jsonwebtoken-ed25519
v8.3.1-rc.0
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JSON Web Token implementation (symmetric and asymmetric)
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jsonwebtoken-ed25519
An implementation of JSON Web Tokens.
This was developed against draft-ietf-oauth-json-web-token-08
. It makes use of node-jws
Fork Changes
This package is a fork of jsonwebtoken with two major changes:
verify()
must always be called with a specific algorithm name.
It will not trust the algorithm that is packed inside the token (anything in the token should not be trusted before verification, including the verification-algorithm). It will also not try to guess the algorithm based on the textual format of the secret/public-key. Those approaches may lead to critical vulnerabilities.
For simplicity, you may also specify the algorithm in together with the key in a single object. i.e.
verify(token, { key: "shhh", algorithm: "HS512"})
is equivalent to
verify(token, "shhh", { algorithm: "HS512"})
This allows you to store { key: "shhh", algorithm: "HS512"}
in a single constant, and use it easily.
Specifying multiple algorithms (via options.algorithms
) is also not allowed.
Signing without an algorithm name is still allowed, and uses HS256 like before.
Ed25519
Support for signing and verifying Ed25519 using the ed25519 package. Keys may be specified as Buffers, base64 strings or hex strings (not pem files!).
You may create key-pairs by installing the ed25519 package and calling:
require('ed25519').MakeKeypair(crypto.randomBytes(32))
Ed25519 is not specified in the jwt draft. The token alg value (in the jwt header) will be "Ed25519".
Install
$ npm install jsonwebtoken-ed25519
Migration notes
Usage
jwt.sign(payload, secretOrPrivateKey, [options, callback])
(Asynchronous) If a callback is supplied, the callback is called with the err
or the JWT.
(Synchronous) Returns the JsonWebToken as string
payload
could be an object literal, buffer or string representing valid JSON. Please note that exp
or any other claim is only set if the payload is an object literal. Buffer or string payloads are not checked for JSON validity.
secretOrPrivateKey
is a string, buffer, or object containing either the secret for HMAC algorithms or the PEM
encoded private key for RSA and ECDSA. In case of a private key with passphrase an object { key, passphrase }
can be used (based on crypto documentation), in this case be sure you pass the algorithm
option.
options
:
algorithm
(default:HS256
)expiresIn
: expressed in seconds or a string describing a time span zeit/ms. Eg:60
,"2 days"
,"10h"
,"7d"
. A numeric value is interpreted as a seconds count. If you use a string be sure you provide the time units (days, hours, etc), otherwise milliseconds unit is used by default ("120"
is equal to"120ms"
).notBefore
: expressed in seconds or a string describing a time span zeit/ms. Eg:60
,"2 days"
,"10h"
,"7d"
. A numeric value is interpreted as a seconds count. If you use a string be sure you provide the time units (days, hours, etc), otherwise milliseconds unit is used by default ("120"
is equal to"120ms"
).audience
issuer
jwtid
subject
noTimestamp
header
keyid
mutatePayload
: if true, the sign function will modify the payload object directly. This is useful if you need a raw reference to the payload after claims have been applied to it but before it has been encoded into a token.
If payload
is not a buffer or a string, it will be coerced into a string using JSON.stringify
.
There are no default values for expiresIn
, notBefore
, audience
, subject
, issuer
. These claims can also be provided in the payload directly with exp
, nbf
, aud
, sub
and iss
respectively, but you can't include in both places.
Remember that exp
, nbf
and iat
are NumericDate, see related Token Expiration (exp claim)
The header can be customized via the options.header
object.
Generated jwts will include an iat
(issued at) claim by default unless noTimestamp
is specified. If iat
is inserted in the payload, it will be used instead of the real timestamp for calculating other things like exp
given a timespan in options.expiresIn
.
Sign with default (HMAC SHA256)
var jwt = require('jsonwebtoken');
var token = jwt.sign({ foo: 'bar' }, 'shhhhh');
Sign with RSA SHA256
// sign with RSA SHA256
var cert = fs.readFileSync('private.key');
var token = jwt.sign({ foo: 'bar' }, cert, { algorithm: 'RS256'});
Sign asynchronously
jwt.sign({ foo: 'bar' }, cert, { algorithm: 'RS256' }, function(err, token) {
console.log(token);
});
Backdate a jwt 30 seconds
var older_token = jwt.sign({ foo: 'bar', iat: Math.floor(Date.now() / 1000) - 30 }, 'shhhhh');
Token Expiration (exp claim)
The standard for JWT defines an exp
claim for expiration. The expiration is represented as a NumericDate:
A JSON numeric value representing the number of seconds from 1970-01-01T00:00:00Z UTC until the specified UTC date/time, ignoring leap seconds. This is equivalent to the IEEE Std 1003.1, 2013 Edition [POSIX.1] definition "Seconds Since the Epoch", in which each day is accounted for by exactly 86400 seconds, other than that non-integer values can be represented. See RFC 3339 [RFC3339] for details regarding date/times in general and UTC in particular.
This means that the exp
field should contain the number of seconds since the epoch.
Signing a token with 1 hour of expiration:
jwt.sign({
exp: Math.floor(Date.now() / 1000) + (60 * 60),
data: 'foobar'
}, 'secret');
Another way to generate a token like this with this library is:
jwt.sign({
data: 'foobar'
}, 'secret', { expiresIn: 60 * 60 });
//or even better:
jwt.sign({
data: 'foobar'
}, 'secret', { expiresIn: '1h' });
jwt.verify(token, secretOrPublicKey, [options, callback])
(Asynchronous) If a callback is supplied, function acts asynchronously. The callback is called with the decoded payload if the signature is valid and optional expiration, audience, or issuer are valid. If not, it will be called with the error.
(Synchronous) If a callback is not supplied, function acts synchronously. Returns the payload decoded if the signature is valid and optional expiration, audience, or issuer are valid. If not, it will throw the error.
token
is the JsonWebToken string
secretOrPublicKey
is a string or buffer containing either the secret for HMAC algorithms, or the PEM
encoded public key for RSA and ECDSA.
If jwt.verify
is called asynchronous, secretOrPublicKey
can be a function that should fetch the secret or public key. See below for a detailed example
As mentioned in this comment, there are other libraries that expect base64 encoded secrets (random bytes encoded using base64), if that is your case you can pass Buffer.from(secret, 'base64')
, by doing this the secret will be decoded using base64 and the token verification will use the original random bytes.
options
algorithms
: List of strings with the names of the allowed algorithms. For instance,["HS256", "HS384"]
.audience
: if you want to check audience (aud
), provide a value here. The audience can be checked against a string, a regular expression or a list of strings and/or regular expressions. Eg:"urn:foo"
,/urn:f[o]{2}/
,[/urn:f[o]{2}/, "urn:bar"]
issuer
(optional): string or array of strings of valid values for theiss
field.ignoreExpiration
: iftrue
do not validate the expiration of the token.ignoreNotBefore
...subject
: if you want to check subject (sub
), provide a value hereclockTolerance
: number of seconds to tolerate when checking thenbf
andexp
claims, to deal with small clock differences among different serversmaxAge
: the maximum allowed age for tokens to still be valid. It is expressed in seconds or a string describing a time span zeit/ms. Eg:1000
,"2 days"
,"10h"
,"7d"
. A numeric value is interpreted as a seconds count. If you use a string be sure you provide the time units (days, hours, etc), otherwise milliseconds unit is used by default ("120"
is equal to"120ms"
).clockTimestamp
: the time in seconds that should be used as the current time for all necessary comparisons.
// verify a token symmetric - synchronous
var decoded = jwt.verify(token, 'shhhhh', { algorithm: "HS256" });
console.log(decoded.foo) // bar
// verify a token symmetric
jwt.verify(token, 'shhhhh', { algorithm: "HS256" }, function(err, decoded) {
console.log(decoded.foo) // bar
});
// invalid token - synchronous
try {
var decoded = jwt.verify(token, 'wrong-secret', { algorithm: "HS256" });
} catch(err) {
// err
}
// invalid token
jwt.verify(token, 'wrong-secret', { algorithm: "HS256" }, function(err, decoded) {
// err
// decoded undefined
});
// verify a token asymmetric
var cert = fs.readFileSync('public.pem'); // get public key
jwt.verify(token, cert, { algorithm: "RS256" }, function(err, decoded) {
console.log(decoded.foo) // bar
});
// verify audience
var cert = fs.readFileSync('public.pem'); // get public key
jwt.verify(token, cert, { audience: 'urn:foo', algorithm: "RS256" }, function(err, decoded) {
// if audience mismatch, err == invalid audience
});
// verify issuer
var cert = fs.readFileSync('public.pem'); // get public key
jwt.verify(token, cert, { audience: 'urn:foo', issuer: 'urn:issuer', algorithm: "RS256" }, function(err, decoded) {
// if issuer mismatch, err == invalid issuer
});
// verify jwt id
var cert = fs.readFileSync('public.pem'); // get public key
jwt.verify(token, cert, { audience: 'urn:foo', issuer: 'urn:issuer', jwtid: 'jwtid', algorithm: "RS256" }, function(err, decoded) {
// if jwt id mismatch, err == invalid jwt id
});
// verify subject
var cert = fs.readFileSync('public.pem'); // get public key
jwt.verify(token, cert, { audience: 'urn:foo', issuer: 'urn:issuer', jwtid: 'jwtid', subject: 'subject', algorithm: "RS256" }, function(err, decoded) {
// if subject mismatch, err == invalid subject
});
// alg mismatch
var cert = fs.readFileSync('public.pem'); // get public key
jwt.verify(token, cert, { algorithm: 'RS256' }, function (err, payload) {
// if token alg != RS256, err == invalid signature
});
// Verify using getKey callback
// Example uses https://github.com/auth0/node-jwks-rsa as a way to fetch the keys.
var jwksClient = require('jwks-rsa');
var client = jwksClient({
jwksUri: 'https://sandrino.auth0.com/.well-known/jwks.json'
});
function getKey(header, callback){
client.getSigningKey(header.kid, function(err, key) {
var signingKey = key.publicKey || key.rsaPublicKey;
callback(null, signingKey);
});
}
jwt.verify(token, getKey, options, function(err, decoded) {
console.log(decoded.foo) // bar
});
jwt.decode(token [, options])
(Synchronous) Returns the decoded payload without verifying if the signature is valid.
Warning: This will not verify whether the signature is valid. You should not use this for untrusted messages. You most likely want to use jwt.verify
instead.
token
is the JsonWebToken string
options
:
json
: force JSON.parse on the payload even if the header doesn't contain"typ":"JWT"
.complete
: return an object with the decoded payload and header.
Example
// get the decoded payload ignoring signature, no secretOrPrivateKey needed
var decoded = jwt.decode(token);
// get the decoded payload and header
var decoded = jwt.decode(token, {complete: true});
console.log(decoded.header);
console.log(decoded.payload)
Errors & Codes
Possible thrown errors during verification. Error is the first argument of the verification callback.
TokenExpiredError
Thrown error if the token is expired.
Error object:
- name: 'TokenExpiredError'
- message: 'jwt expired'
- expiredAt: [ExpDate]
jwt.verify(token, 'shhhhh', { algorithm: "HS256" }, function(err, decoded) {
if (err) {
/*
err = {
name: 'TokenExpiredError',
message: 'jwt expired',
expiredAt: 1408621000
}
*/
}
});
JsonWebTokenError
Error object:
- name: 'JsonWebTokenError'
- message:
- 'jwt malformed'
- 'jwt signature is required'
- 'invalid signature'
- 'jwt audience invalid. expected: [OPTIONS AUDIENCE]'
- 'jwt issuer invalid. expected: [OPTIONS ISSUER]'
- 'jwt id invalid. expected: [OPTIONS JWT ID]'
- 'jwt subject invalid. expected: [OPTIONS SUBJECT]'
jwt.verify(token, 'shhhhh', { algorithm: "HS256" }, function(err, decoded) {
if (err) {
/*
err = {
name: 'JsonWebTokenError',
message: 'jwt malformed'
}
*/
}
});
Algorithms supported
Array of supported algorithms. The following algorithms are currently supported.
alg Parameter Value | Digital Signature or MAC Algorithm ----------------|---------------------------- HS256 | HMAC using SHA-256 hash algorithm HS384 | HMAC using SHA-384 hash algorithm HS512 | HMAC using SHA-512 hash algorithm RS256 | RSASSA using SHA-256 hash algorithm RS384 | RSASSA using SHA-384 hash algorithm RS512 | RSASSA 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 none | No digital signature or MAC value included
Refreshing JWTs
First of all, we recommend to think carefully if auto-refreshing a JWT will not introduce any vulnerability in your system.
We are not comfortable including this as part of the library, however, you can take a look to this example to show how this could be accomplished. Apart from that example there are an issue and a pull request to get more knowledge about this topic.
TODO
- X.509 certificate chain is not checked
Issue Reporting
If you have found a bug or if you have a feature request, please report them at this repository issues section. Please do not report security vulnerabilities on the public GitHub issue tracker. The Responsible Disclosure Program details the procedure for disclosing security issues.
Author
License
This project is licensed under the MIT license. See the LICENSE file for more info.