641 lines
24 KiB
Markdown
641 lines
24 KiB
Markdown
---
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title: LDAP Guide | ldapjs
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markdown2extras: wiki-tables
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logo-color: green
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logo-font-family: google:Aldrich, Verdana, sans-serif
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header-font-family: google:Aldrich, Verdana, sans-serif
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---
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# LDAP Guide
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This guide was written assuming that you (1) don't know anything about ldapjs,
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and perhaps more importantly (2) know little, if anything about LDAP. If you're
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already an LDAP whiz, please don't read this and feel it's condescending. Most
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people don't know how LDAP works, other than that "it's that thing that has my
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password."
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By the end of this guide, we'll have a simple LDAP server that accomplishes a
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"real" task.
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# What exactly is LDAP?
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If you haven't already read the
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[wikipedia](http://en.wikipedia.org/wiki/Lightweight_Directory_Access_Protocol)
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entry (which you should go do right now), LDAP is the "Lightweight Directory
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Access Protocol". A directory service basically breaks down as follows:
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* A directory is a tree of entries (similar to but different than an FS).
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* Every entry has a unique name in the tree.
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* An entry is a set of attributes.
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* An attribute is a key/value(s) pairing (multivalue is natural).
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It might be helpful to visualize:
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o=example
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/ \
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ou=users ou=groups
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/ | | \
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cn=john cn=jane cn=dudes cn=dudettes
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/
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keyid=foo
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Let's say we wanted to look at the record cn=john:
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dn: cn=john, ou=users, o=example
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cn: john
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sn: smith
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email: john@example.com
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email: john.smith@example.com
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objectClass: person
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A few things to note:
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* All names in a directory tree are actually referred to as a _distinguished
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name_, or _dn_ for short. A dn is comprised of attributes that lead to that
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node in the tree, as shown above (the syntax is foo=bar, ...).
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* The root of the tree is at the right of the _dn_, which is inverted from a
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filesystem hierarchy.
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* Every entry in the tree is an _instance of_ an _objectclass_.
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* An _objectclass_ is a schema concept; think of it like a table in a
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traditional ORM.
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* An _objectclass_ defines what _attributes_ an entry can have (on the ORM
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analogy, an _attribute_ would be like a column).
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That's it. LDAP, then, is the protocol for interacting with the directory tree,
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and it's comprehensively specified for common operations, like
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add/update/delete and importantly, search. Really, the power of LDAP comes
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through the search operations defined in the protocol, which are richer
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than HTTP query string filtering, but less powerful than full SQL. You can
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think of LDAP as a NoSQL/document store with a well-defined query syntax.
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So, why isn't LDAP more popular for a lot of applications? Like anything else
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that has "simple" or "lightweight" in the name, it's not really that
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lightweight. In particular, almost all of the implementations of LDAP stem
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from the original University of Michigan codebase written in 1996. At that
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time, the original intention of LDAP was to be an IP-accessible gateway to the
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much more complex X.500 directories, which means that a lot of that
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baggage has carried through to today. That makes for a high barrier to entry,
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when most applications just don't need most of those features.
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## How is ldapjs any different?
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Well, on the one hand, since ldapjs has to be 100% wire compatible with LDAP to
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be useful, it's not. On the other hand, there are no forced assumptions about
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what you need and don't need for your use of a directory system. For example,
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want to run with no-schema in OpenLDAP/389DS/et al? Good luck. Most of the
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server implementations support arbitrary "backends" for persistence, but really
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you'll be using [BDB](http://www.oracle.com/technetwork/database/berkeleydb/overview/index.html).
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Want to run schema-less in ldapjs, or wire it up with some mongoose models? No
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problem. Want to back it to redis? Should be able to get some basics up in a
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day or two.
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Basically, the ldapjs philospohy is to deal with the "muck" of LDAP, and then
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get out of the way so you can just use the "good parts."
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# Ok, cool. Learn me some LDAP!
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With the initial fluff out of the way, let's do something crazy to teach
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you some LDAP. Let's put an LDAP server up over the top of your (Linux) host's
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/etc/passwd and /etc/group files. Usually sysadmins "go the other way," and
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replace /etc/passwd with a
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[PAM](http://en.wikipedia.org/wiki/Pluggable_authentication_module "Pluggable
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authentication module") module to LDAP. While this is probably not a super
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useful real-world use case, it will teach you some of the basics. If it is
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useful to you, then that's gravy.
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## Install
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If you don't already have node.js and npm, clearly you need those, so follow
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the steps at [nodejs.org](http://nodejs.org) and [npmjs.org](http://npmjs.org),
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respectively. After that, run:
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$ npm install ldapjs
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Rather than overload you with client-side programming for now, we'll use
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the OpenLDAP CLI to interact with our server. It's almost certainly already
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installed on your system, but if not, you can get it from brew/apt/yum/your
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package manager here.
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To get started, open some file, and let's get the library loaded and a server
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created:
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var ldap = require('ldapjs');
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var server = ldap.createServer();
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server.listen(1389, function() {
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console.log('/etc/passwd LDAP server up at: %s', server.url);
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});
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And run that. Doing anything will give you errors (LDAP "No Such Object")
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since we haven't added any support in yet, but go ahead and try it anyway:
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$ ldapsearch -H ldap://localhost:1389 -x -b "o=myhost" objectclass=*
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Before we go any further, note that the complete code for the server we are
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about to build up is on the [examples](http://ldapjs.org/examples.html) page.
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## Bind
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So, lesson #1 about LDAP: unlike HTTP, it's connection-oriented; that means that
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you authenticate (in LDAP nomenclature this is called a _bind_), and all
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subsequent operations operate at the level of priviledge you established during
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a bind. You can bind any number of times on a single connection and change that
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identity. Technically, it's optional, and you can support _anonymous_
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operations from clients, but (1) you probably don't want that, and (2) most
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LDAP clients will initiate a bind anyway (OpenLDAP will), so let's add it in
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and get it out of our way.
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What we're going to do is add a "root" user to our LDAP server. This root user
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has no correspondence to our Unix root user, it's just something we're making up
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and going to use for allowing an (LDAP) admin to do anything. To do so, add
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this code into your file:
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server.bind('cn=root', function(req, res, next) {
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if (req.dn.toString() !== 'cn=root' || req.credentials !== 'secret')
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return next(new ldap.InvalidCredentialsError());
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res.end();
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return next();
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});
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Not very secure, but this is a demo. What we did there was "mount" a tree in
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the ldapjs server, and add a handler for the _bind_ method. If you've ever used
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express, this pattern should be really familiar; you can add any number of
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handlers in, as we'll see later.
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On to the meat of the method. What's up with this?
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if (req.dn.toString() !== 'cn=root' || req.credentials !== 'secret')
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The first part `req.dn.toString() !== 'cn=root'`: you're probably thinking
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"WTF?!? Does ldapjs allow something other than cn=root into this handler?" Sort
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of. It allows cn=root *and any children* into that handler. So the entries
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`cn=root` and `cn=evil, cn=root` would both match and flow into this handler.
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Hence that check. The second check `req.credentials` is probably obvious, but
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it brings up an important point, and that is the `req`, `res` objects in ldapjs
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are not homogenous across server operation types. Unlike HTTP, there's not a
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single message format, so each of the operations has fields and functions
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appropriate to that type. The LDAP bind operation has `credentials`, which are
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a string representation of the client's password. This is logically the same as
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HTTP Basic Authentication (there are other mechanisms, but that's out of scope
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for a getting started guide). Ok, if either of those checks failed, we pass a
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new ldapjs `Error` back into the server, and it will (1) halt the chain, and (2)
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send the proper error code back to the client.
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Lastly, assuming that this request was ok, we just end the operation with
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`res.end()`. The `return next()` isn't strictly necessary, since here we only
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have one handler in the chain, but it's good habit to always do that, so if you
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add another handler in later you won't get bit by it not being invoked.
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Blah blah, let's try running the ldap client again, first with a bad password:
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$ ldapsearch -H ldap://localhost:1389 -x -D cn=root -w foo -b "o=myhost" objectclass=*
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ldap_bind: Invalid credentials (49)
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matched DN: cn=root
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additional info: Invalid Credentials
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And again with the correct one:
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$ ldapsearch -H ldap://localhost:1389 -x -D cn=root -w secret -LLL -b "o=myhost" objectclass=*
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No such object (32)
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Additional information: No tree found for: o=myhost
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Don't worry about all the flags we're passing into OpenLDAP, that's just to make
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their CLI less annonyingly noisy. This time, we got another `No such object`
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error, but it's for the tree `o=myhost`. That means our bind went through, and
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our search failed, since we haven't yet added a search handler. Just one more
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small thing to do first.
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Remember earlier I said there were no authorization rules baked into LDAP? Well,
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we added a bind route, so the only user that can authenticate is `cn=root`, but
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what if the remote end doesn't authenticate at all? Right, nothing says they
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*have to* bind, that's just what the common clients do. Let's add a quick
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authorization handler that we'll use in all our subsequent routes:
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function authorize(req, res, next) {
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if (!req.connection.ldap.bindDN.equals('cn=root'))
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return next(new ldap.InsufficientAccessRightsError());
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return next();
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}
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Should be pretty self-explanatory, but as a reminder, LDAP is connection
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oriented, so we check that the connection remote user was indeed our `cn=root`
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(by default ldapjs will have a DN of `cn=anonymous` if the client didn't bind).
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## Search
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We said we wanted to allow LDAP operations over /etc/passwd, so let's detour
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for a moment to explain an /etc/passwd record.
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jsmith:x:1001:1000:Joe Smith,Room 1007,(234)555-8910,(234)555-0044,email:/home/jsmith:/bin/sh
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The sample record above maps to:
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||jsmith||user name.||
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||x||historically this contained the password hash, but that's usually in /etc/shadow now, so you get an 'x'.||
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||1001||the unix numeric user id.||
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||1000||the unix numeric group id. (primary).||
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||'Joe Smith,...'||the "gecos," which is a description, and is usually a comma separated list of contact details.||
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||/home/jsmith||the user's home directory.||
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||/bin/sh||the user's shell.||
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Let's write some handlers to parse that and transform it into an LDAP search
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record (note, you'll need to add `var fs = require('fs');` at the top of the
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source file).
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First, make a handler that just loads the "user database" in a "pre" handler:
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function loadPasswdFile(req, res, next) {
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fs.readFile('/etc/passwd', 'utf8', function(err, data) {
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if (err)
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return next(new ldap.OperationsError(err.message));
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req.users = {};
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var lines = data.split('\n');
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for (var i = 0; i < lines.length; i++) {
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if (!lines[i] || /^#/.test(lines[i]))
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continue;
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var record = lines[i].split(':');
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if (!record || !record.length)
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continue;
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req.users[record[0]] = {
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dn: 'cn=' + record[0] + ', ou=users, o=myhost',
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attributes: {
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cn: record[0],
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uid: record[2],
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gid: record[3],
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description: record[4],
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homedirectory: record[5],
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shell: record[6] || '',
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objectclass: 'unixUser'
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}
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};
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}
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return next();
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});
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}
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Ok, all that did is tack the /etc/passwd records onto req.users so that any
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subsequent handler doesn't have to reload the file. Next, let's write a search
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handler to process that:
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var pre = [authorize, loadPasswdFile];
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server.search('o=myhost', pre, function(req, res, next) {
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Object.keys(req.users).forEach(function(k) {
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if (req.filter.matches(req.users[k].attributes))
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res.send(req.users[k]);
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});
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res.end();
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return next();
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});
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And try running:
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$ ldapsearch -H ldap://localhost:1389 -x -D cn=root -w secret -LLL -b "o=myhost" cn=root
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dn: cn=root, ou=users, o=myhost
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cn: root
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uid: 0
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gid: 0
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description: System Administrator
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homedirectory: /var/root
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shell: /bin/sh
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objectclass: unixUser
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Sweet! Try this out too:
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$ ldapsearch -H ldap://localhost:1389 -x -D cn=root -w secret -LLL -b "o=myhost" objectclass=*
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...
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You should have seen an entry for every record in /etc/passwd with the second.
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What all did we do here? A lot. Let's break this down...
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### What did I just do on the command line?
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Let's start with looking at what you even asked for:
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$ ldapsearch -H ldap://localhost:1389 -x -D cn=root -w secret -LLL -b "o=myhost" cn=root
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We can throw away `ldapsearch -H -x -D -w -LLL`, as those just specify the URL
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to connect to, the bind credentials and the `-LLL` just quiets down OpenLDAP.
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That leaves us with: `-b "o=myhost" cn=root`.
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The `-b o=myhost` tells our LDAP server where to _start_ looking in
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the tree for entries that might match the search filter, which above is
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`cn=root`.
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In this little LDAP example, we're mostly throwing out any qualification of the
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"tree," since there's not actually a tree in /etc/passwd (we will extend later
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with /etc/group). Remember how I said ldapjs gets out of the way and doesn't
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force anything on you? Here's an example. If we wanted an LDAP server to run
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over the filesystem, we actually would use this, but here, meh.
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Next, `cn=root` is the search "filter". LDAP has a rich specification of
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filters, where you can specify `and`, `or`, `not`, `>=`, `<=`, `equal`,
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`wildcard`, `present` and a few other esoteric things. Really, `equal`,
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`wildcard`, `present` and the boolean operators are all you'll likely ever need.
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So, the filter `cn=root` is an "equality" filter, and says to only return
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entries that have attributes that match that. In the second invocation, we used
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a 'presence' filter, to say 'return any entries that have an objectclass'
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attribute, which in LDAP parlance is saying "give me everything."
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### The code
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In the code above, let's ignore the fs and split stuff, since really all we
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did was read in /etc/passwd line by line. After that, we looked at each record
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and made the cheesiest transform ever, which is making up a "search entry." A
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search entry _must_ have a DN so the client knows what record it is, and a set
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of attributes. So that's why we did this:
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var entry = {
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dn: 'cn=' + record[0] + ', ou=users, o=myhost',
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attributes: {
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cn: record[0],
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uid: record[2],
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gid: record[3],
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description: record[4],
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homedirectory: record[5],
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shell: record[6] || '',
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objectclass: 'unixUser'
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}
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};
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Next, we let ldapjs do all the hard work of figuring out LDAP search filters
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for us by calling `req.filter.matches`. If it matched, we return the whole
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record with `res.send`. In this little example we're running O(n), so for
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something big and/or slow, you'd have to do some work to effectively write a
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query planner (or just not support it...). For some reference code, check out
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`node-ldapjs-riak`, which takes on the fairly difficult task of writing a 'full'
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LDAP server over riak.
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To demonstrate what ldapjs is doing for you, let's find all users who have a
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shell set to `/bin/false` and whose name starts with `p` (I'm doing this
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on Ubuntu). Then, let's say we only care about their login name and primary
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group id. We'd do this:
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$ ldapsearch -H ldap://localhost:1389 -x -D cn=root -w secret -LLL -b "o=myhost" "(&(shell=/bin/false)(cn=p*))" cn gid
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dn: cn=proxy, ou=users, o=myhost
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cn: proxy
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gid: 13
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dn: cn=pulse, ou=users, o=myhost
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cn: pulse
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gid: 114
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## Add
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This is going to be a little bit ghetto, since what we're going to do is just
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use node's child process module to spawn calls to `adduser`. Go ahead and add
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the following code in as another handler (you'll need a
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`var spawn = require('child_process').spawn;` at the top of your file):
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server.add('ou=users, o=myhost', pre, function(req, res, next) {
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if (!req.dn.rdns[0].cn)
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return next(new ldap.ConstraintViolationError('cn required'));
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if (req.users[req.dn.rdns[0].cn])
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return next(new ldap.EntryAlreadyExistsError(req.dn.toString()));
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var entry = req.toObject().attributes;
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if (entry.objectclass.indexOf('unixUser') === -1)
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return next(new ldap.ConstraintViolation('entry must be a unixUser'));
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var opts = ['-m'];
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if (entry.description) {
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opts.push('-c');
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opts.push(entry.description[0]);
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}
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if (entry.homedirectory) {
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opts.push('-d');
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opts.push(entry.homedirectory[0]);
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}
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if (entry.gid) {
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opts.push('-g');
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opts.push(entry.gid[0]);
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}
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if (entry.shell) {
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opts.push('-s');
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opts.push(entry.shell[0]);
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}
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if (entry.uid) {
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opts.push('-u');
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opts.push(entry.uid[0]);
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}
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opts.push(entry.cn[0]);
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var useradd = spawn('useradd', opts);
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var messages = [];
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useradd.stdout.on('data', function(data) {
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messages.push(data.toString());
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});
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useradd.stderr.on('data', function(data) {
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messages.push(data.toString());
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});
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useradd.on('exit', function(code) {
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if (code !== 0) {
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var msg = '' + code;
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if (messages.length)
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msg += ': ' + messages.join();
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return next(new ldap.OperationsError(msg));
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}
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res.end();
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return next();
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});
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});
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|
|
Then, you'll need to be root to have this running, so start your server with
|
|
`sudo` (or be root, whatever). Now, go ahead and create a file called
|
|
`user.ldif` with the following contents:
|
|
|
|
dn: cn=ldapjs, ou=users, o=myhost
|
|
objectClass: unixUser
|
|
cn: ldapjs
|
|
shell: /bin/bash
|
|
description: Created via ldapadd
|
|
|
|
Now go ahead and invoke with:
|
|
|
|
$ ldapadd -H ldap://localhost:1389 -x -D cn=root -w secret -f ./user.ldif
|
|
adding new entry "cn=ldapjs, ou=users, o=myhost"
|
|
|
|
Let's confirm he got added with an ldapsearch:
|
|
|
|
$ ldapsearch -H ldap://localhost:1389 -LLL -x -D cn=root -w secret -b "ou=users, o=myhost" cn=ldapjs
|
|
dn: cn=ldapjs, ou=users, o=myhost
|
|
cn: ldapjs
|
|
uid: 1001
|
|
gid: 1001
|
|
description: Created via ldapadd
|
|
homedirectory: /home/ldapjs
|
|
shell: /bin/bash
|
|
objectclass: unixUser
|
|
|
|
As before, here's a breakdown of the code:
|
|
|
|
server.add('ou=users, o=myhost', pre, function(req, res, next) {
|
|
if (!req.dn.rdns[0].cn)
|
|
return next(new ldap.ConstraintViolationError('cn required'));
|
|
|
|
if (req.users[req.dn.rdns[0].cn])
|
|
return next(new ldap.EntryAlreadyExistsError(req.dn.toString()));
|
|
|
|
var entry = req.toObject().attributes;
|
|
|
|
if (entry.objectclass.indexOf('unixUser') === -1)
|
|
return next(new ldap.ConstraintViolation('entry must be a unixUser'));
|
|
|
|
A few new things:
|
|
|
|
* We mounted this handler at `ou=users, o=myhost`. Why? What if we want to
|
|
extend this little project with groups? We probably want those under a
|
|
different part of the tree.
|
|
* We did some really minimal schema enforcement by:
|
|
+ Checking that the leaf RDN (relative distinguished name) was a _cn_
|
|
attribute.
|
|
+ We then did `req.toObject()`. As mentioned before, each of the req/res
|
|
objects have special APIs that make sense for that operation. Without getting
|
|
into the details, the LDAP add operation on the wire doesn't look like a JS
|
|
object, and we want to support both the LDAP nerd that wants to see what
|
|
got sent, and the "easy" case. So use `.toObject()`. Note we also filtered
|
|
out to the `attributes` portion of the object since that's all we're really
|
|
looking at.
|
|
+ Lastly, we did a super minimal check to see if the entry was of type
|
|
`unixUser`. Frankly for this case, it's kind of useless, but it does illustrate
|
|
one point: attribute names are case-insensitive, so ldapjs converts them all to
|
|
lower case (note the client sent _objectClass_ over the wire).
|
|
|
|
After that, we really just delegated off to the _useradd_ command. As far as I
|
|
know, there is not a node.js module that wraps up `getpwent` and friends,
|
|
otherwise we'd use that.
|
|
|
|
Now, what's missing? Oh, right, we need to let you set a password. Well, let's
|
|
support that via the _modify_ command.
|
|
|
|
## Modify
|
|
|
|
Unlike HTTP, "partial" document updates are fully specified as part of the
|
|
RFC, so appending, removing, or replacing a single attribute is pretty natural.
|
|
Go ahead and add the following code into your source file:
|
|
|
|
server.modify('ou=users, o=myhost', pre, function(req, res, next) {
|
|
if (!req.dn.rdns[0].cn || !req.users[req.dn.rdns[0].cn])
|
|
return next(new ldap.NoSuchObjectError(req.dn.toString()));
|
|
|
|
if (!req.changes.length)
|
|
return next(new ldap.ProtocolError('changes required'));
|
|
|
|
var user = req.users[req.dn.rdns[0].cn].attributes;
|
|
var mod;
|
|
|
|
for (var i = 0; i < req.changes.length; i++) {
|
|
mod = req.changes[i].modification;
|
|
switch (req.changes[i].operation) {
|
|
case 'replace':
|
|
if (mod.type !== 'userpassword' || !mod.vals || !mod.vals.length)
|
|
return next(new ldap.UnwillingToPerformError('only password updates ' +
|
|
'allowed'));
|
|
break;
|
|
case 'add':
|
|
case 'delete':
|
|
return next(new ldap.UnwillingToPerformError('only replace allowed'));
|
|
}
|
|
}
|
|
|
|
var passwd = spawn('chpasswd', ['-c', 'MD5']);
|
|
passwd.stdin.end(user.cn + ':' + mod.vals[0], 'utf8');
|
|
|
|
passwd.on('exit', function(code) {
|
|
if (code !== 0)
|
|
return next(new ldap.OperationsError(code));
|
|
|
|
res.end();
|
|
return next();
|
|
});
|
|
});
|
|
|
|
|
|
Basically, we made sure the remote client was targeting an entry that exists,
|
|
ensuring that they were asking to "replace" the `userPassword` attribute (which
|
|
is the 'standard' LDAP attribute for passwords; if you think it's easier to use
|
|
'password', knock yourself out), and then just delegating to the `chpasswd`
|
|
command (which lets you change a user's password over stdin). Next, go ahead
|
|
and create a `passwd.ldif` file:
|
|
|
|
dn: cn=ldapjs, ou=users, o=myhost
|
|
changetype: modify
|
|
replace: userPassword
|
|
userPassword: secret
|
|
-
|
|
|
|
And then run the OpenLDAP CLI:
|
|
|
|
$ ldapmodify -H ldap://localhost:1389 -x -D cn=root -w secret -f ./passwd.ldif
|
|
|
|
You should now be able to login to your box as the ldapjs user. Let's get
|
|
the last "mainline" piece of work out of the way, and delete the user.
|
|
|
|
## Delete
|
|
|
|
Delete is pretty straightforward. The client gives you a dn to delete, and you
|
|
delete it :). Add the following code into your server:
|
|
|
|
server.del('ou=users, o=myhost', pre, function(req, res, next) {
|
|
if (!req.dn.rdns[0].cn || !req.users[req.dn.rdns[0].cn])
|
|
return next(new ldap.NoSuchObjectError(req.dn.toString()));
|
|
|
|
var userdel = spawn('userdel', ['-f', req.dn.rdns[0].cn]);
|
|
|
|
var messages = [];
|
|
userdel.stdout.on('data', function(data) {
|
|
messages.push(data.toString());
|
|
});
|
|
userdel.stderr.on('data', function(data) {
|
|
messages.push(data.toString());
|
|
});
|
|
|
|
userdel.on('exit', function(code) {
|
|
if (code !== 0) {
|
|
var msg = '' + code;
|
|
if (messages.length)
|
|
msg += ': ' + messages.join();
|
|
return next(new ldap.OperationsError(msg));
|
|
}
|
|
|
|
res.end();
|
|
return next();
|
|
});
|
|
});
|
|
|
|
And then run the following command:
|
|
|
|
$ ldapdelete -H ldap://localhost:1389 -x -D cn=root -w secret "cn=ldapjs, ou=users, o=myhost"
|
|
|
|
|
|
# Where to go from here
|
|
|
|
The complete source code for this example server is available in
|
|
[examples](/examples.html). Make sure to read up on the [server](/server.html)
|
|
and [client](/client.html) APIs. If you're looking for a "drop in" solution,
|
|
take a look at [ldapjs-riak](https://github.com/mcavage/node-ldapjs-riak).
|
|
|
|
[Mozilla](https://wiki.mozilla.org/Mozilla_LDAP_SDK_Programmer%27s_Guide/Understanding_LDAP)
|
|
still maintains some web pages with LDAP overviews if you look around, if you're
|
|
looking for more tutorials. After that, you'll need to work your way through
|
|
the [RFCs](http://tools.ietf.org/html/rfc4510) as you work through the APIs in
|
|
ldapjs.
|