Courier Mail Server
The advantages of Courier-MTA are:
- Authentication for MTA and POP3/IMAP happens against one data source
- This data source can be a MySQL, PgSQL or LDAP, but also can be simpler like PAM or a compiled plaintextfile (BerkeleyDB)
- Easy support of virtual users
- SMTP-auth out of the box
- Comes with webmail
- Web based administration possible
- Also has a separate mail delivery agent (MDA), if it is needed
The following text describes a setup for two local domains on one physical machine, which is not so uncommon for single users or small companies. We authenticate against a BerkeleyDB-based ".dat" file which is created from a text or multiple textfiles automatically by tools that come with courier. This method is described in the Courier documentation as authuserdb, so do not get confused about names. The authentication against other providers happens in an adequate way and is covered in courier-authlibs documentation. There are differences in the handling of SASL methods (such as PLAIN or CRAM-MD5) depending on which authentication backend (authuserd, authpam, authmysql ...) you like to use. Just do not expect that this setup can be painlessly converted from the described authuserdb to authmysql.
--without-tcpddnsto the configure attributes and go make some coffee, since this will take a while. Then make sure, that you add our dummy domains "domain1" and "domain2" to your
Install the AUR package.
Any other mail transfer agents (like Cyrus) or SMTP servers (Sendmail, Postfix, etc.) must be uninstalled for this, so answer 'yes' when prompted to do so.
You need to obtain a certificate.
Let Courier know that we want to authenticate against authuserdb.
In the file
authmodulelist=... then remove all listed modules except for authuserdb:
authmodulelist="authuserdb" # For test it is useful to set DEBUG_LOGIN from 0 to 2 DEBUG_LOGIN=2
Creating the vmail user
We want to deliver our mail primarily to virtual users, so we can easily create e-mail accounts without creating real users. Granny may want to read her e-mail but she doesn't need ssh access to that box, does she? To make that possible we need one "physical" user, that owns all of our mails physically on the drive. Note, that this is not the courier user which is primarily there to make sure that the actual server process doesn't run as root. Many people save this stuff in
/var since it's primarily thought for these things. You can create the users "home" just anywhere you want! The decision will be influenced by the partition layout of your drive(s).
Add a user "vmail", who is the lord of all of the mail files:
# useradd -u 7200 -m -s /bin/bash vmail # passwd vmail
Creating the email accounts
There is a place where the virtual users and their attributes will be stored. This can be either a plain textfile or a directory where several textfiles are contained. See courier-authlib's documentation for details. The directory-based approach makes maintenance a bit easier since we can separate the users of domains and subdomains, so we'll go with this approach. The name of the directory is not negotiable.
# mkdir /etc/authlib/userdb
The attributes of the "vmail"-system user need to be stored here, too, since we allowed only authuserdb in
/etc/authlib/authdaemonrc . Fortunately, courier comes with a handy script that converts all local users into a file in courier-syntax. This file can be named freely, we call it "system". Later we also create a file for "domain1" and "domain2". Got the idea?
# pw2userdb > /etc/authlib/userdb/system
Keep only the "vmail" user (this means that no local user can receive emails!):
# sed -n -i "/vmail/p" /etc/authlib/userdb/system
Now we create the virtual users in the authentication database. The actual Maildir folders have to be created manually later. This creates a user "user1@domain1" and a "user2@domain2". For details about these commands check the man pages for the command itself and the man pages that are linked to.
# userdb -f /etc/authlib/userdb/domain1 user1@domain1 \ set home=/home/vmail/domain1/user1 uid=7200 gid=7200
Let's set a password for the user (used for PLAIN and LOGIN and APOP):
# userdbpw -md5 | userdb -f /etc/authlib/userdb/domain1 user1@domain1 set systempw
The following is used for CRAM-MD5 and friends (SASL-methods). Also note that this construct pipes the the password directly into the command and thus can be read as cleartext, but can be handy for shell scripts that create new users:
# echo 'pwuser1' | userdbpw -hmac-md5 | \ userdb -f /etc/authlib/userdb/domain1 user1@domain1 set hmac-md5pw
- user2 (repeat for user2@domain2):
# userdb -f /etc/authlib/userdb/domain2 user2@domain2 \ set home=/home/vmail/domain2/user2 uid=7200 gid=7200
# userdbpw | userdb -f /etc/authlib/userdb/domain2 user2@domain2 set systempw
# echo 'pwuser2' | userdbpw -hmac-md5 | \ userdb -f /etc/authlib/userdb/domain2 user2@domain2 set hmac-md5pw
Setting up Maildirs
We need to create the virtual users "Maildir" as a physical place on the hard-drive in the "vmail"-system user home directory. Note that the "vmail" user needs write rights and also will own the files. It's easiest to create that stuff as the "vmail" user:
# su vmail $ mkdir -p /home/vmail/domain1/user1 && maildirmake /home/vmail/domain1/user1/Maildir $ mkdir -p /home/vmail/domain2/user2 && maildirmake /home/vmail/domain2/user2/Maildir
Leave "vmail" account and become root:
Make sure you become root again by leaving the "vmail" account by typing
exit as shown above.
Creating the user database
Now it's time to create the BerkeleyDB from the plain text files. It is important that the files in
/etc/authlib/userdb are visible for root only. If they have any world or group rights, courier will not allow the creation of the db-files from the information.
# chmod 700 /etc/authlib/userdb && chmod 600 /etc/authlib/userdb/* # makeuserdb
Now we can check if the authentication works. Courier comes with a little tool that checks if users can be authenticated. Before using this tool, we must make sure the authentication daemon is running by enabling
# authtest user1@domain1 # authtest user2@domain2
If you encounter any errors while testing the authentication, please consult these instructions, which detail how to use debugging features to pinpoint the problem.
Now we are now done with authentication stuff. It gave us a flexible layout which can be easily extended. Time to move on to courier's configuration itself. First, we will try to give some aliases for the server. The aliases follow the userdb's scheme very closely. Unlike in other servers, there is no need to handle with all aliases in just one file. Again, you can create several plain text files in one folder, where you can handle the aliases by domains or even finer structured if you like. The folder's location is again not negotiable, you must use
/etc/courier/aliases. There is already a "system" file which deals with root, postmaster and the usual suspects. Just add a "user1@domain1" behind the existing "postmaster: " to have all system relevant mails delivered to "user1@domain1". We just assume that this user is your primary account.
# cat > /etc/courier/aliases/domain1 << EOALIASES user1@domain1: user1@domain1 user.user1@domain1: user1@domain1 u.user1@domain1: user1@domain1 userer1@domain1: user1@domain1 looser1@domain1: user1@domain1 EOALIASES
Repeat that for every domain and user, in our test case for user2@domain2. It might help to create another scheme here like naming your files domain1.user1 which makes administration easier and more transparent. This will also help on automated, script-based administration.
Finally, these aliases must be exported to the BerkeleyDB. Again, Courier comes with a little utility for that task, it's called
Just check if everything is fine:
# makealiases -chk
Setting localdomain and hosteddomains
Now we need to tell courier the who is who on this box -- who we serve e-mail for and who we do not. Courier separates this into these levels:
- locals: This is localhost for sure and on dedicated servers you are mostly part of a domain like server234.serverfarm.tld
- hosteddomains: For your hosted domains and subdomains like my-cool-domain.ca, project1.my-cool-domain.ca
For example, lets say you have a server at blahfarm.com. Usually they make your server a host on their domain. This is likely something like server234.blahfarm.com . Now, you want your server available from the web by a more meaningful and even cooler name, so you buy (or rent) a domain name like my-cool-domain.ca . In this case the setup looks like this:
/etc/courier/hosteddomainsif you want to have email addresses like firstname.lastname@example.org
To learn the difference between these specifications, read the manpage for
makehosteddomains. You will figure that the following suits our approach:
# echo localhost > /etc/courier/locals # echo server237.blahfarm.com >> /etc/courier/locals # mkdir /etc/courier/hosteddomains # cat > /etc/courier/hosteddomains/domain1 << EODOMAIN1HOSTED domain1 mail.domain1[TAB]domain1 EODOMAIN1HOSTED # cat > /etc/courier/hosteddomains/domain2 << EODOMAIN2HOSTED domain2 mail.domain2[TAB]domain2 EODOMAIN2HOSTED
Again, these values must be converted into a BerkeleyDB - use the courier command:
Before we go on, one more thing needs to be written -- the domain(s) we accept mail for. In the directory
/etc/courier/esmtpacceptmailfor.dir/ we'll create a file named
domain1 and type
domain1 into it:
# echo domain1 > /etc/courier/esmtpacceptmailfor.dir/domain1
Repeat for domain2:
# echo domain2 > /etc/courier/esmtpacceptmailfor.dir/domain2
Finally, convert into a BerkeleyDB:
...and you are done here.
Testing your setup
Now the server is ready. Let's run several tests on the SMTP server and see if it's working nicely at least for sending and receiving mails.
############################################################################### # this is a test case suggested on couriers very own webpage, we just convert it # from a local to a virtual user # prepare as vmail su vmail cd ~/domain1/user1 maildirmake bounces && maildirmake test echo "./test" > .courier-test-default echo "./bounces" > .courier # back to root, start the server and finally run the script exit /usr/sbin/courier start /usr/lib/courier/perftest1 1000 "user1@domain1 user2@domain2" ###############################################################################
Let us test some more stuff, which can be useful.
Send an ordinary mail (as root or ordinary user):
$ echo "To: user2@domain2 From: user1@domain1" | sendmail
Send a mail to an alias:
$ echo "To: userer2@domain2 From: user1@domain1" | sendmail
Send a mail to an external email address:
$ echo "To: email@example.com From: user1@domain1" | sendmail
Configuring IMAP and POP3
So far, our operations have been focused on the box which runs the server itself. Now we need to setup some interaction related configuration. Since security is important we will setup some nice authentication modes, which doesn't send cleartext passwords. Courier supports CRAM-MD5 among others. You will have to make sure that your clients support that too. So far I tested sylpheed-claws > 1.0.4, esmtp and Thunderbird with these settings.
Now it comes in, that we will have to configure the several server daemons. Courier is already running (from the perftest above) but it doesn't provide services to the network. So we have to configure esmtpd, pop3d and imapd with their respective configuration files in
Since we like to use SMTPAuth instead if a IP/Domain based SMTP authentication we need to activate the AUTHREQUIRED option in esmtpd. Also we activate the CRAM-MD5 challenge method for authorization. NOTE: this setup definitely keeps Outlook losers out. For these buggy and old fashioned clients you will need to use way less restrictive settings!
The imapd setting is a bit different. In
/etc/courier/imapd there is a long line starting with IMAP_CAPABILITY. Just add a "AUTH=CRAM-MD5" at the end of the arguments and you should be done:
Because of our very small test case with just two boxes and no domain control we have to take a look at Courier's intrinsics and work around a little issue. Courier is nitpicking about RFC compliance, which does mean you have to make sure that you understand how to configure your e-mail clients for testing. This will fail in our testing:
+------------+ +---------------+ +-------------------+ |local laptop| -------> |local box(with | ------------> | MTA somewhere on | +------------+ | courier-mta) | | web | +---------------+ +-------------------+
Why? Because you send from a non-valid domain name. I assume here, that we use our "domain1" and "domain2" testpark. Now, when you create an account in Sylpheed which looks like this: Name: user numberone Address: user1@domain1 Sylpheed consequently sends the mail as "user numberone <user1@domain1>". This is wrong, since it violates the RFC. You get a Error: 517 - Syntax Error. For the testing you can simply fool Courier-MTA by setting the domain in sylpheed's dialog to: Address: firstname.lastname@example.org
Something similar (you just get Error 513 - Syntax Error) happens in this case:
+--------------------------+ +------------------------+ |local laptop | -------> |local MTA (courier-mta) | | sylpheed account | | MTA delivers to | | email@example.com sends | | user2@domain2 | | to user2@domain2 | +------------------------+ +--------------------------+
because domain2 is not valid. You can send to mail.domain2 which will work around that. For boxes at the internet and properly configured domains this is absolutely no problem, since you are always part of a domain and thus have one dot (.) behind the @.