Internet Engineering Task Force (IETF) P. Wouters, Ed.
Request for Comments: 9580 Aiven
Obsoletes: 4880, 5581, 6637 D. Huigens
Category: Standards Track Proton AG
ISSN: 2070-1721 J. Winter
Sequoia PGP
Y. Niibe
FSIJ
July 2024
OpenPGP
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 RFCs 4880 ("OpenPGP Message Format"), 5581
("The Camellia Cipher in OpenPGP"), and 6637 ("Elliptic Curve
Cryptography (ECC) in OpenPGP").
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
Internet Standards is available in Section 2 of RFC 7841.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
https://www.rfc-editor.org/info/rfc9580.
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Table of Contents
1. Introduction
1.1. Terms
2. General Functions
2.1. Confidentiality via Encryption
2.2. Authentication via Digital Signature
2.3. Compression
2.4. Conversion to Base64
2.5. Signature-Only Applications
3. Data Element Formats
3.1. Scalar Numbers
3.2. Multiprecision Integers
3.2.1. Using MPIs to Encode Other Data
3.3. Key IDs and Fingerprints
3.4. Text
3.5. Time Fields
3.6. Keyrings
3.7. String-to-Key (S2K) Specifier
3.7.1. S2K Specifier Types
3.7.1.1. Simple S2K
3.7.1.2. Salted S2K
3.7.1.3. Iterated and Salted S2K
3.7.1.4. Argon2
3.7.2. S2K Usage
3.7.2.1. Secret Key Encryption
3.7.2.2. Symmetric Key Message Encryption
4. Packet Syntax
4.1. Overview
4.2. Packet Headers
4.2.1. OpenPGP Format Packet Lengths
4.2.1.1. 1-Octet Lengths
4.2.1.2. 2-Octet Lengths
4.2.1.3. 5-Octet Lengths
4.2.1.4. Partial Body Lengths
4.2.2. Legacy Format Packet Lengths
4.2.3. Packet Length Examples
4.3. Packet Criticality
5. Packet Types
5.1. Public Key Encrypted Session Key Packet (Type ID 1)
5.1.1. Version 3 Public Key Encrypted Session Key Packet
Format
5.1.2. Version 6 Public Key Encrypted Session Key Packet
Format
5.1.3. Algorithm-Specific Fields for RSA Encryption
5.1.4. Algorithm-Specific Fields for Elgamal Encryption
5.1.5. Algorithm-Specific Fields for ECDH Encryption
5.1.6. Algorithm-Specific Fields for X25519 Encryption
5.1.7. Algorithm-Specific Fields for X448 Encryption
5.1.8. Notes on PKESK
5.2. Signature Packet (Type ID 2)
5.2.1. Signature Types
5.2.1.1. Binary Signature (Type ID 0x00) of a Document
5.2.1.2. Text Signature (Type ID 0x01) of a Canonical
Document
5.2.1.3. Standalone Signature (Type ID 0x02)
5.2.1.4. Generic Certification Signature (Type ID 0x10) of a
User ID and Public Key Packet
5.2.1.5. Persona Certification Signature (Type ID 0x11) of a
User ID and Public Key Packet
5.2.1.6. Casual Certification Signature (Type ID 0x12) of a
User ID and Public Key Packet
5.2.1.7. Positive Certification Signature (Type ID 0x13) of
a User ID and Public Key Packet
5.2.1.8. Subkey Binding Signature (Type ID 0x18)
5.2.1.9. Primary Key Binding Signature (Type ID 0x19)
5.2.1.10. Direct Key Signature (Type ID 0x1F)
5.2.1.11. Key Revocation Signature (Type ID 0x20)
5.2.1.12. Subkey Revocation Signature (Type ID 0x28)
5.2.1.13. Certification Revocation Signature (Type ID 0x30)
5.2.1.14. Timestamp Signature (Type ID 0x40)
5.2.1.15. Third-Party Confirmation Signature (Type ID 0x50)
5.2.1.16. Reserved (Type ID 0xFF)
5.2.2. Version 3 Signature Packet Format
5.2.3. Versions 4 and 6 Signature Packet Formats
5.2.3.1. Algorithm-Specific Fields for RSA Signatures
5.2.3.2. Algorithm-Specific Fields for DSA or ECDSA
Signatures
5.2.3.3. Algorithm-Specific Fields for EdDSALegacy
Signatures (Deprecated)
5.2.3.4. Algorithm-Specific Fields for Ed25519 Signatures
5.2.3.5. Algorithm-Specific Fields for Ed448 Signatures
5.2.3.6. Notes on Signatures
5.2.3.7. Signature Subpacket Specification
5.2.3.8. Signature Subpacket Types
5.2.3.9. Notes on Subpackets
5.2.3.10. Notes on Self-Signatures
5.2.3.11. Signature Creation Time
5.2.3.12. Issuer Key ID
5.2.3.13. Key Expiration Time
5.2.3.14. Preferred Symmetric Ciphers for v1 SEIPD
5.2.3.15. Preferred AEAD Ciphersuites
5.2.3.16. Preferred Hash Algorithms
5.2.3.17. Preferred Compression Algorithms
5.2.3.18. Signature Expiration Time
5.2.3.19. Exportable Certification
5.2.3.20. Revocable
5.2.3.21. Trust Signature
5.2.3.22. Regular Expression
5.2.3.23. Revocation Key (Deprecated)
5.2.3.24. Notation Data
5.2.3.25. Key Server Preferences
5.2.3.26. Preferred Key Server
5.2.3.27. Primary User ID
5.2.3.28. Policy URI
5.2.3.29. Key Flags
5.2.3.30. Signer's User ID
5.2.3.31. Reason for Revocation
5.2.3.32. Features
5.2.3.33. Signature Target
5.2.3.34. Embedded Signature
5.2.3.35. Issuer Fingerprint
5.2.3.36. Intended Recipient Fingerprint
5.2.4. Computing Signatures
5.2.4.1. Notes about Signature Computation
5.2.5. Malformed and Unknown Signatures
5.3. Symmetric Key Encrypted Session Key Packet (Type ID 3)
5.3.1. Version 4 Symmetric Key Encrypted Session Key Packet
Format
5.3.2. Version 6 Symmetric Key Encrypted Session Key Packet
Format
5.4. One-Pass Signature Packet (Type ID 4)
5.5. Key Material Packets
5.5.1. Key Packet Variants
5.5.1.1. Public Key Packet (Type ID 6)
5.5.1.2. Public Subkey Packet (Type ID 14)
5.5.1.3. Secret Key Packet (Type ID 5)
5.5.1.4. Secret Subkey Packet (Type ID 7)
5.5.2. Public Key Packet Formats
5.5.2.1. Version 3 Public Keys
5.5.2.2. Version 4 Public Keys
5.5.2.3. Version 6 Public Keys
5.5.3. Secret Key Packet Formats
5.5.4. Key IDs and Fingerprints
5.5.4.1. Version 3 Key ID and Fingerprint
5.5.4.2. Version 4 Key ID and Fingerprint
5.5.4.3. Version 6 Key ID and Fingerprint
5.5.5. Algorithm-Specific Parts of Keys
5.5.5.1. Algorithm-Specific Part for RSA Keys
5.5.5.2. Algorithm-Specific Part for DSA Keys
5.5.5.3. Algorithm-Specific Part for Elgamal Keys
5.5.5.4. Algorithm-Specific Part for ECDSA Keys
5.5.5.5. Algorithm-Specific Part for EdDSALegacy Keys
(Deprecated)
5.5.5.6. Algorithm-Specific Part for ECDH Keys
5.5.5.7. Algorithm-Specific Part for X25519 Keys
5.5.5.8. Algorithm-Specific Part for X448 Keys
5.5.5.9. Algorithm-Specific Part for Ed25519 Keys
5.5.5.10. Algorithm-Specific Part for Ed448 Keys
5.6. Compressed Data Packet (Type ID 8)
5.7. Symmetrically Encrypted Data Packet (Type ID 9)
5.8. Marker Packet (Type ID 10)
5.9. Literal Data Packet (Type ID 11)
5.9.1. Special Filename _CONSOLE (Deprecated)
5.10. Trust Packet (Type ID 12)
5.11. User ID Packet (Type ID 13)
5.12. User Attribute Packet (Type ID 17)
5.12.1. Image Attribute Subpacket
5.13. Symmetrically Encrypted and Integrity Protected Data Packet
(Type ID 18)
5.13.1. Version 1 Symmetrically Encrypted and Integrity
Protected Data Packet Format
5.13.2. Version 2 Symmetrically Encrypted and Integrity
Protected Data Packet Format
5.13.3. EAX Mode
5.13.4. OCB Mode
5.13.5. GCM Mode
5.14. Padding Packet (Type ID 21)
6. Base64 Conversions
6.1. Optional Checksum
6.1.1. An Implementation of the CRC24 in "C"
6.2. Forming ASCII Armor
6.2.1. Armor Header Line
6.2.2. Armor Headers
6.2.2.1. "Version" Armor Header
6.2.2.2. "Comment" Armor Header
6.2.2.3. "Hash" Armor Header
6.2.2.4. "Charset" Armor Header
6.2.3. Armor Tail Line
7. Cleartext Signature Framework
7.1. Cleartext Signed Message Structure
7.2. Dash-Escaped Text
7.3. Issues with the Cleartext Signature Framework
8. Regular Expressions
9. Constants
9.1. Public Key Algorithms
9.2. ECC Curves for OpenPGP
9.2.1. Curve-Specific Wire Formats
9.3. Symmetric Key Algorithms
9.4. Compression Algorithms
9.5. Hash Algorithms
9.6. AEAD Algorithms
10. Packet Sequence Composition
10.1. Transferable Public Keys
10.1.1. OpenPGP Version 6 Certificate Structure
10.1.2. OpenPGP Version 6 Revocation Certificate
10.1.3. OpenPGP Version 4 Certificate Structure
10.1.4. OpenPGP Version 3 Key Structure
10.1.5. Common Requirements
10.2. Transferable Secret Keys
10.3. OpenPGP Messages
10.3.1. Unwrapping Encrypted and Compressed Messages
10.3.2. Additional Constraints on Packet Sequences
10.3.2.1. Packet Versions in Encrypted Messages
10.3.2.2. Packet Versions in Signatures
10.4. Detached Signatures
11. Elliptic Curve Cryptography
11.1. ECC Curves
11.2. EC Point Wire Formats
11.2.1. SEC1 EC Point Wire Format
11.2.2. Prefixed Native EC Point Wire Format
11.2.3. Notes on EC Point Wire Formats
11.3. EC Scalar Wire Formats
11.3.1. EC Octet String Wire Format
11.3.2. EC Prefixed Octet String Wire Format
11.4. Key Derivation Function
11.5. ECDH Algorithm
11.5.1. ECDH Parameters
12. Notes on Algorithms
12.1. PKCS#1 Encoding in OpenPGP
12.1.1. EME-PKCS1-v1_5-ENCODE
12.1.2. EME-PKCS1-v1_5-DECODE
12.1.3. EMSA-PKCS1-v1_5
12.2. Symmetric Algorithm Preferences
12.2.1. Plaintext
12.3. Other Algorithm Preferences
12.3.1. Compression Preferences
12.3.1.1. Uncompressed
12.3.2. Hash Algorithm Preferences
12.4. RSA
12.5. DSA
12.6. Elgamal
12.7. EdDSA
12.8. Reserved Algorithm IDs
12.9. CFB Mode
12.10. Private or Experimental Parameters
12.11. Meta Considerations for Expansion
13. Security Considerations
13.1. SHA-1 Collision Detection
13.2. Advantages of Salted Signatures
13.3. Elliptic Curve Side Channels
13.4. Risks of a Quick Check Oracle
13.5. Avoiding Leaks from PKCS#1 Errors
13.6. Fingerprint Usability
13.7. Avoiding Ciphertext Malleability
13.8. Secure Use of the v2 SEIPD Session-Key-Reuse Feature
13.9. Escrowed Revocation Signatures
13.10. Random Number Generation and Seeding
13.11. Traffic Analysis
13.12. Surreptitious Forwarding
13.13. Hashed vs. Unhashed Subpackets
13.14. Malicious Compressed Data
14. Implementation Considerations
14.1. Constrained Legacy Fingerprint Storage for Version 6 Keys
15. IANA Considerations
15.1. Renamed Protocol Group
15.2. Renamed and Updated Registries
15.3. Removed Registry
15.4. Added Registries
15.5. Registration Policies
15.5.1. Registries That Use RFC Required
15.6. Designated Experts
15.6.1. Key and Signature Versions
15.6.2. Encryption Versions
15.6.3. Algorithms
15.6.3.1. Elliptic Curve Algorithms
15.6.3.2. Symmetric Key Algorithms
15.6.3.3. Hash Algorithms
16. References
16.1. Normative References
16.2. Informative References
Appendix A. Test Vectors
A.1. Sample Version 4 Ed25519Legacy Key
A.2. Sample Version 4 Ed25519Legacy Signature
A.3. Sample Version 6 Certificate (Transferable Public Key)
A.3.1. Hashed Data Stream for Signature Verification
A.4. Sample Version 6 Secret Key (Transferable Secret Key)
A.5. Sample Locked Version 6 Secret Key (Transferable Secret
Key)
A.5.1. Intermediate Data for Locked Primary Key
A.5.2. Intermediate Data for Locked Subkey
A.6. Sample Cleartext Signed Message
A.7. Sample Inline-Signed Message
A.8. Sample X25519-AEAD-OCB Encryption and Decryption
A.8.1. Sample Version 6 Public Key Encrypted Session Key
Packet
A.8.2. X25519 Encryption/Decryption of the Session Key
A.8.3. Sample v2 SEIPD Packet
A.8.4. Decryption of Data
A.8.5. Complete X25519-AEAD-OCB Encrypted Packet Sequence
A.9. Sample AEAD-EAX Encryption and Decryption
A.9.1. Sample Version 6 Symmetric Key Encrypted Session Key
Packet
A.9.2. Starting AEAD-EAX Decryption of the Session Key
A.9.3. Sample v2 SEIPD Packet
A.9.4. Decryption of Data
A.9.5. Complete AEAD-EAX Encrypted Packet Sequence
A.10. Sample AEAD-OCB Encryption and Decryption
A.10.1. Sample Version 6 Symmetric Key Encrypted Session Key
Packet
A.10.2. Starting AEAD-OCB Decryption of the Session Key
A.10.3. Sample v2 SEIPD Packet
A.10.4. Decryption of Data
A.10.5. Complete AEAD-OCB Encrypted Packet Sequence
A.11. Sample AEAD-GCM Encryption and Decryption
A.11.1. Sample Version 6 Symmetric Key Encrypted Session Key
Packet
A.11.2. Starting AEAD-GCM Decryption of the Session Key
A.11.3. Sample v2 SEIPD Packet
A.11.4. Decryption of Data
A.11.5. Complete AEAD-GCM Encrypted Packet Sequence
A.12. Sample Messages Encrypted Using Argon2
A.12.1. V4 SKESK Using Argon2 with AES-128
A.12.2. V4 SKESK Using Argon2 with AES-192
A.12.3. V4 SKESK Using Argon2 with AES-256
Appendix B. Upgrade Guidance (Adapting Implementations from RFCs
4880 and 6637)
B.1. Terminology Changes
Appendix C. Errata Addressed by This Document
Acknowledgements
Authors' Addresses
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 [RFC4880]
("OpenPGP Message Format"), which is a revision of [RFC2440], which
itself replaces [RFC1991] ("PGP Message Exchange Formats").
This document obsoletes [RFC4880] (OpenPGP), [RFC5581] (Camellia in
OpenPGP), and [RFC6637] (Elliptic Curves in OpenPGP). At the time of
writing, this document incorporates all outstanding verified errata,
which are listed in Appendix C.
Software that has already implemented those previous specifications
may want to review Appendix B for pointers to what has changed.
1.1. Terms
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].
Some terminology used in this document has been improved from
previous versions of the OpenPGP specification. See Appendix B.1 for
more details.
2. General Functions
OpenPGP provides data confidentiality and integrity for messages and
data files by using public key and/or symmetric encryption and
digital signatures. It provides formats for encoding and
transferring encrypted and/or signed messages. In addition, OpenPGP
provides functionality for encoding and transferring keys and
certificates, though key storage and management are beyond the scope
of this document.
2.1. Confidentiality via Encryption
OpenPGP combines symmetric key encryption and (optionally) public key
encryption to provide confidentiality. When using public keys, first
the object is encrypted using a symmetric key 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.
2. The sending OpenPGP implementation generates a random session key
for this message.
3. The session key is encrypted using each recipient's public key.
These "encrypted session keys" start the message.
4. The sending OpenPGP implementation optionally compresses the
message and then encrypts it using a message key derived from the
session key. The encrypted message forms the remainder of the
OpenPGP Message.
5. The receiving OpenPGP implementation decrypts the session key
using the recipient's private key.
6. The receiving OpenPGP implementation decrypts the message using
the message key derived from the session key. If the message was
compressed, it will be decompressed.
When using symmetric key encryption, a similar process as described
above is used, but the session key is encrypted with a symmetric
algorithm derived 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 message key derived from the 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 cryptographic hash function and a public
key algorithm capable of signing. The sequence is as follows:
1. The sender creates a message.
2. The sending implementation generates a hash digest of the
message.
3. The sending implementation generates a signature from the hash
digest using the sender's private key.
4. The signature is attached to or transmitted alongside the
message.
5. The receiving implementation obtains a copy of the message and
the message signature.
6. The receiving implementation generates a new hash digest for the
received message and verifies it using the message's signature.
If the verification is successful, the message is accepted as
authentic.
2.3. Compression
An OpenPGP implementation MAY support the compression of data. Many
existing OpenPGP Messages are compressed. Implementers, such as
those working on constrained implementations that do not want to
support compression, might want to consider at least implementing
decompression.
2.4. Conversion to Base64
OpenPGP's underlying representation for encrypted messages,
signatures, keys, and certificates is a stream of arbitrary octets.
Some systems only permit the use of blocks consisting of 7-bit,
printable text. For transporting OpenPGP's raw binary octets through
channels that are not safe to transport raw binary data, a printable
encoding of these binary octets is defined. The raw 8-bit binary
octet stream can be converted to a stream of printable ASCII
characters using base64 encoding in a format called "ASCII Armor"
(see Section 6).
Implementations SHOULD support base64 conversions.
2.5. Signature-Only Applications
OpenPGP is designed for applications that use both encryption and
signatures, but there are a number of use cases that only require 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 support.
3. Data Element Formats
This section describes the data elements used by OpenPGP.
3.1. Scalar Numbers
Scalar numbers are unsigned and always stored in big-endian format.
Using n[k] to refer to the kth octet being interpreted, the value of
a 2-octet scalar is ((n[0] << 8) + n[1]). The value of a 4-octet
scalar is ((n[0] << 24) + (n[1] << 16) + (n[2] << 8) + n[3]).
3.2. Multiprecision Integers
Multiprecision Integers (MPIs) are unsigned integers used to hold
large integers such as the ones used in cryptographic calculations.
An MPI consists of two pieces: a 2-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:
(Note that all numbers in the octet strings identified by square
brackets 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 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 version 6 Key, Signature, or Public Key Encrypted Session Key
(PKESK) packet, the implementation MUST check that the encoded
length matches the length starting from the most significant non-
zero bit; if it doesn't match, reject the packet as malformed.
* Unused bits of an MPI MUST be zero.
3.2.1. Using MPIs to Encode Other Data
Note that in some places, MPIs are used to encode non-integer data,
such as an elliptic curve (EC) point (see Section 11.2) or an octet
string of known, fixed length (see Section 11.3). The wire
representation is the same: 2 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 and Fingerprints
A Key ID is an 8-octet scalar that identifies a key. Implementations
SHOULD NOT assume that Key IDs are unique. A fingerprint is more
likely to be unique than a Key ID. The fingerprint and Key ID of a
key are calculated differently according to the version of the key.
Section 5.5.4 describes how Key IDs and Fingerprints are formed.
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 4-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.
Typically, a keyring is simply a sequential list of keys, but it may
be any suitable database. It is beyond the scope of this
specification to discuss the details of keyrings or other databases.
3.7. String-to-Key (S2K) Specifier
A string-to-key (S2K) Specifier is used to convert a passphrase
string into a symmetric key encryption/decryption key. Passphrases
requiring use of S2K conversion are currently used in two places: to
encrypt the secret part of private keys and for symmetrically
encrypted messages.
3.7.1. S2K Specifier Types
There are four types of S2K Specifiers currently specified and some
reserved values:
+=========+==============+===============+==============+===========+
| ID | S2K Type | S2K Field | Generate? | Reference |
| | | Size | | |
| | | (Octets) | | |
+=========+==============+===============+==============+===========+
| 0 | Simple S2K | 2 | No | Section |
| | | | | 3.7.1.1 |
+---------+--------------+---------------+--------------+-----------+
| 1 | Salted S2K | 10 | Only when | Section |
| | | | string is | 3.7.1.2 |
| | | | high entropy | |
+---------+--------------+---------------+--------------+-----------+
| 2 | Reserved | - | No | |
| | value | | | |
+---------+--------------+---------------+--------------+-----------+
| 3 | Iterated and | 11 | Yes | Section |
| | Salted S2K | | | 3.7.1.3 |
+---------+--------------+---------------+--------------+-----------+
| 4 | Argon2 | 20 | Yes | Section |
| | | | | 3.7.1.4 |
+---------+--------------+---------------+--------------+-----------+
| 100-110 | Private or | - | As | |
| | Experimental | | appropriate | |
| | Use | | | |
+---------+--------------+---------------+--------------+-----------+
Table 1: OpenPGP String-to-Key (S2K) Types Registry
The S2K Specifier Types are described in the subsections below. If
"Yes" is not present in the "Generate?" column, the S2K entry is used
only for reading in backward-compatibility mode and SHOULD NOT be
used to generate new output.
3.7.1.1. Simple S2K
Simple S2K directly hashes the string to produce the key data. This
hashing is done as shown below.
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 depends on the cipher the session key will be used with) 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.
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, the first instance has no preloading, the second gets preloaded
with 1 octet of zero, the third is preloaded with 2 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 a 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, and any excess octets
on the right are discarded.
3.7.1.2. Salted S2K
Salted S2K 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
Iterated and Salted S2K includes both a salt and an octet count. The
salt is combined with the passphrase, and the resulting value is
repeated and then hashed. 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 1-octet coded value
The count is coded into a 1-octet number using the following formula:
#define EXPBIAS 6
count = ((Int32)16 + (c & 15)) << ((c >> 4) + EXPBIAS);
The above formula is described in [C99], where "Int32" is a type for
a 32-bit integer, and the variable "c" is the coded count, octet 10.
Iterated and 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 the same as the other
S2K algorithms, depending on how many octets of key data are needed.
Then the salt, followed by the passphrase data, is repeatedly
processed as input to each hash context until the number of octets
specified by the octet count has been hashed. The input is truncated
to the octet count, except if the octet count is less than the
initial size of the salt plus passphrase. That is, at least one copy
of the full salt plus passphrase will be provided as input to each
hash context regardless of the octet count. After the hashing is
done, the key data is produced from the hash digest(s), which is the
same way it is produced for the other S2K algorithms.
3.7.1.4. Argon2
This S2K method hashes the passphrase using Argon2, as 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: 1-octet number of passes t
Octet 18: 1-octet degree of parallelism p
Octet 19: 1-octet encoded_m, specifying the exponent of
the memory size
The salt SHOULD be unique for each passphrase.
The number of passes t and the degree of parallelism p MUST be non-
zero.
The memory size m is 2^(encoded_m) kibibytes (KiB) of RAM. 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 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; otherwise, round
down (keeping in mind that m must be at least 8*p).
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. S2K 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
initialization vector (IV) reuse (see Section 5.3). Therefore, when
generating an S2K Specifier, an implementation MUST NOT use Simple
S2K. Furthermore, an implementation SHOULD NOT generate a Salted S2K
unless the implementation knows that the input 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. If Argon2 is not
available, Iterated and Salted S2K MAY be used if care is taken to
use a high octet count and a strong passphrase. However, this method
does not provide memory hardness, unlike Argon2.
3.7.2.1. Secret Key Encryption
The first octet following the public key material in a Secret Key
packet (Section 5.5.3) indicates whether and how the secret key
material is passphrase protected. This first octet is known as the
"S2K usage octet".
If the S2K usage octet is zero, the secret key data is unprotected.
If it is non-zero, it describes how to use a passphrase to unlock the
secret key.
Implementations predating [RFC2440] indicated a protected key by
storing a Symmetric Cipher Algorithm ID (see Section 9.3) in the S2K
usage octet. In this case, the MD5 hash function was always used to
convert the passphrase to a key for the specified cipher algorithm.
Later implementations indicate a protected secret key by storing one
of the special values 253 (AEAD), 254 (CFB), or 255 (MalleableCFB) in
the S2K usage octet. The S2K usage octet is then followed
immediately by a set of fields that describe how to convert a
passphrase to a symmetric key that can unlock the secret material,
plus other parameters relevant to the type of encryption used.
The wire format fields also differ based on the version of the
enclosing OpenPGP packet. The table below, indexed by the S2K usage
octet, summarizes the specifics described in Section 5.5.3.
In the table below, check(x) means the "2-octet checksum", which is
the sum of all octets in x mod 65536. The info and packetprefix
parameters are described in detail in Section 5.5.3. Note that the
"Generate?" column header has been shortened to "Gen?" here.
+=========+============+============+==========================+====+
|S2K Usage|Shorthand |Encryption |Encryption |Gen?|
|Octet | |Parameter | | |
| | |Fields | | |
+=========+============+============+==========================+====+
|0 |Unprotected |- |*v3 or v4 keys:* |Yes |
| | | |[cleartext secrets || | |
| | | |check(secrets)] | |
| | | |*v6 keys:* [cleartext | |
| | | |secrets] | |
+---------+------------+------------+--------------------------+----+
|Known |LegacyCFB |IV |CFB(MD5(passphrase), |No |
|symmetric| | |secrets || check(secrets))| |
|cipher | | | | |
|algo ID | | | | |
|(see | | | | |
|Section | | | | |
|9.3) | | | | |
+---------+------------+------------+--------------------------+----+
|253 |AEAD |params- |AEAD(HKDF(S2K(passphrase),|Yes |
| | |length |info), secrets, | |
| | |(*v6-only*),|packetprefix) | |
| | |cipher-algo,| | |
| | |AEAD-mode, | | |
| | |S2K- | | |
| | |specifier- | | |
| | |length | | |
| | |(*v6-only*),| | |
| | |S2K- | | |
| | |specifier, | | |
| | |nonce | | |
+---------+------------+------------+--------------------------+----+
|254 |CFB |params- |CFB(S2K(passphrase), |Yes |
| | |length |secrets || SHA1(secrets)) | |
| | |(*v6-only*),| | |
| | |cipher-algo,| | |
| | |S2K- | | |
| | |specifier- | | |
| | |length | | |
| | |(*v6-only*),| | |
| | |S2K- | | |
| | |specifier, | | |
| | |IV | | |
+---------+------------+------------+--------------------------+----+
|255 |MalleableCFB|cipher-algo,|CFB(S2K(passphrase), |No |
| | |S2K- |secrets || check(secrets))| |
| | |specifier, | | |
| | |IV | | |
+---------+------------+------------+--------------------------+----+
Table 2: OpenPGP Secret Key Encryption (S2K Usage Octet) Registry
When emitting a secret key (with or without passphrase protection),
an implementation MUST only produce data from a row with "Generate?"
marked as "Yes". Each row with "Generate?" marked as "No" is
described for backward compatibility (for reading version 4 and
earlier keys only) and MUST NOT be used to generate new output.
Version 6 secret keys using these formats MUST be rejected.
Note that compared to a version 4 secret key, the parameters of a
passphrase-protected version 6 secret key are stored with an
additional pair of length counts, each of which is 1 octet wide.
Argon2 is only used with Authenticated Encryption with Associated
Data (AEAD) (S2K usage octet 253). An implementation MUST NOT create
and MUST reject as malformed any Secret Key packet where the S2K
usage octet is not AEAD (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 (SKESK)
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 SKESK packets and PKESK packets. This allows
a message to be decrypted with either a passphrase or a public key
pair.
Implementations predating [RFC2440] always used the International
Data Encryption Algorithm (IDEA) with Simple S2K conversion when
encrypting a message with a symmetric algorithm; see Section 5.7.
IDEA 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
typically called packets. A packet is a chunk of data that has a
Type ID specifying its meaning. An OpenPGP Message, keyring,
certificate, detached signature, 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).
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 denotes the format of the rest of the
header, and it encodes the Packet Type ID, indicating the type of the
packet (see Section 5). The remainder of the packet header is the
length of the packet.
There are two packet formats: 1) the (current) OpenPGP packet format
specified by this document and its predecessors [RFC4880] and
[RFC2440] and 2) the Legacy packet format as used by implementations
predating any IETF specification of OpenPGP.
Note that the most significant bit is the leftmost bit, called "bit
7". A mask for this bit is 0x80 in hexadecimal.
+---------------+
Encoded Packet Type ID: |7 6 5 4 3 2 1 0|
+---------------+
OpenPGP format:
Bit 7 -- always one
Bit 6 -- always one
Bits 5 to 0 -- Packet Type ID
Legacy format:
Bit 7 -- always one
Bit 6 -- always zero
Bits 5 to 2 -- Packet Type ID
Bits 1 to 0 -- length-type
Bit 6 of the first octet of the packet header indicates whether the
packet is encoded in the OpenPGP or Legacy packet format. The Legacy
packet format MAY be used when consuming packets to facilitate
interoperability 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. This latter case
is extremely unlikely, as the Legacy packet format was obsoleted by
[RFC2440] in 1998.
An implementation that consumes and redistributes pre-existing
OpenPGP data (such as Transferable Public Keys) may encounter packets
framed with the Legacy packet format. Such an implementation MAY
either redistribute these packets in their Legacy format or transform
them to the current OpenPGP packet format before redistribution.
Note that Legacy format headers only have 4 bits for the Packet Type
ID and hence can only encode Packet Type IDs less than 16, whereas
the OpenPGP format headers can encode IDs as great as 63.
4.2.1. OpenPGP Format Packet Lengths
OpenPGP format packets have four possible ways of encoding length:
1. A 1-octet Body Length header encodes packet lengths of up to 191
octets.
2. A 2-octet Body Length header encodes packet lengths of 192 to
8383 octets.
3. A 5-octet Body Length header encodes packet lengths of up to
4,294,967,295 (0xFFFFFFFF) octets in length. (This actually
encodes a 4-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. 1-Octet Lengths
A 1-octet Body Length header encodes a length of 0 to 191 octets.
This type of length header is recognized because the 1-octet value is
less than 192. The body length is equal to:
bodyLen = 1st_octet;
4.2.1.2. 2-Octet Lengths
A 2-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:
bodyLen = ((1st_octet - 192) << 8) + (2nd_octet) + 192
4.2.1.3. 5-Octet Lengths
A 5-octet Body Length header consists of a single octet holding the
value 255, followed by a 4-octet scalar. The body length is equal
to:
bodyLen = (2nd_octet << 24) | (3rd_octet << 16) |
(4th_octet << 8) | 5th_octet
This basic set of 1-octet, 2-octet, and 5-octet lengths is also used
internally to some packets.
4.2.1.4. Partial Body Lengths
A Partial Body Length header is 1 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
1-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 (1-octet, 2-octet, 5-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,
whether they are 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
A zero in bit 6 of the first octet of the packet indicates a Legacy
packet format. Bits 1 and 0 of the first octet of a Legacy packet
are the "length-type" field. The meaning of length-type in Legacy
format packets is as follows:
0 The packet has a 1-octet length. The header is 2 octets long.
1 The packet has a 2-octet length. The header is 3 octets long.
2 The packet has a 4-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, it 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 that predates
support for [RFC2440].
4.2.3. Packet Length Examples
These examples show ways that OpenPGP format packets might encode the
packet body lengths.
* A packet body with length 100 may have its length encoded in one
octet: 0x64. This is followed by 100 octets of data.
* A packet body 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 body 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 2 octets of data;
* 0xE0, next 1 octet of data;
* 0xF0, next 65536 octets of data; and
* 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 Criticality
The Packet Type ID 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 10). On the other
hand, an unknown non-critical packet MUST be ignored.
Packets with Type IDs from 0 to 39 are critical. Packets with Type
IDs from 40 to 63 are non-critical.
5. Packet Types
The defined packet types are as follows:
+=======+==========+=====================+===========+===========+
| ID | Critical | Packet Type | Shorthand | Reference |
| | | Description | | |
+=======+==========+=====================+===========+===========+
| 0 | Yes | Reserved - this | | |
| | | Packet Type ID MUST | | |
| | | NOT be used | | |
+-------+----------+---------------------+-----------+-----------+
| 1 | Yes | Public Key | PKESK | Section |
| | | Encrypted Session | | 5.1 |
| | | Key Packet | | |
+-------+----------+---------------------+-----------+-----------+
| 2 | Yes | Signature Packet | SIG | Section |
| | | | | 5.2 |
+-------+----------+---------------------+-----------+-----------+
| 3 | Yes | Symmetric Key | SKESK | Section |
| | | Encrypted Session | | 5.3 |
| | | Key Packet | | |
+-------+----------+---------------------+-----------+-----------+
| 4 | Yes | One-Pass Signature | OPS | Section |
| | | Packet | | 5.4 |
+-------+----------+---------------------+-----------+-----------+
| 5 | Yes | Secret Key Packet | SECKEY | Section |
| | | | | 5.5.1.3 |
+-------+----------+---------------------+-----------+-----------+
| 6 | Yes | Public Key Packet | PUBKEY | Section |
| | | | | 5.5.1.1 |
+-------+----------+---------------------+-----------+-----------+
| 7 | Yes | Secret Subkey | SECSUBKEY | Section |
| | | Packet | | 5.5.1.4 |
+-------+----------+---------------------+-----------+-----------+
| 8 | Yes | Compressed Data | COMP | Section |
| | | Packet | | 5.6 |
+-------+----------+---------------------+-----------+-----------+
| 9 | Yes | Symmetrically | SED | Section |
| | | Encrypted Data | | 5.7 |
| | | Packet | | |
+-------+----------+---------------------+-----------+-----------+
| 10 | Yes | Marker Packet | MARKER | Section |
| | | | | 5.8 |
+-------+----------+---------------------+-----------+-----------+
| 11 | Yes | Literal Data Packet | LIT | Section |
| | | | | 5.9 |
+-------+----------+---------------------+-----------+-----------+
| 12 | Yes | Trust Packet | TRUST | Section |
| | | | | 5.10 |
+-------+----------+---------------------+-----------+-----------+
| 13 | Yes | User ID Packet | UID | Section |
| | | | | 5.11 |
+-------+----------+---------------------+-----------+-----------+
| 14 | Yes | Public Subkey | PUBSUBKEY | Section |
| | | Packet | | 5.5.1.2 |
+-------+----------+---------------------+-----------+-----------+
| 17 | Yes | User Attribute | UAT | Section |
| | | Packet | | 5.12 |
+-------+----------+---------------------+-----------+-----------+
| 18 | Yes | Symmetrically | SEIPD | Section |
| | | Encrypted and | | 5.13 |
| | | Integrity Protected | | |
| | | Data Packet | | |
+-------+----------+---------------------+-----------+-----------+
| 19 | Yes | Reserved (formerly | | Section |
| | | Modification | | 5.13.1 |
| | | Detection Code | | |
| | | Packet) | | |
+-------+----------+---------------------+-----------+-----------+
| 20 | Yes | Reserved | | |
+-------+----------+---------------------+-----------+-----------+
| 21 | Yes | Padding Packet | PADDING | Section |
| | | | | 5.14 |
+-------+----------+---------------------+-----------+-----------+
| 22-39 | Yes | Unassigned Critical | | |
| | | Packets | | |
+-------+----------+---------------------+-----------+-----------+
| 40-59 | No | Unassigned Non- | | |
| | | Critical Packets | | |
+-------+----------+---------------------+-----------+-----------+
| 60-63 | No | Private or | | |
| | | Experimental Use | | |
+-------+----------+---------------------+-----------+-----------+
Table 3: OpenPGP Packet Types Registry
The labels in the "Shorthand" column are used for compact reference
elsewhere in this document, and they may also be used by
implementations that provide debugging or inspection affordances for
streams of OpenPGP packets.
5.1. Public Key Encrypted Session Key Packet (Type ID 1)
Zero or more PKESK packets and/or SKESK packets (Section 5.3) precede
an encryption container (that is, a Symmetrically Encrypted and
Integrity Protected Data (SEIPD) packet or -- for historic data -- a
Symmetrically Encrypted Data (SED) 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 1-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.
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 10.3.2.1). Any new
version of the PKESK packet should be registered in the registry
established in Section 10.3.2.1.
5.1.1. Version 3 Public Key Encrypted Session Key Packet Format
A version 3 PKESK packet precedes a v1 SEIPD packet (see
Section 5.13.1). In historic data, it is sometimes found preceding a
deprecated SED packet; see Section 5.7. A v3 PKESK packet MUST NOT
precede a v2 SEIPD packet (see Section 10.3.2.1).
The v3 PKESK packet consists of:
* A 1-octet version number with value 3.
* An 8-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 1-octet number giving the public key algorithm used.
* A series of values comprising the encrypted session key. This is
algorithm specific and described below.
The public key encryption algorithm (described in subsequent
sections) is passed two values:
* The session key.
* The 1-octet algorithm identifier that specifies the symmetric key
encryption algorithm used to encrypt the v1 SEIPD packet described
in the following section.
5.1.2. Version 6 Public Key Encrypted Session Key Packet Format
A v6 PKESK packet precedes a v2 SEIPD packet (see Section 5.13.2). A
v6 PKESK packet MUST NOT precede a v1 SEIPD packet or a deprecated
SED packet (see Section 10.3.2.1).
The v6 PKESK packet consists of the following fields:
* A 1-octet version number with value 6.
* A 1-octet size of the following two fields. This size may be
zero, if the key version number field and the fingerprint field
are omitted for an "anonymous recipient" (see Section 5.1.8).
* A 1-octet key version number.
* 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.
* A 1-octet number giving the public key algorithm used.
* A series of values comprising the encrypted session key. This is
algorithm specific and described below.
The session key is encrypted according to the public key algorithm
used, as described below. No symmetric key encryption algorithm
identifier is passed to the public key algorithm for a v6 PKESK
packet, as it is included in the v2 SEIPD packet.
5.1.3. Algorithm-Specific Fields for RSA Encryption
* MPI of RSA-encrypted value m^e mod n.
To produce the value "m" in the above formula, first concatenate the
following values:
* The 1-octet algorithm identifier, if it was passed (in the case of
a v3 PKESK packet).
* The session key.
* A 2-octet checksum of the session key, equal to the sum of the
session key octets, modulo 65536.
Then, the above values are encoded using the PKCS#1 block encoding
EME-PKCS1-v1_5, as described in Step 2 in Section 7.2.1 of [RFC8017]
(see also Section 12.1.1). When decoding "m" during decryption, an
implementation should follow Step 3 in Section 7.2.2 of [RFC8017]
(see also Section 12.1.2).
Note that when an implementation forms several PKESK packets 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.
This defends against attacks such as those discussed in [HASTAD].
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.
To produce the value "m" in the above formula, first concatenate the
following values:
* The 1-octet algorithm identifier, if it was passed (in the case of
a v3 PKESK packet).
* The session key.
* A 2-octet checksum of the session key, equal to the sum of the
session key octets, modulo 65536.
Then, the above values are encoded using the PKCS#1 block encoding
EME-PKCS1-v1_5, as described in Step 2 in Section 7.2.1 of [RFC8017]
(see also Section 12.1.1). When decoding "m" during decryption, an
implementation should follow Step 3 in Section 7.2.2 of [RFC8017]
(see also Section 12.1.2).
Note that when an implementation forms several PKESK packets 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.
This defends against attacks such as those discussed in [HASTAD].
An implementation MUST NOT generate ElGamal v6 PKESK packets.
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 1-octet size, followed by a symmetric key encoded using the
method described in Section 11.5.
5.1.6. Algorithm-Specific Fields for X25519 Encryption
* 32 octets representing an ephemeral X25519 public key.
* A 1-octet size of the following fields.
* The 1-octet algorithm identifier, if it was passed (in the case of
a v3 PKESK packet).
* The 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 HMAC-based Key
Derivation Function (HKDF) [RFC5869] is then used with SHA256
[RFC6234] and an info parameter of "OpenPGP X25519" and no salt. The
input of HKDF is the concatenation of the following three values:
* 32 octets of the ephemeral X25519 public key from this packet.
* 32 octets of the recipient public key material.
* 32 octets of the shared secret.
The key produced from HKDF is used to encrypt the session key with
AES-128 key wrap, as defined in [RFC3394].
Note that unlike Elliptic Curve Diffie-Hellman (ECDH), no checksum or
padding are appended to the session key before key wrapping.
Finally, note that unlike the other public key algorithms, in the
case of a v3 PKESK packet, the symmetric algorithm ID is not
encrypted. Instead, it is prepended to the encrypted session key in
plaintext. In this case, the symmetric algorithm used MUST be AES-
128, AES-192, or AES-256 (algorithm IDs 7, 8, or 9, respectively).
5.1.7. Algorithm-Specific Fields for X448 Encryption
* 56 octets representing an ephemeral X448 public key.
* A 1-octet size of the following fields.
* The 1-octet algorithm identifier, if it was passed (in the case of
a v3 PKESK packet).
* The encrypted session key.
See Section 6.2 of [RFC7748] for more details on the computation of
the ephemeral public key and the shared secret. HKDF [RFC5869] is
then used with SHA512 [RFC6234] and an info parameter of "OpenPGP
X448" and no salt. The input of HKDF is the concatenation of the
following three values:
* 56 octets of the ephemeral X448 public key from this packet.
* 56 octets of the recipient public key material.
* 56 octets of the shared secret.
The key produced from HKDF is used to encrypt the session key with
AES-256 key wrap, as defined in [RFC3394].
Note that unlike ECDH, no checksum or padding are appended to the
session key before key wrapping. Finally, note that unlike the other
public key algorithms, in the case of a v3 PKESK packet, the
symmetric algorithm ID is not encrypted. Instead, it is prepended to
the encrypted session key in plaintext. In this case, the symmetric
algorithm used MUST be AES-128, AES-192, or AES-256 (algorithm ID 7,
8, or 9).
5.1.8. Notes on PKESK
An implementation MAY accept or use a Key ID of all zeros, or an
omitted 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 (Type ID 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. Any new Signature packet version should be
registered in the registry established in Section 10.3.2.2.
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. See Section 10.3.2.2 for more details about packet
version correspondence between keys and signatures.
5.2.1. Signature Types
There are a number of possible meanings for a signature, which are
indicated by the Signature Type ID in any given signature. Please
note that the vagueness of these meanings is not a flaw but rather 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.
+======+====================================+==================+
| ID | Name | Reference |
+======+====================================+==================+
| 0x00 | Binary Signature | Section 5.2.1.1 |
+------+------------------------------------+------------------+
| 0x01 | Text Signature | Section 5.2.1.2 |
+------+------------------------------------+------------------+
| 0x02 | Standalone Signature | Section 5.2.1.3 |
+------+------------------------------------+------------------+
| 0x10 | Generic Certification Signature | Section 5.2.1.4 |
+------+------------------------------------+------------------+
| 0x11 | Persona Certification Signature | Section 5.2.1.5 |
+------+------------------------------------+------------------+
| 0x12 | Casual Certification Signature | Section 5.2.1.6 |
+------+------------------------------------+------------------+
| 0x13 | Positive Certification Signature | Section 5.2.1.7 |
+------+------------------------------------+------------------+
| 0x18 | Subkey Binding Signature | Section 5.2.1.8 |
+------+------------------------------------+------------------+
| 0x19 | Primary Key Binding Signature | Section 5.2.1.9 |
+------+------------------------------------+------------------+
| 0x1F | Direct Key Signature | Section 5.2.1.10 |
+------+------------------------------------+------------------+
| 0x20 | Key Revocation Signature | Section 5.2.1.11 |
+------+------------------------------------+------------------+
| 0x28 | Subkey Revocation Signature | Section 5.2.1.12 |
+------+------------------------------------+------------------+
| 0x30 | Certification Revocation Signature | Section 5.2.1.13 |
+------+------------------------------------+------------------+
| 0x40 | Timestamp Signature | Section 5.2.1.14 |
+------+------------------------------------+------------------+
| 0x50 | Third-Party Confirmation Signature | Section 5.2.1.15 |
+------+------------------------------------+------------------+
| 0xFF | Reserved | Section 5.2.1.16 |
+------+------------------------------------+------------------+
Table 4: OpenPGP Signature Types Registry
The meanings of each signature type are described in the subsections
below.
5.2.1.1. Binary Signature (Type ID 0x00) of a Document
This means the signer owns it, created it, or certifies that it has
not been modified.
5.2.1.2. Text Signature (Type ID 0x01) of a Canonical Document
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>.
5.2.1.3. Standalone Signature (Type ID 0x02)
This signature is a signature of only its own subpacket contents. It
is calculated identically to a signature over a zero-length binary
document. Version 3 Standalone signatures MUST NOT be generated and
MUST be ignored.
5.2.1.4. Generic Certification Signature (Type ID 0x10) 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.
5.2.1.5. Persona Certification Signature (Type ID 0x11) 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.
5.2.1.6. Casual Certification Signature (Type ID 0x12) of a User ID and
Public Key Packet
The issuer of this certification has done some casual verification of
the claim of identity.
5.2.1.7. Positive Certification Signature (Type ID 0x13) 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 generic
(Type ID 0x10) certifications. Some implementations can issue
0x11-0x13 certifications, but few differentiate between the types.
5.2.1.8. Subkey Binding Signature (Type ID 0x18)
This signature is a statement by the top-level signing key,
indicating 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.
5.2.1.9. Primary Key Binding Signature (Type ID 0x19)
This signature is a statement by a signing subkey, indicating that it
is owned by the primary key. This signature is calculated the same
way as a Subkey Binding signature (Type ID 0x18): directly on the
primary key and subkey, and not on any User ID or other packets.
5.2.1.10. Direct Key Signature (Type ID 0x1F)
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 the (deprecated) Revocation Key
subpacket. 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.
5.2.1.11. Key Revocation Signature (Type ID 0x20)
This 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.
5.2.1.12. Subkey Revocation Signature (Type ID 0x28)
This signature is calculated directly on the primary key and 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.
5.2.1.13. Certification Revocation Signature (Type ID 0x30)
This signature revokes an earlier User ID certification signature
(Type IDs 0x10 through 0x13) or Direct Key signature (Type ID 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 certification that it revokes, and it should
have a later creation date than that certification.
5.2.1.14. Timestamp Signature (Type ID 0x40)
This signature is only meaningful for the timestamp contained in it.
5.2.1.15. Third-Party Confirmation Signature (Type ID 0x50)
This signature is a signature over another OpenPGP Signature packet.
It is analogous to a notary seal on the signed data. A Third-Party
Confirmation signature SHOULD include a Signature Target subpacket
that identifies the confirmed signature.
5.2.1.16. Reserved (Type ID 0xFF)
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.
5.2.2. Version 3 Signature Packet Format
The body of a version 3 Signature packet contains:
* A 1-octet version number with value 3.
* A 1-octet length of the following hashed material; it MUST be 5:
- A 1-octet Signature Type ID.
- A 4-octet creation time.
* An 8-octet Key ID of the signer.
* A 1-octet public key algorithm.
* A 1-octet hash algorithm.
* A 2-octet field holding left 16 bits of the signed hash value.
* One or more MPIs comprising the signature. This portion is
algorithm specific, as described below.
The concatenation of the data to be signed, the signature type, and
the 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:
* 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; see Sections 5.2.3.1 and
5.2.3.2.
5.2.3. Versions 4 and 6 Signature Packet Formats
The body of a version 4 or version 6 Signature packet contains:
* A 1-octet version number. This is 4 for version 4 signatures and
6 for version 6 signatures.
* A 1-octet Signature Type ID.
* A 1-octet public key algorithm.
* A 1-octet hash algorithm.
* A scalar octet count for the hashed subpacket data that follows
this field. For a version 4 signature, this is a 2-octet field.
For a version 6 signature, this is a 4-octet field. Note that
this is the length in octets of all of the hashed subpackets; an
implementation's pointer incremented by this number will skip over
the hashed subpackets.
* A hashed subpacket data set (zero or more subpackets).
* A scalar octet count for the unhashed subpacket data that follows
this field. For a version 4 signature, this is a 2-octet field.
For a version 6 signature, this is a 4-octet field. Note that
this is the length in octets of all of the unhashed subpackets; an
implementation's pointer incremented by this number will skip over
the unhashed subpackets.
* An unhashed subpacket data set (zero or more subpackets).
* A 2-octet field holding the left 16 bits of the signed hash value.
* Only for version 6 signatures, a variable-length field containing:
- A 1-octet salt size. The value MUST match the value defined
for the hash algorithm as specified in Table 23.
- The salt, which is a random value of the specified size.
* One or more MPIs comprising the signature. This portion is
algorithm specific.
5.2.3.1. Algorithm-Specific Fields for RSA Signatures
* MPI of RSA signature value m^d mod n.
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] (see
also Section 12.1.3). This requires inserting the hash value as an
octet string into an ASN.1 structure. The object identifier (OID)
for the hash algorithm itself is also included in the structure; see
the OIDs in Table 24.
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.
A version 3 signature MUST NOT be created and MUST NOT be used with
the Elliptic Curve Digital Signature Algorithm (ECDSA).
A DSA signature MUST use a hash algorithm with a digest size of at
least 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.
An ECDSA signature MUST use a hash algorithm with a digest size of at
least the curve's "fsize" value (see Section 9.2), except in the case
of NIST P-521, for which at least a 512-bit hash algorithm MUST be
used.
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.
An EdDSALegacy signature MUST use a hash algorithm with a digest size
of at least the curve's "fsize" value (see Section 9.2). A verifying
implementation MUST reject any EdDSALegacy signature that uses a hash
algorithm with a smaller digest size.
5.2.3.3.1. Algorithm-Specific Fields for Ed25519Legacy Signatures
(Deprecated)
The two MPIs for Ed25519Legacy represent the octet strings R and S of
the Edwards-curve Digital Signature Algorithm (EdDSA) described in
[RFC8032].
* 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.
Ed25519Legacy MUST NOT be used in Signature packets version 6 or
above.
5.2.3.4. Algorithm-Specific Fields for Ed25519 Signatures
* 64 octets of the native signature.
For more details, see Section 12.7.
A version 3 signature MUST NOT be created and MUST NOT be used with
Ed25519.
An Ed25519 signature MUST use a hash algorithm with a digest size of
at least 256 bits. A verifying implementation MUST reject any
Ed25519 signature that uses a hash algorithm with a smaller digest
size.
5.2.3.5. Algorithm-Specific Fields for Ed448 Signatures
* 114 octets of the native signature.
For more details, see Section 12.7.
A version 3 signature MUST NOT be created and MUST NOT be used with
Ed448.
An Ed448 signature MUST use a hash algorithm with a digest size of at
least 512 bits. A verifying implementation MUST reject any Ed448
signature that uses a hash algorithm with a smaller digest size.
5.2.3.6. Notes on Signatures
The concatenation of the data being signed, the signature data from
the version number through the hashed subpacket data (inclusive), and
(for signature versions later than 3) a 6-octet trailer (see
Section 5.2.4) 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 version 6 signature, an implementation MUST reject the
signature if these octets do not 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 not hashed into the signature. The second set of subpackets (the
"unhashed section") is not cryptographically protected by the
signature and should include only advisory information. See
Section 13.13 for more information.
The differences between a version 4 and version 6 signature are two-
fold: first, a version 6 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 13.2).
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 2-octet
(for version 4 signatures) or 4-octet (for version 6 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 encoded subpacket length (1, 2, or 5 octets).
* The encoded Subpacket Type ID (1 octet).
* The subpacket-specific data.
The subpacket length field covers the encoded Subpacket Type ID and
the subpacket-specific data, and it does not include the subpacket
length field itself. It is encoded similarly to a 1-octet, 2-octet,
or 5-octet OpenPGP format packet header. The encoded subpacket
length can be decoded as follows:
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 = [4-octet scalar starting at 2nd_octet]
Bit 7 of the encoded Subpacket Type ID 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
implementation, the evaluator SHOULD consider the signature to be in
error.
An implementation SHOULD ignore any non-critical subpacket of a type
that it does not recognize.
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.
The other bits of the encoded Subpacket Type ID (i.e., bits 6-0)
contain the Subpacket Type ID.
The following signature subpackets are defined:
+=========+===========================+==================+
| ID | Description | Reference |
+=========+===========================+==================+
| 0 | Reserved | |
+---------+---------------------------+------------------+
| 1 | Reserved | |
+---------+---------------------------+------------------+
| 2 | Signature Creation Time | Section 5.2.3.11 |
+---------+---------------------------+------------------+
| 3 | Signature Expiration Time | Section 5.2.3.18 |
+---------+---------------------------+------------------+
| 4 | Exportable Certification | Section 5.2.3.19 |
+---------+---------------------------+------------------+
| 5 | Trust Signature | Section 5.2.3.21 |
+---------+---------------------------+------------------+
| 6 | Regular Expression | Section 5.2.3.22 |
+---------+---------------------------+------------------+
| 7 | Revocable | Section 5.2.3.20 |
+---------+---------------------------+------------------+
| 8 | Reserved | |
+---------+---------------------------+------------------+
| 9 | Key Expiration Time | Section 5.2.3.13 |
+---------+---------------------------+------------------+
| 10 | Placeholder for backward | |
| | compatibility | |
+---------+---------------------------+------------------+
| 11 | Preferred Symmetric | Section 5.2.3.14 |
| | Ciphers for v1 SEIPD | |
+---------+---------------------------+------------------+
| 12 | Revocation Key | Section 5.2.3.23 |
| | (deprecated) | |
+---------+---------------------------+------------------+
| 13-15 | Reserved | |
+---------+---------------------------+------------------+
| 16 | Issuer Key ID | Section 5.2.3.12 |
+---------+---------------------------+------------------+
| 17-19 | Reserved | |
+---------+---------------------------+------------------+
| 20 | Notation Data | Section 5.2.3.24 |
+---------+---------------------------+------------------+
| 21 | Preferred Hash Algorithms | Section 5.2.3.16 |
+---------+---------------------------+------------------+
| 22 | Preferred Compression | Section 5.2.3.17 |
| | Algorithms | |
+---------+---------------------------+------------------+
| 23 | Key Server Preferences | Section 5.2.3.25 |
+---------+---------------------------+------------------+
| 24 | Preferred Key Server | Section 5.2.3.26 |
+---------+---------------------------+------------------+
| 25 | Primary User ID | Section 5.2.3.27 |
+---------+---------------------------+------------------+
| 26 | Policy URI | Section 5.2.3.28 |
+---------+---------------------------+------------------+
| 27 | Key Flags | Section 5.2.3.29 |
+---------+---------------------------+------------------+
| 28 | Signer's User ID | Section 5.2.3.30 |
+---------+---------------------------+------------------+
| 29 | Reason for Revocation | Section 5.2.3.31 |
+---------+---------------------------+------------------+
| 30 | Features | Section 5.2.3.32 |
+---------+---------------------------+------------------+
| 31 | Signature Target | Section 5.2.3.33 |
+---------+---------------------------+------------------+
| 32 | Embedded Signature | Section 5.2.3.34 |
+---------+---------------------------+------------------+
| 33 | Issuer Fingerprint | Section 5.2.3.35 |
+---------+---------------------------+------------------+
| 34 | Reserved | |
+---------+---------------------------+------------------+
| 35 | Intended Recipient | Section 5.2.3.36 |
| | Fingerprint | |
+---------+---------------------------+------------------+
| 37 | Reserved (Attested | |
| | Certifications) | |
+---------+---------------------------+------------------+
| 38 | Reserved (Key Block) | |
+---------+---------------------------+------------------+
| 39 | Preferred AEAD | Section 5.2.3.15 |
| | Ciphersuites | |
+---------+---------------------------+------------------+
| 100-110 | Private or Experimental | |
| | Use | |
+---------+---------------------------+------------------+
Table 5: OpenPGP Signature Subpacket Types Registry
Implementations SHOULD implement the four preferred algorithm
subpackets (11, 21, 22, and 39), as well as the "Features" (30) and
"Reason for Revocation" (29) subpackets. To avoid surreptitious
forwarding (see Section 13.12), implementations SHOULD also implement
the "Intended Recipients Fingerprint" (35) subpacket. Note that if
an implementation chooses not to implement some of the preferences
subpackets, it MUST default to the mandatory-to-implement algorithms
to ensure interoperability. An encrypting implementation that does
not implement the "Features" (30) subpacket SHOULD select the type of
encrypted data format based on the versions of the recipient keys or
external inference (see Section 13.7 for more details).
5.2.3.8. Signature Subpacket Types
A number of subpackets are currently defined for OpenPGP signatures.
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 in either the hashed or the 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 covered by the cryptographic signature. See Section 13.13 for
more discussion about hashed and unhashed subpackets.
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
hashed section of the signature, but it MAY use any conflict
resolution scheme that makes more sense. Please note that conflict
resolution is intentionally left to the implementer; most conflicts
are simply syntax errors, and the ambiguous 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 version 3 key and a version 4 key that
share the same RSA key material. Either of these keys can verify a
signature created by 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 (Type IDs 0x10-0x13), the Direct Key
signature (Type ID 0x1F), and the Subkey Binding signature (Type ID
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 the 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 MUST have a self-
signature. Subpackets that appear in a certification self-signature
apply to the User ID, 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.
An implementation 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 implementation locates this key via Alice's name, then the
preferred AEAD ciphersuite is AES-256 with OCB; if the implementation
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 it 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 details.
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.
When an implementation imports a secret key, it SHOULD verify that
the key's internal self-signatures do not advertise features or
algorithms that the implementation doesn't support. If an
implementation observes such a mismatch, it SHOULD warn the user and
offer to create new self-signatures that advertise the actual set of
features and algorithms supported by the implementation.
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. To use a version 4 key,
some implementations require at least one User ID with a valid self-
signature to be present. For this reason, it is RECOMMENDED to
include at least one User ID with a self-signature in version 4 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 ID 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 version 6 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 email 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.
This subpacket MUST be present in the hashed area.
When generating this subpacket, it SHOULD be marked as critical.
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.
When an implementation generates this subpacket, it SHOULD be marked
as critical.
5.2.3.14. Preferred Symmetric Ciphers for v1 SEIPD
(array of 1-octet values)
A series of Symmetric Cipher Algorithm IDs indicating how the
keyholder prefers to receive the version 1 Symmetrically Encrypted
and Integrity Protected Data packet (Section 5.13.1). The subpacket
body is an ordered list of octets with the most preferred listed
first. It is assumed that only the algorithms listed are supported
by the recipient's implementation. Algorithm IDs are defined 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 IDs indicating how the keyholder prefers
to receive the version 2 Symmetrically Encrypted and Integrity
Protected Data packet (Section 5.13.2). Each pair of octets
indicates a combination of a symmetric cipher and an AEAD mode that
the keyholder prefers to use. The Symmetric Cipher Algorithm ID
precedes the AEAD algorithm ID 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 implementation, 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 IDs are listed in Section 9.6. Symmetric Cipher
Algorithm IDs are listed in Section 9.3.
For example, a subpacket containing the 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 the version 2 Symmetrically Encrypted and
Integrity Protected Data packet (Section 5.13.2) in general is
indicated by a Features 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 1-octet values)
Message digest algorithm IDs that indicate which algorithms the
keyholder prefers to receive. Like the Preferred AEAD Ciphersuites,
the list is ordered. Algorithm IDs are defined in Section 9.5. This
is only found on a self-signature.
5.2.3.17. Preferred Compression Algorithms
(array of 1-octet values)
Compression algorithm IDs that indicate which algorithms the
keyholder prefers to use. Like the Preferred AEAD Ciphersuites, the
list is ordered. Algorithm IDs are defined in Section 9.4. A zero,
or the absence of this subpacket, denotes that uncompressed data is
preferred; the keyholder's implementation might have no compression
support available. 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.
When an implementation generates this subpacket, it SHOULD be marked
as critical.
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"; it is intended for use by users other 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 local
certifications, 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.
When an implementation generates this subpacket and denotes the
signature as non-exportable, the subpacket MUST be marked as
critical.
5.2.3.20. Revocable
(1 octet of revocability, 0 for not, 1 for revocable)
A Signature's revocability status. The packet body contains a
Boolean flag indicating whether the signature is revocable.
Signatures that are not revocable ignore any later Revocation
Signatures. They represent the signer's commitment that its
signature cannot be revoked for the life of its 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)
The 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 UTF-8 encoded 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 Henry Spencer's
"almost public domain" Regular Expression [REGEX] package. A
description of the syntax is found in Section 8. The Regular
Expression matches (or does not match) a sequence of UTF-8-encoded
Unicode characters from User IDs. The expression itself is also
written with UTF-8 characters.
For historical reasons, this subpacket includes a null character (an
octet with value zero) after the Regular Expression. When an
implementation parses a Regular Expression subpacket, it MUST remove
this octet; if it is not present, it MUST reject the subpacket (i.e.,
ignore the subpacket if it's non-critical and reject the signature if
it's critical). When an implementation generates a Regular
Expression subpacket, it MUST include the null terminator.
When generating this subpacket, it SHOULD be marked as critical.
5.2.3.23. Revocation Key (Deprecated)
(1 octet of class, 1 octet of public key algorithm ID, 20 octets of
version 4 fingerprint)
This mechanism is deprecated. Applications MUST NOT generate such a
subpacket.
An application that wants the functionality of delegating revocation
can use an escrowed Revocation Signature. See Section 13.9 for more
details.
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. The class octet must have bit
0x80 set. If bit 0x40 is set, it means 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 ID 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, i.e., 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 4 octets of
flags.
All undefined flags MUST be zero. Defined flags are as follows:
+=======================+================+================+
| Flag Position | Shorthand | Description |
+=======================+================+================+
| 0x80000000 (first bit | human-readable | Notation value |
| of the first octet) | | is UTF-8 text |
+-----------------------+----------------+----------------+
Table 6: OpenPGP Signature Notation Data Subpacket
Notation Flags Registry
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 |
+===============+===========+================+
| No registrations at this time. |
+============================================+
Table 7: OpenPGP Signature Notation Data
Subpacket Types Registry
This registry is initially empty.
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 1-bit flags that indicates preferences that the
keyholder has about how the key is handled on a key server. All
undefined flags MUST be zero.
+=========+===========+===========================================+
| Flag | Shorthand | Definition |
+=========+===========+===========================================+
| 0x80... | No-modify | The keyholder requests that this key only |
| | | be modified or updated by the keyholder |
| | | or an administrator of the key server. |
+---------+-----------+-------------------------------------------+
Table 8: OpenPGP Key Server Preference Flags Registry
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 keyholder 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 https, ftp,
http, 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, for example, 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, 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.
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, so that 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:
+===========+======================================================+
| Flag | Definition |
+===========+======================================================+
| 0x01... | This key may be used to make User ID certifications |
| | (Signature Type IDs 0x10-0x13) or Direct Key |
| | signatures (Signature Type ID 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. |
+-----------+------------------------------------------------------+
| 0x0004... | Reserved (ADSK) |
+-----------+------------------------------------------------------+
| 0x0008... | Reserved (timestamping) |
+-----------+------------------------------------------------------+
Table 9: OpenPGP Key Flags Registry
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. However, note that determining what is
"communications" and what is "storage" is a thorny issue. 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 ID 0x1F) or a Subkey Binding signature (Type ID 0x18), one that
refers to the key the flag applies to.
When an implementation generates this subpacket, it SHOULD be marked
as critical.
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
certification was revoked.
The first octet contains a machine-readable code that denotes the
reason for the revocation:
+=========+========================================+
| Code | Reason |
+=========+========================================+
| 0 | No reason specified (Key Revocation or |
| | Certification Revocation signatures) |
+---------+----------------------------------------+
| 1 | Key is superseded (Key Revocation |
| | signatures) |
+---------+----------------------------------------+
| 2 | Key material has been compromised (Key |
| | Revocation signatures) |
+---------+----------------------------------------+
| 3 | Key is retired and no longer used (Key |
| | Revocation signatures) |
+---------+----------------------------------------+
| 32 | User ID information is no longer valid |
| | (Certification Revocation signatures) |
+---------+----------------------------------------+
| 100-110 | Private Use |
+---------+----------------------------------------+
Table 10: OpenPGP Reason for Revocation
(Revocation Octet) Registry
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
signature revocation SHOULD include a Reason for Revocation subpacket
containing code 32.
Note that any certification 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.
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 backward 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, unless the
implementation can infer support for the feature from another
implementation-dependent mechanism.
Defined features are as follows:
First octet:
+=========+=====================================+===========+
| Feature | Definition | Reference |
+=========+=====================================+===========+
| 0x01... | Version 1 Symmetrically Encrypted | Section |
| | and Integrity Protected Data packet | 5.13.1 |
+---------+-------------------------------------+-----------+
| 0x02... | Reserved | |
+---------+-------------------------------------+-----------+
| 0x04... | Reserved | |
+---------+-------------------------------------+-----------+
| 0x08... | Version 2 Symmetrically Encrypted | Section |
| | and Integrity Protected Data packet | 5.13.2 |
+---------+-------------------------------------+-----------+
Table 11: OpenPGP Features Flags Registry
If an implementation implements any of the defined features, it
SHOULD implement the Features subpacket, too.
See Section 13.7 for details about how to use the Features subpacket
when generating encryption data.
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 Confirmation 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 signature's hash.
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)
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 13.12).
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.
When generating this subpacket in a version 6 signature, it SHOULD be
marked as critical.
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 creating or verifying a version 6 signature, the salt is fed
into the hash context before any other data.
For binary document signatures (Type ID 0x00), the document data is
hashed directly. For text document signatures (Type ID 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 byte stream is hashed.
When a version 4 signature is made over a key, the hash data starts
with the octet 0x99, followed by a 2-octet length of the key,
followed by the body of the key packet. When a version 6 signature
is made over a key, the hash data starts with the salt and then octet
0x9B, followed by a 4-octet length of the key, followed by the body
of the key packet.
A Subkey Binding signature (Type ID 0x18) or Primary Key Binding
signature (Type ID 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 ID 0x20) hash only the key
being revoked. A Subkey Revocation signature (Type ID 0x28) first
hashes the primary key and then the subkey being revoked.
A Certification signature (Type IDs 0x10 through 0x13) hashes the
User ID that is bound to the key into the hash context after the
above data. A version 3 certification hashes the contents of the
User ID or User Attribute packet without the packet header. A
version 4 or version 6 certification hashes the constant 0xB4 for
User ID certifications or the constant 0xD1 for User Attribute
certifications, followed by a 4-octet number giving the length of the
User ID or User Attribute data, followed by the User ID or User
Attribute data.
A Third-Party Confirmation signature (Type ID 0x50) hashes the salt
(version 6 signatures only), followed by the octet 0x88, followed by
the 4-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 version 3 signature hashes five octets of the packet body,
starting from the signature type field. This data is the
signature type, followed by the 4-octet Signature Creation Time.
* A version 4 or version 6 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 version 4,
and 0x06 for version 6),
- the signature type,
- the public key algorithm,
- the hash algorithm,
- the hashed subpacket length,
- the hashed subpacket body,
- a second version octet (0x04 for version 4, and 0x06 for
version 6),
- a single octet 0xFF, and
- a number representing the length (in octets) of the hashed data
from the Signature packet through the hashed subpacket body.
This a 4-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.
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 the 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 version 3 signature uses the fifth octet from the end to store
its Signature Type ID. This MUST NOT be Signature Type ID 0xFF.
* All signature versions later than version 3 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 hash algorithm known to be weak (e.g., MD5)
* A mismatch between the expected salt length of the hash algorithm
and the actual salt length
* A mismatch between the One-Pass Signature version and the
Signature version (see Section 10.3.2.2)
* A signature with a version other than 6, made by a version 6 key
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 Packet (Type ID 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 precede an
encryption container (that is, a Symmetrically Encrypted and
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 1-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
passphrase and in what they encode. The version of the SKESK packet
must align with the version of the SEIPD packet (see
Section 10.3.2.1). Any new version of the SKESK packet should be
registered in the registry established in Section 10.3.2.1.
5.3.1. Version 4 Symmetric Key Encrypted Session Key Packet Format
A v4 SKESK packet precedes a v1 SEIPD (see Section 5.13.1). In
historic data, it is sometimes found preceding a deprecated SED
packet (see Section 5.7). A v4 SKESK packet MUST NOT precede a v2
SEIPD packet (see Section 10.3.2.1).
A version 4 Symmetric Key Encrypted Session Key packet consists of:
* A 1-octet version number with value 4.
* A 1-octet number describing the symmetric algorithm used.
* An S2K Specifier. The length of the S2K Specifier depends on its
type (see Section 3.7.1).
* Optionally, the encrypted session key itself, which is decrypted
with the S2K 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 ID 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 1-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, a Salted S2K, an Iterated and 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. Version 6 Symmetric Key Encrypted Session Key Packet Format
A v6 SKESK packet precedes a v2 SEIPD packet (see Section 5.13.2). A
v6 SKESK packet MUST NOT precede a v1 SEIPD packet or a deprecated
Symmetrically Encrypted Data packet (see Section 10.3.2.1).
A version 6 Symmetric Key Encrypted Session Key packet consists of:
* A 1-octet version number with value 6.
* A 1-octet scalar octet count for the 5 fields following this
octet.
* A 1-octet Symmetric Cipher Algorithm ID (from Table 21).
* A 1-octet AEAD algorithm identifier (from Table 25).
* A 1-octet scalar octet count of the following field.
* An S2K Specifier. The length of the S2K Specifier depends on its
type (see Section 3.7.1).
* A starting IV of the size specified by the AEAD algorithm.
* The encrypted session key itself.
* An authentication tag for the AEAD mode.
A key-encryption key (KEK) is derived using HKDF [RFC5869] with
SHA256 [RFC6234] as the hash algorithm. The Initial Keying Material
(IKM) for HKDF is the key derived from S2K. No salt is used. The
info parameter is comprised of the Packet Type ID in OpenPGP format
encoding (bits 7 and 6 are set, and bits 5-0 carry the Packet Type
ID), the packet version, and the cipher-algo and AEAD-mode used to
encrypt the key material.
Then, the session key is encrypted using the resulting key, with the
AEAD algorithm specified for the version 2 Symmetrically Encrypted
and Integrity Protected Data packet. Note that no chunks are used
and that there is only one authentication tag. The Packet Type ID
encoded in OpenPGP format (bits 7 and 6 are set, and bits 5-0 carry
the Packet Type ID), the packet version number, the cipher algorithm
ID, and the AEAD algorithm ID 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 Packet (Type ID 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 1-octet version number. The currently defined versions are 3
and 6. Any new One-Pass Signature packet version should be
registered in the registry established in Section 10.3.2.2.
* A 1-octet Signature Type ID. Signature types are described in
Section 5.2.1.
* A 1-octet number describing the hash algorithm used.
* A 1-octet number describing the public key algorithm used.
* Only for version 6 packets, a variable-length field containing:
- A 1-octet salt size. The value MUST match the value defined
for the hash algorithm as specified in Table 23.
- The salt; a random value of the specified size. The value MUST
match the salt field of the corresponding Signature packet.
* Only for v3 packets, an 8-octet number holding the Key ID of the
signing key.
* Only for version 6 packets, 32 octets of the fingerprint of the
signing key. Since a version 6 signature can only be made by a
version 6 key, the length of the fingerprint is fixed.
* A 1-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 version 4 keys use a version 3 One-
Pass Signature packet (there is no version 4 OPS). See
Section 10.3.2.2 for the full correspondence of versions between
Keys, Signatures, and One-Pass Signatures.
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
Signature packet and the final Signature packet corresponds to the
first One-Pass Signature packet.
5.5. Key Material Packets
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 packets are
unspecified.
5.5.1. Key Packet Variants
5.5.1.1. Public Key Packet (Type ID 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 (Type ID 14)
A Public Subkey packet (Type ID 14) has exactly the same format as a
Public Key packet, but it denotes a subkey. One or more subkeys may
be associated with a top-level key. By convention, the top-level key
offers certification capability, but it does not provide encryption
services, while a dedicated subkey provides encryption (see
Section 10.1.5).
5.5.1.3. Secret Key Packet (Type ID 5)
A Secret Key packet contains all the information that is found in a
Public Key packet, including the public key material, but it also
includes the secret key material after all the public key fields.
5.5.1.4. Secret Subkey Packet (Type ID 7)
A Secret Subkey packet (Type ID 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 four versions of key material packets. Versions 2 and 3
have been deprecated since 1998. Version 4 has been deprecated by
this document.
OpenPGP implementations SHOULD create keys with version 6 format.
Version 4 keys are deprecated; an implementation SHOULD NOT generate
a version 4 key but SHOULD accept it. Version 3 keys are deprecated;
an implementation MUST NOT generate a version 3 key but MAY accept
it. Version 2 keys are deprecated; an implementation MUST NOT
generate a version 2 key but MAY accept it.
Any new Key Version must be registered in the registry established in
Section 10.3.2.2.
5.5.2.1. Version 3 Public Keys
Version 2 keys are identical to version 3 keys except for the version
number. A version 3 Public Key or Public Subkey packet contains:
* A 1-octet version number (3).
* A 4-octet number denoting the time that the key was created.
* A 2-octet number denoting the time in days that the key is valid.
If this number is zero, then it does not expire.
* A 1-octet number denoting the public key algorithm of the key.
* A series of multiprecision integers comprising the key material:
- MPI of RSA public modulus n.
- MPI of RSA public encryption exponent e.
Version 3 keys are deprecated. They contain three weaknesses.
First, it is relatively easy to construct a version 3 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. Second, because the fingerprint of a
version 3 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 cause developers to
prefer other algorithms. See Section 5.5.4 for a fuller discussion
of Key IDs and fingerprints.
5.5.2.2. Version 4 Public Keys
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 1-octet version number (4).
* A 4-octet number denoting the time that the key was created.
* A 1-octet number denoting the public key algorithm of the key.
* A series of values comprising the key material. This is algorithm
specific and described in Section 5.5.5.
5.5.2.3. Version 6 Public Keys
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 1-octet version number (6).
* A 4-octet number denoting the time that the key was created.
* A 1-octet number denoting the public key algorithm of the key.
* A 4-octet scalar octet count for the public key material specified
in the next field.
* 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 (the "S2K usage octet") indicating whether and how the
secret key material is protected by a passphrase. Zero indicates
that the secret key data is not encrypted. 253 (AEAD), 254 (CFB),
or 255 (MalleableCFB) indicates that an S2K Specifier and other
parameters will follow. Any other value is a symmetric key
encryption algorithm identifier. A version 6 packet MUST NOT use
the value 255 (MalleableCFB).
* Only for a version 6 packet where the secret key material is
encrypted (that is, where the previous octet is not zero), a
1-octet scalar octet count of the cumulative length of all the
following conditionally included S2K parameter fields.
* Conditionally included S2K parameter fields:
- If the S2K usage octet was 253, 254, or 255, a 1-octet
symmetric key encryption algorithm.
- If the S2K usage octet was 253 (AEAD), a 1-octet AEAD
algorithm.
- Only for a version 6 packet, and if the S2K usage octet was 253
or 254, a 1-octet count of the size of the one field following
this octet.
- If the S2K usage octet was 253, 254, or 255, an S2K Specifier.
The length of the S2K Specifier depends on its type (see
Section 3.7.1).
- If the S2K usage octet was 253 (AEAD), an IV of a size
specified by the AEAD algorithm (see Section 5.13.2), which is
used as the nonce for the AEAD algorithm.
- If the S2K usage octet was 254, 255, or a cipher algorithm ID
(that is, the secret data uses some form of CFB encryption), an
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 S2K usage octet is 253 (AEAD), then an AEAD
authentication tag is at the end of that data. If the S2K usage
octet is 254 (CFB), a 20-octet SHA-1 hash of the plaintext of the
algorithm-specific portion is appended to plaintext and encrypted
with it. If the S2K usage octet is 255 (MalleableCFB) or another
non-zero value (that is, a symmetric key encryption algorithm
identifier), a 2-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 S2K usage octet is
zero, a 2-octet checksum of the algorithm-specific portion (sum of
all octets, mod 65536).
The details about storing algorithm-specific secrets above are
summarized in Table 2.
Note that the version 6 packet format adds two count values to help
parsing packets with unknown S2K or public key algorithms.
Secret MPI values can be encrypted using a passphrase. If an S2K
Specifier is given, it describes the algorithm for converting the
passphrase to a key; otherwise, a simple MD5 hash of the passphrase
is used. An implementation producing a passphrase-protected Secret
Key packet MUST use an S2K Specifier; the simple hash is for read-
only backward compatibility, 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 IV from the packet. If the S2K
usage octet is not 253, CFB mode is used. A different mode is used
with version 3 keys (which are only RSA) than with other key formats.
With version 3 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 version 4 and version 6 keys, a simpler method is used. All
secret MPI values are encrypted, including the MPI bit count prefix.
If the S2K usage octet is 253, the KEK is derived using HKDF
[RFC5869] to provide key separation. SHA256 [RFC6234] is used as the
hash algorithm for HKDF. IKM for HKDF is the key derived from S2K.
No salt is used. The info parameter is comprised of the Packet Type
ID encoded in OpenPGP format (bits 7 and 6 are set, and bits 5-0
carry the Packet Type ID), the packet version, and the cipher-algo
and AEAD-mode used to encrypt the key material.
Then, the encrypted MPI values are encrypted as one combined
plaintext using one of the AEAD algorithms specified for the version
2 Symmetrically Encrypted and Integrity Protected Data packet. Note
that no chunks are used and that there is only one authentication
tag. As additional data, the Packet Type ID in OpenPGP format
encoding (bits 7 and 6 are set, and bits 5-0 carry the Packet Type
ID), 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 4-octet octet count of the
public key material would be included as well (see Section 5.5.2).
The 2-octet checksum that follows the algorithm-specific portion is
the algebraic sum, mod 65536, of the plaintext of all the algorithm-
specific octets (including the MPI prefix and data). With version 3
keys, the checksum is stored in the clear. With version 4 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, and an implementation SHOULD NOT use it;
instead, an implementation should use the SHA-1 hash denoted with a
usage octet of 254. The reason for this is that there are some
attacks that involve modifying the secret key undetected. If the S2K
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 any secret key material whose cleartext
length does not align with the lengths of the unwrapped MPI objects
as unusable.
5.5.4. Key IDs and Fingerprints
Every OpenPGP Key has a fingerprint and a Key ID. The computation of
these values differs based on the key version. The fingerprint
length varies with the key version, but the Key ID (which is only
used in v3 PKESK packets; see Section 5.1.1) is always 64 bits. The
following registry represents the subsections below:
+=======+===================+===============+=============+=========+
|Key | Fingerprint | Fingerprint | Key ID |Reference|
|Version| | Length | | |
| | | (Bits) | | |
+=======+===================+===============+=============+=========+
|3 | MD5(MPIs without | 128 | low 64 bits |Section |
| | length octets) | | of RSA |5.5.4.1 |
| | | | modulus | |
+-------+-------------------+---------------+-------------+---------+
|4 | SHA1(normalized | 160 | last 64 |Section |
| | pubkey packet) | | bits of |5.5.4.2 |
| | | | fingerprint | |
+-------+-------------------+---------------+-------------+---------+
|6 | SHA256(normalized | 256 | first 64 |Section |
| | pubkey packet) | | bits of |5.5.4.3 |
| | | | fingerprint | |
+-------+-------------------+---------------+-------------+---------+
Table 12: OpenPGP Key IDs and Fingerprints Registry
5.5.4.1. Version 3 Key ID and Fingerprint
For a version 3 key, the 8-octet Key ID consists of the low 64 bits
of the public modulus of the RSA key.
The fingerprint of a version 3 key is formed by hashing the body (but
not the 2-octet length) of the MPIs that form the key material
(public modulus n, followed by exponent e) with MD5. Note that both
version 3 keys and MD5 are deprecated.
5.5.4.2. Version 4 Key ID and Fingerprint
A version 4 fingerprint is the 160-bit SHA-1 hash of the octet 0x99,
followed by the 2-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, including an example of an Ed25519 key:
a.1) 0x99 (1 octet)
a.2) 2-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):
e.1) 32 octets representing the public key
5.5.4.3. Version 6 Key ID and Fingerprint
A version 6 fingerprint is the 256-bit SHA2-256 hash of the octet
0x9B, followed by the 4-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, including an example of an Ed25519 key:
a.1) 0x9B (1 octet)
a.2) 4-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) 4-octet scalar octet count for the key material specified in the
next field
f) algorithm-specific public key material
Algorithm-specific fields for Ed25519 keys (example):
f.1) 32 octets representing the public key
Note that it is possible for there to be collisions of Key IDs --
that is, 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 version 3, version 4, and version 6 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 (version 4 key) or
0x9B (version 6 key) as the first octet (even though this is not a
valid Packet Type ID for a public subkey).
5.5.5. Algorithm-Specific Parts of Keys
The public and secret key formats specify algorithm-specific parts of
a key. The following sections describe them in detail.
5.5.5.1. Algorithm-Specific Part for RSA Keys
For RSA keys, the public key consists of this series of
multiprecision integers:
* MPI of RSA public modulus n,
* MPI of RSA public encryption exponent e.
The secret key consists of 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); and
* MPI of u, the multiplicative inverse of p, mod q.
5.5.5.2. Algorithm-Specific Part for DSA Keys
For DSA keys, the public key consists of 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; and
* MPI of DSA public key value y (= g^x mod p where x is secret).
The secret key consists of this single multiprecision integer:
* MPI of DSA secret exponent x.
5.5.5.3. Algorithm-Specific Part for Elgamal Keys
For Elgamal keys, the public key consists of this series of
multiprecision integers:
* MPI of Elgamal prime p;
* MPI of Elgamal group generator g; and
* MPI of Elgamal public key value y (= g^x mod p where x is secret).
The secret key consists of this single multiprecision integer:
* MPI of Elgamal secret exponent x.
5.5.5.4. Algorithm-Specific Part for ECDSA Keys
For ECDSA keys, the public key consists of this series of values:
* A variable-length field containing a curve OID, which is formatted
as follows:
- A 1-octet size of the following field; values 0 and 0xFF are
reserved for future extensions.
- The octets representing a curve OID, as defined in Section 9.2.
* An MPI of an EC point representing a public key.
The secret key consists of this single multiprecision integer:
* An 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)
For EdDSALegacy keys (deprecated), the public key consists of this
series of values:
* A variable-length field containing a curve OID, formatted as
follows:
- A 1-octet size of the following field; values 0 and 0xFF are
reserved for future extensions.
- The octets representing a curve OID, as defined in Section 9.2.
* An MPI of an EC point representing a public key Q in prefixed
native form (see Section 11.2.2).
The secret key consists of this single multiprecision integer:
* An MPI-encoded octet string representing the native form of the
secret key in the curve-specific format, as described in
Section 9.2.1.
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 Section 5.1.5 of
[RFC8032] for more details about how to use the native octet strings
for Ed25519Legacy. The value stored in an OpenPGP EdDSALegacy Secret
Key packet is the original sequence of random octets.
Note that the only curve defined for use with EdDSALegacy is the
Ed25519Legacy OID.
5.5.5.6. Algorithm-Specific Part for ECDH Keys
For ECDH keys, the public key consists of this series of values:
* A variable-length field containing a curve OID, which is formatted
as follows:
- A 1-octet size of the following field; values 0 and 0xFF are
reserved for future extensions.
- The octets representing a curve OID, as defined in Section 9.2.
* An 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 key derivation function (KDF)
parameters, which is formatted as follows:
- A 1-octet size of the following fields; values 0 and 0xFF are
reserved for future extensions.
- A 1-octet value 1, reserved for future extensions.
- A 1-octet hash function ID used with a KDF.
- A 1-octet algorithm ID for the symmetric algorithm that is used
to wrap the symmetric key for message encryption; see
Section 11.5 for details.
The secret key consists of this single multiprecision integer:
* An MPI representing the secret key, in the curve-specific format
described in Section 9.2.1.
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 as described in [RFC7748]):
def curve25519Legacy_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
For X25519 keys, the public key consists of this single value:
* 32 octets of the native public key.
The secret key consists of 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).
5.5.5.8. Algorithm-Specific Part for X448 Keys
For X448 keys, the public key consists of this single value:
* 56 octets of the native public key.
The secret key consists of 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
For Ed25519 keys, the public key consists of this single value:
* 32 octets of the native public key.
The secret key consists of 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
For Ed448 keys, the public key consists of this single value:
* 57 octets of the native public key.
The secret key consists of 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.
5.6. Compressed Data Packet (Type ID 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 specifying the algorithm used to compress the packet.
* Compressed data, which makes up the remainder of the packet.
A Compressed Data packet's body contains data that is a compression
of a series of OpenPGP packets. See Section 10 for details on how
messages are formed.
A ZIP-compressed series of packets is compressed into raw DEFLATE
blocks [RFC1951].
A ZLIB-compressed series of packets is compressed with raw ZLIB-style
blocks [RFC1950].
A BZip2-compressed series of packets is compressed using the BZip2
[BZ2] algorithm.
An implementation that generates a Compressed Data packet MUST use
the OpenPGP 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 predating support for [RFC2440]
MAY interpret Compressed Data packets that use the Legacy format for
packet framing.
5.7. Symmetrically Encrypted Data Packet (Type ID 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, it could be another sequence of packets that
forms a valid OpenPGP Message).
This packet is obsolete. An implementation MUST NOT create this
packet. An implementation SHOULD reject such a packet and stop
processing the message. If an implementation chooses to process the
packet anyway, it MUST return a clear warning that a non-integrity-
protected packet has been processed.
This packet format is impossible to handle safely in general because
the ciphertext it provides is malleable. See Section 13.7 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,
16 octets for a 128-bit block length) followed by a copy of the
last two octets, encrypted together using Cipher Feedback (CFB)
mode, with an 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 ID 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 Section 12.9). For the random
prefix, the IV is specified as all zeros. Instead of achieving
randomized encryption through an IV, a string of length equal to the
block size of the cipher plus two is encrypted for this purpose. The
first block-size octets (for example, 16 octets for a 128-bit block
length) are random, and the following two octets are copies of the
last two octets of the first block-size random octets. For example,
for a 16-octet block length, octet 17 is a copy of octet 15, and
octet 18 is a copy of octet 16. For a cipher of block length 8,
octet 9 is a copy of octet 7, and octet 10 is a copy of octet 8. (In
both of 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 13.4 for hints on the proper use of this "quick check".
5.8. Marker Packet (Type ID 10)
The body of the Marker 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 (Type ID 11)
A Literal Data packet contains the body of a message; that is, data
that is not to be further interpreted.
The body of this packet consists of:
* A 1-octet field that describes how the data is formatted.
If it is a b (0x62), then the Literal Data packet contains binary
data. If it is a u (0x75), then the Literal Data packet contains
UTF-8-encoded text data and thus may need line ends converted to
local form or other text mode changes.
Previous versions of the OpenPGP specification 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.
Some implementations predating [RFC2440] also defined a value of l
as a "local" mode for machine-local conversions. [RFC1991]
incorrectly states that this local mode flag is 1 (ASCII numeral
one). Both of these local modes are deprecated.
* The file name as a string (1-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, it will be the name of the
encrypted file. An implementation MAY consider the file name in
the Literal Data packet to be a more authoritative name than the
actual file name.
* A 4-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.
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
implementation.
Note that OpenPGP signatures do not include the formatting octet, the
file name, and the date field of the Literal Data packet in a
signature hash; therefore, 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 when either 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 MUST
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 an implementation that predates support for [RFC2440]
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.
It is NOT RECOMMENDED to use this special filename in a newly
generated Literal Data packet.
5.10. Trust Packet (Type ID 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 keyholders are trustworthy introducers, along
with other information that implementation 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 (Type ID 13)
A User ID packet consists of UTF-8 text that is intended to represent
the name and email address of the keyholder. By convention, it
includes a mail name-addr as described in [RFC2822], 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 (Type ID 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
specification, 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 ID (1 octet)
and is followed by the subpacket specific data.
The following table lists the currently known subpackets:
+=========+=============================+================+
| ID | Attribute Subpacket | Reference |
+=========+=============================+================+
| 0 | Reserved | |
+---------+-----------------------------+----------------+
| 1 | Image Attribute Subpacket | Section 5.12.1 |
+---------+-----------------------------+----------------+
| 100-110 | Private or Experimental Use | |
+---------+-----------------------------+----------------+
Table 13: OpenPGP User Attribute Subpacket Types Registry
An implementation SHOULD ignore any subpacket of a type that it does
not recognize.
5.12.1. 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.
+=========+================+
| Version | Reference |
+=========+================+
| 1 | Section 5.12.1 |
+---------+----------------+
Table 14: OpenPGP Image
Attribute Versions
Registry
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 IDs 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.
+=========+=============================+
| ID | Encoding |
+=========+=============================+
| 0 | Reserved |
+---------+-----------------------------+
| 1 | JPEG [JFIF] |
+---------+-----------------------------+
| 100-110 | Private or Experimental Use |
+---------+-----------------------------+
Table 15: OpenPGP Image Attribute
Encoding Format Registry
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.
5.13. Symmetrically Encrypted and Integrity Protected Data Packet (Type
ID 18)
The SEIPD packet contains integrity-protected and encrypted data.
When it has been decrypted, it will contain other packets forming an
OpenPGP Message (see Section 10.3).
The first octet of this packet is always used to indicate the version
number, but different versions contain ciphertext that is structured
differently. Version 1 of this packet contains data encrypted with a
symmetric key algorithm and is thus protected against modification by
the SHA-1 hash algorithm. This mechanism was introduced in [RFC4880]
and offers some protections against ciphertext malleability.
Version 2 of this packet contains data encrypted with an AEAD
construction. This offers a more cryptographically rigorous defense
against ciphertext malleability. See Section 13.7 for more details
on choosing between these formats.
Any new version of the SEIPD packet should be registered in the
registry established in Section 10.3.2.1.
5.13.1. Version 1 Symmetrically Encrypted and Integrity Protected Data
Packet Format
A version 1 Symmetrically Encrypted and Integrity Protected Data
packet consists of:
* A 1-octet version number with value 1.
* Encrypted data -- the output of the selected symmetric key cipher
operating in 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 and Integrity Protected Data packet. In
either case, the cipher algorithm ID is prefixed to the session key
before it is encrypted.
The data is encrypted in CFB mode (see Section 12.9). The IV is
specified as all zeros. Instead of achieving randomized encryption
through an IV, OpenPGP prefixes an octet string to the data before it
is encrypted for this purpose. 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.
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 13.4 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 is
comprised of the prefix data described above and 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 MDC system, as the integrity protection mechanism of the
version 1 Symmetrically Encrypted and 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.
CFB encryption has a limitation as 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 that are beyond
the scope of this document. Suffice it to say that many people
consider properties such as deniability to be as valuable as
integrity.
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 Message Authentication Code (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 is an attack that would
replace 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 Symmetrically Encrypted and Integrity Protected Data
Packet Format
A version 2 Symmetrically Encrypted and Integrity Protected Data
packet consists of:
* A 1-octet version number with value 2.
* A 1-octet cipher algorithm ID.
* A 1-octet AEAD algorithm identifier.
* A 1-octet chunk size.
* 32 octets of salt. The salt is used to derive the message key and
MUST be securely generated (see Section 13.10).
* Encrypted data; that is, 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 the IV, 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 leftmost M bits are used as a symmetric algorithm key, and the
remaining N - 64 bits are used as an IV. HKDF is used with SHA256
[RFC6234] as hash algorithm. The session key is used as IKM and the
salt as salt. The Packet Type ID in OpenPGP format encoding (bits 7
and 6 are set, and bits 5-0 carry the Packet Type ID), version
number, cipher algorithm ID, AEAD algorithm ID, and chunk size octet
are used 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 that
yields a new, unique message key. See Section 13.8 for guidance on
how applications can securely implement this feature.
A v2 SEIPD packet consists of one or more chunks of data. The
plaintext of each chunk is of a size specified by 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; nevertheless, it is followed
by a full authentication tag.
For each chunk, the AEAD construction is given the Packet Type ID
encoded in OpenPGP format (bits 7 and 6 are set, and bits 5-0 carry
the Packet Type ID), version number, cipher algorithm ID, AEAD
algorithm ID, 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 8-octet, big-
endian value specifying the total number of plaintext octets
encrypted. This allows detection of a truncated ciphertext.
The chunk size octet specifies the size of chunks using the following
formula (in C [C99]), 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 leftmost N - 64 bits are the IV derived using HKDF.
The rightmost 64 bits are the chunk index as a 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 (Type ID 21)
The Padding packet contains random data and can be used to defend
against traffic analysis (see Section 13.11) on v2 SEIPD messages
(see Section 5.13.2) and Transferable Public Keys (see Section 10.1).
Such a packet MUST be ignored when received.
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 version 6 Transferable Public Key that is
transferred over an encrypted channel (see Section 10.1).
* As the last packet of an Optionally Padded Message within a
version 2 Symmetrically Encrypted and Integrity Protected Data
packet (see Section 10.3.1).
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. Base64 Conversions
As stated in the introduction, OpenPGP's underlying 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 OpenPGP data structures. The
OpenPGP specification specifies one such printable encoding scheme to
ensure interoperability; see Section 6.2.
The 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
whitespace.
6.1. Optional Checksum
The optional checksum is a 24-bit Cyclic Redundancy Check (CRC)
converted to four characters of base64 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 base64 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 the
context or by the OpenPGP object being encoded that the consuming
implementation accepts base64-encoded blocks without a CRC24 footer.
Notably:
* An ASCII-armored Encrypted Message packet sequence that ends in a
v2 SEIPD packet MUST NOT contain a CRC24 footer.
* An ASCII-armored sequence of Signature packets that only includes
version 6 Signature packets MUST NOT contain a CRC24 footer.
* An ASCII-armored Transferable Public Key packet sequence of a
version 6 key MUST NOT contain a CRC24 footer.
* An ASCII-armored keyring consisting of only version 6 keys MUST
NOT contain a CRC24 footer.
Rationale: Previous draft versions of this document stated 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 CRC24 in "C"
The following code is written in [C99].
#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 base64-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
6.2.1. 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 on the type of data
being encoded in Armor and how it is being encoded. Header line
texts include the following strings:
+===================+============================================+
| Armor Header | Use |
+===================+============================================+
| BEGIN PGP MESSAGE | Used for signed, encrypted, or compressed |
| | files. |
+-------------------+--------------------------------------------+
| BEGIN PGP PUBLIC | Used for armoring public keys. |
| KEY BLOCK | |
+-------------------+--------------------------------------------+
| BEGIN PGP PRIVATE | Used for armoring private keys. |
| KEY BLOCK | |
+-------------------+--------------------------------------------+
| BEGIN PGP | Used for detached signatures, OpenPGP/MIME |
| SIGNATURE | signatures, and cleartext signatures. |
+-------------------+--------------------------------------------+
Table 16: OpenPGP Armor Header Lines Registry
Note that all of these Armor Header Lines are to consist of a
complete line. Therefore, the header lines MUST start at the
beginning of a line and MUST NOT have text other than whitespace
following them on the same line.
6.2.2. Armor Headers
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
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
(: 0x3A) and a single space (0x20) separate the key and value. An
OpenPGP implementation may consider improperly formatted Armor
Headers to be a corruption of the ASCII Armor, but it 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. For
example, the SMTP protocol that transports email messages has a line
length limit of 998 characters (see Section 2.1.1 of [RFC5322]).
While there is a limit of 76 characters for the base64 data
(Section 6), there is no limit for the length of Armor Headers. Care
should be taken to ensure 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:
+=========+==============================+=================+
| Key | Summary | Reference |
+=========+==============================+=================+
| Version | Implementation information | Section 6.2.2.1 |
+---------+------------------------------+-----------------+
| Comment | Arbitrary text | Section 6.2.2.2 |
+---------+------------------------------+-----------------+
| Hash | Hash algorithms used in some | Section 6.2.2.3 |
| | v4 cleartext signed messages | |
+---------+------------------------------+-----------------+
| Charset | Character set | Section 6.2.2.4 |
+---------+------------------------------+-----------------+
Table 17: OpenPGP Armor Header Keys Registry
6.2.2.1. "Version" Armor Header
The Armor Header Key Version describes 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.
6.2.2.2. "Comment" Armor Header
The Armor Header Key Comment supplies 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 7-bit
clean data. Consequently, if a comment has characters that are
outside the ASCII range of UTF-8, they may very well not survive
transport.
6.2.2.3. "Hash" Armor Header
The Armor Header Key Hash is deprecated, but some older
implementations expect it in messages using the Cleartext Signature
Framework (Section 7). When present, this Armor Header Key contains
a comma-separated list of hash algorithms used in the signatures on
message, with digest names as specified in the "Text Name" column in
Table 23. These headers SHOULD NOT be emitted unless:
* the cleartext signed message contains a version 4 signature made
using a SHA2-based digest (SHA224, SHA256, SHA384, or SHA512), and
* the cleartext signed message might be verified by a legacy OpenPGP
implementation that requires this header.
A verifying application MUST decline to validate any signature in a
message with a non-conformant Hash header (that is, a Hash header
that contains anything other than a comma-separated list of hash
algorithms). When a conformant Hash header is present, a verifying
application MUST ignore its contents, deferring to the hash algorithm
indicated in the Embedded Signature.
6.2.2.4. "Charset" Armor Header
The Armor Header Key Charset contains a description of the character
set that the plaintext is in (see [RFC2978]). Please note that
OpenPGP defines text to be in UTF-8. An implementation will get the
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.
6.2.3. Armor Tail Line
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".
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 with any tool capable of rendering text. In order to bind a
signature to such a cleartext, the Cleartext Signature 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 reversible. [RFC3156] defines another way to
sign cleartext messages for environments that support MIME.)
7.1. Cleartext Signed Message Structure
An OpenPGP cleartext signed message consists of:
* The cleartext header -----BEGIN PGP SIGNED MESSAGE----- on a
single line.
* One or more legacy Hash Armor Headers that MAY be included by some
implementations and MUST be ignored when well formed (see
Section 6.2.2.3).
* An empty line (not included in the message digest).
* The dash-escaped cleartext.
* A line ending separating the cleartext and following armored
signature (not included in the message digest).
* The ASCII-armored signature(s), including the -----BEGIN PGP
SIGNATURE----- Armor Header and Armor Tail Lines.
As with any other Text signature (Section 5.2.1.2), a cleartext
signature is calculated on the text using canonical <CR><LF> line
endings. As described above, the line ending before the -----BEGIN
PGP SIGNATURE----- Armor Header Line of the armored signature is not
considered part of the signed text.
Also, any trailing whitespace -- spaces (0x20) and tabs (0x09) -- at
the end of any line is removed before signing or verifying a
cleartext signed message.
Between the -----BEGIN PGP SIGNED MESSAGE----- line and the first
empty line, the only Armor Header permitted is a well-formed Hash
Armor Header (see Section 6.2.2.3). To reduce the risk of confusion
about what has been signed, a verifying implementation MUST decline
to validate any signature in a cleartext message if that message has
any other Armor Header present in this location.
7.2. 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 in "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.
When reversing dash-escaping, an implementation MUST strip the string
- if it occurs at the beginning of a line, and it SHOULD provide a
warning for - and any character other than a space at the beginning
of a line.
7.3. Issues with the Cleartext Signature Framework
Since creating a cleartext signed message 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.
Furthermore, a Cleartext Signature Framework message that is very
large is unlikely to work well. In particular, it will be difficult
for any human reading the message to know which part is covered by
the signature because they can't understand the whole message at
once, especially in the case where an Armor Header line is placed
somewhere in the body. And, very large Cleartext Signature Framework
messages cannot be processed in a single pass, since the signature
salt and digest algorithms are only discovered at the end.
An implementation that knows it is working with a textual stream with
any of the above characteristics SHOULD NOT use the Cleartext
Signature Framework. Safe alternatives for a semantically meaningful
OpenPGP signature over such a file format are:
* A signed message, as described in Section 10.3.
* A detached signature, as described in Section 10.4.
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.
Finally, when a Cleartext Signature Framework message is presented to
the user as is, an attacker can include additional text in the Hash
header, which may mislead the user into thinking it is part of the
signed text. The signature validation constraints described in
Sections 6.2.2.3 and 7.1 help to mitigate the risk of arbitrary or
misleading text in the Armor Headers.
8. Regular Expressions
This section describes Regular Expressions.
Regular Expression: Zero or more branches, separated by |. It
matches anything that matches one of the branches.
Branch: Zero or more pieces, concatenated. It matches a match for
the first, followed by a match for the second, etc.
Piece: 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.
Atom: A Regular Expression in parentheses (matching a match for the
Regular Expression), a range (see below), a . (matching any single
Unicode character), a ^ (matching the null string at the beginning
of the input string), a $ (matching the null string at the end of
the input string), a \ followed by a single Unicode character
(matching that character), or a single Unicode character with no
other significance (matching that character).
Range: A sequence of characters enclosed in []. It normally matches
any single character from the sequence. If the sequence begins
with ^, it matches any single Unicode 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 Unicode characters
between them in codepoint order (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 that is not on these lists, as long as the
algorithm IDs are chosen from the Private or Experimental Use
algorithm range.
See Section 12 for more discussion of the algorithms.
9.1. Public Key Algorithms
+===+==============+=========+============+===========+=============+
| ID| Algorithm |Public | Secret Key | Signature | PKESK |
| | |Key | Format | Format | Format |
| | |Format | | | |
+===+==============+=========+============+===========+=============+
| 0| Reserved | | | | |
+---+--------------+---------+------------+-----------+-------------+
| 1| RSA (Encrypt |MPI(n), | MPI(d), | MPI(m^d | MPI(m^e |
| | or Sign) |MPI(e) | MPI(p), | mod n) | mod n) |
| | [FIPS186] |[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 |MPI(e) | MPI(p), | | mod n) |
| | [FIPS186] |[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 |MPI(e) | MPI(p), | mod n) | |
| | [FIPS186] |[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 |
| | |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] | |
| | |[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, |
| | |[Sections| | | encoded |
| | |9.2.1 and| | | key |
| | |5.5.5.6] | | | [Sections |
| | | | | | 9.2.1, |
| | | | | | 5.1.5, |
| | | | | | and 11.5] |
+---+--------------+---------+------------+-----------+-------------+
| 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- | [Sections | |
| | |in | specific | 9.2.1 and | |
| | |prefixed | format) | 5.2.3.3] | |
| | |native | [Section | | |
| | |format) | 9.2.1] | | |
| | |[Sections| | | |
| | |11.2.2 | | | |
| | |and | | | |
| | |5.5.5.5] | | | |
+---+--------------+---------+------------+-----------+-------------+
| 23| Reserved | | | | |
| | (AEDH) | | | | |
+---+--------------+---------+------------+-----------+-------------+
| 24| Reserved | | | | |
| | (AEDSA) | | | | |
+---+--------------+---------+------------+-----------+-------------+
| 25| X25519 |32 octets| 32 octets | N/A | 32 |
| | |[Section | | | octets, |
| | |5.5.5.7] | | | size |
| | | | | | octet, |
| | | | | | encoded |
| | | | | | key |
| | | | | | [Section |
| | | | | | 5.1.6] |
+---+--------------+---------+------------+-----------+-------------+
| 26| X448 |56 octets| 56 octets | N/A | 56 |
| | |[Section | | | octets, |
| | |5.5.5.8] | | | size |
| | | | | | octet, |
| | | | | | encoded |
| | | | | | key |
| | | | | | [Section |
| | | | | | 5.1.7] |
+---+--------------+---------+------------+-----------+-------------+
| 27| Ed25519 |32 octets| 32 octets | 64 octets | |
| | |[Section | | [Section | |
| | |5.5.5.9] | | 5.2.3.4] | |
+---+--------------+---------+------------+-----------+-------------+
| 28| Ed448 |57 octets| 57 octets | 114 | |
| | |[Section | | octets | |
| | |5.5.5.10]| | [Section | |
| | | | | 5.2.3.5] | |
+---+--------------+---------+------------+-----------+-------------+
|100| Private or | | | | |
| to| Experimental | | | | |
|110| Use | | | | |
+---+--------------+---------+------------+-----------+-------------+
Table 18: OpenPGP Public Key Algorithms 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 12.4). Elgamal
(16) keys are deprecated and MUST NOT be generated (see
Section 12.6). DSA (17) keys are deprecated and MUST NOT be
generated (see Section 12.5). For notes on Elgamal Encrypt or Sign
(20) and X9.42 (21), see Section 12.8. Implementations MAY implement
any other algorithm.
Note that an implementation conforming to the previous version of
this specification [RFC4880] has only DSA (17) and Elgamal (16) as
the algorithms that MUST be implemented.
A compatible specification of ECDSA is given in [RFC6090] (as "KT-I
Signatures") and in [SEC1]; ECDH is defined in Section 11.5 of this
document.
9.2. ECC Curves for OpenPGP
The parameter curve OID is an array of octets that defines a named
curve.
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. Note that there is a break in
"EdDSALegacy" for display purposes only.
+======================+===+========+================+======+=======+
|ASN.1 Object |OID| Curve |Curve Name |Usage |Field |
|Identifier |Len| OID | | |Size |
| | | Octets | | |(fsize)|
+======================+===+========+================+======+=======+
|1.2.840.10045.3.1.7 |8 | 2A 86 |NIST P-256 |ECDSA,|32 |
| | | 48 CE | |ECDH | |
| | | 3D 03 | | | |
| | | 01 07 | | | |
+----------------------+---+--------+----------------+------+-------+
|1.3.132.0.34 |5 | 2B 81 |NIST P-384 |ECDSA,|48 |
| | | 04 00 | |ECDH | |
| | | 22 | | | |
+----------------------+---+--------+----------------+------+-------+
|1.3.132.0.35 |5 | 2B 81 |NIST P-521 |ECDSA,|66 |
| | | 04 00 | |ECDH | |
| | | 23 | | | |
+----------------------+---+--------+----------------+------+-------+
|1.3.36.3.3.2.8.1.1.7 |9 | 2B 24 |brainpoolP256r1 |ECDSA,|32 |
| | | 03 03 | |ECDH | |
| | | 02 08 | | | |
| | | 01 01 | | | |
| | | 07 | | | |
+----------------------+---+--------+----------------+------+-------+
|1.3.36.3.3.2.8.1.1.11 |9 | 2B 24 |brainpoolP384r1 |ECDSA,|48 |
| | | 03 03 | |ECDH | |
| | | 02 08 | | | |
| | | 01 01 | | | |
| | | 0B | | | |
+----------------------+---+--------+----------------+------+-------+
|1.3.36.3.3.2.8.1.1.13 |9 | 2B 24 |brainpoolP512r1 |ECDSA,|64 |
| | | 03 03 | |ECDH | |
| | | 02 08 | | | |
| | | 01 01 | | | |
| | | 0D | | | |
+----------------------+---+--------+----------------+------+-------+
|1.3.6.1.4.1.11591.15.1|9 | 2B 06 |Ed25519Legacy |EdDSA |32 |
| | | 01 04 | |Legacy| |
| | | 01 DA | | | |
| | | 47 0F | | | |
| | | 01 | | | |
+----------------------+---+--------+----------------+------+-------+
|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: OpenPGP ECC Curve OIDs 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. The curves specified
here, and scalars such as the base point order and the private key,
can be represented in fsize octets. However, note that curves exist
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 1 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
only in version 4 keys and signatures. Implementations MAY implement
these variants for compatibility with existing version 4 key material
and signatures. Implementations MUST NOT accept or generate version
6 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.
+================+========+============+=======+=========+==========+
|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 |N/A |N/A |N/A |
| |native |(Section | | | |
| | |5.5.5.6.1.1)| | | |
+----------------+--------+------------+-------+---------+----------+
Table 20: OpenPGP ECC Curve-Specific Wire Formats Registry
For the native octet-string forms of Ed25519Legacy values, see
[RFC8032]. For the native octet-string forms of Curve25519Legacy
secret scalars and points, see [RFC7748].
9.3. Symmetric Key Algorithms
+=========+============================================+
| ID | Algorithm |
+=========+============================================+
| 0 | Plaintext or unencrypted data |
+---------+--------------------------------------------+
| 1 | IDEA [IDEA] |
+---------+--------------------------------------------+
| 2 | TripleDES (or DES-EDE) [SP800-67] with |
| | 168-bit key derived from 192 |
+---------+--------------------------------------------+
| 3 | CAST5 with 128-bit key [RFC2144] |
+---------+--------------------------------------------+
| 4 | Blowfish with 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 |
+---------+--------------------------------------------+
| 100-110 | Private or Experimental Use |
+---------+--------------------------------------------+
| 253-255 | Reserved to avoid collision with Secret |
| | Key Encryption (Table 2 and Section 5.5.3) |
+---------+--------------------------------------------+
Table 21: OpenPGP Symmetric Key Algorithms 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 implementations predating support for [RFC2440].
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] |
+---------+-----------------------------+
| 2 | ZLIB [RFC1950] |
+---------+-----------------------------+
| 3 | BZip2 [BZ2] |
+---------+-----------------------------+
| 100-110 | Private or Experimental Use |
+---------+-----------------------------+
Table 22: OpenPGP Compression
Algorithms 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 |
+=========+==================+=============+========================+
| 0 | Reserved | | |
+---------+------------------+-------------+------------------------+
| 1 | MD5 [RFC1321] | "MD5" | N/A |
+---------+------------------+-------------+------------------------+
| 2 | SHA-1 [FIPS180] | "SHA1" | N/A |
+---------+------------------+-------------+------------------------+
| 3 | RIPEMD-160 | "RIPEMD160" | N/A |
| | [RIPEMD-160] | | |
+---------+------------------+-------------+------------------------+
| 4 | Reserved | | |
+---------+------------------+-------------+------------------------+
| 5 | Reserved | | |
+---------+------------------+-------------+------------------------+
| 6 | Reserved | | |
+---------+------------------+-------------+------------------------+
| 7 | Reserved | | |
+---------+------------------+-------------+------------------------+
| 8 | SHA2-256 | "SHA256" | 16 |
| | [FIPS180] | | |
+---------+------------------+-------------+------------------------+
| 9 | SHA2-384 | "SHA384" | 24 |
| | [FIPS180] | | |
+---------+------------------+-------------+------------------------+
| 10 | SHA2-512 | "SHA512" | 32 |
| | [FIPS180] | | |
+---------+------------------+-------------+------------------------+
| 11 | SHA2-224 | "SHA224" | 16 |
| | [FIPS180] | | |
+---------+------------------+-------------+------------------------+
| 12 | SHA3-256 | "SHA3-256" | 16 |
| | [FIPS202] | | |
+---------+------------------+-------------+------------------------+
| 13 | Reserved | | |
+---------+------------------+-------------+------------------------+
| 14 | SHA3-512 | "SHA3-512" | 32 |
| | [FIPS202] | | |
+---------+------------------+-------------+------------------------+
| 100-110 | Private or | | |
| | Experimental Use | | |
+---------+------------------+-------------+------------------------+
Table 23: OpenPGP Hash Algorithms Registry
+============+=========================+=========================+
| Hash | OID | Full Hash Prefix |
| Algorithm | | |
+============+=========================+=========================+
| MD5 | 1.2.840.113549.2.5 | 0x30, 0x20, 0x30, 0x0C, |
| | | 0x06, 0x08, 0x2A, 0x86, |
| | | 0x48, 0x86, 0xF7, 0x0D, |
| | | 0x02, 0x05, 0x05, 0x00, |
| | | 0x04, 0x10 |
+------------+-------------------------+-------------------------+
| SHA-1 | 1.3.14.3.2.26 | 0x30, 0x21, 0x30, 0x09, |
| | | 0x06, 0x05, 0x2B, 0x0E, |
| | | 0x03, 0x02, 0x1A, 0x05, |
| | | 0x00, 0x04, 0x14 |
+------------+-------------------------+-------------------------+
| RIPEMD-160 | 1.3.36.3.2.1 | 0x30, 0x21, 0x30, 0x09, |
| | | 0x06, 0x05, 0x2B, 0x24, |
| | | 0x03, 0x02, 0x01, 0x05, |
| | | 0x00, 0x04, 0x14 |
+------------+-------------------------+-------------------------+
| SHA2-256 | 2.16.840.1.101.3.4.2.1 | 0x30, 0x31, 0x30, 0x0D, |
| | | 0x06, 0x09, 0x60, 0x86, |
| | | 0x48, 0x01, 0x65, 0x03, |
| | | 0x04, 0x02, 0x01, 0x05, |
| | | 0x00, 0x04, 0x20 |
+------------+-------------------------+-------------------------+
| SHA2-384 | 2.16.840.1.101.3.4.2.2 | 0x30, 0x41, 0x30, 0x0D, |
| | | 0x06, 0x09, 0x60, 0x86, |
| | | 0x48, 0x01, 0x65, 0x03, |
| | | 0x04, 0x02, 0x02, 0x05, |
| | | 0x00, 0x04, 0x30 |
+------------+-------------------------+-------------------------+
| SHA2-512 | 2.16.840.1.101.3.4.2.3 | 0x30, 0x51, 0x30, 0x0D, |
| | | 0x06, 0x09, 0x60, 0x86, |
| | | 0x48, 0x01, 0x65, 0x03, |
| | | 0x04, 0x02, 0x03, 0x05, |
| | | 0x00, 0x04, 0x40 |
+------------+-------------------------+-------------------------+
| SHA2-224 | 2.16.840.1.101.3.4.2.4 | 0x30, 0x2D, 0x30, 0x0D, |
| | | 0x06, 0x09, 0x60, 0x86, |
| | | 0x48, 0x01, 0x65, 0x03, |
| | | 0x04, 0x02, 0x04, 0x05, |
| | | 0x00, 0x04, 0x1C |
+------------+-------------------------+-------------------------+
| SHA3-256 | 2.16.840.1.101.3.4.2.8 | 0x30, 0x31, 0x30, 0x0D, |
| | | 0x06, 0x09, 0x60, 0x86, |
| | | 0x48, 0x01, 0x65, 0x03, |
| | | 0x04, 0x02, 0x08, 0x05, |
| | | 0x00, 0x04, 0x20 |
+------------+-------------------------+-------------------------+
| SHA3-512 | 2.16.840.1.101.3.4.2.10 | 0x30, 0x51, 0x30, 0x0D, |
| | | 0x06, 0x09, 0x60, 0x86, |
| | | 0x48, 0x01, 0x65, 0x03, |
| | | 0x04, 0x02, 0x0a, 0x05, |
| | | 0x00, 0x04, 0x40 |
+------------+-------------------------+-------------------------+
Table 24: OpenPGP Hash Algorithm Identifiers for RSA
Signatures' Use of EMSA-PKCS1-v1_5 Padding Registry
Implementations MUST implement SHA2-256. Implementations SHOULD
implement SHA2-384 and SHA2-512. Implementations MAY implement other
algorithms. Implementations SHOULD NOT create messages that require
the use of SHA-1, with the exception of computing version 4 key
fingerprints for purposes of the MDC in version 1 Symmetrically
Encrypted and 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 generate packets
using MD5, SHA-1, or RIPEMD-160 as a hash function in an S2K KDF.
Implementations MUST NOT decrypt a secret using MD5, SHA-1, or
RIPEMD-160 as a hash function in an S2K KDF in a version 6 (or later)
packet. 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 | Name | Nonce Length | Authentication Tag |
| | | (Octets) | Length (Octets) |
+=========+==================+==============+====================+
| 0 | Reserved | | |
+---------+------------------+--------------+--------------------+
| 1 | EAX [EAX] | 16 | 16 |
+---------+------------------+--------------+--------------------+
| 2 | OCB [RFC7253] | 15 | 16 |
+---------+------------------+--------------+--------------------+
| 3 | GCM [SP800-38D] | 12 | 16 |
+---------+------------------+--------------+--------------------+
| 100-110 | Private or | | |
| | Experimental Use | | |
+---------+------------------+--------------+--------------------+
Table 25: OpenPGP AEAD Algorithms Registry
Implementations MUST implement OCB. Implementations MAY implement
EAX, GCM, and other algorithms.
10. Packet Sequence 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 10.1) and their close
counterpart, Transferable Secret Keys (Section 10.2)
* OpenPGP Messages (Section 10.3)
* Detached Signatures (Section 10.4)
Each sequence has an explicit grammar of what packet types (Table 3)
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). On the other
hand, unknown non-critical packets can appear anywhere within any
sequence. This provides a structured way to introduce new packets
into OpenPGP, 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, implementations of
the previous versions 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, if an implementation
encounters a critical packet of an inappropriate type according to
the relevant grammar, the implementation MUST reject the sequence
with an error.
10.1. Transferable Public Keys
OpenPGP users may transfer public keys. This section describes the
structure of public keys in transit to ensure interoperability. An
OpenPGP Transferable Public Key is also known as an OpenPGP
certificate, in order to distinguish it from both its constituent
Public Key packets (Sections 5.5.1.1 and 5.5.1.2) and the underlying
cryptographic key material.
10.1.1. OpenPGP Version 6 Certificate Structure
The format of an OpenPGP version 6 certificate is as follows.
Entries in square brackets are optional and ellipses indicate
repetition.
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 version 6 key uses a self-signed Direct Key signature to
store algorithm preferences.
Every subkey for a version 6 primary key MUST be a version 6 subkey.
Every subkey MUST have at least one Subkey Binding signature. Every
Subkey Binding signature MUST be a self-signature (that is, made by
the version 6 primary key). Like all other signatures, every self-
signature made by a version 6 key MUST be a version 6 signature.
10.1.2. OpenPGP Version 6 Revocation Certificate
When a primary version 6 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.
10.1.3. OpenPGP Version 4 Certificate Structure
The format of an OpenPGP version 4 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 version 3 or version 4
format, but they SHOULD be in version 4 format. Subkeys that can
issue signatures MUST have a version 4 binding signature due to the
REQUIRED embedded Primary Key Binding signature.
Every subkey for a version 4 primary key MUST be a version 4 subkey.
When a primary version 4 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 version 6 revocation certificate MUST
include the primary key packet, as described in Section 10.1.2.
10.1.4. OpenPGP Version 3 Key Structure
The format of an OpenPGP version 3 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. Version 3 keys are deprecated.
Implementations MUST NOT generate new version 3 keys but MAY continue
to use existing ones.
Version 3 keys MUST NOT have subkeys.
10.1.5. Common Requirements
The Public Key packet occurs first.
The primary key MUST be an algorithm capable of making signatures
(that is, not an encryption-only algorithm). This is because the
primary key needs to be able to create self-signatures (see
Section 5.2.3.10). 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 subkey, 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.
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 the 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, as long as the signatures that follow them are
maintained on the proper User Attribute or User ID packet.
After the sequence of User ID packets and Attribute packets and their
associated signatures, zero or more Subkey packets follow, each with
their own signatures. In general, subkeys are provided in cases
where the top-level public key is a certification-only key. However,
any version 4 or version 6 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 (Type ID 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 13.11). For maximum interoperability,
if the Public Key packet is a version 4 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 version 6
Public Key primary key MUST be able to accept (and ignore) the
trailing optional Padding packet.
Transferable Public Key packet sequences may be concatenated to allow
transferring multiple public keys in one operation (see Section 3.6).
10.2. 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 6.2.1). An implementation 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. An
implementation MAY choose to omit the self-signatures, especially if
a Transferable Public Key accompanies the Transferable Secret Key.
10.3. OpenPGP Messages
An OpenPGP Message is a packet or sequence of packets that adheres to
the following grammatical rules (a comma (,) represents sequential
composition, and a 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 and 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.
In addition to these rules, a Marker packet (Section 5.8) can appear
anywhere in the sequence.
10.3.1. 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 of 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.
10.3.2. Additional Constraints on Packet Sequences
Note that some subtle combinations that are formally acceptable by
this grammar are nonetheless unacceptable.
10.3.2.1. Packet Versions in Encrypted Messages
As noted above, an Encrypted Message is a sequence of zero or more
PKESK packets (Section 5.1) and SKESK packets (Section 5.3), followed
by an SEIPD (Section 5.13) payload. In some historic data, the
payload may be a deprecated SED packet (Section 5.7) instead of
SEIPD, though implementations MUST NOT generate SED packets (see
Section 13.7). 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.
v3 PKESK and v4 SKESK packets both contain the Symmetric Cipher
Algorithm ID and the session key for the subsequent SEIPD packet in
their cleartext. Since a v1 SEIPD does not contain a symmetric
algorithm ID, 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 ID, 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 IDs,
and for simplicity, implementations MUST NOT precede a v2 SEIPD
payload with either v3 PKESK or v4 SKESK packets.
The versions of packets found in an Encrypted Message are summarized
in the following table. An implementation MUST only generate an
Encrypted Message using packet versions that match a row with "Yes"
in the "Generate?" column. Other rows are provided for the purpose
of historic interoperability. A conforming implementation MUST only
generate an Encrypted Message using packets whose versions correspond
to a single row.
+==============+=====================+==================+===========+
| Version of | Version of | Version of | Generate? |
| Encrypted | Preceding Symmetric | Preceding | |
| Data Payload | Key ESK (If Any) | Public Key | |
| | | ESK (If Any) | |
+==============+=====================+==================+===========+
| SED (Section | - | v2 PKESK | No |
| 5.7) | | [RFC2440] | |
+--------------+---------------------+------------------+-----------+
| SED (Section | v4 SKESK | v3 PKESK | No |
| 5.7) | (Section 5.3.1) | (Section | |
| | | 5.1.1) | |
+--------------+---------------------+------------------+-----------+
| v1 SEIPD | v4 SKESK | v3 PKESK | Yes |
| (Section | (Section 5.3.1) | (Section | |
| 5.13.1) | | 5.1.1) | |
+--------------+---------------------+------------------+-----------+
| v2 SEIPD | v6 SKESK | v6 PKESK | Yes |
| (Section | (Section 5.3.2) | (Section | |
| 5.13.2) | | 5.1.2) | |
+--------------+---------------------+------------------+-----------+
Table 26: OpenPGP Encrypted Message Packet Versions Registry
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.
10.3.2.2. Packet Versions in Signatures
OpenPGP Key packets and Signature packets are also versioned. The
version of a Signature typically matches the version of the signing
key. When a version 6 key produces a Signature packet, it MUST
produce a version 6 Signature packet, regardless of the Signature
packet type. When a message is signed or verified using the one-pass
construction, the version of the One-Pass Signature packet
(Section 5.4) should also be aligned to the other versions.
Some legacy implementations have produced unaligned signature
versions for older key material, which are also described in the
table below for the purpose of historic interoperability. A
conforming implementation MUST only generate Signature packets with
version numbers matching rows with "Yes" in the "Generate?" column.
+=====================+================+============+===========+
| Signing Key Version | Signature | OPS Packet | Generate? |
| | Packet Version | Version | |
+=====================+================+============+===========+
| 3 (Section 5.5.2.1) | 3 (Section | 3 (Section | No |
| | 5.2.2) | 5.4) | |
+---------------------+----------------+------------+-----------+
| 4 (Section 5.5.2.2) | 3 (Section | 3 (Section | No |
| | 5.2.2) | 5.4) | |
+---------------------+----------------+------------+-----------+
| 4 (Section 5.5.2.2) | 4 (Section | 3 (Section | Yes |
| | 5.2.3) | 5.4) | |
+---------------------+----------------+------------+-----------+
| 6 (Section 5.5.2.3) | 6 (Section | 6 (Section | Yes |
| | 5.2.3) | 5.4) | |
+---------------------+----------------+------------+-----------+
Table 27: OpenPGP Key and Signature Versions Registry
Note, however, that a version mismatch between these packets does not
invalidate the packet sequence as a whole; it merely invalidates the
signature, as a signature with an unknown version SHOULD be discarded
(see Section 5.2.5).
10.4. 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.
11. 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]. Refer to [FIPS186], Appendix B.4, for the
methods to generate a uniformly distributed ECC private key.
None of the ECC methods described in this document are allowed with
deprecated version 3 keys.
11.1. 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". All six
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
[RFC7748] and Ed25519 and Ed448 [RFC8032]. Additionally, legacy OIDs
are defined for "Curve25519Legacy" (for encryption using the ECDH
algorithm) and "Ed25519Legacy" (for signing using the EdDSALegacy
algorithm).
11.2. 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 1 bit set to make the MPI a
constant size.
+=================+================+================+
| Name | Wire Format | Reference |
+=================+================+================+
| SEC1 | 0x04 || x || y | Section 11.2.1 |
+-----------------+----------------+----------------+
| Prefixed native | 0x40 || native | Section 11.2.2 |
+-----------------+----------------+----------------+
Table 28: OpenPGP Elliptic Curve Point Wire
Formats Registry
11.2.1. 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].
11.2.2. 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.
11.2.3. 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 an 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 other than the wire
format associated with the curve.
11.3. 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
they 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 encoded in big-endian format | Section |
| | as a standard OpenPGP MPI | 3.2 |
+----------+-------------------------------------------+-----------+
| octet | An octet string of fixed length that may | Section |
| string | be shorter on the wire due to leading | 11.3.1 |
| | 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 | 11.3.2 |
| | leading zero octet | |
+----------+-------------------------------------------+-----------+
Table 29: OpenPGP Elliptic Curve Scalar Encodings Registry
11.3.1. 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 5-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, set the MPI's 2-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 can take the following
steps, if it knows that X has an expected length of, for example, 5
octets:
* Ensure that the MPI's 2-octet bit count 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
11.3.2. EC Prefixed Octet String Wire Format
Another way to ensure that a fixed-length bytes string is encoded
simply to the wire while remaining in MPI format is to prefix the
byte string with a dedicated non-zero octet. This specification uses
0x40 as the prefix octet. This is represented in this specification
as MPI(prefixed N octets of X), where N is the known byte string
length.
For example, a 5-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, prefix it with the octet 0x40 (whose 7th bit is
set), and then set the MPI's 2-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 2-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 11.2.2.
11.4. 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.
// 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].
11.5. ECDH Algorithm
This section describes the One-Pass Diffie-Hellman method, which is a
combination of the ECC Diffie-Hellman method that establishes a
shared secret and the key derivation method that processes the shared
secret into a derived key. Additionally, this section describes 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 Cofactor
Diffie-Hellman (CDH) primitive employed by this method is modified to
always assume the cofactor is 1, the KDF specified in Section 11.4 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 bit string [SP800-56A]:
* A variable-length field containing a curve OID, which is formatted
as follows:
- A 1-octet size of the following field.
- The octets representing a curve OID, as defined in Section 9.2.
* A 1-octet public key algorithm ID, as 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
formatted as follows:
- A 1-octet size of the following fields; values 0 and 0xFF are
reserved for future extensions.
- A 1-octet value 0x01, reserved for future extensions.
- A 1-octet hash function ID used with the KDF.
- A 1-octet algorithm ID for the symmetric algorithm that is used
to wrap the symmetric key for message encryption; see
Section 11.5 for details.
* 20 octets representing the UTF-8 encoding of the string "Anonymous
Sender" padded at the end with spaces (0x20) to 20 octets, 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, as defined above,
for encrypting to a version 4 key is 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 version 6 key, the size of the sequence is 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 KEK as specified in [RFC3394].
Refer to Section 11.5.1 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].
To produce the input to the key wrapping method, first concatenate
the following values:
* The 1-octet algorithm identifier, if it was passed (in the case of
a v3 PKESK packet).
* The session key.
* A 2-octet checksum of the session key, equal to the sum of the
session key octets, modulo 65536.
Then, the above values are padded to an 8-octet granularity using the
method described in [RFC8018].
For example, in a version 3 Public Key Encrypted Session Key packet,
an AES-256 session key is encoded as follows, forming a 40-octet
sequence:
09 k0 k1 ... k31 s0 s1 05 05 05 05 05
The octets k0 to k31 above denote the session key, and the octets s0
and s1 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 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 version 6 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, single-use 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)
* Param = curve_OID_len || curve_OID || public_key_alg_ID || 03 ||
01 || KDF_hash_ID || KEK_alg_ID for AESKeyWrap || 41 6E 6F 6E 79
6D 6F 75 73 20 53 65 6E 64 65 72 20 20 20 20 ||
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 ) (per [RFC3394])
* Wipe the memory that contained S, v, and Z to avoid leaking
ephemeral secrets
* 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 with key pair (r,R) obtains the shared secret by
calculating:
S = rV = rvG
11.5.1. ECDH Parameters
ECDH keys have a hash algorithm parameter for key derivation and a
symmetric algorithm for key encapsulation.
For version 6 keys, the following algorithms MUST be used depending
on the curve. An implementation MUST NOT generate a version 6 ECDH
key over any listed curve that uses different KDF or KEK parameters.
An implementation MUST NOT encrypt any message to a version 6 ECDH
key over a listed curve that announces a different KDF or KEK
parameter.
For version 4 keys, the following algorithms SHOULD be used depending
on the curve. An implementation SHOULD only use an AES algorithm as
a KEK algorithm.
+==================+================+=====================+
| 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 |
+------------------+----------------+---------------------+
| Curve25519Legacy | SHA2-256 | AES-128 |
+------------------+----------------+---------------------+
Table 30: OpenPGP ECDH KDF and KEK Parameters Registry
12. Notes on Algorithms
12.1. PKCS#1 Encoding in OpenPGP
This specification makes use of the PKCS#1 functions EME-PKCS1-v1_5
and EMSA-PKCS1-v1_5. However, the calling conventions of these
functions have 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.
12.1.1. EME-PKCS1-v1_5-ENCODE
Input:
k = key modulus length in octets.
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".
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
pseudorandomly generated non-zero octets. The length of PS will
be at least 8 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.
12.1.2. EME-PKCS1-v1_5-DECODE
Input:
EM = encoded message; an octet string.
Output:
M = decoded 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 non-zero 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, the
second octet of EM does not have hexadecimal value 0x02, there is no
octet with hexadecimal value 0x00 to separate PS from M, or the
length of PS is less than 8 octets, output "decryption error" and
stop. See also Section 13.5 regarding differences in reporting
between a decryption error and a padding error.
12.1.3. EMSA-PKCS1-v1_5
This encoding method is deterministic and only has an encoding
operation.
Input:
Hash = hash function to be used.
M = message to be encoded.
emLen = intended length of the encoded message in octets, 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 hash value H:
H = Hash(M).
If the hash function outputs "message too long," output "message
too long" and stop.
2. Let T be the Full Hash Prefix from Table 24 for the given hash
function, concatenated with the hash digest H (representing an
ASN.1 DER value for the hash function used and the hash digest).
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.
12.2. 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 algorithm that MUST be implemented, 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. Furthermore, note that
implementations conforming to the previous version of this
specification [RFC4880] have TripleDES as the only algorithm that
MUST be implemented.
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
since the AES-128 algorithm MUST be implemented, the intersection is
guaranteed to be non-empty.
If an implementation can decrypt a message that a keyholder doesn't
have in their preferences, the implementation SHOULD decrypt the
message anyway, but it MUST warn the keyholder. For example, suppose
that Alice (above) has an implementation 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 implementation warns her that
someone sent an IDEA-encrypted message, but it would ideally decrypt
it anyway.
12.2.1. Plaintext
Algorithm 0, "plaintext", may only be used to denote secret keys that
are stored in the clear. An implementation MUST NOT use algorithm 0
as the indicated symmetric cipher for an encrypted data packet
(Sections 5.7 or 5.13); it can use a Literal Data packet
(Section 5.9) to encode unencrypted literal data.
12.3. 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 in which further comments
are needed: the compression preferences and the hash preferences.
12.3.1. 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.
12.3.1.1. Uncompressed
Algorithm 0, "uncompressed", may only be used to denote a preference
for uncompressed data. An implementation MUST NOT use algorithm 0 as
the indicated compression algorithm in a Compressed Data packet
(Section 5.6); it can use a Literal Data packet (Section 5.9) to
encode uncompressed literal data.
12.3.2. Hash Algorithm Preferences
Typically, the signer chooses which hash algorithm to use, rather
than the verifier, because a signer rarely knows who is going to be
verifying the signature. This preference 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 implementation
uses. This preference allows Bob to state which algorithms Alice may
use in his key.
Since SHA2-256 is the hash algorithm that MUST be implemented, if it
is not explicitly in the list, it is tacitly at the end. However, it
is good form to place it there explicitly.
12.4. 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 in favor of the Key Flags signature
subpacket. An implementation MUST NOT create such a key, but it MAY
interpret it.
An implementation MUST NOT generate RSA keys of a size less than 3072
bits. An implementation SHOULD NOT encrypt, sign, or verify using
RSA keys of a size less than 3072 bits. An implementation MUST NOT
encrypt, sign, or verify using RSA keys of a size less than 2048
bits. An implementation that decrypts a message using an RSA secret
key of a size less than 3072 bits SHOULD generate a deprecation
warning that the key is too weak for modern use.
12.5. DSA
DSA is no longer recommended. It has also been deprecated in
[FIPS186]. Therefore, an implementation MUST NOT generate DSA keys.
An implementation MUST NOT sign or verify using DSA keys.
12.6. 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.
12.7. EdDSA
Although the EdDSA algorithm allows arbitrary data as input, its use
with OpenPGP requires that a digest of the message be 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.
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.
12.8. Reserved Algorithm IDs
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 as reserved in Section 9.1.
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 the OpenPGP specification permitted Elgamal
[ELGAMAL] signatures with a public key algorithm ID of 20. These are
no longer permitted. An implementation MUST NOT generate such keys.
An implementation MUST NOT generate Elgamal signatures; see
[BLEICHENBACHER].
12.9. 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 used).
12.10. Private or Experimental Parameters
S2K Specifiers, Signature Subpacket Type IDs, User Attribute
Subpacket Type IDs, image format IDs, and the various algorithm IDs
described in Section 9 all reserve the range 100 to 110 for Private
and Experimental Use. Packet Type IDs reserve the range 60 to 63 for
Private and Experimental Use. These are intentionally managed by the
Private Use and Experimental Use policies, 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.
12.11. Meta Considerations for Expansion
If OpenPGP is extended in a way that is not backward compatible,
meaning that old implementations will not gracefully handle their
absence of a new feature, the extension proposal can be declared in
the keyholder's self-signature as part of the Features signature
subpacket.
We cannot state definitively what extensions will not be forward
compatible, but typically new algorithms are forward 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.
13. Security Considerations
* As with any technology involving cryptography, implementers should
check the current literature to determine if any algorithms used
here have been found to be vulnerable to an attack. If so,
implementers should consider disallowing such algorithms for new
data and warning the end user, or preventing use, when they are
trying to consume data protected by such algorithms that are now
vulnerable.
* 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 and SHA-1 hash algorithms have been found to have
weaknesses, with collisions found in a number of cases. MD5 and
SHA-1 are deprecated for use in OpenPGP (see Section 9.5).
* 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 version 4 key format with separate signature and
encryption keys. Using a single key for encrypting and signing is
discouraged.
* The DSA algorithm will work with any hash, but it 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 to ensure 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] contains recommendations
(current at the time of this publication) about equivalent
security levels of different algorithms.
* 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.
* Some of the encryption algorithms mentioned in this document have
been analyzed less than others. For example, although TWOFISH is
presently considered reasonably strong, it has been analyzed much
less than AES. Other algorithms may have other concerns
surrounding them.
* In late summer 2002, Jallad, Katz, and Schneier published an
interesting attack on previous versions of the OpenPGP
specification 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 13.7 for information on how
to defend against such an attack using more recent versions of
OpenPGP.
13.1. 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 version 4 public keys. In particular, the version 4
fingerprint derivation uses SHA-1. So as long as an OpenPGP
implementation supports version 4 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
reject the hash input deliberately 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].
13.2. Advantages of Salted Signatures
Version 6 signatures include a salt that is hashed first, and it's
size depends on the hashing algorithm. This makes version 6 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.
While the material to be signed could 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" [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 is 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, which mitigates this risk.
13.3. 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 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.
13.4. 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 when 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 encrypted data whose session key is protected by a
passphrase using a v4 SKESK, the quick check may be convenient to the
user by informing them early that they typed the wrong passphrase.
But 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 13.7.
13.5. 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, and 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
of PKESK processing errors as well as SEIPD integrity errors (this
also includes session key parsing errors, such as on an invalid
cipher algorithm for v3 PKESK, or a 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.
13.6. Fingerprint Usability
This specification uses fingerprints in several places on the wire
(e.g., Sections 5.2.3.23, 5.2.3.35, and 5.2.3.36) and in processing
(e.g., in ECDH KDF Section 11.5). 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. There is 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
[USENIX-STUDY].
The version 6 fingerprint makes the challenge for a human verifier
even worse. At 256 bits (compared to version 4's 160-bit
fingerprint), a version 6 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 version 4 fingerprints, this document does not attempt
to standardize any specific human-readable form of version 6
fingerprint for this discouraged use case.
NOTE: the topic of interoperable human-in-the-loop key verification
needs more work, which will be done in a separate document.
13.7. 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 [RFC4880] and later versions of OpenPGP offer
mechanisms to defend against it. However, OpenPGP data may have been
created before these defense 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 generate a clear error message
that indicates the integrity of the message is suspect, it SHOULD NOT
attempt to parse nor release decrypted data to the user, and it
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 it 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, 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 the 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 and Integrity Protected Data
packet (Section 5.13.1) where the internal Modification Detection
Code does not validate.
* Any version 2 Symmetrically Encrypted and 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.
* 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 253 (AEAD): where the AEAD authentication tag is invalid.
- Value 254 (CFB): where the SHA1 checksum is mismatched.
- Value 255 (MalleableCFB) or raw cipher algorithm: where the
trailing 2-octet checksum does not match.
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:
- If all recipient keys indicate support for a version 2
Symmetrically Encrypted and Integrity Protected Data packet in
their Features signature subpacket (Section 5.2.3.32), if all
recipient keys are version 6 keys without a Features signature
subpacket, or the implementation can otherwise infer that all
recipients support v2 SEIPD packets, the implementation SHOULD
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.
* Passphrase-protected secret key material in a version 6 Secret Key
or version 6 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. An
implementation should be aware that, in scenarios where an
attacker has write 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 are RECOMMENDED to migrate to AEAD.
13.8. Secure Use of the v2 SEIPD Session-Key-Reuse Feature
The salted key derivation of v2 SEIPD packets (Section 5.13.2) allows
the recipient of an encrypted message to reply to the sender and all
other recipients without needing their public keys but by using the
same v6 PKESK packets it received and a different random salt value.
This ensures a secure mechanism on the cryptographic level that
enables the use of message encryption in cases where a sender does
not have a copy of an encryption-capable certificate for one or more
participants in the conversation and thus can enhance the overall
security of an application. However, care must be taken when using
this mechanism not to create security vulnerabilities, such as the
following:
* Replying to only a subset of the original recipients and the
original sender by use of the session-key-reuse feature would mean
that the remaining recipients (including the sender) of the
original message could read the encrypted reply message, too.
* Adding a further recipient to the reply that is encrypted using
the session-key-reuse feature gives that further recipient also
cryptographic access to the original message that is being replied
to (and potentially to a longer history of previous messages).
* A modification of the list of recipients addressed in the above
points also needs to be safeguarded when a message is initially
composed as a reply with session-key reuse but then is stored
(e.g., as a draft) and later reopened for further editing and to
be finally sent.
* There is the potential threat that an attacker with network or
mailbox access, who is at the same time a recipient of the
original message, silently removes themselves from the message
before the victim's client receives it. The victim's client that
then uses the mechanism for replying with session-key reuse would
unknowingly compose an encrypted message that could be read by the
attacker. Implementations are encouraged to use the Intended
Recipient Fingerprint subpacket (Section 5.2.3.36) when composing
messages and checking the consistency of the set of recipients of
a message before replying to it with session-key reuse.
* When using the session-key-reuse feature in any higher-layer
protocol, care should be taken to ensure that there is no other
potentially interfering practice of session-key reuse established
in that protocol. Such interfering session-key reuse could, for
instance, be given -- if an initial message is already composed --
by reusing the session key of an existing encrypted file that may
have been shared among a group of users already. Using the
session-key-reuse feature to compose an encrypted reply to such a
message would unknowingly give this whole group of users
cryptographic access to the encrypted message.
* Generally, the use of the session-key-reuse feature should be
under the control of the user. Specifically, care should be taken
so that this feature is not silently used when the user assumes
that proper public key encryption is used. This can be the case,
for instance, when the public key of one of the recipients of the
reply is known but has expired. Special care should be taken to
ensure that users do not get caught in continued use of the
session-key reuse unknowingly but instead receive the chance to
switch to proper fresh public key encryption as soon as possible.
* Whenever possible, a client should prefer a fresh public key
encryption over the session-key reuse.
Even though this is not necessarily a security aspect, note that
initially composing an encrypted reply using the session-key-reuse
feature on one client and then storing it (e.g., as a draft) and
later reopening the stored unfinished reply with another client that
does not support the session-key-reuse feature may lead to
interoperability problems.
Avoiding the pitfalls described above requires context-specific
expertise. An implementation should only make use of the session-
key-reuse feature in any particular application layer when it can
follow reasonable documentation about how to deploy the feature
safely in the specific application. At the time of this writing,
there is no known documentation about safe reuse of OpenPGP session
keys for any specific context. An implementer that intends to make
use of this feature should publish their own proposed guidance for
others to review.
13.9. Escrowed Revocation Signatures
A keyholder, Alice, may wish to designate a third party to be able to
revoke her own key.
The preferred way for Alice to do this is to produce a specific
Revocation Signature (Signature Type ID 0x20, 0x28, or 0x30) and
distribute it securely to a 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 the 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.
13.10. 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 on Linux or BSD,
which should be used absent other (for example, performance)
concerns. It is RECOMMENDED to use an existing CSPRNG implementation
as opposed 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:
* 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.
* In entirely private data, such as asymmetric key generation.
With a properly functioning CSPRNG, this range of visibility 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.
13.11. 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 (3 octets) or no (2 octets) and the messages
are sent within a Symmetrically Encrypted and 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 (e.g.,
which individual is trying to contact another individual) 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).
13.12. 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, an implementation SHOULD implement the Intended
Recipient Fingerprint subpacket (Section 5.2.3.36).
13.13. Hashed vs. Unhashed Subpackets
Each OpenPGP signature can have subpackets in two different sections.
The first set of subpackets (the "hashed section") is covered by the
signature itself. The second set has no cryptographic protections
and is used for advisory material only, including locally stored
annotations about the signature.
For example, consider an implementation working with a specific
signature that happens to know that the signature was made by a
certain key, even though the signature contains no Issuer Fingerprint
subpacket (Section 5.2.3.35) in the hashed section. That
implementation MAY synthesize an Issuer Fingerprint subpacket and
store it in the unhashed section so that it will be able to recall
which key issued the signature in the future.
Some subpackets are only useful when they are in the hashed section,
and an implementation SHOULD ignore them when they are found with
unknown provenance in the unhashed section. For example, a Preferred
AEAD Ciphersuites subpacket (Section 5.2.3.15) in a Direct Key self-
signature indicates the preferences of the keyholder when encrypting
v2 SEIPD data to the key. An implementation that observes such a
subpacket found in the unhashed section would open itself to an
attack where the recipient's certificate is tampered with to
encourage the use of a specific cipher or mode of operation.
13.14. Malicious Compressed Data
It is possible to form a compression quine that produces itself upon
decompression, leading to infinite regress in any implementation
willing to parse arbitrary numbers of layers of compression. This
could cause resource exhaustion, which itself could lead to
termination by the operating system. If the operating system creates
a "crash report", that report could contain confidential information.
An OpenPGP implementation SHOULD limit the number of layers of
compression it is willing to decompress in a single message.
14. Implementation Considerations
This section is a collection of comments to help an implementer who
has a particular interest in 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 achieve backward compatibility.
* There are many possible ways for two keys to have the same key
material but different fingerprints (and thus different Key IDs).
For example, since a version 4 fingerprint is constructed by
hashing the key creation time along with other things, two version
4 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, 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.
* What this document calls the "Legacy packet format"
(Section 4.2.2) is what older documents called the "old packet
format". It is the packet format used by implementations
predating [RFC2440]. The current "OpenPGP packet format"
(Section 4.2.1) was called the "new packet format" by older RFCs.
This is the format introduced in [RFC2440] and maintained through
[RFC4880] to this document.
14.1. Constrained Legacy Fingerprint Storage for Version 6 Keys
Some OpenPGP implementations have fixed length constraints for key
fingerprint storage that will not fit all 32 octets of a version 6
fingerprint. For example, [OPENPGPCARD] reserves 20 octets for each
stored fingerprint.
An OpenPGP implementation MUST NOT attempt to map any part of a
version 6 fingerprint to such a constrained field unless the relevant
specification for the constrained environment has explicit guidance
for storing a version 6 fingerprint that distinguishes it from a
version 4 fingerprint. An implementation interacting with such a
constrained field SHOULD directly calculate the version 6 fingerprint
from public key material and associated metadata instead of relying
on the constrained field.
15. IANA Considerations
This document obsoletes [RFC4880]. IANA has updated all registration
information that references [RFC4880] to reference this RFC instead.
15.1. Renamed Protocol Group
IANA bundles a set of registries associated with a particular
protocol into a "protocol group". IANA has updated the name of the
"Pretty Good Privacy (PGP)" protocol group (i.e., the group of
registries described at <https://www.iana.org/assignments/pgp-
parameters>) to "OpenPGP". IANA has arranged a permanent redirect
from the existing URL to the new URL for the registries in this
protocol group. All further updates specified below are for
registries within this same OpenPGP protocol group.
15.2. Renamed and Updated Registries
IANA has renamed the "PGP String-to-Key (S2K)" registry to "OpenPGP
String-to-Key (S2K) Types" and updated its contents as shown in
Table 1.
IANA has renamed the "PGP Packet Types/Tags" registry to "OpenPGP
Packet Types" and updated its contents as shown in Table 3.
IANA has renamed the "Signature Subpacket Types" registry to "OpenPGP
Signature Subpacket Types" and updated its contents as shown in
Table 5.
IANA has renamed the "Key Server Preference Extensions" registry to
"OpenPGP Key Server Preference Flags" and updated its contents as
shown in Table 8.
IANA has renamed the "Key Flags Extensions" registry to "OpenPGP Key
Flags" and updated its contents as shown in Table 9.
IANA has renamed the "Reason for Revocation Extensions" registry to
"OpenPGP Reason for Revocation (Revocation Octet)" and updated its
contents as shown in Table 10.
IANA has renamed the "Implementation Features" registry to "OpenPGP
Features Flags" and updated its contents as shown in Table 11.
IANA has renamed the "PGP User Attribute Types" registry to "OpenPGP
User Attribute Subpacket Types" and updated its contents as shown in
Table 13.
IANA has renamed the "Image Format Subpacket Types" registry to
"OpenPGP Image Attribute Encoding Format" and updated its contents as
shown in Table 15.
IANA has renamed the "Public Key Algorithms" registry to "OpenPGP
Public Key Algorithms" and updated its contents as shown in Table 18.
IANA has renamed the "Symmetric Key Algorithms" registry to "OpenPGP
Symmetric Key Algorithms" and updated its contents as shown in
Table 21.
IANA has renamed the "Compression Algorithms" registry to "OpenPGP
Compression Algorithms" and updated its contents as shown in
Table 22.
IANA has renamed the "Hash Algorithms" registry to "OpenPGP Hash
Algorithms" and updated its contents as shown in Table 23.
15.3. Removed Registry
IANA has marked the empty "New Packet Versions" registry as OBSOLETE.
A tombstone note has been added to the OpenPGP protocol group with
the following content:
| Those wishing to use the removed "New Packet Versions" registry
| should instead register new versions of the relevant packets in
| the "OpenPGP Key and Signature Versions", "OpenPGP Key IDs and
| Fingerprints", and "OpenPGP Encrypted Message Packet Versions"
| registries.
15.4. Added Registries
IANA has added the following registries in the OpenPGP protocol
group. Note that the initial contents of each registry is shown in
the corresponding table.
* "OpenPGP Secret Key Encryption (S2K Usage Octet)" (Table 2).
* "OpenPGP Signature Types" (Table 4).
* "OpenPGP Signature Notation Data Subpacket Notation Flags"
(Table 6).
* "OpenPGP Signature Notation Data Subpacket Types" (Table 7).
* "OpenPGP Key IDs and Fingerprints" (Table 12).
* "OpenPGP Image Attribute Versions" (Table 14).
* "OpenPGP Armor Header Lines" (Table 16).
* "OpenPGP Armor Header Keys" (Table 17).
* "OpenPGP ECC Curve OIDs and Usage" (Table 19).
* "OpenPGP ECC Curve-Specific Wire Formats" (Table 20).
* "OpenPGP Hash Algorithm Identifiers for RSA Signatures' Use of
EMSA-PKCS1-v1_5 Padding" (Table 24).
* "OpenPGP AEAD Algorithms" (Table 25).
* "OpenPGP Encrypted Message Packet Versions" (Table 26).
* "OpenPGP Key and Signature Versions" (Table 27).
* "OpenPGP Elliptic Curve Point Wire Formats" (Table 28).
* "OpenPGP Elliptic Curve Scalar Encodings" (Table 29).
* "OpenPGP ECDH KDF and KEK Parameters" (Table 30).
15.5. Registration Policies
All registries within the OpenPGP protocol group, with the exception
of the registries listed in Section 15.5.1, use the Specification
Required registration policy; see Section 4.6 of [RFC8126]. This
policy means that review and approval by a designated expert is
required and that the IDs 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.
15.5.1. Registries That Use RFC Required
The following registries use the RFC Required registration policy, as
described in Section 4.7 of [RFC8126]:
* "OpenPGP Packet Types" (Table 3).
* "OpenPGP Key IDs and Fingerprints" (Table 12).
* "OpenPGP Encrypted Message Packet Versions" (Table 26).
* "OpenPGP Key and Signature Versions" (Table 27).
15.6. Designated Experts
The designated experts will determine whether the new registrations
retain the security properties that are expected by the base
implementation and whether these new registrations do not cause
interoperability issues with existing implementations, other than not
producing or consuming the IDs associated with these new
registrations. Registration proposals that fail to meet these
criteria could instead be proposed as new work items for the OpenPGP
Working Group or its successor.
The subsections below describe specific guidance for classes of
registry updates that a designated expert will consider.
The designated experts should also consider Section 12.11 when
reviewing proposed additions to the OpenPGP protocol group.
15.6.1. Key and Signature Versions
When defining a new version of OpenPGP Keys or Signatures, the
"OpenPGP Key and Signature Versions" registry (Table 27) should be
updated. When a new version of OpenPGP Key is defined, the "OpenPGP
Key IDs and Fingerprints" registry (Table 12) should also be updated.
15.6.2. Encryption Versions
When defining a new version of the Symmetrically Encrypted and
Integrity Protected Data packet (Section 5.13), Public Key Encrypted
Session Key packet (Section 5.1), and/or Symmetric Key Encrypted
Session Key packet (Section 5.3), the "OpenPGP Encrypted Message
Packet Versions" registry (Table 26) should be updated. When the
SEIPD is updated, consider also adding a corresponding flag to the
"OpenPGP Features Flags" registry (Table 11).
15.6.3. Algorithms
Section 9 lists the cryptographic and compression algorithms that
OpenPGP uses. Adding new algorithms is usually simple; in some
cases, allocating an ID and pointing to a reference is only needed.
But some algorithm registries require some subtle additional details
when a new algorithm is introduced.
15.6.3.1. Elliptic Curve Algorithms
To register a new elliptic curve for use with OpenPGP, its OID needs
to be registered in the "OpenPGP ECC Curve OIDs and Usage" registry
(Table 19), its wire format needs to be documented in the "OpenPGP
ECC Curve-Specific Wire Formats" registry (Table 20), and if used for
ECDH, its KDF and KEK parameters must be populated in the "OpenPGP
ECDH KDF and KEK Parameters" registry (Table 30). If the wire
format(s) used is not already defined in the "OpenPGP Elliptic Curve
Point Wire Formats" (Table 28) or "OpenPGP Elliptic Curve Scalar
Encodings" (Table 29) registries, they should be defined there as
well.
15.6.3.2. Symmetric Key Algorithms
When registering a new symmetric cipher with a block size of 64 or
128 bits and a key size that is a multiple of 64 bits, no new
considerations are needed.
If the new cipher has a different block size, there needs to be
additional documentation describing how to use the cipher in CFB
mode.
If the new cipher has an unusual key size, then padding needs to be
considered for X25519 and X448 key wrapping, which currently needs no
padding.
15.6.3.3. Hash Algorithms
When registering a new hash algorithm in the "OpenPGP Hash
Algorithms" registry (Table 23), if the algorithm is also to be used
with RSA signing schemes, it must also have an entry in the "OpenPGP
Hash Algorithm Identifiers for RSA Signatures' Use of EMSA-PKCS1-v1_5
Padding" registry (Table 24).
16. References
16.1. Normative References
[AES] NIST, "Advanced Encryption Standard (AES)", Updated May
2023, FIPS PUB 197, DOI 10.6028/NIST.FIPS.197-upd1,
November 2001, <https://nvlpubs.nist.gov/nistpubs/FIPS/
NIST.FIPS.197-upd1.pdf>.
[BLOWFISH] Schneier, B., "Description of a New Variable-Length Key,
64-Bit Block Cipher (Blowfish)", Fast Software Encryption,
Cambridge Security Workshop Proceedings, pp. 191-204,
December 1993,
<https://www.schneier.com/academic/archives/1994/09/
description_of_a_new.html>.
[BZ2] bzip2, "bzip2 and libbzip2", 2010,
<https://sourceware.org/bzip2/>.
[EAX] Bellare, M., Rogaway, P., and D. Wagner, "A Conventional
Authenticated-Encryption Mode", April 2003,
<https://seclab.cs.ucdavis.edu/papers/eax.pdf>.
[ELGAMAL] Elgamal, T., "A Public Key Cryptosystem and a Signature
Scheme Based on Discrete Logarithms", IEEE Transactions on
Information Theory, Vol. 31, Issue 4, pp. 469-472,
DOI 10.1109/TIT.1985.1057074, July 1985,
<https://doi.org/10.1109/TIT.1985.1057074>.
[FIPS180] NIST, "Secure Hash Standard (SHS)", FIPS PUB 180-4,
DOI 10.6028/NIST.FIPS.180-4, August 2015,
<https://nvlpubs.nist.gov/nistpubs/fips/
nist.fips.180-4.pdf>.
[FIPS186] NIST, "Digital Signature Standard (DSS)", FIPS PUB 186-5,
DOI 10.6028/NIST.FIPS.186-5, February 2023,
<https://nvlpubs.nist.gov/nistpubs/FIPS/
NIST.FIPS.186-5.pdf>.
[FIPS202] NIST, "SHA-3 Standard: Permutation-Based Hash and
Extendable-Output Functions", FIPS PUB 202,
DOI 10.6028/NIST.FIPS.202, August 2015,
<https://nvlpubs.nist.gov/nistpubs/fips/
nist.fips.202.pdf>.
[IDEA] Lai, X. and J. L. Massey, "A Proposal for a New Block
Encryption Standard", Advances in Cryptology - EUROCRYPT
'90, Vol. 473, pp. 389-404, DOI 10.1007/3-540-46877-3_35,
January 1991, <https://link.springer.com/
chapter/10.1007/3-540-46877-3_35>.
[ISO10646] ISO, "Information technology - Universal coded character
set (UCS)", ISO/IEC 10646:2020, December 2020,
<https://www.iso.org/standard/76835.html>.
[JFIF] ITU-T, "Information technology - Digital compression and
coding of continuous-tone still images: JPEG File
Interchange Format (JFIF)", Recommendation ITU-T T.871,
May 2011, <https://www.itu.int/rec/T-REC-T.871-201105-I>.
[RFC1321] Rivest, R., "The MD5 Message-Digest Algorithm", RFC 1321,
DOI 10.17487/RFC1321, April 1992,
<https://www.rfc-editor.org/info/rfc1321>.
[RFC1950] Deutsch, P. and J. Gailly, "ZLIB Compressed Data Format
Specification version 3.3", RFC 1950,
DOI 10.17487/RFC1950, May 1996,
<https://www.rfc-editor.org/info/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/info/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/info/rfc2119>.
[RFC2144] Adams, C., "The CAST-128 Encryption Algorithm", RFC 2144,
DOI 10.17487/RFC2144, May 1997,
<https://www.rfc-editor.org/info/rfc2144>.
[RFC2822] Resnick, P., Ed., "Internet Message Format", RFC 2822,
DOI 10.17487/RFC2822, April 2001,
<https://www.rfc-editor.org/info/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/info/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/info/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/info/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/info/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/info/rfc4086>.
[RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data
Encodings", RFC 4648, DOI 10.17487/RFC4648, October 2006,
<https://www.rfc-editor.org/info/rfc4648>.
[RFC5322] Resnick, P., Ed., "Internet Message Format", RFC 5322,
DOI 10.17487/RFC5322, October 2008,
<https://www.rfc-editor.org/info/rfc5322>.
[RFC6234] Eastlake 3rd, D. and T. Hansen, "US Secure Hash Algorithms
(SHA and SHA-based HMAC and HKDF)", RFC 6234,
DOI 10.17487/RFC6234, May 2011,
<https://www.rfc-editor.org/info/rfc6234>.
[RFC7253] Krovetz, T. and P. Rogaway, "The OCB Authenticated-
Encryption Algorithm", RFC 7253, DOI 10.17487/RFC7253, May
2014, <https://www.rfc-editor.org/info/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/info/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/info/rfc8017>.
[RFC8018] Moriarty, K., Ed., Kaliski, B., and A. Rusch, "PKCS #5:
Password-Based Cryptography Specification Version 2.1",
RFC 8018, DOI 10.17487/RFC8018, January 2017,
<https://www.rfc-editor.org/info/rfc8018>.
[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/info/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/info/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/info/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/info/rfc9106>.
[RIPEMD-160]
ISO, "Information technology - Security techniques - Hash-
functions - Part 3: Dedicated hash-functions", ISO/
IEC 10118-3:1998, May 1998.
[SP800-38A]
NIST, "Recommendation for Block Cipher Modes of Operation:
Methods and Techniques", NIST Special Publication 800-38A,
DOI 10.6028/NIST.SP.800-38A, December 2001,
<https://nvlpubs.nist.gov/nistpubs/legacy/sp/
nistspecialpublication800-38a.pdf>.
[SP800-38D]
NIST, "Recommendation for Block Cipher Modes of Operation:
Galois/Counter Mode (GCM) and GMAC", NIST Special
Publication 800-38D, DOI 10.6028/NIST.SP.800-38D, November
2007, <https://nvlpubs.nist.gov/nistpubs/legacy/sp/
nistspecialpublication800-38d.pdf>.
[SP800-56A]
NIST, "Recommendation for Pair-Wise Key Establishment
Schemes Using Discrete Logarithm Cryptography", NIST
Special Publication 800-56A Revision 3,
DOI 10.6028/NIST.SP.800-56Ar, April 2018,
<https://nvlpubs.nist.gov/nistpubs/SpecialPublications/
nist.sp.800-56Ar3.pdf>.
[SP800-67] NIST, "Recommendation for the Triple Data Encryption
Algorithm (TDEA) Block Cipher", NIST Special
Publication 800-67 Revision 2,
DOI 10.6028/NIST.SP.800-67r2, November 2017,
<https://nvlpubs.nist.gov/nistpubs/SpecialPublications/
NIST.SP.800-67r2.pdf>.
[TWOFISH] Schneier, B., Kelsey, J., Whiting, D., Wagner, D., Hall,
C., and N. Ferguson, "Twofish: A 128-Bit Block Cipher",
June 1998, <https://www.schneier.com/wp-
content/uploads/2016/02/paper-twofish-paper.pdf>.
16.2. Informative References
[BLEICHENBACHER]
Bleichenbacher, D., "Generating ElGamal Signatures Without
Knowing the Secret Key", EUROCRYPT'96: International
Conference on the Theory and Applications of Cryptographic
Techniques Proceedings, Vol. 1070, pp. 10-18, May 1996.
[BLEICHENBACHER-PKCS1]
Bleichenbacher, D., "Chosen Ciphertext Attacks Against
Protocols Based on the RSA Encryption Standard PKCS #1",
CRYPTO '98: International Cryptology Conference
Proceedings, Vol. 1462, pp. 1-12, August 1998,
<http://archiv.infsec.ethz.ch/education/fs08/secsem/
Bleichenbacher98.pdf>.
[C99] ISO, "Information technology - Programming languages: C",
ISO/IEC 9899:2018, June 2018,
<https://www.iso.org/standard/74528.html>.
[CHECKOWAY]
Checkoway, S., Maskiewicz, J., Garman, C., Fried, J.,
Cohney, S., Green, M., Heninger, N., Weinmann, RP.,
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 Security Symposium, August 2018,
<https://www.usenix.org/system/files/conference/
usenixsecurity18/sec18-poddebniak.pdf>.
[Errata-2199]
RFC Errata, Erratum ID 2199, RFC 4880,
<https://www.rfc-editor.org/errata/eid2199>.
[Errata-2200]
RFC Errata, Erratum ID 2200, RFC 4880,
<https://www.rfc-editor.org/errata/eid2200>.
[Errata-2206]
RFC Errata, Erratum ID 2206, RFC 4880,
<https://www.rfc-editor.org/errata/eid2206>.
[Errata-2208]
RFC Errata, Erratum ID 2208, RFC 4880,
<https://www.rfc-editor.org/errata/eid2208>.
[Errata-2214]
RFC Errata, Erratum ID 2214, RFC 4880,
<https://www.rfc-editor.org/errata/eid2214>.
[Errata-2216]
RFC Errata, Erratum ID 2216, RFC 4880,
<https://www.rfc-editor.org/errata/eid2216>.
[Errata-2219]
RFC Errata, Erratum ID 2219, RFC 4880,
<https://www.rfc-editor.org/errata/eid2219>.
[Errata-2222]
RFC Errata, Erratum ID 2222, RFC 4880,
<https://www.rfc-editor.org/errata/eid2222>.
[Errata-2226]
RFC Errata, Erratum ID 2226, RFC 4880,
<https://www.rfc-editor.org/errata/eid2226>.
[Errata-2234]
RFC Errata, Erratum ID 2234, RFC 4880,
<https://www.rfc-editor.org/errata/eid2234>.
[Errata-2235]
RFC Errata, Erratum ID 2235, RFC 4880,
<https://www.rfc-editor.org/errata/eid2235>.
[Errata-2236]
RFC Errata, Erratum ID 2236, RFC 4880,
<https://www.rfc-editor.org/errata/eid2236>.
[Errata-2238]
RFC Errata, Erratum ID 2238, RFC 4880,
<https://www.rfc-editor.org/errata/eid2238>.
[Errata-2240]
RFC Errata, Erratum ID 2240, RFC 4880,
<https://www.rfc-editor.org/errata/eid2240>.
[Errata-2242]
RFC Errata, Erratum ID 2242, RFC 4880,
<https://www.rfc-editor.org/errata/eid2242>.
[Errata-2243]
RFC Errata, Erratum ID 2243, RFC 4880,
<https://www.rfc-editor.org/errata/eid2243>.
[Errata-2270]
RFC Errata, Erratum ID 2270, RFC 4880,
<https://www.rfc-editor.org/errata/eid2270>.
[Errata-2271]
RFC Errata, Erratum ID 2271, RFC 4880,
<https://www.rfc-editor.org/errata/eid2271>.
[Errata-3298]
RFC Errata, Erratum ID 3298, RFC 4880,
<https://www.rfc-editor.org/errata/eid3298>.
[Errata-5491]
RFC Errata, Erratum ID 5491, RFC 4880,
<https://www.rfc-editor.org/errata/eid5491>.
[Errata-7545]
RFC Errata, Erratum ID 7545, RFC 4880,
<https://www.rfc-editor.org/errata/eid7545>.
[Errata-7889]
RFC Errata, Erratum ID 7889, RFC 4880,
<https://www.rfc-editor.org/errata/eid7889>.
[HASTAD] Hastad, J., "Solving Simultaneous Modular Equations of Low
Degree", DOI 10.1137/0217019, April 1988,
<https://doi.org/10.1137/0217019>.
[JKS02] Jallad, K., Katz, J., and B. Schneier, "Implementation of
Chosen-Ciphertext Attacks against PGP and GnuPG",
DOI 0.1007/3-540-45811-5_7, September 2002,
<https://www.schneier.com/academic/archives/2002/01/
implementation_of_ch.html>.
[KOBLITZ] Koblitz, N., "A course in number theory and cryptography",
Chapter VI: Elliptic Curves, DOI 10.2307/3618498, 1997,
<https://doi.org/10.2307/3618498>.
[KOPENPGP] Bruseghini, L., Paterson, K. G., and D. Huigens, "Victory
by KO: Attacking OpenPGP Using Key Overwriting",
Proceedings of the ACM SIGSAC Conference on Computer and
Communications Security, pp. 411-423,
DOI 10.1145/3548606.3559363, November 2022,
<https://dl.acm.org/doi/10.1145/3548606.3559363>.
[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, Paper 2002/076, March 2001,
<https://eprint.iacr.org/2002/076>.
[MRLG15] Maury, F., Reinhard, JR., Levillain, O., and H. Gilbert,
"Format Oracles on OpenPGP", Topics in Cryptology -- CT-
RSA 2015, Vol. 9048, pp. 220-236,
DOI 10.1007/978-3-319-16715-2_12, January 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", Cryptology ePrint Archive,
Paper 2005/033, 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, March 2020, <https://gnupg.org/ftp/specs/OpenPGP-
smart-card-application-3.4.1.pdf>.
[PAX] The Open Group, "The Open Group Base Specifications", 'pax
- portable archive interchange', Issue 7, 2018 Edition,
IEEE Std 1003.1-2017, 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", Cryptology ePrint Archive, Paper
2017/1014, October 2017,
<https://eprint.iacr.org/2017/1014>.
[REGEX] regex, "Henry Spencer's regular expression libraries",
<https://garyhouston.github.io/regex/>.
[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/info/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/info/rfc2440>.
[RFC2978] Freed, N. and J. Postel, "IANA Charset Registration
Procedures", BCP 19, RFC 2978, DOI 10.17487/RFC2978,
October 2000, <https://www.rfc-editor.org/info/rfc2978>.
[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/info/rfc4880>.
[RFC5581] Shaw, D., "The Camellia Cipher in OpenPGP", RFC 5581,
DOI 10.17487/RFC5581, June 2009,
<https://www.rfc-editor.org/info/rfc5581>.
[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/info/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/info/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/info/rfc6090>.
[RFC6637] Jivsov, A., "Elliptic Curve Cryptography (ECC) in
OpenPGP", RFC 6637, DOI 10.17487/RFC6637, June 2012,
<https://www.rfc-editor.org/info/rfc6637>.
[SEC1] Standards for Efficient Cryptography Group, "SEC 1:
Elliptic Curve Cryptography", May 2009,
<https://www.secg.org/sec1-v2.pdf>.
[SHA1CD] "sha1collisiondetection", commit b4a7b0b, December 2020,
<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", August 2020,
<https://dl.acm.org/doi/abs/10.5555/3489212.3489316/>.
[SP800-131A]
NIST, "Transitioning the Use of Cryptographic Algorithms
and Key Lengths", NIST Special Publication 800-131A,
Revision 2, DOI 10.6028/NIST.SP.800-131Ar2, March 2019,
<https://nvlpubs.nist.gov/nistpubs/SpecialPublications/
NIST.SP.800-131Ar2.pdf>.
[SP800-57] NIST, "Recommendation for Key Management: Part 1 -
General", NIST Special Publication 800-57 Part 1, Revision
5, DOI 10.6028/NIST.SP.800-57pt1r5, May 2020,
<https://nvlpubs.nist.gov/nistpubs/SpecialPublications/
NIST.SP.800-57pt1r5.pdf>.
[STEVENS2013]
Stevens, M., "Counter-cryptanalysis", Cryptology ePrint
Archive, Paper 2013/358, June 2013,
<https://eprint.iacr.org/2013/358>.
[UNIFIED-DIFF]
Free Software Foundation, "Comparing and Merging Files",
'Detailed Description of Unified Format', Section 2.2.2.2,
January 2021,
<https://www.gnu.org/software/diffutils/manual/html_node/
Detailed-Unified.html>.
[USENIX-STUDY]
Dechand, S., Schürmann, D., Busse, K., Acar, Y., Fahl, S.,
and M. Smith, "An Empirical Study of Textual Key-
Fingerprint Representations", ISBN 978-1-931971-32-4,
August 2016,
<https://www.usenix.org/system/files/conference/
usenixsecurity16/sec16_paper_dechand.pdf>.
Appendix A. Test Vectors
To help with the implementation of this specification, a set of non-
normative examples follow.
A.1. Sample Version 4 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-----
A.2. Sample Version 4 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 the
following 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 Version 6 Certificate (Transferable Public Key)
Here is a Transferable Public Key consisting of:
* A version 6 Ed25519 Public Key packet
* A version 6 Direct Key self-signature
* A version 6 X25519 Public Subkey packet
* A version 6 Subkey Binding signature
The primary key has the following fingerprint:
CB186C4F0609A697E4D52DFA6C722B0C1F1E27C18A56708F6525EC27BAD9ACC9
The subkey has the following fingerprint:
12C83F1E706F6308FE151A417743A1F033790E93E9978488D1DB378DA9930885
-----BEGIN PGP PUBLIC KEY BLOCK-----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-----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
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 key packet
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 6
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: {v1SEIPD, v2SEIPD}
0x0070 22 subpkt length
0x0071 21 subpkt type: Issuer Fingerprint
0x0072 06 Fingerprint version 6
0x0073 cb 18 6c 4f 06 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 6
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 key packet
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 key packet
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 6
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 6
0x00b3 ff sentinel octet
0x00b4 00 00 00 34 trailer length
A.4. Sample Version 6 Secret Key (Transferable Secret Key)
Here is a Transferable Secret Key consisting of:
* A version 6 Ed25519 Secret Key packet
* A version 6 Direct Key self-signature
* A version 6 X25519 Secret Subkey packet
* A version 6 Subkey Binding signature
-----BEGIN PGP PRIVATE KEY BLOCK-----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-----END PGP PRIVATE KEY BLOCK-----
The corresponding Transferable Public Key can be found in
Appendix A.3.
A.5. Sample Locked Version 6 Secret Key (Transferable Secret Key)
Here is the same secret key as in Appendix A.4, but the secret key
material is locked with a passphrase using AEAD and Argon2.
The passphrase is the ASCII string:
correct horse battery staple
-----BEGIN PGP PRIVATE KEY BLOCK-----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-----END PGP PRIVATE KEY BLOCK-----
A.5.1. Intermediate Data for Locked Primary Key
The S2K-derived material for the primary key is:
832bd2662a5c2b251ee3fc82aec349a766ca539015880133002e5a21960b3bcf
After HKDF, the symmetric key used for AEAD encryption of the primary
key is:
9e37cb26787f37e18db172795c4c297550d39ac82511d9af4c8706db6a77fd51
The additional data for AEAD for the primary key is:
c50663877fe31b00000020f94da7bb48d60a61e567706a6587d0331999bb9d89
1a08242ead84543df895a3
A.5.2. Intermediate Data for Locked Subkey
The S2K-derived key material for the subkey is:
f74a6ce873a089ef13a3da9ac059777bb22340d15eaa6c9dc0f8ef09035c67cd
After HKDF, the symmetric key used for AEAD encryption of the subkey
is:
3c60cb63285f62f4c3de49835786f011cf6f4c069f61232cd7013ff5fd31e603
The additional data for AEAD for the subkey is:
c70663877fe319000000208693248367f9e5015db922f8f48095dda784987f2d
5985b12fbad16caf5e4435
A.6. Sample Cleartext Signed Message
Here is a signed message that uses the Cleartext Signature Framework
(Section 7). It can be verified with the certificate from
Appendix A.3.
Note that this message makes use of dash-escaping (Section 7.2) due
to its contents.
-----BEGIN PGP SIGNED MESSAGE-----
What we need from the grocery store:
- - tofu
- - vegetables
- - noodles
-----BEGIN PGP SIGNATURE-----
wpgGARsKAAAAKQWCY5ijYyIhBssYbE8GCaaX5NUt+mxyKwwfHifBilZwj2Ul7Ce6
2azJAAAAAGk2IHZJX1AhiJD39eLuPBgiUU9wUA9VHYblySHkBONKU/usJ9BvuAqo
/FvLFuGWMbKAdA+epq7V4HOtAPlBWmU8QOd6aud+aSunHQaaEJ+iTFjP2OMW0KBr
NK2ay45cX1IVAQ==
-----END PGP SIGNATURE-----
The Signature packet here is:
0x0000 c2 packet type: Signature
0x0001 98 packet length
0x0002 06 sig version 6
0x0003 01 sig type: Canonical Text
0x0004 1b pubkey algorithm: Ed25519
0x0005 0a hash algorithm used: SHA2-512
0x0006 00 00 hashed subpackets length: 41
0x0008 00 29
0x000a 05 subpkt length
0x000b 82 critical subpkt: Sig Creation Time
0x000c 63 98 a3 63 (2022-12-13T16:08:03Z)
0x0010 22 subpkt length
0x0011 21 subpkt type: Issuer Fingerprint
0x0012 06 Fingerprint version 6
0x0013 cb 18 6c 4f 06 Fingerprint
0x001a 09 a6 97 e4 d5 2d fa 6c
0x0020 72 2b 0c 1f 1e 27 c1 8a
0x0028 56 70 8f 65 25 ec 27 ba
0x0030 d9 ac c9
0x0033 00 00 00 00 unhashed subpackets length: 0
0x0037 69 left 16 bits of signed hash
0x0038 36
0x0039 20 salt length
0x003a 76 49 5f 50 21 88 salt
0x0040 90 f7 f5 e2 ee 3c 18 22
0x0048 51 4f 70 50 0f 55 1d 86
0x0050 e5 c9 21 e4 04 e3 4a 53
0x0058 fb ac
0x005a 27 d0 6f b8 0a a8 Ed25519 signature
0x0060 fc 5b cb 16 e1 96 31 b2
0x0068 80 74 0f 9e a6 ae d5 e0
0x0070 73 ad 00 f9 41 5a 65 3c
0x0078 40 e7 7a 6a e7 7e 69 2b
0x0080 a7 1d 06 9a 10 9f a2 4c
0x0088 58 cf d8 e3 16 d0 a0 6b
0x0090 34 ad 9a cb 8e 5c 5f 52
0x0098 15 01
The signature is made over the following data:
0x0000 76 49 5f 50 21 88 90 f7
0x0008 f5 e2 ee 3c 18 22 51 4f
0x0010 70 50 0f 55 1d 86 e5 c9
0x0018 21 e4 04 e3 4a 53 fb ac
0x0020 57 68 61 74 20 77 65 20
0x0028 6e 65 65 64 20 66 72 6f
0x0030 6d 20 74 68 65 20 67 72
0x0038 6f 63 65 72 79 20 73 74
0x0040 6f 72 65 3a 0d 0a 0d 0a
0x0048 2d 20 74 6f 66 75 0d 0a
0x0050 2d 20 76 65 67 65 74 61
0x0058 62 6c 65 73 0d 0a 2d 20
0x0060 6e 6f 6f 64 6c 65 73 0d
0x0068 0a 06 01 1b 0a 00 00 00
0x0070 29 05 82 63 98 a3 63 22
0x0078 21 06 cb 18 6c 4f 06 09
0x0080 a6 97 e4 d5 2d fa 6c 72
0x0088 2b 0c 1f 1e 27 c1 8a 56
0x0090 70 8f 65 25 ec 27 ba d9
0x0098 ac c9 06 ff 00 00 00 31
The same data, broken out by octet and semantics, is:
0x0000 76 49 5f 50 21 88 90 f7 salt
0x0008 f5 e2 ee 3c 18 22 51 4f
0x0010 70 50 0f 55 1d 86 e5 c9
0x0018 21 e4 04 e3 4a 53 fb ac
[ message begins ]
0x0020 57 68 61 74 20 77 65 20 canonicalized message
0x0028 6e 65 65 64 20 66 72 6f
0x0030 6d 20 74 68 65 20 67 72
0x0038 6f 63 65 72 79 20 73 74
0x0040 6f 72 65 3a 0d 0a 0d 0a
0x0048 2d 20 74 6f 66 75 0d 0a
0x0050 2d 20 76 65 67 65 74 61
0x0058 62 6c 65 73 0d 0a 2d 20
0x0060 6e 6f 6f 64 6c 65 73 0d
0x0068 0a
[ trailer begins ]
0x0069 06 sig version 6
0x006a 01 sig type: Canonical Text
0x006b 1b pubkey algorithm: Ed25519
0x006c 0a hash algorithm: SHA2-512
0x006d 00 00 00 hashed subpackets length
0x0070 29
0x0071 05 subpacket length
0x0072 82 critical subpkt: Sig Creation Time
0x0073 63 98 a3 63 (2022-12-13T16:08:03Z)
0x0077 22 subpkt length
0x0078 21 subpkt type: Issuer Fingerprint
0x0079 06 Fingerprint version 6
0x007a cb 18 6c 4f 06 09 Fingerprint
0x0080 a6 97 e4 d5 2d fa 6c 72
0x0088 2b 0c 1f 1e 27 c1 8a 56
0x0090 70 8f 65 25 ec 27 ba d9
0x0098 ac c9
0x009a 06 sig version 6
0x009b ff sentinel octet
0x009c 00 00 00 31 trailer length
The calculated SHA2-512 hash digest over this data is:
69365bf44a97af1f0844f1f6ab83fdf6b36f26692efaa621a8aac91c4e29ea07
e894cabc6e2f20eedfce6c03b89141a2cc7cbe245e6e7a5654addbec5000b89b
A.7. Sample Inline-Signed Message
This is the same message and signature as in Appendix A.6 but as an
inline-signed message. The hashed data is exactly the same, and all
intermediate values and annotated hex dumps are also applicable.
-----BEGIN PGP MESSAGE-----
xEYGAQobIHZJX1AhiJD39eLuPBgiUU9wUA9VHYblySHkBONKU/usyxhsTwYJppfk
1S36bHIrDB8eJ8GKVnCPZSXsJ7rZrMkBy0p1AAAAAABXaGF0IHdlIG5lZWQgZnJv
bSB0aGUgZ3JvY2VyeSBzdG9yZToKCi0gdG9mdQotIHZlZ2V0YWJsZXMKLSBub29k
bGVzCsKYBgEbCgAAACkFgmOYo2MiIQbLGGxPBgmml+TVLfpscisMHx4nwYpWcI9l
JewnutmsyQAAAABpNiB2SV9QIYiQ9/Xi7jwYIlFPcFAPVR2G5ckh5ATjSlP7rCfQ
b7gKqPxbyxbhljGygHQPnqau1eBzrQD5QVplPEDnemrnfmkrpx0GmhCfokxYz9jj
FtCgazStmsuOXF9SFQE=
-----END PGP MESSAGE-----
A.8. Sample X25519-AEAD-OCB Encryption and Decryption
This example encrypts the cleartext string Hello, world! for the
sample cert (see Appendix A.3), using AES-128 with AEAD-OCB
encryption.
A.8.1. Sample Version 6 Public Key Encrypted Session Key Packet
This packet contains the following series of octets:
0x0000 c1 5d 06 21 06 12 c8 3f
0x0008 1e 70 6f 63 08 fe 15 1a
0x0010 41 77 43 a1 f0 33 79 0e
0x0018 93 e9 97 84 88 d1 db 37
0x0020 8d a9 93 08 85 19 87 cf
0x0028 18 d5 f1 b5 3f 81 7c ce
0x0030 5a 00 4c f3 93 cc 89 58
0x0038 bd dc 06 5f 25 f8 4a f5
0x0040 09 b1 7d d3 67 64 18 de
0x0048 a3 55 43 79 56 61 79 01
0x0050 e0 69 57 fb ca 8a 6a 47
0x0058 a5 b5 15 3e 8d 3a b7
The same data, broken out by octet and semantics, is:
0x0000 c1 packet type: PKESK
0x0001 5d packet length
0x0002 06 v6 PKESK
0x0003 21 length of fingerprint
0x0004 06 Key version 6
0x0005 12 c8 3f Key fingerprint
0x0008 1e 70 6f 63 08 fe 15 1a
0x0010 41 77 43 a1 f0 33 79 0e
0x0018 93 e9 97 84 88 d1 db 37
0x0020 8d a9 93 08 85
0x0025 19 algorithm: X25519
0x0026 87 cf Ephemeral key
0x0028 18 d5 f1 b5 3f 81 7c ce
0x0030 5a 00 4c f3 93 cc 89 58
0x0038 bd dc 06 5f 25 f8 4a f5
0x0040 09 b1 7d d3 67 64
0x0046 18 ESK length
0x0047 de ESK
0x0048 a3 55 43 79 56 61 79 01
0x0050 e0 69 57 fb ca 8a 6a 47
0x0058 a5 b5 15 3e 8d 3a b7
A.8.2. X25519 Encryption/Decryption of the Session Key
Ephemeral key:
87 cf 18 d5 f1 b5 3f 81 7c ce 5a 00 4c f3 93 cc
89 58 bd dc 06 5f 25 f8 4a f5 09 b1 7d d3 67 64
This ephemeral key is derived from the following ephemeral secret key
material, which is never placed on the wire:
af 1e 43 c0 d1 23 ef e8 93 a7 d4 d3 90 f3 a7 61
e3 fa c3 3d fc 7f 3e da a8 30 c9 01 13 52 c7 79
Public key from the target certificate (see Appendix A.3):
86 93 24 83 67 f9 e5 01 5d b9 22 f8 f4 80 95 dd
a7 84 98 7f 2d 59 85 b1 2f ba d1 6c af 5e 44 35
The corresponding long-lived X25519 private key material (see
Appendix A.4):
4d 60 0a 4f 79 4d 44 77 5c 57 a2 6e 0f ee fe d5
58 e9 af ff d6 ad 0d 58 2d 57 fb 2b a2 dc ed b8
Shared point:
67 e3 0e 69 cd c7 ba b2 a2 68 0d 78 ac a4 6a 2f
8b 6e 2a e4 4d 39 8b dc 6f 92 c5 ad 4a 49 25 14
HKDF output:
f6 6d ad cf f6 45 92 23 9b 25 45 39 b6 4f f6 07
Decrypted session key:
dd 70 8f 6f a1 ed 65 11 4d 68 d2 34 3e 7c 2f 1d
A.8.3. Sample v2 SEIPD Packet
This packet contains the following series of octets:
0x0000 d2 69 02 07 02 06 61 64
0x0008 16 53 5b e0 b0 71 6d 60
0x0010 e0 52 a5 6c 4c 40 7f 9e
0x0018 b3 6b 0e fa fe 9a d0 a0
0x0020 df 9b 03 3c 69 a2 1b a9
0x0028 eb d2 c0 ec 95 bf 56 9d
0x0030 25 c9 99 ee 4a 3d e1 70
0x0038 58 f4 0d fa 8b 4c 68 2b
0x0040 e3 fb bb d7 b2 7e b0 f5
0x0048 9b b5 00 5f 80 c7 c6 f4
0x0050 03 88 c3 0a d4 06 ab 05
0x0058 13 dc d6 f9 fd 73 76 56
0x0060 28 6e 11 77 d0 0f 88 8a
0x0068 db 31 c4
The same data, broken out by octet and semantics, is:
0x0000 d2 packet type: SEIPD
0x0001 69 packet length
0x0002 02 v2 SEIPD
0x0003 07 cipher: AES128
0x0004 02 AEAD mode: OCB
0x0005 06 chunk size (2^12 octets)
0x0006 61 64 salt
0x0008 16 53 5b e0 b0 71 6d 60
0x0010 e0 52 a5 6c 4c 40 7f 9e
0x0018 b3 6b 0e fa fe 9a d0 a0
0x0020 df 9b 03 3c 69 a2
0x0026 1b a9 chunk #0 encrypted data
0x0028 eb d2 c0 ec 95 bf 56 9d
0x0030 25 c9 99 ee 4a 3d e1 70
0x0038 58 f4 0d fa 8b 4c 68 2b
0x0040 e3 fb bb d7 b2 7e b0 f5
0x0048 9b b5 00
0x004b 5f 80 c7 c6 f4 chunk #0 AEAD tag
0x0050 03 88 c3 0a d4 06 ab 05
0x0058 13 dc d6
0x005b f9 fd 73 76 56 final AEAD tag (#1)
S0x0060 28 6e 11 77 d0 0f 88 8a
0x0068 db 31 c4
A.8.4. Decryption of Data
Starting AEAD-OCB decryption of data, using the session key.
HKDF info:
d2 02 07 02 06
HKDF output:
45 12 f7 14 9d 86 33 41 52 7c 65 67 d5 bf fc 42
5f af 32 50 21 2f f9
Message key:
45 12 f7 14 9d 86 33 41 52 7c 65 67 d5 bf fc 42
Initialization vector:
5f af 32 50 21 2f f9
Chunk #0:
Nonce:
5f af 32 50 21 2f f9 00 00 00 00 00 00 00 00
Additional authenticated data:
d2 02 07 02 06
Encrypted data chunk:
1b a9 eb d2 c0 ec 95 bf 56 9d 25 c9 99 ee 4a 3d
e1 70 58 f4 0d fa 8b 4c 68 2b e3 fb bb d7 b2 7e
b0 f5 9b b5 00 5f 80 c7 c6 f4 03 88 c3 0a d4 06
ab 05 13 dc d6
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 c5 a2 93 07 29 91 62 81 47 d7 2c 8f 86 b7
Authenticating final tag:
Final nonce:
5f af 32 50 21 2f f9 00 00 00 00 00 00 00 01
Final additional authenticated data:
d2 02 07 02 06 00 00 00 00 00 00 00 25
A.8.5. Complete X25519-AEAD-OCB Encrypted Packet Sequence
-----BEGIN PGP MESSAGE-----
wV0GIQYSyD8ecG9jCP4VGkF3Q6HwM3kOk+mXhIjR2zeNqZMIhRmHzxjV8bU/gXzO
WgBM85PMiVi93AZfJfhK9QmxfdNnZBjeo1VDeVZheQHgaVf7yopqR6W1FT6NOrfS
aQIHAgZhZBZTW+CwcW1g4FKlbExAf56zaw76/prQoN+bAzxpohup69LA7JW/Vp0l
yZnuSj3hcFj0DfqLTGgr4/u717J+sPWbtQBfgMfG9AOIwwrUBqsFE9zW+f1zdlYo
bhF30A+IitsxxA==
-----END PGP MESSAGE-----
A.9. Sample AEAD-EAX Encryption and Decryption
This example encrypts the cleartext string Hello, world! with the
passphrase password, using AES-128 with AEAD-EAX encryption.
A.9.1. Sample Version 6 Symmetric Key Encrypted Session Key Packet
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
The same data, broken out by octet and semantics, is:
0x0000 c3 packet type: SKESK
0x0001 40 packet length
0x0002 06 v6 SKESK
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.9.2. 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:
38 81 ba fe 98 54 12 45 9b 86 c3 6f 98 cb 9a 5e
A.9.3. 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, is:
0x0000 d2 packet type: SEIPD
0x0001 69 packet length
0x0002 02 v2 SEIPD
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
A.9.4. 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
Final additional authenticated data:
d2 02 07 01 06 00 00 00 00 00 00 00 25
A.9.5. 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.10. Sample AEAD-OCB Encryption and Decryption
This example encrypts the cleartext string Hello, world! with the
passphrase password, using AES-128 with AEAD-OCB encryption.
A.10.1. Sample Version 6 Symmetric Key Encrypted Session Key Packet
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, is:
0x0000 c3 packet type: SKESK
0x0001 3f packet length
0x0002 06 v6 SKESK
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.10.2. 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
A.10.3. 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, is:
0x0000 d2 packet type: SEIPD
0x0001 69 packet length
0x0002 02 v2 SEIPD
0x0003 07 cipher: AES128
0x0004 02 AEAD mode: OCB
0x0005 06 chunk size (2^12 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
A.10.4. 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
Final additional authenticated data:
d2 02 07 02 06 00 00 00 00 00 00 00 25
A.10.5. 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.11. Sample AEAD-GCM Encryption and Decryption
This example encrypts the cleartext string Hello, world! with the
passphrase password, using AES-128 with AEAD-GCM encryption.
A.11.1. Sample Version 6 Symmetric Key Encrypted Session Key Packet
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, is:
0x0000 c3 packet type: SKESK
0x0001 3c packet length
0x0002 06 v6 SKESK
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.11.2. 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
A.11.3. Sample v2 SEIPD Packet
This packet contains the following series of octets, is:
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, is:
0x0000 d2 packet type: SEIPD
0x0001 69 packet length
0x0002 02 v2 SEIPD
0x0003 07 cipher: AES128
0x0004 03 AEAD mode: GCM
0x0005 06 chunk size (2^12 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
A.11.4. 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
Final additional authenticated data:
d2 02 07 03 06 00 00 00 00 00 00 00 25
A.11.5. 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.12. 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.12.1. 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.12.2. 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.12.3. V4 SKESK Using Argon2 with AES-256
-----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. Upgrade Guidance (Adapting Implementations from RFCs 4880
and 6637)
This subsection offers a concise, non-normative summary of the
substantial additions to and departures from [RFC4880] and [RFC6637].
It is intended to help implementers who are augmenting an existing
implementation from those specifications to comply with this
specification. Cryptographic algorithms marked with "MTI" are
mandatory to implement.
* Public Key Signing Algorithms:
- Ed25519 (Sections 5.5.5.9 and 5.2.3.4) -- MTI
- Ed448 (Sections 5.5.5.10 and 5.2.3.5)
- EdDSALegacy with Ed25519Legacy (Sections 5.5.5.5 and 5.2.3.3)
- ECDSA with Brainpool curves (Section 9.2)
* Public Key Encryption Algorithms:
- X25519 (Sections 5.5.5.7 and 5.1.6) -- MTI
- X448 (Sections 5.5.5.8 and 5.1.7)
- ECDH with Curve25519Legacy (Section 9.2)
- ECDH with Brainpool curves (Section 9.2)
* AEAD Encryption:
- V2 SEIPD (Section 5.13.2)
- AEAD modes:
o OCB mode (Section 5.13.4) -- MTI
o EAX mode (Section 5.13.3)
o GCM mode (Section 5.13.5)
- V6 PKESK (Section 5.1.2)
- V6 SKESK (Section 5.3.2)
- Features signature subpacket: add flag for v2 SEIPD
(Section 5.2.3.32)
- Signature Subpacket: Preferred AEAD Ciphersuites
(Section 5.2.3.15)
- Secret key encryption: AEAD "S2K usage octet" (Sections 3.7.2
and 5.5.3)
* Version 6 Keys and Signatures:
- Version 6 Public Keys (Section 5.5.2.3)
- Version 6 Fingerprint and Key ID (Section 5.5.4.3)
- Version 6 Secret Keys (Section 5.5.3)
- Version 6 Signatures (Section 5.2.3)
- Version 6 One-Pass Signatures (Section 5.4)
* Certificate (Transferable Public Key) Structure:
- Preferences subpackets in Direct Key signatures
(Section 5.2.3.10)
- Self-verifying revocation certificate (Section 10.1.2)
- User ID is explicitly optional (Section 10.1.1)
* S2K: Argon2 (Section 3.7.1.4)
* Subpacket: Intended Recipient Fingerprint (Section 5.2.3.36)
* Digest Algorithms: SHA3-256 and SHA3-512 (Section 9.5)
* Packet: Padding (Section 5.14)
* Message Structure: Packet Criticality (Section 4.3)
* Deprecations:
- Public Key Algorithms:
o Avoid RSA weak keys (Section 12.4)
o Avoid DSA (Section 12.5)
o Avoid ElGamal (Sections 12.6 and 5.1.4)
o For Version 6 Keys: Avoid EdDSA25519Legacy and
Curve25519Legacy (Section 9.2)
- Digest Algorithms:
o Avoid MD5, SHA1, and RIPEMD160 (Section 9.5)
- Symmetric Key Algorithms:
o Avoid IDEA, TripleDES, and CAST5 (Section 9.3)
- S2K Specifier:
o Avoid Simple S2K (Section 3.7.1.1)
- Secret Key Protections (a.k.a. S2K Usage):
o Avoid MalleableCFB (Section 3.7.2.1)
- Packet Types:
o Avoid Symmetrically Encrypted Data (Sections 5.7 and 13.7)
- Literal Data Packet Metadata:
o Avoid Filename and Date fields (Section 5.9)
o Avoid Special _CONSOLE "filename" (Section 5.9.1)
- Packet Versions:
o Avoid Version 3 Public Keys (Section 5.5.2.1)
o Avoid Version 3 Signatures (Section 5.2)
- Signature Types:
o Avoid Reserved Signature Type ID 0xFF (Sections 5.2.1.16 and
5.2.4.1)
- Signature Subpackets:
o For Version 6 Signatures: Avoid Issuer Key ID
(Section 5.2.3.12)
o Avoid Revocation Key (Section 5.2.3.23)
- ASCII Armor:
o Ignore; do not emit CRC (Section 6.1)
o Do not emit "Version" Armor Header (Section 6.2.2.1)
- Cleartext Signature Framework:
o Ignore; avoid emitting unnecessary Hash: headers
(Section 6.2.2.3)
o Reject Cleartext Signature Framework signatures with invalid
Hash: headers (Section 6.2.2.3) or any other Armor Header
(Section 7.1)
B.1. Terminology Changes
Note that some of the words used in previous versions of the OpenPGP
specification have been improved in this document.
In previous versions, the following terms were used:
* "Radix-64" was used to refer to OpenPGP's ASCII Armor base64
encoding (Section 6).
* "Old packet format" was used to refer to the Legacy packet format
(Section 4.2.2) predating [RFC2440].
* "New packet format" was used to refer to the OpenPGP packet format
(Section 4.2.1) introduced in [RFC2440].
* "Certificate" was used ambiguously to mean multiple things. In
this document, it means "Transferable Public Key" exclusively.
* "Preferred Symmetric Algorithms" was the old name for the
"Preferred Symmetric Ciphers for v1 SEIPD" subpacket
(Section 5.2.3.14).
* "Modification Detection Code" or "MDC" was originally described as
a distinct packet (Packet Type ID 19), and its corresponding flag
in the Features signature subpacket (Section 5.2.3.32) was known
as "Modification Detection". It is now described as an intrinsic
part of v1 SEIPD (Section 5.13.1), and the same corresponding flag
is known as "Version 1 Symmetrically Encrypted and Integrity
Protected Data packet".
* "Packet Tag" was used to refer to the Packet Type ID (Section 5)
or sometimes to the encoded Packet Type ID (Section 4.2).
Appendix C. Errata Addressed by This Document
The following verified errata have been incorporated or are otherwise
resolved by this document:
* [Errata-2199] - S2K hash/cipher octet correction
* [Errata-2200] - No implicit use of IDEA correction
* [Errata-2206] - PKESK acronym expansion
* [Errata-2208] - Signature key owner clarification
* [Errata-2214] - Signature hashing clarification
* [Errata-2216] - Self-signature applies to user ID correction
* [Errata-2219] - Session key encryption storage clarification
* [Errata-2222] - Simple hash MUST/MAY clarification
* [Errata-2226] - Native line endings SHOULD clarification
* [Errata-2234] - Radix-64/base64 clarification
* [Errata-2235] - ASCII/UTF-8 collation sequence clarification
* [Errata-2236] - Packet Composition is a sequence clarification
* [Errata-2238] - Subkey packets come after all User ID packets
clarification
* [Errata-2240] - Subkey removal clarification
* [Errata-2242] - mL/emLen variable correction
* [Errata-2243] - CFB mode initialization vector (IV) clarification
* [Errata-2270] - SHA-224 octet sequence correction
* [Errata-2271] - Radix-64 correction
* [Errata-3298] - Key Revocation signatures correction
* [Errata-5491] - C code fix for CRC24_POLY define
* [Errata-7545] - Armor Header colon hex fix
* [Errata-7889] - Signature/certification correction
Acknowledgements
Thanks to the OpenPGP Design Team for working on this document and
preparing 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 the work on [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, Daphne 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