rtt-f030/components/external/SQLite-3.8.1/test/trans2.test

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# 2008 August 27
#
# The author disclaims copyright to this source code. In place of
# a legal notice, here is a blessing:
#
# May you do good and not evil.
# May you find forgiveness for yourself and forgive others.
# May you share freely, never taking more than you give.
#
#***********************************************************************
#
# This file implements regression tests for SQLite library. The
# focus of this script is transactions
#
# $Id: trans2.test,v 1.1 2008/08/27 18:56:36 drh Exp $
#
set testdir [file dirname $argv0]
source $testdir/tester.tcl
# A procedure to scramble the elements of list $inlist into a random order.
#
proc scramble {inlist} {
set y {}
foreach x $inlist {
lappend y [list [expr {rand()}] $x]
}
set y [lsort $y]
set outlist {}
foreach x $y {
lappend outlist [lindex $x 1]
}
return $outlist
}
# Generate a UUID using randomness.
#
expr srand(1)
proc random_uuid {} {
set u {}
for {set i 0} {$i<5} {incr i} {
append u [format %06x [expr {int(rand()*16777216)}]]
}
return $u
}
# Compute hashes on the u1 and u2 fields of the sample data.
#
proc hash1 {} {
global data
set x ""
foreach rec [lsort -integer -index 0 $data] {
append x [lindex $rec 1]
}
return [md5 $x]
}
proc hash2 {} {
global data
set x ""
foreach rec [lsort -integer -index 0 $data] {
append x [lindex $rec 3]
}
return [md5 $x]
}
# Create the initial data set
#
unset -nocomplain data i max_rowid todel n rec max1 id origres newres
unset -nocomplain inssql modsql s j z
set data {}
for {set i 0} {$i<400} {incr i} {
set rec [list $i [random_uuid] [expr {int(rand()*5000)+1000}] [random_uuid]]
lappend data $rec
}
set max_rowid [expr {$i-1}]
# Create the T1 table used to hold test data. Populate that table with
# the initial data set and check hashes to make sure everything is correct.
#
do_test trans2-1.1 {
execsql {
PRAGMA cache_size=100;
CREATE TABLE t1(
id INTEGER PRIMARY KEY,
u1 TEXT UNIQUE,
z BLOB NOT NULL,
u2 TEXT UNIQUE
);
}
foreach rec [scramble $data] {
foreach {id u1 z u2} $rec break
db eval {INSERT INTO t1 VALUES($id,$u1,zeroblob($z),$u2)}
}
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} [list [hash1] [hash2]]
# Repeat the main test loop multiple times.
#
for {set i 2} {$i<=30} {incr i} {
# Delete one row out of every 10 in the database. This will add
# many pages to the freelist.
#
set todel {}
set n [expr {[llength $data]/10}]
set data [scramble $data]
foreach rec [lrange $data 0 $n] {
lappend todel [lindex $rec 0]
}
set data [lrange $data [expr {$n+1}] end]
set max1 [lindex [lindex $data 0] 0]
foreach rec $data {
set id [lindex $rec 0]
if {$id>$max1} {set max1 $id}
}
set origres [list [hash1] [hash2]]
do_test trans2-$i.1 {
db eval "DELETE FROM t1 WHERE id IN ([join $todel ,])"
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $origres
integrity_check trans2-$i.2
# Begin a transaction and insert many new records.
#
set newdata {}
foreach id $todel {
set rec [list $id [random_uuid] \
[expr {int(rand()*5000)+1000}] [random_uuid]]
lappend newdata $rec
lappend data $rec
}
for {set j 1} {$j<50} {incr j} {
set id [expr {$max_rowid+$j}]
lappend todel $id
set rec [list $id [random_uuid] \
[expr {int(rand()*5000)+1000}] [random_uuid]]
lappend newdata $rec
lappend data $rec
}
set max_rowid [expr {$max_rowid+$j-1}]
set modsql {}
set inssql {}
set newres [list [hash1] [hash2]]
do_test trans2-$i.3 {
db eval BEGIN
foreach rec [scramble $newdata] {
foreach {id u1 z u2} $rec break
set s "INSERT INTO t1 VALUES($id,'$u1',zeroblob($z),'$u2');"
append modsql $s\n
append inssql $s\n
db eval $s
}
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $newres
integrity_check trans2-$i.4
# Do a large update that aborts do to a constraint failure near
# the end. This stresses the statement journal mechanism.
#
do_test trans2-$i.10 {
catchsql {
UPDATE t1 SET u1=u1||'x',
z = CASE WHEN id<$max_rowid
THEN zeroblob((random()&65535)%5000 + 1000) END;
}
} {1 {t1.z may not be NULL}}
do_test trans2-$i.11 {
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $newres
# Delete all of the newly inserted records. Verify that the database
# is back to its original state.
#
do_test trans2-$i.20 {
set s "DELETE FROM t1 WHERE id IN ([join $todel ,]);"
append modsql $s\n
db eval $s
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $origres
# Do another large update that aborts do to a constraint failure near
# the end. This stresses the statement journal mechanism.
#
do_test trans2-$i.30 {
catchsql {
UPDATE t1 SET u1=u1||'x',
z = CASE WHEN id<$max1
THEN zeroblob((random()&65535)%5000 + 1000) END;
}
} {1 {t1.z may not be NULL}}
do_test trans2-$i.31 {
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $origres
# Redo the inserts
#
do_test trans2-$i.40 {
db eval $inssql
append modsql $inssql
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $newres
# Rollback the transaction. Verify that the content is restored.
#
do_test trans2-$i.90 {
db eval ROLLBACK
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $origres
integrity_check trans2-$i.91
# Repeat all the changes, but this time commit.
#
do_test trans2-$i.92 {
db eval BEGIN
catchsql {
UPDATE t1 SET u1=u1||'x',
z = CASE WHEN id<$max1
THEN zeroblob((random()&65535)%5000 + 1000) END;
}
db eval $modsql
catchsql {
UPDATE t1 SET u1=u1||'x',
z = CASE WHEN id<$max1
THEN zeroblob((random()&65535)%5000 + 1000) END;
}
db eval COMMIT
db eval {SELECT md5sum(u1), md5sum(u2) FROM t1 ORDER BY id}
} $newres
integrity_check trans2-$i.93
}
unset -nocomplain data i max_rowid todel n rec max1 id origres newres
unset -nocomplain inssql modsql s j z
finish_test