| PostgreSQL 8.3.23 Documentation | ||||
|---|---|---|---|---|
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Table 9-44 shows several functions that extract session and system information.
In addition to the functions listed in this section, there are a number of functions related to the statistics system that also provide system information. See Section 26.2.2 for more information.
Table 9-44. 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 |
inet_client_addr() |
inet | address of the remote connection |
inet_client_port() |
int | port of the remote connection |
inet_server_addr() |
inet | address of the local connection |
inet_server_port() |
int | port of the local connection |
pg_my_temp_schema() |
oid | OID of session's temporary schema, or 0 if none |
pg_is_other_temp_schema(oid) |
boolean | is schema another session's temporary schema? |
pg_postmaster_start_time() |
timestamp with time zone | server start time |
session_user |
name | session user name |
user |
name | equivalent to current_user |
version() |
text | PostgreSQL version information |
The session_user is normally the
user who initiated the current database connection; but
superusers can change this setting with SET SESSION
AUTHORIZATION. The current_user
is the user identifier that is applicable for permission
checking. Normally, it is equal to the session user, but it can
be changed with SET
ROLE. It also 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, anduserhave 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.
Note: The search path can be altered at run time. The command is:
SET search_path TO schema [, schema, ...]
inet_client_addr returns the IP
address of the current client, and inet_client_port returns the port number.
inet_server_addr returns the IP
address on which the server accepted the current connection, and
inet_server_port returns the port
number. All these functions return NULL if the current connection
is via a Unix-domain socket.
pg_my_temp_schema returns the
OID of the current session's temporary schema, or 0 if it has
none (because it has not created any temporary tables).
pg_is_other_temp_schema returns
true if the given OID is the OID of any other session's temporary
schema. (This can be useful, for example, to exclude other
sessions' temporary tables from a catalog display.)
pg_postmaster_start_time returns
the timestamp with time zone when the
server started.
version returns a string
describing the PostgreSQL
server's version.
Table 9-45 lists functions that allow the user to query object access privileges programmatically. See Section 5.6 for more information about privileges.
Table 9-45. Access Privilege Inquiry Functions
| Name | Return Type | Description |
|---|---|---|
has_database_privilege(user, database, privilege) |
boolean | does user have privilege for database |
has_database_privilege(database, privilege) |
boolean | does current user have privilege for database |
has_function_privilege(user, function, privilege) |
boolean | does user have privilege for function |
has_function_privilege(function, privilege) |
boolean | does current user have privilege for function |
has_language_privilege(user, language, privilege) |
boolean | does user have privilege for language |
has_language_privilege(language, privilege) |
boolean | does current user have privilege for language |
has_schema_privilege(user, schema,
privilege) |
boolean | does user have privilege for schema |
has_schema_privilege(schema, privilege) |
boolean | does current user have privilege for schema |
has_table_privilege(user, table,
privilege) |
boolean | does user have privilege for table |
has_table_privilege(table, privilege) |
boolean | does current user have privilege for table |
has_tablespace_privilege(user, tablespace, privilege) |
boolean | does user have privilege for tablespace |
has_tablespace_privilege(tablespace, privilege) |
boolean | does current user have privilege for tablespace |
pg_has_role(user, role,
privilege) |
boolean | does user have privilege for role |
pg_has_role(role, privilege) |
boolean | does current user have privilege for role |
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
privilege type must evaluate to CREATE,
CONNECT, 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 (see
Section 8.16). The desired access
privilege type must evaluate to EXECUTE.
An example is:
SELECT has_function_privilege('joeuser', 'myfunc(int, text)', '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 privilege type must 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
privilege type must evaluate to CREATE
or USAGE.
has_table_privilege checks
whether a user can access a table in a particular way. The user
can be specified by name or by OID (pg_authid.oid), 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 privilege type
is specified by a text string, which must evaluate to one of the
values SELECT, INSERT, UPDATE,
DELETE, REFERENCES, or TRIGGER.
(Case of the string is not significant, however.) An example
is:
SELECT has_table_privilege('myschema.mytable', 'select');
has_tablespace_privilege checks
whether a user can access a tablespace in a particular way. The
possibilities for its arguments are analogous to has_table_privilege. The desired access
privilege type must evaluate to CREATE.
pg_has_role checks whether a
user can access a role in a particular way. The possibilities for
its arguments are analogous to has_table_privilege. The desired access
privilege type must evaluate to MEMBER
or USAGE. MEMBER denotes direct or indirect membership in
the role (that is, the right to do SET
ROLE), while USAGE denotes whether
the privileges of the role are immediately available without
doing SET ROLE.
To test whether a user holds a grant option on the privilege, append WITH GRANT OPTION to the privilege key word; for example 'UPDATE WITH GRANT OPTION'.
Table 9-46 shows functions that determine whether a certain object is visible in the current schema search path. For example, 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. To list the names of all visible tables:
SELECT relname FROM pg_class WHERE pg_table_is_visible(oid);
Table 9-46. Schema Visibility Inquiry Functions
| Name | Return Type | Description |
|---|---|---|
pg_conversion_is_visible(conversion_oid) |
boolean | is conversion visible in search path |
pg_function_is_visible(function_oid) |
boolean | is function visible in search path |
pg_operator_is_visible(operator_oid) |
boolean | is operator visible in search path |
pg_opclass_is_visible(opclass_oid) |
boolean | is operator class visible in search path |
pg_table_is_visible(table_oid) |
boolean | is table visible in search path |
pg_ts_config_is_visible(config_oid) |
boolean | is text search configuration visible in search path |
pg_ts_dict_is_visible(dict_oid) |
boolean | is text search dictionary visible in search path |
pg_ts_parser_is_visible(parser_oid) |
boolean | is text search parser visible in search path |
pg_ts_template_is_visible(template_oid) |
boolean | is text search template visible in search path |
pg_type_is_visible(type_oid) |
boolean | is type (or domain) visible in search path |
Each function performs the visibility check for one type of
database object. Note that pg_table_is_visible can also be used with
views, indexes and sequences; pg_type_is_visible can also be used with
domains. 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, regoperator, regconfig, or regdictionary), 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 9-47 lists functions that extract information from the system catalogs.
Table 9-47. System Catalog Information Functions
| Name | Return Type | Description |
|---|---|---|
format_type(type_oid, typemod) |
text | get SQL name of a data type |
pg_get_constraintdef(constraint_oid) |
text | get definition of a constraint |
pg_get_constraintdef(constraint_oid, pretty_bool) |
text | get definition of a constraint |
pg_get_expr(expr_text, relation_oid) |
text | decompile internal form of an expression, assuming that any Vars in it refer to the relation indicated by the second parameter |
pg_get_expr(expr_text, relation_oid, pretty_bool) |
text | decompile internal form of an expression, assuming that any Vars in it refer to the relation indicated by the second parameter |
pg_get_indexdef(index_oid) |
text | get CREATE INDEX command for index |
pg_get_indexdef(index_oid, column_no, pretty_bool) |
text | get CREATE INDEX command for index, or definition of just one index column when column_no is not zero |
pg_get_ruledef(rule_oid) |
text | get CREATE RULE command for rule |
pg_get_ruledef(rule_oid, pretty_bool) |
text | get CREATE RULE command for rule |
pg_get_serial_sequence(table_name, column_name) |
text | get name of the sequence that a serial or bigserial column uses |
pg_get_triggerdef(trigger_oid) |
text | get CREATE [ CONSTRAINT ] TRIGGER command for trigger |
pg_get_userbyid(roleid) |
name | get role name with given ID |
pg_get_viewdef(view_name) |
text | get underlying SELECT command for view (deprecated) |
pg_get_viewdef(view_name, pretty_bool) |
text | get underlying SELECT command for view (deprecated) |
pg_get_viewdef(view_oid) |
text | get underlying SELECT command for view |
pg_get_viewdef(view_oid, pretty_bool) |
text | get underlying SELECT command for view |
pg_tablespace_databases(tablespace_oid) |
setof oid | get the set of database OIDs that have objects in the tablespace |
format_type returns the SQL name
of a data type that is identified by its type OID and possibly a
type modifier. Pass NULL for the type modifier if no specific
modifier is known.
pg_get_constraintdef,
pg_get_indexdef, pg_get_ruledef, and pg_get_triggerdef, respectively reconstruct the
creating command for a constraint, index, rule, or trigger. (Note
that this is a decompiled reconstruction, not the original text
of the command.) pg_get_expr
decompiles the internal form of an individual expression, such as
the default value for a column. It can be useful when examining
the contents of system catalogs. pg_get_viewdef reconstructs the SELECT query that defines a view. Most of these
functions come in two variants, one of which can optionally
"pretty-print" the result. The
pretty-printed format is more readable, but the default format is
more likely to be interpreted the same way by future versions of
PostgreSQL; avoid using
pretty-printed output for dump purposes. Passing false for the pretty-print parameter yields the
same result as the variant that does not have the parameter at
all.
pg_get_serial_sequence returns
the name of the sequence associated with a column, or NULL if no
sequence is associated with the column. The first input parameter
is a table name with optional schema, and the second parameter is
a column name. Because the first parameter is potentially a
schema and table, it is not treated as a double-quoted
identifier, meaning it is lowercased by default, while the second
parameter, being just a column name, is treated as double-quoted
and has its case preserved. The function returns a value suitably
formatted for passing to the sequence functions (see Section 9.15). This association can
be modified or removed with ALTER SEQUENCE
OWNED BY. (The function probably should have been called
pg_get_owned_sequence; its name
reflects the fact that it's typically used with serial or bigserial
columns.)
pg_get_userbyid extracts a
role's name given its OID.
pg_tablespace_databases allows a
tablespace to be examined. It returns the set of OIDs of
databases that have objects stored in the tablespace. If this
function returns any rows, the tablespace is not empty and cannot
be dropped. To display the specific objects populating the
tablespace, you will need to connect to the databases identified
by pg_tablespace_databases and
query their pg_class
catalogs.
The functions shown in Table 9-48 extract comments previously stored with the COMMENT command. A null value is returned if no comment could be found matching the specified parameters.
Table 9-48. Comment Information Functions
| Name | Return Type | Description |
|---|---|---|
col_description(table_oid, column_number) |
text | get comment for a table column |
obj_description(object_oid, catalog_name) |
text | get comment for a database object |
obj_description(object_oid) |
text | get comment for a database object (deprecated) |
shobj_description(object_oid, catalog_name) |
text | get comment for a shared database object |
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.
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.
shobj_description is used just
like obj_description only that it
is used for retrieving comments on shared objects. Some system
catalogs are global to all databases within each cluster and
their descriptions are stored globally as well.
The functions shown in Table 9-49 export server internal transaction information to user level. The main use of these functions is to determine which transactions were committed between two snapshots.
Table 9-49. Transaction IDs and snapshots
| Name | Return Type | Description |
|---|---|---|
txid_current() |
bigint | get current transaction ID |
txid_current_snapshot() |
txid_snapshot | get current snapshot |
txid_snapshot_xmin(txid_snapshot) |
bigint | get xmin of snapshot |
txid_snapshot_xmax(txid_snapshot) |
bigint | get xmax of snapshot |
txid_snapshot_xip(txid_snapshot) |
setof bigint | get in-progress transaction IDs in snapshot |
txid_visible_in_snapshot(bigint, txid_snapshot) |
boolean | is transaction ID visible in snapshot? |
The internal transaction ID type (xid) is 32 bits wide and so it wraps around every 4 billion transactions. However, these functions export a 64-bit format that is extended with an "epoch" counter so that it will not wrap around for the life of an installation. The data type used by these functions, txid_snapshot, stores information about transaction ID visibility at a particular moment in time. Its components are described in Table 9-50.
Table 9-50. Snapshot components
| Name | Description |
|---|---|
| xmin | Earliest transaction ID (txid) that is still active. All earlier transactions will either be committed and visible, or rolled back and dead. |
| xmax | First as-yet-unassigned txid. All txids later than this one are not yet started as of the time of the snapshot, and thus invisible. |
| xip_list | Active txids at the time of the snapshot. All of them are between xmin and xmax. A txid that is xmin <= txid < xmax and not in this list was already completed at the time of the snapshot, and thus either visible or dead according to its commit status. |
txid_snapshot's textual representation is xmin:xmax:xip_list. For example 10:20:10,14,15 means xmin=10, xmax=20, xip_list=10, 14, 15.