5.7. Row Security Policies
In addition to the SQL-standard privilege system available through GRANT, tables can have row security policies that restrict, on a per-user basis, which rows can be returned by normal queries or inserted, updated, or deleted by data modification commands. This feature is also known as Row-Level Security. By default, tables do not have any policies, so that if a user has access privileges to a table according to the SQL privilege system, all rows within it are equally available for querying or updating.
When row security is enabled on a table (with ALTER TABLE ... ENABLE ROW LEVEL SECURITY), all normal access to the table for selecting rows or modifying rows must be allowed by a row security policy. (However, the table's owner is typically not subject to row security policies.) If no policy exists for the table, a default-deny policy is used, meaning that no rows are visible or can be modified. Operations that apply to the whole table, such as
REFERENCES, are not subject to row security.
Row security policies can be specific to commands, or to roles, or to both. A policy can be specified to apply to
ALL commands, or to
DELETE. Multiple roles can be assigned to a given policy, and normal role membership and inheritance rules apply.
To specify which rows are visible or modifiable according to a policy, an expression is required that returns a Boolean result. This expression will be evaluated for each row prior to any conditions or functions coming from the user's query. (The only exceptions to this rule are
leakproof functions, which are guaranteed to not leak information; the optimizer may choose to apply such functions ahead of the row-security check.) Rows for which the expression does not return
true will not be processed. Separate expressions may be specified to provide independent control over the rows which are visible and the rows which are allowed to be modified. Policy expressions are run as part of the query and with the privileges of the user running the query, although security-definer functions can be used to access data not available to the calling user.
Superusers and roles with the
BYPASSRLS attribute always bypass the row security system when accessing a table. Table owners normally bypass row security as well, though a table owner can choose to be subject to row security with ALTER TABLE ... FORCE ROW LEVEL SECURITY.
Enabling and disabling row security, as well as adding policies to a table, is always the privilege of the table owner only.
Policies are created using the CREATE POLICY command, altered using the ALTER POLICY command, and dropped using the DROP POLICY command. To enable and disable row security for a given table, use the ALTER TABLE command.
Each policy has a name and multiple policies can be defined for a table. As policies are table-specific, each policy for a table must have a unique name. Different tables may have policies with the same name.
When multiple policies apply to a given query, they are combined using either
OR (for permissive policies, which are the default) or using
AND (for restrictive policies). This is similar to the rule that a given role has the privileges of all roles that they are a member of. Permissive vs. restrictive policies are discussed further below.
As a simple example, here is how to create a policy on the
account relation to allow only members of the
managers role to access rows, and only rows of their accounts:
CREATE TABLE accounts (manager text, company text, contact_email text); ALTER TABLE accounts ENABLE ROW LEVEL SECURITY; CREATE POLICY account_managers ON accounts TO managers USING (manager = current_user);
The policy above implicitly provides a
WITH CHECK clause identical to its
USING clause, so that the constraint applies both to rows selected by a command (so a manager cannot
DELETE existing rows belonging to a different manager) and to rows modified by a command (so rows belonging to a different manager cannot be created via
If no role is specified, or the special user name
PUBLIC is used, then the policy applies to all users on the system. To allow all users to access only their own row in a
users table, a simple policy can be used:
CREATE POLICY user_policy ON users USING (user_name = current_user);
This works similarly to the previous example.
To use a different policy for rows that are being added to the table compared to those rows that are visible, multiple policies can be combined. This pair of policies would allow all users to view all rows in the
users table, but only modify their own:
CREATE POLICY user_sel_policy ON users FOR SELECT USING (true); CREATE POLICY user_mod_policy ON users USING (user_name = current_user);
SELECT command, these two policies are combined using
OR, with the net effect being that all rows can be selected. In other command types, only the second policy applies, so that the effects are the same as before.
Row security can also be disabled with the
ALTER TABLE command. Disabling row security does not remove any policies that are defined on the table; they are simply ignored. Then all rows in the table are visible and modifiable, subject to the standard SQL privileges system.
Below is a larger example of how this feature can be used in production environments. The table
passwd emulates a Unix password file:
-- Simple passwd-file based example CREATE TABLE passwd ( user_name text UNIQUE NOT NULL, pwhash text, uid int PRIMARY KEY, gid int NOT NULL, real_name text NOT NULL, home_phone text, extra_info text, home_dir text NOT NULL, shell text NOT NULL ); CREATE ROLE admin; -- Administrator CREATE ROLE bob; -- Normal user CREATE ROLE alice; -- Normal user -- Populate the table INSERT INTO passwd VALUES ('admin','xxx',0,0,'Admin','111-222-3333',null,'/root','/bin/dash'); INSERT INTO passwd VALUES ('bob','xxx',1,1,'Bob','123-456-7890',null,'/home/bob','/bin/zsh'); INSERT INTO passwd VALUES ('alice','xxx',2,1,'Alice','098-765-4321',null,'/home/alice','/bin/zsh'); -- Be sure to enable row level security on the table ALTER TABLE passwd ENABLE ROW LEVEL SECURITY; -- Create policies -- Administrator can see all rows and add any rows CREATE POLICY admin_all ON passwd TO admin USING (true) WITH CHECK (true); -- Normal users can view all rows CREATE POLICY all_view ON passwd FOR SELECT USING (true); -- Normal users can update their own records, but -- limit which shells a normal user is allowed to set CREATE POLICY user_mod ON passwd FOR UPDATE USING (current_user = user_name) WITH CHECK ( current_user = user_name AND shell IN ('/bin/bash','/bin/sh','/bin/dash','/bin/zsh','/bin/tcsh') ); -- Allow admin all normal rights GRANT SELECT, INSERT, UPDATE, DELETE ON passwd TO admin; -- Users only get select access on public columns GRANT SELECT (user_name, uid, gid, real_name, home_phone, extra_info, home_dir, shell) ON passwd TO public; -- Allow users to update certain columns GRANT UPDATE (pwhash, real_name, home_phone, extra_info, shell) ON passwd TO public;
As with any security settings, it's important to test and ensure that the system is behaving as expected. Using the example above, this demonstrates that the permission system is working properly.
-- admin can view all rows and fields postgres=> set role admin; SET postgres=> table passwd; user_name | pwhash | uid | gid | real_name | home_phone | extra_info | home_dir | shell -----------+--------+-----+-----+-----------+--------------+------------+-------------+----------- admin | xxx | 0 | 0 | Admin | 111-222-3333 | | /root | /bin/dash bob | xxx | 1 | 1 | Bob | 123-456-7890 | | /home/bob | /bin/zsh alice | xxx | 2 | 1 | Alice | 098-765-4321 | | /home/alice | /bin/zsh (3 rows) -- Test what Alice is able to do postgres=> set role alice; SET postgres=> table passwd; ERROR: permission denied for relation passwd postgres=> select user_name,real_name,home_phone,extra_info,home_dir,shell from passwd; user_name | real_name | home_phone | extra_info | home_dir | shell -----------+-----------+--------------+------------+-------------+----------- admin | Admin | 111-222-3333 | | /root | /bin/dash bob | Bob | 123-456-7890 | | /home/bob | /bin/zsh alice | Alice | 098-765-4321 | | /home/alice | /bin/zsh (3 rows) postgres=> update passwd set user_name = 'joe'; ERROR: permission denied for relation passwd -- Alice is allowed to change her own real_name, but no others postgres=> update passwd set real_name = 'Alice Doe'; UPDATE 1 postgres=> update passwd set real_name = 'John Doe' where user_name = 'admin'; UPDATE 0 postgres=> update passwd set shell = '/bin/xx'; ERROR: new row violates WITH CHECK OPTION for "passwd" postgres=> delete from passwd; ERROR: permission denied for relation passwd postgres=> insert into passwd (user_name) values ('xxx'); ERROR: permission denied for relation passwd -- Alice can change her own password; RLS silently prevents updating other rows postgres=> update passwd set pwhash = 'abc'; UPDATE 1
All of the policies constructed thus far have been permissive policies, meaning that when multiple policies are applied they are combined using the “OR” Boolean operator. While permissive policies can be constructed to only allow access to rows in the intended cases, it can be simpler to combine permissive policies with restrictive policies (which the records must pass and which are combined using the “AND” Boolean operator). Building on the example above, we add a restrictive policy to require the administrator to be connected over a local Unix socket to access the records of the
CREATE POLICY admin_local_only ON passwd AS RESTRICTIVE TO admin USING (pg_catalog.inet_client_addr() IS NULL);
We can then see that an administrator connecting over a network will not see any records, due to the restrictive policy:
=> SELECT current_user; current_user -------------- admin (1 row) => select inet_client_addr(); inet_client_addr ------------------ 127.0.0.1 (1 row) => SELECT current_user; current_user -------------- admin (1 row) => TABLE passwd; user_name | pwhash | uid | gid | real_name | home_phone | extra_info | home_dir | shell -----------+--------+-----+-----+-----------+------------+------------+----------+------- (0 rows) => UPDATE passwd set pwhash = NULL; UPDATE 0
Referential integrity checks, such as unique or primary key constraints and foreign key references, always bypass row security to ensure that data integrity is maintained. Care must be taken when developing schemas and row level policies to avoid “covert channel” leaks of information through such referential integrity checks.
In some contexts it is important to be sure that row security is not being applied. For example, when taking a backup, it could be disastrous if row security silently caused some rows to be omitted from the backup. In such a situation, you can set the row_security configuration parameter to
off. This does not in itself bypass row security; what it does is throw an error if any query's results would get filtered by a policy. The reason for the error can then be investigated and fixed.
In the examples above, the policy expressions consider only the current values in the row to be accessed or updated. This is the simplest and best-performing case; when possible, it's best to design row security applications to work this way. If it is necessary to consult other rows or other tables to make a policy decision, that can be accomplished using sub-
SELECTs, or functions that contain
SELECTs, in the policy expressions. Be aware however that such accesses can create race conditions that could allow information leakage if care is not taken. As an example, consider the following table design:
-- definition of privilege groups CREATE TABLE groups (group_id int PRIMARY KEY, group_name text NOT NULL); INSERT INTO groups VALUES (1, 'low'), (2, 'medium'), (5, 'high'); GRANT ALL ON groups TO alice; -- alice is the administrator GRANT SELECT ON groups TO public; -- definition of users' privilege levels CREATE TABLE users (user_name text PRIMARY KEY, group_id int NOT NULL REFERENCES groups); INSERT INTO users VALUES ('alice', 5), ('bob', 2), ('mallory', 2); GRANT ALL ON users TO alice; GRANT SELECT ON users TO public; -- table holding the information to be protected CREATE TABLE information (info text, group_id int NOT NULL REFERENCES groups); INSERT INTO information VALUES ('barely secret', 1), ('slightly secret', 2), ('very secret', 5); ALTER TABLE information ENABLE ROW LEVEL SECURITY; -- a row should be visible to/updatable by users whose security group_id is -- greater than or equal to the row's group_id CREATE POLICY fp_s ON information FOR SELECT USING (group_id <= (SELECT group_id FROM users WHERE user_name = current_user)); CREATE POLICY fp_u ON information FOR UPDATE USING (group_id <= (SELECT group_id FROM users WHERE user_name = current_user)); -- we rely only on RLS to protect the information table GRANT ALL ON information TO public;
Now suppose that
alice wishes to change the “slightly secret” information, but decides that
mallory should not be trusted with the new content of that row, so she does:
BEGIN; UPDATE users SET group_id = 1 WHERE user_name = 'mallory'; UPDATE information SET info = 'secret from mallory' WHERE group_id = 2; COMMIT;
That looks safe; there is no window wherein
mallory should be able to see the “secret from mallory” string. However, there is a race condition here. If
mallory is concurrently doing, say,
SELECT * FROM information WHERE group_id = 2 FOR UPDATE;
and her transaction is in
READ COMMITTED mode, it is possible for her to see “secret from mallory”. That happens if her transaction reaches the
information row just after
alice's does. It blocks waiting for
alice's transaction to commit, then fetches the updated row contents thanks to the
FOR UPDATE clause. However, it does not fetch an updated row for the implicit
users, because that sub-
SELECT did not have
FOR UPDATE; instead the
users row is read with the snapshot taken at the start of the query. Therefore, the policy expression tests the old value of
mallory's privilege level and allows her to see the updated row.
There are several ways around this problem. One simple answer is to use
SELECT ... FOR SHARE in sub-
SELECTs in row security policies. However, that requires granting
UPDATE privilege on the referenced table (here
users) to the affected users, which might be undesirable. (But another row security policy could be applied to prevent them from actually exercising that privilege; or the sub-
SELECT could be embedded into a security definer function.) Also, heavy concurrent use of row share locks on the referenced table could pose a performance problem, especially if updates of it are frequent. Another solution, practical if updates of the referenced table are infrequent, is to take an exclusive lock on the referenced table when updating it, so that no concurrent transactions could be examining old row values. Or one could just wait for all concurrent transactions to end after committing an update of the referenced table and before making changes that rely on the new security situation.