draft-ietf-jose-json-web-algorithms-38

JOSE Working Group M. Jones
Internet-Draft Microsoft
Intended status: Standards Track December 9, 2014
Expires: June 12, 2015
 JSON Web Algorithms (JWA)
 draft-ietf-jose-json-web-algorithms-38
Abstract
 The JSON Web Algorithms (JWA) specification registers cryptographic
 algorithms and identifiers to be used with the JSON Web Signature
 (JWS), JSON Web Encryption (JWE), and JSON Web Key (JWK)
 specifications. It defines several IANA registries for these
 identifiers.
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 http://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 June 12, 2015.
Copyright Notice
 Copyright (c) 2014 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
 (http://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
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 the Trust Legal Provisions and are provided without warranty as
 described in the Simplified BSD License.
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Table of Contents
 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 5
 1.1. Notational Conventions . . . . . . . . . . . . . . . . . . 5
 2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 5
 3. Cryptographic Algorithms for Digital Signatures and MACs . . . 6
 3.1. "alg" (Algorithm) Header Parameter Values for JWS . . . . 6
 3.2. HMAC with SHA-2 Functions . . . . . . . . . . . . . . . . 7
 3.3. Digital Signature with RSASSA-PKCS1-V1_5 . . . . . . . . . 8
 3.4. Digital Signature with ECDSA . . . . . . . . . . . . . . . 9
 3.5. Digital Signature with RSASSA-PSS . . . . . . . . . . . . 11
 3.6. Using the Algorithm "none" . . . . . . . . . . . . . . . . 12
 4. Cryptographic Algorithms for Key Management . . . . . . . . . 12
 4.1. "alg" (Algorithm) Header Parameter Values for JWE . . . . 12
 4.2. Key Encryption with RSAES-PKCS1-V1_5 . . . . . . . . . . . 14
 4.3. Key Encryption with RSAES OAEP . . . . . . . . . . . . . . 14
 4.4. Key Wrapping with AES Key Wrap . . . . . . . . . . . . . . 15
 4.5. Direct Encryption with a Shared Symmetric Key . . . . . . 16
 4.6. Key Agreement with Elliptic Curve Diffie-Hellman
 Ephemeral Static (ECDH-ES) . . . . . . . . . . . . . . . . 16
 4.6.1. Header Parameters Used for ECDH Key Agreement . . . . 17
 4.6.1.1. "epk" (Ephemeral Public Key) Header Parameter . . 17
 4.6.1.2. "apu" (Agreement PartyUInfo) Header Parameter . . 17
 4.6.1.3. "apv" (Agreement PartyVInfo) Header Parameter . . 17
 4.6.2. Key Derivation for ECDH Key Agreement . . . . . . . . 18
 4.7. Key Encryption with AES GCM . . . . . . . . . . . . . . . 19
 4.7.1. Header Parameters Used for AES GCM Key Encryption . . 20
 4.7.1.1. "iv" (Initialization Vector) Header Parameter . . 20
 4.7.1.2. "tag" (Authentication Tag) Header Parameter . . . 20
 4.8. Key Encryption with PBES2 . . . . . . . . . . . . . . . . 20
 4.8.1. Header Parameters Used for PBES2 Key Encryption . . . 21
 4.8.1.1. "p2s" (PBES2 salt input) Parameter . . . . . . . . 21
 4.8.1.2. "p2c" (PBES2 count) Parameter . . . . . . . . . . 21
 5. Cryptographic Algorithms for Content Encryption . . . . . . . 22
 5.1. "enc" (Encryption Algorithm) Header Parameter Values
 for JWE . . . . . . . . . . . . . . . . . . . . . . . . . 22
 5.2. AES_CBC_HMAC_SHA2 Algorithms . . . . . . . . . . . . . . . 23
 5.2.1. Conventions Used in Defining AES_CBC_HMAC_SHA2 . . . . 23
 5.2.2. Generic AES_CBC_HMAC_SHA2 Algorithm . . . . . . . . . 23
 5.2.2.1. AES_CBC_HMAC_SHA2 Encryption . . . . . . . . . . . 23
 5.2.2.2. AES_CBC_HMAC_SHA2 Decryption . . . . . . . . . . . 25
 5.2.3. AES_128_CBC_HMAC_SHA_256 . . . . . . . . . . . . . . . 25
 5.2.4. AES_192_CBC_HMAC_SHA_384 . . . . . . . . . . . . . . . 26
 5.2.5. AES_256_CBC_HMAC_SHA_512 . . . . . . . . . . . . . . . 26
 5.2.6. Content Encryption with AES_CBC_HMAC_SHA2 . . . . . . 27
 5.3. Content Encryption with AES GCM . . . . . . . . . . . . . 27
 6. Cryptographic Algorithms for Keys . . . . . . . . . . . . . . 28
 6.1. "kty" (Key Type) Parameter Values . . . . . . . . . . . . 28
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 6.2. Parameters for Elliptic Curve Keys . . . . . . . . . . . . 28
 6.2.1. Parameters for Elliptic Curve Public Keys . . . . . . 28
 6.2.1.1. "crv" (Curve) Parameter . . . . . . . . . . . . . 29
 6.2.1.2. "x" (X Coordinate) Parameter . . . . . . . . . . . 29
 6.2.1.3. "y" (Y Coordinate) Parameter . . . . . . . . . . . 29
 6.2.2. Parameters for Elliptic Curve Private Keys . . . . . . 30
 6.2.2.1. "d" (ECC Private Key) Parameter . . . . . . . . . 30
 6.3. Parameters for RSA Keys . . . . . . . . . . . . . . . . . 30
 6.3.1. Parameters for RSA Public Keys . . . . . . . . . . . . 30
 6.3.1.1. "n" (Modulus) Parameter . . . . . . . . . . . . . 30
 6.3.1.2. "e" (Exponent) Parameter . . . . . . . . . . . . . 30
 6.3.2. Parameters for RSA Private Keys . . . . . . . . . . . 31
 6.3.2.1. "d" (Private Exponent) Parameter . . . . . . . . . 31
 6.3.2.2. "p" (First Prime Factor) Parameter . . . . . . . . 31
 6.3.2.3. "q" (Second Prime Factor) Parameter . . . . . . . 31
 6.3.2.4. "dp" (First Factor CRT Exponent) Parameter . . . . 31
 6.3.2.5. "dq" (Second Factor CRT Exponent) Parameter . . . 31
 6.3.2.6. "qi" (First CRT Coefficient) Parameter . . . . . . 31
 6.3.2.7. "oth" (Other Primes Info) Parameter . . . . . . . 32
 6.4. Parameters for Symmetric Keys . . . . . . . . . . . . . . 32
 6.4.1. "k" (Key Value) Parameter . . . . . . . . . . . . . . 32
 7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 33
 7.1. JSON Web Signature and Encryption Algorithms Registry . . 34
 7.1.1. Registration Template . . . . . . . . . . . . . . . . 34
 7.1.2. Initial Registry Contents . . . . . . . . . . . . . . 35
 7.2. Header Parameter Names Registration . . . . . . . . . . . 41
 7.2.1. Registry Contents . . . . . . . . . . . . . . . . . . 41
 7.3. JSON Web Encryption Compression Algorithms Registry . . . 42
 7.3.1. Registration Template . . . . . . . . . . . . . . . . 42
 7.3.2. Initial Registry Contents . . . . . . . . . . . . . . 43
 7.4. JSON Web Key Types Registry . . . . . . . . . . . . . . . 43
 7.4.1. Registration Template . . . . . . . . . . . . . . . . 44
 7.4.2. Initial Registry Contents . . . . . . . . . . . . . . 44
 7.5. JSON Web Key Parameters Registration . . . . . . . . . . . 45
 7.5.1. Registry Contents . . . . . . . . . . . . . . . . . . 45
 7.6. JSON Web Key Elliptic Curve Registry . . . . . . . . . . . 47
 7.6.1. Registration Template . . . . . . . . . . . . . . . . 47
 7.6.2. Initial Registry Contents . . . . . . . . . . . . . . 48
 8. Security Considerations . . . . . . . . . . . . . . . . . . . 49
 8.1. Cryptographic Agility . . . . . . . . . . . . . . . . . . 49
 8.2. Key Lifetimes . . . . . . . . . . . . . . . . . . . . . . 49
 8.3. RSAES-PKCS1-v1_5 Security Considerations . . . . . . . . . 49
 8.4. AES GCM Security Considerations . . . . . . . . . . . . . 49
 8.5. Unsecured JWS Security Considerations . . . . . . . . . . 50
 8.6. Denial of Service Attacks . . . . . . . . . . . . . . . . 50
 8.7. Reusing Key Material when Encrypting Keys . . . . . . . . 51
 8.8. Password Considerations . . . . . . . . . . . . . . . . . 51
 8.9. Key Entropy and Random Values . . . . . . . . . . . . . . 52
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 8.10. Differences between Digital Signatures and MACs . . . . . 52
 8.11. Using Matching Algorithm Strengths . . . . . . . . . . . . 52
 8.12. Adaptive Chosen-Ciphertext Attacks . . . . . . . . . . . . 52
 8.13. Timing Attacks . . . . . . . . . . . . . . . . . . . . . . 52
 8.14. RSA Private Key Representations and Blinding . . . . . . . 52
 9. Internationalization Considerations . . . . . . . . . . . . . 52
 10. References . . . . . . . . . . . . . . . . . . . . . . . . . . 52
 10.1. Normative References . . . . . . . . . . . . . . . . . . . 52
 10.2. Informative References . . . . . . . . . . . . . . . . . . 54
 Appendix A. Algorithm Identifier Cross-Reference . . . . . . . . 56
 A.1. Digital Signature/MAC Algorithm Identifier
 Cross-Reference . . . . . . . . . . . . . . . . . . . . . 57
 A.2. Key Management Algorithm Identifier Cross-Reference . . . 57
 A.3. Content Encryption Algorithm Identifier Cross-Reference . 58
 Appendix B. Test Cases for AES_CBC_HMAC_SHA2 Algorithms . . . . . 59
 B.1. Test Cases for AES_128_CBC_HMAC_SHA_256 . . . . . . . . . 60
 B.2. Test Cases for AES_192_CBC_HMAC_SHA_384 . . . . . . . . . 61
 B.3. Test Cases for AES_256_CBC_HMAC_SHA_512 . . . . . . . . . 62
 Appendix C. Example ECDH-ES Key Agreement Computation . . . . . . 63
 Appendix D. Acknowledgements . . . . . . . . . . . . . . . . . . 65
 Appendix E. Document History . . . . . . . . . . . . . . . . . . 66
 Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 77
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. Introduction
 The JSON Web Algorithms (JWA) specification registers cryptographic
 algorithms and identifiers to be used with the JSON Web Signature
 (JWS) [JWS], JSON Web Encryption (JWE) [JWE], and JSON Web Key (JWK)
 [JWK] specifications. It defines several IANA registries for these
 identifiers. All these specifications utilize JavaScript Object
 Notation (JSON) [RFC7159] based data structures. This specification
 also describes the semantics and operations that are specific to
 these algorithms and key types.
 Registering the algorithms and identifiers here, rather than in the
 JWS, JWE, and JWK specifications, is intended to allow them to remain
 unchanged in the face of changes in the set of Required, Recommended,
 Optional, and Deprecated algorithms over time. This also allows
 changes to the JWS, JWE, and JWK specifications without changing this
 document.
 Names defined by this specification are short because a core goal is
 for the resulting representations to be compact.
1.1. Notational Conventions
 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 Key
 words for use in RFCs to Indicate Requirement Levels [RFC2119]. If
 these words are used without being spelled in uppercase then they are
 to be interpreted with their normal natural language meanings.
 BASE64URL(OCTETS) denotes the base64url encoding of OCTETS, per
 Section 2 of [JWS].
 UTF8(STRING) denotes the octets of the UTF-8 [RFC3629] representation
 of STRING.
 ASCII(STRING) denotes the octets of the ASCII [RFC20] representation
 of STRING.
 The concatenation of two values A and B is denoted as A || B.
. Terminology
 These terms defined by the JSON Web Signature (JWS) [JWS]
 specification are incorporated into this specification: "JSON Web
 Signature (JWS)", "Base64url Encoding", "Header Parameter", "JOSE
 Header", "JWS Payload", "JWS Protected Header", "JWS Signature", "JWS
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 Signing Input", and "Unsecured JWS".
 These terms defined by the JSON Web Encryption (JWE) [JWE]
 specification are incorporated into this specification: "JSON Web
 Encryption (JWE)", "Additional Authenticated Data (AAD)",
 "Authentication Tag", "Content Encryption Key (CEK)", "Direct
 Encryption", "Direct Key Agreement", "JWE Authentication Tag", "JWE
 Ciphertext", "JWE Encrypted Key", "JWE Initialization Vector", "JWE
 Protected Header", "Key Agreement with Key Wrapping", "Key
 Encryption", "Key Management Mode", and "Key Wrapping".
 These terms defined by the JSON Web Key (JWK) [JWK] specification are
 incorporated into this specification: "JSON Web Key (JWK)" and "JSON
 Web Key Set (JWK Set)".
 These terms defined by the Internet Security Glossary, Version 2
 [RFC4949] are incorporated into this specification: "Ciphertext",
 "Digital Signature", "Message Authentication Code (MAC)", and
 "Plaintext".
 This term is defined by this specification:
 Base64urlUInt
 The representation of a positive or zero integer value as the
 base64url encoding of the value's unsigned big endian
 representation as an octet sequence. The octet sequence MUST
 utilize the minimum number of octets needed to represent the
 value. Zero is represented as BASE64URL(single zero-valued
 octet), which is "AA".
. Cryptographic Algorithms for Digital Signatures and MACs
 JWS uses cryptographic algorithms to digitally sign or create a
 Message Authentication Code (MAC) of the contents of the JWS
 Protected Header and the JWS Payload.
3.1. "alg" (Algorithm) Header Parameter Values for JWS
 The table below is the set of "alg" (algorithm) header parameter
 values defined by this specification for use with JWS, each of which
 is explained in more detail in the following sections:
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 +--------------+-----------------------------------+----------------+
 | alg Param | Digital Signature or MAC | Implementation |
 | Value | Algorithm | Requirements |
 +--------------+-----------------------------------+----------------+
 | HS256 | HMAC using SHA-256 | Required |
 | HS384 | HMAC using SHA-384 | Optional |
 | HS512 | HMAC using SHA-512 | Optional |
 | RS256 | RSASSA-PKCS-v1_5 using SHA-256 | Recommended |
 | RS384 | RSASSA-PKCS-v1_5 using SHA-384 | Optional |
 | RS512 | RSASSA-PKCS-v1_5 using SHA-512 | Optional |
 | ES256 | ECDSA using P-256 and SHA-256 | Recommended+ |
 | ES384 | ECDSA using P-384 and SHA-384 | Optional |
 | ES512 | ECDSA using P-521 and SHA-512 | Optional |
 | PS256 | RSASSA-PSS using SHA-256 and MGF1 | Optional |
 | | with SHA-256 | |
 | PS384 | RSASSA-PSS using SHA-384 and MGF1 | Optional |
 | | with SHA-384 | |
 | PS512 | RSASSA-PSS using SHA-512 and MGF1 | Optional |
 | | with SHA-512 | |
 | none | No digital signature or MAC | Optional |
 | | performed | |
 +--------------+-----------------------------------+----------------+
 The use of "+" in the Implementation Requirements indicates that the
 requirement strength is likely to be increased in a future version of
 the specification.
 See Appendix A.1 for a table cross-referencing the JWS digital
 signature and MAC "alg" (algorithm) values defined in this
 specification with the equivalent identifiers used by other standards
 and software packages.
3.2. HMAC with SHA-2 Functions
 Hash-based Message Authentication Codes (HMACs) enable one to use a
 secret plus a cryptographic hash function to generate a Message
 Authentication Code (MAC). This can be used to demonstrate that
 whoever generated the MAC was in possession of the MAC key. The
 algorithm for implementing and validating HMACs is provided in RFC
 2104 [RFC2104].
 A key of the same size as the hash output (for instance, 256 bits for
 "HS256") or larger MUST be used with this algorithm. (This
 requirement is based on Section 5.3.4 (Security Effect of the HMAC
 Key) of NIST SP 800-117 [NIST.800-107], which states that the
 effective security strength is the minimum of the security strength
 of the key and two times the size of the internal hash value.)
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 The HMAC SHA-256 MAC is generated per RFC 2104, using SHA-256 as the
 hash algorithm "H", using the JWS Signing Input as the "text" value,
 and using the shared key. The HMAC output value is the JWS
 Signature.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWS Signature is an HMAC value computed using the
 corresponding algorithm:
 +-----------------+--------------------+
 | alg Param Value | MAC Algorithm |
 +-----------------+--------------------+
 | HS256 | HMAC using SHA-256 |
 | HS384 | HMAC using SHA-384 |
 | HS512 | HMAC using SHA-512 |
 +-----------------+--------------------+
 The HMAC SHA-256 MAC for a JWS is validated by computing an HMAC
 value per RFC 2104, using SHA-256 as the hash algorithm "H", using
 the received JWS Signing Input as the "text" value, and using the
 shared key. This computed HMAC value is then compared to the result
 of base64url decoding the received encoded JWS Signature value. The
 comparison of the computed HMAC value to the JWS Signature value MUST
 be done in a constant-time manner to thwart timing attacks.
 Alternatively, the computed HMAC value can be base64url encoded and
 compared to the received encoded JWS Signature value (also in a
 constant-time manner), as this comparison produces the same result as
 comparing the unencoded values. In either case, if the values match,
 the HMAC has been validated.
 Securing content and validation with the HMAC SHA-384 and HMAC SHA-
 512 algorithms is performed identically to the procedure for HMAC
 SHA-256 -- just using the corresponding hash algorithms with
 correspondingly larger minimum key sizes and result values: 384 bits
 each for HMAC SHA-384 and 512 bits each for HMAC SHA-512.
 An example using this algorithm is shown in Appendix A.1 of [JWS].
3.3. Digital Signature with RSASSA-PKCS1-V1_5
 This section defines the use of the RSASSA-PKCS1-V1_5 digital
 signature algorithm as defined in Section 8.2 of RFC 3447 [RFC3447]
 (commonly known as PKCS #1), using SHA-2 [SHS] hash functions.
 A key of size 2048 bits or larger MUST be used with these algorithms.
 The RSASSA-PKCS1-V1_5 SHA-256 digital signature is generated as
 follows: Generate a digital signature of the JWS Signing Input using
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 RSASSA-PKCS1-V1_5-SIGN and the SHA-256 hash function with the desired
 private key. This is the JWS Signature value.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWS Signature is a digital signature value computed
 using the corresponding algorithm:
 +-----------------+--------------------------------+
 | alg Param Value | Digital Signature Algorithm |
 +-----------------+--------------------------------+
 | RS256 | RSASSA-PKCS-v1_5 using SHA-256 |
 | RS384 | RSASSA-PKCS-v1_5 using SHA-384 |
 | RS512 | RSASSA-PKCS-v1_5 using SHA-512 |
 +-----------------+--------------------------------+
 The RSASSA-PKCS1-V1_5 SHA-256 digital signature for a JWS is
 validated as follows: Submit the JWS Signing Input, the JWS
 Signature, and the public key corresponding to the private key used
 by the signer to the RSASSA-PKCS1-V1_5-VERIFY algorithm using SHA-256
 as the hash function.
 Signing and validation with the RSASSA-PKCS1-V1_5 SHA-384 and RSASSA-
 PKCS1-V1_5 SHA-512 algorithms is performed identically to the
 procedure for RSASSA-PKCS1-V1_5 SHA-256 -- just using the
 corresponding hash algorithms instead of SHA-256.
 An example using this algorithm is shown in Appendix A.2 of [JWS].
3.4. Digital Signature with ECDSA
 The Elliptic Curve Digital Signature Algorithm (ECDSA) [DSS] provides
 for the use of Elliptic Curve cryptography, which is able to provide
 equivalent security to RSA cryptography but using shorter key sizes
 and with greater processing speed for many operations. This means
 that ECDSA digital signatures will be substantially smaller in terms
 of length than equivalently strong RSA digital signatures.
 This specification defines the use of ECDSA with the P-256 curve and
 the SHA-256 cryptographic hash function, ECDSA with the P-384 curve
 and the SHA-384 hash function, and ECDSA with the P-521 curve and the
 SHA-512 hash function. The P-256, P-384, and P-521 curves are
 defined in [DSS].
 The ECDSA P-256 SHA-256 digital signature is generated as follows:
 1. Generate a digital signature of the JWS Signing Input using ECDSA
 P-256 SHA-256 with the desired private key. The output will be
 the pair (R, S), where R and S are 256 bit unsigned integers.
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 2. Turn R and S into octet sequences in big endian order, with each
 array being be 32 octets long. The octet sequence
 representations MUST NOT be shortened to omit any leading zero
 octets contained in the values.
 3. Concatenate the two octet sequences in the order R and then S.
 (Note that many ECDSA implementations will directly produce this
 concatenation as their output.)
 4. The resulting 64 octet sequence is the JWS Signature value.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWS Signature is a digital signature value computed
 using the corresponding algorithm:
 +-----------------+-------------------------------+
 | alg Param Value | Digital Signature Algorithm |
 +-----------------+-------------------------------+
 | ES256 | ECDSA using P-256 and SHA-256 |
 | ES384 | ECDSA using P-384 and SHA-384 |
 | ES512 | ECDSA using P-521 and SHA-512 |
 +-----------------+-------------------------------+
 The ECDSA P-256 SHA-256 digital signature for a JWS is validated as
 follows:
 1. The JWS Signature value MUST be a 64 octet sequence. If it is
 not a 64 octet sequence, the validation has failed.
 2. Split the 64 octet sequence into two 32 octet sequences. The
 first octet sequence represents R and the second S. The values R
 and S are represented as octet sequences using the Integer-to-
 OctetString Conversion defined in Section 2.3.7 of SEC1 [SEC1]
 (in big endian octet order).
 3. Submit the JWS Signing Input R, S and the public key (x, y) to
 the ECDSA P-256 SHA-256 validator.
 Signing and validation with the ECDSA P-384 SHA-384 and ECDSA P-521
 SHA-512 algorithms is performed identically to the procedure for
 ECDSA P-256 SHA-256 -- just using the corresponding hash algorithms
 with correspondingly larger result values. For ECDSA P-384 SHA-384,
 R and S will be 384 bits each, resulting in a 96 octet sequence. For
 ECDSA P-521 SHA-512, R and S will be 521 bits each, resulting in a
 132 octet sequence. (Note that the Integer-to-OctetString Conversion
 defined in Section 2.3.7 of SEC1 [SEC1] used to represent R and S as
 octet sequences adds zero-valued high-order padding bits when needed
 to round the size up to a multiple of 8 bits; thus, each 521-bit
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 integer is represented using 528 bits in 66 octets.)
 Examples using these algorithms are shown in Appendices A.3 and A.4
 of [JWS].
3.5. Digital Signature with RSASSA-PSS
 This section defines the use of the RSASSA-PSS digital signature
 algorithm as defined in Section 8.1 of RFC 3447 [RFC3447] with the
 MGF1 mask generation function and SHA-2 hash functions, always using
 the same hash function for both the RSASSA-PSS hash function and the
 MGF1 hash function. The size of the salt value is the same size as
 the hash function output. All other algorithm parameters use the
 defaults specified in Section A.2.3 of RFC 3447.
 A key of size 2048 bits or larger MUST be used with this algorithm.
 The RSASSA-PSS SHA-256 digital signature is generated as follows:
 Generate a digital signature of the JWS Signing Input using RSASSA-
 PSS-SIGN, the SHA-256 hash function, and the MGF1 mask generation
 function with SHA-256 with the desired private key. This is the JWS
 signature value.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWS Signature is a digital signature value computed
 using the corresponding algorithm:
 +-----------------+------------------------------------------------+
 | alg Param Value | Digital Signature Algorithm |
 +-----------------+------------------------------------------------+
 | PS256 | RSASSA-PSS using SHA-256 and MGF1 with SHA-256 |
 | PS384 | RSASSA-PSS using SHA-384 and MGF1 with SHA-384 |
 | PS512 | RSASSA-PSS using SHA-512 and MGF1 with SHA-512 |
 +-----------------+------------------------------------------------+
 The RSASSA-PSS SHA-256 digital signature for a JWS is validated as
 follows: Submit the JWS Signing Input, the JWS Signature, and the
 public key corresponding to the private key used by the signer to the
 RSASSA-PSS-VERIFY algorithm using SHA-256 as the hash function and
 using MGF1 as the mask generation function with SHA-256.
 Signing and validation with the RSASSA-PSS SHA-384 and RSASSA-PSS
 SHA-512 algorithms is performed identically to the procedure for
 RSASSA-PSS SHA-256 -- just using the alternative hash algorithm in
 both roles.
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3.6. Using the Algorithm "none"
 JWSs MAY also be created that do not provide integrity protection.
 Such a JWS is called an Unsecured JWS. An Unsecured JWS uses the
 "alg" value "none" and is formatted identically to other JWSs, but
 MUST use the empty octet sequence as its JWS Signature value.
 Recipients MUST verify that the JWS Signature value is the empty
 octet sequence.
 Implementations that support Unsecured JWSs MUST NOT accept such
 objects as valid unless the application specifies that it is
 acceptable for a specific object to not be integrity protected.
 Implementations MUST NOT accept Unsecured JWSs by default. In order
 to mitigate downgrade attacks, applications MUST NOT signal
 acceptance of Unsecured JWSs at a global level, and SHOULD signal
 acceptance on a per-object basis. See Section 8.5 for security
 considerations associated with using this algorithm.
. Cryptographic Algorithms for Key Management
 JWE uses cryptographic algorithms to encrypt or determine the Content
 Encryption Key (CEK).
4.1. "alg" (Algorithm) Header Parameter Values for JWE
 The table below is the set of "alg" (algorithm) Header Parameter
 values that are defined by this specification for use with JWE.
 These algorithms are used to encrypt the CEK, producing the JWE
 Encrypted Key, or to use key agreement to agree upon the CEK.
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 +--------------------+--------------------+--------+----------------+
 | alg Param Value | Key Management | More | Implementation |
 | | Algorithm | Header | Requirements |
 | | | Params | |
 +--------------------+--------------------+--------+----------------+
 | RSA1_5 | RSAES-PKCS1-V1_5 | (none) | Recommended- |
 | RSA-OAEP | RSAES OAEP using | (none) | Recommended+ |
 | | default parameters | | |
 | RSA-OAEP-256 | RSAES OAEP using | (none) | Optional |
 | | SHA-256 and MGF1 | | |
 | | with SHA-256 | | |
 | A128KW | AES Key Wrap with | (none) | Recommended |
 | | default initial | | |
 | | value using 128 | | |
 | | bit key | | |
 | A192KW | AES Key Wrap with | (none) | Optional |
 | | default initial | | |
 | | value using 192 | | |
 | | bit key | | |
 | A256KW | AES Key Wrap with | (none) | Recommended |
 | | default initial | | |
 | | value using 256 | | |
 | | bit key | | |
 | dir | Direct use of a | (none) | Recommended |
 | | shared symmetric | | |
 | | key as the CEK | | |
 | ECDH-ES | Elliptic Curve | "epk", | Recommended+ |
 | | Diffie-Hellman | "apu", | |
 | | Ephemeral Static | "apv" | |
 | | key agreement | | |
 | | using Concat KDF | | |
 | ECDH-ES+A128KW | ECDH-ES using | "epk", | Recommended |
 | | Concat KDF and CEK | "apu", | |
 | | wrapped with | "apv" | |
 | | "A128KW" | | |
 | ECDH-ES+A192KW | ECDH-ES using | "epk", | Optional |
 | | Concat KDF and CEK | "apu", | |
 | | wrapped with | "apv" | |
 | | "A192KW" | | |
 | ECDH-ES+A256KW | ECDH-ES using | "epk", | Recommended |
 | | Concat KDF and CEK | "apu", | |
 | | wrapped with | "apv" | |
 | | "A256KW" | | |
 | A128GCMKW | Key wrapping with | "iv", | Optional |
 | | AES GCM using 128 | "tag" | |
 | | bit key | | |
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 | A192GCMKW | Key wrapping with | "iv", | Optional |
 | | AES GCM using 192 | "tag" | |
 | | bit key | | |
 | A256GCMKW | Key wrapping with | "iv", | Optional |
 | | AES GCM using 256 | "tag" | |
 | | bit key | | |
 | PBES2-HS256+A128KW | PBES2 with HMAC | "p2s", | Optional |
 | | SHA-256 and | "p2c" | |
 | | "A128KW" wrapping | | |
 | PBES2-HS384+A192KW | PBES2 with HMAC | "p2s", | Optional |
 | | SHA-384 and | "p2c" | |
 | | "A192KW" wrapping | | |
 | PBES2-HS512+A256KW | PBES2 with HMAC | "p2s", | Optional |
 | | SHA-512 and | "p2c" | |
 | | "A256KW" wrapping | | |
 +--------------------+--------------------+--------+----------------+
 The More Header Params column indicates what additional Header
 Parameters are used by the algorithm, beyond "alg", which all use.
 All but "dir" and "ECDH-ES" also produce a JWE Encrypted Key value.
 The use of "+" in the Implementation Requirements indicates that the
 requirement strength is likely to be increased in a future version of
 the specification.
 See Appendix A.2 for a table cross-referencing the JWE "alg"
 (algorithm) values defined in this specification with the equivalent
 identifiers used by other standards and software packages.
4.2. Key Encryption with RSAES-PKCS1-V1_5
 This section defines the specifics of encrypting a JWE CEK with
 RSAES-PKCS1-V1_5 [RFC3447]. The "alg" Header Parameter value
 "RSA1_5" is used for this algorithm.
 A key of size 2048 bits or larger MUST be used with this algorithm.
 An example using this algorithm is shown in Appendix A.2 of [JWE].
4.3. Key Encryption with RSAES OAEP
 This section defines the specifics of encrypting a JWE CEK with RSAES
 using Optimal Asymmetric Encryption Padding (OAEP) [RFC3447]. Two
 sets of parameters for using OAEP are defined, which use different
 hash functions. In the first case, the default parameters specified
 by RFC 3447 in Section A.2.1 are used. (Those default parameters are
 the SHA-1 hash function and the MGF1 with SHA-1 mask generation
 function.) In the second case, the SHA-256 hash function and the
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 MGF1 with SHA-256 mask generation function are used.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWE Encrypted Key is the result of encrypting the
 CEK using the corresponding algorithm:
 +-----------------+------------------------------------------------+
 | alg Param Value | Key Management Algorithm |
 +-----------------+------------------------------------------------+
 | RSA-OAEP | RSAES OAEP using default parameters |
 | RSA-OAEP-256 | RSAES OAEP using SHA-256 and MGF1 with SHA-256 |
 +-----------------+------------------------------------------------+
 A key of size 2048 bits or larger MUST be used with these algorithms.
 (This requirement is based on Table 4 (Security-strength time frames)
 of NIST SP 800-57 [NIST.800-57], which requires 112 bits of security
 for new uses, and Table 2 (Comparable strengths) of the same, which
 states that 2048 bit RSA keys provide 112 bits of security.)
 An example using RSAES OAEP with the default parameters is shown in
 Appendix A.1 of [JWE].
4.4. Key Wrapping with AES Key Wrap
 This section defines the specifics of encrypting a JWE CEK with the
 Advanced Encryption Standard (AES) Key Wrap Algorithm [RFC3394] using
 the default initial value specified in Section 2.2.3.1.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWE Encrypted Key is the result of encrypting the
 CEK using the corresponding algorithm and key size:
 +---------------+---------------------------------------------------+
 | alg Param | Key Management Algorithm |
 | Value | |
 +---------------+---------------------------------------------------+
 | A128KW | AES Key Wrap with default initial value using 128 |
 | | bit key |
 | A192KW | AES Key Wrap with default initial value using 192 |
 | | bit key |
 | A256KW | AES Key Wrap with default initial value using 256 |
 | | bit key |
 +---------------+---------------------------------------------------+
 An example using this algorithm is shown in Appendix A.3 of [JWE].
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4.5. Direct Encryption with a Shared Symmetric Key
 This section defines the specifics of directly performing symmetric
 key encryption without performing a key wrapping step. In this case,
 the shared symmetric key is used directly as the Content Encryption
 Key (CEK) value for the "enc" algorithm. An empty octet sequence is
 used as the JWE Encrypted Key value. The "alg" Header Parameter
 value "dir" is used in this case.
 Refer to the security considerations on key lifetimes in Section 8.2
 and AES GCM in Section 8.4 when considering utilizing direct
 encryption.
4.6. Key Agreement with Elliptic Curve Diffie-Hellman Ephemeral Static
 (ECDH-ES)
 This section defines the specifics of key agreement with Elliptic
 Curve Diffie-Hellman Ephemeral Static [RFC6090], in combination with
 the Concat KDF, as defined in Section 5.8.1 of [NIST.800-56A]. The
 key agreement result can be used in one of two ways:
 1. directly as the Content Encryption Key (CEK) for the "enc"
 algorithm, in the Direct Key Agreement mode, or
 2. as a symmetric key used to wrap the CEK with the "A128KW",
 "A192KW", or "A256KW" algorithms, in the Key Agreement with Key
 Wrapping mode.
 A new ephemeral public key value MUST be generated for each key
 agreement operation.
 In Direct Key Agreement mode, the output of the Concat KDF MUST be a
 key of the same length as that used by the "enc" algorithm. In this
 case, the empty octet sequence is used as the JWE Encrypted Key
 value. The "alg" Header Parameter value "ECDH-ES" is used in the
 Direct Key Agreement mode.
 In Key Agreement with Key Wrapping mode, the output of the Concat KDF
 MUST be a key of the length needed for the specified key wrapping
 algorithm. In this case, the JWE Encrypted Key is the CEK wrapped
 with the agreed upon key.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWE Encrypted Key is the result of encrypting the
 CEK using the result of the key agreement algorithm as the key
 encryption key for the corresponding key wrapping algorithm:
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 +----------------+--------------------------------------------------+
 | alg Param | Key Management Algorithm |
 | Value | |
 +----------------+--------------------------------------------------+
 | ECDH-ES+A128KW | ECDH-ES using Concat KDF and CEK wrapped with |
 | | "A128KW" |
 | ECDH-ES+A192KW | ECDH-ES using Concat KDF and CEK wrapped with |
 | | "A192KW" |
 | ECDH-ES+A256KW | ECDH-ES using Concat KDF and CEK wrapped with |
 | | "A256KW" |
 +----------------+--------------------------------------------------+
4.6.1. Header Parameters Used for ECDH Key Agreement
 The following Header Parameter names are used for key agreement as
 defined below.
4.6.1.1. "epk" (Ephemeral Public Key) Header Parameter
 The "epk" (ephemeral public key) value created by the originator for
 the use in key agreement algorithms. This key is represented as a
 JSON Web Key [JWK] public key value. It MUST contain only public key
 parameters and SHOULD contain only the minimum JWK parameters
 necessary to represent the key; other JWK parameters included can be
 checked for consistency and honored or can be ignored. This Header
 Parameter MUST be present and MUST be understood and processed by
 implementations when these algorithms are used.
4.6.1.2. "apu" (Agreement PartyUInfo) Header Parameter
 The "apu" (agreement PartyUInfo) value for key agreement algorithms
 using it (such as "ECDH-ES"), represented as a base64url encoded
 string. When used, the PartyUInfo value contains information about
 the producer. Use of this Header Parameter is OPTIONAL. This Header
 Parameter MUST be understood and processed by implementations when
 these algorithms are used.
4.6.1.3. "apv" (Agreement PartyVInfo) Header Parameter
 The "apv" (agreement PartyVInfo) value for key agreement algorithms
 using it (such as "ECDH-ES"), represented as a base64url encoded
 string. When used, the PartyVInfo value contains information about
 the recipient. Use of this Header Parameter is OPTIONAL. This
 Header Parameter MUST be understood and processed by implementations
 when these algorithms are used.
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4.6.2. Key Derivation for ECDH Key Agreement
 The key derivation process derives the agreed upon key from the
 shared secret Z established through the ECDH algorithm, per Section
 6.2.2.2 of [NIST.800-56A].
 Key derivation is performed using the Concat KDF, as defined in
 Section 5.8.1 of [NIST.800-56A], where the Digest Method is SHA-256.
 The Concat KDF parameters are set as follows:
 Z
 This is set to the representation of the shared secret Z as an
 octet sequence.
 keydatalen
 This is set to the number of bits in the desired output key. For
 "ECDH-ES", this is length of the key used by the "enc" algorithm.
 For "ECDH-ES+A128KW", "ECDH-ES+A192KW", and "ECDH-ES+A256KW", this
 is 128, 192, and 256, respectively.
 AlgorithmID
 The AlgorithmID value is of the form Datalen || Data, where Data
 is a variable-length string of zero or more octets, and Datalen is
 a fixed-length, big endian 32 bit counter that indicates the
 length (in octets) of Data. In the Direct Key Agreement case,
 Data is set to the octets of the ASCII representation of the "enc"
 Header Parameter value. In the Key Agreement with Key Wrapping
 case, Data is set to the octets of the ASCII representation of the
 "alg" Header Parameter value.
 PartyUInfo
 The PartyUInfo value is of the form Datalen || Data, where Data is
 a variable-length string of zero or more octets, and Datalen is a
 fixed-length, big endian 32 bit counter that indicates the length
 (in octets) of Data. If an "apu" (agreement PartyUInfo) Header
 Parameter is present, Data is set to the result of base64url
 decoding the "apu" value and Datalen is set to the number of
 octets in Data. Otherwise, Datalen is set to 0 and Data is set to
 the empty octet sequence.
 PartyVInfo
 The PartyVInfo value is of the form Datalen || Data, where Data is
 a variable-length string of zero or more octets, and Datalen is a
 fixed-length, big endian 32 bit counter that indicates the length
 (in octets) of Data. If an "apv" (agreement PartyVInfo) Header
 Parameter is present, Data is set to the result of base64url
 decoding the "apv" value and Datalen is set to the number of
 octets in Data. Otherwise, Datalen is set to 0 and Data is set to
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 the empty octet sequence.
 SuppPubInfo
 This is set to the keydatalen represented as a 32 bit big endian
 integer.
 SuppPrivInfo
 This is set to the empty octet sequence.
 Applications need to specify how the "apu" and "apv" parameters are
 used for that application. The "apu" and "apv" values MUST be
 distinct, when used. Applications wishing to conform to
 [NIST.800-56A] need to provide values that meet the requirements of
 that document, e.g., by using values that identify the producer and
 consumer. Alternatively, applications MAY conduct key derivation in
 a manner similar to The Diffie-Hellman Key Agreement Method
 [RFC2631]: In that case, the "apu" field MAY either be omitted or
 represent a random 512-bit value (analogous to PartyAInfo in
 Ephemeral-Static mode in RFC 2631) and the "apv" field SHOULD NOT be
 present.
 See Appendix C for an example key agreement computation using this
 method.
4.7. Key Encryption with AES GCM
 This section defines the specifics of encrypting a JWE Content
 Encryption Key (CEK) with Advanced Encryption Standard (AES) in
 Galois/Counter Mode (GCM) [AES, NIST.800-38D].
 Use of an Initialization Vector of size 96 bits is REQUIRED with this
 algorithm. The Initialization Vector is represented in base64url
 encoded form as the "iv" (initialization vector) Header Parameter
 value.
 The Additional Authenticated Data value used is the empty octet
 string.
 The requested size of the Authentication Tag output MUST be 128 bits,
 regardless of the key size.
 The JWE Encrypted Key value is the Ciphertext output.
 The Authentication Tag output is represented in base64url encoded
 form as the "tag" (authentication tag) Header Parameter value.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWE Encrypted Key is the result of encrypting the
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 CEK using the corresponding algorithm and key size:
 +-----------------+---------------------------------------------+
 | alg Param Value | Key Management Algorithm |
 +-----------------+---------------------------------------------+
 | A128GCMKW | Key wrapping with AES GCM using 128 bit key |
 | A192GCMKW | Key wrapping with AES GCM using 192 bit key |
 | A256GCMKW | Key wrapping with AES GCM using 256 bit key |
 +-----------------+---------------------------------------------+
4.7.1. Header Parameters Used for AES GCM Key Encryption
 The following Header Parameters are used for AES GCM key encryption.
4.7.1.1. "iv" (Initialization Vector) Header Parameter
 The "iv" (initialization vector) Header Parameter value is the
 base64url encoded representation of the 96 bit Initialization Vector
 value used for the key encryption operation. This Header Parameter
 MUST be present and MUST be understood and processed by
 implementations when these algorithms are used.
4.7.1.2. "tag" (Authentication Tag) Header Parameter
 The "tag" (authentication tag) Header Parameter value is the
 base64url encoded representation of the 128 bit Authentication Tag
 value resulting from the key encryption operation. This Header
 Parameter MUST be present and MUST be understood and processed by
 implementations when these algorithms are used.
4.8. Key Encryption with PBES2
 This section defines the specifics of performing password-based
 encryption of a JWE CEK, by first deriving a key encryption key from
 a user-supplied password using PBES2 schemes as specified in Section
 6.2 of [RFC2898], then by encrypting the JWE CEK using the derived
 key.
 These algorithms use HMAC SHA-2 algorithms as the Pseudo-Random
 Function (PRF) for the PBKDF2 key derivation and AES Key Wrap
 [RFC3394] for the encryption scheme. The PBES2 password input is an
 octet sequence; if the password to be used is represented as a text
 string rather than an octet sequence, the UTF-8 encoding of the text
 string MUST be used as the octet sequence. The salt parameter MUST
 be computed from the "p2s" (PBES2 salt input) Header Parameter value
 and the "alg" (algorithm) Header Parameter value as specified in the
 "p2s" definition below. The iteration count parameter MUST be
 provided as the "p2c" Header Parameter value. The algorithms
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 respectively use HMAC SHA-256, HMAC SHA-384, and HMAC SHA-512 as the
 PRF and use 128, 192, and 256 bit AES Key Wrap keys. Their derived-
 key lengths respectively are 16, 24, and 32 octets.
 The following "alg" (algorithm) Header Parameter values are used to
 indicate that the JWE Encrypted Key is the result of encrypting the
 CEK using the result of the corresponding password-based encryption
 algorithm as the key encryption key for the corresponding key
 wrapping algorithm:
 +--------------------+----------------------------------------------+
 | alg Param Value | Key Management Algorithm |
 +--------------------+----------------------------------------------+
 | PBES2-HS256+A128KW | PBES2 with HMAC SHA-256 and "A128KW" |
 | | wrapping |
 | PBES2-HS384+A192KW | PBES2 with HMAC SHA-384 and "A192KW" |
 | | wrapping |
 | PBES2-HS512+A256KW | PBES2 with HMAC SHA-512 and "A256KW" |
 | | wrapping |
 +--------------------+----------------------------------------------+
 See Appendix C of JSON Web Key (JWK) [JWK] for an example key
 encryption computation using "PBES2-HS256+A128KW".
4.8.1. Header Parameters Used for PBES2 Key Encryption
 The following Header Parameters are used for Key Encryption with
 PBES2.
4.8.1.1. "p2s" (PBES2 salt input) Parameter
 The "p2s" (PBES2 salt input) Header Parameter encodes a Salt Input
 value, which is used as part of the PBKDF2 salt value. The "p2s"
 value is BASE64URL(Salt Input). This Header Parameter MUST be
 present and MUST be understood and processed by implementations when
 these algorithms are used.
 The salt expands the possible keys that can be derived from a given
 password. A Salt Input value containing 8 or more octets MUST be
 used. A new Salt Input value MUST be generated randomly for every
 encryption operation; see RFC 4086 [RFC4086] for considerations on
 generating random values. The salt value used is (UTF8(Alg) || 0x00
 || Salt Input), where Alg is the "alg" Header Parameter value.
4.8.1.2. "p2c" (PBES2 count) Parameter
 The "p2c" (PBES2 count) Header Parameter contains the PBKDF2
 iteration count, represented as a positive JSON integer. This Header
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 Parameter MUST be present and MUST be understood and processed by
 implementations when these algorithms are used.
 The iteration count adds computational expense, ideally compounded by
 the possible range of keys introduced by the salt. A minimum
 iteration count of 1000 is RECOMMENDED.
. Cryptographic Algorithms for Content Encryption
 JWE uses cryptographic algorithms to encrypt and integrity protect
 the Plaintext and to also integrity protect additional authenticated
 data.
5.1. "enc" (Encryption Algorithm) Header Parameter Values for JWE
 The table below is the set of "enc" (encryption algorithm) Header
 Parameter values that are defined by this specification for use with
 JWE.
 +---------------+----------------------------------+----------------+
 | enc Param | Content Encryption Algorithm | Implementation |
 | Value | | Requirements |
 +---------------+----------------------------------+----------------+
 | A128CBC-HS256 | AES_128_CBC_HMAC_SHA_256 | Required |
 | | authenticated encryption | |
 | | algorithm, as defined in | |
 | | Section 5.2.3 | |
 | A192CBC-HS384 | AES_192_CBC_HMAC_SHA_384 | Optional |
 | | authenticated encryption | |
 | | algorithm, as defined in | |
 | | Section 5.2.4 | |
 | A256CBC-HS512 | AES_256_CBC_HMAC_SHA_512 | Required |
 | | authenticated encryption | |
 | | algorithm, as defined in | |
 | | Section 5.2.5 | |
 | A128GCM | AES GCM using 128 bit key | Recommended |
 | A192GCM | AES GCM using 192 bit key | Optional |
 | A256GCM | AES GCM using 256 bit key | Recommended |
 +---------------+----------------------------------+----------------+
 All also use a JWE Initialization Vector value and produce JWE
 Ciphertext and JWE Authentication Tag values.
 See Appendix A.3 for a table cross-referencing the JWE "enc"
 (encryption algorithm) values defined in this specification with the
 equivalent identifiers used by other standards and software packages.
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5.2. AES_CBC_HMAC_SHA2 Algorithms
 This section defines a family of authenticated encryption algorithms
 built using a composition of Advanced Encryption Standard (AES) [AES]
 in Cipher Block Chaining (CBC) mode [NIST.800-38A] with PKCS #7
 padding [RFC5652], Section 6.3 operations and HMAC [RFC2104, SHS]
 operations. This algorithm family is called AES_CBC_HMAC_SHA2. It
 also defines three instances of this family, the first using 128 bit
 CBC keys and HMAC SHA-256, the second using 192 bit CBC keys and HMAC
 SHA-384, and the third using 256 bit CBC keys and HMAC SHA-512. Test
 cases for these algorithms can be found in Appendix B.
 These algorithms are based upon Authenticated Encryption with AES-CBC
 and HMAC-SHA [I-D.mcgrew-aead-aes-cbc-hmac-sha2], performing the same
 cryptographic computations, but with the Initialization Vector and
 Authentication Tag values remaining separate, rather than being
 concatenated with the Ciphertext value in the output representation.
 This option is discussed in Appendix B of that specification. This
 algorithm family is a generalization of the algorithm family in
 [I-D.mcgrew-aead-aes-cbc-hmac-sha2], and can be used to implement
 those algorithms.
5.2.1. Conventions Used in Defining AES_CBC_HMAC_SHA2
 We use the following notational conventions.
 CBC-PKCS5-ENC(X, P) denotes the AES CBC encryption of P using PKCS
 #7 padding using the cipher with the key X.
 MAC(Y, M) denotes the application of the Message Authentication
 Code (MAC) to the message M, using the key Y.
5.2.2. Generic AES_CBC_HMAC_SHA2 Algorithm
 This section defines AES_CBC_HMAC_SHA2 in a manner that is
 independent of the AES CBC key size or hash function to be used.
 Section 5.2.2.1 and Section 5.2.2.2 define the generic encryption and
 decryption algorithms. Sections 5.2.3 through 5.2.5 define instances
 of AES_CBC_HMAC_SHA2 that specify those details.
5.2.2.1. AES_CBC_HMAC_SHA2 Encryption
 The authenticated encryption algorithm takes as input four octet
 strings: a secret key K, a plaintext P, additional authenticated data
 A, and an initialization vector IV. The authenticated ciphertext
 value E and the authentication tag value T are provided as outputs.
 The data in the plaintext are encrypted and authenticated, and the
 additional authenticated data are authenticated, but not encrypted.
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 The encryption process is as follows, or uses an equivalent set of
 steps:
 1. The secondary keys MAC_KEY and ENC_KEY are generated from the
 input key K as follows. Each of these two keys is an octet
 string.
 MAC_KEY consists of the initial MAC_KEY_LEN octets of K, in
 order.
 ENC_KEY consists of the final ENC_KEY_LEN octets of K, in
 order.
 The number of octets in the input key K MUST be the sum of
 MAC_KEY_LEN and ENC_KEY_LEN. The values of these parameters are
 specified by the Authenticated Encryption algorithms in Sections
 5.2.3 through 5.2.5. Note that the MAC key comes before the
 encryption key in the input key K; this is in the opposite order
 of the algorithm names in the identifier "AES_CBC_HMAC_SHA2".
 2. The Initialization Vector (IV) used is a 128 bit value generated
 randomly or pseudorandomly for use in the cipher.
 3. The plaintext is CBC encrypted using PKCS #7 padding using
 ENC_KEY as the key, and the IV. We denote the ciphertext output
 from this step as E.
 4. The octet string AL is equal to the number of bits in the
 additional authenticated data A expressed as a 64-bit unsigned
 big endian integer.
 5. A message authentication tag T is computed by applying HMAC
 [RFC2104] to the following data, in order:
 the additional authenticated data A,
 the initialization vector IV,
 the ciphertext E computed in the previous step, and
 the octet string AL defined above.
 The string MAC_KEY is used as the MAC key. We denote the output
 of the MAC computed in this step as M. The first T_LEN bits of M
 are used as T.
 6. The Ciphertext E and the Authentication Tag T are returned as the
 outputs of the authenticated encryption.
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 The encryption process can be illustrated as follows. Here K, P, A,
 IV, and E denote the key, plaintext, additional authenticated data,
 initialization vector, and ciphertext, respectively.
 MAC_KEY = initial MAC_KEY_LEN octets of K,
 ENC_KEY = final ENC_KEY_LEN octets of K,
 E = CBC-PKCS5-ENC(ENC_KEY, P),
 M = MAC(MAC_KEY, A || IV || E || AL),
 T = initial T_LEN octets of M.
5.2.2.2. AES_CBC_HMAC_SHA2 Decryption
 The authenticated decryption operation has five inputs: K, A, IV, E,
 and T as defined above. It has only a single output, either a
 plaintext value P or a special symbol FAIL that indicates that the
 inputs are not authentic. The authenticated decryption algorithm is
 as follows, or uses an equivalent set of steps:
 1. The secondary keys MAC_KEY and ENC_KEY are generated from the
 input key K as in Step 1 of Section 5.2.2.1.
 2. The integrity and authenticity of A and E are checked by
 computing an HMAC with the inputs as in Step 5 of
 Section 5.2.2.1. The value T, from the previous step, is
 compared to the first MAC_KEY length bits of the HMAC output. If
 those values are identical, then A and E are considered valid,
 and processing is continued. Otherwise, all of the data used in
 the MAC validation are discarded, and the Authenticated
 Encryption decryption operation returns an indication that it
 failed, and the operation halts. (But see Section 11.5 of [JWE]
 for security considerations on thwarting timing attacks.)
 3. The value E is decrypted and the PKCS #7 padding is checked and
 removed. The value IV is used as the initialization vector. The
 value ENC_KEY is used as the decryption key.
 4. The plaintext value is returned.
5.2.3. AES_128_CBC_HMAC_SHA_256
 This algorithm is a concrete instantiation of the generic
 AES_CBC_HMAC_SHA2 algorithm above. It uses the HMAC message
 authentication code [RFC2104] with the SHA-256 hash function [SHS] to
 provide message authentication, with the HMAC output truncated to 128
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 bits, corresponding to the HMAC-SHA-256-128 algorithm defined in
 [RFC4868]. For encryption, it uses AES in the Cipher Block Chaining
 (CBC) mode of operation as defined in Section 6.2 of [NIST.800-38A],
 with PKCS #7 padding and a 128 bit initialization vector (IV) value.
 The AES_CBC_HMAC_SHA2 parameters specific to AES_128_CBC_HMAC_SHA_256
 are:
 The input key K is 32 octets long.
 ENC_KEY_LEN is 16 octets.
 MAC_KEY_LEN is 16 octets.
 The SHA-256 hash algorithm is used for the HMAC.
 The HMAC-SHA-256 output is truncated to T_LEN=16 octets, by
 stripping off the final 16 octets.
5.2.4. AES_192_CBC_HMAC_SHA_384
 AES_192_CBC_HMAC_SHA_384 is based on AES_128_CBC_HMAC_SHA_256, but
 with the following differences:
 The input key K is 48 octets long instead of 32.
 ENC_KEY_LEN is 24 octets instead of 16.
 MAC_KEY_LEN is 24 octets instead of 16.
 SHA-384 is used for the HMAC instead of SHA-256.
 The HMAC SHA-384 value is truncated to T_LEN=24 octets instead of
 16.
5.2.5. AES_256_CBC_HMAC_SHA_512
 AES_256_CBC_HMAC_SHA_512 is based on AES_128_CBC_HMAC_SHA_256, but
 with the following differences:
 The input key K is 64 octets long instead of 32.
 ENC_KEY_LEN is 32 octets instead of 16.
 MAC_KEY_LEN is 32 octets instead of 16.
 SHA-512 is used for the HMAC instead of SHA-256.
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 The HMAC SHA-512 value is truncated to T_LEN=32 octets instead of
 16.
5.2.6. Content Encryption with AES_CBC_HMAC_SHA2
 This section defines the specifics of performing authenticated
 encryption with the AES_CBC_HMAC_SHA2 algorithms.
 The CEK is used as the secret key K.
 The following "enc" (encryption algorithm) Header Parameter values
 are used to indicate that the JWE Ciphertext and JWE Authentication
 Tag values have been computed using the corresponding algorithm:
 +---------------+---------------------------------------------------+
 | enc Param | Content Encryption Algorithm |
 | Value | |
 +---------------+---------------------------------------------------+
 | A128CBC-HS256 | AES_128_CBC_HMAC_SHA_256 authenticated encryption |
 | | algorithm, as defined in Section 5.2.3 |
 | A192CBC-HS384 | AES_192_CBC_HMAC_SHA_384 authenticated encryption |
 | | algorithm, as defined in Section 5.2.4 |
 | A256CBC-HS512 | AES_256_CBC_HMAC_SHA_512 authenticated encryption |
 | | algorithm, as defined in Section 5.2.5 |
 +---------------+---------------------------------------------------+
5.3. Content Encryption with AES GCM
 This section defines the specifics of performing authenticated
 encryption with Advanced Encryption Standard (AES) in Galois/Counter
 Mode (GCM) [AES, NIST.800-38D].
 The CEK is used as the encryption key.
 Use of an initialization vector of size 96 bits is REQUIRED with this
 algorithm.
 The requested size of the Authentication Tag output MUST be 128 bits,
 regardless of the key size.
 The following "enc" (encryption algorithm) Header Parameter values
 are used to indicate that the JWE Ciphertext and JWE Authentication
 Tag values have been computed using the corresponding algorithm and
 key size:
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 +-----------------+------------------------------+
 | enc Param Value | Content Encryption Algorithm |
 +-----------------+------------------------------+
 | A128GCM | AES GCM using 128 bit key |
 | A192GCM | AES GCM using 192 bit key |
 | A256GCM | AES GCM using 256 bit key |
 +-----------------+------------------------------+
 An example using this algorithm is shown in Appendix A.1 of [JWE].
. Cryptographic Algorithms for Keys
 A JSON Web Key (JWK) [JWK] is a JSON data structure that represents a
 cryptographic key. These keys can be either asymmetric or symmetric.
 They can hold both public and private information about the key.
 This section defines the parameters for keys using the algorithms
 specified by this document.
6.1. "kty" (Key Type) Parameter Values
 The table below is the set of "kty" (key type) parameter values that
 are defined by this specification for use in JWKs.
 +-------------+------------------------------------+----------------+
 | kty Param | Key Type | Implementation |
 | Value | | Requirements |
 +-------------+------------------------------------+----------------+
 | EC | Elliptic Curve [DSS] | Recommended+ |
 | RSA | RSA [RFC3447] | Required |
 | oct | Octet sequence (used to represent | Required |
 | | symmetric keys) | |
 +-------------+------------------------------------+----------------+
 The use of "+" in the Implementation Requirements indicates that the
 requirement strength is likely to be increased in a future version of
 the specification.
6.2. Parameters for Elliptic Curve Keys
 JWKs can represent Elliptic Curve [DSS] keys. In this case, the
 "kty" member value is "EC".
6.2.1. Parameters for Elliptic Curve Public Keys
 An elliptic curve public key is represented by a pair of coordinates
 drawn from a finite field, which together define a point on an
 elliptic curve. The following members MUST be present for all
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 elliptic curve public keys:
 o "crv"
 o "x"
 The following member MUST also be present for elliptic curve public
 keys for the three curves defined in the following section:
 o "y"
6.2.1.1. "crv" (Curve) Parameter
 The "crv" (curve) member identifies the cryptographic curve used with
 the key. Curve values from [DSS] used by this specification are:
 o "P-256"
 o "P-384"
 o "P-521"
 These values are registered in the IANA JSON Web Key Elliptic Curve
 registry defined in Section 7.6. Additional "crv" values can be
 registered by other specifications. Specifications registering
 additional curves must define what parameters are used to represent
 keys for the curves registered. The "crv" value is a case-sensitive
 string.
 SEC1 [SEC1] point compression is not supported for any of these three
 curves.
6.2.1.2. "x" (X Coordinate) Parameter
 The "x" (x coordinate) member contains the x coordinate for the
 elliptic curve point. It is represented as the base64url encoding of
 the octet string representation of the coordinate, as defined in
 Section 2.3.5 of SEC1 [SEC1]. The length of this octet string MUST
 be the full size of a coordinate for the curve specified in the "crv"
 parameter. For example, if the value of "crv" is "P-521", the octet
 string must be 66 octets long.
6.2.1.3. "y" (Y Coordinate) Parameter
 The "y" (y coordinate) member contains the y coordinate for the
 elliptic curve point. It is represented as the base64url encoding of
 the octet string representation of the coordinate, as defined in
 Section 2.3.5 of SEC1 [SEC1]. The length of this octet string MUST
 be the full size of a coordinate for the curve specified in the "crv"
 parameter. For example, if the value of "crv" is "P-521", the octet
 string must be 66 octets long.
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6.2.2. Parameters for Elliptic Curve Private Keys
 In addition to the members used to represent Elliptic Curve public
 keys, the following member MUST be present to represent Elliptic
 Curve private keys.
6.2.2.1. "d" (ECC Private Key) Parameter
 The "d" (ECC private key) member contains the Elliptic Curve private
 key value. It is represented as the base64url encoding of the octet
 string representation of the private key value, as defined in Section
 2.3.7 of SEC1 [SEC1]. The length of this octet string MUST be
 ceiling(log-base-2(n)/8) octets (where n is the order of the curve).
6.3. Parameters for RSA Keys
 JWKs can represent RSA [RFC3447] keys. In this case, the "kty"
 member value is "RSA". The semantics of the parameters defined below
 are the same as those defined in Sections 3.1 and 3.2 of RFC 3447.
6.3.1. Parameters for RSA Public Keys
 The following members MUST be present for RSA public keys.
6.3.1.1. "n" (Modulus) Parameter
 The "n" (modulus) member contains the modulus value for the RSA
 public key. It is represented as a Base64urlUInt encoded value.
 Note that implementers have found that some cryptographic libraries
 prefix an extra zero-valued octet to the modulus representations they
 return, for instance, returning 257 octets for a 2048 bit key, rather
 than 256. Implementations using such libraries will need to take
 care to omit the extra octet from the base64url encoded
 representation.
6.3.1.2. "e" (Exponent) Parameter
 The "e" (exponent) member contains the exponent value for the RSA
 public key. It is represented as a Base64urlUInt encoded value.
 For instance, when representing the value 65537, the octet sequence
 to be base64url encoded MUST consist of the three octets [1, 0, 1];
 the resulting representation for this value is "AQAB".
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6.3.2. Parameters for RSA Private Keys
 In addition to the members used to represent RSA public keys, the
 following members are used to represent RSA private keys. The
 parameter "d" is REQUIRED for RSA private keys. The others enable
 optimizations and SHOULD be included by producers of JWKs
 representing RSA private keys. If the producer includes any of the
 other private key parameters, then all of the others MUST be present,
 with the exception of "oth", which MUST only be present when more
 than two prime factors were used.
6.3.2.1. "d" (Private Exponent) Parameter
 The "d" (private exponent) member contains the private exponent value
 for the RSA private key. It is represented as a Base64urlUInt
 encoded value.
6.3.2.2. "p" (First Prime Factor) Parameter
 The "p" (first prime factor) member contains the first prime factor.
 It is represented as a Base64urlUInt encoded value.
6.3.2.3. "q" (Second Prime Factor) Parameter
 The "q" (second prime factor) member contains the second prime
 factor. It is represented as a Base64urlUInt encoded value.
6.3.2.4. "dp" (First Factor CRT Exponent) Parameter
 The "dp" (first factor CRT exponent) member contains the Chinese
 Remainder Theorem (CRT) exponent of the first factor. It is
 represented as a Base64urlUInt encoded value.
6.3.2.5. "dq" (Second Factor CRT Exponent) Parameter
 The "dq" (second factor CRT exponent) member contains the Chinese
 Remainder Theorem (CRT) exponent of the second factor. It is
 represented as a Base64urlUInt encoded value.
6.3.2.6. "qi" (First CRT Coefficient) Parameter
 The "qi" (first CRT coefficient) member contains the Chinese
 Remainder Theorem (CRT) coefficient of the second factor. It is
 represented as a Base64urlUInt encoded value.
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6.3.2.7. "oth" (Other Primes Info) Parameter
 The "oth" (other primes info) member contains an array of information
 about any third and subsequent primes, should they exist. When only
 two primes have been used (the normal case), this parameter MUST be
 omitted. When three or more primes have been used, the number of
 array elements MUST be the number of primes used minus two. For more
 information on this case, see the description of the OtherPrimeInfo
 parameters in Section A.1.2 of RFC 3447 [RFC3447], upon which the
 following parameters are modelled. If the consumer of a JWK does not
 support private keys with more than two primes and it encounters a
 private key that includes the "oth" parameter, then it MUST NOT use
 the key. Each array element MUST be an object with the following
 members:
6.3.2.7.1. "r" (Prime Factor)
 The "r" (prime factor) parameter within an "oth" array member
 represents the value of a subsequent prime factor. It is represented
 as a Base64urlUInt encoded value.
6.3.2.7.2. "d" (Factor CRT Exponent)
 The "d" (Factor CRT Exponent) parameter within an "oth" array member
 represents the CRT exponent of the corresponding prime factor. It is
 represented as a Base64urlUInt encoded value.
6.3.2.7.3. "t" (Factor CRT Coefficient)
 The "t" (factor CRT coefficient) parameter within an "oth" array
 member represents the CRT coefficient of the corresponding prime
 factor. It is represented as a Base64urlUInt encoded value.
6.4. Parameters for Symmetric Keys
 When the JWK "kty" member value is "oct" (octet sequence), the member
 "k" is used to represent a symmetric key (or another key whose value
 is a single octet sequence). An "alg" member SHOULD also be present
 to identify the algorithm intended to be used with the key, unless
 the application uses another means or convention to determine the
 algorithm used.
6.4.1. "k" (Key Value) Parameter
 The "k" (key value) member contains the value of the symmetric (or
 other single-valued) key. It is represented as the base64url
 encoding of the octet sequence containing the key value.
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. IANA Considerations
 The following registration procedure is used for all the registries
 established by this specification.
 Values are registered on a Specification Required [RFC5226] basis
 after a three-week review period on the jose-reg-review@ietf.org
 mailing list, on the advice of one or more Designated Experts.
 However, to allow for the allocation of values prior to publication,
 the Designated Expert(s) may approve registration once they are
 satisfied that such a specification will be published.
 Registration requests must be sent to the jose-reg-review@ietf.org
 mailing list for review and comment, with an appropriate subject
 (e.g., "Request to register algorithm: example").
 Within the review period, the Designated Expert(s) will either
 approve or deny the registration request, communicating this decision
 to the review list and IANA. Denials should include an explanation
 and, if applicable, suggestions as to how to make the request
 successful. Registration requests that are undetermined for a period
 longer than 21 days can be brought to the IESG's attention (using the
 iesg@ietf.org mailing list) for resolution.
 Criteria that should be applied by the Designated Expert(s) includes
 determining whether the proposed registration duplicates existing
 functionality, determining whether it is likely to be of general
 applicability or whether it is useful only for a single application,
 and whether the registration description is clear.
 IANA must only accept registry updates from the Designated Expert(s)
 and should direct all requests for registration to the review mailing
 list.
 It is suggested that multiple Designated Experts be appointed who are
 able to represent the perspectives of different applications using
 this specification, in order to enable broadly-informed review of
 registration decisions. In cases where a registration decision could
 be perceived as creating a conflict of interest for a particular
 Expert, that Expert should defer to the judgment of the other
 Expert(s).
 [[ Note to the RFC Editor and IANA: Pearl Liang of ICANN had
 requested that the draft supply the following proposed registry
 description information. It is to be used for all registries
 established by this specification.
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 o Protocol Category: JSON Object Signing and Encryption (JOSE)
 o Registry Location: http://www.iana.org/assignments/jose
 o Webpage Title: (same as the protocol category)
 o Registry Name: (same as the section title, but excluding the word
 "Registry", for example "JSON Web Signature and Encryption
 Algorithms")
 ]]
7.1. JSON Web Signature and Encryption Algorithms Registry
 This specification establishes the IANA JSON Web Signature and
 Encryption Algorithms registry for values of the JWS and JWE "alg"
 (algorithm) and "enc" (encryption algorithm) Header Parameters. The
 registry records the algorithm name, the algorithm usage locations,
 implementation requirements, and a reference to the specification
 that defines it. The same algorithm name can be registered multiple
 times, provided that the sets of usage locations are disjoint.
 It is suggested that when multiple variations of algorithms are being
 registered that use keys of different lengths and the key lengths for
 each need to be fixed (for instance, because they will be created by
 key derivation functions), that the length of the key be included in
 the algorithm name. This allows readers of the JSON text to more
 easily make security decisions.
 The Designated Expert(s) should perform reasonable due diligence that
 algorithms being registered are either currently considered
 cryptographically credible or are being registered as Deprecated or
 Prohibited.
 The implementation requirements of an algorithm may be changed over
 time as the cryptographic landscape evolves, for instance, to change
 the status of an algorithm to Deprecated, or to change the status of
 an algorithm from Optional to Recommended+ or Required. Changes of
 implementation requirements are only permitted on a Specification
 Required basis after review by the Designated Experts(s), with the
 new specification defining the revised implementation requirements
 level.
7.1.1. Registration Template
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 Algorithm Name:
 The name requested (e.g., "HS256"). This name is a case-sensitive
 ASCII string. Names may not match other registered names in a
 case-insensitive manner unless the Designated Expert(s) state that
 there is a compelling reason to allow an exception in this
 particular case.
 Algorithm Description:
 Brief description of the Algorithm (e.g., "HMAC using SHA-256").
 Algorithm Usage Location(s):
 The algorithm usage location. This must be one or more of the
 values "alg" or "enc" if the algorithm is to be used with JWS or
 JWE. The value "JWK" is used if the algorithm identifier will be
 used as a JWK "alg" member value, but will not be used with JWS or
 JWE; this could be the case, for instance, for non-authenticated
 encryption algorithms. Other values may be used with the approval
 of a Designated Expert.
 JOSE Implementation Requirements:
 The algorithm implementation requirements for JWS and JWE, which
 must be one the words Required, Recommended, Optional, Deprecated,
 or Prohibited. Optionally, the word can be followed by a "+" or
 "-". The use of "+" indicates that the requirement strength is
 likely to be increased in a future version of the specification.
 The use of "-" indicates that the requirement strength is likely
 to be decreased in a future version of the specification. Any
 identifiers registered for non-authenticated encryption algorithms
 or other algorithms that are otherwise unsuitable for direct use
 as JWS or JWE algorithms must be registered as "Prohibited".
 Change Controller:
 For Standards Track RFCs, state "IESG". For others, give the name
 of the responsible party. Other details (e.g., postal address,
 email address, home page URI) may also be included.
 Specification Document(s):
 Reference to the document(s) that specify the parameter,
 preferably including URI(s) that can be used to retrieve copies of
 the document(s). An indication of the relevant sections may also
 be included but is not required.
7.1.2. Initial Registry Contents
 o Algorithm Name: "HS256"
 o Algorithm Description: HMAC using SHA-256
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 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Required
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "HS384"
 o Algorithm Description: HMAC using SHA-384
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "HS512"
 o Algorithm Description: HMAC using SHA-512
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "RS256"
 o Algorithm Description: RSASSA-PKCS-v1_5 using SHA-256
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "RS384"
 o Algorithm Description: RSASSA-PKCS-v1_5 using SHA-384
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "RS512"
 o Algorithm Description: RSASSA-PKCS-v1_5 using SHA-512
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "ES256"
 o Algorithm Description: ECDSA using P-256 and SHA-256
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended+
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
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 o Algorithm Name: "ES384"
 o Algorithm Description: ECDSA using P-384 and SHA-384
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "ES512"
 o Algorithm Description: ECDSA using P-521 and SHA-512
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "PS256"
 o Algorithm Description: RSASSA-PSS using SHA-256 and MGF1 with SHA-
 256
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "PS384"
 o Algorithm Description: RSASSA-PSS using SHA-384 and MGF1 with SHA-
 384
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "PS512"
 o Algorithm Description: RSASSA-PSS using SHA-512 and MGF1 with SHA-
 512
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "none"
 o Algorithm Description: No digital signature or MAC performed
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 3.1 of [[ this document ]]
 o Algorithm Name: "RSA1_5"
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 o Algorithm Description: RSAES-PKCS1-V1_5
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended-
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "RSA-OAEP"
 o Algorithm Description: RSAES OAEP using default parameters
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended+
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "RSA-OAEP-256"
 o Algorithm Description: RSAES OAEP using SHA-256 and MGF1 with SHA-
 256
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "A128KW"
 o Algorithm Description: AES Key Wrap using 128 bit key
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "A192KW"
 o Algorithm Description: AES Key Wrap using 192 bit key
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "A256KW"
 o Algorithm Description: AES Key Wrap using 256 bit key
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "dir"
 o Algorithm Description: Direct use of a shared symmetric key
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended
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 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "ECDH-ES"
 o Algorithm Description: ECDH-ES using Concat KDF
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended+
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "ECDH-ES+A128KW"
 o Algorithm Description: ECDH-ES using Concat KDF and "A128KW"
 wrapping
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "ECDH-ES+A192KW"
 o Algorithm Description: ECDH-ES using Concat KDF and "A192KW"
 wrapping
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "ECDH-ES+A256KW"
 o Algorithm Description: ECDH-ES using Concat KDF and "A256KW"
 wrapping
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Recommended
 o Change Controller: IESG
 o Specification Document(s): Section 4.1 of [[ this document ]]
 o Algorithm Name: "A128GCMKW"
 o Algorithm Description: Key wrapping with AES GCM using 128 bit key
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.7 of [[ this document ]]
 o Algorithm Name: "A192GCMKW"
 o Algorithm Description: Key wrapping with AES GCM using 192 bit key
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
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 o Specification Document(s): Section 4.7 of [[ this document ]]
 o Algorithm Name: "A256GCMKW"
 o Algorithm Description: Key wrapping with AES GCM using 256 bit key
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.7 of [[ this document ]]
 o Algorithm Name: "PBES2-HS256+A128KW"
 o Algorithm Description: PBES2 with HMAC SHA-256 and "A128KW"
 wrapping
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.8 of [[ this document ]]
 o Algorithm Name: "PBES2-HS384+A192KW"
 o Algorithm Description: PBES2 with HMAC SHA-384 and "A192KW"
 wrapping
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.8 of [[ this document ]]
 o Algorithm Name: "PBES2-HS512+A256KW"
 o Algorithm Description: PBES2 with HMAC SHA-512 and "A256KW"
 wrapping
 o Algorithm Usage Location(s): "alg"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 4.8 of [[ this document ]]
 o Algorithm Name: "A128CBC-HS256"
 o Algorithm Description: AES_128_CBC_HMAC_SHA_256 authenticated
 encryption algorithm
 o Algorithm Usage Location(s): "enc"
 o JOSE Implementation Requirements: Required
 o Change Controller: IESG
 o Specification Document(s): Section 5.1 of [[ this document ]]
 o Algorithm Name: "A192CBC-HS384"
 o Algorithm Description: AES_192_CBC_HMAC_SHA_384 authenticated
 encryption algorithm
 o Algorithm Usage Location(s): "enc"
 o JOSE Implementation Requirements: Optional
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 o Change Controller: IESG
 o Specification Document(s): Section 5.1 of [[ this document ]]
 o Algorithm Name: "A256CBC-HS512"
 o Algorithm Description: AES_256_CBC_HMAC_SHA_512 authenticated
 encryption algorithm
 o Algorithm Usage Location(s): "enc"
 o JOSE Implementation Requirements: Required
 o Change Controller: IESG
 o Specification Document(s): Section 5.1 of [[ this document ]]
 o Algorithm Name: "A128GCM"
 o Algorithm Description: AES GCM using 128 bit key
 o Algorithm Usage Location(s): "enc"
 o JOSE Implementation Requirements: Recommended
 o Change Controller: IESG
 o Specification Document(s): Section 5.1 of [[ this document ]]
 o Algorithm Name: "A192GCM"
 o Algorithm Description: AES GCM using 192 bit key
 o Algorithm Usage Location(s): "enc"
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 5.1 of [[ this document ]]
 o Algorithm Name: "A256GCM"
 o Algorithm Description: AES GCM using 256 bit key
 o Algorithm Usage Location(s): "enc"
 o JOSE Implementation Requirements: Recommended
 o Change Controller: IESG
 o Specification Document(s): Section 5.1 of [[ this document ]]
7.2. Header Parameter Names Registration
 This specification registers the Header Parameter names defined in
 Section 4.6.1, Section 4.7.1, and Section 4.8.1 in the IANA JSON Web
 Signature and Encryption Header Parameters registry defined in [JWS].
7.2.1. Registry Contents
 o Header Parameter Name: "epk"
 o Header Parameter Description: Ephemeral Public Key
 o Header Parameter Usage Location(s): JWE
 o Change Controller: IESG
 o Specification Document(s): Section 4.6.1.1 of [[ this document ]]
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 o Header Parameter Name: "apu"
 o Header Parameter Description: Agreement PartyUInfo
 o Header Parameter Usage Location(s): JWE
 o Change Controller: IESG
 o Specification Document(s): Section 4.6.1.2 of [[ this document ]]
 o Header Parameter Name: "apv"
 o Header Parameter Description: Agreement PartyVInfo
 o Header Parameter Usage Location(s): JWE
 o Change Controller: IESG
 o Specification Document(s): Section 4.6.1.3 of [[ this document ]]
 o Header Parameter Name: "iv"
 o Header Parameter Description: Initialization Vector
 o Header Parameter Usage Location(s): JWE
 o Change Controller: IESG
 o Specification Document(s): Section 4.7.1.1 of [[ this document ]]
 o Header Parameter Name: "tag"
 o Header Parameter Description: Authentication Tag
 o Header Parameter Usage Location(s): JWE
 o Change Controller: IESG
 o Specification Document(s): Section 4.7.1.2 of [[ this document ]]
 o Header Parameter Name: "p2s"
 o Header Parameter Description: PBES2 salt
 o Header Parameter Usage Location(s): JWE
 o Change Controller: IESG
 o Specification Document(s): Section 4.8.1.1 of [[ this document ]]
 o Header Parameter Name: "p2c"
 o Header Parameter Description: PBES2 count
 o Header Parameter Usage Location(s): JWE
 o Change Controller: IESG
 o Specification Document(s): Section 4.8.1.2 of [[ this document ]]
7.3. JSON Web Encryption Compression Algorithms Registry
 This specification establishes the IANA JSON Web Encryption
 Compression Algorithms registry for JWE "zip" member values. The
 registry records the compression algorithm value and a reference to
 the specification that defines it.
7.3.1. Registration Template
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 Compression Algorithm Value:
 The name requested (e.g., "DEF"). Because a core goal of this
 specification is for the resulting representations to be compact,
 it is RECOMMENDED that the name be short -- not to exceed 8
 characters without a compelling reason to do so. This name is
 case-sensitive. Names may not match other registered names in a
 case-insensitive manner unless the Designated Expert(s) state that
 there is a compelling reason to allow an exception in this
 particular case.
 Compression Algorithm Description:
 Brief description of the compression algorithm (e.g., "DEFLATE").
 Change Controller:
 For Standards Track RFCs, state "IESG". For others, give the name
 of the responsible party. Other details (e.g., postal address,
 email address, home page URI) may also be included.
 Specification Document(s):
 Reference to the document(s) that specify the parameter,
 preferably including URI(s) that can be used to retrieve copies of
 the document(s). An indication of the relevant sections may also
 be included but is not required.
7.3.2. Initial Registry Contents
 o Compression Algorithm Value: "DEF"
 o Compression Algorithm Description: DEFLATE
 o Change Controller: IESG
 o Specification Document(s): JSON Web Encryption (JWE) [JWE]
7.4. JSON Web Key Types Registry
 This specification establishes the IANA JSON Web Key Types registry
 for values of the JWK "kty" (key type) parameter. The registry
 records the "kty" value, implementation requirements, and a reference
 to the specification that defines it.
 The implementation requirements of a key type may be changed over
 time as the cryptographic landscape evolves, for instance, to change
 the status of a key type to Deprecated, or to change the status of a
 key type from Optional to Recommended+ or Required. Changes of
 implementation requirements are only permitted on a Specification
 Required basis after review by the Designated Experts(s), with the
 new specification defining the revised implementation requirements
 level.
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7.4.1. Registration Template
 "kty" Parameter Value:
 The name requested (e.g., "EC"). Because a core goal of this
 specification is for the resulting representations to be compact,
 it is RECOMMENDED that the name be short -- not to exceed 8
 characters without a compelling reason to do so. This name is
 case-sensitive. Names may not match other registered names in a
 case-insensitive manner unless the Designated Expert(s) state that
 there is a compelling reason to allow an exception in this
 particular case.
 Key Type Description:
 Brief description of the Key Type (e.g., "Elliptic Curve").
 Change Controller:
 For Standards Track RFCs, state "IESG". For others, give the name
 of the responsible party. Other details (e.g., postal address,
 email address, home page URI) may also be included.
 JOSE Implementation Requirements:
 The key type implementation requirements for JWS and JWE, which
 must be one the words Required, Recommended, Optional, Deprecated,
 or Prohibited. Optionally, the word can be followed by a "+" or
 "-". The use of "+" indicates that the requirement strength is
 likely to be increased in a future version of the specification.
 The use of "-" indicates that the requirement strength is likely
 to be decreased in a future version of the specification.
 Specification Document(s):
 Reference to the document(s) that specify the parameter,
 preferably including URI(s) that can be used to retrieve copies of
 the document(s). An indication of the relevant sections may also
 be included but is not required.
7.4.2. Initial Registry Contents
 This specification registers the values defined in Section 6.1.
 o "kty" Parameter Value: "EC"
 o Key Type Description: Elliptic Curve
 o JOSE Implementation Requirements: Recommended+
 o Change Controller: IESG
 o Specification Document(s): Section 6.2 of [[ this document ]]
 o "kty" Parameter Value: "RSA"
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 o Key Type Description: RSA
 o JOSE Implementation Requirements: Required
 o Change Controller: IESG
 o Specification Document(s): Section 6.3 of [[ this document ]]
 o "kty" Parameter Value: "oct"
 o Key Type Description: Octet sequence
 o JOSE Implementation Requirements: Required
 o Change Controller: IESG
 o Specification Document(s): Section 6.4 of [[ this document ]]
7.5. JSON Web Key Parameters Registration
 This specification registers the parameter names defined in Sections
 6.2, 6.3, and 6.4 in the IANA JSON Web Key Parameters registry
 defined in [JWK].
7.5.1. Registry Contents
 o Parameter Name: "crv"
 o Parameter Description: Curve
 o Used with "kty" Value(s): "EC"
 o Parameter Information Class: Public
 o Change Controller: IESG
 o Specification Document(s): Section 6.2.1.1 of [[ this document ]]
 o Parameter Name: "x"
 o Parameter Description: X Coordinate
 o Used with "kty" Value(s): "EC"
 o Parameter Information Class: Public
 o Change Controller: IESG
 o Specification Document(s): Section 6.2.1.2 of [[ this document ]]
 o Parameter Name: "y"
 o Parameter Description: Y Coordinate
 o Used with "kty" Value(s): "EC"
 o Parameter Information Class: Public
 o Change Controller: IESG
 o Specification Document(s): Section 6.2.1.3 of [[ this document ]]
 o Parameter Name: "d"
 o Parameter Description: ECC Private Key
 o Used with "kty" Value(s): "EC"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.2.2.1 of [[ this document ]]
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 o Parameter Name: "n"
 o Parameter Description: Modulus
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Public
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.1.1 of [[ this document ]]
 o Parameter Name: "e"
 o Parameter Description: Exponent
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Public
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.1.2 of [[ this document ]]
 o Parameter Name: "d"
 o Parameter Description: Private Exponent
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.2.1 of [[ this document ]]
 o Parameter Name: "p"
 o Parameter Description: First Prime Factor
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.2.2 of [[ this document ]]
 o Parameter Name: "q"
 o Parameter Description: Second Prime Factor
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.2.3 of [[ this document ]]
 o Parameter Name: "dp"
 o Parameter Description: First Factor CRT Exponent
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.2.4 of [[ this document ]]
 o Parameter Name: "dq"
 o Parameter Description: Second Factor CRT Exponent
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Private
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 o Change Controller: IESG
 o Specification Document(s): Section 6.3.2.5 of [[ this document ]]
 o Parameter Name: "qi"
 o Parameter Description: First CRT Coefficient
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.2.6 of [[ this document ]]
 o Parameter Name: "oth"
 o Parameter Description: Other Primes Info
 o Used with "kty" Value(s): "RSA"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.3.2.7 of [[ this document ]]
 o Parameter Name: "k"
 o Parameter Description: Key Value
 o Used with "kty" Value(s): "oct"
 o Parameter Information Class: Private
 o Change Controller: IESG
 o Specification Document(s): Section 6.4.1 of [[ this document ]]
7.6. JSON Web Key Elliptic Curve Registry
 This specification establishes the IANA JSON Web Key Elliptic Curve
 registry for JWK "crv" member values. The registry records the curve
 name, implementation requirements, and a reference to the
 specification that defines it. This specification registers the
 parameter names defined in Section 6.2.1.1.
 The implementation requirements of a curve may be changed over time
 as the cryptographic landscape evolves, for instance, to change the
 status of a curve to Deprecated, or to change the status of a curve
 from Optional to Recommended+ or Required. Changes of implementation
 requirements are only permitted on a Specification Required basis
 after review by the Designated Experts(s), with the new specification
 defining the revised implementation requirements level.
7.6.1. Registration Template
 Curve Name:
 The name requested (e.g., "P-256"). Because a core goal of this
 specification is for the resulting representations to be compact,
 it is RECOMMENDED that the name be short -- not to exceed 8
 characters without a compelling reason to do so. This name is
 case-sensitive. Names may not match other registered names in a
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 case-insensitive manner unless the Designated Expert(s) state that
 there is a compelling reason to allow an exception in this
 particular case.
 Curve Description:
 Brief description of the curve (e.g., "P-256 curve").
 JOSE Implementation Requirements:
 The curve implementation requirements for JWS and JWE, which must
 be one the words Required, Recommended, Optional, Deprecated, or
 Prohibited. Optionally, the word can be followed by a "+" or "-".
 The use of "+" indicates that the requirement strength is likely
 to be increased in a future version of the specification. The use
 of "-" indicates that the requirement strength is likely to be
 decreased in a future version of the specification.
 Change Controller:
 For Standards Track RFCs, state "IESG". For others, give the name
 of the responsible party. Other details (e.g., postal address,
 email address, home page URI) may also be included.
 Specification Document(s):
 Reference to the document(s) that specify the parameter,
 preferably including URI(s) that can be used to retrieve copies of
 the document(s). An indication of the relevant sections may also
 be included but is not required.
7.6.2. Initial Registry Contents
 o Curve Name: "P-256"
 o Curve Description: P-256 curve
 o JOSE Implementation Requirements: Recommended+
 o Change Controller: IESG
 o Specification Document(s): Section 6.2.1.1 of [[ this document ]]
 o Curve Name: "P-384"
 o Curve Description: P-384 curve
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 6.2.1.1 of [[ this document ]]
 o Curve Name: "P-521"
 o Curve Description: P-521 curve
 o JOSE Implementation Requirements: Optional
 o Change Controller: IESG
 o Specification Document(s): Section 6.2.1.1 of [[ this document ]]
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. Security Considerations
 All of the security issues that are pertinent to any cryptographic
 application must be addressed by JWS/JWE/JWK agents. Among these
 issues are protecting the user's asymmetric private and symmetric
 secret keys and employing countermeasures to various attacks.
 The security considerations in [AES], [DSS], [JWE], [JWK], [JWS],
 [NIST.800-38D], [NIST.800-56A], [NIST.800-107], [RFC2104], [RFC3394],
 [RFC3447], [RFC5116], [RFC6090], and [SHS] apply to this
 specification.
8.1. Cryptographic Agility
 Implementers should be aware that cryptographic algorithms become
 weaker with time. As new cryptanalysis techniques are developed and
 computing performance improves, the work factor to break a particular
 cryptographic algorithm will be reduced. Therefore, implementers and
 deployments must be prepared for the set of algorithms that are
 supported and used to change over time. Thus, cryptographic
 algorithm implementations should be modular, allowing new algorithms
 to be readily inserted.
8.2. Key Lifetimes
 Many algorithms have associated security considerations related to
 key lifetimes and/or the number of times that a key may be used.
 Those security considerations continue to apply when using those
 algorithms with JOSE data structures. See NIST SP 800-57
 [NIST.800-57] for specific guidance on key lifetimes.
8.3. RSAES-PKCS1-v1_5 Security Considerations
 While Section 8 of RFC 3447 [RFC3447] explicitly calls for people not
 to adopt RSASSA-PKCS-v1_5 for new applications and instead requests
 that people transition to RSASSA-PSS, this specification does include
 RSASSA-PKCS-v1_5, for interoperability reasons, because it is
 commonly implemented.
 Keys used with RSAES-PKCS1-v1_5 must follow the constraints in
 Section 7.2 of RFC 3447. Also, keys with a low public key exponent
 value, as described in Section 3 of Twenty years of attacks on the
 RSA cryptosystem [Boneh99], must not be used.
8.4. AES GCM Security Considerations
 Keys used with AES GCM must follow the constraints in Section 8.3 of
 [NIST.800-38D], which states: "The total number of invocations of the
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 authenticated encryption function shall not exceed 2^32, including
 all IV lengths and all instances of the authenticated encryption
 function with the given key". In accordance with this rule, AES GCM
 MUST NOT be used with the same key value more than 2^32 times.
 An Initialization Vector value MUST NOT ever be used multiple times
 with the same AES GCM key. One way to prevent this is to store a
 counter with the key and increment it with every use. The counter
 can also be used to prevent exceeding the 2^32 limit above.
 This security consideration does not apply to the composite AES-CBC
 HMAC SHA-2 or AES Key Wrap algorithms.
8.5. Unsecured JWS Security Considerations
 Unsecured JWSs (JWSs that use the "alg" value "none") provide no
 integrity protection. Thus, they must only be used in contexts in
 which the payload is secured by means other than a digital signature
 or MAC value, or need not be secured.
 An example means of preventing accepting Unsecured JWSs by default is
 for the "verify" method of a hypothetical JWS software library to
 have a Boolean "acceptUnsecured" parameter that indicates "none" is
 an acceptable "alg" value. As another example, the "verify" method
 might take a list of algorithms that are acceptable to the
 application as a parameter and would reject Unsecured JWS values if
 "none" is not in that list.
 The following example illustrates the reasons for not accepting
 Unsecured JWSs at a global level. Suppose an application accepts
 JWSs over two channels, (1) HTTP and (2) HTTPS with client
 authentication. It requires a JWS signature on objects received over
 HTTP, but accepts Unsecured JWSs over HTTPS. If the application were
 to globally indicate that "none" is acceptable, then an attacker
 could provide it with an Unsecured JWS over HTTP and still have that
 object successfully validate. Instead, the application needs to
 indicate acceptance of "none" for each object received over HTTPS
 (e.g., by setting "acceptUnsecured" to "true" for the first
 hypothetical JWS software library above), but not for each object
 received over HTTP.
8.6. Denial of Service Attacks
 Receiving agents that validate signatures and sending agents that
 encrypt messages need to be cautious of cryptographic processing
 usage when validating signatures and encrypting messages using keys
 larger than those mandated in this specification. An attacker could
 supply content using keys that would result in excessive
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 cryptographic processing, for example, keys larger than those
 mandated in this specification. Implementations should set and
 enforce upper limits on the key sizes they accept. Section 5.6.1
 (Comparable Algorithm Strengths) of NIST SP 800-57 [NIST.800-57]
 contains statements on largest approved key sizes that may be
 applicable.
8.7. Reusing Key Material when Encrypting Keys
 It is NOT RECOMMENDED to reuse the same entire set of key material
 (Key Encryption Key, Content Encryption Key, Initialization Vector,
 etc.) to encrypt multiple JWK or JWK Set objects, or to encrypt the
 same JWK or JWK Set object multiple times. One suggestion for
 preventing re-use is to always generate at least one new piece of key
 material for each encryption operation (e.g., a new Content
 Encryption Key, a new Initialization Vector, and/or a new PBES2
 Salt), based on the considerations noted in this document as well as
 from RFC 4086 [RFC4086].
8.8. Password Considerations
 Passwords are vulnerable to a number of attacks. To help mitigate
 some of these limitations, this document applies principles from RFC
 2898 [RFC2898] to derive cryptographic keys from user-supplied
 passwords.
 However, the strength of the password still has a significant impact.
 A high-entropy password has greater resistance to dictionary attacks.
 [NIST.800-63-1] contains guidelines for estimating password entropy,
 which can help applications and users generate stronger passwords.
 An ideal password is one that is as large as (or larger than) the
 derived key length. However, passwords larger than a certain
 algorithm-specific size are first hashed, which reduces an attacker's
 effective search space to the length of the hash algorithm. It is
 RECOMMENDED that a password used for "PBES2-HS256+A128KW" be no
 shorter than 16 octets and no longer than 128 octets and a password
 used for "PBES2-HS512+A256KW" be no shorter than 32 octets and no
 longer than 128 octets long.
 Still, care needs to be taken in where and how password-based
 encryption is used. These algorithms can still be susceptible to
 dictionary-based attacks if the iteration count is too small; this is
 of particular concern if these algorithms are used to protect data
 that an attacker can have indefinite number of attempts to circumvent
 the protection, such as protected data stored on a file system.
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8.9. Key Entropy and Random Values
 See Section 10.1 of [JWS] for security considerations on key entropy
 and random values.
8.10. Differences between Digital Signatures and MACs
 See Section 10.5 of [JWS] for security considerations on differences
 between digital signatures and MACs.
8.11. Using Matching Algorithm Strengths
 See Section 11.3 of [JWE] for security considerations on using
 matching algorithm strengths.
8.12. Adaptive Chosen-Ciphertext Attacks
 See Section 11.4 of [JWE] for security considerations on adaptive
 chosen-ciphertext attacks.
8.13. Timing Attacks
 See Section 10.9 of [JWS] and Section 11.5 of [JWE] for security
 considerations on timing attacks.
8.14. RSA Private Key Representations and Blinding
 See Section 9.3 of [JWK] for security considerations on RSA private
 key representations and blinding.
. Internationalization Considerations
 Passwords obtained from users are likely to require preparation and
 normalization to account for differences of octet sequences generated
 by different input devices, locales, etc. It is RECOMMENDED that
 applications to perform the steps outlined in
 [I-D.ietf-precis-saslprepbis] to prepare a password supplied directly
 by a user before performing key derivation and encryption.
. References
10.1. Normative References
 [AES] National Institute of Standards and Technology (NIST),
 "Advanced Encryption Standard (AES)", FIPS PUB 197,
 November 2001.
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 [Boneh99] "Twenty years of attacks on the RSA cryptosystem", Notices
 of the American Mathematical Society (AMS), Vol. 46, No.
 2, pp. 203-213 http://crypto.stanford.edu/~dabo/pubs/
 papers/RSA-survey.pdf, 1999.
 [DSS] National Institute of Standards and Technology, "Digital
 Signature Standard (DSS)", FIPS PUB 186-4, July 2013.
 [JWE] Jones, M. and J. Hildebrand, "JSON Web Encryption (JWE)",
 draft-ietf-jose-json-web-encryption (work in progress),
 December 2014.
 [JWK] Jones, M., "JSON Web Key (JWK)",
 draft-ietf-jose-json-web-key (work in progress),
 December 2014.
 [JWS] Jones, M., Bradley, J., and N. Sakimura, "JSON Web
 Signature (JWS)", draft-ietf-jose-json-web-signature (work
 in progress), December 2014.
 [NIST.800-38A]
 National Institute of Standards and Technology (NIST),
 "Recommendation for Block Cipher Modes of Operation",
 NIST PUB 800-38A, December 2001.
 [NIST.800-38D]
 National Institute of Standards and Technology (NIST),
 "Recommendation for Block Cipher Modes of Operation:
 Galois/Counter Mode (GCM) and GMAC", NIST PUB 800-38D,
 December 2001.
 [NIST.800-56A]
 National Institute of Standards and Technology (NIST),
 "Recommendation for Pair-Wise Key Establishment Schemes
 Using Discrete Logarithm Cryptography", NIST Special
 Publication 800-56A, Revision 2, May 2013.
 [NIST.800-57]
 National Institute of Standards and Technology (NIST),
 "Recommendation for Key Management - Part 1: General
 (Revision 3)", NIST Special Publication 800-57, Part 1,
 Revision 3, July 2012.
 [RFC20] Cerf, V., "ASCII format for Network Interchange", RFC 20,
 October 1969.
 [RFC2104] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed-
 Hashing for Message Authentication", RFC 2104,
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 February 1997.
 [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
 Requirement Levels", BCP 14, RFC 2119, March 1997.
 [RFC2898] Kaliski, B., "PKCS #5: Password-Based Cryptography
 Specification Version 2.0", RFC 2898, September 2000.
 [RFC3394] Schaad, J. and R. Housley, "Advanced Encryption Standard
 (AES) Key Wrap Algorithm", RFC 3394, September 2002.
 [RFC3447] Jonsson, J. and B. Kaliski, "Public-Key Cryptography
 Standards (PKCS) #1: RSA Cryptography Specifications
 Version 2.1", RFC 3447, February 2003.
 [RFC3629] Yergeau, F., "UTF-8, a transformation format of ISO
 10646", STD 63, RFC 3629, November 2003.
 [RFC4868] Kelly, S. and S. Frankel, "Using HMAC-SHA-256, HMAC-SHA-
 384, and HMAC-SHA-512 with IPsec", RFC 4868, May 2007.
 [RFC4949] Shirey, R., "Internet Security Glossary, Version 2",
 RFC 4949, August 2007.
 [RFC5652] Housley, R., "Cryptographic Message Syntax (CMS)", STD 70,
 RFC 5652, September 2009.
 [RFC6090] McGrew, D., Igoe, K., and M. Salter, "Fundamental Elliptic
 Curve Cryptography Algorithms", RFC 6090, February 2011.
 [RFC7159] Bray, T., "The JavaScript Object Notation (JSON) Data
 Interchange Format", RFC 7159, March 2014.
 [SEC1] Standards for Efficient Cryptography Group, "SEC 1:
 Elliptic Curve Cryptography", Version 2.0, May 2009.
 [SHS] National Institute of Standards and Technology, "Secure
 Hash Standard (SHS)", FIPS PUB 180-4, March 2012.
10.2. Informative References
 [CanvasApp]
 Facebook, "Canvas Applications", 2010.
 [I-D.ietf-precis-saslprepbis]
 Saint-Andre, P. and A. Melnikov, "Preparation,
 Enforcement, and Comparison of Internationalized Strings
 Representing Usernames and Passwords",
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 draft-ietf-precis-saslprepbis-12 (work in progress),
 December 2014.
 [I-D.mcgrew-aead-aes-cbc-hmac-sha2]
 McGrew, D., Foley, J., and K. Paterson, "Authenticated
 Encryption with AES-CBC and HMAC-SHA",
 draft-mcgrew-aead-aes-cbc-hmac-sha2-05 (work in progress),
 July 2014.
 [I-D.miller-jose-jwe-protected-jwk]
 Miller, M., "Using JavaScript Object Notation (JSON) Web
 Encryption (JWE) for Protecting JSON Web Key (JWK)
 Objects", draft-miller-jose-jwe-protected-jwk-02 (work in
 progress), June 2013.
 [I-D.rescorla-jsms]
 Rescorla, E. and J. Hildebrand, "JavaScript Message
 Security Format", draft-rescorla-jsms-00 (work in
 progress), March 2011.
 [JCA] Oracle, "Java Cryptography Architecture (JCA) Reference
 Guide", 2014.
 [JSE] Bradley, J. and N. Sakimura (editor), "JSON Simple
 Encryption", September 2010.
 [JSS] Bradley, J. and N. Sakimura (editor), "JSON Simple Sign",
 September 2010.
 [MagicSignatures]
 Panzer (editor), J., Laurie, B., and D. Balfanz, "Magic
 Signatures", January 2011.
 [NIST.800-107]
 National Institute of Standards and Technology (NIST),
 "Recommendation for Applications Using Approved Hash
 Algorithms", NIST Special Publication 800-107, Revision 1,
 August 2012.
 [NIST.800-63-1]
 National Institute of Standards and Technology (NIST),
 "Electronic Authentication Guideline", NIST Special
 Publication 800-63-1, December 2011.
 [RFC2631] Rescorla, E., "Diffie-Hellman Key Agreement Method",
 RFC 2631, June 1999.
 [RFC3275] Eastlake, D., Reagle, J., and D. Solo, "(Extensible Markup
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 Language) XML-Signature Syntax and Processing", RFC 3275,
 March 2002.
 [RFC4086] Eastlake, D., Schiller, J., and S. Crocker, "Randomness
 Requirements for Security", BCP 106, RFC 4086, June 2005.
 [RFC5116] McGrew, D., "An Interface and Algorithms for Authenticated
 Encryption", RFC 5116, January 2008.
 [RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
 IANA Considerations Section in RFCs", BCP 26, RFC 5226,
 May 2008.
 [W3C.NOTE-xmldsig-core2-20130411]
 Eastlake, D., Reagle, J., Solo, D., Hirsch, F., Roessler,
 T., Yiu, K., Datta, P., and S. Cantor, "XML Signature
 Syntax and Processing Version 2.0", World Wide Web
 Consortium Note NOTE-xmldsig-core2-20130411, April 2013,
 <http://www.w3.org/TR/2013/NOTE-xmldsig-core2-20130411/>.
 [W3C.REC-xmlenc-core-20021210]
 Eastlake, D. and J. Reagle, "XML Encryption Syntax and
 Processing", World Wide Web Consortium Recommendation REC-
 xmlenc-core-20021210, December 2002,
 <http://www.w3.org/TR/2002/REC-xmlenc-core-20021210>.
 [W3C.REC-xmlenc-core1-20130411]
 Eastlake, D., Reagle, J., Hirsch, F., and T. Roessler,
 "XML Encryption Syntax and Processing Version 1.1", World
 Wide Web Consortium Recommendation REC-xmlenc-core1-
 20130411, April 2013,
 <http://www.w3.org/TR/2013/REC-xmlenc-core1-20130411/>.
Appendix A. Algorithm Identifier Cross-Reference
 This appendix contains tables cross-referencing the cryptographic
 algorithm identifier values defined in this specification with the
 equivalent identifiers used by other standards and software packages.
 See XML DSIG [RFC3275], XML DSIG 2.0
 [W3C.NOTE-xmldsig-core2-20130411], XML Encryption
 [W3C.REC-xmlenc-core-20021210], XML Encryption 1.1
 [W3C.REC-xmlenc-core1-20130411], and Java Cryptography Architecture
 [JCA] for more information about the names defined by those
 documents.
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A.1. Digital Signature/MAC Algorithm Identifier Cross-Reference
 This section contains a table cross-referencing the JWS digital
 signature and MAC "alg" (algorithm) values defined in this
 specification with the equivalent identifiers used by other standards
 and software packages.
 +-------+------------------------------+-------------+--------------+
 | JWS | XML DSIG | JCA | OID |
 +-------+------------------------------+-------------+--------------+
 | HS256 | http://www.w3.org/2001/04/xm | HmacSHA256 | 1.2.840.1135 |
 | | ldsig-more#hmac-sha256 | | 49.2.9 |
 | HS384 | http://www.w3.org/2001/04/xm | HmacSHA384 | 1.2.840.1135 |
 | | ldsig-more#hmac-sha384 | | 49.2.10 |
 | HS512 | http://www.w3.org/2001/04/xm | HmacSHA512 | 1.2.840.1135 |
 | | ldsig-more#hmac-sha512 | | 49.2.11 |
 | RS256 | http://www.w3.org/2001/04/xm | SHA256withR | 1.2.840.1135 |
 | | ldsig-more#rsa-sha256 | SA | 49.1.1.11 |
 | RS384 | http://www.w3.org/2001/04/xm | SHA384withR | 1.2.840.1135 |
 | | ldsig-more#rsa-sha384 | SA | 49.1.1.12 |
 | RS512 | http://www.w3.org/2001/04/xm | SHA512withR | 1.2.840.1135 |
 | | ldsig-more#rsa-sha512 | SA | 49.1.1.13 |
 | ES256 | http://www.w3.org/2001/04/xm | SHA256withE | 1.2.840.1004 |
 | | ldsig-more#ecdsa-sha256 | CDSA | 5.4.3.2 |
 | ES384 | http://www.w3.org/2001/04/xm | SHA384withE | 1.2.840.1004 |
 | | ldsig-more#ecdsa-sha384 | CDSA | 5.4.3.3 |
 | ES512 | http://www.w3.org/2001/04/xm | SHA512withE | 1.2.840.1004 |
 | | ldsig-more#ecdsa-sha512 | CDSA | 5.4.3.4 |
 | PS256 | http://www.w3.org/2007/05/xm | SHA256withR | 1.2.840.1135 |
 | | ldsig-more#sha256-rsa-MGF1 | SAandMGF1 | 49.1.1.10 |
 | PS384 | http://www.w3.org/2007/05/xm | SHA384withR | 1.2.840.1135 |
 | | ldsig-more#sha384-rsa-MGF1 | SAandMGF1 | 49.1.1.10 |
 | PS512 | http://www.w3.org/2007/05/xm | SHA512withR | 1.2.840.1135 |
 | | ldsig-more#sha512-rsa-MGF1 | SAandMGF1 | 49.1.1.10 |
 +-------+------------------------------+-------------+--------------+
A.2. Key Management Algorithm Identifier Cross-Reference
 This section contains a table cross-referencing the JWE "alg"
 (algorithm) values defined in this specification with the equivalent
 identifiers used by other standards and software packages.
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 +----------+----------------------+-------------------+-------------+
 | JWE | XML ENC | JCA | OID |
 +----------+----------------------+-------------------+-------------+
 | RSA1_5 | http://www.w3.org/20 | RSA/ECB/PKCS1Padd | 1.2.840.113 |
 | | 01/04/xmlenc#rsa-1_5 | ing | 549.1.1.1 |
 | RSA-OAEP | http://www.w3.org/20 | RSA/ECB/OAEPWithS | 1.2.840.113 |
 | | 01/04/xmlenc#rsa-oae | HA-1AndMGF1Paddin | 549.1.1.7 |
 | | p-mgf1p | g | |
 | RSA-OAEP | http://www.w3.org/20 | RSA/ECB/OAEPWithS | 1.2.840.113 |
 | -256 | 09/xmlenc11#rsa-oaep | HA-256AndMGF1Padd | 549.1.1.7 |
 | | & | ing & | |
 | | http://www.w3.org/2 | MGF1ParameterSp | |
 | | 009/xmlenc11#mgf1sha | ec.SHA256 | |
 | | 256 | | |
 | ECDH-ES | http://www.w3.org/20 | ECDH | 1.3.132.1.1 |
 | | 09/xmlenc11#ECDH-ES | | 2 |
 | A128KW | http://www.w3.org/20 | AESWrap | 2.16.840.1. |
 | | 01/04/xmlenc#kw-aes1 | | 101.3.4.1.5 |
 | | 28 | | |
 | A192KW | http://www.w3.org/20 | AESWrap | 2.16.840.1. |
 | | 01/04/xmlenc#kw-aes1 | | 101.3.4.1.2 |
 | | 92 | | 5 |
 | A256KW | http://www.w3.org/20 | AESWrap | 2.16.840.1. |
 | | 01/04/xmlenc#kw-aes2 | | 101.3.4.1.4 |
 | | 56 | | 5 |
 +----------+----------------------+-------------------+-------------+
A.3. Content Encryption Algorithm Identifier Cross-Reference
 This section contains a table cross-referencing the JWE "enc"
 (encryption algorithm) values defined in this specification with the
 equivalent identifiers used by other standards and software packages.
 For the composite algorithms "A128CBC-HS256", "A192CBC-HS384", and
 "A256CBC-HS512", the corresponding AES CBC algorithm identifiers are
 listed.
 +----------+-------------------------+--------------+---------------+
 | JWE | XML ENC | JCA | OID |
 +----------+-------------------------+--------------+---------------+
 | A128CBC- | http://www.w3.org/2001/ | AES/CBC/PKCS | 2.16.840.1.10 |
 | HS256 | 04/xmlenc#aes128-cbc | 5Padding | 1.3.4.1.2 |
 | A192CBC- | http://www.w3.org/2001/ | AES/CBC/PKCS | 2.16.840.1.10 |
 | HS384 | 04/xmlenc#aes192-cbc | 5Padding | 1.3.4.1.22 |
 | A256CBC- | http://www.w3.org/2001/ | AES/CBC/PKCS | 2.16.840.1.10 |
 | HS512 | 04/xmlenc#aes256-cbc | 5Padding | 1.3.4.1.42 |
 | A128GCM | http://www.w3.org/2009/ | AES/GCM/NoPa | 2.16.840.1.10 |
 | | xmlenc11#aes128-gcm | dding | 1.3.4.1.6 |
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 | A192GCM | http://www.w3.org/2009/ | AES/GCM/NoPa | 2.16.840.1.10 |
 | | xmlenc11#aes192-gcm | dding | 1.3.4.1.26 |
 | A256GCM | http://www.w3.org/2009/ | AES/GCM/NoPa | 2.16.840.1.10 |
 | | xmlenc11#aes256-gcm | dding | 1.3.4.1.46 |
 +----------+-------------------------+--------------+---------------+
Appendix B. Test Cases for AES_CBC_HMAC_SHA2 Algorithms
 The following test cases can be used to validate implementations of
 the AES_CBC_HMAC_SHA2 algorithms defined in Section 5.2. They are
 also intended to correspond to test cases that may appear in a future
 version of [I-D.mcgrew-aead-aes-cbc-hmac-sha2], demonstrating that
 the cryptographic computations performed are the same.
 The variable names are those defined in Section 5.2. All values are
 hexadecimal.
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B.1. Test Cases for AES_128_CBC_HMAC_SHA_256
 AES_128_CBC_HMAC_SHA_256
 K = 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
 10 11 12 13 14 15 16 17 18 19 1a 1b 1c 1d 1e 1f
 MAC_KEY = 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
 ENC_KEY = 10 11 12 13 14 15 16 17 18 19 1a 1b 1c 1d 1e 1f
 P = 41 20 63 69 70 68 65 72 20 73 79 73 74 65 6d 20
 6d 75 73 74 20 6e 6f 74 20 62 65 20 72 65 71 75
 69 72 65 64 20 74 6f 20 62 65 20 73 65 63 72 65
 74 2c 20 61 6e 64 20 69 74 20 6d 75 73 74 20 62
 65 20 61 62 6c 65 20 74 6f 20 66 61 6c 6c 20 69
 6e 74 6f 20 74 68 65 20 68 61 6e 64 73 20 6f 66
 20 74 68 65 20 65 6e 65 6d 79 20 77 69 74 68 6f
 75 74 20 69 6e 63 6f 6e 76 65 6e 69 65 6e 63 65
 IV = 1a f3 8c 2d c2 b9 6f fd d8 66 94 09 23 41 bc 04
 A = 54 68 65 20 73 65 63 6f 6e 64 20 70 72 69 6e 63
 69 70 6c 65 20 6f 66 20 41 75 67 75 73 74 65 20
 4b 65 72 63 6b 68 6f 66 66 73
 AL = 00 00 00 00 00 00 01 50
 E = c8 0e df a3 2d df 39 d5 ef 00 c0 b4 68 83 42 79
 a2 e4 6a 1b 80 49 f7 92 f7 6b fe 54 b9 03 a9 c9
 a9 4a c9 b4 7a d2 65 5c 5f 10 f9 ae f7 14 27 e2
 fc 6f 9b 3f 39 9a 22 14 89 f1 63 62 c7 03 23 36
 09 d4 5a c6 98 64 e3 32 1c f8 29 35 ac 40 96 c8
 6e 13 33 14 c5 40 19 e8 ca 79 80 df a4 b9 cf 1b
 38 4c 48 6f 3a 54 c5 10 78 15 8e e5 d7 9d e5 9f
 bd 34 d8 48 b3 d6 95 50 a6 76 46 34 44 27 ad e5
 4b 88 51 ff b5 98 f7 f8 00 74 b9 47 3c 82 e2 db
 M = 65 2c 3f a3 6b 0a 7c 5b 32 19 fa b3 a3 0b c1 c4
 e6 e5 45 82 47 65 15 f0 ad 9f 75 a2 b7 1c 73 ef
 T = 65 2c 3f a3 6b 0a 7c 5b 32 19 fa b3 a3 0b c1 c4
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B.2. Test Cases for AES_192_CBC_HMAC_SHA_384
 K = 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
 10 11 12 13 14 15 16 17 18 19 1a 1b 1c 1d 1e 1f
 20 21 22 23 24 25 26 27 28 29 2a 2b 2c 2d 2e 2f
 MAC_KEY = 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
 10 11 12 13 14 15 16 17
 ENC_KEY = 18 19 1a 1b 1c 1d 1e 1f 20 21 22 23 24 25 26 27
 28 29 2a 2b 2c 2d 2e 2f
 P = 41 20 63 69 70 68 65 72 20 73 79 73 74 65 6d 20
 6d 75 73 74 20 6e 6f 74 20 62 65 20 72 65 71 75
 69 72 65 64 20 74 6f 20 62 65 20 73 65 63 72 65
 74 2c 20 61 6e 64 20 69 74 20 6d 75 73 74 20 62
 65 20 61 62 6c 65 20 74 6f 20 66 61 6c 6c 20 69
 6e 74 6f 20 74 68 65 20 68 61 6e 64 73 20 6f 66
 20 74 68 65 20 65 6e 65 6d 79 20 77 69 74 68 6f
 75 74 20 69 6e 63 6f 6e 76 65 6e 69 65 6e 63 65
 IV = 1a f3 8c 2d c2 b9 6f fd d8 66 94 09 23 41 bc 04
 A = 54 68 65 20 73 65 63 6f 6e 64 20 70 72 69 6e 63
 69 70 6c 65 20 6f 66 20 41 75 67 75 73 74 65 20
 4b 65 72 63 6b 68 6f 66 66 73
 AL = 00 00 00 00 00 00 01 50
 E = ea 65 da 6b 59 e6 1e db 41 9b e6 2d 19 71 2a e5
 d3 03 ee b5 00 52 d0 df d6 69 7f 77 22 4c 8e db
 00 0d 27 9b dc 14 c1 07 26 54 bd 30 94 42 30 c6
 57 be d4 ca 0c 9f 4a 84 66 f2 2b 22 6d 17 46 21
 4b f8 cf c2 40 0a dd 9f 51 26 e4 79 66 3f c9 0b
 3b ed 78 7a 2f 0f fc bf 39 04 be 2a 64 1d 5c 21
 05 bf e5 91 ba e2 3b 1d 74 49 e5 32 ee f6 0a 9a
 c8 bb 6c 6b 01 d3 5d 49 78 7b cd 57 ef 48 49 27
 f2 80 ad c9 1a c0 c4 e7 9c 7b 11 ef c6 00 54 e3
 M = 84 90 ac 0e 58 94 9b fe 51 87 5d 73 3f 93 ac 20
 75 16 80 39 cc c7 33 d7 45 94 f8 86 b3 fa af d4
 86 f2 5c 71 31 e3 28 1e 36 c7 a2 d1 30 af de 57
 T = 84 90 ac 0e 58 94 9b fe 51 87 5d 73 3f 93 ac 20
 75 16 80 39 cc c7 33 d7
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B.3. Test Cases for AES_256_CBC_HMAC_SHA_512
 K = 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
 10 11 12 13 14 15 16 17 18 19 1a 1b 1c 1d 1e 1f
 20 21 22 23 24 25 26 27 28 29 2a 2b 2c 2d 2e 2f
 30 31 32 33 34 35 36 37 38 39 3a 3b 3c 3d 3e 3f
 MAC_KEY = 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f
 10 11 12 13 14 15 16 17 18 19 1a 1b 1c 1d 1e 1f
 ENC_KEY = 20 21 22 23 24 25 26 27 28 29 2a 2b 2c 2d 2e 2f
 30 31 32 33 34 35 36 37 38 39 3a 3b 3c 3d 3e 3f
 P = 41 20 63 69 70 68 65 72 20 73 79 73 74 65 6d 20
 6d 75 73 74 20 6e 6f 74 20 62 65 20 72 65 71 75
 69 72 65 64 20 74 6f 20 62 65 20 73 65 63 72 65
 74 2c 20 61 6e 64 20 69 74 20 6d 75 73 74 20 62
 65 20 61 62 6c 65 20 74 6f 20 66 61 6c 6c 20 69
 6e 74 6f 20 74 68 65 20 68 61 6e 64 73 20 6f 66
 20 74 68 65 20 65 6e 65 6d 79 20 77 69 74 68 6f
 75 74 20 69 6e 63 6f 6e 76 65 6e 69 65 6e 63 65
 IV = 1a f3 8c 2d c2 b9 6f fd d8 66 94 09 23 41 bc 04
 A = 54 68 65 20 73 65 63 6f 6e 64 20 70 72 69 6e 63
 69 70 6c 65 20 6f 66 20 41 75 67 75 73 74 65 20
 4b 65 72 63 6b 68 6f 66 66 73
 AL = 00 00 00 00 00 00 01 50
 E = 4a ff aa ad b7 8c 31 c5 da 4b 1b 59 0d 10 ff bd
 3d d8 d5 d3 02 42 35 26 91 2d a0 37 ec bc c7 bd
 82 2c 30 1d d6 7c 37 3b cc b5 84 ad 3e 92 79 c2
 e6 d1 2a 13 74 b7 7f 07 75 53 df 82 94 10 44 6b
 36 eb d9 70 66 29 6a e6 42 7e a7 5c 2e 08 46 a1
 1a 09 cc f5 37 0d c8 0b fe cb ad 28 c7 3f 09 b3
 a3 b7 5e 66 2a 25 94 41 0a e4 96 b2 e2 e6 60 9e
 31 e6 e0 2c c8 37 f0 53 d2 1f 37 ff 4f 51 95 0b
 be 26 38 d0 9d d7 a4 93 09 30 80 6d 07 03 b1 f6
 M = 4d d3 b4 c0 88 a7 f4 5c 21 68 39 64 5b 20 12 bf
 2e 62 69 a8 c5 6a 81 6d bc 1b 26 77 61 95 5b c5
 fd 30 a5 65 c6 16 ff b2 f3 64 ba ec e6 8f c4 07
 53 bc fc 02 5d de 36 93 75 4a a1 f5 c3 37 3b 9c
 T = 4d d3 b4 c0 88 a7 f4 5c 21 68 39 64 5b 20 12 bf
 2e 62 69 a8 c5 6a 81 6d bc 1b 26 77 61 95 5b c5
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Appendix C. Example ECDH-ES Key Agreement Computation
 This example uses ECDH-ES Key Agreement and the Concat KDF to derive
 the Content Encryption Key (CEK) in the manner described in
 Section 4.6. In this example, the ECDH-ES Direct Key Agreement mode
 ("alg" value "ECDH-ES") is used to produce an agreed upon key for AES
 GCM with a 128 bit key ("enc" value "A128GCM").
 In this example, a producer Alice is encrypting content to a consumer
 Bob. The producer (Alice) generates an ephemeral key for the key
 agreement computation. Alice's ephemeral key (in JWK format) used
 for the key agreement computation in this example (including the
 private part) is:
 {"kty":"EC",
 "crv":"P-256",
 "x":"gI0GAILBdu7T53akrFmMyGcsF3n5dO7MmwNBHKW5SV0",
 "y":"SLW_xSffzlPWrHEVI30DHM_4egVwt3NQqeUD7nMFpps",
 "d":"0_NxaRPUMQoAJt50Gz8YiTr8gRTwyEaCumd-MToTmIo"
 }
 The consumer's (Bob's) key (in JWK format) used for the key agreement
 computation in this example (including the private part) is:
 {"kty":"EC",
 "crv":"P-256",
 "x":"weNJy2HscCSM6AEDTDg04biOvhFhyyWvOHQfeF_PxMQ",
 "y":"e8lnCO-AlStT-NJVX-crhB7QRYhiix03illJOVAOyck",
 "d":"VEmDZpDXXK8p8N0Cndsxs924q6nS1RXFASRl6BfUqdw"
 }
 Header Parameter values used in this example are as follows. In this
 example, the "apu" (agreement PartyUInfo) parameter value is the
 base64url encoding of the UTF-8 string "Alice" and the "apv"
 (agreement PartyVInfo) parameter value is the base64url encoding of
 the UTF-8 string "Bob". The "epk" parameter is used to communicate
 the producer's (Alice's) ephemeral public key value to the consumer
 (Bob).
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 {"alg":"ECDH-ES",
 "enc":"A128GCM",
 "apu":"QWxpY2U",
 "apv":"Qm9i",
 "epk":
 {"kty":"EC",
 "crv":"P-256",
 "x":"gI0GAILBdu7T53akrFmMyGcsF3n5dO7MmwNBHKW5SV0",
 "y":"SLW_xSffzlPWrHEVI30DHM_4egVwt3NQqeUD7nMFpps"
 }
 }
 The resulting Concat KDF [NIST.800-56A] parameter values are:
 Z
 This is set to the ECDH-ES key agreement output. (This value is
 often not directly exposed by libraries, due to NIST security
 requirements, and only serves as an input to a KDF.) In this
 example, Z is following the octet sequence (using JSON array
 notation):
 [158, 86, 217, 29, 129, 113, 53, 211, 114, 131, 66, 131, 191, 132,
 38, 156, 251, 49, 110, 163, 218, 128, 106, 72, 246, 218, 167, 121,
 140, 254, 144, 196].
 keydatalen
 This value is 128 - the number of bits in the desired output key
 (because "A128GCM" uses a 128 bit key).
 AlgorithmID
 This is set to the octets representing the 32 bit big endian value
 7 - [0, 0, 0, 7] - the number of octets in the AlgorithmID content
 "A128GCM", followed, by the octets representing the ASCII string
 "A128GCM" - [65, 49, 50, 56, 71, 67, 77].
 PartyUInfo
 This is set to the octets representing the 32 bit big endian value
 5 - [0, 0, 0, 5] - the number of octets in the PartyUInfo content
 "Alice", followed, by the octets representing the UTF-8 string
 "Alice" - [65, 108, 105, 99, 101].
 PartyVInfo
 This is set to the octets representing the 32 bit big endian value
 3 - [0, 0, 0, 3] - the number of octets in the PartyUInfo content
 "Bob", followed, by the octets representing the UTF-8 string "Bob"
 - [66, 111, 98].
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 SuppPubInfo
 This is set to the octets representing the 32 bit big endian value
 128 - [0, 0, 0, 128] - the keydatalen value.
 SuppPrivInfo
 This is set to the empty octet sequence.
 Concatenating the parameters AlgorithmID through SuppPubInfo results
 in an OtherInfo value of:
 [0, 0, 0, 7, 65, 49, 50, 56, 71, 67, 77, 0, 0, 0, 5, 65, 108, 105,
 99, 101, 0, 0, 0, 3, 66, 111, 98, 0, 0, 0, 128]
 Concatenating the round number 1 ([0, 0, 0, 1]), Z, and the OtherInfo
 value results in the Concat KDF round 1 hash input of:
 [0, 0, 0, 1,
 158, 86, 217, 29, 129, 113, 53, 211, 114, 131, 66, 131, 191, 132, 38,
 156, 251, 49, 110, 163, 218, 128, 106, 72, 246, 218, 167, 121, 140,
 254, 144, 196,
 0, 0, 0, 7, 65, 49, 50, 56, 71, 67, 77, 0, 0, 0, 5, 65, 108, 105, 99,
 101, 0, 0, 0, 3, 66, 111, 98, 0, 0, 0, 128]
 The resulting derived key, which is the first 128 bits of the round 1
 hash output is:
 [86, 170, 141, 234, 248, 35, 109, 32, 92, 34, 40, 205, 113, 167, 16,
 26]
 The base64url encoded representation of this derived key is:
 VqqN6vgjbSBcIijNcacQGg
Appendix D. Acknowledgements
 Solutions for signing and encrypting JSON content were previously
 explored by Magic Signatures [MagicSignatures], JSON Simple Sign
 [JSS], Canvas Applications [CanvasApp], JSON Simple Encryption [JSE],
 and JavaScript Message Security Format [I-D.rescorla-jsms], all of
 which influenced this draft.
 The Authenticated Encryption with AES-CBC and HMAC-SHA
 [I-D.mcgrew-aead-aes-cbc-hmac-sha2] specification, upon which the
 AES_CBC_HMAC_SHA2 algorithms are based, was written by David A.
 McGrew and Kenny Paterson. The test cases for AES_CBC_HMAC_SHA2 are
 based upon those for [I-D.mcgrew-aead-aes-cbc-hmac-sha2] by John
 Foley.
 Matt Miller wrote Using JavaScript Object Notation (JSON) Web
 Encryption (JWE) for Protecting JSON Web Key (JWK) Objects
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 [I-D.miller-jose-jwe-protected-jwk], which the password-based
 encryption content of this draft is based upon.
 This specification is the work of the JOSE Working Group, which
 includes dozens of active and dedicated participants. In particular,
 the following individuals contributed ideas, feedback, and wording
 that influenced this specification:
 Dirk Balfanz, Richard Barnes, Carsten Bormann, John Bradley, Brian
 Campbell, Alissa Cooper, Breno de Medeiros, Vladimir Dzhuvinov, Roni
 Even, Stephen Farrell, Yaron Y. Goland, Dick Hardt, Joe Hildebrand,
 Jeff Hodges, Edmund Jay, Charlie Kaufman, Barry Leiba, James Manger,
 Matt Miller, Kathleen Moriarty, Tony Nadalin, Axel Nennker, John
 Panzer, Emmanuel Raviart, Eric Rescorla, Pete Resnick, Nat Sakimura,
 Jim Schaad, Hannes Tschofenig, and Sean Turner.
 Jim Schaad and Karen O'Donoghue chaired the JOSE working group and
 Sean Turner, Stephen Farrell, and Kathleen Moriarty served as
 Security area directors during the creation of this specification.
Appendix E. Document History
 [[ to be removed by the RFC Editor before publication as an RFC ]]
 -38
 o Require discarding private keys with an "oth" parameter when the
 implementation does not support private keys with more than two
 primes.
 o Replaced uses of the phrases "JWS object" and "JWE object" with
 "JWS" and "JWE".
 -37
 o Restricted algorithm names to using only ASCII characters.
 o Added language about ignoring private keys with an "oth" parameter
 when the implementation does not support private keys with more
 than two primes.
 o Updated the example IANA registration request subject line.
 -36
 o Moved the normative "alg":"none" security considerations text into
 the algorithm definition.
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 o Specified that registration reviews occur on the
 jose-reg-review@ietf.org mailing list.
 -35
 o Addressed AppsDir reviews by Carsten Bormann.
 o Adjusted some table column widths.
 -34
 o Addressed IESG review comments by Barry Leiba, Alissa Cooper, Pete
 Resnick, Stephen Farrell, and Richard Barnes.
 -33
 o Changed the registration review period to three weeks.
 o Acknowledged additional contributors.
 -32
 o Added a note to implementers about libraries that prefix an extra
 zero-valued octet to RSA modulus representations returned.
 o Addressed secdir review comments by Charlie Kaufman, Scott Kelly,
 and Stephen Kent.
 o Addressed Gen-ART review comments by Roni Even.
 o Replaced the term Plaintext JWS with Unsecured JWS.
 -31
 o Referenced NIST SP 800-57 for guidance on key lifetimes.
 o Updated the reference to draft-mcgrew-aead-aes-cbc-hmac-sha2.
 -30
 o Cleaned up the reference syntax in a few places.
 o Applied minor wording changes to the Security Considerations
 section.
 -29
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 o Replaced the terms JWS Header, JWE Header, and JWT Header with a
 single JOSE Header term defined in the JWS specification. This
 also enabled a single Header Parameter definition to be used and
 reduced other areas of duplication between specifications.
 -28
 o Specified the use of PKCS #7 padding with AES CBC, rather than
 PKCS #5. (PKCS #7 is a superset of PKCS #5, and is appropriate
 for the 16 octet blocks used by AES CBC.)
 o Revised the introduction to the Security Considerations section.
 Also introduced additional subsection headings for security
 considerations items and moved a few security consideration items
 from here to the JWS and JWE drafts.
 -27
 o Described additional security considerations.
 o Updated the JCA and XMLENC parameters for "RSA-OAEP-256" and the
 JCA parameters for "A128KW", "A192KW", "A256KW", and "ECDH-ES".
 -26
 o Added algorithm identifier "RSA-OAEP-256" for RSAES OAEP using
 SHA-256 and MGF1 with SHA-256.
 o Clarified that the ECDSA signature values R and S are represented
 as octet sequences as defined in Section 2.3.7 of SEC1 [SEC1].
 o Noted that octet sequences are depicted using JSON array notation.
 o Updated references, including to W3C specifications.
 -25
 o Corrected an external section number reference that had changed.
 -24
 o Replaced uses of the term "associated data" wherever it was used
 to refer to a data value with "additional authenticated data",
 since both terms were being used as synonyms, causing confusion.
 o Updated the JSON reference to RFC 7159.
 -23
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 o No changes were made, other than to the version number and date.
 -22
 o Corrected RFC 2119 terminology usage.
 o Replaced references to draft-ietf-json-rfc4627bis with RFC 7158.
 -21
 o Compute the PBES2 salt parameter as (UTF8(Alg) || 0x00 || Salt
 Input), where the "p2s" Header Parameter encodes the Salt Input
 value and Alg is the "alg" Header Parameter value.
 o Changed some references from being normative to informative,
 addressing issue #90.
 -20
 o Replaced references to RFC 4627 with draft-ietf-json-rfc4627bis,
 addressing issue #90.
 -19
 o Used tables to show the correspondence between algorithm
 identifiers and algorithm descriptions and parameters in the
 algorithm definition sections, addressing issue #183.
 o Changed the "Implementation Requirements" registry field names to
 "JOSE Implementation Requirements" to make it clear that these
 implementation requirements apply only to JWS and JWE
 implementations.
 -18
 o Changes to address editorial and minor issues #129, #134, #135,
 #158, #161, #185, #186, and #187.
 o Added and used Description registry fields.
 -17
 o Explicitly named all the logical components of a JWS and JWE and
 defined the processing rules and serializations in terms of those
 components, addressing issues #60, #61, and #62.
 o Removed processing steps in algorithm definitions that duplicated
 processing steps in JWS or JWE, addressing issue #56.
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 o Replaced verbose repetitive phases such as "base64url encode the
 octets of the UTF-8 representation of X" with mathematical
 notation such as "BASE64URL(UTF8(X))".
 o Terms used in multiple documents are now defined in one place and
 incorporated by reference. Some lightly used or obvious terms
 were also removed. This addresses issue #58.
 o Changes to address minor issue #53.
 -16
 o Added a DataLen prefix to the AlgorithmID value in the Concat KDF
 computation.
 o Added OIDs for encryption algorithms, additional signature
 algorithm OIDs, and additional XML DSIG/ENC URIs in the algorithm
 cross-reference tables.
 o Changes to address editorial and minor issues #28, #36, #39, #52,
 #53, #55, #127, #128, #136, #137, #141, #150, #151, #152, and
 #155.
 -15
 o Changed statements about rejecting JWSs to statements about
 validation failing, addressing issue #35.
 o Stated that changes of implementation requirements are only
 permitted on a Specification Required basis, addressing issue #38.
 o Made "oct" a required key type, addressing issue #40.
 o Updated the example ECDH-ES key agreement values.
 o Changes to address editorial and minor issues #34, #37, #49, #63,
 #123, #124, #125, #130, #132, #133, #138, #139, #140, #142, #143,
 #144, #145, #148, #149, #150, and #162.
 -14
 o Removed "PBKDF2" key type and added "p2s" and "p2c" header
 parameters for use with the PBES2 algorithms.
 o Made the RSA private key parameters that are there to enable
 optimizations be RECOMMENDED rather than REQUIRED.
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 o Added algorithm identifiers for AES algorithms using 192 bit keys
 and for RSASSA-PSS using HMAC SHA-384.
 o Added security considerations about key lifetimes, addressing
 issue #18.
 o Added an example ECDH-ES key agreement computation.
 -13
 o Added key encryption with AES GCM as specified in
 draft-jones-jose-aes-gcm-key-wrap-01, addressing issue #13.
 o Added security considerations text limiting the number of times
 that an AES GCM key can be used for key encryption or direct
 encryption, per Section 8.3 of NIST SP 800-38D, addressing issue
 #28.
 o Added password-based key encryption as specified in
 draft-miller-jose-jwe-protected-jwk-02.
 -12
 o In the Direct Key Agreement case, the Concat KDF AlgorithmID is
 set to the octets of the UTF-8 representation of the "enc" header
 parameter value.
 o Restored the "apv" (agreement PartyVInfo) parameter.
 o Moved the "epk", "apu", and "apv" Header Parameter definitions to
 be with the algorithm descriptions that use them.
 o Changed terminology from "block encryption" to "content
 encryption".
 -11
 o Removed the Encrypted Key value from the AAD computation since it
 is already effectively integrity protected by the encryption
 process. The AAD value now only contains the representation of
 the JWE Encrypted Header.
 o Removed "apv" (agreement PartyVInfo) since it is no longer used.
 o Added more information about the use of PartyUInfo during key
 agreement.
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 o Use the keydatalen as the SuppPubInfo value for the Concat KDF
 when doing key agreement, as RFC 2631 does.
 o Added algorithm identifiers for RSASSA-PSS with SHA-256 and SHA-
 512.
 o Added a Parameter Information Class value to the JSON Web Key
 Parameters registry, which registers whether the parameter conveys
 public or private information.
 -10
 o Changed the JWE processing rules for multiple recipients so that a
 single AAD value contains the header parameters and encrypted key
 values for all the recipients, enabling AES GCM to be safely used
 for multiple recipients.
 -09
 o Expanded the scope of the JWK parameters to include private and
 symmetric key representations, as specified by
 draft-jones-jose-json-private-and-symmetric-key-00.
 o Changed term "JWS Secured Input" to "JWS Signing Input".
 o Changed from using the term "byte" to "octet" when referring to 8
 bit values.
 o Specified that AES Key Wrap uses the default initial value
 specified in Section 2.2.3.1 of RFC 3394. This addressed issue
 #19.
 o Added Key Management Mode definitions to terminology section and
 used the defined terms to provide clearer key management
 instructions. This addressed issue #5.
 o Replaced "A128CBC+HS256" and "A256CBC+HS512" with "A128CBC-HS256"
 and "A256CBC-HS512". The new algorithms perform the same
 cryptographic computations as [I-D.mcgrew-aead-aes-cbc-hmac-sha2],
 but with the Initialization Vector and Authentication Tag values
 remaining separate from the Ciphertext value in the output
 representation. Also deleted the header parameters "epu"
 (encryption PartyUInfo) and "epv" (encryption PartyVInfo), since
 they are no longer used.
 o Changed from using the term "Integrity Value" to "Authentication
 Tag".
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Internet-Draft JSON Web Algorithms (JWA) December 2014
 -08
 o Changed the name of the JWK key type parameter from "alg" to
 "kty".
 o Replaced uses of the term "AEAD" with "Authenticated Encryption",
 since the term AEAD in the RFC 5116 sense implied the use of a
 particular data representation, rather than just referring to the
 class of algorithms that perform authenticated encryption with
 associated data.
 o Applied editorial improvements suggested by Jeff Hodges. Many of
 these simplified the terminology used.
 o Added seriesInfo information to Internet Draft references.
 -07
 o Added a data length prefix to PartyUInfo and PartyVInfo values.
 o Changed the name of the JWK RSA modulus parameter from "mod" to
 "n" and the name of the JWK RSA exponent parameter from "xpo" to
 "e", so that the identifiers are the same as those used in RFC
 3447.
 o Made several local editorial changes to clean up loose ends left
 over from to the decision to only support block encryption methods
 providing integrity.
 -06
 o Removed the "int" and "kdf" parameters and defined the new
 composite Authenticated Encryption algorithms "A128CBC+HS256" and
 "A256CBC+HS512" to replace the former uses of AES CBC, which
 required the use of separate integrity and key derivation
 functions.
 o Included additional values in the Concat KDF calculation -- the
 desired output size and the algorithm value, and optionally
 PartyUInfo and PartyVInfo values. Added the optional header
 parameters "apu" (agreement PartyUInfo), "apv" (agreement
 PartyVInfo), "epu" (encryption PartyUInfo), and "epv" (encryption
 PartyVInfo).
 o Changed the name of the JWK RSA exponent parameter from "exp" to
 "xpo" so as to allow the potential use of the name "exp" for a
 future extension that might define an expiration parameter for
 keys. (The "exp" name is already used for this purpose in the JWT
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Internet-Draft JSON Web Algorithms (JWA) December 2014
 specification.)
 o Applied changes made by the RFC Editor to RFC 6749's registry
 language to this specification.
 -05
 o Support both direct encryption using a shared or agreed upon
 symmetric key, and the use of a shared or agreed upon symmetric
 key to key wrap the CMK. Specifically, added the "alg" values
 "dir", "ECDH-ES+A128KW", and "ECDH-ES+A256KW" to finish filling in
 this set of capabilities.
 o Updated open issues.
 -04
 o Added text requiring that any leading zero bytes be retained in
 base64url encoded key value representations for fixed-length
 values.
 o Added this language to Registration Templates: "This name is case
 sensitive. Names that match other registered names in a case
 insensitive manner SHOULD NOT be accepted."
 o Described additional open issues.
 o Applied editorial suggestions.
 -03
 o Always use a 128 bit "authentication tag" size for AES GCM,
 regardless of the key size.
 o Specified that use of a 128 bit IV is REQUIRED with AES CBC. It
 was previously RECOMMENDED.
 o Removed key size language for ECDSA algorithms, since the key size
 is implied by the algorithm being used.
 o Stated that the "int" key size must be the same as the hash output
 size (and not larger, as was previously allowed) so that its size
 is defined for key generation purposes.
 o Added the "kdf" (key derivation function) header parameter to
 provide crypto agility for key derivation. The default KDF
 remains the Concat KDF with the SHA-256 digest function.
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Internet-Draft JSON Web Algorithms (JWA) December 2014
 o Clarified that the "mod" and "exp" values are unsigned.
 o Added Implementation Requirements columns to algorithm tables and
 Implementation Requirements entries to algorithm registries.
 o Changed AES Key Wrap to RECOMMENDED.
 o Moved registries JSON Web Signature and Encryption Header
 Parameters and JSON Web Signature and Encryption Type Values to
 the JWS specification.
 o Moved JSON Web Key Parameters registry to the JWK specification.
 o Changed registration requirements from RFC Required to
 Specification Required with Expert Review.
 o Added Registration Template sections for defined registries.
 o Added Registry Contents sections to populate registry values.
 o No longer say "the UTF-8 representation of the JWS Secured Input
 (which is the same as the ASCII representation)". Just call it
 "the ASCII representation of the JWS Secured Input".
 o Added "Collision Resistant Namespace" to the terminology section.
 o Numerous editorial improvements.
 -02
 o For AES GCM, use the "additional authenticated data" parameter to
 provide integrity for the header, encrypted key, and ciphertext
 and use the resulting "authentication tag" value as the JWE
 Authentication Tag.
 o Defined minimum required key sizes for algorithms without
 specified key sizes.
 o Defined KDF output key sizes.
 o Specified the use of PKCS #5 padding with AES CBC.
 o Generalized text to allow key agreement to be employed as an
 alternative to key wrapping or key encryption.
 o Clarified that ECDH-ES is a key agreement algorithm.
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Internet-Draft JSON Web Algorithms (JWA) December 2014
 o Required implementation of AES-128-KW and AES-256-KW.
 o Removed the use of "A128GCM" and "A256GCM" for key wrapping.
 o Removed "A512KW" since it turns out that it's not a standard
 algorithm.
 o Clarified the relationship between "typ" header parameter values
 and MIME types.
 o Generalized language to refer to Message Authentication Codes
 (MACs) rather than Hash-based Message Authentication Codes (HMACs)
 unless in a context specific to HMAC algorithms.
 o Established registries: JSON Web Signature and Encryption Header
 Parameters, JSON Web Signature and Encryption Algorithms, JSON Web
 Signature and Encryption "typ" Values, JSON Web Key Parameters,
 and JSON Web Key Algorithm Families.
 o Moved algorithm-specific definitions from JWK to JWA.
 o Reformatted to give each member definition its own section
 heading.
 -01
 o Moved definition of "alg":"none" for JWSs here from the JWT
 specification since this functionality is likely to be useful in
 more contexts that just for JWTs.
 o Added Advanced Encryption Standard (AES) Key Wrap Algorithm using
 512 bit keys ("A512KW").
 o Added text "Alternatively, the Encoded JWS Signature MAY be
 base64url decoded to produce the JWS Signature and this value can
 be compared with the computed HMAC value, as this comparison
 produces the same result as comparing the encoded values".
 o Corrected the Magic Signatures reference.
 o Made other editorial improvements suggested by JOSE working group
 participants.
 -00
 o Created the initial IETF draft based upon
 draft-jones-json-web-signature-04 and
 draft-jones-json-web-encryption-02 with no normative changes.
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 o Changed terminology to no longer call both digital signatures and
 HMACs "signatures".
Author's Address
 Michael B. Jones
 Microsoft
 Email: mbj@microsoft.com
 URI: http://self-issued.info/
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