third_party/sqlite/src/test/subquery.test - cobalt - Git at Google

 # 2005 January 19
 #
 # 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 script is testing correlated subqueries
 #
 # $Id: subquery.test,v 1.17 2009/01/09 01:12:28 drh Exp $
 #

 set testdir [file dirname $argv0]
 source $testdir/tester.tcl

 ifcapable !subquery {
   finish_test
   return
 }

 do_test subquery-1.1 {
   execsql {
     BEGIN;
     CREATE TABLE t1(a,b);
     INSERT INTO t1 VALUES(1,2);
     INSERT INTO t1 VALUES(3,4);
     INSERT INTO t1 VALUES(5,6);
     INSERT INTO t1 VALUES(7,8);
     CREATE TABLE t2(x,y);
     INSERT INTO t2 VALUES(1,1);
     INSERT INTO t2 VALUES(3,9);
     INSERT INTO t2 VALUES(5,25);
     INSERT INTO t2 VALUES(7,49);
     COMMIT;
   }
   execsql {
     SELECT a, (SELECT y FROM t2 WHERE x=a) FROM t1 WHERE b<8
   }
 } {1 1 3 9 5 25}
 do_test subquery-1.2 {
   execsql {
     UPDATE t1 SET b=b+(SELECT y FROM t2 WHERE x=a);
     SELECT * FROM t1;
   }
 } {1 3 3 13 5 31 7 57}

 do_test subquery-1.3 {
   execsql {
     SELECT b FROM t1 WHERE EXISTS(SELECT * FROM t2 WHERE y=a)
   }
 } {3}
 do_test subquery-1.4 {
   execsql {
     SELECT b FROM t1 WHERE NOT EXISTS(SELECT * FROM t2 WHERE y=a)
   }
 } {13 31 57}

 # Simple tests to make sure correlated subqueries in WHERE clauses
 # are used by the query optimizer correctly.
 do_test subquery-1.5 {
   execsql {
     SELECT a, x FROM t1, t2 WHERE t1.a = (SELECT x);
   }
 } {1 1 3 3 5 5 7 7}
 do_test subquery-1.6 {
   execsql {
     CREATE INDEX i1 ON t1(a);
     SELECT a, x FROM t1, t2 WHERE t1.a = (SELECT x);
   }
 } {1 1 3 3 5 5 7 7}
 do_test subquery-1.7 {
   execsql {
     SELECT a, x FROM t2, t1 WHERE t1.a = (SELECT x);
   }
 } {1 1 3 3 5 5 7 7}

 # Try an aggregate in both the subquery and the parent query.
 do_test subquery-1.8 {
   execsql {
     SELECT count(*) FROM t1 WHERE a > (SELECT count(*) FROM t2);
   }
 } {2}

 # Test a correlated subquery disables the "only open the index" optimization.
 do_test subquery-1.9.1 {
   execsql {
     SELECT (y*2)>b FROM t1, t2 WHERE a=x;
   }
 } {0 1 1 1}
 do_test subquery-1.9.2 {
   execsql {
     SELECT a FROM t1 WHERE (SELECT (y*2)>b FROM t2 WHERE a=x);
   }
 } {3 5 7}

 # Test that the flattening optimization works with subquery expressions.
 do_test subquery-1.10.1 {
   execsql {
     SELECT (SELECT a), b FROM t1;
   }
 } {1 3 3 13 5 31 7 57}
 do_test subquery-1.10.2 {
   execsql {
     SELECT * FROM (SELECT (SELECT a), b FROM t1);
   }
 } {1 3 3 13 5 31 7 57}
 do_test subquery-1.10.3 {
   execsql {
     SELECT * FROM (SELECT (SELECT sum(a) FROM t1));
   }
 } {16}
 do_test subquery-1.10.4 {
   execsql {
     CREATE TABLE t5 (val int, period text PRIMARY KEY);
     INSERT INTO t5 VALUES(5, '2001-3');
     INSERT INTO t5 VALUES(10, '2001-4');
     INSERT INTO t5 VALUES(15, '2002-1');
     INSERT INTO t5 VALUES(5, '2002-2');
     INSERT INTO t5 VALUES(10, '2002-3');
     INSERT INTO t5 VALUES(15, '2002-4');
     INSERT INTO t5 VALUES(10, '2003-1');
     INSERT INTO t5 VALUES(5, '2003-2');
     INSERT INTO t5 VALUES(25, '2003-3');
     INSERT INTO t5 VALUES(5, '2003-4');

     SELECT period, vsum
     FROM (SELECT
       a.period,
       (select sum(val) from t5 where period between a.period and '2002-4') vsum
       FROM t5 a where a.period between '2002-1' and '2002-4')
     WHERE vsum < 45 ;
   }
 } {2002-2 30 2002-3 25 2002-4 15}
 do_test subquery-1.10.5 {
   execsql {
     SELECT period, vsum from
       (select a.period,
       (select sum(val) from t5 where period between a.period and '2002-4') vsum
     FROM t5 a where a.period between '2002-1' and '2002-4')
     WHERE vsum < 45 ;
   }
 } {2002-2 30 2002-3 25 2002-4 15}
 do_test subquery-1.10.6 {
   execsql {
     DROP TABLE t5;
   }
 } {}


 #------------------------------------------------------------------
 # The following test cases - subquery-2.* - are not logically
 # organized. They're here largely because they were failing during
 # one stage of development of sub-queries.
 #
 do_test subquery-2.1 {
   execsql {
     SELECT (SELECT 10);
   }
 } {10}
 do_test subquery-2.2.1 {
   execsql {
     CREATE TABLE t3(a PRIMARY KEY, b);
     INSERT INTO t3 VALUES(1, 2);
     INSERT INTO t3 VALUES(3, 1);
   }
 } {}
 do_test subquery-2.2.2 {
   execsql {
     SELECT * FROM t3 WHERE a IN (SELECT b FROM t3);
   }
 } {1 2}
 do_test subquery-2.2.3 {
   execsql {
     DROP TABLE t3;
   }
 } {}
 do_test subquery-2.3.1 {
   execsql {
     CREATE TABLE t3(a TEXT);
     INSERT INTO t3 VALUES('10');
   }
 } {}
 do_test subquery-2.3.2 {
   execsql {
     SELECT a IN (10.0, 20) FROM t3;
   }
 } {0}
 do_test subquery-2.3.3 {
   execsql {
     DROP TABLE t3;
   }
 } {}
 do_test subquery-2.4.1 {
   execsql {
     CREATE TABLE t3(a TEXT);
     INSERT INTO t3 VALUES('XX');
   }
 } {}
 do_test subquery-2.4.2 {
   execsql {
     SELECT count(*) FROM t3 WHERE a IN (SELECT 'XX')
   }
 } {1}
 do_test subquery-2.4.3 {
   execsql {
     DROP TABLE t3;
   }
 } {}
 do_test subquery-2.5.1 {
   execsql {
     CREATE TABLE t3(a INTEGER);
     INSERT INTO t3 VALUES(10);

     CREATE TABLE t4(x TEXT);
     INSERT INTO t4 VALUES('10.0');
   }
 } {}
 do_test subquery-2.5.2 {
   # In the expr "x IN (SELECT a FROM t3)" the RHS of the IN operator
   # has text affinity and the LHS has integer affinity.  The rule is
   # that we try to convert both sides to an integer before doing the
   # comparision.  Hence, the integer value 10 in t3 will compare equal
   # to the string value '10.0' in t4 because the t4 value will be
   # converted into an integer.
   execsql {
     SELECT * FROM t4 WHERE x IN (SELECT a FROM t3);
   }
 } {10.0}
 do_test subquery-2.5.3.1 {
   # The t4i index cannot be used to resolve the "x IN (...)" constraint
   # because the constraint has integer affinity but t4i has text affinity.
   execsql {
     CREATE INDEX t4i ON t4(x);
     SELECT * FROM t4 WHERE x IN (SELECT a FROM t3);
   }
 } {10.0}
 do_test subquery-2.5.3.2 {
   # Verify that the t4i index was not used in the previous query
   set ::sqlite_query_plan
 } {t4 {}}
 do_test subquery-2.5.4 {
   execsql {
     DROP TABLE t3;
     DROP TABLE t4;
   }
 } {}

 #------------------------------------------------------------------
 # The following test cases - subquery-3.* - test tickets that
 # were raised during development of correlated subqueries.
 #

 # Ticket 1083
 ifcapable view {
   do_test subquery-3.1 {
     catchsql { DROP TABLE t1; }
     catchsql { DROP TABLE t2; }
     execsql {
       CREATE TABLE t1(a,b);
       INSERT INTO t1 VALUES(1,2);
       CREATE VIEW v1 AS SELECT b FROM t1 WHERE a>0;
       CREATE TABLE t2(p,q);
       INSERT INTO t2 VALUES(2,9);
       SELECT * FROM v1 WHERE EXISTS(SELECT * FROM t2 WHERE p=v1.b);
     }
   } {2}
   do_test subquery-3.1.1 {
     execsql {
       SELECT * FROM v1 WHERE EXISTS(SELECT 1);
     }
   } {2}
 } else {
   catchsql { DROP TABLE t1; }
   catchsql { DROP TABLE t2; }
   execsql {
     CREATE TABLE t1(a,b);
     INSERT INTO t1 VALUES(1,2);
     CREATE TABLE t2(p,q);
     INSERT INTO t2 VALUES(2,9);
   }
 }

 # Ticket 1084
 do_test subquery-3.2 {
   catchsql {
     CREATE TABLE t1(a,b);
     INSERT INTO t1 VALUES(1,2);
   }
   execsql {
     SELECT (SELECT t1.a) FROM t1;
   }
 } {1}

 # Test Cases subquery-3.3.* test correlated subqueries where the
 # parent query is an aggregate query. Ticket #1105 is an example
 # of such a query.
 #
 do_test subquery-3.3.1 {
   execsql {
     SELECT a, (SELECT b) FROM t1 GROUP BY a;
   }
 } {1 2}
 do_test subquery-3.3.2 {
   catchsql {DROP TABLE t2}
   execsql {
     CREATE TABLE t2(c, d);
     INSERT INTO t2 VALUES(1, 'one');
     INSERT INTO t2 VALUES(2, 'two');
     SELECT a, (SELECT d FROM t2 WHERE a=c) FROM t1 GROUP BY a;
   }
 } {1 one}
 do_test subquery-3.3.3 {
   execsql {
     INSERT INTO t1 VALUES(2, 4);
     SELECT max(a), (SELECT d FROM t2 WHERE a=c) FROM t1;
   }
 } {2 two}
 do_test subquery-3.3.4 {
   execsql {
     SELECT a, (SELECT (SELECT d FROM t2 WHERE a=c)) FROM t1 GROUP BY a;
   }
 } {1 one 2 two}
 do_test subquery-3.3.5 {
   execsql {
     SELECT a, (SELECT count(*) FROM t2 WHERE a=c) FROM t1;
   }
 } {1 1 2 1}

 #------------------------------------------------------------------
 # These tests - subquery-4.* - use the TCL statement cache to try
 # and expose bugs to do with re-using statements that have been
 # passed to sqlite3_reset().
 #
 # One problem was that VDBE memory cells were not being initialised
 # to NULL on the second and subsequent executions.
 #
 do_test subquery-4.1.1 {
   execsql {
     SELECT (SELECT a FROM t1);
   }
 } {1}
 do_test subquery-4.2 {
   execsql {
     DELETE FROM t1;
     SELECT (SELECT a FROM t1);
   }
 } {{}}
 do_test subquery-4.2.1 {
   execsql {
     CREATE TABLE t3(a PRIMARY KEY);
     INSERT INTO t3 VALUES(10);
   }
   execsql {INSERT INTO t3 VALUES((SELECT max(a) FROM t3)+1)}
 } {}
 do_test subquery-4.2.2 {
   execsql {INSERT INTO t3 VALUES((SELECT max(a) FROM t3)+1)}
 } {}

 #------------------------------------------------------------------
 # The subquery-5.* tests make sure string literals in double-quotes
 # are handled efficiently.  Double-quote literals are first checked
 # to see if they match any column names.  If there is not column name
 # match then those literals are used a string constants.  When a
 # double-quoted string appears, we want to make sure that the search
 # for a matching column name did not cause an otherwise static subquery
 # to become a dynamic (correlated) subquery.
 #
 do_test subquery-5.1 {
   proc callcntproc {n} {
     incr ::callcnt
     return $n
   }
   set callcnt 0
   db function callcnt callcntproc
   execsql {
     CREATE TABLE t4(x,y);
     INSERT INTO t4 VALUES('one',1);
     INSERT INTO t4 VALUES('two',2);
     INSERT INTO t4 VALUES('three',3);
     INSERT INTO t4 VALUES('four',4);
     CREATE TABLE t5(a,b);
     INSERT INTO t5 VALUES(1,11);
     INSERT INTO t5 VALUES(2,22);
     INSERT INTO t5 VALUES(3,33);
     INSERT INTO t5 VALUES(4,44);
     SELECT b FROM t5 WHERE a IN
        (SELECT callcnt(y)+0 FROM t4 WHERE x="two")
   }
 } {22}
 do_test subquery-5.2 {
   # This is the key test.  The subquery should have only run once.  If
   # The double-quoted identifier "two" were causing the subquery to be
   # processed as a correlated subquery, then it would have run 4 times.
   set callcnt
 } {1}


 # Ticket #1380.  Make sure correlated subqueries on an IN clause work
 # correctly when the left-hand side of the IN operator is constant.
 #
 do_test subquery-6.1 {
   set callcnt 0
   execsql {
     SELECT x FROM t4 WHERE 1 IN (SELECT callcnt(count(*)) FROM t5 WHERE a=y)
   }
 } {one two three four}
 do_test subquery-6.2 {
   set callcnt
 } {4}
 do_test subquery-6.3 {
   set callcnt 0
   execsql {
     SELECT x FROM t4 WHERE 1 IN (SELECT callcnt(count(*)) FROM t5 WHERE a=1)
   }
 } {one two three four}
 do_test subquery-6.4 {
   set callcnt
 } {1}

 if 0 {   #############  disable until we get #2652 fixed
 # Ticket #2652.  Allow aggregate functions of outer queries inside
 # a non-aggregate subquery.
 #
 do_test subquery-7.1 {
   execsql {
     CREATE TABLE t7(c7);
     INSERT INTO t7 VALUES(1);
     INSERT INTO t7 VALUES(2);
     INSERT INTO t7 VALUES(3);
     CREATE TABLE t8(c8);
     INSERT INTO t8 VALUES(100);
     INSERT INTO t8 VALUES(200);
     INSERT INTO t8 VALUES(300);
     CREATE TABLE t9(c9);
     INSERT INTO t9 VALUES(10000);
     INSERT INTO t9 VALUES(20000);
     INSERT INTO t9 VALUES(30000);

     SELECT (SELECT c7+c8 FROM t7) FROM t8;
   }
 } {101 201 301}
 do_test subquery-7.2 {
   execsql {
     SELECT (SELECT max(c7)+c8 FROM t7) FROM t8;
   }
 } {103 203 303}
 do_test subquery-7.3 {
   execsql {
     SELECT (SELECT c7+max(c8) FROM t8) FROM t7
   }
 } {301}
 do_test subquery-7.4 {
   execsql {
     SELECT (SELECT max(c7)+max(c8) FROM t8) FROM t7
   }
 } {303}
 do_test subquery-7.5 {
   execsql {
     SELECT (SELECT c8 FROM t8 WHERE rowid=max(c7)) FROM t7
   }
 } {300}
 do_test subquery-7.6 {
   execsql {
     SELECT (SELECT (SELECT max(c7+c8+c9) FROM t9) FROM t8) FROM t7
   }
 } {30101 30102 30103}
 do_test subquery-7.7 {
   execsql {
     SELECT (SELECT (SELECT c7+max(c8+c9) FROM t9) FROM t8) FROM t7
   }
 } {30101 30102 30103}
 do_test subquery-7.8 {
   execsql {
     SELECT (SELECT (SELECT max(c7)+c8+c9 FROM t9) FROM t8) FROM t7
   }
 } {10103}
 do_test subquery-7.9 {
   execsql {
     SELECT (SELECT (SELECT c7+max(c8)+c9 FROM t9) FROM t8) FROM t7
   }
 } {10301 10302 10303}
 do_test subquery-7.10 {
   execsql {
     SELECT (SELECT (SELECT c7+c8+max(c9) FROM t9) FROM t8) FROM t7
   }
 } {30101 30102 30103}
 do_test subquery-7.11 {
   execsql {
     SELECT (SELECT (SELECT max(c7)+max(c8)+max(c9) FROM t9) FROM t8) FROM t7
   }
 } {30303}
 }  ;############# Disabled

 finish_test
	# 2005 January 19
	#
	# 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 script is testing correlated subqueries
	#
	# $Id: subquery.test,v 1.17 2009/01/09 01:12:28 drh Exp $
	#

	set testdir [file dirname $argv0]
	source $testdir/tester.tcl

	ifcapable !subquery {
	finish_test
	return
	}

	do_test subquery-1.1 {
	execsql {
	BEGIN;
	CREATE TABLE t1(a,b);
	INSERT INTO t1 VALUES(1,2);
	INSERT INTO t1 VALUES(3,4);
	INSERT INTO t1 VALUES(5,6);
	INSERT INTO t1 VALUES(7,8);
	CREATE TABLE t2(x,y);
	INSERT INTO t2 VALUES(1,1);
	INSERT INTO t2 VALUES(3,9);
	INSERT INTO t2 VALUES(5,25);
	INSERT INTO t2 VALUES(7,49);
	COMMIT;
	}
	execsql {
	SELECT a, (SELECT y FROM t2 WHERE x=a) FROM t1 WHERE b<8
	}
	} {1 1 3 9 5 25}
	do_test subquery-1.2 {
	execsql {
	UPDATE t1 SET b=b+(SELECT y FROM t2 WHERE x=a);
	SELECT * FROM t1;
	}
	} {1 3 3 13 5 31 7 57}

	do_test subquery-1.3 {
	execsql {
	SELECT b FROM t1 WHERE EXISTS(SELECT * FROM t2 WHERE y=a)
	}
	} {3}
	do_test subquery-1.4 {
	execsql {
	SELECT b FROM t1 WHERE NOT EXISTS(SELECT * FROM t2 WHERE y=a)
	}
	} {13 31 57}

	# Simple tests to make sure correlated subqueries in WHERE clauses
	# are used by the query optimizer correctly.
	do_test subquery-1.5 {
	execsql {
	SELECT a, x FROM t1, t2 WHERE t1.a = (SELECT x);
	}
	} {1 1 3 3 5 5 7 7}
	do_test subquery-1.6 {
	execsql {
	CREATE INDEX i1 ON t1(a);
	SELECT a, x FROM t1, t2 WHERE t1.a = (SELECT x);
	}
	} {1 1 3 3 5 5 7 7}
	do_test subquery-1.7 {
	execsql {
	SELECT a, x FROM t2, t1 WHERE t1.a = (SELECT x);
	}
	} {1 1 3 3 5 5 7 7}

	# Try an aggregate in both the subquery and the parent query.
	do_test subquery-1.8 {
	execsql {
	SELECT count() FROM t1 WHERE a > (SELECT count() FROM t2);
	}
	} {2}

	# Test a correlated subquery disables the "only open the index" optimization.
	do_test subquery-1.9.1 {
	execsql {
	SELECT (y*2)>b FROM t1, t2 WHERE a=x;
	}
	} {0 1 1 1}
	do_test subquery-1.9.2 {
	execsql {
	SELECT a FROM t1 WHERE (SELECT (y*2)>b FROM t2 WHERE a=x);
	}
	} {3 5 7}

	# Test that the flattening optimization works with subquery expressions.
	do_test subquery-1.10.1 {
	execsql {
	SELECT (SELECT a), b FROM t1;
	}
	} {1 3 3 13 5 31 7 57}
	do_test subquery-1.10.2 {
	execsql {
	SELECT * FROM (SELECT (SELECT a), b FROM t1);
	}
	} {1 3 3 13 5 31 7 57}
	do_test subquery-1.10.3 {
	execsql {
	SELECT * FROM (SELECT (SELECT sum(a) FROM t1));
	}
	} {16}
	do_test subquery-1.10.4 {
	execsql {
	CREATE TABLE t5 (val int, period text PRIMARY KEY);
	INSERT INTO t5 VALUES(5, '2001-3');
	INSERT INTO t5 VALUES(10, '2001-4');
	INSERT INTO t5 VALUES(15, '2002-1');
	INSERT INTO t5 VALUES(5, '2002-2');
	INSERT INTO t5 VALUES(10, '2002-3');
	INSERT INTO t5 VALUES(15, '2002-4');
	INSERT INTO t5 VALUES(10, '2003-1');
	INSERT INTO t5 VALUES(5, '2003-2');
	INSERT INTO t5 VALUES(25, '2003-3');
	INSERT INTO t5 VALUES(5, '2003-4');

	SELECT period, vsum
	FROM (SELECT
	a.period,
	(select sum(val) from t5 where period between a.period and '2002-4') vsum
	FROM t5 a where a.period between '2002-1' and '2002-4')
	WHERE vsum < 45 ;
	}
	} {2002-2 30 2002-3 25 2002-4 15}
	do_test subquery-1.10.5 {
	execsql {
	SELECT period, vsum from
	(select a.period,
	(select sum(val) from t5 where period between a.period and '2002-4') vsum
	FROM t5 a where a.period between '2002-1' and '2002-4')
	WHERE vsum < 45 ;
	}
	} {2002-2 30 2002-3 25 2002-4 15}
	do_test subquery-1.10.6 {
	execsql {
	DROP TABLE t5;
	}
	} {}



	#------------------------------------------------------------------
	# The following test cases - subquery-2.* - are not logically
	# organized. They're here largely because they were failing during
	# one stage of development of sub-queries.
	#
	do_test subquery-2.1 {
	execsql {
	SELECT (SELECT 10);
	}
	} {10}
	do_test subquery-2.2.1 {
	execsql {
	CREATE TABLE t3(a PRIMARY KEY, b);
	INSERT INTO t3 VALUES(1, 2);
	INSERT INTO t3 VALUES(3, 1);
	}
	} {}
	do_test subquery-2.2.2 {
	execsql {
	SELECT * FROM t3 WHERE a IN (SELECT b FROM t3);
	}
	} {1 2}
	do_test subquery-2.2.3 {
	execsql {
	DROP TABLE t3;
	}
	} {}
	do_test subquery-2.3.1 {
	execsql {
	CREATE TABLE t3(a TEXT);
	INSERT INTO t3 VALUES('10');
	}
	} {}
	do_test subquery-2.3.2 {
	execsql {
	SELECT a IN (10.0, 20) FROM t3;
	}
	} {0}
	do_test subquery-2.3.3 {
	execsql {
	DROP TABLE t3;
	}
	} {}
	do_test subquery-2.4.1 {
	execsql {
	CREATE TABLE t3(a TEXT);
	INSERT INTO t3 VALUES('XX');
	}
	} {}
	do_test subquery-2.4.2 {
	execsql {
	SELECT count(*) FROM t3 WHERE a IN (SELECT 'XX')
	}
	} {1}
	do_test subquery-2.4.3 {
	execsql {
	DROP TABLE t3;
	}
	} {}
	do_test subquery-2.5.1 {
	execsql {
	CREATE TABLE t3(a INTEGER);
	INSERT INTO t3 VALUES(10);

	CREATE TABLE t4(x TEXT);
	INSERT INTO t4 VALUES('10.0');
	}
	} {}
	do_test subquery-2.5.2 {
	# In the expr "x IN (SELECT a FROM t3)" the RHS of the IN operator
	# has text affinity and the LHS has integer affinity. The rule is
	# that we try to convert both sides to an integer before doing the
	# comparision. Hence, the integer value 10 in t3 will compare equal
	# to the string value '10.0' in t4 because the t4 value will be
	# converted into an integer.
	execsql {
	SELECT * FROM t4 WHERE x IN (SELECT a FROM t3);
	}
	} {10.0}
	do_test subquery-2.5.3.1 {
	# The t4i index cannot be used to resolve the "x IN (...)" constraint
	# because the constraint has integer affinity but t4i has text affinity.
	execsql {
	CREATE INDEX t4i ON t4(x);
	SELECT * FROM t4 WHERE x IN (SELECT a FROM t3);
	}
	} {10.0}
	do_test subquery-2.5.3.2 {
	# Verify that the t4i index was not used in the previous query
	set ::sqlite_query_plan
	} {t4 {}}
	do_test subquery-2.5.4 {
	execsql {
	DROP TABLE t3;
	DROP TABLE t4;
	}
	} {}

	#------------------------------------------------------------------
	# The following test cases - subquery-3.* - test tickets that
	# were raised during development of correlated subqueries.
	#

	# Ticket 1083
	ifcapable view {
	do_test subquery-3.1 {
	catchsql { DROP TABLE t1; }
	catchsql { DROP TABLE t2; }
	execsql {
	CREATE TABLE t1(a,b);
	INSERT INTO t1 VALUES(1,2);
	CREATE VIEW v1 AS SELECT b FROM t1 WHERE a>0;
	CREATE TABLE t2(p,q);
	INSERT INTO t2 VALUES(2,9);
	SELECT * FROM v1 WHERE EXISTS(SELECT * FROM t2 WHERE p=v1.b);
	}
	} {2}
	do_test subquery-3.1.1 {
	execsql {
	SELECT * FROM v1 WHERE EXISTS(SELECT 1);
	}
	} {2}
	} else {
	catchsql { DROP TABLE t1; }
	catchsql { DROP TABLE t2; }
	execsql {
	CREATE TABLE t1(a,b);
	INSERT INTO t1 VALUES(1,2);
	CREATE TABLE t2(p,q);
	INSERT INTO t2 VALUES(2,9);
	}
	}

	# Ticket 1084
	do_test subquery-3.2 {
	catchsql {
	CREATE TABLE t1(a,b);
	INSERT INTO t1 VALUES(1,2);
	}
	execsql {
	SELECT (SELECT t1.a) FROM t1;
	}
	} {1}

	# Test Cases subquery-3.3.* test correlated subqueries where the
	# parent query is an aggregate query. Ticket #1105 is an example
	# of such a query.
	#
	do_test subquery-3.3.1 {
	execsql {
	SELECT a, (SELECT b) FROM t1 GROUP BY a;
	}
	} {1 2}
	do_test subquery-3.3.2 {
	catchsql {DROP TABLE t2}
	execsql {
	CREATE TABLE t2(c, d);
	INSERT INTO t2 VALUES(1, 'one');
	INSERT INTO t2 VALUES(2, 'two');
	SELECT a, (SELECT d FROM t2 WHERE a=c) FROM t1 GROUP BY a;
	}
	} {1 one}
	do_test subquery-3.3.3 {
	execsql {
	INSERT INTO t1 VALUES(2, 4);
	SELECT max(a), (SELECT d FROM t2 WHERE a=c) FROM t1;
	}
	} {2 two}
	do_test subquery-3.3.4 {
	execsql {
	SELECT a, (SELECT (SELECT d FROM t2 WHERE a=c)) FROM t1 GROUP BY a;
	}
	} {1 one 2 two}
	do_test subquery-3.3.5 {
	execsql {
	SELECT a, (SELECT count(*) FROM t2 WHERE a=c) FROM t1;
	}
	} {1 1 2 1}

	#------------------------------------------------------------------
	# These tests - subquery-4.* - use the TCL statement cache to try
	# and expose bugs to do with re-using statements that have been
	# passed to sqlite3_reset().
	#
	# One problem was that VDBE memory cells were not being initialised
	# to NULL on the second and subsequent executions.
	#
	do_test subquery-4.1.1 {
	execsql {
	SELECT (SELECT a FROM t1);
	}
	} {1}
	do_test subquery-4.2 {
	execsql {
	DELETE FROM t1;
	SELECT (SELECT a FROM t1);
	}
	} {{}}
	do_test subquery-4.2.1 {
	execsql {
	CREATE TABLE t3(a PRIMARY KEY);
	INSERT INTO t3 VALUES(10);
	}
	execsql {INSERT INTO t3 VALUES((SELECT max(a) FROM t3)+1)}
	} {}
	do_test subquery-4.2.2 {
	execsql {INSERT INTO t3 VALUES((SELECT max(a) FROM t3)+1)}
	} {}

	#------------------------------------------------------------------
	# The subquery-5.* tests make sure string literals in double-quotes
	# are handled efficiently. Double-quote literals are first checked
	# to see if they match any column names. If there is not column name
	# match then those literals are used a string constants. When a
	# double-quoted string appears, we want to make sure that the search
	# for a matching column name did not cause an otherwise static subquery
	# to become a dynamic (correlated) subquery.
	#
	do_test subquery-5.1 {
	proc callcntproc {n} {
	incr ::callcnt
	return $n
	}
	set callcnt 0
	db function callcnt callcntproc
	execsql {
	CREATE TABLE t4(x,y);
	INSERT INTO t4 VALUES('one',1);
	INSERT INTO t4 VALUES('two',2);
	INSERT INTO t4 VALUES('three',3);
	INSERT INTO t4 VALUES('four',4);
	CREATE TABLE t5(a,b);
	INSERT INTO t5 VALUES(1,11);
	INSERT INTO t5 VALUES(2,22);
	INSERT INTO t5 VALUES(3,33);
	INSERT INTO t5 VALUES(4,44);
	SELECT b FROM t5 WHERE a IN
	(SELECT callcnt(y)+0 FROM t4 WHERE x="two")
	}
	} {22}
	do_test subquery-5.2 {
	# This is the key test. The subquery should have only run once. If
	# The double-quoted identifier "two" were causing the subquery to be
	# processed as a correlated subquery, then it would have run 4 times.
	set callcnt
	} {1}


	# Ticket #1380. Make sure correlated subqueries on an IN clause work
	# correctly when the left-hand side of the IN operator is constant.
	#
	do_test subquery-6.1 {
	set callcnt 0
	execsql {
	SELECT x FROM t4 WHERE 1 IN (SELECT callcnt(count(*)) FROM t5 WHERE a=y)
	}
	} {one two three four}
	do_test subquery-6.2 {
	set callcnt
	} {4}
	do_test subquery-6.3 {
	set callcnt 0
	execsql {
	SELECT x FROM t4 WHERE 1 IN (SELECT callcnt(count(*)) FROM t5 WHERE a=1)
	}
	} {one two three four}
	do_test subquery-6.4 {
	set callcnt
	} {1}

	if 0 { ############# disable until we get #2652 fixed
	# Ticket #2652. Allow aggregate functions of outer queries inside
	# a non-aggregate subquery.
	#
	do_test subquery-7.1 {
	execsql {
	CREATE TABLE t7(c7);
	INSERT INTO t7 VALUES(1);
	INSERT INTO t7 VALUES(2);
	INSERT INTO t7 VALUES(3);
	CREATE TABLE t8(c8);
	INSERT INTO t8 VALUES(100);
	INSERT INTO t8 VALUES(200);
	INSERT INTO t8 VALUES(300);
	CREATE TABLE t9(c9);
	INSERT INTO t9 VALUES(10000);
	INSERT INTO t9 VALUES(20000);
	INSERT INTO t9 VALUES(30000);

	SELECT (SELECT c7+c8 FROM t7) FROM t8;
	}
	} {101 201 301}
	do_test subquery-7.2 {
	execsql {
	SELECT (SELECT max(c7)+c8 FROM t7) FROM t8;
	}
	} {103 203 303}
	do_test subquery-7.3 {
	execsql {
	SELECT (SELECT c7+max(c8) FROM t8) FROM t7
	}
	} {301}
	do_test subquery-7.4 {
	execsql {
	SELECT (SELECT max(c7)+max(c8) FROM t8) FROM t7
	}
	} {303}
	do_test subquery-7.5 {
	execsql {
	SELECT (SELECT c8 FROM t8 WHERE rowid=max(c7)) FROM t7
	}
	} {300}
	do_test subquery-7.6 {
	execsql {
	SELECT (SELECT (SELECT max(c7+c8+c9) FROM t9) FROM t8) FROM t7
	}
	} {30101 30102 30103}
	do_test subquery-7.7 {
	execsql {
	SELECT (SELECT (SELECT c7+max(c8+c9) FROM t9) FROM t8) FROM t7
	}
	} {30101 30102 30103}
	do_test subquery-7.8 {
	execsql {
	SELECT (SELECT (SELECT max(c7)+c8+c9 FROM t9) FROM t8) FROM t7
	}
	} {10103}
	do_test subquery-7.9 {
	execsql {
	SELECT (SELECT (SELECT c7+max(c8)+c9 FROM t9) FROM t8) FROM t7
	}
	} {10301 10302 10303}
	do_test subquery-7.10 {
	execsql {
	SELECT (SELECT (SELECT c7+c8+max(c9) FROM t9) FROM t8) FROM t7
	}
	} {30101 30102 30103}
	do_test subquery-7.11 {
	execsql {
	SELECT (SELECT (SELECT max(c7)+max(c8)+max(c9) FROM t9) FROM t8) FROM t7
	}
	} {30303}
	} ;############# Disabled

	finish_test