       5.1.3.  Algorithm-Specific Fields for RSA encryption  . . . .  27
       5.1.4.  Algorithm-Specific Fields for Elgamal encryption  . .  27
       5.1.5.  Algorithm-Specific Fields for ECDH encryption . . . .  28
       5.1.6.  Algorithm-Specific Fields for X25519 encryption . . .  28
       5.1.7.  Algorithm-Specific Fields for X448 encryption . . . .  28
       5.1.8.  Notes on PKESK  . . . . . . . . . . . . . . . . . . .  29
     5.2.  Signature Packet (Tag 2)  . . . . . . . . . . . . . . . .  29
       5.2.1.  Signature Types . . . . . . . . . . . . . . . . . . .  29
       5.2.2.  Version 3 Signature Packet Format . . . . . . . . . .  32
       5.2.3.  Version 4 and 6 Signature Packet Formats  . . . . . .  35
         5.2.3.1.  Algorithm-Specific Fields for RSA signatures  . .  36
         5.2.3.2.  Algorithm-Specific Fields for DSA or ECDSA
                 signatures  . . . . . . . . . . . . . . . . . . . .  36
         5.2.3.3.  Algorithm-Specific Fields for EdDSALegacy
                 signatures (deprecated) . . . . . . . . . . . . . .  37
         5.2.3.4.  Algorithm-Specific Fields for Ed25519
                 signatures  . . . . . . . . . . . . . . . . . . . .  37
         5.2.3.5.  Algorithm-Specific Fields for Ed448 signatures  .  37
         5.2.3.6.  Notes on Signatures . . . . . . . . . . . . . . .  38
         5.2.3.7.  Signature Subpacket Specification . . . . . . . .  38
         5.2.3.8.  Signature Subpacket Types . . . . . . . . . . . .  41
         5.2.3.9.  Notes on Subpackets . . . . . . . . . . . . . . .  41

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         5.2.3.10. Notes on Self-Signatures  . . . . . . . . . . . .  42
         5.2.3.11. Signature Creation Time . . . . . . . . . . . . .  43
         5.2.3.12. Issuer Key ID . . . . . . . . . . . . . . . . . .  44
         5.2.3.13. Key Expiration Time . . . . . . . . . . . . . . .  44
         5.2.3.14. Preferred Symmetric Ciphers for v1 SEIPD  . . . .  44
         5.2.3.15. Preferred AEAD Ciphersuites . . . . . . . . . . .  44
         5.2.3.16. Preferred Hash Algorithms . . . . . . . . . . . .  45
         5.2.3.17. Preferred Compression Algorithms  . . . . . . . .  45
         5.2.3.18. Signature Expiration Time . . . . . . . . . . . .  46
         5.2.3.19. Exportable Certification  . . . . . . . . . . . .  46
         5.2.3.20. Revocable . . . . . . . . . . . . . . . . . . . .  46
         5.2.3.21. Trust Signature . . . . . . . . . . . . . . . . .  47
         5.2.3.22. Regular Expression  . . . . . . . . . . . . . . .  47
         5.2.3.23. Revocation Key  . . . . . . . . . . . . . . . . .  47
         5.2.3.24. Notation Data . . . . . . . . . . . . . . . . . .  48
         5.2.3.25. Key Server Preferences  . . . . . . . . . . . . .  49
         5.2.3.26. Preferred Key Server  . . . . . . . . . . . . . .  50
         5.2.3.27. Primary User ID . . . . . . . . . . . . . . . . .  50
         5.2.3.28. Policy URI  . . . . . . . . . . . . . . . . . . .  50
         5.2.3.29. Key Flags . . . . . . . . . . . . . . . . . . . .  51
         5.2.3.30. Signer's User ID  . . . . . . . . . . . . . . . .  52
         5.2.3.31. Reason for Revocation . . . . . . . . . . . . . .  52
         5.2.3.32. Features  . . . . . . . . . . . . . . . . . . . .  54
         5.2.3.33. Signature Target  . . . . . . . . . . . . . . . .  55
         5.2.3.34. Embedded Signature  . . . . . . . . . . . . . . .  55
         5.2.3.35. Issuer Fingerprint  . . . . . . . . . . . . . . .  55
         5.2.3.36. Intended Recipient Fingerprint  . . . . . . . . .  55
       5.2.4.  Computing Signatures  . . . . . . . . . . . . . . . .  56
         5.2.4.1.  Notes About Signature Computation . . . . . . . .  58
       5.2.5.  Malformed and Unknown Signatures  . . . . . . . . . .  58
     5.3.  Symmetric-Key Encrypted Session Key Packets (Tag 3) . . .  59
       5.3.1.  v4 SKESK  . . . . . . . . . . . . . . . . . . . . . .  59
       5.3.2.  v6 SKESK  . . . . . . . . . . . . . . . . . . . . . .  60
     5.4.  One-Pass Signature Packets (Tag 4)  . . . . . . . . . . .  61
     5.5.  Key Material Packet . . . . . . . . . . . . . . . . . . .  63
       5.5.1.  Key Packet Variants . . . . . . . . . . . . . . . . .  63
         5.5.1.1.  Public-Key Packet (Tag 6) . . . . . . . . . . . .  63
         5.5.1.2.  Public-Subkey Packet (Tag 14) . . . . . . . . . .  63
         5.5.1.3.  Secret-Key Packet (Tag 5) . . . . . . . . . . . .  63
         5.5.1.4.  Secret-Subkey Packet (Tag 7)  . . . . . . . . . .  63
       5.5.2.  Public-Key Packet Formats . . . . . . . . . . . . . .  63
       5.5.3.  Secret-Key Packet Formats . . . . . . . . . . . . . .  65
       5.5.4.  Key IDs and Fingerprints  . . . . . . . . . . . . . .  68
       5.5.5.  Algorithm-specific Parts of Keys  . . . . . . . . . .  69
         5.5.5.1.  Algorithm-Specific Part for RSA Keys  . . . . . .  70
         5.5.5.2.  Algorithm-Specific Part for DSA Keys  . . . . . .  70
         5.5.5.3.  Algorithm-Specific Part for Elgamal Keys  . . . .  70
         5.5.5.4.  Algorithm-Specific Part for ECDSA Keys  . . . . .  71

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         5.5.5.5.  Algorithm-Specific Part for EdDSALegacy Keys
                 (deprecated)  . . . . . . . . . . . . . . . . . . .  71
         5.5.5.6.  Algorithm-Specific Part for ECDH Keys . . . . . .  72
         5.5.5.7.  Algorithm-Specific Part for X25519 Keys . . . . .  73
         5.5.5.8.  Algorithm-Specific Part for X448 Keys . . . . . .  74
         5.5.5.9.  Algorithm-Specific Part for Ed25519 Keys  . . . .  74
         5.5.5.10. Algorithm-Specific Part for Ed448 Keys  . . . . .  74
     5.6.  Compressed Data Packet (Tag 8)  . . . . . . . . . . . . .  75
     5.7.  Symmetrically Encrypted Data Packet (Tag 9) . . . . . . .  75
     5.8.  Marker Packet (Tag 10)  . . . . . . . . . . . . . . . . .  77
     5.9.  Literal Data Packet (Tag 11)  . . . . . . . . . . . . . .  77
       5.9.1.  Special Filename _CONSOLE (Deprecated)  . . . . . . .  78
     5.10. Trust Packet (Tag 12) . . . . . . . . . . . . . . . . . .  79
     5.11. User ID Packet (Tag 13) . . . . . . . . . . . . . . . . .  79
     5.12. User Attribute Packet (Tag 17)  . . . . . . . . . . . . .  79
       5.12.1.  The Image Attribute Subpacket  . . . . . . . . . . .  80
     5.13. Sym. Encrypted Integrity Protected Data Packet (Tag
            18)  . . . . . . . . . . . . . . . . . . . . . . . . . .  81
       5.13.1.  Version 1 Sym. Encrypted Integrity Protected Data
               Packet Format . . . . . . . . . . . . . . . . . . . .  81
       5.13.2.  Version 2 Sym. Encrypted Integrity Protected Data
               Packet Format . . . . . . . . . . . . . . . . . . . .  83
       5.13.3.  EAX Mode . . . . . . . . . . . . . . . . . . . . . .  85
       5.13.4.  OCB Mode . . . . . . . . . . . . . . . . . . . . . .  85
       5.13.5.  GCM Mode . . . . . . . . . . . . . . . . . . . . . .  85
     5.14. Padding Packet (Tag 21) . . . . . . . . . . . . . . . . .  85
   6.  Radix-64 Conversions  . . . . . . . . . . . . . . . . . . . .  86
     6.1.  Optional checksum . . . . . . . . . . . . . . . . . . . .  87
       6.1.1.  An Implementation of the CRC-24 in "C"  . . . . . . .  87
     6.2.  Forming ASCII Armor . . . . . . . . . . . . . . . . . . .  88
     6.3.  Example of an ASCII Armored Message . . . . . . . . . . .  90
   7.  Cleartext Signature Framework . . . . . . . . . . . . . . . .  90
     7.1.  Dash-Escaped Text . . . . . . . . . . . . . . . . . . . .  92
     7.2.  Incompatibilities with Cleartext Signature Framework  . .  92
   8.  Regular Expressions . . . . . . . . . . . . . . . . . . . . .  93
   9.  Constants . . . . . . . . . . . . . . . . . . . . . . . . . .  93
     9.1.  Public-Key Algorithms . . . . . . . . . . . . . . . . . .  94
     9.2.  ECC Curves for OpenPGP  . . . . . . . . . . . . . . . . .  96
       9.2.1.  Curve-Specific Wire Formats . . . . . . . . . . . . .  98
     9.3.  Symmetric-Key Algorithms  . . . . . . . . . . . . . . . .  99
     9.4.  Compression Algorithms  . . . . . . . . . . . . . . . . . 100
     9.5.  Hash Algorithms . . . . . . . . . . . . . . . . . . . . . 101
     9.6.  AEAD Algorithms . . . . . . . . . . . . . . . . . . . . . 102
   10. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 103
     10.1.  String-to-Key Specifier Types  . . . . . . . . . . . . . 103
     10.2.  Packet . . . . . . . . . . . . . . . . . . . . . . . . . 103
       10.2.1.  User Attribute Subpackets  . . . . . . . . . . . . . 104
         10.2.1.1.  Image Attribute Formats  . . . . . . . . . . . . 104

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       10.2.2.  Signature Subpackets . . . . . . . . . . . . . . . . 104
         10.2.2.1.  Signature Notation Data Subpackets . . . . . . . 104
         10.2.2.2.  Signature Notation Data Subpacket Notation
                 Flags . . . . . . . . . . . . . . . . . . . . . . . 105
         10.2.2.3.  Key Server Preference Extensions . . . . . . . . 105
         10.2.2.4.  Key Flags Extensions . . . . . . . . . . . . . . 105
         10.2.2.5.  Reason for Revocation Extensions . . . . . . . . 105
         10.2.2.6.  Implementation Features  . . . . . . . . . . . . 105
       10.2.3.  Packet Versions  . . . . . . . . . . . . . . . . . . 106
     10.3.  Algorithms . . . . . . . . . . . . . . . . . . . . . . . 106
       10.3.1.  Public-Key Algorithms  . . . . . . . . . . . . . . . 106
         10.3.1.1.  Elliptic Curve Algorithms  . . . . . . . . . . . 107
       10.3.2.  Symmetric-Key Algorithms . . . . . . . . . . . . . . 107
       10.3.3.  Hash Algorithms  . . . . . . . . . . . . . . . . . . 107
       10.3.4.  Compression Algorithms . . . . . . . . . . . . . . . 108
       10.3.5.  Elliptic Curve Algorithms  . . . . . . . . . . . . . 108
     10.4.  Elliptic Curve Point and Scalar Wire Formats . . . . . . 109
     10.5.  Changes to existing registries . . . . . . . . . . . . . 109
   11. Packet Composition  . . . . . . . . . . . . . . . . . . . . . 109
     11.1.  Transferable Public Keys . . . . . . . . . . . . . . . . 110
       11.1.1.  OpenPGP v6 Key Structure . . . . . . . . . . . . . . 110
       11.1.2.  OpenPGP v4 Key Structure . . . . . . . . . . . . . . 111
       11.1.3.  OpenPGP v3 Key Structure . . . . . . . . . . . . . . 112
       11.1.4.  Common requirements  . . . . . . . . . . . . . . . . 112
     11.2.  Transferable Secret Keys . . . . . . . . . . . . . . . . 114
     11.3.  OpenPGP Messages . . . . . . . . . . . . . . . . . . . . 114
       11.3.1.  Unwrapping Encrypted and Compressed Messages . . . . 115
       11.3.2.  Additional Constraints on Packet Sequences . . . . . 115
         11.3.2.1.  Packet Versions in Encrypted Messages  . . . . . 115
     11.4.  Detached Signatures  . . . . . . . . . . . . . . . . . . 116
   12. Elliptic Curve Cryptography . . . . . . . . . . . . . . . . . 117
     12.1.  Supported ECC Curves . . . . . . . . . . . . . . . . . . 117
     12.2.  EC Point Wire Formats  . . . . . . . . . . . . . . . . . 117
       12.2.1.  SEC1 EC Point Wire Format  . . . . . . . . . . . . . 118
       12.2.2.  Prefixed Native EC Point Wire Format . . . . . . . . 118
       12.2.3.  Notes on EC Point Wire Formats . . . . . . . . . . . 118
     12.3.  EC Scalar Wire Formats . . . . . . . . . . . . . . . . . 119
       12.3.1.  EC Octet String Wire Format  . . . . . . . . . . . . 119
       12.3.2.  Elliptic Curve Prefixed Octet String Wire Format . . 120
     12.4.  Key Derivation Function  . . . . . . . . . . . . . . . . 120
     12.5.  EC DH Algorithm (ECDH) . . . . . . . . . . . . . . . . . 121
       12.5.1.  ECDH Parameters  . . . . . . . . . . . . . . . . . . 124
   13. Notes on Algorithms . . . . . . . . . . . . . . . . . . . . . 125
     13.1.  PKCS#1 Encoding in OpenPGP . . . . . . . . . . . . . . . 125
       13.1.1.  EME-PKCS1-v1_5-ENCODE  . . . . . . . . . . . . . . . 125
       13.1.2.  EME-PKCS1-v1_5-DECODE  . . . . . . . . . . . . . . . 126
       13.1.3.  EMSA-PKCS1-v1_5  . . . . . . . . . . . . . . . . . . 126
     13.2.  Symmetric Algorithm Preferences  . . . . . . . . . . . . 128

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       13.2.1.  Plaintext  . . . . . . . . . . . . . . . . . . . . . 128
     13.3.  Other Algorithm Preferences  . . . . . . . . . . . . . . 129
       13.3.1.  Compression Preferences  . . . . . . . . . . . . . . 129
         13.3.1.1.  Uncompressed . . . . . . . . . . . . . . . . . . 129
       13.3.2.  Hash Algorithm Preferences . . . . . . . . . . . . . 129
     13.4.  RSA  . . . . . . . . . . . . . . . . . . . . . . . . . . 130
     13.5.  DSA  . . . . . . . . . . . . . . . . . . . . . . . . . . 130
     13.6.  Elgamal  . . . . . . . . . . . . . . . . . . . . . . . . 130
     13.7.  EdDSA  . . . . . . . . . . . . . . . . . . . . . . . . . 130
     13.8.  Reserved Algorithm Numbers . . . . . . . . . . . . . . . 131
     13.9.  CFB Mode . . . . . . . . . . . . . . . . . . . . . . . . 131
     13.10. Private or Experimental Parameters . . . . . . . . . . . 131
     13.11. Meta-Considerations for Expansion  . . . . . . . . . . . 132
   14. Security Considerations . . . . . . . . . . . . . . . . . . . 132
     14.1.  SHA-1 Collision Detection  . . . . . . . . . . . . . . . 134
     14.2.  Advantages of Salted Signatures  . . . . . . . . . . . . 135
     14.3.  Elliptic Curve Side Channels . . . . . . . . . . . . . . 135
     14.4.  Risks of a Quick Check Oracle  . . . . . . . . . . . . . 136
     14.5.  Avoiding Leaks From PKCS#1 Errors  . . . . . . . . . . . 136
     14.6.  Fingerprint Usability  . . . . . . . . . . . . . . . . . 137
     14.7.  Avoiding Ciphertext Malleability . . . . . . . . . . . . 138
     14.8.  Escrowed Revocation Signatures . . . . . . . . . . . . . 139
     14.9.  Random Number Generation and Seeding . . . . . . . . . . 140
     14.10. Traffic Analysis . . . . . . . . . . . . . . . . . . . . 141
     14.11. Surreptitious Forwarding . . . . . . . . . . . . . . . . 142
   15. Implementation Nits . . . . . . . . . . . . . . . . . . . . . 142
     15.1.  Constrained Legacy Fingerprint Storage for v6 Keys . . . 143
   16. References  . . . . . . . . . . . . . . . . . . . . . . . . . 143
     16.1.  Normative References . . . . . . . . . . . . . . . . . . 143
     16.2.  Informative References . . . . . . . . . . . . . . . . . 146
   Appendix A.  Test vectors . . . . . . . . . . . . . . . . . . . . 150
     A.1.  Sample v4 Ed25519Legacy key . . . . . . . . . . . . . . . 150
     A.2.  Sample v4 Ed25519Legacy signature . . . . . . . . . . . . 151
     A.3.  Sample v6 Certificate (Transferable Public Key) . . . . . 151
       A.3.1.  Hashed Data Stream for Signature Verification . . . . 152
     A.4.  Sample v6 Secret Key (Transferable Secret Key)  . . . . . 156
     A.5.  Sample AEAD-EAX encryption and decryption . . . . . . . . 156
       A.5.1.  Sample symmetric-key encrypted session key packet
               (v6)  . . . . . . . . . . . . . . . . . . . . . . . . 156
       A.5.2.  Starting AEAD-EAX decryption of the session key . . . 157
       A.5.3.  Sample v2 SEIPD packet  . . . . . . . . . . . . . . . 158
       A.5.4.  Decryption of data  . . . . . . . . . . . . . . . . . 159
       A.5.5.  Complete AEAD-EAX encrypted packet sequence . . . . . 160
     A.6.  Sample AEAD-OCB encryption and decryption . . . . . . . . 160
       A.6.1.  Sample symmetric-key encrypted session key packet
               (v6)  . . . . . . . . . . . . . . . . . . . . . . . . 160
       A.6.2.  Starting AEAD-OCB decryption of the session key . . . 161
       A.6.3.  Sample v2 SEIPD packet  . . . . . . . . . . . . . . . 162

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       A.6.4.  Decryption of data  . . . . . . . . . . . . . . . . . 163
       A.6.5.  Complete AEAD-OCB encrypted packet sequence . . . . . 164
     A.7.  Sample AEAD-GCM encryption and decryption . . . . . . . . 164
       A.7.1.  Sample symmetric-key encrypted session key packet
               (v6)  . . . . . . . . . . . . . . . . . . . . . . . . 164
       A.7.2.  Starting AEAD-GCM decryption of the session key . . . 165
       A.7.3.  Sample v2 SEIPD packet  . . . . . . . . . . . . . . . 166
       A.7.4.  Decryption of data  . . . . . . . . . . . . . . . . . 167
       A.7.5.  Complete AEAD-GCM encrypted packet sequence . . . . . 168
     A.8.  Sample messages encrypted using Argon2  . . . . . . . . . 168
       A.8.1.  v4 SKESK using Argon2 with AES-128  . . . . . . . . . 168
       A.8.2.  v4 SKESK using Argon2 with AES-192  . . . . . . . . . 168
       A.8.3.  v4 SKESK using Argon2 with AES-256  . . . . . . . . . 168
   Appendix B.  Acknowledgements . . . . . . . . . . . . . . . . . . 169
   Authors' Addresses  . . . . . . . . . . . . . . . . . . . . . . . 169

1.  Introduction

   This document provides information on the message-exchange packet
   formats used by OpenPGP to provide encryption, decryption, signing,
   and key management functions.  It is a revision of RFC 4880, "OpenPGP
   Message Format", which is a revision of RFC 2440, which itself
   replaces RFC 1991, "PGP Message Exchange Formats" [RFC1991] [RFC2440]
   [RFC4880].

   This document obsoletes: RFC 4880 (OpenPGP), RFC 5581 (Camellia in
   OpenPGP) and RFC 6637 (Elliptic Curves in OpenPGP).

1.1.  Terms

   *  OpenPGP - This is a term for the IETF specification of PGP which
      originates with RFC 2440 (OpenPGP Message Format) which was based
      on PGP 5, and which has since been maintained by the IETF, of
      which this document is the latest specification (at the time of
      writing).

   *  PGP - Pretty Good Privacy.  PGP is a family of software systems
      developed by Philip R. Zimmermann from which OpenPGP is based.

   *  PGP 2 - This version of PGP has many variants; where necessary a
      more detailed version number is used here.  PGP 2 uses only RSA,
      MD5, and IDEA for its cryptographic transforms.  An informational
      RFC, RFC 1991, was written describing this version of PGP.

   *  PGP 5 - This version of PGP is formerly known as "PGP 3" in the
      community.  It has new formats and corrects a number of problems
      in the PGP 2 design.  It is referred to here as PGP 5 because that
      software was the first release of the "PGP 3" code base.

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   *  GnuPG - GNU Privacy Guard, also called GPG.  GnuPG is an OpenPGP
      implementation that avoids all encumbered algorithms.
      Consequently, early versions of GnuPG did not include RSA public
      keys.

   "PGP", "Pretty Good", and "Pretty Good Privacy" are trademarks of PGP
   Corporation and are used with permission.  The term "OpenPGP" refers
   to the protocol described in this and related documents.

   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 key words "PRIVATE USE", "SPECIFICATION REQUIRED", and "RFC
   REQUIRED" that appear in this document when used to describe
   namespace allocation are to be interpreted as described in [RFC8126].

2.  General functions

   OpenPGP provides data integrity services for messages and data files
   by using these core technologies:

   *  digital signatures

   *  encryption

   *  compression

   *  Radix-64 conversion

   In addition, OpenPGP provides key management and certificate
   services, but many of these are beyond the scope of this document.

2.1.  Confidentiality via Encryption

   OpenPGP combines symmetric-key encryption and public-key encryption
   to provide confidentiality.  When made confidential, first the object
   is encrypted using a symmetric encryption algorithm.  Each symmetric
   key is used only once, for a single object.  A new "session key" is
   generated as a random number for each object (sometimes referred to
   as a session).  Since it is used only once, the session key is bound
   to the message and transmitted with it.  To protect the key, it is
   encrypted with the receiver's public key.  The sequence is as
   follows:

   1.  The sender creates a message.

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   2.  The sending OpenPGP generates a random number to be used as a
       session key for this message only.

   3.  The session key is encrypted using each recipient's public key.
       These "encrypted session keys" start the message.

   4.  The sending OpenPGP encrypts the message using the session key,
       which forms the remainder of the message.

   5.  The receiving OpenPGP decrypts the session key using the
       recipient's private key.

   6.  The receiving OpenPGP decrypts the message using the session key.
       If the message was compressed, it will be decompressed.

   With symmetric-key encryption, an object may be encrypted with a
   symmetric key derived from a passphrase (or other shared secret), or
   a two-stage mechanism similar to the public-key method described
   above in which a session key is itself encrypted with a symmetric
   algorithm keyed from a shared secret.

   Both digital signature and confidentiality services may be applied to
   the same message.  First, a signature is generated for the message
   and attached to the message.  Then the message plus signature is
   encrypted using a symmetric session key.  Finally, the session key is
   encrypted using public-key encryption and prefixed to the encrypted
   block.

2.2.  Authentication via Digital Signature

   The digital signature uses a hash code or message digest algorithm,
   and a public-key signature algorithm.  The sequence is as follows:

   1.  The sender creates a message.

   2.  The sending software generates a hash code of the message.

   3.  The sending software generates a signature from the hash code
       using the sender's private key.

   4.  The binary signature is attached to the message.

   5.  The receiving software keeps a copy of the message signature.

   6.  The receiving software generates a new hash code for the received
       message and verifies it using the message's signature.  If the
       verification is successful, the message is accepted as authentic.

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2.3.  Compression

   If an implementation does not implement compression, its authors
   should be aware that most OpenPGP messages in the world are
   compressed.  Thus, it may even be wise for a space-constrained
   implementation to implement decompression, but not compression.

2.4.  Conversion to Radix-64

   OpenPGP's underlying native representation for encrypted messages,
   signature certificates, and keys is a stream of arbitrary octets.
   Some systems only permit the use of blocks consisting of seven-bit,
   printable text.  For transporting OpenPGP's native raw binary octets
   through channels that are not safe to raw binary data, a printable
   encoding of these binary octets is needed.  OpenPGP provides the
   service of converting the raw 8-bit binary octet stream to a stream
   of printable ASCII characters, called Radix-64 encoding or ASCII
   Armor.

   Implementations SHOULD provide Radix-64 conversions.

2.5.  Signature-Only Applications

   OpenPGP is designed for applications that use both encryption and
   signatures, but there are a number of problems that are solved by a
   signature-only implementation.  Although this specification requires
   both encryption and signatures, it is reasonable for there to be
   subset implementations that are non-conformant only in that they omit
   encryption.

3.  Data Element Formats

   This section describes the data elements used by OpenPGP.

3.1.  Scalar Numbers

   Scalar numbers are unsigned and are always stored in big-endian
   format.  Using n[k] to refer to the kth octet being interpreted, the
   value of a two-octet scalar is ((n[0] << 8) + n[1]).  The value of a
   four-octet scalar is ((n[0] << 24) + (n[1] << 16) + (n[2] << 8) +
   n[3]).

3.2.  Multiprecision Integers

   Multiprecision integers (also called MPIs) are unsigned integers used
   to hold large integers such as the ones used in cryptographic
   calculations.

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   An MPI consists of two pieces: a two-octet scalar that is the length
   of the MPI in bits followed by a string of octets that contain the
   actual integer.

   These octets form a big-endian number; a big-endian number can be
   made into an MPI by prefixing it with the appropriate length.

   Examples:

   (all numbers are in hexadecimal)

   The string of octets [00 00] forms an MPI with the value 0.  The
   string of octets [00 01 01] forms an MPI with the value 1.  The
   string [00 09 01 FF] forms an MPI with the value of 511.

   Additional rules:

   The size of an MPI is ((MPI.length + 7) / 8) + 2 octets.

   The length field of an MPI describes the length starting from its
   most significant non-zero bit.  Thus, the MPI [00 02 01] is not
   formed correctly.  It should be [00 01 01].  When parsing an MPI in a
   v6 Key, Signature, or Public-Key Encrypted Session Key packet, the
   implementation MUST check that the encoded length matches the length
   starting from the most significant non-zero bit, and reject the
   packet as malformed if not.

   Unused bits of an MPI MUST be zero.

   Also note that when an MPI is encrypted, the length refers to the
   plaintext MPI.  It may be ill-formed in its ciphertext.

3.2.1.  Using MPIs to encode other data

   Note that MPIs are used in some places used to encode non-integer
   data, such as an elliptic curve point (see Section 12.2, or an octet
   string of known, fixed length (see Section 12.3).  The wire
   representation is the same: two octets of length in bits counted from
   the first non-zero bit, followed by the smallest series of octets
   that can represent the value while stripping off any leading zero
   octets.

3.3.  Key IDs

   A Key ID is an eight-octet scalar that identifies a key.
   Implementations SHOULD NOT assume that Key IDs are unique.
   Section 5.5.4 describes how Key IDs are formed.

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3.4.  Text

   Unless otherwise specified, the character set for text is the UTF-8
   [RFC3629] encoding of Unicode [ISO10646].

3.5.  Time Fields

   A time field is an unsigned four-octet number containing the number
   of seconds elapsed since midnight, 1 January 1970 UTC.

3.6.  Keyrings

   A keyring is a collection of one or more keys in a file or database.
   Traditionally, a keyring is simply a sequential list of keys, but may
   be any suitable database.  It is beyond the scope of this standard to
   discuss the details of keyrings or other databases.

3.7.  String-to-Key (S2K) Specifiers

   A string-to-key (S2K) specifier is used to convert a passphrase
   string into a symmetric-key encryption/decryption key.  They are used
   in two places, currently: to encrypt the secret part of private keys
   in the private keyring, and to convert passphrases to encryption keys
   for symmetrically encrypted messages.

3.7.1.  String-to-Key (S2K) Specifier Types

   There are four types of S2K specifiers currently supported, and some
   reserved values:

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   +=====+==============+==================+===============+===========+
   |  ID | S2K Type     | Generate?        | S2K field     | Reference |
   |     |              |                  | size (octets) |           |
   +=====+==============+==================+===============+===========+
   |   0 | Simple S2K   | N                | 2             | Section   |
   |     |              |                  |               | 3.7.1.1   |
   +-----+--------------+------------------+---------------+-----------+
   |   1 | Salted S2K   | Only when        | 10            | Section   |
   |     |              | string is        |               | 3.7.1.2   |
   |     |              | high entropy     |               |           |
   +-----+--------------+------------------+---------------+-----------+
   |   2 | Reserved     | N                |               |           |
   |     | value        |                  |               |           |
   +-----+--------------+------------------+---------------+-----------+
   |   3 | Iterated and | Y                | 11            | Section   |
   |     | Salted S2K   |                  |               | 3.7.1.3   |
   +-----+--------------+------------------+---------------+-----------+
   |   4 | Argon2       | Y                | 20            | Section   |
   |     |              |                  |               | 3.7.1.4   |
   +-----+--------------+------------------+---------------+-----------+
   | 100 | Private/     | As               |               |           |
   |  to | Experimental | appropriate      |               |           |
   | 110 | S2K          |                  |               |           |
   +-----+--------------+------------------+---------------+-----------+

                         Table 1: S2K type registry

   These are described in the subsections below.  If the "Generate?"
   column is not "Y", the S2K entry is used only for reading in
   backwards compatibility mode and should not be used to generate new
   output.

3.7.1.1.  Simple S2K

   This directly hashes the string to produce the key data.  See below
   for how this hashing is done.

     Octet 0:        0x00
     Octet 1:        hash algorithm

   Simple S2K hashes the passphrase to produce the session key.  The
   manner in which this is done depends on the size of the session key
   (which will depend on the cipher used) and the size of the hash
   algorithm's output.  If the hash size is greater than the session key
   size, the high-order (leftmost) octets of the hash are used as the
   key.

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   If the hash size is less than the key size, multiple instances of the
   hash context are created --- enough to produce the required key data.
   These instances are preloaded with 0, 1, 2, ... octets of zeros (that
   is to say, the first instance has no preloading, the second gets
   preloaded with 1 octet of zero, the third is preloaded with two
   octets of zeros, and so forth).

   As the data is hashed, it is given independently to each hash
   context.  Since the contexts have been initialized differently, they
   will each produce different hash output.  Once the passphrase is
   hashed, the output data from the multiple hashes is concatenated,
   first hash leftmost, to produce the key data, with any excess octets
   on the right discarded.

3.7.1.2.  Salted S2K

   This includes a "salt" value in the S2K specifier --- some arbitrary
   data --- that gets hashed along with the passphrase string, to help
   prevent dictionary attacks.

     Octet 0:        0x01
     Octet 1:        hash algorithm
     Octets 2-9:     8-octet salt value

   Salted S2K is exactly like Simple S2K, except that the input to the
   hash function(s) consists of the 8 octets of salt from the S2K
   specifier, followed by the passphrase.

3.7.1.3.  Iterated and Salted S2K

   This includes both a salt and an octet count.  The salt is combined
   with the passphrase and the resulting value is hashed repeatedly.
   This further increases the amount of work an attacker must do to try
   dictionary attacks.

     Octet  0:        0x03
     Octet  1:        hash algorithm
     Octets 2-9:      8-octet salt value
     Octet  10:       count, a one-octet, coded value

   The count is coded into a one-octet number using the following
   formula:

     #define EXPBIAS 6
         count = ((Int32)16 + (c & 15)) << ((c >> 4) + EXPBIAS);

   The above formula is in C, where "Int32" is a type for a 32-bit
   integer, and the variable "c" is the coded count, Octet 10.

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   Iterated-Salted S2K hashes the passphrase and salt data multiple
   times.  The total number of octets to be hashed is specified in the
   encoded count in the S2K specifier.  Note that the resulting count
   value is an octet count of how many octets will be hashed, not an
   iteration count.

   Initially, one or more hash contexts are set up as with the other S2K
   algorithms, depending on how many octets of key data are needed.
   Then the salt, followed by the passphrase data, is repeatedly hashed
   until the number of octets specified by the octet count has been
   hashed.  The one exception is that if the octet count is less than
   the size of the salt plus passphrase, the full salt plus passphrase
   will be hashed even though that is greater than the octet count.
   After the hashing is done, the data is unloaded from the hash
   context(s) as with the other S2K algorithms.

3.7.1.4.  Argon2

   This S2K method hashes the passphrase using Argon2, specified in
   [RFC9106].  This provides memory-hardness, further protecting the
   passphrase against brute-force attacks.

     Octet  0:        0x04
     Octets 1-16:     16-octet salt value
     Octet  17:       one-octet number of passes t
     Octet  18:       one-octet degree of parallelism p
     Octet  19:       one-octet exponent indicating the memory size m

   The salt SHOULD be unique for each password.

   The number of passes t and the degree of parallelism p MUST be non-
   zero.

   The memory size m is 2**encoded_m kibibytes of RAM, where "encoded_m"
   is the encoded memory size in Octet 19.  The encoded memory size MUST
   be a value from 3+ceil(log_2(p)) to 31, such that the decoded memory
   size m is a value from 8*p to 2**31.  Note that memory-hardness size
   is indicated in kibibytes (KiB), not octets.

   Argon2 is invoked with the passphrase as P, the salt as S, the values
   of t, p and m as described above, the required key size as the tag
   length T, 0x13 as the version v, and Argon2id as the type.

   For the recommended values of t, p and m, see Section 4 of [RFC9106].
   If the recommended value of m for a given application is not a power
   of 2, it is RECOMMENDED to round up to the next power of 2 if the
   resulting performance would be acceptable, and round down otherwise
   (keeping in mind that m must be at least 8*p).

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   As an example, with the first recommended option (t=1, p=4, m=2**21),
   the full S2K specifier would be:

     04 XX XX XX XX XX XX XX XX XX XX XX XX XX XX XX
     XX 01 04 15

   (where XX represents a random octet of salt).

3.7.2.  String-to-Key Usage

   Simple S2K and Salted S2K specifiers can be brute-forced when used
   with a low-entropy string, such as those typically provided by users.
   In addition, the usage of Simple S2K can lead to key and IV reuse
   (see Section 5.3).  Therefore, when generating S2K specifiers,
   implementations MUST NOT use Simple S2K, and SHOULD NOT use Salted
   S2K unless the implementation knows that the string is high-entropy
   (for example, it generated the string itself using a known-good
   source of randomness).  It is RECOMMENDED that implementations use
   Argon2.

3.7.2.1.  Secret-Key Encryption

   An S2K specifier can be stored in the secret keyring to specify how
   to convert the passphrase to a key that unlocks the secret data.
   Older versions of PGP just stored a symmetric cipher algorithm octet
   preceding the secret data or a zero to indicate that the secret data
   was unencrypted.  The MD5 hash function was always used to convert
   the passphrase to a key for the specified cipher algorithm.

   For compatibility, when an S2K specifier is used, the special value
   253, 254, or 255 is stored in the position where the cipher algorithm
   octet would have been in the old data structure.  This is then
   followed immediately by a one-octet algorithm identifier, and other
   fields relevant to the type of encryption used.

   Therefore, the first octet of the secret key material describes how
   the secret key data is presented.  The structures differ based on the
   version of the enclosing OpenPGP packet.  The tables below summarize
   the details described in Section 5.5.3.

   In the tables below, check(x) means the "2-octet checksum" meaning
   the sum of all octets in x mod 65536.

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    +==============+================+=====================+===========+
    | First octet  | Encryption     | Encryption          | Generate? |
    |              | parameter      |                     |           |
    |              | fields         |                     |           |
    +==============+================+=====================+===========+
    | 0            | -              | cleartext           | Yes       |
    |              |                | secrets ||          |           |
    |              |                | check(secrets)      |           |
    +--------------+----------------+---------------------+-----------+
    | Known        | IV             | CFB(MD5(password),  | No        |
    | symmetric    |                | secrets ||          |           |
    | cipher algo  |                | check(secrets))     |           |
    | ID (see      |                |                     |           |
    | Section 9.3) |                |                     |           |
    +--------------+----------------+---------------------+-----------+
    | 253          | cipher-algo,   | AEAD(S2K(password), | Yes       |
    |              | AEAD-mode,     | secrets, pubkey)    |           |
    |              | S2K-specifier, |                     |           |
    |              | nonce          |                     |           |
    +--------------+----------------+---------------------+-----------+
    | 254          | cipher-algo,   | CFB(S2K(password),  | Yes       |
    |              | S2K-specifier, | secrets ||          |           |
    |              | IV             | SHA1(secrets))      |           |
    +--------------+----------------+---------------------+-----------+
    | 255          | cipher-algo,   | CFB(S2K(password),  | No        |
    |              | S2K-specifier, | secrets ||          |           |
    |              | IV             | check(secrets))     |           |
    +--------------+----------------+---------------------+-----------+

              Table 2: Version 4 Secret Key protection details

   If the "Generate?" column is not "Y", the Secret Key protection
   details entry is used only for reading in backwards compatibility
   mode and MUST NOT be used to generate new output.

   Each row with "Generate?" marked as "No" is described for backward
   compatibility, and MUST NOT be generated.

   A version 6 secret key that is cryptographically protected is stored
   with an additional pair of length counts, each of which is one octet
   wide:

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      +=======+==============================+=====================+
      | First | Encryption parameter fields  | Encryption          |
      | octet |                              |                     |
      +=======+==============================+=====================+
      | 0     | -                            | cleartext secrets   |
      +-------+------------------------------+---------------------+
      | 253   | params-length, cipher-algo,  | AEAD(S2K(password), |
      |       | AEAD-mode, S2K-specifier-    | secrets, pubkey)    |
      |       | length, S2K-specifier, nonce |                     |
      +-------+------------------------------+---------------------+
      | 254   | params-length, cipher-algo,  | CFB(S2K(password),  |
      |       | S2K-specifier-length, S2K-   | secrets ||          |
      |       | specifier, IV                | SHA1(secrets))      |
      +-------+------------------------------+---------------------+

             Table 3: Version 6 Secret Key protection details

   An implementation MUST NOT create and MUST reject as malformed a
   secret key packet where the S2K usage octet is anything but 253 and
   the S2K specifier type is Argon2.

3.7.2.2.  Symmetric-Key Message Encryption

   OpenPGP can create a Symmetric-key Encrypted Session Key (ESK) packet
   at the front of a message.  This is used to allow S2K specifiers to
   be used for the passphrase conversion or to create messages with a
   mix of symmetric-key ESKs and public-key ESKs.  This allows a message
   to be decrypted either with a passphrase or a public-key pair.

   PGP 2 always used IDEA with Simple string-to-key conversion when
   encrypting a message with a symmetric algorithm.  See Section 5.7.
   This MUST NOT be generated, but MAY be consumed for backward-
   compatibility.

4.  Packet Syntax

   This section describes the packets used by OpenPGP.

4.1.  Overview

   An OpenPGP message is constructed from a number of records that are
   traditionally called packets.  A packet is a chunk of data that has a
   tag specifying its meaning.  An OpenPGP message, keyring,
   certificate, and so forth consists of a number of packets.  Some of
   those packets may contain other OpenPGP packets (for example, a
   compressed data packet, when uncompressed, contains OpenPGP packets).

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   Each packet consists of a packet header, followed by the packet body.
   The packet header is of variable length.

   When handling a stream of packets, the length information in each
   packet header is the canonical source of packet boundaries.  An
   implementation handling a packet stream that wants to find the next
   packet MUST look for it at the precise offset indicated in the
   previous packet header.

   Additionally, some packets contain internal length indicators (for
   example, a subfield within the packet).  In the event that a subfield
   length indicator within a packet implies inclusion of octets outside
   the range indicated in the packet header, a parser MUST abort without
   writing outside the indicated range and MUST treat the packet as
   malformed and unusable.

   An implementation MUST NOT interpret octets outside the range
   indicated in the packet header as part of the contents of the packet.

4.2.  Packet Headers

   The first octet of the packet header is called the "Packet Tag".  It
   determines the format of the header and denotes the packet contents.
   The remainder of the packet header is the length of the packet.

   There are two packet formats, the (current) OpenPGP packet format
   specified by this document and its predecessors and the Legacy packet
   format as used by PGP 2.x implementations.

   Note that the most significant bit is the leftmost bit, called bit 7.
   A mask for this bit is 0x80 in hexadecimal.

          ┌───────────────┐
     PTag │7 6 5 4 3 2 1 0│
          └───────────────┘
     Bit 7 -- Always one
     Bit 6 -- Always one (except for Legacy packet format)

   The Legacy packet format MAY be used when consuming packets to
   facilitate interoperability with legacy implementations and accessing
   archived data.  The Legacy packet format SHOULD NOT be used to
   generate new data, unless the recipient is known to only support the
   Legacy packet format.

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   An implementation that consumes and re-distributes pre-existing
   OpenPGP data (such as Transferable Public Keys) may encounter packets
   framed with the Legacy packet format.  Such an implementation MAY
   either re-distribute these packets in their Legacy format, or
   transform them to the current OpenPGP packet format before re-
   distribution.

   The current OpenPGP packet format packets contain:

     Bits 5 to 0 -- packet tag

   Legacy packet format packets contain:

     Bits 5 to 2 -- packet tag
     Bits 1 to 0 -- length-type

4.2.1.  OpenPGP Format Packet Lengths

   OpenPGP format packets have four possible ways of encoding length:

   1.  A one-octet Body Length header encodes packet lengths of up to
       191 octets.

   2.  A two-octet Body Length header encodes packet lengths of 192 to
       8383 octets.

   3.  A five-octet Body Length header encodes packet lengths of up to
       4,294,967,295 (0xFFFFFFFF) octets in length.  (This actually
       encodes a four-octet scalar number.)

   4.  When the length of the packet body is not known in advance by the
       issuer, Partial Body Length headers encode a packet of
       indeterminate length, effectively making it a stream.

4.2.1.1.  One-Octet Lengths

   A one-octet Body Length header encodes a length of 0 to 191 octets.
   This type of length header is recognized because the one octet value
   is less than 192.  The body length is equal to:

     bodyLen = 1st_octet;

4.2.1.2.  Two-Octet Lengths

   A two-octet Body Length header encodes a length of 192 to 8383
   octets.  It is recognized because its first octet is in the range 192
   to 223.  The body length is equal to:

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     bodyLen = ((1st_octet - 192) << 8) + (2nd_octet) + 192

4.2.1.3.  Five-Octet Lengths

   A five-octet Body Length header consists of a single octet holding
   the value 255, followed by a four-octet scalar.  The body length is
   equal to:

     bodyLen = (2nd_octet << 24) | (3rd_octet << 16) |
               (4th_octet << 8)  | 5th_octet

   This basic set of one, two, and five-octet lengths is also used
   internally to some packets.

4.2.1.4.  Partial Body Lengths

   A Partial Body Length header is one octet long and encodes the length
   of only part of the data packet.  This length is a power of 2, from 1
   to 1,073,741,824 (2 to the 30th power).  It is recognized by its one
   octet value that is greater than or equal to 224, and less than 255.
   The Partial Body Length is equal to:

     partialBodyLen = 1 << (1st_octet & 0x1F);

   Each Partial Body Length header is followed by a portion of the
   packet body data.  The Partial Body Length header specifies this
   portion's length.  Another length header (one octet, two-octet, five-
   octet, or partial) follows that portion.  The last length header in
   the packet MUST NOT be a Partial Body Length header.  Partial Body
   Length headers may only be used for the non-final parts of the
   packet.

   Note also that the last Body Length header can be a zero-length
   header.

   An implementation MAY use Partial Body Lengths for data packets, be
   they literal, compressed, or encrypted.  The first partial length
   MUST be at least 512 octets long.  Partial Body Lengths MUST NOT be
   used for any other packet types.

4.2.2.  Legacy Format Packet Lengths

   The meaning of the length-type in Legacy format packets is:

   0  The packet has a one-octet length.  The header is 2 octets long.

   1  The packet has a two-octet length.  The header is 3 octets long.

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   2  The packet has a four-octet length.  The header is 5 octets long.

   3  The packet is of indeterminate length.  The header is 1 octet
      long, and the implementation must determine how long the packet
      is.  If the packet is in a file, this means that the packet
      extends until the end of the file.  The OpenPGP format headers
      have a mechanism for precisely encoding data of indeterminate
      length.  An implementation MUST NOT generate a Legacy format
      packet with indeterminate length.  An implementation MAY interpret
      an indeterminate length Legacy format packet in order to deal with
      historic data, or data generated by a legacy system.

4.2.3.  Packet Length Examples

   These examples show ways that OpenPGP format packets might encode the
   packet lengths.

   A packet with length 100 may have its length encoded in one octet:
   0x64.  This is followed by 100 octets of data.

   A packet with length 1723 may have its length encoded in two octets:
   0xC5, 0xFB.  This header is followed by the 1723 octets of data.

   A packet with length 100000 may have its length encoded in five
   octets: 0xFF, 0x00, 0x01, 0x86, 0xA0.

   It might also be encoded in the following octet stream: 0xEF, first
   32768 octets of data; 0xE1, next two octets of data; 0xE0, next one
   octet of data; 0xF0, next 65536 octets of data; 0xC5, 0xDD, last 1693
   octets of data.  This is just one possible encoding, and many
   variations are possible on the size of the Partial Body Length
   headers, as long as a regular Body Length header encodes the last
   portion of the data.

   Please note that in all of these explanations, the total length of
   the packet is the length of the header(s) plus the length of the
   body.

4.3.  Packet Tags

   The packet tag denotes what type of packet the body holds.  Note that
   Legacy format headers can only have tags less than 16, whereas
   OpenPGP format headers can have tags as great as 63.  The defined
   tags (in decimal) are as follows:

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          +=======+==========+=================================+
          |   Tag | Critical | Packet Type                     |
          +=======+==========+=================================+
          |     0 | yes      | Reserved - a packet tag MUST    |
          |       |          | NOT have this value             |
          +-------+----------+---------------------------------+
          |     1 | yes      | Public-Key Encrypted Session    |
          |       |          | Key Packet                      |
          +-------+----------+---------------------------------+
          |     2 | yes      | Signature Packet                |
          +-------+----------+---------------------------------+
          |     3 | yes      | Symmetric-Key Encrypted Session |
          |       |          | Key Packet                      |
          +-------+----------+---------------------------------+
          |     4 | yes      | One-Pass Signature Packet       |
          +-------+----------+---------------------------------+
          |     5 | yes      | Secret-Key Packet               |
          +-------+----------+---------------------------------+
          |     6 | yes      | Public-Key Packet               |
          +-------+----------+---------------------------------+
          |     7 | yes      | Secret-Subkey Packet            |
          +-------+----------+---------------------------------+
          |     8 | yes      | Compressed Data Packet          |
          +-------+----------+---------------------------------+
          |     9 | yes      | Symmetrically Encrypted Data    |
          |       |          | Packet                          |
          +-------+----------+---------------------------------+
          |    10 | yes      | Marker Packet                   |
          +-------+----------+---------------------------------+
          |    11 | yes      | Literal Data Packet             |
          +-------+----------+---------------------------------+
          |    12 | yes      | Trust Packet                    |
          +-------+----------+---------------------------------+
          |    13 | yes      | User ID Packet                  |
          +-------+----------+---------------------------------+
          |    14 | yes      | Public-Subkey Packet            |
          +-------+----------+---------------------------------+
          |    17 | yes      | User Attribute Packet           |
          +-------+----------+---------------------------------+
          |    18 | yes      | Sym. Encrypted and Integrity    |
          |       |          | Protected Data Packet           |
          +-------+----------+---------------------------------+
          |    19 | yes      | Reserved (formerly Modification |
          |       |          | Detection Code Packet)          |
          +-------+----------+---------------------------------+
          |    20 | yes      | Reserved (formerly AEAD         |
          |       |          | Encrypted Data Packet)          |
          +-------+----------+---------------------------------+

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          |    21 | yes      | Padding Packet                  |
          +-------+----------+---------------------------------+
          | 22 to | yes      | Unassigned Critical Packet      |
          |    39 |          |                                 |
          +-------+----------+---------------------------------+
          | 40 to | no       | Unassigned Non-Critical Packet  |
          |    59 |          |                                 |
          +-------+----------+---------------------------------+
          | 60 to | no       | Private or Experimental Values  |
          |    63 |          |                                 |
          +-------+----------+---------------------------------+

                      Table 4: Packet type registry

4.3.1.  Packet Criticality

   The Packet Tag space is partitioned into critical packets and non-
   critical packets.  If an implementation encounters a critical packet
   where the packet type is unknown in a packet sequence, it MUST reject
   the whole packet sequence (see Section 11).  On the other hand, an
   unknown non-critical packet MUST be ignored.

   Packet Tags from 0 to 39 are critical.  Packet Tags from 40 to 63 are
   non-critical.

5.  Packet Types

5.1.  Public-Key Encrypted Session Key Packets (Tag 1)

   Zero or more Public-Key Encrypted Session Key (PKESK) packets and/or
   Symmetric-Key Encrypted Session Key packets (Section 5.3) may precede
   an encryption container (that is, a Symmetrically Encrypted Integrity
   Protected Data packet or --- for historic data --- a Symmetrically
   Encrypted Data packet), which holds an encrypted message.  The
   message is encrypted with the session key, and the session key is
   itself encrypted and stored in the Encrypted Session Key packet(s).
   The encryption container is preceded by one Public-Key Encrypted
   Session Key packet for each OpenPGP key to which the message is
   encrypted.  The recipient of the message finds a session key that is
   encrypted to their public key, decrypts the session key, and then
   uses the session key to decrypt the message.

   The body of this packet starts with a one-octet number giving the
   version number of the packet type.  The currently defined versions
   are 3 and 6.  The remainder of the packet depends on the version.

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   The versions differ in how they identify the recipient key, and in
   what they encode.  The version of the PKESK packet must align with
   the version of the SEIPD packet (see Section 11.3.2.1).

5.1.1.  v3 PKESK

   A version 3 Public-Key Encrypted Session Key (PKESK) packet precedes
   a version 1 Symmetrically Encrypted Integrity Protected Data (v1
   SEIPD, see Section 5.13.1) packet.  In historic data, it is sometimes
   found preceding a deprecated Symmetrically Encrypted Data packet
   (SED, see Section 5.7).  A v3 PKESK packet MUST NOT precede a v2
   SEIPD packet (see Section 11.3.2.1).

   The v3 PKESK packet consists of:

   *  A one-octet version number with value 3.

   *  An eight-octet number that gives the Key ID of the public key to
      which the session key is encrypted.  If the session key is
      encrypted to a subkey, then the Key ID of this subkey is used here
      instead of the Key ID of the primary key.  The Key ID may also be
      all zeros, for an "anonymous recipient" (see Section 5.1.8).

   *  A one-octet number giving the public-key algorithm used.

   *  A series of values comprising the encrypted session key.  This is
      algorithm-specific and described below.

   When creating a v3 PKESK packet, the session key is prefixed with a
   one-octet algorithm identifier that specifies the symmetric
   encryption algorithm used to encrypt the following encryption
   container.

   The resulting octet string (algorithm identifier and session key) is
   encrypted according to the public-key algorithm used, as described
   below.

5.1.2.  v6 PKESK

   A version 6 Public-Key Encrypted Session Key (PKESK) packet precedes
   a version 2 Symmetrically Encrypted Integrity Protected Data (v2
   SEIPD, see Section 5.13.2) packet.  A v6 PKESK packet MUST NOT
   precede a v1 SEIPD packet or a deprecated Symmetrically Encrypted
   Data packet (see Section 11.3.2.1).

   The v6 PKESK packet consists of:

   *  A one-octet version number with value 6.

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   *  A one octet key version number and N octets of the fingerprint of
      the public key or subkey to which the session key is encrypted.
      Note that the length N of the fingerprint for a version 4 key is
      20 octets; for a version 6 key N is 32.  The key version number
      may also be zero, and the fingerprint omitted (that is, the length
      N is zero in this case), for an "anonymous recipient" (see
      Section 5.1.8).

   *  A one-octet number giving the public-key algorithm used.

   *  A series of values comprising the encrypted session key.  This is
      algorithm-specific and described below.

   When creating a v6 PKESK packet, the symmetric encryption algorithm
   identifier is not included.

   The session key is encrypted according to the public-key algorithm
   used, as described below.

5.1.3.  Algorithm-Specific Fields for RSA encryption

   *  Multiprecision integer (MPI) of RSA-encrypted value m**e mod n.

   The value "m" in the above formula is the plaintext value described
   above, with a two-octet checksum appended (equal to the sum of the
   preceding octets, modulo 65536), and then encoded in the PKCS#1 block
   encoding EME-PKCS1-v1_5 described in Section 7.2.1 of [RFC8017] (see
   also Section 13.1).  Note that when an implementation forms several
   PKESKs with one session key, forming a message that can be decrypted
   by several keys, the implementation MUST make a new PKCS#1 encoding
   for each key.

5.1.4.  Algorithm-Specific Fields for Elgamal encryption

   *  MPI of Elgamal (Diffie-Hellman) value g**k mod p.

   *  MPI of Elgamal (Diffie-Hellman) value m * y**k mod p.

   The value "m" in the above formula is the plaintext value described
   above, with a two-octet checksum appended (equal to the sum of the
   preceding octets, modulo 65536), and then encoded in the PKCS#1 block
   encoding EME-PKCS1-v1_5 described in Section 7.2.1 of [RFC8017] (see
   also Section 13.1).  Note that when an implementation forms several
   PKESKs with one session key, forming a message that can be decrypted
   by several keys, the implementation MUST make a new PKCS#1 encoding
   for each key.

   An implementation MUST NOT generate ElGamal v6 PKESKs.

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5.1.5.  Algorithm-Specific Fields for ECDH encryption

   *  MPI of an EC point representing an ephemeral public key, in the
      point format associated with the curve as specified in
      Section 9.2.

   *  A one-octet size, followed by a symmetric key encoded using the
      method described in Section 12.5.

5.1.6.  Algorithm-Specific Fields for X25519 encryption

   *  32 octets representing an ephemeral X25519 public key.

   *  A one-octet size, followed by an encrypted session key.

   See section 6.1 of [RFC7748] for more details on the computation of
   the ephemeral public key and the shared secret.  The shared secret is
   passed to HKDF (see [RFC5869]) using SHA256, and the UTF-8-encoded
   string "OpenPGP X25519" as the info parameter.  The resulting key is
   used to encrypt the session key with AES-128 keywrap, defined in
   [RFC3394].  For v3 PKESK packets, seven zero-octets are added as
   padding after the algorithm identifier and before the session key and
   no checksum is added.  For v6 PKESK packets, no checksum or padding
   are added to the session key before keywrapping.  Additionally,
   unlike ECDH, the derived key is not bound to the recipient key.
   Instead, the Intended Recipient Fingerprint subpacket SHOULD be used
   when creating a signed and encrypted message (see Section 5.2.3.36).

5.1.7.  Algorithm-Specific Fields for X448 encryption

   *  56 octets representing an ephemeral X448 public key.

   *  A one-octet size, followed by an encrypted session key.

   See section 6.2 of [RFC7748] for more details on the computation of
   the ephemeral public key and the shared secret.  The shared secret is
   passed to HKDF (see [RFC5869]) using SHA512, and the UTF-8-encoded
   string "OpenPGP X448" as the info parameter.  The resulting key is
   used to encrypt the session key with AES-256 keywrap, defined in
   [RFC3394].  For v3 PKESK packets, seven zero-octets are added as
   padding after the algorithm identifier and before the session key and
   no checksum is added.  For v6 PKESK packets, no checksum or padding
   are added to the session key before keywrapping.  Additionally,
   unlike ECDH, the derived key is not bound to the recipient key.
   Instead, the Intended Recipient Fingerprint subpacket SHOULD be used
   when creating a signed and encrypted message (see Section 5.2.3.36).

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5.1.8.  Notes on PKESK

   An implementation MAY accept or use a Key ID of all zeros, or a key
   version of zero and no key fingerprint, to hide the intended
   decryption key.  In this case, the receiving implementation would try
   all available private keys, checking for a valid decrypted session
   key.  This format helps reduce traffic analysis of messages.

5.2.  Signature Packet (Tag 2)

   A Signature packet describes a binding between some public key and
   some data.  The most common signatures are a signature of a file or a
   block of text, and a signature that is a certification of a User ID.

   Three versions of Signature packets are defined.  Version 3 provides
   basic signature information, while versions 4 and 6 provide an
   expandable format with subpackets that can specify more information
   about the signature.

   For historical reasons, versions 1, 2, and 5 of the Signature packet
   are unspecified.

   An implementation MUST generate a version 6 signature when signing
   with a version 6 key.  An implementation MUST generate a version 4
   signature when signing with a version 4 key.  Implementations MUST
   NOT create version 3 signatures; they MAY accept version 3
   signatures.

5.2.1.  Signature Types

   There are a number of possible meanings for a signature, which are
   indicated in a signature type octet in any given signature.  Please
   note that the vagueness of these meanings is not a flaw, but a
   feature of the system.  Because OpenPGP places final authority for
   validity upon the receiver of a signature, it may be that one
   signer's casual act might be more rigorous than some other
   authority's positive act.  See Section 5.2.4 for detailed information
   on how to compute and verify signatures of each type.

   These meanings are as follows:

   0x00: Signature of a binary document.
      This means the signer owns it, created it, or certifies that it
      has not been modified.

   0x01: Signature of a canonical text document.

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      This means the signer owns it, created it, or certifies that it
      has not been modified.  The signature is calculated over the text
      data with its line endings converted to <CR><LF>.

   0x02: Standalone signature.
      This signature is a signature of only its own subpacket contents.
      It is calculated identically to a signature over a zero-length
      binary document.  V3 standalone signatures MUST NOT be generated
      and MUST be ignored.

   0x10: Generic certification of a User ID and Public-Key packet.
      The issuer of this certification does not make any particular
      assertion as to how well the certifier has checked that the owner
      of the key is in fact the person described by the User ID.

   0x11: Persona certification of a User ID and Public-Key packet.
      The issuer of this certification has not done any verification of
      the claim that the owner of this key is the User ID specified.

   0x12: Casual certification of a User ID and Public-Key packet.
      The issuer of this certification has done some casual verification
      of the claim of identity.

   0x13: Positive certification of a User ID and Public-Key packet.
      The issuer of this certification has done substantial verification
      of the claim of identity.

      Most OpenPGP implementations make their "key signatures" as 0x10
      certifications.  Some implementations can issue 0x11-0x13
      certifications, but few differentiate between the types.

   0x18: Subkey Binding Signature.
      This signature is a statement by the top-level signing key that
      indicates that it owns the subkey.  This signature is calculated
      directly on the primary key and subkey, and not on any User ID or
      other packets.  A signature that binds a signing subkey MUST have
      an Embedded Signature subpacket in this binding signature that
      contains a 0x19 signature made by the signing subkey on the
      primary key and subkey.

   0x19: Primary Key Binding Signature.
      This signature is a statement by a signing subkey, indicating that
      it is owned by the primary key and subkey.  This signature is
      calculated the same way as a 0x18 signature: directly on the
      primary key and subkey, and not on any User ID or other packets.

   0x1F: Signature directly on a key.

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      This signature is calculated directly on a key.  It binds the
      information in the Signature subpackets to the key, and is
      appropriate to be used for subpackets that provide information
      about the key, such as the Key Flags subpacket or (deprecated)
      Revocation Key. It is also appropriate for statements that non-
      self certifiers want to make about the key itself, rather than the
      binding between a key and a name.

   0x20: Key revocation signature.
      The signature is calculated directly on the key being revoked.  A
      revoked key is not to be used.  Only revocation signatures by the
      key being revoked, or by a (deprecated) Revocation Key, should be
      considered valid revocation signatures.

   0x28: Subkey revocation signature.
      The signature is calculated directly on the subkey being revoked.
      A revoked subkey is not to be used.  Only revocation signatures by
      the top-level signature key that is bound to this subkey, or by a
      (deprecated) Revocation Key, should be considered valid revocation
      signatures.

   0x30: Certification revocation signature.
      This signature revokes an earlier User ID certification signature
      (signature class 0x10 through 0x13) or direct-key signature
      (0x1F).  It should be issued by the same key that issued the
      revoked signature or by a (deprecated) Revocation Key. The
      signature is computed over the same data as the certificate that
      it revokes, and should have a later creation date than that
      certificate.

   0x40: Timestamp signature.
      This signature is only meaningful for the timestamp contained in
      it.

   0x50: Third-Party Confirmation signature.
      This signature is a signature over some other OpenPGP Signature
      packet(s).  It is analogous to a notary seal on the signed data.
      A third-party signature SHOULD include Signature Target
      subpacket(s) to give easy identification.  Note that we really do
      mean SHOULD.  There are plausible uses for this (such as a blind
      party that only sees the signature, not the key or source
      document) that cannot include a target subpacket.

   0xFF: Reserved.
      An implementation MUST NOT create any signature with this type,
      and MUST NOT validate any signature made with this type.  See
      Section 5.2.4.1 for more details.

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5.2.2.  Version 3 Signature Packet Format

   The body of a version 3 Signature Packet contains:

   *  One-octet version number (3).

   *  One-octet length of following hashed material.  MUST be 5.

      -  One-octet signature type.

      -  Four-octet creation time.

   *  Eight-octet Key ID of signer.

   *  One-octet public-key algorithm.

   *  One-octet hash algorithm.

   *  Two-octet field holding left 16 bits of signed hash value.

   *  One or more multiprecision integers comprising the signature.
      This portion is algorithm-specific, as described below.

   The concatenation of the data to be signed, the signature type, and
   creation time from the Signature packet (5 additional octets) is
   hashed.  The resulting hash value is used in the signature algorithm.
   The high 16 bits (first two octets) of the hash are included in the
   Signature packet to provide a way to reject some invalid signatures
   without performing a signature verification.

   Algorithm-Specific Fields for RSA signatures:

   *  Multiprecision integer (MPI) of RSA signature value m**d mod n.

   Algorithm-Specific Fields for DSA signatures:

   *  MPI of DSA value r.

   *  MPI of DSA value s.

   The signature calculation is based on a hash of the signed data, as
   described above.  The details of the calculation are different for
   DSA signatures than for RSA signatures.

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   With RSA signatures, the hash value is encoded using PKCS#1 encoding
   type EMSA-PKCS1-v1_5 as described in Section 9.2 of [RFC8017].  This
   requires inserting the hash value as an octet string into an ASN.1
   structure.  The object identifier for the type of hash being used is
   included in the structure.  The hexadecimal representations for the
   currently defined hash algorithms are as follows:

   +============+======================================================+
   | algorithm  | hexadecimal representation                           |
   +============+======================================================+
   | MD5        | 0x2A, 0x86, 0x48, 0x86, 0xF7, 0x0D, 0x02, 0x05       |
   +------------+------------------------------------------------------+
   | RIPEMD-160 | 0x2B, 0x24, 0x03, 0x02, 0x01                         |
   +------------+------------------------------------------------------+
   | SHA-1      | 0x2B, 0x0E, 0x03, 0x02, 0x1A                         |
   +------------+------------------------------------------------------+
   | SHA224     | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04,            |
   |            | 0x02, 0x04                                           |
   +------------+------------------------------------------------------+
   | SHA256     | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04,            |
   |            | 0x02, 0x01                                           |
   +------------+------------------------------------------------------+
   | SHA384     | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04,            |
   |            | 0x02, 0x02                                           |
   +------------+------------------------------------------------------+
   | SHA512     | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04,            |
   |            | 0x02, 0x03                                           |
   +------------+------------------------------------------------------+

                 Table 5: Hash hexadecimal representations

   The ASN.1 Object Identifiers (OIDs) are as follows:

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                  +============+========================+
                  | algorithm  | OID                    |
                  +============+========================+
                  | MD5        | 1.2.840.113549.2.5     |
                  +------------+------------------------+
                  | RIPEMD-160 | 1.3.36.3.2.1           |
                  +------------+------------------------+
                  | SHA-1      | 1.3.14.3.2.26          |
                  +------------+------------------------+
                  | SHA224     | 2.16.840.1.101.3.4.2.4 |
                  +------------+------------------------+
                  | SHA256     | 2.16.840.1.101.3.4.2.1 |
                  +------------+------------------------+
                  | SHA384     | 2.16.840.1.101.3.4.2.2 |
                  +------------+------------------------+
                  | SHA512     | 2.16.840.1.101.3.4.2.3 |
                  +------------+------------------------+

                             Table 6: Hash OIDs

   The full hash prefixes for these are as follows:

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         +============+==========================================+
         | algorithm  | full hash prefix                         |
         +============+==========================================+
         | MD5        | 0x30, 0x20, 0x30, 0x0C, 0x06, 0x08,      |
         |            | 0x2A, 0x86, 0x48, 0x86, 0xF7, 0x0D,      |
         |            | 0x02, 0x05, 0x05, 0x00, 0x04, 0x10       |
         +------------+------------------------------------------+
         | RIPEMD-160 | 0x30, 0x21, 0x30, 0x09, 0x06, 0x05,      |
         |            | 0x2B, 0x24, 0x03, 0x02, 0x01, 0x05,      |
         |            | 0x00, 0x04, 0x14                         |
         +------------+------------------------------------------+
         | SHA-1      | 0x30, 0x21, 0x30, 0x09, 0x06, 0x05,      |
         |            | 0x2B, 0x0E, 0x03, 0x02, 0x1A, 0x05,      |
         |            | 0x00, 0x04, 0x14                         |
         +------------+------------------------------------------+
         | SHA224     | 0x30, 0x2D, 0x30, 0x0D, 0x06, 0x09,      |
         |            | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03,      |
         |            | 0x04, 0x02, 0x04, 0x05, 0x00, 0x04, 0x1C |
         +------------+------------------------------------------+
         | SHA256     | 0x30, 0x31, 0x30, 0x0D, 0x06, 0x09,      |
         |            | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03,      |
         |            | 0x04, 0x02, 0x01, 0x05, 0x00, 0x04, 0x20 |
         +------------+------------------------------------------+
         | SHA384     | 0x30, 0x41, 0x30, 0x0D, 0x06, 0x09,      |
         |            | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03,      |
         |            | 0x04, 0x02, 0x02, 0x05, 0x00, 0x04, 0x30 |
         +------------+------------------------------------------+
         | SHA512     | 0x30, 0x51, 0x30, 0x0D, 0x06, 0x09,      |
         |            | 0x60, 0x86, 0x48, 0x01, 0x65, 0x03,      |
         |            | 0x04, 0x02, 0x03, 0x05, 0x00, 0x04, 0x40 |
         +------------+------------------------------------------+

                     Table 7: Hash hexadecimal prefixes

   DSA signatures MUST use hashes that are equal in size to the number
   of bits of q, the group generated by the DSA key's generator value.

   If the output size of the chosen hash is larger than the number of
   bits of q, the hash result is truncated to fit by taking the number
   of leftmost bits equal to the number of bits of q.  This (possibly
   truncated) hash function result is treated as a number and used
   directly in the DSA signature algorithm.

5.2.3.  Version 4 and 6 Signature Packet Formats

   The body of a v4 or v6 Signature packet contains:

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   *  One-octet version number.  This is 4 for v4 signatures and 6 for
      v6 signatures.

   *  One-octet signature type.

   *  One-octet public-key algorithm.

   *  One-octet hash algorithm.

   *  A scalar octet count for the following hashed subpacket data.  For
      a v4 signature, this is a two-octet field.  For a v6 signature,
      this is a four-octet field.  Note that this is the length in
      octets of all of the hashed subpackets; a pointer incremented by
      this number will skip over the hashed subpackets.

   *  Hashed subpacket data set (zero or more subpackets).

   *  A scalar octet count for the following unhashed subpacket data.
      For a v4 signature, this is a two-octet field.  For a v6
      signature, this is a four-octet field.  Note that this is the
      length in octets of all of the unhashed subpackets; a pointer
      incremented by this number will skip over the unhashed subpackets.

   *  Unhashed subpacket data set (zero or more subpackets).

   *  Two-octet field holding the left 16 bits of the signed hash value.

   *  Only for v6 signatures, a variable-length field containing:

      -  A one-octet salt size.  The value MUST match the value defined
         for the hash algorithm as specified in table Table 23.

      -  The salt; a random value value of the specified size.

   *  One or more multiprecision integers comprising the signature.
      This portion is algorithm-specific:

5.2.3.1.  Algorithm-Specific Fields for RSA signatures

   *  Multiprecision integer (MPI) of RSA signature value m**d mod n.

5.2.3.2.  Algorithm-Specific Fields for DSA or ECDSA signatures

   *  MPI of DSA or ECDSA value r.

   *  MPI of DSA or ECDSA value s.

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   A version 3 signature MUST NOT be created and MUST NOT be used with
   ECDSA.

5.2.3.3.  Algorithm-Specific Fields for EdDSALegacy signatures
          (deprecated)

   *  Two MPI-encoded values, whose contents and formatting depend on
      the choice of curve used (see Section 9.2.1).

   A version 3 signature MUST NOT be created and MUST NOT be used with
   EdDSALegacy.

5.2.3.3.1.  Algorithm-Specific Fields for Ed25519Legacy signatures
            (deprecated)

   The two MPIs for Ed25519Legacy use octet strings R and S as described
   in [RFC8032].  Ed25519Legacy MUST NOT be used in signature packets
   version 6 or above.

   *  MPI of an EC point R, represented as a (non-prefixed) native
      (little-endian) octet string up to 32 octets.

   *  MPI of EdDSA value S, also in (non-prefixed) native (little-
      endian) format with a length up to 32 octets.

5.2.3.4.  Algorithm-Specific Fields for Ed25519 signatures

   *  64 octets of the native signature.

   For more details, see Section 13.7.

   A version 3 signature MUST NOT be created and MUST NOT be used with
   Ed25519.

5.2.3.5.  Algorithm-Specific Fields for Ed448 signatures

   *  114 octets of the native signature.

   For more details, see Section 13.7.

   A version 3 signature MUST NOT be created and MUST NOT be used with
   Ed448.

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5.2.3.6.  Notes on Signatures

   The concatenation of the data being signed and the signature data
   from the version number through the hashed subpacket data (inclusive)
   is hashed.  The resulting hash value is what is signed.  The high 16
   bits (first two octets) of the hash are included in the Signature
   packet to provide a way to reject some invalid signatures without
   performing a signature verification.  When verifying a v6 signature,
   an implementation MUST reject the signature if these octets don't
   match the first two octets of the computed hash.

   There are two fields consisting of Signature subpackets.  The first
   field is hashed with the rest of the signature data, while the second
   is unhashed.  The second set of subpackets is not cryptographically
   protected by the signature and should include only advisory
   information.

   The differences between a v4 and v6 signature are two-fold: first, a
   v6 signature increases the width of the fields that indicate the size
   of the hashed and unhashed subpackets, making it possible to include
   significantly more data in subpackets.  Second, the hash is salted
   with random data (see Section 14.2).

   The algorithms for converting the hash function result to a signature
   are described in Section 5.2.4.

5.2.3.7.  Signature Subpacket Specification

   A subpacket data set consists of zero or more Signature subpackets.
   In Signature packets, the subpacket data set is preceded by a two-
   octet (for v4 signatures) or four-octet (for v6 signatures) scalar
   count of the length in octets of all the subpackets.  A pointer
   incremented by this number will skip over the subpacket data set.

   Each subpacket consists of a subpacket header and a body.  The header
   consists of:

   *  The subpacket length (1, 2, or 5 octets),

   *  The subpacket type (1 octet),

   and is followed by the subpacket-specific data.

   The length includes the type octet but not this length.  Its format
   is similar to the OpenPGP format packet header lengths, but cannot
   have Partial Body Lengths.  That is:

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   if the 1st octet <  192, then
       lengthOfLength = 1
       subpacketLen = 1st_octet

   if the 1st octet >= 192 and < 255, then
       lengthOfLength = 2
       subpacketLen = ((1st_octet - 192) << 8) + (2nd_octet) + 192

   if the 1st octet = 255, then
       lengthOfLength = 5
       subpacket length = [four-octet scalar starting at 2nd_octet]

   The value of the subpacket type octet may be:

         +============+==========================================+
         |       Type | Description                              |
         +============+==========================================+
         |          0 | Reserved                                 |
         +------------+------------------------------------------+
         |          1 | Reserved                                 |
         +------------+------------------------------------------+
         |          2 | Signature Creation Time                  |
         +------------+------------------------------------------+
         |          3 | Signature Expiration Time                |
         +------------+------------------------------------------+
         |          4 | Exportable Certification                 |
         +------------+------------------------------------------+
         |          5 | Trust Signature                          |
         +------------+------------------------------------------+
         |          6 | Regular Expression                       |
         +------------+------------------------------------------+
         |          7 | Revocable                                |
         +------------+------------------------------------------+
         |          8 | Reserved                                 |
         +------------+------------------------------------------+
         |          9 | Key Expiration Time                      |
         +------------+------------------------------------------+
         |         10 | Placeholder for backward compatibility   |
         +------------+------------------------------------------+
         |         11 | Preferred Symmetric Ciphers for v1 SEIPD |
         +------------+------------------------------------------+
         |         12 | Revocation Key (deprecated)              |
         +------------+------------------------------------------+
         |   13 to 15 | Reserved                                 |
         +------------+------------------------------------------+
         |         16 | Issuer Key ID                            |
         +------------+------------------------------------------+
         |   17 to 19 | Reserved                                 |

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         +------------+------------------------------------------+
         |         20 | Notation Data                            |
         +------------+------------------------------------------+
         |         21 | Preferred Hash Algorithms                |
         +------------+------------------------------------------+
         |         22 | Preferred Compression Algorithms         |
         +------------+------------------------------------------+
         |         23 | Key Server Preferences                   |
         +------------+------------------------------------------+
         |         24 | Preferred Key Server                     |
         +------------+------------------------------------------+
         |         25 | Primary User ID                          |
         +------------+------------------------------------------+
         |         26 | Policy URI                               |
         +------------+------------------------------------------+
         |         27 | Key Flags                                |
         +------------+------------------------------------------+
         |         28 | Signer's User ID                         |
         +------------+------------------------------------------+
         |         29 | Reason for Revocation                    |
         +------------+------------------------------------------+
         |         30 | Features                                 |
         +------------+------------------------------------------+
         |         31 | Signature Target                         |
         +------------+------------------------------------------+
         |         32 | Embedded Signature                       |
         +------------+------------------------------------------+
         |         33 | Issuer Fingerprint                       |
         +------------+------------------------------------------+
         |         34 | Reserved                                 |
         +------------+------------------------------------------+
         |         35 | Intended Recipient Fingerprint           |
         +------------+------------------------------------------+
         |         37 | Reserved (Attested Certifications)       |
         +------------+------------------------------------------+
         |         38 | Reserved (Key Block)                     |
         +------------+------------------------------------------+
         |         39 | Preferred AEAD Ciphersuites              |
         +------------+------------------------------------------+
         | 100 to 110 | Private or experimental                  |
         +------------+------------------------------------------+

                      Table 8: Subpacket type registry

   An implementation SHOULD ignore any subpacket of a type that it does
   not recognize.

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   Bit 7 of the subpacket type is the "critical" bit.  If set, it
   denotes that the subpacket is one that is critical for the evaluator
   of the signature to recognize.  If a subpacket is encountered that is
   marked critical but is unknown to the evaluating software, the
   evaluator SHOULD consider the signature to be in error.

   An evaluator may "recognize" a subpacket, but not implement it.  The
   purpose of the critical bit is to allow the signer to tell an
   evaluator that it would prefer a new, unknown feature to generate an
   error rather than being ignored.

   Implementations SHOULD implement the four preferred algorithm
   subpackets (11, 21, 22, and 39), as well as the "Reason for
   Revocation" subpacket.  Note, however, that if an implementation
   chooses not to implement some of the preferences, it is required to
   behave in a polite manner to respect the wishes of those users who do
   implement these preferences.

5.2.3.8.  Signature Subpacket Types

   A number of subpackets are currently defined.  Some subpackets apply
   to the signature itself and some are attributes of the key.
   Subpackets that are found on a self-signature are placed on a
   certification made by the key itself.  Note that a key may have more
   than one User ID, and thus may have more than one self-signature, and
   differing subpackets.

   A subpacket may be found either in the hashed or unhashed subpacket
   sections of a signature.  If a subpacket is not hashed, then the
   information in it cannot be considered definitive because it is not
   part of the signature proper.

5.2.3.9.  Notes on Subpackets

   It is certainly possible for a signature to contain conflicting
   information in subpackets.  For example, a signature may contain
   multiple copies of a preference or multiple expiration times.  In
   most cases, an implementation SHOULD use the last subpacket in the
   signature, but MAY use any conflict resolution scheme that makes more
   sense.  Please note that we are intentionally leaving conflict
   resolution to the implementer; most conflicts are simply syntax
   errors, and the wishy-washy language here allows a receiver to be
   generous in what they accept, while putting pressure on a creator to
   be stingy in what they generate.

   Some apparent conflicts may actually make sense --- for example,
   suppose a keyholder has a v3 key and a v4 key that share the same RSA
   key material.  Either of these keys can verify a signature created by

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   the other, and it may be reasonable for a signature to contain an
   Issuer Key ID subpacket (Section 5.2.3.12) for each key, as a way of
   explicitly tying those keys to the signature.

5.2.3.10.  Notes on Self-Signatures

   A self-signature is a binding signature made by the key to which the
   signature refers.  There are three types of self-signatures, the
   certification signatures (types 0x10-0x13), the direct-key signature
   (type 0x1F), and the subkey binding signature (type 0x18).  A
   cryptographically-valid self-signature should be accepted from any
   primary key, regardless of what Key Flags (Section 5.2.3.29) apply to
   the primary key.  In particular, a primary key does not need to have
   0x01 set in the first octet of Key Flags order to make a valid self-
   signature.

   For certification self-signatures, each User ID may have a self-
   signature, and thus different subpackets in those self-signatures.
   For subkey binding signatures, each subkey in fact has a self-
   signature.  Subpackets that appear in a certification self-signature
   apply to the user name, and subpackets that appear in the subkey
   self-signature apply to the subkey.  Lastly, subpackets on the
   direct-key signature apply to the entire key.

   Implementing software should interpret a self-signature's preference
   subpackets as narrowly as possible.  For example, suppose a key has
   two user names, Alice and Bob. Suppose that Alice prefers the AEAD
   ciphersuite AES-256 with OCB, and Bob prefers Camellia-256 with GCM.
   If the software locates this key via Alice's name, then the preferred
   AEAD ciphersuite is AES-256 with OCB; if software locates the key via
   Bob's name, then the preferred algorithm is Camellia-256 with GCM.
   If the key is located by Key ID, the algorithm of the primary User ID
   of the key provides the preferred AEAD ciphersuite.

   Revoking a self-signature or allowing it to expire has a semantic
   meaning that varies with the signature type.  Revoking the self-
   signature on a User ID effectively retires that user name.  The self-
   signature is a statement, "My name X is tied to my signing key K" and
   is corroborated by other users' certifications.  If another user
   revokes their certification, they are effectively saying that they no
   longer believe that name and that key are tied together.  Similarly,
   if the users themselves revoke their self-signature, then the users
   no longer go by that name, no longer have that email address, etc.
   Revoking a binding signature effectively retires that subkey.
   Revoking a direct-key signature cancels that signature.  Please see
   Section 5.2.3.31 for more relevant detail.

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   Since a self-signature contains important information about the key's
   use, an implementation SHOULD allow the user to rewrite the self-
   signature, and important information in it, such as preferences and
   key expiration.

   It is good practice to verify that a self-signature imported into an
   implementation doesn't advertise features that the implementation
   doesn't support, rewriting the signature as appropriate.

   An implementation that encounters multiple self-signatures on the
   same object MUST select the most recent valid self-signature, and
   ignore all other self-signatures.

   By convention, a version 4 key stores information about the primary
   Public-Key (key flags, key expiration, etc.) and the Transferable
   Public Key as a whole (features, algorithm preferences, etc.) in a
   User ID self-signature of type 0x10 or 0x13.  Some implementations
   require at least one User ID with a valid self-signature to be
   present to use a v4 key.  For this reason, it is RECOMMENDED to
   include at least one User ID with a self-signature in v4 keys.

   For version 6 keys, it is RECOMMENDED to store information about the
   primary Public-Key as well as the Transferable Public Key as a whole
   (key flags, key expiration, features, algorithm preferences, etc.) in
   a direct-key signature (type 0x1F) over the Public-Key instead of
   placing that information in a User ID self-signature.  An
   implementation MUST ensure that a valid direct-key signature is
   present before using a v6 key.  This prevents certain attacks where
   an adversary strips a self-signature specifying a key expiration time
   or certain preferences.

   An implementation SHOULD NOT require a User ID self-signature to be
   present in order to consume or use a key, unless the particular use
   is contingent on the keyholder identifying themselves with the
   textual label in the User ID.  For example, when refreshing a key to
   learn about changes in expiration, advertised features, algorithm
   preferences, revocation, subkey rotation, and so forth, there is no
   need to require a User ID self-signature.  On the other hand, when
   verifying a signature over an e-mail message, an implementation MAY
   choose to only accept a signature from a key that has a valid self-
   signature over a User ID that matches the message's From: header, as
   a way to avoid a signature transplant attack.

5.2.3.11.  Signature Creation Time

   (4-octet time field)

   The time the signature was made.

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   MUST be present in the hashed area.

5.2.3.12.  Issuer Key ID

   (8-octet Key ID)

   The OpenPGP Key ID of the key issuing the signature.  If the version
   of that key is greater than 4, this subpacket MUST NOT be included in
   the signature.  For these keys, consider the Issuer Fingerprint
   subpacket (Section 5.2.3.35) instead.

   Note: in previous versions of this specification, this subpacket was
   simply known as the "Issuer" subpacket.

5.2.3.13.  Key Expiration Time

   (4-octet time field)

   The validity period of the key.  This is the number of seconds after
   the key creation time that the key expires.  For a direct or
   certification self-signature, the key creation time is that of the
   primary key.  For a subkey binding signature, the key creation time
   is that of the subkey.  If this is not present or has a value of
   zero, the key never expires.  This is found only on a self-signature.

5.2.3.14.  Preferred Symmetric Ciphers for v1 SEIPD

   (array of one-octet values)

   A series of symmetric cipher algorithm identifiers indicating how the
   keyholder prefers to receive version 1 Symmetrically Encrypted
   Integrity Protected Data (Section 5.13.1).  The subpacket body is an
   ordered list of octets with the most preferred listed first.  It is
   assumed that only algorithms listed are supported by the recipient's
   software.  Algorithm numbers are in Section 9.3.  This is only found
   on a self-signature.

   When generating a v2 SEIPD packet, this preference list is not
   relevant.  See Section 5.2.3.15 instead.

5.2.3.15.  Preferred AEAD Ciphersuites

   (array of pairs of octets indicating Symmetric Cipher and AEAD
   algorithms)

   A series of paired algorithm identifiers indicating how the keyholder
   prefers to receive version 2 Symmetrically Encrypted Integrity
   Protected Data (Section 5.13.2).  Each pair of octets indicates a

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   combination of a symmetric cipher and an AEAD mode that the key
   holder prefers to use.  The symmetric cipher identifier precedes the
   AEAD identifier in each pair.  The subpacket body is an ordered list
   of pairs of octets with the most preferred algorithm combination
   listed first.

   It is assumed that only the combinations of algorithms listed are
   supported by the recipient's software, with the exception of the
   mandatory-to-implement combination of AES-128 and OCB.  If AES-128
   and OCB are not found in the subpacket, it is implicitly listed at
   the end.

   AEAD algorithm numbers are listed in Section 9.6.  Symmetric cipher
   algorithm numbers are listed in Section 9.3.

   For example, a subpacket with content of these six octets:

   09 02 09 03 13 02

   Indicates that the keyholder prefers to receive v2 SEIPD using
   AES-256 with OCB, then AES-256 with GCM, then Camellia-256 with OCB,
   and finally the implicit AES-128 with OCB.

   Note that support for version 2 of the Symmetrically Encrypted
   Integrity Protected Data packet (Section 5.13.2) in general is
   indicated by a Feature Flag (Section 5.2.3.32).

   This subpacket is only found on a self-signature.

   When generating a v1 SEIPD packet, this preference list is not
   relevant.  See Section 5.2.3.14 instead.

5.2.3.16.  Preferred Hash Algorithms

   (array of one-octet values)

   Message digest algorithm numbers that indicate which algorithms the
   key holder prefers to receive.  Like the preferred AEAD ciphersuites,
   the list is ordered.  Algorithm numbers are in Section 9.5.  This is
   only found on a self-signature.

5.2.3.17.  Preferred Compression Algorithms

   (array of one-octet values)

   Compression algorithm numbers that indicate which algorithms the key
   holder prefers to use.  Like the preferred AEAD ciphersuites, the
   list is ordered.  Algorithm numbers are in Section 9.4.  A zero, or

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   the absence of this subpacket, denotes that uncompressed data is
   preferred; the key holder's software might have no compression
   software in that implementation.  This is only found on a self-
   signature.

5.2.3.18.  Signature Expiration Time

   (4-octet time field)

   The validity period of the signature.  This is the number of seconds
   after the signature creation time that the signature expires.  If
   this is not present or has a value of zero, it never expires.

5.2.3.19.  Exportable Certification

   (1 octet of exportability, 0 for not, 1 for exportable)

   This subpacket denotes whether a certification signature is
   "exportable", to be used by other users than the signature's issuer.
   The packet body contains a Boolean flag indicating whether the
   signature is exportable.  If this packet is not present, the
   certification is exportable; it is equivalent to a flag containing a
   1.

   Non-exportable, or "local", certifications are signatures made by a
   user to mark a key as valid within that user's implementation only.

   Thus, when an implementation prepares a user's copy of a key for
   transport to another user (this is the process of "exporting" the
   key), any local certification signatures are deleted from the key.

   The receiver of a transported key "imports" it, and likewise trims
   any local certifications.  In normal operation, there won't be any,
   assuming the import is performed on an exported key.  However, there
   are instances where this can reasonably happen.  For example, if an
   implementation allows keys to be imported from a key database in
   addition to an exported key, then this situation can arise.

   Some implementations do not represent the interest of a single user
   (for example, a key server).  Such implementations always trim local
   certifications from any key they handle.

5.2.3.20.  Revocable

   (1 octet of revocability, 0 for not, 1 for revocable)

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   Signature's revocability status.  The packet body contains a Boolean
   flag indicating whether the signature is revocable.  Signatures that
   are not revocable have any later revocation signatures ignored.  They
   represent a commitment by the signer that he cannot revoke his
   signature for the life of his key.  If this packet is not present,
   the signature is revocable.

5.2.3.21.  Trust Signature

   (1 octet "level" (depth), 1 octet of trust amount)

   Signer asserts that the key is not only valid but also trustworthy at
   the specified level.  Level 0 has the same meaning as an ordinary
   validity signature.  Level 1 means that the signed key is asserted to
   be a valid trusted introducer, with the 2nd octet of the body
   specifying the degree of trust.  Level 2 means that the signed key is
   asserted to be trusted to issue level 1 trust signatures; that is,
   the signed key is a "meta introducer".  Generally, a level n trust
   signature asserts that a key is trusted to issue level n-1 trust
   signatures.  The trust amount is in a range from 0-255, interpreted
   such that values less than 120 indicate partial trust and values of
   120 or greater indicate complete trust.  Implementations SHOULD emit
   values of 60 for partial trust and 120 for complete trust.

5.2.3.22.  Regular Expression

   (null-terminated regular expression)

   Used in conjunction with trust Signature packets (of level > 0) to
   limit the scope of trust that is extended.  Only signatures by the
   target key on User IDs that match the regular expression in the body
   of this packet have trust extended by the trust Signature subpacket.
   The regular expression uses the same syntax as the Henry Spencer's
   "almost public domain" regular expression [REGEX] package.  A
   description of the syntax is found in Section 8.

5.2.3.23.  Revocation Key

   (1 octet of class, 1 octet of public-key algorithm ID, 20 octets of
   v4 fingerprint)

   This mechanism is deprecated.  Applications MUST NOT generate such a
   subpacket.

   An application that wants the functionality of delegating revocation
   SHOULD instead use an escrowed Revocation Signature.  See
   Section 14.8 for more details.

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   The remainder of this section describes how some implementations
   attempt to interpret this deprecated subpacket.

   This packet was intended to authorize the specified key to issue
   revocation signatures for this key.  Class octet must have bit 0x80
   set.  If the bit 0x40 is set, then this means that the revocation
   information is sensitive.  Other bits are for future expansion to
   other kinds of authorizations.  This is only found on a direct-key
   self-signature (type 0x1f).  The use on other types of self-
   signatures is unspecified.

   If the "sensitive" flag is set, the keyholder feels this subpacket
   contains private trust information that describes a real-world
   sensitive relationship.  If this flag is set, implementations SHOULD
   NOT export this signature to other users except in cases where the
   data needs to be available: when the signature is being sent to the
   designated revoker, or when it is accompanied by a revocation
   signature from that revoker.  Note that it may be appropriate to
   isolate this subpacket within a separate signature so that it is not
   combined with other subpackets that need to be exported.

5.2.3.24.  Notation Data

   (4 octets of flags, 2 octets of name length (M), 2 octets of value
   length (N), M octets of name data, N octets of value data)

   This subpacket describes a "notation" on the signature that the
   issuer wishes to make.  The notation has a name and a value, each of
   which are strings of octets.  There may be more than one notation in
   a signature.  Notations can be used for any extension the issuer of
   the signature cares to make.  The "flags" field holds four octets of
   flags.

   All undefined flags MUST be zero.  Defined flags are as follows:

    +====+=========+===========+===========+================+=========+
    |Flag|Shorthand|Description|Security   |Interoperability|Reference|
    |    |         |           |Recommended|Recommended     |         |
    +====+=========+===========+===========+================+=========+
    |0x80|human-   |Notation   |No         |Yes             |This     |
    |0x00|readable |value is   |           |                |document |
    |0x00|         |text.      |           |                |         |
    |0x00|         |           |           |                |         |
    +----+---------+-----------+-----------+----------------+---------+

     Table 9: Signature Notation Data Subpacket Notation Flag registry

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   Notation names are arbitrary strings encoded in UTF-8.  They reside
   in two namespaces: The IETF namespace and the user namespace.

   The IETF namespace is registered with IANA.  These names MUST NOT
   contain the "@" character (0x40).  This is a tag for the user
   namespace.

        +===============+===========+================+===========+
        | Notation Name | Data Type | Allowed Values | Reference |
        +===============+===========+================+===========+
        +---------------+-----------+----------------+-----------+

           Table 10: Signature Notation Data Subpacket registry

   Names in the user namespace consist of a UTF-8 string tag followed by
   "@" followed by a DNS domain name.  Note that the tag MUST NOT
   contain an "@" character.  For example, the "sample" tag used by
   Example Corporation could be "sample@example.com".

   Names in a user space are owned and controlled by the owners of that
   domain.  Obviously, it's bad form to create a new name in a DNS space
   that you don't own.

   Since the user namespace is in the form of an email address,
   implementers MAY wish to arrange for that address to reach a person
   who can be consulted about the use of the named tag.  Note that due
   to UTF-8 encoding, not all valid user space name tags are valid email
   addresses.

   If there is a critical notation, the criticality applies to that
   specific notation and not to notations in general.

5.2.3.25.  Key Server Preferences

   (N octets of flags)

   This is a list of one-bit flags that indicate preferences that the
   key holder has about how the key is handled on a key server.  All
   undefined flags MUST be zero.

   First octet:

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     +======+===========+============================================+
     | flag | shorthand | definition                                 |
     +======+===========+============================================+
     | 0x80 | No-modify | The key holder requests that this key only |
     |      |           | be modified or updated by the key holder   |
     |      |           | or an administrator of the key server.     |
     +------+-----------+--------------------------------------------+

        Table 11: Key server preferences flag registry (first octet)

   This is found only on a self-signature.

5.2.3.26.  Preferred Key Server

   (String)

   This is a URI of a key server that the key holder prefers be used for
   updates.  Note that keys with multiple User IDs can have a preferred
   key server for each User ID.  Note also that since this is a URI, the
   key server can actually be a copy of the key retrieved by ftp, http,
   finger, etc.

5.2.3.27.  Primary User ID

   (1 octet, Boolean)

   This is a flag in a User ID's self-signature that states whether this
   User ID is the main User ID for this key.  It is reasonable for an
   implementation to resolve ambiguities in preferences, etc. by
   referring to the primary User ID.  If this flag is absent, its value
   is zero.  If more than one User ID in a key is marked as primary, the
   implementation may resolve the ambiguity in any way it sees fit, but
   it is RECOMMENDED that priority be given to the User ID with the most
   recent self-signature.

   When appearing on a self-signature on a User ID packet, this
   subpacket applies only to User ID packets.  When appearing on a self-
   signature on a User Attribute packet, this subpacket applies only to
   User Attribute packets.  That is to say, there are two different and
   independent "primaries" --- one for User IDs, and one for User
   Attributes.

5.2.3.28.  Policy URI

   (String)

   This subpacket contains a URI of a document that describes the policy
   under which the signature was issued.

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5.2.3.29.  Key Flags

   (N octets of flags)

   This subpacket contains a list of binary flags that hold information
   about a key.  It is a string of octets, and an implementation MUST
   NOT assume a fixed size.  This is so it can grow over time.  If a
   list is shorter than an implementation expects, the unstated flags
   are considered to be zero.  The defined flags are as follows:

   First octet:

      +======+=====================================================+
      | flag | definition                                          |
      +======+=====================================================+
      | 0x01 | This key may be used to make User ID certifications |
      |      | (signature types 0x10-0x13) or direct-key           |
      |      | signatures (signature type 0x1F) over other keys.   |
      +------+-----------------------------------------------------+
      | 0x02 | This key may be used to sign data.                  |
      +------+-----------------------------------------------------+
      | 0x04 | This key may be used to encrypt communications.     |
      +------+-----------------------------------------------------+
      | 0x08 | This key may be used to encrypt storage.            |
      +------+-----------------------------------------------------+
      | 0x10 | The private component of this key may have been     |
      |      | split by a secret-sharing mechanism.                |
      +------+-----------------------------------------------------+
      | 0x20 | This key may be used for authentication.            |
      +------+-----------------------------------------------------+
      | 0x80 | The private component of this key may be in the     |
      |      | possession of more than one person.                 |
      +------+-----------------------------------------------------+

                Table 12: Key flags registry (first octet)

   Second octet:

                    +======+==========================+
                    | flag | definition               |
                    +======+==========================+
                    | 0x04 | Reserved (ADSK).         |
                    +------+--------------------------+
                    | 0x08 | Reserved (timestamping). |
                    +------+--------------------------+

                        Table 13: Key flags registry
                               (second octet)

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   Usage notes:

   The flags in this packet may appear in self-signatures or in
   certification signatures.  They mean different things depending on
   who is making the statement --- for example, a certification
   signature that has the "sign data" flag is stating that the
   certification is for that use.  On the other hand, the
   "communications encryption" flag in a self-signature is stating a
   preference that a given key be used for communications.  Note
   however, that it is a thorny issue to determine what is
   "communications" and what is "storage".  This decision is left wholly
   up to the implementation; the authors of this document do not claim
   any special wisdom on the issue and realize that accepted opinion may
   change.

   The "split key" (0x10) and "group key" (0x80) flags are placed on a
   self-signature only; they are meaningless on a certification
   signature.  They SHOULD be placed only on a direct-key signature
   (type 0x1F) or a subkey signature (type 0x18), one that refers to the
   key the flag applies to.

5.2.3.30.  Signer's User ID

   (String)

   This subpacket allows a keyholder to state which User ID is
   responsible for the signing.  Many keyholders use a single key for
   different purposes, such as business communications as well as
   personal communications.  This subpacket allows such a keyholder to
   state which of their roles is making a signature.

   This subpacket is not appropriate to use to refer to a User Attribute
   packet.

5.2.3.31.  Reason for Revocation

   (1 octet of revocation code, N octets of reason string)

   This subpacket is used only in key revocation and certification
   revocation signatures.  It describes the reason why the key or
   certificate was revoked.

   The first octet contains a machine-readable code that denotes the
   reason for the revocation:

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              +=========+==================================+
              |    Code | Reason                           |
              +=========+==================================+
              |       0 | No reason specified (key         |
              |         | revocations or cert revocations) |
              +---------+----------------------------------+
              |       1 | Key is superseded (key           |
              |         | revocations)                     |
              +---------+----------------------------------+
              |       2 | Key material has been            |
              |         | compromised (key revocations)    |
              +---------+----------------------------------+
              |       3 | Key is retired and no longer     |
              |         | used (key revocations)           |
              +---------+----------------------------------+
              |      32 | User ID information is no longer |
              |         | valid (cert revocations)         |
              +---------+----------------------------------+
              | 100-110 | Private Use                      |
              +---------+----------------------------------+

                     Table 14: Reasons for revocation

   Following the revocation code is a string of octets that gives
   information about the Reason for Revocation in human-readable form
   (UTF-8).  The string may be null (of zero length).  The length of the
   subpacket is the length of the reason string plus one.  An
   implementation SHOULD implement this subpacket, include it in all
   revocation signatures, and interpret revocations appropriately.
   There are important semantic differences between the reasons, and
   there are thus important reasons for revoking signatures.

   If a key has been revoked because of a compromise, all signatures
   created by that key are suspect.  However, if it was merely
   superseded or retired, old signatures are still valid.  If the
   revoked signature is the self-signature for certifying a User ID, a
   revocation denotes that that user name is no longer in use.  Such a
   revocation SHOULD include a 0x20 code.

   Note that any signature may be revoked, including a certification on
   some other person's key.  There are many good reasons for revoking a
   certification signature, such as the case where the keyholder leaves
   the employ of a business with an email address.  A revoked
   certification is no longer a part of validity calculations.

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5.2.3.32.  Features

   (N octets of flags)

   The Features subpacket denotes which advanced OpenPGP features a
   user's implementation supports.  This is so that as features are
   added to OpenPGP that cannot be backwards-compatible, a user can
   state that they can use that feature.  The flags are single bits that
   indicate that a given feature is supported.

   This subpacket is similar to a preferences subpacket, and only
   appears in a self-signature.

   An implementation SHOULD NOT use a feature listed when sending to a
   user who does not state that they can use it.

   Defined features are as follows:

   First octet:

        +=========+===================================+===========+
        | Feature | Definition                        | Reference |
        +=========+===================================+===========+
        | 0x01    | Symmetrically Encrypted Integrity | Section   |
        |         | Protected Data packet version 1   | 5.13.1    |
        +---------+-----------------------------------+-----------+
        | 0x02    | Reserved                          |           |
        +---------+-----------------------------------+-----------+
        | 0x04    | Reserved                          |           |
        +---------+-----------------------------------+-----------+
        | 0x08    | Symmetrically Encrypted Integrity | Section   |
        |         | Protected Data packet version 2   | 5.13.2    |
        +---------+-----------------------------------+-----------+

                        Table 15: Features registry

   If an implementation implements any of the defined features, it
   SHOULD implement the Features subpacket, too.

   An implementation may freely infer features from other suitable
   implementation-dependent mechanisms.

   See Section 14.7 for details about how to use the Features subpacket
   when generating encryption data.

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5.2.3.33.  Signature Target

   (1 octet public-key algorithm, 1 octet hash algorithm, N octets hash)

   This subpacket identifies a specific target signature to which a
   signature refers.  For revocation signatures, this subpacket provides
   explicit designation of which signature is being revoked.  For a
   third-party or timestamp signature, this designates what signature is
   signed.  All arguments are an identifier of that target signature.

   The N octets of hash data MUST be the size of the hash of the
   signature.  For example, a target signature with a SHA-1 hash MUST
   have 20 octets of hash data.

5.2.3.34.  Embedded Signature

   (1 signature packet body)

   This subpacket contains a complete Signature packet body as specified
   in Section 5.2.  It is useful when one signature needs to refer to,
   or be incorporated in, another signature.

5.2.3.35.  Issuer Fingerprint

   (1 octet key version number, N octets of fingerprint)

   The OpenPGP Key fingerprint of the key issuing the signature.  This
   subpacket SHOULD be included in all signatures.  If the version of
   the issuing key is 4 and an Issuer Key ID subpacket
   (Section 5.2.3.12) is also included in the signature, the key ID of
   the Issuer Key ID subpacket MUST match the low 64 bits of the
   fingerprint.

   Note that the length N of the fingerprint for a version 4 key is 20
   octets; for a version 6 key N is 32.  Since the version of the
   signature is bound to the version of the key, the version octet here
   MUST match the version of the signature.  If the version octet does
   not match the signature version, the receiving implementation MUST
   treat it as a malformed signature (see Section 5.2.5).

5.2.3.36.  Intended Recipient Fingerprint

   (1 octet key version number, N octets of fingerprint)

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   The OpenPGP Key fingerprint of the intended recipient primary key.
   If one or more subpackets of this type are included in a signature,
   it SHOULD be considered valid only in an encrypted context, where the
   key it was encrypted to is one of the indicated primary keys, or one
   of their subkeys.  This can be used to prevent forwarding a signature
   outside of its intended, encrypted context (see Section 14.11).

   Note that the length N of the fingerprint for a version 4 key is 20
   octets; for a version 6 key N is 32.

   An implementation SHOULD generate this subpacket when creating a
   signed and encrypted message.

5.2.4.  Computing Signatures

   All signatures are formed by producing a hash over the signature
   data, and then using the resulting hash in the signature algorithm.

   When a v6 signature is made, the salt is hashed first.

   For binary document signatures (type 0x00), the document data is
   hashed directly.  For text document signatures (type 0x01), the
   implementation MUST first canonicalize the document by converting
   line endings to <CR><LF> and encoding it in UTF-8 (see [RFC3629]).
   The resulting UTF-8 bytestream is hashed.

   When a v4 signature is made over a key, the hash data starts with the
   octet 0x99, followed by a two-octet length of the key, and then the
   body of the key packet.  When a v6 signature is made over a key, the
   hash data starts with the octet 0x9b, followed by a four-octet length
   of the key, and then the body of the key packet.

   A subkey binding signature (type 0x18) or primary key binding
   signature (type 0x19) then hashes the subkey using the same format as
   the main key (also using 0x99 or 0x9b as the first octet).  Primary
   key revocation signatures (type 0x20) hash only the key being
   revoked.  Subkey revocation signature (type 0x28) hash first the
   primary key and then the subkey being revoked.

   A certification signature (type 0x10 through 0x13) hashes the User ID
   being bound to the key into the hash context after the above data.  A
   v3 certification hashes the contents of the User ID or attribute
   packet packet, without any header.  A v4 or v6 certification hashes
   the constant 0xB4 for User ID certifications or the constant 0xD1 for
   User Attribute certifications, followed by a four-octet number giving
   the length of the User ID or User Attribute data, and then the User
   ID or User Attribute data.

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   When a signature is made over a Signature packet (type 0x50, "Third-
   Party Confirmation signature"), the hash data starts with the octet
   0x88, followed by the four-octet length of the signature, and then
   the body of the Signature packet.  (Note that this is a Legacy packet
   header for a Signature packet with the length-of-length field set to
   zero.)  The unhashed subpacket data of the Signature packet being
   hashed is not included in the hash, and the unhashed subpacket data
   length value is set to zero.

   Once the data body is hashed, then a trailer is hashed.  This trailer
   depends on the version of the signature.

   *  A v3 signature hashes five octets of the packet body, starting
      from the signature type field.  This data is the signature type,
      followed by the four-octet signature creation time.

   *  A v4 or v6 signature hashes the packet body starting from its
      first field, the version number, through the end of the hashed
      subpacket data and a final extra trailer.  Thus, the hashed fields
      are:

      -  An octet indicating the signature version (0x04 for v4, 0x06
         for v6),

      -  The signature type,

      -  The public-key algorithm,

      -  The hash algorithm,

      -  The hashed subpacket length,

      -  The hashed subpacket body,

      -  A second version octet (0x04 for v4, 0x06 for v6)

      -  A single octet 0xFF,

      -  A number representing the length (in octets) of the hashed data
         from the Signature packet through the hashed subpacket body.
         This a four-octet big-endian unsigned integer of the length
         modulo 2**32.

   After all this has been hashed in a single hash context, the
   resulting hash field is used in the signature algorithm and its first
   two octets are placed in the Signature packet, as described in
   Section 5.2.3.

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   For worked examples of the data hashed during a signature, see
   Appendix A.3.1.

5.2.4.1.  Notes About Signature Computation

   The data actually hashed by OpenPGP varies depending on signature
   version, in order to ensure that a signature made using one version
   cannot be repurposed as a signature with a different version over
   subtly different data.  The hashed data streams differ based on their
   trailer, most critically in the fifth and sixth octets from the end
   of the stream.  In particular:

   *  A v3 signature uses the fifth octet from the end to store its
      signature type.  This MUST NOT be signature type 0xff.

   *  All signature versions later than v3 always use a literal 0xff in
      the fifth octet from the end.  For these later signature versions,
      the sixth octet from the end (the octet before the 0xff) stores
      the signature version number.

5.2.5.  Malformed and Unknown Signatures

   In some cases, a signature packet (or its corresponding One-Pass
   Signature Packet, see Section 5.4) may be malformed or unknown.  For
   example, it might encounter any of the following problems (this is
   not an exhaustive list):

   *  An unknown signature type

   *  An unknown signature version

   *  An unsupported signature version

   *  An unknown "critical" subpacket (see Section 5.2.3.7) in the
      hashed area

   *  A subpacket with a length that diverges from the expected length

   *  A hashed subpacket area with length that exceeds the length of the
      signature packet itself

   *  A known-weak hash algorithm (e.g.  MD5)

   *  A mismatch between the hash algorithm expected salt length and the
      actual salt length

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   When an implementation encounters such a malformed or unknown
   signature, it MUST ignore the signature for validation purposes.  It
   MUST NOT indicate a successful signature validation for such a
   signature.  At the same time, it MUST NOT halt processing on the
   packet stream or reject other signatures in the same packet stream
   just because an unknown or invalid signature exists.

   This requirement is necessary for forward-compatibility.  Producing
   an output that indicates that no successful signatures were found is
   preferable to aborting processing entirely.

5.3.  Symmetric-Key Encrypted Session Key Packets (Tag 3)

   The Symmetric-Key Encrypted Session Key (SKESK) packet holds the
   symmetric-key encryption of a session key used to encrypt a message.
   Zero or more Public-Key Encrypted Session Key packets (Section 5.1)
   and/or Symmetric-Key Encrypted Session Key packets may precede an
   encryption container (that is, a Symmetrically Encrypted Integrity
   Protected Data packet or --- for historic data --- a Symmetrically
   Encrypted Data packet) that holds an encrypted message.  The message
   is encrypted with a session key, and the session key is itself
   encrypted and stored in the Encrypted Session Key packet(s).

   If the encryption container is preceded by one or more Symmetric-Key
   Encrypted Session Key packets, each specifies a passphrase that may
   be used to decrypt the message.  This allows a message to be
   encrypted to a number of public keys, and also to one or more
   passphrases.

   The body of this packet starts with a one-octet number giving the
   version number of the packet type.  The currently defined versions
   are 4 and 6.  The remainder of the packet depends on the version.

   The versions differ in how they encrypt the session key with the
   password, and in what they encode.  The version of the SKESK packet
   must align with the version of the SEIPD packet (see
   Section 11.3.2.1).

5.3.1.  v4 SKESK

   A version 4 Symmetric-Key Encrypted Session Key (SKESK) packet
   precedes a version 1 Symmetrically Encrypted Integrity Protected Data
   (v1 SEIPD, see Section 5.13.1) packet.  In historic data, it is
   sometimes found preceding a deprecated Symmetrically Encrypted Data
   packet (SED, see Section 5.7).  A v4 SKESK packet MUST NOT precede a
   v2 SEIPD packet (see Section 11.3.2.1).

   A version 4 Symmetric-Key Encrypted Session Key packet consists of:

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   *  A one-octet version number with value 4.

   *  A one-octet number describing the symmetric algorithm used.

   *  A string-to-key (S2K) specifier.  The length of the string-to-key
      specifier depends on its type (see Section 3.7.1).

   *  Optionally, the encrypted session key itself, which is decrypted
      with the string-to-key object.

   If the encrypted session key is not present (which can be detected on
   the basis of packet length and S2K specifier size), then the S2K
   algorithm applied to the passphrase produces the session key for
   decrypting the message, using the symmetric cipher algorithm from the
   Symmetric-Key Encrypted Session Key packet.

   If the encrypted session key is present, the result of applying the
   S2K algorithm to the passphrase is used to decrypt just that
   encrypted session key field, using CFB mode with an IV of all zeros.
   The decryption result consists of a one-octet algorithm identifier
   that specifies the symmetric-key encryption algorithm used to encrypt
   the following encryption container, followed by the session key
   octets themselves.

   Note: because an all-zero IV is used for this decryption, the S2K
   specifier MUST use a salt value, either a Salted S2K, an Iterated-
   Salted S2K, or Argon2.  The salt value will ensure that the
   decryption key is not repeated even if the passphrase is reused.

5.3.2.  v6 SKESK

   A version 6 Symmetric-Key Encrypted Session Key (SKESK) packet
   precedes a version 2 Symmetrically Encrypted Integrity Protected Data
   (v2 SEIPD, see Section 5.13.2) packet.  A v6 SKESK packet MUST NOT
   precede a v1 SEIPD packet or a deprecated Symmetrically Encrypted
   Data packet (see Section 11.3.2.1).

   A version 6 Symmetric-Key Encrypted Session Key packet consists of:

   *  A one-octet version number with value 6.

   *  A one-octet scalar octet count of the following 5 fields.

   *  A one-octet symmetric cipher algorithm identifier.

   *  A one-octet AEAD algorithm identifier.

   *  A one-octet scalar octet count of the following field.

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   *  A string-to-key (S2K) specifier.  The length of the string-to-key
      specifier depends on its type (see Section 3.7.1).

   *  A starting initialization vector of size specified by the AEAD
      algorithm.

   *  The encrypted session key itself.

   *  An authentication tag for the AEAD mode.

   HKDF is used with SHA256 as hash algorithm, the key derived from S2K
   as Initial Keying Material (IKM), no salt, and the Packet Tag in the
   OpenPGP format encoding (bits 7 and 6 set, bits 5-0 carry the packet
   tag), the packet version, and the cipher-algo and AEAD-mode used to
   encrypt the key material, are used as info parameter.  Then, the
   session key is encrypted using the resulting key, with the AEAD
   algorithm specified for version 2 of the Symmetrically Encrypted
   Integrity Protected Data packet.  Note that no chunks are used and
   that there is only one authentication tag.  The Packet Tag in OpenPGP
   format encoding (bits 7 and 6 set, bits 5-0 carry the packet tag),
   the packet version number, the cipher algorithm octet, and the AEAD
   algorithm octet are given as additional data.  For example, the
   additional data used with AES-128 with OCB consists of the octets
   0xC3, 0x06, 0x07, and 0x02.

5.4.  One-Pass Signature Packets (Tag 4)

   The One-Pass Signature packet precedes the signed data and contains
   enough information to allow the receiver to begin calculating any
   hashes needed to verify the signature.  It allows the Signature
   packet to be placed at the end of the message, so that the signer can
   compute the entire signed message in one pass.

   The body of this packet consists of:

   *  A one-octet version number.  The currently defined versions are 3
      and 6.

   *  A one-octet signature type.  Signature types are described in
      Section 5.2.1.

   *  A one-octet number describing the hash algorithm used.

   *  A one-octet number describing the public-key algorithm used.

   *  Only for v6 signatures, a variable-length field containing:

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      -  A one-octet salt size.  The value MUST match the value defined
         for the hash algorithm as specified in table Table 23.

      -  The salt; a random value value of the specified size.  The
         value MUST match the salt field of the corresponding Signature
         packet.

   *  Only for v3 packets, an eight-octet number holding the Key ID of
      the signing key.

   *  Only for v6 packets, a one octet key version number and N octets
      of the fingerprint of the signing key.  Note that the length N of
      the fingerprint for a version 6 key is 32.  Since a v6 signature
      can only be made by a v6 key, the key version number MUST be 6.
      An application that encounters a v6 One-Pass Signature packet
      where the key version number is not 6 MUST treat the signature as
      invalid (see Section 5.2.5).

   *  A one-octet number holding a flag showing whether the signature is
      nested.  A zero value indicates that the next packet is another
      One-Pass Signature packet that describes another signature to be
      applied to the same message data.

   When generating a one-pass signature, the OPS packet version MUST
   correspond to the version of the associated signature packet, except
   for the historical accident that v4 keys use a v3 one-pass signature
   packet (there is no v4 OPS):

       +=====================+====================+================+
       | Signing key version | OPS packet version | Signature      |
       |                     |                    | packet version |
       +=====================+====================+================+
       | 4                   | 3                  | 4              |
       +---------------------+--------------------+----------------+
       | 6                   | 6                  | 6              |
       +---------------------+--------------------+----------------+

         Table 16: Versions of packets used in a one-pass signature

   Note that if a message contains more than one one-pass signature,
   then the Signature packets bracket the message; that is, the first
   Signature packet after the message corresponds to the last one-pass
   packet and the final Signature packet corresponds to the first one-
   pass packet.

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5.5.  Key Material Packet

   A key material packet contains all the information about a public or
   private key.  There are four variants of this packet type, two major
   versions (versions 4 and 6), and two strongly deprecated versions
   (versions 2 and 3).  Consequently, this section is complex.

   For historical reasons, versions 1 and 5 of the key packet are
   unspecified.

5.5.1.  Key Packet Variants

5.5.1.1.  Public-Key Packet (Tag 6)

   A Public-Key packet starts a series of packets that forms an OpenPGP
   key (sometimes called an OpenPGP certificate).

5.5.1.2.  Public-Subkey Packet (Tag 14)

   A Public-Subkey packet (tag 14) has exactly the same format as a
   Public-Key packet, but denotes a subkey.  One or more subkeys may be
   associated with a top-level key.  By convention, the top-level key
   provides signature services, and the subkeys provide encryption
   services.

5.5.1.3.  Secret-Key Packet (Tag 5)

   A Secret-Key packet contains all the information that is found in a
   Public-Key packet, including the public-key material, but also
   includes the secret-key material after all the public-key fields.

5.5.1.4.  Secret-Subkey Packet (Tag 7)

   A Secret-Subkey packet (tag 7) is the subkey analog of the Secret Key
   packet and has exactly the same format.

5.5.2.  Public-Key Packet Formats

   There are three versions of key-material packets.

   OpenPGP implementations SHOULD create keys with version 6 format.  V4
   keys are deprecated; an implementation SHOULD NOT generate a v4 key,
   but SHOULD accept it.  V3 keys are deprecated; an implementation MUST
   NOT generate a v3 key, but MAY accept it.  V2 keys are deprecated; an
   implementation MUST NOT generate a v2 key, but MAY accept it.

   A version 3 public key or public-subkey packet contains:

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   *  A one-octet version number (3).

   *  A four-octet number denoting the time that the key was created.

   *  A two-octet number denoting the time in days that this key is
      valid.  If this number is zero, then it does not expire.

   *  A one-octet number denoting the public-key algorithm of this key.

   *  A series of multiprecision integers comprising the key material:

      -  A multiprecision integer (MPI) of RSA public modulus n;

      -  An MPI of RSA public encryption exponent e.

   V3 keys are deprecated.  They contain three weaknesses.  First, it is
   relatively easy to construct a v3 key that has the same Key ID as any
   other key because the Key ID is simply the low 64 bits of the public
   modulus.  Secondly, because the fingerprint of a v3 key hashes the
   key material, but not its length, there is an increased opportunity
   for fingerprint collisions.  Third, there are weaknesses in the MD5
   hash algorithm that make developers prefer other algorithms.  See
   Section 5.5.4 for a fuller discussion of Key IDs and fingerprints.

   V2 keys are identical to the deprecated v3 keys except for the
   version number.

   The version 4 format is similar to the version 3 format except for
   the absence of a validity period.  This has been moved to the
   Signature packet.  In addition, fingerprints of version 4 keys are
   calculated differently from version 3 keys, as described in
   Section 5.5.4.

   A version 4 packet contains:

   *  A one-octet version number (4).

   *  A four-octet number denoting the time that the key was created.

   *  A one-octet number denoting the public-key algorithm of this key.

   *  A series of values comprising the key material.  This is
      algorithm-specific and described in Section 5.5.5.

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   The version 6 format is similar to the version 4 format except for
   the addition of a count for the key material.  This count helps
   parsing secret key packets (which are an extension of the public key
   packet format) in the case of an unknown algorithm.  In addition,
   fingerprints of version 6 keys are calculated differently from
   version 4 keys, as described in Section 5.5.4.

   A version 6 packet contains:

   *  A one-octet version number (6).

   *  A four-octet number denoting the time that the key was created.

   *  A one-octet number denoting the public-key algorithm of this key.

   *  A four-octet scalar octet count for the following public key
      material.

   *  A series of values comprising the public key material.  This is
      algorithm-specific and described in Section 5.5.5.

5.5.3.  Secret-Key Packet Formats

   The Secret-Key and Secret-Subkey packets contain all the data of the
   Public-Key and Public-Subkey packets, with additional algorithm-
   specific secret-key data appended, usually in encrypted form.

   The packet contains:

   *  The fields of a Public-Key or Public-Subkey packet, as described
      above.

   *  One octet indicating string-to-key usage conventions.  Zero
      indicates that the secret-key data is not encrypted. 255, 254, or
      253 indicates that a string-to-key specifier is being given.  Any
      other value is a symmetric-key encryption algorithm identifier.  A
      version 6 packet MUST NOT use the value 255.

   *  Only for a version 6 packet where the secret key material is
      encrypted (that is, where the previous octet is not zero), a one-
      octet scalar octet count of the cumulative length of all the
      following optional string-to-key parameter fields.

   *  [Optional] If string-to-key usage octet was 255, 254, or 253, a
      one-octet symmetric encryption algorithm.

   *  [Optional] If string-to-key usage octet was 253, a one-octet AEAD
      algorithm.

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   *  [Optional] Only for a version 6 packet, and if string-to-key usage
      octet was 255, 254, or 253, an one-octet count of the following
      field.

   *  [Optional] If string-to-key usage octet was 255, 254, or 253, a
      string-to-key (S2K) specifier.  The length of the string-to-key
      specifier depends on its type (see Section 3.7.1).

   *  [Optional] If string-to-key usage octet was 253 (that is, the
      secret data is AEAD-encrypted), an initialization vector (IV) of
      size specified by the AEAD algorithm (see Section 5.13.2), which
      is used as the nonce for the AEAD algorithm.

   *  [Optional] If string-to-key usage octet was 255, 254, or a cipher
      algorithm identifier (that is, the secret data is CFB-encrypted),
      an initialization vector (IV) of the same length as the cipher's
      block size.

   *  Plain or encrypted multiprecision integers comprising the secret
      key data.  This is algorithm-specific and described in
      Section 5.5.5.  If the string-to-key usage octet is 253, then an
      AEAD authentication tag is part of that data.  If the string-to-
      key usage octet is 254, a 20-octet SHA-1 hash of the plaintext of
      the algorithm-specific portion is appended to plaintext and
      encrypted with it.  If the string-to-key usage octet is 255 or
      another nonzero value (that is, a symmetric-key encryption
      algorithm identifier), a two-octet checksum of the plaintext of
      the algorithm-specific portion (sum of all octets, mod 65536) is
      appended to plaintext and encrypted with it.  (This is deprecated
      and SHOULD NOT be used, see below.)

   *  Only for a version 3 or 4 packet where the string-to-key usage
      octet is zero, a two-octet checksum of the algorithm-specific
      portion (sum of all octets, mod 65536).

   The details about storing algorithm-specific secrets above are
   summarized in Section 3.7.2.1.

   Note that the version 6 packet format adds two count values to help
   parsing packets with unknown S2K or public key algorithms.

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   Secret MPI values can be encrypted using a passphrase.  If a string-
   to-key specifier is given, that describes the algorithm for
   converting the passphrase to a key, else a simple MD5 hash of the
   passphrase is used.  Implementations MUST use a string-to-key
   specifier; the simple hash is for backward compatibility and is
   deprecated, though implementations MAY continue to use existing
   private keys in the old format.  The cipher for encrypting the MPIs
   is specified in the Secret-Key packet.

   Encryption/decryption of the secret data is done using the key
   created from the passphrase and the initialization vector from the
   packet.  If the string-to-key usage octet is not 253, CFB mode is
   used.  A different mode is used with v3 keys (which are only RSA)
   than with other key formats.  With v3 keys, the MPI bit count prefix
   (that is, the first two octets) is not encrypted.  Only the MPI non-
   prefix data is encrypted.  Furthermore, the CFB state is
   resynchronized at the beginning of each new MPI value, so that the
   CFB block boundary is aligned with the start of the MPI data.

   With v4 and v6 keys, a simpler method is used.  All secret MPI values
   are encrypted, including the MPI bitcount prefix.

   If the string-to-key usage octet is 253, the key encryption key is
   derived using HKDF (see [RFC5869]) to provide key separation.  HKDF
   is used with SHA256 as hash algorithm, the key derived from S2K as
   Initial Keying Material (IKM), no salt, and the Packet Tag in OpenPGP
   format encoding (bits 7 and 6 set, bits 5-0 carry the packet tag),
   the packet version, and the cipher-algo and AEAD-mode used to encrypt
   the key material, are used as info parameter.  Then, the encrypted
   MPI values are encrypted as one combined plaintext using one of the
   AEAD algorithms specified for version 2 of the Symmetrically
   Encrypted Integrity Protected Data packet.  Note that no chunks are
   used and that there is only one authentication tag.  As additional
   data, the Packet Tag in OpenPGP format encoding (bits 7 and 6 set,
   bits 5-0 carry the packet tag), followed by the public key packet
   fields, starting with the packet version number, are passed to the
   AEAD algorithm.  For example, the additional data used with a Secret-
   Key Packet of version 4 consists of the octets 0xC5, 0x04, followed
   by four octets of creation time, one octet denoting the public-key
   algorithm, and the algorithm-specific public-key parameters.  For a
   Secret-Subkey Packet, the first octet would be 0xC7.  For a version 6
   key packet, the second octet would be 0x06, and the four-octet octet
   count of the public key material would be included as well (see
   Section 5.5.2).

   The two-octet checksum that follows the algorithm-specific portion is
   the algebraic sum, mod 65536, of the plaintext of all the algorithm-
   specific octets (including MPI prefix and data).  With v3 keys, the

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   checksum is stored in the clear.  With v4 keys, the checksum is
   encrypted like the algorithm-specific data.  This value is used to
   check that the passphrase was correct.  However, this checksum is
   deprecated; an implementation SHOULD NOT use it, but should rather
   use the SHA-1 hash denoted with a usage octet of 254.  The reason for
   this is that there are some attacks that involve undetectably
   modifying the secret key.  If the string-to-key usage octet is 253 no
   checksum or SHA-1 hash is used but the authentication tag of the AEAD
   algorithm follows.

   When decrypting the secret key material using any of these schemes
   (that is, where the usage octet is non-zero), the resulting cleartext
   octet stream MUST be well-formed.  In particular, an implementation
   MUST NOT interpret octets beyond the unwrapped cleartext octet stream
   as part of any of the unwrapped MPI objects.  Furthermore, an
   implementation MUST reject as unusable any secret key material whose
   cleartext length does not align with the lengths of the unwrapped MPI
   objects.

5.5.4.  Key IDs and Fingerprints

   For a v3 key, the eight-octet Key ID consists of the low 64 bits of
   the public modulus of the RSA key.

   The fingerprint of a v3 key is formed by hashing the body (but not
   the two-octet length) of the MPIs that form the key material (public
   modulus n, followed by exponent e) with MD5.  Note that both v3 keys
   and MD5 are deprecated.

   A v4 fingerprint is the 160-bit SHA-1 hash of the octet 0x99,
   followed by the two-octet packet length, followed by the entire
   Public-Key packet starting with the version field.  The Key ID is the
   low-order 64 bits of the fingerprint.  Here are the fields of the
   hash material, with the example of an Ed25519 key:

   a.1) 0x99 (1 octet)

   a.2) two-octet, big-endian scalar octet count of (b)-(e)

   b) version number = 4 (1 octet);

   c) timestamp of key creation (4 octets);

   d) algorithm (1 octet): 27 = Ed25519 (example);

   e) Algorithm-specific fields.

   Algorithm-Specific Fields for Ed25519 keys (example):

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   e.1) 32 octets representing the public key.

   A v6 fingerprint is the 256-bit SHA2-256 hash of the octet 0x9b,
   followed by the four-octet packet length, followed by the entire
   Public-Key packet starting with the version field.  The Key ID is the
   high-order 64 bits of the fingerprint.  Here are the fields of the
   hash material, with the example of an Ed25519 key:

   a.1) 0x9b (1 octet)

   a.2) four-octet scalar octet count of (b)-(f)

   b) version number = 6 (1 octet);

   c) timestamp of key creation (4 octets);

   d) algorithm (1 octet): 27 = Ed25519 (example);

   e) four-octet scalar octet count for the following key material;

   f) algorithm-specific fields.

   Algorithm-Specific Fields for Ed25519 keys (example):

   e.1) 32 octets representing the public key.

   Note that it is possible for there to be collisions of Key IDs ---
   two different keys with the same Key ID.  Note that there is a much
   smaller, but still non-zero, probability that two different keys have
   the same fingerprint.

   Also note that if v3, v4, and v6 format keys share the same RSA key
   material, they will have different Key IDs as well as different
   fingerprints.

   Finally, the Key ID and fingerprint of a subkey are calculated in the
   same way as for a primary key, including the 0x99 (v4 key) or 0x9b
   (v6 key) as the first octet (even though this is not a valid packet
   ID for a public subkey).

5.5.5.  Algorithm-specific Parts of Keys

   The public and secret key format specifies algorithm-specific parts
   of a key.  The following sections describe them in detail.

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5.5.5.1.  Algorithm-Specific Part for RSA Keys

   The public key is this series of multiprecision integers:

   *  MPI of RSA public modulus n;

   *  MPI of RSA public encryption exponent e.

   The secret key is this series of multiprecision integers:

   *  MPI of RSA secret exponent d;

   *  MPI of RSA secret prime value p;

   *  MPI of RSA secret prime value q (p < q);

   *  MPI of u, the multiplicative inverse of p, mod q.

5.5.5.2.  Algorithm-Specific Part for DSA Keys

   The public key is this series of multiprecision integers:

   *  MPI of DSA prime p;

   *  MPI of DSA group order q (q is a prime divisor of p-1);

   *  MPI of DSA group generator g;

   *  MPI of DSA public-key value y (= g**x mod p where x is secret).

   The secret key is this single multiprecision integer:

   *  MPI of DSA secret exponent x.

5.5.5.3.  Algorithm-Specific Part for Elgamal Keys

   The public key is this series of multiprecision integers:

   *  MPI of Elgamal prime p;

   *  MPI of Elgamal group generator g;

   *  MPI of Elgamal public key value y (= g**x mod p where x is
      secret).

   The secret key is this single multiprecision integer:

   *  MPI of Elgamal secret exponent x.

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5.5.5.4.  Algorithm-Specific Part for ECDSA Keys

   The public key is this series of values:

   *  A variable-length field containing a curve OID, which is formatted
      as follows:

      -  A one-octet size of the following field; values 0 and 0xFF are
         reserved for future extensions,

      -  The octets representing a curve OID (defined in Section 9.2);

   *  MPI of an EC point representing a public key.

   The secret key is this single multiprecision integer:

   *  MPI of an integer representing the secret key, which is a scalar
      of the public EC point.

5.5.5.5.  Algorithm-Specific Part for EdDSALegacy Keys (deprecated)

   The public key is this series of values:

   *  A variable-length field containing a curve OID, formatted as
      follows:

      -  A one-octet size of the following field; values 0 and 0xFF are
         reserved for future extensions,

      -  The octets representing a curve OID, defined in Section 9.2;

   *  An MPI of an EC point representing a public key Q in prefixed
      native form (see Section 12.2.2).

   The secret key is this single multiprecision integer:

   *  An MPI-encoded octet string representing the native form of the
      secret key, in the curve-specific format described in
      Section 9.2.1.

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   Note that the native form for an EdDSA secret key is a fixed-width
   sequence of unstructured random octets, with size corresponding to
   the specific curve.  That sequence of random octets is used with a
   cryptographic digest to produce both a curve-specific secret scalar
   and a prefix used when making a signature.  See [RFC8032] for more
   details about how to use the native octet strings (section 5.1.5 for
   Ed25519 and 5.2.5 for Ed448).  The value stored in an OpenPGP
   EdDSALegacy secret key packet is the original sequence of random
   octets.

5.5.5.6.  Algorithm-Specific Part for ECDH Keys

   The public key is this series of values:

   *  A variable-length field containing a curve OID, which is formatted
      as follows:

      -  A one-octet size of the following field; values 0 and 0xFF are
         reserved for future extensions,

      -  Octets representing a curve OID, defined in Section 9.2;

   *  MPI of an EC point representing a public key, in the point format
      associated with the curve as specified in Section 9.2.1

   *  A variable-length field containing KDF parameters, which is
      formatted as follows:

      -  A one-octet size of the following fields; values 0 and 0xFF are
         reserved for future extensions,

      -  A one-octet value 1, reserved for future extensions,

      -  A one-octet hash function ID used with a KDF,

      -  A one-octet algorithm ID for the symmetric algorithm used to
         wrap the symmetric key used for the message encryption; see
         Section 12.5 for details.

   The secret key is this single multiprecision integer:

   *  An MPI representing the secret key, in the curve-specific format
      described in Section 9.2.1.

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5.5.5.6.1.  ECDH Secret Key Material

   When curve NIST P-256, NIST P-384, NIST P-521, brainpoolP256r1,
   brainpoolP384r1, or brainpoolP512r1 are used in ECDH, their secret
   keys are represented as a simple integer in standard MPI form.  Other
   curves are presented on the wire differently (though still as a
   single MPI), as described below and in Section 9.2.1.

5.5.5.6.1.1.  Curve25519Legacy ECDH Secret Key Material (deprecated)

   A Curve25519Legacy secret key is stored as a standard integer in big-
   endian MPI form.  Curve25519Legacy MUST NOT be used in key packets
   version 6 or above.  Note that this form is in reverse octet order
   from the little-endian "native" form found in [RFC7748].

   Note also that the integer for a Curve25519Legacy secret key for
   OpenPGP MUST have the appropriate form: that is, it MUST be divisible
   by 8, MUST be at least 2**254, and MUST be less than 2**255.  The
   length of this MPI in bits is by definition always 255, so the two
   leading octets of the MPI will always be 00 ff and reversing the
   following 32 octets from the wire will produce the "native" form.

   When generating a new Curve25519Legacy secret key from 32 fully-
   random octets, the following pseudocode produces the MPI wire format
   (note the similarity to decodeScalar25519 from [RFC7748]):

   def curve25519_MPI_from_random(octet_list):
       octet_list[0] &= 248
       octet_list[31] &= 127
       octet_list[31] |= 64
       mpi_header = [ 0x00, 0xff ]
       return mpi_header || reversed(octet_list)

5.5.5.7.  Algorithm-Specific Part for X25519 Keys

   The public key is this single value:

   *  32 octets of the native public key.

   The secret key is this single value:

   *  32 octets of the native secret key.

   See section 6.1 of [RFC7748] for more details about how to use the
   native octet strings.  The value stored in an OpenPGP X25519 secret
   key packet is the original sequence of random octets.  The value
   stored in an OpenPGP X25519 public key packet is the value
   X25519(secretKey, 9).

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5.5.5.8.  Algorithm-Specific Part for X448 Keys

   The public key is this single value:

   *  56 octets of the native public key.

   The secret key is this single value:

   *  56 octets of the native secret key.

   See section 6.2 of [RFC7748] for more details about how to use the
   native octet strings.  The value stored in an OpenPGP X448 secret key
   packet is the original sequence of random octets.  The value stored
   in an OpenPGP X448 public key packet is the value X448(secretKey, 5).

5.5.5.9.  Algorithm-Specific Part for Ed25519 Keys

   The public key is this single value:

   *  32 octets of the native public key.

   The secret key is this single value:

   *  32 octets of the native secret key.

   See section 5.1.5 of [RFC8032] for more details about how to use the
   native octet strings.  The value stored in an OpenPGP Ed25519 secret
   key packet is the original sequence of random octets.

5.5.5.10.  Algorithm-Specific Part for Ed448 Keys

   The public key is this single value:

   *  57 octets of the native public key.

   The secret key is this single value:

   *  57 octets of the native secret key.

   See section 5.2.5 of [RFC8032] for more details about how to use the
   native octet strings.  The value stored in an OpenPGP Ed448 secret
   key packet is the original sequence of random octets.

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5.6.  Compressed Data Packet (Tag 8)

   The Compressed Data packet contains compressed data.  Typically, this
   packet is found as the contents of an encrypted packet, or following
   a Signature or One-Pass Signature packet, and contains a literal data
   packet.

   The body of this packet consists of:

   *  One octet that gives the algorithm used to compress the packet.

   *  Compressed data, which makes up the remainder of the packet.

   A Compressed Data Packet's body contains a block that compresses some
   set of packets.  See Section 11 for details on how messages are
   formed.

   ZIP-compressed packets are compressed with raw [RFC1951] DEFLATE
   blocks.

   ZLIB-compressed packets are compressed with [RFC1950] ZLIB-style
   blocks.

   BZip2-compressed packets are compressed using the BZip2 [BZ2]
   algorithm.

   An implementation that generates a Compressed Data packet MUST use
   the non-legacy format for packet framing (see Section 4.2.1).  It
   MUST NOT generate a Compressed Data packet with Legacy format
   (Section 4.2.2)

   An implementation that deals with either historic data or data
   generated by legacy implementations MAY interpret Compressed Data
   packets that use the Legacy format for packet framing.

5.7.  Symmetrically Encrypted Data Packet (Tag 9)

   The Symmetrically Encrypted Data packet contains data encrypted with
   a symmetric-key algorithm.  When it has been decrypted, it contains
   other packets (usually a literal data packet or compressed data
   packet, but in theory other Symmetrically Encrypted Data packets or
   sequences of packets that form whole OpenPGP messages).

   This packet is obsolete.  An implementation MUST NOT create this
   packet.  An implementation MAY process such a packet but it MUST
   return a clear diagnostic that a non-integrity protected packet has
   been processed.  The implementation SHOULD also return an error in
   this case and stop processing.

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   This packet format is impossible to handle safely in general because
   the ciphertext it provides is malleable.  See Section 14.7 about
   selecting a better OpenPGP encryption container that does not have
   this flaw.

   The body of this packet consists of:

   *  A random prefix, containing block-size random octets (for example,
      8 octets for a 64-bit block length) followed by a copy of the last
      two octets, encrypted together using Cipher Feedback (CFB) mode,
      with an Initial Vector (IV) of all zeros.

   *  Data encrypted using CFB mode, with the last block-size octets of
      the first ciphertext as the IV.

   The symmetric cipher used may be specified in a Public-Key or
   Symmetric-Key Encrypted Session Key packet that precedes the
   Symmetrically Encrypted Data packet.  In that case, the cipher
   algorithm octet is prefixed to the session key before it is
   encrypted.  If no packets of these types precede the encrypted data,
   the IDEA algorithm is used with the session key calculated as the MD5
   hash of the passphrase, though this use is deprecated.

   The data is encrypted in CFB mode (see {#cfb-mode}).  For the random
   prefix, the Initial Vector (IV) is specified as all zeros.  Instead
   of using an IV, a string of length equal to the block size of the
   cipher plus two is encrypted.  The first block-size octets (for
   example, 8 octets for a 64-bit block length) are random, and the
   following two octets are copies of the last two octets of the IV.
   For example, in an 8-octet block, octet 9 is a repeat of octet 7, and
   octet 10 is a repeat of octet 8.  In a cipher of length 16, octet 17
   is a repeat of octet 15 and octet 18 is a repeat of octet 16.  (In
   both these examples, we consider the first octet to be numbered 1.)

   After encrypting these block-size-plus-two octets, a new CFB context
   is created for the encryption of the data, with the last block-size
   octets of the first ciphertext as the IV.  (Alternatively and
   equivalently, the CFB state is resynchronized: the last block-size
   octets of ciphertext are passed through the cipher and the block
   boundary is reset.)

   The repetition of two octets in the random prefix allows the receiver
   to immediately check whether the session key is incorrect.  See
   Section 14.4 for hints on the proper use of this "quick check".

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5.8.  Marker Packet (Tag 10)

   The body of this packet consists of:

   *  The three octets 0x50, 0x47, 0x50 (which spell "PGP" in UTF-8).

   Such a packet MUST be ignored when received.

5.9.  Literal Data Packet (Tag 11)

   A Literal Data packet contains the body of a message; data that is
   not to be further interpreted.

   The body of this packet consists of:

   *  A one-octet field that describes how the data is formatted.

      If it is a b (0x62), then the Literal packet contains binary data.
      If it is a u (0x75), then the Literal packet contains UTF-
      8-encoded text data, and thus may need line ends converted to
      local form, or other text mode changes.

      Older versions of OpenPGP used t (0x74) to indicate textual data,
      but did not specify the character encoding.  Implementations
      SHOULD NOT emit this value.  An implementation that receives a
      literal data packet with this value in the format field SHOULD
      interpret the packet data as UTF-8 encoded text, unless reliable
      (not attacker-controlled) context indicates a specific alternate
      text encoding.  This mode is deprecated due to its ambiguity.

      Early versions of PGP also defined a value of l as a 'local' mode
      for machine-local conversions.  [RFC1991] incorrectly stated this
      local mode flag as 1 (ASCII numeral one).  Both of these local
      modes are deprecated.

   *  File name as a string (one-octet length, followed by a file name).
      This may be a zero-length string.  Commonly, if the source of the
      encrypted data is a file, this will be the name of the encrypted
      file.  An implementation MAY consider the file name in the Literal
      packet to be a more authoritative name than the actual file name.

   *  A four-octet number that indicates a date associated with the
      literal data.  Commonly, the date might be the modification date
      of a file, or the time the packet was created, or a zero that
      indicates no specific time.

   *  The remainder of the packet is literal data.

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      Text data MUST be encoded with UTF-8 (see [RFC3629]), and stored
      with <CR><LF> text endings (that is, network-normal line endings).
      These should be converted to native line endings by the receiving
      software.

   Note that OpenPGP signatures do not include the formatting octet, the
   file name, and the date field of the literal packet in a signature
   hash and thus those fields are not protected against tampering in a
   signed document.  A receiving implementation MUST NOT treat those
   fields as though they were cryptographically secured by the
   surrounding signature either when representing them to the user or
   acting on them.

   Due to their inherent malleability, an implementation that generates
   a literal data packet SHOULD avoid storing any significant data in
   these fields.  If the implementation is certain that the data is
   textual and is encoded with UTF-8 (for example, if it will follow
   this literal data packet with a signature packet of type 0x01 (see
   Section 5.2.1), it MAY set the format octet to u.  Otherwise, it
   SHOULD set the format octet to b.  It SHOULD set the filename to the
   empty string (encoded as a single zero octet), and the timestamp to
   zero (encoded as four zero octets).

   An application that wishes to include such filesystem metadata within
   a signature is advised to sign an encapsulated archive (for example,
   [PAX]).

   An implementation that generates a Literal Data packet MUST use the
   OpenPGP format for packet framing (see Section 4.2.1).  It MUST NOT
   generate a Literal Data packet with Legacy format (Section 4.2.2)

   An implementation that deals with either historic data or data
   generated by legacy implementations MAY interpret Literal Data
   packets that use the Legacy format for packet framing.

5.9.1.  Special Filename _CONSOLE (Deprecated)

   The Literal Data packet's filename field has a historical special
   case for the special name _CONSOLE.  When the filename field is
   _CONSOLE, the message is considered to be "for your eyes only".  This
   advises that the message data is unusually sensitive, and the
   receiving program should process it more carefully, perhaps avoiding
   storing the received data to disk, for example.

   An OpenPGP deployment that generates literal data packets MUST NOT
   depend on this indicator being honored in any particular way.  It
   cannot be enforced, and the field itself is not covered by any
   cryptographic signature.

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   It is NOT RECOMMENDED to use this special filename in a newly-
   generated literal data packet.

5.10.  Trust Packet (Tag 12)

   The Trust packet is used only within keyrings and is not normally
   exported.  Trust packets contain data that record the user's
   specifications of which key holders are trustworthy introducers,
   along with other information that implementing software uses for
   trust information.  The format of Trust packets is defined by a given
   implementation.

   Trust packets SHOULD NOT be emitted to output streams that are
   transferred to other users, and they SHOULD be ignored on any input
   other than local keyring files.

5.11.  User ID Packet (Tag 13)

   A User ID packet consists of UTF-8 text that is intended to represent
   the name and email address of the key holder.  By convention, it
   includes an [RFC2822] mail name-addr, but there are no restrictions
   on its content.  The packet length in the header specifies the length
   of the User ID.

5.12.  User Attribute Packet (Tag 17)

   The User Attribute packet is a variation of the User ID packet.  It
   is capable of storing more types of data than the User ID packet,
   which is limited to text.  Like the User ID packet, a User Attribute
   packet may be certified by the key owner ("self-signed") or any other
   key owner who cares to certify it.  Except as noted, a User Attribute
   packet may be used anywhere that a User ID packet may be used.

   While User Attribute packets are not a required part of the OpenPGP
   standard, implementations SHOULD provide at least enough
   compatibility to properly handle a certification signature on the
   User Attribute packet.  A simple way to do this is by treating the
   User Attribute packet as a User ID packet with opaque contents, but
   an implementation may use any method desired.

   The User Attribute packet is made up of one or more attribute
   subpackets.  Each subpacket consists of a subpacket header and a
   body.  The header consists of:

   *  The subpacket length (1, 2, or 5 octets)

   *  The subpacket type (1 octet)

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   and is followed by the subpacket specific data.

   The following table lists the currently known subpackets:

                  +=========+===========================+
                  |    Type | Attribute Subpacket       |
                  +=========+===========================+
                  |       1 | Image Attribute Subpacket |
                  +---------+---------------------------+
                  | 100-110 | Private/Experimental Use  |
                  +---------+---------------------------+

                   Table 17: User Attribute type registry

   An implementation SHOULD ignore any subpacket of a type that it does
   not recognize.

5.12.1.  The Image Attribute Subpacket

   The Image Attribute subpacket is used to encode an image, presumably
   (but not required to be) that of the key owner.

   The Image Attribute subpacket begins with an image header.  The first
   two octets of the image header contain the length of the image
   header.  Note that unlike other multi-octet numerical values in this
   document, due to a historical accident this value is encoded as a
   little-endian number.  The image header length is followed by a
   single octet for the image header version.  The only currently
   defined version of the image header is 1, which is a 16-octet image
   header.  The first three octets of a version 1 image header are thus
   0x10, 0x00, 0x01.

   The fourth octet of a version 1 image header designates the encoding
   format of the image.  The only currently defined encoding format is
   the value 1 to indicate JPEG.  Image format types 100 through 110 are
   reserved for private or experimental use.  The rest of the version 1
   image header is made up of 12 reserved octets, all of which MUST be
   set to 0.

   The rest of the image subpacket contains the image itself.  As the
   only currently defined image type is JPEG, the image is encoded in
   the JPEG File Interchange Format (JFIF), a standard file format for
   JPEG images [JFIF].

   An implementation MAY try to determine the type of an image by
   examination of the image data if it is unable to handle a particular
   version of the image header or if a specified encoding format value
   is not recognized.

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5.13.  Sym. Encrypted Integrity Protected Data Packet (Tag 18)

   This packet contains integrity protected and encrypted data.  When it
   has been decrypted, it will contain other packets forming an OpenPGP
   Message (see Section 11.3).

   The first octet of this packet is always used to indicate the version
   number, but different versions contain differently-structured
   ciphertext.  Version 1 of this packet contains data encrypted with a
   symmetric-key algorithm and protected against modification by the
   SHA-1 hash algorithm.  This is a legacy OpenPGP mechanism that offers
   some protections against ciphertext malleability.

   Version 2 of this packet contains data encrypted with an
   authenticated encryption and additional data (AEAD) construction.
   This offers a more cryptographically rigorous defense against
   ciphertext malleability, but may not be as widely supported yet.  See
   Section 14.7 for more details on choosing between these formats.

5.13.1.  Version 1 Sym. Encrypted Integrity Protected Data Packet Format

   A version 1 Symmetrically Encrypted Integrity Protected Data packet
   consists of:

   *  A one-octet version number with value 1.

   *  Encrypted data, the output of the selected symmetric-key cipher
      operating in Cipher Feedback (CFB) mode.

   The symmetric cipher used MUST be specified in a Public-Key or
   Symmetric-Key Encrypted Session Key packet that precedes the
   Symmetrically Encrypted Integrity Protected Data packet.  In either
   case, the cipher algorithm octet is prefixed to the session key
   before it is encrypted.

   The data is encrypted in CFB mode (see {#cfb-mode}).  The Initial
   Vector (IV) is specified as all zeros.  Instead of using an IV,
   OpenPGP prefixes an octet string to the data before it is encrypted.
   The length of the octet string equals the block size of the cipher in
   octets, plus two.  The first octets in the group, of length equal to
   the block size of the cipher, are random; the last two octets are
   each copies of their 2nd preceding octet.  For example, with a cipher
   whose block size is 128 bits or 16 octets, the prefix data will
   contain 16 random octets, then two more octets, which are copies of
   the 15th and 16th octets, respectively.  Unlike the deprecated
   Symmetrically Encrypted Data Packet (Section 5.7), this prefix data
   is encrypted in the same CFB context, and no special CFB
   resynchronization is done.

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   The repetition of 16 bits in the random data prefixed to the message
   allows the receiver to immediately check whether the session key is
   incorrect.  See Section 14.4 for hints on the proper use of this
   "quick check".

   Two constant octets with the values 0xD3 and 0x14 are appended to the
   plaintext.  Then, the plaintext of the data to be encrypted is passed
   through the SHA-1 hash function.  The input to the hash function
   includes the prefix data described above; it includes all of the
   plaintext, including the trailing constant octets 0xD3, 0x14.  The 20
   octets of the SHA-1 hash are then appended to the plaintext (after
   the constant octets 0xD3, 0x14) and encrypted along with the
   plaintext using the same CFB context.  This trailing checksum is
   known as the Modification Detection Code (MDC).

   During decryption, the plaintext data should be hashed with SHA-1,
   including the prefix data as well as the trailing constant octets
   0xD3, 0x14, but excluding the last 20 octets containing the SHA-1
   hash.  The computed SHA-1 hash is then compared with the last 20
   octets of plaintext.  A mismatch of the hash indicates that the
   message has been modified and MUST be treated as a security problem.
   Any failure SHOULD be reported to the user.

      NON-NORMATIVE EXPLANATION

      The Modification Detection Code (MDC) system, as the integrity
      protection mechanism of version 1 of the Symmetrically Encrypted
      Integrity Protected Data packet is called, was created to provide
      an integrity mechanism that is less strong than a signature, yet
      stronger than bare CFB encryption.

      It is a limitation of CFB encryption that damage to the ciphertext
      will corrupt the affected cipher blocks and the block following.
      Additionally, if data is removed from the end of a CFB-encrypted
      block, that removal is undetectable.  (Note also that CBC mode has
      a similar limitation, but data removed from the front of the block
      is undetectable.)

      The obvious way to protect or authenticate an encrypted block is
      to digitally sign it.  However, many people do not wish to
      habitually sign data, for a large number of reasons beyond the
      scope of this document.  Suffice it to say that many people
      consider properties such as deniability to be as valuable as
      integrity.

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      OpenPGP addresses this desire to have more security than raw
      encryption and yet preserve deniability with the MDC system.  An
      MDC is intentionally not a MAC.  Its name was not selected by
      accident.  It is analogous to a checksum.

      Despite the fact that it is a relatively modest system, it has
      proved itself in the real world.  It is an effective defense to
      several attacks that have surfaced since it has been created.  It
      has met its modest goals admirably.

      Consequently, because it is a modest security system, it has
      modest requirements on the hash function(s) it employs.  It does
      not rely on a hash function being collision-free, it relies on a
      hash function being one-way.  If a forger, Frank, wishes to send
      Alice a (digitally) unsigned message that says, "I've always
      secretly loved you, signed Bob", it is far easier for him to
      construct a new message than it is to modify anything intercepted
      from Bob.  (Note also that if Bob wishes to communicate secretly
      with Alice, but without authentication or identification and with
      a threat model that includes forgers, he has a problem that
      transcends mere cryptography.)

      Note also that unlike nearly every other OpenPGP subsystem, there
      are no parameters in the MDC system.  It hard-defines SHA-1 as its
      hash function.  This is not an accident.  It is an intentional
      choice to avoid downgrade and cross-grade attacks while making a
      simple, fast system.  (A downgrade attack would be an attack that
      replaced SHA2-256 with SHA-1, for example.  A cross-grade attack
      would replace SHA-1 with another 160-bit hash, such as RIPEMD-160,
      for example.)

      However, no update will be needed because the MDC has been
      replaced by the AEAD encryption described in this document.

5.13.2.  Version 2 Sym. Encrypted Integrity Protected Data Packet Format

   A version 2 Symmetrically Encrypted Integrity Protected Data packet
   consists of:

   *  A one-octet version number with value 2.

   *  A one-octet cipher algorithm.

   *  A one-octet AEAD algorithm.

   *  A one-octet chunk size.

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   *  Thirty-two octets of salt.  The salt is used to derive the message
      key and must be unique.

   *  Encrypted data, the output of the selected symmetric-key cipher
      operating in the given AEAD mode.

   *  A final, summary authentication tag for the AEAD mode.

   The decrypted session key and the salt are used to derive an M-bit
   message key and N-64 bits used as initialization vector, where M is
   the key size of the symmetric algorithm and N is the nonce size of
   the AEAD algorithm.  M + N - 64 bits are derived using HKDF (see
   [RFC5869]).  The left-most M bits are used as symmetric algorithm
   key, the remaining N - 64 bits are used as initialization vector.
   HKDF is used with SHA256 as hash algorithm, the session key as
   Initial Keying Material (IKM), the salt as salt, and the Packet Tag
   in OpenPGP format encoding (bits 7 and 6 set, bits 5-0 carry the
   packet tag), version number, cipher algorithm octet, AEAD algorithm
   octet, and chunk size octet as info parameter.

   The KDF mechanism provides key separation between cipher and AEAD
   algorithms.  Furthermore, an implementation can securely reply to a
   message even if a recipient's certificate is unknown by reusing the
   encrypted session key packets and replying with a different salt
   yielding a new, unique message key.

   A v2 SEIPD packet consists of one or more chunks of data.  The
   plaintext of each chunk is of a size specified using the chunk size
   octet using the method specified below.

   The encrypted data consists of the encryption of each chunk of
   plaintext, followed immediately by the relevant authentication tag.
   If the last chunk of plaintext is smaller than the chunk size, the
   ciphertext for that data may be shorter; it is nevertheless followed
   by a full authentication tag.

   For each chunk, the AEAD construction is given the Packet Tag in
   OpenPGP format encoding (bits 7 and 6 set, bits 5-0 carry the packet
   tag), version number, cipher algorithm octet, AEAD algorithm octet,
   and chunk size octet as additional data.  For example, the additional
   data of the first chunk using EAX and AES-128 with a chunk size of
   2**22 octets consists of the octets 0xD2, 0x02, 0x07, 0x01, and 0x10.

   After the final chunk, the AEAD algorithm is used to produce a final
   authentication tag encrypting the empty string.  This AEAD instance
   is given the additional data specified above, plus an eight-octet,
   big-endian value specifying the total number of plaintext octets
   encrypted.  This allows detection of a truncated ciphertext.

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   The chunk size octet specifies the size of chunks using the following
   formula (in C), where c is the chunk size octet:

     chunk_size = (uint32_t) 1 << (c + 6)

   An implementation MUST accept chunk size octets with values from 0 to
   16.  An implementation MUST NOT create data with a chunk size octet
   value larger than 16 (4 MiB chunks).

   The nonce for AEAD mode consists of two parts.  Let N be the size of
   the nonce.  The left-most N - 64 bits are the initialization vector
   derived using HKDF.  The right-most 64 bits are the chunk index as
   big-endian value.  The index of the first chunk is zero.

5.13.3.  EAX Mode

   The EAX AEAD Algorithm used in this document is defined in [EAX].

   The EAX algorithm can only use block ciphers with 16-octet blocks.
   The nonce is 16 octets long.  EAX authentication tags are 16 octets
   long.

5.13.4.  OCB Mode

   The OCB AEAD Algorithm used in this document is defined in [RFC7253].

   The OCB algorithm can only use block ciphers with 16-octet blocks.
   The nonce is 15 octets long.  OCB authentication tags are 16 octets
   long.

5.13.5.  GCM Mode

   The GCM AEAD Algorithm used in this document is defined in
   [SP800-38D].

   The GCM algorithm can only use block ciphers with 16-octet blocks.
   The nonce is 12 octets long.  GCM authentication tags are 16 octets
   long.

5.14.  Padding Packet (Tag 21)

   The Padding packet contains random data, and can be used to defend
   against traffic analysis (see Section 14.10) on version 2 SEIPD
   messages (see Section 5.13.2) and Transferable Public Keys (see
   Section 11.1).

   Such a packet MUST be ignored when received.

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   Its contents SHOULD be random octets to make the length obfuscation
   it provides more robust even when compressed.

   An implementation adding padding to an OpenPGP stream SHOULD place
   such a packet:

   *  At the end of a v6 Transferable Public Key that is transferred
      over an encrypted channel (see Section 11.1).

   *  As the last packet of an Optionally Padded Message within a
      version 2 Symmetrically Encrypted Integrity Protected Data Packet
      (see Section 11.3.1).

   An implementation MUST be able to process padding packets anywhere
   else in an OpenPGP stream, so that future revisions of this document
   may specify further locations for padding.

   Policy about how large to make such a packet to defend against
   traffic analysis is beyond the scope of this document.

6.  Radix-64 Conversions

   As stated in the introduction, OpenPGP's underlying native
   representation for objects is a stream of arbitrary octets, and some
   systems desire these objects to be immune to damage caused by
   character set translation, data conversions, etc.

   In principle, any printable encoding scheme that met the requirements
   of the unsafe channel would suffice, since it would not change the
   underlying binary bit streams of the native OpenPGP data structures.
   The OpenPGP standard specifies one such printable encoding scheme to
   ensure interoperability.

   OpenPGP's Radix-64 encoding is composed of two parts: a base64
   encoding of the binary data and an optional checksum.  The base64
   encoding used is described in Section 4 of [RFC4648], and it is
   wrapped into lines of no more than 76 characters each.

   When decoding base64, an OpenPGP implementation must ignore all white
   space.

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6.1.  Optional checksum

   The optional checksum is a 24-bit Cyclic Redundancy Check (CRC)
   converted to four characters of radix-64 encoding by the same MIME
   base64 transformation, preceded by an equal sign (=).  The CRC is
   computed by using the generator 0x864CFB and an initialization of
   0xB704CE.  The accumulation is done on the data before it is
   converted to radix-64, rather than on the converted data.  A sample
   implementation of this algorithm is in Section 6.1.1.

   If present, the checksum with its leading equal sign MUST appear on
   the next line after the base64 encoded data.

   An implementation MUST NOT reject an OpenPGP object when the CRC24
   footer is present, missing, malformed, or disagrees with the computed
   CRC24 sum.  When forming ASCII Armor, the CRC24 footer SHOULD NOT be
   generated, unless interoperability with implementations that require
   the CRC24 footer to be present is a concern.

   The CRC24 footer MUST NOT be generated if it can be determined by
   context or by the OpenPGP object being encoded that the consuming
   implementation accepts Radix-64 encoded blocks without CRC24 footer.
   Notably:

   *  An ASCII-armored Encrypted Message packet sequence that ends in an
      v2 SEIPD packet MUST NOT contain a CRC24 footer.

   *  An ASCII-armored sequence of Signature packets that only includes
      v6 Signature packets MUST NOT contain a CRC24 footer.

   *  An ASCII-armored Transferable Public Key packet sequence of a v6
      key MUST NOT contain a CRC24 footer.

   *  An ASCII-armored keyring consisting of only v6 keys MUST NOT
      contain a CRC24 footer.

   Rationale: Previous versions of this document state that the CRC24
   footer is optional, but the text was ambiguous.  In practice, very
   few implementations require the CRC24 footer to be present.
   Computing the CRC24 incurs a significant cost, while providing no
   meaningful integrity protection.  Therefore, generating it is now
   discouraged.

6.1.1.  An Implementation of the CRC-24 in "C"

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   #define CRC24_INIT 0xB704CEL
   #define CRC24_GENERATOR 0x864CFBL

   typedef unsigned long crc24;
   crc24 crc_octets(unsigned char *octets, size_t len)
   {
       crc24 crc = CRC24_INIT;
       int i;
       while (len--) {
           crc ^= (*octets++) << 16;
           for (i = 0; i < 8; i++) {
               crc <<= 1;
               if (crc & 0x1000000) {
                   crc &= 0xffffff; /* Clear bit 25 to avoid overflow */
                   crc ^= CRC24_GENERATOR;
               }
           }
       }
       return crc & 0xFFFFFFL;
   }

6.2.  Forming ASCII Armor

   When OpenPGP encodes data into ASCII Armor, it puts specific headers
   around the Radix-64 encoded data, so OpenPGP can reconstruct the data
   later.  An OpenPGP implementation MAY use ASCII armor to protect raw
   binary data.  OpenPGP informs the user what kind of data is encoded
   in the ASCII armor through the use of the headers.

   Concatenating the following data creates ASCII Armor:

   *  An Armor Header Line, appropriate for the type of data

   *  Armor Headers

   *  A blank (zero-length, or containing only whitespace) line

   *  The ASCII-Armored data

   *  An optional Armor Checksum (discouraged, see Section 6.1)

   *  The Armor Tail, which depends on the Armor Header Line

   An Armor Header Line consists of the appropriate header line text
   surrounded by five (5) dashes (-, 0x2D) on either side of the header
   line text.  The header line text is chosen based upon the type of
   data that is being encoded in Armor, and how it is being encoded.
   Header line texts include the following strings:

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   BEGIN PGP MESSAGE
      Used for signed, encrypted, or compressed files.

   BEGIN PGP PUBLIC KEY BLOCK
      Used for armoring public keys.

   BEGIN PGP PRIVATE KEY BLOCK
      Used for armoring private keys.

   BEGIN PGP SIGNATURE
      Used for detached signatures, OpenPGP/MIME signatures, and
      cleartext signatures.

   Note that all these Armor Header Lines are to consist of a complete
   line.  The header lines, therefore, MUST start at the beginning of a
   line, and MUST NOT have text other than whitespace following them on
   the same line.  These line endings are considered a part of the Armor
   Header Line for the purposes of determining the content they delimit.
   This is particularly important when computing a cleartext signature
   (see Section 7).

   The Armor Headers are pairs of strings that can give the user or the
   receiving OpenPGP implementation some information about how to decode
   or use the message.  The Armor Headers are a part of the armor, not a
   part of the message, and hence are not protected by any signatures
   applied to the message.

   The format of an Armor Header is that of a key-value pair.  A colon
   (: 0x38) and a single space (0x20) separate the key and value.  An
   OpenPGP implementation may consider improperly formatted Armor
   Headers to be corruption of the ASCII Armor, but SHOULD make an
   effort to recover.  Unknown keys should be silently ignored, and an
   OpenPGP implementation SHOULD continue to process the message.

   Note that some transport methods are sensitive to line length.  While
   there is a limit of 76 characters for the Radix-64 data (Section 6),
   there is no limit to the length of Armor Headers.  Care should be
   taken that the Armor Headers are short enough to survive transport.
   One way to do this is to repeat an Armor Header Key multiple times
   with different values for each so that no one line is overly long.

   Currently defined Armor Header Keys are as follows:

   *  "Version", which states the OpenPGP implementation and version
      used to encode the message.  To minimize metadata, implementations
      SHOULD NOT emit this key and its corresponding value except for
      debugging purposes with explicit user consent.

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   *  "Comment", a user-defined comment.  OpenPGP defines all text to be
      in UTF-8.  A comment may be any UTF-8 string.  However, the whole
      point of armoring is to provide seven-bit-clean data.
      Consequently, if a comment has characters that are outside the US-
      ASCII range of UTF, they may very well not survive transport.

   *  "Hash", a comma-separated list of hash algorithms used in this
      message.  This is used only in cleartext signed messages.

   *  "SaltedHash", a salt and hash algorithm used in this message.
      This is used only in cleartext signed messages that are followed
      by a v6 Signature.

   *  "Charset", a description of the character set that the plaintext
      is in.  Please note that OpenPGP defines text to be in UTF-8.  An
      implementation will get best results by translating into and out
      of UTF-8.  However, there are many instances where this is easier
      said than done.  Also, there are communities of users who have no
      need for UTF-8 because they are all happy with a character set
      like ISO Latin-5 or a Japanese character set.  In such instances,
      an implementation MAY override the UTF-8 default by using this
      header key.  An implementation MAY implement this key and any
      translations it cares to; an implementation MAY ignore it and
      assume all text is UTF-8.

   The Armor Tail Line is composed in the same manner as the Armor
   Header Line, except the string "BEGIN" is replaced by the string
   "END".

6.3.  Example of an ASCII Armored Message

   -----BEGIN PGP MESSAGE-----

   yDgBO22WxBHv7O8X7O/jygAEzol56iUKiXmV+XmpCtmpqQUKiQrFqclFqUDBovzS
   vBSFjNSiVHsuAA==
   -----END PGP MESSAGE-----

   Note that this example has extra indenting; an actual armored message
   would have no leading whitespace.

7.  Cleartext Signature Framework

   It is desirable to be able to sign a textual octet stream without
   ASCII armoring the stream itself, so the signed text is still
   readable without special software.  In order to bind a signature to
   such a cleartext, this framework is used, which follows the same
   basic format and restrictions as the ASCII armoring described in
   Section 6.2.  (Note that this framework is not intended to be

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   reversible.  [RFC3156] defines another way to sign cleartext messages
   for environments that support MIME.)

   The cleartext signed message consists of:

   *  The cleartext header -----BEGIN PGP SIGNED MESSAGE----- on a
      single line,

   *  If the message is signed using v3 or v4 Signatures, one or more
      "Hash" Armor Headers,

   *  If the message is signed using v6 Signatures, one or more
      "SaltedHash" Armor Headers,

   *  Exactly one empty line not included into the message digest,

   *  The dash-escaped cleartext that is included into the message
      digest,

   *  The ASCII armored signature(s) including the -----BEGIN PGP
      SIGNATURE----- Armor Header and Armor Tail Lines.

   If the "Hash" Armor Header is given, the specified message digest
   algorithm(s) are used for the signature.  If more than one message
   digest is used in the signatures, each digest algorithm has to be
   specified.  To that end, the "Hash" Armor Header contains a comma-
   delimited list of used message digests, and the "Hash" Armor Header
   can be given multiple times.

   If the "SaltedHash" Armor Header is given, the specified message
   digest algorithm and salt are used for a signature.  The message
   digest name is followed by a colon (:) followed by a random value
   encoded in Radix-64 without padding, which decoded length depends on
   the hash as specified in table Table 23.  Note: The "SaltedHash"
   Armor Header contains digest algorithm and salt for a single
   signature; a second signature requires a second "SaltedHash" Armor
   Header.

   If neither a "Hash" nor a "SaltedHash" Armor Header is given, or the
   message digest algorithms (and salts) used in the signatures do not
   match the information in the headers, the signature MUST be
   considered invalid.

   Current message digest names are described with the algorithm IDs in
   Section 9.5.

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   An implementation SHOULD add a line break after the cleartext, but
   MAY omit it if the cleartext ends with a line break.  This is for
   visual clarity.

7.1.  Dash-Escaped Text

   The cleartext content of the message must also be dash-escaped.

   Dash-escaped cleartext is the ordinary cleartext where every line
   starting with a "-" (HYPHEN-MINUS, U+002D) is prefixed by the
   sequence "-" (HYPHEN-MINUS, U+002D) and " " (SPACE, U+0020).  This
   prevents the parser from recognizing armor headers of the cleartext
   itself.  An implementation MAY dash-escape any line, SHOULD dash-
   escape lines commencing "From" followed by a space, and MUST dash-
   escape any line commencing in a dash.  The message digest is computed
   using the cleartext itself, not the dash-escaped form.

   As with binary signatures on text documents, a cleartext signature is
   calculated on the text using canonical <CR><LF> line endings.  The
   line ending (that is, the <CR><LF>) before the -----BEGIN PGP
   SIGNATURE----- line that terminates the signed text is not considered
   part of the signed text.

   When reversing dash-escaping, an implementation MUST strip the string
   - if it occurs at the beginning of a line, and SHOULD warn on - and
   any character other than a space at the beginning of a line.

   Also, any trailing whitespace --- spaces (0x20) and tabs (0x09) ---
   at the end of any line is removed when the cleartext signature is
   generated.

7.2.  Incompatibilities with Cleartext Signature Framework

   Since dash-escaping (Section 7.1) also involves trimming trailing
   whitespace on every line, the Cleartext Signature Framework will fail
   to safely round-trip any textual stream that may include semantically
   meaningful whitespace.

   For example, the Unified Diff format [UNIFIED-DIFF] contains
   semantically meaningful whitespace: an empty line of context will
   consist of a line with a single " " (SPACE, U+0020) character, and
   any line that has trailing whitespace added or removed will represent
   such a change with semantically meaningful whitespace.

   An implementation that knows it is working with such a textual stream
   SHOULD NOT use the Cleartext Signature Framework.  Safe alternatives
   for a semantically meaningful OpenPGP signature over such a file
   format are:

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   *  A Signed Message or One-Pass Signed Message object, as described
      in Section 11.3.

   *  A Detached Signature as described in Section 11.4.

   Either of these alternatives may be ASCII-armored (see Section 6.2)
   if they need to be transmitted across a text-only (or 7-bit clean)
   channel.

8.  Regular Expressions

   A regular expression is zero or more branches, separated by |. It
   matches anything that matches one of the branches.

   A branch is zero or more pieces, concatenated.  It matches a match
   for the first, followed by a match for the second, etc.

   A piece is an atom possibly followed by *, +, or ?. An atom followed
   by * matches a sequence of 0 or more matches of the atom.  An atom
   followed by + matches a sequence of 1 or more matches of the atom.
   An atom followed by ? matches a match of the atom, or the null
   string.

   An atom is a regular expression in parentheses (matching a match for
   the regular expression), a range (see below), . (matching any single
   character), ^ (matching the null string at the beginning of the input
   string), $ (matching the null string at the end of the input string),
   a \ followed by a single character (matching that character), or a
   single character with no other significance (matching that
   character).

   A range is a sequence of characters enclosed in [].  It normally
   matches any single character from the sequence.  If the sequence
   begins with ^, it matches any single character not from the rest of
   the sequence.  If two characters in the sequence are separated by -,
   this is shorthand for the full list of ASCII characters between them
   (for example, [0-9] matches any decimal digit).  To include a literal
   ] in the sequence, make it the first character (following a possible
   ^).  To include a literal -, make it the first or last character.

9.  Constants

   This section describes the constants used in OpenPGP.

   Note that these tables are not exhaustive lists; an implementation
   MAY implement an algorithm not on these lists, so long as the
   algorithm numbers are chosen from the private or experimental
   algorithm range.

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   See Section 13 for more discussion of the algorithms.

9.1.  Public-Key Algorithms

   +===+==============+=========+============+===========+=============+
   | ID| Algorithm    |Public   | Secret Key | Signature | PKESK       |
   |   |              |Key      | Format     | Format    | Format      |
   |   |              |Format   |            |           |             |
   +===+==============+=========+============+===========+=============+
   |  1| RSA (Encrypt |MPI(n),  | MPI(d),    | MPI(m**d  | MPI(m**e    |
   |   | or Sign)     |MPI(e)   | MPI(p),    | mod n)    | mod n)      |
   |   | [HAC]        |[Section | MPI(q),    | [Section  | [Section    |
   |   |              |5.5.5.1] | MPI(u)     | 5.2.3.1]  | 5.1.3]      |
   +---+--------------+---------+------------+-----------+-------------+
   |  2| RSA Encrypt- |MPI(n),  | MPI(d),    | N/A       | MPI(m**e    |
   |   | Only [HAC]   |MPI(e)   | MPI(p),    |           | mod n)      |
   |   |              |[Section | MPI(q),    |           | [Section    |
   |   |              |5.5.5.1] | MPI(u)     |           | 5.1.3]      |
   +---+--------------+---------+------------+-----------+-------------+
   |  3| RSA Sign-    |MPI(n),  | MPI(d),    | MPI(m**d  | N/A         |
   |   | Only [HAC]   |MPI(e)   | MPI(p),    | mod n)    |             |
   |   |              |[Section | MPI(q),    | [Section  |             |
   |   |              |5.5.5.1] | MPI(u)     | 5.2.3.1]  |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 16| Elgamal      |MPI(p),  | MPI(x)     | N/A       | MPI(g**k    |
   |   | (Encrypt-    |MPI(g),  |            |           | mod p),     |
   |   | Only)        |MPI(y)   |            |           | MPI (m *    |
   |   | [ELGAMAL]    |[Section |            |           | y**k mod    |
   |   | [HAC]        |5.5.5.3] |            |           | p)          |
   |   |              |         |            |           | [Section    |
   |   |              |         |            |           | 5.1.4]      |
   +---+--------------+---------+------------+-----------+-------------+
   | 17| DSA (Digital |MPI(p),  | MPI(x)     | MPI(r),   | N/A         |
   |   | Signature    |MPI(q),  |            | MPI(s)    |             |
   |   | Algorithm)   |MPI(g),  |            | [Section  |             |
   |   | [FIPS186]    |MPI(y)   |            | 5.2.3.2]  |             |
   |   | [HAC]        |[Section |            |           |             |
   |   |              |5.5.5.2] |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 18| ECDH public  |OID,     | MPI(value  | N/A       | MPI(point   |
   |   | key          |MPI(point| in curve-  |           | in curve-   |
   |   | algorithm    |in curve-| specific   |           | specific    |
   |   |              |specific | format)    |           | point       |
   |   |              |point    | [Section   |           | format),    |
   |   |              |format), | 9.2.1]     |           | size        |
   |   |              |KDFParams|            |           | octet,      |
   |   |              |[see     |            |           | encoded     |
   |   |              |Section  |            |           | key         |

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   |   |              |9.2.1,   |            |           | [Section    |
   |   |              |Section  |            |           | 9.2.1,      |
   |   |              |5.5.5.6] |            |           | Section     |
   |   |              |         |            |           | 5.1.5,      |
   |   |              |         |            |           | Section     |
   |   |              |         |            |           | 12.5]       |
   +---+--------------+---------+------------+-----------+-------------+
   | 19| ECDSA public |OID,     | MPI(value) | MPI(r),   | N/A         |
   |   | key          |MPI(point|            | MPI(s)    |             |
   |   | algorithm    |in SEC1  |            | [Section  |             |
   |   | [FIPS186]    |format)  |            | 5.2.3.2]  |             |
   |   |              |[Section |            |           |             |
   |   |              |5.5.5.4] |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 20| Reserved     |         |            |           |             |
   |   | (formerly    |         |            |           |             |
   |   | Elgamal      |         |            |           |             |
   |   | Encrypt or   |         |            |           |             |
   |   | Sign)        |         |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 21| Reserved for |         |            |           |             |
   |   | Diffie-      |         |            |           |             |
   |   | Hellman      |         |            |           |             |
   |   | (X9.42, as   |         |            |           |             |
   |   | defined for  |         |            |           |             |
   |   | IETF-S/MIME) |         |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 22| EdDSALegacy  |OID,     | MPI(value  | MPI, MPI  | N/A         |
   |   | (deprecated) |MPI(point| in curve-  | [see      |             |
   |   |              |in       | specific   | Section   |             |
   |   |              |prefixed | format)    | 9.2.1,    |             |
   |   |              |native   | [see       | Section   |             |
   |   |              |format)  | Section    | 5.2.3.3]  |             |
   |   |              |[see     | 9.2.1]     |           |             |
   |   |              |Section  |            |           |             |
   |   |              |12.2.2,  |            |           |             |
   |   |              |Section  |            |           |             |
   |   |              |5.5.5.5] |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 23| Reserved     |         |            |           |             |
   |   | (AEDH)       |         |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 24| Reserved     |         |            |           |             |
   |   | (AEDSA)      |         |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 25| X25519       |32 octets| 32 octets  | N/A       | 32          |
   |   |              |         |            |           | octets,     |
   |   |              |         |            |           | size        |

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   |   |              |         |            |           | octet,      |
   |   |              |         |            |           | encoded     |
   |   |              |         |            |           | key         |
   +---+--------------+---------+------------+-----------+-------------+
   | 26| X448         |56 octets| 56 octets  | N/A       | 56          |
   |   |              |         |            |           | octets,     |
   |   |              |         |            |           | size        |
   |   |              |         |            |           | octet,      |
   |   |              |         |            |           | encoded     |
   |   |              |         |            |           | key         |
   +---+--------------+---------+------------+-----------+-------------+
   | 27| Ed25519      |32 octets| 32 octets  | 64 octets |             |
   +---+--------------+---------+------------+-----------+-------------+
   | 28| Ed448        |57 octets| 57 octets  | 114       |             |
   |   |              |         |            | octets    |             |
   +---+--------------+---------+------------+-----------+-------------+
   |100| Private/     |         |            |           |             |
   | to| Experimental |         |            |           |             |
   |110| algorithm    |         |            |           |             |
   +---+--------------+---------+------------+-----------+-------------+

                  Table 18: Public-key algorithm registry

   Implementations MUST implement Ed25519 (27) for signatures, and
   X25519 (25) for encryption.  Implementations SHOULD implement Ed448
   (28) and X448 (26).

   RSA (1) keys are deprecated and SHOULD NOT be generated, but may be
   interpreted.  RSA Encrypt-Only (2) and RSA Sign-Only (3) are
   deprecated and MUST NOT be generated.  See Section 13.4.  Elgamal
   (16) keys are deprecated and MUST NOT be generated (see
   Section 13.6).  DSA (17) keys are deprecated and MUST NOT be
   generated (see Section 13.5).  See Section 13.8 for notes on Elgamal
   Encrypt or Sign (20), and X9.42 (21).  Implementations MAY implement
   any other algorithm.

   Note that an implementation conforming to the previous version of
   this standard ([RFC4880]) has only DSA (17) and Elgamal (16) as its
   MUST-implement algorithms.

   A compatible specification of ECDSA is given in [RFC6090] as "KT-I
   Signatures" and in [SEC1]; ECDH is defined in Section 12.5 of this
   document.

9.2.  ECC Curves for OpenPGP

   The parameter curve OID is an array of octets that defines a named
   curve.

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   The table below specifies the exact sequence of octets for each named
   curve referenced in this document.  It also specifies which public
   key algorithms the curve can be used with, as well as the size of
   expected elements in octets:

   +======================+===+======+================+===========+=======+
   |ASN.1 Object          |OID|Curve |Curve name      |Usage      |Field  |
   |Identifier            |len|OID   |                |           |Size   |
   |                      |   |octets|                |           |(fsize)|
   |                      |   |in hex|                |           |       |
   +======================+===+======+================+===========+=======+
   |1.2.840.10045.3.1.7   |8  |2A 86 |NIST P-256      |ECDSA, ECDH|32     |
   |                      |   |48 CE |                |           |       |
   |                      |   |3D 03 |                |           |       |
   |                      |   |01 07 |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+
   |1.3.132.0.34          |5  |2B 81 |NIST P-384      |ECDSA, ECDH|48     |
   |                      |   |04 00 |                |           |       |
   |                      |   |22    |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+
   |1.3.132.0.35          |5  |2B 81 |NIST P-521      |ECDSA, ECDH|66     |
   |                      |   |04 00 |                |           |       |
   |                      |   |23    |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+
   |1.3.36.3.3.2.8.1.1.7  |9  |2B 24 |brainpoolP256r1 |ECDSA, ECDH|32     |
   |                      |   |03 03 |                |           |       |
   |                      |   |02 08 |                |           |       |
   |                      |   |01 01 |                |           |       |
   |                      |   |07    |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+
   |1.3.36.3.3.2.8.1.1.11 |9  |2B 24 |brainpoolP384r1 |ECDSA, ECDH|48     |
   |                      |   |03 03 |                |           |       |
   |                      |   |02 08 |                |           |       |
   |                      |   |01 01 |                |           |       |
   |                      |   |0B    |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+
   |1.3.36.3.3.2.8.1.1.13 |9  |2B 24 |brainpoolP512r1 |ECDSA, ECDH|64     |
   |                      |   |03 03 |                |           |       |
   |                      |   |02 08 |                |           |       |
   |                      |   |01 01 |                |           |       |
   |                      |   |0D    |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+
   |1.3.6.1.4.1.11591.15.1|9  |2B 06 |Ed25519Legacy   |EdDSALegacy|32     |
   |                      |   |01 04 |                |           |       |
   |                      |   |01 DA |                |           |       |
   |                      |   |47 0F |                |           |       |
   |                      |   |01    |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+

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   |1.3.6.1.4.1.3029.1.5.1|10 |2B 06 |Curve25519Legacy|ECDH       |32     |
   |                      |   |01 04 |                |           |       |
   |                      |   |01 97 |                |           |       |
   |                      |   |55 01 |                |           |       |
   |                      |   |05 01 |                |           |       |
   +----------------------+---+------+----------------+-----------+-------+

                 Table 19: ECC Curve OID and usage registry

   The "Field Size (fsize)" column represents the field size of the
   group in number of octets, rounded up, such that x or y coordinates
   for a point on the curve or native point representations for the
   curve can be represented in that many octets.  For the curves
   specified here, also scalars such as the base point order and the
   private key can be represented in fsize octets.  Note that, however,
   there exist curves outside this specification where the
   representation of scalars requires an additional octet.

   The sequence of octets in the third column is the result of applying
   the Distinguished Encoding Rules (DER) to the ASN.1 Object Identifier
   with subsequent truncation.  The truncation removes the two fields of
   encoded Object Identifier.  The first omitted field is one octet
   representing the Object Identifier tag, and the second omitted field
   is the length of the Object Identifier body.  For example, the
   complete ASN.1 DER encoding for the NIST P-256 curve OID is "06 08 2A
   86 48 CE 3D 03 01 07", from which the first entry in the table above
   is constructed by omitting the first two octets.  Only the truncated
   sequence of octets is the valid representation of a curve OID.

   The deprecated OIDs for Ed25519Legacy and Curve25519Legacy are used
   in legacy version 4 keys and signatures.  Implementations MAY
   implement these variants for compatibility with existing v4 key
   material and signatures.  Implementations MUST NOT accept or generate
   v6 key material using the deprecated OIDs.

9.2.1.  Curve-Specific Wire Formats

   Some Elliptic Curve Public Key Algorithms use different conventions
   for specific fields depending on the curve in use.  Each field is
   always formatted as an MPI, but with a curve-specific framing.  This
   table summarizes those distinctions.

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   +================+========+============+=======+=========+==========+
   |Curve           |ECDH    |ECDH Secret |EdDSA  |EdDSA    |EdDSA     |
   |                |Point   |Key MPI     |Secret |Signature|Signature |
   |                |Format  |            |Key MPI|first MPI|second    |
   |                |        |            |       |         |MPI       |
   +================+========+============+=======+=========+==========+
   |NIST P-256      |SEC1    |integer     |N/A    |N/A      |N/A       |
   +----------------+--------+------------+-------+---------+----------+
   |NIST P-384      |SEC1    |integer     |N/A    |N/A      |N/A       |
   +----------------+--------+------------+-------+---------+----------+
   |NIST P-521      |SEC1    |integer     |N/A    |N/A      |N/A       |
   +----------------+--------+------------+-------+---------+----------+
   |brainpoolP256r1 |SEC1    |integer     |N/A    |N/A      |N/A       |
   +----------------+--------+------------+-------+---------+----------+
   |brainpoolP384r1 |SEC1    |integer     |N/A    |N/A      |N/A       |
   +----------------+--------+------------+-------+---------+----------+
   |brainpoolP512r1 |SEC1    |integer     |N/A    |N/A      |N/A       |
   +----------------+--------+------------+-------+---------+----------+
   |Ed25519Legacy   |N/A     |N/A         |32     |32 octets|32 octets |
   |                |        |            |octets |of R     |of S      |
   |                |        |            |of     |         |          |
   |                |        |            |secret |         |          |
   +----------------+--------+------------+-------+---------+----------+
   |Curve25519Legacy|prefixed|integer (see|N/A    |N/A      |N/A       |
   |                |native  |Section     |       |         |          |
   |                |        |5.5.5.6.1.1)|       |         |          |
   +----------------+--------+------------+-------+---------+----------+

                   Table 20: Curve-specific wire formats

   For the native octet-string forms of EdDSA values, see [RFC8032].
   For the native octet-string forms of ECDH secret scalars and points,
   see [RFC7748].

9.3.  Symmetric-Key Algorithms

     +==========+====================================================+
     |       ID | Algorithm                                          |
     +==========+====================================================+
     |        0 | Plaintext or unencrypted data                      |
     +----------+----------------------------------------------------+
     |        1 | IDEA [IDEA]                                        |
     +----------+----------------------------------------------------+
     |        2 | TripleDES (DES-EDE, [SCHNEIER], [HAC] - 168 bit    |
     |          | key derived from 192)                              |
     +----------+----------------------------------------------------+
     |        3 | CAST5 (128 bit key, as per [RFC2144])              |
     +----------+----------------------------------------------------+

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     |        4 | Blowfish (128 bit key, 16 rounds) [BLOWFISH]       |
     +----------+----------------------------------------------------+
     |        5 | Reserved                                           |
     +----------+----------------------------------------------------+
     |        6 | Reserved                                           |
     +----------+----------------------------------------------------+
     |        7 | AES with 128-bit key [AES]                         |
     +----------+----------------------------------------------------+
     |        8 | AES with 192-bit key                               |
     +----------+----------------------------------------------------+
     |        9 | AES with 256-bit key                               |
     +----------+----------------------------------------------------+
     |       10 | Twofish with 256-bit key [TWOFISH]                 |
     +----------+----------------------------------------------------+
     |       11 | Camellia with 128-bit key [RFC3713]                |
     +----------+----------------------------------------------------+
     |       12 | Camellia with 192-bit key                          |
     +----------+----------------------------------------------------+
     |       13 | Camellia with 256-bit key                          |
     +----------+----------------------------------------------------+
     |   100 to | Private/Experimental algorithm                     |
     |      110 |                                                    |
     +----------+----------------------------------------------------+
     | 253, 254 | Reserved to avoid collision with Secret Key        |
     |  and 255 | Encryption (see Section 3.7.2.1 and Section 5.5.3) |
     +----------+----------------------------------------------------+

                 Table 21: Symmetric-key algorithm registry

   Implementations MUST implement AES-128.  Implementations SHOULD
   implement AES-256.  Implementations MUST NOT encrypt data with IDEA,
   TripleDES, or CAST5.  Implementations MAY decrypt data that uses
   IDEA, TripleDES, or CAST5 for the sake of reading older messages or
   new messages from legacy clients.  An Implementation that decrypts
   data using IDEA, TripleDES, or CAST5 SHOULD generate a deprecation
   warning about the symmetric algorithm, indicating that message
   confidentiality is suspect.  Implementations MAY implement any other
   algorithm.

9.4.  Compression Algorithms

              +============+================================+
              |         ID | Algorithm                      |
              +============+================================+
              |          0 | Uncompressed                   |
              +------------+--------------------------------+
              |          1 | ZIP [RFC1951]                  |
              +------------+--------------------------------+

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              |          2 | ZLIB [RFC1950]                 |
              +------------+--------------------------------+
              |          3 | BZip2 [BZ2]                    |
              +------------+--------------------------------+
              | 100 to 110 | Private/Experimental algorithm |
              +------------+--------------------------------+

                  Table 22: Compression algorithm registry

   Implementations MUST implement uncompressed data.  Implementations
   SHOULD implement ZLIB.  For interoperability reasons implementations
   SHOULD be able to decompress using ZIP.  Implementations MAY
   implement any other algorithm.

9.5.  Hash Algorithms

      +========+======================+=============+==============+
      |     ID | Algorithm            | Text Name   | V6 signature |
      |        |                      |             | salt size    |
      +========+======================+=============+==============+
      |      1 | MD5 [HAC]            | "MD5"       | N/A          |
      +--------+----------------------+-------------+--------------+
      |      2 | SHA-1 [FIPS180],     | "SHA1"      | N/A          |
      |        | Section 14.1         |             |              |
      +--------+----------------------+-------------+--------------+
      |      3 | RIPEMD-160 [HAC]     | "RIPEMD160" | N/A          |
      +--------+----------------------+-------------+--------------+
      |      4 | Reserved             |             |              |
      +--------+----------------------+-------------+--------------+
      |      5 | Reserved             |             |              |
      +--------+----------------------+-------------+--------------+
      |      6 | Reserved             |             |              |
      +--------+----------------------+-------------+--------------+
      |      7 | Reserved             |             |              |
      +--------+----------------------+-------------+--------------+
      |      8 | SHA2-256 [FIPS180]   | "SHA256"    | 16           |
      +--------+----------------------+-------------+--------------+
      |      9 | SHA2-384 [FIPS180]   | "SHA384"    | 24           |
      +--------+----------------------+-------------+--------------+
      |     10 | SHA2-512 [FIPS180]   | "SHA512"    | 32           |
      +--------+----------------------+-------------+--------------+
      |     11 | SHA2-224 [FIPS180]   | "SHA224"    | 16           |
      +--------+----------------------+-------------+--------------+
      |     12 | SHA3-256 [FIPS202]   | "SHA3-256"  | 16           |
      +--------+----------------------+-------------+--------------+
      |     13 | Reserved             |             |              |
      +--------+----------------------+-------------+--------------+
      |     14 | SHA3-512 [FIPS202]   | "SHA3-512"  | 32           |

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      +--------+----------------------+-------------+--------------+
      | 100 to | Private/Experimental |             |              |
      |    110 | algorithm            |             |              |
      +--------+----------------------+-------------+--------------+

                    Table 23: Hash algorithm registry

   Implementations MUST implement SHA2-256.  Implementations SHOULD
   implement SHA2-384 and SHA2-512.  Implementations MAY implement other
   algorithms.  Implementations SHOULD NOT create messages which require
   the use of SHA-1 with the exception of computing version 4 key
   fingerprints and for purposes of the Modification Detection Code
   (MDC) in version 1 Symmetrically Encrypted Integrity Protected Data
   packets.  Implementations MUST NOT generate signatures with MD5, SHA-
   1, or RIPEMD-160.  Implementations MUST NOT use MD5, SHA-1, or
   RIPEMD-160 as a hash function in an ECDH KDF.  Implementations MUST
   NOT validate any recent signature that depends on MD5, SHA-1, or
   RIPEMD-160.  Implementations SHOULD NOT validate any old signature
   that depends on MD5, SHA-1, or RIPEMD-160 unless the signature's
   creation date predates known weakness of the algorithm used, and the
   implementation is confident that the message has been in the secure
   custody of the user the whole time.

9.6.  AEAD Algorithms

    +========+======================+===========+====================+
    |     ID | Algorithm            | IV length | authentication tag |
    |        |                      | (octets)  | length (octets)    |
    +========+======================+===========+====================+
    |      1 | EAX [EAX]            | 16        | 16                 |
    +--------+----------------------+-----------+--------------------+
    |      2 | OCB [RFC7253]        | 15        | 16                 |
    +--------+----------------------+-----------+--------------------+
    |      3 | GCM [SP800-38D]      | 12        | 16                 |
    +--------+----------------------+-----------+--------------------+
    | 100 to | Private/Experimental |           |                    |
    |    110 | algorithm            |           |                    |
    +--------+----------------------+-----------+--------------------+

                    Table 24: AEAD algorithm registry

   Implementations MUST implement OCB.  Implementations MAY implement
   EAX, GCM and other algorithms.

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10.  IANA Considerations

   Because this document obsoletes [RFC4880], IANA is requested to
   update all registration information that references [RFC4880] to
   instead reference this RFC.

   OpenPGP is highly parameterized, and consequently there are a number
   of considerations for allocating parameters for extensions.

   This section describes the updated IANA registration policies.  Most
   of the registries listed below have been moved the SPECIFICATION
   REQUIRED registration policy, see [RFC8126].  This policy means that
   review and approval by a designated expert is required, and that the
   values and their meanings must be documented in a permanent and
   readily available public specification, in sufficient detail so that
   interoperability between independent implementations is possible.
   The designated expert will determine whether the new code points
   retain the security properties that are expected by the base
   implementation and that these new code points do not cause
   interoperability issues with existing implementations other than not
   producing or consuming these new code points.  Code point proposals
   that fail to meet these criteria should instead be proposed as work
   items for the OpenPGP working group or its successor.

10.1.  String-to-Key Specifier Types

   OpenPGP S2K specifiers contain a mechanism for new algorithms to turn
   a string into a key.  This specification creates a registry of S2K
   specifier types.  The registry includes the S2K type, the name of the
   S2K, and a reference to the defining specification.  The initial
   values for this registry can be found in Section 3.7.1.  Adding a new
   S2K specifier MUST be done through the SPECIFICATION REQUIRED method,
   as described in [RFC8126].

   IANA should add a column "Generate?" to the S2K type registry, with
   initial values taken from Section 3.7.1.

10.2.  Packet

   Major new features of OpenPGP are defined through new packet types.
   This specification creates a registry of packet types.  The registry
   includes the packet type, the name of the packet, and a reference to
   the defining specification.  The initial values for this registry can
   be found in Section 4.3.  Adding a new packet type MUST be done
   through the RFC REQUIRED method, as described in [RFC8126].

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10.2.1.  User Attribute Subpackets

   The User Attribute packet permits an extensible mechanism for other
   types of certificate identification.  This specification creates a
   registry of User Attribute types.  The registry includes the User
   Attribute type, the name of the User Attribute, and a reference to
   the defining specification.  The initial values for this registry can
   be found in Section 5.12.  Adding a new User Attribute type MUST be
   done through the SPECIFICATION REQUIRED method, as described in
   [RFC8126].

10.2.1.1.  Image Attribute Formats

   Within User Attribute packets, there is an extensible mechanism for
   other types of image-based User Attributes.  This specification
   creates a registry of Image Attribute subpacket types.  The registry
   includes the Image Attribute subpacket type, the name of the Image
   Attribute subpacket, and a reference to the defining specification.
   The initial values for this registry can be found in Section 5.12.1.
   Adding a new Image Attribute subpacket type MUST be done through the
   SPECIFICATION REQUIRED method, as described in [RFC8126].

10.2.2.  Signature Subpackets

   OpenPGP signatures contain a mechanism for signed (or unsigned) data
   to be added to them for a variety of purposes in the Signature
   subpackets as discussed in Section 5.2.3.7.  This specification
   creates a registry of Signature subpacket types.  The registry
   includes the Signature subpacket type, the name of the subpacket, and
   a reference to the defining specification.  The initial values for
   this registry can be found in Section 5.2.3.7.  Adding a new
   Signature subpacket MUST be done through the SPECIFICATION REQUIRED
   method, as described in [RFC8126].

10.2.2.1.  Signature Notation Data Subpackets

   OpenPGP signatures further contain a mechanism for extensions in
   signatures.  These are the Notation Data subpackets, which contain a
   key/value pair.  Notations contain a user space that is completely
   unmanaged and an IETF space.

   This specification creates a registry of Signature Notation Data
   types.  The registry includes the name of the Signature Notation
   Data, the Signature Notation Data type, its allowed values, and a
   reference to the defining specification.  The initial values for this
   registry can be found in Section 5.2.3.24.  Adding a new Signature
   Notation Data subpacket MUST be done through the SPECIFICATION
   REQUIRED method, as described in [RFC8126].

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10.2.2.2.  Signature Notation Data Subpacket Notation Flags

   This specification creates a new registry of Signature Notation Data
   Subpacket Notation Flags.  The registry includes the columns "Flag",
   "Shorthand", "Description", "Security Recommended", "Interoperability
   Recommended", and "Reference".  The initial values for this registry
   can be found in Section 5.2.3.24.  Adding a new item MUST be done
   through the SPECIFICATION REQUIRED method, as described in [RFC8126].

10.2.2.3.  Key Server Preference Extensions

   OpenPGP signatures contain a mechanism for preferences to be
   specified about key servers.  This specification creates a registry
   of key server preferences.  The registry includes the key server
   preference, the name of the preference, and a reference to the
   defining specification.  The initial values for this registry can be
   found in Section 5.2.3.25.  Adding a new key server preference MUST
   be done through the SPECIFICATION REQUIRED method, as described in
   [RFC8126].

10.2.2.4.  Key Flags Extensions

   OpenPGP signatures contain a mechanism for flags to be specified
   about key usage.  This specification creates a registry of key usage
   flags.  The registry includes the key flags value, the name of the
   flag, and a reference to the defining specification.  The initial
   values for this registry can be found in Section 5.2.3.29.  Adding a
   new key usage flag MUST be done through the SPECIFICATION REQUIRED
   method, as described in [RFC8126].

10.2.2.5.  Reason for Revocation Extensions

   OpenPGP signatures contain a mechanism for flags to be specified
   about why a key was revoked.  This specification creates a registry
   of "Reason for Revocation" flags.  The registry includes the "Reason
   for Revocation" flags value, the name of the flag, and a reference to
   the defining specification.  The initial values for this registry can
   be found in Section 5.2.3.31.  Adding a new feature flag MUST be done
   through the SPECIFICATION REQUIRED method, as described in [RFC8126].

10.2.2.6.  Implementation Features

   OpenPGP signatures contain a mechanism for flags to be specified
   stating which optional features an implementation supports.  This
   specification creates a registry of feature-implementation flags.
   The registry includes the feature-implementation flags value, the
   name of the flag, and a reference to the defining specification.  The
   initial values for this registry can be found in Section 5.2.3.32.

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   Adding a new feature-implementation flag MUST be done through the
   SPECIFICATION REQUIRED method, as described in [RFC8126].

   Also see Section 13.11 for more information about when feature flags
   are needed.

10.2.3.  Packet Versions

   The core OpenPGP packets all have version numbers, and can be revised
   by introducing a new version of an existing packet.  This
   specification creates a registry of packet types.  The registry
   includes the packet type, the number of the version, and a reference
   to the defining specification.  The initial values for this registry
   can be found in Section 5.  Adding a new packet version MUST be done
   through the RFC REQUIRED method, as described in [RFC8126].

10.3.  Algorithms

   Section 9 lists the core algorithms that OpenPGP uses.  Adding in a
   new algorithm is usually simple.  For example, adding in a new
   symmetric cipher usually would not need anything more than allocating
   a constant for that cipher.  If that cipher had other than a 64-bit
   or 128-bit block size, there might need to be additional
   documentation describing how the use of CFB mode would be adjusted.
   Similarly, when DSA was expanded from a maximum of 1024-bit public
   keys to 3072-bit public keys, the revision of FIPS 186 contained
   enough information itself to allow implementation.  Changes to this
   document were made mainly for emphasis.

10.3.1.  Public-Key Algorithms

   OpenPGP specifies a number of public-key algorithms.  This
   specification creates a registry of public-key algorithm identifiers.
   The registry includes the algorithm name, its key sizes and
   parameters, and a reference to the defining specification.  The
   initial values for this registry can be found in Section 9.1.  Adding
   a new public-key algorithm MUST be done through the SPECIFICATION
   REQUIRED method, as described in [RFC8126].

   This document requests IANA register the following new public-key
   algorithms:

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             +====+=============+============================+
             | ID | Algorithm   | Reference                  |
             +====+=============+============================+
             | 22 | EdDSALegacy | This doc, Section 13.7     |
             +----+-------------+----------------------------+
             | 25 | X25519      | This doc, Section 5.5.5.7  |
             +----+-------------+----------------------------+
             | 26 | X448        | This doc, Section 5.5.5.8  |
             +----+-------------+----------------------------+
             | 27 | Ed25519     | This doc, Section 5.5.5.9  |
             +----+-------------+----------------------------+
             | 28 | Ed448       | This doc, Section 5.5.5.10 |
             +----+-------------+----------------------------+

               Table 25: New public-Key algorithms registered

   [ Note to RFC-Editor: Please remove the table above on publication. ]

10.3.1.1.  Elliptic Curve Algorithms

   Some public key algorithms use Elliptic Curves.  In particular,
   ECDH/ECDSA/EdDSALegacy public key algorithms all allow specific
   curves to be used, as indicated by OID.  To register a new elliptic
   curve for use with OpenPGP, its OID needs to be registered in
   Table 19, its wire format needs to be documented in Table 20, and if
   used for ECDH, its KDF and KEK parameters must be populated in
   Table 30.

10.3.2.  Symmetric-Key Algorithms

   OpenPGP specifies a number of symmetric-key algorithms.  This
   specification creates a registry of symmetric-key algorithm
   identifiers.  The registry includes the algorithm name, its key sizes
   and block size, and a reference to the defining specification.  The
   initial values for this registry can be found in Section 9.3.  Adding
   a new symmetric-key algorithm MUST be done through the SPECIFICATION
   REQUIRED method, as described in [RFC8126].

10.3.3.  Hash Algorithms

   OpenPGP specifies a number of hash algorithms.  This specification
   creates a registry of hash algorithm identifiers.  The registry
   includes the algorithm name, a text representation of that name, its
   block size, an OID hash prefix, and a reference to the defining
   specification.  The initial values for this registry can be found in
   Section 9.5 for the algorithm identifiers and text names, and
   Section 5.2.2 for the OIDs and expanded signature prefixes.  Adding a
   new hash algorithm MUST be done through the SPECIFICATION REQUIRED

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   method, as described in [RFC8126].

   This document requests IANA register the following hash algorithms:

                      +====+===========+===========+
                      | ID | Algorithm | Reference |
                      +====+===========+===========+
                      | 12 | SHA3-256  | This doc  |
                      +----+-----------+-----------+
                      | 13 | Reserved  |           |
                      +----+-----------+-----------+
                      | 14 | SHA3-512  | This doc  |
                      +----+-----------+-----------+

                            Table 26: New hash
                          algorithms registered

   [Notes to RFC-Editor: Please remove the table above on publication.
   It is desirable not to reuse old or reserved algorithms because some
   existing tools might print a wrong description.  The ID 13 has been
   reserved so that the SHA3 algorithm IDs align nicely with their SHA2
   counterparts.]

10.3.4.  Compression Algorithms

   OpenPGP specifies a number of compression algorithms.  This
   specification creates a registry of compression algorithm
   identifiers.  The registry includes the algorithm name and a
   reference to the defining specification.  The initial values for this
   registry can be found in Section 9.4.  Adding a new compression key
   algorithm MUST be done through the SPECIFICATION REQUIRED method, as
   described in [RFC8126].

10.3.5.  Elliptic Curve Algorithms

   This document requests IANA add a registry of elliptic curves for use
   in OpenPGP.

   Each curve is identified on the wire by OID, and is acceptable for
   use in certain OpenPGP public key algorithms.  The table's initial
   headings and values can be found in Section 9.2.  Adding a new
   elliptic curve algorithm to OpenPGP MUST be done through the
   SPECIFICATION REQUIRED method, as described in [RFC8126].  If the new
   curve can be used for ECDH, it must also be added to the "Curve-
   specific wire formats" table described in Section 9.2.1.

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10.4.  Elliptic Curve Point and Scalar Wire Formats

   This document requests IANA add a registry of wire formats that
   represent elliptic curve points.  The table's initial headings and
   values can be found in Section 12.2.  Adding a new EC point wire
   format MUST be done through the SPECIFICATION REQUIRED method, as
   described in [RFC8126].

   This document also requests IANA add a registry of wire formats that
   represent scalars for use with elliptic curve cryptography.  The
   table's initial headings and values can be found in Section 12.3.
   Adding a new EC scalar wire format MUST be done through the
   SPECIFICATION REQUIRED method, as described in [RFC8126].

   This document also requests that IANA add a registry mapping curve-
   specific MPI octet-string encoding conventions for ECDH and
   EdDSALegacy.  The table's initial headings and values can be found in
   Section 9.2.1.  Adding a new elliptic curve algorithm to OpenPGP MUST
   be done through the SPECIFICATION REQUIRED method, as described in
   [RFC8126], and requires adding an entry to this table if the curve is
   to be used with ECDH.

10.5.  Changes to existing registries

   This document requests IANA add the following wire format columns to
   the OpenPGP public-key algorithm registry:

   *  Public Key Format

   *  Secret Key Format

   *  Signature Format

   *  PKESK Format

   And populate them with the values found in Section 9.1.

11.  Packet Composition

   OpenPGP packets are assembled into sequences in order to create
   messages and to transfer keys.  Not all possible packet sequences are
   meaningful and correct.  This section describes the rules for how
   packets should be placed into sequences.

   There are three distinct sequences of packets:

   *  Transferable Public Keys (Section 11.1) and its close counterpart,
      Transferable Secret Keys (Section 11.2)

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   *  OpenPGP Messages (Section 11.3)

   *  Detached Signatures (Section 11.4)

   Each sequence has an explicit grammar of what packet types (Table 4)
   can appear in what place.  The presence of an unknown critical
   packet, or a known but unexpected packet is a critical error,
   invalidating the entire sequence (see Section 4.3.1).  On the other
   hand, unknown non-critical packets can appear anywhere within any
   sequence.  This provides a structured way to introduce new packets
   into the protocol, while making sure that certain packets will be
   handled strictly.

   An implementation may "recognize" a packet, but not implement it.
   The purpose of Packet Criticality is to allow the producer to tell
   the consumer whether it would prefer a new, unknown packet to
   generate an error or be ignored.

   Note that previous versions of this document did not have a concept
   of Packet Criticality, and did not give clear guidance on what to do
   when unknown packets are encountered.  Therefore, a legacy
   implementation may reject unknown non-critical packets, or accept
   unknown critical packets.

   When generating a sequence of OpenPGP packets according to one of the
   three grammars, an implementation MUST NOT inject a critical packet
   of a type that does not adhere to the grammar.

   When consuming a sequence of OpenPGP packets according to one of the
   three grammars, an implementation MUST reject the sequence with an
   error if it encounters a critical packet of inappropriate type
   according to the grammar.

11.1.  Transferable Public Keys

   OpenPGP users may transfer public keys.  This section describes the
   structure of public keys in transit to ensure interoperability.

11.1.1.  OpenPGP v6 Key Structure

   The format of an OpenPGP v6 key is as follows.  Entries in square
   brackets are optional and ellipses indicate repetition.

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   Primary Key
      [Revocation Signature...]
       Direct-Key Signature...
      [User ID or User Attribute
              [Certification Revocation Signature...]
              [Certification Signature...]]...
      [Subkey [Subkey Revocation Signature...]
              Subkey Binding Signature...]...
      [Padding]

   In addition to these rules, a marker packet (Section 5.8) can appear
   anywhere in the sequence.

   Note, that a v6 key uses a Direct-Key Signature to store algorithm
   preferences.

   Every subkey for a v6 primary key MUST be a v6 subkey.

   When a primary v6 Public Key is revoked, it is sometimes distributed
   with only the revocation signature:

   Primary Key
       Revocation Signature

   In this case, the direct-key signature is no longer necessary, since
   the primary key itself has been marked as unusable.

11.1.2.  OpenPGP v4 Key Structure

   The format of an OpenPGP v4 key is as follows.

   Primary Key
      [Revocation Signature]
      [Direct-Key Signature...]
      [User ID or User Attribute [Signature...]]...
      [Subkey [Subkey Revocation Signature...]
              Subkey Binding Signature...]...

   In addition to these rules, a marker packet (Section 5.8) can appear
   anywhere in the sequence.

   A subkey always has at least one subkey binding signature after it
   that is issued using the primary key to tie the two keys together.
   These binding signatures may be in either v3 or v4 format, but SHOULD
   be in v4 format.  Subkeys that can issue signatures MUST have a v4
   binding signature due to the REQUIRED embedded primary key binding
   signature.

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   Every subkey for a v4 primary key MUST be a v4 subkey.

   When a primary v4 Public Key is revoked, the revocation signature is
   sometimes distributed by itself, without the primary key packet it
   applies to.  This is referred to as a "revocation certificate".
   Instead, a v6 revocation certificate MUST include the primary key
   packet, as described above.

11.1.3.  OpenPGP v3 Key Structure

   The format of an OpenPGP v3 key is as follows.

   RSA Public Key
      [Revocation Signature]
       User ID [Signature...]
      [User ID [Signature...]]...

   In addition to these rules, a marker packet (Section 5.8) can appear
   anywhere in the sequence.

   Each signature certifies the RSA public key and the preceding User
   ID.  The RSA public key can have many User IDs and each User ID can
   have many signatures.  V3 keys are deprecated.  Implementations MUST
   NOT generate new v3 keys, but MAY continue to use existing ones.

   V3 keys MUST NOT have subkeys.

11.1.4.  Common requirements

   The Public-Key packet occurs first.

   In order to create self-signatures (see Section 5.2.3.10), the
   primary key MUST be an algorithm capable of making signatures (that
   is, not an encryption-only algorithm).  The subkeys may be keys of
   any type.  For example, there may be a single-key RSA key, an Ed25519
   primary key with an RSA encryption key, or an Ed25519 primary key
   with an X25519 subkey, etc.

   Each of the following User ID packets provides the identity of the
   owner of this public key.  If there are multiple User ID packets,
   this corresponds to multiple means of identifying the same unique
   individual user; for example, a user may have more than one email
   address, and construct a User ID for each one.  A transferable public
   key SHOULD include at least one User ID packet unless storage
   requirements prohibit this.

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   Immediately following each User ID packet, there are zero or more
   Signature packets.  Each Signature packet is calculated on the
   immediately preceding User ID packet and the initial Public-Key
   packet.  The signature serves to certify the corresponding public key
   and User ID.  In effect, the signer is testifying to his or her
   belief that this public key belongs to the user identified by this
   User ID.

   Within the same section as the User ID packets, there are zero or
   more User Attribute packets.  Like the User ID packets, a User
   Attribute packet is followed by zero or more Signature packets
   calculated on the immediately preceding User Attribute packet and the
   initial Public-Key packet.

   User Attribute packets and User ID packets may be freely intermixed
   in this section, so long as the signatures that follow them are
   maintained on the proper User Attribute or User ID packet.

   After the User ID packet or Attribute packet, there may be zero or
   more Subkey packets.  In general, subkeys are provided in cases where
   the top-level public key is a certification-only key.  However, any
   v4 or v6 key may have subkeys, and the subkeys may be encryption
   keys, signing keys, authentication keys, etc.  It is good practice to
   use separate subkeys for every operation (i.e. signature-only,
   encryption-only, authentication-only keys, etc.).

   Each Subkey packet MUST be followed by one Signature packet, which
   should be a subkey binding signature issued by the top-level key.
   For subkeys that can issue signatures, the subkey binding signature
   MUST contain an Embedded Signature subpacket with a primary key
   binding signature (0x19) issued by the subkey on the top-level key.

   Subkey and Key packets may each be followed by a revocation Signature
   packet to indicate that the key is revoked.  Revocation signatures
   are only accepted if they are issued by the key itself, or by a key
   that is authorized to issue revocations via a Revocation Key
   subpacket in a self-signature by the top-level key.

   The optional trailing Padding packet is a mechanism to defend against
   traffic analysis (see Section 14.10).  For maximum interoperability,
   if the Public-Key packet is a v4 key, the optional Padding packet
   SHOULD NOT be present unless the recipient has indicated that they
   are capable of ignoring it successfully.  An implementation that is
   capable of receiving a transferable public key with a v6 Public-Key
   primary key MUST be able to accept (and ignore) the trailing optional
   Padding packet.

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   Transferable public-key packet sequences may be concatenated to allow
   transferring multiple public keys in one operation (see Section 3.6).

11.2.  Transferable Secret Keys

   OpenPGP users may transfer secret keys.  The format of a transferable
   secret key is the same as a transferable public key except that
   secret-key and secret-subkey packets can be used in addition to the
   public key and public-subkey packets.  If a single secret-key or
   secret-subkey packet is included in a packet sequence, it is a
   transferable secret key and should be handled and marked as such (see
   Section 6.2).  Implementations SHOULD include self-signatures on any
   User IDs and subkeys, as this allows for a complete public key to be
   automatically extracted from the transferable secret key.
   Implementations MAY choose to omit the self-signatures, especially if
   a transferable public key accompanies the transferable secret key.

11.3.  OpenPGP Messages

   An OpenPGP message is a packet or sequence of packets that
   corresponds to the following grammatical rules (comma represents
   sequential composition, and vertical bar separates alternatives):

   OpenPGP Message :-  Encrypted Message | Signed Message | Compressed
      Message | Literal Message.

   Compressed Message :-  Compressed Data Packet.

   Literal Message :-  Literal Data Packet.

   ESK :-  Public-Key Encrypted Session Key Packet | Symmetric-Key
      Encrypted Session Key Packet.

   ESK Sequence :-  ESK | ESK Sequence, ESK.

   Encrypted Data :-  Symmetrically Encrypted Data Packet |
      Symmetrically Encrypted Integrity Protected Data Packet

   Encrypted Message :-  Encrypted Data | ESK Sequence, Encrypted Data.

   One-Pass Signed Message :-  One-Pass Signature Packet, OpenPGP
      Message, Corresponding Signature Packet.

   Signed Message :-  Signature Packet, OpenPGP Message | One-Pass
      Signed Message.

   Optionally Padded Message :-  OpenPGP Message | OpenPGP Message,
      Padding Packet.

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   In addition to these rules, a marker packet (Section 5.8) can appear
   anywhere in the sequence.

11.3.1.  Unwrapping Encrypted and Compressed Messages

   In addition to the above grammar, certain messages can be "unwrapped"
   to yield new messages.  In particular:

   *  Decrypting a version 2 Symmetrically Encrypted and Integrity
      Protected Data packet must yield a valid Optionally Padded
      Message.

   *  Decrypting a version 1 Symmetrically Encrypted and Integrity
      Protected Data packet or --- for historic data --- a Symmetrically
      Encrypted Data packet must yield a valid OpenPGP Message.

   *  Decompressing a Compressed Data packet must also yield a valid
      OpenPGP Message.

   When any unwrapping is performed, the resulting stream of octets is
   parsed into a series OpenPGP packets like any other stream of octets.
   The packet boundaries found in the series of octets are expected to
   align with the length of the unwrapped octet stream.  An
   implementation MUST NOT interpret octets beyond the boundaries of the
   unwrapped octet stream as part of any OpenPGP packet.  If an
   implementation encounters a packet whose header length indicates that
   it would extend beyond the boundaries of the unwrapped octet stream,
   the implementation MUST reject that packet as malformed and unusable.

11.3.2.  Additional Constraints on Packet Sequences

   Note that some subtle combinations that are formally acceptable by
   this grammar are nonetheless unacceptable.

11.3.2.1.  Packet Versions in Encrypted Messages

   As noted above, an Encrypted Message is a sequence of zero or more
   PKESKs (Section 5.1) and SKESKs (Section 5.3), followed by an SEIPD
   (Section 5.13) payload.  In some historic data, the payload may be a
   deprecated SED (Section 5.7) packet instead of SEIPD, though
   implementations MUST NOT generate SED packets (see Section 14.7).
   The versions of the preceding ESK packets within an Encrypted Message
   MUST align with the version of the payload SEIPD packet, as described
   in this section.

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   v3 PKESK and v4 SKESK packets both contain in their cleartext the
   symmetric cipher algorithm identifier in addition to the session key
   for the subsequent SEIPD packet.  Since a v1 SEIPD does not contain a
   symmetric algorithm identifier, all ESK packets preceding a v1 SEIPD
   payload MUST be either v3 PKESK or v4 SKESK.

   On the other hand, the cleartext of the v6 ESK packets (either PKESK
   or SKESK) do not contain a symmetric cipher algorithm identifier, so
   they cannot be used in combination with a v1 SEIPD payload.  The
   payload following any v6 PKESK or v6 SKESK packet MUST be a v2 SEIPD.

   Additionally, to avoid potentially conflicting cipher algorithm
   identifiers, and for simplicity, implementations MUST NOT precede a
   v2 SEIPD payload with either v3 PKESK or v4 SKESK packets.

   The acceptable versions of packets in an Encrypted Message are
   summarized in the following table:

    +======================+======================+===================+
    | Version of Encrypted | Version of preceding | Version of        |
    | Data payload         | Symmetric-Key ESK    | preceding Public- |
    |                      | (if any)             | Key ESK (if any)  |
    +======================+======================+===================+
    | v1 SEIPD             | v4 SKESK             | v3 PKESK          |
    +----------------------+----------------------+-------------------+
    | v2 SEIPD             | v6 SKESK             | v6 PKESK          |
    +----------------------+----------------------+-------------------+

            Table 27: Encrypted Message Packet Version Alignment

   An implementation processing an Encrypted Message MUST discard any
   preceding ESK packet with a version that does not align with the
   version of the payload.

11.4.  Detached Signatures

   Some OpenPGP applications use so-called "detached signatures".  For
   example, a program bundle may contain a file, and with it a second
   file that is a detached signature of the first file.  These detached
   signatures are simply one or more Signature packets stored separately
   from the data for which they are a signature.

   In addition, a marker packet (Section 5.8) and a padding packet
   (Section 5.14) can appear anywhere in the sequence.

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12.  Elliptic Curve Cryptography

   This section describes algorithms and parameters used with Elliptic
   Curve Cryptography (ECC) keys.  A thorough introduction to ECC can be
   found in [KOBLITZ].

   None of the ECC methods described in this document are allowed with
   deprecated v3 keys.  Refer to [FIPS186], B.4.1, for the method to
   generate a uniformly distributed ECC private key.

12.1.  Supported ECC Curves

   This document references three named prime field curves defined in
   [FIPS186] as "Curve P-256", "Curve P-384", and "Curve P-521"; and
   three named prime field curves defined in [RFC5639] as
   "brainpoolP256r1", "brainpoolP384r1", and "brainpoolP512r1".  These
   three [FIPS186] curves and the three [RFC5639] curves can be used
   with ECDSA and ECDH public key algorithms.  They are referenced using
   a sequence of octets, referred to as the curve OID.  Section 9.2
   describes in detail how this sequence of octets is formed.

   Separate algorithms are also defined for the use of X25519 and X448,
   defined in [RFC7748]; and Ed25519 and Ed448, defined in [RFC8032].
   Additionally, legacy OIDs are defined for "Curve25519Legacy" (for
   encryption using the ECDH algorithm) and "Ed25519Legacy" (for signing
   using the EdDSALegacy algorithm).

12.2.  EC Point Wire Formats

   A point on an elliptic curve will always be represented on the wire
   as an MPI.  Each curve uses a specific point format for the data
   within the MPI itself.  Each format uses a designated prefix octet to
   ensure that the high octet has at least one bit set to make the MPI a
   constant size.

           +=================+================+================+
           |            Name | Wire Format    | Reference      |
           +=================+================+================+
           |            SEC1 | 0x04 || x || y | Section 12.2.1 |
           +-----------------+----------------+----------------+
           | Prefixed native | 0x40 || native | Section 12.2.2 |
           +-----------------+----------------+----------------+

                Table 28: Elliptic Curve Point Wire Formats

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12.2.1.  SEC1 EC Point Wire Format

   For a SEC1-encoded (uncompressed) point the content of the MPI is:

   B = 04 || x || y

   where x and y are coordinates of the point P = (x, y), and each is
   encoded in the big-endian format and zero-padded to the adjusted
   underlying field size.  The adjusted underlying field size is the
   underlying field size rounded up to the nearest 8-bit boundary, as
   noted in the "fsize" column in Section 9.2.  This encoding is
   compatible with the definition given in [SEC1].

12.2.2.  Prefixed Native EC Point Wire Format

   For a custom compressed point the content of the MPI is:

   B = 40 || p

   where p is the public key of the point encoded using the rules
   defined for the specified curve.  This format is used for ECDH keys
   based on curves expressed in Montgomery form, and for points when
   using EdDSA.

12.2.3.  Notes on EC Point Wire Formats

   Given the above definitions, the exact size of the MPI payload for an
   encoded point is 515 bits for both NIST P-256 and brainpoolP256r1,
   771 for both NIST P-384 and brainpoolP384r1, 1059 for NIST P-521,
   1027 for brainpoolP512r1, and 263 for both Curve25519Legacy and
   Ed25519Legacy.  For example, the length of a EdDSALegacy public key
   for the curve Ed25519Legacy is 263 bits: 7 bits to represent the 0x40
   prefix octet and 32 octets for the native value of the public key.

   Even though the zero point, also called the point at infinity, may
   occur as a result of arithmetic operations on points of an elliptic
   curve, it SHALL NOT appear in data structures defined in this
   document.

   Each particular curve uses a designated wire format for the point
   found in its public key or ECDH data structure.  An implementation
   MUST NOT use a different wire format for a point than the wire format
   associated with the curve.

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12.3.  EC Scalar Wire Formats

   Some non-curve values in elliptic curve cryptography (for example,
   secret keys and signature components) are not points on a curve, but
   are also encoded on the wire in OpenPGP as an MPI.

   Because of different patterns of deployment, some curves treat these
   values as opaque bit strings with the high bit set, while others are
   treated as actual integers, encoded in the standard OpenPGP big-
   endian form.  The choice of encoding is specific to the public key
   algorithm in use.

   +==========+===========================================+===========+
   | Type     | Description                               | Reference |
   +==========+===========================================+===========+
   | integer  | An integer, big-endian encoded as a       | Section   |
   |          | standard OpenPGP MPI                      | 3.2       |
   +----------+-------------------------------------------+-----------+
   | octet    | An octet string of fixed length, that may | Section   |
   | string   | be shorter on the wire due to leading     | 12.3.1    |
   |          | zeros being stripped by the MPI encoding, |           |
   |          | and may need to be zero-padded before use |           |
   +----------+-------------------------------------------+-----------+
   | prefixed | An octet string of fixed length N,        | Section   |
   | N octets | prefixed with octet 0x40 to ensure no     | 12.3.2    |
   |          | leading zero octet                        |           |
   +----------+-------------------------------------------+-----------+

                Table 29: Elliptic Curve Scalar Encodings

12.3.1.  EC Octet String Wire Format

   Some opaque strings of octets are represented on the wire as an MPI
   by simply stripping the leading zeros and counting the remaining
   bits.  These strings are of known, fixed length.  They are
   represented in this document as MPI(N octets of X) where N is the
   expected length in octets of the octet string.

   For example, a five-octet opaque string (MPI(5 octets of X)) where X
   has the value 00 02 ee 19 00 would be represented on the wire as an
   MPI like so: 00 1a 02 ee 19 00.

   To encode X to the wire format, we set the MPI's two-octet bit
   counter to the value of the highest set bit (bit 26, or 0x001a), and
   do not transfer the leading all-zero octet to the wire.

   To reverse the process, an implementation that knows this value has
   an expected length of 5 octets can take the following steps:

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   *  Ensure that the MPI's two-octet bitcount is less than or equal to
      40 (5 octets of 8 bits)

   *  Allocate 5 octets, setting all to zero initially

   *  Copy the MPI data octets (without the two count octets) into the
      lower octets of the allocated space

12.3.2.  Elliptic Curve Prefixed Octet String Wire Format

   Another way to ensure that a fixed-length bytestring is encoded
   simply to the wire while remaining in MPI format is to prefix the
   bytestring with a dedicated non-zero octet.  This specification uses
   0x40 as the prefix octet.  This is represented in this standard as
   MPI(prefixed N octets of X), where N is the known bytestring length.

   For example, a five-octet opaque string using MPI(prefixed 5 octets
   of X) where X has the value 00 02 ee 19 00 would be written to the
   wire form as: 00 2f 40 00 02 ee 19 00.

   To encode the string, we prefix it with the octet 0x40 (whose 7th bit
   is set), then set the MPI's two-octet bit counter to 47 (0x002f, 7
   bits for the prefix octet and 40 bits for the string).

   To decode the string from the wire, an implementation that knows that
   the variable is formed in this way can:

   *  Ensure that the first three octets of the MPI (the two bit-count
      octets plus the prefix octet) are 00 2f 40, and

   *  Use the remainder of the MPI directly off the wire.

   Note that this is a similar approach to that used in the EC point
   encodings found in Section 12.2.2.

12.4.  Key Derivation Function

   A key derivation function (KDF) is necessary to implement EC
   encryption.  The Concatenation Key Derivation Function (Approved
   Alternative 1) [SP800-56A] with the KDF hash function that is
   SHA2-256 [FIPS180] or stronger is REQUIRED.

   For convenience, the synopsis of the encoding method is given below
   with significant simplifications attributable to the restricted
   choice of hash functions in this document.  However, [SP800-56A] is
   the normative source of the definition.

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   //   Implements KDF( X, oBits, Param );
   //   Input: point X = (x,y)
   //   oBits - the desired size of output
   //   hBits - the size of output of hash function Hash
   //   Param - octets representing the parameters
   //   Assumes that oBits <= hBits
   // Convert the point X to the octet string:
   //   ZB' = 04 || x || y
   // and extract the x portion from ZB'
   ZB = x;
   MB = Hash ( 00 || 00 || 00 || 01 || ZB || Param );
   return oBits leftmost bits of MB.

   Note that ZB in the KDF description above is the compact
   representation of X as defined in Section 4.2 of [RFC6090].

12.5.  EC DH Algorithm (ECDH)

   The method is a combination of an ECC Diffie-Hellman method to
   establish a shared secret, a key derivation method to process the
   shared secret into a derived key, and a key wrapping method that uses
   the derived key to protect a session key used to encrypt a message.

   The One-Pass Diffie-Hellman method C(1, 1, ECC CDH) [SP800-56A] MUST
   be implemented with the following restrictions: the ECC CDH primitive
   employed by this method is modified to always assume the cofactor is
   1, the KDF specified in Section 12.4 is used, and the KDF parameters
   specified below are used.

   The KDF parameters are encoded as a concatenation of the following 5
   variable-length and fixed-length fields, which are compatible with
   the definition of the OtherInfo bitstring [SP800-56A]:

   *  A variable-length field containing a curve OID, which is formatted
      as follows:

      -  A one-octet size of the following field,

      -  The octets representing a curve OID defined in Section 9.2;

   *  A one-octet public key algorithm ID defined in Section 9.1;

   *  A variable-length field containing KDF parameters, which are
      identical to the corresponding field in the ECDH public key, and
      are formatted as follows:

      -  A one-octet size of the following fields; values 0 and 0xFF are
         reserved for future extensions,

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      -  A one-octet value 0x01, reserved for future extensions,

      -  A one-octet hash function ID used with the KDF,

      -  A one-octet algorithm ID for the symmetric algorithm used to
         wrap the symmetric key for message encryption; see Section 12.5
         for details;

   *  20 octets representing the UTF-8 encoding of the string Anonymous
      Sender    , which is the octet sequence 41 6E 6F 6E 79 6D 6F 75 73
      20 53 65 6E 64 65 72 20 20 20 20;

   *  A variable-length field containing the fingerprint of the
      recipient encryption subkey identifying the key material that is
      needed for decryption.  For version 4 keys, this field is 20
      octets.  For version 6 keys, this field is 32 octets.

   The size in octets of the KDF parameters sequence, defined above, for
   encrypting to a v4 key is either 54 for curve NIST P-256, 51 for
   curves NIST P-384 and NIST P-521, 55 for curves brainpoolP256r1,
   brainpoolP384r1 and brainpoolP512r1, or 56 for Curve25519Legacy.  For
   encrypting to a v6 key, the size of the sequence is either 66 for
   curve NIST P-256, 63 for curves NIST P-384 and NIST P-521, or 67 for
   curves brainpoolP256r1, brainpoolP384r1 and brainpoolP512r1.

   The key wrapping method is described in [RFC3394].  The KDF produces
   a symmetric key that is used as a key-encryption key (KEK) as
   specified in [RFC3394].  Refer to Section 12.5.1 for the details
   regarding the choice of the KEK algorithm, which SHOULD be one of the
   three AES algorithms.  Key wrapping and unwrapping is performed with
   the default initial value of [RFC3394].

   The input to the key wrapping method is the plaintext described in
   Section 5.1, "Public-Key Encrypted Session Key Packets (Tag 1)", with
   a two-octet checksum appended (equal to the sum of the preceding
   octets, modulo 65536), and then padded using the method described in
   [PKCS5] to an 8-octet granularity.

   For example, in a v3 Public-Key Encrypted Session Key packet, the
   following AES-256 session key, in which 32 octets are denoted from k0
   to k31, is composed to form the following 40 octet sequence:

   09 k0 k1 ... k31 s0 s1 05 05 05 05 05

   The octets s0 and s1 above denote the checksum of the session key
   octets.  This encoding allows the sender to obfuscate the size of the
   symmetric encryption key used to encrypt the data.  For example,
   assuming that an AES algorithm is used for the session key, the

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   sender MAY use 21, 13, and 5 octets of padding for AES-128, AES-192,
   and AES-256, respectively, to provide the same number of octets, 40
   total, as an input to the key wrapping method.

   In a v6 Public-Key Encrypted Session Key packet, the symmetric
   algorithm is not included, as described in Section 5.1.  For example,
   an AES-256 session key would be composed as follows:

   k0 k1 ... k31 s0 s1 06 06 06 06 06 06

   The octets k0 to k31 above again denote the session key, and the
   octets s0 and s1 denote the checksum.  In this case, assuming that an
   AES algorithm is used for the session key, the sender MAY use 22, 14,
   and 6 octets of padding for AES-128, AES-192, and AES-256,
   respectively, to provide the same number of octets, 40 total, as an
   input to the key wrapping method.

   The output of the method consists of two fields.  The first field is
   the MPI containing the ephemeral key used to establish the shared
   secret.  The second field is composed of the following two subfields:

   *  One octet encoding the size in octets of the result of the key
      wrapping method; the value 255 is reserved for future extensions;

   *  Up to 254 octets representing the result of the key wrapping
      method, applied to the 8-octet padded session key, as described
      above.

   Note that for session key sizes 128, 192, and 256 bits, the size of
   the result of the key wrapping method is, respectively, 32, 40, and
   48 octets, unless size obfuscation is used.

   For convenience, the synopsis of the encoding method is given below;
   however, this section, [SP800-56A], and [RFC3394] are the normative
   sources of the definition.

   *  Obtain the authenticated recipient public key R

   *  Generate an ephemeral key pair {v, V=vG}

   *  Compute the shared point S = vR;

   *  m = symm_alg_ID || session key || checksum || pkcs5_padding;

   *  curve_OID_len = (octet)len(curve_OID);

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   *  Param = curve_OID_len || curve_OID || public_key_alg_ID || 03 ||
      01 || KDF_hash_ID || KEK_alg_ID for AESKeyWrap || Anonymous
      Sender     || recipient_fingerprint;

   *  Z_len = the key size for the KEK_alg_ID used with AESKeyWrap

   *  Compute Z = KDF( S, Z_len, Param );

   *  Compute C = AESKeyWrap( Z, m ) as per [RFC3394]

   *  VB = convert point V to the octet string

   *  Output (MPI(VB) || len(C) || C).

   The decryption is the inverse of the method given.  Note that the
   recipient obtains the shared secret by calculating

   S = rV = rvG, where (r,R) is the recipient's key pair.

12.5.1.  ECDH Parameters

   ECDH keys have a hash algorithm parameter for key derivation and a
   symmetric algorithm for key encapsulation.

   For v6 keys, the following algorithms MUST be used depending on the
   curve.  An implementation MUST NOT generate a v6 ECDH key over any
   listed curve that uses different KDF or KEK parameters.  An
   implementation MUST NOT encrypt any message to a v6 ECDH key over a
   listed curve that announces a different KDF or KEK parameter.

   For v4 keys, the following algorithms SHOULD be used depending on the
   curve.  An implementation SHOULD only use an AES algorithm as a KEK
   algorithm.

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        +=================+================+=====================+
        | Curve           | Hash algorithm | Symmetric algorithm |
        +=================+================+=====================+
        | NIST P-256      | SHA2-256       | AES-128             |
        +-----------------+----------------+---------------------+
        | NIST P-384      | SHA2-384       | AES-192             |
        +-----------------+----------------+---------------------+
        | NIST P-521      | SHA2-512       | AES-256             |
        +-----------------+----------------+---------------------+
        | brainpoolP256r1 | SHA2-256       | AES-128             |
        +-----------------+----------------+---------------------+
        | brainpoolP384r1 | SHA2-384       | AES-192             |
        +-----------------+----------------+---------------------+
        | brainpoolP512r1 | SHA2-512       | AES-256             |
        +-----------------+----------------+---------------------+
        | Curve25519      | SHA2-256       | AES-128             |
        +-----------------+----------------+---------------------+

                  Table 30: ECDH KDF and KEK parameters

13.  Notes on Algorithms

13.1.  PKCS#1 Encoding in OpenPGP

   This standard makes use of the PKCS#1 functions EME-PKCS1-v1_5 and
   EMSA-PKCS1-v1_5.  However, the calling conventions of these functions
   has changed in the past.  To avoid potential confusion and
   interoperability problems, we are including local copies in this
   document, adapted from those in PKCS#1 v2.1 [RFC8017].  [RFC8017]
   should be treated as the ultimate authority on PKCS#1 for OpenPGP.
   Nonetheless, we believe that there is value in having a self-
   contained document that avoids problems in the future with needed
   changes in the conventions.

13.1.1.  EME-PKCS1-v1_5-ENCODE

   Input:

   k =  the length in octets of the key modulus.

   M =  message to be encoded, an octet string of length mLen, where
      mLen <= k - 11.

   Output:

   EM =  encoded message, an octet string of length k.

   Error: "message too long".

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   1.  Length checking: If mLen > k - 11, output "message too long" and
       stop.

   2.  Generate an octet string PS of length k - mLen - 3 consisting of
       pseudo-randomly generated nonzero octets.  The length of PS will
       be at least eight octets.

   3.  Concatenate PS, the message M, and other padding to form an
       encoded message EM of length k octets as

      EM = 0x00 || 0x02 || PS || 0x00 || M.

   4.  Output EM.

13.1.2.  EME-PKCS1-v1_5-DECODE

   Input:

   EM =  encoded message, an octet string

   Output:

   M =  message, an octet string.

   Error: "decryption error".

   To decode an EME-PKCS1_v1_5 message, separate the encoded message EM
   into an octet string PS consisting of nonzero octets and a message M
   as follows

     EM = 0x00 || 0x02 || PS || 0x00 || M.

   If the first octet of EM does not have hexadecimal value 0x00, if the
   second octet of EM does not have hexadecimal value 0x02, if there is
   no octet with hexadecimal value 0x00 to separate PS from M, or if the
   length of PS is less than 8 octets, output "decryption error" and
   stop.  See also Section 14.5 regarding differences in reporting
   between a decryption error and a padding error.

13.1.3.  EMSA-PKCS1-v1_5

   This encoding method is deterministic and only has an encoding
   operation.

   Option:

   Hash -  a hash function in which hLen denotes the length in octets of
      the hash function output.

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   Input:

   M =  message to be encoded.

   emLen =  intended length in octets of the encoded message, at least
      tLen + 11, where tLen is the octet length of the DER encoding T of
      a certain value computed during the encoding operation.

   Output:

   EM =  encoded message, an octet string of length emLen.

   Errors: "message too long"; "intended encoded message length too
   short".

   Steps:

   1.  Apply the hash function to the message M to produce a hash value
       H:

       H = Hash(M).

       If the hash function outputs "message too long," output "message
       too long" and stop.

   2.  Using the list in Section 5.2.2, produce an ASN.1 DER value for
       the hash function used.  Let T be the full hash prefix from the
       list, and let tLen be the length in octets of T.

   3.  If emLen < tLen + 11, output "intended encoded message length too
       short" and stop.

   4.  Generate an octet string PS consisting of emLen - tLen - 3 octets
       with hexadecimal value 0xFF.  The length of PS will be at least 8
       octets.

   5.  Concatenate PS, the hash prefix T, and other padding to form the
       encoded message EM as

      EM = 0x00 || 0x01 || PS || 0x00 || T.

   6.  Output EM.

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13.2.  Symmetric Algorithm Preferences

   The symmetric algorithm preference is an ordered list of algorithms
   that the keyholder accepts.  Since it is found on a self-signature,
   it is possible that a keyholder may have multiple, different
   preferences.  For example, Alice may have AES-128 only specified for
   "alice@work.com" but Camellia-256, Twofish, and AES-128 specified for
   "alice@home.org".  Note that it is also possible for preferences to
   be in a subkey's binding signature.

   Since AES-128 is the MUST-implement algorithm, if it is not
   explicitly in the list, it is tacitly at the end.  However, it is
   good form to place it there explicitly.  Note also that if an
   implementation does not implement the preference, then it is
   implicitly an AES-128-only implementation.  Note further that
   implementations conforming to previous versions of this standard
   [RFC4880] have TripleDES as its only MUST-implement algorithm.

   An implementation MUST NOT use a symmetric algorithm that is not in
   the recipient's preference list.  When encrypting to more than one
   recipient, the implementation finds a suitable algorithm by taking
   the intersection of the preferences of the recipients.  Note that the
   MUST-implement algorithm, AES-128, ensures that the intersection is
   not null.  The implementation may use any mechanism to pick an
   algorithm in the intersection.

   If an implementation can decrypt a message that a keyholder doesn't
   have in their preferences, the implementation SHOULD decrypt the
   message anyway, but MUST warn the keyholder that the protocol has
   been violated.  For example, suppose that Alice, above, has software
   that implements all algorithms in this specification.  Nonetheless,
   she prefers subsets for work or home.  If she is sent a message
   encrypted with IDEA, which is not in her preferences, the software
   warns her that someone sent her an IDEA-encrypted message, but it
   would ideally decrypt it anyway.

13.2.1.  Plaintext

   Algorithm 0, "plaintext", may only be used to denote secret keys that
   are stored in the clear.  Implementations MUST NOT use plaintext in
   encrypted data packets; they must use Literal Data packets to encode
   unencrypted literal data.

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13.3.  Other Algorithm Preferences

   Other algorithm preferences work similarly to the symmetric algorithm
   preference, in that they specify which algorithms the keyholder
   accepts.  There are two interesting cases that other comments need to
   be made about, though, the compression preferences and the hash
   preferences.

13.3.1.  Compression Preferences

   Like the algorithm preferences, an implementation MUST NOT use an
   algorithm that is not in the preference vector.  If Uncompressed (0)
   is not explicitly in the list, it is tacitly at the end.  That is,
   uncompressed messages may always be sent.

   Note that earlier implementations may assume that the absence of
   compression preferences means that [ZIP(1), Uncompressed(0)] are
   preferred, and default to ZIP compression.  Therefore, an
   implementation that prefers uncompressed data SHOULD explicitly state
   this in the preferred compression algorithms.

13.3.1.1.  Uncompressed

   Algorithm 0, "uncompressed", may only be used to denote a preference
   for uncompressed data.  Implementations MUST NOT use uncompressed in
   Compressed Data packets; they must use Literal Data packets to encode
   uncompressed literal data.

13.3.2.  Hash Algorithm Preferences

   Typically, the choice of a hash algorithm is something the signer
   does, rather than the verifier, because a signer rarely knows who is
   going to be verifying the signature.  This preference, though, allows
   a protocol based upon digital signatures ease in negotiation.

   Thus, if Alice is authenticating herself to Bob with a signature, it
   makes sense for her to use a hash algorithm that Bob's software uses.
   This preference allows Bob to state in his key which algorithms Alice
   may use.

   Since SHA2-256 is the MUST-implement hash algorithm, if it is not
   explicitly in the list, it is tacitly at the end.  However, it is
   good form to place it there explicitly.

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13.4.  RSA

   The PKCS1-v1_5 padding scheme, used by the RSA algorithms defined in
   this document, is no longer recommended, and its use is deprecated by
   [SP800-131A].  Therefore, an implementation SHOULD NOT generate RSA
   keys.

   There are algorithm types for RSA Sign-Only, and RSA Encrypt-Only
   keys.  These types are deprecated.  The "key flags" subpacket in a
   signature is a much better way to express the same idea, and
   generalizes it to all algorithms.  An implementation MUST NOT create
   such a key, but MAY interpret it.

   An implementation MUST NOT generate RSA keys of size less than 3072
   bits.  An implementation SHOULD NOT encrypt, sign or verify using RSA
   keys of size less than 3072 bits.  An implementation MUST NOT
   encrypt, sign or verify using RSA keys of size less than 2048 bits.
   An implementation that decrypts a message using an RSA secret key of
   size less than 3072 bits SHOULD generate a deprecation warning that
   the key is too weak for modern use.

13.5.  DSA

   DSA is expected to be deprecated in [FIPS186-5].  Therefore, an
   implementation MUST NOT generate DSA keys.

   An implementation MUST NOT sign or verify using DSA keys.

13.6.  Elgamal

   The PKCS1-v1_5 padding scheme, used by the Elgamal algorithm defined
   in this document, is no longer recommended, and its use is deprecated
   by [SP800-131A].  Therefore, an implementation MUST NOT generate
   Elgamal keys.

   An implementation MUST NOT encrypt using Elgamal keys.  An
   implementation that decrypts a message using an Elgamal secret key
   SHOULD generate a deprecation warning that the key is too weak for
   modern use.

13.7.  EdDSA

   Although the EdDSA algorithm allows arbitrary data as input, its use
   with OpenPGP requires that a digest of the message is used as input
   (pre-hashed).  See Section 5.2.4 for details.  Truncation of the
   resulting digest is never applied; the resulting digest value is used
   verbatim as input to the EdDSA algorithm.

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   For clarity: while [RFC8032] describes different variants of EdDSA,
   OpenPGP uses the "pure" variant (PureEdDSA).  The hashing that
   happens with OpenPGP is done as part of the standard OpenPGP
   signature process, and that hash itself is fed as the input message
   to the PureEdDSA algorithm.

   As specified in [RFC8032], Ed448 also expects a "context string".  In
   OpenPGP, Ed448 is used with the empty string as a context string.

13.8.  Reserved Algorithm Numbers

   A number of algorithm IDs have been reserved for algorithms that
   would be useful to use in an OpenPGP implementation, yet there are
   issues that prevent an implementer from actually implementing the
   algorithm.  These are marked in Section 9.1 as "reserved for".

   The reserved public-key algorithm X9.42 (21) does not have the
   necessary parameters, parameter order, or semantics defined.  The
   same is currently true for reserved public-key algorithms AEDH (23)
   and AEDSA (24).

   Previous versions of OpenPGP permitted Elgamal [ELGAMAL] signatures
   with a public-key identifier of 20.  These are no longer permitted.
   An implementation MUST NOT generate such keys.  An implementation
   MUST NOT generate Elgamal signatures.  See [BLEICHENBACHER].

13.9.  CFB Mode

   The Cipher Feedback (CFB) mode used in this document is defined in
   Section 6.3 of [SP800-38A].

   The CFB segment size s is equal to the block size of the cipher
   (i.e., n-bit CFB mode where n is the block size is used).

13.10.  Private or Experimental Parameters

   S2K specifiers, Signature subpacket types, User Attribute types,
   image format types, and algorithms described in Section 9 all reserve
   the range 100 to 110 for private and experimental use.  Packet types
   reserve the range 60 to 63 for private and experimental use.  These
   are intentionally managed with the PRIVATE USE method, as described
   in [RFC8126].

   However, implementations need to be careful with these and promote
   them to full IANA-managed parameters when they grow beyond the
   original, limited system.

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13.11.  Meta-Considerations for Expansion

   If OpenPGP is extended in a way that is not backwards-compatible,
   meaning that old implementations will not gracefully handle their
   absence of a new feature, the extension proposal can be declared in
   the key holder's self-signature as part of the Features signature
   subpacket.

   We cannot state definitively what extensions will not be upwards-
   compatible, but typically new algorithms are upwards-compatible,
   whereas new packets are not.

   If an extension proposal does not update the Features system, it
   SHOULD include an explanation of why this is unnecessary.  If the
   proposal contains neither an extension to the Features system nor an
   explanation of why such an extension is unnecessary, the proposal
   SHOULD be rejected.

14.  Security Considerations

   *  As with any technology involving cryptography, you should check
      the current literature to determine if any algorithms used here
      have been found to be vulnerable to attack.

   *  This specification uses Public-Key Cryptography technologies.  It
      is assumed that the private key portion of a public-private key
      pair is controlled and secured by the proper party or parties.

   *  The MD5 hash algorithm has been found to have weaknesses, with
      collisions found in a number of cases.  MD5 is deprecated for use
      in OpenPGP.  Implementations MUST NOT generate new signatures
      using MD5 as a hash function.  They MAY continue to consider old
      signatures that used MD5 as valid.

   *  SHA2-224 and SHA2-384 require the same work as SHA2-256 and
      SHA2-512, respectively.  In general, there are few reasons to use
      them outside of DSS compatibility.  You need a situation where one
      needs more security than smaller hashes, but does not want to have
      the full 256-bit or 512-bit data length.

   *  Many security protocol designers think that it is a bad idea to
      use a single key for both privacy (encryption) and integrity
      (signatures).  In fact, this was one of the motivating forces
      behind the v4 key format with separate signature and encryption
      keys.  If you as an implementer promote dual-use keys, you should
      at least be aware of this controversy.

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   *  The DSA algorithm will work with any hash, but is sensitive to the
      quality of the hash algorithm.  Verifiers should be aware that
      even if the signer used a strong hash, an attacker could have
      modified the signature to use a weak one.  Only signatures using
      acceptably strong hash algorithms should be accepted as valid.

   *  As OpenPGP combines many different asymmetric, symmetric, and hash
      algorithms, each with different measures of strength, care should
      be taken that the weakest element of an OpenPGP message is still
      sufficiently strong for the purpose at hand.  While consensus
      about the strength of a given algorithm may evolve, NIST Special
      Publication 800-57 [SP800-57] recommends the following list of
      equivalent strengths:

         +=====================+===========+====================+
         | Asymmetric key size | Hash size | Symmetric key size |
         +=====================+===========+====================+
         |                1024 | 160       | 80                 |
         +---------------------+-----------+--------------------+
         |                2048 | 224       | 112                |
         +---------------------+-----------+--------------------+
         |                3072 | 256       | 128                |
         +---------------------+-----------+--------------------+
         |                7680 | 384       | 192                |
         +---------------------+-----------+--------------------+
         |               15360 | 512       | 256                |
         +---------------------+-----------+--------------------+

                    Table 31: Key length equivalences

   *  There is a somewhat-related potential security problem in
      signatures.  If an attacker can find a message that hashes to the
      same hash with a different algorithm, a bogus signature structure
      can be constructed that evaluates correctly.

      For example, suppose Alice DSA signs message M using hash
      algorithm H.  Suppose that Mallet finds a message M' that has the
      same hash value as M with H'.  Mallet can then construct a
      signature block that verifies as Alice's signature of M' with H'.
      However, this would also constitute a weakness in either H or H'
      or both.  Should this ever occur, a revision will have to be made
      to this document to revise the allowed hash algorithms.

   *  If you are building an authentication system, the recipient may
      specify a preferred signing algorithm.  However, the signer would
      be foolish to use a weak algorithm simply because the recipient
      requests it.

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   *  Some of the encryption algorithms mentioned in this document have
      been analyzed less than others.  For example, although CAST5 is
      presently considered strong, it has been analyzed less than
      TripleDES.  Other algorithms may have other controversies
      surrounding them.

   *  In late summer 2002, Jallad, Katz, and Schneier published an
      interesting attack on older versions of the OpenPGP protocol and
      some of its implementations [JKS02].  In this attack, the attacker
      modifies a message and sends it to a user who then returns the
      erroneously decrypted message to the attacker.  The attacker is
      thus using the user as a decryption oracle, and can often decrypt
      the message.  This attack is a particular form of ciphertext
      malleability.  See Section 14.7 for information on how to defend
      against such an attack using more recent versions of OpenPGP.

   *  Some technologies mentioned here may be subject to government
      control in some countries.

14.1.  SHA-1 Collision Detection

   As described in [SHAMBLES], the SHA-1 digest algorithm is not
   collision-resistant.  However, an OpenPGP implementation cannot
   completely discard the SHA-1 algorithm, because it is required for
   implementing and reasoning about v4 public keys.  In particular, the
   v4 fingerprint derivation uses SHA-1.  So as long as an OpenPGP
   implementation supports v4 public keys, it will need to implement
   SHA-1 in at least some scenarios.

   To avoid the risk of uncertain breakage from a maliciously introduced
   SHA-1 collision, an OpenPGP implementation MAY attempt to detect when
   a hash input is likely from a known collision attack, and then either
   deliberately reject the hash input or modify the hash output.  This
   should convert an uncertain breakage (where it is unclear what the
   effect of a collision will be) to an explicit breakage, which is more
   desirable for a robust implementation.

   [STEVENS2013] describes a method for detecting indicators of well-
   known SHA-1 collision attacks.  Some example C code implementing this
   technique can be found at [SHA1CD].

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14.2.  Advantages of Salted Signatures

   V6 signatures include a salt that is hashed first, which size depends
   on the hashing algorithm.  This makes v6 OpenPGP signatures non-
   deterministic and protects against a broad class of attacks that
   depend on creating a signature over a predictable message.  By
   selecting a new random salt for each signature made, the signed
   hashes and the signatures are not predictable.

   When the material to be signed may be attacker-controlled, hashing
   the salt first means that there is no attacker controlled hashed
   prefix.  An example of this kind of attack is described in the paper
   SHA-1 Is A Shambles (see [SHAMBLES]), which leverages a chosen prefix
   collision attack against SHA-1.  This means that an adversary
   carrying out a chosen-message attack will not be able to control the
   hash that is being signed, and will need to break second-preimage
   resistance instead of the simpler collision resistance to create two
   messages having the same signature.  The size of the salt is bound to
   the hash function to match the expected collision resistance level,
   and at least 16 octets.

   In some cases, an attacker may be able to induce a signature to be
   made, even if they do not control the content of the message.  In
   some scenarios, a repeated signature over the exact same message may
   risk leakage of part or all of the signing key, for example see
   discussion of hardware faults over EdDSA and deterministic ECDSA in
   [PSSLR17].  Choosing a new random salt for each signature ensures
   that no repeated signatures are produced, and mitigates this risk.

14.3.  Elliptic Curve Side Channels

   Side channel attacks are a concern when a compliant application's use
   of the OpenPGP format can be modeled by a decryption or signing
   oracle, for example, when an application is a network service
   performing decryption to unauthenticated remote users.  ECC scalar
   multiplication operations used in ECDSA and ECDH are vulnerable to
   side channel attacks.  Countermeasures can often be taken at the
   higher protocol level, such as limiting the number of allowed
   failures or time-blinding of the operations associated with each
   network interface.  Mitigations at the scalar multiplication level
   seek to eliminate any measurable distinction between the ECC point
   addition and doubling operations.

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14.4.  Risks of a Quick Check Oracle

   In winter 2005, Serge Mister and Robert Zuccherato from Entrust
   released a paper describing a way that the "quick check" in v1 SEIPD
   and SED packets can be used as an oracle to decrypt two octets of
   every cipher block [MZ05].  This check was intended for early
   detection of session key decryption errors, particularly to detect a
   wrong passphrase, since v4 SKESK packets do not include an integrity
   check.

   There is a danger to using the quick check if timing or error
   information about the check can be exposed to an attacker,
   particularly via an automated service that allows rapidly repeated
   queries.

   Disabling the quick check prevents the attack.

   For very large legacy encrypted data whose session key is protected
   by a passphrase (v4 SKESK), while the quick check may be convenient
   to the user to be informed early on that they typed the wrong
   passphrase, the implementation should use the quick check with care.
   The recommended approach for secure and early detection of decryption
   failure is to encrypt data using v2 SEIPD.  If the session key is
   public-key encrypted, the quick check is not useful as the public-key
   encryption of the session key should guarantee that it is the right
   session key.

   The quick check oracle attack is a particular type of attack that
   exploits ciphertext malleability.  For information about other
   similar attacks, see Section 14.7.

14.5.  Avoiding Leaks From PKCS#1 Errors

   The PKCS#1 padding (used in RSA-encrypted and ElGamal-encrypted
   PKESK) has been found to be vulnerable to attacks in which a system
   that allows distinguishing padding errors from other decryption
   errors can act as a decryption and/or signing oracle that can leak
   the session key or allow signing arbitrary data, respectively
   [BLEICHENBACHER-PKCS1].  The number of queries required to carry out
   an attack can range from thousands to millions, depending on how
   strict and careful an implementation is in processing the padding.

   To make the attack more difficult, an implementation SHOULD implement
   strict, robust, constant time padding checks.

   To prevent the attack, in settings where the attacker does not have
   access to timing information concerning message decryption, the
   simplest solution is to report a single error code for all variants

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   of PKESK processing errors as well as SEIPD integrity errors (this
   includes also session key parsing errors, such as on invalid cipher
   algorithm for v3 PKESK, or session key size mismatch for v6 PKESK).
   If the attacker may have access to timing information, then a
   constant time solution is also needed.  This requires careful design,
   especially for v3 PKESK, where session key size and cipher
   information is typically not known in advance, as it is part of the
   PKESK encrypted payload.

14.6.  Fingerprint Usability

   This specification uses fingerprints in several places on the wire
   (e.g., Section 5.2.3.23, Section 5.2.3.35, and Section 5.2.3.36), and
   in processing (e.g., in ECDH KDF Section 12.5).  An implementation
   may also use the fingerprint internally, for example as an index to a
   keystore.

   Additionally, some OpenPGP users have historically used manual
   fingerprint comparison to verify the public key of a peer.  For a
   version 4 fingerprint, this has typically been done with the
   fingerprint represented as 40 hexadecimal digits, often broken into
   groups of four digits with whitespace between each group.

   When a human is actively involved, the result of such a verification
   is dubious.  We have little evidence that most humans are good at
   precise comparison of high-entropy data, particularly when that data
   is represented in compact textual form like a hexadecimal
   fingerprint.

   The version 6 Fingerprint makes the challenge for a human verifier
   even worse.  At 256 bits (compared to v4's 160 bit fingerprint), a v6
   fingerprint is even harder for a human to successfully compare.

   An OpenPGP implementation should prioritize mechanical fingerprint
   transfer and comparison where possible, and SHOULD NOT promote manual
   transfer or comparison of full fingerprints by a human unless there
   is no other way to achieve the desired result.

   While this subsection acknowledges existing practice for human-
   representable v4 fingerprints, this document does not attempt to
   standardize any specific human-readable form of v6 fingerprint for
   this discouraged use case.

   NOTE: the topic of interoperable human-in-the-loop key verification
   needs more work, probably in a separate document.

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14.7.  Avoiding Ciphertext Malleability

   If ciphertext can be modified by an attacker but still subsequently
   decrypted to some new plaintext, it is considered "malleable".  A
   number of attacks can arise in any cryptosystem that uses malleable
   encryption, so modern OpenPGP offers mechanisms to defend against it.
   However, legacy OpenPGP data may have been created before these
   mechanisms were available.  Because OpenPGP implementations deal with
   historic stored data, they may encounter malleable ciphertexts.

   When an OpenPGP implementation discovers that it is decrypting data
   that appears to be malleable, it MUST indicate a clear error message
   that the integrity of the message is suspect, SHOULD NOT attempt to
   parse nor release decrypted data to the user, and SHOULD halt with an
   error.  Parsing or releasing decrypted data before having confirmed
   its integrity can leak the decrypted data [EFAIL], [MRLG15].

   In the case of AEAD encrypted data, if the authentication tag fails
   to verify, the implementation MUST NOT attempt to parse nor release
   decrypted data to the user, and MUST halt with an error.

   An implementation that encounters malleable ciphertext MAY choose to
   release cleartext to the user if it is not encrypted using AEAD, and
   it is known to be dealing with historic archived legacy data, and the
   user is aware of the risks.

   In the case of AEAD encrypted messages, if the message is truncated,
   i.e. the final zero-octet chunk and possibly (part of) some chunks
   before it are missing, the implementation MAY choose to release
   cleartext from fully authenticated chunks before it to the user if it
   is operating in a streaming fashion, but it MUST indicate a clear
   error message as soon as the truncation is detected.

   Any of the following OpenPGP data elements indicate that malleable
   ciphertext is present:

   *  All Symmetrically Encrypted Data packets (Section 5.7).

   *  Within any encrypted container, any Compressed Data packet
      (Section 5.6) where there is a decompression failure.

   *  Any version 1 Symmetrically Encrypted Integrity Protected Data
      packet (Section 5.13.1) where the internal Modification Detection
      Code does not validate.

   *  Any version 2 Symmetrically Encrypted Integrity Protected Data
      packet (Section 5.13.2) where the authentication tag of any chunk
      fails, or where there is no final zero-octet chunk.

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   *  Any Secret Key packet with encrypted secret key material
      (Section 3.7.2.1) where there is an integrity failure, based on
      the value of the secret key protection octet:

      -  Value 255 or raw cipher algorithm: where the trailing 2-octet
         checksum does not match.

      -  Value 254: where the SHA1 checksum is mismatched.

      -  Value 253: where the AEAD authentication tag is invalid.

   To avoid these circumstances, an implementation that generates
   OpenPGP encrypted data SHOULD select the encrypted container format
   with the most robust protections that can be handled by the intended
   recipients.  In particular:

   *  The SED packet is deprecated, and MUST NOT be generated.

   *  When encrypting to one or more public keys:

      -  All recipient keys indicate support for version 2 of the
         Symmetrically Encrypted Integrity Protected Data packet in
         their Features subpacket (Section 5.2.3.32), or are v6 keys
         without a Features subpacket, or the implementation can
         otherwise infer that all recipients support v2 SEIPD packets,
         the implementation MUST encrypt using a v2 SEIPD packet.

      -  If one of the recipients does not support v2 SEIPD packets,
         then the message generator MAY use a v1 SEIPD packet instead.

   *  Password-protected secret key material in a v6 Secret Key or v6
      Secret Subkey packet SHOULD be protected with AEAD encryption (S2K
      usage octet 253) unless it will be transferred to an
      implementation that is known to not support AEAD.  Implementations
      should be aware that, in scenarios where an attacker has access to
      encrypted private keys, CFB-encrypted keys (S2K usage octet 254 or
      255) are vulnerable to corruption attacks that can cause leakage
      of secret data when the secret key is used [KOPENPGP], [KR02].

   Implementers should implement AEAD (v2 SEIPD and S2K usage octet 253)
   promptly and encourage its spread.

   Users should migrate to AEAD with all due speed.

14.8.  Escrowed Revocation Signatures

   A keyholder, Alice, may wish to designate a third party to be able to
   revoke Alice's own key.

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   The preferred way for her to do this is to produce a specific
   Revocation Signature (signature types 0x20, 0x28, or 0x30) and
   distribute it securely to her preferred revoker who can hold it in
   escrow.  The preferred revoker can then publish the escrowed
   Revocation Signature at whatever time is deemed appropriate, rather
   than generating a revocation signature themselves.

   There are multiple advantages of using an escrowed Revocation
   Signature over the deprecated Revocation Key subpacket
   (Section 5.2.3.23):

   *  The keyholder can constrain what types of revocation the preferred
      revoker can issue, by only escrowing those specific signatures.

   *  There is no public/visible linkage between the keyholder and the
      preferred revoker.

   *  Third parties can verify the revocation without needing to find
      the key of the preferred revoker.

   *  The preferred revoker doesn't even need to have a public OpenPGP
      key if some other secure transport is possible between them and
      the keyholder.

   *  Implementation support for enforcing a revocation from an
      authorized Revocation Key subpacket is uneven and unreliable.

   *  If the fingerprint mechanism suffers a cryptanalytic flaw, the
      escrowed Revocation Signature is not affected.

   A Revocation Signature may also be split up into shares and
   distributed among multiple parties, requiring some subset of those
   parties to collaborate before the escrowed Revocation Signature is
   recreated.

14.9.  Random Number Generation and Seeding

   OpenPGP requires a cryptographically secure pseudorandom number
   generator (CSPRNG).  In most cases, the operating system provides an
   appropriate facility such as a getrandom() syscall, which should be
   used absent other (for example, performance) concerns.  It is
   RECOMMENDED to use an existing CSPRNG implementation in preference to
   crafting a new one.  Many adequate cryptographic libraries are
   already available under favorable license terms.  Should those prove
   unsatisfactory, [RFC4086] provides guidance on the generation of
   random values.

   OpenPGP uses random data with three different levels of visibility:

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   *  In publicly-visible fields such as nonces, IVs, public padding
      material, or salts,

   *  In shared-secret values, such as session keys for encrypted data
      or padding material within an encrypted packet, and

   *  In entirely private data, such as asymmetric key generation.

   With a properly functioning CSPRNG, this does not present a security
   problem, as it is not feasible to determine the CSPRNG state from its
   output.  However, with a broken CSPRNG, it may be possible for an
   attacker to use visible output to determine the CSPRNG internal state
   and thereby predict less-visible data like keying material, as
   documented in [CHECKOWAY].

   An implementation can provide extra security against this form of
   attack by using separate CSPRNGs to generate random data with
   different levels of visibility.

14.10.  Traffic Analysis

   When sending OpenPGP data through the network, the size of the data
   may leak information to an attacker.  There are circumstances where
   such a leak could be unacceptable from a security perspective.

   For example, if possible cleartext messages for a given protocol are
   known to be either yes (three octets) and no (two octets) and the
   messages are sent within a Symmetrically-Encrypted Integrity
   Protected Data packet, the length of the encrypted message will
   reveal the contents of the cleartext.

   In another example, sending an OpenPGP Transferable Public Key over
   an encrypted network connection might reveal the length of the
   certificate.  Since the length of an OpenPGP certificate varies based
   on the content, an external observer interested in metadata (who is
   trying to contact whom) may be able to guess the identity of the
   certificate sent, if its length is unique.

   In both cases, an implementation can adjust the size of the compound
   structure by including a Padding packet (see Section 5.14).

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14.11.  Surreptitious Forwarding

   When an attacker obtains a signature for some text, e.g. by receiving
   a signed message, they may be able to use that signature maliciously
   by sending a message purporting to come from the original sender,
   with the same body and signature, to a different recipient.  To
   prevent this, implementations SHOULD implement the Intended Recipient
   Fingerprint signature subpacket (Section 5.2.3.36).

15.  Implementation Nits

   This section is a collection of comments to help an implementer,
   particularly with an eye to backward compatibility.  Often the
   differences are small, but small differences are frequently more
   vexing than large differences.  Thus, this is a non-comprehensive
   list of potential problems and gotchas for a developer who is trying
   to be backward-compatible.

   *  There are many ways possible for two keys to have the same key
      material, but different fingerprints (and thus Key IDs).  For
      example, since a v4 fingerprint is constructed by hashing the key
      creation time along with other things, two v4 keys created at
      different times, yet with the same key material will have
      different fingerprints.

   *  OpenPGP does not put limits on the size of public keys.  However,
      larger keys are not necessarily better keys.  Larger keys take
      more computation time to use, and this can quickly become
      impractical.  Different OpenPGP implementations may also use
      different upper bounds for public key sizes, and so care should be
      taken when choosing sizes to maintain interoperability.

   *  ASCII armor is an optional feature of OpenPGP.  The OpenPGP
      working group strives for a minimal set of mandatory-to-implement
      features, and since there could be useful implementations that
      only use binary object formats, this is not a "MUST" feature for
      an implementation.  For example, an implementation that is using
      OpenPGP as a mechanism for file signatures may find ASCII armor
      unnecessary.  OpenPGP permits an implementation to declare what
      features it does and does not support, but ASCII armor is not one
      of these.  Since most implementations allow binary and armored
      objects to be used indiscriminately, an implementation that does
      not implement ASCII armor may find itself with compatibility
      issues with general-purpose implementations.  Moreover,
      implementations of OpenPGP-MIME [RFC3156] already have a
      requirement for ASCII armor so those implementations will
      necessarily have support.

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   *  What this document calls Legacy packet format Section 4.2.2 is
      what older documents called the "old packet format".  It is the
      packet format of the legacy PGP 2 implementation.  Older RFCs
      called the current OpenPGP packet format Section 4.2.1 the "new
      packet format".

15.1.  Constrained Legacy Fingerprint Storage for v6 Keys

   Some OpenPGP implementations have fixed length constraints for key
   fingerprint storage that will not fit all 32 octets of a v6
   fingerprint.  For example, [OPENPGPCARD] reserves 20 octets for each
   stored fingerprint.

   An OpenPGP implementation MUST NOT attempt to map any part of a v6
   fingerprint to such a constrained field unless the relevant spec for
   the constrained environment has explicit guidance for storing a v6
   fingerprint that distinguishes it from a v4 fingerprint.  An
   implementation interacting with such a constrained field SHOULD
   directly calculate the v6 fingerprint from public key material and
   associated metadata instead of relying on the constrained field.

16.  References

16.1.  Normative References

   [AES]      "Advanced encryption standard (AES)", National Institute
              of Standards and Technology report,
              DOI 10.6028/nist.fips.197, November 2001,
              <https://doi.org/10.6028/nist.fips.197>.

   [BLOWFISH] Schneier, B., "Description of a New Variable-Length Key,
              64-Bit Block Cipher (Blowfish)", Fast Software Encryption,
              Cambridge Security Workshop Proceedings Springer-Verlag,
              1994, pp191-204, December 1993,
              <http://www.counterpane.com/bfsverlag.html>.

   [BZ2]      Seward, J., "The Bzip2 and libbzip2 home page", 2010,
              <http://www.bzip.org/>.

   [EAX]      Bellare, M., Rogaway, P., and D. Wagner, "A Conventional
              Authenticated-Encryption Mode", April 2003.

   [ELGAMAL]  Elgamal, T., "A Public-Key Cryptosystem and a Signature
              Scheme Based on Discrete Logarithms", IEEE Transactions on
              Information Theory v. IT-31, n. 4, 1985, pp. 469-472,
              1985.

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   [FIPS180]  Dang, Q., "Secure Hash Standard", National Institute of
              Standards and Technology report,
              DOI 10.6028/nist.fips.180-4, July 2015,
              <https://doi.org/10.6028/nist.fips.180-4>.

   [FIPS186]  "Digital Signature Standard (DSS)", National Institute of
              Standards and Technology report,
              DOI 10.6028/nist.fips.186-4, July 2013,
              <https://doi.org/10.6028/nist.fips.186-4>.

   [FIPS202]  Dworkin, M., "SHA-3 Standard: Permutation-Based Hash and
              Extendable-Output Functions", National Institute of
              Standards and Technology report,
              DOI 10.6028/nist.fips.202, July 2015,
              <https://doi.org/10.6028/nist.fips.202>.

   [HAC]      Menezes, A. J., v Oorschot, P., and S. Vanstone, "Handbook
              of Applied Cryptography", 1996.

   [IDEA]     Lai, X., "On the design and security of block ciphers",
              ETH Series in Information Processing, J.L. Massey
              (editor) Vol. 1, Hartung-Gorre Verlag Konstanz, Technische
              Hochschule (Zurich), 1992.

   [ISO10646] International Organization for Standardization,
              "Information Technology - Universal Multiple-octet coded
              Character Set (UCS) - Part 1: Architecture and Basic
              Multilingual Plane", ISO Standard 10646-1, May 1993.

   [JFIF]     CA, E. H. M., "JPEG File Interchange Format (Version
              1.02).", September 1996.

   [PKCS5]    RSA Laboratories, "PKCS #5 v2.0: Password-Based
              Cryptography Standard", 25 March 1999.

   [RFC1950]  Deutsch, P. and J-L. Gailly, "ZLIB Compressed Data Format
              Specification version 3.3", RFC 1950,
              DOI 10.17487/RFC1950, May 1996,
              <https://www.rfc-editor.org/rfc/rfc1950>.

   [RFC1951]  Deutsch, P., "DEFLATE Compressed Data Format Specification
              version 1.3", RFC 1951, DOI 10.17487/RFC1951, May 1996,
              <https://www.rfc-editor.org/rfc/rfc1951>.

   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
              Requirement Levels", BCP 14, RFC 2119,
              DOI 10.17487/RFC2119, March 1997,
              <https://www.rfc-editor.org/rfc/rfc2119>.

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   [RFC2144]  Adams, C., "The CAST-128 Encryption Algorithm", RFC 2144,
              DOI 10.17487/RFC2144, May 1997,
              <https://www.rfc-editor.org/rfc/rfc2144>.

   [RFC2822]  Resnick, P., Ed., "Internet Message Format", RFC 2822,
              DOI 10.17487/RFC2822, April 2001,
              <https://www.rfc-editor.org/rfc/rfc2822>.

   [RFC3156]  Elkins, M., Del Torto, D., Levien, R., and T. Roessler,
              "MIME Security with OpenPGP", RFC 3156,
              DOI 10.17487/RFC3156, August 2001,
              <https://www.rfc-editor.org/rfc/rfc3156>.

   [RFC3394]  Schaad, J. and R. Housley, "Advanced Encryption Standard
              (AES) Key Wrap Algorithm", RFC 3394, DOI 10.17487/RFC3394,
              September 2002, <https://www.rfc-editor.org/rfc/rfc3394>.

   [RFC3629]  Yergeau, F., "UTF-8, a transformation format of ISO
              10646", STD 63, RFC 3629, DOI 10.17487/RFC3629, November
              2003, <https://www.rfc-editor.org/rfc/rfc3629>.

   [RFC3713]  Matsui, M., Nakajima, J., and S. Moriai, "A Description of
              the Camellia Encryption Algorithm", RFC 3713,
              DOI 10.17487/RFC3713, April 2004,
              <https://www.rfc-editor.org/rfc/rfc3713>.

   [RFC4086]  Eastlake 3rd, D., Schiller, J., and S. Crocker,
              "Randomness Requirements for Security", BCP 106, RFC 4086,
              DOI 10.17487/RFC4086, June 2005,
              <https://www.rfc-editor.org/rfc/rfc4086>.

   [RFC4648]  Josefsson, S., "The Base16, Base32, and Base64 Data
              Encodings", RFC 4648, DOI 10.17487/RFC4648, October 2006,
              <https://www.rfc-editor.org/rfc/rfc4648>.

   [RFC7253]  Krovetz, T. and P. Rogaway, "The OCB Authenticated-
              Encryption Algorithm", RFC 7253, DOI 10.17487/RFC7253, May
              2014, <https://www.rfc-editor.org/rfc/rfc7253>.

   [RFC7748]  Langley, A., Hamburg, M., and S. Turner, "Elliptic Curves
              for Security", RFC 7748, DOI 10.17487/RFC7748, January
              2016, <https://www.rfc-editor.org/rfc/rfc7748>.

   [RFC8017]  Moriarty, K., Ed., Kaliski, B., Jonsson, J., and A. Rusch,
              "PKCS #1: RSA Cryptography Specifications Version 2.2",
              RFC 8017, DOI 10.17487/RFC8017, November 2016,
              <https://www.rfc-editor.org/rfc/rfc8017>.

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   [RFC8032]  Josefsson, S. and I. Liusvaara, "Edwards-Curve Digital
              Signature Algorithm (EdDSA)", RFC 8032,
              DOI 10.17487/RFC8032, January 2017,
              <https://www.rfc-editor.org/rfc/rfc8032>.

   [RFC8126]  Cotton, M., Leiba, B., and T. Narten, "Guidelines for
              Writing an IANA Considerations Section in RFCs", BCP 26,
              RFC 8126, DOI 10.17487/RFC8126, June 2017,
              <https://www.rfc-editor.org/rfc/rfc8126>.

   [RFC8174]  Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
              2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
              May 2017, <https://www.rfc-editor.org/rfc/rfc8174>.

   [RFC9106]  Biryukov, A., Dinu, D., Khovratovich, D., and S.
              Josefsson, "Argon2 Memory-Hard Function for Password
              Hashing and Proof-of-Work Applications", RFC 9106,
              DOI 10.17487/RFC9106, September 2021,
              <https://www.rfc-editor.org/rfc/rfc9106>.

   [SCHNEIER] Schneier, B., "Applied Cryptography Second Edition:
              protocols, algorithms, and source code in C", 1996.

   [SP800-38A]
              Dworkin, M., "Recommendation for Block Cipher Modes of
              Operation: Methods and Techniques", NIST Special
              Publication 800-38A, December 2001.

   [SP800-38D]
              Dworkin, M., "Recommendation for Block Cipher Modes of
              Operation: Galois/Counter Mode (GCM) and GMAC", NIST
              Special Publication 800-38D, November 2007.

   [SP800-56A]
              Barker, E., Johnson, D., and M. Smid, "Recommendation for
              Pair-Wise Key Establishment Schemes Using Discrete
              Logarithm Cryptography", NIST Special Publication 800-56A
              Revision 1, March 2007.

   [TWOFISH]  Schneier, B., Kelsey, J., Whiting, D., Wagner, D., Hall,
              C., and N. Ferguson, "The Twofish Encryption Algorithm",
              1999.

16.2.  Informative References

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   [BLEICHENBACHER]
              Bleichenbacher, D., "Generating ElGamal Signatures Without
              Knowing the Secret Key", Lecture Notes in Computer
              Science Volume 1070, pp. 10-18, 1996.

   [BLEICHENBACHER-PKCS1]
              Bleichenbacher, D., "Chosen Ciphertext Attacks Against
              Protocols Based on the RSA Encryption Standard PKCS \#1",
              1998, <http://archiv.infsec.ethz.ch/education/fs08/secsem/
              Bleichenbacher98.pdf>.

   [CHECKOWAY]
              Checkoway, S., Maskiewicz, J., Garman, C., Fried, J.,
              Cohney, S., Green, M., Heninger, N., Weinmann, R.,
              Rescorla, E., and H. Shacham, "A Systematic Analysis of
              the Juniper Dual EC Incident", Proceedings of the 2016 ACM
              SIGSAC Conference on Computer and Communications Security,
              DOI 10.1145/2976749.2978395, October 2016,
              <https://doi.org/10.1145/2976749.2978395>.

   [EFAIL]    Poddebniak, D., Dresen, C., Müller, J., Ising, F.,
              Schinzel, S., Friedberger, S., Somorovsky, J., and J.
              Schwenk, "Efail: Breaking S/MIME and OpenPGP Email
              Encryption using Exfiltration Channels", Proceedings of
              the 27th USENIX Conference on Security Symposium, August
              2018, Pages 549-566 , 2018,
              <https://www.usenix.org/system/files/conference/
              usenixsecurity18/sec18-poddebniak.pdf>.

   [FIPS186-5]
              Regenscheid, A., "Digital Signature Standard (DSS):
              Elliptic Curve Domain Parameters", National Institute of
              Standards and Technology (NIST) posted-content,
              DOI 10.6028/nist.fips.186-5-draft, October 2019,
              <https://doi.org/10.6028/nist.fips.186-5-draft>.

   [JKS02]    Jallad, K., Katz, J., and B. Schneier, "Implementation of
              Chosen-Ciphertext Attacks against PGP and GnuPG", 2002,
              <http://www.counterpane.com/pgp-attack.html>.

   [KOBLITZ]  Koblitz, N., "A course in number theory and cryptography,
              Chapter VI. Elliptic Curves", ISBN 0-387-96576-9, 1997.

   [KOPENPGP] Bruseghini, L., Paterson, K. G., and D. Huigens, "Victory
              by KO: Attacking OpenPGP Using Key Overwriting",
              Proceedings of the 29th ACM Conference on Computer and
              Communications Security, November 2022 (to appear) , 2022,
              <https://www.kopenpgp.com/>.

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   [KR02]     Klíma, V. and T. Rosa, "Attack on Private Signature Keys
              of the OpenPGP Format, PGP(TM) Programs and Other
              Applications Compatible with OpenPGP", Cryptology ePrint
              Archive, Report 2002/076 , 2002,
              <https://eprint.iacr.org/2002/076>.

   [MRLG15]   Maury, F., Reinhard, J.-R., Levillain, O., and H. Gilbert,
              "Format Oracles on OpenPGP", CT-RSA 2015 Topics in
              Cryptology -- CT-RSA 2015 pp 220-236,
              DOI 10.1007/978-3-319-16715-2_12, 2015,
              <https://doi.org/10.1007/978-3-319-16715-2_12>.

   [MZ05]     Mister, S. and R. Zuccherato, "An Attack on CFB Mode
              Encryption As Used By OpenPGP", IACR ePrint Archive Report
              2005/033, 8 February 2005,
              <http://eprint.iacr.org/2005/033>.

   [OPENPGPCARD]
              Pietig, A., "Functional Specification of the OpenPGP
              application on ISO Smart Card Operating Systems (version
              3.4.1)", 2020, <https://gnupg.org/ftp/specs/OpenPGP-smart-
              card-application-3.4.1.pdf>.

   [PAX]      The Open Group, "IEEE Standard for Information
              Technology--Portable Operating System Interface (POSIX(R))
              Base Specifications, Issue 7: pax - portable archive
              interchange", IEEE Standard 1003.1-2017,
              DOI 10.1109/IEEESTD.2018.8277153, 2018,
              <https://pubs.opengroup.org/onlinepubs/9699919799/
              utilities/pax.html>.

   [PSSLR17]  Poddebniak, D., Somorovsky, J., Schinzel, S., Lochter, M.,
              and P. Rösler, "Attacking Deterministic Signature Schemes
              using Fault Attacks", October 2017,
              <https://eprint.iacr.org/2017/1014>.

   [REGEX]    Friedl, J., "Mastering Regular Expressions",
              ISBN 0-596-00289-0, August 2002.

   [RFC1991]  Atkins, D., Stallings, W., and P. Zimmermann, "PGP Message
              Exchange Formats", RFC 1991, DOI 10.17487/RFC1991, August
              1996, <https://www.rfc-editor.org/rfc/rfc1991>.

   [RFC2440]  Callas, J., Donnerhacke, L., Finney, H., and R. Thayer,
              "OpenPGP Message Format", RFC 2440, DOI 10.17487/RFC2440,
              November 1998, <https://www.rfc-editor.org/rfc/rfc2440>.

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   [RFC4880]  Callas, J., Donnerhacke, L., Finney, H., Shaw, D., and R.
              Thayer, "OpenPGP Message Format", RFC 4880,
              DOI 10.17487/RFC4880, November 2007,
              <https://www.rfc-editor.org/rfc/rfc4880>.

   [RFC5639]  Lochter, M. and J. Merkle, "Elliptic Curve Cryptography
              (ECC) Brainpool Standard Curves and Curve Generation",
              RFC 5639, DOI 10.17487/RFC5639, March 2010,
              <https://www.rfc-editor.org/rfc/rfc5639>.

   [RFC5869]  Krawczyk, H. and P. Eronen, "HMAC-based Extract-and-Expand
              Key Derivation Function (HKDF)", RFC 5869,
              DOI 10.17487/RFC5869, May 2010,
              <https://www.rfc-editor.org/rfc/rfc5869>.

   [RFC6090]  McGrew, D., Igoe, K., and M. Salter, "Fundamental Elliptic
              Curve Cryptography Algorithms", RFC 6090,
              DOI 10.17487/RFC6090, February 2011,
              <https://www.rfc-editor.org/rfc/rfc6090>.

   [RFC6637]  Jivsov, A., "Elliptic Curve Cryptography (ECC) in
              OpenPGP", RFC 6637, DOI 10.17487/RFC6637, June 2012,
              <https://www.rfc-editor.org/rfc/rfc6637>.

   [SEC1]     Standards for Efficient Cryptography Group, "Standards for
              Efficient Cryptography 1 (SEC 1)", May 2009,
              <https://www.secg.org/sec1-v2.pdf>.

   [SHA1CD]   Stevens, M. and D. Shumow, "sha1collisiondetection", 2017,
              <https://github.com/cr-marcstevens/
              sha1collisiondetection>.

   [SHAMBLES] Leurent, G. and T. Peyrin, "Sha-1 is a shambles: First
              chosen-prefix collision on sha-1 and application to the
              PGP web of trust", 2020, <https://sha-mbles.github.io/>.

   [SP800-131A]
              Barker, E. and A. Roginsky, "Transitioning the Use of
              Cryptographic Algorithms and Key Lengths", NIST Special
              Publication 800-131A Revision 2, March 2019,
              <https://nvlpubs.nist.gov/nistpubs/SpecialPublications/
              NIST.SP.800-131Ar2.pdf>.

   [SP800-57] NIST, "Recommendation on Key Management", NIST Special
              Publication 800-57, March 2007,
              <http://csrc.nist.gov/publications/nistpubs/800-57/
              SP800-57-Part{1,2}.pdf>.

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   [STEVENS2013]
              Stevens, M., "Counter-cryptanalysis", June 2013,
              <https://eprint.iacr.org/2013/358>.

   [UNIFIED-DIFF]
              Free Software Foundation, "Detailed Description of Unified
              Format", 2 January 2021,
              <https://www.gnu.org/software/diffutils/manual/html_node/
              Detailed-Unified.html>.

Appendix A.  Test vectors

   To help implementing this specification a non-normative example for
   the EdDSA algorithm is given.

A.1.  Sample v4 Ed25519Legacy key

   The secret key used for this example is:

   D: 1a8b1ff05ded48e18bf50166c664ab023ea70003d78d9e41f5758a91d850f8d2

   Note that this is the raw secret key used as input to the EdDSA
   signing operation.  The key was created on 2014-08-19 14:28:27 and
   thus the fingerprint of the OpenPGP key is:

      C959 BDBA FA32 A2F8 9A15  3B67 8CFD E121 9796 5A9A

   The algorithm-specific input parameters without the MPI length
   headers are:

   oid: 2b06010401da470f01

   q: 403f098994bdd916ed4053197934e4a87c80733a1280d62f8010992e43ee3b2406

   The entire public key packet is thus:

      98 33 04 53 f3 5f 0b 16  09 2b 06 01 04 01 da 47
      0f 01 01 07 40 3f 09 89  94 bd d9 16 ed 40 53 19
      79 34 e4 a8 7c 80 73 3a  12 80 d6 2f 80 10 99 2e
      43 ee 3b 24 06

   The same packet, represented in ASCII-armored form is:

   -----BEGIN PGP PUBLIC KEY BLOCK-----

   xjMEU/NfCxYJKwYBBAHaRw8BAQdAPwmJlL3ZFu1AUxl5NOSofIBzOhKA1i+AEJku
   Q+47JAY=
   -----END PGP PUBLIC KEY BLOCK-----

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A.2.  Sample v4 Ed25519Legacy signature

   The signature is created using the sample key over the input data
   "OpenPGP" on 2015-09-16 12:24:53 UTC and thus the input to the hash
   function is:

   m: 4f70656e504750040016080006050255f95f9504ff0000000c

   Using the SHA2-256 hash algorithm yields the digest:

   d: f6220a3f757814f4c2176ffbb68b00249cd4ccdc059c4b34ad871f30b1740280

   Which is fed into the EdDSA signature function and yields this
   signature:

   r: 56f90cca98e2102637bd983fdb16c131dfd27ed82bf4dde5606e0d756aed3366

   s: d09c4fa11527f038e0f57f2201d82f2ea2c9033265fa6ceb489e854bae61b404

   The entire signature packet is thus:

      88 5e 04 00 16 08 00 06  05 02 55 f9 5f 95 00 0a
      09 10 8c fd e1 21 97 96  5a 9a f6 22 00 ff 56 f9
      0c ca 98 e2 10 26 37 bd  98 3f db 16 c1 31 df d2
      7e d8 2b f4 dd e5 60 6e  0d 75 6a ed 33 66 01 00
      d0 9c 4f a1 15 27 f0 38  e0 f5 7f 22 01 d8 2f 2e
      a2 c9 03 32 65 fa 6c eb  48 9e 85 4b ae 61 b4 04

   The same packet represented in ASCII-armored form is:

   -----BEGIN PGP SIGNATURE-----

   iF4EABYIAAYFAlX5X5UACgkQjP3hIZeWWpr2IgD/VvkMypjiECY3vZg/2xbBMd/S
   ftgr9N3lYG4NdWrtM2YBANCcT6EVJ/A44PV/IgHYLy6iyQMyZfps60iehUuuYbQE
   -----END PGP SIGNATURE-----

A.3.  Sample v6 Certificate (Transferable Public Key)

   Here is a Transferable Public Key consisting of:

   *  A v6 Ed25519 Public-Key packet

   *  A v6 direct key self-signature

   *  A v6 X25519 Public-Subkey packet

   *  A v6 subkey binding signature

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   The primary key has the fingerprint
   CB186C4F0609A697E4D52DFA6C722B0C1F1E27C18A56708F6525EC27BAD9ACC9.

   The subkey has the fingerprint
   12C83F1E706F6308FE151A417743A1F033790E93E9978488D1DB378DA9930885.

   -----BEGIN PGP PUBLIC KEY BLOCK-----

   xioGY4d/4xsAAAAg+U2nu0jWCmHlZ3BqZYfQMxmZu52JGggkLq2EVD34laPCsQYf
   GwoAAABCBYJjh3/jAwsJBwUVCg4IDAIWAAKbAwIeCSIhBssYbE8GCaaX5NUt+mxy
   KwwfHifBilZwj2Ul7Ce62azJBScJAgcCAAAAAK0oIBA+LX0ifsDm185Ecds2v8lw
   gyU2kCcUmKfvBXbAf6rhRYWzuQOwEn7E/aLwIwRaLsdry0+VcallHhSu4RN6HWaE
   QsiPlR4zxP/TP7mhfVEe7XWPxtnMUMtf15OyA51YBM4qBmOHf+MZAAAAIIaTJINn
   +eUBXbki+PSAld2nhJh/LVmFsS+60WyvXkQ1wpsGGBsKAAAALAWCY4d/4wKbDCIh
   BssYbE8GCaaX5NUt+mxyKwwfHifBilZwj2Ul7Ce62azJAAAAAAQBIKbpGG2dWTX8
   j+VjFM21J0hqWlEg+bdiojWnKfA5AQpWUWtnNwDEM0g12vYxoWM8Y81W+bHBw805
   I8kWVkXU6vFOi+HWvv/ira7ofJu16NnoUkhclkUrk0mXubZvyl4GBg==
   -----END PGP PUBLIC KEY BLOCK-----

   The corresponding Transferable Secret Key can be found in
   Appendix A.4.

A.3.1.  Hashed Data Stream for Signature Verification

   The direct key self signature in the certificate in Appendix A.3 is
   made over the following sequence of data:

   0x0000  10 3e 2d 7d 22 7e c0 e6
   0x0008  d7 ce 44 71 db 36 bf c9
   0x0010  70 83 25 36 90 27 14 98
   0x0018  a7 ef 05 76 c0 7f aa e1
   0x0020  9b 00 00 00 2a 06 63 87
   0x0028  7f e3 1b 00 00 00 20 f9
   0x0030  4d a7 bb 48 d6 0a 61 e5
   0x0038  67 70 6a 65 87 d0 33 19
   0x0040  99 bb 9d 89 1a 08 24 2e
   0x0048  ad 84 54 3d f8 95 a3 06
   0x0050  1f 1b 0a 00 00 00 42 05
   0x0058  82 63 87 7f e3 03 0b 09
   0x0060  07 05 15 0a 0e 08 0c 02
   0x0068  16 00 02 9b 03 02 1e 09
   0x0070  22 21 06 cb 18 6c 4f 06
   0x0078  09 a6 97 e4 d5 2d fa 6c
   0x0080  72 2b 0c 1f 1e 27 c1 8a
   0x0088  56 70 8f 65 25 ec 27 ba
   0x0090  d9 ac c9 05 27 09 02 07
   0x0098  02 06 ff 00 00 00 4a

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   The same data, broken out by octet and semantics, is:

   0x0000  10 3e 2d 7d 22 7e c0 e6  salt
   0x0008  d7 ce 44 71 db 36 bf c9
   0x0010  70 83 25 36 90 27 14 98
   0x0018  a7 ef 05 76 c0 7f aa e1
           [ pubkey begins ]
   0x0020  9b                       v6 pubkey
   0x0021     00 00 00 2a           pubkey length
   0x0025                 06        pubkey version
   0x0026                    63 87  creation time
   0x0028  7f e3                      (2022-11-30T16:08:03Z)
   0x002a        1b                 key algo: Ed25519
   0x002b           00 00 00 20     key length
   0x002f                       f9  Ed25519 public key
   0x0030  4d a7 bb 48 d6 0a 61 e5
   0x0038  67 70 6a 65 87 d0 33 19
   0x0040  99 bb 9d 89 1a 08 24 2e
   0x0048  ad 84 54 3d f8 95 a3
            [ trailer begins ]
   0x004f                       06  sig version
   0x0050  1f                       sig type: direct key signature
   0x0051     1b                    sig algo: Ed25519
   0x0052        0a                 hash ago: SHA2-512
   0x0053           00 00 00 42     hashed subpackets length
   0x0057                       05  subpkt length
   0x0058  82                       critical subpkt: Sig Creation Time
   0x0059     63 87 7f e3           Signature Creation Time
   0x005d                 03        subpkt length
   0x005e                    0b     subpkt type: Pref. v1 SEIPD Ciphers
   0x005f                       09  Ciphers: [AES256 AES128]
   0x0060  07
   0x0061     05                    subpkt length
   0x0062        15                 subpkt type: Pref. Hash Algorithms
   0x0063           0a 0e           Hashes: [SHA2-512 SHA3-512
   0x0065                 08 0c              SHA2-256 SHA3-256]
   0x0067                       02  subpkt length
   0x0068  16                       subpkt type: Pref. Compression
   0x0069     00                    Compression: [none]
   0x006a        02                 subpkt length
   0x006b           9b              critical subpkt: Key Flags
   0x006c              03           Key Flags: {certify, sign}
   0x006d                 02        subpkt length
   0x006e                    1e     subpkt type: Features
   0x006f                       09  Features: {SEIPDv1, SEIPDv2}
   0x0070  22                       subpkt length
   0x0071     21                    subpkt type: Issuer Fingerprint
   0x0072        06                 Fingerprint version 6

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   0x0073           cb 18 6c 4f 06  Issuer Fingerprint
   0x0078  09 a6 97 e4 d5 2d fa 6c
   0x0080  72 2b 0c 1f 1e 27 c1 8a
   0x0088  56 70 8f 65 25 ec 27 ba
   0x0090  d9 ac c9
   0x0093           05              subpkt length
   0x0094              27           subpkt type: Pref. AEAD Ciphersuites
   0x0095                 09 02 07  Ciphersuites:
   0x0098  02                         [ AES256-OCB, AES128-OCB ]
   0x0099     06                    sig version
   0x009a        ff                 sentinel octet
   0x009b           00 00 00 4a     trailer length

   The subkey binding signature in Appendix A.3 is made over the
   following sequence of data:

   0x0000  a6 e9 18 6d 9d 59 35 fc
   0x0008  8f e5 63 14 cd b5 27 48
   0x0010  6a 5a 51 20 f9 b7 62 a2
   0x0018  35 a7 29 f0 39 01 0a 56
   0x0020  9b 00 00 00 2a 06 63 87
   0x0028  7f e3 1b 00 00 00 20 f9
   0x0030  4d a7 bb 48 d6 0a 61 e5
   0x0038  67 70 6a 65 87 d0 33 19
   0x0040  99 bb 9d 89 1a 08 24 2e
   0x0048  ad 84 54 3d f8 95 a3 9b
   0x0050  00 00 00 2a 06 63 87 7f
   0x0058  e3 19 00 00 00 20 86 93
   0x0060  24 83 67 f9 e5 01 5d b9
   0x0068  22 f8 f4 80 95 dd a7 84
   0x0070  98 7f 2d 59 85 b1 2f ba
   0x0078  d1 6c af 5e 44 35 06 18
   0x0080  1b 0a 00 00 00 2c 05 82
   0x0088  63 87 7f e3 02 9b 0c 22
   0x0090  21 06 cb 18 6c 4f 06 09
   0x0098  a6 97 e4 d5 2d fa 6c 72
   0x00a0  2b 0c 1f 1e 27 c1 8a 56
   0x00a8  70 8f 65 25 ec 27 ba d9
   0x00b0  ac c9 06 ff 00 00 00 34

   The same data, broken out by octet and semantics, is:

   0x0000  a6 e9 18 6d 9d 59 35 fc  salt
   0x0008  8f e5 63 14 cd b5 27 48
   0x0010  6a 5a 51 20 f9 b7 62 a2
   0x0018  35 a7 29 f0 39 01 0a 56
         [ primary pubkey begins ]
   0x0020  9b                       v6 pubkey

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   0x0021     00 00 00 2a           pubkey length
   0x0025                 06        pubkey version
   0x0026                    63 87  creation time
   0x0028  7f e3                      (2022-11-30T16:08:03Z)
   0x002a        1b                 key algo: Ed25519
   0x002b           00 00 00 20     key length
   0x002f                       f9  Ed25519 public key
   0x0030  4d a7 bb 48 d6 0a 61 e5
   0x0038  67 70 6a 65 87 d0 33 19
   0x0040  99 bb 9d 89 1a 08 24 2e
   0x0048  ad 84 54 3d f8 95 a3
         [ subkey pubkey begins ]
   0x004f                       9b  v6 key
   0x0050  00 00 00 2a              pubkey length
   0x0054              06           pubkey version
   0x0055                 63 87 7f  creation time (2022-11-30T16:08:03Z)
   0x0058  e3
   0x0059     19                    key algo: X25519
   0x005a        00 00 00 20        key length
   0x005e                    86 93  X25519 public key
   0x0060  24 83 67 f9 e5 01 5d b9
   0x0068  22 f8 f4 80 95 dd a7 84
   0x0070  98 7f 2d 59 85 b1 2f ba
   0x0078  d1 6c af 5e 44 35
          [ trailer begins ]
   0x007e                    06     sig version
   0x007f                       18  sig type: Subkey Binding sig
   0x0080  1b                       sig algo Ed25519
   0x0081     0a                    hash algo: SHA2-512
   0x0082        00 00 00 2c        hashed subpackets length
   0x0086                    05     subpkt length
   0x0087                       82  critical subpkt: Sig Creation Time
   0x0088  63 87 7f e3              Signature Creation Time
   0x008c              02           subpkt length
   0x008d                 9b        critical subpkt: Key Flags
   0x008e                    0c     Key Flags: {EncComms, EncStorage}
   0x008f                       22  subpkt length
   0x0090  21                       subpkt type: Issuer Fingerprint
   0x0091     06                    Fingerprint version 6
   0x0092        cb 18 6c 4f 06 09  Fingerprint
   0x0098  a6 97 e4 d5 2d fa 6c 72
   0x00a0  2b 0c 1f 1e 27 c1 8a 56
   0x00a8  70 8f 65 25 ec 27 ba d9
   0x00b0  ac c9
   0x00b2        06                 sig version
   0x00b3           ff              sentinel octet
   0x00b4              00 00 00 34  trailer length

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A.4.  Sample v6 Secret Key (Transferable Secret Key)

   Here is a Transferable Secret Key consisting of:

   *  A v6 Ed25519 Secret-Key packet

   *  A v6 direct key self-signature

   *  A v6 X25519 Secret-Subkey packet

   *  A v6 subkey binding signature

   -----BEGIN PGP PRIVATE KEY BLOCK-----

   xUsGY4d/4xsAAAAg+U2nu0jWCmHlZ3BqZYfQMxmZu52JGggkLq2EVD34laMAGXKB
   exK+cH6NX1hs5hNhIB00TrJmosgv3mg1ditlsLfCsQYfGwoAAABCBYJjh3/jAwsJ
   BwUVCg4IDAIWAAKbAwIeCSIhBssYbE8GCaaX5NUt+mxyKwwfHifBilZwj2Ul7Ce6
   2azJBScJAgcCAAAAAK0oIBA+LX0ifsDm185Ecds2v8lwgyU2kCcUmKfvBXbAf6rh
   RYWzuQOwEn7E/aLwIwRaLsdry0+VcallHhSu4RN6HWaEQsiPlR4zxP/TP7mhfVEe
   7XWPxtnMUMtf15OyA51YBMdLBmOHf+MZAAAAIIaTJINn+eUBXbki+PSAld2nhJh/
   LVmFsS+60WyvXkQ1AE1gCk95TUR3XFeibg/u/tVY6a//1q0NWC1X+yui3O24wpsG
   GBsKAAAALAWCY4d/4wKbDCIhBssYbE8GCaaX5NUt+mxyKwwfHifBilZwj2Ul7Ce6
   2azJAAAAAAQBIKbpGG2dWTX8j+VjFM21J0hqWlEg+bdiojWnKfA5AQpWUWtnNwDE
   M0g12vYxoWM8Y81W+bHBw805I8kWVkXU6vFOi+HWvv/ira7ofJu16NnoUkhclkUr
   k0mXubZvyl4GBg==
   -----END PGP PRIVATE KEY BLOCK-----

   The corresponding Transferable Public Key can be found in
   Appendix A.3.

A.5.  Sample AEAD-EAX encryption and decryption

   This example encrypts the cleartext string Hello, world! with the
   password password, using AES-128 with AEAD-EAX encryption.

A.5.1.  Sample symmetric-key encrypted session key packet (v6)

   This packet contains the following series of octets:

   0x0000  c3 40 06 1e 07 01 0b 03
   0x0008  08 a5 ae 57 9d 1f c5 d8
   0x0010  2b ff 69 22 4f 91 99 93
   0x0018  b3 50 6f a3 b5 9a 6a 73
   0x0020  cf f8 c5 ef c5 f4 1c 57
   0x0028  fb 54 e1 c2 26 81 5d 78
   0x0030  28 f5 f9 2c 45 4e b6 5e
   0x0038  be 00 ab 59 86 c6 8e 6e
   0x0040  7c 55

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   The same data, broken out by octet and semantics:

   0x0000  c3                       packet tag: SKESK
   0x0001     40                    packet length
   0x0002        06                 SKESK version 6
   0x0003           1e              length through end of AEAD nonce
   0x0004              07           cipher: AES128
   0x0005                 01        AEAD mode: EAX
   0x0006                    0b     length of S2K
   0x0007                       03  S2K type: iterated+salted
   0x0008  08                       S2K hash: SHA2-256
   0x0009     a5 ae 57 9d 1f c5 d8  S2K salt
   0x0010  2b
   0x0011     ff                    S2K iterations (65011712 octets)
   0x0012        69 22 4f 91 99 93  AEAD nonce
   0x0018  b3 50 6f a3 b5 9a 6a 73
   0x0020  cf f8
   0x0022        c5 ef c5 f4 1c 57  encrypted session key
   0x0028  fb 54 e1 c2 26 81 5d 78
   0x0030  28 f5
   0x0032        f9 2c 45 4e b6 5e  AEAD tag
   0x0038  be 00 ab 59 86 c6 8e 6e
   0x0040  7c 55

A.5.2.  Starting AEAD-EAX decryption of the session key

   The derived key is:

     15 49 67 e5 90 aa 1f 92 3e 1c 0a c6 4c 88 f2 3d

   HKDF info:

     c3 06 07 01

   HKDF output:

     2f ce 33 1f 39 dd 95 5c c4 1e 95 d8 70 c7 21 39

   Authenticated Data:

     c3 06 07 01

   Nonce:

     69 22 4f 91 99 93 b3 50 6f a3 b5 9a 6a 73 cf f8

   Decrypted session key:

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     38 81 ba fe 98 54 12 45 9b 86 c3 6f 98 cb 9a 5e

A.5.3.  Sample v2 SEIPD packet

   This packet contains the following series of octets:

   0x0000  d2 69 02 07 01 06 9f f9
   0x0008  0e 3b 32 19 64 f3 a4 29
   0x0010  13 c8 dc c6 61 93 25 01
   0x0018  52 27 ef b7 ea ea a4 9f
   0x0020  04 c2 e6 74 17 5d 4a 3d
   0x0028  22 6e d6 af cb 9c a9 ac
   0x0030  12 2c 14 70 e1 1c 63 d4
   0x0038  c0 ab 24 1c 6a 93 8a d4
   0x0040  8b f9 9a 5a 99 b9 0b ba
   0x0048  83 25 de 61 04 75 40 25
   0x0050  8a b7 95 9a 95 ad 05 1d
   0x0058  da 96 eb 15 43 1d fe f5
   0x0060  f5 e2 25 5c a7 82 61 54
   0x0068  6e 33 9a

   The same data, broken out by octet and semantics:

   0x0000  d2                       packet tag: SEIPD
   0x0001     69                    packet length
   0x0002        02                 SEIPD version 2
   0x0003           07              cipher: AES128
   0x0004              01           AEAD mode: EAX
   0x0005                 06        chunk size (2**12 octets)
   0x0005                    9f f9  salt
   0x0008  0e 3b 32 19 64 f3 a4 29
   0x0010  13 c8 dc c6 61 93 25 01
   0x0018  52 27 ef b7 ea ea a4 9f
   0x0020  04 c2 e6 74 17 5d
   0x0026                    4a 3d  chunk #0 encrypted data
   0x0028  22 6e d6 af cb 9c a9 ac
   0x0030  12 2c 14 70 e1 1c 63 d4
   0x0038  c0 ab 24 1c 6a 93 8a d4
   0x0040  8b f9 9a 5a 99 b9 0b ba
   0x0048  83 25 de
   0x004b           61 04 75 40 25  chunk #0 AEAD tag
   0x0050  8a b7 95 9a 95 ad 05 1d
   0x0058  da 96 eb
   0x005b           15 43 1d fe f5  final AEAD tag (#1)
   0x0060  f5 e2 25 5c a7 82 61 54
   0x0068  6e 33 9a

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A.5.4.  Decryption of data

   Starting AEAD-EAX decryption of data, using the session key.

   HKDF info:

     d2 02 07 01 06

   HKDF output:

     b5 04 22 ac 1c 26 be 9d dd 83 1d 5b bb 36 b6 4f
     78 b8 33 f2 e9 4a 60 c0

   Message key:

     b5 04 22 ac 1c 26 be 9d dd 83 1d 5b bb 36 b6 4f

   Initialization vector:

     78 b8 33 f2 e9 4a 60 c0

   Chunk #0:

   Nonce:

     78 b8 33 f2 e9 4a 60 c0 00 00 00 00 00 00 00 00

   Additional authenticated data:

     d2 02 07 01 06

   Decrypted chunk #0.

   Literal data packet with the string contents Hello, world!:

     cb 13 62 00 00 00 00 00 48 65 6c 6c 6f 2c 20 77
     6f 72 6c 64 21

   Padding packet:

     d5 0e ae 5b f0 cd 67 05 50 03 55 81 6c b0 c8 ff

   Authenticating final tag:

   Final nonce:

     78 b8 33 f2 e9 4a 60 c0 00 00 00 00 00 00 00 01

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   Final additional authenticated data:

     d2 02 07 01 06 00 00 00 00 00 00 00 25

A.5.5.  Complete AEAD-EAX encrypted packet sequence

   -----BEGIN PGP MESSAGE-----

   w0AGHgcBCwMIpa5XnR/F2Cv/aSJPkZmTs1Bvo7WaanPP+MXvxfQcV/tU4cImgV14
   KPX5LEVOtl6+AKtZhsaObnxV0mkCBwEGn/kOOzIZZPOkKRPI3MZhkyUBUifvt+rq
   pJ8EwuZ0F11KPSJu1q/LnKmsEiwUcOEcY9TAqyQcapOK1Iv5mlqZuQu6gyXeYQR1
   QCWKt5Wala0FHdqW6xVDHf719eIlXKeCYVRuM5o=
   -----END PGP MESSAGE-----

A.6.  Sample AEAD-OCB encryption and decryption

   This example encrypts the cleartext string Hello, world! with the
   password password, using AES-128 with AEAD-OCB encryption.

A.6.1.  Sample symmetric-key encrypted session key packet (v6)

   This packet contains the following series of octets:

   0x0000  c3 3f 06 1d 07 02 0b 03
   0x0008  08 56 a2 98 d2 f5 e3 64
   0x0010  53 ff cf cc 5c 11 66 4e
   0x0018  db 9d b4 25 90 d7 dc 46
   0x0020  b0 72 41 b6 12 c3 81 2c
   0x0028  ff fb ea 00 f2 34 7b 25
   0x0030  64 11 23 f8 87 ae 60 d4
   0x0038  fd 61 4e 08 37 d8 19 d3
   0x0040  6c

   The same data, broken out by octet and semantics:

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   0x0000  c3                       packet tag: SKESK
   0x0001     3f                    packet length
   0x0002        06                 SKESK version 6
   0x0003           1d              length through end of AEAD nonce
   0x0004              07           cipher: AES128
   0x0005                 02        AEAD mode: OCB
   0x0006                    0b     length of S2K
   0x0007                       03  S2K type: iterated+salted
   0x0008  08                       S2K hash: SHA2-256
   0x0009     56 a2 98 d2 f5 e3 64  S2K salt
   0x0010  53
   0x0011    ff                     S2K iterations (65011712 octets)
   0x0012        cf cc 5c 11 66 4e  AEAD nonce
   0x0018  db 9d b4 25 90 d7 dc 46
   0x0020  b0
   0x0021     72 41 b6 12 c3 81 2c  encrypted session key
   0x0028  ff fb ea 00 f2 34 7b 25
   0x0030  64
   0x0031     11 23 f8 87 ae 60 d4  AEAD tag
   0x0038  fd 61 4e 08 37 d8 19 d3
   0x0040  6c

A.6.2.  Starting AEAD-OCB decryption of the session key

   The derived key is:

     e8 0d e2 43 a3 62 d9 3b 9d c6 07 ed e9 6a 73 56

   HKDF info:

     c3 06 07 02

   HKDF output:

     38 a9 b3 45 b5 68 0b b6 1b b6 5d 73 ee c7 ec d9

   Authenticated Data:

     c3 06 07 02

   Nonce:

     cf cc 5c 11 66 4e db 9d b4 25 90 d7 dc 46 b0

   Decrypted session key:

     28 e7 9a b8 23 97 d3 c6 3d e2 4a c2 17 d7 b7 91

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A.6.3.  Sample v2 SEIPD packet

   This packet contains the following series of octets:

   0x0000  d2 69 02 07 02 06 20 a6
   0x0008  61 f7 31 fc 9a 30 32 b5
   0x0010  62 33 26 02 7e 3a 5d 8d
   0x0018  b5 74 8e be ff 0b 0c 59
   0x0020  10 d0 9e cd d6 41 ff 9f
   0x0028  d3 85 62 75 80 35 bc 49
   0x0030  75 4c e1 bf 3f ff a7 da
   0x0038  d0 a3 b8 10 4f 51 33 cf
   0x0040  42 a4 10 0a 83 ee f4 ca
   0x0048  1b 48 01 a8 84 6b f4 2b
   0x0050  cd a7 c8 ce 9d 65 e2 12
   0x0058  f3 01 cb cd 98 fd ca de
   0x0060  69 4a 87 7a d4 24 73 23
   0x0068  f6 e8 57

   The same data, broken out by octet and semantics:

   0x0000  d2                       packet tag: SEIPD
   0x0001     69                    packet length
   0x0002        02                 SEIPD version 2
   0x0003           07              cipher: AES128
   0x0004              02           AEAD mode: OCB
   0x0005                 06        chunk size (2**21 octets)
   0x0006                    20 a6  salt
   0x0008  61 f7 31 fc 9a 30 32 b5
   0x0010  62 33 26 02 7e 3a 5d 8d
   0x0018  b5 74 8e be ff 0b 0c 59
   0x0020  10 d0 9e cd d6 41
   0x0026                    ff 9f  chunk #0 encrypted data
   0x0028  d3 85 62 75 80 35 bc 49
   0x0030  75 4c e1 bf 3f ff a7 da
   0x0038  d0 a3 b8 10 4f 51 33 cf
   0x0040  42 a4 10 0a 83 ee f4 ca
   0x0048  1b 48 01
   0x004b           a8 84 6b f4 2b  chunk #0 authentication tag
   0x0050  cd a7 c8 ce 9d 65 e2 12
   0x0058  f3 01 cb
   0x005b           cd 98 fd ca de  final AEAD tag (#1)
   0x0060  69 4a 87 7a d4 24 73 23
   0x0068  f6 e8 57

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A.6.4.  Decryption of data

   Starting AEAD-OCB decryption of data, using the session key.

   HKDF info:

     d2 02 07 02 06

   HKDF output:

     71 66 2a 11 ee 5b 4e 08 14 4e 6d e8 83 a0 09 99
     eb de 12 bb 57 0d cf

   Message key:

     71 66 2a 11 ee 5b 4e 08 14 4e 6d e8 83 a0 09 99

   Initialization vector:

     eb de 12 bb 57 0d cf

   Chunk #0:

   Nonce:

     eb de 12 bb 57 0d cf 00 00 00 00 00 00 00 00

   Additional authenticated data:

     d2 02 07 02 06

   Decrypted chunk #0.

   Literal data packet with the string contents Hello, world!:

     cb 13 62 00 00 00 00 00 48 65 6c 6c 6f 2c 20 77
     6f 72 6c 64 21

   Padding packet:

     d5 0e ae 6a a1 64 9b 56 aa 83 5b 26 13 90 2b d2

   Authenticating final tag:

   Final nonce:

     eb de 12 bb 57 0d cf 00 00 00 00 00 00 00 01

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   Final additional authenticated data:

     d2 02 07 02 06 00 00 00 00 00 00 00 25

A.6.5.  Complete AEAD-OCB encrypted packet sequence

   -----BEGIN PGP MESSAGE-----

   wz8GHQcCCwMIVqKY0vXjZFP/z8xcEWZO2520JZDX3EawckG2EsOBLP/76gDyNHsl
   ZBEj+IeuYNT9YU4IN9gZ02zSaQIHAgYgpmH3MfyaMDK1YjMmAn46XY21dI6+/wsM
   WRDQns3WQf+f04VidYA1vEl1TOG/P/+n2tCjuBBPUTPPQqQQCoPu9MobSAGohGv0
   K82nyM6dZeIS8wHLzZj9yt5pSod61CRzI/boVw==
   -----END PGP MESSAGE-----

A.7.  Sample AEAD-GCM encryption and decryption

   This example encrypts the cleartext string Hello, world! with the
   password password, using AES-128 with AEAD-GCM encryption.

   This example encrypts the cleartext string Hello, world! with the
   password password, using AES-128 with AEAD-OCB encryption.

A.7.1.  Sample symmetric-key encrypted session key packet (v6)

   This packet contains the following series of octets:

   0x0000  c3 3c 06 1a 07 03 0b 03
   0x0008  08 e9 d3 97 85 b2 07 00
   0x0010  08 ff b4 2e 7c 48 3e f4
   0x0018  88 44 57 cb 37 26 b9 b3
   0x0020  db 9f f7 76 e5 f4 d9 a4
   0x0028  09 52 e2 44 72 98 85 1a
   0x0030  bf ff 75 26 df 2d d5 54
   0x0038  41 75 79 a7 79 9f

   The same data, broken out by octet and semantics:

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   0x0000  c3                       packet tag: SKESK
   0x0001     3c                    packet length
   0x0002        06                 SKESK version 6
   0x0003           1a              length through end of AEAD nonce
   0x0004              07           cipher: AES128
   0x0005                 03        AEAD mode: GCM
   0x0006                    0b     length of S2K
   0x0007                       03  S2K type: iterated+salted
   0x0008  08                       S2K hash: SHA2-256
   0x0009     e9 d3 97 85 b2 07 00  S2K salt
   0x0010  08
   0x0011     ff                    S2K iterations (65011712 octets)
   0x0012        b4 2e 7c 48 3e f4  AEAD nonce
   0x0018  88 44 57 cb 37 26
   0x001e                    b9 b3  encrypted session key
   0x0020  db 9f f7 76 e5 f4 d9 a4
   0x0028  09 52 e2 44 72 98
   0x002e                     85 1a  AEAD tag
   0x0030  bf ff 75 26 df 2d d5 54
   0x0038  41 75 79 a7 79 9f

A.7.2.  Starting AEAD-GCM decryption of the session key

   The derived key is:

     25 02 81 71 5b ba 78 28 ef 71 ef 64 c4 78 47 53

   HKDF info:

     c3 06 07 03

   HKDF output:

     7a 6f 9a b7 f9 9f 7e f8 db ef 84 1c 65 08 00 f5

   Authenticated Data:

     c3 06 07 03

   Nonce:

     b4 2e 7c 48 3e f4 88 44 57 cb 37 26

   Decrypted session key:

     19 36 fc 85 68 98 02 74 bb 90 0d 83 19 36 0c 77

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A.7.3.  Sample v2 SEIPD packet

   This packet contains the following series of octets:

   0x0000  d2 69 02 07 03 06 fc b9
   0x0008  44 90 bc b9 8b bd c9 d1
   0x0010  06 c6 09 02 66 94 0f 72
   0x0018  e8 9e dc 21 b5 59 6b 15
   0x0020  76 b1 01 ed 0f 9f fc 6f
   0x0028  c6 d6 5b bf d2 4d cd 07
   0x0030  90 96 6e 6d 1e 85 a3 00
   0x0038  53 78 4c b1 d8 b6 a0 69
   0x0040  9e f1 21 55 a7 b2 ad 62
   0x0048  58 53 1b 57 65 1f d7 77
   0x0050  79 12 fa 95 e3 5d 9b 40
   0x0058  21 6f 69 a4 c2 48 db 28
   0x0060  ff 43 31 f1 63 29 07 39
   0x0068  9e 6f f9

   The same data, broken out by octet and semantics:

   0x0000  d2                       packet tag: SEIPD
   0x0001     69                    packet length
   0x0002        02                 SEIPD version 2
   0x0003           07              cipher: AES128
   0x0004              03           AEAD mode: GCM
   0x0005                 06        chunk size (2**21 octets)
   0x0006                    fc b9  salt
   0x0008  44 90 bc b9 8b bd c9 d1
   0x0010  06 c6 09 02 66 94 0f 72
   0x0018  e8 9e dc 21 b5 59 6b 15
   0x0020  76 b1 01 ed 0f 9f
   0x0026                    fc 6f  chunk #0 encrypted data
   0x0028  c6 d6 5b bf d2 4d cd 07
   0x0030  90 96 6e 6d 1e 85 a3 00
   0x0038  53 78 4c b1 d8 b6 a0 69
   0x0040  9e f1 21 55 a7 b2 ad 62
   0x0048  58 53 1b
   0x004b           57 65 1f d7 77  chunk #0 authentication tag
   0x0050  79 12 fa 95 e3 5d 9b 40
   0x0058  21 6f 69
   0x005b           a4 c2 48 db 28  final AEAD tag (#1)
   0x0060  ff 43 31 f1 63 29 07 39
   0x0068  9e 6f f9

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A.7.4.  Decryption of data

   Starting AEAD-GCM decryption of data, using the session key.

   HKDF info:

     d2 02 07 03 06

   HKDF output:

     ea 14 38 80 3c b8 a4 77 40 ce 9b 54 c3 38 77 8d
     4d 2b dc 2b

   Message key:

     ea 14 38 80 3c b8 a4 77 40 ce 9b 54 c3 38 77 8d

   Initialization vector:

     4d 2b dc 2b

   Chunk #0:

   Nonce:

     4d 2b dc 2b 00 00 00 00 00 00 00 00

   Additional authenticated data:

     d2 02 07 03 06

   Decrypted chunk #0.

   Literal data packet with the string contents Hello, world!:

     cb 13 62 00 00 00 00 00 48 65 6c 6c 6f 2c 20 77
     6f 72 6c 64 21

   Padding packet:

     d5 0e 1c e2 26 9a 9e dd ef 81 03 21 72 b7 ed 7c

   Authenticating final tag:

   Final nonce:

     4d 2b dc 2b 00 00 00 00 00 00 00 01

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   Final additional authenticated data:

     d2 02 07 03 06 00 00 00 00 00 00 00 25

A.7.5.  Complete AEAD-GCM encrypted packet sequence

   -----BEGIN PGP MESSAGE-----

   wzwGGgcDCwMI6dOXhbIHAAj/tC58SD70iERXyzcmubPbn/d25fTZpAlS4kRymIUa
   v/91Jt8t1VRBdXmneZ/SaQIHAwb8uUSQvLmLvcnRBsYJAmaUD3LontwhtVlrFXax
   Ae0Pn/xvxtZbv9JNzQeQlm5tHoWjAFN4TLHYtqBpnvEhVaeyrWJYUxtXZR/Xd3kS
   +pXjXZtAIW9ppMJI2yj/QzHxYykHOZ5v+Q==
   -----END PGP MESSAGE-----

A.8.  Sample messages encrypted using Argon2

   These messages are the literal data "Hello, world!" encrypted using
   v1 SEIPD, with Argon2 and the passphrase "password", using different
   session key sizes.  In each example, the choice of symmetric cipher
   is the same in both the v4 SKESK packet and v1 SEIPD packet.  In all
   cases, the Argon2 parameters are t = 1, p = 4, and m = 21.

A.8.1.  v4 SKESK using Argon2 with AES-128

   -----BEGIN PGP MESSAGE-----
   Comment: Encrypted using AES with 128-bit key
   Comment: Session key: 01FE16BBACFD1E7B78EF3B865187374F

   wycEBwScUvg8J/leUNU1RA7N/zE2AQQVnlL8rSLPP5VlQsunlO+ECxHSPgGYGKY+
   YJz4u6F+DDlDBOr5NRQXt/KJIf4m4mOlKyC/uqLbpnLJZMnTq3o79GxBTdIdOzhH
   XfA3pqV4mTzF
   -----END PGP MESSAGE-----

A.8.2.  v4 SKESK using Argon2 with AES-192

   -----BEGIN PGP MESSAGE-----
   Comment: Encrypted using AES with 192-bit key
   Comment: Session key: 27006DAE68E509022CE45A14E569E91001C2955...
   Comment: Session key: ...AF8DFE194

   wy8ECAThTKxHFTRZGKli3KNH4UP4AQQVhzLJ2va3FG8/pmpIPd/H/mdoVS5VBLLw
   F9I+AdJ1Sw56PRYiKZjCvHg+2bnq02s33AJJoyBexBI4QKATFRkyez2gldJldRys
   LVg77Mwwfgl2n/d572WciAM=
   -----END PGP MESSAGE-----

A.8.3.  v4 SKESK using Argon2 with AES-256

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   -----BEGIN PGP MESSAGE-----
   Comment: Encrypted using AES with 256-bit key
   Comment: Session key: BBEDA55B9AAE63DAC45D4F49D89DACF4AF37FEF
   Comment: Session key: ...C13BAB2F1F8E18FB74580D8B0

   wzcECQS4eJUgIG/3mcaILEJFpmJ8AQQVnZ9l7KtagdClm9UaQ/Z6M/5roklSGpGu
   623YmaXezGj80j4B+Ku1sgTdJo87X1Wrup7l0wJypZls21Uwd67m9koF60eefH/K
   95D1usliXOEm8ayQJQmZrjf6K6v9PWwqMQ==
   -----END PGP MESSAGE-----

Appendix B.  Acknowledgements

   Thanks to the openpgp design team for working on this document to
   prepare it for working group consumption: Stephen Farrell, Daniel
   Kahn Gillmor, Daniel Huigens, Jeffrey Lau, Yutaka Niibe, Justus
   Winter and Paul Wouters.

   Thanks to Werner Koch for the early work on rfc4880bis and Andrey
   Jivsov for [RFC6637].

   This document also draws on much previous work from a number of other
   authors, including: Derek Atkins, Charles Breed, Dave Del Torto, Marc
   Dyksterhouse, Gail Haspert, Gene Hoffman, Paul Hoffman, Ben Laurie,
   Raph Levien, Colin Plumb, Will Price, David Shaw, William Stallings,
   Mark Weaver, and Philip R. Zimmermann.

Authors' Addresses

   Paul Wouters (editor)
   Aiven
   Email: paul.wouters@aiven.io

   Daniel Huigens
   Proton AG
   Email: d.huigens@protonmail.com

   Justus Winter
   Sequoia-PGP
   Email: justus@sequoia-pgp.org

   Yutaka Niibe
   FSIJ
   Email: gniibe@fsij.org

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