-- Generic extended statistics support -- -- Note: tables for which we check estimated row counts should be created -- with autovacuum_enabled = off, so that we don't have unstable results -- from auto-analyze happening when we didn't expect it. -- -- check the number of estimated/actual rows in the top node create function check_estimated_rows(text) returns table (estimated int, actual int) language plpgsql as $$ declare ln text; tmp text[]; first_row bool := true; begin for ln in execute format('explain analyze %s', $1) loop if first_row then first_row := false; tmp := regexp_match(ln, 'rows=(\d*) .* rows=(\d*)'); return query select tmp[1]::int, tmp[2]::int; end if; end loop; end; $$; -- Verify failures CREATE TABLE ext_stats_test (x text, y int, z int); CREATE STATISTICS tst; CREATE STATISTICS tst ON a, b; CREATE STATISTICS tst FROM sometab; CREATE STATISTICS tst ON a, b FROM nonexistent; CREATE STATISTICS tst ON a, b FROM ext_stats_test; CREATE STATISTICS tst ON x, x, y FROM ext_stats_test; CREATE STATISTICS tst ON x, x, y, x, x, y, x, x, y FROM ext_stats_test; CREATE STATISTICS tst ON x, x, y, x, x, (x || 'x'), (y + 1), (x || 'x'), (x || 'x'), (y + 1) FROM ext_stats_test; CREATE STATISTICS tst ON (x || 'x'), (x || 'x'), (y + 1), (x || 'x'), (x || 'x'), (y + 1), (x || 'x'), (x || 'x'), (y + 1) FROM ext_stats_test; CREATE STATISTICS tst ON (x || 'x'), (x || 'x'), y FROM ext_stats_test; CREATE STATISTICS tst (unrecognized) ON x, y FROM ext_stats_test; -- incorrect expressions CREATE STATISTICS tst ON (y) FROM ext_stats_test; -- single column reference CREATE STATISTICS tst ON y + z FROM ext_stats_test; -- missing parentheses CREATE STATISTICS tst ON (x, y) FROM ext_stats_test; -- tuple expression DROP TABLE ext_stats_test; -- Ensure stats are dropped sanely, and test IF NOT EXISTS while at it CREATE TABLE ab1 (a INTEGER, b INTEGER, c INTEGER); CREATE STATISTICS IF NOT EXISTS ab1_a_b_stats ON a, b FROM ab1; COMMENT ON STATISTICS ab1_a_b_stats IS 'new comment'; CREATE ROLE regress_stats_ext; SET SESSION AUTHORIZATION regress_stats_ext; COMMENT ON STATISTICS ab1_a_b_stats IS 'changed comment'; DROP STATISTICS ab1_a_b_stats; ALTER STATISTICS ab1_a_b_stats RENAME TO ab1_a_b_stats_new; RESET SESSION AUTHORIZATION; DROP ROLE regress_stats_ext; CREATE STATISTICS IF NOT EXISTS ab1_a_b_stats ON a, b FROM ab1; DROP STATISTICS ab1_a_b_stats; CREATE SCHEMA regress_schema_2; CREATE STATISTICS regress_schema_2.ab1_a_b_stats ON a, b FROM ab1; -- Let's also verify the pg_get_statisticsobjdef output looks sane. SELECT pg_get_statisticsobjdef(oid) FROM pg_statistic_ext WHERE stxname = 'ab1_a_b_stats'; DROP STATISTICS regress_schema_2.ab1_a_b_stats; -- Ensure statistics are dropped when columns are CREATE STATISTICS ab1_b_c_stats ON b, c FROM ab1; CREATE STATISTICS ab1_a_b_c_stats ON a, b, c FROM ab1; CREATE STATISTICS ab1_b_a_stats ON b, a FROM ab1; ALTER TABLE ab1 DROP COLUMN a; \d ab1 -- Ensure statistics are dropped when table is SELECT stxname FROM pg_statistic_ext WHERE stxname LIKE 'ab1%'; DROP TABLE ab1; SELECT stxname FROM pg_statistic_ext WHERE stxname LIKE 'ab1%'; -- Ensure things work sanely with SET STATISTICS 0 CREATE TABLE ab1 (a INTEGER, b INTEGER); ALTER TABLE ab1 ALTER a SET STATISTICS 0; INSERT INTO ab1 SELECT a, a%23 FROM generate_series(1, 1000) a; CREATE STATISTICS ab1_a_b_stats ON a, b FROM ab1; ANALYZE ab1; ALTER TABLE ab1 ALTER a SET STATISTICS -1; -- setting statistics target 0 skips the statistics, without printing any message, so check catalog ALTER STATISTICS ab1_a_b_stats SET STATISTICS 0; \d ab1 ANALYZE ab1; SELECT stxname, stxdndistinct, stxddependencies, stxdmcv, stxdinherit FROM pg_statistic_ext s LEFT JOIN pg_statistic_ext_data d ON (d.stxoid = s.oid) WHERE s.stxname = 'ab1_a_b_stats'; ALTER STATISTICS ab1_a_b_stats SET STATISTICS -1; \d+ ab1 -- partial analyze doesn't build stats either ANALYZE ab1 (a); ANALYZE ab1; DROP TABLE ab1; ALTER STATISTICS ab1_a_b_stats SET STATISTICS 0; ALTER STATISTICS IF EXISTS ab1_a_b_stats SET STATISTICS 0; -- Ensure we can build statistics for tables with inheritance. CREATE TABLE ab1 (a INTEGER, b INTEGER); CREATE TABLE ab1c () INHERITS (ab1); INSERT INTO ab1 VALUES (1,1); CREATE STATISTICS ab1_a_b_stats ON a, b FROM ab1; ANALYZE ab1; DROP TABLE ab1 CASCADE; -- Tests for stats with inheritance CREATE TABLE stxdinh(a int, b int); CREATE TABLE stxdinh1() INHERITS(stxdinh); CREATE TABLE stxdinh2() INHERITS(stxdinh); INSERT INTO stxdinh SELECT mod(a,50), mod(a,100) FROM generate_series(0, 1999) a; INSERT INTO stxdinh1 SELECT mod(a,100), mod(a,100) FROM generate_series(0, 999) a; INSERT INTO stxdinh2 SELECT mod(a,100), mod(a,100) FROM generate_series(0, 999) a; VACUUM ANALYZE stxdinh, stxdinh1, stxdinh2; -- Ensure non-inherited stats are not applied to inherited query -- Without stats object, it looks like this SELECT * FROM check_estimated_rows('SELECT a, b FROM stxdinh* GROUP BY 1, 2'); SELECT * FROM check_estimated_rows('SELECT a, b FROM stxdinh* WHERE a = 0 AND b = 0'); CREATE STATISTICS stxdinh ON a, b FROM stxdinh; VACUUM ANALYZE stxdinh, stxdinh1, stxdinh2; -- See if the extended stats affect the estimates SELECT * FROM check_estimated_rows('SELECT a, b FROM stxdinh* GROUP BY 1, 2'); -- Dependencies are applied at individual relations (within append), so -- this estimate changes a bit because we improve estimates for the parent SELECT * FROM check_estimated_rows('SELECT a, b FROM stxdinh* WHERE a = 0 AND b = 0'); -- Ensure correct (non-inherited) stats are applied to inherited query SELECT * FROM check_estimated_rows('SELECT a, b FROM ONLY stxdinh GROUP BY 1, 2'); SELECT * FROM check_estimated_rows('SELECT a, b FROM ONLY stxdinh WHERE a = 0 AND b = 0'); DROP TABLE stxdinh, stxdinh1, stxdinh2; -- Ensure inherited stats ARE applied to inherited query in partitioned table CREATE TABLE stxdinp(i int, a int, b int) PARTITION BY RANGE (i); CREATE TABLE stxdinp1 PARTITION OF stxdinp FOR VALUES FROM (1) TO (100); INSERT INTO stxdinp SELECT 1, a/100, a/100 FROM generate_series(1, 999) a; CREATE STATISTICS stxdinp ON (a + 1), a, b FROM stxdinp; VACUUM ANALYZE stxdinp; -- partitions are processed recursively SELECT 1 FROM pg_statistic_ext WHERE stxrelid = 'stxdinp'::regclass; SELECT * FROM check_estimated_rows('SELECT a, b FROM stxdinp GROUP BY 1, 2'); SELECT * FROM check_estimated_rows('SELECT a + 1, b FROM ONLY stxdinp GROUP BY 1, 2'); DROP TABLE stxdinp; -- basic test for statistics on expressions CREATE TABLE ab1 (a INTEGER, b INTEGER, c TIMESTAMP, d TIMESTAMPTZ); -- expression stats may be built on a single expression column CREATE STATISTICS ab1_exprstat_1 ON (a+b) FROM ab1; -- with a single expression, we only enable expression statistics CREATE STATISTICS ab1_exprstat_2 ON (a+b) FROM ab1; SELECT stxkind FROM pg_statistic_ext WHERE stxname = 'ab1_exprstat_2'; -- adding anything to the expression builds all statistics kinds CREATE STATISTICS ab1_exprstat_3 ON (a+b), a FROM ab1; SELECT stxkind FROM pg_statistic_ext WHERE stxname = 'ab1_exprstat_3'; -- date_trunc on timestamptz is not immutable, but that should not matter CREATE STATISTICS ab1_exprstat_4 ON date_trunc('day', d) FROM ab1; -- date_trunc on timestamp is immutable CREATE STATISTICS ab1_exprstat_5 ON date_trunc('day', c) FROM ab1; -- check use of a boolean-returning expression CREATE STATISTICS ab1_exprstat_6 ON (case a when 1 then true else false end), b FROM ab1; -- insert some data and run analyze, to test that these cases build properly INSERT INTO ab1 SELECT x / 10, x / 3, '2020-10-01'::timestamp + x * interval '1 day', '2020-10-01'::timestamptz + x * interval '1 day' FROM generate_series(1, 100) x; ANALYZE ab1; -- apply some stats SELECT * FROM check_estimated_rows('SELECT * FROM ab1 WHERE (case a when 1 then true else false end) AND b=2'); DROP TABLE ab1; -- Verify supported object types for extended statistics CREATE schema tststats; CREATE TABLE tststats.t (a int, b int, c text); CREATE INDEX ti ON tststats.t (a, b); CREATE SEQUENCE tststats.s; CREATE VIEW tststats.v AS SELECT * FROM tststats.t; CREATE MATERIALIZED VIEW tststats.mv AS SELECT * FROM tststats.t; CREATE TYPE tststats.ty AS (a int, b int, c text); CREATE FOREIGN DATA WRAPPER extstats_dummy_fdw; CREATE SERVER extstats_dummy_srv FOREIGN DATA WRAPPER extstats_dummy_fdw; CREATE FOREIGN TABLE tststats.f (a int, b int, c text) SERVER extstats_dummy_srv; CREATE TABLE tststats.pt (a int, b int, c text) PARTITION BY RANGE (a, b); CREATE TABLE tststats.pt1 PARTITION OF tststats.pt FOR VALUES FROM (-10, -10) TO (10, 10); CREATE STATISTICS tststats.s1 ON a, b FROM tststats.t; CREATE STATISTICS tststats.s2 ON a, b FROM tststats.ti; CREATE STATISTICS tststats.s3 ON a, b FROM tststats.s; CREATE STATISTICS tststats.s4 ON a, b FROM tststats.v; CREATE STATISTICS tststats.s5 ON a, b FROM tststats.mv; CREATE STATISTICS tststats.s6 ON a, b FROM tststats.ty; CREATE STATISTICS tststats.s7 ON a, b FROM tststats.f; CREATE STATISTICS tststats.s8 ON a, b FROM tststats.pt; CREATE STATISTICS tststats.s9 ON a, b FROM tststats.pt1; DO $$ DECLARE relname text := reltoastrelid::regclass FROM pg_class WHERE oid = 'tststats.t'::regclass; BEGIN EXECUTE 'CREATE STATISTICS tststats.s10 ON a, b FROM ' || relname; EXCEPTION WHEN wrong_object_type THEN RAISE NOTICE 'stats on toast table not created'; END; $$; DROP SCHEMA tststats CASCADE; DROP FOREIGN DATA WRAPPER extstats_dummy_fdw CASCADE; -- n-distinct tests CREATE TABLE ndistinct ( filler1 TEXT, filler2 NUMERIC, a INT, b INT, filler3 DATE, c INT, d INT ) WITH (autovacuum_enabled = off); -- over-estimates when using only per-column statistics INSERT INTO ndistinct (a, b, c, filler1) SELECT i/100, i/100, i/100, (i/100) || ' dollars and zero cents' FROM generate_series(1,1000) s(i); ANALYZE ndistinct; -- Group Aggregate, due to over-estimate of the number of groups SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY b, c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY b, c, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (a+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100), (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (a+1), (b+100)'); -- correct command CREATE STATISTICS s10 ON a, b, c FROM ndistinct; ANALYZE ndistinct; SELECT s.stxkind, d.stxdndistinct FROM pg_statistic_ext s, pg_statistic_ext_data d WHERE s.stxrelid = 'ndistinct'::regclass AND d.stxoid = s.oid; -- minor improvement, make sure the ctid does not break the matching SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY ctid, a, b'); -- Hash Aggregate, thanks to estimates improved by the statistic SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY b, c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c'); -- partial improvement (match on attributes) SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (a+1)'); -- expressions - no improvement SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100), (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (a+1), (b+100)'); -- last two plans keep using Group Aggregate, because 'd' is not covered -- by the statistic and while it's NULL-only we assume 200 values for it SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY b, c, d'); TRUNCATE TABLE ndistinct; -- under-estimates when using only per-column statistics INSERT INTO ndistinct (a, b, c, filler1) SELECT mod(i,13), mod(i,17), mod(i,19), mod(i,23) || ' dollars and zero cents' FROM generate_series(1,1000) s(i); ANALYZE ndistinct; SELECT s.stxkind, d.stxdndistinct FROM pg_statistic_ext s, pg_statistic_ext_data d WHERE s.stxrelid = 'ndistinct'::regclass AND d.stxoid = s.oid; -- correct estimates SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY b, c, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (a+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100), (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (a+1), (b+100)'); DROP STATISTICS s10; SELECT s.stxkind, d.stxdndistinct FROM pg_statistic_ext s, pg_statistic_ext_data d WHERE s.stxrelid = 'ndistinct'::regclass AND d.stxoid = s.oid; -- dropping the statistics results in under-estimates SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, c, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY b, c, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, d'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (a+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100), (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (a+1), (b+100)'); -- ndistinct estimates with statistics on expressions SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100), (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (a+1), (b+100)'); CREATE STATISTICS s10 (ndistinct) ON (a+1), (b+100), (2*c) FROM ndistinct; ANALYZE ndistinct; SELECT s.stxkind, d.stxdndistinct FROM pg_statistic_ext s, pg_statistic_ext_data d WHERE s.stxrelid = 'ndistinct'::regclass AND d.stxoid = s.oid; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a+1), (b+100), (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (a+1), (b+100)'); DROP STATISTICS s10; -- a mix of attributes and expressions SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (2*c)'); CREATE STATISTICS s10 (ndistinct) ON a, b, (2*c) FROM ndistinct; ANALYZE ndistinct; SELECT s.stxkind, d.stxdndistinct FROM pg_statistic_ext s, pg_statistic_ext_data d WHERE s.stxrelid = 'ndistinct'::regclass AND d.stxoid = s.oid; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (2*c)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (2*c)'); DROP STATISTICS s10; -- combination of multiple ndistinct statistics, with/without expressions TRUNCATE ndistinct; -- two mostly independent groups of columns INSERT INTO ndistinct (a, b, c, d) SELECT mod(i,3), mod(i,9), mod(i,5), mod(i,20) FROM generate_series(1,1000) s(i); ANALYZE ndistinct; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1), c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (c*10)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1), c, (d - 1)'); -- basic statistics on both attributes (no expressions) CREATE STATISTICS s11 (ndistinct) ON a, b FROM ndistinct; CREATE STATISTICS s12 (ndistinct) ON c, d FROM ndistinct; ANALYZE ndistinct; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1), c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (c*10)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1), c, (d - 1)'); -- replace the second statistics by statistics on expressions DROP STATISTICS s12; CREATE STATISTICS s12 (ndistinct) ON (c * 10), (d - 1) FROM ndistinct; ANALYZE ndistinct; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1), c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (c*10)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1), c, (d - 1)'); -- replace the second statistics by statistics on both attributes and expressions DROP STATISTICS s12; CREATE STATISTICS s12 (ndistinct) ON c, d, (c * 10), (d - 1) FROM ndistinct; ANALYZE ndistinct; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1), c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (c*10)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1), c, (d - 1)'); -- replace the other statistics by statistics on both attributes and expressions DROP STATISTICS s11; CREATE STATISTICS s11 (ndistinct) ON a, b, (a*5), (b+1) FROM ndistinct; ANALYZE ndistinct; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1), c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (c*10)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1), c, (d - 1)'); -- replace statistics by somewhat overlapping ones (this expected to get worse estimate -- because the first statistics shall be applied to 3 columns, and the second one can't -- be really applied) DROP STATISTICS s11; DROP STATISTICS s12; CREATE STATISTICS s11 (ndistinct) ON a, b, (a*5), (b+1) FROM ndistinct; CREATE STATISTICS s12 (ndistinct) ON a, (b+1), (c * 10) FROM ndistinct; ANALYZE ndistinct; SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), b'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY (a*5), (b+1), c'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, b, (c*10)'); SELECT * FROM check_estimated_rows('SELECT COUNT(*) FROM ndistinct GROUP BY a, (b+1), c, (d - 1)'); DROP STATISTICS s11; DROP STATISTICS s12; -- functional dependencies tests CREATE TABLE functional_dependencies ( filler1 TEXT, filler2 NUMERIC, a INT, b TEXT, filler3 DATE, c INT, d TEXT ) WITH (autovacuum_enabled = off); CREATE INDEX fdeps_ab_idx ON functional_dependencies (a, b); CREATE INDEX fdeps_abc_idx ON functional_dependencies (a, b, c); -- random data (no functional dependencies) INSERT INTO functional_dependencies (a, b, c, filler1) SELECT mod(i, 5), mod(i, 7), mod(i, 11), i FROM generate_series(1,1000) s(i); ANALYZE functional_dependencies; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'' AND c = 1'); -- create statistics CREATE STATISTICS func_deps_stat (dependencies) ON a, b, c FROM functional_dependencies; ANALYZE functional_dependencies; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'' AND c = 1'); -- a => b, a => c, b => c TRUNCATE functional_dependencies; DROP STATISTICS func_deps_stat; -- now do the same thing, but with expressions INSERT INTO functional_dependencies (a, b, c, filler1) SELECT i, i, i, i FROM generate_series(1,5000) s(i); ANALYZE functional_dependencies; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE mod(a, 11) = 1 AND mod(b::int, 13) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE mod(a, 11) = 1 AND mod(b::int, 13) = 1 AND mod(c, 7) = 1'); -- create statistics CREATE STATISTICS func_deps_stat (dependencies) ON (mod(a,11)), (mod(b::int, 13)), (mod(c, 7)) FROM functional_dependencies; ANALYZE functional_dependencies; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE mod(a, 11) = 1 AND mod(b::int, 13) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE mod(a, 11) = 1 AND mod(b::int, 13) = 1 AND mod(c, 7) = 1'); -- a => b, a => c, b => c TRUNCATE functional_dependencies; DROP STATISTICS func_deps_stat; INSERT INTO functional_dependencies (a, b, c, filler1) SELECT mod(i,100), mod(i,50), mod(i,25), i FROM generate_series(1,5000) s(i); ANALYZE functional_dependencies; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'' AND c = 1'); -- IN SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 51, 52) AND b IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 51, 52) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 26, 51, 76) AND b IN (''1'', ''26'') AND c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 26, 51, 76) AND b IN (''1'', ''26'') AND c IN (1)'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 26, 27, 51, 52, 76, 77) AND b IN (''1'', ''2'', ''26'', ''27'') AND c IN (1, 2)'); -- OR clauses referencing the same attribute SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR a = 51) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR a = 51) AND (b = ''1'' OR b = ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR a = 2 OR a = 51 OR a = 52) AND (b = ''1'' OR b = ''2'')'); -- OR clauses referencing different attributes SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR b = ''1'') AND b = ''1'''); -- ANY SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 51]) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 51]) AND b = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 2, 51, 52]) AND b = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 26, 51, 76]) AND b = ANY (ARRAY[''1'', ''26'']) AND c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 26, 51, 76]) AND b = ANY (ARRAY[''1'', ''26'']) AND c = ANY (ARRAY[1])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 2, 26, 27, 51, 52, 76, 77]) AND b = ANY (ARRAY[''1'', ''2'', ''26'', ''27'']) AND c = ANY (ARRAY[1, 2])'); -- ANY with inequalities should not benefit from functional dependencies SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a < ANY (ARRAY[1, 51]) AND b > ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a >= ANY (ARRAY[1, 51]) AND b <= ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a <= ANY (ARRAY[1, 2, 51, 52]) AND b >= ANY (ARRAY[''1'', ''2''])'); -- ALL (should not benefit from functional dependencies) SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b = ALL (ARRAY[''1''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b = ALL (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 51, 52) AND b = ALL (ARRAY[''1'', ''2''])'); -- create statistics CREATE STATISTICS func_deps_stat (dependencies) ON a, b, c FROM functional_dependencies; ANALYZE functional_dependencies; -- print the detected dependencies SELECT dependencies FROM pg_stats_ext WHERE statistics_name = 'func_deps_stat'; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'' AND c = 1'); -- IN SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 51, 52) AND b IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 51, 52) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 26, 51, 76) AND b IN (''1'', ''26'') AND c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 26, 51, 76) AND b IN (''1'', ''26'') AND c IN (1)'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 26, 27, 51, 52, 76, 77) AND b IN (''1'', ''2'', ''26'', ''27'') AND c IN (1, 2)'); -- OR clauses referencing the same attribute SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR a = 51) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR a = 51) AND (b = ''1'' OR b = ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR a = 2 OR a = 51 OR a = 52) AND (b = ''1'' OR b = ''2'')'); -- OR clauses referencing different attributes are incompatible SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a = 1 OR b = ''1'') AND b = ''1'''); -- ANY SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 51]) AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 51]) AND b = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 2, 51, 52]) AND b = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 26, 51, 76]) AND b = ANY (ARRAY[''1'', ''26'']) AND c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 26, 51, 76]) AND b = ANY (ARRAY[''1'', ''26'']) AND c = ANY (ARRAY[1])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = ANY (ARRAY[1, 2, 26, 27, 51, 52, 76, 77]) AND b = ANY (ARRAY[''1'', ''2'', ''26'', ''27'']) AND c = ANY (ARRAY[1, 2])'); -- ANY with inequalities should not benefit from functional dependencies SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a < ANY (ARRAY[1, 51]) AND b > ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a >= ANY (ARRAY[1, 51]) AND b <= ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a <= ANY (ARRAY[1, 2, 51, 52]) AND b >= ANY (ARRAY[''1'', ''2''])'); -- ALL (should not benefit from functional dependencies) SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b = ALL (ARRAY[''1''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 51) AND b = ALL (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a IN (1, 2, 51, 52) AND b = ALL (ARRAY[''1'', ''2''])'); -- changing the type of column c causes all its stats to be dropped, reverting -- to default estimates without any statistics, i.e. 0.5% selectivity for each -- condition ALTER TABLE functional_dependencies ALTER COLUMN c TYPE numeric; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'' AND c = 1'); ANALYZE functional_dependencies; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE a = 1 AND b = ''1'' AND c = 1'); DROP STATISTICS func_deps_stat; -- now try functional dependencies with expressions SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = 2 AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = 2 AND upper(b) = ''1'' AND (c + 1) = 2'); -- IN SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 102, 104) AND upper(b) IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 102, 104) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 52, 102, 152) AND upper(b) IN (''1'', ''26'') AND (c + 1) = 2'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 52, 102, 152) AND upper(b) IN (''1'', ''26'') AND (c + 1) IN (2)'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 52, 54, 102, 104, 152, 154) AND upper(b) IN (''1'', ''2'', ''26'', ''27'') AND (c + 1) IN (2, 3)'); -- OR clauses referencing the same attribute SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR (a * 2) = 102) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR (a * 2) = 102) AND (upper(b) = ''1'' OR upper(b) = ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR (a * 2) = 4 OR (a * 2) = 102 OR (a * 2) = 104) AND (upper(b) = ''1'' OR upper(b) = ''2'')'); -- OR clauses referencing different attributes SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR upper(b) = ''1'') AND upper(b) = ''1'''); -- ANY SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 102]) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 102]) AND upper(b) = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 4, 102, 104]) AND upper(b) = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 52, 102, 152]) AND upper(b) = ANY (ARRAY[''1'', ''26'']) AND (c + 1) = 2'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 52, 102, 152]) AND upper(b) = ANY (ARRAY[''1'', ''26'']) AND (c + 1) = ANY (ARRAY[2])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 4, 52, 54, 102, 104, 152, 154]) AND upper(b) = ANY (ARRAY[''1'', ''2'', ''26'', ''27'']) AND (c + 1) = ANY (ARRAY[2, 3])'); -- ANY with inequalities should not benefit from functional dependencies -- the estimates however improve thanks to having expression statistics SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) < ANY (ARRAY[2, 102]) AND upper(b) > ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) >= ANY (ARRAY[2, 102]) AND upper(b) <= ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) <= ANY (ARRAY[2, 4, 102, 104]) AND upper(b) >= ANY (ARRAY[''1'', ''2''])'); -- ALL (should not benefit from functional dependencies) SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) = ALL (ARRAY[''1''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) = ALL (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 102, 104) AND upper(b) = ALL (ARRAY[''1'', ''2''])'); -- create statistics on expressions CREATE STATISTICS func_deps_stat (dependencies) ON (a * 2), upper(b), (c + 1) FROM functional_dependencies; ANALYZE functional_dependencies; -- print the detected dependencies SELECT dependencies FROM pg_stats_ext WHERE statistics_name = 'func_deps_stat'; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = 2 AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = 2 AND upper(b) = ''1'' AND (c + 1) = 2'); -- IN SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 102, 104) AND upper(b) IN (''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 102, 104) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 52, 102, 152) AND upper(b) IN (''1'', ''26'') AND (c + 1) = 2'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 52, 102, 152) AND upper(b) IN (''1'', ''26'') AND (c + 1) IN (2)'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 52, 54, 102, 104, 152, 154) AND upper(b) IN (''1'', ''2'', ''26'', ''27'') AND (c + 1) IN (2, 3)'); -- OR clauses referencing the same attribute SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR (a * 2) = 102) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR (a * 2) = 102) AND (upper(b) = ''1'' OR upper(b) = ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR (a * 2) = 4 OR (a * 2) = 102 OR (a * 2) = 104) AND (upper(b) = ''1'' OR upper(b) = ''2'')'); -- OR clauses referencing different attributes SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE ((a * 2) = 2 OR upper(b) = ''1'') AND upper(b) = ''1'''); -- ANY SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 102]) AND upper(b) = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 102]) AND upper(b) = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 4, 102, 104]) AND upper(b) = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 52, 102, 152]) AND upper(b) = ANY (ARRAY[''1'', ''26'']) AND (c + 1) = 2'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 52, 102, 152]) AND upper(b) = ANY (ARRAY[''1'', ''26'']) AND (c + 1) = ANY (ARRAY[2])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) = ANY (ARRAY[2, 4, 52, 54, 102, 104, 152, 154]) AND upper(b) = ANY (ARRAY[''1'', ''2'', ''26'', ''27'']) AND (c + 1) = ANY (ARRAY[2, 3])'); -- ANY with inequalities should not benefit from functional dependencies -- the estimates however improve thanks to having expression statistics SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) < ANY (ARRAY[2, 102]) AND upper(b) > ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) >= ANY (ARRAY[2, 102]) AND upper(b) <= ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) <= ANY (ARRAY[2, 4, 102, 104]) AND upper(b) >= ANY (ARRAY[''1'', ''2''])'); -- ALL (should not benefit from functional dependencies) SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) = ALL (ARRAY[''1''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 102) AND upper(b) = ALL (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies WHERE (a * 2) IN (2, 4, 102, 104) AND upper(b) = ALL (ARRAY[''1'', ''2''])'); -- check the ability to use multiple functional dependencies CREATE TABLE functional_dependencies_multi ( a INTEGER, b INTEGER, c INTEGER, d INTEGER ) WITH (autovacuum_enabled = off); INSERT INTO functional_dependencies_multi (a, b, c, d) SELECT mod(i,7), mod(i,7), mod(i,11), mod(i,11) FROM generate_series(1,5000) s(i); ANALYZE functional_dependencies_multi; -- estimates without any functional dependencies SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE a = 0 AND b = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE 0 = a AND 0 = b'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE a = 0 AND b = 0 AND c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE 0 = a AND b = 0 AND 0 = c AND d = 0'); -- create separate functional dependencies CREATE STATISTICS functional_dependencies_multi_1 (dependencies) ON a, b FROM functional_dependencies_multi; CREATE STATISTICS functional_dependencies_multi_2 (dependencies) ON c, d FROM functional_dependencies_multi; ANALYZE functional_dependencies_multi; SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE a = 0 AND b = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE 0 = a AND 0 = b'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE a = 0 AND b = 0 AND c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM functional_dependencies_multi WHERE 0 = a AND b = 0 AND 0 = c AND d = 0'); DROP TABLE functional_dependencies_multi; -- MCV lists CREATE TABLE mcv_lists ( filler1 TEXT, filler2 NUMERIC, a INT, b VARCHAR, filler3 DATE, c INT, d TEXT, ia INT[] ) WITH (autovacuum_enabled = off); -- random data (no MCV list) INSERT INTO mcv_lists (a, b, c, filler1) SELECT mod(i,37), mod(i,41), mod(i,43), mod(i,47) FROM generate_series(1,5000) s(i); ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'' AND c = 1'); -- create statistics CREATE STATISTICS mcv_lists_stats (mcv) ON a, b, c FROM mcv_lists; ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'' AND c = 1'); TRUNCATE mcv_lists; DROP STATISTICS mcv_lists_stats; -- random data (no MCV list), but with expression INSERT INTO mcv_lists (a, b, c, filler1) SELECT i, i, i, i FROM generate_series(1,1000) s(i); ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,7) = 1 AND mod(b::int,11) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,7) = 1 AND mod(b::int,11) = 1 AND mod(c,13) = 1'); -- create statistics CREATE STATISTICS mcv_lists_stats (mcv) ON (mod(a,7)), (mod(b::int,11)), (mod(c,13)) FROM mcv_lists; ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,7) = 1 AND mod(b::int,11) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,7) = 1 AND mod(b::int,11) = 1 AND mod(c,13) = 1'); -- 100 distinct combinations, all in the MCV list TRUNCATE mcv_lists; DROP STATISTICS mcv_lists_stats; INSERT INTO mcv_lists (a, b, c, ia, filler1) SELECT mod(i,100), mod(i,50), mod(i,25), array[mod(i,25)], i FROM generate_series(1,5000) s(i); ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 = a AND ''1'' = b'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < 1 AND b < ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 > a AND ''1'' > b'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= 0 AND b <= ''0'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 0 >= a AND ''0'' >= b'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'' AND c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < 5 AND b < ''1'' AND c < 5'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < 5 AND ''1'' > b AND 5 > c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= 4 AND b <= ''0'' AND c <= 4'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 4 >= a AND ''0'' >= b AND 4 >= c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 OR b = ''1'' OR c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 OR b = ''1'' OR c = 1 OR d IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IN (1, 2, 51, 52) AND b IN ( ''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IN (1, 2, 51, 52, NULL) AND b IN ( ''1'', ''2'', NULL)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = ANY (ARRAY[1, 2, 51, 52]) AND b = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = ANY (ARRAY[NULL, 1, 2, 51, 52]) AND b = ANY (ARRAY[''1'', ''2'', NULL])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= ANY (ARRAY[1, 2, 3]) AND b IN (''1'', ''2'', ''3'')'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= ANY (ARRAY[1, NULL, 2, 3]) AND b IN (''1'', ''2'', NULL, ''3'')'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND c > ANY (ARRAY[1, 2, 3])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND c > ANY (ARRAY[1, 2, 3, NULL])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND b IN (''1'', ''2'', ''3'') AND c > ANY (ARRAY[1, 2, 3])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND b IN (''1'', ''2'', NULL, ''3'') AND c > ANY (ARRAY[1, 2, NULL, 3])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = ANY (ARRAY[4,5]) AND 4 = ANY(ia)'); -- create statistics CREATE STATISTICS mcv_lists_stats (mcv) ON a, b, c, ia FROM mcv_lists; ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 = a AND ''1'' = b'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < 1 AND b < ''1'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 > a AND ''1'' > b'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= 0 AND b <= ''0'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 0 >= a AND ''0'' >= b'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'' AND c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < 5 AND b < ''1'' AND c < 5'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < 5 AND ''1'' > b AND 5 > c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= 4 AND b <= ''0'' AND c <= 4'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 4 >= a AND ''0'' >= b AND 4 >= c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 OR b = ''1'' OR c = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 OR b = ''1'' OR c = 1 OR d IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 OR b = ''1'' OR c = 1 OR d IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IN (1, 2, 51, 52) AND b IN ( ''1'', ''2'')'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IN (1, 2, 51, 52, NULL) AND b IN ( ''1'', ''2'', NULL)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = ANY (ARRAY[1, 2, 51, 52]) AND b = ANY (ARRAY[''1'', ''2''])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = ANY (ARRAY[NULL, 1, 2, 51, 52]) AND b = ANY (ARRAY[''1'', ''2'', NULL])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= ANY (ARRAY[1, 2, 3]) AND b IN (''1'', ''2'', ''3'')'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a <= ANY (ARRAY[1, NULL, 2, 3]) AND b IN (''1'', ''2'', NULL, ''3'')'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND c > ANY (ARRAY[1, 2, 3])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND c > ANY (ARRAY[1, 2, 3, NULL])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND b IN (''1'', ''2'', ''3'') AND c > ANY (ARRAY[1, 2, 3])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a < ALL (ARRAY[4, 5]) AND b IN (''1'', ''2'', NULL, ''3'') AND c > ANY (ARRAY[1, 2, NULL, 3])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = ANY (ARRAY[4,5]) AND 4 = ANY(ia)'); -- check change of unrelated column type does not reset the MCV statistics ALTER TABLE mcv_lists ALTER COLUMN d TYPE VARCHAR(64); SELECT d.stxdmcv IS NOT NULL FROM pg_statistic_ext s, pg_statistic_ext_data d WHERE s.stxname = 'mcv_lists_stats' AND d.stxoid = s.oid; -- check change of column type resets the MCV statistics ALTER TABLE mcv_lists ALTER COLUMN c TYPE numeric; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'''); ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 AND b = ''1'''); -- 100 distinct combinations, all in the MCV list, but with expressions TRUNCATE mcv_lists; DROP STATISTICS mcv_lists_stats; INSERT INTO mcv_lists (a, b, c, filler1) SELECT i, i, i, i FROM generate_series(1,1000) s(i); ANALYZE mcv_lists; -- without any stats on the expressions, we have to use default selectivities, which -- is why the estimates here are different from the pre-computed case above SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 AND mod(b::int,10) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 = mod(a,20) AND 1 = mod(b::int,10)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) < 1 AND mod(b::int,10) < 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 > mod(a,20) AND 1 > mod(b::int,10)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 AND mod(b::int,10) = 1 AND mod(c,5) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 OR mod(b::int,10) = 1 OR mod(c,25) = 1 OR d IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) IN (1, 2, 51, 52, NULL) AND mod(b::int,10) IN ( 1, 2, NULL)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = ANY (ARRAY[1, 2, 51, 52]) AND mod(b::int,10) = ANY (ARRAY[1, 2])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) <= ANY (ARRAY[1, NULL, 2, 3]) AND mod(b::int,10) IN (1, 2, NULL, 3)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) < ALL (ARRAY[4, 5]) AND mod(b::int,10) IN (1, 2, 3) AND mod(c,5) > ANY (ARRAY[1, 2, 3])'); -- create statistics with expressions only (we create three separate stats, in order not to build more complex extended stats) CREATE STATISTICS mcv_lists_stats_1 ON (mod(a,20)) FROM mcv_lists; CREATE STATISTICS mcv_lists_stats_2 ON (mod(b::int,10)) FROM mcv_lists; CREATE STATISTICS mcv_lists_stats_3 ON (mod(c,5)) FROM mcv_lists; ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 AND mod(b::int,10) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 = mod(a,20) AND 1 = mod(b::int,10)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) < 1 AND mod(b::int,10) < 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 > mod(a,20) AND 1 > mod(b::int,10)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 AND mod(b::int,10) = 1 AND mod(c,5) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 OR mod(b::int,10) = 1 OR mod(c,25) = 1 OR d IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) IN (1, 2, 51, 52, NULL) AND mod(b::int,10) IN ( 1, 2, NULL)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = ANY (ARRAY[1, 2, 51, 52]) AND mod(b::int,10) = ANY (ARRAY[1, 2])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) <= ANY (ARRAY[1, NULL, 2, 3]) AND mod(b::int,10) IN (1, 2, NULL, 3)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) < ALL (ARRAY[4, 5]) AND mod(b::int,10) IN (1, 2, 3) AND mod(c,5) > ANY (ARRAY[1, 2, 3])'); DROP STATISTICS mcv_lists_stats_1; DROP STATISTICS mcv_lists_stats_2; DROP STATISTICS mcv_lists_stats_3; -- create statistics with both MCV and expressions CREATE STATISTICS mcv_lists_stats (mcv) ON (mod(a,20)), (mod(b::int,10)), (mod(c,5)) FROM mcv_lists; ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 AND mod(b::int,10) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 = mod(a,20) AND 1 = mod(b::int,10)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) < 1 AND mod(b::int,10) < 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE 1 > mod(a,20) AND 1 > mod(b::int,10)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 AND mod(b::int,10) = 1 AND mod(c,5) = 1'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 OR mod(b::int,10) = 1 OR mod(c,25) = 1 OR d IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) IN (1, 2, 51, 52, NULL) AND mod(b::int,10) IN ( 1, 2, NULL)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = ANY (ARRAY[1, 2, 51, 52]) AND mod(b::int,10) = ANY (ARRAY[1, 2])'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) <= ANY (ARRAY[1, NULL, 2, 3]) AND mod(b::int,10) IN (1, 2, NULL, 3)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) < ALL (ARRAY[4, 5]) AND mod(b::int,10) IN (1, 2, 3) AND mod(c,5) > ANY (ARRAY[1, 2, 3])'); -- we can't use the statistic for OR clauses that are not fully covered (missing 'd' attribute) SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE mod(a,20) = 1 OR mod(b::int,10) = 1 OR mod(c,5) = 1 OR d IS NOT NULL'); -- 100 distinct combinations with NULL values, all in the MCV list TRUNCATE mcv_lists; DROP STATISTICS mcv_lists_stats; INSERT INTO mcv_lists (a, b, c, filler1) SELECT (CASE WHEN mod(i,100) = 1 THEN NULL ELSE mod(i,100) END), (CASE WHEN mod(i,50) = 1 THEN NULL ELSE mod(i,50) END), (CASE WHEN mod(i,25) = 1 THEN NULL ELSE mod(i,25) END), i FROM generate_series(1,5000) s(i); ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND b IS NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND b IS NULL AND c IS NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND b IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NOT NULL AND b IS NULL AND c IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IN (0, 1) AND b IN (''0'', ''1'')'); -- create statistics CREATE STATISTICS mcv_lists_stats (mcv) ON a, b, c FROM mcv_lists; ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND b IS NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND b IS NULL AND c IS NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND b IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NOT NULL AND b IS NULL AND c IS NOT NULL'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IN (0, 1) AND b IN (''0'', ''1'')'); -- test pg_mcv_list_items with a very simple (single item) MCV list TRUNCATE mcv_lists; INSERT INTO mcv_lists (a, b, c) SELECT 1, 2, 3 FROM generate_series(1,1000) s(i); ANALYZE mcv_lists; SELECT m.* FROM pg_statistic_ext s, pg_statistic_ext_data d, pg_mcv_list_items(d.stxdmcv) m WHERE s.stxname = 'mcv_lists_stats' AND d.stxoid = s.oid; -- 2 distinct combinations with NULL values, all in the MCV list TRUNCATE mcv_lists; DROP STATISTICS mcv_lists_stats; INSERT INTO mcv_lists (a, b, c, d) SELECT NULL, -- always NULL (CASE WHEN mod(i,2) = 0 THEN NULL ELSE 'x' END), (CASE WHEN mod(i,2) = 0 THEN NULL ELSE 0 END), (CASE WHEN mod(i,2) = 0 THEN NULL ELSE 'x' END) FROM generate_series(1,5000) s(i); ANALYZE mcv_lists; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE b = ''x'' OR d = ''x'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 OR b = ''x'' OR d = ''x'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND (b = ''x'' OR d = ''x'')'); -- create statistics CREATE STATISTICS mcv_lists_stats (mcv) ON a, b, d FROM mcv_lists; ANALYZE mcv_lists; -- test pg_mcv_list_items with MCV list containing variable-length data and NULLs SELECT m.* FROM pg_statistic_ext s, pg_statistic_ext_data d, pg_mcv_list_items(d.stxdmcv) m WHERE s.stxname = 'mcv_lists_stats' AND d.stxoid = s.oid; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE b = ''x'' OR d = ''x'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a = 1 OR b = ''x'' OR d = ''x'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists WHERE a IS NULL AND (b = ''x'' OR d = ''x'')'); -- mcv with pass-by-ref fixlen types, e.g. uuid CREATE TABLE mcv_lists_uuid ( a UUID, b UUID, c UUID ) WITH (autovacuum_enabled = off); INSERT INTO mcv_lists_uuid (a, b, c) SELECT fipshash(mod(i,100)::text)::uuid, fipshash(mod(i,50)::text)::uuid, fipshash(mod(i,25)::text)::uuid FROM generate_series(1,5000) s(i); ANALYZE mcv_lists_uuid; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_uuid WHERE a = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'' AND b = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_uuid WHERE a = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'' AND b = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'' AND c = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'''); CREATE STATISTICS mcv_lists_uuid_stats (mcv) ON a, b, c FROM mcv_lists_uuid; ANALYZE mcv_lists_uuid; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_uuid WHERE a = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'' AND b = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'''); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_uuid WHERE a = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'' AND b = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'' AND c = ''e7f6c011-776e-8db7-cd33-0b54174fd76f'''); DROP TABLE mcv_lists_uuid; -- mcv with arrays CREATE TABLE mcv_lists_arrays ( a TEXT[], b NUMERIC[], c INT[] ) WITH (autovacuum_enabled = off); INSERT INTO mcv_lists_arrays (a, b, c) SELECT ARRAY[fipshash((i/100)::text), fipshash((i/100-1)::text), fipshash((i/100+1)::text)], ARRAY[(i/100-1)::numeric/1000, (i/100)::numeric/1000, (i/100+1)::numeric/1000], ARRAY[(i/100-1), i/100, (i/100+1)] FROM generate_series(1,5000) s(i); CREATE STATISTICS mcv_lists_arrays_stats (mcv) ON a, b, c FROM mcv_lists_arrays; ANALYZE mcv_lists_arrays; -- mcv with bool CREATE TABLE mcv_lists_bool ( a BOOL, b BOOL, c BOOL ) WITH (autovacuum_enabled = off); INSERT INTO mcv_lists_bool (a, b, c) SELECT (mod(i,2) = 0), (mod(i,4) = 0), (mod(i,8) = 0) FROM generate_series(1,10000) s(i); ANALYZE mcv_lists_bool; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE a AND b AND c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE NOT a AND b AND c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE NOT a AND NOT b AND c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE NOT a AND b AND NOT c'); CREATE STATISTICS mcv_lists_bool_stats (mcv) ON a, b, c FROM mcv_lists_bool; ANALYZE mcv_lists_bool; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE a AND b AND c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE NOT a AND b AND c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE NOT a AND NOT b AND c'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_bool WHERE NOT a AND b AND NOT c'); -- mcv covering just a small fraction of data CREATE TABLE mcv_lists_partial ( a INT, b INT, c INT ); -- 10 frequent groups, each with 100 elements INSERT INTO mcv_lists_partial (a, b, c) SELECT mod(i,10), mod(i,10), mod(i,10) FROM generate_series(0,999) s(i); -- 100 groups that will make it to the MCV list (includes the 10 frequent ones) INSERT INTO mcv_lists_partial (a, b, c) SELECT i, i, i FROM generate_series(0,99) s(i); -- 4000 groups in total, most of which won't make it (just a single item) INSERT INTO mcv_lists_partial (a, b, c) SELECT i, i, i FROM generate_series(0,3999) s(i); ANALYZE mcv_lists_partial; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 AND b = 0 AND c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 OR b = 0 OR c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 10 AND b = 10 AND c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 10 OR b = 10 OR c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 AND b = 0 AND c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 OR b = 0 OR c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE (a = 0 AND b = 0 AND c = 0) OR (a = 1 AND b = 1 AND c = 1) OR (a = 2 AND b = 2 AND c = 2)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE (a = 0 AND b = 0) OR (a = 0 AND c = 0) OR (b = 0 AND c = 0)'); CREATE STATISTICS mcv_lists_partial_stats (mcv) ON a, b, c FROM mcv_lists_partial; ANALYZE mcv_lists_partial; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 AND b = 0 AND c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 OR b = 0 OR c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 10 AND b = 10 AND c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 10 OR b = 10 OR c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 AND b = 0 AND c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE a = 0 OR b = 0 OR c = 10'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE (a = 0 AND b = 0 AND c = 0) OR (a = 1 AND b = 1 AND c = 1) OR (a = 2 AND b = 2 AND c = 2)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_partial WHERE (a = 0 AND b = 0) OR (a = 0 AND c = 0) OR (b = 0 AND c = 0)'); DROP TABLE mcv_lists_partial; -- check the ability to use multiple MCV lists CREATE TABLE mcv_lists_multi ( a INTEGER, b INTEGER, c INTEGER, d INTEGER ) WITH (autovacuum_enabled = off); INSERT INTO mcv_lists_multi (a, b, c, d) SELECT mod(i,5), mod(i,5), mod(i,7), mod(i,7) FROM generate_series(1,5000) s(i); ANALYZE mcv_lists_multi; -- estimates without any mcv statistics SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE a = 0 AND b = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE b = 0 AND c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE b = 0 OR c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE a = 0 AND b = 0 AND c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE (a = 0 AND b = 0) OR (c = 0 AND d = 0)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE a = 0 OR b = 0 OR c = 0 OR d = 0'); -- create separate MCV statistics CREATE STATISTICS mcv_lists_multi_1 (mcv) ON a, b FROM mcv_lists_multi; CREATE STATISTICS mcv_lists_multi_2 (mcv) ON c, d FROM mcv_lists_multi; ANALYZE mcv_lists_multi; SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE a = 0 AND b = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE b = 0 AND c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE b = 0 OR c = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE a = 0 AND b = 0 AND c = 0 AND d = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE (a = 0 AND b = 0) OR (c = 0 AND d = 0)'); SELECT * FROM check_estimated_rows('SELECT * FROM mcv_lists_multi WHERE a = 0 OR b = 0 OR c = 0 OR d = 0'); DROP TABLE mcv_lists_multi; -- statistics on integer expressions CREATE TABLE expr_stats (a int, b int, c int); INSERT INTO expr_stats SELECT mod(i,10), mod(i,10), mod(i,10) FROM generate_series(1,1000) s(i); ANALYZE expr_stats; SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE (2*a) = 0 AND (3*b) = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE (a+b) = 0 AND (a-b) = 0'); CREATE STATISTICS expr_stats_1 (mcv) ON (a+b), (a-b), (2*a), (3*b) FROM expr_stats; ANALYZE expr_stats; SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE (2*a) = 0 AND (3*b) = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE (a+b) = 0 AND (a-b) = 0'); DROP STATISTICS expr_stats_1; DROP TABLE expr_stats; -- statistics on a mix columns and expressions CREATE TABLE expr_stats (a int, b int, c int); INSERT INTO expr_stats SELECT mod(i,10), mod(i,10), mod(i,10) FROM generate_series(1,1000) s(i); ANALYZE expr_stats; SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 0 AND (2*a) = 0 AND (3*b) = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 3 AND b = 3 AND (a-b) = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 0 AND b = 1 AND (a-b) = 0'); CREATE STATISTICS expr_stats_1 (mcv) ON a, b, (2*a), (3*b), (a+b), (a-b) FROM expr_stats; ANALYZE expr_stats; SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 0 AND (2*a) = 0 AND (3*b) = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 3 AND b = 3 AND (a-b) = 0'); SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 0 AND b = 1 AND (a-b) = 0'); DROP TABLE expr_stats; -- statistics on expressions with different data types CREATE TABLE expr_stats (a int, b name, c text); INSERT INTO expr_stats SELECT mod(i,10), fipshash(mod(i,10)::text), fipshash(mod(i,10)::text) FROM generate_series(1,1000) s(i); ANALYZE expr_stats; SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 0 AND (b || c) <= ''z'' AND (c || b) >= ''0'''); CREATE STATISTICS expr_stats_1 (mcv) ON a, b, (b || c), (c || b) FROM expr_stats; ANALYZE expr_stats; SELECT * FROM check_estimated_rows('SELECT * FROM expr_stats WHERE a = 0 AND (b || c) <= ''z'' AND (c || b) >= ''0'''); DROP TABLE expr_stats; -- test handling of a mix of compatible and incompatible expressions CREATE TABLE expr_stats_incompatible_test ( c0 double precision, c1 boolean NOT NULL ); CREATE STATISTICS expr_stat_comp_1 ON c0, c1 FROM expr_stats_incompatible_test; INSERT INTO expr_stats_incompatible_test VALUES (1234,false), (5678,true); ANALYZE expr_stats_incompatible_test; SELECT c0 FROM ONLY expr_stats_incompatible_test WHERE ( upper('x') LIKE ('x'||('[0,1]'::int4range)) AND (c0 IN (0, 1) OR c1) ); DROP TABLE expr_stats_incompatible_test; -- Permission tests. Users should not be able to see specific data values in -- the extended statistics, if they lack permission to see those values in -- the underlying table. -- -- Currently this is only relevant for MCV stats. CREATE SCHEMA tststats; CREATE TABLE tststats.priv_test_tbl ( a int, b int ); INSERT INTO tststats.priv_test_tbl SELECT mod(i,5), mod(i,10) FROM generate_series(1,100) s(i); CREATE STATISTICS tststats.priv_test_stats (mcv) ON a, b FROM tststats.priv_test_tbl; ANALYZE tststats.priv_test_tbl; -- Check printing info about extended statistics by \dX create table stts_t1 (a int, b int); create statistics (ndistinct) on a, b from stts_t1; create statistics (ndistinct, dependencies) on a, b from stts_t1; create statistics (ndistinct, dependencies, mcv) on a, b from stts_t1; create table stts_t2 (a int, b int, c int); create statistics on b, c from stts_t2; create table stts_t3 (col1 int, col2 int, col3 int); create statistics stts_hoge on col1, col2, col3 from stts_t3; create schema stts_s1; create schema stts_s2; create statistics stts_s1.stts_foo on col1, col2 from stts_t3; create statistics stts_s2.stts_yama (dependencies, mcv) on col1, col3 from stts_t3; insert into stts_t1 select i,i from generate_series(1,100) i; analyze stts_t1; set search_path to public, stts_s1, stts_s2, tststats; \dX \dX stts_t* \dX *stts_hoge \dX+ \dX+ stts_t* \dX+ *stts_hoge \dX+ stts_s2.stts_yama create statistics (mcv) ON a, b, (a+b), (a-b) FROM stts_t1; create statistics (mcv) ON a, b, (a+b), (a-b) FROM stts_t1; create statistics (mcv) ON (a+b), (a-b) FROM stts_t1; \dX stts_t*expr* drop statistics stts_t1_a_b_expr_expr_stat; drop statistics stts_t1_a_b_expr_expr_stat1; drop statistics stts_t1_expr_expr_stat; set search_path to public, stts_s1; \dX create role regress_stats_ext nosuperuser; set role regress_stats_ext; \dX reset role; drop table stts_t1, stts_t2, stts_t3; drop schema stts_s1, stts_s2 cascade; drop user regress_stats_ext; reset search_path; -- User with no access CREATE USER regress_stats_user1; GRANT USAGE ON SCHEMA tststats TO regress_stats_user1; SET SESSION AUTHORIZATION regress_stats_user1; SELECT * FROM tststats.priv_test_tbl; -- Permission denied -- Check individual columns if we don't have table privilege SELECT * FROM tststats.priv_test_tbl WHERE a = 1 and tststats.priv_test_tbl.* > (1, 1) is not null; -- Attempt to gain access using a leaky operator CREATE FUNCTION op_leak(int, int) RETURNS bool AS 'BEGIN RAISE NOTICE ''op_leak => %, %'', $1, $2; RETURN $1 < $2; END' LANGUAGE plpgsql; CREATE OPERATOR <<< (procedure = op_leak, leftarg = int, rightarg = int, restrict = scalarltsel); SELECT * FROM tststats.priv_test_tbl WHERE a <<< 0 AND b <<< 0; -- Permission denied DELETE FROM tststats.priv_test_tbl WHERE a <<< 0 AND b <<< 0; -- Permission denied -- Grant access via a security barrier view, but hide all data RESET SESSION AUTHORIZATION; CREATE VIEW tststats.priv_test_view WITH (security_barrier=true) AS SELECT * FROM tststats.priv_test_tbl WHERE false; GRANT SELECT, DELETE ON tststats.priv_test_view TO regress_stats_user1; -- Should now have access via the view, but see nothing and leak nothing SET SESSION AUTHORIZATION regress_stats_user1; SELECT * FROM tststats.priv_test_view WHERE a <<< 0 AND b <<< 0; -- Should not leak DELETE FROM tststats.priv_test_view WHERE a <<< 0 AND b <<< 0; -- Should not leak -- Grant table access, but hide all data with RLS RESET SESSION AUTHORIZATION; ALTER TABLE tststats.priv_test_tbl ENABLE ROW LEVEL SECURITY; GRANT SELECT, DELETE ON tststats.priv_test_tbl TO regress_stats_user1; -- Should now have direct table access, but see nothing and leak nothing SET SESSION AUTHORIZATION regress_stats_user1; SELECT * FROM tststats.priv_test_tbl WHERE a <<< 0 AND b <<< 0; -- Should not leak DELETE FROM tststats.priv_test_tbl WHERE a <<< 0 AND b <<< 0; -- Should not leak -- privilege checks for pg_stats_ext and pg_stats_ext_exprs RESET SESSION AUTHORIZATION; CREATE TABLE stats_ext_tbl (id INT PRIMARY KEY GENERATED BY DEFAULT AS IDENTITY, col TEXT); INSERT INTO stats_ext_tbl (col) VALUES ('secret'), ('secret'), ('very secret'); CREATE STATISTICS s_col ON id, col FROM stats_ext_tbl; CREATE STATISTICS s_expr ON mod(id, 2), lower(col) FROM stats_ext_tbl; ANALYZE stats_ext_tbl; -- unprivileged role should not have access SET SESSION AUTHORIZATION regress_stats_user1; SELECT statistics_name, most_common_vals FROM pg_stats_ext x WHERE tablename = 'stats_ext_tbl' ORDER BY ROW(x.*); SELECT statistics_name, most_common_vals FROM pg_stats_ext_exprs x WHERE tablename = 'stats_ext_tbl' ORDER BY ROW(x.*); -- give unprivileged role ownership of table RESET SESSION AUTHORIZATION; ALTER TABLE stats_ext_tbl OWNER TO regress_stats_user1; -- unprivileged role should now have access SET SESSION AUTHORIZATION regress_stats_user1; SELECT statistics_name, most_common_vals FROM pg_stats_ext x WHERE tablename = 'stats_ext_tbl' ORDER BY ROW(x.*); SELECT statistics_name, most_common_vals FROM pg_stats_ext_exprs x WHERE tablename = 'stats_ext_tbl' ORDER BY ROW(x.*); -- Tidy up DROP OPERATOR <<< (int, int); DROP FUNCTION op_leak(int, int); RESET SESSION AUTHORIZATION; DROP TABLE stats_ext_tbl; DROP SCHEMA tststats CASCADE; DROP USER regress_stats_user1;