809badc93a
FossilOrigin-Name: a192a718d513002b58ad585fcb3d8b9b49b4b123
528 lines
15 KiB
Plaintext
528 lines
15 KiB
Plaintext
# 2010 April 13
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#
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# The author disclaims copyright to this source code. In place of
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# a legal notice, here is a blessing:
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#
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# May you do good and not evil.
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# May you find forgiveness for yourself and forgive others.
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# May you share freely, never taking more than you give.
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#
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#***********************************************************************
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# This file implements regression tests for SQLite library. The
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# focus of this file is testing the operation of the library in
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# "PRAGMA journal_mode=WAL" mode with multiple threads.
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#
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set testdir [file dirname $argv0]
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source $testdir/tester.tcl
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source $testdir/lock_common.tcl
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if {[run_thread_tests]==0} { finish_test ; return }
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ifcapable !wal { finish_test ; return }
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set sqlite_walsummary_mmap_incr 64
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# How long, in seconds, to run each test for. If a test is set to run for
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# 0 seconds, it is omitted entirely.
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#
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unset -nocomplain seconds
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set seconds(walthread-1) 20
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set seconds(walthread-2) 20
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set seconds(walthread-3) 20
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set seconds(walthread-4) 20
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set seconds(walthread-5) 1
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# The parameter is the name of a variable in the callers context. The
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# variable may or may not exist when this command is invoked.
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#
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# If the variable does exist, its value is returned. Otherwise, this
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# command uses [vwait] to wait until it is set, then returns the value.
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# In other words, this is a version of the [set VARNAME] command that
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# blocks until a variable exists.
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#
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proc wait_for_var {varname} {
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if {0==[uplevel [list info exists $varname]]} {
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uplevel [list vwait $varname]
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}
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uplevel [list set $varname]
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}
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# The argument is the name of a list variable in the callers context. The
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# first element of the list is removed and returned. For example:
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#
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# set L {a b c}
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# set x [lshift L]
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# assert { $x == "a" && $L == "b c" }
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#
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proc lshift {lvar} {
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upvar $lvar L
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set ret [lindex $L 0]
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set L [lrange $L 1 end]
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return $ret
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}
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#-------------------------------------------------------------------------
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# do_thread_test TESTNAME OPTIONS...
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#
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# where OPTIONS are:
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#
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# -seconds SECONDS How many seconds to run the test for
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# -init SCRIPT Script to run before test.
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# -thread NAME COUNT SCRIPT Scripts to run in threads (or processes).
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# -processes BOOLEAN True to use processes instead of threads.
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# -check SCRIPT Script to run after test.
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#
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proc do_thread_test {args} {
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set A $args
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set P(testname) [lshift A]
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set P(seconds) 5
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set P(init) ""
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set P(threads) [list]
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set P(processes) 0
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set P(check) {
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set ic [db eval "PRAGMA integrity_check"]
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if {$ic != "ok"} { error $ic }
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}
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unset -nocomplain ::done
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while {[llength $A]>0} {
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set a [lshift A]
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switch -glob -- $a {
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-seconds {
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set P(seconds) [lshift A]
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}
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-init {
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set P(init) [lshift A]
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}
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-processes {
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set P(processes) [lshift A]
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}
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-check {
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set P(check) [lshift A]
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}
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-thread {
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set name [lshift A]
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set count [lshift A]
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set prg [lshift A]
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lappend P(threads) [list $name $count $prg]
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}
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default {
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error "Unknown option: $a"
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}
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}
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}
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if {$P(seconds) == 0} {
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puts "Skipping $P(testname)"
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return
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}
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puts "Running $P(testname) for $P(seconds) seconds..."
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catch { db close }
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forcedelete test.db test.db-journal test.db-wal
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sqlite3 db test.db
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eval $P(init)
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catch { db close }
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foreach T $P(threads) {
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set name [lindex $T 0]
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set count [lindex $T 1]
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set prg [lindex $T 2]
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for {set i 1} {$i <= $count} {incr i} {
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set vars "
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set E(pid) $i
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set E(nthread) $count
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set E(seconds) $P(seconds)
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"
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set program [string map [list %TEST% $prg %VARS% $vars] {
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%VARS%
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proc usleep {ms} {
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set ::usleep 0
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after $ms {set ::usleep 1}
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vwait ::usleep
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}
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proc integrity_check {{db db}} {
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set ic [$db eval {PRAGMA integrity_check}]
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if {$ic != "ok"} {error $ic}
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}
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proc busyhandler {n} { usleep 10 ; return 0 }
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sqlite3 db test.db
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db busy busyhandler
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db eval { SELECT randomblob($E(pid)*5) }
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set ::finished 0
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after [expr $E(seconds) * 1000] {set ::finished 1}
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proc tt_continue {} { update ; expr ($::finished==0) }
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set rc [catch { %TEST% } msg]
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catch { db close }
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list $rc $msg
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}]
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if {$P(processes)==0} {
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sqlthread spawn ::done($name,$i) $program
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} else {
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testfixture_nb ::done($name,$i) $program
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}
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}
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}
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set report " Results:"
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foreach T $P(threads) {
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set name [lindex $T 0]
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set count [lindex $T 1]
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set prg [lindex $T 2]
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set reslist [list]
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for {set i 1} {$i <= $count} {incr i} {
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set res [wait_for_var ::done($name,$i)]
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lappend reslist [lindex $res 1]
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do_test $P(testname).$name.$i [list lindex $res 0] 0
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}
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append report " $name $reslist"
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}
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puts $report
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sqlite3 db test.db
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set res ""
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if {[catch $P(check) msg]} { set res $msg }
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do_test $P(testname).check [list set {} $res] ""
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}
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# A wrapper around [do_thread_test] which runs the specified test twice.
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# Once using processes, once using threads. This command takes the same
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# arguments as [do_thread_test], except specifying the -processes switch
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# is illegal.
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#
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proc do_thread_test2 {args} {
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set name [lindex $args 0]
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if {[lsearch $args -processes]>=0} { error "bad option: -processes"}
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uplevel [lreplace $args 0 0 do_thread_test "$name-threads" -processes 0]
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uplevel [lreplace $args 0 0 do_thread_test "$name-processes" -processes 1]
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}
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#--------------------------------------------------------------------------
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# Start 10 threads. Each thread performs both read and write
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# transactions. Each read transaction consists of:
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#
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# 1) Reading the md5sum of all but the last table row,
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# 2) Running integrity check.
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# 3) Reading the value stored in the last table row,
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# 4) Check that the values read in steps 1 and 3 are the same, and that
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# the md5sum of all but the last table row has not changed.
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#
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# Each write transaction consists of:
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#
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# 1) Modifying the contents of t1 (inserting, updating, deleting rows).
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# 2) Appending a new row to the table containing the md5sum() of all
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# rows in the table.
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#
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# Each of the N threads runs N read transactions followed by a single write
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# transaction in a loop as fast as possible.
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#
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# There is also a single checkpointer thread. It runs the following loop:
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#
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# 1) Execute "PRAGMA wal_checkpoint"
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# 2) Sleep for 500 ms.
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#
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do_thread_test2 walthread-1 -seconds $seconds(walthread-1) -init {
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execsql {
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PRAGMA journal_mode = WAL;
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CREATE TABLE t1(x PRIMARY KEY);
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PRAGMA lock_status;
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INSERT INTO t1 VALUES(randomblob(100));
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INSERT INTO t1 VALUES(randomblob(100));
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INSERT INTO t1 SELECT md5sum(x) FROM t1;
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}
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} -thread main 10 {
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proc read_transaction {} {
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set results [db eval {
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BEGIN;
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PRAGMA integrity_check;
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SELECT md5sum(x) FROM t1 WHERE rowid != (SELECT max(rowid) FROM t1);
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SELECT x FROM t1 WHERE rowid = (SELECT max(rowid) FROM t1);
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SELECT md5sum(x) FROM t1 WHERE rowid != (SELECT max(rowid) FROM t1);
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COMMIT;
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}]
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if {[llength $results]!=4
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|| [lindex $results 0] != "ok"
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|| [lindex $results 1] != [lindex $results 2]
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|| [lindex $results 2] != [lindex $results 3]
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} {
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error "Failed read transaction: $results"
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}
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}
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proc write_transaction {} {
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db eval {
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BEGIN;
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INSERT INTO t1 VALUES(randomblob(101 + $::E(pid)));
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INSERT INTO t1 VALUES(randomblob(101 + $::E(pid)));
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INSERT INTO t1 SELECT md5sum(x) FROM t1;
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COMMIT;
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}
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}
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# Turn off auto-checkpoint. Otherwise, an auto-checkpoint run by a
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# writer may cause the dedicated checkpoint thread to return an
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# SQLITE_BUSY error.
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#
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db eval { PRAGMA wal_autocheckpoint = 0 }
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set nRun 0
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while {[tt_continue]} {
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read_transaction
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write_transaction
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incr nRun
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}
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set nRun
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} -thread ckpt 1 {
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set nRun 0
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while {[tt_continue]} {
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db eval "PRAGMA wal_checkpoint"
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usleep 500
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incr nRun
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}
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set nRun
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}
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#--------------------------------------------------------------------------
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# This test has clients run the following procedure as fast as possible
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# in a loop:
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#
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# 1. Open a database handle.
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# 2. Execute a read-only transaction on the db.
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# 3. Do "PRAGMA journal_mode = XXX", where XXX is one of WAL or DELETE.
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# Ignore any SQLITE_BUSY error.
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# 4. Execute a write transaction to insert a row into the db.
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# 5. Run "PRAGMA integrity_check"
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#
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# At present, there are 4 clients in total. 2 do "journal_mode = WAL", and
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# two do "journal_mode = DELETE".
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#
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# Each client returns a string of the form "W w, R r", where W is the
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# number of write-transactions performed using a WAL journal, and D is
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# the number of write-transactions performed using a rollback journal.
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# For example, "192 w, 185 r".
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#
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do_thread_test2 walthread-2 -seconds $seconds(walthread-2) -init {
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execsql { CREATE TABLE t1(x INTEGER PRIMARY KEY, y UNIQUE) }
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} -thread RB 2 {
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db close
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set nRun 0
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set nDel 0
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while {[tt_continue]} {
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sqlite3 db test.db
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db busy busyhandler
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db eval { SELECT * FROM sqlite_master }
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catch { db eval { PRAGMA journal_mode = DELETE } }
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db eval {
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BEGIN;
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INSERT INTO t1 VALUES(NULL, randomblob(100+$E(pid)));
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}
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incr nRun 1
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incr nDel [file exists test.db-journal]
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if {[file exists test.db-journal] + [file exists test.db-wal] != 1} {
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error "File-system looks bad..."
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}
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db eval COMMIT
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integrity_check
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db close
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}
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list $nRun $nDel
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set {} "[expr $nRun-$nDel] w, $nDel r"
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} -thread WAL 2 {
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db close
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set nRun 0
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set nDel 0
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while {[tt_continue]} {
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sqlite3 db test.db
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db busy busyhandler
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db eval { SELECT * FROM sqlite_master }
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catch { db eval { PRAGMA journal_mode = WAL } }
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db eval {
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BEGIN;
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INSERT INTO t1 VALUES(NULL, randomblob(110+$E(pid)));
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}
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incr nRun 1
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incr nDel [file exists test.db-journal]
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if {[file exists test.db-journal] + [file exists test.db-wal] != 1} {
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error "File-system looks bad..."
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}
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db eval COMMIT
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integrity_check
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db close
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}
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set {} "[expr $nRun-$nDel] w, $nDel r"
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}
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do_thread_test walthread-3 -seconds $seconds(walthread-3) -init {
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execsql {
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PRAGMA journal_mode = WAL;
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CREATE TABLE t1(cnt PRIMARY KEY, sum1, sum2);
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CREATE INDEX i1 ON t1(sum1);
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CREATE INDEX i2 ON t1(sum2);
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INSERT INTO t1 VALUES(0, 0, 0);
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}
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} -thread t 10 {
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set nextwrite $E(pid)
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proc wal_hook {zDb nEntry} {
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if {$nEntry>10} {
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set rc [catch { db eval {PRAGMA wal_checkpoint} } msg]
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if {$rc && $msg != "database is locked"} { error $msg }
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}
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return 0
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}
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db wal_hook wal_hook
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while {[tt_continue]} {
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set max 0
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while { $max != ($nextwrite-1) && [tt_continue] } {
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set max [db eval { SELECT max(cnt) FROM t1 }]
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}
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if {[tt_continue]} {
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set sum1 [db eval { SELECT sum(cnt) FROM t1 }]
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set sum2 [db eval { SELECT sum(sum1) FROM t1 }]
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db eval { INSERT INTO t1 VALUES($nextwrite, $sum1, $sum2) }
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incr nextwrite $E(nthread)
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integrity_check
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}
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}
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set {} ok
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} -check {
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puts " Final db contains [db eval {SELECT count(*) FROM t1}] rows"
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puts " Final integrity-check says: [db eval {PRAGMA integrity_check}]"
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# Check that the contents of the database are Ok.
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set c 0
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set s1 0
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set s2 0
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db eval { SELECT cnt, sum1, sum2 FROM t1 ORDER BY cnt } {
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if {$c != $cnt || $s1 != $sum1 || $s2 != $sum2} {
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error "database content is invalid"
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}
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incr s2 $s1
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incr s1 $c
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incr c 1
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}
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}
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do_thread_test2 walthread-4 -seconds $seconds(walthread-4) -init {
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execsql {
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PRAGMA journal_mode = WAL;
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CREATE TABLE t1(a INTEGER PRIMARY KEY, b UNIQUE);
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}
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} -thread r 1 {
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# This connection only ever reads the database. Therefore the
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# busy-handler is not required. Disable it to check that this is true.
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#
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# UPDATE: That is no longer entirely true - as we don't use a blocking
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# lock to enter RECOVER state. Which means there is a small chance a
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# reader can see an SQLITE_BUSY.
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#
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while {[tt_continue]} {
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integrity_check
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}
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set {} ok
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} -thread w 1 {
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proc wal_hook {zDb nEntry} {
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if {$nEntry>15} {db eval {PRAGMA wal_checkpoint}}
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return 0
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}
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db wal_hook wal_hook
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set row 1
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while {[tt_continue]} {
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db eval { REPLACE INTO t1 VALUES($row, randomblob(300)) }
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incr row
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if {$row == 10} { set row 1 }
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}
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set {} ok
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}
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# This test case attempts to provoke a deadlock condition that existed in
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# the unix VFS at one point. The problem occurred only while recovering a
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# very large wal file (one that requires a wal-index larger than the
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# initial default allocation of 64KB).
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#
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do_thread_test walthread-5 -seconds $seconds(walthread-5) -init {
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proc log_file_size {nFrame pgsz} {
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expr {12 + ($pgsz+16)*$nFrame}
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}
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execsql {
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PRAGMA page_size = 1024;
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PRAGMA journal_mode = WAL;
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CREATE TABLE t1(x);
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BEGIN;
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INSERT INTO t1 VALUES(randomblob(900));
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 2 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 4 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 8 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 16 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 32 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 64 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 128 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 256 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 512 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 1024 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 2048 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 4096 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 8192 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 16384 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 32768 */
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INSERT INTO t1 SELECT randomblob(900) FROM t1; /* 65536 */
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COMMIT;
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}
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forcecopy test.db-wal bak.db-wal
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forcecopy test.db bak.db
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db close
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forcecopy bak.db-wal test.db-wal
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forcecopy bak.db test.db
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if {[file size test.db-wal] < [log_file_size [expr 64*1024] 1024]} {
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error "Somehow failed to create a large log file"
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}
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puts "Database with large log file recovered. Now running clients..."
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} -thread T 5 {
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db eval { SELECT count(*) FROM t1 }
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}
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unset -nocomplain seconds
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|
|
finish_test
|