openid-client is a server side OpenID Relying Party (RP, Client) implementation for Node.js runtime, supports passport.
The following client/RP features from OpenID Connect/OAuth2.0 specifications are implemented by openid-client.
- OpenID Connect Core 1.0
- Authorization Callback
- Authorization Code Flow
- Implicit Flow
- Hybrid Flow
- UserInfo Request
- Fetching Distributed Claims
- Unpacking Aggregated Claims
- Offline Access / Refresh Token Grant
- Client Credentials Grant
- Client Authentication
- none
- client_secret_basic
- client_secret_post
- client_secret_jwt
- private_key_jwt
- Consuming Self-Issued OpenID Provider ID Token response
- Authorization Callback
- RFC8414 - OAuth 2.0 Authorization Server Metadata and OpenID Connect Discovery 1.0
- Discovery of OpenID Provider (Issuer) Metadata
- Discovery of OpenID Provider (Issuer) Metadata via user provided inputs (via webfinger)
- OpenID Connect Dynamic Client Registration 1.0
- Dynamic Client Registration request
- Client initialization via registration client uri
- RFC7009 - OAuth 2.0 Token revocation
- Client Authenticated request to token revocation
- RFC7662 - OAuth 2.0 Token introspection
- Client Authenticated request to token introspection
- RFC8628 - OAuth 2.0 Device Authorization Grant (Device Flow)
- draft-ietf-oauth-mtls - OAuth 2.0 Mutual TLS Client Authentication and Certificate-Bound Access Tokens
- Mutual TLS Client Certificate-Bound Access Tokens
- Metadata for Mutual TLS Endpoint Aliases
- Client Authentication
- tls_client_auth
- self_signed_tls_client_auth
- OpenID Connect Session Management 1.0 - draft 28
- RP-Initiated Logout
Filip Skokan has certified that oidc-provider
conforms to the following profiles of the OpenID Connect™ protocol
If you want to quickly add OpenID Connect authentication to Node.js apps, feel free to check out Auth0's Node.js SDK and free plan at auth0.com/overview.
If you or your business use openid-client, please consider becoming a sponsor so I can continue maintaining it and adding new features carefree.
The library exposes what are essentially steps necessary to be done by a relying party consuming OpenID Connect Authorization Server responses or wrappers around requests to its endpoints. Aside from a generic OpenID Connect passport strategy it does not expose neither express or koa middlewares. Those can however be built using the exposed API.
Node.js version >=12.0.0 is recommended, but ^10.13.0 lts/dubnium is also supported.
npm install openid-client
Discover an Issuer configuration using its published .well-known endpoints
const { Issuer } = require('openid-client');
Issuer.discover('https://accounts.google.com') // => Promise
.then(function (googleIssuer) {
console.log('Discovered issuer %s %O', googleIssuer.issuer, googleIssuer.metadata);
});
Authorization Code flow is for obtaining Access Tokens (and optionally Refresh Tokens) to use with
third party APIs securely as well as Refresh Tokens. In this quick start your application also uses
PKCE instead of state
parameter for CSRF protection.
Create a Client instance for that issuer's authorization server intended for Authorization Code flow.
See the documentation for full API details.
const client = new googleIssuer.Client({
client_id: 'zELcpfANLqY7Oqas',
client_secret: 'TQV5U29k1gHibH5bx1layBo0OSAvAbRT3UYW3EWrSYBB5swxjVfWUa1BS8lqzxG/0v9wruMcrGadany3',
redirect_uris: ['http://localhost:3000/cb'],
response_types: ['code'],
// id_token_signed_response_alg (default "RS256")
// token_endpoint_auth_method (default "client_secret_basic")
}); // => Client
When you want to have your end-users authorize you need to send them to the issuer's
authorization_endpoint
. Consult the web framework of your choice on how to redirect but here's how
to get the authorization endpoint's URL with parameters already encoded in the query to redirect
to.
const { generators } = require('openid-client');
const code_verifier = generators.codeVerifier();
// store the code_verifier in your framework's session mechanism, if it is a cookie based solution
// it should be httpOnly (not readable by javascript) and encrypted.
const code_challenge = generators.codeChallenge(code_verifier);
client.authorizationUrl({
scope: 'openid email profile',
resource: 'https://my.api.example.com/resource/32178',
code_challenge,
code_challenge_method: 'S256',
});
When end-users are redirected back to your redirect_uri
your application consumes the callback and
passes in the code_verifier
to include it in the authorization code grant token exchange.
const params = client.callbackParams(req);
client.callback('https://client.example.com/callback', params, { code_verifier }) // => Promise
.then(function (tokenSet) {
console.log('received and validated tokens %j', tokenSet);
console.log('validated ID Token claims %j', tokenSet.claims());
});
You can then call the userinfo_endpoint
.
client.userinfo(access_token) // => Promise
.then(function (userinfo) {
console.log('userinfo %j', userinfo);
});
And later refresh the tokenSet if it had a refresh_token
.
client.refresh(refresh_token) // => Promise
.then(function (tokenSet) {
console.log('refreshed and validated tokens %j', tokenSet);
console.log('refreshed ID Token claims %j', tokenSet.claims());
});
Implicit response_type=id_token
flow is perfect for simply authenticating your end-users, assuming
the only job you want done is authenticating the user and then relying on your own session mechanism
with no need for accessing any third party APIs with an Access Token from the Authorization Server.
Create a Client instance for that issuer's authorization server intended for ID Token implicit flow.
See the documentation for full API details.
const client = new googleIssuer.Client({
client_id: 'zELcpfANLqY7Oqas',
redirect_uris: ['http://localhost:3000/cb'],
response_types: ['id_token'],
// id_token_signed_response_alg (default "RS256")
}); // => Client
When you want to have your end-users authorize you need to send them to the issuer's
authorization_endpoint
. Consult the web framework of your choice on how to redirect but here's how
to get the authorization endpoint's URL with parameters already encoded in the query to redirect
to.
const { generators } = require('openid-client');
const nonce = generators.nonce();
// store the nonce in your framework's session mechanism, if it is a cookie based solution
// it should be httpOnly (not readable by javascript) and encrypted.
client.authorizationUrl({
scope: 'openid email profile',
response_mode: 'form_post',
nonce,
});
When end-users hit back your redirect_uri
with a POST (authorization request included form_post
response mode) your application consumes the callback and passes the nonce
in to include it in the
ID Token verification steps.
// assumes req.body is populated from your web framework's body parser
const params = client.callbackParams(req);
client.callback('https://client.example.com/callback', params, { nonce }) // => Promise
.then(function (tokenSet) {
console.log('received and validated tokens %j', tokenSet);
console.log('validated ID Token claims %j', tokenSet.claims());
});
RFC8628 - OAuth 2.0 Device Authorization Grant (Device Flow) is started by starting a Device Authorization Request.
const handle = await client.deviceAuthorization();
console.log('User Code: ', handle.user_code);
console.log('Verification URI: ', handle.verification_uri);
console.log('Verification URI (complete): ', handle.verification_uri_complete);
The handle represents a Device Authorization Response with the verification_uri
, user_code
and
other defined response properties.
You will display the instructions to the end-user and have him directed at verification_uri
or
verification_uri_complete
, afterwards you can start polling for the Device Access Token Response.
const tokenSet = await handle.poll();
console.log('received tokens %j', tokenSet);
This will poll in the defined interval and only resolve with a TokenSet once one is received. This
will handle the defined authorization_pending
and slow_down
"soft" errors and continue polling
but upon any other error it will reject. With tokenSet received you can throw away the handle.
Electron >=v6.0.0 runtime is supported to the extent of the crypto engine BoringSSL feature parity with standard Node.js OpenSSL.
Yes. Everything that's either exported in the TypeScript definitions file or documented is subject to Semantic Versioning 2.0.0. The rest is to be considered private API and is subject to change between any versions.
It is only built for ^10.13.0 || >=12.0.0 Node.js environment - including openid-client in transpiled browser-environment targeted projects is not supported and may result in unexpected results.
- Simplified API which consumes a lot of the common configuration issues
- New documentation
- Added support for mutual-TLS client authentication
- Added support for any additional token exchange parameters to support specifications such as Resource Indicators
- Typed errors
- TypeScript definitions
See Client Authentication Methods (docs).
See Customizing (docs).
See Customizing (docs).