postgres_fdw module provides the foreign-data wrapper
postgres_fdw, which can be used to access data stored in external PostgreSQL servers.
The functionality provided by this module overlaps substantially with the functionality of the older dblink module. But
postgres_fdw provides more transparent and standards-compliant syntax for accessing remote tables, and can give better performance in many cases.
To prepare for remote access using
postgres_fdw extension using CREATE EXTENSION.
Create a foreign server object, using CREATE SERVER, to represent each remote database you want to connect to. Specify connection information, except
password, as options of the server object.
Create a user mapping, using CREATE USER MAPPING, for each database user you want to allow to access each foreign server. Specify the remote user name and password to use as
password options of the user mapping.
Create a foreign table, using CREATE FOREIGN TABLE or IMPORT FOREIGN SCHEMA, for each remote table you want to access. The columns of the foreign table must match the referenced remote table. You can, however, use table and/or column names different from the remote table's, if you specify the correct remote names as options of the foreign table object.
Now you need only
SELECT from a foreign table to access the data stored in its underlying remote table. You can also modify the remote table using
DELETE. (Of course, the remote user you have specified in your user mapping must have privileges to do these things.)
postgres_fdw currently lacks support for
INSERT statements with an
ON CONFLICT DO UPDATE clause. However, the
ON CONFLICT DO NOTHING clause is supported, provided a unique index inference specification is omitted.
It is generally recommended that the columns of a foreign table be declared with exactly the same data types, and collations if applicable, as the referenced columns of the remote table. Although
postgres_fdw is currently rather forgiving about performing data type conversions at need, surprising semantic anomalies may arise when types or collations do not match, due to the remote server interpreting
WHERE clauses slightly differently from the local server.
Note that a foreign table can be declared with fewer columns, or with a different column order, than its underlying remote table has. Matching of columns to the remote table is by name, not position.
A foreign server using the
postgres_fdw foreign data wrapper can have the same options that libpq accepts in connection strings, as described in Section 33.1.2, except that these options are not allowed:
password (specify these in a user mapping, instead)
client_encoding (this is automatically set from the local server encoding)
fallback_application_name (always set to
Only superusers may connect to foreign servers without password authentication, so always specify the
password option for user mappings belonging to non-superusers.
These options can be used to control the names used in SQL statements sent to the remote PostgreSQL server. These options are needed when a foreign table is created with names different from the underlying remote table's names.
This option, which can be specified for a foreign table, gives the schema name to use for the foreign table on the remote server. If this option is omitted, the name of the foreign table's schema is used.
This option, which can be specified for a foreign table, gives the table name to use for the foreign table on the remote server. If this option is omitted, the foreign table's name is used.
This option, which can be specified for a column of a foreign table, gives the column name to use for the column on the remote server. If this option is omitted, the column's name is used.
postgres_fdw retrieves remote data by executing queries against remote servers, so ideally the estimated cost of scanning a foreign table should be whatever it costs to be done on the remote server, plus some overhead for communication. The most reliable way to get such an estimate is to ask the remote server and then add something for overhead — but for simple queries, it may not be worth the cost of an additional remote query to get a cost estimate. So
postgres_fdw provides the following options to control how cost estimation is done:
This option, which can be specified for a foreign table or a foreign server, controls whether
postgres_fdw issues remote
EXPLAIN commands to obtain cost estimates. A setting for a foreign table overrides any setting for its server, but only for that table. The default is
This option, which can be specified for a foreign server, is a numeric value that is added to the estimated startup cost of any foreign-table scan on that server. This represents the additional overhead of establishing a connection, parsing and planning the query on the remote side, etc. The default value is
This option, which can be specified for a foreign server, is a numeric value that is used as extra cost per-tuple for foreign-table scans on that server. This represents the additional overhead of data transfer between servers. You might increase or decrease this number to reflect higher or lower network delay to the remote server. The default value is
use_remote_estimate is true,
postgres_fdw obtains row count and cost estimates from the remote server and then adds
fdw_tuple_cost to the cost estimates. When
use_remote_estimate is false,
postgres_fdw performs local row count and cost estimation and then adds
fdw_tuple_cost to the cost estimates. This local estimation is unlikely to be very accurate unless local copies of the remote table's statistics are available. Running ANALYZE on the foreign table is the way to update the local statistics; this will perform a scan of the remote table and then calculate and store statistics just as though the table were local. Keeping local statistics can be a useful way to reduce per-query planning overhead for a remote table — but if the remote table is frequently updated, the local statistics will soon be obsolete.
By default, only
WHERE clauses using built-in operators and functions will be considered for execution on the remote server. Clauses involving non-built-in functions are checked locally after rows are fetched. If such functions are available on the remote server and can be relied on to produce the same results as they do locally, performance can be improved by sending such
WHERE clauses for remote execution. This behavior can be controlled using the following option:
This option is a comma-separated list of names of PostgreSQL extensions that are installed, in compatible versions, on both the local and remote servers. Functions and operators that are immutable and belong to a listed extension will be considered shippable to the remote server. This option can only be specified for foreign servers, not per-table.
When using the
extensions option, it is the user's responsibility that the listed extensions exist and behave identically on both the local and remote servers. Otherwise, remote queries may fail or behave unexpectedly.
This option specifies the number of rows
postgres_fdw should get in each fetch operation. It can be specified for a foreign table or a foreign server. The option specified on a table overrides an option specified for the server. The default is
By default all foreign tables using
postgres_fdw are assumed to be updatable. This may be overridden using the following option:
This option controls whether
postgres_fdw allows foreign tables to be modified using
DELETE commands. It can be specified for a foreign table or a foreign server. A table-level option overrides a server-level option. The default is
Of course, if the remote table is not in fact updatable, an error would occur anyway. Use of this option primarily allows the error to be thrown locally without querying the remote server. Note however that the
information_schema views will report a
postgres_fdw foreign table to be updatable (or not) according to the setting of this option, without any check of the remote server.
postgres_fdw is able to import foreign table definitions using IMPORT FOREIGN SCHEMA. This command creates foreign table definitions on the local server that match tables or views present on the remote server. If the remote tables to be imported have columns of user-defined data types, the local server must have compatible types of the same names.
Importing behavior can be customized with the following options (given in the
IMPORT FOREIGN SCHEMA command):
This option controls whether column
COLLATE options are included in the definitions of foreign tables imported from a foreign server. The default is
true. You might need to turn this off if the remote server has a different set of collation names than the local server does, which is likely to be the case if it's running on a different operating system.
This option controls whether column
DEFAULT expressions are included in the definitions of foreign tables imported from a foreign server. The default is
false. If you enable this option, be wary of defaults that might get computed differently on the local server than they would be on the remote server;
nextval() is a common source of problems. The
IMPORT will fail altogether if an imported default expression uses a function or operator that does not exist locally.
This option controls whether column
NOT NULL constraints are included in the definitions of foreign tables imported from a foreign server. The default is
Note that constraints other than
NOT NULL will never be imported from the remote tables. Although PostgreSQL does support
CHECK constraints on foreign tables, there is no provision for importing them automatically, because of the risk that a constraint expression could evaluate differently on the local and remote servers. Any such inconsistency in the behavior of a
CHECK constraint could lead to hard-to-detect errors in query optimization. So if you wish to import
CHECK constraints, you must do so manually, and you should verify the semantics of each one carefully. For more detail about the treatment of
CHECK constraints on foreign tables, see CREATE FOREIGN TABLE.
Tables or foreign tables which are partitions of some other table are automatically excluded. Partitioned tables are imported, unless they are a partition of some other table. Since all data can be accessed through the partitioned table which is the root of the partitioning hierarchy, this approach should allow access to all the data without creating extra objects.
postgres_fdw establishes a connection to a foreign server during the first query that uses a foreign table associated with the foreign server. This connection is kept and re-used for subsequent queries in the same session. However, if multiple user identities (user mappings) are used to access the foreign server, a connection is established for each user mapping.
During a query that references any remote tables on a foreign server,
postgres_fdw opens a transaction on the remote server if one is not already open corresponding to the current local transaction. The remote transaction is committed or aborted when the local transaction commits or aborts. Savepoints are similarly managed by creating corresponding remote savepoints.
The remote transaction uses
SERIALIZABLE isolation level when the local transaction has
SERIALIZABLE isolation level; otherwise it uses
REPEATABLE READ isolation level. This choice ensures that if a query performs multiple table scans on the remote server, it will get snapshot-consistent results for all the scans. A consequence is that successive queries within a single transaction will see the same data from the remote server, even if concurrent updates are occurring on the remote server due to other activities. That behavior would be expected anyway if the local transaction uses
REPEATABLE READ isolation level, but it might be surprising for a
READ COMMITTED local transaction. A future PostgreSQL release might modify these rules.
Note that it is currently not supported by
postgres_fdw to prepare the remote transaction for two-phase commit.
postgres_fdw attempts to optimize remote queries to reduce the amount of data transferred from foreign servers. This is done by sending query
WHERE clauses to the remote server for execution, and by not retrieving table columns that are not needed for the current query. To reduce the risk of misexecution of queries,
WHERE clauses are not sent to the remote server unless they use only data types, operators, and functions that are built-in or belong to an extension that's listed in the foreign server's
extensions option. Operators and functions in such clauses must be
IMMUTABLE as well. For an
postgres_fdw attempts to optimize the query execution by sending the whole query to the remote server if there are no query
WHERE clauses that cannot be sent to the remote server, no local joins for the query, no row-level local
AFTER triggers on the target table, and no
CHECK OPTION constraints from parent views. In
UPDATE, expressions to assign to target columns must use only built-in data types,
IMMUTABLE operators, or
IMMUTABLE functions, to reduce the risk of misexecution of the query.
postgres_fdw encounters a join between foreign tables on the same foreign server, it sends the entire join to the foreign server, unless for some reason it believes that it will be more efficient to fetch rows from each table individually, or unless the table references involved are subject to different user mappings. While sending the
JOIN clauses, it takes the same precautions as mentioned above for the
The query that is actually sent to the remote server for execution can be examined using
In the remote sessions opened by
postgres_fdw, the search_path parameter is set to just
pg_catalog, so that only built-in objects are visible without schema qualification. This is not an issue for queries generated by
postgres_fdw itself, because it always supplies such qualification. However, this can pose a hazard for functions that are executed on the remote server via triggers or rules on remote tables. For example, if a remote table is actually a view, any functions used in that view will be executed with the restricted search path. It is recommended to schema-qualify all names in such functions, or else attach
SET search_path options (see CREATE FUNCTION) to such functions to establish their expected search path environment.
postgres_fdw likewise establishes remote session settings for various parameters:
These are less likely to be problematic than
search_path, but can be handled with function
SET options if the need arises.
It is not recommended that you override this behavior by changing the session-level settings of these parameters; that is likely to cause
postgres_fdw to malfunction.
postgres_fdw can be used with remote servers dating back to PostgreSQL 8.3. Read-only capability is available back to 8.1. A limitation however is that
postgres_fdw generally assumes that immutable built-in functions and operators are safe to send to the remote server for execution, if they appear in a
WHERE clause for a foreign table. Thus, a built-in function that was added since the remote server's release might be sent to it for execution, resulting in “function does not exist” or a similar error. This type of failure can be worked around by rewriting the query, for example by embedding the foreign table reference in a sub-
OFFSET 0 as an optimization fence, and placing the problematic function or operator outside the sub-
Here is an example of creating a foreign table with
postgres_fdw. First install the extension:
CREATE EXTENSION postgres_fdw;
Then create a foreign server using CREATE SERVER. In this example we wish to connect to a PostgreSQL server on host
188.8.131.52 listening on port
5432. The database to which the connection is made is named
foreign_db on the remote server:
CREATE SERVER foreign_server FOREIGN DATA WRAPPER postgres_fdw OPTIONS (host '184.108.40.206', port '5432', dbname 'foreign_db');
A user mapping, defined with CREATE USER MAPPING, is needed as well to identify the role that will be used on the remote server:
CREATE USER MAPPING FOR local_user SERVER foreign_server OPTIONS (user 'foreign_user', password 'password');
Now it is possible to create a foreign table with CREATE FOREIGN TABLE. In this example we wish to access the table named
some_schema.some_table on the remote server. The local name for it will be
CREATE FOREIGN TABLE foreign_table ( id integer NOT NULL, data text ) SERVER foreign_server OPTIONS (schema_name 'some_schema', table_name 'some_table');
It's essential that the data types and other properties of the columns declared in
CREATE FOREIGN TABLE match the actual remote table. Column names must match as well, unless you attach
column_name options to the individual columns to show how they are named in the remote table. In many cases, use of IMPORT FOREIGN SCHEMA is preferable to constructing foreign table definitions manually.
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