An extensible authentication and authorization library for Clojure/Ring web applications and services.
Picking up his staff he stood before the rock and said in a clear voice:
Mellon!
The star shone out briefly and faded again. Then silently a great
doorway was outlined, though not a crack or joint had been visible
before. Slowly it divided in the middle and swung outwards inch by inch,
until both doors lay back against the wall. Through the opening a
shadowy stair could be seen climbing steeply up; but beyond the lower
steps the darkness was deeper than the night. The Company stared in
wonder.
"I was wrong after all," said Gandalf, "and Gimli too. Merry, of all
people, was on the right track. The opening word was inscribed on the
archway all the time! The translation should have been: Say 'Friend' and
enter. I had only to speak the Elvish word for friend and the doors
opened. Quite simple. Too simple for a learned lore master in these
suspicious days. Those were happier times. Now let us go!"
— J.R.R. Tolkien, Lord of the Rings
Friend is intended to provide a foundation for addressing all of the authentication and authorization concerns associated with web apps:
su
capabilities (a.k.a. "log in as"), enabling users to maintain
multiple simultaneous logins, as well as to allow administrators to
take on users' identities for debugging or support purposes (in
progress)Nothing like Friend exists, and it needs to. Securing Ring applications and services is (charitably speaking) a PITA right now, with everyone rolling their own, or starting with relatively low-level middlewares and frameworks. This will never do. Serious web applications need to take security seriously, and need to readily interoperate with all sorts of authentication mechanisms that have come to litter the web as well as internal networks.
Friend has been built with one eye on a number of frameworks.
Very stable, widely-used in production AFAIK.
Note: while actively maintained, Friend is in search of a new maintainer.
Available here.
su
mechanism is in-progressFriend is available in Clojars. Add this :dependency
to your Leiningen
project.clj
:
[com.cemerick/friend "0.2.3"]
Or, add this to your Maven project's pom.xml
:
<repository>
<id>clojars</id>
<url>http://clojars.org/repo</url>
</repository>
<dependency>
<groupId>com.cemerick</groupId>
<artifactId>friend</artifactId>
<version>0.2.3</version>
</dependency>
Friend is compatible with Clojure 1.2.0 - 1.5.0+.
How you use Friend will vary, sometimes significantly, depending on the authentication providers you use and the authorization policy/ies you want to enforce. A generic example of typical usage of Friend is below, but the best way to become familiar with Friend and how it can be used would be to go check out
…a collection of tiny demonstration apps using Friend. It should be easy to find the one(s) that apply to your situation, and go straight to its source so you can see how all the pieces fit together.
Here's probably the most self-contained Friend usage possible:
(ns your.ring.app
(:require [cemerick.friend :as friend]
(cemerick.friend [workflows :as workflows]
[credentials :as creds])))
; a dummy in-memory user "database"
(def users {"root" {:username "root"
:password (creds/hash-bcrypt "admin_password")
:roles #{::admin}}
"jane" {:username "jane"
:password (creds/hash-bcrypt "user_password")
:roles #{::user}}})
(def ring-app ; ... assemble routes however you like ...
)
(def secured-app
(-> ring-app
(friend/authenticate {:credential-fn (partial creds/bcrypt-credential-fn users)
:workflows [(workflows/interactive-form)]})
; ...required Ring middlewares ...
))
We have an unadorned (and unsecured) Ring application (ring-app
, which
can be any Ring handler), and then the usage of Friend's authenticate
middleware. This is where all of the authentication work will be done,
with the return value being a secured Ring application (secured-app
),
the requests to which are subject to the configuration provided to
authenticate
and the authorization contexts that are defined within
ring-app
(which we'll get to shortly).
(If you're newer to Clojure, you might not recognize the tokens prefixed with
two colons [e.g. ::admin
]. These are auto-namespaced keywords; in the example
above, ::admin
expands to :your.ring.app/admin
.)
There are two key abstractions employed during authentication:
workflow
and
credential
functions. The example above defines a single workflow — one supporting
the POST
ing of :username
and :password
parameters to (by default)
/login
— which will discover the specified :credential-fn
and use it
to validate submitted credentials. The bcrypt-credential-fn
function
verifies a submitted map of {:username "..." :password "..."}
credentials against one loaded from another function based on the
:username
value; in this case, we're just looking up the username in a
fixed Clojure map that has username, (bcrypted) password, and roles
entries. If a submitted set of credentials matches those in the
authoritative store, the latter are returned (sans :password
) as an
authentication map.
(Each workflow can have its own local configuration — including a
credential function — that is used in preference to the configuration
specified at the authenticate
level.)
The authenticate
middleware runs every incoming request through each
of the workflows with which it is created. It further handles things
like retaining authentication details in the user session (by default)
and managing the redirection of users when they attempt to access
protected resources without the requisite authentication or
authorization (first to the start of an authentication workflow, e.g.
GET
of a /login
URI, and then back to the originally-requested
protected resource once the authentication workflow is completed).
(Note that Friend itself requires some core Ring middlewares: params
,
keyword-params
and nested-params
. Most workflows will additionally
require session
in order to support post-authentication redirection to
previously-unauthorized resources, retention of tokens and nonces for
workflows like OpenId and oAuth, etc. HTTP Basic is the only provided
workflow that does not require session
middleware.)
Individual authentication methods (e.g., form-based auth, HTTP Basic, OpenID, oAuth, etc.) are implemented as workflows in Friend. A workflow is a regular Ring handler function, except that a workflow function can opt to return an authentication map instead of a Ring response if a request is authenticated. A diagram may help:
You can define any number of workflows in a :workflows
kwarg to
authenticate
. Incoming requests are always run through the configured
workflows prior to potentially being passed along to the secured Ring
application.
If a workflow returns an authentication map, then the authenticate
middleware will either:
If a workflow returns a Ring response, then that response is sent back
to the user agent straight away (after some bookkeeping by the
authenticate
middleware to preserve session states and such). This
makes it possible for a workflow to control a "local" dataflow between
itself, the user agent, and any necessary external authorities (e.g. by
redirecting a user agent to an OpenId endpoint, performing token
exchange in the case of oAuth, etc., eventually returning a complete
authentication map that will allow the user agent to proceed on its
desired vector).
Workflows use a credential function to verify the credentials provided
to them via requests. Credential functions can be specified either as a
:credential-fn
option to cemerick.friend/authenticate
, or often as
an (overriding) :credential-fn
option to individual workflow
functions.
All credential functions take a single argument, a map containing the
available credentials that additionally contains a
:cemerick.friend/workflow
slot identifying which workflow has produced
the credential. For example, the default form-based authentication
credential map looks like this:
{:username "...", :password "...", :cemerick.friend/workflow :form}
HTTP Basic credentials are much the same, but with a workflow value of
:http-basic
, etc. Different workflows may have significantly different
credential maps (e.g. an OpenID workflow does not provide username and
password, but rather a token returned by an OpenID provider along with
potentially some number of "attributes" like the user's name, email
address, default language, etc.), and unique credential verification
requirements (again, contrast the simple username/password verification
of form or HTTP Basic credentials and OpenId, which, in
general, when presented with unknown credentials, should register the
indicated identity rather than verifying it).
In summary, the contract of what exactly must be in the map provided to credential functions is entirely at the discretion of each workflow function, as is the semantics of the credential function.
If a map of credentials is verified by a credential function, it should return a authentication map that aggregates all authentication and authorization information available for the identified user. This map may contain many entries, depending upon the authentication information that is relevant for the workflow in question and the user data relevant to the application, but two entries are privileged:
:identity
(required) corresponds with e.g. the username in a
form or HTTP Basic authentication, an oAuth token, etc.; this value
must be unique across all users within the application:roles
, an optional collection of values enumerating the roles for
which the user is authorized, or a function returning the same.If a map of credentials is found to be invalid, the credential function must return nil.
As is, the example above doesn't do a lot: users can opt to be authenticated, but we've not described any kind of security policy, identified routes or functions or forms that require particular roles to access, and so on. This is where authorization mechanisms come into play.
While Friend has a single point of authentication — the authenticate
middleware — it has many different options for restricting access to
particular resources or code:
authenticated
is a macro that requires that the current user must be
authenticatedauthorized?
is a predicate that returns true only if the current
user (as determined via the authentication map returned by a
workflow) possesses the specified roles. You'll usually want to use
one of the higher-level facilities (keep reading), but authorized?
may
come in handy if access to a certain resource or operation cannot be
specified declaratively.The rest of the authorization utilities use authorized?
to determine
whether a user may gain access to whatever the utility is protecting:
authorize
is a macro that guards any body of code from
being executed within a thread associated with a user that is not
authorized?
wrap-authorize
is a Ring middleware that only allows requests to
pass through to the wrapped handler if their associated user is
authorized?
authorize-hook
is a function intended to be used with the Robert
Hooke library that
allows you to place authorization guards around functions defined in
code you don't control.Here's an extension of the example above that adds some actual routes (using Compojure) and handler that require authentication:
(use '[compojure.core :as compojure :only (GET ANY defroutes)])
(defroutes user-routes
(GET "/account" request (page-bodies (:uri request)))
(GET "/private-page" request (page-bodies (:uri request))))
(defroutes ring-app
;; requires user role
(compojure/context "/user" request
(friend/wrap-authorize user-routes #{::user}))
;; requires admin role
(GET "/admin" request (friend/authorize #{::admin}
#_any-code-requiring-admin-authorization
"Admin page."))
;; anonymous
(GET "/" request "Landing page.")
(GET "/login" request "Login page.")
(friend/logout (ANY "/logout" request (ring.util.response/redirect "/"))))
This should be easy to grok, but some highlights:
context
utility to
wire them up into a common URI segment.authorize
to put authorization guards
around any code, anywhere.logout
middleware can be applied to any Ring handler, and will
remove all authentication information from the session assuming a
non-nil
response from the wrapped handler.Note that, so far, all of the authorization checks will be completely
"strict", e.g. the admin user won't have access to /user
because it
requires the ::user
role. This is where hierarchies are unreasonably
helpful.
derive
, isa?
, et al.)The foundational authorized?
predicate uses isa?
to check if any of
the current user's roles match one of those specified. This means that
you can take advantage of Clojure's hierarchies via derive
to
establish relationships between roles. e.g., this is all that is
required to give a user with the ::admin
role all of the privileges of
a user with the ::user
role:
(derive ::admin ::user)
Of course, you are free to construct your role hierarchy(ies) however you like, to suit your application and your security requirements.
If you are using Nginx to, e.g, terminate SSL, set the appropriate headers so that the Clojure backend can generate the correct return-to
URLs for the openid and similar workflows:
upstream jetty_upstream {
ip_hash;
server 127.0.0.1:8080;
keepalive 64;
}
server {
listen 443 ssl;
#...SSL termination config, &c.
location / {
proxy_set_header host $host;
proxy_set_header x-forwarded-for $remote_addr;
proxy_set_header x-forwarded-host $host;
proxy_set_header x-forwarded-proto $scheme;
proxy_set_header x-forwarded-port $server_port;
proxy_pass http://jetty_upstream;
}
}
:cemerick.friend/workflow
metadata:type
::friend/workflow
::friend/redirect-on-auth?
::friend/ensure-session
Ping cemerick
on freenode irc or
twitter if you have questions or would
like to contribute patches.
Copyright ©2012-2013 Chas Emerick and other contributors.
Distributed under the Eclipse Public License, the same as Clojure.
Please see the epl-v10.html
file at the top level of this repo.
Can you improve this documentation? These fine people already did:
Chas Emerick, Kevin J. Lynagh, Andrew Meredith, bonkydog, Mike Breen, Gabriel Horner, gary.yao & Yoshito KomatsuEdit on GitHub
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