#pragma ident "%Z%%M% %I% %E% SMI"

# 2001 September 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.

#

#***********************************************************************

# This file implements regression tests for SQLite library. The

# focus of this script is btree database backend

#

# $Id: btree2.test,v 1.10 2002/02/19 13:39:23 drh Exp $

set testdir [file dirname $argv0]

source $testdir/tester.tcl

if {[info commands btree_open]!=""} {

# Create a new database file containing no entries. The database should

# contain 5 tables:

#

# 2 The descriptor table

# 3 The foreground table

# 4 The background table

# 5 The long key table

# 6 The long data table

#

# An explanation for what all these tables are used for is provided below.

#

do_test btree2-1.1 {

expr srand(1)

file delete -force test2.bt

file delete -force test2.bt-journal

set ::b [btree_open test2.bt]

btree_begin_transaction $::b

btree_create_table $::b

} {3}

do_test btree2-1.2 {

btree_create_table $::b

} {4}

do_test btree2-1.3 {

btree_create_table $::b

} {5}

do_test btree2-1.4 {

btree_create_table $::b

} {6}

do_test btree2-1.5 {

set ::c2 [btree_cursor $::b 2 1]

btree_insert $::c2 {one} {1}

btree_delete $::c2

btree_close_cursor $::c2

btree_commit $::b

btree_integrity_check $::b 2 3 4 5 6

} {}

# This test module works by making lots of pseudo-random changes to a

# database while simultaneously maintaining an invariant on that database.

# Periodically, the script does a sanity check on the database and verifies

# that the invariant is satisfied.

#

# The invariant is as follows:

#

# 1. The descriptor table always contains 2 enters. An entry keyed by

# "N" is the number of elements in the foreground and background tables

# combined. The entry keyed by "L" is the number of digits in the keys

# for foreground and background tables.

#

# 2. The union of the foreground an background tables consists of N entries

# where each entry an L-digit key. (Actually, some keys can be longer

# than L characters, but they always start with L digits.) The keys

# cover all integers between 1 and N. Whenever an entry is added to

# the foreground it is removed form the background and vice versa.

#

# 3. Some entries in the foreground and background tables have keys that

# begin with an L-digit number but are followed by additional characters.

# For each such entry there is a corresponding entry in the long key

# table. The long key table entry has a key which is just the L-digit

# number and data which is the length of the key in the foreground and

# background tables.

#

# 4. The data for both foreground and background entries is usually a

# short string. But some entries have long data strings. For each

# such entries there is an entry in the long data type. The key to

# long data table is an L-digit number. (The extension on long keys

# is omitted.) The data is the number of charaters in the data of the

# foreground or background entry.

#

# The following function builds a database that satisfies all of the above

# invariants.

#

proc build_db {N L} {

for {set i 2} {$i<=6} {incr i} {

catch {btree_close_cursor [set ::c$i]}

btree_clear_table $::b $i

set ::c$i [btree_cursor $::b $i 1]

}

btree_insert $::c2 N $N

btree_insert $::c2 L $L

set format %0${L}d

for {set i 1} {$i<=$N} {incr i} {

set key [format $format $i]

set data $key

btree_insert $::c3 $key $data

}

}

# Given a base key number and a length, construct the full text of the key

# or data.

#

proc make_payload {keynum L len} {

set key [format %0${L}d $keynum]

set r $key

set i 1

while {[string length $r]<$len} {

append r " ($i) $key"

incr i

}

return [string range $r 0 [expr {$len-1}]]

}

# Verify the invariants on the database. Return an empty string on

# success or an error message if something is amiss.

#

proc check_invariants {} {

set ck [btree_integrity_check $::b 2 3 4 5 6]

if {$ck!=""} {

puts "\n*** SANITY:\n$ck"

exit

return $ck

}

btree_move_to $::c3 {}

btree_move_to $::c4 {}

btree_move_to $::c2 N

set N [btree_data $::c2]

btree_move_to $::c2 L

set L [btree_data $::c2]

set LM1 [expr {$L-1}]

for {set i 1} {$i<=$N} {incr i} {

set key [btree_key $::c3]

if {[scan $key %d k]<1} {set k 0}

if {$k!=$i} {

set key [btree_key $::c4]

if {[scan $key %d k]<1} {set k 0}

if {$k!=$i} {

# puts "MISSING $i"

# puts {Page 3:}; btree_page_dump $::b 3

# puts {Page 4:}; btree_page_dump $::b 4

# exit

return "Key $i is missing from both foreground and background"

}

set data [btree_data $::c4]

btree_next $::c4

} else {

set data [btree_data $::c3]

btree_next $::c3

}

set skey [string range $key 0 $LM1]

if {[btree_move_to $::c5 $skey]==0} {

set keylen [btree_data $::c5]

} else {

set keylen $L

}

if {[string length $key]!=$keylen} {

return "Key $i is the wrong size.\

Is \"$key\" but should be \"[make_payload $k $L $keylen]\""

}

if {[make_payload $k $L $keylen]!=$key} {

return "Key $i has an invalid extension"

}

if {[btree_move_to $::c6 $skey]==0} {

set datalen [btree_data $::c6]

} else {

set datalen $L

}

if {[string length $data]!=$datalen} {

return "Data for $i is the wrong size.\

Is [string length $data] but should be $datalen"

}

if {[make_payload $k $L $datalen]!=$data} {

return "Entry $i has an incorrect data"

}

}

}

# Make random changes to the database such that each change preserves

# the invariants. The number of changes is $n*N where N is the parameter

# from the descriptor table. Each changes begins with a random key.

# the entry with that key is put in the foreground table with probability

# $I and it is put in background with probability (1.0-$I). It gets

# a long key with probability $K and long data with probability $D.

#

set chngcnt 0

proc random_changes {n I K D} {

btree_move_to $::c2 N

set N [btree_data $::c2]

btree_move_to $::c2 L

set L [btree_data $::c2]

set LM1 [expr {$L-1}]

set total [expr {int($N*$n)}]

set format %0${L}d

for {set i 0} {$i<$total} {incr i} {

set k [expr {int(rand()*$N)+1}]

set insert [expr {rand()<=$I}]

set longkey [expr {rand()<=$K}]

set longdata [expr {rand()<=$D}]

# incr ::chngcnt

# if {$::chngcnt==251} {btree_tree_dump $::b 3}

# puts "CHANGE $::chngcnt: $k $insert $longkey $longdata"

if {$longkey} {

set x [expr {rand()}]

set keylen [expr {int($x*$x*$x*$x*3000)+10}]

} else {

set keylen $L

}

set key [make_payload $k $L $keylen]

if {$longdata} {

set x [expr {rand()}]

set datalen [expr {int($x*$x*$x*$x*3000)+10}]

} else {

set datalen $L

}

set data [make_payload $k $L $datalen]

set basekey [format $format $k]

if {[set c [btree_move_to $::c3 $basekey]]==0} {

btree_delete $::c3

} else {

if {$c<0} {btree_next $::c3}

if {[string match $basekey* [btree_key $::c3]]} {

btree_delete $::c3

}

}

if {[set c [btree_move_to $::c4 $basekey]]==0} {

btree_delete $::c4

} else {

if {$c<0} {btree_next $::c4}

if {[string match $basekey* [btree_key $::c4]]} {

btree_delete $::c4

}

}

if {[scan [btree_key $::c4] %d kx]<1} {set kx -1}

if {$kx==$k} {

btree_delete $::c4

}

if {$insert} {

btree_insert $::c3 $key $data

} else {

btree_insert $::c4 $key $data

}

if {$longkey} {

btree_insert $::c5 $basekey $keylen

} elseif {[btree_move_to $::c5 $basekey]==0} {

btree_delete $::c5

}

if {$longdata} {

btree_insert $::c6 $basekey $datalen

} elseif {[btree_move_to $::c6 $basekey]==0} {

btree_delete $::c6

}

# set ck [btree_integrity_check $::b 2 3 4 5 6]

# if {$ck!=""} {

# puts "\nSANITY CHECK FAILED!\n$ck"

# exit

# }

# puts "PAGE 3:"; btree_page_dump $::b 3

# puts "PAGE 4:"; btree_page_dump $::b 4

}

}

# Repeat this test sequence on database of various sizes

#

set testno 2

foreach {N L} {

10 2

50 2

200 3

2000 5

} {

puts "**** N=$N L=$L ****"

set hash [md5file test2.bt]

do_test btree2-$testno.1 [subst -nocommands {

set ::c2 [btree_cursor $::b 2 1]

set ::c3 [btree_cursor $::b 3 1]

set ::c4 [btree_cursor $::b 4 1]

set ::c5 [btree_cursor $::b 5 1]

set ::c6 [btree_cursor $::b 6 1]

btree_begin_transaction $::b

build_db $N $L

check_invariants

}] {}

do_test btree2-$testno.2 {

btree_close_cursor $::c2

btree_close_cursor $::c3

btree_close_cursor $::c4

btree_close_cursor $::c5

btree_close_cursor $::c6

btree_rollback $::b

md5file test2.bt

} $hash

do_test btree2-$testno.3 [subst -nocommands {

btree_begin_transaction $::b

set ::c2 [btree_cursor $::b 2 1]

set ::c3 [btree_cursor $::b 3 1]

set ::c4 [btree_cursor $::b 4 1]

set ::c5 [btree_cursor $::b 5 1]

set ::c6 [btree_cursor $::b 6 1]

build_db $N $L

check_invariants

}] {}

do_test btree2-$testno.4 {

btree_commit $::b

check_invariants

} {}

do_test btree2-$testno.5 {

lindex [btree_pager_stats $::b] 1

} {6}

do_test btree2-$testno.6 {

btree_close_cursor $::c2

btree_close_cursor $::c3

btree_close_cursor $::c4

btree_close_cursor $::c5

btree_close_cursor $::c6

lindex [btree_pager_stats $::b] 1

} {0}

do_test btree2-$testno.7 {

btree_close $::b

} {}

after 100

# For each database size, run various changes tests.

#

set num2 1

foreach {n I K D} {

0.5 0.5 0.1 0.1

1.0 0.2 0.1 0.1

1.0 0.8 0.1 0.1

2.0 0.0 0.1 0.1

2.0 1.0 0.1 0.1

2.0 0.0 0.0 0.0

2.0 1.0 0.0 0.0

} {

set testid btree2-$testno.8.$num2

set hash [md5file test2.bt]

do_test $testid.0 {

set ::b [btree_open test2.bt]

set ::c2 [btree_cursor $::b 2 1]

set ::c3 [btree_cursor $::b 3 1]

set ::c4 [btree_cursor $::b 4 1]

set ::c5 [btree_cursor $::b 5 1]

set ::c6 [btree_cursor $::b 6 1]

check_invariants

} {}

set cnt 6

for {set i 2} {$i<=6} {incr i} {

if {[lindex [btree_cursor_dump [set ::c$i]] 0]!=$i} {incr cnt}

}

do_test $testid.1 {

btree_begin_transaction $::b

lindex [btree_pager_stats $::b] 1

} $cnt

# exec cp test2.bt test2.bt.bu1

do_test $testid.2 [subst {

random_changes $n $I $K $D

}] {}

do_test $testid.3 {

check_invariants

} {}

do_test $testid.4 {

btree_close_cursor $::c2

btree_close_cursor $::c3

btree_close_cursor $::c4

btree_close_cursor $::c5

btree_close_cursor $::c6

btree_rollback $::b

md5file test2.bt

} $hash

# exec cp test2.bt test2.bt.bu2

btree_begin_transaction $::b

set ::c2 [btree_cursor $::b 2 1]

set ::c3 [btree_cursor $::b 3 1]

set ::c4 [btree_cursor $::b 4 1]

set ::c5 [btree_cursor $::b 5 1]

set ::c6 [btree_cursor $::b 6 1]

do_test $testid.5 [subst {

random_changes $n $I $K $D

}] {}

do_test $testid.6 {

check_invariants

} {}

do_test $testid.7 {

btree_commit $::b

check_invariants

} {}

set hash [md5file test2.bt]

do_test $testid.8 {

btree_close_cursor $::c2

btree_close_cursor $::c3

btree_close_cursor $::c4

btree_close_cursor $::c5

btree_close_cursor $::c6

lindex [btree_pager_stats $::b] 1

} {0}

do_test $testid.9 {

btree_close $::b

set ::b [btree_open test2.bt]

set ::c2 [btree_cursor $::b 2 1]

set ::c3 [btree_cursor $::b 3 1]

set ::c4 [btree_cursor $::b 4 1]

set ::c5 [btree_cursor $::b 5 1]

set ::c6 [btree_cursor $::b 6 1]

check_invariants

} {}

do_test $testid.10 {

btree_close_cursor $::c2

btree_close_cursor $::c3

btree_close_cursor $::c4

btree_close_cursor $::c5

btree_close_cursor $::c6

lindex [btree_pager_stats $::b] 1

} {0}

do_test $testid.11 {

btree_close $::b

} {}

incr num2

}

incr testno

set ::b [btree_open test2.bt]

}

# Testing is complete. Shut everything down.

#

do_test btree-999.1 {

lindex [btree_pager_stats $::b] 1

} {0}

do_test btree-999.2 {

btree_close $::b

} {}

do_test btree-999.3 {

file delete -force test2.bt

file exists test2.bt-journal

} {0}

} ;# end if( not mem: and has pager_open command );

finish_test