A JavaScript implementation of the JSON Object Signing and Encryption (JOSE) for current web browsers and node.js-based servers. This library implements (wherever possible) all algorithms, formats, and options in JWS, JWE, JWK, and JWA and uses native cryptographic support (WebCrypto API or node.js' "crypto" module) where feasible.
To install the latest from NPM:
npm install node-jose
Or to install a specific release:
npm install node-jose@0.3.0
Alternatively, the latest unpublished code can be installed directly from the repository:
npm install git+https://github.com/cisco/node-jose.git
Require the library as normal:
var jose = require('node-jose');
This library uses Promises for nearly every operation.
This library supports Browserify and Webpack. To use in a web browser, require('node-jose')
and bundle with the rest of your app.
The content to be signed/encrypted -- or returned from being verified/decrypted -- are Buffer objects.
The jose.JWK
namespace deals with JWK and JWK-sets.
jose.JWK.Key
is a logical representation of a JWK, and is the "raw" entry point for various cryptographic operations (e.g., sign, verify, encrypt, decrypt).jose.JWK.KeyStore
represents a collection of Keys.Creating a JWE or JWS ultimately require one or more explicit Key objects.
Processing a JWE or JWS relies on a KeyStore.
To create an empty keystore:
keystore = jose.JWK.createKeyStore();
To import a JWK-set as a keystore:
// {input} is a String or JSON object representing the JWK-set jose.JWK.asKeyStore(input). then(function(result) { // {result} is a jose.JWK.KeyStore keystore = result; });
To export the public keys of a keystore as a JWK-set:
output = keystore.toJSON();
To export all the keys of a keystore:
output = keystore.toJSON(true);
To retrieve a key from a keystore:
// by 'kid' key = keystore.get(kid);
This retrieves the first key that matches the given {kid}. If multiple keys have the same {kid}, you can further narrow what to retrieve:
// ... and by 'kty' key = keystore.get(kid, { kty: 'RSA' }); // ... and by 'use' key = keystore.get(kid, { use: 'enc' }); // ... and by 'alg' key = keystore.get(kid, { use: 'RSA-OAEP' }); // ... and by 'kty' and 'use' key = keystore.get(kid, { kty: 'RSA', use: 'enc' }); // same as above, but with a single {props} argument key = keystore.get({ kid: kid, kty: 'RSA', use: 'enc' });
To retrieve all the keys from a keystore:
everything = keystore.all();
all()
can be filtered much like get()
:
// filter by 'kid' everything = keystore.all({ kid: kid }); // filter by 'kty' everything = keystore.all({ kty: 'RSA' }); // filter by 'use' everything = keystore.all({ use: 'enc' }); // filter by 'alg' everything = keystore.all({ alg: 'RSA-OAEP' }); // filter by 'kid' + 'kty' + 'alg' everything = keystore.all({ kid: kid, kty: 'RSA', alg: 'RSA-OAEP' });
To import an existing Key (as a JSON object or Key instance):
// input is either a: // * jose.JWK.Key to copy from; or // * JSON object representing a JWK; or keystore.add(input). then(function(result) { // {result} is a jose.JWK.Key key = result; });
To import and existing Key from a PEM or DER:
// input is either a: // * String serialization of a JSON JWK/(base64-encoded) PEM/(binary-encoded) DER // * Buffer of a JSON JWK/(base64-encoded) PEM/(binary-encoded) DER // form is either a: // * "json" for a JSON stringified JWK // * "private" for a DER encoded 'raw' private key // * "pkcs8" for a DER encoded (unencrypted!) PKCS8 private key // * "public" for a DER encoded SPKI public key (alternate to 'spki') // * "spki" for a DER encoded SPKI public key // * "pkix" for a DER encoded PKIX X.509 certificate // * "x509" for a DER encoded PKIX X.509 certificate // * "pem" for a PEM encoded of PKCS8 / SPKI / PKIX keystore.add(input, form). then(function(result) { // {result} is a jose.JWK.Key });
To generate a new Key:
// first argument is the key type (kty) // second is the key size (in bits) or named curve ('crv') for "EC" keystore.generate("oct", 256). then(function(result) { // {result} is a jose.JWK.Key key = result; }); // ... with properties var props = { kid: 'gBdaS-G8RLax2qgObTD94w', alg: 'A256GCM', use: 'enc' }; keystore.generate("oct", 256, props). then(function(result) { // {result} is a jose.JWK.Key key = result; });
To remove a Key from its Keystore:
keystore.remove(key); // NOTE: key.keystore does not change!!
To create a single "stand alone" key:
jose.JWK.createKey("oct", 256, { alg: "A256GCM" }). then(function(result) { // {result} is a jose.JWK.Key // {result.keystore} is a unique jose.JWK.KeyStore });
To import a single Key:
// where input is either a: // * jose.JWK.Key instance // * JSON Object representation of a JWK jose.JWK.asKey(input). then(function(result) { // {result} is a jose.JWK.Key // {result.keystore} is a unique jose.JWK.KeyStore }); // where input is either a: // * String serialization of a JSON JWK/(base64-encoded) PEM/(binary-encoded) DER // * Buffer of a JSON JWK/(base64-encoded) PEM/(binary-encoded) DER // form is either a: // * "json" for a JSON stringified JWK // * "pkcs8" for a DER encoded (unencrypted!) PKCS8 private key // * "spki" for a DER encoded SPKI public key // * "pkix" for a DER encoded PKIX X.509 certificate // * "x509" for a DER encoded PKIX X.509 certificate // * "pem" for a PEM encoded of PKCS8 / SPKI / PKIX jose.JWK.asKey(input, form). then(function(result) { // {result} is a jose.JWK.Key // {result.keystore} is a unique jose.JWK.KeyStore });
To export the public portion of a Key as a JWK:
var output = key.toJSON();
To export the public and private portions of a Key:
var output = key.toJSON(true);
To get or calculate a RFC 7638 thumbprint for a key:
// where hash is a supported algorithm, currently one of: // * SHA-1 // * SHA-256 // * SHA-384 // * SHA-512 key.thumbprint(hash). then(function(print) { // {print} is a Buffer containing the thumbprint binary value });
When importing or generating a key that does not have a "kid" defined, a
"SHA-256" thumbprint is calculated and used as the "kid".
When signing content, the key is expected to meet one of the following:
"kty":"oct"
)"kty":"EC"
or "kty":"RSA"
) key pairWhen verifying content, the key is expected to meet one of the following:
"kty":"oct"
)"kty":"EC"
or "kty":"RSA"
) key pairAt its simplest, to create a JWS:
// {input} is a Buffer jose.JWS.createSign(key). update(input). final(). then(function(result) { // {result} is a JSON object -- JWS using the JSON General Serialization });
The JWS is signed using the preferred algorithm appropriate for the given Key. The preferred algorithm is the first item returned by key.algorithms("sign")
.
To create a JWS using another serialization format:
jose.JWS.createSign({ format: 'flattened' }, key). update(input). final(). then(function(result) { // {result} is a JSON object -- JWS using the JSON Flattened Serialization }); jose.JWS.createSign({ format: 'compact' }, key). update(input). final(). then(function(result) { // {result} is a String -- JWS using the Compact Serialization });
To create a JWS using a specific algorithm:
jose.JWS.createSign({ fields: { alg: 'PS256' } }, key). update(input). final(). then(function(result) { // .... });
To create a JWS for a specified content type:
jose.JWS.createSign({ fields: { cty: 'jwk+json' } }, key). update(input). final(). then(function(result) { // .... });
To create a JWS from String content:
jose.JWS.createSign(key). update(input, "utf8"). final(). then(function(result) { // .... });
To create a JWS with multiple signatures:
// {keys} is an Array of jose.JWK.Key instances jose.JWS.createSign(keys). update(input). final(). then(function(result) { // .... });
To verify a JWS, and retrieve the payload:
jose.JWS.createVerify(keystore). verify(input). then(function(result) { // {result} is a Object with: // * header: the combined 'protected' and 'unprotected' header members // * payload: Buffer of the signed content // * signature: Buffer of the verified signature // * key: The key used to verify the signature });
To verify using an implied Key:
// {key} can be: // * jose.JWK.Key // * JSON object representing a JWK jose.JWS.createVerify(key). verify(input). then(function(result) { // ... });
To verify using a key embedded in the JWS:
jose.JWS.createVerify(). verify(input, { allowEmbeddedKey: true }). then(function(result) { // ... });
Alternatively, a cached createVerify()
can be configured to allow an embedded key:
var verifier = jose.JWS.createVerify({ allowEmbeddedKey: true }); verifier.verify(input). then(function(result) { // ... });
The key can be embedded using either 'jwk' or 'x5c', and can be located in either the JWS Unprotected Header or JWS Protected Header.
NOTE: verify()
will use the embedded key (if found and permitted) instead of any other key.
To restrict what signature algorithms are allowed when verifying, add the algorithms
member to the options
Object. The algorithms
member is either a string or an array of strings, where the string value(s) can be one of the following:
"*"
: accept all supported algorithms<alg name>
(e.g., "PS256"
): accept the specific algorithm (can have a single '*' to match a range of algorithms)!<alg name>
(e.g., "!RS256"
): do not accept the specific algorithm (can have a single '*' to match a range of algorithms)The negation is intended to be used with the wildcard accept string, and disallow takes precedence over allowed.
To only accept RSA-PSS sigatures:
var opts = { algorithms: ["PS*"] }; jose.JWS.createVerify(key, opts). verify(input). then(function(result) { // ... });
To accept any algorithm, but disallow HMAC-based signatures:
var opts = { algorithms: ["*", "!HS*"] }; jose.JWS.createVerify(key, opts). verify(input). then(function(result) { // ... });
crit
Header MembersTo accept 'crit' field members, add the handlers
member to the options Object. The handlers
member is itself an Object, where its member names are the crit
header member, and the value is one of:
Function
: takes the JWE decrypt output (just prior to decrypting) and returns a Promise for the processing of the member.Object
: An object with the following Function
members:
NOTE If the handler function returns a promise, the fulfilled value is ignored. It is expected these handler functions will modify the provided value directly.
To perform additional (pre-verify) processing on a crit
header member:
var opts = { handlers: { "exp": function(jws) { // {jws} is the JWS verify output, pre-verification jws.header.exp = new Date(jws.header.exp); } } }; jose.JWS.createVerify(key, opts). verify(input). then(function(result) { // ... });
To perform additional (post-verify) processing on a crit
header member:
var opts = { handlers: { "exp": { complete: function(jws) { // {jws} is the JWS verify output, post-verification jws.header.exp = new Date(jws.header.exp); } } } }; jose.JWS.createVerify(key, opts). verify(input). then(function(result) { // ... });
When encrypting content, the key is expected to meet one of the following:
"kty":"oct"
)"kty":"EC"
or "kty":"RSA"
) key pairWhen decrypting content, the key is expected to meet one of the following:
"kty":"oct"
)"kty":"EC"
or "kty":"RSA"
) key pairAt its simplest, to create a JWE:
// {input} is a Buffer jose.JWE.createEncrypt(key). update(input). final(). then(function(result) { // {result} is a JSON Object -- JWE using the JSON General Serialization });
How the JWE content is encrypted depends on the provided Key.
key.algorithms("encrypt")
.key.algorithms("wrap")
.To create a JWE using a different serialization format:
jose.JWE.createEncrypt({ format: 'compact' }, key). update(input). final(). then(function(result) { // {result} is a String -- JWE using the Compact Serialization }); jose.JWE.createEncrypt({ format: 'flattened' }, key). update(input). final(). then(function(result) { // {result} is a JSON Object -- JWE using the JSON Flattened Serialization });
To create a JWE and compressing the content before encrypting:
jose.JWE.createEncrypt({ zip: true }, key). update(input). final(). then(function(result) { // .... });
To create a JWE for a specific content type:
jose.JWE.createEncrypt({ fields: { cty : 'jwk+json' } }, key). update(input). final(). then(function(result) { // .... });
To create a JWE with multiple recipients:
// {keys} is an Array of jose.JWK.Key instances jose.JWE.createEncrypt(keys). update(input). final(). then(function(result) { // .... });
To decrypt a JWE, and retrieve the plaintext:
jose.JWE.createDecrypt(keystore). decrypt(input). then(function(result) { // {result} is a Object with: // * header: the combined 'protected' and 'unprotected' header members // * protected: an array of the member names from the "protected" member // * key: Key used to decrypt // * payload: Buffer of the decrypted content // * plaintext: Buffer of the decrypted content (alternate) });
To decrypt a JWE using an implied key:
jose.JWE.createDecrypt(key). decrypt(input). then(function(result) { // .... });
To restrict what encryption algorithms are allowed when verifying, add the algorithms
member to the options
Object. The algorithms
member is either a string or an array of strings, where the string value(s) can be one of the following:
"*"
: accept all supported algorithms<alg name>
(e.g., "A128KW"
): accept the specific algorithm (can have a single '*' to match a range of similar algorithms)!<alg name>
(e.g., "!RSA1_5"
): do not accept the specific algorithm (can have a single '*' to match a range of similar algorithms)The negation is intended to be used with the wildcard accept string, and disallow takes precedence over allowed.
To only accept "dir" and AES-GCM encryption:
var opts = { algorithms: ["dir", "A*GCM"] }; jose.JWE.createDecrypt(key, opts). decrypt(input). then(function(result) { // ... });
To accept any algorithm, but disallow RSA-based encryption:
var opts = { algorithms: ["*", "!RSA*"] }; jose.JWS.createVerify(key, opts). verify(input). then(function(result) { // ... });
crit
Header MembersTo accept 'crit' field members, add the handlers
member to the options Object. The handlers
member is itself an Object, where its member names are the crit
header member, and the value is one of:
Function
: takes the JWE decrypt output (just prior to decrypting) and returns a Promise for the processing of the member.Object
: An object with the following Function
members:
NOTE If the handler function returns a promise, the fulfilled value is ignored. It is expected these handler functions will modify the provided value directly.
To perform additional (pre-decrypt) processing on a crit
header member:
var opts = { handlers: { "exp": function(jwe) { // {jwe} is the JWE decrypt output, pre-decryption jwe.header.exp = new Date(jwe.header.exp); } } }; jose.JWE.createDecrypt(key, opts). decrypt(input). then(function(result) { // ... });
To perform additional (post-decrypt) processing on a crit
header member:
var opts = { handlers: { "exp": { complete: function(jwe) { // {jwe} is the JWE decrypt output, post-decryption jwe.header.exp = new Date(jwe.header.exp); } } } }; jose.JWE.createDecrypt(key, opts). decrypt(input). then(function(result) { // ... });
To convert a Typed Array, ArrayBuffer, or Array of Numbers to a Buffer:
buff = jose.util.asBuffer(input);
This exposes urlsafe-base64's encode
and decode
methods as encode
and decode
(respectively).
To convert from a Buffer to a base64uri-encoded String:
var output = jose.util.base64url.encode(input);
To convert a String to a base64uri-encoded String:
// explicit encoding output = jose.util.base64url.encode(input, "utf8"); // implied "utf8" encoding output = jose.util.base64url.encode(input);
To convert a base64uri-encoded String to a Buffer:
var output = jose.util.base64url.decode(input);
To generate a Buffer of octets, regardless of platform:
// argument is size (in bytes) var rnd = jose.util.randomBytes(32);
This function uses:
crypto.randomBytes()
on node.jscrypto.getRandomValues()
on modern browsersOwner
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