openpgp D. K. Gillmor Internet-Draft ACLU Intended status: Informational 15 May 2022 Expires: 16 November 2022 Stateless OpenPGP Command Line Interface draft-dkg-openpgp-stateless-cli-04 Abstract This document defines a generic stateless command-line interface for dealing with OpenPGP messages, known as sop. It aims for a minimal, well-structured API covering OpenPGP object security. About This Document This note is to be removed before publishing as an RFC. The latest revision of this draft can be found at https://dkg.gitlab.io/openpgp-stateless-cli/. Status information for this document may be found at https://datatracker.ietf.org/doc/draft- dkg-openpgp-stateless-cli/. Discussion of this document takes place on the OpenPGP Working Group mailing list (mailto:openpgp@ietf.org), which is archived at https://mailarchive.ietf.org/arch/browse/openpgp/. Source for this draft and an issue tracker can be found at https://gitlab.com/dkg/openpgp-stateless-cli/. Status of This Memo This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet- Drafts is at https://datatracker.ietf.org/drafts/current/. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." This Internet-Draft will expire on 16 November 2022. Gillmor Expires 16 November 2022 [Page 1] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 Copyright Notice Copyright (c) 2022 IETF Trust and the persons identified as the document authors. All rights reserved. This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/ license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Revised BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Revised BSD License. Table of Contents 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3 1.1. Requirements Language . . . . . . . . . . . . . . . . . . 4 1.2. Terminology . . . . . . . . . . . . . . . . . . . . . . . 4 1.3. Using sop in a Test Suite . . . . . . . . . . . . . . . . 5 2. Examples . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3. Subcommands . . . . . . . . . . . . . . . . . . . . . . . . . 5 3.1. version: Version Information . . . . . . . . . . . . . . 6 3.2. generate-key: Generate a Secret Key . . . . . . . . . . . 7 3.3. extract-cert: Extract a Certificate from a Secret Key . . 8 3.4. sign: Create Detached Signatures . . . . . . . . . . . . 8 3.5. verify: Verify Detached Signatures . . . . . . . . . . . 9 3.6. encrypt: Encrypt a Message . . . . . . . . . . . . . . . 10 3.7. decrypt: Decrypt a Message . . . . . . . . . . . . . . . 12 3.8. armor: Convert Binary to ASCII . . . . . . . . . . . . . 14 3.9. dearmor: Convert ASCII to Binary . . . . . . . . . . . . 16 3.10. inline-detach: Split Signatures from an Inline-Signed Message . . . . . . . . . . . . . . . . . . . . . . . . 16 3.11. inline-verify: Verify an Inline-Signed Message . . . . . 18 3.12. inline-sign: Create an Inline-Signed Message . . . . . . 19 4. Input String Types . . . . . . . . . . . . . . . . . . . . . 20 4.1. DATE . . . . . . . . . . . . . . . . . . . . . . . . . . 20 4.2. USERID . . . . . . . . . . . . . . . . . . . . . . . . . 21 5. Input/Output Indirect Types . . . . . . . . . . . . . . . . . 21 5.1. Special Designators for Indirect Types . . . . . . . . . 21 5.2. CERTS . . . . . . . . . . . . . . . . . . . . . . . . . . 22 5.3. KEYS . . . . . . . . . . . . . . . . . . . . . . . . . . 22 5.4. CIPHERTEXT . . . . . . . . . . . . . . . . . . . . . . . 22 5.5. INLINESIGNED . . . . . . . . . . . . . . . . . . . . . . 23 5.6. SIGNATURES . . . . . . . . . . . . . . . . . . . . . . . 24 5.7. SESSIONKEY . . . . . . . . . . . . . . . . . . . . . . . 24 5.8. MICALG . . . . . . . . . . . . . . . . . . . . . . . . . 24 5.9. PASSWORD . . . . . . . . . . . . . . . . . . . . . . . . 25 Gillmor Expires 16 November 2022 [Page 2] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 5.10. VERIFICATIONS . . . . . . . . . . . . . . . . . . . . . . 25 5.11. DATA . . . . . . . . . . . . . . . . . . . . . . . . . . 25 6. Failure Modes . . . . . . . . . . . . . . . . . . . . . . . . 26 7. Alternate Interfaces . . . . . . . . . . . . . . . . . . . . 28 8. Guidance for Implementers . . . . . . . . . . . . . . . . . . 28 8.1. One OpenPGP Message at a Time . . . . . . . . . . . . . . 28 8.2. Simplified Subset of OpenPGP Message . . . . . . . . . . 28 8.3. Validate Signatures Only from Known Signers . . . . . . . 29 8.4. OpenPGP Inputs can be either Binary or ASCII-armored . . 29 8.5. Complexities of the Cleartext Signature Framework . . . . 30 8.6. Reliance on Supplied Certs and Keys . . . . . . . . . . . 31 8.7. Text is always UTF-8 . . . . . . . . . . . . . . . . . . 31 8.8. Passwords are Human-Readable . . . . . . . . . . . . . . 32 8.8.1. Generating Material with Human-Readable Passwords . . 32 8.8.2. Consuming Password-protected Material . . . . . . . . 32 8.9. Be Careful with Special Designators . . . . . . . . . . . 33 9. Guidance for Consumers . . . . . . . . . . . . . . . . . . . 34 9.1. Choosing Between --as=text and --as=binary . . . . . . . 34 9.2. Special Designators and Unusual Filenames . . . . . . . . 34 10. Security Considerations . . . . . . . . . . . . . . . . . . . 35 10.1. Signature Verification . . . . . . . . . . . . . . . . . 35 10.2. Compression . . . . . . . . . . . . . . . . . . . . . . 36 11. Privacy Considerations . . . . . . . . . . . . . . . . . . . 36 11.1. Object Security vs. Transport Security . . . . . . . . . 36 12. References . . . . . . . . . . . . . . . . . . . . . . . . . 36 12.1. Normative References . . . . . . . . . . . . . . . . . . 36 12.2. Informative References . . . . . . . . . . . . . . . . . 37 Appendix A. Acknowledgements . . . . . . . . . . . . . . . . . . 38 Appendix B. Future Work . . . . . . . . . . . . . . . . . . . . 39 Appendix C. Document History . . . . . . . . . . . . . . . . . . 40 C.1. Substantive Changes between -03 and -04: . . . . . . . . 40 C.2. Substantive Changes between -02 and -03: . . . . . . . . 40 C.3. Substantive Changes between -01 and -02: . . . . . . . . 40 C.4. Substantive Changes between -00 and -01: . . . . . . . . 41 Author's Address . . . . . . . . . . . . . . . . . . . . . . . . 41 1. Introduction Different OpenPGP implementations have many different requirements, which typically break down in two main categories: key/certificate management and object security. The purpose of this document is to provide a "stateless" interface that primarily handles the object security side of things, and assumes that secret key management and certificate management will be handled some other way. Gillmor Expires 16 November 2022 [Page 3] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 Isolating object security from key/certificate management should make it easier to provide interoperability testing for the object security side of OpenPGP implementations, as described in Section 1.3. This document defines a generic stateless command-line interface for dealing with OpenPGP messages, known here by the placeholder sop. It aims for a minimal, well-structured API. An OpenPGP implementation should not name its executable sop to implement this specification. It just needs to provide a program that conforms to this interface. A sop implementation should leave no trace on the system, and its behavior should not be affected by anything other than command-line arguments and input. Obviously, the user will need to manage their secret keys (and their peers' certificates) somehow, but the goal of this interface is to separate out that task from the task of interacting with OpenPGP messages. While this document identifies a command-line interface, the rough outlines of this interface should also be amenable to relatively straightforward library implementations in different languages. 1.1. Requirements Language 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. 1.2. Terminology This document uses the term "key" to refer exclusively to OpenPGP Transferable Secret Keys (see Section 11.2 of [RFC4880]). It uses the term "certificate" to refer to OpenPGP Transferable Public Key (see Section 11.1 of [RFC4880]). "Stateless" in "Stateless OpenPGP" means avoiding secret key and certificate state. The user is responsible for managing all OpenPGP certificates and secret keys themselves, and passing them to sop as needed. The user should also not be concerned that any state could affect the underlying operations. Gillmor Expires 16 November 2022 [Page 4] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 OpenPGP revocations can have "Reason for Revocation" (Section 5.2.3.23 of [RFC4880]), which can be either "soft" or "hard". The set of "soft" reasons is: "Key is superseded" and "Key is retired and no longer used". All other reasons (and revocations that do not state a reason) are "hard" revocations. 1.3. Using sop in a Test Suite If an OpenPGP implementation provides a sop interface, it can be used to test interoperability (e.g., [OpenPGP-Interoperability-Test-Suite]). Such an interop test suite can, for example, use custom code (_not_ sop) to generate a new OpenPGP object that incorporates new primitives, and feed that object to a stable of sop implementations, to determine whether those implementations can consume the new form. Or, the test suite can drive each sop implementation with a simple input, and observe which cryptographic primitives each implementation chooses to use as it produces output. 2. Examples These examples show no error checking, but give a flavor of how sop might be used in practice from a shell. The key and certificate files described in them (e.g. alice.sec) could be for example those found in [I-D.draft-bre-openpgp-samples-01]. sop generate-key "Alice Lovelace " > alice.sec sop extract-cert < alice.sec > alice.pgp sop generate-key "Bob Babbage " > bob.sec sop extract-cert < bob.sec > bob.pgp sop sign --as=text alice.sec < statement.txt > statement.txt.asc sop verify statement.txt.asc alice.pgp < statement.txt sop encrypt --sign-with=alice.sec bob.pgp < msg.eml > ciphertext.asc sop decrypt bob.sec < ciphertext.asc > cleartext.eml See Section 6 for more information about errors and error handling. 3. Subcommands sop uses a subcommand interface, similar to those popularized by systems like git and svn. Gillmor Expires 16 November 2022 [Page 5] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 If the user supplies a subcommand that sop does not implement, it fails with UNSUPPORTED_SUBCOMMAND. If a sop implementation does not handle a supplied option for a given subcommand, it fails with UNSUPPORTED_OPTION. All subcommands that produce OpenPGP material on standard output produce ASCII-armored (Section 6 of [I-D.ietf-openpgp-crypto-refresh-05]) objects by default (except for sop dearmor). These subcommands have a --no-armor option, which causes them to produce binary OpenPGP material instead. All subcommands that accept OpenPGP material on input should be able to accept either ASCII-armored or binary inputs (see Section 8.4) and behave accordingly. See Section 5 for details about how various forms of OpenPGP material are expected to be structured. 3.1. version: Version Information sop version [--backend|--extended] * Standard Input: ignored * Standard Output: version information This subcommand emits version information as UTF-8-encoded text. With no arguments, the version string emitted should contain the name of the sop implementation, followed by a single space, followed by the version number. A sop implementation should use a version number that respects an established standard that is easily comparable and parsable, like [SEMVER]. If --backend is supplied, the implementation should produce a comparable line of implementation and version information about the primary underlying OpenPGP toolkit. If --extended is supplied, the implementation may emit multiple lines of version information. The first line MUST match the information produced by a simple invocation, but the rest of the text has no defined structure. --backend and --extended are mutually-exclusive options. Example: Gillmor Expires 16 November 2022 [Page 6] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 $ sop version ExampleSop 0.2.1 $ sop version --backend LibExamplePGP 3.4.2 $ sop version --extended ExampleSop 0.2.1 Running on MonkeyScript 4.5 LibExamplePGP 3.4.2 LibExampleCrypto 3.1.1 LibXCompression 4.0.2 See https://pgp.example/sop/ for more information $ 3.2. generate-key: Generate a Secret Key sop generate-key [--no-armor] [--with-key-password=PASSWORD] [--] [USERID...] * Standard Input: ignored * Standard Output: KEYS (Section 5.3) Generate a single default OpenPGP key with zero or more User IDs. The generated secret key SHOULD be usable for as much of the sop functionality as possible. In particular: * It should be possible to extract an OpenPGP certificate from the key in KEYS with sop extract-cert. * The key in KEYS should be able to create signatures (with sop sign) that are verifiable by using sop verify with the extracted certificate. * The key in KEYS should be able to decrypt messages (with sop decrypt) that are encrypted by using sop encrypt with the extracted certificate. The detailed internal structure of the certificate is left to the discretion of the sop implementation. If the --with-key-password option is supplied, the generated key will be password-protected (locked) with the supplied password. Note that PASSWORD is an indirect data type from which the actual password is acquired (Section 5). See also the guidance on ensuring that the password is human-readable in Section 8.8.1. Gillmor Expires 16 November 2022 [Page 7] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 If no --with-key-password option is supplied, the generated key will be unencrypted. Example: $ sop generate-key 'Alice Lovelace ' > alice.sec $ head -n1 < alice.sec -----BEGIN PGP PRIVATE KEY BLOCK----- $ 3.3. extract-cert: Extract a Certificate from a Secret Key sop extract-cert [--no-armor] * Standard Input: KEYS (Section 5.3) * Standard Output: CERTS (Section 5.2) The output should contain one OpenPGP certificate in CERTS per OpenPGP Transferable Secret Key found in KEYS. There is no guarantee what order the CERTS will be in. sop extract-cert SHOULD work even if any of the keys in KEYS is password-protected. Example: $ sop extract-cert < alice.sec > alice.pgp $ head -n1 < alice.pgp -----BEGIN PGP PUBLIC KEY BLOCK----- $ 3.4. sign: Create Detached Signatures sop sign [--no-armor] [--micalg-out=MICALG] [--with-key-password=PASSWORD...] [--as={binary|text}] [--] KEYS [KEYS...] * Standard Input: DATA (Section 5.11) * Standard Output: SIGNATURES (Section 5.6) Exactly one signature will be made by each key in the supplied KEYS arguments. --as defaults to binary. If --as=text and the input DATA is not valid UTF-8 (Section 8.7), sop sign fails with EXPECTED_TEXT. Gillmor Expires 16 November 2022 [Page 8] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 --as=binary SHOULD result in OpenPGP signatures of type 0x00 ("Signature of a binary document"). --as=text SHOULD result in OpenPGP signatures of type 0x01 ("Signature of a canonical text document"). See Section 5.2.1 of [RFC4880] for more details. When generating PGP/MIME messages ([RFC3156]), it is useful to know what digest algorithm was used for the generated signature. When -- micalg-out is supplied, sop sign emits the digest algorithm used to the specified MICALG file in a way that can be used to populate the micalg parameter for the Content-Type (see Section 5.8). If the specified MICALG file already exists in the filesystem, sop sign will fail with OUTPUT_EXISTS. When signing with multiple keys, sop sign SHOULD use the same digest algorithm for every signature generated in a single run, unless there is some internal constraint on the KEYS objects. If --micalg-out is requested, and multiple incompatibly-constrained KEYS objects are supplied, sop sign MUST emit the empty string to the designated MICALG. If the signing key material in any key in the KEYS objects is password-protected, sop sign SHOULD try all supplied --with-key- password options to unlock the key material until it finds one that enables the use of the key for signing. If none of the PASSWORD options unlock the key (or if no such option is supplied), sop sign will fail with KEY_IS_PROTECTED. Note that PASSWORD is an indirect data type from which the actual password is acquired (Section 5). Note also the guidance for retrying variants of a non-human-readable password in Section 8.8.2. If any key in the KEYS objects is not capable of producing a signature, sop sign will fail with KEY_CANNOT_SIGN. sop sign MUST NOT produce any extra signatures beyond those from KEYS objects supplied on the command line. Example: $ sop sign --as=text alice.sec < message.txt > message.txt.asc $ head -n1 < message.txt.asc -----BEGIN PGP SIGNATURE----- $ 3.5. verify: Verify Detached Signatures sop verify [--not-before=DATE] [--not-after=DATE] [--] SIGNATURES CERTS [CERTS...] Gillmor Expires 16 November 2022 [Page 9] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 * Standard Input: DATA (Section 5.11) * Standard Output: VERIFICATIONS (Section 5.10) --not-before and --not-after indicate that signatures with dates outside certain range MUST NOT be considered valid. --not-before defaults to the beginning of time. Accepts the special value - to indicate the beginning of time (i.e. no lower boundary). --not-after defaults to the current system time (now). Accepts the special value - to indicate the end of time (i.e. no upper boundary). sop verify only returns OK if at least one certificate included in any CERTS object made a valid signature in the time window specified over the DATA supplied. For details about the valid signatures, the user MUST inspect the VERIFICATIONS output. If no CERTS are supplied, sop verify fails with MISSING_ARG. If no valid signatures are found, sop verify fails with NO_SIGNATURE. See Section 10.1 for more details about signature verification. Example: (In this example, we see signature verification succeed first, and then fail on a modified version of the message.) $ sop verify message.txt.asc alice.pgp < message.txt 2019-10-29T18:36:45Z EB85BB5FA33A75E15E944E63F231550C4F47E38E EB85BB5FA33A75E15E944E63F231550C4F47E38E signed by alice.pgp $ echo $? 0 $ tr a-z A-Z < message.txt | sop verify message.txt.asc alice.pgp $ echo $? 3 $ 3.6. encrypt: Encrypt a Message sop encrypt [--as={binary|text}] [--no-armor] [--with-password=PASSWORD...] [--sign-with=KEYS...] [--] [CERTS...] Gillmor Expires 16 November 2022 [Page 10] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 * Standard Input: DATA (Section 5.11) * Standard Output: CIPHERTEXT (Section 5.4) --as defaults to binary. The setting of --as corresponds to the one octet format field found in the Literal Data packet at the core of the output CIPHERTEXT. If --as is set to binary, the octet is b (0x62). If it is text, the format octet is u (0x75). --with-password enables symmetric encryption (and can be used multiple times if multiple passwords are desired). PASSWORD is an indirect data type from which the actual password is acquired (Section 5). If sop encrypt encounters a password which is not a valid UTF-8 string (Section 8.7), or is otherwise not robust in its representation to humans, it fails with PASSWORD_NOT_HUMAN_READABLE. If sop encrypt sees trailing whitespace at the end of a password, it will trim the trailing whitespace before using the password. See Section 8.8 for more discussion about passwords. --sign-with creates exactly one signature by for each secret key found in the supplied KEYS object (this can also be used multiple times if signatures from keys found in separaate files are desired). If any key in any supplied KEYS objects is not capable of producing a signature, sop sign will fail with KEY_CANNOT_SIGN. If --as is set to binary, then --sign-with will sign as a binary document (OpenPGP signature type 0x00). If --as is set to text, then --sign-with will sign as a canonical text document (OpenPGP signature type 0x01). In this case, if the input DATA is not valid UTF-8 (Section 8.7), sop encrypt fails with EXPECTED_TEXT. If --sign-with is supplied for input DATA that is not valid UTF-8, sop encrypt MAY sign as a binary document (OpenPGP signature type 0x00). sop encrypt MUST NOT produce any extra signatures beyond those from KEYS objects identified by --sign-with. The resulting CIPHERTEXT should be decryptable by the secret keys corresponding to every certificate included in all CERTS, as well as each password given with --with-password. If no CERTS or --with-password options are present, sop encrypt fails with MISSING_ARG. Gillmor Expires 16 November 2022 [Page 11] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 If at least one of the identified certificates requires encryption to an unsupported asymmetric algorithm, sop encrypt fails with UNSUPPORTED_ASYMMETRIC_ALGO. If at least one of the identified certificates is not encryption- capable (e.g., revoked, expired, no encryption-capable flags on primary key and valid subkeys), sop encrypt fails with CERT_CANNOT_ENCRYPT. If sop encrypt fails for any reason, it emits no CIPHERTEXT. Example: (In this example, bob.bin is a file containing Bob's binary-formatted OpenPGP certificate. Alice is encrypting a message to both herself and Bob.) $ sop encrypt --as=text --sign-with=alice.key alice.asc bob.bin < message.eml > encrypted.asc $ head -n1 encrypted.asc -----BEGIN PGP MESSAGE----- $ 3.7. decrypt: Decrypt a Message sop decrypt [--session-key-out=SESSIONKEY] [--with-session-key=SESSIONKEY...] [--with-password=PASSWORD...] [--with-key-password=PASSWORD...] [--verify-out=VERIFICATIONS [--verify-with=CERTS...] [--verify-not-before=DATE] [--verify-not-after=DATE] ] [--] [KEYS...] * Standard Input: CIPHERTEXT (Section 5.4) * Standard Output: DATA (Section 5.11) The caller can ask sop for the session key discovered during decryption by supplying the --session-key-out option. If the specified file already exists in the filesystem, sop decrypt will fail with OUTPUT_EXISTS. When decryption is successful, sop decrypt writes the discovered session key to the specified file. Gillmor Expires 16 November 2022 [Page 12] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 --with-session-key enables decryption of the CIPHERTEXT using the session key directly against the SEIPD packet. This option can be used multiple times if several possible session keys should be tried. SESSIONKEY is an indirect data type from which the actual sessionkey value is acquired (Section 5). --with-password enables decryption based on any SKESK (Section 5.3 of [I-D.ietf-openpgp-crypto-refresh-05]) packets in the CIPHERTEXT. This option can be used multiple times if the user wants to try more than one password. --with-key-password lets the user use password-protected (locked) secret key material. If the decryption-capable secret key material in any key in the KEYS objects is password-protected, sop decrypt SHOULD try all supplied --with-key-password options to unlock the key material until it finds one that enables the use of the key for decryption. If none of the --with-key-password options unlock the key (or if no such option is supplied), and the message cannot be decrypted with any other KEYS, --with-session-key, or --with-password options, sop decrypt will fail with KEY_IS_PROTECTED. Note that the two kinds of PASSWORD options are for different domains: --with-password is for unlocking an SKESK, and --with-key- password is for unlocking secret key material in KEYS. sop decrypt SHOULD NOT apply the --with-key-password argument to any SKESK, or the --with-password argument to any KEYS. Each PASSWORD argument is an indirect data type from which the actual password is acquired (Section 5). If sop decrypt tries and fails to use a password supplied by a PASSWORD, and it observes that there is trailing UTF-8 whitespace at the end of the password, it will retry with the trailing whitespace stripped. See Section 8.8.2 for more discussion about consuming password-protected key material. --verify-out produces signature verification status to the designated file. If the designated file already exists in the filesystem, sop decrypt will fail with OUTPUT_EXISTS. The return code of sop decrypt is not affected by the results of signature verification. The caller MUST check the returned VERIFICATIONS to confirm signature status. An empty VERIFICATIONS output indicates that no valid signatures were found. --verify-with identifies a set of certificates whose signatures would be acceptable for signatures over this message. Gillmor Expires 16 November 2022 [Page 13] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 If the caller is interested in signature verification, both --verify- out and at least one --verify-with must be supplied. If only one of these options is supplied, sop decrypt fails with INCOMPLETE_VERIFICATION. --verify-not-before and --verify-not-after provide a date range for acceptable signatures, by analogy with the options for sop verify (see Section 3.5). They should only be supplied when doing signature verification. See Section 10.1 for more details about signature verification. If no KEYS or --with-password or --with-session-key options are present, sop decrypt fails with MISSING_ARG. If unable to decrypt, sop decrypt fails with CANNOT_DECRYPT. sop decrypt only emits cleartext to Standard Output that was successfully decrypted. Example: (In this example, Alice stashes and re-uses the session key of an encrypted message.) $ sop decrypt --session-key-out=session.key alice.sec < ciphertext.asc > cleartext.out $ ls -l ciphertext.asc cleartext.out -rw-r--r-- 1 user user 321 Oct 28 01:34 ciphertext.asc -rw-r--r-- 1 user user 285 Oct 28 01:34 cleartext.out $ sop decrypt --with-session-key=session.key < ciphertext.asc > cleartext2.out $ diff cleartext.out cleartext2.out $ 3.8. armor: Convert Binary to ASCII sop armor [--label={auto|sig|key|cert|message}] * Standard Input: OpenPGP material (SIGNATURES, KEYS, CERTS, CIPHERTEXT, or INLINESIGNED) * Standard Output: the same material with ASCII-armoring added, if not already present The user can choose to specify the label used in the header and tail of the armoring. Gillmor Expires 16 November 2022 [Page 14] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 The default for --label is auto, in which case, sop inspects the input and chooses the label appropriately, based on the OpenPGP packets encountered. If the type of the first OpenPGP packet is: * 0x05 (Secret-Key), the packet stream should be parsed as a KEYS input (with Armor Header BEGIN PGP PRIVATE KEY BLOCK). * 0x06 (Public-Key), the packet stream should be parsed as a CERTS input (with Armor Header BEGIN PGP PUBLIC KEY BLOCK). * 0x01 (Public-key Encrypted Session Key) or 0x03 (Symmetric-key Encrypted Session Key), the packet stream should be parsed as a CIPHERTEXT input (with Armor Header BEGIN PGP MESSAGE). * 0x04 (One-Pass Signature), the packet stream should be parsed as an INLINESIGNED input (with Armor Header BEGIN PGP MESSAGE). * 0x02 (Signature), the packet stream may be either a SIGNATURES input or an INLINESIGNED input. If the packet stream contains only Signature packets, it should be parsed as aSIGNATURES input (with Armor Header BEGIN PGP SIGNATURE). If it contains any packet other than a Signature packet, it should be parsed as an INLINESIGNED input (with Armor Header BEGIN PGP MESSAGE). If the input packet stream does not match the expected sequence of packet types, sop armor fails with BAD_DATA. Note that --label=message may be used for either INLINESIGNED or CIPHERTEXT inputs. Since sop armor accepts ASCII-armored input as well as binary input, this operation is idempotent on well-structured data. A caller can use this subcommand blindly to ensure that any well-formed OpenPGP packet stream is 7-bit clean. FIXME: what to do if the input is a CSF INLINESIGNED message? Three choices: * Leave it untouched -- this violates the claim about blindly ensuring 7-bit clean, since UTF-8-encoded message text is not necessarily 7-bit clean. * Convert to ASCII-armored INLINESIGNED -- this requires synthesis of OPS packet (from the CSF Hash header) and Literal Data packet (from the message body). * Raise a specific error. Gillmor Expires 16 November 2022 [Page 15] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 Example: $ sop armor < bob.bin > bob.pgp $ head -n1 bob.pgp -----BEGIN PGP PUBLIC KEY BLOCK----- $ 3.9. dearmor: Convert ASCII to Binary sop dearmor * Standard Input: OpenPGP material (SIGNATURES, KEYS, CERTS, CIPHERTEXT, or INLINESIGNED) * Standard Output: the same material with any ASCII-armoring removed If the input packet stream does not match any of the expected sequence of packet types, sop dearmor fails with BAD_DATA. See also Section 8.4. Since sop dearmor accepts binary-formatted input as well as ASCII- armored input, this operation is idempotent on well-structured data. A caller can use this subcommand blindly ensure that any well-formed OpenPGP packet stream is in its standard binary representation. FIXME: what to do if the input is a CSF INLINESIGNED? Three choices: * Leave it untouched -- output data is not really in binary format. * Convert to binary-format INLINESIGNED -- this requires synthesis of OPS packet (from CSF Hash header) and Literal Data packet (from the message body). * Raise a specific error. Example: $ sop dearmor < message.txt.asc > message.txt.sig $ 3.10. inline-detach: Split Signatures from an Inline-Signed Message sop inline-detach [--no-armor] --signatures-out=SIGNATURES * Standard Input: INLINESIGNED * Standard Output: DATA (the message without any signatures) Gillmor Expires 16 November 2022 [Page 16] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 In some contexts, the user may expect an inline-signed message of some form or another (INLINESIGNED, see Section 5.5) rather than a message and its detached signature. sop inline-detach takes such an inline-signed message on standard input, and splits it into: * the potentially signed material on standard output, and * a detached signature block to the destination identified by -- signatures-out Note that no cryptographic verification of the signatures is done by this subcommand. Once the inline-signed message is separated, verification of the detached signature can be done with sop verify. If no --signatures-out is supplied, sop inline-detach fails with MISSING_ARG. Note that there may be more than one Signature packet in an inline- signed message. All signatures found in the inline-signed message will be emitted to the --signatures-out destination. If the inline-signed message uses the Cleartext Signature Framework, it may be dash-escaped (see Section 7.1 of [RFC4880]). The output of sop detach-inband-signature-and-message will have any dash-escaping removed. If the input is not an INLINESIGNED message, sop inline-detach fails with BAD_DATA. If the input contains more than one object that could be interpreted as an INLINESIGNED message, sop inline-detach also fails with BAD_DATA. A sop implementation MAY accept (and discard) leading and trailing data when the incoming INLINESIGNED message uses the Cleartext Signature Framework. If the file designated by --signatures-out already exists in the filesystem, sop detach-inband-signature-and-message will fail with OUTPUT_EXISTS. Note that --no-armor here governs the data written to the -- signatures-out destination. Standard output is always the raw message, not an OpenPGP packet. Example: $ sop inline-detach --signatures-out=Release.pgp < InRelease >Release $ sop verify Release.pgp archive-keyring.pgp < Release $ Gillmor Expires 16 November 2022 [Page 17] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 3.11. inline-verify: Verify an Inline-Signed Message sop inline-verify [--not-before=DATE] [--not-after=DATE] [--verifications-out=VERIFICATIONS] [--] CERTS [CERTS...] * Standard Input: INLINESIGNED (Section 5.5) * Standard Output: DATA (Section 5.11) This command is similar to sop verify (Section 3.5) except that it takes an INLINESIGNED message (see Section 5.5) and produces the message body (without signatures) on standard output. It is also similar to sop inline-detach (Section 3.10) except that it actually performs signature verification. --not-before and --not-after indicate that signatures with dates outside certain range MUST NOT be considered valid. --not-before defaults to the beginning of time. Accepts the special value - to indicate the beginning of time (i.e. no lower boundary). --not-after defaults to the current system time (now). Accepts the special value - to indicate the end of time (i.e. no upper boundary). sop inline-verify only returns OK if INLINESIGNED contains at least one valid signature made during the time window specified by a certificate included in any CERTS object. For details about the valid signatures, the user MUST inspect the VERIFICATIONS output. If no CERTS are supplied, sop inline-verify fails with MISSING_ARG. If no valid signatures are found, sop inline-verify fails with NO_SIGNATURE and emits nothing on standard output. See Section 10.1 for more details about signature verification. Example: (In this example, we see signature verification succeed first, and then fail on a modified version of the message.) Gillmor Expires 16 November 2022 [Page 18] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 $ sop inline-verify -- alice.pgp < message.txt Hello, world! $ echo $? 0 $ sed s/Hello/Goodbye/ < message.txt | sop inline-verify -- alice.pgp $ echo $? 3 $ 3.12. inline-sign: Create an Inline-Signed Message sop inline-sign [--no-armor] [--with-key-password=PASSWORD...] [--as={binary|text|clearsigned}] [--] KEYS [KEYS...] * Standard Input: DATA (Section 5.11) * Standard Output: INLINESIGNED (Section 5.5) Exactly one signature will be made by each key in the supplied KEYS arguments. The generated output stream will be an inline-signed message, by default producing an OpenPGP "Signed Message" packet stream. --as defaults to binary. If --as= is set to either text or clearsigned, and the input DATA is not valid UTF-8 (Section 8.7), sop inline-sign fails with EXPECTED_TEXT. --as=binary SHOULD result in OpenPGP signatures of type 0x00 ("Signature of a binary document"). --as=text SHOULD result in an OpenPGP signature of type 0x01 ("Signature of a canonical text document"). See Section 5.2.1 of [RFC4880] for more details. --as=clearsigned SHOULD behave the same way as --as=text except that it produces an output stream using the Cleartext Signature Framework (see Section 7 of [RFC4880] and Section 8.5). If both --no-armor and --as=clearsigned are supplied, sop inline-sign fails with INCOMPATIBLE_OPTIONS. Gillmor Expires 16 November 2022 [Page 19] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 If the signing key material in any key in the KEYS objects is password-protected, sop inline-sign SHOULD try all supplied --with- key-password options to unlock the key material until it finds one that enables the use of the key for signing. If none of the PASSWORD options unlock the key (or if no such option is supplied), sop inline-sign will fail with KEY_IS_PROTECTED. Note that PASSWORD is an indirect data type from which the actual password is acquired (Section 5). Note also the guidance for retrying variants of a non- human-readable password in Section 8.8.2. If any key in the KEYS objects is not capable of producing a signature, sop inline-sign will fail with KEY_CANNOT_SIGN. sop inline-sign MUST NOT produce any extra signatures beyond those from KEYS objects supplied on the command line. Example: $ sop inline-sign --as=clearsigned alice.sec < message.txt > message-signed.txt $ head -n5 < message-signed.txt -----BEGIN PGP SIGNED MESSAGE----- Hash: SHA256 This is the message. -----BEGIN PGP SIGNATURE----- $ 4. Input String Types Some material is passed to sop directly as a string on the command line. 4.1. DATE An ISO-8601 formatted timestamp with time zone, or the special value now to indicate the current system time. Examples: * now * 2019-10-29T12:11:04+00:00 * 2019-10-24T23:48:29Z * 20191029T121104Z Gillmor Expires 16 November 2022 [Page 20] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 In some cases where used to specify lower and upper boundaries, a DATE value can be set to - to indicate "no time limit". A flexible implementation of sop MAY accept date inputs in other unambiguous forms. Note that whenever sop emits a timestamp (e.g. in Section 5.10) it MUST produce only a UTC-based ISO-8601 compliant representation with a resolution of one second, using the literal Z suffix to indicate timezone. 4.2. USERID This is an arbitrary UTF-8 string (Section 8.7). By convention, most User IDs are of the form Display Name , but they do not need to be. 5. Input/Output Indirect Types Some material is passed to sop indirectly, typically by referring to a filename containing the data in question. This type of data may also be passed to sop on Standard Input, or delivered by sop to Standard Output. If any input data is specified explicitly to be read from a file that does not exist, sop will fail with MISSING_INPUT. If any input data does not meet the requirements described below, sop will fail with BAD_DATA. 5.1. Special Designators for Indirect Types An indirect argument or parameter that starts with "@" (COMMERCIAL AT, U+0040) is not treated as a filename, but is reserved for special handling, based on the prefix that follows the @. We describe two of those prefixes (@ENV: and @FD:) here. A sop implementation that receives such a special designator but does not know how to handle a given prefix in that context MUST fail with UNSUPPORTED_SPECIAL_PREFIX. If the filename for any indirect material used as input has the special form @ENV:xxx, then contents of environment variable $xxx is used instead of looking in the filesystem. @ENV is for input only: if the prefix @ENV: is used for any output argument, sop fails with UNSUPPORTED_SPECIAL_PREFIX. Gillmor Expires 16 November 2022 [Page 21] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 If the filename for any indirect material used as either input or output has the special form @FD:nnn where nnn is a decimal integer, then the associated data is read from file descriptor nnn. See Section 8.9 for more details about safe handling of these special designators. 5.2. CERTS One or more OpenPGP certificates (Section 11.1 of [I-D.ietf-openpgp-crypto-refresh-05]), aka "Transferable Public Key". May be armored (see Section 8.4). Although some existing workflows may prefer to use one CERTS object with multiple certificates in it (a "keyring"), supplying exactly one certificate per CERTS input will make error reporting clearer and easier. 5.3. KEYS One or more OpenPGP Transferable Secret Keys (Section 11.2 of [I-D.ietf-openpgp-crypto-refresh-05]). May be armored (see Section 8.4). By default, secret key material is expected to be in cleartext (that is, not locked with a password). If any secret key material is locked with a password and no --with-key-password option is supplied, sop may fail with error KEY_IS_PROTECTED. Although some existing workflows may prefer to use one KEYS object with multiple keys in it (a "secret keyring"), supplying exactly one key per KEYS input will make error reporting clearer and easier. 5.4. CIPHERTEXT sop accepts only a restricted subset of the arbitrarily-nested grammar allowed by the OpenPGP Messages definition (Section 11.3 of [I-D.ietf-openpgp-crypto-refresh-05]). In particular, it accepts and generates only: An OpenPGP message, consisting of a sequence of PKESKs (Section 5.1 of [I-D.ietf-openpgp-crypto-refresh-05]) and SKESKs (Section 5.3 of [I-D.ietf-openpgp-crypto-refresh-05]), followed by one SEIPD (Section 5.14 of [I-D.ietf-openpgp-crypto-refresh-05]). The SEIPD can decrypt into one of two things: Gillmor Expires 16 November 2022 [Page 22] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 * "Maybe Signed Data" (see below), or * Compressed data packet that contains "Maybe Signed Data" "Maybe Signed Data" is a sequence of: * N (zero or more) one-pass signature packets, followed by * zero or more signature packets, followed by * one Literal data packet, followed by * N signature packets (corresponding to the outer one-pass signatures packets) FIXME: does any tool do compression inside signing? Do we need to handle that? May be armored (see Section 8.4). 5.5. INLINESIGNED An inline-signed message may take any one of three different forms: * A binary sequence of OpenPGP packets that matches a subset of the "Signed Message" element in the grammar in Section 11.3 of [I-D.ietf-openpgp-crypto-refresh-05] * The same sequence of packets, but ASCII-armored (see Section 8.4) * A message using the Cleartext Signature Framework described in Section 7 of [I-D.ietf-openpgp-crypto-refresh-05] The subset of the packet grammar expected in the first two forms consists of either: * a series of Signature packets followed by a Literal Data packet * a series of One-Pass Signature (OPS) packets, followed by one Literal Data packet, followed by an equal number of Signature packets corresponding to the OPS packets When the message is in the third form (Cleartext Signature Framework), it has the following properties: * The stream SHOULD consist solely of UTF-8 text Gillmor Expires 16 November 2022 [Page 23] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 * Every Signature packet found in the stream SHOULD have Signature Type 0x01 (canonical text document). * It SHOULD NOT contain leading text (before the -----BEGIN PGP SIGNED MESSAGE----- cleartext header) or trailing text (after the -----END PGP SIGNATURE----- armor tail). While some OpenPGP implementations MAY produce more complicated inline signed messages, a sop implementation SHOULD limit itself to producing these straightforward forms. 5.6. SIGNATURES One or more OpenPGP Signature packets. May be armored (see Section 8.4). 5.7. SESSIONKEY This documentation uses the GnuPG defacto ASCII representation: ALGONUM:HEXKEY where ALGONUM is the decimal value associated with the OpenPGP Symmetric Key Algorithms (Section 9.3 of [I-D.ietf-openpgp-crypto-refresh-05]) and HEXKEY is the hexadecimal representation of the binary key. Example AES-256 session key: 9:FCA4BEAF687F48059CACC14FB019125CD57392BAB7037C707835925CBF9F7BCD 5.8. MICALG This output indicates the cryptographic digest used when making a signature. It is useful specifically when generating signed PGP/MIME objects, which want a micalg= parameter for the multipart/signed content type as described in Section 5 of [RFC3156]. It will typically be a string like pgp-sha512, but in some situations (multiple signatures using different digests) it will be the empty string. If the user of sop is assembling a PGP/MIME signed object, and the MICALG output is the empty string, the user should omit the micalg= parameter entirely. Gillmor Expires 16 November 2022 [Page 24] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 5.9. PASSWORD This is expected to be a UTF-8 string (Section 8.7), but for sop decrypt, any bytestring that the user supplies will be accepted. Note the details in sop encrypt and sop decrypt about trailing whitespace! See also Section 8.8 for more discussion. 5.10. VERIFICATIONS One line per successful signature verification. Each line has three structured fields delimited by a single space, followed by arbitrary text to the end of the line that forms a message describing the verification. * ISO-8601 UTC datestamp, to one second precision, using the Z suffix * Fingerprint of the signing key (may be a subkey) * Fingerprint of primary key of signing certificate (if signed by primary key, same as the previous field) * message describing the verification (free form) Note that while Section 4.1 permits a sop implementation to accept other unambiguous date representations, its date output here MUST be a strict ISO-8601 UTC date timestamp. In particular: * the date and time fields MUST be separated by T, not by whitespace, since whitespace is used as a delimiter * the time MUST be emitted in UTC, with the explicit suffix Z * the time MUST be emitted with one-second precision Example: 2019-10-24T23:48:29Z C90E6D36200A1B922A1509E77618196529AE5FF8 C4BC2DDB38CCE96485EBE9C2F20691179038E5C6 certificate from dkg.asc 5.11. DATA Cleartext, arbitrary data. This is either a bytestream or UTF-8 text. Gillmor Expires 16 November 2022 [Page 25] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 It MUST only be UTF-8 text in the case of input supplied to sop sign --as=text or sop encrypt --as=text. If sop receives DATA containing non-UTF-8 octets in this case, it will fail (see Section 8.7) with EXPECTED_TEXT. 6. Failure Modes sop return codes have both mnemonics and numeric values. When sop succeeds, it will return 0 (OK) and emit nothing to Standard Error. When sop fails, it fails with a non-zero return code, and emits one or more warning messages on Standard Error. Known return codes include: +=======+=============================+===========================+ | Value | Mnemonic | Meaning | +=======+=============================+===========================+ | 0 | OK | Success | +-------+-----------------------------+---------------------------+ | 3 | NO_SIGNATURE | No acceptable signatures | | | | found (sop verify) | +-------+-----------------------------+---------------------------+ | 13 | UNSUPPORTED_ASYMMETRIC_ALGO | Asymmetric algorithm | | | | unsupported (sop encrypt) | +-------+-----------------------------+---------------------------+ | 17 | CERT_CANNOT_ENCRYPT | Certificate not | | | | encryption-capable (e.g., | | | | expired, revoked, | | | | unacceptable usage flags) | | | | (sop encrypt) | +-------+-----------------------------+---------------------------+ | 19 | MISSING_ARG | Missing required argument | +-------+-----------------------------+---------------------------+ | 23 | INCOMPLETE_VERIFICATION | Incomplete verification | | | | instructions (sop | | | | decrypt) | +-------+-----------------------------+---------------------------+ | 29 | CANNOT_DECRYPT | Unable to decrypt (sop | | | | decrypt) | +-------+-----------------------------+---------------------------+ | 31 | PASSWORD_NOT_HUMAN_READABLE | Non-UTF-8 or otherwise | | | | unreliable password (sop | | | | encrypt, sop generate- | | | | key) | +-------+-----------------------------+---------------------------+ | 37 | UNSUPPORTED_OPTION | Unsupported option | +-------+-----------------------------+---------------------------+ | 41 | BAD_DATA | Invalid data type (no | Gillmor Expires 16 November 2022 [Page 26] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 | | | secret key where KEYS | | | | expected, etc) | +-------+-----------------------------+---------------------------+ | 53 | EXPECTED_TEXT | Non-text input where text | | | | expected | +-------+-----------------------------+---------------------------+ | 59 | OUTPUT_EXISTS | Output file already | | | | exists | +-------+-----------------------------+---------------------------+ | 61 | MISSING_INPUT | Input file does not exist | +-------+-----------------------------+---------------------------+ | 67 | KEY_IS_PROTECTED | A KEYS input is password- | | | | protected (locked), and | | | | sop cannot unlock it with | | | | any of the --with-key- | | | | password options | +-------+-----------------------------+---------------------------+ | 69 | UNSUPPORTED_SUBCOMMAND | Unsupported subcommand | +-------+-----------------------------+---------------------------+ | 71 | UNSUPPORTED_SPECIAL_PREFIX | An indirect parameter is | | | | a special designator (it | | | | starts with @) but sop | | | | does not know how to | | | | handle the prefix | +-------+-----------------------------+---------------------------+ | 73 | AMBIGUOUS_INPUT | A indirect input | | | | parameter is a special | | | | designator (it starts | | | | with @), and a filename | | | | matching the designator | | | | is actually present | +-------+-----------------------------+---------------------------+ | 79 | KEY_CANNOT_SIGN | Key not signature-capable | | | | (e.g., expired, revoked, | | | | unacceptable usage flags) | | | | (sop sign and sop encrypt | | | | with --sign-with) | +-------+-----------------------------+---------------------------+ | 83 | INCOMPATIBLE_OPTIONS | Options were supplied | | | | that are incompatible | | | | with each other | +-------+-----------------------------+---------------------------+ Table 1 If a sop implementation fails in some way not contemplated by this document, it MAY return any non-zero error code, not only those listed above. Gillmor Expires 16 November 2022 [Page 27] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 7. Alternate Interfaces This draft primarily defines a command line interface, but future versions may try to outline a comparable idiomatic interface for C or some other widely-used programming language. Comparable idiomatic interfaces are already active in the wild for different programming languages, in particular: * Rust: [RUST-SOP] * Java: [SOP-JAVA] * Python: [PYTHON-SOP] These programmatic interfaces are typically coupled with a wrapper that can automatically generate a command-line tool compatible with this draft. An implementation that uses one of these languages should target the corresponding idiomatic interface for ease of development and interoperability. 8. Guidance for Implementers sop uses a few assumptions that implementers might want to consider. 8.1. One OpenPGP Message at a Time sop is intended to be a simple tool that operates on one OpenPGP object at a time. It should be composable, if you want to use it to deal with multiple OpenPGP objects. FIXME: discuss what this means for streaming. The stdio interface doesn't necessarily imply streamed output. 8.2. Simplified Subset of OpenPGP Message While the formal grammar for OpenPGP Message is arbitrarily nestable, sop constrains itself to what it sees as a single "layer" (see Section 5.4). This is a deliberate choice, because it is what most consumers expect. Also, if an arbitrarily-nested structure is parsed with a recursive algorithm, this risks a denial of service vulnerability. sop intends to be implementable with a parser that defensively declines to do recursive descent into an OpenPGP Message. Gillmor Expires 16 November 2022 [Page 28] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 Note that an implementation of sop decrypt MAY choose to handle more complex structures, but if it does, it should document the other structures it handles and why it chooses to do so. We can use such documentation to improve future versions of this spec. 8.3. Validate Signatures Only from Known Signers There are generally only a few signers who are relevant for a given OpenPGP message. When verifying signatures, sop expects that the caller can identify those relevant signers ahead of time. 8.4. OpenPGP Inputs can be either Binary or ASCII-armored OpenPGP material on input can be in either ASCII-armored or binary form. This is a deliberate choice because there are typical scenarios where the program can't predict which form will appear. Expecting the caller of sop to detect the form and adjust accordingly seems both redundant and error-prone. The simple way to detect possible ASCII-armoring is to see whether the high bit of the first octet is set: Section 4.2 of [RFC4880] indicates that bit 7 is always one in the first octet of an OpenPGP packet. In standard ASCII-armor, the first character is "-" (HYPHEN- MINUS, U+002D), so the high bit should be cleared. When considering an input as ASCII-armored OpenPGP material, sop MAY reject an input based on any of the following variations (see Section 6.2 of [RFC4880] for precise definitions): * An unknown Armor Header Line * Any text before the Armor Header Line * Malformed lines in the Armor Headers section * Any non-whitespace data after the Armor Tail * Any Radix-64 encoded line with more than 76 characters * Invalid characters in the Radix-64-encoded data * An invalid Armor Checksum * A mismatch between the Armor Header Line and the Armor Tail For robustness, sop SHOULD be willing to ignore whitespace after the Armor Tail. Gillmor Expires 16 November 2022 [Page 29] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 When considering OpenPGP material as input, regardless of whether it is ASCII-armored or binary, sop SHOULD reject any material that doesn't produce a valid stream of OpenPGP packets. For example, sop SHOULD raise an error if an OpenPGP packet header is malformed, or if there is trailing garbage after the end of a packet. For a given type of OpenPGP input material (i.e., SIGNATURES, CERTS, KEYS, or CIPHERTEXT), sop SHOULD also reject any input that does not conform to the expected packet stream. See Section 5 for the expected packet stream for different types. 8.5. Complexities of the Cleartext Signature Framework sop prefers a detached signature as the baseline form of OpenPGP signature, but provides affordances for dealing with inline-signed messages (see INLINESIGNED, Section 5.5) as well. The most complex form of inline-signed messages is the Cleartext Signature Framework (CSF). Handling the CSF structure requires parsing to delimit the multiple parts of the document, including at least: * any preamble before the message * the inline message header (delimiter line, OpenPGP headers) * the message itself * the divider between the message and the signature (including any OpenPGP headers there) * the signature * the divider that terminates the signature * any suffix after the signature Note also that the preamble or the suffix might be arbitrary text, and might themselves contain OpenPGP messages (whether signatures or otherwise). If the parser that does this split differs in any way from the parser that does the verification, or parts of the message are confused, it would be possible to produce a verification status and an actual signed message that don't correspond to one another. Blurred boundary problems like this can produce ugly attacks similar to those found in [EFAIL]. Gillmor Expires 16 November 2022 [Page 30] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 A user of sop that receives an inline-signed message (whether the message uses the CSF or not) can detach the signature from the message with sop inline-detach (see Section 3.10). Alternately, the user can send the message through sop inline-verify to confirm required signatures, and then (if signatures are valid) supply its output to the consumer of the signed message. 8.6. Reliance on Supplied Certs and Keys A truly stateless implementation may find that it spends more time validating the internal consistency of certificates and keys than it does on the actual object security operations. For performance reasons, an implementation may choose to ignore validation on certificate and key material supplied to it. The security implications of doing so depend on how the certs and keys are managed outside of sop. 8.7. Text is always UTF-8 Various places in this specification require UTF-8 [RFC3629] when encoding text. sop implementations SHOULD NOT consider textual data in any other character encoding. OpenPGP Implementations MUST already handle UTF-8, because various parts of [RFC4880] require it, including: * User ID * Notation name * Reason for revocation * ASCII-armor Comment: header Dealing with messages in other charsets leads to weird security failures like [Charset-Switching], especially when the charset indication is not covered by any sort of cryptographic integrity check. Restricting textual data to UTF-8 universally across the OpenPGP ecosystem eliminates any such risk without losing functionality, since UTF-8 can encode all known characters. Gillmor Expires 16 November 2022 [Page 31] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 8.8. Passwords are Human-Readable Passwords are generally expected to be human-readable, as they are typically recorded and transmitted as human-visible, human- transferable strings. However, they are used in the OpenPGP protocol as bytestrings, so it is important to ensure that there is a reliable bidirectional mapping between strings and bytes. The maximally robust behavior here is for sop encrypt and sop generate-key to constrain the choice of passwords to strings that have such a mapping, and for sop decrypt and sop sign to try multiple plausible versions of any password supplied by PASSWORD. 8.8.1. Generating Material with Human-Readable Passwords When generating material based on a password, sop encrypt and sop generate-key enforce that the password is actually meaningfully human-transferable (requiring UTF-8, trimming trailing whitespace). Some sop encrypt and sop generate-key implementations may make even more strict requirements on input to ensure that they are transferable between humans in a robust way. For example, a more strict sop encrypt or sop generate-key MAY also: * forbid leading whitespace * forbid non-printing characters other than SPACE (U+0020), such as ZERO WIDTH NON-JOINER (U+200C) or TAB (U+0009) * require the password to be in Unicode Normal Form C ([UNICODE-NORMALIZATION]) Violations of these more-strict policies SHOULD result in an error of PASSWORD_NOT_HUMAN_READABLE. A sop encrypt or sop generate-key implementation typically SHOULD NOT attempt enforce a minimum "password strength", but in the event that some implementation does, it MUST NOT represent a weak password with PASSWORD_NOT_HUMAN_READABLE. 8.8.2. Consuming Password-protected Material When sop decrypt receives a PASSWORD input, either from a --with-key- password or --with-password option, it sees its content as a bytestring. sop sign also sees the content of any PASSWORD input supplied to its --with-key-password option as a bytestring. If the bytestring fails to work as a password, but ends in UTF-8 whitespace, it will try again with the trailing whitespace removed. This handles a common pattern of using a file with a final newline, for example. Gillmor Expires 16 November 2022 [Page 32] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 The pattern here is one of robustness in the face of typical errors in human-transferred textual data. A more robust sop decrypt or sop sign implementation that finds neither of the above two attempts work for a given PASSWORD MAY try additional variations if they produce a different bytestring, such as: * trimming any leading whitespace, if discovered * trimming any internal non-printable characters other than SPACE (U+0020) * converting the supplied PASSWORD into Unicode Normal Form C ([UNICODE-NORMALIZATION]) A sop decrypt or sop sign implementation that stages multiple decryption attempts like this SHOULD consider the computational resources consumed by each attempt, to avoid presenting an attack surface for resource exhaustion in the face of a non-standard PASSWORD input. 8.9. Be Careful with Special Designators As documented in Section 5.1, special designators for indirect inputs like @ENV: and @FD: (and indirect outputs using @FD:) warrant some special/cautious handling. For one thing, it's conceivable that the filesystem could contain a file with these literal names. If sop receives an indirect output parameter that starts with an "@" (COMMERCIAL AT, U+0040) it MUST NOT write to the filesystem for that parameter. A sop implementation that receives such a parameter as input MAY test for the presence of such a file in the filesystem and fail with AMBIGUOUS_INPUT to warn the user of the ambiguity and possible confusion. These special designators are likely to be used to pass sensitive data (like secret key material or passwords) so that it doesn't need to touch the filesystem. Given this sensitivity, sop should be careful with such an input, and minimize its leakage to other processes. In particular, sop SHOULD NOT leak any environment variable identified by @ENV: or file descriptor identified by @FD: to any subprocess unless the subprocess specifically needs access to that data. Gillmor Expires 16 November 2022 [Page 33] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 9. Guidance for Consumers While sop is originally conceived of as an interface for interoperability testing, it's conceivable that an application that uses OpenPGP for object security would want to use it. FIXME: more guidance for how to use such a tool safely and efficiently goes here. FIXME: if an encrypted OpenPGP message arrives without metadata, it is difficult to know which signers to consider when decrypting. How do we do this efficiently without invoking sop decrypt twice, once without --verify-* and again with the expected identity material? 9.1. Choosing Between --as=text and --as=binary A program that invokes sop to generate an OpenPGP signature typically needs to decide whether it is making a text or binary signature. By default, sop will make a binary signature. The caller of sop sign should choose --as=text only when it knows that: - the data being signed is in fact textual, and encoded in UTF-8, and - the signed data might be transmitted to the recipient (the verifier of the signature) over a channel that has the propensity to transform line- endings. Examples of such channels include FTP ([RFC0959]) and SMTP ([RFC5321]). 9.2. Special Designators and Unusual Filenames In some cases, a user of sop might want to pass all the files in a given directory as positional parameters (e.g., a list of CERTS files to test a signature against). If one of the files has a name that starts with --, it might be confused by sop for an option. If one of the files has a name that starts with @, it might be confused by sop as a special designator (Section 5.1). If the user wants to deliberately refer to such an ambiguously-named file in the filesystem, they should prefix the filename with ./ or use an absolute path. Any specific @FD: special designator SHOULD NOT be supplied more than once to an invocation of sop. If a sop invocation sees multiple copies of a specific @FD:n input (e.g., sop sign @FD:3 @FD:3), it MAY fail with MISSING_INPUT even if file descriptor 3 contains a valid Gillmor Expires 16 November 2022 [Page 34] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 KEYS, because the bytestream for the KEYS was consumed by the first argument. Doubling up on the same @FD: for output (e.g., sop decrypt --session-key-out=@FD:3 --verify-out=@FD:3) also results in an ambiguous data stream. 10. Security Considerations The OpenPGP object security model is typically used for confidentiality and authenticity purposes. 10.1. Signature Verification In many contexts, an OpenPGP signature is verified to prove the origin and integrity of an underlying object. When sop checks a signature (e.g. via sop verify or sop decrypt -- verify-with), it MUST NOT consider it to be verified unless all of these conditions are met: * The signature must be made by a signing-capable public key that is present in one of the supplied certificates * The certificate and signing subkey must have been created before or at the signature time * The certificate and signing subkey must not have been expired at the signature time * The certificate and signing subkey must not be revoked with a "hard" revocation * If the certificate or signing subkey is revoked with a "soft" revocation, then the signature time must predate the revocation * The signing subkey must be properly bound to the primary key, and cross-signed * The signature (and any dependent signature, such as the cross-sig or subkey binding signatures) must be made with strong cryptographic algorithms (e.g., not MD5 or a 1024-bit RSA key) Implementers MAY also consider other factors in addition to the origin and authenticity, including application-specific information. Gillmor Expires 16 November 2022 [Page 35] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 For example, consider the application domain of checking software updates. If software package Foo version 13.3.2 was signed on 2019-10-04, and the user receives a copy of Foo version 12.4.8 that was signed on 2019-10-16, it may be authentic and have a more recent signature date. But it is not an upgrade (12.4.8 < 13.3.2), and therefore it should not be applied automatically. In such cases, it is critical that the application confirms that the other information verified is _also_ protected by the relevant OpenPGP signature. Signature validity is a complex topic (see for example the discussion at [DISPLAYING-SIGNATURES]), and this documentation cannot list all possible details. 10.2. Compression The interface as currently specified does not allow for control of compression. Compressing and encrypting data that may contain both attacker-supplied material and sensitive material could leak information about the sensitive material (see the CRIME attack). Unless an application knows for sure that no attacker-supplied material is present in the input, it should not compress during encryption. 11. Privacy Considerations Material produced by sop encrypt may be placed on an untrusted machine (e.g., sent through the public SMTP network). That material may contain metadata that leaks associational information (e.g., recipient identifiers in PKESK packets (Section 5.1 of [I-D.ietf-openpgp-crypto-refresh-05])). FIXME: document things like PURBs and --hidden-recipient) 11.1. Object Security vs. Transport Security OpenPGP offers an object security model, but says little to nothing about how the secured objects get to the relevant parties. When sending or receiving OpenPGP material, the implementer should consider what privacy leakage is implicit with the transport. 12. References 12.1. Normative References Gillmor Expires 16 November 2022 [Page 36] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 [I-D.ietf-openpgp-crypto-refresh-05] Koch, W. and P. Wouters, "OpenPGP Message Format", Work in Progress, Internet-Draft, draft-ietf-openpgp-crypto- refresh-05, 7 March 2022, . [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997, . [RFC3156] Elkins, M., Del Torto, D., Levien, R., and T. Roessler, "MIME Security with OpenPGP", RFC 3156, DOI 10.17487/RFC3156, August 2001, . [RFC3629] Yergeau, F., "UTF-8, a transformation format of ISO 10646", STD 63, RFC 3629, DOI 10.17487/RFC3629, November 2003, . [RFC4880] Callas, J., Donnerhacke, L., Finney, H., Shaw, D., and R. Thayer, "OpenPGP Message Format", RFC 4880, DOI 10.17487/RFC4880, November 2007, . [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, May 2017, . 12.2. Informative References [Charset-Switching] Gillmor, D. K., "Inline PGP Considered Harmful", 24 February 2014, . [DISPLAYING-SIGNATURES] Brunschwig, P., "On Displaying Signatures", n.d., . [EFAIL] Poddebniak, D. and C. Dresen, "Efail: Breaking S/MIME and OpenPGP Email Encryption using Exfiltration Channels", n.d., . Gillmor Expires 16 November 2022 [Page 37] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 [I-D.draft-bre-openpgp-samples-01] Einarsson, B. R., "juga", and D. K. Gillmor, "OpenPGP Example Keys and Certificates", Work in Progress, Internet-Draft, draft-bre-openpgp-samples-01, 20 December 2019, . [OpenPGP-Interoperability-Test-Suite] "OpenPGP Interoperability Test Suite", 25 October 2021, . [PYTHON-SOP] Gillmor, D., "SOP for python", n.d., . [RFC0959] Postel, J. and J. Reynolds, "File Transfer Protocol", STD 9, RFC 959, DOI 10.17487/RFC0959, October 1985, . [RFC5321] Klensin, J., "Simple Mail Transfer Protocol", RFC 5321, DOI 10.17487/RFC5321, October 2008, . [RUST-SOP] Winter, J., "A Rust implementation of the Stateless OpenPGP Protocol", n.d., . [SEMVER] Preston-Werner, T., "Semantic Versioning 2.0.0", 18 June 2013, . [SOP-JAVA] Schaub, P., "Stateless OpenPGP Protocol for Java.", n.d., . [UNICODE-NORMALIZATION] Whistler, K., "Unicode Normalization Forms", 4 February 2019, . Appendix A. Acknowledgements This work was inspired by Justus Winter's [OpenPGP-Interoperability-Test-Suite]. The following people contributed helpful feedback and considerations to this draft, but are not responsible for its problems: * Allan Nordhoey * Antoine Beaupre Gillmor Expires 16 November 2022 [Page 38] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 * Edwin Taylor * Heiko Schaefer * Jameson Rollins * Justus Winter * Paul Schaub * Vincent Breitmoser Appendix B. Future Work * certificate transformation into popular publication forms: - WKD - DANE OPENPGPKEY - Autocrypt * sop encrypt -- specify compression? (see Section 10.2) * sop encrypt -- specify padding policy/mechanism? * sop decrypt -- how can it more safely handle zip bombs? * sop decrypt -- what should it do when encountering weakly- encrypted (or unencrypted) input? * sop encrypt -- minimize metadata (e.g. --throw-keyids)? * specify an error if a DATE arrives as input without a time zone? * add considerations about what it means for armored CERTS to contain multiple certificates -- multiple armorings? one big blob? * do we need an interface or option (for performance?) with the semantics that sop doesn't validate certificates internally, it just accepts whatever's given as legit data? (see Section 8.6) * do we need to be able to convert a message with a text-based signature to a CSF INLINESIGNED message? I'd rather not, given the additional complications. Gillmor Expires 16 November 2022 [Page 39] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 Appendix C. Document History C.1. Substantive Changes between -03 and -04: * Reinforce that PASSWORD and SESSIONKEY are indirect data types * sign: remove --as=mime option * Handle password-locked secret key material: add --with-key- password options to generate-key, sign, and decrypt. * Introduce INLINESIGNED message type (Section 5.5) * Rename detach-inband-signature-and-message to inline-detach, clarify its possible inputs * Add inline-verify * Add inline-sign C.2. Substantive Changes between -02 and -03: * Added --micalg-out parameter to sign * Change from KEY to KEYS (permit multiple secret keys in each blob) * New error code: KEY_CANNOT_SIGN * version now has --backend and --extended options C.3. Substantive Changes between -01 and -02: * Added mnemonics for return codes * decrypt should fail when asked to output to a pre-existing file * Removed superfluous --armor option * Much more specific about what armor --label=auto should do * armor and dearmor are now fully idempotent, but work only well- formed OpenPGP streams * Dropped armor --allow-nested * Specified what encrypt --as= means * New error code: KEY_IS_PROTECTED Gillmor Expires 16 November 2022 [Page 40] Internet-Draft Stateless OpenPGP Command Line Interface May 2022 * Documented expectations around human-readable, human-transferable passwords * New subcommand: detach-inband-signature-and-message * More specific guidance about special designators like @FD: and @ENV:, including new error codes UNSUPPORTED_SPECIAL_PREFIX and AMBIGUOUS_INPUT C.4. Substantive Changes between -00 and -01: * Changed generate subcommand to generate-key * Changed convert subcommand to extract-cert * Added "Input String Types" section as distinct from indirect I/O * Made implicit arguments potentially explicit (e.g. sop armor --label=auto) * Added --allow-nested to sop armor to make it idempotent by default * Added fingerprint of signing (sub)key to VERIFICATIONS output * Dropped --mode and --session-key arguments for sop encrypt (no plausible use, not needed for interop) * Added --with-session-key argument to sop decrypt to allow for session-key-based decryption * Added examples to each subcommand * More detailed error codes for sop encrypt * Move from CERT to CERTS (each CERTS argument might contain multiple certificates) Author's Address Daniel Kahn Gillmor American Civil Liberties Union 125 Broad St. New York, NY, 10004 United States of America Email: dkg@fifthhorseman.net Gillmor Expires 16 November 2022 [Page 41]