Table 6-27 shows several
functions that extract session and system information.
Table 6-27. Session Information Functions
| Name | Return Type | Description |
|---|
| current_database() | name | name of current database |
| current_schema() | name | name of current schema |
| current_schemas(boolean) | name[] | names of schemas in search path optionally including implicit schemas |
| current_user | name | user name of current execution context |
| session_user | name | session user name |
| user | name | equivalent to current_user |
| version | text | PostgreSQL version information |
The session_user is the user that initiated a
database connection; it is fixed for the duration of that
connection. The current_user is the user identifier
that is applicable for permission checking. Normally, it is equal
to the session user, but it changes during the execution of
functions with the attribute SECURITY DEFINER.
In Unix parlance, the session user is the "real user" and
the current user is the "effective user".
Note: current_user, session_user, and
user have special syntactic status in SQL:
they must be called without trailing parentheses.
current_schema returns the name of the schema that is
at the front of the search path (or a null value if the search path is
empty). This is the schema that will be used for any tables or
other named objects that are created without specifying a target schema.
current_schemas(boolean) returns an array of the names of all
schemas presently in the search path. The boolean option determines whether or not
implicitly included system schemas such as pg_catalog are included in the search
path returned.
The search path may be altered by a run-time setting. The
command to use is SET SEARCH_PATH 'schema'[,'schema']...
version() returns a string describing the PostgreSQL
server's version.
Table 6-28 shows the functions
available to query and alter run-time configuration parameters.
Table 6-28. Configuration Settings Information Functions
| Name | Return Type | Description |
|---|
| current_setting(setting_name)
| text | value of current setting |
| set_config(setting_name,
new_value,
is_local)
| text | new value of current setting |
The current_setting is used to obtain the current
value of the setting_name setting, as a query
result. It is the equivalent to the SQL SHOW command.
For example:
select current_setting('DateStyle');
current_setting
---------------------------------------
ISO with US (NonEuropean) conventions
(1 row)
set_config allows the setting_name
setting to be changed to new_value.
If is_local is set to true,
the new value will only apply to the current transaction. If you want
the new value to apply for the current session, use
false instead. It is the equivalent to the SQL
SET command. For example:
select set_config('show_statement_stats','off','f');
set_config
------------
off
(1 row)
Table 6-29 lists functions that
allow the user to query object access privileges programmatically.
See Section 2.7 for more information about
privileges.
Table 6-29. Access Privilege Inquiry Functions
| Name | Return Type | Description |
|---|
| has_table_privilege(user,
table,
access)
| boolean | does user have access to table |
| has_table_privilege(table,
access)
| boolean | does current user have access to table |
| has_database_privilege(user,
database,
access)
| boolean | does user have access to database |
| has_database_privilege(database,
access)
| boolean | does current user have access to database |
| has_function_privilege(user,
function,
access)
| boolean | does user have access to function |
| has_function_privilege(function,
access)
| boolean | does current user have access to function |
| has_language_privilege(user,
language,
access)
| boolean | does user have access to language |
| has_language_privilege(language,
access)
| boolean | does current user have access to language |
| has_schema_privilege(user,
schema,
access)
| boolean | does user have access to schema |
| has_schema_privilege(schema,
access)
| boolean | does current user have access to schema |
has_table_privilege checks whether a user
can access a table in a particular way. The user can be
specified by name or by ID
(pg_user.usesysid), or if the argument is
omitted
current_user is assumed. The table can be specified
by name or by OID. (Thus, there are actually six variants of
has_table_privilege, which can be distinguished by
the number and types of their arguments.) When specifying by name,
the name can be schema-qualified if necessary.
The desired access type
is specified by a text string, which must evaluate to one of the
values SELECT, INSERT, UPDATE,
DELETE, RULE, REFERENCES, or
TRIGGER. (Case of the string is not significant, however.)
An example is:
SELECT has_table_privilege('myschema.mytable', 'select');
has_database_privilege checks whether a user
can access a database in a particular way. The possibilities for its
arguments are analogous to has_table_privilege.
The desired access type must evaluate to
CREATE,
TEMPORARY, or
TEMP (which is equivalent to
TEMPORARY).
has_function_privilege checks whether a user
can access a function in a particular way. The possibilities for its
arguments are analogous to has_table_privilege.
When specifying a function by a text string rather than by OID,
the allowed input is the same as for the regprocedure data type.
The desired access type must currently evaluate to
EXECUTE.
has_language_privilege checks whether a user
can access a procedural language in a particular way. The possibilities
for its arguments are analogous to has_table_privilege.
The desired access type must currently evaluate to
USAGE.
has_schema_privilege checks whether a user
can access a schema in a particular way. The possibilities for its
arguments are analogous to has_table_privilege.
The desired access type must evaluate to
CREATE or
USAGE.
Table 6-30 shows functions that
determine whether a certain object is visible in the
current schema search path. A table is said to be visible if its
containing schema is in the search path and no table of the same
name appears earlier in the search path. This is equivalent to the
statement that the table can be referenced by name without explicit
schema qualification. For example, to list the names of all
visible tables:
SELECT relname FROM pg_class WHERE pg_table_is_visible(oid);
Table 6-30. Schema Visibility Inquiry Functions
| Name | Return Type | Description |
|---|
| pg_table_is_visible(tableOID)
| boolean | is table visible in search path |
| pg_type_is_visible(typeOID)
| boolean | is type visible in search path |
| pg_function_is_visible(functionOID)
| boolean | is function visible in search path |
| pg_operator_is_visible(operatorOID)
| boolean | is operator visible in search path |
| pg_opclass_is_visible(opclassOID)
| boolean | is operator class visible in search path |
pg_table_is_visible performs the check for
tables (or views, or any other kind of pg_class entry).
pg_type_is_visible,
pg_function_is_visible,
pg_operator_is_visible, and
pg_opclass_is_visible perform the same sort of
visibility check for types, functions, operators, and operator
classes, respectively. For functions and operators, an object in
the search path is visible if there is no object of the same name
and argument data type(s) earlier in the path. For
operator classes, both name and associated index access method are
considered.
All these functions require object OIDs to identify the object to be
checked. If you want to test an object by name, it is convenient to use
the OID alias types (regclass, regtype,
regprocedure, or regoperator), for example
SELECT pg_type_is_visible('myschema.widget'::regtype);
Note that it would not make much sense to test an unqualified name in
this way --- if the name can be recognized at all, it must be visible.
Table 6-31 lists functions that
extract information from the system catalogs.
pg_get_viewdef(),
pg_get_ruledef(),
pg_get_indexdef(), and
pg_get_constraintdef() respectively
reconstruct the creating command for a view, rule, index, or
constraint. (Note that this is a decompiled reconstruction, not
the verbatim text of the command.) At present
pg_get_constraintdef() only works for
foreign-key constraints. pg_get_userbyid()
extracts a user's name given a usesysid
value.
Table 6-31. Catalog Information Functions
| Name | Return Type | Description |
|---|
| pg_get_viewdef(viewname) | text | Get CREATE VIEW command for view (deprecated) |
| pg_get_viewdef(viewOID) | text | Get CREATE VIEW command for view |
| pg_get_ruledef(ruleOID) | text | Get CREATE RULE command for rule |
| pg_get_indexdef(indexOID) | text | Get CREATE INDEX command for index |
| pg_get_constraintdef(constraintOID) | text | Get definition of a constraint |
| pg_get_userbyid(userid) | name | Get user name with given ID |
The function shown in Table 6-32 extract comments
previously stored with the COMMENT command. A
null value is returned if no comment can be found matching the
specified parameters.
Table 6-32. Comment Information Functions
| Name | Return Type | Description |
|---|
| obj_description(objectOID, tablename) | text | Get comment for a database object |
| obj_description(objectOID) | text | Get comment for a database object (deprecated) |
| col_description(tableOID, columnnumber) | text | Get comment for a table column |
The two-parameter form of obj_description() returns the
comment for a database object specified by its OID and the name of the
containing system catalog. For example,
obj_description(123456,'pg_class')
would retrieve the comment for a table with OID 123456.
The one-parameter form of obj_description() requires only
the object OID. It is now deprecated since there is no guarantee that
OIDs are unique across different system catalogs; therefore, the wrong
comment could be returned.
col_description() returns the comment for a table column,
which is specified by the OID of its table and its column number.
obj_description() cannot be used for table columns since
columns do not have OIDs of their own.
