/* * This test is intended to pass on all platforms supported by Postgres. * We can therefore only assume that the default, C, and POSIX collations * are available --- and since the regression tests are often run in a * C-locale database, these may well all have the same behavior. But * fortunately, the system doesn't know that and will treat them as * incompatible collations. It is therefore at least possible to test * parser behaviors such as collation conflict resolution. This test will, * however, be more revealing when run in a database with non-C locale, * since any departure from C sorting behavior will show as a failure. */ CREATE SCHEMA collate_tests; SET search_path = collate_tests; CREATE TABLE collate_test1 ( a int, b text COLLATE "C" NOT NULL ); \d collate_test1 CREATE TABLE collate_test_fail ( a int COLLATE "C", b text ); CREATE TABLE collate_test_like ( LIKE collate_test1 ); \d collate_test_like CREATE TABLE collate_test2 ( a int, b text COLLATE "POSIX" ); INSERT INTO collate_test1 VALUES (1, 'abc'), (2, 'Abc'), (3, 'bbc'), (4, 'ABD'); INSERT INTO collate_test2 SELECT * FROM collate_test1; SELECT * FROM collate_test1 WHERE b COLLATE "C" >= 'abc'; SELECT * FROM collate_test1 WHERE b >= 'abc' COLLATE "C"; SELECT * FROM collate_test1 WHERE b COLLATE "C" >= 'abc' COLLATE "C"; SELECT * FROM collate_test1 WHERE b COLLATE "C" >= 'bbc' COLLATE "POSIX"; -- fail CREATE DOMAIN testdomain_p AS text COLLATE "POSIX"; CREATE DOMAIN testdomain_i AS int COLLATE "POSIX"; -- fail CREATE TABLE collate_test4 ( a int, b testdomain_p ); INSERT INTO collate_test4 SELECT * FROM collate_test1; SELECT a, b FROM collate_test4 ORDER BY b; CREATE TABLE collate_test5 ( a int, b testdomain_p COLLATE "C" ); INSERT INTO collate_test5 SELECT * FROM collate_test1; SELECT a, b FROM collate_test5 ORDER BY b; SELECT a, b FROM collate_test1 ORDER BY b; SELECT a, b FROM collate_test2 ORDER BY b; SELECT a, b FROM collate_test1 ORDER BY b COLLATE "C"; -- star expansion SELECT * FROM collate_test1 ORDER BY b; SELECT * FROM collate_test2 ORDER BY b; -- constant expression folding SELECT 'bbc' COLLATE "C" > 'Abc' COLLATE "C" AS "true"; SELECT 'bbc' COLLATE "POSIX" < 'Abc' COLLATE "POSIX" AS "false"; -- upper/lower CREATE TABLE collate_test10 ( a int, x text COLLATE "C", y text COLLATE "POSIX" ); INSERT INTO collate_test10 VALUES (1, 'hij', 'hij'), (2, 'HIJ', 'HIJ'); SELECT a, lower(x), lower(y), upper(x), upper(y), initcap(x), initcap(y) FROM collate_test10; SELECT a, lower(x COLLATE "C"), lower(y COLLATE "C") FROM collate_test10; SELECT a, x, y FROM collate_test10 ORDER BY lower(y), a; -- backwards parsing CREATE VIEW collview1 AS SELECT * FROM collate_test1 WHERE b COLLATE "C" >= 'bbc'; CREATE VIEW collview2 AS SELECT a, b FROM collate_test1 ORDER BY b COLLATE "C"; CREATE VIEW collview3 AS SELECT a, lower((x || x) COLLATE "POSIX") FROM collate_test10; SELECT table_name, view_definition FROM information_schema.views WHERE table_name LIKE 'collview%' ORDER BY 1; -- collation propagation in various expression types SELECT a, coalesce(b, 'foo') FROM collate_test1 ORDER BY 2; SELECT a, coalesce(b, 'foo') FROM collate_test2 ORDER BY 2; SELECT a, lower(coalesce(x, 'foo')), lower(coalesce(y, 'foo')) FROM collate_test10; SELECT a, b, greatest(b, 'CCC') FROM collate_test1 ORDER BY 3; SELECT a, b, greatest(b, 'CCC') FROM collate_test2 ORDER BY 3; SELECT a, x, y, lower(greatest(x, 'foo')), lower(greatest(y, 'foo')) FROM collate_test10; SELECT a, nullif(b, 'abc') FROM collate_test1 ORDER BY 2; SELECT a, nullif(b, 'abc') FROM collate_test2 ORDER BY 2; SELECT a, lower(nullif(x, 'foo')), lower(nullif(y, 'foo')) FROM collate_test10; SELECT a, CASE b WHEN 'abc' THEN 'abcd' ELSE b END FROM collate_test1 ORDER BY 2; SELECT a, CASE b WHEN 'abc' THEN 'abcd' ELSE b END FROM collate_test2 ORDER BY 2; CREATE DOMAIN testdomain AS text; SELECT a, b::testdomain FROM collate_test1 ORDER BY 2; SELECT a, b::testdomain FROM collate_test2 ORDER BY 2; SELECT a, b::testdomain_p FROM collate_test2 ORDER BY 2; SELECT a, lower(x::testdomain), lower(y::testdomain) FROM collate_test10; SELECT min(b), max(b) FROM collate_test1; SELECT min(b), max(b) FROM collate_test2; SELECT array_agg(b ORDER BY b) FROM collate_test1; SELECT array_agg(b ORDER BY b) FROM collate_test2; -- In aggregates, ORDER BY expressions don't affect aggregate's collation SELECT string_agg(x COLLATE "C", y COLLATE "POSIX") FROM collate_test10; -- fail SELECT array_agg(x COLLATE "C" ORDER BY y COLLATE "POSIX") FROM collate_test10; SELECT array_agg(a ORDER BY x COLLATE "C", y COLLATE "POSIX") FROM collate_test10; SELECT array_agg(a ORDER BY x||y) FROM collate_test10; -- fail SELECT a, b FROM collate_test1 UNION ALL SELECT a, b FROM collate_test1 ORDER BY 2; SELECT a, b FROM collate_test2 UNION SELECT a, b FROM collate_test2 ORDER BY 2; SELECT a, b FROM collate_test2 WHERE a < 4 INTERSECT SELECT a, b FROM collate_test2 WHERE a > 1 ORDER BY 2; SELECT a, b FROM collate_test2 EXCEPT SELECT a, b FROM collate_test2 WHERE a < 2 ORDER BY 2; SELECT a, b FROM collate_test1 UNION ALL SELECT a, b FROM collate_test2 ORDER BY 2; -- fail SELECT a, b FROM collate_test1 UNION ALL SELECT a, b FROM collate_test2; -- ok SELECT a, b FROM collate_test1 UNION SELECT a, b FROM collate_test2 ORDER BY 2; -- fail SELECT a, b COLLATE "C" FROM collate_test1 UNION SELECT a, b FROM collate_test2 ORDER BY 2; -- ok SELECT a, b FROM collate_test1 INTERSECT SELECT a, b FROM collate_test2 ORDER BY 2; -- fail SELECT a, b FROM collate_test1 EXCEPT SELECT a, b FROM collate_test2 ORDER BY 2; -- fail CREATE TABLE test_u AS SELECT a, b FROM collate_test1 UNION ALL SELECT a, b FROM collate_test2; -- fail -- ideally this would be a parse-time error, but for now it must be run-time: select x < y from collate_test10; -- fail select x || y from collate_test10; -- ok, because || is not collation aware select x, y from collate_test10 order by x || y; -- not so ok -- collation mismatch between recursive and non-recursive term WITH RECURSIVE foo(x) AS (SELECT x FROM (VALUES('a' COLLATE "C"),('b')) t(x) UNION ALL SELECT (x || 'c') COLLATE "POSIX" FROM foo WHERE length(x) < 10) SELECT * FROM foo; SELECT a, b, a < b as lt FROM (VALUES ('a', 'B'), ('A', 'b' COLLATE "C")) v(a,b); -- collation mismatch in subselects SELECT * FROM collate_test10 WHERE (x, y) NOT IN (SELECT y, x FROM collate_test10); -- now it works with overrides SELECT * FROM collate_test10 WHERE (x COLLATE "POSIX", y COLLATE "C") NOT IN (SELECT y, x FROM collate_test10); SELECT * FROM collate_test10 WHERE (x, y) NOT IN (SELECT y COLLATE "C", x COLLATE "POSIX" FROM collate_test10); -- casting SELECT CAST('42' AS text COLLATE "C"); SELECT a, CAST(b AS varchar) FROM collate_test1 ORDER BY 2; SELECT a, CAST(b AS varchar) FROM collate_test2 ORDER BY 2; -- result of a SQL function CREATE FUNCTION vc (text) RETURNS text LANGUAGE sql AS 'select $1::varchar'; SELECT a, b FROM collate_test1 ORDER BY a, vc(b); -- polymorphism SELECT * FROM unnest((SELECT array_agg(b ORDER BY b) FROM collate_test1)) ORDER BY 1; SELECT * FROM unnest((SELECT array_agg(b ORDER BY b) FROM collate_test2)) ORDER BY 1; CREATE FUNCTION dup (anyelement) RETURNS anyelement AS 'select $1' LANGUAGE sql; SELECT a, dup(b) FROM collate_test1 ORDER BY 2; SELECT a, dup(b) FROM collate_test2 ORDER BY 2; -- indexes CREATE INDEX collate_test1_idx1 ON collate_test1 (b); CREATE INDEX collate_test1_idx2 ON collate_test1 (b COLLATE "POSIX"); CREATE INDEX collate_test1_idx3 ON collate_test1 ((b COLLATE "POSIX")); -- this is different grammatically CREATE INDEX collate_test1_idx4 ON collate_test1 (((b||'foo') COLLATE "POSIX")); CREATE INDEX collate_test1_idx5 ON collate_test1 (a COLLATE "POSIX"); -- fail CREATE INDEX collate_test1_idx6 ON collate_test1 ((a COLLATE "POSIX")); -- fail SELECT relname, pg_get_indexdef(oid) FROM pg_class WHERE relname LIKE 'collate_test%_idx%' ORDER BY 1; -- foreign keys -- force indexes and mergejoins to be used for FK checking queries, -- else they might not exercise collation-dependent operators SET enable_seqscan TO 0; SET enable_hashjoin TO 0; SET enable_nestloop TO 0; CREATE TABLE collate_test20 (f1 text COLLATE "C" PRIMARY KEY); INSERT INTO collate_test20 VALUES ('foo'), ('bar'); CREATE TABLE collate_test21 (f2 text COLLATE "POSIX" REFERENCES collate_test20); INSERT INTO collate_test21 VALUES ('foo'), ('bar'); INSERT INTO collate_test21 VALUES ('baz'); -- fail CREATE TABLE collate_test22 (f2 text COLLATE "POSIX"); INSERT INTO collate_test22 VALUES ('foo'), ('bar'), ('baz'); ALTER TABLE collate_test22 ADD FOREIGN KEY (f2) REFERENCES collate_test20; -- fail DELETE FROM collate_test22 WHERE f2 = 'baz'; ALTER TABLE collate_test22 ADD FOREIGN KEY (f2) REFERENCES collate_test20; RESET enable_seqscan; RESET enable_hashjoin; RESET enable_nestloop; -- EXPLAIN EXPLAIN (COSTS OFF) SELECT * FROM collate_test10 ORDER BY x, y; EXPLAIN (COSTS OFF) SELECT * FROM collate_test10 ORDER BY x DESC, y COLLATE "C" ASC NULLS FIRST; -- CREATE/DROP COLLATION CREATE COLLATION mycoll1 FROM "C"; CREATE COLLATION mycoll2 ( LC_COLLATE = "POSIX", LC_CTYPE = "POSIX" ); CREATE COLLATION mycoll3 FROM "default"; -- intentionally unsupported DROP COLLATION mycoll1; CREATE TABLE collate_test23 (f1 text collate mycoll2); DROP COLLATION mycoll2; -- fail -- invalid: non-lowercase quoted identifiers CREATE COLLATION case_coll ("Lc_Collate" = "POSIX", "Lc_Ctype" = "POSIX"); -- 9.1 bug with useless COLLATE in an expression subject to length coercion CREATE TEMP TABLE vctable (f1 varchar(25)); INSERT INTO vctable VALUES ('foo' COLLATE "C"); SELECT collation for ('foo'); -- unknown type - null SELECT collation for ('foo'::text); SELECT collation for ((SELECT a FROM collate_test1 LIMIT 1)); -- non-collatable type - error SELECT collation for ((SELECT b FROM collate_test1 LIMIT 1)); -- old bug with not dropping COLLATE when coercing to non-collatable type CREATE VIEW collate_on_int AS SELECT c1+1 AS c1p FROM (SELECT ('4' COLLATE "C")::INT AS c1) ss; \d+ collate_on_int -- -- Clean up. Many of these table names will be re-used if the user is -- trying to run any platform-specific collation tests later, so we -- must get rid of them. -- DROP SCHEMA collate_tests CASCADE;