# 2010 June 15
#
# 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.
#
#***********************************************************************
#
set testdir [file dirname $argv0]
source $testdir/tester.tcl
source $testdir/lock_common.tcl
source $testdir/malloc_common.tcl
source $testdir/wal_common.tcl
# Do not use a codec for tests in this file, as the database file is
# manipulated directly using tcl scripts (using the [hexio_write] command).
#
do_not_use_codec
#
# pager1-1.*: Test inter-process locking (clients in multiple processes).
#
# pager1-2.*: Test intra-process locking (multiple clients in this process).
#
# pager1-3.*: Savepoint related tests.
#
# pager1-4.*: Hot-journal related tests.
#
# pager1-5.*: Cases related to multi-file commits.
#
# pager1-6.*: Cases related to "PRAGMA max_page_count"
#
# pager1-7.*: Cases specific to "PRAGMA journal_mode=TRUNCATE"
#
# pager1-8.*: Cases using temporary and in-memory databases.
#
# pager1-9.*: Tests related to the backup API.
#
# pager1-10.*: Test that the assumed file-system sector-size is limited to
# 64KB.
#
# pager1-12.*: Tests involving "PRAGMA page_size"
#
# pager1-13.*: Cases specific to "PRAGMA journal_mode=PERSIST"
#
# pager1-14.*: Cases specific to "PRAGMA journal_mode=OFF"
#
# pager1-15.*: Varying sqlite3_vfs.szOsFile
#
# pager1-16.*: Varying sqlite3_vfs.mxPathname
#
# pager1-17.*: Tests related to "PRAGMA omit_readlock"
#
# pager1-18.*: Test that the pager layer responds correctly if the b-tree
# requests an invalid page number (due to db corruption).
#
proc recursive_select {id table {script {}}} {
set cnt 0
db eval "SELECT rowid, * FROM $table WHERE rowid = ($id-1)" {
recursive_select $rowid $table $script
incr cnt
}
if {$cnt==0} { eval $script }
}
set a_string_counter 1
proc a_string {n} {
global a_string_counter
incr a_string_counter
string range [string repeat "${a_string_counter}." $n] 1 $n
}
db func a_string a_string
do_multiclient_test tn {
# Create and populate a database table using connection [db]. Check
# that connections [db2] and [db3] can see the schema and content.
#
do_test pager1-$tn.1 {
sql1 {
CREATE TABLE t1(a PRIMARY KEY, b);
CREATE INDEX i1 ON t1(b);
INSERT INTO t1 VALUES(1, 'one'); INSERT INTO t1 VALUES(2, 'two');
}
} {}
do_test pager1-$tn.2 { sql2 { SELECT * FROM t1 } } {1 one 2 two}
do_test pager1-$tn.3 { sql3 { SELECT * FROM t1 } } {1 one 2 two}
# Open a transaction and add a row using [db]. This puts [db] in
# RESERVED state. Check that connections [db2] and [db3] can still
# read the database content as it was before the transaction was
# opened. [db] should see the inserted row.
#
do_test pager1-$tn.4 {
sql1 {
BEGIN;
INSERT INTO t1 VALUES(3, 'three');
}
} {}
do_test pager1-$tn.5 { sql2 { SELECT * FROM t1 } } {1 one 2 two}
do_test pager1-$tn.7 { sql1 { SELECT * FROM t1 } } {1 one 2 two 3 three}
# [db] still has an open write transaction. Check that this prevents
# other connections (specifically [db2]) from writing to the database.
#
# Even if [db2] opens a transaction first, it may not write to the
# database. After the attempt to write the db within a transaction,
# [db2] is left with an open transaction, but not a read-lock on
# the main database. So it does not prevent [db] from committing.
#
do_test pager1-$tn.8 {
csql2 { UPDATE t1 SET a = a + 10 }
} {1 {database is locked}}
do_test pager1-$tn.9 {
csql2 {
BEGIN;
UPDATE t1 SET a = a + 10;
}
} {1 {database is locked}}
# Have [db] commit its transactions. Check the other connections can
# now see the new database content.
#
do_test pager1-$tn.10 { sql1 { COMMIT } } {}
do_test pager1-$tn.11 { sql1 { SELECT * FROM t1 } } {1 one 2 two 3 three}
do_test pager1-$tn.12 { sql2 { SELECT * FROM t1 } } {1 one 2 two 3 three}
do_test pager1-$tn.13 { sql3 { SELECT * FROM t1 } } {1 one 2 two 3 three}
# Check that, as noted above, [db2] really did keep an open transaction
# after the attempt to write the database failed.
#
do_test pager1-$tn.14 {
csql2 { BEGIN }
} {1 {cannot start a transaction within a transaction}}
do_test pager1-$tn.15 { sql2 { ROLLBACK } } {}
# Have [db2] open a transaction and take a read-lock on the database.
# Check that this prevents [db] from writing to the database (outside
# of any transaction). After this fails, check that [db3] can read
# the db (showing that [db] did not take a PENDING lock etc.)
#
do_test pager1-$tn.15 {
sql2 { BEGIN; SELECT * FROM t1; }
} {1 one 2 two 3 three}
do_test pager1-$tn.16 {
csql1 { UPDATE t1 SET a = a + 10 }
} {1 {database is locked}}
do_test pager1-$tn.17 { sql3 { SELECT * FROM t1 } } {1 one 2 two 3 three}
# This time, have [db] open a transaction before writing the database.
# This works - [db] gets a RESERVED lock which does not conflict with
# the SHARED lock [db2] is holding.
#
do_test pager1-$tn.18 {
sql1 {
BEGIN;
UPDATE t1 SET a = a + 10;
}
} {}
do_test pager1-$tn-19 {
sql1 { PRAGMA lock_status }
} {main reserved temp closed}
do_test pager1-$tn-20 {
sql2 { PRAGMA lock_status }
} {main shared temp closed}
# Check that all connections can still read the database. Only [db] sees
# the updated content (as the transaction has not been committed yet).
#
do_test pager1-$tn.21 { sql1 { SELECT * FROM t1 } } {11 one 12 two 13 three}
do_test pager1-$tn.22 { sql2 { SELECT * FROM t1 } } {1 one 2 two 3 three}
do_test pager1-$tn.23 { sql3 { SELECT * FROM t1 } } {1 one 2 two 3 three}
# Because [db2] still has the SHARED lock, [db] is unable to commit the
# transaction. If it tries, an error is returned and the connection
# upgrades to a PENDING lock.
#
# Once this happens, [db] can read the database and see the new content,
# [db2] (still holding SHARED) can still read the old content, but [db3]
# (not holding any lock) is prevented by [db]'s PENDING from reading
# the database.
#
do_test pager1-$tn.24 { csql1 { COMMIT } } {1 {database is locked}}
do_test pager1-$tn-25 {
sql1 { PRAGMA lock_status }
} {main pending temp closed}
do_test pager1-$tn.26 { sql1 { SELECT * FROM t1 } } {11 one 12 two 13 three}
do_test pager1-$tn.27 { sql2 { SELECT * FROM t1 } } {1 one 2 two 3 three}
do_test pager1-$tn.28 { csql3 { SELECT * FROM t1 } } {1 {database is locked}}
# Have [db2] commit its read transaction, releasing the SHARED lock it
# is holding. Now, neither [db2] nor [db3] may read the database (as [db]
# is still holding a PENDING).
#
do_test pager1-$tn.29 { sql2 { COMMIT } } {}
do_test pager1-$tn.30 { csql2 { SELECT * FROM t1 } } {1 {database is locked}}
do_test pager1-$tn.31 { csql3 { SELECT * FROM t1 } } {1 {database is locked}}
# [db] is now able to commit the transaction. Once the transaction is
# committed, all three connections can read the new content.
#
do_test pager1-$tn.25 { sql1 { UPDATE t1 SET a = a+10 } } {}
do_test pager1-$tn.26 { sql1 { COMMIT } } {}
do_test pager1-$tn.27 { sql1 { SELECT * FROM t1 } } {21 one 22 two 23 three}
do_test pager1-$tn.27 { sql2 { SELECT * FROM t1 } } {21 one 22 two 23 three}
do_test pager1-$tn.28 { sql3 { SELECT * FROM t1 } } {21 one 22 two 23 three}
# Install a busy-handler for connection [db].
#
set ::nbusy [list]
proc busy {n} {
lappend ::nbusy $n
if {$n>5} { sql2 COMMIT }
return 0
}
db busy busy
do_test pager1-$tn.29 {
sql1 { BEGIN ; INSERT INTO t1 VALUES('x', 'y') }
} {}
do_test pager1-$tn.30 {
sql2 { BEGIN ; SELECT * FROM t1 }
} {21 one 22 two 23 three}
do_test pager1-$tn.31 { sql1 COMMIT } {}
do_test pager1-$tn.32 { set ::nbusy } {0 1 2 3 4 5 6}
}
#-------------------------------------------------------------------------
# Savepoint related test cases.
#
# pager1-3.1.2.*: Force a savepoint rollback to cause the database file
# to grow.
#
# pager1-3.1.3.*: Use a journal created in synchronous=off mode as part
# of a savepoint rollback.
#
do_test pager1-3.1.1 {
faultsim_delete_and_reopen
execsql {
CREATE TABLE t1(a PRIMARY KEY, b);
CREATE TABLE counter(
i CHECK (i<5),
u CHECK (u<10)
);
INSERT INTO counter VALUES(0, 0);
CREATE TRIGGER tr1 AFTER INSERT ON t1 BEGIN
UPDATE counter SET i = i+1;
END;
CREATE TRIGGER tr2 AFTER UPDATE ON t1 BEGIN
UPDATE counter SET u = u+1;
END;
}
execsql { SELECT * FROM counter }
} {0 0}
do_execsql_test pager1-3.1.2 {
PRAGMA cache_size = 10;
BEGIN;
INSERT INTO t1 VALUES(1, randomblob(1500));
INSERT INTO t1 VALUES(2, randomblob(1500));
INSERT INTO t1 VALUES(3, randomblob(1500));
SELECT * FROM counter;
} {3 0}
do_catchsql_test pager1-3.1.3 {
INSERT INTO t1 SELECT a+3, randomblob(1500) FROM t1
} {1 {constraint failed}}
do_execsql_test pager1-3.4 { SELECT * FROM counter } {3 0}
do_execsql_test pager1-3.5 { SELECT a FROM t1 } {1 2 3}
do_execsql_test pager1-3.6 { COMMIT } {}
foreach {tn sql tcl} {
7 { PRAGMA synchronous = NORMAL ; PRAGMA temp_store = 0 } {
testvfs tv -default 1
tv devchar safe_append
}
8 { PRAGMA synchronous = NORMAL ; PRAGMA temp_store = 2 } {
testvfs tv -default 1
tv devchar sequential
}
9 { PRAGMA synchronous = FULL } { }
10 { PRAGMA synchronous = NORMAL } { }
11 { PRAGMA synchronous = OFF } { }
12 { PRAGMA synchronous = FULL ; PRAGMA fullfsync = 1 } { }
13 { PRAGMA synchronous = FULL } {
testvfs tv -default 1
tv devchar sequential
}
14 { PRAGMA locking_mode = EXCLUSIVE } {
}
} {
do_test pager1-3.$tn.1 {
eval $tcl
faultsim_delete_and_reopen
db func a_string a_string
execsql $sql
execsql {
PRAGMA auto_vacuum = 2;
PRAGMA cache_size = 10;
CREATE TABLE z(x INTEGER PRIMARY KEY, y);
BEGIN;
INSERT INTO z VALUES(NULL, a_string(800));
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 2
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 4
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 8
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 16
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 32
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 64
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 128
INSERT INTO z SELECT NULL, a_string(800) FROM z; -- 256
COMMIT;
}
execsql { PRAGMA auto_vacuum }
} {2}
do_execsql_test pager1-3.$tn.2 {
BEGIN;
INSERT INTO z VALUES(NULL, a_string(800));
INSERT INTO z VALUES(NULL, a_string(800));
SAVEPOINT one;
UPDATE z SET y = NULL WHERE x>256;
PRAGMA incremental_vacuum;
SELECT count(*) FROM z WHERE x < 100;
ROLLBACK TO one;
COMMIT;
} {99}
do_execsql_test pager1-3.$tn.3 {
BEGIN;
SAVEPOINT one;
UPDATE z SET y = y||x;
ROLLBACK TO one;
COMMIT;
SELECT count(*) FROM z;
} {258}
do_execsql_test pager1-3.$tn.4 {
SAVEPOINT one;
UPDATE z SET y = y||x;
ROLLBACK TO one;
} {}
do_execsql_test pager1-3.$tn.5 {
SELECT count(*) FROM z;
RELEASE one;
PRAGMA integrity_check;
} {258 ok}
do_execsql_test pager1-3.$tn.6 {
SAVEPOINT one;
RELEASE one;
} {}
db close
catch { tv delete }
}
#-------------------------------------------------------------------------
# Hot journal rollback related test cases.
#
# pager1.4.1.*: Test that the pager module deletes very small invalid
# journal files.
#
# pager1.4.2.*: Test that if the master journal pointer at the end of a
# hot-journal file appears to be corrupt (checksum does not
# compute) the associated journal is rolled back (and no
# xAccess() call to check for the presence of any master
# journal file is made).
#
# pager1.4.3.*: Test that the contents of a hot-journal are ignored if the
# page-size or sector-size in the journal header appear to
# be invalid (too large, too small or not a power of 2).
#
# pager1.4.4.*: Test hot-journal rollback of journal file with a master
# journal pointer generated in various "PRAGMA synchronous"
# modes.
#
# pager1.4.5.*: Test that hot-journal rollback stops if it encounters a
# journal-record for which the checksum fails.
#
# pager1.4.6.*: Test that when rolling back a hot-journal that contains a
# master journal pointer, the master journal file is deleted
# after all the hot-journals that refer to it are deleted.
#
# pager1.4.7.*: Test that if a hot-journal file exists but a client can
# open it for reading only, the database cannot be accessed and
# SQLITE_CANTOPEN is returned.
#
do_test pager1.4.1.1 {
faultsim_delete_and_reopen
execsql {
CREATE TABLE x(y, z);
INSERT INTO x VALUES(1, 2);
}
set fd [open test.db-journal w]
puts -nonewline $fd "helloworld"
close $fd
file exists test.db-journal
} {1}
do_test pager1.4.1.2 { execsql { SELECT * FROM x } } {1 2}
do_test pager1.4.1.3 { file exists test.db-journal } {0}
# Set up a [testvfs] to snapshot the file-system just before SQLite
# deletes the master-journal to commit a multi-file transaction.
#
# In subsequent test cases, invoking [faultsim_restore_and_reopen] sets
# up the file system to contain two databases, two hot-journal files and
# a master-journal.
#
do_test pager1.4.2.1 {
testvfs tstvfs -default 1
tstvfs filter xDelete
tstvfs script xDeleteCallback
proc xDeleteCallback {method file args} {
set file [file tail $file]
if { [string match *mj* $file] } { faultsim_save }
}
faultsim_delete_and_reopen
db func a_string a_string
execsql {
ATTACH 'test.db2' AS aux;
PRAGMA journal_mode = DELETE;
PRAGMA main.cache_size = 10;
PRAGMA aux.cache_size = 10;
CREATE TABLE t1(a UNIQUE, b UNIQUE);
CREATE TABLE aux.t2(a UNIQUE, b UNIQUE);
INSERT INTO t1 VALUES(a_string(200), a_string(300));
INSERT INTO t1 SELECT a_string(200), a_string(300) FROM t1;
INSERT INTO t1 SELECT a_string(200), a_string(300) FROM t1;
INSERT INTO t2 SELECT * FROM t1;
BEGIN;
INSERT INTO t1 SELECT a_string(201), a_string(301) FROM t1;
INSERT INTO t1 SELECT a_string(202), a_string(302) FROM t1;
INSERT INTO t1 SELECT a_string(203), a_string(303) FROM t1;
INSERT INTO t1 SELECT a_string(204), a_string(304) FROM t1;
REPLACE INTO t2 SELECT * FROM t1;
COMMIT;
}
db close
tstvfs delete
} {}
if {$::tcl_platform(platform)!="windows"} {
do_test pager1.4.2.2 {
faultsim_restore_and_reopen
execsql {
SELECT count(*) FROM t1;
PRAGMA integrity_check;
}
} {4 ok}
do_test pager1.4.2.3 {
faultsim_restore_and_reopen
foreach f [glob test.db-mj*] { forcedelete $f }
execsql {
SELECT count(*) FROM t1;
PRAGMA integrity_check;
}
} {64 ok}
do_test pager1.4.2.4 {
faultsim_restore_and_reopen
hexio_write test.db-journal [expr [file size test.db-journal]-20] 123456
execsql {
SELECT count(*) FROM t1;
PRAGMA integrity_check;
}
} {4 ok}
do_test pager1.4.2.5 {
faultsim_restore_and_reopen
hexio_write test.db-journal [expr [file size test.db-journal]-20] 123456
foreach f [glob test.db-mj*] { forcedelete $f }
execsql {
SELECT count(*) FROM t1;
PRAGMA integrity_check;
}
} {4 ok}
}
do_test pager1.4.3.1 {
testvfs tstvfs -default 1
tstvfs filter xSync
tstvfs script xSyncCallback
proc xSyncCallback {method file args} {
set file [file tail $file]
if { 0==[string match *journal $file] } { faultsim_save }
}
faultsim_delete_and_reopen
execsql {
PRAGMA journal_mode = DELETE;
CREATE TABLE t1(a, b);
INSERT INTO t1 VALUES(1, 2);
INSERT INTO t1 VALUES(3, 4);
}
db close
tstvfs delete
} {}
foreach {tn ofst value result} {
2 20 31 {1 2 3 4}
3 20 32 {1 2 3 4}
4 20 33 {1 2 3 4}
5 20 65536 {1 2 3 4}
6 20 131072 {1 2 3 4}
7 24 511 {1 2 3 4}
8 24 513 {1 2 3 4}
9 24 131072 {1 2 3 4}
10 32 65536 {1 2}
} {
do_test pager1.4.3.$tn {
faultsim_restore_and_reopen
hexio_write test.db-journal $ofst [format %.8x $value]
execsql { SELECT * FROM t1 }
} $result
}
db close
# Set up a VFS that snapshots the file-system just before a master journal
# file is deleted to commit a multi-file transaction. Specifically, the
# file-system is saved just before the xDelete() call to remove the
# master journal file from the file-system.
#
testvfs tv -default 1
tv script copy_on_mj_delete
set ::mj_filename_length 0
proc copy_on_mj_delete {method filename args} {
if {[string match *mj* [file tail $filename]]} {
set ::mj_filename_length [string length $filename]
faultsim_save
}
return SQLITE_OK
}
set pwd [pwd]
foreach {tn1 tcl} {
1 { set prefix "test.db" }
2 {
# This test depends on the underlying VFS being able to open paths
# 512 bytes in length. The idea is to create a hot-journal file that
# contains a master-journal pointer so large that it could contain
# a valid page record (if the file page-size is 512 bytes). So as to
# make sure SQLite doesn't get confused by this.
#
set nPadding [expr 511 - $::mj_filename_length]
if {$tcl_platform(platform)=="windows"} {
# TBD need to figure out how to do this correctly for Windows!!!
set nPadding [expr 255 - $::mj_filename_length]
}
# We cannot just create a really long database file name to open, as
# Linux limits a single component of a path to 255 bytes by default
# (and presumably other systems have limits too). So create a directory
# hierarchy to work in.
#
set dirname "d123456789012345678901234567890/"
set nDir [expr $nPadding / 32]
if { $nDir } {
set p [string repeat $dirname $nDir]
file mkdir $p
cd $p
}
set padding [string repeat x [expr $nPadding %32]]
set prefix "test.db${padding}"
}
} {
eval $tcl
foreach {tn2 sql} {
o {
PRAGMA main.synchronous=OFF;
PRAGMA aux.synchronous=OFF;
PRAGMA journal_mode = DELETE;
}
o512 {
PRAGMA main.synchronous=OFF;
PRAGMA aux.synchronous=OFF;
PRAGMA main.page_size = 512;
PRAGMA aux.page_size = 512;
PRAGMA journal_mode = DELETE;
}
n {
PRAGMA main.synchronous=NORMAL;
PRAGMA aux.synchronous=NORMAL;
PRAGMA journal_mode = DELETE;
}
f {
PRAGMA main.synchronous=FULL;
PRAGMA aux.synchronous=FULL;
PRAGMA journal_mode = DELETE;
}
} {
set tn "${tn1}.${tn2}"
# Set up a connection to have two databases, test.db (main) and
# test.db2 (aux). Then run a multi-file transaction on them. The
# VFS will snapshot the file-system just before the master-journal
# file is deleted to commit the transaction.
#
tv filter xDelete
do_test pager1-4.4.$tn.1 {
faultsim_delete_and_reopen $prefix
execsql "
ATTACH '${prefix}2' AS aux;
$sql
CREATE TABLE a(x);
CREATE TABLE aux.b(x);
INSERT INTO a VALUES('double-you');
INSERT INTO a VALUES('why');
INSERT INTO a VALUES('zed');
INSERT INTO b VALUES('won');
INSERT INTO b VALUES('too');
INSERT INTO b VALUES('free');
"
execsql {
BEGIN;
INSERT INTO a SELECT * FROM b WHERE rowid<=3;
INSERT INTO b SELECT * FROM a WHERE rowid<=3;
COMMIT;
}
} {}
tv filter {}
# Check that the transaction was committed successfully.
#
do_execsql_test pager1-4.4.$tn.2 {
SELECT * FROM a
} {double-you why zed won too free}
do_execsql_test pager1-4.4.$tn.3 {
SELECT * FROM b
} {won too free double-you why zed}
# Restore the file-system and reopen the databases. Check that it now
# appears that the transaction was not committed (because the file-system
# was restored to the state where it had not been).
#
do_test pager1-4.4.$tn.4 {
faultsim_restore_and_reopen $prefix
execsql "ATTACH '${prefix}2' AS aux"
} {}
do_execsql_test pager1-4.4.$tn.5 {SELECT * FROM a} {double-you why zed}
do_execsql_test pager1-4.4.$tn.6 {SELECT * FROM b} {won too free}
# Restore the file-system again. This time, before reopening the databases,
# delete the master-journal file from the file-system. It now appears that
# the transaction was committed (no master-journal file == no rollback).
#
do_test pager1-4.4.$tn.7 {
faultsim_restore_and_reopen $prefix
foreach f [glob ${prefix}-mj*] { forcedelete $f }
execsql "ATTACH '${prefix}2' AS aux"
} {}
do_execsql_test pager1-4.4.$tn.8 {
SELECT * FROM a
} {double-you why zed won too free}
do_execsql_test pager1-4.4.$tn.9 {
SELECT * FROM b
} {won too free double-you why zed}
}
cd $pwd
}
db close
tv delete
forcedelete $dirname
# Set up a VFS to make a copy of the file-system just before deleting a
# journal file to commit a transaction. The transaction modifies exactly
# two database pages (and page 1 - the change counter).
#
testvfs tv -default 1
tv sectorsize 512
tv script copy_on_journal_delete
tv filter xDelete
proc copy_on_journal_delete {method filename args} {
if {[string match *journal $filename]} faultsim_save
return SQLITE_OK
}
faultsim_delete_and_reopen
do_execsql_test pager1.4.5.1 {
PRAGMA journal_mode = DELETE;
PRAGMA page_size = 1024;
CREATE TABLE t1(a, b);
CREATE TABLE t2(a, b);
INSERT INTO t1 VALUES('I', 'II');
INSERT INTO t2 VALUES('III', 'IV');
BEGIN;
INSERT INTO t1 VALUES(1, 2);
INSERT INTO t2 VALUES(3, 4);
COMMIT;
} {delete}
tv filter {}
# Check the transaction was committed:
#
do_execsql_test pager1.4.5.2 {
SELECT * FROM t1;
SELECT * FROM t2;
} {I II 1 2 III IV 3 4}
# Now try four tests:
#
# pager1-4.5.3: Restore the file-system. Check that the whole transaction
# is rolled back.
#
# pager1-4.5.4: Restore the file-system. Corrupt the first record in the
# journal. Check the transaction is not rolled back.
#
# pager1-4.5.5: Restore the file-system. Corrupt the second record in the
# journal. Check that the first record in the transaction is
# played back, but not the second.
#
# pager1-4.5.6: Restore the file-system. Try to open the database with a
# readonly connection. This should fail, as a read-only
# connection cannot roll back the database file.
#
faultsim_restore_and_reopen
do_execsql_test pager1.4.5.3 {
SELECT * FROM t1;
SELECT * FROM t2;
} {I II III IV}
faultsim_restore_and_reopen
hexio_write test.db-journal [expr 512+4+1024 - 202] 0123456789ABCDEF
do_execsql_test pager1.4.5.4 {
SELECT * FROM t1;
SELECT * FROM t2;
} {I II 1 2 III IV 3 4}
faultsim_restore_and_reopen
hexio_write test.db-journal [expr 512+4+1024+4+4+1024 - 202] 0123456789ABCDEF
do_execsql_test pager1.4.5.5 {
SELECT * FROM t1;
SELECT * FROM t2;
} {I II III IV 3 4}
faultsim_restore_and_reopen
db close
sqlite3 db test.db -readonly 1
do_catchsql_test pager1.4.5.6 {
SELECT * FROM t1;
SELECT * FROM t2;
} {1 {disk I/O error}}
db close
# Snapshot the file-system just before multi-file commit. Save the name
# of the master journal file in $::mj_filename.
#
tv script copy_on_mj_delete
tv filter xDelete
proc copy_on_mj_delete {method filename args} {
if {[string match *mj* [file tail $filename]]} {
set ::mj_filename $filename
faultsim_save
}
return SQLITE_OK
}
do_test pager1.4.6.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA journal_mode = DELETE;
ATTACH 'test.db2' AS two;
CREATE TABLE t1(a, b);
CREATE TABLE two.t2(a, b);
INSERT INTO t1 VALUES(1, 't1.1');
INSERT INTO t2 VALUES(1, 't2.1');
BEGIN;
UPDATE t1 SET b = 't1.2';
UPDATE t2 SET b = 't2.2';
COMMIT;
}
tv filter {}
db close
} {}
faultsim_restore_and_reopen
do_execsql_test pager1.4.6.2 { SELECT * FROM t1 } {1 t1.1}
do_test pager1.4.6.3 { file exists $::mj_filename } {1}
do_execsql_test pager1.4.6.4 {
ATTACH 'test.db2' AS two;
SELECT * FROM t2;
} {1 t2.1}
do_test pager1.4.6.5 { file exists $::mj_filename } {0}
faultsim_restore_and_reopen
db close
do_test pager1.4.6.8 {
set ::mj_filename1 $::mj_filename
tv filter xDelete
sqlite3 db test.db2
execsql {
PRAGMA journal_mode = DELETE;
ATTACH 'test.db3' AS three;
CREATE TABLE three.t3(a, b);
INSERT INTO t3 VALUES(1, 't3.1');
BEGIN;
UPDATE t2 SET b = 't2.3';
UPDATE t3 SET b = 't3.3';
COMMIT;
}
expr {$::mj_filename1 != $::mj_filename}
} {1}
faultsim_restore_and_reopen
tv filter {}
# The file-system now contains:
#
# * three databases
# * three hot-journal files
# * two master-journal files.
#
# The hot-journals associated with test.db2 and test.db3 point to
# master journal $::mj_filename. The hot-journal file associated with
# test.db points to master journal $::mj_filename1. So reading from
# test.db should delete $::mj_filename1.
#
do_test pager1.4.6.9 {
lsort [glob test.db*]
} [lsort [list \
test.db test.db2 test.db3 \
test.db-journal test.db2-journal test.db3-journal \
[file tail $::mj_filename] [file tail $::mj_filename1]
]]
# The master-journal $::mj_filename1 contains pointers to test.db and
# test.db2. However the hot-journal associated with test.db2 points to
# a different master-journal. Therefore, reading from test.db only should
# be enough to cause SQLite to delete $::mj_filename1.
#
do_test pager1.4.6.10 { file exists $::mj_filename } {1}
do_test pager1.4.6.11 { file exists $::mj_filename1 } {1}
do_execsql_test pager1.4.6.12 { SELECT * FROM t1 } {1 t1.1}
do_test pager1.4.6.13 { file exists $::mj_filename } {1}
do_test pager1.4.6.14 { file exists $::mj_filename1 } {0}
do_execsql_test pager1.4.6.12 {
ATTACH 'test.db2' AS two;
SELECT * FROM t2;
} {1 t2.1}
do_test pager1.4.6.13 { file exists $::mj_filename } {1}
do_execsql_test pager1.4.6.14 {
ATTACH 'test.db3' AS three;
SELECT * FROM t3;
} {1 t3.1}
do_test pager1.4.6.15 { file exists $::mj_filename } {0}
db close
tv delete
testvfs tv -default 1
tv sectorsize 512
tv script copy_on_journal_delete
tv filter xDelete
proc copy_on_journal_delete {method filename args} {
if {[string match *journal $filename]} faultsim_save
return SQLITE_OK
}
faultsim_delete_and_reopen
do_execsql_test pager1.4.7.1 {
PRAGMA journal_mode = DELETE;
CREATE TABLE t1(x PRIMARY KEY, y);
CREATE INDEX i1 ON t1(y);
INSERT INTO t1 VALUES('I', 'one');
INSERT INTO t1 VALUES('II', 'four');
INSERT INTO t1 VALUES('III', 'nine');
BEGIN;
INSERT INTO t1 VALUES('IV', 'sixteen');
INSERT INTO t1 VALUES('V' , 'twentyfive');
COMMIT;
} {delete}
tv filter {}
db close
tv delete
do_test pager1.4.7.2 {
faultsim_restore_and_reopen
catch {file attributes test.db-journal -permissions r--------}
catch {file attributes test.db-journal -readonly 1}
catchsql { SELECT * FROM t1 }
} {1 {unable to open database file}}
do_test pager1.4.7.3 {
db close
catch {file attributes test.db-journal -permissions rw-rw-rw-}
catch {file attributes test.db-journal -readonly 0}
delete_file test.db-journal
file exists test.db-journal
} {0}
#-------------------------------------------------------------------------
# The following tests deal with multi-file commits.
#
# pager1-5.1.*: The case where a multi-file cannot be committed because
# another connection is holding a SHARED lock on one of the
# files. After the SHARED lock is removed, the COMMIT succeeds.
#
# pager1-5.2.*: Multi-file commits with journal_mode=memory.
#
# pager1-5.3.*: Multi-file commits with journal_mode=memory.
#
# pager1-5.4.*: Check that with synchronous=normal, the master-journal file
# name is added to a journal file immediately after the last
# journal record. But with synchronous=full, extra unused space
# is allocated between the last journal record and the
# master-journal file name so that the master-journal file
# name does not lie on the same sector as the last journal file
# record.
#
# pager1-5.5.*: Check that in journal_mode=PERSIST mode, a journal file is
# truncated to zero bytes when a multi-file transaction is
# committed (instead of the first couple of bytes being zeroed).
#
#
do_test pager1-5.1.1 {
faultsim_delete_and_reopen
execsql {
ATTACH 'test.db2' AS aux;
CREATE TABLE t1(a, b);
CREATE TABLE aux.t2(a, b);
INSERT INTO t1 VALUES(17, 'Lenin');
INSERT INTO t1 VALUES(22, 'Stalin');
INSERT INTO t1 VALUES(53, 'Khrushchev');
}
} {}
do_test pager1-5.1.2 {
execsql {
BEGIN;
INSERT INTO t1 VALUES(64, 'Brezhnev');
INSERT INTO t2 SELECT * FROM t1;
}
sqlite3 db2 test.db2
execsql {
BEGIN;
SELECT * FROM t2;
} db2
} {}
do_test pager1-5.1.3 {
catchsql COMMIT
} {1 {database is locked}}
do_test pager1-5.1.4 {
execsql COMMIT db2
execsql COMMIT
execsql { SELECT * FROM t2 } db2
} {17 Lenin 22 Stalin 53 Khrushchev 64 Brezhnev}
do_test pager1-5.1.5 {
db2 close
} {}
do_test pager1-5.2.1 {
execsql {
PRAGMA journal_mode = memory;
BEGIN;
INSERT INTO t1 VALUES(84, 'Andropov');
INSERT INTO t2 VALUES(84, 'Andropov');
COMMIT;
}
} {memory}
do_test pager1-5.3.1 {
execsql {
PRAGMA journal_mode = off;
BEGIN;
INSERT INTO t1 VALUES(85, 'Gorbachev');
INSERT INTO t2 VALUES(85, 'Gorbachev');
COMMIT;
}
} {off}
do_test pager1-5.4.1 {
db close
testvfs tv
sqlite3 db test.db -vfs tv
execsql { ATTACH 'test.db2' AS aux }
tv filter xDelete
tv script max_journal_size
tv sectorsize 512
set ::max_journal 0
proc max_journal_size {method args} {
set sz 0
catch { set sz [file size test.db-journal] }
if {$sz > $::max_journal} {
set ::max_journal $sz
}
return SQLITE_OK
}
execsql {
PRAGMA journal_mode = DELETE;
PRAGMA synchronous = NORMAL;
BEGIN;
INSERT INTO t1 VALUES(85, 'Gorbachev');
INSERT INTO t2 VALUES(85, 'Gorbachev');
COMMIT;
}
# The size of the journal file is now:
#
# 1) 512 byte header +
# 2) 2 * (1024+8) byte records +
# 3) 20+N bytes of master-journal pointer, where N is the size of
# the master-journal name encoded as utf-8 with no nul term.
#
set mj_pointer [expr {
20 + [string length [pwd]] + [string length "/test.db-mjXXXXXX9XX"]
}]
expr {$::max_journal==(512+2*(1024+8)+$mj_pointer)}
} 1
do_test pager1-5.4.2 {
set ::max_journal 0
execsql {
PRAGMA synchronous = full;
BEGIN;
DELETE FROM t1 WHERE b = 'Lenin';
DELETE FROM t2 WHERE b = 'Lenin';
COMMIT;
}
# In synchronous=full mode, the master-journal pointer is not written
# directly after the last record in the journal file. Instead, it is
# written starting at the next (in this case 512 byte) sector boundary.
#
set mj_pointer [expr {
20 + [string length [pwd]] + [string length "/test.db-mjXXXXXX9XX"]
}]
expr {$::max_journal==(((512+2*(1024+8)+511)/512)*512 + $mj_pointer)}
} 1
db close
tv delete
do_test pager1-5.5.1 {
sqlite3 db test.db
execsql {
ATTACH 'test.db2' AS aux;
PRAGMA journal_mode = PERSIST;
CREATE TABLE t3(a, b);
INSERT INTO t3 SELECT randomblob(1500), randomblob(1500) FROM t1;
UPDATE t3 SET b = randomblob(1500);
}
expr [file size test.db-journal] > 15000
} {1}
do_test pager1-5.5.2 {
execsql {
PRAGMA synchronous = full;
BEGIN;
DELETE FROM t1 WHERE b = 'Stalin';
DELETE FROM t2 WHERE b = 'Stalin';
COMMIT;
}
file size test.db-journal
} {0}
#-------------------------------------------------------------------------
# The following tests work with "PRAGMA max_page_count"
#
do_test pager1-6.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA auto_vacuum = none;
PRAGMA max_page_count = 10;
CREATE TABLE t2(a, b);
CREATE TABLE t3(a, b);
CREATE TABLE t4(a, b);
CREATE TABLE t5(a, b);
CREATE TABLE t6(a, b);
CREATE TABLE t7(a, b);
CREATE TABLE t8(a, b);
CREATE TABLE t9(a, b);
CREATE TABLE t10(a, b);
}
} {10}
do_catchsql_test pager1-6.2 {
CREATE TABLE t11(a, b)
} {1 {database or disk is full}}
do_execsql_test pager1-6.4 { PRAGMA max_page_count } {10}
do_execsql_test pager1-6.5 { PRAGMA max_page_count = 15 } {15}
do_execsql_test pager1-6.6 { CREATE TABLE t11(a, b) } {}
do_execsql_test pager1-6.7 {
BEGIN;
INSERT INTO t11 VALUES(1, 2);
PRAGMA max_page_count = 13;
} {13}
do_execsql_test pager1-6.8 {
INSERT INTO t11 VALUES(3, 4);
PRAGMA max_page_count = 10;
} {11}
do_execsql_test pager1-6.9 { COMMIT } {}
do_execsql_test pager1-6.10 { PRAGMA max_page_count = 10 } {11}
do_execsql_test pager1-6.11 { SELECT * FROM t11 } {1 2 3 4}
do_execsql_test pager1-6.12 { PRAGMA max_page_count } {11}
#-------------------------------------------------------------------------
# The following tests work with "PRAGMA journal_mode=TRUNCATE" and
# "PRAGMA locking_mode=EXCLUSIVE".
#
# Each test is specified with 5 variables. As follows:
#
# $tn: Test Number. Used as part of the [do_test] test names.
# $sql: SQL to execute.
# $res: Expected result of executing $sql.
# $js: The expected size of the journal file, in bytes, after executing
# the SQL script. Or -1 if the journal is not expected to exist.
# $ws: The expected size of the WAL file, in bytes, after executing
# the SQL script. Or -1 if the WAL is not expected to exist.
#
ifcapable wal {
faultsim_delete_and_reopen
foreach {tn sql res js ws} [subst {
1 {
CREATE TABLE t1(a, b);
PRAGMA auto_vacuum=OFF;
PRAGMA synchronous=NORMAL;
PRAGMA page_size=1024;
PRAGMA locking_mode=EXCLUSIVE;
PRAGMA journal_mode=TRUNCATE;
INSERT INTO t1 VALUES(1, 2);
} {exclusive truncate} 0 -1
2 {
BEGIN IMMEDIATE;
SELECT * FROM t1;
COMMIT;
} {1 2} 0 -1
3 {
BEGIN;
SELECT * FROM t1;
COMMIT;
} {1 2} 0 -1
4 { PRAGMA journal_mode = WAL } wal -1 -1
5 { INSERT INTO t1 VALUES(3, 4) } {} -1 [wal_file_size 1 1024]
6 { PRAGMA locking_mode = NORMAL } exclusive -1 [wal_file_size 1 1024]
7 { INSERT INTO t1 VALUES(5, 6); } {} -1 [wal_file_size 2 1024]
8 { PRAGMA journal_mode = TRUNCATE } truncate 0 -1
9 { INSERT INTO t1 VALUES(7, 8) } {} 0 -1
10 { SELECT * FROM t1 } {1 2 3 4 5 6 7 8} 0 -1
}] {
do_execsql_test pager1-7.1.$tn.1 $sql $res
catch { set J -1 ; set J [file size test.db-journal] }
catch { set W -1 ; set W [file size test.db-wal] }
do_test pager1-7.1.$tn.2 { list $J $W } [list $js $ws]
}
}
do_test pager1-7.2.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA locking_mode = EXCLUSIVE;
CREATE TABLE t1(a, b);
BEGIN;
PRAGMA journal_mode = delete;
PRAGMA journal_mode = truncate;
}
} {exclusive delete truncate}
do_test pager1-7.2.2 {
execsql { INSERT INTO t1 VALUES(1, 2) }
execsql { PRAGMA journal_mode = persist }
} {truncate}
do_test pager1-7.2.3 {
execsql { COMMIT }
execsql {
PRAGMA journal_mode = persist;
PRAGMA journal_size_limit;
}
} {persist -1}
#-------------------------------------------------------------------------
# The following tests, pager1-8.*, test that the special filenames
# ":memory:" and "" open temporary databases.
#
foreach {tn filename} {
1 :memory:
2 ""
} {
do_test pager1-8.$tn.1 {
faultsim_delete_and_reopen
db close
sqlite3 db $filename
execsql {
PRAGMA auto_vacuum = 1;
CREATE TABLE x1(x);
INSERT INTO x1 VALUES('Charles');
INSERT INTO x1 VALUES('James');
INSERT INTO x1 VALUES('Mary');
SELECT * FROM x1;
}
} {Charles James Mary}
do_test pager1-8.$tn.2 {
sqlite3 db2 $filename
catchsql { SELECT * FROM x1 } db2
} {1 {no such table: x1}}
do_execsql_test pager1-8.$tn.3 {
BEGIN;
INSERT INTO x1 VALUES('William');
INSERT INTO x1 VALUES('Anne');
ROLLBACK;
} {}
}
#-------------------------------------------------------------------------
# The next block of tests - pager1-9.* - deal with interactions between
# the pager and the backup API. Test cases:
#
# pager1-9.1.*: Test that a backup completes successfully even if the
# source db is written to during the backup op.
#
# pager1-9.2.*: Test that a backup completes successfully even if the
# source db is written to and then rolled back during a
# backup operation.
#
do_test pager1-9.0.1 {
faultsim_delete_and_reopen
db func a_string a_string
execsql {
PRAGMA cache_size = 10;
BEGIN;
CREATE TABLE ab(a, b, UNIQUE(a, b));
INSERT INTO ab VALUES( a_string(200), a_string(300) );
INSERT INTO ab SELECT a_string(200), a_string(300) FROM ab;
INSERT INTO ab SELECT a_string(200), a_string(300) FROM ab;
INSERT INTO ab SELECT a_string(200), a_string(300) FROM ab;
INSERT INTO ab SELECT a_string(200), a_string(300) FROM ab;
INSERT INTO ab SELECT a_string(200), a_string(300) FROM ab;
INSERT INTO ab SELECT a_string(200), a_string(300) FROM ab;
INSERT INTO ab SELECT a_string(200), a_string(300) FROM ab;
COMMIT;
}
} {}
do_test pager1-9.0.2 {
sqlite3 db2 test.db2
db2 eval { PRAGMA cache_size = 10 }
sqlite3_backup B db2 main db main
list [B step 10000] [B finish]
} {SQLITE_DONE SQLITE_OK}
do_test pager1-9.0.3 {
db one {SELECT md5sum(a, b) FROM ab}
} [db2 one {SELECT md5sum(a, b) FROM ab}]
do_test pager1-9.1.1 {
execsql { UPDATE ab SET a = a_string(201) }
sqlite3_backup B db2 main db main
B step 30
} {SQLITE_OK}
do_test pager1-9.1.2 {
execsql { UPDATE ab SET b = a_string(301) }
list [B step 10000] [B finish]
} {SQLITE_DONE SQLITE_OK}
do_test pager1-9.1.3 {
db one {SELECT md5sum(a, b) FROM ab}
} [db2 one {SELECT md5sum(a, b) FROM ab}]
do_test pager1-9.1.4 { execsql { SELECT count(*) FROM ab } } {128}
do_test pager1-9.2.1 {
execsql { UPDATE ab SET a = a_string(202) }
sqlite3_backup B db2 main db main
B step 30
} {SQLITE_OK}
do_test pager1-9.2.2 {
execsql {
BEGIN;
UPDATE ab SET b = a_string(301);
ROLLBACK;
}
list [B step 10000] [B finish]
} {SQLITE_DONE SQLITE_OK}
do_test pager1-9.2.3 {
db one {SELECT md5sum(a, b) FROM ab}
} [db2 one {SELECT md5sum(a, b) FROM ab}]
do_test pager1-9.2.4 { execsql { SELECT count(*) FROM ab } } {128}
db close
db2 close
do_test pager1-9.3.1 {
testvfs tv -default 1
tv sectorsize 4096
faultsim_delete_and_reopen
execsql { PRAGMA page_size = 1024 }
for {set ii 0} {$ii < 4} {incr ii} { execsql "CREATE TABLE t${ii}(a, b)" }
} {}
do_test pager1-9.3.2 {
sqlite3 db2 test.db2
execsql {
PRAGMA page_size = 4096;
PRAGMA synchronous = OFF;
CREATE TABLE t1(a, b);
CREATE TABLE t2(a, b);
} db2
sqlite3_backup B db2 main db main
B step 30
list [B step 10000] [B finish]
} {SQLITE_DONE SQLITE_OK}
do_test pager1-9.3.3 {
db2 close
db close
tv delete
file size test.db2
} [file size test.db]
do_test pager1-9.4.1 {
faultsim_delete_and_reopen
sqlite3 db2 test.db2
execsql {
PRAGMA page_size = 4096;
CREATE TABLE t1(a, b);
CREATE TABLE t2(a, b);
} db2
sqlite3_backup B db2 main db main
list [B step 10000] [B finish]
} {SQLITE_DONE SQLITE_OK}
do_test pager1-9.4.2 {
list [file size test.db2] [file size test.db]
} {0 0}
db2 close
#-------------------------------------------------------------------------
# Test that regardless of the value returned by xSectorSize(), the
# minimum effective sector-size is 512 and the maximum 65536 bytes.
#
testvfs tv -default 1
foreach sectorsize {
32 64 128 256 512 1024 2048
4096 8192 16384 32768 65536 131072 262144
} {
tv sectorsize $sectorsize
tv devchar {}
set eff $sectorsize
if {$sectorsize < 512} { set eff 512 }
if {$sectorsize > 65536} { set eff 65536 }
do_test pager1-10.$sectorsize.1 {
faultsim_delete_and_reopen
db func a_string a_string
execsql {
PRAGMA journal_mode = PERSIST;
PRAGMA page_size = 1024;
BEGIN;
CREATE TABLE t1(a, b);
CREATE TABLE t2(a, b);
CREATE TABLE t3(a, b);
COMMIT;
}
file size test.db-journal
} [expr $sectorsize > 65536 ? 65536 : $sectorsize]
do_test pager1-10.$sectorsize.2 {
execsql {
INSERT INTO t3 VALUES(a_string(300), a_string(300));
INSERT INTO t3 SELECT * FROM t3; /* 2 */
INSERT INTO t3 SELECT * FROM t3; /* 4 */
INSERT INTO t3 SELECT * FROM t3; /* 8 */
INSERT INTO t3 SELECT * FROM t3; /* 16 */
INSERT INTO t3 SELECT * FROM t3; /* 32 */
}
} {}
do_test pager1-10.$sectorsize.3 {
db close
sqlite3 db test.db
execsql {
PRAGMA cache_size = 10;
BEGIN;
}
recursive_select 32 t3 {db eval "INSERT INTO t2 VALUES(1, 2)"}
execsql {
COMMIT;
SELECT * FROM t2;
}
} {1 2}
do_test pager1-10.$sectorsize.4 {
execsql {
CREATE TABLE t6(a, b);
CREATE TABLE t7(a, b);
CREATE TABLE t5(a, b);
DROP TABLE t6;
DROP TABLE t7;
}
execsql {
BEGIN;
CREATE TABLE t6(a, b);
}
recursive_select 32 t3 {db eval "INSERT INTO t5 VALUES(1, 2)"}
execsql {
COMMIT;
SELECT * FROM t5;
}
} {1 2}
}
db close
tv sectorsize 4096
do_test pager1.10.x.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA auto_vacuum = none;
PRAGMA page_size = 1024;
CREATE TABLE t1(x);
}
for {set i 0} {$i<30} {incr i} {
execsql { INSERT INTO t1 VALUES(zeroblob(900)) }
}
file size test.db
} {32768}
do_test pager1.10.x.2 {
execsql {
CREATE TABLE t2(x);
DROP TABLE t2;
}
file size test.db
} {33792}
do_test pager1.10.x.3 {
execsql {
BEGIN;
CREATE TABLE t2(x);
}
recursive_select 30 t1
execsql {
CREATE TABLE t3(x);
COMMIT;
}
} {}
db close
tv delete
testvfs tv -default 1
faultsim_delete_and_reopen
db func a_string a_string
do_execsql_test pager1-11.1 {
PRAGMA journal_mode = DELETE;
PRAGMA cache_size = 10;
BEGIN;
CREATE TABLE zz(top PRIMARY KEY);
INSERT INTO zz VALUES(a_string(222));
INSERT INTO zz SELECT a_string((SELECT 222+max(rowid) FROM zz)) FROM zz;
INSERT INTO zz SELECT a_string((SELECT 222+max(rowid) FROM zz)) FROM zz;
INSERT INTO zz SELECT a_string((SELECT 222+max(rowid) FROM zz)) FROM zz;
INSERT INTO zz SELECT a_string((SELECT 222+max(rowid) FROM zz)) FROM zz;
INSERT INTO zz SELECT a_string((SELECT 222+max(rowid) FROM zz)) FROM zz;
COMMIT;
BEGIN;
UPDATE zz SET top = a_string(345);
} {delete}
proc lockout {method args} { return SQLITE_IOERR }
tv script lockout
tv filter {xWrite xTruncate xSync}
do_catchsql_test pager1-11.2 { COMMIT } {1 {disk I/O error}}
tv script {}
do_test pager1-11.3 {
sqlite3 db2 test.db
execsql {
PRAGMA journal_mode = TRUNCATE;
PRAGMA integrity_check;
} db2
} {truncate ok}
do_test pager1-11.4 {
db2 close
file exists test.db-journal
} {0}
do_execsql_test pager1-11.5 { SELECT count(*) FROM zz } {32}
db close
tv delete
#-------------------------------------------------------------------------
# Test "PRAGMA page_size"
#
testvfs tv -default 1
tv sectorsize 1024
foreach pagesize {
512 1024 2048 4096 8192 16384 32768
} {
faultsim_delete_and_reopen
# The sector-size (according to the VFS) is 1024 bytes. So if the
# page-size requested using "PRAGMA page_size" is greater than the
# compile time value of SQLITE_MAX_PAGE_SIZE, then the effective
# page-size remains 1024 bytes.
#
set eff $pagesize
if {$eff > $::SQLITE_MAX_PAGE_SIZE} { set eff 1024 }
do_test pager1-12.$pagesize.1 {
sqlite3 db2 test.db
execsql "
PRAGMA page_size = $pagesize;
CREATE VIEW v AS SELECT * FROM sqlite_master;
" db2
file size test.db
} $eff
do_test pager1-12.$pagesize.2 {
sqlite3 db2 test.db
execsql {
SELECT count(*) FROM v;
PRAGMA main.page_size;
} db2
} [list 1 $eff]
do_test pager1-12.$pagesize.3 {
execsql {
SELECT count(*) FROM v;
PRAGMA main.page_size;
}
} [list 1 $eff]
db2 close
}
db close
tv delete
#-------------------------------------------------------------------------
# Test specal "PRAGMA journal_mode=PERSIST" test cases.
#
# pager1-13.1.*: This tests a special case encountered in persistent
# journal mode: If the journal associated with a transaction
# is smaller than the journal file (because a previous
# transaction left a very large non-hot journal file in the
# file-system), then SQLite has to be careful that there is
# not a journal-header left over from a previous transaction
# immediately following the journal content just written.
# If there is, and the process crashes so that the journal
# becomes a hot-journal and must be rolled back by another
# process, there is a danger that the other process may roll
# back the aborted transaction, then continue copying data
# from an older transaction from the remainder of the journal.
# See the syncJournal() function for details.
#
# pager1-13.2.*: Same test as the previous. This time, throw an index into
# the mix to make the integrity-check more likely to catch
# errors.
#
testvfs tv -default 1
tv script xSyncCb
tv filter xSync
proc xSyncCb {method filename args} {
set t [file tail $filename]
if {$t == "test.db"} faultsim_save
return SQLITE_OK
}
faultsim_delete_and_reopen
db func a_string a_string
# The UPDATE statement at the end of this test case creates a really big
# journal. Since the cache-size is only 10 pages, the journal contains
# frequent journal headers.
#
do_execsql_test pager1-13.1.1 {
PRAGMA page_size = 1024;
PRAGMA journal_mode = PERSIST;
PRAGMA cache_size = 10;
BEGIN;
CREATE TABLE t1(a INTEGER PRIMARY KEY, b BLOB);
INSERT INTO t1 VALUES(NULL, a_string(400));
INSERT INTO t1 SELECT NULL, a_string(400) FROM t1; /* 2 */
INSERT INTO t1 SELECT NULL, a_string(400) FROM t1; /* 4 */
INSERT INTO t1 SELECT NULL, a_string(400) FROM t1; /* 8 */
INSERT INTO t1 SELECT NULL, a_string(400) FROM t1; /* 16 */
INSERT INTO t1 SELECT NULL, a_string(400) FROM t1; /* 32 */
INSERT INTO t1 SELECT NULL, a_string(400) FROM t1; /* 64 */
INSERT INTO t1 SELECT NULL, a_string(400) FROM t1; /* 128 */
COMMIT;
UPDATE t1 SET b = a_string(400);
} {persist}
if {$::tcl_platform(platform)!="windows"} {
# Run transactions of increasing sizes. Eventually, one (or more than one)
# of these will write just enough content that one of the old headers created
# by the transaction in the block above lies immediately after the content
# journalled by the current transaction.
#
for {set nUp 1} {$nUp<64} {incr nUp} {
do_execsql_test pager1-13.1.2.$nUp.1 {
UPDATE t1 SET b = a_string(399) WHERE a <= $nUp
} {}
do_execsql_test pager1-13.1.2.$nUp.2 { PRAGMA integrity_check } {ok}
# Try to access the snapshot of the file-system.
#
sqlite3 db2 sv_test.db
do_test pager1-13.1.2.$nUp.3 {
execsql { SELECT sum(length(b)) FROM t1 } db2
} [expr {128*400 - ($nUp-1)}]
do_test pager1-13.1.2.$nUp.4 {
execsql { PRAGMA integrity_check } db2
} {ok}
db2 close
}
}
if {$::tcl_platform(platform)!="windows"} {
# Same test as above. But this time with an index on the table.
#
do_execsql_test pager1-13.2.1 {
CREATE INDEX i1 ON t1(b);
UPDATE t1 SET b = a_string(400);
} {}
for {set nUp 1} {$nUp<64} {incr nUp} {
do_execsql_test pager1-13.2.2.$nUp.1 {
UPDATE t1 SET b = a_string(399) WHERE a <= $nUp
} {}
do_execsql_test pager1-13.2.2.$nUp.2 { PRAGMA integrity_check } {ok}
sqlite3 db2 sv_test.db
do_test pager1-13.2.2.$nUp.3 {
execsql { SELECT sum(length(b)) FROM t1 } db2
} [expr {128*400 - ($nUp-1)}]
do_test pager1-13.2.2.$nUp.4 {
execsql { PRAGMA integrity_check } db2
} {ok}
db2 close
}
}
db close
tv delete
#-------------------------------------------------------------------------
# Test specal "PRAGMA journal_mode=OFF" test cases.
#
faultsim_delete_and_reopen
do_execsql_test pager1-14.1.1 {
PRAGMA journal_mode = OFF;
CREATE TABLE t1(a, b);
BEGIN;
INSERT INTO t1 VALUES(1, 2);
COMMIT;
SELECT * FROM t1;
} {off 1 2}
do_catchsql_test pager1-14.1.2 {
BEGIN;
INSERT INTO t1 VALUES(3, 4);
ROLLBACK;
} {0 {}}
do_execsql_test pager1-14.1.3 {
SELECT * FROM t1;
} {1 2}
do_catchsql_test pager1-14.1.4 {
BEGIN;
INSERT INTO t1(rowid, a, b) SELECT a+3, b, b FROM t1;
INSERT INTO t1(rowid, a, b) SELECT a+3, b, b FROM t1;
} {1 {PRIMARY KEY must be unique}}
do_execsql_test pager1-14.1.5 {
COMMIT;
SELECT * FROM t1;
} {1 2 2 2}
#-------------------------------------------------------------------------
# Test opening and closing the pager sub-system with different values
# for the sqlite3_vfs.szOsFile variable.
#
faultsim_delete_and_reopen
do_execsql_test pager1-15.0 {
CREATE TABLE tx(y, z);
INSERT INTO tx VALUES('Ayutthaya', 'Beijing');
INSERT INTO tx VALUES('London', 'Tokyo');
} {}
db close
for {set i 0} {$i<513} {incr i 3} {
testvfs tv -default 1 -szosfile $i
sqlite3 db test.db
do_execsql_test pager1-15.$i.1 {
SELECT * FROM tx;
} {Ayutthaya Beijing London Tokyo}
db close
tv delete
}
#-------------------------------------------------------------------------
# Check that it is not possible to open a database file if the full path
# to the associated journal file will be longer than sqlite3_vfs.mxPathname.
#
testvfs tv -default 1
tv script xOpenCb
tv filter xOpen
proc xOpenCb {method filename args} {
set ::file_len [string length $filename]
}
sqlite3 db test.db
db close
tv delete
for {set ii [expr $::file_len-5]} {$ii < [expr $::file_len+20]} {incr ii} {
testvfs tv -default 1 -mxpathname $ii
# The length of the full path to file "test.db-journal" is ($::file_len+8).
# If the configured sqlite3_vfs.mxPathname value greater than or equal to
# this, then the file can be opened. Otherwise, it cannot.
#
if {$ii >= [expr $::file_len+8]} {
set res {0 {}}
} else {
set res {1 {unable to open database file}}
}
do_test pager1-16.1.$ii {
list [catch { sqlite3 db test.db } msg] $msg
} $res
catch {db close}
tv delete
}
#-------------------------------------------------------------------------
# Test "PRAGMA omit_readlock".
#
# pager1-17.$tn.1.*: Test that if a second connection has an open
# read-transaction, it is not usually possible to write
# the database.
#
# pager1-17.$tn.2.*: Test that if the second connection was opened with
# the SQLITE_OPEN_READONLY flag, and
# "PRAGMA omit_readlock = 1" is executed before attaching
# the database and opening a read-transaction on it, it is
# possible to write the db.
#
# pager1-17.$tn.3.*: Test that if the second connection was *not* opened with
# the SQLITE_OPEN_READONLY flag, executing
# "PRAGMA omit_readlock = 1" has no effect.
#
do_multiclient_test tn {
do_test pager1-17.$tn.1.1 {
sql1 {
CREATE TABLE t1(a, b);
INSERT INTO t1 VALUES(1, 2);
}
sql2 {
BEGIN;
SELECT * FROM t1;
}
} {1 2}
do_test pager1-17.$tn.1.2 {
csql1 { INSERT INTO t1 VALUES(3, 4) }
} {1 {database is locked}}
do_test pager1-17.$tn.1.3 {
sql2 { COMMIT }
sql1 { INSERT INTO t1 VALUES(3, 4) }
} {}
do_test pager1-17.$tn.2.1 {
code2 {
db2 close
sqlite3 db2 :memory: -readonly 1
}
sql2 {
PRAGMA omit_readlock = 1;
ATTACH 'test.db' AS two;
BEGIN;
SELECT * FROM t1;
}
} {1 2 3 4}
do_test pager1-17.$tn.2.2 { sql1 "INSERT INTO t1 VALUES(5, 6)" } {}
do_test pager1-17.$tn.2.3 { sql2 "SELECT * FROM t1" } {1 2 3 4}
do_test pager1-17.$tn.2.4 { sql2 "COMMIT ; SELECT * FROM t1" } {1 2 3 4 5 6}
do_test pager1-17.$tn.3.1 {
code2 {
db2 close
sqlite3 db2 :memory:
}
sql2 {
PRAGMA omit_readlock = 1;
ATTACH 'test.db' AS two;
BEGIN;
SELECT * FROM t1;
}
} {1 2 3 4 5 6}
do_test pager1-17.$tn.3.2 {
csql1 { INSERT INTO t1 VALUES(3, 4) }
} {1 {database is locked}}
do_test pager1-17.$tn.3.3 { sql2 COMMIT } {}
}
#-------------------------------------------------------------------------
# Test the pagers response to the b-tree layer requesting illegal page
# numbers:
#
# + The locking page,
# + Page 0,
# + A page with a page number greater than (2^31-1).
#
# These tests will not work if SQLITE_DIRECT_OVERFLOW_READ is defined. In
# that case IO errors are sometimes reported instead of SQLITE_CORRUPT.
#
ifcapable !direct_read {
do_test pager1-18.1 {
faultsim_delete_and_reopen
db func a_string a_string
execsql {
PRAGMA page_size = 1024;
CREATE TABLE t1(a, b);
INSERT INTO t1 VALUES(a_string(500), a_string(200));
INSERT INTO t1 SELECT a_string(500), a_string(200) FROM t1;
INSERT INTO t1 SELECT a_string(500), a_string(200) FROM t1;
INSERT INTO t1 SELECT a_string(500), a_string(200) FROM t1;
INSERT INTO t1 SELECT a_string(500), a_string(200) FROM t1;
INSERT INTO t1 SELECT a_string(500), a_string(200) FROM t1;
INSERT INTO t1 SELECT a_string(500), a_string(200) FROM t1;
INSERT INTO t1 SELECT a_string(500), a_string(200) FROM t1;
}
} {}
do_test pager1-18.2 {
set root [db one "SELECT rootpage FROM sqlite_master"]
set lockingpage [expr (0x10000/1024) + 1]
execsql {
PRAGMA writable_schema = 1;
UPDATE sqlite_master SET rootpage = $lockingpage;
}
sqlite3 db2 test.db
catchsql { SELECT count(*) FROM t1 } db2
} {1 {database disk image is malformed}}
db2 close
do_test pager1-18.3 {
execsql {
CREATE TABLE t2(x);
INSERT INTO t2 VALUES(a_string(5000));
}
set pgno [expr ([file size test.db] / 1024)-2]
hexio_write test.db [expr ($pgno-1)*1024] 00000000
sqlite3 db2 test.db
catchsql { SELECT length(x) FROM t2 } db2
} {1 {database disk image is malformed}}
db2 close
do_test pager1-18.4 {
hexio_write test.db [expr ($pgno-1)*1024] 90000000
sqlite3 db2 test.db
catchsql { SELECT length(x) FROM t2 } db2
} {1 {database disk image is malformed}}
db2 close
do_test pager1-18.5 {
sqlite3 db ""
execsql {
CREATE TABLE t1(a, b);
CREATE TABLE t2(a, b);
PRAGMA writable_schema = 1;
UPDATE sqlite_master SET rootpage=5 WHERE tbl_name = 't1';
PRAGMA writable_schema = 0;
ALTER TABLE t1 RENAME TO x1;
}
catchsql { SELECT * FROM x1 }
} {1 {database disk image is malformed}}
db close
do_test pager1-18.6 {
faultsim_delete_and_reopen
db func a_string a_string
execsql {
PRAGMA page_size = 1024;
CREATE TABLE t1(x);
INSERT INTO t1 VALUES(a_string(800));
INSERT INTO t1 VALUES(a_string(800));
}
set root [db one "SELECT rootpage FROM sqlite_master"]
db close
hexio_write test.db [expr ($root-1)*1024 + 8] 00000000
sqlite3 db test.db
catchsql { SELECT length(x) FROM t1 }
} {1 {database disk image is malformed}}
}
do_test pager1-19.1 {
sqlite3 db ""
db func a_string a_string
execsql {
PRAGMA page_size = 512;
PRAGMA auto_vacuum = 1;
CREATE TABLE t1(aa, ab, ac, ad, ae, af, ag, ah, ai, aj, ak, al, am, an,
ba, bb, bc, bd, be, bf, bg, bh, bi, bj, bk, bl, bm, bn,
ca, cb, cc, cd, ce, cf, cg, ch, ci, cj, ck, cl, cm, cn,
da, db, dc, dd, de, df, dg, dh, di, dj, dk, dl, dm, dn,
ea, eb, ec, ed, ee, ef, eg, eh, ei, ej, ek, el, em, en,
fa, fb, fc, fd, fe, ff, fg, fh, fi, fj, fk, fl, fm, fn,
ga, gb, gc, gd, ge, gf, gg, gh, gi, gj, gk, gl, gm, gn,
ha, hb, hc, hd, he, hf, hg, hh, hi, hj, hk, hl, hm, hn,
ia, ib, ic, id, ie, if, ig, ih, ii, ij, ik, il, im, ix,
ja, jb, jc, jd, je, jf, jg, jh, ji, jj, jk, jl, jm, jn,
ka, kb, kc, kd, ke, kf, kg, kh, ki, kj, kk, kl, km, kn,
la, lb, lc, ld, le, lf, lg, lh, li, lj, lk, ll, lm, ln,
ma, mb, mc, md, me, mf, mg, mh, mi, mj, mk, ml, mm, mn
);
CREATE TABLE t2(aa, ab, ac, ad, ae, af, ag, ah, ai, aj, ak, al, am, an,
ba, bb, bc, bd, be, bf, bg, bh, bi, bj, bk, bl, bm, bn,
ca, cb, cc, cd, ce, cf, cg, ch, ci, cj, ck, cl, cm, cn,
da, db, dc, dd, de, df, dg, dh, di, dj, dk, dl, dm, dn,
ea, eb, ec, ed, ee, ef, eg, eh, ei, ej, ek, el, em, en,
fa, fb, fc, fd, fe, ff, fg, fh, fi, fj, fk, fl, fm, fn,
ga, gb, gc, gd, ge, gf, gg, gh, gi, gj, gk, gl, gm, gn,
ha, hb, hc, hd, he, hf, hg, hh, hi, hj, hk, hl, hm, hn,
ia, ib, ic, id, ie, if, ig, ih, ii, ij, ik, il, im, ix,
ja, jb, jc, jd, je, jf, jg, jh, ji, jj, jk, jl, jm, jn,
ka, kb, kc, kd, ke, kf, kg, kh, ki, kj, kk, kl, km, kn,
la, lb, lc, ld, le, lf, lg, lh, li, lj, lk, ll, lm, ln,
ma, mb, mc, md, me, mf, mg, mh, mi, mj, mk, ml, mm, mn
);
INSERT INTO t1(aa) VALUES( a_string(100000) );
INSERT INTO t2(aa) VALUES( a_string(100000) );
VACUUM;
}
} {}
#-------------------------------------------------------------------------
# Test a couple of special cases that come up while committing
# transactions:
#
# pager1-20.1.*: Committing an in-memory database transaction when the
# database has not been modified at all.
#
# pager1-20.2.*: As above, but with a normal db in exclusive-locking mode.
#
# pager1-20.3.*: Committing a transaction in WAL mode where the database has
# been modified, but all dirty pages have been flushed to
# disk before the commit.
#
do_test pager1-20.1.1 {
catch {db close}
sqlite3 db :memory:
execsql {
CREATE TABLE one(two, three);
INSERT INTO one VALUES('a', 'b');
}
} {}
do_test pager1-20.1.2 {
execsql {
BEGIN EXCLUSIVE;
COMMIT;
}
} {}
do_test pager1-20.2.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA locking_mode = exclusive;
PRAGMA journal_mode = persist;
CREATE TABLE one(two, three);
INSERT INTO one VALUES('a', 'b');
}
} {exclusive persist}
do_test pager1-20.2.2 {
execsql {
BEGIN EXCLUSIVE;
COMMIT;
}
} {}
ifcapable wal {
do_test pager1-20.3.1 {
faultsim_delete_and_reopen
db func a_string a_string
execsql {
PRAGMA cache_size = 10;
PRAGMA journal_mode = wal;
BEGIN;
CREATE TABLE t1(x);
CREATE TABLE t2(y);
INSERT INTO t1 VALUES(a_string(800));
INSERT INTO t1 SELECT a_string(800) FROM t1; /* 2 */
INSERT INTO t1 SELECT a_string(800) FROM t1; /* 4 */
INSERT INTO t1 SELECT a_string(800) FROM t1; /* 8 */
INSERT INTO t1 SELECT a_string(800) FROM t1; /* 16 */
INSERT INTO t1 SELECT a_string(800) FROM t1; /* 32 */
COMMIT;
}
} {wal}
do_test pager1-20.3.2 {
execsql {
BEGIN;
INSERT INTO t2 VALUES('xxxx');
}
recursive_select 32 t1
execsql COMMIT
} {}
}
#-------------------------------------------------------------------------
# Test that a WAL database may not be opened if:
#
# pager1-21.1.*: The VFS has an iVersion less than 2, or
# pager1-21.2.*: The VFS does not provide xShmXXX() methods.
#
ifcapable wal {
do_test pager1-21.0 {
faultsim_delete_and_reopen
execsql {
PRAGMA journal_mode = WAL;
CREATE TABLE ko(c DEFAULT 'abc', b DEFAULT 'def');
INSERT INTO ko DEFAULT VALUES;
}
} {wal}
do_test pager1-21.1 {
testvfs tv -noshm 1
sqlite3 db2 test.db -vfs tv
catchsql { SELECT * FROM ko } db2
} {1 {unable to open database file}}
db2 close
tv delete
do_test pager1-21.2 {
testvfs tv -iversion 1
sqlite3 db2 test.db -vfs tv
catchsql { SELECT * FROM ko } db2
} {1 {unable to open database file}}
db2 close
tv delete
}
#-------------------------------------------------------------------------
# Test that a "PRAGMA wal_checkpoint":
#
# pager1-22.1.*: is a no-op on a non-WAL db, and
# pager1-22.2.*: does not cause xSync calls with a synchronous=off db.
#
ifcapable wal {
do_test pager1-22.1.1 {
faultsim_delete_and_reopen
execsql {
CREATE TABLE ko(c DEFAULT 'abc', b DEFAULT 'def');
INSERT INTO ko DEFAULT VALUES;
}
execsql { PRAGMA wal_checkpoint }
} {0 -1 -1}
do_test pager1-22.2.1 {
testvfs tv -default 1
tv filter xSync
tv script xSyncCb
proc xSyncCb {args} {incr ::synccount}
set ::synccount 0
sqlite3 db test.db
execsql {
PRAGMA synchronous = off;
PRAGMA journal_mode = WAL;
INSERT INTO ko DEFAULT VALUES;
}
execsql { PRAGMA wal_checkpoint }
set synccount
} {0}
db close
tv delete
}
#-------------------------------------------------------------------------
# Tests for changing journal mode.
#
# pager1-23.1.*: Test that when changing from PERSIST to DELETE mode,
# the journal file is deleted.
#
# pager1-23.2.*: Same test as above, but while a shared lock is held
# on the database file.
#
# pager1-23.3.*: Same test as above, but while a reserved lock is held
# on the database file.
#
# pager1-23.4.*: And, for fun, while holding an exclusive lock.
#
# pager1-23.5.*: Try to set various different journal modes with an
# in-memory database (only MEMORY and OFF should work).
#
# pager1-23.6.*: Try to set locking_mode=normal on an in-memory database
# (doesn't work - in-memory databases always use
# locking_mode=exclusive).
#
do_test pager1-23.1.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA journal_mode = PERSIST;
CREATE TABLE t1(a, b);
}
file exists test.db-journal
} {1}
do_test pager1-23.1.2 {
execsql { PRAGMA journal_mode = DELETE }
file exists test.db-journal
} {0}
do_test pager1-23.2.1 {
execsql {
PRAGMA journal_mode = PERSIST;
INSERT INTO t1 VALUES('Canberra', 'ACT');
}
db eval { SELECT * FROM t1 } {
db eval { PRAGMA journal_mode = DELETE }
}
execsql { PRAGMA journal_mode }
} {delete}
do_test pager1-23.2.2 {
file exists test.db-journal
} {0}
do_test pager1-23.3.1 {
execsql {
PRAGMA journal_mode = PERSIST;
INSERT INTO t1 VALUES('Darwin', 'NT');
BEGIN IMMEDIATE;
}
db eval { PRAGMA journal_mode = DELETE }
execsql { PRAGMA journal_mode }
} {delete}
do_test pager1-23.3.2 {
file exists test.db-journal
} {0}
do_test pager1-23.3.3 {
execsql COMMIT
} {}
do_test pager1-23.4.1 {
execsql {
PRAGMA journal_mode = PERSIST;
INSERT INTO t1 VALUES('Adelaide', 'SA');
BEGIN EXCLUSIVE;
}
db eval { PRAGMA journal_mode = DELETE }
execsql { PRAGMA journal_mode }
} {delete}
do_test pager1-23.4.2 {
file exists test.db-journal
} {0}
do_test pager1-23.4.3 {
execsql COMMIT
} {}
do_test pager1-23.5.1 {
faultsim_delete_and_reopen
sqlite3 db :memory:
} {}
foreach {tn mode possible} {
2 off 1
3 memory 1
4 persist 0
5 delete 0
6 wal 0
7 truncate 0
} {
do_test pager1-23.5.$tn.1 {
execsql "PRAGMA journal_mode = off"
execsql "PRAGMA journal_mode = $mode"
} [if $possible {list $mode} {list off}]
do_test pager1-23.5.$tn.2 {
execsql "PRAGMA journal_mode = memory"
execsql "PRAGMA journal_mode = $mode"
} [if $possible {list $mode} {list memory}]
}
do_test pager1-23.6.1 {
execsql {PRAGMA locking_mode = normal}
} {exclusive}
do_test pager1-23.6.2 {
execsql {PRAGMA locking_mode = exclusive}
} {exclusive}
do_test pager1-23.6.3 {
execsql {PRAGMA locking_mode}
} {exclusive}
do_test pager1-23.6.4 {
execsql {PRAGMA main.locking_mode}
} {exclusive}
#-------------------------------------------------------------------------
#
do_test pager1-24.1.1 {
faultsim_delete_and_reopen
db func a_string a_string
execsql {
PRAGMA cache_size = 10;
PRAGMA auto_vacuum = FULL;
CREATE TABLE x1(x, y, z, PRIMARY KEY(y, z));
CREATE TABLE x2(x, y, z, PRIMARY KEY(y, z));
INSERT INTO x2 VALUES(a_string(400), a_string(500), a_string(600));
INSERT INTO x2 SELECT a_string(600), a_string(400), a_string(500) FROM x2;
INSERT INTO x2 SELECT a_string(500), a_string(600), a_string(400) FROM x2;
INSERT INTO x2 SELECT a_string(400), a_string(500), a_string(600) FROM x2;
INSERT INTO x2 SELECT a_string(600), a_string(400), a_string(500) FROM x2;
INSERT INTO x2 SELECT a_string(500), a_string(600), a_string(400) FROM x2;
INSERT INTO x2 SELECT a_string(400), a_string(500), a_string(600) FROM x2;
INSERT INTO x1 SELECT * FROM x2;
}
} {}
do_test pager1-24.1.2 {
execsql {
BEGIN;
DELETE FROM x1 WHERE rowid<32;
}
recursive_select 64 x2
} {}
do_test pager1-24.1.3 {
execsql {
UPDATE x1 SET z = a_string(300) WHERE rowid>40;
COMMIT;
PRAGMA integrity_check;
SELECT count(*) FROM x1;
}
} {ok 33}
do_test pager1-24.1.4 {
execsql {
DELETE FROM x1;
INSERT INTO x1 SELECT * FROM x2;
BEGIN;
DELETE FROM x1 WHERE rowid<32;
UPDATE x1 SET z = a_string(299) WHERE rowid>40;
}
recursive_select 64 x2 {db eval COMMIT}
execsql {
PRAGMA integrity_check;
SELECT count(*) FROM x1;
}
} {ok 33}
do_test pager1-24.1.5 {
execsql {
DELETE FROM x1;
INSERT INTO x1 SELECT * FROM x2;
}
recursive_select 64 x2 { db eval {CREATE TABLE x3(x, y, z)} }
execsql { SELECT * FROM x3 }
} {}
#-------------------------------------------------------------------------
#
do_test pager1-25-1 {
faultsim_delete_and_reopen
execsql {
BEGIN;
SAVEPOINT abc;
CREATE TABLE t1(a, b);
ROLLBACK TO abc;
COMMIT;
}
db close
} {}
breakpoint
do_test pager1-25-2 {
faultsim_delete_and_reopen
execsql {
SAVEPOINT abc;
CREATE TABLE t1(a, b);
ROLLBACK TO abc;
COMMIT;
}
db close
} {}
#-------------------------------------------------------------------------
# Sector-size tests.
#
do_test pager1-26.1 {
testvfs tv -default 1
tv sectorsize 4096
faultsim_delete_and_reopen
db func a_string a_string
execsql {
PRAGMA page_size = 512;
CREATE TABLE tbl(a PRIMARY KEY, b UNIQUE);
BEGIN;
INSERT INTO tbl VALUES(a_string(25), a_string(600));
INSERT INTO tbl SELECT a_string(25), a_string(600) FROM tbl;
INSERT INTO tbl SELECT a_string(25), a_string(600) FROM tbl;
INSERT INTO tbl SELECT a_string(25), a_string(600) FROM tbl;
INSERT INTO tbl SELECT a_string(25), a_string(600) FROM tbl;
INSERT INTO tbl SELECT a_string(25), a_string(600) FROM tbl;
INSERT INTO tbl SELECT a_string(25), a_string(600) FROM tbl;
INSERT INTO tbl SELECT a_string(25), a_string(600) FROM tbl;
COMMIT;
}
} {}
do_execsql_test pager1-26.1 {
UPDATE tbl SET b = a_string(550);
} {}
db close
tv delete
#-------------------------------------------------------------------------
#
do_test pager1.27.1 {
faultsim_delete_and_reopen
sqlite3_pager_refcounts db
execsql {
BEGIN;
CREATE TABLE t1(a, b);
}
sqlite3_pager_refcounts db
execsql COMMIT
} {}
#-------------------------------------------------------------------------
# Test that attempting to open a write-transaction with
# locking_mode=exclusive in WAL mode fails if there are other clients on
# the same database.
#
catch { db close }
ifcapable wal {
do_multiclient_test tn {
do_test pager1-28.$tn.1 {
sql1 {
PRAGMA journal_mode = WAL;
CREATE TABLE t1(a, b);
INSERT INTO t1 VALUES('a', 'b');
}
} {wal}
do_test pager1-28.$tn.2 { sql2 { SELECT * FROM t1 } } {a b}
do_test pager1-28.$tn.3 { sql1 { PRAGMA locking_mode=exclusive } } {exclusive}
do_test pager1-28.$tn.4 {
csql1 { BEGIN; INSERT INTO t1 VALUES('c', 'd'); }
} {1 {database is locked}}
code2 { db2 close ; sqlite3 db2 test.db }
do_test pager1-28.$tn.4 {
sql1 { INSERT INTO t1 VALUES('c', 'd'); COMMIT }
} {}
}
}
#-------------------------------------------------------------------------
# Normally, when changing from journal_mode=PERSIST to DELETE the pager
# attempts to delete the journal file. However, if it cannot obtain a
# RESERVED lock on the database file, this step is skipped.
#
do_multiclient_test tn {
do_test pager1-28.$tn.1 {
sql1 {
PRAGMA journal_mode = PERSIST;
CREATE TABLE t1(a, b);
INSERT INTO t1 VALUES('a', 'b');
}
} {persist}
do_test pager1-28.$tn.2 { file exists test.db-journal } 1
do_test pager1-28.$tn.3 { sql1 { PRAGMA journal_mode = DELETE } } delete
do_test pager1-28.$tn.4 { file exists test.db-journal } 0
do_test pager1-28.$tn.5 {
sql1 {
PRAGMA journal_mode = PERSIST;
INSERT INTO t1 VALUES('c', 'd');
}
} {persist}
do_test pager1-28.$tn.6 { file exists test.db-journal } 1
do_test pager1-28.$tn.7 {
sql2 { BEGIN; INSERT INTO t1 VALUES('e', 'f'); }
} {}
do_test pager1-28.$tn.8 { file exists test.db-journal } 1
do_test pager1-28.$tn.9 { sql1 { PRAGMA journal_mode = DELETE } } delete
do_test pager1-28.$tn.10 { file exists test.db-journal } 1
do_test pager1-28.$tn.11 { sql2 COMMIT } {}
do_test pager1-28.$tn.12 { file exists test.db-journal } 0
do_test pager1-28-$tn.13 {
code1 { set channel [db incrblob -readonly t1 a 2] }
sql1 {
PRAGMA journal_mode = PERSIST;
INSERT INTO t1 VALUES('g', 'h');
}
} {persist}
do_test pager1-28.$tn.14 { file exists test.db-journal } 1
do_test pager1-28.$tn.15 {
sql2 { BEGIN; INSERT INTO t1 VALUES('e', 'f'); }
} {}
do_test pager1-28.$tn.16 { sql1 { PRAGMA journal_mode = DELETE } } delete
do_test pager1-28.$tn.17 { file exists test.db-journal } 1
do_test pager1-28.$tn.17 { csql2 { COMMIT } } {1 {database is locked}}
do_test pager1-28-$tn.18 { code1 { read $channel } } c
do_test pager1-28-$tn.19 { code1 { close $channel } } {}
do_test pager1-28.$tn.20 { sql2 { COMMIT } } {}
}
do_test pager1-29.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA page_size = 1024;
PRAGMA auto_vacuum = full;
PRAGMA locking_mode=exclusive;
CREATE TABLE t1(a, b);
INSERT INTO t1 VALUES(1, 2);
}
file size test.db
} [expr 1024*3]
do_test pager1-29.2 {
execsql {
PRAGMA page_size = 4096;
VACUUM;
}
file size test.db
} [expr 4096*3]
#-------------------------------------------------------------------------
# Test that if an empty database file (size 0 bytes) is opened in
# exclusive-locking mode, any journal file is deleted from the file-system
# without being rolled back. And that the RESERVED lock obtained while
# doing this is not released.
#
do_test pager1-30.1 {
db close
delete_file test.db
delete_file test.db-journal
set fd [open test.db-journal w]
seek $fd [expr 512+1032*2]
puts -nonewline $fd x
close $fd
sqlite3 db test.db
execsql {
PRAGMA locking_mode=EXCLUSIVE;
SELECT count(*) FROM sqlite_master;
PRAGMA lock_status;
}
} {exclusive 0 main reserved temp closed}
#-------------------------------------------------------------------------
# Test that if the "page-size" field in a journal-header is 0, the journal
# file can still be rolled back. This is required for backward compatibility -
# versions of SQLite prior to 3.5.8 always set this field to zero.
#
if {$tcl_platform(platform)=="unix"} {
do_test pager1-31.1 {
faultsim_delete_and_reopen
execsql {
PRAGMA cache_size = 10;
PRAGMA page_size = 1024;
CREATE TABLE t1(x, y, UNIQUE(x, y));
INSERT INTO t1 VALUES(randomblob(1500), randomblob(1500));
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
INSERT INTO t1 SELECT randomblob(1500), randomblob(1500) FROM t1;
BEGIN;
UPDATE t1 SET y = randomblob(1499);
}
copy_file test.db test.db2
copy_file test.db-journal test.db2-journal
hexio_write test.db2-journal 24 00000000
sqlite3 db2 test.db2
execsql { PRAGMA integrity_check } db2
} {ok}
}
#-------------------------------------------------------------------------
# Test that a database file can be "pre-hinted" to a certain size and that
# subsequent spilling of the pager cache does not result in the database
# file being shrunk.
#
catch {db close}
forcedelete test.db
do_test pager1-32.1 {
sqlite3 db test.db
execsql {
CREATE TABLE t1(x, y);
}
db close
sqlite3 db test.db
execsql {
BEGIN;
INSERT INTO t1 VALUES(1, randomblob(10000));
}
file_control_chunksize_test db main 1024
file_control_sizehint_test db main 20971520; # 20MB
execsql {
PRAGMA cache_size = 10;
INSERT INTO t1 VALUES(1, randomblob(10000));
INSERT INTO t1 VALUES(2, randomblob(10000));
INSERT INTO t1 SELECT x+2, randomblob(10000) from t1;
INSERT INTO t1 SELECT x+4, randomblob(10000) from t1;
INSERT INTO t1 SELECT x+8, randomblob(10000) from t1;
INSERT INTO t1 SELECT x+16, randomblob(10000) from t1;
SELECT count(*) FROM t1;
COMMIT;
}
db close
file size test.db
} {20971520}
# Cleanup 20MB file left by the previous test.
forcedelete test.db
finish_test
FreeBSD-CVSweb <freebsd-cvsweb@FreeBSD.org>