# 2006 October 27 # # 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 use of indices in WHERE clauses. # This file was created when support for optimizing IS NULL phrases # was added. And so the principle purpose of this file is to test # that IS NULL phrases are correctly optimized. But you can never # have too many tests, so some other tests are thrown in as well. # # $Id: where4.test,v 1.5 2007/09/12 17:01:45 danielk1977 Exp $ set testdir [file dirname $argv0] source $testdir/tester.tcl ifcapable !tclvar||!bloblit { finish_test return } # Build some test data # do_test where4-1.0 { execsql { CREATE TABLE t1(w, x, y); CREATE INDEX i1wxy ON t1(w,x,y); INSERT INTO t1 VALUES(1,2,3); INSERT INTO t1 VALUES(1,NULL,3); INSERT INTO t1 VALUES('a','b','c'); INSERT INTO t1 VALUES('a',NULL,'c'); INSERT INTO t1 VALUES(X'78',x'79',x'7a'); INSERT INTO t1 VALUES(X'78',NULL,X'7A'); INSERT INTO t1 VALUES(NULL,NULL,NULL); SELECT count(*) FROM t1; } } {7} # Do an SQL statement. Append the search count to the end of the result. # proc count sql { set ::sqlite_search_count 0 return [concat [execsql $sql] $::sqlite_search_count] } # Verify that queries use an index. We are using the special variable # "sqlite_search_count" which tallys the number of executions of MoveTo # and Next operators in the VDBE. By verifing that the search count is # small we can be assured that indices are being used properly. # do_test where4-1.1 { count {SELECT rowid FROM t1 WHERE w IS NULL} } {7 2} do_test where4-1.2 { count {SELECT rowid FROM t1 WHERE +w IS NULL} } {7 6} do_test where4-1.3 { count {SELECT rowid FROM t1 WHERE w=1 AND x IS NULL} } {2 2} do_test where4-1.4 { count {SELECT rowid FROM t1 WHERE w=1 AND +x IS NULL} } {2 3} do_test where4-1.5 { count {SELECT rowid FROM t1 WHERE w=1 AND x>0} } {1 2} do_test where4-1.6 { count {SELECT rowid FROM t1 WHERE w=1 AND x<9} } {1 3} do_test where4-1.7 { count {SELECT rowid FROM t1 WHERE w=1 AND x IS NULL AND y=3} } {2 2} do_test where4-1.8 { count {SELECT rowid FROM t1 WHERE w=1 AND x IS NULL AND y>2} } {2 2} do_test where4-1.9 { count {SELECT rowid FROM t1 WHERE w='a' AND x IS NULL AND y='c'} } {4 2} do_test where4-1.10 { count {SELECT rowid FROM t1 WHERE w=x'78' AND x IS NULL} } {6 2} do_test where4-1.11 { count {SELECT rowid FROM t1 WHERE w=x'78' AND x IS NULL AND y=123} } {1} do_test where4-1.12 { count {SELECT rowid FROM t1 WHERE w=x'78' AND x IS NULL AND y=x'7A'} } {6 2} do_test where4-1.13 { count {SELECT rowid FROM t1 WHERE w IS NULL AND x IS NULL} } {7 2} do_test where4-1.14 { count {SELECT rowid FROM t1 WHERE w IS NULL AND x IS NULL AND y IS NULL} } {7 2} do_test where4-1.15 { count {SELECT rowid FROM t1 WHERE w IS NULL AND x IS NULL AND y<0} } {2} do_test where4-1.16 { count {SELECT rowid FROM t1 WHERE w IS NULL AND x IS NULL AND y>=0} } {1} do_test where4-2.1 { execsql {SELECT rowid FROM t1 ORDER BY w, x, y} } {7 2 1 4 3 6 5} do_test where4-2.2 { execsql {SELECT rowid FROM t1 ORDER BY w DESC, x, y} } {6 5 4 3 2 1 7} do_test where4-2.3 { execsql {SELECT rowid FROM t1 ORDER BY w, x DESC, y} } {7 1 2 3 4 5 6} # Ticket #2177 # # Suppose you have a left join where the right table of the left # join (the one that can be NULL) has an index on two columns. # The first indexed column is used in the ON clause of the join. # The second indexed column is used in the WHERE clause with an IS NULL # constraint. It is not allowed to use the IS NULL optimization to # optimize the query because the second column might be NULL because # the right table did not match - something the index does not know # about. # do_test where4-3.1 { execsql { CREATE TABLE t2(a); INSERT INTO t2 VALUES(1); INSERT INTO t2 VALUES(2); INSERT INTO t2 VALUES(3); CREATE TABLE t3(x,y,UNIQUE(x,y)); INSERT INTO t3 VALUES(1,11); INSERT INTO t3 VALUES(2,NULL); SELECT * FROM t2 LEFT JOIN t3 ON a=x WHERE +y IS NULL; } } {2 2 {} 3 {} {}} do_test where4-3.2 { execsql { SELECT * FROM t2 LEFT JOIN t3 ON a=x WHERE y IS NULL; } } {2 2 {} 3 {} {}} # Ticket #2189. Probably the same bug as #2177. # do_test where4-4.1 { execsql { CREATE TABLE test(col1 TEXT PRIMARY KEY); INSERT INTO test(col1) values('a'); INSERT INTO test(col1) values('b'); INSERT INTO test(col1) values('c'); CREATE TABLE test2(col1 TEXT PRIMARY KEY); INSERT INTO test2(col1) values('a'); INSERT INTO test2(col1) values('b'); INSERT INTO test2(col1) values('c'); SELECT * FROM test t1 LEFT OUTER JOIN test2 t2 ON t1.col1 = t2.col1 WHERE +t2.col1 IS NULL; } } {} do_test where4-4.2 { execsql { SELECT * FROM test t1 LEFT OUTER JOIN test2 t2 ON t1.col1 = t2.col1 WHERE t2.col1 IS NULL; } } {} do_test where4-4.3 { execsql { SELECT * FROM test t1 LEFT OUTER JOIN test2 t2 ON t1.col1 = t2.col1 WHERE +t1.col1 IS NULL; } } {} do_test where4-4.4 { execsql { SELECT * FROM test t1 LEFT OUTER JOIN test2 t2 ON t1.col1 = t2.col1 WHERE t1.col1 IS NULL; } } {} # Ticket #2273. Problems with IN operators and NULLs. # do_test where4-5.1 { execsql { CREATE TABLE t4(x,y,z,PRIMARY KEY(x,y)); } execsql { SELECT * FROM t2 LEFT JOIN t4 b1 LEFT JOIN t4 b2 ON b2.x=b1.x AND b2.y IN (b1.y); } } {1 {} {} {} {} {} {} 2 {} {} {} {} {} {} 3 {} {} {} {} {} {}} do_test where4-5.2 { execsql { INSERT INTO t4 VALUES(1,1,11); INSERT INTO t4 VALUES(1,2,12); INSERT INTO t4 VALUES(1,3,13); INSERT INTO t4 VALUES(2,2,22); SELECT rowid FROM t4 WHERE x IN (1,9,2,5) AND y IN (1,3,NULL,2) AND z!=13; } } {1 2 4} do_test where4-5.3 { execsql { SELECT rowid FROM t4 WHERE x IN (1,9,NULL,2) AND y IN (1,3,2) AND z!=13; } } {1 2 4} do_test where4-6.1 { execsql { CREATE TABLE t5(a,b,c,d,e,f,UNIQUE(a,b,c,d,e,f)); INSERT INTO t5 VALUES(1,1,1,1,1,11111); INSERT INTO t5 VALUES(2,2,2,2,2,22222); INSERT INTO t5 VALUES(1,2,3,4,5,12345); INSERT INTO t5 VALUES(2,3,4,5,6,23456); } execsql { SELECT rowid FROM t5 WHERE a IN (1,9,2) AND b=2 AND c IN (1,2,3,4) AND d>0 } } {3 2} do_test where4-6.2 { execsql { SELECT rowid FROM t5 WHERE a IN (1,NULL,2) AND b=2 AND c IN (1,2,3,4) AND d>0 } } {3 2} do_test where4-7.1 { execsql { CREATE TABLE t6(y,z,PRIMARY KEY(y,z)); } execsql { SELECT * FROM t6 WHERE y=NULL AND z IN ('hello'); } } {} integrity_check {where4-99.0} do_test where4-7.1 { execsql { BEGIN; CREATE TABLE t8(a, b, c, d); CREATE INDEX t8_i ON t8(a, b, c); CREATE TABLE t7(i); INSERT INTO t7 VALUES(1); INSERT INTO t7 SELECT i*2 FROM t7; INSERT INTO t7 SELECT i*2 FROM t7; INSERT INTO t7 SELECT i*2 FROM t7; INSERT INTO t7 SELECT i*2 FROM t7; INSERT INTO t7 SELECT i*2 FROM t7; INSERT INTO t7 SELECT i*2 FROM t7; COMMIT; } } {} # At one point the sub-select inside the aggregate sum() function in the # following query was leaking a couple of stack entries. This query # runs the SELECT in a loop enough times that an assert() fails. Or rather, # did fail before the bug was fixed. # do_test where4-7.2 { execsql { SELECT sum(( SELECT d FROM t8 WHERE a = i AND b = i AND c < NULL )) FROM t7; } } {{}} finish_test