JSON Web Signature (JWS)Microsoftmbj@microsoft.comhttp://self-issued.info/independentve7jtb@ve7jtb.comNomura Research Instituten-sakimura@nri.co.jp
Security
JOSE Working GroupRFCRequest for CommentsI-DInternet-DraftJavaScript Object NotationJSONJSON Web TokenJWTJSON Web SignatureJWSJSON Web EncryptionJWEJSON Web KeyJWKJSON Web AlgorithmsJWA
JSON Web Signature (JWS) is a means of
representing content secured with digital signatures or
Hash-based Message Authentication Codes (HMACs)
using JSON data structures.
Cryptographic algorithms and identifiers used with this
specification are enumerated in the separate
JSON Web Algorithms (JWA) specification.
Related encryption capabilities are described in the separate
JSON Web Encryption (JWE) specification.
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.
JSON Web Signature (JWS) is a compact format for
representing content secured with digital signatures or
Hash-based Message Authentication Codes (HMACs)
intended for space constrained environments such as HTTP
Authorization headers and URI query parameters. It represents
this content using JSON data
structures. The JWS digital signature and HMAC mechanisms are independent of
the type of content being secured, allowing arbitrary content
to be secured.
Cryptographic algorithms and identifiers used with this
specification are enumerated in the separate
JSON Web Algorithms (JWA) specification.
Related encryption capabilities are described in the separate
JSON Web Encryption (JWE) specification.
A data structure cryptographically securing a JWS Header
and a JWS Payload with a JWS Signature value.
A string representing a JSON object that describes the
digital signature or HMAC applied to the JWS Header and the JWS Payload to
create the JWS Signature value.
The bytes to be secured - a.k.a., the message.
A byte array containing the cryptographic
material that secures the contents of the JWS Header
and the JWS Payload.
Base64url encoding of the bytes of the
UTF-8 RFC 3629
representation of the JWS Header.
Base64url encoding of the JWS Payload.
Base64url encoding of the JWS Signature.
The concatenation of the Encoded JWS Header, a period ('.')
character, and the Encoded JWS Payload.
The names of the members within the JSON object
represented in a JWS Header.
The values of the members within the JSON object
represented in a JWS Header.
A representation of the JWS as the concatenation of the
Encoded JWS Header, the Encoded JWS Payload, and the
Encoded JWS Signature in that order, with the three
strings being separated by period ('.') characters.
For the purposes of this specification, this term always
refers to the URL- and filename-safe Base64 encoding
described in RFC 4648,
Section 5, with the (non URL-safe) '=' padding characters
omitted, as permitted by Section 3.2. (See for notes on implementing
base64url encoding without padding.)
JWS represents digitally signed or HMACed content using JSON data
structures and base64url encoding. The representation
consists of three parts: the JWS Header, the JWS Payload,
and the JWS Signature.
In the Compact Serialization, the three parts are
base64url-encoded for transmission, and represented
as the concatenation of the encoded strings in that order,
with the three strings being separated by period ('.')
characters.
(A JSON Serialization for this information is defined in the separate
JSON Web Signature JSON Serialization (JWS-JS)
specification.)
The JWS Header describes the signature or HMAC method and parameters employed.
The JWS Payload is the message content to be secured.
The JWS Signature ensures the integrity of
both the JWS Header and the JWS Payload.
The following example JWS Header declares that the
encoded object is a JSON Web Token (JWT)
and the JWS Header and the JWS Payload are
secured using the HMAC SHA-256 algorithm:
Base64url encoding the bytes of the UTF-8 representation of
the JWS Header yields this Encoded JWS Header value:
The following is an example of a JSON object that can be
used as a JWS Payload. (Note that the payload can be any
content, and need not be a representation of a JSON object.)
Base64url encoding the bytes of the UTF-8 representation of the JSON
object yields the following Encoded JWS Payload
(with line breaks for display purposes only):
Computing the HMAC of the UTF-8 representation of the JWS Secured Input
(the concatenation of the Encoded JWS Header, a period ('.')
character, and the Encoded JWS Payload) with the HMAC
SHA-256 algorithm and base64url encoding the result, as per
,
yields this Encoded JWS Signature value:
Concatenating these parts in the order
Header.Payload.Signature with period characters between the
parts yields this complete JWS representation
(with line breaks for display purposes only):
This computation is illustrated in more detail in .
The members of the JSON object represented by the JWS Header describe the
digital signature or HMAC applied to the
Encoded JWS Header and the Encoded JWS Payload and optionally
additional properties of the JWS.
The Header Parameter Names within this object MUST be unique.
Implementations MUST
understand the entire contents of the header; otherwise, the
JWS MUST be rejected.
The JWS Header MUST contain an alg (algorithm)
parameter, the value of
which is a string that unambiguously identifies the algorithm
used to secure the JWS Header and the JWS Payload to
produce the JWS Signature.
There are three classes of Header Parameter Names:
Reserved Header Parameter Names, Public Header Parameter Names,
and Private 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 Parameter NameJSON Value TypeHeader Parameter SyntaxHeader Parameter SemanticsalgstringStringOrURI
The alg (algorithm) header
parameter identifies the cryptographic algorithm used to
secure the JWS. A list of defined
alg values is presented in
Section 3, Table 1 of the
JSON Web Algorithms (JWA) specification.
The processing of the alg header parameter
requires that the value MUST be one that
is both supported and for which there exists a key for use
with that algorithm associated with the
party that digitally signed or HMACed the content.
The alg parameter value is case sensitive.
This header parameter is REQUIRED.
jkustringURL
The jku (JSON Web Key URL)
header parameter is an absolute URL that refers to a
resource for a set of JSON-encoded public keys, one of
which corresponds to the key that was used to
digitally sign the JWS.
The keys MUST be encoded as described in the JSON Web Key
(JWK) specification.
The protocol used to acquire the resource MUST provide
integrity protection. An HTTP GET request to retrieve the
certificate MUST use TLS RFC
2818RFC 5246 with
server authentication RFC
6125.
This header parameter is OPTIONAL.
kidstringString
The kid (key ID) header
parameter is a hint indicating which specific key owned by
the signer should be used to validate the digital signature. This
allows signers to explicitly signal a change of key to
recipients. The interpretation of the
contents of the kid parameter
is unspecified.
This header parameter is OPTIONAL.
jpkobjectJWK Key Object
The jpk (JSON Public Key)
header parameter is a public key that corresponds to the
key that was used to digitally sign the JWS.
This key is represented in the same manner as a JSON Web
Key JWK Key Object value.
This header parameter is OPTIONAL.
x5ustringURL
The x5u (X.509 URL) header
parameter is an absolute URL that refers to a resource for
the X.509 public key certificate or certificate chain
corresponding to the key used to digitally sign the JWS.
The identified resource MUST provide a representation of
the certificate or certificate chain that conforms to
RFC 5280 in PEM encoded form
RFC 1421.
The certificate containing the public key of the entity
signing the JWS MUST be the first certificate. This MAY
be followed by additional certificates, with each
subsequent certificate being the one used to certify the
previous one.
The protocol used to acquire the resource MUST provide
integrity protection. An HTTP GET request to retrieve the
certificate MUST use TLS RFC
2818RFC 5246 with
server authentication RFC
6125.
This header parameter is OPTIONAL.
x5tstringString
The x5t (x.509 certificate
thumbprint) header parameter provides a base64url encoded
SHA-1 thumbprint (a.k.a. digest) of the DER encoding of an
X.509 certificate that can be used to match the certificate.
This header parameter is OPTIONAL.
x5carrayArrayOfStrings
The x5c (x.509 certificate
chain) header parameter contains the X.509 public key
certificate or certificate chain corresponding to the key
used to digitally sign the JWS.
The certificate or certificate chain is represented as an
array of certificate values. Each value is a
base64-encoded (not base64url encoded) DER/BER PKIX
certificate value.
The certificate containing the public key of the entity
signing the JWS MUST be the first certificate. This MAY
be followed by additional certificates, with each
subsequent certificate being the one used to certify the
previous one.
The recipient MUST verify the certificate chain according
to and reject the JWS if any
validation failure occurs.
This header parameter is OPTIONAL.
typstringString
The typ (type) header
parameter is used to declare the type of the secured
content.
The typ value is case sensitive.
This header parameter is OPTIONAL.
Additional reserved header parameter names MAY be defined
via the IANA JSON Web Signature Header Parameters registry,
as per . The syntax values used above
are defined as follows:
Syntax NameSyntax DefinitionIntDate
The number of seconds from 1970-01-01T0:0:0Z as measured
in UTC until the desired date/time. See RFC 3339 for details regarding
date/times in general and UTC in particular.
String
Any string value MAY be used.
StringOrURI
Any string value MAY be used but a value containing a ":"
character MUST be a URI as defined in RFC 3986.
URL
A URL as defined in RFC 1738.
ArrayOfStrings
An array of string values.
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 needs to 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 since
an implementation that does not understand a parameter MUST
reject the JWS.
A producer and consumer of a JWS may agree to any header
parameter name that is not a Reserved Name or a Public
Name . 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.
To create a JWS, one MUST perform these steps. The order of
the steps is not significant in cases where there are no
dependencies between the inputs and outputs of the steps.
Create the content to be used as the JWS Payload.
Base64url encode the bytes of the JWS Payload. This
encoding becomes the Encoded JWS Payload.
Create a JWS Header containing the desired set of header
parameters. Note that white space is explicitly allowed
in the representation and no canonicalization need be performed
before encoding.
Base64url encode the bytes of the UTF-8 representation of
the JWS Header to create the Encoded JWS Header.
Compute the JWS Signature in the manner defined for
the particular algorithm being used. The JWS Secured Input
is always the concatenation of the Encoded JWS Header,
a period ('.') character, and the Encoded JWS Payload.
(Note that if the JWS represents a JWT, this corresponds
to the portion of the JWT representation preceding the
second period character.)
The alg (algorithm) header parameter MUST be
present in the JSON Header, with the algorithm value
accurately representing the algorithm used to construct
the JWS Signature.
Base64url encode the representation of the JWS Signature
to create the Encoded JWS Signature.
The three encoded parts, taken together, are the result.
The Compact Serialization of this result is the
concatenation of the Encoded JWS Header, the Encoded JWS
Payload, and the Encoded JWS Signature in that order, with
the three strings being separated by period ('.')
characters.
When validating a JWS, the following steps MUST be taken. The
order of the steps is not significant in cases where there are
no dependencies between the inputs and outputs of the steps.
If any of the listed steps fails, then the JWS MUST be
rejected.
Parse the three parts of the input (which are separated by
period characters when using the JWS Compact
Serialization) into the Encoded JWS Header, the Encoded
JWS Payload, and the Encoded JWS Signature.
The Encoded JWS Header MUST be successfully base64url
decoded following the restriction given in this specification that
no padding characters have been used.
The JWS Header MUST be completely valid
JSON syntax conforming to RFC
4627.
The JWS Header MUST be validated to only include
parameters and values whose syntax and semantics are both
understood and supported.
The Encoded JWS Payload MUST be successfully base64url
decoded following the restriction given in this specification that
no padding characters have been used.
The Encoded JWS Signature MUST be successfully base64url
decoded following the restriction given in this specification that
no padding characters have been used.
The JWS Signature MUST be successfully validated
against the JWS Secured Input (the concatenation of the
Encoded JWS Header, a period ('.') character, and the
Encoded JWS Payload)
in the manner defined for the algorithm being used, which
MUST be accurately represented by the value of the alg (algorithm)
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 the JWS Header
to 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.
Comparisons between JSON strings and other Unicode strings
MUST be performed as specified below:
Remove any JSON applied escaping to produce an array of
Unicode code points.
Unicode Normalization MUST NOT
be applied at any point to either the JSON string or to
the string it is to be compared against.
Comparisons between the two strings MUST be performed as a
Unicode code point to code point equality comparison.
JWS uses cryptographic algorithms to digitally sign or HMAC the contents
of the JWS Header and the JWS Payload. The
JSON Web Algorithms (JWA)
specification enumerates a set of cryptographic algorithms and
identifiers to be used with this specification.
Specifically, Section 3, Table 1 enumerates a set of
alg (algorithm) header parameter values
intended for use this specification.
It also describes the semantics and operations that are
specific to these algorithms and algorithm families.
Public keys employed for digital signing can be identified using the
Header Parameter methods described in or can be distributed
using methods that are outside the scope of this
specification.
This specification calls for:
A new IANA registry entitled "JSON Web Signature Header
Parameters" for reserved header parameter names is defined
in .
Inclusion in the registry is RFC Required in the RFC 5226 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
.
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).
When utilizing TLS to retrieve information, the authority
providing the resource MUST be authenticated and the
information retrieved MUST be free from modification.
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, 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.
The following items remain to be done in this draft:
EDITORIAL: Give each header parameter definition its own
section. This will let them appear in the index, will
give space for examples when needed, and will get rid of
the way-too-cramped tables.
Describe the relationship between the JWS, JWE, and JWT
header parameters. In particular, point out that the set
of alg values defined by each
must be compatible and non-overlapping.
Combine the JWS and JWE alg
parameter registries and possibly also the header parameter
registries.
Clarify the intended use of the typ Header Parameter across the JWS,
JWE, and JWT specifications. Decide whether a registry of
typ values is appropriate.
Add normative text that requires rejecting headers in
which member names occur multiple times, as apparently
this is legal JSON.
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?
Consider whether a key type parameter should also be introduced.
It would be good to have a confirmation method element so
it could be used with holder-of-key.
EDITORIAL:
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.
Write a note in the Security Considerations section about
how x5t (x.509 certificate
thumbprint) should be deprecated because of known problems
with SHA-1.
Add Security Considerations text on timing attacks.
Finish the Security Considerations section.
EDITORIAL:
Add an example in which the payload is not a base64url
encoded JSON object.
Unicode Normalization Formsmarkdavis@google.comken@unicode.orgJSON Web Key (JWK)Microsoftmbj@microsoft.comhttp://self-issued.info/JSON Web Algorithms (JWA)Microsoftmbj@microsoft.comhttp://self-issued.info/JSON Web Token (JWT)Microsoftmbj@microsoft.comhttp://self-issued.info/Googlebalfanz@google.comindependentve7jtb@ve7jtb.comMicrosoftyarong@microsoft.comGooglejpanzer@google.comNomura Research Instituten-sakimura@nri.co.jpFacebookpt@fb.comJSON Web Signature JSON Serialization (JWS-JS)Microsoftmbj@microsoft.comhttp://self-issued.info/independentve7jtb@ve7jtb.comNomura Research Instituten-sakimura@nri.co.jpMagic SignaturesJSON Simple SignindependentNomura Research InstituteCanvas ApplicationsJSON Web Encryption (JWE)Microsoftmbj@microsoft.comhttp://self-issued.info/RTFM, Inc.ekr@rtfm.comCisco Systems, Inc.jhildebr@cisco.com
This section provides several examples of JWSs. While these
examples all represent JSON Web Tokens (JWTs) , the payload can be any base64url encoded
content.
The following example JWS Header declares that the
data structure is a JSON Web Token (JWT)
and the JWS Secured Input is secured using
the HMAC SHA-256 algorithm.
The following byte array contains the UTF-8 characters for
the JWS 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 Header value:
The JWS Payload used in this example
follows. (Note that the payload can be any base64url
encoded content, and need not be a base64url encoded JSON
object.)
The following byte array contains the UTF-8 characters
for the JWS 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 Payload value
(with line breaks for display purposes only):
Concatenating the Encoded JWS Header, a period character,
and the Encoded JWS Payload yields this JWS Secured Input
value (with line breaks for display purposes only):
The UTF-8 representation of the JWS Secured 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 Secured 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 JWS Signature value:
Decoding the JWS first requires removing the base64url
encoding from the Encoded JWS Header, the Encoded JWS Payload,
and the Encoded JWS Signature. We base64url decode
the inputs and
turn them into the corresponding byte arrays. We
translate the header input byte array containing UTF-8
encoded characters into the JWS Header
string.
Next we validate the decoded results. Since the alg
parameter in the header is "HS256", we validate the HMAC
SHA-256 value contained in the JWS Signature. If
any of the validation steps fail, the JWS MUST be
rejected.
First, we validate that the JWS Header
string is legal JSON.
To validate the HMAC value, we repeat the previous process
of using the correct key and the UTF-8 representation of
the JWS Secured Input as input to a SHA-256 HMAC function
and then taking the output and determining if it matches
the JWS Signature. If it matches exactly,
the HMAC has been validated.
The JWS Header in 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 algorithm employed.) The
JWS Header used is:
The following byte array contains the UTF-8 characters for
the JWS 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 Header value:
The JWS Payload used in this example, which
follows, is the same as in the previous example. Since
the Encoded JWS Payload will therefore be the same, its
computation is not repeated here.
Concatenating the Encoded JWS Header, a period character,
and the Encoded JWS Payload yields this JWS Secured Input
value (with line breaks for display purposes only):
The UTF-8 representation of the JWS Secured 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 NameValuen
[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 Secured Input as
inputs. The result of the digital signature is a byte array S,
which represents a big endian integer. In this example, S
is:
Result NameValueS
[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 digital signature produces this value for
the Encoded JWS Signature
(with line breaks for display purposes only):
Decoding the JWS from this example requires processing the
Encoded JWS Header and Encoded JWS Payload exactly as
done in the first example.
Since the alg parameter in the header is "RS256", we
validate the RSA SHA-256 digital signature contained in the JWS Signature. If any of the validation steps fail, the
JWS MUST be rejected.
First, we validate that the JWS Header
string is legal JSON.
Validating the JWS Signature is a little different
from the previous example. First, we base64url decode the
Encoded JWS Signature to produce a digital signature S to check. We
then pass (n, e), S and the UTF-8 representation of the
JWS Secured Input to an RSA signature verifier that has
been configured to use the SHA-256 hash function.
The JWS Header for this example differs from
the previous example because a different algorithm is
being used. The JWS Header used is:
The following byte array contains the UTF-8 characters for
the JWS 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 Header value:
The JWS Payload used in this example, which
follows, is the same as in the previous examples. Since
the Encoded JWS Payload will therefore be the same, its
computation is not repeated here.
Concatenating the Encoded JWS Header, a period character,
and the Encoded JWS Payload yields this JWS Secured Input
value (with line breaks for display purposes only):
The UTF-8 representation of the JWS Secured 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 NameValuex
[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 Secured Input as inputs. The result of the
digital 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 NameValueR
[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 JWS Signature
(with line breaks for display purposes only):
Decoding the JWS from this example requires processing the
Encoded JWS Header and Encoded JWS Payload exactly as
done in the first example.
Since the alg parameter in the header is "ES256", we
validate the ECDSA P-256 SHA-256 digital signature contained in
the JWS Signature. If any of the validation steps
fail, the JWS MUST be rejected.
First, we validate that the JWS Header
string is legal JSON.
Validating the JWS Signature is a little different
from the first example. First, we base64url decode the Encoded JWS Signature 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 Secured 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 Section 3.3 of the
JSON Web Algorithms (JWA) specification, the
use of the k value in ECDSA means that we cannot validate
the correctness of the digital signature in the same way we
validated the correctness of the HMAC. Instead,
implementations MUST use an ECDSA validator to validate
the digital signature.
The following example JWS Header declares that the
encoded object is a Plaintext JWS:
Base64url encoding the bytes of the UTF-8 representation of
the JWS Header yields this Encoded JWS Header:
The JWS Payload used in this example, which
follows, is the same as in the previous examples. Since
the Encoded JWS Payload will therefore be the same, its
computation is not repeated here.
The Encoded JWS Signature is the empty string.
Concatenating these parts in the order
Header.Payload.Signature with period characters between the
parts yields this complete JWS (with line breaks for
display purposes only):
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.
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.
Solutions for signing JSON content were previously explored by
Magic Signatures, JSON Simple Sign, and Canvas Applications, all of which
influenced this draft.
Dirk Balfanz, Yaron Y. Goland, John Panzer, and Paul Tarjan
all made significant contributions to the design of this
specification.
-01
Moved definition of Plaintext JWSs (using "alg":"none")
here from the JWT specification since this functionality is
likely to be useful in more contexts that just for JWTs.
Added jpk and x5c header parameters for including
JWK public keys and X.509 certificate chains directly in
the header.
Clarified that this specification is defining the JWS
Compact Serialization. Referenced the new JWS-JS spec,
which defines the JWS JSON Serialization.
Added text "New header parameters should be introduced
sparingly since an implementation that does not understand
a parameter MUST reject the JWS".
Clarified that the order of the creation and validation
steps is not significant in cases where there are no
dependencies between the inputs and outputs of the steps.
Changed "no canonicalization is performed" to "no
canonicalization need be performed".
Corrected the Magic Signatures reference.
Made other editorial improvements suggested by JOSE
working group participants.
-00
Created the initial IETF draft based upon
draft-jones-json-web-signature-04 with no normative
changes.
Changed terminology to no longer call both digital
signatures and HMACs "signatures".