# 2009 August 06 # # 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. This file # implements tests for range and LIKE constraints that use bound variables # instead of literal constant arguments. # set testdir [file dirname $argv0] source $testdir/tester.tcl set testprefix analyze3 ifcapable !stat4 { finish_test return } # This test cannot be run with the sqlite3_prepare() permutation, as it # tests that stat4 data can be used to influence the plans of queries # based on bound variable values. And this is not possible when using # sqlite3_prepare() - as queries cannot be internally re-prepared after # binding values are available. if {[permutation]=="prepare"} { finish_test return } #---------------------------------------------------------------------- # Test Organization: # # analyze3-1.*: Test that the values of bound parameters are considered # in the same way as constants when planning queries that # use range constraints. # # analyze3-2.*: Test that the values of bound parameters are considered # in the same way as constants when planning queries that # use LIKE expressions in the WHERE clause. # # analyze3-3.*: Test that binding to a variable does not invalidate the # query plan when there is no way in which replanning the # query may produce a superior outcome. # # analyze3-4.*: Test that SQL or authorization callback errors occuring # within sqlite3Reprepare() are handled correctly. # # analyze3-5.*: Check that the query plans of applicable statements are # invalidated if the values of SQL parameter are modified # using the clear_bindings() or transfer_bindings() APIs. # # analyze3-6.*: Test that the problem fixed by commit [127a5b776d] is fixed. # # analyze3-7.*: Test that some memory leaks discovered by fuzz testing # have been fixed. # proc getvar {varname} { uplevel #0 set $varname } db function var getvar proc eqp {sql {db db}} { uplevel execsql [list "EXPLAIN QUERY PLAN $sql"] $db } proc sf_execsql {sql {db db}} { set ::sqlite_search_count 0 set r [uplevel [list execsql $sql $db]] concat $::sqlite_search_count [$db status step] $r } #------------------------------------------------------------------------- # # analyze3-1.1.1: # Create a table with two columns. Populate the first column (affinity # INTEGER) with integer values from 100 to 1100. Create an index on this # column. ANALYZE the table. # # analyze3-1.1.2 - 3.1.3 # Show that there are two possible plans for querying the table with # a range constraint on the indexed column - "full table scan" or "use # the index". When the range is specified using literal values, SQLite # is able to pick the best plan based on the samples in sqlite_stat3. # # analyze3-1.1.4 - 3.1.9 # Show that using SQL variables produces the same results as using # literal values to constrain the range scan. # # These tests also check that the compiler code considers column # affinities when estimating the number of rows scanned by the "use # index strategy". # do_test analyze3-1.1.1 { execsql { BEGIN; CREATE TABLE t1(x INTEGER, y); CREATE INDEX i1 ON t1(x); } for {set i 0} {$i < 1000} {incr i} { execsql { INSERT INTO t1 VALUES($i+100, $i) } } execsql { COMMIT; ANALYZE; } execsql { SELECT count(*)>0 FROM sqlite_stat4; } } {1} do_execsql_test analyze3-1.1.x { SELECT count(*) FROM t1 WHERE x>200 AND x<300; SELECT count(*) FROM t1 WHERE x>0 AND x<1100; } {99 1000} # The first of the following two SELECT statements visits 99 rows. So # it is better to use the index. But the second visits every row in # the table (1000 in total) so it is better to do a full-table scan. # do_eqp_test analyze3-1.1.2 { SELECT sum(y) FROM t1 WHERE x>200 AND x<300 } {SEARCH t1 USING INDEX i1 (x>? AND x<?)} do_eqp_test analyze3-1.1.3 { SELECT sum(y) FROM t1 WHERE x>0 AND x<1100 } {SCAN t1} # 2017-06-26: Verify that the SQLITE_DBCONFIG_ENABLE_QPSG setting disables # the use of bound parameters by STAT4 # db cache flush unset -nocomplain l unset -nocomplain u do_eqp_test analyze3-1.1.3.100 { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } {SEARCH t1 USING INDEX i1 (x>? AND x<?)} set l 200 set u 300 do_eqp_test analyze3-1.1.3.101 { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } {SEARCH t1 USING INDEX i1 (x>? AND x<?)} set l 0 set u 1100 do_eqp_test analyze3-1.1.3.102 { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } {SCAN t1} db cache flush sqlite3_db_config db ENABLE_QPSG 1 do_eqp_test analyze3-1.1.3.103 { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } {SEARCH t1 USING INDEX i1 (x>? AND x<?)} db cache flush sqlite3_db_config db ENABLE_QPSG 0 do_eqp_test analyze3-1.1.3.104 { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } {SCAN t1} do_test analyze3-1.1.4 { sf_execsql { SELECT sum(y) FROM t1 WHERE x>200 AND x<300 } } {199 0 14850} do_test analyze3-1.1.5 { set l [string range "200" 0 end] set u [string range "300" 0 end] sf_execsql { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } } {199 0 14850} do_test analyze3-1.1.6 { set l [expr int(200)] set u [expr int(300)] sf_execsql { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } } {199 0 14850} do_test analyze3-1.1.7 { sf_execsql { SELECT sum(y) FROM t1 WHERE x>0 AND x<1100 } } {999 999 499500} do_test analyze3-1.1.8 { set l [string range "0" 0 end] set u [string range "1100" 0 end] sf_execsql { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } } {999 999 499500} do_test analyze3-1.1.9 { set l [expr int(0)] set u [expr int(1100)] sf_execsql { SELECT sum(y) FROM t1 WHERE x>$l AND x<$u } } {999 999 499500} # The following tests are similar to the block above. The difference is # that the indexed column has TEXT affinity in this case. In the tests # above the affinity is INTEGER. # do_test analyze3-1.2.1 { execsql { BEGIN; CREATE TABLE t2(x TEXT, y); INSERT INTO t2 SELECT * FROM t1; CREATE INDEX i2 ON t2(x); COMMIT; ANALYZE; } } {} do_execsql_test analyze3-2.1.x { SELECT count(*) FROM t2 WHERE x>1 AND x<2; SELECT count(*) FROM t2 WHERE x>0 AND x<99; } {200 990} do_eqp_test analyze3-1.2.2 { SELECT sum(y) FROM t2 WHERE x>1 AND x<2 } {SEARCH t2 USING INDEX i2 (x>? AND x<?)} do_eqp_test analyze3-1.2.3 { SELECT sum(y) FROM t2 WHERE x>0 AND x<99 } {SCAN t2} do_test analyze3-1.2.4 { sf_execsql { SELECT sum(y) FROM t2 WHERE x>12 AND x<20 } } {161 0 4760} do_test analyze3-1.2.5 { set l [string range "12" 0 end] set u [string range "20" 0 end] sf_execsql {SELECT typeof($l), typeof($u), sum(y) FROM t2 WHERE x>$l AND x<$u} } {161 0 text text 4760} do_test analyze3-1.2.6 { set l [expr int(12)] set u [expr int(20)] sf_execsql {SELECT typeof($l), typeof($u), sum(y) FROM t2 WHERE x>$l AND x<$u} } {161 0 integer integer 4760} do_test analyze3-1.2.7 { sf_execsql { SELECT sum(y) FROM t2 WHERE x>0 AND x<99 } } {999 999 490555} do_test analyze3-1.2.8 { set l [string range "0" 0 end] set u [string range "99" 0 end] sf_execsql {SELECT typeof($l), typeof($u), sum(y) FROM t2 WHERE x>$l AND x<$u} } {999 999 text text 490555} do_test analyze3-1.2.9 { set l [expr int(0)] set u [expr int(99)] sf_execsql {SELECT typeof($l), typeof($u), sum(y) FROM t2 WHERE x>$l AND x<$u} } {999 999 integer integer 490555} # Same tests a third time. This time, column x has INTEGER affinity and # is not the leftmost column of the table. This triggered a bug causing # SQLite to use sub-optimal query plans in 3.6.18 and earlier. # do_test analyze3-1.3.1 { execsql { BEGIN; CREATE TABLE t3(y TEXT, x INTEGER); INSERT INTO t3 SELECT y, x FROM t1; CREATE INDEX i3 ON t3(x); COMMIT; ANALYZE; } } {} do_execsql_test analyze3-1.3.x { SELECT count(*) FROM t3 WHERE x>200 AND x<300; SELECT count(*) FROM t3 WHERE x>0 AND x<1100 } {99 1000} do_eqp_test analyze3-1.3.2 { SELECT sum(y) FROM t3 WHERE x>200 AND x<300 } {SEARCH t3 USING INDEX i3 (x>? AND x<?)} do_eqp_test analyze3-1.3.3 { SELECT sum(y) FROM t3 WHERE x>0 AND x<1100 } {SCAN t3} do_test analyze3-1.3.4 { sf_execsql { SELECT sum(y) FROM t3 WHERE x>200 AND x<300 } } {199 0 14850} do_test analyze3-1.3.5 { set l [string range "200" 0 end] set u [string range "300" 0 end] sf_execsql { SELECT sum(y) FROM t3 WHERE x>$l AND x<$u } } {199 0 14850} do_test analyze3-1.3.6 { set l [expr int(200)] set u [expr int(300)] sf_execsql { SELECT sum(y) FROM t3 WHERE x>$l AND x<$u } } {199 0 14850} do_test analyze3-1.3.7 { sf_execsql { SELECT sum(y) FROM t3 WHERE x>0 AND x<1100 } } {999 999 499500} do_test analyze3-1.3.8 { set l [string range "0" 0 end] set u [string range "1100" 0 end] sf_execsql { SELECT sum(y) FROM t3 WHERE x>$l AND x<$u } } {999 999 499500} do_test analyze3-1.3.9 { set l [expr int(0)] set u [expr int(1100)] sf_execsql { SELECT sum(y) FROM t3 WHERE x>$l AND x<$u } } {999 999 499500} #------------------------------------------------------------------------- # Test that the values of bound SQL variables may be used for the LIKE # optimization. # drop_all_tables do_test analyze3-2.1 { execsql { PRAGMA case_sensitive_like=off; BEGIN; CREATE TABLE t1(a, b TEXT COLLATE nocase); CREATE INDEX i1 ON t1(b); } for {set i 0} {$i < 1000} {incr i} { set t "" append t [lindex {a b c d e f g h i j} [expr $i/100]] append t [lindex {a b c d e f g h i j} [expr ($i/10)%10]] append t [lindex {a b c d e f g h i j} [expr ($i%10)]] execsql { INSERT INTO t1 VALUES($i, $t) } } execsql COMMIT } {} do_eqp_test analyze3-2.2 { SELECT count(a) FROM t1 WHERE b LIKE 'a%' } {SEARCH t1 USING INDEX i1 (b>? AND b<?)} do_eqp_test analyze3-2.3 { SELECT count(a) FROM t1 WHERE b LIKE '%a' } {SCAN t1} # Return the first argument if like_match_blobs is true (the default) # or the second argument if not # proc ilmb {a b} { ifcapable like_match_blobs {return $a} return $b } do_test analyze3-2.4 { sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE 'a%' } } [list [ilmb 102 101] 0 100] do_test analyze3-2.5 { sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE '%a' } } {999 999 100} do_test analyze3-2.6 { set like "a%" sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE $like } } [list [ilmb 102 101] 0 100] do_test analyze3-2.7 { set like "%a" sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE $like } } {999 999 100} do_test analyze3-2.8 { set like "a" sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE $like } } [list [ilmb 102 101] 0 0] do_test analyze3-2.9 { set like "ab" sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE $like } } [list [ilmb 12 11] 0 0] do_test analyze3-2.10 { set like "abc" sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE $like } } [list [ilmb 3 2] 0 1] do_test analyze3-2.11 { set like "a_c" sf_execsql { SELECT count(*) FROM t1 WHERE b LIKE $like } } [list [ilmb 102 101] 0 10] #------------------------------------------------------------------------- # This block of tests checks that statements are correctly marked as # expired when the values bound to any parameters that may affect the # query plan are modified. # drop_all_tables db auth auth proc auth {args} { set ::auth 1 return SQLITE_OK } do_test analyze3-3.1 { execsql { BEGIN; CREATE TABLE t1(a, b, c); CREATE INDEX i1 ON t1(b); } for {set i 0} {$i < 100} {incr i} { execsql { INSERT INTO t1 VALUES($i, $i, $i) } } execsql COMMIT execsql ANALYZE } {} do_test analyze3-3.2.1 { set S [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE b>?" -1 dummy] sqlite3_expired $S } {0} do_test analyze3-3.2.2 { sqlite3_bind_text $S 1 "abc" 3 sqlite3_expired $S } {1} do_test analyze3-3.2.4 { sqlite3_finalize $S } {SQLITE_OK} do_test analyze3-3.2.5 { set S [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE b=?" -1 dummy] sqlite3_expired $S } {0} do_test analyze3-3.2.6 { sqlite3_bind_text $S 1 "abc" 3 sqlite3_expired $S } {1} do_test analyze3-3.2.7 { sqlite3_finalize $S } {SQLITE_OK} do_test analyze3-3.4.1 { set S [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE a=? AND b>?" -1 dummy] sqlite3_expired $S } {0} do_test analyze3-3.4.2 { sqlite3_bind_text $S 1 "abc" 3 sqlite3_expired $S } {0} do_test analyze3-3.4.3 { sqlite3_bind_text $S 2 "def" 3 sqlite3_expired $S } {1} do_test analyze3-3.4.4 { sqlite3_bind_text $S 2 "ghi" 3 sqlite3_expired $S } {1} do_test analyze3-3.4.5 { sqlite3_expired $S } {1} do_test analyze3-3.4.6 { sqlite3_finalize $S } {SQLITE_OK} do_test analyze3-3.5.1 { set S [sqlite3_prepare_v2 db { SELECT * FROM t1 WHERE a IN ( ?1, ?2, ?3, ?4, ?5, ?6, ?7, ?8, ?9, ?10, ?11, ?12, ?13, ?14, ?15, ?16, ?17, ?18, ?19, ?20, ?21, ?22, ?23, ?24, ?25, ?26, ?27, ?28, ?29, ?30, ?31 ) AND b>?32; } -1 dummy] sqlite3_expired $S } {0} do_test analyze3-3.5.2 { sqlite3_bind_text $S 31 "abc" 3 sqlite3_expired $S } {0} do_test analyze3-3.5.3 { sqlite3_bind_text $S 32 "def" 3 sqlite3_expired $S } {1} do_test analyze3-3.5.5 { sqlite3_finalize $S } {SQLITE_OK} do_test analyze3-3.6.1 { set S [sqlite3_prepare_v2 db { SELECT * FROM t1 WHERE a IN ( ?1, ?2, ?3, ?4, ?5, ?6, ?7, ?8, ?9, ?10, ?11, ?12, ?13, ?14, ?15, ?16, ?17, ?18, ?19, ?20, ?21, ?22, ?23, ?24, ?25, ?26, ?27, ?28, ?29, ?30, ?31, ?32 ) AND b>?33; } -1 dummy] sqlite3_expired $S } {0} do_test analyze3-3.6.2 { sqlite3_bind_text $S 32 "abc" 3 sqlite3_expired $S } {1} do_test analyze3-3.6.3 { sqlite3_bind_text $S 33 "def" 3 sqlite3_expired $S } {1} do_test analyze3-3.6.5 { sqlite3_finalize $S } {SQLITE_OK} do_test analyze3-3.7.1 { set S [sqlite3_prepare_v2 db { SELECT * FROM t1 WHERE a IN ( ?1, ?2, ?3, ?4, ?5, ?6, ?7, ?8, ?9, ?33, ?11, ?12, ?13, ?14, ?15, ?16, ?17, ?18, ?19, ?20, ?21, ?22, ?23, ?24, ?25, ?26, ?27, ?28, ?29, ?30, ?31, ?32 ) AND b>?10; } -1 dummy] sqlite3_expired $S } {0} do_test analyze3-3.7.2 { sqlite3_bind_text $S 32 "abc" 3 sqlite3_expired $S } {0} do_test analyze3-3.7.3 { sqlite3_bind_text $S 33 "def" 3 sqlite3_expired $S } {0} do_test analyze3-3.7.4 { sqlite3_bind_text $S 10 "def" 3 sqlite3_expired $S } {1} do_test analyze3-3.7.6 { sqlite3_finalize $S } {SQLITE_OK} do_test analyze3-3.8.1 { execsql { CREATE TABLE t4(x, y TEXT COLLATE NOCASE); CREATE INDEX i4 ON t4(y); } } {} do_test analyze3-3.8.2 { set S [sqlite3_prepare_v2 db { SELECT * FROM t4 WHERE x != ? AND y LIKE ? } -1 dummy] sqlite3_expired $S } {0} do_test analyze3-3.8.3 { sqlite3_bind_text $S 1 "abc" 3 sqlite3_expired $S } {0} do_test analyze3-3.8.4 { sqlite3_bind_text $S 2 "def" 3 sqlite3_expired $S } {1} do_test analyze3-3.8.7 { sqlite3_bind_text $S 2 "ghi%" 4 sqlite3_expired $S } {1} do_test analyze3-3.8.8 { sqlite3_expired $S } {1} do_test analyze3-3.8.9 { sqlite3_bind_text $S 2 "ghi%def" 7 sqlite3_expired $S } {1} do_test analyze3-3.8.10 { sqlite3_expired $S } {1} do_test analyze3-3.8.11 { sqlite3_bind_text $S 2 "%ab" 3 sqlite3_expired $S } {1} do_test analyze3-3.8.12 { sqlite3_expired $S } {1} do_test analyze3-3.8.12 { sqlite3_bind_text $S 2 "%de" 3 sqlite3_expired $S } {1} do_test analyze3-3.8.13 { sqlite3_expired $S } {1} do_test analyze3-3.8.14 { sqlite3_finalize $S } {SQLITE_OK} #------------------------------------------------------------------------- # These tests check that errors encountered while repreparing an SQL # statement within sqlite3Reprepare() are handled correctly. # # Check a schema error. # do_test analyze3-4.1.1 { set S [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE a=? AND b>?" -1 dummy] sqlite3_step $S } {SQLITE_DONE} do_test analyze3-4.1.2 { sqlite3_reset $S sqlite3_bind_text $S 2 "abc" 3 execsql { DROP TABLE t1 } sqlite3_step $S } {SQLITE_ERROR} do_test analyze3-4.1.3 { sqlite3_finalize $S } {SQLITE_ERROR} # Check an authorization error. # do_test analyze3-4.2.1 { execsql { BEGIN; CREATE TABLE t1(a, b, c); CREATE INDEX i1 ON t1(b); } for {set i 0} {$i < 100} {incr i} { execsql { INSERT INTO t1 VALUES($i, $i, $i) } } execsql COMMIT execsql ANALYZE set S [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE a=? AND b>?" -1 dummy] sqlite3_step $S } {SQLITE_DONE} db auth auth proc auth {args} { if {[lindex $args 0] == "SQLITE_READ"} {return SQLITE_DENY} return SQLITE_OK } do_test analyze3-4.2.2 { sqlite3_reset $S sqlite3_bind_text $S 2 "abc" 3 sqlite3_step $S } {SQLITE_AUTH} do_test analyze3-4.2.4 { sqlite3_finalize $S } {SQLITE_AUTH} # Check the effect of an authorization error that occurs in a re-prepare # performed by sqlite3_step() is the same as one that occurs within # sqlite3Reprepare(). # do_test analyze3-4.3.1 { db auth {} set S [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE a=? AND b>?" -1 dummy] execsql { CREATE TABLE t2(d, e, f) } db auth auth sqlite3_step $S } {SQLITE_AUTH} do_test analyze3-4.3.2 { sqlite3_finalize $S } {SQLITE_AUTH} db auth {} #------------------------------------------------------------------------- # Test that modifying bound variables using the clear_bindings() or # transfer_bindings() APIs works. # # analyze3-5.1.*: sqlite3_clear_bindings() # analyze3-5.2.*: sqlite3_transfer_bindings() # do_test analyze3-5.1.1 { drop_all_tables execsql { CREATE TABLE t1(x TEXT COLLATE NOCASE); CREATE INDEX i1 ON t1(x); INSERT INTO t1 VALUES('aaa'); INSERT INTO t1 VALUES('abb'); INSERT INTO t1 VALUES('acc'); INSERT INTO t1 VALUES('baa'); INSERT INTO t1 VALUES('bbb'); INSERT INTO t1 VALUES('bcc'); } set S [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE x LIKE ?" -1 dummy] sqlite3_bind_text $S 1 "a%" 2 set R [list] while { "SQLITE_ROW" == [sqlite3_step $S] } { lappend R [sqlite3_column_text $S 0] } concat [sqlite3_reset $S] $R } {SQLITE_OK aaa abb acc} do_test analyze3-5.1.2 { sqlite3_clear_bindings $S set R [list] while { "SQLITE_ROW" == [sqlite3_step $S] } { lappend R [sqlite3_column_text $S 0] } concat [sqlite3_reset $S] $R } {SQLITE_OK} do_test analyze3-5.1.3 { sqlite3_finalize $S } {SQLITE_OK} do_test analyze3-5.1.1 { set S1 [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE x LIKE ?" -1 dummy] sqlite3_bind_text $S1 1 "b%" 2 set R [list] while { "SQLITE_ROW" == [sqlite3_step $S1] } { lappend R [sqlite3_column_text $S1 0] } concat [sqlite3_reset $S1] $R } {SQLITE_OK baa bbb bcc} do_test analyze3-5.1.2 { set S2 [sqlite3_prepare_v2 db "SELECT * FROM t1 WHERE x = ?" -1 dummy] sqlite3_bind_text $S2 1 "a%" 2 sqlite3_transfer_bindings $S2 $S1 set R [list] while { "SQLITE_ROW" == [sqlite3_step $S1] } { lappend R [sqlite3_column_text $S1 0] } concat [sqlite3_reset $S1] $R } {SQLITE_OK aaa abb acc} do_test analyze3-5.1.3 { sqlite3_finalize $S2 sqlite3_finalize $S1 } {SQLITE_OK} #------------------------------------------------------------------------- do_test analyze3-6.1 { execsql { DROP TABLE IF EXISTS t1 } execsql BEGIN execsql { CREATE TABLE t1(a, b, c) } for {set i 0} {$i < 1000} {incr i} { execsql "INSERT INTO t1 VALUES([expr $i/100], 'x', [expr $i/10])" } execsql { CREATE INDEX i1 ON t1(a, b); CREATE INDEX i2 ON t1(c); } execsql COMMIT execsql ANALYZE } {} do_eqp_test analyze3-6-3 { SELECT * FROM t1 WHERE a = 5 AND c = 13; } {SEARCH t1 USING INDEX i2 (c=?)} do_eqp_test analyze3-6-2 { SELECT * FROM t1 WHERE a = 5 AND b > 'w' AND c = 13; } {SEARCH t1 USING INDEX i2 (c=?)} #----------------------------------------------------------------------------- # 2015-04-20. # Memory leak in sqlite3Stat4ProbeFree(). (Discovered while fuzzing.) # do_execsql_test analyze-7.1 { DROP TABLE IF EXISTS t1; CREATE TABLE t1(a INTEGER PRIMARY KEY, b, c); INSERT INTO t1 VALUES(1,1,'0000'); CREATE INDEX t0b ON t1(b); ANALYZE; SELECT c FROM t1 WHERE b=3 AND a BETWEEN 30 AND hex(1); } {} # At one point duplicate stat1 entries were causing a memory leak. # reset_db do_execsql_test 7.2 { CREATE TABLE t1(a,b,c); CREATE INDEX t1a ON t1(a); ANALYZE; SELECT * FROM sqlite_stat1; INSERT INTO sqlite_stat1(tbl,idx,stat) VALUES('t1','t1a','12000'); INSERT INTO sqlite_stat1(tbl,idx,stat) VALUES('t1','t1a','12000'); ANALYZE sqlite_master; } # 2023-04-22 https://sqlite.org/forum/info/6c118daad0f1f5ef # Case differences in the sqlite_stat4.idx field should not matter. # reset_db do_execsql_test 8.0 { CREATE TABLE t1(a PRIMARY KEY, v) WITHOUT ROWID; ANALYZE sqlite_schema; INSERT INTO sqlite_stat1 VALUES('t1','t1','1 1'); INSERT INTO sqlite_stat4 VALUES('t1','t1','1','0','0',X'021b76657273696f6e'); INSERT INTO sqlite_stat4 VALUES('T1','T1','1','0','0',X'021b76657273696f6e'); ANALYZE sqlite_schema; } {} # 2023-05-03 https://sqlite.org/forum/forumpost/537d8ab118 # Same index appears by two different names in the sqlite_stat4 table. # reset_db do_execsql_test 8.1 { CREATE TABLE t1(a INT PRIMARY KEY, b INT) WITHOUT ROWID; ANALYZE sqlite_schema; INSERT INTO sqlite_stat4 VALUES ('t1','t1','1','2','2',X'03000103'), ('t1','sqlite_autoindex_t1_1','1','2','2',X'03000103'); ANALYZE sqlite_schema; PRAGMA integrity_check; } {ok} finish_test