Network Working Group M. Jones Internet-Draft Microsoft Intended status: Standards Track D. Balfanz Expires:October 31, 2011May 2, 2012 Google J. Bradley independent Y. Goland Microsoft J. Panzer Google N. Sakimura Nomura Research Institute P. Tarjan FacebookApril 29,October 30, 2011 JSON Web Signature (JWS)draft-jones-json-web-signature-02draft-jones-json-web-signature-03 Abstract JSON Web Signature (JWS) is a means of representing signed content using JSON data structures. Related encryption capabilities are described in the separate JSON Web Encryption (JWE) specification. Requirements Language The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119 [RFC2119]. 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 onOctober 31, 2011.May 2, 2012. Copyright Notice Copyright (c) 2011 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 to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License. Table of Contents 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4 2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4 3. JSON Web Signature (JWS) Overview . . . . . . . . . . . . . . 5 3.1. Example JWS . . . . . . . . . . . . . . . . . . . . . . . 5 4. JWS Header . . . . . . . . . . . . . . . . . . . . . . . . . . 6 4.1. Reserved Header Parameter Names . . . . . . . . . . . . . 6 4.2. Public Header Parameter Names . . . . . . . . . . . . . .910 4.3. Private Header Parameter Names . . . . . . . . . . . . . .910 5. Rules for Creating and Validating a JWS . . . . . . . . . . .910 6.Base64url encoding as used by JWSs . . . . . . . . . . . . . . 11 7.Signing JWSs with Cryptographic Algorithms . . . . . . . . . .11 7.1.12 6.1. Creating a JWS with HMAC SHA-256, HMAC SHA-384, or HMAC SHA-512 . . . . . . . . . . . . . . . . . . . . . . .12 7.2.13 6.2. Creating a JWS with RSA SHA-256, RSA SHA-384, or RSA SHA-512 . . . . . . . . . . . . . . . . . . . . . . . . .13 7.3.14 6.3. Creating a JWS with ECDSA P-256 SHA-256, ECDSA P-384 SHA-384, or ECDSA P-521 SHA-512 . . . . . . . . . . . . .14 7.4.15 6.4. Additional Algorithms . . . . . . . . . . . . . . . . . .16 8.17 7. IANA Considerations . . . . . . . . . . . . . . . . . . . . .16 9.17 8. Security Considerations . . . . . . . . . . . . . . . . . . .16 9.1.18 8.1. Unicode Comparison Security Issues . . . . . . . . . . . .17 10.18 9. Open Issues and Things To Be Done (TBD) . . . . . . . . . . .17 11.19 10. References . . . . . . . . . . . . . . . . . . . . . . . . . .18 11.1.20 10.1. Normative References . . . . . . . . . . . . . . . . . . .18 11.2.20 10.2. Informative References . . . . . . . . . . . . . . . . . .2022 Appendix A. JWS Examples . . . . . . . . . . . . . . . . . . . .2022 A.1. JWS using HMAC SHA-256 . . . . . . . . . . . . . . . . . .2022 A.1.1. Encoding . . . . . . . . . . . . . . . . . . . . . . .2122 A.1.2. Decoding . . . . . . . . . . . . . . . . . . . . . . .2224 A.1.3. Validating . . . . . . . . . . . . . . . . . . . . . .2224 A.2. JWS using RSA SHA-256 . . . . . . . . . . . . . . . . . .2324 A.2.1. Encoding . . . . . . . . . . . . . . . . . . . . . . .2325 A.2.2. Decoding . . . . . . . . . . . . . . . . . . . . . . .2628 A.2.3. Validating . . . . . . . . . . . . . . . . . . . . . .2628 A.3. JWS using ECDSA P-256 SHA-256 . . . . . . . . . . . . . .2729 A.3.1. Encoding . . . . . . . . . . . . . . . . . . . . . . .2729 A.3.2. Decoding . . . . . . . . . . . . . . . . . . . . . . .2830 A.3.3. Validating . . . . . . . . . . . . . . . . . . . . . .2931 Appendix B. Algorithm Identifier Cross-Reference . . . . . . . .2931 Appendix C. Notes on implementing base64url encoding without padding . . . . . . . . . . . . . . . . . . . . . . .3133 Appendix D. Acknowledgements . . . . . . . . . . . . . . . . . .3234 Appendix E. Document History . . . . . . . . . . . . . . . . . .3335 Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . .3336 1. Introduction JSON Web Signature (JWS) is a compact signature format intended for space constrained environments such as HTTP Authorization headers and URI query parameters. It represents signed content using JSON [RFC4627] data structures. The JWS signature mechanisms are independent of the type of content being signed, allowing arbitrary content to be signed. A related encryption capability is described in a separate JSON Web Encryption (JWE) [JWE] specification. 2. Terminology JSON Web Signature (JWS) A data structure cryptographically securing a JWS HeaderInputand a JWS PayloadInputwith a JWSCrypto Output.Signature. JWS HeaderInputA string containing abase64url encodedJSON object that describes thecryptographic operationssignature applied to the JWS HeaderInputand the JWS PayloadInput.to create the JWS Signature. JWS PayloadInput A string containing base64url encoded content.The bytes to be signed - a.k.a., the message. JWSCrypto OutputSignature Astringbyte array containingbase64url encodedthe cryptographic material that secures the contents of the JWS HeaderInputand the JWSPayload Input. DecodedPayload. Encoded JWS HeaderInputBase64url encoding of the bytes of the UTF-8 RFC 3629 [RFC3629] representation of the JWSHeader Input that has been base64url decoded back into a JSON object. DecodedHeader. Encoded JWS PayloadInputBase64url encoding of the JWSPayload Input that has been base64url decoded. DecodedPayload. Encoded JWSCrypto OutputSignature Base64url encoding of the JWSCrypto Output that has been base64url decoded back into cryptographic material.Signature. JWS Signing Input The concatenation of the Encoded JWSHeader Input,Header, a period ('.') character, and the Encoded JWSPayload Input.Payload. Header Parameter Names The names of the members within the JSON object represented in a JWSHeader Input.Header. Header Parameter Values The values of the members within the JSON object represented in a JWSHeader Input.Header. Digital Signature For the purposes of this specification, we use this term to encompass both Hash-based Message Authentication Codes (HMACs), which can provide authenticity but not non- repudiation, and digital signatures using public key algorithms, which can provide both. Readers should be aware of this distinction, despite the decision to use a single term for both concepts to improve readability of the specification. Base64url Encoding For the purposes of this specification, this term always refers to the he URL- and filename-safe Base64 encoding described in RFC 4648 [RFC4648], Section 5, with the (non URL- safe) '=' padding characters omitted, as permitted by Section 3.2. (See Appendix C for notes on implementing base64url encoding without padding.) 3. JSON Web Signature (JWS) OverviewJWSs representJWS represents signed content using JSON data structures and base64url encoding. The representation consists of three parts: the JWS Header, the JWS Payload, and the JWS Signature. The three parts are base64url-encoded for transmission, and typically represented as the concatenation of the encoded strings in that order, with the three strings being separated by period ('.') characters, as is done when used in JSON Web Tokens (JWTs) [JWT]. A base64url encodedand digitally signed, and optionally encrypted, usingJSONdata structures.object - the JWS Header - describes the signature method used. A portion of the base64url encoded content that is signed is the Encoded JWSPayload Input. An accompanying base64url encoded JSON object -Payload. Finally, JWSs contain a signature that ensures the integrity of the contents of the JWS HeaderInput - describesand the JWS Payload. This signaturemethod used.value is base64url encoded to produce the Encoded JWS Signature. The member names within theDecodedJWS HeaderInputare referred to as Header Parameter Names. These names MUST be unique. The corresponding values are referred to as Header Parameter Values.JWSs contain a signature that ensures the integrity of the contents of the JWS Header Input and the JWS Payload Input. This signature value is the JWS Crypto Output.TheJSONJWS HeaderobjectMUST contain an "alg" parameter, the value of which is a string that unambiguously identifies the algorithm used to sign the JWS HeaderInputand the JWS PayloadInputto produce the JWSCrypto Output.Signature. 3.1. Example JWS The following exampleJSON header objectJWS Header declares that the encoded object is a JSON Web Token (JWT) [JWT] and the JWS HeaderInputand the JWS PayloadInputare signed using the HMAC SHA-256 algorithm: {"typ":"JWT", "alg":"HS256"} Base64url encoding the bytes of the UTF-8 representation of theJSON header objectJWS Header yields this Encoded JWS HeaderInputvalue: eyJ0eXAiOiJKV1QiLA0KICJhbGciOiJIUzI1NiJ9 The following is an example of a JSON object that can beencoded to produceused as a JWSPayload Input.Payload. (Note that the payload can be anybase64url encodedcontent, and need not be abase64url encodedrepresentation of a JSON object.) {"iss":"joe", "exp":1300819380, "http://example.com/is_root":true} Base64url encoding the bytes of the UTF-8 representation of the JSON object yields the following Encoded JWSPayload Input.Payload. eyJpc3MiOiJqb2UiLA0KICJleHAiOjEzMDA4MTkzODAsDQogImh0dHA6Ly9leGFtcGxlLmNvbS9pc19yb290Ijp0cnVlfQ Signing the UTF-8 representation of the JWS Signing Input (the concatenation of the Encoded JWSHeader Input,Header, a period ('.') character, and the Encoded JWSPayload Input)Payload) with the HMAC SHA-256 algorithm and base64url encoding the result, as per Section7.1,6.1, yields this Encoded JWSCrypto OutputSignature value: dBjftJeZ4CVP-mB92K27uhbUJU1p1r_wW1gFWFOEjXk This computation is illustrated in more detail in Appendix A.1. 4. JWS Header The members of the JSON object represented by theDecodedJWS HeaderInputdescribe the signature applied to the Encoded JWS HeaderInputand the Encoded JWS PayloadInputand optionally additional properties of the JWS. Implementations MUST understand the entire contents of the header; otherwise, the JWS MUST be rejected for processing. 4.1. Reserved Header Parameter Names The following header parameter names are reserved. All the names are short because a core goal of JWSs is for the representations to be compact.+-----------+--------+--------------+-------------------------------++-----------+--------+-------------+--------------------------------+ | Header | JSON | Header | Header Parameter Semantics | | Parameter | Value | Parameter | | | Name | Type | Syntax | |+-----------+--------+--------------+-------------------------------++-----------+--------+-------------+--------------------------------+ | alg | string |StringAndURIStringOrURI | The "alg" (algorithm) header | | | | | parameter identifies the | | | | | cryptographic algorithm used | | | | | to secure the JWS. A list of | | | | | reserved alg values is in | | | | | Table 3. The processing of | | | | | the "alg" (algorithm) header | | | | | parameter, if present, | | | | | requires that the value of the | | | | |the"alg" header parameter MUST be | | | | |MUST beone that is both supported and | | | | |supported andfor which there| | | | |exists a keyfor use with| | | | | for use with that algorithmassociated| | | | | associated with the signer ofthe| | | | | the content. The "alg"parameter| | | | | parameter value is casesensitive.| | | | | sensitive. This headerparameter is| | | | | parameter is REQUIRED. | | typ | string | String | The "typ" (type) header | | | | | parameter is used to declare | | | | | the type of the signed | | | | | content. The "typ" value is | | | | | case sensitive. This header | | | | | parameter is OPTIONAL. | | jku | string | URL | The "jku" (JSON Web Key URL) | | | | | header parameter isa URLan | | | | | absolute URL thatpointsrefers toJSON-encodeda | | | | | resource for a set of | | | | | JSON-encoded publickeys that can be usedkeys, one | | | | | of which corresponds tovalidatethesignature.| | | | | key that was used to sign the | | | | | JWS. The keys MUST be encodedas| | | | |peras described in the JSON WebKey (JWK)| | | | | Key (JWK) [JWK] specification.This| | | | | The protocol used to acquire | | | | | the resource MUST provide | | | | | integrity protection. An HTTP | | | | | GET request to retrieve the | | | | | certificate MUST use TLS RFC | | | | | 2818 [RFC2818] RFC 5246 | | | | | [RFC5246] with server | | | | | authentication RFC 6125 | | | | | [RFC6125]. This header | | | | | parameter is OPTIONAL. | | kid | string | String | The "kid" (key ID) header | | | | | parameter is a hint indicating | | | | |indicatingwhich specific key owned by | | | | |owned bythe signer should be| | | | |used tovalidate the| | | | | validate the signature. Thisallows| | | | | allows signers to explicitlysignal| | | | | signal a change of key to | | | | | recipients.Omitting this | | | | | parameter is equivalent to | | | | | setting it to an empty | | | | | string.Theinterpretation| | | | | interpretation of the contentsof the "kid"| | | | | of the "kid" parameter isunspecified.| | | | | unspecified. This headerparameter is| | | | | parameter is OPTIONAL. | | x5u | string | URL | The "x5u" (X.509 URL) header | | | | | parameter isaan absolute URLutilizing| | | | |TLS RFC 5785 [RFC5785]that refers to a resource for | | | | |points to anthe X.509 public key | | | | | certificate or certificate | | | | | chainthat can be usedcorresponding to the key | | | | |validateused to sign thesignature. ThisJWS. The | | | | | identified resource MUST | | | | | provide a representation of | | | | | the certificate or certificate | | | | | chainMUST use thethat conforms to RFC | | | | | 5280 [RFC5280] in PEM encoded | | | | |encodingform RFC 1421[RFC1421][RFC1421]. The | | | | |andprotocol used to acquire the | | | | | resource MUSTconformprovide | | | | | integrity protection. An HTTP | | | | | GET request to retrieve the | | | | | certificate MUST use TLS RFC5280| | | | |[RFC5280].2818 [RFC2818] RFC 5246 | | | | | [RFC5246] with server | | | | | authentication RFC 6125 | | | | | [RFC6125]. This header | | | | | parameter is OPTIONAL. | | x5t | string | String | The "x5t" (x.509 certificate | | | | | thumbprint) header parameter | | | | | provides a base64url encoded | | | | | SHA-1 thumbprint (a.k.a. | | | | | digest) of the DER encoding of | | | | |ofan X.509 certificate that can | | | | |canbe used to match the | | | | | certificate. This header | | | | | parameter is OPTIONAL. |+-----------+--------+--------------+-------------------------------++-----------+--------+-------------+--------------------------------+ Table 1: Reserved Header Parameter Definitions Additional reserved header parameter names MAY be defined via the IANA JSON Web Signature Header Parameters registry, as per Section8.7. The syntax values used above are defined as follows:+--------------+----------------------------------------------------++-------------+-----------------------------------------------------+ | Syntax Name | Syntax Definition |+--------------+----------------------------------------------------++-------------+-----------------------------------------------------+ | IntDate | The number of seconds from 1970-01-01T0:0:0Z as | | | measured in UTC until the desired date/time. See | | | RFC 3339 [RFC3339] for details regarding date/times | | |date/timesin general and UTC in particular. | | String | Any string value MAY be used. | |StringAndURIStringOrURI | Any string value MAY be used but a value containing | | |containinga ":" character MUST be a URI as| | |defined in RFC | | | 3986 [RFC3986]. | | URL | A URL as defined in RFC 1738 [RFC1738]. |+--------------+----------------------------------------------------++-------------+-----------------------------------------------------+ Table 2: Header Parameter Syntax Definitions 4.2. Public Header Parameter Names Additional header parameter names can be defined by those using JWSs. However, in order to prevent collisions, any new header parameter name or algorithm value SHOULD either be defined in the IANA JSON Web Signature Header Parameters registry or be defined as a URI that contains a collision resistant namespace. In each case, the definer of the name or value MUST take reasonable precautions to make sure they are in control of the part of the namespace they use to define the header parameter name. New header parameters should be introduced sparingly, as they can result in non-interoperable JWSs. 4.3. Private Header Parameter Names A producer and consumer of a JWS may agree to any header parameter name that is not a Reserved Name Section 4.1 or a Public Name Section 4.2. Unlike Public Names, these private names are subject to collision and should be used with caution. New header parameters should be introduced sparingly, as they can result in non-interoperable JWSs. 5. Rules for Creating and Validating a JWS To create a JWS, one MUST follow these steps: 1. Create thepayloadcontent to beencodedused as theDecodedJWSPayload Input.Payload. 2. Base64url encode theDecodedJWSPayload Input.Payload. This encoding becomes the Encoded JWSPayload Input.Payload. 3. Create a JSON object containing a set of desired header parameters. Note that white space is explicitly allowed in the representation and no canonicalization is performed before encoding. 4. Translate this JSON object's Unicode code points into UTF-8, as defined in RFC 3629 [RFC3629]. 5. Base64url encode the UTF-8 representation of this JSON object as defined in this specification (without padding). This encoding becomes the Encoded JWSHeader Input.Header. 6. Compute the JWSCrypto OutputSignature in the manner defined for the particular algorithm being used. The JWS Signing Input is always the concatenation of the Encoded JWSHeader Input,Header, a period ('.') character, and the Encoded JWSPayload Input.Payload. The "alg" header parameter MUST be present in the JSONHeader Input,Header, with the algorithm value accurately representing the algorithm used to construct the JWSCrypto Input.Signature. 7. Base64url encode the representation of the JWS Signature to create the Encoded JWS Signature. When validating a JWS, the following steps MUST be taken. If any of the listed steps fails, then the signed content MUST be rejected. 1. The Encoded JWS PayloadInputMUST be successfully base64url decoded following the restriction given in this specification that no padding characters have been used. 2. The Encoded JWS HeaderInputMUST be successfully base64url decoded following the restriction given in this specification that no padding characters have been used. 3. TheDecodedJWS HeaderInputMUST be completely valid JSON syntax conforming to RFC 4627 [RFC4627]. 4. The Encoded JWSCrypto OutputSignature MUST be successfully base64url decoded following the restriction given in this specification that no padding characters have been used. 5. The JWS HeaderInputMUST be validated to only include parameters and values whose syntax and semantics are both understood and supported. 6. The JWSCrypto OutputSignature MUST be successfully validated against the JWS HeaderInputand JWS PayloadInputin the manner defined for the algorithm being used, which MUST be accurately represented by the value of the "alg" header parameter, which MUST be present. Processing a JWS inevitably requires comparing known strings to values in the header. For example, in checking what the algorithm is, the Unicode string encoding "alg" will be checked against the member names in theDecodedJWS HeaderInputto see if there is a matching header parameter name. A similar process occurs when determining if the value of the "alg" header parameter represents a supported algorithm. Comparing Unicode strings, however, has significant security implications, as per Section9.8. Comparisons between JSON strings and other Unicode strings MUST be performed as specified below: 1. Remove any JSON applied escaping to produce an array of Unicode code points. 2. Unicode Normalization [USA15] MUST NOT be applied at any point to either the JSON string or to the string it is to be compared against. 3. Comparisons between the two strings MUST be performed as a Unicode code point to code point equality comparison. 6.Base64url encoding as used by JWSs JWSs make use of the base64url encoding as defined in RFC 4648 [RFC4648]. As allowed by Section 3.2 of the RFC, this specification mandates that base64url encoding when used with JWSs MUST NOT use padding. The reason for this restriction is that the padding character ('=') is not URL safe. For notes on implementing base64url encoding without padding, see Appendix C. 7.Signing JWSs with Cryptographic Algorithms JWSs use specific cryptographic algorithms to sign the contents of the JWS HeaderInputand the JWSPayload Input.Payload. The use of the following algorithms for producing JWSs is defined in this section. The table below is the list of "alg" header parameter values reserved by this specification, each of which is explained in more detail in the following sections: +--------------------+----------------------------------------------+ | Alg Parameter | Algorithm | | Value | | +--------------------+----------------------------------------------+ | HS256 | HMAC using SHA-256 hash algorithm | | HS384 | HMAC using SHA-384 hash algorithm | | HS512 | HMAC using SHA-512 hash algorithm | | RS256 | RSA using SHA-256 hash algorithm | | RS384 | RSA using SHA-384 hash algorithm | | RS512 | RSA using SHA-512 hash algorithm | | ES256 | ECDSA using P-256 curve and SHA-256 hash | | | algorithm | | ES384 | ECDSA using P-384 curve and SHA-384 hash | | | algorithm | | ES512 | ECDSA using P-521 curve and SHA-512 hash | | | algorithm | +--------------------+----------------------------------------------+ Table 3: JSON Web Signature Reserved Algorithm Values See Appendix B for a table cross-referencing the "alg" values used in this specification with the equivalent identifiers used by other standards and software packages. Of these algorithms, only HMAC SHA-256 MUST be implemented by conforming implementations. It is RECOMMENDED that implementations also support the RSA SHA-256 and ECDSA P-256 SHA-256 algorithms. Support for other algorithms and key sizes is OPTIONAL. The signed content for a JWS is the same for all algorithms: the concatenation of the Encoded JWSHeader Input,Header, a period ('.') character, and the Encoded JWSPayload Input.Payload. This character sequence is referred to as the JWS Signing Input. Note that if the JWS represents a JWT, this corresponds to the portion of the JWT representation preceding the second period character. The UTF-8 representation of the JWS Signing Input is passed to the respective signing algorithms.7.1.6.1. Creating a JWS with HMAC SHA-256, HMAC SHA-384, or HMAC SHA-512 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 the MAC matches the hashed content, in this case the JWS Signing Input, which therefore demonstrates that whoever generated the MAC was in possession of the secret. The means of exchanging the shared key is outside the scope of this specification. The algorithm for implementing and validating HMACs is provided in RFC 2104 [RFC2104]. This section defines the use of the HMAC SHA- 256, HMAC SHA-384, and HMAC SHA-512 cryptographic hash functions as defined in FIPS 180-3 [FIPS.180-3]. The reserved "alg" header parameter values "HS256", "HS384", and "HS512" are used in the JWS HeaderInputto indicate that the Encoded JWSCrypto OutputSignature contains a base64url encoded HMAC value using the respective hash function. The HMAC SHA-256 MAC is generated as follows: 1. Apply the HMAC SHA-256 algorithm to the UTF-8 representation of the JWS Signing Input using the shared key to produce an HMAC. 2. Base64url encode the HMAC, as defined in this specification. The output is the Encoded JWSCrypto OutputSignature for that JWS. The HMAC SHA-256 MAC for a JWS is validated as follows: 1. Apply the HMAC SHA-256 algorithm to the UTF-8 representation of the JWS Signing Input of the JWS using the shared key. 2. Base64url encode the previously generated HMAC, as defined in this specification. 3. If the JWSCrypto OutputSignature and the previously calculated value exactly match, then one has confirmation that the key was used to generate the HMAC on the JWS and that the contents of the JWS have not be tampered with. 4. If the validation fails, the signed content MUST be rejected. Signing with the HMAC SHA-384 and HMAC SHA-512 algorithms is performed identically to the procedure for HMAC SHA-256 - just with correspondingly longer key and result values.7.2.6.2. Creating a JWS with RSA SHA-256, RSA SHA-384, or RSA SHA-512 This section defines the use of the RSASSA-PKCS1-v1_5 signature algorithm as defined in RFC 3447 [RFC3447], Section 8.2 (commonly known as PKCS#1), using SHA-256, SHA-384, or SHA-512 as the hash function. The RSASSA-PKCS1-v1_5 algorithm is described in FIPS 186-3 [FIPS.186-3], Section 5.5, and the SHA-256, SHA-384, and SHA-512 cryptographic hash functions are defined in FIPS 180-3 [FIPS.180-3]. The reserved "alg" header parameter values "RS256", "RS384", and "RS512" are used in the JWS HeaderInputto indicate that the Encoded JWSCrypto OutputSignature contains a base64url encoded RSA signature using the respective hash function. The public keys employed may be retrieved using Header Parameter methods described in Section 4.1 or may be distributed using methods that are outside the scope of this specification. A 2048-bit or longer key length MUST be used with this algorithm. The RSA SHA-256 signature is generated as follows: 1. Generate a digital signature of the UTF-8 representation of the JWS Signing Input using RSASSA-PKCS1-V1_5-SIGN and the SHA-256 hash function with the desired private key. The output will be a byte array. 2. Base64url encode the byte array, as defined in this specification. The output is the Encoded JWSCrypto OutputSignature for that JWS. The RSA SHA-256 signature for a JWS is validated as follows: 1. Take the Encoded JWSCrypto OutputSignature and base64url decode it into a byte array. If decoding fails, the signed content MUST be rejected. 2. Submit the UTF-8 representation of the JWS Signing Input 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. 3. If the validation fails, the signed content MUST be rejected. Signing with the RSA SHA-384 and RSA SHA-512 algorithms is performed identically to the procedure for RSA SHA-256 - just with correspondingly longer key and result values.7.3.6.3. Creating a JWS with ECDSA P-256 SHA-256, ECDSA P-384 SHA-384, or ECDSA P-521 SHA-512 The Elliptic Curve Digital Signature Algorithm (ECDSA) is defined by FIPS 186-3 [FIPS.186-3]. ECDSA provides for the use of Elliptic Curve cryptography, which is able to provide equivalent security to RSA cryptography but using shorter key lengths and with greater processing speed. This means that ECDSA 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 also defined in FIPS 186-3. The reserved "alg" header parameter values "ES256", "ES384", and "ES512" are used in the JWS HeaderInputto indicate that the Encoded JWSCrypto OutputSignature contains abased64urlbase64url encoded ECDSA P-256 SHA-256, ECDSA P-384 SHA-384, or ECDSA P-521 SHA-512 signature, respectively. The public keys employed may be retrieved using Header Parameter methods described in Section 4.1 or may be distributed using methods that are outside the scope of this specification. A JWS is signed with an ECDSA P-256 SHA-256 signature as follows: 1. Generate a digital signature of the UTF-8 representation of the JWS Signing Input using ECDSA P-256 SHA-256 with the desired private key. The output will be the EC point (R, S), where R and S are unsigned integers. 2. Turn R and S into byte arrays in big endian order. Each array will be 32 bytes long. 3. Concatenate the two byte arrays in the order R and then S. 4. Base64url encode the 64 byte array, as defined in this specification. The output is the Encoded JWSCrypto OutputSignature for the JWS. The ECDSA P-256 SHA-256 signature for a JWS is validated as follows: 1. Take the Encoded JWSCrypto OutputSignature and base64url decode it into a byte array. If decoding fails, the signed content MUST be rejected. 2. The output of the base64url decoding MUST be a 64 byte array. 3. Split the 64 byte array into two 32 byte arrays. The first array will be R and the second S. Remember that the byte arrays are in big endian byte order; please check the ECDSA validator in use to see what byte order it requires. 4. Submit the UTF-8 representation of the JWS Signing Input, R, S and the public key (x, y) to the ECDSA P-256 SHA-256 validator. 5. If the validation fails, the signed content MUST be rejected. The ECDSA validator will then determine if the digital signature is valid, given the inputs. Note that ECDSA digital signature contains a value referred to as K, which is a random number generated for each digital signature instance. This means that two ECDSA digital signatures using exactly the same input parameters will output different signatures because their K values will be different. The consequence of this is that one must validate an ECDSA signature by submitting the previously specified inputs to an ECDSA validator. Signing 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 with correspondingly longer key and result values.7.4.6.4. Additional Algorithms Additional algorithms MAY be used to protect JWSs with corresponding "alg" header parameter values being defined to refer to them. New "alg" header parameter values SHOULD either be defined in the IANA JSON Web Signature Algorithms registry or be a URI that contains a collision resistant namespace. In particular, the use of algorithm identifiers defined in XML DSIG [RFC3275] and related specifications is permitted.8.7. IANA Considerations This specification calls for: o A new IANA registry entitled "JSON Web Signature Header Parameters" for reserved header parameter names is defined in Section 4.1. Inclusion in the registry is RFC Required in the RFC 5226 [RFC5226] sense for reserved JWS header parameter names that are intended to be interoperable between implementations. The registry will just record the reserved header parameter name and a pointer to the RFC that defines it. This specification defines inclusion of the header parameter names defined in Table 1. o A new IANA registry entitled "JSON Web Signature Algorithms" for reserved values used with the "alg" header parameter values is defined in Section7.4.6.4. Inclusion in the registry is RFC Required in the RFC 5226 [RFC5226] sense. The registry will just record the "alg" value and a pointer to the RFC that defines it. This specification defines inclusion of the algorithm values defined in Table 3.9.8. Security Considerations TBD: Lots of work to do here. We need to remember to look into any issues relating to security and JSON parsing. One wonders just how secure most JSON parsing libraries are. Were they ever hardened for security scenarios? If not, what kind of holes does that open up? Also, we need to walk through the JSON standard and see what kind of issues we have especially around comparison of names. For instance, comparisons of header parameter names and other parameters must occur after they are unescaped. Need to also put in text about: Importance of keeping secrets secret. Rotating keys. Strengths and weaknesses of the different algorithms. TBD: Need to put in text about why strict JSON validation is necessary. Basically, that if malformed JSON is received then the intent of the sender is impossible to reliably discern. One example of malformed JSON that MUST be rejected is an object in which the same member name occurs multiple times. TBD: Write security considerations about the implications of using a SHA-1 hash (for compatibility reasons) for the "x5t" (x.509 certificate thumbprint).9.1.When utilizing TLS to retrieve information, the authority providing the resource MUST be authenticated and the information retrieved MUST be free from modification. 8.1. Unicode Comparison Security Issues Header parameter names in JWSs are Unicode strings. For security reasons, the representations of these names must be compared verbatim after performing any escape processing (as per RFC 4627 [RFC4627], Section 2.5). This means, for instance, that these JSON strings must compare as being equal ("sig", "\u0073ig"), whereas these must all compare as being not equal to the first set or to each other ("SIG", "Sig", "si\u0047"). JSON strings MAY contain characters outside the Unicode Basic Multilingual Plane. For instance, the G clef character (U+1D11E) may be represented in a JSON string as "\uD834\uDD1E". Ideally, JWS implementations SHOULD ensure that characters outside the Basic Multilingual Plane are preserved and compared correctly; alternatively, if this is not possible due to these characters exercising limitations present in the underlying JSON implementation, then input containing them MUST be rejected.10.9. Open Issues and Things To Be Done (TBD) The following items remain to be done in thisdraft (and related drafts):draft: o Consider whether there is a better term than "Digital Signature" for the concept that includes both HMACs and digital signatures using public keys. o Consider whether we really want to allow private header parameter names that are not registered with IANA and are not in collision- resistant namespaces. Eventually this could result in interop nightmares where you need to have different code to talk to different endpoints that "knows" about each endpoint's private parameters. o Clarify the optional ability to provide type information in the JWS header. Specifically, clarify the intended use of the "typ" Header Parameter, whether it conveys syntax or semantics, and indeed, whether this is the right approach. Also clarify the relationship between these type values and MIME [RFC2045] types. o Clarify the semantics of the "kid" (key ID) header parameter. Open issues include: What happens if a "kid" header is received with an unrecognized value? Is that an error? Should it be treated as if it's empty? What happens if the header has a recognized value but the value doesn't match the key associated with that value, but it does match another key that is associated with the issuer? Is that an error? o Consider whether a key type parameter should also be introduced. o Since RFC 3447 Section 8 explicitly calls for people NOT to adopt RSASSA-PKCS1 for new applications and instead requests that people transition to RSASSA-PSS, we probably need some Security Considerations text explaining why RSASSA-PKCS1 is being used (it's what's commonly implemented) and what the potential consequences are. o Add Security Considerations text on timing attacks. o It would be good to have a confirmation method element so it could be used with holder-of-key. o Think about how to best describe the concept currently described as "the bytes of the UTF-8 representation of". Possible terms to use instead of "bytes of" include "byte sequence", "octet series", and "octet sequence". Also consider whether we want to add an overall clarifying statement somewhere in each spec something like "every place we say 'the UTF-8 representation of X', we mean 'the bytes of the UTF-8 representation of X'". That would potentially allow us to omit the "the bytes of" part everywhere else. o Consider whether a media type should be proposed, such as "application/jws". o Finish the Security Considerations section. oSort out what to do withAdd an example in which theIANA registries if thispayload isfirst standardized asnot a base64url encoded JSON object. o Consider having anOpenID specification.algorithm that is a MAC using SHA-256 that provides content integrity but for which there is no associated secret. This would be like the JWT "alg":"none", in that no validation of the authenticity content is provided, but with a checksum provided. oFinishConsider whether to define thecompanion encryption specification, perJWT "alg":"none" here, rather than in theagreements documented at http://self-issued.info/?p=378. 11.JWT spec. 10. References11.1.10.1. Normative References [FIPS.180-3] National Institute of Standards and Technology, "Secure Hash Standard (SHS)", FIPS PUB 180-3, October 2008. [FIPS.186-3] National Institute of Standards and Technology, "Digital Signature Standard (DSS)", FIPS PUB 186-3, June 2009. [JWK] Jones, M., "JSON Web Key (JWK)",April 2011. [JWT] Jones, M., Balfanz, D., Bradley, J., Goland, Y., Panzer, J., Sakimura, N., and P. Tarjan, "JSON Web Token (JWT)", MarchOctober 2011. [RFC1421] Linn, J., "Privacy Enhancement for Internet Electronic Mail: Part I: Message Encryption and Authentication Procedures", RFC 1421, February 1993. [RFC1738] Berners-Lee, T., Masinter, L., and M. McCahill, "Uniform Resource Locators (URL)", RFC 1738, December 1994. [RFC2045] Freed, N. and N. Borenstein, "Multipurpose Internet Mail Extensions (MIME) Part One: Format of Internet Message Bodies", RFC 2045, November 1996. [RFC2104] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed- Hashing for Message Authentication", RFC 2104, February 1997. [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC2818] Rescorla, E., "HTTP Over TLS", RFC 2818, May 2000. [RFC3339] Klyne, G., Ed. and C. Newman, "Date and Time on the Internet: Timestamps", RFC 3339, July 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. [RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform Resource Identifier (URI): Generic Syntax", STD 66, RFC 3986, January 2005. [RFC4627] Crockford, D., "The application/json Media Type for JavaScript Object Notation (JSON)", RFC 4627, July 2006. [RFC4648] Josefsson, S., "The Base16, Base32, and Base64 Data Encodings", RFC 4648, October 2006. [RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an IANA Considerations Section in RFCs", BCP 26, RFC 5226, May 2008. [RFC5246] Dierks, T. and E. Rescorla, "The Transport Layer Security (TLS) Protocol Version 1.2", RFC 5246, August 2008. [RFC5280] Cooper, D., Santesson, S., Farrell, S., Boeyen, S., Housley, R., and W. Polk, "Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile", RFC 5280, May 2008. [RFC5785] Nottingham, M. and E. Hammer-Lahav, "Defining Well-Known Uniform Resource Identifiers (URIs)", RFC 5785, April 2010. [RFC6125] Saint-Andre, P. and J. Hodges, "Representation and Verification of Domain-Based Application Service Identity within Internet Public Key Infrastructure Using X.509 (PKIX) Certificates in the Context of Transport Layer Security (TLS)", RFC 6125, March 2011. [USA15] Davis, M., Whistler, K., and M. Duerst, "Unicode Normalization Forms", Unicode Standard Annex 15, 09 2009.11.2.10.2. Informative References [CanvasApp] Facebook, "Canvas Applications", 2010. [JCA] Oracle, "Java Cryptography Architecture", 2011. [JSS] Bradley, J. and N. Sakimura (editor), "JSON Simple Sign", September 2010. [JWE] Jones, M., Bradley, J., and N. Sakimura, "JSON Web Encryption (JWE)",MarchOctober 2011. [JWT] Jones, M., Balfanz, D., Bradley, J., Goland, Y., Panzer, J., Sakimura, N., and P. Tarjan, "JSON Web Token (JWT)", October 2011. [MagicSignatures] Panzer (editor), J., Laurie, B., and D. Balfanz, "Magic Signatures", August 2010. [RFC3275] Eastlake, D., Reagle, J., and D. Solo, "(Extensible Markup Language) XML-Signature Syntax and Processing", RFC 3275, March 2002. Appendix A. JWS Examples This section provides several examples of JWSs. While these examples all represent JSON Web Tokens (JWTs) [JWT], the payload can be any base64url encoded content. A.1. JWS using HMAC SHA-256 A.1.1. Encoding The following exampleJSON header objectJWS Header declares that the data structure is a JSON Web Token (JWT) [JWT] and the JWS Signing Input is signed using the HMAC SHA-256 algorithm. Note that white space is explicitly allowed inDecodedJWS HeaderInputstrings and no canonicalization is performed before encoding. {"typ":"JWT", "alg":"HS256"} The following byte array contains the UTF-8 characters for theDecodedJWSHeader Input:Header: [123, 34, 116, 121, 112, 34, 58, 34, 74, 87, 84, 34, 44, 13, 10, 32, 34, 97, 108, 103, 34, 58, 34, 72, 83, 50, 53, 54, 34, 125] Base64url encoding this UTF-8 representation yields this Encoded JWS HeaderInputvalue: eyJ0eXAiOiJKV1QiLA0KICJhbGciOiJIUzI1NiJ9 TheDecodedJWS PayloadInputused in this example follows. (Note that the payload can be any base64url encoded content, and need not be a base64url encoded JSON object.) {"iss":"joe", "exp":1300819380, "http://example.com/is_root":true} The following byte array contains the UTF-8 characters for theDecodedJWSPayload Input:Payload: [123, 34, 105, 115, 115, 34, 58, 34, 106, 111, 101, 34, 44, 13, 10, 32, 34, 101, 120, 112, 34, 58, 49, 51, 48, 48, 56, 49, 57, 51, 56, 48, 44, 13, 10, 32, 34, 104, 116, 116, 112, 58, 47, 47, 101, 120, 97, 109, 112, 108, 101, 46, 99, 111, 109, 47, 105, 115, 95, 114, 111, 111, 116, 34, 58, 116, 114, 117, 101, 125] Base64url encoding the above yields the Encoded JWS PayloadInputvalue: eyJpc3MiOiJqb2UiLA0KICJleHAiOjEzMDA4MTkzODAsDQogImh0dHA6Ly9leGFtcGxlLmNvbS9pc19yb290Ijp0cnVlfQ Concatenating the Encoded JWSHeader Input,Header, a period character, and the Encoded JWS PayloadInputyields this JWS Signing Input value (with line breaks for display purposes only): eyJ0eXAiOiJKV1QiLA0KICJhbGciOiJIUzI1NiJ9 . eyJpc3MiOiJqb2UiLA0KICJleHAiOjEzMDA4MTkzODAsDQogImh0dHA6Ly9leGFtcGxlLmNvbS9pc19yb290Ijp0cnVlfQ The UTF-8 representation of the JWS Signing Input is the following byte array: [101, 121, 74, 48, 101, 88, 65, 105, 79, 105, 74, 75, 86, 49, 81, 105, 76, 65, 48, 75, 73, 67, 74, 104, 98, 71, 99, 105, 79, 105, 74, 73, 85, 122, 73, 49, 78, 105, 74, 57, 46, 101, 121, 74, 112, 99, 51, 77, 105, 79, 105, 74, 113, 98, 50, 85, 105, 76, 65, 48, 75, 73, 67, 74, 108, 101, 72, 65, 105, 79, 106, 69, 122, 77, 68, 65, 52, 77, 84, 107, 122, 79, 68, 65, 115, 68, 81, 111, 103, 73, 109, 104, 48, 100, 72, 65, 54, 76, 121, 57, 108, 101, 71, 70, 116, 99, 71, 120, 108, 76, 109, 78, 118, 98, 83, 57, 112, 99, 49, 57, 121, 98, 50, 57, 48, 73, 106, 112, 48, 99, 110, 86, 108, 102, 81] HMACs are generated using keys. This example uses the key represented by the following byte array: [3, 35, 53, 75, 43, 15, 165, 188, 131, 126, 6, 101, 119, 123, 166, 143, 90, 179, 40, 230, 240, 84, 201, 40, 169, 15, 132, 178, 210, 80, 46, 191, 211, 251, 90, 146, 210, 6, 71, 239, 150, 138, 180, 195, 119, 98, 61, 34, 61, 46, 33, 114, 5, 46, 79, 8, 192, 205, 154, 245, 103, 208, 128, 163] Running the HMAC SHA-256 algorithm on the UTF-8 representation of the JWS Signing Input with this key yields the following byte array: [116, 24, 223, 180, 151, 153, 224, 37, 79, 250, 96, 125, 216, 173, 187, 186, 22, 212, 37, 77, 105, 214, 191, 240, 91, 88, 5, 88, 83, 132, 141, 121] Base64url encoding the above HMAC output yields the Encoded JWSCrypto OutputSignature value: dBjftJeZ4CVP-mB92K27uhbUJU1p1r_wW1gFWFOEjXk A.1.2. Decoding Decoding the JWS first requires removing the base64url encoding from the Encoded JWSHeader Input,Header, the Encoded JWSPayload Input,Payload, and the Encoded JWSCrypto Output.Signature. We base64url decode the inputsper Section 6and turn them into the corresponding byte arrays. We translate the header input byte array containing UTF-8 encoded characters into theDecodedJWS HeaderInputstring. A.1.3. Validating Next we validate the decoded results. Since the "alg" parameter in the header is "HS256", we validate the HMAC SHA-256 signature contained in the JWSCrypto Output.Signature. If any of the validation steps fail, the signed content MUST be rejected. First, we validate that thedecodedJWS HeaderInputstring is legal JSON. To validate the signature, we repeat the previous process of using the correct key and the UTF-8 representation of the JWS Signing Input as input to a SHA-256 HMAC function and then taking the output and determining if it matches theDecodedJWSCrypto Output.Signature. If it matches exactly, the signature has been validated. A.2. JWS using RSA SHA-256 A.2.1. Encoding TheDecodedJWS HeaderInputin this example is different from the previous example in two ways: First, because a different algorithm is being used, the "alg" value is different. Second, for illustration purposes only, the optional "typ" parameter is not used. (This difference is not related to the signature algorithm employed.) TheDecodedJWS HeaderInputused is: {"alg":"RS256"} The following byte array contains the UTF-8 characters for theDecodedJWSHeader Input:Header: [123, 34, 97, 108, 103, 34, 58, 34, 82, 83, 50, 53, 54, 34, 125] Base64url encoding this UTF-8 representation yields this Encoded JWS HeaderInputvalue: eyJhbGciOiJSUzI1NiJ9 TheDecodedJWS PayloadInputused in this example, which follows, is the same as in the previous example. Since the Encoded JWS PayloadInputwill therefore be the same, its computation is not repeated here. {"iss":"joe", "exp":1300819380, "http://example.com/is_root":true} Concatenating the Encoded JWSHeader Input,Header, a period character, and the Encoded JWS PayloadInputyields this JWS Signing Input value (with line breaks for display purposes only): eyJhbGciOiJSUzI1NiJ9 . eyJpc3MiOiJqb2UiLA0KICJleHAiOjEzMDA4MTkzODAsDQogImh0dHA6Ly9leGFtcGxlLmNvbS9pc19yb290Ijp0cnVlfQ The UTF-8 representation of the JWS Signing Input is the following byte array: [101, 121, 74, 104, 98, 71, 99, 105, 79, 105, 74, 83, 85, 122, 73, 49, 78, 105, 74, 57, 46, 101, 121, 74, 112, 99, 51, 77, 105, 79, 105, 74, 113, 98, 50, 85, 105, 76, 65, 48, 75, 73, 67, 74, 108, 101, 72, 65, 105, 79, 106, 69, 122, 77, 68, 65, 52, 77, 84, 107, 122, 79, 68, 65, 115, 68, 81, 111, 103, 73, 109, 104, 48, 100, 72, 65, 54, 76, 121, 57, 108, 101, 71, 70, 116, 99, 71, 120, 108, 76, 109, 78, 118, 98, 83, 57, 112, 99, 49, 57, 121, 98, 50, 57, 48, 73, 106, 112, 48, 99, 110, 86, 108, 102, 81] The RSA key consists of a public part (n, e), and a private exponent d. The values of the RSA key used in this example, presented as the byte arrays representing big endian integers are: +-----------+-------------------------------------------------------+ | Parameter | Value | | Name | | +-----------+-------------------------------------------------------+ | n | [161, 248, 22, 10, 226, 227, 201, 180, 101, 206, 141, | | | 45, 101, 98, 99, 54, 43, 146, 125, 190, 41, 225, 240, | | | 36, 119, 252, 22, 37, 204, 144, 161, 54, 227, 139, | | | 217, 52, 151, 197, 182, 234, 99, 221, 119, 17, 230, | | | 124, 116, 41, 249, 86, 176, 251, 138, 143, 8, 154, | | | 220, 75, 105, 137, 60, 193, 51, 63, 83, 237, 208, 25, | | | 184, 119, 132, 37, 47, 236, 145, 79, 228, 133, 119, | | | 105, 89, 75, 234, 66, 128, 211, 44, 15, 85, 191, 98, | | | 148, 79, 19, 3, 150, 188, 110, 155, 223, 110, 189, | | | 210, 189, 163, 103, 142, 236, 160, 198, 104, 247, 1, | | | 179, 141, 191, 251, 56, 200, 52, 44, 226, 254, 109, | | | 39, 250, 222, 74, 90, 72, 116, 151, 157, 212, 185, | | | 207, 154, 222, 196, 199, 91, 5, 133, 44, 44, 15, 94, | | | 248, 165, 193, 117, 3, 146, 249, 68, 232, 237, 100, | | | 193, 16, 198, 182, 71, 96, 154, 164, 120, 58, 235, | | | 156, 108, 154, 215, 85, 49, 48, 80, 99, 139, 131, | | | 102, 92, 111, 111, 122, 130, 163, 150, 112, 42, 31, | | | 100, 27, 130, 211, 235, 242, 57, 34, 25, 73, 31, 182, | | | 134, 135, 44, 87, 22, 245, 10, 248, 53, 141, 154, | | | 139, 157, 23, 195, 64, 114, 143, 127, 135, 216, 154, | | | 24, 216, 252, 171, 103, 173, 132, 89, 12, 46, 207, | | | 117, 147, 57, 54, 60, 7, 3, 77, 111, 96, 111, 158, | | | 33, 224, 84, 86, 202, 229, 233, 161] | | e | [1, 0, 1] | | d | [18, 174, 113, 164, 105, 205, 10, 43, 195, 126, 82, | | | 108, 69, 0, 87, 31, 29, 97, 117, 29, 100, 233, 73, | | | 112, 123, 98, 89, 15, 157, 11, 165, 124, 150, 60, 64, | | | 30, 63, 207, 47, 44, 211, 189, 236, 136, 229, 3, 191, | | | 198, 67, 155, 11, 40, 200, 47, 125, 55, 151, 103, 31, | | | 82, 19, 238, 216, 193, 90, 37, 216, 213, 206, 160, 2, | | | 94, 227, 171, 46, 139, 127, 121, 33, 111, 198, 59, | | | 234, 86, 39, 83, 180, 6, 68, 198, 161, 81, 39, 217, | | | 178, 149, 69, 64, 160, 187, 225, 163, 5, 86, 152, 45, | | | 78, 159, 222, 95, 100, 37, 241, 77, 75, 113, 52, 65, | | | 181, 93, 199, 59, 155, 74, 237, 204, 146, 172, 227, | | | 146, 126, 55, 245, 125, 12, 253, 94, 117, 129, 250, | | | 81, 44, 143, 73, 97, 169, 235, 11, 128, 248, 168, 7, | | | 70, 114, 138, 85, 255, 70, 71, 31, 52, 37, 6, 59, | | | 157, 83, 100, 47, 94, 222, 30, 132, 214, 19, 8, 26, | | | 250, 92, 34, 208, 81, 40, 91, 214, 59, 148, 59, 86, | | | 93, 137, 138, 5, 104, 84, 19, 229, 60, 60, 108, 101, | | | 37, 255, 31, 227, 78, 61, 220, 112, 240, 213, 100, | | | 80, 253, 164, 139, 161, 46, 16, 78, 157, 235, 159, | | | 184, 24, 129, 225, 196, 189, 242, 93, 146, 71, 244, | | | 80, 200, 101, 146, 121, 104, 231, 115, 52, 244, 65, | | | 79, 117, 167, 80, 225, 57, 84, 110, 58, 138, 115, | | | 157] | +-----------+-------------------------------------------------------+ The RSA private key (n, d) is then passed to the RSA signing function, which also takes the hash type, SHA-256, and the UTF-8 representation of the JWS Signing Input as inputs. The result of the signature is a byte array S, which represents a big endian integer. In this example, S is: +--------+----------------------------------------------------------+ | Result | Value | | Name | | +--------+----------------------------------------------------------+ | S | [112, 46, 33, 137, 67, 232, 143, 209, 30, 181, 216, 45, | | | 191, 120, 69, 243, 65, 6, 174, 27, 129, 255, 247, 115, | | | 17, 22, 173, 209, 113, 125, 131, 101, 109, 66, 10, 253, | | | 60, 150, 238, 221, 115, 162, 102, 62, 81, 102, 104, 123, | | | 0, 11, 135, 34, 110, 1, 135, 237, 16, 115, 249, 69, 229, | | | 130, 173, 252, 239, 22, 216, 90, 121, 142, 232, 198, | | | 109, 219, 61, 184, 151, 91, 23, 208, 148, 2, 190, 237, | | | 213, 217, 217, 112, 7, 16, 141, 178, 129, 96, 213, 248, | | | 4, 12, 167, 68, 87, 98, 184, 31, 190, 127, 249, 217, 46, | | | 10, 231, 111, 36, 242, 91, 51, 187, 230, 244, 74, 230, | | | 30, 177, 4, 10, 203, 32, 4, 77, 62, 249, 18, 142, 212, | | | 1, 48, 121, 91, 212, 189, 59, 65, 238, 202, 208, 102, | | | 171, 101, 25, 129, 253, 228, 141, 247, 127, 55, 45, 195, | | | 139, 159, 175, 221, 59, 239, 177, 139, 93, 163, 204, 60, | | | 46, 176, 47, 158, 58, 65, 214, 18, 202, 173, 21, 145, | | | 18, 115, 160, 95, 35, 185, 232, 56, 250, 175, 132, 157, | | | 105, 132, 41, 239, 90, 30, 136, 121, 130, 54, 195, 212, | | | 14, 96, 69, 34, 165, 68, 200, 242, 122, 122, 45, 184, 6, | | | 99, 209, 108, 247, 202, 234, 86, 222, 64, 92, 178, 33, | | | 90, 69, 178, 194, 85, 102, 181, 90, 193, 167, 72, 160, | | | 112, 223, 200, 163, 42, 70, 149, 67, 208, 25, 238, 251, | | | 71] | +--------+----------------------------------------------------------+ Base64url encoding the signature produces this value for the Encoded JWSCrypto Output:Signature: cC4hiUPoj9Eetdgtv3hF80EGrhuB__dzERat0XF9g2VtQgr9PJbu3XOiZj5RZmh7AAuHIm4Bh-0Qc_lF5YKt_O8W2Fp5jujGbds9uJdbF9CUAr7t1dnZcAcQjbKBYNX4BAynRFdiuB--f_nZLgrnbyTyWzO75vRK5h6xBArLIARNPvkSjtQBMHlb1L07Qe7K0GarZRmB_eSN9383LcOLn6_dO--xi12jzDwusC-eOkHWEsqtFZESc6BfI7noOPqvhJ1phCnvWh6IeYI2w9QOYEUipUTI8np6LbgGY9Fs98rqVt5AXLIhWkWywlVmtVrBp0igcN_IoypGlUPQGe77Rw A.2.2. Decoding Decoding the JWS from this example requires processing the Encoded JWS HeaderInputand Encoded JWS PayloadInputexactly as done in the first example. A.2.3. Validating Since the "alg" parameter in the header is "RS256", we validate the RSA SHA-256 signature contained in the JWSCrypto Output.Signature. If any of the validation steps fail, the signed content MUST be rejected. First, we validate that thedecodedJWS HeaderInputstring is legal JSON. Validating the JWSCrypto OutputSignature is a little different from the previous example. First, we base64url decode the Encoded JWSCrypto OutputSignature to produce a signature S to check. We then pass (n, e), S and the UTF-8 representation of the JWS Signing Input to an RSA signature verifier that has been configured to use the SHA-256 hash function. A.3. JWS using ECDSA P-256 SHA-256 A.3.1. Encoding TheDecodedJWS HeaderInputfor this example differs from the previous example because a different algorithm is being used. TheDecodedJWS HeaderInputused is: {"alg":"ES256"} The following byte array contains the UTF-8 characters for theDecodedJWSHeader Input:Header: [123, 34, 97, 108, 103, 34, 58, 34, 69, 83, 50, 53, 54, 34, 125] Base64url encoding this UTF-8 representation yields this Encoded JWS HeaderInputvalue: eyJhbGciOiJFUzI1NiJ9 TheDecodedJWS PayloadInputused in this example, which follows, is the same as in the previous examples. Since the Encoded JWS PayloadInputwill therefore be the same, its computation is not repeated here. {"iss":"joe", "exp":1300819380, "http://example.com/is_root":true} Concatenating the Encoded JWSHeader Input,Header, a period character, and the Encoded JWS PayloadInputyields this JWS Signing Input value (with line breaks for display purposes only): eyJhbGciOiJFUzI1NiJ9 . eyJpc3MiOiJqb2UiLA0KICJleHAiOjEzMDA4MTkzODAsDQogImh0dHA6Ly9leGFtcGxlLmNvbS9pc19yb290Ijp0cnVlfQ The UTF-8 representation of the JWS Signing Input is the following byte array: [101, 121, 74, 104, 98, 71, 99, 105, 79, 105, 74, 70, 85, 122, 73, 49, 78, 105, 74, 57, 46, 101, 121, 74, 112, 99, 51, 77, 105, 79, 105, 74, 113, 98, 50, 85, 105, 76, 65, 48, 75, 73, 67, 74, 108, 101, 72, 65, 105, 79, 106, 69, 122, 77, 68, 65, 52, 77, 84, 107, 122, 79, 68, 65, 115, 68, 81, 111, 103, 73, 109, 104, 48, 100, 72, 65, 54, 76, 121, 57, 108, 101, 71, 70, 116, 99, 71, 120, 108, 76, 109, 78, 118, 98, 83, 57, 112, 99, 49, 57, 121, 98, 50, 57, 48, 73, 106, 112, 48, 99, 110, 86, 108, 102, 81] The ECDSA key consists of a public part, the EC point (x, y), and a private part d. The values of the ECDSA key used in this example, presented as the byte arrays representing big endian integers are: +-----------+-------------------------------------------------------+ | Parameter | Value | | Name | | +-----------+-------------------------------------------------------+ | x | [127, 205, 206, 39, 112, 246, 196, 93, 65, 131, 203, | | | 238, 111, 219, 75, 123, 88, 7, 51, 53, 123, 233, 239, | | | 19, 186, 207, 110, 60, 123, 209, 84, 69] | | y | [199, 241, 68, 205, 27, 189, 155, 126, 135, 44, 223, | | | 237, 185, 238, 185, 244, 179, 105, 93, 110, 169, 11, | | | 36, 173, 138, 70, 35, 40, 133, 136, 229, 173] | | d | [142, 155, 16, 158, 113, 144, 152, 191, 152, 4, 135, | | | 223, 31, 93, 119, 233, 203, 41, 96, 110, 190, 210, | | | 38, 59, 95, 87, 194, 19, 223, 132, 244, 178] | +-----------+-------------------------------------------------------+ The ECDSA private part d is then passed to an ECDSA signing function, which also takes the curve type, P-256, the hash type, SHA-256, and the UTF-8 representation of the JWS Signing Input as inputs. The result of the signature is the EC point (R, S), where R and S are unsigned integers. In this example, the R and S values, given as byte arrays representing big endian integers are: +--------+----------------------------------------------------------+ | Result | Value | | Name | | +--------+----------------------------------------------------------+ | R | [14, 209, 33, 83, 121, 99, 108, 72, 60, 47, 127, 21, 88, | | | 7, 212, 2, 163, 178, 40, 3, 58, 249, 124, 126, 23, 129, | | | 154, 195, 22, 158, 166, 101] | | S | [197, 10, 7, 211, 140, 60, 112, 229, 216, 241, 45, 175, | | | 8, 74, 84, 128, 166, 101, 144, 197, 242, 147, 80, 154, | | | 143, 63, 127, 138, 131, 163, 84, 213] | +--------+----------------------------------------------------------+ Concatenating the S array to the end of the R array and base64url encoding the result produces this value for the Encoded JWSCrypto Output:Signature: DtEhU3ljbEg8L38VWAfUAqOyKAM6-Xx-F4GawxaepmXFCgfTjDxw5djxLa8ISlSApmWQxfKTUJqPP3-Kg6NU1Q A.3.2. Decoding Decoding the JWS from this example requires processing the Encoded JWS HeaderInputand Encoded JWS PayloadInputexactly as done in the first example. A.3.3. Validating Since the "alg" parameter in the header is "ES256", we validate the ECDSA P-256 SHA-256 signature contained in the JWSCrypto Output.Signature. If any of the validation steps fail, the signed content MUST be rejected. First, we validate that thedecodedJWS HeaderInputstring is legal JSON. Validating the JWSCrypto OutputSignature is a little different from the first example. First, we base64url decode the Encoded JWSCrypto OutputSignature as in the previous examples but we then need to split the 64 member byte array that must result into two 32 byte arrays, the first R and the second S. We then pass (x, y), (R, S) and the UTF-8 representation of the JWS Signing Input to an ECDSA signature verifier that has been configured to use the P-256 curve with the SHA-256 hash function. As explained in Section7.3,6.3, the use of the k value in ECDSA means that we cannot validate the correctness of the signature in the same way we validated the correctness of the HMAC. Instead, implementations MUST use an ECDSA validator to validate the signature. Appendix B. Algorithm Identifier Cross-Reference This appendix contains a table cross-referencing the "alg" values used in this specification with the equivalent identifiers used by other standards and software packages. See XML DSIG [RFC3275] and Java Cryptography Architecture [JCA] for more information about the names defined by those documents. +-------+-----+----------------------------+----------+-------------+ | Algor | JWS | XML DSIG | JCA | OID | | ithm | | | | | +-------+-----+----------------------------+----------+-------------+ | HMAC | HS2 | http://www.w3.org/2001/04/ | HmacSHA2 | 1.2.840.113 | | using | 56 | xmldsig-more#hmac-sha256 | 56 | 549.2.9 | | SHA-2 | | | | | | 56 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | HMAC | HS3 | http://www.w3.org/2001/04/ | HmacSHA3 | 1.2.840.113 | | using | 84 | xmldsig-more#hmac-sha384 | 84 | 549.2.10 | | SHA-3 | | | | | | 84 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | HMAC | HS5 | http://www.w3.org/2001/04/ | HmacSHA5 | 1.2.840.113 | | using | 12 | xmldsig-more#hmac-sha512 | 12 | 549.2.11 | | SHA-5 | | | | | | 12 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | RSA | RS2 | http://www.w3.org/2001/04/ | SHA256wi | 1.2.840.113 | | using | 56 | xmldsig-more#rsa-sha256 | thRSA | 549.1.1.11 | | SHA-2 | | | | | | 56 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | RSA | RS3 | http://www.w3.org/2001/04/ | SHA384wi | 1.2.840.113 | | using | 84 | xmldsig-more#rsa-sha384 | thRSA | 549.1.1.12 | | SHA-3 | | | | | | 84 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | RSA | RS5 | http://www.w3.org/2001/04/ | SHA512wi | 1.2.840.113 | | using | 12 | xmldsig-more#rsa-sha512 | thRSA | 549.1.1.13 | | SHA-5 | | | | | | 12 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | ECDSA | ES2 | http://www.w3.org/2001/04/ | SHA256wi | 1.2.840.100 | | using | 56 | xmldsig-more#ecdsa-sha256 | thECDSA | 45.3.1.7 | | P-256 | | | | | | curve | | | | | | and | | | | | | SHA-2 | | | | | | 56 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | ECDSA | ES3 | http://www.w3.org/2001/04/ | SHA384wi | 1.3.132.0.3 | | using | 84 | xmldsig-more#ecdsa-sha384 | thECDSA | 4 | | P-384 | | | | | | curve | | | | | | and | | | | | | SHA-3 | | | | | | 84 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | | ECDSA | ES5 | http://www.w3.org/2001/04/ | SHA512wi | 1.3.132.0.3 | | using | 12 | xmldsig-more#ecdsa-sha512 | thECDSA | 5 | | P-521 | | | | | | curve | | | | | | and | | | | | | SHA-5 | | | | | | 12 | | | | | | hash | | | | | | algo | | | | | | rithm | | | | | +-------+-----+----------------------------+----------+-------------+ Table 4: Algorithm Identifier Cross-Reference Appendix C. Notes on implementing base64url encoding without padding This appendix describes how to implement base64url encoding and decoding functions without padding based upon standard base64 encoding and decoding functions that do use padding. To be concrete, example C# code implementing these functions is shown below. Similar code could be used in other languages. static string base64urlencode(byte [] arg) { string s = Convert.ToBase64String(arg); // Standard base64 encoder s = s.Split('=')[0]; // Remove any trailing '='s s = s.Replace('+', '-'); // 62nd char of encoding s = s.Replace('/', '_'); // 63rd char of encoding return s; } static byte [] base64urldecode(string arg) { string s = arg; s = s.Replace('-', '+'); // 62nd char of encoding s = s.Replace('_', '/'); // 63rd char of encoding switch (s.Length % 4) // Pad with trailing '='s { case 0: break; // No pad chars in this case case 2: s += "=="; break; // Two pad chars case 3: s += "="; break; // One pad char default: throw new System.Exception( "Illegal base64url string!"); } return Convert.FromBase64String(s); // Standard base64 decoder } As per the example code above, the number of '=' padding characters that needs to be added to the end of a base64url encoded string without padding to turn it into one with padding is a deterministic function of the length of the encoded string. Specifically, if the length mod 4 is 0, no padding is added; if the length mod 4 is 2, two '=' padding characters are added; if the length mod 4 is 3, one '=' padding character is added; if the length mod 4 is 1, the input is malformed. An example correspondence between unencoded and encoded values follows. The byte sequence below encodes into the string below, which when decoded, reproduces the byte sequence. 3 236 255 224 193 A-z_4ME Appendix D. Acknowledgements Solutions for signing JSON content were previously explored by Magic Signatures [MagicSignatures], JSON Simple Sign [JSS], and Canvas Applications [CanvasApp], all of which influenced this draft. Appendix E. Document History -03 o Simplified terminology to better match JWE, where the terms "JWS Header" and "Encoded JWS Header", are now used, for instance, rather than the previous terms "Decoded JWS Header Input" and "JWS Header Input". Likewise the terms "JWS Payload" and "JWS Signature" are now used, rather than "JWS Payload Input" and "JWS Crypto Output". o The "jku" and "x5u" URLs are now required to be absolute URLs. o Removed this unnecessary language from the "kid" description: "Omitting this parameter is equivalent to setting it to an empty string". o Changed StringAndURI to StringOrURI. -02 o Reference the JSON Web Key (JWK) specification from the "jku" header parameter. -01 o Changed RSA SHA-256 from MUST be supported to RECOMMENDED that it be supported. Rationale: Several people have objected to the requirement for implementing RSA SHA-256, some because they will only be using HMACs and symmetric keys, and others because they only want to use ECDSA when using asymmetric keys, either for security or key length reasons, or both. o Clarified that "x5u" is an HTTPS URL referencing a PEM-encoded certificate or certificate chain. o Clarified that the "alg" parameter value is case sensitive. o Changed "x5t" (x.509 certificate thumbprint) to use a SHA-1 hash, rather than a SHA-256 hash, for compatibility reasons. -00 o Created first signature draft using content split from draft-jones-json-web-token-01. This split introduced no semantic changes. Authors' Addresses Michael B. Jones Microsoft Email: mbj@microsoft.com URI: http://self-issued.info/ Dirk Balfanz Google Email: balfanz@google.com John Bradley independent Email: ve7jtb@ve7jtb.com Yaron Y. Goland Microsoft Email: yarong@microsoft.com John Panzer Google Email: jpanzer@google.com Nat Sakimura Nomura Research Institute Email: n-sakimura@nri.co.jp Paul Tarjan Facebook Email: pt@fb.com