sqlite/ext/session/session2.test

582 lines
15 KiB
Plaintext
Raw Normal View History

# 2011 Mar 16
#
# 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.
#
#***********************************************************************
#
# The focus of this file is testing the session module.
#
if {![info exists testdir]} {
set testdir [file join [file dirname [info script]] .. .. test]
}
source [file join [file dirname [info script]] session_common.tcl]
source $testdir/tester.tcl
ifcapable !session {finish_test; return}
set testprefix session2
proc test_reset {} {
catch { db close }
catch { db2 close }
forcedelete test.db test.db2
sqlite3 db test.db
sqlite3 db2 test.db2
}
##########################################################################
# End of proc definitions. Start of tests.
##########################################################################
test_reset
do_execsql_test 1.0 {
CREATE TABLE t1(a PRIMARY KEY, b);
INSERT INTO t1 VALUES('i', 'one');
}
do_iterator_test 1.1 t1 {
DELETE FROM t1 WHERE a = 'i';
INSERT INTO t1 VALUES('ii', 'two');
} {
{DELETE t1 0 X. {t i t one} {}}
{INSERT t1 0 X. {} {t ii t two}}
}
do_iterator_test 1.2 t1 {
INSERT INTO t1 VALUES(1.5, 99.9)
} {
{INSERT t1 0 X. {} {f 1.5 f 99.9}}
}
do_iterator_test 1.3 t1 {
UPDATE t1 SET b = 100.1 WHERE a = 1.5;
UPDATE t1 SET b = 99.9 WHERE a = 1.5;
} { }
do_iterator_test 1.4 t1 {
UPDATE t1 SET b = 100.1 WHERE a = 1.5;
} {
{UPDATE t1 0 X. {f 1.5 f 99.9} {{} {} f 100.1}}
}
# Execute each of the following blocks of SQL on database [db1]. Collect
# changes using a session object. Apply the resulting changeset to
# database [db2]. Then check that the contents of the two databases are
# identical.
#
set set_of_tests {
1 { INSERT INTO %T1% VALUES(1, 2) }
2 {
INSERT INTO %T2% VALUES(1, NULL);
INSERT INTO %T2% VALUES(2, NULL);
INSERT INTO %T2% VALUES(3, NULL);
DELETE FROM %T2% WHERE a = 2;
INSERT INTO %T2% VALUES(4, NULL);
UPDATE %T2% SET b=0 WHERE b=1;
}
3 { INSERT INTO %T3% SELECT *, NULL FROM %T2% }
4 {
INSERT INTO %T3% SELECT a||a, b||b, NULL FROM %T3%;
DELETE FROM %T3% WHERE rowid%2;
}
5 { UPDATE %T3% SET c = a||b }
6 { UPDATE %T1% SET a = 32 }
7 {
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
DELETE FROM %T1% WHERE (rowid%3)==0;
}
8 {
BEGIN;
INSERT INTO %T1% SELECT randomblob(32), randomblob(32) FROM %T1%;
ROLLBACK;
}
9 {
BEGIN;
UPDATE %T1% SET b = 'xxx';
ROLLBACK;
}
10 {
BEGIN;
DELETE FROM %T1% WHERE 1;
ROLLBACK;
}
11 {
INSERT INTO %T1% VALUES(randomblob(21000), randomblob(0));
INSERT INTO %T1% VALUES(1.5, 1.5);
INSERT INTO %T1% VALUES(4.56, -99.999999999999999999999);
}
12 {
INSERT INTO %T2% VALUES(NULL, NULL);
}
13 {
DELETE FROM %T1% WHERE 1;
-- Insert many rows with real primary keys. Enough to force the session
-- objects hash table to resize.
INSERT INTO %T1% VALUES(0.1, 0.1);
INSERT INTO %T1% SELECT a+0.1, b+0.1 FROM %T1%;
INSERT INTO %T1% SELECT a+0.2, b+0.2 FROM %T1%;
INSERT INTO %T1% SELECT a+0.4, b+0.4 FROM %T1%;
INSERT INTO %T1% SELECT a+0.8, b+0.8 FROM %T1%;
INSERT INTO %T1% SELECT a+1.6, b+1.6 FROM %T1%;
INSERT INTO %T1% SELECT a+3.2, b+3.2 FROM %T1%;
INSERT INTO %T1% SELECT a+6.4, b+6.4 FROM %T1%;
INSERT INTO %T1% SELECT a+12.8, b+12.8 FROM %T1%;
INSERT INTO %T1% SELECT a+25.6, b+25.6 FROM %T1%;
INSERT INTO %T1% SELECT a+51.2, b+51.2 FROM %T1%;
INSERT INTO %T1% SELECT a+102.4, b+102.4 FROM %T1%;
INSERT INTO %T1% SELECT a+204.8, b+204.8 FROM %T1%;
}
14 {
DELETE FROM %T1% WHERE 1;
}
15 {
INSERT INTO %T1% VALUES(1, 1);
INSERT INTO %T1% SELECT a+2, b+2 FROM %T1%;
INSERT INTO %T1% SELECT a+4, b+4 FROM %T1%;
INSERT INTO %T1% SELECT a+8, b+8 FROM %T1%;
INSERT INTO %T1% SELECT a+256, b+256 FROM %T1%;
}
16 {
INSERT INTO %T4% VALUES('abc', 'def');
INSERT INTO %T4% VALUES('def', 'abc');
}
17 { UPDATE %T4% SET b = 1 }
18 { DELETE FROM %T4% WHERE 1 }
}
test_reset
do_common_sql {
CREATE TABLE t1(a PRIMARY KEY, b);
CREATE TABLE t2(a, b INTEGER PRIMARY KEY);
CREATE TABLE t3(a, b, c, PRIMARY KEY(a, b));
CREATE TABLE t4(a, b, PRIMARY KEY(b, a));
}
foreach {tn sql} [string map {%T1% t1 %T2% t2 %T3% t3 %T4% t4} $set_of_tests] {
do_then_apply_sql $sql
do_test 2.$tn { compare_db db db2 } {}
}
# The following block of tests is similar to the last, except that the
# session object is recording changes made to an attached database. The
# main database contains a table of the same name as the table being
# modified within the attached db.
#
test_reset
forcedelete test.db3
sqlite3 db3 test.db3
do_test 3.0 {
execsql {
ATTACH 'test.db3' AS 'aux';
CREATE TABLE t1(a, b PRIMARY KEY);
CREATE TABLE t2(x, y, z);
CREATE TABLE t3(a);
CREATE TABLE aux.t1(a PRIMARY KEY, b);
CREATE TABLE aux.t2(a, b INTEGER PRIMARY KEY);
CREATE TABLE aux.t3(a, b, c, PRIMARY KEY(a, b));
CREATE TABLE aux.t4(a, b, PRIMARY KEY(b, a));
}
execsql {
CREATE TABLE t1(a PRIMARY KEY, b);
CREATE TABLE t2(a, b INTEGER PRIMARY KEY);
CREATE TABLE t3(a, b, c, PRIMARY KEY(a, b));
CREATE TABLE t4(a, b, PRIMARY KEY(b, a));
} db2
} {}
proc xTrace {args} { puts $args }
foreach {tn sql} [
string map {%T1% aux.t1 %T2% aux.t2 %T3% aux.t3 %T4% aux.t4} $set_of_tests
] {
do_then_apply_sql $sql aux
do_test 3.$tn { compare_db db2 db3 } {}
}
catch {db3 close}
#-------------------------------------------------------------------------
# The following tests verify that NULL values in primary key columns are
# handled correctly by the session module.
#
test_reset
do_execsql_test 4.0 {
CREATE TABLE t1(a PRIMARY KEY);
CREATE TABLE t2(a, b, c, PRIMARY KEY(c, b));
CREATE TABLE t3(a, b INTEGER PRIMARY KEY);
}
foreach {tn sql changeset} {
1 {
INSERT INTO t1 VALUES(123);
INSERT INTO t1 VALUES(NULL);
INSERT INTO t1 VALUES(456);
} {
{INSERT t1 0 X {} {i 456}}
{INSERT t1 0 X {} {i 123}}
}
2 {
UPDATE t1 SET a = NULL;
} {
{DELETE t1 0 X {i 456} {}}
{DELETE t1 0 X {i 123} {}}
}
3 { DELETE FROM t1 } { }
4 {
INSERT INTO t3 VALUES(NULL, NULL)
} {
{INSERT t3 0 .X {} {n {} i 1}}
}
5 { INSERT INTO t2 VALUES(1, 2, NULL) } { }
6 { INSERT INTO t2 VALUES(1, NULL, 3) } { }
7 { INSERT INTO t2 VALUES(1, NULL, NULL) } { }
8 { INSERT INTO t2 VALUES(1, 2, 3) } { {INSERT t2 0 .XX {} {i 1 i 2 i 3}} }
9 { DELETE FROM t2 WHERE 1 } { {DELETE t2 0 .XX {i 1 i 2 i 3} {}} }
} {
do_iterator_test 4.$tn {t1 t2 t3} $sql $changeset
}
#-------------------------------------------------------------------------
# Test that if NULL is passed to sqlite3session_attach(), all database
# tables are attached to the session object.
#
test_reset
do_execsql_test 5.0 {
CREATE TABLE t1(a PRIMARY KEY);
CREATE TABLE t2(x, y PRIMARY KEY);
}
foreach {tn sql changeset} {
1 { INSERT INTO t1 VALUES(35) } { {INSERT t1 0 X {} {i 35}} }
2 { INSERT INTO t2 VALUES(36, 37) } { {INSERT t2 0 .X {} {i 36 i 37}} }
3 {
DELETE FROM t1 WHERE 1;
UPDATE t2 SET x = 34;
} {
{UPDATE t2 0 .X {i 36 i 37} {i 34 {} {}}}
{DELETE t1 0 X {i 35} {}}
}
} {
do_iterator_test 5.$tn * $sql $changeset
}
#-------------------------------------------------------------------------
# The next block of tests verify that the "indirect" flag is set
# correctly within changesets. The indirect flag is set for a change
# if either of the following are true:
#
# * The sqlite3session_indirect() API has been used to set the session
# indirect flag to true, or
# * The change was made by a trigger.
#
# If the same row is updated more than once during a session, then the
# change is considered indirect only if all changes meet the criteria
# above.
#
test_reset
db function indirect [list S indirect]
do_execsql_test 6.0 {
CREATE TABLE t1(a PRIMARY KEY, b, c);
CREATE TABLE t2(x PRIMARY KEY, y);
CREATE TRIGGER AFTER INSERT ON t2 WHEN new.x%2 BEGIN
INSERT INTO t2 VALUES(new.x+1, NULL);
END;
}
do_iterator_test 6.1.1 * {
INSERT INTO t1 VALUES(1, 'one', 'i');
SELECT indirect(1);
INSERT INTO t1 VALUES(2, 'two', 'ii');
SELECT indirect(0);
INSERT INTO t1 VALUES(3, 'three', 'iii');
} {
{INSERT t1 0 X.. {} {i 1 t one t i}}
{INSERT t1 1 X.. {} {i 2 t two t ii}}
{INSERT t1 0 X.. {} {i 3 t three t iii}}
}
do_iterator_test 6.1.2 * {
SELECT indirect(1);
UPDATE t1 SET c = 'I' WHERE a = 1;
SELECT indirect(0);
} {
{UPDATE t1 1 X.. {i 1 {} {} t i} {{} {} {} {} t I}}
}
do_iterator_test 6.1.3 * {
SELECT indirect(1);
UPDATE t1 SET c = '.' WHERE a = 1;
SELECT indirect(0);
UPDATE t1 SET c = 'o' WHERE a = 1;
} {
{UPDATE t1 0 X.. {i 1 {} {} t I} {{} {} {} {} t o}}
}
do_iterator_test 6.1.4 * {
SELECT indirect(0);
UPDATE t1 SET c = 'x' WHERE a = 1;
SELECT indirect(1);
UPDATE t1 SET c = 'i' WHERE a = 1;
} {
{UPDATE t1 0 X.. {i 1 {} {} t o} {{} {} {} {} t i}}
}
do_iterator_test 6.1.4 * {
SELECT indirect(1);
UPDATE t1 SET c = 'y' WHERE a = 1;
SELECT indirect(1);
UPDATE t1 SET c = 'I' WHERE a = 1;
} {
{UPDATE t1 1 X.. {i 1 {} {} t i} {{} {} {} {} t I}}
}
do_iterator_test 6.1.5 * {
INSERT INTO t2 VALUES(1, 'x');
} {
{INSERT t2 0 X. {} {i 1 t x}}
{INSERT t2 1 X. {} {i 2 n {}}}
}
do_iterator_test 6.1.6 * {
SELECT indirect(1);
INSERT INTO t2 VALUES(3, 'x');
SELECT indirect(0);
UPDATE t2 SET y = 'y' WHERE x>2;
} {
{INSERT t2 0 X. {} {i 3 t y}}
{INSERT t2 0 X. {} {i 4 t y}}
}
do_iterator_test 6.1.7 * {
SELECT indirect(1);
DELETE FROM t2 WHERE x = 4;
SELECT indirect(0);
INSERT INTO t2 VALUES(4, 'new');
} {
{UPDATE t2 0 X. {i 4 t y} {{} {} t new}}
}
do_iterator_test 6.1.8 * {
CREATE TABLE t3(a, b PRIMARY KEY);
CREATE TABLE t4(a, b PRIMARY KEY);
CREATE TRIGGER t4t AFTER UPDATE ON t4 BEGIN
UPDATE t3 SET a = new.a WHERE b = new.b;
END;
SELECT indirect(1);
INSERT INTO t3 VALUES('one', 1);
INSERT INTO t4 VALUES('one', 1);
SELECT indirect(0);
UPDATE t4 SET a = 'two' WHERE b = 1;
} {
{INSERT t4 0 .X {} {t two i 1}}
{INSERT t3 1 .X {} {t two i 1}}
}
sqlite3session S db main
do_execsql_test 6.2.1 {
SELECT indirect(0);
SELECT indirect(-1);
SELECT indirect(45);
SELECT indirect(-100);
} {0 0 1 1}
S delete
#-------------------------------------------------------------------------
# Test that if a conflict-handler that has been passed either NOTFOUND or
# CONSTRAINT returns REPLACE - the sqlite3changeset_apply() call returns
# MISUSE and rolls back any changes made so far.
#
# 7.1.*: NOTFOUND conflict-callback.
# 7.2.*: CONSTRAINT conflict-callback.
#
proc xConflict {args} {return REPLACE}
test_reset
do_execsql_test 7.1.1 {
CREATE TABLE t1(a PRIMARY KEY, b);
INSERT INTO t1 VALUES(1, 'one');
INSERT INTO t1 VALUES(2, 'two');
}
do_test 7.1.2 {
execsql {
CREATE TABLE t1(a PRIMARY KEY, b NOT NULL);
INSERT INTO t1 VALUES(1, 'one');
} db2
} {}
do_test 7.1.3 {
set changeset [changeset_from_sql {
UPDATE t1 SET b = 'five' WHERE a = 1;
UPDATE t1 SET b = 'six' WHERE a = 2;
}]
set x [list]
sqlite3session_foreach c $changeset { lappend x $c }
set x
} [list \
{UPDATE t1 0 X. {i 1 t one} {{} {} t five}} \
{UPDATE t1 0 X. {i 2 t two} {{} {} t six}} \
]
do_test 7.1.4 {
list [catch {sqlite3changeset_apply db2 $changeset xConflict} msg] $msg
} {1 SQLITE_MISUSE}
do_test 7.1.5 { execsql { SELECT * FROM t1 } db2 } {1 one}
do_test 7.2.1 {
set changeset [changeset_from_sql { UPDATE t1 SET b = NULL WHERE a = 1 }]
set x [list]
sqlite3session_foreach c $changeset { lappend x $c }
set x
} [list \
{UPDATE t1 0 X. {i 1 t five} {{} {} n {}}} \
]
do_test 7.2.2 {
list [catch {sqlite3changeset_apply db2 $changeset xConflict} msg] $msg
} {1 SQLITE_MISUSE}
do_test 7.2.3 { execsql { SELECT * FROM t1 } db2 } {1 one}
#-------------------------------------------------------------------------
# Test that if a conflict-handler returns ABORT, application of the
# changeset is rolled back and the sqlite3changeset_apply() method returns
# SQLITE_ABORT.
#
# Also test that the same thing happens if a conflict handler returns an
# unrecognized integer value. Except, in this case SQLITE_MISUSE is returned
# instead of SQLITE_ABORT.
#
foreach {tn conflict_return apply_return} {
1 ABORT SQLITE_ABORT
2 567 SQLITE_MISUSE
} {
test_reset
proc xConflict {args} [list return $conflict_return]
do_test 8.$tn.0 {
do_common_sql {
CREATE TABLE t1(x, y, PRIMARY KEY(x, y));
INSERT INTO t1 VALUES('x', 'y');
}
execsql { INSERT INTO t1 VALUES('w', 'w') }
set changeset [changeset_from_sql { DELETE FROM t1 WHERE 1 }]
set x [list]
sqlite3session_foreach c $changeset { lappend x $c }
set x
} [list \
{DELETE t1 0 XX {t w t w} {}} \
{DELETE t1 0 XX {t x t y} {}} \
]
do_test 8.$tn.1 {
list [catch {sqlite3changeset_apply db2 $changeset xConflict} msg] $msg
} [list 1 $apply_return]
do_test 8.$tn.2 {
execsql {SELECT * FROM t1} db2
} {x y}
}
#-------------------------------------------------------------------------
# Try to cause an infinite loop as follows:
#
# 1. Have a changeset insert a row that causes a CONFLICT callback,
# 2. Have the conflict handler return REPLACE,
# 3. After the session module deletes the conflicting row, have a trigger
# re-insert it.
# 4. Goto step 1...
#
# This doesn't work, as the second invocation of the conflict handler is a
# CONSTRAINT, not a CONFLICT. There is at most one CONFLICT callback for
# each change in the changeset.
#
test_reset
proc xConflict {type args} {
if {$type == "CONFLICT"} { return REPLACE }
return OMIT
}
do_test 9.1 {
execsql {
CREATE TABLE t1(a PRIMARY KEY, b);
}
execsql {
CREATE TABLE t1(a PRIMARY KEY, b);
INSERT INTO t1 VALUES('x', 2);
CREATE TRIGGER tr1 AFTER DELETE ON t1 BEGIN
INSERT INTO t1 VALUES(old.a, old.b);
END;
} db2
} {}
do_test 9.2 {
set changeset [changeset_from_sql { INSERT INTO t1 VALUES('x', 1) }]
sqlite3changeset_apply db2 $changeset xConflict
} {}
do_test 9.3 {
execsql { SELECT * FROM t1 } db2
} {x 2}
#-------------------------------------------------------------------------
#
test_reset
db function enable [list S enable]
do_common_sql {
CREATE TABLE t1(a PRIMARY KEY, b);
INSERT INTO t1 VALUES('x', 'X');
}
do_iterator_test 10.1 t1 {
INSERT INTO t1 VALUES('y', 'Y');
SELECT enable(0);
INSERT INTO t1 VALUES('z', 'Z');
SELECT enable(1);
} {
{INSERT t1 0 X. {} {t y t Y}}
}
sqlite3session S db main
do_execsql_test 10.2 {
SELECT enable(0);
SELECT enable(-1);
SELECT enable(1);
SELECT enable(-1);
} {0 0 1 1}
S delete
finish_test