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postgresql/src/test/regress/sql/foreign_key.sql
Amit Langote b7b27eb41a Optimize fast-path FK checks with batched index probes 
Instead of probing the PK index on each trigger invocation, buffer
FK rows in a new per-constraint cache entry (RI_FastPathEntry) and
flush them as a batch.

On each trigger invocation, the new ri_FastPathBatchAdd() buffers
the FK row in RI_FastPathEntry.  When the buffer fills (64 rows)
or the trigger-firing cycle ends, the new ri_FastPathBatchFlush()
probes the index for all buffered rows, sharing a single
CommandCounterIncrement, snapshot, permission check, and security
context switch across the batch, rather than repeating each per row
as the SPI path does.  Per-flush CCI is safe because all AFTER
triggers for the buffered rows have already fired by flush time.

For single-column foreign keys, the new ri_FastPathFlushArray()
builds an ArrayType from the buffered FK values (casting to the
PK-side type if needed) and constructs a scan key with the
SK_SEARCHARRAY flag.  The index AM sorts and deduplicates the array
internally, then walks matching leaf pages in one ordered traversal
instead of descending from the root once per row.  A matched[] bitmap
tracks which batch items were satisfied; the first unmatched item is
reported as a violation.  Multi-column foreign keys fall back to
per-row probing via the new ri_FastPathFlushLoop().

The fast path introduced in the previous commit (2da86c1ef9) yields
~1.8x speedup.  This commit adds ~1.6x on top of that, for a combined
~2.9x speedup over the unpatched code (int PK / int FK, 1M rows, PK
table and index cached in memory).

FK tuples are materialized via ExecCopySlotHeapTuple() into a new
purpose-specific memory context (flush_cxt), child of
TopTransactionContext, which is also used for per-flush transient
work: cast results, the search array, and index scan allocations.
It is reset after each flush and deleted in teardown.

The PK relation, index, tuple slots, and fast-path metadata are
cached in RI_FastPathEntry across trigger invocations within a
trigger-firing batch, avoiding repeated open/close overhead.  The
snapshot and IndexScanDesc are taken fresh per flush.  The entry is
not subject to cache invalidation: cached relations are held with
locks for the transaction duration, and the entry's lifetime is
bounded by the trigger-firing cycle.

Lifecycle management for RI_FastPathEntry relies on three new
mechanisms:

  - AfterTriggerBatchCallback: A new general-purpose callback
    mechanism in trigger.c.  Callbacks registered via
    RegisterAfterTriggerBatchCallback() fire at the end of each
    trigger-firing batch (AfterTriggerEndQuery for immediate
    constraints, AfterTriggerFireDeferred at COMMIT, and
    AfterTriggerSetState for SET CONSTRAINTS IMMEDIATE).  The RI
    code registers ri_FastPathEndBatch as a batch callback.

  - Batch callbacks only fire at the outermost query level
    (checked inside FireAfterTriggerBatchCallbacks), so nested
    queries from SPI inside other AFTER triggers do not tear down
    the cache mid-batch.

  - XactCallback: ri_FastPathXactCallback NULLs the static cache
    pointer at transaction end, handling the abort path where the
    batch callback never fired.

  - SubXactCallback: ri_FastPathSubXactCallback NULLs the static
    cache pointer on subtransaction abort, preventing the batch
    callback from accessing already-released resources.

  - AfterTriggerBatchIsActive(): A new exported accessor that
    returns true when afterTriggers.query_depth >= 0.  During
    ALTER TABLE ... ADD FOREIGN KEY validation, RI triggers are
    called directly outside the after-trigger framework, so batch
    callbacks would never fire.  The fast-path code uses this to
    fall back to the non-cached per-invocation path in that
    context.

ri_FastPathEndBatch() flushes any partial batch before tearing
down cached resources.  Since the FK relation may already be
closed by flush time (e.g. for deferred constraints at COMMIT),
it reopens the relation using entry->fk_relid if needed.

The existing ALTER TABLE validation path bypasses batching and
continues to call ri_FastPathCheck() directly per row, because
RI triggers are called outside the after-trigger framework there
and batch callbacks would never fire to flush the buffer.

Suggested-by: David Rowley <dgrowleyml@gmail.com>
Author: Amit Langote <amitlangote09@gmail.com>
Co-authored-by: Junwang Zhao <zhjwpku@gmail.com>
Reviewed-by: Haibo Yan <tristan.yim@gmail.com>
Reviewed-by: Chao Li <li.evan.chao@gmail.com>
Tested-by: Tomas Vondra <tomas@vondra.me>
Discussion: https://postgr.es/m/CA+HiwqF4C0ws3cO+z5cLkPuvwnAwkSp7sfvgGj3yQ=Li6KNMqA@mail.gmail.com
2026-04-03 14:33:53 +09:00

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--
-- FOREIGN KEY
--
-- NOT ENFORCED
--
-- First test, check and cascade
--
CREATE TABLE PKTABLE ( ptest1 int PRIMARY KEY, ptest2 text );
CREATE TABLE FKTABLE ( ftest1 int CONSTRAINT fktable_ftest1_fkey REFERENCES PKTABLE MATCH FULL ON DELETE CASCADE ON UPDATE CASCADE NOT ENFORCED,
ftest2 int );
-- Inserting into the foreign key table will not result in an error, even if
-- there is no matching key in the referenced table.
INSERT INTO FKTABLE VALUES (1, 2);
INSERT INTO FKTABLE VALUES (2, 3);
-- Check FKTABLE
SELECT * FROM FKTABLE;
-- Reverting it back to ENFORCED will result in failure because constraint validation will be triggered,
-- as it was previously in a valid state.
ALTER TABLE FKTABLE ALTER CONSTRAINT fktable_ftest1_fkey ENFORCED;
-- Insert referenced data that satisfies the constraint, then attempt to
-- change it.
INSERT INTO PKTABLE VALUES (1, 'Test1');
INSERT INTO PKTABLE VALUES (2, 'Test2');
ALTER TABLE FKTABLE ALTER CONSTRAINT fktable_ftest1_fkey ENFORCED;
-- Any further inserts will fail due to the enforcement.
INSERT INTO FKTABLE VALUES (3, 4);
--
-- MATCH FULL
--
-- First test, check and cascade
--
-- Insert test data into PKTABLE
INSERT INTO PKTABLE VALUES (3, 'Test3');
INSERT INTO PKTABLE VALUES (4, 'Test4');
INSERT INTO PKTABLE VALUES (5, 'Test5');
-- Insert successful rows into FK TABLE
INSERT INTO FKTABLE VALUES (3, 4);
INSERT INTO FKTABLE VALUES (NULL, 1);
-- Insert a failed row into FK TABLE
INSERT INTO FKTABLE VALUES (100, 2);
-- Check FKTABLE
SELECT * FROM FKTABLE;
-- Delete a row from PK TABLE
DELETE FROM PKTABLE WHERE ptest1=1;
-- Check FKTABLE for removal of matched row
SELECT * FROM FKTABLE;
-- Update a row from PK TABLE
UPDATE PKTABLE SET ptest1=1 WHERE ptest1=2;
-- Check FKTABLE for update of matched row
SELECT * FROM FKTABLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
--
-- check set NULL and table constraint on multiple columns
--
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, ptest3 text, PRIMARY KEY(ptest1, ptest2) );
CREATE TABLE FKTABLE ( ftest1 int, ftest2 int, ftest3 int, CONSTRAINT constrname FOREIGN KEY(ftest1, ftest2)
REFERENCES PKTABLE MATCH FULL ON DELETE SET NULL ON UPDATE SET NULL);
-- Test comments
COMMENT ON CONSTRAINT constrname_wrong ON FKTABLE IS 'fk constraint comment';
COMMENT ON CONSTRAINT constrname ON FKTABLE IS 'fk constraint comment';
COMMENT ON CONSTRAINT constrname ON FKTABLE IS NULL;
-- Insert test data into PKTABLE
INSERT INTO PKTABLE VALUES (1, 2, 'Test1');
INSERT INTO PKTABLE VALUES (1, 3, 'Test1-2');
INSERT INTO PKTABLE VALUES (2, 4, 'Test2');
INSERT INTO PKTABLE VALUES (3, 6, 'Test3');
INSERT INTO PKTABLE VALUES (4, 8, 'Test4');
INSERT INTO PKTABLE VALUES (5, 10, 'Test5');
-- Insert successful rows into FK TABLE
INSERT INTO FKTABLE VALUES (1, 2, 4);
INSERT INTO FKTABLE VALUES (1, 3, 5);
INSERT INTO FKTABLE VALUES (2, 4, 8);
INSERT INTO FKTABLE VALUES (3, 6, 12);
INSERT INTO FKTABLE VALUES (NULL, NULL, 0);
-- Insert failed rows into FK TABLE
INSERT INTO FKTABLE VALUES (100, 2, 4);
INSERT INTO FKTABLE VALUES (2, 2, 4);
INSERT INTO FKTABLE VALUES (NULL, 2, 4);
INSERT INTO FKTABLE VALUES (1, NULL, 4);
-- Check FKTABLE
SELECT * FROM FKTABLE;
-- Delete a row from PK TABLE
DELETE FROM PKTABLE WHERE ptest1=1 and ptest2=2;
-- Check FKTABLE for removal of matched row
SELECT * FROM FKTABLE;
-- Delete another row from PK TABLE
DELETE FROM PKTABLE WHERE ptest1=5 and ptest2=10;
-- Check FKTABLE (should be no change)
SELECT * FROM FKTABLE;
-- Update a row from PK TABLE
UPDATE PKTABLE SET ptest1=1 WHERE ptest1=2;
-- Check FKTABLE for update of matched row
SELECT * FROM FKTABLE;
-- Check update with part of key null
UPDATE FKTABLE SET ftest1 = NULL WHERE ftest1 = 1;
-- Check update with old and new key values equal
UPDATE FKTABLE SET ftest1 = 1 WHERE ftest1 = 1;
-- Try altering the column type where foreign keys are involved
ALTER TABLE PKTABLE ALTER COLUMN ptest1 TYPE bigint;
ALTER TABLE FKTABLE ALTER COLUMN ftest1 TYPE bigint;
SELECT * FROM PKTABLE;
SELECT * FROM FKTABLE;
DROP TABLE PKTABLE CASCADE;
DROP TABLE FKTABLE;
--
-- check set default and table constraint on multiple columns
--
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, ptest3 text, PRIMARY KEY(ptest1, ptest2) );
CREATE TABLE FKTABLE ( ftest1 int DEFAULT -1, ftest2 int DEFAULT -2, ftest3 int, CONSTRAINT constrname2 FOREIGN KEY(ftest1, ftest2)
REFERENCES PKTABLE MATCH FULL ON DELETE SET DEFAULT ON UPDATE SET DEFAULT);
-- Insert a value in PKTABLE for default
INSERT INTO PKTABLE VALUES (-1, -2, 'The Default!');
-- Insert test data into PKTABLE
INSERT INTO PKTABLE VALUES (1, 2, 'Test1');
INSERT INTO PKTABLE VALUES (1, 3, 'Test1-2');
INSERT INTO PKTABLE VALUES (2, 4, 'Test2');
INSERT INTO PKTABLE VALUES (3, 6, 'Test3');
INSERT INTO PKTABLE VALUES (4, 8, 'Test4');
INSERT INTO PKTABLE VALUES (5, 10, 'Test5');
-- Insert successful rows into FK TABLE
INSERT INTO FKTABLE VALUES (1, 2, 4);
INSERT INTO FKTABLE VALUES (1, 3, 5);
INSERT INTO FKTABLE VALUES (2, 4, 8);
INSERT INTO FKTABLE VALUES (3, 6, 12);
INSERT INTO FKTABLE VALUES (NULL, NULL, 0);
-- Insert failed rows into FK TABLE
INSERT INTO FKTABLE VALUES (100, 2, 4);
INSERT INTO FKTABLE VALUES (2, 2, 4);
INSERT INTO FKTABLE VALUES (NULL, 2, 4);
INSERT INTO FKTABLE VALUES (1, NULL, 4);
-- Check FKTABLE
SELECT * FROM FKTABLE;
-- Delete a row from PK TABLE
DELETE FROM PKTABLE WHERE ptest1=1 and ptest2=2;
-- Check FKTABLE to check for removal
SELECT * FROM FKTABLE;
-- Delete another row from PK TABLE
DELETE FROM PKTABLE WHERE ptest1=5 and ptest2=10;
-- Check FKTABLE (should be no change)
SELECT * FROM FKTABLE;
-- Update a row from PK TABLE
UPDATE PKTABLE SET ptest1=1 WHERE ptest1=2;
-- Check FKTABLE for update of matched row
SELECT * FROM FKTABLE;
-- this should fail for lack of CASCADE
DROP TABLE PKTABLE;
DROP TABLE PKTABLE CASCADE;
DROP TABLE FKTABLE;
--
-- First test, check with no on delete or on update
--
CREATE TABLE PKTABLE ( ptest1 int PRIMARY KEY, ptest2 text );
CREATE TABLE FKTABLE ( ftest1 int REFERENCES PKTABLE MATCH FULL, ftest2 int );
-- Insert test data into PKTABLE
INSERT INTO PKTABLE VALUES (1, 'Test1');
INSERT INTO PKTABLE VALUES (2, 'Test2');
INSERT INTO PKTABLE VALUES (3, 'Test3');
INSERT INTO PKTABLE VALUES (4, 'Test4');
INSERT INTO PKTABLE VALUES (5, 'Test5');
-- Insert successful rows into FK TABLE
INSERT INTO FKTABLE VALUES (1, 2);
INSERT INTO FKTABLE VALUES (2, 3);
INSERT INTO FKTABLE VALUES (3, 4);
INSERT INTO FKTABLE VALUES (NULL, 1);
-- Insert a failed row into FK TABLE
INSERT INTO FKTABLE VALUES (100, 2);
-- Check FKTABLE
SELECT * FROM FKTABLE;
-- Check PKTABLE
SELECT * FROM PKTABLE;
-- Delete a row from PK TABLE (should fail)
DELETE FROM PKTABLE WHERE ptest1=1;
-- Delete a row from PK TABLE (should succeed)
DELETE FROM PKTABLE WHERE ptest1=5;
-- Check PKTABLE for deletes
SELECT * FROM PKTABLE;
-- Update a row from PK TABLE (should fail)
UPDATE PKTABLE SET ptest1=0 WHERE ptest1=2;
-- Update a row from PK TABLE (should succeed)
UPDATE PKTABLE SET ptest1=0 WHERE ptest1=4;
-- Check PKTABLE for updates
SELECT * FROM PKTABLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
--
-- Check RLS
--
CREATE TABLE PKTABLE ( ptest1 int PRIMARY KEY, ptest2 text );
CREATE TABLE FKTABLE ( ftest1 int REFERENCES PKTABLE, ftest2 int );
-- Insert test data into PKTABLE
INSERT INTO PKTABLE VALUES (1, 'Test1');
INSERT INTO PKTABLE VALUES (2, 'Test2');
INSERT INTO PKTABLE VALUES (3, 'Test3');
-- Grant privileges on PKTABLE/FKTABLE to user regress_foreign_key_user
CREATE USER regress_foreign_key_user NOLOGIN;
GRANT SELECT ON PKTABLE TO regress_foreign_key_user;
GRANT SELECT, INSERT ON FKTABLE TO regress_foreign_key_user;
-- Enable RLS on PKTABLE and Create policies
ALTER TABLE PKTABLE ENABLE ROW LEVEL SECURITY;
CREATE POLICY pktable_view_odd_policy ON PKTABLE TO regress_foreign_key_user USING (ptest1 % 2 = 1);
ALTER TABLE PKTABLE OWNER to regress_foreign_key_user;
SET ROLE regress_foreign_key_user;
INSERT INTO FKTABLE VALUES (3, 5);
INSERT INTO FKTABLE VALUES (2, 5); -- success, REFERENCES are not subject to row security
RESET ROLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
DROP USER regress_foreign_key_user;
--
-- Check ACL
--
CREATE TABLE PKTABLE ( ptest1 int PRIMARY KEY, ptest2 text );
CREATE TABLE FKTABLE ( ftest1 int REFERENCES PKTABLE, ftest2 int );
-- Insert test data into PKTABLE
INSERT INTO PKTABLE VALUES (1, 'Test1');
INSERT INTO PKTABLE VALUES (2, 'Test2');
INSERT INTO PKTABLE VALUES (3, 'Test3');
-- Grant usage on PKTABLE to user regress_foreign_key_user
CREATE USER regress_foreign_key_user NOLOGIN;
GRANT SELECT ON PKTABLE TO regress_foreign_key_user;
ALTER TABLE PKTABLE OWNER to regress_foreign_key_user;
-- Inserting into FKTABLE should work
INSERT INTO FKTABLE VALUES (3, 5);
-- Revoke usage on PKTABLE from user regress_foreign_key_user
REVOKE SELECT ON PKTABLE FROM regress_foreign_key_user;
-- Inserting into FKTABLE should fail
INSERT INTO FKTABLE VALUES (2, 6);
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
DROP USER regress_foreign_key_user;
--
-- Check initial check upon ALTER TABLE
--
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, PRIMARY KEY(ptest1, ptest2) );
CREATE TABLE FKTABLE ( ftest1 int, ftest2 int );
INSERT INTO PKTABLE VALUES (1, 2);
INSERT INTO FKTABLE VALUES (1, NULL);
ALTER TABLE FKTABLE ADD FOREIGN KEY(ftest1, ftest2) REFERENCES PKTABLE MATCH FULL;
-- Modifying other attributes of a constraint should not affect its enforceability, and vice versa
ALTER TABLE FKTABLE ADD CONSTRAINT fk_con FOREIGN KEY(ftest1, ftest2) REFERENCES PKTABLE NOT VALID NOT ENFORCED;
ALTER TABLE FKTABLE ALTER CONSTRAINT fk_con DEFERRABLE INITIALLY DEFERRED;
SELECT condeferrable, condeferred, conenforced, convalidated
FROM pg_constraint WHERE conname = 'fk_con';
ALTER TABLE FKTABLE ALTER CONSTRAINT fk_con NOT ENFORCED;
SELECT condeferrable, condeferred, conenforced, convalidated
FROM pg_constraint WHERE conname = 'fk_con';
-- Enforceability also changes the validate state, as data validation will be
-- performed during this transformation.
ALTER TABLE FKTABLE ALTER CONSTRAINT fk_con ENFORCED;
SELECT condeferrable, condeferred, conenforced, convalidated
FROM pg_constraint WHERE conname = 'fk_con';
-- Can change enforceability and deferrability together
ALTER TABLE FKTABLE ALTER CONSTRAINT fk_con NOT ENFORCED NOT DEFERRABLE;
SELECT condeferrable, condeferred, conenforced, convalidated
FROM pg_constraint WHERE conname = 'fk_con';
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- MATCH SIMPLE
-- Base test restricting update/delete
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, ptest3 int, ptest4 text, PRIMARY KEY(ptest1, ptest2, ptest3) );
CREATE TABLE FKTABLE ( ftest1 int, ftest2 int, ftest3 int, ftest4 int, CONSTRAINT constrname3
FOREIGN KEY(ftest1, ftest2, ftest3) REFERENCES PKTABLE);
-- Insert Primary Key values
INSERT INTO PKTABLE VALUES (1, 2, 3, 'test1');
INSERT INTO PKTABLE VALUES (1, 3, 3, 'test2');
INSERT INTO PKTABLE VALUES (2, 3, 4, 'test3');
INSERT INTO PKTABLE VALUES (2, 4, 5, 'test4');
-- Insert Foreign Key values
INSERT INTO FKTABLE VALUES (1, 2, 3, 1);
INSERT INTO FKTABLE VALUES (NULL, 2, 3, 2);
INSERT INTO FKTABLE VALUES (2, NULL, 3, 3);
INSERT INTO FKTABLE VALUES (NULL, 2, 7, 4);
INSERT INTO FKTABLE VALUES (NULL, 3, 4, 5);
-- Insert a failed values
INSERT INTO FKTABLE VALUES (1, 2, 7, 6);
-- Show FKTABLE
SELECT * from FKTABLE;
-- Try to update something that should fail
UPDATE PKTABLE set ptest2=5 where ptest2=2;
-- Try to update something that should succeed
UPDATE PKTABLE set ptest1=1 WHERE ptest2=3;
-- Try to delete something that should fail
DELETE FROM PKTABLE where ptest1=1 and ptest2=2 and ptest3=3;
-- Try to delete something that should work
DELETE FROM PKTABLE where ptest1=2;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- restrict with null values
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, ptest3 int, ptest4 text, UNIQUE(ptest1, ptest2, ptest3) );
CREATE TABLE FKTABLE ( ftest1 int, ftest2 int, ftest3 int, ftest4 int, CONSTRAINT constrname3
FOREIGN KEY(ftest1, ftest2, ftest3) REFERENCES PKTABLE (ptest1, ptest2, ptest3));
INSERT INTO PKTABLE VALUES (1, 2, 3, 'test1');
INSERT INTO PKTABLE VALUES (1, 3, NULL, 'test2');
INSERT INTO PKTABLE VALUES (2, NULL, 4, 'test3');
INSERT INTO FKTABLE VALUES (1, 2, 3, 1);
DELETE FROM PKTABLE WHERE ptest1 = 2;
SELECT * FROM PKTABLE;
SELECT * FROM FKTABLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- cascade update/delete
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, ptest3 int, ptest4 text, PRIMARY KEY(ptest1, ptest2, ptest3) );
CREATE TABLE FKTABLE ( ftest1 int, ftest2 int, ftest3 int, ftest4 int, CONSTRAINT constrname3
FOREIGN KEY(ftest1, ftest2, ftest3) REFERENCES PKTABLE
ON DELETE CASCADE ON UPDATE CASCADE);
-- Insert Primary Key values
INSERT INTO PKTABLE VALUES (1, 2, 3, 'test1');
INSERT INTO PKTABLE VALUES (1, 3, 3, 'test2');
INSERT INTO PKTABLE VALUES (2, 3, 4, 'test3');
INSERT INTO PKTABLE VALUES (2, 4, 5, 'test4');
-- Insert Foreign Key values
INSERT INTO FKTABLE VALUES (1, 2, 3, 1);
INSERT INTO FKTABLE VALUES (NULL, 2, 3, 2);
INSERT INTO FKTABLE VALUES (2, NULL, 3, 3);
INSERT INTO FKTABLE VALUES (NULL, 2, 7, 4);
INSERT INTO FKTABLE VALUES (NULL, 3, 4, 5);
-- Insert a failed values
INSERT INTO FKTABLE VALUES (1, 2, 7, 6);
-- Show FKTABLE
SELECT * from FKTABLE;
-- Try to update something that will cascade
UPDATE PKTABLE set ptest2=5 where ptest2=2;
-- Try to update something that should not cascade
UPDATE PKTABLE set ptest1=1 WHERE ptest2=3;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
-- Try to delete something that should cascade
DELETE FROM PKTABLE where ptest1=1 and ptest2=5 and ptest3=3;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
-- Try to delete something that should not have a cascade
DELETE FROM PKTABLE where ptest1=2;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- set null update / set default delete
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, ptest3 int, ptest4 text, PRIMARY KEY(ptest1, ptest2, ptest3) );
CREATE TABLE FKTABLE ( ftest1 int DEFAULT 0, ftest2 int, ftest3 int, ftest4 int, CONSTRAINT constrname3
FOREIGN KEY(ftest1, ftest2, ftest3) REFERENCES PKTABLE
ON DELETE SET DEFAULT ON UPDATE SET NULL);
-- Insert Primary Key values
INSERT INTO PKTABLE VALUES (1, 2, 3, 'test1');
INSERT INTO PKTABLE VALUES (1, 3, 3, 'test2');
INSERT INTO PKTABLE VALUES (2, 3, 4, 'test3');
INSERT INTO PKTABLE VALUES (2, 4, 5, 'test4');
-- Insert Foreign Key values
INSERT INTO FKTABLE VALUES (1, 2, 3, 1);
INSERT INTO FKTABLE VALUES (2, 3, 4, 1);
INSERT INTO FKTABLE VALUES (NULL, 2, 3, 2);
INSERT INTO FKTABLE VALUES (2, NULL, 3, 3);
INSERT INTO FKTABLE VALUES (NULL, 2, 7, 4);
INSERT INTO FKTABLE VALUES (NULL, 3, 4, 5);
-- Insert a failed values
INSERT INTO FKTABLE VALUES (1, 2, 7, 6);
-- Show FKTABLE
SELECT * from FKTABLE;
-- Try to update something that will set null
UPDATE PKTABLE set ptest2=5 where ptest2=2;
-- Try to update something that should not set null
UPDATE PKTABLE set ptest2=2 WHERE ptest2=3 and ptest1=1;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
-- Try to delete something that should set default
DELETE FROM PKTABLE where ptest1=2 and ptest2=3 and ptest3=4;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
-- Try to delete something that should not set default
DELETE FROM PKTABLE where ptest2=5;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- set default update / set null delete
CREATE TABLE PKTABLE ( ptest1 int, ptest2 int, ptest3 int, ptest4 text, PRIMARY KEY(ptest1, ptest2, ptest3) );
CREATE TABLE FKTABLE ( ftest1 int DEFAULT 0, ftest2 int DEFAULT -1, ftest3 int DEFAULT -2, ftest4 int, CONSTRAINT constrname3
FOREIGN KEY(ftest1, ftest2, ftest3) REFERENCES PKTABLE
ON DELETE SET NULL ON UPDATE SET DEFAULT);
-- Insert Primary Key values
INSERT INTO PKTABLE VALUES (1, 2, 3, 'test1');
INSERT INTO PKTABLE VALUES (1, 3, 3, 'test2');
INSERT INTO PKTABLE VALUES (2, 3, 4, 'test3');
INSERT INTO PKTABLE VALUES (2, 4, 5, 'test4');
INSERT INTO PKTABLE VALUES (2, -1, 5, 'test5');
-- Insert Foreign Key values
INSERT INTO FKTABLE VALUES (1, 2, 3, 1);
INSERT INTO FKTABLE VALUES (2, 3, 4, 1);
INSERT INTO FKTABLE VALUES (2, 4, 5, 1);
INSERT INTO FKTABLE VALUES (NULL, 2, 3, 2);
INSERT INTO FKTABLE VALUES (2, NULL, 3, 3);
INSERT INTO FKTABLE VALUES (NULL, 2, 7, 4);
INSERT INTO FKTABLE VALUES (NULL, 3, 4, 5);
-- Insert a failed values
INSERT INTO FKTABLE VALUES (1, 2, 7, 6);
-- Show FKTABLE
SELECT * from FKTABLE;
-- Try to update something that will fail
UPDATE PKTABLE set ptest2=5 where ptest2=2;
-- Try to update something that will set default
UPDATE PKTABLE set ptest1=0, ptest2=-1, ptest3=-2 where ptest2=2;
UPDATE PKTABLE set ptest2=10 where ptest2=4;
-- Try to update something that should not set default
UPDATE PKTABLE set ptest2=2 WHERE ptest2=3 and ptest1=1;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
-- Try to delete something that should set null
DELETE FROM PKTABLE where ptest1=2 and ptest2=3 and ptest3=4;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
-- Try to delete something that should not set null
DELETE FROM PKTABLE where ptest2=-1 and ptest3=5;
-- Show PKTABLE and FKTABLE
SELECT * from PKTABLE;
SELECT * from FKTABLE;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- Test for ON DELETE SET NULL/DEFAULT (column_list);
CREATE TABLE PKTABLE (tid int, id int, PRIMARY KEY (tid, id));
CREATE TABLE FKTABLE (tid int, id int, foo int, FOREIGN KEY (tid, id) REFERENCES PKTABLE ON DELETE SET NULL (bar));
CREATE TABLE FKTABLE (tid int, id int, foo int, FOREIGN KEY (tid, id) REFERENCES PKTABLE ON DELETE SET NULL (foo));
CREATE TABLE FKTABLE (tid int, id int, foo int, FOREIGN KEY (tid, foo) REFERENCES PKTABLE ON UPDATE SET NULL (foo));
CREATE TABLE FKTABLE (
tid int, id int,
fk_id_del_set_null int,
fk_id_del_set_default int DEFAULT 0,
FOREIGN KEY (tid, fk_id_del_set_null) REFERENCES PKTABLE ON DELETE SET NULL (fk_id_del_set_null),
-- this tests handling of duplicate entries in SET DEFAULT column list
FOREIGN KEY (tid, fk_id_del_set_default) REFERENCES PKTABLE ON DELETE SET DEFAULT (fk_id_del_set_default, fk_id_del_set_default)
);
SELECT pg_get_constraintdef(oid) FROM pg_constraint WHERE conrelid = 'fktable'::regclass::oid ORDER BY oid;
INSERT INTO PKTABLE VALUES (1, 0), (1, 1), (1, 2);
INSERT INTO FKTABLE VALUES
(1, 1, 1, NULL),
(1, 2, NULL, 2);
DELETE FROM PKTABLE WHERE id = 1 OR id = 2;
SELECT * FROM FKTABLE ORDER BY id;
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- Test some invalid FK definitions
CREATE TABLE PKTABLE (ptest1 int PRIMARY KEY, someoid oid);
CREATE TABLE FKTABLE_FAIL1 ( ftest1 int, CONSTRAINT fkfail1 FOREIGN KEY (ftest2) REFERENCES PKTABLE);
CREATE TABLE FKTABLE_FAIL2 ( ftest1 int, CONSTRAINT fkfail1 FOREIGN KEY (ftest1) REFERENCES PKTABLE(ptest2));
CREATE TABLE FKTABLE_FAIL3 ( ftest1 int, CONSTRAINT fkfail1 FOREIGN KEY (tableoid) REFERENCES PKTABLE(someoid));
CREATE TABLE FKTABLE_FAIL4 ( ftest1 oid, CONSTRAINT fkfail1 FOREIGN KEY (ftest1) REFERENCES PKTABLE(tableoid));
DROP TABLE PKTABLE;
-- Test for referencing column number smaller than referenced constraint
CREATE TABLE PKTABLE (ptest1 int, ptest2 int, UNIQUE(ptest1, ptest2));
CREATE TABLE FKTABLE_FAIL1 (ftest1 int REFERENCES pktable(ptest1));
DROP TABLE FKTABLE_FAIL1;
DROP TABLE PKTABLE;
--
-- Tests for mismatched types
--
-- Basic one column, two table setup
CREATE TABLE PKTABLE (ptest1 int PRIMARY KEY);
INSERT INTO PKTABLE VALUES(42);
-- This next should fail, because int=inet does not exist
CREATE TABLE FKTABLE (ftest1 inet REFERENCES pktable);
-- This should also fail for the same reason, but here we
-- give the column name
CREATE TABLE FKTABLE (ftest1 inet REFERENCES pktable(ptest1));
-- This should succeed, even though they are different types,
-- because int=int8 exists and is a member of the integer opfamily
CREATE TABLE FKTABLE (ftest1 int8 REFERENCES pktable);
-- Check it actually works
INSERT INTO FKTABLE VALUES(42); -- should succeed
INSERT INTO FKTABLE VALUES(43); -- should fail
UPDATE FKTABLE SET ftest1 = ftest1; -- should succeed
UPDATE FKTABLE SET ftest1 = ftest1 + 1; -- should fail
DROP TABLE FKTABLE;
-- This should fail, because we'd have to cast numeric to int which is
-- not an implicit coercion (or use numeric=numeric, but that's not part
-- of the integer opfamily)
CREATE TABLE FKTABLE (ftest1 numeric REFERENCES pktable);
DROP TABLE PKTABLE;
-- On the other hand, this should work because int implicitly promotes to
-- numeric, and we allow promotion on the FK side
CREATE TABLE PKTABLE (ptest1 numeric PRIMARY KEY);
INSERT INTO PKTABLE VALUES(42);
CREATE TABLE FKTABLE (ftest1 int REFERENCES pktable);
-- Check it actually works
INSERT INTO FKTABLE VALUES(42); -- should succeed
INSERT INTO FKTABLE VALUES(43); -- should fail
UPDATE FKTABLE SET ftest1 = ftest1; -- should succeed
UPDATE FKTABLE SET ftest1 = ftest1 + 1; -- should fail
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- Two columns, two tables
CREATE TABLE PKTABLE (ptest1 int, ptest2 inet, PRIMARY KEY(ptest1, ptest2));
-- This should fail, because we just chose really odd types
CREATE TABLE FKTABLE (ftest1 cidr, ftest2 timestamp, FOREIGN KEY(ftest1, ftest2) REFERENCES pktable);
-- Again, so should this...
CREATE TABLE FKTABLE (ftest1 cidr, ftest2 timestamp, FOREIGN KEY(ftest1, ftest2) REFERENCES pktable(ptest1, ptest2));
-- This fails because we mixed up the column ordering
CREATE TABLE FKTABLE (ftest1 int, ftest2 inet, FOREIGN KEY(ftest2, ftest1) REFERENCES pktable);
-- As does this...
CREATE TABLE FKTABLE (ftest1 int, ftest2 inet, FOREIGN KEY(ftest2, ftest1) REFERENCES pktable(ptest1, ptest2));
-- And again..
CREATE TABLE FKTABLE (ftest1 int, ftest2 inet, FOREIGN KEY(ftest1, ftest2) REFERENCES pktable(ptest2, ptest1));
-- This works...
CREATE TABLE FKTABLE (ftest1 int, ftest2 inet, FOREIGN KEY(ftest2, ftest1) REFERENCES pktable(ptest2, ptest1));
DROP TABLE FKTABLE;
-- As does this
CREATE TABLE FKTABLE (ftest1 int, ftest2 inet, FOREIGN KEY(ftest1, ftest2) REFERENCES pktable(ptest1, ptest2));
DROP TABLE FKTABLE;
DROP TABLE PKTABLE;
-- Two columns, same table
-- Make sure this still works...
CREATE TABLE PKTABLE (ptest1 int, ptest2 inet, ptest3 int, ptest4 inet, PRIMARY KEY(ptest1, ptest2), FOREIGN KEY(ptest3,
ptest4) REFERENCES pktable(ptest1, ptest2));
DROP TABLE PKTABLE;
-- And this,
CREATE TABLE PKTABLE (ptest1 int, ptest2 inet, ptest3 int, ptest4 inet, PRIMARY KEY(ptest1, ptest2), FOREIGN KEY(ptest3,
ptest4) REFERENCES pktable);
DROP TABLE PKTABLE;
-- This shouldn't (mixed up columns)
CREATE TABLE PKTABLE (ptest1 int, ptest2 inet, ptest3 int, ptest4 inet, PRIMARY KEY(ptest1, ptest2), FOREIGN KEY(ptest3,
ptest4) REFERENCES pktable(ptest2, ptest1));
-- Nor should this... (same reason, we have 4,3 referencing 1,2 which mismatches types
CREATE TABLE PKTABLE (ptest1 int, ptest2 inet, ptest3 int, ptest4 inet, PRIMARY KEY(ptest1, ptest2), FOREIGN KEY(ptest4,
ptest3) REFERENCES pktable(ptest1, ptest2));
-- Not this one either... Same as the last one except we didn't defined the columns being referenced.
CREATE TABLE PKTABLE (ptest1 int, ptest2 inet, ptest3 int, ptest4 inet, PRIMARY KEY(ptest1, ptest2), FOREIGN KEY(ptest4,
ptest3) REFERENCES pktable);
--
-- Now some cases with inheritance
-- Basic 2 table case: 1 column of matching types.
create table pktable_base (base1 int not null);
create table pktable (ptest1 int, primary key(base1), unique(base1, ptest1)) inherits (pktable_base);
create table fktable (ftest1 int references pktable(base1));
-- now some ins, upd, del
insert into pktable(base1) values (1);
insert into pktable(base1) values (2);
-- let's insert a non-existent fktable value
insert into fktable(ftest1) values (3);
-- let's make a valid row for that
insert into pktable(base1) values (3);
insert into fktable(ftest1) values (3);
-- let's try removing a row that should fail from pktable
delete from pktable where base1>2;
-- okay, let's try updating all of the base1 values to *4
-- which should fail.
update pktable set base1=base1*4;
-- okay, let's try an update that should work.
update pktable set base1=base1*4 where base1<3;
-- and a delete that should work
delete from pktable where base1>3;
-- cleanup
drop table fktable;
delete from pktable;
-- Now 2 columns 2 tables, matching types
create table fktable (ftest1 int, ftest2 int, foreign key(ftest1, ftest2) references pktable(base1, ptest1));
-- now some ins, upd, del
insert into pktable(base1, ptest1) values (1, 1);
insert into pktable(base1, ptest1) values (2, 2);
-- let's insert a non-existent fktable value
insert into fktable(ftest1, ftest2) values (3, 1);
-- let's make a valid row for that
insert into pktable(base1,ptest1) values (3, 1);
insert into fktable(ftest1, ftest2) values (3, 1);
-- let's try removing a row that should fail from pktable
delete from pktable where base1>2;
-- okay, let's try updating all of the base1 values to *4
-- which should fail.
update pktable set base1=base1*4;
-- okay, let's try an update that should work.
update pktable set base1=base1*4 where base1<3;
-- and a delete that should work
delete from pktable where base1>3;
-- cleanup
drop table fktable;
drop table pktable;
drop table pktable_base;
-- Now we'll do one all in 1 table with 2 columns of matching types
create table pktable_base(base1 int not null, base2 int);
create table pktable(ptest1 int, ptest2 int, primary key(base1, ptest1), foreign key(base2, ptest2) references
pktable(base1, ptest1)) inherits (pktable_base);
insert into pktable (base1, ptest1, base2, ptest2) values (1, 1, 1, 1);
insert into pktable (base1, ptest1, base2, ptest2) values (2, 1, 1, 1);
insert into pktable (base1, ptest1, base2, ptest2) values (2, 2, 2, 1);
insert into pktable (base1, ptest1, base2, ptest2) values (1, 3, 2, 2);
-- fails (3,2) isn't in base1, ptest1
insert into pktable (base1, ptest1, base2, ptest2) values (2, 3, 3, 2);
-- fails (2,2) is being referenced
delete from pktable where base1=2;
-- fails (1,1) is being referenced (twice)
update pktable set base1=3 where base1=1;
-- this sequence of two deletes will work, since after the first there will be no (2,*) references
delete from pktable where base2=2;
delete from pktable where base1=2;
drop table pktable;
drop table pktable_base;
-- 2 columns (2 tables), mismatched types
create table pktable_base(base1 int not null);
create table pktable(ptest1 inet, primary key(base1, ptest1)) inherits (pktable_base);
-- just generally bad types (with and without column references on the referenced table)
create table fktable(ftest1 cidr, ftest2 int[], foreign key (ftest1, ftest2) references pktable);
create table fktable(ftest1 cidr, ftest2 int[], foreign key (ftest1, ftest2) references pktable(base1, ptest1));
-- let's mix up which columns reference which
create table fktable(ftest1 int, ftest2 inet, foreign key(ftest2, ftest1) references pktable);
create table fktable(ftest1 int, ftest2 inet, foreign key(ftest2, ftest1) references pktable(base1, ptest1));
create table fktable(ftest1 int, ftest2 inet, foreign key(ftest1, ftest2) references pktable(ptest1, base1));
drop table pktable;
drop table pktable_base;
-- 2 columns (1 table), mismatched types
create table pktable_base(base1 int not null, base2 int);
create table pktable(ptest1 inet, ptest2 inet[], primary key(base1, ptest1), foreign key(base2, ptest2) references
pktable(base1, ptest1)) inherits (pktable_base);
create table pktable(ptest1 inet, ptest2 inet, primary key(base1, ptest1), foreign key(base2, ptest2) references
pktable(ptest1, base1)) inherits (pktable_base);
create table pktable(ptest1 inet, ptest2 inet, primary key(base1, ptest1), foreign key(ptest2, base2) references
pktable(base1, ptest1)) inherits (pktable_base);
create table pktable(ptest1 inet, ptest2 inet, primary key(base1, ptest1), foreign key(ptest2, base2) references
pktable(base1, ptest1)) inherits (pktable_base);
drop table pktable;
drop table pktable_base;
--
-- Deferrable constraints
--
-- deferrable, explicitly deferred
CREATE TABLE pktable (
id INT4 PRIMARY KEY,
other INT4
);
CREATE TABLE fktable (
id INT4 PRIMARY KEY,
fk INT4 REFERENCES pktable DEFERRABLE
);
-- default to immediate: should fail
INSERT INTO fktable VALUES (5, 10);
-- explicitly defer the constraint
BEGIN;
SET CONSTRAINTS ALL DEFERRED;
INSERT INTO fktable VALUES (10, 15);
INSERT INTO pktable VALUES (15, 0); -- make the FK insert valid
COMMIT;
DROP TABLE fktable, pktable;
-- deferrable, initially deferred
CREATE TABLE pktable (
id INT4 PRIMARY KEY,
other INT4
);
CREATE TABLE fktable (
id INT4 PRIMARY KEY,
fk INT4 REFERENCES pktable DEFERRABLE INITIALLY DEFERRED
);
-- default to deferred, should succeed
BEGIN;
INSERT INTO fktable VALUES (100, 200);
INSERT INTO pktable VALUES (200, 500); -- make the FK insert valid
COMMIT;
-- default to deferred, explicitly make immediate
BEGIN;
SET CONSTRAINTS ALL IMMEDIATE;
-- should fail
INSERT INTO fktable VALUES (500, 1000);
COMMIT;
-- Check that the existing FK trigger is both deferrable and initially deferred
SELECT conname, tgrelid::regclass as tgrel,
regexp_replace(tgname, '[0-9]+', 'N') as tgname, tgtype,
tgdeferrable, tginitdeferred
FROM pg_trigger t JOIN pg_constraint c ON (t.tgconstraint = c.oid)
WHERE conrelid = 'fktable'::regclass AND conname = 'fktable_fk_fkey'
ORDER BY tgrelid, tgtype;
-- Changing the constraint to NOT ENFORCED drops the associated FK triggers
ALTER TABLE FKTABLE ALTER CONSTRAINT fktable_fk_fkey NOT ENFORCED;
SELECT conname, tgrelid::regclass as tgrel,
regexp_replace(tgname, '[0-9]+', 'N') as tgname, tgtype,
tgdeferrable, tginitdeferred
FROM pg_trigger t JOIN pg_constraint c ON (t.tgconstraint = c.oid)
WHERE conrelid = 'fktable'::regclass AND conname = 'fktable_fk_fkey'
ORDER BY tgrelid, tgtype;
-- Changing it back to ENFORCED will recreate the necessary FK triggers
-- that are deferrable and initially deferred
ALTER TABLE FKTABLE ALTER CONSTRAINT fktable_fk_fkey ENFORCED;
SELECT conname, tgrelid::regclass as tgrel,
regexp_replace(tgname, '[0-9]+', 'N') as tgname, tgtype,
tgdeferrable, tginitdeferred
FROM pg_trigger t JOIN pg_constraint c ON (t.tgconstraint = c.oid)
WHERE conrelid = 'fktable'::regclass AND conname = 'fktable_fk_fkey'
ORDER BY tgrelid, tgtype;
-- Verify that a deferrable, initially deferred foreign key still works
-- as expected after being set to NOT ENFORCED and then re-enabled
BEGIN;
-- doesn't match PK, but no error yet
INSERT INTO fktable VALUES (2, 20);
-- should catch error from INSERT at commit
COMMIT;
DROP TABLE fktable, pktable;
-- tricky behavior: according to SQL99, if a deferred constraint is set
-- to 'immediate' mode, it should be checked for validity *immediately*,
-- not when the current transaction commits (i.e. the mode change applies
-- retroactively)
CREATE TABLE pktable (
id INT4 PRIMARY KEY,
other INT4
);
CREATE TABLE fktable (
id INT4 PRIMARY KEY,
fk INT4 REFERENCES pktable DEFERRABLE
);
BEGIN;
SET CONSTRAINTS ALL DEFERRED;
-- should succeed, for now
INSERT INTO fktable VALUES (1000, 2000);
-- should cause transaction abort, due to preceding error
SET CONSTRAINTS ALL IMMEDIATE;
INSERT INTO pktable VALUES (2000, 3); -- too late
COMMIT;
DROP TABLE fktable, pktable;
-- deferrable, initially deferred
CREATE TABLE pktable (
id INT4 PRIMARY KEY,
other INT4
);
CREATE TABLE fktable (
id INT4 PRIMARY KEY,
fk INT4 REFERENCES pktable DEFERRABLE INITIALLY DEFERRED
);
BEGIN;
-- no error here
INSERT INTO fktable VALUES (100, 200);
-- error here on commit
COMMIT;
DROP TABLE pktable, fktable;
-- test notice about expensive referential integrity checks,
-- where the index cannot be used because of type incompatibilities.
CREATE TEMP TABLE pktable (
id1 INT4 PRIMARY KEY,
id2 VARCHAR(4) UNIQUE,
id3 REAL UNIQUE,
UNIQUE(id1, id2, id3)
);
CREATE TEMP TABLE fktable (
x1 INT4 REFERENCES pktable(id1),
x2 VARCHAR(4) REFERENCES pktable(id2),
x3 REAL REFERENCES pktable(id3),
x4 TEXT,
x5 INT2
);
-- check individual constraints with alter table.
-- should fail
-- varchar does not promote to real
ALTER TABLE fktable ADD CONSTRAINT fk_2_3
FOREIGN KEY (x2) REFERENCES pktable(id3);
-- nor to int4
ALTER TABLE fktable ADD CONSTRAINT fk_2_1
FOREIGN KEY (x2) REFERENCES pktable(id1);
-- real does not promote to int4
ALTER TABLE fktable ADD CONSTRAINT fk_3_1
FOREIGN KEY (x3) REFERENCES pktable(id1);
-- int4 does not promote to text
ALTER TABLE fktable ADD CONSTRAINT fk_1_2
FOREIGN KEY (x1) REFERENCES pktable(id2);
-- should succeed
-- int4 promotes to real
ALTER TABLE fktable ADD CONSTRAINT fk_1_3
FOREIGN KEY (x1) REFERENCES pktable(id3);
-- text is compatible with varchar
ALTER TABLE fktable ADD CONSTRAINT fk_4_2
FOREIGN KEY (x4) REFERENCES pktable(id2);
-- int2 is part of integer opfamily as of 8.0
ALTER TABLE fktable ADD CONSTRAINT fk_5_1
FOREIGN KEY (x5) REFERENCES pktable(id1);
-- check multikey cases, especially out-of-order column lists
-- these should work
ALTER TABLE fktable ADD CONSTRAINT fk_123_123
FOREIGN KEY (x1,x2,x3) REFERENCES pktable(id1,id2,id3);
ALTER TABLE fktable ADD CONSTRAINT fk_213_213
FOREIGN KEY (x2,x1,x3) REFERENCES pktable(id2,id1,id3);
ALTER TABLE fktable ADD CONSTRAINT fk_253_213
FOREIGN KEY (x2,x5,x3) REFERENCES pktable(id2,id1,id3);
-- these should fail
ALTER TABLE fktable ADD CONSTRAINT fk_123_231
FOREIGN KEY (x1,x2,x3) REFERENCES pktable(id2,id3,id1);
ALTER TABLE fktable ADD CONSTRAINT fk_241_132
FOREIGN KEY (x2,x4,x1) REFERENCES pktable(id1,id3,id2);
DROP TABLE pktable, fktable;
-- test a tricky case: we can elide firing the FK check trigger during
-- an UPDATE if the UPDATE did not change the foreign key
-- field. However, we can't do this if our transaction was the one that
-- created the updated row and the trigger is deferred, since our UPDATE
-- will have invalidated the original newly-inserted tuple, and therefore
-- cause the on-INSERT RI trigger not to be fired.
CREATE TEMP TABLE pktable (
id int primary key,
other int
);
CREATE TEMP TABLE fktable (
id int primary key,
fk int references pktable deferrable initially deferred
);
INSERT INTO pktable VALUES (5, 10);
BEGIN;
-- doesn't match PK, but no error yet
INSERT INTO fktable VALUES (0, 20);
-- don't change FK
UPDATE fktable SET id = id + 1;
-- should catch error from initial INSERT
COMMIT;
-- check same case when insert is in a different subtransaction than update
BEGIN;
-- doesn't match PK, but no error yet
INSERT INTO fktable VALUES (0, 20);
-- UPDATE will be in a subxact
SAVEPOINT savept1;
-- don't change FK
UPDATE fktable SET id = id + 1;
-- should catch error from initial INSERT
COMMIT;
BEGIN;
-- INSERT will be in a subxact
SAVEPOINT savept1;
-- doesn't match PK, but no error yet
INSERT INTO fktable VALUES (0, 20);
RELEASE SAVEPOINT savept1;
-- don't change FK
UPDATE fktable SET id = id + 1;
-- should catch error from initial INSERT
COMMIT;
BEGIN;
-- doesn't match PK, but no error yet
INSERT INTO fktable VALUES (0, 20);
-- UPDATE will be in a subxact
SAVEPOINT savept1;
-- don't change FK
UPDATE fktable SET id = id + 1;
-- Roll back the UPDATE
ROLLBACK TO savept1;
-- should catch error from initial INSERT
COMMIT;
--
-- check ALTER CONSTRAINT
--
INSERT INTO fktable VALUES (1, 5);
ALTER TABLE fktable ALTER CONSTRAINT fktable_fk_fkey DEFERRABLE INITIALLY IMMEDIATE;
BEGIN;
-- doesn't match FK, should throw error now
UPDATE pktable SET id = 10 WHERE id = 5;
COMMIT;
BEGIN;
-- doesn't match PK, should throw error now
INSERT INTO fktable VALUES (0, 20);
COMMIT;
ALTER TABLE fktable ALTER CONSTRAINT fktable_fk_fkey NOT ENFORCED;
BEGIN;
-- doesn't match FK, but no error.
UPDATE pktable SET id = 10 WHERE id = 5;
-- doesn't match PK, but no error.
INSERT INTO fktable VALUES (0, 20);
ROLLBACK;
-- try additional syntax
ALTER TABLE fktable ALTER CONSTRAINT fktable_fk_fkey NOT DEFERRABLE;
-- illegal options
ALTER TABLE fktable ALTER CONSTRAINT fktable_fk_fkey NOT DEFERRABLE INITIALLY DEFERRED;
ALTER TABLE fktable ALTER CONSTRAINT fktable_fk_fkey NO INHERIT;
ALTER TABLE fktable ALTER CONSTRAINT fktable_fk_fkey NOT VALID;
ALTER TABLE fktable ALTER CONSTRAINT fktable_fk_fkey ENFORCED NOT ENFORCED;
CREATE TEMP TABLE fktable2 (fk int references pktable ENFORCED NOT ENFORCED);
-- test order of firing of FK triggers when several RI-induced changes need to
-- be made to the same row. This was broken by subtransaction-related
-- changes in 8.0.
CREATE TEMP TABLE users (
id INT PRIMARY KEY,
name VARCHAR NOT NULL
);
INSERT INTO users VALUES (1, 'Jozko');
INSERT INTO users VALUES (2, 'Ferko');
INSERT INTO users VALUES (3, 'Samko');
CREATE TEMP TABLE tasks (
id INT PRIMARY KEY,
owner INT REFERENCES users ON UPDATE CASCADE ON DELETE SET NULL,
worker INT REFERENCES users ON UPDATE CASCADE ON DELETE SET NULL,
checked_by INT REFERENCES users ON UPDATE CASCADE ON DELETE SET NULL
);
INSERT INTO tasks VALUES (1,1,NULL,NULL);
INSERT INTO tasks VALUES (2,2,2,NULL);
INSERT INTO tasks VALUES (3,3,3,3);
SELECT * FROM tasks;
UPDATE users SET id = 4 WHERE id = 3;
SELECT * FROM tasks;
DELETE FROM users WHERE id = 4;
SELECT * FROM tasks;
-- could fail with only 2 changes to make, if row was already updated
BEGIN;
UPDATE tasks set id=id WHERE id=2;
SELECT * FROM tasks;
DELETE FROM users WHERE id = 2;
SELECT * FROM tasks;
COMMIT;
--
-- Test self-referential FK with CASCADE (bug #6268)
--
create temp table selfref (
a int primary key,
b int,
foreign key (b) references selfref (a)
on update cascade on delete cascade
);
insert into selfref (a, b)
values
(0, 0),
(1, 1);
begin;
update selfref set a = 123 where a = 0;
select a, b from selfref;
update selfref set a = 456 where a = 123;
select a, b from selfref;
commit;
--
-- Test that SET DEFAULT actions recognize updates to default values
--
create temp table defp (f1 int primary key);
create temp table defc (f1 int default 0
references defp on delete set default);
insert into defp values (0), (1), (2);
insert into defc values (2);
select * from defc;
delete from defp where f1 = 2;
select * from defc;
delete from defp where f1 = 0; -- fail
alter table defc alter column f1 set default 1;
delete from defp where f1 = 0;
select * from defc;
delete from defp where f1 = 1; -- fail
--
-- Test the difference between NO ACTION and RESTRICT
--
create temp table pp (f1 int primary key);
create temp table cc (f1 int references pp on update no action on delete no action);
insert into pp values(12);
insert into pp values(11);
update pp set f1=f1+1;
insert into cc values(13);
update pp set f1=f1+1;
update pp set f1=f1+1; -- fail
delete from pp where f1 = 13; -- fail
drop table pp, cc;
create temp table pp (f1 int primary key);
create temp table cc (f1 int references pp on update restrict on delete restrict);
insert into pp values(12);
insert into pp values(11);
update pp set f1=f1+1;
insert into cc values(13);
update pp set f1=f1+1; -- fail
delete from pp where f1 = 13; -- fail
drop table pp, cc;
--
-- Test interaction of foreign-key optimization with rules (bug #14219)
--
create temp table t1 (a integer primary key, b text);
create temp table t2 (a integer primary key, b integer references t1);
create rule r1 as on delete to t1 do delete from t2 where t2.b = old.a;
explain (costs off) delete from t1 where a = 1;
delete from t1 where a = 1;
-- Test a primary key with attributes located in later attnum positions
-- compared to the fk attributes.
create table pktable2 (a int, b int, c int, d int, e int, primary key (d, e));
create table fktable2 (d int, e int, foreign key (d, e) references pktable2);
insert into pktable2 values (1, 2, 3, 4, 5);
insert into fktable2 values (4, 5);
delete from pktable2;
update pktable2 set d = 5;
drop table pktable2, fktable2;
-- Test truncation of long foreign key names
create table pktable1 (a int primary key);
create table pktable2 (a int, b int, primary key (a, b));
create table fktable2 (
a int,
b int,
very_very_long_column_name_to_exceed_63_characters int,
foreign key (very_very_long_column_name_to_exceed_63_characters) references pktable1,
foreign key (a, very_very_long_column_name_to_exceed_63_characters) references pktable2,
foreign key (a, very_very_long_column_name_to_exceed_63_characters) references pktable2
);
select conname from pg_constraint where conrelid = 'fktable2'::regclass order by conname;
drop table pktable1, pktable2, fktable2;
--
-- Test deferred FK check on a tuple deleted by a rolled-back subtransaction
--
create table pktable2(f1 int primary key);
create table fktable2(f1 int references pktable2 deferrable initially deferred);
insert into pktable2 values(1);
begin;
insert into fktable2 values(1);
savepoint x;
delete from fktable2;
rollback to x;
commit;
begin;
insert into fktable2 values(2);
savepoint x;
delete from fktable2;
rollback to x;
commit; -- fail
--
-- Test that we prevent dropping FK constraint with pending trigger events
--
begin;
insert into fktable2 values(2);
alter table fktable2 drop constraint fktable2_f1_fkey;
commit;
begin;
delete from pktable2 where f1 = 1;
alter table fktable2 drop constraint fktable2_f1_fkey;
commit;
drop table pktable2, fktable2;
--
-- Test keys that "look" different but compare as equal
--
create table pktable2 (a float8, b float8, primary key (a, b));
create table fktable2 (x float8, y float8, foreign key (x, y) references pktable2 (a, b) on update cascade);
insert into pktable2 values ('-0', '-0');
insert into fktable2 values ('-0', '-0');
select * from pktable2;
select * from fktable2;
update pktable2 set a = '0' where a = '-0';
select * from pktable2;
-- should have updated fktable2.x
select * from fktable2;
drop table pktable2, fktable2;
--
-- Foreign keys and partitioned tables
--
-- Creation of a partitioned hierarchy with irregular definitions
CREATE TABLE fk_notpartitioned_pk (fdrop1 int, a int, fdrop2 int, b int,
PRIMARY KEY (a, b));
ALTER TABLE fk_notpartitioned_pk DROP COLUMN fdrop1, DROP COLUMN fdrop2;
CREATE TABLE fk_partitioned_fk (b int, fdrop1 int, a int) PARTITION BY RANGE (a, b);
ALTER TABLE fk_partitioned_fk DROP COLUMN fdrop1;
CREATE TABLE fk_partitioned_fk_1 (fdrop1 int, fdrop2 int, a int, fdrop3 int, b int);
ALTER TABLE fk_partitioned_fk_1 DROP COLUMN fdrop1, DROP COLUMN fdrop2, DROP COLUMN fdrop3;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_1 FOR VALUES FROM (0,0) TO (1000,1000);
ALTER TABLE fk_partitioned_fk ADD CONSTRAINT fk_partitioned_fk_a_b_fkey FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk NOT ENFORCED;
CREATE TABLE fk_partitioned_fk_2 (b int, fdrop1 int, fdrop2 int, a int);
ALTER TABLE fk_partitioned_fk_2 DROP COLUMN fdrop1, DROP COLUMN fdrop2;
ALTER TABLE fk_partitioned_fk_2 ADD CONSTRAINT fk_partitioned_fk_a_b_fkey FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk NOT ENFORCED;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES FROM (1000,1000) TO (2000,2000);
ALTER TABLE fk_partitioned_fk ALTER CONSTRAINT fk_partitioned_fk_a_b_fkey ENFORCED;
CREATE TABLE fk_partitioned_fk_3 (fdrop1 int, fdrop2 int, fdrop3 int, fdrop4 int, b int, a int)
PARTITION BY HASH (a);
ALTER TABLE fk_partitioned_fk_3 DROP COLUMN fdrop1, DROP COLUMN fdrop2,
DROP COLUMN fdrop3, DROP COLUMN fdrop4;
CREATE TABLE fk_partitioned_fk_3_0 PARTITION OF fk_partitioned_fk_3 FOR VALUES WITH (MODULUS 5, REMAINDER 0);
CREATE TABLE fk_partitioned_fk_3_1 PARTITION OF fk_partitioned_fk_3 FOR VALUES WITH (MODULUS 5, REMAINDER 1);
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_3
FOR VALUES FROM (2000,2000) TO (3000,3000);
-- Creating a foreign key with ONLY on a partitioned table referencing
-- a non-partitioned table fails.
ALTER TABLE ONLY fk_partitioned_fk ADD FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk;
-- these inserts, targeting both the partition directly as well as the
-- partitioned table, should all fail
INSERT INTO fk_partitioned_fk (a,b) VALUES (500, 501);
INSERT INTO fk_partitioned_fk_1 (a,b) VALUES (500, 501);
INSERT INTO fk_partitioned_fk (a,b) VALUES (1500, 1501);
INSERT INTO fk_partitioned_fk_2 (a,b) VALUES (1500, 1501);
INSERT INTO fk_partitioned_fk (a,b) VALUES (2500, 2502);
INSERT INTO fk_partitioned_fk_3 (a,b) VALUES (2500, 2502);
INSERT INTO fk_partitioned_fk (a,b) VALUES (2501, 2503);
INSERT INTO fk_partitioned_fk_3 (a,b) VALUES (2501, 2503);
-- but if we insert the values that make them valid, then they work
INSERT INTO fk_notpartitioned_pk VALUES (500, 501), (1500, 1501),
(2500, 2502), (2501, 2503);
INSERT INTO fk_partitioned_fk (a,b) VALUES (500, 501);
INSERT INTO fk_partitioned_fk (a,b) VALUES (1500, 1501);
INSERT INTO fk_partitioned_fk (a,b) VALUES (2500, 2502);
INSERT INTO fk_partitioned_fk (a,b) VALUES (2501, 2503);
-- this update fails because there is no referenced row
UPDATE fk_partitioned_fk SET a = a + 1 WHERE a = 2501;
-- but we can fix it thusly:
INSERT INTO fk_notpartitioned_pk (a,b) VALUES (2502, 2503);
UPDATE fk_partitioned_fk SET a = a + 1 WHERE a = 2501;
-- these updates would leave lingering rows in the referencing table; disallow
UPDATE fk_notpartitioned_pk SET b = 502 WHERE a = 500;
UPDATE fk_notpartitioned_pk SET b = 1502 WHERE a = 1500;
UPDATE fk_notpartitioned_pk SET b = 2504 WHERE a = 2500;
-- check psql behavior
\d fk_notpartitioned_pk
-- Check the existing FK trigger
SELECT conname, tgrelid::regclass as tgrel, regexp_replace(tgname, '[0-9]+', 'N') as tgname, tgtype
FROM pg_trigger t JOIN pg_constraint c ON (t.tgconstraint = c.oid)
WHERE tgrelid IN (SELECT relid FROM pg_partition_tree('fk_partitioned_fk'::regclass)
UNION ALL SELECT 'fk_notpartitioned_pk'::regclass)
ORDER BY tgrelid, tgtype;
ALTER TABLE fk_partitioned_fk ALTER CONSTRAINT fk_partitioned_fk_a_b_fkey NOT ENFORCED;
-- No triggers
SELECT conname, tgrelid::regclass as tgrel, regexp_replace(tgname, '[0-9]+', 'N') as tgname, tgtype
FROM pg_trigger t JOIN pg_constraint c ON (t.tgconstraint = c.oid)
WHERE tgrelid IN (SELECT relid FROM pg_partition_tree('fk_partitioned_fk'::regclass)
UNION ALL SELECT 'fk_notpartitioned_pk'::regclass)
ORDER BY tgrelid, tgtype;
-- Changing it back to ENFORCED will recreate the necessary triggers.
ALTER TABLE fk_partitioned_fk ALTER CONSTRAINT fk_partitioned_fk_a_b_fkey ENFORCED;
-- Should be exactly the same number of triggers found as before
SELECT conname, tgrelid::regclass as tgrel, regexp_replace(tgname, '[0-9]+', 'N') as tgname, tgtype
FROM pg_trigger t JOIN pg_constraint c ON (t.tgconstraint = c.oid)
WHERE tgrelid IN (SELECT relid FROM pg_partition_tree('fk_partitioned_fk'::regclass)
UNION ALL SELECT 'fk_notpartitioned_pk'::regclass)
ORDER BY tgrelid, tgtype;
ALTER TABLE fk_partitioned_fk DROP CONSTRAINT fk_partitioned_fk_a_b_fkey;
-- done.
DROP TABLE fk_notpartitioned_pk, fk_partitioned_fk;
-- Altering a type referenced by a foreign key needs to drop/recreate the FK.
-- Ensure that works.
CREATE TABLE fk_notpartitioned_pk (a INT, PRIMARY KEY(a), CHECK (a > 0));
CREATE TABLE fk_partitioned_fk (a INT REFERENCES fk_notpartitioned_pk(a) PRIMARY KEY) PARTITION BY RANGE(a);
CREATE TABLE fk_partitioned_fk_1 PARTITION OF fk_partitioned_fk FOR VALUES FROM (MINVALUE) TO (MAXVALUE);
INSERT INTO fk_notpartitioned_pk VALUES (1);
INSERT INTO fk_partitioned_fk VALUES (1);
ALTER TABLE fk_notpartitioned_pk ALTER COLUMN a TYPE bigint;
DELETE FROM fk_notpartitioned_pk WHERE a = 1;
DROP TABLE fk_notpartitioned_pk, fk_partitioned_fk;
-- NOT VALID foreign keys on partitioned table
CREATE TABLE fk_notpartitioned_pk (a int, b int, PRIMARY KEY (a, b));
CREATE TABLE fk_partitioned_fk (b int, a int) PARTITION BY RANGE (a, b);
ALTER TABLE fk_partitioned_fk ADD FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk NOT VALID;
-- Attaching a child table with the same valid foreign key constraint.
CREATE TABLE fk_partitioned_fk_1 (a int, b int);
ALTER TABLE fk_partitioned_fk_1 ADD FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_1 FOR VALUES FROM (0,0) TO (1000,1000);
-- Child constraint will remain valid.
SELECT conname, convalidated, conrelid::regclass FROM pg_constraint
WHERE conrelid::regclass::text like 'fk_partitioned_fk%' ORDER BY oid::regclass::text;
-- Validate the constraint
ALTER TABLE fk_partitioned_fk VALIDATE CONSTRAINT fk_partitioned_fk_a_b_fkey;
-- All constraints are now valid.
SELECT conname, convalidated, conrelid::regclass FROM pg_constraint
WHERE conrelid::regclass::text like 'fk_partitioned_fk%' ORDER BY oid::regclass::text;
-- Attaching a child with a NOT VALID constraint.
CREATE TABLE fk_partitioned_fk_2 (a int, b int);
INSERT INTO fk_partitioned_fk_2 VALUES(1000, 1000); -- doesn't exist in referenced table
ALTER TABLE fk_partitioned_fk_2 ADD FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk NOT VALID;
-- It will fail because the attach operation implicitly validates the data.
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES FROM (1000,1000) TO (2000,2000);
-- Remove the invalid data and try again.
TRUNCATE fk_partitioned_fk_2;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES FROM (1000,1000) TO (2000,2000);
-- The child constraint will also be valid.
SELECT conname, convalidated FROM pg_constraint
WHERE conrelid = 'fk_partitioned_fk_2'::regclass ORDER BY oid::regclass::text;
-- Test case where the child constraint is invalid, the grandchild constraint
-- is valid, and the validation for the grandchild should be skipped when a
-- valid constraint is applied to the top parent.
CREATE TABLE fk_partitioned_fk_3 (a int, b int) PARTITION BY RANGE (a, b);
ALTER TABLE fk_partitioned_fk_3 ADD FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk NOT VALID;
CREATE TABLE fk_partitioned_fk_3_1 (a int, b int);
ALTER TABLE fk_partitioned_fk_3_1 ADD FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk;
ALTER TABLE fk_partitioned_fk_3 ATTACH PARTITION fk_partitioned_fk_3_1 FOR VALUES FROM (2000,2000) TO (3000,3000);
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_3 FOR VALUES FROM (2000,2000) TO (3000,3000);
-- All constraints are now valid.
SELECT conname, convalidated, conrelid::regclass FROM pg_constraint
WHERE conrelid::regclass::text like 'fk_partitioned_fk%' ORDER BY oid::regclass::text;
DROP TABLE fk_partitioned_fk, fk_notpartitioned_pk;
-- NOT VALID and NOT ENFORCED foreign key on a non-partitioned table
-- referencing a partitioned table
CREATE TABLE fk_partitioned_pk (a int, b int, PRIMARY KEY (a, b)) PARTITION BY RANGE (a, b);
CREATE TABLE fk_partitioned_pk_1 PARTITION OF fk_partitioned_pk FOR VALUES FROM (0,0) TO (1000,1000);
CREATE TABLE fk_partitioned_pk_2 PARTITION OF fk_partitioned_pk FOR VALUES FROM (1000,1000) TO (2000,2000);
CREATE TABLE fk_notpartitioned_fk (b int, a int);
INSERT INTO fk_partitioned_pk VALUES(100,100), (1000,1000);
INSERT INTO fk_notpartitioned_fk VALUES(100,100), (1000,1000);
ALTER TABLE fk_notpartitioned_fk ADD CONSTRAINT fk_notpartitioned_fk_a_b_fkey
FOREIGN KEY (a, b) REFERENCES fk_partitioned_pk NOT VALID;
ALTER TABLE fk_notpartitioned_fk ADD CONSTRAINT fk_notpartitioned_fk_a_b_fkey2
FOREIGN KEY (a, b) REFERENCES fk_partitioned_pk NOT ENFORCED;
-- All constraints will be invalid, and _fkey2 constraints will not be enforced.
SELECT conname, conenforced, convalidated FROM pg_constraint
WHERE conrelid = 'fk_notpartitioned_fk'::regclass ORDER BY oid::regclass::text;
ALTER TABLE fk_notpartitioned_fk VALIDATE CONSTRAINT fk_notpartitioned_fk_a_b_fkey;
ALTER TABLE fk_notpartitioned_fk ALTER CONSTRAINT fk_notpartitioned_fk_a_b_fkey2 ENFORCED;
-- All constraints are now valid and enforced.
SELECT conname, conenforced, convalidated FROM pg_constraint
WHERE conrelid = 'fk_notpartitioned_fk'::regclass ORDER BY oid::regclass::text;
-- test a self-referential FK
ALTER TABLE fk_partitioned_pk ADD CONSTRAINT selffk FOREIGN KEY (a, b) REFERENCES fk_partitioned_pk NOT VALID;
CREATE TABLE fk_partitioned_pk_3 PARTITION OF fk_partitioned_pk FOR VALUES FROM (2000,2000) TO (3000,3000)
PARTITION BY RANGE (a);
CREATE TABLE fk_partitioned_pk_3_1 PARTITION OF fk_partitioned_pk_3 FOR VALUES FROM (2000) TO (2100);
SELECT conname, conenforced, convalidated FROM pg_constraint
WHERE conrelid = 'fk_partitioned_pk'::regclass AND contype = 'f'
ORDER BY oid::regclass::text;
ALTER TABLE fk_partitioned_pk_2 VALIDATE CONSTRAINT selffk;
ALTER TABLE fk_partitioned_pk VALIDATE CONSTRAINT selffk;
SELECT conname, conenforced, convalidated FROM pg_constraint
WHERE conrelid = 'fk_partitioned_pk'::regclass AND contype = 'f'
ORDER BY oid::regclass::text;
DROP TABLE fk_notpartitioned_fk, fk_partitioned_pk;
-- Test some other exotic foreign key features: MATCH SIMPLE, ON UPDATE/DELETE
-- actions
CREATE TABLE fk_notpartitioned_pk (a int, b int, primary key (a, b));
CREATE TABLE fk_partitioned_fk (a int default 2501, b int default 142857) PARTITION BY LIST (a);
CREATE TABLE fk_partitioned_fk_1 PARTITION OF fk_partitioned_fk FOR VALUES IN (NULL,500,501,502);
ALTER TABLE fk_partitioned_fk ADD FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk MATCH SIMPLE
ON DELETE SET NULL ON UPDATE SET NULL;
CREATE TABLE fk_partitioned_fk_2 PARTITION OF fk_partitioned_fk FOR VALUES IN (1500,1502);
CREATE TABLE fk_partitioned_fk_3 (a int, b int);
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_3 FOR VALUES IN (2500,2501,2502,2503);
-- this insert fails
INSERT INTO fk_partitioned_fk (a, b) VALUES (2502, 2503);
INSERT INTO fk_partitioned_fk_3 (a, b) VALUES (2502, 2503);
-- but since the FK is MATCH SIMPLE, this one doesn't
INSERT INTO fk_partitioned_fk_3 (a, b) VALUES (2502, NULL);
-- now create the referenced row ...
INSERT INTO fk_notpartitioned_pk VALUES (2502, 2503);
--- and now the same insert work
INSERT INTO fk_partitioned_fk_3 (a, b) VALUES (2502, 2503);
-- this always works
INSERT INTO fk_partitioned_fk (a,b) VALUES (NULL, NULL);
-- MATCH FULL
INSERT INTO fk_notpartitioned_pk VALUES (1, 2);
CREATE TABLE fk_partitioned_fk_full (x int, y int) PARTITION BY RANGE (x);
CREATE TABLE fk_partitioned_fk_full_1 PARTITION OF fk_partitioned_fk_full DEFAULT;
INSERT INTO fk_partitioned_fk_full VALUES (1, NULL);
ALTER TABLE fk_partitioned_fk_full ADD FOREIGN KEY (x, y) REFERENCES fk_notpartitioned_pk MATCH FULL; -- fails
TRUNCATE fk_partitioned_fk_full;
ALTER TABLE fk_partitioned_fk_full ADD FOREIGN KEY (x, y) REFERENCES fk_notpartitioned_pk MATCH FULL;
INSERT INTO fk_partitioned_fk_full VALUES (1, NULL); -- fails
DROP TABLE fk_partitioned_fk_full;
-- ON UPDATE SET NULL
SELECT tableoid::regclass, a, b FROM fk_partitioned_fk WHERE b IS NULL ORDER BY a;
UPDATE fk_notpartitioned_pk SET a = a + 1 WHERE a = 2502;
SELECT tableoid::regclass, a, b FROM fk_partitioned_fk WHERE b IS NULL ORDER BY a;
-- ON DELETE SET NULL
INSERT INTO fk_partitioned_fk VALUES (2503, 2503);
SELECT count(*) FROM fk_partitioned_fk WHERE a IS NULL;
DELETE FROM fk_notpartitioned_pk;
SELECT count(*) FROM fk_partitioned_fk WHERE a IS NULL;
-- ON UPDATE/DELETE SET DEFAULT
ALTER TABLE fk_partitioned_fk DROP CONSTRAINT fk_partitioned_fk_a_b_fkey;
ALTER TABLE fk_partitioned_fk ADD FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk
ON DELETE SET DEFAULT ON UPDATE SET DEFAULT;
INSERT INTO fk_notpartitioned_pk VALUES (2502, 2503);
INSERT INTO fk_partitioned_fk_3 (a, b) VALUES (2502, 2503);
-- this fails, because the defaults for the referencing table are not present
-- in the referenced table:
UPDATE fk_notpartitioned_pk SET a = 1500 WHERE a = 2502;
-- but inserting the row we can make it work:
INSERT INTO fk_notpartitioned_pk VALUES (2501, 142857);
UPDATE fk_notpartitioned_pk SET a = 1500 WHERE a = 2502;
SELECT * FROM fk_partitioned_fk WHERE b = 142857;
-- ON DELETE SET NULL column_list
ALTER TABLE fk_partitioned_fk DROP CONSTRAINT fk_partitioned_fk_a_b_fkey;
ALTER TABLE fk_partitioned_fk ADD FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk
ON DELETE SET NULL (a);
BEGIN;
DELETE FROM fk_notpartitioned_pk WHERE b = 142857;
SELECT * FROM fk_partitioned_fk WHERE a IS NOT NULL OR b IS NOT NULL ORDER BY a NULLS LAST;
ROLLBACK;
-- ON DELETE SET DEFAULT column_list
ALTER TABLE fk_partitioned_fk DROP CONSTRAINT fk_partitioned_fk_a_b_fkey;
ALTER TABLE fk_partitioned_fk ADD FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk
ON DELETE SET DEFAULT (a);
BEGIN;
DELETE FROM fk_partitioned_fk;
DELETE FROM fk_notpartitioned_pk;
INSERT INTO fk_notpartitioned_pk VALUES (500, 100000), (2501, 100000);
INSERT INTO fk_partitioned_fk VALUES (500, 100000);
DELETE FROM fk_notpartitioned_pk WHERE a = 500;
SELECT * FROM fk_partitioned_fk ORDER BY a;
ROLLBACK;
-- ON UPDATE/DELETE CASCADE
ALTER TABLE fk_partitioned_fk DROP CONSTRAINT fk_partitioned_fk_a_b_fkey;
ALTER TABLE fk_partitioned_fk ADD FOREIGN KEY (a, b)
REFERENCES fk_notpartitioned_pk
ON DELETE CASCADE ON UPDATE CASCADE;
UPDATE fk_notpartitioned_pk SET a = 2502 WHERE a = 2501;
SELECT * FROM fk_partitioned_fk WHERE b = 142857;
-- Now you see it ...
SELECT * FROM fk_partitioned_fk WHERE b = 142857;
DELETE FROM fk_notpartitioned_pk WHERE b = 142857;
-- now you don't.
SELECT * FROM fk_partitioned_fk WHERE a = 142857;
-- verify that DROP works
DROP TABLE fk_partitioned_fk_2;
-- Test behavior of the constraint together with attaching and detaching
-- partitions.
CREATE TABLE fk_partitioned_fk_2 PARTITION OF fk_partitioned_fk FOR VALUES IN (1500,1502);
ALTER TABLE fk_partitioned_fk DETACH PARTITION fk_partitioned_fk_2;
BEGIN;
DROP TABLE fk_partitioned_fk;
-- constraint should still be there
\d fk_partitioned_fk_2;
ROLLBACK;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES IN (1500,1502);
DROP TABLE fk_partitioned_fk_2;
CREATE TABLE fk_partitioned_fk_2 (b int, c text, a int,
FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk ON UPDATE CASCADE ON DELETE CASCADE);
ALTER TABLE fk_partitioned_fk_2 DROP COLUMN c;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES IN (1500,1502);
-- should have only one constraint
\d fk_partitioned_fk_2
DROP TABLE fk_partitioned_fk_2;
CREATE TABLE fk_partitioned_fk_2 (b int, a int,
CONSTRAINT fk_part_con FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk ON UPDATE CASCADE ON DELETE CASCADE NOT ENFORCED);
-- fail -- cannot merge constraints with different enforceability.
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES IN (1500,1502);
-- If the constraint is modified to match the enforceability of the parent, it will work.
BEGIN;
-- change child constraint
ALTER TABLE fk_partitioned_fk_2 ALTER CONSTRAINT fk_part_con ENFORCED;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES IN (1500,1502);
\d fk_partitioned_fk_2
ROLLBACK;
BEGIN;
-- or change parent constraint
ALTER TABLE fk_partitioned_fk ALTER CONSTRAINT fk_partitioned_fk_a_b_fkey NOT ENFORCED;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2 FOR VALUES IN (1500,1502);
\d fk_partitioned_fk_2
ROLLBACK;
DROP TABLE fk_partitioned_fk_2;
CREATE TABLE fk_partitioned_fk_4 (a int, b int, FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk(a, b) ON UPDATE CASCADE ON DELETE CASCADE) PARTITION BY RANGE (b, a);
CREATE TABLE fk_partitioned_fk_4_1 PARTITION OF fk_partitioned_fk_4 FOR VALUES FROM (1,1) TO (100,100);
CREATE TABLE fk_partitioned_fk_4_2 (a int, b int, FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk(a, b) ON UPDATE SET NULL);
ALTER TABLE fk_partitioned_fk_4 ATTACH PARTITION fk_partitioned_fk_4_2 FOR VALUES FROM (100,100) TO (1000,1000);
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_4 FOR VALUES IN (3500,3502);
ALTER TABLE fk_partitioned_fk DETACH PARTITION fk_partitioned_fk_4;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_4 FOR VALUES IN (3500,3502);
-- should only have one constraint
\d fk_partitioned_fk_4
\d fk_partitioned_fk_4_1
-- this one has an FK with mismatched properties
\d fk_partitioned_fk_4_2
CREATE TABLE fk_partitioned_fk_5 (a int, b int,
FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk(a, b) ON UPDATE CASCADE ON DELETE CASCADE DEFERRABLE,
FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk(a, b) MATCH FULL ON UPDATE CASCADE ON DELETE CASCADE)
PARTITION BY RANGE (a);
CREATE TABLE fk_partitioned_fk_5_1 (a int, b int, FOREIGN KEY (a, b) REFERENCES fk_notpartitioned_pk);
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_5 FOR VALUES IN (4500);
ALTER TABLE fk_partitioned_fk_5 ATTACH PARTITION fk_partitioned_fk_5_1 FOR VALUES FROM (0) TO (10);
ALTER TABLE fk_partitioned_fk DETACH PARTITION fk_partitioned_fk_5;
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_5 FOR VALUES IN (4500);
-- this one has two constraints, similar but not quite the one in the parent,
-- so it gets a new one
\d fk_partitioned_fk_5
-- verify that it works to reattaching a child with multiple candidate
-- constraints
ALTER TABLE fk_partitioned_fk_5 DETACH PARTITION fk_partitioned_fk_5_1;
ALTER TABLE fk_partitioned_fk_5 ATTACH PARTITION fk_partitioned_fk_5_1 FOR VALUES FROM (0) TO (10);
\d fk_partitioned_fk_5_1
-- verify that attaching a table checks that the existing data satisfies the
-- constraint
CREATE TABLE fk_partitioned_fk_2 (a int, b int) PARTITION BY RANGE (b);
CREATE TABLE fk_partitioned_fk_2_1 PARTITION OF fk_partitioned_fk_2 FOR VALUES FROM (0) TO (1000);
CREATE TABLE fk_partitioned_fk_2_2 PARTITION OF fk_partitioned_fk_2 FOR VALUES FROM (1000) TO (2000);
INSERT INTO fk_partitioned_fk_2 VALUES (1600, 601), (1600, 1601);
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2
FOR VALUES IN (1600);
INSERT INTO fk_notpartitioned_pk VALUES (1600, 601), (1600, 1601);
ALTER TABLE fk_partitioned_fk ATTACH PARTITION fk_partitioned_fk_2
FOR VALUES IN (1600);
-- leave these tables around intentionally
-- Verify that attaching a table that's referenced by an existing FK
-- in the parent throws an error
CREATE TABLE fk_partitioned_pk_6 (a int PRIMARY KEY);
CREATE TABLE fk_partitioned_fk_6 (a int REFERENCES fk_partitioned_pk_6) PARTITION BY LIST (a);
ALTER TABLE fk_partitioned_fk_6 ATTACH PARTITION fk_partitioned_pk_6 FOR VALUES IN (1);
DROP TABLE fk_partitioned_pk_6, fk_partitioned_fk_6;
-- Verify that attaching to a parent with two identical constraints work
CREATE TABLE fk_partitioned_pk_6 (a int PRIMARY KEY);
CREATE TABLE fk_partitioned_fk_6 (a int,
FOREIGN KEY (a) REFERENCES fk_partitioned_pk_6,
FOREIGN KEY (a) REFERENCES fk_partitioned_pk_6
) PARTITION BY LIST (a);
CREATE TABLE fk_partitioned_fk_6_1 PARTITION OF fk_partitioned_fk_6 FOR VALUES IN (1);
ALTER TABLE fk_partitioned_fk_6 DETACH PARTITION fk_partitioned_fk_6_1;
ALTER TABLE fk_partitioned_fk_6 ATTACH PARTITION fk_partitioned_fk_6_1 FOR VALUES IN (1);
DROP TABLE fk_partitioned_pk_6, fk_partitioned_fk_6;
-- This case is similar to above, but the referenced relation is one level
-- lower in the hierarchy. This one fails in a different way as the above,
-- because we don't bother to protect against this case explicitly. If the
-- current error stops happening, we'll need to add a better protection.
CREATE TABLE fk_partitioned_pk_6 (a int PRIMARY KEY) PARTITION BY list (a);
CREATE TABLE fk_partitioned_pk_61 PARTITION OF fk_partitioned_pk_6 FOR VALUES IN (1);
CREATE TABLE fk_partitioned_fk_6 (a int REFERENCES fk_partitioned_pk_61) PARTITION BY LIST (a);
ALTER TABLE fk_partitioned_fk_6 ATTACH PARTITION fk_partitioned_pk_6 FOR VALUES IN (1);
DROP TABLE fk_partitioned_pk_6, fk_partitioned_fk_6;
-- test the case when the referenced table is owned by a different user
create role regress_other_partitioned_fk_owner;
grant references on fk_notpartitioned_pk to regress_other_partitioned_fk_owner;
set role regress_other_partitioned_fk_owner;
create table other_partitioned_fk(a int, b int) partition by list (a);
create table other_partitioned_fk_1 partition of other_partitioned_fk
for values in (2048);
insert into other_partitioned_fk
select 2048, x from generate_series(1,10) x;
-- this should fail
alter table other_partitioned_fk add foreign key (a, b)
references fk_notpartitioned_pk(a, b);
-- add the missing keys and retry
reset role;
insert into fk_notpartitioned_pk (a, b)
select 2048, x from generate_series(1,10) x;
set role regress_other_partitioned_fk_owner;
alter table other_partitioned_fk add foreign key (a, b)
references fk_notpartitioned_pk(a, b);
-- clean up
drop table other_partitioned_fk;
reset role;
revoke all on fk_notpartitioned_pk from regress_other_partitioned_fk_owner;
drop role regress_other_partitioned_fk_owner;
--
-- Test self-referencing foreign key with partition.
-- This should create only one fk constraint per partition
--
CREATE TABLE parted_self_fk (
id bigint NOT NULL PRIMARY KEY,
id_abc bigint,
FOREIGN KEY (id_abc) REFERENCES parted_self_fk(id)
)
PARTITION BY RANGE (id);
CREATE TABLE part1_self_fk (
id bigint NOT NULL PRIMARY KEY,
id_abc bigint
);
ALTER TABLE parted_self_fk ATTACH PARTITION part1_self_fk FOR VALUES FROM (0) TO (10);
CREATE TABLE part2_self_fk PARTITION OF parted_self_fk FOR VALUES FROM (10) TO (20);
CREATE TABLE part3_self_fk ( -- a partitioned partition
id bigint NOT NULL PRIMARY KEY,
id_abc bigint
) PARTITION BY RANGE (id);
CREATE TABLE part32_self_fk PARTITION OF part3_self_fk FOR VALUES FROM (20) TO (30);
ALTER TABLE parted_self_fk ATTACH PARTITION part3_self_fk FOR VALUES FROM (20) TO (40);
CREATE TABLE part33_self_fk (
id bigint NOT NULL PRIMARY KEY,
id_abc bigint
);
ALTER TABLE part3_self_fk ATTACH PARTITION part33_self_fk FOR VALUES FROM (30) TO (40);
-- verify that this constraint works
INSERT INTO parted_self_fk VALUES (1, NULL), (2, NULL), (3, NULL);
INSERT INTO parted_self_fk VALUES (10, 1), (11, 2), (12, 3) RETURNING tableoid::regclass;
INSERT INTO parted_self_fk VALUES (4, 5); -- error: referenced doesn't exist
DELETE FROM parted_self_fk WHERE id = 1 RETURNING *; -- error: reference remains
SELECT cr.relname, co.conname, co.convalidated,
p.conname AS conparent, p.convalidated, cf.relname AS foreignrel
FROM pg_constraint co
JOIN pg_class cr ON cr.oid = co.conrelid
LEFT JOIN pg_class cf ON cf.oid = co.confrelid
LEFT JOIN pg_constraint p ON p.oid = co.conparentid
WHERE co.contype = 'f' AND
cr.oid IN (SELECT relid FROM pg_partition_tree('parted_self_fk'))
ORDER BY cr.relname, co.conname, p.conname;
-- detach and re-attach multiple times just to ensure everything is kosher
ALTER TABLE parted_self_fk DETACH PARTITION part2_self_fk;
INSERT INTO part2_self_fk VALUES (16, 9); -- error: referenced doesn't exist
DELETE FROM parted_self_fk WHERE id = 2 RETURNING *; -- error: reference remains
ALTER TABLE parted_self_fk ATTACH PARTITION part2_self_fk FOR VALUES FROM (10) TO (20);
INSERT INTO parted_self_fk VALUES (16, 9); -- error: referenced doesn't exist
DELETE FROM parted_self_fk WHERE id = 3 RETURNING *; -- error: reference remains
ALTER TABLE parted_self_fk DETACH PARTITION part2_self_fk;
ALTER TABLE parted_self_fk ATTACH PARTITION part2_self_fk FOR VALUES FROM (10) TO (20);
ALTER TABLE parted_self_fk DETACH PARTITION part3_self_fk;
ALTER TABLE parted_self_fk ATTACH PARTITION part3_self_fk FOR VALUES FROM (30) TO (40);
ALTER TABLE part3_self_fk DETACH PARTITION part33_self_fk;
ALTER TABLE part3_self_fk ATTACH PARTITION part33_self_fk FOR VALUES FROM (30) TO (40);
SELECT cr.relname, co.conname, co.convalidated,
p.conname AS conparent, p.convalidated, cf.relname AS foreignrel
FROM pg_constraint co
JOIN pg_class cr ON cr.oid = co.conrelid
LEFT JOIN pg_class cf ON cf.oid = co.confrelid
LEFT JOIN pg_constraint p ON p.oid = co.conparentid
WHERE co.contype = 'f' AND
cr.oid IN (SELECT relid FROM pg_partition_tree('parted_self_fk'))
ORDER BY cr.relname, co.conname, p.conname;
-- Leave this table around, for pg_upgrade/pg_dump tests
-- Test creating a constraint at the parent that already exists in partitions.
-- There should be no duplicated constraints, and attempts to drop the
-- constraint in partitions should raise appropriate errors.
create schema fkpart0
create table pkey (a int primary key)
create table fk_part (a int) partition by list (a)
create table fk_part_1 partition of fk_part
(foreign key (a) references fkpart0.pkey) for values in (1)
create table fk_part_23 partition of fk_part
(foreign key (a) references fkpart0.pkey) for values in (2, 3)
partition by list (a)
create table fk_part_23_2 partition of fk_part_23 for values in (2);
alter table fkpart0.fk_part add foreign key (a) references fkpart0.pkey;
\d fkpart0.fk_part_1 \\ -- should have only one FK
alter table fkpart0.fk_part_1 drop constraint fk_part_1_a_fkey;
\d fkpart0.fk_part_23 \\ -- should have only one FK
\d fkpart0.fk_part_23_2 \\ -- should have only one FK
alter table fkpart0.fk_part_23 drop constraint fk_part_23_a_fkey;
alter table fkpart0.fk_part_23_2 drop constraint fk_part_23_a_fkey;
create table fkpart0.fk_part_4 partition of fkpart0.fk_part for values in (4);
\d fkpart0.fk_part_4
alter table fkpart0.fk_part_4 drop constraint fk_part_a_fkey;
create table fkpart0.fk_part_56 partition of fkpart0.fk_part
for values in (5,6) partition by list (a);
create table fkpart0.fk_part_56_5 partition of fkpart0.fk_part_56
for values in (5);
\d fkpart0.fk_part_56
alter table fkpart0.fk_part_56 drop constraint fk_part_a_fkey;
alter table fkpart0.fk_part_56_5 drop constraint fk_part_a_fkey;
-- verify that attaching and detaching partitions maintains the right set of
-- triggers
create schema fkpart1
create table pkey (a int primary key)
create table fk_part (a int) partition by list (a)
create table fk_part_1 partition of fk_part for values in (1) partition by list (a)
create table fk_part_1_1 partition of fk_part_1 for values in (1);
alter table fkpart1.fk_part add foreign key (a) references fkpart1.pkey;
insert into fkpart1.fk_part values (1); -- should fail
insert into fkpart1.pkey values (1);
insert into fkpart1.fk_part values (1);
delete from fkpart1.pkey where a = 1; -- should fail
alter table fkpart1.fk_part detach partition fkpart1.fk_part_1;
create table fkpart1.fk_part_1_2 partition of fkpart1.fk_part_1 for values in (2);
insert into fkpart1.fk_part_1 values (2); -- should fail
delete from fkpart1.pkey where a = 1;
-- verify that attaching and detaching partitions manipulates the inheritance
-- properties of their FK constraints correctly
create schema fkpart2
create table pkey (a int primary key)
create table fk_part (a int, constraint fkey foreign key (a) references fkpart2.pkey) partition by list (a)
create table fk_part_1 partition of fkpart2.fk_part for values in (1) partition by list (a)
create table fk_part_1_1 (a int, constraint my_fkey foreign key (a) references fkpart2.pkey);
alter table fkpart2.fk_part_1 attach partition fkpart2.fk_part_1_1 for values in (1);
alter table fkpart2.fk_part_1 drop constraint fkey; -- should fail
alter table fkpart2.fk_part_1_1 drop constraint my_fkey; -- should fail
alter table fkpart2.fk_part detach partition fkpart2.fk_part_1;
alter table fkpart2.fk_part_1 drop constraint fkey; -- ok
alter table fkpart2.fk_part_1_1 drop constraint my_fkey; -- doesn't exist
-- verify constraint deferrability
create schema fkpart3
create table pkey (a int primary key)
create table fk_part (a int, constraint fkey foreign key (a) references fkpart3.pkey deferrable initially immediate) partition by list (a)
create table fk_part_1 partition of fkpart3.fk_part for values in (1) partition by list (a)
create table fk_part_1_1 partition of fkpart3.fk_part_1 for values in (1)
create table fk_part_2 partition of fkpart3.fk_part for values in (2);
begin;
set constraints fkpart3.fkey deferred;
insert into fkpart3.fk_part values (1);
insert into fkpart3.pkey values (1);
commit;
begin;
set constraints fkpart3.fkey deferred;
delete from fkpart3.pkey;
delete from fkpart3.fk_part;
commit;
drop schema fkpart0, fkpart1, fkpart2, fkpart3 cascade;
-- Test a partitioned table as referenced table.
-- Verify basic functionality with a regular partition creation and a partition
-- with a different column layout, as well as partitions added (created and
-- attached) after creating the foreign key.
CREATE SCHEMA fkpart3;
SET search_path TO fkpart3;
CREATE TABLE pk (a int PRIMARY KEY) PARTITION BY RANGE (a);
CREATE TABLE pk1 PARTITION OF pk FOR VALUES FROM (0) TO (1000);
CREATE TABLE pk2 (b int, a int);
ALTER TABLE pk2 DROP COLUMN b;
ALTER TABLE pk2 ALTER a SET NOT NULL;
ALTER TABLE pk ATTACH PARTITION pk2 FOR VALUES FROM (1000) TO (2000);
CREATE TABLE fk (a int) PARTITION BY RANGE (a);
CREATE TABLE fk1 PARTITION OF fk FOR VALUES FROM (0) TO (750);
ALTER TABLE fk ADD FOREIGN KEY (a) REFERENCES pk;
CREATE TABLE fk2 (b int, a int) ;
ALTER TABLE fk2 DROP COLUMN b;
ALTER TABLE fk ATTACH PARTITION fk2 FOR VALUES FROM (750) TO (3500);
CREATE TABLE pk3 PARTITION OF pk FOR VALUES FROM (2000) TO (3000);
CREATE TABLE pk4 (LIKE pk);
ALTER TABLE pk ATTACH PARTITION pk4 FOR VALUES FROM (3000) TO (4000);
CREATE TABLE pk5 (c int, b int, a int NOT NULL) PARTITION BY RANGE (a);
ALTER TABLE pk5 DROP COLUMN b, DROP COLUMN c;
CREATE TABLE pk51 PARTITION OF pk5 FOR VALUES FROM (4000) TO (4500);
CREATE TABLE pk52 PARTITION OF pk5 FOR VALUES FROM (4500) TO (5000);
ALTER TABLE pk ATTACH PARTITION pk5 FOR VALUES FROM (4000) TO (5000);
CREATE TABLE fk3 PARTITION OF fk FOR VALUES FROM (3500) TO (5000);
-- these should fail: referenced value not present
INSERT into fk VALUES (1);
INSERT into fk VALUES (1000);
INSERT into fk VALUES (2000);
INSERT into fk VALUES (3000);
INSERT into fk VALUES (4000);
INSERT into fk VALUES (4500);
-- insert into the referenced table, now they should work
INSERT into pk VALUES (1), (1000), (2000), (3000), (4000), (4500);
INSERT into fk VALUES (1), (1000), (2000), (3000), (4000), (4500);
-- should fail: referencing value present
DELETE FROM pk WHERE a = 1;
DELETE FROM pk WHERE a = 1000;
DELETE FROM pk WHERE a = 2000;
DELETE FROM pk WHERE a = 3000;
DELETE FROM pk WHERE a = 4000;
DELETE FROM pk WHERE a = 4500;
UPDATE pk SET a = 2 WHERE a = 1;
UPDATE pk SET a = 1002 WHERE a = 1000;
UPDATE pk SET a = 2002 WHERE a = 2000;
UPDATE pk SET a = 3002 WHERE a = 3000;
UPDATE pk SET a = 4002 WHERE a = 4000;
UPDATE pk SET a = 4502 WHERE a = 4500;
-- now they should work
DELETE FROM fk;
UPDATE pk SET a = 2 WHERE a = 1;
DELETE FROM pk WHERE a = 2;
UPDATE pk SET a = 1002 WHERE a = 1000;
DELETE FROM pk WHERE a = 1002;
UPDATE pk SET a = 2002 WHERE a = 2000;
DELETE FROM pk WHERE a = 2002;
UPDATE pk SET a = 3002 WHERE a = 3000;
DELETE FROM pk WHERE a = 3002;
UPDATE pk SET a = 4002 WHERE a = 4000;
DELETE FROM pk WHERE a = 4002;
UPDATE pk SET a = 4502 WHERE a = 4500;
DELETE FROM pk WHERE a = 4502;
-- Also, detaching a partition that has the FK itself should work
-- https://postgr.es/m/CAAJ_b97GuPh6wQPbxQS-Zpy16Oh+0aMv-w64QcGrLhCOZZ6p+g@mail.gmail.com
CREATE TABLE ffk (a int, b int REFERENCES pk) PARTITION BY list (a);
CREATE TABLE ffk1 PARTITION OF ffk FOR VALUES IN (1);
ALTER TABLE ffk1 ADD FOREIGN KEY (a) REFERENCES pk;
ALTER TABLE ffk DETACH PARTITION ffk1;
DROP TABLE ffk, ffk1;
CREATE SCHEMA fkpart4;
SET search_path TO fkpart4;
-- dropping/detaching PARTITIONs is prevented if that would break
-- a foreign key's existing data
CREATE TABLE droppk (a int PRIMARY KEY) PARTITION BY RANGE (a);
CREATE TABLE droppk1 PARTITION OF droppk FOR VALUES FROM (0) TO (1000);
CREATE TABLE droppk_d PARTITION OF droppk DEFAULT;
CREATE TABLE droppk2 PARTITION OF droppk FOR VALUES FROM (1000) TO (2000)
PARTITION BY RANGE (a);
CREATE TABLE droppk21 PARTITION OF droppk2 FOR VALUES FROM (1000) TO (1400);
CREATE TABLE droppk2_d PARTITION OF droppk2 DEFAULT;
INSERT into droppk VALUES (1), (1000), (1500), (2000);
CREATE TABLE dropfk (a int REFERENCES droppk);
INSERT into dropfk VALUES (1), (1000), (1500), (2000);
-- these should all fail
ALTER TABLE droppk DETACH PARTITION droppk_d;
ALTER TABLE droppk2 DETACH PARTITION droppk2_d;
ALTER TABLE droppk DETACH PARTITION droppk1;
ALTER TABLE droppk DETACH PARTITION droppk2;
ALTER TABLE droppk2 DETACH PARTITION droppk21;
-- dropping partitions is disallowed
DROP TABLE droppk_d;
DROP TABLE droppk2_d;
DROP TABLE droppk1;
DROP TABLE droppk2;
DROP TABLE droppk21;
DELETE FROM dropfk;
-- dropping partitions is disallowed, even when no referencing values
DROP TABLE droppk_d;
DROP TABLE droppk2_d;
DROP TABLE droppk1;
-- but DETACH is allowed, and DROP afterwards works
ALTER TABLE droppk2 DETACH PARTITION droppk21;
DROP TABLE droppk2;
-- Verify that initial constraint creation and cloning behave correctly
CREATE SCHEMA fkpart5;
SET search_path TO fkpart5;
CREATE TABLE pk (a int PRIMARY KEY) PARTITION BY LIST (a);
CREATE TABLE pk1 PARTITION OF pk FOR VALUES IN (1) PARTITION BY LIST (a);
CREATE TABLE pk11 PARTITION OF pk1 FOR VALUES IN (1);
CREATE TABLE fk (a int) PARTITION BY LIST (a);
CREATE TABLE fk1 PARTITION OF fk FOR VALUES IN (1) PARTITION BY LIST (a);
CREATE TABLE fk11 PARTITION OF fk1 FOR VALUES IN (1);
ALTER TABLE fk ADD FOREIGN KEY (a) REFERENCES pk;
CREATE TABLE pk2 PARTITION OF pk FOR VALUES IN (2);
CREATE TABLE pk3 (a int NOT NULL) PARTITION BY LIST (a);
CREATE TABLE pk31 PARTITION OF pk3 FOR VALUES IN (31);
CREATE TABLE pk32 (b int, a int NOT NULL);
ALTER TABLE pk32 DROP COLUMN b;
ALTER TABLE pk3 ATTACH PARTITION pk32 FOR VALUES IN (32);
ALTER TABLE pk ATTACH PARTITION pk3 FOR VALUES IN (31, 32);
CREATE TABLE fk2 PARTITION OF fk FOR VALUES IN (2);
CREATE TABLE fk3 (b int, a int);
ALTER TABLE fk3 DROP COLUMN b;
ALTER TABLE fk ATTACH PARTITION fk3 FOR VALUES IN (3);
SELECT pg_describe_object('pg_constraint'::regclass, oid, 0), confrelid::regclass,
CASE WHEN conparentid <> 0 THEN pg_describe_object('pg_constraint'::regclass, conparentid, 0) ELSE 'TOP' END
FROM pg_catalog.pg_constraint
WHERE conrelid IN (SELECT relid FROM pg_partition_tree('fk'))
ORDER BY conrelid::regclass::text, conname;
CREATE TABLE fk4 (LIKE fk);
INSERT INTO fk4 VALUES (50);
ALTER TABLE fk ATTACH PARTITION fk4 FOR VALUES IN (50);
-- Verify constraint deferrability
CREATE SCHEMA fkpart9;
SET search_path TO fkpart9;
CREATE TABLE pk (a int PRIMARY KEY) PARTITION BY LIST (a);
CREATE TABLE pk1 PARTITION OF pk FOR VALUES IN (1, 2) PARTITION BY LIST (a);
CREATE TABLE pk11 PARTITION OF pk1 FOR VALUES IN (1);
CREATE TABLE pk3 PARTITION OF pk FOR VALUES IN (3);
CREATE TABLE fk (a int REFERENCES pk DEFERRABLE INITIALLY IMMEDIATE);
INSERT INTO fk VALUES (1); -- should fail
BEGIN;
SET CONSTRAINTS fk_a_fkey DEFERRED;
INSERT INTO fk VALUES (1);
COMMIT; -- should fail
BEGIN;
SET CONSTRAINTS fk_a_fkey DEFERRED;
INSERT INTO fk VALUES (1);
INSERT INTO pk VALUES (1);
COMMIT; -- OK
BEGIN;
SET CONSTRAINTS fk_a_fkey DEFERRED;
DELETE FROM pk WHERE a = 1;
DELETE FROM fk WHERE a = 1;
COMMIT; -- OK
-- Verify constraint deferrability when changed by ALTER
-- Partitioned table at referencing end
CREATE TABLE pt(f1 int, f2 int, f3 int, PRIMARY KEY(f1,f2));
CREATE TABLE ref(f1 int, f2 int, f3 int)
PARTITION BY list(f1);
CREATE TABLE ref1 PARTITION OF ref FOR VALUES IN (1);
CREATE TABLE ref2 PARTITION OF ref FOR VALUES in (2);
ALTER TABLE ref ADD FOREIGN KEY(f1,f2) REFERENCES pt;
ALTER TABLE ref ALTER CONSTRAINT ref_f1_f2_fkey
DEFERRABLE INITIALLY DEFERRED;
INSERT INTO pt VALUES(1,2,3);
INSERT INTO ref VALUES(1,2,3);
BEGIN;
DELETE FROM pt;
DELETE FROM ref;
ABORT;
DROP TABLE pt, ref;
-- Multi-level partitioning at referencing end
CREATE TABLE pt(f1 int, f2 int, f3 int, PRIMARY KEY(f1,f2));
CREATE TABLE ref(f1 int, f2 int, f3 int)
PARTITION BY list(f1);
CREATE TABLE ref1_2 PARTITION OF ref FOR VALUES IN (1, 2) PARTITION BY list (f2);
CREATE TABLE ref1 PARTITION OF ref1_2 FOR VALUES IN (1);
CREATE TABLE ref2 PARTITION OF ref1_2 FOR VALUES IN (2) PARTITION BY list (f2);
CREATE TABLE ref22 PARTITION OF ref2 FOR VALUES IN (2);
ALTER TABLE ref ADD FOREIGN KEY(f1,f2) REFERENCES pt;
INSERT INTO pt VALUES(1,2,3);
INSERT INTO ref VALUES(1,2,3);
ALTER TABLE ref22 ALTER CONSTRAINT ref_f1_f2_fkey
DEFERRABLE INITIALLY IMMEDIATE; -- fails
ALTER TABLE ref ALTER CONSTRAINT ref_f1_f2_fkey
DEFERRABLE INITIALLY DEFERRED;
BEGIN;
DELETE FROM pt;
DELETE FROM ref;
ABORT;
DROP TABLE pt, ref;
-- Partitioned table at referenced end
CREATE TABLE pt(f1 int, f2 int, f3 int, PRIMARY KEY(f1,f2))
PARTITION BY LIST(f1);
CREATE TABLE pt1 PARTITION OF pt FOR VALUES IN (1);
CREATE TABLE pt2 PARTITION OF pt FOR VALUES IN (2);
CREATE TABLE ref(f1 int, f2 int, f3 int);
ALTER TABLE ref ADD FOREIGN KEY(f1,f2) REFERENCES pt;
ALTER TABLE ref ALTER CONSTRAINT ref_f1_f2_fkey
DEFERRABLE INITIALLY DEFERRED;
INSERT INTO pt VALUES(1,2,3);
INSERT INTO ref VALUES(1,2,3);
BEGIN;
DELETE FROM pt;
DELETE FROM ref;
ABORT;
DROP TABLE pt, ref;
-- Multi-level partitioning at referenced end
CREATE TABLE pt(f1 int, f2 int, f3 int, PRIMARY KEY(f1,f2))
PARTITION BY LIST(f1);
CREATE TABLE pt1_2 PARTITION OF pt FOR VALUES IN (1, 2) PARTITION BY LIST (f1);
CREATE TABLE pt1 PARTITION OF pt1_2 FOR VALUES IN (1);
CREATE TABLE pt2 PARTITION OF pt1_2 FOR VALUES IN (2);
CREATE TABLE ref(f1 int, f2 int, f3 int);
ALTER TABLE ref ADD FOREIGN KEY(f1,f2) REFERENCES pt;
ALTER TABLE ref ALTER CONSTRAINT ref_f1_f2_fkey_1
DEFERRABLE INITIALLY DEFERRED; -- fails
ALTER TABLE ref ALTER CONSTRAINT ref_f1_f2_fkey
DEFERRABLE INITIALLY DEFERRED;
INSERT INTO pt VALUES(1,2,3);
INSERT INTO ref VALUES(1,2,3);
BEGIN;
DELETE FROM pt;
DELETE FROM ref;
ABORT;
DROP TABLE pt, ref;
DROP SCHEMA fkpart9 CASCADE;
-- Verify ON UPDATE/DELETE behavior
CREATE SCHEMA fkpart6;
SET search_path TO fkpart6;
CREATE TABLE pk (a int PRIMARY KEY) PARTITION BY RANGE (a);
CREATE TABLE pk1 PARTITION OF pk FOR VALUES FROM (1) TO (100) PARTITION BY RANGE (a);
CREATE TABLE pk11 PARTITION OF pk1 FOR VALUES FROM (1) TO (50);
CREATE TABLE pk12 PARTITION OF pk1 FOR VALUES FROM (50) TO (100);
CREATE TABLE fk (a int) PARTITION BY RANGE (a);
CREATE TABLE fk1 PARTITION OF fk FOR VALUES FROM (1) TO (100) PARTITION BY RANGE (a);
CREATE TABLE fk11 PARTITION OF fk1 FOR VALUES FROM (1) TO (10);
CREATE TABLE fk12 PARTITION OF fk1 FOR VALUES FROM (10) TO (100);
ALTER TABLE fk ADD FOREIGN KEY (a) REFERENCES pk ON UPDATE CASCADE ON DELETE CASCADE;
CREATE TABLE fk_d PARTITION OF fk DEFAULT;
INSERT INTO pk VALUES (1);
INSERT INTO fk VALUES (1);
UPDATE pk SET a = 20;
SELECT tableoid::regclass, * FROM fk;
DELETE FROM pk WHERE a = 20;
SELECT tableoid::regclass, * FROM fk;
DROP TABLE fk;
TRUNCATE TABLE pk;
INSERT INTO pk VALUES (20), (50);
CREATE TABLE fk (a int) PARTITION BY RANGE (a);
CREATE TABLE fk1 PARTITION OF fk FOR VALUES FROM (1) TO (100) PARTITION BY RANGE (a);
CREATE TABLE fk11 PARTITION OF fk1 FOR VALUES FROM (1) TO (10);
CREATE TABLE fk12 PARTITION OF fk1 FOR VALUES FROM (10) TO (100);
ALTER TABLE fk ADD FOREIGN KEY (a) REFERENCES pk ON UPDATE SET NULL ON DELETE SET NULL;
CREATE TABLE fk_d PARTITION OF fk DEFAULT;
INSERT INTO fk VALUES (20), (50);
UPDATE pk SET a = 21 WHERE a = 20;
DELETE FROM pk WHERE a = 50;
SELECT tableoid::regclass, * FROM fk;
DROP TABLE fk;
TRUNCATE TABLE pk;
INSERT INTO pk VALUES (20), (30), (50);
CREATE TABLE fk (id int, a int DEFAULT 50) PARTITION BY RANGE (a);
CREATE TABLE fk1 PARTITION OF fk FOR VALUES FROM (1) TO (100) PARTITION BY RANGE (a);
CREATE TABLE fk11 PARTITION OF fk1 FOR VALUES FROM (1) TO (10);
CREATE TABLE fk12 PARTITION OF fk1 FOR VALUES FROM (10) TO (100);
ALTER TABLE fk ADD FOREIGN KEY (a) REFERENCES pk ON UPDATE SET DEFAULT ON DELETE SET DEFAULT;
CREATE TABLE fk_d PARTITION OF fk DEFAULT;
INSERT INTO fk VALUES (1, 20), (2, 30);
DELETE FROM pk WHERE a = 20 RETURNING *;
UPDATE pk SET a = 90 WHERE a = 30 RETURNING *;
SELECT tableoid::regclass, * FROM fk;
DROP TABLE fk;
TRUNCATE TABLE pk;
INSERT INTO pk VALUES (20), (30);
CREATE TABLE fk (a int DEFAULT 50) PARTITION BY RANGE (a);
CREATE TABLE fk1 PARTITION OF fk FOR VALUES FROM (1) TO (100) PARTITION BY RANGE (a);
CREATE TABLE fk11 PARTITION OF fk1 FOR VALUES FROM (1) TO (10);
CREATE TABLE fk12 PARTITION OF fk1 FOR VALUES FROM (10) TO (100);
ALTER TABLE fk ADD FOREIGN KEY (a) REFERENCES pk ON UPDATE RESTRICT ON DELETE RESTRICT;
CREATE TABLE fk_d PARTITION OF fk DEFAULT;
INSERT INTO fk VALUES (20), (30);
DELETE FROM pk WHERE a = 20;
UPDATE pk SET a = 90 WHERE a = 30;
SELECT tableoid::regclass, * FROM fk;
DROP TABLE fk;
-- test for reported bug: relispartition not set
-- https://postgr.es/m/CA+HiwqHMsRtRYRWYTWavKJ8x14AFsv7bmAV46mYwnfD3vy8goQ@mail.gmail.com
CREATE SCHEMA fkpart7
CREATE TABLE pkpart (a int) PARTITION BY LIST (a)
CREATE TABLE pkpart1 PARTITION OF pkpart FOR VALUES IN (1);
ALTER TABLE fkpart7.pkpart1 ADD PRIMARY KEY (a);
ALTER TABLE fkpart7.pkpart ADD PRIMARY KEY (a);
CREATE TABLE fkpart7.fk (a int REFERENCES fkpart7.pkpart);
DROP SCHEMA fkpart7 CASCADE;
-- ensure we check partitions are "not used" when dropping constraints
CREATE SCHEMA fkpart8
CREATE TABLE tbl1(f1 int PRIMARY KEY)
CREATE TABLE tbl2(f1 int REFERENCES tbl1 DEFERRABLE INITIALLY DEFERRED) PARTITION BY RANGE(f1)
CREATE TABLE tbl2_p1 PARTITION OF tbl2 FOR VALUES FROM (minvalue) TO (maxvalue);
INSERT INTO fkpart8.tbl1 VALUES(1);
BEGIN;
INSERT INTO fkpart8.tbl2 VALUES(1);
ALTER TABLE fkpart8.tbl2 DROP CONSTRAINT tbl2_f1_fkey;
COMMIT;
DROP SCHEMA fkpart8 CASCADE;
-- ensure FK referencing a multi-level partitioned table are
-- enforce reference to sub-children.
CREATE SCHEMA fkpart9
CREATE TABLE pk (a INT PRIMARY KEY) PARTITION BY RANGE (a)
CREATE TABLE fk (
fk_a INT REFERENCES pk(a) ON DELETE CASCADE
)
CREATE TABLE pk1 PARTITION OF pk FOR VALUES FROM (30) TO (50) PARTITION BY RANGE (a)
CREATE TABLE pk11 PARTITION OF pk1 FOR VALUES FROM (30) TO (40);
INSERT INTO fkpart9.pk VALUES (35);
INSERT INTO fkpart9.fk VALUES (35);
DELETE FROM fkpart9.pk WHERE a=35;
SELECT * FROM fkpart9.pk;
SELECT * FROM fkpart9.fk;
DROP SCHEMA fkpart9 CASCADE;
-- test that ri_Check_Pk_Match() scans the correct partition for a deferred
-- ON DELETE/UPDATE NO ACTION constraint
CREATE SCHEMA fkpart10
CREATE TABLE tbl1(f1 int PRIMARY KEY) PARTITION BY RANGE(f1)
CREATE TABLE tbl1_p1 PARTITION OF tbl1 FOR VALUES FROM (minvalue) TO (1)
CREATE TABLE tbl1_p2 PARTITION OF tbl1 FOR VALUES FROM (1) TO (maxvalue)
CREATE TABLE tbl2(f1 int REFERENCES tbl1 DEFERRABLE INITIALLY DEFERRED)
CREATE TABLE tbl3(f1 int PRIMARY KEY) PARTITION BY RANGE(f1)
CREATE TABLE tbl3_p1 PARTITION OF tbl3 FOR VALUES FROM (minvalue) TO (1)
CREATE TABLE tbl3_p2 PARTITION OF tbl3 FOR VALUES FROM (1) TO (maxvalue)
CREATE TABLE tbl4(f1 int REFERENCES tbl3 DEFERRABLE INITIALLY DEFERRED);
INSERT INTO fkpart10.tbl1 VALUES (0), (1);
INSERT INTO fkpart10.tbl2 VALUES (0), (1);
INSERT INTO fkpart10.tbl3 VALUES (-2), (-1), (0);
INSERT INTO fkpart10.tbl4 VALUES (-2), (-1);
BEGIN;
DELETE FROM fkpart10.tbl1 WHERE f1 = 0;
UPDATE fkpart10.tbl1 SET f1 = 2 WHERE f1 = 1;
INSERT INTO fkpart10.tbl1 VALUES (0), (1);
COMMIT;
-- test that cross-partition updates correctly enforces the foreign key
-- restriction (specifically testing INITIALLY DEFERRED)
BEGIN;
UPDATE fkpart10.tbl1 SET f1 = 3 WHERE f1 = 0;
UPDATE fkpart10.tbl3 SET f1 = f1 * -1;
INSERT INTO fkpart10.tbl1 VALUES (4);
COMMIT;
BEGIN;
UPDATE fkpart10.tbl3 SET f1 = f1 * -1;
UPDATE fkpart10.tbl3 SET f1 = f1 + 3;
UPDATE fkpart10.tbl1 SET f1 = 3 WHERE f1 = 0;
INSERT INTO fkpart10.tbl1 VALUES (0);
COMMIT;
BEGIN;
UPDATE fkpart10.tbl3 SET f1 = f1 * -1;
UPDATE fkpart10.tbl1 SET f1 = 3 WHERE f1 = 0;
INSERT INTO fkpart10.tbl1 VALUES (0);
INSERT INTO fkpart10.tbl3 VALUES (-2), (-1);
COMMIT;
-- test where the updated table now has both an IMMEDIATE and a DEFERRED
-- constraint pointing into it
CREATE TABLE fkpart10.tbl5(f1 int REFERENCES fkpart10.tbl3);
INSERT INTO fkpart10.tbl5 VALUES (-2), (-1);
BEGIN;
UPDATE fkpart10.tbl3 SET f1 = f1 * -3;
COMMIT;
-- Now test where the row referenced from the table with an IMMEDIATE
-- constraint stays in place, while those referenced from the table with a
-- DEFERRED constraint don't.
DELETE FROM fkpart10.tbl5;
INSERT INTO fkpart10.tbl5 VALUES (0);
BEGIN;
UPDATE fkpart10.tbl3 SET f1 = f1 * -3;
COMMIT;
DROP SCHEMA fkpart10 CASCADE;
-- verify foreign keys are enforced during cross-partition updates,
-- especially on the PK side
CREATE SCHEMA fkpart11
CREATE TABLE pk (a INT PRIMARY KEY, b text) PARTITION BY LIST (a)
CREATE TABLE fk (
a INT,
CONSTRAINT fkey FOREIGN KEY (a) REFERENCES pk(a) ON UPDATE CASCADE ON DELETE CASCADE
)
CREATE TABLE fk_parted (
a INT PRIMARY KEY,
CONSTRAINT fkey FOREIGN KEY (a) REFERENCES pk(a) ON UPDATE CASCADE ON DELETE CASCADE
) PARTITION BY LIST (a)
CREATE TABLE fk_another (
a INT,
CONSTRAINT fkey FOREIGN KEY (a) REFERENCES fk_parted (a) ON UPDATE CASCADE ON DELETE CASCADE
)
CREATE TABLE pk1 PARTITION OF pk FOR VALUES IN (1, 2) PARTITION BY LIST (a)
CREATE TABLE pk2 PARTITION OF pk FOR VALUES IN (3)
CREATE TABLE pk3 PARTITION OF pk FOR VALUES IN (4)
CREATE TABLE fk1 PARTITION OF fk_parted FOR VALUES IN (1, 2)
CREATE TABLE fk2 PARTITION OF fk_parted FOR VALUES IN (3)
CREATE TABLE fk3 PARTITION OF fk_parted FOR VALUES IN (4);
CREATE TABLE fkpart11.pk11 (b text, a int NOT NULL);
ALTER TABLE fkpart11.pk1 ATTACH PARTITION fkpart11.pk11 FOR VALUES IN (1);
CREATE TABLE fkpart11.pk12 (b text, c int, a int NOT NULL);
ALTER TABLE fkpart11.pk12 DROP c;
ALTER TABLE fkpart11.pk1 ATTACH PARTITION fkpart11.pk12 FOR VALUES IN (2);
INSERT INTO fkpart11.pk VALUES (1, 'xxx'), (3, 'yyy');
INSERT INTO fkpart11.fk VALUES (1), (3);
INSERT INTO fkpart11.fk_parted VALUES (1), (3);
INSERT INTO fkpart11.fk_another VALUES (1), (3);
-- moves 2 rows from one leaf partition to another, with both updates being
-- cascaded to fk and fk_parted. Updates of fk_parted, of which one is
-- cross-partition (3 -> 4), are further cascaded to fk_another.
UPDATE fkpart11.pk SET a = a + 1 RETURNING tableoid::pg_catalog.regclass, *;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.fk;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.fk_parted;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.fk_another;
-- let's try with the foreign key pointing at tables in the partition tree
-- that are not the same as the query's target table
-- 1. foreign key pointing into a non-root ancestor
--
-- A cross-partition update on the root table will fail, because we currently
-- can't enforce the foreign keys pointing into a non-leaf partition
ALTER TABLE fkpart11.fk DROP CONSTRAINT fkey;
DELETE FROM fkpart11.fk WHERE a = 4;
ALTER TABLE fkpart11.fk ADD CONSTRAINT fkey FOREIGN KEY (a) REFERENCES fkpart11.pk1 (a) ON UPDATE CASCADE ON DELETE CASCADE;
UPDATE fkpart11.pk SET a = a - 1;
-- it's okay though if the non-leaf partition is updated directly
UPDATE fkpart11.pk1 SET a = a - 1;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.pk;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.fk;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.fk_parted;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.fk_another;
-- 2. foreign key pointing into a single leaf partition
--
-- A cross-partition update that deletes from the pointed-to leaf partition
-- is allowed to succeed
ALTER TABLE fkpart11.fk DROP CONSTRAINT fkey;
ALTER TABLE fkpart11.fk ADD CONSTRAINT fkey FOREIGN KEY (a) REFERENCES fkpart11.pk11 (a) ON UPDATE CASCADE ON DELETE CASCADE;
-- will delete (1) from p11 which is cascaded to fk
UPDATE fkpart11.pk SET a = a + 1 WHERE a = 1;
SELECT tableoid::pg_catalog.regclass, * FROM fkpart11.fk;
DROP TABLE fkpart11.fk;
-- check that regular and deferrable AR triggers on the PK tables
-- still work as expected
CREATE FUNCTION fkpart11.print_row () RETURNS TRIGGER LANGUAGE plpgsql AS $$
BEGIN
RAISE NOTICE 'TABLE: %, OP: %, OLD: %, NEW: %', TG_RELNAME, TG_OP, OLD, NEW;
RETURN NULL;
END;
$$;
CREATE TRIGGER trig_upd_pk AFTER UPDATE ON fkpart11.pk FOR EACH ROW EXECUTE FUNCTION fkpart11.print_row();
CREATE TRIGGER trig_del_pk AFTER DELETE ON fkpart11.pk FOR EACH ROW EXECUTE FUNCTION fkpart11.print_row();
CREATE TRIGGER trig_ins_pk AFTER INSERT ON fkpart11.pk FOR EACH ROW EXECUTE FUNCTION fkpart11.print_row();
CREATE CONSTRAINT TRIGGER trig_upd_fk_parted AFTER UPDATE ON fkpart11.fk_parted INITIALLY DEFERRED FOR EACH ROW EXECUTE FUNCTION fkpart11.print_row();
CREATE CONSTRAINT TRIGGER trig_del_fk_parted AFTER DELETE ON fkpart11.fk_parted INITIALLY DEFERRED FOR EACH ROW EXECUTE FUNCTION fkpart11.print_row();
CREATE CONSTRAINT TRIGGER trig_ins_fk_parted AFTER INSERT ON fkpart11.fk_parted INITIALLY DEFERRED FOR EACH ROW EXECUTE FUNCTION fkpart11.print_row();
UPDATE fkpart11.pk SET a = 3 WHERE a = 4;
UPDATE fkpart11.pk SET a = 1 WHERE a = 2;
DROP SCHEMA fkpart11 CASCADE;
-- When a table is attached as partition to a partitioned table that has
-- a foreign key to another partitioned table, it acquires a clone of the
-- FK. Upon detach, this clone is not removed, but instead becomes an
-- independent FK. If it then attaches to the partitioned table again,
-- the FK from the parent "takes over" ownership of the independent FK rather
-- than creating a separate one.
CREATE SCHEMA fkpart12
CREATE TABLE fk_p ( id int, jd int, PRIMARY KEY(id, jd)) PARTITION BY list (id)
CREATE TABLE fk_p_1 PARTITION OF fk_p FOR VALUES IN (1) PARTITION BY list (jd)
CREATE TABLE fk_p_1_1 PARTITION OF fk_p_1 FOR VALUES IN (1)
CREATE TABLE fk_p_1_2 (x int, y int, jd int NOT NULL, id int NOT NULL)
CREATE TABLE fk_p_2 PARTITION OF fk_p FOR VALUES IN (2) PARTITION BY list (jd)
CREATE TABLE fk_p_2_1 PARTITION OF fk_p_2 FOR VALUES IN (1)
CREATE TABLE fk_p_2_2 PARTITION OF fk_p_2 FOR VALUES IN (2)
CREATE TABLE fk_r_1 ( p_jd int NOT NULL, x int, id int PRIMARY KEY, p_id int NOT NULL)
CREATE TABLE fk_r_2 ( id int PRIMARY KEY, p_id int NOT NULL, p_jd int NOT NULL) PARTITION BY list (id)
CREATE TABLE fk_r_2_1 PARTITION OF fk_r_2 FOR VALUES IN (2, 1)
CREATE TABLE fk_r ( id int PRIMARY KEY, p_id int NOT NULL, p_jd int NOT NULL,
FOREIGN KEY (p_id, p_jd) REFERENCES fk_p (id, jd)
) PARTITION BY list (id);
SET search_path TO fkpart12;
ALTER TABLE fk_p_1_2 DROP COLUMN x, DROP COLUMN y;
ALTER TABLE fk_p_1 ATTACH PARTITION fk_p_1_2 FOR VALUES IN (2);
ALTER TABLE fk_r_1 DROP COLUMN x;
INSERT INTO fk_p VALUES (1, 1);
ALTER TABLE fk_r ATTACH PARTITION fk_r_1 FOR VALUES IN (1);
ALTER TABLE fk_r ATTACH PARTITION fk_r_2 FOR VALUES IN (2);
\d fk_r_2
INSERT INTO fk_r VALUES (1, 1, 1);
INSERT INTO fk_r VALUES (2, 2, 1);
ALTER TABLE fk_r DETACH PARTITION fk_r_1;
ALTER TABLE fk_r DETACH PARTITION fk_r_2;
\d fk_r_2
INSERT INTO fk_r_1 (id, p_id, p_jd) VALUES (2, 1, 2); -- should fail
DELETE FROM fk_p; -- should fail
ALTER TABLE fk_r ATTACH PARTITION fk_r_1 FOR VALUES IN (1);
ALTER TABLE fk_r ATTACH PARTITION fk_r_2 FOR VALUES IN (2);
\d fk_r_2
DELETE FROM fk_p; -- should fail
-- these should all fail
ALTER TABLE fk_r_1 DROP CONSTRAINT fk_r_p_id_p_jd_fkey;
ALTER TABLE fk_r DROP CONSTRAINT fk_r_p_id_p_jd_fkey_1;
ALTER TABLE fk_r_2 DROP CONSTRAINT fk_r_p_id_p_jd_fkey;
SET client_min_messages TO warning;
DROP SCHEMA fkpart12 CASCADE;
RESET client_min_messages;
RESET search_path;
-- Exercise the column mapping code with foreign keys. In this test we'll
-- create a partitioned table which has a partition with a dropped column and
-- check to ensure that an UPDATE cascades the changes correctly to the
-- partitioned table.
CREATE SCHEMA fkpart13;
SET search_path TO fkpart13;
CREATE TABLE fkpart13_t1 (a int PRIMARY KEY);
CREATE TABLE fkpart13_t2 (
part_id int PRIMARY KEY,
column_to_drop int,
FOREIGN KEY (part_id) REFERENCES fkpart13_t1 ON UPDATE CASCADE ON DELETE CASCADE
) PARTITION BY LIST (part_id);
CREATE TABLE fkpart13_t2_p1 PARTITION OF fkpart13_t2 FOR VALUES IN (1);
-- drop the column
ALTER TABLE fkpart13_t2 DROP COLUMN column_to_drop;
-- create a new partition without the dropped column
CREATE TABLE fkpart13_t2_p2 PARTITION OF fkpart13_t2 FOR VALUES IN (2);
CREATE TABLE fkpart13_t3 (
a int NOT NULL,
FOREIGN KEY (a)
REFERENCES fkpart13_t2
ON UPDATE CASCADE ON DELETE CASCADE
);
INSERT INTO fkpart13_t1 (a) VALUES (1);
INSERT INTO fkpart13_t2 (part_id) VALUES (1);
INSERT INTO fkpart13_t3 (a) VALUES (1);
-- Test that a cascading update works correctly with the dropped column
UPDATE fkpart13_t1 SET a = 2 WHERE a = 1;
SELECT tableoid::regclass,* FROM fkpart13_t2;
SELECT tableoid::regclass,* FROM fkpart13_t3;
-- Exercise code in ExecGetTriggerResultRel() as there's been previous issues
-- with ResultRelInfos being returned with the incorrect ri_RootResultRelInfo
WITH cte AS (
UPDATE fkpart13_t2_p1 SET part_id = part_id
) UPDATE fkpart13_t1 SET a = 2 WHERE a = 1;
DROP SCHEMA fkpart13 CASCADE;
RESET search_path;
-- Tests foreign key check fast-path no-cache path.
CREATE TABLE fp_pk_alter (a int PRIMARY KEY);
INSERT INTO fp_pk_alter SELECT generate_series(1, 100);
CREATE TABLE fp_fk_alter (a int);
INSERT INTO fp_fk_alter SELECT generate_series(1, 100);
-- Validation path: should succeed
ALTER TABLE fp_fk_alter ADD FOREIGN KEY (a) REFERENCES fp_pk_alter;
INSERT INTO fp_fk_alter VALUES (101); -- should fail (constraint active)
DROP TABLE fp_fk_alter, fp_pk_alter;
-- Separate test: validation catches existing violation
CREATE TABLE fp_pk_alter2 (a int PRIMARY KEY);
INSERT INTO fp_pk_alter2 VALUES (1);
CREATE TABLE fp_fk_alter2 (a int);
INSERT INTO fp_fk_alter2 VALUES (1), (200); -- 200 has no PK match
ALTER TABLE fp_fk_alter2 ADD FOREIGN KEY (a) REFERENCES fp_pk_alter2; -- should fail
DROP TABLE fp_fk_alter2, fp_pk_alter2;
-- Tests that the fast-path handles caching for multiple constraints
CREATE TABLE fp_pk1 (a int PRIMARY KEY);
CREATE TABLE fp_pk2 (b int PRIMARY KEY);
INSERT INTO fp_pk1 VALUES (1);
INSERT INTO fp_pk2 VALUES (1);
CREATE TABLE fp_multi_fk (
a int REFERENCES fp_pk1,
b int REFERENCES fp_pk2
);
INSERT INTO fp_multi_fk VALUES (1, 1); -- two constraints, one batch
INSERT INTO fp_multi_fk VALUES (1, 2); -- second constraint fails
DROP TABLE fp_multi_fk, fp_pk1, fp_pk2;
-- Test that fast-path cache handles deferred constraints and SET CONSTRAINTS IMMEDIATE
CREATE TABLE fp_pk_defer (a int PRIMARY KEY);
CREATE TABLE fp_fk_defer (a int REFERENCES fp_pk_defer DEFERRABLE INITIALLY DEFERRED);
INSERT INTO fp_pk_defer VALUES (1), (2);
BEGIN;
INSERT INTO fp_fk_defer VALUES (1);
INSERT INTO fp_fk_defer VALUES (2);
SET CONSTRAINTS ALL IMMEDIATE; -- fires batch callback here
INSERT INTO fp_fk_defer VALUES (3); -- should fail, also tests that cache was cleaned up
COMMIT;
DROP TABLE fp_pk_defer, fp_fk_defer;
-- Subtransaction abort: cached state must be invalidated on ROLLBACK TO
CREATE TABLE fp_pk_subxact (a int PRIMARY KEY);
CREATE TABLE fp_fk_subxact (a int REFERENCES fp_pk_subxact);
INSERT INTO fp_pk_subxact VALUES (1), (2);
BEGIN;
INSERT INTO fp_fk_subxact VALUES (1);
SAVEPOINT sp1;
INSERT INTO fp_fk_subxact VALUES (2);
ROLLBACK TO sp1;
INSERT INTO fp_fk_subxact VALUES (1);
COMMIT;
SELECT * FROM fp_fk_subxact;
DROP TABLE fp_fk_subxact, fp_pk_subxact;
-- FK check must see PK rows inserted by earlier AFTER triggers
-- firing on the same statement
CREATE TABLE fp_pk_cci (a int PRIMARY KEY);
CREATE TABLE fp_fk_cci (a int REFERENCES fp_pk_cci);
CREATE FUNCTION fp_auto_pk() RETURNS trigger AS $$
BEGIN
RAISE NOTICE 'fp_auto_pk called';
INSERT INTO fp_pk_cci VALUES (NEW.a);
RETURN NEW;
END $$ LANGUAGE plpgsql;
-- Name sorts before the RI trigger, so fires first per row
CREATE TRIGGER "AAA_auto" AFTER INSERT ON fp_fk_cci
FOR EACH ROW EXECUTE FUNCTION fp_auto_pk();
-- Should succeed: AAA_auto provisions the PK row before RI check
INSERT INTO fp_fk_cci VALUES (1), (2), (3);
DROP TABLE fp_fk_cci, fp_pk_cci;
DROP FUNCTION fp_auto_pk;
-- Multi-column FK: exercises batched per-row probing with composite keys
CREATE TABLE fp_pk_multi (a int, b int, PRIMARY KEY (a, b));
INSERT INTO fp_pk_multi SELECT i, i FROM generate_series(1, 100) i;
CREATE TABLE fp_fk_multi (x int, a int, b int,
FOREIGN KEY (a, b) REFERENCES fp_pk_multi);
INSERT INTO fp_fk_multi SELECT i, i, i FROM generate_series(1, 100) i;
INSERT INTO fp_fk_multi VALUES (1, 999, 999);
DROP TABLE fp_fk_multi, fp_pk_multi;
-- Deferred constraint: batch flushed at COMMIT, not at statement end
CREATE TABLE fp_pk_commit (a int PRIMARY KEY);
CREATE TABLE fp_fk_commit (a int REFERENCES fp_pk_commit
DEFERRABLE INITIALLY DEFERRED);
INSERT INTO fp_pk_commit VALUES (1);
BEGIN;
INSERT INTO fp_fk_commit VALUES (1);
INSERT INTO fp_fk_commit VALUES (1);
INSERT INTO fp_fk_commit VALUES (999);
COMMIT;
DROP TABLE fp_fk_commit, fp_pk_commit;
-- Cross-type FK with bulk insert: int8 FK referencing int4 PK,
-- values cast during array construction
CREATE TABLE fp_pk_cross (a int4 PRIMARY KEY);
INSERT INTO fp_pk_cross SELECT generate_series(1, 200);
CREATE TABLE fp_fk_cross (a int8 REFERENCES fp_pk_cross);
INSERT INTO fp_fk_cross SELECT generate_series(1, 200);
INSERT INTO fp_fk_cross VALUES (999);
DROP TABLE fp_fk_cross, fp_pk_cross;
-- Duplicate FK values: when using the batched SAOP path, every
-- row must be recognized as satisfied, not just the first match
CREATE TABLE fp_pk_dup (a int PRIMARY KEY);
INSERT INTO fp_pk_dup VALUES (1);
CREATE TABLE fp_fk_dup (a int REFERENCES fp_pk_dup);
INSERT INTO fp_fk_dup SELECT 1 FROM generate_series(1, 100);
DROP TABLE fp_fk_dup, fp_pk_dup;
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