third_party/sqlite/src/test/wal3.test - cobalt - Git at Google

 # 2010 April 13
 #
 # 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 file is testing the operation of the library in
 # "PRAGMA journal_mode=WAL" mode.
 #

 set testdir [file dirname $argv0]
 source $testdir/tester.tcl
 source $testdir/lock_common.tcl
 source $testdir/wal_common.tcl
 source $testdir/malloc_common.tcl
 ifcapable !wal {finish_test ; return }

 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

 #-------------------------------------------------------------------------
 # When a rollback or savepoint rollback occurs, the client may remove
 # elements from one of the hash tables in the wal-index. This block
 # of test cases tests that nothing appears to go wrong when this is
 # done.
 #
 do_test wal3-1.0 {
   execsql {
     PRAGMA cache_size = 2000;
     PRAGMA page_size = 1024;
     PRAGMA auto_vacuum = off;
     PRAGMA synchronous = normal;
     PRAGMA journal_mode = WAL;
     PRAGMA wal_autocheckpoint = 0;
     BEGIN;
       CREATE TABLE t1(x);
       INSERT INTO t1 VALUES( a_string(800) );                  /*    1 */
       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 */
       INSERT INTO t1 SELECT a_string(800) FROM t1;             /*   64 */
       INSERT INTO t1 SELECT a_string(800) FROM t1;             /*  128*/
       INSERT INTO t1 SELECT a_string(800) FROM t1;             /*  256 */
       INSERT INTO t1 SELECT a_string(800) FROM t1;             /*  512 */
       INSERT INTO t1 SELECT a_string(800) FROM t1;             /* 1024 */
       INSERT INTO t1 SELECT a_string(800) FROM t1;             /* 2048 */
       INSERT INTO t1 SELECT a_string(800) FROM t1 LIMIT 1970;  /* 4018 */
     COMMIT;
     PRAGMA cache_size = 10;
   }
   wal_frame_count test.db-wal 1024
 } 4056

 for {set i 1} {$i < 50} {incr i} {

   do_test wal3-1.$i.1 {
     set str [a_string 800]
     execsql { UPDATE t1 SET x = $str WHERE rowid = $i }
     lappend L [wal_frame_count test.db-wal 1024]
     execsql {
       BEGIN;
         INSERT INTO t1 SELECT a_string(800) FROM t1 LIMIT 100;
       ROLLBACK;
       PRAGMA integrity_check;
     }
   } {ok}

   # Check that everything looks OK from the point of view of an
   # external connection.
   #
   sqlite3 db2 test.db
   do_test wal3-1.$i.2 {
     execsql { SELECT count(*) FROM t1 } db2
   } 4018
   do_test wal3-1.$i.3 {
     execsql { SELECT x FROM t1 WHERE rowid = $i }
   } $str
   do_test wal3-1.$i.4 {
     execsql { PRAGMA integrity_check } db2
   } {ok}
   db2 close

   # Check that the file-system in its current state can be recovered.
   #
   file copy -force test.db test2.db
   file copy -force test.db-wal test2.db-wal
   file delete -force test2.db-journal
   sqlite3 db2 test2.db
   do_test wal3-1.$i.5 {
     execsql { SELECT count(*) FROM t1 } db2
   } 4018
   do_test wal3-1.$i.6 {
     execsql { SELECT x FROM t1 WHERE rowid = $i }
   } $str
   do_test wal3-1.$i.7 {
     execsql { PRAGMA integrity_check } db2
   } {ok}
   db2 close
 }

 proc byte_is_zero {file offset} {
   if {[file size test.db] <= $offset} { return 1 }
   expr { [hexio_read $file $offset 1] == "00" }
 }

 do_multiclient_test i {

   set testname(1) multiproc
   set testname(2) singleproc
   set tn $testname($i)

   do_test wal3-2.$tn.1 {
     sql1 {
       PRAGMA page_size = 1024;
       PRAGMA journal_mode = WAL;
     }
     sql1 {
       CREATE TABLE t1(a, b);
       INSERT INTO t1 VALUES(1, 'one');
       BEGIN;
         SELECT * FROM t1;
     }
   } {1 one}
   do_test wal3-2.$tn.2 {
     sql2 {
       CREATE TABLE t2(a, b);
       INSERT INTO t2 VALUES(2, 'two');
       BEGIN;
         SELECT * FROM t2;
     }
   } {2 two}
   do_test wal3-2.$tn.3 {
     sql3 {
       CREATE TABLE t3(a, b);
       INSERT INTO t3 VALUES(3, 'three');
       BEGIN;
         SELECT * FROM t3;
     }
   } {3 three}

   # Try to checkpoint the database using [db]. It should be possible to
   # checkpoint everything except the table added by [db3] (checkpointing
   # these frames would clobber the snapshot currently being used by [db2]).
   #
   # After [db2] has committed, a checkpoint can copy the entire log to the
   # database file. Checkpointing after [db3] has committed is therefore a
   # no-op, as the entire log has already been backfilled.
   #
   do_test wal3-2.$tn.4 {
     sql1 {
       COMMIT;
       PRAGMA wal_checkpoint;
     }
     byte_is_zero test.db [expr $AUTOVACUUM ? 4*1024 : 3*1024]
   } {1}
   do_test wal3-2.$tn.5 {
     sql2 {
       COMMIT;
       PRAGMA wal_checkpoint;
     }
     list [byte_is_zero test.db [expr $AUTOVACUUM ? 4*1024 : 3*1024]]   \
          [byte_is_zero test.db [expr $AUTOVACUUM ? 5*1024 : 4*1024]]
   } {0 1}
   do_test wal3-2.$tn.6 {
     sql3 {
       COMMIT;
       PRAGMA wal_checkpoint;
     }
     list [byte_is_zero test.db [expr $AUTOVACUUM ? 4*1024 : 3*1024]]   \
          [byte_is_zero test.db [expr $AUTOVACUUM ? 5*1024 : 4*1024]]
   } {0 1}
 }
 catch {db close}

 #-------------------------------------------------------------------------
 # Test that that for the simple test:
 #
 #   CREATE TABLE x(y);
 #   INSERT INTO x VALUES('z');
 #   PRAGMA wal_checkpoint;
 #
 # in WAL mode the xSync method is invoked as expected for each of
 # synchronous=off, synchronous=normal and synchronous=full.
 #
 foreach {tn syncmode synccount} {
   1 off
     {}
   2 normal
     {test.db-wal normal test.db normal}
   3 full
     {test.db-wal normal test.db-wal normal test.db-wal normal test.db normal}
 } {

   proc sync_counter {args} {
     foreach {method filename id flags} $args break
     lappend ::syncs [file tail $filename] $flags
   }
   do_test wal3-3.$tn {
     file delete -force test.db test.db-wal test.db-journal

     testvfs T
     T filter {}
     T script sync_counter
     sqlite3 db test.db -vfs T

     execsql "PRAGMA synchronous = $syncmode"
     execsql { PRAGMA journal_mode = WAL }

     set ::syncs [list]
     T filter xSync
     execsql {
       CREATE TABLE x(y);
       INSERT INTO x VALUES('z');
       PRAGMA wal_checkpoint;
     }
     T filter {}
     set ::syncs
   } $synccount

   db close
   T delete
 }

 #-------------------------------------------------------------------------
 # When recovering the contents of a WAL file, a process obtains the WRITER
 # lock, then locks all other bytes before commencing recovery. If it fails
 # to lock all other bytes (because some other process is holding a read
 # lock) it should retry up to 100 times. Then return SQLITE_PROTOCOL to the
 # caller. Test this (test case wal3-4.3).
 #
 # Also test the effect of hitting an SQLITE_BUSY while attempting to obtain
 # the WRITER lock (should be the same). Test case wal3-4.4.
 #
 proc lock_callback {method filename handle lock} {
   lappend ::locks $lock
 }
 do_test wal3-4.1 {
   testvfs T
   T filter xShmLock
   T script lock_callback
   set ::locks [list]
   sqlite3 db test.db -vfs T
   execsql { SELECT * FROM x }
   lrange $::locks 0 3
 } [list {0 1 lock exclusive} {1 7 lock exclusive}      \
         {1 7 unlock exclusive} {0 1 unlock exclusive}  \
 ]
 do_test wal3-4.2 {
   db close
   set ::locks [list]
   sqlite3 db test.db -vfs T
   execsql { SELECT * FROM x }
   lrange $::locks 0 3
 } [list {0 1 lock exclusive} {1 7 lock exclusive}      \
         {1 7 unlock exclusive} {0 1 unlock exclusive}  \
 ]
 proc lock_callback {method filename handle lock} {
   if {$lock == "1 7 lock exclusive"} { return SQLITE_BUSY }
   return SQLITE_OK
 }
 puts "  Warning: This next test case causes SQLite to call xSleep(1) 100 times."
 puts "  Normally this equates to a 100ms delay, but if SQLite is built on unix"
 puts "  without HAVE_USLEEP defined, it may be 100 seconds."
 do_test wal3-4.3 {
   db close
   set ::locks [list]
   sqlite3 db test.db -vfs T
   catchsql { SELECT * FROM x }
 } {1 {locking protocol}}

 puts "  Warning: Same again!"
 proc lock_callback {method filename handle lock} {
   if {$lock == "0 1 lock exclusive"} { return SQLITE_BUSY }
   return SQLITE_OK
 }
 do_test wal3-4.4 {
   db close
   set ::locks [list]
   sqlite3 db test.db -vfs T
   catchsql { SELECT * FROM x }
 } {1 {locking protocol}}
 db close
 T delete


 #-------------------------------------------------------------------------
 # Only one client may run recovery at a time. Test this mechanism.
 #
 # When client-2 tries to open a read transaction while client-1 is
 # running recovery, it fails to obtain a lock on an aReadMark[] slot
 # (because they are all locked by recovery). It then tries to obtain
 # a shared lock on the RECOVER lock to see if there really is a
 # recovery running or not.
 #
 # This block of tests checks the effect of an SQLITE_BUSY or SQLITE_IOERR
 # being returned when client-2 attempts a shared lock on the RECOVER byte.
 #
 # An SQLITE_BUSY should be converted to an SQLITE_BUSY_RECOVERY. An
 # SQLITE_IOERR should be returned to the caller.
 #
 do_test wal3-5.1 {
   faultsim_delete_and_reopen
   execsql {
     PRAGMA journal_mode = WAL;
     CREATE TABLE t1(a, b);
     INSERT INTO t1 VALUES(1, 2);
     INSERT INTO t1 VALUES(3, 4);
   }
   faultsim_save_and_close
 } {}

 testvfs T -default 1
 T script method_callback

 proc method_callback {method args} {
   if {$method == "xShmBarrier"} {
     incr ::barrier_count
     if {$::barrier_count == 2} {
       # This code is executed within the xShmBarrier() callback invoked
       # by the client running recovery as part of writing the recovered
       # wal-index header. If a second client attempts to access the
       # database now, it reads a corrupt (partially written) wal-index
       # header. But it cannot even get that far, as the first client
       # is still holding all the locks (recovery takes an exclusive lock
       # on *all* db locks, preventing access by any other client).
       #
       # If global variable ::wal3_do_lockfailure is non-zero, then set
       # things up so that an IO error occurs within an xShmLock() callback
       # made by the second client (aka [db2]).
       #
       sqlite3 db2 test.db
       if { $::wal3_do_lockfailure } { T filter xShmLock }
       set ::testrc [ catch { db2 eval "SELECT * FROM t1" } ::testmsg ]
       T filter {}
       db2 close
     }
   }

   if {$method == "xShmLock"} {
     foreach {file handle spec} $args break
     if { $spec == "2 1 lock shared" } {
       return SQLITE_IOERR
     }
   }

   return SQLITE_OK
 }

 # Test a normal SQLITE_BUSY return.
 #
 T filter xShmBarrier
 set testrc ""
 set testmsg ""
 set barrier_count 0
 set wal3_do_lockfailure 0
 do_test wal3-5.2 {
   faultsim_restore_and_reopen
   execsql { SELECT * FROM t1 }
 } {1 2 3 4}
 do_test wal3-5.3 {
   list $::testrc $::testmsg
 } {1 {database is locked}}
 db close

 # Test an SQLITE_IOERR return.
 #
 T filter xShmBarrier
 set barrier_count 0
 set wal3_do_lockfailure 1
 set testrc ""
 set testmsg ""
 do_test wal3-5.4 {
   faultsim_restore_and_reopen
   execsql { SELECT * FROM t1 }
 } {1 2 3 4}
 do_test wal3-5.5 {
   list $::testrc $::testmsg
 } {1 {disk I/O error}}

 db close
 T delete

 #-------------------------------------------------------------------------
 # When opening a read-transaction on a database, if the entire log has
 # already been copied to the database file, the reader grabs a special
 # kind of read lock (on aReadMark[0]). This set of test cases tests the
 # outcome of the following:
 #
 #   + The reader discovering that between the time when it determined
 #     that the log had been completely backfilled and the lock is obtained
 #     that a writer has written to the log. In this case the reader should
 #     acquire a different read-lock (not aReadMark[0]) and read the new
 #     snapshot.
 #
 #   + The attempt to obtain the lock on aReadMark[0] fails with SQLITE_BUSY.
 #     This can happen if a checkpoint is ongoing. In this case also simply
 #     obtain a different read-lock.
 #
 catch {db close}
 testvfs T -default 1
 do_test wal3-6.1.1 {
   file delete -force test.db test.db-journal test.db wal
   sqlite3 db test.db
   execsql { PRAGMA auto_vacuum = off }
   execsql { PRAGMA journal_mode = WAL }
   execsql {
     CREATE TABLE t1(a, b);
     INSERT INTO t1 VALUES('o', 't');
     INSERT INTO t1 VALUES('t', 'f');
   }
 } {}
 do_test wal3-6.1.2 {
   sqlite3 db2 test.db
   sqlite3 db3 test.db
   execsql { BEGIN ; SELECT * FROM t1 } db3
 } {o t t f}
 do_test wal3-6.1.3 {
   execsql { PRAGMA wal_checkpoint } db2
 } {0 7 7}

 # At this point the log file has been fully checkpointed. However,
 # connection [db3] holds a lock that prevents the log from being wrapped.
 # Test case 3.6.1.4 has [db] attempt a read-lock on aReadMark[0]. But
 # as it is obtaining the lock, [db2] appends to the log file.
 #
 T filter xShmLock
 T script lock_callback
 proc lock_callback {method file handle spec} {
   if {$spec == "3 1 lock shared"} {
     # This is the callback for [db] to obtain the read lock on aReadMark[0].
     # Disable future callbacks using [T filter {}] and write to the log
     # file using [db2]. [db3] is preventing [db2] from wrapping the log
     # here, so this is an append.
     T filter {}
     db2 eval { INSERT INTO t1 VALUES('f', 's') }
   }
   return SQLITE_OK
 }
 do_test wal3-6.1.4 {
   execsql {
     BEGIN;
     SELECT * FROM t1;
   }
 } {o t t f f s}

 # [db] should be left holding a read-lock on some slot other than
 # aReadMark[0]. Test this by demonstrating that the read-lock is preventing
 # the log from being wrapped.
 #
 do_test wal3-6.1.5 {
   db3 eval COMMIT
   db2 eval { PRAGMA wal_checkpoint }
   set sz1 [file size test.db-wal]
   db2 eval { INSERT INTO t1 VALUES('s', 'e') }
   set sz2 [file size test.db-wal]
   expr {$sz2>$sz1}
 } {1}

 # Test that if [db2] had not interfered when [db] was trying to grab
 # aReadMark[0], it would have been possible to wrap the log in 3.6.1.5.
 #
 do_test wal3-6.1.6 {
   execsql { COMMIT }
   execsql { PRAGMA wal_checkpoint } db2
   execsql {
     BEGIN;
     SELECT * FROM t1;
   }
 } {o t t f f s s e}
 do_test wal3-6.1.7 {
   db2 eval { PRAGMA wal_checkpoint }
   set sz1 [file size test.db-wal]
   db2 eval { INSERT INTO t1 VALUES('n', 't') }
   set sz2 [file size test.db-wal]
   expr {$sz2==$sz1}
 } {1}

 db3 close
 db2 close
 db close

 do_test wal3-6.2.1 {
   file delete -force test.db test.db-journal test.db wal
   sqlite3 db test.db
   sqlite3 db2 test.db
   execsql { PRAGMA auto_vacuum = off }
   execsql { PRAGMA journal_mode = WAL }
   execsql {
     CREATE TABLE t1(a, b);
     INSERT INTO t1 VALUES('h', 'h');
     INSERT INTO t1 VALUES('l', 'b');
   }
 } {}

 T filter xShmLock
 T script lock_callback
 proc lock_callback {method file handle spec} {
   if {$spec == "3 1 unlock exclusive"} {
     T filter {}
     set ::R [db2 eval {
       BEGIN;
       SELECT * FROM t1;
     }]
   }
 }
 do_test wal3-6.2.2 {
   execsql { PRAGMA wal_checkpoint }
 } {0 7 7}
 do_test wal3-6.2.3 {
   set ::R
 } {h h l b}
 do_test wal3-6.2.4 {
   set sz1 [file size test.db-wal]
   execsql { INSERT INTO t1 VALUES('b', 'c'); }
   set sz2 [file size test.db-wal]
   expr {$sz2 > $sz1}
 } {1}
 do_test wal3-6.2.5 {
   db2 eval { COMMIT }
   execsql { PRAGMA wal_checkpoint }
   set sz1 [file size test.db-wal]
   execsql { INSERT INTO t1 VALUES('n', 'o'); }
   set sz2 [file size test.db-wal]
   expr {$sz2 == $sz1}
 } {1}

 db2 close
 db close
 T delete

 #-------------------------------------------------------------------------
 # When opening a read-transaction on a database, if the entire log has
 # not yet been copied to the database file, the reader grabs a read
 # lock on aReadMark[x], where x>0. The following test cases experiment
 # with the outcome of the following:
 #
 #   + The reader discovering that between the time when it read the
 #     wal-index header and the lock was obtained that a writer has
 #     written to the log. In this case the reader should re-read the
 #     wal-index header and lock a snapshot corresponding to the new
 #     header.
 #
 #   + The value in the aReadMark[x] slot has been modified since it was
 #     read.
 #
 catch {db close}
 testvfs T -default 1
 do_test wal3-7.1.1 {
   file delete -force test.db test.db-journal test.db wal
   sqlite3 db test.db
   execsql {
     PRAGMA journal_mode = WAL;
     CREATE TABLE blue(red PRIMARY KEY, green);
   }
 } {wal}

 T script method_callback
 T filter xOpen
 proc method_callback {method args} {
   if {$method == "xOpen"} { return "reader" }
 }
 do_test wal3-7.1.2 {
   sqlite3 db2 test.db
   execsql { SELECT * FROM blue } db2
 } {}

 T filter xShmLock
 set ::locks [list]
 proc method_callback {method file handle spec} {
   if {$handle != "reader" } { return }
   if {$method == "xShmLock"} {
     catch { execsql { INSERT INTO blue VALUES(1, 2) } }
     catch { execsql { INSERT INTO blue VALUES(3, 4) } }
   }
   lappend ::locks $spec
 }
 do_test wal3-7.1.3 {
   execsql { SELECT * FROM blue } db2
 } {1 2 3 4}
 do_test wal3-7.1.4 {
   set ::locks
 } {{4 1 lock shared} {4 1 unlock shared} {5 1 lock shared} {5 1 unlock shared}}

 set ::locks [list]
 proc method_callback {method file handle spec} {
   if {$handle != "reader" } { return }
   if {$method == "xShmLock"} {
     catch { execsql { INSERT INTO blue VALUES(5, 6) } }
   }
   lappend ::locks $spec
 }
 do_test wal3-7.2.1 {
   execsql { SELECT * FROM blue } db2
 } {1 2 3 4 5 6}
 do_test wal3-7.2.2 {
   set ::locks
 } {{5 1 lock shared} {5 1 unlock shared} {4 1 lock shared} {4 1 unlock shared}}

 db close
 db2 close
 T delete

 #-------------------------------------------------------------------------
 #
 do_test wal3-8.1 {
   file delete -force test.db test.db-journal test.db wal
   sqlite3 db test.db
   sqlite3 db2 test.db
   execsql {
     PRAGMA auto_vacuum = off;
     PRAGMA journal_mode = WAL;
     CREATE TABLE b(c);
     INSERT INTO b VALUES('Tehran');
     INSERT INTO b VALUES('Qom');
     INSERT INTO b VALUES('Markazi');
     PRAGMA wal_checkpoint;
   }
 } {wal 0 9 9}
 do_test wal3-8.2 {
   execsql { SELECT * FROM b }
 } {Tehran Qom Markazi}
 do_test wal3-8.3 {
   db eval { SELECT * FROM b } {
     db eval { INSERT INTO b VALUES('Qazvin') }
     set r [db2 eval { SELECT * FROM b }]
     break
   }
   set r
 } {Tehran Qom Markazi Qazvin}
 do_test wal3-8.4 {
   execsql {
     INSERT INTO b VALUES('Gilan');
     INSERT INTO b VALUES('Ardabil');
   }
 } {}
 db2 close

 faultsim_save_and_close
 testvfs T -default 1
 faultsim_restore_and_reopen
 T filter xShmLock
 T script lock_callback

 proc lock_callback {method file handle spec} {
   if {$spec == "4 1 unlock exclusive"} {
     T filter {}
     set ::r [catchsql { SELECT * FROM b } db2]
   }
 }
 sqlite3 db test.db
 sqlite3 db2 test.db
 do_test wal3-8.5 {
   execsql { SELECT * FROM b }
 } {Tehran Qom Markazi Qazvin Gilan Ardabil}
 do_test wal3-8.6 {
   set ::r
 } {1 {locking protocol}}

 db close
 db2 close

 faultsim_restore_and_reopen
 sqlite3 db2 test.db
 T filter xShmLock
 T script lock_callback
 proc lock_callback {method file handle spec} {
   if {$spec == "1 7 unlock exclusive"} {
     T filter {}
     set ::r [catchsql { SELECT * FROM b } db2]
   }
 }
 unset ::r
 do_test wal3-8.5 {
   execsql { SELECT * FROM b }
 } {Tehran Qom Markazi Qazvin Gilan Ardabil}
 do_test wal3-8.6 {
   set ::r
 } {1 {locking protocol}}

 db close
 db2 close
 T delete

 #-------------------------------------------------------------------------
 # When a connection opens a read-lock on the database, it searches for
 # an aReadMark[] slot that is already set to the mxFrame value for the
 # new transaction. If it cannot find one, it attempts to obtain an
 # exclusive lock on an aReadMark[] slot for the purposes of modifying
 # the value, then drops back to a shared-lock for the duration of the
 # transaction.
 #
 # This test case verifies that if an exclusive lock cannot be obtained
 # on any aReadMark[] slot (because there are already several readers),
 # the client takes a shared-lock on a slot without modifying the value
 # and continues.
 #
 set nConn 50
 if { [string match *BSD $tcl_platform(os)] } { set nConn 35 }
 do_test wal3-9.0 {
   file delete -force test.db test.db-journal test.db wal
   sqlite3 db test.db
   execsql {
     PRAGMA page_size = 1024;
     PRAGMA journal_mode = WAL;
     CREATE TABLE whoami(x);
     INSERT INTO whoami VALUES('nobody');
   }
 } {wal}
 for {set i 0} {$i < $nConn} {incr i} {
   set c db$i
   do_test wal3-9.1.$i {
     sqlite3 $c test.db
     execsql { UPDATE whoami SET x = $c }
     execsql {
       BEGIN;
       SELECT * FROM whoami
     } $c
   } $c
 }
 for {set i 0} {$i < $nConn} {incr i} {
   set c db$i
   do_test wal3-9.2.$i {
     execsql { SELECT * FROM whoami } $c
   } $c
 }

 set sz [expr 1024 * (2+$AUTOVACUUM)]
 do_test wal3-9.3 {
   for {set i 0} {$i < ($nConn-1)} {incr i} { db$i close }
   execsql { PRAGMA wal_checkpoint }
   byte_is_zero test.db [expr $sz-1024]
 } {1}
 do_test wal3-9.4 {
   db[expr $nConn-1] close
   execsql { PRAGMA wal_checkpoint }
   set sz2 [file size test.db]
   byte_is_zero test.db [expr $sz-1024]
 } {0}

 do_multiclient_test tn {
   do_test wal3-10.$tn.1 {
     sql1 {
       PRAGMA page_size = 1024;
       CREATE TABLE t1(x);
       PRAGMA journal_mode = WAL;
       PRAGMA wal_autocheckpoint = 100000;
       BEGIN;
         INSERT INTO t1 VALUES(randomblob(800));
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 2
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 4
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 8
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 16
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 32
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 64
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 128
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 256
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 512
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 1024
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 2048
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 4096
         INSERT INTO t1 SELECT randomblob(800) FROM t1;   -- 8192
       COMMIT;
       CREATE INDEX i1 ON t1(x);
     }

     expr {[file size test.db-wal] > [expr 1032*9000]}
   } 1

   do_test wal3-10.$tn.2 {
     sql2 {PRAGMA integrity_check}
   } {ok}
 }

 finish_test
	# 2010 April 13
	#
	# 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 file is testing the operation of the library in
	# "PRAGMA journal_mode=WAL" mode.
	#

	set testdir [file dirname $argv0]
	source $testdir/tester.tcl
	source $testdir/lock_common.tcl
	source $testdir/wal_common.tcl
	source $testdir/malloc_common.tcl
	ifcapable !wal {finish_test ; return }

	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

	#-------------------------------------------------------------------------
	# When a rollback or savepoint rollback occurs, the client may remove
	# elements from one of the hash tables in the wal-index. This block
	# of test cases tests that nothing appears to go wrong when this is
	# done.
	#
	do_test wal3-1.0 {
	execsql {
	PRAGMA cache_size = 2000;
	PRAGMA page_size = 1024;
	PRAGMA auto_vacuum = off;
	PRAGMA synchronous = normal;
	PRAGMA journal_mode = WAL;
	PRAGMA wal_autocheckpoint = 0;
	BEGIN;
	CREATE TABLE t1(x);
	INSERT INTO t1 VALUES( a_string(800) ); /* 1 */
	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 */
	INSERT INTO t1 SELECT a_string(800) FROM t1; /* 64 */
	INSERT INTO t1 SELECT a_string(800) FROM t1; /* 128*/
	INSERT INTO t1 SELECT a_string(800) FROM t1; /* 256 */
	INSERT INTO t1 SELECT a_string(800) FROM t1; /* 512 */
	INSERT INTO t1 SELECT a_string(800) FROM t1; /* 1024 */
	INSERT INTO t1 SELECT a_string(800) FROM t1; /* 2048 */
	INSERT INTO t1 SELECT a_string(800) FROM t1 LIMIT 1970; /* 4018 */
	COMMIT;
	PRAGMA cache_size = 10;
	}
	wal_frame_count test.db-wal 1024
	} 4056

	for {set i 1} {$i < 50} {incr i} {

	do_test wal3-1.$i.1 {
	set str [a_string 800]
	execsql { UPDATE t1 SET x = $str WHERE rowid = $i }
	lappend L [wal_frame_count test.db-wal 1024]
	execsql {
	BEGIN;
	INSERT INTO t1 SELECT a_string(800) FROM t1 LIMIT 100;
	ROLLBACK;
	PRAGMA integrity_check;
	}
	} {ok}

	# Check that everything looks OK from the point of view of an
	# external connection.
	#
	sqlite3 db2 test.db
	do_test wal3-1.$i.2 {
	execsql { SELECT count(*) FROM t1 } db2
	} 4018
	do_test wal3-1.$i.3 {
	execsql { SELECT x FROM t1 WHERE rowid = $i }
	} $str
	do_test wal3-1.$i.4 {
	execsql { PRAGMA integrity_check } db2
	} {ok}
	db2 close

	# Check that the file-system in its current state can be recovered.
	#
	file copy -force test.db test2.db
	file copy -force test.db-wal test2.db-wal
	file delete -force test2.db-journal
	sqlite3 db2 test2.db
	do_test wal3-1.$i.5 {
	execsql { SELECT count(*) FROM t1 } db2
	} 4018
	do_test wal3-1.$i.6 {
	execsql { SELECT x FROM t1 WHERE rowid = $i }
	} $str
	do_test wal3-1.$i.7 {
	execsql { PRAGMA integrity_check } db2
	} {ok}
	db2 close
	}

	proc byte_is_zero {file offset} {
	if {[file size test.db] <= $offset} { return 1 }
	expr { [hexio_read $file $offset 1] == "00" }
	}

	do_multiclient_test i {

	set testname(1) multiproc
	set testname(2) singleproc
	set tn $testname($i)

	do_test wal3-2.$tn.1 {
	sql1 {
	PRAGMA page_size = 1024;
	PRAGMA journal_mode = WAL;
	}
	sql1 {
	CREATE TABLE t1(a, b);
	INSERT INTO t1 VALUES(1, 'one');
	BEGIN;
	SELECT * FROM t1;
	}
	} {1 one}
	do_test wal3-2.$tn.2 {
	sql2 {
	CREATE TABLE t2(a, b);
	INSERT INTO t2 VALUES(2, 'two');
	BEGIN;
	SELECT * FROM t2;
	}
	} {2 two}
	do_test wal3-2.$tn.3 {
	sql3 {
	CREATE TABLE t3(a, b);
	INSERT INTO t3 VALUES(3, 'three');
	BEGIN;
	SELECT * FROM t3;
	}
	} {3 three}

	# Try to checkpoint the database using [db]. It should be possible to
	# checkpoint everything except the table added by [db3] (checkpointing
	# these frames would clobber the snapshot currently being used by [db2]).
	#
	# After [db2] has committed, a checkpoint can copy the entire log to the
	# database file. Checkpointing after [db3] has committed is therefore a
	# no-op, as the entire log has already been backfilled.
	#
	do_test wal3-2.$tn.4 {
	sql1 {
	COMMIT;
	PRAGMA wal_checkpoint;
	}
	byte_is_zero test.db [expr $AUTOVACUUM ? 41024 : 31024]
	} {1}
	do_test wal3-2.$tn.5 {
	sql2 {
	COMMIT;
	PRAGMA wal_checkpoint;
	}
	list [byte_is_zero test.db [expr $AUTOVACUUM ? 41024 : 31024]] \
	[byte_is_zero test.db [expr $AUTOVACUUM ? 51024 : 41024]]
	} {0 1}
	do_test wal3-2.$tn.6 {
	sql3 {
	COMMIT;
	PRAGMA wal_checkpoint;
	}
	list [byte_is_zero test.db [expr $AUTOVACUUM ? 41024 : 31024]] \
	[byte_is_zero test.db [expr $AUTOVACUUM ? 51024 : 41024]]
	} {0 1}
	}
	catch {db close}

	#-------------------------------------------------------------------------
	# Test that that for the simple test:
	#
	# CREATE TABLE x(y);
	# INSERT INTO x VALUES('z');
	# PRAGMA wal_checkpoint;
	#
	# in WAL mode the xSync method is invoked as expected for each of
	# synchronous=off, synchronous=normal and synchronous=full.
	#
	foreach {tn syncmode synccount} {
	1 off
	{}
	2 normal
	{test.db-wal normal test.db normal}
	3 full
	{test.db-wal normal test.db-wal normal test.db-wal normal test.db normal}
	} {

	proc sync_counter {args} {
	foreach {method filename id flags} $args break
	lappend ::syncs [file tail $filename] $flags
	}
	do_test wal3-3.$tn {
	file delete -force test.db test.db-wal test.db-journal

	testvfs T
	T filter {}
	T script sync_counter
	sqlite3 db test.db -vfs T

	execsql "PRAGMA synchronous = $syncmode"
	execsql { PRAGMA journal_mode = WAL }

	set ::syncs [list]
	T filter xSync
	execsql {
	CREATE TABLE x(y);
	INSERT INTO x VALUES('z');
	PRAGMA wal_checkpoint;
	}
	T filter {}
	set ::syncs
	} $synccount

	db close
	T delete
	}

	#-------------------------------------------------------------------------
	# When recovering the contents of a WAL file, a process obtains the WRITER
	# lock, then locks all other bytes before commencing recovery. If it fails
	# to lock all other bytes (because some other process is holding a read
	# lock) it should retry up to 100 times. Then return SQLITE_PROTOCOL to the
	# caller. Test this (test case wal3-4.3).
	#
	# Also test the effect of hitting an SQLITE_BUSY while attempting to obtain
	# the WRITER lock (should be the same). Test case wal3-4.4.
	#
	proc lock_callback {method filename handle lock} {
	lappend ::locks $lock
	}
	do_test wal3-4.1 {
	testvfs T
	T filter xShmLock
	T script lock_callback
	set ::locks [list]
	sqlite3 db test.db -vfs T
	execsql { SELECT * FROM x }
	lrange $::locks 0 3
	} [list {0 1 lock exclusive} {1 7 lock exclusive} \
	{1 7 unlock exclusive} {0 1 unlock exclusive} \
	]
	do_test wal3-4.2 {
	db close
	set ::locks [list]
	sqlite3 db test.db -vfs T
	execsql { SELECT * FROM x }
	lrange $::locks 0 3
	} [list {0 1 lock exclusive} {1 7 lock exclusive} \
	{1 7 unlock exclusive} {0 1 unlock exclusive} \
	]
	proc lock_callback {method filename handle lock} {
	if {$lock == "1 7 lock exclusive"} { return SQLITE_BUSY }
	return SQLITE_OK
	}
	puts " Warning: This next test case causes SQLite to call xSleep(1) 100 times."
	puts " Normally this equates to a 100ms delay, but if SQLite is built on unix"
	puts " without HAVE_USLEEP defined, it may be 100 seconds."
	do_test wal3-4.3 {
	db close
	set ::locks [list]
	sqlite3 db test.db -vfs T
	catchsql { SELECT * FROM x }
	} {1 {locking protocol}}

	puts " Warning: Same again!"
	proc lock_callback {method filename handle lock} {
	if {$lock == "0 1 lock exclusive"} { return SQLITE_BUSY }
	return SQLITE_OK
	}
	do_test wal3-4.4 {
	db close
	set ::locks [list]
	sqlite3 db test.db -vfs T
	catchsql { SELECT * FROM x }
	} {1 {locking protocol}}
	db close
	T delete


	#-------------------------------------------------------------------------
	# Only one client may run recovery at a time. Test this mechanism.
	#
	# When client-2 tries to open a read transaction while client-1 is
	# running recovery, it fails to obtain a lock on an aReadMark[] slot
	# (because they are all locked by recovery). It then tries to obtain
	# a shared lock on the RECOVER lock to see if there really is a
	# recovery running or not.
	#
	# This block of tests checks the effect of an SQLITE_BUSY or SQLITE_IOERR
	# being returned when client-2 attempts a shared lock on the RECOVER byte.
	#
	# An SQLITE_BUSY should be converted to an SQLITE_BUSY_RECOVERY. An
	# SQLITE_IOERR should be returned to the caller.
	#
	do_test wal3-5.1 {
	faultsim_delete_and_reopen
	execsql {
	PRAGMA journal_mode = WAL;
	CREATE TABLE t1(a, b);
	INSERT INTO t1 VALUES(1, 2);
	INSERT INTO t1 VALUES(3, 4);
	}
	faultsim_save_and_close
	} {}

	testvfs T -default 1
	T script method_callback

	proc method_callback {method args} {
	if {$method == "xShmBarrier"} {
	incr ::barrier_count
	if {$::barrier_count == 2} {
	# This code is executed within the xShmBarrier() callback invoked
	# by the client running recovery as part of writing the recovered
	# wal-index header. If a second client attempts to access the
	# database now, it reads a corrupt (partially written) wal-index
	# header. But it cannot even get that far, as the first client
	# is still holding all the locks (recovery takes an exclusive lock
	# on all db locks, preventing access by any other client).
	#
	# If global variable ::wal3_do_lockfailure is non-zero, then set
	# things up so that an IO error occurs within an xShmLock() callback
	# made by the second client (aka [db2]).
	#
	sqlite3 db2 test.db
	if { $::wal3_do_lockfailure } { T filter xShmLock }
	set ::testrc [ catch { db2 eval "SELECT * FROM t1" } ::testmsg ]
	T filter {}
	db2 close
	}
	}

	if {$method == "xShmLock"} {
	foreach {file handle spec} $args break
	if { $spec == "2 1 lock shared" } {
	return SQLITE_IOERR
	}
	}

	return SQLITE_OK
	}

	# Test a normal SQLITE_BUSY return.
	#
	T filter xShmBarrier
	set testrc ""
	set testmsg ""
	set barrier_count 0
	set wal3_do_lockfailure 0
	do_test wal3-5.2 {
	faultsim_restore_and_reopen
	execsql { SELECT * FROM t1 }
	} {1 2 3 4}
	do_test wal3-5.3 {
	list $::testrc $::testmsg
	} {1 {database is locked}}
	db close

	# Test an SQLITE_IOERR return.
	#
	T filter xShmBarrier
	set barrier_count 0
	set wal3_do_lockfailure 1
	set testrc ""
	set testmsg ""
	do_test wal3-5.4 {
	faultsim_restore_and_reopen
	execsql { SELECT * FROM t1 }
	} {1 2 3 4}
	do_test wal3-5.5 {
	list $::testrc $::testmsg
	} {1 {disk I/O error}}

	db close
	T delete

	#-------------------------------------------------------------------------
	# When opening a read-transaction on a database, if the entire log has
	# already been copied to the database file, the reader grabs a special
	# kind of read lock (on aReadMark[0]). This set of test cases tests the
	# outcome of the following:
	#
	# + The reader discovering that between the time when it determined
	# that the log had been completely backfilled and the lock is obtained
	# that a writer has written to the log. In this case the reader should
	# acquire a different read-lock (not aReadMark[0]) and read the new
	# snapshot.
	#
	# + The attempt to obtain the lock on aReadMark[0] fails with SQLITE_BUSY.
	# This can happen if a checkpoint is ongoing. In this case also simply
	# obtain a different read-lock.
	#
	catch {db close}
	testvfs T -default 1
	do_test wal3-6.1.1 {
	file delete -force test.db test.db-journal test.db wal
	sqlite3 db test.db
	execsql { PRAGMA auto_vacuum = off }
	execsql { PRAGMA journal_mode = WAL }
	execsql {
	CREATE TABLE t1(a, b);
	INSERT INTO t1 VALUES('o', 't');
	INSERT INTO t1 VALUES('t', 'f');
	}
	} {}
	do_test wal3-6.1.2 {
	sqlite3 db2 test.db
	sqlite3 db3 test.db
	execsql { BEGIN ; SELECT * FROM t1 } db3
	} {o t t f}
	do_test wal3-6.1.3 {
	execsql { PRAGMA wal_checkpoint } db2
	} {0 7 7}

	# At this point the log file has been fully checkpointed. However,
	# connection [db3] holds a lock that prevents the log from being wrapped.
	# Test case 3.6.1.4 has [db] attempt a read-lock on aReadMark[0]. But
	# as it is obtaining the lock, [db2] appends to the log file.
	#
	T filter xShmLock
	T script lock_callback
	proc lock_callback {method file handle spec} {
	if {$spec == "3 1 lock shared"} {
	# This is the callback for [db] to obtain the read lock on aReadMark[0].
	# Disable future callbacks using [T filter {}] and write to the log
	# file using [db2]. [db3] is preventing [db2] from wrapping the log
	# here, so this is an append.
	T filter {}
	db2 eval { INSERT INTO t1 VALUES('f', 's') }
	}
	return SQLITE_OK
	}
	do_test wal3-6.1.4 {
	execsql {
	BEGIN;
	SELECT * FROM t1;
	}
	} {o t t f f s}

	# [db] should be left holding a read-lock on some slot other than
	# aReadMark[0]. Test this by demonstrating that the read-lock is preventing
	# the log from being wrapped.
	#
	do_test wal3-6.1.5 {
	db3 eval COMMIT
	db2 eval { PRAGMA wal_checkpoint }
	set sz1 [file size test.db-wal]
	db2 eval { INSERT INTO t1 VALUES('s', 'e') }
	set sz2 [file size test.db-wal]
	expr {$sz2>$sz1}
	} {1}

	# Test that if [db2] had not interfered when [db] was trying to grab
	# aReadMark[0], it would have been possible to wrap the log in 3.6.1.5.
	#
	do_test wal3-6.1.6 {
	execsql { COMMIT }
	execsql { PRAGMA wal_checkpoint } db2
	execsql {
	BEGIN;
	SELECT * FROM t1;
	}
	} {o t t f f s s e}
	do_test wal3-6.1.7 {
	db2 eval { PRAGMA wal_checkpoint }
	set sz1 [file size test.db-wal]
	db2 eval { INSERT INTO t1 VALUES('n', 't') }
	set sz2 [file size test.db-wal]
	expr {$sz2==$sz1}
	} {1}

	db3 close
	db2 close
	db close

	do_test wal3-6.2.1 {
	file delete -force test.db test.db-journal test.db wal
	sqlite3 db test.db
	sqlite3 db2 test.db
	execsql { PRAGMA auto_vacuum = off }
	execsql { PRAGMA journal_mode = WAL }
	execsql {
	CREATE TABLE t1(a, b);
	INSERT INTO t1 VALUES('h', 'h');
	INSERT INTO t1 VALUES('l', 'b');
	}
	} {}

	T filter xShmLock
	T script lock_callback
	proc lock_callback {method file handle spec} {
	if {$spec == "3 1 unlock exclusive"} {
	T filter {}
	set ::R [db2 eval {
	BEGIN;
	SELECT * FROM t1;
	}]
	}
	}
	do_test wal3-6.2.2 {
	execsql { PRAGMA wal_checkpoint }
	} {0 7 7}
	do_test wal3-6.2.3 {
	set ::R
	} {h h l b}
	do_test wal3-6.2.4 {
	set sz1 [file size test.db-wal]
	execsql { INSERT INTO t1 VALUES('b', 'c'); }
	set sz2 [file size test.db-wal]
	expr {$sz2 > $sz1}
	} {1}
	do_test wal3-6.2.5 {
	db2 eval { COMMIT }
	execsql { PRAGMA wal_checkpoint }
	set sz1 [file size test.db-wal]
	execsql { INSERT INTO t1 VALUES('n', 'o'); }
	set sz2 [file size test.db-wal]
	expr {$sz2 == $sz1}
	} {1}

	db2 close
	db close
	T delete

	#-------------------------------------------------------------------------
	# When opening a read-transaction on a database, if the entire log has
	# not yet been copied to the database file, the reader grabs a read
	# lock on aReadMark[x], where x>0. The following test cases experiment
	# with the outcome of the following:
	#
	# + The reader discovering that between the time when it read the
	# wal-index header and the lock was obtained that a writer has
	# written to the log. In this case the reader should re-read the
	# wal-index header and lock a snapshot corresponding to the new
	# header.
	#
	# + The value in the aReadMark[x] slot has been modified since it was
	# read.
	#
	catch {db close}
	testvfs T -default 1
	do_test wal3-7.1.1 {
	file delete -force test.db test.db-journal test.db wal
	sqlite3 db test.db
	execsql {
	PRAGMA journal_mode = WAL;
	CREATE TABLE blue(red PRIMARY KEY, green);
	}
	} {wal}

	T script method_callback
	T filter xOpen
	proc method_callback {method args} {
	if {$method == "xOpen"} { return "reader" }
	}
	do_test wal3-7.1.2 {
	sqlite3 db2 test.db
	execsql { SELECT * FROM blue } db2
	} {}

	T filter xShmLock
	set ::locks [list]
	proc method_callback {method file handle spec} {
	if {$handle != "reader" } { return }
	if {$method == "xShmLock"} {
	catch { execsql { INSERT INTO blue VALUES(1, 2) } }
	catch { execsql { INSERT INTO blue VALUES(3, 4) } }
	}
	lappend ::locks $spec
	}
	do_test wal3-7.1.3 {
	execsql { SELECT * FROM blue } db2
	} {1 2 3 4}
	do_test wal3-7.1.4 {
	set ::locks
	} {{4 1 lock shared} {4 1 unlock shared} {5 1 lock shared} {5 1 unlock shared}}

	set ::locks [list]
	proc method_callback {method file handle spec} {
	if {$handle != "reader" } { return }
	if {$method == "xShmLock"} {
	catch { execsql { INSERT INTO blue VALUES(5, 6) } }
	}
	lappend ::locks $spec
	}
	do_test wal3-7.2.1 {
	execsql { SELECT * FROM blue } db2
	} {1 2 3 4 5 6}
	do_test wal3-7.2.2 {
	set ::locks
	} {{5 1 lock shared} {5 1 unlock shared} {4 1 lock shared} {4 1 unlock shared}}

	db close
	db2 close
	T delete

	#-------------------------------------------------------------------------
	#
	do_test wal3-8.1 {
	file delete -force test.db test.db-journal test.db wal
	sqlite3 db test.db
	sqlite3 db2 test.db
	execsql {
	PRAGMA auto_vacuum = off;
	PRAGMA journal_mode = WAL;
	CREATE TABLE b(c);
	INSERT INTO b VALUES('Tehran');
	INSERT INTO b VALUES('Qom');
	INSERT INTO b VALUES('Markazi');
	PRAGMA wal_checkpoint;
	}
	} {wal 0 9 9}
	do_test wal3-8.2 {
	execsql { SELECT * FROM b }
	} {Tehran Qom Markazi}
	do_test wal3-8.3 {
	db eval { SELECT * FROM b } {
	db eval { INSERT INTO b VALUES('Qazvin') }
	set r [db2 eval { SELECT * FROM b }]
	break
	}
	set r
	} {Tehran Qom Markazi Qazvin}
	do_test wal3-8.4 {
	execsql {
	INSERT INTO b VALUES('Gilan');
	INSERT INTO b VALUES('Ardabil');
	}
	} {}
	db2 close

	faultsim_save_and_close
	testvfs T -default 1
	faultsim_restore_and_reopen
	T filter xShmLock
	T script lock_callback

	proc lock_callback {method file handle spec} {
	if {$spec == "4 1 unlock exclusive"} {
	T filter {}
	set ::r [catchsql { SELECT * FROM b } db2]
	}
	}
	sqlite3 db test.db
	sqlite3 db2 test.db
	do_test wal3-8.5 {
	execsql { SELECT * FROM b }
	} {Tehran Qom Markazi Qazvin Gilan Ardabil}
	do_test wal3-8.6 {
	set ::r
	} {1 {locking protocol}}

	db close
	db2 close

	faultsim_restore_and_reopen
	sqlite3 db2 test.db
	T filter xShmLock
	T script lock_callback
	proc lock_callback {method file handle spec} {
	if {$spec == "1 7 unlock exclusive"} {
	T filter {}
	set ::r [catchsql { SELECT * FROM b } db2]
	}
	}
	unset ::r
	do_test wal3-8.5 {
	execsql { SELECT * FROM b }
	} {Tehran Qom Markazi Qazvin Gilan Ardabil}
	do_test wal3-8.6 {
	set ::r
	} {1 {locking protocol}}

	db close
	db2 close
	T delete

	#-------------------------------------------------------------------------
	# When a connection opens a read-lock on the database, it searches for
	# an aReadMark[] slot that is already set to the mxFrame value for the
	# new transaction. If it cannot find one, it attempts to obtain an
	# exclusive lock on an aReadMark[] slot for the purposes of modifying
	# the value, then drops back to a shared-lock for the duration of the
	# transaction.
	#
	# This test case verifies that if an exclusive lock cannot be obtained
	# on any aReadMark[] slot (because there are already several readers),
	# the client takes a shared-lock on a slot without modifying the value
	# and continues.
	#
	set nConn 50
	if { [string match *BSD $tcl_platform(os)] } { set nConn 35 }
	do_test wal3-9.0 {
	file delete -force test.db test.db-journal test.db wal
	sqlite3 db test.db
	execsql {
	PRAGMA page_size = 1024;
	PRAGMA journal_mode = WAL;
	CREATE TABLE whoami(x);
	INSERT INTO whoami VALUES('nobody');
	}
	} {wal}
	for {set i 0} {$i < $nConn} {incr i} {
	set c db$i
	do_test wal3-9.1.$i {
	sqlite3 $c test.db
	execsql { UPDATE whoami SET x = $c }
	execsql {
	BEGIN;
	SELECT * FROM whoami
	} $c
	} $c
	}
	for {set i 0} {$i < $nConn} {incr i} {
	set c db$i
	do_test wal3-9.2.$i {
	execsql { SELECT * FROM whoami } $c
	} $c
	}

	set sz [expr 1024 * (2+$AUTOVACUUM)]
	do_test wal3-9.3 {
	for {set i 0} {$i < ($nConn-1)} {incr i} { db$i close }
	execsql { PRAGMA wal_checkpoint }
	byte_is_zero test.db [expr $sz-1024]
	} {1}
	do_test wal3-9.4 {
	db[expr $nConn-1] close
	execsql { PRAGMA wal_checkpoint }
	set sz2 [file size test.db]
	byte_is_zero test.db [expr $sz-1024]
	} {0}

	do_multiclient_test tn {
	do_test wal3-10.$tn.1 {
	sql1 {
	PRAGMA page_size = 1024;
	CREATE TABLE t1(x);
	PRAGMA journal_mode = WAL;
	PRAGMA wal_autocheckpoint = 100000;
	BEGIN;
	INSERT INTO t1 VALUES(randomblob(800));
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 2
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 4
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 8
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 16
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 32
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 64
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 128
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 256
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 512
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 1024
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 2048
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 4096
	INSERT INTO t1 SELECT randomblob(800) FROM t1; -- 8192
	COMMIT;
	CREATE INDEX i1 ON t1(x);
	}

	expr {[file size test.db-wal] > [expr 1032*9000]}
	} 1

	do_test wal3-10.$tn.2 {
	sql2 {PRAGMA integrity_check}
	} {ok}
	}

	finish_test