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PPoossttffiixx LLooookkuupp TTaabbllee OOvveerrvviieeww
-------------------------------------------------------------------------------
OOvveerrvviieeww
This document covers the following topics:
* The Postfix lookup table model
* Postfix lists versus tables
* Preparing Postfix for LDAP or SQL lookups
* Maintaining Postfix lookup table files
* Updating Berkeley DB files safely
* Postfix lookup table types
TThhee PPoossttffiixx llooookkuupp ttaabbllee mmooddeell
Postfix uses lookup tables to store and look up information for access control,
address rewriting and even for content filtering. All Postfix lookup tables are
specified as "type:table", where "type" is one of the database types described
under "Postfix lookup table types" at the end of this document, and where
"table" is the lookup table name. The Postfix documentation uses the terms
"database" and "lookup table" for the same thing.
Examples of lookup tables that appear often in the Postfix documentation:
/etc/postfix/main.cf:
alias_maps = hash:/etc/postfix/aliases (local aliasing)
header_checks = regexp:/etc/postfix/header_checks (content filtering)
transport_maps = hash:/etc/postfix/transport (routing table)
virtual_alias_maps = hash:/etc/postfix/virtual (address rewriting)
All Postfix lookup tables store information as (key, value) pairs. This
interface may seem simplistic at first, but it turns out to be very powerful.
The (key, value) query interface completely hides the complexities of LDAP or
SQL from Postfix. This is a good example of connecting complex systems with
simple interfaces.
Benefits of the Postfix (key, value) query interface:
* You can implement Postfix lookup tables first with local Berkeley DB files
and then switch to LDAP or MySQL without any impact on the Postfix
configuration itself, as described under "Preparing Postfix for LDAP or SQL
lookups" below.
* You can use Berkeley DB files with fixed lookup strings for simple address
rewriting operations and you can use regular expression tables for the more
complicated work. In other words, you don't have to put everything into the
same table.
PPoossttffiixx lliissttss vveerrssuuss ttaabblleess
Most Postfix lookup tables are used to look up information. Examples are
address rewriting (the lookup string is the old address, and the result is the
new address) or access control (the lookup string is the client, sender or
recipient, and the result is an action such as "reject").
With some tables, however, Postfix needs to know only if the lookup key exists.
Any non-empty lookup result value may be used here: the lookup result is not
used. Examples are the local_recipient_maps that determine what local
recipients Postfix accepts in mail from the network, the mydestination
parameter that specifies what domains Postfix delivers locally, or the
mynetworks parameter that specifies the IP addresses of trusted clients or
client networks. Technically, these are lists, not tables. Despite the
difference, Postfix lists are described here because they use the same
underlying infrastructure as Postfix lookup tables.
PPrreeppaarriinngg PPoossttffiixx ffoorr LLDDAAPP oorr SSQQLL llooookkuuppss
LDAP and SQL are complex systems. Trying to set up both Postfix and LDAP or SQL
at the same time is definitely not a good idea. You can save yourself a lot of
time by implementing Postfix first with local files such as Berkeley DB. Local
files have few surprises, and are easy to debug with the postmap(1) command:
% ppoossttmmaapp --qq iinnffoo@@eexxaammppllee..ccoomm hhaasshh:://eettcc//ppoossttffiixx//vviirrttuuaall
Once you have local files working properly you can follow the instructions in
ldap_table(5), mysql_table(5), pgsql_table(5) or sqlite_table(5) and replace
local file lookups with LDAP or SQL lookups. When you do this, you should use
the postmap(1) command again, to verify that database lookups still produce the
exact same results as local file lookup:
% ppoossttmmaapp --qq iinnffoo@@eexxaammppllee..ccoomm llddaapp:://eettcc//ppoossttffiixx//vviirrttuuaall..ccff
Be sure to exercise all the partial address or parent domain queries that are
documented under "table search order" in the relevant manual page: access(5),
canonical(5), virtual(5), transport(5), or under the relevant configuration
parameter: mynetworks, relay_domains, parent_domain_matches_subdomains.
MMaaiinnttaaiinniinngg PPoossttffiixx llooookkuupp ttaabbllee ffiilleess
When you make changes to a database while the mail system is running, it would
be desirable if Postfix avoids reading information while that information is
being changed. It would also be nice if you can change a database without
having to execute "postfix reload", in order to force Postfix to use the new
information. Each time you do "postfix reload" Postfix loses a lot of
performance.
* If you change a network database such as LDAP, NIS or SQL, there is no need
to execute "postfix reload". The LDAP, NIS or SQL server takes care of
read/write access conflicts and gives the new data to Postfix once that
data is available.
* If you change a regexp:, pcre:, cidr: or texthash: file then Postfix may
not pick up the file changes immediately. This is because a Postfix process
reads the entire file into memory once and never examines the file again.
o If the file is used by a short-running process such as smtpd(8),
cleanup(8) or local(8), there is no need to execute "postfix reload"
after making a change.
o If the file is being used by a long-running process such as trivial-
rewrite(8) on a busy server it may be necessary to execute "postfix
reload".
* If you change a local file based database such as DBM or Berkeley DB, there
is no need to execute "postfix reload". Postfix uses file locking to avoid
read/write access conflicts, and whenever a Postfix daemon process notices
that a file has changed it will terminate before handling the next client
request, so that a new process can initialize with the new database.
UUppddaattiinngg BBeerrkkeelleeyy DDBB ffiilleess ssaaffeellyy
Postfix uses file locking to avoid access conflicts while updating Berkeley DB
or other local database files. This used to be safe, but as Berkeley DB has
evolved to use more aggressive caching, file locking may no longer be
sufficient.
Furthermore, file locking would not prevent problems when the update fails
because the disk is full or something else causes a database update to fail. In
particular, commands such as postmap(1) or postalias(1) overwrite existing
files. If the overwrite fails in the middle then you have no usable database,
and Postfix will stop working. This is not an issue with the CDB database type
available with Postfix 2.2 and later: CDB creates a new file, and renames the
file upon successful completion.
With Berkeley DB and other "one file" databases, it is possible to add some
extra robustness by using "mv" to REPLACE an existing database file instead of
overwriting it:
# ppoossttmmaapp aacccceessss..iinn &&&& mmvv aacccceessss..iinn..ddbb aacccceessss..ddbb
This converts the input file "access.in" into the output file "access.in.db",
and replaces the file "access.db" only when the postmap(1) command was
successful. Of course typing such commands becomes boring quickly, and this is
why people use "make" instead, as shown below. User input is shown in bold
font.
# ccaatt MMaakkeeffiillee
all: aliases.db access.db virtual.db ...etcetera...
# Note 1: commands are specified after a TAB character.
# Note 2: use postalias(1) for local aliases, postmap(1) for the rest.
aliases.db: aliases.in
postalias aliases.in
mv aliases.in.db aliases.db
access.db: access.in
postmap access.in
mv access.in.db access.db
virtual.db: virtual.in
postmap virtual.in
mv virtual.in.db virtual.db
...etcetera...
# vvii aacccceessss..iinn
...editing session not shown...
# mmaakkee
postmap access.in
mv access.in.db access.db
#
The "make" command updates only the files that have changed. In case of error,
the "make" command will stop and will not invoke the "mv" command, so that
Postfix will keep using the existing database file as if nothing happened.
PPoossttffiixx llooookkuupp ttaabbllee ttyyppeess
To find out what database types your Postfix system supports, use the "ppoossttccoonnff
--mm" command. Here is a list of database types that are often supported:
bbttrreeee
A sorted, balanced tree structure. This is available only on systems
with support for Berkeley DB databases. Database files are created with
the postmap(1) or postalias(1) command. The lookup table name as used
in "btree:table" is the database file name without the ".db" suffix.
ccddbb
A read-optimized structure with no support for incremental updates.
Database files are created with the postmap(1) or postalias(1) command.
The lookup table name as used in "cdb:table" is the database file name
without the ".cdb" suffix. This feature is available with Postfix 2.2
and later.
cciiddrr
A table that associates values with Classless Inter-Domain Routing
(CIDR) patterns. The table format is described in cidr_table(5).
ddbbmm
An indexed file type based on hashing. This is available only on
systems with support for DBM databases. Public database files are
created with the postmap(1) or postalias(1) command, and private
databases are maintained by Postfix daemons. The lookup table name as
used in "dbm:table" is the database file name without the ".dir" or
".pag" suffix.
eennvviirroonn
The UNIX process environment array. The lookup key is the variable
name. The lookup table name in "environ:table" is ignored.
ffaaiill
A table that reliably fails all requests. The lookup table name is used
for logging only. This table exists to simplify Postfix error tests.
hhaasshh
An indexed file type based on hashing. This is available only on
systems with support for Berkeley DB databases. Public database files
are created with the postmap(1) or postalias(1) command, and private
databases are maintained by Postfix daemons. The database name as used
in "hash:table" is the database file name without the ".db" suffix.
iinnlliinnee (read-only)
A non-shared, in-memory lookup table. Example: "inline:{ key=value,
{ key = text with whitespace or comma }}". Key-value pairs are
separated by whitespace or comma; with a key-value pair inside "{}",
whitespace is ignored after the opening "{", around the "=" between key
and value, and before the closing "}". Inline tables eliminate the need
to create a database file for just a few fixed elements. See also the
static: map type.
iinntteerrnnaall
A non-shared, in-memory hash table. Its content are lost when a process
terminates.
llmmddbb
OpenLDAP LMDB database. This is available only on systems with support
for LMDB databases. Public database files are created with the postmap
(1) or postalias(1) command, and private databases are maintained by
Postfix daemons. The database name as used in "lmdb:table" is the
database file name without the ".lmdb" suffix. See lmdb_table(5) for
details.
llddaapp (read-only)
LDAP database client. Configuration details are given in the ldap_table
(5).
mmeemmccaacchhee
Memcache database client. Configuration details are given in
memcache_table(5).
mmyyssqqll (read-only)
MySQL database client. Configuration details are given in mysql_table
(5).
nneettiinnffoo (read-only)
Netinfo database client.
nniiss (read-only)
NIS database client.
nniisspplluuss (read-only)
NIS+ database client. Configuration details are given in nisplus_table
(5).
ppccrree (read-only)
A lookup table based on Perl Compatible Regular Expressions. The file
format is described in pcre_table(5). The lookup table name as used in
"pcre:table" is the name of the regular expression file.
ppiippeemmaapp (read-only)
A pipeline of lookup tables. Example: "pipemap:{type1:name1, ...,
typen:namen}". Each "pipemap:" query is given to the first table. Each
lookup result becomes the query for the next table in the pipeline, and
the last table produces the final result. When any table lookup
produces no result, the pipeline produces no result. The first and last
characters of the "pipemap:" table name must be "{" and "}". Within
these, individual maps are separated with comma or whitespace.
ppggssqqll (read-only)
PostgreSQL database client. Configuration details are given in
pgsql_table(5).
pprrooxxyy
Postfix proxymap(8) client for shared access to Postfix databases. The
lookup table name syntax is "proxy:type:table".
rraannddmmaapp (read-only)
An in-memory table that performs random selection. Example: "randmap:
{result1. ..., resultn}". Each table query returns a random choice from
the specified results. The first and last characters of the "randmap:
" table name must be "{" and "}". Within these, individual maps are
separated with comma or whitespace. To give a specific result more
weight, specify it multiple times.
rreeggeexxpp (read-only)
A lookup table based on regular expressions. The file format is
described in regexp_table(5). The lookup table name as used in "regexp:
table" is the name of the regular expression file.
ssddbbmm
An indexed file type based on hashing. This is available only on
systems with support for SDBM databases. Public database files are
created with the postmap(1) or postalias(1) command, and private
databases are maintained by Postfix daemons. The lookup table name as
used in "sdbm:table" is the database file name without the ".dir" or
".pag" suffix.
ssoocckkeettmmaapp (read-only)
Sendmail-style socketmap client. The name of the table is either iinneett:
host:port:name for a TCP/IP server, or uunniixx:pathname:name for a UNIX-
domain server. See socketmap_table(5) for details.
ssqqlliittee (read-only)
SQLite database. Configuration details are given in sqlite_table(5).
ssttaattiicc (read-only)
A table that always returns its name as the lookup result. For example,
"static:foobar" always returns the string "foobar" as lookup result.
Specify "static:{ text with whitespace }" when the result contains
whitespace; this form ignores whitespace after the opening "{" and
before the closing "}". See also the inline: map type.
ttccpp
TCP/IP client. The protocol is described in tcp_table(5). The lookup
table name is "tcp:host:port" where "host" specifies a symbolic
hostname or a numeric IP address, and "port" specifies a symbolic
service name or a numeric port number.
tteexxtthhaasshh (read-only)
A table that produces similar results as hash: files, except that you
don't have to run the postmap(1) command before you can use the file,
and that texthash: does not detect changes after the file is read. The
lookup table name is "texthash:filename", where the file name is taken
literally; no suffix is appended.
uunniioonnmmaapp (read-only)
A table that sends each query to multiple lookup tables and that
concatenates all found results, separated by comma. The table name
syntax is the same as for pipemap tables.
uunniixx (read-only)
A limited view of the UNIX authentication database. The following
tables are implemented:
uunniixx::ppaasssswwdd..bbyynnaammee
The table is the UNIX password database. The key is a login name.
The result is a password file entry in passwd(5) format.
uunniixx::ggrroouupp..bbyynnaammee
The table is the UNIX group database. The key is a group name. The
result is a group file entry in group(5) format.
Other lookup table types may be available depending on how Postfix was built.
With some Postfix distributions the list is dynamically extensible as support
for lookup tables is dynamically linked into Postfix.
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