0
0
mirror of https://github.com/tursodatabase/libsql.git synced 2024-11-23 12:06:16 +00:00
libsql/libsql-sqlite3/test/where3.test
Pekka Enberg 9ed72eb5ae Merge upstream SQLite 3.45.1
This merges the version-3.45.1 tag from upstream SQLite git repository
to libSQL with the following conflicts resolved:

Conflicts:
      README.md
      ext/jni/src/org/sqlite/jni/capi/ConfigSqllogCallback.java
      libsql-sqlite3/configure
      libsql-sqlite3/doc/jsonb.md
      libsql-sqlite3/ext/fts5/test/fts5faultH.test
      libsql-sqlite3/ext/fts5/test/fts5origintext.test
      libsql-sqlite3/ext/fts5/test/fts5origintext2.test
      libsql-sqlite3/ext/fts5/test/fts5origintext3.test
      libsql-sqlite3/ext/fts5/test/fts5origintext4.test
      libsql-sqlite3/ext/fts5/test/fts5origintext5.test
      libsql-sqlite3/ext/fts5/test/fts5secure8.test
      libsql-sqlite3/ext/fts5/test/fts5tokenizer2.test
      libsql-sqlite3/ext/fts5/test/fts5trigram2.test
      libsql-sqlite3/ext/jni/src/org/sqlite/jni/annotation/Experimental.java
      libsql-sqlite3/ext/jni/src/org/sqlite/jni/capi/ConfigSqlLogCallback.java
      libsql-sqlite3/ext/jni/src/org/sqlite/jni/capi/ConfigSqllogCallback.java
      libsql-sqlite3/ext/jni/src/org/sqlite/jni/wrapper1/WindowFunction.java
      libsql-sqlite3/ext/wasm/GNUmakefile
      libsql-sqlite3/ext/wasm/batch-runner-sahpool.html
      libsql-sqlite3/ext/wasm/batch-runner-sahpool.js
      libsql-sqlite3/src/pager.c
      libsql-sqlite3/src/shell.c.in
      libsql-sqlite3/src/sqliteInt.h
      libsql-sqlite3/src/wal.c
      libsql-sqlite3/test/fts3integrity.test
      libsql-sqlite3/test/json/jsonb-q1.txt
      libsql-sqlite3/test/json106.test
      libsql-sqlite3/test/json107.test
      libsql-sqlite3/test/jsonb01.test
      libsql-sqlite3/test/mmapcorrupt.test
      libsql-sqlite3/test/releasetest_data.tcl
      libsql-sqlite3/test/shell9.test
      libsql-sqlite3/test/wapp.tcl
      libsql-sqlite3/test/wapptest.tcl
2024-07-25 13:45:06 +03:00

519 lines
16 KiB
Plaintext

# 2006 January 31
#
# The author disclaims copyright to this source code. In place of
# a legal notice, here is a blessing:
#
# May you do good and not evil.
# May you find forgiveness for yourself and forgive others.
# May you share freely, never taking more than you give.
#
#***********************************************************************
# This file implements regression tests for SQLite library. The
# focus of this file is testing the join reordering optimization
# in cases that include a LEFT JOIN.
#
# $Id: where3.test,v 1.4 2008/04/17 19:14:02 drh Exp $
set testdir [file dirname $argv0]
source $testdir/tester.tcl
# The following is from ticket #1652.
#
# A comma join then a left outer join: A,B left join C.
# Arrange indices so that the B table is chosen to go first.
# Also put an index on C, but make sure that A is chosen before C.
#
do_test where3-1.1 {
execsql {
CREATE TABLE t1(a, b);
CREATE TABLE t2(p, q);
CREATE TABLE t3(x, y);
INSERT INTO t1 VALUES(111,'one');
INSERT INTO t1 VALUES(222,'two');
INSERT INTO t1 VALUES(333,'three');
INSERT INTO t2 VALUES(1,111);
INSERT INTO t2 VALUES(2,222);
INSERT INTO t2 VALUES(4,444);
CREATE INDEX t2i1 ON t2(p);
INSERT INTO t3 VALUES(999,'nine');
CREATE INDEX t3i1 ON t3(x);
SELECT * FROM t1, t2 LEFT JOIN t3 ON q=x WHERE p=2 AND a=q;
}
} {222 two 2 222 {} {}}
ifcapable explain&&!cursorhints {
do_test where3-1.1.1 {
explain_no_trace {SELECT * FROM t1, t2 LEFT JOIN t3 ON q=x
WHERE p=2 AND a=q}
} [explain_no_trace {SELECT * FROM t1, t2 LEFT JOIN t3 ON x=q
WHERE p=2 AND a=q}]
}
# Ticket #1830
#
# This is similar to the above but with the LEFT JOIN on the
# other side.
#
do_test where3-1.2 {
execsql {
CREATE TABLE parent1(parent1key, child1key, Child2key, child3key);
CREATE TABLE child1 ( child1key NVARCHAR, value NVARCHAR );
CREATE UNIQUE INDEX PKIDXChild1 ON child1 ( child1key );
CREATE TABLE child2 ( child2key NVARCHAR, value NVARCHAR );
INSERT INTO parent1(parent1key,child1key,child2key)
VALUES ( 1, 'C1.1', 'C2.1' );
INSERT INTO child1 ( child1key, value ) VALUES ( 'C1.1', 'Value for C1.1' );
INSERT INTO child2 ( child2key, value ) VALUES ( 'C2.1', 'Value for C2.1' );
INSERT INTO parent1 ( parent1key, child1key, child2key )
VALUES ( 2, 'C1.2', 'C2.2' );
INSERT INTO child2 ( child2key, value ) VALUES ( 'C2.2', 'Value for C2.2' );
INSERT INTO parent1 ( parent1key, child1key, child2key )
VALUES ( 3, 'C1.3', 'C2.3' );
INSERT INTO child1 ( child1key, value ) VALUES ( 'C1.3', 'Value for C1.3' );
INSERT INTO child2 ( child2key, value ) VALUES ( 'C2.3', 'Value for C2.3' );
SELECT parent1.parent1key, child1.value, child2.value
FROM parent1
LEFT OUTER JOIN child1 ON child1.child1key = parent1.child1key
INNER JOIN child2 ON child2.child2key = parent1.child2key;
}
} {1 {Value for C1.1} {Value for C2.1} 2 {} {Value for C2.2} 3 {Value for C1.3} {Value for C2.3}}
ifcapable explain&&!cursorhints {
do_test where3-1.2.1 {
explain_no_trace {
SELECT parent1.parent1key, child1.value, child2.value
FROM parent1
LEFT OUTER JOIN child1 ON child1.child1key = parent1.child1key
INNER JOIN child2 ON child2.child2key = parent1.child2key;
}
} [explain_no_trace {
SELECT parent1.parent1key, child1.value, child2.value
FROM parent1
LEFT OUTER JOIN child1 ON parent1.child1key = child1.child1key
INNER JOIN child2 ON child2.child2key = parent1.child2key;
}]
}
# This procedure executes the SQL. Then it appends
# the names of the table and index used
#
proc queryplan {sql} {
set ::sqlite_sort_count 0
set data [execsql $sql]
set eqp [execsql "EXPLAIN QUERY PLAN $sql"]
# puts eqp=$eqp
foreach {a b c x} $eqp {
if {[regexp {SCAN CONSTANT} $x]} {
# noop
} elseif {[regexp {(SCAN|SEARCH) (\w+ AS )?(\w+) USING.* INDEX (\w+)\y} \
$x all ss as tab idx]} {
lappend data $tab $idx
} elseif {[regexp {(SCAN|SEARCH) (\w+ AS )?(\w+)\y} $x all ss as tab]} {
lappend data $tab *
}
}
return $data
}
# If you have a from clause of the form: A B C left join D
# then make sure the query optimizer is able to reorder the
# A B C part anyway it wants.
#
# Following the fix to ticket #1652, there was a time when
# the C table would not reorder. So the following reorderings
# were possible:
#
# A B C left join D
# B A C left join D
#
# But these reorders were not allowed
#
# C A B left join D
# A C B left join D
# C B A left join D
# B C A left join D
#
# The following tests are here to verify that the latter four
# reorderings are allowed again.
#
do_test where3-2.1 {
execsql {
CREATE TABLE tA(apk integer primary key, ax);
CREATE TABLE tB(bpk integer primary key, bx);
CREATE TABLE tC(cpk integer primary key, cx);
CREATE TABLE tD(dpk integer primary key, dx);
}
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE cpk=bx AND bpk=ax
}
} {tA * tB * tC * tD *}
do_test where3-2.1.1 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON cx=dpk
WHERE cpk=bx AND bpk=ax
}
} {tA * tB * tC * tD *}
do_test where3-2.1.2 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON cx=dpk
WHERE bx=cpk AND bpk=ax
}
} {tA * tB * tC * tD *}
do_test where3-2.1.3 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON cx=dpk
WHERE bx=cpk AND ax=bpk
}
} {tA * tB * tC * tD *}
do_test where3-2.1.4 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE bx=cpk AND ax=bpk
}
} {tA * tB * tC * tD *}
do_test where3-2.1.5 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE cpk=bx AND ax=bpk
}
} {tA * tB * tC * tD *}
do_test where3-2.2 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE cpk=bx AND apk=bx
}
} {tB * tA * tC * tD *}
do_test where3-2.3 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE cpk=bx AND apk=bx
}
} {tB * tA * tC * tD *}
do_test where3-2.4 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE apk=cx AND bpk=ax
}
} {tC * tA * tB * tD *}
do_test where3-2.5 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE cpk=ax AND bpk=cx
}
} {tA * tC * tB * tD *}
do_test where3-2.6 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE bpk=cx AND apk=bx
}
} {tC * tB * tA * tD *}
do_test where3-2.7 {
queryplan {
SELECT * FROM tA, tB, tC LEFT JOIN tD ON dpk=cx
WHERE cpk=bx AND apk=cx
}
} {tB * tC * tA * tD *}
# Ticket [13f033c865f878953]
# If the outer loop must be a full table scan, do not let ANALYZE trick
# the planner into use a table for the outer loop that might be indexable
# if held until an inner loop.
#
do_execsql_test where3-3.0 {
CREATE TABLE t301(a INTEGER PRIMARY KEY,b,c);
CREATE INDEX t301c ON t301(c);
INSERT INTO t301 VALUES(1,2,3);
INSERT INTO t301 VALUES(2,2,3);
CREATE TABLE t302(x, y);
INSERT INTO t302 VALUES(4,5);
ANALYZE;
}
do_eqp_test where3-3.0a {
SELECT * FROM t302, t301 WHERE t302.x=5 AND t301.a=t302.y;
} {
QUERY PLAN
|--SCAN t302
`--SEARCH t301 USING INTEGER PRIMARY KEY (rowid=?)
}
do_eqp_test where3-3.1 {
SELECT * FROM t301, t302 WHERE t302.x=5 AND t301.a=t302.y;
} {
QUERY PLAN
|--SCAN t302
`--SEARCH t301 USING INTEGER PRIMARY KEY (rowid=?)
}
do_execsql_test where3-3.2 {
SELECT * FROM t301 WHERE c=3 AND a IS NULL;
} {}
do_execsql_test where3-3.3 {
SELECT * FROM t301 WHERE c=3 AND a IS NOT NULL;
} {1 2 3 2 2 3}
if 0 { # Query planner no longer does this
# Verify that when there are multiple tables in a join which must be
# full table scans that the query planner attempts put the table with
# the fewest number of output rows as the outer loop.
#
do_execsql_test where3-4.0 {
CREATE TABLE t400(a INTEGER PRIMARY KEY, b, c);
CREATE TABLE t401(p INTEGER PRIMARY KEY, q, r);
CREATE TABLE t402(x INTEGER PRIMARY KEY, y, z);
EXPLAIN QUERY PLAN
SELECT * FROM t400, t401, t402 WHERE t402.z GLOB 'abc*';
} {
0 0 2 {SCAN t402}
0 1 0 {SCAN t400}
0 2 1 {SCAN t401}
}
do_execsql_test where3-4.1 {
EXPLAIN QUERY PLAN
SELECT * FROM t400, t401, t402 WHERE t401.r GLOB 'abc*';
} {
0 0 1 {SCAN t401}
0 1 0 {SCAN t400}
0 2 2 {SCAN t402}
}
do_execsql_test where3-4.2 {
EXPLAIN QUERY PLAN
SELECT * FROM t400, t401, t402 WHERE t400.c GLOB 'abc*';
} {
0 0 0 {SCAN t400}
0 1 1 {SCAN t401}
0 2 2 {SCAN t402}
}
} ;# endif
# Verify that a performance regression encountered by firefox
# has been fixed.
#
do_execsql_test where3-5.0 {
CREATE TABLE aaa (id INTEGER PRIMARY KEY, type INTEGER,
fk INTEGER DEFAULT NULL, parent INTEGER,
position INTEGER, title LONGVARCHAR,
keyword_id INTEGER, folder_type TEXT,
dateAdded INTEGER, lastModified INTEGER);
CREATE INDEX aaa_111 ON aaa (fk, type);
CREATE INDEX aaa_222 ON aaa (parent, position);
CREATE INDEX aaa_333 ON aaa (fk, lastModified);
CREATE TABLE bbb (id INTEGER PRIMARY KEY, type INTEGER,
fk INTEGER DEFAULT NULL, parent INTEGER,
position INTEGER, title LONGVARCHAR,
keyword_id INTEGER, folder_type TEXT,
dateAdded INTEGER, lastModified INTEGER);
CREATE INDEX bbb_111 ON bbb (fk, type);
CREATE INDEX bbb_222 ON bbb (parent, position);
CREATE INDEX bbb_333 ON bbb (fk, lastModified);
}
do_eqp_test where3-5.0a {
SELECT bbb.title AS tag_title
FROM aaa JOIN bbb ON bbb.id = aaa.parent
WHERE aaa.fk = 'constant'
AND LENGTH(bbb.title) > 0
AND bbb.parent = 4
ORDER BY bbb.title COLLATE NOCASE ASC;
} {
QUERY PLAN
|--SEARCH aaa USING INDEX aaa_333 (fk=?)
|--SEARCH bbb USING INTEGER PRIMARY KEY (rowid=?)
`--USE TEMP B-TREE FOR ORDER BY
}
do_eqp_test where3-5.1 {
SELECT bbb.title AS tag_title
FROM aaa JOIN aaa AS bbb ON bbb.id = aaa.parent
WHERE aaa.fk = 'constant'
AND LENGTH(bbb.title) > 0
AND bbb.parent = 4
ORDER BY bbb.title COLLATE NOCASE ASC;
} {
QUERY PLAN
|--SEARCH aaa USING INDEX aaa_333 (fk=?)
|--SEARCH bbb USING INTEGER PRIMARY KEY (rowid=?)
`--USE TEMP B-TREE FOR ORDER BY
}
do_eqp_test where3-5.2 {
SELECT bbb.title AS tag_title
FROM bbb JOIN aaa ON bbb.id = aaa.parent
WHERE aaa.fk = 'constant'
AND LENGTH(bbb.title) > 0
AND bbb.parent = 4
ORDER BY bbb.title COLLATE NOCASE ASC;
} {
QUERY PLAN
|--SEARCH aaa USING INDEX aaa_333 (fk=?)
|--SEARCH bbb USING INTEGER PRIMARY KEY (rowid=?)
`--USE TEMP B-TREE FOR ORDER BY
}
do_eqp_test where3-5.3 {
SELECT bbb.title AS tag_title
FROM aaa AS bbb JOIN aaa ON bbb.id = aaa.parent
WHERE aaa.fk = 'constant'
AND LENGTH(bbb.title) > 0
AND bbb.parent = 4
ORDER BY bbb.title COLLATE NOCASE ASC;
} {
QUERY PLAN
|--SEARCH aaa USING INDEX aaa_333 (fk=?)
|--SEARCH bbb USING INTEGER PRIMARY KEY (rowid=?)
`--USE TEMP B-TREE FOR ORDER BY
}
# Name resolution with NATURAL JOIN and USING
#
do_test where3-6.setup {
db eval {
CREATE TABLE t6w(a, w);
INSERT INTO t6w VALUES(1, 'w-one');
INSERT INTO t6w VALUES(2, 'w-two');
INSERT INTO t6w VALUES(9, 'w-nine');
CREATE TABLE t6x(a, x);
INSERT INTO t6x VALUES(1, 'x-one');
INSERT INTO t6x VALUES(3, 'x-three');
INSERT INTO t6x VALUES(9, 'x-nine');
CREATE TABLE t6y(a, y);
INSERT INTO t6y VALUES(1, 'y-one');
INSERT INTO t6y VALUES(4, 'y-four');
INSERT INTO t6y VALUES(9, 'y-nine');
CREATE TABLE t6z(a, z);
INSERT INTO t6z VALUES(1, 'z-one');
INSERT INTO t6z VALUES(5, 'z-five');
INSERT INTO t6z VALUES(9, 'z-nine');
}
} {}
set cnt 0
foreach predicate {
{}
{ORDER BY a}
{ORDER BY t6w.a}
{WHERE a>0}
{WHERE t6y.a>0}
{WHERE a>0 ORDER BY a}
} {
incr cnt
do_test where3-6.$cnt.1 {
set sql "SELECT * FROM t6w NATURAL JOIN t6x NATURAL JOIN t6y"
append sql " NATURAL JOIN t6z "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
do_test where3-6.$cnt.2 {
set sql "SELECT * FROM t6w JOIN t6x USING(a) JOIN t6y USING(a)"
append sql " JOIN t6z USING(a) "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
do_test where3-6.$cnt.3 {
set sql "SELECT * FROM t6w NATURAL JOIN t6x JOIN t6y USING(a)"
append sql " JOIN t6z USING(a) "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
do_test where3-6.$cnt.4 {
set sql "SELECT * FROM t6w JOIN t6x USING(a) NATURAL JOIN t6y"
append sql " JOIN t6z USING(a) "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
do_test where3-6.$cnt.5 {
set sql "SELECT * FROM t6w JOIN t6x USING(a) JOIN t6y USING(a)"
append sql " NATURAL JOIN t6z "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
do_test where3-6.$cnt.6 {
set sql "SELECT * FROM t6w JOIN t6x USING(a) NATURAL JOIN t6y"
append sql " NATURAL JOIN t6z "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
do_test where3-6.$cnt.7 {
set sql "SELECT * FROM t6w NATURAL JOIN t6x JOIN t6y USING(a)"
append sql " NATURAL JOIN t6z "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
do_test where3-6.$cnt.8 {
set sql "SELECT * FROM t6w NATURAL JOIN t6x NATURAL JOIN t6y"
append sql " JOIN t6z USING(a) "
append sql $::predicate
db eval $sql
} {1 w-one x-one y-one z-one 9 w-nine x-nine y-nine z-nine}
}
do_execsql_test where3-7-setup {
CREATE TABLE t71(x1 INTEGER PRIMARY KEY, y1);
CREATE TABLE t72(x2 INTEGER PRIMARY KEY, y2);
CREATE TABLE t73(x3, y3);
CREATE TABLE t74(x4, y4);
INSERT INTO t71 VALUES(123,234);
INSERT INTO t72 VALUES(234,345);
INSERT INTO t73 VALUES(123,234);
INSERT INTO t74 VALUES(234,345);
INSERT INTO t74 VALUES(234,678);
} {}
foreach disabled_opt {none omit-noop-join all} {
optimization_control db all 1
optimization_control db $disabled_opt 0
do_execsql_test where3-7.$disabled_opt.1 {
SELECT x1 FROM t71 LEFT JOIN t72 ON x2=y1;
} {123}
do_execsql_test where3-7.$disabled_opt.2 {
SELECT x1 FROM t71 LEFT JOIN t72 ON x2=y1 WHERE y2 IS NULL;
} {}
do_execsql_test where3-7.$disabled_opt.3 {
SELECT x1 FROM t71 LEFT JOIN t72 ON x2=y1 WHERE y2 IS NOT NULL;
} {123}
do_execsql_test where3-7.$disabled_opt.4 {
SELECT x1 FROM t71 LEFT JOIN t72 ON x2=y1 AND y2 IS NULL;
} {123}
do_execsql_test where3-7.$disabled_opt.5 {
SELECT x1 FROM t71 LEFT JOIN t72 ON x2=y1 AND y2 IS NOT NULL;
} {123}
do_execsql_test where3-7.$disabled_opt.6 {
SELECT x3 FROM t73 LEFT JOIN t72 ON x2=y3;
} {123}
do_execsql_test where3-7.$disabled_opt.7 {
SELECT DISTINCT x3 FROM t73 LEFT JOIN t72 ON x2=y3;
} {123}
do_execsql_test where3-7.$disabled_opt.8 {
SELECT x3 FROM t73 LEFT JOIN t74 ON x4=y3;
} {123 123}
do_execsql_test where3-7.$disabled_opt.9 {
SELECT DISTINCT x3 FROM t73 LEFT JOIN t74 ON x4=y3;
} {123}
}
# 2023-12-23
# https://sqlite.org/forum/forumpost/2568d1f6e6
#
# Index usage should be "x=? and y=?" - equality on both values.
# Not: "x=? AND y>?" - inequality on "y"
#
reset_db
do_execsql_test where3-8.1 {
CREATE TABLE t1(a,b,c,d); INSERT INTO t1 VALUES(1,2,3,4);
CREATE TABLE t2(x,y); INSERT INTO t2 VALUES(3,4);
CREATE INDEX t2xy ON t2(x,y);
SELECT 1 FROM t1 JOIN t2 ON x=c AND y=d WHERE d>0;
} 1
do_eqp_test where3-8.2 {
SELECT 1 FROM t1 JOIN t2 ON x=c AND y=d WHERE d>0;
} {
QUERY PLAN
|--SCAN t1
`--SEARCH t2 USING COVERING INDEX t2xy (x=? AND y=?)
}
finish_test