# 21.1. The
Client authentication is controlled by a configuration file, which traditionally is named
pg_hba.conf and is stored in the database cluster's data directory. (HBA stands for host-based authentication.) A default
pg_hba.conf file is installed when the data directory is initialized by
initdb. It is possible to place the authentication configuration file elsewhere, however; see the hba_file configuration parameter.
The general format of the
pg_hba.conf file is a set of records, one per line. Blank lines are ignored, as is any text after the
# comment character. A record can be continued onto the next line by ending the line with a backslash. (Backslashes are not special except at the end of a line.) A record is made up of a number of fields which are separated by spaces and/or tabs. Fields can contain white space if the field value is double-quoted. Quoting one of the keywords in a database, user, or address field (e.g.,
replication) makes the word lose its special meaning, and just match a database, user, or host with that name. Backslash line continuation applies even within quoted text or comments.
Each record specifies a connection type, a client IP address range (if relevant for the connection type), a database name, a user name, and the authentication method to be used for connections matching these parameters. The first record with a matching connection type, client address, requested database, and user name is used to perform authentication. There is no “fall-through” or “backup”: if one record is chosen and the authentication fails, subsequent records are not considered. If no record matches, access is denied.
A record can have several formats:
local database user auth-method [auth-options] host database user address auth-method [auth-options] hostssl database user address auth-method [auth-options] hostnossl database user address auth-method [auth-options] hostgssenc database user address auth-method [auth-options] hostnogssenc database user address auth-method [auth-options] host database user IP-address IP-mask auth-method [auth-options] hostssl database user IP-address IP-mask auth-method [auth-options] hostnossl database user IP-address IP-mask auth-method [auth-options] hostgssenc database user IP-address IP-mask auth-method [auth-options] hostnogssenc database user IP-address IP-mask auth-method [auth-options]
The meaning of the fields is as follows:
This record matches connection attempts using Unix-domain sockets. Without a record of this type, Unix-domain socket connections are disallowed.
This record matches connection attempts made using TCP/IP.
host records match SSL or non-SSL connection attempts as well as GSSAPI encrypted or non-GSSAPI encrypted connection attempts.
Remote TCP/IP connections will not be possible unless the server is started with an appropriate value for the listen_addresses configuration parameter, since the default behavior is to listen for TCP/IP connections only on the local loopback address
This record matches connection attempts made using TCP/IP, but only when the connection is made with SSL encryption.
To make use of this option the server must be built with SSL support. Furthermore, SSL must be enabled by setting the ssl configuration parameter (see Section 19.9 for more information). Otherwise, the
hostssl record is ignored except for logging a warning that it cannot match any connections.
This record type has the opposite behavior of
hostssl; it only matches connection attempts made over TCP/IP that do not use SSL.
This record matches connection attempts made using TCP/IP, but only when the connection is made with GSSAPI encryption.
To make use of this option the server must be built with GSSAPI support. Otherwise, the
hostgssenc record is ignored except for logging a warning that it cannot match any connections.
This record type has the opposite behavior of
hostgssenc; it only matches connection attempts made over TCP/IP that do not use GSSAPI encryption.
Specifies which database name(s) this record matches. The value
all specifies that it matches all databases. The value
sameuser specifies that the record matches if the requested database has the same name as the requested user. The value
samerole specifies that the requested user must be a member of the role with the same name as the requested database. (
samegroup is an obsolete but still accepted spelling of
samerole.) Superusers are not considered to be members of a role for the purposes of
samerole unless they are explicitly members of the role, directly or indirectly, and not just by virtue of being a superuser. The value
replication specifies that the record matches if a physical replication connection is requested, however, it doesn't match with logical replication connections. Note that physical replication connections do not specify any particular database whereas logical replication connections do specify it. Otherwise, this is the name of a specific PostgreSQL database. Multiple database names can be supplied by separating them with commas. A separate file containing database names can be specified by preceding the file name with
Specifies which database user name(s) this record matches. The value
all specifies that it matches all users. Otherwise, this is either the name of a specific database user, or a group name preceded by
+. (Recall that there is no real distinction between users and groups in PostgreSQL; a
+ mark really means “match any of the roles that are directly or indirectly members of this role”, while a name without a
+ mark matches only that specific role.) For this purpose, a superuser is only considered to be a member of a role if they are explicitly a member of the role, directly or indirectly, and not just by virtue of being a superuser. Multiple user names can be supplied by separating them with commas. A separate file containing user names can be specified by preceding the file name with
Specifies the client machine address(es) that this record matches. This field can contain either a host name, an IP address range, or one of the special key words mentioned below.
An IP address range is specified using standard numeric notation for the range's starting address, then a slash (
/) and a CIDR mask length. The mask length indicates the number of high-order bits of the client IP address that must match. Bits to the right of this should be zero in the given IP address. There must not be any white space between the IP address, the
/, and the CIDR mask length.
Typical examples of an IPv4 address range specified this way are
172.20.143.89/32 for a single host, or
172.20.143.0/24 for a small network, or
10.6.0.0/16 for a larger one. An IPv6 address range might look like
::1/128 for a single host (in this case the IPv6 loopback address) or
fe80::7a31:c1ff:0000:0000/96 for a small network.
0.0.0.0/0 represents all IPv4 addresses, and
::0/0 represents all IPv6 addresses. To specify a single host, use a mask length of 32 for IPv4 or 128 for IPv6. In a network address, do not omit trailing zeroes.
An entry given in IPv4 format will match only IPv4 connections, and an entry given in IPv6 format will match only IPv6 connections, even if the represented address is in the IPv4-in-IPv6 range. Note that entries in IPv6 format will be rejected if the system's C library does not have support for IPv6 addresses.
You can also write
all to match any IP address,
samehost to match any of the server's own IP addresses, or
samenet to match any address in any subnet that the server is directly connected to.
If a host name is specified (anything that is not an IP address range or a special key word is treated as a host name), that name is compared with the result of a reverse name resolution of the client's IP address (e.g., reverse DNS lookup, if DNS is used). Host name comparisons are case insensitive. If there is a match, then a forward name resolution (e.g., forward DNS lookup) is performed on the host name to check whether any of the addresses it resolves to are equal to the client's IP address. If both directions match, then the entry is considered to match. (The host name that is used in
pg_hba.conf should be the one that address-to-name resolution of the client's IP address returns, otherwise the line won't be matched. Some host name databases allow associating an IP address with multiple host names, but the operating system will only return one host name when asked to resolve an IP address.)
A host name specification that starts with a dot (
.) matches a suffix of the actual host name. So
.example.com would match
foo.example.com (but not just
When host names are specified in
pg_hba.conf, you should make sure that name resolution is reasonably fast. It can be of advantage to set up a local name resolution cache such as
nscd. Also, you may wish to enable the configuration parameter
log_hostname to see the client's host name instead of the IP address in the log.
These fields do not apply to
Users sometimes wonder why host names are handled in this seemingly complicated way, with two name resolutions including a reverse lookup of the client's IP address. This complicates use of the feature in case the client's reverse DNS entry is not set up or yields some undesirable host name. It is done primarily for efficiency: this way, a connection attempt requires at most two resolver lookups, one reverse and one forward. If there is a resolver problem with some address, it becomes only that client's problem. A hypothetical alternative implementation that only did forward lookups would have to resolve every host name mentioned in
pg_hba.conf during every connection attempt. That could be quite slow if many names are listed. And if there is a resolver problem with one of the host names, it becomes everyone's problem.
Also, a reverse lookup is necessary to implement the suffix matching feature, because the actual client host name needs to be known in order to match it against the pattern.
Note that this behavior is consistent with other popular implementations of host name-based access control, such as the Apache HTTP Server and TCP Wrappers.
These two fields can be used as an alternative to the
mask-length notation. Instead of specifying the mask length, the actual mask is specified in a separate column. For example,
255.0.0.0 represents an IPv4 CIDR mask length of 8, and
255.255.255.255 represents a CIDR mask length of 32.
These fields do not apply to
Specifies the authentication method to use when a connection matches this record. The possible choices are summarized here; details are in Section 21.3.
Allow the connection unconditionally. This method allows anyone that can connect to the PostgreSQL database server to login as any PostgreSQL user they wish, without the need for a password or any other authentication. See Section 21.4 for details.
Reject the connection unconditionally. This is useful for “filtering out” certain hosts from a group, for example a
reject line could block a specific host from connecting, while a later line allows the remaining hosts in a specific network to connect.
Perform SCRAM-SHA-256 authentication to verify the user's password. See Section 21.5 for details.
Perform SCRAM-SHA-256 or MD5 authentication to verify the user's password. See Section 21.5 for details.
Require the client to supply an unencrypted password for authentication. Since the password is sent in clear text over the network, this should not be used on untrusted networks. See Section 21.5 for details.
Use GSSAPI to authenticate the user. This is only available for TCP/IP connections. See Section 21.6 for details. It can be used in conjunction with GSSAPI encryption.
Use SSPI to authenticate the user. This is only available on Windows. See Section 21.7 for details.
Obtain the operating system user name of the client by contacting the ident server on the client and check if it matches the requested database user name. Ident authentication can only be used on TCP/IP connections. When specified for local connections, peer authentication will be used instead. See Section 21.8 for details.
Obtain the client's operating system user name from the operating system and check if it matches the requested database user name. This is only available for local connections. See Section 21.9 for details.
Authenticate using an LDAP server. See Section 21.10 for details.
Authenticate using a RADIUS server. See Section 21.11 for details.
Authenticate using SSL client certificates. See Section 21.12 for details.
Authenticate using the Pluggable Authentication Modules (PAM) service provided by the operating system. See Section 21.13 for details.
Authenticate using the BSD Authentication service provided by the operating system. See Section 21.14 for details.
auth-method field, there can be field(s) of the form
value that specify options for the authentication method. Details about which options are available for which authentication methods appear below.
In addition to the method-specific options listed below, there is a method-independent authentication option
clientcert, which can be specified in any
hostssl record. This option can be set to
verify-full. Both options require the client to present a valid (trusted) SSL certificate, while
verify-full additionally enforces that the
cn (Common Name) in the certificate matches the username or an applicable mapping. This behavior is similar to the
cert authentication method (see Section 21.12) but enables pairing the verification of client certificates with any authentication method that supports
On any record using client certificate authentication (i.e. one using the
cert authentication method or one using the
clientcert option), you can specify which part of the client certificate credentials to match using the
clientname option. This option can have one of two values. If you specify
clientname=CN, which is the default, the username is matched against the certificate's
Common Name (CN). If instead you specify
clientname=DN the username is matched against the entire
Distinguished Name (DN) of the certificate. This option is probably best used in conjunction with a username map. The comparison is done with the
DN in RFC 2253 (opens new window) format. To see the
DN of a client certificate in this format, do
openssl x509 -in myclient.crt -noout --subject -nameopt RFC2253 | sed "s/^subject=//"
Care needs to be taken when using this option, especially when using regular expression matching against the
Files included by
@ constructs are read as lists of names, which can be separated by either whitespace or commas. Comments are introduced by
#, just as in
pg_hba.conf, and nested
@ constructs are allowed. Unless the file name following
@ is an absolute path, it is taken to be relative to the directory containing the referencing file.
pg_hba.conf records are examined sequentially for each connection attempt, the order of the records is significant. Typically, earlier records will have tight connection match parameters and weaker authentication methods, while later records will have looser match parameters and stronger authentication methods. For example, one might wish to use
trust authentication for local TCP/IP connections but require a password for remote TCP/IP connections. In this case a record specifying
trust authentication for connections from 127.0.0.1 would appear before a record specifying password authentication for a wider range of allowed client IP addresses.
pg_hba.conf file is read on start-up and when the main server process receives a SIGHUP signal. If you edit the file on an active system, you will need to signal the postmaster (using
pg_ctl reload, calling the SQL function
pg_reload_conf(), or using
kill -HUP) to make it re-read the file.
The preceding statement is not true on Microsoft Windows: there, any changes in the
pg_hba.conf file are immediately applied by subsequent new connections.
The system view
pg_hba_file_rules can be helpful for pre-testing changes to the
pg_hba.conf file, or for diagnosing problems if loading of the file did not have the desired effects. Rows in the view with non-null
error fields indicate problems in the corresponding lines of the file.
To connect to a particular database, a user must not only pass the
pg_hba.conf checks, but must have the
CONNECT privilege for the database. If you wish to restrict which users can connect to which databases, it's usually easier to control this by granting/revoking
CONNECT privilege than to put the rules in
Some examples of
pg_hba.conf entries are shown in Example 21.1. See the next section for details on the different authentication methods.
Example 21.1. Example
# Allow any user on the local system to connect to any database with # any database user name using Unix-domain sockets (the default for local # connections). # # TYPE DATABASE USER ADDRESS METHOD local all all trust # The same using local loopback TCP/IP connections. # # TYPE DATABASE USER ADDRESS METHOD host all all 127.0.0.1/32 trust # The same as the previous line, but using a separate netmask column # # TYPE DATABASE USER IP-ADDRESS IP-MASK METHOD host all all 127.0.0.1 255.255.255.255 trust # The same over IPv6. # # TYPE DATABASE USER ADDRESS METHOD host all all ::1/128 trust # The same using a host name (would typically cover both IPv4 and IPv6). # # TYPE DATABASE USER ADDRESS METHOD host all all localhost trust # Allow any user from any host with IP address 192.168.93.x to connect # to database "postgres" as the same user name that ident reports for # the connection (typically the operating system user name). # # TYPE DATABASE USER ADDRESS METHOD host postgres all 192.168.93.0/24 ident # Allow any user from host 192.168.12.10 to connect to database # "postgres" if the user's password is correctly supplied. # # TYPE DATABASE USER ADDRESS METHOD host postgres all 192.168.12.10/32 scram-sha-256 # Allow any user from hosts in the example.com domain to connect to # any database if the user's password is correctly supplied. # # Require SCRAM authentication for most users, but make an exception # for user 'mike', who uses an older client that doesn't support SCRAM # authentication. # # TYPE DATABASE USER ADDRESS METHOD host all mike .example.com md5 host all all .example.com scram-sha-256 # In the absence of preceding "host" lines, these three lines will # reject all connections from 192.168.54.1 (since that entry will be # matched first), but allow GSSAPI-encrypted connections from anywhere else # on the Internet. The zero mask causes no bits of the host IP address to # be considered, so it matches any host. Unencrypted GSSAPI connections # (which "fall through" to the third line since "hostgssenc" only matches # encrypted GSSAPI connections) are allowed, but only from 192.168.12.10. # # TYPE DATABASE USER ADDRESS METHOD host all all 192.168.54.1/32 reject hostgssenc all all 0.0.0.0/0 gss host all all 192.168.12.10/32 gss # Allow users from 192.168.x.x hosts to connect to any database, if # they pass the ident check. If, for example, ident says the user is # "bryanh" and he requests to connect as PostgreSQL user "guest1", the # connection is allowed if there is an entry in pg_ident.conf for map # "omicron" that says "bryanh" is allowed to connect as "guest1". # # TYPE DATABASE USER ADDRESS METHOD host all all 192.168.0.0/16 ident map=omicron # If these are the only three lines for local connections, they will # allow local users to connect only to their own databases (databases # with the same name as their database user name) except for administrators # and members of role "support", who can connect to all databases. The file # $PGDATA/admins contains a list of names of administrators. Passwords # are required in all cases. # # TYPE DATABASE USER ADDRESS METHOD local sameuser all md5 local all @admins md5 local all +support md5 # The last two lines above can be combined into a single line: local all @admins,+support md5 # The database column can also use lists and file names: local db1,db2,@demodbs all md5